Doc/c-api/buffer.rst - external/github.com/python/cpython - Git at Google

 .. highlightlang:: c

 .. index::
    single: buffer protocol
    single: buffer interface; (see buffer protocol)
    single: buffer object; (see buffer protocol)

 .. _bufferobjects:

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

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


 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 desirable, 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 :ref:`buffer
 protocol <bufferobjects>`.  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 an :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.


 .. _buffer-structure:

 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.

 For short instructions how to write an exporting object, see
 :ref:`Buffer Object Structures <buffer-structs>`. For obtaining
 a buffer, see :c:func:`PyObject_GetBuffer`.

 .. c:type:: Py_buffer

    .. c:member:: void \*buf

       A pointer to the start of the logical structure described by the buffer
       fields. This can be any location within the underlying physical memory
       block of the exporter. For example, with negative :c:member:`~Py_buffer.strides`
       the value may point to the end of the memory block.

       For :term:`contiguous` arrays, the value points to the beginning of
       the memory block.

    .. c:member:: void \*obj

       A new reference to the exporting object. The reference is owned by
       the consumer and automatically decremented and set to *NULL* by
       :c:func:`PyBuffer_Release`. The field is the equivalent of the return
       value of any standard C-API function.

       As a special case, for *temporary* buffers that are wrapped by
       :c:func:`PyMemoryView_FromBuffer` or :c:func:`PyBuffer_FillInfo`
       this field is *NULL*. In general, exporting objects MUST NOT
       use this scheme.

    .. c:member:: Py_ssize_t len

       ``product(shape) * itemsize``. For contiguous arrays, this is the length
       of the underlying memory block. For non-contiguous arrays, it is the length
       that the logical structure would have if it were copied to a contiguous
       representation.

       Accessing ``((char *)buf)[0] up to ((char *)buf)[len-1]`` is only valid
       if the buffer has been obtained by a request that guarantees contiguity. In
       most cases such a request will be :c:macro:`PyBUF_SIMPLE` or :c:macro:`PyBUF_WRITABLE`.

    .. c:member:: int readonly

       An indicator of whether the buffer is read-only. This field is controlled
       by the :c:macro:`PyBUF_WRITABLE` flag.

    .. c:member:: Py_ssize_t itemsize

       Item size in bytes of a single element. Same as the value of :func:`struct.calcsize`
       called on non-NULL :c:member:`~Py_buffer.format` values.

       Important exception: If a consumer requests a buffer without the
       :c:macro:`PyBUF_FORMAT` flag, :c:member:`~Py_buffer.format` will
       be set to  *NULL*,  but :c:member:`~Py_buffer.itemsize` still has
       the value for the original format.

       If :c:member:`~Py_buffer.shape` is present, the equality
       ``product(shape) * itemsize == len`` still holds and the consumer
       can use :c:member:`~Py_buffer.itemsize` to navigate the buffer.

       If :c:member:`~Py_buffer.shape` is *NULL* as a result of a :c:macro:`PyBUF_SIMPLE`
       or a :c:macro:`PyBUF_WRITABLE` request, the consumer must disregard
       :c:member:`~Py_buffer.itemsize` and assume ``itemsize == 1``.

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

       A *NUL* terminated string in :mod:`struct` module style syntax describing
       the contents of a single item. If this is *NULL*, ``"B"`` (unsigned bytes)
       is assumed.

       This field is controlled by the :c:macro:`PyBUF_FORMAT` flag.

    .. c:member:: int ndim

       The number of dimensions the memory represents as an n-dimensional array.
       If it is ``0``, :c:member:`~Py_buffer.buf` points to a single item representing
       a scalar. In this case, :c:member:`~Py_buffer.shape`, :c:member:`~Py_buffer.strides`
       and :c:member:`~Py_buffer.suboffsets` MUST be *NULL*.

       The macro :c:macro:`PyBUF_MAX_NDIM` limits the maximum number of dimensions
       to 64. Exporters MUST respect this limit, consumers of multi-dimensional
       buffers SHOULD be able to handle up to :c:macro:`PyBUF_MAX_NDIM` dimensions.

    .. c:member:: Py_ssize_t \*shape

       An array of :c:type:`Py_ssize_t` of length :c:member:`~Py_buffer.ndim`
       indicating the shape of the memory as an n-dimensional array. Note that
       ``shape[0] * ... * shape[ndim-1] * itemsize`` MUST be equal to
       :c:member:`~Py_buffer.len`.

       Shape values are restricted to ``shape[n] >= 0``. The case
       ``shape[n] == 0`` requires special attention. See `complex arrays`_
       for further information.

       The shape array is read-only for the consumer.

    .. c:member:: Py_ssize_t \*strides

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

       Stride values can be any integer. For regular arrays, strides are
       usually positive, but a consumer MUST be able to handle the case
       ``strides[n] <= 0``. See `complex arrays`_ for further information.

       The strides array is read-only for the consumer.

    .. c:member:: Py_ssize_t \*suboffsets

       An array of :c:type:`Py_ssize_t` of length :c:member:`~Py_buffer.ndim`.
       If ``suboffsets[n] >= 0``, the values stored along the nth dimension are
       pointers and the suboffset value dictates how many bytes to add to each
       pointer after de-referencing. A suboffset value that is negative
       indicates that no de-referencing should occur (striding in a contiguous
       memory block).

       If all suboffsets are negative (i.e. no de-referencing is needed, then
       this field must be NULL (the default value).

       This type of array representation is used by the Python Imaging Library
       (PIL). See `complex arrays`_ for further information how to access elements
       of such an array.

       The suboffsets array is read-only for the consumer.

    .. 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 MUST NOT alter this
       value.

 .. _buffer-request-types:

 Buffer request types
 ====================

 Buffers are usually obtained by sending a buffer request to an exporting
 object via :c:func:`PyObject_GetBuffer`. Since the complexity of the logical
 structure of the memory can vary drastically, the consumer uses the *flags*
 argument to specify the exact buffer type it can handle.

 All :c:data:`Py_buffer` fields are unambiguously defined by the request
 type.

 request-independent fields
 ~~~~~~~~~~~~~~~~~~~~~~~~~~
 The following fields are not influenced by *flags* and must always be filled in
 with the correct values: :c:member:`~Py_buffer.obj`, :c:member:`~Py_buffer.buf`,
 :c:member:`~Py_buffer.len`, :c:member:`~Py_buffer.itemsize`, :c:member:`~Py_buffer.ndim`.


 readonly, format
 ~~~~~~~~~~~~~~~~

    .. c:macro:: PyBUF_WRITABLE

       Controls the :c:member:`~Py_buffer.readonly` field. If set, the exporter
       MUST provide a writable buffer or else report failure. Otherwise, the
       exporter MAY provide either a read-only or writable buffer, but the choice
       MUST be consistent for all consumers.

    .. c:macro:: PyBUF_FORMAT

       Controls the :c:member:`~Py_buffer.format` field. If set, this field MUST
       be filled in correctly. Otherwise, this field MUST be *NULL*.


 :c:macro:`PyBUF_WRITABLE` can be \|'d to any of the flags in the next section.
 Since :c:macro:`PyBUF_SIMPLE` is defined as 0, :c:macro:`PyBUF_WRITABLE`
 can be used as a stand-alone flag to request a simple writable buffer.

 :c:macro:`PyBUF_FORMAT` can be \|'d to any of the flags except :c:macro:`PyBUF_SIMPLE`.
 The latter already implies format ``B`` (unsigned bytes).


 shape, strides, suboffsets
 ~~~~~~~~~~~~~~~~~~~~~~~~~~

 The flags that control the logical structure of the memory are listed
 in decreasing order of complexity. Note that each flag contains all bits
 of the flags below it.

 .. tabularcolumns:: |p{0.35\linewidth}|l|l|l|

 +-----------------------------+-------+---------+------------+
 |  Request                    | shape | strides | suboffsets |
 +=============================+=======+=========+============+
 | .. c:macro:: PyBUF_INDIRECT |  yes  |   yes   | if needed  |
 +-----------------------------+-------+---------+------------+
 | .. c:macro:: PyBUF_STRIDES  |  yes  |   yes   |    NULL    |
 +-----------------------------+-------+---------+------------+
 | .. c:macro:: PyBUF_ND       |  yes  |   NULL  |    NULL    |
 +-----------------------------+-------+---------+------------+
 | .. c:macro:: PyBUF_SIMPLE   |  NULL |   NULL  |    NULL    |
 +-----------------------------+-------+---------+------------+


 .. index:: contiguous, C-contiguous, Fortran contiguous

 contiguity requests
 ~~~~~~~~~~~~~~~~~~~

 C or Fortran :term:`contiguity <contiguous>` can be explicitly requested,
 with and without stride information. Without stride information, the buffer
 must be C-contiguous.

 .. tabularcolumns:: |p{0.35\linewidth}|l|l|l|l|

 +-----------------------------------+-------+---------+------------+--------+
 |  Request                          | shape | strides | suboffsets | contig |
 +===================================+=======+=========+============+========+
 | .. c:macro:: PyBUF_C_CONTIGUOUS   |  yes  |   yes   |    NULL    |   C    |
 +-----------------------------------+-------+---------+------------+--------+
 | .. c:macro:: PyBUF_F_CONTIGUOUS   |  yes  |   yes   |    NULL    |   F    |
 +-----------------------------------+-------+---------+------------+--------+
 | .. c:macro:: PyBUF_ANY_CONTIGUOUS |  yes  |   yes   |    NULL    | C or F |
 +-----------------------------------+-------+---------+------------+--------+
 | .. c:macro:: PyBUF_ND             |  yes  |   NULL  |    NULL    |   C    |
 +-----------------------------------+-------+---------+------------+--------+


 compound requests
 ~~~~~~~~~~~~~~~~~

 All possible requests are fully defined by some combination of the flags in
 the previous section. For convenience, the buffer protocol provides frequently
 used combinations as single flags.

 In the following table *U* stands for undefined contiguity. The consumer would
 have to call :c:func:`PyBuffer_IsContiguous` to determine contiguity.

 .. tabularcolumns:: |p{0.35\linewidth}|l|l|l|l|l|l|

 +-------------------------------+-------+---------+------------+--------+----------+--------+
 |  Request                      | shape | strides | suboffsets | contig | readonly | format |
 +===============================+=======+=========+============+========+==========+========+
 | .. c:macro:: PyBUF_FULL       |  yes  |   yes   | if needed  |   U    |     0    |  yes   |
 +-------------------------------+-------+---------+------------+--------+----------+--------+
 | .. c:macro:: PyBUF_FULL_RO    |  yes  |   yes   | if needed  |   U    |  1 or 0  |  yes   |
 +-------------------------------+-------+---------+------------+--------+----------+--------+
 | .. c:macro:: PyBUF_RECORDS    |  yes  |   yes   |    NULL    |   U    |     0    |  yes   |
 +-------------------------------+-------+---------+------------+--------+----------+--------+
 | .. c:macro:: PyBUF_RECORDS_RO |  yes  |   yes   |    NULL    |   U    |  1 or 0  |  yes   |
 +-------------------------------+-------+---------+------------+--------+----------+--------+
 | .. c:macro:: PyBUF_STRIDED    |  yes  |   yes   |    NULL    |   U    |     0    |  NULL  |
 +-------------------------------+-------+---------+------------+--------+----------+--------+
 | .. c:macro:: PyBUF_STRIDED_RO |  yes  |   yes   |    NULL    |   U    |  1 or 0  |  NULL  |
 +-------------------------------+-------+---------+------------+--------+----------+--------+
 | .. c:macro:: PyBUF_CONTIG     |  yes  |   NULL  |    NULL    |   C    |     0    |  NULL  |
 +-------------------------------+-------+---------+------------+--------+----------+--------+
 | .. c:macro:: PyBUF_CONTIG_RO  |  yes  |   NULL  |    NULL    |   C    |  1 or 0  |  NULL  |
 +-------------------------------+-------+---------+------------+--------+----------+--------+


 Complex arrays
 ==============

 NumPy-style: shape and strides
 ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~

 The logical structure of NumPy-style arrays is defined by :c:member:`~Py_buffer.itemsize`,
 :c:member:`~Py_buffer.ndim`, :c:member:`~Py_buffer.shape` and :c:member:`~Py_buffer.strides`.

 If ``ndim == 0``, the memory location pointed to by :c:member:`~Py_buffer.buf` is
 interpreted as a scalar of size :c:member:`~Py_buffer.itemsize`. In that case,
 both :c:member:`~Py_buffer.shape` and :c:member:`~Py_buffer.strides` are *NULL*.

 If :c:member:`~Py_buffer.strides` is *NULL*, the array is interpreted as
 a standard n-dimensional C-array. Otherwise, the consumer must access an
 n-dimensional array as follows:

    ``ptr = (char *)buf + indices[0] * strides[0] + ... + indices[n-1] * strides[n-1]``
    ``item = *((typeof(item) *)ptr);``


 As noted above, :c:member:`~Py_buffer.buf` can point to any location within
 the actual memory block. An exporter can check the validity of a buffer with
 this function:

 .. code-block:: python

    def verify_structure(memlen, itemsize, ndim, shape, strides, offset):
        """Verify that the parameters represent a valid array within
           the bounds of the allocated memory:
               char *mem: start of the physical memory block
               memlen: length of the physical memory block
               offset: (char *)buf - mem
        """
        if offset % itemsize:
            return False
        if offset < 0 or offset+itemsize > memlen:
            return False
        if any(v % itemsize for v in strides):
            return False

        if ndim <= 0:
            return ndim == 0 and not shape and not strides
        if 0 in shape:
            return True

        imin = sum(strides[j]*(shape[j]-1) for j in range(ndim)
                   if strides[j] <= 0)
        imax = sum(strides[j]*(shape[j]-1) for j in range(ndim)
                   if strides[j] > 0)

        return 0 <= offset+imin and offset+imax+itemsize <= memlen


 PIL-style: shape, strides and suboffsets
 ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~

 In addition to the regular items, PIL-style arrays can contain pointers
 that must be followed in order to get to the next element in a dimension.
 For example, the regular three-dimensional C-array ``char v[2][2][3]`` can
 also be viewed as an array of 2 pointers to 2 two-dimensional arrays:
 ``char (*v[2])[2][3]``. In suboffsets representation, those two pointers
 can be embedded at the start of :c:member:`~Py_buffer.buf`, pointing
 to two ``char x[2][3]`` arrays that can be located anywhere in memory.


 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;
    }


 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 *exporter, Py_buffer *view, int flags)

    Send a request to *exporter* to fill in *view* as specified by  *flags*.
    If the exporter cannot provide a buffer of the exact type, it MUST raise
    :c:data:`PyExc_BufferError`, set :c:member:`view->obj` to *NULL* and
    return ``-1``.

    On success, fill in *view*, set :c:member:`view->obj` to a new reference
    to *exporter* and return 0. In the case of chained buffer providers
    that redirect requests to a single object, :c:member:`view->obj` MAY
    refer to this object instead of *exporter* (See :ref:`Buffer Object Structures <buffer-structs>`).

    Successful calls to :c:func:`PyObject_GetBuffer` must be paired with calls
    to :c:func:`PyBuffer_Release`, similar to :c:func:`malloc` and :c:func:`free`.
    Thus, after the consumer is done with the buffer, :c:func:`PyBuffer_Release`
    must be called exactly once.


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

    Release the buffer *view* and decrement the reference count for
    :c:member:`view->obj`. This function MUST be called when the buffer
    is no longer being used, otherwise reference leaks may occur.

    It is an error to call this function on a buffer that was not obtained via
    :c:func:`PyObject_GetBuffer`.


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

    Return the implied :c:data:`~Py_buffer.itemsize` from :c:data:`~Py_buffer.format`.
    This function is not yet implemented.


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

    Return ``1`` if the memory defined by the *view* is C-style (*order* is
    ``'C'``) or Fortran-style (*order* is ``'F'``) :term:`contiguous` or either one
    (*order* 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 order)

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


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

    Handle buffer requests for an exporter that wants to expose *buf* of size *len*
    with writability set according to *readonly*. *buf* is interpreted as a sequence
    of unsigned bytes.

    The *flags* argument indicates the request type. This function always fills in
    *view* as specified by flags, unless *buf* has been designated as read-only
    and :c:macro:`PyBUF_WRITABLE` is set in *flags*.

    On success, set :c:member:`view->obj` to a new reference to *exporter* and
    return 0. Otherwise, raise :c:data:`PyExc_BufferError`, set
    :c:member:`view->obj` to *NULL* and return ``-1``;

    If this function is used as part of a :ref:`getbufferproc <buffer-structs>`,
    *exporter* MUST be set to the exporting object and *flags* must be passed
    unmodified. Otherwise, *exporter* MUST be NULL.
	.. highlightlang:: c

	.. index::
	single: buffer protocol
	single: buffer interface; (see buffer protocol)
	single: buffer object; (see buffer protocol)

	.. _bufferobjects:

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

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


	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 desirable, 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 :ref:`buffer
	protocol <bufferobjects>`. 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 an :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.


	.. _buffer-structure:

	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.

	For short instructions how to write an exporting object, see
	:ref:`Buffer Object Structures <buffer-structs>`. For obtaining
	a buffer, see :c:func:`PyObject_GetBuffer`.

	.. c:type:: Py_buffer

	.. c:member:: void \*buf

	A pointer to the start of the logical structure described by the buffer
	fields. This can be any location within the underlying physical memory
	block of the exporter. For example, with negative :c:member:`~Py_buffer.strides`
	the value may point to the end of the memory block.

	For :term:`contiguous` arrays, the value points to the beginning of
	the memory block.

	.. c:member:: void \*obj

	A new reference to the exporting object. The reference is owned by
	the consumer and automatically decremented and set to NULL by
	:c:func:`PyBuffer_Release`. The field is the equivalent of the return
	value of any standard C-API function.

	As a special case, for temporary buffers that are wrapped by
	:c:func:`PyMemoryView_FromBuffer` or :c:func:`PyBuffer_FillInfo`
	this field is NULL. In general, exporting objects MUST NOT
	use this scheme.

	.. c:member:: Py_ssize_t len

	``product(shape) * itemsize``. For contiguous arrays, this is the length
	of the underlying memory block. For non-contiguous arrays, it is the length
	that the logical structure would have if it were copied to a contiguous
	representation.

	Accessing ``((char )buf)[0] up to ((char )buf)[len-1]`` is only valid
	if the buffer has been obtained by a request that guarantees contiguity. In
	most cases such a request will be :c:macro:`PyBUF_SIMPLE` or :c:macro:`PyBUF_WRITABLE`.

	.. c:member:: int readonly

	An indicator of whether the buffer is read-only. This field is controlled
	by the :c:macro:`PyBUF_WRITABLE` flag.

	.. c:member:: Py_ssize_t itemsize

	Item size in bytes of a single element. Same as the value of :func:`struct.calcsize`
	called on non-NULL :c:member:`~Py_buffer.format` values.

	Important exception: If a consumer requests a buffer without the
	:c:macro:`PyBUF_FORMAT` flag, :c:member:`~Py_buffer.format` will
	be set to NULL, but :c:member:`~Py_buffer.itemsize` still has
	the value for the original format.

	If :c:member:`~Py_buffer.shape` is present, the equality
	``product(shape) * itemsize == len`` still holds and the consumer
	can use :c:member:`~Py_buffer.itemsize` to navigate the buffer.

	If :c:member:`~Py_buffer.shape` is NULL as a result of a :c:macro:`PyBUF_SIMPLE`
	or a :c:macro:`PyBUF_WRITABLE` request, the consumer must disregard
	:c:member:`~Py_buffer.itemsize` and assume ``itemsize == 1``.

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

	A NUL terminated string in :mod:`struct` module style syntax describing
	the contents of a single item. If this is NULL, ``"B"`` (unsigned bytes)
	is assumed.

	This field is controlled by the :c:macro:`PyBUF_FORMAT` flag.

	.. c:member:: int ndim

	The number of dimensions the memory represents as an n-dimensional array.
	If it is ``0``, :c:member:`~Py_buffer.buf` points to a single item representing
	a scalar. In this case, :c:member:`~Py_buffer.shape`, :c:member:`~Py_buffer.strides`
	and :c:member:`~Py_buffer.suboffsets` MUST be NULL.

	The macro :c:macro:`PyBUF_MAX_NDIM` limits the maximum number of dimensions
	to 64. Exporters MUST respect this limit, consumers of multi-dimensional
	buffers SHOULD be able to handle up to :c:macro:`PyBUF_MAX_NDIM` dimensions.

	.. c:member:: Py_ssize_t \*shape

	An array of :c:type:`Py_ssize_t` of length :c:member:`~Py_buffer.ndim`
	indicating the shape of the memory as an n-dimensional array. Note that
	``shape[0] * ... * shape[ndim-1] * itemsize`` MUST be equal to
	:c:member:`~Py_buffer.len`.

	Shape values are restricted to ``shape[n] >= 0``. The case
	``shape[n] == 0`` requires special attention. See `complex arrays`_
	for further information.

	The shape array is read-only for the consumer.

	.. c:member:: Py_ssize_t \*strides

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

	Stride values can be any integer. For regular arrays, strides are
	usually positive, but a consumer MUST be able to handle the case
	``strides[n] <= 0``. See `complex arrays`_ for further information.

	The strides array is read-only for the consumer.

	.. c:member:: Py_ssize_t \*suboffsets

	An array of :c:type:`Py_ssize_t` of length :c:member:`~Py_buffer.ndim`.
	If ``suboffsets[n] >= 0``, the values stored along the nth dimension are
	pointers and the suboffset value dictates how many bytes to add to each
	pointer after de-referencing. A suboffset value that is negative
	indicates that no de-referencing should occur (striding in a contiguous
	memory block).

	If all suboffsets are negative (i.e. no de-referencing is needed, then
	this field must be NULL (the default value).

	This type of array representation is used by the Python Imaging Library
	(PIL). See `complex arrays`_ for further information how to access elements
	of such an array.

	The suboffsets array is read-only for the consumer.

	.. 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 MUST NOT alter this
	value.

	.. _buffer-request-types:

	Buffer request types
	====================

	Buffers are usually obtained by sending a buffer request to an exporting
	object via :c:func:`PyObject_GetBuffer`. Since the complexity of the logical
	structure of the memory can vary drastically, the consumer uses the flags
	argument to specify the exact buffer type it can handle.

	All :c:data:`Py_buffer` fields are unambiguously defined by the request
	type.

	request-independent fields
	~~~~~~~~~~~~~~~~~~~~~~~~~~
	The following fields are not influenced by flags and must always be filled in
	with the correct values: :c:member:`~Py_buffer.obj`, :c:member:`~Py_buffer.buf`,
	:c:member:`~Py_buffer.len`, :c:member:`~Py_buffer.itemsize`, :c:member:`~Py_buffer.ndim`.


	readonly, format
	~~~~~~~~~~~~~~~~

	.. c:macro:: PyBUF_WRITABLE

	Controls the :c:member:`~Py_buffer.readonly` field. If set, the exporter
	MUST provide a writable buffer or else report failure. Otherwise, the
	exporter MAY provide either a read-only or writable buffer, but the choice
	MUST be consistent for all consumers.

	.. c:macro:: PyBUF_FORMAT

	Controls the :c:member:`~Py_buffer.format` field. If set, this field MUST
	be filled in correctly. Otherwise, this field MUST be NULL.


	:c:macro:`PyBUF_WRITABLE` can be \\|'d to any of the flags in the next section.
	Since :c:macro:`PyBUF_SIMPLE` is defined as 0, :c:macro:`PyBUF_WRITABLE`
	can be used as a stand-alone flag to request a simple writable buffer.

	:c:macro:`PyBUF_FORMAT` can be \\|'d to any of the flags except :c:macro:`PyBUF_SIMPLE`.
	The latter already implies format ``B`` (unsigned bytes).


	shape, strides, suboffsets
	~~~~~~~~~~~~~~~~~~~~~~~~~~

	The flags that control the logical structure of the memory are listed
	in decreasing order of complexity. Note that each flag contains all bits
	of the flags below it.

	.. tabularcolumns:: \|p{0.35\linewidth}\|l\|l\|l\|

	+-----------------------------+-------+---------+------------+
	\| Request \| shape \| strides \| suboffsets \|
	+=============================+=======+=========+============+
	\| .. c:macro:: PyBUF_INDIRECT \| yes \| yes \| if needed \|
	+-----------------------------+-------+---------+------------+
	\| .. c:macro:: PyBUF_STRIDES \| yes \| yes \| NULL \|
	+-----------------------------+-------+---------+------------+
	\| .. c:macro:: PyBUF_ND \| yes \| NULL \| NULL \|
	+-----------------------------+-------+---------+------------+
	\| .. c:macro:: PyBUF_SIMPLE \| NULL \| NULL \| NULL \|
	+-----------------------------+-------+---------+------------+


	.. index:: contiguous, C-contiguous, Fortran contiguous

	contiguity requests
	~~~~~~~~~~~~~~~~~~~

	C or Fortran :term:`contiguity <contiguous>` can be explicitly requested,
	with and without stride information. Without stride information, the buffer
	must be C-contiguous.

	.. tabularcolumns:: \|p{0.35\linewidth}\|l\|l\|l\|l\|

	+-----------------------------------+-------+---------+------------+--------+
	\| Request \| shape \| strides \| suboffsets \| contig \|
	+===================================+=======+=========+============+========+
	\| .. c:macro:: PyBUF_C_CONTIGUOUS \| yes \| yes \| NULL \| C \|
	+-----------------------------------+-------+---------+------------+--------+
	\| .. c:macro:: PyBUF_F_CONTIGUOUS \| yes \| yes \| NULL \| F \|
	+-----------------------------------+-------+---------+------------+--------+
	\| .. c:macro:: PyBUF_ANY_CONTIGUOUS \| yes \| yes \| NULL \| C or F \|
	+-----------------------------------+-------+---------+------------+--------+
	\| .. c:macro:: PyBUF_ND \| yes \| NULL \| NULL \| C \|
	+-----------------------------------+-------+---------+------------+--------+


	compound requests
	~~~~~~~~~~~~~~~~~

	All possible requests are fully defined by some combination of the flags in
	the previous section. For convenience, the buffer protocol provides frequently
	used combinations as single flags.

	In the following table U stands for undefined contiguity. The consumer would
	have to call :c:func:`PyBuffer_IsContiguous` to determine contiguity.

	.. tabularcolumns:: \|p{0.35\linewidth}\|l\|l\|l\|l\|l\|l\|

	+-------------------------------+-------+---------+------------+--------+----------+--------+
	\| Request \| shape \| strides \| suboffsets \| contig \| readonly \| format \|
	+===============================+=======+=========+============+========+==========+========+
	\| .. c:macro:: PyBUF_FULL \| yes \| yes \| if needed \| U \| 0 \| yes \|
	+-------------------------------+-------+---------+------------+--------+----------+--------+
	\| .. c:macro:: PyBUF_FULL_RO \| yes \| yes \| if needed \| U \| 1 or 0 \| yes \|
	+-------------------------------+-------+---------+------------+--------+----------+--------+
	\| .. c:macro:: PyBUF_RECORDS \| yes \| yes \| NULL \| U \| 0 \| yes \|
	+-------------------------------+-------+---------+------------+--------+----------+--------+
	\| .. c:macro:: PyBUF_RECORDS_RO \| yes \| yes \| NULL \| U \| 1 or 0 \| yes \|
	+-------------------------------+-------+---------+------------+--------+----------+--------+
	\| .. c:macro:: PyBUF_STRIDED \| yes \| yes \| NULL \| U \| 0 \| NULL \|
	+-------------------------------+-------+---------+------------+--------+----------+--------+
	\| .. c:macro:: PyBUF_STRIDED_RO \| yes \| yes \| NULL \| U \| 1 or 0 \| NULL \|
	+-------------------------------+-------+---------+------------+--------+----------+--------+
	\| .. c:macro:: PyBUF_CONTIG \| yes \| NULL \| NULL \| C \| 0 \| NULL \|
	+-------------------------------+-------+---------+------------+--------+----------+--------+
	\| .. c:macro:: PyBUF_CONTIG_RO \| yes \| NULL \| NULL \| C \| 1 or 0 \| NULL \|
	+-------------------------------+-------+---------+------------+--------+----------+--------+


	Complex arrays
	==============

	NumPy-style: shape and strides
	~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~

	The logical structure of NumPy-style arrays is defined by :c:member:`~Py_buffer.itemsize`,
	:c:member:`~Py_buffer.ndim`, :c:member:`~Py_buffer.shape` and :c:member:`~Py_buffer.strides`.

	If ``ndim == 0``, the memory location pointed to by :c:member:`~Py_buffer.buf` is
	interpreted as a scalar of size :c:member:`~Py_buffer.itemsize`. In that case,
	both :c:member:`~Py_buffer.shape` and :c:member:`~Py_buffer.strides` are NULL.

	If :c:member:`~Py_buffer.strides` is NULL, the array is interpreted as
	a standard n-dimensional C-array. Otherwise, the consumer must access an
	n-dimensional array as follows:

	``ptr = (char )buf + indices[0] strides[0] + ... + indices[n-1] * strides[n-1]``
	``item = ((typeof(item) )ptr);``


	As noted above, :c:member:`~Py_buffer.buf` can point to any location within
	the actual memory block. An exporter can check the validity of a buffer with
	this function:

	.. code-block:: python

	def verify_structure(memlen, itemsize, ndim, shape, strides, offset):
	"""Verify that the parameters represent a valid array within
	the bounds of the allocated memory:
	char *mem: start of the physical memory block
	memlen: length of the physical memory block
	offset: (char *)buf - mem
	"""
	if offset % itemsize:
	return False
	if offset < 0 or offset+itemsize > memlen:
	return False
	if any(v % itemsize for v in strides):
	return False

	if ndim <= 0:
	return ndim == 0 and not shape and not strides
	if 0 in shape:
	return True

	imin = sum(strides[j]*(shape[j]-1) for j in range(ndim)
	if strides[j] <= 0)
	imax = sum(strides[j]*(shape[j]-1) for j in range(ndim)
	if strides[j] > 0)

	return 0 <= offset+imin and offset+imax+itemsize <= memlen


	PIL-style: shape, strides and suboffsets
	~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~

	In addition to the regular items, PIL-style arrays can contain pointers
	that must be followed in order to get to the next element in a dimension.
	For example, the regular three-dimensional C-array ``char v[2][2][3]`` can
	also be viewed as an array of 2 pointers to 2 two-dimensional arrays:
	``char (*v[2])[2][3]``. In suboffsets representation, those two pointers
	can be embedded at the start of :c:member:`~Py_buffer.buf`, pointing
	to two ``char x[2][3]`` arrays that can be located anywhere in memory.


	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;
	}


	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 exporter, Py_buffer view, int flags)

	Send a request to exporter to fill in view as specified by flags.
	If the exporter cannot provide a buffer of the exact type, it MUST raise
	:c:data:`PyExc_BufferError`, set :c:member:`view->obj` to NULL and
	return ``-1``.

	On success, fill in view, set :c:member:`view->obj` to a new reference
	to exporter and return 0. In the case of chained buffer providers
	that redirect requests to a single object, :c:member:`view->obj` MAY
	refer to this object instead of exporter (See :ref:`Buffer Object Structures <buffer-structs>`).

	Successful calls to :c:func:`PyObject_GetBuffer` must be paired with calls
	to :c:func:`PyBuffer_Release`, similar to :c:func:`malloc` and :c:func:`free`.
	Thus, after the consumer is done with the buffer, :c:func:`PyBuffer_Release`
	must be called exactly once.


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

	Release the buffer view and decrement the reference count for
	:c:member:`view->obj`. This function MUST be called when the buffer
	is no longer being used, otherwise reference leaks may occur.

	It is an error to call this function on a buffer that was not obtained via
	:c:func:`PyObject_GetBuffer`.


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

	Return the implied :c:data:`~Py_buffer.itemsize` from :c:data:`~Py_buffer.format`.
	This function is not yet implemented.


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

	Return ``1`` if the memory defined by the view is C-style (order is
	``'C'``) or Fortran-style (order is ``'F'``) :term:`contiguous` or either one
	(order 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 order)

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


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

	Handle buffer requests for an exporter that wants to expose buf of size len
	with writability set according to readonly. buf is interpreted as a sequence
	of unsigned bytes.

	The flags argument indicates the request type. This function always fills in
	view as specified by flags, unless buf has been designated as read-only
	and :c:macro:`PyBUF_WRITABLE` is set in flags.

	On success, set :c:member:`view->obj` to a new reference to exporter and
	return 0. Otherwise, raise :c:data:`PyExc_BufferError`, set
	:c:member:`view->obj` to NULL and return ``-1``;

	If this function is used as part of a :ref:`getbufferproc <buffer-structs>`,
	exporter MUST be set to the exporting object and flags must be passed
	unmodified. Otherwise, exporter MUST be NULL.