/usr/lib/swi-prolog/library/MANUAL is in swi-prolog-nox 6.6.6-5.
This file is owned by root:root, with mode 0o644.
The actual contents of the file can be viewed below.
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29108 29109 29110 29111 29112 29113 29114 29115 29116 29117 | VU University Amsterdam University of Amsterdam
~ De1Boelelaan01081a,81 HV Amsterdam KruislaanV419,A1098Amsterdam
The Netherlands The Netherlands
SWI-Prolog 6.6
Reference Manual
_U_p_d_a_t_e_d _f_o_r _v_e_r_s_i_o_n _6_._6_._6_, _M_a_y _2_0_1_4
_J_a_n _W_i_e_l_e_m_a_k_e_r
J.Wielemaker@vu.nl
http://www.swi-prolog.org
SWI-Prolog is a comprehensive and portable implementation of
the Prolog programming language. SWI-Prolog aims to be a
robust and scalable implementation supporting a wide range of
applications. In particular, it ships with a wide range of
interface libraries, providing interfaces to other languages,
databases, graphics and networking. It provides extensive
support for managing HTML/SGML/XML and RDF documents. The
system is particularly suited for server applications due to
robust support for multithreading and HTTP server libraries.
SWI-Prolog is designed in the `Edinburgh tradition'. In
addition to the ISO Prolog standard it is largely compatible
to Quintus, SICStus and YAP Prolog. SWI-Prolog provides a
compatibility framework developed in cooperation with YAP and
instantiated for YAP, SICStus and IF/Prolog.
SWI-Prolog aims at providing a good development environment,
including extensive editor support, graphical source-level
debugger, autoloading and `make' facility and much more.
SWI-Prolog editor and the PDT plugin for Eclipse provide
alternative environments.
This document gives an overview of the features, system limits
and built-in predicates.
~
This work is licensed under the Creative Commons Attribution-
ShareAlike 3.0 Unported License. To view a copy of this
license, visit http://creativecommons.org/licenses/by-sa/3.0/
or send a letter to Creative Commons, 444 Castro Street, Suite
900, Mountain View, California, 94041, USA.
CChhaapptteerr 11.. IINNTTRROODDUUCCTTIIOONN
This document is a _r_e_f_e_r_e_n_c_e _m_a_n_u_a_l. That means that it documents
the system, but it does not explain the basics of the Prolog
language and it leaves many details of the syntax, semantics and
built-in primitives undefined where SWI-Prolog follows the standards.
This manual is intended for people that are familiar with Prolog.
For those not familiar with Prolog, we recommend to start with a
Prolog textbook such as [Bratko, 1986], [Sterling & Shapiro, 1986] or
[Clocksin & Melish, 1987]. For more advanced Prolog usage we recommend
[O'Keefe, 1990].
11..11 PPoossiittiioonniinngg SSWWII--PPrroolloogg
Most implementations of the Prolog language are designed to serve a
limited set of use cases. SWI-Prolog is no exception to this rule.
SWI-Prolog positions itself primarily as a Prolog environment for
`programming in the large' and use cases where it plays a central role
in an application, i.e., where it acts as `glue' between components.
At the same time, SWI-Prolog aims at providing a productive rapid
prototyping environment. Its orientation towards programming in the
large is backed up by scalability, compiler speed, program structuring
(modules), support for multithreading to accommodate servers, Unicode
and interfaces to a large number of document formats, protocols and
programming languages. Prototyping is facilitated by good development
tools, both for command line usage as for usage with graphical
development tools. Demand loading of predicates from the library and
a `make' facility avoids the _r_e_q_u_i_r_e_m_e_n_t for using declarations and
reduces typing.
SWI-Prolog is traditionally strong in education because it is free and
portable, but also because of its compatibility with textbooks and its
easy-to-use environment.
Note that these positions do not imply that the system cannot be used
with other scenarios. SWI-Prolog is used as an embedded language where
it serves as a small rule subsystem in a large application. It is also
used as a deductive database. In some cases this is the right choice
because SWI-Prolog has features that are required in the application,
such as threading or Unicode support. In general though, for example,
GNU-Prolog is more suited for embedding because it is small and can
compile to native code, XSB is better for deductive databases because
it provides advanced resolution techniques (tabling), and ECLiPSe is
better at constraint handling.
The syntax and set of built-in predicates is based on the ISO
standard [Hodgson, 1998]. Most extensions follow the `Edinburgh
tradition' (DEC10 Prolog and C-Prolog) and Quintus Prolog [Qui, 1997].
The infrastructure for constraint programming is based on hProlog
[Demoen, 2002]. Some libraries are copied from the YAP system.
Together with YAP we developed a portability framework (see
section 13). This framework has been filled for SICStus Prolog, YAP
and IF/Prolog.
11..22 SSttaattuuss aanndd rreelleeaasseess
This manual describes version 6.6 of SWI-Prolog. SWI-Prolog is widely
considered to be a robust and scalable implementation of the Prolog
language. It is widely used in education and research. In addition,
it is in use for 247* mission critical commercial server processes.
The site http://www.swi-prolog.org is hosted using the SWI-Prolog HTTP
server infrastructure. It receives approximately 2.3 million hits
and serves approximately 300 Gbytes on manual data and downloads each
month. SWI-Prolog applications range from student assignments to
commercial applications that count more than one million lines of
Prolog code.
SWI-Prolog has two development tracks. _S_t_a_b_l_e releases have an even
_m_i_n_o_r version number (e.g., 6.2.1) and are released as a branch from
the development version when the development version is considered
stable and there is sufficient new functionality to justify a stable
release. Stable releases often get a few patch updates to deal with
installation issues or major flaws. A new _D_e_v_e_l_o_p_m_e_n_t version is
typically released every couple of weeks as a snapshot of the public
git repository. `Extra editions' of the development version may
be released after problems that severely hindered the user in their
progress have been fixed.
Known bugs that are not likely to be fixed soon are described as
footnotes in this manual.
11..33 SShhoouulldd II bbee uussiinngg SSWWII--PPrroolloogg??
There are a number of reasons why it might be better to choose a
commercial, or another free, Prolog system:
o _S_W_I_-_P_r_o_l_o_g _c_o_m_e_s _w_i_t_h _n_o _w_a_r_r_a_n_t_i_e_s
Although the developers or the community often provide a
work-around or a fix for a bug, there is no place you can go to for
guaranteed support. However, the full source archive is available
and can be used to compile and debug SWI-Prolog using free tools on
all major platforms. Users requiring more support should ensure
access to knowledgeable developers.
o _P_e_r_f_o_r_m_a_n_c_e _i_s _y_o_u_r _f_i_r_s_t _c_o_n_c_e_r_n
Various free and commercial systems have better performance. But,
`standard' Prolog benchmarks disregard many factors that are often
critical to the performance of large applications. SWI-Prolog is
not good at fast calling of simple predicates and if-then-else
selection based on simple built-in tests, but it is fast with
dynamic code, meta-calling and predicates that contain large
numbers of clauses. Many of SWI-Prolog's built-in predicates are
written in C and have excellent performance.
o _Y_o_u _n_e_e_d _f_e_a_t_u_r_e_s _n_o_t _o_f_f_e_r_e_d _b_y _S_W_I_-_P_r_o_l_o_g
Although SWI-Prolog has many features, it also lacks some
important features. The most well known is probably _t_a_b_l_i_n_g
[Freire _e_t _a_l_., 1997]. If you require additional features and you
have resources, be it financial or expertise, please contact the
developers.
On the other hand, SWI-Prolog offers some facilities that are widely
appreciated by users:
o _N_i_c_e _e_n_v_i_r_o_n_m_e_n_t
SWI-Prolog provides a good command line environment, including `Do
What I Mean', autocompletion, history and a tracer that operates on
single key strokes. The system automatically recompiles modified
parts of the source code using the make/0 command. The system can
be instructed to open an arbitrary editor on the right file and
line based on its source database. It ships with various graphical
tools and can be combined with the SWI-Prolog editor, PDT (Eclipse
plugin for Prolog) or GNU-Emacs.
o _F_a_s_t _c_o_m_p_i_l_e_r
Even very large applications can be loaded in seconds on most
machines. If this is not enough, there is the Quick Load Format.
See qcompile/1 and qsave_program/2.
o _T_r_a_n_s_p_a_r_e_n_t _c_o_m_p_i_l_e_d _c_o_d_e
SWI-Prolog compiled code can be treated just as interpreted code:
you can list it, trace it, etc. This implies you do not have to
decide beforehand whether a module should be loaded for debugging
or not, and the performance of debugged code is close to that of
normal operation.
o _S_o_u_r_c_e _l_e_v_e_l _d_e_b_u_g_g_e_r
The source level debugger provides a good overview of your
current location in the search tree, variable bindings, your
source code and open choice points. Choice point inspection
provides meaningful insight to both novices and experienced users.
Avoiding unintended choice points often provides a huge increase in
performance and a huge saving in memory usage.
o _P_r_o_f_i_l_i_n_g
SWI-Prolog offers an execution profiler with either textual output
or graphical output. Finding and improving hotspots in a Prolog
program may result in huge speedups.
o _F_l_e_x_i_b_i_l_i_t_y
SWI-Prolog can easily be integrated with C, supporting non-
determinism in Prolog calling C as well as C calling Prolog (see
section 9). It can also be _e_m_b_e_d_d_e_d in external programs (see
section 9.5). System predicates can be redefined locally to
provide compatibility with other Prolog systems.
o _T_h_r_e_a_d_s
Robust support for multiple threads may improve performance and is
a key enabling factor for deploying Prolog in server applications.
o _I_n_t_e_r_f_a_c_e_s
SWI-Prolog ships with many extension packages that provide
robust interfaces to processes, encryption, TCP/IP, TIPC, ODBC,
SGML/XML/HTML, RDF, HTTP, graphics and much more.
11..44 SSuuppppoorrtt tthhee SSWWII--PPrroolloogg pprroojjeecctt
You can support the SWI-Prolog project in several ways. Academics
are invited to cite one of the publications on SWI-Prolog. Users
can help by identifying and/or fixing problems with the code or
its documentation.. Users can contribute new features or, more
lightweight, contribute packs. Commercial users may consider
contacting the developers to sponsor the development of new features
or seek for opportunities to cooperate with the developers or other
commercial users.
11..55 IImmpplleemmeennttaattiioonn hhiissttoorryy
SWI-Prolog started back in 1986 with the requirement for a Prolog that
could handle recursive interaction with the C-language: Prolog calling
C and C calling Prolog recursively. In those days Prolog systems were
not very aware of their environment and we needed such a system to
support interactive applications. Since then, SWI-Prolog's development
has been guided by requests from the user community, especially
focussing on (in arbitrary order) interaction with the environment,
scalability, (I/O) performance, standard compliance, teaching and the
program development environment.
SWI-Prolog is based on a simple Prolog virtual machine called
ZIP [Bowen _e_t _a_l_., 1983, Neumerkel, 1993] which defines only 7
instructions. Prolog can easily be compiled into this language,
and the abstract machine code is easily decompiled back into Prolog.
As it is also possible to wire a standard 4-port debugger in the
virtual machine, there is no need for a distinction between compiled
and interpreted code. Besides simplifying the design of the Prolog
system itself, this approach has advantages for program development:
the compiler is simple and fast, the user does not have to decide
in advance whether debugging is required, and the system only runs
slightly slower in debug mode compared to normal execution. The price
we have to pay is some performance degradation (taking out the debugger
from the VM interpreter improves performance by about 20%) and somewhat
additional memory usage to help the decompiler and debugger.
SWI-Prolog extends the minimal set of instructions described in
[Bowen _e_t _a_l_., 1983] to improve performance. While extending this
set, care has been taken to maintain the advantages of decompilation
and tracing of compiled code. The extensions include specialised
instructions for unification, predicate invocation, some frequently
used built-in predicates, arithmetic, and control (;/2, |/2), if-then
(->/2) and negation-by-failure (\+/1).
11..66 AAcckknnoowwlleeddggeemmeennttss
Some small parts of the Prolog code of SWI-Prolog are modified versions
of the corresponding Edinburgh C-Prolog code: grammar rule compilation
and writef/2. Also some of the C-code originates from C-Prolog:
finding the path of the currently running executable and some of the
code underlying absolute_file_name/2. Ideas on programming style and
techniques originate from C-Prolog and Richard O'Keefe's _t_h_i_e_f editor.
An important source of inspiration are the programming techniques
introduced by Anjo Anjewierden in PCE version 1 and 2.
Our special thanks go to those who had the fate of using the early
versions of this system, suggested extensions or reported bugs. Among
them are Anjo Anjewierden, Huub Knops, Bob Wielinga, Wouter Jansweijer,
Luc Peerdeman, Eric Nombden, Frank van Harmelen, Bert Rengel.
Martin Jansche (jansche@novell1.gs.uni-heidelberg.de) has been so kind
to reorganise the sources for version 2.1.3 of this manual. Horst von
Brand has been so kind to fix many typos in the 2.7.14 manual. Thanks!
Randy Sharp fixed many issues in the 6.0.x version of the manual.
Bart Demoen and Tom Schrijvers have helped me adding coroutining,
constraints, global variables and support for cyclic terms to the
kernel. Tom Schrijvers has provided a first clp(fd) constraint solver,
the CHR compiler and some of the coroutining predicates. Markus Triska
contributed the current clp(fd) implementation.
Paul Singleton has integrated Fred Dushin's Java-calls-Prolog side with
his Prolog-calls-Java side into the current bidirectional JPL interface
package.
Richard O'Keefe is gratefully acknowledged for his efforts to educate
beginners as well as valuable comments on proposed new developments.
Scientific Software and Systems Limited, www.sss.co.nz has sponsored
the development of the SSL library, unbounded integer and rational
number arithmetic and many enhancements to the memory management of the
system.
Leslie de Koninck has made clp(QR) available to SWI-Prolog.
Jeff Rosenwald contributed the TIPC networking library and Google's
protocol buffer handling.
Paulo Moura's great experience in maintaining Logtalk for many
Prolog systems including SWI-Prolog has helped in many places fixing
compatibility issues. He also worked on the MacOS port and fixed many
typos in the 5.6.9 release of the documentation.
CChhaapptteerr 22.. OOVVEERRVVIIEEWW
22..11 GGeettttiinngg ssttaarrtteedd qquuiicckkllyy
22..11..11 SSttaarrttiinngg SSWWII--PPrroolloogg
22..11..11..11 SSttaarrttiinngg SSWWII--PPrroolloogg oonn UUnniixx
By default, SWI-Prolog is installed as `swipl'. The command line
arguments of SWI-Prolog itself and its utility programs are documented
using standard Unix man pages. SWI-Prolog is normally operated as an
interactive application simply by starting the program:
________________________________________________________________________| |
|machine% swipl |
|Welcome to SWI-Prolog ... |
|... |
| |
|1|?-___________________________________________________________________ | |
After starting Prolog, one normally loads a program into it using
consult/1, which may be abbreviated by putting the name of the program
file between square brackets. The following goal loads the file
likes.pl containing clauses for the predicates likes/2:
________________________________________________________________________| |
|?- [likes]. |
|% likes compiled, 0.00 sec, 17 clauses |
|true. |
| |
|?-|____________________________________________________________________ | |
After this point, Unix and Windows users unite, so if you are using
Unix please continue at section 2.1.2.
22..11..11..22 SSttaarrttiinngg SSWWII--PPrroolloogg oonn WWiinnddoowwss
After SWI-Prolog has been installed on a Windows system, the following
important new things are available to the user:
o A folder (called _d_i_r_e_c_t_o_r_y in the remainder of this document)
called swipl containing the executables, libraries, etc., of the
system. No files are installed outside this directory.
o A program swipl-win.exe, providing a window for interaction with
Prolog. The program swipl.exe is a version of SWI-Prolog that runs
in a console window.
o The file extension .pl is associated with the program swipl-
win.exe. Opening a .pl file will cause swipl-win.exe to start,
change directory to the directory in which the file to open
resides, and load this file.
The normal way to start the likes.pl file mentioned in section 2.1.1.1
is by simply double-clicking this file in the Windows explorer.
22..11..22 EExxeeccuuttiinngg aa qquueerryy
After loading a program, one can ask Prolog queries about the program.
The query below asks Prolog what food `sam' likes. The system responds
with X = <_v_a_l_u_e> if it can prove the goal for a certain _X. The user can
type the semi-colon (;) or spacebar if (s)he wants another solution.
Use the return key if you do not want to see the more answers. Prolog
completes the output with a full stop (.) if the user uses the return
key or Prolog _k_n_o_w_s there are no more answers. If Prolog cannot find
(more) answers, it writes ffaallssee.. Finally, Prolog answers using an
error message to indicate the query or program contains an error.
________________________________________________________________________| |
|?- likes(sam, X). |
|X = dahl ; |
|X = tandoori ; |
|... |
|X = chips. |
| |
|?-|____________________________________________________________________ | |
Note that the answer written by Prolog is a valid Prolog program
that, when executed, produces the same set of answers as the original
program.
22..22 TThhee uusseerr''ss iinniittiiaalliissaattiioonn ffiillee
After the system initialisation, the system consults (see consult/1)
the user's startup file. The basename of this file follows conventions
of the operating system. On MS-Windows, it is the file pl.ini and on
Unix systems .plrc. The file is searched using the file_search_path/2
clauses for user_profile. The table below shows the default value for
this search path. The phrase <_a_p_p_d_a_t_a> refers to the Windows CSIDL
name for the folder. The actual name depends on the Windows language.
English versions typically use ApplicationData. See also win_folder/2
__________________________________
|____________|UUnniixx__||WWiinnddoowwss__________________________ ||
||_hhoommee_||~____|<_a_p_p_d_a_t_a>/SWI-Prolog_|
After the first startup file is found it is loaded and Prolog stops
looking for further startup files. The name of the startup file can be
changed with the `-f file' option. If _F_i_l_e denotes an absolute path,
this file is loaded, otherwise the file is searched for using the same
conventions as for the default startup file. Finally, if _f_i_l_e is none,
no file is loaded.
The installation provides a file customize/dotplrc with (commented)
commands that are often used to customize the behaviour of Prolog, such
as interfacing to the editor, color selection or history parameters.
Many of the development tools provide menu entries for editing the
startup file and starting a fresh startup file from the system
skeleton.
See also the -s (script) and -F (system-wide initialisation) in
section 2.4 and section 2.3.
22..33 IInniittiiaalliissaattiioonn ffiilleess aanndd ggooaallss
Using command line arguments (see section 2.4), SWI-Prolog can be
forced to load files and execute queries for initialisation purposes
or non-interactive operation. The most commonly used options are
-f file or -s file to make Prolog load a file, -g goal to define an
initialisation goal and -t goal to define the _t_o_p_-_l_e_v_e_l _g_o_a_l. The
following is a typical example for starting an application directly
from the command line.
________________________________________________________________________| |
|machine%|swipl_-s_load.pl_-g_go_-t_halt________________________________ | |
It tells SWI-Prolog to load load.pl, start the application using
the _e_n_t_r_y _p_o_i_n_t go/0 and ---instead of entering the interactive top
level--- exit after completing go/0. The -q may be used to suppress
all informational messages.
In MS-Windows, the same can be achieved using a short-cut with
appropriately defined command line arguments. A typically seen
alternative is to write a file run.pl with content as illustrated
below. Double-clicking run.pl will start the application.
________________________________________________________________________| |
|:- [load]. % load program |
|:- go. % run it |
|:-|halt.________________________%_and_exit_____________________________ | |
Section 2.10.2.1 discusses further scripting options, and chapter 10
discusses the generation of runtime executables. Runtime executables
are a means to deliver executables that do not require the Prolog
system.
22..44 CCoommmmaanndd lliinnee ooppttiioonnss
SWI-Prolog can be executed in one of the following modes:
swipl --help
swipl --version
swipl --arch
swipl --dump-runtime-variables
These options must appear as only option. They cause Prolog to
print an informational message and exit. See section 2.4.1.
swipl [[_o_p_t_i_o_n ......]] _s_c_r_i_p_t_-_f_i_l_e [[_a_r_g ......]]
These arguments are passed on Unix systems if file that starts with
#!/path/to/executable [_o_p_t_i_o_n ...] is executed. Arguments after
the script file are made available in the Prolog flag argv.
swipl [[_o_p_t_i_o_n ......]] _p_r_o_l_o_g_-_f_i_l_e ...... [[[[--]] _a_r_g ......]]
This is the normal way to start Prolog. The options are described
in section 2.4.2, section 2.4.3 and section 2.4.4. The Prolog flag
argc provides access to _a_r_g ... If the _o_p_t_i_o_n_s are followed by
one or more Prolog file names (i.e., names with extension .pl,
.prolog or (on Windows) the user preferred extension registered
during installation), these files are loaded. The first file
is registered in the Prolog flag associated_file. In addition,
pl-win[.exe] switches to the directory in which this primary source
file is located using working_directory/2.
swipl --oo _o_u_t_p_u_t --cc _p_r_o_l_o_g_-_f_i_l_e ......
The -c option is used to compile a set of Prolog files into an
executable. See section 2.4.5.
swipl --oo _o_u_t_p_u_t --bb _b_o_o_t_f_i_l_e _p_r_o_l_o_g_-_f_i_l_e ......
Bootstrap compilation. See section 2.4.6.
22..44..11 IInnffoorrmmaattiioonnaall ccoommmmaanndd lliinnee ooppttiioonnss
--arch
When given as the only option, it prints the architecture
identifier (see Prolog flag arch) and exits. See also
-dump-runtime-variables. Also available as -arch.
--dump-runtime-variables _[_=_f_o_r_m_a_t_]
When given as the only option, it prints a sequence of variable
settings that can be used in shell scripts to deal with
Prolog parameters. This feature is also used by swipl-ld (see
section 9.5). Below is a typical example of using this feature.
____________________________________________________________________| |
| eval `swipl --dump-runtime-variables` |
||cc_-I$PLBASE/include_-L$PLBASE/lib/$PLARCH_...____________________ ||
The option can be followed by =sh to dump in POSIX shell format
(default) or cmd to dump in MS-Windows cmd.exe compatible format.
--help
When given as the only option, it summarises the most important
options. Also available as -h and -help.
--version
When given as the only option, it summarises the version and the
architecture identifier. Also available as -v.
22..44..22 CCoommmmaanndd lliinnee ooppttiioonnss ffoorr rruunnnniinngg PPrroolloogg
--home=DIR
Use DIR as home directory. See section 9.6 for details.
--quiet
Set the Prolog flag verbose to silent, suppressing informational
and banner messages. Also available as -q.
--nodebug
Disable debugging. See the current_prolog_flag/2 flag
generate_debug_info for details.
--nosignals
Inhibit any signal handling by Prolog, a property that is sometimes
desirable for embedded applications. This option sets the flag
signals to false. See section 9.4.21.1 for details.
--pldoc _[_=_p_o_r_t_]
Start the PlDoc documentation system on a free network port and
launch the user's browser on http://localhost:<_p_o_r_t>. If _p_o_r_t is
specified, the server is started at the given port and the browser
is _n_o_t launched.
-tty
Unix only. Switches controlling the terminal for allowing
single-character commands to the tracer and get_single_char/1. By
default, manipulating the terminal is enabled unless the system
detects it is not connected to a terminal or it is running as a
GNU-Emacs inferior process. This flag is sometimes required for
smooth interaction with other applications.
--win_app
This option is available only in swipl-win.exe and is used
for the start-menu item. If causes plwin to start in the
folder ...\My Documents\Prolog or local equivalent thereof (see
win_folder/2). The Prolog subdirectory is created if it does not
exist.
-O
Optimised compilation. See current_prolog_flag/2flag optimise for
details.
-s _f_i_l_e
Use _f_i_l_e as a script file. The script file is loaded after the
initialisation file specified with the -f file option. Unlike
-f file, using -s does not stop Prolog from loading the personal
initialisation file.
-f _f_i_l_e
Use _f_i_l_e as initialisation file instead of the default .plrc (Unix)
or pl.ini (Windows). `-f none' stops SWI-Prolog from searching for
a startup file. This option can be used as an alternative to
-s file that stops Prolog from loading the personal initialisation
file. See also section 2.2.
-F _s_c_r_i_p_t
Select a startup script from the SWI-Prolog home directory. The
script file is named <_s_c_r_i_p_t>.rc. The default _s_c_r_i_p_t name is
deduced from the executable, taking the leading alphanumerical
characters (letters, digits and underscore) from the program name.
-F none stops looking for a script. Intended for simple management
of slightly different versions. One could, for example, write
a script iso.rc and then select ISO compatibility mode using
pl -F iso or make a link from iso-pl to pl.
-x _b_o_o_t_f_i_l_e
Boot from _b_o_o_t_f_i_l_e instead of the system's default boot file. A
boot file is a file resulting from a Prolog compilation using the
-b or -c option or a program saved using qsave_program/[1,2].
-p _a_l_i_a_s_=_p_a_t_h_1_[_:_p_a_t_h_2 _._._._]
Define a path alias for file_search_path. _a_l_i_a_s is the name
of the alias, and argpath1 ... is a list of values for the
alias. On Windows the list separator is ;. On other systems
it is :. A value is either a term of the form alias(value) or
pathname. The computed aliases are added to file_search_path/2
using asserta/1, so they precede predefined values for the alias.
See file_search_path/2 for details on using this file location
mechanism.
--
Stops scanning for more arguments, so you can pass arguments for
your application after this one. See current_prolog_flag/2 using
the flag argv for obtaining the command line arguments.
22..44..33 CCoonnttrroolllliinngg tthhee ssttaacckk ssiizzeess
The default limit for the Prolog stacks is 128 MB on 32-bit and 256 MB
on 64-bit hardware. The 128 MB limit on 32-bit systems is the highest
possible value and the command line options can thus only be used to
lower the limit. On 64-bit systems, the limit can both be reduced
and enlarged. See section 2.19. Below are two examples, the first
reducing the local stack limit to catch unbounded recursion quickly and
the second using a big (32 GB) global limit, which is only possible on
64-bit hardware. Note that setting the limit using the command line
only sets a _s_o_f_t limit. Stack parameters can be changed (both reduced
and enlarged) at any time using the predicate set_prolog_stack/2.
________________________________________________________________________| |
|$ swipl -L8m |
|$|swipl_-G32g__________________________________________________________ | |
-G_s_i_z_e_[_k_m_g_]
Limit for the global stack (sometimes also called _t_e_r_m _s_t_a_c_k or
_h_e_a_p). This is where compound terms and large numbers live.
-L_s_i_z_e_[_k_m_g_]
Limit for the local stack (sometimes also called _e_n_v_i_r_o_n_m_e_n_t
_s_t_a_c_k). This is where environments and choice points live.
-T_s_i_z_e_[_k_m_g_]
Limit for the trail stack. This is where we keep track of
assignments, so we can rollback on backtracking or exceptions.
22..44..44 RRuunnnniinngg ggooaallss ffrroomm tthhee ccoommmmaanndd lliinnee
-g _g_o_a_l
_G_o_a_l is executed just before entering the top level. Default is a
predicate which prints the welcome message. The welcome message
can be suppressed with --quiet, but also with -g true. _g_o_a_l can be
a complex term. In this case quotes are normally needed to protect
it from being expanded by the shell. A safe way to run a goal
non-interactively is here:
____________________________________________________________________| |
||%_swipl_<options>_-g_go,halt_-t_'halt(1)'_________________________ ||
-t _g_o_a_l
Use _g_o_a_l as interactive top level instead of the default goal
prolog/0. _g_o_a_l can be a complex term. If the top-level goal
succeeds SWI-Prolog exits with status 0. If it fails the exit
status is 1. If the top level raises an exception, this is printed
as an uncaught error and the top level is restarted. This flag
also determines the goal started by break/0 and abort/0. If you
want to stop the user from entering interactive mode, start the
application with `-g goal' and give `halt' as top level.
22..44..55 CCoommppiillaattiioonn ooppttiioonnss
-c _f_i_l_e _._._.
Compile files into an `intermediate code file'. See section 2.10.
-o _o_u_t_p_u_t
Used in combination with -c or -b to determine output file for
compilation.
22..44..66 MMaaiinntteennaannccee ooppttiioonnss
The following options are for system maintenance. They are given for
reference only.
-b _i_n_i_t_f_i_l_e _._._.-c _f_i_l_e _._._.
Boot compilation. _i_n_i_t_f_i_l_e _._._. are compiled by the C-written
bootstrap compiler, _f_i_l_e _._._. by the normal Prolog compiler.
System maintenance only.
-d _t_o_k_e_n_1_,_t_o_k_e_n_2_,_._._.
Print debug messages for DEBUG statements tagged with one of the
indicated tokens. Only has effect if the system is compiled with
the -DO_DEBUG flag. System maintenance only.
22..55 GGNNUU EEmmaaccss IInntteerrffaaccee
Unfortunately the default Prolog mode of GNU-Emacs is not very good.
There are several alternatives though:
o http://turing.ubishops.ca/home/bruda/emacs-prolog/
o http://stud4.tuwien.ac.at/ e0225855/ediprolog/ediprolog.html
o http://stud4.tuwien.ac.at/ e0225855/pceprolog/pceprolog.html
o http://stud4.tuwien.ac.at/ e0225855/etrace/etrace.html
22..66 OOnnlliinnee HHeellpp
SWI-Prolog provides an online help system that covers this manual.
If the XPCE graphics system is available, online help opens a
graphical window. Otherwise the documentation is shown in the
Prolog console. The help system is controlled by the predicates
below. Note that this help system only covers the core SWI-Prolog
manual. The website provides an integrated manual that covers the core
system as well as all standard extension packages. It is possible
to install the SWI-Prolog website locally by cloning the website
repository git://www.swi-prolog.org/home/pl/git/plweb.git and following
the instructions in the README file.
hheellpp
Equivalent to help(help/1).
hheellpp((_+_W_h_a_t))
Show specified part of the manual. _W_h_a_t is one of:
<_N_a_m_e>/<_A_r_i_t_y> Give help on specified predicate
<_N_a_m_e> Give help on named predicate with any
arity or C interface function with that
name
<_S_e_c_t_i_o_n> Display specified section. Section
numbers are dash-separated numbers: 2-3
refers to section 2.3 of the manual.
Section numbers are obtained using
apropos/1.
Examples:
?- help(assert). Give help on predicate assert
?- help(3-4). Display section 3.4 of the manual
?- help('PL_retry'). Give help on interface function
PL_retry()
See also apropos/1 and the SWI-Prolog home page at http://www.swi-
prolog.org, which provides a FAQ, an HTML version of the manual for
online browsing, and HTML and PDF versions for downloading.
aapprrooppooss((_+_P_a_t_t_e_r_n))
Display all predicates, functions and sections that have _P_a_t_t_e_r_n in
their name or summary description. Lowercase letters in _P_a_t_t_e_r_n
also match a corresponding uppercase letter. Example:
?- apropos(file). Display predicates, functions
and sections that have `file'
(or `File', etc.) in their
summary description.
eexxppllaaiinn((_+_T_o_E_x_p_l_a_i_n))
Give an explanation on the given `object'. The argument may be any
Prolog data object. If the argument is an atom, a term of the
form _N_a_m_e_/_A_r_i_t_y or a term of the form _M_o_d_u_l_e_:_N_a_m_e_/_A_r_i_t_y, explain/1
describes the predicate as well as possible references to it. See
also gxref/0.
eexxppllaaiinn((_+_T_o_E_x_p_l_a_i_n_, _-_E_x_p_l_a_n_a_t_i_o_n))
Unify _E_x_p_l_a_n_a_t_i_o_n with an explanation for _T_o_E_x_p_l_a_i_n. Backtracking
yields further explanations.
22..77 CCoommmmaanndd lliinnee hhiissttoorryy
SWI-Prolog offers a query substitution mechanism similar to what is
seen in Unix shells. The availability of this feature is controlled by
set_prolog_flag/2, using the history Prolog flag. By default, history
is available if the Prolog flag readline is false. To enable this
feature, remembering the last 50 commands, put the following into your
startup file (see section 2.2):
________________________________________________________________________| |
|:-|set_prolog_flag(history,_50)._______________________________________ | |
The history system allows the user to compose new queries from those
typed before and remembered by the system. The available history
commands are shown in table 2.1. History expansion is not done if
these sequences appear in quoted atoms or strings.
______________________________________________
| !!. |Repeat last query |
| !nr. |Repeat query numbered <_n_r> |
| !str. |Repeat last query starting with <_s_t_r> |
| h. |Show history of commands |
|_!h.___|Show_this_list_______________________ |
Table 2.1: History commands
22..88 RReeuussee ooff ttoopp--lleevveell bbiinnddiinnggss
Bindings resulting from the successful execution of a top-level goal
are asserted in a database _i_f _t_h_e_y _a_r_e _n_o_t _t_o_o _l_a_r_g_e. These values may
be reused in further top-level queries as $Var. If the same variable
name is used in a subsequent query the system associates the variable
with the latest binding. Example:
________________________________________________________________________| |
|1 ?- maplist(plus(1), "hello", X). |
|X = [105,102,109,109,112]. |
| |
|2 ?- format('~s~n', [$X]). |
|ifmmp |
|true. |
| |
|3|?-___________________________________________________________________ | |
Figure 2.1: Reusing top-level bindings
Note that variables may be set by executing =/2:
________________________________________________________________________| |
|6 ?- X = statistics. |
|X = statistics. |
| |
|7 ?- $X. |
|28.00 seconds cpu time for 183,128 inferences |
|4,016 atoms, 1,904 functors, 2,042 predicates, 52 modules |
|55,915 byte codes; 11,239 external references |
| |
| Limit Allocated In use |
|Heap : 624,820 Bytes |
|Local stack : 2,048,000 8,192 404 Bytes |
|Global stack : 4,096,000 16,384 968 Bytes |
|Trail stack : 4,096,000 8,192 432 Bytes |
|true.|_________________________________________________________________ | |
22..99 OOvveerrvviieeww ooff tthhee DDeebbuuggggeerr
SWI-Prolog has a 6-port tracer, extending the standard 4-port tracer
[Byrd, 1980, Clocksin & Melish, 1987] with two additional ports. The
optional _u_n_i_f_y port allows the user to inspect the result after
unification of the head. The _e_x_c_e_p_t_i_o_n port shows exceptions raised by
throw/1 or one of the built-in predicates. See section 4.10.
The standard ports are called call, exit, redo, fail and unify. The
tracer is started by the trace/0 command, when a spy point is reached
and the system is in debugging mode (see spy/1 and debug/0), or when an
exception is raised that is not caught.
The interactive top-level goal trace/0 means ``trace the next query''.
The tracer shows the port, displaying the port name, the current depth
of the recursion and the goal. The goal is printed using the Prolog
predicate write_term/2. The style is defined by the Prolog flag
debugger_print_options and can be modified using this flag or using the
w, p and d commands of the tracer.
________________________________________________________________________| |
|min_numlist([H|T], Min) :- |
| min_numlist(T, H, Min). |
| |
|min_numlist([], Min, Min). |
|min_numlist([H|T], Min0, Min) :- |
| Min1 is min(H, Min0), |
||_______min_numlist(T,_Min1,_Min)._____________________________________ ||
________________________________________________________________________| |
|1 ?- visible(+all), leash(-exit). |
|true. |
| |
|2 ?- trace, min_numlist([3, 2], X). |
| Call: (7) min_numlist([3, 2], _G0) ? creep |
| Unify: (7) min_numlist([3, 2], _G0) |
| Call: (8) min_numlist([2], 3, _G0) ? creep |
| Unify: (8) min_numlist([2], 3, _G0) |
|^ Call: (9) _G54 is min(2, 3) ? creep |
|^ Exit: (9) 2 is min(2, 3) |
| Call: (9) min_numlist([], 2, _G0) ? creep |
| Unify: (9) min_numlist([], 2, 2) |
| Exit: (9) min_numlist([], 2, 2) |
| Exit: (8) min_numlist([2], 3, 2) |
| Exit: (7) min_numlist([3, 2], 2) |
|X|=_2._________________________________________________________________ | |
Figure 2.2: Example trace of the program above showing all ports.
The lines marked ^ indicate calls to _t_r_a_n_s_p_a_r_e_n_t predicates. See
section 5.
On _l_e_a_s_h_e_d _p_o_r_t_s (set with the predicate leash/1, default are call,
exit, redo and fail) the user is prompted for an action. All actions
are single-character commands which are executed wwiitthhoouutt waiting for a
return, unless the command line option -tty is active. Tracer options:
+ ((SSppyy))
Set a spy point (see spy/1) on the current predicate.
- ((NNoo ssppyy))
Remove the spy point (see nospy/1) from the current predicate.
/ ((FFiinndd))
Search for a port. After the `/', the user can enter a line to
specify the port to search for. This line consists of a set of
letters indicating the port type, followed by an optional term,
that should unify with the goal run by the port. If no term is
specified it is taken as a variable, searching for any port of the
specified type. If an atom is given, any goal whose functor has a
name equal to that atom matches. Examples:
/f Search for any fail port
/fe solve Search for a fail or exit port of
any goal with name solve
/c solve(a, _) Search for a call to solve/2 whose
first argument is a variable or the
atom a
/a member(_, _) Search for any port on member/2.
This is equivalent to setting a spy
point on member/2.
. ((RReeppeeaatt ffiinndd))
Repeat the last find command (see `/').
A ((AAlltteerrnnaattiivveess))
Show all goals that have alternatives.
C ((CCoonntteexxtt))
Toggle `Show Context'. If on, the context module of the goal is
displayed between square brackets (see section 5). Default is off.
L ((LLiissttiinngg))
List the current predicate with listing/1.
a ((AAbboorrtt))
Abort Prolog execution (see abort/0).
b ((BBrreeaakk))
Enter a Prolog break environment (see break/0).
c ((CCrreeeepp))
Continue execution, stop at next port. (Also return, space).
d ((DDiissppllaayy))
Set the max_depth(_D_e_p_t_h) option of debugger_print_options, limiting
the depth to which terms are printed. See also the w and p
options.
e ((EExxiitt))
Terminate Prolog (see halt/0).
f ((FFaaiill))
Force failure of the current goal.
g ((GGooaallss))
Show the list of parent goals (the execution stack). Note that due
to tail recursion optimization a number of parent goals might not
exist any more.
h ((HHeellpp))
Show available options (also `?').
i ((IIggnnoorree))
Ignore the current goal, pretending it succeeded.
l ((LLeeaapp))
Continue execution, stop at next spy point.
n ((NNoo ddeebbuugg))
Continue execution in `no debug' mode.
p ((PPrriinntt))
Set the Prolog flag debugger_print_options to [quoted(true), por-
tray(true), max_depth(10), priority(699)]. This is the default.
r ((RReettrryy))
Undo all actions (except for database and I/O actions) back to the
call port of the current goal and resume execution at the call
port.
s ((SSkkiipp))
Continue execution, stop at the next port of tthhiiss goal (thus
skipping all calls to children of this goal).
u ((UUpp))
Continue execution, stop at the next port of tthhee ppaarreenntt goal (thus
skipping this goal and all calls to children of this goal). This
option is useful to stop tracing a failure driven loop.
w ((WWrriittee))
Set the Prolog flag debugger_print_options to [quoted(true), at-
tributes(write), priority(699)], bypassing portray/1, etc.
The ideal 4-port model [Byrd, 1980] as described in many Prolog books
[Clocksin & Melish, 1987] is not visible in many Prolog implementations
because code optimisation removes part of the choice and exit
points. Backtrack points are not shown if either the goal succeeded
deterministically or its alternatives were removed using the cut. When
running in debug mode (debug/0) choice points are only destroyed when
removed by the cut. In debug mode, last call optimisation is switched
off.
Reference information to all predicates available for manipulating the
debugger is in section 4.38.
22..1100 CCoommppiillaattiioonn
22..1100..11 DDuurriinngg pprrooggrraamm ddeevveellooppmmeenntt
During program development, programs are normally loaded using the
list abbreviation (?- [load].). It is common practice to organise a
project as a collection of source files and a _l_o_a_d _f_i_l_e, a Prolog file
containing only use_module/[1,2] or ensure_loaded/1 directives, possibly
with a definition of the _e_n_t_r_y _p_o_i_n_t of the program, the predicate that
is normally used to start the program. This file is often called
load.pl. If the entry point is called _g_o, a typical session starts as:
________________________________________________________________________| |
|% swipl |
|<banner> |
| |
|1 ?- [load]. |
|<compilation messages> |
|true. |
| |
|2 ?- go. |
|<program|interaction>__________________________________________________ | |
When using Windows, the user may open load.pl from the Windows
explorer, which will cause swipl-win.exe to be started in the directory
holding load.pl. Prolog loads load.pl before entering the top level.
If Prolog is started from an interactive shell, one may choose the type
swipl -s load.pl.
22..1100..22 FFoorr rruunnnniinngg tthhee rreessuulltt
There are various options if you want to make your program ready for
real usage. The best choice depends on whether the program is to be
used only on machines holding the SWI-Prolog development system, the
size of the program, and the operating system (Unix vs. Windows).
22..1100..22..11 UUssiinngg PPrroollooggSSccrriipptt
A Prolog source file can be used directly as a Unix program using the
Unix #! magic start. The same mechanism is useful for specifying
additional parameters for running a Prolog file on Windows. The Unix
#! magic is allowed because if the first letter of a Prolog file is #,
the first line is treated as a comment. To create a Prolog script,
make the first line start like this:
#!/path/to/swipl <_o_p_t_i_o_n_s> -s
Prolog recognises this starting sequence and causes the interpreter to
receive the following argument list:
/path/to/swipl <_o_p_t_i_o_n_s> -s <_s_c_r_i_p_t> -- <_S_c_r_i_p_t_A_r_g_u_m_e_n_t_s>
Instead of -s, the user may use -f to stop Prolog from looking for a
personal initialisation file.
Here is a simple script doing expression evaluation:
________________________________________________________________________| |
|#!/usr/bin/swipl -q -t main -f |
| |
|eval :- |
| current_prolog_flag(argv, Argv), |
| append(_, [--|Args], Argv), |
| concat_atom(Args, ' ', SingleArg), |
| term_to_atom(Term, SingleArg), |
| Val is Term, |
| format('~w~n', [Val]). |
| |
|main :- |
| catch(eval, E, (print_message(error, E), fail)), |
| halt. |
|main :- |
||_______halt(1)._______________________________________________________ ||
And here are two example runs:
________________________________________________________________________| |
|% eval 1+2 |
|3 |
|% eval foo |
|ERROR: Arithmetic: `foo/0' is not a function |
|%|_____________________________________________________________________ | |
TThhee WWiinnddoowwss vveerrssiioonn supports the #! construct too, but here it serves
a rather different role. The Windows shell already allows the user
to start Prolog source files directly through the Windows file-type
association. However, Windows makes it rather complicated to provide
additional parameters for opening an individual Prolog file. If the
file starts with #!, the first line is analysed to obtain additional
command line arguments. The example below runs the system in `quiet'
mode.
________________________________________________________________________| |
|#!/usr/bin/swipl -q -s |
| |
|....|__________________________________________________________________ | |
Note the use of /usr/bin/swipl, which specifies the interpreter. This
argument is ignored in the Windows version, but must be present to
ensure best cross-platform compatibility.
22..1100..22..22 CCrreeaattiinngg aa sshheellll ssccrriipptt
With the introduction of _P_r_o_l_o_g_S_c_r_i_p_t (see section 2.10.2.1), using
shell scripts as explained in this section has become redundant for
most applications.
Especially on Unix systems and not-too-large applications, writing a
shell script that simply loads your application and calls the entry
point is often a good choice. A skeleton for the script is given
below, followed by the Prolog code to obtain the program arguments.
________________________________________________________________________| |
|#!/bin/sh |
| |
|base=<absolute-path-to-source> |
|PL=swipl |
| |
|exec|$PL_-q_-f_'$base/load_-t_go_--_**_________________________________ | |
________________________________________________________________________| |
|go :- |
| current_prolog_flag(argv, Arguments), |
| append(_SytemArgs, [--|Args], Arguments), !, |
| go(Args). |
| |
|go(Args) :- |
||_______...____________________________________________________________ ||
On Windows systems, similar behaviour can be achieved by creating a
shortcut to Prolog, passing the proper options or writing a .bat file.
22..1100..22..33 CCrreeaattiinngg aa ssaavveedd ssttaattee
For larger programs, as well as for programs that are required to
run on systems that do not have the SWI-Prolog development system
installed, creating a saved state is the best solution. A saved
state is created using qsave_program/[1,2] or the -c command line
option. A saved state is a file containing machine-independent
intermediate code in a format dedicated for fast loading. Optionally,
the emulator may be integrated in the saved state, creating a single
file, but machine-dependent, executable. This process is described in
chapter 10.
22..1100..22..44 CCoommppiillaattiioonn uussiinngg tthhee --cc ccoommmmaanndd lliinnee ooppttiioonn
This mechanism loads a series of Prolog source files and then creates a
saved state as qsave_program/2 does. The command syntax is:
________________________________________________________________________| |
|%|swipl_[option_...]_[-o_output]_-c_file.pl_...________________________ | |
The _o_p_t_i_o_n_s argument are options to qsave_program/2 written in the
format below. The option names and their values are described with
qsave_program/2.
--_o_p_t_i_o_n_-_n_a_m_e=_o_p_t_i_o_n_-_v_a_l_u_e
For example, to create a stand-alone executable that starts by
executing main/0 and for which the source is loaded through load.pl,
use the command
________________________________________________________________________| |
|%|swipl_--goal=main_--stand_alone=true_-o_myprog_-c_load.pl____________ | |
This performs exactly the same as executing
________________________________________________________________________| |
|% swipl |
|<banner> |
| |
|?- [load]. |
|?- qsave_program(myprog, |
| [ goal(main), |
| stand_alone(true) |
| ]). |
|?-|halt._______________________________________________________________ | |
22..1111 EEnnvviirroonnmmeenntt CCoonnttrrooll ((PPrroolloogg ffllaaggss))
The predicates current_prolog_flag/2 and set_prolog_flag/2 allow the
user to examine and modify the execution environment. It provides
access to whether optional features are available on this version,
operating system, foreign code environment, command line arguments,
version, as well as runtime flags to control the runtime behaviour
of certain predicates to achieve compatibility with other Prolog
environments.
ccuurrrreenntt__pprroolloogg__ffllaagg((_?_K_e_y_, _-_V_a_l_u_e)) _[_I_S_O_]
The predicate current_prolog_flag/2defines an interface to instal-
lation features: options compiled in, version, home, etc. With
both arguments unbound, it will generate all defined Prolog flags.
With `Key' instantiated, it unifies the value of the Prolog flag.
Flag values are typed. Flags marked as bool can have the values
true or false. Some Prolog flags are not defined in all versions,
which is normally indicated in the documentation below as _`_`_i_f
_p_r_e_s_e_n_t _a_n_d _t_r_u_e_'_'. A boolean Prolog flag is true iff the Prolog
flag is present aanndd the _V_a_l_u_e is the atom true. Tests for such
flags should be written as below:
____________________________________________________________________| |
| ( current_prolog_flag(windows, true) |
| -> <Do MS-Windows things> |
| ; <Do normal things> |
||________)_________________________________________________________ ||
Some Prolog flags are scoped to a source file. This implies
that if they are set using a directive inside a file, the flag
value encountered when loading of the file started is restored when
loading of the file is completed. Currently, the following flags
are scoped to the source file: generate_debug_info and optimise.
A new thread (see section 8) _c_o_p_i_e_s all flags from the thread that
created the new thread (its _p_a_r_e_n_t). As a consequence, modifying a
flag inside a thread does not affect other threads.
aacccceessss__lleevveell _(_a_t_o_m_, _c_h_a_n_g_e_a_b_l_e_)
This flag defines a normal `user' view (user, default) or
a `system' view. In system view all system code is fully
accessible as if it was normal user code. In user view,
certain operations are not permitted and some details are kept
invisible. We leave the exact consequences undefined, but,
for example, system code can be traced using system access and
system predicates can be redefined.
aaddddrreessss__bbiittss _(_i_n_t_e_g_e_r_)
Address size of the hosting machine. Typically 32 or 64.
Except for the maximum stack limit, this has few implications
to the user. See also the Prolog flag arch.
aaggcc__mmaarrggiinn _(_i_n_t_e_g_e_r_, _c_h_a_n_g_e_a_b_l_e_)
If this amount of atoms possible garbage atoms exist perform
atom garbage collection at the first opportunity. Initial
value is 10,000. May be changed. A value of 0 (zero)
disables atom garbage collection. See also PL_register_atom().
aappppllee _(_b_o_o_l_)
If present and true, the operating system is MacOSX. Defined
if the C compiler used to compile this version of SWI-Prolog
defines __APPLE__. Note that the unix is also defined for
MacOSX.
aallllooww__vvaarriiaabbllee__nnaammee__aass__ffuunnccttoorr _(_b_o_o_l_, _c_h_a_n_g_e_a_b_l_e_)
If true (default is false), Functor(arg) is read as if it
were written 'Functor'(arg). Some applications use the Prolog
read/1 predicate for reading an application-defined script
language. In these cases, it is often difficult to explain
to non-Prolog users of the application that constants and
functions can only start with a lowercase letter. Variables
can be turned into atoms starting with an uppercase atom by
calling read_term/2 using the option variable_names and binding
the variables to their name. Using this feature, F(x) can be
turned into valid syntax for such script languages. Suggested
by Robert van Engelen. SWI-Prolog specific.
aarrggvv _(_l_i_s_t_, _c_h_a_n_g_e_a_b_l_e_)
List is a list of atoms representing the application command
line arguments. Application command line arguments are
those that have _n_o_t been processed by Prolog during its
initialization. Note that Prolog's argument processing stops
at -- or the first non-option argument. See also os_argv.
aarrcchh _(_a_t_o_m_)
Identifier for the hardware and operating system SWI-Prolog
is running on. Used to select foreign files for the right
architecture. See also section 9.2.3 and file_search_path/2.
aassssoocciiaatteedd__ffiillee _(_a_t_o_m_)
Set if Prolog was started with a prolog file as argument.
Used by e.g., edit/0 to edit the initial file.
aauuttoollooaadd _(_b_o_o_l_, _c_h_a_n_g_e_a_b_l_e_)
If true (default) autoloading of library functions is enabled.
bbaacckkqquuootteedd__ssttrriinngg _(_b_o_o_l_, _c_h_a_n_g_e_a_b_l_e_)
If true (default false), read translates text between back-
quotes into a string object (see section 4.24). This flag is
mainly for compatibility with LPA Prolog.
bboouunnddeedd _(_b_o_o_l_)
ISO Prolog flag. If true, integer representation is bound
by min_integer and max_integer. If false integers can be
arbitrarily large and the min_integer and max_integer are not
present. See section 4.27.2.1.
bbrreeaakk__lleevveell _(_i_n_t_e_g_e_r_)
Current break-level. The initial top level (started with -t)
has value 0. See break/0. This flag is absent from threads
that are not running a top-level loop.
cc__cccc _(_a_t_o_m_, _c_h_a_n_g_e_a_b_l_e_)
Name of the C compiler used to compile SWI-Prolog. Normally
either gcc or cc. See section 9.5.
cc__ccffllaaggss _(_a_t_o_m_, _c_h_a_n_g_e_a_b_l_e_)
CFLAGS used to compile SWI-Prolog. See section 9.5.
cc__llddffllaaggss _(_a_t_o_m_, _c_h_a_n_g_e_a_b_l_e_)
LDFLAGS used to link SWI-Prolog. See section 9.5.
cc__lliibbss _(_a_t_o_m_, _c_h_a_n_g_e_a_b_l_e_)
Libraries needed to link executables that embed SWI-Prolog.
Typically -lswipl if the SWI-Prolog kernel is a shared (DLL).
If the SWI-Prolog kernel is in a static library, this flag
also contains the dependencies.
cc__lliibbppllssoo _(_a_t_o_m_, _c_h_a_n_g_e_a_b_l_e_)
Libraries needed to link extensions (shared object, DLL) to
SWI-Prolog. Typically empty on ELF systems and -lswipl on
COFF-based systems. See section 9.5.
cchhaarr__ccoonnvveerrssiioonn _(_b_o_o_l_, _c_h_a_n_g_e_a_b_l_e_)
Determines whether character conversion takes place while
reading terms. See also char_conversion/2.
cchhaarraacctteerr__eessccaappeess _(_b_o_o_l_, _c_h_a_n_g_e_a_b_l_e_)
If true (default), read/1 interprets \ escape sequences in
quoted atoms and strings. May be changed. This flag is local
to the module in which it is changed.
ccoolloonn__sseettss__ccaalllliinngg__ccoonntteexxtt _(_b_o_o_l_)
Using the construct <_m_o_d_u_l_e>:<_g_o_a_l> sets the _c_a_l_l_i_n_g _c_o_n_t_e_x_t for
executing <_g_o_a_l>. This flag is defined by ISO/IEC 13211-2
(Prolog modules standard). See section 5.
ccoolloorr__tteerrmm _(_b_o_o_l_, _c_h_a_n_g_e_a_b_l_e_)
This flag is managed by library ansi_term, which is loaded at
startup if the two conditions below are both true. Note that
this implies that setting this flag to false from the system
or personal initialization file (see section 2.2 disables
colored output. The predicate message_property/2 can be used
to control the actual color scheme depending in the message
type passed to print_message/2.
o stream_property(current_output, tty(true))
o \+ current_prolog_flag(color_term, false)
ccoommppiillee__mmeettaa__aarrgguummeennttss _(_a_t_o_m_, _c_h_a_n_g_e_a_b_l_e_)
Experimental flag that controls compilation of arguments
passed to meta-calls marked `0' or `^' (see meta_predicate/1).
Supported values are:
ffaallssee
(default). Meta-arguments are passed verbatim.
ccoonnttrrooll
Compile meta-arguments that contain control structures
((A,B), (A;B), (A->B;C), etc.). If not compiled at
compile time, such arguments are compiled to a temporary
clause before execution. Using this option enhances
performance of processing complex meta-goals that are
known at compile time.
ttrruuee
Also compile references to normal user predicates. This
harms performance (a little), but enhances the power of
poor-mens consistency check used by make/0 and implemented
by list_undefined/0.
aallwwaayyss
Always create an intermediate clause, even for system
predicates. This prepares for replacing the normal
head of the generated predicate with a special reference
(similar to database references as used by, e.g.,
assert/2) that provides direct access to the executable
code, thus avoiding runtime lookup of predicates for
meta-calling.
ccoommppiilleedd__aatt _(_a_t_o_m_)
Describes when the system has been compiled. Only available
if the C compiler used to compile SWI-Prolog provides the
__DATE__and __TIME__macros.
ccoonnssoollee__mmeennuu _(_b_o_o_l_)
Set to true in swipl-win.exe to indicate that the console
supports menus. See also section 4.34.3.
ccppuu__ccoouunntt _(_i_n_t_e_g_e_r_, _c_h_a_n_g_e_a_b_l_e_)
Number of physical CPUs or cores in the system. The flag is
marked read-write both to allow pretending the system has more
or less processors. See also thread_setconcurrency/2 and the
library thread. This flag is not available on systems where
we do not know how to get the number of CPUs. This flag is
not included in a saved state (see qsave_program/1).
ddddee _(_b_o_o_l_)
Set to true if this instance of Prolog supports DDE as
described in section 4.42.
ddeebbuugg _(_b_o_o_l_, _c_h_a_n_g_e_a_b_l_e_)
Switch debugging mode on/off. If debug mode is activated
the system traps encountered spy points (see spy/1) and trace
points (see trace/1). In addition, last-call optimisation
is disabled and the system is more conservative in destroying
choice points to simplify debugging.
Disabling these optimisations can cause the system to run out
of memory on programs that behave correctly if debug mode is
off.
ddeebbuugg__oonn__eerrrroorr _(_b_o_o_l_, _c_h_a_n_g_e_a_b_l_e_)
If true, start the tracer after an error is detected.
Otherwise just continue execution. The goal that raised the
error will normally fail. See also fileerrors/2 and the
Prolog flag report_error. May be changed. Default is true,
except for the runtime version.
ddeebbuuggggeerr__pprriinntt__ooppttiioonnss _(_t_e_r_m_, _c_h_a_n_g_e_a_b_l_e_)
This argument is given as option-list to write_term/2 for
printing goals by the debugger. Modified by the `w', `p' and
`<_N> d' commands of the debugger. Default is [quoted(true),
portray(true), max_depth(10), attributes(portray)].
ddeebbuuggggeerr__sshhooww__ccoonntteexxtt _(_b_o_o_l_, _c_h_a_n_g_e_a_b_l_e_)
If true, show the context module while printing a stack-frame
in the tracer. Normally controlled using the `C' option of
the tracer.
ddiiaalleecctt _(_a_t_o_m_)
Fixed to swi. The code below is a reliable and portable way
to detect SWI-Prolog.
_______________________________________________________________| |
|is_dialect(swi) :- |
||_______catch(current_prolog_flag(dialect,_swi),__,_fail).____ ||
ddoouubbllee__qquuootteess _(_c_o_d_e_s_,_c_h_a_r_s_,_a_t_o_m_,_s_t_r_i_n_g_, _c_h_a_n_g_e_a_b_l_e_)
This flag determines how double quoted strings are read by
Prolog and is ---like character_escapes--- maintained for each
module. If codes (default), a list of character codes is
returned, if chars a list of one-character atoms, if atom
double quotes are the same as single quotes and finally,
string reads the text into a Prolog string (see section 4.24).
See also atom_chars/2 and atom_codes/2.
eeddiittoorr _(_a_t_o_m_, _c_h_a_n_g_e_a_b_l_e_)
Determines the editor used by edit/1. See section 4.5 for
details on selecting the editor used.
eemmaaccss__iinnffeerriioorr__pprroocceessss _(_b_o_o_l_)
If true, SWI-Prolog is running as an _i_n_f_e_r_i_o_r _p_r_o_c_e_s_s of
(GNU/X-)Emacs. SWI-Prolog assumes this is the case if the
environment variable EMACS is t and INFERIOR is yes.
eennccooddiinngg _(_a_t_o_m_, _c_h_a_n_g_e_a_b_l_e_)
Default encoding used for opening files in text mode. The
initial value is deduced from the environment. See
section 2.18.1 for details.
eexxeeccuuttaabbllee _(_a_t_o_m_)
Pathname of the running executable. Used by qsave_program/2 as
default emulator.
eexxiitt__ssttaattuuss _(_i_n_t_e_g_e_r_)
Set by halt/1 to its argument, making the exit status
available to hooks registered with at_halt/1.
ffiillee__nnaammee__vvaarriiaabblleess _(_b_o_o_l_, _c_h_a_n_g_e_a_b_l_e_)
If true (default false), expand $_v_a_r_n_a_m_e and ~ in ar-
guments of built-in predicates that accept a file name
(open/3, exists_file/1, access_file/2, etc.). The predicate
expand_file_name/2 can be used to expand environment variables
and wildcard patterns. This Prolog flag is intended for
backward compatibility with older versions of SWI-Prolog.
ggcc _(_b_o_o_l_, _c_h_a_n_g_e_a_b_l_e_)
If true (default), the garbage collector is active. If false,
neither garbage collection, nor stack shifts will take place,
even not on explicit request. May be changed.
ggeenneerraattee__ddeebbuugg__iinnffoo _(_b_o_o_l_, _c_h_a_n_g_e_a_b_l_e_)
If true (default) generate code that can be debugged using
trace/0, spy/1, etc. Can be set to false using the -nodebug.
This flag is scoped within a source file. Many of the
libraries have :- set_prolog_flag(generate_debug_info, false)
to hide their details from a normal trace.
ggmmpp__vveerrssiioonn _(_i_n_t_e_g_e_r_)
If Prolog is linked with GMP, this flag gives the major
version of the GMP library used. See also section 9.4.8.
gguuii _(_b_o_o_l_)
Set to true if XPCE is around and can be used for graphics.
hhiissttoorryy _(_i_n_t_e_g_e_r_, _c_h_a_n_g_e_a_b_l_e_)
If _i_n_t_e_g_e_r >0, support Unix csh(1)-like history as described
in section 2.7. Otherwise, only support reusing commands
through the command line editor. The default is to set this
Prolog flag to 0 if a command line editor is provided (see
Prolog flag readline) and 15 otherwise.
hhoommee _(_a_t_o_m_)
SWI-Prolog's notion of the home directory. SWI-Prolog
uses its home directory to find its startup file as
<_h_o_m_e>/boot32.prc(32-bit machines) or <_h_o_m_e>/boot64.prc (64-bit
machines) and to find its library as <_h_o_m_e>/library.
hhwwnndd _(_i_n_t_e_g_e_r_)
In swipl-win.exe, this refers to the MS-Windows window handle
of the console window.
iinntteeggeerr__rroouunnddiinngg__ffuunnccttiioonn _(_d_o_w_n_,_t_o_w_a_r_d___z_e_r_o_)
ISO Prolog flag describing rounding by // and rem arithmetic
functions. Value depends on the C compiler used.
iissoo _(_b_o_o_l_, _c_h_a_n_g_e_a_b_l_e_)
Include some weird ISO compatibility that is incompatible with
normal SWI-Prolog behaviour. Currently it has the following
effect:
o The //2 (float division) _a_l_w_a_y_s returns a float, even if
applied to integers that can be divided.
o In the standard order of terms (see section 4.7.1), all
floats are before all integers.
o atom_length/2 yields a type error if the first argument is
a number.
o clause/[2,3] raises a permission error when accessing
static predicates.
o abolish/[1,2] raises a permission error when accessing
static predicates.
o Syntax is closer to the ISO standard:
{{ Unquoted commas and bars appearing as atoms are not
allowed. Instead of f(,,a) now write f(',',a).
Unquoted commas can only be used to separate
arguments in functional notation and list notation,
and as a conjunction operator. Unquoted bars
can only appear within lists to separate head and
tail, like [Head|Tail], and as infix operator for
alternation in grammar rules, like a --> b | c.
{{ Within functional notation and list notation terms
must have priority below 1000. That means that
rules and control constructs appearing as arguments
need bracketing. A term like [a :- b, c]. must
now be disambiguated to mean [(a :- b), c]. or
[(a :- b, c)].
{{ Operators appearing as operands must be bracketed.
Instead of X == -, true. write X == (-), true.
Currently, this is not entirely enforced.
{{ Backslash-escaped newlines are interpreted according
to the ISO standard. See section 2.15.1.2.
llaarrggee__ffiilleess _(_b_o_o_l_)
If present and true, SWI-Prolog has been compiled with _l_a_r_g_e
_f_i_l_e _s_u_p_p_o_r_t (LFS) and is capable of accessing files larger
than 2GB on 32-bit hardware. Large file support is default on
installations built using configure that support it and may be
switched off using the configure option --disable-largefile.
llaasstt__ccaallll__ooppttiimmiissaattiioonn _(_b_o_o_l_, _c_h_a_n_g_e_a_b_l_e_)
Determines whether or not last-call optimisation is enabled.
Normally the value of this flag is the negation of the
debug flag. As programs may run out of stack if last-call
optimisation is omitted, it is sometimes necessary to enable
it during debugging.
mmaaxx__aarriittyy _(_u_n_b_o_u_n_d_e_d_)
ISO Prolog flag describing there is no maximum arity to
compound terms.
mmaaxx__iinntteeggeerr _(_i_n_t_e_g_e_r_)
Maximum integer value if integers are _b_o_u_n_d_e_d. See also the
flag bounded and section 4.27.2.1.
mmaaxx__ttaaggggeedd__iinntteeggeerr _(_i_n_t_e_g_e_r_)
Maximum integer value represented as a `tagged' value. Tagged
integers require one word storage. Larger integers are
represented as `indirect data' and require significantly more
space.
mmiinn__iinntteeggeerr _(_i_n_t_e_g_e_r_)
Minimum integer value if integers are _b_o_u_n_d_e_d. See also the
flag bounded and section 4.27.2.1.
mmiinn__ttaaggggeedd__iinntteeggeerr _(_i_n_t_e_g_e_r_)
Start of the tagged-integer value range.
ooccccuurrss__cchheecckk _(_a_t_o_m_, _c_h_a_n_g_e_a_b_l_e_)
This flag controls unification that creates an infinite
tree (also called _c_y_c_l_i_c _t_e_r_m) and can have three values.
Using false (default), unification succeeds, creating an
infinite tree. Using true, unification behaves as
unify_with_occurs_check/2, failing silently. Using error, an
attempt to create a cyclic term results in an occurs_check
exception. The latter is intended for debugging unintentional
creations of cyclic terms. Note that this flag is a global
flag modifying fundamental behaviour of Prolog. Changing the
flag from its default may cause libraries to stop functioning
properly.
ooppeenn__sshhaarreedd__oobbjjeecctt _(_b_o_o_l_)
If true, open_shared_object/2 and friends are implemented,
providing access to shared libraries (.so files) or dynamic
link libraries (.DLL files).
ooppttiimmiissee _(_b_o_o_l_, _c_h_a_n_g_e_a_b_l_e_)
If true, compile in optimised mode. The initial value is true
if Prolog was started with the -O command line option. The
optimise flag is scoped to a source file.
Currently optimised compilation implies compilation of
arithmetic, and deletion of redundant true/0 that may result
from expand_goal/2.
Later versions might imply various other optimisations such as
integrating small predicates into their callers, eliminating
constant expressions and other predictable constructs. Source
code optimisation is never applied to predicates that are
declared dynamic (see dynamic/1).
ooss__aarrggvv _(_l_i_s_t_, _c_h_a_n_g_e_a_b_l_e_)
List is a list of atoms representing the command line
arguments used to invoke SWI-Prolog. Please note that aallll
arguments are included in the list returned. See argv to get
the application options.
ppiidd _(_i_n_t_)
Process identifier of the running Prolog process. Existence
of this flag is implementation-defined.
ppiippee _(_b_o_o_l_, _c_h_a_n_g_e_a_b_l_e_)
If true, open(pipe(command), mode, Stream), etc. are sup-
ported. Can be changed to disable the use of pipes in
applications testing this feature. Not recommended.
pprroommpptt__aalltteerrnnaattiivveess__oonn _(_a_t_o_m_, _c_h_a_n_g_e_a_b_l_e_)
Determines prompting for alternatives in the Prolog top level.
Default is determinism, which implies the system prompts
for alternatives if the goal succeeded while leaving choice
points. Many classical Prolog systems behave as groundness:
they prompt for alternatives if and only if the query contains
variables.
qqccoommppiillee _(_a_t_o_m_, _c_h_a_n_g_e_a_b_l_e_)
This option provides the default for the qcompile(_+_A_t_o_m)
option of load_files/2.
rreeaaddlliinnee _(_b_o_o_l_)
If true, SWI-Prolog is linked with the readline library. This
is done by default if you have this library installed on
your system. It is also true for the Win32 swipl-win.exe
version of SWI-Prolog, which realises a subset of the readline
functionality.
rreessoouurrccee__ddaattaabbaassee _(_a_t_o_m_)
Set to the absolute filename of the attached state. Typically
this is the file boot32.prc, the file specified with -x or the
running executable. See also resource/3.
rreeppoorrtt__eerrrroorr _(_b_o_o_l_, _c_h_a_n_g_e_a_b_l_e_)
If true, print error messages; otherwise suppress them. May
be changed. See also the debug_on_errorProlog flag. Default
is true, except for the runtime version.
rruunnttiimmee _(_b_o_o_l_)
If present and true, SWI-Prolog is compiled with -DO_RUNTIME,
disabling various useful development features (currently the
tracer and profiler).
ssaannddbbooxxeedd__llooaadd _(_b_o_o_l_, _c_h_a_n_g_e_a_b_l_e_)
If true (default false), load_files/2 calls hooks to allow
library(sandbox) to verify the safety of directives.
ssaavveedd__pprrooggrraamm _(_b_o_o_l_)
If present and true, Prolog has been started from a state
saved with qsave_program/[1,2].
sshhaarreedd__oobbjjeecctt__eexxtteennssiioonn _(_a_t_o_m_)
Extension used by the operating system for shared objects.
.so for most Unix systems and .dll for Windows. Used for
locating files using the file_type executable. See also
absolute_file_name/3.
sshhaarreedd__oobbjjeecctt__sseeaarrcchh__ppaatthh _(_a_t_o_m_)
Name of the environment variable used by the system to search
for shared objects.
ssiiggnnaallss _(_b_o_o_l_)
Determine whether Prolog is handling signals (software in-
terrupts). This flag is false if the hosting OS does not
support signal handling or the command line option -nosignals
is active. See section 9.4.21.1 for details.
ssttrreeaamm__ttyyppee__cchheecckk _(_a_t_o_m_, _c_h_a_n_g_e_a_b_l_e_)
Defines whether and how strictly the system validates that
byte I/O should not be applied to text streams and text I/O
should not be applied to binary streams. Values are false (no
checking), true (full checking) and loose. Using checking
mode loose (default), the system accepts byte I/O from text
stream that use ISO Latin-1 encoding and accepts writing text
to binary streams.
ssyysstteemm__tthhrreeaadd__iidd _(_i_n_t_)
Available in multithreaded version (see section 8) where
the operating system provides system-wide integer thread
identifiers. The integer is the thread identifier used
by the operating system for the calling thread. See also
thread_self/1.
ttiimmeezzoonnee _(_i_n_t_e_g_e_r_)
Offset in seconds west of GMT of the current time zone. Set
at initialization time from the timezone variable associated
with the POSIX tzset() function. See also convert_time/2.
ttoopplleevveell__pprriinntt__aannoonn _(_b_o_o_l_, _c_h_a_n_g_e_a_b_l_e_)
If true, top-level variables starting with an underscore (_)
are printed normally. If false they are hidden. This may be
used to hide bindings in complex queries from the top level.
ttoopplleevveell__pprriinntt__ffaaccttoorriizzeedd _(_b_o_o_l_, _c_h_a_n_g_e_a_b_l_e_)
If true (default false) show the internal sharing of subterms
in the answer substitution. The example below reveals
internal sharing of leaf nodes in _r_e_d_-_b_l_a_c_k _t_r_e_e_s as
implemented by the rbtrees predicate rb_new/1:
_______________________________________________________________| |
|?- set_prolog_flag(toplevel_print_factorized, true). |
|?- rb_new(X). |
|X = t(_S1, _S1), % where |
||____S1_=_black('',__G387,__G388,_'').________________________ ||
If this flag is false, the % where notation is still used to
indicate cycles as illustrated below. This example also shows
that the implementation reveals the internal cycle length, and
_n_o_t the minimal cycle length. Cycles of different length are
indistinguishable in Prolog (as illustrated by S == R).
_______________________________________________________________| |
|?- S = s(S), R = s(s(R)), S == R. |
|S = s(S), |
|R|=_s(s(R)).__________________________________________________ | |
ttoopplleevveell__pprriinntt__ooppttiioonnss _(_t_e_r_m_, _c_h_a_n_g_e_a_b_l_e_)
This argument is given as option-list to write_term/2 for
printing results of queries. Default is [quoted(true),
portray(true), max_depth(10), attributes(portray)].
ttoopplleevveell__pprroommpptt _(_a_t_o_m_, _c_h_a_n_g_e_a_b_l_e_)
Define the prompt that is used by the interactive top level.
The following ~ (tilde) sequences are replaced:
_____________________________________________________________________~m_T_y_p_e _i_n module if not user (see module/1)
~l _B_r_e_a_k _l_e_v_e_l if not 0 (see break/0)
~d _D_e_b_u_g_g_i_n_g _s_t_a_t_e if not normal execution (see debug/0, trace/0)
_~!___H_i_s_t_o_r_y__e_v_e_n_t_if_history_is_enabled_(see_flag_history)__________
ttoopplleevveell__vvaarr__ssiizzee _(_i_n_t_, _c_h_a_n_g_e_a_b_l_e_)
Maximum size counted in literals of a term returned as a
binding for a variable in a top-level query that is saved for
re-use using the $ variable reference. See section 2.8.
ttrraaccee__ggcc _(_b_o_o_l_, _c_h_a_n_g_e_a_b_l_e_)
If true (default false), garbage collections and stack-shifts
will be reported on the terminal. May be changed. Values are
reported in bytes as G+T, where G is the global stack value
and T the trail stack value. `Gained' describes the number
of bytes reclaimed. `used' the number of bytes on the stack
after GC and `free' the number of bytes allocated, but not in
use. Below is an example output.
_______________________________________________________________| |
|% GC: gained 236,416+163,424 in 0.00 sec; |
||_____used_13,448+5,808;_free_72,568+47,440___________________ ||
ttttyy__ccoonnttrrooll _(_b_o_o_l_, _c_h_a_n_g_e_a_b_l_e_)
Determines whether the terminal is switched to raw mode for
get_single_char/1, which also reads the user actions for the
trace. May be set. See also the +/-tty command line option.
uunniixx _(_b_o_o_l_)
If present and true, the operating system is some version
of Unix. Defined if the C compiler used to compile this
version of SWI-Prolog either defines __unix__ or unix. On
other systems this flag is not available. See also apple and
windows.
uunnkknnoowwnn _(_f_a_i_l_,_w_a_r_n_i_n_g_,_e_r_r_o_r_, _c_h_a_n_g_e_a_b_l_e_)
Determines the behaviour if an undefined procedure is en-
countered. If fail, the predicate fails silently. If
warn, a warning is printed, and execution continues as if
the predicate was not defined, and if error (default), an
existence_error exception is raised. This flag is local to
each module and inherited from the module's _i_m_p_o_r_t_-_m_o_d_u_l_e.
Using default setup, this implies that normal modules inherit
the flag from user, which in turn inherit the value error
from system. The user may change the flag for module user
to change the default for all application modules or for
a specific module. It is strongly advised to keep the
error default and use dynamic/1 and/or multifile/1 to specify
possible non-existence of a predicate.
uusseerr__ffllaaggss _(_A_t_o_m_, _c_h_a_n_g_e_a_b_l_e_)
Define the behaviour of set_prolog_flag/2 if the flag is
not known. Values are silent, warning and error. The
first two create the flag on-the-fly, where warning prints
a message. The value error is consistent with ISO: it
raises an existence error and does not create the flag. See
also create_prolog_flag/3. The default is silent, but future
versions may change that. Developers are encouraged to use
another value and ensure proper use of create_prolog_flag/3 to
create flags for their library.
vveerrbboossee _(_A_t_o_m_, _c_h_a_n_g_e_a_b_l_e_)
This flag is used by print_message/2. If its value is silent,
messages of type informational and banner are suppressed. The
-q switches the value from the initial normal to silent.
vveerrbboossee__aauuttoollooaadd _(_b_o_o_l_, _c_h_a_n_g_e_a_b_l_e_)
If true the normal consult message will be printed if a
library is autoloaded. By default this message is suppressed.
Intended to be used for debugging purposes.
vveerrbboossee__llooaadd _(_a_t_o_m_, _c_h_a_n_g_e_a_b_l_e_)
Determines messages printed for loading (compiling) Prolog
files. Current values are full, normal (default) and silent.
The value of this flag is normally controlled by the option
silent(_B_o_o_l) provided by load_files/2.
vveerrbboossee__ffiillee__sseeaarrcchh _(_b_o_o_l_, _c_h_a_n_g_e_a_b_l_e_)
If true (default false), print messages indicating the
progress of absolute_file_name/[2,3] in locating files.
Intended for debugging complicated file-search paths. See
also file_search_path/2.
vveerrssiioonn _(_i_n_t_e_g_e_r_)
The version identifier is an integer with value:
10000_*Major+ 100_*Minor+_P_a_t_c_h
Note that in releases up to 2.7.10 this Prolog flag
yielded an atom holding the three numbers separated by dots.
The current representation is much easier for implementing
version-conditional statements.
vveerrssiioonn__ddaattaa _(_s_w_i_(_M_a_j_o_r_, _M_i_n_o_r_, _P_a_t_c_h_, _E_x_t_r_a_)_)
Part of the dialect compatibility layer; see also the Prolog
flag dialect and section 13. _E_x_t_r_a provides platform-specific
version information. Currently it is simply unified to [].
vveerrssiioonn__ggiitt _(_a_t_o_m_)
Available if created from a git repository. See git-describe
for details.
wwaarrnn__oovveerrrriiddee__iimmpplliicciitt__iimmppoorrtt _(_b_o_o_l_, _c_h_a_n_g_e_a_b_l_e_)
If true (default), a warning is printed if an implicitly
imported predicate is clobbered by a local definition. See
use_module/1 for details.
wwiinnddoowwss _(_b_o_o_l_)
If present and true, the operating system is an implementation
of Microsoft Windows (NT/2000/XP, etc.). This flag is only
available on MS-Windows based versions.
wwrriittee__aattttrriibbuutteess _(_a_t_o_m_, _c_h_a_n_g_e_a_b_l_e_)
Defines how write/1 and friends write attributed variables.
The option values are described with the attributes option of
write_term/3. Default is ignore.
wwrriittee__hheellpp__wwiitthh__oovveerrssttrriikkee _(_b_o_o_l_)
Internal flag used by help/1 when writing to a terminal. If
present and true it prints bold and underlined text using
_o_v_e_r_s_t_r_i_k_e.
xxppccee _(_b_o_o_l_)
Available and set to true if the XPCE graphics system is
loaded.
xxppccee__vveerrssiioonn _(_a_t_o_m_)
Available and set to the version of the loaded XPCE system.
sseett__pprroolloogg__ffllaagg((_:_K_e_y_, _+_V_a_l_u_e)) _[_I_S_O_]
Define a new Prolog flag or change its value. _K_e_y is an atom.
If the flag is a system-defined flag that is not marked _c_h_a_n_g_e_a_b_l_e
above, an attempt to modify the flag yields a permission_error.
If the provided _V_a_l_u_e does not match the type of the flag, a
type_error is raised.
Some flags (e.g., unknown) are maintained on a per-module basis.
The addressed module is determined by the _K_e_y argument.
In addition to ISO, SWI-Prolog allows for user-defined Prolog
flags. The type of the flag is determined from the initial value
and cannot be changed afterwards. Defined types are boolean (if
the initial value is one of false, true, on or off), atom if the
initial value is any other atom, integer if the value is an integer
that can be expressed as a 64-bit signed value. Any other initial
value results in an untyped flag that can represent any valid
Prolog term.
The behaviour when _K_e_y denotes a non-existent key depends on the
Prolog flag user_flags. The default is to define them silently.
New code is encouraged to use create_prolog_flag/3 for portability.
ccrreeaattee__pprroolloogg__ffllaagg((_+_K_e_y_, _+_V_a_l_u_e_, _+_O_p_t_i_o_n_s)) _[_Y_A_P_]
Create a new Prolog flag. The ISO standard does not foresee
creation of new flags, but many libraries introduce new flags.
_O_p_t_i_o_n_s is a list of the options below. See also user_flags.
aacccceessss((_+_A_c_c_e_s_s))
Define access rights for the flag. Values are read_write and
read_only. The default is read_write.
ttyyppee((_+_A_t_o_m))
Define a type restriction. Possible values are boolean, atom,
integer, float and term. The default is determined from
the initial value. Note that term restricts the term to be
ground.
kkeeeepp((_+_B_o_o_l_e_a_n))
If true, to not modify the flag if it already exists. Other-
wise (default), this predicate behaves as set_prolog_flag/2 if
the flag already exists.
22..1122 AAnn oovveerrvviieeww ooff hhooookk pprreeddiiccaatteess
SWI-Prolog provides a large number of hooks, mainly to control handling
messages, debugging, startup, shut-down, macro-expansion, etc. Below
is a summary of all defined hooks with an indication of their
portability.
o _p_o_r_t_r_a_y_/_1
Hook into write_term/3 to alter the way terms are printed (ISO).
o _m_e_s_s_a_g_e___h_o_o_k_/_3
Hook into print_message/2 to alter the way system messages are
printed (Quintus/SICStus).
o _m_e_s_s_a_g_e___p_r_o_p_e_r_t_y_/_2
Hook into print_message/2 that defines prefix, output stream,
color, etc.
o _l_i_b_r_a_r_y___d_i_r_e_c_t_o_r_y_/_1
Hook into absolute_file_name/3 to define new library directories
(most Prolog systems).
o _f_i_l_e___s_e_a_r_c_h___p_a_t_h_/_2
Hook into absolute_file_name/3 to define new search paths
(Quintus/SICStus).
o _t_e_r_m___e_x_p_a_n_s_i_o_n_/_2
Hook into load_files/2 to modify read terms before they are
compiled (macro-processing) (most Prolog systems).
o _g_o_a_l___e_x_p_a_n_s_i_o_n_/_2
Same as term_expansion/2 for individual goals (SICStus).
o _p_r_o_l_o_g___l_o_a_d___f_i_l_e_/_2
Hook into load_files/2 to load other data formats for Prolog
sources from `non-file' resources. The load_files/2 predicate is
the ancestor of consult/1, use_module/1, etc.
o _p_r_o_l_o_g___e_d_i_t_:_l_o_c_a_t_e_/_3
Hook into edit/1 to locate objects (SWI).
o _p_r_o_l_o_g___e_d_i_t_:_e_d_i_t___s_o_u_r_c_e_/_1
Hook into edit/1 to call an internal editor (SWI).
o _p_r_o_l_o_g___e_d_i_t_:_e_d_i_t___c_o_m_m_a_n_d_/_2
Hook into edit/1 to define the external editor to use (SWI).
o _p_r_o_l_o_g___l_i_s_t___g_o_a_l_/_1
Hook into the tracer to list the code associated to a particular
goal (SWI).
o _p_r_o_l_o_g___t_r_a_c_e___i_n_t_e_r_c_e_p_t_i_o_n_/_4
Hook into the tracer to handle trace events (SWI).
o _p_r_o_l_o_g_:_d_e_b_u_g___c_o_n_t_r_o_l___h_o_o_k_/_1
Hook in spy/1, nospy/1, nospyall/0 and debugging/0 to extend these
control predicates to higher-level libraries.
o _p_r_o_l_o_g_:_h_e_l_p___h_o_o_k_/_1
Hook in help/0, help/1 and apropos/1 to extend the help system.
o _r_e_s_o_u_r_c_e_/_3
Define a new resource (not really a hook, but similar) (SWI).
o _e_x_c_e_p_t_i_o_n_/_3
Old attempt to a generic hook mechanism. Handles undefined
predicates (SWI).
o _a_t_t_r___u_n_i_f_y___h_o_o_k_/_2
Unification hook for attributed variables. Can be defined in any
module. See section 6.1 for details.
22..1133 AAuuttoommaattiicc llooaaddiinngg ooff lliibbrraarriieess
If ---at runtime--- an undefined predicate is trapped, the system will
first try to import the predicate from the module's default module (see
section 5.9. If this fails the _a_u_t_o _l_o_a_d_e_r is activated. On first
activation an index to all library files in all library directories
is loaded in core (see library_directory/1, file_search_path/2 and
reload_library_index/0). If the undefined predicate can be located in
one of the libraries, that library file is automatically loaded and the
call to the (previously undefined) predicate is restarted. By default
this mechanism loads the file silently. The current_prolog_flag/2 key
verbose_autoload is provided to get verbose loading. The Prolog flag
autoload can be used to enable/disable the autoload system.
Autoloading only handles (library) source files that use the module
mechanism described in chapter 5. The files are loaded with
use_module/2 and only the trapped undefined predicate is imported into
the module where the undefined predicate was called. Each library
directory must hold a file INDEX.pl that contains an index to all
library files in the directory. This file consists of lines of the
following format:
________________________________________________________________________| |
|index(Name,|Arity,_Module,_File).______________________________________ | |
The predicate make/0 updates the autoload index. It searches for
all library directories (see library_directory/1 and file_search_path/2)
holding the file MKINDEX.pl or INDEX.pl. If the current user can write
or create the file INDEX.pl and it does not exist or is older than the
directory or one of its files, the index for this directory is updated.
If the file MKINDEX.pl exists, updating is achieved by loading this
file, normally containing a directive calling make_library_index/2.
Otherwise make_library_index/1is called, creating an index for all *.pl
files containing a module.
Below is an example creating an indexed library directory.
________________________________________________________________________| |
|% mkdir ~/lib/prolog |
|% cd ~/lib/prolog |
|%|swipl_-g_true_-t_'make_library_index(.)'_____________________________ | |
If there is more than one library file containing the desired
predicate, the following search schema is followed:
1. If there is a library file that defines the module in which the
undefined predicate is trapped, this file is used.
2. Otherwise library files are considered in the order they appear
in the library_directory/1 predicate and within the directory
alphabetically.
aauuttoollooaadd__ppaatthh((_+_D_i_r_A_l_i_a_s))
Add _D_i_r_A_l_i_a_s to the libraries that are used by the autoloader.
This extends the search path autoload and reloads the library
index. For example:
____________________________________________________________________| |
||:-_autoload_path(library(http)).__________________________________ ||
If this call appears as a directive, it is term-expanded
into a clause for user:file_search_path/2 and a directive calling
reload_library_index/0. This keeps source information and allows
for removing this directive.
mmaakkee__lliibbrraarryy__iinnddeexx((_+_D_i_r_e_c_t_o_r_y))
Create an index for this directory. The index is written to the
file 'INDEX.pl' in the specified directory. Fails with a warning
if the directory does not exist or is write protected.
mmaakkee__lliibbrraarryy__iinnddeexx((_+_D_i_r_e_c_t_o_r_y_, _+_L_i_s_t_O_f_P_a_t_t_e_r_n_s))
Normally used in MKINDEX.pl, this predicate creates INDEX.pl for
_D_i_r_e_c_t_o_r_y, indexing all files that match one of the file patterns
in _L_i_s_t_O_f_P_a_t_t_e_r_n_s.
Sometimes library packages consist of one public load file and a
number of files used by this load file, exporting predicates that
should not be used directly by the end user. Such a library can be
placed in a sub-directory of the library and the files containing
public functionality can be added to the index of the library.
As an example we give the XPCE library's MKINDEX.pl, including
the public functionality of trace/browse.pl to the autoloadable
predicates for the XPCE package.
____________________________________________________________________| |
| :- make_library_index('.', |
| [ '*.pl', |
| 'trace/browse.pl' |
||______________________])._________________________________________ ||
rreellooaadd__lliibbrraarryy__iinnddeexx
Force reloading the index after modifying the set of library
directories by changing the rules for library_directory/1,
file_search_path/2, adding or deleting INDEX.pl files. This
predicate does _n_o_t update the INDEX.pl files. Check
make_library_index/[1,2] and make/0 for updating the index files.
Normally, the index is reloaded automatically if a predicate cannot
be found in the index and the set of library directories has
changed. Using reload_library_index/0 is necessary if directories
are removed or the order of the library directories is changed.
When creating an executable using either qsave_program/2 or the -c
command line options, it is necessarry to load all predicates that
would normally be autoloaded explicitly. This is discussed in
section 10. See autoload/0.
22..1144 GGaarrbbaaggee CCoolllleeccttiioonn
SWI-Prolog provides garbage collection, last-call optimization and atom
garbage collection. These features are controlled using Prolog flags
(see current_prolog_flag/2).
22..1155 SSyynnttaaxx NNootteess
SWI-Prolog syntax is close to ISO-Prolog standard syntax, which is
closely compatible with Edinburgh Prolog syntax. A description of this
syntax can be found in the Prolog books referenced in the introduction.
Below are some non-standard or non-common constructs that are accepted
by SWI-Prolog:
o /* .../* ...*/ ...*/
The /* ...*/ comment statement can be nested. This is useful
if some code with /* ...*/ comment statements in it should be
commented out.
22..1155..11 IISSOO SSyynnttaaxx SSuuppppoorrtt
SWI-Prolog offers ISO compatible extensions to the Edinburgh syntax.
22..1155..11..11 PPrroocceessssoorr CChhaarraacctteerr SSeett
The processor character set specifies the class of each character used
for parsing Prolog source text. Character classification is fixed to
use UCS/Unicode as provided by the C library wchar_t based primitives.
See also section 2.18.
22..1155..11..22 CChhaarraacctteerr EEssccaappee SSyynnttaaxx
Within quoted atoms (using single quotes: '<atom>') special characters
are represented using escape sequences. An escape sequence is led
in by the backslash (\) character. The list of escape sequences
is compatible with the ISO standard but contains some extensions, and
the interpretation of numerically specified characters is slightly more
flexible to improve compatibility. Undefined escape characters raise a
syntax_error exception.
\a
Alert character. Normally the ASCII character 7 (beep).
\b
Backspace character.
\c
No output. All input characters up to but not including the
first non-layout character are skipped. This allows for the
specification of pretty-looking long lines. Not supported by ISO.
Example:
____________________________________________________________________| |
| format('This is a long line that looks better if it was \c |
||_______split_across_multiple_physical_lines_in_the_input')________ ||
\<NEWLINE>
When in ISO mode (see the Prolog flag iso), only skip this
sequence. In native mode, white space that follows the newline
is skipped as well and a warning is printed, indicating that this
construct is deprecated and advising to use \c. We advise using
\c or putting the layout _b_e_f_o_r_e the \, as shown below. Using
\c is supported by various other Prolog implementations and will
remain supported by SWI-Prolog. The style shown below is the most
compatible solution.
____________________________________________________________________| |
| format('This is a long line that looks better if it was \ |
||split_across_multiple_physical_lines_in_the_input')_______________ ||
instead of
____________________________________________________________________| |
| format('This is a long line that looks better if it was\ |
||_split_across_multiple_physical_lines_in_the_input')______________ ||
\e
Escape character (ASCII 27). Not ISO, but widely supported.
\f
Form-feed character.
\n
Next-line character.
\r
Carriage-return only (i.e., go back to the start of the line).
\s
Space character. Intended to allow writing 0'\s to get the
character code of the space character. Not ISO.
\t
Horizontal tab character.
\v
Vertical tab character (ASCII 11).
\xXX..\
Hexadecimal specification of a character. The closing \ is
obligatory according to the ISO standard, but optional in
SWI-Prolog to enhance compatibility with the older Edinburgh
standard. The code \xa\3 emits the character 10 (hexadecimal `a')
followed by `3'. Characters specified this way are interpreted as
Unicode characters. See also \u.
\uXXXX
Unicode character specification where the character is specified
using _e_x_a_c_t_l_y 4 hexadecimal digits. This is an extension to the
ISO standard, fixing two problems. First, where \x defines a
numeric character code, it doesn't specify the character set in
which the character should be interpreted. Second, it is not
needed to use the idiosyncratic closing \ ISO Prolog syntax.
\UXXXXXXXX
Same as \uXXXX, but using 8 digits to cover the whole Unicode set.
\40
Octal character specification. The rules and remarks for
hexadecimal specifications apply to octal specifications as well.
\\
Escapes the backslash itself. Thus, '\\' is an atom consisting of
a single \.
\quote
If the current quote (" or ') is preceded by a backslash, it is
copied verbatim. Thus, '\'' and '''' both describe the atom with a
single '.
Character escaping is only available if
current_prolog_flag(character_escapes, true) is active (default). See
current_prolog_flag/2. Character escapes conflict with writef/2 in
two ways: \40 is interpreted as decimal 40 by writef/2, but as
octal 40 (decimal 32) by read. Also, the writef/2 sequence \l is
illegal. It is advised to use the more widely supported format/[2,3]
predicate instead. If you insist upon using writef/2, either switch
character_escapes to false, or use double \\, as in writef('\\l').
22..1155..11..33 SSyynnttaaxx ffoorr nnoonn--ddeecciimmaall nnuummbbeerrss
SWI-Prolog implements both Edinburgh and ISO representations for
non-decimal numbers. According to Edinburgh syntax, such numbers are
written as <_r_a_d_i_x>'<number>, where <_r_a_d_i_x> is a number between 2 and 36.
ISO defines binary, octal and hexadecimal numbers using 0[bxo]<_n_u_m_b_e_r>.
For example: A is 0b100 \/ 0xf00 is a valid expression. Such numbers
are always unsigned.
22..1155..11..44 UUssiinngg ddiiggiitt ggrroouuppss iinn llaarrggee iinntteeggeerrss
SWI-Prolog supports splitting long integers into _d_i_g_i_t _g_r_o_u_p_s.
Digit groups can be separated with the sequence <_u_n_d_e_r_s_c_o_r_e>,
<_o_p_t_i_o_n_a_l _w_h_i_t_e _s_p_a_c_e>. If the <_r_a_d_i_x> is 10 or lower, they may also
be separated with exactly one space. The following all express the
integer 1 million:
________________________________________________________________________| |
|1_000_000 |
|1 000 000 |
|1_000_/*more*/000|_____________________________________________________ | |
Integers can be printed using this notation with format/2, using the ~I
format specifier. For example:
________________________________________________________________________| |
|?- format('~I', [1000000]). |
|1_000_000|_____________________________________________________________ | |
The current syntax has been proposed by Ulrich Neumerkel on the
SWI-Prolog mailinglist.
22..1155..11..55 UUnniiccooddee PPrroolloogg ssoouurrccee
The ISO standard specifies the Prolog syntax in ASCII characters. As
SWI-Prolog supports Unicode in source files we must extend the syntax.
This section describes the implication for the source files, while
writing international source files is described in section 3.1.3.
The SWI-Prolog Unicode character classification is based on version
6.0.0 of the Unicode standard. Please note that char_type/2 and
friends, intended to be used with all text except Prolog source code,
is based on the C library locale-based classification routines.
o _Q_u_o_t_e_d _a_t_o_m_s _a_n_d _s_t_r_i_n_g_s
Any character of any script can be used in quoted atoms and
strings. The escape sequences \uXXXX and \UXXXXXXXX (see
section 2.15.1.2) were introduced to specify Unicode code points in
ASCII files.
o _A_t_o_m_s _a_n_d _V_a_r_i_a_b_l_e_s
We handle them in one item as they are closely related. The
Unicode standard defines a syntax for identifiers in computer
languages. In this syntax identifiers start with ID_Start followed
by a sequence of ID_Continue codes. Such sequences are handled as
a single token in SWI-Prolog. The token is a _v_a_r_i_a_b_l_e iff it
starts with an uppercase character or an underscore (_). Otherwise
it is an atom. Note that many languages do not have the notion
of character case. In such languages variables _m_u_s_t be written as
_name.
o _W_h_i_t_e _s_p_a_c_e
All characters marked as separators (Z*) in the Unicode tables are
handled as layout characters.
o _C_o_n_t_r_o_l _a_n_d _u_n_a_s_s_i_g_n_e_d _c_h_a_r_a_c_t_e_r_s
Control and unassigned (C*) characters produce a syntax error if
encountered outside quoted atoms/strings and outside comments.
o _O_t_h_e_r _c_h_a_r_a_c_t_e_r_s
The first 128 characters follow the ISO Prolog standard. Unicode
symbol and punctuation characters (general category S* and P*) act
as glueing symbol characters (i.e., just like ==: an unquoted
sequence of symbol characters are combined into an atom).
Other characters (this is mainly No: _a _n_u_m_e_r_i_c _c_h_a_r_a_c_t_e_r _o_f _o_t_h_e_r
_t_y_p_e) are currently handled as `solo'.
22..1155..11..66 SSiinngglleettoonn vvaarriiaabbllee cchheecckkiinngg
A _s_i_n_g_l_e_t_o_n _v_a_r_i_a_b_l_e is a variable that appears only one time in a
clause. It can always be replaced by _, the _a_n_o_n_y_m_o_u_s variable. In
some cases, however, people prefer to give the variable a name. As
mistyping a variable is a common mistake, Prolog systems generally give
a warning (controlled by style_check/1) if a variable is used only
once. The system can be informed that a variable is meant to appear
once by _s_t_a_r_t_i_n_g it with an underscore, e.g., _Name. Please note that
any variable, except plain _, shares with variables of the same name.
The term t(_X, _X) is equivalent to t(X, X), which is _d_i_f_f_e_r_e_n_t from
t(_, _).
As Unicode requires variables to start with an underscore in many
languages, this schema needs to be extended. First we define the two
classes of named variables.
o _N_a_m_e_d _s_i_n_g_l_e_t_o_n _v_a_r_i_a_b_l_e_s
Named singletons start with a double underscore (__) or a single
underscore followed by an uppercase letter, e.g., __var or _Var.
o _N_o_r_m_a_l _v_a_r_i_a_b_l_e_s
All other variables are `normal' variables. Note this makes _var a
normal variable.
Any normal variable appearing exactly once in the clause _a_n_d any named
singleton variables appearing more than once are reported. Below are
some examples with warnings in the right column. Singleton messages
can be suppressed using the style_check/1 directive.
___________________________________________________________________________
| test(_). | |
| test(_a). |Singleton variables: [_a] |
| test(_12). |Singleton variables: [_12] |
| test(A). |Singleton variables: [A] |
| test(_A). | |
| test(__a). | |
| test(_, _). | |
| test(_a, _a). | |
| test(__a, __a).S|ingleton-marked variables appearing more than once: [__a] |
| test(_A, _A). |Singleton-marked variables appearing more than once: [_A] |
|_test(A,_A).__|__________________________________________________________|_
SSeemmaannttiicc ssiinngglleettoonnss
Starting with version 6.5.1, SWI-Prolog has _s_y_n_t_a_c_t_i_c _s_i_n_g_l_e_t_o_n_s and
_s_e_m_a_n_t_i_c _s_i_n_g_l_e_t_o_n_s. The first are checked by read_clause/3 (and
read_term/3 using the option singletons(_w_a_r_n_i_n_g)). The latter are
generated by the compiler for variables that appear alone in a _b_r_a_n_c_h.
For example, in the code below the variable _X is not a _s_y_n_t_a_c_t_i_c
singleton, but the variable _X does not communicate any bindings and
replacing _X with _does not change the semantics.
________________________________________________________________________| |
|test :- |
| ( test_1(X) |
| ; test_2(X) |
||_______)._____________________________________________________________ ||
22..1166 RRaattiioonnaall ttrreeeess ((ccyycclliicc tteerrmmss))
SWI-Prolog supports rational trees, also known as cyclic terms.
`Supports' is so defined that most relevant built-in predicates
terminate when faced with rational trees. Almost all SWI-Prolog's
built-in term manipulation predicates process terms in a time that is
linear to the amount of memory used to represent the term on the stack.
The following set of predicates safely handles rational trees: =../2,
==/2, =@=/2, =/2, @</2 , @=</2, @>=/2, @>/2, \==/2, \=@=/2, \=/2,
acyclic_term/1, bagof/3, compare/3, copy_term/2, cyclic_term/1, dif/2,
duplicate_term/2, findall/3, ground/1, term_hash/2, numbervars/[3,4],
recorda/3, recordz/3, setof/3, subsumes_term/2, term_variables/2,
throw/1, unify_with_occurs_check/2, unifiable/3, when/2, write/1 (and
related predicates) .
In addition, some built-ins recognise rational trees and raise an
appropriate exception. Arithmetic evaluation belongs to this group.
The compiler (asserta/1, etc.) also raises an exception. Future
versions may support rational trees. Predicates that could provide
meaningful processing of rational trees raise a representation_error.
Predicates for which rational trees have no meaningful interpretation
raise a type_error. For example:
________________________________________________________________________| |
|1 ?- A = f(A), asserta(a(A)). |
|ERROR: asserta/1: Cannot represent due to `cyclic_term' |
|2 ?- A = 1+A, B is A. |
|ERROR: is/2: Type error: `expression' expected, found |
||____________`@(S_1,[S_1=1+S_1])'_(cyclic_term)________________________ ||
22..1177 JJuusstt--iinn--ttiimmee ccllaauussee iinnddeexxiinngg
SWI-Prolog provides `just-in-time' indexing over multiple arguments.
`Just-in-time' means that clause indexes are not built by the compiler
(or asserta/1 for dynamic predicates), but on the first call to such
a predicate where an index might help (i.e., a call where at least
one argument is instantiated). This section describes the rules used
by the indexing logic. Note that this logic is not `set in stone'.
The indexing capabilities of the system will change. Although this
inevitably leads to some regressing on some particular use cases, we
strive to avoid significant slowdowns.
The list below describes the clause selection process for various
predicates and calls. The alternatives are considered in the order
they are presented.
o _S_p_e_c_i_a_l _p_u_r_p_o_s_e _c_o_d_e
Currently two special cases are recognised by the compiler: static
code with exactly one clause and static code with two clauses, one
where the first argument is the empty list ([]) and one where the
first argument is a non-empty list ([_|_]).
o _L_i_n_e_a_r _s_c_a_n _o_n _f_i_r_s_t _a_r_g_u_m_e_n_t
The principal clause list maintains a _k_e_y for the first argument.
An indexing key is either a constant or a functor (name/arity
reference). Calls with an instantiated first argument and less
than 10 clauses perform a linear scan for a possible matching
clause using this index key.
o _H_a_s_h _l_o_o_k_u_p
If none of the above applies, the system considers the available
hash tables for which the corresponding argument is instantiated.
If a table is found with acceptable characteristics, it is used.
Otherwise, there are two cases. First, if no hash table is
available for the instantiated arguments, it assesses the clauses
for all instantiated arguments and selects the best candidate for
creating a hash table. Arguments that cannot be indexed are
flagged to avoid repeated scanning. Second, if there is a hash
table for an indexed argument but it has poor characteristics, the
system scans other instantiated arguments to see whether it can
create a better hash table. The system maintains a bit vector on
each table in which it marks arguments that are less suitable than
the argument to which the table belongs.
Clauses that have a variable at an otherwise indexable argument
must be linked into all hash buckets. Currently, predicates that
have more than 10% such clauses for a specific argument are not
considered for indexing on that argument.
Disregarding variables, the suitability of an argument for hashing
is expressed as the number of unique indexable values divided by
the standard deviation of the number of duplicate values for each
value plus one.
The indexes of dynamic predicates are deleted if the number of
clauses is doubled since its creation or reduced below 1/4th.
The JIT approach will recreate a suitable index on the next
call. Indexes of running predicates cannot be deleted. They
are added to a `removed index list' associated to the predicate.
Dynamic predicates maintain a counter for the number of goals
running the predicate (a predicate can `run' multiple times due to
recursion, open choice points, and multiple threads) and destroy
removed indexes if this count drops to zero. Outdated indexes of
static predicates (e.g., due to reconsult or enlarging multifile
predicates) are reclaimed by garbage_collect_clauses/0.
22..1177..11 FFuuttuurree ddiirreeccttiioonnss
o The current indexing system is largely prepared for secondary
indexes. This implies that if there are many clauses that match
a given key, the system could (JIT) create a secondary index.
This secondary index could exploit another argument or, if the key
denotes a functor, an argument inside the compound term.
o The `special cases' can be extended. This is notably attractive
for static predicates with a relatively small number of clauses
where a hash lookup is too costly.
22..1177..22 IInnddeexxiinngg aanndd ppoorrttaabbiilliittyy
The base-line functionality of Prolog implementations provides indexing
on constants and functor (name/arity) on the first argument. This must
be your assumption if wide portability of your program is important.
This can typically be achieved by exploiting term_hash/2 or term_hash/4
and/or maintaining multiple copies of a predicate with reordered
arguments and wrappers that update all implementations (assert/retract)
and selects the appropriate implementation (query).
YAP provides full JIT indexing, including indexing arguments of
compound terms. YAP's indexing has been the inspiration for enhancing
SWI-Prolog's indexing capabilities.
22..1188 WWiiddee cchhaarraacctteerr ssuuppppoorrtt
SWI-Prolog supports _w_i_d_e _c_h_a_r_a_c_t_e_r_s, characters with character codes
above 255 that cannot be represented in a single _b_y_t_e. _U_n_i_v_e_r_s_a_l
_C_h_a_r_a_c_t_e_r _S_e_t (UCS) is the ISO/IEC 10646 standard that specifies a
unique 31-bit unsigned integer for any character in any language. It
is a superset of 16-bit Unicode, which in turn is a superset of
ISO 8859-1 (ISO Latin-1), a superset of US-ASCII. UCS can handle
strings holding characters from multiple languages, and character
classification (uppercase, lowercase, digit, etc.) and operations such
as case conversion are unambiguously defined.
For this reason SWI-Prolog has two representations for atoms and string
objects (see section 4.24). If the text fits in ISO Latin-1, it is
represented as an array of 8-bit characters. Otherwise the text is
represented as an array of 32-bit numbers. This representational issue
is completely transparent to the Prolog user. Users of the foreign
language interface as described in chapter 9 sometimes need to be aware
of these issues though.
Character coding comes into view when characters of strings need to be
read from or written to file or when they have to be communicated to
other software components using the foreign language interface. In
this section we only deal with I/O through streams, which includes file
I/O as well as I/O through network sockets.
22..1188..11 WWiiddee cchhaarraacctteerr eennccooddiinnggss oonn ssttrreeaammss
Although characters are uniquely coded using the UCS standard
internally, streams and files are byte (8-bit) oriented and there are
a variety of ways to represent the larger UCS codes in an 8-bit octet
stream. The most popular one, especially in the context of the web,
is UTF-8. Bytes 0 ... 127 represent simply the corresponding US-ASCII
character, while bytes 128 ... 255 are used for multi-byte encoding of
characters placed higher in the UCS space. Especially on MS-Windows
the 16-bit Unicode standard, represented by pairs of bytes, is also
popular.
Prolog I/O streams have a property called _e_n_c_o_d_i_n_g which specifies the
used encoding that influences get_code/2 and put_code/2 as well as all
the other text I/O predicates.
The default encoding for files is derived from the Prolog flag
encoding, which is initialised from the environment. If the
environment variable LANG ends in "UTF-8", this encoding is assumed.
Otherwise the default is text and the translation is left to
the wide-character functions of the C library. The encoding can
be specified explicitly in load_files/2 for loading Prolog source
with an alternative encoding, open/4 when opening files or using
set_stream/2 on any open stream. For Prolog source files we also
provide the encoding/1 directive that can be used to switch between
encodings that are compatible with US-ASCII (ascii, iso_latin_1, utf8
and many locales). See also section 3.1.3 for writing Prolog
files with non-US-ASCII characters and section 2.15.1.5 for syntax
issues. For additional information and Unicode resources, please visit
http://www.unicode.org/.
SWI-Prolog currently defines and supports the following encodings:
oocctteett
Default encoding for binary streams. This causes the stream to be
read and written fully untranslated.
aasscciiii
7-bit encoding in 8-bit bytes. Equivalent to iso_latin_1, but
generates errors and warnings on encountering values above 127.
iissoo__llaattiinn__11
8-bit encoding supporting many Western languages. This causes the
stream to be read and written fully untranslated.
tteexxtt
C library default locale encoding for text files. Files are read
and written using the C library functions mbrtowc() and wcrtomb().
This may be the same as one of the other locales, notably it may be
the same as iso_latin_1 for Western languages and utf8 in a UTF-8
context.
uuttff88
Multi-byte encoding of full UCS, compatible with ascii. See above.
uunniiccooddee__bbee
Unicode _B_i_g _E_n_d_i_a_n. Reads input in pairs of bytes, most
significant byte first. Can only represent 16-bit characters.
uunniiccooddee__llee
Unicode _L_i_t_t_l_e _E_n_d_i_a_n. Reads input in pairs of bytes, least
significant byte first. Can only represent 16-bit characters.
Note that not all encodings can represent all characters. This implies
that writing text to a stream may cause errors because the stream
cannot represent these characters. The behaviour of a stream on these
errors can be controlled using set_stream/2. Initially the terminal
stream writes the characters using Prolog escape sequences while other
streams generate an I/O exception.
22..1188..11..11 BBOOMM:: BByyttee OOrrddeerr MMaarrkk
From section 2.18.1, you may have got the impression that text files
are complicated. This section deals with a related topic, making
life often easier for the user, but providing another worry to the
programmer. BBOOMM or _B_y_t_e _O_r_d_e_r _M_a_r_k_e_r is a technique for identifying
Unicode text files as well as the encoding they use. Such files start
with the Unicode character 0xFEFF, a non-breaking, zero-width space
character. This is a pretty unique sequence that is not likely to be
the start of a non-Unicode file and uniquely distinguishes the various
Unicode file formats. As it is a zero-width blank, it even doesn't
produce any output. This solves all problems, or ...
Some formats start off as US-ASCII and may contain some encoding mark
to switch to UTF-8, such as the encoding="UTF-8" in an XML header.
Such formats often explicitly forbid the use of a UTF-8 BOM. In other
cases there is additional information revealing the encoding, making
the use of a BOM redundant or even illegal.
The BOM is handled by SWI-Prolog open/4 predicate. By default, text
files are probed for the BOM when opened for reading. If a BOM is
found, the encoding is set accordingly and the property bom(_t_r_u_e) is
available through stream_property/2. When opening a file for writing,
writing a BOM can be requested using the option bom(_t_r_u_e) with open/4.
22..1199 SSyysstteemm lliimmiittss
22..1199..11 LLiimmiittss oonn mmeemmoorryy aarreeaass
SWI-Prolog has a number of memory areas which are only enlarged to a
certain limit. The internal data representation limits the local,
global and trail stack to 128 MB on 32-bit processors, or more
generally to 2 to the power bits-per-pointer - 5 bytes. Considering
that almost all modern hardware can deal with this amount of memory
with ease, the default limits are set to their maximum on 32-bit
hardware. The representation limits can easily exceed physical memory
on 64-bit hardware. The default limits on 64-bit hardware are double
that of 32-bit hardware, which allows for storing the same amount of
(Prolog) data.
The limits can be changed from the command line as well as at runtime
using set_prolog_stack/2. The table below shows these areas. The first
column gives the option name to modify the size of the area. The
option character is immediately followed by a number and optionally by
a k or m. With k or no unit indicator, the value is interpreted
in Kbytes (1024 bytes); with m, the value is interpreted in Mbytes
(10241* 024 bytes).
The PrologScript facility described in section 2.10.2.1 provides a
mechanism for specifying options with the load file. On Windows the
default stack sizes are controlled using the Windows registry on the
key HKEY_CURRENT_USER\Software\SWI\Prolog using the names localSize,
globalSize and trailSize. The value is a DWORD expressing the default
stack size in Kbytes. A GUI for modifying these values is provided
using the XPCE package. To use this, start the XPCE manual tools using
manpce/0, after which you find _P_r_e_f_e_r_e_n_c_e_s in the _F_i_l_e menu.
Considering portability, applications that need to modify the default
limits are advised to do so using set_prolog_stack/2.
___________________________________________________________
|_Option_|Default_|Area_name______|Description____________|_||-L||128Mlloocc||aallTssttaacckkhe|l||||ocal|stack is used
| | to store the execu- | | ||
| | tion environments of | | ||
| | procedure invocations. | | ||
| | The space for an en- | | ||
| | vironment is reclaimed | | ||
| | when it fails, exits | | ||
| | without leaving choice | | ||
| | points, the alterna- | | ||
| | tives are cut off with | | ||
| | | | ||
| | the !/0 predicate or | | ||
| | no choice points have | | ||
| | been created since the | | ||
| | invocation and the last | | ||
| | subclause is started | | ||
| | (last call optimisa- | | ||
|| || | ||tion). || | ||
| -G |128M |gglloobbaall ssttaacckk ||Theusglobaled stacktois store| terms
| | | ||created during Prolog's |
| | | ||execution. Terms on |
| | | || |
| | | ||this stack will be re- |
| | | ||claimed by backtracking |
| | | ||to a point before the |
| | | ||term was created or |
| | | ||by garbage collection |
| | | ||(provided the term is |
|| || || ||no||longer referenced). ||
| -T |128M |ttrraaiill ssttaacckk ||Theusetraild stackto isstore| as-
| | | ||signments during execu- |
| | | || |
| | | ||tion. Entries on this |
| | | ||stack remain alive un- |
| | | ||til backtracking before |
| | | ||the point of creation |
| | | ||or the garbage collec- |
| | | ||tor determines they are |
|| || || ||no||longer needed. ||
| -A | 1M |aarrgguummeenntt ssttaacckk ||Theusargumentestackd isto|store one of
| | | ||the Virtual Machine's |
| | | ||registers. The amount |
| | | || |
| | | ||of space needed on this |
| | | ||stack is determined en- |
| | | ||tirely by the depth in |
| | | ||which terms are nested |
| | | ||in the clauses that |
| | | ||constitute the program. |
|________|_______|_______________||Overflow_is_unlikely.___|_
Table 2.2: Memory areas
22..1199..11..11 TThhee hheeaapp
With the heap, we refer to the memory area used by malloc() and
friends. SWI-Prolog uses the area to store atoms, functors, predicates
and their clauses, records and other dynamic data. No limits are
imposed on the addresses returned by malloc() and friends.
22..1199..22 OOtthheerr LLiimmiittss
CCllaauusseess The only limit on clauses is their arity (the number of
arguments to the head), which is limited to 1024. Raising this
limit is easy and relatively cheap; removing it is harder.
AAttoommss aanndd SSttrriinnggss SWI-Prolog has no limits on the sizes of atoms and
strings. read/1 and its derivatives, however, normally limit
the number of newlines in an atom or string to 6 to improve
error detection and recovery. This can be switched off with
style_check/1.
The number of atoms is limited to 16777216 (16M) on 32-bit
machines. On 64-bit machines this is virtually unlimited. See
also section 9.4.2.1.
MMeemmoorryy aarreeaass On 32-bit hardware, SWI-Prolog data is packed in a 32-bit
word, which contains both type and value information. The size
of the various memory areas is limited to 128 MB for each of the
areas, except for the program heap, which is not limited. On
64-bit hardware there are no meaningful limits.
NNeessttiinngg ooff tteerrmmss Most built-in predicates that process Prolog terms
create an explicitly managed stack and perform optimization for
processing the last argument of a term. This implies they can
process deeply nested terms at constant and low usage of the C
stack, and the system raises a resource error if no more stack
can be allocated. Currently only read/1 and write/1 (and all
variations thereof) still use the C stack and may cause the system
to crash in an uncontrolled way (i.e., not mapped to a Prolog
exception that can be caught).
IInntteeggeerrss On most systems SWI-Prolog is compiled with support for
unbounded integers by means of the GNU GMP library. In practice
this means that integers are bound by the global stack size. Too
large integers cause a resource_error. On systems that lack GMP,
integers are 64-bit on 32- as well as 64-bit machines.
Integers up to the value of the max_tagged_integerProlog flag are
represented more efficiently on the stack. For integers that
appear in clauses, the value (below max_tagged_integeror not) has
little impact on the size of the clause.
FFllooaattiinngg ppooiinntt nnuummbbeerrss Floating point numbers are represented as
C-native double precision floats, 64-bit IEEE on most machines.
22..1199..33 RReesseerrvveedd NNaammeess
The boot compiler (see -b option) does not support the module system.
As large parts of the system are written in Prolog itself we need some
way to avoid name clashes with the user's predicates, database keys,
etc. Like Edinburgh C-Prolog [Pereira, 1986] all predicates, database
keys, etc., that should be hidden from the user start with a dollar ($)
sign.
22..2200 SSWWII--PPrroolloogg aanndd 6644--bbiitt mmaacchhiinneess
Most of today's 64-bit platforms are capable of running both 32-bit
and 64-bit applications. This asks for some clarifications on the
advantages and drawbacks of 64-bit addressing for (SWI-)Prolog.
22..2200..11 SSuuppppoorrtteedd ppllaattffoorrmmss
SWI-Prolog can be compiled for a 32- or 64-bit address space on any
system with a suitable C compiler. Pointer arithmetic is based on the
type (u)intptr_t from stdint.h, with suitable emulation on MS-Windows.
22..2200..22 CCoommppaarriinngg 3322-- aanndd 6644--bbiittss PPrroolloogg
Most of Prolog's memory usage consists of pointers. This indicates the
primary drawback: Prolog memory usage almost doubles when using the
64-bit addressing model. Using more memory means copying more data
between CPU and main memory, slowing down the system.
What then are the advantages? First of all, SWI-Prolog's addressing
of the Prolog stacks does not cover the whole address space due to
the use of _t_y_p_e _t_a_g _b_i_t_s and _g_a_r_b_a_g_e _c_o_l_l_e_c_t_i_o_n _f_l_a_g_s. On 32-bit
hardware the stacks are limited to 128 MB each. This tends to be too
low for demanding applications on modern hardware. On 64-bit hardware
the limit is 232 times higher, exceeding the addressing capabilities of
today's CPUs and operating systems. This implies Prolog can be started
with stack sizes that use the full capabilities of your hardware.
Multi-threaded applications profit much more because every thread has
its own set of stacks. The Prolog stacks start small and are
dynamically expanded (see section 2.19.1). The C stack is also
dynamically expanded, but the maximum size is _r_e_s_e_r_v_e_d when a thread
is started. Using 100 threads at the maximum default C stack of 8Mb
(Linux) costs 800Mb virtual memory!
The implications of theoretical performance loss due to increased
memory bandwidth implied by exchanging wider pointers depend on the
design of the hardware. We only have data for the popular IA32 vs.
AMD64 architectures. Here, it appears that the loss is compensated for
by an instruction set that has been optimized for modern programming.
In particular, the AMD64 has more registers and the relative addressing
capabilities have been improved. Where we see a 10% performance
degradation when placing the SWI-Prolog kernel in a Unix shared object,
we cannot find a measurable difference on AMD64.
22..2200..33 CChhoooossiinngg bbeettwweeeenn 3322-- aanndd 6644--bbiitt PPrroolloogg
For those cases where we can choose between 32 and 64 bits, either
because the hardware and OS support both or because we can still choose
the hardware and OS, we give guidelines for this decision.
First of all, if SWI-Prolog needs to be linked against 32- or 64-bit
native libraries, there is no choice as it is not possible to link
32- and 64-bit code into a single executable. Only if all required
libraries are available in both sizes and there is no clear reason to
use either do the different characteristics of Prolog become important.
Prolog applications that require more than the 128 MB stack limit
provided in 32-bit addressing mode must use the 64-bit edition. Note
however that the limits must be doubled to accommodate the same Prolog
application.
If the system is tight on physical memory, 32-bit Prolog has the clear
advantage of using only slightly more than half of the memory of 64-bit
Prolog. This argument applies as long as the application fits in the
_v_i_r_t_u_a_l _a_d_d_r_e_s_s _s_p_a_c_e of the machine. The virtual address space of
32-bit hardware is 4GB, but in many cases the operating system provides
less to user applications.
The only standard SWI-Prolog library adding significantly to this
calculation is the RDF database provided by the _s_e_m_w_e_b package. It
uses approximately 80 bytes per triple on 32-bit hardware and 150 bytes
on 64-bit hardware. Details depend on how many different resources and
literals appear in the dataset as well as desired additional literal
indexes.
Summarizing, if applications are small enough to fit comfortably in
virtual and physical memory, simply take the model used by most of
the applications on the OS. If applications require more than 128 MB
per stack, use the 64-bit edition. If applications approach the
size of physical memory, fit in the 128 MB stack limit and fit in
virtual memory, the 32-bit version has clear advantages. For demanding
applications on 64-bit hardware with more than about 6GB physical
memory the 64-bit model is the model of choice.
CChhaapptteerr 33.. IINNIITTIIAALLIISSIINNGG AANNDD MMAANNAAGGIINNGG AA PPRROOLLOOGG PPRROOJJEECCTT
Prolog text-books give you an overview of the Prolog language. The
manual tells you what predicates are provided in the system and what
they do. This chapter explains how to run a project. There is no
ultimate `right' way to do this. Over the years we developed some
practice in this area and SWI-Prolog's commands are there to support
this practice. This chapter describes the conventions and supporting
commands.
The first two sections (section 3.1 and section 3.2) only require plain
Prolog. The remainder discusses the use of the built-in graphical
tools that require the XPCE graphical library installed on your system.
33..11 TThhee pprroojjeecctt ssoouurrccee ffiilleess
Organisation of source files depends largely on the size of your
project. If you are doing exercises for a Prolog course you'll
normally use one file for each exercise. If you have a small project
you'll work with one directory holding a couple of files and some files
to link it all together. Even bigger projects will be organised in
sub-projects, each using its own directory.
33..11..11 FFiillee NNaammeess aanndd LLooccaattiioonnss
33..11..11..11 FFiillee NNaammee EExxtteennssiioonnss
The first consideration is what extension to use for the source
files. Tradition calls for .pl, but conflicts with Perl force the
use of another extension on systems where extensions have global
meaning, such as MS-Windows. On such systems .pro is the common
alternative. On MS-Windows, the alternative extension is stored
in the registry key HKEY_CURRENT_USER/Software/SWI/Prolog/fileExtension
or HKEY_LOCAL_MACHINE/Software/SWI/Prolog/fileExtension. All versions
of SWI-Prolog load files with the extension .pl as well as with
the registered alternative extension without explicitly specifying
the extension. For portability reasons we propose the following
convention:
IIff tthheerree iiss nnoo ccoonnfflliicctt because you do not use a conflicting
application or the system does not force a unique relation between
extension and application, use .pl.
WWiitthh aa ccoonnfflliicctt choose .pro and use this extension for the files you
want to load through your file manager. Use .pl for all other
files for maximal portability.
33..11..11..22 PPrroojjeecctt DDiirreeccttoorriieess
Large projects are generally composed of sub-projects, each using its
own directory or directory structure. If nobody else will ever touch
your files and you use only one computer, there is little to worry
about, but this is rarely the case with a large project.
To improve portability, SWI-Prolog uses the POSIX notation
for filenames, which uses the forward slash (/) to separate
directories. Just before reaching the file system, SWI-Prolog uses
prolog_to_os_filename/2to convert the filename to the conventions used
by the hosting operating system. It is _s_t_r_o_n_g_l_y advised to write
paths using the /, especially on systems using the \ for this purpose
(MS-Windows). Using \ violates the portability rules and requires you
to _d_o_u_b_l_e the \ due to the Prolog quoted-atom escape rules.
Portable code should use prolog_to_os_filename/2to convert computed
paths into system paths when constructing commands for shell/1 and
friends.
33..11..11..33 SSuubb--pprroojjeeccttss uussiinngg sseeaarrcchh ppaatthhss
Thanks to Quintus, Prolog adapted an extensible mechanism for searching
files using file_search_path/2. This mechanism allows for comfortable
and readable specifications.
Suppose you have extensive library packages on graph algorithms,
set operations and GUI primitives. These sub-projects are likely
candidates for re-use in future projects. A good choice is to create a
directory with sub-directories for each of these sub-projects.
Next, there are three options. One is to add the sub-projects to
the directory hierarchy of the current project. Another is to use a
completely dislocated directory. Third, the sub-project can be added
to the SWI-Prolog hierarchy. Using local installation, a typical
file_search_path/2is:
________________________________________________________________________| |
|:- prolog_load_context(directory, Dir), |
| asserta(user:file_search_path(myapp, Dir)). |
| |
|user:file_search_path(graph, myapp(graph)). |
|user:file_search_path(ui,|___myapp(ui))._______________________________ | |
When using sub-projects in the SWI-Prolog hierarchy, one should use
the path alias swi as basis. For a system-wide installation, use an
absolute path.
Extensive sub-projects with a small well-defined API should define a
load file with calls to use_module/1 to import the various library
components and export the API.
33..11..22 PPrroojjeecctt SSppeecciiaall FFiilleess
There are a number of tasks you typically carry out on your project,
such as loading it, creating a saved state, debugging it, etc. Good
practice on large projects is to define small files that hold the
commands to execute such a task, name this file after the task and give
it a file extension that makes starting easy (see section 3.1.1.1).
The task _l_o_a_d is generally central to these tasks. Here is a tentative
list:
o load.pl
Use this file to set up the environment (Prolog flags and file
search paths) and load the sources. Quite commonly this file also
provides convenient predicates to parse command line options and
start the application.
o run.pl
Use this file to start the application. Normally it loads load.pl
in silent-mode, and calls one of the starting predicates from
load.pl.
o save.pl
Use this file to create a saved state of the application by loading
load.pl and calling qsave_program/2 to generate a saved state with
the proper options.
o debug.pl
Loads the program for debugging. In addition to loading load.pl
this file defines rules for portray/1 to modify printing rules for
complex terms and customisation rules for the debugger and editing
environment. It may start some of these tools.
33..11..33 IInntteerrnnaattiioonnaall ssoouurrccee ffiilleess
As discussed in section 2.18, SWI-Prolog supports international
character handling. Its internal encoding is UNICODE. I/O streams
convert to/from this internal format. This section discusses the
options for source files not in US-ASCII.
SWI-Prolog can read files in any of the encodings described in
section 2.18. Two encodings are of particular interest. The text
encoding deals with the current _l_o_c_a_l_e, the default used by this
computer for representing text files. The encodings utf8, unicode_le
and unicode_be are _U_N_I_C_O_D_E encodings: they can represent---in the same
file---characters of virtually any known language. In addition, they
do so unambiguously.
If one wants to represent non US-ASCII text as Prolog terms in a source
file, there are several options:
o _U_s_e _e_s_c_a_p_e _s_e_q_u_e_n_c_e_s
This approach describes NON-ASCII as sequences of the form \_o_c_t_a_l\.
The numerical argument is interpreted as a UNICODE character. The
resulting Prolog file is strict 7-bit US-ASCII, but if there are
many NON-ASCII characters it becomes very unreadable.
o _U_s_e _l_o_c_a_l _c_o_n_v_e_n_t_i_o_n_s
Alternatively the file may be specified using local conventions,
such as the EUC encoding for Japanese text. The disadvantage is
portability. If the file is moved to another machine, this machine
must use the same _l_o_c_a_l_e or the file is unreadable. There is no
elegant way if files from multiple locales must be united in one
application using this technique. In other words, it is fine for
local projects in countries with uniform locale conventions.
o _U_s_i_n_g _U_T_F_-_8 _f_i_l_e_s
The best way to specify source files with many NON-ASCII characters
is definitely the use of UTF-8 encoding. Prolog can be notified of
this encoding in two ways, using a UTF-8 _B_O_M (see section 2.18.1.1)
or using the directive :- encoding(utf8). Many of today's text
editors, including PceEmacs, are capable of editing UTF-8 files.
Projects that were started using local conventions can be re-coded
using the Unix iconv tool or often using commands offered by the
editor.
33..22 UUssiinngg mmoodduulleess
Modules have been debated fiercely in the Prolog world. Despite all
counter-arguments we feel they are extremely useful because:
o _T_h_e_y _h_i_d_e _l_o_c_a_l _p_r_e_d_i_c_a_t_e_s
This is the reason they were invented in the first place. Hiding
provides two features. They allow for short predicate names
without worrying about conflicts. Given the flat name-space
introduced by modules, they still require meaningful module names
as well as meaningful names for exported predicates.
o _T_h_e_y _d_o_c_u_m_e_n_t _t_h_e _i_n_t_e_r_f_a_c_e
Possibly more important than avoiding name conflicts is their role
in documenting which part of the file is for public usage and
which is private. When editing a module you may assume you
can reorganise anything except the name and the semantics of the
exported predicates without worrying.
o _T_h_e_y _h_e_l_p _t_h_e _e_d_i_t_o_r
The PceEmacs built-in editor does on-the-fly cross-referencing of
the current module, colouring predicates based on their origin and
usage. Using modules, the editor can quickly find out what is
provided by the imported modules by reading just the first term.
This allows it to indicate in real-time which predicates are not
used or not defined.
Using modules is generally easy. Only if you write meta-predicates
(predicates reasoning about other predicates) that are exported from a
module is a good understanding required of the resolution of terms to
predicates inside a module. Here is a typical example from readutil.
________________________________________________________________________| |
|:- module(read_util, |
| [ read_line_to_codes/2, % +Fd, -Codes |
| read_line_to_codes/3, % +Fd, -Codes, ?Tail |
| read_stream_to_codes/2, % +Fd, -Codes |
| read_stream_to_codes/3, % +Fd, -Codes, ?Tail |
| read_file_to_codes/3, % +File, -Codes, +Options |
| read_file_to_terms/3 % +File, -Terms, +Options |
||_________]).__________________________________________________________ ||
33..33 TThhee tteesstt--eeddiitt--rreellooaadd ccyyccllee
SWI-Prolog does not enforce the use of a particular editor for
writing Prolog source code. Editors are complicated programs that
must be mastered in detail for real productive programming. If
you are familiar with a specific editor you should not be forced
to change. You may specify your favourite editor using the Prolog
flag editor, the environment variable EDITOR or by defining rules for
prolog_edit:edit_source/1 (see section 4.5).
The use of a built-in editor, which is selected by setting the Prolog
flag editor to pce_emacs, has advantages. The XPCE _e_d_i_t_o_r object,
around which the built-in PceEmacs is built, can be opened as a Prolog
stream allowing analysis of your source by the real Prolog system.
33..33..11 LLooccaattiinngg tthhiinnggss ttoo eeddiitt
The central predicate for editing something is edit/1, an extensible
front-end that searches for objects (files, predicates, modules, as
well as XPCE classes and methods) in the Prolog database. If multiple
matches are found it provides a choice. Together with the built-in
completion on atoms bound to the TAB key this provides a quick way to
edit objects:
________________________________________________________________________| |
|?- edit(country). |
|Please select item to edit: |
| |
| 1 chat:country/10 '/staff/jan/lib/prolog/chat/countr.pl':16 |
| 2 chat:country/1 '/staff/jan/lib/prolog/chat/world0.pl':72 |
| |
|Your|choice?___________________________________________________________ | |
33..33..22 EEddiittiinngg aanndd iinnccrreemmeennttaall ccoommppiillaattiioonn
One of the nice features of Prolog is that the code can be modified
while the program is running. Using pure Prolog you can trace a
program, find it is misbehaving, enter a _b_r_e_a_k _e_n_v_i_r_o_n_m_e_n_t, modify
the source code, reload it and finally do _r_e_t_r_y on the misbehaving
predicate and try again. This sequence is not uncommon for
long-running programs. For faster programs one will normally abort
after understanding the misbehaviour, edit the source, reload it and
try again.
One of the nice features of SWI-Prolog is the availability of make/0, a
simple predicate that checks all loaded source files to see which ones
you have modified. It then reloads these files, considering the module
from which the file was loaded originally. This greatly simplifies
the trace-edit-verify development cycle. For example, after the tracer
reveals there is something wrong with prove/3, you do:
________________________________________________________________________| |
|?-|edit(prove).________________________________________________________ | |
Now edit the source, possibly switching to other files and making
multiple changes. After finishing, invoke make/0, either through the
editor UI (Compile/Make (Control-C Control-M)) or on the top level, and
watch the files being reloaded.
________________________________________________________________________| |
|?- make. |
|%|show_compiled_into_photo_gallery_0.03_sec,_3,360_bytes_______________ | |
33..44 UUssiinngg tthhee PPcceeEEmmaaccss bbuuiilltt--iinn eeddiittoorr
33..44..11 AAccttiivvaattiinngg PPcceeEEmmaaccss
Initially edit/1 uses the editor specified in the EDITOR environment
variable. There are two ways to force it to use the built-in editor.
One is to set the Prolog flag editor to pce_emacs and the other is by
starting the editor explicitly using the emacs/[0,1] predicates.
33..44..22 BBlluuffffiinngg tthhrroouugghh PPcceeEEmmaaccss
PceEmacs closely mimics Richard Stallman's GNU-Emacs commands, adding
features from modern window-based editors to make it more acceptable
for beginners.
At the basis, PceEmacs maps keyboard sequences to methods defined on
the extended _e_d_i_t_o_r object. Some frequently used commands are, with
their key-binding, presented in the menu bar above each editor window.
A complete overview of the bindings for the current _m_o_d_e is provided
through Help/Show key bindings (Control-h Control-b).
33..44..22..11 EEddiitt mmooddeess
Modes are the heart of (Pce)Emacs. Modes define dedicated editing
support for a particular kind of (source) text. For our purpose we
want _P_r_o_l_o_g _m_o_d_e. There are various ways to make PceEmacs use Prolog
mode for a file.
o _U_s_i_n_g _t_h_e _p_r_o_p_e_r _e_x_t_e_n_s_i_o_n
If the file ends in .pl or the selected alternative (e.g. .pro)
extension, Prolog mode is selected.
o _U_s_i_n_g #!/path/to/pl
If the file is a _P_r_o_l_o_g _S_c_r_i_p_t file, starting with the line
#!/path/to/pl options -s, Prolog mode is selected regardless of the
extension.
o _U_s_i_n_g -*- Prolog -*-
If the above sequence appears in the first line of the file (inside
a Prolog comment) Prolog mode is selected.
o _E_x_p_l_i_c_i_t _s_e_l_e_c_t_i_o_n
Finally, using File/Mode/Prolog (y)ou can switch to Prolog mode
explicitly.
33..44..22..22 FFrreeqquueennttllyy uusseedd eeddiittoorr ccoommmmaannddss
Below we list a few important commands and how to activate them.
o _C_u_t_/_C_o_p_y_/_P_a_s_t_e
These commands follow Unix/X11 traditions. You're best suited
with a three-button mouse. After selecting using the left-mouse
(double-click uses word-mode and triple line-mode), the selected
text is _a_u_t_o_m_a_t_i_c_a_l_l_y copied to the clipboard (X11 primary
selection on Unix). _C_u_t is achieved using the DEL key or by
typing something else at the location. _P_a_s_t_e is achieved using the
middle-mouse (or wheel) button. If you don't have a middle-mouse
button, pressing the left- and right-button at the same time is
interpreted as a middle-button click. If nothing helps, there is
the Edit/Paste menu entry. Text is pasted at the caret location.
o _U_n_d_o
Undo is bound to the GNU-Emacs Control-_ as well as the MS-Windows
Control-Z sequence.
o _A_b_o_r_t
Multi-key sequences can be aborted at any stage using Control-G.
o _F_i_n_d
Find (Search) is started using Control-S (forward) or Control-R
(backward). PceEmacs implements _i_n_c_r_e_m_e_n_t_a_l _s_e_a_r_c_h. This is
difficult to use for novices, but very powerful once you get the
clue. After one of the above start keys, the system indicates
search mode in the status line. As you are typing the search
string, the system searches for it, extending the search with every
character you type. It illustrates the current match using a green
background.
If the target cannot be found, PceEmacs warns you and no longer
extends the search string. During search, some characters have
special meaning. Typing anything but these characters commits the
search, re-starting normal edit mode. Special commands are:
Control-S
Search forwards for next.
Control-R
Search backwards for next.
Control-W
Extend search to next word boundary.
Control-G
Cancel search, go back to where it started.
ESC
Commit search, leaving caret at found location.
Backspace
Remove a character from the search string.
o _D_y_n_a_m_i_c _A_b_b_r_e_v_i_a_t_i_o_n
Also called _d_a_b_b_r_e_v, dynamic abbreviation is an important feature
of Emacs clones to support programming. After typing the first few
letters of an identifier, you may press Alt-/, causing PceEmacs to
search backwards for identifiers that start the same and use it
to complete the text you typed. A second Alt-/ searches further
backwards. If there are no hits before the caret, it starts
searching forwards. With some practice, this system allows for
entering code very fast with nice and readable identifiers (or
other difficult long words).
o _O_p_e_n _(_a _f_i_l_e_)
Is called File/Find file (Control-x Control-f). By default the
file is loaded into the current window. If you want to keep this
window, press Alt-s or click the little icon at the bottom left to
make the window _s_t_i_c_k_y.
o _S_p_l_i_t _v_i_e_w
Sometimes you want to look at two places in the same file. To do
this, use Control-x 2 to create a new window pointing to the same
file. Do not worry, you can edit as well as move around in both.
Control-x 1 kills all other windows running on the same file.
These are the most commonly used commands. In section 3.4.3 we discuss
specific support for dealing with Prolog source code.
33..44..33 PPrroolloogg MMooddee
In the previous section (section 3.4.2) we explained the basics
of PceEmacs. Here we continue with Prolog-specific functionality.
Possibly the most interesting is _S_y_n_t_a_x _h_i_g_h_l_i_g_h_t_i_n_g. Unlike most
editors where this is based on simple patterns, PceEmacs syntax
highlighting is achieved by Prolog itself actually reading and
interpreting the source as you type it. There are three moments at
which PceEmacs checks (part of) the syntax.
o _A_f_t_e_r _t_y_p_i_n_g _a .
After typing a . that is not preceded by a _s_y_m_b_o_l character, the
system assumes you completed a clause, tries to find the start of
this clause and verifies the syntax. If this process succeeds it
colours the elements of the clause according to the rules given
below. Colouring is done using information from the last full
check on this file. If it fails, the syntax error is displayed in
the status line and the clause is not coloured.
o _A_f_t_e_r _t_h_e _c_o_m_m_a_n_d Control-c Control-s
Acronym for CCheck SSyntax, it performs the same checks as above for
the clause surrounding the caret. On a syntax error, however, the
caret is moved to the expected location of the error.
o _A_f_t_e_r _p_a_u_s_i_n_g _f_o_r _t_w_o _s_e_c_o_n_d_s
After a short pause (2 seconds), PceEmacs opens the edit buffer
and reads it as a whole, creating an index of defined, called,
dynamic, imported and exported predicates. After completing this,
it re-reads the file and colours all clauses and calls with valid
syntax.
o _A_f_t_e_r _t_y_p_i_n_g Control-l Control-l
The Control-l command re-centers the window (scrolls the window to
make the caret the center of the window). Typing this command
twice starts the same process as above.
TThhee ccoolloouurr sscchheemmaa
itself is defined in emacs/prolog_colour. The colouring can be
extended and modified using multifile predicates. Please check this
source file for details. In general, underlined objects have a popup
(right-mouse button) associated with common commands such as viewing
the documentation or source. BBoolldd text is used to indicate the
definition of objects (typically predicates when using plain Prolog).
Other colours follow intuitive conventions. See table 3.4.3.
_____________________________________________________
|______________________Clauses_______________________|
| Blue bold |Head of an exported predicate |
| Red bold |Head of a predicate that is not called |
|_Black_bold_|Head_of_remaining_predicates___________|
|______________Calls_in_the_clause_body______________|
| Blue |Call to built-in or imported predicate |
| Red |Call to undefined predicate |
|_Purple_____|Call_to_dynamic_predicate______________|
|___________________Other_entities___________________|
| Dark green |Comment |
| Dark blue |Quoted atom or string |
|_Brown______|Variable_______________________________|
Table 3.1: Colour conventions
LLaayyoouutt ssuuppppoorrtt Layout is not `just nice', it is _e_s_s_e_n_t_i_a_l for writing
readable code. There is much debate on the proper layout of Prolog.
PceEmacs, being a rather small project, supports only one particular
style for layout. Below are examples of typical constructs.
________________________________________________________________________| |
|head(arg1, arg2). |
| |
|head(arg1, arg2) :- !. |
| |
|head(Arg1, arg2) :- !, |
| call1(Arg1). |
| |
|head(Arg1, arg2) :- |
| ( if(Arg1) |
| -> then |
| ; else |
| ). |
| |
|head(Arg1) :- |
| ( a |
| ; b |
| ). |
| |
|head :- |
| a(many, |
| long, |
| arguments(with, |
| many, |
| more), |
| and([ a, |
| long, |
| list, |
| with, |
| a, |
| | tail |
||_____________]))._____________________________________________________ ||
PceEmacs uses the same conventions as GNU-Emacs. The TAB key indents
the current line according to the syntax rules. Alt-q indents all
lines of the current clause. It provides support for head, calls
(indented 1 tab), if-then-else, disjunction and argument lists broken
across multiple lines as illustrated above.
33..44..33..11 FFiinnddiinngg yyoouurr wwaayy aarroouunndd
The command Alt-. extracts name and arity from the caret location and
jumps (after conformation or edit) to the definition of the predicate.
It does so based on the source-location database of loaded predicates
also used by edit/1. This makes locating predicates reliable if all
sources are loaded and up-to-date (see make/0).
In addition, references to files in use_module/[1,2], consult/1, etc.
are red if the file cannot be found and underlined blue if the file can
be loaded. A popup allows for opening the referenced file.
33..55 TThhee GGrraapphhiiccaall DDeebbuuggggeerr
SWI-Prolog offers two debuggers. One is the traditional text
console-based 4-port Prolog tracer and the other is a window-based
source level debugger. The window-based debugger requires XPCE
installed. It operates based on the prolog_trace_interception/4 hook
and other low-level functionality described in chapter 12.
Window-based tracing provides a much better overview due to the eminent
relation to your source code, a clear list of named variables and their
bindings as well as a graphical overview of the call and choice point
stack. There are some drawbacks though. Using a textual trace on the
console, one can scroll back and examine the past, while the graphical
debugger just presents a (much better) overview of the current state.
33..55..11 IInnvvookkiinngg tthhee wwiinnddooww--bbaasseedd ddeebbuuggggeerr
Whether the text-based or window-based debugger is used is controlled
using the predicates guitracer/0 and noguitracer/0. Entering debug
mode is controlled using the normal predicates for this: trace/0
and spy/1. In addition, PceEmacs prolog mode provides the command
Prolog/Break at (Control-c b) to insert a break-point at a specific
location in the source code.
The graphical tracer is particulary useful for debugging threads. The
tracer must be loaded from the main thread before it can be used from a
background thread.
gguuiittrraacceerr
This predicate installs the above-mentioned hooks that redirect
tracing to the window-based environment. No window appears.
The debugger window appears as actual tracing is started through
trace/0, by hitting a spy point defined by spy/1 or a break point
defined using the PceEmacs command Prolog/Break at (Control-c b).
nnoogguuiittrraacceerr
Disable the hooks installed by guitracer/0, reverting to normal
text console-based tracing.
ggttrraaccee
Utility defined as guitracer,trace.
ggddeebbuugg
Utility defined as guitracer,debug.
ggssppyy((_+_P_r_e_d_i_c_a_t_e))
Utility defined as guitracer,spy(Predicate).
33..66 TThhee PPrroolloogg NNaavviiggaattoorr
Another tool is the _P_r_o_l_o_g _N_a_v_i_g_a_t_o_r. This tool can be started
from PceEmacs using the command Browse/Prolog navigator, from the
GUI debugger or using the programmatic IDE interface described in
section 3.8.
33..77 CCrroossss--rreeffeerreenncceerr
A cross-referencer is a tool that examines the caller-callee relation
between predicates, and, using this information to explicate dependency
relations between source files, finds calls to non-existing predicates
and predicates for which no callers can be found. Cross-referencing
is useful during program development, reorganisation, clean-up, porting
and other program maintenance tasks. The dynamic nature of Prolog
makes the task non-trivial. Goals can be created dynamically using
call/1 after construction of a goal term. Abstract interpretation
can find some of these calls, but they can also come from external
communication, making it impossible to predict the callee. In
other words, the cross-referencer has only partial understanding of
the program, and its results are necessarily incomplete. Still, it
provides valuable information to the developer.
SWI-Prolog's cross-referencer is split into two parts. The standard
Prolog library prolog_xref is an extensible library for information
gathering described in section 11.22, and the XPCE library pce_xref
provides a graphical front-end for the cross-referencer described here.
We demonstrate the tool on CHAT80, a natural language question and
answer system by Fernando C.N. Pereira and David H.D. Warren.
ggxxrreeff
Run cross-referencer on all currently loaded files and present a
graphical overview of the result. As the predicate operates on
the currently loaded application it must be run after loading the
application.
The lleefftt wwiinnddooww (see figure ????) provides browsers for loaded files and
predicates. To avoid long file paths, the file hierarchy has three
main branches. The first is the current directory holding the sources.
The second is marked alias, and below it are the file-search-path
aliases (see file_search_path/2 and absolute_file_name/3). Here you
find files loaded from the system as well as modules of the program
loaded from other locations using the file search path. All loaded
files that fall outside these categories are below the last branch
called /. Files where the system found suspicious dependencies are
marked with an exclamation mark. This also holds for directories
holding such files. Clicking on a file opens a _F_i_l_e _i_n_f_o window in the
right pane.
The FFiillee iinnffoo window shows a file, its main properties, its undefined
and not-called predicates and its import and export relations to other
files in the project. Both predicates and files can be opened by
clicking on them. The number of callers in a file for a certain
predicate is indicated with a blue underlined number. A left-click
will open a list and allow editing the calling predicate.
The DDeeppeennddeenncciieess (see figure ????) window displays a graphical overview
of dependencies between files. Using the background menu a complete
graph of the project can be created. It is also possible to drag files
onto the graph window and use the menu on the nodes to incrementally
expand the graph. The underlined blue text indicates the number of
predicates used in the destination file. Left-clicking opens a menu to
open the definition or select one of the callers.
MMoodduullee aanndd nnoonn--mmoodduullee ffiilleess The cross-referencer threads module and
non-module project files differently. Module files have explicit
import and export relations and the tool shows the usage and
consistency of the relations. Using the Header menu command, the tool
creates a consistent import list for the module that can be included
in the file. The tool computes the dependency relations between the
non-module files. If the user wishes to convert the project into a
module-based one, the Header command generates an appropriate module
header and import list. Note that the cross-referencer may have missed
dependencies and does not deal with meta-predicates defined in one
module and called in another. Such problems must be resolved manually.
SSeettttiinnggss The following settings can be controlled from the settings
menu:
WWaarrnn aauuttoollooaadd
By default disabled. If enabled, modules that require predicates
to be autoloaded are flagged with a warning and the file info
window of a module shows the required autoload predicates.
WWaarrnn nnoott ccaalllleedd
If enabled (default), the file overview shows an alert icon for
files that have predicates that are not called.
33..88 AAcccceessssiinngg tthhee IIDDEE ffrroomm yyoouurr pprrooggrraamm
Over the years a collection of IDE components have been developed, each
with its own interface. In addition, some of these components require
each other, and loading IDE components must be on demand to avoid
the IDE being part of a saved state (see qsave_program/2). For this
reason, access to the IDE is concentrated on a single interface called
prolog_ide/1:
pprroolloogg__iiddee((_+_A_c_t_i_o_n))
This predicate ensures the IDE-enabling XPCE component is loaded,
creates the XPCE class _p_r_o_l_o_g___i_d_e and sends _A_c_t_i_o_n to its one and
only instance @prolog_ide. _A_c_t_i_o_n is one of the following:
ooppeenn__nnaavviiggaattoorr((_+_D_i_r_e_c_t_o_r_y))
Open the Prolog Navigator (see section 3.6) in the given
_D_i_r_e_c_t_o_r_y.
ooppeenn__ddeebbuugg__ssttaattuuss
Open a window to edit spy and trace points.
ooppeenn__qquueerryy__wwiinnddooww
Open a little window to run Prolog queries from a GUI
component.
tthhrreeaadd__mmoonniittoorr
Open a graphical window indicating existing threads and their
status.
ddeebbuugg__mmoonniittoorr
Open a graphical front-end for the debug library that provides
an overview of the topics and catches messages.
xxrreeff
Open a graphical front-end for the cross-referencer that
provides an overview of predicates and their callers.
33..99 SSuummmmaarryy ooff tthhee IIDDEE
The SWI-Prolog development environment consists of a number of
interrelated but not (yet) integrated tools. Here is a list of the
most important features and tips.
o _A_t_o_m _c_o_m_p_l_e_t_i_o_n
The console completes a partial atom on the TAB key and shows
alternatives on the command Alt-?.
o _U_s_e edit/1 _f_o_r _f_i_n_d_i_n_g _l_o_c_a_t_i_o_n_s
The command edit/1 takes the name of a file, module, predicate or
other entity registered through extensions and starts the user's
preferred editor at the right location.
o _S_e_l_e_c_t _e_d_i_t_o_r
External editors are selected using the EDITOR environment
variable, by setting the Prolog flag editor, or by defining the
hook prolog_edit:edit_source/1.
o _U_p_d_a_t_e _P_r_o_l_o_g _a_f_t_e_r _e_d_i_t_i_n_g
Using make/0, all files you have edited are re-loaded.
o _P_c_e_E_m_a_c_s
Offers syntax highlighting and checking based on real-time parsing
of the editor's buffer, layout support and navigation support.
o _U_s_i_n_g _t_h_e _g_r_a_p_h_i_c_a_l _d_e_b_u_g_g_e_r
The predicates guitracer/0 and noguitracer/0 switch between
traditional text-based and window-based debugging. The tracer is
activated using the trace/0, spy/1 or menu items from PceEmacs or
the Prolog Navigator.
o _T_h_e _P_r_o_l_o_g _N_a_v_i_g_a_t_o_r
Shows the file structure and structure inside the file. It allows
for loading files, editing, setting spy points, etc.
CChhaapptteerr 44.. BBUUIILLTT--IINN PPRREEDDIICCAATTEESS
44..11 NNoottaattiioonn ooff PPrreeddiiccaattee DDeessccrriippttiioonnss
We have tried to keep the predicate descriptions clear and concise.
First, the predicate name is printed in bold face, followed by the
arguments in italics. Arguments are preceded by a mode indicator.
There is no complete agreement on mode indicators in the Prolog
community. We use the following definitions:
________________________________________________________+Argument must be fully instantiated to a term that
satisfies the required argument type. Think of
the argument as _i_n_p_u_t.
- Argument must be unbound. Think of the argument
as _o_u_t_p_u_t.
? Argument must be bound to a _p_a_r_t_i_a_l _t_e_r_m
of the indicated type. Note that a
variable is a partial term for any type.
Think of the argument as either _i_n_p_u_t or
_o_u_t_p_u_t or _b_o_t_h input and output. For
example, in stream_property(S, reposition(Bool)),
the reposition part of the term is input and the
uninstantiated _B_o_o_l is output.
: Argument is a meta-argument. Implies +. See
chapter 5 for more information on module handling.
@ Argument is not further instantiated. Typically
used for type tests.
! Argument contains a mutable structure that may be
____modified_using_setarg/3_or_nb_setarg/3._____________
Referring to a predicate in running text is done using a _p_r_e_d_i_c_a_t_e
_i_n_d_i_c_a_t_o_r. The canonical and most generic form of a predicate
indicator is a term <_m_o_d_u_l_e>:<_n_a_m_e>/<_a_r_i_t_y>. If the module is irrelevant
(built-in predicate) or can be inferred from the context it is
often omitted. Compliant to the ISO standard draft on DCG (see
section 4.12), SWI-Prolog also allows for [<_m_o_d_u_l_e>]:<_n_a_m_e>//<_a_r_i_t_y> to
refer to a grammar rule. For all non-negative arity, <_n_a_m_e>//<_a_r_i_t_y>
is the same as <_n_a_m_e>/<_a_r_i_t_y>+2, regardless of whether or not the
referenced predicate is defined or can be used as a grammar rule.
The //-notation can be used in all places that traditionally allow
for a predicate indicator, e.g., the module declaration, spy/1, and
dynamic/1.
44..22 CChhaarraacctteerr rreepprreesseennttaattiioonn
In traditional (Edinburgh) Prolog, characters are represented using
_c_h_a_r_a_c_t_e_r _c_o_d_e_s. Character codes are integer indices into a specific
character set. Traditionally the character set was 7-bit US-ASCII.
8-bit character sets have been allowed for a long time, providing
support for national character sets, of which iso-latin-1 (ISO 8859-1)
is applicable to many Western languages.
ISO Prolog introduces three types, two of which are used for characters
and one for accessing binary streams (see open/4). These types are:
o _c_o_d_e
A _c_h_a_r_a_c_t_e_r _c_o_d_e is an integer representing a single character.
As files may use multi-byte encoding for supporting different
character sets (utf-8 encoding for example), reading a code from a
text file is in general not the same as reading a byte.
o _c_h_a_r
Alternatively, characters may be represented as _o_n_e_-_c_h_a_r_a_c_t_e_r
_a_t_o_m_s. This is a natural representation, hiding encoding problems
from the programmer as well as providing much easier debugging.
o _b_y_t_e
Bytes are used for accessing binary streams.
In SWI-Prolog, character codes are _a_l_w_a_y_s the Unicode equivalent of
the encoding. That is, if get_code/1 reads from a stream encoded as
KOI8-R (used for the Cyrillic alphabet), it returns the corresponding
Unicode code points. Similarly, assembling or disassembling atoms
using atom_codes/2 interprets the codes as Unicode points. See
section 2.18.1 for details.
To ease the pain of the two character representations (code and char),
SWI-Prolog's built-in predicates dealing with character data work as
flexible as possible: they accept data in any of these formats as
long as the interpretation is unambiguous. In addition, for output
arguments that are instantiated, the character is extracted before
unification. This implies that the following two calls are identical,
both testing whether the next input character is an a.
________________________________________________________________________| |
|peek_code(Stream, a). |
|peek_code(Stream,|97)._________________________________________________ | |
The two character representations are handled by a large number of
built-in predicates, all of which are ISO-compatible. For converting
between code and character there is char_code/2. For breaking
atoms and numbers into characters there are atom_chars/2, atom_codes/2,
number_chars/2 and number_codes/2. For character I/O on streams there
are get_char/[1,2], get_code/[1,2], get_byte/[1,2], peek_char/[1,2],
peek_code/[1,2], peek_byte/[1,2], put_code/[1,2], put_char/[1,2] and
put_byte/[1,2]. The Prolog flag double_quotes controls how text between
double quotes is interpreted.
44..33 LLooaaddiinngg PPrroolloogg ssoouurrccee ffiilleess
This section deals with loading Prolog source files. A Prolog source
file is a plain text file containing a Prolog program or part thereof.
Prolog source files come in three flavours:
AA ttrraaddiittiioonnaall Prolog source file contains Prolog clauses and
directives, but no _m_o_d_u_l_e _d_e_c_l_a_r_a_t_i_o_n (see module/1). They are
normally loaded using consult/1 or ensure_loaded/1. Currently, a
non-module file can only be loaded into a single module.
AA mmoodduullee Prolog source file starts with a module declaration. The
subsequent Prolog code is loaded into the specified module, and
only the _e_x_p_o_r_t_e_d predicates are made available to the context
loading the module. Module files are normally loaded with
use_module/[1,2]. See chapter 5 for details.
AAnn iinncclluuddee Prolog source file is loaded using the include/1
directive, textually including Prolog text into another Prolog
source. A file may be included into multiple source files and is
typically used to share _d_e_c_l_a_r_a_t_i_o_n_s such as multifile or dynamic
between source files.
Prolog source files are located using absolute_file_name/3 with the
following options:
________________________________________________________________________| |
|locate_prolog_file(Spec, Path) :- |
| absolute_file_name(Spec, |
| [ file_type(prolog), |
| access(read) |
| ], |
||__________________________Path).______________________________________ ||
The file_type(_p_r_o_l_o_g) option is used to determine the extension of the
file using prolog_file_type/2. The default extension is .pl. _S_p_e_c
allows for the _p_a_t_h _a_l_i_a_s construct defined by absolute_file_name/3.
The most commonly used path alias is library(_L_i_b_r_a_r_y_F_i_l_e). The example
below loads the library file ordsets.pl (containing predicates for
manipulating ordered sets).
________________________________________________________________________| |
|:-|use_module(library(ordsets))._______________________________________ | |
SWI-Prolog recognises grammar rules (DCG) as defined in
[Clocksin & Melish, 1987]. The user may define additional com-
pilation of the source file by defining the dynamic multifile
predicates term_expansion/2, term_expansion/4, goal_expansion/2 and
goal_expansion/4. It is not allowed to use assert/1, retract/1
or any other database predicate in term_expansion/2 other than for
local computational purposes. Code that needs to create additional
clauses must use compile_aux_clauses/1. See library(apply_macros) for
an example.
A _d_i_r_e_c_t_i_v_e is an instruction to the compiler. Directives are used
to set (predicate) properties (see section 4.14), set flags (see
set_prolog_flag/2) and load files (this section). Directives are terms
of the form :- <_t_e_r_m>.. Here are some examples:
________________________________________________________________________| |
|:- use_module(library(lists)). |
|:- dynamic |
||_______store/2.________________%_Name,_Value__________________________ ||
The directive initialization/1 can be used to run arbitrary Prolog
goals. The specified goal is started _a_f_t_e_r loading the file in which
it appears has completed.
SWI-Prolog compiles code as it is read from the file, and directives
are executed as _g_o_a_l_s. This implies that directives may call any
predicate that has been defined before the point where the directive
appears. It also accepts ?- <_t_e_r_m>.as a synonym.
SWI-Prolog does not have a separate reconsult/1 predicate.
Reconsulting is implied automatically by the fact that a file is
consulted which is already loaded.
Advanced topics are handled in subsequent sections: mutually dependent
files (section 4.3.2.1), multithreaded loading (section 4.3.2.2) and
reloading running code (section 4.3.2.3).
The core of the family of loading predicates is load_files/2. The
predicates consult/1, ensure_loaded/1, use_module/1, use_module/2 and
reexport/1 pass the file argument directly to load_files/2 and pass
additional options as expressed in the table 4.1:
_______________________________________________________PPrreeddiiccaatteeiiffmmuusstt__bbee__mmoodduulleeiimmppoorrtt
______________________________________________________________________________________________________________consult/1truefalseall
ensure_loaded/1 not_loaded false all
use_module/1 not_loaded true all
use_module/2 not_loaded true specified
reexport/1 not_loaded true all
_reexport/2______not_loaded_______true______specified__
Table 4.1: Properties of the file-loading predicates. The _i_m_p_o_r_t
column specifies what is imported if the loaded file is a module file.
llooaadd__ffiilleess((_:_F_i_l_e_s_, _+_O_p_t_i_o_n_s))
The predicate load_files/2 is the parent of all the other loading
predicates except for include/1. It currently supports a subset
of the options of Quintus load_files/2. _F_i_l_e_s is either a single
source file or a list of source files. The specification for a
source file is handed to absolute_file_name/2. See this predicate
for the supported expansions. _O_p_t_i_o_n_s is a list of options using
the format _O_p_t_i_o_n_N_a_m_e(_O_p_t_i_o_n_V_a_l_u_e).
The following options are currently supported:
aauuttoollooaadd((_B_o_o_l))
If true (default false), indicate that this load is a _d_e_m_a_n_d
load. This implies that, depending on the setting of the
Prolog flag verbose_autoload, the load action is printed at
level informational or silent. See also print_message/2 and
current_prolog_flag/2.
ddeerriivveedd__ffrroomm((_F_i_l_e))
Indicate that the loaded file is derived from _F_i_l_e. Used by
make/0 to time-check and load the original file rather than
the derived file.
ddiiaalleecctt((_+_D_i_a_l_e_c_t))
Load _F_i_l_e_s with enhanced compatibility with the target Prolog
system identified by _D_i_a_l_e_c_t. See expects_dialect/1 and
section 13 for details.
eennccooddiinngg((_E_n_c_o_d_i_n_g))
Specify the way characters are encoded in the file. Default
is taken from the Prolog flag encoding. See section 2.18.1
for details.
eexxppaanndd((_B_o_o_l))
If true, run the filenames through expand_file_name/2 and load
the returned files. Default is false, except for consult/1
which is intended for interactive use. Flexible location of
files is defined by file_search_path/2.
ffoorrmmaatt((_+_F_o_r_m_a_t))
Used to specify the file format if data is loaded from a
stream using the stream(_S_t_r_e_a_m) option. Default is source,
loading Prolog source text. If qlf, load QLF data (see
qcompile/1).
iiff((_C_o_n_d_i_t_i_o_n))
Load the file only if the specified condition is satisfied.
The value true loads the file unconditionally, changed loads
the file if it was not loaded before or has been modified
since it was loaded the last time, and not_loaded loads the
file if it was not loaded before.
iimmppoorrttss((_I_m_p_o_r_t))
Specify what to import from the loaded module. The default
for use_module/1 is all. _I_m_p_o_r_t is passed from the second
argument of use_module/2. Traditionally it is a list of
predicate indicators to import. As part of the SWI-Prolog/YAP
integration, we also support _P_r_e_d as _N_a_m_e to import a
predicate under another name. Finally, _I_m_p_o_r_t can be the term
except(_E_x_c_e_p_t_i_o_n_s), where _E_x_c_e_p_t_i_o_n_s is a list of predicate
indicators that specify predicates that are _n_o_t imported or
_P_r_e_d as _N_a_m_e terms to denote renamed predicates. See also
reexport/2 and use_module/2.
If _I_m_p_o_r_t equals all, all operators are imported as well.
Otherwise, operators are _n_o_t imported. Operators can be
imported selectively by adding terms op(_P_r_i_,_A_s_s_o_c_,_N_a_m_e) to the
_I_m_p_o_r_t list. If such a term is encountered, all exported
operators that unify with this term are imported. Typically,
this construct will be used with all arguments unbound to
import all operators or with only _N_a_m_e bound to import a
particular operator.
mmooddiiffiieedd((_T_i_m_e_S_t_a_m_p))
Claim that the source was loaded at _T_i_m_e_S_t_a_m_p without checking
the source. This option is intended to be used together with
the stream(_I_n_p_u_t) option, for example after extracting the
time from an HTTP server or database.
mmuusstt__bbee__mmoodduullee((_B_o_o_l))
If true, raise an error if the file is not a module file.
Used by use_module/[1,2].
qqccoommppiillee((_A_t_o_m))
How to deal with quick-load-file compilation by qcompile/1.
Values are:
nneevveerr
Default. Do not use qcompile unless called explicitly.
aauuttoo
Use qcompile for all writeable files. See comment below.
llaarrggee
Use qcompile if the file is `large'. Currently, files
larger than 100 Kbytes are considered large.
ppaarrtt
If this load_file/2 appears in a directive of a file that
is compiled into Quick Load Format using qcompile/1, the
contents of the argument files are included in the .qlf
file instead of the loading directive.
If this option is not present, it uses the value of the Prolog
flag qcompile as default.
rreeddeeffiinnee__mmoodduullee((_+_A_c_t_i_o_n))
Defines what to do if a file is loaded that provides a module
that is already loaded from another file. _A_c_t_i_o_n is one of
false (default), which prints an error and refuses to load the
file, or true, which uses unload_file/1 on the old file and
then proceeds loading the new file. Finally, there is ask,
which starts interaction with the user. ask is only provided
if the stream user_input is associated with a terminal.
rreeeexxppoorrtt((_B_o_o_l))
If true re-export the imported predicate. Used by reexport/1
and reexport/2.
rreeggiisstteerr((_B_o_o_l))
If false, do not register the load location and options. This
option is used by make/0 and load_hotfixes/1 to avoid polluting
the load-context database. See source_file_property/2.
ssaannddbbooxxeedd((_B_o_o_l))
Load the file in _s_a_n_d_b_o_x_e_d mode. This option controls the
flag sandboxed_load. The only meaningful value for _B_o_o_l is
true. Using false while the Prolog flag is set to true raises
a permission error.
ssccooppee__sseettttiinnggss((_B_o_o_l))
Scope style_check/1 and expects_dialect/1to the file and files
loaded from the file after the directive. Default is true.
The system and user initialization files (see -f and -F) are
loading with scope_settings(_f_a_l_s_e).
ssiilleenntt((_B_o_o_l))
If true, load the file without printing a message. The
specified value is the default for all files loaded as a
result of loading the specified files. This option writes the
Prolog flag verbose_load with the negation of _B_o_o_l.
ssttrreeaamm((_I_n_p_u_t))
This SWI-Prolog extension compiles the data from the stream
_I_n_p_u_t. If this option is used, _F_i_l_e_s must be a single atom
which is used to identify the source location of the loaded
clauses as well as to remove all clauses if the data is
reconsulted.
This option is added to allow compiling from non-file
locations such as databases, the web, the _u_s_e_r (see consult/1)
or other servers. It can be combined with format(_q_l_f) to load
QLF data from a stream.
The load_files/2 predicate can be hooked to load other data or
data from objects other than files. See prolog_load_file/2 for
a description and http/http_load for an example. All hooks for
load_files/2 are documented in section 12.9.
ccoonnssuulltt((_:_F_i_l_e))
Read _F_i_l_e as a Prolog source file. Calls to consult/1 may
be abbreviated by just typing a number of filenames in a list.
Examples:
?- consult(load). % consult load or load.pl
?- [library(lists)]. % load library lists
?- [user]. % Type program on the terminal
The predicate consult/1 is equivalent to load_files(File, []),
except for handling the special file user, which reads clauses from
the terminal. See also the stream(_I_n_p_u_t) option of load_files/2.
eennssuurree__llooaaddeedd((_:_F_i_l_e))
If the file is not already loaded, this is equivalent to consult/1.
Otherwise, if the file defines a module, import all public
predicates. Finally, if the file is already loaded, is not a
module file, and the context module is not the global user module,
ensure_loaded/1 will call consult/1.
With this semantics, we hope to get as close as possible to
the clear semantics without the presence of a module system.
Applications using modules should consider using use_module/[1,2].
Equivalent to load_files(Files, [if(not_loaded)]).
iinncclluuddee((_+_F_i_l_e)) _[_I_S_O_]
Textually include the content of _F_i_l_e in the file in which the
_d_i_r_e_c_t_i_v_e :- include(File). appears. The include construct is only
honoured if it appears as a directive in a source file. _T_e_x_t_u_a_l
include (similar to C/C++ #include) is obviously useful for sharing
declarations such as dynamic/1 or multifile/1 by including a file
with directives from multiple files that use these predicates.
Textual including files that contain clauses is less obvious.
Normally, in SWI-Prolog, clauses are _o_w_n_e_d by the file in which
they are defined. This information is used to _r_e_p_l_a_c_e the old
definition after the file has beeen modified and is reloaded
by, e.g., make/0. As we understand it, include/1 is intended
to include the same file multiple times. Including a file
holding clauses multiple times into the same module is rather
meaningless as it just duplicates the same clauses. Including a
file holding clauses in multiple modules does not suffer from this
problem, but leads to multiple equivalent _c_o_p_i_e_s of predicates.
Using use_module/1 can achieve the same result while _s_h_a_r_i_n_g the
predicates.
Despite these observations, various projects seem to be using
include/1 to load files holding clauses, typically loading them
only once. Such usage would allow replacement by, e.g., consult/1.
Unfortunately, the same project might use include/1 to share
directives. Another example of a limitation of mapping to
consult/1 is that if the clauses of a predicate are distributed
over two included files, discontiguous/1 is appropriate, while
if they are distributed over two consulted files, one must use
multifile/1.
To accommodate included files holding clauses, SWI-Prolog
distinguishes between the source location of a clause (in this
case the included file) and the _o_w_n_e_r of a clause (the file that
includes the file holding the clause). The source location is
used by, e.g., edit/1, the graphical tracer, etc., while the
owner is used to determine which clauses are removed if the file
is modified. Relevant information is found with the following
predicates:
o source_file/2 describes the owner relation.
o predicate_property/2 describes the source location (of the
first clause).
o clause_property/2 provides access to both source and ownership.
o source_file_property/2 can be used to query include relation-
ships between files.
rreeqquuiirree((_+_L_i_s_t_O_f_N_a_m_e_A_n_d_A_r_i_t_y))
Declare that this file/module requires the specified predicates
to be defined ``with their commonly accepted definition''. This
predicate originates from the Prolog portability layer for XPCE.
It is intended to provide a portable mechanism for specifying that
this module requires the specified predicates.
The implementation normally first verifies whether the predicate is
already defined. If not, it will search the libraries and load the
required library.
SWI-Prolog, having autoloading, does nnoott load the library. Instead
it creates a procedure header for the predicate if it does not
exist. This will flag the predicate as `undefined'. See also
check/0 and autoload/0.
eennccooddiinngg((_+_E_n_c_o_d_i_n_g))
This directive can appear anywhere in a source file to define how
characters are encoded in the remainder of the file. It can
be used in files that are encoded with a superset of US-ASCII,
currently UTF-8 and ISO Latin-1. See also section 2.18.1.
mmaakkee
Consult all source files that have been changed since they were
consulted. It checks _a_l_l loaded source files: files loaded into
a compiled state using pl -c ... and files loaded using consult/1
or one of its derivatives. The predicate make/0 is called
after edit/1, automatically reloading all modified files. If the
user uses an external editor (in a separate window), make/0 is
normally used to update the program after editing. In addition,
make/0 updates the autoload indices (see section 2.13) and runs
list_undefined/0 from the check library to report on undefined
predicates.
lliibbrraarryy__ddiirreeccttoorryy((_?_A_t_o_m))
Dynamic predicate used to specify library directories. Default
./lib, ~/lib/prolog and the system's library (in this order) are
defined. The user may add library directories using assertz/1,
asserta/1 or remove system defaults using retract/1. Deprecated.
New code should use file_search_path/2.
ffiillee__sseeaarrcchh__ppaatthh((_+_A_l_i_a_s_, _?_P_a_t_h))
Dynamic predicate used to specify `path aliases'. This feature is
best described using an example. Given the definition:
____________________________________________________________________| |
||file_search_path(demo,_'/usr/lib/prolog/demo').___________________ ||
the file specification demo(myfile) will be expanded to /usr/lib/
prolog/demo/myfile. The second argument of file_search_path/2 may
be another alias.
Below is the initial definition of the file search path. This
path implies swi(<_P_a_t_h>) and refers to a file in the SWI-Prolog
home directory. The alias foreign(<_P_a_t_h>) is intended for
storing shared libraries (.so or .DLL files). See also
load_foreign_library/[1,2].
____________________________________________________________________| |
| user:file_search_path(library, X) :- |
| library_directory(X). |
| user:file_search_path(swi, Home) :- |
| current_prolog_flag(home, Home). |
| user:file_search_path(foreign, swi(ArchLib)) :- |
| current_prolog_flag(arch, Arch), |
| atom_concat('lib/', Arch, ArchLib). |
| user:file_search_path(foreign, swi(lib)). |
| user:file_search_path(path, Dir) :- |
| getenv('PATH', Path), |
| ( current_prolog_flag(windows, true) |
| -> atomic_list_concat(Dirs, (;), Path) |
| ; atomic_list_concat(Dirs, :, Path) |
| ), |
||________member(Dir,_Dirs).________________________________________ ||
The file_search_path/2expansion is used by all loading predicates
as well as by absolute_file_name/[2,3].
The Prolog flag verbose_file_search can be set to true to help
debugging Prolog's search for files.
eexxppaanndd__ffiillee__sseeaarrcchh__ppaatthh((_+_S_p_e_c_, _-_P_a_t_h))
Unifies _P_a_t_h with all possible expansions of the filename specifi-
cation _S_p_e_c. See also absolute_file_name/3.
pprroolloogg__ffiillee__ttyyppee((_?_E_x_t_e_n_s_i_o_n_, _?_T_y_p_e))
This dynamic multifile predicate defined in module user determines
the extensions considered by file_search_path/2. _E_x_t_e_n_s_i_o_n is the
filename extension without the leading dot, and _T_y_p_e denotes the
type as used by the file_type(_T_y_p_e) option of file_search_path/2.
Here is the initial definition of prolog_file_type/2:
____________________________________________________________________| |
| user:prolog_file_type(pl, prolog). |
| user:prolog_file_type(Ext, prolog) :- |
| current_prolog_flag(associate, Ext), |
| Ext \== pl. |
| user:prolog_file_type(qlf, qlf). |
| user:prolog_file_type(Ext, executable) :- |
||________current_prolog_flag(shared_object_extension,_Ext).________ ||
Users can add extensions for Prolog source files to avoid conflicts
(for example with perl) as well as to be compatible with another
Prolog implementation. We suggest using .pro for avoiding
conflicts with perl. Overriding the system definitions can stop
the system from finding libraries.
ssoouurrccee__ffiillee((_?_F_i_l_e))
True if _F_i_l_e is a loaded Prolog source file. _F_i_l_e is the absolute
and canonical path to the source file.
ssoouurrccee__ffiillee((_?_P_r_e_d_, _?_F_i_l_e))
True if the predicate specified by _P_r_e_d was loaded from file _F_i_l_e,
where _F_i_l_e is an absolute path name (see absolute_file_name/2).
Can be used with any instantiation pattern, but the database
only maintains the source file for each predicate. See also
clause_property/2. Note that the relation between files and
predicates is more complicated if include/1 is used. The predicate
describes the _o_w_n_e_r of the predicate. See include/1 for details.
ssoouurrccee__ffiillee__pprrooppeerrttyy((_?_F_i_l_e_, _?_P_r_o_p_e_r_t_y))
True when _P_r_o_p_e_r_t_y is a property of the loaded file _F_i_l_e. If
_F_i_l_e is non-var, it can be a file specification that is valid for
load_files/2. Defined properties are:
ddeerriivveedd__ffrroomm((_O_r_i_g_i_n_a_l_, _O_r_i_g_i_n_a_l_M_o_d_i_f_i_e_d))
_F_i_l_e was generated from the file _O_r_i_g_i_n_a_l, which was last
modified at time _O_r_i_g_i_n_a_l_M_o_d_i_f_i_e_d at the time it was loaded.
This property is available if _F_i_l_e was loaded using the
derived_from(_O_r_i_g_i_n_a_l) option to load_files/2.
iinncclluuddeess((_I_n_c_l_u_d_e_d_F_i_l_e_, _I_n_c_l_u_d_e_d_F_i_l_e_M_o_d_i_f_i_e_d))
_F_i_l_e used include/1 to include _I_n_c_l_u_d_e_d_F_i_l_e. The last
modified time of _I_n_c_l_u_d_e_d_F_i_l_e was _I_n_c_l_u_d_e_d_F_i_l_e_M_o_d_i_f_i_e_d at the
time it was included.
iinncclluuddeedd__iinn((_M_a_s_t_e_r_F_i_l_e_, _L_i_n_e))
_F_i_l_e was included into _M_a_s_t_e_r_F_i_l_e from line _L_i_n_e. This is the
inverse of the includes property.
llooaadd__ccoonntteexxtt((_M_o_d_u_l_e_, _L_o_c_a_t_i_o_n_, _O_p_t_i_o_n_s))
_M_o_d_u_l_e is the module into which the file was loaded. If _F_i_l_e
is a module, this is the module into which the exports are
imported. Otherwise it is the module into which the clauses
of the non-module file are loaded. _L_o_c_a_t_i_o_n describes the
file location from which the file was loaded. It is either
a term <_f_i_l_e>:<_l_i_n_e> or the atom user if the file was loaded
from the terminal or another unknown source. _O_p_t_i_o_n_s are the
options passed to load_files/2. Note that all predicates
to load files are mapped to load_files/2, using the option
argument to specify the exact behaviour.
mmooddiiffiieedd((_S_t_a_m_p))
File modification time when _F_i_l_e was loaded. This is used by
make/0 to find files whose modification time is different from
when it was loaded.
mmoodduullee((_M_o_d_u_l_e))
_F_i_l_e is a module file that declares the module _M_o_d_u_l_e.
uunnllooaadd__ffiillee((_+_F_i_l_e))
Remove all clauses loaded from _F_i_l_e. If _F_i_l_e loaded a module,
clear the module's export list and disassociate it from the file.
_F_i_l_e is a canonical filename or a file indicator that is valid for
load_files/2.
This predicate should be used with care. The multithreaded nature
of SWI-Prolog makes removing static code unsafe. Attempts to do
this should be reserved for development or situations where the
application can guarantee that none of the clauses associated to
_F_i_l_e are active.
pprroolloogg__llooaadd__ccoonntteexxtt((_?_K_e_y_, _?_V_a_l_u_e))
Obtain context information during compilation. This predicate
can be used from directives appearing in a source file to
get information about the file being loaded. See also
source_location/2 and if/1. The following keys are defined:
______________________________________________________________________
|__KKeeyy________________________||DDeessccrriippttiioonn________________________________________________________________________________||__
|| module |Module into which file is loaded |
| source |File being loaded. If the system is processing an|
| |included file, the value is the _m_a_i_n file. Returns|
| |the original Prolog file when loading a .qlf file. |
| file |Similar to source, but returns the file being|
| |included when called while an include file is being|
| |processed |
| stream |Stream identifier (see current_input/1) |
| directory |Directory in which source lives |
| dialect |Compatibility mode. See expects_dialect/1. |
| term_position |Position of last term read. Term of the|
| |form '$stream_position'(0,<_L_i_n_e>,0,0,0). See also|
| |stream_position_data/3. |
| variable_names |A list of `_N_a_m_e = _V_a_r' of the last term read. See|
| |read_term/2for details. |
| script |Boolean that indicates whether the file is loaded|
|________________|as_a_script_file_(see_-s)__________________________|_
The directory is commonly used to add rules to file_search_path/2,
setting up a search path for finding files with
absolute_file_name/3. For example:
____________________________________________________________________| |
| :- dynamic user:file_search_path/2. |
| :- multifile user:file_search_path/2. |
| |
| :- prolog_load_context(directory, Dir), |
| asserta(user:file_search_path(my_program_home, Dir)). |
| |
| ... |
| absolute_file_name(my_program_home('README.TXT'), ReadMe, |
| [ access(read) ]), |
||____...___________________________________________________________ ||
ssoouurrccee__llooccaattiioonn((_-_F_i_l_e_, _-_L_i_n_e))
If the last term has been read from a physical file (i.e., not from
the file user or a string), unify _F_i_l_e with an absolute path to the
file and _L_i_n_e with the line number in the file. New code should
use prolog_load_context/2.
aatt__hhaalltt((_:_G_o_a_l))
Register _G_o_a_l to be run from PL_cleanup(), which is called when
the system halts. The hooks are run in the reverse order
they were registered (FIFO). Success or failure executing a hook
is ignored. If the hook raises an exception this is printed
using print_message/2. An attempt to call halt/[0,1] from a hook
is ignored. Hooks may call cancel_halt/1, causing halt/0 and
PL_halt(_0) to print a message indicating that halting the system
has been cancelled.
ccaanncceell__hhaalltt((_+_R_e_a_s_o_n))
If this predicate is called from a hook registered with at_halt/1,
halting Prolog is cancelled and an informational message is printed
that includes _R_e_a_s_o_n. This is used by the development tools to
cancel halting the system if the editor has unsafed data and the
user decides to cancel.
::-- iinniittiiaalliizzaattiioonn((_:_G_o_a_l)) _[_I_S_O_]
Call _G_o_a_l _a_f_t_e_r loading the source file in which this directive
appears has been completed. In addition, _G_o_a_l is executed if a
saved state created using qsave_program/1 is restored.
The ISO standard only allows for using :- Term if _T_e_r_m is a
_d_i_r_e_c_t_i_v_e. This means that arbitrary goals can only be called from
a directive by means of the initialization/1 directive. SWI-Prolog
does not enforce this rule.
The initialization/1 directive must be used to do program
initialization in saved states (see qsave_program/1). A saved
state contains the predicates, Prolog flags and operators present
at the moment the state was created. Other resources (records,
foreign resources, etc.) must be recreated using initialization/1
directives or from the entry goal of the saved state.
Up to SWI-Prolog 5.7.11, _G_o_a_l was executed immediately rather than
after loading the program text in which the directive appears
as dictated by the ISO standard. In many cases the exact
moment of execution is irrelevant, but there are exceptions.
For example, load_foreign_library/1 must be executed immediately
to make the loaded foreign predicates available for exporting.
SWI-Prolog now provides the directive use_foreign_library/1 to
ensure immediate loading as well as loading after restoring
a saved state. If the system encounters a directive
:- initialization(load_foreign_library(...)), it will load the
foreign library immediately and issue a warning to update your
code. This behaviour can be extended by providing clauses for
the multifile hook predicate prolog:initialize_now(_T_e_r_m_, _A_d_v_i_c_e),
where _A_d_v_i_c_e is an atom that gives advice on how to resolve the
compatibility issue.
iinniittiiaalliizzaattiioonn((_:_G_o_a_l_, _+_W_h_e_n))
Similar to initialization/1, but allows for specifying when _G_o_a_l is
executed while loading the program text:
nnooww
Execute _G_o_a_l immediately.
aafftteerr__llooaadd
Execute _G_o_a_l after loading program text. This is the same as
initialization/1.
rreessttoorree
Do not execute _G_o_a_l while loading the program, but _o_n_l_y when
restoring a state.
ccoommppiilliinngg
True if the system is compiling source files with the -c option or
qcompile/1 into an intermediate code file. Can be used to perform
conditional code optimisations in term_expansion/2(see also the -O
option) or to omit execution of directives during compilation.
44..33..11 CCoonnddiittiioonnaall ccoommppiillaattiioonn aanndd pprrooggrraamm ttrraannssffoorrmmaattiioonn
ISO Prolog defines no way for program transformations such as
macro expansion or conditional compilation. Expansion through
term_expansion/2 and expand_term/2 can be seen as part of the de-facto
standard. This mechanism can do arbitrary translation between valid
Prolog terms read from the source file to Prolog terms handed to the
compiler. As term_expansion/2 can return a list, the transformation
does not need to be term-to-term.
Various Prolog dialects provide the analogous goal_expansion/2 and
expand_goal/2 that allow for translation of individual body terms,
freeing the user of the task to disassemble each clause.
tteerrmm__eexxppaannssiioonn((_+_T_e_r_m_1_, _-_T_e_r_m_2))
Dynamic and multifile predicate, normally not defined. When
defined by the user all terms read during consulting are given to
this predicate. If the predicate succeeds Prolog will assert _T_e_r_m_2
in the database rather than the read term (_T_e_r_m_1). _T_e_r_m_2 may be a
term of the form ?- Goal. or :- Goal. _G_o_a_l is then treated as a
directive. If _T_e_r_m_2 is a list, all terms of the list are stored
in the database or called (for directives). If _T_e_r_m_2 is of the
form below, the system will assert _C_l_a_u_s_e and record the indicated
source location with it:
'$source_location'(<_F_i_l_e>, <_L_i_n_e>):<_C_l_a_u_s_e>
When compiling a module (see chapter 5 and the directive module/2),
expand_term/2 will first try term_expansion/2 in the module being
compiled to allow for term expansion rules that are local to
a module. If there is no local definition, or the local
definition fails to translate the term, expand_term/2 will try
term_expansion/2 in module user. For compatibility with SICStus
and Quintus Prolog, this feature should not be used. See also
expand_term/2, goal_expansion/2 and expand_goal/2.
eexxppaanndd__tteerrmm((_+_T_e_r_m_1_, _-_T_e_r_m_2))
This predicate is normally called by the compiler on terms read
from the input to perform preprocessing. It consists of four
steps, where each step processes the output of the previous step.
1. Test conditional compilation directives and translate all
input to [] if we are in a `false branch' of the conditional
compilation. See section 4.3.1.2.
2. Call term_expansion/2. This predicate is first tried in the
module that is being compiled and then in the module user.
3. Call DCG expansion (dcg_translate_rule/2).
4. Call expand_goal/2 on each body term that appears in the output
of the previous steps.
ggooaall__eexxppaannssiioonn((_+_G_o_a_l_1_, _-_G_o_a_l_2))
Like term_expansion/2, goal_expansion/2 provides for macro ex-
pansion of Prolog source code. Between expand_term/2 and the
actual compilation, the body of clauses analysed and the goals are
handed to expand_goal/2, which uses the goal_expansion/2 hook to do
user-defined expansion.
The predicate goal_expansion/2 is first called in the module that
is being compiled, and then on the user module. If _G_o_a_l is of the
form _M_o_d_u_l_e:_G_o_a_l where _M_o_d_u_l_e is instantiated, goal_expansion/2 is
called on _G_o_a_l using rules from module _M_o_d_u_l_e followed by user.
Only goals appearing in the body of clauses when reading a
source file are expanded using this mechanism, and only if they
appear literally in the clause, or as an argument to a defined
meta-predicate that is annotated using `0' (see meta_predicate/1).
Other cases need a real predicate definition.
eexxppaanndd__ggooaall((_+_G_o_a_l_1_, _-_G_o_a_l_2))
This predicate is normally called by the compiler to perform
preprocessing using goal_expansion/2. The predicate computes a
fixed-point by applying transformations until there are no more
changes. If optimisation is enabled (see -O and optimise),
expand_goal/2 simplifies the result by removing unneeded calls to
true/0 and fail/0 as well as unreachable branches.
ccoommppiillee__aauuxx__ccllaauusseess((_+_C_l_a_u_s_e_s))
Compile clauses on behalf of goal_expansion/2. This predicate
compiles the argument clauses into static predicates, associating
the predicates with the current file but avoids changing the notion
of current predicate and therefore discontiguous warnings.
ddccgg__ttrraannssllaattee__rruullee((_+_I_n_, _-_O_u_t))
This predicate performs the translation of a term Head-->Body into
a normal Prolog clause. Normally this functionality should be
accessed using expand_term/2.
44..33..11..11 PPrrooggrraamm ttrraannssffoorrmmaattiioonn wwiitthh ssoouurrccee llaayyoouutt iinnffoo
This sections documents extended versions of the program transformation
predicates that also transform the source layout information. Extended
layout information is currently processed, but unused. Future versions
will use for the following enhancements:
o More precise locations of warnings and errors
o More reliable setting of breakpoints
o More reliable source layout information in the graphical debugger.
eexxppaanndd__ggooaall((_+_G_o_a_l_1_, _?_L_a_y_o_u_t_1_, _-_G_o_a_l_2_, _-_L_a_y_o_u_t_2))
ggooaall__eexxppaannssiioonn((_+_G_o_a_l_1_, _?_L_a_y_o_u_t_1_, _-_G_o_a_l_2_, _-_L_a_y_o_u_t_2))
eexxppaanndd__tteerrmm((_+_T_e_r_m_1_, _?_L_a_y_o_u_t_1_, _-_T_e_r_m_2_, _-_L_a_y_o_u_t_2))
tteerrmm__eexxppaannssiioonn((_+_T_e_r_m_1_, _?_L_a_y_o_u_t_1_, _-_T_e_r_m_2_, _-_L_a_y_o_u_t_2))
ddccgg__ttrraannssllaattee__rruullee((_+_I_n_, _?_L_a_y_o_u_t_I_n_, _-_O_u_t_, _-_L_a_y_o_u_t_O_u_t))
These versions are called _b_e_f_o_r_e their 2-argument counterparts.
The input layout term is either a variable (if no layout
information is available) or a term carrying detailed layout
information as returned by the subterm_positions of read_term/2.
44..33..11..22 CCoonnddiittiioonnaall ccoommppiillaattiioonn
Conditional compilation builds on the same principle as
term_expansion/2, goal_expansion/2 and the expansion of grammar
rules to compile sections of the source code conditionally. One of the
reasons for introducing conditional compilation is to simplify writing
portable code. See section 13 for more information. Here is a simple
example:
________________________________________________________________________| |
|:- if(\+source_exports(library(lists), suffix/2)). |
| |
|suffix(Suffix, List) :- |
| append(_, Suffix, List). |
| |
|:-|endif.______________________________________________________________ | |
Note that these directives can only appear as separate terms in the
input. Typical usage scenarios include:
o Load different libraries on different dialects.
o Define a predicate if it is missing as a system predicate.
o Realise totally different implementations for a particular part of
the code due to different capabilities.
o Realise different configuration options for your software.
::-- iiff((_:_G_o_a_l))
Compile subsequent code only if _G_o_a_l succeeds. For enhanced
portability, _G_o_a_l is processed by expand_goal/2 before execution.
If an error occurs, the error is printed and processing proceeds as
if _G_o_a_l has failed.
::-- eelliiff((_:_G_o_a_l))
Equivalent to :- else. :-if(Goal). ... :- endif. In a sequence as
below, the section below the first matching elif is processed. If
no test succeeds, the else branch is processed.
____________________________________________________________________| |
| :- if(test1). |
| section_1. |
| :- elif(test2). |
| section_2. |
| :- elif(test3). |
| section_3. |
| :- else. |
| section_else. |
||:-_endif._________________________________________________________ ||
::-- eellssee
Start `else' branch.
::-- eennddiiff
End of conditional compilation.
44..33..22 LLooaaddiinngg ffiilleess,, aaccttiivvee ccooddee aanndd tthhrreeaaddss
Traditionally, Prolog environments allow for reloading files holding
currently active code. In particular, the following sequence is a
valid use of the development environment:
o Trace a goal
o Find unexpected behaviour of a predicate
o Enter a _b_r_e_a_k using the bb command
o Fix the sources and reload them using make/0
o Exit the break, _r_e_t_r_y using the rr command
Goals running during the reload keep running on the old definition,
while new goals use the reloaded definition, which is why the _r_e_t_r_y
must be used _a_f_t_e_r the reload. This implies that clauses of predicates
that are active during the reload cannot be reclaimed. Normally a
small amount of dead clauses should not be an issue during development.
Such clauses can be reclaimed with garbage_collect_clauses/0.
ggaarrbbaaggee__ccoolllleecctt__ccllaauusseess
Clean up all _d_i_r_t_y predicates, where dirty predicates are defined
to be predicates that have both old and new definitions due to
reloading a source file while the predicate was active. Of
course, predicates that are active using garbage_collect_clauses/0
cannot be reclaimed and remain _d_i_r_t_y. Predicates are, like atoms,
shared resources and therefore all threads are suspended during the
execution of this predicate.
44..33..22..11 CCoommppiillaattiioonn ooff mmuuttuuaallllyy ddeeppeennddeenntt ccooddee
Large programs are generally split into multiple files. If file
A accesses predicates from file B which accesses predicates from
file A, we consider this a mutual or circular dependency. If
traditional load predicates (e.g., consult/1) are used to include file
B from A and A from B, loading either file results in a loop.
This is because consult/1 is mapped to load_files/2 using the option
if(true)(_.) Such programs are typically loaded using a _l_o_a_d _f_i_l_e
that consults all required (non-module) files. If modules are used,
the dependencies are made explicit using use_module/1 statements. The
use_module/1 predicate, however, maps to load_files/2 with the option
if(not_loaded)(_.) A use_module/1 on an already loaded file merely makes
the public predicates of the used module available.
Summarizing, mutual dependency of source files is fully supported
with no precautions when using modules. Modules can use each other
in an arbitrary dependency graph. When using consult/1, predicate
dependencies between loaded files can still be arbitrary, but the
consult relations between files must be a proper tree.
44..33..22..22 CCoommppiillaattiioonn wwiitthh mmuullttiippllee tthhrreeaaddss
This section discusses compiling files for the first time. For
reloading, see section 4.3.2.3.
In older versions, compilation was thread-safe due to a global _l_o_c_k in
load_files/2 and the code dealing with _a_u_t_o_l_o_a_d_i_n_g (see section 2.13).
Besides unnecessary stalling when multiple threads trap unrelated
undefined predicates, this easily leads to deadlocks, notably if
threads are started from an initialization/1 directive.
Starting with version 5.11.27, the autoloader is no longer locked and
multiple threads can compile files concurrently. This requires special
precautions only if multiple threads wish to load the same file at
the same time. Therefore, load_files/2 checks automatically whether
some other thread is already loading the file. If not, it starts
loading the file. If another thread is already loading the file, the
thread blocks until the other thread finishes loading the file. After
waiting, and if the file is a module file, it will make the public
predicates available.
Note that this schema does not prevent deadlocks under all situations.
Consider two mutually dependent (see section 4.3.2.1) module files A
and B, where thread 1 starts loading A and thread 2 starts loading B
at the same time. Both threads will deadlock when trying to load the
used module.
The current implementation does not detect such cases and the involved
threads will freeze. This problem can be avoided if a mutually
dependent collection of files is always loaded from the same start
file.
44..33..22..33 RReellooaaddiinngg rruunnnniinngg ccooddee
This section discusses _n_o_t _r_e_-loading of code. Initial loading of code
is discussed in section 4.3.2.2.
As of version 5.5.30, there is basic thread-safety for reloading source
files while other threads are executing code defined in these source
files. Reloading a file freezes all threads after marking the active
predicates originating from the file being reloaded. The threads are
resumed after the file has been loaded. In addition, after completing
loading the outermost file, the system runs garbage_collect_clauses/0.
What does that mean? Unfortunately it does _n_o_t mean we can `hot-swap'
modules. Consider the case where thread A is executing the recursive
predicate P. We `fix' P and reload. The already running goals for
P continue to run the old definition, but new recursive calls will
use the new definition! Many similar cases can be constructed with
dependent predicates.
It provides some basic security for reloading files in multithreaded
applications during development. In the above scenario the system does
not crash uncontrolled, but behaves like any broken program: it may
return the wrong bindings, wrong truth value or raise an exception.
Future versions may have an `update now' facility. Such a facility
can be implemented on top of the _l_o_g_i_c_a_l _u_p_d_a_t_e _v_i_e_w. It would allow
threads to do a controlled update between processing independent jobs.
44..33..33 QQuuiicckk llooaadd ffiilleess
SWI-Prolog supports compilation of individual or multiple Prolog source
files into `Quick Load Files'. A `Quick Load File' (.qlf file) stores
the contents of the file in a precompiled format.
These files load considerably faster than source files and are normally
more compact. They are machine-independent and may thus be loaded on
any implementation of SWI-Prolog. Note, however, that clauses are
stored as virtual machine instructions. Changes to the compiler will
generally make old compiled files unusable.
Quick Load Files are created using qcompile/1. They are loaded using
consult/1 or one of the other file-loading predicates described in
section 4.3. If consult/1 is given an explicit .pl file, it will load
the Prolog source. When given a .qlf file, it will load the file.
When no extension is specified, it will load the .qlf file when present
and the .pl file otherwise.
qqccoommppiillee((_:_F_i_l_e))
Takes a file specification as consult/1, etc., and, in addition to
the normal compilation, creates a _Q_u_i_c_k _L_o_a_d _F_i_l_e from _F_i_l_e. The
file extension of this file is .qlf. The basename of the Quick
Load File is the same as the input file.
If the file contains `:- consult(_+_F_i_l_e)', `:- [_+_F_i_l_e]' or
`:- load_files(_+_F_i_l_e, [qcompile(part), ...])' statements, the re-
ferred files are compiled into the same .qlf file. Other
directives will be stored in the .qlf file and executed in the same
fashion as when loading the .pl file.
For term_expansion/2, the same rules as described in section 2.10
apply.
Conditional execution or optimisation may test the predicate
compiling/0.
Source references (source_file/2) in the Quick Load File refer to
the Prolog source file from which the compiled code originates.
qqccoommppiillee((_:_F_i_l_e_, _+_O_p_t_i_o_n_s))
As qcompile/1, but processes additional options as defined by
load_files/2.
44..44 EEddiittoorr IInntteerrffaaccee
SWI-Prolog offers an extensible interface which allows the user to
edit objects of the program: predicates, modules, files, etc. The
editor interface is implemented by edit/1 and consists of three parts:
_l_o_c_a_t_i_n_g, _s_e_l_e_c_t_i_n_g and _s_t_a_r_t_i_n_g the editor. Any of these parts may be
customized. See section 4.4.1.
The built-in edit specifications for edit/1 (see prolog_edit:locate/3)
are described in the table below:
___________________________________________________________________
|__________________________________________FFuullllyy__ssppeecciiffiieedd__oobbjjeeccttss____________________________________________||
|| <_M_o_d_u_l_e>:<_N_a_m_e>/<_A_r_i_t_y>R|efers to a predicate |
| module(<_M_o_d_u_l_e>) |Refers to a module |
| file(<_P_a_t_h>) |Refers to a file |
|_source_file(<_P_a_t_h>)___R|efers_to_a_loaded_source_file___________|_
|__________________________________________AAmmbbiigguuoouuss__ssppeecciiffiiccaattiioonnss__________________________________________||
|| <_N_a_m_e>/<_A_r_i_t_y> R|efers to this predicate in any module |
| <_N_a_m_e> |Refers to (1) the named predicate in any|
| |module with any arity, (2) a (source)|
|_______________________|file,_or_(3)_a_module.___________________|_
eeddiitt((_+_S_p_e_c_i_f_i_c_a_t_i_o_n))
First, exploit prolog_edit:locate/3 to translate _S_p_e_c_i_f_i_c_a_t_i_o_n into
a list of _L_o_c_a_t_i_o_n_s. If there is more than one `hit', the
user is asked to select from the locations found. Finally,
prolog_edit:edit_source/1 is used to invoke the user's preferred
editor. Typically, edit/1 can be handed the name of a predicate,
module, basename of a file, XPCE class, XPCE method, etc.
eeddiitt
Edit the `default' file using edit/1. The default file is the file
loaded with the command line option -s or, in Windows, the file
loaded by double-clicking from the Windows shell.
44..44..11 CCuussttoommiizziinngg tthhee eeddiittoorr iinntteerrffaaccee
The predicates described in this section are _h_o_o_k_s that can be defined
to disambiguate specifications given to edit/1, find the related
source, and open an editor at the given source location.
pprroolloogg__eeddiitt::llooccaattee((_+_S_p_e_c_, _-_F_u_l_l_S_p_e_c_, _-_L_o_c_a_t_i_o_n))
Where _S_p_e_c is the specification provided through edit/1. This
multifile predicate is used to enumerate locations where an object
satisfying the given _S_p_e_c can be found. _F_u_l_l_S_p_e_c is unified with
the complete specification for the object. This distinction is
used to allow for ambiguous specifications. For example, if _S_p_e_c
is an atom, which appears as the basename of a loaded file and as
the name of a predicate, _F_u_l_l_S_p_e_c will be bound to file(_P_a_t_h) or
_N_a_m_e/_A_r_i_t_y.
_L_o_c_a_t_i_o_n is a list of attributes of the location. Normally, this
list will contain the term file(_F_i_l_e) and, if available, the term
line(_L_i_n_e).
pprroolloogg__eeddiitt::llooccaattee((_+_S_p_e_c_, _-_L_o_c_a_t_i_o_n))
Same as prolog_edit:locate/3, but only deals with fully specified
objects.
pprroolloogg__eeddiitt::eeddiitt__ssoouurrccee((_+_L_o_c_a_t_i_o_n))
Start editor on _L_o_c_a_t_i_o_n. See prolog_edit:locate/3 for the format
of a location term. This multifile predicate is normally not
defined. If it succeeds, edit/1 assumes the editor is started.
If it fails, edit/1 uses its internal defaults, which are defined
by the Prolog flag editor and/or the environment variable EDITOR.
The following rules apply. If the Prolog flag editor is of
the format $<_n_a_m_e>, the editor is determined by the environment
variable <_n_a_m_e>. Else, if this flag is pce_emacs or built_in _a_n_d
XPCE is loaded or can be loaded, the built-in Emacs clone is
used. Else, if the environment EDITOR is set, this editor is used.
Finally, vi is used as default on Unix systems and notepad on
Windows.
See the default user preferences file dotfiles/dotplrc for
examples.
pprroolloogg__eeddiitt::eeddiitt__ccoommmmaanndd((_+_E_d_i_t_o_r_, _-_C_o_m_m_a_n_d))
Determines how _E_d_i_t_o_r is to be invoked using shell/1. _E_d_i_t_o_r is
the determined editor (see edit_source/1), without the full path
specification, and without a possible (.exe) extension. _C_o_m_m_a_n_d
is an atom describing the command. The following %-sequences are
replaced in _C_o_m_m_a_n_d before the result is handed to shell/1:
________________________________________________
| %e |Replaced by the (OS) command name of the |
| |editor |
| %f |Replaced by the (OS) full path name of |
| |the file |
|_%d_|Replaced_by_the_line_number_______________|
If the editor can deal with starting at a specified line, two
clauses should be provided. The first pattern invokes the editor
with a line number, while the second is used if the line number is
unknown.
The default contains definitions for vi, emacs, emacsclient, vim,
notepad* and wordpad*. Starred editors do not provide starting at
a given line number.
Please contribute your specifications to bugs@swi-prolog.org.
pprroolloogg__eeddiitt::llooaadd
Normally an undefined multifile predicate. This predicate may
be defined to provide loading hooks for user extensions to the
edit module. For example, XPCE provides the code below to load
swi_edit, containing definitions to locate classes and methods as
well as to bind this package to the PceEmacs built-in editor.
____________________________________________________________________| |
| :- multifile prolog_edit:load/0. |
| |
| prolog_edit:load :- |
||________ensure_loaded(library(swi_edit))._________________________ ||
44..55 LLiisstt tthhee pprrooggrraamm,, pprreeddiiccaatteess oorr ccllaauusseess
lliissttiinngg((_:_P_r_e_d))
List predicates specified by _P_r_e_d. _P_r_e_d may be a predicate name
(atom), which lists all predicates with this name, regardless of
their arity. It can also be a predicate indicator (<_n_a_m_e>/<_a_r_i_t_y>
or <_n_a_m_e>//<_a_r_i_t_y>), possibly qualified with a module. For example:
?- listing(lists:member/2)..
A listing is produced by enumerating the clauses of the predicate
using clause/2 and printing each clause using portray_clause/1.
This implies that the variable names are generated (_A, _B, ...) and
the layout is defined by rules in portray_clause/1.
lliissttiinngg
List all predicates from the calling module using listing/1. For
example, ?- listing. lists clauses in the default user module and
?- lists:listing. lists the clauses in the module lists.
ppoorrttrraayy__ccllaauussee((_+_C_l_a_u_s_e))
Pretty print a clause. A clause should be specified as a term
`<_H_e_a_d> :- <_B_o_d_y>'. Facts are represented as `<_H_e_a_d> :- true' or
simply <_H_e_a_d>. Variables in the clause are written as A, B, ....
Singleton variables are written as _. See also portray_clause/2.
ppoorrttrraayy__ccllaauussee((_+_S_t_r_e_a_m_, _+_C_l_a_u_s_e))
Pretty print a clause to _S_t_r_e_a_m. See portray_clause/1 for details.
44..66 VVeerriiffyy TTyyppee ooff aa TTeerrmm
Type tests are semi-deterministic predicates that succeed if the
argument satisfies the requested type. Type-test predicates have no
error condition and do not instantiate their argument. See also
library error.
vvaarr((_@_T_e_r_m)) _[_I_S_O_]
True if _T_e_r_m currently is a free variable.
nnoonnvvaarr((_@_T_e_r_m)) _[_I_S_O_]
True if _T_e_r_m currently is not a free variable.
iinntteeggeerr((_@_T_e_r_m)) _[_I_S_O_]
True if _T_e_r_m is bound to an integer.
ffllooaatt((_@_T_e_r_m)) _[_I_S_O_]
True if _T_e_r_m is bound to a floating point number.
rraattiioonnaall((_@_T_e_r_m))
True if _T_e_r_m is bound to a rational number. Rational numbers
include integers.
rraattiioonnaall((_@_T_e_r_m_, _-_N_u_m_e_r_a_t_o_r_, _-_D_e_n_o_m_i_n_a_t_o_r))
True if _T_e_r_m is a rational number with given _N_u_m_e_r_a_t_o_r and
_D_e_n_o_m_i_n_a_t_o_r. The _N_u_m_e_r_a_t_o_r and _D_e_n_o_m_i_n_a_t_o_r are in canonical form,
which means _D_e_n_o_m_i_n_a_t_o_r is a positive integer and there are no
common divisors between _N_u_m_e_r_a_t_o_r and _D_e_n_o_m_i_n_a_t_o_r.
nnuummbbeerr((_@_T_e_r_m)) _[_I_S_O_]
True if _T_e_r_m is bound to an integer or floating point number.
aattoomm((_@_T_e_r_m)) _[_I_S_O_]
True if _T_e_r_m is bound to an atom.
bblloobb((_@_T_e_r_m_, _?_T_y_p_e))
True if _T_e_r_m is a _b_l_o_b of type _T_y_p_e. See section 9.4.7.
ssttrriinngg((_@_T_e_r_m))
True if _T_e_r_m is bound to a string. Note that string here refers to
the built-in atomic type string as described in section 4.24, Text
in double quotes such as "hello" creates a _l_i_s_t of _c_h_a_r_a_c_t_e_r _c_o_d_e_s.
We illustrate the issues in the example queries below.
____________________________________________________________________| |
| ?- write("hello"). |
| [104, 101, 108, 108, 111] |
| true. |
| |
| ?- string("hello"). |
| false. |
| |
| ?- is_list("hello"). |
||true._____________________________________________________________ ||
aattoommiicc((_@_T_e_r_m)) _[_I_S_O_]
True if _T_e_r_m is bound to an atom, string, integer or floating
point number. Note that string refers to the built-in type. See
string/1. Strings in the classical Prolog sense are lists and
therefore compound.
ccoommppoouunndd((_@_T_e_r_m)) _[_I_S_O_]
True if _T_e_r_m is bound to a compound term. See also functor/3 and
=../2.
ccaallllaabbllee((_@_T_e_r_m)) _[_I_S_O_]
True if _T_e_r_m is bound to an atom or a compound term. This was
intended as a type-test for arguments to call/1 and call/2.. Note
that callable only tests the _s_u_r_f_a_c_e _t_e_r_m. Terms such as (22,true)
are considered callable, but cause call/1 to raise a type error.
Module-qualification of meta-argument (see meta_predicate/1) using
:/2 causes callable to succeed on any meta-argument. Consider the
program and query below:
____________________________________________________________________| |
| :- meta_predicate p(0). |
| |
| p(G) :- callable(G), call(G). |
| |
| ?- p(22). |
| ERROR: Type error: `callable' expected, found `22' |
| ERROR: In: |
||ERROR:____[6]_p(user:22)__________________________________________ ||
ggrroouunndd((_@_T_e_r_m)) _[_I_S_O_]
True if _T_e_r_m holds no free variables.
ccyycclliicc__tteerrmm((_@_T_e_r_m))
True if _T_e_r_m contains cycles, i.e. is an infinite term. See also
acyclic_term/1 and section 2.16.
aaccyycclliicc__tteerrmm((_@_T_e_r_m)) _[_I_S_O_]
True if _T_e_r_m does not contain cycles, i.e. can be processed
recursively in finite time. See also cyclic_term/1 and
section 2.16.
44..77 CCoommppaarriissoonn aanndd UUnniiffiiccaattiioonn ooff TTeerrmmss
Although unification is mostly done implicitly while matching the head
of a predicate, it is also provided by the predicate =/2.
_?_T_e_r_m_1 = _?_T_e_r_m_2 _[_I_S_O_]
Unify _T_e_r_m_1 with _T_e_r_m_2. True if the unification succeeds. For
behaviour on cyclic terms see the Prolog flag occurs_check. It
acts as if defined by the following fact:
____________________________________________________________________| |
||=(Term,_Term).____________________________________________________ ||
_@_T_e_r_m_1 \= _@_T_e_r_m_2 _[_I_S_O_]
Equivalent to \+Term1 = Term2. See also dif/2.
44..77..11 SSttaannddaarrdd OOrrddeerr ooff TTeerrmmss
Comparison and unification of arbitrary terms. Terms are ordered in
the so-called ``standard order''. This order is defined as follows:
1. _V_a_r_i_a_b_l_e_s <_N_u_m_b_e_r_s <_A_t_o_m_s <_S_t_r_i_n_g_s <_C_o_m_p_o_u_n_d _T_e_r_m_s
2. Variables are sorted by address. Attaching attributes (see
section 6.1) does not affect the ordering.
3. _A_t_o_m_s are compared alphabetically.
4. _S_t_r_i_n_g_s are compared alphabetically.
5. _N_u_m_b_e_r_s are compared by value. Mixed integer/float are compared as
floats. If the comparison is equal, the float is considered the
smaller value. If the Prolog flag iso is defined, all floating
point numbers precede all integers.
6. _C_o_m_p_o_u_n_d terms are first checked on their arity, then on their
functor name (alphabetically) and finally recursively on their
arguments, leftmost argument first.
_@_T_e_r_m_1 == _@_T_e_r_m_2 _[_I_S_O_]
True if _T_e_r_m_1 is equivalent to _T_e_r_m_2. A variable is only identical
to a sharing variable.
_@_T_e_r_m_1 \== _@_T_e_r_m_2 _[_I_S_O_]
Equivalent to \+Term1 == Term2.
_@_T_e_r_m_1 @< _@_T_e_r_m_2 _[_I_S_O_]
True if _T_e_r_m_1 is before _T_e_r_m_2 in the standard order of terms.
_@_T_e_r_m_1 @=< _@_T_e_r_m_2 _[_I_S_O_]
True if both terms are equal (==/2) or _T_e_r_m_1 is before _T_e_r_m_2 in the
standard order of terms.
_@_T_e_r_m_1 @> _@_T_e_r_m_2 _[_I_S_O_]
True if _T_e_r_m_1 is after _T_e_r_m_2 in the standard order of terms.
_@_T_e_r_m_1 @>= _@_T_e_r_m_2 _[_I_S_O_]
True if both terms are equal (==/2) or _T_e_r_m_1 is after _T_e_r_m_2 in the
standard order of terms.
ccoommppaarree((_?_O_r_d_e_r_, _@_T_e_r_m_1_, _@_T_e_r_m_2)) _[_I_S_O_]
Determine or test the _O_r_d_e_r between two terms in the standard order
of terms. _O_r_d_e_r is one of <, > or =, with the obvious meaning.
44..77..22 SSppeecciiaall uunniiffiiccaattiioonn aanndd ccoommppaarriissoonn pprreeddiiccaatteess
This section describes special purpose variations on Prolog
unification. The predicate unify_with_occurs_check/2 provides sound
unification and is part of the ISO standard. The predicate
subsumes_term/2 defines `one-sided unification' and is part of the ISO
proposal established in Edinburgh (2010). Finally, unifiable/3 is a
`what-if' version of unification that is often used as a building block
in constraint reasoners.
uunniiffyy__wwiitthh__ooccccuurrss__cchheecckk((_+_T_e_r_m_1_, _+_T_e_r_m_2)) _[_I_S_O_]
As =/2, but using _s_o_u_n_d _u_n_i_f_i_c_a_t_i_o_n. That is, a variable only
unifies to a term if this term does not contain the variable
itself. To illustrate this, consider the two queries below.
____________________________________________________________________| |
| 1 ?- A = f(A). |
| A = f(A). |
| 2 ?- unify_with_occurs_check(A, f(A)). |
||false.____________________________________________________________ ||
The first statement creates a _c_y_c_l_i_c _t_e_r_m, also called a _r_a_t_i_o_n_a_l
_t_r_e_e. The second executes logically sound unification and thus
fails. Note that the behaviour of unification through =/2 as well
as implicit unification in the head can be changed using the Prolog
flag occurs_check.
The SWI-Prolog implementation of unify_with_occurs_check/2 is
cycle-safe and only guards against _c_r_e_a_t_i_n_g cycles, not against
cycles that may already be present in one of the arguments. This
is illustrated in the following two queries:
____________________________________________________________________| |
| ?- X = f(X), Y = X, unify_with_occurs_check(X, Y). |
| X = Y, Y = f(Y). |
| ?- X = f(X), Y = f(Y), unify_with_occurs_check(X, Y). |
||X_=_Y,_Y_=_f(Y).__________________________________________________ ||
Some other Prolog systems interpret unify_with_occurs_check/2 as
if defined by the clause below, causing failure on the above
two queries. Direct use of acyclic_term/1 is portable and more
appropriate for such applications.
____________________________________________________________________| |
||unify_with_occurs_check(X,X)_:-_acyclic_term(X).__________________ ||
_+_T_e_r_m_1 =@= _+_T_e_r_m_2
True if _T_e_r_m_1 is a _v_a_r_i_a_n_t of (or _s_t_r_u_c_t_u_r_a_l_l_y _e_q_u_i_v_a_l_e_n_t to)
_T_e_r_m_2. Testing for a variant is weaker than equivalence (==/2),
but stronger than unification (=/2). Two terms A and B are
variants iff there exists a renaming of the variables in A that
makes A equivalent (==) to B and vice versa. Examples:
1 a =@= A false
2 A =@= B true
3 x(A,A) =@= x(B,C) false
4 x(A,A) =@= x(B,B) true
5 x(A,A) =@= x(A,B) false
6 x(A,B) =@= x(C,D) true
7 x(A,B) =@= x(B,A) true
8 x(A,B) =@= x(C,A) true
A term is always a variant of a copy of itself. Term copying takes
place in, e.g., copy_term/2, findall/3 or proving a clause added
with asserta/1. In the pure Prolog world (i.e., without attributed
variables), =@=/2 behaves as if defined below. With attributed
variables, variant of the attributes is tested rather than trying
to satisfy the constraints.
____________________________________________________________________| |
| A =@= B :- |
| copy_term(A, Ac), |
| copy_term(B, Bc), |
| numbervars(Ac, 0, N), |
| numbervars(Bc, 0, N), |
||________Ac_==_Bc._________________________________________________ ||
The SWI-Prolog implementation is cycle-safe and can deal with
variables that are shared between the left and right argument. Its
performance is comparable to ==/2, both on success and (early)
failure.
This predicate is known by the name variant/2 in some other Prolog
systems. Be aware of possible differences in semantics if the
arguments contain attributed variables or share variables.
_+_T_e_r_m_1 \=@= _+_T_e_r_m_2
Equivalent to `\+Term1 =@= Term2'. See =@=/2 for details.
ssuubbssuummeess__tteerrmm((_@_G_e_n_e_r_i_c_, _@_S_p_e_c_i_f_i_c)) _[_I_S_O_]
True if _G_e_n_e_r_i_c can be made equivalent to _S_p_e_c_i_f_i_c by only binding
variables in _G_e_n_e_r_i_c. The current implementation performs the
unification and ensures that the variable set of _S_p_e_c_i_f_i_c is not
changed by the unification. On success, the bindings are undone.
This predicate respects constraints.
tteerrmm__ssuubbssuummeerr((_+_S_p_e_c_i_a_l_1_, _+_S_p_e_c_i_a_l_2_, _-_G_e_n_e_r_a_l))
_G_e_n_e_r_a_l is the most specific term that is a generalisation of
_S_p_e_c_i_a_l_1 and _S_p_e_c_i_a_l_2. The implementation can handle cyclic terms.
uunniiffiiaabbllee((_@_X_, _@_Y_, _-_U_n_i_f_i_e_r))
If _X and _Y can unify, unify _U_n_i_f_i_e_r with a list of _V_a_r = _V_a_l_u_e,
representing the bindings required to make _X and _Y equivalent.
This predicate can handle cyclic terms. Attributed variables are
handled as normal variables. Associated hooks are _n_o_t executed.
??==((_@_T_e_r_m_1_, _@_T_e_r_m_2))
Succeeds if the syntactic equality of _T_e_r_m_1 and _T_e_r_m_2 can be
decided safely, i.e. if the result of Term1 == Term2 will not
change due to further instantiation of either term. It behaves as
if defined by ?=(X,Y) :- \+ unifiable(X,Y,[_|_]).
44..88 CCoonnttrrooll PPrreeddiiccaatteess
The predicates of this section implement control structures. Normally
the constructs in this section, except for repeat/0, are translated by
the compiler. Please note that complex goals passed as arguments to
meta-predicates such as findall/3 below cause the goal to be compiled
to a temporary location before execution. It is faster to define a
sub-predicate (i.e. one_character_atoms/1 in the example below) and make
a call to this simple predicate.
________________________________________________________________________| |
|one_character_atoms(As) :- |
||_______findall(A,_(current_atom(A),_atom_length(A,_1)),_As).__________ ||
ffaaiill _[_I_S_O_]
Always fail. The predicate fail/0 is translated into a single
virtual machine instruction.
ffaallssee _[_I_S_O_]
Same as fail, but the name has a more declarative connotation.
ttrruuee _[_I_S_O_]
Always succeed. The predicate true/0 is translated into a single
virtual machine instruction.
rreeppeeaatt _[_I_S_O_]
Always succeed, provide an infinite number of choice points.
! _[_I_S_O_]
Cut. Discard all choice points created since entering the
predicate in which the cut appears. In other words, _c_o_m_m_i_t to the
clause in which the cut appears _a_n_d discard choice points that
have been created by goals to the left of the cut in the current
clause. Meta calling is opaque to the cut. This implies that
cuts that appear in a term that is subject to meta-calling (call/1)
only affect choice points created by the meta-called term. The
following control structures are transparent to the cut: ;/2, ->/2
and *->/2 . Cuts appearing in the _c_o_n_d_i_t_i_o_n part of ->/2 and *->/2
are opaque to the cut. The table below explains the scope of the
cut with examples. _P_r_u_n_e_s here means ``prunes X choice point
created by X''.
t0 :- (a, !, b). % prunes a/0 and t0/0
t1 :- (a, !, fail ; b). % prunes a/0 and t1/0
t2 :- (a -> b, ! ; c). % prunes b/0 and t2/0
t3 :- call((a, !, fail ; b)). % prunes a/0
t4 :- \+(a, !, fail). % prunes a/0
_:_G_o_a_l_1 , _:_G_o_a_l_2 _[_I_S_O_]
Conjunction. True if both `Goal1' and `Goal2' can be proved. It
is defined as follows (this definition does not lead to a loop as
the second comma is handled by the compiler):
____________________________________________________________________| |
||Goal1,_Goal2_:-_Goal1,_Goal2._____________________________________ ||
_:_G_o_a_l_1 ; _:_G_o_a_l_2 _[_I_S_O_]
The `or' predicate is defined as:
____________________________________________________________________| |
| Goal1 ; _Goal2 :- Goal1. |
||_Goal1_;_Goal2_:-_Goal2.__________________________________________ ||
_:_G_o_a_l_1 | _:_G_o_a_l_2
Equivalent to ;/2. Retained for compatibility only. New code
should use ;/2.
_:_C_o_n_d_i_t_i_o_n -> _:_A_c_t_i_o_n _[_I_S_O_]
If-then and If-Then-Else. The ->/2 construct commits to the
choices made at its left-hand side, destroying choice points
created inside the clause (by ;/2), or by goals called by this
clause. Unlike !/0, the choice point of the predicate as a whole
(due to multiple clauses) is nnoott destroyed. The combination ;/2
and ->/2 acts as if defined as:
____________________________________________________________________| |
| If -> Then; _Else :- If, !, Then. |
| If -> _Then; Else :- !, Else. |
||If_->_Then_:-_If,_!,_Then.________________________________________ ||
Please note that (If -> Then) acts as (If -> Then ; ffaaiill), making
the construct _f_a_i_l if the condition fails. This unusual semantics
is part of the ISO and all de-facto Prolog standards.
_:_C_o_n_d_i_t_i_o_n *-> _:_A_c_t_i_o_n _; _:_E_l_s_e
This construct implements the so-called `soft-cut'. The control
is defined as follows: If _C_o_n_d_i_t_i_o_n succeeds at least once, the
semantics is the same as (_C_o_n_d_i_t_i_o_n, _A_c_t_i_o_n). If _C_o_n_d_i_t_i_o_n does
not succeed, the semantics is that of (\+ _C_o_n_d_i_t_i_o_n, _E_l_s_e). In
other words, if _C_o_n_d_i_t_i_o_n succeeds at least once, simply behave as
the conjunction of _C_o_n_d_i_t_i_o_n and _A_c_t_i_o_n, otherwise execute _E_l_s_e.
The construct _A *-> _B, i.e. without an _E_l_s_e branch, is translated
as the normal conjunction _A, _B.
\+ _:_G_o_a_l _[_I_S_O_]
True if `Goal' cannot be proven (mnemonic: + refers to _p_r_o_v_a_b_l_e
and the backslash (\) is normally used to indicate negation in
Prolog).
44..99 MMeettaa--CCaallll PPrreeddiiccaatteess
Meta-call predicates are used to call terms constructed at run time.
The basic meta-call mechanism offered by SWI-Prolog is to use variables
as a subclause (which should of course be bound to a valid goal at
runtime). A meta-call is slower than a normal call as it involves
actually searching the database at runtime for the predicate, while for
normal calls this search is done at compile time.
ccaallll((_:_G_o_a_l)) _[_I_S_O_]
Invoke _G_o_a_l as a goal. Note that clauses may have variables as
subclauses, which is identical to call/1.
ccaallll((_:_G_o_a_l_, _+_E_x_t_r_a_A_r_g_1_, _._._.)) _[_I_S_O_]
Append _E_x_t_r_a_A_r_g_1_, _E_x_t_r_a_A_r_g_2_, _._._. to the argument list of _G_o_a_l
and call the result. For example, call(plus(1), 2, X) will call
plus(1, 2, X), binding _X to 3.
The call/[2..] construct is handled by the compiler. The
predicates call/[2-8] are defined as real (meta-)predicates
and are available to inspection through current_predicate/1,
predicate_property/2, etc. Higher arities are handled by the
compiler and runtime system, but the predicates are not accessible
for inspection.
aappppllyy((_:_G_o_a_l_, _+_L_i_s_t))
Append the members of _L_i_s_t to the arguments of _G_o_a_l and call
the resulting term. For example: apply(plus(1), [2, X]) calls
plus(1, 2, X). New code should use call/[2..] if the length of
_L_i_s_t is fixed.
nnoott((_:_G_o_a_l))
True if _G_o_a_l cannot be proven. Retained for compatibility only.
New code should use \+/1.
oonnccee((_:_G_o_a_l)) _[_I_S_O_]
Defined as:
____________________________________________________________________| |
| once(Goal) :- |
||________Goal,_!.__________________________________________________ ||
once/1 can in many cases be replaced with ->/2. The only
difference is how the cut behaves (see !/0). The following two
clauses are identical:
____________________________________________________________________| |
| 1) a :- once((b, c)), d. |
||2)_a_:-_b,_c_->_d.________________________________________________ ||
iiggnnoorree((_:_G_o_a_l))
Calls _G_o_a_l as once/1, but succeeds, regardless of whether _G_o_a_l
succeeded or not. Defined as:
____________________________________________________________________| |
| ignore(Goal) :- |
| Goal, !. |
||ignore(_).________________________________________________________ ||
ccaallll__wwiitthh__ddeepptthh__lliimmiitt((_:_G_o_a_l_, _+_L_i_m_i_t_, _-_R_e_s_u_l_t))
If _G_o_a_l can be proven without recursion deeper than _L_i_m_i_t levels,
call_with_depth_limit/3 succeeds, binding _R_e_s_u_l_t to the deepest
recursion level used during the proof. Otherwise, _R_e_s_u_l_t is
unified with depth_limit_exceeded if the limit was exceeded during
the proof, or the entire predicate fails if _G_o_a_l fails without
exceeding _L_i_m_i_t.
The depth limit is guarded by the internal machinery. This
may differ from the depth computed based on a theoretical model.
For example, true/0 is translated into an inline virtual machine
instruction. Also, repeat/0 is not implemented as below, but as a
non-deterministic foreign predicate.
____________________________________________________________________| |
| repeat. |
| repeat :- |
||________repeat.___________________________________________________ ||
As a result, call_with_depth_limit/3may still loop infinitely on
programs that should theoretically finish in finite time. This
problem can be cured by using Prolog equivalents to such built-in
predicates.
This predicate may be used for theorem provers to realise
techniques like _i_t_e_r_a_t_i_v_e _d_e_e_p_e_n_i_n_g. It was implemented after
discussion with Steve Moyle smoyle@ermine.ox.ac.uk.
sseettuupp__ccaallll__cclleeaannuupp((_:_S_e_t_u_p_, _:_G_o_a_l_, _:_C_l_e_a_n_u_p))
Calls (once(Setup), Goal). If _S_e_t_u_p succeeds, _C_l_e_a_n_u_p will
be called exactly once after _G_o_a_l is finished: either on
failure, deterministic success, commit, or an exception. The
execution of _S_e_t_u_p is protected from asynchronous interrupts like
call_with_time_limit/2 (package clib) or thread_signal/2. In most
uses, _S_e_t_u_p will perform temporary side-effects required by _G_o_a_l
that are finally undone by _C_l_e_a_n_u_p.
Success or failure of _C_l_e_a_n_u_p is ignored, and choice points it
created are destroyed (as once/1). If _C_l_e_a_n_u_p throws an exception,
this is executed as normal.
Typically, this predicate is used to cleanup permanent data storage
required to execute _G_o_a_l, close file descriptors, etc. The example
below provides a non-deterministic search for a term in a file,
closing the stream as needed.
____________________________________________________________________| |
| term_in_file(Term, File) :- |
| setup_call_cleanup(open(File, read, In), |
| term_in_stream(Term, In), |
| close(In) ). |
| |
| term_in_stream(Term, In) :- |
| repeat, |
| read(In, T), |
| ( T == end_of_file |
| -> !, fail |
| ; T = Term |
||________).________________________________________________________ ||
Note that it is impossible to implement this predicate in Prolog.
The closest approximation would be to read all terms into a list,
close the file and call member/2. Without setup_call_cleanup/3
there is no way to gain control if the choice point left by
repeat/0 is removed by a cut or an exception.
setup_call_cleanup/3 can also be used to test determinism of a
goal, providing a portable alternative to deterministic/1:
____________________________________________________________________| |
| ?- setup_call_cleanup(true,(X=1;X=2), Det=yes). |
| |
| X = 1 ; |
| |
| X = 2, |
||Det_=_yes_;_______________________________________________________ ||
This predicate is under consideration for inclusion into the ISO
standard. For compatibility with other Prolog implementations see
call_cleanup/2.
sseettuupp__ccaallll__ccaattcchheerr__cclleeaannuupp((_:_S_e_t_u_p_, _:_G_o_a_l_, _+_C_a_t_c_h_e_r_, _:_C_l_e_a_n_u_p))
Similar to setup_call_cleanup(_S_e_t_u_p_, _G_o_a_l_, _C_l_e_a_n_u_p) with additional
information on the reason for calling _C_l_e_a_n_u_p. Prior to calling
_C_l_e_a_n_u_p, _C_a_t_c_h_e_r unifies with the termination code (see below). If
this unification fails, _C_l_e_a_n_u_p is _n_o_t called.
eexxiitt
_G_o_a_l succeeded without leaving any choice points.
ffaaiill
_G_o_a_l failed.
!
_G_o_a_l succeeded with choice points and these are now discarded
by the execution of a cut (or other pruning of the search tree
such as if-then-else).
eexxcceeppttiioonn((_E_x_c_e_p_t_i_o_n))
_G_o_a_l raised the given _E_x_c_e_p_t_i_o_n.
eexxtteerrnnaall__eexxcceeppttiioonn((_E_x_c_e_p_t_i_o_n))
_G_o_a_l succeeded with choice points and these are now discarded
due to an exception. For example:
_______________________________________________________________| |
|?- setup_call_catcher_cleanup(true, (X=1;X=2), |
| Catcher, writeln(Catcher)), |
| throw(ball). |
|external_exception(ball) |
|ERROR:|Unhandled_exception:_Unknown_message:_ball_____________ | |
ccaallll__cclleeaannuupp((_:_G_o_a_l_, _:_C_l_e_a_n_u_p))
Same as setup_call_cleanup(_t_r_u_e_, _G_o_a_l_, _C_l_e_a_n_u_p). This is provided
for compatibility with a number of other Prolog implementations
only. Do not use call_cleanup/2 if you perform side-effects
prior to calling that will be undone by _C_l_e_a_n_u_p. Instead, use
setup_call_cleanup/3 with an appropriate first argument to perform
those side-effects.
ccaallll__cclleeaannuupp((_:_G_o_a_l_, _+_C_a_t_c_h_e_r_, _:_C_l_e_a_n_u_p))
Same as setup_call_catcher_cleanup(_t_r_u_e_, _G_o_a_l_, _C_a_t_c_h_e_r_, _C_l_e_a_n_u_p).
The same warning as for call_cleanup/2 applies.
44..1100 IISSOO ccoommpplliiaanntt EExxcceeppttiioonn hhaannddlliinngg
SWI-Prolog defines the predicates catch/3 and throw/1 for ISO compliant
raising and catching of exceptions. In the current implementation
(as of 4.0.6), most of the built-in predicates generate exceptions,
but some obscure predicates merely print a message, start the debugger
and fail, which was the normal behaviour before the introduction of
exceptions.
ccaattcchh((_:_G_o_a_l_, _+_C_a_t_c_h_e_r_, _:_R_e_c_o_v_e_r)) _[_I_S_O_]
Behaves as call/1 if no exception is raised when executing _G_o_a_l.
If an exception is raised using throw/1 while _G_o_a_l executes, and
the _G_o_a_l is the innermost goal for which _C_a_t_c_h_e_r unifies with the
argument of throw/1, all choice points generated by _G_o_a_l are cut,
the system backtracks to the start of catch/3 while preserving the
thrown exception term, and _R_e_c_o_v_e_r is called as in call/1.
The overhead of calling a goal through catch/3 is comparable to
call/1. Recovery from an exception is much slower, especially if
the exception term is large due to the copying thereof.
tthhrrooww((_+_E_x_c_e_p_t_i_o_n)) _[_I_S_O_]
Raise an exception. The system looks for the innermost catch/3
ancestor for which _E_x_c_e_p_t_i_o_n unifies with the _C_a_t_c_h_e_r argument of
the catch/3 call. See catch/3 for details.
ISO demands that throw/1 make a copy of _E_x_c_e_p_t_i_o_n, walk up the
stack to a catch/3 call, backtrack and try to unify the copy
of _E_x_c_e_p_t_i_o_n with _C_a_t_c_h_e_r. SWI-Prolog delays making a copy of
_E_x_c_e_p_t_i_o_n and backtracking until it actually finds a matching
catch/3 goal. The advantage is that we can start the debugger at
the first possible location while preserving the entire exception
context if there is no matching catch/3 goal. This approach can
lead to different behaviour if _G_o_a_l and _C_a_t_c_h_e_r of catch/3 call
shared variables. We assume this to be highly unlikely and could
not think of a scenario where this is useful.
If an exception is raised in a call-back from C (see chapter 9) and
not caught in the same call-back, PL_next_solution()fails and the
exception context can be retrieved using PL_exception().
44..1100..11 DDeebbuuggggiinngg aanndd eexxcceeppttiioonnss
Before the introduction of exceptions in SWI-Prolog a runtime error
was handled by printing an error message, after which the predicate
failed. If the Prolog flag debug_on_errorwas in effect (default), the
tracer was switched on. The combination of the error message and trace
information is generally sufficient to locate the error.
With exception handling, things are different. A programmer may wish
to trap an exception using catch/3 to avoid it reaching the user. If
the exception is not handled by user code, the interactive top level
will trap it to prevent termination.
If we do not take special precautions, the context information
associated with an unexpected exception (i.e., a programming error) is
lost. Therefore, if an exception is raised which is not caught using
catch/3 and the top level is running, the error will be printed, and
the system will enter trace mode.
If the system is in a non-interactive call-back from foreign code and
there is no catch/3 active in the current context, it cannot determine
whether or not the exception will be caught by the external routine
calling Prolog. It will then base its behaviour on the Prolog flag
debug_on_error:
o _c_u_r_r_e_n_t___p_r_o_l_o_g___f_l_a_g_(_d_e_b_u_g___o_n___e_r_r_o_r_, _f_a_l_s_e_)
The exception does not trap the debugger and is returned to the
foreign routine calling Prolog, where it can be accessed using
PL_exception(). This is the default.
o _c_u_r_r_e_n_t___p_r_o_l_o_g___f_l_a_g_(_d_e_b_u_g___o_n___e_r_r_o_r_, _t_r_u_e_)
If the exception is not caught by Prolog in the current context, it
will trap the tracer to help analyse the context of the error.
While looking for the context in which an exception takes place, it is
advised to switch on debug mode using the predicate debug/0. The hook
prolog_exception_hook/4 can be used to add more debugging facilities to
exceptions. An example is the library http/http_error, generating a
full stack trace on errors in the HTTP server library.
44..1100..22 TThhee eexxcceeppttiioonn tteerrmm
Built-in predicates generate exceptions using a term error(_F_o_r_m_a_l_,
_C_o_n_t_e_x_t). The first argument is the `formal' description of the
error, specifying the class and generic defined context information.
When applicable, the ISO error term definition is used. The second
part describes some additional context to help the programmer while
debugging. In its most generic form this is a term of the form
context(_N_a_m_e_/_A_r_i_t_y_, _M_e_s_s_a_g_e), where _N_a_m_e/_A_r_i_t_y describes the built-in
predicate that raised the error, and _M_e_s_s_a_g_e provides an additional
description of the error. Any part of this structure may be a variable
if no information was present.
44..1100..33 PPrriinnttiinngg mmeessssaaggeess
The predicate print_message/2 is used to print a message term in a
human-readable format. The other predicates from this section allow
the user to refine and extend the message system. A common usage of
print_message/2 is to print error messages from exceptions. The code
below prints errors encountered during the execution of _G_o_a_l, without
further propagating the exception and without starting the debugger.
________________________________________________________________________| |
| ..., |
| catch(Goal, E, |
| ( print_message(error, E), |
| fail |
| )), |
||_______...____________________________________________________________ ||
Another common use is to define message_hook/3 for printing messages
that are normally _s_i_l_e_n_t, suppressing messages, redirecting messages or
make something happen in addition to printing the message.
pprriinntt__mmeessssaaggee((_+_K_i_n_d_, _+_T_e_r_m))
The predicate print_message/2 is used by the system and libraries
to print messages. _K_i_n_d describes the nature of the message,
while _T_e_r_m is a Prolog term that describes the content. Printing
messages through this indirection instead of using format/3 to
the stream user_error allows displaying the message appropriate to
the application (terminal, logfile, graphics), acting on messages
based on their content instead of a string (see message_hook/3) and
creating language specific versions of the messages. See also
section 4.10.3.1. The following message kinds are known:
bbaannnneerr
The system banner message. Banner messages can be suppressed
by setting the Prolog flag verbose to silent.
ddeebbuugg((_T_o_p_i_c))
Message from library(debug). See debug/3.
eerrrroorr
The message indicates an erroneous situation. This kind
is used to print uncaught exceptions of type error(_F_o_r_m_a_l_,
_C_o_n_t_e_x_t). See section introduction (section 4.10.3).
hheellpp
User requested help message, for example after entering `h' or
`?' to a prompt.
iinnffoorrmmaattiioonn
Information that is requested by the user. An example is
statistics/0.
iinnffoorrmmaattiioonnaall
Typically messages of events are progres that are considered
useful to a developer. Such messages can be suppressed by
setting the Prolog flag verbose to silent.
ssiilleenntt
Message that is normally not printed. Applications may define
message_hook/3 to act upon such messages.
ttrraaccee
Messages from the (command line) tracer.
wwaarrnniinngg
The message indicates something dubious that is not considered
fatal. For example, discontiguous predicates (see
discontiguous/1).
The predicate print_message/2first translates the _T_e_r_m into a list
of `message lines' (see print_message_lines/3 for details). Next,
it calls the hook message_hook/3to allow the user to intercept the
message. If message_hook/3fails it prints the message unless _K_i_n_d
is silent.
The print_message/2 predicate and its rules are in the file
<_p_l_h_o_m_e>/boot/messages.pl, which may be inspected for more
information on the error messages and related error terms. If you
need to write messages from your own predicates, it is recommended
to reuse the existing message terms if applicable. If no existing
message term is applicable, invent a fairly unique term that
represents the event and define a rule for the multifile predicate
prolog:message//1. See section 4.10.3.1 for a deeper discussion
and examples.
See also message_to_string/2.
pprriinntt__mmeessssaaggee__lliinneess((_+_S_t_r_e_a_m_, _+_P_r_e_f_i_x_, _+_L_i_n_e_s))
Print a message (see print_message/2) that has been translated to a
list of message elements. The elements of this list are:
<_F_o_r_m_a_t>--<_A_r_g_s>
Where _F_o_r_m_a_t is an atom and _A_r_g_s is a list of format
arguments. Handed to format/3.
fflluusshh
If this appears as the last element, _S_t_r_e_a_m is flushed (see
flush_output/1) and no final newline is generated. This
is combined with a subsequent message that starts with
at_same_line to complete the line.
aatt__ssaammee__lliinnee
If this appears as first element, no prefix is printed for
the first line and the line position is not forced to 0 (see
format/1, ~N).
aannssii((_+_A_t_t_r_i_b_u_t_e_s_, _+_F_o_r_m_a_t_, _+_A_r_g_s))
This message may be intercepted by means of the hook pro-
log:message_line_element/2. The library ansi_term implements
this hook to achieve coloured output. If it is not
intercepted it invokes format(_S_t_r_e_a_m_, _F_o_r_m_a_t_, _A_r_g_s).
nnll
A new line is started. If the message is not complete, _P_r_e_f_i_x
is printed before the remainder of the message.
bbeeggiinn((_K_i_n_d_, _V_a_r))
eenndd((_V_a_r))
The entire message is headed by begin(_K_i_n_d_, _V_a_r) and ended by
end(_V_a_r). This feature is used by, e.g., library ansi_term to
colour entire messages.
<_F_o_r_m_a_t>
Handed to format/3 as format(_S_t_r_e_a_m_, _F_o_r_m_a_t_, _[_]). Deprecated
because it is ambiguous if _F_o_r_m_a_t collides with one of the
atomic commands.
See also print_message/2 and message_hook/3.
mmeessssaaggee__hhooookk((_+_T_e_r_m_, _+_K_i_n_d_, _+_L_i_n_e_s))
Hook predicate that may be defined in the module user to intercept
messages from print_message/2. _T_e_r_m and _K_i_n_d are the same as
passed to print_message/2. _L_i_n_e_s is a list of format statements as
described with print_message_lines/3. See also message_to_string/2.
This predicate must be defined dynamic and multifile to allow other
modules defining clauses for it too.
tthhrreeaadd__mmeessssaaggee__hhooookk((_+_T_e_r_m_, _+_K_i_n_d_, _+_L_i_n_e_s))
As message_hook/3, but this predicate is local to the calling
thread (see thread_local/1). This hook is called _b_e_f_o_r_e
message_hook/3. The `pre-hook' is indented to catch messages
they may be produced by calling some goal without affecting other
threads.
mmeessssaaggee__pprrooppeerrttyy((_+_K_i_n_d_, _?_P_r_o_p_e_r_t_y))
This hook can be used to define additional message kinds and the
way they are displayed. The following properties are defined:
ccoolloorr((_-_A_t_t_r_i_b_u_t_e_s))
Print message using ANSI terminal attributes. See
ansi_format/3 for details. Here is an example, printing help
messages in blue:
_______________________________________________________________| |
|:- multifile user:message_property/2. |
| |
|user:message_property(help,|color([fg(blue)]))._______________ | |
pprreeffiixx((_-_P_r_e_f_i_x))
Prefix printed before each line. This argument is handed to
format/3. The default is '~N'. For example, messages of kind
warning use '~NWarning: '.
llooccaattiioonn__pprreeffiixx((_+_L_o_c_a_t_i_o_n_, _-_F_i_r_s_t_P_r_e_f_i_x_, _-_C_o_n_t_i_n_u_e_P_r_e_f_i_x))
Used for printing messages that are related to a source loca-
tion. Currently, _L_o_c_a_t_i_o_n is a term _F_i_l_e:_L_i_n_e. _F_i_r_s_t_P_r_e_f_i_x
is the prefix for the first line and _-_C_o_n_t_i_n_u_e_P_r_e_f_i_x is the
prefix for continuation lines. For example, the default for
errors is
_______________________________________________________________| |
||___location_prefix(File:Line,_'~NERROR:_~w:~d:'-[File,Line],_'~N\t')).||
ssttrreeaamm((_-_S_t_r_e_a_m))
Stream to which to print the message. Default is user_error.
wwaaiitt((_-_S_e_c_o_n_d_s))
Amount of time to wait after printing the message. Default is
not to wait.
pprroolloogg::mmeessssaaggee__lliinnee__eelleemmeenntt((_+_S_t_r_e_a_m_, _+_T_e_r_m))
This hook is called to print the individual elements of a message
from print_message_lines/3. This hook is used by e.g., library
ansi_term to colour messages on ANSI-capable terminals.
mmeessssaaggee__ttoo__ssttrriinngg((_+_T_e_r_m_, _-_S_t_r_i_n_g))
Translates a message term into a string object (see section 4.24).
vveerrssiioonn
Write the SWI-Prolog banner message as well as additional messages
registered using version/1. This is the default _i_n_i_t_i_a_l_i_z_a_t_i_o_n
_g_o_a_l which can be modified using -g.
vveerrssiioonn((_+_M_e_s_s_a_g_e))
Register additional messages to be printed by version/0. Each
registered message is handed to the message translation DCG and can
thus be defined using the hook prolog:message//1. Of not defined,
it is simply printed.
44..1100..33..11 PPrriinnttiinngg ffrroomm lliibbrraarriieess
Libraries should _n_o_t use format/3 or other output predicates directly.
Libraries that print informational output directly to the console are
hard to use from code that depend on your textual output, such as a CGI
script. The predicates in section 4.10.3 define the API for dealing
with messages. The idea behind this is that a library that wants
to provide information about its status, progress, events or problems
calls print_message/2. The first argument is the _l_e_v_e_l. The supported
levels are described with print_message/2. Libraries typically use
informational and warning, while libraries should use exceptions for
errors (see throw/1, type_error/2, etc.).
The second argument is an arbitrary Prolog term that carries the
information of the message, but _n_o_t the precise text. The text
is defined by the grammar rule prolog:message//1. This distinction
is made to allow for translations and to allow hooks processing the
information in a different way (e.g., to translate progress messages
into a progress bar).
For example, suppose we have a library that must download data from
the Internet (e.g., based on http_open/3). The library wants to print
the progress after each downloaded file. The code below is a good
skeleton:
________________________________________________________________________| |
|download_urls(List) :- |
| length(List, Total), |
| forall(nth1(I, List, URL), |
| ( download_url(URL), |
| print_message(informational, |
||________________________________download_url(URL,_I,_Total))))._______ ||
The programmer can now specify the default textual output using the
rule below. Note that this rule may be in the same file or anywhere
else. Notably, the application may come with several rule sets for
different languages. This, and the user-hook example below are the
reason to represent the message as a compound term rather than a
string. This is similar to using message numbers in non-symbolic
languages. The documentation of print_message_lines/3 describes the
elements that may appear in the output list.
________________________________________________________________________| |
|:- multifile |
| prolog:message//1. |
| |
|prolog:message(download_url(URL, I, Total)) --> |
| { Perc is round(I*100/Total) }, |
||_______[_'Downloaded_~w;_~D_from_~D_(~d%)'-[URL,_I,_Total,_Perc]_].___ ||
A _u_s_e_r of the library may define rules for message_hook/3. The rule
below acts on the message content. Other applications can act on the
message level and, for example, popup a message box for warnings and
errors.
________________________________________________________________________| |
|:- multifile user:message_hook/3. |
| |
|message_hook(download_url(URL, I, Total), _Kind, _Lines) :- |
||_______<send_this_information_to_a_GUI_component>_____________________ ||
In addition, using the command line option -q, the user can disable all
_i_n_f_o_r_m_a_t_i_o_n_a_l messages.
44..1111 HHaannddlliinngg ssiiggnnaallss
As of version 3.1.0, SWI-Prolog is able to handle software
interrupts (signals) in Prolog as well as in foreign (C) code (see
section 9.4.13).
Signals are used to handle internal errors (execution of a non-existing
CPU instruction, arithmetic domain errors, illegal memory access,
resource overflow, etc.), as well as for dealing with asynchronous
interprocess communication.
Signals are defined by the POSIX standard and part of all Unix
machines. The MS-Windows Win32 provides a subset of the signal
handling routines, lacking the vital functionality to raise a signal in
another thread for achieving asynchronous interprocess (or interthread)
communication (Unix kill() function).
oonn__ssiiggnnaall((_+_S_i_g_n_a_l_, _-_O_l_d_, _:_N_e_w))
Determines the reaction on _S_i_g_n_a_l. _O_l_d is unified with the old
behaviour, while the behaviour is switched to _N_e_w. As with similar
environment control predicates, the current value is retrieved
using on_signal(Signal, Current, Current).
The action description is an atom denoting the name of the
predicate that will be called if _S_i_g_n_a_l arrives. on_signal/3 is a
meta-predicate, which implies that <_M_o_d_u_l_e>:<_N_a_m_e> refers to <_N_a_m_e>/1
in module <_M_o_d_u_l_e>. The handler is called with a single argument:
the name of the signal as an atom. The Prolog names for signals
are explained below.
Two predicate names have special meaning. throw implies Prolog
will map the signal onto a Prolog exception as described in
section 4.10. default resets the handler to the settings active
before SWI-Prolog manipulated the handler.
Signals bound to a foreign function through PL_signal() are
reported using the term $foreign_function(_A_d_d_r_e_s_s).
After receiving a signal mapped to throw, the exception raised has
the following structure:
error(signal(<_S_i_g_N_a_m_e>, <_S_i_g_N_u_m>), <_C_o_n_t_e_x_t>)
The signal names are defined by the POSIX standard as symbols
of the form SIG<_S_I_G_N_A_M_E>. The Prolog name for a signal is the
lowercase version of <_S_I_G_N_A_M_E>. The predicate current_signal/3 may
be used to map between names and signals.
Initially, some signals are mapped to throw, while all other
signals are default. The following signals throw an exception:
fpe, alrm, xcpu, xfsz and vtalrm.
ccuurrrreenntt__ssiiggnnaall((_?_N_a_m_e_, _?_I_d_, _?_H_a_n_d_l_e_r))
Enumerate the currently defined signal handling. _N_a_m_e is the
signal name, _I_d is the numerical identifier and _H_a_n_d_l_e_r is the
currently defined handler (see on_signal/3).
44..1111..11 NNootteess oonn ssiiggnnaall hhaannddlliinngg
Before deciding to deal with signals in your application, please
consider the following:
o _P_o_r_t_a_b_i_l_i_t_y
On MS-Windows, the signal interface is severely limited. Different
Unix brands support different sets of signals, and the relation
between signal name and number may vary. Currently, the system
only supports signals numbered 1 to 32. Installing a signal
outside the limited set of supported signals in MS-Windows crashes
the application.
o _S_a_f_e_t_y
Immediately delivered signals (see below) are unsafe. This implies
that foreign functions called from a handler cannot safely use
the SWI-Prolog API and cannot use C longjmp(). Handlers defined
as throw are unsafe. Handlers defined to call a predicate are
safe. Note that the predicate can call throw/1, but the delivery
is delayed until Prolog is in a safe state.
The C-interface described in section 9.4.13 provides the option
PL_SIGSYNC to select either safe synchronous or unsafe asynchronous
delivery.
o _T_i_m_e _o_f _d_e_l_i_v_e_r_y
Using throw or a foreign handler, signals are delivered immediately
(as defined by the OS). When using a Prolog predicate, delivery is
delayed to a safe moment. Blocking system calls or foreign loops
may cause long delays. Foreign code can improve on that by calling
PL_handle_signals().
Signals are blocked when the garbage collector is active.
44..1122 DDCCGG GGrraammmmaarr rruulleess
Grammar rules form a comfortable interface to _d_i_f_f_e_r_e_n_c_e _l_i_s_t_s. They
are designed both to support writing parsers that build a parse tree
from a list of characters or tokens and for generating a flat list from
a term.
Grammar rules look like ordinary clauses using -->/2 for separating
the head and body rather than :-/2. Expanding grammar rules is done
by expand_term/2, which adds two additional arguments to each term for
representing the difference list.
The body of a grammar rule can contain three types of terms. A
callable term is interpreted as a reference to a grammar rule. Code
between {...} is interpreted as plain Prolog code, and finally,
a list is interpreted as a sequence of _l_i_t_e_r_a_l_s. The Prolog
control-constructs (\+/1, ->/2 , ;//2, ,/2 and !/0) can be used in
grammar rules.
We illustrate the behaviour by defining a rule set for parsing an
integer.
________________________________________________________________________| |
|integer(I) --> |
| digit(D0), |
| digits(D), |
| { number_codes(I, [D0|D]) |
| }. |
| |
|digits([D|T]) --> |
| digit(D), !, |
| digits(T). |
|digits([]) --> |
| []. |
| |
|digit(D) --> |
| [D], |
| { code_type(D, digit) |
||_______}._____________________________________________________________ ||
Grammar rule sets are called using the built-in predicates phrase/2 and
phrase/3:
pphhrraassee((_:_D_C_G_B_o_d_y_, _?_L_i_s_t))
Equivalent to phrase(_D_C_G_B_o_d_y, _I_n_p_u_t_L_i_s_t, []).
pphhrraassee((_:_D_C_G_B_o_d_y_, _?_L_i_s_t_, _?_R_e_s_t))
True when _D_C_G_B_o_d_y applies to the difference _L_i_s_t/_R_e_s_t. Although
_D_C_G_B_o_d_y is typically a _c_a_l_l_a_b_l_e term that denotes a grammar rule,
it can be any term that is valid as the body of a DCG rule.
The example below calls the rule set `integer' defined in
section 4.12, binding _R_e_s_t to the remainder of the input after
matching the integer.
____________________________________________________________________| |
| ?- phrase(integer(X), "42 times", Rest). |
| X = 42 |
||Rest_=_[32,_116,_105,_109,_101,_115]______________________________ ||
The next example exploits a complete body.
____________________________________________________________________| |
| digit_weight(W) --> |
| [D], |
| { code_type(D, digit(W)) }. |
| |
| ?- phrase(("Version ", |
| digit_weight(Major),".",digit_weight(Minor)), |
| "Version 3.4"). |
| Major = 3, |
||Minor_=_4.________________________________________________________ ||
See also portray_text/1, which can be used to print lists of
character codes as a string to the top level and debugger
to facilitate debugging DCGs that process character codes.
The library apply_macros compiles phrase/3 if the argument is
sufficiently instantiated, eliminating the runtime overhead of
translating _D_C_G_B_o_d_y and meta-calling.
As stated above, grammar rules are a general interface to difference
lists. To illustrate, we show a DCG-based implementation of reverse/2:
________________________________________________________________________| |
|reverse(List, Reversed) :- |
| phrase(reverse(List), Reversed). |
| |
|reverse([]) --> []. |
|reverse([H|T])|-->_reverse(T),_[H].____________________________________ | |
44..1133 DDaattaabbaassee
SWI-Prolog offers three different database mechanisms. The first one
is the common assert/retract mechanism for manipulating the clause
database. As facts and clauses asserted using assert/1 or one of
its derivatives become part of the program, these predicates compile
the term given to them. retract/1 and retractall/1 have to unify a
term and therefore have to decompile the program. For these reasons
the assert/retract mechanism is expensive. On the other hand, once
compiled, queries to the database are faster than querying the recorded
database discussed below. See also dynamic/1.
The second way of storing arbitrary terms in the database is using the
`recorded database'. In this database terms are associated with a _k_e_y.
A key can be an atom, small integer or term. In the last case only the
functor and arity determine the key. Each key has a chain of terms
associated with it. New terms can be added either at the head or at
the tail of this chain.
Following the Edinburgh tradition, SWI-Prolog provides database keys to
clauses and records in the recorded database. As of 5.9.10, these
keys are represented by non-textual atoms (`blobs', see section 9.4.7),
which makes accessing the database through references safe.
The third mechanism is a special-purpose one. It associates an integer
or atom with a key, which is an atom, integer or term. Each key can
only have one atom or integer associated with it.
aabboolliisshh((_:_P_r_e_d_i_c_a_t_e_I_n_d_i_c_a_t_o_r)) _[_I_S_O_]
Removes all clauses of a predicate with functor _F_u_n_c_t_o_r and arity
_A_r_i_t_y from the database. All predicate attributes (dynamic,
multifile, index, etc.) are reset to their defaults. Abolishing
an imported predicate only removes the import link; the predicate
will keep its old definition in its definition module.
According to the ISO standard, abolish/1 can only be applied to
dynamic procedures. This is odd, as for dealing with dynamic
procedures there is already retract/1 and retractall/1. The
abolish/1 predicate was introduced in DEC-10 Prolog precisely for
dealing with static procedures. In SWI-Prolog, abolish/1 works on
static procedures, unless the Prolog flag iso is set to true.
It is advised to use retractall/1 for erasing all clauses of a
dynamic predicate.
aabboolliisshh((_+_N_a_m_e_, _+_A_r_i_t_y))
Same as abolish(_N_a_m_e_/_A_r_i_t_y). The predicate abolish/2 conforms to
the Edinburgh standard, while abolish/1 is ISO compliant.
ccooppyy__pprreeddiiccaattee__ccllaauusseess((_:_F_r_o_m_, _:_T_o))
Copy all clauses of predicate _F_r_o_m to _T_o. The predicate _T_o must
be dynamic or undefined. If _T_o is undefined, it is created as
a dynamic predicate holding a copy of the clauses of _F_r_o_m. If
_T_o is a dynamic predicate, the clauses of _F_r_o_m are added (as in
assertz/1) to the clauses of _T_o. _T_o and _F_r_o_m must have the same
arity. Acts as if defined by the program below, but at a much
better performance by avoiding decompilation and compilation.
____________________________________________________________________| |
| copy_predicate_clauses(From, To) :- |
| head(From, MF:FromHead), |
| head(To, MT:ToHead), |
| FromHead =.. [_|Args], |
| ToHead =.. [_|Args], |
| forall(clause(MF:FromHead, Body), |
| assertz(MT:ToHead, Body)). |
| |
| head(From, M:Head) :- |
| strip_module(From, M, Name/Arity), |
||________functor(Head,_Name,_Arity)._______________________________ ||
rreeddeeffiinnee__ssyysstteemm__pprreeddiiccaattee((_+_H_e_a_d))
This directive may be used both in module user and in normal
modules to redefine any system predicate. If the system definition
is redefined in module user, the new definition is the default
definition for all sub-modules. Otherwise the redefinition is
local to the module. The system definition remains in the module
system.
Redefining system predicate facilitates the definition of
compatibility packages. Use in other contexts is discouraged.
rreettrraacctt((_+_T_e_r_m)) _[_I_S_O_]
When _T_e_r_m is an atom or a term it is unified with the first
unifying fact or clause in the database. The fact or clause is
removed from the database.
rreettrraaccttaallll((_+_H_e_a_d)) _[_I_S_O_]
All facts or clauses in the database for which the _h_e_a_d unifies
with _H_e_a_d are removed. If _H_e_a_d refers to a predicate that is not
defined, it is implicitly created as a dynamic predicate. See also
dynamic/1.
aasssseerrttaa((_+_T_e_r_m)) _[_I_S_O_]
Assert a fact or clause in the database. _T_e_r_m is asserted as the
first fact or clause of the corresponding predicate. Equivalent
to assert/1, but _T_e_r_m is asserted as first clause or fact of the
predicate.
aasssseerrttzz((_+_T_e_r_m)) _[_I_S_O_]
Equivalent to asserta/1, but _T_e_r_m is asserted as the last clause or
fact of the predicate.
aasssseerrtt((_+_T_e_r_m))
Equivalent to assertz/1. Deprecated: new code should use
assertz/1.
aasssseerrttaa((_+_T_e_r_m_, _-_R_e_f_e_r_e_n_c_e))
Asserts a clause as asserta/1 and unifies _R_e_f_e_r_e_n_c_e with a handle
to this clause. The handle can be used to access this specific
clause using clause/3 and erase/1.
aasssseerrttzz((_+_T_e_r_m_, _-_R_e_f_e_r_e_n_c_e))
Equivalent to asserta/1, asserting the new clause as the last
clause of the predicate.
aasssseerrtt((_+_T_e_r_m_, _-_R_e_f_e_r_e_n_c_e))
Equivalent to assertz/2. Deprecated: new code should use
assertz/2.
rreeccoorrddaa((_+_K_e_y_, _+_T_e_r_m_, _-_R_e_f_e_r_e_n_c_e))
Assert _T_e_r_m in the recorded database under key _K_e_y. _K_e_y is a
small integer (range min_tagged_integer ...max_tagged_integer, atom
or compound term. If the key is a compound term, only the name and
arity define the key. _R_e_f_e_r_e_n_c_e is unified with an opaque handle
to the record (see erase/1).
rreeccoorrddaa((_+_K_e_y_, _+_T_e_r_m))
Equivalent to recorda(_K_e_y, _T_e_r_m, _).
rreeccoorrddzz((_+_K_e_y_, _+_T_e_r_m_, _-_R_e_f_e_r_e_n_c_e))
Equivalent to recorda/3, but puts the _T_e_r_m at the tail of the terms
recorded under _K_e_y.
rreeccoorrddzz((_+_K_e_y_, _+_T_e_r_m))
Equivalent to recordz(_K_e_y, _T_e_r_m, _).
rreeccoorrddeedd((_?_K_e_y_, _?_V_a_l_u_e_, _?_R_e_f_e_r_e_n_c_e))
True if _V_a_l_u_e is recorded under _K_e_y and has the given database
_R_e_f_e_r_e_n_c_e. If _R_e_f_e_r_e_n_c_e is given, this predicate is semi-
deterministic. Otherwise, it must be considered non-deterministic.
If neither _R_e_f_e_r_e_n_c_e nor _K_e_y is given, the triples are generated as
in the code snippet below. See also current_key/1.
____________________________________________________________________| |
| current_key(Key), |
||________recorded(Key,_Value,_Reference)___________________________ ||
rreeccoorrddeedd((_+_K_e_y_, _-_V_a_l_u_e))
Equivalent to recorded(_K_e_y, _V_a_l_u_e, _).
eerraassee((_+_R_e_f_e_r_e_n_c_e))
Erase a record or clause from the database. _R_e_f_e_r_e_n_c_e is
a db-reference returned by recorda/3, recordz/3 or recorded/3,
clause/3, assert/2, asserta/2 or assertz/2. Fail silently if the
referenced object no longer exists.
iinnssttaannccee((_+_R_e_f_e_r_e_n_c_e_, _-_T_e_r_m))
Unify _T_e_r_m with the referenced clause or database record. Unit
clauses are represented as _H_e_a_d :- true.
ffllaagg((_+_K_e_y_, _-_O_l_d_, _+_N_e_w))
_K_e_y is an atom, integer or term. As with the recorded database, if
_K_e_y is a term, only the name and arity are used to locate the flag.
Unify _O_l_d with the old value associated with _K_e_y. If the key is
used for the first time _O_l_d is unified with the integer 0. Then
store the value of _N_e_w, which should be an integer, float, atom
or arithmetic expression, under _K_e_y. flag/3 is a fast mechanism
for storing simple facts in the database. The flag database is
shared between threads and updates are atomic, making it suitable
for generating unique integer counters.
44..1133..11 UUppddaattee vviieeww
Traditionally, Prolog systems used the _i_m_m_e_d_i_a_t_e _u_p_d_a_t_e _v_i_e_w: new
clauses became visible to predicates backtracking over dynamic
predicates immediately, and retracted clauses became invisible
immediately.
Starting with SWI-Prolog 3.3.0 we adhere to the _l_o_g_i_c_a_l _u_p_d_a_t_e _v_i_e_w,
where backtrackable predicates that enter the definition of a predicate
will not see any changes (either caused by assert/1 or retract/1) to
the predicate. This view is the ISO standard, the most commonly
used and the most `safe'. Logical updates are realised by keeping
reference counts on predicates and _g_e_n_e_r_a_t_i_o_n information on clauses.
Each change to the database causes an increment of the generation of
the database. Each goal is tagged with the generation in which it was
started. Each clause is flagged with the generation it was created
in as well as the generation it was erased from. Only clauses with
a `created' ...`erased' interval that encloses the generation of the
current goal are considered visible.
44..1133..22 IInnddeexxiinngg ddaattaabbaasseess
The indexing capabilities of SWI-Prolog are described in section 2.17.
Summarizing, SWI-Prolog creates indexes for any applicable argument,
but only on one argument, and does not index on arguments of compound
terms. The predicates below provide building blocks to circumvent the
limitations of the current indexing system.
Programs that aim at portability should consider using term_hash/2 and
term_hash/4 to design their database such that indexing on constant or
functor (name/arity reference) on the first argument is sufficient.
tteerrmm__hhaasshh((_+_T_e_r_m_, _-_H_a_s_h_K_e_y)) _[_d_e_t_]
If _T_e_r_m is a ground term (see ground/1), _H_a_s_h_K_e_y is unified with
a positive integer value that may be used as a hash key to the
value. If _T_e_r_m is not ground, the predicate leaves _H_a_s_h_K_e_y an
unbound variable. Hash keys are in the range 0:::16;777; 215, the
maximal integer that can be stored efficiently on both 32 and 64
bit platforms.
This predicate may be used to build hash tables as well as to
exploit argument indexing to find complex terms more quickly.
The hash key does not rely on temporary information like addresses
of atoms and may be assumed constant over different invocations
and versions of SWI-Prolog. Hashes differ between big and little
endian machines. The term_hash/2 predicate is cycle-safe.
tteerrmm__hhaasshh((_+_T_e_r_m_, _+_D_e_p_t_h_, _+_R_a_n_g_e_, _-_H_a_s_h_K_e_y)) _[_d_e_t_]
As term_hash/2, but only considers _T_e_r_m to the specified _D_e_p_t_h.
The top-level term has depth 1, its arguments have depth 2, etc.
That is, _D_e_p_t_h =0 hashes nothing; _D_e_p_t_h= 1 hashes atomic values
or the functor and arity of a compound term, not its arguments;
_D_e_p_t_h =2 also indexes the immediate arguments, etc.
_H_a_s_h_K_e_y is in the range [0:::_R_a_n_g_e-1]. _R_a_n_g_e must be in the range
[1:::2147483647]
vvaarriiaanntt__sshhaa11((_+_T_e_r_m_, _-_S_H_A_1)) _[_d_e_t_]
Compute a SHA1-hash from _T_e_r_m. The hash is represented as a
40-byte hexadecimal atom. Unlike term_hash/2 and friends, this
predicate produces a hash key for non-ground terms. The hash is
invariant over variable-renaming (see =@=/2) and constants over
different invocations of Prolog.
This predicate raises an exception when trying to compute the hash
on a cyclic term or attributed term. Attributed terms are not
handled because subsumes_chk/2 is not considered well defined for
attributed terms. Cyclic terms are not supported because this
would require establishing a canonical cycle. That is, given
A=[a_A] and B=[a,a_B], _A and _B should produce the same hash. This
is not (yet) implemented.
This hash was developed for lookup of solutions to a goal stored
in a table. By using a cryptographic hash, heuristic algorithms
can often ignore the possibility of hash collisions and thus avoid
storing the goal term itself as well as testing using =@=/2.
44..1144 DDeeccllaarriinngg pprreeddiiccaattee pprrooppeerrttiieess
This section describes directives which manipulate attributes of
predicate definitions. The functors dynamic/1, multifile/1,
discontiguous/1 and public/1 are operators of priority 1150 (see op/3),
which implies that the list of predicates they involve can just be a
comma-separated list:
________________________________________________________________________| |
|:- dynamic |
| foo/0, |
||_______baz/2._________________________________________________________ ||
In SWI-Prolog all these directives are just predicates. This implies
they can also be called by a program. Do not rely on this feature if
you want to maintain portability to other Prolog implementations.
ddyynnaammiicc _:_P_r_e_d_i_c_a_t_e_I_n_d_i_c_a_t_o_r_, _._._. _[_I_S_O_]
Informs the interpreter that the definition of the predicate(s)
may change during execution (using assert/1 and/or retract/1). In
the multithreaded version, the clauses of dynamic predicates are
shared between the threads. The directive thread_local/1 provides
an alternative where each thread has its own clause list for the
predicate. Dynamic predicates can be turned into static ones using
compile_predicates/1.
ccoommppiillee__pprreeddiiccaatteess((_:_L_i_s_t_O_f_P_r_e_d_i_c_a_t_e_I_n_d_i_c_a_t_o_r_s))
Compile a list of specified dynamic predicates (see dynamic/1 and
assert/1) into normal static predicates. This call tells the
Prolog environment the definition will not change anymore and
further calls to assert/1 or retract/1 on the named predicates
raise a permission error. This predicate is designed to deal with
parts of the program that are generated at runtime but do not
change during the remainder of the program execution.
mmuullttiiffiillee _:_P_r_e_d_i_c_a_t_e_I_n_d_i_c_a_t_o_r_, _._._. _[_I_S_O_]
Informs the system that the specified predicate(s) may be defined
over more than one file. This stops consult/1 from redefining a
predicate when a new definition is found.
ddiissccoonnttiigguuoouuss _:_P_r_e_d_i_c_a_t_e_I_n_d_i_c_a_t_o_r_, _._._. _[_I_S_O_]
Informs the system that the clauses of the specified predicate(s)
might not be together in the source file. See also style_check/1.
ppuubblliicc _:_P_r_e_d_i_c_a_t_e_I_n_d_i_c_a_t_o_r_, _._._.
Instructs the cross-referencer that the predicate can be called.
It has no semantics. The public declaration can be queried using
predicate_property/2. The public/1 directive does _n_o_t export the
predicate (see module/1 and export/1). The public directive is
used for (1) direct calls into the module from, e.g., foreign code,
(2) direct calls into the module from other modules, or (3) flag a
predicate as being called if the call is generated by meta-calling
constructs that are not analysed by the cross-referencer.
44..1155 EExxaammiinniinngg tthhee pprrooggrraamm
ccuurrrreenntt__aattoomm((_-_A_t_o_m))
Successively unifies _A_t_o_m with all atoms known to the system. Note
that current_atom/1 always succeeds if _A_t_o_m is instantiated to an
atom.
ccuurrrreenntt__bblloobb((_?_B_l_o_b_, _?_T_y_p_e))
Examine the type or enumerate blobs of the given _T_y_p_e. Typed blobs
are supported through the foreign language interface for storing
arbitrary BLOBs (Binary Large Object) or handles to external
entities. See section 9.4.7 for details.
ccuurrrreenntt__ffuunnccttoorr((_?_N_a_m_e_, _?_A_r_i_t_y))
Successively unifies _N_a_m_e with the name and _A_r_i_t_y with the arity of
functors known to the system.
ccuurrrreenntt__ffllaagg((_-_F_l_a_g_K_e_y))
Successively unifies _F_l_a_g_K_e_y with all keys used for flags (see
flag/3).
ccuurrrreenntt__kkeeyy((_-_K_e_y))
Successively unifies _K_e_y with all keys used for records (see
recorda/3, etc.).
ccuurrrreenntt__pprreeddiiccaattee((_:_P_r_e_d_i_c_a_t_e_I_n_d_i_c_a_t_o_r)) _[_I_S_O_]
True if _P_r_e_d_i_c_a_t_e_I_n_d_i_c_a_t_o_r is a currently defined predicate. A
predicate is considered defined if it exists in the specified
module, is imported into the module or is defined in one of
the modules from which the predicate will be imported if it is
called (see section 5.9). Note that current_predicate/1 does
_n_o_t succeed for predicates that can be _a_u_t_o_l_o_a_d_e_d. See also
current_predicate/2 and predicate_property/2.
If _P_r_e_d_i_c_a_t_e_I_n_d_i_c_a_t_o_r is not fully specified, the predicate only
generates values that are defined in or already imported into
the target module. Generating all callable predicates therefore
requires enumerating modules using current_module/1. Generating
predicates callable in a given module requires enumerating
the import modules using import_module/2 and the autoloadable
predicates using the predicate_property/2 autoload.
ccuurrrreenntt__pprreeddiiccaattee((_?_N_a_m_e_, _:_H_e_a_d))
Classical pre-ISO implementation of current_predicate/1, where the
predicate is represented by the head term. The advantage is that
this can be used for checking the existence of a predicate before
calling it without the need for functor/3:
____________________________________________________________________| |
| call_if_exists(G) :- |
| current_predicate(_, G), |
||________call(G).__________________________________________________ ||
Because of this intended usage, current_predicate/2 also succeeds
if the predicate can be autoloaded. Unfortunately, checking the
autoloader makes this predicate relatively slow, in particular
because a failed lookup of the autoloader will cause the autoloader
to verify that its index is up-to-date.
pprreeddiiccaattee__pprrooppeerrttyy((_:_H_e_a_d_, _?_P_r_o_p_e_r_t_y))
True when _H_e_a_d refers to a predicate that has property _P_r_o_p_e_r_t_y.
With sufficiently instantiated _H_e_a_d, predicate_property/2 tries
to resolve the predicate the same way as calling it would
do: if the predicate is not defined it scans the default
modules (see default_module/2) and finally tries the autoloader.
Unlike calling, failure to find the target predicate causes
predicate_property/2 to fail silently. If _H_e_a_d is not sufficiently
bound, only currently locally defined and already imported
predicates are enumerated. See current_predicate/1 for enumerating
all predicates. A common issue concerns _g_e_n_e_r_a_t_i_n_g all built-in
predicates. This can be achieved using the code below:
____________________________________________________________________| |
| generate_built_in(Name/Arity) :- |
| predicate_property(system:Head, built_in), |
| functor(Head, Name, Arity), |
||____\+_sub_atom(Name,_0,__,__,_$).___%_discard_reserved_names_____ ||
_P_r_o_p_e_r_t_y is one of:
aauuttoollooaadd((_F_i_l_e))
True if the predicate can be autoloaded from the file _F_i_l_e.
Like undefined, this property is _n_o_t generated.
bbuuiilltt__iinn
True if the predicate is locked as a built-in predicate. This
implies it cannot be redefined in its definition module and it
can normally not be seen in the tracer.
ddyynnaammiicc
True if assert/1 and retract/1 may be used to modify the
predicate. This property is set using dynamic/1.
eexxppoorrtteedd
True if the predicate is in the public list of the context
module.
iimmppoorrtteedd__ffrroomm((_M_o_d_u_l_e))
Is true if the predicate is imported into the context module
from module _M_o_d_u_l_e.
ffiillee((_F_i_l_e_N_a_m_e))
Unify _F_i_l_e_N_a_m_e with the name of the source file in which
the predicate is defined. See also source_file/2 and the
property line_count. Note that this reports the file of the
first clause of a predicate. A more robust interface can be
achieved using nth_clause/3 and clause_property/2.
ffoorreeiiggnn
True if the predicate is defined in the C language.
iinnddeexxeedd((_I_n_d_e_x_e_s))
_I_n_d_e_x_e_s is a list of additional (hash) indexes on the
predicate. Each element of the list is a term _A_r_g_S_p_e_c-_I_n_d_e_x.
Currently _A_r_g_S_p_e_c is an integer denoting the argument position
and _I_n_d_e_x is a term hash(_B_u_c_k_e_t_s_, _S_p_e_e_d_u_p_, _I_s_L_i_s_t). Here
_B_u_c_k_e_t_s is the number of buckets in the hash and _S_p_e_e_d_u_p is
the expected speedup relative to trying all clauses linearly.
_I_s_L_i_s_t indicates that a list is created for all clauses with
the same key. This is currently not used.
iinntteerrpprreetteedd
True if the predicate is defined in Prolog. We return true
on this because, although the code is actually compiled, it is
completely transparent, just like interpreted code.
iissoo
True if the predicate is covered by the ISO standard (ISO/IEC
13211-1).
lliinnee__ccoouunntt((_L_i_n_e_N_u_m_b_e_r))
Unify _L_i_n_e_N_u_m_b_e_r with the line number of the first clause of
the predicate. Fails if the predicate is not associated with
a file. See also source_file/2. See also the file property
above, notably the reference to clause_property/2.
mmuullttiiffiillee
True if there may be multiple (or no) files providing clauses
for the predicate. This property is set using multifile/1.
mmeettaa__pprreeddiiccaattee((_H_e_a_d))
If the predicate is declared as a meta-predicate using
meta_predicate/1, unify _H_e_a_d with the head-pattern. The
head-pattern is a compound term with the same name and
arity as the predicate where each argument of the term is a
meta-predicate specifier. See meta_predicate/1 for details.
nnooddeebbuugg
Details of the predicate are not shown by the debugger. This
is the default for built-in predicates. User predicates can
be compiled this way using the Prolog flag generate_debug_info.
nnoottrraaccee
Do not show ports of this predicate in the debugger.
nnuummbbeerr__ooff__ccllaauusseess((_C_l_a_u_s_e_C_o_u_n_t))
Unify _C_l_a_u_s_e_C_o_u_n_t to the number of clauses associated with the
predicate. Fails for foreign predicates.
nnuummbbeerr__ooff__rruulleess((_R_u_l_e_C_o_u_n_t))
Unify _R_u_l_e_C_o_u_n_t to the number of clauses associated with
the predicate. A _r_u_l_e is defined as a clauses that has
a body that is not just true (i.e., a _f_a_c_t). Fails for
foreign predicates. This property is used to avoid analysing
predicates with only facts in prolog_codewalk.
ppuubblliicc
Predicate is declared public using public/1. Note that
without further definition, public predicates are considered
undefined and this property is _n_o_t reported.
qquuaassii__qquuoottaattiioonn__ssyynnttaaxx((_T))
he predicate (with arity 4) is declared to provide quasi
quotation syntax with quasi_quotation_syntax/1.
tthhrreeaadd__llooccaall
If true (only possible on the multithreaded version) each
thread has its own clauses for the predicate. This property
is set using thread_local/1.
ttrraannssppaarreenntt
True if the predicate is declared transparent using the
module_transparent/1 or meta_predicate/1 declaration. In the
latter case the property meta_predicate(_H_e_a_d) is also provided.
See chapter 5 for details.
uunnddeeffiinneedd
True if a procedure definition block for the predicate exists,
but there are no clauses for it and it is not declared dynamic
or multifile. This is true if the predicate occurs in the
body of a loaded predicate, an attempt to call it has been
made via one of the meta-call predicates, or the predicate had
a definition in the past. See the library package check for
example usage.
vviissiibbllee
True when predicate can be called without raising a predicate
existence error. This means that the predicate is (1)
defined, (2) can be inherited from one of the default modules
(see default_module/2) or (3) can be autoloaded. The behaviour
is logically consistent iff the property visible is provided
explicitly. If the property is left unbound, only defined
predicates are enumerated.
vvoollaattiillee
If true, the clauses are not saved into a saved state by
qsave_program/[1,2]. This property is set using volatile/1.
ddwwiimm__pprreeddiiccaattee((_+_T_e_r_m_, _-_D_w_i_m))
`Do What I Mean' (`dwim') support predicate. _T_e_r_m is a term,
whose name and arity are used as a predicate specification. _D_w_i_m
is instantiated with the most general term built from _N_a_m_e and the
arity of a defined predicate that matches the predicate specified
by _T_e_r_m in the `Do What I Mean' sense. See dwim_match/2 for `Do
What I Mean' string matching. Internal system predicates are not
generated, unless the access level is system (see access_level).
Backtracking provides all alternative matches.
ccllaauussee((_:_H_e_a_d_, _?_B_o_d_y)) _[_I_S_O_]
True if _H_e_a_d can be unified with a clause head and _B_o_d_y with
the corresponding clause body. Gives alternative clauses on
backtracking. For facts, _B_o_d_y is unified with the atom _t_r_u_e.
ccllaauussee((_:_H_e_a_d_, _?_B_o_d_y_, _?_R_e_f_e_r_e_n_c_e))
Equivalent to clause/2, but unifies _R_e_f_e_r_e_n_c_e with a unique
reference to the clause (see also assert/2, erase/1). If _R_e_f_e_r_e_n_c_e
is instantiated to a reference the clause's head and body will be
unified with _H_e_a_d and _B_o_d_y.
nntthh__ccllaauussee((_?_P_r_e_d_, _?_I_n_d_e_x_, _?_R_e_f_e_r_e_n_c_e))
Provides access to the clauses of a predicate using their index
number. Counting starts at 1. If _R_e_f_e_r_e_n_c_e is specified it
unifies _P_r_e_d with the most general term with the same name/arity
as the predicate and _I_n_d_e_x with the index number of the clause.
Otherwise the name and arity of _P_r_e_d are used to determine the
predicate. If _I_n_d_e_x is provided, _R_e_f_e_r_e_n_c_e will be unified with
the clause reference. If _I_n_d_e_x is unbound, backtracking will
yield both the indexes and the references of all clauses of the
predicate. The following example finds the 2nd clause of append/3:
____________________________________________________________________| |
| ?- use_module(library(lists)). |
| ... |
| ?- nth_clause(append(_,_,_), 2, Ref), clause(Head, Body, Ref). |
| Ref = <clause>(0x994290), |
| Head = lists:append([_G23|_G24], _G21, [_G23|_G27]), |
||Body_=_append(_G24,__G21,__G27).__________________________________ ||
ccllaauussee__pprrooppeerrttyy((_+_C_l_a_u_s_e_R_e_f_, _-_P_r_o_p_e_r_t_y))
Queries properties of a clause. _C_l_a_u_s_e_R_e_f is a reference
to a clause as produced by clause/3, nth_clause/3 or
prolog_frame_attribute/3. Unlike most other predicates that access
clause references, clause_property/2may be used to get information
about erased clauses that have not yet been reclaimed. _P_r_o_p_e_r_t_y is
one of the following:
ffiillee((_F_i_l_e_N_a_m_e))
Unify _F_i_l_e_N_a_m_e with the name of the file in which the clause
textually appears. Fails if the clause is created by loading
a file (e.g., clauses added using assertz/1). See also
source.
lliinnee__ccoouunntt((_L_i_n_e_N_u_m_b_e_r))
Unify _L_i_n_e_N_u_m_b_e_r with the line number of the clause. Fails if
the clause is not associated to a file.
ssoouurrccee((_F_i_l_e_N_a_m_e))
Unify _F_i_l_e_N_a_m_e with the name of the source file that created
the clause. This is the same as the file property, unless
the file is loaded from a file that is textually included
into source using include/1. In this scenario, file is the
included file, while the source property refers to the _m_a_i_n
file.
ffaacctt
True if the clause has no body.
eerraasseedd
True if the clause has been erased, but not yet reclaimed
because it is referenced.
pprreeddiiccaattee((_P_r_e_d_i_c_a_t_e_I_n_d_i_c_a_t_o_r))
_P_r_e_d_i_c_a_t_e_I_n_d_i_c_a_t_o_r denotes the predicate to which this clause
belongs. This is needed to obtain information on erased
clauses because the usual way to obtain this information using
clause/3 fails for erased clauses.
44..1166 IInnppuutt aanndd oouuttppuutt
SWI-Prolog provides two different packages for input and output. The
native I/O system is based on the ISO standard predicates open/3,
close/1 and friends. Being more widely portable and equipped with a
clearer and more robust specification, new code is encouraged to use
these predicates for manipulation of I/O streams.
Section 4.16.3 describes tell/1, see/1 and friends, providing I/O in
the spirit of the traditional Edinburgh standard. These predicates
are layered on top of the ISO predicates. Both packages are fully
integrated; the user may switch freely between them.
44..1166..11 PPrreeddeeffiinneedd ssttrreeaamm aalliiaasseess
Each thread has five stream aliases: user_input, user_output,
user_error, current_input, and current_output. Newly created threads
inherit these stream aliases from theyr parent. The user_input,
user_output and user_error aliases of the main thread are initially
bound to the standard operating system I/O streams (_s_t_d_i_n, _s_t_d_o_u_t and
_s_t_d_e_r_r, normally bound to the POSIX file handles 0, 1 and 2). These
aliases may be re-bound, for example if standard I/O refers to a window
such as in the swipl-win.exe GUI executable for Windows. They can be
re-bound by the user using set_prolog_IO/3 and set_stream/2 by setting
the alias of a stream (e.g, set_stream(S, alias(user_output))). An
example of rebinding can be found in library prolog_server, providing
a telnet service. The aliases current_input and current_output define
the source and destination for predicates that do not take a stream
argument (e.g., read/1, write/1, get_code/1, ...). Initially, these
are bound to the same stream as user_input and user_error. They
are re-bound by see/1, tell/1, set_input/1 and set_output/1. The
current_output stream is also temporary re-bound by with_output_to/2
or format/3 using e.g., format(atom(A), .... Note that code which
explicitly writes to the streams user_output and user_error will not be
redirected by with_output_to/2.
CCoommppaattiibbiilliittyy Note that the ISO standard only defines the user_*
streams. The `current' streams can be accessed using current_input/1
and current_output/1. For example, an ISO compatible implementation of
write/1 is
________________________________________________________________________| |
|write(Term)|:-_current_output(Out),_write_term(Out,_Term)._____________ | |
while SWI-Prolog additionally allows for
________________________________________________________________________| |
|write(Term)|:-_write(current_output,_Term).____________________________ | |
44..1166..22 IISSOO IInnppuutt aanndd OOuuttppuutt SSttrreeaammss
The predicates described in this section provide ISO compliant I/O,
where streams are explicitly created using the predicate open/3. The
resulting stream identifier is then passed as a parameter to the
reading and writing predicates to specify the source or destination of
the data.
This schema is not vulnerable to filename and stream ambiguities as
well as changes to the working directory. On the other hand, using the
notion of current-I/O simplifies reusability of code without the need
to pass arguments around. E.g., see with_output_to/2.
SWI-Prolog streams are, compatible with the ISO standard, either input
or output streams. To accommodate portability to other systems, a pair
of streams can be packed into a _s_t_r_e_a_m_-_p_a_i_r. See stream_pair/3 for
details.
SWI-Prolog stream handles are unique symbols that have no syntactical
representation. They are written as \bnfmeta{stream}(hex-number),
which is not valid input for read/1. They are realised using a _b_l_o_b of
type stream (see blob/2 and section 9.4.7).
ooppeenn((_+_S_r_c_D_e_s_t_, _+_M_o_d_e_, _-_S_t_r_e_a_m_, _+_O_p_t_i_o_n_s)) _[_I_S_O_]
True when _S_r_c_D_e_s_t can be opened in _M_o_d_e and _S_t_r_e_a_m is an I/O
stream to/from the object. _S_r_c_D_e_s_t is normally the name of a
file, represented as an atom or string. _M_o_d_e is one of read,
write, append or update. Mode append opens the file for writing,
positioning the file pointer at the end. Mode update opens the
file for writing, positioning the file pointer at the beginning of
the file without truncating the file. _S_t_r_e_a_m is either a variable,
in which case it is bound to an integer identifying the stream, or
an atom, in which case this atom will be the stream identifier.
SWI-Prolog also allows _S_r_c_D_e_s_t to be a term pipe(_C_o_m_m_a_n_d). In
this form, _C_o_m_m_a_n_d is started as a child process and if _M_o_d_e is
write, output written to _S_t_r_e_a_m is sent to the standard input of
_C_o_m_m_a_n_d. Viso versa, if _M_o_d_e is read, data written by _C_o_m_m_a_n_d to
the standard output may be read from _S_t_r_e_a_m. On Unix systems,
_C_o_m_m_a_n_d is handed to popen() which hands it to the Unix shell. On
Windows, _C_o_m_m_a_n_d is executed directly. See also process_create/3
from process.
The following _O_p_t_i_o_n_s are recognised by open/4:
ttyyppee((_T_y_p_e))
Using type text (default), Prolog will write a text file in an
operating system compatible way. Using type binary the bytes
will be read or written without any translation. See also the
option encoding.
aalliiaass((_A_t_o_m))
Gives the stream a name. Below is an example. Be careful
with this option as stream names are global. See also
set_stream/2.
_______________________________________________________________| |
|?- open(data, read, Fd, [alias(input)]). |
| |
| ..., |
| read(input, Term), |
||_______...___________________________________________________ ||
eennccooddiinngg((_E_n_c_o_d_i_n_g))
Define the encoding used for reading and writing text to this
stream. The default encoding for type text is derived from
the Prolog flag encoding. For binary streams the default
encoding is octet. For details on encoding issues, see
section 2.18.1.
bboomm((_B_o_o_l))
Check for a BOM (_B_y_t_e _O_r_d_e_r _M_a_r_k_e_r) or write one. If omitted,
the default is true for mode read and false for mode write.
See also stream_property/2 and especially section 2.18.1.1 for
a discussion of this feature.
eeooff__aaccttiioonn((_A_c_t_i_o_n))
Defines what happens if the end of the input stream is
reached. Action eof_code makes get0/1 and friends return -1,
and read/1 and friends return the atom end_of_file. Repetitive
reading keeps yielding the same result. Action error is like
eof_code, but repetitive reading will raise an error. With
action reset, Prolog will examine the file again and return
more data if the file has grown.
bbuuffffeerr((_B_u_f_f_e_r_i_n_g))
Defines output buffering. The atom full (default) defines
full buffering, line buffering by line, and false implies the
stream is fully unbuffered. Smaller buffering is useful if
another process or the user is waiting for the output as it is
being produced. See also flush_output/[0,1]. This option is
not an ISO option.
cclloossee__oonn__aabboorrtt((_B_o_o_l))
If true (default), the stream is closed on an abort (see
abort/0). If false, the stream is not closed. If it is
an output stream, however, it will be flushed. Useful for
logfiles and if the stream is associated to a process (using
the pipe/1 construct).
llooccaallee((_+_L_o_c_a_l_e))
Set the locale that is used by notably format/2 for output on
this stream. See section 4.22.
lloocckk((_L_o_c_k_i_n_g_M_o_d_e))
Try to obtain a lock on the open file. Default is none, which
does not lock the file. The value read or shared means other
processes may read the file, but not write it. The value
write or exclusive means no other process may read or write
the file.
Locks are acquired through the POSIX function fcntl() using
the command F_SETLKW, which makes a blocked call wait for the
lock to be released. Please note that fcntl() locks are
_a_d_v_i_s_o_r_y and therefore only other applications using the same
advisory locks honour your lock. As there are many issues
around locking in Unix, especially related to NFS (network
file system), please study the fcntl() manual page before
trusting your locks!
The lock option is a SWI-Prolog extension.
wwaaiitt((_B_o_o_l))
This option can be combined with the lock option. If false
(default true), the open call returns immediately with an
exception if the file is locked. The exception has the format
permission_error(_l_o_c_k_, _s_o_u_r_c_e___s_i_n_k_, _S_r_c_D_e_s_t).
The option reposition is not supported in SWI-Prolog. All streams
connected to a file may be repositioned.
ooppeenn((_+_S_r_c_D_e_s_t_, _+_M_o_d_e_, _?_S_t_r_e_a_m)) _[_I_S_O_]
Equivalent to open/4 with an empty option list.
ooppeenn__nnuullll__ssttrreeaamm((_?_S_t_r_e_a_m))
Open an output stream that produces no output. All counting
functions are enabled on such a stream. It can be used to discard
output (like Unix /dev/null) or exploit the counting properties.
The initial encoding of _S_t_r_e_a_m is utf8, enabling arbitrary Unicode
output. The encoding can be changed to determine byte counts
of the output in a particular encoding or validate if output is
possible in a particular encoding. For example, the code below
determines the number of characters emitted when writing _T_e_r_m.
____________________________________________________________________| |
| write_length(Term, Len) :- |
| open_null_stream(Out), |
| write(Out, Term), |
| character_count(Out, Len0), |
| close(Out), |
||________Len_=_Len0._______________________________________________ ||
cclloossee((_+_S_t_r_e_a_m)) _[_I_S_O_]
Close the specified stream. If _S_t_r_e_a_m is not open, an existence
error is raised. However, closing a stream multiple times
may crash Prolog. This is particularly true for multithreaded
applications.
If the closed stream is the current input or output stream, the
terminal is made the current input or output.
cclloossee((_+_S_t_r_e_a_m_, _+_O_p_t_i_o_n_s)) _[_I_S_O_]
Provides close(_S_t_r_e_a_m_, _[_f_o_r_c_e_(_t_r_u_e_)_]) as the only option. Called
this way, any resource errors (such as write errors while flushing
the output buffer) are ignored.
ssttrreeaamm__pprrooppeerrttyy((_?_S_t_r_e_a_m_, _?_S_t_r_e_a_m_P_r_o_p_e_r_t_y)) _[_I_S_O_]
ISO compatible predicate for querying the status of open I/O
streams. _S_t_r_e_a_m_P_r_o_p_e_r_t_y is one of:
aalliiaass((_A_t_o_m))
If _A_t_o_m is bound, test if the stream has the specified alias.
Otherwise unify _A_t_o_m with the first alias of the stream.
bbuuffffeerr((_B_u_f_f_e_r_i_n_g))
SWI-Prolog extension to query the buffering mode of this
stream. _B_u_f_f_e_r_i_n_g is one of full, line or false. See also
open/4.
bbuuffffeerr__ssiizzee((_I_n_t_e_g_e_r))
SWI-Prolog extension to query the size of the I/O buffer
associated to a stream in bytes. Fails if the stream is not
buffered.
bboomm((_B_o_o_l))
If present and true, a BOM (_B_y_t_e _O_r_d_e_r _M_a_r_k) was detected
while opening the file for reading, or a BOM was written while
opening the stream. See section 2.18.1.1 for details.
cclloossee__oonn__aabboorrtt((_B_o_o_l))
Determine whether or not abort/0 closes the stream. By
default streams are closed.
cclloossee__oonn__eexxeecc((_B_o_o_l))
Determine whether or not the stream is closed when executing
a new process (exec() in Unix, CreateProcess() in Windows).
Default is to close streams. This maps to fcntl()
F_SETFD using the flag FD_CLOEXEC on Unix and (negated)
HANDLE_FLAG_INHERIT on Windows.
eennccooddiinngg((_E_n_c_o_d_i_n_g))
Query the encoding used for text. See section 2.18.1 for an
overview of wide character and encoding issues in SWI-Prolog.
eenndd__ooff__ssttrreeaamm((_E))
If _S_t_r_e_a_m is an input stream, unify _E with one of the atoms
not, at or past. See also at_end_of_stream/[0,1].
eeooff__aaccttiioonn((_A))
Unify _A with one of eof_code, reset or error. See open/4 for
details.
ffiillee__nnaammee((_A_t_o_m))
If _S_t_r_e_a_m is associated to a file, unify _A_t_o_m to the name of
this file.
ffiillee__nnoo((_I_n_t_e_g_e_r))
If the stream is associated with a POSIX file descriptor,
unify _I_n_t_e_g_e_r with the descriptor number. SWI-Prolog
extension used primarily for integration with foreign code.
See also Sfileno() from SWI-Stream.h.
iinnppuutt
True if _S_t_r_e_a_m has mode read.
llooccaallee((_L_o_c_a_l_e))
True when _L_o_c_a_l_e is the current locale associated with the
stream. See section 4.22.
mmooddee((_I_O_M_o_d_e))
Unify _I_O_M_o_d_e to the mode given to open/4 for opening the
stream. Values are: read, write, append and the SWI-Prolog
extension update.
nneewwlliinnee((_N_e_w_l_i_n_e_M_o_d_e))
One of posix or dos. If dos, text streams will emit \r\n for
\n and discard \r from input streams. Default depends on the
operating system.
nnlliinnkk((_-_C_o_u_n_t))
Number of hard links to the file. This expresses the number
of `names' the file has. Not supported on all operating
systems and the value might be bogus. See the documentation
of fstat() for your OS and the value st_nlink.
oouuttppuutt
True if _S_t_r_e_a_m has mode write, append or update.
ppoossiittiioonn((_P_o_s))
Unify _P_o_s with the current stream position. A stream
position is an opaque term whose fields can be extracted using
stream_position_data/3. See also set_stream_position/2.
rreeppoossiittiioonn((_B_o_o_l))
Unify _B_o_o_l with _t_r_u_e if the position of the stream can be set
(see seek/4). It is assumed the position can be set if the
stream has a _s_e_e_k_-_f_u_n_c_t_i_o_n and is not based on a POSIX file
descriptor that is not associated to a regular file.
rreepprreesseennttaattiioonn__eerrrroorrss((_M_o_d_e))
Determines behaviour of character output if the stream cannot
represent a character. For example, an ISO Latin-1 stream
cannot represent Cyrillic characters. The behaviour is one
of error (throw an I/O error exception), prolog (write \...\
escape code) or xml (write &#...; XML character entity). The
initial mode is prolog for the user streams and error for all
other streams. See also section 2.18.1 and set_stream/2.
ttiimmeeoouutt((_-_T_i_m_e))
_T_i_m_e is the timeout currently associated with the stream. See
set_stream/2 with the same option. If no timeout is specified,
_T_i_m_e is unified to the atom infinite.
ttyyppee((_T_y_p_e))
Unify _T_y_p_e with text or binary.
ttttyy((_B_o_o_l))
This property is reported with _B_o_o_l equal to true if the
stream is associated with a terminal. See also set_stream/2.
ccuurrrreenntt__ssttrreeaamm((_?_O_b_j_e_c_t_, _?_M_o_d_e_, _?_S_t_r_e_a_m))
The predicate current_stream/3 is used to access the status of a
stream as well as to generate all open streams. _O_b_j_e_c_t is the
name of the file opened if the stream refers to an open file, an
integer file descriptor if the stream encapsulates an operating
system stream, or the atom [] if the stream refers to some other
object. _M_o_d_e is one of read or write.
iiss__ssttrreeaamm((_+_T_e_r_m))
True if _T_e_r_m is a stream name or valid stream handle. This
predicate realises a safe test for the existence of a stream alias
or handle.
ssttrreeaamm__ppaaiirr((_?_S_t_r_e_a_m_P_a_i_r_, _?_R_e_a_d_, _?_W_r_i_t_e))
This predicate can be used in mode (-,+,+) to create a _s_t_r_e_a_m_-_p_a_i_r
from an input stream and an output stream. Stream-pairs can be
used by all I/O operations on streams, where the operation selects
the appropriate member of the pair. The predicate close/1 closes
both streams of the pair. Mode (+,-,-) can be used to get access
to the underlying streams.
sseett__ssttrreeaamm__ppoossiittiioonn((_+_S_t_r_e_a_m_, _+_P_o_s)) _[_I_S_O_]
Set the current position of _S_t_r_e_a_m to _P_o_s. _P_o_s is a term as
returned by stream_property/2 using the position(_P_o_s) property.
See also seek/4.
ssttrreeaamm__ppoossiittiioonn__ddaattaa((_?_F_i_e_l_d_, _+_P_o_s_, _-_D_a_t_a))
Extracts information from the opaque stream position term as re-
turned by stream_property/2 requesting the position(_P_o_s) property.
_F_i_e_l_d is one of line_count, line_position, char_count or byte_count.
See also line_count/2, line_position/2, character_count/2 and
byte_count/2.
sseeeekk((_+_S_t_r_e_a_m_, _+_O_f_f_s_e_t_, _+_M_e_t_h_o_d_, _-_N_e_w_L_o_c_a_t_i_o_n))
Reposition the current point of the given _S_t_r_e_a_m. _M_e_t_h_o_d is one of
bof, current or eof, indicating positioning relative to the start,
current point or end of the underlying object. _N_e_w_L_o_c_a_t_i_o_n is
unified with the new offset, relative to the start of the stream.
Positions are counted in `units'. A unit is 1 byte, except
for text files using 2-byte Unicode encoding (2 bytes) or _w_c_h_a_r
encoding (sizeof(wchar_t)). The latter guarantees comfortable
interaction with wide-character text objects. Otherwise, the
use of seek/4 on non-binary files (see open/4) is of limited
use, especially when using multi-byte text encodings (e.g. UTF-8)
or multi-byte newline files (e.g. DOS/Windows). On text
files, SWI-Prolog offers reliable backup to an old position
using stream_property/2 and set_stream_position/2. Skipping N
character codes is achieved calling get_code/2 N times or using
copy_stream_data/3, directing the output to a null stream (see
open_null_stream/1). If the seek modifies the current location,
the line number and character position in the line are set to 0.
If the stream cannot be repositioned, a permission_error is raised.
If applying the offset would result in a file position less
than zero, a domain_error is raised. Behaviour when seeking to
positions beyond the size of the underlying object depend on the
object and possibly the operating system. The predicate seek/4
is compatible with Quintus Prolog, though the error conditions
and signalling is ISO compliant. See also stream_property/2 and
set_stream_position/2.
sseett__ssttrreeaamm((_+_S_t_r_e_a_m_, _+_A_t_t_r_i_b_u_t_e))
Modify an attribute of an existing stream. _A_t_t_r_i_b_u_t_e specifies
the stream property to set. If stream is a _p_a_i_r (see
stream_pair/3) both streams are modified, unless the property is
only meaningful on one of the streams or setting both is not
meaningful. In particular, eof_action only applies to the _r_e_a_d
stream, representation_errors only applies to the _w_r_i_t_e stream
and trying to set alias or line_position on a pair results in a
permission_error exception. See also stream_property/2 and open/4.
aalliiaass((_A_l_i_a_s_N_a_m_e))
Set the alias of an already created stream. If _A_l_i_a_s_N_a_m_e
is the name of one of the standard streams, this stream
is rebound. Thus, set_stream(S, current_input) is the same
as set_input/1, and by setting the alias of a stream to
user_input, etc., all user terminal input is read from this
stream. See also interactor/0.
bbuuffffeerr((_B_u_f_f_e_r_i_n_g))
Set the buffering mode of an already created stream. Buffer-
ing is one of full, line or false.
bbuuffffeerr__ssiizzee((_+_S_i_z_e))
Set the size of the I/O buffer of the underlying stream to
_S_i_z_e bytes.
cclloossee__oonn__aabboorrtt((_B_o_o_l))
Determine whether or not the stream is closed by abort/0. By
default, streams are closed.
cclloossee__oonn__eexxeecc((_B_o_o_l))
Set the close_on_exec property. See stream_property/2.
eennccooddiinngg((_A_t_o_m))
Defines the mapping between bytes and character codes used for
the stream. See section 2.18.1 for supported encodings.
eeooff__aaccttiioonn((_A_c_t_i_o_n))
Set end-of-file handling to one of eof_code, reset or error.
ffiillee__nnaammee((_F_i_l_e_N_a_m_e))
Set the filename associated to this stream. This call can be
used to set the file for error locations if _S_t_r_e_a_m corresponds
to _F_i_l_e_N_a_m_e and is not obtained by opening the file directly
but, for example, through a network service.
lliinnee__ppoossiittiioonn((_L_i_n_e_P_o_s))
Set the line position attribute of the stream. This feature
is intended to correct position management of the stream
after sending a terminal escape sequence (e.g., setting ANSI
character attributes). Setting this attribute raises a
permission error if the stream does not record positions. See
line_position/2 and stream_property/2(property position).
llooccaallee((_+_L_o_c_a_l_e))
Change the locale of the stream. See section 4.22.
nneewwlliinnee((_N_e_w_l_i_n_e_M_o_d_e))
Set input or output translation for newlines. See correspond-
ing stream_property/2 for details. In addition to the detected
modes, an input stream can be set in mode detect. It will be
set to dos if a \r character was removed.
ttiimmeeoouutt((_S_e_c_o_n_d_s))
This option can be used to make streams generate an exception
if it takes longer than _S_e_c_o_n_d_s before any new data arrives
at the stream. The value _i_n_f_i_n_i_t_e (default) makes the
stream block indefinitely. Like wait_for_input/3, this call
only applies to streams that support the select() system
call. For further information about timeout handling, see
wait_for_input/3. The exception is of the form
error(timeout_error_(_r_e_a_d_, _S_t_r_e_a_m_)_, __)
ttyyppee((_T_y_p_e))
Set the type of the stream to one of text or binary. See also
open/4 and the encoding property of streams. Switching to
binary sets the encoding to octet. Switching to text sets the
encoding to the default text encoding.
rreeccoorrdd__ppoossiittiioonn((_B_o_o_l))
Do/do not record the line count and line position (see
line_count/2 and line_position/2).
rreepprreesseennttaattiioonn__eerrrroorrss((_M_o_d_e))
Change the behaviour when writing characters to the stream
that cannot be represented by the encoding. See also
stream_property/2 and section 2.18.1.
ttttyy((_B_o_o_l))
Modify whether Prolog thinks there is a terminal (i.e. human
interaction) connected to this stream. On Unix systems the
initial value comes from isatty(). On Windows, the initial
user streams are supposed to be associated to a terminal. See
also stream_property/2.
sseett__pprroolloogg__IIOO((_+_I_n_, _+_O_u_t_, _+_E_r_r_o_r))
Prepare the given streams for interactive behaviour normally
associated to the terminal. _I_n becomes the user_input and
current_input of the calling thread. _O_u_t becomes user_output
and current_output. If _E_r_r_o_r equals _O_u_t an unbuffered stream
is associated to the same destination and linked to user_error.
Otherwise _E_r_r_o_r is used for user_error. Output buffering for _O_u_t
is set to line and buffering on _E_r_r_o_r is disabled. See also
prolog/0 and set_stream/2. The _c_l_i_b package provides the library
prolog_server, creating a TCP/IP server for creating an interactive
session to Prolog.
44..1166..33 EEddiinnbbuurrgghh--ssttyyllee II//OO
The package for implicit input and output destinations is (almost)
compatible with Edinburgh DEC-10 and C-Prolog. The reading and writing
predicates refer to, resp., the _c_u_r_r_e_n_t input and output streams.
Initially these streams are connected to the terminal. The current
output stream is changed using tell/1 or append/1. The current input
stream is changed using see/1. The stream's current value can be
obtained using telling/1 for output and seeing/1 for input.
Source and destination are either a file, user, or a term
`pipe(_C_o_m_m_a_n_d)'. The reserved stream name user refers to the terminal.
In the predicate descriptions below we will call the source/destination
argument `_S_r_c_D_e_s_t'. Below are some examples of source/destination
specifications.
?- see(data). % Start reading from file `data'.
?- tell(user). % Start writing to the terminal.
?- tell(pipe(lpr)). % Start writing to the printer.
Another example of using the pipe/1 construct is shown below. Note
that the pipe/1 construct is not part of Prolog's standard I/O
repertoire.
________________________________________________________________________| |
|getwd(Wd) :- |
| seeing(Old), see(pipe(pwd)), |
| collect_wd(String), |
| seen, see(Old), |
| atom_codes(Wd, String). |
| |
|collect_wd([C|R]) :- |
| get0(C), C \== -1, !, |
| collect_wd(R). |
|collect_wd([]).|_______________________________________________________ | |
The effect of tell/1 is not undone on backtracking, and since the
stream handle is not specified explicitly in further I/O operations
when using Edinburgh-style I/O, you may write to unintended streams
more easily than when using ISO compliant I/O. For example, the
following query writes both "a" and "b" into the file `out' :
________________________________________________________________________| |
|?-|(tell(out),_write(a),_false_;_write(b)),_told.______________________ | |
CCoommppaattiibbiilliittyy nnootteess
Unlike Edinburgh Prolog systems, telling/1 and seeing/1 do not return
the filename of the current input/output but rather the stream
identifier, to ensure the design pattern below works under all
circumstances:
________________________________________________________________________| |
| ..., |
| telling(Old), tell(x), |
| ..., |
| told, tell(Old), |
||_______...,___________________________________________________________ ||
The predicates tell/1 and see/1 first check for user, the pipe(_c_o_m_m_a_n_d)
and a stream handle. Otherwise, if the argument is an atom it is first
compared to open streams associated to a file with _e_x_a_c_t_l_y the same
name. If such a stream exists, created using tell/1 or see/1, output
(input) is switched to the open stream. Otherwise a file with the
specified name is opened.
The behaviour is compatible with Edinburgh Prolog. This is not without
problems. Changing directory, non-file streams, and multiple names
referring to the same file easily lead to unexpected behaviour. New
code, especially when managing multiple I/O channels, should consider
using the ISO I/O predicates defined in section 4.16.2.
sseeee((_+_S_r_c_D_e_s_t))
Open _S_r_c_D_e_s_t for reading and make it the current input (see
set_input/1). If _S_r_c_D_e_s_t is a stream handle, just make this stream
the current input. See the introduction of section 4.16.3 for
details.
tteellll((_+_S_r_c_D_e_s_t))
Open _S_r_c_D_e_s_t for writing and make it the current output (see
set_output/1). If _S_r_c_D_e_s_t is a stream handle, just make this
stream the current output. See the introduction of section 4.16.3
for details.
aappppeenndd((_+_F_i_l_e))
Similar to tell/1, but positions the file pointer at the end of
_F_i_l_e rather than truncating an existing file. The pipe construct
is not accepted by this predicate.
sseeeeiinngg((_?_S_r_c_D_e_s_t))
Same as current_input/1, except that user is returned if the
current input is the stream user_input to improve compatibility
with traditional Edinburgh I/O. See the introduction of
section 4.16.3 for details.
tteelllliinngg((_?_S_r_c_D_e_s_t))
Same as current_output/1, except that user is returned if the
current output is the stream user_output to improve compatibility
with traditional Edinburgh I/O. See the introduction of
section 4.16.3 for details.
sseeeenn
Close the current input stream. The new input stream becomes
user_input.
ttoolldd
Close the current output stream. The new output stream becomes
user_output.
44..1166..44 SSwwiittcchhiinngg bbeettwweeeenn EEddiinnbbuurrgghh aanndd IISSOO II//OO
The predicates below can be used for switching between the implicit and
the explicit stream-based I/O predicates.
sseett__iinnppuutt((_+_S_t_r_e_a_m)) _[_I_S_O_]
Set the current input stream to become _S_t_r_e_a_m. Thus,
open(file, read, Stream), set_input(Stream) is equivalent to
see(file).
sseett__oouuttppuutt((_+_S_t_r_e_a_m)) _[_I_S_O_]
Set the current output stream to become _S_t_r_e_a_m. See also
with_output_to/2.
ccuurrrreenntt__iinnppuutt((_-_S_t_r_e_a_m)) _[_I_S_O_]
Get the current input stream. Useful for getting access to the
status predicates associated with streams.
ccuurrrreenntt__oouuttppuutt((_-_S_t_r_e_a_m)) _[_I_S_O_]
Get the current output stream.
44..1166..55 WWrriittee oonnttoo aattoommss,, ccooddee--lliissttss,, eettcc..
wwiitthh__oouuttppuutt__ttoo((_+_O_u_t_p_u_t_, _:_G_o_a_l))
Run _G_o_a_l as once/1, while characters written to the current
output are sent to _O_u_t_p_u_t. The predicate is SWI-Prolog-specific,
inspired by various posts to the mailinglist. It provides a
flexible replacement for predicates such as sformat/3, swritef/3,
term_to_atom/2, atom_number/2 converting numbers to atoms, etc. The
predicate format/3 accepts the same terms as output argument.
Applications should generally avoid creating atoms by breaking and
concatenating other atoms, as the creation of large numbers of
intermediate atoms generally leads to poor performance, even more
so in multithreaded applications. This predicate supports creating
difference lists from character data efficiently. The example
below defines the DCG rule term//1 to insert a term in the output:
____________________________________________________________________| |
| term(Term, In, Tail) :- |
| with_output_to(codes(In, Tail), write(Term)). |
| |
| ?- phrase(term(hello), X). |
| |
||X_=_[104,_101,_108,_108,_111]_____________________________________ ||
AA SSttrreeaamm hhaannddllee oorr aalliiaass
Temporarily switch current output to the given stream. Redi-
rection using with_output_to/2guarantees the original output
is restored, also if _G_o_a_l fails or raises an exception. See
also call_cleanup/2.
aattoomm((_-_A_t_o_m))
Create an atom from the emitted characters. Please note the
remark above.
ssttrriinngg((_-_S_t_r_i_n_g))
Create a string object as defined in section 4.24.
ccooddeess((_-_C_o_d_e_s))
Create a list of character codes from the emitted characters,
similar to atom_codes/2.
ccooddeess((_-_C_o_d_e_s_, _-_T_a_i_l))
Create a list of character codes as a difference list.
cchhaarrss((_-_C_h_a_r_s))
Create a list of one-character atoms from the emitted charac-
ters, similar to atom_chars/2.
cchhaarrss((_-_C_h_a_r_s_, _-_T_a_i_l))
Create a list of one-character atoms as a difference list.
44..1177 SSttaattuuss ooff ssttrreeaammss
wwaaiitt__ffoorr__iinnppuutt((_+_L_i_s_t_O_f_S_t_r_e_a_m_s_, _-_R_e_a_d_y_L_i_s_t_, _+_T_i_m_e_O_u_t))
Wait for input on one of the streams in _L_i_s_t_O_f_S_t_r_e_a_m_s and return
a list of streams on which input is available in _R_e_a_d_y_L_i_s_t.
wait_for_input/3 waits for at most _T_i_m_e_O_u_t seconds. _T_i_m_e_o_u_t may
be specified as a floating point number to specify fractions of
a second. If _T_i_m_e_o_u_t equals infinite, wait_for_input/3 waits
indefinitely.
This predicate can be used to implement timeout while reading and
to handle input from multiple sources. The following example
will wait for input from the user and an explicitly opened second
terminal. On return, _I_n_p_u_t_s may hold user_input or _P_4 or both.
____________________________________________________________________| |
| ?- open('/dev/ttyp4', read, P4), |
||___wait_for_input([user_input,_P4],_Inputs,_0).___________________ ||
This predicate relies on the select() call on most operating
systems. On Unix this call is implemented for any stream referring
to a file handle, which implies all OS-based streams: sockets,
terminals, pipes, etc. On non-Unix systems select() is generally
only implemented for socket-based streams. See also socket from
the clib package.
Note that wait_for_input/3 returns streams that have data waiting.
This does not mean you can, for example, call read/2 on the
stream without blocking as the stream might hold an incomplete
term. The predicate set_stream/2 using the option timeout(_S_e_c_o_n_d_s)
can be used to make the stream generate an exception if no new
data arrives within the timeout period. Suppose two processes
communicate by exchanging Prolog terms. The following code makes
the server immune for clients that write an incomplete term:
____________________________________________________________________| |
| ..., |
| tcp_accept(Server, Socket, _Peer), |
| tcp_open(Socket, In, Out), |
| set_stream(In, timeout(10)), |
| catch(read(In, Term), _, (close(Out), close(In), fail)), |
||____...,__________________________________________________________ ||
bbyyttee__ccoouunntt((_+_S_t_r_e_a_m_, _-_C_o_u_n_t))
Byte position in _S_t_r_e_a_m. For binary streams this is the same as
character_count/2. For text files the number may be different due
to multi-byte encodings or additional record separators (such as
Control-M in Windows).
cchhaarraacctteerr__ccoouunntt((_+_S_t_r_e_a_m_, _-_C_o_u_n_t))
Unify _C_o_u_n_t with the current character index. For input streams
this is the number of characters read since the open; for output
streams this is the number of characters written. Counting starts
at 0.
lliinnee__ccoouunntt((_+_S_t_r_e_a_m_, _-_C_o_u_n_t))
Unify _C_o_u_n_t with the number of lines read or written. Counting
starts at 1.
lliinnee__ppoossiittiioonn((_+_S_t_r_e_a_m_, _-_C_o_u_n_t))
Unify _C_o_u_n_t with the position on the current line. Note that this
assumes the position is 0 after the open. Tabs are assumed to
be defined on each 8-th character, and backspaces are assumed to
reduce the count by one, provided it is positive.
44..1188 PPrriimmiittiivvee cchhaarraacctteerr II//OO
See section 4.2 for an overview of supported character representations.
nnll _[_I_S_O_]
Write a newline character to the current output stream. On Unix
systems nl/0 is equivalent to put(10).
nnll((_+_S_t_r_e_a_m)) _[_I_S_O_]
Write a newline to _S_t_r_e_a_m.
ppuutt((_+_C_h_a_r))
Write _C_h_a_r to the current output stream. _C_h_a_r is either an
integer expression evaluating to a character code or an atom of
one character. Deprecated. New code should use put_char/1 or
put_code/1.
ppuutt((_+_S_t_r_e_a_m_, _+_C_h_a_r))
Write _C_h_a_r to _S_t_r_e_a_m. See put/1 for details.
ppuutt__bbyyttee((_+_B_y_t_e)) _[_I_S_O_]
Write a single byte to the output. _B_y_t_e must be an integer between
0 and 255.
ppuutt__bbyyttee((_+_S_t_r_e_a_m_, _+_B_y_t_e)) _[_I_S_O_]
Write a single byte to _S_t_r_e_a_m. _B_y_t_e must be an integer between 0
and 255.
ppuutt__cchhaarr((_+_C_h_a_r)) _[_I_S_O_]
Write a character to the current output, obeying the encoding
defined for the current output stream. Note that this may raise
an exception if the encoding of the output stream cannot represent
_C_h_a_r.
ppuutt__cchhaarr((_+_S_t_r_e_a_m_, _+_C_h_a_r)) _[_I_S_O_]
Write a character to _S_t_r_e_a_m, obeying the encoding defined for
_S_t_r_e_a_m. Note that this may raise an exception if the encoding of
_S_t_r_e_a_m cannot represent _C_h_a_r.
ppuutt__ccooddee((_+_C_o_d_e)) _[_I_S_O_]
Similar to put_char/1, but using a _c_h_a_r_a_c_t_e_r _c_o_d_e. _C_o_d_e is a
non-negative integer. Note that this may raise an exception if the
encoding of the output stream cannot represent _C_o_d_e.
ppuutt__ccooddee((_+_S_t_r_e_a_m_, _+_C_o_d_e)) _[_I_S_O_]
Same as put_code/1 but directing _C_o_d_e to _S_t_r_e_a_m.
ttaabb((_+_A_m_o_u_n_t))
Write _A_m_o_u_n_t spaces on the current output stream. _A_m_o_u_n_t should
be an expression that evaluates to a positive integer (see
section 4.27).
ttaabb((_+_S_t_r_e_a_m_, _+_A_m_o_u_n_t))
Write _A_m_o_u_n_t spaces to _S_t_r_e_a_m.
fflluusshh__oouuttppuutt _[_I_S_O_]
Flush pending output on current output stream. flush_output/0 is
automatically generated by read/1 and derivatives if the current
input stream is user and the cursor is not at the left margin.
fflluusshh__oouuttppuutt((_+_S_t_r_e_a_m)) _[_I_S_O_]
Flush output on the specified stream. The stream must be open for
writing.
ttttyyfflluusshh
Flush pending output on stream user. See also flush_output/[0,1].
ggeett__bbyyttee((_-_B_y_t_e)) _[_I_S_O_]
Read the current input stream and unify the next byte with _B_y_t_e (an
integer between 0 and 255). _B_y_t_e is unified with -1 on end of
file.
ggeett__bbyyttee((_+_S_t_r_e_a_m_, _-_B_y_t_e)) _[_I_S_O_]
Read the next byte from _S_t_r_e_a_m and unify _B_y_t_e with an integer
between 0 and 255.
ggeett__ccooddee((_-_C_o_d_e)) _[_I_S_O_]
Read the current input stream and unify _C_o_d_e with the character
code of the next character. _C_o_d_e is unified with -1 on end of
file. See also get_char/1.
ggeett__ccooddee((_+_S_t_r_e_a_m_, _-_C_o_d_e)) _[_I_S_O_]
Read the next character code from _S_t_r_e_a_m.
ggeett__cchhaarr((_-_C_h_a_r)) _[_I_S_O_]
Read the current input stream and unify _C_h_a_r with the next
character as a one-character atom. See also atom_chars/2. On
end-of-file, _C_h_a_r is unified to the atom end_of_file.
ggeett__cchhaarr((_+_S_t_r_e_a_m_, _-_C_h_a_r)) _[_I_S_O_]
Unify _C_h_a_r with the next character from _S_t_r_e_a_m as a one-character
atom. See also get_char/2, get_byte/2 and get_code/2.
ggeett00((_-_C_h_a_r)) _[_d_e_p_r_e_c_a_t_e_d_]
Edinburgh version of the ISO get_code/1 predicate. Note that
Edinburgh Prolog didn't support wide characters and therefore
technically speaking get0/1 should have been mapped to get_byte/1.
The intention of get0/1, however, is to read character codes.
ggeett00((_+_S_t_r_e_a_m_, _-_C_h_a_r)) _[_d_e_p_r_e_c_a_t_e_d_]
Edinburgh version of the ISO get_code/2 predicate. See also
get0/1.
ggeett((_-_C_h_a_r)) _[_d_e_p_r_e_c_a_t_e_d_]
Read the current input stream and unify the next non-blank
character with _C_h_a_r. _C_h_a_r is unified with -1 on end of file. The
predicate get/1 operates on character _c_o_d_e_s. See also get0/1.
ggeett((_+_S_t_r_e_a_m_, _-_C_h_a_r)) _[_d_e_p_r_e_c_a_t_e_d_]
Read the next non-blank character from _S_t_r_e_a_m. See also get/1,
get0/1 and get0/2.
ppeeeekk__bbyyttee((_-_B_y_t_e)) _[_I_S_O_]
ppeeeekk__bbyyttee((_+_S_t_r_e_a_m_, _-_B_y_t_e)) _[_I_S_O_]
ppeeeekk__ccooddee((_-_C_o_d_e)) _[_I_S_O_]
ppeeeekk__ccooddee((_+_S_t_r_e_a_m_, _-_C_o_d_e)) _[_I_S_O_]
ppeeeekk__cchhaarr((_-_C_h_a_r)) _[_I_S_O_]
ppeeeekk__cchhaarr((_+_S_t_r_e_a_m_, _-_C_h_a_r)) _[_I_S_O_]
Read the next byte/code/char from the input without removing
it. These predicates do not modify the stream's position or
end-of-file status. These predicates require a buffered stream
(see set_stream/2) and raise a permission error if the stream
is unbuffered or the buffer is too small to hold the longest
multi-byte sequence that might need to be buffered.
sskkiipp((_+_C_o_d_e))
Read the input until _C_o_d_e or the end of the file is encountered. A
subsequent call to get_code/1 will read the first character after
_C_o_d_e.
sskkiipp((_+_S_t_r_e_a_m_, _+_C_o_d_e))
Skip input (as skip/1) on _S_t_r_e_a_m.
ggeett__ssiinnggllee__cchhaarr((_-_C_o_d_e))
Get a single character from input stream `user' (regardless of the
current input stream). Unlike get_code/1, this predicate does not
wait for a return. The character is not echoed to the user's
terminal. This predicate is meant for keyboard menu selection,
etc. If SWI-Prolog was started with the -tty option this predicate
reads an entire line of input and returns the first non-blank
character on this line, or the character code of the newline (10)
if the entire line consisted of blank characters.
aatt__eenndd__ooff__ssttrreeaamm _[_I_S_O_]
Succeeds after the last character of the current input stream has
been read. Also succeeds if there is no valid current input
stream.
aatt__eenndd__ooff__ssttrreeaamm((_+_S_t_r_e_a_m)) _[_I_S_O_]
Succeeds after the last character of the named stream is read, or
_S_t_r_e_a_m is not a valid input stream. The end-of-stream test is only
available on buffered input streams (unbuffered input streams are
rarely used; see open/4).
sseett__eenndd__ooff__ssttrreeaamm((_+_S_t_r_e_a_m))
Set the size of the file opened as _S_t_r_e_a_m to the current file
position. This is typically used in combination with the open-mode
update.
ccooppyy__ssttrreeaamm__ddaattaa((_+_S_t_r_e_a_m_I_n_, _+_S_t_r_e_a_m_O_u_t_, _+_L_e_n))
Copy _L_e_n codes from _S_t_r_e_a_m_I_n to _S_t_r_e_a_m_O_u_t. Note that the copy is
done using the semantics of get_code/2 and put_code/2, taking care
of possibly recoding that needs to take place between two text
files. See section 2.18.1.
ccooppyy__ssttrreeaamm__ddaattaa((_+_S_t_r_e_a_m_I_n_, _+_S_t_r_e_a_m_O_u_t))
Copy all (remaining) data from _S_t_r_e_a_m_I_n to _S_t_r_e_a_m_O_u_t.
rreeaadd__ppeennddiinngg__iinnppuutt((_+_S_t_r_e_a_m_I_n_, _-_C_o_d_e_s_, _?_T_a_i_l))
Read input pending in the input buffer of _S_t_r_e_a_m_I_n and return it in
the difference list _C_o_d_e_s-_T_a_i_l. That is, the available characters
codes are used to create the list _C_o_d_e_s ending in the tail _T_a_i_l.
This predicate is intended for efficient unbuffered copying and
filtering of input coming from network connections or devices.
The following code fragment realises efficient non-blocking copying
of data from an input to an output stream. The at_end_of_stream/1
call checks for end-of-stream and fills the input buffer. Note
that the use of a get_code/2 and put_code/2 based loop requires a
flush_output/1 call after _e_a_c_h put_code/2. The copy_stream_data/2
does not allow for inspection of the copied data and suffers from
the same buffering issues.
____________________________________________________________________| |
| copy(In, Out) :- |
| repeat, |
| ( at_end_of_stream(In) |
| -> ! |
| ; read_pending_input(In, Chars, []), |
| format(Out, '~s', [Chars]), |
| flush_output(Out), |
| fail |
||____________).____________________________________________________ ||
44..1199 TTeerrmm rreeaaddiinngg aanndd wwrriittiinngg
This section describes the basic term reading and writing predicates.
The predicates format/[1,2] and writef/2 provide formatted output.
Writing to Prolog data structures such as atoms or code-lists is
supported by with_output_to/2and format/3.
Reading is sensitive to the Prolog flag character_escapes, which
controls the interpretation of the \ character in quoted atoms and
strings.
wwrriittee__tteerrmm((_+_T_e_r_m_, _+_O_p_t_i_o_n_s)) _[_I_S_O_]
The predicate write_term/2 is the generic form of all Prolog
term-write predicates. Valid options are:
aattttrriibbuutteess((_A_t_o_m))
Define how attributed variables (see section 6.1) are written.
The default is determined by the Prolog flag write_attributes.
Defined values are ignore (ignore the attribute), dots (write
the attributes as {...}), write (simply hand the attributes
recursively to write_term/2) and portray (hand the attributes
to attr_portray_hook/2).
bbaacckkqquuootteedd__ssttrriinngg((_B_o_o_l))
If true, write a string object (see section 4.24) as `...`.
The default depends on the Prolog flag backquoted_string.
bblloobbss((_A_t_o_m))
Define how non-text blobs are handled. By default, this is
left to the write handler specified with the blob type. Using
portray, portray/1 is called for each blob encountered. See
section 9.4.7.
cchhaarraacctteerr__eessccaappeess((_B_o_o_l))
If true and quoted(_t_r_u_e) is active, special characters in
quoted atoms and strings are emitted as ISO escape sequences.
Default is taken from the reference module (see below).
ccyycclleess((_B_o_o_l))
If true (default), cyclic terms are written as @(_T_e_m_p_l_a_t_e_,
_S_u_b_s_t_i_t_u_t_i_o_n_s), where _S_u_b_s_t_i_t_u_t_i_o_n_s is a list _V_a_r = _V_a_l_u_e. If
cycles is false, max_depth is not given, and _T_e_r_m is cyclic,
write_term/2 raises a domain_error. See also the cycles option
in read_term/2.
iiggnnoorree__ooppss((_B_o_o_l))
If true, the generic term representation (<_f_u_n_c_t_o_r>(<_a_r_g_s> ...))
will be used for all terms. Otherwise (default), operators,
list notation and {}/1 will be written using their special
syntax.
mmaaxx__ddeepptthh((_I_n_t_e_g_e_r))
If the term is nested deeper than _I_n_t_e_g_e_r, print the remainder
as ellipses (...). A 0 (zero) value (default) imposes no
depth limit. This option also delimits the number of printed
items in a list. Example:
_______________________________________________________________| |
|?- write_term(a(s(s(s(s(0)))), [a,b,c,d,e,f]), |
| [max_depth(3)]). |
|a(s(s(...)), [a, b|...]) |
|true.|________________________________________________________ | |
Used by the top level and debugger to limit screen
output. See also the Prolog flags toplevel_print_options and
debugger_print_options.
mmoodduullee((_M_o_d_u_l_e))
Define the reference module (default user). This defines the
default value for the character_escapes option as well as the
operator definitions to use. See also op/3.
nnuummbbeerrvvaarrss((_B_o_o_l))
If true, terms of the format $VAR(N), where <_N> is a positive
integer, will be written as a variable name. If _N is an
atom it is written without quotes. This extension allows for
writing variables with user-provided names. The default is
false. See also numbervars/3.
ppaarrttiiaall((_B_o_o_l))
If true (default false), do not reset the logic that inserts
extra spaces that separate tokens where needed. This is
intended to solve the problems with the code below. Calling
write_value(.) writes .., which cannot be read. By adding
partial(_t_r_u_e) to the option list, it correctly emits . ..
Similar problems appear when emitting operators using multiple
calls to write_term/3.
_______________________________________________________________| |
|write_value(Value) :- |
| write_term(Value, [partial(true)]), |
||_______write('.'),_nl._______________________________________ ||
ppoorrttrraayy((_B_o_o_l))
If true, the hook portray/1 is called before printing a term
that is not a variable. If portray/1 succeeds, the term is
considered printed. See also print/1. The default is false.
This option is an extension to the ISO write_term options.
ppoorrttrraayy__ggooaall((_:_G_o_a_l))
Implies portray(_t_r_u_e), but calls _G_o_a_l rather than the prede-
fined hook portray/1. _G_o_a_l is called through call/3, where
the first argument is _G_o_a_l, the second is the term to be
printed and the 3rd argument is the current write option list.
The write option list is copied from the write_term call,
but the list is guaranteed to hold an option priority that
reflects the current priority.
pprriioorriittyy((_I_n_t_e_g_e_r))
An integer between 0 and 1200 representing the `context
priority'. Default is 1200. Can be used to write partial
terms appearing as the argument to an operator. For example:
_______________________________________________________________| |
| format('~w = ', [VarName]), |
||_______write_term(Value,_[quoted(true),_priority(699)])______ ||
qquuootteedd((_B_o_o_l))
If true, atoms and functors that need quotes will be quoted.
The default is false.
ssppaacciinngg((_+_S_p_a_c_i_n_g))
Determines whether and where extra white space is added to
enhance readability. The default is standard, adding only
space where needed for proper tokenization by read_term/3.
Currently, the only other value is next_argument, adding a
space after a comma used to separate arguments in a term or
list.
vvaarriiaabbllee__nnaammeess((_+_L_i_s_t))
Assign names to variables in _T_e_r_m. _L_i_s_t is a list of terms
_N_a_m_e = _V_a_r, where _N_a_m_e is an atom that represents a valid
Prolog variable name. Terms where _V_a_r is bound or is a
variable that does not appear in _T_e_r_m are ignored. Raises an
error if _L_i_s_t is not a list, one of the members is not a term
_N_a_m_e = _V_a_r, _N_a_m_e is not an atom or _N_a_m_e does not represent a
valid Prolog variable name.
The implementation binds the variables from _L_i_s_t to a term
'$VAR'(_N_a_m_e). Like write_canonical/1, terms that where already
bound to '$VAR'(_X) before write_term/2 are printed normally,
unless the option numbervars(_t_r_u_e) is also provided. If the
option numbervars(_t_r_u_e) is used, the user is responsible for
avoiding collisions between assigned names and numbered names.
See also the variable_names option of read_term/2.
Possible variable attributes (see section 6) are ignored. In
most cases one should use copy_term/3 to obtain a copy that
is free of attributed variables and handle the associated
constraints as appropriate for the use-case.
wwrriittee__tteerrmm((_+_S_t_r_e_a_m_, _+_T_e_r_m_, _+_O_p_t_i_o_n_s)) _[_I_S_O_]
As write_term/2, but output is sent to _S_t_r_e_a_m rather than the
current output.
wwrriittee__lleennggtthh((_+_T_e_r_m_, _-_L_e_n_g_t_h_, _+_O_p_t_i_o_n_s)) _[_s_e_m_i_d_e_t_]
True when _L_e_n_g_t_h is the number of characters emitted for
_w_r_i_t_e___t_e_r_mTerm, Options. In addition to valid options for
write_term/2, it processes the option:
mmaaxx__lleennggtthh((_+_M_a_x_L_e_n_g_t_h))
If provided, fail if _L_e_n_g_t_h would be larger than _M_a_x_L_e_n_g_t_h.
The implementation ensures that the runtime is limited when
computing the length of a huge term with a bounded maximum.
wwrriittee__ccaannoonniiccaall((_+_T_e_r_m)) _[_I_S_O_]
Write _T_e_r_m on the current output stream using standard paren-
thesised prefix notation (i.e., ignoring operator declarations).
Atoms that need quotes are quoted. Terms written with this
predicate can always be read back, regardless of current operator
declarations. Equivalent to write_term/2 using the options
ignore_ops, quoted and numbervars after numbervars/4 using the
singletons option.
Note that due to the use of numbervars/4, non-ground terms must be
written using a _s_i_n_g_l_e write_canonical/1 call. This used to be
the case anyhow, as garbage collection between multiple calls to
one of the write predicates can change the _G<_N_N_N> identity of the
variables.
wwrriittee__ccaannoonniiccaall((_+_S_t_r_e_a_m_, _+_T_e_r_m)) _[_I_S_O_]
Write _T_e_r_m in canonical form on _S_t_r_e_a_m.
wwrriittee((_+_T_e_r_m)) _[_I_S_O_]
Write _T_e_r_m to the current output, using brackets and operators
where appropriate.
wwrriittee((_+_S_t_r_e_a_m_, _+_T_e_r_m)) _[_I_S_O_]
Write _T_e_r_m to _S_t_r_e_a_m.
wwrriitteeqq((_+_T_e_r_m)) _[_I_S_O_]
Write _T_e_r_m to the current output, using brackets and operators
where appropriate. Atoms that need quotes are quoted. Terms
written with this predicate can be read back with read/1 provided
the currently active operator declarations are identical.
wwrriitteeqq((_+_S_t_r_e_a_m_, _+_T_e_r_m)) _[_I_S_O_]
Write _T_e_r_m to _S_t_r_e_a_m, inserting quotes.
wwrriitteellnn((_+_T_e_r_m))
Equivalent to write(Term), nl..
pprriinntt((_+_T_e_r_m))
Prints _T_e_r_m on the current output stream similar to write/1,
but for each (sub)term of _T_e_r_m, the dynamic predicate portray/1
is first called. If this predicate succeeds _p_r_i_n_t assumes the
(sub)term has been written. This allows for user-defined term
writing. See also portray_text.
pprriinntt((_+_S_t_r_e_a_m_, _+_T_e_r_m))
Print _T_e_r_m to _S_t_r_e_a_m.
ppoorrttrraayy((_+_T_e_r_m))
A dynamic predicate, which can be defined by the user to change the
behaviour of print/1 on (sub)terms. For each subterm encountered
that is not a variable print/1 first calls portray/1 using the term
as argument. For lists, only the list as a whole is given to
portray/1. If portray/1 succeeds print/1 assumes the term has been
written.
rreeaadd((_-_T_e_r_m)) _[_I_S_O_]
Read the next Prolog term from the current input stream and unify
it with _T_e_r_m. On a syntax error read/1 displays an error message,
attempts to skip the erroneous term and fails. On reaching
end-of-file _T_e_r_m is unified with the atom end_of_file.
rreeaadd((_+_S_t_r_e_a_m_, _-_T_e_r_m)) _[_I_S_O_]
Read _T_e_r_m from _S_t_r_e_a_m.
rreeaadd__ccllaauussee((_+_S_t_r_e_a_m_, _-_T_e_r_m_, _+_O_p_t_i_o_n_s))
Equivalent to read_term/3, but sets options according to the
current compilation context and optionally processes comments.
Defined options:
ssyynnttaaxx__eerrrroorrss((_+_A_t_o_m))
See read_term/3, but the default is dec10 (report and restart).
tteerrmm__ppoossiittiioonn((_-_T_e_r_m_P_o_s))
Same as for read_term/3.
ssuubbtteerrmm__ppoossiittiioonnss((_-_T_e_r_m_P_o_s))
Same as for read_term/3.
vvaarriiaabbllee__nnaammeess((_-_B_i_n_d_i_n_g_s))
Same as for read_term/3.
pprroocceessss__ccoommmmeenntt((_+_B_o_o_l_e_a_n))
If true (default), call prolog:comment_hook(_C_o_m_m_e_n_t_s_, _T_e_r_m_P_o_s_,
_T_e_r_m) if this multifile hook is defined (see pro-
log:comment_hook/3). This is used to drive PlDoc.
ccoommmmeennttss((_-_C_o_m_m_e_n_t_s))
If provided, unify _C_o_m_m_e_n_t_s with the comments encountered
while reading _T_e_r_m. This option implies pro-
cess_comment(_f_a_l_s_e).
The singletons option of read_term/3is initialised from the active
style-checking mode. The module option is initialised to the
current compilation module (see prolog_load_context/2).
rreeaadd__tteerrmm((_-_T_e_r_m_, _+_O_p_t_i_o_n_s)) _[_I_S_O_]
Read a term from the current input stream and unify the term with
_T_e_r_m. The reading is controlled by options from the list of
_O_p_t_i_o_n_s. If this list is empty, the behaviour is the same as for
read/1. The options are upward compatible with Quintus Prolog.
The argument order is according to the ISO standard. Syntax
errors are always reported using exception-handling (see catch/3).
Options:
bbaacckkqquuootteedd__ssttrriinngg((_B_o_o_l))
If true, read `...` to a string object (see section 4.24).
The default depends on the Prolog flag backquoted_string.
cchhaarraacctteerr__eessccaappeess((_B_o_o_l))
Defines how to read \ escape sequences in quoted atoms. See
the Prolog flag character_escapes in current_prolog_flag/2.
(SWI-Prolog).
ccoommmmeennttss((_-_C_o_m_m_e_n_t_s))
Unify _C_o_m_m_e_n_t_s with a list of _P_o_s_i_t_i_o_n-_C_o_m_m_e_n_t, where _P_o_s_i_t_i_o_n
is a stream position object (see stream_position_data/3)
indicating the start of a comment and _C_o_m_m_e_n_t is a string
object containing the text including delimiters of a comment.
It returns all comments from where the read_term/2 call started
up to the end of the term read.
ccyycclleess((_B_o_o_l))
If true (default false), re-instantiate templates as produced
by the corresponding write_term/2 option. Note that the
default is false to avoid misinterpretation of @(_T_e_m_p_l_a_t_e_,
_S_u_b_s_t_u_t_i_o_n_s), while the default of write_term/2 is true because
emitting cyclic terms without using the template construct
produces an infinitely large term (read: it will generate an
error after producing a huge amount of output).
ddoouubbllee__qquuootteess((_A_t_o_m))
Defines how to read "..." strings. See the Prolog flag
double_quotes. (SWI-Prolog).
mmoodduullee((_M_o_d_u_l_e))
Specify _M_o_d_u_l_e for operators, character_escapes flag and
double_quotes flag. The value of the latter two is overruled
if the corresponding read_term/3 option is provided. If no
module is specified, the current `source module' is used.
(SWI-Prolog).
qquuaassii__qquuoottaattiioonnss((_-_L_i_s_t))
If present, unify _L_i_s_t with the quasi quotations (see sec-
tion 11.23 instead of evaluating quasi quotations. Each
quasi quotation is a term quasi_quotation(_+_S_y_n_t_a_x_, _+_Q_u_o_t_a_t_i_o_n_,
_+_V_a_r_D_i_c_t_, _-_R_e_s_u_l_t), where _S_y_n_t_a_x is the term in {|Syntax||,
_Q_u_o_t_a_t_i_o_n is a list of character codes that represent the
quotation, _V_a_r_D_i_c_t is a list of _N_a_m_e=_V_a_r_i_a_b_l_e and _R_e_s_u_l_t is a
variable that shares with the place where the quotation must
be inserted. This option is intended to support tools that
manipulate Prolog source text.
ssiinngglleettoonnss((_V_a_r_s))
As variable_names, but only reports the variables occurring
only once in the _T_e_r_m read. Variables starting with an
underscore (`_') are not included in this list. (ISO). If
_V_a_r_s is the constant warning, singleton variables are reported
using print_message/2.
ssyynnttaaxx__eerrrroorrss((_A_t_o_m))
If error (default), throw an exception on a syntax error.
Other values are fail, which causes a message to be printed
using print_message/2, after which the predicate fails, quiet
which causes the predicate to fail silently, and dec10 which
causes syntax errors to be printed, after which read_term/[2,3]
continues reading the next term. Using dec10, read_term/[2,3]
never fails. (Quintus, SICStus).
ssuubbtteerrmm__ppoossiittiioonnss((_T_e_r_m_P_o_s))
Describes the detailed layout of the term. The formats for
the various types of terms are given below. All positions are
character positions. If the input is related to a normal
stream, these positions are relative to the start of the
input; when reading from the terminal, they are relative to
the start of the term.
_F_r_o_m--_T_o
Used for primitive types (atoms, numbers, variables).
ssttrriinngg__ppoossiittiioonn((_F_r_o_m_, _T_o))
Used to indicate the position of a string enclosed in
double quotes (").
bbrraaccee__tteerrmm__ppoossiittiioonn((_F_r_o_m_, _T_o_, _A_r_g))
Term of the form {...}, as used in DCG rules. _A_r_g
describes the argument.
lliisstt__ppoossiittiioonn((_F_r_o_m_, _T_o_, _E_l_m_s_, _T_a_i_l))
A list. _E_l_m_s describes the positions of the elements. If
the list specifies the tail as |<_T_a_i_l_T_e_r_m>, _T_a_i_l is unified
with the term position of the tail, otherwise with the
atom none.
tteerrmm__ppoossiittiioonn((_F_r_o_m_, _T_o_, _F_F_r_o_m_, _F_T_o_, _S_u_b_P_o_s))
Used for a compound term not matching one of the above.
_F_F_r_o_m and _F_T_o describe the position of the functor.
_S_u_b_P_o_s is a list, each element of which describes the term
position of the corresponding subterm.
tteerrmm__ppoossiittiioonn((_P_o_s))
Unifies _P_o_s with the starting position of the term read. _P_o_s
is of the same format as used by stream_property/2.
vvaarriiaabblleess((_V_a_r_s))
Unify _V_a_r_s with a list of variables in the term. The
variables appear in the order they have been read. See also
term_variables/2. (ISO).
vvaarriiaabbllee__nnaammeess((_V_a_r_s))
Unify _V_a_r_s with a list of `_N_a_m_e = _V_a_r', where _N_a_m_e is an atom
describing the variable name and _V_a_r is a variable that shares
with the corresponding variable in _T_e_r_m. (ISO).
rreeaadd__tteerrmm((_+_S_t_r_e_a_m_, _-_T_e_r_m_, _+_O_p_t_i_o_n_s)) _[_I_S_O_]
Read term with options from _S_t_r_e_a_m. See read_term/2.
rreeaadd__tteerrmm__ffrroomm__aattoomm((_+_A_t_o_m_, _-_T_e_r_m_, _+_O_p_t_i_o_n_s))
Use read_term/3 to read the next term from _A_t_o_m. _A_t_o_m is either an
atom or a string object (see section 4.24). It is not required
for _A_t_o_m to end with a full-stop. This predicate supersedes
atom_to_term/3.
rreeaadd__hhiissttoorryy((_+_S_h_o_w_, _+_H_e_l_p_, _+_S_p_e_c_i_a_l_, _+_P_r_o_m_p_t_, _-_T_e_r_m_, _-_B_i_n_d_i_n_g_s))
Similar to read_term/2 using the option variable_names, but allows
for history substitutions. read_history/6is used by the top level
to read the user's actions. _S_h_o_w is the command the user should
type to show the saved events. _H_e_l_p is the command to get an
overview of the capabilities. _S_p_e_c_i_a_l is a list of commands that
are not saved in the history. _P_r_o_m_p_t is the first prompt given.
Continuation prompts for more lines are determined by prompt/2.
A %w in the prompt is substituted by the event number. See
section 2.7 for available substitutions.
SWI-Prolog calls read_history/6 as follows:
____________________________________________________________________| |
||read_history(h,_'!h',_[trace],_'%w_?-_',_Goal,_Bindings)__________ ||
pprroommpptt((_-_O_l_d_, _+_N_e_w))
Set prompt associated with read/1 and its derivatives. _O_l_d is
first unified with the current prompt. On success the prompt will
be set to _N_e_w if this is an atom. Otherwise an error message is
displayed. A prompt is printed if one of the read predicates is
called and the cursor is at the left margin. It is also printed
whenever a newline is given and the term has not been terminated.
Prompts are only printed when the current input stream is _u_s_e_r.
pprroommpptt11((_+_P_r_o_m_p_t))
Sets the prompt for the next line to be read. Continuation lines
will be read using the prompt defined by prompt/2.
44..2200 AAnnaallyyssiinngg aanndd CCoonnssttrruuccttiinngg TTeerrmmss
ffuunnccttoorr((_?_T_e_r_m_, _?_N_a_m_e_, _?_A_r_i_t_y)) _[_I_S_O_]
True when _T_e_r_m is a term with functor _N_a_m_e/_A_r_i_t_y. If _T_e_r_m is a
variable it is unified with a new term whose arguments are all
different variables (such a term is called a skeleton). If _T_e_r_m is
atomic, _A_r_i_t_y will be unified with the integer 0, and _N_a_m_e will be
unified with _T_e_r_m. Raises instantiation_error if _T_e_r_m is unbound
and _N_a_m_e/_A_r_i_t_y is insufficiently instantiated.
aarrgg((_?_A_r_g_, _+_T_e_r_m_, _?_V_a_l_u_e)) _[_I_S_O_]
_T_e_r_m should be instantiated to a term, _A_r_g to an integer between
1 and the arity of _T_e_r_m. _V_a_l_u_e is unified with the _A_r_g-th
argument of _T_e_r_m. _A_r_g may also be unbound. In this case _V_a_l_u_e
will be unified with the successive arguments of the term. On
successful unification, _A_r_g is unified with the argument number.
Backtracking yields alternative solutions. The predicate arg/3
fails silently if _A_r_g= 0 or _A_r_g > _a_r_i_t_y and raises the exception
domain_error(not_less_than_zero, _A_r_g)if _A_r_g <0.
_?_T_e_r_m =.. _?_L_i_s_t _[_I_S_O_]
_L_i_s_t is a list whose head is the functor of _T_e_r_m and the remaining
arguments are the arguments of the term. Either side of the
predicate may be a variable, but not both. This predicate is
called `Univ'. Examples:
____________________________________________________________________| |
| ?- foo(hello, X) =.. List. |
| |
| List = [foo, hello, X] |
| |
| ?- Term =.. [baz, foo(1)] |
| |
||Term_=_baz(foo(1))________________________________________________ ||
nnuummbbeerrvvaarrss((_+_T_e_r_m_, _+_S_t_a_r_t_, _-_E_n_d))
Unify the free variables of _T_e_r_m with a term $VAR(_N), where _N is
the number of the variable. Counting starts at _S_t_a_r_t. _E_n_d is
unified with the number that should be given to the next variable.
Example:
____________________________________________________________________| |
| ?- numbervars(foo(A, B, A), 0, End). |
| A = '$VAR'(0), |
| B = '$VAR'(1), |
||End_=_2.__________________________________________________________ ||
See also the numbervars option to write_term/3 and numbervars/4.
nnuummbbeerrvvaarrss((_+_T_e_r_m_, _+_S_t_a_r_t_, _-_E_n_d_, _+_O_p_t_i_o_n_s))
As numbervars/3, but providing the following options:
ffuunnccttoorr__nnaammee((_+_A_t_o_m))
Name of the functor to use instead of $VAR.
aattttvvaarr((_+_A_c_t_i_o_n))
What to do if an attributed variable is encountered. Options
are skip, which causes numbervars/3 to ignore the attributed
variable, bind which causes it to thread it as a normal
variable and assign the next '$VAR'(N) term to it, or
(default) error which raises a type_error exception.
ssiinngglleettoonnss((_+_B_o_o_l))
If true (default false), numbervars/4 does singleton detec-
tion. Singleton variables are unified with '$VAR'('_'),
causing them to be printed as _ by write_term/2 using
the numbervars option. This option is exploited by
portray_clause/2 and write_canonical/2.
vvaarr__nnuummbbeerr((_@_T_e_r_m_, _-_V_a_r_N_u_m_b_e_r))
True if _T_e_r_m is numbered by numbervars/3 and _V_a_r_N_u_m_b_e_r is the
number given to this variable. This predicate avoids the need for
unification with '$VAR'(X) and opens the path for replacing this
valid Prolog term by an internal representation that has no textual
equivalent.
tteerrmm__vvaarriiaabblleess((_+_T_e_r_m_, _-_L_i_s_t)) _[_I_S_O_]
Unify _L_i_s_t with a list of variables, each sharing with a unique
variable of _T_e_r_m. The variables in _L_i_s_t are ordered in order of
appearance traversing _T_e_r_m depth-first and left-to-right. See also
term_variables/3. For example:
____________________________________________________________________| |
| ?- term_variables(a(X, b(Y, X), Z), L). |
||L_=_[X,_Y,_Z].____________________________________________________ ||
tteerrmm__vvaarriiaabblleess((_+_T_e_r_m_, _-_L_i_s_t_, _?_T_a_i_l))
Difference list version of term_variables/2. That is, _T_a_i_l is the
tail of the variable list _L_i_s_t.
ccooppyy__tteerrmm((_+_I_n_, _-_O_u_t)) _[_I_S_O_]
Create a version of _I_n with renamed (fresh) variables and unify
it to _O_u_t. Attributed variables (see section 6.1) have their
attributes copied. The implementation of copy_term/2 can deal
with infinite trees (cyclic terms). As pure Prolog cannot
distinguish a ground term from another ground term with exactly the
same structure, ground sub-terms are _s_h_a_r_e_d between _I_n and _O_u_t.
Sharing ground terms does affect setarg/3. SWI-Prolog provides
duplicate_term/2 to create a true copy of a term.
44..2200..11 NNoonn--llooggiiccaall ooppeerraattiioonnss oonn tteerrmmss
Prolog is not able to _m_o_d_i_f_y instantiated parts of a term. Lacking
that capability makes the language much safer, but unfortunately there
are problems that suffer severely in terms of time and/or memory usage.
Always try hard to avoid the use of these primitives, but they can be a
good alternative to using dynamic predicates. See also section 6.3,
discussing the use of global variables.
sseettaarrgg((_+_A_r_g_, _+_T_e_r_m_, _+_V_a_l_u_e))
Extra-logical predicate. Assigns the _A_r_g-th argument of the
compound term _T_e_r_m with the given _V_a_l_u_e. The assignment is undone
if backtracking brings the state back into a position before the
setarg/3 call. See also nb_setarg/3.
This predicate may be used for destructive assignment to terms,
using them as an extra-logical storage bin. Always try hard to
avoid the use of setarg/3 as it is not supported by many Prolog
systems and one has to be very careful about unexpected copying
as well as unexpected noncopying of terms. A good practice to
improve somewhat on this situation is to make sure that terms whose
arguments are subject to setarg/3 have one unused and unshared
variable in addition to the used arguments. This variable avoids
unwanted sharing in, e.g., copy_term/2, and causes the term to be
considered as non-ground.
nnbb__sseettaarrgg((_+_A_r_g_, _+_T_e_r_m_, _+_V_a_l_u_e))
Assigns the _A_r_g-th argument of the compound term _T_e_r_m with the
given _V_a_l_u_e as setarg/3, but on backtracking the assignment
is _n_o_t reversed. If _V_a_l_u_e is not atomic, it is duplicated
using duplicate_term/2. This predicate uses the same technique
as nb_setval/2. We therefore refer to the description of
nb_setval/2 for details on non-backtrackable assignment of terms.
This predicate is compatible with GNU-Prolog setarg(_A_,_T_,_V_,_f_a_l_s_e),
removing the type restriction on _V_a_l_u_e. See also nb_linkarg/3.
Below is an example for counting the number of solutions of a
goal. Note that this implementation is thread-safe, reentrant
and capable of handling exceptions. Realising these features with
a traditional implementation based on assert/retract or flag/3 is
much more complicated.
____________________________________________________________________| |
| :- meta_predicate |
| succeeds_n_times(0, -). |
| |
| succeeds_n_times(Goal, Times) :- |
| Counter = counter(0), |
| ( Goal, |
| arg(1, Counter, N0), |
| N is N0 + 1, |
| nb_setarg(1, Counter, N), |
| fail |
| ; arg(1, Counter, Times) |
||________).________________________________________________________ ||
nnbb__lliinnkkaarrgg((_+_A_r_g_, _+_T_e_r_m_, _+_V_a_l_u_e))
As nb_setarg/3, but like nb_linkval/2 it does _n_o_t duplicate _V_a_l_u_e.
Use with extreme care and consult the documentation of nb_linkval/2
before use.
dduupplliiccaattee__tteerrmm((_+_I_n_, _-_O_u_t))
Version of copy_term/2 that also copies ground terms and therefore
ensures that destructive modification using setarg/3 does not
affect the copy. See also nb_setval/2, nb_linkval/2, nb_setarg/3
and nb_linkarg/3.
ssaammee__tteerrmm((_@_T_1_, _@_T_2)) _[_s_e_m_i_d_e_t_]
True if _T_1 and _T_2 are equivalent and will remain equivalent, even
if setarg/3 is used on either of them. This means _T_1 and _T_2
are the same variable, equivalent atomic data or a compound term
allocated at the same address.
44..2211 AAnnaallyyssiinngg aanndd CCoonnssttrruuccttiinngg AAttoommss
These predicates convert between Prolog constants and lists of
character codes. The predicates atom_codes/2, number_codes/2 and name/2
behave the same when converting from a constant to a list of character
codes. When converting the other way around, atom_codes/2 will
generate an atom, number_codes/2 will generate a number or exception
and name/2 will return a number if possible and an atom otherwise.
The ISO standard defines atom_chars/2 to describe the `broken-up' atom
as a list of one-character atoms instead of a list of codes. Up
to version 3.2.x, SWI-Prolog's atom_chars/2 behaved like atom_codes,
compatible with Quintus and SICStus Prolog. As of 3.3.x, SWI-Prolog
atom_codes/2 and atom_chars/2are compliant to the ISO standard.
To ease the pain of all variations in the Prolog community, all
SWI-Prolog predicates behave as flexible as possible. This implies
the `list-side' accepts either a code-list or a char-list and the
`atom-side' accepts all atomic types (atom, number and string).
aattoomm__ccooddeess((_?_A_t_o_m_, _?_S_t_r_i_n_g)) _[_I_S_O_]
Convert between an atom and a list of character codes. If _A_t_o_m is
instantiated, it will be translated into a list of character codes
and the result is unified with _S_t_r_i_n_g. If _A_t_o_m is unbound and
_S_t_r_i_n_g is a list of character codes, _A_t_o_m will be unified with an
atom constructed from this list.
aattoomm__cchhaarrss((_?_A_t_o_m_, _?_C_h_a_r_L_i_s_t)) _[_I_S_O_]
As atom_codes/2, but _C_h_a_r_L_i_s_t is a list of one-character atoms
rather than a list of character codes.
____________________________________________________________________| |
| ?- atom_chars(hello, X). |
| |
||X_=_[h,_e,_l,_l,_o]_______________________________________________ ||
cchhaarr__ccooddee((_?_A_t_o_m_, _?_C_o_d_e)) _[_I_S_O_]
Convert between character and character code for a single charac-
ter.
nnuummbbeerr__cchhaarrss((_?_N_u_m_b_e_r_, _?_C_h_a_r_L_i_s_t)) _[_I_S_O_]
Similar to atom_chars/2, but converts between a number and its
representation as a list of one-character atoms. Fails with a
syntax_error if _N_u_m_b_e_r is unbound or _C_h_a_r_L_i_s_t does not describe a
number. Following the ISO standard, it allows for _l_e_a_d_i_n_g white
space (including newlines) and does not allow for _t_r_a_i_l_i_n_g white
space.
nnuummbbeerr__ccooddeess((_?_N_u_m_b_e_r_, _?_C_o_d_e_L_i_s_t)) _[_I_S_O_]
As number_chars/2, but converts to a list of character codes rather
than one-character atoms. In the mode (-, +), both predicates
behave identically to improve handling of non-ISO source.
aattoomm__nnuummbbeerr((_?_A_t_o_m_, _?_N_u_m_b_e_r))
Realises the popular combination of atom_codes/2 and number_codes/2
to convert between atom and number (integer or float) in
one predicate, avoiding the intermediate list. Unlike the
ISO number_codes/2 predicates, atom_number/2 fails silently in
mode (+,-) if _A_t_o_m does not represent a number. See also
atomic_list_concat/2 for assembling an atom from atoms and numbers.
nnaammee((_?_A_t_o_m_i_c_, _?_C_o_d_e_L_i_s_t))
_C_o_d_e_L_i_s_t is a list of character codes representing the same text
as _A_t_o_m_i_c. Each of the arguments may be a variable, but not
both. When _C_o_d_e_L_i_s_t describes an integer or floating point number
and _A_t_o_m_i_c is a variable, _A_t_o_m_i_c will be unified with the numeric
value described by _C_o_d_e_L_i_s_t (e.g., name(N, "300"), 400 is N + 100
succeeds). If _C_o_d_e_L_i_s_t is not a representation of a number, _A_t_o_m_i_c
will be unified with the atom with the name given by the character
code list. When _A_t_o_m_i_c is an atom or number, the unquoted print
representation of it as a character code list will be unified with
_C_o_d_e_L_i_s_t.
Note that it is not possible to produce the atom '300'
using name/2, and that name(300, CodeList), name('300', CodeList)
succeeds. For these reasons, new code should consider using
the ISO predicates atom_codes/2 or number_codes/2. See also
atom_number/2.
tteerrmm__ttoo__aattoomm((_?_T_e_r_m_, _?_A_t_o_m))
True if _A_t_o_m describes a term that unifies with _T_e_r_m. When _A_t_o_m
is instantiated, _A_t_o_m is converted and then unified with _T_e_r_m.
If _A_t_o_m has no valid syntax, a syntax_error exception is raised.
Otherwise _T_e_r_m is ``written'' on _A_t_o_m using write_term/2 with the
option quoted(_t_r_u_e). See also format/3 and with_output_to/2.
aattoomm__ttoo__tteerrmm((_+_A_t_o_m_, _-_T_e_r_m_, _-_B_i_n_d_i_n_g_s)) _[_d_e_p_r_e_c_a_t_e_d_]
Use _A_t_o_m as input to read_term/2 using the option variable_names
and return the read term in _T_e_r_m and the variable bindings in
_B_i_n_d_i_n_g_s. _B_i_n_d_i_n_g_s is a list of _N_a_m_e =_V_a_r couples, thus providing
access to the actual variable names. See also read_term/2. If
_A_t_o_m has no valid syntax, a syntax_error exception is raised. New
code should use read_from_atom/3.
aattoomm__ccoonnccaatt((_?_A_t_o_m_1_, _?_A_t_o_m_2_, _?_A_t_o_m_3)) _[_I_S_O_]
_A_t_o_m_3 forms the concatenation of _A_t_o_m_1 and _A_t_o_m_2. At least two
of the arguments must be instantiated to atoms. This predicate
also allows for the mode (-,-,+), non-deterministically splitting
the 3rd argument into two parts (as append/3 does for lists).
SWI-Prolog allows for atomic arguments. Portable code must use
atomic_concat/3 if non-atom arguments are involved.
aattoommiicc__ccoonnccaatt((_+_A_t_o_m_i_c_1_, _+_A_t_o_m_i_c_2_, _-_A_t_o_m))
_A_t_o_m represents the text after converting _A_t_o_m_i_c_1 and _A_t_o_m_i_c_2 to
text and concatenating the result:
____________________________________________________________________| |
| ?- atomic_concat(name, 42, X). |
||X_=_name42._______________________________________________________ ||
aattoommiicc__lliisstt__ccoonnccaatt((_+_L_i_s_t_, _-_A_t_o_m)) _[_c_o_m_m_o_n_s_]
_L_i_s_t is a list of atoms, integers or floating point numbers.
Succeeds if _A_t_o_m can be unified with the concatenated elements of
_L_i_s_t. Equivalent to atomic_list_concat(_L_i_s_t_, _'_'_, _A_t_o_m).
aattoommiicc__lliisstt__ccoonnccaatt((_+_L_i_s_t_, _+_S_e_p_a_r_a_t_o_r_, _-_A_t_o_m)) _[_c_o_m_m_o_n_s_]
Creates an atom just like atomic_list_concat/2, but inserts _S_e_p_a_r_a_-
_t_o_r between each pair of atoms. For example:
____________________________________________________________________| |
| ?- atomic_list_concat([gnu, gnat], ', ', A). |
| |
||A_=_'gnu,_gnat'___________________________________________________ ||
The SWI-Prolog version of this predicate can also be used to split
atoms by instantiating _S_e_p_a_r_a_t_o_r and _A_t_o_m as shown below. We
kept this functionality to simplify porting old SWI-Prolog code
where this predicate was called concat_atom/3. When used in
mode (-,+,+), _S_e_p_a_r_a_t_o_r must be a non-empty atom. See also
split_string/4.
____________________________________________________________________| |
| ?- atomic_list_concat(L, -, 'gnu-gnat'). |
| |
||L_=_[gnu,_gnat]___________________________________________________ ||
aattoomm__lleennggtthh((_+_A_t_o_m_, _-_L_e_n_g_t_h)) _[_I_S_O_]
True if _A_t_o_m is an atom of _L_e_n_g_t_h characters. The SWI-Prolog
version accepts all atomic types, as well as code-lists and
character-lists. New code should avoid this feature and use
write_length/3 to get the number of characters that would be
written if the argument was handed to write_term/3.
aattoomm__pprreeffiixx((_+_A_t_o_m_, _+_P_r_e_f_i_x)) _[_d_e_p_r_e_c_a_t_e_d_]
True if _A_t_o_m starts with the characters from _P_r_e_f_i_x. Its behaviour
is equivalent to ?- sub_atom(_A_t_o_m, 0, _, _, _P_r_e_f_i_x). Deprecated.
ssuubb__aattoomm((_+_A_t_o_m_, _?_B_e_f_o_r_e_, _?_L_e_n_, _?_A_f_t_e_r_, _?_S_u_b)) _[_I_S_O_]
ISO predicate for breaking atoms. It maintains the following
relation: _S_u_b is a sub-atom of _A_t_o_m that starts at _B_e_f_o_r_e, has _L_e_n
characters, and _A_t_o_m contains _A_f_t_e_r characters after the match.
____________________________________________________________________| |
| ?- sub_atom(abc, 1, 1, A, S). |
| |
||A_=_1,_S_=_b______________________________________________________ ||
The implementation minimises non-determinism and creation of atoms.
This is a very flexible predicate that can do search, prefix- and
suffix-matching, etc.
ssuubb__aattoomm__iiccaasseecchhkk((_+_H_a_y_s_t_a_c_k_, _?_S_t_a_r_t_, _+_N_e_e_d_l_e)) _[_s_e_m_i_d_e_t_]
True when _N_e_e_d_l_e is a sub atom of _H_a_y_s_t_a_c_k starting at _S_t_a_r_t. The
match is `half case insensitive', i.e., uppercase letters in _N_e_e_d_l_e
only match themselves, while lowercase letters in _N_e_e_d_l_e match case
insensitively. _S_t_a_r_t is the first 0-based offset inside _H_a_y_s_t_a_c_k
where _N_e_e_d_l_e matches.
44..2222 LLooccaalliizzaattiioonn ((llooccaallee)) ssuuppppoorrtt
SWI-Prolog provides (currently limited) support for localized
applications.
o The predicates char_type/2 and code_type/2 query character classes
depending on the locale.
o The predicates collation_key/2 and locale_sort/2 can be used for
locale dependent sorting of atoms.
o The predicate format_time/3 can be used to format time and date
representations, where some of the specifiers are locale dependent.
o The predicate format/2 provides locale-specific formating of
numbers. This functionality is based on a more fine-grained
localization model that is the subject of this section.
A locale is a (optionally named) read-only object that provides
information to locale specific functions. The system creates a default
locale object named default from the system locale. This locale is
used as the initial locale for the three standard streams as well as
the main thread. Locale sensitive output predicates such as format/3
get their locale from the stream to which they deliver their output.
New streams get their locale from the thread that created the stream.
Threads get their locale from the thread that created them.
llooccaallee__ccrreeaattee((_-_L_o_c_a_l_e_, _+_D_e_f_a_u_l_t_, _+_O_p_t_i_o_n_s))
Create a new locale object. _D_e_f_a_u_l_t is either an existing locale
or a string that denotes the name of a locale provided by the
system, such as "en_EN.UTF-8". The values read from the default
locale can be modified using _O_p_t_i_o_n_s. _O_p_t_i_o_n_s provided are:
aalliiaass((_+_A_t_o_m))
Give the locale a name.
ddeecciimmaall__ppooiinntt((_+_A_t_o_m))
Specify the decimal point to use.
tthhoouussaannddss__sseepp((_+_A_t_o_m))
Specify the string that delimits digit groups. Only effective
is grouping is also specified.
ggrroouuppiinngg((_+_L_i_s_t))
Specify the grouping of digits. Groups are created from the
right (least significant) digits, left of the decimal point.
_L_i_s_t is a list of integers, specifying the number of digits in
each group, counting from the right. If the last element is
repeat(_C_o_u_n_t), the remaining digits are grouped in groups of
size _C_o_u_n_t. If the last element is a normal integer, digits
further to the left are not grouped.
For example, the English locale uses
____________________________________________________________________| |
||[_decimal_point('.'),_thousands_sep(','),_grouping([repeat(3)])_]_ ||
Named locales exists until they are destroyed using
locale_destroy/1 and they are no longer referenced. Un-
named locales are subject to (atom) garbage collection.
llooccaallee__ddeessttrrooyy((_+_L_o_c_a_l_e))
Destroy a locale. If the locale is named, this removes the name
association from the locale, after which the locale is left to be
reclaimed by garbage collection.
llooccaallee__pprrooppeerrttyy((_?_L_o_c_a_l_e_, _?_P_r_o_p_e_r_t_y))
True when _L_o_c_a_l_e has _P_r_o_p_e_r_t_y. Properties are the same as the
_O_p_t_i_o_n_s described with locale_create/3.
sseett__llooccaallee((_+_L_o_c_a_l_e))
Set the default locale for the current thread, as well as
the locale for the standard streams (user_input, user_output,
user_error, current_output and current_input. This locale is used
for new streams, unless overruled using the locale(_L_o_c_a_l_e) option
of open/4 or set_stream/2.
ccuurrrreenntt__llooccaallee((_-_L_o_c_a_l_e))
True when _L_o_c_a_l_e is the locale of the calling thread.
44..2233 CChhaarraacctteerr pprrooppeerrttiieess
SWI-Prolog offers two comprehensive predicates for classifying
characters and character codes. These predicates are defined
as built-in predicates to exploit the C-character classification's
handling of _l_o_c_a_l_e (handling of local character sets). These
predicates are fast, logical and deterministic if applicable.
In addition, there is the library ctype providing compatibility with
some other Prolog systems. The predicates of this library are defined
in terms of code_type/2.
cchhaarr__ttyyppee((_?_C_h_a_r_, _?_T_y_p_e))
Tests or generates alternative _T_y_p_es or _C_h_a_rs. The character types
are inspired by the standard C <ctype.h> primitives.
aallnnuumm
_C_h_a_r is a letter (upper- or lowercase) or digit.
aallpphhaa
_C_h_a_r is a letter (upper- or lowercase).
ccssyymm
_C_h_a_r is a letter (upper- or lowercase), digit or the un-
derscore (_). These are valid C and Prolog symbol
characters.
ccssyymmff
_C_h_a_r is a letter (upper- or lowercase) or the underscore (_).
These are valid first characters for C and Prolog symbols.
aasscciiii
_C_h_a_r is a 7-bit ASCII character (0..127).
wwhhiittee
_C_h_a_r is a space or tab, i.e. white space inside a line.
ccnnttrrll
_C_h_a_r is an ASCII control character (0..31).
ddiiggiitt
_C_h_a_r is a digit.
ddiiggiitt((_W_e_i_g_h_t))
_C_h_a_r is a digit with value _W_e_i_g_h_t. I.e. char_type(X, digit(6)
yields _X = '6'. Useful for parsing numbers.
xxddiiggiitt((_W_e_i_g_h_t))
_C_h_a_r is a hexadecimal digit with value _W_e_i_g_h_t. I.e.
char_type(a, xdigit(X) yields _X = '10'. Useful for parsing
numbers.
ggrraapphh
_C_h_a_r produces a visible mark on a page when printed. Note
that the space is not included!
lloowweerr
_C_h_a_r is a lowercase letter.
lloowweerr((_U_p_p_e_r))
_C_h_a_r is a lowercase version of _U_p_p_e_r. Only true if _C_h_a_r is
lowercase and _U_p_p_e_r uppercase.
ttoo__lloowweerr((_U_p_p_e_r))
_C_h_a_r is a lowercase version of _U_p_p_e_r. For non-letters, or
letter without case, _C_h_a_r and _L_o_w_e_r are the same. See also
upcase_atom/2 and downcase_atom/2.
uuppppeerr
_C_h_a_r is an uppercase letter.
uuppppeerr((_L_o_w_e_r))
_C_h_a_r is an uppercase version of _L_o_w_e_r. Only true if _C_h_a_r is
uppercase and _L_o_w_e_r lowercase.
ttoo__uuppppeerr((_L_o_w_e_r))
_C_h_a_r is an uppercase version of _L_o_w_e_r. For non-letters, or
letter without case, _C_h_a_r and _L_o_w_e_r are the same. See also
upcase_atom/2 and downcase_atom/2.
ppuunncctt
_C_h_a_r is a punctuation character. This is a graph character
that is not a letter or digit.
ssppaaccee
_C_h_a_r is some form of layout character (tab, vertical tab,
newline, etc.).
eenndd__ooff__ffiillee
_C_h_a_r is -1.
eenndd__ooff__lliinnee
_C_h_a_r ends a line (ASCII: 10..13).
nneewwlliinnee
_C_h_a_r is a newline character (10).
ppeerriioodd
_C_h_a_r counts as the end of a sentence (.,!,?).
qquuoottee
_C_h_a_r is a quote character (", ', `).
ppaarreenn((_C_l_o_s_e))
_C_h_a_r is an open parenthesis and _C_l_o_s_e is the corresponding
close parenthesis.
pprroolloogg__vvaarr__ssttaarrtt
_C_h_a_r can start a Prolog variable name.
pprroolloogg__aattoomm__ssttaarrtt
_C_h_a_r can start a unquoted Prolog atom that is not a symbol.
pprroolloogg__iiddeennttiiffiieerr__ccoonnttiinnuuee
_C_h_a_r can continue a Prolog variable name or atom.
pprroolloogg__pprroolloogg__ssyymmbbooll
_C_h_a_r is a Prolog symbol character. Sequences of Prolog symbol
characters glue together to form an unquoted atom. Examples
are =.., \=, etc.
ccooddee__ttyyppee((_?_C_o_d_e_, _?_T_y_p_e))
As char_type/2, but uses character codes rather than one-character
atoms. Please note that both predicates are as flexible as
possible. They handle either representation if the argument is
instantiated and will instantiate only with an integer code or a
one-character atom, depending of the version used. See also the
Prolog flag double_quotes, atom_chars/2 and atom_codes/2.
44..2233..11 CCaassee ccoonnvveerrssiioonn
There is nothing in the Prolog standard for converting case in textual
data. The SWI-Prolog predicates code_type/2 and char_type/2 can be
used to test and convert individual characters. We have started some
additional support:
ddoowwnnccaassee__aattoomm((_+_A_n_y_C_a_s_e_, _-_L_o_w_e_r_C_a_s_e))
Converts the characters of _A_n_y_C_a_s_e into lowercase as char_type/2
does (i.e. based on the defined _l_o_c_a_l_e if Prolog provides locale
support on the hosting platform) and unifies the lowercase atom
with _L_o_w_e_r_C_a_s_e.
uuppccaassee__aattoomm((_+_A_n_y_C_a_s_e_, _-_U_p_p_e_r_C_a_s_e))
Converts, similar to downcase_atom/2, an atom to uppercase.
44..2233..22 WWhhiittee ssppaaccee nnoorrmmaalliizzaattiioonn
nnoorrmmaalliizzee__ssppaaccee((_-_O_u_t_, _+_I_n))
Normalize white space in _I_n. All leading and trailing white
space is removed. All non-empty sequences for Unicode white space
characters are replaced by a single space (\u0020) character. _O_u_t
uses the same conventions as with_output_to/2 and format/3.
44..2233..33 LLaanngguuaaggee--ssppeecciiffiicc ccoommppaarriissoonn
This section deals with predicates for language-specific string
comparison operations.
ccoollllaattiioonn__kkeeyy((_+_A_t_o_m_, _-_K_e_y))
Create a _K_e_y from _A_t_o_m for locale-specific comparison. The key is
defined such that if the key of atom A precedes the key of atom B
in the standard order of terms, A is alphabetically smaller than B
using the sort order of the current locale.
The predicate collation_key/2 is used by locale_sort/2 from
library(sort). Please examine the implementation of locale_sort/2
as an example of using this call.
The _K_e_y is an implementation-defined and generally unreadable
string. On systems that do not support locale handling, _K_e_y is
simply unified with _A_t_o_m.
llooccaallee__ssoorrtt((_+_L_i_s_t_, _-_S_o_r_t_e_d))
Sort a list of atoms using the current locale. _L_i_s_t is a list of
atoms or string objects (see section 4.24). _S_o_r_t_e_d is unified with
a list containing all atoms of _L_i_s_t, sorted to the rules of the
current locale. See also collation_key/2 and setlocale/3.
44..2244 RReepprreesseennttiinngg tteexxtt iinn ssttrriinnggss
SWI-Prolog supports the data type _s_t_r_i_n_g. Strings are a time- and
space-efficient mechanism to handle text in Prolog. Strings are stored
as a byte array on the global (term) stack and are thus destroyed on
backtracking and reclaimed by the garbage collector.
Strings were added to SWI-Prolog based on an early draft of the ISO
standard, offering a mechanism to represent temporary character data
efficiently. As SWI-Prolog strings can handle 0-bytes, they are
frequently used through the foreign language interface (section 9) for
storing arbitrary byte sequences.
Starting with version 3.3, SWI-Prolog offers garbage collection on the
atom space as well as representing 0-bytes in atoms. Although strings
and atoms still have different features, new code should consider
using atoms to avoid too many representations for text as well as for
compatibility with other Prolog implementations. Below are some of the
differences:
o _c_r_e_a_t_i_o_n
Creating strings is fast, as the data is simply copied to the
global stack. Atoms are unique and therefore more expensive in
terms of memory and time to create. On the other hand, if the
same text has to be represented multiple times, atoms are more
efficient.
o _d_e_s_t_r_u_c_t_i_o_n
Backtracking destroys strings at no cost. They are cheap to handle
by the garbage collector, but it should be noted that extensive
use of strings will cause many garbage collections. Atom garbage
collection is generally faster.
String objects by default have no lexical representation and thus can
only be created using the predicates below or through the foreign
language interface (see chapter 9). There are two ways to make
read/1 read text into strings, both controlled through Prolog flags.
One is by setting the double_quotes flag to string, and the other
is by setting the backquoted_string flag to true. In the latter
case, `Hello world` is read into a string and write_term/2 prints
strings between back-quotes if quoted is true. This flag provides
compatibility with LPA Prolog string handling.
aattoomm__ssttrriinngg((_?_A_t_o_m_, _?_S_t_r_i_n_g))
Bi-directional conversion between an atom and a string. At least
one of the two arguments must be instantiated. _A_t_o_m can also be an
integer or floating point number.
ssttrriinngg__ccooddeess((_?_S_t_r_i_n_g_, _?_C_o_d_e_s))
Bi-directional conversion between a string and a list of character
codes. At least one of the two arguments must be instantiated.
ssttrriinngg__lleennggtthh((_+_S_t_r_i_n_g_, _-_L_e_n_g_t_h))
Unify _L_e_n_g_t_h with the number of characters in _S_t_r_i_n_g. This
predicate is functionally equivalent to atom_length/2 and also
accepts atoms, integers and floats as its first argument.
ssttrriinngg__ccooddee((_?_I_n_d_e_x_, _+_S_t_r_i_n_g_, _?_C_o_d_e))
True when _C_o_d_e represents the character at the 0-based _I_n_d_e_x
position in _S_t_r_i_n_g. If _I_n_d_e_x is unbound the string is scanned
from index 0. Raises a domain error if _I_n_d_e_x is negative. The
mode string_code(_-_,_+_,_+) is deterministic if the searched-for _C_o_d_e
appears only once in _S_t_r_i_n_g. Note that this is similar to
sub_string(_S_t_r_i_n_g_, _I_n_d_e_x_, _1_, ___, _C_h_a_r), except that the character
is represented as a code in string_code/3 and as a one-character
string in sub_string/5. See also sub_atom/5.
ssttrriinngg__ccoonnccaatt((_?_S_t_r_i_n_g_1_, _?_S_t_r_i_n_g_2_, _?_S_t_r_i_n_g_3))
Similar to atom_concat/3, but the unbound argument will be unified
with a string object rather than an atom. Also, if both _S_t_r_i_n_g_1
and _S_t_r_i_n_g_2 are unbound and _S_t_r_i_n_g_3 is bound to text, it breaks
_S_t_r_i_n_g_3, unifying the start with _S_t_r_i_n_g_1 and the end with _S_t_r_i_n_g_2
as append does with lists. Note that this is not particularly
fast on long strings, as for each redo the system has to create
two entirely new strings, while the list equivalent only creates a
single new list-cell and moves some pointers around.
ssuubb__ssttrriinngg((_+_S_t_r_i_n_g_, _?_S_t_a_r_t_, _?_L_e_n_g_t_h_, _?_A_f_t_e_r_, _?_S_u_b))
_S_u_b is a substring of _S_t_r_i_n_g starting at _S_t_a_r_t, with length _L_e_n_g_t_h,
and _S_t_r_i_n_g has _A_f_t_e_r characters left after the match. See also
sub_atom/5.
44..2255 OOppeerraattoorrss
Operators are defined to improve the readability of source code.
For example, without operators, to write 2*3+4*5 one would have to
write +(*(2,3),*(4,5)). In Prolog, a number of operators have been
predefined. All operators, except for the comma (,) can be redefined
by the user.
Some care has to be taken before defining new operators. Defining
too many operators might make your source `natural' looking, but at
the same time make it hard to understand the limits of your syntax.
To ease the pain, as of SWI-Prolog 3.3.0, operators are local to the
module in which they are defined. Operators can be exported from
modules using a term op(_P_r_e_c_e_d_e_n_c_e_, _T_y_p_e_, _N_a_m_e) in the export list as
specified by module/2. This is an extension specific to SWI-Prolog and
the recommended mechanism if portability is not an important concern.
The module table of the module user acts as default table for all
modules and can be modified explicitly from inside a module to achieve
compatibility with other Prolog systems:
________________________________________________________________________| |
|:- module(prove, |
| [ prove/1 |
| ]). |
| |
|:-|op(900,_xfx,_user:(=>)).____________________________________________ | |
Unlike what many users think, operators and quoted atoms have no
relation: defining an atom as an operator does nnoott influence parsing
characters into atoms, and quoting an atom does nnoott stop it from acting
as an operator. To stop an atom acting as an operator, enclose it in
parentheses like this: (myop).
oopp((_+_P_r_e_c_e_d_e_n_c_e_, _+_T_y_p_e_, _:_N_a_m_e)) _[_I_S_O_]
Declare _N_a_m_e to be an operator of type _T_y_p_e with precedence
_P_r_e_c_e_d_e_n_c_e. _N_a_m_e can also be a list of names, in which case
all elements of the list are declared to be identical operators.
_P_r_e_c_e_d_e_n_c_e is an integer between 0 and 1200. Precedence 0 removes
the declaration. _T_y_p_e is one of: xf, yf, xfx, xfy, yfx, fy or
fx. The `f' indicates the position of the functor, while x and y
indicate the position of the arguments. `y' should be interpreted
as ``on this position a term with precedence lower or equal to the
precedence of the functor should occur''. For `x' the precedence
of the argument must be strictly lower. The precedence of a term
is 0, unless its principal functor is an operator, in which case
the precedence is the precedence of this operator. A term enclosed
in parentheses (...) has precedence 0.
The predefined operators are shown in table 4.2. Operators can
be redefined, unless prohibited by one of the limitations below.
Applications must be careful with (re-)defining operators because
changing operators may cause (other) files to be interpreted
ddiiffffeerreennttllyy. Often this will lead to a syntax error. In other
cases, text is read silently into a different term which may lead
to subtle and difficult to track errors.
o It is not allowed to redefine the comma (',').
o The bar (|) can only be (re-)defined as infix operator with
priority not less than 1001.
o It is not allowed to define the empty list ([]) or the
curly-bracket pair ({}) as operators.
In SWI-Prolog, operators are _l_o_c_a_l to a module (see also
section 5.8). Keeping operators in modules and using controlled
import/export of operators as described with the module/2 directive
keep the issues manageable. The module system provides the
operators from table 4.2 and these operators cannot be modified.
Files that are loaded from the SWI-Prolog directories resolve
operators and predicates from this system module rather than user,
which makes the semantics of the library and development system
modules independent of operator changes to the user module.
______________________________________________________________
| 1200 |xfx |-->, :- |
| 1200 | fx |:-, ?- |
| 1150 | fx |dynamic, discontiguous, initialization, |
| | |meta_predicate, module_transparent, multifile,|
| | |thread_local, volatile |
| 1100 |xfy |;, | |
| 1050 |xfy |->, *-> |
| 1000 |xfy |, |
| 900 | fy |\+ |
| 900 | fx |~ |
| 700 |xfx |<, =, =.., =@=, =:=, =<, ==, =\=, >, >=, @<, |
| | |@=<, @>, @>=, \=, \==, is |
| 600 |xfy |: |
| 500 | yfx |+, -, /\, \/, xor |
| 500 | fx |? |
| 400 | yfx |*, /, //, rdiv, <<, >>, mod, rem |
| 200 |xfx |** |
| 200 |xfy |^ |
|__200_|_fy__|+,_-,_\________________________________________|_
Table 4.2: System operators
ccuurrrreenntt__oopp((_?_P_r_e_c_e_d_e_n_c_e_, _?_T_y_p_e_, _?_:_N_a_m_e)) _[_I_S_O_]
True if _N_a_m_e is currently defined as an operator of type _T_y_p_e with
precedence _P_r_e_c_e_d_e_n_c_e. See also op/3.
44..2266 CChhaarraacctteerr CCoonnvveerrssiioonn
Although I wouldn't really know why you would like to use these
features, they are provided for ISO compliance.
cchhaarr__ccoonnvveerrssiioonn((_+_C_h_a_r_I_n_, _+_C_h_a_r_O_u_t)) _[_I_S_O_]
Define that term input (see read_term/3) maps each character read
as _C_h_a_r_I_n to the character _C_h_a_r_O_u_t. Character conversion is only
executed if the Prolog flag char_conversion is set to true and
not inside quoted atoms or strings. The initial table maps each
character onto itself. See also current_char_conversion/2.
ccuurrrreenntt__cchhaarr__ccoonnvveerrssiioonn((_?_C_h_a_r_I_n_, _?_C_h_a_r_O_u_t)) _[_I_S_O_]
Queries the current character conversion table. See
char_conversion/2 for details.
44..2277 AArriitthhmmeettiicc
Arithmetic can be divided into some special purpose integer predicates
and a series of general predicates for integer, floating point and
rational arithmetic as appropriate. The general arithmetic predicates
all handle _e_x_p_r_e_s_s_i_o_n_s. An expression is either a simple number or a
_f_u_n_c_t_i_o_n. The arguments of a function are expressions. The functions
are described in section 4.27.2.3.
44..2277..11 SSppeecciiaall ppuurrppoossee iinntteeggeerr aarriitthhmmeettiicc
The predicates in this section provide more logical operations between
integers. They are not covered by the ISO standard, although they are
`part of the community' and found as either library or built-in in many
other Prolog systems.
bbeettwweeeenn((_+_L_o_w_, _+_H_i_g_h_, _?_V_a_l_u_e))
_L_o_w and _H_i_g_h are integers, _H_i_g_h >=_L_o_w. If _V_a_l_u_e is an integer,
_L_o_w=< _V_a_l_u_e=< _H_i_g_h. When _V_a_l_u_e is a variable it is successively
bound to all integers between _L_o_w and _H_i_g_h. If _H_i_g_h is inf
or infinite between/3 is true iff _V_a_l_u_e>= _L_o_w, a feature that is
particularly interesting for generating integers from a certain
value.
ssuucccc((_?_I_n_t_1_, _?_I_n_t_2))
True if _I_n_t_2= _I_n_t_1+1 and _I_n_t_1>=0. At least one of the arguments
must be instantiated to a natural number. This predicate raises
the domain error not_less_than_zero if called with a negative
integer. E.g. succ(_X_, _0) fails silently and succ(_X_, _-_1) raises a
domain error.
pplluuss((_?_I_n_t_1_, _?_I_n_t_2_, _?_I_n_t_3))
True if _I_n_t_3 =_I_n_t_1 +_I_n_t_2. At least two of the three arguments
must be instantiated to integers.
44..2277..22 GGeenneerraall ppuurrppoossee aarriitthhmmeettiicc
The general arithmetic predicates are optionally compiled (see
set_prolog_flag/2 and the -O command line option). Compiled
arithmetic reduces global stack requirements and improves performance.
Unfortunately compiled arithmetic cannot be traced, which is why it is
optional.
_+_E_x_p_r_1 > _+_E_x_p_r_2 _[_I_S_O_]
True if expression _E_x_p_r_1 evaluates to a larger number than _E_x_p_r_2.
_+_E_x_p_r_1 < _+_E_x_p_r_2 _[_I_S_O_]
True if expression _E_x_p_r_1 evaluates to a smaller number than _E_x_p_r_2.
_+_E_x_p_r_1 =< _+_E_x_p_r_2 _[_I_S_O_]
True if expression _E_x_p_r_1 evaluates to a smaller or equal number to
_E_x_p_r_2.
_+_E_x_p_r_1 >= _+_E_x_p_r_2 _[_I_S_O_]
True if expression _E_x_p_r_1 evaluates to a larger or equal number to
_E_x_p_r_2.
_+_E_x_p_r_1 =\= _+_E_x_p_r_2 _[_I_S_O_]
True if expression _E_x_p_r_1 evaluates to a number non-equal to _E_x_p_r_2.
_+_E_x_p_r_1 =:= _+_E_x_p_r_2 _[_I_S_O_]
True if expression _E_x_p_r_1 evaluates to a number equal to _E_x_p_r_2.
_-_N_u_m_b_e_r iiss _+_E_x_p_r _[_I_S_O_]
True when _N_u_m_b_e_r is the value to which _E_x_p_r evaluates. Typically,
is/2 should be used with unbound left operand. If equality is to
be tested, =:=/2 should be used. For example:
?- 1 is sin(pi/2). Fails! sin(pi/2) evaluates
to the float 1.0, which does
not unify with the integer 1.
?- 1 =:= sin(pi/2). Succeeds as expected.
44..2277..22..11 AArriitthhmmeettiicc ttyyppeess
SWI-Prolog defines the following numeric types:
o _i_n_t_e_g_e_r
If SWI-Prolog is built using the _G_N_U _m_u_l_t_i_p_l_e _p_r_e_c_i_s_i_o_n _a_r_i_t_h_m_e_t_i_c
_l_i_b_r_a_r_y (GMP), integer arithmetic is _u_n_b_o_u_n_d_e_d, which means that
the size of integers is limited by available memory only. Without
GMP, SWI-Prolog integers are 64-bits, regardless of the native
integer size of the platform. The type of integer support
can be detected using the Prolog flags bounded, min_integer and
max_integer. As the use of GMP is default, most of the following
descriptions assume unbounded integer arithmetic.
Internally, SWI-Prolog has three integer representations. Small
integers (defined by the Prolog flag max_tagged_integer) are
encoded directly. Larger integers are represented as 64-bit values
on the global stack. Integers that do not fit in 64 bits are
represented as serialised GNU MPZ structures on the global stack.
o _r_a_t_i_o_n_a_l _n_u_m_b_e_r
Rational numbers (Q) are quotients of two integers. Rational
arithmetic is only provided if GMP is used (see above). Rational
numbers are currently not supported by a Prolog type. They are
represented by the compound term rdiv(_N_,_M). Rational numbers that
are returned from is/2 are _c_a_n_o_n_i_c_a_l, which means M is positive
and N and M have no common divisors. Rational numbers are
introduced in the computation using the rational/1, rationalize/1
or the rdiv/2 (rational division) function. Using the same functor
for rational division and for representing rational numbers allows
for passing rational numbers between computations as well as for
using format/3 for printing.
In the long term, it is likely that rational numbers will become
_a_t_o_m_i_c as well as a subtype of _n_u_m_b_e_r. User code that creates
or inspects the rdiv(_M_,_N) terms will not be portable to future
versions. Rationals are created using one of the functions
mentioned above and inspected using rational/3.
o _f_l_o_a_t
Floating point numbers are represented using the C type double.
On most of today's platforms these are 64-bit IEEE floating point
numbers.
Arithmetic functions that require integer arguments accept, in addition
to integers, rational numbers with (canonical) denominator `1'. If
the required argument is a float the argument is converted to float.
Note that conversion of integers to floating point numbers may raise an
overflow exception. In all other cases, arguments are converted to the
same type using the order below.
integer ! rational number ! floating point number
44..2277..22..22 RRaattiioonnaall nnuummbbeerr eexxaammpplleess
The use of rational numbers with unbounded integers allows for
exact integer or _f_i_x_e_d _p_o_i_n_t arithmetic under addition, subtraction,
multiplication and division. To exploit rational arithmetic rdiv/2
should be used instead of `/' and floating point numbers must be
converted to rational using rational/1. Omitting the rational/1 on
floats will convert a rational operand to float and continue the
arithmetic using floating point numbers. Here are some examples.
A is 2 rdiv 6 A = 1 rdiv 3
A is 4 rdiv 3 + 1 A = 7 rdiv 3
A is 4 rdiv 3 + 1.5 A = 2.83333
A is 4 rdiv 3 + rational(1.5) A = 17 rdiv 6
Note that floats cannot represent all decimal numbers exactly. The
function rational/1 creates an _e_x_a_c_t equivalent of the float, while
rationalize/1 creates a rational number that is within the float
rounding error from the original float. Please check the documentation
of these functions for details and examples.
Rational numbers can be printed as decimal numbers with arbitrary
precision using the format/3 floating point conversion:
________________________________________________________________________| |
|?- A is 4 rdiv 3 + rational(1.5), |
| format('~50f~n', [A]). |
|2.83333333333333333333333333333333333333333333333333 |
| |
|A|=_17_rdiv_6__________________________________________________________ | |
44..2277..22..33 AArriitthhmmeettiicc FFuunnccttiioonnss
Arithmetic functions are terms which are evaluated by the arithmetic
predicates described in section 4.27.2. There are four types of
arguments to functions:
_E_x_p_r Arbitrary expression, returning either a
floating point value or an integer.
_I_n_t_E_x_p_r Arbitrary expression that must evaluate to an
integer.
_R_a_t_E_x_p_r Arbitrary expression that must evaluate to a
rational number.
_F_l_o_a_t_E_x_p_r Arbitrary expression that must evaluate to a
floating point.
For systems using bounded integer arithmetic (default is unbounded,
see section 4.27.2.1 for details), integer operations that would cause
overflow automatically convert to floating point arithmetic.
SWI-Prolog provides many extensions to the set of floating point
functions defined by the ISO standard. The current policy is to
provide such functions on `as-needed' basis if the function is widely
supported elsewhere and notably if it is part of the C99 mathematical
library. In addition, we try to maintain compatibility with YAP.
- _+_E_x_p_r _[_I_S_O_]
_R_e_s_u_l_t =-_E_x_p_r
+ _+_E_x_p_r _[_I_S_O_]
_R_e_s_u_l_t =_E_x_p_r. Note that if + is followed by a number, the parser
discards the +. I.e. ?- integer(+1) succeeds.
_+_E_x_p_r_1 + _+_E_x_p_r_2 _[_I_S_O_]
_R_e_s_u_l_t =_E_x_p_r_1 +_E_x_p_r_2
_+_E_x_p_r_1 - _+_E_x_p_r_2 _[_I_S_O_]
_R_e_s_u_l_t =_E_x_p_r_1 -_E_x_p_r_2
_+_E_x_p_r_1 * _+_E_x_p_r_2 _[_I_S_O_]
_R_e_s_u_l_t =_E_x_p_r_1_*Expr2
_+_E_x_p_r_1 / _+_E_x_p_r_2 _[_I_S_O_]
_R_e_s_u_l_t = _E_x_p_r_1=_E_x_p_r_2. If the flag iso is true, both arguments are
converted to float and the return value is a float. Otherwise
(default), if both arguments are integers the operation returns an
integer if the division is exact. If at least one of the arguments
is rational and the other argument is integer, the operation
returns a rational number. In all other cases the return value is
a float. See also ///2 and rdiv/2.
_+_I_n_t_E_x_p_r_1 mmoodd _+_I_n_t_E_x_p_r_2 _[_I_S_O_]
Modulo, defined as _R_e_s_u_l_t = _I_n_t_E_x_p_r_1 - (_I_n_t_E_x_p_r_1 div _I_n_t_E_x_p_r_2) * _I_n_t_E_x_p_r_2,
where div is _f_l_o_o_r_e_d division.
_+_I_n_t_E_x_p_r_1 rreemm _+_I_n_t_E_x_p_r_2 _[_I_S_O_]
Remainder of integer division. Behaves as if defined by
_R_e_s_u_l_t is _I_n_t_E_x_p_r_1 - (_I_n_t_E_x_p_r_1 // _I_n_t_E_x_p_r_2) * _I_n_t_E_x_p_r_2
_+_I_n_t_E_x_p_r_1 // _+_I_n_t_E_x_p_r_2 _[_I_S_O_]
Integer division, defined as _R_e_s_u_l_t is rndI(_E_x_p_r_1/_E_x_p_r_2). The
function rndI is the default rounding used by the C compiler and
available through the Prolog flag integer_rounding_function. In
the C99 standard, C-rounding is defined as towards_zero.
ddiivv((_+_I_n_t_E_x_p_r_1_, _+_I_n_t_E_x_p_r_2)) _[_I_S_O_]
Integer division, defined as
_R_e_s_u_l_t is (_I_n_t_E_x_p_r_1 - _I_n_t_E_x_p_r_1 mod _I_n_t_E_x_p_r_2) // _I_n_t_E_x_p_r_2 . In
other words, this is integer division that rounds towards
-infinity. This function guarantees behaviour that is consistent
with mod/2, i.e., the following holds for every pair of integers
X; Y where Y =\= 0.
____________________________________________________________________| |
| Q is div(X, Y), |
| M is mod(X, Y), |
||________X_=:=_Y*Q+M.______________________________________________ ||
_+_R_a_t_E_x_p_r rrddiivv _+_R_a_t_E_x_p_r
Rational number division. This function is only available if
SWI-Prolog has been compiled with rational number support. See
section 4.27.2.2 for details.
_+_I_n_t_E_x_p_r_1 ggccdd _+_I_n_t_E_x_p_r_2
Result is the greatest common divisor of _I_n_t_E_x_p_r_1, _I_n_t_E_x_p_r_2.
aabbss((_+_E_x_p_r)) _[_I_S_O_]
Evaluate _E_x_p_r and return the absolute value of it.
ssiiggnn((_+_E_x_p_r)) _[_I_S_O_]
Evaluate to -1 if _E_x_p_r< 0, 1 if _E_x_p_r> 0 and 0 if _E_x_p_r= 0. If _E_x_p_r
evaluates to a float, the return value is a float (e.g., -1.0, 0.0
or 1.0). In particular, note that sign(-0.0) evaluates to 0.0.
See also copysign/1
ccooppyyssiiggnn((_+_E_x_p_r_1_, _+_E_x_p_r_2)) _[_I_S_O_]
Evaluate to _X, where the absolute value of _X equals the absolute
value of _E_x_p_r_1 and the sign of _X matches the sign of _E_x_p_r_2.
This function is based on copysign() from C99, which works on
double precision floats and deals with handling the sign of special
floating point values such as -0.0. Our implementation follows C99
if both arguments are floats. Otherwise, copysign/1 evaluates to
_E_x_p_r_1 if the sign of both expressions matches or -_E_x_p_r_1 if the
signs do not match. Here, we use the extended notion of signs for
floating point numbers, where the sign of -0.0 and other special
floats is negative.
mmaaxx((_+_E_x_p_r_1_, _+_E_x_p_r_2)) _[_I_S_O_]
Evaluate to the larger of _E_x_p_r_1 and _E_x_p_r_2. Both arguments are
compared after converting to the same type, but the return value is
in the original type. For example, max(2.5, 3) compares the two
values after converting to float, but returns the integer 3.
mmiinn((_+_E_x_p_r_1_, _+_E_x_p_r_2)) _[_I_S_O_]
Evaluate to the smaller of _E_x_p_r_1 and _E_x_p_r_2. See max/2 for a
description of type handling.
.((_+_I_n_t_, _[_]))
A list of one element evaluates to the element. This implies "a"
evaluates to the character code of the letter `a' (97) using the
traditional mapping of double quoted string to a list of character
codes. Arithmetic evaluation also translates a string object (see
section 4.24) of one character length into the character code for
that character. This implies that expression "a" also works of the
Prolog flag double_quotesis set to string. The recommended way to
specify the character code of the letter `a' is 0'a.
rraannddoomm((_+_I_n_t_E_x_p_r))
Evaluate to a random integer _i for which 0=< i< _I_n_t_E_x_p_r. The
system has two implementations. If it is compiled with support
for unbounded arithmetic (default) it uses the GMP library random
functions. In this case, each thread keeps its own random state.
The default algorithm is the _M_e_r_s_e_n_n_e _T_w_i_s_t_e_r algorithm. The seed
is set when the first random number in a thread is generated. If
available, it is set from /dev/random. Otherwise it is set from
the system clock. If unbounded arithmetic is not supported, random
numbers are shared between threads and the seed is initialised from
the clock when SWI-Prolog was started. The predicate set_random/1
can be used to control the random number generator.
rraannddoomm__ffllooaatt
Evaluate to a random float I for which 0:0 <i <1:0. This function
shares the random state with random/1. All remarks with the
function random/1 also apply for random_float/0. Note that both
sides of the domain are _o_p_e_n. This avoids evaluation errors on,
e.g., log/1 or //2 while no practical application can expect 0.0.
rroouunndd((_+_E_x_p_r)) _[_I_S_O_]
Evaluate _E_x_p_r and round the result to the nearest integer.
iinntteeggeerr((_+_E_x_p_r))
Same as round/1 (backward compatibility).
ffllooaatt((_+_E_x_p_r)) _[_I_S_O_]
Translate the result to a floating point number. Normally, Prolog
will use integers whenever possible. When used around the 2nd
argument of is/2, the result will be returned as a floating point
number. In other contexts, the operation has no effect.
rraattiioonnaall((_+_E_x_p_r))
Convert the _E_x_p_r to a rational number or integer. The function
returns the input on integers and rational numbers. For floating
point numbers, the returned rational number _e_x_a_c_t_l_y represents the
float. As floats cannot exactly represent all decimal numbers
the results may be surprising. In the examples below, doubles
can represent 0.25 and the result is as expected, in contrast to
the result of rational(_0_._1). The function rationalize/1 remedies
this. See section 4.27.2.2 for more information on rational number
support.
____________________________________________________________________| |
| ?- A is rational(0.25). |
| |
| A is 1 rdiv 4 |
| ?- A is rational(0.1). |
||A_=_3602879701896397_rdiv_36028797018963968_______________________ ||
rraattiioonnaalliizzee((_+_E_x_p_r))
Convert the _E_x_p_r to a rational number or integer. The function
is similar to rational/1, but the result is only accurate within
the rounding error of floating point numbers, generally producing a
much smaller denominator.
____________________________________________________________________| |
| ?- A is rationalize(0.25). |
| |
| A = 1 rdiv 4 |
| ?- A is rationalize(0.1). |
| |
||A_=_1_rdiv_10_____________________________________________________ ||
ffllooaatt__ffrraaccttiioonnaall__ppaarrtt((_+_E_x_p_r)) _[_I_S_O_]
Fractional part of a floating point number. Negative if
_E_x_p_r is negative, rational if _E_x_p_r is rational and 0 if
_E_x_p_r is integer. The following relation is always true:
Xisfloatfractionalpart(X)+ floatintegerpart(X).
ffllooaatt__iinntteeggeerr__ppaarrtt((_+_E_x_p_r)) _[_I_S_O_]
Integer part of floating point number. Negative if _E_x_p_r is
negative, _E_x_p_r if _E_x_p_r is integer.
ttrruunnccaattee((_+_E_x_p_r)) _[_I_S_O_]
Truncate _E_x_p_r to an integer. If _E_x_p_r>= 0 this is the same as
floor(_E_x_p_r). For _E_x_p_r <0 this is the same as ceil(_E_x_p_r). That is,
truncate/1 rounds towards zero.
fflloooorr((_+_E_x_p_r)) _[_I_S_O_]
Evaluate _E_x_p_r and return the largest integer smaller or equal to
the result of the evaluation.
cceeiilliinngg((_+_E_x_p_r)) _[_I_S_O_]
Evaluate _E_x_p_r and return the smallest integer larger or equal to
the result of the evaluation.
cceeiill((_+_E_x_p_r))
Same as ceiling/1 (backward compatibility).
_+_I_n_t_E_x_p_r_1 >> _+_I_n_t_E_x_p_r_2 _[_I_S_O_]
Bitwise shift _I_n_t_E_x_p_r_1 by _I_n_t_E_x_p_r_2 bits to the right. The
operation performs _a_r_i_t_h_m_e_t_i_c _s_h_i_f_t, which implies that the
inserted most significant bits are copies of the original most
significant bits.
_+_I_n_t_E_x_p_r_1 << _+_I_n_t_E_x_p_r_2 _[_I_S_O_]
Bitwise shift _I_n_t_E_x_p_r_1 by _I_n_t_E_x_p_r_2 bits to the left.
_+_I_n_t_E_x_p_r_1 \/ _+_I_n_t_E_x_p_r_2 _[_I_S_O_]
Bitwise `or' _I_n_t_E_x_p_r_1 and _I_n_t_E_x_p_r_2.
_+_I_n_t_E_x_p_r_1 /\ _+_I_n_t_E_x_p_r_2 _[_I_S_O_]
Bitwise `and' _I_n_t_E_x_p_r_1 and _I_n_t_E_x_p_r_2.
_+_I_n_t_E_x_p_r_1 xxoorr _+_I_n_t_E_x_p_r_2 _[_I_S_O_]
Bitwise `exclusive or' _I_n_t_E_x_p_r_1 and _I_n_t_E_x_p_r_2.
\ _+_I_n_t_E_x_p_r _[_I_S_O_]
Bitwise negation. The returned value is the one's complement of
_I_n_t_E_x_p_r.
ssqqrrtt((_+_E_x_p_r)) _[_I_S_O_]
_R_e_s_u_l_t =square root of _E_x_p_r
ssiinn((_+_E_x_p_r)) _[_I_S_O_]
_R_e_s_u_l_t =sine of _E_x_p_r. _E_x_p_r is the angle in radians.
ccooss((_+_E_x_p_r)) _[_I_S_O_]
_R_e_s_u_l_t =cosine of _E_x_p_r. _E_x_p_r is the angle in radians.
ttaann((_+_E_x_p_r)) _[_I_S_O_]
_R_e_s_u_l_t =tangus of _E_x_p_r. _E_x_p_r is the angle in radians.
aassiinn((_+_E_x_p_r)) _[_I_S_O_]
_R_e_s_u_l_t =inverse sine of _E_x_p_r. _R_e_s_u_l_t is the angle in radians.
aaccooss((_+_E_x_p_r)) _[_I_S_O_]
_R_e_s_u_l_t =inverse cosine of _E_x_p_r. _R_e_s_u_l_t is the angle in radians.
aattaann((_+_E_x_p_r)) _[_I_S_O_]
_R_e_s_u_l_t =inverse tangus of _E_x_p_r. _R_e_s_u_l_t is the angle in radians.
aattaann22((_+_Y_E_x_p_r_, _+_X_E_x_p_r)) _[_I_S_O_]
_R_e_s_u_l_t = inverse tangus of _Y_E_x_p_r / _X_E_x_p_r. _R_e_s_u_l_t is the angle in
radians. The return value is in the range [-pi:::pi]. Used to
convert between rectangular and polar coordinate system.
aattaann((_+_Y_E_x_p_r_, _+_X_E_x_p_r))
Same as atan2/2 (backward compatibility).
ssiinnhh((_+_E_x_p_r))
_R_e_s_u_l_t = sinh_E_x_p_r. The hyperbolic sine of X is defined as
e to the power X -e to the power -X=2.
ccoosshh((_+_E_x_p_r))
_R_e_s_u_l_t = cosh_E_x_p_r. The hyperbolic cosine of X is defined as
e to the power X +e to the power -X=2.
ttaannhh((_+_E_x_p_r))
_R_e_s_u_l_t = tanh_E_x_p_r. The hyperbolic tangent of X is defined as
sinhX=coshX.
aassiinnhh((_+_E_x_p_r))
_R_e_s_u_l_t =arcsinh(_E_x_p_r) (inverse hyperbolic sine).
aaccoosshh((_+_E_x_p_r))
_R_e_s_u_l_t =arccosh(_E_x_p_r) (inverse hyperbolic cosine).
aattaannhh((_+_E_x_p_r))
_R_e_s_u_l_t =arctanh(_E_x_p_r). (inverse hyperbolic tangent).
lloogg((_+_E_x_p_r)) _[_I_S_O_]
Natural logarithm. _R_e_s_u_l_t =natural logarithm of _E_x_p_r
lloogg1100((_+_E_x_p_r))
Base-10 logarithm. _R_e_s_u_l_t =10 base logarithm of _E_x_p_r
eexxpp((_+_E_x_p_r)) _[_I_S_O_]
_R_e_s_u_l_t =e to the power _E_x_p_r
_+_E_x_p_r_1 ** _+_E_x_p_r_2 _[_I_S_O_]
_R_e_s_u_l_t = _E_x_p_r_1 to the power _E_x_p_r_2. The result is a float, unless
SWI-Prolog is compiled with unbounded integer support and the
inputs are integers and produce an integer result. The integer ex-
pressions 0 to the power I, 1 to the power I and -1 to the power I
are guaranteed to work for any integer I. Other integer base
values generate a resource error if the result does not fit in
memory.
The ISO standard demands a float result for all inputs and
introduces ^/2 for integer exponentiation. The function float/1
can be used on one or both arguments to force a floating point
result. Note that casting the _i_n_p_u_t result in a floating
point computation, while casting the _o_u_t_p_u_t performs integer
exponentiation followed by a conversion to float.
_+_E_x_p_r_1 ^ _+_E_x_p_r_2 _[_I_S_O_]
In SWI-Prolog, ^/2 is equivalent to **/2. The ISO version is
similar, except that it produces a evaluation error if both _E_x_p_r_1
and _E_x_p_r_2 are integers and the result is not an integer. The table
below illustrates the behaviour of the exponentiation functions in
ISO and SWI.
_____________________________________________________
|__E_x_p_r_1__E_x_p_r_2__|Function_|SWI__________|ISO__________|_
| Int Int |**/2 |Int or Float |Float |
| Int Float |**/2 |Float |Float |
| Float Int |**/2 |Float |Float |
|_Float_Float_|**/2_____|Float________|Float________|_
| Int Int |^/2 |Int or Float |Int or error |
| Int Float |^/2 |Float |Float |
| Float Int |^/2 |Float |Float |
|_Float_Float_|^/2______|Float________|Float________|_
ppoowwmm((_+_I_n_t_E_x_p_r_B_a_s_e_, _+_I_n_t_E_x_p_r_E_x_p_, _+_I_n_t_E_x_p_r_M_o_d))
_R_e_s_u_l_t = (_I_n_t_E_x_p_r_B_a_s_e to the power _I_n_t_E_x_p_r_E_x_p) modulo _I_n_t_E_x_p_r_M_o_d.
Only available when compiled with unbounded integer support. This
formula is required for Diffie-Hellman key-exchange, a technique
where two parties can establish a secret key over a public network.
llggaammmmaa((_+_E_x_p_r))
Return the natural logarithm of the absolute value of the Gamma
function.
eerrff((_+_E_x_p_r))
WikipediA: ``In mathematics, the error function (also called the
Gauss error function) is a special function (non-elementary) of
sigmoid shape which occurs in probability, statistics and partial
differential equations.''
eerrffcc((_+_E_x_p_r))
WikipediA: ``The complementary error function.''
ppii _[_I_S_O_]
Evaluate to the mathematical constant pi (3.14159...).
ee
Evaluate to the mathematical constant e (2.71828...).
eeppssiilloonn
Evaluate to the difference between the float 1.0 and the first
larger floating point number.
ccppuuttiimmee
Evaluate to a floating point number expressing the cpu time (in
seconds) used by Prolog up till now. See also statistics/2 and
time/1.
eevvaall((_+_E_x_p_r))
Evaluate _E_x_p_r. Although ISO standard dictates that `A=1+2, B is
A' works and unifies B to 3, it is widely felt that source level
variables in arithmetic expressions should have been limited to
numbers. In this view the eval function can be used to evaluate
arbitrary expressions.
BBiittvveeccttoorr ffuunnccttiioonnss
The functions below are not covered by the standard. The msb/1
function is compatible with hProlog. The others are private extensions
that improve handling of ---unbounded--- integers as bit-vectors.
mmssbb((_+_I_n_t_E_x_p_r))
Return the largest integer N such that (IntExpr >> N) /\ 1 =:= 1.
This is the (zero-origin) index of the most significant 1 bit in
the value of _I_n_t_E_x_p_r, which must evaluate to a positive integer.
Errors for 0, negative integers, and non-integers.
llssbb((_+_I_n_t_E_x_p_r))
Return the smallest integer N such that (IntExpr >> N) /\ 1 =:= 1.
This is the (zero-origin) index of the least significant 1 bit in
the value of _I_n_t_E_x_p_r, which must evaluate to a positive integer.
Errors for 0, negative integers, and non-integers.
ppooppccoouunntt((_+_I_n_t_E_x_p_r))
Return the number of 1s in the binary representation of the
non-negative integer _I_n_t_E_x_p_r.
44..2288 MMiisscc aarriitthhmmeettiicc ssuuppppoorrtt pprreeddiiccaatteess
sseett__rraannddoomm((_+_O_p_t_i_o_n))
Controls the random number generator accessible through the
_f_u_n_c_t_i_o_n_s random/1 and random_float/0. Note that the library
random provides an alternative API to the same random primitives.
sseeeedd((_+_S_e_e_d))
Set the seed of the random generator for this thread. _S_e_e_d
is an integer or the atom random. If random, repeat the
initialization procedure described with the function random/1.
Here is an example:
_______________________________________________________________| |
|?- set_random(seed(111)), A is random(6). |
|A = 5. |
|?- set_random(seed(111)), A is random(6). |
|A|=_5.________________________________________________________ | |
ssttaattee((_+_S_t_a_t_e))
Set the generator to a state fetched using the state property
of random_property/1. Using other values may lead to undefined
behaviour.
rraannddoomm__pprrooppeerrttyy((_?_O_p_t_i_o_n))
True when _O_p_t_i_o_n is a current property of the random generator.
Currently, this predicate provides access to the state. This
predicate is not present on systems where the state is
inaccessible.
ssttaattee((_-_S_t_a_t_e))
Describes the current state of the random generator. State
is a normal Prolog term that can be asserted or written to a
file. Applications should make no other assumptions about its
representation. The only meaningful operation is to use as
argument to set_random/1 using the state(_S_t_a_t_e) option.
ccuurrrreenntt__aarriitthhmmeettiicc__ffuunnccttiioonn((_?_H_e_a_d))
True when _H_e_a_d is an evaluable function. For example:
____________________________________________________________________| |
| ?- current_arithmetic_function(sin(_)). |
||true._____________________________________________________________ ||
44..2299 BBuuiilltt--iinn lliisstt ooppeerraattiioonnss
Most list operations are defined in the library lists described
in section 11.12. Some that are implemented with more low-level
primitives are built-in and described here.
iiss__lliisstt((_+_T_e_r_m))
True if _T_e_r_m is bound to the empty list ([]) or a term with functor
`.' and arity 2 and the second argument is a list. This predicate
acts as if defined by the definition below on _a_c_y_c_l_i_c terms. The
implementation _f_a_i_l_s safely if _T_e_r_m represents a cyclic list.
____________________________________________________________________| |
| is_list(X) :- |
| var(X), !, |
| fail. |
| is_list([]). |
| is_list([_|T]) :- |
||________is_list(T)._______________________________________________ ||
mmeemmbbeerrcchhkk((_?_E_l_e_m_, _+_L_i_s_t)) _[_]
True when _E_l_e_m is an element of _L_i_s_t. This `chk' variant
of member/2 is semi deterministic and typically used to test
membership of a list. Raises a type error if scanning _L_i_s_t
encounters a non-list. Note that memberchk/2 does _n_o_t perform a
full list typecheck. For example, memberchk(a, [a|b]) succeeds
without error and memberchk/2 loops on a cyclic list if _E_l_e_m is not
a member of _L_i_s_t.
lleennggtthh((_?_L_i_s_t_, _?_I_n_t)) _[_I_S_O_]
True if _I_n_t represents the number of elements in _L_i_s_t. This
predicate is a true relation and can be used to find the length
of a list or produce a list (holding variables) of length _I_n_t.
The predicate is non-deterministic, producing lists of increasing
length if _L_i_s_t is a _p_a_r_t_i_a_l _l_i_s_t and _I_n_t is unbound. It raises
errors if
o _I_n_t is bound to a non-integer.
o _I_n_t is a negative integer.
o _L_i_s_t is neither a list nor a partial list. This error
condition includes cyclic lists.
This predicate fails if the tail of _L_i_s_t is equivalent to _I_n_t
(e.g., length(L,L)).
ssoorrtt((_+_L_i_s_t_, _-_S_o_r_t_e_d)) _[_I_S_O_]
True if _S_o_r_t_e_d can be unified with a list holding the elements of
_L_i_s_t, sorted to the standard order of terms (see section 4.7).
Duplicates are removed. The implementation is in C, using _n_a_t_u_r_a_l
_m_e_r_g_e _s_o_r_t. The sort/2 predicate can sort a cyclic list, returning
a non-cyclic version with the same elements.
mmssoorrtt((_+_L_i_s_t_, _-_S_o_r_t_e_d))
Equivalent to sort/2, but does not remove duplicates. Raises a
type_error if _L_i_s_t is a cyclic list or not a list.
kkeeyyssoorrtt((_+_L_i_s_t_, _-_S_o_r_t_e_d)) _[_I_S_O_]
Sort a list of _p_a_i_r_s. _L_i_s_t must be a list of _K_e_y-_V_a_l_u_e pairs,
terms whose principal functor is (-)/2. _L_i_s_t is sorted on _K_e_y
according to the standard order of terms (see section 4.7.1).
Duplicates are _n_o_t removed. Sorting is _s_t_a_b_l_e with regard to the
order of the _V_a_l_u_e_s, i.e., the order of multiple elements that have
the same _K_e_y is not changed.
The keysort/2 predicate is often used together with library pairs.
It can be used to sort lists on different or multiple criteria.
For example, the following predicates sorts a list of atoms
according to their length, maintaining the initial order for atoms
that have the same length.
____________________________________________________________________| |
| :- use_module(library(pairs)). |
| |
| sort_atoms_by_length(Atoms, ByLength) :- |
| map_list_to_pairs(atom_length, Atoms, Pairs), |
| keysort(Pairs, Sorted), |
||________pairs_values(Sorted,_ByLength).___________________________ ||
pprreeddssoorrtt((_+_P_r_e_d_, _+_L_i_s_t_, _-_S_o_r_t_e_d))
Sorts similar to sort/2, but determines the order of two terms by
calling _P_r_e_d(-_D_e_l_t_a, +_E_1, +_E_2). This call must unify _D_e_l_t_a with
one of <, > or =. If the built-in predicate compare/3 is used, the
result is the same as sort/2. See also keysort/2.
44..3300 FFiinnddiinngg aallll SSoolluuttiioonnss ttoo aa GGooaall
ffiinnddaallll((_+_T_e_m_p_l_a_t_e_, _:_G_o_a_l_, _-_B_a_g)) _[_I_S_O_]
Create a list of the instantiations _T_e_m_p_l_a_t_e gets successively on
backtracking over _G_o_a_l and unify the result with _B_a_g. Succeeds
with an empty list if _G_o_a_l has no solutions. findall/3 is
equivalent to bagof/3 with all free variables bound with the
existential operator (^), except that bagof/3 fails when _G_o_a_l has
no solutions.
ffiinnddaallll((_+_T_e_m_p_l_a_t_e_, _:_G_o_a_l_, _-_B_a_g_, _+_T_a_i_l))
As findall/3, but returns the result as the difference list
_B_a_g-_T_a_i_l. The 3-argument version is defined as
____________________________________________________________________| |
| findall(Templ, Goal, Bag) :- |
||________findall(Templ,_Goal,_Bag,_[])_____________________________ ||
bbaaggooff((_+_T_e_m_p_l_a_t_e_, _:_G_o_a_l_, _-_B_a_g)) _[_I_S_O_]
Unify _B_a_g with the alternatives of _T_e_m_p_l_a_t_e. If _G_o_a_l has free
variables besides the one sharing with _T_e_m_p_l_a_t_e, bagof/3 will
backtrack over the alternatives of these free variables, unifying
_B_a_g with the corresponding alternatives of _T_e_m_p_l_a_t_e. The construct
+_V_a_r^_G_o_a_l tells bagof/3 not to bind _V_a_r in _G_o_a_l. bagof/3 fails if
_G_o_a_l has no solutions.
The example below illustrates bagof/3 and the ^ operator. The
variable bindings are printed together on one line to save paper.
____________________________________________________________________| |
| 2 ?- listing(foo). |
| foo(a, b, c). |
| foo(a, b, d). |
| foo(b, c, e). |
| foo(b, c, f). |
| foo(c, c, g). |
| true. |
| |
| 3 ?- bagof(C, foo(A, B, C), Cs). |
| A = a, B = b, C = G308, Cs = [c, d] ; |
| A = b, B = c, C = G308, Cs = [e, f] ; |
| A = c, B = c, C = G308, Cs = [g]. |
| |
| 4 ?- bagof(C, A^foo(A, B, C), Cs). |
| A = G324, B = b, C = G326, Cs = [c, d] ; |
| A = G324, B = c, C = G326, Cs = [e, f, g]. |
| |
||5_?-______________________________________________________________ ||
sseettooff((_+_T_e_m_p_l_a_t_e_, _+_G_o_a_l_, _-_S_e_t)) _[_I_S_O_]
Equivalent to bagof/3, but sorts the result using sort/2 to get a
sorted list of alternatives without duplicates.
44..3311 FFoorraallll
ffoorraallll((_:_C_o_n_d_, _:_A_c_t_i_o_n)) _[_s_e_m_i_d_e_t_]
For all alternative bindings of _C_o_n_d, _A_c_t_i_o_n can be proven. The
example verifies that all arithmetic statements in the given list
are correct. It does not say which is wrong if one proves wrong.
____________________________________________________________________| |
| ?- forall(member(Result = Formula, [2 = 1 + 1, 4 = 2 * 2]), |
||_________________Result_=:=_Formula)._____________________________ ||
The predicate forall/2 is implemented as \+ ( Cond, \+ Action),
i.e., _T_h_e_r_e _i_s _n_o _i_n_s_t_a_n_t_i_a_t_i_o_n _o_f _C_o_n_d _f_o_r _w_h_i_c_h _A_c_t_i_o_n _i_s _f_a_l_s_e_..
The use of double negation implies that forall/2 _d_o_e_s _n_o_t _c_h_a_n_g_e
_a_n_y _v_a_r_i_a_b_l_e _b_i_n_d_i_n_g_s. It proves a relation. The forall/2 control
structure can be used for its side-effects. E.g., the following
asserts relations in a list into the dynamic database:
____________________________________________________________________| |
| ?- forall(member(Child-Parent), ChildPairs), |
||__________assertz(child_of(Child,_Parent))).______________________ ||
Using forall/2 as forall(_G_e_n_e_r_a_t_o_r_, _S_i_d_e_E_f_f_e_c_t) is preferred over
the classical _f_a_i_l_u_r_e _d_r_i_v_e_n _l_o_o_p as shown below because it makes
it explicit which part of the construct is the generator and which
part creates the side effects. Also, unexpected failure of the
side effect causes the construct to fail. Failure makes it evident
that there is an issue with the code, while a failure driven loop
would succeed with an erroneous result.
____________________________________________________________________| |
| ..., |
| ( Generator, |
| SideEffect, |
| fail |
| ; true |
||________)_________________________________________________________ ||
If your intent is to create variable bindings, the forall/2 control
structure is inadequate. Possibly you are looking for maplist/2,
findall/3 or foreach/2.
44..3322 FFoorrmmaatttteedd WWrriittee
The current version of SWI-Prolog provides two formatted write
predicates. The `writef' family (writef/1, writef/2, swritef/3), is
compatible with Edinburgh C-Prolog and should be considered _d_e_p_r_e_c_a_t_e_d.
The `format' family (format/1, format/2, format/3), was defined by
Quintus Prolog and currently available in many Prolog systems, although
the details vary.
44..3322..11 WWrriitteeff
wwrriitteeff((_+_A_t_o_m)) _[_d_e_p_r_e_c_a_t_e_d_]
Equivalent to writef(Atom, []). See writef/2 for details.
wwrriitteeff((_+_F_o_r_m_a_t_, _+_A_r_g_u_m_e_n_t_s)) _[_d_e_p_r_e_c_a_t_e_d_]
Formatted write. _F_o_r_m_a_t is an atom whose characters will be
printed. _F_o_r_m_a_t may contain certain special character sequences
which specify certain formatting and substitution actions.
_A_r_g_u_m_e_n_t_s provides all the terms required to be output.
Escape sequences to generate a single special character:
__________________________________________________
| \n |Output a newline character (see also |
| |nl/[0,1]) |
| \l |Output a line separator (same as \n) |
| \r |Output a carriage return character |
| |(ASCII 13) |
| \t |Output the ASCII character TAB (9) |
| \\ |The character \ is output |
| \% |The character % is output |
| \nnn |where <_n_n_n> is an integer (1-3 digits); |
| |the character with code <_n_n_n> is output |
|______|(NB_:_<_n_n_n>_is_read_as_ddeecciimmaall)___________|
Note that \l, \nnn and \\ are interpreted differently when
character escapes are in effect. See section 2.15.1.2.
Escape sequences to include arguments from _A_r_g_u_m_e_n_t_s. Each time
a % escape sequence is found in _F_o_r_m_a_t the next argument from
_A_r_g_u_m_e_n_t_s is formatted according to the specification.
_________________________________________________%t
| %w print/1 the next item (mnemonic: term) | |
| %q |write/1the next item |
| |writeq/1the next item |
| %d |Write the term, ignoring operators. See|
| |also write_term/2. Mnemonic: old|
| %p |Edinburgh display/1 |
| |print/1the next item (identical to %t) |
| %n |Put the next item as a character (i.e.,|
| |it is a character code) |
| %r |Write the next item N times where N is|
| |the second item (an integer) |
| %s |Write the next item as a String (so it|
| |must be a list of characters) |
| %f |Perform a ttyflush/0 (no items used) |
| %Nc |Write the next item Centered in N |
| |columns |
| %Nl |Write the next item Left justified in N |
| |columns |
| %Nr |Write the next item Right justified in N |
| |columns. N is a decimal number with at|
| |least one digit. The item must be an|
|_____|atom,_integer,_float_or_string.__________|_
sswwrriitteeff((_-_S_t_r_i_n_g_, _+_F_o_r_m_a_t_, _+_A_r_g_u_m_e_n_t_s)) _[_d_e_p_r_e_c_a_t_e_d_]
Equivalent to writef/2, but ``writes'' the result on _S_t_r_i_n_g instead
of the current output stream. Example:
____________________________________________________________________| |
| ?- swritef(S, '%15L%w', ['Hello', 'World']). |
| |
||S_=_"Hello__________World"________________________________________ ||
sswwrriitteeff((_-_S_t_r_i_n_g_, _+_F_o_r_m_a_t)) _[_d_e_p_r_e_c_a_t_e_d_]
Equivalent to swritef(String, Format, []).
44..3322..22 FFoorrmmaatt
The format family of predicates is the most versatile and portable way
to produce textual output.
ffoorrmmaatt((_+_F_o_r_m_a_t))
Defined as `format(Format) :- format(Format, []).'. See format/2
for details.
ffoorrmmaatt((_+_F_o_r_m_a_t_, _:_A_r_g_u_m_e_n_t_s))
_F_o_r_m_a_t is an atom, list of character codes, or a Prolog string.
_A_r_g_u_m_e_n_t_s provides the arguments required by the format
specification. If only one argument is required and this single
argument is not a list, the argument need not be put in a list.
Otherwise the arguments are put in a list.
Special sequences start with the tilde (~), followed by an optional
numeric argument, optionally followed by a colon modifier (:),
followed by a character describing the action to be undertaken. A
numeric argument is either a sequence of digits, representing a
positive decimal number, a sequence `<_c_h_a_r_a_c_t_e_r>, representing the
character code value of the character (only useful for ~t) or a
asterisk (*), in which case the numeric argument is taken from the
next argument of the argument list, which should be a positive
integer. E.g., the following three examples all pass 46 (.) to ~t:
____________________________________________________________________| |
| ?- format('~w ~46t ~w~72|~n', ['Title', 'Page']). |
| ?- format('~w ~`.t ~w~72|~n', ['Title', 'Page']). |
||?-_format('~w_~*t_~w~72|~n',_['Title',_46,_'Page']).______________ ||
Numeric conversion (d, D, e, E, f, g and G) accept an arithmetic
expression as argument. This is introduced to handle rational
numbers transparently (see section 4.27.2.2). The floating point
conversions allow for unlimited precision for printing rational
numbers in decimal form. E.g., the following will write as many
3's as you want by changing the `70'.
____________________________________________________________________| |
| ?- format('~50f', [10 rdiv 3]). |
||3.33333333333333333333333333333333333333333333333333______________ ||
~ Output the tilde itself.
a Output the next argument, which must be an atom. This option
is equivalent to ww, except that it requires the argument to be
an atom.
c Interpret the next argument as a character code and add it to
the output. This argument must be a valid Unicode character
code. Note that the actually emitted bytes are defined by the
character encoding of the output stream and an exception may
be raised if the output stream is not capable of representing
the requested Unicode character. See section 2.18.1 for
details.
d Output next argument as a decimal number. It should be
an integer. If a numeric argument is specified, a dot is
inserted _a_r_g_u_m_e_n_t positions from the right (useful for doing
fixed point arithmetic with integers, such as handling amounts
of money).
The colon modifier (e.g., ~:d) causes the number to be
printed according to the locale of the output stream. See
section 4.22.
D Same as dd, but makes large values easier to read by inserting
a comma every three digits left or right of the dot. This is
the same as ~:d, but using the fixed English locale.
e Output next argument as a floating point number in exponential
notation. The numeric argument specifies the precision.
Default is 6 digits. Exact representation depends on the C
library function printf(). This function is invoked with the
format %.<_p_r_e_c_i_s_i_o_n>e.
E Equivalent to ee, but outputs a capital E to indicate the
exponent.
f Floating point in non-exponential notation. The numeric
argument defines the number of digits right of the decimal
point. If the colon modifier (:) is used, the float is
formatted using conventions from the current locale, which may
define the decimal point as well as grouping of digits left of
the decimal point.
g Floating point in ee or ff notation, whichever is shorter.
G Floating point in EE or ff notation, whichever is shorter.
i Ignore next argument of the argument list. Produces no
output.
I Emit a decimal number using Prolog digit grouping (the
underscore, _). The argument describes the size of each digit
group. The default is 3. See also section 2.15.1.4. For
example:
_______________________________________________________________| |
|?- A is 1<<100, format('~10I', [A]). |
|1_2676506002_2822940149_6703205376|___________________________ | |
k Give the next argument to write_canonical/1.
n Output a newline character.
N Only output a newline if the last character output on this
stream was not a newline. Not properly implemented yet.
p Give the next argument to print/1.
q Give the next argument to writeq/1.
r Print integer in radix numeric argument notation. Thus ~16r
prints its argument hexadecimal. The argument should be in
the range [2;:::;36]. Lowercase letters are used for digits above
9. The colon modifier may be used to form locale-specific
digit groups.
R Same as rr, but uses uppercase letters for digits above 9.
s Output text from a list of character codes or a string (see
string/1 and section 4.24) from the next argument.
@ Interpret the next argument as a goal and execute it. Output
written to the current_output stream is inserted at this place.
Goal is called in the module calling format/3. This option
is not present in the original definition by Quintus, but
supported by some other Prolog systems.
t All remaining space between 2 tab stops is distributed equally
over ~t statements between the tab stops. This space is
padded with spaces by default. If an argument is supplied, it
is taken to be the character code of the character used for
padding. This can be used to do left or right alignment,
centering, distributing, etc. See also ~| and ~+ to set tab
stops. A tab stop is assumed at the start of each line.
| Set a tab stop on the current position. If an argument is
supplied set a tab stop on the position of that argument.
This will cause all ~t's to be distributed between the
previous and this tab stop.
+ Set a tab stop (as ~|) relative to the last tab stop or
the beginning of the line if no tab stops are set before
the ~+. This constructs can be used to fill fields. The
partial format sequence below prints an integer right-aligned
and padded with zeros in 6 columns. The ... sequences in the
example illustrate that the integer is aligned in 6 columns
regardless of the remainder of the format specification.
_______________________________________________________________| |
||_______format('...~|~`0t~d~6+...',_[...,_Integer,_...])______ ||
w Give the next argument to write/1.
W Give the next two arguments to write_term/2. For example,
format('~W', [Term, [numbervars(true)]]). This option is
SWI-Prolog specific.
Example:
____________________________________________________________________| |
| simple_statistics :- |
| <obtain statistics> % left to the user |
| format('~tStatistics~t~72|~n~n'), |
| format('Runtime: ~`.t ~2f~34| Inferences: ~`.t ~D~72|~n', |
| [RunT, Inf]), |
||____....__________________________________________________________ ||
will output
____________________________________________________________________| |
| Statistics |
| |
||Runtime:_.................._3.45__Inferences:_.........._60,345___ ||
ffoorrmmaatt((_+_O_u_t_p_u_t_, _+_F_o_r_m_a_t_, _:_A_r_g_u_m_e_n_t_s))
As format/2, but write the output on the given _O_u_t_p_u_t. The de-
facto standard only allows _O_u_t_p_u_t to be a stream. The SWI-Prolog
implementation allows all valid arguments for with_output_to/2.
For example:
____________________________________________________________________| |
| ?- format(atom(A), '~D', [1000000]). |
||A_=_'1,000,000'___________________________________________________ ||
44..3322..33 PPrrooggrraammmmiinngg FFoorrmmaatt
ffoorrmmaatt__pprreeddiiccaattee((_+_C_h_a_r_, _+_H_e_a_d))
If a sequence ~c (tilde, followed by some character) is found, the
format/3 and friends first check whether the user has defined a
predicate to handle the format. If not, the built-in formatting
rules described above are used. _C_h_a_r is either a character code
or a one-character atom, specifying the letter to be (re)defined.
_H_e_a_d is a term, whose name and arity are used to determine the
predicate to call for the redefined formatting character. The
first argument to the predicate is the numeric argument of the
format command, or the atom default if no argument is specified.
The remaining arguments are filled from the argument list. The
example below defines ~T to print a timestamp in ISO8601 format
(see format_time/3). The subsequent block illustrates a possible
call.
____________________________________________________________________| |
| :- format_predicate('T', format_time(_Arg,_Time)). |
| |
| format_time(_Arg, Stamp) :- |
| must_be(number, Stamp), |
||________format_time(current_output,_'%FT%T%z',_Stamp).____________ ||
____________________________________________________________________| |
| ?- get_time(Now), |
| format('Now, it is ~T~n', [Now]). |
| Now, it is 2012-06-04T19:02:01+0200 |
||Now_=_1338829321.6620328._________________________________________ ||
ccuurrrreenntt__ffoorrmmaatt__pprreeddiiccaattee((_?_C_o_d_e_, _?_:_H_e_a_d))
True when ~_C_o_d_e is handled by the user-defined predicate specified
by _H_e_a_d.
44..3333 TTeerrmmiinnaall CCoonnttrrooll
The following predicates form a simple access mechanism to the
Unix termcap library to provide terminal-independent I/O for screen
terminals. These predicates are only available on Unix machines. The
SWI-Prolog Windows console accepts the ANSI escape sequences.
ttttyy__ggeett__ccaappaabbiilliittyy((_+_N_a_m_e_, _+_T_y_p_e_, _-_R_e_s_u_l_t))
Get the capability named _N_a_m_e from the termcap library. See
termcap(5) for the capability names. _T_y_p_e specifies the type of
the expected result, and is one of string, number or bool. String
results are returned as an atom, number results as an integer, and
bool results as the atom on or off. If an option cannot be found,
this predicate fails silently. The results are only computed once.
Successive queries on the same capability are fast.
ttttyy__ggoottoo((_+_X_, _+_Y))
Goto position (_X, _Y) on the screen. Note that the predicates
line_count/2 and line_position/2 will not have a well-defined
behaviour while using this predicate.
ttttyy__ppuutt((_+_A_t_o_m_, _+_L_i_n_e_s))
Put an atom via the termcap library function tputs(). This
function decodes padding information in the strings returned by
tty_get_capability/3 and should be used to output these strings.
_L_i_n_e_s is the number of lines affected by the operation, or 1 if not
applicable (as in almost all cases).
ttttyy__ssiizzee((_-_R_o_w_s_, _-_C_o_l_u_m_n_s))
Determine the size of the terminal. Platforms:
UUnniixx If the system provides _i_o_c_t_l calls for this, these are
used and tty_size/2 properly reflects the actual size after a
user resize of the window. As a fallback, the system uses
tty_get_capability/3 using li and co capabilities. In this
case the reported size reflects the size at the first call and
is not updated after a user-initiated resize of the terminal.
WWiinnddoowwss Getting the size of the terminal is provided for
swipl-win.exe. The requested value reflects the current size.
For the multithreaded version the console that is associated
with the user_input stream is used.
44..3344 OOppeerraattiinngg SSyysstteemm IInntteerraaccttiioonn
sshheellll((_+_C_o_m_m_a_n_d_, _-_S_t_a_t_u_s))
Execute _C_o_m_m_a_n_d on the operating system. _C_o_m_m_a_n_d is given to the
Bourne shell (/bin/sh). _S_t_a_t_u_s is unified with the exit status of
the command.
On Windows, shell/[1,2] executes the command using the
CreateProcess() API and waits for the command to terminate. If the
command ends with a & sign, the command is handed to the WinExec()
API, which does not wait for the new task to terminate. See also
win_exec/2 and win_shell/2. Please note that the CreateProcess()
API does nnoott imply the Windows command interpreter (cmd.exe and
therefore commands that are built in the command interpreter can
only be activated using the command interpreter. For example, a
file can be compied using the command below.
____________________________________________________________________| |
||?-_shell('cmd.exe_/C_copy_file1.txt_file2.txt').__________________ ||
Note that many of the operations that can be achieved using
the shell built-in commands can easily be achieved using Prolog
primitives. See make_directory/1, delete_file/1, rename_file/2,
etc. The clib package provides filesex, implementing various high
level file operations such as copy_file/2. Using Prolog primitives
instead of shell commands improves the portability of your program.
The library process provides process_create/3 and several related
primitives that support more fine-grained interaction with
processes, including I/O redirection and management of asynchronous
processes.
sshheellll((_+_C_o_m_m_a_n_d))
Equivalent to `shell(Command, 0)'.
sshheellll
Start an interactive Unix shell. Default is /bin/sh; the
environment variable SHELL overrides this default. Not available
for Win32 platforms.
ggeetteennvv((_+_N_a_m_e_, _-_V_a_l_u_e))
Get environment variable. Fails silently if the variable does
not exist. Please note that environment variable names are
case-sensitive on Unix systems and case-insensitive on Windows.
sseetteennvv((_+_N_a_m_e_, _+_V_a_l_u_e))
Set an environment variable. _N_a_m_e and _V_a_l_u_e must be instantiated
to atoms or integers. The environment variable will be passed
to shell/[0-2] and can be requested using getenv/2. They also
influence expand_file_name/2. Environment variables are shared
between threads. Depending on the underlying C library, setenv/2
and unsetenv/1 may not be thread-safe and may cause memory leaks.
Only changing the environment once and before starting threads is
safe in all versions of SWI-Prolog.
uunnsseetteennvv((_+_N_a_m_e))
Remove an environment variable from the environment. Some systems
lack the underlying unsetenv() library function. On these systems
unsetenv/1 sets the variable to the empty string.
sseettllooccaallee((_+_C_a_t_e_g_o_r_y_, _-_O_l_d_, _+_N_e_w))
Set/Query the _l_o_c_a_l_e setting which tells the C library how to
interpret text files, write numbers, dates, etc. Category is
one of all, collate, ctype, messages, monetary, numeric or time.
For details, please consult the C library locale documentation.
See also section 2.18.1. Please note that the locale is shared
between all threads and thread-safe usage of setlocale/3 is in
general not possible. Do locale operations before starting
threads or thoroughly study threading aspects of locale support
in your environment before using in multithreaded environments.
Locale settings are used by format_time/3, collation_key/2 and
locale_sort/2.
uunniixx((_+_C_o_m_m_a_n_d))
This predicate comes from the Quintus compatibility library and
provides a partial implementation thereof. It provides access to
some operating system features and unlike the name suggests, is not
operating system specific. Defined _C_o_m_m_a_n_d's are below.
ssyysstteemm((_+_C_o_m_m_a_n_d))
Equivalent to calling shell/1. Use for compatibility only.
sshheellll((_+_C_o_m_m_a_n_d))
Equivalent to calling shell/1. Use for compatibility only.
sshheellll
Equivalent to calling shell/0. Use for compatibility only.
ccdd
Equivalent to calling working_directory/2 to the expansion (see
expand_file_name/2) of ~. For compatibility only.
ccdd((_+_D_i_r_e_c_t_o_r_y))
Equivalent to calling working_directory/2. Use for compatibil-
ity only.
aarrggvv((_-_A_r_g_v))
Unify _A_r_g_v with the list of command line arguments provided to
this Prolog run. Please note that Prolog system arguments and
application arguments are separated by --. Integer arguments
are passed as Prolog integers, float arguments and Prolog
floating point numbers and all other arguments as Prolog
atoms. New applications should use the Prolog flag argv. See
also the Prolog flag argv.
A stand-alone program could use the following skeleton to
handle command line arguments. See also section 2.10.2.4.
_______________________________________________________________| |
|main :- |
| current_prolog_flag(argv, Argv), |
| append(_PrologArgs, [--|AppArgs], Argv), !, |
||_______main(AppArgs).________________________________________ ||
44..3344..11 WWiinnddoowwss--ssppeecciiffiicc OOppeerraattiinngg SSyysstteemm IInntteerraaccttiioonn
The predicates in this section are only available on the Windows
version of SWI-Prolog. Their use is discouraged if there are
portably alternatives. For example, win_exec/2 and will_shell/2 can
often be replaced by the more portable shell/2 or the more powerful
process_create/3.
wwiinn__eexxeecc((_+_C_o_m_m_a_n_d_, _+_S_h_o_w))
Windows only. Spawns a Windows task without waiting for its
completion. _S_h_o_w is one of the Win32 SW_* constants written
in lowercase without the SW_*: hide maximize minimize restore
show showdefault showmaximized showminimized showminnoactive showna
shownoactive shownormal. In addition, iconic is a synonym for
minimize and normal for shownormal.
wwiinn__sshheellll((_+_O_p_e_r_a_t_i_o_n_, _+_F_i_l_e_, _+_S_h_o_w))
Windows only. Opens the document _F_i_l_e using the Windows shell
rules for doing so. _O_p_e_r_a_t_i_o_n is one of open, print or explore or
another operation registered with the shell for the given document
type. On modern systems it is also possible to pass a URL as _F_i_l_e,
opening the URL in Windows default browser. This call interfaces
to the Win32 API ShellExecute(). The _S_h_o_w argument determines the
initial state of the opened window (if any). See win_exec/2 for
defined values.
wwiinn__sshheellll((_+_O_p_e_r_a_t_i_o_n_, _+_F_i_l_e))
Same as win_shell(_O_p_e_r_a_t_i_o_n_, _F_i_l_e_, _n_o_r_m_a_l)
wwiinn__rreeggiissttrryy__ggeett__vvaalluuee((_+_K_e_y_, _+_N_a_m_e_, _-_V_a_l_u_e))
Windows only. Fetches the value of a Windows registry key. _K_e_y
is an atom formed as a path name describing the desired registry
key. _N_a_m_e is the desired attribute name of the key. _V_a_l_u_e is
unified with the value. If the value is of type DWORD, the
value is returned as an integer. If the value is a string, it
is returned as a Prolog atom. Other types are currently not
supported. The default `root' is HKEY_CURRENT_USER. Other roots
can be specified explicitly as HKEY_CLASSES_ROOT, HKEY_CURRENT_USER,
HKEY_LOCAL_MACHINE or HKEY_USERS. The example below fetches the
extension to use for Prolog files (see README.TXT on the Windows
version):
____________________________________________________________________| |
| ?- win_registry_get_value( |
| 'HKEY_LOCAL_MACHINE/Software/SWI/Prolog', |
| fileExtension, |
| Ext). |
| |
||Ext_=_pl__________________________________________________________ ||
wwiinn__ffoollddeerr((_?_N_a_m_e_, _-_D_i_r_e_c_t_o_r_y))
True if _N_a_m_e is the Windows `CSIDL' of _D_i_r_e_c_t_o_r_y. If _N_a_m_e is
unbound, all known Windows special paths are generated. _N_a_m_e
is the CSIDL after deleting the leading CSIDL_ and mapping the
constant to lowercase. Check the Windows documentation for the
function SHGetSpecialFolderPath() for a description of the defined
constants. This example extracts the `My Documents' folder:
____________________________________________________________________| |
| ?- win_folder(personal, MyDocuments). |
| |
||MyDocuments_=_'C:/Documents_and_Settings/jan/My_Documents'________ ||
wwiinn__aadddd__ddllll__ddiirreeccttoorryy((_+_A_b_s_D_i_r))
This predicate adds a directory to the search path for de-
pendent DLL files. If possible, this is achieved with
win_add_dll_directory/2. Otherwise, %PATH% is extended with the
provided directory. _A_b_s_D_i_r may be specified in the Prolog
canonical syntax. See prolog_to_os_filename/2. Note that
use_foreign_library/1 passes an absolute path to the DLL if the
destination DLL can be located from the specification using
absolute_file_name/3.
wwiinn__aadddd__ddllll__ddiirreeccttoorryy((_+_A_b_s_D_i_r_, _-_C_o_o_k_i_e))
This predicate adds a directory to the search path for dependent
DLL files. If the call is successful it unifies _C_o_o_k_i_e with a
handle that must be passed to win_remove_dll_directory/1to remove
the directory from the search path. Error conditions:
o This predicate is available in the Windows port of SWI-Prolog
starting from 6.3.8/6.2.6.
o This predicate _f_a_i_l_s if Windows does not yet support the
underlying primitives. These are available in recently
patched Windows 7 systems and later.
o This predicate throws an acception if the provided path is
invalid or the underlying Windows API returns an error.
If open_shared_object/2 is passed an _a_b_s_o_l_u_t_e path to
a DLL on a Windows installation that supports Ad-
dDllDirectory() and friends, SWI-Prolog uses LoadLi-
braryEx() with the flags LOAD_LIBRARY_SEARCH_DLL_LOAD_DIR and
LOAD_LIBRARY_SEARCH_DEFAULT_DIRS. In this scenario, directories from
%PATH% and _n_o_t searched. Additional directories can be added using
win_add_dll_directory/2.
wwiinn__rreemmoovvee__ddllll__ddiirreeccttoorryy((_-_C_o_o_k_i_e))
Remove a DLL search directory installed using
win_add_dll_directory/2.
44..3344..22 DDeeaalliinngg wwiitthh ttiimmee aanndd ddaattee
Representing time in a computer system is surprisingly complicated.
There are a large number of time representations in use, and the
correct choice depends on factors such as compactness, resolution and
desired operations. Humans tend to think about time in hours, days,
months, years or centuries. Physicists think about time in seconds.
But, a month does not have a defined number of seconds. Even a day
does not have a defined number of seconds as sometimes a leap-second
is introduced to synchronise properly with our earth's rotation. At
the same time, resolution demands a range from better than pico-seconds
to millions of years. Finally, civilizations have a wide range of
calendars. Although there exist libraries dealing with most if this
complexity, our desire to keep Prolog clean and lean stops us from
fully supporting these.
For human-oriented tasks, time can be broken into years, months, days,
hours, minutes, seconds and a timezone. Physicists prefer to have
time in an arithmetic type representing seconds or fraction thereof, so
basic arithmetic deals with comparison and durations. An additional
advantage of the physicist's approach is that it requires much less
space. For these reasons, SWI-Prolog uses an arithmetic type as its
prime time representation.
Many C libraries deal with time using fixed-point arithmetic, dealing
with a large but finite time interval at constant resolution. In our
opinion, using a floating point number is a more natural choice as we
can use a natural unit and the interface does not need to be changed if
a higher resolution is required in the future. Our unit of choice is
the second as it is the scientific unit. We have placed our origin at
1970-1-1T0:0:0Z for compatibility with the POSIX notion of time as well
as with older time support provided by SWI-Prolog.
Where older versions of SWI-Prolog relied on the POSIX conversion
functions, the current implementation uses libtai to realise conversion
between time-stamps and calendar dates for a period of 10 million
years.
44..3344..22..11 TTiimmee aanndd ddaattee ddaattaa ssttrruuccttuurreess
We use the following time representations
TTiimmeeSSttaammpp
A TimeStamp is a floating point number expressing the time in
seconds since the Epoch at 1970-1-1.
ddaattee((_Y_,_M_,_D_,_H_,_M_n_,_S_,_O_f_f_,_T_Z_,_D_S_T))
We call this term a _d_a_t_e_-_t_i_m_e structure. The first 5 fields are
integers expressing the year, month (1..12), day (1..31), hour
(0..23) and minute (0..59). The _S field holds the seconds as a
floating point number between 0.0 and 60.0. _O_f_f is an integer
representing the offset relative to UTC in seconds, where positive
values are west of Greenwich. If converted from local time (see
stamp_date_time/3), _T_Z holds the name of the local timezone. If
the timezone is not known, _T_Z is the atom -. _D_S_T is true if
daylight saving time applies to the current time, false if daylight
saving time is relevant but not effective, and - if unknown or the
timezone has no daylight saving time.
ddaattee((_Y_,_M_,_D))
Date using the same values as described above. Extracted using
date_time_value/3.
ttiimmee((_H_,_M_n_,_S))
Time using the same values as described above. Extracted using
date_time_value/3.
44..3344..22..22 TTiimmee aanndd ddaattee pprreeddiiccaatteess
ggeett__ttiimmee((_-_T_i_m_e_S_t_a_m_p))
Return the current time as a _T_i_m_e_S_t_a_m_p. The granularity is
system-dependent. See section 4.34.2.1.
ssttaammpp__ddaattee__ttiimmee((_+_T_i_m_e_S_t_a_m_p_, _-_D_a_t_e_T_i_m_e_, _+_T_i_m_e_Z_o_n_e))
Convert a _T_i_m_e_S_t_a_m_p to a _D_a_t_e_T_i_m_e in the given timezone. See
section 4.34.2.1 for details on the data types. _T_i_m_e_Z_o_n_e describes
the timezone for the conversion. It is one of local to extract the
local time, 'UTC' to extract a UTC time or an integer describing
the seconds west of Greenwich.
ddaattee__ttiimmee__ssttaammpp((_+_D_a_t_e_T_i_m_e_, _-_T_i_m_e_S_t_a_m_p))
Compute the timestamp from a date/9 term. Values for month, day,
hour, minute or second need not be normalized. This flexibility
allows for easy computation of the time at any given number of
these units from a given timestamp. Normalization can be achieved
following this call with stamp_date_time/3. This example computes
the date 200 days after 2006-7-14:
____________________________________________________________________| |
| ?- date_time_stamp(date(2006,7,214,0,0,0,0,-,-), Stamp), |
| stamp_date_time(Stamp, D, 0), |
| date_time_value(date, D, Date). |
||Date_=_date(2007,_1,_30)__________________________________________ ||
When computing a time stamp from a local time specification, the
UTC offset (arg 7), TZ (arg 8) and DST (arg 9) argument may be left
unbound and are unified with the proper information. The example
below, executed in Amsterdam, illustrates this behaviour. On the
25th of March at 01:00, DST does not apply. At 02.00, the clock is
advanced by one hour and thus both 02:00 and 03:00 represent the
same time stamp.
____________________________________________________________________| |
| 1 ?- date_time_stamp(date(2012,3,25,1,0,0,UTCOff,TZ,DST), |
| Stamp). |
| UTCOff = -3600, |
| TZ = 'CET', |
| DST = false, |
| Stamp = 1332633600.0. |
| |
| 2 ?- date_time_stamp(date(2012,3,25,2,0,0,UTCOff,TZ,DST), |
| Stamp). |
| UTCOff = -7200, |
| TZ = 'CEST', |
| DST = true, |
| Stamp = 1332637200.0. |
| |
| 3 ?- date_time_stamp(date(2012,3,25,3,0,0,UTCOff,TZ,DST), |
| Stamp). |
| UTCOff = -7200, |
| TZ = 'CEST', |
| DST = true, |
||Stamp_=_1332637200.0._____________________________________________ ||
Note that DST and offset calculation are based on the
POSIX function mktime(). If mktime() returns an error, a
representation_error dst is generated.
ddaattee__ttiimmee__vvaalluuee((_?_K_e_y_, _+_D_a_t_e_T_i_m_e_, _?_V_a_l_u_e))
Extract values from a date/9 term. Provided keys are:
______________________________________________________________kkeeyyvvaalluuee
____________________________________________________________________________________________________________________________yearCalendar year as an integer
month Calendar month as an integer 1..12
day Calendar day as an integer 1..31
hour Clock hour as an integer 0..23
minute Clock minute as an integer 0..59
second Clock second as a float 0.0..60.0
utc_offset Offset to UTC in seconds (positive is west)
time_zone Name of timezone; fails if unknown
daylight_saving Bool (true) if dst is in effect
date Term date(_Y_,_M_,_D)
_time_____________Term_time(_H_,_M_,_S)____________________________
ffoorrmmaatt__ttiimmee((_+_O_u_t_, _+_F_o_r_m_a_t_, _+_S_t_a_m_p_O_r_D_a_t_e_T_i_m_e))
Modelled after POSIX strftime(), using GNU extensions. _O_u_t is
a destination as specified with with_output_to/2. _F_o_r_m_a_t is
an atom or string with the following conversions. Conversions
start with a tilde (%) character. _S_t_a_m_p_O_r_D_a_t_e_T_i_m_e is either a
numeric time-stamp, a term date(_Y_,_M_,_D_,_H_,_M_,_S_,_O_,_T_Z_,_D_S_T) or a term
date(_Y_,_M_,_D).
a The abbreviated weekday name according to the current locale.
Use format_time/4 for POSIX locale.
A The full weekday name according to the current locale. Use
format_time/4 for POSIX locale.
b The abbreviated month name according to the current locale.
Use format_time/4 for POSIX locale.
B The full month name according to the current locale. Use
format_time/4 for POSIX locale.
c The preferred date and time representation for the current
locale.
C The century number (year/100) as a 2-digit integer.
d The day of the month as a decimal number (range 01 to 31).
D Equivalent to %m/%d/%y. (For Americans only. Americans
should note that in other countries %d/%m/%y is rather common.
This means that in an international context this format is
ambiguous and should not be used.)
e Like %d, the day of the month as a decimal number, but a
leading zero is replaced by a space.
E Modifier. Not implemented.
f Number of microseconds. The f can be prefixed by an integer
to print the desired number of digits. E.g., %3f prints
milliseconds. This format is not covered by any standard,
but available with different format specifiers in various
incarnations of the strftime() function.
F Equivalent to %Y-%m-%d (the ISO 8601 date format).
g Like %G, but without century, i.e., with a 2-digit year
(00-99).
G The ISO 8601 year with century as a decimal number. The
4-digit year corresponding to the ISO week number (see %V).
This has the same format and value as %y, except that if the
ISO week number belongs to the previous or next year, that
year is used instead.
V The ISO 8601:1988 week number of the current year as a decimal
number, range 01 to 53, where week 1 is the first week that
has at least 4 days in the current year, and with Monday as
the first day of the week. See also %U and %W.
h Equivalent to %b.
H The hour as a decimal number using a 24-hour clock (range 00
to 23).
I The hour as a decimal number using a 12-hour clock (range 01
to 12).
j The day of the year as a decimal number (range 001 to 366).
k The hour (24-hour clock) as a decimal number (range 0 to 23);
single digits are preceded by a blank. (See also %H.)
l The hour (12-hour clock) as a decimal number (range 1 to 12);
single digits are preceded by a blank. (See also %I.)
m The month as a decimal number (range 01 to 12).
M The minute as a decimal number (range 00 to 59).
n A newline character.
O Modifier to select locale-specific output. Not implemented.
p Either `AM' or `PM' according to the given time value, or the
corresponding strings for the current locale. Noon is treated
as `pm' and midnight as `am'.
P Like %p but in lowercase: `am' or `pm' or a corresponding
string for the current locale.
r The time in a.m. or p.m. notation. In the POSIX locale this
is equivalent to `%I:%M:%S %p'.
R The time in 24-hour notation (%H:%M). For a version including
the seconds, see %T below.
s The number of seconds since the Epoch, i.e., since 1970-01-01
00:00:00 UTC.
S The second as a decimal number (range 00 to 60). (The range
is up to 60 to allow for occasional leap seconds.)
t A tab character.
T The time in 24-hour notation (%H:%M:%S).
u The day of the week as a decimal, range 1 to 7, Monday being
1. See also %w.
U The week number of the current year as a decimal number, range
00 to 53, starting with the first Sunday as the first day of
week 01. See also %V and %W.
w The day of the week as a decimal, range 0 to 6, Sunday being
0. See also %u.
W The week number of the current year as a decimal number, range
00 to 53, starting with the first Monday as the first day of
week 01.
x The preferred date representation for the current locale
without the time.
X The preferred time representation for the current locale
without the date.
y The year as a decimal number without a century (range 00 to
99).
Y The year as a decimal number including the century.
z The timezone as hour offset from GMT using the format
HHmm. Required to emit RFC822-conforming dates (using
'%a, %d %b %Y %T %z'). Our implementation supports %:z, which
modifies the output to HH:mm as required by XML-Schema. Note
that both notations are valid in ISO 8601. The sequence %:z
is compatible to the GNU date(1) command.
Z The timezone or name or abbreviation.
+ The date and time in date(1) format.
% A literal `%' character.
The table below gives some format strings for popular time
representations. RFC1123 is used by HTTP. The full implementation
of http_timestamp/2 as available from http/http_header is here.
____________________________________________________________________| |
| http_timestamp(Time, Atom) :- |
| stamp_date_time(Time, Date, 'UTC'), |
| format_time(atom(Atom), |
| '%a, %d %b %Y %T GMT', |
||____________________Date,_posix)._________________________________ ||
__________________________________SSttaannddaarrddFFoorrmmaatt ssttrriinngg
____________________________________________________________________xxssdd'%FT%T%:z'
IISSOO88660011 '%FT%T%z'
RRFFCC882222 '%a, %d %b %Y %T %z'
_RRFFCC11112233___'%a,_%d_%b_%Y_%T_GMT'__
ffoorrmmaatt__ttiimmee((_+_O_u_t_, _+_F_o_r_m_a_t_, _+_S_t_a_m_p_O_r_D_a_t_e_T_i_m_e_, _+_L_o_c_a_l_e))
Format time given a specified _L_o_c_a_l_e. This predicate is a
work-around for lacking proper portable and thread-safe time
and locale handling in current C libraries. In its current
implementation the only value allowed for _L_o_c_a_l_e is posix, which
currently only modifies the behaviour of the a, A, b and B format
specifiers. The predicate is used to be able to emit POSIX locale
week and month names for emitting standardised time-stamps such as
RFC1123.
ppaarrssee__ttiimmee((_+_T_e_x_t_, _-_S_t_a_m_p))
Same as parse_time(_T_e_x_t_, ___F_o_r_m_a_t_, _S_t_a_m_p). See parse_time/3.
ppaarrssee__ttiimmee((_+_T_e_x_t_, _?_F_o_r_m_a_t_, _-_S_t_a_m_p))
Parse a textual time representation, producing a time-stamp.
Supported formats for _T_e_x_t are in the table below. If the
format is known, it may be given to reduce parse time and
avoid ambiguities. Otherwise, _F_o_r_m_a_t is unified with the format
encountered.
_________________________________________
|__NNaammee________||EExxaammppllee______________________________________________||
||_rfc_1123F|ri,_08_Dec_2006_15:29:44_GMT_|
| iso_86012|006-12-08T17:29:44+02:00 |
| |20061208T172944+0200 |
| |2006-12-08T15:29Z |
| |2006-12-08 |
| |20061208 |
| |2006-12 |
| |2006-W49-5 |
|_________|2006-342______________________|
ddaayy__ooff__tthhee__wweeeekk((_+_D_a_t_e_,_-_D_a_y_O_f_T_h_e_W_e_e_k))
Computes the day of the week for a given date.
_D_a_t_e = date(_Y_e_a_r,_M_o_n_t_h,_D_a_y). Days of the week are num-
bered from one to seven: Monday = 1, Tuesday = 2, ..., Sunday =
7.
44..3344..33 CCoonnttrroolllliinngg tthhee swipl-win.exe ccoonnssoollee wwiinnddooww
The Windows executable swipl-win.exe console has a number of predicates
to control the appearance of the console. Being totally non-portable,
we do not advise using it for your own application, but use XPCE or
another portable GUI platform instead. We give the predicates for
reference here.
wwiinnddooww__ttiittllee((_-_O_l_d_, _+_N_e_w))
Unify _O_l_d with the title displayed in the console and change the
title to _N_e_w.
wwiinn__wwiinnddooww__ppooss((_+_L_i_s_t_O_f_O_p_t_i_o_n_s))
Interface to the MS-Windows SetWindowPos() function, controlling
size, position and stacking order of the window. _L_i_s_t_O_f_O_p_t_i_o_n_s is
a list that may hold any number of the terms below:
ssiizzee((_W_, _H))
Change the size of the window. _W and _H are expressed in
character units.
ppoossiittiioonn((_X_, _Y))
Change the top-left corner of the window. The values are
expressed in pixel units.
zzoorrddeerr((_Z_O_r_d_e_r))
Change the location in the window stacking order. Values
are bottom, top, topmost and notopmost. _T_o_p_m_o_s_t windows are
displayed above all other windows.
sshhooww((_B_o_o_l))
If true, show the window, if false hide the window.
aaccttiivvaattee
If present, activate the window.
wwiinn__hhaass__mmeennuu
True if win_insert_menu/2 and win_insert_menu_item/4are present.
wwiinn__iinnsseerrtt__mmeennuu((_+_L_a_b_e_l_, _+_B_e_f_o_r_e))
Insert a new entry (pulldown) in the menu. If the menu already
contains this entry, nothing is done. The _L_a_b_e_l is the label
and, using the Windows convention, a letter prefixed with & is
underlined and defines the associated accelerator key. _B_e_f_o_r_e is
the label before which this one must be inserted. Using - adds the
new entry at the end (right). For example, the call below adds an
Application entry just before the Help menu.
____________________________________________________________________| |
||win_insert_menu('&Application',_'&Help')__________________________ ||
wwiinn__iinnsseerrtt__mmeennuu__iitteemm((_+_P_u_l_l_d_o_w_n_, _+_L_a_b_e_l_, _+_B_e_f_o_r_e_, _:_G_o_a_l))
Add an item to the named _P_u_l_l_d_o_w_n menu. _L_a_b_e_l and _B_e_f_o_r_e
are handled as in win_insert_menu/2, but the label - inserts a
_s_e_p_a_r_a_t_o_r. _G_o_a_l is called if the user selects the item.
44..3355 FFiillee SSyysstteemm IInntteerraaccttiioonn
aacccceessss__ffiillee((_+_F_i_l_e_, _+_M_o_d_e))
True if _F_i_l_e exists and can be accessed by this Prolog process
under mode _M_o_d_e. _M_o_d_e is one of the atoms read, write, append,
exist, none or execute. _F_i_l_e may also be the name of a directory.
Fails silently otherwise. access_file(File, none)simply succeeds
without testing anything.
If _M_o_d_e is write or append, this predicate also succeeds if the
file does not exist and the user has write access to the directory
of the specified location.
eexxiissttss__ffiillee((_+_F_i_l_e))
True if _F_i_l_e exists and is a regular file. This does not imply the
user has read and/or write permission for the file.
ffiillee__ddiirreeccttoorryy__nnaammee((_+_F_i_l_e_, _-_D_i_r_e_c_t_o_r_y))
Extracts the directory part of _F_i_l_e. The returned _D_i_r_e_c_t_o_r_y name
does not end in /. There are two special cases. The directory
name of / is / itself, and the directory name is . if _F_i_l_e does
not contain any / characters. See also directory_file_path/3 from
filesex. The system ensures that for every valid _P_a_t_h using
the Prolog (POSIX) directory separators, following is true on
systems with a sound implementation of same_file/2. See also
prolog_to_os_filename/2.
____________________________________________________________________| |
| ..., |
| file_directory_name(Path, Dir), |
| file_base_name(Path, File), |
| directory_file_path(Dir, File, Path2), |
||________same_file(Path,_Path2).___________________________________ ||
ffiillee__bbaassee__nnaammee((_+_F_i_l_e_, _-_B_a_s_e_N_a_m_e))
Extracts the filename part from a path specification. If _F_i_l_e does
not contain any directory separators, _F_i_l_e is returned in _B_a_s_e_N_a_m_e.
See also file_directory_name/2.
ssaammee__ffiillee((_+_F_i_l_e_1_, _+_F_i_l_e_2))
True if both filenames refer to the same physical file. That
is, if _F_i_l_e_1 and _F_i_l_e_2 are the same string or both names exist
and point to the same file (due to hard or symbolic links
and/or relative vs. absolute paths). On systems that provide
stat() with meaningful values for st_dev and st_inode, same_file/2
is implemented by comparing the device and inode identifiers.
On Windows, same_file/2 compares the strings returned by the
GetFullPathName() system call.
eexxiissttss__ddiirreeccttoorryy((_+_D_i_r_e_c_t_o_r_y))
True if _D_i_r_e_c_t_o_r_y exists and is a directory. This does not imply
the user has read, search or write permission for the directory.
ddeelleettee__ffiillee((_+_F_i_l_e))
Remove _F_i_l_e from the file system.
rreennaammee__ffiillee((_+_F_i_l_e_1_, _+_F_i_l_e_2))
Rename _F_i_l_e_1 as _F_i_l_e_2. The semantics is compatible to the POSIX
semantics of the rename() system call as far as the operating
system allows. Notably, if _F_i_l_e_2 exists, the operation succeeds
(except for possible permission errors) and is _a_t_o_m_i_c (meaning
there is no window where _F_i_l_e_2 does not exist).
ssiizzee__ffiillee((_+_F_i_l_e_, _-_S_i_z_e))
Unify _S_i_z_e with the size of _F_i_l_e in bytes.
ttiimmee__ffiillee((_+_F_i_l_e_, _-_T_i_m_e))
Unify the last modification time of _F_i_l_e with _T_i_m_e. _T_i_m_e is a
floating point number expressing the seconds elapsed since Jan 1,
1970. See also convert_time/[2,8] and get_time/1.
aabbssoolluuttee__ffiillee__nnaammee((_+_F_i_l_e_, _-_A_b_s_o_l_u_t_e))
Expand a local filename into an absolute path. The absolute
path is canonicalised: references to . and .. are deleted.
This predicate ensures that expanding a filename returns the same
absolute path regardless of how the file is addressed. SWI-Prolog
uses absolute filenames to register source files independent of the
current working directory. See also absolute_file_name/3. See
also absolute_file_name/3 and expand_file_name/2.
aabbssoolluuttee__ffiillee__nnaammee((_+_S_p_e_c_, _-_A_b_s_o_l_u_t_e_, _+_O_p_t_i_o_n_s))
Convert the given file specification into an absolute path. _S_p_e_c
is a term Alias(Relative) (e.g., (library(lists)), a relative
filename or an absolute filename. The primary intention of this
predicate is to resolve files specified as Alias(Relative). _O_p_t_i_o_n
is a list of options to guide the conversion:
eexxtteennssiioonnss((_L_i_s_t_O_f_E_x_t_e_n_s_i_o_n_s))
List of file extensions to try. Default is ''. For each
extension, absolute_file_name/3 will first add the extension
and then verify the conditions imposed by the other options.
If the condition fails, the next extension on the list is
tried. Extensions may be specified both as .ext or plain ext.
rreellaattiivvee__ttoo((_+_F_i_l_e_O_r_D_i_r))
Resolve the path relative to the given directory or the
directory holding the given file. Without this option,
paths are resolved relative to the working directory
(see working_directory/2) or, if _S_p_e_c is atomic and
absolute_file_name/[2,3] is executed in a directive, it uses
the current source file as reference.
aacccceessss((_M_o_d_e))
Imposes the condition access_file(_F_i_l_e, _M_o_d_e). _M_o_d_e is one
of read, write, append, execute, exist or none. See also
access_file/2.
ffiillee__ttyyppee((_T_y_p_e))
Defines extensions. Current mapping: txt implies [''],
prolog implies ['.pl', ''], executable implies ['.so', ''],
qlf implies ['.qlf', ''] and directory implies ['']. The
file type source is an alias for prolog for compatibility
with SICStus Prolog. See also prolog_file_type/2. This
predicate only returns non-directories, unless the option
file_type(_d_i_r_e_c_t_o_r_y) is specified.
ffiillee__eerrrroorrss((_f_a_i_l_/_e_r_r_o_r))
If error (default), throw an existence_error exception if the
file cannot be found. If fail, stay silent.
ssoolluuttiioonnss((_f_i_r_s_t_/_a_l_l))
If first (default), the predicate leaves no choice point.
Otherwise a choice point will be left and backtracking may
yield more solutions.
eexxppaanndd((_t_r_u_e_/_f_a_l_s_e))
If true (default is false) and _S_p_e_c is atomic, call
expand_file_name/2 followed by member/2 on _S_p_e_c before
proceeding. This is a SWI-Prolog extension.
The Prolog flag verbose_file_search can be set to true to help
debugging Prolog's search for files.
This predicate is derived from Quintus Prolog. In Quintus Prolog,
the argument order was absolute_file_name(_+_S_p_e_c_, _+_O_p_t_i_o_n_s_, _-_P_a_t_h).
The argument order has been changed for compatibility with ISO and
SICStus. The Quintus argument order is still accepted.
iiss__aabbssoolluuttee__ffiillee__nnaammee((_+_F_i_l_e))
True if _F_i_l_e specifies an absolute path name. On Unix systems,
this implies the path starts with a `/'. For Microsoft-based sys-
tems this implies the path starts with <_l_e_t_t_e_r>:. This predicate
is intended to provide platform-independent checking for absolute
paths. See also absolute_file_name/2 and prolog_to_os_filename/2.
ffiillee__nnaammee__eexxtteennssiioonn((_?_B_a_s_e_, _?_E_x_t_e_n_s_i_o_n_, _?_N_a_m_e))
This predicate is used to add, remove or test filename extensions.
The main reason for its introduction is to deal with different
filename properties in a portable manner. If the file system
is case-insensitive, testing for an extension will also be done
case-insensitive. _E_x_t_e_n_s_i_o_n may be specified with or without a
leading dot (.). If an _E_x_t_e_n_s_i_o_n is generated, it will not have a
leading dot.
ddiirreeccttoorryy__ffiilleess((_+_D_i_r_e_c_t_o_r_y_, _-_E_n_t_r_i_e_s))
Unify _E_n_t_r_i_e_s with a list of entries in _D_i_r_e_c_t_o_r_y. Each member
of _E_n_t_r_i_e_s is an atom denoting an entry relative to _D_i_r_e_c_t_o_r_y.
_E_n_t_r_i_e_s contains all entries, including hidden files and, if
supplied by the OS, the special entries . and ... See also
expand_file_name/2.
eexxppaanndd__ffiillee__nnaammee((_+_W_i_l_d_C_a_r_d_, _-_L_i_s_t))
Unify _L_i_s_t with a sorted list of files or directories matching
_W_i_l_d_C_a_r_d. The normal Unix wildcard constructs `?', `*', `[...]'
and `{...}' are recognised. The interpretation of `{...}' is
slightly different from the C shell (csh(1)). The comma-separated
argument can be arbitrary patterns, including `{...}' patterns.
The empty pattern is legal as well: `\{.pl,\}' matches either
`.pl' or the empty string.
If the pattern contains wildcard characters, only existing files
and directories are returned. Expanding a `pattern' without
wildcard characters returns the argument, regardless of whether or
not it exists.
Before expanding wildcards, the construct $_v_a_r is expanded to the
value of the environment variable _v_a_r, and a possible leading ~
character is expanded to the user's home directory.
pprroolloogg__ttoo__ooss__ffiilleennaammee((_?_P_r_o_l_o_g_P_a_t_h_, _?_O_s_P_a_t_h))
Convert between the internal Prolog path name conventions and the
operating system path name conventions. The internal conventions
follow the POSIX standard, which implies that this predicate is
equivalent to =/2 (unify) on POSIX (e.g., Unix) systems. On
Windows systems it changes the directory separator from \ into /.
rreeaadd__lliinnkk((_+_F_i_l_e_, _-_L_i_n_k_, _-_T_a_r_g_e_t))
If _F_i_l_e points to a symbolic link, unify _L_i_n_k with the value of the
link and _T_a_r_g_e_t to the file the link is pointing to. _T_a_r_g_e_t points
to a file, directory or non-existing entry in the file system, but
never to a link. Fails if _F_i_l_e is not a link. Fails always on
systems that do not support symbolic links.
ttmmpp__ffiillee((_+_B_a_s_e_, _-_T_m_p_N_a_m_e)) _[_d_e_p_r_e_c_a_t_e_d_]
Create a name for a temporary file. _B_a_s_e is an identifier for the
category of file. The _T_m_p_N_a_m_e is guaranteed to be unique. If the
system halts, it will automatically remove all created temporary
files. _B_a_s_e is used as part of the final filename. Portable
applications should limit themselves to alphanumeric characters.
Because it is possible to guess the generated filename, attackers
may create the filesystem entry as a link and possibly create a
security issue. New code should use tmp_file_stream/3.
ttmmpp__ffiillee__ssttrreeaamm((_+_E_n_c_o_d_i_n_g_, _-_F_i_l_e_N_a_m_e_, _-_S_t_r_e_a_m))
Create a temporary filename _F_i_l_e_N_a_m_e and open it for writing
in the given _E_n_c_o_d_i_n_g. _E_n_c_o_d_i_n_g is a text-encoding name or
binary. _S_t_r_e_a_m is the output stream. If the OS supports it,
the created file is only accessible to the current user. If the
OS supports it, the file is created using the open()-flag O_EXCL,
which guarantees that the file did not exist before this call.
This predicate is a safe replacement of tmp_file/2. Note that in
those cases where the temporary file is needed to store output from
an external command, the file must be closed first. E.g., the
following downloads a file from a URL to a temporary file and opens
the file for reading (on Unix systems you can delete the file for
cleanup after opening it for reading):
____________________________________________________________________| |
| open_url(URL, In) :- |
| tmp_file_stream(text, File, Stream), |
| close(Stream), |
| process_create(curl, ['-o', File, URL], []), |
| open(File, read, In), |
||________delete_file(File).______________%_Unix-only_______________ ||
Temporary files created using this call are removed if the
Prolog process terminates _g_r_a_c_e_f_u_l_l_y. Calling delete_file/1
using _F_i_l_e_N_a_m_e removes the file and removes the entry from the
administration of files-to-be-deleted.
mmaakkee__ddiirreeccttoorryy((_+_D_i_r_e_c_t_o_r_y))
Create a new directory (folder) on the filesystem. Raises an
exception on failure. On Unix systems, the directory is created
with default permissions (defined by the process _u_m_a_s_k setting).
ddeelleettee__ddiirreeccttoorryy((_+_D_i_r_e_c_t_o_r_y))
Delete directory (folder) from the filesystem. Raises an exception
on failure. Please note that in general it will not be possible to
delete a non-empty directory.
wwoorrkkiinngg__ddiirreeccttoorryy((_-_O_l_d_, _+_N_e_w))
Unify _O_l_d with an absolute path to the current working directory
and change working directory to _N_e_w. Use the pattern
working_directory(_C_W_D_, _C_W_D) to get the current directory. See also
absolute_file_name/2 and chdir/1. Note that the working directory
is shared between all threads.
cchhddiirr((_+_P_a_t_h))
Compatibility predicate. New code should use working_directory/2.
44..3366 UUsseerr TToopp--lleevveell MMaanniippuullaattiioonn
bbrreeaakk
Recursively start a new Prolog top level. This Prolog top level
has its own stacks, but shares the heap with all break environments
and the top level. Debugging is switched off on entering a break
and restored on leaving one. The break environment is terminated
by typing the system's end-of-file character (control-D). If the
-t toplevel command line option is given, this goal is started
instead of entering the default interactive top level (prolog/0).
aabboorrtt
Abort the Prolog execution and restart the top level. If the
-t toplevel command line option is given, this goal is started
instead of entering the default interactive top level.
Aborting is implemented by throwing the reserved exception
'$aborted'. This exception can be caught using catch/3, but the
recovery goal is wrapped with a predicate that prunes the choice
points of the recovery goal (i.e., as once/1) and re-throws the
exception. This is illustrated in the example below, where we
press control-C and `a'.
____________________________________________________________________| |
| ?- catch((repeat,fail), E, true). |
| ^CAction (h for help) ? abort |
||%_Execution_Aborted_______________________________________________ ||
hhaalltt _[_I_S_O_]
Terminate Prolog execution. This is the same as halt(_0). See
halt/1 for details.
hhaalltt((_+_S_t_a_t_u_s)) _[_I_S_O_]
Terminate Prolog execution with _S_t_a_t_u_s. This predicate calls
PL_halt() which preforms the following steps:
1. Set the Prolog flag exit_status to _S_t_a_t_u_s.
2. Call all hooks registered using at_halt/1. If _S_t_a_t_u_s equals 0
(zero), any of these hooks calls cancel_halt/1, termination is
cancelled.
3. Call all hooks registered using PL_at_halt(). In the future,
if any of these hooks returns non-zero, termination will be
cancelled. Currently, this only prints a warning.
4. Perform the following system cleanup actions:
o Cancel all threads, calling thread_at_exit/1 registered
termination hooks. Threads not responding within 1 second
are cancelled forcefully.
o Flush I/O and close all streams except for standard I/O.
o Reset the terminal if its properties were changed.
o Remove temporary files and incomplete compilation output.
o Reclaim memory.
5. Call exit(Status) to terminate the process
pprroolloogg
This goal starts the default interactive top level. Queries are
read from the stream user_input. See also the Prolog flag history.
The prolog/0 predicate is terminated (succeeds) by typing the
end-of-file character (typically control-D).
The following two hooks allow for expanding queries and handling the
result of a query. These hooks are used by the top level variable
expansion mechanism described in section 2.8.
eexxppaanndd__qquueerryy((_+_Q_u_e_r_y_, _-_E_x_p_a_n_d_e_d_, _+_B_i_n_d_i_n_g_s_, _-_E_x_p_a_n_d_e_d_B_i_n_d_i_n_g_s))
Hook in module user, normally not defined. _Q_u_e_r_y and _B_i_n_d_i_n_g_s
represents the query read from the user and the names of the
free variables as obtained using read_term/3. If this predicate
succeeds, it should bind _E_x_p_a_n_d_e_d and _E_x_p_a_n_d_e_d_B_i_n_d_i_n_g_s to the query
and bindings to be executed by the top level. This predicate is
used by the top level (prolog/0). See also expand_answer/2 and
term_expansion/2.
eexxppaanndd__aannsswweerr((_+_B_i_n_d_i_n_g_s_, _-_E_x_p_a_n_d_e_d_B_i_n_d_i_n_g_s))
Hook in module user, normally not defined. Expand the result of
a successfully executed top-level query. _B_i_n_d_i_n_g_s is the query
<_N_a_m_e>= <_V_a_l_u_e>binding list from the query. _E_x_p_a_n_d_e_d_B_i_n_d_i_n_g_s must
be unified with the bindings the top level should print.
44..3377 CCrreeaattiinngg aa PPrroottooccooll ooff tthhee UUsseerr IInntteerraaccttiioonn
SWI-Prolog offers the possibility to log the interaction with the user
on a file. All Prolog interaction, including warnings and tracer
output, are written to the protocol file.
pprroottooccooll((_+_F_i_l_e))
Start protocolling on file _F_i_l_e. If there is already a protocol
file open, then close it first. If _F_i_l_e exists it is truncated.
pprroottooccoollaa((_+_F_i_l_e))
Equivalent to protocol/1, but does not truncate the _F_i_l_e if it
exists.
nnoopprroottooccooll
Stop making a protocol of the user interaction. Pending output is
flushed on the file.
pprroottooccoolllliinngg((_-_F_i_l_e))
True if a protocol was started with protocol/1 or protocola/1 and
unifies _F_i_l_e with the current protocol output file.
44..3388 DDeebbuuggggiinngg aanndd TTrraacciinngg PPrrooggrraammss
This section is a reference to the debugger interaction predicates. A
more use-oriented overview of the debugger is in section 2.9.
If you have installed XPCE, you can use the graphical front-end of the
tracer. This front-end is installed using the predicate guitracer/0.
ttrraaccee
Start the tracer. trace/0 itself cannot be seen in the tracer.
Note that the Prolog top level treats trace/0 special; it means
`trace the next goal'.
ttrraacciinngg
True if the tracer is currently switched on. tracing/0 itself
cannot be seen in the tracer.
nnoottrraaccee
Stop the tracer. notrace/0 itself cannot be seen in the tracer.
gguuiittrraacceerr
Installs hooks (see prolog_trace_interception/4) into the system
that redirect tracing information to a GUI front-end providing
structured access to variable bindings, graphical overview of the
stack and highlighting of relevant source code.
nnoogguuiittrraacceerr
Revert back to the textual tracer.
ttrraaccee((_+_P_r_e_d))
Equivalent to trace(_P_r_e_d, +all).
ttrraaccee((_+_P_r_e_d_, _+_P_o_r_t_s))
Put a trace point on all predicates satisfying the predicate
specification _P_r_e_d. _P_o_r_t_s is a list of port names (call, redo,
exit, fail). The atom all refers to all ports. If the port is
preceded by a - sign, the trace point is cleared for the port. If
it is preceded by a +, the trace point is set.
The predicate trace/2 activates debug mode (see debug/0). Each
time a port (of the 4-port model) is passed that has a trace point
set, the goal is printed as with trace/0. Unlike trace/0, however,
the execution is continued without asking for further information.
Examples:
?- trace(hello). Trace all ports of hello with any
arity in any module.
?- trace(foo/2, +fail). Trace failures of foo/2 in any
module.
?- trace(bar/1, -all). Stop tracing bar/1.
The predicate debugging/0 shows all currently defined trace points.
nnoottrraaccee((_:_G_o_a_l))
Call _G_o_a_l, but suspend the debugger while _G_o_a_l is executing.
The current implementation cuts the choice points of _G_o_a_l after
successful completion. See once/1. Later implementations may have
the same semantics as call/1.
ddeebbuugg
Start debugger. In debug mode, Prolog stops at spy and trace
points, disables last-call optimisation and aggressive destruction
of choice points to make debugging information accessible.
Implemented by the Prolog flag debug.
Note that the min_free parameter of all stacks is enlarged to
8 K cells if debugging is switched off in order to avoid
excessive GC. GC complicates tracing because it renames the
__G<_N_N_N> variables and replaces unreachable variables with the atom
\bnfmeta{garbage_collected}. Calling nodebug/0 does _n_o_t reset the
initial free-margin because several parts of the top level and
debugger disable debugging of system code regions. See also
set_prolog_stack/2.
nnooddeebbuugg
Stop debugger. Implemented by the Prolog flag debug. See also
debug/0.
ddeebbuuggggiinngg
Print debug status and spy points on current output stream. See
also the Prolog flag debug.
ssppyy((_+_P_r_e_d))
Put a spy point on all predicates meeting the predicate specifica-
tion _P_r_e_d. See section 4.5.
nnoossppyy((_+_P_r_e_d))
Remove spy point from all predicates meeting the predicate
specification _P_r_e_d.
nnoossppyyaallll
Remove all spy points from the entire program.
lleeaasshh((_?_P_o_r_t_s))
Set/query leashing (ports which allow for user interaction). _P_o_r_t_s
is one of _+_N_a_m_e, _-_N_a_m_e, _?_N_a_m_e or a list of these. _+_N_a_m_e enables
leashing on that port, _-_N_a_m_e disables it and _?_N_a_m_e succeeds or
fails according to the current setting. Recognised ports are call,
redo, exit, fail and unify. The special shorthand all refers to
all ports, full refers to all ports except for the unify port
(default). half refers to the call, redo and fail port.
vviissiibbllee((_+_P_o_r_t_s))
Set the ports shown by the debugger. See leash/1 for a description
of the _P_o_r_t_s specification. Default is full.
uunnkknnoowwnn((_-_O_l_d_, _+_N_e_w))
Edinburgh-Prolog compatibility predicate, interfacing to the ISO
Prolog flag unknown. Values are trace (meaning error) and fail.
If the unknown flag is set to warning, unknown/2 reports the value
as trace.
ssttyyllee__cchheecckk((_+_S_p_e_c))
Modify/query style checking options. _S_p_e_c is one of the terms
below or a list of these.
o +_S_t_y_l_e enables a style check
o -_S_t_y_l_e disables a style check
o ?(_S_t_y_l_e) queries a style check (note the brackets). If _S_t_y_l_e
is unbound, all active style check options are returned on
backtracking.
Loading a file using load_files/2 or one of its derived predicates
reset the style checking options to their value before loading the
file, scoping the option to the remainder of the file and all files
loaded _a_f_t_e_r changing the style checking.
ssiinngglleettoonn((_t_r_u_e))
The predicate read_clause/3 (used by the compiler to read
source code) warns on variables appearing only once in a term
(clause) which have a name not starting with an underscore.
See section 2.15.1.6 for details on variable handling and
warnings.
nnoo__eeffffeecctt((_t_r_u_e))
This warning is generated by the compiler for BIPs (built-in
predicates) that are inlined by the compiler and for which
the compiler can prove that they are meaningless. An
example is using ==/2 against a not-yet-initialised variable
as illustrated in the example below. This comparison is
always false.
_______________________________________________________________| |
|always_false(X) :- |
| X == Y, |
||_______write(Y)._____________________________________________ ||
vvaarr__bbrraanncchheess((_f_a_l_s_e))
Verifies that if a variable is introduced in a branch and used
_a_f_t_e_r the branch, it is introduced in all branches. This code
aims at bugs following the skeleton below, where p(_N_e_x_t) may
be called with _N_e_x_t unbound.
_______________________________________________________________| |
|p(Arg) :- |
| ( Cond |
| -> Next = value1 |
| ; true |
| ), |
||_______p(Next).______________________________________________ ||
If a variable _V is intended to be left unbound, one can use
V=_. This construct is removed by the compiler and thus has no
implications for the performance of your program.
This check was suggested together with _s_e_m_a_n_t_i_c singleton
checking. The SWI-Prolog libraries contain about a hundred
clauses that are triggered by this style check. Unlike
semantic singleton analysis, only a tiny fraction of these
clauses proofed faulty. In most cases, the branches failing
to bind the variable fail or raise an exception or the caller
handles the case where the variable is unbound. The status
of this style check is unclear. It might be removed in the
future or it might be enhanced with a deeper analysis to be
more precise.
aattoomm((_t_r_u_e))
The predicate read/1 and derived predicates produce an error
message on quoted atoms or strings with more than 6 _u_n_e_s_c_a_p_e_d
newlines. Newlines may be escaped with \ or \c. This
flag also enables warnings on \<_n_e_w_l_i_n_e> followed by blank
space in native mode. See section 2.15.1.2. Note that the
ISO standard does not allow for unescaped newlines in quoted
atoms.
ddiissccoonnttiigguuoouuss((_t_r_u_e))
Warn if the clauses for a predicate are not together in the
same source file. It is advised to disable the warning for
discontiguous predicates using the discontiguous/1 directive.
cchhaarrsseett((_f_a_l_s_e))
Warn on atoms and variable names holding non-ASCII characters
that are not quoted. See also section 2.15.1.1.
44..3399 OObbttaaiinniinngg RRuunnttiimmee SSttaattiissttiiccss
ssttaattiissttiiccss((_+_K_e_y_, _-_V_a_l_u_e))
Unify system statistics determined by _K_e_y with _V_a_l_u_e. The
possible keys are given in the table 4.3. This predicate
supports additional keys for compatibility reasons. These keys are
described in table 4.4.
___________________________________________________________________________
|_________________Native_keys_(times_as_float_in_seconds)__________________|
| agc |Number of atom garbage collections performed |
| agc_gained N|umber of atoms removed |
| agc_time T|ime spent in atom garbage collections |
| process_cputime(|User) cpu time since Prolog was started in seconds |
| cputime |(User) cpu time since thread was started in seconds |
| inferences |Total number of passes via the call and redo ports|
| |since Prolog was started |
| heapused |Bytes of heap in use by Prolog (0 if not maintained) |
| heap_gc N|umber of heap garbage collections performed. Only|
| p|rovided if SWI-Prolog is configured with Boehm-GC. See|
| a|lso garbage_collect_heap/0. |
| c_stack S|ystem (C-) stack limit. 0 if not known. |
| stack |Total memory in use for stacks in all threads |
| local |Allocated size of the local stack in bytes |
| localused |Number of bytes in use on the local stack |
| locallimit |Size to which the local stack is allowed to grow |
| local_shifts N|umber of local stack expansions |
| global |Allocated size of the global stack in bytes |
| globalused |Number of bytes in use on the global stack |
| globallimit |Size to which the global stack is allowed to grow |
| global_shifts N|umber of global stack expansions |
| trail |Allocated size of the trail stack in bytes |
| trailused |Number of bytes in use on the trail stack |
| traillimit |Size to which the trail stack is allowed to grow |
| trail_shifts N|umber of trail stack expansions |
| shift_time T|ime spent in stack-shifts |
| atoms |Total number of defined atoms |
| functors |Total number of defined name/arity pairs |
| clauses |Total number of clauses in the program |
| modules |Total number of defined modules |
| codes |Total size of (virtual) executable code in words |
| threads |MT-version: number of active threads |
| threads_createdM|T-version: number of created threads |
| thread_cputime M|T-version: seconds CPU time used by finished threads.|
| S|upported on Windows-NT and later, Linux and possibly|
| a| few more. Verify it gives plausible results before |
|________________u|sing.__________________________________________________|_
Table 4.3: Keys for statistics/2. Space is expressed in bytes. Time
is expressed in seconds, represented as a floating point number.
__________________________________________________________________________________
|____________________Compatibility_keys_(times_in_milliseconds)___________________|
| runtime |[ CPU time, CPU time since last ] (milliseconds,|
| |excluding time spent in garbage collection) |
| system_time [| System CPU time, System CPU time since last ] |
| (|milliseconds) |
| real_time [|Wall time, Wall time since last ] (integer seconds. |
| S|ee get_time/1) |
| walltime |[ Wall time since start, Wall time since last]|
| |(milliseconds, SICStus compatibility) |
| memory |[ Total unshared data, free memory ] (Uses getrusage()|
| |if available, otherwise incomplete own statistics.) |
| stacks |[ global use, local use ] |
| program |[ heap, 0 ] |
| global_stack [|global use, global free ] |
| local_stack [|local use, local free ] |
| trail |[ trail use, trail free ] |
| garbage_collection [|number of GC, bytes gained, time spent, bytes left ] |
| T|he last column is a SWI-Prolog extension. It contains|
| t|he sum of the memory left after each collection,|
| w|hich can be divided by the count to find the average|
| w|orking set size after GC. Use [Count, Gained, Time|_]|
| f|or compatiblity. |
| stack_shifts [|global shifts, local shifts, time spent ] |
| atoms |[ number, memory use, 0 ] |
| atom_garbage_collection[|number of AGC, bytes gained, time spent ] |
|_core___________________|Same_as_memory_________________________________________|_
Table 4.4: Compatibility keys for statistics/2. Time is expressed in
milliseconds.
ssttaattiissttiiccss
Display a table of system statistics on the stream user_error.
ttiimmee((_:_G_o_a_l))
Execute _G_o_a_l just like call/1 and print time used, number of
logical inferences and the average number of _l_i_p_s (logical
inferences per second). Note that SWI-Prolog counts the actual
executed number of inferences rather than the number of passes
through the call and redo ports of the theoretical 4-port model.
If _G_o_a_l is non-deterministic, print statistics for each solution,
where the reported values are relative to the previous answer.
44..4400 EExxeeccuuttiioonn pprrooffiilliinngg
This section describes the hierarchical execution profiler. This pro-
filer is based on ideas from gprof described in [Graham _e_t _a_l_., 1982].
The profiler consists of two parts: the information-gathering
component built into the kernel, and a presentation component which is
defined in the statistics library. The latter can be hooked, which
is used by the XPCE module swi/pce_profile to provide an interactive
graphical frontend for the results.
44..4400..11 PPrrooffiilliinngg pprreeddiiccaatteess
The following predicates are defined to interact with the profiler.
pprrooffiillee((_:_G_o_a_l))
Execute _G_o_a_l just like once/1, collecting profiling statistics, and
call show_profile(_[_]). With XPCE installed this opens a graphical
interface to examine the collected profiling data.
pprrooffiillee((_:_G_o_a_l_, _+_O_p_t_i_o_n_s))
Execute _G_o_a_l just like once/1. Collect profiling statistics
according to _O_p_t_i_o_n_s and call show_profile/1 with _O_p_t_i_o_n_s. The
default collects CPU profiling and opens a graphical interface when
provided, printing the `plain' time usage of the top 25 predicates
as a ballback. Options are described below. Remaining options are
passed to show_profile/1.
ttiimmee((_+_W_h_i_c_h))
If _W_h_i_c_h is cpu (default), collect CPU timing statistics. If
wall, collect wall time statistics based on a 5 millisecond
sampling rate. Wall time statistics can be useful if _G_o_a_l
calls blocking system calls.
sshhooww__pprrooffiillee((_+_O_p_t_i_o_n_s))
This predicate first calls prolog:show_profile_hook/1. If XPCE is
loaded, this hook is used to activate a GUI interface to visualise
the profile results. If not, a report is printed to the terminal
according to _O_p_t_i_o_n_s:
ttoopp((_+_N))
Show the only top _N predicates. Default is 25.
ccuummmmuullaattiivvee((_+_B_o_o_l))
If true (default false), include the time spent in children in
the time reported for a predicate.
pprrooffiilleerr((_-_O_l_d_, _+_N_e_w))
Query or change the status of the profiler. The status is one of
ffaallssee
The profiler is not activated.
ccppuuttiimmee
The profiler collects CPU statistics.
wwaallllttiimmee
The profiler collects wall time statistics.
The value true is accepted as a synonym for cputime for
compatibility reasons.
rreesseett__pprrooffiilleerr
Switches the profiler to false and clears all collected statistics.
nnoopprrooffiillee((_+_N_a_m_e_/_+_A_r_i_t_y_, _._._.))
Declares the predicate _N_a_m_e/_A_r_i_t_y to be invisible to the profiler.
The time spent in the named predicate is added to the caller,
and the callees are linked directly to the caller. This is
particularly useful for simple meta-predicates such as call/1,
ignore/1, catch/3, etc.
44..4400..22 VViissuuaalliizziinngg pprrooffiilliinngg ddaattaa
Browsing the annotated call-tree as described in section 4.40.3
itself is not very attractive. Therefore, the results are combined
per predicate, collecting all _c_a_l_l_e_r_s and _c_a_l_l_e_e_s as well as the
propagation of time and activations in both directions. Figure ????
illustrates this. The central yellowish line is the `current'
predicate with counts for time spent in the predicate (`Self'), time
spent in its children (`Siblings'), activations through the call and
redo ports. Above that are the _c_a_l_l_e_r_s. Here, the two time fields
indicate how much time is spent serving each of the callers. The
columns sum to the time in the yellowish line. The caller <_r_e_c_u_r_s_i_v_e>
is the number of recursive calls. Below the yellowish lines are the
callees, with the time spent in the callee itself for serving the
current predicate and the time spent in the callees of the callee
('Siblings'), so the whole time-block adds up to the `Siblings' field
of the current predicate. The `Access' fields show how many times the
current predicate accesses each of the callees.
The predicates have a menu that allows changing the view of the detail
window to the given caller or callee, showing the documentation (if it
is a built-in) and/or jumping to the source.
The statistics shown in the report field of figure ???? show the
following information:
o _s_a_m_p_l_e_s
Number of times the call-tree was sampled for collecting time
statistics. On most hardware, the resolution of SIGPROF is 1/100
second. This number must be sufficiently large to get reliable
timing figures. The Time menu allows viewing time as samples,
relative time or absolute time.
o _s_e_c
Total user CPU time with the profiler active.
o _p_r_e_d_i_c_a_t_e_s
Total count of predicates that have been called at least one time
during the profile.
o _n_o_d_e_s
Number of nodes in the call-tree.
o _d_i_s_t_o_r_t_i_o_n
How much of the time is spent building the call-tree as a
percentage of the total execution time. Timing samples while the
profiler is building the call-tree are not added to the call-tree.
44..4400..33 IInnffoorrmmaattiioonn ggaatthheerriinngg
While the program executes under the profiler, the system builds a
_d_y_n_a_m_i_c call-tree. It does this using three hooks from the kernel:
one that starts a new goal (_p_r_o_f_C_a_l_l), one that tells the system
which goal is resumed after an _e_x_i_t (_p_r_o_f_E_x_i_t) and one that tells the
system which goal is resumed after a _f_a_i_l (i.e., which goal is used
to _r_e_t_r_y (_p_r_o_f_R_e_d_o)). The profCall() function finds or creates the
subnode for the argument predicate below the current node, increments
the call-count of this link and returns the sub-node which is recorded
in the Prolog stack-frame. Choice-points are marked with the current
profiling node. profExit() and profRedo() pass the profiling node
where execution resumes.
Just using the above algorithm would create a much too big tree due to
recursion. For this reason the system performs detection of recursion.
In the simplest case, recursive procedures increment the `recursive'
count on the current node. Mutual recursion, however, is not easily
detected. For example, call/1 can call a predicate that uses call/1
itself. This can be viewed as a recursive invocation, but this is
generally not desirable. Recursion is currently assumed if the same
predicate _w_i_t_h _t_h_e _s_a_m_e _p_a_r_e_n_t appears higher in the call-graph. Early
experience with some non-trivial programs are promising.
The last part of the profiler collects statistics on the CPU time
used in each node. On systems providing setitimer() with SIGPROF, it
`ticks' the current node of the call-tree each time the timer fires.
On Windows, a MM-timer in a separate thread checks 100 times per second
how much time is spent in the profiled thread and adds this to the
current node. See section 4.40.3.1 for details.
44..4400..33..11 PPrrooffiilliinngg iinn tthhee WWiinnddoowwss IImmpplleemmeennttaattiioonn
Profiling in the Windows version is similar, but as profiling is a
statistical process it is good to be aware of the implementation for
proper interpretation of the results.
Windows does not provide timers that fire asynchronously, frequent and
proportional to the CPU time used by the process. Windows does provide
multi-media timers that can run at high frequency. Such timers,
however, run in a separate thread of execution and they are fired on
the wall clock rather than the amount of CPU time used. The profiler
installs such a timer running, for saving CPU time, rather inaccurately
at about 100 Hz. Each time it is fired, it determines the CPU time in
milliseconds used by Prolog since the last time it was fired. If this
value is non-zero, active predicates are incremented with this value.
44..4411 MMeemmoorryy MMaannaaggeemmeenntt
ggaarrbbaaggee__ccoolllleecctt
Invoke the global and trail stack garbage collector. Normally
the garbage collector is invoked automatically if necessary.
Explicit invocation might be useful to reduce the need for
garbage collections in time-critical segments of the code. After
the garbage collection trim_stacks/0 is invoked to release the
collected memory resources.
ggaarrbbaaggee__ccoolllleecctt__aattoommss
Reclaim unused atoms. Normally invoked after agc_margin (a Prolog
flag) atoms have been created. On multithreaded versions the
actual collection is delayed until there are no threads performing
normal garbage collection. In this case garbage_collect_atoms/0
returns immediately. Note that there is no guarantee it will
_e_v_e_r happen, as there may always be threads performing garbage
collection.
ttrriimm__ssttaacckkss
Release stack memory resources that are not in use at this moment,
returning them to the operating system. It can be used to release
memory resources in a backtracking loop, where the iterations
require typically seconds of execution time and very different,
potentially large, amounts of stack space. Such a loop can be
written as follows:
____________________________________________________________________| |
| loop :- |
| generator, |
| trim_stacks, |
| potentially_expensive_operation, |
||________stop_condition,_!.________________________________________ ||
The Prolog top-level loop is written this way, reclaiming memory
resources after every user query.
sseett__pprroolloogg__ssttaacckk((_+_S_t_a_c_k_, _+_K_e_y_V_a_l_u_e))
Set a parameter for one of the Prolog runtime stacks. _S_t_a_c_k is one
of local, global, trail or argument. The table below describes the
_K_e_y(_V_a_l_u_e) pairs. _V_a_l_u_e can be an arithmetic integer expression.
For example, to specify a 2 GB limit for the global stack, one can
use:
____________________________________________________________________| |
||?-_set_prolog_stack(global,_limit(2*10**9)).______________________ ||
Current settings can be retrieved with prolog_stack_property/2.
lliimmiitt((_+_B_y_t_e_s))
Set the limit to which the stack is allowed to grow. If
the specified value is lower than the current usage a
permission_error is raised. If the limit is larger than
supported, the system silently reduces the requested limit to
the system limit.
mmiinn__ffrreeee((_+_C_e_l_l_s))
Minimum amount of free space after trimming or shifting the
stack. Setting this value higher can reduce the number of
garbage collections and stack-shifts at the cost of higher
memory usage. The spare stack amount is reported and
specified in `cells'. A cell is 4 bytes in the 32-bit version
and 8 bytes on the 64-bit version. See address_bits. See also
trim_stacks/0 and debug/0.
ssppaarree((_+_C_e_l_l_s))
All stacks trigger overflow before actually reaching the
limit, so the resulting error can be handled gracefully.
The spare stack is used for print_message/2 from the garbage
collector and for handling exceptions. The default suffices,
unless the user redefines related hooks. Do nnoott specify
large values for this because it reduces the amount of memory
available for your real task.
Related hooks are message_hook/3 (redefining GC messages),
prolog_trace_interception/4and prolog_exception_hook/4.
pprroolloogg__ssttaacckk__pprrooppeerrttyy((_?_S_t_a_c_k_, _?_K_e_y_V_a_l_u_e))
True if _K_e_y_V_a_l_u_e is a current property of _S_t_a_c_k. See
set_prolog_stack/2 for defined properties.
44..4422 WWiinnddoowwss DDDDEE iinntteerrffaaccee
The predicates in this section deal with MS-Windows `Dynamic Data
Exchange' or DDE protocol. A Windows DDE conversation is a form
of interprocess communication based on sending reserved window events
between the communicating processes.
Failing DDE operations raise an error of the structure below, where
_O_p_e_r_a_t_i_o_n is the name of the (partial) operation that failed and
_M_e_s_s_a_g_e is a translation of the operator error code. For some errors,
_C_o_n_t_e_x_t provides additional comments.
________________________________________________________________________| |
||_______error(dde_error(Operation,_Message),_Context)__________________ ||
44..4422..11 DDDDEE cclliieenntt iinntteerrffaaccee
The DDE client interface allows Prolog to talk to DDE server programs.
We will demonstrate the use of the DDE interface using the Windows
PROGMAN (Program Manager) application:
________________________________________________________________________| |
|1 ?- open_dde_conversation(progman, progman, C). |
| |
|C = 0 |
|2 ?- dde_request(0, groups, X) |
| |
|--> Unifies X with description of groups |
| |
|3 ?- dde_execute(0, '[CreateGroup("DDE Demo")]'). |
|true. |
| |
|4 ?- close_dde_conversation(0). |
|true.|_________________________________________________________________ | |
For details on interacting with progman, use the SDK online
manual section on the Shell DDE interface. See also the Prolog
library(progman), which may be used to write simple Windows setup
scripts in Prolog.
ooppeenn__ddddee__ccoonnvveerrssaattiioonn((_+_S_e_r_v_i_c_e_, _+_T_o_p_i_c_, _-_H_a_n_d_l_e))
Open a conversation with a server supporting the given service name
and topic (atoms). If successful, _H_a_n_d_l_e may be used to send
transactions to the server. If no willing server is found this
predicate fails silently.
cclloossee__ddddee__ccoonnvveerrssaattiioonn((_+_H_a_n_d_l_e))
Close the conversation associated with _H_a_n_d_l_e. All opened
conversations should be closed when they're no longer needed,
although the system will close any that remain open on process
termination.
ddddee__rreeqquueesstt((_+_H_a_n_d_l_e_, _+_I_t_e_m_, _-_V_a_l_u_e))
Request a value from the server. _I_t_e_m is an atom that identifies
the requested data, and _V_a_l_u_e will be a string (CF_TEXT data in DDE
parlance) representing that data, if the request is successful.
ddddee__eexxeeccuuttee((_+_H_a_n_d_l_e_, _+_C_o_m_m_a_n_d))
Request the DDE server to execute the given command string.
Succeeds if the command could be executed and fails with an error
message otherwise.
ddddee__ppookkee((_+_H_a_n_d_l_e_, _+_I_t_e_m_, _+_C_o_m_m_a_n_d))
Issue a POKE command to the server on the specified _I_t_e_m. _c_o_m_m_a_n_d
is passed as data of type CF_TEXT.
44..4422..22 DDDDEE sseerrvveerr mmooddee
The library(dde) defines primitives to realise simple DDE server
applications in SWI-Prolog. These features are provided as of version
2.0.6 and should be regarded as prototypes. The C part of the DDE
server can handle some more primitives, so if you need features not
provided by this interface, please study library(dde).
ddddee__rreeggiisstteerr__sseerrvviiccee((_+_T_e_m_p_l_a_t_e_, _+_G_o_a_l))
Register a server to handle DDE request or DDE execute requests
from other applications. To register a service for a DDE request,
_T_e_m_p_l_a_t_e is of the form:
+Service(+Topic, +Item, +Value)
_S_e_r_v_i_c_e is the name of the DDE service provided (like progman in
the client example above). _T_o_p_i_c is either an atom, indicating
_G_o_a_l only handles requests on this topic, or a variable that also
appears in _G_o_a_l. _I_t_e_m and _V_a_l_u_e are variables that also appear in
_G_o_a_l. _I_t_e_m represents the request data as a Prolog atom.
The example below registers the Prolog current_prolog_flag/2
predicate to be accessible from other applications. The request
may be given from the same Prolog as well as from another
application.
____________________________________________________________________| |
| ?- dde_register_service(prolog(current_prolog_flag, F, V), |
| current_prolog_flag(F, V)). |
| |
| ?- open_dde_conversation(prolog, current_prolog_flag, Handle), |
| dde_request(Handle, home, Home), |
| close_dde_conversation(Handle). |
| |
||Home_=_'/usr/local/lib/pl-2.0.6/'_________________________________ ||
Handling DDE execute requests is very similar. In this case the
template is of the form:
+Service(+Topic, +Item)
Passing a _V_a_l_u_e argument is not needed as execute requests either
succeed or fail. If _G_o_a_l fails, a `not processed' is passed back
to the caller of the DDE request.
ddddee__uunnrreeggiisstteerr__sseerrvviiccee((_+_S_e_r_v_i_c_e))
Stop responding to _S_e_r_v_i_c_e. If Prolog is halted, it will
automatically call this on all open services.
ddddee__ccuurrrreenntt__sseerrvviiccee((_-_S_e_r_v_i_c_e_, _-_T_o_p_i_c))
Find currently registered services and the topics served on them.
ddddee__ccuurrrreenntt__ccoonnnneeccttiioonn((_-_S_e_r_v_i_c_e_, _-_T_o_p_i_c))
Find currently open conversations.
44..4433 MMiisscceellllaanneeoouuss
ddwwiimm__mmaattcchh((_+_A_t_o_m_1_, _+_A_t_o_m_2))
True if _A_t_o_m_1 matches _A_t_o_m_2 in the `Do What I Mean' sense. Both
_A_t_o_m_1 and _A_t_o_m_2 may also be integers or floats. The two atoms
match if:
o They are identical
o They differ by one character (spy spu)
o One character is inserted/deleted (debug deug)
o Two characters are transposed (trace tarce)
o `Sub-words' are glued differently (existsfile existsFile
exists_file)
o Two adjacent sub-words are transposed (existsFile
fileExists)
ddwwiimm__mmaattcchh((_+_A_t_o_m_1_, _+_A_t_o_m_2_, _-_D_i_f_f_e_r_e_n_c_e))
Equivalent to dwim_match/2, but unifies _D_i_f_f_e_r_e_n_c_e with an atom
identifying the difference between _A_t_o_m_1 and _A_t_o_m_2. The return
values are (in the same order as above): equal, mismatched_char,
inserted_char, transposed_char, separated and transposed_word.
wwiillddccaarrdd__mmaattcchh((_+_P_a_t_t_e_r_n_, _+_S_t_r_i_n_g))
True if _S_t_r_i_n_g matches the wildcard pattern _P_a_t_t_e_r_n. _P_a_t_t_e_r_n is
very similar to the Unix csh pattern matcher. The patterns are
given below:
? Matches one arbitrary character.
* Matches any number of arbitrary characters.
[...] Matches one of the characters specified between the brackets.
<_c_h_a_r_1>-<_c_h_a_r_2>indicates a range.
{...} Matches any of the patterns of the comma-separated list between the braces.
Example:
____________________________________________________________________| |
| ?- wildcard_match('[a-z]*.{pro,pl}[%~]', 'a_hello.pl%'). |
||true._____________________________________________________________ ||
sslleeeepp((_+_T_i_m_e))
Suspend execution _T_i_m_e seconds. _T_i_m_e is either a floating point
number or an integer. Granularity is dependent on the system's
timer granularity. A negative time causes the timer to return
immediately. On most non-realtime operating systems we can only
ensure execution is suspended for aatt lleeaasstt _T_i_m_e seconds.
On Unix systems the sleep/1 predicate is realised ---in order of
preference--- by nanosleep(), usleep(), select() if the time is
below 1 minute, or sleep(). On Windows systems Sleep() is used.
CChhaapptteerr 55.. MMOODDUULLEESS
A Prolog module is a collection of predicates which defines a public
interface by means of a set of provided predicates and operators.
Prolog modules are defined by an ISO standard. Unfortunately, the
standard is considered a failure and, as far as we are aware, not
implemented by any concrete Prolog implementation. The SWI-Prolog
module system syntax is derived from the Quintus Prolog module system.
The Quintus module system has been the starting point for the module
systems of a number of mainstream Prolog systems, such as SICStus,
Ciao and YAP. The underlying primitives of the SWI-Prolog module system
differ from the mentioned systems. These primitives allow for multiple
modules in a file, hierarchical modules, emulation of other modules
interfaces, etc.
This chapter motivates and describes the SWI-Prolog module system.
Novices can start using the module system after reading section 5.2
and section 5.3. The primitives defined in these sections suffice for
basic usage until one needs to export predicates that call or manage
other predicates dynamically (e.g., use call/1, assert/1, etc.). Such
predicates are called _m_e_t_a _p_r_e_d_i_c_a_t_e_s and are discussed in section 5.4.
Section 5.5 to section 5.8 describe more advanced issues. Starting
with section 5.9, we discuss more low-level aspects of the SWI-Prolog
module system that are used to implement the visible module system, and
can be used to build other code reuse mechanisms.
55..11 WWhhyy UUssee MMoodduulleess??
In classic Prolog systems, all predicates are organised in a single
namespace and any predicate can call any predicate. Because each
predicate in a file can be called from anywhere in the program,
it becomes very hard to find the dependencies and enhance the
implementation of a predicate without risking to break the overall
application. This is true for any language, but even worse for Prolog
due to its frequent need for `helper predicates'.
A Prolog module encapsulates a set of predicates and defines an
_i_n_t_e_r_f_a_c_e. Modules can import other modules, which makes the
dependencies explicit. Given explicit dependencies and a well-defined
interface, it becomes much easier to change the internal organisation
of a module without breaking the overall application.
Explicit dependencies can also be used by the development environment.
The SWI-Prolog library prolog_xref can be used to analyse completeness
and consistency of modules. This library is used by the built-in
editor PceEmacs for syntax highlighting, jump-to-definition, etc.
55..22 DDeeffiinniinngg aa MMoodduullee
Modules are normally created by loading a _m_o_d_u_l_e _f_i_l_e. A module file
is a file holding a module/2 directive as its first term. The module/2
directive declares the name and the public (i.e., externally visible)
predicates of the module. The rest of the file is loaded into the
module. Below is an example of a module file, defining reverse/2 and
hiding the helper predicate rev/3. A module can use all built-in
predicates and, by default, cannot redefine system predicates.
________________________________________________________________________| |
|:- module(reverse, [reverse/2]). |
| |
|reverse(List1, List2) :- |
| rev(List1, [], List2). |
| |
|rev([], List, List). |
|rev([Head|List1], List2, List3) :- |
||_______rev(List1,_[Head|List2],_List3)._______________________________ ||
The module is named reverse. Typically, the name of a module is
the same as the name of the file by which it is defined without the
filename extension, but this naming is not enforced. Modules are
organised in a single and flat namespace and therefore module names
must be chosen with some care to avoid conflicts. As we will see,
typical applications of the module system rarely use the name of a
module explicitly in the source text.
::-- mmoodduullee((_+_M_o_d_u_l_e_, _+_P_u_b_l_i_c_L_i_s_t))
This directive can only be used as the first term of a source
file. It declares the file to be a _m_o_d_u_l_e _f_i_l_e, defining a
module named _M_o_d_u_l_e. Note that a module name is an atom. The
module exports the predicates of _P_u_b_l_i_c_L_i_s_t. _P_u_b_l_i_c_L_i_s_t is a
list of predicate indicators (name/arity or name//arity pairs) or
operator declarations using the format op(_P_r_e_c_e_d_e_n_c_e_, _T_y_p_e_, _N_a_m_e).
Operators defined in the export list are available inside the
module as well as to modules importing this module. See also
section 4.25.
Compatible to Ciao Prolog, if _M_o_d_u_l_e is unbound, it is unified with
the basename without extension of the file being loaded.
::-- mmoodduullee((_+_M_o_d_u_l_e_, _+_P_u_b_l_i_c_L_i_s_t_, _+_D_i_a_l_e_c_t))
Same as module/2. The additional _D_i_a_l_e_c_t argument provides a list
of _l_a_n_g_u_a_g_e _o_p_t_i_o_n_s. Each atom in the list _D_i_a_l_e_c_t is mapped to a
use_module/1 goal as given below. See also section 13. The third
argument is supported for compatibility with the Prolog Commons
project.
____________________________________________________________________| |
||:-_use_module(library(dialect/LangOption))._______________________ ||
55..33 IImmppoorrttiinngg PPrreeddiiccaatteess iinnttoo aa MMoodduullee
Predicates can be added to a module by _i_m_p_o_r_t_i_n_g them from another
module. Importing adds predicates to the namespace of a module. An
imported predicate can be called exactly the same as a locally defined
predicate, although its implementation remains part of the module in
which it has been defined.
Importing the predicates from another module is achieved using the
directives use_module/1 or use_module/2. Note that both directives take
_f_i_l_e_n_a_m_e_(_s_) as arguments. That is, modules are imported based on their
filename rather than their module name.
uussee__mmoodduullee((_+_F_i_l_e_s))
Load the file(s) specified with _F_i_l_e_s just like ensure_loaded/1.
The files must all be module files. All exported predicates
from the loaded files are imported into the module from which
this predicate is called. This predicate is equivalent to
ensure_loaded/1, except that it raises an error if _F_i_l_e_s are not
module files.
The imported predicates act as _w_e_a_k _s_y_m_b_o_l_s in the module into
which they are imported. This implies that a local definition of
a predicate overrides (clobbers) the imported definition. If the
flag warn_override_implicit_importis true (default), a warning is
printed. Below is an example of a module that uses library(lists),
but redefines flatten/2, giving it a totally different meaning:
____________________________________________________________________| |
| :- module(shapes, []). |
| :- use_module(library(lists)). |
| |
| flatten(cube, square). |
||flatten(ball,_circle).____________________________________________ ||
Loading the above file prints the following message:
____________________________________________________________________| |
| Warning: /home/janw/Bugs/Import/t.pl:5: |
| Local definition of shapes:flatten/2 |
||________overrides_weak_import_from_lists__________________________ ||
This warning can be avoided by (1) using use_module/2 to only
import the predicates from the lists library that are actually used
in the `shapes' module, (2) using the except([flatten/2]) option
of use_module/2, (3) use :- abolish(flatten/2). before the local
definition or (4) setting warn_override_implicit_import to false.
Globally disabling this warning is only recommended if overriding
imported predicates is common as a result of design choices or the
program is ported from a system that silently overrides imported
predicates.
Note that it is always an error to import two modules with
use_module/1 that export the same predicate. Such conflicts must
be resolved with use_module/2 as described above.
uussee__mmoodduullee((_+_F_i_l_e_, _+_I_m_p_o_r_t_L_i_s_t))
Load _F_i_l_e, which must be a module file, and import the predicates
as specified by _I_m_p_o_r_t_L_i_s_t. _I_m_p_o_r_t_L_i_s_t is a list of predicate
indicators specifying the predicates that will be imported
from the loaded module. _I_m_p_o_r_t_L_i_s_t also allows for renaming
or import-everything-except. See also the import option of
load_files/2. The first example below loads member/2 from the
lists library and append/2 under the name list_concat, which is
how this predicate is named in YAP. The second example loads all
exports from library option except for meta_options/3. These
renaming facilities are generally used to deal with portability
issues with as few changes as possible to the actual code. See
also section 13 and section 5.7.
____________________________________________________________________| |
| :- use_module(library(lists), [ member/2, |
| append/2 as list_concat |
| ]). |
||:-_use_module(library(option),_except([meta_options/3]))._________ ||
The module/2, use_module/1 and use_module/2 directives are sufficient
to partition a simple Prolog program into modules. The SWI-Prolog
graphical cross-referencing tool gxref/0 can be used to analyse the
dependencies between non-module files and propose module declarations
for each file.
55..44 DDeeffiinniinngg aa mmeettaa--pprreeddiiccaattee
A meta-predicate is a predicate that calls other predicates
dynamically, modifies a predicate, or reasons about properties of
a predicate. Such predicates use either a compound term or a
_p_r_e_d_i_c_a_t_e _i_n_d_i_c_a_t_o_r to describe the predicate they address, e.g.,
assert(name(jan)) or abolish(name/1). With modules, this simple
schema no longer works as each module defines its own mapping from
name+arity to predicate. This is resolved by wrapping the original
description in a term <_m_o_d_u_l_e>:<_t_e_r_m>, e.g., assert(person:name(jan)) or
abolish(person:name/1).
Of course, when calling assert/1 from inside a module, we expect to
assert to a predicate local to this module. In other words, we do
not wish to provide this :/2 wrapper by hand. The meta_predicate/1
directive tells the compiler that certain arguments are terms that will
be used to look up a predicate and thus need to be wrapped (qualified)
with <_m_o_d_u_l_e>:<_t_e_r_m>, unless they are already wrapped.
In the example below, we use this to define maplist/3 inside a
module. The argument `2' in the meta_predicate declaration means that
the argument is module-sensitive and refers to a predicate with an
arity that is two more than the term that is passed in. The compiler
only distinguishes the values 0..9 and :, which denote module-sensitive
arguments, from +, - and ?, which denote _m_o_d_e_s. The values 0..9
are used by the _c_r_o_s_s_-_r_e_f_e_r_e_n_c_e_r and syntax highlighting. Note that
the helper predicate maplist_/3 does not need to be declared as a
meta-predicate because the maplist/3 wrapper already ensures that _G_o_a_l
is qualified as <_m_o_d_u_l_e>:_G_o_a_l. See the description of meta_predicate/1
for details.
________________________________________________________________________| |
|:- module(maplist, [maplist/3]). |
|:- meta_predicate maplist(2, ?, ?). |
| |
|%% maplist(:Goal, +List1, ?List2) |
|% |
|% True if Goal can successfully be applied to all |
|% successive pairs of elements from List1 and List2. |
| |
|maplist(Goal, L1, L2) :- |
| maplist_(L1, L2, Goal). |
| |
|maplist_([], [], _). |
|maplist_([H0|T0], [H|T], Goal) :- |
| call(Goal, H0, H), |
||_______maplist_(T0,_T,_Goal)._________________________________________ ||
mmeettaa__pprreeddiiccaattee _+_H_e_a_d_, _._._.
Define the predicates referenced by the comma-separated list _H_e_a_d
as _m_e_t_a_-_p_r_e_d_i_c_a_t_e_s. Each argument of each head is a _m_e_t_a _a_r_g_u_m_e_n_t
_s_p_e_c_i_f_i_e_r. Defined specifiers are given below. Only 0..9, : and ^
are interpreted; the mode declarations +, - and ? are ignored.
00....99
The argument is a term that is used to reference a predicate
with N more arguments than the given argument term. For
example: call(0) or maplist(1, +).
:
The argument is module-sensitive, but does not directly refer
to a predicate. For example: consult(:).
-
The argument is not module-sensitive and unbound on entry.
?
The argument is not module-sensitive and the mode is unspeci-
fied.
*
The argument is not module-sensitive and the mode is unspeci-
fied. The specification * is equivalent to ?. It is accepted
for compatibility reasons. The predicate predicate_property/2
reports arguments declared using * with ?.
+
The argument is not module-sensitive and bound (i.e., nonvar)
on entry.
^
This extension is used to denote the possibly ^-annotated goal
of setof/3, bagof/3, aggregate/3 and aggregate/4. It is
processed similar to `0', but leaving the ^/2 intact.
//
The argument is a DCG body. See phrase/3.
Each argument that is module-sensitive (i.e., marked 0..9, : or ^)
is qualified with the context module of the caller if it is not
already qualified. The implementation ensures that the argument is
passed as <_m_o_d_u_l_e>:<_t_e_r_m>, where <_m_o_d_u_l_e> is an atom denoting the
name of a module and <_t_e_r_m> itself is not a :/2 term where the
first argument is an atom. Below is a simple declaration and a
number of queries.
____________________________________________________________________| |
| :- meta_predicate |
| meta(0, +). |
| |
| meta(Module:Term, _Arg) :- |
||________format('Module=~w,_Term_=_~q~n',_[Module,_Term])._________ ||
____________________________________________________________________| |
| ?- meta(test, x). |
| Module=user, Term = test |
| ?- meta(m1:test, x). |
| Module=m1, Term = test |
| ?- m2:meta(test, x). |
| Module=m2, Term = test |
| ?- m1:meta(m2:test, x). |
| Module=m2, Term = test |
| ?- meta(m1:m2:test, x). |
| Module=m2, Term = test |
| ?- meta(m1:42:test, x). |
||Module=42,_Term_=_test____________________________________________ ||
The meta_predicate/1 declaration is the portable mechanism
for defining meta-predicates and replaces the old SWI-Prolog
specific mechanism provided by the deprecated predicates
module_transparent/1, context_module/1 and strip_module/3. See also
section 5.15.
55..55 OOvveerrrruulliinngg MMoodduullee BBoouunnddaarriieess
The module system described so far is sufficient to distribute programs
over multiple modules. There are, however, cases in which we would
like to be able to overrule this schema and explicitly call a predicate
in some module or assert explicitly into some module. Calling in
a particular module is useful for debugging from the user's top
level or to access multiple implementations of the same interface
that reside in multiple modules. Accessing the same interface from
multiple modules cannot be achieved using importing because importing a
predicate with the same name and arity from two modules results in a
name conflict. Asserting in a different module can be used to create
models dynamically in a new module. See section 5.12.
Direct addressing of modules is achieved using a :/2 explicitly in a
program and relies on the module qualification mechanism described in
section 5.4. Here are a few examples:
________________________________________________________________________| |
|?- assert(world:done). % asserts done/0 into module world |
|?- world:asserta(done). % the same |
|?-|world:done.___________%_calls_done/0_in_module_world________________ | |
Note that the second example is the same due to the Prolog flag
colon_sets_calling_context. The system predicate asserta/1 is called
in the module world, which is possible because system predicates are
_v_i_s_i_b_l_e in all modules. At the same time, the _c_a_l_l_i_n_g _c_o_n_t_e_x_t is
set to world. Because meta arguments are qualified with the calling
context, the resulting call is the same as the first example.
55..55..11 EExxpplliicciitt mmaanniippuullaattiioonn ooff tthhee ccaalllliinngg ccoonntteexxtt
Quintus' derived module systems have no means to separate the
lookup module (for finding predicates) from the calling context (for
qualifying meta arguments). Some other Prolog implementations (e.g.,
ECLiPSe and IF/Proloog) distinguish these operations, using @/2 for
setting the calling context of a goal. This is provided by SWI-Prolog,
currently mainly to support compatibility layers.
@@((_:_G_o_a_l_, _+_M_o_d_u_l_e))
Execute _G_o_a_l, setting the calling context to _M_o_d_u_l_e. Setting
the calling context affects meta-predicates, for which meta
arguments are qualified with _M_o_d_u_l_e and transparent predicates
(see module_transparent/1). It has no implications for other
predicates.
For example, the code asserta(done)@world is the same as
asserta(world:done). Unlike in world:asserta(done), asserta/1 is
resolved in the current module rather than the module world. This
makes no difference for system predicates, but usually does make a
difference for user predicates.
Not that SWI-Prolog does not define @ as an operator. Some systems
define this construct using op(900, xfx, @).
55..66 IInntteerraaccttiinngg wwiitthh mmoodduulleess ffrroomm tthhee ttoopp lleevveell
Debugging often requires interaction with predicates that reside in
modules: running them, setting spy points on them, etc. This can
be achieved using the <_m_o_d_u_l_e>:<_t_e_r_m> construct explicitly as described
above. In SWI-Prolog, you may also wish to omit the module
qualification. Setting a spy point (spy/1) on a plain predicate sets
a spy point on any predicate with that name in any module. Editing
(edit/1) or calling an unqualified predicate invokes the DWIM (Do
What I Mean) mechanism, which generally suggests the correct qualified
query.
Mainly for compatibility, we provide module/1 to switch the module with
which the interactive top level interacts:
mmoodduullee((_+_M_o_d_u_l_e))
The call module(_M_o_d_u_l_e) may be used to switch the default working
module for the interactive top level (see prolog/0). This may be
used when debugging a module. The example below lists the clauses
of file_of_label/2 in the module tex.
____________________________________________________________________| |
| 1 ?- module(tex). |
| true. |
| tex: 2 ?- listing(file_of_label/2). |
||..._______________________________________________________________ ||
55..77 CCoommppoossiinngg mmoodduulleess ffrroomm ootthheerr mmoodduulleess
The predicates in this section are intended to create new modules
from the content of other modules. Below is an example to define
a _c_o_m_p_o_s_i_t_e module. The example exports all public predicates of
module_1, module_2 and module_3, pred/1 from module_4, all predicates
from module_5 except do_not_use/1 and all predicates from module_6 while
renaming pred/1 into mypred/1.
________________________________________________________________________| |
|:- module(my_composite, []). |
|:- reexport([ module_1, |
| module_2, |
| module_3 |
| ]). |
|:- reexport(module_4, [ pred/1 ]). |
|:- reexport(module_5, except([do_not_use/1])). |
|:-|reexport(module_6,_except([pred/1_as_mypred]))._____________________ | |
rreeeexxppoorrtt((_+_F_i_l_e_s))
Load and import predicates as use_module/1 and re-export all
imported predicates. The reexport declarations must immediately
follow the module declaration.
rreeeexxppoorrtt((_+_F_i_l_e_, _+_I_m_p_o_r_t))
Import from _F_i_l_e as use_module/2 and re-export the imported
predicates. The reexport declarations must immediately follow the
module declaration.
55..88 OOppeerraattoorrss aanndd mmoodduulleess
Operators (section 4.25) are local to modules, where the initial
table behaves as if it is copied from the module user (see
section 5.10). A specific operator can be disabled inside a module
using :- op(0, Type, Name). Inheritance from the public table can be
restored using :- op(-1, Type, Name).
In addition to using the op/3 directive, operators can be declared in
the module/2 directive as shown below. Such operator declarations
are visible inside the module, and importing such a module makes
the operators visible in the target module. Exporting operators is
typically used by modules that implement sub-languages such as chr (see
chapter 7). The example below is copied from the library clpfd.
________________________________________________________________________| |
|:- module(clpfd, |
| [ op(760, yfx, #<==>), |
| op(750, xfy, #==>), |
| op(750, yfx, #<==), |
| op(740, yfx, #\/), |
| ... |
| (#<==>)/2, |
| (#==>)/2, |
| (#<==)/2, |
| (#\/)/2, |
| ... |
||_________]).__________________________________________________________ ||
55..99 DDyynnaammiicc iimmppoorrttiinngg uussiinngg iimmppoorrtt mmoodduulleess
Until now we discussed the public module interface that is, at least
to some extent, portable between Prolog implementations with a module
system that is derived from Quintus Prolog. The remainder of this
chapter describes the underlying mechanisms that can be used to emulate
other module systems or implement other code-reuse mechanisms.
In addition to built-in predicates, imported predicates and locally
defined predicates, SWI-Prolog modules can also call predicates from
its _i_m_p_o_r_t _m_o_d_u_l_e_s. Each module has a (possibly empty) list of import
modules. In the default setup, each new module has a single import
module, which is user for all normal user modules and system for all
system library modules. Module user imports from system where all
built-in predicates reside. These special modules are described in
more detail in section 5.10.
The list of import modules can be manipulated and queried using the
following predicates, as well as using set_module/1.
iimmppoorrtt__mmoodduullee((_+_M_o_d_u_l_e_, _-_I_m_p_o_r_t)) _[_n_o_n_d_e_t_]
True if _M_o_d_u_l_e inherits directly from _I_m_p_o_r_t. All normal
modules only import from user, which imports from system. The
predicates add_import_module/3 and delete_import_module/2 can be
used to manipulate the import list. See also default_module/2.
ddeeffaauulltt__mmoodduullee((_+_M_o_d_u_l_e_, _-_D_e_f_a_u_l_t)) _[_m_u_l_t_i_]
True if predicates and operators in _D_e_f_a_u_l_t are visible in _M_o_d_u_l_e.
Modules are returned in the same search order used for predicates
and operators. That is, _D_e_f_a_u_l_t is first unified with _M_o_d_u_l_e,
followed by the depth-first transitive closure of import_module/2.
aadddd__iimmppoorrtt__mmoodduullee((_+_M_o_d_u_l_e_, _+_I_m_p_o_r_t_, _+_S_t_a_r_t_O_r_E_n_d))
If _I_m_p_o_r_t is not already an import module for _M_o_d_u_l_e, add it to
this list at the start or end depending on _S_t_a_r_t_O_r_E_n_d. See also
import_module/2 and delete_import_module/2.
ddeelleettee__iimmppoorrtt__mmoodduullee((_+_M_o_d_u_l_e_, _+_I_m_p_o_r_t))
Delete _I_m_p_o_r_t from the list of import modules for _M_o_d_u_l_e. Fails
silently if _I_m_p_o_r_t is not in the list.
One usage scenario of import modules is to define a module that is a
copy of another, but where one or more predicates have an alternative
definition.
55..1100 RReesseerrvveedd MMoodduulleess aanndd uussiinngg tthhee ``uusseerr'' mmoodduullee
As mentioned above, SWI-Prolog contains two special modules. The
first one is the module system. This module contains all built-in
predicates. Module system has no import module. The second special
module is the module user. This module forms the initial working space
of the user. Initially it is empty. The import module of module user
is system, making all built-in predicates available.
All other modules import from the module user. This implies they
can use all predicates imported into user without explicitly importing
them. If an application loads all modules from the user module using
use_module/1, one achieves a scoping system similar to the C-language,
where every module can access all exported predicates without any
special precautions.
55..1111 AAnn aalltteerrnnaattiivvee iimmppoorrtt//eexxppoorrtt iinntteerrffaaccee
The use_module/1 predicate from section 5.3 defines import and export
relations based on the filename from which a module is loaded. If
modules are created differently, such as by asserting predicates into a
new module as described in section 5.12, this interface cannot be used.
The interface below provides for import/export from modules that are
not created using a module file.
eexxppoorrtt((_+_P_r_e_d_i_c_a_t_e_I_n_d_i_c_a_t_o_r_, _._._.))
Add predicates to the public list of the context module. This
implies the predicate will be imported into another module if this
module is imported with use_module/[1,2]. Note that predicates are
normally exported using the directive module/2. export/1 is meant
to handle export from dynamically created modules.
iimmppoorrtt((_+_P_r_e_d_i_c_a_t_e_I_n_d_i_c_a_t_o_r_, _._._.))
Import predicates _P_r_e_d_i_c_a_t_e_I_n_d_i_c_a_t_o_r into the current context
module. _P_r_e_d_i_c_a_t_e_I_n_d_i_c_a_t_o_r must specify the source module using
the <_m_o_d_u_l_e>:<_p_i>construct. Note that predicates are normally
imported using one of the directives use_module/[1,2]. The
import/1 alternative is meant for handling imports into dynamically
created modules. See also export/1 and export_list/2.
55..1122 DDyynnaammiicc MMoodduulleess
So far, we discussed modules that were created by loading a module
file. These modules have been introduced to facilitate the development
of large applications. The modules are fully defined at load-time of
the application and normally will not change during execution. Having
the notion of a set of predicates as a self-contained world can
be attractive for other purposes as well. For example, assume an
application that can reason about multiple worlds. It is attractive
to store the data of a particular world in a module, so we extract
information from a world simply by invoking goals in this world.
Dynamic modules can easily be created. Any built-in predicate that
tries to locate a predicate in a specific module will create this
module as a side-effect if it did not yet exist. For example:
________________________________________________________________________| |
|?- assert(world_a:consistent), |
||__world_a:set_prolog_flag(unknown,_fail)._____________________________ ||
These calls create a module called `world_a' and make the call
`world_a:consistent' succeed. Undefined predicates will not raise an
exception for this module (see unknown).
Import and export from a dynamically created world can be achieved
using import/1 and export/1 or by specifying the import module as
described in section 5.9.
________________________________________________________________________| |
|?- world_b:export(solve/2). % exports solve/2 from world_b |
|?-|world_c:import(world_b:solve/2).__%_and_import_it_to_world_c________ | |
55..1133 TTrraannssppaarreenntt pprreeddiiccaatteess:: ddeeffiinniittiioonn aanndd ccoonntteexxtt mmoodduullee
_T_h_e _`_m_o_d_u_l_e_-_t_r_a_n_s_p_a_r_e_n_t_' _m_e_c_h_a_n_i_s_m _i_s _s_t_i_l_l _u_n_d_e_r_l_y_i_n_g _t_h_e _a_c_t_u_a_l
_i_m_p_l_e_m_e_n_t_a_t_i_o_n_. _D_i_r_e_c_t _u_s_a_g_e _b_y _p_r_o_g_r_a_m_m_e_r_s _i_s _d_e_p_r_e_c_a_t_e_d_. _P_l_e_a_s_e _u_s_e
meta_predicate/1 _t_o _d_e_a_l _w_i_t_h _m_e_t_a_-_p_r_e_d_i_c_a_t_e_s_.
The qualification of module-sensitive arguments described in
section 5.4 is realised using _t_r_a_n_s_p_a_r_e_n_t predicates. It is now
deprecated to use this mechanism directly. However, studying the
underlying mechanism helps to understand SWI-Prolog's modules. In some
respect, the transparent mechanism is more powerful than meta-predicate
declarations.
Each predicate of the program is assigned a module, called its
_d_e_f_i_n_i_t_i_o_n _m_o_d_u_l_e. The definition module of a predicate is always the
module in which the predicate was originally defined. Each active goal
in the Prolog system has a _c_o_n_t_e_x_t _m_o_d_u_l_e assigned to it.
The context module is used to find predicates for a Prolog term. By
default, the context module is the definition module of the predicate
running the goal. For transparent predicates, however, this is the
context module of the goal inherited from the parent goal. Below,
we implement maplist/3 using the transparent mechanism. The code of
maplist/3 and maplist_/3 is the same as in section 5.4, but now we must
declare both the main predicate and the helper as transparent to avoid
changing the context module when calling the helper.
________________________________________________________________________| |
|:- module(maplist, maplist/3). |
| |
|:- module_transparent |
| maplist/3, |
| maplist_/3. |
| |
|maplist(Goal, L1, L2) :- |
| maplist_(L1, L2, G). |
| |
|maplist_([], [], _). |
|maplist_([H0|T0], [H|T], Goal) :- |
| call(Goal, H0, H), |
||_______maplist_(T0,_T,_Goal)._________________________________________ ||
Note that _a_n_y call that translates terms into predicates is
subject to the transparent mechanism, not just the terms passed
to module-sensitive arguments. For example, the module below
counts the number of unique atoms returned as bindings for a
variable. It works as expected. If we use the directive
:- module_transparent count_atom_results/3. instead, atom_result/2 is
called wrongly in the module _c_a_l_l_i_n_g count_atom_results/3. This can
be solved using strip_module/3 to create a qualified goal and a
non-transparent helper predicate that is defined in the same module.
________________________________________________________________________| |
|:- module(count_atom_results, |
| [ count_atom_results/3 |
| ]). |
|:- meta_predicate count_atom_results(-,0,-). |
| |
|count_atom_results(A, Goal, Count) :- |
| setof(A, atom_result(A, Goal), As), !, |
| length(As, Count). |
|count_atom_results(_, _, 0). |
| |
|atom_result(Var, Goal) :- |
| call(Goal), |
||_______atom(Var)._____________________________________________________ ||
The following predicates support the module-transparent interface:
::-- mmoodduullee__ttrraannssppaarreenntt((_+_P_r_e_d_s))
_P_r_e_d_s is a comma-separated list of name/arity pairs (like
dynamic/1). Each goal associated with a transparent-declared
predicate will inherit the _c_o_n_t_e_x_t _m_o_d_u_l_e from its parent goal.
ccoonntteexxtt__mmoodduullee((_-_M_o_d_u_l_e))
Unify _M_o_d_u_l_e with the context module of the current goal.
context_module/1 itself is, of course, transparent.
ssttrriipp__mmoodduullee((_+_T_e_r_m_, _-_M_o_d_u_l_e_, _-_P_l_a_i_n))
Used in module-transparent predicates or meta-predicates to extract
the referenced module and plain term. If _T_e_r_m is a
module-qualified term, i.e. of the format _M_o_d_u_l_e:_P_l_a_i_n, _M_o_d_u_l_e and
_P_l_a_i_n are unified to these values. Otherwise, _P_l_a_i_n is unified to
_T_e_r_m and _M_o_d_u_l_e to the context module.
55..1144 MMoodduullee pprrooppeerrttiieess
The following predicates can be used to query the module system for
reflexive programming:
ccuurrrreenntt__mmoodduullee((_?_M_o_d_u_l_e)) _[_n_o_n_d_e_t_]
True if _M_o_d_u_l_e is a currently defined module. This predicate
enumerates all modules, whether loaded from a file or created
dynamically. Note that modules cannot be destroyed in the current
version of SWI-Prolog.
mmoodduullee__pprrooppeerrttyy((_?_M_o_d_u_l_e_, _?_P_r_o_p_e_r_t_y))
True if _P_r_o_p_e_r_t_y is a property of _M_o_d_u_l_e. Defined properties are:
ccllaassss((_-_C_l_a_s_s))
True when _C_l_a_s_s is the class of the module. Defined classes
are
uusseerr
Default for user-defined modules.
ssyysstteemm
Module system and modules from <_h_o_m_e>/boot.
lliibbrraarryy
Other modules from the system directories.
tteesstt
Modules that create tests.
ddeevveellooppmmeenntt
Modules that only support the development environment.
ffiillee((_?_F_i_l_e))
True if _M_o_d_u_l_e was loaded from _F_i_l_e.
lliinnee__ccoouunntt((_-_L_i_n_e))
True if _M_o_d_u_l_e was loaded from the N-th line of file.
eexxppoorrttss((_-_L_i_s_t_O_f_P_r_e_d_i_c_a_t_e_I_n_d_i_c_a_t_o_r_s))
True if _M_o_d_u_l_e exports the given predicates. Predicate
indicators are in canonical form (i.e., always using
name/arity and never the DCG form name//arity). Future
versions may also use the DCG form and include public
operators. See also predicate_property/2.
eexxppoorrtteedd__ooppeerraattoorrss((_-_L_i_s_t_O_f_O_p_e_r_a_t_o_r_s))
True if _M_o_d_u_l_e exports the given operators. Each exported
operator is represented as a term op(_P_r_i_,_A_s_s_o_c_,_N_a_m_e).
sseett__mmoodduullee((_:_P_r_o_p_e_r_t_y))
Modify properties of the module. Currently, the following
properties may be modified:
bbaassee((_+_B_a_s_e))
Set the default import module of the current module to _M_o_d_u_l_e.
Typically, _M_o_d_u_l_e is one of user or system. See section 5.9.
ccllaassss((_+_C_l_a_s_s))
Set the class of the module. See module_property/2.
55..1155 CCoommppaattiibbiilliittyy ooff tthhee MMoodduullee SSyysstteemm
The SWI-Prolog module system is largely derived from the Quintus
Prolog module system, which is also adopted by SICStus, Ciao and YAP.
Originally, the mechanism for defining meta-predicates in SWI-Prolog
was based on the module_transparent/1 directive and strip_module/3.
Since 5.7.4 it supports the de-facto standard meta_predicate/1
directive for implementing meta-predicates, providing much better
compatibility.
The support for the meta_predicate/1 mechanism, however, is
considerably different. On most systems, the _c_a_l_l_e_r of a
meta-predicate is compiled differently to provide the required
<_m_o_d_u_l_e>:<_t_e_r_m> qualification. This implies that the meta-declaration
must be available to the compiler when compiling code that calls a
meta-predicate. In practice, this implies that other systems pose the
following restrictions on meta-predicates:
o Modules that provide meta-predicates for a module to be compiled
must be loaded explicitly by that module.
o The meta-predicate directives of exported predicates must follow
the module/2 directive immediately.
o After changing a meta-declaration, all modules that _c_a_l_l the
modified predicates need to be recompiled.
In SWI-Prolog, meta-predicates are also _m_o_d_u_l_e_-_t_r_a_n_s_p_a_r_e_n_t, and
qualifying the module-sensitive arguments is done inside the meta-
predicate. As a result, the caller need not be aware that it is
calling a meta-predicate and none of the above restrictions hold for
SWI-Prolog. However, code that aims at portability must obey the above
rules.
Other differences are listed below.
o If a module does not define a predicate, it is searched for in the
_i_m_p_o_r_t _m_o_d_u_l_e_s. By default, the import module of any user-defined
module is the user module. In turn, the user module imports from
the module system that provides all built-in predicates. The
auto-import hierarchy can be changed using add_import_module/3 and
delete_import_module/2.
This mechanism can be used to realise a simple object-oriented
system or a hierarchical module system.
o Operator declarations are local to a module and may be exported.
In Quintus and SICStus all operators are global. YAP and Ciao
also use local operators. SWI-Prolog provides global operator
declarations from within a module by explicitly qualifying the
operator name with the user module. I.e., operators are inherited
from the _i_m_p_o_r_t _m_o_d_u_l_e_s (see above).
____________________________________________________________________| |
||:-_op(precedence,_type,_user:(operatorname))._____________________ ||
CChhaapptteerr 66.. SSPPEECCIIAALL VVAARRIIAABBLLEESS AANNDD CCOORROOUUTTIINNIINNGG
This chapter deals with extensions primarily designed to support
constraint logic programming (CLP). The low-level attributed variable
interface defined in section 6.1 is not intended for the typical Prolog
programmer. Instead, the typical Prolog programmer should use the
coroutining predicates and the various constraint solvers built on top
of attributed variables. CHR (chapter 7) provides a general purpose
constraint handling language.
As a rule of thumb, constraint programming reduces the search space
by reordering goals and joining goals based on domain knowledge. A
typical example is constraint reasoning over integer domains. Plain
Prolog has no efficient means to deal with (integer) X >0 and X <3.
At best it could translate X >0 with uninstantiated X to between(_1_,
_i_n_f_i_n_i_t_e_, _X) and a similar primitive for X< 3. If the two are
combined it has no choice but to generate and test over this infinite
two-dimensional space. Instead, a constraint system will _d_e_l_a_y an
uninstantiated goal to X> 0. If, later, it finds a value for _X
it will execute the test. If it finds X< 3 it will combine this
knowledge to infer that X is in 1..2 (see below). If it never finds a
concrete value for _X it can be asked to _l_a_b_e_l _X and produce 1 and 2 on
backtracking. See section 11.7.
________________________________________________________________________| |
|1 ?- [library(clpfd)]. |
|... |
|true. |
| |
|2 ?- X #> 0, X #< 3. |
|X|in_1..2._____________________________________________________________ | |
Using constraints generally makes your program more _d_e_c_l_a_r_a_t_i_v_e. There
are some caveats though:
o Constraints and cuts do not merge well. A cut after a goal that is
delayed prunes the search space before the condition is true.
o Term-copying operations (assert/1, retract/2, findall/3,
copy_term/2, etc.) generally also copy constraints. The
effect varies from ok, silent copying of huge constraint networks
to violations of the internal consistency of constraint networks.
As a rule of thumb, copying terms holding attributes must be
deprecated.
66..11 AAttttrriibbuutteedd vvaarriiaabblleess
_A_t_t_r_i_b_u_t_e_d _v_a_r_i_a_b_l_e_s provide a technique for extending the Prolog
unification algorithm [Holzbaur, 1992] by hooking the binding of
attributed variables. There is no consensus in the Prolog community
on the exact definition and interface to attributed variables. The
SWI-Prolog interface is identical to the one realised by Bart Demoen
for hProlog [Demoen, 2002]. This interface is simple and available on
all Prolog systems that can run the Leuven CHR system (see chapter 7
and the Leuven CHR page).
Binding an attributed variable schedules a goal to be executed at
the first possible opportunity. In the current implementation the
hooks are executed immediately after a successful unification of the
clause-head or successful completion of a foreign language (built-in)
predicate. Each attribute is associated to a module, and the hook
(attr_unify_hook/2) is executed in this module. The example below
realises a very simple and incomplete finite domain reasoner:
________________________________________________________________________| |
|:- module(domain, |
| [ domain/2 % Var, ?Domain |
| ]). |
|:- use_module(library(ordsets)). |
| |
|domain(X, Dom) :- |
| var(Dom), !, |
| get_attr(X, domain, Dom). |
|domain(X, List) :- |
| list_to_ord_set(List, Domain), |
| put_attr(Y, domain, Domain), |
| X = Y. |
| |
|% An attributed variable with attribute value Domain has been |
|% assigned the value Y |
| |
|attr_unify_hook(Domain, Y) :- |
| ( get_attr(Y, domain, Dom2) |
| -> ord_intersection(Domain, Dom2, NewDomain), |
| ( NewDomain == [] |
| -> fail |
| ; NewDomain = [Value] |
| -> Y = Value |
| ; put_attr(Y, domain, NewDomain) |
| ) |
| ; var(Y) |
| -> put_attr( Y, domain, Domain ) |
| ; ord_memberchk(Y, Domain) |
| ). |
| |
|% Translate attributes from this module to residual goals |
| |
|attribute_goals(X) --> |
| { get_attr(X, domain, List) }, |
||_______[domain(X,_List)]._____________________________________________ ||
Before explaining the code we give some example queries:
?- domain(X, [a,b]), X = c fail
?- domain(X, [a,b]), domain(X, [a,c]). X = a
?- domain(X, [a,b,c]), domain(X, [a,c]). domain(X, [a, c])
The predicate domain/2 fetches (first clause) or assigns (second
clause) the variable a _d_o_m_a_i_n, a set of values the variable can
be unified with. In the second clause, domain/2 first associates
the domain with a fresh variable (Y) and then unifies X to this
variable to deal with the possibility that X already has a domain.
The predicate attr_unify_hook/2 (see below) is a hook called after a
variable with a domain is assigned a value. In the simple case where
the variable is bound to a concrete value, we simply check whether this
value is in the domain. Otherwise we take the intersection of the
domains and either fail if the intersection is empty (first example),
assign the value if there is only one value in the intersection
(second example), or assign the intersection as the new domain of the
variable (third example). The nonterminal attribute_goals/3 is used
to translate remaining attributes to user-readable goals that, when
executed, reinstate these attributes.
66..11..11 AAttttrriibbuuttee mmaanniippuullaattiioonn pprreeddiiccaatteess
aattttvvaarr((_@_T_e_r_m))
Succeeds if _T_e_r_m is an attributed variable. Note that var/1 also
succeeds on attributed variables. Attributed variables are created
with put_attr/3.
ppuutt__aattttrr((_+_V_a_r_, _+_M_o_d_u_l_e_, _+_V_a_l_u_e))
If _V_a_r is a variable or attributed variable, set the value for
the attribute named _M_o_d_u_l_e to _V_a_l_u_e. If an attribute with this
name is already associated with _V_a_r, the old value is replaced.
Backtracking will restore the old value (i.e., an attribute is
a mutable term; see also setarg/3). This predicate raises a
representation error if _V_a_r is not a variable and a type error if
_M_o_d_u_l_e is not an atom.
ggeett__aattttrr((_+_V_a_r_, _+_M_o_d_u_l_e_, _-_V_a_l_u_e))
Request the current _v_a_l_u_e for the attribute named _M_o_d_u_l_e. If
_V_a_r is not an attributed variable or the named attribute is not
associated to _V_a_r this predicate fails silently. If _M_o_d_u_l_e is not
an atom, a type error is raised.
ddeell__aattttrr((_+_V_a_r_, _+_M_o_d_u_l_e))
Delete the named attribute. If _V_a_r loses its last attribute it
is transformed back into a traditional Prolog variable. If _M_o_d_u_l_e
is not an atom, a type error is raised. In all other cases this
predicate succeeds regardless of whether or not the named attribute
is present.
66..11..22 AAttttrriibbuutteedd vvaarriiaabbllee hhooookkss
Attribute names are linked to modules. This means that certain
operations on attributed variables cause _h_o_o_k_s to be called in the
module whose name matches the attribute name.
aattttrr__uunniiffyy__hhooookk((_+_A_t_t_V_a_l_u_e_, _+_V_a_r_V_a_l_u_e))
A hook that must be defined in the module to which an attributed
variable refers. It is called _a_f_t_e_r the attributed variable has
been unified with a non-var term, possibly another attributed
variable. _A_t_t_V_a_l_u_e is the attribute that was associated to the
variable in this module and _V_a_r_V_a_l_u_e is the new value of the
variable. Normally this predicate fails to veto binding the
variable to _V_a_r_V_a_l_u_e, forcing backtracking to undo the binding. If
_V_a_r_V_a_l_u_e is another attributed variable the hook often combines the
two attributes and associates the combined attribute with _V_a_r_V_a_l_u_e
using put_attr/3.
aattttrr__ppoorrttrraayy__hhooookk((_+_A_t_t_V_a_l_u_e_, _+_V_a_r))
Called by write_term/2and friends for each attribute if the option
attributes(_p_o_r_t_r_a_y) is in effect. If the hook succeeds the
attribute is considered printed. Otherwise Module = ... is printed
to indicate the existence of a variable. New infrastructure
dealing with communicating attribute values must be based on
copy_term/3 and its hook attribute_goals//1.
aattttrriibbuuttee__ggooaallss((_+_V_a_r)) //
This nonterminal, if it is defined in a module, is used by
copy_term/3 to project attributes of that module to residual goals.
It is also used by the top level to obtain residual goals after
executing a query.
66..11..33 OOppeerraattiioonnss oonn tteerrmmss wwiitthh aattttrriibbuutteedd vvaarriiaabblleess
ccooppyy__tteerrmm((_+_T_e_r_m_, _-_C_o_p_y_, _-_G_s))
Create a regular term _C_o_p_y as a copy of _T_e_r_m (without any
attributes), and a list _G_s of goals that represents the attributes.
The goal maplist(call,_G_s) recreates the attributes for _C_o_p_y. The
nonterminal attribute_goals//1, as defined in the modules the
attributes stem from, is used to convert attributes to lists of
goals.
This building block is used by the top level to report pending
attributes in a portable and understandable fashion. This
predicate is the preferred way to reason about and communicate
terms with constraints.
ccooppyy__tteerrmm__nnaatt((_+_T_e_r_m_, _-_C_o_p_y))
As copy_term/2. Attributes, however, are _n_o_t copied but replaced
by fresh variables.
tteerrmm__aattttvvaarrss((_+_T_e_r_m_, _-_A_t_t_V_a_r_s))
_A_t_t_V_a_r_s is a list of all attributed variables in _T_e_r_m and
its attributes. That is, term_attvars/2 works recursively
through attributes. This predicate is cycle-safe. The goal
term_attvars(_T_e_r_m_, _[_]) in an efficient test that _T_e_r_m has _n_o
attributes; scanning the term is aborted after the first attributed
variable is found.
66..11..44 SSppeecciiaall ppuurrppoossee pprreeddiiccaatteess ffoorr aattttrriibbuutteess
Normal user code should deal with put_attr/3, get_attr/3 and del_attr/2.
The routines in this section fetch or set the entire attribute list of
a variable. Use of these predicates is anticipated to be restricted to
printing and other special purpose operations.
ggeett__aattttrrss((_+_V_a_r_, _-_A_t_t_r_i_b_u_t_e_s))
Get all attributes of _V_a_r. _A_t_t_r_i_b_u_t_e_s is a term of the form
att(_M_o_d_u_l_e_, _V_a_l_u_e_, _M_o_r_e_A_t_t_r_i_b_u_t_e_s), where _M_o_r_e_A_t_t_r_i_b_u_t_e_s is [] for
the last attribute.
ppuutt__aattttrrss((_+_V_a_r_, _-_A_t_t_r_i_b_u_t_e_s))
Set all attributes of _V_a_r. See get_attrs/2 for a description of
_A_t_t_r_i_b_u_t_e_s.
ddeell__aattttrrss((_+_V_a_r))
If _V_a_r is an attributed variable, delete _a_l_l its attributes. In
all other cases, this predicate succeeds without side-effects.
66..22 CCoorroouuttiinniinngg
Coroutining deals with having Prolog goals scheduled for execution
as soon as some conditions are fulfilled. In Prolog the most
commonly used condition is the instantiation (binding) of a variable.
Scheduling a goal to execute immediately after a variable is bound
can be used to avoid instantiation errors for some built-in predicates
(e.g. arithmetic), do work _l_a_z_y, prevent the binding of a variable to
a particular value, etc. Using freeze/2 for example we can define a
variable that can only be assigned an even number:
________________________________________________________________________| |
|?- freeze(X, X mod 2 =:= 0), X = 3 |
| |
|No|____________________________________________________________________ | |
ffrreeeezzee((_+_V_a_r_, _:_G_o_a_l))
Delay the execution of _G_o_a_l until _V_a_r is bound (i.e. is not a
variable or attributed variable). If _V_a_r is bound on entry
freeze/2 is equivalent to call/1. The freeze/2 predicate is
realised using an attributed variable associated with the module
freeze. Use frozen(Var, Goal) to find out whether and which goals
are delayed on _V_a_r.
ffrroozzeenn((_@_V_a_r_, _-_G_o_a_l))
Unify _G_o_a_l with the goal or conjunction of goals delayed on _V_a_r.
If no goals are frozen on _V_a_r, _G_o_a_l is unified to true.
wwhheenn((_@_C_o_n_d_i_t_i_o_n_, _:_G_o_a_l))
Execute _G_o_a_l when _C_o_n_d_i_t_i_o_n becomes true. _C_o_n_d_i_t_i_o_n is one of
?=(_X_, _Y), nonvar(_X), ground(_X), ,(_C_o_n_d_1_, _C_o_n_d_2) or ;(_C_o_n_d_1_, _C_o_n_d_2).
See also freeze/2 and dif/2. The implementation can deal with
cyclic terms in _X and _Y.
The when/2 predicate is realised using attributed variables
associated with the module when. It is defined in the autoload
library when.
ddiiff((_@_A_, _@_B))
The dif/2 predicate provides a constraint stating that _A and _B
are different terms. If _A and _B can never unify, dif/2 succeeds
deterministically. If _A and _B are identical it fails immediately,
and finally, if _A and _B can unify, goals are delayed that prevent
_A and _B to become equal. The dif/2 predicate behaves as if
defined by dif(X, Y) :- when(?=(X, Y), X \== Y). See also ?=/2.
The implementation can deal with cyclic terms.
The dif/2 predicate is realised using attributed variables
associated with the module dif. It is defined in the autoload
library dif.
ccaallll__rreessiidduuee__vvaarrss((_:_G_o_a_l_, _-_V_a_r_s))
Find residual attributed variables left by _G_o_a_l. This predicate is
intended for debugging programs using coroutining or constraints.
Consider a program that poses contradicting constraints on a
variable. Such programs should fail, but sometimes succeed because
the constraint solver is too weak to detect the contradiction.
Ideally, delayed goals and constraints are all executed at the end
of the computation. The meta predicate call_residue_vars/2 finds
variables that are given attribute variables or whose attributes
are modified by _G_o_a_l, regardless of whether or not these variables
are reachable from the arguments of _G_o_a_l.
The predicate has considerable implications. During the execution
of _G_o_a_l, the garbage collector does not reclaim attributed
variables. This causes some degradation of GC performance. In
a well-behaved program there are no such variables, so the space
impact is generally minimal. The actual collection of _V_a_r_s is
implemented using a scan of the trail and global stacks.
66..33 GGlloobbaall vvaarriiaabblleess
Global variables are associations between names (atoms) and terms.
They differ in various ways from storing information using assert/1 or
recorda/3.
o The value lives on the Prolog (global) stack. This implies that
lookup time is independent of the size of the term. This is
particularly interesting for large data structures such as parsed
XML documents or the CHR global constraint store.
o They support both global assignment using nb_setval/2 and
backtrackable assignment using b_setval/2.
o Only one value (which can be an arbitrary complex Prolog term) can
be associated to a variable at a time.
o Their value cannot be shared among threads. Each thread has its
own namespace and values for global variables.
o Currently global variables are scoped globally. We may consider
module scoping in future versions.
Both b_setval/2 and nb_setval/2 implicitly create a variable if the
referenced name does not already refer to a variable.
Global variables may be initialised from directives to make them
available during the program lifetime, but some considerations are
necessary for saved states and threads. Saved states do not
store global variables, which implies they have to be declared with
initialization/1 to recreate them after loading the saved state. Each
thread has its own set of global variables, starting with an empty
set. Using thread_initialization/1 to define a global variable it will
be defined, restored after reloading a saved state and created in all
threads that are created _a_f_t_e_r the registration. Finally, global
variables can be initialised using the exception hook exception/3. The
latter technique is used by CHR (see chapter 7).
bb__sseettvvaall((_+_N_a_m_e_, _+_V_a_l_u_e))
Associate the term _V_a_l_u_e with the atom _N_a_m_e or replace the
currently associated value with _V_a_l_u_e. If _N_a_m_e does not refer
to an existing global variable, a variable with initial value []
is created (the empty list). On backtracking the assignment is
reversed.
bb__ggeettvvaall((_+_N_a_m_e_, _-_V_a_l_u_e))
Get the value associated with the global variable _N_a_m_e and unify it
with _V_a_l_u_e. Note that this unification may further instantiate the
value of the global variable. If this is undesirable the normal
precautions (double negation or copy_term/2) must be taken. The
b_getval/2 predicate generates errors if _N_a_m_e is not an atom or the
requested variable does not exist.
nnbb__sseettvvaall((_+_N_a_m_e_, _+_V_a_l_u_e))
Associates a copy of _V_a_l_u_e created with duplicate_term/2 with the
atom _N_a_m_e. Note that this can be used to set an initial value
other than [] prior to backtrackable assignment.
nnbb__ggeettvvaall((_+_N_a_m_e_, _-_V_a_l_u_e))
The nb_getval/2 predicate is a synonym for b_getval/2, introduced
for compatibility and symmetry. As most scenarios will use
a particular global variable using either non-backtrackable or
backtrackable assignment, using nb_getval/2can be used to document
that the variable is non-backtrackable.
nnbb__lliinnkkvvaall((_+_N_a_m_e_, _+_V_a_l_u_e))
Associates the term _V_a_l_u_e with the atom _N_a_m_e without copying it.
This is a fast special-purpose variation of nb_setval/2 intended
for expert users only because the semantics on backtracking
to a point before creating the link are poorly defined for
compound terms. The principal term is always left untouched,
but backtracking behaviour on arguments is undone if the original
assignment was _t_r_a_i_l_e_d and left alone otherwise, which implies
that the history that created the term affects the behaviour on
backtracking. Consider the following example:
____________________________________________________________________| |
| demo_nb_linkval :- |
| T = nice(N), |
| ( N = world, |
| nb_linkval(myvar, T), |
| fail |
| ; nb_getval(myvar, V), |
| writeln(V) |
||________).________________________________________________________ ||
nnbb__ccuurrrreenntt((_?_N_a_m_e_, _?_V_a_l_u_e))
Enumerate all defined variables with their value. The order of
enumeration is undefined.
nnbb__ddeelleettee((_+_N_a_m_e))
Delete the named global variable.
66..33..11 CCoommppaattiibbiilliittyy ooff SSWWII--PPrroolloogg GGlloobbaall VVaarriiaabblleess
Global variables have been introduced by various Prolog implementations
recently. The implementation of them in SWI-Prolog is based on hProlog
by Bart Demoen. In discussion with Bart it was decided that the
semantics of hProlog nb_setval/2, which is equivalent to nb_linkval/2,
is not acceptable for normal Prolog users as the behaviour is
influenced by how built-in predicates that construct terms (read/1,
=../2, etc.) are implemented.
GNU-Prolog provides a rich set of global variables, including arrays.
Arrays can be implemented easily in SWI-Prolog using functor/3 and
setarg/3 due to the unrestricted arity of compound terms.
CChhaapptteerr 77.. CCHHRR:: CCOONNSSTTRRAAIINNTT HHAANNDDLLIINNGG RRUULLEESS
This chapter is written by Tom Schrijvers, K.U. Leuven, and adjustments
by Jan Wielemaker.
The CHR system of SWI-Prolog is the _K_._U_._L_e_u_v_e_n _C_H_R _s_y_s_t_e_m. The runtime
environment is written by Christian Holzbaur and Tom Schrijvers while
the compiler is written by Tom Schrijvers. Both are integrated with
SWI-Prolog and licensed under compatible conditions with permission
from the authors.
The main reference for the K.U.Leuven CHR system is:
o T. Schrijvers, and B. Demoen, _T_h_e _K_._U_._L_e_u_v_e_n _C_H_R _S_y_s_t_e_m_:
_I_m_p_l_e_m_e_n_t_a_t_i_o_n _a_n_d _A_p_p_l_i_c_a_t_i_o_n, First Workshop on Constraint
Handling Rules: Selected Contributions (Fr"uhwirth, T. and Meister,
M., eds.), pp. 1--5, 2004.
On the K.U.Leuven CHR website (http://dtai.cs.kuleuven.be/CHR/) you can
find more related papers, references and example programs.
77..11 IInnttrroodduuccttiioonn
Constraint Handling Rules (CHR) is a committed-choice rule-based
language embedded in Prolog. It is designed for writing constraint
solvers and is particularly useful for providing application-specific
constraints. It has been used in many kinds of applications, like
scheduling, model checking, abduction, and type checking, among many
others.
CHR has previously been implemented in other Prolog systems (SICStus,
Eclipse, Yap), Haskell and Java. This CHR system is based on the
compilation scheme and runtime environment of CHR in SICStus.
In this documentation we restrict ourselves to giving a short overview
of CHR in general and mainly focus on elements specific to this
implementation. For a more thorough review of CHR we refer the
reader to [Fr"uhwirth, 2009]. More background on CHR can be found at
[Fr"uhwirth,].
In section 7.2 we present the syntax of CHR in Prolog and explain
informally its operational semantics. Next, section 7.3 deals with
practical issues of writing and compiling Prolog programs containing
CHR. Section 7.4 explains the (currently primitive) CHR debugging
facilities. Section 7.4.3 provides a few useful predicates to inspect
the constraint store, and section 7.5 illustrates CHR with two example
programs. Section 7.6 describes some compatibility issues with older
versions of this system and SICStus' CHR system. Finally, section 7.7
concludes with a few practical guidelines for using CHR.
77..22 SSyynnttaaxx aanndd SSeemmaannttiiccss
77..22..11 SSyynnttaaxx ooff CCHHRR rruulleess
________________________________________________________________________________________________________________________________________________|| ||
||rules --> rule, rules ; []. |
| |
|rule --> name, actual_rule, pragma, [atom('.')]. |
| |
|name --> atom, [atom('@')] ; []. |
| |
|actual_rule --> simplification_rule. |
|actual_rule --> propagation_rule. |
|actual_rule --> simpagation_rule. |
| |
|simplification_rule --> head, [atom('<=>')], guard, body. |
|propagation_rule --> head, [atom('==>')], guard, body. |
|simpagation_rule --> head, [atom('\')], head, [atom('<=>')], |
| guard, body. |
| |
|head --> constraints. |
| |
|constraints --> constraint, constraint_id. |
|constraints --> constraint, constraint_id, |
| [atom(',')], constraints. |
| |
|constraint --> compound_term. |
| |
|constraint_id --> []. |
|constraint_id --> [atom('#')], variable. |
|constraint_id --> [atom('#')], [atom('passive')] . |
| |
|guard --> [] ; goal, [atom('|')]. |
| |
|body --> goal. |
| |
|pragma --> []. |
|pragma --> [atom('pragma')], actual_pragmas. |
| |
|actual_pragmas --> actual_pragma. |
|actual_pragmas --> actual_pragma, [atom(',')], actual_pragmas. |
| |
|actual_pragma|-->_[atom('passive(')],_variable,_[atom(')')].___________ | |
Note that the guard of a rule may not contain any goal that binds a
variable in the head of the rule with a non-variable or with another
variable in the head of the rule. It may, however, bind variables
that do not appear in the head of the rule, e.g. an auxiliary variable
introduced in the guard.
77..22..22 SSeemmaannttiiccss
In this subsection the operational semantics of CHR in Prolog are
presented informally. They do not differ essentially from other CHR
systems.
When a constraint is called, it is considered an active constraint and
the system will try to apply the rules to it. Rules are tried and
executed sequentially in the order they are written.
A rule is conceptually tried for an active constraint in the following
way. The active constraint is matched with a constraint in the head of
the rule. If more constraints appear in the head, they are looked for
among the suspended constraints, which are called passive constraints
in this context. If the necessary passive constraints can be found and
all match with the head of the rule and the guard of the rule succeeds,
then the rule is committed and the body of the rule executed. If not
all the necessary passive constraints can be found, or the matching
or the guard fails, then the body is not executed and the process of
trying and executing simply continues with the following rules. If
for a rule there are multiple constraints in the head, the active
constraint will try the rule sequentially multiple times, each time
trying to match with another constraint.
This process ends either when the active constraint disappears, i.e. it
is removed by some rule, or after the last rule has been processed. In
the latter case the active constraint becomes suspended.
A suspended constraint is eligible as a passive constraint for an
active constraint. The other way it may interact again with the rules
is when a variable appearing in the constraint becomes bound to either
a non-variable or another variable involved in one or more constraints.
In that case the constraint is triggered, i.e. it becomes an active
constraint and all the rules are tried.
RRuullee TTyyppeess There are three different kinds of rules, each with its
specific semantics:
o _s_i_m_p_l_i_f_i_c_a_t_i_o_n
The simplification rule removes the constraints in its head and
calls its body.
o _p_r_o_p_a_g_a_t_i_o_n
The propagation rule calls its body exactly once for the
constraints in its head.
o _s_i_m_p_a_g_a_t_i_o_n
The simpagation rule removes the constraints in its head after the
\ and then calls its body. It is an optimization of simplification
rules of the form:
constraints1;constraints2<=> constraints1;body
Namely, in the simpagation form:
constraints1\constraints2<=> body
The constraints1constraints are not called in the body.
RRuullee NNaammeess
Naming a rule is optional and has no semantic meaning. It only
functions as documentation for the programmer.
PPrraaggmmaass The semantics of the pragmas are:
ppaassssiivvee((_I_d_e_n_t_i_f_i_e_r))
The constraint in the head of a rule _I_d_e_n_t_i_f_i_e_r can only match a
passive constraint in that rule. There is an abbreviated syntax
for this pragma. Instead of:
____________________________________________________________________| |
||________________...,_c_#_Id,_..._<=>_..._pragma_passive(Id)_______ ||
you can also write
____________________________________________________________________| |
||________________...,_c_#_passive,_..._<=>_..._____________________ ||
Additional pragmas may be released in the future.
::-- cchhrr__ooppttiioonn((_+_O_p_t_i_o_n_, _+_V_a_l_u_e))
It is possible to specify options that apply to all the CHR
rules in the module. Options are specified with the chr_option/2
declaration:
____________________________________________________________________| |
||:-_chr_option(Option,Value).______________________________________ ||
and may appear in the file anywhere after the first constraints
declaration.
Available options are:
cchheecckk__gguuaarrdd__bbiinnddiinnggss
This option controls whether guards should be checked for
(illegal) variable bindings or not. Possible values for this
option are on to enable the checks, and off to disable the
checks. If this option is on, any guard fails when it binds
a variable that appears in the head of the rule. When the
option is off (default), the behaviour of a binding in the
guard is undefined.
ooppttiimmiizzee
This option controls the degree of optimization. Possible
values are full to enable all available optimizations, and
off (default) to disable all optimizations. The default
is derived from the SWI-Prolog flag optimise, where true is
mapped to full. Therefore the command line option -O provides
full CHR optimization. If optimization is enabled, debugging
must be disabled.
ddeebbuugg
This option enables or disables the possibility to debug the
CHR code. Possible values are on (default) and off. See
section 7.4 for more details on debugging. The default is
derived from the Prolog flag generate_debug_info, which is
true by default. See -nodebug. If debugging is enabled,
optimization must be disabled.
77..33 CCHHRR iinn SSWWII--PPrroolloogg PPrrooggrraammss
77..33..11 EEmmbbeeddddiinngg iinn PPrroolloogg PPrrooggrraammss
The CHR constraints defined in a .pl file are associated with a module.
The default module is user. One should never load different .pl files
with the same CHR module name.
77..33..22 CCoonnssttrraaiinntt ddeeccllaarraattiioonn
::-- cchhrr__ccoonnssttrraaiinntt((_+_S_p_e_c_i_f_i_e_r))
Every constraint used in CHR rules has to be declared with a
chr_constraint/1 declaration by the _c_o_n_s_t_r_a_i_n_t _s_p_e_c_i_f_i_e_r. For
convenience multiple constraints may be declared at once with the
same chr_constraint/1 declaration followed by a comma-separated
list of constraint specifiers.
A constraint specifier is, in its compact form, F/A where F and
A are respectively the functor name and arity of the constraint,
e.g.:
____________________________________________________________________| |
| :- chr_constraint foo/1. |
||:-_chr_constraint_bar/2,_baz/3.___________________________________ ||
In its extended form, a constraint specifier is c(A1,...,An) where
c is the constraint's functor, n its arity and the Aiare argument
specifiers. An argument specifier is a mode, optionally followed
by a type. Example:
____________________________________________________________________| |
| :- chr_constraint get_value(+,?). |
| :- chr_constraint domain(?int, +list(int)), |
||__________________alldifferent(?list(int))._______________________ ||
MMooddeess
A mode is one of:
-
The corresponding argument of every occurrence of the constraint is
always unbound.
+
The corresponding argument of every occurrence of the constraint is
always ground.
?
The corresponding argument of every occurrence of the constraint
can have any instantiation, which may change over time. This is
the default value.
TTyyppeess
A type can be a user-defined type or one of the built-in types. A type
comprises a (possibly infinite) set of values. The type declaration
for a constraint argument means that for every instance of that
constraint the corresponding argument is only ever bound to values in
that set. It does not state that the argument necessarily has to be
bound to a value.
The built-in types are:
iinntt
The corresponding argument of every occurrence of the constraint is
an integer number.
ddeennssee__iinntt
The corresponding argument of every occurrence of the constraint is
an integer that can be used as an array index. Note that if this
argument takes values in [0; n], the array takes O(n) space.
ffllooaatt
...a floating point number.
nnuummbbeerr
...a number.
nnaattuurraall
...a positive integer.
aannyy
The corresponding argument of every occurrence of the constraint
can have any type. This is the default value.
::-- cchhrr__ttyyppee((_+_T_y_p_e_D_e_c_l_a_r_a_t_i_o_n))
User-defined types are algebraic data types, similar to those in
Haskell or the discriminated unions in Mercury. An algebraic data
type is defined using chr_type/1:
____________________________________________________________________| |
||:-_chr_type_type_--->_body._______________________________________ ||
If the type term is a functor of arity zero (i.e. one having zero
arguments), it names a monomorphic type. Otherwise, it names a
polymorphic type; the arguments of the functor must be distinct
type variables. The body term is defined as a sequence of
constructor definitions separated by semi-colons.
Each constructor definition must be a functor whose arguments
(if any) are types. Discriminated union definitions must be
transparent: all type variables occurring in the body must also
occur in the type.
Here are some examples of algebraic data type definitions:
____________________________________________________________________| |
| :- chr_type color ---> red ; blue ; yellow ; green. |
| |
| :- chr_type tree ---> empty ; leaf(int) ; branch(tree, tree). |
| |
| :- chr_type list(T) ---> [] ; [T | list(T)]. |
| |
||:-_chr_type_pair(T1,_T2)_--->_(T1_-_T2).__________________________ ||
Each algebraic data type definition introduces a distinct type.
Two algebraic data types that have the same bodies are considered
to be distinct types (name equivalence).
Constructors may be overloaded among different types: there may be
any number of constructors with a given name and arity, so long as
they all have different types.
Aliases can be defined using ==. For example, if your program uses
lists of lists of integers, you can define an alias as follows:
____________________________________________________________________| |
||:-_chr_type_lli_==_list(list(int))._______________________________ ||
TTyyppee CChheecckkiinngg
Currently two complementary forms of type checking are performed:
1. Static type checking is always performed by the compiler. It is
limited to CHR rule heads and CHR constraint calls in rule bodies.
Two kinds of type error are detected. The first is where a
variable has to belong to two types. For example, in the program:
____________________________________________________________________| |
| :-chr_type foo ---> foo. |
| :-chr_type bar ---> bar. |
| |
| :-chr_constraint abc(?foo). |
| :-chr_constraint def(?bar). |
| |
||foobar_@_abc(X)_<=>_def(X)._______________________________________ ||
the variable X has to be of both type foo and bar. This is
reported as a type clash error:
____________________________________________________________________| |
| CHR compiler ERROR: |
| `--> Type clash for variable _ in rule foobar: |
| expected type foo in body goal def(_, _) |
||________________expected_type_bar_in_head_def(_,__)_______________ ||
The second kind of error is where a functor is used that does not
belong to the declared type. For example in:
____________________________________________________________________| |
| :- chr_type foo ---> foo. |
| :- chr_type bar ---> bar. |
| |
| :- chr_constraint abc(?foo). |
| |
||foo_@_abc(bar)_<=>_true.__________________________________________ ||
bar appears in the head of the rule where something of type foo is
expected. This is reported as:
____________________________________________________________________| |
| CHR compiler ERROR: |
| `--> Invalid functor in head abc(bar) of rule foo: |
| found `bar', |
||________________expected_type_`foo'!______________________________ ||
No runtime overhead is incurred in static type checking.
2. Dynamic type checking checks at runtime, during program execution,
whether the arguments of CHR constraints respect their declared
types. The when/2 co-routining library is used to delay dynamic
type checks until variables are instantiated.
The kind of error detected by dynamic type checking is where a
functor is used that does not belong to the declared type. For
example, for the program:
____________________________________________________________________| |
| :-chr_type foo ---> foo. |
| |
||:-chr_constraint_abc(?foo)._______________________________________ ||
we get the following error in an erroneous query:
____________________________________________________________________| |
| ?- abc(bar). |
| ERROR: Type error: `foo' expected, found `bar' |
||_______(CHR_Runtime_Type_Error)___________________________________ ||
Dynamic type checking is weaker than static type checking in the
sense that it only checks the particular program execution at hand
rather than all possible executions. It is stronger in the sense
that it tracks types throughout the whole program.
Note that it is enabled only in debug mode, as it incurs some
(minor) runtime overhead.
77..33..33 CCoommppiillaattiioonn
The SWI-Prolog CHR compiler exploits term_expansion/2 rules to
translate the constraint handling rules to plain Prolog. These rules
are loaded from the library chr. They are activated if the compiled
file has the .chr extension or after finding a declaration in the
following format:
________________________________________________________________________| |
|:-|chr_constraint_...__________________________________________________ | |
It is advised to define CHR rules in a module file, where the module
declaration is immediately followed by including the library(chr)
library as exemplified below:
________________________________________________________________________| |
|:- module(zebra, [ zebra/0 ]). |
|:- use_module(library(chr)). |
| |
|:-|chr_constraint_...__________________________________________________ | |
Using this style, CHR rules can be defined in ordinary Prolog .pl files
and the operator definitions required by CHR do not leak into modules
where they might cause conflicts.
77..44 DDeebbuuggggiinngg
The CHR debugging facilities are currently rather limited. Only
tracing is currently available. To use the CHR debugging facilities
for a CHR file it must be compiled for debugging. Generating debug
info is controlled by the CHR option debug, whose default is derived
from the SWI-Prolog flag generate_debug_info. Therefore debug info is
provided unless the -nodebug is used.
77..44..11 PPoorrttss
For CHR constraints the four standard ports are defined:
ccaallll
A new constraint is called and becomes active.
eexxiitt
An active constraint exits: it has either been inserted in
the store after trying all rules or has been removed from the
constraint store.
ffaaiill
An active constraint fails.
rreeddoo
An active constraint starts looking for an alternative solution.
In addition to the above ports, CHR constraints have five additional
ports:
wwaakkee
A suspended constraint is woken and becomes active.
iinnsseerrtt
An active constraint has tried all rules and is suspended in the
constraint store.
rreemmoovvee
An active or passive constraint is removed from the constraint
store.
ttrryy
An active constraint tries a rule with possibly some passive
constraints. The try port is entered just before committing to the
rule.
aappppllyy
An active constraint commits to a rule with possibly some passive
constraints. The apply port is entered just after committing to
the rule.
77..44..22 TTrraacciinngg
Tracing is enabled with the chr_trace/0 predicate and disabled with the
chr_notrace/0 predicate.
When enabled the tracer will step through the call, exit, fail, wake
and apply ports, accepting debug commands, and simply write out the
other ports.
The following debug commands are currently supported:
CHR debug options:
<cr> creep c creep
s skip
g ancestors
n nodebug
b break
a abort
f fail
? help h help
Their meaning is:
ccrreeeepp
Step to the next port.
sskkiipp
Skip to exit port of this call or wake port.
aanncceessttoorrss
Print list of ancestor call and wake ports.
nnooddeebbuugg
Disable the tracer.
bbrreeaakk
Enter a recursive Prolog top level. See break/0.
aabboorrtt
Exit to the top level. See abort/0.
ffaaiill
Insert failure in execution.
hheellpp
Print the above available debug options.
77..44..33 CCHHRR DDeebbuuggggiinngg PPrreeddiiccaatteess
The chr module contains several predicates that allow inspecting and
printing the content of the constraint store.
cchhrr__ttrraaccee
Activate the CHR tracer. By default the CHR tracer is activated
and deactivated automatically by the Prolog predicates trace/0 and
notrace/0.
cchhrr__nnoottrraaccee
Deactivate the CHR tracer. By default the CHR tracer is activated
and deactivated automatically by the Prolog predicates trace/0 and
notrace/0.
cchhrr__lleeaasshh((_+_S_p_e_c))
Define the set of CHR ports on which the CHR tracer asks for user
intervention (i.e. stops). _S_p_e_c is either a list of ports as
defined in section 7.4.1 or a predefined `alias'. Defined aliases
are: full to stop at all ports, none or off to never stop, and
default to stop at the call, exit, fail, wake and apply ports. See
also leash/1.
cchhrr__sshhooww__ssttoorree((_+_M_o_d))
Prints all suspended constraints of module _M_o_d to the standard
output. This predicate is automatically called by the SWI-Prolog
top level at the end of each query for every CHR module currently
loaded. The Prolog flag chr_toplevel_show_store controls whether
the top level shows the constraint stores. The value true enables
it. Any other value disables it.
ffiinndd__cchhrr__ccoonnssttrraaiinntt((_-_C_o_n_s_t_r_a_i_n_t))
Returns a constraint in the constraint store. Via backtracking,
all constraints in the store can be enumerated.
77..55 EExxaammpplleess
Here are two example constraint solvers written in CHR.
o The program below defines a solver with one constraint, leq/2/,
which is a less-than-or-equal constraint, also known as a partial
order constraint.
____________________________________________________________________| |
| :- module(leq,[leq/2]). |
| :- use_module(library(chr)). |
| |
| :- chr_constraint leq/2. |
| reflexivity @ leq(X,X) <=> true. |
| antisymmetry @ leq(X,Y), leq(Y,X) <=> X = Y. |
| idempotence @ leq(X,Y) \ leq(X,Y) <=> true. |
||transitivity_@_leq(X,Y),_leq(Y,Z)_==>_leq(X,Z).___________________ ||
When the above program is saved in a file and loaded in SWI-Prolog,
you can call the leq/2 constraints in a query, e.g.:
____________________________________________________________________| |
| ?- leq(X,Y), leq(Y,Z). |
| leq(_G23837, _G23841) |
| leq(_G23838, _G23841) |
| leq(_G23837, _G23838) |
||true_.____________________________________________________________ ||
When the query succeeds, the SWI-Prolog top level prints the
content of the CHR constraint store and displays the bindings
generated during the query. Some of the query variables may
have been bound to attributed variables, as you see in the above
example.
o The program below implements a simple finite domain constraint
solver.
____________________________________________________________________| |
| :- module(dom,[dom/2]). |
| :- use_module(library(chr)). |
| |
| :- chr_constraint dom(?int,+list(int)). |
| :- chr_type list(T) ---> [] ; [T|list(T)]. |
| |
| dom(X,[]) <=> fail. |
| dom(X,[Y]) <=> X = Y. |
| dom(X,L) <=> nonvar(X) | memberchk(X,L). |
||dom(X,L1),_dom(X,L2)_<=>_intersection(L1,L2,L3),_dom(X,L3)._______ ||
When the above program is saved in a file and loaded in SWI-Prolog,
you can call the dom/2 constraints in a query, e.g.:
____________________________________________________________________| |
| ?- dom(A,[1,2,3]), dom(A,[3,4,5]). |
||A_=_3.____________________________________________________________ ||
77..66 BBaacckkwwaarrddss CCoommppaattiibbiilliittyy
77..66..11 TThhee OOlldd SSIICCSSttuuss CCHHRR iimmpplleemmeennaattiioonn
There are small differences between the current K.U.Leuven CHR system
in SWI-Prolog, older versions of the same system, and SICStus' CHR
system.
The current system maps old syntactic elements onto new ones and
ignores a number of no longer required elements. However, for each a
_d_e_p_r_e_c_a_t_e_d warning is issued. You are strongly urged to replace or
remove deprecated features.
Besides differences in available options and pragmas, the following
differences should be noted:
o _T_h_e constraints/1 _d_e_c_l_a_r_a_t_i_o_n
This declaration is deprecated. It has been replaced with the
chr_constraint/1 declaration.
o _T_h_e option/2 _d_e_c_l_a_r_a_t_i_o_n
This declaration is deprecated. It has been replaced with the
chr_option/2 declaration.
o _T_h_e handler/1 _d_e_c_l_a_r_a_t_i_o_n
In SICStus every CHR module requires a handler/1 declaration
declaring a unique handler name. This declaration is valid syntax
in SWI-Prolog, but will have no effect. A warning will be given
during compilation.
o _T_h_e rules/1 _d_e_c_l_a_r_a_t_i_o_n
In SICStus, for every CHR module it is possible to only enable a
subset of the available rules through the rules/1 declaration. The
declaration is valid syntax in SWI-Prolog, but has no effect. A
warning is given during compilation.
o _G_u_a_r_d _b_i_n_d_i_n_g_s
The check_guard_bindings option only turns invalid calls to
unification into failure. In SICStus this option does more: it
intercepts instantiation errors from Prolog built-ins such as is/2
and turns them into failure. In SWI-Prolog, we do not go this far,
as we like to separate concerns more. The CHR compiler is aware of
the CHR code, the Prolog system, and the programmer should be aware
of the appropriate meaning of the Prolog goals used in guards and
bodies of CHR rules.
77..66..22 TThhee OOlldd EECCLLiiPPSSee CCHHRR iimmpplleemmeennaattiioonn
The old ECLiPSe CHR implementation features a label_with/1 construct
for labeling variables in CHR constraints. This feature has long
since been abandoned. However, a simple transformation is all that is
required to port the functionality.
________________________________________________________________________| |
|label_with Constraint1 if Condition1. |
|... |
|label_with ConstraintN if ConditionN. |
|Constraint1 :- Body1. |
|... |
|ConstraintN|:-_BodyN.__________________________________________________ | |
is transformed into
________________________________________________________________________| |
|:- chr_constraint my_labeling/0. |
| |
|my_labeling \ Constraint1 <=> Condition1 | Body1. |
|... |
|my_labeling \ ConstraintN <=> ConditionN | BodyN. |
|my_labeling|<=>_true.__________________________________________________ | |
Be sure to put this code after all other rules in your program! With
my_labeling/0 (or another predicate name of your choosing) the labeling
is initiated, rather than ECLiPSe's chr_labeling/0.
77..77 PPrrooggrraammmmiinngg TTiippss aanndd TTrriicckkss
In this section we cover several guidelines on how to use CHR to write
constraint solvers and how to do so efficiently.
o _C_h_e_c_k _g_u_a_r_d _b_i_n_d_i_n_g_s _y_o_u_r_s_e_l_f
It is considered bad practice to write guards that bind variables
of the head and to rely on the system to detect this at runtime.
It is inefficient and obscures the working of the program.
o _S_e_t _s_e_m_a_n_t_i_c_s
The CHR system allows the presence of identical constraints, i.e.
multiple constraints with the same functor, arity and arguments.
For most constraint solvers, this is not desirable: it affects
efficiency and possibly termination. Hence appropriate simpagation
rules should be added of the form:
constraint\constraint <=>true
o _M_u_l_t_i_-_h_e_a_d_e_d _r_u_l_e_s
Multi-headed rules are executed more efficiently when the
constraints share one or more variables.
o _M_o_d_e _a_n_d _t_y_p_e _d_e_c_l_a_r_a_t_i_o_n_s
Provide mode and type declarations to get more efficient program
execution. Make sure to disable debug (-nodebug) and enable
optimization (-O).
o _C_o_m_p_i_l_e _o_n_c_e_, _r_u_n _m_a_n_y _t_i_m_e_s
Does consulting your CHR program take a long time in SWI-Prolog?
Probably it takes the CHR compiler a long time to compile the
CHR rules into Prolog code. When you disable optimizations the
CHR compiler will be a lot quicker, but you may lose performance.
Alternatively, you can just use SWI-Prolog's qcompile/1 to generate
a .qlf file once from your .pl file. This .qlf contains the
generated code of the CHR compiler (be it in a binary format).
When you consult the .qlf file, the CHR compiler is not invoked and
consultation is much faster.
o _F_i_n_d_i_n_g _C_o_n_s_t_r_a_i_n_t_s
The find_chr_constraint/1 predicate is fairly expensive. Avoid
it, if possible. If you must use it, try to use it with an
instantiated top-level constraint symbol.
77..88 CCoommppiilleerr EErrrroorrss aanndd WWaarrnniinnggss
In this section we summarize the most important error and warning
messages of the CHR compiler.
77..88..11 CCHHRR CCoommppiilleerr EErrrroorrss
TTyyppee ccllaasshh for variable ... in rule ...
This error indicates an inconsistency between declared types; a
variable can not belong to two types. See static type checking.
IInnvvaalliidd ffuunnccttoorr in head ... of rule ...
This error indicates an inconsistency between a declared type and
the use of a functor in a rule. See static type checking.
CCyycclliicc aalliiaass definition: ... == ...
You have defined a type alias in terms of itself, either directly
or indirectly.
AAmmbbiigguuoouuss ttyyppee aalliiaasseess You have defined two overlapping type aliases.
MMuullttiippllee ddeeffiinniittiioonnss for type
You have defined the same type multiple times.
NNoonn--ggrroouunndd ttyyppee in constraint definition: ...
You have declared a non-ground type for a constraint argument.
CCoouulldd nnoott ffiinndd ttyyppee ddeeffiinniittiioonn for ...
You have used an undefined type in a type declaration.
IIlllleeggaall mmooddee//ttyyppee ddeeccllaarraattiioonn You have used invalid syntax in a
constraint declaration.
CCoonnssttrraaiinntt mmuullttiippllyy ddeeffiinneedd There is more than one declaration for the
same constraint.
UUnnddeeccllaarreedd ccoonnssttrraaiinntt ... in head of ...
You have used an undeclared constraint in the head of a rule. This
often indicates a misspelled constraint name or wrong number of
arguments.
IInnvvaalliidd pprraaggmmaa ... in ... Pragma should not be a variable.
You have used a variable as a pragma in a rule. This is not
allowed.
IInnvvaalliidd iiddeennttiiffiieerr ... in pragma passive in ...
You have used an identifier in a passive pragma that does not
correspond to an identifier in the head of the rule. Likely the
identifier name is misspelled.
UUnnkknnoowwnn pprraaggmmaa ... in ...
You have used an unknown pragma in a rule. Likely the pragma is
misspelled or not supported.
SSoommeetthhiinngg uunneexxppeecctteedd happened in the CHR compiler
You have most likely bumped into a bug in the CHR compiler. Please
contact Tom Schrijvers to notify him of this error.
CChhaapptteerr 88.. MMUULLTTIITTHHRREEAADDEEDD AAPPPPLLIICCAATTIIOONNSS
SWI-Prolog multithreading is based on standard C language multithread-
ing support. It is not like _P_a_r_L_o_g or other parallel implementations
of the Prolog language. Prolog threads have their own stacks and only
share the Prolog _h_e_a_p: predicates, records, flags and other global
non-backtrackable data. SWI-Prolog thread support is designed with the
following goals in mind.
o _M_u_l_t_i_t_h_r_e_a_d_e_d _s_e_r_v_e_r _a_p_p_l_i_c_a_t_i_o_n_s
Today's computing services often focus on (internet) server
applications. Such applications often have need for communication
between services and/or fast non-blocking service to multiple
concurrent clients. The shared heap provides fast communication,
and thread creation is relatively cheap.
o _I_n_t_e_r_a_c_t_i_v_e _a_p_p_l_i_c_a_t_i_o_n_s
Interactive applications often need to perform extensive
computation. If such computations are executed in a new thread,
the main thread can process events and allow the user to cancel
the ongoing computation. User interfaces can also use multiple
threads, each thread dealing with input from a distinct group of
windows. See also section 8.7.
o _N_a_t_u_r_a_l _i_n_t_e_g_r_a_t_i_o_n _w_i_t_h _f_o_r_e_i_g_n _c_o_d_e
Each Prolog thread runs in a native thread of the operating system,
automatically making them cooperate with _M_T_-_s_a_f_e foreign code. In
addition, any foreign thread can create its own Prolog engine for
dealing with calling Prolog from C code.
SWI-Prolog multithreading is based on the POSIX thread standard
[Butenhof, 1997] used on most popular systems except for MS-Windows.
On Windows it uses the pthread-win32 emulation of POSIX threads mixed
with the Windows native API for smoother and faster operation.
88..11 CCrreeaattiinngg aanndd ddeessttrrooyyiinngg PPrroolloogg tthhrreeaaddss
tthhrreeaadd__ccrreeaattee((_:_G_o_a_l_, _-_I_d_, _+_O_p_t_i_o_n_s))
Create a new Prolog thread (and underlying C thread) and start it
by executing _G_o_a_l. If the thread is created successfully, the
thread identifier of the created thread is unified to _I_d. _O_p_t_i_o_n_s
is a list of options. The currently defined options are below.
Stack size options can also take the value inf or infinite, which
is mapped to the maximum stack size supported by the platform.
aalliiaass((_A_l_i_a_s_N_a_m_e))
Associate an `alias name' with the thread. This name may be
used to refer to the thread and remains valid until the thread
is joined (see thread_join/2).
aatt__eexxiitt((_:_A_t_E_x_i_t))
Register _A_t_E_x_i_t as using thread_at_exit/1 before entering the
thread goal. Unlike calling thread_at_exit/1 as part of
the normal _G_o_a_l, this _e_n_s_u_r_e_s the _G_o_a_l is called. Using
thread_at_exit/1, the thread may be signalled or run out of
resources before thread_at_exit/1is reached.
ddeettaacchheedd((_B_o_o_l))
If false (default), the thread can be waited for using
thread_join/2. thread_join/2 must be called on this thread
to reclaim all resources associated with the thread. If
true, the system will reclaim all associated resources
automatically after the thread finishes. Please note that
thread identifiers are freed for reuse after a detached thread
finishes or a normal thread has been joined. See also
thread_join/2 and thread_detach/1.
If a detached thread dies due to failure or exception
of the initial goal, the thread prints a message using
print_message/2. If such termination is considered normal, the
code must be wrapped using ignore/1 and/or catch/3 to ensure
successful completion.
iinnhheerriitt__ffrroomm((_+_T_h_r_e_a_d_I_d))
Inherit defaults from the given _T_h_r_e_a_d_I_d instead of the
calling thread. This option was added to ensure that the
__thread_pool_manager (see thread_create_in_pool/4), which is
created lazily, has a predictable state. The following
properties are inherited:
o The prompt (see prompt/2)
o The _t_y_p_e_i_n module (see module/1)
o The standard streams (user_input, etc.)
o The default encoding (see encoding)
o The default locale (see setlocale/1)
o All prolog flags
o The limits of Prolog stacks (see set_prolog_stack/2)
gglloobbaall((_K_-_B_y_t_e_s))
Set the limit to which the global stack of this thread may
grow. If omitted, the limit of the calling thread is used.
See also the -G command line option.
llooccaall((_K_-_B_y_t_e_s))
Set the limit to which the local stack of this thread may
grow. If omitted, the limit of the calling thread is used.
See also the -L command line option.
cc__ssttaacckk((_K_-_B_y_t_e_s))
Set the limit to which the system stack of this thread
may grow. The default, minimum and maximum values are
system-dependent..
ttrraaiill((_K_-_B_y_t_e_s))
Set the limit to which the trail stack of this thread may
grow. If omitted, the limit of the calling thread is used.
See also the -T command line option.
The _G_o_a_l argument is _c_o_p_i_e_d to the new Prolog engine. This implies
that further instantiation of this term in either thread does not
have consequences for the other thread: Prolog threads do not
share data from their stacks.
tthhrreeaadd__sseellff((_-_I_d))
Get the Prolog thread identifier of the running thread. If the
thread has an alias, the alias name is returned.
tthhrreeaadd__jjooiinn((_+_I_d_, _-_S_t_a_t_u_s))
Wait for the termination of the thread with the given _I_d. Then
unify the result status of the thread with _S_t_a_t_u_s. After this
call, _I_d becomes invalid and all resources associated with the
thread are reclaimed. Note that threads with the attribute
detached(_t_r_u_e) cannot be joined. See also thread_property/2.
A thread that has been completed without thread_join/2 being called
on it is partly reclaimed: the Prolog stacks are released and the
C thread is destroyed. A small data structure representing the
exit status of the thread is retained until thread_join/2 is called
on the thread. Defined values for _S_t_a_t_u_s are:
ttrruuee
The goal has been proven successfully.
ffaallssee
The goal has failed.
eexxcceeppttiioonn((_T_e_r_m))
The thread is terminated on an exception. See print_message/2
to turn system exceptions into readable messages.
eexxiitteedd((_T_e_r_m))
The thread is terminated on thread_exit/1 using the argument
_T_e_r_m.
tthhrreeaadd__ddeettaacchh((_+_I_d))
Switch thread into detached state (see detached(_B_o_o_l) option at
thread_create/3) at runtime. _I_d is the identifier of the thread
placed in detached state. This may be the result of thread_self/1.
One of the possible applications is to simplify debugging.
Threads that are created as _d_e_t_a_c_h_e_d leave no traces if they
crash. For non-detached threads the status can be inspected using
thread_property/2. Threads nobody is waiting for may be created
normally and detach themselves just before completion. This way
they leave no traces on normal completion and their reason for
failure can be inspected.
tthhrreeaadd__eexxiitt((_+_T_e_r_m)) _[_d_e_p_r_e_c_a_t_e_d_]
Terminates the thread immediately, leaving exited(_T_e_r_m) as result
state for thread_join/2. If the thread has the attribute
detached(_t_r_u_e) it terminates, but its exit status cannot be
retrieved using thread_join/2, making the value of _T_e_r_m irrelevant.
The Prolog stacks and C thread are reclaimed.
The current implementation does not guarantee proper releasing
of all mutexes and proper cleanup in setup_call_cleanup/3, etc.
Please use the exception mechanism (throw/1) to abort execution
using non-standard control.
tthhrreeaadd__iinniittiiaalliizzaattiioonn((_:_G_o_a_l))
Run _G_o_a_l when thread is started. This predicate is similar to
initialization/1, but is intended for initialization operations of
the runtime stacks, such as setting global variables as described
in section 6.3. _G_o_a_l is run on four occasions: at the call to
this predicate, after loading a saved state, on starting a new
thread and on creating a Prolog engine through the C interface.
On loading a saved state, _G_o_a_l is executed _a_f_t_e_r running the
initialization/1 hooks.
tthhrreeaadd__aatt__eexxiitt((_:_G_o_a_l))
Run _G_o_a_l just before releasing the thread resources. This is
to be compared to at_halt/1, but only for the current thread.
These hooks are run regardless of why the execution of the thread
has been completed. When these hooks are run, the return code
is already available through thread_property/2 using the result
of thread_self/1 as thread identifier. Note that there are
two scenarios for using exit hooks. Using thread_at_exit/1 is
typically used if the thread creates a side-effect that must be
reverted if the thread dies. Another scenario is where the creator
of the thread wants to be informed when the thread ends. That
cannot be guaranteed by means of thread_at_exit/1 because it is
possible that the thread cannot be created or dies almost instantly
due to a signal or resource error. The at_exit(_G_o_a_l) option of
thread_create/3 is designed to deal with this scenario.
tthhrreeaadd__sseettccoonnccuurrrreennccyy((_-_O_l_d_, _+_N_e_w))
Determine the concurrency of the process, which is defined as the
maximum number of concurrently active threads. `Active' here means
they are using CPU time. This option is provided if the thread
implementation provides pthread_setconcurrency(). Solaris is a
typical example of this family. On other systems this predicate
unifies _O_l_d to 0 (zero) and succeeds silently.
88..22 MMoonniittoorriinngg tthhrreeaaddss
Normal multithreaded applications should not need the predicates from
this section because almost any usage of these predicates is unsafe.
For example checking the existence of a thread before signalling it is
of no use as it may vanish between the two calls. Catching exceptions
using catch/3 is the only safe way to deal with thread-existence
errors.
These predicates are provided for diagnosis and monitoring tasks. See
also section 8.5, describing more high-level primitives.
tthhrreeaadd__pprrooppeerrttyy((_?_I_d_, _?_P_r_o_p_e_r_t_y))
True if thread _I_d has _P_r_o_p_e_r_t_y. Either or both arguments may
be unbound, enumerating all relations on backtracking. Calling
thread_property/2 does not influence any thread. See also
thread_join/2. For threads that have an alias name, this name is
returned in _I_d instead of the opaque thread identifier. Defined
properties are:
aalliiaass((_A_l_i_a_s))
_A_l_i_a_s is the alias name of thread _I_d.
ddeettaacchheedd((_B_o_o_l_e_a_n))
Current detached status of the thread.
ssttaattuuss((_S_t_a_t_u_s))
Current status of the thread. _S_t_a_t_u_s is one of:
rruunnnniinngg
The thread is running. This is the initial status of a
thread. Please note that threads waiting for something
are considered running too.
ffaallssee
The _G_o_a_l of the thread has been completed and failed.
ttrruuee
The _G_o_a_l of the thread has been completed and succeeded.
eexxiitteedd((_T_e_r_m))
The _G_o_a_l of the thread has been terminated using
thread_exit/1 with _T_e_r_m as argument. If the underlying
native thread has exited (using pthread_exit()) _T_e_r_m is
unbound.
eexxcceeppttiioonn((_T_e_r_m))
The _G_o_a_l of the thread has been terminated due to an
uncaught exception (see throw/1 and catch/3).
See also thread_statistics/3 to obtain resource usage information
and message_queue_property/2 to get the number of queued messages
for a thread.
tthhrreeaadd__ssttaattiissttiiccss((_+_I_d_, _+_K_e_y_, _-_V_a_l_u_e))
Obtains statistical information on thread _I_d as statistics/2 does
in single-threaded applications. This call supports all keys
of statistics/2, although only stack sizes and CPU time yield
different values for each thread.
mmuutteexx__ssttaattiissttiiccss
Print usage statistics on internal mutexes and mutexes associated
with dynamic predicates. For each mutex two numbers are printed:
the number of times the mutex was acquired and the number of
_c_o_l_l_i_s_i_o_n_s: the number of times the calling thread has to wait
for the mutex. Generally collision count is close to zero on
single-CPU hardware.
88..33 TThhrreeaadd ccoommmmuunniiccaattiioonn
88..33..11 MMeessssaaggee qquueeuueess
Prolog threads can exchange data using dynamic predicates, database
records, and other globally shared data. These provide no suitable
means to wait for data or a condition as they can only be checked in an
expensive polling loop. _M_e_s_s_a_g_e _q_u_e_u_e_s provide a means for threads to
wait for data or conditions without using the CPU.
Each thread has a message queue attached to it that is identified by
the thread. Additional queues are created using message_queue_create/1.
tthhrreeaadd__sseenndd__mmeessssaaggee((_+_Q_u_e_u_e_O_r_T_h_r_e_a_d_I_d_, _+_T_e_r_m))
Place _T_e_r_m in the given queue or default queue of the indicated
thread (which can even be the message queue of itself, see
thread_self/1). Any term can be placed in a message queue, but
note that the term is copied to the receiving thread and variable
bindings are thus lost. This call returns immediately.
If more than one thread is waiting for messages on the given queue
and at least one of these is waiting with a partially instantiated
_T_e_r_m, the waiting threads are _a_l_l sent a wake-up signal, starting a
rush for the available messages in the queue. This behaviour can
seriously harm performance with many threads waiting on the same
queue as all-but-the-winner perform a useless scan of the queue.
If there is only one waiting thread or all waiting threads wait
with an unbound variable, an arbitrary thread is restarted to scan
the queue.
tthhrreeaadd__ggeett__mmeessssaaggee((_?_T_e_r_m))
Examines the thread message queue and if necessary blocks execution
until a term that unifies to _T_e_r_m arrives in the queue. After a
term from the queue has been unified to _T_e_r_m, the term is deleted
from the queue.
Please note that non-unifying messages remain in the queue. After
the following has been executed, thread 1 has the term b(_g_n_u) in
its queue and continues execution using _A = gnat.
____________________________________________________________________| |
| <thread 1> |
| thread_get_message(a(A)), |
| |
| <thread 2> |
| thread_send_message(Thread_1, b(gnu)), |
||___thread_send_message(Thread_1,_a(gnat)),________________________ ||
See also thread_peek_message/1.
tthhrreeaadd__ppeeeekk__mmeessssaaggee((_?_T_e_r_m))
Examines the thread message queue and compares the queued terms
with _T_e_r_m until one unifies or the end of the queue has
been reached. In the first case the call succeeds, possibly
instantiating _T_e_r_m. If no term from the queue unifies, this call
fails. I.e., thread_peek_message/1never waits and does not remove
any term from the queue. See also thread_get_message/3.
mmeessssaaggee__qquueeuuee__ccrreeaattee((_?_Q_u_e_u_e))
If _Q_u_e_u_e is an atom, create a named queue. To avoid ambiguity of
thread_send_message/2, the name of a queue may not be in use as a
thread name. If _Q_u_e_u_e is unbound an anonymous queue is created and
_Q_u_e_u_e is unified to its identifier.
mmeessssaaggee__qquueeuuee__ccrreeaattee((_-_Q_u_e_u_e_, _+_O_p_t_i_o_n_s))
Create a message queue from _O_p_t_i_o_n_s. Defined options are:
aalliiaass((_+_A_l_i_a_s))
Same as message_queue_create(_A_l_i_a_s), but according to the ISO
draft on Prolog threads.
mmaaxx__ssiizzee((_+_S_i_z_e))
Maximum number of terms in the queue. If this number is
reached, thread_send_message/2 will suspend until the queue
is drained. The option can be used if the source, sending
messages to the queue, is faster than the drain, consuming the
messages.
mmeessssaaggee__qquueeuuee__ddeessttrrooyy((_+_Q_u_e_u_e)) _[_d_e_t_]
Destroy a message queue created with message_queue_create/1. A
permission error is raised if _Q_u_e_u_e refers to (the default queue
of) a thread. Other threads that are waiting for _Q_u_e_u_e using
thread_get_message/2 receive an existence error.
tthhrreeaadd__ggeett__mmeessssaaggee((_+_Q_u_e_u_e_, _?_T_e_r_m)) _[_d_e_t_]
As thread_get_message/1, operating on a given queue. It is allowed
(but not advised) to get messages from the queue of other threads.
This predicate raises an existence error exception if _Q_u_e_u_e doesn't
exist or is destroyed using message_queue_destroy/1 while this
predicate is waiting.
tthhrreeaadd__ggeett__mmeessssaaggee((_+_Q_u_e_u_e_, _?_T_e_r_m_, _+_O_p_t_i_o_n_s)) _[_s_e_m_i_d_e_t_]
As thread_get_message/2, but providing additional _O_p_t_i_o_n_s:
ddeeaaddlliinnee((_+_A_b_s_T_i_m_e))
The call fails (silently) if no message has arrived before
_A_b_s_T_i_m_e. See get_time/1 for the representation of absolute
time. If _A_b_s_T_i_m_e is earlier then the current time,
thread_get_message/3 fails immediately. Both resolution and
maximum wait time is platform-dependent.
ttiimmeeoouutt((_+_T_i_m_e))
_T_i_m_e is a float or integer and specifies the maximum time to
wait in seconds. This is a relative-time version of the
deadline option. If both options are provided, the earliest
time is effective.
It _T_i_m_e is 0 or 0.0, thread_get_message/3 examines the queue
but does not suspend if no matching term is available. Note
that unlike thread_peek_message/2, a matching term is removed
from the queue.
It _T_i_m_e <0, thread_get_message/3 fails immediately.
tthhrreeaadd__ppeeeekk__mmeessssaaggee((_+_Q_u_e_u_e_, _?_T_e_r_m)) _[_s_e_m_i_d_e_t_]
As thread_peek_message/1, operating on a given queue. It is
allowed to peek into another thread's message queue, an operation
that can be used to check whether a thread has swallowed a message
sent to it.
mmeessssaaggee__qquueeuuee__pprrooppeerrttyy((_?_Q_u_e_u_e_, _?_P_r_o_p_e_r_t_y))
True if _P_r_o_p_e_r_t_y is a property of _Q_u_e_u_e. Defined properties are:
aalliiaass((_A_l_i_a_s))
Queue has the given alias name.
mmaaxx__ssiizzee((_S_i_z_e))
Maximum number of terms that can be in the queue. See
message_queue_create/2. This property is not present if there
is no limit (default).
ssiizzee((_S_i_z_e))
Queue currently contains _S_i_z_e terms. Note that due to
concurrent access the returned value may be outdated before it
is returned. It can be used for debugging purposes as well as
work distribution purposes.
The size(_S_i_z_e) property is always present and may be used to
enumerate the created message queues. Note that this predicate
does _n_o_t _e_n_u_m_e_r_a_t_e threads, but can be used to query the properties
of the default queue of a thread.
Explicit message queues are designed with the _w_o_r_k_e_r_-_p_o_o_l model in
mind, where multiple threads wait on a single queue and pick up
the first goal to execute. Below is a simple implementation where
the workers execute arbitrary Prolog goals. Note that this example
provides no means to tell when all work is done. This must be realised
using additional synchronisation.
________________________________________________________________________| |
|%% create_workers(?Id, +N) |
|% |
|% Create a pool with Id and number of workers. |
|% After the pool is created, post_job/1 can be used to |
|% send jobs to the pool. |
| |
|create_workers(Id, N) :- |
| message_queue_create(Id), |
| forall(between(1, N, _), |
| thread_create(do_work(Id), _, [])). |
| |
|do_work(Id) :- |
| repeat, |
| thread_get_message(Id, Goal), |
| ( catch(Goal, E, print_message(error, E)) |
| -> true |
| ; print_message(error, goal_failed(Goal, worker(Id))) |
| ), |
| fail. |
| |
|%% post_job(+Id, +Goal) |
|% |
|% Post a job to be executed by one of the pool's workers. |
| |
|post_job(Id, Goal) :- |
||_______thread_send_message(Id,_Goal)._________________________________ ||
88..33..22 SSiiggnnaalllliinngg tthhrreeaaddss
These predicates provide a mechanism to make another thread execute
some goal as an _i_n_t_e_r_r_u_p_t. Signalling threads is safe as these
interrupts are only checked at safe points in the virtual machine.
Nevertheless, signalling in multithreaded environments should be
handled with care as the receiving thread may hold a _m_u_t_e_x (see
with_mutex/2). Signalling probably only makes sense to start debugging
threads and to cancel no-longer-needed threads with throw/1, where the
receiving thread should be designed carefully to handle exceptions at
any point.
tthhrreeaadd__ssiiggnnaall((_+_T_h_r_e_a_d_I_d_, _:_G_o_a_l))
Make thread _T_h_r_e_a_d_I_d execute _G_o_a_l at the first opportunity. In the
current implementation, this implies at the first pass through the
_C_a_l_l _p_o_r_t. The predicate thread_signal/2 itself places _G_o_a_l into
the signalled thread's signal queue and returns immediately.
Signals (interrupts) do not cooperate well with the world of
multithreading, mainly because the status of mutexes cannot be
guaranteed easily. At the call port, the Prolog virtual machine
holds no locks and therefore the asynchronous execution is safe.
_G_o_a_l can be any valid Prolog goal, including throw/1 to make
the receiving thread generate an exception, and trace/0 to start
tracing the receiving thread.
In the Windows version, the receiving thread immediately executes
the signal if it reaches a Windows GetMessage() call, which
generally happens if the thread is waiting for (user) input.
88..33..33 TThhrreeaaddss aanndd ddyynnaammiicc pprreeddiiccaatteess
Besides queues (section 8.3.1) threads can share and exchange data
using dynamic predicates. The multithreaded version knows about two
types of dynamic predicates. By default, a predicate declared _d_y_n_a_m_i_c
(see dynamic/1) is shared by all threads. Each thread may assert,
retract and run the dynamic predicate. Synchronisation inside Prolog
guarantees the consistency of the predicate. Updates are _l_o_g_i_c_a_l:
visible clauses are not affected by assert/retract after a query
started on the predicate. In many cases primitives from section 8.4
should be used to ensure that application invariants on the predicate
are maintained.
Besides shared predicates, dynamic predicates can be declared with the
thread_local/1 directive. Such predicates share their attributes, but
the clause list is different in each thread.
tthhrreeaadd__llooccaall _+_F_u_n_c_t_o_r_/_+_A_r_i_t_y_, _._._.
This directive is related to the dynamic/1 directive. It tells
the system that the predicate may be modified using assert/1,
retract/1, etc., during execution of the program. Unlike normal
shared dynamic data, however, each thread has its own clause list
for the predicate. As a thread starts, this clause list is empty.
If there are still clauses when the thread terminates, these are
automatically reclaimed by the system (see also volatile/1). The
thread_local property implies the properties _d_y_n_a_m_i_c and _v_o_l_a_t_i_l_e.
Thread-local dynamic predicates are intended for maintaining
thread-specific state or intermediate results of a computation.
It is not recommended to put clauses for a thread-local predicate
into a file, as in the example below, because the clause is only
visible from the thread that loaded the source file. All other
threads start with an empty clause list.
____________________________________________________________________| |
| :- thread_local |
| foo/1. |
| |
||foo(gnat).________________________________________________________ ||
DDIISSCCLLAAIIMMEERR Whether or not this declaration is appropriate in the
sense of the proper mechanism to reach the goal is still debated.
If you have strong feelings in favour or against, please share them
in the SWI-Prolog mailing list.
88..44 TThhrreeaadd ssyynncchhrroonniissaattiioonn
All internal Prolog operations are thread-safe. This implies that
two Prolog threads can operate on the same dynamic predicate without
corrupting the consistency of the predicate. This section deals with
user-level _m_u_t_e_x_e_s (called _m_o_n_i_t_o_r_s in ADA or _c_r_i_t_i_c_a_l _s_e_c_t_i_o_n_s by
Microsoft). A mutex is a MMUUTTual EEXXclusive device, which implies that
at most one thread can _h_o_l_d a mutex.
Mutexes are used to realise related updates to the Prolog database.
With `related', we refer to the situation where a `transaction' implies
two or more changes to the Prolog database. For example, we have
a predicate address/2, representing the address of a person and we
want to change the address by retracting the old and asserting the
new address. Between these two operations the database is invalid:
this person has either no address or two addresses, depending on the
assert/retract order.
Here is how to realise a correct update:
________________________________________________________________________| |
|:- initialization |
| mutex_create(addressbook). |
| |
|change_address(Id, Address) :- |
| mutex_lock(addressbook), |
| retractall(address(Id, _)), |
| asserta(address(Id, Address)), |
||_______mutex_unlock(addressbook)._____________________________________ ||
mmuutteexx__ccrreeaattee((_?_M_u_t_e_x_I_d))
Create a mutex. If _M_u_t_e_x_I_d is an atom, a _n_a_m_e_d mutex is created.
If it is a variable, an anonymous mutex reference is returned.
There is no limit to the number of mutexes that can be created.
mmuutteexx__ccrreeaattee((_-_M_u_t_e_x_I_d_, _+_O_p_t_i_o_n_s))
Create a mutex using options. Defined options are:
aalliiaass((_A_l_i_a_s))
Set the alias name. Using mutex_create(_X_, _[_a_l_i_a_s_(_n_a_m_e_)_]) is
preferred over the equivalent mutex_create(_n_a_m_e).
mmuutteexx__ddeessttrrooyy((_+_M_u_t_e_x_I_d))
Destroy a mutex. After this call, _M_u_t_e_x_I_d becomes invalid and
further references yield an existence_error exception.
wwiitthh__mmuutteexx((_+_M_u_t_e_x_I_d_, _:_G_o_a_l))
Execute _G_o_a_l while holding _M_u_t_e_x_I_d. If _G_o_a_l leaves choice
points, these are destroyed (as in once/1). The mutex is
unlocked regardless of whether _G_o_a_l succeeds, fails or raises an
exception. An exception thrown by _G_o_a_l is re-thrown after the
mutex has been successfully unlocked. See also mutex_create/1 and
setup_call_cleanup/3.
Although described in the thread section, this predicate is also
available in the single-threaded version, where it behaves simply
as once/1.
mmuutteexx__lloocckk((_+_M_u_t_e_x_I_d))
Lock the mutex. Prolog mutexes are _r_e_c_u_r_s_i_v_e mutexes: they can be
locked multiple times by the same thread. Only after unlocking it
as many times as it is locked does the mutex become available for
locking by other threads. If another thread has locked the mutex
the calling thread is suspended until the mutex is unlocked.
If _M_u_t_e_x_I_d is an atom, and there is no current mutex with that
name, the mutex is created automatically using mutex_create/1.
This implies named mutexes need not be declared explicitly.
Please note that locking and unlocking mutexes should be paired
carefully. Especially make sure to unlock mutexes even if
the protected code fails or raises an exception. For most
common cases, use with_mutex/2, which provides a safer way for
handling Prolog-level mutexes. The predicate setup_call_cleanup/3
is another way to guarantee that the mutex is unlocked while
retaining non-determinism.
mmuutteexx__ttrryylloocckk((_+_M_u_t_e_x_I_d))
As mutex_lock/1, but if the mutex is held by another thread, this
predicates fails immediately.
mmuutteexx__uunnlloocckk((_+_M_u_t_e_x_I_d))
Unlock the mutex. This can only be called if the mutex is held by
the calling thread. If this is not the case, a permission_error
exception is raised.
mmuutteexx__uunnlloocckk__aallll
Unlock all mutexes held by the current thread. This call is
especially useful to handle thread termination using abort/0 or
exceptions. See also thread_signal/2.
mmuutteexx__pprrooppeerrttyy((_?_M_u_t_e_x_I_d_, _?_P_r_o_p_e_r_t_y))
True if _P_r_o_p_e_r_t_y is a property of _M_u_t_e_x_I_d. Defined properties are:
aalliiaass((_A_l_i_a_s))
Mutex has the defined alias name. See mutex_create/2 using the
`alias' option.
ssttaattuuss((_S_t_a_t_u_s))
Current status of the mutex. One of unlocked if the mutex
is currently not locked, or locked(_O_w_n_e_r_, _C_o_u_n_t) if mutex is
locked _C_o_u_n_t times by thread _O_w_n_e_r. Note that unless _O_w_n_e_r is
the calling thread, the locked status can change at any time.
There is no useful application of this property, except for
diagnostic purposes.
88..55 TThhrreeaadd ssuuppppoorrtt lliibbrraarryy((tthhrreeaadduuttiill))
This library defines a couple of useful predicates for demonstrating
and debugging multithreaded applications. This library is certainly
not complete.
tthhrreeaaddss
Lists all current threads and their status.
jjooiinn__tthhrreeaaddss
Join all terminated threads. For normal applications, dealing with
terminated threads must be part of the application logic, either
detaching the thread before termination or making sure it will be
joined. The predicate join_threads/0 is intended for interactive
sessions to reclaim resources from threads that died unexpectedly
during development.
iinntteerraaccttoorr
Create a new console and run the Prolog top level in this new
console. See also attach_console/0. In the Windows version a new
interactor can also be created from the Run/New thread menu.
88..55..11 DDeebbuuggggiinngg tthhrreeaaddss
Support for debugging threads is still very limited. Debug and
trace mode are flags that are local to each thread. Individual
threads can be debugged either using the graphical debugger described
in section 3.5 (see tspy/1 and friends) or by attaching a console
to the thread and running the traditional command line debugger (see
attach_console/0). When using the graphical debugger, the debugger
must be _l_o_a_d_e_d from the main thread (for example using guitracer)
before gtrace/0 can be called from a thread.
aattttaacchh__ccoonnssoollee
If the current thread has no console attached yet, attach one
and redirect the user streams (input, output, and error) to the
new console window. On Unix systems the console is an xterm
application. On Windows systems this requires the GUI version
swipl-win.exe rather than the console-based swipl.exe.
This predicate has a couple of useful applications. One is to
separate (debugging) I/O of different threads. Another is to start
debugging a thread that is running in the background. If thread
10 is running, the following sequence starts the tracer on this
thread:
____________________________________________________________________| |
||?-_thread_signal(10,_(attach_console,_trace)).____________________ ||
ttddeebbuugg((_+_T_h_r_e_a_d_I_d))
Prepare _T_h_r_e_a_d_I_d for debugging using the graphical tracer. This
implies installing the tracer hooks in the thread and switching the
thread to debug mode using debug/0. The call is injected into
the thread using thread_signal/2. We refer to the documentation
of this predicate for asynchronous interaction with threads. New
threads created inherit their debug mode from the thread that
created them.
ttddeebbuugg
Call tdebug/1 in all running threads.
ttnnooddeebbuugg((_+_T_h_r_e_a_d_I_d))
Disable debugging thread _T_h_r_e_a_d_I_d.
ttnnooddeebbuugg
Disable debugging in all threads.
ttssppyy((_:_S_p_e_c_, _+_T_h_r_e_a_d_I_d))
Set a spy point as spy/1 and enable the thread for debugging using
tdebug/1. Note that a spy point is a global flag on a predicate
that is visible from all threads. Spy points are honoured in all
threads that are in debug mode and ignored in threads that are in
nodebug mode.
ttssppyy((_:_S_p_e_c))
Set a spy point as spy/1 and enable debugging in all threads
using tdebug/0. Note that removing spy points can be done using
nospy/1. Disabling spy points in a specific thread is achieved by
tnodebug/1.
88..55..22 PPrrooffiilliinngg tthhrreeaaddss
In the current implementation, at most one thread can be profiled at
any moment. Any thread can call profile/1 to profile the execution of
some part of its code. The predicate tprofile/1 allows for profiling
the execution of another thread until the user stops collecting profile
data.
ttpprrooffiillee((_+_T_h_r_e_a_d_I_d))
Start collecting profile data in _T_h_r_e_a_d_I_d and ask the user to hit
<_r_e_t_u_r_n> to stop the profiler. See section 4.40 for details on the
execution profiler.
88..66 MMuullttiitthhrreeaaddeedd mmiixxeedd CC aanndd PPrroolloogg aapppplliiccaattiioonnss
All foreign code linked to the multithreading version of SWI-Prolog
should be thread-safe (_r_e_e_n_t_r_a_n_t) or guarded in Prolog using
with_mutex/2 from simultaneous access from multiple Prolog threads.
If you want to write mixed multithreaded C and Prolog applications
you should first familiarise yourself with writing multithreaded
applications in C (C++).
If you are using SWI-Prolog as an embedded engine in a multithreaded
application you can access the Prolog engine from multiple threads by
creating an _e_n_g_i_n_e in each thread from which you call Prolog. Without
creating an engine, a thread can only use functions that do _n_o_t use the
term_t type (for example PL_new_atom()).
The system supports two models. Section 8.6.1 describes the original
one-to-one mapping. In this schema a native thread attaches a Prolog
thread if it needs to call Prolog and detaches it when finished, as
opposed to the model from section 8.6.2, where threads temporarily use
a Prolog engine.
88..66..11 AA PPrroolloogg tthhrreeaadd ffoorr eeaacchh nnaattiivvee tthhrreeaadd ((oonnee--ttoo--oonnee))
In the one-to-one model, the thread that called PL_initialise()
has a Prolog engine attached. If another C thread in the
system wishes to call Prolog it must first attach an engine using
PL_thread_attach_engine() and call PL_thread_destroy_engine()after all
Prolog work is finished. This model is especially suitable with
long running threads that need to do Prolog work regularly. See
section 8.6.2 for the alternative many-to-many model.
int PPLL__tthhrreeaadd__sseellff()
Returns the integer Prolog identifier of the engine or -1 if
the calling thread has no Prolog engine. This function is also
provided in the single-threaded version of SWI-Prolog, where it
returns -2.
int PPLL__uunniiffyy__tthhrreeaadd__iidd(_t_e_r_m___t _t_, _i_n_t _i)
Unify _t with the Prolog thread identifier for thread _i. Thread
identifiers are normally returned from PL_thread_self(). Returns
-1 if the thread does not exist or the unification fails.
int PPLL__tthhrreeaadd__aattttaacchh__eennggiinnee(_c_o_n_s_t _P_L___t_h_r_e_a_d___a_t_t_r___t _*_a_t_t_r)
Creates a new Prolog engine in the calling thread. If the calling
thread already has an engine the reference count of the engine is
incremented. The _a_t_t_r argument can be NULL to create a thread with
default attributes. Otherwise it is a pointer to a structure with
the definition below. For any field with value `0', the default
is used. The cancel field may be filled with a pointer to a
function that is called when PL_cleanup() terminates the running
Prolog engines. If this function is not present or returns FALSE
pthread_cancel() is used. The flags field defines the following
flags:
PPLL__TTHHRREEAADD__NNOO__DDEEBBUUGG
If this flag is present, the thread starts in normal no-debug
status. By default, the debug status is inherited from the
main thread.
____________________________________________________________________| |
| typedef struct |
| { unsigned long local_size; /* Stack sizes (Kbytes) */ |
| unsigned long global_size; |
| unsigned long trail_size; |
| unsigned long argument_size; |
| char * alias; /* alias name */ |
| int (*cancel)(int thread); |
| intptr_t flags; |
||}_PL_thread_attr_t;_______________________________________________ ||
The structure may be destroyed after PL_thread_attach_engine() has
returned. On success it returns the Prolog identifier for the
thread (as returned by PL_thread_self()). If an error occurs, -1
is returned. If this Prolog is not compiled for multithreading, -2
is returned.
int PPLL__tthhrreeaadd__ddeessttrrooyy__eennggiinnee()
Destroy the Prolog engine in the calling thread. Only takes
effect if PL_thread_destroy_engine() is called as many times as
PL_thread_attach_engine() in this thread. Returns TRUE on success
and FALSE if the calling thread has no engine or this Prolog does
not support threads.
Please note that construction and destruction of engines are
relatively expensive operations. Only destroy an engine if
performance is not critical and memory is a critical resource.
int PPLL__tthhrreeaadd__aatt__eexxiitt(_v_o_i_d _(_*_f_u_n_c_t_i_o_n_)_(_v_o_i_d _*_)_, _v_o_i_d _*_c_l_o_s_u_r_e_, _i_n_t _g_l_o_b_a_l)
Register a handle to be called as the Prolog engine is destroyed.
The handler function is called with one void * argument holding
_c_l_o_s_u_r_e. If _g_l_o_b_a_l is TRUE, the handler is installed _f_o_r _a_l_l
_t_h_r_e_a_d_s. Globally installed handlers are executed after the
thread-local handlers. If the handler is installed local for the
current thread only (_g_l_o_b_a_l == FALSE) it is stored in the same FIFO
queue as used by thread_at_exit/1.
88..66..22 PPoooolliinngg PPrroolloogg eennggiinneess ((mmaannyy--ttoo--mmaannyy))
In this model Prolog engines live as entities that are independent from
threads. If a thread needs to call Prolog it takes one of the engines
from the pool and returns the engine when done. This model is suitable
in the following identified cases:
o _C_o_m_p_a_t_i_b_i_l_i_t_y _w_i_t_h _t_h_e _s_i_n_g_l_e_-_t_h_r_e_a_d_e_d _v_e_r_s_i_o_n
In the single-threaded version, foreign threads must serialise
access to the one and only thread engine. Functions from this
section allow sharing one engine among multiple threads.
o _M_a_n_y _n_a_t_i_v_e _t_h_r_e_a_d_s _w_i_t_h _i_n_f_r_e_q_u_e_n_t _P_r_o_l_o_g _w_o_r_k
Prolog threads are expensive in terms of memory and time to create
and destroy them. For systems that use a large number of threads
that only infrequently need to call Prolog, it is better to take an
engine from a pool and return it there.
o _P_r_o_l_o_g _s_t_a_t_u_s _m_u_s_t _b_e _h_a_n_d_e_d _t_o _a_n_o_t_h_e_r _t_h_r_e_a_d
This situation has been identified by Uwe Lesta when creating
a .NET interface for SWI-Prolog. .NET distributes work for an
active internet connection over a pool of threads. If a Prolog
engine contains the state for a connection, it must be possible to
detach the engine from a thread and re-attach it to another thread
handling the same connection.
PL_engine_t PPLL__ccrreeaattee__eennggiinnee(_P_L___t_h_r_e_a_d___a_t_t_r___t _*_a_t_t_r_i_b_u_t_e_s)
Create a new Prolog engine. _a_t_t_r_i_b_u_t_e_s is described with
PL_thread_attach_engine(). Any thread can make this call after
PL_initialise() returns success. The returned engine is not
attached to any thread and lives until PL_destroy_engine()is used
on the returned handle.
In the single-threaded version this call always returns NULL,
indicating failure.
int PPLL__ddeessttrrooyy__eennggiinnee(_P_L___e_n_g_i_n_e___t _e)
Destroy the given engine. Destroying an engine is only allowed if
the engine is not attached to any thread or attached to the calling
thread. On success this function returns TRUE, on failure the
return value is FALSE.
int PPLL__sseett__eennggiinnee(_P_L___e_n_g_i_n_e___t _e_n_g_i_n_e_, _P_L___e_n_g_i_n_e___t _*_o_l_d)
Make the calling thread ready to use _e_n_g_i_n_e. If _o_l_d is non-NULL
the current engine associated with the calling thread is stored
at the given location. If _e_n_g_i_n_e equals PL_ENGINE_MAIN the
initial engine is attached to the calling thread. If _e_n_g_i_n_e is
PL_ENGINE_CURRENT the engine is not changed. This can be used
to query the current engine. This call returns PL_ENGINE_SET if
the engine was switched successfully, PL_ENGINE_INVAL if _e_n_g_i_n_e is
not a valid engine handle and PL_ENGINE_INUSE if the engine is
currently in use by another thread.
Engines can be changed at any time. For example, it is allowed
to select an engine to initiate a Prolog goal, detach it and at a
later moment execute the goal from another thread. Note, however,
that the term_t, qid_t and fid_t types are interpreted relative to
the engine for which they are created. Behaviour when passing one
of these types from one engine to another is undefined.
In the single-threaded version this call only succeeds if _e_n_g_i_n_e
refers to the main engine.
88..77 MMuullttiitthhrreeaaddiinngg aanndd tthhee XXPPCCEE ggrraapphhiiccss ssyysstteemm
GUI applications written in XPCE can benefit from Prolog threads if
they need to do expensive computations that would otherwise block the
UI. The XPCE message passing system is guarded with a single _m_u_t_e_x,
which synchronises both access from Prolog and activation through the
GUI. In MS-Windows, GUI events are processed by the thread that created
the window in which the event occurred, whereas in Unix/X11 they
are processed by the thread that dispatches messages. In practice,
the most feasible approach to graphical Prolog implementations is to
control XPCE from a single thread and deploy other threads for (long)
computations.
Traditionally, XPCE runs in the foreground (main) thread. We are
working towards a situation where XPCE can run comfortably in a
separate thread. A separate XPCE thread can be created using
pce_dispatch/1. It is also possible to create this thread as the (pce)
is loaded by setting the xpce_threaded to true.
Threads other than the thread in which XPCE runs are provided with two
predicates to communicate with XPCE.
iinn__ppccee__tthhrreeaadd((_:_G_o_a_l)) _[_d_e_t_]
Assuming XPCE is running in the foreground thread, this call gives
background threads the opportunity to make calls to the XPCE
thread. A call to in_pce_thread/1 succeeds immediately, copying
_G_o_a_l to the XPCE thread. _G_o_a_l is added to the XPCE event queue
and executed synchronous to normal user events like typing and
clicking.
iinn__ppccee__tthhrreeaadd__ssyynncc((_:_G_o_a_l)) _[_s_e_m_i_d_e_t_]
Same as in_pce_thread/1, but wait for _G_o_a_l to be completed.
Success depends on the success of executing _G_o_a_l. Variable
bindings inside _G_o_a_l are visible to the caller, but it should
be noted that the values are being _c_o_p_i_e_d. If _G_o_a_l throws an
exception, this exception is re-thrown by in_pce_thread/1. If the
calling thread is the `pce thread', in_pce_thread_sync/1 executes a
direct meta-call. See also pce_thread/1.
Note that in_pce_thread_sync/1 is expensive because it re-
quires copying and thread communication. For example,
in_pce_thread_synctrue runs at approximately 50,000 calls per second
(AMD Phenom 9600B, Ubuntu 11.04).
ppccee__ddiissppaattcchh((_+_O_p_t_i_o_n_s))
Create a Prolog thread with the alias name pce for XPCE event
handling. In the X11 version this call creates a thread that
executes the X11 event-dispatch loop. In MS-Windows it creates
a thread that executes a windows event-dispatch loop. The XPCE
event-handling thread has the alias pce. _O_p_t_i_o_n_s specifies the
thread attributes as thread_create/3.
CChhaapptteerr 99.. FFOORREEIIGGNN LLAANNGGUUAAGGEE IINNTTEERRFFAACCEE
SWI-Prolog offers a powerful interface to C
[Kernighan & Ritchie, 1978]. The main design objectives of the
foreign language interface are flexibility and performance. A foreign
predicate is a C function that has the same number of arguments as
the predicate represented. C functions are provided to analyse the
passed terms, convert them to basic C types as well as to instantiate
arguments using unification. Non-deterministic foreign predicates are
supported, providing the foreign function with a handle to control
backtracking.
C can call Prolog predicates, providing both a query interface and an
interface to extract multiple solutions from a non-deterministic Prolog
predicate. There is no limit to the nesting of Prolog calling C,
calling Prolog, etc. It is also possible to write the `main' in C and
use Prolog as an embedded logical engine.
99..11 OOvveerrvviieeww ooff tthhee IInntteerrffaaccee
A special include file called SWI-Prolog.h should be included with each
C source file that is to be loaded via the foreign interface. The
installation process installs this file in the directory include in the
SWI-Prolog home directory (?- current_prolog_flag(home, Home).). This C
header file defines various data types, macros and functions that can
be used to communicate with SWI-Prolog. Functions and macros can be
divided into the following categories:
o Analysing Prolog terms
o Constructing new terms
o Unifying terms
o Returning control information to Prolog
o Registering foreign predicates with Prolog
o Calling Prolog from C
o Recorded database interactions
o Global actions on Prolog (halt, break, abort, etc.)
99..22 LLiinnkkiinngg FFoorreeiiggnn MMoodduulleess
Foreign modules may be linked to Prolog in two ways. Using _s_t_a_t_i_c
_l_i_n_k_i_n_g, the extensions, a (short) file defining main() which attaches
the extension calls to Prolog, and the SWI-Prolog kernel distributed
as a C library, are linked together to form a new executable. Using
_d_y_n_a_m_i_c _l_i_n_k_i_n_g, the extensions are linked to a shared library (.so
file on most Unix systems) or dynamic link library (.DLL file on
Microsoft platforms) and loaded into the running Prolog process.
99..22..11 WWhhaatt lliinnkkiinngg iiss pprroovviiddeedd??
The _s_t_a_t_i_c _l_i_n_k_i_n_g schema can be used on all versions of SWI-Prolog.
Whether or not dynamic linking is supported can be deduced from the
Prolog flag open_shared_object (see current_prolog_flag/2). If this
Prolog flag yields true, open_shared_object/2 and related predicates are
defined. See section 9.2.3 for a suitable high-level interface to
these predicates.
99..22..22 WWhhaatt kkiinndd ooff llooaaddiinngg sshhoouulldd II bbee uussiinngg??
All described approaches have their advantages and disadvantages.
Static linking is portable and allows for debugging on all platforms.
It is relatively cumbersome and the libraries you need to pass to the
linker may vary from system to system, though the utility program
swipl-ld described in section 9.5 often hides these problems from the
user.
Loading shared objects (DLL files on Windows) provides sharing and
protection and is generally the best choice. If a saved state is
created using qsave_program/[1,2], an initialization/1 directive may be
used to load the appropriate library at startup.
Note that the definition of the foreign predicates is the same,
regardless of the linking type used.
99..22..33 lliibbrraarryy((sshhlliibb)):: UUttiilliittyy lliibbrraarryy ffoorr llooaaddiinngg ffoorreeiiggnn oobbjjeeccttss
((DDLLLLss,, sshhaarreedd oobbjjeeccttss))
This section discusses the functionality of the (autoload)
library(shlib), providing an interface to manage shared libraries. We
describe the procedure for using a foreign resource (DLL in Windows and
shared object in Unix) called mylib.
First, one must assemble the resource and make it compatible to
SWI-Prolog. The details for this vary between platforms. The
swipl-ld(1) utility can be used to deal with this in a portable manner.
The typical commandline is:
________________________________________________________________________| |
|swipl-ld|-o_mylib_file.{c,o,cc,C}_...__________________________________ | |
Make sure that one of the files provides a global function
install_mylib() that initialises the module using calls to
PL_register_foreign(). Here is a simple example file mylib.c, which
creates a Windows MessageBox:
________________________________________________________________________| |
|#include <windows.h> |
|#include <SWI-Prolog.h> |
| |
|static foreign_t |
|pl_say_hello(term_t to) |
|{ char *a; |
| |
| if ( PL_get_atom_chars(to, &a) ) |
| { MessageBox(NULL, a, "DLL test", MB_OK|MB_TASKMODAL); |
| |
| PL_succeed; |
| } |
| |
| PL_fail; |
|} |
| |
|install_t |
|install_mylib() |
|{ PL_register_foreign("say_hello", 1, pl_say_hello, 0); |
|}|_____________________________________________________________________ | |
Now write a file mylib.pl:
________________________________________________________________________| |
|:- module(mylib, [ say_hello/1 ]). |
|:-|use_foreign_library(foreign(mylib)).________________________________ | |
The file mylib.pl can be loaded as a normal Prolog file and provides
the predicate defined in C.
llooaadd__ffoorreeiiggnn__lliibbrraarryy((_:_F_i_l_e_S_p_e_c)) _[_d_e_t_]
llooaadd__ffoorreeiiggnn__lliibbrraarryy((_:_F_i_l_e_S_p_e_c_, _+_E_n_t_r_y_:_a_t_o_m)) _[_d_e_t_]
Load a _s_h_a_r_e_d _o_b_j_e_c_t or _D_L_L. After loading the _E_n_t_r_y function
is called without arguments. The default entry function is
composed from =install_=, followed by the file base-name. E.g.,
the load-call below calls the function install_mylib(). If the
platform prefixes extern functions with =_=, this prefix is added
before calling.
____________________________________________________________________| |
| ... |
| load_foreign_library(foreign(mylib)), |
||______..._________________________________________________________ ||
___________________________________________________________Arguments_
_F_i_l_e_S_p_e_c is a specification for absolute_file_name/3.
If searching the file fails, the plain name
is passed to the OS to try the default
method of the OS for locating foreign objects.
The default definition of file_search_path/2
searches <prolog home>/lib/<arch> on Unix and
<prolog home>/bin on Windows.
SSeeee aallssoo use_foreign_library/1,2 are intended for use in
directives.
uussee__ffoorreeiiggnn__lliibbrraarryy((_+_F_i_l_e_S_p_e_c)) _[_d_e_t_]
uussee__ffoorreeiiggnn__lliibbrraarryy((_+_F_i_l_e_S_p_e_c_, _+_E_n_t_r_y_:_a_t_o_m)) _[_d_e_t_]
Load and install a foreign library as load_foreign_library/1,2 and
register the installation using initialization/2 with the option
now. This is similar to using:
____________________________________________________________________| |
||:-_initialization(load_foreign_library(foreign(mylib))).__________ ||
but using the initialization/1 wrapper causes the library to be
loaded _a_f_t_e_r loading of the file in which it appears is completed,
while use_foreign_library/1 loads the library _i_m_m_e_d_i_a_t_e_l_y. I.e.
the difference is only relevant if the remainder of the file uses
functionality of the C-library.
uunnllooaadd__ffoorreeiiggnn__lliibbrraarryy((_+_F_i_l_e_S_p_e_c)) _[_d_e_t_]
uunnllooaadd__ffoorreeiiggnn__lliibbrraarryy((_+_F_i_l_e_S_p_e_c_, _+_E_x_i_t_:_a_t_o_m)) _[_d_e_t_]
Unload a _s_h_a_r_e_d _o_b_j_e_c_t or _D_L_L. After calling the _E_x_i_t function,
the shared object is removed from the process. The default
exit function is composed from =uninstall_=, followed by the file
base-name.
ccuurrrreenntt__ffoorreeiiggnn__lliibbrraarryy((_?_F_i_l_e_, _?_P_u_b_l_i_c))
Query currently loaded shared libraries.
rreellooaadd__ffoorreeiiggnn__lliibbrraarriieess
Reload all foreign libraries loaded (after restore of a state
created using qsave_program/2.
99..22..44 LLooww--lleevveell ooppeerraattiioonnss oonn sshhaarreedd lliibbrraarriieess
The interface defined in this section allows the user to load shared
libraries (.so files on most Unix systems, .dll files on Windows).
This interface is portable to Windows as well as to Unix machines
providing dlopen(2) (Solaris, Linux, FreeBSD, Irix and many more)
or shl_open(2) (HP/UX). It is advised to use the predicates from
section 9.2.3 in your application.
ooppeenn__sshhaarreedd__oobbjjeecctt((_+_F_i_l_e_, _-_H_a_n_d_l_e))
_F_i_l_e is the name of a shared object file (DLL in MS-Windows).
This file is attached to the current process, and _H_a_n_d_l_e
is unified with a handle to the library. Equivalent to
open_shared_object(File, Handle, []). See also open_shared_object/3
and load_foreign_library/1.
On errors, an exception shared_object(_A_c_t_i_o_n_, _M_e_s_s_a_g_e) is raised.
_M_e_s_s_a_g_e is the return value from dlerror().
ooppeenn__sshhaarreedd__oobbjjeecctt((_+_F_i_l_e_, _-_H_a_n_d_l_e_, _+_O_p_t_i_o_n_s))
As open_shared_object/2, but allows for additional flags to be
passed. _O_p_t_i_o_n_s is a list of atoms. now implies the symbols are
resolved immediately rather than lazy (default). global implies
symbols of the loaded object are visible while loading other shared
objects (by default they are local). Note that these flags may not
be supported by your operating system. Check the documentation of
dlopen() or equivalent on your operating system. Unsupported flags
are silently ignored.
cclloossee__sshhaarreedd__oobbjjeecctt((_+_H_a_n_d_l_e))
Detach the shared object identified by _H_a_n_d_l_e.
ccaallll__sshhaarreedd__oobbjjeecctt__ffuunnccttiioonn((_+_H_a_n_d_l_e_, _+_F_u_n_c_t_i_o_n))
Call the named function in the loaded shared library. The function
is called without arguments and the return value is ignored.
Normally this function installs foreign language predicates using
calls to PL_register_foreign().
99..22..55 SSttaattiicc LLiinnkkiinngg
Below is an outline of the file structure required for statically
linking SWI-Prolog with foreign extensions. .../swipl refers to the
SWI-Prolog home directory (see the Prolog flag home). <_a_r_c_h> refers to
the architecture identifier that may be obtained using the Prolog flag
arch.
.../swipl/runtime/<_a_r_c_h>/libswipl.a SWI-Library
.../swipl/include/SWI-Prolog.h Include file
.../swipl/include/SWI-Stream.h Stream I/O include file
.../swipl/include/SWI-Exports Export declarations (AIX only)
.../swipl/include/stub.c Extension stub
The definition of the foreign predicates is the same as for dynamic
linking. Unlike with dynamic linking, however, there is no
initialisation function. Instead, the file .../swipl/include/stub.c
may be copied to your project and modified to define the foreign
extensions. Below is stub.c, modified to link the lowercase example
described later in this chapter:
________________________________________________________________________| |
|#include <stdio.h> |
|#include <SWI-Prolog.h> |
| |
|extern foreign_t pl_lowercase(term, term); |
| |
|PL_extension predicates[] = |
|{ |
|/*{ "name", arity, function, PL_FA_<flags> },*/ |
| |
| { "lowercase", 2 pl_lowercase, 0 }, |
| { NULL, 0, NULL, 0 } /* terminating line */ |
|}; |
| |
| |
|int |
|main(int argc, char **argv) |
|{ PL_register_extensions(predicates); |
| |
| if ( !PL_initialise(argc, argv) ) |
| PL_halt(1); |
| |
| PL_install_readline(); /* delete if not required */ |
| |
| PL_halt(PL_toplevel() ? 0 : 1); |
|}|_____________________________________________________________________ | |
Now, a new executable may be created by compiling this file and
linking it to libpl.a from the runtime directory and the libraries
required by both the extensions and the SWI-Prolog kernel. This
may be done by hand, or by using the swipl-ld utility described in
section 9.5. If the linking is performed by hand, the command line
option -dump-runtime-variables (see section 2.4) can be used to obtain
the required paths, libraries and linking options to link the new
executable.
99..33 IInntteerrffaaccee DDaattaa TTyyppeess
99..33..11 TTyyppee term_t:: aa rreeffeerreennccee ttoo aa PPrroolloogg tteerrmm
The principal data type is term_t. Type term_t is what Quintus calls
QP_term_ref. This name indicates better what the type represents: it
is a _h_a_n_d_l_e for a term rather than the term itself. Terms can only be
represented and manipulated using this type, as this is the only safe
way to ensure the Prolog kernel is aware of all terms referenced by
foreign code and thus allows the kernel to perform garbage collection
and/or stack-shifts while foreign code is active, for example during a
callback from C.
A term reference is a C unsigned long, representing the offset of a
variable on the Prolog environment stack. A foreign function is passed
term references for the predicate arguments, one for each argument. If
references for intermediate results are needed, such references may be
created using PL_new_term_ref() or PL_new_term_refs(). These references
normally live till the foreign function returns control back to Prolog.
Their scope can be explicitly limited using PL_open_foreign_frame() and
PL_close_foreign_frame()/PL_discard_foreign_frame().
A term_t always refers to a valid Prolog term (variable, atom, integer,
float or compound term). A term lives either until backtracking
takes us back to a point before the term was created, the garbage
collector has collected the term, or the term was created after a
PL_open_foreign_frame()and PL_discard_foreign_frame()has been called.
The foreign interface functions can either _r_e_a_d, _u_n_i_f_y or _w_r_i_t_e to
term references. In this document we use the following notation for
arguments of type term_t:
term_t +t Accessed in read-mode. The `+' indicates the
argument is `input'.
term_t -t Accessed in write-mode.
term_t ?t Accessed in unify-mode.
Term references are obtained in any of the following ways:
o _P_a_s_s_e_d _a_s _a_r_g_u_m_e_n_t
The C functions implementing foreign predicates are passed their
arguments as term references. These references may be read or
unified. Writing to these variables causes undefined behaviour.
o _C_r_e_a_t_e_d _b_y PL_new_term_ref()
A term created by PL_new_term_ref() is normally used to build
temporary terms or to be written by one of the interface functions.
For example, PL_get_arg() writes a reference to the term argument
in its last argument.
o _C_r_e_a_t_e_d _b_y PL_new_term_refs(_i_n_t _n)
This function returns a set of term references with the same
characteristics as PL_new_term_ref(). See PL_open_query().
o _C_r_e_a_t_e_d _b_y PL_copy_term_ref(_t_e_r_m___t _t)
Creates a new term reference to the same term as the argument. The
term may be written to. See figure 9.2.
Term references can safely be copied to other C variables of type
term_t, but all copies will always refer to the same term.
term_t PPLL__nneeww__tteerrmm__rreeff()
Return a fresh reference to a term. The reference is allocated
on the _l_o_c_a_l stack. Allocating a term reference may trigger a
stack-shift on machines that cannot use sparse memory management
for allocation of the Prolog stacks. The returned reference
describes a variable.
term_t PPLL__nneeww__tteerrmm__rreeffss(_i_n_t _n)
Return _n new term references. The first term reference is
returned. The others are _t +1, _t +2, etc. There are two reasons
for using this function. PL_open_query()expects the arguments as
a set of consecutive term references, and _v_e_r_y time-critical code
requiring a number of term references can be written as:
____________________________________________________________________| |
| pl_mypredicate(term_t a0, term_t a1) |
| { term_t t0 = PL_new_term_refs(2); |
| term_t t1 = t0+1; |
| |
| ... |
||}_________________________________________________________________ ||
term_t PPLL__ccooppyy__tteerrmm__rreeff(_t_e_r_m___t _f_r_o_m)
Create a new term reference and make it point initially to the same
term as _f_r_o_m. This function is commonly used to copy a predicate
argument to a term reference that may be written.
void PPLL__rreesseett__tteerrmm__rreeffss(_t_e_r_m___t _a_f_t_e_r)
Destroy all term references that have been created after _a_f_t_e_r,
including _a_f_t_e_r itself. Any reference to the invalidated term
references after this call results in undefined behaviour.
Note that returning from the foreign context to Prolog will
reclaim all references used in the foreign context. This call
is only necessary if references are created inside a loop that
never exits back to Prolog. See also PL_open_foreign_frame(),
PL_close_foreign_frame() and PL_discard_foreign_frame().
99..33..11..11 IInntteerraaccttiioonn wwiitthh tthhee ggaarrbbaaggee ccoolllleeccttoorr aanndd ssttaacckk--sshhiifftteerr
Prolog implements two mechanisms for avoiding stack overflow: garbage
collection and stack expansion. On machines that allow for it, Prolog
will use virtual memory management to detect stack overflow and expand
the runtime stacks. On other machines Prolog will reallocate the
stacks and update all pointers to them. To do so, Prolog needs to
know which data is referenced by C code. As all Prolog data known by
C is referenced through term references (term_t), Prolog has all the
information necessary to perform its memory management without special
precautions from the C programmer.
99..33..22 OOtthheerr ffoorreeiiggnn iinntteerrffaaccee ttyyppeess
aattoomm__tt An atom in Prolog's internal representation. Atoms are pointers
to an opaque structure. They are a unique representation for
represented text, which implies that atom A represents the same
text as atom B if and only if A and B are the same pointer.
Atoms are the central representation for textual constants in
Prolog. The transformation of a character string C to an atom
implies a hash-table lookup. If the same atom is needed often, it
is advised to store its reference in a global variable to avoid
repeated lookup.
ffuunnccttoorr__tt A functor is the internal representation of a name/arity
pair. They are used to find the name and arity of a compound term
as well as to construct new compound terms. Like atoms they live
for the whole Prolog session and are unique.
pprreeddiiccaattee__tt Handle to a Prolog predicate. Predicate handles live
forever (although they can lose their definition).
qqiidd__tt Query identifier. Used by PL_open_query(), PL_next_solution() and
PL_close_query() to handle backtracking from C.
ffiidd__tt Frame identifier. Used by PL_open_foreign_frame() and
PL_close_foreign_frame().
mmoodduullee__tt A module is a unique handle to a Prolog module. Modules are
used only to call predicates in a specific module.
ffoorreeiiggnn__tt Return type for a C function implementing a Prolog predicate.
ccoonnttrrooll__tt Passed as additional argument to non-deterministic foreign
functions. See PL_retry*() and PL_foreign_context*().
iinnssttaallll__tt Type for the install() and uninstall() functions of shared or
dynamic link libraries. See section 9.2.3.
iinntt6644__tt Actually part of the C99 standard rather than Prolog. As
of version 5.5.6, Prolog integers are 64-bit on all hardware.
The C99 type int64_t is defined in the stdint.h standard header
and provides platform-independent 64-bit integers. Portable code
accessing Prolog should use this type to exchange integer values.
Please note that PL_get_long() can return FALSE on Prolog integers
that cannot be represented as a C long. Robust code should not
assume any of the integer fetching functions to succeed, _e_v_e_n if
the Prolog term is known to be an integer.
99..44 TThhee FFoorreeiiggnn IInncclluuddee FFiillee
99..44..11 AArrgguummeenntt PPaassssiinngg aanndd CCoonnttrrooll
If Prolog encounters a foreign predicate at run time it will call
a function specified in the predicate definition of the foreign
predicate. The arguments 1;:::; <_a_r_i_t_y>pass the Prolog arguments to the
goal as Prolog terms. Foreign functions should be declared of type
foreign_t. Deterministic foreign functions have two alternatives to
return control back to Prolog:
_(_r_e_t_u_r_n_) _f_o_r_e_i_g_n___t PPLL__ssuucccceeeedd(())
Succeed deterministically. PL_succeed is defined as return TRUE.
_(_r_e_t_u_r_n_) _f_o_r_e_i_g_n___t PPLL__ffaaiill(())
Fail and start Prolog backtracking. PL_fail is defined as
return FALSE.
99..44..11..11 NNoonn--ddeetteerrmmiinniissttiicc FFoorreeiiggnn PPrreeddiiccaatteess
By default foreign predicates are deterministic. Using the
PL_FA_NONDETERMINISTIC attribute (see PL_register_foreign()) it is
possible to register a predicate as a non-deterministic predicate.
Writing non-deterministic foreign predicates is slightly more
complicated as the foreign function needs context information for
generating the next solution. Note that the same foreign function
should be prepared to be simultaneously active in more than one
goal. Suppose the natural_number_below_n/2 is a non-deterministic
foreign predicate, backtracking over all natural numbers lower than the
first argument. Now consider the following predicate:
________________________________________________________________________| |
|quotient_below_n(Q, N) :- |
| natural_number_below_n(N, N1), |
| natural_number_below_n(N, N2), |
||_______Q_=:=_N1_/_N2,_!.______________________________________________ ||
In this predicate the function natural_number_below_n/2 simultaneously
generates solutions for both its invocations.
Non-deterministic foreign functions should be prepared to handle three
different calls from Prolog:
o _I_n_i_t_i_a_l _c_a_l_l _(PL_FIRST_CALL_)
Prolog has just created a frame for the foreign function and asks
it to produce the first answer.
o _R_e_d_o _c_a_l_l _(PL_REDO_)
The previous invocation of the foreign function associated with the
current goal indicated it was possible to backtrack. The foreign
function should produce the next solution.
o _T_e_r_m_i_n_a_t_e _c_a_l_l _(PL_PRUNED_)
The choice point left by the foreign function has been destroyed by
a cut. The foreign function is given the opportunity to clean the
environment.
Both the context information and the type of call is provided
by an argument of type control_t appended to the argument list
for deterministic foreign functions. The macro PL_foreign_control()
extracts the type of call from the control argument. The
foreign function can pass a context handle using the PL_retry*()
macros and extract the handle from the extra argument using the
PL_foreign_context*() macro.
_(_r_e_t_u_r_n_) _f_o_r_e_i_g_n___t PPLL__rreettrryy((_i_n_t_p_t_r___t _v_a_l_u_e))
The foreign function succeeds while leaving a choice point. On
backtracking over this goal the foreign function will be called
again, but the control argument now indicates it is a `Redo'
call and the macro PL_foreign_context() returns the handle passed
via PL_retry(). This handle is a signed value two bits smaller
than a pointer, i.e., 30 or 62 bits (two bits are used for
status indication). Defined as return _PL_retry(_n). See also
PL_succeed().
_(_r_e_t_u_r_n_) _f_o_r_e_i_g_n___t PPLL__rreettrryy__aaddddrreessss((_v_o_i_d _*))
As PL_retry(), but ensures an address as returned by malloc() is
correctly recovered by PL_foreign_context_address(). Defined as
return _PL_retry_address(_n). See also PL_succeed().
_i_n_t PPLL__ffoorreeiiggnn__ccoonnttrrooll((_c_o_n_t_r_o_l___t))
Extracts the type of call from the control argument. The return
values are described above. Note that the function should be
prepared to handle the PL_PRUNED case and should be aware that the
other arguments are not valid in this case.
_i_n_t_p_t_r___t PPLL__ffoorreeiiggnn__ccoonntteexxtt((_c_o_n_t_r_o_l___t))
Extracts the context from the context argument. If the call type
is PL_FIRST_CALL the context value is 0L. Otherwise it is the value
returned by the last PL_retry() associated with this goal (both if
the call type is PL_REDO or PL_PRUNED).
_v_o_i_d _* PPLL__ffoorreeiiggnn__ccoonntteexxtt__aaddddrreessss((_c_o_n_t_r_o_l___t))
Extracts an address as passed in by PL_retry_address().
Note: If a non-deterministic foreign function returns using
PL_succeed() or PL_fail(), Prolog assumes the foreign function has
cleaned its environment. NNoo call with control argument PL_PRUNED will
follow.
The code of figure 9.1 shows a skeleton for a non-deterministic foreign
predicate definition.
________________________________________________________________________| |
|typedef struct /* define a context structure */ |
|{ ... |
|} context; |
| |
|foreign_t |
|my_function(term_t a0, term_t a1, control_t handle) |
|{ struct context * ctxt; |
| |
| switch( PL_foreign_control(handle) ) |
| { case PL_FIRST_CALL: |
| ctxt = malloc(sizeof(struct context)); |
| ... |
| PL_retry_address(ctxt); |
| case PL_REDO: |
| ctxt = PL_foreign_context_address(handle); |
| ... |
| PL_retry_address(ctxt); |
| case PL_PRUNED: |
| ctxt = PL_foreign_context_address(handle); |
| ... |
| free(ctxt); |
| PL_succeed; |
| } |
|}|_____________________________________________________________________ | |
Figure 9.1: Skeleton for non-deterministic foreign functions
99..44..22 AAttoommss aanndd ffuunnccttoorrss
The following functions provide for communication using atoms and
functors.
atom_t PPLL__nneeww__aattoomm(_c_o_n_s_t _c_h_a_r _*)
Return an atom handle for the given C-string. This function always
succeeds. The returned handle is valid as long as the atom is
referenced (see section 9.4.2.1). The following atoms are provided
as macros, giving access to the empty list symbol and the name of
the list constructor. Prior to version 7, ATOM_nil is the same
as PL_new_atom(_"_[_]_") and ATOM_dot is the same as PL_new_atom(_"_._").
This is no long the case in SWI-Prolog version 7.
_a_t_o_m___t AATTOOMM__nniill((_A))
tomic constant that represents the empty list. It is
adviced to use PL_get_nil(), PL_put_nil() or PL_unify_nil()
where applicable.
_a_t_o_m___t AATTOOMM__ddoott((_A))
tomic constant that represents the name of the list con-
structor. The list constructor itself is created using
PL_new_functor(_A_T_O_M___d_o_t_,_2). It is adviced to use PL_get_list(),
PL_put_list()or PL_unify_list() where applicable.
const char* PPLL__aattoomm__cchhaarrss(_a_t_o_m___t _a_t_o_m)
Return a C-string for the text represented by the given atom. The
returned text will not be changed by Prolog. It is not allowed to
modify the contents, not even `temporary' as the string may reside
in read-only memory. The returned string becomes invalid if the
atom is garbage collected (see section 9.4.2.1). Foreign functions
that require the text from an atom passed in a term_t normally use
PL_get_atom_chars() or PL_get_atom_nchars().
functor_t PPLL__nneeww__ffuunnccttoorr(_a_t_o_m___t _n_a_m_e_, _i_n_t _a_r_i_t_y)
Returns a _f_u_n_c_t_o_r _i_d_e_n_t_i_f_i_e_r, a handle for the name/arity pair.
The returned handle is valid for the entire Prolog session.
atom_t PPLL__ffuunnccttoorr__nnaammee(_f_u_n_c_t_o_r___t _f)
Return an atom representing the name of the given functor.
int PPLL__ffuunnccttoorr__aarriittyy(_f_u_n_c_t_o_r___t _f)
Return the arity of the given functor.
99..44..22..11 AAttoommss aanndd aattoomm ggaarrbbaaggee ccoolllleeccttiioonn
With the introduction of atom garbage collection in version 3.3.0,
atoms no longer live as long as the process. Instead, their
lifetime is guaranteed only as long as they are referenced. In the
single-threaded version, atom garbage collections are only invoked at
the _c_a_l_l_-_p_o_r_t. In the multithreaded version (see chapter 8), they
appear asynchronously, except for the invoking thread.
For dealing with atom garbage collection, two additional functions are
provided:
void PPLL__rreeggiisstteerr__aattoomm(_a_t_o_m___t _a_t_o_m)
Increment the reference count of the atom by one. PL_new_atom()
performs this automatically, returning an atom with a reference
count of at least one.
void PPLL__uunnrreeggiisstteerr__aattoomm(_a_t_o_m___t _a_t_o_m)
Decrement the reference count of the atom. If the reference count
drops below zero, an assertion error is raised.
Please note that the following two calls are different with respect to
atom garbage collection:
________________________________________________________________________| |
|PL_unify_atom_chars(t, "text"); |
|PL_unify_atom(t,|PL_new_atom("text"));_________________________________ | |
The latter increments the reference count of the atom text, which
effectively ensures the atom will never be collected. It is advised to
use the *_chars() or *_nchars() functions whenever applicable.
99..44..33 AAnnaallyyssiinngg TTeerrmmss vviiaa tthhee FFoorreeiiggnn IInntteerrffaaccee
Each argument of a foreign function (except for the control argument)
is of type term_t, an opaque handle to a Prolog term. Three groups of
functions are available for the analysis of terms. The first just
validates the type, like the Prolog predicates var/1, atom/1, etc.,
and are called PL_is_*(). The second group attempts to translate the
argument into a C primitive type. These predicates take a term_t and a
pointer to the appropriate C type and return TRUE or FALSE depending on
successful or unsuccessful translation. If the translation fails, the
pointed-to data is never modified.
99..44..33..11 TTeessttiinngg tthhee ttyyppee ooff aa tteerrmm
int PPLL__tteerrmm__ttyyppee(_t_e_r_m___t)
Obtain the type of a term, which should be a term returned by
one of the other interface predicates or passed as an argument.
The function returns the type of the Prolog term. The type
identifiers are listed below. Note that the extraction functions
PL_get_*() also validate the type and thus the two sections below
are equivalent.
____________________________________________________________________| |
| if ( PL_is_atom(t) ) |
| { char *s; |
| |
| PL_get_atom_chars(t, &s); |
| ...; |
| } |
| |
| or |
| |
| char *s; |
| if ( PL_get_atom_chars(t, &s) ) |
| { ...; |
||________}_________________________________________________________ ||
_______________________________________________________________
| PL_VARIABLE |An unbound variable. The value of|
| |term as such is a unique identifier|
| |for the variable. |
| PL_ATOM |A Prolog atom. |
| PL_STRING |A Prolog string. |
| PL_INTEGER |A Prolog integer. |
| PL_FLOAT |A Prolog floating point number. |
| PL_TERM |A compound term. Note that a list|
|________________________|is_a_compound_term_./2.______________|
The functions PL_is_<_t_y_p_e> are an alternative to PL_term_type(). The test
PL_is_variable(_t_e_r_m) is equivalent to PL_term_type(_t_e_r_m)== PL_VARIABLE,
but the first is considerably faster. On the other hand, using a
switch over PL_term_type() is faster and more readable then using an
if-then-else using the functions below. All these functions return
either TRUE or FALSE.
int PPLL__iiss__vvaarriiaabbllee(_t_e_r_m___t)
Returns non-zero if _t_e_r_m is a variable.
int PPLL__iiss__ggrroouunndd(_t_e_r_m___t)
Returns non-zero if _t_e_r_m is a ground term. See also ground/1.
This function is cycle-safe.
int PPLL__iiss__aattoomm(_t_e_r_m___t)
Returns non-zero if _t_e_r_m is an atom.
int PPLL__iiss__ssttrriinngg(_t_e_r_m___t)
Returns non-zero if _t_e_r_m is a string.
int PPLL__iiss__iinntteeggeerr(_t_e_r_m___t)
Returns non-zero if _t_e_r_m is an integer.
int PPLL__iiss__ffllooaatt(_t_e_r_m___t)
Returns non-zero if _t_e_r_m is a float.
int PPLL__iiss__ccaallllaabbllee(_t_e_r_m___t)
Returns non-zero if _t_e_r_m is a callable term. See callable/1 for
details.
int PPLL__iiss__ccoommppoouunndd(_t_e_r_m___t)
Returns non-zero if _t_e_r_m is a compound term.
int PPLL__iiss__ffuunnccttoorr(_t_e_r_m___t_, _f_u_n_c_t_o_r___t)
Returns non-zero if _t_e_r_m is compound and its functor is _f_u_n_c_t_o_r.
This test is equivalent to PL_get_functor(), followed by testing
the functor, but easier to write and faster.
int PPLL__iiss__lliisstt(_t_e_r_m___t)
Returns non-zero if _t_e_r_m is a compound term with functor ./2 or the
atom []. See also PL_is_pair() and PL_skip_list().
int PPLL__iiss__ppaaiirr(_t_e_r_m___t)
Returns non-zero if _t_e_r_m is a compound term with functor ./2. See
also PL_is_list() and PL_skip_list().
int PPLL__iiss__aattoommiicc(_t_e_r_m___t)
Returns non-zero if _t_e_r_m is atomic (not variable or compound).
int PPLL__iiss__nnuummbbeerr(_t_e_r_m___t)
Returns non-zero if _t_e_r_m is an integer or float.
int PPLL__iiss__aaccyycclliicc(_t_e_r_m___t)
Returns non-zero if _t_e_r_m is acyclic (i.e. a finite tree).
99..44..33..22 RReeaaddiinngg ddaattaa ffrroomm aa tteerrmm
The functions PL_get_*() read information from a Prolog term. Most of
them take two arguments. The first is the input term and the second is
a pointer to the output value or a term reference.
int PPLL__ggeett__aattoomm(_t_e_r_m___t _+_t_, _a_t_o_m___t _*_a)
If _t is an atom, store the unique atom identifier over _a. See also
PL_atom_chars() and PL_new_atom(). If there is no need to access
the data (characters) of an atom, it is advised to manipulate atoms
using their handle. As the atom is referenced by _t, it will live
at least as long as _t does. If longer live-time is required, the
atom should be locked using PL_register_atom().
int PPLL__ggeett__aattoomm__cchhaarrss(_t_e_r_m___t _+_t_, _c_h_a_r _*_*_s)
If _t is an atom, store a pointer to a 0-terminated C-string in _s.
It is explicitly nnoott allowed to modify the contents of this string.
Some built-in atoms may have the string allocated in read-only
memory, so `temporary manipulation' can cause an error.
int PPLL__ggeett__ssttrriinngg__cchhaarrss(_t_e_r_m___t _+_t_, _c_h_a_r _*_*_s_, _i_n_t _*_l_e_n)
If _t is a string object, store a pointer to a 0-terminated
C-string in _s and the length of the string in _l_e_n. Note that
this pointer is invalidated by backtracking, garbage collection and
stack-shifts, so generally the only save operations are to pass it
immediately to a C function that doesn't involve Prolog.
int PPLL__ggeett__cchhaarrss(_t_e_r_m___t _+_t_, _c_h_a_r _*_*_s_, _u_n_s_i_g_n_e_d _f_l_a_g_s)
Convert the argument term _t to a 0-terminated C-string. _f_l_a_g_s is
a bitwise disjunction from two groups of constants. The first
specifies which term types should be converted and the second
how the argument is stored. Below is a specification of these
constants. BUF_RING implies, if the data is not static (as from an
atom), that the data is copied to the next buffer from a ring of 16
buffers. This is a convenient way of converting multiple arguments
passed to a foreign predicate to C-strings. If BUF_MALLOC is used,
the data must be freed using PL_free() when no longer needed.
With the introduction of wide characters (see section 2.18.1), not
all atoms can be converted into a char*. This function fails if _t
is of the wrong type, but also if the text cannot be represented.
See the REP_* flags below for details.
CCVVTT__AATTOOMM
Convert if term is an atom.
CCVVTT__SSTTRRIINNGG
Convert if term is a string.
CCVVTT__LLIISSTT
Convert if term is a list of of character codes.
CCVVTT__IINNTTEEGGEERR
Convert if term is an integer.
CCVVTT__FFLLOOAATT
Convert if term is a float. The characters returned are the
same as write/1 would write for the floating point number.
CCVVTT__NNUUMMBBEERR
Convert if term is an integer or float.
CCVVTT__AATTOOMMIICC
Convert if term is atomic.
CCVVTT__VVAARRIIAABBLLEE
Convert variable to print-name
CCVVTT__WWRRIITTEE
Convert any term that is not converted by any of the other
flags using write/1. If no BUF_* is provided, BUF_RING is
implied.
CCVVTT__WWRRIITTEE__CCAANNOONNIICCAALL
As CVT_WRITE, but using write_canonical/2.
CCVVTT__WWRRIITTEEQQ
As CVT_WRITE, but using writeq/2.
CCVVTT__AALLLL
Convert if term is any of the above, except for CVT_VARIABLE
and CVT_WRITE*.
CCVVTT__EEXXCCEEPPTTIIOONN
If conversion fails due to a type error, raise a Prolog type
error exception in addition to failure
BBUUFF__DDIISSCCAARRDDAABBLLEE
Data must copied immediately
BBUUFF__RRIINNGG
Data is stored in a ring of buffers
BBUUFF__MMAALLLLOOCC
Data is copied to a new buffer returned by PL_malloc(3). When
no longer needed the user must call PL_free() on the data.
RREEPP__IISSOO__LLAATTIINN__11
Text is in ISO Latin-1 encoding and the call fails if text
cannot be represented. This flag has the value 0 and is thus
the default.
RREEPP__UUTTFF88
Convert the text to a UTF-8 string. This works for all text.
RREEPP__MMBB
Convert to default locale-defined 8-bit string. Success
depends on the locale. Conversion is done using the wcrtomb()
C library function.
int PPLL__ggeett__lliisstt__cchhaarrss(_+_t_e_r_m___t _l_, _c_h_a_r _*_*_s_, _u_n_s_i_g_n_e_d _f_l_a_g_s)
Same as PL_get_chars(_l_, _s_, _C_V_T___L_I_S_T___f_l_a_g_s), provided _f_l_a_g_s contains
none of the CVT_* flags.
int PPLL__ggeett__iinntteeggeerr(_+_t_e_r_m___t _t_, _i_n_t _*_i)
If _t is a Prolog integer, assign its value over _i. On 32-bit
machines, this is the same as PL_get_long(), but avoids a warning
from the compiler. See also PL_get_long().
int PPLL__ggeett__lloonngg(_t_e_r_m___t _+_t_, _l_o_n_g _*_i)
If _t is a Prolog integer that can be represented as a long, assign
its value over _i. If _t is an integer that cannot be represented by
a C long, this function returns FALSE. If _t is a floating point
number that can be represented as a long, this function succeeds as
well. See also PL_get_int64().
int PPLL__ggeett__iinntt6644(_t_e_r_m___t _+_t_, _i_n_t_6_4___t _*_i)
If _t is a Prolog integer or float that can be represented as a
int64_t, assign its value over _i. Currently all Prolog integers
can be represented using this type, but this might change if
SWI-Prolog introduces unbounded integers.
int PPLL__ggeett__iinnttppttrr(_t_e_r_m___t _+_t_, _i_n_t_p_t_r___t _*_i)
Get an integer that is at least as wide as a pointer. On most
platforms this is the same as PL_get_long(), but on Win64 pointers
are 8 bytes and longs only 4. Unlike PL_get_pointer(), the value
is not modified.
int PPLL__ggeett__bbooooll(_t_e_r_m___t _+_t_, _i_n_t _*_v_a_l)
If _t has the value true or false, set _v_a_l to the C constant TRUE or
FALSE and return success, otherwise return failure.
int PPLL__ggeett__ppooiinntteerr(_t_e_r_m___t _+_t_, _v_o_i_d _*_*_p_t_r)
In the current system, pointers are represented by Prolog integers,
but need some manipulation to make sure they do not get truncated
due to the limited Prolog integer range. PL_put_pointer() and
PL_get_pointer() guarantee pointers in the range of malloc() are
handled without truncating.
int PPLL__ggeett__ffllooaatt(_t_e_r_m___t _+_t_, _d_o_u_b_l_e _*_f)
If _t is a float or integer, its value is assigned over _f.
int PPLL__ggeett__ffuunnccttoorr(_t_e_r_m___t _+_t_, _f_u_n_c_t_o_r___t _*_f)
If _t is compound or an atom, the Prolog representation of
the name-arity pair will be assigned over _f. See also
PL_get_name_arity() and PL_is_functor().
int PPLL__ggeett__nnaammee__aarriittyy(_t_e_r_m___t _+_t_, _a_t_o_m___t _*_n_a_m_e_, _i_n_t _*_a_r_i_t_y)
If _t is compound or an atom, the functor name will be assigned
over _n_a_m_e and the arity over _a_r_i_t_y. See also PL_get_functor() and
PL_is_functor().
int PPLL__ggeett__mmoodduullee(_t_e_r_m___t _+_t_, _m_o_d_u_l_e___t _*_m_o_d_u_l_e)
If _t is an atom, the system will look up or create the
corresponding module and assign an opaque pointer to it over
_m_o_d_u_l_e.
int PPLL__ggeett__aarrgg(_i_n_t _i_n_d_e_x_, _t_e_r_m___t _+_t_, _t_e_r_m___t _-_a)
If _t is compound and index is between 1 and arity (inclusive),
assign _a with a term reference to the argument.
int _PPLL__ggeett__aarrgg(_i_n_t _i_n_d_e_x_, _t_e_r_m___t _+_t_, _t_e_r_m___t _-_a)
Same as PL_get_arg(), but no checking is performed, neither whether
_t is actually a term nor whether _i_n_d_e_x is a valid argument index.
99..44..33..33 EExxcchhaannggiinngg tteexxtt uussiinngg lleennggtthh aanndd ssttrriinngg
All internal text representation in SWI-Prolog is represented using
char * plus length and allow for _0_-_b_y_t_e_s in them. The foreign library
supports this by implementing a *_nchars() function for each applicable
*_chars() function. Below we briefly present the signatures of these
functions. For full documentation consult the *_chars() function.
int PPLL__ggeett__aattoomm__nncchhaarrss(_t_e_r_m___t _t_, _s_i_z_e___t _*_l_e_n_, _c_h_a_r _*_*_s)
See PL_get_atom_chars().
int PPLL__ggeett__lliisstt__nncchhaarrss(_t_e_r_m___t _t_, _s_i_z_e___t _*_l_e_n_, _c_h_a_r _*_*_s)
See PL_get_list_chars().
int PPLL__ggeett__nncchhaarrss(_t_e_r_m___t _t_, _s_i_z_e___t _*_l_e_n_, _c_h_a_r _*_*_s_, _u_n_s_i_g_n_e_d _i_n_t _f_l_a_g_s)
See PL_get_chars().
int PPLL__ppuutt__aattoomm__nncchhaarrss(_t_e_r_m___t _t_, _s_i_z_e___t _l_e_n_, _c_o_n_s_t _c_h_a_r _*_s)
See PL_put_atom_chars().
int PPLL__ppuutt__ssttrriinngg__nncchhaarrss(_t_e_r_m___t _t_, _s_i_z_e___t _l_e_n_, _c_o_n_s_t _c_h_a_r _*_s)
See PL_put_string_chars().
int PPLL__ppuutt__lliisstt__nnccooddeess(_t_e_r_m___t _t_, _s_i_z_e___t _l_e_n_, _c_o_n_s_t _c_h_a_r _*_s)
See PL_put_list_codes().
int PPLL__ppuutt__lliisstt__nncchhaarrss(_t_e_r_m___t _t_, _s_i_z_e___t _l_e_n_, _c_o_n_s_t _c_h_a_r _*_s)
See PL_put_list_chars().
int PPLL__uunniiffyy__aattoomm__nncchhaarrss(_t_e_r_m___t _t_, _s_i_z_e___t _l_e_n_, _c_o_n_s_t _c_h_a_r _*_s)
See PL_unify_atom_chars().
int PPLL__uunniiffyy__ssttrriinngg__nncchhaarrss(_t_e_r_m___t _t_, _s_i_z_e___t _l_e_n_, _c_o_n_s_t _c_h_a_r _*_s)
See PL_unify_string_chars().
int PPLL__uunniiffyy__lliisstt__nnccooddeess(_t_e_r_m___t _t_, _s_i_z_e___t _l_e_n_, _c_o_n_s_t _c_h_a_r _*_s)
See PL_unify_codes().
int PPLL__uunniiffyy__lliisstt__nncchhaarrss(_t_e_r_m___t _t_, _s_i_z_e___t _l_e_n_, _c_o_n_s_t _c_h_a_r _*_s)
See PL_unify_list_chars().
In addition, the following functions are available for creating and
inspecting atoms:
atom_t PPLL__nneeww__aattoomm__nncchhaarrss(_s_i_z_e___t _l_e_n_, _c_o_n_s_t _c_h_a_r _*_s)
Create a new atom as PL_new_atom(), but using the given length and
characters. If _l_e_n is (size_t)-1, it is computed from _s using
strlen().
const char * PPLL__aattoomm__nncchhaarrss(_a_t_o_m___t _a_, _s_i_z_e___t _*_l_e_n)
Extract the text and length of an atom.
99..44..33..44 WWiiddee--cchhaarraacctteerr vveerrssiioonnss
Support for exchange of wide-character strings is still under
consideration. The functions dealing with 8-bit character strings
return failure when operating on a wide-character atom or Prolog string
object. The functions below can extract and unify both 8-bit and wide
atoms and string objects. Wide character strings are represented as
C arrays of objects of the type pl_wchar_t, which is guaranteed to be
the same as wchar_t on platforms supporting this type. For example, on
MS-Windows, this represents 16-bit UCS2 characters, while using the GNU
C library (glibc) this represents 32-bit UCS4 characters.
atom_t PPLL__nneeww__aattoomm__wwcchhaarrss(_s_i_z_e___t _l_e_n_, _c_o_n_s_t _p_l___w_c_h_a_r___t _*_s)
Create atom from wide-character string as PL_new_atom_nchars() does
for ISO-Latin-1 strings. If _s only contains ISO-Latin-1 characters
a normal byte-array atom is created. If _l_e_n is (size_t)-1, it is
computed from _s using wcslen().
pl_wchar_t* PPLL__aattoomm__wwcchhaarrss(_a_t_o_m___t _a_t_o_m_, _i_n_t _*_l_e_n)
Extract characters from a wide-character atom. Succeeds on any
atom marked as `text'. If the underlying atom is a wide-character
atom, the returned pointer is a pointer into the atom structure.
If it is an ISO-Latin-1 character, the returned pointer comes from
Prolog's `buffer ring' (see PL_get_chars()).
int PPLL__ggeett__wwcchhaarrss(_t_e_r_m___t _t_, _s_i_z_e___t _*_l_e_n_, _p_l___w_c_h_a_r___t _*_*_s_, _u_n_s_i_g_n_e_d _f_l_a_g_s)
Wide-character version of PL_get_chars(). The _f_l_a_g_s argument is
the same as for PL_get_chars().
int PPLL__uunniiffyy__wwcchhaarrss(_t_e_r_m___t _t_, _i_n_t _t_y_p_e_, _s_i_z_e___t _l_e_n_, _c_o_n_s_t _p_l___w_c_h_a_r___t _*_s)
Unify _t with a textual representation of the C wide-character array
_s. The _t_y_p_e argument defines the Prolog representation and is one
of PL_ATOM, PL_STRING, PL_CODE_LIST or PL_CHAR_LIST.
int PPLL__uunniiffyy__wwcchhaarrss__ddiiffff(_t_e_r_m___t _+_t_, _t_e_r_m___t _-_t_a_i_l_, _i_n_t _t_y_p_e_, _s_i_z_e___t _l_e_n_, _c_o_n_s_t _p_l___w_c_h_a_r___t _*_s)
Difference list version of PL_unify_wchars(), only supporting the
types PL_CODE_LIST and PL_CHAR_LIST. It serves two purposes. It
allows for returning very long lists from data read from a stream
without the need for a resizing buffer in C. Also, the use of
difference lists is often practical for further processing in
Prolog. Examples can be found in packages/clib/readutil.c from the
source distribution.
99..44..33..55 RReeaaddiinngg aa lliisstt
The functions from this section are intended to read a Prolog list from
C. Suppose we expect a list of atoms; the following code will print the
atoms, each on a line:
________________________________________________________________________| |
|foreign_t |
|pl_write_atoms(term_t l) |
|{ term_t head = PL_new_term_ref(); /* the elements */ |
| term_t list = PL_copy_term_ref(l); /* copy (we modify list) */ |
| |
| while( PL_get_list(list, head, list) ) |
| { char *s; |
| |
| if ( PL_get_atom_chars(head, &s) ) |
| Sprintf("%s\n", s); |
| else |
| PL_fail; |
| } |
| |
| return PL_get_nil(list); /* test end for [] */ |
|}|_____________________________________________________________________ | |
int PPLL__ggeett__lliisstt(_t_e_r_m___t _+_l_, _t_e_r_m___t _-_h_, _t_e_r_m___t _-_t)
If _l is a list and not [] assign a term reference to the head to _h
and to the tail to _t.
int PPLL__ggeett__hheeaadd(_t_e_r_m___t _+_l_, _t_e_r_m___t _-_h)
If _l is a list and not [] assign a term reference to the head to _h.
int PPLL__ggeett__ttaaiill(_t_e_r_m___t _+_l_, _t_e_r_m___t _-_t)
If _l is a list and not [] assign a term reference to the tail to _t.
int PPLL__ggeett__nniill(_t_e_r_m___t _+_l)
Succeeds if _l represents the atom [].
int PPLL__sskkiipp__lliisstt(_t_e_r_m___t _+_l_i_s_t_, _t_e_r_m___t _-_t_a_i_l_, _s_i_z_e___t _*_l_e_n)
This is a multi-purpose function to deal with lists. It allows for
finding the length of a list, checking whether something is a list,
etc. The reference _t_a_i_l is set to point to the end of the list,
_l_e_n is filled with the number of list-cells skipped, and the return
value indicates the status of the list:
PPLL__LLIISSTT
The list is a `proper' list: one that ends in [] and _t_a_i_l is
filled with []
PPLL__PPAARRTTIIAALL__LLIISSTT
The list is a `partial' list: one that ends in a variable and
_t_a_i_l is a reference to this variable.
PPLL__CCYYCCLLIICC__TTEERRMM
The list is cyclic (e.g. X = [a_X]). _t_a_i_l points to an
arbitrary cell of the list and _l_e_n is at most twice the cycle
length of the list.
PPLL__NNOOTT__AA__LLIISSTT
The term _l_i_s_t is not a list at all. _t_a_i_l is bound to
the non-list term and _l_e_n is set to the number of list-cells
skipped.
It is allowed to pass 0 for _t_a_i_l and NULL for _l_e_n.
99..44..33..66 AAnn eexxaammppllee:: ddeeffiinniinngg write/1 iinn CC
Figure 9.2 shows a simplified definition of write/1 to illustrate
the described functions. This simplified version does not deal with
operators. It is called display/1, because it mimics closely the
behaviour of this Edinburgh predicate.
________________________________________________________________________| |
|foreign_t |
|pl_display(term_t t) |
|{ functor_t functor; |
| int arity, len, n; |
| char *s; |
| |
| switch( PL_term_type(t) ) |
| { case PL_VARIABLE: |
| case PL_ATOM: |
| case PL_INTEGER: |
| case PL_FLOAT: |
| PL_get_chars(t, &s, CVT_ALL); |
| Sprintf("%s", s); |
| break; |
| case PL_STRING: |
| PL_get_string_chars(t, &s, &len); |
| Sprintf("\"%s\"", s); |
| break; |
| case PL_TERM: |
| { term_t a = PL_new_term_ref(); |
| |
| PL_get_name_arity(t, &name, &arity); |
| Sprintf("%s(", PL_atom_chars(name)); |
| for(n=1; n<=arity; n++) |
| { PL_get_arg(n, t, a); |
| if ( n > 1 ) |
| Sprintf(", "); |
| pl_display(a); |
| } |
| Sprintf(")"); |
| break; |
| default: |
| PL_fail; /* should not happen */ |
| } |
| } |
| |
| PL_succeed; |
|}|_____________________________________________________________________ | |
Figure 9.2: A Foreign definition of display/1
99..44..44 CCoonnssttrruuccttiinngg TTeerrmmss
Terms can be constructed using functions from the PL_put_*() and
PL_cons_*() families. This approach builds the term `inside-out',
starting at the leaves and subsequently creating compound terms.
Alternatively, terms may be created `top-down', first creating
a compound holding only variables and subsequently unifying the
arguments. This section discusses functions for the first approach.
This approach is generally used for creating arguments for PL_call()
and PL_open_query().
void PPLL__ppuutt__vvaarriiaabbllee(_t_e_r_m___t _-_t)
Put a fresh variable in the term, resetting the term reference to
its initial state.
void PPLL__ppuutt__aattoomm(_t_e_r_m___t _-_t_, _a_t_o_m___t _a)
Put an atom in the term reference from a handle. See also
PL_new_atom() and PL_atom_chars().
void PPLL__ppuutt__bbooooll(_t_e_r_m___t _-_t_, _i_n_t _v_a_l)
Put one of the atoms true or false in the term reference See also
PL_put_atom(), PL_unify_bool()and PL_get_bool().
int PPLL__ppuutt__aattoomm__cchhaarrss(_t_e_r_m___t _-_t_, _c_o_n_s_t _c_h_a_r _*_c_h_a_r_s)
Put an atom in the term reference constructed from the zero-
terminated string. The string itself will never be referenced by
Prolog after this function.
int PPLL__ppuutt__ssttrriinngg__cchhaarrss(_t_e_r_m___t _-_t_, _c_o_n_s_t _c_h_a_r _*_c_h_a_r_s)
Put a zero-terminated string in the term reference. The data will
be copied. See also PL_put_string_nchars().
int PPLL__ppuutt__ssttrriinngg__nncchhaarrss(_t_e_r_m___t _-_t_, _s_i_z_e___t _l_e_n_, _c_o_n_s_t _c_h_a_r _*_c_h_a_r_s)
Put a string, represented by a length/start pointer pair in the
term reference. The data will be copied. This interface can deal
with 0-bytes in the string. See also section 9.4.20.
int PPLL__ppuutt__lliisstt__cchhaarrss(_t_e_r_m___t _-_t_, _c_o_n_s_t _c_h_a_r _*_c_h_a_r_s)
Put a list of ASCII values in the term reference.
int PPLL__ppuutt__iinntteeggeerr(_t_e_r_m___t _-_t_, _l_o_n_g _i)
Put a Prolog integer in the term reference.
int PPLL__ppuutt__iinntt6644(_t_e_r_m___t _-_t_, _i_n_t_6_4___t _i)
Put a Prolog integer in the term reference.
int PPLL__ppuutt__ppooiinntteerr(_t_e_r_m___t _-_t_, _v_o_i_d _*_p_t_r)
Put a Prolog integer in the term reference. Provided _p_t_r is in the
`malloc()-area', PL_get_pointer() will get the pointer back.
int PPLL__ppuutt__ffllooaatt(_t_e_r_m___t _-_t_, _d_o_u_b_l_e _f)
Put a floating-point value in the term reference.
int PPLL__ppuutt__ffuunnccttoorr(_t_e_r_m___t _-_t_, _f_u_n_c_t_o_r___t _f_u_n_c_t_o_r)
Create a new compound term from _f_u_n_c_t_o_r and bind _t to this term.
All arguments of the term will be variables. To create a term with
instantiated arguments, either instantiate the arguments using the
PL_unify_*() functions or use PL_cons_functor().
int PPLL__ppuutt__lliisstt(_t_e_r_m___t _-_l)
Same as PL_put_functor(_l_, _P_L___n_e_w___f_u_n_c_t_o_r_(_P_L___n_e_w___a_t_o_m_(_"_._"), 2)).
int PPLL__ppuutt__nniill(_t_e_r_m___t _-_l)
Same as PL_put_atom_chars(_"_[_]_"). Always returns TRUE.
void PPLL__ppuutt__tteerrmm(_t_e_r_m___t _-_t_1_, _t_e_r_m___t _+_t_2)
Make _t_1 point to the same term as _t_2.
int PPLL__ccoonnss__ffuunnccttoorr(_t_e_r_m___t _-_h_, _f_u_n_c_t_o_r___t _f_, _._._.)
Create a term whose arguments are filled from a variable argument
list holding the same number of term_t objects as the arity of the
functor. To create the term animal(gnu, 50), use:
____________________________________________________________________| |
| { term_t a1 = PL_new_term_ref(); |
| term_t a2 = PL_new_term_ref(); |
| term_t t = PL_new_term_ref(); |
| functor_t animal2; |
| |
| /* animal2 is a constant that may be bound to a global |
| variable and re-used |
| */ |
| animal2 = PL_new_functor(PL_new_atom("animal"), 2); |
| |
| PL_put_atom_chars(a1, "gnu"); |
| PL_put_integer(a2, 50); |
| PL_cons_functor(t, animal2, a1, a2); |
||}_________________________________________________________________ ||
After this sequence, the term references _a_1 and _a_2 may be used for
other purposes.
int PPLL__ccoonnss__ffuunnccttoorr__vv(_t_e_r_m___t _-_h_, _f_u_n_c_t_o_r___t _f_, _t_e_r_m___t _a_0)
Create a compound term like PL_cons_functor(), but _a_0 is an array
of term references as returned by PL_new_term_refs(). The length
of this array should match the number of arguments required by the
functor.
int PPLL__ccoonnss__lliisstt(_t_e_r_m___t _-_l_, _t_e_r_m___t _+_h_, _t_e_r_m___t _+_t)
Create a list (cons-) cell in _l from the head _h and tail _t. The
code below creates a list of atoms from a char **. The list is
built tail-to-head. The PL_unify_*() functions can be used to
build a list head-to-tail.
____________________________________________________________________| |
| void |
| put_list(term_t l, int n, char **words) |
| { term_t a = PL_new_term_ref(); |
| |
| PL_put_nil(l); |
| while( --n >= 0 ) |
| { PL_put_atom_chars(a, words[n]); |
| PL_cons_list(l, a, l); |
| } |
||}_________________________________________________________________ ||
Note that _l can be redefined within a PL_cons_list call as shown
here because operationally its old value is consumed before its new
value is set.
99..44..55 UUnniiffyyiinngg ddaattaa
The functions of this section _u_n_i_f_y terms with other terms or
translated C data structures. Except for PL_unify(), these functions
are specific to SWI-Prolog. They have been introduced because they
shorten the code for returning data to Prolog and at the same time make
this more efficient by avoiding the need to allocate temporary term
references and reduce the number of calls to the Prolog API. Consider
the case where we want a foreign function to return the host name of
the machine Prolog is running on. Using the PL_get_*() and PL_put_*()
functions, the code becomes:
________________________________________________________________________| |
|foreign_t |
|pl_hostname(term_t name) |
|{ char buf[100]; |
| |
| if ( gethostname(buf, sizeof(buf)) ) |
| { term_t tmp = PL_new_term_ref(); |
| |
| PL_put_atom_chars(tmp, buf); |
| return PL_unify(name, tmp); |
| } |
| |
| PL_fail; |
|}|_____________________________________________________________________ | |
Using PL_unify_atom_chars(), this becomes:
________________________________________________________________________| |
|foreign_t |
|pl_hostname(term_t name) |
|{ char buf[100]; |
| |
| if ( gethostname(buf, sizeof(buf)) ) |
| return PL_unify_atom_chars(name, buf); |
| |
| PL_fail; |
|}|_____________________________________________________________________ | |
Note that unification functions that perform multiple bindings may
leave part of the bindings in case of failure. See PL_unify() for
details.
int PPLL__uunniiffyy(_t_e_r_m___t _?_t_1_, _t_e_r_m___t _?_t_2)
Unify two Prolog terms and return TRUE on success.
Care is needed if PL_unify() returns FAIL and the foreign function
does not _i_m_m_e_d_i_a_t_e_l_y return to Prolog with FAIL. Unification may
perform multiple changes to either _t_1 or _t_2. A failing unification
may have created bindings before failure is detected. _A_l_r_e_a_d_y
_c_r_e_a_t_e_d _b_i_n_d_i_n_g_s _a_r_e _n_o_t _u_n_d_o_n_e. For example, calling PL_unify()
on a(_X_, _a) and a(_c_,_b) binds _X to c and fails when trying to unify a
to b. If control remains in C or even if we want to return success
to Prolog, we _m_u_s_t undo such bindings. This is achieved using
PL_open_foreign_frame() and PL_rewind_foreign_frame(), as shown in
the snippet below.
____________________________________________________________________| |
| { fid_t fid = PL_open_foreign_frame(); |
| |
| ... |
| if ( !PL_unify(t1, t2) ) |
| PL_rewind_foreign_frame(fid); |
| ... |
| |
| PL_close_foreign_frame(fid); |
||____}_____________________________________________________________ ||
In addition, PL_unify() may have failed on an eexxcceeppttiioonn,
typically a resource (stack) overflow. This can be tested
using PL_exception(), passing 0 (zero) for the query-id argument.
Foreign functions that encounter an exception must return FAIL to
Prolog as soon as possible or call PL_clear_exception() if they
wish to ignore the exception.
int PPLL__uunniiffyy__aattoomm(_t_e_r_m___t _?_t_, _a_t_o_m___t _a)
Unify _t with the atom _a and return non-zero on success.
int PPLL__uunniiffyy__bbooooll(_t_e_r_m___t _?_t_, _i_n_t _a)
Unify _t with either true or false.
int PPLL__uunniiffyy__cchhaarrss(_t_e_r_m___t _?_t_, _i_n_t _f_l_a_g_s_, _s_i_z_e___t _l_e_n_, _c_o_n_s_t _c_h_a_r _*_c_h_a_r_s)
New function to deal with unification of char* with various
encodings to a Prolog representation. The _f_l_a_g_s argument is a
bitwise _o_r specifying the Prolog target type and the encoding of
_c_h_a_r_s. A Prolog type is one of PL_ATOM, PL_STRING, PL_CODE_LIST or
PL_CHAR_LIST. A representation is one of REP_ISO_LATIN_1, REP_UTF8
or REP_MB. See PL_get_chars() for a definition of the representation
types. If _l_e_n is -1 _c_h_a_r_s must be zero-terminated and the length
is computed from _c_h_a_r_s using strlen().
If _f_l_a_g_s includes PL_DIFF_LIST and type is one of PL_CODE_LIST or
PL_CHAR_LIST, the text is converted to a _d_i_f_f_e_r_e_n_c_e _l_i_s_t. The tail
of the difference list is t +1.
int PPLL__uunniiffyy__aattoomm__cchhaarrss(_t_e_r_m___t _?_t_, _c_o_n_s_t _c_h_a_r _*_c_h_a_r_s)
Unify _t with an atom created from _c_h_a_r_s and return non-zero on
success.
int PPLL__uunniiffyy__lliisstt__cchhaarrss(_t_e_r_m___t _?_t_, _c_o_n_s_t _c_h_a_r _*_c_h_a_r_s)
Unify _t with a list of ASCII characters constructed from _c_h_a_r_s.
void PPLL__uunniiffyy__ssttrriinngg__cchhaarrss(_t_e_r_m___t _?_t_, _c_o_n_s_t _c_h_a_r _*_c_h_a_r_s)
Unify _t with a Prolog string object created from the zero-
terminated string _c_h_a_r_s. The data will be copied. See also
PL_unify_string_nchars().
void PPLL__uunniiffyy__ssttrriinngg__nncchhaarrss(_t_e_r_m___t _?_t_, _s_i_z_e___t _l_e_n_, _c_o_n_s_t _c_h_a_r _*_c_h_a_r_s)
Unify _t with a Prolog string object created from the string created
from the _l_e_n/_c_h_a_r_s pair. The data will be copied. This interface
can deal with 0-bytes in the string. See also section 9.4.20.
int PPLL__uunniiffyy__iinntteeggeerr(_t_e_r_m___t _?_t_, _i_n_t_p_t_r___t _n)
Unify _t with a Prolog integer from _n.
int PPLL__uunniiffyy__iinntt6644(_t_e_r_m___t _?_t_, _i_n_t_6_4___t _n)
Unify _t with a Prolog integer from _n.
int PPLL__uunniiffyy__ffllooaatt(_t_e_r_m___t _?_t_, _d_o_u_b_l_e _f)
Unify _t with a Prolog float from _f.
int PPLL__uunniiffyy__ppooiinntteerr(_t_e_r_m___t _?_t_, _v_o_i_d _*_p_t_r)
Unify _t with a Prolog integer describing the pointer. See also
PL_put_pointer() and PL_get_pointer().
int PPLL__uunniiffyy__ffuunnccttoorr(_t_e_r_m___t _?_t_, _f_u_n_c_t_o_r___t _f)
If _t is a compound term with the given functor, just succeed. If
it is unbound, create a term and bind the variable, else fail.
Note that this function does not create a term if the argument is
already instantiated.
int PPLL__uunniiffyy__lliisstt(_t_e_r_m___t _?_l_, _t_e_r_m___t _-_h_, _t_e_r_m___t _-_t)
Unify _l with a list-cell (./2). If successful, write a reference
to the head of the list into _h and a reference to the tail of the
list into _t. This reference may be used for subsequent calls to
this function. Suppose we want to return a list of atoms from
a char **. We could use the example described by PL_put_list(),
followed by a call to PL_unify(), or we can use the code below. If
the predicate argument is unbound, the difference is minimal (the
code based on PL_put_list() is probably slightly faster). If the
argument is bound, the code below may fail before reaching the end
of the word list, but even if the unification succeeds, this code
avoids a duplicate (garbage) list and a deep unification.
____________________________________________________________________| |
| foreign_t |
| pl_get_environ(term_t env) |
| { term_t l = PL_copy_term_ref(env); |
| term_t a = PL_new_term_ref(); |
| extern char **environ; |
| char **e; |
| |
| for(e = environ; *e; e++) |
| { if ( !PL_unify_list(l, a, l) || |
| !PL_unify_atom_chars(a, *e) ) |
| PL_fail; |
| } |
| |
| return PL_unify_nil(l); |
||}_________________________________________________________________ ||
int PPLL__uunniiffyy__nniill(_t_e_r_m___t _?_l)
Unify _l with the atom [].
int PPLL__uunniiffyy__aarrgg(_i_n_t _i_n_d_e_x_, _t_e_r_m___t _?_t_, _t_e_r_m___t _?_a)
Unifies the _i_n_d_e_x_-_t_h argument (1-based) of _t with _a.
int PPLL__uunniiffyy__tteerrmm(_t_e_r_m___t _?_t_, _._._.)
Unify _t with a (normally) compound term. The remaining arguments
are a sequence of a type identifier followed by the required
arguments. This predicate is an extension to the Quintus
and SICStus foreign interface from which the SWI-Prolog foreign
interface has been derived, but has proved to be a powerful and
comfortable way to create compound terms from C. Due to the vararg
packing/unpacking and the required type-switching this interface is
slightly slower than using the primitives. Please note that some
bad C compilers have fairly low limits on the number of arguments
that may be passed to a function.
Special attention is required when passing numbers. C `promotes'
any integral smaller than int to int. That is, the types char,
short and int are all passed as int. In addition, on most 32-bit
platforms int and long are the same. Up to version 4.0.5, only
PL_INTEGER could be specified, which was taken from the stack
as long. Such code fails when passing small integral types on
machines where int is smaller than long. It is advised to use
PL_SHORT, PL_INT or PL_LONG as appropriate. Similarly, C compilers
promote float to double and therefore PL_FLOAT and PL_DOUBLE are
synonyms.
The type identifiers are:
PL_VARIABLE _n_o_n_e
No op. Used in arguments of PL_FUNCTOR.
PL_BOOL _i_n_t
Unify the argument with true or false.
PL_ATOM _a_t_o_m___t
Unify the argument with an atom, as in PL_unify_atom().
PL_CHARS _c_o_n_s_t _c_h_a_r _*
Unify the argument with an atom constructed from the C char *,
as in PL_unify_atom_chars().
PL_NCHARS _s_i_z_e___t_, _c_o_n_s_t _c_h_a_r _*
Unify the argument with an atom constructed from length and
char* as in PL_unify_atom_nchars().
PL_UTF8_CHARS _c_o_n_s_t _c_h_a_r _*
Create an atom from a UTF-8 string.
PL_UTF8_STRING _c_o_n_s_t _c_h_a_r _*
Create a packed string object from a UTF-8 string.
PL_MBCHARS _c_o_n_s_t _c_h_a_r _*
Create an atom from a multi-byte string in the current locale.
PL_MBCODES _c_o_n_s_t _c_h_a_r _*
Create a list of character codes from a multi-byte string in
the current locale.
PL_MBSTRING _c_o_n_s_t _c_h_a_r _*
Create a packed string object from a multi-byte string in the
current locale.
PL_NWCHARS _s_i_z_e___t_, _c_o_n_s_t _w_c_h_a_r___t _*
Create an atom from a length and a wide character pointer.
PL_NWCODES _s_i_z_e___t_, _c_o_n_s_t _w_c_h_a_r___t _*
Create a list of character codes from a length and a wide
character pointer.
PL_NWSTRING _s_i_z_e___t_, _c_o_n_s_t _w_c_h_a_r___t _*
Create a packed string object from a length and a wide
character pointer.
PL_SHORT _s_h_o_r_t
Unify the argument with an integer, as in PL_unify_integer().
As short is promoted to int, PL_SHORT is a synonym for PL_INT.
PL_INTEGER _l_o_n_g
Unify the argument with an integer, as in PL_unify_integer().
PL_INT _i_n_t
Unify the argument with an integer, as in PL_unify_integer().
PL_LONG _l_o_n_g
Unify the argument with an integer, as in PL_unify_integer().
PL_INT64 _i_n_t_6_4___t
Unify the argument with a 64-bit integer, as in
PL_unify_int64().
PL_INTPTR _i_n_t_p_t_r___t
Unify the argument with an integer with the same width as a
pointer. On most machines this is the same as PL_LONG. but on
64-bit MS-Windows pointers are 64 bits while longs are only 32
bits.
PL_DOUBLE _d_o_u_b_l_e
Unify the argument with a float, as in PL_unify_float().
Note that, as the argument is passed using the C vararg
conventions, a float must be casted to a double explicitly.
PL_FLOAT _d_o_u_b_l_e
Unify the argument with a float, as in PL_unify_float().
PL_POINTER _v_o_i_d _*
Unify the argument with a pointer, as in PL_unify_pointer().
PL_STRING _c_o_n_s_t _c_h_a_r _*
Unify the argument with a string object, as in
PL_unify_string_chars().
PL_TERM _t_e_r_m___t
Unify a subterm. Note this may be the return value of a
PL_new_term_ref()call to get access to a variable.
PL_FUNCTOR _f_u_n_c_t_o_r___t_, _._._.
Unify the argument with a compound term. This specification
should be followed by exactly as many specifications as the
number of arguments of the compound term.
PL_FUNCTOR_CHARS _c_o_n_s_t _c_h_a_r _*_n_a_m_e_, _i_n_t _a_r_i_t_y_, _._._.
Create a functor from the given name and arity and then behave
as PL_FUNCTOR.
PL_LIST _i_n_t _l_e_n_g_t_h_, _._._.
Create a list of the indicated length. The remaining
arguments contain the elements of the list.
For example, to unify an argument with the term language(dutch),
the following skeleton may be used:
____________________________________________________________________| |
| static functor_t FUNCTOR_language1; |
| |
| static void |
| init_constants() |
| { FUNCTOR_language1 = PL_new_functor(PL_new_atom("language"),1); |
| } |
| |
| foreign_t |
| pl_get_lang(term_t r) |
| { return PL_unify_term(r, |
| PL_FUNCTOR, FUNCTOR_language1, |
| PL_CHARS, "dutch"); |
| } |
| |
| install_t |
| install() |
| { PL_register_foreign("get_lang", 1, pl_get_lang, 0); |
| init_constants(); |
||}_________________________________________________________________ ||
int PPLL__cchhaarrss__ttoo__tteerrmm(_c_o_n_s_t _c_h_a_r _*_c_h_a_r_s_, _t_e_r_m___t _-_t)
Parse the string _c_h_a_r_s and put the resulting Prolog term into _t.
_c_h_a_r_s may or may not be closed using a Prolog full-stop (i.e., a
dot followed by a blank). Returns FALSE if a syntax error was
encountered and TRUE after successful completion. In addition to
returning FALSE, the exception-term is returned in _t on a syntax
error. See also term_to_atom/2.
The following example builds a goal term from a string and calls
it.
____________________________________________________________________| |
| int |
| call_chars(const char *goal) |
| { fid_t fid = PL_open_foreign_frame(); |
| term_t g = PL_new_term_ref(); |
| BOOL rval; |
| |
| if ( PL_chars_to_term(goal, g) ) |
| rval = PL_call(goal, NULL); |
| else |
| rval = FALSE; |
| |
| PL_discard_foreign_frame(fid); |
| return rval; |
| } |
| ... |
| call_chars("consult(load)"); |
||__..._____________________________________________________________ ||
int PPLL__wwcchhaarrss__ttoo__tteerrmm(_c_o_n_s_t _p_l___w_c_h_a_r___t _*_c_h_a_r_s_, _t_e_r_m___t _-_t)
Wide character version of PL_chars_to_term().
char * PPLL__qquuoottee(_i_n_t _c_h_r_, _c_o_n_s_t _c_h_a_r _*_s_t_r_i_n_g)
Return a quoted version of _s_t_r_i_n_g. If _c_h_r is '\'', the result is a
quoted atom. If _c_h_r is '"', the result is a string. The result
string is stored in the same ring of buffers as described with the
BUF_RING argument of PL_get_chars();
In the current implementation, the string is surrounded by _c_h_r and
any occurrence of _c_h_r is doubled. In the future the behaviour will
depend on the character_escapes Prolog flag.
99..44..66 CCoonnvveenniieenntt ffuunnccttiioonnss ttoo ggeenneerraattee PPrroolloogg eexxcceeppttiioonnss
The typical implementation of a foreign predicate first uses the
PL_get_*() functions to extract C data types from the Prolog terms.
Failure of any of these functions is normally because the Prolog term
is of the wrong type. The *_ex() family of functions are wrappers
around (mostly) the PL_get_*() functions, such that we can write code
in the style below and get proper exceptions if an argument is
uninstantiated or of the wrong type.
________________________________________________________________________| |
|/** set_size(+Name:atom, +Width:int, +Height:int) is det. |
| |
|static foreign_t |
|set_size(term_t name, term_t width, term_t height) |
|{ char *n; |
| int w, h; |
| |
| if ( !PL_get_chars(name, &n, CVT_ATOM|CVT_EXCEPTION) || |
| !PL_get_integer_ex(with, &w) || |
| !PL_get_integer_ex(height, &h) ) |
| return FALSE; |
| |
| ... |
| |
|}|_____________________________________________________________________ | |
int PPLL__ggeett__aattoomm__eexx(_t_e_r_m___t _t_, _a_t_o_m___t _*_a)
As PL_get_atom(), but raises a type or instantiation error if _t is
not an atom.
int PPLL__ggeett__iinntteeggeerr__eexx(_t_e_r_m___t _t_, _i_n_t _*_i)
As PL_get_integer(), but raises a type or instantiation error if _t
is not an integer, or a representation error if the Prolog integer
does not fit in a C int.
int PPLL__ggeett__lloonngg__eexx(_t_e_r_m___t _t_, _l_o_n_g _*_i)
As PL_get_long(), but raises a type or instantiation error if _t is
not an atom, or a representation error if the Prolog integer does
not fit in a C long.
int PPLL__ggeett__iinntt6644__eexx(_t_e_r_m___t _t_, _i_n_t_6_4___t _*_i)
As PL_get_int64(), but raises a type or instantiation error if _t is
not an atom, or a representation error if the Prolog integer does
not fit in a C int64_t.
int PPLL__ggeett__iinnttppttrr__eexx(_t_e_r_m___t _t_, _i_n_t_p_t_r___t _*_i)
As PL_get_intptr(), but raises a type or instantiation error if _t
is not an atom, or a representation error if the Prolog integer
does not fit in a C intptr_t.
int PPLL__ggeett__ssiizzee__eexx(_t_e_r_m___t _t_, _s_i_z_e___t _*_i)
As PL_get_size(), but raises a type or instantiation error if _t is
not an atom, or a representation error if the Prolog integer does
not fit in a C size_t.
int PPLL__ggeett__bbooooll__eexx(_t_e_r_m___t _t_, _i_n_t _*_i)
As PL_get_bool(), but raises a type or instantiation error if _t is
not an boolean.
int PPLL__ggeett__ffllooaatt__eexx(_t_e_r_m___t _t_, _d_o_u_b_l_e _*_f)
As PL_get_float(), but raises a type or instantiation error if _t is
not a float.
int PPLL__ggeett__cchhaarr__eexx(_t_e_r_m___t _t_, _i_n_t _*_p_, _i_n_t _e_o_f)
Get a character code from _t, where _t is either an integer or an
atom with length one. If _e_o_f is TRUE and _t is -1, _p is filled with
-1. Raises an appropriate error if the conversion is not possible.
int PPLL__ggeett__ppooiinntteerr__eexx(_t_e_r_m___t _t_, _v_o_i_d _*_*_a_d_d_r_p)
As PL_get_pointer(), but raises a type or instantiation error if _t
is not a pointer.
int PPLL__ggeett__lliisstt__eexx(_t_e_r_m___t _l_, _t_e_r_m___t _h_, _t_e_r_m___t _t)
As PL_get_list(), but raises a type or instantiation error if _t is
not a list.
int PPLL__ggeett__nniill__eexx(_t_e_r_m___t _l)
As PL_get_nil(), but raises a type or instantiation error if _t is
not the empty list.
int PPLL__uunniiffyy__lliisstt__eexx(_t_e_r_m___t _l_, _t_e_r_m___t _h_, _t_e_r_m___t _t)
As PL_unify_list(), but raises a type error if _t is not a variable,
list-cell or the empty list.
int PPLL__uunniiffyy__nniill__eexx(_t_e_r_m___t _l)
As PL_unify_nil(), but raises a type error if _t is not a variable,
list-cell or the empty list.
int PPLL__uunniiffyy__bbooooll__eexx(_t_e_r_m___t _t_, _i_n_t _v_a_l)
As PL_unify_bool(), but raises a type error if _t is not a variable
or a boolean.
The second family of functions in this section simplifies the
generation of ISO compatible error terms. Any foreign function that
calls this function must return to Prolog with the return code of
the error function or the constant FALSE. If available, these error
functions add the name of the calling predicate to the error context.
See also PL_raise_exception().
int PPLL__iinnssttaannttiiaattiioonn__eerrrroorr(_t_e_r_m___t _c_u_l_p_r_i_t)
Raise instantiation_error. _C_u_l_p_r_i_t is ignored, but should be bound
to the term that is not a variable. See instantiation_error/1.
int PPLL__uunniinnssttaannttiiaattiioonn__eerrrroorr(_t_e_r_m___t _c_u_l_p_r_i_t)
Raise uninstantiation_error(culprit). This should be called if an
argument that must be unbound at entry is bound to _c_u_l_p_r_i_t.
int PPLL__rreepprreesseennttaattiioonn__eerrrroorr(_c_o_n_s_t _c_h_a_r _*_r_e_s_o_u_r_c_e)
Raise representation_error(resource). See representation_error/1.
int PPLL__ttyyppee__eerrrroorr(_c_o_n_s_t _c_h_a_r _*_e_x_p_e_c_t_e_d_, _t_e_r_m___t _c_u_l_p_r_i_t)
Raise type_error(expected, culprit). See type_error/2.
int PPLL__ddoommaaiinn__eerrrroorr(_c_o_n_s_t _c_h_a_r _*_e_x_p_e_c_t_e_d_, _t_e_r_m___t _c_u_l_p_r_i_t)
Raise domain_error(expected, culprit). See domain_error/2.
int PPLL__eexxiisstteennccee__eerrrroorr(_c_o_n_s_t _c_h_a_r _*_t_y_p_e_, _t_e_r_m___t _c_u_l_p_r_i_t)
Raise existence_error(type, culprit). See type_error/2.
int PPLL__ppeerrmmiissssiioonn__eerrrroorr(_c_o_n_s_t _c_h_a_r _*_o_p_e_r_a_t_i_o_n_, _c_o_n_s_t _c_h_a_r _*_t_y_p_e_, _t_e_r_m___t _c_u_l_p_r_i_t)
Raise permission_error(operation, type, culprit). See
permission_error/3.
int PPLL__rreessoouurrccee__eerrrroorr(_c_o_n_s_t _c_h_a_r _*_r_e_s_o_u_r_c_e)
Raise resource_error(resource). See resource_error/1.
99..44..77 BBLLOOBBSS:: UUssiinngg aattoommss ttoo ssttoorree aarrbbiittrraarryy bbiinnaarryy ddaattaa
SWI-Prolog atoms as well as strings can represent arbitrary binary data
of arbitrary length. This facility is attractive for storing foreign
data such as images in an atom. An atom is a unique handle to this
data and the atom garbage collector is able to destroy atoms that are
no longer referenced by the Prolog engine. This property of atoms
makes them attractive as a handle to foreign resources, such as Java
atoms, Microsoft's COM objects, etc., providing safe combined garbage
collection.
To exploit these features safely and in an organised manner,
the SWI-Prolog foreign interface allows for creating `atoms' with
additional type information. The type is represented by a structure
holding C function pointers that tell Prolog how to handle releasing
the atom, writing it, sorting it, etc. Two atoms created with
different types can represent the same sequence of bytes. Atoms are
first ordered on the rank number of the type and then on the result of
the compare() function. Rank numbers are assigned when the type is
registered.
99..44..77..11 DDeeffiinniinngg aa BBLLOOBB ttyyppee
The type PL_blob_t represents a structure with the layout displayed
below. The structure contains additional fields at the ...for internal
bookkeeping as well as future extensions.
________________________________________________________________________| |
|typedef struct PL_blob_t |
|{ uintptr_t magic; /* PL_BLOB_MAGIC */ |
| uintptr_t flags; /* Bitwise or of PL_BLOB_* */ |
| char * name; /* name of the type */ |
| int (*release)(atom_t a); |
| int (*compare)(atom_t a, atom_t b); |
| int (*write)(IOSTREAM *s, atom_t a, int flags); |
| void (*acquire)(atom_t a); |
| ... |
|}|PL_blob_t;___________________________________________________________ | |
For each type, exactly one such structure should be allocated. Its
first field must be initialised to PL_BLOB_MAGIC. The _f_l_a_g_s is a bitwise
_o_r of the following constants:
PPLL__BBLLOOBB__TTEEXXTT
If specified the blob is assumed to contain text and is considered
a normal Prolog atom.
PPLL__BBLLOOBB__UUNNIIQQUUEE
If specified the system ensures that the blob-handle is a unique
reference for a blob with the given type, length and content. If
this flag is not specified, each lookup creates a new blob.
PPLL__BBLLOOBB__NNOOCCOOPPYY
By default the content of the blob is copied. Using this flag
the blob references the external data directly. The user must
ensure the provided pointer is valid as long as the atom lives.
If PL_BLOB_UNIQUE is also specified, uniqueness is determined by
comparing the pointer rather than the data pointed at.
The _n_a_m_e field represents the type name as available to Prolog. See
also current_blob/2. The other fields are function pointers that must
be initialised to proper functions or NULL to get the default behaviour
of built-in atoms. Below are the defined member functions:
void aaccqquuiirree(_a_t_o_m___t _a)
Called if a new blob of this type is created through PL_put_blob()
or PL_unify_blob(). This callback may be used together with the
release hook to deal with reference-counted external objects.
int rreelleeaassee(_a_t_o_m___t _a)
The blob (atom) _a is about to be released. This function can
retrieve the data of the blob using PL_blob_data(). If it returns
FALSE the atom garbage collector will _n_o_t reclaim the atom.
int ccoommppaarree(_a_t_o_m___t _a_, _a_t_o_m___t _b)
Compare the blobs _a and _b, both of which are of the type associated
to this blob type. Return values are, as memcmp(), < 0 if _a is
less than _b, = 0 if both are equal, and >0 otherwise.
int wwrriittee(_I_O_S_T_R_E_A_M _*_s_, _a_t_o_m___t _a_, _i_n_t _f_l_a_g_s)
Write the content of the blob _a to the stream _s respecting the
_f_l_a_g_s. The _f_l_a_g_s are a bitwise _o_r _o_f _z_e_r_o _o_r _m_o_r_e _o_f _t_h_e PL_WRT_*
_f_l_a_g_s _d_e_f_i_n_e_d _i_n SWI-Prolog.h_. _T_h_i_s _p_r_o_t_o_t_y_p_e _i_s _a_v_a_i_l_a_b_l_e _i_f _t_h_e
_u_n_d_o_c_u_m_e_n_t_e_d SWI-Stream.h _i_s _i_n_c_l_u_d_e_d _b_e_f_o_r_e SWI-Prolog.h_.
_I_f _t_h_i_s _f_u_n_c_t_i_o_n _i_s _n_o_t _p_r_o_v_i_d_e_d_, write/1 _e_m_i_t_s _t_h_e _c_o_n_t_e_n_t _o_f _t_h_e
_b_l_o_b _f_o_r _b_l_o_b_s _o_f _t_y_p_e PL_BLOB_TEXT _o_r _a _s_t_r_i_n_g _o_f _t_h_e _f_o_r_m_a_t <#_h_e_x
_d_a_t_a> _f_o_r _b_i_n_a_r_y _b_l_o_b_s_.
If a blob type is registered from a loadable object (shared object
or DLL) the blob type must be deregistered before the object may be
released.
int PPLL__uunnrreeggiisstteerr__bblloobb__ttyyppee(_P_L___b_l_o_b___t _*_t_y_p_e)
Unlink the blob type from the registered type and transform the
type of possible living blobs to unregistered, avoiding further
reference to the type structure, functions referred by it, as well
as the data. This function returns TRUE if no blobs of this type
existed and FALSE otherwise. PL_unregister_blob_type() is intended
for the uninstall() hook of foreign modules, avoiding further
references to the module.
99..44..77..22 AAcccceessssiinngg bblloobbss
The blob access functions are similar to the atom accessing functions.
Blobs being atoms, the atom functions operate on blobs and vice versa.
For clarity and possible future compatibility issues, however, it is
not advised to rely on this.
int PPLL__iiss__bblloobb(_t_e_r_m___t _t_, _P_L___b_l_o_b___t _*_*_t_y_p_e)
Succeeds if _t refers to a blob, in which case _t_y_p_e is filled with
the type of the blob.
int PPLL__uunniiffyy__bblloobb(_t_e_r_m___t _t_, _v_o_i_d _*_b_l_o_b_, _s_i_z_e___t _l_e_n_, _P_L___b_l_o_b___t _*_t_y_p_e)
Unify _t to a new blob constructed from the given data and
associated to the given type. See also PL_unify_atom_nchars().
int PPLL__ppuutt__bblloobb(_t_e_r_m___t _t_, _v_o_i_d _*_b_l_o_b_, _s_i_z_e___t _l_e_n_, _P_L___b_l_o_b___t _*_t_y_p_e)
Store the described blob in _t. The return value indicates whether
a new blob was allocated (FALSE) or the blob is a reference to
an existing blob (TRUE). Reporting new/existing can be used to
deal with external objects having their own reference counts. If
the return is TRUE this reference count must be incremented, and
it must be decremented on blob destruction callback. See also
PL_put_atom_nchars().
int PPLL__ggeett__bblloobb(_t_e_r_m___t _t_, _v_o_i_d _*_*_b_l_o_b_, _s_i_z_e___t _*_l_e_n_, _P_L___b_l_o_b___t _*_*_t_y_p_e)
If _t holds a blob or atom, get the data and type and return TRUE.
Otherwise return FALSE. Each result pointer may be NULL, in which
case the requested information is ignored.
void * PPLL__bblloobb__ddaattaa(_a_t_o_m___t _a_, _s_i_z_e___t _*_l_e_n_, _P_L___b_l_o_b___t _*_*_t_y_p_e)
Get the data and type associated to a blob. This function
is mainly used from the callback functions described in
section 9.4.7.1.
99..44..88 EExxcchhaannggiinngg GGMMPP nnuummbbeerrss
If SWI-Prolog is linked with the GNU Multiple Precision Arithmetic
Library (GMP, used by default), the foreign interface provides
functions for exchanging numeric values to GMP types. To
access these functions the header <gmp.h> must be included _b_e_f_o_r_e
<SWI-Prolog.h>. Foreign code using GMP linked to SWI-Prolog asks for
some considerations.
o SWI-Prolog normally rebinds the GMP allocation functions us-
ing mp_set_memory_functions(). This means SWI-Prolog must be
initialised before the foreign code touches any GMP function.
You can call \cfuncref{PL_action}{PL_GMP_SET_ALLOC_FUNCTIONS, TRUE}
to force Prolog's GMP initialization without doing the
rest of the Prolog initialization. If you do
not want Prolog rebinding the GMP allocation, call
\cfuncref{PL_action}{PL_GMP_SET_ALLOC_FUNCTIONS, FALSE} _b_e_f_o_r_e ini-
tializing Prolog.
o On Windows, each DLL has its own memory pool. To make exchange
of GMP numbers between Prolog and foreign code possible you must
either let Prolog rebind the allocation functions (default) or you
must recompile SWI-Prolog to link to a DLL version of the GMP
library.
Here is an example exploiting the function mpz_nextprime():
________________________________________________________________________| |
|#include <gmp.h> |
|#include <SWI-Prolog.h> |
| |
|static foreign_t |
|next_prime(term_t n, term_t prime) |
|{ mpz_t mpz; |
| int rc; |
| |
| mpz_init(mpz); |
| if ( PL_get_mpz(n, mpz) ) |
| { mpz_nextprime(mpz, mpz); |
| |
| rc = PL_unify_mpz(prime, mpz); |
| } else |
| rc = FALSE; |
| |
| mpz_clear(mpz); |
| return rc; |
|} |
| |
|install_t |
|install() |
|{ PL_register_foreign("next_prime", 2, next_prime, 0); |
|}|_____________________________________________________________________ | |
int PPLL__ggeett__mmppzz(_t_e_r_m___t _t_, _m_p_z___t _m_p_z)
If _t represents an integer, _m_p_z is filled with the value and the
function returns TRUE. Otherwise _m_p_z is untouched and the function
returns FALSE. Note that _m_p_z must have been initialised before
calling this function and must be cleared using mpz_clear() to
reclaim any storage associated with it.
int PPLL__ggeett__mmppqq(_t_e_r_m___t _t_, _m_p_q___t _m_p_q)
If _t is an integer or rational number (term rdiv/2), _m_p_q is filled
with the _n_o_r_m_a_l_i_s_e_d rational number and the function returns TRUE.
Otherwise _m_p_q is untouched and the function returns FALSE. Note
that _m_p_q must have been initialised before calling this function
and must be cleared using mpq_clear() to reclaim any storage
associated with it.
int PPLL__uunniiffyy__mmppzz(_t_e_r_m___t _t_, _m_p_z___t _m_p_z)
Unify _t with the integer value represented by _m_p_z and return TRUE
on success. The _m_p_z argument is not changed.
int PPLL__uunniiffyy__mmppqq(_t_e_r_m___t _t_, _m_p_q___t _m_p_q)
Unify _t with a rational number represented by _m_p_q and return TRUE
on success. Note that _t is unified with an integer if the
denominator is 1. The _m_p_q argument is not changed.
99..44..99 CCaalllliinngg PPrroolloogg ffrroomm CC
The Prolog engine can be called from C. There are two interfaces
for this. For the first, a term is created that could be used as
an argument to call/1, and then PL_call() is used to call Prolog.
This system is simple, but does not allow to inspect the different
answers to a non-deterministic goal and is relatively slow as the
runtime system needs to find the predicate. The other interface
is based on PL_open_query(), PL_next_solution() and PL_cut_query() or
PL_close_query(). This mechanism is more powerful, but also more
complicated to use.
99..44..99..11 PPrreeddiiccaattee rreeffeerreenncceess
This section discusses the functions used to communicate about
predicates. Though a Prolog predicate may be defined or not,
redefined, etc., a Prolog predicate has a handle that is neither
destroyed nor moved. This handle is known by the type predicate_t.
predicate_t PPLL__pprreedd(_f_u_n_c_t_o_r___t _f_, _m_o_d_u_l_e___t _m)
Return a handle to a predicate for the specified name/arity in the
given module. This function always succeeds, creating a handle for
an undefined predicate if no handle was available. If the module
argument _m is NULL, the current context module is used.
predicate_t PPLL__pprreeddiiccaattee(_c_o_n_s_t _c_h_a_r _*_n_a_m_e_, _i_n_t _a_r_i_t_y_, _c_o_n_s_t _c_h_a_r_* _m_o_d_u_l_e)
Same as PL_pred(), but provides a more convenient interface to the
C programmer.
void PPLL__pprreeddiiccaattee__iinnffoo(_p_r_e_d_i_c_a_t_e___t _p_, _a_t_o_m___t _*_n_, _i_n_t _*_a_, _m_o_d_u_l_e___t _*_m)
Return information on the predicate _p. The name is stored over
_n, the arity over _a, while _m receives the definition module.
Note that the latter need not be the same as specified with
PL_predicate(). If the predicate is imported into the module given
to PL_predicate(), this function will return the module where the
predicate is defined. Any of the arguments _n, _a and _m can be NULL.
99..44..99..22 IInniittiiaattiinngg aa qquueerryy ffrroomm CC
This section discusses the functions for creating and manipulating
queries from C. Note that a foreign context can have at most one active
query. This implies that it is allowed to make strictly nested calls
between C and Prolog (Prolog calls C, calls Prolog, calls C, etc.),
but it is nnoott allowed to open multiple queries and start generating
solutions for each of them by calling PL_next_solution(). Be sure to
call PL_cut_query() or PL_close_query() on any query you opened before
opening the next or returning control back to Prolog.
qid_t PPLL__ooppeenn__qquueerryy(_m_o_d_u_l_e___t _c_t_x_, _i_n_t _f_l_a_g_s_, _p_r_e_d_i_c_a_t_e___t _p_, _t_e_r_m___t _+_t_0)
Opens a query and returns an identifier for it. _c_t_x is the
_c_o_n_t_e_x_t _m_o_d_u_l_e of the goal. When NULL, the context module
of the calling context will be used, or user if there is no
calling context (as may happen in embedded systems). Note
that the context module only matters for _m_e_t_a_-_p_r_e_d_i_c_a_t_e_s. See
meta_predicate/1, context_module/1 and module_transparent/1. The _p
argument specifies the predicate, and should be the result of a
call to PL_pred() or PL_predicate(). Note that it is allowed to
store this handle as global data and reuse it for future queries.
The term reference _t_0 is the first of a vector of term references
as returned by PL_new_term_refs(_n).
The _f_l_a_g_s arguments provides some additional options concerning
debugging and exception handling. It is a bitwise _o_r of the
following values:
PL_Q_NORMAL
Normal operation. The debugger inherits its settings from the
environment. If an exception occurs that is not handled in
Prolog, a message is printed and the tracer is started to
debug the error.
PL_Q_NODEBUG
Switch off the debugger while executing the goal. This option
is used by many calls to hook-predicates to avoid tracing the
hooks. An example is print/1 calling portray/1 from foreign
code.
PL_Q_CATCH_EXCEPTION
If an exception is raised while executing the goal, do not
report it, but make it available for PL_exception().
PL_Q_PASS_EXCEPTION
As PL_Q_CATCH_EXCEPTION, but do not invalidate the exception-
term while calling PL_close_query(). This option is
experimental.
PL_open_query() can return the query identifier `0' if there is not
enough space on the environment stack. This function succeeds,
even if the referenced predicate is not defined. In this
case, running the query using PL_next_solution() will return an
existence_error. See PL_exception().
The example below opens a query to the predicate is_a/2 to find the
ancestor of `me'. The reference to the predicate is valid for the
duration of the process and may be cached by the client.
____________________________________________________________________| |
| char * |
| ancestor(const char *me) |
| { term_t a0 = PL_new_term_refs(2); |
| static predicate_t p; |
| |
| if ( !p ) |
| p = PL_predicate("is_a", 2, "database"); |
| |
| PL_put_atom_chars(a0, me); |
| PL_open_query(NULL, PL_Q_NORMAL, p, a0); |
| ... |
||}_________________________________________________________________ ||
int PPLL__nneexxtt__ssoolluuttiioonn(_q_i_d___t _q_i_d)
Generate the first (next) solution for the given query. The return
value is TRUE if a solution was found, or FALSE to indicate the
query could not be proven. This function may be called repeatedly
until it fails to generate all solutions to the query.
void PPLL__ccuutt__qquueerryy(_q_i_d___t _q_i_d)
Discards the query, but does not delete any of the data created by
the query. It just invalidates _q_i_d, allowing for a new call to
PL_open_query() in this context.
void PPLL__cclloossee__qquueerryy(_q_i_d___t _q_i_d)
As PL_cut_query(), but all data and bindings created by the query
are destroyed.
int PPLL__ccaallll__pprreeddiiccaattee(_m_o_d_u_l_e___t _m_, _i_n_t _f_l_a_g_s_, _p_r_e_d_i_c_a_t_e___t _p_r_e_d_, _t_e_r_m___t _+_t_0)
Shorthand for PL_open_query(), PL_next_solution(), PL_cut_query(),
generating a single solution. The arguments are the same as for
PL_open_query(), the return value is the same as PL_next_solution().
int PPLL__ccaallll(_t_e_r_m___t _t_, _m_o_d_u_l_e___t _m)
Call term _t just like the Prolog predicate once/1. _t is called in
the module _m, or in the context module if _m == NULL. Returns TRUE
if the call succeeds, FALSE otherwise. Figure 9.3 shows an example
to obtain the number of defined atoms. All checks are omitted to
improve readability.
99..44..1100 DDiissccaarrddiinngg DDaattaa
The Prolog data created and term references needed to set up the call
and/or analyse the result can in most cases be discarded right after
the call. PL_close_query() allows for destroying the data, while
leaving the term references. The calls below may be used to destroy
term references and data. See figure 9.3 for an example.
fid_t PPLL__ooppeenn__ffoorreeiiggnn__ffrraammee()
Create a foreign frame, holding a mark that allows the system
to undo bindings and destroy data created after it, as well as
providing the environment for creating term references. This
function is called by the kernel before calling a foreign
predicate.
void PPLL__cclloossee__ffoorreeiiggnn__ffrraammee(_f_i_d___t _i_d)
Discard all term references created after the frame was opened.
All other Prolog data is retained. This function is called by the
kernel whenever a foreign function returns control back to Prolog.
void PPLL__ddiissccaarrdd__ffoorreeiiggnn__ffrraammee(_f_i_d___t _i_d)
Same as PL_close_foreign_frame(), but also undo all bindings made
since the open and destroy all Prolog data.
void PPLL__rreewwiinndd__ffoorreeiiggnn__ffrraammee(_f_i_d___t _i_d)
Undo all bindings and discard all term references created since the
frame was created, but do not pop the frame. That is, the same
frame can be rewound multiple times, and must eventually be closed
or discarded.
It is obligatory to call either of the two closing functions to discard
a foreign frame. Foreign frames may be nested.
________________________________________________________________________| |
|int |
|count_atoms() |
|{ fid_t fid = PL_open_foreign_frame(); |
| term_t goal = PL_new_term_ref(); |
| term_t a1 = PL_new_term_ref(); |
| term_t a2 = PL_new_term_ref(); |
| functor_t s2 = PL_new_functor(PL_new_atom("statistics"), 2); |
| int atoms; |
| |
| PL_put_atom_chars(a1, "atoms"); |
| PL_cons_functor(goal, s2, a1, a2); |
| PL_call(goal, NULL); /* call it in current module */ |
| |
| PL_get_integer(a2, &atoms); |
| PL_discard_foreign_frame(fid); |
| |
| return atoms; |
|}|_____________________________________________________________________ | |
Figure 9.3: Calling Prolog
99..44..1111 FFoorreeiiggnn CCooddee aanndd MMoodduulleess
Modules are identified via a unique handle. The following functions
are available to query and manipulate modules.
module_t PPLL__ccoonntteexxtt()
Return the module identifier of the context module of the currently
active foreign predicate.
int PPLL__ssttrriipp__mmoodduullee(_t_e_r_m___t _+_r_a_w_, _m_o_d_u_l_e___t _*_m_, _t_e_r_m___t _-_p_l_a_i_n)
Utility function. If _r_a_w is a term, possibly holding the module
construct <_m_o_d_u_l_e>:<_r_e_s_t>, this function will make _p_l_a_i_n a reference
to <_r_e_s_t> and fill _m_o_d_u_l_e _* with <_m_o_d_u_l_e>. For further nested
module constructs the innermost module is returned via _m_o_d_u_l_e _*.
If _r_a_w is not a module construct, _r_a_w will simply be put in _p_l_a_i_n.
The value pointed to by _m must be initialized before calling
PL_strip_module(), either to the default module or to NULL. A NULL
value is replaced by the current context module if _r_a_w carries no
module. The following example shows how to obtain the plain term
and module if the default module is the user module:
____________________________________________________________________| |
| { module m = PL_new_module(PL_new_atom("user")); |
| term_t plain = PL_new_term_ref(); |
| |
| PL_strip_module(term, &m, plain); |
| ... |
||}_________________________________________________________________ ||
atom_t PPLL__mmoodduullee__nnaammee(_m_o_d_u_l_e___t _m_o_d_u_l_e)
Return the name of _m_o_d_u_l_e as an atom.
module_t PPLL__nneeww__mmoodduullee(_a_t_o_m___t _n_a_m_e)
Find an existing module or create a new module with the name _n_a_m_e.
99..44..1122 PPrroolloogg eexxcceeppttiioonnss iinn ffoorreeiiggnn ccooddee
This section discusses PL_exception(), PL_throw() and
PL_raise_exception(), the interface functions to detect and generate
Prolog exceptions from C code. PL_throw() and PL_raise_exception() from
the C interface raise an exception from foreign code. PL_throw()
exploits the C function longjmp() to return immediately to the
innermost PL_next_solution(). PL_raise_exception() registers the
exception term and returns FALSE. If a foreign predicate returns FALSE,
while an exception term is registered, a Prolog exception will be
raised by the virtual machine.
Calling these functions outside the context of a function implementing
a foreign predicate results in undefined behaviour.
PL_exception() may be used after a call to PL_next_solution() fails,
and returns a term reference to an exception term if an exception was
raised, and 0 otherwise.
If a C function implementing a predicate calls Prolog and detects
an exception using PL_exception(), it can handle this exception or
return with the exception. Some caution is required though. It
is nnoott allowed to call PL_close_query() or PL_discard_foreign_frame()
afterwards, as this will invalidate the exception term. Below
is the code that calls a Prolog-defined arithmetic function (see
arithmetic_function/1).
If PL_next_solution() succeeds, the result is analysed and translated
to a number, after which the query is closed and all Prolog data
created after PL_open_foreign_frame() is destroyed. On the other
hand, if PL_next_solution() fails and if an exception was raised,
just pass it. Otherwise generate an exception (PL_error() is an
internal call for building the standard error terms and calling
PL_raise_exception()). After this, the Prolog environment should be
discarded using PL_cut_query() and PL_close_foreign_frame() to avoid
invalidating the exception term.
________________________________________________________________________| |
|static int |
|prologFunction(ArithFunction f, term_t av, Number r) |
|{ int arity = f->proc->definition->functor->arity; |
| fid_t fid = PL_open_foreign_frame(); |
| qid_t qid; |
| int rval; |
| |
| qid = PL_open_query(NULL, PL_Q_NORMAL, f->proc, av); |
| |
| if ( PL_next_solution(qid) ) |
| { rval = valueExpression(av+arity-1, r); |
| PL_close_query(qid); |
| PL_discard_foreign_frame(fid); |
| } else |
| { term_t except; |
| |
| if ( (except = PL_exception(qid)) ) |
| { rval = PL_throw(except); /* pass exception */ |
| } else |
| { char *name = stringAtom(f->proc->definition->functor->name); |
| |
| /* generate exception */ |
| rval = PL_error(name, arity-1, NULL, ERR_FAILED, f->proc); |
| } |
| |
| PL_cut_query(qid); /* donot destroy data */ |
| PL_close_foreign_frame(fid); /* same */ |
| } |
| |
| return rval; |
|}|_____________________________________________________________________ | |
int PPLL__rraaiissee__eexxcceeppttiioonn(_t_e_r_m___t _e_x_c_e_p_t_i_o_n)
Generate an exception (as throw/1) and return FALSE. Below is an
example returning an exception from a foreign predicate:
____________________________________________________________________| |
| foreign_t |
| pl_hello(term_t to) |
| { char *s; |
| |
| if ( PL_get_atom_chars(to, &s) ) |
| { Sprintf("Hello \"%s\"\n", s); |
| |
| PL_succeed; |
| } else |
| { term_t except = PL_new_term_ref(); |
| |
| PL_unify_term(except, |
| PL_FUNCTOR_CHARS, "type_error", 2, |
| PL_CHARS, "atom", |
| PL_TERM, to); |
| |
| return PL_raise_exception(except); |
| } |
||}_________________________________________________________________ ||
int PPLL__tthhrrooww(_t_e_r_m___t _e_x_c_e_p_t_i_o_n)
Similar to PL_raise_exception(), but returns using the C longjmp()
function to the innermost PL_next_solution().
term_t PPLL__eexxcceeppttiioonn(_q_i_d___t _q_i_d)
If PL_next_solution() fails, this can be due to normal failure
of the Prolog call, or because an exception was raised using
throw/1. This function returns a handle to the exception term if
an exception was raised, or 0 if the Prolog goal simply failed. If
there is an exception, PL_exception()allocates a term-handle using
PL_new_term_ref() that is used to return the exception term.
Additionally, \cfuncref{PL_exception}{0} returns the pending
exception in the current query or 0 if no exception is pending.
This can be used to check the error status after a failing call to,
e.g., one of the unification functions.
void PPLL__cclleeaarr__eexxcceeppttiioonn(_v_o_i_d)
Tells Prolog that the encountered exception must be ignored. This
function must be called if control remains in C after a previous
API call fails with an exception.
99..44..1133 CCaattcchhiinngg SSiiggnnaallss ((SSooffttwwaarree IInntteerrrruuppttss))
SWI-Prolog offers both a C and Prolog interface to deal with software
interrupts (signals). The Prolog mapping is defined in section 4.11.
This subsection deals with handling signals from C.
If a signal is not used by Prolog and the handler does not call Prolog
in any way, the native signal interface routines may be used.
Some versions of SWI-Prolog, notably running on popular Unix platforms,
handle SIG_SEGV for guarding the Prolog stacks. If the application
wishes to handle this signal too, it should use PL_signal() to install
its handler after initialising Prolog. SWI-Prolog will pass SIG_SEGV
to the user code if it detected the signal is not related to a Prolog
stack overflow.
Any handler that wishes to call one of the Prolog interface functions
should call PL_signal() for its installation.
void (*)() PPLL__ssiiggnnaall(_s_i_g_, _f_u_n_c)
This function is equivalent to the BSD-Unix signal() function,
regardless of the platform used. The signal handler is blocked
while the signal routine is active, and automatically reactivated
after the handler returns.
After a signal handler is registered using this function, the
native signal interface redirects the signal to a generic signal
handler inside SWI-Prolog. This generic handler validates the
environment, creates a suitable environment for calling the
interface functions described in this chapter and finally calls the
registered user-handler.
By default, signals are handled asynchronously (i.e., at the time
they arrive). It is inherently dangerous to call extensive code
fragments, and especially exception related code from asynchronous
handlers. The interface allows for _s_y_n_c_h_r_o_n_o_u_s handling of
signals. In this case the native OS handler just schedules the
signal using PL_raise(), which is checked by PL_handle_signals() at
the call- and redo-port. This behaviour is realised by _o_r-ing _s_i_g
with the constant PL_SIGSYNC.
Signal handling routines may raise exceptions using
PL_raise_exception(). The use of PL_throw() is not safe.
If a synchronous handler raises an exception, the exception is
delayed to the next call to PL_handle_signals();
int PPLL__rraaiissee(_i_n_t _s_i_g)
Register _s_i_g for _s_y_n_c_h_r_o_n_o_u_s handling by Prolog. Synchronous
signals are handled at the call-port or if foreign code calls
PL_handle_signals(). See also thread_signal/2.
int PPLL__hhaannddllee__ssiiggnnaallss(_v_o_i_d)
Handle any signals pending from PL_raise(). PL_handle_signals()
is called at each pass through the call- and redo-port at a safe
point. Exceptions raised by the handler using PL_raise_exception()
are properly passed to the environment.
The user may call this function inside long-running foreign
functions to handle scheduled interrupts. This routine returns the
number of signals handled. If a handler raises an exception, the
return value is -1 and the calling routine should return with FALSE
as soon as possible.
int PPLL__ggeett__ssiiggnnuumm__eexx(_t_e_r_m___t _t_, _i_n_t _*_s_i_g)
Extract a signal specification from a Prolog term and store as an
integer signal number in _s_i_g. The specification is an integer, a
lowercase signal name without SIG or the full signal name. These
refer to the same: 9, kill and SIGKILL. Leaves a typed, domain or
instantiation error if the conversion fails.
99..44..1144 MMiisscceellllaanneeoouuss
99..44..1144..11 TTeerrmm CCoommppaarriissoonn
int PPLL__ccoommppaarree(_t_e_r_m___t _t_1_, _t_e_r_m___t _t_2)
Compares two terms using the standard order of terms and returns
-1, 0 or 1. See also compare/3.
int PPLL__ssaammee__ccoommppoouunndd(_t_e_r_m___t _t_1_, _t_e_r_m___t _t_2)
Yields TRUE if _t_1 and _t_2 refer to physically the same compound term
and FALSE otherwise.
99..44..1144..22 RReeccoorrddeedd ddaattaabbaassee
In some applications it is useful to store and retrieve Prolog terms
from C code. For example, the XPCE graphical environment does this for
storing arbitrary Prolog data as slot-data of XPCE objects.
Please note that the returned handles have no meaning at the Prolog
level and the recorded terms are not visible from Prolog. The
functions PL_recorded() and PL_erase() are the only functions that can
operate on the stored term.
Two groups of functions are provided. The first group (PL_record() and
friends) store Prolog terms on the Prolog heap for retrieval during the
same session. These functions are also used by recorda/3 and friends.
The recorded database may be used to communicate Prolog terms between
threads.
record_t PPLL__rreeccoorrdd(_t_e_r_m___t _+_t)
Record the term _t into the Prolog database as recorda/3 and return
an opaque handle to the term. The returned handle remains valid
until PL_erase() is called on it. PL_recorded() is used to copy
recorded terms back to the Prolog stack.
int PPLL__rreeccoorrddeedd(_r_e_c_o_r_d___t _r_e_c_o_r_d_, _t_e_r_m___t _-_t)
Copy a recorded term back to the Prolog stack. The same record may
be used to copy multiple instances at any time to the Prolog stack.
Returns TRUE on success, and FALSE if there is not enough space
on the stack to accommodate the term. See also PL_record() and
PL_erase().
void PPLL__eerraassee(_r_e_c_o_r_d___t _r_e_c_o_r_d)
Remove the recorded term from the Prolog database, reclaiming all
associated memory resources.
The second group (headed by PL_record_external()) provides the same
functionality, but the returned data has properties that enable storing
the data on an external device. It has been designed to make
it possible to store Prolog terms fast and compact in an external
database. Here are the main features:
o _I_n_d_e_p_e_n_d_e_n_t _o_f _s_e_s_s_i_o_n
Records can be communicated to another Prolog session and made
visible using PL_recorded_external().
o _B_i_n_a_r_y
The representation is binary for maximum performance. The returned
data may contain zero bytes.
o _B_y_t_e_-_o_r_d_e_r _i_n_d_e_p_e_n_d_e_n_t
The representation can be transferred between machines with
different byte order.
o _N_o _a_l_i_g_n_m_e_n_t _r_e_s_t_r_i_c_t_i_o_n_s
There are no memory alignment restrictions and copies of the record
can thus be moved freely. For example, it is possible to use
this representation to exchange terms using shared memory between
different Prolog processes.
o _C_o_m_p_a_c_t
It is assumed that a smaller memory footprint will eventually
outperform slightly faster representations.
o _S_t_a_b_l_e
The format is designed for future enhancements without breaking
compatibility with older records.
char * PPLL__rreeccoorrdd__eexxtteerrnnaall(_t_e_r_m___t _+_t_, _s_i_z_e___t _*_l_e_n)
Record the term _t into the Prolog database as recorda/3 and return
an opaque handle to the term. The returned handle remains valid
until PL_erase_external() is called on it.
It is allowed to copy the data and use PL_recorded_external() on
the copy. The user is responsible for the memory management of
the copy. After copying, the original may be discarded using
PL_erase_external().
PL_recorded_external() is used to copy such recorded terms back to
the Prolog stack.
int PPLL__rreeccoorrddeedd__eexxtteerrnnaall(_c_o_n_s_t _c_h_a_r _*_r_e_c_o_r_d_, _t_e_r_m___t _-_t)
Copy a recorded term back to the Prolog stack. The same record may
be used to copy multiple instances at any time to the Prolog stack.
See also PL_record_external() and PL_erase_external().
int PPLL__eerraassee__eexxtteerrnnaall(_c_h_a_r _*_r_e_c_o_r_d)
Remove the recorded term from the Prolog database, reclaiming all
associated memory resources.
99..44..1144..33 GGeettttiinngg ffiillee nnaammeess
The function PL_get_file_name() provides access to Prolog filenames and
its file-search mechanism described with absolute_file_name/3. Its
existence is motivated to realise a uniform interface to deal with file
properties, search, naming conventions, etc., from foreign code.
int PPLL__ggeett__ffiillee__nnaammee(_t_e_r_m___t _s_p_e_c_, _c_h_a_r _*_*_n_a_m_e_, _i_n_t _f_l_a_g_s)
Translate a Prolog term into a file name. The name is stored
in the static buffer ring described with th PL_get_chars() option
BUF_RING. Conversion from the internal UNICODE encoding is done
using standard C library functions. _f_l_a_g_s is a bit-mask
controlling the conversion process. Options are:
PL_FILE_ABSOLUTE
Return an absolute path to the requested file.
PL_FILE_OSPATH
Return the name using the hosting OS conventions. On
MS-Windows, \ is used to separate directories rather than the
canonical /.
PL_FILE_SEARCH
Invoke absolute_file_name/3. This implies rules from
file_search_path/2are used.
PL_FILE_EXIST
Demand the path to refer to an existing entity.
PL_FILE_READ
Demand read-access on the result.
PL_FILE_WRITE
Demand write-access on the result.
PL_FILE_EXECUTE
Demand execute-access on the result.
PL_FILE_NOERRORS
Do not raise any exceptions.
int PPLL__ggeett__ffiillee__nnaammeeWW(_t_e_r_m___t _s_p_e_c_, _w_c_h_a_r___t _*_*_n_a_m_e_, _i_n_t _f_l_a_g_s)
Same as PL_get_file_name(), but returns the filename as a wide-
character string. This is intended for Windows to access the
Unicode version of the Win32 API. Note that the flag PL_FILE_OSPATH
must be provided to fetch a filename in OS native (e.g., C:\x\y)
notation.
99..44..1155 EErrrroorrss aanndd wwaarrnniinnggss
PL_warning() prints a standard Prolog warning message to the standard
error (user_error) stream. Please note that new code should consider
using PL_raise_exception() to raise a Prolog exception. See also
section 4.10.
int PPLL__wwaarrnniinngg(_f_o_r_m_a_t_, _a_1_, _._._.)
Print an error message starting with `[WARNING: ', followed by
the output from _f_o_r_m_a_t, followed by a `]' and a newline. Then
start the tracer. _f_o_r_m_a_t and the arguments are the same as for
printf(2). Always returns FALSE.
99..44..1166 EEnnvviirroonnmmeenntt CCoonnttrrooll ffrroomm FFoorreeiiggnn CCooddee
int PPLL__aaccttiioonn(_i_n_t_, _._._.)
Perform some action on the Prolog system. _i_n_t describes the
action. Remaining arguments depend on the requested action. The
actions are listed below:
PPLL__AACCTTIIOONN__TTRRAACCEE
Start Prolog tracer (trace/0). Requires no arguments.
PPLL__AACCTTIIOONN__DDEEBBUUGG
Switch on Prolog debug mode (debug/0). Requires no arguments.
PPLL__AACCTTIIOONN__BBAACCKKTTRRAACCEE
Print backtrace on current output stream. The argument (an
int) is the number of frames printed.
PPLL__AACCTTIIOONN__HHAALLTT
Halt Prolog execution. This action should be called rather
than Unix exit() to give Prolog the opportunity to clean up.
This call does not return. The argument (an int) is the exit
code. See halt/1.
PPLL__AACCTTIIOONN__AABBOORRTT
Generate a Prolog abort (abort/0). This call does not return.
Requires no arguments.
PPLL__AACCTTIIOONN__BBRREEAAKK
Create a standard Prolog break environment (break/0). Returns
after the user types the end-of-file character. Requires no
arguments.
PPLL__AACCTTIIOONN__GGUUIIAAPPPP
Windows: Used to indicate to the kernel that the application
is a GUI application if the argument is not 0, and a console
application if the argument is 0. If a fatal error occurs,
the system uses a windows messagebox to report this on a GUI
application, and otherwise simply prints the error and exits.
PPLL__AACCTTIIOONN__WWRRIITTEE
Write the argument, a char * to the current output stream.
PPLL__AACCTTIIOONN__FFLLUUSSHH
Flush the current output stream. Requires no arguments.
PPLL__AACCTTIIOONN__AATTTTAACCHH__CCOONNSSOOLLEE
Attach a console to a thread if it does not have one. See
attach_console/0.
PPLL__GGMMPP__SSEETT__AALLLLOOCC__FFUUNNCCTTIIOONNSS
Takes an integer argument. If TRUE, the GMP allocations
are immediately bound to the Prolog functions. If FALSE,
SWI-Prolog will never rebind the GMP allocation functions.
See mp_set_memory_functions() in the GMP documentation. The
action returns FALSE if there is no GMP support or GMP is
already initialised.
int PPLL__bbaacckkttrraaccee(_i_n_t _d_e_p_t_h_, _i_n_t _f_l_a_g_s)
Print a Prolog backtrace to the standard error stream. The _d_e_p_t_h
argument specifies the maximum number of frames to print. The
_f_l_a_g_s argument is a bitwise or of the constants PL_BT_SAFE (0x1)
and PL_BT_USER (0x2). PL_BT_SAFE causes frames not to be printed
as normal Prolog goals, but using the predicate, program counter
and clause-number. For example, the dump below indicates the frame
is executing the 2nd clause of $autoload:load_library_index_p/0 at
program pointer 25. This can be interpreted by dumping the virtual
machine code using vm_list/1.
____________________________________________________________________| |
||__[34]_$autoload:load_library_index_p/0_[PC=19_in_clause_2]_______ ||
If the constant PL_BT_USER is specified, `no-debug' frames are
ignored. This predicate may be used from the C-debugger (e.g.,
gdb) to get the Prolog stack at a crash location. Here is an
example dumping the top 20 frames of the Prolog stack.
____________________________________________________________________| |
||(gdb)_call_PL_backtrace(20,0)_____________________________________ ||
99..44..1177 QQuueerryyiinngg PPrroolloogg
long PPLL__qquueerryy(_i_n_t)
Obtain status information on the Prolog system. The actual
argument type depends on the information required. _i_n_t describes
what information is wanted. The options are given in table 9.1.
__________________________________________________________
| PL_QUERY_ARGC |Return an integer holding the|
| |number of arguments given to|
| |Prolog from Unix. |
| PL_QUERY_ARGV |Return a char ** holding the|
| |argument vector given to Prolog|
| |from Unix. |
| PL_QUERY_SYMBOLFILE |Return a char * holding the|
| |current symbol file of the|
| |running process. |
| PL_MAX_INTEGER |Return a long, representing the|
| |maximal integer value repre-|
| |sented by a Prolog integer. |
| PL_MIN_INTEGER |Return a long, representing the|
| |minimal integer value. |
| PL_QUERY_VERSION |Return a long, representing the|
| |version as 10;000M* +100m* +p,|
| |where M is the major, m the |
| |minor version number and p the|
| |patch level. For example, 20717|
| |means 2.7.17. |
| PL_QUERY_ENCODING |Return the default stream encod-|
| |ing of Prolog (of type IOENC). |
| PL_QUERY_USER_CPU |Get amount of user CPU time of|
|________________________|the_process_in_milliseconds.____|
Table 9.1: PL_query() options
99..44..1188 RReeggiisstteerriinngg FFoorreeiiggnn PPrreeddiiccaatteess
int PPLL__rreeggiisstteerr__ffoorreeiiggnn__iinn__mmoodduullee(_c_h_a_r _*_m_o_d_, _c_h_a_r _*_n_a_m_e_, _i_n_t _a_r_i_t_y_, _f_o_r_e_i_g_n___t _(_*_f_)_(_)_, _i_n_t _f_l_a_g_s_, _._._.)
Register the C function _f to implement a Prolog predicate. After
this call returns successfully a predicate with name _n_a_m_e (a char
*) and arity _a_r_i_t_y (a C int) is created in module _m_o_d. If _m_o_d
is NULL, the predicate is created in the module of the calling
context, or if no context is present in the module user.
When called in Prolog, Prolog will call _f_u_n_c_t_i_o_n. _f_l_a_g_s form a
bitwise _o_r'ed list of options for the installation. These are:
_______________________________________________________________
| PL_FA_META |Provide meta-predicate info (see|
| |below) |
| PL_FA_TRANSPARENT |Predicate is module transparent|
| |(deprecated) |
| PL_FA_NONDETERMINISTIC |Predicate is non-deterministic. See|
| |also PL_retry(). |
| PL_FA_NOTRACE |Predicate cannot be seen in the|
| |tracer |
|_PL_FA_VARARGS__________|Use_alternative_calling_convention.__|
If PL_FA_META is provided, PL_register_foreign_in_module()takes one
extra argument. This argument is of type const char*. This
string must be exactly as long as the number of arguments of
the predicate and filled with characters from the set 0-9:^-+?.
See meta_predicate/1 for details. PL_FA_TRANSPARENT is implied
if at least one meta-argument is provided (0-9:^). Note that
meta-arguments are _n_o_t _a_l_w_a_y_s passed as <_m_o_d_u_l_e>:<_t_e_r_m>. Always
use PL_strip_module()to extract the module and plain term from a
meta-argument.
Predicates may be registered either before or after
PL_initialise(). When registered before initialisation the
registration is recorded and executed after installing the system
predicates and before loading the saved state.
Default calling (i.e. without PL_FA_VARARGS) _f_u_n_c_t_i_o_n is passed the
same number of term_t arguments as the arity of the predicate and,
if the predicate is non-deterministic, an extra argument of type
control_t (see section 9.4.1.1). If PL_FA_VARARGS is provided,
_f_u_n_c_t_i_o_n is called with three arguments. The first argument is
a term_t handle to the first argument. Further arguments can be
reached by adding the offset (see also PL_new_term_refs()). The
second argument is the arity, which defines the number of valid
term references in the argument vector. The last argument is used
for non-deterministic calls. It is currently undocumented and
should be defined of type void*. Here is an example:
____________________________________________________________________| |
| static foreign_t |
| atom_checksum(term_t a0, int arity, void* context) |
| { char *s; |
| |
| if ( PL_get_atom_chars(a0, &s) ) |
| { int sum; |
| |
| for(sum=0; *s; s++) |
| sum += *s&0xff; |
| |
| return PL_unify_integer(a0+1, sum&0xff); |
| } |
| |
| return FALSE; |
| } |
| |
| install_t |
| install() |
| { PL_register_foreign("atom_checksum", 2, |
| atom_checksum, PL_FA_VARARGS); |
||}_________________________________________________________________ ||
int PPLL__rreeggiisstteerr__ffoorreeiiggnn(_c_o_n_s_t _c_h_a_r _*_n_a_m_e_, _i_n_t _a_r_i_t_y_, _f_o_r_e_i_g_n___t _(_*_f_u_n_c_t_i_o_n_)_(_)_, _i_n_t _f_l_a_g_s_, _._._.)
Same as PL_register_foreign_in_module(), passing NULL for the
_m_o_d_u_l_e.
void PPLL__rreeggiisstteerr__eexxtteennssiioonnss__iinn__mmoodduullee(_c_o_n_s_t _c_h_a_r _*_m_o_d_u_l_e_, _P_L___e_x_t_e_n_s_i_o_n _*_e)
Register a series of predicates from an array of definitions of the
type PL_extension in the given _m_o_d_u_l_e. If _m_o_d_u_l_e is NULL, the
predicate is created in the module of the calling context, or if no
context is present in the module user. The PL_extension type is
defined as
____________________________________________________________________| |
| typedef struct PL_extension |
| { char *predicate_name; /* Name of the predicate */ |
| short arity; /* Arity of the predicate */ |
| pl_function_t function; /* Implementing functions */ |
| short flags; /* Or of PL_FA_... */ |
||}_PL_extension;___________________________________________________ ||
For details, see PL_register_foreign_in_module(). Here is an
example of its usage:
____________________________________________________________________| |
| static PL_extension predicates[] = { |
| { "foo", 1, pl_foo, 0 }, |
| { "bar", 2, pl_bar, PL_FA_NONDETERMINISTIC }, |
| { NULL, 0, NULL, 0 } |
| }; |
| |
| main(int argc, char **argv) |
| { PL_register_extensions_in_module("user", predicates); |
| |
| if ( !PL_initialise(argc, argv) ) |
| PL_halt(1); |
| |
| ... |
||}_________________________________________________________________ ||
void PPLL__rreeggiisstteerr__eexxtteennssiioonnss( _P_L___e_x_t_e_n_s_i_o_n _*_e)
Same as PL_register_extensions_in_module()using NULL for the _m_o_d_u_l_e
argument.
99..44..1199 FFoorreeiiggnn CCooddee HHooookkss
For various specific applications some hooks are provided.
PL_dispatch_hook_t PPLL__ddiissppaattcchh__hhooookk(_P_L___d_i_s_p_a_t_c_h___h_o_o_k___t)
If this hook is not NULL, this function is called when reading from
the terminal. It is supposed to dispatch events when SWI-Prolog
is connected to a window environment. It can return two values:
PL_DISPATCH_INPUT indicates Prolog input is available on file
descriptor 0 or PL_DISPATCH_TIMEOUT to indicate a timeout. The old
hook is returned. The type PL_dispatch_hook_t is defined as:
____________________________________________________________________| |
||typedef_int__(*PL_dispatch_hook_t)(void);_________________________ ||
void PPLL__aabboorrtt__hhooookk(_P_L___a_b_o_r_t___h_o_o_k___t)
Install a hook when abort/0 is executed. SWI-Prolog abort/0 is
implemented using C setjmp()/longjmp() construct. The hooks are
executed in the reverse order of their registration after the
longjmp() took place and before the Prolog top level is reinvoked.
The type PL_abort_hook_t is defined as:
____________________________________________________________________| |
||typedef_void_(*PL_abort_hook_t)(void);____________________________ ||
int PPLL__aabboorrtt__uunnhhooookk(_P_L___a_b_o_r_t___h_o_o_k___t)
Remove a hook installed with PL_abort_hook(). Returns FALSE if no
such hook is found, TRUE otherwise.
void PPLL__oonn__hhaalltt(_i_n_t _(_*_f_)_(_i_n_t_, _v_o_i_d _*_)_, _v_o_i_d _*_c_l_o_s_u_r_e)
Register the function _f to be called if SWI-Prolog is halted. The
function is called with two arguments: the exit code of the
process (0 if this cannot be determined) and the _c_l_o_s_u_r_e argument
passed to the PL_on_halt() call. Handlers _m_u_s_t return 0. Other
return values are reserved for future use. See also at_halt/1.
These handlers are called _b_e_f_o_r_e system cleanup and can therefore
access all normal Prolog resources. See also PL_exit_hook().
void PPLL__eexxiitt__hhooookk(_i_n_t _(_*_f_)_(_i_n_t_, _v_o_i_d _*_)_, _v_o_i_d _*_c_l_o_s_u_r_e)
Similar to PL_on_halt(), but the hooks are executed by PL_halt()
instead of PL_cleanup() just before calling exit().
PL_agc_hook_t PPLL__aaggcc__hhooookk(_P_L___a_g_c___h_o_o_k___t _n_e_w)
Register a hook with the atom-garbage collector (see
garbage_collect_atoms/0) that is called on any atom that is
reclaimed. The old hook is returned. If no hook is currently
defined, NULL is returned. The argument of the called hook is the
atom that is to be garbage collected. The return value is an int.
If the return value is zero, the atom is nnoott reclaimed. The hook
may invoke any Prolog predicate.
The example below defines a foreign library for printing the
garbage collected atoms for debugging purposes.
____________________________________________________________________| |
| #include <SWI-Stream.h> |
| #include <SWI-Prolog.h> |
| |
| static int |
| atom_hook(atom_t a) |
| { Sdprintf("AGC: deleting %s\n", PL_atom_chars(a)); |
| |
| return TRUE; |
| } |
| |
| static PL_agc_hook_t old; |
| |
| install_t |
| install() |
| { old = PL_agc_hook(atom_hook); |
| } |
| |
| install_t |
| uninstall() |
| { PL_agc_hook(old); |
||}_________________________________________________________________ ||
99..44..2200 SSttoorriinngg ffoorreeiiggnn ddaattaa
When combining foreign code with Prolog, it can be necessary to make
data represented in the foreign language available to Prolog. For
example, to pass it to another foreign function. At the end of this
section, there is a partial implementation of using foreign functions
to manage bit-vectors. Another example is the SGML/XML library that
manages a `parser' object, an object that represents the current state
of the parser and that can be directed to perform actions such as
parsing a document or make queries about the document content.
This section provides some hints for handling foreign data in Prolog.
There are four options for storing such data:
o _N_a_t_u_r_a_l _P_r_o_l_o_g _d_a_t_a
Uses the representation one would choose if no foreign interface
was required. For example, a bitvector representing a list of
small integers can be represented as a Prolog list of integers.
o _O_p_a_q_u_e _p_a_c_k_e_d _d_a_t_a _o_n _t_h_e _s_t_a_c_k_s
It is possible to represent the raw binary representation of the
foreign object as a Prolog string (see section 4.24). Strings
may be created from foreign data using PL_put_string_nchars() and
retrieved using PL_get_string_chars(). It is good practice to wrap
the string in a compound term with arity 1, so Prolog can identify
the type. The hook portray/1 rules may be used to streamline
printing such terms during development.
o _O_p_a_q_u_e _p_a_c_k_e_d _d_a_t_a _i_n _a _b_l_o_b
Similar to the above solution, binary data can be stored in an
atom. The blob interface (section 9.4.7) provides additional
facilities to assign a type and hook-functions that act on creation
and destruction of the underlying atom.
o _N_a_t_u_r_a_l _f_o_r_e_i_g_n _d_a_t_a_, _p_a_s_s_e_d _a_s _a _p_o_i_n_t_e_r
An alternative is to pass a pointer to the foreign data. Again,
the pointer is often wrapped in a compound term.
The choice may be guided using the following distinctions
o _I_s _t_h_e _d_a_t_a _o_p_a_q_u_e _t_o _P_r_o_l_o_g
With `opaque' data, we refer to data handled in foreign functions,
passed around in Prolog, but where Prolog never examines the
contents of the data itself. If the data is opaque to Prolog, the
selection will be driven solely by simplicity of the interface and
performance.
o _W_h_a_t _i_s _t_h_e _l_i_f_e_t_i_m_e _o_f _t_h_e _d_a_t_a
With `lifetime' we refer to how it is decided that the object is
(or can be) destroyed. We can distinguish three cases:
1. The object must be destroyed on backtracking and normal Prolog
garbage collection (i.e., it acts as a normal Prolog term).
In this case, representing the object as a Prolog string
(second option above) is the only feasible solution.
2. The data must survive Prolog backtracking. This leaves two
options. One is to represent the object using a pointer and
use explicit creation and destruction, making the programmer
responsible. The alternative is to use the blob-interface,
leaving destruction to the (atom) garbage collector.
3. The data lives as during the lifetime of a foreign
function that implements a predicate. If the predicate
is deterministic, foreign automatic variables are suitable.
If the predicate is non-deterministic, the data may be
allocated using malloc() and a pointer may be passed. See
section 9.4.1.1.
99..44..2200..11 EExxaammpplleess ffoorr ssttoorriinngg ffoorreeiiggnn ddaattaa
In this section, we outline some examples, covering typical cases.
In the first example, we will deal with extending Prolog's data
representation with integer sets, represented as bit-vectors. Then, we
discuss the outline of the DDE interface.
IInntteeggeerr sseettss with not-too-far-apart upper- and lower-bounds can be
represented using bit-vectors. Common set operations, such as union,
intersection, etc., are reduced to simple _a_n_d'ing and _o_r'ing the
bit-vectors. This can be done using Prolog's unbounded integers.
For really demanding applications, foreign representation will perform
better, especially time-wise. Bit-vectors are naturally expressed
using string objects. If the string is wrapped in bitvector/1, the
lower-bound of the vector is 0 and the upper-bound is not defined; an
implementation for getting and putting the sets as well as the union
predicate for it is below.
________________________________________________________________________| |
|#include <SWI-Prolog.h> |
| |
|#define max(a, b) ((a) > (b) ? (a) : (b)) |
|#define min(a, b) ((a) < (b) ? (a) : (b)) |
| |
|static functor_t FUNCTOR_bitvector1; |
| |
|static int |
|get_bitvector(term_t in, int *len, unsigned char **data) |
|{ if ( PL_is_functor(in, FUNCTOR_bitvector1) ) |
| { term_t a = PL_new_term_ref(); |
| |
| PL_get_arg(1, in, a); |
| return PL_get_string(a, (char **)data, len); |
| } |
| |
| PL_fail; |
|} |
| |
|static int |
|unify_bitvector(term_t out, int len, const unsigned char *data) |
|{ if ( PL_unify_functor(out, FUNCTOR_bitvector1) ) |
| { term_t a = PL_new_term_ref(); |
| |
| PL_get_arg(1, out, a); |
| |
| return PL_unify_string_nchars(a, len, (const char *)data); |
| } |
| |
| PL_fail; |
|} |
| |
|static foreign_t |
|pl_bitvector_union(term_t t1, term_t t2, term_t u) |
|{ unsigned char *s1, *s2; |
| int l1, l2; |
| |
| if ( get_bitvector(t1, &l1, &s1) && |
| get_bitvector(t2, &l2, &s2) ) |
| { int l = max(l1, l2); |
| unsigned char *s3 = alloca(l); |
| |
| if ( s3 ) |
| { int n; |
| int ml = min(l1, l2); |
| |
| for(n=0; n<ml; n++) |
| s3[n] = s1[n] | s2[n]; |
| for( ; n < l1; n++) |
| s3[n] = s1[n]; |
| for( ; n < l2; n++) |
| s3[n] = s2[n]; |
| |
| return unify_bitvector(u, l, s3); |
| } |
| |
| return PL_warning("Not enough memory"); |
| } |
| |
| PL_fail; |
|} |
| |
| |
|install_t |
|install() |
|{ PL_register_foreign("bitvector_union", 3, pl_bitvector_union, 0); |
| |
| FUNCTOR_bitvector1 = PL_new_functor(PL_new_atom("bitvector"), 1); |
|}|_____________________________________________________________________ | |
TThhee DDDDEE iinntteerrffaaccee (see section 4.42) represents another common usage
of the foreign interface: providing communication to new operating
system features. The DDE interface requires knowledge about active DDE
server and client channels. These channels contains various foreign
data types. Such an interface is normally achieved using an open/close
protocol that creates and destroys a _h_a_n_d_l_e. The handle is a reference
to a foreign data structure containing the relevant information.
There are a couple of possibilities for representing the handle. The
choice depends on responsibilities and debugging facilities. The
simplest approach is to use PL_unify_pointer() and PL_get_pointer().
This approach is fast and easy, but has the drawbacks of (untyped)
pointers: there is no reliable way to detect the validity of the
pointer, nor to verify that it is pointing to a structure of the
desired type. The pointer may be wrapped into a compound term with
arity 1 (i.e., dde_channel(<_P_o_i_n_t_e_r>)), making the type-problem less
serious.
Alternatively (used in the DDE interface), the interface code can
maintain a (preferably variable length) array of pointers and return
the index in this array. This provides better protection. Especially
for debugging purposes, wrapping the handle in a compound is a good
suggestion.
99..44..2211 EEmmbbeeddddiinngg SSWWII--PPrroolloogg iinn ootthheerr aapppplliiccaattiioonnss
With embedded Prolog we refer to the situation where the `main' program
is not the Prolog application. Prolog is sometimes embedded in C, C++,
Java or other languages to provide logic based services in a larger
application. Embedding loads the Prolog engine as a library to the
external language. Prolog itself only provides for embedding in the C
language (compatible with C++). Embedding in Java is achieved using
JPL using a C-glue between the Java and Prolog C interfaces.
The most simple embedded program is below. The interface
function PL_initialise() mmuusstt be called before any of the other
SWI-Prolog foreign language functions described in this chapter,
except for PL_initialise_hook(), PL_new_atom(), PL_new_functor() and
PL_register_foreign(). PL_initialise() interprets all the command line
arguments, except for the -t toplevel flag that is interpreted by
PL_toplevel().
________________________________________________________________________| |
|int |
|main(int argc, char **argv) |
|{ |
|#ifdef READLINE /* Remove if you don't want readline */ |
| PL_initialise_hook(install_readline); |
|#endif |
| |
| if ( !PL_initialise(argc, argv) ) |
| PL_halt(1); |
| |
| PL_halt(PL_toplevel() ? 0 : 1); |
|}|_____________________________________________________________________ | |
int PPLL__iinniittiiaalliissee(_i_n_t _a_r_g_c_, _c_h_a_r _*_*_a_r_g_v)
Initialises the SWI-Prolog heap and stacks, restores the Prolog
state, loads the system and personal initialisation files, runs the
initialization/1 hooks and finally runs the -g goal hook.
Special consideration is required for argv[0]. On UUnniixx, this
argument passes the part of the command line that is used to locate
the executable. Prolog uses this to find the file holding the
running executable. The WWiinnddoowwss version uses this to find a _m_o_d_u_l_e
of the running executable. If the specified module cannot be
found, it tries the module libpl.dll, containing the Prolog runtime
kernel. In all these cases, the resulting file is used for two
purposes:
o See whether a Prolog saved state is appended to the file. If
this is the case, this state will be loaded instead of the
default boot.prc file from the SWI-Prolog home directory. See
also qsave_program/[1,2] and section 9.5.
o Find the Prolog home directory. This process is described in
detail in section 9.6.
PL_initialise() returns 1 if all initialisation succeeded and 0
otherwise.
In most cases, _a_r_g_c and _a_r_g_v will be passed from the main program.
It is allowed to create your own argument vector, provided argv[0]
is constructed according to the rules above. For example:
____________________________________________________________________| |
| int |
| main(int argc, char **argv) |
| { char *av[10]; |
| int ac = 0; |
| |
| av[ac++] = argv[0]; |
| av[ac++] = "-x"; |
| av[ac++] = "mystate"; |
| av[ac] = NULL; |
| |
| if ( !PL_initialise(ac, av) ) |
| PL_halt(1); |
| ... |
||}_________________________________________________________________ ||
Please note that the passed argument vector may be referred from
Prolog at any time and should therefore be valid as long as the
Prolog engine is used.
A good setup in Windows is to add SWI-Prolog's bin directory to
your PATH and either pass a module holding a saved state, or
"libpl.dll" as argv[0]. If the Prolog state is attached to a DLL
(see the -dll option of swipl-ld), pass the name of this DLL.
int PPLL__iiss__iinniittiiaalliisseedd(_i_n_t _*_a_r_g_c_, _c_h_a_r _*_*_*_a_r_g_v)
Test whether the Prolog engine is already initialised. Returns
FALSE if Prolog is not initialised and TRUE otherwise. If the
engine is initialised and _a_r_g_c is not NULL, the argument count used
with PL_initialise() is stored in _a_r_g_c. Same for the argument
vector _a_r_g_v.
void PPLL__iinnssttaallll__rreeaaddlliinnee()
Installs the GNU readline line editor. Embedded applications that
do not use the Prolog top level should normally delete this line,
shrinking the Prolog kernel significantly. Note that the Windows
version does not use GNU readline.
int PPLL__ttoopplleevveell()
Runs the goal of the -t toplevel switch (default prolog/0) and
returns 1 if successful, 0 otherwise.
int PPLL__cclleeaannuupp(_i_n_t _s_t_a_t_u_s)
This function performs the reverse of PL_initialise(). It runs the
PL_on_halt() and at_halt/1 handlers, closes all streams (except for
the `standard I/O' streams which are flushed only), deallocates
all memory and restores all signal handlers. The _s_t_a_t_u_s argument
is passed to the various termination hooks and indicates the
_e_x_i_t_-_s_t_a_t_u_s.
The function returns TRUE if successful and FALSE otherwise.
Currently, FALSE is returned when an attempt is made to call
PL_cleanup() recursively or if one of the exit handlers cancels the
termination using cancel_halt/1. Exit handlers may only cancel
termination if _s_t_a_t_u_s is 0.
In theory, this function allows deleting and restarting the Prolog
system in the same process. In practice, SWI-Prolog's cleanup
process is far from complete, and trying to revive the system using
PL_initialise() will leak memory in the best case. It can also
crash the appliction.
In this state, there is little practical use for this function.
If you want to use Prolog temporarily, consider running it in a
separate process. If you want to be able to reset Prolog, your
options are (again) a separate process, modules or threads.
void PPLL__cclleeaannuupp__ffoorrkk()
Stop intervaltimer that may be running on behalf of profile/1. The
call is intended to be used in combination with fork():
____________________________________________________________________| |
| if ( (pid=fork()) == 0 ) |
| { PL_cleanup_fork(); |
| <some exec variation> |
||____}_____________________________________________________________ ||
The call behaves the same on Windows, though there is probably no
meaningful application.
int PPLL__hhaalltt(_i_n_t _s_t_a_t_u_s)
Clean up the Prolog environment using PL_cleanup() and if success-
ful call exit() with the status argument. Returns FALSE if exit
was cancelled by PL_cleanup().
99..44..2211..11 TThhrreeaaddiinngg,, SSiiggnnaallss aanndd eemmbbeeddddeedd PPrroolloogg
This section applies to Unix-based environments that have signals or
multithreading. The Windows version is compiled for multithreading,
and Windows lacks proper signals.
We can distinguish two classes of embedded executables. There are
small C/C++ programs that act as an interfacing layer around Prolog.
Most of these programs can be replaced using the normal Prolog
executable extended with a dynamically loaded foreign extension and in
most cases this is the preferred route. In other cases, Prolog is
embedded in a complex application that---like Prolog---wants to control
the process environment. A good example is Java. Embedding Prolog
is generally the only way to get these environments together in one
process image. Java applications, however, are by nature multithreaded
and appear to do signal handling (software interrupts).
On Unix systems, SWI-Prolog uses three signals:
SSIIGGUUSSRR11 is used to sychronise atom and clause garbage collection.
The handler is installed at the start of garbage collection and
reverted to the old setting after completion.
SSIIGGUUSSRR22 has an empty signal handler. This signal is sent to a thread
after sending a thread-signal (see thread_signal/2). It causes
blocking system calls to return with EINTR, which gives them the
opportunity to react to thread-signals.
SSIIGGIINNTT is used by the top level to activate the tracer (typically bound
to control-C). The first control-C posts a request for starting the
tracer in a safe, synchronous fashion. If control-C is hit again
before the safe route is executed, it prompts the user whether or
not a forced interrupt is desired.
The --nosignals option can be used to inhibit processing of SIGINT. The
other signals are vital for the functioning of SWI-Prolog. If they
conflict with other applications, signal handling of either component
must be modified. The SWI-Prolog signals are defined in pl-thread.h of
the source distribution.
99..55 LLiinnkkiinngg eemmbbeeddddeedd aapppplliiccaattiioonnss uussiinngg sswwiippll--lldd
The utility program swipl-ld (Win32: swipl-ld.exe) may be used to
link a combination of C files and Prolog files into a stand-alone
executable. swipl-ld automates most of what is described in the
previous sections.
In normal usage, a copy is made of the default embedding template
.../swipl/include/stub.c. The main() routine is modified to suit
your application. PL_initialise() mmuusstt be passed the program name
(_a_r_g_v_[_0_]) (Win32: the executing program can be obtained using
GetModuleFileName()). The other elements of the command line may be
modified. Next, swipl-ld is typically invoked as:
________________________________________________________________________| |
|swipl-ld|-o_output_stubfile.c_[other-c-or-o-files]_[plfiles]___________ | |
swipl-ld will first split the options into various groups for both the
C compiler and the Prolog compiler. Next, it will add various default
options to the C compiler and call it to create an executable holding
the user's C code and the Prolog kernel. Then, it will call the
SWI-Prolog compiler to create a saved state from the provided Prolog
files and finally, it will attach this saved state to the created
emulator to create the requested executable.
Below, it is described how the options are split and which additional
options are passed.
-help
Print brief synopsis.
-pl _p_r_o_l_o_g
Select the Prolog to use. This Prolog is used for two purposes:
get the home directory as well as the compiler/linker options and
create a saved state of the Prolog code.
-ld _l_i_n_k_e_r
Linker used to link the raw executable. Default is to use the C
compiler (Win32: link.exe).
-cc _C _c_o_m_p_i_l_e_r
Compiler for .c files found on the command line. Default is the
compiler used to build SWI-Prolog accessible through the Prolog
flag c_cc (Win32: cl.exe).
-c++ _C_+_+_-_c_o_m_p_i_l_e_r
Compiler for C++ source file (extensions .cpp, .cxx, .cc or .C)
found on the command line. Default is c++ or g++ if the C compiler
is gcc (Win32: cl.exe).
-nostate
Just relink the kernel, do not add any Prolog code to the
new kernel. This is used to create a new kernel holding
additional foreign predicates on machines that do not support
the shared-library (DLL) interface, or if building the state
cannot be handled by the default procedure used by swipl-ld.
In the latter case the state is created separately and
appended to the kernel using cat <_k_e_r_n_e_l> <_s_t_a_t_e> > <_o_u_t>(Win32:
copy /b <_k_e_r_n_e_l>+<_s_t_a_t_e> <_o_u_t>).
-shared
Link C, C++ or object files into a shared object (DLL) that can be
loaded by the load_foreign_library/1predicate. If used with -c
it sets the proper options to compile a C or C++ file ready for
linking into a shared object.
-dll
_W_i_n_d_o_w_s _o_n_l_y. Embed SWI-Prolog into a DLL rather than an
executable.
-c
Compile C or C++ source files into object files. This turns
swipl-ld into a replacement for the C or C++ compiler, where proper
options such as the location of the include directory are passed
automatically to the compiler.
-E
Invoke the C preprocessor. Used to make swipl-ld a replacement for
the C or C++ compiler.
-pl-options _,_._._.
Additional options passed to Prolog when creating the saved state.
The first character immediately following pl-options is used as
separator and translated to spaces when the argument is built.
Example: -pl-options,-F,xpce passes -F xpce as additional flags to
Prolog.
-ld-options _,_._._.
Passes options to the linker, similar to -pl-options.
-cc-options _,_._._.
Passes options to the C/C++ compiler, similar to -pl-options.
-v
Select verbose operation, showing the various programs and their
options.
-o _o_u_t_f_i_l_e
Reserved to specify the final output file.
-l_l_i_b_r_a_r_y
Specifies a library for the C compiler. By default, -lswipl
(Win32: libpl.lib) and the libraries needed by the Prolog kernel
are given.
-L_l_i_b_r_a_r_y_-_d_i_r_e_c_t_o_r_y
Specifies a library directory for the C compiler. By default
the directory containing the Prolog C library for the current
architecture is passed.
-g | -I_i_n_c_l_u_d_e_-_d_i_r_e_c_t_o_r_y | -D_d_e_f_i_n_i_t_i_o_n
These options are passed to the C compiler. By default, the
include directory containing SWI-Prolog.h is passed. swipl-ld adds
two additional * -Ddef flags:
-D__SWI_PROLOG__
Indicates the code is to be connected to SWI-Prolog.
-D__SWI_EMBEDDED__
Indicates the creation of an embedded program.
_*_._o | _*_._c | _*_._C | _*_._c_x_x | _*_._c_p_p
Passed as input files to the C compiler.
_*_._p_l |_*_._q_l_f
Passed as input files to the Prolog compiler to create the saved
state.
*
All other options. These are passed as linker options to the C
compiler.
99..55..11 AA ssiimmppllee eexxaammppllee
The following is a very simple example going through all the steps
outlined above. It provides an arithmetic expression evaluator. We
will call the application calc and define it in the files calc.c and
calc.pl. The Prolog file is simple:
________________________________________________________________________| |
|calc(Atom) :- |
| term_to_atom(Expr, Atom), |
| A is Expr, |
| write(A), |
||_______nl.____________________________________________________________ ||
The C part of the application parses the command line options,
initialises the Prolog engine, locates the calc/1 predicate and calls
it. The coder is in figure 9.4.
________________________________________________________________________| |
|#include <stdio.h> |
|#include <SWI-Prolog.h> |
| |
|#define MAXLINE 1024 |
| |
|int |
|main(int argc, char **argv) |
|{ char expression[MAXLINE]; |
| char *e = expression; |
| char *program = argv[0]; |
| char *plav[2]; |
| int n; |
| |
| /* combine all the arguments in a single string */ |
| |
| for(n=1; n<argc; n++) |
| { if ( n != 1 ) |
| *e++ = ' '; |
| strcpy(e, argv[n]); |
| e += strlen(e); |
| } |
| |
| /* make the argument vector for Prolog */ |
| |
| plav[0] = program; |
| plav[1] = NULL; |
| |
| /* initialise Prolog */ |
| |
| if ( !PL_initialise(1, plav) ) |
| PL_halt(1); |
| |
| /* Lookup calc/1 and make the arguments and call */ |
| |
| { predicate_t pred = PL_predicate("calc", 1, "user"); |
| term_t h0 = PL_new_term_refs(1); |
| int rval; |
| |
| PL_put_atom_chars(h0, expression); |
| rval = PL_call_predicate(NULL, PL_Q_NORMAL, pred, h0); |
| |
| PL_halt(rval ? 0 : 1); |
| } |
| |
| return 0; |
|}|_____________________________________________________________________ | |
Figure 9.4: C source for the calc application
The application is now created using the following command line:
________________________________________________________________________| |
|%|swipl-ld_-o_calc_calc.c_calc.pl______________________________________ | |
The following indicates the usage of the application:
________________________________________________________________________| |
|% calc pi/2 |
|1.5708|________________________________________________________________ | |
99..66 TThhee PPrroolloogg ``hhoommee'' ddiirreeccttoorryy
Executables embedding SWI-Prolog should be able to find the `home'
directory of the development environment unless a self-contained saved
state has been added to the executable (see qsave_program/[1,2] and
section 9.5).
If Prolog starts up, it will try to locate the development environment.
To do so, it will try the following steps until one succeeds:
1. If the --home=DIR is provided, use this.
2. If the environment variable SWI_HOME_DIRis defined and points to
an existing directory, use this.
3. If the environment variable SWIPL is defined and points to an
existing directory, use this.
4. Locate the primary executable or (Windows only) a component
(_m_o_d_u_l_e) thereof and check whether the parent directory of the
directory holding this file contains the file swipl. If so, this
file contains the (relative) path to the home directory. If this
directory exists, use this. This is the normal mechanism used by
the binary distribution.
5. If the precompiled path exists, use it. This is only useful for a
source installation.
If all fails and there is no state attached to the executable or
provided Windows module (see PL_initialise()), SWI-Prolog gives up. If
a state is attached, the current working directory is used.
The file_search_path/2 alias swi is set to point to the home directory
located.
99..77 EExxaammppllee ooff UUssiinngg tthhee FFoorreeiiggnn IInntteerrffaaccee
Below is an example showing all stages of the declaration of a foreign
predicate that transforms atoms possibly holding uppercase letters into
an atom only holding lowercase letters. Figure 9.5 shows the C source
file, figure 9.6 illustrates compiling and loading of foreign code.
________________________________________________________________________| |
|/* Include file depends on local installation */ |
|#include <SWI-Prolog.h> |
|#include <stdlib.h> |
|#include <string.h> |
|#include <ctype.h> |
| |
|foreign_t |
|pl_lowercase(term_t u, term_t l) |
|{ char *copy; |
| char *s, *q; |
| int rval; |
| |
| if ( !PL_get_atom_chars(u, &s) ) |
| return PL_warning("lowercase/2: instantiation fault"); |
| copy = malloc(strlen(s)+1); |
| |
| for( q=copy; *s; q++, s++) |
| *q = (isupper(*s) ? tolower(*s) : *s); |
| *q = '\0'; |
| |
| rval = PL_unify_atom_chars(l, copy); |
| free(copy); |
| |
| return rval; |
|} |
| |
|install_t |
|install() |
|{ PL_register_foreign("lowercase", 2, pl_lowercase, 0); |
|}|_____________________________________________________________________ | |
Figure 9.5: Lowercase source file
________________________________________________________________________| |
|% gcc -I/usr/local/lib/swipl-\plversion/include -fpic -c lowercase.c |
|% gcc -shared -o lowercase.so lowercase.o |
|% swipl |
|Welcome to SWI-Prolog (Version \plversion) |
|... |
| |
|1 ?- load_foreign_library(lowercase). |
|true. |
| |
|2 ?- lowercase('Hello World!', L). |
|L|=_'hello_world!'.____________________________________________________ | |
Figure 9.6: Compiling the C source and loading the object file
99..88 NNootteess oonn UUssiinngg FFoorreeiiggnn CCooddee
99..88..11 MMeemmoorryy AAllllooccaattiioonn
SWI-Prolog's heap memory allocation is based on the malloc(3) library
routines. SWI-Prolog provides the functions below as a wrapper around
malloc(). Allocation errors in these functions trap SWI-Prolog's
fatal-error handler, in which case PL_malloc() or PL_realloc() do not
return.
Portable applications must use PL_free() to release strings returned by
PL_get_chars()using the BUF_MALLOC argument. Portable applications may
use both PL_malloc() and friends or malloc() and friends but should not
mix these two sets of functions on the same memory.
void * PPLL__mmaalllloocc(_s_i_z_e___t _b_y_t_e_s)
Allocate _b_y_t_e_s of memory. On failure SWI-Prolog's fatal-error
handler is called and PL_malloc() does not return. Memory
allocated using these functions must use PL_realloc() and PL_free()
rather than realloc() and free().
void * PPLL__rreeaalllloocc(_v_o_i_d _*_m_e_m_, _s_i_z_e___t _s_i_z_e)
Change the size of the allocated chunk, possibly moving it. The
_m_e_m argument must be obtained from a previous PL_malloc() or
PL_realloc() call.
void PPLL__ffrreeee(_v_o_i_d _*_m_e_m)
Release memory. The _m_e_m argument must be obtained from a previous
PL_malloc() or PL_realloc() call.
99..88..11..11 BBooeehhmm--GGCC ssuuppppoorrtt
To accommodate future use of the Boehm garbage collector for heap
memory allocation, the interface provides the functions described
below. Foreign extensions that wish to use the Boehm-GC facilities can
use these wrappers. Please note that if SWI-Prolog is not compiled to
use Boehm-GC (default), the user is responsible for calling PL_free()
to reclaim memory.
void* PPLL__mmaalllloocc__aattoommiicc(_s_i_z_e___t _b_y_t_e_s)
void* PPLL__mmaalllloocc__uunnccoolllleeccttaabbllee(_s_i_z_e___t _b_y_t_e_s)
void* PPLL__mmaalllloocc__aattoommiicc__uunnccoolllleeccttaabbllee(_s_i_z_e___t _b_y_t_e_s)
If Boehm-GC is not used, these are all the same as PL_malloc().
With Boehm-GC, these map to the corresponding Boehm-GC functions.
_A_t_o_m_i_c means that the content should not be scanned for pointers,
and _u_n_c_o_l_l_e_c_t_a_b_l_e means that the object should never be garbage
collected.
void* PPLL__mmaalllloocc__ssttuubbbboorrnn(_s_i_z_e___t _b_y_t_e_s)
void PPLL__eenndd__ssttuubbbboorrnn__cchhaannggee(_v_o_i_d _*_m_e_m_o_r_y)
These functions allow creating objects, promising GC that the
content will not change after PL_end_stubborn_change().
99..88..22 CCoommppaattiibbiilliittyy bbeettwweeeenn PPrroolloogg vveerrssiioonnss
Great care is taken to ensure binary compatibility of foreign
extensions between different Prolog versions. Only the much less
frequently used stream interface has been responsible for binary
incompatibilities.
Source code that relies on new features of the foreign interface
can use the macro PLVERSION to find the version of SWI-Prolog.h and
PL_query() using the option PL_QUERY_VERSION to find the version of
the attached Prolog system. Both follow the same numbering schema
explained with PL_query().
99..88..33 DDeebbuuggggiinngg aanndd pprrooffiilliinngg ffoorreeiiggnn ccooddee ((vvaallggrriinndd))
This section is only relevant for Unix users on platforms supported by
valgrind. Valgrind is an excellent binary instrumentation platform.
Unlike many other instrumentation platforms, valgrind can deal with
code loaded through dlopen().
The callgrind tool can be used to profile foreign code loaded under
SWI-Prolog. Compile the foreign library adding -g option to gcc
or swipl-ld. By setting the environment variable VALGRIND to yes,
SWI-Prolog will _n_o_t release loaded shared objects using dlclose().
This trick is required to get source information on the loaded library.
Without, valgrind claims that the shared object has no debugging
information. Here is the complete sequence using bash as login shell:
________________________________________________________________________| |
|% VALGRIND=yes valgrind --tool=callgrind pl <args> |
|<prolog interaction> |
|%|kcachegrind_callgrind.out.<pid>______________________________________ | |
99..88..44 NNaammee CCoonnfflliiccttss iinn CC mmoodduulleess
In the current version of the system all public C functions of
SWI-Prolog are in the symbol table. This can lead to name clashes with
foreign code. Someday I should write a program to strip all these
symbols from the symbol table (why does Unix not have that?). For now
I can only suggest you give your function another name. You can do
this using the C preprocessor. If---for example---your foreign package
uses a function warning(), which happens to exist in SWI-Prolog as
well, the following macro should fix the problem:
________________________________________________________________________| |
|#define|warning_warning________________________________________________ | |
Note that shared libraries do not have this problem as the shared
library loader will only look for symbols in the main executable for
symbols that are not defined in the library itself.
99..88..55 CCoommppaattiibbiilliittyy ooff tthhee FFoorreeiiggnn IInntteerrffaaccee
The term reference mechanism was first used by Quintus Prolog
version 3. SICStus Prolog version 3 is strongly based on the Quintus
interface. The described SWI-Prolog interface is similar to using the
Quintus or SICStus interfaces, defining all foreign-predicate arguments
of type +term. SWI-Prolog explicitly uses type functor_t, while
Quintus and SICStus use <_n_a_m_e> and <_a_r_i_t_y>. As the names of the
functions differ from Prolog to Prolog, a simple macro layer dealing
with the names can also deal with this detail. For example:
________________________________________________________________________| |
|#define QP_put_functor(t, n, a) \ |
||_______PL_put_functor(t,_PL_new_functor(n,_a))________________________ ||
The PL_unify_*() functions are lacking from the Quintus and SICStus
interface. They can easily be emulated, or the put/unify approach
should be used to write compatible code.
The PL_open_foreign_frame()/PL_close_foreign_frame() combination is lack-
ing from both other Prologs. SICStus has PL_new_term_refs(_0), followed
by PL_reset_term_refs(), that allows for discarding term references.
The Prolog interface for the graphical user interface package XPCE
shares about 90% of the code using a simple macro layer to deal with
different naming and calling conventions of the interfaces.
CChhaapptteerr 1100.. GGEENNEERRAATTIINNGG RRUUNNTTIIMMEE AAPPPPLLIICCAATTIIOONNSS
This chapter describes the features of SWI-Prolog for delivering
applications that can run without the development version of the system
installed.
A SWI-Prolog runtime executable is a file consisting of two parts. The
first part is the _e_m_u_l_a_t_o_r, which is machine-dependent. The second
part is the _r_e_s_o_u_r_c_e _a_r_c_h_i_v_e, which contains the compiled program in a
machine-independent format, startup options and possibly user-defined
_r_e_s_o_u_r_c_e_s; see resource/3 and open_resource/3.
These two parts can be connected in various ways. The most common way
for distributed runtime applications is to _c_o_n_c_a_t_e_n_a_t_e the two parts.
This can be achieved using external commands (Unix: cat, Windows:
copy), or using the stand_alone option to qsave_program/2. The second
option is to attach a startup script in front of the resource that
starts the emulator with the proper options. This is the default under
Unix. Finally, an emulator can be told to use a specified resource
file using the -x command line switch.
qqssaavvee__pprrooggrraamm((_+_F_i_l_e_, _+_O_p_t_i_o_n_s))
Saves the current state of the program to the file _F_i_l_e. The
result is a resource archive containing a saved state that
expresses all Prolog data from the running program and all
user-defined resources. Depending on the stand_alone option, the
resource is headed by the emulator, a Unix shell script or nothing.
_O_p_t_i_o_n_s is a list of additional options:
llooccaall((_+_K_B_y_t_e_s))
Limit for the local stack. See section 2.4.3.
gglloobbaall((_+_K_B_y_t_e_s))
Limit for the global stack. See section 2.4.3.
ttrraaiill((_+_K_B_y_t_e_s))
Limit for the trail stack. See section 2.4.3.
ggooaall((_:_C_a_l_l_a_b_l_e))
Initialization goal for the new executable (see -g).
ttoopplleevveell((_:_C_a_l_l_a_b_l_e))
Top-level goal for the new executable (see -t).
iinniitt__ffiillee((_+_A_t_o_m))
Default initialization file for the new executable. See -f.
ccllaassss((_+_C_l_a_s_s))
If runtime, only read resources from the state (default).
If kernel, lock all predicates as system predicates. If
development, save the predicates in their current state and
keep reading resources from their source (if present). See
also resource/3.
aauuttoollooaadd((_+_B_o_o_l_e_a_n))
If true (default), run autoload/0 first.
mmaapp((_+_F_i_l_e))
Dump a human-readable trace of what has been saved in _F_i_l_e.
oopp((_+_A_c_t_i_o_n))
One of save (default) to save the current operator table or
standard to use the initial table of the emulator.
ssttaanndd__aalloonnee((_+_B_o_o_l_e_a_n))
If true, the emulator is the first part of the state. If
the emulator is started it will test whether a boot file
(state) is attached to the emulator itself and load this
state. Provided the application has all libraries loaded,
the resulting executable is completely independent of the
runtime environment or location where it was built. See also
section 2.10.2.4.
eemmuullaattoorr((_+_F_i_l_e))
File to use for the emulator. Default is the running Prolog
image.
ffoorreeiiggnn((_+_A_c_t_i_o_n))
If save, include shared objects (DLLs) into the saved state.
See current_foreign_library/2. If the program strip is
available, this is first used to reduce the size of the shared
object. If a state is started, use_foreign_library/1 first
tries to locate the foreign resource in the executable. When
found it copies the content of the resource to a temporary
file and loads it. If possible (Unix), the temporary object
is deleted immediately after opening.
qqssaavvee__pprrooggrraamm((_+_F_i_l_e))
Equivalent to qsave_program(File, []).
aauuttoollooaadd
Check the current Prolog program for predicates that are referred
to, are undefined and have a definition in the Prolog library.
Load the appropriate libraries.
This predicate is used by qsave_program/[1,2] to ensure the saved
state does not depend on availability of the libraries. The
predicate autoload/0 examines all clauses of the loaded program
(obtained with clause/2) and analyzes the body for referenced
goals. Such an analysis cannot be complete in Prolog, which allows
for the creation of arbitrary terms at runtime and the use of them
as a goal. The current analysis is limited to the following:
o Direct goals appearing in the body
o Arguments of declared meta-predicates that are marked with an
integer (0..9). See meta_predicate/1.
The analysis of meta-predicate arguments is limited to cases where
the argument appears literally in the clause or is assigned using
=/2 before the meta-call. That is, the following fragment is
processed correctly:
____________________________________________________________________| |
| ..., |
| Goal = prove(Theory), |
| forall(current_theory(Theory), |
||_______________Goal)),____________________________________________ ||
But, the calls to prove_simple/1 and prove_complex/1 in the example
below are _n_o_t discovered by the analysis and therefore the modules
that define these predicates must be loaded explicitly using
use_module/1,2.
____________________________________________________________________| |
| ..., |
| member(Goal, [ prove_simple(Theory), |
| prove_complex(Theory) |
| ]), |
| forall(current_theory(Theory), |
||_______________Goal)),____________________________________________ ||
It is good practice to use gxref/0 to make sure that the program
has sufficient declarations such that the analaysis tools can
verify that all required predicates can be resolved and that all
code is called. See meta_predicate/1, dynamic/1, public/1 and
prolog:called_by/2.
vvoollaattiillee _+_N_a_m_e_/_A_r_i_t_y_, _._._.
Declare that the clauses of specified predicates should nnoott be
saved to the program. The volatile declaration is normally used to
prevent the clauses of dynamic predicates that represent data for
the current session from being saved in the state file.
1100..11 LLiimmiittaattiioonnss ooff qqssaavvee__pprrooggrraamm
There are three areas that require special attention when using
qsave_program/[1,2].
o If the program is an embedded Prolog application or uses the
foreign language interface, care has to be taken to restore the
appropriate foreign context. See section 10.2 for details.
o If the program uses directives (:- goal. lines) that perform other
actions than setting predicate attributes (dynamic, volatile, etc.)
or loading files (consult, etc.), the directive may need to be
prefixed with initialization/1.
o Database references as returned by clause/3, recorded/3, etc., are
not preserved and may thus not be part of the database when saved.
1100..22 RRuunnttiimmeess aanndd FFoorreeiiggnn CCooddee
Some applications may need to use the foreign language interface.
Object code is by definition machine-dependent and thus cannot be part
of the saved program file.
To complicate the matter even further there are various ways of loading
foreign code:
o _U_s_i_n_g _t_h_e _l_i_b_r_a_r_y_(_s_h_l_i_b_) _p_r_e_d_i_c_a_t_e_s
This is the preferred way of dealing with foreign code. It loads
quickly and ensures an acceptable level of independence between the
versions of the emulator and the foreign code loaded. It works on
Unix machines supporting shared libraries and library functions to
load them. Most modern Unixes, as well as Win32 (Windows 95/NT),
satisfy this constraint.
o _S_t_a_t_i_c _l_i_n_k_i_n_g
This mechanism works on all machines, but generally requires the
same C compiler and linker to be used for the external code as is
used to build SWI-Prolog itself.
To make a runtime executable that can run on multiple platforms one
must make runtime checks to find the correct way of linking. Suppose
we have a source file myextension.c defining the installation function
install().
If this file is compiled into a shared library, load_foreign_library/1
will load this library and call the installation function to initialise
the foreign code. If it is loaded as a static extension, define
install() as the predicate install/0:
________________________________________________________________________| |
|static foreign_t |
|pl_install() |
|{ install(); |
| |
| PL_succeed; |
|} |
| |
|PL_extension PL_extensions [] = |
|{ |
|/*{ "name", arity, function, PL_FA_<flags> },*/ |
| |
| { "install", 0, pl_install, 0 }, |
| { NULL, 0, NULL, 0 } /* terminating line */ |
|};|____________________________________________________________________ | |
Now, use the following Prolog code to load the foreign library:
________________________________________________________________________| |
|load_foreign_extensions :- |
| current_predicate(install, install), !, % static loaded |
| install. |
|load_foreign_extensions :- % shared library |
| load_foreign_library(foreign(myextension)). |
| |
|:-|initialization_load_foreign_extensions._____________________________ | |
The path alias foreign is defined by file_search_path/2. By default
it searches the directories <_h_o_m_e>/lib/<_a_r_c_h> and <_h_o_m_e>/lib. The
application can specify additional rules for file_search_path/2.
1100..33 UUssiinngg pprrooggrraamm rreessoouurrcceess
A _r_e_s_o_u_r_c_e is very similar to a file. Resources, however, can be
represented in two different formats: on files, as well as part of the
resource _a_r_c_h_i_v_e of a saved state (see qsave_program/2).
A resource has a _n_a_m_e and a _c_l_a_s_s. The _s_o_u_r_c_e data of the resource is
a file. Resources are declared by declaring the predicate resource/3.
They are accessed using the predicate open_resource/3.
Before going into details, let us start with an example. Short
texts can easily be expressed in Prolog source code, but long texts
are cumbersome. Assume our application defines a command `help' that
prints a helptext to the screen. We put the content of the helptext
into a file called help.txt. The following code implements our help
command such that help.txt is incorporated into the runtime executable.
________________________________________________________________________| |
|resource(help, text, 'help.txt'). |
| |
|help :- |
| open_resource(help, text, In), |
| call_cleanup(copy_stream_data(In, user_output), |
||____________________close(In))._______________________________________ ||
The predicate help/0 opens the resource as a Prolog stream. If we
are executing this from the development environment, this will actually
return a stream to the file help.txt itself. When executed from the
saved state, the stream will actually be a stream opened on the program
resource file, taking care of the offset and length of the resource.
1100..33..11 RReessoouurrccee mmaanniippuullaattiioonn pprreeddiiccaatteess
rreessoouurrccee((_+_N_a_m_e_, _+_C_l_a_s_s_, _+_F_i_l_e_S_p_e_c))
This predicate is defined as a dynamic predicate in the module
user. Clauses for it may be defined in any module, including
the user module. _N_a_m_e is the name of the resource (an atom).
A resource name may contain any character, except for $ and :,
which are reserved for internal usage by the resource library.
_C_l_a_s_s describes the kind of object stored in the resource. In
the current implementation, it is just an atom. _F_i_l_e_S_p_e_c is
a file specification that may exploit file_search_path/2 (see
absolute_file_name/2).
Normally, resources are defined as unit clauses (facts), but the
definition of this predicate also allows for rules. For proper
generation of the saved state, it must be possible to enumerate
the available resources by calling this predicate with all its
arguments unbound.
Dynamic rules are useful to turn all files in a certain directory
into resources, without specifying a resource for each file. For
example, assume the file_search_path/2icons refers to the resource
directory containing icon files. The following definition makes
all these images available as resources:
____________________________________________________________________| |
| resource(Name, image, icons(XpmName)) :- |
| atom(Name), !, |
| file_name_extension(Name, xpm, XpmName). |
| resource(Name, image, XpmFile) :- |
| var(Name), |
| absolute_file_name(icons(.), [type(directory)], Dir) |
| concat(Dir, '/*.xpm', Pattern), |
| expand_file_name(Pattern, XpmFiles), |
||________member(XpmFile,_XpmFiles).________________________________ ||
ooppeenn__rreessoouurrccee((_+_N_a_m_e_, _?_C_l_a_s_s_, _-_S_t_r_e_a_m))
Opens the resource specified by _N_a_m_e and _C_l_a_s_s. If the latter is a
variable, it will be unified to the class of the first resource
found that has the specified _N_a_m_e. If successful, _S_t_r_e_a_m becomes a
handle to a binary input stream, providing access to the content of
the resource.
The predicate open_resource/3 first checks resource/3. When
successful it will open the returned resource source file.
Otherwise it will look in the program's resource database. When
creating a saved state, the system normally saves the resource
contents into the resource archive, but does not save the resource
clauses.
This way, the development environment uses the files (and
modifications) to the resource/3 declarations and/or files
containing resource info, thus immediately affecting the running
environment, while the runtime system quickly accesses the system
resources.
1100..33..22 TThhee swipl-rc pprrooggrraamm
The utility program swipl-rc can be used to examine and manipulate the
contents of a SWI-Prolog resource file. The options are inspired by
the Unix ar program. The basic command is:
________________________________________________________________________| |
|%|swipl-rc_option_resource-file_member_..._____________________________ | |
The options are described below.
l
List contents of the archive.
x
Extract named (or all) members of the archive into the current
directory.
a
Add files to the archive. If the archive already contains a
member with the same name, the contents are replaced. Anywhere
in the sequence of members, the options --class=_c_l_a_s_s and
--encoding=_e_n_c_o_d_i_n_g may appear. They affect the class and encoding
of subsequent files. The initial class is data and encoding none.
d
Delete named members from the archive.
This command is also described in the pl(1) Unix manual page.
1100..44 FFiinnddiinngg AApppplliiccaattiioonn ffiilleess
If your application uses files that are not part of the saved program
such as database files, configuration files, etc., the runtime version
has to be able to locate these files. The file_search_path/2 mechanism
in combination with the -palias command line argument is the preferred
way to locate runtime files. The first step is to define an alias
for the top-level directory of your application. We will call this
directory gnatdir in our examples.
A good place for storing data associated with SWI-Prolog runtime
systems is below the emulator's home directory. swi is a predefined
alias for this directory. The following is a useful default definition
for the search path.
________________________________________________________________________| |
|user:file_search_path(gnatdir,|swi(gnat))._____________________________ | |
The application should locate all files using absolute_file_name.
Suppose gnatdir contains a file config.pl to define the local
configuration. Then use the code below to load this file:
________________________________________________________________________| |
|configure_gnat :- |
| ( absolute_file_name(gnatdir('config.pl'), ConfigFile) |
| -> consult(ConfigFile) |
| ; format(user_error, 'gnat: Cannot locate config.pl~n'), |
| halt(1) |
||__).__________________________________________________________________ ||
1100..44..11 SSppeecciiffyyiinngg aa ffiillee sseeaarrcchh ppaatthh ffrroomm tthhee ccoommmmaanndd lliinnee
Suppose the system administrator has installed the SWI-Prolog
runtime environment in /usr/local/lib/rt-pl-3.2.0. A user wants
to install gnat, but gnat will look for its configuration in
/usr/local/lib/rt-pl-3.2.0/gnat where the user cannot write.
The user decides to install the gnat runtime files in /users/bob/lib/
gnat. For one-time usage, the user may decide to start gnat using the
command:
________________________________________________________________________| |
|%|gnat_-p_gnatdir=/users/bob/lib/gnat__________________________________ | |
CChhaapptteerr 1111.. TTHHEE SSWWII--PPRROOLLOOGG LLIIBBRRAARRYY
This chapter documents the SWI-Prolog library. As SWI-Prolog provides
auto-loading, there is little difference between library predicates
and built-in predicates. Part of the library is therefore documented
in the rest of the manual. Library predicates differ from built-in
predicates in the following ways:
o User definition of a built-in leads to a permission error, while
using the name of a library predicate is allowed.
o If autoloading is disabled explicitly or because trapping unknown
predicates is disabled (see unknown/2 and current_prolog_flag/2),
library predicates must be loaded explicitly.
o Using libraries reduces the footprint of applications that don't
need them.
_T_h_e _d_o_c_u_m_e_n_t_a_t_i_o_n _o_f _t_h_e _l_i_b_r_a_r_y _h_a_s _j_u_s_t _s_t_a_r_t_e_d_. _M_a_t_e_r_i_a_l
_f_r_o_m _t_h_e _s_t_a_n_d_a_r_d _p_a_c_k_a_g_e_s _s_h_o_u_l_d _b_e _m_o_v_e_d _h_e_r_e_, _s_o_m_e _m_a_t_e_r_i_a_l
_f_r_o_m _o_t_h_e_r _p_a_r_t_s _o_f _t_h_e _m_a_n_u_a_l _s_h_o_u_l_d _b_e _m_o_v_e_d _t_o_o _a_n_d _v_a_r_i_o_u_s
_l_i_b_r_a_r_i_e_s _a_r_e _n_o_t _d_o_c_u_m_e_n_t_e_d _a_t _a_l_l_.
1111..11 lliibbrraarryy((aaggggrreeggaattee)):: AAggggrreeggaattiioonn ooppeerraattoorrss oonn bbaacckkttrraacckkaabbllee
pprreeddiiccaatteess
CCoommppaattiibbiilliittyy Quintus, SICStus 4. The forall/2 is a
SWI-Prolog built-in and term_variables/3 is a SWI-Prolog
with a ddiiffffeerreenntt ddeeffiinniittiioonn.
TToo bbee ddoonnee
- Analysing the aggregation template and compiling a
predicate for the list aggregation can be done at compile
time.
- aggregate_all/3 can be rewritten to run in constant
space using non-backtrackable assignment on a term.
This library provides aggregating operators over the solutions of a
predicate. The operations are a generalisation of the bagof/3, setof/3
and findall/3 built-in predicates. The defined aggregation operations
are counting, computing the sum, minimum, maximum, a bag of solutions
and a set of solutions. We first give a simple example, computing the
country with the smallest area:
________________________________________________________________________| |
|smallest_country(Name, Area) :- |
||_______aggregate(min(A,_N),_country(N,_A),_min(Area,_Name)).__________ ||
There are four aggregation predicates (aggregate/3, aggregate/4,
aggregate_all/3 and aggregate/4), distinguished on two properties.
aaggggrreeggaattee vvss.. aaggggrreeggaattee__aallll The aggregate predicates use setof/3
(aggregate/4) or bagof/3 (aggregate/3), dealing with existential
qualified variables (Var^Goal) and providing multiple solutions
for the remaining free variables in Goal. The aggregate_all/3
predicate uses findall/3, implicitly qualifying all free variables
and providing exactly one solution, while aggregate_all/4 uses
sort/2 over solutions that Discriminator (see below) generated
using findall/3.
TThhee DDiissccrriimmiinnaattoorr aarrgguummeenntt The versions with 4 arguments provide a
Discriminator argument that allows for keeping duplicate bindings
of a variable in the result. For example, if we wish to compute
the total population of all countries, we do not want to lose
results because two countries have the same population. Therefore
we use:
____________________________________________________________________| |
||____aggregate(sum(P),_Name,_country(Name,_P),_Total)______________ ||
All aggregation predicates support the following operators below in
Template. In addition, they allow for an arbitrary named compound
term, where each of the arguments is a term from the list below.
For example, the term r(min(X), max(X)) computes both the minimum and
maximum binding for X.
ccoouunntt
Count number of solutions. Same as sum(1).
ssuumm((_E_x_p_r))
Sum of _E_x_p_r for all solutions.
mmiinn((_E_x_p_r))
Minimum of _E_x_p_r for all solutions.
mmiinn((_E_x_p_r_, _W_i_t_n_e_s_s))
A term min(Min, Witness), where Min is the minimal version of _E_x_p_r
over all solutions, and _W_i_t_n_e_s_s is any other template applied to
solutions that produced Min. If multiple solutions provide the
same minimum, _W_i_t_n_e_s_s corresponds to the first solution.
mmaaxx((_E_x_p_r))
Maximum of _E_x_p_r for all solutions.
mmaaxx((_E_x_p_r_, _W_i_t_n_e_s_s))
As min(Expr, Witness), but producing the maximum result.
sseett((_X))
An ordered set with all solutions for _X.
bbaagg((_X))
A list of all solutions for _X.
AAcckknnoowwlleeddggeemmeennttss
_T_h_e _d_e_v_e_l_o_p_m_e_n_t _o_f _t_h_i_s _l_i_b_r_a_r_y _w_a_s _s_p_o_n_s_o_r_e_d _b_y _S_e_c_u_r_i_t_E_a_s_e_,
http://www.securitease.com
aaggggrreeggaattee((_+_T_e_m_p_l_a_t_e_, _:_G_o_a_l_, _-_R_e_s_u_l_t)) _[_n_o_n_d_e_t_]
Aggregate bindings in _G_o_a_l according to _T_e_m_p_l_a_t_e. The aggregate/3
version performs bagof/3 on _G_o_a_l.
aaggggrreeggaattee((_+_T_e_m_p_l_a_t_e_, _+_D_i_s_c_r_i_m_i_n_a_t_o_r_, _:_G_o_a_l_, _-_R_e_s_u_l_t)) _[_n_o_n_d_e_t_]
Aggregate bindings in _G_o_a_l according to _T_e_m_p_l_a_t_e. The aggregate/4
version performs setof/3 on _G_o_a_l.
aaggggrreeggaattee__aallll((_+_T_e_m_p_l_a_t_e_, _:_G_o_a_l_, _-_R_e_s_u_l_t)) _[_s_e_m_i_d_e_t_]
Aggregate bindings in _G_o_a_l according to _T_e_m_p_l_a_t_e. The
aggregate_all/3 version performs findall/3 on _G_o_a_l.
aaggggrreeggaattee__aallll((_+_T_e_m_p_l_a_t_e_, _+_D_i_s_c_r_i_m_i_n_a_t_o_r_, _:_G_o_a_l_, _-_R_e_s_u_l_t)) _[_s_e_m_i_d_e_t_]
Aggregate bindings in _G_o_a_l according to _T_e_m_p_l_a_t_e. The
aggregate_all/4 version performs findall/3 followed by sort/2 on
_G_o_a_l.
ffoorreeaacchh((_:_G_e_n_e_r_a_t_o_r_, _:_G_o_a_l))
True if conjunction of results is true. Unlike forall/2, which
runs a failure-driven loop that proves _G_o_a_l for each solution of
_G_e_n_e_r_a_t_o_r, foreach/2 creates a conjunction. Each member of the
conjunction is a copy of _G_o_a_l, where the variables it shares
with _G_e_n_e_r_a_t_o_r are filled with the values from the corresponding
solution.
The implementation executes forall/2 if _G_o_a_l does not contain any
variables that are not shared with _G_e_n_e_r_a_t_o_r.
Here is an example:
____________________________________________________________________| |
| ?- foreach(between(1,4,X), dif(X,Y)), Y = 5. |
| Y = 5. |
| ?- foreach(between(1,4,X), dif(X,Y)), Y = 3. |
||false.____________________________________________________________ ||
bbuugg _G_o_a_l is copied repeatedly, which may cause problems
if attributed variables are involved.
ffrreeee__vvaarriiaabblleess((_:_G_e_n_e_r_a_t_o_r_, _+_T_e_m_p_l_a_t_e_, _+_V_a_r_L_i_s_t_0_, _-_V_a_r_L_i_s_t)) _[_d_e_t_]
Find free variables in bagof/setof template. In order to handle
variables properly, we have to find all the universally quantified
variables in the _G_e_n_e_r_a_t_o_r. All variables as yet unbound are
universally quantified, unless
1. they occur in the template
2. they are bound by X^P, setof/3, or bagof/3
free_variables(Generator, Template, OldList, NewList) finds this
set using OldList as an accumulator.
aauutthhoorr
- Richard O'Keefe
- Jan Wielemaker (made some SWI-Prolog enhancements)
lliicceennssee Public domain (from DEC10 library).
TToo bbee ddoonnee
- Distinguish between control-structures and data
terms.
- Exploit our built-in term_variables/2 at some
places?
ssaannddbbooxx::ssaaffee__mmeettaa((_+_G_o_a_l_, _-_C_a_l_l_e_d)) _[_s_e_m_i_d_e_t_,_m_u_l_t_i_f_i_l_e_]
Declare the aggregate meta-calls safe. This cannot be proven due
to the manipulations of the argument _G_o_a_l.
1111..22 lliibbrraarryy((aappppllyy)):: AAppppllyy pprreeddiiccaatteess oonn aa lliisstt
SSeeee aallssoo
- apply_macros.pl provides compile-time expansion for part
of this library.
- http://www.cs.otago.ac.nz/staffpriv/ok/pllib.htm
TToo bbee ddoonnee Add include/4, include/5, exclude/4, exclude/5
This module defines meta-predicates that apply a predicate on all
members of a list.
iinncclluuddee((_:_G_o_a_l_, _+_L_i_s_t_1_, _?_L_i_s_t_2)) _[_d_e_t_]
Filter elements for which _G_o_a_l succeeds. True if _L_i_s_t_2 contains
those elements Xi of _L_i_s_t_1 for which call(Goal, Xi) succeeds.
SSeeee aallssoo Older versions of SWI-Prolog had sublist/3 with
the same arguments and semantics.
eexxcclluuddee((_:_G_o_a_l_, _+_L_i_s_t_1_, _?_L_i_s_t_2)) _[_d_e_t_]
Filter elements for which _G_o_a_l fails. True if _L_i_s_t_2 contains those
elements Xi of _L_i_s_t_1 for which call(Goal, Xi) fails.
ppaarrttiittiioonn((_:_P_r_e_d_, _+_L_i_s_t_, _?_I_n_c_l_u_d_e_d_, _?_E_x_c_l_u_d_e_d)) _[_d_e_t_]
Filter elements of _L_i_s_t according to _P_r_e_d. True if _I_n_c_l_u_d_e_d
contains all elements for which call(Pred, X) succeeds and _E_x_c_l_u_d_e_d
contains the remaining elements.
ppaarrttiittiioonn((_:_P_r_e_d_, _+_L_i_s_t_, _?_L_e_s_s_, _?_E_q_u_a_l_, _?_G_r_e_a_t_e_r)) _[_s_e_m_i_d_e_t_]
Filter _L_i_s_t according to _P_r_e_d in three sets. For each element Xi
of _L_i_s_t, its destination is determined by call(Pred, Xi, Place),
where Place must be unified to one of <, = or >. _P_r_e_d must be
deterministic.
mmaapplliisstt((_:_G_o_a_l_, _?_L_i_s_t))
True if _G_o_a_l can successfully be applied on all elements of _L_i_s_t.
Arguments are reordered to gain performance as well as to make the
predicate deterministic under normal circumstances.
mmaapplliisstt((_:_G_o_a_l_, _?_L_i_s_t_1_, _?_L_i_s_t_2))
As maplist/2, operating on pairs of elements from two lists.
mmaapplliisstt((_:_G_o_a_l_, _?_L_i_s_t_1_, _?_L_i_s_t_2_, _?_L_i_s_t_3))
As maplist/2, operating on triples of elements from three lists.
mmaapplliisstt((_:_G_o_a_l_, _?_L_i_s_t_1_, _?_L_i_s_t_2_, _?_L_i_s_t_3_, _?_L_i_s_t_4))
As maplist/2, operating on quadruples of elements from four lists.
ffoollddll((_:_G_o_a_l_, _+_L_i_s_t_, _+_V_0_, _-_V))
ffoollddll((_:_G_o_a_l_, _+_L_i_s_t_1_, _+_L_i_s_t_2_, _+_V_0_, _-_V))
ffoollddll((_:_G_o_a_l_, _+_L_i_s_t_1_, _+_L_i_s_t_2_, _+_L_i_s_t_3_, _+_V_0_, _-_V))
ffoollddll((_:_G_o_a_l_, _+_L_i_s_t_1_, _+_L_i_s_t_2_, _+_L_i_s_t_3_, _+_L_i_s_t_4_, _+_V_0_, _-_V))
Fold a list, using arguments of the list as left argument. The
foldl family of predicates is defined by:
____________________________________________________________________| |
| foldl(P, [X11,...,X1n], ..., [Xm1,...,Xmn], V0, Vn) :- |
| P(X11, ..., Xm1, V0, V1), |
| ... |
||______P(X1n,_...,_Xmn,_V',_Vn).___________________________________ ||
ssccaannll((_:_G_o_a_l_, _+_L_i_s_t_, _+_V_0_, _-_V_a_l_u_e_s))
ssccaannll((_:_G_o_a_l_, _+_L_i_s_t_1_, _+_L_i_s_t_2_, _+_V_0_, _-_V_a_l_u_e_s))
ssccaannll((_:_G_o_a_l_, _+_L_i_s_t_1_, _+_L_i_s_t_2_, _+_L_i_s_t_3_, _+_V_0_, _-_V_a_l_u_e_s))
ssccaannll((_:_G_o_a_l_, _+_L_i_s_t_1_, _+_L_i_s_t_2_, _+_L_i_s_t_3_, _+_L_i_s_t_4_, _+_V_0_, _-_V_a_l_u_e_s))
Left scan of list. The scanl family of higher order list
operations is defined by:
____________________________________________________________________| |
| scanl(P, [X11,...,X1n], ..., [Xm1,...,Xmn], V0, |
| [V0,V1,...,Vn]) :- |
| P(X11, ..., Xmn, V0, V1), |
| ... |
||______P(X1n,_...,_Xmn,_V',_Vn).___________________________________ ||
1111..33 lliibbrraarryy((aassssoocc)):: AAssssoocciiaattiioonn lliissttss
Authors: _R_i_c_h_a_r_d _A_. _O_'_K_e_e_f_e_, _L_._D_a_m_a_s_, _V_._S_._C_o_s_t_a _a_n_d _M_a_r_k_u_s _T_r_i_s_k_a
Elements of an association list have 2 components: A (unique) _k_e_y and
a _v_a_l_u_e. Keys should be ground, values need not be. An association
list can be used to fetch elements via their keys and to enumerate its
elements in ascending order of their keys. The assoc module uses AVL
trees to implement association lists. This makes inserting, changing
and fetching a single element an O(log(N)) (where N denotes the number
of elements in the list) expected time (and worst-case time) operation.
aassssoocc__ttoo__lliisstt((_+_A_s_s_o_c_, _-_L_i_s_t))
_L_i_s_t is a list of Key-Value pairs corresponding to the associations
in _A_s_s_o_c in ascending order of keys.
aassssoocc__ttoo__kkeeyyss((_+_A_s_s_o_c_, _-_L_i_s_t))
_L_i_s_t is a list of Keys corresponding to the associations in _A_s_s_o_c
in ascending order.
aassssoocc__ttoo__vvaalluueess((_+_A_s_s_o_c_, _-_L_i_s_t))
_L_i_s_t is a list of Values corresponding to the associations in _A_s_s_o_c
in ascending order of the keys they are associated to.
eemmppttyy__aassssoocc((_-_A_s_s_o_c))
_A_s_s_o_c is unified with an empty association list.
ggeenn__aassssoocc((_?_K_e_y_, _+_A_s_s_o_c_, _?_V_a_l_u_e))
Enumerate matching elements of _A_s_s_o_c in ascending order of their
keys via backtracking.
ggeett__aassssoocc((_+_K_e_y_, _+_A_s_s_o_c_, _?_V_a_l_u_e))
_V_a_l_u_e is the value associated with _K_e_y in the association list
_A_s_s_o_c.
ggeett__aassssoocc((_+_K_e_y_, _+_A_s_s_o_c_, _?_O_l_d_, _?_N_e_w_A_s_s_o_c_, _?_N_e_w))
_N_e_w_A_s_s_o_c is an association list identical to _A_s_s_o_c except that the
value associated with _K_e_y is _N_e_w instead of _O_l_d.
lliisstt__ttoo__aassssoocc((_+_L_i_s_t_, _-_A_s_s_o_c))
_A_s_s_o_c is an association list corresponding to the Key-Value pairs
in _L_i_s_t. _L_i_s_t must not contain duplicate keys.
mmaapp__aassssoocc((_:_G_o_a_l_, _+_A_s_s_o_c))
_G_o_a_l_(_V_) is true for every value V in _A_s_s_o_c.
mmaapp__aassssoocc((_:_G_o_a_l_, _+_A_s_s_o_c_I_n_, _?_A_s_s_o_c_O_u_t))
_A_s_s_o_c_O_u_t is _A_s_s_o_c_I_n with _G_o_a_l applied to all corresponding pairs of
values.
mmaaxx__aassssoocc((_+_A_s_s_o_c_, _?_K_e_y_, _?_V_a_l_u_e))
_K_e_y and _V_a_l_u_e are key and value of the element with the largest key
in _A_s_s_o_c.
mmiinn__aassssoocc((_+_A_s_s_o_c_, _?_K_e_y_, _?_V_a_l_u_e))
_K_e_y and _V_a_l_u_e are key and value of the element with the smallest
key in _A_s_s_o_c.
oorrdd__lliisstt__ttoo__aassssoocc((_+_L_i_s_t_, _-_A_s_s_o_c))
_A_s_s_o_c is an association list correspond to the Key-Value pairs in
_L_i_s_t, which must occur in strictly ascending order of their keys.
ppuutt__aassssoocc((_+_K_e_y_, _+_A_s_s_o_c_, _+_V_a_l_u_e_, _?_N_e_w_A_s_s_o_c))
_N_e_w_A_s_s_o_c is an association list identical to _A_s_s_o_c except that _K_e_y
is associated with _V_a_l_u_e. This can be used to insert and change
associations.
iiss__aassssoocc((_+_A_s_s_o_c))
True if Assoc is a valid association list. This predicate verifies
the validity of each node in the AVL tree.
1111..44 lliibbrraarryy((bbrrooaaddccaasstt)):: BBrrooaaddccaasstt aanndd rreecceeiivvee eevveenntt nnoottiiffiiccaattiioonnss
The broadcast library was invented to realise GUI applications
consisting of stand-alone components that use the Prolog database for
storing the application data. Figure ???? illustrates the flow of
information using this design
The broadcasting service provides two services. Using the `shout'
service, an unknown number of agents may listen to the message and act.
The broadcaster is not (directly) aware of the implications. Using the
`request' service, listening agents are asked for an answer one-by-one
and the broadcaster is allowed to reject answers using normal Prolog
failure.
Shouting is often used to inform about changes made to a common
database. Other messages can be ``save yourself'' or ``show this''.
Requesting is used to get information while the broadcaster is not
aware who might be able to answer the question. For example ``who is
showing X?''.
bbrrooaaddccaasstt((_+_T_e_r_m))
Broadcast _T_e_r_m. There are no limitations to _T_e_r_m, though being
a global service, it is good practice to use a descriptive and
unique principal functor. All associated goals are started
and regardless of their success or failure, broadcast/1 always
succeeds. Exceptions are passed.
bbrrooaaddccaasstt__rreeqquueesstt((_+_T_e_r_m))
Unlike broadcast/1, this predicate stops if an associated goal
succeeds. Backtracking causes it to try other listeners. A
broadcast request is used to fetch information without knowing the
identity of the agent providing it. C.f. ``Is there someone who
knows the age of John?'' could be asked using
____________________________________________________________________| |
| ..., |
||________broadcast_request(age_of('John',_Age)),___________________ ||
If there is an agent (_l_i_s_t_e_n_e_r) that registered an `age-of' service
and knows about the age of `John' this question will be answered.
lliisstteenn((_+_T_e_m_p_l_a_t_e_, _:_G_o_a_l))
Register a _l_i_s_t_e_n channel. Whenever a term unifying _T_e_m_p_l_a_t_e
is broadcasted, call _G_o_a_l. The following example traps all
broadcasted messages as a variable unifies to any message. It is
commonly used to debug usage of the library.
____________________________________________________________________| |
| ?- listen(Term, (writeln(Term),fail)). |
| ?- broadcast(hello(world)). |
| hello(world) |
||true._____________________________________________________________ ||
lliisstteenn((_+_L_i_s_t_e_n_e_r_, _+_T_e_m_p_l_a_t_e_, _:_G_o_a_l))
Declare _L_i_s_t_e_n_e_r as the owner of the channel. Unlike a channel
opened using listen/2, channels that have an owner can terminate
the channel. This is commonly used if an object is listening to
broadcast messages. In the example below we define a `name-item'
displaying the name of an identifier represented by the predicate
name_of/2.
____________________________________________________________________| |
| :- pce_begin_class(name_item, text_item). |
| |
| variable(id, any, get, "Id visualised"). |
| |
| initialise(NI, Id:any) :-> |
| name_of(Id, Name), |
| send_super(NI, initialise, name, Name, |
| message(NI, set_name, @arg1)), |
| send(NI, slot, id, Id), |
| listen(NI, name_of(Id, Name), |
| send(NI, selection, Name)). |
| |
| unlink(NI) :-> |
| unlisten(NI), |
| send_super(NI, unlink). |
| |
| set_name(NI, Name:name) :-> |
| get(NI, id, Id), |
| retractall(name_of(Id, _)), |
| assert(name_of(Id, Name)), |
| broadcast(name_of(Id, Name)). |
| |
||:-_pce_end_class._________________________________________________ ||
uunnlliisstteenn((_+_L_i_s_t_e_n_e_r))
Deregister all entries created with listen/3 whose _L_i_s_t_e_n_e_r unify.
uunnlliisstteenn((_+_L_i_s_t_e_n_e_r_, _+_T_e_m_p_l_a_t_e))
Deregister all entries created with listen/3 whose _L_i_s_t_e_n_e_r and
_T_e_m_p_l_a_t_e unify.
uunnlliisstteenn((_+_L_i_s_t_e_n_e_r_, _+_T_e_m_p_l_a_t_e_, _:_G_o_a_l))
Deregister all entries created with listen/3 whose _L_i_s_t_e_n_e_r,
_T_e_m_p_l_a_t_e and _G_o_a_l unify.
lliisstteenniinngg((_?_L_i_s_t_e_n_e_r_, _?_T_e_m_p_l_a_t_e_, _?_G_o_a_l))
Examine the current listeners. This predicate is useful for
debugging purposes.
1111..55 lliibbrraarryy((cchhaarrssiioo)):: II//OO oonn LLiissttss ooff CChhaarraacctteerr CCooddeess
CCoommppaattiibbiilliittyy The naming of this library is not in line
with the ISO standard. We believe that the SWI-Prolog
native predicates form a more elegant alternative for this
library.
This module emulates the Quintus/SICStus library charsio.pl for reading
and writing from/to lists of character codes. Most of these predicates
are straight calls into similar SWI-Prolog primitives. Some can even
be replaced by ISO standard predicates.
ffoorrmmaatt__ttoo__cchhaarrss((_+_F_o_r_m_a_t_, _+_A_r_g_s_, _-_C_o_d_e_s)) _[_d_e_t_]
Use format/2 to write to a list of character codes.
ffoorrmmaatt__ttoo__cchhaarrss((_+_F_o_r_m_a_t_, _+_A_r_g_s_, _-_C_o_d_e_s_, _?_T_a_i_l)) _[_d_e_t_]
Use format/2 to write to a difference list of character codes.
wwrriittee__ttoo__cchhaarrss((_+_T_e_r_m_, _-_C_o_d_e_s))
Write a term to a code list. True when _C_o_d_e_s is a list of
character codes written by write/1 on _T_e_r_m.
wwrriittee__ttoo__cchhaarrss((_+_T_e_r_m_, _-_C_o_d_e_s_, _?_T_a_i_l))
Write a term to a code list. _C_o_d_e_s\_T_a_i_l is a difference list of
character codes produced by write/1 on _T_e_r_m.
aattoomm__ttoo__cchhaarrss((_+_A_t_o_m_, _-_C_o_d_e_s)) _[_d_e_t_]
Convert _A_t_o_m into a list of character codes.
ddeepprreeccaatteedd Use ISO atom_codes/2.
aattoomm__ttoo__cchhaarrss((_+_A_t_o_m_, _-_C_o_d_e_s_, _?_T_a_i_l)) _[_d_e_t_]
Convert _A_t_o_m into a difference list of character codes.
nnuummbbeerr__ttoo__cchhaarrss((_+_N_u_m_b_e_r_, _-_C_o_d_e_s)) _[_d_e_t_]
Convert Atom into a list of character codes.
ddeepprreeccaatteedd Use ISO number_codes/2.
nnuummbbeerr__ttoo__cchhaarrss((_+_N_u_m_b_e_r_, _-_C_o_d_e_s_, _?_T_a_i_l)) _[_d_e_t_]
Convert _N_u_m_b_e_r into a difference list of character codes.
rreeaadd__ffrroomm__cchhaarrss((_+_C_o_d_e_s_, _-_T_e_r_m)) _[_d_e_t_]
Read _C_o_d_e_s into _T_e_r_m.
CCoommppaattiibbiilliittyy The SWI-Prolog version does not require
_C_o_d_e_s to end in a full-stop.
rreeaadd__tteerrmm__ffrroomm__cchhaarrss((_+_C_o_d_e_s_, _-_T_e_r_m_, _+_O_p_t_i_o_n_s)) _[_d_e_t_]
Read _C_o_d_e_s into _T_e_r_m. _O_p_t_i_o_n_s are processed by read_term/3.
CCoommppaattiibbiilliittyy sicstus
ooppeenn__cchhaarrss__ssttrreeaamm((_+_C_o_d_e_s_, _-_S_t_r_e_a_m)) _[_d_e_t_]
Open _C_o_d_e_s as an input stream.
bbuugg Depends on autoloading library(memfile). As many
applications do not need this predicate we do
not want to make the entire library dependent on
autoloading.
wwiitthh__oouuttppuutt__ttoo__cchhaarrss((_:_G_o_a_l_, _-_C_o_d_e_s)) _[_d_e_t_]
Run _G_o_a_l as with once/1. Output written to current_output is
collected in _C_o_d_e_s.
wwiitthh__oouuttppuutt__ttoo__cchhaarrss((_:_G_o_a_l_, _-_C_o_d_e_s_, _?_T_a_i_l)) _[_d_e_t_]
Run _G_o_a_l as with once/1. Output written to current_output is
collected in _C_o_d_e_s\_T_a_i_l.
wwiitthh__oouuttppuutt__ttoo__cchhaarrss((_:_G_o_a_l_, _-_S_t_r_e_a_m_, _-_C_o_d_e_s_, _?_T_a_i_l)) _[_d_e_t_]
Same as with_output_to_chars/3 using an explicit stream. The
difference list _C_o_d_e_s\_T_a_i_l contains the character codes that _G_o_a_l
has written to _S_t_r_e_a_m.
1111..66 lliibbrraarryy((cchheecckk)):: EElleemmeennttaarryy ccoommpplleetteenneessss cchheecckkss
This library defines the predicate check/0 and a few friends that allow
for a quick-and-dirty cross-referencing.
cchheecckk
Performs the three checking passes implemented by list_undefined/0,
list_autoload/0 and list_redefined/0. Please check the definition
of these predicates for details.
The typical usage of this predicate is right after loading your
program to get a quick overview on the completeness and possible
conflicts in your program.
lliisstt__uunnddeeffiinneedd
Scans the database for predicates that have no definition. A
predicate is considered defined if it has clauses or is declared
using dynamic/1 or multifile/1. As a program is compiled, calls
are translated to predicates. If the called predicate is not yet
defined it is created as a predicate without definition. The same
happens with runtime generated calls. This predicate lists all
such undefined predicates that are referenced and not defined in
the library. See also list_autoload/0. Below is an example from
a real program and an illustration of how to edit the referencing
predicate using edit/1.
____________________________________________________________________| |
| ?- list_undefined. |
| Warning: The predicates below are not defined. If these are |
| Warning: defined at runtime using assert/1, use |
| Warning: :- dynamic Name/Arity. |
| Warning: |
| Warning: rdf_edit:rdfe_retract/4, which is referenced by |
| Warning: 1-st clause of rdf_edit:undo/4 |
| Warning: rdf_edit:rdfe_retract/3, which is referenced by |
| Warning: 1-st clause of rdf_edit:delete_object/1 |
| Warning: 1-st clause of rdf_edit:delete_subject/1 |
| Warning: 1-st clause of rdf_edit:delete_predicate/1 |
| |
||?-_edit(rdf_edit:undo/4)._________________________________________ ||
lliisstt__aauuttoollooaadd
Lists all undefined (see list_undefined/0) predicates that have a
definition in the library along with the file from which they will
be autoloaded when accessed. See also autoload/0.
lliisstt__rreeddeeffiinneedd
Lists predicates that are defined in the global module user as well
as in a normal module; that is, predicates for which the local
definition overrules the global default definition.
1111..77 lliibbrraarryy((ccllppffdd)):: CCoonnssttrraaiinntt LLooggiicc PPrrooggrraammmmiinngg oovveerr FFiinniittee DDoommaaiinnss
aauutthhoorr Markus Triska
1111..77..00..11 IInnttrroodduuccttiioonn
Constraint programming is a declarative formalism that lets you
describe conditions a solution must satisfy. This library provides
CLP(FD), Constraint Logic Programming over Finite Domains. It can
be used to model and solve various combinatorial problems such as
planning, scheduling and allocation tasks.
Most predicates of this library are finite domain _c_o_n_s_t_r_a_i_n_t_s, which
are relations over integers. They generalise arithmetic evaluation of
integer expressions in that propagation can proceed in all directions.
This library also provides _e_n_u_m_e_r_a_t_i_o_n _p_r_e_d_i_c_a_t_e_s, which let you
systematically search for solutions on variables whose domains have
become finite.
You can cite this library in your publications as:
________________________________________________________________________| |
|@inproceedings{Triska12, |
| author = {Markus Triska}, |
| title = {The Finite Domain Constraint Solver of {SWI-Prolog}}, |
| booktitle = {FLOPS}, |
| series = {LNCS}, |
| volume = {7294}, |
| year = {2012}, |
| pages = {307-316} |
|}|_____________________________________________________________________ | |
1111..77..00..22 AArriitthhmmeettiicc ccoonnssttrraaiinnttss
A finite domain _a_r_i_t_h_m_e_t_i_c _e_x_p_r_e_s_s_i_o_n is one of:
_______________________________________________________
| _i_n_t_e_g_e_r _|Given value |
| _v_a_r_i_a_b_l_e _|Unknown integer |
| ?(_v_a_r_i_a_b_l_e) |Unknown integer |
| -Expr |Unary minus |
| Expr + Expr |Addition |
| Expr * Expr |Multiplication |
| Expr - Expr |Subtraction |
| Expr ^ Expr |Exponentiation |
| min(Expr,Expr) |Minimum of two expressions |
| max(Expr,Expr) |Maximum of two expressions |
| Expr mod Expr |Modulo induced by floored division |
| Expr rem Expr |Modulo induced by truncated division |
| abs(Expr) |Absolute value |
|_Expr_/_Expr____|Truncated_integer_division___________|
Arithmetic _c_o_n_s_t_r_a_i_n_t_s are relations between arithmetic expressions.
The most important arithmetic constraints are:
___________________________________________________________
| Expr1 #>= Expr2 |Expr1 is greater than or equal to Expr2 |
| Expr1 #=< Expr2 |Expr1 is less than or equal to Expr2 |
| Expr1 #= Expr2 |Expr1 equals Expr2 |
| Expr1 #\= Expr2 |Expr1 is not equal to Expr2 |
| Expr1 #> Expr2 |Expr1 is greater than Expr2 |
|_Expr1_#<__Expr2__|Expr1_is_less_than_Expr2_______________ |
1111..77..00..33 RReeiiffiiccaattiioonn
The constraints in/2, #=/2, #\=/2, #</2, #>/2, #=</2, and #>=/2 can be
_r_e_i_f_i_e_d, which means reflecting their truth values into Boolean values
represented by the integers 0 and 1. Let P and Q denote reifiable
constraints or Boolean variables, then:
_____________________________________________
| #\ Q |True iff Q is false |
| P #\/ Q |True iff either P or Q |
| P #/\ Q |True iff both P and Q |
| P #<==> Q |True iff P and Q are equivalent |
| P #==> Q |True iff P implies Q |
|_P_#<==_Q___|True_iff_Q_implies_P___________ |
The constraints of this table are reifiable as well.
1111..77..00..44 EExxaammpplleess
Here is an example session with a few queries and their answers:
________________________________________________________________________| |
|?- use_module(library(clpfd)). |
|% library(clpfd) compiled into clpfd 0.06 sec, 633,732 bytes |
|true. |
| |
|?- X #> 3. |
|X in 4..sup. |
| |
|?- X #\= 20. |
|X in inf..19\/21..sup. |
| |
|?- 2*X #= 10. |
|X = 5. |
| |
|?- X*X #= 144. |
|X in -12\/12. |
| |
|?- 4*X + 2*Y #= 24, X + Y #= 9, [X,Y] ins 0..sup. |
|X = 3, |
|Y = 6. |
| |
|?- Vs = [X,Y,Z], Vs ins 1..3, all_different(Vs), X = 1, Y #\= 2. |
|Vs = [1, 3, 2], |
|X = 1, |
|Y = 3, |
|Z = 2. |
| |
|?- X #= Y #<==> B, X in 0..3, Y in 4..5. |
|B = 0, |
|X in 0..3, |
|Y|in_4..5._____________________________________________________________ | |
In each case, and as for all pure programs, the answer is declaratively
equivalent to the original query, and in many cases the constraint
solver has deduced additional domain restrictions.
1111..77..00..55 SSeeaarrcchh
A common usage of this library is to first post the desired constraints
among the variables of a model, and then to use enumeration predicates
to search for solutions. As an example of a constraint satisfaction
problem, consider the cryptoarithmetic puzzle SEND + MORE = MONEY,
where different letters denote distinct integers between 0 and 9. It
can be modeled in CLP(FD) as follows:
________________________________________________________________________| |
|:- use_module(library(clpfd)). |
| |
|puzzle([S,E,N,D] + [M,O,R,E] = [M,O,N,E,Y]) :- |
| Vars = [S,E,N,D,M,O,R,Y], |
| Vars ins 0..9, |
| all_different(Vars), |
| S*1000 + E*100 + N*10 + D + |
| M*1000 + O*100 + R*10 + E #= |
| M*10000 + O*1000 + N*100 + E*10 + Y, |
||_______M_#\=_0,_S_#\=_0.______________________________________________ ||
Sample query and its result (actual variables replaced for
readability):
________________________________________________________________________| |
|?- puzzle(As+Bs=Cs). |
|As = [9, _A2, _A3, _A4], |
|Bs = [1, 0, _B3, _A2], |
|Cs = [1, 0, _A3, _A2, _C5], |
|_A2 in 4..7, |
|all_different([9, _A2, _A3, _A4, 1, 0, _B3, _C5]), |
|1000*9+91*_A2+ -90*_A3+_A4+ -9000*1+ -900*0+10*_B3+ -1*_C5#=0, |
|_A3 in 5..8, |
|_A4 in 2..8, |
|_B3 in 2..8, |
|_C5|in_2..8.___________________________________________________________ | |
Here, the constraint solver has deduced more stringent bounds for all
variables. It is good practice to keep the modeling part separate from
the actual search. This lets you observe termination and determinism
properties of the modeling part in isolation from the search. Labeling
can then be used to search for solutions in a separate predicate or
goal:
________________________________________________________________________| |
|?- puzzle(As+Bs=Cs), label(As). |
|As = [9, 5, 6, 7], |
|Bs = [1, 0, 8, 5], |
|Cs = [1, 0, 6, 5, 2] ; |
|false.|________________________________________________________________ | |
In this case, it suffices to label a subset of variables to find the
puzzle's unique solution, since the constraint solver is strong enough
to reduce the domains of remaining variables to singleton sets. In
general though, it is necessary to label all variables to obtain ground
solutions.
1111..77..00..66 DDeeccllaarraattiivvee iinntteeggeerr aarriitthhmmeettiicc
You can also use CLP(FD) constraints as a more declarative alternative
for ordinary integer arithmetic with is/2, >/2 etc. For example:
________________________________________________________________________| |
|:- use_module(library(clpfd)). |
| |
|n_factorial(0, 1). |
|n_factorial(N, F) :- |
| N #> 0, N1 #= N - 1, F #= N * F1, |
||_______n_factorial(N1,_F1).___________________________________________ ||
This predicate can be used in all directions. For example:
________________________________________________________________________| |
|?- n_factorial(47, F). |
|F = 258623241511168180642964355153611979969197632389120000000000 ; |
|false. |
| |
|?- n_factorial(N, 1). |
|N = 0 ; |
|N = 1 ; |
|false. |
| |
|?- n_factorial(N, 3). |
|false.|________________________________________________________________ | |
To make the predicate terminate if any argument is instantiated, add
the (implied) constraint F #\= 0 before the recursive call. Otherwise,
the query n_factorial(N, 0) is the only non-terminating case of this
kind.
<### Advanced topics {#clpfd-advanced-topics}
This library uses goal_expansion/2 to rewrite constraints at
compilation time. The expansion's aim is to transparently bring
the performance of CLP(FD) constraints close to that of conventional
arithmetic predicates (</2, =:=/2, is/2 etc.) when the constraints are
used in modes that can also be handled by built-in arithmetic. To
disable the expansion, set the flag clpfd_goal_expansion to false.
If you set the flag clpfd_monotonic to true, then CLP(FD) is monotonic:
Adding new constraints cannot yield new solutions. When this flag is
true, you must wrap variables that occur in arithmetic expressions with
the functor (?)/1. For example, ?(X) #= ?(Y) + ?(Z). The wrapper can
be omitted for variables that are already constrained to integers.
Use call_residue_vars/2 and copy_term/3 to inspect residual goals and
the constraints in which a variable is involved. This library also
provides _r_e_f_l_e_c_t_i_o_n predicates (like fd_dom/2, fd_size/2 etc.) with
which you can inspect a variable's current domain. These predicates
can be useful if you want to implement your own labeling strategies.
You can also define custom constraints. The mechanism to do this is
not yet finalised, and we welcome suggestions and descriptions of use
cases that are important to you. As an example of how it can be
done currently, let us define a new custom constraint oneground(X,Y,Z),
where Z shall be 1 if at least one of X and Y is instantiated:
________________________________________________________________________| |
|:- use_module(library(clpfd)). |
| |
|:- multifile clpfd:run_propagator/2. |
| |
|oneground(X, Y, Z) :- |
| clpfd:make_propagator(oneground(X, Y, Z), Prop), |
| clpfd:init_propagator(X, Prop), |
| clpfd:init_propagator(Y, Prop), |
| clpfd:trigger_once(Prop). |
| |
|clpfd:run_propagator(oneground(X, Y, Z), MState) :- |
| ( integer(X) -> clpfd:kill(MState), Z = 1 |
| ; integer(Y) -> clpfd:kill(MState), Z = 1 |
| ; true |
||_______)._____________________________________________________________ ||
First, clpfd:make_propagator/2 is used to transform a user-defined
representation of the new constraint to an internal form. With
clpfd:init_propagator/2, this internal form is then attached to X and
Y. From now on, the propagator will be invoked whenever the domains of
X or Y are changed. Then, clpfd:trigger_once/1 is used to give the
propagator its first chance for propagation even though the variables'
domains have not yet changed. Finally, clpfd:run_propagator/2 is
extended to define the actual propagator. As explained, this predicate
is automatically called by the constraint solver. The first argument
is the user-defined representation of the constraint as used in
clpfd:make_propagator/2, and the second argument is a mutable state
that can be used to prevent further invocations of the propagator when
the constraint has become entailed, by using clpfd:kill/1. An example
of using the new constraint:
________________________________________________________________________| |
|?- oneground(X, Y, Z), Y = 5. |
|Y = 5, |
|Z = 1, |
|X|in_inf..sup._________________________________________________________ | |
_?_V_a_r iinn _+_D_o_m_a_i_n
_V_a_r is an element of _D_o_m_a_i_n. _D_o_m_a_i_n is one of:
_I_n_t_e_g_e_r
Singleton set consisting only of _I_n_t_e_g_e_r.
_L_o_w_e_r .... _U_p_p_e_r
All integers _I such that _L_o_w_e_r =< _I =< _U_p_p_e_r. _L_o_w_e_r must be
an integer or the atom iinnff, which denotes negative infinity.
_U_p_p_e_r must be an integer or the atom ssuupp, which denotes
positive infinity.
_D_o_m_a_i_n_1 \/ _D_o_m_a_i_n_2
The union of _D_o_m_a_i_n_1 and _D_o_m_a_i_n_2.
_+_V_a_r_s iinnss _+_D_o_m_a_i_n
The variables in the list _V_a_r_s are elements of _D_o_m_a_i_n.
iinnddoommaaiinn((_?_V_a_r))
Bind _V_a_r to all feasible values of its domain on backtracking. The
domain of _V_a_r must be finite.
llaabbeell((_+_V_a_r_s))
Equivalent to labeling([], Vars).
llaabbeelliinngg((_+_O_p_t_i_o_n_s_, _+_V_a_r_s))
Assign a value to each variable in _V_a_r_s. Labeling means
systematically trying out values for the finite domain variables
_V_a_r_s until all of them are ground. The domain of each variable in
_V_a_r_s must be finite. _O_p_t_i_o_n_s is a list of options that let you
exhibit some control over the search process. Several categories
of options exist:
The variable selection strategy lets you specify which variable of
_V_a_r_s is labeled next and is one of:
lleeffttmmoosstt
Label the variables in the order they occur in _V_a_r_s. This is
the default.
ffff
_F_i_r_s_t _f_a_i_l. Label the leftmost variable with smallest domain
next, in order to detect infeasibility early. This is often a
good strategy.
ffffcc
Of the variables with smallest domains, the leftmost one
participating in most constraints is labeled next.
mmiinn
Label the leftmost variable whose lower bound is the lowest
next.
mmaaxx
Label the leftmost variable whose upper bound is the highest
next.
The value order is one of:
uupp
Try the elements of the chosen variable's domain in ascending
order. This is the default.
ddoowwnn
Try the domain elements in descending order.
The branching strategy is one of:
sstteepp
For each variable X, a choice is made between X = V and X #\=
V, where V is determined by the value ordering options. This
is the default.
eennuumm
For each variable X, a choice is made between X = V_1, X = V_2
etc., for all values V_i of the domain of X. The order is
determined by the value ordering options.
bbiisseecctt
For each variable X, a choice is made between X #=< M and X #>
M, where M is the midpoint of the domain of X.
At most one option of each category can be specified, and an option
must not occur repeatedly.
The order of solutions can be influenced with:
o min(Expr)
o max(Expr)
This generates solutions in ascending/descending order with respect
to the evaluation of the arithmetic expression Expr. Labeling _V_a_r_s
must make Expr ground. If several such options are specified, they
are interpreted from left to right, e.g.:
____________________________________________________________________| |
||?-_[X,Y]_ins_10..20,_labeling([max(X),min(Y)],[X,Y])._____________ ||
This generates solutions in descending order of X, and for each
binding of X, solutions are generated in ascending order of Y. To
obtain the incomplete behaviour that other systems exhibit with
"maximize(Expr)" and "minimize(Expr)", use once/1, e.g.:
____________________________________________________________________| |
||once(labeling([max(Expr)],_Vars))_________________________________ ||
Labeling is always complete, always terminates, and yields no
redundant solutions.
aallll__ddiiffffeerreenntt((_+_V_a_r_s))
_V_a_r_s are pairwise distinct.
aallll__ddiissttiinncctt((_+_L_s))
Like all_different/1, with stronger propagation. For example,
all_distinct/1 can detect that not all variables can assume
distinct values given the following domains:
____________________________________________________________________| |
| ?- maplist(in, Vs, |
| [1\/3..4, 1..2\/4, 1..2\/4, 1..3, 1..3, 1..6]), |
| all_distinct(Vs). |
||false.____________________________________________________________ ||
ssuumm((_+_V_a_r_s_, _+_R_e_l_, _?_E_x_p_r))
The sum of elements of the list _V_a_r_s is in relation _R_e_l to _E_x_p_r.
_R_e_l is one of #=, #\=, #<, #>, #=< or #>=. For example:
____________________________________________________________________| |
| ?- [A,B,C] ins 0..sup, sum([A,B,C], #=, 100). |
| A in 0..100, |
| A+B+C#=100, |
| B in 0..100, |
||C_in_0..100.______________________________________________________ ||
ssccaallaarr__pprroodduucctt((_+_C_s_, _+_V_s_, _+_R_e_l_, _?_E_x_p_r))
_C_s is a list of integers, _V_s is a list of variables and integers.
True if the scalar product of _C_s and _V_s is in relation _R_e_l to _E_x_p_r,
where _R_e_l is #=, #\=, #<, #>, #=< or #>=.
_?_X #>= _?_Y
_X is greater than or equal to _Y.
_?_X #=< _?_Y
_X is less than or equal to _Y.
_?_X #= _?_Y
_X equals _Y.
_?_X #\= _?_Y
_X is not _Y.
_?_X #> _?_Y
_X is greater than _Y.
_?_X #< _?_Y
_X is less than _Y. In addition to its regular use in problems
that require it, this constraint can also be useful to eliminate
uninteresting symmetries from a problem. For example, all possible
matches between pairs built from four players in total:
____________________________________________________________________| |
| ?- Vs = [A,B,C,D], Vs ins 1..4, |
| all_different(Vs), |
| A #< B, C #< D, A #< C, |
| findall(pair(A,B)-pair(C,D), label(Vs), Ms). |
| Ms = [ pair(1, 2)-pair(3, 4), |
| pair(1, 3)-pair(2, 4), |
||_______pair(1,_4)-pair(2,_3)].____________________________________ ||
#\ _+_Q
The reifiable constraint _Q does _n_o_t hold. For example, to obtain
the complement of a domain:
____________________________________________________________________| |
| ?- #\ X in -3..0\/10..80. |
||X_in_inf.._-4\/1..9\/81..sup._____________________________________ ||
_?_P #<==> _?_Q
_P and _Q are equivalent. For example:
____________________________________________________________________| |
| ?- X #= 4 #<==> B, X #\= 4. |
| B = 0, |
||X_in_inf..3\/5..sup.______________________________________________ ||
The following example uses reified constraints to relate a list of
finite domain variables to the number of occurrences of a given
value:
____________________________________________________________________| |
| :- use_module(library(clpfd)). |
| |
| vs_n_num(Vs, N, Num) :- |
| maplist(eq_b(N), Vs, Bs), |
| sum(Bs, #=, Num). |
| |
||eq_b(X,_Y,_B)_:-_X_#=_Y_#<==>_B.__________________________________ ||
Sample queries and their results:
____________________________________________________________________| |
| ?- Vs = [X,Y,Z], Vs ins 0..1, vs_n_num(Vs, 4, Num). |
| Vs = [X, Y, Z], |
| Num = 0, |
| X in 0..1, |
| Y in 0..1, |
| Z in 0..1. |
| |
| ?- vs_n_num([X,Y,Z], 2, 3). |
| X = 2, |
| Y = 2, |
||Z_=_2.____________________________________________________________ ||
_?_P #==> _?_Q
_P implies _Q.
_?_P #<== _?_Q
_Q implies _P.
_?_P #/\ _?_Q
_P and _Q hold.
_?_P #\/ _?_Q
_P or _Q holds. For example, the sum of natural numbers below 1000
that are multiples of 3 or 5:
____________________________________________________________________| |
| ?- findall(N, (N mod 3 #= 0 #\/ N mod 5 #= 0, N in 0..999, |
| indomain(N)), |
| Ns), |
| sum(Ns, #=, Sum). |
| Ns = [0, 3, 5, 6, 9, 10, 12, 15, 18|...], |
||Sum_=_233168._____________________________________________________ ||
lleexx__cchhaaiinn((_+_L_i_s_t_s))
_L_i_s_t_s are lexicographically non-decreasing.
ttuupplleess__iinn((_+_T_u_p_l_e_s_, _+_R_e_l_a_t_i_o_n))
_R_e_l_a_t_i_o_n must be a list of lists of integers. The elements of the
list _T_u_p_l_e_s are constrained to be elements of _R_e_l_a_t_i_o_n. Arbitrary
finite relations, such as compatibility tables, can be modeled in
this way. For example, if 1 is compatible with 2 and 5, and 4 is
compatible with 0 and 3:
____________________________________________________________________| |
| ?- tuples_in([[X,Y]], [[1,2],[1,5],[4,0],[4,3]]), X = 4. |
| X = 4, |
||Y_in_0\/3.________________________________________________________ ||
As another example, consider a train schedule represented as a list
of quadruples, denoting departure and arrival places and times for
each train. In the following program, Ps is a feasible journey
of length 3 from A to D via trains that are part of the given
schedule.
____________________________________________________________________| |
| :- use_module(library(clpfd)). |
| |
| trains([[1,2,0,1], |
| [2,3,4,5], |
| [2,3,0,1], |
| [3,4,5,6], |
| [3,4,2,3], |
| [3,4,8,9]]). |
| |
| threepath(A, D, Ps) :- |
| Ps = [[A,B,_T0,T1],[B,C,T2,T3],[C,D,T4,_T5]], |
| T2 #> T1, |
| T4 #> T3, |
| trains(Ts), |
||________tuples_in(Ps,_Ts).________________________________________ ||
In this example, the unique solution is found without labeling:
____________________________________________________________________| |
| ?- threepath(1, 4, Ps). |
||Ps_=_[[1,_2,_0,_1],_[2,_3,_4,_5],_[3,_4,_8,_9]].__________________ ||
sseerriiaalliizzeedd((_+_S_t_a_r_t_s_, _+_D_u_r_a_t_i_o_n_s))
Describes a set of non-overlapping tasks. _S_t_a_r_t_s = [S_1,...,S_n],
is a list of variables or integers, _D_u_r_a_t_i_o_n_s = [D_1,...,D_n] is a
list of non-negative integers. Constrains _S_t_a_r_t_s and _D_u_r_a_t_i_o_n_s to
denote a set of non-overlapping tasks, i.e.: S_i + D_i =< S_j or S_j
+ D_j =< S_i for all 1 =< i < j =< n. Example:
____________________________________________________________________| |
| ?- length(Vs, 3), |
| Vs ins 0..3, |
| serialized(Vs, [1,2,3]), |
| label(Vs). |
| Vs = [0, 1, 3] ; |
| Vs = [2, 0, 3] ; |
||false.____________________________________________________________ ||
SSeeee aallssoo Dorndorf et al. 2000, "Constraint Propagation
Techniques for the Disjunctive Scheduling Problem"
eelleemmeenntt((_?_N_, _+_V_s_, _?_V))
The _N-th element of the list of finite domain variables _V_s is _V.
Analogous to nth1/3.
gglloobbaall__ccaarrddiinnaalliittyy((_+_V_s_, _+_P_a_i_r_s))
Global Cardinality constraint. Equivalent to
global_cardinality(Vs, Pairs, []). Example:
____________________________________________________________________| |
| ?- Vs = [_,_,_], global_cardinality(Vs, [1-2,3-_]), label(Vs). |
| Vs = [1, 1, 3] ; |
| Vs = [1, 3, 1] ; |
||Vs_=_[3,_1,_1].___________________________________________________ ||
gglloobbaall__ccaarrddiinnaalliittyy((_+_V_s_, _+_P_a_i_r_s_, _+_O_p_t_i_o_n_s))
Global Cardinality constraint. _V_s is a list of finite domain
variables, _P_a_i_r_s is a list of Key-Num pairs, where Key is an
integer and Num is a finite domain variable. The constraint holds
iff each V in _V_s is equal to some key, and for each Key-Num pair in
_P_a_i_r_s, the number of occurrences of Key in _V_s is Num. _O_p_t_i_o_n_s is a
list of options. Supported options are:
ccoonnssiisstteennccyy((_v_a_l_u_e))
A weaker form of consistency is used.
ccoosstt((_C_o_s_t_, _M_a_t_r_i_x))
_M_a_t_r_i_x is a list of rows, one for each variable, in the order
they occur in _V_s. Each of these rows is a list of integers,
one for each key, in the order these keys occur in _P_a_i_r_s.
When variable v_i is assigned the value of key k_j, then the
associated cost is _M_a_t_r_i_x__{ij}. _C_o_s_t is the sum of all costs.
cciirrccuuiitt((_+_V_s))
True if the list _V_s of finite domain variables induces a
Hamiltonian circuit. The k-th element of _V_s denotes the successor
of node k. Node indexing starts with 1. Examples:
____________________________________________________________________| |
| ?- length(Vs, _), circuit(Vs), label(Vs). |
| Vs = [] ; |
| Vs = [1] ; |
| Vs = [2, 1] ; |
| Vs = [2, 3, 1] ; |
| Vs = [3, 1, 2] ; |
||Vs_=_[2,_3,_4,_1]_._______________________________________________ ||
ccuummuullaattiivvee((_+_T_a_s_k_s))
Equivalent to cumulative(Tasks, [limit(1)]).
ccuummuullaattiivvee((_+_T_a_s_k_s_, _+_O_p_t_i_o_n_s))
_T_a_s_k_s is a list of tasks, each of the form
task(S_i, D_i, E_i, C_i, T_i). S_i denotes the start time,
D_i the positive duration, E_i the end time, C_i the non-negative
resource consumption, and T_i the task identifier. Each of these
arguments must be a finite domain variable with bounded domain, or
an integer. The constraint holds if at any time during the start
and end of each task, the total resource consumption of all tasks
running at that time does not exceed the global resource limit
(which is 1 by default). _O_p_t_i_o_n_s is a list of options. Currently,
the only supported option is:
lliimmiitt((_L))
The integer _L is the global resource limit.
For example, given the following predicate that relates three tasks
of durations 2 and 3 to a list containing their starting times:
____________________________________________________________________| |
| tasks_starts(Tasks, [S1,S2,S3]) :- |
| Tasks = [task(S1,3,_,1,_), |
| task(S2,2,_,1,_), |
||_________________task(S3,2,_,1,_)]._______________________________ ||
We can use cumulative/2 as follows, and obtain a schedule:
____________________________________________________________________| |
| ?- tasks_starts(Tasks, Starts), Starts ins 0..10, |
| cumulative(Tasks, [limit(2)]), label(Starts). |
| Tasks = [task(0, 3, 3, 1, _G36), task(0, 2, 2, 1, _G45), ...], |
||Starts_=_[0,_0,_2]_.______________________________________________ ||
aauuttoommaattoonn((_+_S_i_g_n_a_t_u_r_e_, _+_N_o_d_e_s_, _+_A_r_c_s))
Describes a list of finite domain variables
with a finite automaton. Equivalent to
automaton(_, _, Signature, Nodes, Arcs, [], [], _), a common
use case of automaton/8. In the following example, a list of
binary finite domain variables is constrained to contain at least
two consecutive ones:
____________________________________________________________________| |
| :- use_module(library(clpfd)). |
| |
| two_consecutive_ones(Vs) :- |
| automaton(Vs, [source(a),sink(c)], |
| [arc(a,0,a), arc(a,1,b), |
| arc(b,0,a), arc(b,1,c), |
||___________________arc(c,0,c),_arc(c,1,c)]).______________________ ||
Example query:
____________________________________________________________________| |
| ?- length(Vs, 3), two_consecutive_ones(Vs), label(Vs). |
| Vs = [0, 1, 1] ; |
| Vs = [1, 1, 0] ; |
||Vs_=_[1,_1,_1].___________________________________________________ ||
aauuttoommaattoonn((_?_S_e_q_u_e_n_c_e_, _?_T_e_m_p_l_a_t_e_, _+_S_i_g_n_a_t_u_r_e_, _+_N_o_d_e_s_, _+_A_r_c_s_, _+_C_o_u_n_t_e_r_s_, _+_I_n_i_t_i_a_l_s_, _?_F_i_n_a_l_s))
Describes a list of finite domain variables with a finite
automaton. True if the finite automaton induced by _N_o_d_e_s and
_A_r_c_s (extended with _C_o_u_n_t_e_r_s) accepts _S_i_g_n_a_t_u_r_e. _S_e_q_u_e_n_c_e is a
list of terms, all of the same shape. Additional constraints
must link _S_e_q_u_e_n_c_e to _S_i_g_n_a_t_u_r_e, if necessary. _N_o_d_e_s is a
list of source(Node) and sink(Node) terms. _A_r_c_s is a list of
arc(Node,Integer,Node) and arc(Node,Integer,Node,Exprs) terms that
denote the automaton's transitions. Each node is represented
by an arbitrary term. Transitions that are not mentioned go
to an implicit failure node. Exprs is a list of arithmetic
expressions, of the same length as _C_o_u_n_t_e_r_s. In each expression,
variables occurring in _C_o_u_n_t_e_r_s correspond to old counter values,
and variables occurring in _T_e_m_p_l_a_t_e correspond to the current
element of _S_e_q_u_e_n_c_e. When a transition containing expressions is
taken, counters are updated as stated. By default, counters remain
unchanged. _C_o_u_n_t_e_r_s is a list of variables that must not occur
anywhere outside of the constraint goal. _I_n_i_t_i_a_l_s is a list of
the same length as _C_o_u_n_t_e_r_s. Counter arithmetic on the transitions
relates the counter values in _I_n_i_t_i_a_l_s to _F_i_n_a_l_s.
The following example is taken from Beldiceanu, Carlsson, Debruyne
and Petit: "Reformulation of Global Constraints Based on
Constraints Checkers", Constraints 10(4), pp 339-362 (2005). It
relates a sequence of integers and finite domain variables to its
number of inflexions, which are switches between strictly ascending
and strictly descending subsequences:
____________________________________________________________________| |
| :- use_module(library(clpfd)). |
| |
| sequence_inflexions(Vs, N) :- |
| variables_signature(Vs, Sigs), |
| automaton(_, _, Sigs, |
| [source(s),sink(i),sink(j),sink(s)], |
| [arc(s,0,s), arc(s,1,j), arc(s,2,i), |
| arc(i,0,i), arc(i,1,j,[C+1]), arc(i,2,i), |
| arc(j,0,j), arc(j,1,j), |
| arc(j,2,i,[C+1])], |
| [C], [0], [N]). |
| |
| variables_signature([], []). |
| variables_signature([V|Vs], Sigs) :- |
| variables_signature_(Vs, V, Sigs). |
| |
| variables_signature_([], _, []). |
| variables_signature_([V|Vs], Prev, [S|Sigs]) :- |
| V #= Prev #<==> S #= 0, |
| Prev #< V #<==> S #= 1, |
| Prev #> V #<==> S #= 2, |
||________variables_signature_(Vs,_V,_Sigs).________________________ ||
Example queries:
____________________________________________________________________| |
| ?- sequence_inflexions([1,2,3,3,2,1,3,0], N). |
| N = 3. |
| |
| ?- length(Ls, 5), Ls ins 0..1, |
| sequence_inflexions(Ls, 3), label(Ls). |
| Ls = [0, 1, 0, 1, 0] ; |
||Ls_=_[1,_0,_1,_0,_1]._____________________________________________ ||
ttrraannssppoossee((_+_M_a_t_r_i_x_, _?_T_r_a_n_s_p_o_s_e))
_T_r_a_n_s_p_o_s_e a list of lists of the same length. Example:
____________________________________________________________________| |
| ?- transpose([[1,2,3],[4,5,6],[7,8,9]], Ts). |
||Ts_=_[[1,_4,_7],_[2,_5,_8],_[3,_6,_9]].___________________________ ||
This predicate is useful in many constraint programs. Consider for
instance Sudoku:
____________________________________________________________________| |
| :- use_module(library(clpfd)). |
| |
| sudoku(Rows) :- |
| length(Rows, 9), maplist(length_(9), Rows), |
| append(Rows, Vs), Vs ins 1..9, |
| maplist(all_distinct, Rows), |
| transpose(Rows, Columns), |
| maplist(all_distinct, Columns), |
| Rows = [A,B,C,D,E,F,G,H,I], |
| blocks(A, B, C), blocks(D, E, F), blocks(G, H, I). |
| |
| length_(L, Ls) :- length(Ls, L). |
| |
| blocks([], [], []). |
| blocks([A,B,C|Bs1], [D,E,F|Bs2], [G,H,I|Bs3]) :- |
| all_distinct([A,B,C,D,E,F,G,H,I]), |
| blocks(Bs1, Bs2, Bs3). |
| |
| problem(1, [[_,_,_,_,_,_,_,_,_], |
| [_,_,_,_,_,3,_,8,5], |
| [_,_,1,_,2,_,_,_,_], |
| [_,_,_,5,_,7,_,_,_], |
| [_,_,4,_,_,_,1,_,_], |
| [_,9,_,_,_,_,_,_,_], |
| [5,_,_,_,_,_,_,7,3], |
| [_,_,2,_,1,_,_,_,_], |
||____________[_,_,_,_,4,_,_,_,9]]).________________________________ ||
Sample query:
____________________________________________________________________| |
| ?- problem(1, Rows), sudoku(Rows), maplist(writeln, Rows). |
| [9, 8, 7, 6, 5, 4, 3, 2, 1] |
| [2, 4, 6, 1, 7, 3, 9, 8, 5] |
| [3, 5, 1, 9, 2, 8, 7, 4, 6] |
| [1, 2, 8, 5, 3, 7, 6, 9, 4] |
| [6, 3, 4, 8, 9, 2, 1, 5, 7] |
| [7, 9, 5, 4, 6, 1, 8, 3, 2] |
| [5, 1, 9, 2, 8, 6, 4, 7, 3] |
| [4, 7, 2, 3, 1, 9, 5, 6, 8] |
| [8, 6, 3, 7, 4, 5, 2, 1, 9] |
||Rows_=_[[9,_8,_7,_6,_5,_4,_3,_2|...],_..._,_[...|...]].___________ ||
zzccoommppaarree((_?_O_r_d_e_r_, _?_A_, _?_B))
Analogous to compare/3, with finite domain variables _A and _B.
Example:
____________________________________________________________________| |
| :- use_module(library(clpfd)). |
| |
| n_factorial(N, F) :- |
| zcompare(C, N, 0), |
| n_factorial_(C, N, F). |
| |
| n_factorial_(=, _, 1). |
| n_factorial_(>, N, F) :- |
| F #= F0*N, N1 #= N - 1, |
||______n_factorial(N1,_F0).________________________________________ ||
This version is deterministic if the first argument is
instantiated:
____________________________________________________________________| |
| ?- n_factorial(30, F). |
||F_=_265252859812191058636308480000000.____________________________ ||
cchhaaiinn((_+_Z_s_, _+_R_e_l_a_t_i_o_n))
_Z_s form a chain with respect to _R_e_l_a_t_i_o_n. _Z_s is a list of finite
domain variables that are a chain with respect to the partial order
_R_e_l_a_t_i_o_n, in the order they appear in the list. _R_e_l_a_t_i_o_n must be
#=, #=<, #>=, #< or #>. For example:
____________________________________________________________________| |
| ?- chain([X,Y,Z], #>=). |
| X#>=Y, |
||Y#>=Z.____________________________________________________________ ||
ffdd__vvaarr((_+_V_a_r))
True iff _V_a_r is a CLP(FD) variable.
ffdd__iinnff((_+_V_a_r_, _-_I_n_f))
_I_n_f is the infimum of the current domain of _V_a_r.
ffdd__ssuupp((_+_V_a_r_, _-_S_u_p))
_S_u_p is the supremum of the current domain of _V_a_r.
ffdd__ssiizzee((_+_V_a_r_, _-_S_i_z_e))
Determine the size of a variable's domain. _S_i_z_e is the number of
elements of the current domain of _V_a_r, or the atom ssuupp if the
domain is unbounded.
ffdd__ddoomm((_+_V_a_r_, _-_D_o_m))
_D_o_m is the current domain (see in/2) of _V_a_r. This predicate is
useful if you want to reason about domains. It is not needed
if you only want to display remaining domains; instead, separate
your model from the search part and let the toplevel display this
information via residual goals.
1111..88 lliibbrraarryy((ccllppqqrr)):: CCoonnssttrraaiinntt LLooggiicc PPrrooggrraammmmiinngg oovveerr RRaattiioonnaallss aanndd
RReeaallss
Author: _C_h_r_i_s_t_i_a_n _H_o_l_z_b_a_u_r, ported to SWI-Prolog by _L_e_s_l_i_e _D_e
_K_o_n_i_n_c_k, K.U. Leuven
This CLP(Q,R) system is a port of the CLP(Q,R) system of Sicstus Prolog
by Christian Holzbaur: Holzbaur C.: OFAI clp(q,r) Manual, Edition
1.3.3, Austrian Research Institute for Artificial Intelligence, Vienna,
TR-95-09, 1995. This manual is roughly based on the manual of the
above mentioned CLP(Q,R) implementation.
The CLP(Q,R) system consists of two components: the CLP(Q) library for
handling constraints over the rational numbers and the CLP(R) library
for handling constraints over the real numbers (using floating point
numbers as representation). Both libraries offer the same predicates
(with exception of bb_inf/4 in CLP(Q) and bb_inf/5 in CLP(R)). It is
allowed to use both libraries in one program, but using both CLP(Q) and
CLP(R) constraints on the same variable will result in an exception.
Please note that the clpqr library is _n_o_t an _a_u_t_o_l_o_a_d library and
therefore this library must be loaded explicitly before using it:
________________________________________________________________________| |
|:-|use_module(library(clpq)).__________________________________________ | |
or
________________________________________________________________________| |
|:-|use_module(library(clpr)).__________________________________________ | |
1111..88..11 SSoollvveerr pprreeddiiccaatteess
The following predicates are provided to work with constraints:
{}((_+_C_o_n_s_t_r_a_i_n_t_s))
Adds the constraints given by _C_o_n_s_t_r_a_i_n_t_s to the constraint store.
eennttaaiilleedd((_+_C_o_n_s_t_r_a_i_n_t))
Succeeds if _C_o_n_s_t_r_a_i_n_t is necessarily true within the current
constraint store. This means that adding the negation of the
constraint to the store results in failure.
iinnff((_+_E_x_p_r_e_s_s_i_o_n_, _-_I_n_f))
Computes the infimum of _E_x_p_r_e_s_s_i_o_n within the current state of the
constraint store and returns that infimum in _I_n_f. This predicate
does not change the constraint store.
ssuupp((_+_E_x_p_r_e_s_s_i_o_n_, _-_S_u_p))
Computes the supremum of _E_x_p_r_e_s_s_i_o_n within the current state of the
constraint store and returns that supremum in _S_u_p. This predicate
does not change the constraint store.
mmiinniimmiizzee((_+_E_x_p_r_e_s_s_i_o_n))
Minimizes _E_x_p_r_e_s_s_i_o_n within the current constraint store. This is
the same as computing the infimum and equating the expression to
that infimum.
mmaaxxiimmiizzee((_+_E_x_p_r_e_s_s_i_o_n))
Maximizes _E_x_p_r_e_s_s_i_o_n within the current constraint store. This is
the same as computing the supremum and equating the expression to
that supremum.
bbbb__iinnff((_+_I_n_t_s_, _+_E_x_p_r_e_s_s_i_o_n_, _-_I_n_f_, _-_V_e_r_t_e_x_, _+_E_p_s))
This predicate is offered in CLP(R) only. It computes the
infimum of _E_x_p_r_e_s_s_i_o_n within the current constraint store, with the
additional constraint that in that infimum, all variables in _I_n_t_s
have integral values. _V_e_r_t_e_x will contain the values of _I_n_t_s in
the infimum. _E_p_s denotes how much a value may differ from an
integer to be considered an integer. E.g. when _E_p_s = 0.001, then X
= 4.999 will be considered as an integer (5 in this case). _E_p_s
should be between 0 and 0.5.
bbbb__iinnff((_+_I_n_t_s_, _+_E_x_p_r_e_s_s_i_o_n_, _-_I_n_f_, _-_V_e_r_t_e_x))
This predicate is offered in CLP(Q) only. It behaves the same as
bb_inf/5 but does not use an error margin.
bbbb__iinnff((_+_I_n_t_s_, _+_E_x_p_r_e_s_s_i_o_n_, _-_I_n_f))
The same as bb_inf/5 or bb_inf/4 but without returning the values
of the integers. In CLP(R), an error margin of 0.001 is used.
dduummpp((_+_T_a_r_g_e_t_, _+_N_e_w_v_a_r_s_, _-_C_o_d_e_d_A_n_s_w_e_r))
Returns the constraints on _T_a_r_g_e_t in the list _C_o_d_e_d_A_n_s_w_e_r where all
variables of _T_a_r_g_e_t have been replaced by _N_e_w_V_a_r_s. This operation
does not change the constraint store. E.g. in
____________________________________________________________________| |
||dump([X,Y,Z],[x,y,z],Cons)________________________________________ ||
Cons will contain the constraints on X, Y and Z, where these
variables have been replaced by atoms x, y and z.
1111..88..22 SSyynnttaaxx ooff tthhee pprreeddiiccaattee aarrgguummeennttss
The arguments of the predicates defined in the subsection above are
defined in table 11.1. Failing to meet the syntax rules will result in
an exception.
_______________________________________________________________________
| <_C_o_n_s_t_r_a_i_n_t_s>::= <_C_o_n_s_t_r_a_i_n_t> |single constraint |
| | <_C_o_n_s_t_r_a_i_n_t> , <_C_o_n_s_t_r_a_i_n_t_s> |conjunction |
| | <_C_o_n_s_t_r_a_i_n_t> ; <_C_o_n_s_t_r_a_i_n_t_s> |disjunction |
| <_C_o_n_s_t_r_a_i_n_t> ::= <_E_x_p_r_e_s_s_i_o_n> < <_E_x_p_r_e_s_s_i_o_n> |less than |
| | <_E_x_p_r_e_s_s_i_o_n> > <_E_x_p_r_e_s_s_i_o_n> |greater than |
| | <_E_x_p_r_e_s_s_i_o_n> =< <_E_x_p_r_e_s_s_i_o_n> |less or equal |
| | <=(<_E_x_p_r_e_s_s_i_o_n>, <_E_x_p_r_e_s_s_i_o_n>) |less or equal |
| | <_E_x_p_r_e_s_s_i_o_n> >= <_E_x_p_r_e_s_s_i_o_n> |greater or equal |
| | <_E_x_p_r_e_s_s_i_o_n> =\= <_E_x_p_r_e_s_s_i_o_n> |not equal |
| | <_E_x_p_r_e_s_s_i_o_n> =:= <_E_x_p_r_e_s_s_i_o_n> |equal |
| | <_E_x_p_r_e_s_s_i_o_n> = <_E_x_p_r_e_s_s_i_o_n> |equal |
| <_E_x_p_r_e_s_s_i_o_n> ::= <_V_a_r_i_a_b_l_e> |Prolog variable |
| | <_N_u_m_b_e_r> |Prolog number |
| | +<_E_x_p_r_e_s_s_i_o_n> |unary plus |
| | -<_E_x_p_r_e_s_s_i_o_n> |unary minus |
| | <_E_x_p_r_e_s_s_i_o_n> + <_E_x_p_r_e_s_s_i_o_n> |addition |
| | <_E_x_p_r_e_s_s_i_o_n> - <_E_x_p_r_e_s_s_i_o_n> |substraction |
| | <_E_x_p_r_e_s_s_i_o_n> * <_E_x_p_r_e_s_s_i_o_n> |multiplication |
| | <_E_x_p_r_e_s_s_i_o_n> / <_E_x_p_r_e_s_s_i_o_n> |division |
| | abs(<_E_x_p_r_e_s_s_i_o_n>) |absolute value |
| | sin(<_E_x_p_r_e_s_s_i_o_n>) |sine |
| | cos(<_E_x_p_r_e_s_s_i_o_n>) |cosine |
| | tan(<_E_x_p_r_e_s_s_i_o_n>) |tangent |
| | exp(<_E_x_p_r_e_s_s_i_o_n>) |exponent |
| | pow(<_E_x_p_r_e_s_s_i_o_n>) |exponent |
| | <_E_x_p_r_e_s_s_i_o_n> ^ <_E_x_p_r_e_s_s_i_o_n> |exponent |
| | min(<_E_x_p_r_e_s_s_i_o_n>, <_E_x_p_r_e_s_s_i_o_n>) |minimum |
|_________________|_max(<_E_x_p_r_e_s_s_i_o_n>,_<_E_x_p_r_e_s_s_i_o_n>)_|maximum___________|
Table 11.1: CLP(Q,R) constraint BNF
1111..88..33 UUssee ooff uunniiffiiccaattiioonn
Instead of using the {}/1 predicate, you can also use the standard
unification mechanism to store constraints. The following code samples
are equivalent:
____________________________________________________________________| |
o _U_n_i_f_i_c_a_t_i_o_n_|_w_i_t_h{_aX_v_a_r_i_a_b_l_e=:= Y} |
| {X = Y} |
||X_=_Y_____________________________________________________________ ||
____________________________________________________________________| |
o _U_n_i_f_i_c_a_t_i_o_n_|_w_i_t_h{_aX_n_u_m_b_e_r=:= 5.0} |
| {X = 5.0} |
||X_=_5.0___________________________________________________________ ||
1111..88..44 NNoonn--lliinneeaarr ccoonnssttrraaiinnttss
The CLP(Q,R) system deals only passively with non-linear constraints.
They remain in a passive state until certain conditions are satisfied.
These conditions, which are called the isolation axioms, are given in
table 11.2.
______________________________________________________________
| A =B *C |B or C is ground |A = 5 * C or A = B * |
| | |4 |
| |A and (B or C) are|20 = 5 * C or 20 = B |
|______________|ground________________|*_4___________________|_
| A =B=C |C is ground |A = B / 3 |
|______________|A_and_B_are_ground____|4_=_12_/_C____________|_
| X =min(Y; Z) |Y and Z are ground |X = min(4,3) |
| X =max(Y; Z) |Y and Z are ground |X = max(4,3) |
|_X_=abs(Y_)___|Y_is_ground___________|X_=_abs(-7)___________|_
| X =pow(Y; Z) |X and Y are ground |8 = 2 ^ Z |
| X =exp(Y; Z) |X and Z are ground |8 = Y ^ 3 |
|_X_=Y__^_Z___|Y_and_Z_are_ground_____|X_=_2_^_3_____________|_
| X =sin(Y ) X|is ground |1 = sin(Y) |
| X =cos(Y ) Y|is ground |X = sin(1.5707) |
|_X_=tan(Y_)___|______________________|______________________|_
Table 11.2: CLP(Q,R) isolating axioms
1111..88..55 SSttaattuuss aanndd kknnoowwnn pprroobblleemmss
The clpq and clpr libraries are `orphaned', i.e., they currently have
no maintainer.
o _T_o_p_-_l_e_v_e_l _o_u_t_p_u_t
The top-level output may contain variables not present in the
original query:
____________________________________________________________________| |
| ?- {X+Y>=1}. |
| {Y=1-X+_G2160, _G2160>=0}. |
| |
||?-________________________________________________________________ ||
Nonetheless, for linear constraints this kind of answer means
unconditional satisfiability.
o _D_u_m_p_i_n_g _c_o_n_s_t_r_a_i_n_t_s
The first argument of dump/3 has to be a list of free variables at
call-time:
____________________________________________________________________| |
| ?- {X=1},dump([X],[Y],L). |
| ERROR: Unhandled exception: Unknown message: |
| instantiation_error(dump([1],[_G11],_G6),1) |
||?-________________________________________________________________ ||
1111..99 lliibbrraarryy((ccssvv)):: PPrroocceessss CCSSVV ((CCoommmmaa--SSeeppaarraatteedd VVaalluueess)) ddaattaa
SSeeee aallssoo RFC 4180
TToo bbee ddoonnee
- Implement immediate assert of the data to avoid possible
stack overflows.
- Writing creates an intermediate code-list, possibly
overflowing resources. This waits for pure output!
This library parses and generates CSV data. CSV data is represented in
Prolog as a list of rows. Each row is a compound term, where all rows
have the same name and arity.
ccssvv__rreeaadd__ffiillee((_+_F_i_l_e_, _-_R_o_w_s)) _[_d_e_t_]
ccssvv__rreeaadd__ffiillee((_+_F_i_l_e_, _-_R_o_w_s_, _+_O_p_t_i_o_n_s)) _[_d_e_t_]
Read a CSV file into a list of rows. Each row is a Prolog term
with the same arity. _O_p_t_i_o_n_s is handed to csv//2. Remaining
options are processed by phrase_from_file/3. The default separator
depends on the file name extension and is \t for .tsv files and ,
otherwise.
Suppose we want to create a predicate table/6 from a CSV file that
we know contains 6 fields per record. This can be done using the
code below. Without the option arity(6), this would generate a
predicate table/N, where N is the number of fields per record in
the data.
____________________________________________________________________| |
| ?- csv_read_file(File, Rows, [functor(table), arity(6)]), |
||___maplist(assert,_Rows)._________________________________________ ||
ccssvv((_?_R_o_w_s)) // _[_d_e_t_]
ccssvv((_?_R_o_w_s_, _+_O_p_t_i_o_n_s)) // _[_d_e_t_]
Prolog DCG to `read/write' CSV data. _O_p_t_i_o_n_s:
sseeppaarraattoorr((_+_C_o_d_e))
The comma-separator. Must be a character code. Default is
(of course) the comma. Character codes can be specified using
the 0' notion. E.g., using separator(0';) parses a semicolon
separated file.
iiggnnoorree__qquuootteess((_+_B_o_o_l_e_a_n))
If true (default false), threat double quotes as a normal
character.
ssttrriipp((_+_B_o_o_l_e_a_n))
If true (default false), strip leading and trailing blank
space. RFC4180 says that blank space is part of the data.
ccoonnvveerrtt((_+_B_o_o_l_e_a_n))
If true (default), use name/2 on the field data. This
translates the field into a number if possible.
ffuunnccttoorr((_+_A_t_o_m))
Functor to use for creating row terms. Default is row.
aarriittyy((_?_A_r_i_t_y))
Number of fields in each row. This predicate raises a
domain_error(row_arity(Expected), Found) if a row is found
with different arity.
mmaattcchh__aarriittyy((_+_B_o_o_l_e_a_n))
If false (default true), do not reject CSV files where lines
provide a varying number of fields (columns). This can be a
work-around to use some incorrect CSV files.
ccssvv__rreeaadd__ffiillee__rrooww((_+_F_i_l_e_, _-_R_o_w_, _+_O_p_t_i_o_n_s)) _[_n_o_n_d_e_t_]
True when _R_o_w is a row in _F_i_l_e. First unifies _R_o_w with the first
row in _F_i_l_e. Backtracking yields the second, ... row. This
interface is an alternative to csv_read_file/3that avoids loading
all rows in memory. Note that this interface does not guarantee
that all rows in _F_i_l_e have the same arity.
In addition to the options of csv_read_file/3, this predicate
processes the option:
lliinnee((_-_L_i_n_e))
_L_i_n_e is unified with the 1-based line-number from which _R_o_w is
read. Note that _L_i_n_e is not the physical line, but rather the
_l_o_g_i_c_a_l record number.
TToo bbee ddoonnee Input is read line by line. If a record
separator is embedded in a quoted field, parsing the
record fails and another line is added to the input.
This does not nicely deal with other reasons why
parsing the row may fail.
ccssvv__wwrriittee__ffiillee((_+_F_i_l_e_, _+_D_a_t_a)) _[_d_e_t_]
ccssvv__wwrriittee__ffiillee((_+_F_i_l_e_, _+_D_a_t_a_, _+_O_p_t_i_o_n_s)) _[_d_e_t_]
Write a list of Prolog terms to a CSV file. _O_p_t_i_o_n_s are given
to csv//2. Remaining options are given to open/4. The default
separator depends on the file name extension and is \t for .tsv
files and , otherwise.
ccssvv__wwrriittee__ssttrreeaamm((_+_S_t_r_e_a_m_, _+_D_a_t_a_, _+_O_p_t_i_o_n_s)) _[_d_e_t_]
Write the rows in _D_a_t_a to _S_t_r_e_a_m. This is similar to
csv_write_file/3, but can deal with data that is produced
incrementally. The example below saves all answers from the
predicate data/3 to File.
____________________________________________________________________| |
| save_data(File) :- |
| setup_call_cleanup( |
| open(File, write, Out), |
| forall(data(C1,C2,C3), |
| csv_write_stream(Out, [row(C1,C2,C3)], [])), |
||_______close(Out)),_______________________________________________ ||
1111..1100 lliibbrraarryy((ddeebbuugg)):: PPrriinntt ddeebbuugg mmeessssaaggeess aanndd tteesstt aasssseerrttiioonnss
aauutthhoorr Jan Wielemaker
This library is a replacement for format/3 for printing debug messages.
Messages are assigned a _t_o_p_i_c. By dynamically enabling or disabling
topics the user can select desired messages. Debug statements are
removed when the code is compiled for optimization.
See manual for details. With XPCE, you can use the call below to start
a graphical monitoring tool.
________________________________________________________________________| |
|?-|prolog_ide(debug_monitor).__________________________________________ | |
Using the predicate assertion/1 you can make assumptions about your
program explicit, trapping the debugger if the condition does not hold.
ddeebbuuggggiinngg((_+_T_o_p_i_c)) _[_s_e_m_i_d_e_t_]
ddeebbuuggggiinngg((_-_T_o_p_i_c)) _[_n_o_n_d_e_t_]
ddeebbuuggggiinngg((_?_T_o_p_i_c_, _?_B_o_o_l)) _[_n_o_n_d_e_t_]
Examine debug topics. The form debugging(+Topic) may be used to
perform more complex debugging tasks. A typical usage skeleton is:
____________________________________________________________________| |
| ( debugging(mytopic) |
| -> <perform debugging actions> |
| ; true |
| ), |
||______..._________________________________________________________ ||
The other two calls are intended to examine existing and enabled
debugging tokens and are typically not used in user programs.
ddeebbuugg((_+_T_o_p_i_c)) _[_d_e_t_]
nnooddeebbuugg((_+_T_o_p_i_c)) _[_d_e_t_]
Add/remove a topic from being printed. nodebug(_) removes all
topics. Gives a warning if the topic is not defined unless it is
used from a directive. The latter allows placing debug topics at
the start of a (load-)file without warnings.
For debug/1, _T_o_p_i_c can be a term _T_o_p_i_c > Out, where Out is either
a stream or stream-alias or a filename (atom). This redirects
debug information on this topic to the given output.
lliisstt__ddeebbuugg__ttooppiiccss _[_d_e_t_]
List currently known debug topics and their setting.
ddeebbuugg__mmeessssaaggee__ccoonntteexxtt((_+_W_h_a_t)) _[_d_e_t_]
Specify additional context for debug messages. _W_h_a_t is one
of +Context or -Context, and Context is one of thread, time
or time(Format), where Format is a format specification for
format_time/3 (default is %T.%3f). Initially, debug/3 shows only
thread information.
ddeebbuugg((_+_T_o_p_i_c_, _+_F_o_r_m_a_t_, _:_A_r_g_s)) _[_d_e_t_]
_F_o_r_m_a_t a message if debug topic is enabled. Similar to format/3 to
user_error, but only prints if _T_o_p_i_c is activated through debug/1.
_A_r_g_s is a meta-argument to deal with goal for the @-command.
Output is first handed to the hook prolog:debug_print_hook/3. If
this fails, _F_o_r_m_a_t+_A_r_g_s is translated to text using the message-
translation (see print_message/2) for the term debug(Format, Args)
and then printed to every matching destination (controlled by
debug/1) using print_message_lines/3.
The message is preceded by '% ' and terminated with a newline.
SSeeee aallssoo format/3.
pprroolloogg::ddeebbuugg__pprriinntt__hhooookk((_+_T_o_p_i_c_, _+_F_o_r_m_a_t_, _+_A_r_g_s)) _[_s_e_m_i_d_e_t_,_m_u_l_t_i_f_i_l_e_]
Hook called by debug/3. This hook is used by the graphical
frontend that can be activated using prolog_ide/1:
____________________________________________________________________| |
||?-_prolog_ide(debug_monitor)._____________________________________ ||
aasssseerrttiioonn((_:_G_o_a_l)) _[_d_e_t_]
Acts similar to C assert() macro. It has no effect if _G_o_a_l
succeeds. If _G_o_a_l fails or throws an exception, the following
steps are taken:
o call prolog:assertion_failed/2. If prolog:assertion_failed/2
fails, then:
{{ If this is an interactive toplevel thread, print a
message, the stack-trace, and finally trap the debugger.
{{ Otherwise, throw error(assertion_error(Reason, G),_) where
Reason is one of fail or the exception raised.
pprroolloogg::aasssseerrttiioonn__ffaaiilleedd((_+_R_e_a_s_o_n_, _+_G_o_a_l)) _[_s_e_m_i_d_e_t_,_m_u_l_t_i_f_i_l_e_]
This hook is called if the _G_o_a_l of assertion/1 fails. _R_e_a_s_o_n is
unified with either fail if _G_o_a_l simply failed or an exception call
otherwise. If this hook fails, the default behaviour is activated.
If the hooks throws an exception it will be propagated into the
caller of assertion/1.
1111..1111 lliibbrraarryy((ggeennssyymm)):: GGeenneerraattee uunniiqquuee iiddeennttiiffiieerrss
Gensym (GGeennerate SSyymmbols) is an old library for generating unique
symbols (atoms). Such symbols are generated from a base atom which
gets a sequence number appended. Of course there is no guarantee that
`catch22' is not an already defined atom and therefore one must be
aware these atoms are only unique in an isolated context.
The SWI-Prolog gensym library is thread-safe. The sequence numbers are
global over all threads and therefore generated atoms are unique over
all threads.
ggeennssyymm((_+_B_a_s_e_, _-_U_n_i_q_u_e))
Generate a unique atom from base _B_a_s_e and unify it with _U_n_i_q_u_e.
_B_a_s_e should be an atom. The first call will return <_b_a_s_e>1, the
next <_b_a_s_e>2, etc. Note that this is no guarantee that the atom is
unique in the system.
rreesseett__ggeennssyymm((_+_B_a_s_e))
Restart generation of identifiers from _B_a_s_e at <_B_a_s_e>1. Used to
make sure a program produces the same results on subsequent runs.
Use with care.
rreesseett__ggeennssyymm
Reset gensym for all registered keys. This predicate is available
for compatibility only. New code is strongly advised to avoid the
use of reset_gensym or at least to reset only the keys used by your
program to avoid unexpected side effects on other components.
1111..1122 lliibbrraarryy((lliissttss)):: LLiisstt MMaanniippuullaattiioonn
CCoommppaattiibbiilliittyy Virtually every Prolog system has
library(lists), but the set of provided predicates
is diverse. There is a fair agreement on the semantics
of most of these predicates, although error handling may
vary.
This library provides commonly accepted basic predicates for list
manipulation in the Prolog community. Some additional list
manipulations are built-in. See e.g., memberchk/2, length/2.
The implementation of this library is copied from many places. These
include: "The Craft of Prolog", the DEC-10 Prolog library (LISTRO.PL)
and the YAP lists library. Some predicates are reimplemented based on
their specification by Quintus and SICStus.
mmeemmbbeerr((_?_E_l_e_m_, _?_L_i_s_t))
True if _E_l_e_m is a member of _L_i_s_t. The SWI-Prolog definition
differs from the classical one. Our definition avoids unpacking
each list element twice and provides determinism on the last
element. E.g. this is deterministic:
____________________________________________________________________| |
||____member(X,_[One])._____________________________________________ ||
aauutthhoorr Gertjan van Noord
aappppeenndd((_?_L_i_s_t_1_, _?_L_i_s_t_2_, _?_L_i_s_t_1_A_n_d_L_i_s_t_2))
_L_i_s_t_1_A_n_d_L_i_s_t_2 is the concatenation of _L_i_s_t_1 and _L_i_s_t_2
aappppeenndd((_+_L_i_s_t_O_f_L_i_s_t_s_, _?_L_i_s_t))
Concatenate a list of lists. Is true if _L_i_s_t_O_f_L_i_s_t_s is a list of
lists, and _L_i_s_t is the concatenation of these lists.
___________________________________________________________Arguments_
_L_i_s_t_O_f_L_i_s_t_s must be a list of _p_o_s_s_i_b_l_y partial lists
pprreeffiixx((_?_P_a_r_t_, _?_W_h_o_l_e))
True iff _P_a_r_t is a leading substring of _W_h_o_l_e. This is the same as
append(Part, _, Whole).
sseelleecctt((_?_E_l_e_m_, _?_L_i_s_t_1_, _?_L_i_s_t_2))
Is true when _L_i_s_t_1, with _E_l_e_m removed, results in _L_i_s_t_2.
sseelleeccttcchhkk((_+_E_l_e_m_, _+_L_i_s_t_, _-_R_e_s_t)) _[_s_e_m_i_d_e_t_]
Semi-deterministic removal of first element in _L_i_s_t that unifies
with _E_l_e_m.
sseelleecctt((_?_X_, _?_X_L_i_s_t_, _?_Y_, _?_Y_L_i_s_t)) _[_n_o_n_d_e_t_]
Select from two lists at the same positon. True if _X_L_i_s_t is
unifiable with _Y_L_i_s_t apart a single element at the same position
that is unified with _X in _X_L_i_s_t and with _Y in _Y_L_i_s_t. A typical
use for this predicate is to _r_e_p_l_a_c_e an element, as shown in
the example below. All possible substitutions are performed on
backtracking.
____________________________________________________________________| |
| ?- select(b, [a,b,c,b], 2, X). |
| X = [a, 2, c, b] ; |
| X = [a, b, c, 2] ; |
||false.____________________________________________________________ ||
SSeeee aallssoo selectchk/4 provides a semidet version.
sseelleeccttcchhkk((_?_X_, _?_X_L_i_s_t_, _?_Y_, _?_Y_L_i_s_t)) _[_s_e_m_i_d_e_t_]
Semi-deterministic version of select/4.
nneexxttttoo((_?_X_, _?_Y_, _?_L_i_s_t))
True if _Y follows _X in _L_i_s_t.
ddeelleettee((_+_L_i_s_t_1_, _@_E_l_e_m_, _-_L_i_s_t_2)) _[_d_e_t_]
Delete matching elements from a list. True when _L_i_s_t_2 is a list
with all elements from _L_i_s_t_1 except for those that unify with _E_l_e_m.
Matching _E_l_e_m with elements of _L_i_s_t_1 is uses \+ Elem \= H, which
implies that _E_l_e_m is not changed.
SSeeee aallssoo select/3, subtract/3.
ddeepprreeccaatteedd There are too many ways in which one might
want to delete elements from a list to justify the
name. Think of matching (= vs. ==), delete
first/all, be deterministic or not.
nntthh00((_?_I_n_d_e_x_, _?_L_i_s_t_, _?_E_l_e_m))
True when _E_l_e_m is the _I_n_d_e_x'th element of _L_i_s_t. Counting starts at
0.
EErrrroorrss type_error(integer, Index) if _I_n_d_e_x is not an
integer or unbound.
SSeeee aallssoo nth1/3.
nntthh11((_?_I_n_d_e_x_, _?_L_i_s_t_, _?_E_l_e_m))
Is true when _E_l_e_m is the _I_n_d_e_x'th element of _L_i_s_t. Counting starts
at 1.
SSeeee aallssoo nth0/3.
nntthh00((_?_N_, _?_L_i_s_t_, _?_E_l_e_m_, _?_R_e_s_t)) _[_d_e_t_]
Select/insert element at index. True when _E_l_e_m is the _N'th
(0-based) element of _L_i_s_t and _R_e_s_t is the remainder (as in by
select/3) of _L_i_s_t. For example:
____________________________________________________________________| |
| ?- nth0(I, [a,b,c], E, R). |
| I = 0, E = a, R = [b, c] ; |
| I = 1, E = b, R = [a, c] ; |
| I = 2, E = c, R = [a, b] ; |
||false.____________________________________________________________ ||
____________________________________________________________________| |
| ?- nth0(1, L, a1, [a,b]). |
||L_=_[a,_a1,_b].___________________________________________________ ||
nntthh11((_?_N_, _?_L_i_s_t_, _?_E_l_e_m_, _?_R_e_s_t)) _[_d_e_t_]
As nth0/4, but counting starts at 1.
llaasstt((_?_L_i_s_t_, _?_L_a_s_t))
Succeeds when _L_a_s_t is the last element of _L_i_s_t. This predicate is
semidet if _L_i_s_t is a list and multi if _L_i_s_t is a partial list.
CCoommppaattiibbiilliittyy There is no de-facto standard for the
argument order of last/2. Be careful when porting
code or use append(_, [Last], List) as a portable
alternative.
pprrooppeerr__lleennggtthh((_@_L_i_s_t_, _-_L_e_n_g_t_h)) _[_s_e_m_i_d_e_t_]
True when _L_e_n_g_t_h is the number of elements in the proper list _L_i_s_t.
This is equivalent to
____________________________________________________________________| |
| proper_length(List, Length) :- |
| is_list(List), |
||______length(List,_Length)._______________________________________ ||
ssaammee__lleennggtthh((_?_L_i_s_t_1_, _?_L_i_s_t_2))
Is true when _L_i_s_t_1 and _L_i_s_t_2 are lists with the same number of
elements. The predicate is deterministic if at least one of the
arguments is a proper list. It is non-deterministic if both
arguments are partial lists.
SSeeee aallssoo length/2
rreevveerrssee((_?_L_i_s_t_1_, _?_L_i_s_t_2))
Is true when the elements of _L_i_s_t_2 are in reverse order compared to
_L_i_s_t_1.
ppeerrmmuuttaattiioonn((_?_X_s_, _?_Y_s)) _[_n_o_n_d_e_t_]
True when _X_s is a permutation of _Y_s. This can solve for
_Y_s given _X_s or _X_s given _Y_s, or even enumerate _X_s and _Y_s
together. The predicate permutation/2 is primarily intended
to generate permutations. Note that a list of length N has
N! permutations, and unbounded permutation generation becomes
prohibitively expensive, even for rather short lists (10! =
3,628,800).
If both _X_s and _Y_s are provided and both lists have equal length the
order is |_X_s|^2. Simply testing whether _X_s is a permutation of _Y_s
can be achieved in order log(|_X_s|) using msort/2 as illustrated
below with the semidet predicate is_permutation/2:
____________________________________________________________________| |
| is_permutation(Xs, Ys) :- |
| msort(Xs, Sorted), |
||__msort(Ys,_Sorted).______________________________________________ ||
The example below illustrates that _X_s and _Y_s being proper lists is
not a sufficient condition to use the above replacement.
____________________________________________________________________| |
| ?- permutation([1,2], [X,Y]). |
| X = 1, Y = 2 ; |
| X = 2, Y = 1 ; |
||false.____________________________________________________________ ||
EErrrroorrss type_error(list, Arg) if either argument is not a
proper or partial list.
ffllaatttteenn((_+_L_i_s_t_1_, _?_L_i_s_t_2)) _[_d_e_t_]
Is true if _L_i_s_t_2 is a non-nested version of _L_i_s_t_1.
SSeeee aallssoo append/2
ddeepprreeccaatteedd Ending up needing flatten/3 often indicates,
like append/3 for appending two lists, a bad design.
Efficient code that generates lists from generated
small lists must use difference lists, often possible
through grammar rules for optimal readability.
mmaaxx__mmeemmbbeerr((_-_M_a_x_, _+_L_i_s_t)) _[_s_e_m_i_d_e_t_]
True when _M_a_x is the largest member in the standard order of terms.
Fails if _L_i_s_t is empty.
SSeeee aallssoo
- compare/3
- max_list/2 for the maximum of a list of numbers.
mmiinn__mmeemmbbeerr((_-_M_i_n_, _+_L_i_s_t)) _[_s_e_m_i_d_e_t_]
True when _M_i_n is the smallest member in the standard order of
terms. Fails if _L_i_s_t is empty.
SSeeee aallssoo
- compare/3
- min_list/2 for the minimum of a list of numbers.
ssuumm__lliisstt((_+_L_i_s_t_, _-_S_u_m)) _[_d_e_t_]
_S_u_m is the result of adding all numbers in _L_i_s_t.
mmaaxx__lliisstt((_+_L_i_s_t_:_l_i_s_t_(_n_u_m_b_e_r_)_, _-_M_a_x_:_n_u_m_b_e_r)) _[_s_e_m_i_d_e_t_]
True if _M_a_x is the largest number in _L_i_s_t. Fails if _L_i_s_t is empty.
SSeeee aallssoo max_member/2.
mmiinn__lliisstt((_+_L_i_s_t_:_l_i_s_t_(_n_u_m_b_e_r_)_, _-_M_i_n_:_n_u_m_b_e_r)) _[_s_e_m_i_d_e_t_]
True if _M_i_n is the smallest number in _L_i_s_t. Fails if _L_i_s_t is
empty.
SSeeee aallssoo min_member/2.
nnuummlliisstt((_+_L_o_w_, _+_H_i_g_h_, _-_L_i_s_t)) _[_s_e_m_i_d_e_t_]
_L_i_s_t is a list [_L_o_w, _L_o_w+1, ... _H_i_g_h]. Fails if _H_i_g_h < _L_o_w.
EErrrroorrss
- type_error(integer, Low)
- type_error(integer, High)
iiss__sseett((_@_S_e_t)) _[_d_e_t_]
True if _S_e_t is a proper list without duplicates. Equivalence is
based on ==/2. The implementation uses sort/2, which implies
that the complexity is N*log(N) and the predicate may cause a
resource-error. There are no other error conditions.
lliisstt__ttoo__sseett((_+_L_i_s_t_, _?_S_e_t)) _[_d_e_t_]
True when _S_e_t has the same elements as _L_i_s_t in the same order. The
left-most copy of duplicate elements is retained. _L_i_s_t may contain
variables. Elements _E_1 and _E_2 are considered duplicates iff _E_1 ==
_E_2 holds. The complexity of the implementation is N*log(N).
EErrrroorrss _L_i_s_t is type-checked.
aauutthhoorr Ulrich Neumerkel
SSeeee aallssoo sort/2 can be used to create an ordered set.
Many set operations on ordered sets are order N
rather than order N**2. The list_to_set/2 predicate
is is more expensive than sort/2 because it involves,
in addition to a sort, three linear scans of the
list.
CCoommppaattiibbiilliittyy Up to version 6.3.11, list_to_set/2 had
complexity N**2 and equality was tested using =/2.
iinntteerrsseeccttiioonn((_+_S_e_t_1_, _+_S_e_t_2_, _-_S_e_t_3)) _[_d_e_t_]
True if _S_e_t_3 unifies with the intersection of _S_e_t_1 and _S_e_t_2. The
complexity of this predicate is |_S_e_t_1|*|_S_e_t_2|
SSeeee aallssoo ord_intersection/3.
uunniioonn((_+_S_e_t_1_, _+_S_e_t_2_, _-_S_e_t_3)) _[_d_e_t_]
True if _S_e_t_3 unifies with the union of _S_e_t_1 and _S_e_t_2. The
complexity of this predicate is |_S_e_t_1|*|_S_e_t_2|
SSeeee aallssoo ord_union/3.
ssuubbsseett((_+_S_u_b_S_e_t_, _+_S_e_t)) _[_s_e_m_i_d_e_t_]
True if all elements of _S_u_b_S_e_t belong to _S_e_t as well. Membership
test is based on memberchk/2. The complexity is |_S_u_b_S_e_t|*|_S_e_t|.
SSeeee aallssoo ord_subset/2.
ssuubbttrraacctt((_+_S_e_t_, _+_D_e_l_e_t_e_, _-_R_e_s_u_l_t)) _[_d_e_t_]
_D_e_l_e_t_e all elements in _D_e_l_e_t_e from _S_e_t. Deletion is based on
unification using memberchk/2. The complexity is |_D_e_l_e_t_e|*|_S_e_t|.
SSeeee aallssoo ord_subtract/3.
1111..1133 lliibbrraarryy((nnbb__sseett)):: NNoonn--bbaacckkttrraacckkaabbllee sseett
The library nb_set defines _n_o_n_-_b_a_c_k_t_r_a_c_k_a_b_l_e _s_e_t_s, implemented as
binary trees. The sets are represented as compound terms and
manipulated using nb_setarg/3. Non-backtrackable manipulation of
datastructures is not supported by a large number of Prolog
implementations, but it has several advantages over using the database.
It produces less garbage, is thread-safe, reentrant and deals with
exceptions without leaking data.
Similar to the assoc library, keys can be any Prolog term, but it is
not allowed to instantiate or modify a term.
One of the ways to use this library is to generate unique values on
backtracking _w_i_t_h_o_u_t generating _a_l_l solutions first, for example to
act as a filter between a generator producing many duplicates and an
expensive test routine, as outlined below:
________________________________________________________________________| |
|generate_and_test(Solution) :- |
| empty_nb_set(Set), |
| generate(Solution), |
| add_nb_set(Solution, Set, true), |
||_______test(Solution).________________________________________________ ||
eemmppttyy__nnbb__sseett((_?_S_e_t))
True if _S_e_t is a non-backtrackable empty set.
aadddd__nnbb__sseett((_+_K_e_y_, _!_S_e_t))
Add _K_e_y to _S_e_t. If _K_e_y is already a member of _S_e_t, add_nb_set/3
succeeds without modifying _S_e_t.
aadddd__nnbb__sseett((_+_K_e_y_, _!_S_e_t_, _?_N_e_w))
If _K_e_y is not in _S_e_t and _N_e_w is unified to true, _K_e_y is added to
_S_e_t. If _K_e_y is in _S_e_t, _N_e_w is unified to false. It can be used
for many purposes:
add_nb_set(+, +, false) Test membership
add_nb_set(+, +, true) Succeed only if new member
add_nb_set(+, +, Var) Succeed, binding _V_a_r
ggeenn__nnbb__sseett((_+_S_e_t_, _-_K_e_y))
Generate all members of _S_e_t on backtracking in the standard order
of terms. To test membership, use add_nb_set/3.
ssiizzee__nnbb__sseett((_+_S_e_t_, _-_S_i_z_e))
Unify _S_i_z_e with the number of elements in _S_e_t.
nnbb__sseett__ttoo__lliisstt((_+_S_e_t_, _-_L_i_s_t))
Unify _L_i_s_t with a list of all elements in _S_e_t in the standard order
of terms (i.e., an _o_r_d_e_r_e_d _l_i_s_t).
1111..1144 lliibbrraarryy((wwwwww__bbrroowwsseerr)):: AAccttiivvaattiinngg yyoouurr WWeebb--bbrroowwsseerr
This library deals with the very system-dependent task of opening a web
page in a browser. See also url and the HTTP package.
wwwwww__ooppeenn__uurrll((_+_U_R_L))
Open _U_R_L in an external web browser. The reason to place this
in the library is to centralise the maintenance on this highly
platform- and browser-specific task. It distinguishes between the
following cases:
o _M_S_-_W_i_n_d_o_w_s
If it detects MS-Windows it uses win_shell/2 to open the _U_R_L.
The behaviour and browser started depends on the version of
Windows and Windows-shell configuration, but in general it
should be the behaviour expected by the user.
o _O_t_h_e_r _p_l_a_t_f_o_r_m_s
On other platforms it tests the environment variable (see
getenv/2) named BROWSER or uses netscape if this variable is
not set. If the browser is either mozilla or netscape,
www_open_url/1 first tries to open a new window on a running
browser using the -remote option of Netscape. If this fails
or the browser is not mozilla or netscape the system simply
passes the URL as first argument to the program.
1111..1155 lliibbrraarryy((ooppttiioonn)):: OOppttiioonn lliisstt pprroocceessssiinngg
SSeeee aallssoo
- library(record)
- Option processing capabilities may be declared using the
directive predicate_options/3.
TToo bbee ddoonnee We should consider putting many options in an assoc
or record with appropriate preprocessing to achieve better
performance.
The library(option) provides some utilities for processing option
lists. Option lists are commonly used as an alternative for
many arguments. Examples of built-in predicates are open/4 and
write_term/3. Naming the arguments results in more readable code, and
the list nature makes it easy to extend the list of options accepted
by a predicate. Option lists come in two styles, both of which are
handled by this library.
NNaammee((VVaalluuee)) This is the preferred style.
NNaammee == VVaalluuee This is often used, but deprecated.
Processing options inside time-critical code (loops) can cause serious
overhead. One possibility is to define a record using library(record)
and initialise this using make_<record>/2. In addition to providing
good performance, this also provides type-checking and central
declaration of defaults.
________________________________________________________________________| |
|:- record atts(width:integer=100, shape:oneof([box,circle])=box). |
| |
|process(Data, Options) :- |
| make_atts(Options, Attributes), |
| action(Data, Attributes). |
| |
|action(Data, Attributes) :- |
| atts_shape(Attributes, Shape), |
||_______...____________________________________________________________ ||
Options typically have exactly one argument. The library does
support options with 0 or more than one argument with the following
restrictions:
o The predicate option/3 and select_option/4, involving default
are meaningless. They perform an arg(1, Option, Default),
causing failure without arguments and filling only the first
option-argument otherwise.
o meta_options/3 can only qualify options with exactly one argument.
ooppttiioonn((_?_O_p_t_i_o_n_, _+_O_p_t_i_o_n_L_i_s_t_, _+_D_e_f_a_u_l_t)) _[_s_e_m_i_d_e_t_]
Get an _O_p_t_i_o_n Qfrom _O_p_t_i_o_n_L_i_s_t. _O_p_t_i_o_n_L_i_s_t can use the Name=Value
as well as the Name(Value) convention.
___________________________________________________________Arguments_
_O_p_t_i_o_n Term of the form Name(?Value).
ooppttiioonn((_?_O_p_t_i_o_n_, _+_O_p_t_i_o_n_L_i_s_t)) _[_s_e_m_i_d_e_t_]
Get an _O_p_t_i_o_n from _O_p_t_i_o_n_L_i_s_t. _O_p_t_i_o_n_L_i_s_t can use the Name=Value
as well as the Name(Value) convention. Fails silently if the
option does not appear in _O_p_t_i_o_n_L_i_s_t.
___________________________________________________________Arguments_
_O_p_t_i_o_n Term of the form Name(?Value).
sseelleecctt__ooppttiioonn((_?_O_p_t_i_o_n_, _+_O_p_t_i_o_n_s_, _-_R_e_s_t_O_p_t_i_o_n_s)) _[_s_e_m_i_d_e_t_]
Get and remove _O_p_t_i_o_n from an option list. As option/2, removing
the matching option from _O_p_t_i_o_n_s and unifying the remaining options
with _R_e_s_t_O_p_t_i_o_n_s.
sseelleecctt__ooppttiioonn((_?_O_p_t_i_o_n_, _+_O_p_t_i_o_n_s_, _-_R_e_s_t_O_p_t_i_o_n_s_, _+_D_e_f_a_u_l_t)) _[_d_e_t_]
Get and remove _O_p_t_i_o_n with default value. As select_option/3, but
if _O_p_t_i_o_n is not in _O_p_t_i_o_n_s, its value is unified with _D_e_f_a_u_l_t and
_R_e_s_t_O_p_t_i_o_n_s with _O_p_t_i_o_n_s.
mmeerrggee__ooppttiioonnss((_+_N_e_w_, _+_O_l_d_, _-_M_e_r_g_e_d)) _[_d_e_t_]
Merge two option lists. _M_e_r_g_e_d is a sorted list of options using
the canonical format Name(Value) holding all options from _N_e_w and
_O_l_d, after removing conflicting options from _O_l_d.
Multi-values options (e.g., proxy(Host, Port)) are allowed, where
both option-name and arity define the identity of the option.
mmeettaa__ooppttiioonnss((_+_I_s_M_e_t_a_, _:_O_p_t_i_o_n_s_0_, _-_O_p_t_i_o_n_s)) _[_d_e_t_]
Perform meta-expansion on options that are module-sensitive.
Whether an option name is module-sensitive is determined by calling
call(IsMeta, Name). Here is an example:
____________________________________________________________________| |
| meta_options(is_meta, OptionsIn, Options), |
| ... |
| |
||is_meta(callback).________________________________________________ ||
Meta-options must have exactly one argument. This argument will be
qualified.
TToo bbee ddoonnee Should be integrated with declarations from
predicate_options/3.
1111..1166 lliibbrraarryy((ooppttppaarrssee)):: ccoommmmaanndd lliinnee ppaarrssiinngg
aauutthhoorr Marcus Uneson
vveerrssiioonn 0.20 (2011-04-27)
TToo bbee ddoonnee : validation? e.g, numbers; file path existence;
one-out-of-a-set-of-atoms
This module helps in building a command-line interface to an
application. In particular, it provides functions that take an option
specification and a list of atoms, probably given to the program on
the command line, and return a parsed representation (a list of the
customary Key(Val) by default; or optionally, a list of Func(Key, Val)
terms in the style of current_prolog_flag/2). It can also synthesize a
simple help text from the options specification.
The terminology in the following is partly borrowed from python,
see http://docs.python.org/library/optparse.html#terminology . Very
briefly, _a_r_g_u_m_e_n_t_s is what you provide on the command line
and for many prologs show up as a list of atoms Args in
current_prolog_flag(argv, Args). For a typical prolog incantation,
they can be divided into
o _r_u_n_t_i_m_e _a_r_g_u_m_e_n_t_s, which controls the prolog runtime; convention-
ally, they are ended by '--';
o _o_p_t_i_o_n_s, which are key-value pairs (with a boolean value possibly
implicit) intended to control your program in one way or another;
and
o _p_o_s_i_t_i_o_n_a_l _a_r_g_u_m_e_n_t_s, which is what remains after all runtime
arguments and options have been removed (with implicit arguments --
true/false for booleans -- filled in).
Positional arguments are in particular used for mandatory arguments
without which your program won't work and for which there are no
sensible defaults (e.g,, input file names). Options, by contrast,
offer flexibility by letting you change a default setting. Options
are optional not only by etymology: this library has no notion of
mandatory or required options (see the python docs for other rationales
than laziness).
The command-line arguments enter your program as a list of atoms, but
the programs perhaps expects booleans, integers, floats or even prolog
terms. You tell the parser so by providing an _o_p_t_i_o_n_s _s_p_e_c_i_f_i_c_a_t_i_o_n.
This is just a list of individual option specifications. One of those,
in turn, is a list of ground prolog terms in the customary Name(Value)
format. The following terms are recognized (any others raise error).
oopptt((_K_e_y))
_K_e_y is what the option later will be accessed by, just like for
current_prolog_flag(Key, Value). This term is mandatory (an error
is thrown if missing).
sshhoorrttffllaaggss((_L_i_s_t_O_f_F_l_a_g_s))
_L_i_s_t_O_f_F_l_a_g_s denotes any single-dashed, single letter args specify-
ing the current option (-s , -K, etc). Uppercase letters must
be quoted. Usually _L_i_s_t_O_f_F_l_a_g_s will be a singleton list, but
sometimes aliased flags may be convenient.
lloonnggffllaaggss((_L_i_s_t_O_f_F_l_a_g_s))
_L_i_s_t_O_f_F_l_a_g_s denotes any double-dashed arguments specifying the
current option (--verbose, --no-debug, etc). They are basically a
more readable alternative to short flags, except
1. long flags can be specified as --flag value or --flag=value (but
not as --flagvalue); short flags as -f val or -fval (but not
-f=val)
2. boolean long flags can be specified as --bool-flag or
--bool-flag=true or --bool-flag true; and they can be negated as
--no-bool-flag or --bool-flag=false or --bool-flag false.
Except that shortflags must be single characters, the distinction
between long and short is in calling convention, not in namespaces.
Thus, if you have shortflags([v]), you can use it as -v2 or -v 2 or
--v=2 or --v 2 (but not -v=2 or --v2).
Shortflags and longflags both default to []. It can be useful to
have flagless options -- see example below.
mmeettaa((_M_e_t_a))
_M_e_t_a is optional and only relevant for the synthesized usage
message and is the name (an atom) of the metasyntactic variable
(possibly) appearing in it together with type and default value
(e.g, x:integer=3, interest:float=0.11). It may be useful to have
named variables (x, interest) in case you wish to mention them
again in the help text. If not given the Meta: part is suppressed
-- see example below.
ttyyppee((_T_y_p_e))
_T_y_p_e is one of boolean, atom, integer, float, term. The corre-
sponding argument will be parsed appropriately. This term is
optional; if not given, defaults to term.
ddeeffaauulltt((_D_e_f_a_u_l_t))
_D_e_f_a_u_l_t value. This term is optional; if not given, or if given
the special value '_', an uninstantiated variable is created (and
any type declaration is ignored).
hheellpp((_H_e_l_p))
_H_e_l_p is (usually) an atom of text describing the option in the help
text. This term is optional (but obviously strongly recommended
for all options which have flags).
Long lines are subject to basic word wrapping -- split on white
space, reindent, rejoin. However, you can get more control by
supplying the line breaking yourself: rather than a single line
of text, you can provide a list of lines (as atoms). If you do,
they will be joined with the appropriate indent but otherwise left
untouched (see the option mode in the example below).
Absence of mandatory option specs or the presence of more than one for
a particular option throws an error, as do unknown or incompatible
types.
As a concrete example from a fictive application, suppose we want the
following options to be read from the command line (long flag(s), short
flag(s), meta:type=default, help)
________________________________________________________________________| |
|--mode -m atom=SCAN data gathering mode, |
| one of |
| SCAN: do this |
| READ: do that |
| MAKE: make numbers |
| WAIT: do nothing |
|--rebuild-cache -r boolean=true rebuild cache in |
| each iteration |
|--heisenberg-threshold -t,-h float=0.1 heisenberg threshold |
|--depths, --iters -i,-d K:integer=3 stop after K |
| iterations |
|--distances term=[1,2,3,5] initial prolog term |
|--output-file -o FILE:atom=_ write output to FILE |
|--label -l atom=REPORT report label |
|--verbosity -v V:integer=2 verbosity level, |
||______________________________________________1_<=_V_<=_3_____________ ||
We may also have some configuration parameters which we currently
think not needs to be controlled from the command line, say
path('/some/file/path').
This interface is described by the following options specification
(order between the specifications of a particular option is
irrelevant).
________________________________________________________________________| |
|ExampleOptsSpec = |
| [ [opt(mode ), type(atom), default('SCAN'), |
| shortflags([m]), longflags(['mode'] ), |
| help([ 'data gathering mode, one of' |
| , ' SCAN: do this' |
| , ' READ: do that' |
| , ' MAKE: fabricate some numbers' |
| , ' WAIT: don''t do anything'])] |
| |
| , [opt(cache), type(boolean), default(true), |
| shortflags([r]), longflags(['rebuild-cache']), |
| help('rebuild cache in each iteration')] |
| |
| , [opt(threshold), type(float), default(0.1), |
| shortflags([t,h]), longflags(['heisenberg-threshold']), |
| help('heisenberg threshold')] |
| |
| , [opt(depth), meta('K'), type(integer), default(3), |
| shortflags([i,d]),longflags([depths,iters]), |
| help('stop after K iterations')] |
| |
| , [opt(distances), default([1,2,3,5]), |
| longflags([distances]), |
| help('initial prolog term')] |
| |
| , [opt(outfile), meta('FILE'), type(atom), |
| shortflags([o]), longflags(['output-file']), |
| help('write output to FILE')] |
| |
| , [opt(label), type(atom), default('REPORT'), |
| shortflags([l]), longflags([label]), |
| help('report label')] |
| |
| , [opt(verbose), meta('V'), type(integer), default(2), |
| shortflags([v]), longflags([verbosity]), |
| help('verbosity level, 1 <= V <= 3')] |
| |
| , [opt(path), default('/some/file/path/')] |
||___]._________________________________________________________________ ||
The help text above was accessed by
opt_help(ExamplesOptsSpec, HelpText). The options appear in the
same order as in the OptsSpec.
Given ExampleOptsSpec, a command line (somewhat syntactically
inconsistent, in order to demonstrate different calling conventions)
may look as follows
________________________________________________________________________| |
|ExampleArgs = [ '-d5' |
| , '--heisenberg-threshold', '0.14' |
| , '--distances=[1,1,2,3,5,8]' |
| , '--iters', '7' |
| , '-ooutput.txt' |
| , '--rebuild-cache', 'true' |
| , 'input.txt' |
| , '--verbosity=2' |
||_____________]._______________________________________________________ ||
opt_parse(ExampleOptsSpec, ExampleArgs, Opts, PositionalArgs) would
then succeed with
________________________________________________________________________| |
|Opts = [ mode('SCAN') |
| , label('REPORT') |
| , path('/some/file/path') |
| , threshold(0.14) |
| , distances([1,1,2,3,5,8]) |
| , depth(7) |
| , outfile('output.txt') |
| , cache(true) |
| , verbose(2) |
| ], |
|PositionalArgs|=_['input.txt'].________________________________________ | |
Note that path('/some/file/path') showing up in Opts has a default
value (of the implicit type 'term'), but no corresponding flags
in OptsSpec. Thus it can't be set from the command line.
The rest of your program doesn't need to know that, of course.
This provides an alternative to the common practice of asserting
such hard-coded parameters under a single predicate (for instance
setting(path, '/some/file/path')), with the advantage that you may
seamlessly upgrade them to command-line options, should you one day
find this a good idea. Just add an appropriate flag or two and a
line of help text. Similarly, suppressing an option in a cluttered
interface amounts to commenting out the flags.
opt_parse/5 allows more control through an additional argument list as
shown in the example below.
________________________________________________________________________| |
|?- opt_parse(ExampleOptsSpec, ExampleArgs, Opts, PositionalArgs, |
| [ output_functor(appl_config) |
| ]). |
| |
|Opts = [ appl_config(verbose, 2), |
| , appl_config(label, 'REPORT') |
| ... |
||_________]____________________________________________________________ ||
This representation may be preferable with the empty-flag configuration
parameter style above (perhaps with asserting appl_config/2).
1111..1166..11 NNootteess aanndd ttiippss
o In the example we were mostly explicit about the types. Since
the default is term, which subsumes integer, float, atom, it may
be possible to get away cheaper (e.g., by only giving booleans).
However, it is recommended practice to always specify types:
parsing becomes more reliable and error messages will be easier to
interpret.
o Note that -sbar is taken to mean -s bar, not -s -b -a -r, that is,
there is no clustering of flags.
o -s=foo is disallowed. The rationale is that although some
command-line parsers will silently interpret this as -s =foo, this
is very seldom what you want. To have an option argument start
with '=' (very un-recommended), say so explicitly.
o The example specifies the option depth twice: once as -d5 and
once as --iters 7. The default when encountering duplicated flags
is to keeplast (this behaviour can be controlled, by ParseOption
duplicated_flags).
o The order of the options returned by the parsing functions is the
same as given on the command line, with non-overridden defaults
prepended and duplicates removed as in previous item. You should
not rely on this, however.
o Unknown flags (not appearing in OptsSpec) will throw errors. This
is usually a Good Thing. Sometimes, however, you may wish to pass
along flags to an external program (say, one called by shell/2),
and it means duplicated effort and a maintenance headache to have
to specify all possible flags for the external program explicitly
(if it even can be done). On the other hand, simply taking all
unknown flags as valid makes error checking much less efficient
and identification of positional arguments uncertain. A better
solution is to collect all arguments intended for passing along to
an indirectly called program as a single argument, probably as an
atom (if you don't need to inspect them first) or as a prolog term
(if you do).
oopptt__aarrgguummeennttss((_+_O_p_t_s_S_p_e_c_, _-_O_p_t_s_, _-_P_o_s_i_t_i_o_n_a_l_A_r_g_s)) _[_d_e_t_]
Extract commandline options according to a specification. Con-
venience predicate, assuming that command-line arguments can be
accessed by current_prolog_flag/2 (as in swi-prolog). For other
access mechanisms and/or more control, get the args and pass them
as a list of atoms to opt_parse/4 or opt_parse/5 instead.
_O_p_t_s is a list of parsed options in the form Key(Value). Dashed
args not in _O_p_t_s_S_p_e_c are not permitted and will raise error (see
tip on how to pass unknown flags in the module description).
_P_o_s_i_t_i_o_n_a_l_A_r_g_s are the remaining non-dashed args after each flag
has taken its argument (filling in true or false for booleans).
There are no restrictions on non-dashed arguments and they may go
anywhere (although it is good practice to put them last). Any
leading arguments for the runtime (up to and including '--') are
discarded.
oopptt__ppaarrssee((_+_O_p_t_s_S_p_e_c_, _+_A_p_p_l_A_r_g_s_, _-_O_p_t_s_, _-_P_o_s_i_t_i_o_n_a_l_A_r_g_s)) _[_d_e_t_]
Equivalent to opt_parse(OptsSpec, ApplArgs, Opts, PositionalArgs, []).
oopptt__ppaarrssee((_+_O_p_t_s_S_p_e_c_, _+_A_p_p_l_A_r_g_s_, _-_O_p_t_s_, _-_P_o_s_i_t_i_o_n_a_l_A_r_g_s_, _+_P_a_r_s_e_O_p_t_i_o_n_s))_[_d_e_t_]
Parse the arguments Args (as list of atoms) according to _O_p_t_s_S_p_e_c.
Any runtime arguments (typically terminated by '--') are assumed to
be removed already.
_O_p_t_s is a list of parsed options in the form Key(Value), or (with
the option functor(Func) given) in the form Func(Key, Value).
Dashed args not in _O_p_t_s_S_p_e_c are not permitted and will raise error
(see tip on how to pass unknown flags in the module description).
_P_o_s_i_t_i_o_n_a_l_A_r_g_s are the remaining non-dashed args after each flag
has taken its argument (filling in true or false for booleans).
There are no restrictions on non-dashed arguments and they may
go anywhere (although it is good practice to put them last).
_P_a_r_s_e_O_p_t_i_o_n_s are
oouuttppuutt__ffuunnccttoorr((_F_u_n_c))
Set the functor _F_u_n_c of the returned options _F_u_n_c(Key,Value).
Default is the special value 'OPTION' (upper-case), which
makes the returned options have form Key(Value).
dduupplliiccaatteedd__ffllaaggss((_K_e_e_p))
Controls how to handle options given more than once on the
commad line. _K_e_e_p is one of keepfirst, keeplast, keepall with
the obvious meaning. Default is keeplast.
aallllooww__eemmppttyy__ffllaagg__ssppeecc((_B_o_o_l))
If true (default), a flag specification is not required (it
is allowed that both shortflags and longflags be either []
or absent). Flagless options cannot be manipulated from the
command line and will not show up in the generated help.
This is useful when you have (also) general configuration
parameters in your _O_p_t_s_S_p_e_c, especially if you think they one
day might need to be controlled externally. See example in
the module overview. allow_empty_flag_spec(false) gives the
more customary behaviour of raising error on empty flags.
oopptt__hheellpp((_+_O_p_t_s_S_p_e_c_, _-_H_e_l_p_:_a_t_o_m)) _[_d_e_t_]
True when _H_e_l_p is a help string synthesized from _O_p_t_s_S_p_e_c.
1111..1177 lliibbrraarryy((oorrddsseettss)):: OOrrddeerreedd sseett mmaanniippuullaattiioonn
Ordered sets are lists with unique elements sorted to the standard
order of terms (see sort/2). Exploiting ordering, many of the set
operations can be expressed in order N rather than N^2 when dealing
with unordered sets that may contain duplicates. The library(ordsets)
is available in a number of Prolog implementations. Our predicates are
designed to be compatible with common practice in the Prolog community.
The implementation is incomplete and relies partly on library(oset),
an older ordered set library distributed with SWI-Prolog. New
applications are advised to use library(ordsets).
Some of these predicates match directly to corresponding list
operations. It is advised to use the versions from this library
to make clear you are operating on ordered sets. An exception is
member/2. See ord_memberchk/2.
The ordsets library is based on the standard order of terms. This
implies it can handle all Prolog terms, including variables. Note
however, that the ordering is not stable if a term inside the set is
further instantiated. Also note that variable ordering changes if
variables in the set are unified with each other or a variable in the
set is unified with a variable that is `older' than the newest variable
in the set. In practice, this implies that it is allowed to use
member(X, OrdSet) on an ordered set that holds variables only if X is a
fresh variable. In other cases one should cease using it as an ordset
because the order it relies on may have been changed.
iiss__oorrddsseett((_@_T_e_r_m)) _[_s_e_m_i_d_e_t_]
True if _T_e_r_m is an ordered set. All predicates in this library
expect ordered sets as input arguments. Failing to fullfil this
assumption results in undefined behaviour. Typically, ordered sets
are created by predicates from this library, sort/2 or setof/3.
oorrdd__eemmppttyy((_?_L_i_s_t)) _[_s_e_m_i_d_e_t_]
True when _L_i_s_t is the empty ordered set. Simply unifies list with
the empty list. Not part of Quintus.
oorrdd__sseetteeqq((_+_S_e_t_1_, _+_S_e_t_2)) _[_s_e_m_i_d_e_t_]
True if _S_e_t_1 and _S_e_t_2 have the same elements. As both are
canonical sorted lists, this is the same as ==/2.
CCoommppaattiibbiilliittyy sicstus
lliisstt__ttoo__oorrdd__sseett((_+_L_i_s_t_, _-_O_r_d_S_e_t)) _[_d_e_t_]
Transform a list into an ordered set. This is the same as sorting
the list.
oorrdd__iinntteerrsseecctt((_+_S_e_t_1_, _+_S_e_t_2)) _[_s_e_m_i_d_e_t_]
True if both ordered sets have a non-empty intersection.
oorrdd__ddiissjjooiinntt((_+_S_e_t_1_, _+_S_e_t_2)) _[_s_e_m_i_d_e_t_]
True if _S_e_t_1 and _S_e_t_2 have no common elements. This is the
negation of ord_intersect/2.
oorrdd__iinntteerrsseecctt((_+_S_e_t_1_, _+_S_e_t_2_, _-_I_n_t_e_r_s_e_c_t_i_o_n))
_I_n_t_e_r_s_e_c_t_i_o_n holds the common elements of _S_e_t_1 and _S_e_t_2.
ddeepprreeccaatteedd Use ord_intersection/3
oorrdd__iinntteerrsseeccttiioonn((_+_P_o_w_e_r_S_e_t_, _-_I_n_t_e_r_s_e_c_t_i_o_n))
_I_n_t_e_r_s_e_c_t_i_o_n of a powerset. True when _I_n_t_e_r_s_e_c_t_i_o_n is an ordered
set holding all elements common to all sets in _P_o_w_e_r_S_e_t.
CCoommppaattiibbiilliittyy sicstus
oorrdd__iinntteerrsseeccttiioonn((_+_S_e_t_1_, _+_S_e_t_2_, _-_I_n_t_e_r_s_e_c_t_i_o_n)) _[_d_e_t_]
_I_n_t_e_r_s_e_c_t_i_o_n holds the common elements of _S_e_t_1 and _S_e_t_2.
oorrdd__iinntteerrsseeccttiioonn((_+_S_e_t_1_, _+_S_e_t_2_, _?_I_n_t_e_r_s_e_c_t_i_o_n_, _?_D_i_f_f_e_r_e_n_c_e)) _[_d_e_t_]
_I_n_t_e_r_s_e_c_t_i_o_n and difference between two ordered sets. _I_n_t_e_r_s_e_c_t_i_o_n
is the intersection between _S_e_t_1 and _S_e_t_2, while _D_i_f_f_e_r_e_n_c_e is
defined by ord_subtract(Set2, Set1, Difference).
SSeeee aallssoo ord_intersection/3 and ord_subtract/3.
oorrdd__aadddd__eelleemmeenntt((_+_S_e_t_1_, _+_E_l_e_m_e_n_t_, _?_S_e_t_2)) _[_d_e_t_]
Insert an element into the set. This is the same as
ord_union(Set1, [Element], Set2).
oorrdd__ddeell__eelleemmeenntt((_+_S_e_t_, _+_E_l_e_m_e_n_t_, _-_N_e_w_S_e_t)) _[_d_e_t_]
Delete an element from an ordered set. This is the same as
ord_subtract(Set, [Element], NewSet).
oorrdd__sseelleeccttcchhkk((_+_I_t_e_m_, _?_S_e_t_1_, _?_S_e_t_2)) _[_s_e_m_i_d_e_t_]
Selectchk/3, specialised for ordered sets. Is true when
select(Item, Set1, Set2) and _S_e_t_1, _S_e_t_2 are both sorted lists
without duplicates. This implementation is only expected to work
for _I_t_e_m ground and either _S_e_t_1 or _S_e_t_2 ground. The "chk"
suffix is meant to remind you of memberchk/2, which also expects
its first argument to be ground. ord_selectchk(X, S, T) =>
ord_memberchk(X, S) & \+ ord_memberchk(X, T).
aauutthhoorr Richard O'Keefe
oorrdd__mmeemmbbeerrcchhkk((_+_E_l_e_m_e_n_t_, _+_O_r_d_S_e_t)) _[_s_e_m_i_d_e_t_]
True if _E_l_e_m_e_n_t is a member of _O_r_d_S_e_t, compared using ==. Note
that _e_n_u_m_e_r_a_t_i_n_g elements of an ordered set can be done using
member/2.
Some Prolog implementations also provide ord_member/2, with the
same semantics as ord_memberchk/2. We believe that having a
semidet ord_member/2 is unacceptably inconsistent with the *_chk
convention. Portable code should use ord_memberchk/2 or member/2.
aauutthhoorr Richard O'Keefe
oorrdd__ssuubbsseett((_+_S_u_b_, _+_S_u_p_e_r)) _[_s_e_m_i_d_e_t_]
Is true if all elements of _S_u_b are in _S_u_p_e_r
oorrdd__ssuubbttrraacctt((_+_I_n_O_S_e_t_, _+_N_o_t_I_n_O_S_e_t_, _-_D_i_f_f)) _[_d_e_t_]
_D_i_f_f is the set holding all elements of _I_n_O_S_e_t that are not in
_N_o_t_I_n_O_S_e_t.
oorrdd__uunniioonn((_+_S_e_t_O_f_S_e_t_s_, _-_U_n_i_o_n)) _[_d_e_t_]
True if _U_n_i_o_n is the union of all elements in the superset
_S_e_t_O_f_S_e_t_s. Each member of _S_e_t_O_f_S_e_t_s must be an ordered set, the
sets need not be ordered in any way.
aauutthhoorr Copied from YAP, probably originally by Richard
O'Keefe.
oorrdd__uunniioonn((_+_S_e_t_1_, _+_S_e_t_2_, _?_U_n_i_o_n)) _[_d_e_t_]
_U_n_i_o_n is the union of _S_e_t_1 and _S_e_t_2
oorrdd__uunniioonn((_+_S_e_t_1_, _+_S_e_t_2_, _-_U_n_i_o_n_, _-_N_e_w)) _[_d_e_t_]
True iff ord_union(Set1, Set2, Union) and
ord_subtract(Set2, Set1, New).
oorrdd__ssyymmddiiffff((_+_S_e_t_1_, _+_S_e_t_2_, _?_D_i_f_f_e_r_e_n_c_e)) _[_d_e_t_]
Is true when _D_i_f_f_e_r_e_n_c_e is the symmetric difference of _S_e_t_1 and
_S_e_t_2. I.e., _D_i_f_f_e_r_e_n_c_e contains all elements that are not in
the intersection of _S_e_t_1 and _S_e_t_2. The semantics is the same as
the sequence below (but the actual implementation requires only a
single scan).
____________________________________________________________________| |
| ord_union(Set1, Set2, Union), |
| ord_intersection(Set1, Set2, Intersection), |
||______ord_subtract(Union,_Intersection,_Difference).______________ ||
For example:
____________________________________________________________________| |
| ?- ord_symdiff([1,2], [2,3], X). |
||X_=_[1,3].________________________________________________________ ||
1111..1188 lliibbrraarryy((ppaaiirrss)):: OOppeerraattiioonnss oonn kkeeyy--vvaalluuee lliissttss
aauutthhoorr Jan Wielemaker
SSeeee aallssoo keysort/2, library(assoc)
This module implements common operations on Key-Value lists, also
known as _P_a_i_r_s. Pairs have great practical value, especially due to
keysort/2 and the library assoc.pl.
This library is based on disussion in the SWI-Prolog mailinglist,
including specifications from Quintus and a library proposal by Richard
O'Keefe.
ppaaiirrss__kkeeyyss__vvaalluueess((_?_P_a_i_r_s_, _?_K_e_y_s_, _?_V_a_l_u_e_s)) _[_d_e_t_]
True if _K_e_y_s holds the keys of _P_a_i_r_s and _V_a_l_u_e_s the values.
Deterministic if any argument is instantiated to a finite list and
the others are either free or finite lists. All three lists are in
the same order.
SSeeee aallssoo pairs_values/2 and pairs_keys/2.
ppaaiirrss__vvaalluueess((_+_P_a_i_r_s_, _-_V_a_l_u_e_s)) _[_d_e_t_]
Remove the keys from a list of Key-Value pairs. Same as
pairs_keys_values(Pairs, _, Values)
ppaaiirrss__kkeeyyss((_+_P_a_i_r_s_, _-_K_e_y_s)) _[_d_e_t_]
Remove the values from a list of Key-Value pairs. Same as
pairs_keys_values(Pairs, Keys, _)
ggrroouupp__ppaaiirrss__bbyy__kkeeyy((_+_P_a_i_r_s_, _-_J_o_i_n_e_d_:_l_i_s_t_(_K_e_y_-_V_a_l_u_e_s_))) _[_d_e_t_]
Group values with the same key. _P_a_i_r_s must be a key-sorted list.
For example:
____________________________________________________________________| |
| ?- group_pairs_by_key([a-2, a-1, b-4], X). |
| |
||X_=_[a-[2,1],_b-[4]]______________________________________________ ||
___________________________________________________________Arguments_
_P_a_i_r_s _K_e_y-Value list, sorted to the standard order of
terms (as keysort/2 does)
_J_o_i_n_e_d List of _K_e_y-Group, where Group is the list of
_V_a_l_u_e_s associated with _K_e_y.
ttrraannssppoossee__ppaaiirrss((_+_P_a_i_r_s_, _-_T_r_a_n_s_p_o_s_e_d)) _[_d_e_t_]
Swap Key-Value to Value-Key. The resulting list is sorted using
keysort/2 on the new key.
mmaapp__lliisstt__ttoo__ppaaiirrss((_:_F_u_n_c_t_i_o_n_, _+_L_i_s_t_, _-_K_e_y_e_d))
Create a Key-Value list by mapping each element of _L_i_s_t. For
example, if we have a list of lists we can create a list of
Length-_L_i_s_t using
____________________________________________________________________| |
||________map_list_to_pairs(length,_ListOfLists,_Pairs),____________ ||
1111..1199 lliibbrraarryy((ppiioo)):: PPuurree II//OO
This library provides pure list-based I/O processing for Prolog, where
the communication to the actual I/O device is performed transparently
through coroutining. This module itself is just an interface to the
actual implementation modules.
1111..1199..11 lliibbrraarryy((ppuurree__iinnppuutt)):: PPuurree IInnppuutt ffrroomm ffiilleess
aauutthhoorr
- Ulrich Neumerkel
- Jan Wielemaker
TToo bbee ddoonnee
- Provide support for alternative input readers, e.g.
reading terms, tokens, etc.
- Support non-repositioning streams, such as sockets and
pipes.
This module is part of pio.pl, dealing with _p_u_r_e _i_n_p_u_t: processing
input streams from the outside world using pure predicates, notably
grammar rules (DCG). Using pure predicates makes non-deterministic
processing of input much simpler.
Pure input uses coroutining (freeze/2) to read input from the external
source into a list _o_n _d_e_m_a_n_d. The overhead of lazy reading is more
than compensated for by using block reads based on read_pending_input/3.
pphhrraassee__ffrroomm__ffiillee((_:_G_r_a_m_m_a_r_, _+_F_i_l_e)) _[_n_o_n_d_e_t_]
Process the content of _F_i_l_e using the DCG rule _G_r_a_m_m_a_r. The
space usage of this mechanism depends on the length of the not
committed part of _G_r_a_m_m_a_r. Committed parts of the temporary list
are reclaimed by the garbage collector, while the list is extended
on demand. Here is a very simple definition for searching a string
in a file:
____________________________________________________________________| |
| ... --> []|[_],... . |
| |
| file_contains(File, Pattern) :- |
| phrase_from_file((..., Pattern, ...), File). |
| |
| match_count(File, Pattern, Count) :- |
| findall(x, file_contains(File, Pattern), Xs), |
||________length(Xs,_Count).________________________________________ ||
This can be called as (note that the pattern must be a string (code
list)):
____________________________________________________________________| |
||?-_match_count('pure_input.pl',_"file",_Count).___________________ ||
pphhrraassee__ffrroomm__ffiillee((_:_G_r_a_m_m_a_r_, _+_F_i_l_e_, _+_O_p_t_i_o_n_s)) _[_n_o_n_d_e_t_]
As phrase_from_file/2, providing additional _O_p_t_i_o_n_s. _O_p_t_i_o_n_s are
passed to open/4, except for buffer_size, which is passed to
set_stream/2. If not specified, the default buffer size is 512
bytes. Of particular importance are the open/4 options type and
encoding.
pphhrraassee__ffrroomm__ssttrreeaamm((_:_G_r_a_m_m_e_r_, _+_S_t_r_e_a_m))
Helper for phrase_from_file/3. This predicate cooperates with
syntax_error//1 to generate syntax error locations for grammars.
ssyynnttaaxx__eerrrroorr((_+_E_r_r_o_r)) //
Throw the syntax error _E_r_r_o_r at the current location of the input.
This predicate is designed to be called from the handler of
phrase_from_file/3.
tthhrroowwss error(syntax_error(Error), Location)
llaazzyy__lliisstt__llooccaattiioonn((_-_L_o_c_a_t_i_o_n)) // _[_d_e_t_]
Determine current (error) location in a lazy list. True when
_L_o_c_a_t_i_o_n is an (error) location term that represents the current
location in the DCG list.
___________________________________________________________Arguments_
_L_o_c_a_t_i_o_n is a term file(Name, Line, LinePos, CharNo)
or stream(Stream, Line, LinePos, CharNo) if no
file is associated to the stream RestLazyList.
Finally, if the Lazy list is fully materialized
(ends in []), _L_o_c_a_t_i_o_n is unified with
end_of_file-CharCount.
SSeeee aallssoo lazy_list_character_count//1 only provides the
character count.
llaazzyy__lliisstt__cchhaarraacctteerr__ccoouunntt((_-_C_h_a_r_C_o_u_n_t)) //
True when _C_h_a_r_C_o_u_n_t is the current character count in the Lazy
list. The character count is computed by finding the distance to
the next frozen tail of the lazy list. _C_h_a_r_C_o_u_n_t is one of:
o An integer
o A term end_of_file-Count
SSeeee aallssoo lazy_list_location//1 provides full details of
the location for error reporting.
ssttrreeaamm__ttoo__llaazzyy__lliisstt((_+_S_t_r_e_a_m_, _-_L_i_s_t)) _[_d_e_t_]
Create a lazy list representing the character codes in _S_t_r_e_a_m. It
must be possible to reposition _S_t_r_e_a_m. _L_i_s_t is a list that ends in
a delayed goal. _L_i_s_t can be unified completely transparent to a
(partial) list and processed transparently using DCGs, but please
be aware that a lazy list is not the same as a materialized list in
all respects.
Typically, this predicate is used as a building block for more high
level safe predicates such as phrase_from_file/2.
TToo bbee ddoonnee Enhance of lazy list throughout the system.
1111..2200 lliibbrraarryy((pprreeddiiccaattee__ooppttiioonnss)):: DDeeccllaarree ooppttiioonn--pprroocceessssiinngg ooff pprreeddii--
ccaatteess
_D_i_s_c_u_s_s_i_o_n_s _w_i_t_h _J_e_f_f _S_c_h_u_l_t_z _h_e_l_p_e_d _s_h_a_p_i_n_g _t_h_i_s _l_i_b_r_a_r_y
1111..2200..11 TThhee ssttrreennggtthh aanndd wweeaakknneessss ooff pprreeddiiccaattee ooppttiioonnss
Many ISO predicates accept options, e.g., open/4, write_term/3.
Options offer an attractive alternative to proliferation into many
predicates and using high-arity predicates. Properly defined and used,
they also form a mechanism for extending the API of both system and
application predicates without breaking portability. I.e., previously
fixed behaviour can be replaced by dynamic behaviour controlled by an
option where the default is the previously defined fixed behaviour.
The alternative to using options is to add an additional argument
and maintain the previous definition. While a series of predicates
with increasing arity is adequate for a small number of additional
parameters, the untyped positional argument handling of Prolog quickly
makes this unmanageable.
The ISO standard uses the extensibility offered by options by allowing
implementations to extend the set of accepted options. While options
form a perfect solution to maintain backward portability in a linear
development model, it is not well equipped to deal with concurrent
branches because
1. There is no API to find which options are supported in a particular
implementation.
2. While the portability problem caused by a missing predicate in
Prolog _A can easily be solved by implementing this predicate, it is
much harder to add processing of an additional option to an already
existing predicate.
Different Prolog implementations can be seen as concurrent development
branches of the Prolog language. Different sets of supported options
pose a serious portability issue. Using an option _O that establishes
the desired behaviour on system _A leads (on most systems) to an error
or system _B. Porting may require several actions:
o Drop _O (if the option is not vital, such as the layout options to
write_term/3)
o Replace _O by _O_2 (i.e., a differently named option doing the same)
o Something else (cannot be ported; requires a totally different
approach, etc.)
Predicates that process options are particularly a problem when writing
a compatibility layer to run programs developed for System _A on System
_B because complete emulation is often hard, may cause a serious
slowdown and is often not needed because the application-to-be-ported
only uses options that are shared by all target Prolog implementations.
Unfortunately, the consequences of a partial emulation cannot be
assessed by tools.
1111..2200..22 OOppttiioonnss aass aarrgguummeennttss oorr eennvviirroonnmmeenntt??
We distinguish two views on options. One is to see them as additional
parameters that require strict existence, type and domain-checking and
the other is to consider them `locally scoped environment variables'.
Most systems adopt the first option. SWI-Prolog adopts the second:
it silently ignores options that are not supported but does type and
domain checking of option-values. The `environment' view is commonly
used in applications to create predicates supporting more options using
the skeleton below. This way of programming requires that _p_r_e_d_1 and
_p_r_e_d_2 do not interpret the same option differently. In cases where
this is not true, the options must be distributed by _s_o_m_e___p_r_e_d. We
have been using this programming style for many years and in practice
it turns out that the need for active distribution of options is
rare. I.e., options either have distinct names or multiple predicates
implement the same option but this has the desired effect. An example
of the latter is the encoding option, which typically needs to be
applied consistently.
________________________________________________________________________| |
|some_pred(..., Options) :- |
| pred1(..., Options), |
||_____pred2(...,_Options)._____________________________________________ ||
As stated before, options provide a readable alternative to high-arity
predicates and offer a robust mechanism to evolve the API, but at the
cost of some runtime overhead and weaker consistency checking, both
at compiletime and runtime. From our experience, the `environment'
approach is productive, but the consequence is that mistyped options
are silently ignored. The option infrastructure described in this
section tries to remedy these problems.
1111..2200..33 IImmpprroovviinngg oonn tthhee ccuurrrreenntt ssiittuuaattiioonn
Whether we see options as arguments or locally scoped environment
variables, the most obvious way to improve on the current situation is
to provide reflective support for options: discover that an argument
is an option-list and find what options are supported. Reflective
access to options can be used by the compiler and development
environment as well as by the runtime system to warn or throw errors.
1111..2200..33..11 OOppttiioonnss aass ttyyppeess
An obvious approach to deal with options is to define the different
possible option values as a type and type the argument that processes
the option as list(<option_type>), as illustrated below. Considering
options as types fully covers the case where we consider options as
additional parameters.
________________________________________________________________________| |
|:- type open_option ---> type(stream_type) | |
| alias(atom) | ... . |
|:-|pred_open(source_sink,_open_mode,_stream,_list(open_option))._______ | |
There are three reasons for considering a different approach:
o There is no consensus about types in the Prolog world, neither
about what types should look like, nor whether or not they are
desirable. It is not likely that this debate will be resolved
shortly.
o Considering options as types does not support the `environment'
view, which we consider the most productive.
o Even when using types, we need reflective access to what options
are provided in order to be able to write compile or runtime
conditional code.
1111..2200..33..22 RReefflleeccttiivvee aacccceessss ttoo ooppttiioonnss
From the above, we conclude that we require reflective access to
find out whether an option is supported and valid for a particular
predicate. Possible option values must be described by types. Due to
lack of a type system, we use library(error) to describe allowed option
values. Predicate options are declared using predicate_options/3:
pprreeddiiccaattee__ooppttiioonnss((_:_P_I_, _+_A_r_g_, _+_O_p_t_i_o_n_s)) _[_d_e_t_]
Declare that the predicate _P_I processes options on _A_r_g. _O_p_t_i_o_n_s is
a list of options processed. Each element is one of:
o Option(ModeAndType) _P_I processes Option. The option-value
must comply to ModeAndType. Mode is one of + or - and Type is
a type as accepted by must_be/2.
o pass_to(:_P_I,_A_r_g) The option-list is passed to the indicated
predicate.
Below is an example that processes the option header(boolean) and
passes all options to open/4:
____________________________________________________________________| |
| :- predicate_options(write_xml_file/3, 3, |
| [ header(boolean), |
| pass_to(open/4, 4) |
| ]). |
| |
| write_xml_file(File, XMLTerm, Options) :- |
| open(File, write, Out, Options), |
| ( option(header(true), Option, true) |
| -> write_xml_header(Out) |
| ; true |
| ), |
||____...___________________________________________________________ ||
This predicate may only be used as a _d_i_r_e_c_t_i_v_e and is processed by
expand_term/2. Option processing can be specified at runtime using
assert_predicate_options/3, which is intended to support program
analysis.
aasssseerrtt__pprreeddiiccaattee__ooppttiioonnss((_:_P_I_, _+_A_r_g_, _+_O_p_t_i_o_n_s_, _?_N_e_w)) _[_s_e_m_i_d_e_t_]
As predicate_options(:_P_I, +_A_r_g, +_O_p_t_i_o_n_s). _N_e_w is a boolean
indicating whether the declarations have changed. If _N_e_w is
provided and false, the predicate becomes semidet and fails without
modifications if modifications are required.
The predicates below realise the support for compile and runtime
checking for supported options.
ccuurrrreenntt__pprreeddiiccaattee__ooppttiioonn((_:_P_I_, _?_A_r_g_, _?_O_p_t_i_o_n)) _[_n_o_n_d_e_t_]
True when _A_r_g of _P_I processes _O_p_t_i_o_n. For example, the following
is true:
____________________________________________________________________| |
| ?- current_predicate_option(open/4, 4, type(text)). |
||true._____________________________________________________________ ||
This predicate is intended to support conditional compilation using
if/1 ... endif/0. The predicate current_predicate_options/3 can
be used to access the full capabilities of a predicate.
cchheecckk__pprreeddiiccaattee__ooppttiioonn((_:_P_I_, _+_A_r_g_, _+_O_p_t_i_o_n)) _[_d_e_t_]
Verify predicate options at runtime. Similar to
current_predicate_option/3, but intended to support runtime
checking.
EErrrroorrss
- existence_error(option, OptionName) if the option
is not supported by _P_I.
- type_error(Type, Value) if the option is supported
but the value does not match the option type. See
must_be/2.
The predicates below can be used in a development environment to inform
the user about supported options. PceEmacs uses this for colouring
option names and values.
ccuurrrreenntt__ooppttiioonn__aarrgg((_:_P_I_, _?_A_r_g)) _[_n_o_n_d_e_t_]
True when _A_r_g of _P_I processes predicate options. Which options are
processed can be accessed using current_predicate_option/3.
ccuurrrreenntt__pprreeddiiccaattee__ooppttiioonnss((_:_P_I_, _?_A_r_g_, _?_O_p_t_i_o_n_s)) _[_n_o_n_d_e_t_]
True when _O_p_t_i_o_n_s is the current active option declaration for _P_I
on _A_r_g. See predicate_options/3for the argument descriptions. If
_P_I is ground and refers to an undefined predicate, the autoloader
is used to obtain a definition of the predicate.
The library can execute a complete check of your program using
check_predicate_options/0:
cchheecckk__pprreeddiiccaattee__ooppttiioonnss _[_d_e_t_]
Analyse loaded program for erroneous options. This predicate
decompiles the current program and searches for calls to predicates
that process options. For each option list, it validates whether
the provided options are supported and validates the argument
type. This predicate performs partial dataflow analysis to track
option-lists inside a clause.
SSeeee aallssoo derive_predicate_options/0 can be used to derive
declarations for predicates that pass options.
This predicate should normally be called before
check_predicate_options/0.
The library offers predicates that may be used to create declarations
for your application. These predicates are designed to cooperate with
the module system.
ddeerriivvee__pprreeddiiccaattee__ooppttiioonnss _[_d_e_t_]
Derive new predicate option declarations. This predicate analyses
the loaded program to find clauses that process options using one
of the predicates from library(option) or passes options to other
predicates that are known to process options. The process is
repeated until no new declarations are retrieved.
SSeeee aallssoo autoload/0 may be used to complete the loaded
program.
rreettrraaccttaallll__pprreeddiiccaattee__ooppttiioonnss _[_d_e_t_]
Remove all dynamically (derived) predicate options.
ddeerriivveedd__pprreeddiiccaattee__ooppttiioonnss((_:_P_I_, _?_A_r_g_, _?_O_p_t_i_o_n_s)) _[_n_o_n_d_e_t_]
Derive option arguments using static analysis. True when _O_p_t_i_o_n_s
is the current _d_e_r_i_v_e_d active option declaration for _P_I on _A_r_g.
ddeerriivveedd__pprreeddiiccaattee__ooppttiioonnss((_+_M_o_d_u_l_e)) _[_d_e_t_]
Derive predicate option declarations for a module. The derived
options are printed to the current_output stream.
1111..2211 lliibbrraarryy((pprroolloogg__ppaacckk)):: AA ppaacckkaaggee mmaannaaggeerr ffoorr PPrroolloogg
SSeeee aallssoo Installed packages can be inspected using
?- doc_browser.
TToo bbee ddoonnee
- Version logic
- Find and resolve conflicts
- Upgrade git packages
- Validate git packages
- Test packages: run tests from directory `test'.
The library(prolog_pack) provides the SWI-Prolog package manager. This
library lets you inspect installed packages, install packages, remove
packages, etc. It is complemented by the built-in attach_packs/0 that
makes installed packages available as libaries.
ppaacckk__lliisstt__iinnssttaalllleedd _[_d_e_t_]
List currently installed packages. Unlike pack_list/1, only
locally installed packages are displayed and no connection is made
to the internet.
SSeeee aallssoo Use pack_list/1 to find packages.
ppaacckk__iinnffoo((_+_P_a_c_k))
Print more detailed information about _P_a_c_k.
ppaacckk__sseeaarrcchh((_+_Q_u_e_r_y)) _[_d_e_t_]
ppaacckk__lliisstt((_+_Q_u_e_r_y)) _[_d_e_t_]
_Q_u_e_r_y package server and installed packages and display results.
_Q_u_e_r_y is matches case-insensitively against the name and title of
known and installed packages. For each matching package, a single
line is displayed that provides:
o Installation status
{{ pp: package, not installed
{{ ii: installed package; up-to-date with public version
{{ UU: installed package; can be upgraded
{{ AA: installed package; newer than publically available
{{ ll: installed package; not on server
o Name@Version
o Name@Version(ServerVersion)
o Title
Hint: ?- pack_list(''). lists all packages.
The predicates pack_list/1 and pack_search/1 are synonyms. Both
contact the package server at http://www.swi-prolog.org to find
available packages.
SSeeee aallssoo pack_list_installed/0 to list installed packages
without contacting the server.
ppaacckk__iinnssttaallll((_+_S_p_e_c_:_a_t_o_m)) _[_d_e_t_]
Install a package. _S_p_e_c is one of
o Archive file name
o HTTP URL of an archive file name. This URL may contain a star
(*) for the version. In this case pack_install asks for the
deirectory content and selects the latest version.
o GIT URL (not well supported yet)
o A local directory name
o A package name. This queries the package repository at
http://www.swi-prolog.org
After resolving the type of package, pack_install/2 is used to do
the actual installation.
ppaacckk__iinnssttaallll((_+_N_a_m_e_, _+_O_p_t_i_o_n_s)) _[_d_e_t_]
Install package _N_a_m_e. _O_p_t_i_o_n_s:
uurrll((_+_U_R_L))
Source for downloading the package
ppaacckkaaggee__ddiirreeccttoorryy((_+_D_i_r))
Directory into which to install the package
iinntteerraaccttiivvee((_+_B_o_o_l_e_a_n))
Use default answer without asking the user if there is a
default action.
ppaacckk__rreebbuuiilldd((_+_P_a_c_k)) _[_d_e_t_]
Rebuilt possible foreign components of _P_a_c_k.
ppaacckk__rreebbuuiilldd _[_d_e_t_]
Rebuild foreign components of all packages.
eennvviirroonnmmeenntt((_-_N_a_m_e_, _-_V_a_l_u_e)) _[_n_o_n_d_e_t_,_m_u_l_t_i_f_i_l_e_]
Hook to define the environment for building packs. This
Multifile hook extends the process environment for building foreign
extensions. A value provided by this hook overrules defaults
provided by def_environment/2. In addition to changing the
environment, this may be used to pass additional values to the
environment, as in:
____________________________________________________________________| |
| prolog_pack:environment('USER', User) :- |
||____getenv('USER',_User)._________________________________________ ||
___________________________________________________________Arguments_
_N_a_m_e is an atom denoting a valid variable name
_V_a_l_u_e is either an atom or number representing the
value of the variable.
ppaacckk__uuppggrraaddee((_+_P_a_c_k)) _[_s_e_m_i_d_e_t_]
Try to upgrade the package _P_a_c_k.
TToo bbee ddoonnee Update dependencies when updating a pack from
git?
ppaacckk__rreemmoovvee((_+_N_a_m_e)) _[_d_e_t_]
Remove the indicated package.
ppaacckk__pprrooppeerrttyy((_?_P_a_c_k_, _?_P_r_o_p_e_r_t_y)) _[_n_o_n_d_e_t_]
True when _P_r_o_p_e_r_t_y is a property of _P_a_c_k. This interface is
intended for programs that wish to interact with the package
manager. Defined properties are:
ddiirreeccttoorryy((_D_i_r_e_c_t_o_r_y))
_D_i_r_e_c_t_o_r_y into which the package is installed
vveerrssiioonn((_V_e_r_s_i_o_n))
Installed version
ttiittllee((_T_i_t_l_e))
Full title of the package
aauutthhoorr((_A_u_t_h_o_r))
Registered author
ddoowwnnllooaadd((_U_R_L))
Official download _U_R_L
rreeaaddmmee((_F_i_l_e))
Package README file (if present)
ttooddoo((_F_i_l_e))
Package TODO file (if present)
1111..2222 lliibbrraarryy((pprroolloogg__xxrreeff)):: CCrroossss--rreeffeerreennccee ddaattaa ccoolllleeccttiioonn lliibbrraarryy
This library collects information on defined and used objects in Prolog
source files. Typically these are predicates, but we expect the
library to deal with other types of objects in the future. The
library is a building block for tools doing dependency tracking in
applications. Dependency tracking is useful to reveal the structure of
an unknown program or detect missing components at compile time, but
also for program transformation or minimising a program saved state by
only saving the reachable objects.
This section gives a partial description of the library API, providing
some insight in how you can use it for analysing your program. The
library should be further modularized, moving its knowledge about, for
example, XPCE into a different file and allowing for adding knowledge
about other libraries such as Logtalk. PPlleeaassee ddoo nnoott ccoonnssiiddeerr tthhiiss
iinntteerrffaaccee rroocckk--ssoolliidd..
The library is exploited by two graphical tools in the SWI-Prolog
environment: the XPCE front-end started by gxref/0 and described in
section 3.7, and PceEmacs (section 3.4), which exploits this library
for its syntax colouring.
For all predicates described below, _S_o_u_r_c_e is the source that is
processed. This is normally a filename in any notation acceptable
to the file loading predicates (see load_files/2). Using the hooks
defined in section 11.22.1 it can be anything else that can be
translated into a Prolog stream holding Prolog source text. _C_a_l_l_a_b_l_e
is a callable term (see callable/1). Callables do not carry a module
qualifier unless the referred predicate is not in the module defined
_S_o_u_r_c_e.
xxrreeff__ssoouurrccee((_+_S_o_u_r_c_e))
Gather information on _S_o_u_r_c_e. If _S_o_u_r_c_e has already been processed
and is still up-to-date according to the file timestamp, no action
is taken. This predicate must be called on a file before
information can be gathered.
xxrreeff__ccuurrrreenntt__ssoouurrccee((_?_S_o_u_r_c_e))
_S_o_u_r_c_e has been processed.
xxrreeff__cclleeaann((_+_S_o_u_r_c_e))
Remove the information gathered for _S_o_u_r_c_e
xxrreeff__ddeeffiinneedd((_?_S_o_u_r_c_e_, _?_C_a_l_l_a_b_l_e_, _-_H_o_w))
_C_a_l_l_a_b_l_e is defined in _S_o_u_r_c_e. _H_o_w is one of
dynamic(_L_i_n_e) Declared dynamic at _L_i_n_e
thread_local(_L_i_n_e) Declared thread local at _L_i_n_e
multifile(_L_i_n_e) Declared multifile at _L_i_n_e
local(_L_i_n_e) First clause at _L_i_n_e
foreign(_L_i_n_e) Foreign library loaded at _L_i_n_e
constraint(_L_i_n_e) CHR Constraint at _L_i_n_e
imported(_F_i_l_e) Imported from _F_i_l_e
xxrreeff__ccaalllleedd((_?_S_o_u_r_c_e_, _?_C_a_l_l_a_b_l_e_, _?_B_y))
_C_a_l_l_a_b_l_e is called in _S_o_u_r_c_e by _B_y.
xxrreeff__eexxppoorrtteedd((_?_S_o_u_r_c_e_, _?_C_a_l_l_a_b_l_e))
_C_a_l_l_a_b_l_e is public (exported from the module).
xxrreeff__mmoodduullee((_?_S_o_u_r_c_e_, _?_M_o_d_u_l_e))
_S_o_u_r_c_e is a module file defining the given module.
xxrreeff__bbuuiilltt__iinn((_?_C_a_l_l_a_b_l_e))
True if _C_a_l_l_a_b_l_e is a built-in predicate. Currently this is
assumed for all predicates defined in the system module and having
the property built_in. Built-in predicates are not registered as
`called'.
1111..2222..11 EExxtteennddiinngg tthhee lliibbrraarryy
The library provides hooks for extending the rules it uses for finding
predicates called by some programming construct.
pprroolloogg::ccaalllleedd__bbyy((_+_G_o_a_l_, _-_C_a_l_l_e_d))
_G_o_a_l is a non-var subgoal appearing in the called object (typically
a clause body). If it succeeds it must return a list of goals
called by _G_o_a_l. As a special construct, if a term Callable +N
is returned, N variable arguments are added to _C_a_l_l_a_b_l_e before
further processing. For simple meta-calls a single fact suffices.
Complex rules as used in the html_write library provided by the
HTTP package examine the arguments and create a list of called
objects.
The current system cannot deal with the same name/arity in
different modules that behave differently with respect to called
arguments.
1111..2233 lliibbrraarryy((qquuaassii__qquuoottaattiioonnss)):: DDeeffiinnee QQuuaassii QQuuoottaattiioonn ssyynnttaaxx
aauutthhoorr Jan Wielemaker. Introduction of Quasi Quotation was
suggested by Michael Hendricks.
SSeeee aallssoo
Inspired by Haskell, SWI-Prolog support _q_u_a_s_i _q_u_o_t_a_t_i_o_n. Quasi
quotation allows for embedding (long) strings using the syntax of an
external language (e.g., HTML, SQL) in Prolog text and syntax-aware
embedding of Prolog variables in this syntax. At the same time, quasi
quotation provides an alternative to represent long strings and atoms
in Prolog.
The basic form of a quasi quotation is defined below. Here, _S_y_n_t_a_x
is an arbitrary Prolog term that must parse into a _c_a_l_l_a_b_l_e (atom or
compound) term and Quotation is an arbitrary sequence of characters,
not including the sequence |}. If this sequence needs to be embedded,
it must be escaped according to the rules of the target language or the
`quoter' must provide an escaping mechanism.
________________________________________________________________________| |
|{|Syntax||Quotation|}|_________________________________________________ | |
While reading a Prolog term, and if the Prolog flag quasi_quotes is
set to true (which is the case if this library is loaded), the parser
collects quasi quotations. After reading the final full stop, the
parser makes the call below. Here, _S_y_n_t_a_x_N_a_m_e is the functor name
of _S_y_n_t_a_x above and _S_y_n_t_a_x_A_r_g_s is a list holding the arguments, i.e.,
Syntax =.. [SyntaxName|SyntaxArgs]. Splitting the syntax into its name
and arguments is done to make the quasi quotation parser a predicate
with a consistent arity 4, regardless of the number of additional
arguments.
________________________________________________________________________| |
|call(+SyntaxName,|+Content,_+SyntaxArgs,_+VariableNames,_-Result)______ | |
The arguments are defined as
o _S_y_n_t_a_x_N_a_m_e is the principal functor of the quasi quotation syntax.
This must be declared using quasi_quotation_syntax/1and there must
be a predicate SyntaxName/4.
o _C_o_n_t_e_n_t is an opaque term that carries the content of the quasi
quoted material and position information about the source code. It
is passed to with_quasi_quote_input/3.
o _S_y_n_t_a_x_A_r_g_s carries the additional arguments of the _S_y_n_t_a_x. These
are commonly used to make the parameter passing between the clause
and the quasi quotation explicit. For example:
____________________________________________________________________| |
| ..., |
| {|html(Name, Address)|| |
| <tr><td>Name<td>Address</tr> |
||_____|}___________________________________________________________ ||
o _V_a_r_i_a_b_l_e_N_a_m_e_s is the complete variable dictionary of the clause
as it is made available throug read_term/3 with the option
variable_names. It is a list of terms Name = Var.
o _R_e_s_u_l_t is a variable that must be unified to resulting term.
Typically, this term is structured Prolog tree that carries a
(partial) representation of the abstract syntax tree with embedded
variables that pass the Prolog parameters. This term is normally
either passed to a predicate that serializes the abstract syntax
tree, or a predicate that processes the result in Prolog. For
example, HTML is commonly embedded for writing HTML documents
(see library(http/html_write)). Examples of languages that may be
embedded for processing in Prolog are SPARQL, RuleML or regular
expressions.
The file library(http/html_quasiquotations) provides the, suprisingly
simple, quasi quotation parser for HTML.
wwiitthh__qquuaassii__qquuoottaattiioonn__iinnppuutt((_+_C_o_n_t_e_n_t_, _-_S_t_r_e_a_m_, _:_G_o_a_l)) _[_d_e_t_]
Process the quasi-quoted _C_o_n_t_e_n_t using _S_t_r_e_a_m parsed by _G_o_a_l.
_S_t_r_e_a_m is a temporary stream with the following properties:
o Its initial _p_o_s_i_t_i_o_n represents the position of the start of
the quoted material.
o It is a text stream, using utf8 _e_n_c_o_d_i_n_g.
o It allows for repositioning
o It will be closed after _G_o_a_l completes.
___________________________________________________________Arguments_
_G_o_a_l is executed as once(Goal). _G_o_a_l must succeed.
Failure or exceptions from _G_o_a_l are interpreted
as syntax errors.
SSeeee aallssoo phrase_from_quasi_quotation/2 can be used to
process a quotation using a grammar.
pphhrraassee__ffrroomm__qquuaassii__qquuoottaattiioonn((_:_G_r_a_m_m_a_r_, _+_C_o_n_t_e_n_t)) _[_d_e_t_]
Process the quasi quotation using the DCG _G_r_a_m_m_a_r. Failure of the
grammer is interpreted as a syntax error.
SSeeee aallssoo with_quasi_quotation_input/3 for processing quo-
tations from stream.
qquuaassii__qquuoottaattiioonn__ssyynnttaaxx((_:_S_y_n_t_a_x_N_a_m_e)) _[_d_e_t_]
Declare the predicate _S_y_n_t_a_x_N_a_m_e/4 to implement the the quasi quote
syntax _S_y_n_t_a_x_N_a_m_e. Normally used as a directive.
qquuaassii__qquuoottaattiioonn__ssyynnttaaxx__eerrrroorr((_+_E_r_r_o_r))
Report syntax_error(Error) using the current location in the quasi
quoted input parser.
tthhrroowwss error(syntax_error(Error), Position)
1111..2244 lliibbrraarryy((rraannddoomm)):: RRaannddoomm nnuummbbeerrss
aauutthhoorr R.A. O'Keefe, V.S. Costa, L. Damas, Jan Wielemaker
SSeeee aallssoo Built-in function random/1: A is random(10)
This library is derived from the DEC10 library random. Later,
the core random generator was moved to C. The current version uses
the SWI-Prolog arithmetic functions to realise this library. These
functions are based on the GMP library.
rraannddoomm((_-_R_:_f_l_o_a_t)) _[_d_e_t_]
Binds _R to a new random float in the _o_p_e_n interval (0.0,1.0).
SSeeee aallssoo
- setrand/1, getrand/1 may be used to fetch/set the
state.
- In SWI-Prolog, random/1 is implemented by the
function random_float/0.
rraannddoomm__bbeettwweeeenn((_+_L_:_i_n_t_, _+_U_:_i_n_t_, _-_R_:_i_n_t)) _[_s_e_m_i_d_e_t_]
Binds _R to a random integer in [_L,_U] (i.e., including both _L and
_U). Fails silently if _U<_L.
rraannddoomm((_+_L_:_i_n_t_, _+_U_:_i_n_t_, _-_R_:_i_n_t)) _[_d_e_t_]
rraannddoomm((_+_L_:_f_l_o_a_t_, _+_U_:_f_l_o_a_t_, _-_R_:_f_l_o_a_t)) _[_d_e_t_]
Generate a random integer or float in a range. If _L and _U are both
integers, _R is a random integer in the half open interval [_L,_U). If
_L and _U are both floats, _R is a float in the open interval (_L,_U).
ddeepprreeccaatteedd Please use random/1 for generating a random
float and random_between/3 for generating a random
integer. Note that the random_between/3 includes the
upper bound, while this predicate excludes the upper
bound.
sseettrraanndd((_+_S_t_a_t_e)) _[_d_e_t_]
ggeettrraanndd((_-_S_t_a_t_e)) _[_d_e_t_]
Query/set the state of the random generator. This is intended for
restarting the generator at a known state only. The predicate
setrand/1 accepts an opaque term returned by getrand/1. This term
may be asserted, written and read. The application may not make
other assumptions about this term.
For compatibility reasons with older versions of this library,
setrand/1 also accepts a term rand(A,B,C), where A, B and C are
integers in the range 1..30,000. This argument is used to seed the
random generator. Deprecated.
EErrrroorrss existence_error(random_state, _) is raised if the
underlying infrastructure cannot fetch the random
state. This is currently the case if SWI-Prolog is
not compiled with the GMP library.
SSeeee aallssoo set_random/1 and random_property/1 provide the
SWI-Prolog native implementation.
mmaayybbee _[_s_e_m_i_d_e_t_]
Succeed/fail with equal probability (variant of maybe/1).
mmaayybbee((_+_P)) _[_s_e_m_i_d_e_t_]
Succeed with probability _P, fail with probability 1-_P
mmaayybbee((_+_K_, _+_N)) _[_s_e_m_i_d_e_t_]
Succeed with probability _K/_N (variant of maybe/1)
rraannddoomm__ppeerrmm22((_?_A_, _?_B_, _?_X_, _?_Y)) _[_s_e_m_i_d_e_t_]
Does _X=_A,_Y=_B or _X=_B,_Y=_A with equal probability.
rraannddoomm__mmeemmbbeerr((_-_X_, _+_L_i_s_t_:_l_i_s_t)) _[_s_e_m_i_d_e_t_]
_X is a random member of _L_i_s_t. Equivalent to random_between(1,
|_L_i_s_t|), followed by nth1/3. Fails of _L_i_s_t is the empty list.
CCoommppaattiibbiilliittyy Quintus and SICStus libraries.
rraannddoomm__sseelleecctt((_-_X_, _+_L_i_s_t_, _-_R_e_s_t)) _[_s_e_m_i_d_e_t_]
rraannddoomm__sseelleecctt((_+_X_, _-_L_i_s_t_, _+_R_e_s_t)) _[_d_e_t_]
Randomly select or insert an element. Either _L_i_s_t or _R_e_s_t must be
a list. Fails if _L_i_s_t is the empty list.
CCoommppaattiibbiilliittyy Quintus and SICStus libraries.
rraannddsseett((_+_K_:_i_n_t_, _+_N_:_i_n_t_, _-_S_:_l_i_s_t_(_i_n_t_))) _[_d_e_t_]
_S is a sorted list of _K unique random integers in the range 1.._N.
Implemented by enumerating 1.._N and deciding whether or not the
number should be part of the set. For example:
____________________________________________________________________| |
| ?- randset(5, 5, S). |
| S = [1, 2, 3, 4, 5]. (always) |
| ?- randset(5, 20, S). |
||S_=_[2,_7,_10,_19,_20].___________________________________________ ||
SSeeee aallssoo randseq/3.
bbuugg Slow if _N is large and _K is small.
rraannddsseeqq((_+_K_:_i_n_t_, _+_N_:_i_n_t_, _-_L_i_s_t_:_l_i_s_t_(_i_n_t_))) _[_d_e_t_]
S is a list of _K unique random integers in the range 1.._N. The
order is random. Works as if defined by the following code.
____________________________________________________________________| |
| randseq(K, N, List) :- |
| randset(K, N, Set), |
||______random_permutation(Set,_List).______________________________ ||
SSeeee aallssoo randset/3.
rraannddoomm__ppeerrmmuuttaattiioonn((_+_L_i_s_t_, _-_P_e_r_m_u_t_a_t_i_o_n)) _[_d_e_t_]
rraannddoomm__ppeerrmmuuttaattiioonn((_-_L_i_s_t_, _+_P_e_r_m_u_t_a_t_i_o_n)) _[_d_e_t_]
_P_e_r_m_u_t_a_t_i_o_n is a random permutation of _L_i_s_t. This is intended to
process the elements of _L_i_s_t in random order. The predicate is
symmetric.
EErrrroorrss instantiation_error, type_error(list, _).
1111..2255 lliibbrraarryy((rreeaadduuttiill)):: RReeaaddiinngg lliinneess,, ssttrreeaammss aanndd ffiilleess
This library contains primitives to read lines, files, multiple terms,
etc. The package clib provides a shared object (DLL) named readutil.
If the library can locate this shared object it will use the foreign
implementation for reading character codes. Otherwise it will use a
Prolog implementation. Distributed applications should make sure to
deliver the readutil shared object if performance of these predicates
is critical.
rreeaadd__lliinnee__ttoo__ccooddeess((_+_S_t_r_e_a_m_, _-_C_o_d_e_s))
Read the next line of input from _S_t_r_e_a_m and unify the result
with _C_o_d_e_s _a_f_t_e_r the line has been read. A line is ended by a
newline character or end-of-file. Unlike read_line_to_codes/3, this
predicate removes a trailing newline character.
On end-of-file the atom end_of_file is returned. See also
at_end_of_stream/[0,1].
rreeaadd__lliinnee__ttoo__ccooddeess((_+_S_t_r_e_a_m_, _-_C_o_d_e_s_, _?_T_a_i_l))
Difference-list version to read an input line to a list of
character codes. Reading stops at the newline or end-of-file
character, but unlike read_line_to_codes/2, the newline is retained
in the output. This predicate is especially useful for reading a
block of lines up to some delimiter. The following example reads
an HTTP header ended by a blank line:
____________________________________________________________________| |
| read_header_data(Stream, Header) :- |
| read_line_to_codes(Stream, Header, Tail), |
| read_header_data(Header, Stream, Tail). |
| |
| read_header_data("\r\n", _, _) :- !. |
| read_header_data("\n", _, _) :- !. |
| read_header_data("", _, _) :- !. |
| read_header_data(_, Stream, Tail) :- |
| read_line_to_codes(Stream, Tail, NewTail), |
||________read_header_data(Tail,_Stream,_NewTail).__________________ ||
rreeaadd__ssttrreeaamm__ttoo__ccooddeess((_+_S_t_r_e_a_m_, _-_C_o_d_e_s))
Read all input until end-of-file and unify the result to _C_o_d_e_s.
rreeaadd__ssttrreeaamm__ttoo__ccooddeess((_+_S_t_r_e_a_m_, _-_C_o_d_e_s_, _?_T_a_i_l))
Difference-list version of read_stream_to_codes/2.
rreeaadd__ffiillee__ttoo__ccooddeess((_+_S_p_e_c_, _-_C_o_d_e_s_, _+_O_p_t_i_o_n_s))
Read a file to a list of character codes. _S_p_e_c is a file
specification for absolute_file_name/3. _C_o_d_e_s is the resulting
code list. _O_p_t_i_o_n_s is a list of options for absolute_file_name/3
and open/4. In addition, the option tail(_T_a_i_l) is defined, forming
a difference-list.
rreeaadd__ffiillee__ttoo__tteerrmmss((_+_S_p_e_c_, _-_T_e_r_m_s_, _+_O_p_t_i_o_n_s))
Read a file to a list of Prolog terms (see read/1). _S_p_e_c
is a file specification for absolute_file_name/3. _T_e_r_m_s is the
resulting list of Prolog terms. _O_p_t_i_o_n_s is a list of options
for absolute_file_name/3 and open/4. In addition, the option
tail(_T_a_i_l) is defined, forming a difference-list.
1111..2266 lliibbrraarryy((rreeccoorrdd)):: AAcccceessss nnaammeedd ffiieellddss iinn aa tteerrmm
The library record provides named access to fields in a record
represented as a compound term such as point(X, Y). The Prolog world
knows various approaches to solve this problem, unfortunately with no
consensus. The approach taken by this library is proposed by Richard
O'Keefe on the SWI-Prolog mailinglist.
The approach automates a technique commonly described in Prolog
text-books, where access and modification predicates are defined for
the record type. Such predicates are subject to normal import/export
as well as analysis by cross-referencers. Given the simple nature of
the access predicates, an optimizing compiler can easily inline them
for optimal preformance.
A record is defined using the directive record/1. We introduce the
library with a short example:
________________________________________________________________________| |
|:- record point(x:integer=0, y:integer=0). |
| |
| ..., |
| default_point(Point), |
| point_x(Point, X), |
| set_x_of_point(10, Point, Point1), |
| |
||_______make_point([y(20)],_YPoint),___________________________________ ||
The principal functor and arity of the term used defines the name and
arity of the compound used as records. Each argument is described
using a term of the format below.
<_n_a_m_e>[:<_t_y_p_e>][=<_d_e_f_a_u_l_t>]
In this definition, <_n_a_m_e> is an atom defining the name of the argument,
<_t_y_p_e> is an optional type specification as defined by must_be/2 from
library error, and <_d_e_f_a_u_l_t> is the default initial value. The <_t_y_p_e>
defaults to any. If no default value is specified the default is an
unbound variable.
A record declaration creates a set of predicates through _t_e_r_m_-
_e_x_p_a_n_s_i_o_n. We describe these predicates below. In this description,
<_c_o_n_s_t_r_u_c_t_o_r> refers to the name of the record (`point' in the example
above) and <_n_a_m_e> to the name of an argument (field).
o _d_e_f_a_u_l_t__<_c_o_n_s_t_r_u_c_t_o_r>_(_-_R_e_c_o_r_d_)
Create a new record where all fields have their default values.
This is the same as make_<_c_o_n_s_t_r_u_c_t_o_r>([], Record).
o _m_a_k_e__<_c_o_n_s_t_r_u_c_t_o_r>_(_+_F_i_e_l_d_s_, _-_R_e_c_o_r_d_)
Create a new record where specified fields have the specified
values and remaining fields have their default value. Each
field is specified as a term <_n_a_m_e>(<_v_a_l_u_e>). See example in the
introduction.
o _m_a_k_e__<_c_o_n_s_t_r_u_c_t_o_r>_(_+_F_i_e_l_d_s_, _-_R_e_c_o_r_d_, _-_R_e_s_t_F_i_e_l_d_s_)
Same as make_<_c_o_n_s_t_r_u_c_t_o_r>/2, but named fields that do not appear in
_R_e_c_o_r_d are returned in _R_e_s_t_F_i_e_l_d_s. This predicate is motivated by
option-list processing. See library option.
o <_c_o_n_s_t_r_u_c_t_o_r>_<_n_a_m_e>_(_R_e_c_o_r_d_, _V_a_l_u_e_)
Unify _V_a_l_u_e with argument in _R_e_c_o_r_d named <_n_a_m_e>.
o <_c_o_n_s_t_r_u_c_t_o_r>__d_a_t_a_(_?_N_a_m_e_, _+_R_e_c_o_r_d_, _?_V_a_l_u_e_)
True when _V_a_l_u_e is the value for the field named _N_a_m_e in _R_e_c_o_r_d.
This predicate does not perform type-checking.
o _s_e_t__<_n_a_m_e>__o_f__<_c_o_n_s_t_r_u_c_t_o_r>_(_+_V_a_l_u_e_, _+_O_l_d_R_e_c_o_r_d_, _-_N_e_w_R_e_c_o_r_d_)
Replace the value for <_n_a_m_e> in _O_l_d_R_e_c_o_r_d by _V_a_l_u_e and unify the
result with _N_e_w_R_e_c_o_r_d.
o _s_e_t__<_n_a_m_e>__o_f__<_c_o_n_s_t_r_u_c_t_o_r>_(_+_V_a_l_u_e_, _!_R_e_c_o_r_d_)
Destructively replace the argument <_n_a_m_e> in _R_e_c_o_r_d by _V_a_l_u_e based
on setarg/3. Use with care.
o _n_b___s_e_t__<_n_a_m_e>__o_f__<_c_o_n_s_t_r_u_c_t_o_r>_(_+_V_a_l_u_e_, _!_R_e_c_o_r_d_)
As above, but using non-backtrackable assignment based on
nb_setarg/3. Use with _e_x_t_r_e_m_e care.
o _s_e_t__<_c_o_n_s_t_r_u_c_t_o_r>__f_i_e_l_d_s_(_+_F_i_e_l_d_s_, _+_R_e_c_o_r_d_0_, _-_R_e_c_o_r_d_)
Set multiple fields using the same syntax as make_<_c_o_n_s_t_r_u_c_t_o_r>/2,
but starting with _R_e_c_o_r_d_0 rather than the default record.
o _s_e_t__<_c_o_n_s_t_r_u_c_t_o_r>__f_i_e_l_d_s_(_+_F_i_e_l_d_s_, _+_R_e_c_o_r_d_0_, _-_R_e_c_o_r_d_, _-_R_e_s_t_F_i_e_l_d_s_)
Similar to set_<_c_o_n_s_t_r_u_c_t_o_r>_fields/4, but fields not defined by
<_c_o_n_s_t_r_u_c_t_o_r> are returned in _R_e_s_t_F_i_e_l_d_s.
o _s_e_t__<_c_o_n_s_t_r_u_c_t_o_r>__f_i_e_l_d_(_+_F_i_e_l_d_, _+_R_e_c_o_r_d_0_, _-_R_e_c_o_r_d_)
Set a single field specified as a term <_n_a_m_e>(<_v_a_l_u_e>).
rreeccoorrdd((_+_S_p_e_c))
The construct :- record Spec, ... is used to define access to
named fields in a compound. It is subject to term-expansion
(see expand_term/2) and cannot be called as a predicate. See
section 11.26 for details.
1111..2277 lliibbrraarryy((rreeggiissttrryy)):: MMaanniippuullaattiinngg tthhee WWiinnddoowwss rreeggiissttrryy
The registry is only available on the MS-Windows version of SWI-Prolog.
It loads the foreign extension plregtry.dll, providing the predicates
described below. This library only makes the most common operations
on the registry available through the Prolog user. The underlying DLL
provides a more complete coverage of the Windows registry API. Please
consult the sources in pl/src/win32/foreign/plregtry.c for further
details.
In all these predicates, _P_a_t_h refers to a `/' separated path into
the registry. This is _n_o_t an atom containing `/'-characters as used
for filenames, but a term using the functor //2. Windows defines
the following roots for the registry: classes_root, current_user,
local_machine and users.
rreeggiissttrryy__ggeett__kkeeyy((_+_P_a_t_h_, _-_V_a_l_u_e))
Get the principal (default) value associated to this key. Fails
silently if the key does not exist.
rreeggiissttrryy__ggeett__kkeeyy((_+_P_a_t_h_, _+_N_a_m_e_, _-_V_a_l_u_e))
Get a named value associated to this key.
rreeggiissttrryy__sseett__kkeeyy((_+_P_a_t_h_, _+_V_a_l_u_e))
Set the principal (default) value of this key. Creates (a path to)
the key if it does not already exist.
rreeggiissttrryy__sseett__kkeeyy((_+_P_a_t_h_, _+_N_a_m_e_, _+_V_a_l_u_e))
Associate a named value to this key. Creates (a path to) the key
if it does not already exist.
rreeggiissttrryy__ddeelleettee__kkeeyy((_+_P_a_t_h))
Delete the indicated key.
sshheellll__rreeggiisstteerr__ffiillee__ttyyppee((_+_E_x_t_, _+_T_y_p_e_, _+_N_a_m_e_, _+_O_p_e_n_A_c_t_i_o_n))
Register a file-type. _E_x_t is the extension to associate. _T_y_p_e
is the type name, often something like prolog.type. _N_a_m_e is the
name visible in the Windows file-type browser. Finally, _O_p_e_n_A_c_t_i_o_n
defines the action to execute when a file with this extension is
opened in the Windows explorer.
sshheellll__rreeggiisstteerr__ddddee((_+_T_y_p_e_, _+_A_c_t_i_o_n_, _+_S_e_r_v_i_c_e_, _+_T_o_p_i_c_, _+_C_o_m_m_a_n_d_, _+_I_f_N_o_t_R_u_n_n_i_n_g))
Associate DDE actions to a type. _T_y_p_e is the same type as used for
the 2nd argument of shell_register_file_type/4, _A_c_t_i_o_n is the action
to perform, _S_e_r_v_i_c_e and _T_o_p_i_c specify the DDE topic to address,
and _C_o_m_m_a_n_d is the command to execute on this topic. Finally,
_I_f_N_o_t_R_u_n_n_i_n_g defines the command to execute if the required DDE
server is not present.
sshheellll__rreeggiisstteerr__pprroolloogg((_+_E_x_t))
Default registration of SWI-Prolog, which is invoked as part of the
initialisation process on Windows systems. As the source also
includes the above predicates, it is given as an example:
____________________________________________________________________| |
| shell_register_prolog(Ext) :- |
| current_prolog_flag(argv, [Me|_]), |
| atomic_list_concat(['"', Me, '" "%1"'], OpenCommand), |
| shell_register_file_type( |
| Ext, 'prolog.type', 'Prolog Source', OpenCommand), |
| shell_register_dde( |
| 'prolog.type', consult, |
| prolog, control, 'consult(''%1'')', Me), |
| shell_register_dde( |
| 'prolog.type', edit, |
||____________prolog,_control,_'edit(''%1'')',_Me)._________________ ||
1111..2288 lliibbrraarryy((ssiimmpplleexx)):: SSoollvvee lliinneeaarr pprrooggrraammmmiinngg pprroobblleemmss
Author: _M_a_r_k_u_s _T_r_i_s_k_a
A linear programming problem consists of a set of (linear) constraints,
a number of variables and a linear objective function. The goal is
to assign values to the variables so as to maximize (or minimize) the
value of the objective function while satisfying all constraints.
Many optimization problems can be modeled in this way. Consider having
a knapsack with fixed capacity C, and a number of items with sizes s(i)
and values v(i). The goal is to put as many items as possible in the
knapsack (not exceeding its capacity) while maximizing the sum of their
values.
As another example, suppose you are given a set of coins with certain
values, and you are to find the minimum number of coins such that their
values sum up to a fixed amount. Instances of these problems are
solved below.
The simplex module provides the following predicates:
aassssiiggnnmmeenntt((_+_C_o_s_t_, _-_A_s_s_i_g_n_m_e_n_t))
_C_o_s_t is a list of lists representing the quadratic cost matrix,
where element (i,j) denotes the cost of assigning entity i to
entity j. An assignment with minimal cost is computed and unified
with _A_s_s_i_g_n_m_e_n_t as a list of lists, representing an adjacency
matrix.
ccoonnssttrraaiinntt((_+_C_o_n_s_t_r_a_i_n_t_, _+_S_0_, _-_S))
Adds a linear or integrality constraint to the linear program
corresponding to state _S_0. A linear constraint is of the form
"Left Op C", where "Left" is a list of Coefficient*Variable terms
(variables in the context of linear programs can be atoms or
compound terms) and C is a non-negative numeric constant. The list
represents the sum of its elements. _O_p can be =, =< or >=. The
coefficient "1" can be omitted. An integrality constraint is of
the form integral(Variable) and constrains Variable to an integral
value.
ccoonnssttrraaiinntt((_+_N_a_m_e_, _+_C_o_n_s_t_r_a_i_n_t_, _+_S_0_, _-_S))
Like constraint/3, and attaches the name _N_a_m_e (an atom or compound
term) to the new constraint.
ccoonnssttrraaiinntt__aadddd((_+_N_a_m_e_, _+_L_e_f_t_, _+_S_0_, _-_S))
_L_e_f_t is a list of Coefficient*Variable terms. The terms are added
to the left-hand side of the constraint named _N_a_m_e. _S is unified
with the resulting state.
ggeenn__ssttaattee((_-_S_t_a_t_e))
Generates an initial state corresponding to an empty linear
program.
mmaaxxiimmiizzee((_+_O_b_j_e_c_t_i_v_e_, _+_S_0_, _-_S))
Maximizes the objective function, stated as a list of "Coeffi-
cient*Variable" terms that represents the sum of its elements, with
respect to the linear program corresponding to state _S_0. _S is
unified with an internal representation of the solved instance.
mmiinniimmiizzee((_+_O_b_j_e_c_t_i_v_e_, _+_S_0_, _-_S))
Analogous to maximize/3.
oobbjjeeccttiivvee((_+_S_t_a_t_e_, _-_O_b_j_e_c_t_i_v_e))
Unifies _O_b_j_e_c_t_i_v_e with the result of the objective function at the
obtained extremum. _S_t_a_t_e must correspond to a solved instance.
sshhaaddooww__pprriiccee((_+_S_t_a_t_e_, _+_N_a_m_e_, _-_V_a_l_u_e))
Unifies _V_a_l_u_e with the shadow price corresponding to the linear
constraint whose name is _N_a_m_e. _S_t_a_t_e must correspond to a solved
instance.
ttrraannssppoorrttaattiioonn((_+_S_u_p_p_l_i_e_s_, _+_D_e_m_a_n_d_s_, _+_C_o_s_t_s_, _-_T_r_a_n_s_p_o_r_t))
_S_u_p_p_l_i_e_s and _D_e_m_a_n_d_s are both lists of positive numbers. Their
respective sums must be equal. _C_o_s_t_s is a list of lists
representing the cost matrix, where an entry (i,j) denotes the cost
of transporting one unit from i to j. A transportation plan having
minimum cost is computed and unified with _T_r_a_n_s_p_o_r_t in the form of
a list of lists that represents the transportation matrix, where
element (i,j) denotes how many units to ship from i to j.
vvaarriiaabbllee__vvaalluuee((_+_S_t_a_t_e_, _+_V_a_r_i_a_b_l_e_, _-_V_a_l_u_e))
_V_a_l_u_e is unified with the value obtained for _V_a_r_i_a_b_l_e. _S_t_a_t_e must
correspond to a solved instance.
All numeric quantities are converted to rationals via rationalize/1,
and rational arithmetic is used throughout solving linear programs. In
the current implementation, all variables are implicitly constrained
to be non-negative. This may change in future versions, and
non-negativity constraints should therefore be stated explicitly.
1111..2288..11 EExxaammppllee 11
This is the "radiation therapy" example, taken from "Introduction to
Operations Research" by Hillier and Lieberman. DCG notation is used to
implicitly thread the state through posting the constraints:
________________________________________________________________________| |
|:- use_module(library(simplex)). |
| |
|post_constraints --> |
| constraint([0.3*x1, 0.1*x2] =< 2.7), |
| constraint([0.5*x1, 0.5*x2] = 6), |
| constraint([0.6*x1, 0.4*x2] >= 6), |
| constraint([x1] >= 0), |
| constraint([x2] >= 0). |
| |
|radiation(S) :- |
| gen_state(S0), |
| post_constraints(S0, S1), |
||_______minimize([0.4*x1,_0.5*x2],_S1,_S)._____________________________ ||
An example query:
________________________________________________________________________| |
|?- radiation(S), variable_value(S, x1, Val1), |
| variable_value(S, x2, Val2). |
| |
|Val1 = 15 rdiv 2 |
|Val2|=_9_rdiv_2_;______________________________________________________ | |
1111..2288..22 EExxaammppllee 22
Here is an instance of the knapsack problem described above, where C
= 8, and we have two types of items: One item with value 7 and size
6, and 2 items each having size 4 and value 4. We introduce two
variables, x(1) and x(2) that denote how many items to take of each
type.
________________________________________________________________________| |
|knapsack_constrain(S) :- |
| gen_state(S0), |
| constraint([6*x(1), 4*x(2)] =< 8, S0, S1), |
| constraint([x(1)] =< 1, S1, S2), |
| constraint([x(2)] =< 2, S2, S). |
| |
|knapsack(S) :- |
| knapsack_constrain(S0), |
||_______maximize([7*x(1),_4*x(2)],_S0,_S)._____________________________ ||
An example query yields:
________________________________________________________________________| |
|?- knapsack(S), variable_value(S, x(1), X1), |
| variable_value(S, x(2), X2). |
| |
|X1 = 1 |
|X2|=_1_rdiv_2_;________________________________________________________ | |
That is, we are to take the one item of the first type, and half of one
of the items of the other type to maximize the total value of items in
the knapsack.
If items can not be split, integrality constraints have to be imposed:
________________________________________________________________________| |
|knapsack_integral(S) :- |
| knapsack_constrain(S0), |
| constraint(integral(x(1)), S0, S1), |
| constraint(integral(x(2)), S1, S2), |
||_______maximize([7*x(1),_4*x(2)],_S2,_S)._____________________________ ||
Now the result is different:
________________________________________________________________________| |
|?- knapsack_integral(S), variable_value(S, x(1), X1), |
| variable_value(S, x(2), X2). |
| |
|X1 = 0 |
|X2|=_2_________________________________________________________________ | |
That is, we are to take only the two items of the second type.
Notice in particular that always choosing the remaining item with best
performance (ratio of value to size) that still fits in the knapsack
does not necessarily yield an optimal solution in the presence of
integrality constraints.
1111..2288..33 EExxaammppllee 33
We are given 3 coins each worth 1, 20 coins each worth 5, and 10 coins
each worth 20 units of money. The task is to find a minimal number of
these coins that amount to 111 units of money. We introduce variables
c(1), c(5) and c(20) denoting how many coins to take of the respective
type:
________________________________________________________________________| |
|coins --> |
| constraint([c(1), 5*c(5), 20*c(20)] = 111), |
| constraint([c(1)] =< 3), |
| constraint([c(5)] =< 20), |
| constraint([c(20)] =< 10), |
| constraint([c(1)] >= 0), |
| constraint([c(5)] >= 0), |
| constraint([c(20)] >= 0), |
| constraint(integral(c(1))), |
| constraint(integral(c(5))), |
| constraint(integral(c(20))), |
| minimize([c(1), c(5), c(20)]). |
| |
|coins(S) :- |
| gen_state(S0), |
||_______coins(S0,_S).__________________________________________________ ||
An example query:
________________________________________________________________________| |
|?- coins(S), variable_value(S, c(1), C1), |
| variable_value(S, c(5), C5), |
| variable_value(S, c(20), C20). |
| |
|C1 = 1 |
|C5 = 2 |
|C20|=_5________________________________________________________________ | |
1111..2299 lliibbrraarryy((tthhrreeaadd__ppooooll)):: RReessoouurrccee bboouunnddeedd tthhrreeaadd mmaannaaggeemmeenntt
SSeeee aallssoo http_handler/3 and http_spawn/2.
The module library(thread_pool) manages threads in pools. A pool
defines properties of its member threads and the maximum number of
threads that can coexist in the pool. The call thread_create_in_pool/4
allocates a thread in the pool, just like thread_create/3. If the pool
is fully allocated it can be asked to wait or raise an error.
The library has been designed to deal with server applications that
receive a variety of requests, such as HTTP servers. Simply starting a
thread for each request is a bit too simple minded for such servers:
o Creating many CPU intensive threads often leads to a slow-down
rather than a speedup.
o Creating many memory intensive threads may exhaust resources
o Tasks that require little CPU and memory but take long waiting for
external resources can run many threads.
Using this library, one can define a pool for each set of tasks with
comparable characteristics and create threads in this pool. Unlike the
worker-pool model, threads are not started immediately. Depending on
the design, both approaches can be attractive.
The library is implemented by means of a manager thread with the
fixed thread id __thread_pool_manager. All state is maintained in
this manager thread, which receives and processes requests to create
and destroy pools, create threads in a pool and handle messages from
terminated threads. Thread pools are _n_o_t saved in a saved state and
must therefore be recreated using the initialization/1 directive or
otherwise during startup of the application.
tthhrreeaadd__ppooooll__ccrreeaattee((_+_P_o_o_l_, _+_S_i_z_e_, _+_O_p_t_i_o_n_s)) _[_d_e_t_]
Create a pool of threads. A pool of threads is a declaration
for creating threads with shared properties (stack sizes) and
a limited number of threads. Threads are created using
thread_create_in_pool/4. If all threads in the pool are in use,
the behaviour depends on the wait option of thread_create_in_pool/4
and the backlog option described below. _O_p_t_i_o_n_s are passed to
thread_create/3, except for
bbaacckklloogg((_+_M_a_x_B_a_c_k_L_o_g))
Maximum number of requests that can be suspended. Default is
infinite. Otherwise it must be a non-negative integer. Using
backlog(0) will never delay thread creation for this pool.
The pooling mechanism does _n_o_t interact with the detached state of
a thread. Threads can be created both detached and normal and must
be joined using thread_join/2 if they are not detached.
tthhrreeaadd__ppooooll__ddeessttrrooyy((_+_N_a_m_e)) _[_d_e_t_]
Destroy the thread pool named _N_a_m_e.
EErrrroorrss existence_error(thread_pool, Name).
ccuurrrreenntt__tthhrreeaadd__ppooooll((_?_N_a_m_e)) _[_n_o_n_d_e_t_]
True if _N_a_m_e refers to a defined thread pool.
tthhrreeaadd__ppooooll__pprrooppeerrttyy((_?_N_a_m_e_, _?_P_r_o_p_e_r_t_y)) _[_n_o_n_d_e_t_]
True if _P_r_o_p_e_r_t_y is a property of thread pool _N_a_m_e. Defined
properties are:
ooppttiioonnss((_O_p_t_i_o_n_s))
Thread creation options for this pool
ffrreeee((_S_i_z_e))
Number of free slots on this pool
ssiizzee((_S_i_z_e))
Total number of slots on this pool
mmeemmbbeerrss((_L_i_s_t_O_f_I_D_s))
_L_i_s_t_O_f_I_D_s is the list or threads running in this pool
rruunnnniinngg((_R_u_n_n_i_n_g))
Number of running threads in this pool
bbaacckklloogg((_S_i_z_e))
Number of delayed thread creations on this pool
tthhrreeaadd__ccrreeaattee__iinn__ppooooll((_+_P_o_o_l_, _:_G_o_a_l_, _-_I_d_, _+_O_p_t_i_o_n_s)) _[_d_e_t_]
Create a thread in _P_o_o_l. _O_p_t_i_o_n_s overrule default thread creation
options associated to the pool. In addition, the following option
is defined:
wwaaiitt((_+_B_o_o_l_e_a_n))
If true (default) and the pool is full, wait until a member of
the pool completes. If false, throw a resource_error.
EErrrroorrss
- resource_error(threads_in_pool(Pool)) is raised if
wait is false or the backlog limit has been reached.
- existence_error(thread_pool, Pool) if _P_o_o_l does not
exist.
ccrreeaattee__ppooooll((_+_P_o_o_l_N_a_m_e)) _[_s_e_m_i_d_e_t_,_m_u_l_t_i_f_i_l_e_]
Hook to create a thread pool lazily. The hook is called if
thread_create_in_pool/4 discovers that the thread pool does not
exist. If the hook succeeds, thread_create_in_pool/4 retries
creating the thread. For example, we can use the following
declaration to create threads in the pool media, which holds a
maximum of 20 threads.
____________________________________________________________________| |
| :- multifile thread_pool:create_pool/1. |
| |
| thread_pool:create_pool(media) :- |
||____thread_pool_create(media,_20,_[]).____________________________ ||
1111..3300 lliibbrraarryy((uuggrraapphhss)):: UUnnwweeiigghhtteedd GGrraapphhss
Authors: _R_i_c_h_a_r_d _O_'_K_e_e_f_e _& _V_i_t_o_r _S_a_n_t_o_s _C_o_s_t_a
_I_m_p_l_e_m_e_n_t_a_t_i_o_n _a_n_d _d_o_c_u_m_e_n_t_a_t_i_o_n _a_r_e _c_o_p_i_e_d _f_r_o_m _Y_A_P _5_._0_._1_.
_T_h_e ugraph _l_i_b_r_a_r_y _i_s _b_a_s_e_d _o_n _c_o_d_e _o_r_i_g_i_n_a_l_l_y _w_r_i_t_t_e_n
_b_y _R_i_c_h_a_r_d _O_'_K_e_e_f_e_. _T_h_e _c_o_d_e _w_a_s _t_h_e_n _e_x_t_e_n_d_e_d _t_o _b_e
_c_o_m_p_a_t_i_b_l_e _w_i_t_h _t_h_e _S_I_C_S_t_u_s _P_r_o_l_o_g _u_g_r_a_p_h_s _l_i_b_r_a_r_y_. _C_o_d_e _a_n_d
_d_o_c_u_m_e_n_t_a_t_i_o_n _h_a_v_e _b_e_e_n _c_l_e_a_n_e_d _a_n_d _s_t_y_l_e _h_a_s _b_e_e_n _c_h_a_n_g_e_d _t_o
_b_e _m_o_r_e _i_n _l_i_n_e _w_i_t_h _t_h_e _r_e_s_t _o_f _S_W_I_-_P_r_o_l_o_g_.
_T_h_e _u_g_r_a_p_h_s _l_i_b_r_a_r_y _w_a_s _o_r_i_g_i_n_a_l_l_y _r_e_l_e_a_s_e_d _i_n _t_h_e _p_u_b_l_i_c
_d_o_m_a_i_n_. _T_h_e _Y_A_P _v_e_r_s_i_o_n _i_s _c_o_v_e_r_e_d _b_y _t_h_e _P_e_r_l _A_r_t_i_s_t_i_c
_l_i_c_e_n_s_e_, _v_e_r_s_i_o_n _2_._0_. _T_h_i_s _c_o_d_e _i_s _d_u_a_l_-_l_i_c_e_n_s_e_d _u_n_d_e_r _t_h_e
_m_o_d_i_f_i_e_d _G_P_L _a_s _u_s_e_d _f_o_r _a_l_l _S_W_I_-_P_r_o_l_o_g _l_i_b_r_a_r_i_e_s _o_r _t_h_e _P_e_r_l
_A_r_t_i_s_t_i_c _l_i_c_e_n_s_e_, _v_e_r_s_i_o_n _2_._0_.
The routines assume directed graphs; undirected graphs may be
implemented by using two edges.
Originally graphs were represented in two formats. The SICStus library
and this version of ugraphs.pl only use the _S_-_r_e_p_r_e_s_e_n_t_a_t_i_o_n. The
S-representation of a graph is a list of (vertex-neighbors) pairs,
where the pairs are in standard order (as produced by keysort) and the
neighbors of each vertex are also in standard order (as produced by
sort). This form is convenient for many calculations. Each vertex
appears in the S-representation, even if it has no neighbors.
vveerrttiicceess__eeddggeess__ttoo__uuggrraapphh((_+_V_e_r_t_i_c_e_s_, _+_E_d_g_e_s_, _-_G_r_a_p_h))
Given a graph with a set of _V_e_r_t_i_c_e_s and a set of _E_d_g_e_s, _G_r_a_p_h must
unify with the corresponding S-representation. Note that vertices
without edges will appear in _V_e_r_t_i_c_e_s but not in _E_d_g_e_s. Moreover,
it is sufficient for a vertex to appear in _E_d_g_e_s.
____________________________________________________________________| |
| ?- vertices_edges_to_ugraph([],[1-3,2-4,4-5,1-5], L). |
||L_=_[1-[3,5],_2-[4],_3-[],_4-[5],_5-[]]___________________________ ||
In this case all vertices are defined implicitly. The next example
shows three unconnected vertices:
____________________________________________________________________| |
| ?- vertices_edges_to_ugraph([6,7,8],[1-3,2-4,4-5,1-5], L). |
||L_=_[1-[3,5],_2-[4],_3-[],_4-[5],_5-[],_6-[],_7-[],_8-[]]_?_______ ||
vveerrttiicceess((_+_G_r_a_p_h_, _-_V_e_r_t_i_c_e_s))
Unify _V_e_r_t_i_c_e_s with all vertices appearing in _G_r_a_p_h. Example:
____________________________________________________________________| |
| ?- vertices([1-[3,5],2-[4],3-[],4-[5],5-[]], L). |
||L_=_[1,_2,_3,_4,_5]_______________________________________________ ||
eeddggeess((_+_G_r_a_p_h_, _-_E_d_g_e_s))
Unify _E_d_g_e_s with all edges appearing in _G_r_a_p_h. Example:
____________________________________________________________________| |
| ?- edges([1-[3,5],2-[4],3-[],4-[5],5-[]], L). |
||L_=_[1-3,_1-5,_2-4,_4-5]__________________________________________ ||
aadddd__vveerrttiicceess((_+_G_r_a_p_h_, _+_V_e_r_t_i_c_e_s_, _-_N_e_w_G_r_a_p_h))
Unify _N_e_w_G_r_a_p_h with a new graph obtained by adding the list of
_V_e_r_t_i_c_e_s to _G_r_a_p_h. Example:
____________________________________________________________________| |
| ?- add_vertices([1-[3,5],2-[]], [0,1,2,9], NG). |
||NG_=_[0-[],_1-[3,5],_2-[],_9-[]]__________________________________ ||
ddeell__vveerrttiicceess((_+_G_r_a_p_h_, _+_V_e_r_t_i_c_e_s_, _-_N_e_w_G_r_a_p_h))
Unify _N_e_w_G_r_a_p_h with a new graph obtained by deleting the list
of _V_e_r_t_i_c_e_s and all edges that start from or go to a vertex in
_V_e_r_t_i_c_e_s from _G_r_a_p_h. Example:
____________________________________________________________________| |
| ?- del_vertices([2,1], |
| [1-[3,5],2-[4],3-[],4-[5], |
| 5-[],6-[],7-[2,6],8-[]], |
| NL). |
||NL_=_[3-[],4-[5],5-[],6-[],7-[6],8-[]]____________________________ ||
aadddd__eeddggeess((_+_G_r_a_p_h_, _+_E_d_g_e_s_, _-_N_e_w_G_r_a_p_h))
Unify _N_e_w_G_r_a_p_h with a new graph obtained by adding the list of
_E_d_g_e_s to _G_r_a_p_h. Example:
____________________________________________________________________| |
| ?- add_edges([1-[3,5],2-[4],3-[],4-[5], |
| 5-[],6-[],7-[],8-[]], |
| [1-6,2-3,3-2,5-7,3-2,4-5], |
| NL). |
| NL = [1-[3,5,6], 2-[3,4], 3-[2], 4-[5], |
||______5-[7],_6-[],_7-[],_8-[]]____________________________________ ||
ddeell__eeddggeess((_+_G_r_a_p_h_, _+_E_d_g_e_s_, _-_N_e_w_G_r_a_p_h))
Unify _N_e_w_G_r_a_p_h with a new graph obtained by removing the list of
_E_d_g_e_s from _G_r_a_p_h. Notice that no vertices are deleted. Example:
____________________________________________________________________| |
| ?- del_edges([1-[3,5],2-[4],3-[],4-[5],5-[],6-[],7-[],8-[]], |
| [1-6,2-3,3-2,5-7,3-2,4-5,1-3], |
| NL). |
||NL_=_[1-[5],2-[4],3-[],4-[],5-[],6-[],7-[],8-[]]__________________ ||
ttrraannssppoossee((_+_G_r_a_p_h_, _-_N_e_w_G_r_a_p_h))
Unify _N_e_w_G_r_a_p_h with a new graph obtained from _G_r_a_p_h by replacing
all edges of the form V1-V2 by edges of the form V2-V1. The cost
is O(|V|2). Notice that an undirected graph is its own transpose.
Example:
____________________________________________________________________| |
| ?- transpose([1-[3,5],2-[4],3-[],4-[5], |
| 5-[],6-[],7-[],8-[]], NL). |
||NL_=_[1-[],2-[],3-[1],4-[2],5-[1,4],6-[],7-[],8-[]]_______________ ||
nneeiigghhbboouurrss((_+_V_e_r_t_e_x_, _+_G_r_a_p_h_, _-_V_e_r_t_i_c_e_s))
Unify _V_e_r_t_i_c_e_s with the list of neighbours of vertex _V_e_r_t_e_x in
_G_r_a_p_h. Example:
____________________________________________________________________| |
| ?- neighbours(4,[1-[3,5],2-[4],3-[], |
| 4-[1,2,7,5],5-[],6-[],7-[],8-[]], NL). |
||NL_=_[1,2,7,5]____________________________________________________ ||
nneeiigghhbboorrss((_+_V_e_r_t_e_x_, _+_G_r_a_p_h_, _-_V_e_r_t_i_c_e_s))
American version of neighbours/3.
ccoommpplleemmeenntt((_+_G_r_a_p_h_, _-_N_e_w_G_r_a_p_h))
Unify _N_e_w_G_r_a_p_h with the graph complementary to _G_r_a_p_h. Example:
____________________________________________________________________| |
| ?- complement([1-[3,5],2-[4],3-[], |
| 4-[1,2,7,5],5-[],6-[],7-[],8-[]], NL). |
| NL = [1-[2,4,6,7,8],2-[1,3,5,6,7,8],3-[1,2,4,5,6,7,8], |
| 4-[3,5,6,8],5-[1,2,3,4,6,7,8],6-[1,2,3,4,5,7,8], |
||______7-[1,2,3,4,5,6,8],8-[1,2,3,4,5,6,7]]________________________ ||
ccoommppoossee((_+_L_e_f_t_G_r_a_p_h_, _+_R_i_g_h_t_G_r_a_p_h_, _-_N_e_w_G_r_a_p_h))
Compose _N_e_w_G_r_a_p_h by connecting the _d_r_a_i_n_s of _L_e_f_t_G_r_a_p_h to the
_s_o_u_r_c_e_s of _R_i_g_h_t_G_r_a_p_h. Example:
____________________________________________________________________| |
| ?- compose([1-[2],2-[3]],[2-[4],3-[1,2,4]],L). |
||L_=_[1-[4],_2-[1,2,4],_3-[]]______________________________________ ||
uuggrraapphh__uunniioonn((_+_G_r_a_p_h_1_, _+_G_r_a_p_h_2_, _-_N_e_w_G_r_a_p_h))
_N_e_w_G_r_a_p_h is the union of _G_r_a_p_h_1 and _G_r_a_p_h_2. Example:
____________________________________________________________________| |
| ?- ugraph_union([1-[2],2-[3]],[2-[4],3-[1,2,4]],L). |
||L_=_[1-[2],_2-[3,4],_3-[1,2,4]]___________________________________ ||
ttoopp__ssoorrtt((_+_G_r_a_p_h_, _-_S_o_r_t))
Generate the set of nodes _S_o_r_t as a topological sorting of _G_r_a_p_h,
if one is possible. A toplogical sort is possible if the graph
is connected and acyclic. In the example we show how topological
sorting works for a linear graph:
____________________________________________________________________| |
| ?- top_sort([1-[2], 2-[3], 3-[]], L). |
||L_=_[1,_2,_3]_____________________________________________________ ||
ttoopp__ssoorrtt((_+_G_r_a_p_h_, _-_S_o_r_t_0_, _-_S_o_r_t))
Generate the difference list Sort-Sort0 as a topological sorting of
_G_r_a_p_h, if one is possible.
ttrraannssiittiivvee__cclloossuurree((_+_G_r_a_p_h_, _-_C_l_o_s_u_r_e))
Generate the graph Closure as the transitive closure of _G_r_a_p_h.
Example:
____________________________________________________________________| |
| ?- transitive_closure([1-[2,3],2-[4,5],4-[6]],L). |
||L_=_[1-[2,3,4,5,6],_2-[4,5,6],_4-[6]]_____________________________ ||
rreeaacchhaabbllee((_+_V_e_r_t_e_x_, _+_G_r_a_p_h_, _-_V_e_r_t_i_c_e_s))
Unify _V_e_r_t_i_c_e_s with the set of all vertices in _G_r_a_p_h that are
reachable from _V_e_r_t_e_x. Example:
____________________________________________________________________| |
| ?- reachable(1,[1-[3,5],2-[4],3-[],4-[5],5-[]],V). |
||V_=_[1,_3,_5]_____________________________________________________ ||
1111..3311 lliibbrraarryy((uurrll)):: AAnnaallyyssiinngg aanndd ccoonnssttrruuccttiinngg UURRLL
aauutthhoorr
- Jan Wielemaker
- Lukas Faulstich
ddeepprreeccaatteedd New code should use library(uri), provided by the
clib package.
This library deals with the analysis and construction of a URL,
Universal Resource Locator. URL is the basis for communicating
locations of resources (data) on the web. A URL consists of a protocol
identifier (e.g. HTTP, FTP, and a protocol-specific syntax further
defining the location. URLs are standardized in RFC-1738.
The implementation in this library covers only a small portion of the
defined protocols. Though the initial implementation followed RFC-1738
strictly, the current is more relaxed to deal with frequent violations
of the standard encountered in practical use.
gglloobbaall__uurrll((_+_U_R_L_, _+_B_a_s_e_, _-_G_l_o_b_a_l)) _[_d_e_t_]
Translate a possibly relative _U_R_L into an absolute one.
EErrrroorrss syntax_error(illegal_url) if _U_R_L is not legal.
iiss__aabbssoolluuttee__uurrll((_+_U_R_L))
True if _U_R_L is an absolute _U_R_L. That is, a _U_R_L that starts with a
protocol identifier.
hhttttpp__llooccaattiioonn((_?_P_a_r_t_s_, _?_L_o_c_a_t_i_o_n))
Construct or analyze an HTTP location. This is similar to
parse_url/2, but only deals with the location part of an HTTP URL.
That is, the path, search and fragment specifiers. In the HTTP
protocol, the first line of a message is
____________________________________________________________________| |
||<Action>_<Location>_HTTP/<version>________________________________ ||
___________________________________________________________Arguments_
_L_o_c_a_t_i_o_n Atom or list of character codes.
ppaarrssee__uurrll((_+_U_R_L_, _-_A_t_t_r_i_b_u_t_e_s)) _[_d_e_t_]
Construct or analyse a _U_R_L. _U_R_L is an atom holding a _U_R_L or a
variable. _A_t_t_r_i_b_u_t_e_s is a list of components. Each component is
of the format Name(Value). Defined components are:
pprroottooccooll((_P_r_o_t_o_c_o_l))
The used protocol. This is, after the optional url:, an
identifier separated from the remainder of the _U_R_L using
:. parse_url/2 assumes the http protocol if no protocol is
specified and the _U_R_L can be parsed as a valid HTTP url.
In addition to the RFC-1738 specified protocols, the file
protocol is supported as well.
hhoosstt((_H_o_s_t))
_H_o_s_t-name or IP-address on which the resource is located.
Supported by all network-based protocols.
ppoorrtt((_P_o_r_t))
Integer port-number to access on the \arg{Host}. This only
appears if the port is explicitly specified in the _U_R_L.
Implicit default ports (e.g., 80 for HTTP) do _n_o_t appear in
the part-list.
ppaatthh((_P_a_t_h))
(File-) path addressed by the _U_R_L. This is supported for the
ftp, http and file protocols. If no path appears, the library
generates the path /.
sseeaarrcchh((_L_i_s_t_O_f_N_a_m_e_V_a_l_u_e))
Search-specification of HTTP _U_R_L. This is the part after the
?, normally used to transfer data from HTML forms that use the
GET protocol. In the _U_R_L it consists of a www-form-encoded
list of Name=Value pairs. This is mapped to a list of Prolog
Name=Value terms with decoded names and values.
ffrraaggmmeenntt((_F_r_a_g_m_e_n_t))
_F_r_a_g_m_e_n_t specification of HTTP _U_R_L. This is the part after the
# character.
The example below illustrates all of this for an HTTP _U_R_L.
____________________________________________________________________| |
| ?- parse_url('http://www.xyz.org/hello?msg=Hello+World%21#x', |
| P). |
| |
| P = [ protocol(http), |
| host('www.xyz.org'), |
| fragment(x), |
| search([ msg = 'Hello World!' |
| ]), |
| path('/hello') |
||____]_____________________________________________________________ ||
By instantiating the parts-list this predicate can be used to
create a _U_R_L.
ppaarrssee__uurrll((_+_U_R_L_, _+_B_a_s_e_U_R_L_, _-_A_t_t_r_i_b_u_t_e_s)) _[_d_e_t_]
Similar to parse_url/2 for relative URLs. If _U_R_L is relative, it
is resolved using the absolute _U_R_L _B_a_s_e_U_R_L.
wwwwww__ffoorrmm__eennccooddee((_+_V_a_l_u_e_, _-_X_W_W_W_F_o_r_m_E_n_c_o_d_e_d)) _[_d_e_t_]
wwwwww__ffoorrmm__eennccooddee((_-_V_a_l_u_e_, _+_X_W_W_W_F_o_r_m_E_n_c_o_d_e_d)) _[_d_e_t_]
En/decode to/from application/x-www-form-encoded. Encoding encodes
all characters except RFC 3986 _u_n_r_e_s_e_r_v_e_d (ASCII alnum (see
code_type/2)), and one of "-._ " using percent encoding. Newline
is mapped to %OD%OA. When decoding, newlines appear as a single
newline (10) character.
Note that a space is encoded as %20 instead of +. Decoding decodes
both to a space.
ddeepprreeccaatteedd Use uri_encoded/3 for new code.
sseett__uurrll__eennccooddiinngg((_?_O_l_d_, _+_N_e_w)) _[_s_e_m_i_d_e_t_]
Query and set the encoding for URLs. The default is utf8. The
only other defined value is iso_latin_1.
TToo bbee ddoonnee Having a global flag is highly inconvenient,
but a work-around for old sites using ISO Latin 1
encoding.
uurrll__iirrii((_+_E_n_c_o_d_e_d_, _-_D_e_c_o_d_e_d)) _[_d_e_t_]
uurrll__iirrii((_-_E_n_c_o_d_e_d_, _+_D_e_c_o_d_e_d)) _[_d_e_t_]
Convert between a URL, encoding in US-ASCII and an IRI. An IRI is a
fully expanded Unicode string. Unicode strings are first encoded
into UTF-8, after which %-encoding takes place.
ppaarrssee__uurrll__sseeaarrcchh((_?_S_p_e_c_, _?_F_i_e_l_d_s_:_l_i_s_t_(_N_a_m_e_=_V_a_l_u_e_))) _[_d_e_t_]
Construct or analyze an HTTP search specification. This deals with
form data using the MIME-type application/x-www-form-urlencoded as
used in HTTP GET requests.
ffiillee__nnaammee__ttoo__uurrll((_+_F_i_l_e_, _-_U_R_L)) _[_d_e_t_]
ffiillee__nnaammee__ttoo__uurrll((_-_F_i_l_e_, _+_U_R_L)) _[_s_e_m_i_d_e_t_]
Translate between a filename and a file:// _U_R_L.
TToo bbee ddoonnee Current implementation does not deal with
paths that need special encoding.
1111..3322 lliibbrraarryy((vvaarrnnuummbbeerrss)):: UUttiilliittiieess ffoorr nnuummbbeerreedd tteerrmmss
SSeeee aallssoo numbervars/4, =@=/2 (variant/2).
CCoommppaattiibbiilliittyy This library was introduced by Quintus and
available in many related implementations, although not
with exactly the same set of predicates.
This library provides the inverse functionality of the built-in
numbervars/3. Note that this library suffers from the known issues
that '$VAR'(X) is a normal Prolog term and, -unlike the built-in
numbervars-, the inverse predicates do _n_o_t process cyclic terms. The
following predicate is true for any acyclic term that contains no
'$VAR'(X), integer(X) terms and no constraint variables:
________________________________________________________________________| |
|always_true(X) :- |
| copy_term(X, X2), |
| numbervars(X), |
| varnumbers(X, Copy), |
||_____Copy_=@=_X2._____________________________________________________ ||
nnuummbbeerrvvaarrss((_+_T_e_r_m)) _[_d_e_t_]
Number variables in _T_e_r_m using $VAR(N). Equivalent to
numbervars(Term, 0, _).
SSeeee aallssoo numbervars/3, numbervars/4
vvaarrnnuummbbeerrss((_+_T_e_r_m_, _-_C_o_p_y)) _[_d_e_t_]
Inverse of numbervars/1. Equivalent to varnumbers(Term, 0, Copy).
vvaarrnnuummbbeerrss((_+_T_e_r_m_, _+_S_t_a_r_t_, _-_C_o_p_y)) _[_d_e_t_]
Inverse of numbervars/3. True when _C_o_p_y is a copy of _T_e_r_m with
all variables numbered >= _S_t_a_r_t consistently replaced by fresh
variables. Variables in _T_e_r_m are _s_h_a_r_e_d with _C_o_p_y rather than
replaced by fresh variables.
EErrrroorrss domain_error(acyclic_term, Term) if _T_e_r_m is
cyclic.
CCoommppaattiibbiilliittyy Quintus, SICStus. Not in YAP version of
this library
mmaaxx__vvaarr__nnuummbbeerr((_+_T_e_r_m_, _+_S_t_a_r_t_, _-_M_a_x)) _[_d_e_t_]
True when _M_a_x is the max of _S_t_a_r_t and the highest numbered $VAR(N)
term.
aauutthhoorr Vitor Santos Costa
CCoommppaattiibbiilliittyy YAP
CChhaapptteerr 1122.. HHAACCKKEERRSS CCOORRNNEERR
This appendix describes a number of predicates which enable the
Prolog user to inspect the Prolog environment and manipulate (or
even redefine) the debugger. They can be used as entry points for
experiments with debugging tools for Prolog. The predicates described
here should be handled with some care as it is easy to corrupt the
consistency of the Prolog system by misusing them.
1122..11 EExxaammiinniinngg tthhee EEnnvviirroonnmmeenntt SSttaacckk
pprroolloogg__ccuurrrreenntt__ffrraammee((_-_F_r_a_m_e)) _[_d_e_t_]
Unify _F_r_a_m_e with an integer providing a reference to the parent
of the current local stack frame. A pointer to the current
local frame cannot be provided as the predicate succeeds
deterministically and therefore its frame is destroyed immediately
after succeeding.
pprroolloogg__ccuurrrreenntt__cchhooiiccee((_-_C_h_o_i_c_e)) _[_s_e_m_i_d_e_t_]
Unify _C_h_o_i_c_e with an integer provided a reference to the last
choice point. Fails if the current environment has no choice
points. See also prolog_choice_attribute/3.
pprroolloogg__ffrraammee__aattttrriibbuuttee((_+_F_r_a_m_e_, _+_K_e_y_, _:_V_a_l_u_e))
Obtain information about the local stack frame _F_r_a_m_e. _F_r_a_m_e
is a frame reference as obtained through prolog_current_frame/1,
prolog_trace_interception/4 or this predicate. The key values are
described below.
aalltteerrnnaattiivvee
_V_a_l_u_e is unified with an integer reference to the local stack
frame in which execution is resumed if the goal associated
with _F_r_a_m_e fails. Fails if the frame has no alternative
frame.
hhaass__aalltteerrnnaattiivveess
_V_a_l_u_e is unified with true if _F_r_a_m_e still is a candidate for
backtracking; false otherwise.
ggooaall
_V_a_l_u_e is unified with the goal associated with _F_r_a_m_e. If
the definition module of the active predicate is not the
calling context, the goal is represented as <_m_o_d_u_l_e>:<_g_o_a_l>.
Do not instantiate variables in this goal unless you kknnooww
what you are doing! Note that the returned term may contain
references to the frame and should be discarded before the
frame terminates.
ppaarreenntt__ggooaall
If _V_a_l_u_e is instantiated to a callable term, find a frame
executing the predicate described by _V_a_l_u_e and unify the
arguments of _V_a_l_u_e to the goal arguments associated with the
frame. This is intended to check the current execution
context. The user must ensure the checked parent goal is not
removed from the stack due to last-call optimisation and be
aware of the slow operation on deeply nested calls.
pprreeddiiccaattee__iinnddiiccaattoorr
Similar to goal, but only returning the
[<_m_o_d_u_l_e>:]<_n_a_m_e>/<_a_r_i_t_y> term describing the term, not
the actual arguments. It avoids creating an illegal term as
goal and is used by the library prolog_stack.
ccllaauussee
_V_a_l_u_e is unified with a reference to the currently running
clause. Fails if the current goal is associated with a
foreign (C) defined predicate. See also nth_clause/3 and
clause_property/2.
lleevveell
_V_a_l_u_e is unified with the recursion level of _F_r_a_m_e. The top
level frame is at level `0'.
ppaarreenntt
_V_a_l_u_e is unified with an integer reference to the parent local
stack frame of _F_r_a_m_e. Fails if _F_r_a_m_e is the top frame.
ccoonntteexxtt__mmoodduullee
_V_a_l_u_e is unified with the name of the context module of the
environment.
ttoopp
_V_a_l_u_e is unified with true if _F_r_a_m_e is the top Prolog goal
from a recursive call back from the foreign language; false
otherwise.
hhiiddddeenn
_V_a_l_u_e is unified with true if the frame is hidden from the
user, either because a parent has the hide-childs attribute
(all system predicates), or the system has no trace-me
attribute.
sskkiippppeedd
_V_a_l_u_e is true if this frame was skipped in the debugger.
ppcc
_V_a_l_u_e is unified with the program pointer saved on behalf
of the parent goal if the parent goal is not owned by a
foreign predicate or belongs to a compound meta-call (e.g.,
call((a,b))).
aarrgguummeenntt((_N))
_V_a_l_u_e is unified with the _N-th slot of the frame. Argument
1 is the first argument of the goal. Arguments above the
arity refer to local variables. Fails silently if _N is out of
range.
pprroolloogg__cchhooiiccee__aattttrriibbuuttee((_+_C_h_o_i_c_e_P_o_i_n_t_, _+_K_e_y_, _-_V_a_l_u_e))
Extract attributes of a choice point. _C_h_o_i_c_e_P_o_i_n_t is a reference
to a choice point as passed to prolog_trace_interception/4 on
the 3rd argument or obtained using prolog_current_choice/1. _K_e_y
specifies the requested information:
ppaarreenntt
Requests a reference to the first older choice point.
ffrraammee
Requests a reference to the frame to which the choice point
refers.
ttyyppee
Requests the type. Defined values are clause (the goal
has alternative clauses), foreign (non-deterministic foreign
predicate), jump (clause internal choice point), top (first
dummy choice point), catch (catch/3 to allow for undo), debug
(help the debugger), or none (has been deleted).
This predicate is used for the graphical debugger to show the
choice point stack.
ddeetteerrmmiinniissttiicc((_-_B_o_o_l_e_a_n))
Unifies its argument with true if no choice point exists that is
more recent than the entry of the clause in which it appears.
There are few realistic situations for using this predicate. It
is used by the prolog/0 top level to check whether Prolog should
prompt the user for alternatives. Similar results can be achieved
in a more portable fashion using call_cleanup/2.
1122..22 AAnncceessttrraall ccuuttss
pprroolloogg__ccuutt__ttoo((_+_C_h_o_i_c_e))
Prunes all choice points created since _C_h_o_i_c_e. Can be used
together with prolog_current_choice/1 to implement _a_n_c_e_s_t_r_a_l cuts.
This predicate is in the hackers corner because it should not be
used in normal Prolog code. It may be used to create new high
level control structures, particularly for compatibility purposes.
1122..33 SSyynnttaaxx eexxtteennssiioonnss
Prolog is commonly used to define _d_o_m_a_i_n _s_p_e_c_i_f_i_c _l_a_n_g_u_a_g_e_s (DSL)
as well as to interact with external languages that have a concrete
syntax, such as HTML, JavaScript or SQL. Standard Prolog provides
operators (see section 4.25) for extending its syntax. Unfortunately,
Prolog's syntax is rather peculiar and operators do not allow
for commonly seen syntactical patterns such as array subscripting,
expressing attributes, scope or a body using curly brackets,
distinguishing identifiers or strings from `functions', etc.
The syntactic extensions described in section 12.3.1 provide additional
constructs to extend the syntax. These extensions allow for coping
with a large part of the _c_u_r_l_y _b_r_a_c_k_e_t _l_a_n_g_u_a_g_e_s, which allows for
defining DSLs that are more natural to use, in particular for people
that are less familiar with Prolog.
For some external languages it can be sufficient to support the simple
data model using a completely different Prolog concrete syntax. This
is for example the case for HTML, as implemented by the library
http/html_write. With the extensions of section 12.3.1, this also
becomes true for the statistics language R, which was one of the
motivations for these extensions. These extensions are motivated in
[Wielemaker & Angelopoulos, ].
Other languages, such as full JavaScript, are too different from
Prolog for dealing with them using (extended) Prolog operator. While
most of the JavaScript syntax can be covered with the extended
notion of operators, the produced Prolog term does not unambiguishly
describe the JavaScript abstract syntax. For example, both ++a and
a++ are, with the appropriate operator declarations, valid Prolog
syntax. However, they both map to the term ++(_a) and thus a Prolog
JavaScript serialization does not know which these two forms the
generate. More classical, "string" produces the same Prolog term as
[115,116,114,105,110,103].
An alternative to syntax extension using (extended) operators are
_q_u_a_s_i _q_u_o_t_a_t_i_o_n_s [Mainland, 2007]. Quasi quotations embed external
languages in a Prolog term using their native syntax. The language
is specified in the quotation. Parsing such a term causes Prolog to
call the associated parser which creates an abstract syntax tree that
unambiguosly represents the code fragment and which can be processed
in Prolog or serialized for external processing. Quasi quotations
are realised by library quasi_quotations, which is documented in
section 11.23.
1122..33..11 BBlloocckk ooppeerraattoorrss
Introducing curly bracket, array subscripting and empty argument lists
is achieved using _b_l_o_c_k _o_p_e_r_a_t_o_r_s. The atoms [], {} and () may be
declared as an operator, which has the following effect:
[[ ]]
This operator is typically declared as a low-priority yf postfix
operator, which allows for array[index] notation. This syntax
produces a term []([index],array).
{ }
This operator is typically declared as a low-priority xf postfix
operator, which allows for head(arg) { body } notation. This
syntax produces a term {}({body},head(arg)).
(( ))
This operator can only meaningfully be declared as a low-priority
xf postfix operator, which allows for name() notation. This syntax
produces a term '()'(name). This transformation only applies if
the opening bracket immediately follows the functor name, i.e.,
following the same rules as for constructing a compound term.
Below is an example that illustrates the representation of a typical
`curly bracket language' in Prolog.
________________________________________________________________________| |
|?- op(1, xf, '()'). |
|?- op(100, xf, {}). |
|?- op(100, yf, []). |
|?- op(1100, yf, ;). |
| |
|?- displayq(func(arg) |
| { a[10] = 5; |
| update(); |
| }). |
|{}({}(;(=([]('.'(10,[]),a),5),;('()'(update)))),func(arg))|____________ | |
1122..44 IInntteerrcceeppttiinngg tthhee TTrraacceerr
pprroolloogg__ttrraaccee__iinntteerrcceeppttiioonn((_+_P_o_r_t_, _+_F_r_a_m_e_, _+_C_h_o_i_c_e_, _-_A_c_t_i_o_n))
Dynamic predicate, normally not defined. This predicate is called
from the SWI-Prolog debugger just before it would show a port.
If this predicate succeeds, the debugger assumes that the trace
action has been taken care of and continues execution as described
by _A_c_t_i_o_n. Otherwise the normal Prolog debugger actions are
performed.
_P_o_r_t denotes the reason to activate the tracer (`port' in the
4/5-port, but with some additions):
ccaallll
Normal entry through the call port of the 4-port debugger.
rreeddoo((_P_C))
Normal entry through the redo port of the 4-port debugger.
The redo port signals resuming a predicate to generate
alternative solutions. If _P_C is 0 (zero), clause indexing has
found another clause that will be tried next. Otherwise, _P_C
is the program counter in the current clause where execution
continues. This implies we are dealing with an in-clause
choice point left by, e.g., ;/2. Note that non-determinism in
foreign predicates are also handled using an in-clause choice
point.
uunniiffyy
The unify port represents the _n_e_c_k instruction, signalling
the end of the head-matching process. This port is normally
invisible. See leash/1 and visible/1.
eexxiitt
The exit port signals the goal is proved. It is possible for
the goal to have alternatives. See prolog_frame_attribute/3 to
examine the goal stack.
ffaaiill
The fail port signals final failure of the goal.
eexxcceeppttiioonn((_E_x_c_e_p_t))
An exception is raised and still pending. This port is
activated on each parent frame of the frame generating the
exception until the exception is caught or the user restarts
normal computation using retry. _E_x_c_e_p_t is the pending
exception term.
bbrreeaakk((_P_C))
A break instruction is executed. _P_C is program counter. This
port is used by the graphical debugger.
ccuutt__ccaallll((_P_C))
A cut is encountered at _P_C. This port is used by the graphical
debugger to visualise the effect of the cut.
ccuutt__eexxiitt((_P_C))
A cut has been executed. See cut_call(_P_C) for more informa-
tion.
_F_r_a_m_e is a reference to the current local stack frame, which
can be examined using prolog_frame_attribute/3. _C_h_o_i_c_e is a
reference to the last choice point and can be examined using
prolog_choice_attribute/3. _A_c_t_i_o_n must be unified with a term that
specifies how execution must continue. The following actions are
defined:
aabboorrtt
Abort execution. See abort/0.
ccoonnttiinnuuee
Continue (i.e., _c_r_e_e_p in the command line debugger).
ffaaiill
Make the current goal fail.
iiggnnoorree
Step over the current goal without executing it.
nnooddeebbuugg
Continue execution in normal nodebugging mode. See nodebug/0.
rreettrryy
Retry the current frame.
rreettrryy((_F_r_a_m_e))
Retry the given frame. This must be a parent of the current
frame.
sskkiipp
Skip over the current goal (i.e., _s_k_i_p in the command line
debugger).
Together with the predicates described in section 4.38 and the
other predicates of this chapter, this predicate enables the Prolog
user to define a complete new debugger in Prolog. Besides this,
it enables the Prolog programmer to monitor the execution of a
program. The example below records all goals trapped by the tracer
in the database.
____________________________________________________________________| |
| prolog_trace_interception(Port, Frame, _PC, continue) :- |
| prolog_frame_attribute(Frame, goal, Goal), |
| prolog_frame_attribute(Frame, level, Level), |
||________recordz(trace,_trace(Port,_Level,_Goal))._________________ ||
To trace the execution of `go' this way the following query should
be given:
____________________________________________________________________| |
||?-_trace,_go,_notrace.____________________________________________ ||
pprroolloogg__sskkiipp__ffrraammee((_-_F_r_a_m_e))
Indicate _F_r_a_m_e as a skipped frame and set the `skip level' (see
prolog_skip_level/2 to the recursion depth of _F_r_a_m_e. The effect of
the skipped flag is that a redo on a child of this frame is handled
differently. First, a redo trace is called for the child, where
the skip level is set to redo_in_skip. Next, the skip level is set
to skip level of the skipped frame.
pprroolloogg__sskkiipp__lleevveell((_-_O_l_d_, _+_N_e_w))
Unify _O_l_d with the old value of `skip level' and then set
this level according to _N_e_w. _N_e_w is an integer, the atom
very_deep (meaning don't skip) or the atom skip_in_redo (see
prolog_skip_frame/1). The `skip level' is a setting of each Prolog
thread that disables the debugger on all recursion levels deeper
than the level of the variable. See also prolog_skip_frame/1.
1122..55 BBrreeaakkppooiinntt aanndd wwaattcchhppooiinntt hhaannddlliinngg
SWI-Prolog support _b_r_e_a_k_p_o_i_n_t_s. Breakpoints can be manipulated with
the library prolog_breakpoints. Setting a breakpoint replaces a
virtual machine instruction with the D_BREAK instruction. If the
virtual machine executes a D_BREAK, it performs a callback to decide on
the action to perform. This section describes this callback, called
prolog:break_hook/6.
pprroolloogg::bbrreeaakk__hhooookk((_+_C_l_a_u_s_e_, _+_P_C_, _+_F_R_, _+_B_F_R_, _+_E_x_p_r_e_s_s_i_o_n_, _-_A_c_t_i_o_n))_[_h_o_o_k_,_s_e_m_i_d_e_t_]
_E_x_p_e_r_i_m_e_n_t_a_l This hook is called if the virtual machine executes a
D_BREAK, set using set_breakpoint/4. _C_l_a_u_s_e and _P_C identify the
breakpoint. _F_R and _B_F_R provide the environment frame and current
choicepoint. _E_x_p_r_e_s_s_i_o_n identifies the action that is interrupted,
and is one of the following:
ccaallll((_G_o_a_l))
The instruction will call _G_o_a_l. This is generated for nearly
all instructions. Note that _G_o_a_l is semantically equivalent
to the compiled body term, but might differ syntactically.
This is notably the case when artithmetic expressions are
compiled in optimized mode (see optimise). In particular,
the arguments of arithmetic expressions have already been
evaluated. Thus, _A is 3*_B, where _B equals 3 results in a
term call(A is 9) if the clause was compiled with optimization
enabled.
!
The instruction will call the cut. Because the semantics of
metacalling the cut differs from executing the cut in its
original context we do not wrap the cut in call/1.
:-
The breakpoint is on the _n_e_c_k instruction, i.e., after
performing the head unifications.
eexxiitt
The breakpoint is on the _e_x_i_t instruction, i.e., at the end of
the clause. Note that the exit instruction may not be reached
due to last-call optimisation.
uunniiffyy__eexxiitt
The breakpoint is on the completion of an in-lined unification
while the system is not in debug mode. If the system is in
debug mode, inlined unification is returned as call(Var=Term).
If prolog:break_hook/6 succeeds, it must unify _A_c_t_i_o_n with a value
that describes how execution must continue. Possible values for
_A_c_t_i_o_n are:
ccoonnttiinnuuee
Just continue as if no breakpoint was present.
ddeebbuugg
Continue in _d_e_b_u_g _m_o_d_e. See debug/0.
ttrraaccee
Continue in _t_r_a_c_e _m_o_d_e. See trace/0.
ccaallll((_G_o_a_l))
Execute _G_o_a_l instead of the goal that would be executed.
_G_o_a_l is executed as call/1, preserving (non-)determinism and
exceptions.
If this hook throws an exception, the exception is propagated
normally. If this hook is not defined or fails, the default action
is executed. This implies that, if the thread is in debug mode,
the tracer will be enabled (trace) and otherwise the breakpoint is
ignored (continue).
This hook allows for injecting various debugging scenarios into the
executable without recompiling. The hook can access variables of
the calling context using the frame inspection predicates. Here
are some examples.
o Create _c_o_n_d_i_t_i_o_n_a_l breakpoints by imposing conditions before
deciding the return trace.
o Watch variables at a specific point in the execution. Note
that binding of these variables can be monitored using
_a_t_t_r_i_b_u_t_e_d _v_a_r_i_a_b_l_e_s, see section 6.1.
o Dynamically add _a_s_s_e_r_t_i_o_n_s on variables using assertion/1.
o Wrap the _G_o_a_l into a meta-call that traces progress of the
_G_o_a_l.
1122..66 AAddddiinngg ccoonntteexxtt ttoo eerrrroorrss:: pprroolloogg__eexxcceeppttiioonn__hhooookk
The hook prolog_exception_hook/4 has been introduced in SWI-Prolog 5.6.5
to provide dedicated exception handling facilities for application
frameworks, for example non-interactive server applications that wish
to provide extensive context for exceptions for offline debugging.
pprroolloogg__eexxcceeppttiioonn__hhooookk((_+_E_x_c_e_p_t_i_o_n_I_n_, _-_E_x_c_e_p_t_i_o_n_O_u_t_, _+_F_r_a_m_e_, _+_C_a_t_c_h_e_r_F_r_a_m_e))
This hook predicate, if defined in the module user, is between
raising an exception and handling it. It is intended to
allow a program adding additional context to an exception to
simplify diagnosing the problem. _E_x_c_e_p_t_i_o_n_I_n is the exception
term as raised by throw/1 or one of the built-in predicates.
The output argument _E_x_c_e_p_t_i_o_n_O_u_t describes the exception that
is actually raised. _F_r_a_m_e is the innermost frame. See
prolog_frame_attribute/3 and the library prolog_stack for getting
information from this. _C_a_t_c_h_e_r_F_r_a_m_e is a reference to the frame
calling the matching catch/3 or none if the exception is not
caught.
The hook is run in `nodebug' mode. If it succeeds, _E_x_c_e_p_t_i_o_n_O_u_t is
considered the current exception. If it fails, _E_x_c_e_p_t_i_o_n_I_n is used
for further processing. The hook is _n_e_v_e_r called recursively. The
hook is _n_o_t allowed to modify _E_x_c_e_p_t_i_o_n_O_u_t in such a way that it no
longer unifies with the catching frame.
Typically, prolog_exception_hook/4 is used to fill the second
argument of error(_F_o_r_m_a_l_, _C_o_n_t_e_x_t) exceptions. _F_o_r_m_a_l is defined
by the ISO standard, while SWI-Prolog defines _C_o_n_t_e_x_t as a
term context(_L_o_c_a_t_i_o_n_, _M_e_s_s_a_g_e). _L_o_c_a_t_i_o_n is bound to a term
<_n_a_m_e>/<_a_r_i_t_y> by the kernel. This hook can be used to add more
information on the calling context, such as a full stack trace.
Applications that use exceptions as part of normal processing must
do a quick test of the environment before starting expensive
gathering information on the state of the program.
The hook can call trace/0 to enter trace mode immediately. For
example, imagine an application performing an unwanted division by
zero while all other errors are expected and handled. We can force
the debugger using the hook definition below. Run the program in
debug mode (see debug/0) to preserve as much as possible of the
error context.
____________________________________________________________________| |
| user:prolog_exception_hook( |
| error(evaluation_error(zero_divisor), _), |
| _, _, _) :- |
||________trace,_fail.______________________________________________ ||
1122..77 HHooookkss uussiinngg tthhee eexxcceeppttiioonn pprreeddiiccaattee
This section describes the predicate exception/3, which can be defined
by the user in the module user as a multifile predicate. Unlike the
name suggests, this is actually a _h_o_o_k predicate that has no relation
to Prolog exceptions as defined by the ISO predicates catch/3 and
throw/1.
The predicate exception/3 is called by the kernel on a couple of
events, allowing the user to `fix' errors just-in-time. The mechanism
allows for _l_a_z_y creation of objects such as predicates.
eexxcceeppttiioonn((_+_E_x_c_e_p_t_i_o_n_, _+_C_o_n_t_e_x_t_, _-_A_c_t_i_o_n))
Dynamic predicate, normally not defined. Called by the Prolog
system on run-time exceptions that can be repaired `just-in-time'.
The values for _E_x_c_e_p_t_i_o_n are described below. See also catch/3 and
throw/1.
If this hook predicate succeeds it must instantiate the _A_c_t_i_o_n
argument to the atom fail to make the operation fail silently,
retry to tell Prolog to retry the operation or error to make the
system generate an exception. The action retry only makes sense if
this hook modified the environment such that the operation can now
succeed without error.
uunnddeeffiinneedd__pprreeddiiccaattee
_C_o_n_t_e_x_t is instantiated to a predicate indicator
([module]:<_n_a_m_e>/<_a_r_i_t_y>). If the predicate fails, Prolog will
generate an existence_error exception. The hook is intended
to implement alternatives to the built-in autoloader, such as
autoloading code from a database. Do _n_o_t use this hook to
suppress existence errors on predicates. See also unknown and
section 2.13.
uunnddeeffiinneedd__gglloobbaall__vvaarriiaabbllee
_C_o_n_t_e_x_t is instantiated to the name of the missing global
variable. The hook must call nb_setval/2 or b_setval/2 before
returning with the action retry.
1122..88 HHooookkss ffoorr iinntteeggrraattiinngg lliibbrraarriieess
Some libraries realise an entirely new programming paradigm on top of
Prolog. An example is XPCE which adds an object system to Prolog as
well as an extensive set of graphical primitives. SWI-Prolog provides
several hooks to improve the integration of such libraries. See also
section 4.5 for editing hooks and section 4.10.3 for hooking into the
message system.
pprroolloogg__lliisstt__ggooaall((_:_G_o_a_l))
Hook, normally not defined. This hook is called by the 'L' command
of the tracer in the module user to list the currently called
predicate. This hook may be defined to list only relevant clauses
of the indicated _G_o_a_l and/or show the actual source code in an
editor. See also portray/1 and multifile/1.
pprroolloogg::ddeebbuugg__ccoonnttrrooll__hhooookk((_:_A_c_t_i_o_n))
Hook for the debugger control predicates that allows the creator of
more high-level programming languages to use the common front-end
predicates to control the debugger. For example, XPCE uses these
hooks to allow for spying methods rather than predicates. _A_c_t_i_o_n
is one of:
ssppyy((_S_p_e_c))
Hook in spy/1. If the hook succeeds spy/1 takes no further
action.
nnoossppyy((_S_p_e_c))
Hook in nospy/1. If the hook succeeds nospy/1 takes no
further action. If spy/1 is hooked, it is advised to place a
complementary hook for nospy/1.
nnoossppyyaallll
Hook in nospyall/0. Should remove all spy points. This hook
is called in a failure-driven loop.
ddeebbuuggggiinngg
Hook in debugging/0. It can be used in two ways. It can
report the status of the additional debug points controlled
by the above hooks and fail to let the system report the
others, or it succeeds, overruling the entire behaviour of
debugging/0.
pprroolloogg::hheellpp__hhooookk((_+_A_c_t_i_o_n))
Hook into help/0 and help/1. If the hook succeeds, the built-in
actions are not executed. For example, ?- help(picture). is caught
by the XPCE help hook to give help on the class _p_i_c_t_u_r_e. Defined
actions are:
hheellpp
User entered plain help/0 to give default help. The default
performs help(help/1), giving help on help.
hheellpp((_W_h_a_t))
Hook in help/1 on the topic _W_h_a_t.
aapprrooppooss((_W_h_a_t))
Hook in apropos/1 on the topic _W_h_a_t.
1122..99 HHooookkss ffoorr llooaaddiinngg ffiilleess
All loading of source files is achieved by load_files/2. The hook
prolog_load_file/2 can be used to load Prolog code from non-files or
even load entirely different information, such as foreign files.
pprroolloogg__llooaadd__ffiillee((_+_S_p_e_c_, _+_O_p_t_i_o_n_s))
Load a single object. If this call succeeds, load_files/2 assumes
the action has been taken care of. This hook is only called if
_O_p_t_i_o_n_s does not contain the stream(_I_n_p_u_t) option. The hook must
be defined in the module user.
This can be used to load from unusual places. For example,
library http/http_load loads Prolog directly from an HTTP server.
It can also be used to load source in unusual forms, such as
loading compressed files without decompressing them first. There
is currently no example of that.
pprroolloogg::ccoommmmeenntt__hhooookk((_+_C_o_m_m_e_n_t_s_, _+_P_o_s_, _+_T_e_r_m))
This hook allows for processing comments encountered by the
compiler. If this hook is defined, the compiler calls read_term/2
with the option comments(_C_o_m_m_e_n_t_s). If the list of comments
returned by read_term/2 is not empty it calls this comment hook
with the following arguments.
o _C_o_m_m_e_n_t_s is the non-empty list of comments. Each comment is
a pair _P_o_s_i_t_i_o_n-_S_t_r_i_n_g, where _S_t_r_i_n_g is a string object (see
section 4.24) that contains the comment _i_n_c_l_u_d_i_n_g delimiters.
Consecutive line comments are returned as a single comment.
o _P_o_s is a stream-position term that describes the starting
position of _T_e_r_m
o _T_e_r_m is the term read.
This hook is exploited by the documentation system. See
stream_position_data/3. See also read_term/3.
1122..1100 RReeaaddlliinnee IInntteerraaccttiioonn
The following predicates are available if SWI-Prolog is linked to the
GNU readline library. This is by default the case on non-Windows
installations and indicated by the Prolog flag readline. See also
readline(3).
rrll__rreeaadd__iinniitt__ffiillee((_+_F_i_l_e))
Read a readline initialisation file. Readline by default reads
~/.inputrc. This predicate may be used to read alternative
readline initialisation files.
rrll__aadddd__hhiissttoorryy((_+_L_i_n_e))
Add a line to the Control-P/Control-N history system of the
readline library.
rrll__wwrriittee__hhiissttoorryy((_+_F_i_l_e_N_a_m_e))
Write current history to _F_i_l_e_N_a_m_e. Can be used from at_halt/1 to
save the history.
rrll__rreeaadd__hhiissttoorryy((_+_F_i_l_e_N_a_m_e))
Read history from _F_i_l_e_N_a_m_e, appending to the current history.
CChhaapptteerr 1133.. CCOOMMPPAATTIIBBIILLIITTYY WWIITTHH OOTTHHEERR PPRROOLLOOGG DDIIAALLEECCTTSS
This chapter explains issues for writing portable Prolog programs.
It was started after discussion with Vitor Santos Costa, the leading
developer of YAP Prolog YAP and SWI-Prolog have expressed the
ambition to enhance the portability beyond the trivial Prolog examples,
including complex libraries involving foreign code.
Although it is our aim to enhance compatibility, we are still faced
with many incompatibilities between the dialects. As a first step both
YAP and SWI will provide some instruments that help developing portable
code. A first release of these tools appeared in SWI-Prolog 5.6.43.
Some of the facilities are implemented in the base system, others in
the library dialect.pl.
o The Prolog flag dialect is an unambiguous and fast way to find out
which Prolog dialect executes your program. It has the value swi
for SWI-Prolog and yap on YAP.
o The Prolog flag version_data is bound to a term swi(_M_a_j_o_r_, _M_i_n_o_r_,
_P_a_t_c_h_, _E_x_t_r_a)
o Conditional compilation using :- if(Condition) ...:- endif is
supported. See section 4.3.1.2.
o The predicate expects_dialect/1 allows for specifying for which
Prolog system the code was written.
o The predicates exists_source/1 and source_exports/2 can be used to
query the library content. The require/1 directive can be used to
get access to predicates without knowing their location.
o The module predicates use_module/1, use_module/2have been extended
with a notion for `import-except' and `import-as'. This is
particularly useful together with reexport/1 and reexport/2 to
compose modules from other modules and mapping names.
o Foreign code can expect __SWI_PROLOG__ when compiled for SWI-Prolog
and __YAP_PROLOG__when compiled on YAP.
::-- eexxppeeccttss__ddiiaalleecctt((_+_D_i_a_l_e_c_t))
This directive states that the code following the directive is
written for the given Prolog _D_i_a_l_e_c_t. See also dialect. The
declaration holds until the end of the file in which it appears.
The current dialect is available using prolog_load_context/2.
The exact behaviour of this predicate is still subject to
discussion. Of course, if _D_i_a_l_e_c_t matches the running dialect the
directive has no effect. Otherwise we check for the existence
of library(_d_i_a_l_e_c_t_/_D_i_a_l_e_c_t) and load it if the file is found.
Currently, this file has this functionality:
o Define system predicates of the requested dialect we do not
have.
o Apply goal_expansion/2 rules that map conflicting predicates
to versions emulating the requested dialect. These expansion
rules reside in the dialect compatibility module, but are
applied if prolog_load_context(dialect, Dialect) is active.
o Modify the search path for library directories, putting
libraries compatible with the target dialect before the native
libraries.
o Setup support for the default filename extension of the
dialect.
eexxiissttss__ssoouurrccee((_+_S_p_e_c))
Is true if _S_p_e_c exists as a Prolog source. _S_p_e_c uses the same
conventions as load_files/2. Fails without error if _S_p_e_c cannot be
found.
ssoouurrccee__eexxppoorrttss((_+_S_p_e_c_, _+_E_x_p_o_r_t))
Is true if source _S_p_e_c exports _E_x_p_o_r_t, a predicate indicator.
Fails without error otherwise.
1133..11 SSoommee ccoonnssiiddeerraattiioonnss ffoorr wwrriittiinngg ppoorrttaabbllee ccooddee
The traditional way to write portable code is to define custom
predicates for all potentially non-portable code and define these
separately for all Prolog dialects one wishes to support. Here are
some considerations.
o Probably the best reason for this is that it allows to define
minimal semantics required by the application for the portability
predicates. Such functionality can often be mapped efficiently to
the target dialect. Contrary, if code was written for dialect
X, the defined semantics are those of dialect X. Emulating all
extreme cases and full error handling compatibility may be tedious
and result in a much slower implementation that needed. Take for
example call_cleanup/2. The SICStus definition is fundamentally
different from the SWI definition, but 99% of the applications just
want to make calls like below to guarantee _S_t_r_e_a_m_I_n is closed, even
if process/1 misbehaves.
____________________________________________________________________| |
||________call_cleanup(process(StreamIn),_close(In))________________ ||
o As a drawback, the code becomes full of _m_y___c_a_l_l___c_l_e_a_n_u_p, etc. and
every potential portability conflict needs to be abstracted. It
is hard for people who have to maintain such code later to grasp
the exact semantics of the _m_y___* predicates and applications that
combine multiple libraries using this compatibility approach are
likely to encounter conflicts between the portability layers. A
good start is not to use _m_y___*, but a prefix derived from the
library or application name or names that explain the intended
semantics more precisely.
o Another problem is that most code is initially not written with
portability in mind. Instead, ports are requested by users or
arise from the desire to switch Prolog dialect. Typically, we want
to achieve compatibility with the new Prolog dialect with minimal
changes, often keeping compatibility with the original dialect(s).
This problem is well known from the C/Unix world and we advise
anyone to study the philosophy of GNU autoconf, from which we will
illustrate some highlights below.
The GNU autoconf suite, known to most people as configure, was an
answer to the frustrating life of Unix/C programmers when Unix dialects
were about as abundant and poorly standardised as Prolog dialects
today. Writing a portable C program can only be achieved using cpp,
the C preprocessor. The C preprocessor performs two tasks: macro
expansion and conditional compilation. Prolog realises macro expansion
through term_expansion/2 and goal_expansion/2. Conditional compilation
is achieved using :- if(Condition) as explained in section 4.3.1.2.
The situation appears similar.
The important lesson learned from GNU autoconf is that the _l_a_s_t resort
for conditional compilation to achieve portability is to switch on the
platform or dialect. Instead, GNU autoconf allows you to write tests
for specific properties of the platform. Most of these are whether
or not some function or file is available. Then there are some
standard tests for difficult-to-write-portable situations and finally
there is a framework that allows you to write arbitrary C programs
and check whether they can be compiled and/or whether they show the
intended behaviour. Using a separate configure program is needed in
C, as you cannot perform C compilation step or run C programs from
the C preprocessor. In most Prolog environments we do not need this
distinction as the compiler is integrated into the runtime environment
and Prolog has excellent reflexion capabilities.
We must learn from the distinction to test for features instead of
platform (dialect), as this makes the platform-specific code robust for
future changes of the dialect. Suppose we need compare/3 as defined in
this manual. The compare/3 predicate is not part of the ISO standard,
but many systems support it and it is not unlikely it will become
ISO standard or the intended dialect will start supporting it. GNU
autoconf strongly advises to test for the availability:
________________________________________________________________________| |
|:- if(\+current_predicate(_, compare(_,_,_))). |
|compare(<, Term1, Term2) :- |
| Term1 @< Term2, !. |
|compare(>, Term1, Term2) :- |
| Term1 @> Term2, !. |
|compare(=, Term1, Term2) :- |
| Term1 == Term2. |
|:-|endif.______________________________________________________________ | |
This code is mmuucchh more robust against changes to the intended dialect
and, possibly at least as important, will provide compatibility with
dialects you didn't even consider porting to right now.
In a more challenging case, the target Prolog has compare/3, but the
semantics are different. What to do? One option is to write a
my_compare/3 and change all occurrences in the code. Alternatively you
can rename calls using goal_expansion/2 like below. This construct
will not only deal with Prolog dialects lacking compare/3 as well as
those that only implement it for numeric comparison or have changed
the argument order. Of course, writing rock-solid code would require
a complete test-suite, but this example will probably cover all
Prolog dialects that allow for conditional compilation, have core ISO
facilities and provide goal_expansion/2, the things we claim a Prolog
dialect should have to start writing portable code for it.
________________________________________________________________________| |
|:- if(\+catch(compare(<,a,b), _, fail)). |
|compare_standard_order(<, Term1, Term2) :- |
| Term1 @< Term2, !. |
|compare_standard_order(>, Term1, Term2) :- |
| Term1 @> Term2, !. |
|compare_standard_order(=, Term1, Term2) :- |
| Term1 == Term2. |
| |
|goal_expansion(compare(Order, Term1, Term2), |
| compare_standard_order(Order, Term1, Term2)). |
|:-|endif.______________________________________________________________ | |
CChhaapptteerr 1144.. GGLLOOSSSSAARRYY OOFF TTEERRMMSS
aannoonnyymmoouuss [[vvaarriiaabbllee]]
The variable _ is called the _a_n_o_n_y_m_o_u_s variable. Multiple
occurrences of _ in a single _t_e_r_m are not _s_h_a_r_e_d.
aarrgguummeennttss
Arguments are _t_e_r_m_s that appear in a _c_o_m_p_o_u_n_d _t_e_r_m. _A_1 and _a_2 are
the first and second argument of the term myterm(_A_1_, _a_2).
aarriittyy
Argument count (= number of arguments) of a _c_o_m_p_o_u_n_d _t_e_r_m.
aasssseerrtt
Add a _c_l_a_u_s_e to a _p_r_e_d_i_c_a_t_e. Clauses can be added at either end of
the clause-list of a _p_r_e_d_i_c_a_t_e. See asserta/1 and assertz/1.
aattoomm
Textual constant. Used as name for _c_o_m_p_o_u_n_d terms, to represent
constants or text.
bbaacckkttrraacckkiinngg
Search process used by Prolog. If a predicate offers multiple
_c_l_a_u_s_e_s to solve a _g_o_a_l, they are tried one-by-one until one
_s_u_c_c_e_e_d_s. If a subsequent part of the proof is not satisfied
with the resulting _v_a_r_i_a_b_l_e _b_i_n_d_i_n_g, it may ask for an alternative
_s_o_l_u_t_i_o_n (= _b_i_n_d_i_n_g of the _v_a_r_i_a_b_l_e_s), causing Prolog to reject the
previously chosen _c_l_a_u_s_e and try the next one.
bbiinnddiinngg [[ooff aa vvaarriiaabbllee]]
Current value of the _v_a_r_i_a_b_l_e. See also _b_a_c_k_t_r_a_c_k_i_n_g and _q_u_e_r_y.
bbuuiilltt--iinn [[pprreeddiiccaattee]]
Predicate that is part of the Prolog system. Built-in predicates
cannot be redefined by the user, unless this is overruled using
redefine_system_predicate/1.
bbooddyy
Part of a _c_l_a_u_s_e behind the _n_e_c_k operator (:-).
ccllaauussee
`Sentence' of a Prolog program. A _c_l_a_u_s_e consists of a _h_e_a_d and
_b_o_d_y separated by the _n_e_c_k operator (:-) or it is a _f_a_c_t. For
example:
____________________________________________________________________| |
| parent(X) :- |
||________father(X,__)._____________________________________________ ||
Expressed as ``X is a parent if X is a father of someone''. See
also _v_a_r_i_a_b_l_e and _p_r_e_d_i_c_a_t_e.
ccoommppiillee
Process where a Prolog _p_r_o_g_r_a_m is translated to a sequence of
instructions. See also _i_n_t_e_r_p_r_e_t_e_d. SWI-Prolog always compiles
your program before executing it.
ccoommppoouunndd [[tteerrmm]]
Also called _s_t_r_u_c_t_u_r_e. It consists of a name followed by _N
_a_r_g_u_m_e_n_t_s, each of which are _t_e_r_m_s. _N is called the _a_r_i_t_y of the
term.
ccoonntteexxtt mmoodduullee
If a _t_e_r_m is referring to a _p_r_e_d_i_c_a_t_e in a _m_o_d_u_l_e, the _c_o_n_t_e_x_t
_m_o_d_u_l_e is used to find the target module. The context module of a
_g_o_a_l is the module in which the _p_r_e_d_i_c_a_t_e is defined, unless this
_p_r_e_d_i_c_a_t_e is _m_o_d_u_l_e _t_r_a_n_s_p_a_r_e_n_t, in which case the _c_o_n_t_e_x_t _m_o_d_u_l_e
is inherited from the parent _g_o_a_l. See also module_transparent/1
and _m_e_t_a_-_p_r_e_d_i_c_a_t_e.
ddyynnaammiicc [[pprreeddiiccaattee]]
A _d_y_n_a_m_i_c predicate is a predicate to which _c_l_a_u_s_e_s may be _a_s_s_e_r_ted
and from which _c_l_a_u_s_e_s may be _r_e_t_r_a_c_ted while the program is
running. See also _u_p_d_a_t_e _v_i_e_w.
eexxppoorrtteedd [[pprreeddiiccaattee]]
A _p_r_e_d_i_c_a_t_e is said to be _e_x_p_o_r_t_e_d from a _m_o_d_u_l_e if it appears
in the _p_u_b_l_i_c _l_i_s_t. This implies that the predicate can be
_i_m_p_o_r_t_e_d into another module to make it visible there. See also
use_module/[1,2].
ffaacctt
_C_l_a_u_s_e without a _b_o_d_y. This is called a fact because, interpreted
as logic, there is no condition to be satisfied. The example below
states john is a person.
____________________________________________________________________| |
||person(john)._____________________________________________________ ||
ffaaiill
A _g_o_a_l is said to haved failed if it could not be _p_r_o_v_e_n.
ffllooaatt
Computer's crippled representation of a real number. Represented
as `IEEE double'.
ffoorreeiiggnn
Computer code expressed in languages other than Prolog. SWI-Prolog
can only cooperate directly with the C and C++ computer languages.
ffuunnccttoorr
Combination of name and _a_r_i_t_y of a _c_o_m_p_o_u_n_d term. The term foo(_a_,
_b_, _c) is said to be a term belonging to the functor foo/3. foo/0
is used to refer to the _a_t_o_m foo.
ggooaall
Question stated to the Prolog engine. A _g_o_a_l is either an _a_t_o_m
or a _c_o_m_p_o_u_n_d term. A _g_o_a_l either succeeds, in which case the
_v_a_r_i_a_b_l_e_s in the _c_o_m_p_o_u_n_d terms have a _b_i_n_d_i_n_g, or it _f_a_i_l_s if
Prolog fails to prove it.
hhaasshhiinngg
_I_n_d_e_x_i_n_g technique used for quick lookup.
hheeaadd
Part of a _c_l_a_u_s_e before the _n_e_c_k operator (:-). This is an _a_t_o_m or
_c_o_m_p_o_u_n_d term.
iimmppoorrtteedd [[pprreeddiiccaattee]]
A _p_r_e_d_i_c_a_t_e is said to be _i_m_p_o_r_t_e_d into a _m_o_d_u_l_e if it is defined
in another _m_o_d_u_l_e and made available in this _m_o_d_u_l_e. See also
chapter 5.
iinnddeexxiinngg
Indexing is a technique used to quickly select candidate _c_l_a_u_s_e_s of
a _p_r_e_d_i_c_a_t_e for a specific _g_o_a_l. In most Prolog systems, indexing
is done (only) on the first _a_r_g_u_m_e_n_t of the _h_e_a_d. If this argument
is instantiated to an _a_t_o_m, _i_n_t_e_g_e_r, _f_l_o_a_t or _c_o_m_p_o_u_n_d term with
_f_u_n_c_t_o_r, _h_a_s_h_i_n_g is used to quickly select all _c_l_a_u_s_e_s where the
first argument may _u_n_i_f_y with the first argument of the _g_o_a_l.
SWI-Prolog supports just-in-time and multi-argument indexing. See
section 2.17.
iinntteeggeerr
Whole number. On all implementations of SWI-Prolog integers are at
least 64-bit signed values. When linked to the GNU GMP library,
integer arithmetic is unbounded. See also current_prolog_flag/2,
flags bounded, max_integer and min_integer.
iinntteerrpprreetteedd
As opposed to _c_o_m_p_i_l_e_d, interpreted means the Prolog system
attempts to prove a _g_o_a_l by directly reading the _c_l_a_u_s_e_s rather
than executing instructions from an (abstract) instruction set that
is not or only indirectly related to Prolog.
mmeettaa--pprreeddiiccaattee
A _p_r_e_d_i_c_a_t_e that reasons about other _p_r_e_d_i_c_a_t_e_s, either by calling
them, (re)defining them or querying _p_r_o_p_e_r_t_i_e_s.
mmoodduullee
Collection of predicates. Each module defines a name-space for
predicates. _b_u_i_l_t_-_i_n predicates are accessible from all modules.
Predicates can be published (_e_x_p_o_r_t_e_d) and _i_m_p_o_r_t_e_d to make their
definition available to other modules.
mmoodduullee ttrraannssppaarreenntt [[pprreeddiiccaattee]]
A _p_r_e_d_i_c_a_t_e that does not change the _c_o_n_t_e_x_t _m_o_d_u_l_e. Sometimes
also called a _m_e_t_a_-_p_r_e_d_i_c_a_t_e.
mmuullttiiffiillee [[pprreeddiiccaattee]]
Predicate for which the definition is distributed over multiple
source files. See multifile/1.
nneecckk
Operator (:-) separating _h_e_a_d from _b_o_d_y in a _c_l_a_u_s_e.
ooppeerraattoorr
Symbol (_a_t_o_m) that may be placed before its _o_p_e_r_a_n_d (prefix), after
its _o_p_e_r_a_n_d (postfix) or between its two _o_p_e_r_a_n_d_s (infix).
In Prolog, the expression a+b is exactly the same as the canonical
term +(a,b).
ooppeerraanndd
_A_r_g_u_m_e_n_t of an _o_p_e_r_a_t_o_r.
pprreecceeddeennccee
The _p_r_i_o_r_i_t_y of an _o_p_e_r_a_t_o_r. Operator precedence is used to
interpret a+b*c as +(a, *(b,c)).
pprreeddiiccaattee
Collection of _c_l_a_u_s_e_s with the same _f_u_n_c_t_o_r (name/_a_r_i_t_y). If a
_g_o_a_l is proved, the system looks for a _p_r_e_d_i_c_a_t_e with the same
functor, then uses _i_n_d_e_x_i_n_g to select candidate _c_l_a_u_s_e_s and then
tries these _c_l_a_u_s_e_s one-by-one. See also _b_a_c_k_t_r_a_c_k_i_n_g.
pprreeddiiccaattee iinnddiiccaattoorr
Term of the form Name/Arity (traditional) or Name//Arity (ISO DCG
proposal), where Name is an atom and Arity a non-negative integer.
It acts as an _i_n_d_i_c_a_t_o_r (or reference) to a predicate or _D_C_G rule.
pprriioorriittyy
In the context of _o_p_e_r_a_t_o_r_s a synonym for _p_r_e_c_e_d_e_n_c_e.
pprrooggrraamm
Collection of _p_r_e_d_i_c_a_t_e_s.
pprrooppeerrttyy
Attribute of an object. SWI-Prolog defines various _*___p_r_o_p_e_r_t_y
predicates to query the status of predicates, clauses. etc.
pprroovvee
Process where Prolog attempts to prove a _q_u_e_r_y using the available
_p_r_e_d_i_c_a_t_e_s.
ppuubblliicc lliisstt
List of _p_r_e_d_i_c_a_t_e_s exported from a _m_o_d_u_l_e.
qquueerryy
See _g_o_a_l.
rreettrraacctt
Remove a _c_l_a_u_s_e from a _p_r_e_d_i_c_a_t_e. See also _d_y_n_a_m_i_c, _u_p_d_a_t_e _v_i_e_w
and _a_s_s_e_r_t.
sshhaarreedd
Two _v_a_r_i_a_b_l_e_s are called _s_h_a_r_e_d after they are _u_n_i_f_i_e_d. This
implies if either of them is _b_o_u_n_d, the other is bound to the same
value:
____________________________________________________________________| |
| ?- A = B, A = a. |
||A_=_B,_B_=_a._____________________________________________________ ||
ssiinngglleettoonn [[vvaarriiaabbllee]]
_V_a_r_i_a_b_l_e appearing only one time in a _c_l_a_u_s_e. SWI-Prolog normally
warns for this to avoid you making spelling mistakes. If a
variable appears on purpose only once in a clause, write it as
_ (see _a_n_o_n_y_m_o_u_s). Rules for naming a variable and avoiding a
warning are given in section 2.15.1.6.
ssoolluuttiioonn
_B_i_n_d_i_n_g_s resulting from a successfully _p_r_o_v_en _g_o_a_l.
ssttrruuccttuurree
Synonym for _c_o_m_p_o_u_n_d term.
ssttrriinngg
Used for the following representations of text: a packed array
(see section 4.24, SWI-Prolog specific), a list of character codes
or a list of one-character _a_t_o_m_s.
ssuucccceeeedd
A _g_o_a_l is said to have _s_u_c_c_e_e_d_e_d if it has been _p_r_o_v_e_n.
tteerrmm
Value in Prolog. A _t_e_r_m is either a _v_a_r_i_a_b_l_e, _a_t_o_m, _i_n_t_e_g_e_r, _f_l_o_a_t
or _c_o_m_p_o_u_n_d term. In addition, SWI-Prolog also defines the type
_s_t_r_i_n_g.
ttrraannssppaarreenntt
See _m_o_d_u_l_e _t_r_a_n_s_p_a_r_e_n_t.
uunniiffyy
Prolog process to make two terms equal by assigning variables in
one term to values at the corresponding location of the other term.
For example:
____________________________________________________________________| |
| ?- foo(a, B) = foo(A, b). |
| A = a, |
||B_=_b.____________________________________________________________ ||
Unlike assignment (which does not exist in Prolog), unification is
not directed.
uuppddaattee vviieeww
How Prolog behaves when a _d_y_n_a_m_i_c _p_r_e_d_i_c_a_t_e is changed while it is
running. There are two models. In most older Prolog systems the
change becomes immediately visible to the _g_o_a_l, in modern systems
including SWI-Prolog, the running _g_o_a_l is not affected. Only new
_g_o_a_l_s `see' the new definition.
vvaarriiaabbllee
A Prolog variable is a value that `is not yet bound'. After
_b_i_n_d_i_n_g a variable, it cannot be modified. _B_a_c_k_t_r_a_c_k_i_n_g to a point
in the execution before the variable was bound will turn it back
into a variable:
____________________________________________________________________| |
| ?- A = b, A = c. |
| false. |
| |
| ?- (A = b; true; A = c). |
| A = b ; |
| true ; |
||A_=_c_.___________________________________________________________ ||
See also _u_n_i_f_y.
CChhaapptteerr 1155.. SSWWII--PPRROOLLOOGG LLIICCEENNSSEE CCOONNDDIITTIIOONNSS AANNDD TTOOOOLLSS
SWI-Prolog licensing aims at a large audience, combining ideas from the
Free Software Foundation and the less principal Open Source Initiative.
The license aims at the following:
o Make SWI-Prolog and its libraries `as free as possible'.
o Allow for easy integration of contributions. See section 15.2.
o Free software can build on SWI-Prolog without limitations.
o Non-free (open or proprietary) software can be produced using
SWI-Prolog, although contributed pure GPL-ed components cannot be
used.
To achieve this, different parts of the system have different licenses.
SWI-Prolog programs consist of a mixture of `native' code (source
compiled to machine instructions) and `virtual machine' code (Prolog
source compiled to SWI-Prolog virtual machine instructions, covering
both compiled SWI-Prolog libraries and your compiled application).
For maximal coherence between free licenses, we start with the two
prime licenses from the Free Software Foundation, the GNU General
Public License (GPL) and the Lesser GNU General Public License (LGPL),
after which we add a proven (used by the GNU C compiler runtime library
as well as the GNU _C_l_a_s_s_P_a_t_h project) exception to deal with the
specific nature of compiled virtual machine code in a saved state.
1155..11 TThhee SSWWII--PPrroolloogg kkeerrnneell aanndd ffoorreeiiggnn lliibbrraarriieess
The SWI-Prolog kernel and our foreign libraries are distributed under
the LLGGPPLL. A Prolog executable consists of the combination of these
`native' code components and Prolog virtual machine code. The
SWI-Prolog swipl-rc utility allows for disassembling and re-assembling
these parts, a process satisfying article 66bb of the LGPL.
Under the LGPL, SWI-Prolog can be linked to code distributed under
arbitrary licenses, provided a number of requirements are fulfilled.
The most important requirement is that if an application relies on
a _m_o_d_i_f_i_e_d version of SWI-Prolog, the modified sources must be made
available.
1155..11..11 TThhee SSWWII--PPrroolloogg PPrroolloogg lliibbrraarriieess
Lacking a satisfactory technical solution to handle article 66 of the
LGPL, this license cannot be used for the Prolog source code that is
part of the SWI-Prolog system (both libraries and kernel code). This
situation is comparable to libgcc, the runtime library used with the
GNU C compiler. Therefore, we use the same proven license terms as
this library. The libgcc license is the with a special exception.
Below we rephrase this exception adjusted to our needs:
_A_s _a _s_p_e_c_i_a_l _e_x_c_e_p_t_i_o_n_, _i_f _y_o_u _l_i_n_k _t_h_i_s _l_i_b_r_a_r_y _w_i_t_h _o_t_h_e_r
_f_i_l_e_s_, _c_o_m_p_i_l_e_d _w_i_t_h _a _F_r_e_e _S_o_f_t_w_a_r_e _c_o_m_p_i_l_e_r_, _t_o _p_r_o_d_u_c_e
_a_n _e_x_e_c_u_t_a_b_l_e_, _t_h_i_s _l_i_b_r_a_r_y _d_o_e_s _n_o_t _b_y _i_t_s_e_l_f _c_a_u_s_e _t_h_e
_r_e_s_u_l_t_i_n_g _e_x_e_c_u_t_a_b_l_e _t_o _b_e _c_o_v_e_r_e_d _b_y _t_h_e _G_N_U _G_e_n_e_r_a_l _P_u_b_l_i_c
_L_i_c_e_n_s_e_. _T_h_i_s _e_x_c_e_p_t_i_o_n _d_o_e_s _n_o_t_, _h_o_w_e_v_e_r_, _i_n_v_a_l_i_d_a_t_e _a_n_y
_o_t_h_e_r _r_e_a_s_o_n_s _w_h_y _t_h_e _e_x_e_c_u_t_a_b_l_e _f_i_l_e _m_i_g_h_t _b_e _c_o_v_e_r_e_d _b_y _t_h_e
_G_N_U _G_e_n_e_r_a_l _P_u_b_l_i_c _L_i_c_e_n_s_e_.
1155..22 CCoonnttrriibbuuttiinngg ttoo tthhee SSWWII--PPrroolloogg pprroojjeecctt
To achieve maximal coherence using SWI-Prolog for Free and Non-Free
software we advise using LGPL for contributed foreign code and using
GPL with the SWI-Prolog exception for Prolog code for contributed
modules.
As a rule of thumb it is advised to use the above licenses whenever
possible, and use a strict GPL compliant license only if the module
contains other code under strict GPL compliant licenses.
1155..33 SSooffttwwaarree ssuuppppoorrtt ttoo kkeeeepp ttrraacckk ooff lliicceennssee ccoonnddiittiioonnss
Given the above, it is possible that SWI-Prolog packages and extensions
will rely on the GPL. The predicates below allow for registering
license requirements for Prolog files and foreign modules. The
predicate eval_license/0 reports which components from the currently
configured system are distributed under copy-left and open source
enforcing licenses (the GPL) and therefore must be replaced before
distributing linked applications under non-free license conditions.
eevvaall__lliicceennssee
Evaluate the license conditions of all loaded components. If the
system contains one or more components that are licenced under
GPL-like restrictions the system indicates this program may only
be distributed under the GPL license as well as which components
prohibit the use of other license conditions.
lliicceennssee((_+_L_i_c_e_n_s_e_I_d_, _+_C_o_m_p_o_n_e_n_t))
Register the fact that _C_o_m_p_o_n_e_n_t is distributed under a license
identified by _L_i_c_e_n_s_e_I_d. The most important _L_i_c_e_n_s_e_I_d's are:
sswwiippll
Indicates this module is distributed under the GNU General
Public License (GPL) with the SWI-Prolog exception:
_A_s _a _s_p_e_c_i_a_l _e_x_c_e_p_t_i_o_n_, _i_f _y_o_u _l_i_n_k _t_h_i_s _l_i_b_r_a_r_y _w_i_t_h
_o_t_h_e_r _f_i_l_e_s_, _c_o_m_p_i_l_e_d _w_i_t_h _S_W_I_-_P_r_o_l_o_g_, _t_o _p_r_o_d_u_c_e _a_n
_e_x_e_c_u_t_a_b_l_e_, _t_h_i_s _l_i_b_r_a_r_y _d_o_e_s _n_o_t _b_y _i_t_s_e_l_f _c_a_u_s_e _t_h_e
_r_e_s_u_l_t_i_n_g _e_x_e_c_u_t_a_b_l_e _t_o _b_e _c_o_v_e_r_e_d _b_y _t_h_e _G_N_U _G_e_n_e_r_a_l
_P_u_b_l_i_c _L_i_c_e_n_s_e_. _T_h_i_s _e_x_c_e_p_t_i_o_n _d_o_e_s _n_o_t_, _h_o_w_e_v_e_r_,
_i_n_v_a_l_i_d_a_t_e _a_n_y _o_t_h_e_r _r_e_a_s_o_n_s _w_h_y _t_h_e _e_x_e_c_u_t_a_b_l_e _f_i_l_e
_m_i_g_h_t _b_e _c_o_v_e_r_e_d _b_y _t_h_e _G_N_U _G_e_n_e_r_a_l _P_u_b_l_i_c _L_i_c_e_n_s_e_.
This should be the default for software contributed to the
SWI-Prolog project as it allows the community to prosper
both in the free and non-free world. Still, people using
SWI-Prolog to create non-free applications must contribute
sources to improvements they make to the community.
llggppll
This is the default license for foreign libraries linked with
SWI-Prolog. Use PL_license() to register the condition from
foreign code.
ggppll
Indicates this module is strictly Free Software, which implies
it cannot be used together with any module that is
incompatible with the GPL. Please only use these conditions
when forced by other code used in the component.
Other licenses known to the system are guile, gnu_ada, x11,
expat, sml, public_domain, cryptix, bsd, zlib, lgpl_compatible and
gpl_compatible. New licenses can be defined by adding clauses for
the multifile predicate license:license/3. Below is an example.
The second argument is either gpl or lgpl to indicate compatibility
with these licenses. Other values cause the license to be
interpreted as _p_r_o_p_r_i_e_t_a_r_y. Proprietary licenses are reported by
eval_license/0. See the file boot/license.pl for details.
____________________________________________________________________| |
| :- multifile license:license/3. |
| |
| license:license(mylicense, lgpl, |
| [ comment('My personal license'), |
| url('http://www.mine.org/license.html') |
| ]). |
| |
||:-_license(mylicense).____________________________________________ ||
lliicceennssee((_+_L_i_c_e_n_s_e_I_d))
Intended as a directive in Prolog source files. It takes the
current filename and calls license/2.
void PPLL__lliicceennssee(_c_o_n_s_t _c_h_a_r _*_L_i_c_e_n_s_e_I_d_, _c_o_n_s_t _c_h_a_r _*_C_o_m_p_o_n_e_n_t)
Intended for the install() procedure of foreign libraries. This
call can be made _b_e_f_o_r_e PL_initialise().
1155..44 LLiicceennssee ccoonnddiittiioonnss iinnhheerriitteedd ffrroomm uusseedd ccooddee
1155..44..11 CCrryyppttooggrraapphhiicc rroouuttiinneess
Cryptographic routines are used in variant_sha1/2 and crypt. These
routines are provided under the following conditions:
Copyright (c) 2002, Dr Brian Gladman, Worcester, UK. All rights reserved.
LICENSE TERMS
The free distribution and use of this software in both source and binary
form is allowed (with or without changes) provided that:
1. distributions of this source code include the above copyright
notice, this list of conditions and the following disclaimer;
2. distributions in binary form include the above copyright
notice, this list of conditions and the following disclaimer
in the documentation and/or other associated materials;
3. the copyright holder's name is not used to endorse products
built using this software without specific written permission.
ALTERNATIVELY, provided that this notice is retained in full, this product
may be distributed under the terms of the GNU General Public License (GPL),
in which case the provisions of the GPL apply INSTEAD OF those given above.
DISCLAIMER
This software is provided 'as is' with no explicit or implied warranties
in respect of its properties, including, but not limited to, correctness
and/or fitness for purpose.
CChhaapptteerr 1166.. SSUUMMMMAARRYY
1166..11 PPrreeddiiccaatteess
The predicate summary is used by the Prolog predicate apropos/1 to
suggest predicates from a keyword.
@/2 Call using calling context
!/0 Cut (discard choicepoints)
,/2 Conjunction of goals
->/2 If-then-else
*->/2 Soft-cut
./2 Consult. Also list constructor
;/2 Disjunction of goals. Same as |/2
</2 Arithmetic smaller
=/2 Unification
=../2 ``Univ.'' Term to list conversion
=:=/2 Arithmetic equal
=</2 Arithmetic smaller or equal
==/2 Identical
=@=/2 Structural identical
=\=/2 Arithmetic not equal
>/2 Arithmetic larger
>=/2 Arithmetic larger or equal
?=/2 Test of terms can be compared now
@</2 Standard order smaller
@=</2 Standard order smaller or equal
@>/2 Standard order larger
@>=/2 Standard order larger or equal
\+/1 Negation by failure. Same as not/1
\=/2 Not unifiable
\==/2 Not identical
\=@=/2 Not structural identical
^/2 Existential quantification (bagof/3, setof/3)
|/2 Disjunction of goals. Same as ;/2
{}/1 DCG escape; constraints
abolish/1 Remove predicate definition from the database
abolish/2 Remove predicate definition from the database
abort/0 Abort execution, return to top level
absolute_file_name/2 Get absolute path name
absolute_file_name/3 Get absolute path name with options
access_file/2 Check access permissions of a file
acyclic_term/1 Test term for cycles
add_import_module/3 Add module to the auto-import list
add_nb_set/2 Add term to a non-backtrackable set
add_nb_set/3 Add term to a non-backtrackable set
append/1 Append to a file
apply/2 Call goal with additional arguments
apropos/1 online_help Search manual
arg/3 Access argument of a term
assoc_to_list/2 Convert association tree to list
assert/1 Add a clause to the database
assert/2 Add a clause to the database, give reference
asserta/1 Add a clause to the database (first)
asserta/2 Add a clause to the database (first)
assertion/1 Make assertions about your program
assertz/1 Add a clause to the database (last)
assertz/2 Add a clause to the database (last)
attach_console/0 Attach I/O console to thread
attribute_goals/3 Project attributes to goals
attr_unify_hook/2 Attributed variable unification hook
attr_portray_hook/2 Attributed variable print hook
attvar/1 Type test for attributed variable
at_end_of_stream/0 Test for end of file on input
at_end_of_stream/1 Test for end of file on stream
at_halt/1 Register goal to run at halt/1
atom/1 Type check for an atom
atom_chars/2 Convert between atom and list of characters
atom_codes/2 Convert between atom and list of characters codes
atom_concat/3 Append two atoms
atom_length/2 Determine length of an atom
atom_number/2 Convert between atom and number
atom_prefix/2 Test for start of atom
atom_string/2 Conversion between atom and string
atom_to_term/3 Convert between atom and term
atomic/1 Type check for primitive
atomic_concat/3 Concatenate two atomic values to an atom
atomic_list_concat/2 Append a list of atoms
atomic_list_concat/3 Append a list of atoms with separator
autoload/0 Autoload all predicates now
autoload_path/1 Add directories for autoloading
b_getval/2 Fetch backtrackable global variable
b_setval/2 Assign backtrackable global variable
bagof/3 Find all solutions to a goal
between/3 Integer range checking/generating
blob/2 Type check for a blob
break/0 Start interactive top level
byte_count/2 Byte-position in a stream
call/1 Call a goal
call/[2..] Call with additional arguments
call_cleanup/3 Guard a goal with a cleaup-handler
call_cleanup/2 Guard a goal with a cleaup-handler
call_residue_vars/2 Find residual attributed variables
call_shared_object_function/2 UNIX: Call C-function in shared (.so) file
call_with_depth_limit/3 Prove goal with bounded depth
callable/1 Test for atom or compound term
cancel_halt/1 Cancel halt/0 from an at_halt/1hook
catch/3 Call goal, watching for exceptions
char_code/2 Convert between character and character code
char_conversion/2 Provide mapping of input characters
char_type/2 Classify characters
character_count/2 Get character index on a stream
chdir/1 Compatibility: change working directory
chr_constraint/1 CHR Constraint declaration
chr_show_store/1 List suspended CHR constraints
chr_trace/0 Start CHR tracer
chr_type/1 CHR Type declaration
chr_notrace/0 Stop CHR tracer
chr_leash/1 Define CHR leashed ports
chr_option/2 Specify CHR compilation options
clause/2 Get clauses of a predicate
clause/3 Get clauses of a predicate
clause_property/2 Get properties of a clause
close/1 Close stream
close/2 Close stream (forced)
close_dde_conversation/1 Win32: Close DDE channel
close_shared_object/1 UNIX: Close shared library (.so file)
collation_key/2 Sort key for locale dependent ordering
comment_hook/3 (hook) handle comments in sources
compare/3 Compare, using a predicate to determine the order
compile_aux_clauses/1 Compile predicates for goal_expansion/2
compile_predicates/1 Compile dynamic code to static
compiling/0 Is this a compilation run?
compound/1 Test for compound term
code_type/2 Classify a character-code
consult/1 Read (compile) a Prolog source file
context_module/1 Get context module of current goal
convert_time/8 Break time stamp into fields
convert_time/2 Convert time stamp to string
copy_stream_data/2 Copy all data from stream to stream
copy_stream_data/3 Copy n bytes from stream to stream
copy_predicate_clauses/2 Copy clauses between predicates
copy_term/2 Make a copy of a term
copy_term/3 Copy a term and obtain attribute-goals
copy_term_nat/2 Make a copy of a term without attributes
create_prolog_flag/3 Create a new Prolog flag
current_arithmetic_function/1 Examine evaluable functions
current_atom/1 Examine existing atoms
current_blob/2 Examine typed blobs
current_char_conversion/2 Query input character mapping
current_flag/1 Examine existing flags
current_foreign_library/2 shlib Examine loaded shared libraries (.so files)
current_format_predicate/2 Enumerate user-defined format codes
current_functor/2 Examine existing name/arity pairs
current_input/1 Get current input stream
current_key/1 Examine existing database keys
current_locale/1 Get the current locale
current_module/1 Examine existing modules
current_op/3 Examine current operator declarations
current_output/1 Get the current output stream
current_predicate/1 Examine existing predicates (ISO)
current_predicate/2 Examine existing predicates
current_signal/3 Current software signal mapping
current_stream/3 Examine open streams
cyclic_term/1 Test term for cycles
day_of_the_week/2 Determine ordinal-day from date
date_time_stamp/2 Convert sate structure to time-stamp
date_time_value/3 Extract info from a date structure
dcg_translate_rule/2 Source translation of DCG rules
dcg_translate_rule/4 Source translation of DCG rules
dde_current_connection/2 Win32: Examine open DDE connections
dde_current_service/2 Win32: Examine DDE services provided
dde_execute/2 Win32: Execute command on DDE server
dde_register_service/2 Win32: Become a DDE server
dde_request/3 Win32: Make a DDE request
dde_poke/3 Win32: POKE operation on DDE server
dde_unregister_service/1 Win32: Terminate a DDE service
debug/0 Test for debugging mode
debug/1 Select topic for debugging
debug/3 Print debugging message on topic
debug_control_hook/1 (hook) Extend spy/1, etc.
debugging/0 Show debugger status
debugging/1 Test where we are debugging topic
default_module/2 Query module inheritance
del_attr/2 Delete attribute from variable
del_attrs/1 Delete all attributes from variable
delete_directory/1 Remove a folder from the file system
delete_file/1 Remove a file from the file system
delete_import_module/2 Remove module from import list
deterministic/1 Test deterministicy of current clause
dif/2 Constrain two terms to be different
directory_files/2 Get entries of a directory/folder
discontiguous/1 Indicate distributed definition of a predicate
downcase_atom/2 Convert atom to lower-case
duplicate_term/2 Create a copy of a term
dwim_match/2 Atoms match in ``Do What I Mean'' sense
dwim_match/3 Atoms match in ``Do What I Mean'' sense
dwim_predicate/2 Find predicate in ``Do What I Mean'' sense
dynamic/1 Indicate predicate definition may change
edit/0 Edit current script- or associated file
edit/1 Edit a file, predicate, module (extensible)
elif/1 Part of conditional compilation (directive)
else/0 Part of conditional compilation (directive)
empty_assoc/1 Create/test empty association tree
empty_nb_set/1 Test/create an empty non-backtrackable set
encoding/1 Define encoding inside a source file
endif/0 End of conditional compilation (directive)
ensure_loaded/1 Consult a file if that has not yet been done
erase/1 Erase a database record or clause
eval_license/0 Evaluate licenses of loaded modules
exception/3 (hook) Handle runtime exceptions
exists_directory/1 Check existence of directory
exists_file/1 Check existence of file
exists_source/1 Check existence of a Prolog source
expand_answer/2 Expand answer of query
expand_file_name/2 Wildcard expansion of file names
expand_file_search_path/2 Wildcard expansion of file paths
expand_goal/2 Compiler: expand goal in clause-body
expand_goal/4 Compiler: expand goal in clause-body
expand_query/4 Expanded entered query
expand_term/2 Compiler: expand read term into clause(s)
expand_term/4 Compiler: expand read term into clause(s)
expects_dialect/1 For which Prolog dialect is this code written?
explain/1 explain Explain argument
explain/2 explain 2nd argument is explanation of first
export/1 Export a predicate from a module
fail/0 Always false
false/0 Always false
current_prolog_flag/2 Get system configuration parameters
file_base_name/2 Get file part of path
file_directory_name/2 Get directory part of path
file_name_extension/3 Add, remove or test file extensions
file_search_path/2 Define path-aliases for locating files
find_chr_constraint/1 Returns a constraint from the store
findall/3 Find all solutions to a goal
findall/4 Difference list version of findall/3
flag/3 Simple global variable system
float/1 Type check for a floating point number
flush_output/0 Output pending characters on current stream
flush_output/1 Output pending characters on specified stream
forall/2 Prove goal for all solutions of another goal
format/1 Formatted output
format/2 Formatted output with arguments
format/3 Formatted output on a stream
format_time/3 C strftime() like date/time formatter
format_time/4 date/time formatter with explicit locale
format_predicate/2 Program format/[1,2]
term_attvars/2 Find attributed variables in a term
term_variables/2 Find unbound variables in a term
term_variables/3 Find unbound variables in a term
freeze/2 Delay execution until variable is bound
frozen/2 Query delayed goals on var
functor/3 Get name and arity of a term or construct a term
garbage_collect/0 Invoke the garbage collector
garbage_collect_atoms/0 Invoke the atom garbage collector
garbage_collect_clauses/0 Invoke clause garbage collector
gen_assoc/3 Enumerate members of association tree
gen_nb_set/2 Generate members of non-backtrackable set
gensym/2 Generate unique atoms from a base
get/1 Read first non-blank character
get/2 Read first non-blank character from a stream
get_assoc/3 Fetch key from association tree
get_assoc/5 Fetch key from association tree
get0/1 Read next character
get0/2 Read next character from a stream
get_attr/3 Fetch named attribute from a variable
get_attrs/2 Fetch all attributes of a variable
get_byte/1 Read next byte (ISO)
get_byte/2 Read next byte from a stream (ISO)
get_char/1 Read next character as an atom (ISO)
get_char/2 Read next character from a stream (ISO)
get_code/1 Read next character (ISO)
get_code/2 Read next character from a stream (ISO)
get_single_char/1 Read next character from the terminal
get_time/1 Get current time
getenv/2 Get shell environment variable
goal_expansion/2 Hook for macro-expanding goals
goal_expansion/4 Hook for macro-expanding goals
ground/1 Verify term holds no unbound variables
gdebug/0 Debug using graphical tracer
gspy/1 Spy using graphical tracer
gtrace/0 Trace using graphical tracer
guitracer/0 Install hooks for the graphical debugger
gxref/0 Cross-reference loaded program
halt/0 Exit from Prolog
halt/1 Exit from Prolog with status
term_hash/2 Hash-value of ground term
term_hash/4 Hash-value of term with depth limit
help/0 Give help on help
help/1 Give help on predicates and show parts of manual
help_hook/1 (hook) User-hook in the help-system
if/1 Start conditional compilation (directive)
ignore/1 Call the argument, but always succeed
import/1 Import a predicate from a module
import_module/2 Query import modules
in_pce_thread/1 Run goal in XPCE thread
in_pce_thread_sync/1 Run goal in XPCE thread
include/1 Include a file with declarations
initialization/1 Initialization directive
initialization/2 Initialization directive
instance/2 Fetch clause or record from reference
integer/1 Type check for integer
interactor/0 Start new thread with console and top level
is/2 Evaluate arithmetic expression
is_absolute_file_name/1 True if arg defines an absolute path
is_assoc/1 Verify association list
is_list/1 Type check for a list
is_stream/1 Type check for a stream handle
join_threads/0 Join all terminated threads interactively
keysort/2 Sort, using a key
last/2 Last element of a list
leash/1 Change ports visited by the tracer
length/2 Length of a list
library_directory/1 (hook) Directories holding Prolog libraries
license/1 Define license for current file
license/2 Define license for named module
line_count/2 Line number on stream
line_position/2 Character position in line on stream
list_debug_topics/0 List registered topics for debugging
list_to_assoc/2 Create association tree from list
list_to_set/2 Remove duplicates from a list
listing/0 List program in current module
listing/1 List predicate
load_files/2 Load source files with options
load_foreign_library/1 shlib Load shared library (.so file)
load_foreign_library/2 shlib Load shared library (.so file)
locale_create/3 Create a new locale object
locale_destroy/1 Destroy a locale object
locale_property/2 Query properties of locale objects
locale_sort/2 Language dependent sort of atoms
make/0 Reconsult all changed source files
make_directory/1 Create a folder on the file system
make_library_index/1 Create autoload file INDEX.pl
make_library_index/2 Create selective autoload file INDEX.pl
map_assoc/2 Map association tree
map_assoc/3 Map association tree
max_assoc/3 Highest key in association tree
memberchk/2 Deterministic member/2
message_hook/3 Intercept print_message/2
message_line_element/2 (hook) Intercept print_message_lines/3
message_property/2 (hook) Define display of a message
message_queue_create/1 Create queue for thread communication
message_queue_create/2 Create queue for thread communication
message_queue_destroy/1 Destroy queue for thread communication
message_queue_property/2 Query message queue properties
message_to_string/2 Translate message-term to string
meta_predicate/1 Declare access to other predicates
min_assoc/3 Lowest key in association tree
module/1 Query/set current type-in module
module/2 Declare a module
module/3 Declare a module with language options
module_property/2 Find properties of a module
module_transparent/1 Indicate module based meta-predicate
msort/2 Sort, do not remove duplicates
multifile/1 Indicate distributed definition of predicate
mutex_create/1 Create a thread-synchronisation device
mutex_create/2 Create a thread-synchronisation device
mutex_destroy/1 Destroy a mutex
mutex_lock/1 Become owner of a mutex
mutex_property/2 Query mutex properties
mutex_statistics/0 Print statistics on mutex usage
mutex_trylock/1 Become owner of a mutex (non-blocking)
mutex_unlock/1 Release ownership of mutex
mutex_unlock_all/0 Release ownership of all mutexes
name/2 Convert between atom and list of character codes
nb_current/2 Enumerate non-backtrackable global variables
nb_delete/1 Delete a non-backtrackable global variable
nb_getval/2 Fetch non-backtrackable global variable
nb_linkarg/3 Non-backtrackable assignment to term
nb_linkval/2 Assign non-backtrackable global variable
nb_set_to_list/2 Convert non-backtrackable set to list
nb_setarg/3 Non-backtrackable assignment to term
nb_setval/2 Assign non-backtrackable global variable
nl/0 Generate a newline
nl/1 Generate a newline on a stream
nodebug/0 Disable debugging
nodebug/1 Disable debug-topic
noguitracer/0 Disable the graphical debugger
nonvar/1 Type check for bound term
noprofile/1 Hide (meta-) predicate for the profiler
noprotocol/0 Disable logging of user interaction
normalize_space/2 Normalize white space
nospy/1 Remove spy point
nospyall/0 Remove all spy points
not/1 Negation by failure (argument not provable). Same as \+/1
notrace/0 Stop tracing
notrace/1 Do not debug argument goal
nth_clause/3 N-th clause of a predicate
number/1 Type check for integer or float
number_chars/2 Convert between number and one-char atoms
number_codes/2 Convert between number and character codes
numbervars/3 Number unbound variables of a term
numbervars/4 Number unbound variables of a term
on_signal/3 Handle a software signal
once/1 Call a goal deterministically
op/3 Declare an operator
open/3 Open a file (creating a stream)
open/4 Open a file (creating a stream)
open_dde_conversation/3 Win32: Open DDE channel
open_null_stream/1 Open a stream to discard output
open_resource/3 Open a program resource as a stream
open_shared_object/2 UNIX: Open shared library (.so file)
open_shared_object/3 UNIX: Open shared library (.so file)
ord_list_to_assoc/2 Convert ordered list to assoc
parse_time/2 Parse text to a time-stamp
parse_time/3 Parse text to a time-stamp
pce_dispatch/1 Run XPCE GUI in separate thread
pce_call/1 Run goal in XPCE GUI thread
peek_byte/1 Read byte without removing
peek_byte/2 Read byte without removing
peek_char/1 Read character without removing
peek_char/2 Read character without removing
peek_code/1 Read character-code without removing
peek_code/2 Read character-code without removing
phrase/2 Activate grammar-rule set
phrase/3 Activate grammar-rule set (returning rest)
please/3 Query/change environment parameters
plus/3 Logical integer addition
portray/1 (hook) Modify behaviour of print/1
portray_clause/1 Pretty print a clause
portray_clause/2 Pretty print a clause to a stream
predicate_property/2 Query predicate attributes
predsort/3 Sort, using a predicate to determine the order
print/1 Print a term
print/2 Print a term on a stream
print_message/2 Print message from (exception) term
print_message_lines/3 Print message to stream
profile/1 Obtain execution statistics
profile/2 Obtain execution statistics
profile_count/3 Obtain profile results on a predicate
profiler/2 Obtain/change status of the profiler
prolog/0 Run interactive top level
prolog_choice_attribute/3 Examine the choice point stack
prolog_current_choice/1 Reference to most recent choice point
prolog_current_frame/1 Reference to goal's environment stack
prolog_cut_to/1 Realise global cuts
prolog_edit:locate/2 Locate targets for edit/1
prolog_edit:locate/3 Locate targets for edit/1
prolog_edit:edit_source/1 Call editor for edit/1
prolog_edit:edit_command/2 Specify editor activation
prolog_edit:load/0 Load edit/1 extensions
prolog_exception_hook/4 Rewrite exceptions
prolog_file_type/2 Define meaning of file extension
prolog_frame_attribute/3 Obtain information on a goal environment
prolog_ide/1 Program access to the development environment
prolog_list_goal/1 (hook) Intercept tracer 'L' command
prolog_load_context/2 Context information for directives
prolog_load_file/2 (hook) Program load_files/2
prolog_skip_level/2 Indicate deepest recursion to trace
prolog_skip_frame/1 Perform `skip' on a frame
prolog_stack_property/2 Query properties of the stacks
prolog_to_os_filename/2 Convert between Prolog and OS filenames
prolog_trace_interception/4 user Intercept the Prolog tracer
prompt1/1 Change prompt for 1 line
prompt/2 Change the prompt used by read/1
protocol/1 Make a log of the user interaction
protocola/1 Append log of the user interaction to file
protocolling/1 On what file is user interaction logged
public/1 Declaration that a predicate may be called
put/1 Write a character
put/2 Write a character on a stream
put_assoc/4 Add Key-Value to association tree
put_attr/3 Put attribute on a variable
put_attrs/2 Set/replace all attributes on a variable
put_byte/1 Write a byte
put_byte/2 Write a byte on a stream
put_char/1 Write a character
put_char/2 Write a character on a stream
put_code/1 Write a character-code
put_code/2 Write a character-code on a stream
qcompile/1 Compile source to Quick Load File
qcompile/2 Compile source to Quick Load File
qsave_program/1 Create runtime application
qsave_program/2 Create runtime application
random_property/1 Query properties of random generation
rational/1 Type check for a rational number
rational/3 Decompose a rational
read/1 Read Prolog term
read/2 Read Prolog term from stream
read_clause/3 Read clause from stream
read_history/6 Read using history substitution
read_link/3 Read a symbolic link
read_pending_input/3 Fetch buffered input from a stream
read_term/2 Read term with options
read_term/3 Read term with options from stream
read_term_from_atom/3 Read term with options from atom
recorda/2 Record term in the database (first)
recorda/3 Record term in the database (first)
recorded/2 Obtain term from the database
recorded/3 Obtain term from the database
recordz/2 Record term in the database (last)
recordz/3 Record term in the database (last)
redefine_system_predicate/1 Abolish system definition
reexport/1 Load files and re-export the imported predicates
reexport/2 Load predicates from a file and re-export it
reload_foreign_libraries/0 Reload DLLs/shared objects
reload_library_index/0 Force reloading the autoload index
rename_file/2 Change name of file
repeat/0 Succeed, leaving infinite backtrack points
require/1 This file requires these predicates
reset_gensym/1 Reset a gensym key
reset_gensym/0 Reset all gensym keys
reset_profiler/0 Clear statistics obtained by the profiler
resource/3 Declare a program resource
retract/1 Remove clause from the database
retractall/1 Remove unifying clauses from the database
same_file/2 Succeeds if arguments refer to same file
same_term/2 Test terms to be at the same address
see/1 Change the current input stream
seeing/1 Query the current input stream
seek/4 Modify the current position in a stream
seen/0 Close the current input stream
set_end_of_stream/1 Set physical end of an open file
set_input/1 Set current input stream from a stream
set_locale/1 Set the default local
set_module/1 Set properties of a module
set_output/1 Set current output stream from a stream
set_prolog_IO/3 Prepare streams for interactive session
set_prolog_flag/2 Define a system feature
set_prolog_stack/2 Modify stack characteristics
set_random/1 Control random number generation
set_stream/2 Set stream attribute
set_stream_position/2 Seek stream to position
setup_call_cleanup/3 Undo side-effects safely
setup_call_catcher_cleanup/4 Undo side-effects safely
setarg/3 Destructive assignment on term
setenv/2 Set shell environment variable
setlocale/3 Set/query C-library regional information
setof/3 Find all unique solutions to a goal
shell/0 Execute interactive subshell
shell/1 Execute OS command
shell/2 Execute OS command
show_profile/1 Show results of the profiler
size_file/2 Get size of a file in characters
size_nb_set/2 Determine size of non-backtrackable set
skip/1 Skip to character in current input
skip/2 Skip to character on stream
rl_add_history/1 Add line to readline(3) history
rl_read_history/1 Read readline(3) history
rl_read_init_file/1 Read readline(3) init file
rl_write_history/1 Write readline(3) history
sleep/1 Suspend execution for specified time
sort/2 Sort elements in a list
source_exports/2 Check whether source exports a predicate
source_file/1 Examine currently loaded source files
source_file/2 Obtain source file of predicate
source_file_property/2 Information about loaded files
source_location/2 Location of last read term
spy/1 Force tracer on specified predicate
stamp_date_time/3 Convert time-stamp to date structure
statistics/0 Show execution statistics
statistics/2 Obtain collected statistics
stream_pair/3 Create/examine a bi-directional stream
stream_position_data/3 Access fields from stream position
stream_property/2 Get stream properties
string/1 Type check for string
string_concat/3 atom_concat/3 for strings
string_length/2 Determine length of a string
string_codes/2 Conversion between string and list of character codes
string_code/3 Get or find a character code in a string
strip_module/3 Extract context module and term
style_check/1 Change level of warnings
sub_atom/5 Take a substring from an atom
sub_atom_icasechk/3 Case insensitive substring match
sub_string/5 Take a substring from a string
subsumes_term/2 One-sided unification test
succ/2 Logical integer successor relation
swritef/2 Formatted write on a string
swritef/3 Formatted write on a string
tab/1 Output number of spaces
tab/2 Output number of spaces on a stream
tdebug/0 Switch all threads into debug mode
tdebug/1 Switch a thread into debug mode
tell/1 Change current output stream
telling/1 Query current output stream
term_expansion/2 (hook) Convert term before compilation
term_expansion/4 (hook) Convert term before compilation
term_subsumer/3 Most specific generalization of two terms
term_to_atom/2 Convert between term and atom
thread_at_exit/1 Register goal to be called at exit
thread_create/3 Create a new Prolog task
thread_detach/1 Make thread cleanup after completion
thread_exit/1 Terminate Prolog task with value
thread_get_message/1 Wait for message
thread_get_message/2 Wait for message in a queue
thread_get_message/3 Wait for message in a queue
thread_initialization/1 Run action at start of thread
thread_join/2 Wait for Prolog task-completion
thread_local/1 Declare thread-specific clauses for a predicate
thread_message_hook/3 Thread local message_hook/3
thread_peek_message/1 Test for message
thread_peek_message/2 Test for message in a queue
thread_property/2 Examine Prolog threads
thread_self/1 Get identifier of current thread
thread_send_message/2 Send message to another thread
thread_setconcurrency/2 Number of active threads
thread_signal/2 Execute goal in another thread
thread_statistics/3 Get statistics of another thread
threads/0 List running threads
throw/1 Raise an exception (see catch/3)
time/1 Determine time needed to execute goal
time_file/2 Get last modification time of file
tmp_file/2 Create a temporary filename
tmp_file_stream/3 Create a temporary file and open it
tnodebug/0 Switch off debug mode in all threads
tnodebug/1 Switch off debug mode in a thread
told/0 Close current output
tprofile/1 Profile a thread for some period
trace/0 Start the tracer
trace/1 Set trace point on predicate
trace/2 Set/Clear trace point on ports
tracing/0 Query status of the tracer
trim_stacks/0 Release unused memory resources
true/0 Succeed
tspy/1 Set spy point and enable debugging in all threads
tspy/2 Set spy point and enable debugging in a thread
tty_get_capability/3 Get terminal parameter
tty_goto/2 Goto position on screen
tty_put/2 Write control string to terminal
tty_size/2 Get row/column size of the terminal
ttyflush/0 Flush output on terminal
unify_with_occurs_check/2 Logically sound unification
unifiable/3 Determining binding required for unification
unix/1 OS interaction
unknown/2 Trap undefined predicates
unload_file/1 Unload a source file
unload_foreign_library/1 shlib Detach shared library (.so file)
unload_foreign_library/2 shlib Detach shared library (.so file)
unsetenv/1 Delete shell environment variable
upcase_atom/2 Convert atom to upper-case
use_foreign_library/1 Load DLL/shared object (directive)
use_foreign_library/2 Load DLL/shared object (directive)
use_module/1 Import a module
use_module/2 Import predicates from a module
var/1 Type check for unbound variable
var_number/2 Check that var is numbered by numbervars
variant_sha1/2 Term-hash for term-variants
version/0 Print system banner message
version/1 Add messages to the system banner
visible/1 Ports that are visible in the tracer
volatile/1 Predicates that are not saved
wait_for_input/3 Wait for input with optional timeout
when/2 Execute goal when condition becomes true
wildcard_match/2 Csh(1) style wildcard match
win_add_dll_directory/1 Add directory to DLL search path
win_add_dll_directory/2 Add directory to DLL search path
win_remove_dll_directory/2 Remove directory from DLL search path
win_exec/2 Win32: spawn Windows task
win_has_menu/0 Win32: true if console menu is available
win_folder/2 Win32: get special folder by CSIDL
win_insert_menu/2 swipl-win.exe: add menu
win_insert_menu_item/4 swipl-win.exe: add item to menu
win_shell/2 Win32: open document through Shell
win_shell/3 Win32: open document through Shell
win_registry_get_value/3 Win32: get registry value
win_window_pos/1 Win32: change size and position of window
window_title/2 Win32: change title of window
with_mutex/2 Run goal while holding mutex
with_output_to/2 Write to strings and more
working_directory/2 Query/change CWD
write/1 Write term
write/2 Write term to stream
writeln/1 Write term, followed by a newline
write_canonical/1 Write a term with quotes, ignore operators
write_canonical/2 Write a term with quotes, ignore operators on a stream
write_length/3 Dermine #characters to output a term
write_term/2 Write term with options
write_term/3 Write term with options to stream
writef/1 Formatted write
writef/2 Formatted write on stream
writeq/1 Write term, insert quotes
writeq/2 Write term, insert quotes on stream
1166..22 LLiibbrraarryy pprreeddiiccaatteess
1166..22..11 lliibbrraarryy((aaggggrreeggaattee))
aggregate/3 Aggregate bindings in Goal according to Template.
aggregate/4 Aggregate bindings in Goal according to Template.
aggregate_all/3 Aggregate bindings in Goal according to Template.
aggregate_all/4 Aggregate bindings in Goal according to Template.
foreach/2 True if conjunction of results is true.
free_variables/4 Find free variables in bagof/setof template.
safe_meta/2 Declare the aggregate meta-calls safe.
1166..22..22 lliibbrraarryy((aappppllyy))
exclude/3 Filter elements for which Goal fails.
foldl/4 Fold a list, using arguments of the list as left argument.
foldl/5 Fold a list, using arguments of the list as left argument.
foldl/6 Fold a list, using arguments of the list as left argument.
foldl/7 Fold a list, using arguments of the list as left argument.
include/3 Filter elements for which Goal succeeds.
maplist/2 True if Goal can successfully be applied on all elements of List.
maplist/3 As maplist/2, operating on pairs of elements from two lists.
maplist/4 As maplist/2, operating on triples of elements from three lists.
maplist/5 As maplist/2, operating on quadruples of elements from four lists.
partition/4 Filter elements of List according to Pred.
partition/5 Filter List according to Pred in three sets.
scanl/4 Left scan of list.
scanl/5 Left scan of list.
scanl/6 Left scan of list.
scanl/7 Left scan of list.
1166..22..33 lliibbrraarryy((aassssoocc))
assoc_to_list/2 Translate assoc into a pairs list
assoc_to_keys/2 Translate assoc into a key list
assoc_to_values/2 Translate assoc into a value list
empty_assoc/1 Test/create an empty assoc
gen_assoc/3 Non-deterministic enumeration of assoc
get_assoc/3 Get associated value
get_assoc/5 Get and replace associated value
list_to_assoc/2 Translate pair list to assoc
map_assoc/2 Test assoc values
map_assoc/3 Map assoc values
max_assoc/3 Max key-value of an assoc
min_assoc/3 Min key-value of an assoc
ord_list_to_assoc/3Translate ordered list into an assoc
put_assoc/4 Add association to an assoc
1166..22..44 lliibbrraarryy((bbrrooaaddccaasstt))
broadcast/1 Send event notification
broadcast_request/1 Request all agents
listen/2 Listen to event notifications
listen/3 Listen to event notifications
unlisten/1 Stop listening to event notifications
unlisten/2 Stop listening to event notifications
unlisten/3 Stop listening to event notifications
listening/3 Who is listening to event notifications?
1166..22..55 lliibbrraarryy((cchhaarrssiioo))
atom_to_chars/2 Convert Atom into a list of character codes.
atom_to_chars/3 Convert Atom into a difference list of character codes.
format_to_chars/3 Use format/2 to write to a list of character codes.
format_to_chars/4 Use format/2 to write to a difference list of character codes.
number_to_chars/2 Convert Atom into a list of character codes.
number_to_chars/3 Convert Number into a difference list of character codes.
open_chars_stream/2 Open Codes as an input stream.
read_from_chars/2 Read Codes into Term.
read_term_from_chars/3Read Codes into Term.
with_output_to_chars/2Run Goal as with once/1.
with_output_to_chars/3Run Goal as with once/1.
with_output_to_chars/4Same as with_output_to_chars/3 using an explicit stream.
write_to_chars/2 Write a term to a code list.
write_to_chars/3 Write a term to a code list.
1166..22..66 lliibbrraarryy((cchheecckk))
check/0 Program completeness and consistency
list_undefined/0 List undefined predicates
list_autoload/0 List predicates that require autoload
list_redefined/0 List locally redefined predicates
1166..22..77 lliibbrraarryy((ccssvv))
csv_read_file/2 Read a CSV file into a list of rows.
csv_read_file/3 Read a CSV file into a list of rows.
csv_read_file_row/3True when Row is a row in File.
csv_write_file/2 Write a list of Prolog terms to a CSV file.
csv_write_file/3 Write a list of Prolog terms to a CSV file.
csv_write_stream/3 Write the rows in Data to Stream.
csv/3 Prolog DCG to `read/write' CSV data.
csv/4 Prolog DCG to `read/write' CSV data.
1166..22..88 lliibbrraarryy((lliissttss))
append/2 Concatenate a list of lists.
append/3 List1AndList2 is the concatenation of List1 and List2.
delete/3 Delete matching elements from a list.
flatten/2 Is true if List2 is a non-nested version of List1.
intersection/3 True if Set3 unifies with the intersection of Set1 and Set2.
is_set/1 True if Set is a proper list without duplicates.
last/2 Succeeds when Last is the last element of List.
list_to_set/2 True when Set has the same elements as List in the same order.
max_list/2 True if Max is the largest number in List.
max_member/2 True when Max is the largest member in the standard order of terms.
member/2 True if Elem is a member of List.
min_list/2 True if Min is the smallest number in List.
min_member/2 True when Min is the smallest member in the standard order of terms.
nextto/3 True if Y follows X in List.
nth0/3 True when Elem is the Index'th element of List.
nth0/4 Select/insert element at index.
nth1/3 Is true when Elem is the Index'th element of List.
nth1/4 As nth0/4, but counting starts at 1.
numlist/3 List is a list [Low, Low+1, ... High].
permutation/2 True when Xs is a permutation of Ys.
prefix/2 True iff Part is a leading substring of Whole.
proper_length/2 True when Length is the number of elements in the proper list List.
reverse/2 Is true when the elements of List2 are in reverse order compared to List1.
same_length/2 Is true when List1 and List2 are lists with the same number of elements.
select/3 Is true when List1, with Elem removed, results in List2.
select/4 Select from two lists at the same positon.
selectchk/3 Semi-deterministic removal of first element in List that unifies with Elem.
selectchk/4 Semi-deterministic version of select/4.
subset/2 True if all elements of SubSet belong to Set as well.
subtract/3 Delete all elements in Delete from Set.
sum_list/2 Sum is the result of adding all numbers in List.
union/3 True if Set3 unifies with the union of Set1 and Set2.
1166..22..99 lliibbrraarryy((ddeebbuugg))
assertion/1 Acts similar to C assert() macro.
assertion_failed/2 This hook is called if the Goal of assertion/1 fails.
debug/1 Add/remove a topic from being printed.
debug/3 Format a message if debug topic is enabled.
debug_message_context/1 Specify additional context for debug messages.
debug_print_hook/3 Hook called by debug/3.
debugging/1 Examine debug topics.
debugging/2 Examine debug topics.
list_debug_topics/0 List currently known debug topics and their setting.
nodebug/1 Add/remove a topic from being printed.
1166..22..1100 lliibbrraarryy((ooppttiioonn))
merge_options/3 Merge two option lists.
meta_options/3 Perform meta-expansion on options that are module-sensitive.
option/2 Get an Option from OptionList.
option/3 Get an Option Qfrom OptionList.
select_option/3 Get and remove Option from an option list.
select_option/4 Get and remove Option with default value.
1166..22..1111 lliibbrraarryy((ooppttppaarrssee))
opt_arguments/3 Extract commandline options according to a specification.
opt_help/2 True when Help is a help string synthesized from OptsSpec.
opt_parse/4 Equivalent to opt_parse(OptsSpec, ApplArgs, Opts, PositionalArgs, []).
opt_parse/5 Parse the arguments Args (as list of atoms) according to OptsSpec.
1166..22..1122 lliibbrraarryy((oorrddsseettss))
is_ordset/1 True if Term is an ordered set.
list_to_ord_set/2 Transform a list into an ordered set.
ord_add_element/3 Insert an element into the set.
ord_del_element/3 Delete an element from an ordered set.
ord_disjoint/2 True if Set1 and Set2 have no common elements.
ord_empty/1 True when List is the empty ordered set.
ord_intersect/2 True if both ordered sets have a non-empty intersection.
ord_intersect/3 Intersection holds the common elements of Set1 and Set2.
ord_intersection/2 Intersection of a powerset.
ord_intersection/3 Intersection holds the common elements of Set1 and Set2.
ord_intersection/4 Intersection and difference between two ordered sets.
ord_memberchk/2 True if Element is a member of OrdSet, compared using ==.
ord_selectchk/3 Selectchk/3, specialised for ordered sets.
ord_seteq/2 True if Set1 and Set2 have the same elements.
ord_subset/2 Is true if all elements of Sub are in Super.
ord_subtract/3 Diff is the set holding all elements of InOSet that are not in NotInOSet.
ord_symdiff/3 Is true when Difference is the symmetric difference of Set1 and Set2.
ord_union/2 True if Union is the union of all elements in the superset SetOfSets.
ord_union/3 Union is the union of Set1 and Set2.
ord_union/4 True iff ord_union(Set1, Set2, Union) and ord_subtract(Set2, Set1, New).
1166..22..1133 lliibbrraarryy((pprreeddiiccaattee__ooppttiioonnss))
assert_predicate_options/4 As predicate_options(:PI, +Arg, +Options).
check_predicate_option/3 Verify predicate options at runtime.
check_predicate_options/0 Analyse loaded program for erroneous options.
current_option_arg/2 True when Arg of PI processes predicate options.
current_predicate_option/3 True when Arg of PI processes Option.
current_predicate_options/3 True when Options is the current active option declaration for PI on Arg.
derive_predicate_options/0 Derive new predicate option declarations.
derived_predicate_options/1 Derive predicate option declarations for a module.
derived_predicate_options/3 Derive option arguments using static analysis.
predicate_options/3 Declare that the predicate PI processes options on Arg.
retractall_predicate_options/0 Remove all dynamically (derived) predicate options.
1166..22..1144 lliibbrraarryy((pprroollooggppaacckk))
environment/2 Hook to define the environment for building packs.
pack_info/1 Print more detailed information about Pack.
pack_install/1 Install a package.
pack_install/2 Install package Name.
pack_list/1 Query package server and installed packages and display results.
pack_list_installed/0 List currently installed packages.
pack_property/2 True when Property is a property of Pack.
pack_rebuild/0 Rebuild foreign components of all packages.
pack_rebuild/1 Rebuilt possible foreign components of Pack.
pack_remove/1 Remove the indicated package.
pack_search/1 Query package server and installed packages and display results.
pack_upgrade/1 Try to upgrade the package Pack.
1166..22..1155 lliibbrraarryy((pprroollooggxxrreeff))
prolog:called_by/2 (hook) Extend cross-referencer
xref_built_in/1 Examine defined built-ins
xref_called/3 Examine called predicates
xref_clean/1 Remove analysis of source
xref_current_source/1 Examine cross-referenced sources
xref_defined/3 Examine defined predicates
xref_exported/2 Examine exported predicates
xref_module/2 Module defined by source
xref_source/1 Cross-reference analysis of source
1166..22..1166 lliibbrraarryy((ppaaiirrss))
group_pairs_by_key/2Group values with the same key.
map_list_to_pairs/3 Create a Key-Value list by mapping each element of List.
pairs_keys/2 Remove the values from a list of Key-Value pairs.
pairs_keys_values/3 True if Keys holds the keys of Pairs and Values the values.
pairs_values/2 Remove the keys from a list of Key-Value pairs.
transpose_pairs/2 Swap Key-Value to Value-Key.
1166..22..1177 lliibbrraarryy((ppiioo))
1166..22..1177..11 lliibbrraarryy((ppuurree__iinnppuutt))
phrase_from_file/2 Process the content of File using the DCG rule Grammar.
phrase_from_file/3 As phrase_from_file/2, providing additional Options.
phrase_from_stream/2 Helper for phrase_from_file/3.
stream_to_lazy_list/2 Create a lazy list representing the character codes in Stream.
lazy_list_character_count/3True when CharCount is the current character count in the Lazy list.
lazy_list_location/3 Determine current (error) location in a lazy list.
syntax_error/3 Throw the syntax error Error at the current location of the input.
1166..22..1188 lliibbrraarryy((rraannddoomm))
getrand/1 Query/set the state of the random generator.
maybe/0 Succeed/fail with equal probability (variant of maybe/1).
maybe/1 Succeed with probability P, fail with probability 1-P.
maybe/2 Succeed with probability K/N (variant of maybe/1).
random/1 Binds R to a new random float in the _open_interval (0.0,1.0).
random/3 Generate a random integer or float in a range.
random_between/3 Binds R to a random integer in [L,U] (i.e., including both L and U).
random_member/2 X is a random member of List.
random_perm2/4 Does X=A,Y=B or X=B,Y=A with equal probability.
random_permutation/2 Permutation is a random permutation of List.
random_select/3 Randomly select or insert an element.
randseq/3 S is a list of K unique random integers in the range 1..N.
randset/3 S is a sorted list of K unique random integers in the range 1..N.
setrand/1 Query/set the state of the random generator.
1166..22..1199 lliibbrraarryy((rreeaadduuttiill))
read_line_to_codes/2 Read line from a stream
read_line_to_codes/3 Read line from a stream
read_stream_to_codes/2Read contents of stream
read_stream_to_codes/3Read contents of stream
read_file_to_codes/3 Read contents of file
read_file_to_terms/3 Read contents of file to Prolog terms
1166..22..2200 lliibbrraarryy((rreeccoorrdd))
record/1 Define named fields in a term
1166..22..2211 lliibbrraarryy((rreeggiissttrryy))
This library is only available on Windows systems.
registry_get_key/2 Get principal value of key
registry_get_key/3 Get associated value of key
registry_set_key/2 Set principal value of key
registry_set_key/3 Set associated value of key
registry_delete_key/1 Remove a key
shell_register_file_type/4Register a file-type
shell_register_dde/6 Register DDE action
shell_register_prolog/1 Register Prolog
1166..22..2222 lliibbrraarryy((uuggrraapphhss))
vertices_edges_to_ugraph/3Create unweighted graph
vertices/2 Find vertices in graph
edges/2 Find edges in graph
add_vertices/3 Add vertices to graph
del_vertices/3 Delete vertices from graph
add_edges/3 Add edges to graph
del_edges/3 Delete edges from graph
transpose/2 Invert the direction of all edges
neighbors/3 Find neighbors of vertice
neighbours/3 Find neighbors of vertice
complement/2 Inverse presense of edges
compose/3
top_sort/2 Sort graph topologically
top_sort/3 Sort graph topologically
transitive_closure/2 Create transitive closure of graph
reachable/3 Find all reachable vertices
ugraph_union/3 Union of two graphs
1166..22..2233 lliibbrraarryy((uurrll))
file_name_to_url/2 Translate between a filename and a file:// URL.
global_url/3 Translate a possibly relative URL into an absolute one.
http_location/2 Construct or analyze an HTTP location.
is_absolute_url/1 True if URL is an absolute URL.
parse_url/2 Construct or analyse a URL.
parse_url/3 Similar to parse_url/2 for relative URLs.
parse_url_search/2 Construct or analyze an HTTP search specification.
set_url_encoding/2 Query and set the encoding for URLs.
url_iri/2 Convert between a URL, encoding in US-ASCII and an IRI.
www_form_encode/2 En/decode to/from application/x-www-form-encoded.
1166..22..2244 lliibbrraarryy((wwwwww__bbrroowwsseerr))
www_open_url/1 Open a web-page in a browser
1166..22..2255 lliibbrraarryy((ccllpp//ccllppffdd))
#/\/2 P and Q hold.
#</2 X is less than Y.
#<==/2 Q implies P.
#<==>/2 P and Q are equivalent.
#=/2 X equals Y.
#=</2 X is less than or equal to Y.
#==>/2 P implies Q.
#>/2 X is greater than Y.
#>=/2 X is greater than or equal to Y.
#\/1 The reifiable constraint Q does _not_hold.
#\//2 P or Q holds.
#\=/2 X is not Y.
all_different/1 Vars are pairwise distinct.
all_distinct/1 Like all_different/1, with stronger propagation.
automaton/3 Describes a list of finite domain variables with a finite automaton.
automaton/8 Describes a list of finite domain variables with a finite automaton.
chain/2 Zs form a chain with respect to Relation.
circuit/1 True if the list Vs of finite domain variables induces a Hamiltonian circuit.
cumulative/1 Equivalent to cumulative(Tasks, [limit(1)]).
cumulative/2 Tasks is a list of tasks, each of the form task(S_i, D_i, E_i, C_i, T_i).
element/3 The N-th element of the list of finite domain variables Vs is V.
fd_dom/2 Dom is the current domain (see in/2) of Var.
fd_inf/2 Inf is the infimum of the current domain of Var.
fd_size/2 Determine the size of a variable's domain.
fd_sup/2 Sup is the supremum of the current domain of Var.
fd_var/1 True iff Var is a CLP(FD) variable.
global_cardinality/2 Global Cardinality constraint.
global_cardinality/3 Global Cardinality constraint.
in/2 Var is an element of Domain.
indomain/1 Bind Var to all feasible values of its domain on backtracking.
ins/2 The variables in the list Vars are elements of Domain.
label/1 Equivalent to labeling([], Vars).
labeling/2 Assign a value to each variable in Vars.
lex_chain/1 Lists are lexicographically non-decreasing.
scalar_product/4 Cs is a list of integers, Vs is a list of variables and integers.
serialized/2 Describes a set of non-overlapping tasks.
sum/3 The sum of elements of the list Vars is in relation Rel to Expr.
transpose/2 Transpose a list of lists of the same length.
tuples_in/2 Relation must be a list of lists of integers.
zcompare/3 Analogous to compare/3, with finite domain variables A and B.
1166..22..2266 lliibbrraarryy((ccllppqqrr))
entailed/1 Check if constraint is entailed
inf/2 Find the infimum of an expression
sup/2 Find the supremum of an expression
minimize/1 Minimizes an expression
maximize/1 Maximizes an expression
bb_inf/3 Infimum of expression for mixed-integer problems
bb_inf/4 Infimum of expression for mixed-integer problems
bb_inf/5 Infimum of expression for mixed-integer problems
dump/3 Dump constraints on variables
1166..22..2277 lliibbrraarryy((ccllpp//ssiimmpplleexx))
assignment/2 Solve assignment problem
constraint/3 Add linear constraint to state
constraint/4 Add named linear constraint to state
constraint_add/4 Extend a named constraint
gen_state/1 Create empty linear program
maximize/3 Maximize objective function in to linear constraints
minimize/3 Minimize objective function in to linear constraints
objective/2 Fetch value of objective function
shadow_price/3 Fetch shadow price in solved state
transportation/4 Solve transportation problem
variable_value/3 Fetch value of variable in solved state
1166..22..2288 lliibbrraarryy((tthhrreeaadd__ppooooll))
create_pool/1 Hook to create a thread pool lazily.
current_thread_pool/1 True if Name refers to a defined thread pool.
thread_create_in_pool/4Create a thread in Pool.
thread_pool_create/3 Create a pool of threads.
thread_pool_destroy/1 Destroy the thread pool named Name.
thread_pool_property/2 True if Property is a property of thread pool Name.
1166..22..2299 lliibbrraarryy((vvaarrnnuummbbeerrss))
max_var_number/3 True when Max is the max of Start and the highest numbered $VAR(N) term.
numbervars/1 Number variables in Term using $VAR(N).
varnumbers/2 Inverse of numbervars/1.
varnumbers/3 Inverse of numbervars/3.
1166..33 AArriitthhmmeettiicc FFuunnccttiioonnss
*/2 Multiplication
**/2 Power function
+/1 Unary plus (No-op)
+/2 Addition
-/1 Unary minus
-/2 Subtraction
//2 Division
///2 Integer division
/\/2 Bitwise and
<</2 Bitwise left shift
>>/2 Bitwise right shift
./2 List of one character: character code
\/1 Bitwise negation
\//2 Bitwise or
^/2 Power function
abs/1 Absolute value
acos/1 Inverse (arc) cosine
acosh/1 Inverse hyperbolic cosine
asin/1 Inverse (arc) sine
asinh/1 Inverse (arc) sine
atan/1 Inverse hyperbolic sine
atan/2 Rectangular to polar conversion
atanh/1 Inverse hyperbolic tangent
atan2/2 Rectangular to polar conversion
ceil/1 Smallest integer larger than arg
ceiling/1 Smallest integer larger than arg
cos/1 Cosine
cosh/1 Hyperbolic cosine
copysign/2 Apply sign of N2 to N1
cputime/0 Get CPU time
div/2 Integer division
e/0 Mathematical constant
epsilon/0 Floating point precision
eval/1 Evaluate term as expression
exp/1 Exponent (base e)
float/1 Explicitly convert to float
float_fractional_part/1 Fractional part of a float
float_integer_part/1 Integer part of a float
floor/1 Largest integer below argument
gcd/2 Greatest common divisor
integer/1 Round to nearest integer
log/1 Natural logarithm
log10/1 10 base logarithm
lsb/1 Least significant bit
max/2 Maximum of two numbers
min/2 Minimum of two numbers
msb/1 Most significant bit
mod/2 Remainder of division
powm/3 Integer exponent and modulo
random/1 Generate random number
random_float/0 Generate random number
rational/1 Convert to rational number
rationalize/1 Convert to rational number
rdiv/2 Ration number division
rem/2 Remainder of division
round/1 Round to nearest integer
truncate/1 Truncate float to integer
pi/0 Mathematical constant
popcount/1 Count 1s in a bitvector
sign/1 Extract sign of value
sin/1 Sine
sinh/1 Hyperbolic sine
sqrt/1 Square root
tan/1 Tangent
tanh/1 Hyperbolic tangent
xor/2 Bitwise exclusive or
1166..44 OOppeerraattoorrss
$ 1 fx Bind top-level variable
^ 200 xfy Predicate
^ 200 xfy Arithmetic function
mod 300 xfx Arithmetic function
* 400 yfx Arithmetic function
/ 400 yfx Arithmetic function
// 400 yfx Arithmetic function
<< 400 yfx Arithmetic function
>> 400 yfx Arithmetic function
xor 400 yfx Arithmetic function
+ 500 fx Arithmetic function
- 500 fx Arithmetic function
? 500 fx XPCE: obtainer
\ 500 fx Arithmetic function
+ 500 yfx Arithmetic function
- 500 yfx Arithmetic function
/\ 500 yfx Arithmetic function
\/ 500 yfx Arithmetic function
: 600 xfy module:term separator
< 700 xfx Predicate
= 700 xfx Predicate
=.. 700 xfx Predicate
=:= 700 xfx Predicate
< 700 xfx Predicate
== 700 xfx Predicate
=@= 700 xfx Predicate
=\= 700 xfx Predicate
> 700 xfx Predicate
>= 700 xfx Predicate
@< 700 xfx Predicate
@=< 700 xfx Predicate
@> 700 xfx Predicate
@>= 700 xfx Predicate
is 700 xfx Predicate
\= 700 xfx Predicate
\== 700 xfx Predicate
=@= 700 xfx Predicate
not 900 fy Predicate
\+ 900 fy Predicate
, 1000 xfy Predicate
-> 1050 xfy Predicate
*-> 1050 xfy Predicate
; 1100 xfy Predicate
| 1105 xfy Predicate
discontiguous 1150 fx Predicate
dynamic 1150 fx Predicate
module_transparent 1150 fx Predicate
meta_predicate 1150 fx Head
multifile 1150 fx Predicate
thread_local 1150 fx Predicate
volatile 1150 fx Predicate
initialization 1150 fx Predicate
:- 1200 fx Introduces a directive
?- 1200 fx Introduces a directive
--> 1200 xfx DCGrammar: rewrite
:- 1200 xfx head :- body. separator
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1671
Index
( _l_i_b_r_a_r_y, 888 PL_rewind_foreign_frame(), 1101
-lswipl _l_i_b_r_a_r_y, 1161 PL_same_compound(), 1120
.pl, 78 PL_set_engine(), 887
.pro, 78 PL_signal(), 1113
?=/2, 208 PL_skip_list(), 1001
@/2, 735 PL_strip_module(), 1104
=:=/2, 481 PL_succeed(), 922
/\/2, 520 PL_term_type(), 943
=\=/2, 480 PL_thread_at_exit(), 883
|/2, 217 PL_thread_attach_engine(), 881
#/\/2, 1291 PL_thread_destroy_engine(), 882
#=/2, 1283 PL_thread_self(), 879
#<==>/2, 1288 PL_throw(), 1109
#>=/2, 1281 PL_toplevel(), 1156
#>/2, 1285 PL_type_error(), 1062
#=</2, 1282 PL_unify(), 1023
#</2, 1286 PL_unify_arg(), 1038
#\=/2, 1284 PL_unify_atom(), 1024
#\/1, 1287 PL_unify_atom_chars(), 1027
,/2, 215 PL_unify_atom_nchars(), 984
#\//2, 1292 PL_unify_blob(), 1076
{}/1, 1314 PL_unify_bool(), 1025
!/0, 214 PL_unify_bool_ex(), 1058
/, 79 PL_unify_chars(), 1026
//2, 491 PL_unify_float(), 1033
./2, 503 PL_unify_functor(), 1035
=/2, 191 PL_unify_int64(), 1032
==/2, 194 PL_unify_integer(), 1031
>=/2, 479 PL_unify_list(), 1036
>/2, 476 PL_unify_list_chars(), 1028
^/2, 542 PL_unify_list_ex(), 1056
///2, 494 PL_unify_list_nchars(), 987
->/2, 218 PL_unify_list_ncodes(), 986
=</2, 478 PL_unify_mpq(), 1084
#<==/2, 1290 PL_unify_mpz(), 1083
<</2, 518 PL_unify_nil(), 1037
</2, 477 PL_unify_nil_ex(), 1057
-/1, 486 PL_unify_pointer(), 1034
-/2, 489 PL_unify_string_chars(), 1029
\=/2, 192 PL_unify_string_nchars(), 985, 1030
\/1, 522 PL_unify_term(), 1039
\==/2, 195 PL_unify_thread_id(), 880
\+/1, 220 PL_unify_wchars(), 994
\//2, 519 PL_unify_wchars_diff(), 995
+/1, 487 PL_uninstantiation_error(), 1060
+/2, 488 PL_unregister_atom(), 940
**/2, 541 PL_unregister_blob_type(), 1073
#==>/2, 1289 PL_warning(), 1132
>>/2, 517 PL_wchars_to_term(), 1041
;/2, 216 plus/3, 474
*->/2, 219 PLVERSION, 1176
=@=/2, 203 popcount/1, 554
\=@=/2, 204 portable
@>=/2, 199 prolog code, 1619
@>/2, 198 portray/1, 32, 81, 384, 394, 396,
*/2, 490 1091, 1150, 1608
@=</2, 197 portray_clause/1, 169, 171, 172
@</2, 196 portray_clause/2, 171, 172, 411
=../2, 409 portray_text _l_i_b_r_a_r_y, 394
\, 79 portray_text/1, 255
_PL_get_arg(), 975 powm/3, 543
64-bits precedence, 1624
platforms, 72 pred/1, 738
abolish/1, 257, 258 predicate,d1624ynamic, 1624
abolish/2, 258 exported, 1624
abolish/[1 imported, 1624
2], 41 predicate indicator, 108, 1624
abort/0, 20, 32, 306, 311, 318, predicate_options/3, 1451
655, 809, 861, 1134, 1145, predicate_property/2, 114, 223,
1598 288, 295, 297, 732, 758
abs/1, 498 predsort/3, 566
absolute_file_name/2, 7, 111, 123, prefix/2, 1357
639, 641, 651, 1189 print/1, 384, 394, 396, 577, 582,
absolute_file_name/3, 41, 44, 103, 1091, 1637
110, 120, 126, 607, 639, print/2, 395
640, 1128, 1129, 1514, 1515 print_message/2, 41, 44, 111, 128,
absolute_file_name/[2 238--241, 248, 400, 704,
3], 41, 119, 640 825, 827, 1637
access_file/2, 41, 629, 640 print_message_lines/3, 239--241,
acos/1, 528 244, 248, 1637
acosh/1, 536 priority, 1624
acquire(), 1069 process _l_i_b_r_a_r_y, 306, 593
acyclic_term/1, 59, 188, 189, 202 process_create/3, 306, 593, 601
add_edges/3, 1555 profile file, 14
add_import_module/3, 743, 745, 760 profile/1, 691, 875, 1158
add_nb_set/2, 1388 profile/3, 692
add_nb_set/3, 1388--1390 profiler/2, 694
add_vertices/3, 1553 profiling
agent, 1236 foreign code, 1177
aggregate/3, 732, 1196 program, 1624
aggregate/4, 732, 1197 prolog/0, 20, 319, 654, 658, 659,
aggregate_all/3, 1198 737, 1156, 1592
aggregate_all/4, 1199 prolog/assertion_failed, 1348
all_different/1, 1277 prolog/debug_print_hook, 1346
all_distinct/1, 1278 prolog:break_hook/6, 1602
AMD64, 73 prolog:called_by/2, 1485
anonymous prolog:comment_hook/3, 1613
variable, 58 prolog:debug_control_hook/1, 1609
anonymous variable, 1624 prolog:help_hook/1, 1610
ansi_format/3, 243 prolog:message_line_element/2, 244
ansi_term _l_i_b_r_a_r_y, 41, 240, 244 prolog_breakpoints _l_i_b_r_a_r_y, 1601
append/1, 320, 324 prolog_choice_attribute/3, 1589,
append/2, 730, 1356 1591, 1598
append/3, 301, 432, 1355 prolog_codewalk _l_i_b_r_a_r_y, 297
apply/2, 224 prolog_current_choice/1, 1589, 1591,
apply_macros _l_i_b_r_a_r_y, 255 1594
apropos/1, 26, 27, 44, 1610, 1637 prolog_current_frame/1, 1588, 1590
arg/3, 408 prolog_cut_to/1, 1594
arithmetic_function/1, 1107 prolog_edit:edit_command/2, 166
arity, 1624 prolog_edit:edit_source/1, 165
asin/1, 527 prolog_edit:load/0, 167
asinh/1, 535 prolog_edit:locate/2, 164
assert, 1624 prolog_edit:locate/3, 163
assert/1, 110, 256, 263, 265, 278, prolog_exception_hook/4, 236, 704,
284, 285, 297, 723, 731, 1603, 1604
761, 786, 852 prolog_file_type/2, 110, 121, 640
assert/2, 41, 268, 275, 300 prolog_frame_attribute/3, 302, 1590,
assert_predicate_options/4, 1452 1598, 1604
asserta/1, 18, 59, 60, 118, 203, prolog_ide _c_l_a_s_s, 105
263, 264, 266, 267, 733, prolog_ide/1, 104, 105
735, 1624 prolog_list_goal/1, 1608
asserta/2, 266, 275 prolog_load_context/2, 126, 127,
assertion/1, 1347, 1602 399, 1620
assertz/1, 118, 259, 264, 265, 302, prolog_load_file/2, 111, 1611, 1612
1624 prolog_server _l_i_b_r_a_r_y, 304, 319
assertz/2, 267, 268, 275 prolog_skip_frame/1, 1599, 1600
assignment/2, 1528 prolog_skip_level/2, 1599, 1600
assoc _l_i_b_r_a_r_y, 1220, 1386 prolog_stack _l_i_b_r_a_r_y, 1590, 1604
assoc_to_keys/2, 1222 prolog_stack_property/2, 704, 705
assoc_to_list/2, 1221 prolog_to_os_filename/2, 79, 607,
assoc_to_values/2, 1223 631, 641, 645
at_end_of_stream/0, 377 prolog_trace_interception/4, 94,
at_end_of_stream/1, 378, 382 670, 704, 1590, 1591, 1598
at_end_of_stream/[0 prolog_xref _l_i_b_r_a_r_y, 102, 724
1], 311, 1510 prompt
at_halt/1, 41, 128, 129, 657, 831, alternatives, 41
1147, 1157, 1617, 1637 prompt/2, 403--405, 825
atan/1, 529 prompt1/1, 405
atan/2, 531 proper_length/2, 1369
atan2/2, 530 property, 1624
atanh/1, 537 protocol/1, 662, 663, 665
atom, 1624 protocola/1, 663, 665
atom/1, 181, 941 protocolling/1, 665
atom_chars/2, 41, 109, 335, 362, prove, 1624
422, 424, 426, 448 public list, 1624
atom_codes/2, 41, 109, 335, 422-- public/1, 283, 288, 297, 1183
424, 428, 429, 448 put/1, 345, 346
atom_concat/3, 432, 462 put/2, 346
ATOM_dot(), 933 put_assoc/4, 1234
atom_length/2, 41, 436, 460 put_attr/3, 764, 765, 769, 776
ATOM_nil(), 932 put_attrs/2, 778
atom_number/2, 335, 428, 429 put_byte/1, 347
atom_prefix/2, 437 put_byte/2, 348
atom_result/2, 752 put_byte/[1
atom_string/2, 458 2], 109
atom_to_chars/2, 1250 put_char/1, 345, 349, 351
atom_to_chars/3, 1251 put_char/2, 350
atom_to_term/3, 402, 431 put_char/[1
atomic/1, 184 2], 109
atomic_concat/3, 432, 433 put_code/1, 345, 351, 352
atomic_list_concat/2, 428, 434, 435 put_code/2, 64, 352, 380, 382
atomic_list_concat/3, 435 put_code/[1
attach_console/0, 866--868, 1134 2], 109
attr_portray_hook/2, 384, 770
attr_unify_hook/2, 762, 769 qcompile/1, 4, 111, 132, 156--158,
attribute_goals//1, 770, 773 820
attribute_goals/1, 771 qcompile/2, 158
attribute_goals/3, 762 qsave_program/1, 41, 130, 1182
attvar/1, 764 qsave_program/2, 4, 39, 41, 49, 81,
autoload/0, 49, 115, 1181, 1183, 104, 1180, 1181, 1187
1263 qsave_program/[1
autoload_path/1, 46 2], 18, 38, 41, 297, 896, 1153,
automaton/3, 1302 1163, 1183, 1185
automaton/8, 1303 quasi_quotation_syntax/1, 297, 1489
b_getval/2, 788, 790 quasi_quotation_syntax_error/1,q1490uasi_quotations _l_i_b_r_a_r_y, 1595
b_setval/2, 786, 787, 1606 query, 1624
backtracking, 1624 quiet, 18
bagof/3, 59, 568, 570, 571, 732,
1637 random _l_i_b_r_a_r_y, 556
bb_inf/3, 1322 random/1, 504, 1492
bb_inf/4, 1321 random/3, 1494, 1495
bb_inf/5, 1320 random_between/3, 1493
between/3, 472 random_float/0, 505
binding, 1624 random_member/2, 1502
bits random_perm2/4, 1501
64, 71 random_permutation/2, 1507, 1508
blackboard, 1236 random_property/1, 556, 557
blob/2, 182, 305 random_select/3, 1503, 1504
body, 1624 randseq/3, 1506
Boehm GC, 1170 randset/3, 1505
BOM, 65 rational
break/0, 20, 32, 41, 654, 809, 1134 number, 483
broadcast, 1236 rational trees, 59
broadcast _l_i_b_r_a_r_y, 1236 rational/1, 178, 509
broadcast/1, 1237, 1238 rational/3, 179, 483
broadcast_request/1, 1238 rationalize/1, 510
built-in predicate, 1624 rb_new/1, 41
Byte Order Mark, 65 rbtrees _l_i_b_r_a_r_y, 41
byte_count/2, 316, 338 RDF
call/1, 102, 186, 214, 222, 234, rdimemoryvusage,/742, 496
674, 688, 696, 698, 723, reachable/3, 1566
781, 1085, 1602 read/1, 41, 69, 304--306, 355, 391,
call/2, 186, 223 397, 400, 404, 457, 684,
call/3, 384 794, 1515, 1637
call/[2-8], 223 read/2, 337, 398
call_cleanup/2, 229, 231, 232, 335, read_clause/3, 58, 399, 684
1592, 1623 read_file_to_codes/3, 1514
call_cleanup/3, 232 read_file_to_terms/3, 1515
call_residue_vars/2, 785 read_from_atom/3, 431
call_shared_object_function/2, 910 read_from_chars/2, 1254
call_with_depth_limit/3, 228 read_history/6, 403
call_with_time_limit/2, 229 read_line_to_codes/2, 1510, 1511
callable/1, 186, 950, 1475 read_line_to_codes/3, 1510, 1511
cancel_halt/1, 128, 129, 657, 1157 read_link/3, 646
catch/3, 233--236, 400, 655, 696, read_pending_input/3, 382
825, 833, 834, 1591, 1604-- read_stream_to_codes/2, 1512, 1513
1606, 1637 read_stream_to_codes/3, 1513
ceil/1, 516 read_term/2, 41, 126, 145, 384,
ceiling/1, 515 400, 401, 403, 431, 1613
chain/2, 1306 read_term/3, 58, 384, 399--402,
char_code/2, 109, 425 468, 659, 1613
char_conversion/2, 41, 468, 469 read_term/[2
char_type/2, 57, 440, 447--450 3], 400
character set, 53 read_term_from_atom/3, 402
character_count/2, 316, 338, 339 read_term_from_chars/3, 1255
chdir/1, 651, 652 readutil _l_i_b_r_a_r_y, 83
check _l_i_b_r_a_r_y, 117, 297 reconsult, 110
check/0, 115, 1260, 1261 record _l_i_b_r_a_r_y, 1516
check_predicate_option/3, 1454 record/1, 1516, 1517
check_predicate_options/0, 1457 recorda/2, 270
chr _l_i_b_r_a_r_y, 806, 810 recorda/3, 59, 269, 271, 275, 294,
chr_constraint/1, 804, 818 786, 1121, 1122, 1125
chr_leash/1, 813 recorded/2, 274
chr_notrace/0, 809, 812 recorded/3, 273, 275, 1185
chr_option/2, 800, 818 recordz/2, 272
chr_show_store/1, 814 recordz/3, 59, 271, 275
chr_trace/0, 809, 811 redefine_system_predicate/1, 260,
chr_type/1, 805 1624
circuit/1, 1299 reexport/1, 110, 111, 739, 1619
clause, 1624 reexport/2, 110, 111, 740, 1619
clause/2, 169, 299, 300, 1183 registry, 67
clause/3, 266, 275, 300, 302, 1185 registry _l_i_b_r_a_r_y, 1518
clause/[2 registry_delete_key/1, 1523
3], 41 registry_get_key/2, 1519
clause_property/2, 114, 123, 297, registry_get_key/3, 1520
302, 1590 registry_set_key/2, 1521
close/1, 303, 309, 314 registry_set_key/3, 1522
close/2, 310 release(), 1070
close_dde_conversation/1, 709 reload_foreign_libraries/0, 905
close_shared_object/1, 909 reload_library_index/0, 45, 46, 49
clpfd _l_i_b_r_a_r_y, 741 rem/2, 493
clpqr _l_i_b_r_a_r_y, 1312 rename_file/2, 593, 636
code_type/2, 440, 446, 448, 449 repeat/0, 209, 213, 228, 229
collate, 454 representation_error/1, 1061
collation_key/2, 440, 455, 456, 599 require/1, 115, 1619
COM, 1067 reset_gensym/0, 1352
command line reset_gensym/1, 1351
arguments, 18 reset_profiler/0, 695
compare resource/3, 41, 1180, 1181, 1187,
language-specific, 454 1189, 1190
compare(), 1071 resource_error/1, 1066
compare/3, 59, 200, 566, 1119, 1623 retract, 1624
compile_aux_clauses/1, 110, 138 retract/1, 110, 118, 256, 257, 261,
compile_predicates/1, 284, 285 278, 284, 285, 297, 852
compiling/0, 132, 157 retract/2, 761
complement/2, 1560 retractall/1, 256, 257, 262
completion retractall_predicate_options/0, 1459
TAB, 85 rev/3, 725
compose/3, 1561 reverse/2, 255, 725, 1371
compound, 1624 rl_add_history/1, 1616
compound/1, 185 rl_read_history/1, 1618
concat_atom/3, 435 rl_read_init_file/1, 1615
constraint/3, 1529, 1530 rl_write_history/1, 1617
constraint/4, 1530 round/1, 506
constraint_add/4, 1531
consult/1, 11, 14, 44, 93, 110- same_file/2, 631, 633
-114, 117, 153, 156, 157, same_length/2, 1370
286 same_term/2, 421
context module, 1624 sandbox/safe_meta, 1202
context_module/1, 732, 754, 1091 scalar_product/4, 1280
convert_time/2, 41 scanl/4, 1216
convert_time/[2 scanl/5, 1217
8], 638 scanl/6, 1218
copy_file/2, 593 scanl/7, 1219
copy_predicate_clauses/2, 259 see/1, 303, 304, 320--322
copy_stream_data/2, 381, 382 seeing/1, 320, 321, 325
copy_stream_data/3, 317, 380 seek/4, 311, 315, 317
copy_term/2, 59, 203, 415, 417, seen/0, 327
420, 761, 774, 788 select(), 337
copy_term/3, 384, 770, 771, 773 select/3, 1358
copy_term_nat/2, 774 select/4, 1360
copysign/1, 500 select_option/3, 1398
cos/1, 525 select_option/4, 1399
cosh/1, 533 selectchk/3, 1359
count_atom_results/3, 752 selectchk/4, 1361
cputime/0, 550 serialize, 253
create_pool/1, 1548 serialized/2, 1295
create_prolog_flag/3, 41--43 set_breakpoint/4, 1602
crypt _l_i_b_r_a_r_y, 1635 set_end_of_stream/1, 379
csv//1, 1331 set_input/1, 304, 318, 322, 330
csv//2, 1332 set_locale/1, 444
csv_read_file/2, 1329 set_module/1, 742, 759
csv_read_file/3, 1330 set_output/1, 304, 323, 331
csv_read_file_row/3, 1333 set_prolog_flag/2, 30, 40--43, 110,
csv_write_file/2, 1334 475
csv_write_file/3, 1335 set_prolog_IO/3, 304, 319
csv_write_stream/3, 1336 set_prolog_stack/2, 19, 67, 675,
ctype _l_i_b_r_a_r_y, 446 704, 705, 825
cumulative/1, 1300 set_random/1, 504, 556, 557
cumulative/2, 1301 set_stream/2, 64, 304, 306, 311,
current_arithmetic_function/1, 558 318, 319, 337, 373, 444
current_atom/1, 290 set_stream_position/2, 311, 315, 317
current_blob/2, 291, 1068 set_url_encoding/2, 1575
current_char_conversion/2, 468, 469 setarg/3, 108, 415, 417, 418, 420,
current_flag/1, 293 421, 765, 794, 1516
current_foreign_library/2, 904, 1181 setenv/2, 597
current_format_predicate/2, 586 setlocale/1, 825
current_functor/2, 292 setlocale/3, 456, 599
current_input/1, 126, 304, 325, 332 setof/3, 59, 571, 732, 1637
current_key/1, 273, 294 setrand/1, 1496
current_locale/1, 445 setup_call_catcher_cleanup/4, 230
current_module/1, 295, 757 setup_call_cleanup/3, 229, 231, 829,
current_op/3, 466 857, 858
current_option_arg/2, 1455 shadow_price/3, 1536
current_output/1, 304, 326, 333 shared, 1624
current_predicate/1, 223, 295--297 shell/0, 595, 600
current_predicate/2, 295, 296 shell/1, 79, 166, 594, 600
current_predicate_option/3, 1453 shell/2, 593, 601
current_predicate_options/3, 1456 shell/[0-2], 597
current_prolog_flag/2, 18, 40, 41, shell/[1
45, 50, 54, 111, 400, 714, 2], 593
895, 1194, 1624 shell_register_dde/6, 1525
current_signal/3, 250, 251 shell_register_file_type/4, 1524,
current_stream/3, 312 1525
current_thread_pool/1, 1545 shell_register_prolog/1, 1526
cyclic terms, 59 shlib _l_i_b_r_a_r_y, 1637
cyclic_term/1, 59, 188, 189 show_profile/1, 692, 693
daemon, 1236 sign/1,s499implex _l_i_b_r_a_r_y, 1527
date_time_stamp/2, 615 sin/1, 524
date_time_value/3, 611, 616 singleton, 1624
day_of_the_week/2, 621 variable, 58
DCG, 110, 253 sinh/1, 532
dcg_translate_rule/2, 135, 139 size_file/2, 637
dcg_translate_rule/4, 145 size_nb_set/2, 1391
dde_current_connection/2, 717 skip/1, 374, 375
dde_current_service/2, 716 skip/2, 375
dde_execute/2, 711 sleep/1, 722
dde_poke/4, 712 socket _l_i_b_r_a_r_y, 337
dde_register_service/2, 714 Solaris, 832
dde_request/3, 710 solution, 1624
dde_unregister_service/1, 715 sort/2, 563, 564, 566, 571
debug _l_i_b_r_a_r_y, 105 source_exports/2, 1619, 1622
debug/0, 32, 41, 236, 673, 675, source_file/1, 122
676, 704, 869, 1134, 1602, source_file/2, 114, 123, 157, 297
1604 source_file_property/2, 111, 114,
debug/1, 1341 124
debug/3, 239, 1345 source_location/2, 126, 127
debug_message_context/1, 1344 split_string/4, 435
debugging spy/1, 32, 41, 44, 95, 96, 106,
exceptions, 236 108, 678, 736, 873, 874,
debugging/0, 44, 673, 677, 1609 1609, 1637
debugging/1, 1338, 1339 sqrt/1, 523
debugging/2, 1340 stack
default_module/2, 297, 743, 744 memory management, 68
del_attr/2, 767, 776 stamp_date_time/3, 611, 614, 615
del_attrs/1, 779 startup file, 14
del_edges/3, 1556 statistics _l_i_b_r_a_r_y, 689
del_vertices/3, 1554 statistics/0, 239, 687
delete/3, 1363 statistics/2, 550, 686, 835
delete_directory/1, 650 stream_pair/3, 305, 314, 318
delete_file/1, 593, 635, 648 stream_position_data/3, 126, 311,
delete_import_module/2, 743, 745, 316, 400, 1613
746, 760 stream_property/2, 65, 306, 311,
derive_predicate_options/0, 1458 315--318, 400
derived_predicate_options/1, 1461 stream_to_lazy_list/2, 1444
derived_predicate_options/3, 1460 string/1, 183, 184, 582
deserialize, 253 string_code/3, 461
deterministic/1, 229, 1592 string_codes/2, 459
Development environment, 75 string_concat/3, 462
dialect.pl _l_i_b_r_a_r_y, 1619 string_length/2, 460
dif _l_i_b_r_a_r_y, 784 strip_module/3, 732, 752, 755, 760
dif/2, 59, 192, 783, 784 structure, 1624
directory_file_path/3, 631 style_check/1, 58, 69, 111, 287,
directory_files/2, 643 684
discontiguous/1, 114, 239, 283, sub_atom/5, 438, 461, 463
287, 684 sub_atom_icasechk/3, 439
display/1, 577, 1002 sub_string/5, 461, 463
div/2, 495 subset/2, 1384
do_not_use/1, 738 subsumes_chk/2, 282
domain/2, 762 subsumes_term/2, 59, 201, 205
domain_error/2, 1063 subtract/3, 1385
downcase_atom/2, 447, 450, 451 succ/2, 473
dump/3, 1323, 1327 succeed, 1624
duplicate_term/2, 59, 415, 418, sum/3, 1279
420, 789 sum_list/2, 1376
dwim_match/2, 298, 719, 720 sup/2, 1317
dwim_match/3, 720 swi/pce_profile _l_i_b_r_a_r_y, 689
dwim_predicate/2, 298 swi_edit _l_i_b_r_a_r_y, 167
dynamic predicate, 1624 swritef/2, 579
dynamic/1, 41, 108, 114, 256, 262, swritef/3, 335, 574, 578
283--285, 297, 753, 851, syntax_error/1, 1441
852, 1183, 1262
e/0, 548 TABcompletion, 85
edges/2, 1552 tab/1, 353
edit/0, 41, 161 tab/2, 354
edit/1, 41, 44, 85, 88, 93, 106, tan/1, 526
114, 117, 159--163, 165, tanh/1, 534
736, 1262, 1637 tdebug/0, 870, 874
edit_source/1, 166 tdebug/1, 869, 870, 873
editor _c_l_a_s_s, 84, 89 tell/1, 303, 304, 320, 321, 323,
element/3, 1296 324
elif/1, 148 telling/1, 320, 321, 326
else/0, 149 term, 1624
Emacs, 23 term//1, 335
emacs/[0 term_attvars/2, 775
1], 88 term_expansion/2, 44, 110, 132--
emacs/prolog_colour _l_i_b_r_a_r_y, 92 136, 146, 157, 659, 806,
empty_assoc/1, 1224 1623
empty_nb_set/1, 1387 term_expansion/4, 110, 144
encoding/1, 64, 116 term_hash/2, 59, 62, 279--282
endif/0, 150 term_hash/4, 62, 279, 281
ensure_loaded/1, 34, 110, 113, 729 term_subsumer/3, 206
entailed/1, 1315 term_to_atom/2, 335, 430, 1040
environment/2, 1471 term_variables/2, 59, 400, 413, 414
epsilon/0, 549 term_variables/3, 413, 414
erase/1, 266, 269, 275, 300 terms
erf/1, 545 cyclic, 59
erfc/1, 546 thread _l_i_b_r_a_r_y, 41
error _l_i_b_r_a_r_y, 173, 1516 thread_at_exit/1, 657, 825, 831, 883
eval/1, 551 thread_create/3, 825, 828, 831, 891
eval_license/0, 1629--1631 thread_create_in_pool/4, 825, 1547
exception/3, 786, 1605, 1606 thread_detach/1, 825, 828
exceptions thread_exit/1, 827, 829, 834
debugging, 236 thread_get_message/1, 840, 845
exclude/3, 1205 thread_get_message/2, 844--846
exists_directory/1, 634 thread_get_message/3, 841, 846
exists_file/1, 41, 630 thread_initialization/1, 786, 830
exists_source/1, 1619, 1621 thread_join/2, 825, 827, 829, 834
exp/1, 540 thread_local/1, 242, 284, 297, 851,
expand_answer/2, 659, 660 852
expand_file_name/2, 41, 111, 597, thread_message_hook/3, 242
600, 639, 640, 643, 644 thread_peek_message/1, 840, 841, 847
expand_file_search_path/2, 120 thread_peek_message/2, 846, 847
expand_goal/2, 41, 133--137, 147 thread_pool_create/3, 1543
expand_goal/4, 141 thread_pool_destroy/1, 1544
expand_query/4, 659 thread_pool_property/2, 1546
expand_term/2, 133--136, 139, 253, thread_property/2, 827, 828, 831,
1517 834
expand_term/4, 143 thread_self/1, 41, 826, 828, 831,
expects_dialect/1, 111, 126, 1619, 839
1620 thread_send_message/2, 839, 842, 843
explain _l_i_b_r_a_r_y, 1637 thread_setconcurrency/2, 41, 832
explain/1, 28 thread_signal/2, 229, 850, 861,
explain/2, 29 869, 1114, 1160
export/1, 288, 749--751 thread_statistics/3, 834, 835
export_list/2, 750 threads/0, 864
exported predicate, 1624 throw/1, 32, 59, 233--235, 248,
fact, 1624 252,11829,08834,, 1849,11850,0, 1604--1606
fail/0, 137, 210 time/1, 550, 688
false/0, 211 time_file/2, 638
fd_dom/2, 1311 tmp_file/2, 647, 648
fd_inf/2, 1308 tmp_file_stream/3, 647, 648
fd_size/2, 1310 tnodebug/0, 872
fd_sup/2, 1309 tnodebug/1, 871, 874
fd_var/1, 1307 told/0, 328
file_base_name/2, 632 top_sort/2, 1563
file_directory_name/2, 631, 632 top_sort/3, 1564
file_name_extension/3, 642 tprofile/1, 875, 876
file_name_to_url/2, 1579, 1580 trace/0, 32, 41, 95, 96, 106, 667,
file_of_label/2, 737 673, 811, 812, 850, 1134,
file_search_path/2, 14, 18, 41, 45, 1602, 1604
49, 80, 103, 111, 118, 119, trace/1, 41, 672
121, 126, 1129, 1163, 1186, trace/2, 673
1189, 1192 tracing/0, 668
fileerrors/2, 41 transformation
filesex _l_i_b_r_a_r_y, 593, 631 of program, 133
find_chr_constraint/1, 815 transitive_closure/2, 1565
findall/3, 59, 203, 209, 568, 569, transparent, 1624
573, 761, 1637 transportation/4, 1537
findall/4, 569 transpose/2, 1304, 1557
flag/3, 277, 293, 418 transpose_pairs/2, 1434
flag:access_level, 41 trim_stacks/0, 701, 703, 704
flag:address_bits, 41 true/0, 41, 137, 212, 228
flag:agc_margin, 41 truncate/1, 513
flag:allow_variable_name_as_functor, tspy/1, 867, 874
41 tspy/2, 873
flag:apple, 41 tty_get_capability/3, 588, 590, 591
flag:arch, 41 tty_goto/2, 589
flag:argv, 41 tty_put/2, 590
flag:associated_file, 41 tty_size/2, 591
flag:autoload, 41 ttyflush/0, 357, 577
flag:backquoted_string, 41 tuples_in/2, 1294
flag:bounded, 41 type_error/2, 248, 1062, 1064
flag:break_level, 41
flag:c_cc, 41 UCS, 63
flag:c_cflags, 41 ugraph _l_i_b_r_a_r_y, 1549
flag:c_ldflags, 41 ugraph_union/3, 1562
flag:c_libplso, 41 ugraphs.pl _l_i_b_r_a_r_y, 1549
flag:c_libs, 41 Unicode, 63
flag:char_conversion, 41 unifiable/3, 59, 201, 207
flag:character_escapes, 41 unify, 1624
flag:colon_sets_calling_context, 41 unify_with_occurs_check/2, 41, 59,
flag:color_term, 41 201, 202
flag:compile_meta_arguments, 41 union/3, 1383
flag:compiled_at, 41 unix, 41
flag:console_menu, 41 unix/1, 600
flag:cpu_count, 41 unknown/2, 683, 1194
flag:dde, 41 unlisten/1, 1241
flag:debug, 41 unlisten/2, 1242
flag:debug_on_error, 41 unlisten/3, 1243
flag:debugger_print_options, 41 unload_file/1, 111, 125
flag:debugger_show_context, 41 unload_foreign_library/1, 902
flag:dialect, 41 unload_foreign_library/2, 903
flag:double_quotes, 41 unsetenv/1, 597, 598
flag:editor, 41 upcase_atom/2, 447, 451
flag:emacs_inferior_process, 41 update view, 278, 1624
flag:encoding, 41 URL, 603
flag:executable, 41 url _l_i_b_r_a_r_y, 1393
flag:exit_status, 41 url_iri/2, 1576, 1577
flag:file_name_variables, 41 use_foreign_library/1, 130, 607,
flag:gc, 41 900, 1181
flag:generate_debug_info, 41 use_foreign_library/2, 901
flag:gmp_version, 41 use_module/1, 41, 44, 80, 110, 111,
flag:gui, 41 114, 153, 727--730, 739,
flag:history, 41 747, 748, 1183, 1619
flag:home, 41 use_module/2, 45, 110, 111, 728--
flag:hwnd, 41 730, 740, 1619
flag:integer_rounding_function, 41 use_module/[1
flag:iso, 41 2], 34, 93, 110, 111, 113, 749,
flag:large_files, 41 750, 1624
flag:last_call_optimisation, 41 user _l_i_b_r_a_r_y, 1637
flag:max_arity, 41 user profile file, 14
flag:max_integer, 41 UTF-8, 63
flag:max_tagged_integer, 41 utf-8, 109
flag:min_integer, 41
flag:min_tagged_integer, 41 valgrind, 1177
flag:occurs_check, 41 var/1, 174, 764, 941
flag:open_shared_object, 41 var_number/2, 412
flag:optimise, 41 variable, 1624
flag:os_argv, 41 anonymous, 1624
flag:pid, 41 variable_value/3, 1538
flag:pipe, 41 variant, 203
flag:prompt_alternatives_on, 41 variant_sha1/2, 282, 1635
flag:qcompile, 41 varnumbers/2, 1583
flag:readline, 41 varnumbers/3, 1584
flag:report_error, 41 verbose, 18
flag:resource_database, 41 version/0, 246, 247
flag:runtime, 41 version/1, 246, 247
flag:sandboxed_load, 41 vertices/2, 1551
flag:saved_program, 41 vertices_edges_to_ugraph/3, 1550
flag:shared_object_extension, 41 view
flag:shared_object_search_path, 41 update, 1624
flag:signals, 41 visible/1, 682, 1598
flag:stream_type_check, 41 vm_list/1, 1135
flag:system_thread_id, 41 volatile/1, 297, 852, 1184
flag:timezone, 41
flag:toplevel_print_anon, 41 wait_for_input/3, 318, 337
flag:toplevel_print_factorized, 41 when _l_i_b_r_a_r_y, 783
flag:toplevel_print_options, 41 when/2, 59, 783
flag:toplevel_prompt, 41 wildcard_match/2, 721
flag:toplevel_var_size, 41 will_shell/2, 601
flag:trace_gc, 41 win_add_dll_directory/1, 607
flag:tty_control, 41 win_add_dll_directory/2, 607--609
flag:unix, 41 win_exec/2, 593, 601--603
flag:unknown, 41 win_folder/2, 14, 18, 606
flag:user_flags, 41 win_has_menu/0, 625
flag:verbose, 41 win_insert_menu/2, 625--627
flag:verbose_autoload, 41 win_insert_menu_item/4, 625, 627
flag:verbose_file_search, 41 win_registry_get_value/3, 605
flag:verbose_load, 41 win_remove_dll_directory/1, 608, 609
flag:version, 41 win_shell/2, 593, 603, 604, 1394
flag:version_data, 41 win_window_pos/1, 624
flag:version_git, 41 window_title/2, 623
flag:warn_override_implicit_import, windows, 41
41 with_mutex/2, 849, 857, 858, 877
flag:windows, 41 with_output_to/2, 304, 305, 331,
flag:write_attributes, 41 335, 383, 430, 453, 583, 617
flag:write_help_with_overstrike, 41 with_output_to_chars/2, 1257
flag:xpce, 41 with_output_to_chars/3, 1258
flag:xpce_version, 41 with_output_to_chars/4, 1259
flatten/2, 729, 1373 with_quasi_quotation_input/3, 1487
float/1, 177, 508 working_directory/2, 16, 600, 640,
float_fractional_part/1, 511 651, 652
float_integer_part/1, 512 write(), 1072
floor/1, 514 write/1, 41, 59, 69, 304, 389, 394,
flush_output/0, 355 577, 582, 962, 1002, 1072
flush_output/1, 240, 356, 382 write/2, 390
flush_output/[0 write_canonical/1, 384, 387, 582
1], 306, 357 write_canonical/2, 388, 411, 962
foldl/4, 1212 write_length/3, 386, 436
foldl/5, 1213 write_term/2, 32, 41, 384--387,
foldl/6, 1214 400, 411, 430, 457, 577,
foldl/7, 1215 582, 770
forall/2, 573 write_term/3, 41, 44, 384, 385,
foreach/2, 573, 1200 410, 436
format/1, 240, 574, 581 write_to_chars/2, 1248
format/2, 56, 306, 440, 574, write_to_chars/3, 1249
581--583 writef/1, 574, 576
format/3, 239, 240, 243, 248, 304, writef/2, 7, 54, 383, 574, 576--578
335, 383, 430, 440, 453, writeln/1, 393
483, 484, 574, 582, 583, 585 writeq/1, 391, 577, 582
format/[1 writeq/2, 392, 962
2], 383, 1637 www_form_encode/2, 1573, 1574
format/[2 www_open_url/1, 1394
3], 54
format_predicate/2, 585 xor/2, 521
format_time/3, 440, 585, 599, 617 xref_built_in/1, 1483
format_time/4, 617, 618 xref_called/3, 1480
format_to_chars/3, 1246 xref_clean/1, 1478
format_to_chars/4, 1247 xref_current_source/1, 1477
free_variables/4, 1201 xref_defined/3, 1479
freeze/2, 780, 781, 783 xref_exported/2, 1481
frozen/2, 782 xref_module/2, 1482
functor, 1624 xref_source/1, 1476
functor/3, 185, 296, 407, 794 YAP
garbage_collect/0, 701 prolog, 1619
garbage_collect_atoms/0, 702, 1149
garbage_collect_clauses/0, 60, 151, zcompare/3, 1305
152, 155
garbage_collect_heap/0, 686
gcd/2, 497
gdebug/0, 99
gen_assoc/3, 1225
gen_nb_set/2, 1390
gen_state/1, 1532
gensym/2, 1350
get/1, 366, 367
get/2, 367
get0/1, 306, 364--367
get0/2, 365, 367
get_assoc/3, 1226
get_assoc/5, 1227
get_attr/3, 766, 776
get_attrs/2, 777, 778
get_byte/1, 358, 364
get_byte/2, 359, 363
get_byte/[1
2], 109
get_char/1, 360, 362
get_char/2, 363
get_char/[1
2], 109
get_code/1, 109, 304, 360, 364,
374, 376
get_code/2, 64, 317, 361, 363, 365,
380, 382
get_code/[1
2], 109
get_single_char/1, 18, 41, 376
get_time/1, 613, 638, 686, 846
getenv/2, 596, 597, 1394
getrand/1, 1497
global_cardinality/2, 1297
global_cardinality/3, 1298
global_url/3, 1568
GMP, 483
GNU-Emacs, 23
goal, 1624
goal_expansion/2, 110, 133, 134,
136--138, 146, 1620, 1623,
1637
goal_expansion/4, 110, 142
ground/1, 59, 187, 280, 945
group_pairs_by_key/2, 1433
gspy/1, 100
gtrace/0, 98, 867
guitracer/0, 95--97, 106, 666, 670
gxref/0, 28, 103, 730, 1183, 1475
halt/0, 32, 128, 656, 1637
halt/1, 41, 656, 657, 1134, 1637
halt/[0
1], 128
hashing, 1624
head, 1624
help/0, 25, 44, 1187, 1610
help/1, 25, 26, 41, 44, 1610
hooks, 44
html_write _l_i_b_r_a_r_y, 1485
http/html_write _l_i_b_r_a_r_y, 1595
http/http_error _l_i_b_r_a_r_y, 236
http/http_header _l_i_b_r_a_r_y, 617
http/http_load _l_i_b_r_a_r_y, 111, 1612
http_location/2, 1570
http_open/3, 248
http_timestamp/2, 617
IA32, 73
IDE, 75
if
directive, 146
if/1, 126, 147
ignore/1, 227, 696, 825
immediate
update view, 278
import/1, 750, 751
import_module/2, 295, 743--745
imported predicate, 1624
in/2, 1272
in_pce_thread/1, 889, 890
in_pce_thread_sync/1, 890
include/1, 110, 111, 114, 123, 124,
302
include/3, 1204
indexing, 1624
term-hashes, 279
indomain/1, 1274
inf/2, 1316
infinite trees, 59
initialization/1, 110, 130, 131,
154, 786, 830, 896, 1153,
1185
initialization/2, 131
ins/2, 1273
instance/2, 276
instantiation_error/1, 1059
integer, 1624
unbounded, 483
integer/1, 176, 507
interactor/0, 318, 866
internationalization, 63
interpreted, 1624
intersection/3, 1382
is/2, 482, 483, 508, 818
is_absolute_file_name/1, 641
is_absolute_url/1, 1569
is_assoc/1, 1235
is_list/1, 560
is_ordset/1, 1409
is_set/1, 1380
is_stream/1, 313
ISO Latin 1, 53
Java, 1067
jitindex, 60
join_threads/0, 865
keysort/2, 565, 566
label/1, 1275
labeling/2, 1276
last/2, 1368
lazy_list_character_count/1, 1443
lazy_list_location//1, 1442
leash/1, 32, 681, 682, 813, 1598
length/2, 562
lex_chain/1, 1293
lgamma/1, 544
library(apply_macros) _l_i_b_r_a_r_y, 110
library_directory/1, 45, 49, 118
license/1, 1632
license/2, 1631, 1632
line_count/2, 316, 318, 340, 589
line_position/2, 316, 318, 341, 589
list_autoload/0, 1261--1263
list_debug_topics/0, 1343
list_redefined/0, 1261, 1264
list_to_assoc/2, 1228
list_to_ord_set/2, 1412
list_to_set/2, 1381
list_undefined/0, 41, 117, 1261--
1263
listen/2, 1239, 1240
listen/3, 1240--1243
listening/3, 1244
listing/0, 170
listing/1, 32, 169, 170
lists _l_i_b_r_a_r_y, 559
load_file/2, 111
load_files/2, 41, 44, 64, 110--112,
124, 125, 153, 154, 158,
684, 730, 1475, 1611, 1612,
1621, 1637
load_foreign_library/1, 130, 898,
907, 1161, 1186
load_foreign_library/2, 899
load_foreign_library/[1
2], 119
load_hotfixes/1, 111
locale, 454
locale_create/3, 441, 443
locale_destroy/1, 441, 442
locale_property/2, 443
locale_sort/2, 440, 455, 456, 599
log/1, 538
log10/1, 539
logical
update view, 278
lsb/1, 553
MacOS, 41
make/0, 4, 41, 45, 49, 86, 93, 106,
111, 114, 117, 124, 151
make_directory/1, 593, 649
make_library_index/1, 45, 47
make_library_index/2, 45, 48
make_library_index/[1
2], 49
manpce/0, 67
map_assoc/2, 1229
map_assoc/3, 1230
map_list_to_pairs/3, 1435
maplist/2, 573, 1208
maplist/3, 731, 752, 1209
maplist/4, 1210
maplist/5, 1211
maplist_/3, 731, 752
max/2, 501
max_assoc/3, 1231
max_list/2, 1377
max_member/2, 1374
max_var_number/3, 1585
maximize/1, 1319
maximize/3, 1533, 1534
maybe/0, 1498
maybe/1, 1499
maybe/2, 1500
member/2, 32, 229, 561, 640, 730,
1354, 1637
memberchk/2, 561
memory
layout, 68
merge_options/3, 1400
message
service, 1236
message_hook/3, 238--242, 248, 704,
1637
message_property/2, 41, 243
message_queue_create/1, 838, 842,
844
message_queue_create/2, 843, 848
message_queue_destroy/1, 844, 845
message_queue_property/2, 834, 848
message_to_string/2, 239, 241, 245
meta-predicate, 1624
meta_options/3, 730, 1401
meta_predicate/1, 41, 136, 186,
297, 731, 732, 752, 760,
1091, 1139, 1183
min/2, 502
min_assoc/3, 1232
min_list/2, 1378
min_member/2, 1375
minimize/1, 1318
minimize/3, 1534
mod/2, 492
module, 1624
contex, 1624
module transparent, 1624
module/1, 41, 110, 288, 736, 737,
825
module/2, 134, 464, 465, 725--727,
730, 741, 749, 760
module/3, 727
module_property/2, 758, 759
module_transparent/1, 297, 732,
735, 753, 760, 1091, 1624
msb/1, 552
msort/2, 564
multifile/1, 41, 114, 283, 286,
297, 1262, 1608, 1624
must_be/2, 1516
mutex_create/1, 854, 857, 858
mutex_create/2, 855, 862
mutex_destroy/1, 856
mutex_lock/1, 858, 859
mutex_property/2, 862
mutex_statistics/0, 836
mutex_trylock/1, 859
mutex_unlock/1, 860
mutex_unlock_all/0, 861
my_compare/3, 1623
mypred/1, 738
name/1, 731
name/2, 422, 429
name_of/2, 1240
nb_current/2, 792
nb_delete/1, 793
nb_getval/2, 790
nb_linkarg/3, 418--420
nb_linkval/2, 419, 420, 791, 794
nb_set _l_i_b_r_a_r_y, 1386
nb_set_to_list/2, 1392
nb_setarg/3, 108, 417--420, 1386,
1516
nb_setval/2, 418, 420, 786, 789,
791, 794, 1606
neck, 1624
neighbors/3, 1559
neighbours/3, 1558, 1559
nextto/3, 1362
nl/0, 343
nl/1, 344
nl/[0
1], 577
nodebug/0, 675, 676, 1598
nodebug/1, 1342
noguitracer/0, 95, 97, 106, 671
nonvar/1, 175
noprofile/1, 696
noprotocol/0, 664
normalize_space/2, 453
nospy/1, 32, 44, 679, 874, 1609
nospyall/0, 44, 680, 1609
not/1, 225, 1637
notrace/0, 669, 811, 812
notrace/1, 674
nth0/3, 1364
nth0/4, 1366
nth1/3, 1365
nth1/4, 1367
nth_clause/3, 297, 301, 302, 1590
number
rational, 483
number/1, 180
number_chars/2, 109, 426, 427
number_codes/2, 109, 422, 427--429
number_to_chars/2, 1252
number_to_chars/3, 1253
numbervars/1, 1582
numbervars/3, 384, 410--412
numbervars/4, 387, 410, 411
numbervars/[3
4], 59
numlist/3, 1379
objective/2, 1535
occurs_check, 202
on_signal/3, 250, 251
once/1, 226, 227, 229, 335, 655,
674, 691, 692, 857, 1096
online_help _l_i_b_r_a_r_y, 1637
op/3, 283, 384, 465, 466, 741
open/3, 41, 303, 305, 307
open/4, 64, 65, 109, 306, 307, 311,
317, 318, 378, 444, 1514,
1515
open_chars_stream/2, 1256
open_dde_conversation/3, 708
open_null_stream/1, 308, 317
open_resource/3, 1180, 1187, 1190
open_shared_object/2, 41, 608, 895,
907, 908
open_shared_object/3, 907, 908
operand, 1624
operator, 1624
and modules, 464
opt_arguments/3, 1404
opt_help/2, 1407
opt_parse/4, 1405
opt_parse/5, 1406
option _l_i_b_r_a_r_y, 1516
option/2, 1397
option/3, 1396
ord_add_element/3, 1419
ord_del_element/3, 1420
ord_disjoint/2, 1414
ord_empty/1, 1410
ord_intersect/2, 1413
ord_intersect/3, 1415
ord_intersection/2, 1416
ord_intersection/3, 1417
ord_intersection/4, 1418
ord_list_to_assoc/2, 1233
ord_memberchk/2, 1422
ord_selectchk/3, 1421
ord_seteq/2, 1411
ord_subset/2, 1423
ord_subtract/3, 1424
ord_symdiff/3, 1428
ord_union/2, 1425
ord_union/3, 1426
ord_union/4, 1427
pack_info/1, 1464
pack_install/1, 1467
pack_install/2, 1468
pack_list/1, 1466
pack_list_installed/0, 1463
pack_property/2, 1474
pack_rebuild/0, 1470
pack_rebuild/1, 1469
pack_remove/1, 1473
pack_search/1, 1465
pack_upgrade/1, 1472
pairs _l_i_b_r_a_r_y, 565
pairs_keys/2, 1432
pairs_keys_values/3, 1430
pairs_values/2, 1431
parse_time/2, 619
parse_time/3, 619, 620
parse_url/2, 1571
parse_url/3, 1572
parse_url_search/2, 1578
partition/4, 1206
partition/5, 1207
pce_dispatch/1, 888, 891
pce_thread/1, 890
pce_xref _l_i_b_r_a_r_y, 102
peek_byte/1, 368
peek_byte/2, 369
peek_byte/[1
2], 109
peek_char/1, 372
peek_char/2, 373
peek_char/[1
2], 109
peek_code/1, 370
peek_code/2, 371
peek_code/[1
2], 109
permission_error/3, 1065
permutation/2, 1372
phrase/2, 253, 254
phrase/3, 253, 255, 732
phrase_from_file/2, 1438
phrase_from_file/3, 1439
phrase_from_quasi_quotation/2, 1488
phrase_from_stream/2, 1440
pi/0, 547
PL_abort_hook(), 1145
PL_abort_unhook(), 1146
PL_action(), 1134
PL_agc_hook(), 1149
PL_atom_chars(), 934
PL_atom_nchars(), 989
PL_atom_wchars(), 992
PL_backtrace(), 1135
PL_blob_data(), 1079
PL_BLOB_NOCOPY, 1068
PL_BLOB_TEXT, 1068
PL_BLOB_UNIQUE, 1068
PL_call(), 1096
PL_call_predicate(), 1095
PL_chars_to_term(), 1040
PL_cleanup(), 1157
PL_cleanup_fork(), 1158
PL_clear_exception(), 1111
PL_close_foreign_frame(), 1099
PL_close_query(), 1094
PL_compare(), 1119
PL_cons_functor(), 1019
PL_cons_functor_v(), 1020
PL_cons_list(), 1021
PL_context(), 1103
PL_copy_term_ref(), 916
PL_create_engine(), 885
PL_cut_query(), 1093
PL_CYCLIC_TERM, 1001
PL_destroy_engine(), 886
PL_discard_foreign_frame(), 1100
PL_dispatch_hook(), 1144
PL_domain_error(), 1063
PL_end_stubborn_change(), 1175
PL_erase(), 1124
PL_erase_external(), 1127
PL_exception(), 1110
PL_existence_error(), 1064
PL_exit_hook(), 1148
PL_fail(), 923
PL_foreign_context(), 928
PL_foreign_context_address(), 929
PL_foreign_control(), 927
PL_free(), 1169
PL_functor_arity(), 937
PL_functor_name(), 936
PL_get_arg(), 974
PL_get_atom(), 959
PL_get_atom_chars(), 960
PL_get_atom_ex(), 1044
PL_get_atom_nchars(), 977
PL_get_blob(), 1078
PL_get_bool(), 968
PL_get_bool_ex(), 1050
PL_get_char_ex(), 1052
PL_get_chars(), 962
PL_get_file_name(), 1129
PL_get_file_nameW(), 1130
PL_get_float(), 970
PL_get_float_ex(), 1051
PL_get_functor(), 971
PL_get_head(), 998
PL_get_int64(), 966
PL_get_int64_ex(), 1047
PL_get_integer(), 964
PL_get_integer_ex(), 1045
PL_get_intptr(), 967
PL_get_intptr_ex(), 1048
PL_get_list(), 997
PL_get_list_chars(), 963
PL_get_list_ex(), 1054
PL_get_list_nchars(), 978
PL_get_long(), 965
PL_get_long_ex(), 1046
PL_get_module(), 973
PL_get_mpq(), 1082
PL_get_mpz(), 1081
PL_get_name_arity(), 972
PL_get_nchars(), 979
PL_get_nil(), 1000
PL_get_nil_ex(), 1055
PL_get_pointer(), 969
PL_get_pointer_ex(), 1053
PL_get_signum_ex(), 1116
PL_get_size_ex(), 1049
PL_get_string_chars(), 961
PL_get_tail(), 999
PL_get_wchars(), 993
PL_halt(), 1159
PL_handle_signals(), 1115
PL_initialise(), 1153
PL_install_readline(), 1155
PL_instantiation_error(), 1059
PL_is_acyclic(), 957
PL_is_atom(), 946
PL_is_atomic(), 955
PL_is_blob(), 1075
PL_is_callable(), 950
PL_is_compound(), 951
PL_is_float(), 949
PL_is_functor(), 952
PL_is_ground(), 945
PL_is_initialised(), 1154
PL_is_integer(), 948
PL_is_list(), 953
PL_is_number(), 956
PL_is_pair(), 954
PL_is_string(), 947
PL_is_variable(), 944
PL_license(), 1633
PL_LIST, 1001
PL_malloc(), 1167
PL_malloc_atomic(), 1171
PL_malloc_atomic_uncollectable(),
1173
PL_malloc_stubborn(), 1174
PL_malloc_uncollectable(), 1172
PL_module_name(), 1105
PL_new_atom(), 931
PL_new_atom_nchars(), 988
PL_new_atom_wchars(), 991
PL_new_functor(), 935
PL_new_module(), 1106
PL_new_term_ref(), 914
PL_new_term_refs(), 915
PL_next_solution(), 1092
PL_NOT_A_LIST, 1001
PL_on_halt(), 1147
PL_open_foreign_frame(), 1098
PL_open_query(), 1091
PL_PARTIAL_LIST, 1001
PL_permission_error(), 1065
PL_pred(), 1087
PL_predicate(), 1088
PL_predicate_info(), 1089
PL_put_atom(), 1005
PL_put_atom_chars(), 1007
PL_put_atom_nchars(), 980
PL_put_blob(), 1077
PL_put_bool(), 1006
PL_put_float(), 1014
PL_put_functor(), 1015
PL_put_int64(), 1012
PL_put_integer(), 1011
PL_put_list(), 1016
PL_put_list_chars(), 1010
PL_put_list_nchars(), 983
PL_put_list_ncodes(), 982
PL_put_nil(), 1017
PL_put_pointer(), 1013
PL_put_string_chars(), 1008
PL_put_string_nchars(), 981, 1009
PL_put_term(), 1018
PL_put_variable(), 1004
PL_query(), 1137
PL_quote(), 1042
PL_raise(), 1114
PL_raise_exception(), 1108
PL_realloc(), 1168
PL_record(), 1122
PL_record_external(), 1125
PL_recorded(), 1123
PL_recorded_external(), 1126
PL_register_atom(), 939
PL_register_extensions(), 1142
PL_register_extensions_in_module(),
1141
PL_register_foreign(), 1140
PL_register_foreign_in_module(), 1139
PL_representation_error(), 1061
PL_reset_term_refs(), 917
PL_resource_error(), 1066
PL_retry(), 925
PL_retry_address(), 926
1672
|