/usr/share/pyshared/Pyrex/Compiler/Nodes.py is in python-pyrex 0.9.8.5-2ubuntu2.
This file is owned by root:root, with mode 0o644.
The actual contents of the file can be viewed below.
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# Pyrex - Parse tree nodes
#
import string, sys
import Code
from Errors import error, InternalError
import Naming
import PyrexTypes
from PyrexTypes import py_object_type, c_int_type, error_type, \
CTypedefType, CFuncType
from Symtab import ModuleScope, LocalScope, \
StructOrUnionScope, PyClassScope, CClassScope
from Pyrex.Utils import open_new_file, replace_suffix
import Options
from DebugFlags import debug_disposal_code
class Node:
# pos (string, int, int) Source file position
# is_name boolean Is a NameNode
# is_literal boolean Is a ConstNode
is_name = 0
is_literal = 0
def __init__(self, pos, **kw):
self.pos = pos
self.__dict__.update(kw)
gil_message = "Operation"
def gil_check(self, env):
if env.nogil:
self.gil_error()
def gil_error(self):
error(self.pos, "%s not allowed without gil" % self.gil_message)
#
# There are 3 phases of parse tree processing, applied in order to
# all the statements in a given scope-block:
#
# (1) analyse_declarations
# Make symbol table entries for all declarations at the current
# level, both explicit (def, cdef, etc.) and implicit (assignment
# to an otherwise undeclared name).
#
# (2) analyse_expressions
# Determine the result types of expressions and fill in the
# 'type' attribute of each ExprNode. Insert coercion nodes into the
# tree where needed to convert to and from Python objects.
# Allocate temporary locals for intermediate results.
#
# (3) generate_code
# Emit C code for all declarations, statements and expressions.
# Recursively applies the 3 processing phases to the bodies of
# functions.
#
def analyse_declarations(self, env):
pass
def analyse_expressions(self, env):
raise InternalError("analyse_expressions not implemented for %s" % \
self.__class__.__name__)
def generate_code(self, code):
raise InternalError("generate_code not implemented for %s" % \
self.__class__.__name__)
class BlockNode:
# Mixin class for nodes representing a declaration block.
pass
# def generate_const_definitions(self, env, code):
# if env.const_entries:
# code.putln("")
# for entry in env.const_entries:
# if not entry.is_interned:
# code.put_var_declaration(entry, static = 1)
# def generate_interned_name_decls(self, env, code):
# # Flush accumulated interned names from the global scope
# # and generate declarations for them.
# genv = env.global_scope()
# intern_map = genv.intern_map
# names = genv.interned_names
# if names:
# code.putln("")
# for name in names:
# code.putln(
# "static PyObject *%s;" % intern_map[name])
# del names[:]
# def generate_py_string_decls(self, env, code):
# entries = env.pystring_entries
# if entries:
# code.putln("")
# for entry in entries:
# code.putln(
# "static PyObject *%s;" % entry.pystring_cname)
class StatListNode(Node):
# stats a list of StatNode
def analyse_declarations(self, env):
#print "StatListNode.analyse_declarations" ###
for stat in self.stats:
stat.analyse_declarations(env)
def analyse_expressions(self, env):
#print "StatListNode.analyse_expressions" ###
for stat in self.stats:
stat.analyse_expressions(env)
def generate_function_definitions(self, env, code):
#print "StatListNode.generate_function_definitions" ###
for stat in self.stats:
stat.generate_function_definitions(env, code)
def generate_execution_code(self, code):
#print "StatListNode.generate_execution_code" ###
for stat in self.stats:
code.mark_pos(stat.pos)
stat.generate_execution_code(code)
class StatNode(Node):
#
# Code generation for statements is split into the following subphases:
#
# (1) generate_function_definitions
# Emit C code for the definitions of any structs,
# unions, enums and functions defined in the current
# scope-block.
#
# (2) generate_execution_code
# Emit C code for executable statements.
#
def generate_function_definitions(self, env, code):
pass
def generate_execution_code(self, code):
raise InternalError("generate_execution_code not implemented for %s" % \
self.__class__.__name__)
class CDefExternNode(StatNode):
# include_file string or None
# body StatNode
def analyse_declarations(self, env):
if self.include_file:
env.add_include_file(self.include_file)
old_cinclude_flag = env.in_cinclude
env.in_cinclude = 1
self.body.analyse_declarations(env)
env.in_cinclude = old_cinclude_flag
def analyse_expressions(self, env):
pass
def generate_execution_code(self, code):
pass
class CDeclaratorNode(Node):
# Part of a C declaration.
#
# Processing during analyse_declarations phase:
#
# analyse
# Returns (name, type) pair where name is the
# CNameDeclaratorNode of the name being declared
# and type is the type it is being declared as.
#
# calling_convention string Calling convention of CFuncDeclaratorNode
# for which this is a base
calling_convention = ""
class CNameDeclaratorNode(CDeclaratorNode):
# name string The Pyrex name being declared
# cname string or None C name, if specified
def analyse(self, base_type, env):
return self, base_type
class CPtrDeclaratorNode(CDeclaratorNode):
# base CDeclaratorNode
def analyse(self, base_type, env):
if base_type.is_pyobject:
error(self.pos,
"Pointer base type cannot be a Python object")
ptr_type = PyrexTypes.c_ptr_type(base_type)
return self.base.analyse(ptr_type, env)
class CArrayDeclaratorNode(CDeclaratorNode):
# base CDeclaratorNode
# dimension ExprNode
def analyse(self, base_type, env):
if self.dimension:
self.dimension.analyse_const_expression(env)
if not self.dimension.type.is_int:
error(self.dimension.pos, "Array dimension not integer")
size = self.dimension.result()
else:
size = None
if not base_type.is_complete():
error(self.pos,
"Array element type '%s' is incomplete" % base_type)
if base_type.is_pyobject:
error(self.pos,
"Array element cannot be a Python object")
if base_type.is_cfunction:
error(self.pos,
"Array element cannot be a function")
array_type = PyrexTypes.c_array_type(base_type, size)
return self.base.analyse(array_type, env)
class CFuncDeclaratorNode(CDeclaratorNode):
# base CDeclaratorNode
# args [CArgDeclNode]
# has_varargs boolean
# exception_value ConstNode
# exception_check boolean True if PyErr_Occurred check needed
# nogil boolean Can be called without gil
# with_gil boolean Acquire gil around function body
def analyse(self, return_type, env):
func_type_args = []
for arg_node in self.args:
name_declarator, type = arg_node.analyse(env)
name = name_declarator.name
if name_declarator.cname:
error(self.pos,
"Function argument cannot have C name specification")
# Turn *[] argument into **
if type.is_array:
type = PyrexTypes.c_ptr_type(type.base_type)
# Catch attempted C-style func(void) decl
if type.is_void:
error(arg_node.pos, "Function argument cannot be void")
func_type_args.append(
PyrexTypes.CFuncTypeArg(name, type, arg_node.pos))
if arg_node.default:
error(arg_node.pos, "C function argument cannot have default value")
exc_val = None
exc_check = 0
if return_type.is_pyobject \
and (self.exception_value or self.exception_check):
error(self.pos,
"Exception clause not allowed for function returning Python object")
else:
if self.exception_value:
self.exception_value.analyse_const_expression(env)
exc_val = self.exception_value.result()
if not return_type.assignable_from(self.exception_value.type):
error(self.exception_value.pos,
"Exception value incompatible with function return type")
exc_check = self.exception_check
if return_type.is_array:
error(self.pos,
"Function cannot return an array")
if return_type.is_cfunction:
error(self.pos,
"Function cannot return a function")
func_type = PyrexTypes.CFuncType(
return_type, func_type_args, self.has_varargs,
exception_value = exc_val, exception_check = exc_check,
calling_convention = self.base.calling_convention,
nogil = self.nogil, with_gil = self.with_gil)
return self.base.analyse(func_type, env)
class CArgDeclNode(Node):
# Item in a function declaration argument list.
#
# base_type CBaseTypeNode
# declarator CDeclaratorNode
# not_none boolean Tagged with 'not None'
# default ExprNode or None
# default_entry Symtab.Entry Entry for the variable holding the default value
# is_self_arg boolean Is the "self" arg of an extension type method
# is_kw_only boolean Is a keyword-only argument
is_self_arg = 0
def analyse(self, env):
#print "CArgDeclNode.analyse: is_self_arg =", self.is_self_arg ###
base_type = self.base_type.analyse(env)
return self.declarator.analyse(base_type, env)
class CBaseTypeNode(Node):
# Abstract base class for C base type nodes.
#
# Processing during analyse_declarations phase:
#
# analyse
# Returns the type.
pass
class CSimpleBaseTypeNode(CBaseTypeNode):
# name string
# module_path [string] Qualifying name components
# is_basic_c_type boolean
# signed boolean
# longness integer
# is_self_arg boolean Is self argument of C method
def analyse(self, env):
# Return type descriptor.
#print "CSimpleBaseTypeNode.analyse: is_self_arg =", self.is_self_arg ###
type = None
if self.is_basic_c_type:
type = PyrexTypes.simple_c_type(self.signed, self.longness, self.name)
if not type:
error(self.pos, "Unrecognised type modifier combination")
elif self.name == "object" and not self.module_path:
type = py_object_type
elif self.name is None:
if self.is_self_arg and env.is_c_class_scope:
#print "CSimpleBaseTypeNode.analyse: defaulting to parent type" ###
type = env.parent_type
else:
type = py_object_type
else:
scope = env.find_imported_module(self.module_path, self.pos)
if scope:
entry = scope.find(self.name, self.pos)
if entry and entry.is_type:
type = entry.type
else:
error(self.pos, "'%s' is not a type identifier" % self.name)
if type:
return type
else:
return PyrexTypes.error_type
class CComplexBaseTypeNode(CBaseTypeNode):
# base_type CBaseTypeNode
# declarator CDeclaratorNode
def analyse(self, env):
base = self.base_type.analyse(env)
_, type = self.declarator.analyse(base, env)
return type
class CVarDefNode(StatNode):
# C variable definition or forward/extern function declaration.
#
# visibility 'private' or 'public' or 'extern'
# base_type CBaseTypeNode
# declarators [CDeclaratorNode]
# in_pxd boolean
# api boolean
def analyse_declarations(self, env, dest_scope = None):
if not dest_scope:
dest_scope = env
base_type = self.base_type.analyse(env)
for declarator in self.declarators:
name_declarator, type = declarator.analyse(base_type, env)
if not type.is_complete():
if not (self.visibility == 'extern' and type.is_array):
error(declarator.pos,
"Variable type '%s' is incomplete" % type)
if self.visibility == 'extern' and type.is_pyobject:
error(declarator.pos,
"Python object cannot be declared extern")
name = name_declarator.name
cname = name_declarator.cname
if type.is_cfunction:
entry = dest_scope.declare_cfunction(name, type, declarator.pos,
cname = cname, visibility = self.visibility, in_pxd = self.in_pxd,
api = self.api)
else:
if self.in_pxd and self.visibility <> 'extern':
error(self.pos,
"Only 'extern' C variable declaration allowed in .pxd file")
dest_scope.declare_var(name, type, declarator.pos,
cname = cname, visibility = self.visibility, is_cdef = 1)
def analyse_expressions(self, env):
pass
def generate_execution_code(self, code):
pass
class CStructOrUnionDefNode(StatNode):
# name string
# cname string or None
# module_path [string]
# kind "struct" or "union"
# typedef_flag boolean
# visibility "public" or "private"
# in_pxd boolean
# attributes [CVarDefNode] or None
# entry Entry
def analyse_declarations(self, env):
scope = None
if self.attributes is not None:
scope = StructOrUnionScope()
if self.module_path:
home_scope = env.find_imported_module(self.module_path, self.pos)
if not home_scope:
return
else:
home_scope = env
self.entry = home_scope.declare_struct_or_union(
self.name, self.kind, scope, self.typedef_flag, self.pos,
self.cname, visibility = self.visibility)
if self.attributes is not None:
if self.in_pxd and not env.in_cinclude:
self.entry.defined_in_pxd = 1
for attr in self.attributes:
attr.analyse_declarations(env, scope)
def analyse_expressions(self, env):
pass
def generate_execution_code(self, code):
pass
class CEnumDefNode(StatNode):
# name string or None
# cname string or None
# items [CEnumDefItemNode]
# typedef_flag boolean
# visibility "public" or "private"
# in_pxd boolean
# entry Entry
def analyse_declarations(self, env):
self.entry = env.declare_enum(self.name, self.pos,
cname = self.cname, typedef_flag = self.typedef_flag,
visibility = self.visibility)
if self.items is not None:
if self.in_pxd and not env.in_cinclude:
self.entry.defined_in_pxd = 1
for item in self.items:
item.analyse_declarations(env, self.entry)
def analyse_expressions(self, env):
pass
def generate_execution_code(self, code):
pass
class CEnumDefItemNode(StatNode):
# name string
# cname string or None
# value ExprNode or None
def analyse_declarations(self, env, enum_entry):
value_node = self.value
if value_node:
value_node.analyse_const_expression(env)
type = value_node.type
if type.is_int or type.is_enum:
value = value_node.result()
else:
error(self.pos,
"Type '%s' is not a valid enum value" % type)
value = "<error>"
else:
value = self.name
entry = env.declare_const(self.name, enum_entry.type,
value, self.pos, cname = self.cname)
enum_entry.enum_values.append(entry)
class CTypeDefNode(StatNode):
# base_type CBaseTypeNode
# declarator CDeclaratorNode
# visibility "public" or "private"
# in_pxd boolean
def analyse_declarations(self, env):
base = self.base_type.analyse(env)
name_declarator, type = self.declarator.analyse(base, env)
name = name_declarator.name
cname = name_declarator.cname
entry = env.declare_typedef(name, type, self.pos,
cname = cname, visibility = self.visibility)
if self.in_pxd and not env.in_cinclude:
entry.defined_in_pxd = 1
def analyse_expressions(self, env):
pass
def generate_execution_code(self, code):
pass
class FuncDefNode(StatNode, BlockNode):
# Base class for function definition nodes.
#
# return_type PyrexType
# #filename string C name of filename string const
# entry Symtab.Entry
def analyse_expressions(self, env):
pass
def need_gil_acquisition(self, lenv):
return 0
def generate_function_definitions(self, env, code):
# Generate C code for header and body of function
genv = env.global_scope()
lenv = LocalScope(name = self.entry.name, outer_scope = genv)
lenv.return_type = self.return_type
type = self.entry.type
if type.is_cfunction:
lenv.nogil = type.nogil and not type.with_gil
code.init_labels()
self.declare_arguments(lenv)
self.body.analyse_declarations(lenv)
self.body.analyse_expressions(lenv)
# Code for nested function definitions would go here
# if we supported them, which we probably won't.
# ----- Top-level constants used by this function
#self.generate_interned_name_decls(lenv, code)
#self.generate_py_string_decls(lenv, code)
#self.generate_const_definitions(lenv, code)
# ----- Function header
code.putln("")
self.generate_function_header(code,
with_pymethdef = env.is_py_class_scope)
# ----- Local variable declarations
self.generate_argument_declarations(lenv, code)
code.put_var_declarations(lenv.var_entries)
init = ""
if not self.return_type.is_void:
code.putln(
"%s%s;" %
(self.return_type.declaration_code(
Naming.retval_cname),
init))
code.put_var_declarations(lenv.temp_entries)
self.generate_keyword_list(code)
# ----- Extern library function declarations
lenv.generate_library_function_declarations(code)
# ----- GIL acquisition
acquire_gil = self.need_gil_acquisition(lenv)
if acquire_gil:
code.putln("PyGILState_STATE _save = PyGILState_Ensure();")
# ----- Fetch arguments
self.generate_argument_parsing_code(code)
self.generate_argument_increfs(lenv, code)
# ----- Initialise local variables
for entry in lenv.var_entries:
if entry.type.is_pyobject and entry.init_to_none and entry.used:
code.put_init_var_to_py_none(entry)
# ----- Check and convert arguments
self.generate_argument_conversion_code(code)
self.generate_argument_type_tests(code)
# ----- Function body
self.body.generate_execution_code(code)
# ----- Default return value
code.putln("")
if self.return_type.is_pyobject:
#if self.return_type.is_extension_type:
# lhs = "(PyObject *)%s" % Naming.retval_cname
#else:
lhs = Naming.retval_cname
code.put_init_to_py_none(lhs, self.return_type)
else:
val = self.return_type.default_value
if val:
code.putln("%s = %s;" % (Naming.retval_cname, val))
#code.putln("goto %s;" % code.return_label)
# ----- Error cleanup
if code.error_label in code.labels_used:
code.put_goto(code.return_label)
code.put_label(code.error_label)
code.put_var_xdecrefs(lenv.temp_entries)
default_retval = self.return_type.default_value
err_val = self.error_value()
exc_check = self.caller_will_check_exceptions()
if err_val or exc_check:
code.putln(
'__Pyx_AddTraceback("%s");' %
self.entry.qualified_name)
val = err_val or default_retval
if val:
code.putln(
"%s = %s;" % (
Naming.retval_cname,
val))
else:
code.use_utility_code(unraisable_exception_utility_code)
code.putln(
'__Pyx_WriteUnraisable("%s");' %
self.entry.qualified_name)
#if not self.return_type.is_void:
if default_retval:
code.putln(
"%s = %s;" % (
Naming.retval_cname,
default_retval))
#self.return_type.default_value))
# ----- Return cleanup
code.put_label(code.return_label)
code.put_var_decrefs(lenv.var_entries, used_only = 1)
#code.put_var_decrefs(lenv.arg_entries)
self.generate_argument_decrefs(lenv, code)
self.put_stararg_decrefs(code)
if acquire_gil:
code.putln("PyGILState_Release(_save);")
if not self.return_type.is_void:
code.putln("return %s;" % Naming.retval_cname)
code.putln("}")
def put_stararg_decrefs(self, code):
pass
def declare_argument(self, env, arg, readonly = 0):
if arg.type.is_void:
error(arg.pos, "Invalid use of 'void'")
elif not arg.type.is_complete() and not arg.type.is_array:
error(arg.pos,
"Argument type '%s' is incomplete" % arg.type)
return env.declare_arg(arg.name, arg.type, arg.pos,
readonly = readonly)
def generate_argument_increfs(self, env, code):
# Turn writable borrowed argument refs into owned refs.
# This is necessary, because if the argument is assigned to,
# it will be decrefed.
for entry in env.arg_entries:
if not entry.is_readonly:
code.put_var_incref(entry)
def generate_argument_decrefs(self, env, code):
for entry in env.arg_entries:
if not entry.is_readonly:
code.put_var_decref(entry)
def generate_execution_code(self, code):
pass
class CFuncDefNode(FuncDefNode):
# C function definition.
#
# visibility 'private' or 'public' or 'extern'
# base_type CBaseTypeNode
# declarator CDeclaratorNode
# body StatListNode
# api boolean
#
# with_gil boolean Acquire GIL around body
# type CFuncType
def unqualified_name(self):
return self.entry.name
def analyse_declarations(self, env):
base_type = self.base_type.analyse(env)
name_declarator, type = self.declarator.analyse(base_type, env)
if not type.is_cfunction:
error(self.pos,
"Suite attached to non-function declaration")
# Remember the actual type according to the function header
# written here, because the type in the symbol table entry
# may be different if we're overriding a C method inherited
# from the base type of an extension type.
self.type = type
name = name_declarator.name
cname = name_declarator.cname
self.entry = env.declare_cfunction(
name, type, self.pos,
cname = cname, visibility = self.visibility,
defining = self.body is not None,
api = self.api)
self.return_type = type.return_type
def declare_arguments(self, env):
type = self.type
without_gil = type.nogil and not type.with_gil
for arg in type.args:
if not arg.name:
error(arg.pos, "Missing argument name")
self.declare_argument(env, arg,
readonly = without_gil and arg.type.is_pyobject)
def need_gil_acquisition(self, lenv):
type = self.type
with_gil = type.with_gil
if type.nogil and not with_gil:
# for arg in type.args:
# if arg.type.is_pyobject:
# error(self.pos,
# "Function with Python argument cannot be declared nogil")
if type.return_type.is_pyobject:
error(self.pos,
"Function with Python return type cannot be declared nogil")
for entry in lenv.var_entries + lenv.temp_entries:
#print "CFuncDefNode.need_gil_acquisition:", entry.name, entry.cname, "readonly =", entry.is_readonly ###
if entry.type.is_pyobject and not entry.is_readonly:
error(self.pos, "Function declared nogil has Python locals or temporaries")
return with_gil
def generate_function_header(self, code, with_pymethdef):
arg_decls = []
type = self.type
visibility = self.entry.visibility
for arg in type.args:
arg_decls.append(arg.declaration_code())
if type.has_varargs:
arg_decls.append("...")
if not arg_decls:
arg_decls = ["void"]
entity = type.function_header_code(self.entry.func_cname,
string.join(arg_decls, ","))
if visibility == 'public':
dll_linkage = "DL_EXPORT"
else:
dll_linkage = None
header = self.return_type.declaration_code(entity,
dll_linkage = dll_linkage)
if visibility <> 'private':
storage_class = "%s " % Naming.extern_c_macro
else:
storage_class = "static "
code.putln("%s%s {" % (
storage_class,
header))
def generate_argument_declarations(self, env, code):
# Arguments already declared in function header
pass
def generate_keyword_list(self, code):
pass
def generate_argument_parsing_code(self, code):
pass
def generate_argument_conversion_code(self, code):
pass
def generate_argument_type_tests(self, code):
pass
def error_value(self):
if self.return_type.is_pyobject:
return "0"
else:
#return None
return self.entry.type.exception_value
def caller_will_check_exceptions(self):
return self.entry.type.exception_check
class PyArgDeclNode(Node):
# Argument which must be a Python object (used
# for * and ** arguments).
#
# name string
# entry Symtab.Entry
pass
class DefNode(FuncDefNode):
# A Python function definition.
#
# name string the Python name of the function
# args [CArgDeclNode] formal arguments
# star_arg PyArgDeclNode or None * argument
# starstar_arg PyArgDeclNode or None ** argument
# doc string or None
# body StatListNode
#
# The following subnode is constructed internally
# when the def statement is inside a Python class definition.
#
# assmt AssignmentNode Function construction/assignment
assmt = None
num_kwonly_args = 0
reqd_kw_flags_cname = "0"
has_star_or_kwonly_args = 0
def __init__(self, pos, **kwds):
FuncDefNode.__init__(self, pos, **kwds)
n = 0
for arg in self.args:
if arg.kw_only:
n += 1
self.num_kwonly_args = n
if self.star_arg or self.starstar_arg or n > 0:
self.has_star_or_kwonly_args = 1
def analyse_declarations(self, env):
for arg in self.args:
base_type = arg.base_type.analyse(env)
name_declarator, type = \
arg.declarator.analyse(base_type, env)
arg.name = name_declarator.name
if name_declarator.cname:
error(self.pos,
"Python function argument cannot have C name specification")
arg.type = type.as_argument_type()
arg.hdr_type = None
arg.needs_conversion = 0
arg.needs_type_test = 0
arg.is_generic = 1
if arg.not_none and not arg.type.is_extension_type:
error(self.pos,
"Only extension type arguments can have 'not None'")
self.declare_pyfunction(env)
self.analyse_signature(env)
self.return_type = self.entry.signature.return_type()
# if self.has_star_or_kwonly_args:
# env.use_utility_code(get_starargs_utility_code)
def analyse_signature(self, env):
any_type_tests_needed = 0
sig = self.entry.signature
nfixed = sig.num_fixed_args()
for i in range(nfixed):
if i < len(self.args):
arg = self.args[i]
arg.is_generic = 0
if sig.is_self_arg(i):
arg.is_self_arg = 1
arg.hdr_type = arg.type = env.parent_type
arg.needs_conversion = 0
else:
arg.hdr_type = sig.fixed_arg_type(i)
if not arg.type.same_as(arg.hdr_type):
if arg.hdr_type.is_pyobject and arg.type.is_pyobject:
arg.needs_type_test = 1
any_type_tests_needed = 1
else:
arg.needs_conversion = 1
if arg.needs_conversion:
arg.hdr_cname = Naming.arg_prefix + arg.name
else:
arg.hdr_cname = Naming.var_prefix + arg.name
else:
self.bad_signature()
return
if nfixed < len(self.args):
if not sig.has_generic_args:
self.bad_signature()
for arg in self.args:
if arg.is_generic and arg.type.is_extension_type:
arg.needs_type_test = 1
any_type_tests_needed = 1
# if any_type_tests_needed:
# env.use_utility_code(arg_type_test_utility_code)
def bad_signature(self):
sig = self.entry.signature
expected_str = "%d" % sig.num_fixed_args()
if sig.has_generic_args:
expected_str = expected_str + " or more"
name = self.name
if name.startswith("__") and name.endswith("__"):
desc = "Special method"
else:
desc = "Method"
error(self.pos,
"%s %s has wrong number of arguments "
"(%d declared, %s expected)" % (
desc, self.name, len(self.args), expected_str))
def declare_pyfunction(self, env):
#print "DefNode.declare_pyfunction:", self.name, "in", env ###
name = self.name
entry = env.declare_pyfunction(self.name, self.pos)
self.entry = entry
prefix = env.scope_prefix
entry.func_cname = \
Naming.func_prefix + prefix + name
entry.pymethdef_cname = \
Naming.pymethdef_prefix + prefix + name
if not entry.is_special:
entry.doc = self.doc
entry.doc_cname = \
Naming.funcdoc_prefix + prefix + name
def declare_arguments(self, env):
for arg in self.args:
if not arg.name:
error(arg.pos, "Missing argument name")
if arg.needs_conversion:
arg.entry = env.declare_var(arg.name, arg.type, arg.pos)
if arg.type.is_pyobject:
arg.entry.init = "0"
arg.entry.init_to_none = 0
else:
arg.entry = self.declare_argument(env, arg)
arg.entry.used = 1
arg.entry.is_self_arg = arg.is_self_arg
if arg.hdr_type:
if arg.is_self_arg or \
(arg.type.is_extension_type and not arg.hdr_type.is_extension_type):
arg.entry.is_declared_generic = 1
self.declare_python_arg(env, self.star_arg)
self.declare_python_arg(env, self.starstar_arg)
def declare_python_arg(self, env, arg):
if arg:
entry = env.declare_var(arg.name,
PyrexTypes.py_object_type, arg.pos)
entry.used = 1
entry.init = "0"
entry.init_to_none = 0
entry.xdecref_cleanup = 1
arg.entry = entry
def analyse_expressions(self, env):
self.analyse_default_values(env)
if env.is_py_class_scope:
self.synthesize_assignment_node(env)
def analyse_default_values(self, env):
for arg in self.args:
if arg.default:
if arg.is_generic:
arg.default.analyse_types(env)
arg.default = arg.default.coerce_to(arg.type, env)
arg.default.allocate_temps(env)
arg.default_entry = env.add_default_value(arg.type)
arg.default_entry.used = 1
else:
error(arg.pos,
"This argument cannot have a default value")
arg.default = None
def synthesize_assignment_node(self, env):
import ExprNodes
self.assmt = SingleAssignmentNode(self.pos,
lhs = ExprNodes.NameNode(self.pos, name = self.name),
rhs = ExprNodes.UnboundMethodNode(self.pos,
class_cname = env.class_obj_cname,
function = ExprNodes.PyCFunctionNode(self.pos,
pymethdef_cname = self.entry.pymethdef_cname)))
self.assmt.analyse_declarations(env)
self.assmt.analyse_expressions(env)
def generate_function_header(self, code, with_pymethdef):
arg_code_list = []
sig = self.entry.signature
if sig.has_dummy_arg:
arg_code_list.append(
"PyObject *%s" % Naming.self_cname)
for arg in self.args:
if not arg.is_generic:
if arg.is_self_arg:
arg_code_list.append("PyObject *%s" % arg.hdr_cname)
else:
arg_code_list.append(
arg.hdr_type.declaration_code(arg.hdr_cname))
if sig.has_generic_args:
arg_code_list.append(
"PyObject *%s, PyObject *%s"
% (Naming.args_cname, Naming.kwds_cname))
arg_code = ", ".join(arg_code_list)
dc = self.return_type.declaration_code(self.entry.func_cname)
header = "static %s(%s)" % (dc, arg_code)
code.putln("%s; /*proto*/" % header)
if self.entry.doc:
code.putln(
'static char %s[] = "%s";' % (
self.entry.doc_cname,
self.entry.doc))
if with_pymethdef:
code.put(
"static PyMethodDef %s = " %
self.entry.pymethdef_cname)
code.put_pymethoddef(self.entry, ";")
code.putln("%s {" % header)
def generate_argument_declarations(self, env, code):
for arg in self.args:
if arg.is_generic: # or arg.needs_conversion:
code.put_var_declaration(arg.entry)
def generate_keyword_list(self, code):
if self.entry.signature.has_generic_args:
reqd_kw_flags = []
has_reqd_kwds = False
code.put(
"static char *%s[] = {" %
Naming.kwdlist_cname)
for arg in self.args:
if arg.is_generic:
code.put(
'"%s",' %
arg.name)
if arg.kw_only and not arg.default:
has_reqd_kwds = 1
flag = "1"
else:
flag = "0"
reqd_kw_flags.append(flag)
code.putln(
"0};")
if has_reqd_kwds:
flags_name = Naming.reqd_kwds_cname
self.reqd_kw_flags_cname = flags_name
code.putln(
"static char %s[] = {%s};" % (
flags_name,
",".join(reqd_kw_flags)))
def generate_argument_parsing_code(self, code):
# Generate PyArg_ParseTuple call for generic
# arguments, if any.
has_kwonly_args = self.num_kwonly_args > 0
has_star_or_kw_args = self.star_arg is not None \
or self.starstar_arg is not None or has_kwonly_args
if not self.entry.signature.has_generic_args:
if has_star_or_kw_args:
error(self.pos, "This method cannot have * or keyword arguments")
else:
arg_addrs = []
arg_formats = []
default_seen = 0
for arg in self.args:
arg_entry = arg.entry
if arg.is_generic:
if arg.default:
code.putln(
"%s = %s;" % (
arg_entry.cname,
arg.default_entry.cname))
if not default_seen:
arg_formats.append("|")
default_seen = 1
elif default_seen and not arg.kw_only:
error(arg.pos, "Non-default argument following default argument")
arg_addrs.append("&" + arg_entry.cname)
format = arg_entry.type.parsetuple_format
if format:
arg_formats.append(format)
else:
error(arg.pos,
"Cannot convert Python object argument to type '%s'"
% arg.type)
error_return_code = "return %s;" % self.error_value()
argformat = '"%s"' % string.join(arg_formats, "")
if has_star_or_kw_args:
self.generate_stararg_getting_code(code)
pt_arglist = [Naming.args_cname, Naming.kwds_cname, argformat,
Naming.kwdlist_cname] + arg_addrs
pt_argstring = string.join(pt_arglist, ", ")
code.put(
'if (!PyArg_ParseTupleAndKeywords(%s)) ' %
pt_argstring)
if has_star_or_kw_args:
code.putln("{")
code.put_xdecref(Naming.args_cname, py_object_type)
code.put_xdecref(Naming.kwds_cname, py_object_type)
self.generate_arg_xdecref(self.star_arg, code)
self.generate_arg_xdecref(self.starstar_arg, code)
code.putln(error_return_code)
code.putln("}")
else:
code.putln(error_return_code)
def put_stararg_decrefs(self, code):
if self.has_star_or_kwonly_args:
code.put_xdecref(Naming.args_cname, py_object_type)
code.put_xdecref(Naming.kwds_cname, py_object_type)
def generate_arg_xdecref(self, arg, code):
if arg:
code.put_var_xdecref(arg.entry)
def arg_address(self, arg):
if arg:
return "&%s" % arg.entry.cname
else:
return 0
def generate_stararg_getting_code(self, code):
num_kwonly = self.num_kwonly_args
nargs = len(self.args) - num_kwonly - self.entry.signature.num_fixed_args()
star_arg_addr = self.arg_address(self.star_arg)
starstar_arg_addr = self.arg_address(self.starstar_arg)
code.use_utility_code(get_starargs_utility_code)
code.putln(
"if (__Pyx_GetStarArgs(&%s, &%s, %s, %s, %s, %s, %s) < 0) return %s;" % (
Naming.args_cname,
Naming.kwds_cname,
Naming.kwdlist_cname,
nargs,
star_arg_addr,
starstar_arg_addr,
self.reqd_kw_flags_cname,
self.error_value()))
def generate_argument_conversion_code(self, code):
# Generate code to convert arguments from
# signature type to declared type, if needed.
for arg in self.args:
if arg.needs_conversion:
self.generate_arg_conversion(arg, code)
def generate_arg_conversion(self, arg, code):
# Generate conversion code for one argument.
old_type = arg.hdr_type
new_type = arg.type
if old_type.is_pyobject:
self.generate_arg_conversion_from_pyobject(arg, code)
elif new_type.is_pyobject:
self.generate_arg_conversion_to_pyobject(arg, code)
else:
if new_type.assignable_from(old_type):
code.putln(
"%s = %s;" % (arg.entry.cname, arg.hdr_cname))
else:
error(arg.pos,
"Cannot convert argument from '%s' to '%s'" %
(old_type, new_type))
def generate_arg_conversion_from_pyobject(self, arg, code):
new_type = arg.type
func = new_type.from_py_function
if func:
code.putln("%s = %s(%s); if (PyErr_Occurred()) %s" % (
arg.entry.cname,
func,
arg.hdr_cname,
code.error_goto(arg.pos)))
else:
error(arg.pos,
"Cannot convert Python object argument to type '%s'"
% new_type)
def generate_arg_conversion_to_pyobject(self, arg, code):
old_type = arg.hdr_type
func = old_type.to_py_function
if func:
code.putln("%s = %s(%s); if (!%s) %s" % (
arg.entry.cname,
func,
arg.hdr_cname,
arg.entry.cname,
code.error_goto(arg.pos)))
else:
error(arg.pos,
"Cannot convert argument of type '%s' to Python object"
% old_type)
def generate_argument_type_tests(self, code):
# Generate type tests for args whose signature
# type is PyObject * and whose declared type is
# a subtype thereof.
for arg in self.args:
if arg.needs_type_test:
self.generate_arg_type_test(arg, code)
def generate_arg_type_test(self, arg, code):
# Generate type test for one argument.
if arg.type.typeobj_is_available():
typeptr_cname = arg.type.typeptr_cname
arg_code = "((PyObject *)%s)" % arg.entry.cname
code.use_utility_code(arg_type_test_utility_code)
code.putln(
'if (!__Pyx_ArgTypeTest(%s, %s, %d, "%s")) %s' % (
arg_code,
typeptr_cname,
not arg.not_none,
arg.name,
code.error_goto(arg.pos)))
else:
error(arg.pos, "Cannot test type of extern C class "
"without type object name specification")
def generate_execution_code(self, code):
# Evaluate and store argument default values
for arg in self.args:
default = arg.default
if default:
default.generate_evaluation_code(code)
default.make_owned_reference(code)
code.putln(
"%s = %s;" % (
arg.default_entry.cname,
default.result_as(arg.default_entry.type)))
default.generate_post_assignment_code(code)
# if default.is_temp and default.type.is_pyobject:
# code.putln(
# "%s = 0;" %
# default.result())
# For Python class methods, create and store function object
if self.assmt:
self.assmt.generate_execution_code(code)
def error_value(self):
return self.entry.signature.error_value
def caller_will_check_exceptions(self):
return 1
class PyClassDefNode(StatNode, BlockNode):
# A Python class definition.
#
# name string Name of the class
# doc string or None
# body StatNode Attribute definition code
# entry Symtab.Entry
# scope PyClassScope
#
# The following subnodes are constructed internally:
#
# dict DictNode Class dictionary
# classobj ClassNode Class object
# target NameNode Variable to assign class object to
def __init__(self, pos, name, bases, doc, body):
StatNode.__init__(self, pos)
self.name = name
self.doc = doc
self.body = body
import ExprNodes
self.dict = ExprNodes.DictNode(pos, key_value_pairs = [])
if self.doc:
doc_node = ExprNodes.StringNode(pos, value = self.doc)
else:
doc_node = None
self.classobj = ExprNodes.ClassNode(pos,
name = ExprNodes.StringNode(pos, value = name),
bases = bases, dict = self.dict, doc = doc_node)
self.target = ExprNodes.NameNode(pos, name = name)
def analyse_declarations(self, env):
self.target.analyse_target_declaration(env)
def analyse_expressions(self, env):
self.dict.analyse_expressions(env)
self.classobj.analyse_expressions(env)
genv = env.global_scope()
cenv = PyClassScope(name = self.name, outer_scope = genv)
cenv.class_dict_cname = self.dict.result()
cenv.class_obj_cname = self.classobj.result()
self.scope = cenv
self.body.analyse_declarations(cenv)
self.body.analyse_expressions(cenv)
self.target.analyse_target_expression(env, self.classobj)
self.dict.release_temp(env)
#self.classobj.release_temp(env)
#self.target.release_target_temp(env)
def generate_function_definitions(self, env, code):
#self.generate_py_string_decls(self.scope, code)
self.body.generate_function_definitions(
self.scope, code)
def generate_execution_code(self, code):
self.dict.generate_evaluation_code(code)
self.classobj.generate_evaluation_code(code)
self.body.generate_execution_code(code)
self.target.generate_assignment_code(self.classobj, code)
self.dict.generate_disposal_code(code)
class CClassDefNode(StatNode):
# An extension type definition.
#
# visibility 'private' or 'public' or 'extern'
# typedef_flag boolean
# api boolean
# module_name string or None For import of extern type objects
# class_name string Unqualified name of class
# as_name string or None Name to declare as in this scope
# base_class_module string or None Module containing the base class
# base_class_name string or None Name of the base class
# objstruct_name string or None Specified C name of object struct
# typeobj_name string or None Specified C name of type object
# in_pxd boolean Is in a .pxd file
# doc string or None
# body StatNode or None
# entry Symtab.Entry
# base_type PyExtensionType or None
entry = None
def analyse_declarations(self, env):
#print "CClassDefNode.analyse_declarations:", self.class_name
#print "...visibility =", self.visibility
#print "...module_name =", self.module_name
if env.in_cinclude and not self.objstruct_name:
error(self.pos, "Object struct name specification required for "
"C class defined in 'extern from' block")
self.base_type = None
if self.base_class_name:
if self.base_class_module:
base_class_scope = env.find_module(self.base_class_module, self.pos)
else:
base_class_scope = env
if base_class_scope:
base_class_entry = base_class_scope.find(self.base_class_name, self.pos)
if base_class_entry:
if not base_class_entry.is_type:
error(self.pos, "'%s' is not a type name" % self.base_class_name)
elif not base_class_entry.type.is_extension_type:
error(self.pos, "'%s' is not an extension type" % self.base_class_name)
elif not base_class_entry.type.is_complete():
error(self.pos, "Base class '%s' is incomplete" % self.base_class_name)
else:
self.base_type = base_class_entry.type
has_body = self.body is not None
if self.module_name and self.visibility <> 'extern':
module_path = self.module_name.split(".")
home_scope = env.find_imported_module(module_path, self.pos)
if not home_scope:
return
else:
home_scope = env
self.entry = home_scope.declare_c_class(
name = self.class_name,
pos = self.pos,
defining = has_body and self.in_pxd,
implementing = has_body and not self.in_pxd,
module_name = self.module_name,
base_type = self.base_type,
objstruct_cname = self.objstruct_name,
typeobj_cname = self.typeobj_name,
visibility = self.visibility,
typedef_flag = self.typedef_flag,
api = self.api)
if home_scope is not env and self.visibility == 'extern':
env.add_imported_entry(self.class_name, self.entry, pos)
scope = self.entry.type.scope
if self.doc:
scope.doc = self.doc
if has_body:
self.body.analyse_declarations(scope)
if self.in_pxd:
scope.defined = 1
else:
scope.implemented = 1
env.allocate_vtable_names(self.entry)
def analyse_expressions(self, env):
if self.body:
self.body.analyse_expressions(env)
def generate_function_definitions(self, env, code):
if self.entry and self.body:
# self.body.generate_function_definitions(
# self.entry.type.scope, code)
self.body.generate_function_definitions(env, code)
def generate_execution_code(self, code):
# This is needed to generate evaluation code for
# default values of method arguments.
if self.body:
self.body.generate_execution_code(code)
class PropertyNode(StatNode):
# Definition of a property in an extension type.
#
# name string
# doc string or None Doc string
# body StatListNode
def analyse_declarations(self, env):
#print "PropertyNode.analyse_declarations:", env ###
entry = env.declare_property(self.name, self.doc, self.pos)
if entry:
#if self.doc:
# doc_entry = env.get_string_const(self.doc)
# entry.doc_cname = doc_entry.cname
self.body.analyse_declarations(entry.scope)
def analyse_expressions(self, env):
self.body.analyse_expressions(env)
def generate_function_definitions(self, env, code):
self.body.generate_function_definitions(env, code)
def generate_execution_code(self, code):
pass
class GlobalNode(StatNode):
# Global variable declaration.
#
# names [string]
def analyse_declarations(self, env):
for name in self.names:
env.declare_global(name, self.pos)
def analyse_expressions(self, env):
pass
def generate_execution_code(self, code):
pass
class ExprStatNode(StatNode):
# Expression used as a statement.
#
# expr ExprNode
def analyse_expressions(self, env):
self.expr.analyse_expressions(env)
self.expr.release_temp(env)
def generate_execution_code(self, code):
self.expr.generate_evaluation_code(code)
if not self.expr.is_temp and self.expr.result():
code.putln("%s;" % self.expr.result())
self.expr.generate_disposal_code(code)
class AssignmentNode(StatNode):
# Abstract base class for assignment nodes.
#
# The analyse_expressions and generate_execution_code
# phases of assignments are split into two sub-phases
# each, to enable all the right hand sides of a
# parallel assignment to be evaluated before assigning
# to any of the left hand sides.
def analyse_expressions(self, env):
self.analyse_types(env)
self.allocate_rhs_temps(env)
self.allocate_lhs_temps(env)
def generate_execution_code(self, code):
self.generate_rhs_evaluation_code(code)
self.generate_assignment_code(code)
class SingleAssignmentNode(AssignmentNode):
# The simplest case:
#
# a = b
#
# lhs ExprNode Left hand side
# rhs ExprNode Right hand side
def analyse_declarations(self, env):
self.lhs.analyse_target_declaration(env)
def analyse_types(self, env, use_temp = 0):
self.rhs.analyse_types(env)
self.lhs.analyse_target_types(env)
self.lhs.gil_assignment_check(env)
self.rhs = self.rhs.coerce_to(self.lhs.type, env)
if use_temp:
self.rhs = self.rhs.coerce_to_temp(env)
def allocate_rhs_temps(self, env):
self.rhs.allocate_temps(env)
def allocate_lhs_temps(self, env):
self.lhs.allocate_target_temps(env, self.rhs)
def generate_rhs_evaluation_code(self, code):
self.rhs.generate_evaluation_code(code)
def generate_assignment_code(self, code):
self.lhs.generate_assignment_code(self.rhs, code)
class AugmentedAssignmentNode(SingleAssignmentNode):
# An in-place operation:
#
# a op= b
#
# lhs ExprNode Left hand side
# operator string
# rhs ExprNode Right hand side
def analyse_types(self, env):
op = self.operator
self.rhs.analyse_types(env)
self.lhs.analyse_inplace_types(env)
type = self.lhs.type
if type.is_pyobject:
type = py_object_type
else:
if type.is_ptr and (op == '+=' or op == '-='):
type = c_int_type
elif op == "**=":
error(self.pos, "**= operator not supported for non-Python types")
return
self.rhs = self.rhs.coerce_to(type, env)
def allocate_lhs_temps(self, env):
self.lhs.allocate_inplace_target_temps(env, self.rhs)
def generate_assignment_code(self, code):
self.lhs.generate_inplace_assignment_code(self.operator, self.rhs, code)
class CascadedAssignmentNode(AssignmentNode):
# An assignment with multiple left hand sides:
#
# a = b = c
#
# lhs_list [ExprNode] Left hand sides
# rhs ExprNode Right hand sides
#
# Used internally:
#
# coerced_rhs_list [ExprNode] RHS coerced to type of each LHS
def analyse_declarations(self, env):
for lhs in self.lhs_list:
lhs.analyse_target_declaration(env)
def analyse_types(self, env, use_temp = 0):
self.rhs.analyse_types(env)
if use_temp:
self.rhs = self.rhs.coerce_to_temp(env)
else:
self.rhs = self.rhs.coerce_to_simple(env)
from ExprNodes import CloneNode
self.coerced_rhs_list = []
for lhs in self.lhs_list:
lhs.analyse_target_types(env)
lhs.gil_assignment_check(env)
rhs = CloneNode(self.rhs)
rhs = rhs.coerce_to(lhs.type, env)
self.coerced_rhs_list.append(rhs)
def allocate_rhs_temps(self, env):
self.rhs.allocate_temps(env)
def allocate_lhs_temps(self, env):
for lhs, rhs in zip(self.lhs_list, self.coerced_rhs_list):
rhs.allocate_temps(env)
lhs.allocate_target_temps(env, rhs)
#lhs.release_target_temp(env)
#rhs.release_temp(env)
self.rhs.release_temp(env)
def generate_rhs_evaluation_code(self, code):
self.rhs.generate_evaluation_code(code)
def generate_assignment_code(self, code):
for i in range(len(self.lhs_list)):
lhs = self.lhs_list[i]
rhs = self.coerced_rhs_list[i]
rhs.generate_evaluation_code(code)
lhs.generate_assignment_code(rhs, code)
# Assignment has disposed of the cloned RHS
self.rhs.generate_disposal_code(code)
class ParallelAssignmentNode(AssignmentNode):
# A combined packing/unpacking assignment:
#
# a, b, c = d, e, f
#
# This has been rearranged by the parser into
#
# a = d ; b = e ; c = f
#
# but we must evaluate all the right hand sides
# before assigning to any of the left hand sides.
#
# stats [AssignmentNode] The constituent assignments
def analyse_declarations(self, env):
for stat in self.stats:
stat.analyse_declarations(env)
def analyse_expressions(self, env):
for stat in self.stats:
stat.analyse_types(env, use_temp = 1)
stat.allocate_rhs_temps(env)
for stat in self.stats:
stat.allocate_lhs_temps(env)
def generate_execution_code(self, code):
for stat in self.stats:
stat.generate_rhs_evaluation_code(code)
for stat in self.stats:
stat.generate_assignment_code(code)
class PrintStatNode(StatNode):
# print statement
#
# args [ExprNode]
# ends_with_comma boolean
def analyse_expressions(self, env):
for i in range(len(self.args)):
arg = self.args[i]
arg.analyse_types(env)
arg = arg.coerce_to_pyobject(env)
arg.allocate_temps(env)
arg.release_temp(env)
self.args[i] = arg
# env.use_utility_code(printing_utility_code)
self.gil_check(env)
gil_message = "Python print statement"
def generate_execution_code(self, code):
for arg in self.args:
arg.generate_evaluation_code(code)
code.use_utility_code(printing_utility_code)
code.putln(
"if (__Pyx_PrintItem(%s) < 0) %s" % (
arg.py_result(),
code.error_goto(self.pos)))
arg.generate_disposal_code(code)
if not self.ends_with_comma:
code.use_utility_code(printing_utility_code)
code.putln(
"if (__Pyx_PrintNewline() < 0) %s" %
code.error_goto(self.pos))
class DelStatNode(StatNode):
# del statement
#
# args [ExprNode]
def analyse_declarations(self, env):
for arg in self.args:
arg.analyse_target_declaration(env)
def analyse_expressions(self, env):
for arg in self.args:
arg.analyse_target_expression(env, None)
if not arg.type.is_pyobject:
error(arg.pos, "Deletion of non-Python object")
else:
self.gil_check(env)
gil_message = "Deleting Python object"
def generate_execution_code(self, code):
for arg in self.args:
if arg.type.is_pyobject:
arg.generate_deletion_code(code)
# else error reported earlier
class PassStatNode(StatNode):
# pass statement
def analyse_expressions(self, env):
pass
def generate_execution_code(self, code):
pass
class BreakStatNode(StatNode):
def analyse_expressions(self, env):
pass
def generate_execution_code(self, code):
if not code.break_label:
error(self.pos, "break statement not inside loop")
else:
#code.putln(
# "goto %s;" %
# code.break_label)
code.put_goto(code.break_label)
class ContinueStatNode(StatNode):
def analyse_expressions(self, env):
pass
def generate_execution_code(self, code):
if code.in_try_finally:
error(self.pos, "continue statement inside try of try...finally")
elif not code.continue_label:
error(self.pos, "continue statement not inside loop")
else:
#code.putln(
# "goto %s;" %
# code.continue_label)
code.put_goto(code.continue_label)
class ReturnStatNode(StatNode):
# return statement
#
# value ExprNode or None
# return_type PyrexType
# temps_in_use [Entry] Temps in use at time of return
def analyse_expressions(self, env):
return_type = env.return_type
self.return_type = return_type
self.temps_in_use = env.temps_in_use()
if not return_type:
error(self.pos, "Return not inside a function body")
return
if self.value:
self.value.analyse_types(env)
if return_type.is_void or return_type.is_returncode:
error(self.value.pos,
"Return with value in void function")
else:
self.value = self.value.coerce_to(env.return_type, env)
self.value.allocate_temps(env)
self.value.release_temp(env)
else:
if (not return_type.is_void
and not return_type.is_pyobject
and not return_type.is_returncode):
error(self.pos, "Return value required")
if return_type.is_pyobject:
self.gil_check(env)
gil_message = "Returning Python object"
def generate_execution_code(self, code):
if not self.return_type:
# error reported earlier
return
if self.value:
self.value.generate_evaluation_code(code)
self.value.make_owned_reference(code)
code.putln(
"%s = %s;" % (
Naming.retval_cname,
self.value.result_as(self.return_type)))
self.value.generate_post_assignment_code(code)
else:
if self.return_type.is_pyobject:
code.put_init_to_py_none(Naming.retval_cname, self.return_type)
elif self.return_type.is_returncode:
code.putln(
"%s = %s;" % (
Naming.retval_cname,
self.return_type.default_value))
for entry in self.temps_in_use:
code.put_var_decref_clear(entry)
#code.putln(
# "goto %s;" %
# code.return_label)
code.put_goto(code.return_label)
class RaiseStatNode(StatNode):
# raise statement
#
# exc_type ExprNode or None
# exc_value ExprNode or None
# exc_tb ExprNode or None
def analyse_expressions(self, env):
if self.exc_type:
self.exc_type.analyse_types(env)
self.exc_type = self.exc_type.coerce_to_pyobject(env)
self.exc_type.allocate_temps(env)
if self.exc_value:
self.exc_value.analyse_types(env)
self.exc_value = self.exc_value.coerce_to_pyobject(env)
self.exc_value.allocate_temps(env)
if self.exc_tb:
self.exc_tb.analyse_types(env)
self.exc_tb = self.exc_tb.coerce_to_pyobject(env)
self.exc_tb.allocate_temps(env)
if self.exc_type:
self.exc_type.release_temp(env)
if self.exc_value:
self.exc_value.release_temp(env)
if self.exc_tb:
self.exc_tb.release_temp(env)
# env.use_utility_code(raise_utility_code)
self.gil_check(env)
gil_message = "Raising exception"
def generate_execution_code(self, code):
if self.exc_type:
self.exc_type.generate_evaluation_code(code)
type_code = self.exc_type.py_result()
else:
type_code = 0
if self.exc_value:
self.exc_value.generate_evaluation_code(code)
value_code = self.exc_value.py_result()
else:
value_code = "0"
if self.exc_tb:
self.exc_tb.generate_evaluation_code(code)
tb_code = self.exc_tb.py_result()
else:
tb_code = "0"
if self.exc_type or self.exc_value or self.exc_tb:
code.use_utility_code(raise_utility_code)
code.putln(
"__Pyx_Raise(%s, %s, %s);" % (
type_code,
value_code,
tb_code))
else:
code.putln(
"__Pyx_ReRaise();")
if self.exc_type:
self.exc_type.generate_disposal_code(code)
if self.exc_value:
self.exc_value.generate_disposal_code(code)
if self.exc_tb:
self.exc_tb.generate_disposal_code(code)
code.putln(
code.error_goto(self.pos))
class ReraiseStatNode(StatNode):
def analyse_expressions(self, env):
# env.use_utility_code(raise_utility_code)
self.gil_check(env)
gil_message = "Raising exception"
def generate_execution_code(self, code):
vars = code.exc_vars
if vars:
code.use_utility_code(raise_utility_code)
code.putln("__Pyx_Raise(%s, %s, %s);" % tuple(vars))
code.putln(code.error_goto(self.pos))
else:
error(self.pos, "Reraise not inside except clause")
class AssertStatNode(StatNode):
# assert statement
#
# cond ExprNode
# value ExprNode or None
def analyse_expressions(self, env):
self.cond = self.cond.analyse_boolean_expression(env)
if self.value:
self.value.analyse_types(env)
self.value = self.value.coerce_to_pyobject(env)
self.value.allocate_temps(env)
self.cond.release_temp(env)
if self.value:
self.value.release_temp(env)
self.gil_check(env)
gil_message = "Raising exception"
def generate_execution_code(self, code):
code.putln("#ifndef PYREX_WITHOUT_ASSERTIONS")
self.cond.generate_evaluation_code(code)
code.putln(
"if (!%s) {" %
self.cond.result())
if self.value:
self.value.generate_evaluation_code(code)
if self.value:
code.putln(
"PyErr_SetObject(PyExc_AssertionError, %s);" %
self.value.py_result())
else:
code.putln(
"PyErr_SetNone(PyExc_AssertionError);")
code.putln(
code.error_goto(self.pos))
code.putln(
"}")
self.cond.generate_disposal_code(code)
# Disposal code for value not needed because exception always raised
#if self.value:
# self.value.generate_disposal_code(code)
code.putln("#endif")
class IfStatNode(StatNode):
# if statement
#
# if_clauses [IfClauseNode]
# else_clause StatNode or None
def analyse_declarations(self, env):
for if_clause in self.if_clauses:
if_clause.analyse_declarations(env)
if self.else_clause:
self.else_clause.analyse_declarations(env)
def analyse_expressions(self, env):
for if_clause in self.if_clauses:
if_clause.analyse_expressions(env)
if self.else_clause:
self.else_clause.analyse_expressions(env)
def generate_execution_code(self, code):
end_label = code.new_label()
for if_clause in self.if_clauses:
if_clause.generate_execution_code(code, end_label)
if self.else_clause:
code.putln("/*else*/ {")
self.else_clause.generate_execution_code(code)
code.putln("}")
code.put_label(end_label)
class IfClauseNode(Node):
# if or elif clause in an if statement
#
# condition ExprNode
# body StatNode
def analyse_declarations(self, env):
self.condition.analyse_declarations(env)
self.body.analyse_declarations(env)
def analyse_expressions(self, env):
self.condition = \
self.condition.analyse_temp_boolean_expression(env)
self.condition.release_temp(env)
self.body.analyse_expressions(env)
def generate_execution_code(self, code, end_label):
self.condition.generate_evaluation_code(code)
code.putln(
"if (%s) {" %
self.condition.result())
self.body.generate_execution_code(code)
#code.putln(
# "goto %s;" %
# end_label)
code.put_goto(end_label)
code.putln("}")
class WhileStatNode(StatNode):
# while statement
#
# condition ExprNode
# body StatNode
# else_clause StatNode
def analyse_declarations(self, env):
self.body.analyse_declarations(env)
if self.else_clause:
self.else_clause.analyse_declarations(env)
def analyse_expressions(self, env):
self.condition = \
self.condition.analyse_temp_boolean_expression(env)
self.condition.release_temp(env)
#env.recycle_pending_temps() # TEMPORARY
self.body.analyse_expressions(env)
if self.else_clause:
self.else_clause.analyse_expressions(env)
def generate_execution_code(self, code):
old_loop_labels = code.new_loop_labels()
code.putln(
"while (1) {")
self.condition.generate_evaluation_code(code)
code.putln(
"if (!%s) break;" %
self.condition.result())
self.body.generate_execution_code(code)
code.put_label(code.continue_label)
code.putln("}")
break_label = code.break_label
code.set_loop_labels(old_loop_labels)
if self.else_clause:
code.putln("/*else*/ {")
self.else_clause.generate_execution_code(code)
code.putln("}")
code.put_label(break_label)
class ForInStatNode(StatNode):
# for statement
#
# target ExprNode
# iterator IteratorNode
# body StatNode
# else_clause StatNode
# item NextNode used internally
def analyse_declarations(self, env):
self.target.analyse_target_declaration(env)
self.body.analyse_declarations(env)
if self.else_clause:
self.else_clause.analyse_declarations(env)
def analyse_expressions(self, env):
import ExprNodes
self.iterator.analyse_expressions(env)
self.target.analyse_target_types(env)
self.item = ExprNodes.NextNode(self.iterator, env)
self.item = self.item.coerce_to(self.target.type, env)
self.item.allocate_temps(env)
self.target.allocate_target_temps(env, self.item)
#self.item.release_temp(env)
#self.target.release_target_temp(env)
self.body.analyse_expressions(env)
if self.else_clause:
self.else_clause.analyse_expressions(env)
self.iterator.release_temp(env)
def generate_execution_code(self, code):
old_loop_labels = code.new_loop_labels()
self.iterator.generate_evaluation_code(code)
code.putln(
"for (;;) {")
self.item.generate_evaluation_code(code)
self.target.generate_assignment_code(self.item, code)
self.body.generate_execution_code(code)
code.put_label(code.continue_label)
code.putln(
"}")
break_label = code.break_label
code.set_loop_labels(old_loop_labels)
if self.else_clause:
code.putln("/*else*/ {")
self.else_clause.generate_execution_code(code)
code.putln("}")
code.put_label(break_label)
self.iterator.generate_disposal_code(code)
class IntegerForStatNode(StatNode):
# for expr rel name rel expr
#
# bound1 ExprNode
# relation1 string
# target NameNode
# relation2 string
# bound2 ExprNode
# body StatNode
# else_clause StatNode or None
#
# Used internally:
#
# is_py_target bool
# loopvar_name string
# py_loopvar_node PyTempNode or None
def analyse_declarations(self, env):
self.target.analyse_target_declaration(env)
self.body.analyse_declarations(env)
if self.else_clause:
self.else_clause.analyse_declarations(env)
def analyse_expressions(self, env):
import ExprNodes
self.target.analyse_target_types(env)
self.bound1.analyse_types(env)
self.bound2.analyse_types(env)
self.bound1 = self.bound1.coerce_to_integer(env)
self.bound2 = self.bound2.coerce_to_integer(env)
if not (self.bound2.is_name or self.bound2.is_literal):
self.bound2 = self.bound2.coerce_to_temp(env)
target_type = self.target.type
if not (target_type.is_pyobject or target_type.is_int):
error(self.target.pos,
"Integer for-loop variable must be of type int or Python object")
#if not (target_type.is_pyobject
# or target_type.assignable_from(PyrexTypes.c_int_type)):
# error(self.target.pos,
# "Cannot assign integer to variable of type '%s'" % target_type)
if target_type.is_int:
self.is_py_target = 0
self.loopvar_name = self.target.entry.cname
self.py_loopvar_node = None
else:
self.is_py_target = 1
c_loopvar_node = ExprNodes.TempNode(self.pos,
PyrexTypes.c_long_type, env)
c_loopvar_node.allocate_temps(env)
self.loopvar_name = c_loopvar_node.result()
self.py_loopvar_node = \
ExprNodes.CloneNode(c_loopvar_node).coerce_to_pyobject(env)
self.bound1.allocate_temps(env)
self.bound2.allocate_temps(env)
if self.is_py_target:
self.py_loopvar_node.allocate_temps(env)
self.target.allocate_target_temps(env, self.py_loopvar_node)
#self.target.release_target_temp(env)
#self.py_loopvar_node.release_temp(env)
self.body.analyse_expressions(env)
if self.is_py_target:
c_loopvar_node.release_temp(env)
if self.else_clause:
self.else_clause.analyse_expressions(env)
self.bound1.release_temp(env)
self.bound2.release_temp(env)
def generate_execution_code(self, code):
old_loop_labels = code.new_loop_labels()
self.bound1.generate_evaluation_code(code)
self.bound2.generate_evaluation_code(code)
offset, incop = self.relation_table[self.relation1]
code.putln(
"for (%s = %s%s; %s %s %s; %s%s) {" % (
self.loopvar_name,
self.bound1.result(), offset,
self.loopvar_name, self.relation2, self.bound2.result(),
incop, self.loopvar_name))
if self.py_loopvar_node:
self.py_loopvar_node.generate_evaluation_code(code)
self.target.generate_assignment_code(self.py_loopvar_node, code)
self.body.generate_execution_code(code)
code.put_label(code.continue_label)
code.putln("}")
break_label = code.break_label
code.set_loop_labels(old_loop_labels)
if self.else_clause:
code.putln("/*else*/ {")
self.else_clause.generate_execution_code(code)
code.putln("}")
code.put_label(break_label)
self.bound1.generate_disposal_code(code)
self.bound2.generate_disposal_code(code)
relation_table = {
# {relop : (initial offset, increment op)}
'<=': ("", "++"),
'<' : ("+1", "++"),
'>=': ("", "--"),
'>' : ("-1", "--")
}
class TryExceptStatNode(StatNode):
# try .. except statement
#
# body StatNode
# except_clauses [ExceptClauseNode]
# else_clause StatNode or None
# cleanup_list [Entry] temps to clean up on error
def analyse_declarations(self, env):
self.body.analyse_declarations(env)
for except_clause in self.except_clauses:
except_clause.analyse_declarations(env)
if self.else_clause:
self.else_clause.analyse_declarations(env)
self.gil_check(env)
def analyse_expressions(self, env):
self.body.analyse_expressions(env)
self.cleanup_list = env.free_temp_entries[:]
for except_clause in self.except_clauses:
except_clause.analyse_expressions(env)
if self.else_clause:
self.else_clause.analyse_expressions(env)
self.gil_check(env)
gil_message = "Try-except statement"
def generate_execution_code(self, code):
old_error_label = code.new_error_label()
our_error_label = code.error_label
end_label = code.new_label()
code.putln(
"/*try:*/ {")
self.body.generate_execution_code(code)
code.putln(
"}")
code.error_label = old_error_label
if self.else_clause:
code.putln(
"/*else:*/ {")
self.else_clause.generate_execution_code(code)
code.putln(
"}")
code.put_goto(end_label)
code.put_label(our_error_label)
code.put_var_xdecrefs_clear(self.cleanup_list)
default_clause_seen = 0
for except_clause in self.except_clauses:
if not except_clause.pattern:
default_clause_seen = 1
else:
if default_clause_seen:
error(except_clause.pos, "Default except clause not last")
except_clause.generate_handling_code(code, end_label)
if not default_clause_seen:
code.put_goto(code.error_label)
code.put_label(end_label)
class ExceptClauseNode(Node):
# Part of try ... except statement.
#
# pattern ExprNode
# target ExprNode or None
# body StatNode
# match_flag string result of exception match
# exc_value ExcValueNode used internally
# function_name string qualified name of enclosing function
# exc_vars (string * 3) local exception variables
def analyse_declarations(self, env):
if self.target:
self.target.analyse_target_declaration(env)
self.body.analyse_declarations(env)
def analyse_expressions(self, env):
import ExprNodes
genv = env.global_scope()
self.function_name = env.qualified_name
if self.pattern:
self.pattern.analyse_expressions(env)
self.pattern = self.pattern.coerce_to_pyobject(env)
self.match_flag = env.allocate_temp(PyrexTypes.c_int_type)
self.pattern.release_temp(env)
env.release_temp(self.match_flag)
self.exc_vars = [env.allocate_temp(py_object_type) for i in xrange(3)]
if self.target:
self.exc_value = ExprNodes.ExcValueNode(self.pos, env, self.exc_vars[1])
self.exc_value.allocate_temps(env)
self.target.analyse_target_expression(env, self.exc_value)
self.body.analyse_expressions(env)
for var in self.exc_vars:
env.release_temp(var)
# env.use_utility_code(get_exception_utility_code)
def generate_handling_code(self, code, end_label):
code.mark_pos(self.pos)
if self.pattern:
self.pattern.generate_evaluation_code(code)
code.putln(
"%s = PyErr_ExceptionMatches(%s);" % (
self.match_flag,
self.pattern.py_result()))
self.pattern.generate_disposal_code(code)
code.putln(
"if (%s) {" %
self.match_flag)
else:
code.putln(
"/*except:*/ {")
code.putln(
'__Pyx_AddTraceback("%s");' % (self.function_name))
# We always have to fetch the exception value even if
# there is no target, because this also normalises the
# exception and stores it in the thread state.
exc_args = "&%s, &%s, &%s" % tuple(self.exc_vars)
code.use_utility_code(get_exception_utility_code)
code.putln("if (__Pyx_GetException(%s) < 0) %s" % (exc_args,
code.error_goto(self.pos)))
if self.target:
self.exc_value.generate_evaluation_code(code)
self.target.generate_assignment_code(self.exc_value, code)
old_exc_vars = code.exc_vars
code.exc_vars = self.exc_vars
self.body.generate_execution_code(code)
code.exc_vars = old_exc_vars
for var in self.exc_vars:
code.putln("Py_DECREF(%s); %s = 0;" % (var, var))
code.put_goto(end_label)
code.putln(
"}")
class TryFinallyStatNode(StatNode):
# try ... finally statement
#
# body StatNode
# finally_clause StatNode
#
# cleanup_list [Entry] temps to clean up on error
#
# The plan is that we funnel all continue, break
# return and error gotos into the beginning of the
# finally block, setting a variable to remember which
# one we're doing. At the end of the finally block, we
# switch on the variable to figure out where to go.
# In addition, if we're doing an error, we save the
# exception on entry to the finally block and restore
# it on exit.
preserve_exception = 1
disallow_continue_in_try_finally = 0
# There doesn't seem to be any point in disallowing
# continue in the try block, since we have no problem
# handling it.
def analyse_declarations(self, env):
self.body.analyse_declarations(env)
self.finally_clause.analyse_declarations(env)
def analyse_expressions(self, env):
self.body.analyse_expressions(env)
self.cleanup_list = env.free_temp_entries[:]
self.finally_clause.analyse_expressions(env)
self.gil_check(env)
gil_message = "Try-finally statement"
def generate_execution_code(self, code):
old_error_label = code.error_label
old_labels = code.all_new_labels()
new_labels = code.get_all_labels()
new_error_label = code.error_label
catch_label = code.new_label()
code.putln(
"/*try:*/ {")
if self.disallow_continue_in_try_finally:
was_in_try_finally = code.in_try_finally
code.in_try_finally = 1
self.body.generate_execution_code(code)
if self.disallow_continue_in_try_finally:
code.in_try_finally = was_in_try_finally
code.putln(
"}")
code.putln(
"/*finally:*/ {")
cases_used = []
error_label_used = 0
for i, new_label in enumerate(new_labels):
if new_label in code.labels_used:
cases_used.append(i)
if new_label == new_error_label:
error_label_used = 1
error_label_case = i
if cases_used:
code.putln(
"int __pyx_why;")
if error_label_used and self.preserve_exception:
code.putln(
"PyObject *%s, *%s, *%s;" % Naming.exc_vars)
code.putln(
"int %s;" % Naming.exc_lineno_name)
code.use_label(catch_label)
code.putln(
"__pyx_why = 0; goto %s;" % catch_label)
for i in cases_used:
new_label = new_labels[i]
#if new_label and new_label <> "<try>":
if new_label == new_error_label and self.preserve_exception:
self.put_error_catcher(code,
new_error_label, i+1, catch_label)
else:
code.putln(
"%s: __pyx_why = %s; goto %s;" % (
new_label,
i+1,
catch_label))
code.put_label(catch_label)
code.set_all_labels(old_labels)
if error_label_used:
code.new_error_label()
finally_error_label = code.error_label
self.finally_clause.generate_execution_code(code)
if error_label_used:
if finally_error_label in code.labels_used and self.preserve_exception:
over_label = code.new_label()
code.put_goto(over_label);
code.put_label(finally_error_label)
code.putln("if (__pyx_why == %d) {" % (error_label_case + 1))
for var in Naming.exc_vars:
code.putln("Py_XDECREF(%s);" % var)
code.putln("}")
code.put_goto(old_error_label)
code.put_label(over_label)
code.error_label = old_error_label
if cases_used:
code.putln(
"switch (__pyx_why) {")
for i in cases_used:
old_label = old_labels[i]
if old_label == old_error_label and self.preserve_exception:
self.put_error_uncatcher(code, i+1, old_error_label)
else:
code.use_label(old_label)
code.putln(
"case %s: goto %s;" % (
i+1,
old_label))
code.putln(
"}")
code.putln(
"}")
def put_error_catcher(self, code, error_label, i, catch_label):
code.putln(
"%s: {" %
error_label)
code.putln(
"__pyx_why = %s;" %
i)
code.put_var_xdecrefs_clear(self.cleanup_list)
code.putln(
"PyErr_Fetch(&%s, &%s, &%s);" %
Naming.exc_vars)
code.putln(
"%s = %s;" % (
Naming.exc_lineno_name, Naming.lineno_cname))
#code.putln(
# "goto %s;" %
# catch_label)
code.put_goto(catch_label)
code.putln(
"}")
def put_error_uncatcher(self, code, i, error_label):
code.putln(
"case %s: {" %
i)
code.putln(
"PyErr_Restore(%s, %s, %s);" %
Naming.exc_vars)
code.putln(
"%s = %s;" % (
Naming.lineno_cname, Naming.exc_lineno_name))
for var in Naming.exc_vars:
code.putln(
"%s = 0;" %
var)
code.put_goto(error_label)
code.putln(
"}")
class GILStatNode(TryFinallyStatNode):
# 'with gil' or 'with nogil' statement
#
# state string 'gil' or 'nogil'
preserve_exception = 0
def __init__(self, pos, state, body):
self.state = state
TryFinallyStatNode.__init__(self, pos,
body = body,
finally_clause = GILExitNode(pos, state = state))
def analyse_expressions(self, env):
was_nogil = env.nogil
env.nogil = 1
TryFinallyStatNode.analyse_expressions(self, env)
env.nogil = was_nogil
def gil_check(self, env):
pass
def generate_execution_code(self, code):
code.putln("/*with %s:*/ {" % self.state)
if self.state == 'gil':
code.putln("PyGILState_STATE _save = PyGILState_Ensure();")
else:
code.putln("PyThreadState *_save;")
code.putln("Py_UNBLOCK_THREADS")
TryFinallyStatNode.generate_execution_code(self, code)
code.putln("}")
class GILExitNode(StatNode):
# Used as the 'finally' block in a GILStatNode
#
# state string 'gil' or 'nogil'
def analyse_expressions(self, env):
pass
def generate_execution_code(self, code):
if self.state == 'gil':
code.putln("PyGILState_Release();")
else:
code.putln("Py_BLOCK_THREADS")
class CImportStatNode(StatNode):
# cimport statement
#
# module_name string Qualified name of module being imported
# as_name string or None Name specified in "as" clause, if any
def analyse_declarations(self, env):
module_scope = env.find_module(self.module_name, self.pos)
if "." in self.module_name:
names = self.module_name.split(".")
top_name = names[0]
top_module_scope = env.context.find_submodule(top_name)
module_scope = top_module_scope
for name in names[1:]:
submodule_scope = module_scope.find_submodule(name)
module_scope.declare_module(name, submodule_scope, self.pos)
if not self.as_name:
env.add_imported_module(submodule_scope)
module_scope = submodule_scope
if self.as_name:
env.declare_module(self.as_name, module_scope, self.pos)
env.add_imported_module(module_scope)
else:
env.declare_module(top_name, top_module_scope, self.pos)
env.add_imported_module(top_module_scope)
else:
name = self.as_name or self.module_name
env.declare_module(name, module_scope, self.pos)
env.add_imported_module(module_scope)
def analyse_expressions(self, env):
pass
def generate_execution_code(self, code):
pass
class FromCImportStatNode(StatNode):
# from ... cimport statement
#
# module_name string Qualified name of module
# imported_names Parsing.ImportedName Names to be imported
def analyse_declarations(self, env):
module_scope = env.find_module(self.module_name, self.pos)
env.add_imported_module(module_scope)
for imp in self.imported_names:
kind = imp.kind
#entry = module_scope.find(imp.name, imp.pos)
entry = module_scope.lookup(imp.name)
if entry:
if kind and not self.declaration_matches(entry, kind):
entry.redeclared(pos)
else:
if kind == 'struct' or kind == 'union':
entry = module_scope.declare_struct_or_union(imp.name,
kind = kind, scope = None, typedef_flag = 0, pos = imp.pos)
elif kind == 'class':
entry = module_scope.declare_c_class(imp.name, pos = imp.pos,
module_name = self.module_name)
else:
error(imp.pos, "Name '%s' not declared in module '%s'"
% (imp.name, self.module_name))
if entry:
local_name = imp.as_name or imp.name
env.add_imported_entry(local_name, entry, imp.pos)
def declaration_matches(self, entry, kind):
if not entry.is_type:
return 0
type = entry.type
if kind == 'class':
if not type.is_extension_type:
return 0
else:
if not type.is_struct_or_union:
return 0
if kind <> type.kind:
return 0
return 1
def analyse_expressions(self, env):
pass
def generate_execution_code(self, code):
pass
class FromImportStatNode(StatNode):
# from ... import statement
#
# module ImportNode
# items [(string, NameNode)]
# #interned_items [(string, NameNode)]
# item PyTempNode used internally
def analyse_declarations(self, env):
for _, target in self.items:
target.analyse_target_declaration(env)
def analyse_expressions(self, env):
import ExprNodes
self.module.analyse_expressions(env)
self.item = ExprNodes.PyTempNode(self.pos, env)
self.item.allocate_temp(env)
#self.interned_items = []
for name, target in self.items:
#self.interned_items.append((env.intern(name), target))
target.analyse_target_expression(env, None)
self.module.release_temp(env)
self.item.release_temp(env)
def generate_execution_code(self, code):
self.module.generate_evaluation_code(code)
#for cname, target in self.interned_items:
for name, target in self.items:
cname = code.intern(name)
code.putln(
'%s = PyObject_GetAttr(%s, %s); if (!%s) %s' % (
self.item.result(),
self.module.py_result(),
cname,
self.item.result(),
code.error_goto(self.pos)))
target.generate_assignment_code(self.item, code)
self.module.generate_disposal_code(code)
#------------------------------------------------------------------------------------
#
# Runtime support code
#
#------------------------------------------------------------------------------------
#utility_function_predeclarations = \
#"""
#typedef struct {PyObject **p; char *s;} __Pyx_InternTabEntry; /*proto*/
#typedef struct {PyObject **p; char *s; long n;} __Pyx_StringTabEntry; /*proto*/
#"""
utility_function_predeclarations = \
"""
typedef struct {PyObject **p; int i; char *s; long n;} __Pyx_StringTabEntry; /*proto*/
"""
#get_name_predeclaration = \
#"static PyObject *__Pyx_GetName(PyObject *dict, char *name); /*proto*/"
#get_name_interned_predeclaration = \
#"static PyObject *__Pyx_GetName(PyObject *dict, PyObject *name); /*proto*/"
#------------------------------------------------------------------------------------
printing_utility_code = [
"""
static int __Pyx_PrintItem(PyObject *); /*proto*/
static int __Pyx_PrintNewline(void); /*proto*/
""",r"""
static PyObject *__Pyx_GetStdout(void) {
PyObject *f = PySys_GetObject("stdout");
if (!f) {
PyErr_SetString(PyExc_RuntimeError, "lost sys.stdout");
}
return f;
}
static int __Pyx_PrintItem(PyObject *v) {
PyObject *f;
if (!(f = __Pyx_GetStdout()))
return -1;
if (PyFile_SoftSpace(f, 1)) {
if (PyFile_WriteString(" ", f) < 0)
return -1;
}
if (PyFile_WriteObject(v, f, Py_PRINT_RAW) < 0)
return -1;
if (PyString_Check(v)) {
char *s = PyString_AsString(v);
Py_ssize_t len = PyString_Size(v);
if (len > 0 &&
isspace(Py_CHARMASK(s[len-1])) &&
s[len-1] != ' ')
PyFile_SoftSpace(f, 0);
}
return 0;
}
static int __Pyx_PrintNewline(void) {
PyObject *f;
if (!(f = __Pyx_GetStdout()))
return -1;
if (PyFile_WriteString("\n", f) < 0)
return -1;
PyFile_SoftSpace(f, 0);
return 0;
}
"""]
#------------------------------------------------------------------------------------
# The following function is based on do_raise() from ceval.c.
raise_utility_code = [
"""
static void __Pyx_Raise(PyObject *type, PyObject *value, PyObject *tb); /*proto*/
""","""
static void __Pyx_Raise(PyObject *type, PyObject *value, PyObject *tb) {
Py_XINCREF(type);
Py_XINCREF(value);
Py_XINCREF(tb);
/* First, check the traceback argument, replacing None with NULL. */
if (tb == Py_None) {
Py_DECREF(tb);
tb = 0;
}
else if (tb != NULL && !PyTraceBack_Check(tb)) {
PyErr_SetString(PyExc_TypeError,
"raise: arg 3 must be a traceback or None");
goto raise_error;
}
/* Next, replace a missing value with None */
if (value == NULL) {
value = Py_None;
Py_INCREF(value);
}
#if PY_VERSION_HEX < 0x02050000
if (!PyClass_Check(type))
#else
if (!PyType_Check(type))
#endif
{
/* Raising an instance. The value should be a dummy. */
if (value != Py_None) {
PyErr_SetString(PyExc_TypeError,
"instance exception may not have a separate value");
goto raise_error;
}
/* Normalize to raise <class>, <instance> */
Py_DECREF(value);
value = type;
#if PY_VERSION_HEX < 0x02050000
if (PyInstance_Check(type)) {
type = (PyObject*) ((PyInstanceObject*)type)->in_class;
Py_INCREF(type);
}
else {
PyErr_SetString(PyExc_TypeError,
"raise: exception must be an old-style class or instance");
goto raise_error;
}
#else
type = (PyObject*) type->ob_type;
Py_INCREF(type);
if (!PyType_IsSubtype((PyTypeObject *)type, (PyTypeObject *)PyExc_BaseException)) {
PyErr_SetString(PyExc_TypeError,
"raise: exception class must be a subclass of BaseException");
goto raise_error;
}
#endif
}
PyErr_Restore(type, value, tb);
return;
raise_error:
Py_XDECREF(value);
Py_XDECREF(type);
Py_XDECREF(tb);
return;
}
"""]
#------------------------------------------------------------------------------------
reraise_utility_code = [
"""
static void __Pyx_ReRaise(void); /*proto*/
""","""
static void __Pyx_ReRaise(void) {
PyThreadState *tstate = PyThreadState_Get();
PyObject *type = tstate->exc_type;
PyObject *value = tstate->exc_value;
PyObject *tb = tstate->exc_traceback;
Py_XINCREF(type);
Py_XINCREF(value);
Py_XINCREF(tb);
PyErr_Restore(type, value, tb);
}
"""]
#------------------------------------------------------------------------------------
arg_type_test_utility_code = [
"""
static int __Pyx_ArgTypeTest(PyObject *obj, PyTypeObject *type, int none_allowed, char *name); /*proto*/
""","""
static int __Pyx_ArgTypeTest(PyObject *obj, PyTypeObject *type, int none_allowed, char *name) {
if (!type) {
PyErr_Format(PyExc_SystemError, "Missing type object");
return 0;
}
if ((none_allowed && obj == Py_None) || PyObject_TypeCheck(obj, type))
return 1;
PyErr_Format(PyExc_TypeError,
"Argument '%s' has incorrect type (expected %s, got %s)",
name, type->tp_name, obj->ob_type->tp_name);
return 0;
}
"""]
#------------------------------------------------------------------------------------
#
# __Pyx_GetStarArgs splits the args tuple and kwds dict into two parts
# each, one part suitable for passing to PyArg_ParseTupleAndKeywords,
# and the other containing any extra arguments. On success, replaces
# the borrowed references *args and *kwds with references to a new
# tuple and dict, and passes back new references in *args2 and *kwds2.
# Does not touch any of its arguments on failure.
#
# Any of *kwds, args2 and kwds2 may be 0 (but not args or kwds). If
# *kwds == 0, it is not changed. If kwds2 == 0 and *kwds != 0, a new
# reference to the same dictionary is passed back in *kwds.
#
# If rqd_kwds is not 0, it is an array of booleans corresponding to the
# names in kwd_list, indicating required keyword arguments. If any of
# these are not present in kwds, an exception is raised.
#
get_starargs_utility_code = [
"""
static int __Pyx_GetStarArgs(PyObject **args, PyObject **kwds, char *kwd_list[], \
Py_ssize_t nargs, PyObject **args2, PyObject **kwds2, char rqd_kwds[]); /*proto*/
""","""
static int __Pyx_GetStarArgs(
PyObject **args,
PyObject **kwds,
char *kwd_list[],
Py_ssize_t nargs,
PyObject **args2,
PyObject **kwds2,
char rqd_kwds[])
{
PyObject *x = 0, *args1 = 0, *kwds1 = 0;
int i;
char **p;
if (args2)
*args2 = 0;
if (kwds2)
*kwds2 = 0;
if (args2) {
args1 = PyTuple_GetSlice(*args, 0, nargs);
if (!args1)
goto bad;
*args2 = PyTuple_GetSlice(*args, nargs, PyTuple_GET_SIZE(*args));
if (!*args2)
goto bad;
}
else if (PyTuple_GET_SIZE(*args) > nargs) {
int m = nargs;
int n = PyTuple_GET_SIZE(*args);
PyErr_Format(PyExc_TypeError,
"function takes at most %d positional arguments (%d given)",
m, n);
goto bad;
}
else {
args1 = *args;
Py_INCREF(args1);
}
if (rqd_kwds && !*kwds)
for (i = 0, p = kwd_list; *p; i++, p++)
if (rqd_kwds[i])
goto missing_kwarg;
if (kwds2) {
if (*kwds) {
kwds1 = PyDict_New();
if (!kwds1)
goto bad;
*kwds2 = PyDict_Copy(*kwds);
if (!*kwds2)
goto bad;
for (i = 0, p = kwd_list; *p; i++, p++) {
x = PyDict_GetItemString(*kwds, *p);
if (x) {
if (PyDict_SetItemString(kwds1, *p, x) < 0)
goto bad;
if (PyDict_DelItemString(*kwds2, *p) < 0)
goto bad;
}
else if (rqd_kwds && rqd_kwds[i])
goto missing_kwarg;
}
}
else {
*kwds2 = PyDict_New();
if (!*kwds2)
goto bad;
}
}
else {
kwds1 = *kwds;
Py_XINCREF(kwds1);
if (rqd_kwds && *kwds)
for (i = 0, p = kwd_list; *p; i++, p++)
if (rqd_kwds[i] && !PyDict_GetItemString(*kwds, *p))
goto missing_kwarg;
}
*args = args1;
*kwds = kwds1;
return 0;
missing_kwarg:
PyErr_Format(PyExc_TypeError,
"required keyword argument '%s' is missing", *p);
bad:
Py_XDECREF(args1);
Py_XDECREF(kwds1);
if (args2) {
Py_XDECREF(*args2);
}
if (kwds2) {
Py_XDECREF(*kwds2);
}
return -1;
}
"""]
#------------------------------------------------------------------------------------
unraisable_exception_utility_code = [
"""
static void __Pyx_WriteUnraisable(char *name); /*proto*/
""","""
static void __Pyx_WriteUnraisable(char *name) {
PyObject *old_exc, *old_val, *old_tb;
PyObject *ctx;
PyErr_Fetch(&old_exc, &old_val, &old_tb);
ctx = PyString_FromString(name);
PyErr_Restore(old_exc, old_val, old_tb);
if (!ctx)
ctx = Py_None;
PyErr_WriteUnraisable(ctx);
}
"""]
#------------------------------------------------------------------------------------
traceback_utility_code = [
"""
static void __Pyx_AddTraceback(char *funcname); /*proto*/
""","""
#include "compile.h"
#include "frameobject.h"
#include "traceback.h"
static void __Pyx_AddTraceback(char *funcname) {
PyObject *py_srcfile = 0;
PyObject *py_funcname = 0;
PyObject *py_globals = 0;
PyObject *empty_tuple = 0;
PyObject *empty_string = 0;
PyCodeObject *py_code = 0;
PyFrameObject *py_frame = 0;
py_srcfile = PyString_FromString(%(FILENAME)s);
if (!py_srcfile) goto bad;
py_funcname = PyString_FromString(funcname);
if (!py_funcname) goto bad;
py_globals = PyModule_GetDict(%(GLOBALS)s);
if (!py_globals) goto bad;
empty_tuple = PyTuple_New(0);
if (!empty_tuple) goto bad;
empty_string = PyString_FromString("");
if (!empty_string) goto bad;
py_code = PyCode_New(
0, /*int argcount,*/
0, /*int nlocals,*/
0, /*int stacksize,*/
0, /*int flags,*/
empty_string, /*PyObject *code,*/
empty_tuple, /*PyObject *consts,*/
empty_tuple, /*PyObject *names,*/
empty_tuple, /*PyObject *varnames,*/
empty_tuple, /*PyObject *freevars,*/
empty_tuple, /*PyObject *cellvars,*/
py_srcfile, /*PyObject *filename,*/
py_funcname, /*PyObject *name,*/
%(LINENO)s, /*int firstlineno,*/
empty_string /*PyObject *lnotab*/
);
if (!py_code) goto bad;
py_frame = PyFrame_New(
PyThreadState_Get(), /*PyThreadState *tstate,*/
py_code, /*PyCodeObject *code,*/
py_globals, /*PyObject *globals,*/
0 /*PyObject *locals*/
);
if (!py_frame) goto bad;
py_frame->f_lineno = %(LINENO)s;
PyTraceBack_Here(py_frame);
bad:
Py_XDECREF(py_srcfile);
Py_XDECREF(py_funcname);
Py_XDECREF(empty_tuple);
Py_XDECREF(empty_string);
Py_XDECREF(py_code);
Py_XDECREF(py_frame);
}
""" % {
'FILENAME': Naming.filename_cname,
'LINENO': Naming.lineno_cname,
'GLOBALS': Naming.module_cname
}]
#------------------------------------------------------------------------------------
set_vtable_utility_code = [
"""
static int __Pyx_SetVtable(PyObject *dict, void *vtable); /*proto*/
""","""
static int __Pyx_SetVtable(PyObject *dict, void *vtable) {
PyObject *pycobj = 0;
int result;
pycobj = PyCObject_FromVoidPtr(vtable, 0);
if (!pycobj)
goto bad;
if (PyDict_SetItemString(dict, "__pyx_vtable__", pycobj) < 0)
goto bad;
result = 0;
goto done;
bad:
result = -1;
done:
Py_XDECREF(pycobj);
return result;
}
"""]
#------------------------------------------------------------------------------------
get_vtable_utility_code = [
"""
static int __Pyx_GetVtable(PyObject *dict, void *vtabptr); /*proto*/
""",r"""
static int __Pyx_GetVtable(PyObject *dict, void *vtabptr) {
int result;
PyObject *pycobj;
pycobj = PyMapping_GetItemString(dict, "__pyx_vtable__");
if (!pycobj)
goto bad;
*(void **)vtabptr = PyCObject_AsVoidPtr(pycobj);
if (!*(void **)vtabptr)
goto bad;
result = 0;
goto done;
bad:
result = -1;
done:
Py_XDECREF(pycobj);
return result;
}
"""]
#------------------------------------------------------------------------------------
#init_intern_tab_utility_code = [
#"""
#static int __Pyx_InternStrings(__Pyx_InternTabEntry *t); /*proto*/
#""","""
#static int __Pyx_InternStrings(__Pyx_InternTabEntry *t) {
# while (t->p) {
# *t->p = PyString_InternFromString(t->s);
# if (!*t->p)
# return -1;
# ++t;
# }
# return 0;
#}
#"""]
#init_intern_tab_utility_code = [
#"""
#static int __Pyx_InternStrings(PyObject **t[]); /*proto*/
#""","""
#static int __Pyx_InternStrings(PyObject **t[]) {
# while (*t) {
# PyString_InternInPlace(*t);
# if (!**t)
# return -1;
# ++t;
# }
# return 0;
#}
#"""]
#------------------------------------------------------------------------------------
init_string_tab_utility_code = [
"""
static int __Pyx_InitStrings(__Pyx_StringTabEntry *t); /*proto*/
""","""
static int __Pyx_InitStrings(__Pyx_StringTabEntry *t) {
while (t->p) {
*t->p = PyString_FromStringAndSize(t->s, t->n - 1);
if (!*t->p)
return -1;
if (t->i)
PyString_InternInPlace(t->p);
++t;
}
return 0;
}
"""]
#------------------------------------------------------------------------------------
get_exception_utility_code = [
"""
static int __Pyx_GetException(PyObject **type, PyObject **value, PyObject **tb); /*proto*/
""","""
static int __Pyx_GetException(PyObject **type, PyObject **value, PyObject **tb) {
PyThreadState *tstate = PyThreadState_Get();
PyErr_Fetch(type, value, tb);
PyErr_NormalizeException(type, value, tb);
if (PyErr_Occurred())
goto bad;
Py_INCREF(*type);
Py_INCREF(*value);
Py_INCREF(*tb);
Py_XDECREF(tstate->exc_type);
Py_XDECREF(tstate->exc_value);
Py_XDECREF(tstate->exc_traceback);
tstate->exc_type = *type;
tstate->exc_value = *value;
tstate->exc_traceback = *tb;
return 0;
bad:
Py_XDECREF(*type);
Py_XDECREF(*value);
Py_XDECREF(*tb);
return -1;
}
"""]
#------------------------------------------------------------------------------------
|