Doc/c-api/buffer.rst - platform/external/python/cpython3 - Gitiles

 .. highlightlang:: c

 .. _bufferobjects:

 Buffer Protocol
 ---------------

 .. sectionauthor:: Greg Stein <gstein@lyra.org>
 .. sectionauthor:: Benjamin Peterson


 .. index::
    single: buffer interface

 Certain objects available in Python wrap access to an underlying memory
 array or *buffer*.  Such objects include the built-in :class:`bytes` and
 :class:`bytearray`, and some extension types like :class:`array.array`.
 Third-party libraries may define their own types for special purposes, such
 as image processing or numeric analysis.

 While each of these types have their own semantics, they share the common
 characteristic of being backed by a possibly large memory buffer.  It is
 then desireable, in some situations, to access that buffer directly and
 without intermediate copying.

 Python provides such a facility at the C level in the form of the *buffer
 protocol*.  This protocol has two sides:

 .. index:: single: PyBufferProcs

 - on the producer side, a type can export a "buffer interface" which allows
   objects of that type to expose information about their underlying buffer.
   This interface is described in the section :ref:`buffer-structs`;

 - on the consumer side, several means are available to obtain a pointer to
   the raw underlying data of an object (for example a method parameter).

 Simple objects such as :class:`bytes` and :class:`bytearray` expose their
 underlying buffer in byte-oriented form.  Other forms are possible; for example,
 the elements exposed by a :class:`array.array` can be multi-byte values.

 An example consumer of the buffer interface is the :meth:`~io.BufferedIOBase.write`
 method of file objects: any object that can export a series of bytes through
 the buffer interface can be written to a file.  While :meth:`write` only
 needs read-only access to the internal contents of the object passed to it,
 other methods such as :meth:`~io.BufferedIOBase.readinto` need write access
 to the contents of their argument.  The buffer interface allows objects to
 selectively allow or reject exporting of read-write and read-only buffers.

 There are two ways for a consumer of the buffer interface to acquire a buffer
 over a target object:

 * call :c:func:`PyObject_GetBuffer` with the right parameters;

 * call :c:func:`PyArg_ParseTuple` (or one of its siblings) with one of the
   ``y*``, ``w*`` or ``s*`` :ref:`format codes <arg-parsing>`.

 In both cases, :c:func:`PyBuffer_Release` must be called when the buffer
 isn't needed anymore.  Failure to do so could lead to various issues such as
 resource leaks.


 The buffer structure
 ====================

 Buffer structures (or simply "buffers") are useful as a way to expose the
 binary data from another object to the Python programmer.  They can also be
 used as a zero-copy slicing mechanism.  Using their ability to reference a
 block of memory, it is possible to expose any data to the Python programmer
 quite easily.  The memory could be a large, constant array in a C extension,
 it could be a raw block of memory for manipulation before passing to an
 operating system library, or it could be used to pass around structured data
 in its native, in-memory format.

 Contrary to most data types exposed by the Python interpreter, buffers
 are not :c:type:`PyObject` pointers but rather simple C structures.  This
 allows them to be created and copied very simply.  When a generic wrapper
 around a buffer is needed, a :ref:`memoryview <memoryview-objects>` object
 can be created.


 .. c:type:: Py_buffer

    .. c:member:: void *buf

       A pointer to the start of the memory for the object.

    .. c:member:: Py_ssize_t len
       :noindex:

       The total length of the memory in bytes.

    .. c:member:: int readonly

       An indicator of whether the buffer is read only.

    .. c:member:: const char *format
       :noindex:

       A *NULL* terminated string in :mod:`struct` module style syntax giving
       the contents of the elements available through the buffer.  If this is
       *NULL*, ``"B"`` (unsigned bytes) is assumed.

    .. c:member:: int ndim

       The number of dimensions the memory represents as a multi-dimensional
       array.  If it is 0, :c:data:`strides` and :c:data:`suboffsets` must be
       *NULL*.

    .. c:member:: Py_ssize_t *shape

       An array of :c:type:`Py_ssize_t`\s the length of :c:data:`ndim` giving the
       shape of the memory as a multi-dimensional array.  Note that
       ``((*shape)[0] * ... * (*shape)[ndims-1])*itemsize`` should be equal to
       :c:data:`len`.

    .. c:member:: Py_ssize_t *strides

       An array of :c:type:`Py_ssize_t`\s the length of :c:data:`ndim` giving the
       number of bytes to skip to get to a new element in each dimension.

    .. c:member:: Py_ssize_t *suboffsets

       An array of :c:type:`Py_ssize_t`\s the length of :c:data:`ndim`.  If these
       suboffset numbers are greater than or equal to 0, then the value stored
       along the indicated dimension is a pointer and the suboffset value
       dictates how many bytes to add to the pointer after de-referencing. A
       suboffset value that it negative indicates that no de-referencing should
       occur (striding in a contiguous memory block).

       Here is a function that returns a pointer to the element in an N-D array
       pointed to by an N-dimensional index when there are both non-NULL strides
       and suboffsets::

           void *get_item_pointer(int ndim, void *buf, Py_ssize_t *strides,
               Py_ssize_t *suboffsets, Py_ssize_t *indices) {
               char *pointer = (char*)buf;
               int i;
               for (i = 0; i < ndim; i++) {
                   pointer += strides[i] * indices[i];
                   if (suboffsets[i] >=0 ) {
                       pointer = *((char**)pointer) + suboffsets[i];
                   }
               }
               return (void*)pointer;
            }


    .. c:member:: Py_ssize_t itemsize

       This is a storage for the itemsize (in bytes) of each element of the
       shared memory. It is technically un-necessary as it can be obtained
       using :c:func:`PyBuffer_SizeFromFormat`, however an exporter may know
       this information without parsing the format string and it is necessary
       to know the itemsize for proper interpretation of striding. Therefore,
       storing it is more convenient and faster.

    .. c:member:: void *internal

       This is for use internally by the exporting object. For example, this
       might be re-cast as an integer by the exporter and used to store flags
       about whether or not the shape, strides, and suboffsets arrays must be
       freed when the buffer is released. The consumer should never alter this
       value.


 Buffer-related functions
 ========================


 .. c:function:: int PyObject_CheckBuffer(PyObject *obj)

    Return 1 if *obj* supports the buffer interface otherwise 0.  When 1 is
    returned, it doesn't guarantee that :c:func:`PyObject_GetBuffer` will
    succeed.


 .. c:function:: int PyObject_GetBuffer(PyObject *obj, Py_buffer *view, int flags)

       Export a view over some internal data from the target object *obj*.
       *obj* must not be NULL, and *view* must point to an existing
       :c:type:`Py_buffer` structure allocated by the caller (most uses of
       this function will simply declare a local variable of type
       :c:type:`Py_buffer`).  The *flags* argument is a bit field indicating
       what kind of buffer is requested.  The buffer interface allows
       for complicated memory layout possibilities; however, some callers
       won't want to handle all the complexity and instead request a simple
       view of the target object (using :c:macro:`PyBUF_SIMPLE` for a read-only
       view and :c:macro:`PyBUF_WRITABLE` for a read-write view).

       Some exporters may not be able to share memory in every possible way and
       may need to raise errors to signal to some consumers that something is
       just not possible. These errors should be a :exc:`BufferError` unless
       there is another error that is actually causing the problem. The
       exporter can use flags information to simplify how much of the
       :c:data:`Py_buffer` structure is filled in with non-default values and/or
       raise an error if the object can't support a simpler view of its memory.

       On success, 0 is returned and the *view* structure is filled with useful
       values.  On error, -1 is returned and an exception is raised; the *view*
       is left in an undefined state.

       The following are the possible values to the *flags* arguments.

       .. c:macro:: PyBUF_SIMPLE

          This is the default flag.  The returned buffer exposes a read-only
          memory area.  The format of data is assumed to be raw unsigned bytes,
          without any particular structure.  This is a "stand-alone" flag
          constant.  It never needs to be '|'d to the others.  The exporter will
          raise an error if it cannot provide such a contiguous buffer of bytes.

       .. c:macro:: PyBUF_WRITABLE

          Like :c:macro:`PyBUF_SIMPLE`, but the returned buffer is writable.  If
          the exporter doesn't support writable buffers, an error is raised.

       .. c:macro:: PyBUF_STRIDES

          This implies :c:macro:`PyBUF_ND`.  The returned buffer must provide
          strides information (i.e. the strides cannot be NULL).  This would be
          used when the consumer can handle strided, discontiguous arrays.
          Handling strides automatically assumes you can handle shape.  The
          exporter can raise an error if a strided representation of the data is
          not possible (i.e. without the suboffsets).

       .. c:macro:: PyBUF_ND

          The returned buffer must provide shape information.  The memory will be
          assumed C-style contiguous (last dimension varies the fastest).  The
          exporter may raise an error if it cannot provide this kind of
          contiguous buffer.  If this is not given then shape will be *NULL*.

       .. c:macro:: PyBUF_C_CONTIGUOUS
                   PyBUF_F_CONTIGUOUS
                   PyBUF_ANY_CONTIGUOUS

          These flags indicate that the contiguity returned buffer must be
          respectively, C-contiguous (last dimension varies the fastest), Fortran
          contiguous (first dimension varies the fastest) or either one.  All of
          these flags imply :c:macro:`PyBUF_STRIDES` and guarantee that the
          strides buffer info structure will be filled in correctly.

       .. c:macro:: PyBUF_INDIRECT

          This flag indicates the returned buffer must have suboffsets
          information (which can be NULL if no suboffsets are needed).  This can
          be used when the consumer can handle indirect array referencing implied
          by these suboffsets. This implies :c:macro:`PyBUF_STRIDES`.

       .. c:macro:: PyBUF_FORMAT

          The returned buffer must have true format information if this flag is
          provided.  This would be used when the consumer is going to be checking
          for what 'kind' of data is actually stored.  An exporter should always
          be able to provide this information if requested.  If format is not
          explicitly requested then the format must be returned as *NULL* (which
          means ``'B'``, or unsigned bytes).

       .. c:macro:: PyBUF_STRIDED

          This is equivalent to ``(PyBUF_STRIDES | PyBUF_WRITABLE)``.

       .. c:macro:: PyBUF_STRIDED_RO

          This is equivalent to ``(PyBUF_STRIDES)``.

       .. c:macro:: PyBUF_RECORDS

          This is equivalent to ``(PyBUF_STRIDES | PyBUF_FORMAT |
          PyBUF_WRITABLE)``.

       .. c:macro:: PyBUF_RECORDS_RO

          This is equivalent to ``(PyBUF_STRIDES | PyBUF_FORMAT)``.

       .. c:macro:: PyBUF_FULL

          This is equivalent to ``(PyBUF_INDIRECT | PyBUF_FORMAT |
          PyBUF_WRITABLE)``.

       .. c:macro:: PyBUF_FULL_RO

          This is equivalent to ``(PyBUF_INDIRECT | PyBUF_FORMAT)``.

       .. c:macro:: PyBUF_CONTIG

          This is equivalent to ``(PyBUF_ND | PyBUF_WRITABLE)``.

       .. c:macro:: PyBUF_CONTIG_RO

          This is equivalent to ``(PyBUF_ND)``.


 .. c:function:: void PyBuffer_Release(Py_buffer *view)

    Release the buffer *view*.  This should be called when the buffer is no
    longer being used as it may free memory from it.


 .. c:function:: Py_ssize_t PyBuffer_SizeFromFormat(const char *)

    Return the implied :c:data:`~Py_buffer.itemsize` from the struct-stype
    :c:data:`~Py_buffer.format`.


 .. c:function:: int PyBuffer_IsContiguous(Py_buffer *view, char fortran)

    Return 1 if the memory defined by the *view* is C-style (*fortran* is
    ``'C'``) or Fortran-style (*fortran* is ``'F'``) contiguous or either one
    (*fortran* is ``'A'``).  Return 0 otherwise.


 .. c:function:: void PyBuffer_FillContiguousStrides(int ndim, Py_ssize_t *shape, Py_ssize_t *strides, Py_ssize_t itemsize, char fortran)

    Fill the *strides* array with byte-strides of a contiguous (C-style if
    *fortran* is ``'C'`` or Fortran-style if *fortran* is ``'F'``) array of the
    given shape with the given number of bytes per element.


 .. c:function:: int PyBuffer_FillInfo(Py_buffer *view, PyObject *obj, void *buf, Py_ssize_t len, int readonly, int infoflags)

    Fill in a buffer-info structure, *view*, correctly for an exporter that can
    only share a contiguous chunk of memory of "unsigned bytes" of the given
    length.  Return 0 on success and -1 (with raising an error) on error.
	.. highlightlang:: c

	.. _bufferobjects:

	Buffer Protocol
	---------------

	.. sectionauthor:: Greg Stein <gstein@lyra.org>
	.. sectionauthor:: Benjamin Peterson


	.. index::
	single: buffer interface

	Certain objects available in Python wrap access to an underlying memory
	array or buffer. Such objects include the built-in :class:`bytes` and
	:class:`bytearray`, and some extension types like :class:`array.array`.
	Third-party libraries may define their own types for special purposes, such
	as image processing or numeric analysis.

	While each of these types have their own semantics, they share the common
	characteristic of being backed by a possibly large memory buffer. It is
	then desireable, in some situations, to access that buffer directly and
	without intermediate copying.

	Python provides such a facility at the C level in the form of the *buffer
	protocol*. This protocol has two sides:

	.. index:: single: PyBufferProcs

	- on the producer side, a type can export a "buffer interface" which allows
	objects of that type to expose information about their underlying buffer.
	This interface is described in the section :ref:`buffer-structs`;

	- on the consumer side, several means are available to obtain a pointer to
	the raw underlying data of an object (for example a method parameter).

	Simple objects such as :class:`bytes` and :class:`bytearray` expose their
	underlying buffer in byte-oriented form. Other forms are possible; for example,
	the elements exposed by a :class:`array.array` can be multi-byte values.

	An example consumer of the buffer interface is the :meth:`~io.BufferedIOBase.write`
	method of file objects: any object that can export a series of bytes through
	the buffer interface can be written to a file. While :meth:`write` only
	needs read-only access to the internal contents of the object passed to it,
	other methods such as :meth:`~io.BufferedIOBase.readinto` need write access
	to the contents of their argument. The buffer interface allows objects to
	selectively allow or reject exporting of read-write and read-only buffers.

	There are two ways for a consumer of the buffer interface to acquire a buffer
	over a target object:

	* call :c:func:`PyObject_GetBuffer` with the right parameters;

	* call :c:func:`PyArg_ParseTuple` (or one of its siblings) with one of the
	``y``, ``w`` or ``s*`` :ref:`format codes <arg-parsing>`.

	In both cases, :c:func:`PyBuffer_Release` must be called when the buffer
	isn't needed anymore. Failure to do so could lead to various issues such as
	resource leaks.


	The buffer structure
	====================

	Buffer structures (or simply "buffers") are useful as a way to expose the
	binary data from another object to the Python programmer. They can also be
	used as a zero-copy slicing mechanism. Using their ability to reference a
	block of memory, it is possible to expose any data to the Python programmer
	quite easily. The memory could be a large, constant array in a C extension,
	it could be a raw block of memory for manipulation before passing to an
	operating system library, or it could be used to pass around structured data
	in its native, in-memory format.

	Contrary to most data types exposed by the Python interpreter, buffers
	are not :c:type:`PyObject` pointers but rather simple C structures. This
	allows them to be created and copied very simply. When a generic wrapper
	around a buffer is needed, a :ref:`memoryview <memoryview-objects>` object
	can be created.


	.. c:type:: Py_buffer

	.. c:member:: void *buf

	A pointer to the start of the memory for the object.

	.. c:member:: Py_ssize_t len
	:noindex:

	The total length of the memory in bytes.

	.. c:member:: int readonly

	An indicator of whether the buffer is read only.

	.. c:member:: const char *format
	:noindex:

	A NULL terminated string in :mod:`struct` module style syntax giving
	the contents of the elements available through the buffer. If this is
	NULL, ``"B"`` (unsigned bytes) is assumed.

	.. c:member:: int ndim

	The number of dimensions the memory represents as a multi-dimensional
	array. If it is 0, :c:data:`strides` and :c:data:`suboffsets` must be
	NULL.

	.. c:member:: Py_ssize_t *shape

	An array of :c:type:`Py_ssize_t`\s the length of :c:data:`ndim` giving the
	shape of the memory as a multi-dimensional array. Note that
	``((shape)[0] ... * (shape)[ndims-1])itemsize`` should be equal to
	:c:data:`len`.

	.. c:member:: Py_ssize_t *strides

	An array of :c:type:`Py_ssize_t`\s the length of :c:data:`ndim` giving the
	number of bytes to skip to get to a new element in each dimension.

	.. c:member:: Py_ssize_t *suboffsets

	An array of :c:type:`Py_ssize_t`\s the length of :c:data:`ndim`. If these
	suboffset numbers are greater than or equal to 0, then the value stored
	along the indicated dimension is a pointer and the suboffset value
	dictates how many bytes to add to the pointer after de-referencing. A
	suboffset value that it negative indicates that no de-referencing should
	occur (striding in a contiguous memory block).

	Here is a function that returns a pointer to the element in an N-D array
	pointed to by an N-dimensional index when there are both non-NULL strides
	and suboffsets::

	void get_item_pointer(int ndim, void buf, Py_ssize_t *strides,
	Py_ssize_t suboffsets, Py_ssize_t indices) {
	char pointer = (char)buf;
	int i;
	for (i = 0; i < ndim; i++) {
	pointer += strides[i] * indices[i];
	if (suboffsets[i] >=0 ) {
	pointer = ((char*)pointer) + suboffsets[i];
	}
	}
	return (void*)pointer;
	}


	.. c:member:: Py_ssize_t itemsize

	This is a storage for the itemsize (in bytes) of each element of the
	shared memory. It is technically un-necessary as it can be obtained
	using :c:func:`PyBuffer_SizeFromFormat`, however an exporter may know
	this information without parsing the format string and it is necessary
	to know the itemsize for proper interpretation of striding. Therefore,
	storing it is more convenient and faster.

	.. c:member:: void *internal

	This is for use internally by the exporting object. For example, this
	might be re-cast as an integer by the exporter and used to store flags
	about whether or not the shape, strides, and suboffsets arrays must be
	freed when the buffer is released. The consumer should never alter this
	value.


	Buffer-related functions
	========================


	.. c:function:: int PyObject_CheckBuffer(PyObject *obj)

	Return 1 if obj supports the buffer interface otherwise 0. When 1 is
	returned, it doesn't guarantee that :c:func:`PyObject_GetBuffer` will
	succeed.


	.. c:function:: int PyObject_GetBuffer(PyObject obj, Py_buffer view, int flags)

	Export a view over some internal data from the target object obj.
	obj must not be NULL, and view must point to an existing
	:c:type:`Py_buffer` structure allocated by the caller (most uses of
	this function will simply declare a local variable of type
	:c:type:`Py_buffer`). The flags argument is a bit field indicating
	what kind of buffer is requested. The buffer interface allows
	for complicated memory layout possibilities; however, some callers
	won't want to handle all the complexity and instead request a simple
	view of the target object (using :c:macro:`PyBUF_SIMPLE` for a read-only
	view and :c:macro:`PyBUF_WRITABLE` for a read-write view).

	Some exporters may not be able to share memory in every possible way and
	may need to raise errors to signal to some consumers that something is
	just not possible. These errors should be a :exc:`BufferError` unless
	there is another error that is actually causing the problem. The
	exporter can use flags information to simplify how much of the
	:c:data:`Py_buffer` structure is filled in with non-default values and/or
	raise an error if the object can't support a simpler view of its memory.

	On success, 0 is returned and the view structure is filled with useful
	values. On error, -1 is returned and an exception is raised; the view
	is left in an undefined state.

	The following are the possible values to the flags arguments.

	.. c:macro:: PyBUF_SIMPLE

	This is the default flag. The returned buffer exposes a read-only
	memory area. The format of data is assumed to be raw unsigned bytes,
	without any particular structure. This is a "stand-alone" flag
	constant. It never needs to be '\|'d to the others. The exporter will
	raise an error if it cannot provide such a contiguous buffer of bytes.

	.. c:macro:: PyBUF_WRITABLE

	Like :c:macro:`PyBUF_SIMPLE`, but the returned buffer is writable. If
	the exporter doesn't support writable buffers, an error is raised.

	.. c:macro:: PyBUF_STRIDES

	This implies :c:macro:`PyBUF_ND`. The returned buffer must provide
	strides information (i.e. the strides cannot be NULL). This would be
	used when the consumer can handle strided, discontiguous arrays.
	Handling strides automatically assumes you can handle shape. The
	exporter can raise an error if a strided representation of the data is
	not possible (i.e. without the suboffsets).

	.. c:macro:: PyBUF_ND

	The returned buffer must provide shape information. The memory will be
	assumed C-style contiguous (last dimension varies the fastest). The
	exporter may raise an error if it cannot provide this kind of
	contiguous buffer. If this is not given then shape will be NULL.

	.. c:macro:: PyBUF_C_CONTIGUOUS
	PyBUF_F_CONTIGUOUS
	PyBUF_ANY_CONTIGUOUS

	These flags indicate that the contiguity returned buffer must be
	respectively, C-contiguous (last dimension varies the fastest), Fortran
	contiguous (first dimension varies the fastest) or either one. All of
	these flags imply :c:macro:`PyBUF_STRIDES` and guarantee that the
	strides buffer info structure will be filled in correctly.

	.. c:macro:: PyBUF_INDIRECT

	This flag indicates the returned buffer must have suboffsets
	information (which can be NULL if no suboffsets are needed). This can
	be used when the consumer can handle indirect array referencing implied
	by these suboffsets. This implies :c:macro:`PyBUF_STRIDES`.

	.. c:macro:: PyBUF_FORMAT

	The returned buffer must have true format information if this flag is
	provided. This would be used when the consumer is going to be checking
	for what 'kind' of data is actually stored. An exporter should always
	be able to provide this information if requested. If format is not
	explicitly requested then the format must be returned as NULL (which
	means ``'B'``, or unsigned bytes).

	.. c:macro:: PyBUF_STRIDED

	This is equivalent to ``(PyBUF_STRIDES \| PyBUF_WRITABLE)``.

	.. c:macro:: PyBUF_STRIDED_RO

	This is equivalent to ``(PyBUF_STRIDES)``.

	.. c:macro:: PyBUF_RECORDS

	This is equivalent to ``(PyBUF_STRIDES \| PyBUF_FORMAT \|
	PyBUF_WRITABLE)``.

	.. c:macro:: PyBUF_RECORDS_RO

	This is equivalent to ``(PyBUF_STRIDES \| PyBUF_FORMAT)``.

	.. c:macro:: PyBUF_FULL

	This is equivalent to ``(PyBUF_INDIRECT \| PyBUF_FORMAT \|
	PyBUF_WRITABLE)``.

	.. c:macro:: PyBUF_FULL_RO

	This is equivalent to ``(PyBUF_INDIRECT \| PyBUF_FORMAT)``.

	.. c:macro:: PyBUF_CONTIG

	This is equivalent to ``(PyBUF_ND \| PyBUF_WRITABLE)``.

	.. c:macro:: PyBUF_CONTIG_RO

	This is equivalent to ``(PyBUF_ND)``.


	.. c:function:: void PyBuffer_Release(Py_buffer *view)

	Release the buffer view. This should be called when the buffer is no
	longer being used as it may free memory from it.


	.. c:function:: Py_ssize_t PyBuffer_SizeFromFormat(const char *)

	Return the implied :c:data:`~Py_buffer.itemsize` from the struct-stype
	:c:data:`~Py_buffer.format`.


	.. c:function:: int PyBuffer_IsContiguous(Py_buffer *view, char fortran)

	Return 1 if the memory defined by the view is C-style (fortran is
	``'C'``) or Fortran-style (fortran is ``'F'``) contiguous or either one
	(fortran is ``'A'``). Return 0 otherwise.


	.. c:function:: void PyBuffer_FillContiguousStrides(int ndim, Py_ssize_t shape, Py_ssize_t strides, Py_ssize_t itemsize, char fortran)

	Fill the strides array with byte-strides of a contiguous (C-style if
	fortran is ``'C'`` or Fortran-style if fortran is ``'F'``) array of the
	given shape with the given number of bytes per element.


	.. c:function:: int PyBuffer_FillInfo(Py_buffer view, PyObject obj, void *buf, Py_ssize_t len, int readonly, int infoflags)

	Fill in a buffer-info structure, view, correctly for an exporter that can
	only share a contiguous chunk of memory of "unsigned bytes" of the given
	length. Return 0 on success and -1 (with raising an error) on error.