616 lines
20 KiB
ReStructuredText
616 lines
20 KiB
ReStructuredText
PEP: 670
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Title: Convert macros to functions in the Python C API
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Author: Erlend Egeberg Aasland <erlend.aasland@protonmail.com>,
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Victor Stinner <vstinner@python.org>
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Status: Draft
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Type: Standards Track
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Content-Type: text/x-rst
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Created: 19-Oct-2021
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Python-Version: 3.11
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Abstract
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========
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Convert macros to static inline functions or regular functions to avoid
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macro pitfalls.
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Convert macros and static inline functions to regular functions to make
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them usable by Python extensions which cannot use macros or static
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inline functions, like extensions written in a programming languages
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other than C or C++.
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Function arguments of pointer types are still cast and return types are
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not changed to prevent emitting new compiler warnings.
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Macros which can be used as l-value in an assignment are not converted
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to functions to avoid introducing incompatible changes.
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Rationale
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=========
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The use of macros may have unintended adverse effects that are hard to
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avoid, even for experienced C developers. Some issues have been known
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for years, while others have been discovered recently in Python.
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Working around macro pitfalls makes the macro coder harder to read and
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to maintain.
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Converting macros to functions has multiple advantages:
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* By design, functions don't have macro pitfalls.
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* Arguments type and return type are well defined.
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* Debuggers and profilers can retrieve the name of inlined functions.
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* Debuggers can put breakpoints on inlined functions.
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* Variables have a well defined scope.
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* Code is usually easier to read and to maintain than similar macro
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code. Functions don't need the following workarounds for macro
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pitfalls:
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* Add parentheses around arguments.
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* Use line continuation characters if the function is written on
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multiple lines.
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* Add commas to execute multiple expressions.
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* Use ``do { ... } while (0)`` to write multiple statements.
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Converting macros and static inline functions to regular functions makes
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these regular functions accessible to projects which use Python but
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cannot use macros and static inline functions.
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Macro Pitfalls
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==============
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The `GCC documentation
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<https://gcc.gnu.org/onlinedocs/cpp/Macro-Pitfalls.html>`_ lists several
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common macro pitfalls:
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- Misnesting
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- Operator precedence problems
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- Swallowing the semicolon
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- Duplication of side effects
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- Self-referential macros
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- Argument prescan
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- Newlines in arguments
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Performance and inlining
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========================
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Static inline functions is a feature added to the C99 standard. Modern C
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compilers have efficient heuristics to decide if a function should be
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inlined or not.
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When a C compiler decides to not inline, there is likely a good reason.
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For example, inlining would reuse a register which requires to
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save/restore the register value on the stack and so increases the stack
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memory usage, or be less efficient.
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Debug build
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-----------
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Benchmarks must not be run on a Python debug build, only on release
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build. Moreover, using LTO and PGO optimizations is recommended for best
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performances and reliable benchmarks. PGO helps the compiler to decide
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if function should be inlined or not.
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``./configure --with-pydebug`` uses the ``-Og`` compiler option if it's
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supported by the compiler (GCC and LLVM Clang support it): optimize
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debugging experience. Otherwise, the ``-O0`` compiler option is used:
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disable most optimizations.
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With GCC 11, ``gcc -Og`` can inline static inline functions, whereas
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``gcc -O0`` does not inline static inline functions. Examples:
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* Call ``Py_INCREF()`` in ``PyBool_FromLong()``:
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* ``gcc -Og``: inlined
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* ``gcc -O0``: not inlined, call ``Py_INCREF()`` function
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* Call ``_PyErr_Occurred()`` in ``_Py_CheckFunctionResult()``:
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* ``gcc -Og``: inlined
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* ``gcc -O0``: not inlined, call ``_PyErr_Occurred()`` function
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On Windows, when Python is built in debug mode by Visual Studio, static
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inline functions are not inlined.
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Force inlining
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--------------
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The ``Py_ALWAYS_INLINE`` macro can be used to force inlining. This macro
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uses ``__attribute__((always_inline))`` with GCC and Clang, and
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``__forceinline`` with MSC.
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Previous attempts to use ``Py_ALWAYS_INLINE`` didn't show any benefit, and were
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abandoned. See for example: `bpo-45094 <https://bugs.python.org/issue45094>`_:
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"Consider using ``__forceinline`` and ``__attribute__((always_inline))`` on
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static inline functions (``Py_INCREF``, ``Py_TYPE``) for debug build".
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When the ``Py_INCREF()`` macro was converted to a static inline
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functions in 2018 (`commit
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<https://github.com/python/cpython/commit/2aaf0c12041bcaadd7f2cc5a54450eefd7a6ff12>`__),
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it was decided not to force inlining. The machine code was analyzed with
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multiple C compilers and compiler options: ``Py_INCREF()`` was always
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inlined without having to force inlining. The only case where it was not
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inlined was the debug build. See discussion in the `bpo-35059
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<https://bugs.python.org/issue35059>`_: "Convert ``Py_INCREF()`` and
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``PyObject_INIT()`` to inlined functions".
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Disable inlining
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----------------
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On the other side, the ``Py_NO_INLINE`` macro can be used to disable
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inlining. It can be used to reduce the stack memory usage, or to prevent
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inlining on LTO+PGO builds, which are generally more aggressive to inline
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code: see `bpo-33720 <https://bugs.python.org/issue33720>`_. The
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``Py_NO_INLINE`` macro uses ``__attribute__ ((noinline))`` with GCC and
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Clang, and ``__declspec(noinline)`` with MSC.
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Specification
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=============
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Convert macros to static inline functions
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-----------------------------------------
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Most macros should be converted to static inline functions to prevent
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`macro pitfalls`_.
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The following macros should not be converted:
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* Empty macros. Example: ``#define Py_HAVE_CONDVAR``.
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* Macros only defining a number, even if a constant with a well defined
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type can better. Example: ``#define METH_VARARGS 0x0001``.
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* Compatibility layer for different C compilers, C language extensions,
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or recent C features.
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Example: ``#define Py_ALWAYS_INLINE __attribute__((always_inline))``.
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* Macros that need C preprocessor features, like stringification and
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concatenation. Example: ``Py_STRINGIFY()``.
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* Macros which can be used as l-value in an assignment. This change is
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an incompatible change and is out of the scope of this PEP.
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Example: ``PyBytes_AS_STRING()``.
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* Macros having different return types depending on the code path.
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Convert static inline functions to regular functions
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----------------------------------------------------
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The performance impact of converting static inline functions to regular
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functions should be measured with benchmarks. If there is a significant
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slowdown, there should be a good reason to do the conversion. One reason
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can be hiding implementation details.
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To avoid any risk of performance slowdown on Python built without LTO,
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it is possible to keep a private static inline function in the internal
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C API and use it in Python, but expose a regular function in the public
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C API.
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Using static inline functions in the internal C API is fine: the
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internal C API exposes implementation details by design and should not be
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used outside Python.
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Cast pointer arguments
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----------------------
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Existing cast
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'''''''''''''
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Currently, most macros accepting pointers cast pointer arguments to
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their expected types. For example, in Python 3.6, the ``Py_TYPE()``
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macro casts its argument to ``PyObject*``::
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#define Py_TYPE(ob) (((PyObject*)(ob))->ob_type)
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The ``Py_TYPE()`` macro accepts the ``PyObject*`` type, but also any
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pointer types, such as ``PyLongObject*`` and ``PyDictObject*``.
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Add a new macro to keep the cast
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''''''''''''''''''''''''''''''''
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When a macro is converted to a function and the macro casts at least one
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of its arguments, a new macro is added to keep the cast. The new macro
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and the function have the same name. Example with the ``Py_TYPE()``
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macro converted to a static inline function::
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static inline PyTypeObject* Py_TYPE(PyObject *ob) {
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return ob->ob_type;
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}
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#define Py_TYPE(ob) Py_TYPE((PyObject*)(ob))
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The cast is kept for all pointer types, not only ``PyObject*``.
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Removing a cast to ``void*`` would emit a new warning if the function is
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called with a variable of ``const void*`` type. For example, the
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``PyUnicode_WRITE()`` macro casts its *data* argument to ``void*``, and
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so accepts ``const void*`` type, even if it writes into *data*.
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Avoid the cast in the limited C API version 3.11
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''''''''''''''''''''''''''''''''''''''''''''''''
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The cast is removed from the limited C API version 3.11 and newer: the
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caller must pass the expected type, or perform the cast. An example with
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the ``Py_TYPE()`` function::
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static inline PyTypeObject* Py_TYPE(PyObject *ob) {
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return ob->ob_type;
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}
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#if !defined(Py_LIMITED_API) || Py_LIMITED_API+0 < 0x030b0000
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# define Py_TYPE(ob) Py_TYPE((PyObject*)(ob))
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#endif
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Return type is not changed
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--------------------------
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When a macro is converted to a function, its return type must not change
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to prevent emitting new compiler warnings.
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For example, Python 3.7 changed ``PyUnicode_AsUTF8()`` return type from
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``char*`` to ``const char*`` (`commit
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<https://github.com/python/cpython/commit/2a404b63d48d73bbaa007d89efb7a01048475acd>`__).
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The change emitted new compiler warnings when building C extensions
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expecting ``char*``. This PEP doesn't change the return type to prevent
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this issue.
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Backwards Compatibility
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=======================
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The PEP is designed to avoid C API incompatible changes.
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Only C extensions explicitly targeting the limited C API version 3.11
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must now pass the expected types to functions: pointer arguments are no
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longer cast to the expected types.
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Function arguments of pointer types are still cast and return types are
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not changed to prevent emitting new compiler warnings.
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Macros which can be used as l-value in an assignment are not modified by
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this PEP to avoid incompatible changes.
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Rejected Ideas
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==============
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Keep macros, but fix some macro issues
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--------------------------------------
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Macros are always "inlined" with any C compiler.
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The duplication of side effects can be worked around in the caller of
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the macro.
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People using macros should be considered "consenting adults". People who
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feel unsafe with macros should simply not use them.
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These ideas are rejected because macros _are_ error prone, and it is too easy
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to miss a macro pitfall when writing and reviewing macro code. Moreover, macros
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are harder to read and maintain than functions.
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Examples of Macro Pitfalls
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==========================
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Duplication of side effects
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---------------------------
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Macros::
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#define PySet_Check(ob) \
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(Py_IS_TYPE(ob, &PySet_Type) \
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|| PyType_IsSubtype(Py_TYPE(ob), &PySet_Type))
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#define Py_IS_NAN(X) ((X) != (X))
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If the *op* or the *X* argument has a side effect, the side effect is
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duplicated: it executed twice by ``PySet_Check()`` and ``Py_IS_NAN()``.
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For example, the ``pos++`` argument in the
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``PyUnicode_WRITE(kind, data, pos++, ch)`` code has a side effect.
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This code is safe because the ``PyUnicode_WRITE()`` macro only uses its
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3rd argument once and so does not duplicate ``pos++`` side effect.
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Misnesting
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----------
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Example of the `bpo-43181: Python macros don't shield arguments
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<https://bugs.python.org/issue43181>`_. The ``PyObject_TypeCheck()``
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macro before it has been fixed::
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#define PyObject_TypeCheck(ob, tp) \
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(Py_IS_TYPE(ob, tp) || PyType_IsSubtype(Py_TYPE(ob), (tp)))
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C++ usage example::
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PyObject_TypeCheck(ob, U(f<a,b>(c)))
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The preprocessor first expands it::
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(Py_IS_TYPE(ob, f<a,b>(c)) || ...)
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C++ ``"<"`` and ``">"`` characters are not treated as brackets by the
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preprocessor, so the ``Py_IS_TYPE()`` macro is invoked with 3 arguments:
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* ``ob``
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* ``f<a``
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* ``b>(c)``
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The compilation fails with an error on ``Py_IS_TYPE()`` which only takes
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2 arguments.
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The bug is that the *op* and *tp* arguments of ``PyObject_TypeCheck()``
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must be put between parentheses: replace ``Py_IS_TYPE(ob, tp)`` with
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``Py_IS_TYPE((ob), (tp))``. In regular C code, these parentheses are
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redundant, can be seen as a bug, and so are often forgotten when writing
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macros.
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To avoid Macro Pitfalls, the ``PyObject_TypeCheck()`` macro has been
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converted to a static inline function:
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`commit <https://github.com/python/cpython/commit/4bb2a1ebc569eee6f1b46ecef1965a26ae8cb76d>`__.
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Examples of hard to read macros
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===============================
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PyObject_INIT()
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---------------
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Example showing the usage of commas in a macro which has a return value.
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Python 3.7 macro::
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#define PyObject_INIT(op, typeobj) \
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( Py_TYPE(op) = (typeobj), _Py_NewReference((PyObject *)(op)), (op) )
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Python 3.8 function (simplified code)::
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static inline PyObject*
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_PyObject_INIT(PyObject *op, PyTypeObject *typeobj)
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{
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Py_TYPE(op) = typeobj;
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_Py_NewReference(op);
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return op;
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}
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#define PyObject_INIT(op, typeobj) \
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_PyObject_INIT(_PyObject_CAST(op), (typeobj))
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* The function doesn't need the line continuation character ``"\"``.
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* It has an explicit ``"return op;"`` rather than the surprising
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``", (op)"`` syntax at the end of the macro.
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* It uses short statements on multiple lines, rather than being written
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as a single long line.
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* Inside the function, the *op* argument has the well defined type
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``PyObject*`` and so doesn't need casts like ``(PyObject *)(op)``.
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* Arguments don't need to be put inside parentheses: use ``typeobj``,
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rather than ``(typeobj)``.
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_Py_NewReference()
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------------------
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Example showing the usage of an ``#ifdef`` inside a macro.
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Python 3.7 macro (simplified code)::
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#ifdef COUNT_ALLOCS
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# define _Py_INC_TPALLOCS(OP) inc_count(Py_TYPE(OP))
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# define _Py_COUNT_ALLOCS_COMMA ,
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#else
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# define _Py_INC_TPALLOCS(OP)
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# define _Py_COUNT_ALLOCS_COMMA
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#endif /* COUNT_ALLOCS */
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#define _Py_NewReference(op) ( \
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_Py_INC_TPALLOCS(op) _Py_COUNT_ALLOCS_COMMA \
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Py_REFCNT(op) = 1)
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Python 3.8 function (simplified code)::
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static inline void _Py_NewReference(PyObject *op)
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{
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_Py_INC_TPALLOCS(op);
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Py_REFCNT(op) = 1;
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}
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PyUnicode_READ_CHAR()
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---------------------
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This macro reuses arguments, and possibly calls ``PyUnicode_KIND`` multiple
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times::
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#define PyUnicode_READ_CHAR(unicode, index) \
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(assert(PyUnicode_Check(unicode)), \
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assert(PyUnicode_IS_READY(unicode)), \
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(Py_UCS4) \
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(PyUnicode_KIND((unicode)) == PyUnicode_1BYTE_KIND ? \
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((const Py_UCS1 *)(PyUnicode_DATA((unicode))))[(index)] : \
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(PyUnicode_KIND((unicode)) == PyUnicode_2BYTE_KIND ? \
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((const Py_UCS2 *)(PyUnicode_DATA((unicode))))[(index)] : \
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((const Py_UCS4 *)(PyUnicode_DATA((unicode))))[(index)] \
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) \
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))
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Possible implementation as a static inlined function::
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static inline Py_UCS4
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PyUnicode_READ_CHAR(PyObject *unicode, Py_ssize_t index)
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{
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assert(PyUnicode_Check(unicode));
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assert(PyUnicode_IS_READY(unicode));
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switch (PyUnicode_KIND(unicode)) {
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case PyUnicode_1BYTE_KIND:
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return (Py_UCS4)((const Py_UCS1 *)(PyUnicode_DATA(unicode)))[index];
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case PyUnicode_2BYTE_KIND:
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return (Py_UCS4)((const Py_UCS2 *)(PyUnicode_DATA(unicode)))[index];
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case PyUnicode_4BYTE_KIND:
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default:
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return (Py_UCS4)((const Py_UCS4 *)(PyUnicode_DATA(unicode)))[index];
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}
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}
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Macros converted to functions since Python 3.8
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==============================================
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List of macros already converted to functions between Python 3.8 and
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Python 3.11 showing that these conversions didn't not impact the Python
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performance and didn't break the backward compatibility, even if some
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converted macros are very commonly used by C extensions like
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``Py_INCREF()``.
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Macros converted to static inline functions
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-------------------------------------------
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Python 3.8:
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* ``Py_DECREF()``
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* ``Py_INCREF()``
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* ``Py_XDECREF()``
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* ``Py_XINCREF()``
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* ``PyObject_INIT()``
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* ``PyObject_INIT_VAR()``
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* ``_PyObject_GC_UNTRACK()``
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* ``_Py_Dealloc()``
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Macros converted to regular functions
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-------------------------------------
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Python 3.9:
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* ``PyIndex_Check()``
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* ``PyObject_CheckBuffer()``
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* ``PyObject_GET_WEAKREFS_LISTPTR()``
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* ``PyObject_IS_GC()``
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* ``PyObject_NEW()``: alias to ``PyObject_New()``
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* ``PyObject_NEW_VAR()``: alias to ``PyObjectVar_New()``
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To avoid any risk of performance slowdown on Python built without LTO,
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private static inline functions have been added to the internal C API:
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* ``_PyIndex_Check()``
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* ``_PyObject_IS_GC()``
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* ``_PyType_HasFeature()``
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* ``_PyType_IS_GC()``
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Static inline functions converted to regular functions
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-------------------------------------------------------
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Python 3.11:
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* ``PyObject_CallOneArg()``
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* ``PyObject_Vectorcall()``
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* ``PyVectorcall_Function()``
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* ``_PyObject_FastCall()``
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To avoid any risk of performance slowdown on Python built without LTO, a
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private static inline function has been added to the internal C API:
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* ``_PyVectorcall_FunctionInline()``
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Incompatible changes
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--------------------
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While other converted macros didn't break the backward compatibility,
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there is an exception.
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The 3 macros ``Py_REFCNT()``, ``Py_TYPE()`` and ``Py_SIZE()`` have been
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converted to static inline functions in Python 3.10 and 3.11 to disallow
|
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using them as l-value in assignment. It is an incompatible change made
|
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on purpose: see `bpo-39573 <https://bugs.python.org/issue39573>`_ for
|
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the rationale.
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This PEP does not convert macros which can be used as l-value to avoid
|
|
introducing incompatible changes.
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Benchmark comparing macros and static inline functions
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|
======================================================
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Benchmark run on Fedora 35 (Linux) with GCC 11 on a laptop with 8
|
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logical CPUs (4 physical CPU cores).
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The `PR 29728 <https://github.com/python/cpython/pull/29728>`_ replaces
|
|
existing the following static inline functions with macros:
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|
|
|
* ``PyObject_TypeCheck()``
|
|
* ``PyType_Check()``, ``PyType_CheckExact()``
|
|
* ``PyType_HasFeature()``
|
|
* ``PyVectorcall_NARGS()``
|
|
* ``Py_DECREF()``, ``Py_XDECREF()``
|
|
* ``Py_INCREF()``, ``Py_XINCREF()``
|
|
* ``Py_IS_TYPE()``
|
|
* ``Py_NewRef()``
|
|
* ``Py_REFCNT()``, ``Py_TYPE()``, ``Py_SIZE()``
|
|
|
|
|
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When static inline functions are inlined: Release build
|
|
-------------------------------------------------------
|
|
|
|
Benchmark of the ``./python -m test -j5`` command on Python built in
|
|
release mode with ``gcc -O3``, LTO and PGO:
|
|
|
|
* Macros (PR 29728): 361 sec +- 1 sec
|
|
* Static inline functions (reference): 361 sec +- 1 sec
|
|
|
|
There is **no significant performance difference** between macros and
|
|
static inline functions when static inline functions **are inlined**.
|
|
|
|
|
|
When static inline functions are not inlined: Debug build and -O0
|
|
-----------------------------------------------------------------
|
|
|
|
Benchmark of the ``./python -m test -j10`` command on Python built in
|
|
debug mode with ``gcc -O0`` (explicitly disable compiler optimizations):
|
|
|
|
* Macros (PR 29728): 345 sec ± 5 sec
|
|
* Static inline functions (reference): 360 sec ± 6 sec
|
|
|
|
Replacing macros with static inline functions makes Python
|
|
**1.04x slower** when the compiler **does not inline** static inline
|
|
functions.
|
|
|
|
|
|
Post History
|
|
============
|
|
|
|
* python-dev: `PEP 670: Convert macros to functions in the Python C API
|
|
<https://mail.python.org/archives/list/python-dev@python.org/thread/2GN646CGWGTO6ZHHU7JTA5XWDF4ULM77/>`_
|
|
(October 2021)
|
|
|
|
|
|
References
|
|
==========
|
|
|
|
* `bpo-45490 <https://bugs.python.org/issue45490>`_:
|
|
[meta][C API] Avoid C macro pitfalls and usage of static inline
|
|
functions (October 2021).
|
|
* `What to do with unsafe macros
|
|
<https://discuss.python.org/t/what-to-do-with-unsafe-macros/7771>`_
|
|
(March 2021).
|
|
* `bpo-43502 <https://bugs.python.org/issue43502>`_:
|
|
[C-API] Convert obvious unsafe macros to static inline functions
|
|
(March 2021).
|
|
|
|
|
|
Version History
|
|
===============
|
|
|
|
* Version 2: No longer remove return values; remove argument casting
|
|
from the limited C API.
|
|
* Version 1: First public version
|
|
|
|
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|
Copyright
|
|
=========
|
|
|
|
This document is placed in the public domain or under the
|
|
CC0-1.0-Universal license, whichever is more permissive.
|