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Code Issues Releases Wiki Activity

- Issue #10181: New memoryview implementation fixes multiple ownership 

and lifetime issues of dynamically allocated Py_buffer members (#9990)
  as well as crashes (#8305, #7433). Many new features have been added
  (See whatsnew/3.3), and the documentation has been updated extensively.
  The ndarray test object from _testbuffer.c implements all aspects of
  PEP-3118, so further development towards the complete implementation
  of the PEP can proceed in a test-driven manner.

  Thanks to Nick Coghlan, Antoine Pitrou and Pauli Virtanen for review
  and many ideas.

- Issue #12834: Fix incorrect results of memoryview.tobytes() for
  non-contiguous arrays.

- Issue #5231: Introduce memoryview.cast() method that allows changing
  format and shape without making a copy of the underlying memory.
This commit is contained in:
Stefan Krah 2012-02-25 12:24:21 +01:00
parent 5a3d04623b
commit 9a2d99e28a
24 changed files with 10011 additions and 1171 deletions
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515
Doc/c-api/buffer.rst
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@ -7,6 +7,7 @@ Buffer Protocol
.. sectionauthor:: Greg Stein <gstein@lyra.org>
.. sectionauthor:: Benjamin Peterson
.. sectionauthor:: Stefan Krah
.. index::
@ -20,7 +21,7 @@ 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
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 *buffer
@ -60,8 +61,10 @@ isn't needed anymore. Failure to do so could lead to various issues such as
resource leaks.
The buffer structure
====================
.. _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
@ -81,56 +84,312 @@ can be created.
.. c:type:: Py_buffer
.. c:member:: void *buf
.. c:member:: void \*obj
A pointer to the start of the memory for the object.
A new reference to the exporting object or *NULL*. The reference is owned
by the consumer and automatically decremented and set to *NULL* by
:c:func:`PyBuffer_Release`.
For temporary buffers that are wrapped by :c:func:`PyMemoryView_FromBuffer`
this field must be *NULL*.
.. 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 contiguous arrays, the value points to the beginning of the memory
block.
.. c:member:: Py_ssize_t len
:noindex:
The total length of the memory in bytes.
``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.
An indicator of whether the buffer is read-only. This field is controlled
by the :c:macro:`PyBUF_WRITABLE` flag.
.. c:member:: const char *format
:noindex:
.. c:member:: Py_ssize_t itemsize
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.
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 a multi-dimensional
array. If it is 0, :c:data:`strides` and :c:data:`suboffsets` must be
*NULL*.
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*.
.. c:member:: Py_ssize_t *shape
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.
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 \*shape
.. c:member:: Py_ssize_t *strides
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`.
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.
Shape values are restricted to ``shape[n] >= 0``. The case
``shape[n] == 0`` requires special attention. See `complex arrays`_
for further information.
.. c:member:: Py_ssize_t *suboffsets
The shape array is read-only for the consumer.
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).
.. c:member:: Py_ssize_t \*strides
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::
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).
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.
+-----------------------------+-------+---------+------------+
| 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 |
+-----------------------------+-------+---------+------------+
contiguity requests
~~~~~~~~~~~~~~~~~~~
C or Fortran contiguity can be explicitly requested, with and without stride
information. Without stride information, the buffer must be C-contiguous.
+-----------------------------------+-------+---------+------------+--------+
| 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.
+-------------------------------+-------+---------+------------+--------+----------+--------+
| 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) {
@ -146,28 +405,9 @@ can be created.
}
.. 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
@ -175,152 +415,69 @@ Buffer-related functions
succeed.
.. c:function:: int PyObject_GetBuffer(PyObject *obj, Py_buffer *view, int flags)
.. c:function:: int PyObject_GetBuffer(PyObject *exporter, 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).
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.
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, fill in *view*, set :c:member:`view->obj` to a new reference
to *exporter* and return 0.
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)``.
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*. This should be called when the buffer is no
longer being used as it may free memory from it.
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 the struct-stype
:c:data:`~Py_buffer.format`.
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 fortran)
.. c:function:: int PyBuffer_IsContiguous(Py_buffer *view, char order)
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.
Return 1 if the memory defined by the *view* is C-style (*order* is
``'C'``) or Fortran-style (*order* is ``'F'``) 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 fortran)
.. 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 contiguous (C-style if
*fortran* is ``'C'`` or Fortran-style if *fortran* is ``'F'``) array of the
*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 *obj, void *buf, Py_ssize_t len, int readonly, int infoflags)
.. 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. Otherwise, *exporter* MUST
be NULL.
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.

29
Doc/c-api/memoryview.rst
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@ -17,16 +17,19 @@ any other object.
Create a memoryview object from an object that provides the buffer interface.
If *obj* supports writable buffer exports, the memoryview object will be
readable and writable, otherwise it will be read-only.
read/write, otherwise it may be either read-only or read/write at the
discretion of the exporter.
.. c:function:: PyObject *PyMemoryView_FromMemory(char *mem, Py_ssize_t size, int flags)
Create a memoryview object using *mem* as the underlying buffer.
*flags* can be one of :c:macro:`PyBUF_READ` or :c:macro:`PyBUF_WRITE`.
.. c:function:: PyObject *PyMemoryView_FromBuffer(Py_buffer *view)
Create a memoryview object wrapping the given buffer structure *view*.
The memoryview object then owns the buffer represented by *view*, which
means you shouldn't try to call :c:func:`PyBuffer_Release` yourself: it
will be done on deallocation of the memoryview object.
For simple byte buffers, :c:func:`PyMemoryView_FromMemory` is the preferred
function.
.. c:function:: PyObject *PyMemoryView_GetContiguous(PyObject *obj, int buffertype, char order)
@ -43,10 +46,16 @@ any other object.
currently allowed to create subclasses of :class:`memoryview`.
.. c:function:: Py_buffer *PyMemoryView_GET_BUFFER(PyObject *obj)
.. c:function:: Py_buffer *PyMemoryView_GET_BUFFER(PyObject *mview)
Return a pointer to the buffer structure wrapped by the given
memoryview object. The object **must** be a memoryview instance;
this macro doesn't check its type, you must do it yourself or you
will risk crashes.
Return a pointer to the memoryview's private copy of the exporter's buffer.
*mview* **must** be a memoryview instance; this macro doesn't check its type,
you must do it yourself or you will risk crashes.
.. c:function:: Py_buffer *PyMemoryView_GET_BASE(PyObject *mview)
Return either a pointer to the exporting object that the memoryview is based
on or *NULL* if the memoryview has been created by one of the functions
:c:func:`PyMemoryView_FromMemory` or :c:func:`PyMemoryView_FromBuffer`.
*mview* **must** be a memoryview instance.

96
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@ -1198,46 +1198,74 @@ Buffer Object Structures
.. sectionauthor:: Greg J. Stein <greg@lyra.org>
.. sectionauthor:: Benjamin Peterson
The :ref:`buffer interface <bufferobjects>` exports a model where an object can expose its internal
data.
If an object does not export the buffer interface, then its :attr:`tp_as_buffer`
member in the :c:type:`PyTypeObject` structure should be *NULL*. Otherwise, the
:attr:`tp_as_buffer` will point to a :c:type:`PyBufferProcs` structure.
.. sectionauthor:: Stefan Krah
.. c:type:: PyBufferProcs
Structure used to hold the function pointers which define an implementation of
the buffer protocol.
This structure holds pointers to the functions required by the
:ref:`Buffer protocol <bufferobjects>`. The protocol defines how
an exporter object can expose its internal data to consumer objects.
.. c:member:: getbufferproc bf_getbuffer
.. c:member:: getbufferproc PyBufferProcs.bf_getbuffer
This should fill a :c:type:`Py_buffer` with the necessary data for
exporting the type. The signature of :data:`getbufferproc` is ``int
(PyObject *obj, Py_buffer *view, int flags)``. *obj* is the object to
export, *view* is the :c:type:`Py_buffer` struct to fill, and *flags* gives
the conditions the caller wants the memory under. (See
:c:func:`PyObject_GetBuffer` for all flags.) :c:member:`bf_getbuffer` is
responsible for filling *view* with the appropriate information.
(:c:func:`PyBuffer_FillView` can be used in simple cases.) See
:c:type:`Py_buffer`\s docs for what needs to be filled in.
The signature of this function is::
int (PyObject *exporter, Py_buffer *view, int flags);
Handle a request to *exporter* to fill in *view* as specified by *flags*.
A standard implementation of this function will take these steps:
- Check if the request can be met. If not, raise :c:data:`PyExc_BufferError`,
set :c:data:`view->obj` to *NULL* and return -1.
- Fill in the requested fields.
- Increment an internal counter for the number of exports.
- Set :c:data:`view->obj` to *exporter* and increment :c:data:`view->obj`.
- Return 0.
The individual fields of *view* are described in section
:ref:`Buffer structure <buffer-structure>`, the rules how an exporter
must react to specific requests are in section
:ref:`Buffer request types <buffer-request-types>`.
All memory pointed to in the :c:type:`Py_buffer` structure belongs to
the exporter and must remain valid until there are no consumers left.
:c:member:`~Py_buffer.shape`, :c:member:`~Py_buffer.strides`,
:c:member:`~Py_buffer.suboffsets` and :c:member:`~Py_buffer.internal`
are read-only for the consumer.
:c:func:`PyBuffer_FillInfo` provides an easy way of exposing a simple
bytes buffer while dealing correctly with all request types.
:c:func:`PyObject_GetBuffer` is the interface for the consumer that
wraps this function.
.. c:member:: releasebufferproc PyBufferProcs.bf_releasebuffer
The signature of this function is::
void (PyObject *exporter, Py_buffer *view);
Handle a request to release the resources of the buffer. If no resources
need to be released, this field may be *NULL*. A standard implementation
of this function will take these steps:
- Decrement an internal counter for the number of exports.
- If the counter is 0, free all memory associated with *view*.
The exporter MUST use the :c:member:`~Py_buffer.internal` field to keep
track of buffer-specific resources (if present). This field is guaranteed
to remain constant, while a consumer MAY pass a copy of the original buffer
as the *view* argument.
.. c:member:: releasebufferproc bf_releasebuffer
This function MUST NOT decrement :c:data:`view->obj`, since that is
done automatically in :c:func:`PyBuffer_Release`.
This should release the resources of the buffer. The signature of
:c:data:`releasebufferproc` is ``void (PyObject *obj, Py_buffer *view)``.
If the :c:data:`bf_releasebuffer` function is not provided (i.e. it is
*NULL*), then it does not ever need to be called.
The exporter of the buffer interface must make sure that any memory
pointed to in the :c:type:`Py_buffer` structure remains valid until
releasebuffer is called. Exporters will need to define a
:c:data:`bf_releasebuffer` function if they can re-allocate their memory,
strides, shape, suboffsets, or format variables which they might share
through the struct bufferinfo.
See :c:func:`PyBuffer_Release`.
:c:func:`PyBuffer_Release` is the interface for the consumer that
wraps this function.

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@ -2377,7 +2377,7 @@ memoryview type
:class:`memoryview` objects allow Python code to access the internal data
of an object that supports the :ref:`buffer protocol <bufferobjects>` without
copying. Memory is generally interpreted as simple bytes.
copying.
.. class:: memoryview(obj)
@ -2391,52 +2391,88 @@ copying. Memory is generally interpreted as simple bytes.
is a single byte, but other types such as :class:`array.array` may have
bigger elements.
``len(view)`` returns the total number of elements in the memoryview,
*view*. The :class:`~memoryview.itemsize` attribute will give you the
``len(view)`` is equal to the length of :class:`~memoryview.tolist`.
If ``view.ndim = 0``, the length is 1. If ``view.ndim = 1``, the length
is equal to the number of elements in the view. For higher dimensions,
the length is equal to the length of the nested list representation of
the view. The :class:`~memoryview.itemsize` attribute will give you the
number of bytes in a single element.
A :class:`memoryview` supports slicing to expose its data. Taking a single
index will return a single element as a :class:`bytes` object. Full
slicing will result in a subview::
A :class:`memoryview` supports slicing to expose its data. If
:class:`~memoryview.format` is one of the native format specifiers
from the :mod:`struct` module, indexing will return a single element
with the correct type. Full slicing will result in a subview::
>>> v = memoryview(b'abcefg')
>>> v[1]
b'b'
98
>>> v[-1]
b'g'
103
>>> v[1:4]
<memory at 0x77ab28>
<memory at 0x7f3ddc9f4350>
>>> bytes(v[1:4])
b'bce'
If the object the memoryview is over supports changing its data, the
memoryview supports slice assignment::
Other native formats::
>>> import array
>>> a = array.array('l', [-11111111, 22222222, -33333333, 44444444])
>>> a[0]
-11111111
>>> a[-1]
44444444
>>> a[2:3].tolist()
[-33333333]
>>> a[::2].tolist()
[-11111111, -33333333]
>>> a[::-1].tolist()
[44444444, -33333333, 22222222, -11111111]
.. versionadded:: 3.3
If the underlying object is writable, the memoryview supports slice
assignment. Resizing is not allowed::
>>> data = bytearray(b'abcefg')
>>> v = memoryview(data)
>>> v.readonly
False
>>> v[0] = b'z'
>>> v[0] = ord(b'z')
>>> data
bytearray(b'zbcefg')
>>> v[1:4] = b'123'
>>> data
bytearray(b'z123fg')
>>> v[2] = b'spam'
>>> v[2:3] = b'spam'
Traceback (most recent call last):
File "<stdin>", line 1, in <module>
ValueError: cannot modify size of memoryview object
ValueError: memoryview assignment: lvalue and rvalue have different structures
>>> v[2:6] = b'spam'
>>> data
bytearray(b'z1spam')
Notice how the size of the memoryview object cannot be changed.
Memoryviews of hashable (read-only) types are also hashable and their
hash value matches the corresponding bytes object::
Memoryviews of hashable (read-only) types are also hashable. The hash
is defined as ``hash(m) == hash(m.tobytes())``::
>>> v = memoryview(b'abcefg')
>>> hash(v) == hash(b'abcefg')
True
>>> hash(v[2:4]) == hash(b'ce')
True
>>> hash(v[::-2]) == hash(b'abcefg'[::-2])
True
Hashing of multi-dimensional objects is supported::
>>> buf = bytes(list(range(12)))
>>> x = memoryview(buf)
>>> y = x.cast('B', shape=[2,2,3])
>>> x.tolist()
[0, 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11]
>>> y.tolist()
[[[0, 1, 2], [3, 4, 5]], [[6, 7, 8], [9, 10, 11]]]
>>> hash(x) == hash(y) == hash(y.tobytes())
True
.. versionchanged:: 3.3
Memoryview objects are now hashable.
@ -2455,12 +2491,20 @@ copying. Memory is generally interpreted as simple bytes.
>>> bytes(m)
b'abc'
For non-contiguous arrays the result is equal to the flattened list
representation with all elements converted to bytes.
.. method:: tolist()
Return the data in the buffer as a list of integers. ::
Return the data in the buffer as a list of elements. ::
>>> memoryview(b'abc').tolist()
[97, 98, 99]
>>> import array
>>> a = array.array('d', [1.1, 2.2, 3.3])
>>> m = memoryview(a)
>>> m.tolist()
[1.1, 2.2, 3.3]
.. method:: release()
@ -2487,7 +2531,7 @@ copying. Memory is generally interpreted as simple bytes.
>>> with memoryview(b'abc') as m:
... m[0]
...
b'a'
97
>>> m[0]
Traceback (most recent call last):
File "<stdin>", line 1, in <module>
@ -2495,45 +2539,219 @@ copying. Memory is generally interpreted as simple bytes.
.. versionadded:: 3.2
.. method:: cast(format[, shape])
Cast a memoryview to a new format or shape. *shape* defaults to
``[byte_length//new_itemsize]``, which means that the result view
will be one-dimensional. The return value is a new memoryview, but
the buffer itself is not copied. Supported casts are 1D -> C-contiguous
and C-contiguous -> 1D. One of the formats must be a byte format
('B', 'b' or 'c'). The byte length of the result must be the same
as the original length.
Cast 1D/long to 1D/unsigned bytes::
>>> import array
>>> a = array.array('l', [1,2,3])
>>> x = memoryview(a)
>>> x.format
'l'
>>> x.itemsize
8
>>> len(x)
3
>>> x.nbytes
24
>>> y = x.cast('B')
>>> y.format
'B'
>>> y.itemsize
1
>>> len(y)
24
>>> y.nbytes
24
Cast 1D/unsigned bytes to 1D/char::
>>> b = bytearray(b'zyz')
>>> x = memoryview(b)
>>> x[0] = b'a'
Traceback (most recent call last):
File "<stdin>", line 1, in <module>
ValueError: memoryview: invalid value for format "B"
>>> y = x.cast('c')
>>> y[0] = b'a'
>>> b
bytearray(b'ayz')
Cast 1D/bytes to 3D/ints to 1D/signed char::
>>> import struct
>>> buf = struct.pack("i"*12, *list(range(12)))
>>> x = memoryview(buf)
>>> y = x.cast('i', shape=[2,2,3])
>>> y.tolist()
[[[0, 1, 2], [3, 4, 5]], [[6, 7, 8], [9, 10, 11]]]
>>> y.format
'i'
>>> y.itemsize
4
>>> len(y)
2
>>> y.nbytes
48
>>> z = y.cast('b')
>>> z.format
'b'
>>> z.itemsize
1
>>> len(z)
48
>>> z.nbytes
48
Cast 1D/unsigned char to to 2D/unsigned long::
>>> buf = struct.pack("L"*6, *list(range(6)))
>>> x = memoryview(buf)
>>> y = x.cast('L', shape=[2,3])
>>> len(y)
2
>>> y.nbytes
48
>>> y.tolist()
[[0, 1, 2], [3, 4, 5]]
.. versionadded:: 3.3
There are also several readonly attributes available:
.. attribute:: obj
The underlying object of the memoryview::
>>> b = bytearray(b'xyz')
>>> m = memoryview(b)
>>> m.obj is b
True
.. versionadded:: 3.3
.. attribute:: nbytes
``nbytes == product(shape) * itemsize == len(m.tobytes())``. This is
the amount of space in bytes that the array would use in a contiguous
representation. It is not necessarily equal to len(m)::
>>> import array
>>> a = array.array('i', [1,2,3,4,5])
>>> m = memoryview(a)
>>> len(m)
5
>>> m.nbytes
20
>>> y = m[::2]
>>> len(y)
3
>>> y.nbytes
12
>>> len(y.tobytes())
12
Multi-dimensional arrays::
>>> import struct
>>> buf = struct.pack("d"*12, *[1.5*x for x in range(12)])
>>> x = memoryview(buf)
>>> y = x.cast('d', shape=[3,4])
>>> y.tolist()
[[0.0, 1.5, 3.0, 4.5], [6.0, 7.5, 9.0, 10.5], [12.0, 13.5, 15.0, 16.5]]
>>> len(y)
3
>>> y.nbytes
96
.. versionadded:: 3.3
.. attribute:: readonly
A bool indicating whether the memory is read only.
.. attribute:: format
A string containing the format (in :mod:`struct` module style) for each
element in the view. This defaults to ``'B'``, a simple bytestring.
element in the view. A memoryview can be created from exporters with
arbitrary format strings, but some methods (e.g. :meth:`tolist`) are
restricted to native single element formats. Special care must be taken
when comparing memoryviews. Since comparisons are required to return a
value for ``==`` and ``!=``, two memoryviews referencing the same
exporter can compare as not-equal if the exporter's format is not
understood::
>>> from ctypes import BigEndianStructure, c_long
>>> class BEPoint(BigEndianStructure):
... _fields_ = [("x", c_long), ("y", c_long)]
...
>>> point = BEPoint(100, 200)
>>> a = memoryview(point)
>>> b = memoryview(point)
>>> a == b
False
>>> a.tolist()
Traceback (most recent call last):
File "<stdin>", line 1, in <module>
NotImplementedError: memoryview: unsupported format T{>l:x:>l:y:}
.. attribute:: itemsize
The size in bytes of each element of the memoryview::
>>> m = memoryview(array.array('H', [1,2,3]))
>>> import array, struct
>>> m = memoryview(array.array('H', [32000, 32001, 32002]))
>>> m.itemsize
2
>>> m[0]
b'\x01\x00'
>>> len(m[0]) == m.itemsize
32000
>>> struct.calcsize('H') == m.itemsize
True
.. attribute:: shape
A tuple of integers the length of :attr:`ndim` giving the shape of the
memory as a N-dimensional array.
.. attribute:: ndim
An integer indicating how many dimensions of a multi-dimensional array the
memory represents.
.. attribute:: shape
A tuple of integers the length of :attr:`ndim` giving the shape of the
memory as a N-dimensional array.
.. attribute:: strides
A tuple of integers the length of :attr:`ndim` giving the size in bytes to
access each element for each dimension of the array.
.. attribute:: readonly
.. attribute:: suboffsets
A bool indicating whether the memory is read only.
Used internally for PIL-style arrays. The value is informational only.
.. memoryview.suboffsets isn't documented because it only seems useful for C
.. attribute:: c_contiguous
A bool indicating whether the memory is C-contiguous.
.. versionadded:: 3.3
.. attribute:: f_contiguous
A bool indicating whether the memory is Fortran contiguous.
.. versionadded:: 3.3
.. attribute:: contiguous
A bool indicating whether the memory is contiguous.
.. versionadded:: 3.3
.. _typecontextmanager:

56
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@ -49,6 +49,62 @@
This article explains the new features in Python 3.3, compared to 3.2.
.. _pep-3118:
PEP 3118: New memoryview implementation and buffer protocol documentation
=========================================================================
:issue:`10181` - memoryview bug fixes and features.
Written by Stefan Krah.
The new memoryview implementation comprehensively fixes all ownership and
lifetime issues of dynamically allocated fields in the Py_buffer struct
that led to multiple crash reports. Additionally, several functions that
crashed or returned incorrect results for non-contiguous or multi-dimensional
input have been fixed.
The memoryview object now has a PEP-3118 compliant getbufferproc()
that checks the consumer's request type. Many new features have been
added, most of them work in full generality for non-contiguous arrays
and arrays with suboffsets.
The documentation has been updated, clearly spelling out responsibilities
for both exporters and consumers. Buffer request flags are grouped into
basic and compound flags. The memory layout of non-contiguous and
multi-dimensional NumPy-style arrays is explained.
Features
--------
* All native single character format specifiers in struct module syntax
(optionally prefixed with '@') are now supported.
* With some restrictions, the cast() method allows changing of format and
shape of C-contiguous arrays.
* Multi-dimensional list representations are supported for any array type.
* Multi-dimensional comparisons are supported for any array type.
* All array types are hashable if the exporting object is hashable
and the view is read-only.
* Arbitrary slicing of any 1-D arrays type is supported. For example, it
is now possible to reverse a memoryview in O(1) by using a negative step.
API changes
-----------
* The maximum number of dimensions is officially limited to 64.
* The representation of empty shape, strides and suboffsets is now
an empty tuple instead of None.
* Accessing a memoryview element with format 'B' (unsigned bytes)
now returns an integer (in accordance with the struct module syntax).
For returning a bytes object the view must be cast to 'c' first.
.. _pep-393:
PEP 393: Flexible String Representation

2
Include/abstract.h
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@ -559,7 +559,7 @@ xxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxx*/
/* Copy the data from the src buffer to the buffer of destination
*/
PyAPI_FUNC(int) PyBuffer_IsContiguous(Py_buffer *view, char fort);
PyAPI_FUNC(int) PyBuffer_IsContiguous(const Py_buffer *view, char fort);
PyAPI_FUNC(void) PyBuffer_FillContiguousStrides(int ndims,

84
Include/memoryobject.h
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@ -6,70 +6,64 @@
extern "C" {
#endif
#ifndef Py_LIMITED_API
PyAPI_DATA(PyTypeObject) _PyManagedBuffer_Type;
#endif
PyAPI_DATA(PyTypeObject) PyMemoryView_Type;
#define PyMemoryView_Check(op) (Py_TYPE(op) == &PyMemoryView_Type)
#ifndef Py_LIMITED_API
/* Get a pointer to the underlying Py_buffer of a memoryview object. */
/* Get a pointer to the memoryview's private copy of the exporter's buffer. */
#define PyMemoryView_GET_BUFFER(op) (&((PyMemoryViewObject *)(op))->view)
/* Get a pointer to the PyObject from which originates a memoryview object. */
/* Get a pointer to the exporting object (this may be NULL!). */
#define PyMemoryView_GET_BASE(op) (((PyMemoryViewObject *)(op))->view.obj)
#endif
PyAPI_FUNC(PyObject *) PyMemoryView_GetContiguous(PyObject *base,
int buffertype,
char fort);
/* Return a contiguous chunk of memory representing the buffer
from an object in a memory view object. If a copy is made then the
base object for the memory view will be a *new* bytes object.
Otherwise, the base-object will be the object itself and no
data-copying will be done.
The buffertype argument can be PyBUF_READ, PyBUF_WRITE,
PyBUF_SHADOW to determine whether the returned buffer
should be READONLY, WRITABLE, or set to update the
original buffer if a copy must be made. If buffertype is
PyBUF_WRITE and the buffer is not contiguous an error will
be raised. In this circumstance, the user can use
PyBUF_SHADOW to ensure that a a writable temporary
contiguous buffer is returned. The contents of this
contiguous buffer will be copied back into the original
object after the memoryview object is deleted as long as
the original object is writable and allows setting an
exclusive write lock. If this is not allowed by the
original object, then a BufferError is raised.
If the object is multi-dimensional and if fortran is 'F',
the first dimension of the underlying array will vary the
fastest in the buffer. If fortran is 'C', then the last
dimension will vary the fastest (C-style contiguous). If
fortran is 'A', then it does not matter and you will get
whatever the object decides is more efficient.
A new reference is returned that must be DECREF'd when finished.
*/
PyAPI_FUNC(PyObject *) PyMemoryView_FromObject(PyObject *base);
PyAPI_FUNC(PyObject *) PyMemoryView_FromMemory(char *mem, Py_ssize_t size,
int flags);
#ifndef Py_LIMITED_API
PyAPI_FUNC(PyObject *) PyMemoryView_FromBuffer(Py_buffer *info);
/* create new if bufptr is NULL
will be a new bytesobject in base */
#endif
PyAPI_FUNC(PyObject *) PyMemoryView_GetContiguous(PyObject *base,
int buffertype,
char order);
/* The struct is declared here so that macros can work, but it shouldn't
be considered public. Don't access those fields directly, use the macros
/* The structs are declared here so that macros can work, but they shouldn't
be considered public. Don't access their fields directly, use the macros
and functions instead! */
#ifndef Py_LIMITED_API
#define _Py_MANAGED_BUFFER_RELEASED 0x001 /* access to exporter blocked */
#define _Py_MANAGED_BUFFER_FREE_FORMAT 0x002 /* free format */
typedef struct {
PyObject_HEAD
Py_buffer view;
Py_hash_t hash;
int flags; /* state flags */
Py_ssize_t exports; /* number of direct memoryview exports */
Py_buffer master; /* snapshot buffer obtained from the original exporter */
} _PyManagedBufferObject;
/* static storage used for casting between formats */
#define _Py_MEMORYVIEW_MAX_FORMAT 3 /* must be >= 3 */
/* memoryview state flags */
#define _Py_MEMORYVIEW_RELEASED 0x001 /* access to master buffer blocked */
#define _Py_MEMORYVIEW_C 0x002 /* C-contiguous layout */
#define _Py_MEMORYVIEW_FORTRAN 0x004 /* Fortran contiguous layout */
#define _Py_MEMORYVIEW_SCALAR 0x008 /* scalar: ndim = 0 */
#define _Py_MEMORYVIEW_PIL 0x010 /* PIL-style layout */
typedef struct {
PyObject_VAR_HEAD
_PyManagedBufferObject *mbuf; /* managed buffer */
Py_hash_t hash; /* hash value for read-only views */
int flags; /* state flags */
Py_ssize_t exports; /* number of buffer re-exports */
Py_buffer view; /* private copy of the exporter's view */
char format[_Py_MEMORYVIEW_MAX_FORMAT]; /* used for casting */
Py_ssize_t ob_array[1]; /* shape, strides, suboffsets */
} PyMemoryViewObject;
#endif

7
Include/object.h
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@ -186,15 +186,16 @@ typedef struct bufferinfo {
Py_ssize_t *shape;
Py_ssize_t *strides;
Py_ssize_t *suboffsets;
Py_ssize_t smalltable[2]; /* static store for shape and strides of
mono-dimensional buffers. */
void *internal;
} Py_buffer;
typedef int (*getbufferproc)(PyObject *, Py_buffer *, int);
typedef void (*releasebufferproc)(PyObject *, Py_buffer *);
/* Flags for getting buffers */
/* Maximum number of dimensions */
#define PyBUF_MAX_NDIM 64
/* Flags for getting buffers */
#define PyBUF_SIMPLE 0
#define PyBUF_WRITABLE 0x0001
/* we used to include an E, backwards compatible alias */

76
Lib/ctypes/test/test_pep3118.py
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@ -25,14 +25,17 @@ class Test(unittest.TestCase):
v = memoryview(ob)
try:
self.assertEqual(normalize(v.format), normalize(fmt))
if shape is not None:
if shape:
self.assertEqual(len(v), shape[0])
else:
self.assertEqual(len(v) * sizeof(itemtp), sizeof(ob))
self.assertEqual(v.itemsize, sizeof(itemtp))
self.assertEqual(v.shape, shape)
# ctypes object always have a non-strided memory block
self.assertEqual(v.strides, None)
# XXX Issue #12851: PyCData_NewGetBuffer() must provide strides
# if requested. memoryview currently reconstructs missing
# stride information, so this assert will fail.
# self.assertEqual(v.strides, ())
# they are always read/write
self.assertFalse(v.readonly)
@ -52,14 +55,15 @@ class Test(unittest.TestCase):
v = memoryview(ob)
try:
self.assertEqual(v.format, fmt)
if shape is not None:
if shape:
self.assertEqual(len(v), shape[0])
else:
self.assertEqual(len(v) * sizeof(itemtp), sizeof(ob))
self.assertEqual(v.itemsize, sizeof(itemtp))
self.assertEqual(v.shape, shape)
# ctypes object always have a non-strided memory block
self.assertEqual(v.strides, None)
# XXX Issue #12851
# self.assertEqual(v.strides, ())
# they are always read/write
self.assertFalse(v.readonly)
@ -110,34 +114,34 @@ native_types = [
## simple types
(c_char, "<c", None, c_char),
(c_byte, "<b", None, c_byte),
(c_ubyte, "<B", None, c_ubyte),
(c_short, "<h", None, c_short),
(c_ushort, "<H", None, c_ushort),
(c_char, "<c", (), c_char),
(c_byte, "<b", (), c_byte),
(c_ubyte, "<B", (), c_ubyte),
(c_short, "<h", (), c_short),
(c_ushort, "<H", (), c_ushort),
# c_int and c_uint may be aliases to c_long
#(c_int, "<i", None, c_int),
#(c_uint, "<I", None, c_uint),
#(c_int, "<i", (), c_int),
#(c_uint, "<I", (), c_uint),
(c_long, "<l", None, c_long),
(c_ulong, "<L", None, c_ulong),
(c_long, "<l", (), c_long),
(c_ulong, "<L", (), c_ulong),
# c_longlong and c_ulonglong are aliases on 64-bit platforms
#(c_longlong, "<q", None, c_longlong),
#(c_ulonglong, "<Q", None, c_ulonglong),
(c_float, "<f", None, c_float),
(c_double, "<d", None, c_double),
(c_float, "<f", (), c_float),
(c_double, "<d", (), c_double),
# c_longdouble may be an alias to c_double
(c_bool, "<?", None, c_bool),
(py_object, "<O", None, py_object),
(c_bool, "<?", (), c_bool),
(py_object, "<O", (), py_object),
## pointers
(POINTER(c_byte), "&<b", None, POINTER(c_byte)),
(POINTER(POINTER(c_long)), "&&<l", None, POINTER(POINTER(c_long))),
(POINTER(c_byte), "&<b", (), POINTER(c_byte)),
(POINTER(POINTER(c_long)), "&&<l", (), POINTER(POINTER(c_long))),
## arrays and pointers
@ -145,32 +149,32 @@ native_types = [
(c_float * 4 * 3 * 2, "(2,3,4)<f", (2,3,4), c_float),
(POINTER(c_short) * 2, "(2)&<h", (2,), POINTER(c_short)),
(POINTER(c_short) * 2 * 3, "(3,2)&<h", (3,2,), POINTER(c_short)),
(POINTER(c_short * 2), "&(2)<h", None, POINTER(c_short)),
(POINTER(c_short * 2), "&(2)<h", (), POINTER(c_short)),
## structures and unions
(Point, "T{<l:x:<l:y:}", None, Point),
(Point, "T{<l:x:<l:y:}", (), Point),
# packed structures do not implement the pep
(PackedPoint, "B", None, PackedPoint),
(Point2, "T{<l:x:<l:y:}", None, Point2),
(EmptyStruct, "T{}", None, EmptyStruct),
(PackedPoint, "B", (), PackedPoint),
(Point2, "T{<l:x:<l:y:}", (), Point2),
(EmptyStruct, "T{}", (), EmptyStruct),
# the pep does't support unions
(aUnion, "B", None, aUnion),
(aUnion, "B", (), aUnion),
## pointer to incomplete structure
(Incomplete, "B", None, Incomplete),
(POINTER(Incomplete), "&B", None, POINTER(Incomplete)),
(Incomplete, "B", (), Incomplete),
(POINTER(Incomplete), "&B", (), POINTER(Incomplete)),
# 'Complete' is a structure that starts incomplete, but is completed after the
# pointer type to it has been created.
(Complete, "T{<l:a:}", None, Complete),
(Complete, "T{<l:a:}", (), Complete),
# Unfortunately the pointer format string is not fixed...
(POINTER(Complete), "&B", None, POINTER(Complete)),
(POINTER(Complete), "&B", (), POINTER(Complete)),
## other
# function signatures are not implemented
(CFUNCTYPE(None), "X{}", None, CFUNCTYPE(None)),
(CFUNCTYPE(None), "X{}", (), CFUNCTYPE(None)),
]
@ -186,10 +190,10 @@ class LEPoint(LittleEndianStructure):
# and little endian machines.
#
endian_types = [
(BEPoint, "T{>l:x:>l:y:}", None, BEPoint),
(LEPoint, "T{<l:x:<l:y:}", None, LEPoint),
(POINTER(BEPoint), "&T{>l:x:>l:y:}", None, POINTER(BEPoint)),
(POINTER(LEPoint), "&T{<l:x:<l:y:}", None, POINTER(LEPoint)),
(BEPoint, "T{>l:x:>l:y:}", (), BEPoint),
(LEPoint, "T{<l:x:<l:y:}", (), LEPoint),
(POINTER(BEPoint), "&T{>l:x:>l:y:}", (), POINTER(BEPoint)),
(POINTER(LEPoint), "&T{<l:x:<l:y:}", (), POINTER(LEPoint)),
]
if __name__ == "__main__":

3437
Lib/test/test_buffer.py Normal file
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50
Lib/test/test_memoryview.py
View File

@ -24,15 +24,14 @@ class AbstractMemoryTests:
return filter(None, [self.ro_type, self.rw_type])
def check_getitem_with_type(self, tp):
item = self.getitem_type
b = tp(self._source)
oldrefcount = sys.getrefcount(b)
m = self._view(b)
self.assertEqual(m[0], item(b"a"))
self.assertIsInstance(m[0], bytes)
self.assertEqual(m[5], item(b"f"))
self.assertEqual(m[-1], item(b"f"))
self.assertEqual(m[-6], item(b"a"))
self.assertEqual(m[0], ord(b"a"))
self.assertIsInstance(m[0], int)
self.assertEqual(m[5], ord(b"f"))
self.assertEqual(m[-1], ord(b"f"))
self.assertEqual(m[-6], ord(b"a"))
# Bounds checking
self.assertRaises(IndexError, lambda: m[6])
self.assertRaises(IndexError, lambda: m[-7])
@ -76,7 +75,9 @@ class AbstractMemoryTests:
b = self.rw_type(self._source)
oldrefcount = sys.getrefcount(b)
m = self._view(b)
m[0] = tp(b"0")
m[0] = ord(b'1')
self._check_contents(tp, b, b"1bcdef")
m[0:1] = tp(b"0")
self._check_contents(tp, b, b"0bcdef")
m[1:3] = tp(b"12")
self._check_contents(tp, b, b"012def")
@ -102,10 +103,17 @@ class AbstractMemoryTests:
# Wrong index/slice types
self.assertRaises(TypeError, setitem, 0.0, b"a")
self.assertRaises(TypeError, setitem, (0,), b"a")
self.assertRaises(TypeError, setitem, (slice(0,1,1), 0), b"a")
self.assertRaises(TypeError, setitem, (0, slice(0,1,1)), b"a")
self.assertRaises(TypeError, setitem, (0,), b"a")
self.assertRaises(TypeError, setitem, "a", b"a")
# Not implemented: multidimensional slices
slices = (slice(0,1,1), slice(0,1,2))
self.assertRaises(NotImplementedError, setitem, slices, b"a")
# Trying to resize the memory object
self.assertRaises(ValueError, setitem, 0, b"")
self.assertRaises(ValueError, setitem, 0, b"ab")
exc = ValueError if m.format == 'c' else TypeError
self.assertRaises(exc, setitem, 0, b"")
self.assertRaises(exc, setitem, 0, b"ab")
self.assertRaises(ValueError, setitem, slice(1,1), b"a")
self.assertRaises(ValueError, setitem, slice(0,2), b"a")
@ -175,7 +183,7 @@ class AbstractMemoryTests:
self.assertEqual(m.shape, (6,))
self.assertEqual(len(m), 6)
self.assertEqual(m.strides, (self.itemsize,))
self.assertEqual(m.suboffsets, None)
self.assertEqual(m.suboffsets, ())
return m
def test_attributes_readonly(self):
@ -209,12 +217,16 @@ class AbstractMemoryTests:
# If tp is a factory rather than a plain type, skip
continue
class MyView():
def __init__(self, base):
self.m = memoryview(base)
class MySource(tp):
pass
class MyObject:
pass
# Create a reference cycle through a memoryview object
# Create a reference cycle through a memoryview object.
# This exercises mbuf_clear().
b = MySource(tp(b'abc'))
m = self._view(b)
o = MyObject()
@ -226,6 +238,17 @@ class AbstractMemoryTests:
gc.collect()
self.assertTrue(wr() is None, wr())
# This exercises memory_clear().
m = MyView(tp(b'abc'))
o = MyObject()
m.x = m
m.o = o
wr = weakref.ref(o)
m = o = None
# The cycle must be broken
gc.collect()
self.assertTrue(wr() is None, wr())
def _check_released(self, m, tp):
check = self.assertRaisesRegex(ValueError, "released")
with check: bytes(m)
@ -283,9 +306,12 @@ class AbstractMemoryTests:
i = io.BytesIO(b'ZZZZ')
self.assertRaises(TypeError, i.readinto, m)
def test_getbuf_fail(self):
self.assertRaises(TypeError, self._view, {})
def test_hash(self):
# Memoryviews of readonly (hashable) types are hashable, and they
# hash as the corresponding object.
# hash as hash(obj.tobytes()).
tp = self.ro_type
if tp is None:
self.skipTest("no read-only type to test")

4
Lib/test/test_sys.py
View File

@ -773,8 +773,8 @@ class SizeofTest(unittest.TestCase):
check(int(PyLong_BASE), size(vh) + 2*self.longdigit)
check(int(PyLong_BASE**2-1), size(vh) + 2*self.longdigit)
check(int(PyLong_BASE**2), size(vh) + 3*self.longdigit)
# memory (Py_buffer + hash value)
check(memoryview(b''), size(h + 'PP2P2i7P' + 'P'))
# memoryview
check(memoryview(b''), size(h + 'PPiP4P2i5P3cP'))
# module
check(unittest, size(h + '3P'))
# None

1
Misc/ACKS
View File

@ -1041,6 +1041,7 @@ John Viega
Kannan Vijayan
Kurt Vile
Norman Vine
Pauli Virtanen
Frank Visser
Johannes Vogel
Sjoerd de Vries

17
Misc/NEWS
View File

@ -10,6 +10,23 @@ What's New in Python 3.3 Alpha 1?
Core and Builtins
-----------------
- Issue #10181: New memoryview implementation fixes multiple ownership
and lifetime issues of dynamically allocated Py_buffer members (#9990)
as well as crashes (#8305, #7433). Many new features have been added
(See whatsnew/3.3), and the documentation has been updated extensively.
The ndarray test object from _testbuffer.c implements all aspects of
PEP-3118, so further development towards the complete implementation
of the PEP can proceed in a test-driven manner.
Thanks to Nick Coghlan, Antoine Pitrou and Pauli Virtanen for review
and many ideas.
- Issue #12834: Fix incorrect results of memoryview.tobytes() for
non-contiguous arrays.
- Issue #5231: Introduce memoryview.cast() method that allows changing
format and shape without making a copy of the underlying memory.
- Issue #14084: Fix a file descriptor leak when importing a module with a
bad encoding.

11
Misc/valgrind-python.supp
View File

@ -412,4 +412,15 @@
fun:SHA1_Update
}
{
test_buffer_non_debug
Memcheck:Addr4
fun:PyUnicodeUCS2_FSConverter
}
{
test_buffer_non_debug
Memcheck:Addr4
fun:PyUnicode_FSConverter
}

2683
Modules/_testbuffer.c Normal file
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91
Modules/_testcapimodule.c
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@ -275,95 +275,6 @@ test_lazy_hash_inheritance(PyObject* self)
}
/* Issue #7385: Check that memoryview() does not crash
* when bf_getbuffer returns an error
*/
static int
broken_buffer_getbuffer(PyObject *self, Py_buffer *view, int flags)
{
PyErr_SetString(
TestError,
"test_broken_memoryview: expected error in bf_getbuffer");
return -1;
}
static PyBufferProcs memoryviewtester_as_buffer = {
(getbufferproc)broken_buffer_getbuffer, /* bf_getbuffer */
0, /* bf_releasebuffer */
};
static PyTypeObject _MemoryViewTester_Type = {
PyVarObject_HEAD_INIT(NULL, 0)
"memoryviewtester", /* Name of this type */
sizeof(PyObject), /* Basic object size */
0, /* Item size for varobject */
(destructor)PyObject_Del, /* tp_dealloc */
0, /* tp_print */
0, /* tp_getattr */
0, /* tp_setattr */
0, /* tp_compare */
0, /* tp_repr */
0, /* tp_as_number */
0, /* tp_as_sequence */
0, /* tp_as_mapping */
0, /* tp_hash */
0, /* tp_call */
0, /* tp_str */
PyObject_GenericGetAttr, /* tp_getattro */
0, /* tp_setattro */
&memoryviewtester_as_buffer, /* tp_as_buffer */
Py_TPFLAGS_DEFAULT, /* tp_flags */
0, /* tp_doc */
0, /* tp_traverse */
0, /* tp_clear */
0, /* tp_richcompare */
0, /* tp_weaklistoffset */
0, /* tp_iter */
0, /* tp_iternext */
0, /* tp_methods */
0, /* tp_members */
0, /* tp_getset */
0, /* tp_base */
0, /* tp_dict */
0, /* tp_descr_get */
0, /* tp_descr_set */
0, /* tp_dictoffset */
0, /* tp_init */
0, /* tp_alloc */
PyType_GenericNew, /* tp_new */
};
static PyObject*
test_broken_memoryview(PyObject* self)
{
PyObject *obj = PyObject_New(PyObject, &_MemoryViewTester_Type);
PyObject *res;
if (obj == NULL) {
PyErr_Clear();
PyErr_SetString(
TestError,
"test_broken_memoryview: failed to create object");
return NULL;
}
res = PyMemoryView_FromObject(obj);
if (res || !PyErr_Occurred()){
PyErr_SetString(
TestError,
"test_broken_memoryview: memoryview() didn't raise an Exception");
Py_XDECREF(res);
Py_DECREF(obj);
return NULL;
}
PyErr_Clear();
Py_DECREF(obj);
Py_RETURN_NONE;
}
/* Tests of PyLong_{As, From}{Unsigned,}Long(), and (#ifdef HAVE_LONG_LONG)
PyLong_{As, From}{Unsigned,}LongLong().
@ -2421,7 +2332,6 @@ static PyMethodDef TestMethods[] = {
{"test_list_api", (PyCFunction)test_list_api, METH_NOARGS},
{"test_dict_iteration", (PyCFunction)test_dict_iteration,METH_NOARGS},
{"test_lazy_hash_inheritance", (PyCFunction)test_lazy_hash_inheritance,METH_NOARGS},
{"test_broken_memoryview", (PyCFunction)test_broken_memoryview,METH_NOARGS},
{"test_long_api", (PyCFunction)test_long_api, METH_NOARGS},
{"test_long_and_overflow", (PyCFunction)test_long_and_overflow,
METH_NOARGS},
@ -2684,7 +2594,6 @@ PyInit__testcapi(void)
return NULL;
Py_TYPE(&_HashInheritanceTester_Type)=&PyType_Type;
Py_TYPE(&_MemoryViewTester_Type)=&PyType_Type;
Py_TYPE(&test_structmembersType)=&PyType_Type;
Py_INCREF(&test_structmembersType);

14
Objects/abstract.c
View File

@ -340,7 +340,7 @@ PyObject_GetBuffer(PyObject *obj, Py_buffer *view, int flags)
}
static int
_IsFortranContiguous(Py_buffer *view)
_IsFortranContiguous(const Py_buffer *view)
{
Py_ssize_t sd, dim;
int i;
@ -361,7 +361,7 @@ _IsFortranContiguous(Py_buffer *view)
}
static int
_IsCContiguous(Py_buffer *view)
_IsCContiguous(const Py_buffer *view)
{
Py_ssize_t sd, dim;
int i;
@ -382,16 +382,16 @@ _IsCContiguous(Py_buffer *view)
}
int
PyBuffer_IsContiguous(Py_buffer *view, char fort)
PyBuffer_IsContiguous(const Py_buffer *view, char order)
{
if (view->suboffsets != NULL) return 0;
if (fort == 'C')
if (order == 'C')
return _IsCContiguous(view);
else if (fort == 'F')
else if (order == 'F')
return _IsFortranContiguous(view);
else if (fort == 'A')
else if (order == 'A')
return (_IsCContiguous(view) || _IsFortranContiguous(view));
return 0;
}
@ -651,7 +651,7 @@ int
PyBuffer_FillInfo(Py_buffer *view, PyObject *obj, void *buf, Py_ssize_t len,
int readonly, int flags)
{
if (view == NULL) return 0;
if (view == NULL) return 0; /* XXX why not -1? */
if (((flags & PyBUF_WRITABLE) == PyBUF_WRITABLE) &&
(readonly == 1)) {
PyErr_SetString(PyExc_BufferError,

3117
Objects/memoryobject.c
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File diff suppressed because it is too large Load Diff

3
Objects/object.c
View File

@ -1650,6 +1650,9 @@ _Py_ReadyTypes(void)
if (PyType_Ready(&PyProperty_Type) < 0)
Py_FatalError("Can't initialize property type");
if (PyType_Ready(&_PyManagedBuffer_Type) < 0)
Py_FatalError("Can't initialize managed buffer type");
if (PyType_Ready(&PyMemoryView_Type) < 0)
Py_FatalError("Can't initialize memoryview type");

521
PCbuild/_testbuffer.vcproj Normal file
View File

@ -0,0 +1,521 @@
<?xml version="1.0" encoding="Windows-1252"?>
<VisualStudioProject
ProjectType="Visual C++"
Version="9.00"
Name="_testbuffer"
ProjectGUID="{A2697BD3-28C1-4AEC-9106-8B748639FD16}"
RootNamespace="_testbuffer"
Keyword="Win32Proj"
TargetFrameworkVersion="196613"
>
<Platforms>
<Platform
Name="Win32"
/>
<Platform
Name="x64"
/>
</Platforms>
<ToolFiles>
</ToolFiles>
<Configurations>
<Configuration
Name="Debug|Win32"
ConfigurationType="2"
InheritedPropertySheets=".\pyd_d.vsprops"
CharacterSet="0"
>
<Tool
Name="VCPreBuildEventTool"
/>
<Tool
Name="VCCustomBuildTool"
/>
<Tool
Name="VCXMLDataGeneratorTool"
/>
<Tool
Name="VCWebServiceProxyGeneratorTool"
/>
<Tool
Name="VCMIDLTool"
/>
<Tool
Name="VCCLCompilerTool"
/>
<Tool
Name="VCManagedResourceCompilerTool"
/>
<Tool
Name="VCResourceCompilerTool"
/>
<Tool
Name="VCPreLinkEventTool"
/>
<Tool
Name="VCLinkerTool"
BaseAddress="0x1e1F0000"
/>
<Tool
Name="VCALinkTool"
/>
<Tool
Name="VCManifestTool"
/>
<Tool
Name="VCXDCMakeTool"
/>
<Tool
Name="VCBscMakeTool"
/>
<Tool
Name="VCFxCopTool"
/>
<Tool
Name="VCAppVerifierTool"
/>
<Tool
Name="VCPostBuildEventTool"
/>
</Configuration>
<Configuration
Name="Debug|x64"
ConfigurationType="2"
InheritedPropertySheets=".\pyd_d.vsprops;.\x64.vsprops"
CharacterSet="0"
>
<Tool
Name="VCPreBuildEventTool"
/>
<Tool
Name="VCCustomBuildTool"
/>
<Tool
Name="VCXMLDataGeneratorTool"
/>
<Tool
Name="VCWebServiceProxyGeneratorTool"
/>
<Tool
Name="VCMIDLTool"
TargetEnvironment="3"
/>
<Tool
Name="VCCLCompilerTool"
/>
<Tool
Name="VCManagedResourceCompilerTool"
/>
<Tool
Name="VCResourceCompilerTool"
/>
<Tool
Name="VCPreLinkEventTool"
/>
<Tool
Name="VCLinkerTool"
BaseAddress="0x1e1F0000"
/>
<Tool
Name="VCALinkTool"
/>
<Tool
Name="VCManifestTool"
/>
<Tool
Name="VCXDCMakeTool"
/>
<Tool
Name="VCBscMakeTool"
/>
<Tool
Name="VCFxCopTool"
/>
<Tool
Name="VCAppVerifierTool"
/>
<Tool
Name="VCPostBuildEventTool"
/>
</Configuration>
<Configuration
Name="Release|Win32"
ConfigurationType="2"
InheritedPropertySheets=".\pyd.vsprops"
CharacterSet="0"
WholeProgramOptimization="1"
>
<Tool
Name="VCPreBuildEventTool"
/>
<Tool
Name="VCCustomBuildTool"
/>
<Tool
Name="VCXMLDataGeneratorTool"
/>
<Tool
Name="VCWebServiceProxyGeneratorTool"
/>
<Tool
Name="VCMIDLTool"
/>
<Tool
Name="VCCLCompilerTool"
/>
<Tool
Name="VCManagedResourceCompilerTool"
/>
<Tool
Name="VCResourceCompilerTool"
/>
<Tool
Name="VCPreLinkEventTool"
/>
<Tool
Name="VCLinkerTool"
BaseAddress="0x1e1F0000"
/>
<Tool
Name="VCALinkTool"
/>
<Tool
Name="VCManifestTool"
/>
<Tool
Name="VCXDCMakeTool"
/>
<Tool
Name="VCBscMakeTool"
/>
<Tool
Name="VCFxCopTool"
/>
<Tool
Name="VCAppVerifierTool"
/>
<Tool
Name="VCPostBuildEventTool"
/>
</Configuration>
<Configuration
Name="Release|x64"
ConfigurationType="2"
InheritedPropertySheets=".\pyd.vsprops;.\x64.vsprops"
CharacterSet="0"
WholeProgramOptimization="1"
>
<Tool
Name="VCPreBuildEventTool"
/>
<Tool
Name="VCCustomBuildTool"
/>
<Tool
Name="VCXMLDataGeneratorTool"
/>
<Tool
Name="VCWebServiceProxyGeneratorTool"
/>
<Tool
Name="VCMIDLTool"
TargetEnvironment="3"
/>
<Tool
Name="VCCLCompilerTool"
/>
<Tool
Name="VCManagedResourceCompilerTool"
/>
<Tool
Name="VCResourceCompilerTool"
/>
<Tool
Name="VCPreLinkEventTool"
/>
<Tool
Name="VCLinkerTool"
BaseAddress="0x1e1F0000"
/>
<Tool
Name="VCALinkTool"
/>
<Tool
Name="VCManifestTool"
/>
<Tool
Name="VCXDCMakeTool"
/>
<Tool
Name="VCBscMakeTool"
/>
<Tool
Name="VCFxCopTool"
/>
<Tool
Name="VCAppVerifierTool"
/>
<Tool
Name="VCPostBuildEventTool"
/>
</Configuration>
<Configuration
Name="PGInstrument|Win32"
ConfigurationType="2"
InheritedPropertySheets=".\pyd.vsprops;.\pginstrument.vsprops"
CharacterSet="0"
WholeProgramOptimization="1"
>
<Tool
Name="VCPreBuildEventTool"
/>
<Tool
Name="VCCustomBuildTool"
/>
<Tool
Name="VCXMLDataGeneratorTool"
/>
<Tool
Name="VCWebServiceProxyGeneratorTool"
/>
<Tool
Name="VCMIDLTool"
/>
<Tool
Name="VCCLCompilerTool"
/>
<Tool
Name="VCManagedResourceCompilerTool"
/>
<Tool
Name="VCResourceCompilerTool"
/>
<Tool
Name="VCPreLinkEventTool"
/>
<Tool
Name="VCLinkerTool"
BaseAddress="0x1e1F0000"
/>
<Tool
Name="VCALinkTool"
/>
<Tool
Name="VCManifestTool"
/>
<Tool
Name="VCXDCMakeTool"
/>
<Tool
Name="VCBscMakeTool"
/>
<Tool
Name="VCFxCopTool"
/>
<Tool
Name="VCAppVerifierTool"
/>
<Tool
Name="VCPostBuildEventTool"
/>
</Configuration>
<Configuration
Name="PGInstrument|x64"
ConfigurationType="2"
InheritedPropertySheets=".\pyd.vsprops;.\x64.vsprops;.\pginstrument.vsprops"
CharacterSet="0"
WholeProgramOptimization="1"
>
<Tool
Name="VCPreBuildEventTool"
/>
<Tool
Name="VCCustomBuildTool"
/>
<Tool
Name="VCXMLDataGeneratorTool"
/>
<Tool
Name="VCWebServiceProxyGeneratorTool"
/>
<Tool
Name="VCMIDLTool"
TargetEnvironment="3"
/>
<Tool
Name="VCCLCompilerTool"
/>
<Tool
Name="VCManagedResourceCompilerTool"
/>
<Tool
Name="VCResourceCompilerTool"
/>
<Tool
Name="VCPreLinkEventTool"
/>
<Tool
Name="VCLinkerTool"
BaseAddress="0x1e1F0000"
TargetMachine="17"
/>
<Tool
Name="VCALinkTool"
/>
<Tool
Name="VCManifestTool"
/>
<Tool
Name="VCXDCMakeTool"
/>
<Tool
Name="VCBscMakeTool"
/>
<Tool
Name="VCFxCopTool"
/>
<Tool
Name="VCAppVerifierTool"
/>
<Tool
Name="VCPostBuildEventTool"
/>
</Configuration>
<Configuration
Name="PGUpdate|Win32"
ConfigurationType="2"
InheritedPropertySheets=".\pyd.vsprops;.\pgupdate.vsprops"
CharacterSet="0"
WholeProgramOptimization="1"
>
<Tool
Name="VCPreBuildEventTool"
/>
<Tool
Name="VCCustomBuildTool"
/>
<Tool
Name="VCXMLDataGeneratorTool"
/>
<Tool
Name="VCWebServiceProxyGeneratorTool"
/>
<Tool
Name="VCMIDLTool"
/>
<Tool
Name="VCCLCompilerTool"
/>
<Tool
Name="VCManagedResourceCompilerTool"
/>
<Tool
Name="VCResourceCompilerTool"
/>
<Tool
Name="VCPreLinkEventTool"
/>
<Tool
Name="VCLinkerTool"
BaseAddress="0x1e1F0000"
/>
<Tool
Name="VCALinkTool"
/>
<Tool
Name="VCManifestTool"
/>
<Tool
Name="VCXDCMakeTool"
/>
<Tool
Name="VCBscMakeTool"
/>
<Tool
Name="VCFxCopTool"
/>
<Tool
Name="VCAppVerifierTool"
/>
<Tool
Name="VCPostBuildEventTool"
/>
</Configuration>
<Configuration
Name="PGUpdate|x64"
ConfigurationType="2"
InheritedPropertySheets=".\pyd.vsprops;.\x64.vsprops;.\pgupdate.vsprops"
CharacterSet="0"
WholeProgramOptimization="1"
>
<Tool
Name="VCPreBuildEventTool"
/>
<Tool
Name="VCCustomBuildTool"
/>
<Tool
Name="VCXMLDataGeneratorTool"
/>
<Tool
Name="VCWebServiceProxyGeneratorTool"
/>
<Tool
Name="VCMIDLTool"
TargetEnvironment="3"
/>
<Tool
Name="VCCLCompilerTool"
/>
<Tool
Name="VCManagedResourceCompilerTool"
/>
<Tool
Name="VCResourceCompilerTool"
/>
<Tool
Name="VCPreLinkEventTool"
/>
<Tool
Name="VCLinkerTool"
BaseAddress="0x1e1F0000"
TargetMachine="17"
/>
<Tool
Name="VCALinkTool"
/>
<Tool
Name="VCManifestTool"
/>
<Tool
Name="VCXDCMakeTool"
/>
<Tool
Name="VCBscMakeTool"
/>
<Tool
Name="VCFxCopTool"
/>
<Tool
Name="VCAppVerifierTool"
/>
<Tool
Name="VCPostBuildEventTool"
/>
</Configuration>
</Configurations>
<References>
</References>
<Files>
<Filter
Name="Source Files"
>
<File
RelativePath="..\Modules\_testbuffer.c"
>
</File>
</Filter>
</Files>
<Globals>
</Globals>
</VisualStudioProject>

21
PCbuild/pcbuild.sln
View File

@ -142,6 +142,11 @@ Project("{8BC9CEB8-8B4A-11D0-8D11-00A0C91BC942}") = "python3dll", "python3dll.vc
EndProject
Project("{8BC9CEB8-8B4A-11D0-8D11-00A0C91BC942}") = "xxlimited", "xxlimited.vcproj", "{F749B822-B489-4CA5-A3AD-CE078F5F338A}"
EndProject
Project("{8BC9CEB8-8B4A-11D0-8D11-00A0C91BC942}") = "_testbuffer", "_testbuffer.vcproj", "{A2697BD3-28C1-4AEC-9106-8B748639FD16}"
ProjectSection(ProjectDependencies) = postProject
{CF7AC3D1-E2DF-41D2-BEA6-1E2556CDEA26} = {CF7AC3D1-E2DF-41D2-BEA6-1E2556CDEA26}
EndProjectSection
EndProject
Global
GlobalSection(SolutionConfigurationPlatforms) = preSolution
Debug|Win32 = Debug|Win32
@ -609,6 +614,22 @@ Global
{F749B822-B489-4CA5-A3AD-CE078F5F338A}.Release|Win32.Build.0 = Release|Win32
{F749B822-B489-4CA5-A3AD-CE078F5F338A}.Release|x64.ActiveCfg = Release|x64
{F749B822-B489-4CA5-A3AD-CE078F5F338A}.Release|x64.Build.0 = Release|x64
{A2697BD3-28C1-4AEC-9106-8B748639FD16}.Debug|Win32.ActiveCfg = Debug|Win32
{A2697BD3-28C1-4AEC-9106-8B748639FD16}.Debug|Win32.Build.0 = Debug|Win32
{A2697BD3-28C1-4AEC-9106-8B748639FD16}.Debug|x64.ActiveCfg = Debug|x64
{A2697BD3-28C1-4AEC-9106-8B748639FD16}.Debug|x64.Build.0 = Debug|x64
{A2697BD3-28C1-4AEC-9106-8B748639FD16}.PGInstrument|Win32.ActiveCfg = PGInstrument|Win32
{A2697BD3-28C1-4AEC-9106-8B748639FD16}.PGInstrument|Win32.Build.0 = PGInstrument|Win32
{A2697BD3-28C1-4AEC-9106-8B748639FD16}.PGInstrument|x64.ActiveCfg = PGInstrument|x64
{A2697BD3-28C1-4AEC-9106-8B748639FD16}.PGInstrument|x64.Build.0 = PGInstrument|x64
{A2697BD3-28C1-4AEC-9106-8B748639FD16}.PGUpdate|Win32.ActiveCfg = PGUpdate|Win32
{A2697BD3-28C1-4AEC-9106-8B748639FD16}.PGUpdate|Win32.Build.0 = PGUpdate|Win32
{A2697BD3-28C1-4AEC-9106-8B748639FD16}.PGUpdate|x64.ActiveCfg = PGUpdate|x64
{A2697BD3-28C1-4AEC-9106-8B748639FD16}.PGUpdate|x64.Build.0 = PGUpdate|x64
{A2697BD3-28C1-4AEC-9106-8B748639FD16}.Release|Win32.ActiveCfg = Release|Win32
{A2697BD3-28C1-4AEC-9106-8B748639FD16}.Release|Win32.Build.0 = Release|Win32
{A2697BD3-28C1-4AEC-9106-8B748639FD16}.Release|x64.ActiveCfg = Release|x64
{A2697BD3-28C1-4AEC-9106-8B748639FD16}.Release|x64.Build.0 = Release|x64
EndGlobalSection
GlobalSection(SolutionProperties) = preSolution
HideSolutionNode = FALSE

3
PCbuild/readme.txt
View File

@ -92,6 +92,9 @@ _socket
_testcapi
tests of the Python C API, run via Lib/test/test_capi.py, and
implemented by module Modules/_testcapimodule.c
_testbuffer
buffer protocol tests, run via Lib/test/test_buffer.py, and
implemented by module Modules/_testbuffer.c
pyexpat
Python wrapper for accelerated XML parsing, which incorporates stable
code from the Expat project: http://sourceforge.net/projects/expat/

2
setup.py
View File

@ -530,6 +530,8 @@ class PyBuildExt(build_ext):
# Python C API test module
exts.append( Extension('_testcapi', ['_testcapimodule.c'],
depends=['testcapi_long.h']) )
# Python PEP-3118 (buffer protocol) test module
exts.append( Extension('_testbuffer', ['_testbuffer.c']) )
# profiler (_lsprof is for cProfile.py)
exts.append( Extension('_lsprof', ['_lsprof.c', 'rotatingtree.c']) )
# static Unicode character database