/usr/lib/python3/dist-packages/h5py/h5t.pyx is in python3-h5py 2.2.1-1build2.
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1622 1623 1624 1625 1626 1627 | # This file is part of h5py, a Python interface to the HDF5 library.
#
# http://www.h5py.org
#
# Copyright 2008-2013 Andrew Collette and contributors
#
# License: Standard 3-clause BSD; see "license.txt" for full license terms
# and contributor agreement.
"""
HDF5 "H5T" data-type API
This module contains the datatype identifier class TypeID, and its
subclasses which represent things like integer/float/compound identifiers.
The majority of the H5T API is presented as methods on these identifiers.
"""
# Pyrex compile-time imports
from _objects cimport pdefault
from numpy cimport dtype, ndarray
from h5r cimport Reference, RegionReference
from utils cimport emalloc, efree, \
require_tuple, convert_dims, convert_tuple
from h5py import _conv
# Runtime imports
import sys
from h5 import get_config
import numpy as np
cfg = get_config()
PY3 = sys.version_info[0] == 3
# === Custom C API ============================================================
cpdef TypeID typewrap(hid_t id_):
cdef H5T_class_t cls
cls = H5Tget_class(id_)
if cls == H5T_INTEGER:
pcls = TypeIntegerID
elif cls == H5T_FLOAT:
pcls = TypeFloatID
elif cls == H5T_TIME:
pcls = TypeTimeID
elif cls == H5T_STRING:
pcls = TypeStringID
elif cls == H5T_BITFIELD:
pcls = TypeBitfieldID
elif cls == H5T_OPAQUE:
pcls = TypeOpaqueID
elif cls == H5T_COMPOUND:
pcls = TypeCompoundID
elif cls == H5T_REFERENCE:
pcls = TypeReferenceID
elif cls == H5T_ENUM:
pcls = TypeEnumID
elif cls == H5T_VLEN:
pcls = TypeVlenID
elif cls == H5T_ARRAY:
pcls = TypeArrayID
else:
pcls = TypeID
return pcls(id_)
cdef object lockid(hid_t id_in):
cdef TypeID tid
tid = typewrap(id_in)
tid.locked = 1
return tid
# === Public constants and data structures ====================================
# Enumeration H5T_class_t
NO_CLASS = H5T_NO_CLASS
INTEGER = H5T_INTEGER
FLOAT = H5T_FLOAT
TIME = H5T_TIME
STRING = H5T_STRING
BITFIELD = H5T_BITFIELD
OPAQUE = H5T_OPAQUE
COMPOUND = H5T_COMPOUND
REFERENCE = H5T_REFERENCE
ENUM = H5T_ENUM
VLEN = H5T_VLEN
ARRAY = H5T_ARRAY
# Enumeration H5T_sign_t
SGN_NONE = H5T_SGN_NONE
SGN_2 = H5T_SGN_2
# Enumeration H5T_order_t
ORDER_LE = H5T_ORDER_LE
ORDER_BE = H5T_ORDER_BE
ORDER_VAX = H5T_ORDER_VAX
ORDER_NONE = H5T_ORDER_NONE
DIR_DEFAULT = H5T_DIR_DEFAULT
DIR_ASCEND = H5T_DIR_ASCEND
DIR_DESCEND = H5T_DIR_DESCEND
# Enumeration H5T_str_t
STR_NULLTERM = H5T_STR_NULLTERM
STR_NULLPAD = H5T_STR_NULLPAD
STR_SPACEPAD = H5T_STR_SPACEPAD
# Enumeration H5T_norm_t
NORM_IMPLIED = H5T_NORM_IMPLIED
NORM_MSBSET = H5T_NORM_MSBSET
NORM_NONE = H5T_NORM_NONE
# Enumeration H5T_cset_t:
CSET_ASCII = H5T_CSET_ASCII
# Enumeration H5T_pad_t:
PAD_ZERO = H5T_PAD_ZERO
PAD_ONE = H5T_PAD_ONE
PAD_BACKGROUND = H5T_PAD_BACKGROUND
if sys.byteorder == "little": # Custom python addition
ORDER_NATIVE = H5T_ORDER_LE
else:
ORDER_NATIVE = H5T_ORDER_BE
# For conversion
BKG_NO = H5T_BKG_NO
BKG_TEMP = H5T_BKG_TEMP
BKG_YES = H5T_BKG_YES
# --- Built-in HDF5 datatypes -------------------------------------------------
# IEEE floating-point
IEEE_F32LE = lockid(H5T_IEEE_F32LE)
IEEE_F32BE = lockid(H5T_IEEE_F32BE)
IEEE_F64LE = lockid(H5T_IEEE_F64LE)
IEEE_F64BE = lockid(H5T_IEEE_F64BE)
# Signed 2's complement integer types
STD_I8LE = lockid(H5T_STD_I8LE)
STD_I16LE = lockid(H5T_STD_I16LE)
STD_I32LE = lockid(H5T_STD_I32LE)
STD_I64LE = lockid(H5T_STD_I64LE)
STD_I8BE = lockid(H5T_STD_I8BE)
STD_I16BE = lockid(H5T_STD_I16BE)
STD_I32BE = lockid(H5T_STD_I32BE)
STD_I64BE = lockid(H5T_STD_I64BE)
# Unsigned integers
STD_U8LE = lockid(H5T_STD_U8LE)
STD_U16LE = lockid(H5T_STD_U16LE)
STD_U32LE = lockid(H5T_STD_U32LE)
STD_U64LE = lockid(H5T_STD_U64LE)
STD_U8BE = lockid(H5T_STD_U8BE)
STD_U16BE = lockid(H5T_STD_U16BE)
STD_U32BE = lockid(H5T_STD_U32BE)
STD_U64BE = lockid(H5T_STD_U64BE)
# Native types by bytesize
NATIVE_INT8 = lockid(H5T_NATIVE_INT8)
NATIVE_UINT8 = lockid(H5T_NATIVE_UINT8)
NATIVE_INT16 = lockid(H5T_NATIVE_INT16)
NATIVE_UINT16 = lockid(H5T_NATIVE_UINT16)
NATIVE_INT32 = lockid(H5T_NATIVE_INT32)
NATIVE_UINT32 = lockid(H5T_NATIVE_UINT32)
NATIVE_INT64 = lockid(H5T_NATIVE_INT64)
NATIVE_UINT64 = lockid(H5T_NATIVE_UINT64)
NATIVE_FLOAT = lockid(H5T_NATIVE_FLOAT)
NATIVE_DOUBLE = lockid(H5T_NATIVE_DOUBLE)
# Unix time types
UNIX_D32LE = lockid(H5T_UNIX_D32LE)
UNIX_D64LE = lockid(H5T_UNIX_D64LE)
UNIX_D32BE = lockid(H5T_UNIX_D32BE)
UNIX_D64BE = lockid(H5T_UNIX_D64BE)
# Reference types
STD_REF_OBJ = lockid(H5T_STD_REF_OBJ)
STD_REF_DSETREG = lockid(H5T_STD_REF_DSETREG)
# Null terminated (C) and Fortran string types
C_S1 = lockid(H5T_C_S1)
FORTRAN_S1 = lockid(H5T_FORTRAN_S1)
VARIABLE = H5T_VARIABLE
# Character sets
CSET_ASCII = H5T_CSET_ASCII
CSET_UTF8 = H5T_CSET_UTF8
# Custom Python object pointer type
PYTHON_OBJECT = lockid(_conv.get_python_obj())
# Mini floats
IEEE_F16BE = IEEE_F32BE.copy()
IEEE_F16BE.set_fields(15, 10, 5, 0, 10)
IEEE_F16BE.set_size(2)
IEEE_F16BE.set_ebias(15)
IEEE_F16BE.lock()
IEEE_F16LE = IEEE_F16BE.copy()
IEEE_F16LE.set_order(H5T_ORDER_LE)
IEEE_F16LE.lock()
# Translation tables for HDF5 -> NumPy dtype conversion
cdef dict _order_map = { H5T_ORDER_NONE: '|', H5T_ORDER_LE: '<', H5T_ORDER_BE: '>'}
cdef dict _sign_map = { H5T_SGN_NONE: 'u', H5T_SGN_2: 'i' }
# === General datatype operations =============================================
def create(int classtype, size_t size):
"""(INT classtype, UINT size) => TypeID
Create a new HDF5 type object. Legal class values are
COMPOUND and OPAQUE. Use enum_create for enums.
"""
# HDF5 versions 1.6.X segfault with anything else
if classtype != H5T_COMPOUND and classtype != H5T_OPAQUE:
raise ValueError("Class must be COMPOUND or OPAQUE.")
return typewrap(H5Tcreate(<H5T_class_t>classtype, size))
def open(ObjectID group not None, char* name):
"""(ObjectID group, STRING name) => TypeID
Open a named datatype from a file.
"""
return typewrap(H5Topen(group.id, name))
def array_create(TypeID base not None, object dims_tpl):
"""(TypeID base, TUPLE dimensions) => TypeArrayID
Create a new array datatype, using and HDF5 parent type and
dimensions given via a tuple of positive integers. "Unlimited"
dimensions are not allowed.
"""
cdef hsize_t rank
cdef hsize_t *dims = NULL
require_tuple(dims_tpl, 0, -1, "dims_tpl")
rank = len(dims_tpl)
dims = <hsize_t*>emalloc(sizeof(hsize_t)*rank)
try:
convert_tuple(dims_tpl, dims, rank)
return TypeArrayID(H5Tarray_create(base.id, rank, dims, NULL))
finally:
efree(dims)
def enum_create(TypeID base not None):
"""(TypeID base) => TypeID
Create a new enumerated type based on an (integer) parent type.
"""
return typewrap(H5Tenum_create(base.id))
def vlen_create(TypeID base not None):
"""(TypeID base) => TypeID
Create a new variable-length datatype, using any HDF5 type as a base.
Although the Python interface can manipulate these types, there is no
provision for reading/writing vlen data.
"""
return typewrap(H5Tvlen_create(base.id))
def decode(char* buf):
"""(STRING buf) => TypeID
Unserialize an HDF5 type. You can also do this with the native
Python pickling machinery.
"""
return typewrap(H5Tdecode(<unsigned char*>buf))
# === Base type class =========================================================
cdef class TypeID(ObjectID):
"""
Base class for type identifiers (implements common operations)
* Hashable: If committed; in HDF5 1.8.X, also if locked
* Equality: Logical H5T comparison
"""
def __hash__(self):
if self._hash is None:
try:
# Try to use object header first
return ObjectID.__hash__(self)
except TypeError:
# It's a transient type object
if self.locked:
self._hash = hash(self.encode())
else:
raise TypeError("Only locked or committed types can be hashed")
return self._hash
def __richcmp__(self, object other, int how):
cdef bint truthval = 0
if how != 2 and how != 3:
return NotImplemented
if isinstance(other, TypeID):
truthval = self.equal(other)
if how == 2:
return truthval
return not truthval
def __copy__(self):
cdef TypeID cpy
cpy = ObjectID.__copy__(self)
return cpy
property dtype:
""" A Numpy-style dtype object representing this object.
"""
def __get__(self):
return self.py_dtype()
cdef object py_dtype(self):
raise TypeError("No NumPy equivalent for %s exists" % self.__class__.__name__)
def commit(self, ObjectID group not None, char* name, ObjectID lcpl=None):
"""(ObjectID group, STRING name, PropID lcpl=None)
Commit this (transient) datatype to a named datatype in a file.
If present, lcpl may be a link creation property list.
"""
H5Tcommit2(group.id, name, self.id, pdefault(lcpl),
H5P_DEFAULT, H5P_DEFAULT)
def committed(self):
"""() => BOOL is_comitted
Determine if a given type object is named (T) or transient (F).
"""
return <bint>(H5Tcommitted(self.id))
def copy(self):
"""() => TypeID
Create a copy of this type object.
"""
return typewrap(H5Tcopy(self.id))
def equal(self, TypeID typeid):
"""(TypeID typeid) => BOOL
Logical comparison between datatypes. Also called by
Python's "==" operator.
"""
return <bint>(H5Tequal(self.id, typeid.id))
def lock(self):
"""()
Lock this datatype, which makes it immutable and indestructible.
Once locked, it can't be unlocked.
"""
H5Tlock(self.id)
self.locked = 1
def get_class(self):
"""() => INT classcode
Determine the datatype's class code.
"""
return <int>H5Tget_class(self.id)
def set_size(self, size_t size):
"""(UINT size)
Set the total size of the datatype, in bytes.
"""
H5Tset_size(self.id, size)
def get_size(self):
""" () => INT size
Determine the total size of a datatype, in bytes.
"""
return H5Tget_size(self.id)
def get_super(self):
"""() => TypeID
Determine the parent type of an array, enumeration or vlen datatype.
"""
return typewrap(H5Tget_super(self.id))
def detect_class(self, int classtype):
"""(INT classtype) => BOOL class_is_present
Determine if a member of the given class exists in a compound
datatype. The search is recursive.
"""
return <bint>(H5Tdetect_class(self.id, <H5T_class_t>classtype))
def _close(self):
"""()
Close this datatype. If it's locked, nothing happens.
You shouldn't ordinarily need to call this function; datatype
objects are automatically closed when they're deallocated.
"""
if not self.locked:
H5Tclose(self.id)
def encode(self):
"""() => STRING
Serialize an HDF5 type. Bear in mind you can also use the
native Python pickle/unpickle machinery to do this. The
returned string may contain binary values, including NULLs.
"""
cdef size_t nalloc = 0
cdef char* buf = NULL
H5Tencode(self.id, NULL, &nalloc)
buf = <char*>emalloc(sizeof(char)*nalloc)
try:
H5Tencode(self.id, <unsigned char*>buf, &nalloc)
pystr = PyBytes_FromStringAndSize(buf, nalloc)
finally:
efree(buf)
return pystr
def __reduce__(self):
return (type(self), (-1,), self.encode())
def __setstate__(self, char* state):
self.id = H5Tdecode(<unsigned char*>state)
# === Top-level classes (inherit directly from TypeID) ========================
cdef class TypeArrayID(TypeID):
"""
Represents an array datatype
"""
def get_array_ndims(self):
"""() => INT rank
Get the rank of the given array datatype.
"""
return H5Tget_array_ndims(self.id)
def get_array_dims(self):
"""() => TUPLE dimensions
Get the dimensions of the given array datatype as
a tuple of integers.
"""
cdef hsize_t rank
cdef hsize_t* dims = NULL
rank = H5Tget_array_dims(self.id, NULL, NULL)
dims = <hsize_t*>emalloc(sizeof(hsize_t)*rank)
try:
H5Tget_array_dims(self.id, dims, NULL)
return convert_dims(dims, rank)
finally:
efree(dims)
cdef object py_dtype(self):
# Numpy translation function for array types
cdef TypeID tmp_type
tmp_type = self.get_super()
base_dtype = tmp_type.py_dtype()
shape = self.get_array_dims()
return dtype( (base_dtype, shape) )
cdef class TypeOpaqueID(TypeID):
"""
Represents an opaque type
"""
def set_tag(self, char* tag):
"""(STRING tag)
Set a string describing the contents of an opaque datatype.
Limited to 256 characters.
"""
H5Tset_tag(self.id, tag)
def get_tag(self):
"""() => STRING tag
Get the tag associated with an opaque datatype.
"""
cdef char* buf = NULL
try:
buf = H5Tget_tag(self.id)
assert buf != NULL
tag = buf
return tag
finally:
free(buf)
cdef object py_dtype(self):
# Numpy translation function for opaque types
return dtype("|V" + str(self.get_size()))
cdef class TypeStringID(TypeID):
"""
String datatypes, both fixed and vlen.
"""
def is_variable_str(self):
"""() => BOOL is_variable
Determine if the given string datatype is a variable-length string.
"""
return <bint>(H5Tis_variable_str(self.id))
def get_cset(self):
"""() => INT character_set
Retrieve the character set used for a string.
"""
return <int>H5Tget_cset(self.id)
def set_cset(self, int cset):
"""(INT character_set)
Set the character set used for a string.
"""
H5Tset_cset(self.id, <H5T_cset_t>cset)
def get_strpad(self):
"""() => INT padding_type
Get the padding type. Legal values are:
STR_NULLTERM
NULL termination only (C style)
STR_NULLPAD
Pad buffer with NULLs
STR_SPACEPAD
Pad buffer with spaces (FORTRAN style)
"""
return <int>H5Tget_strpad(self.id)
def set_strpad(self, int pad):
"""(INT pad)
Set the padding type. Legal values are:
STR_NULLTERM
NULL termination only (C style)
STR_NULLPAD
Pad buffer with NULLs
STR_SPACEPAD
Pad buffer with spaces (FORTRAN style)
"""
H5Tset_strpad(self.id, <H5T_str_t>pad)
cdef object py_dtype(self):
# Numpy translation function for string types
if self.is_variable_str():
if self.get_cset() == H5T_CSET_ASCII:
return special_dtype(vlen=bytes)
elif self.get_cset() == H5T_CSET_UTF8:
return special_dtype(vlen=unicode)
else:
raise TypeError("Unknown string encoding (value %d)" % self.get_cset())
return dtype("|S" + str(self.get_size()))
cdef class TypeVlenID(TypeID):
"""
Non-string vlen datatypes.
"""
pass
cdef class TypeTimeID(TypeID):
"""
Unix-style time_t (deprecated)
"""
pass
cdef class TypeBitfieldID(TypeID):
"""
HDF5 bitfield type
"""
pass
cdef class TypeReferenceID(TypeID):
"""
HDF5 object or region reference
"""
cdef object py_dtype(self):
if H5Tequal(self.id, H5T_STD_REF_OBJ):
return special_dtype(ref=Reference)
elif H5Tequal(self.id, H5T_STD_REF_DSETREG):
return special_dtype(ref=RegionReference)
else:
raise TypeError("Unknown reference type")
# === Numeric classes (integers and floats) ===================================
cdef class TypeAtomicID(TypeID):
"""
Base class for atomic datatypes (float or integer)
"""
def get_order(self):
"""() => INT order
Obtain the byte order of the datatype; one of:
- ORDER_LE
- ORDER_BE
"""
return <int>H5Tget_order(self.id)
def set_order(self, int order):
"""(INT order)
Set the byte order of the datatype; one of:
- ORDER_LE
- ORDER_BE
"""
H5Tset_order(self.id, <H5T_order_t>order)
def get_precision(self):
"""() => UINT precision
Get the number of significant bits (excludes padding).
"""
return H5Tget_precision(self.id)
def set_precision(self, size_t precision):
"""(UINT precision)
Set the number of significant bits (excludes padding).
"""
H5Tset_precision(self.id, precision)
def get_offset(self):
"""() => INT offset
Get the offset of the first significant bit.
"""
return H5Tget_offset(self.id)
def set_offset(self, size_t offset):
"""(UINT offset)
Set the offset of the first significant bit.
"""
H5Tset_offset(self.id, offset)
def get_pad(self):
"""() => (INT lsb_pad_code, INT msb_pad_code)
Determine the padding type. Possible values are:
- PAD_ZERO
- PAD_ONE
- PAD_BACKGROUND
"""
cdef H5T_pad_t lsb
cdef H5T_pad_t msb
H5Tget_pad(self.id, &lsb, &msb)
return (<int>lsb, <int>msb)
def set_pad(self, int lsb, int msb):
"""(INT lsb_pad_code, INT msb_pad_code)
Set the padding type. Possible values are:
- PAD_ZERO
- PAD_ONE
- PAD_BACKGROUND
"""
H5Tset_pad(self.id, <H5T_pad_t>lsb, <H5T_pad_t>msb)
cdef class TypeIntegerID(TypeAtomicID):
"""
Integer atomic datatypes
"""
def get_sign(self):
"""() => INT sign
Get the "signedness" of the datatype; one of:
SGN_NONE
Unsigned
SGN_2
Signed 2's complement
"""
return <int>H5Tget_sign(self.id)
def set_sign(self, int sign):
"""(INT sign)
Set the "signedness" of the datatype; one of:
SGN_NONE
Unsigned
SGN_2
Signed 2's complement
"""
H5Tset_sign(self.id, <H5T_sign_t>sign)
cdef object py_dtype(self):
# Translation function for integer types
return dtype( _order_map[self.get_order()] +
_sign_map[self.get_sign()] + str(self.get_size()) )
cdef class TypeFloatID(TypeAtomicID):
"""
Floating-point atomic datatypes
"""
def get_fields(self):
"""() => TUPLE field_info
Get information about floating-point bit fields. See the HDF5
docs for a full description. Tuple has the following members:
0. UINT spos
1. UINT epos
2. UINT esize
3. UINT mpos
4. UINT msize
"""
cdef size_t spos, epos, esize, mpos, msize
H5Tget_fields(self.id, &spos, &epos, &esize, &mpos, &msize)
return (spos, epos, esize, mpos, msize)
def set_fields(self, size_t spos, size_t epos, size_t esize,
size_t mpos, size_t msize):
"""(UINT spos, UINT epos, UINT esize, UINT mpos, UINT msize)
Set floating-point bit fields. Refer to the HDF5 docs for
argument definitions.
"""
H5Tset_fields(self.id, spos, epos, esize, mpos, msize)
def get_ebias(self):
"""() => UINT ebias
Get the exponent bias.
"""
return H5Tget_ebias(self.id)
def set_ebias(self, size_t ebias):
"""(UINT ebias)
Set the exponent bias.
"""
H5Tset_ebias(self.id, ebias)
def get_norm(self):
"""() => INT normalization_code
Get the normalization strategy. Legal values are:
- NORM_IMPLIED
- NORM_MSBSET
- NORM_NONE
"""
return <int>H5Tget_norm(self.id)
def set_norm(self, int norm):
"""(INT normalization_code)
Set the normalization strategy. Legal values are:
- NORM_IMPLIED
- NORM_MSBSET
- NORM_NONE
"""
H5Tset_norm(self.id, <H5T_norm_t>norm)
def get_inpad(self):
"""() => INT pad_code
Determine the internal padding strategy. Legal values are:
- PAD_ZERO
- PAD_ONE
- PAD_BACKGROUND
"""
return <int>H5Tget_inpad(self.id)
def set_inpad(self, int pad_code):
"""(INT pad_code)
Set the internal padding strategy. Legal values are:
- PAD_ZERO
- PAD_ONE
- PAD_BACKGROUND
"""
H5Tset_inpad(self.id, <H5T_pad_t>pad_code)
cdef object py_dtype(self):
# Translation function for floating-point types
size = self.get_size() # int giving number of bytes
order = _order_map[self.get_order()] # string with '<' or '>'
if size == 2 and not hasattr(np, 'float16'):
# This build doesn't have float16; promote to float32
return dtype(order+"f4")
if size > 8:
# The native NumPy longdouble is used for 96 and 128-bit floats
return dtype(order + "f" + str(np.longdouble(1).dtype.itemsize))
return dtype( _order_map[self.get_order()] + "f" + \
str(self.get_size()) )
# === Composite types (enums and compound) ====================================
cdef class TypeCompositeID(TypeID):
"""
Base class for enumerated and compound types.
"""
def get_nmembers(self):
"""() => INT number_of_members
Determine the number of members in a compound or enumerated type.
"""
return H5Tget_nmembers(self.id)
def get_member_name(self, int member):
"""(INT member) => STRING name
Determine the name of a member of a compound or enumerated type,
identified by its index (0 <= member < nmembers).
"""
cdef char* name
name = NULL
if member < 0:
raise ValueError("Member index must be non-negative.")
try:
name = H5Tget_member_name(self.id, member)
assert name != NULL
pyname = <bytes>name
finally:
free(name)
return pyname
def get_member_index(self, char* name):
"""(STRING name) => INT index
Determine the index of a member of a compound or enumerated datatype
identified by a string name.
"""
return H5Tget_member_index(self.id, name)
cdef class TypeCompoundID(TypeCompositeID):
"""
Represents a compound datatype
"""
def get_member_class(self, int member):
"""(INT member) => INT class
Determine the datatype class of the member of a compound type,
identified by its index (0 <= member < nmembers).
"""
if member < 0:
raise ValueError("Member index must be non-negative.")
return H5Tget_member_class(self.id, member)
def get_member_offset(self, int member):
"""(INT member) => INT offset
Determine the offset, in bytes, of the beginning of the specified
member of a compound datatype.
"""
if member < 0:
raise ValueError("Member index must be non-negative.")
return H5Tget_member_offset(self.id, member)
def get_member_type(self, int member):
"""(INT member) => TypeID
Create a copy of a member of a compound datatype, identified by its
index.
"""
if member < 0:
raise ValueError("Member index must be non-negative.")
return typewrap(H5Tget_member_type(self.id, member))
def insert(self, char* name, size_t offset, TypeID field not None):
"""(STRING name, UINT offset, TypeID field)
Add a named member datatype to a compound datatype. The parameter
offset indicates the offset from the start of the compound datatype,
in bytes.
"""
H5Tinsert(self.id, name, offset, field.id)
def pack(self):
"""()
Recursively removes padding (introduced on account of e.g. compiler
alignment rules) from a compound datatype.
"""
H5Tpack(self.id)
cdef object py_dtype(self):
cdef TypeID tmp_type
cdef list field_names
cdef list field_types
cdef int nfields
field_names = []
field_types = []
nfields = self.get_nmembers()
# First step: read field names and their Numpy dtypes into
# two separate arrays.
for i from 0 <= i < nfields:
tmp_type = self.get_member_type(i)
name = self.get_member_name(i)
field_names.append(name)
field_types.append(tmp_type.py_dtype())
# 1. Check if it should be converted to a complex number
if len(field_names) == 2 and \
tuple(field_names) == (cfg._r_name, cfg._i_name) and \
field_types[0] == field_types[1] and \
field_types[0].kind == 'f':
bstring = field_types[0].str
blen = int(bstring[2:])
nstring = bstring[0] + "c" + str(2*blen)
typeobj = dtype(nstring)
# 2. Otherwise, read all fields of the compound type, in HDF5 order.
else:
if sys.version[0] == '3':
field_names = [x.decode('utf8') for x in field_names]
typeobj = dtype(list(zip(field_names, field_types)))
return typeobj
cdef class TypeEnumID(TypeCompositeID):
"""
Represents an enumerated type
"""
cdef int enum_convert(self, long long *buf, int reverse) except -1:
# Convert the long long value in "buf" to the native representation
# of this (enumerated) type. Conversion performed in-place.
# Reverse: false => llong->type; true => type->llong
cdef hid_t basetype
cdef H5T_class_t class_code
class_code = H5Tget_class(self.id)
if class_code != H5T_ENUM:
raise ValueError("This type (class %d) is not of class ENUM" % class_code)
basetype = H5Tget_super(self.id)
assert basetype > 0
try:
if not reverse:
H5Tconvert(H5T_NATIVE_LLONG, basetype, 1, buf, NULL, H5P_DEFAULT)
else:
H5Tconvert(basetype, H5T_NATIVE_LLONG, 1, buf, NULL, H5P_DEFAULT)
finally:
H5Tclose(basetype)
def enum_insert(self, char* name, long long value):
"""(STRING name, INT/LONG value)
Define a new member of an enumerated type. The value will be
automatically converted to the base type defined for this enum. If
the conversion results in overflow, the value will be silently
clipped.
"""
cdef long long buf
buf = value
self.enum_convert(&buf, 0)
H5Tenum_insert(self.id, name, &buf)
def enum_nameof(self, long long value):
"""(LONG value) => STRING name
Determine the name associated with the given value. Due to a
limitation of the HDF5 library, this can only retrieve names up to
1023 characters in length.
"""
cdef herr_t retval
cdef char name[1024]
cdef long long buf
buf = value
self.enum_convert(&buf, 0)
retval = H5Tenum_nameof(self.id, &buf, name, 1024)
assert retval >= 0
retstring = name
return retstring
def enum_valueof(self, char* name):
"""(STRING name) => LONG value
Get the value associated with an enum name.
"""
cdef long long buf
H5Tenum_valueof(self.id, name, &buf)
self.enum_convert(&buf, 1)
return buf
def get_member_value(self, int idx):
"""(UINT index) => LONG value
Determine the value for the member at the given zero-based index.
"""
cdef herr_t retval
cdef hid_t ptype
cdef long long val
ptype = 0
if idx < 0:
raise ValueError("Index must be non-negative.")
H5Tget_member_value(self.id, idx, &val)
self.enum_convert(&val, 1)
return val
cdef object py_dtype(self):
# Translation function for enum types
cdef TypeID basetype = self.get_super()
nmembers = self.get_nmembers()
members = {}
for idx in xrange(nmembers):
name = self.get_member_name(idx)
val = self.get_member_value(idx)
members[name] = val
ref = {cfg._f_name: 0, cfg._t_name: 1}
# Boolean types have priority over standard enums
if members == ref:
return dtype('bool')
# Convert strings to appropriate representation
members_conv = {}
for name, val in members.iteritems():
try: # ASCII; Py2 -> preserve bytes, Py3 -> make unicode
uname = name.decode('ascii')
if PY3:
name = uname
except UnicodeDecodeError:
try: # Non-ascii; all platforms try unicode
name = name.decode('utf8')
except UnicodeDecodeError:
pass # Last resort: return byte string
members_conv[name] = val
return special_dtype(enum=(basetype.py_dtype(), members_conv))
# === Translation from NumPy dtypes to HDF5 type objects ======================
# The following series of native-C functions each translate a specific class
# of NumPy dtype into an HDF5 type object. The result is guaranteed to be
# transient and unlocked.
cdef dict _float_le = {2: IEEE_F16LE.id, 4: H5T_IEEE_F32LE, 8: H5T_IEEE_F64LE}
cdef dict _float_be = {2: IEEE_F16BE.id, 4: H5T_IEEE_F32BE, 8: H5T_IEEE_F64BE}
cdef dict _float_nt = _float_le if ORDER_NATIVE == H5T_ORDER_LE else _float_be
cdef dict _int_le = {1: H5T_STD_I8LE, 2: H5T_STD_I16LE, 4: H5T_STD_I32LE, 8: H5T_STD_I64LE}
cdef dict _int_be = {1: H5T_STD_I8BE, 2: H5T_STD_I16BE, 4: H5T_STD_I32BE, 8: H5T_STD_I64BE}
cdef dict _int_nt = {1: H5T_NATIVE_INT8, 2: H5T_NATIVE_INT16, 4: H5T_NATIVE_INT32, 8: H5T_NATIVE_INT64}
cdef dict _uint_le = {1: H5T_STD_U8LE, 2: H5T_STD_U16LE, 4: H5T_STD_U32LE, 8: H5T_STD_U64LE}
cdef dict _uint_be = {1: H5T_STD_U8BE, 2: H5T_STD_U16BE, 4: H5T_STD_U32BE, 8: H5T_STD_U64BE}
cdef dict _uint_nt = {1: H5T_NATIVE_UINT8, 2: H5T_NATIVE_UINT16, 4: H5T_NATIVE_UINT32, 8: H5T_NATIVE_UINT64}
cdef TypeFloatID _c_float(dtype dt):
# Floats (single and double)
cdef hid_t tid
try:
if dt.byteorder == c'<':
tid = _float_le[dt.elsize]
elif dt.byteorder == c'>':
tid = _float_be[dt.elsize]
else:
tid = _float_nt[dt.elsize]
except KeyError:
raise TypeError("Unsupported float size (%s)" % dt.elsize)
return TypeFloatID(H5Tcopy(tid))
cdef TypeIntegerID _c_int(dtype dt):
# Integers (ints and uints)
cdef hid_t tid
try:
if dt.kind == c'i':
if dt.byteorder == c'<':
tid = _int_le[dt.elsize]
elif dt.byteorder == c'>':
tid = _int_be[dt.elsize]
else:
tid = _int_nt[dt.elsize]
elif dt.kind == c'u':
if dt.byteorder == c'<':
tid = _uint_le[dt.elsize]
elif dt.byteorder == c'>':
tid = _uint_be[dt.elsize]
else:
tid = _uint_nt[dt.elsize]
else:
raise TypeError('Illegal int kind "%s"' % dt.kind)
except KeyError:
raise TypeError("Unsupported integer size (%s)" % dt.elsize)
return TypeIntegerID(H5Tcopy(tid))
cdef TypeEnumID _c_enum(dtype dt, dict vals):
# Enums
cdef TypeIntegerID base
cdef TypeEnumID out
base = _c_int(dt)
out = TypeEnumID(H5Tenum_create(base.id))
for name in sorted(vals):
if isinstance(name, bytes):
bname = name
else:
bname = unicode(name).encode('utf8')
out.enum_insert(bname, vals[name])
return out
cdef TypeEnumID _c_bool(dtype dt):
# Booleans
global cfg
cdef TypeEnumID out
out = TypeEnumID(H5Tenum_create(H5T_NATIVE_INT8))
out.enum_insert(cfg._f_name, 0)
out.enum_insert(cfg._t_name, 1)
return out
cdef TypeArrayID _c_array(dtype dt, int logical):
# Arrays
cdef dtype base
cdef TypeID type_base
cdef object shape
base, shape = dt.subdtype
try:
shape = tuple(shape)
except TypeError:
try:
shape = (int(shape),)
except TypeError:
raise TypeError("Array shape for dtype must be a sequence or integer")
type_base = py_create(base, logical=logical)
return array_create(type_base, shape)
cdef TypeOpaqueID _c_opaque(dtype dt):
# Opaque
return TypeOpaqueID(H5Tcreate(H5T_OPAQUE, dt.itemsize))
cdef TypeStringID _c_string(dtype dt):
# Strings (fixed-length)
cdef hid_t tid
tid = H5Tcopy(H5T_C_S1)
H5Tset_size(tid, dt.itemsize)
H5Tset_strpad(tid, H5T_STR_NULLPAD)
return TypeStringID(tid)
cdef TypeCompoundID _c_complex(dtype dt):
# Complex numbers (names depend on cfg)
global cfg
cdef hid_t tid, tid_sub
cdef size_t size, off_r, off_i
cdef size_t length = dt.itemsize
cdef char byteorder = dt.byteorder
if length == 8:
size = h5py_size_n64
off_r = h5py_offset_n64_real
off_i = h5py_offset_n64_imag
if byteorder == c'<':
tid_sub = H5T_IEEE_F32LE
elif byteorder == c'>':
tid_sub = H5T_IEEE_F32BE
else:
tid_sub = H5T_NATIVE_FLOAT
elif length == 16:
size = h5py_size_n128
off_r = h5py_offset_n128_real
off_i = h5py_offset_n128_imag
if byteorder == c'<':
tid_sub = H5T_IEEE_F64LE
elif byteorder == c'>':
tid_sub = H5T_IEEE_F64BE
else:
tid_sub = H5T_NATIVE_DOUBLE
else:
raise TypeError("Illegal length %d for complex dtype" % length)
tid = H5Tcreate(H5T_COMPOUND, size)
H5Tinsert(tid, cfg._r_name, off_r, tid_sub)
H5Tinsert(tid, cfg._i_name, off_i, tid_sub)
return TypeCompoundID(tid)
cdef TypeCompoundID _c_compound(dtype dt, int logical):
# Compound datatypes
cdef hid_t tid
cdef TypeID type_tmp
cdef dtype dt_tmp
cdef size_t offset
cdef dict fields = dt.fields
cdef tuple names = dt.names
# Initial size MUST be 1 to avoid segfaults (issue 166)
tid = H5Tcreate(H5T_COMPOUND, 1)
offset = 0
for name in names:
ename = name.encode('utf8') if isinstance(name, unicode) else name
dt_tmp = dt.fields[name][0]
type_tmp = py_create(dt_tmp, logical=logical)
H5Tset_size(tid, offset+type_tmp.get_size())
H5Tinsert(tid, ename, offset, type_tmp.id)
offset += type_tmp.get_size()
return TypeCompoundID(tid)
cdef TypeStringID _c_vlen_str():
# Variable-length strings
cdef hid_t tid
tid = H5Tcopy(H5T_C_S1)
H5Tset_size(tid, H5T_VARIABLE)
return TypeStringID(tid)
cdef TypeStringID _c_vlen_unicode():
cdef hid_t tid
tid = H5Tcopy(H5T_C_S1)
H5Tset_size(tid, H5T_VARIABLE)
H5Tset_cset(tid, H5T_CSET_UTF8)
return TypeStringID(tid)
cdef TypeReferenceID _c_ref(object refclass):
if refclass is Reference:
return STD_REF_OBJ
elif refclass is RegionReference:
return STD_REF_DSETREG
raise TypeError("Unrecognized reference code")
cpdef TypeID py_create(object dtype_in, bint logical=0):
"""(OBJECT dtype_in, BOOL logical=False) => TypeID
Given a Numpy dtype object, generate a byte-for-byte memory-compatible
HDF5 datatype object. The result is guaranteed to be transient and
unlocked.
Argument dtype_in may be a dtype object, or anything which can be
converted to a dtype, including strings like '<i4'.
logical
If this flag is set, instead of returning a byte-for-byte identical
representation of the type, the function returns the closest logically
appropriate HDF5 type. For example, in the case of a "hinted" dtype
of kind "O" representing a string, it would return an HDF5 variable-
length string type.
"""
cdef dtype dt = dtype(dtype_in)
cdef char kind = dt.kind
# Float
if kind == c'f':
return _c_float(dt)
# Integer
elif kind == c'u' or kind == c'i':
if logical:
# Check for an enumeration hint
enum_vals = check_dtype(enum=dt)
if enum_vals is not None:
return _c_enum(dt, enum_vals)
return _c_int(dt)
# Complex
elif kind == c'c':
return _c_complex(dt)
# Compound
elif kind == c'V' and dt.names is not None:
return _c_compound(dt, logical)
# Array or opaque
elif kind == c'V':
if dt.subdtype is not None:
return _c_array(dt, logical)
else:
return _c_opaque(dt)
# String
elif kind == c'S':
return _c_string(dt)
# Boolean
elif kind == c'b':
return _c_bool(dt)
# Object types (including those with vlen hints)
elif kind == c'O':
if logical:
vlen = check_dtype(vlen=dt)
if vlen is bytes:
return _c_vlen_str()
elif vlen is unicode:
return _c_vlen_unicode()
refclass = check_dtype(ref=dt)
if refclass is not None:
return _c_ref(refclass)
raise TypeError("Object dtype %r has no native HDF5 equivalent" % (dt,))
return PYTHON_OBJECT
# Unrecognized
else:
raise TypeError("No conversion path for dtype: %s" % repr(dt))
def special_dtype(**kwds):
""" Create a new h5py "special" type. Only one keyword may be given.
Legal keywords are:
vlen = basetype
Base type for HDF5 variable-length datatype. Currently only the
builtin string class (str) is allowed.
Example: special_dtype( vlen=str )
enum = (basetype, values_dict)
Create a NumPy representation of an HDF5 enumerated type. Provide
a 2-tuple containing an (integer) base dtype and a dict mapping
string names to integer values.
ref = Reference | RegionReference
Create a NumPy representation of an HDF5 object or region reference
type.
"""
if len(kwds) != 1:
raise TypeError("Exactly one keyword may be provided")
name, val = kwds.popitem()
if name == 'vlen':
if val not in (bytes, unicode):
raise NotImplementedError("Only byte or unicode string vlens are currently supported")
return dtype(('O', [( ({'type': val},'vlen'), 'O' )] ))
if name == 'enum':
try:
dt, enum_vals = val
except TypeError:
raise TypeError("Enums must be created from a 2-tuple (basetype, values_dict)")
dt = dtype(dt)
if dt.kind not in "iu":
raise TypeError("Only integer types can be used as enums")
return dtype((dt, [( ({'vals': enum_vals},'enum'), dt )] ))
if name == 'ref':
if val not in (Reference, RegionReference):
raise ValueError("Ref class must be Reference or RegionReference")
return dtype(('O', [( ({'type': val},'ref'), 'O' )] ))
raise TypeError('Unknown special type "%s"' % name)
def check_dtype(**kwds):
""" Check a dtype for h5py special type "hint" information. Only one
keyword may be given.
vlen = dtype
If the dtype represents an HDF5 vlen, returns the Python base class.
Currently only builting string vlens (str) are supported. Returns
None if the dtype does not represent an HDF5 vlen.
enum = dtype
If the dtype represents an HDF5 enumerated type, returns the dictionary
mapping string names to integer values. Returns None if the dtype does
not represent an HDF5 enumerated type.
ref = dtype
If the dtype represents an HDF5 reference type, returns the reference
class (either Reference or RegionReference). Returns None if the dtype
does not represent an HDF5 reference type.
"""
if len(kwds) != 1:
raise TypeError("Exactly one keyword may be provided")
name, dt = kwds.popitem()
if name not in ('vlen', 'enum', 'ref'):
raise TypeError('Unknown special type "%s"' % name)
hintkey = 'type' if name is not 'enum' else 'vals'
if dt.fields is not None and name in dt.fields:
tpl = dt.fields[name]
if len(tpl) == 3:
hint_dict = tpl[2]
if hintkey in hint_dict:
return hint_dict[hintkey]
return None
def convert(TypeID src not None, TypeID dst not None, size_t n,
ndarray buf not None, ndarray bkg=None, ObjectID dxpl=None):
""" (TypeID src, TypeID dst, UINT n, NDARRAY buf, NDARRAY bkg=None,
PropID dxpl=None)
Convert n contiguous elements of a buffer in-place. The array dtype
is ignored. The backing buffer is optional; for conversion of compound
types, a temporary copy of conversion buffer will used for backing if
one is not supplied.
"""
cdef void* bkg_ = NULL
cdef void* buf_ = buf.data
if bkg is None and (src.detect_class(H5T_COMPOUND) or
dst.detect_class(H5T_COMPOUND)):
bkg = buf.copy()
if bkg is not None:
bkg_ = bkg.data
H5Tconvert(src.id, dst.id, n, buf_, bkg_, pdefault(dxpl))
def find(TypeID src not None, TypeID dst not None):
""" (TypeID src, TypeID dst) => TUPLE or None
Determine if a conversion path exists from src to dst. Result is None
or a tuple describing the conversion path. Currently tuple entries are:
1. INT need_bkg: Whether this routine requires a backing buffer.
Values are BKG_NO, BKG_TEMP and BKG_YES.
"""
cdef H5T_cdata_t *data
cdef H5T_conv_t result = NULL
try:
result = H5Tfind(src.id, dst.id, &data)
if result == NULL:
return None
return (data[0].need_bkg,)
except:
return None
# ============================================================================
# Deprecated functions
import warnings
cpdef dtype py_new_enum(object dt_in, dict enum_vals):
""" (DTYPE dt_in, DICT enum_vals) => DTYPE
Deprecated; use special_dtype() instead.
"""
#warnings.warn("Deprecated; use special_dtype(enum=(dtype, values)) instead", DeprecationWarning)
return special_dtype(enum = (dt_in, enum_vals))
cpdef dict py_get_enum(object dt):
""" (DTYPE dt_in) => DICT
Deprecated; use check_dtype() instead.
"""
#warnings.warn("Deprecated; use check_dtype(enum=dtype) instead", DeprecationWarning)
return check_dtype(enum=dt)
cpdef dtype py_new_vlen(object kind):
""" (OBJECT kind) => DTYPE
Deprecated; use special_dtype() instead.
"""
#warnings.warn("Deprecated; use special_dtype(vlen=basetype) instead", DeprecationWarning)
return special_dtype(vlen=kind)
cpdef object py_get_vlen(object dt_in):
""" (OBJECT dt_in) => TYPE
Deprecated; use check_dtype() instead.
"""
#warnings.warn("Deprecated; use check_dtype(vlen=dtype) instead", DeprecationWarning)
return check_dtype(vlen=dt_in)
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