clang-r383902/python3/include/python3.8/internal/pycore_pymem.h - platform/prebuilts/clang/host/darwin-x86 - Git at Google

 #ifndef Py_INTERNAL_PYMEM_H
 #define Py_INTERNAL_PYMEM_H
 #ifdef __cplusplus
 extern "C" {
 #endif

 #ifndef Py_BUILD_CORE
 #  error "this header requires Py_BUILD_CORE define"
 #endif

 #include "objimpl.h"
 #include "pymem.h"


 /* GC runtime state */

 /* If we change this, we need to change the default value in the
    signature of gc.collect. */
 #define NUM_GENERATIONS 3

 /*
    NOTE: about the counting of long-lived objects.

    To limit the cost of garbage collection, there are two strategies;
      - make each collection faster, e.g. by scanning fewer objects
      - do less collections
    This heuristic is about the latter strategy.

    In addition to the various configurable thresholds, we only trigger a
    full collection if the ratio
     long_lived_pending / long_lived_total
    is above a given value (hardwired to 25%).

    The reason is that, while "non-full" collections (i.e., collections of
    the young and middle generations) will always examine roughly the same
    number of objects -- determined by the aforementioned thresholds --,
    the cost of a full collection is proportional to the total number of
    long-lived objects, which is virtually unbounded.

    Indeed, it has been remarked that doing a full collection every
    <constant number> of object creations entails a dramatic performance
    degradation in workloads which consist in creating and storing lots of
    long-lived objects (e.g. building a large list of GC-tracked objects would
    show quadratic performance, instead of linear as expected: see issue #4074).

    Using the above ratio, instead, yields amortized linear performance in
    the total number of objects (the effect of which can be summarized
    thusly: "each full garbage collection is more and more costly as the
    number of objects grows, but we do fewer and fewer of them").

    This heuristic was suggested by Martin von Löwis on python-dev in
    June 2008. His original analysis and proposal can be found at:
     http://mail.python.org/pipermail/python-dev/2008-June/080579.html
 */

 /*
    NOTE: about untracking of mutable objects.

    Certain types of container cannot participate in a reference cycle, and
    so do not need to be tracked by the garbage collector. Untracking these
    objects reduces the cost of garbage collections. However, determining
    which objects may be untracked is not free, and the costs must be
    weighed against the benefits for garbage collection.

    There are two possible strategies for when to untrack a container:

    i) When the container is created.
    ii) When the container is examined by the garbage collector.

    Tuples containing only immutable objects (integers, strings etc, and
    recursively, tuples of immutable objects) do not need to be tracked.
    The interpreter creates a large number of tuples, many of which will
    not survive until garbage collection. It is therefore not worthwhile
    to untrack eligible tuples at creation time.

    Instead, all tuples except the empty tuple are tracked when created.
    During garbage collection it is determined whether any surviving tuples
    can be untracked. A tuple can be untracked if all of its contents are
    already not tracked. Tuples are examined for untracking in all garbage
    collection cycles. It may take more than one cycle to untrack a tuple.

    Dictionaries containing only immutable objects also do not need to be
    tracked. Dictionaries are untracked when created. If a tracked item is
    inserted into a dictionary (either as a key or value), the dictionary
    becomes tracked. During a full garbage collection (all generations),
    the collector will untrack any dictionaries whose contents are not
    tracked.

    The module provides the python function is_tracked(obj), which returns
    the CURRENT tracking status of the object. Subsequent garbage
    collections may change the tracking status of the object.

    Untracking of certain containers was introduced in issue #4688, and
    the algorithm was refined in response to issue #14775.
 */

 struct gc_generation {
     PyGC_Head head;
     int threshold; /* collection threshold */
     int count; /* count of allocations or collections of younger
                   generations */
 };

 /* Running stats per generation */
 struct gc_generation_stats {
     /* total number of collections */
     Py_ssize_t collections;
     /* total number of collected objects */
     Py_ssize_t collected;
     /* total number of uncollectable objects (put into gc.garbage) */
     Py_ssize_t uncollectable;
 };

 struct _gc_runtime_state {
     /* List of objects that still need to be cleaned up, singly linked
      * via their gc headers' gc_prev pointers.  */
     PyObject *trash_delete_later;
     /* Current call-stack depth of tp_dealloc calls. */
     int trash_delete_nesting;

     int enabled;
     int debug;
     /* linked lists of container objects */
     struct gc_generation generations[NUM_GENERATIONS];
     PyGC_Head *generation0;
     /* a permanent generation which won't be collected */
     struct gc_generation permanent_generation;
     struct gc_generation_stats generation_stats[NUM_GENERATIONS];
     /* true if we are currently running the collector */
     int collecting;
     /* list of uncollectable objects */
     PyObject *garbage;
     /* a list of callbacks to be invoked when collection is performed */
     PyObject *callbacks;
     /* This is the number of objects that survived the last full
        collection. It approximates the number of long lived objects
        tracked by the GC.

        (by "full collection", we mean a collection of the oldest
        generation). */
     Py_ssize_t long_lived_total;
     /* This is the number of objects that survived all "non-full"
        collections, and are awaiting to undergo a full collection for
        the first time. */
     Py_ssize_t long_lived_pending;
 };

 PyAPI_FUNC(void) _PyGC_Initialize(struct _gc_runtime_state *);


 /* Set the memory allocator of the specified domain to the default.
    Save the old allocator into *old_alloc if it's non-NULL.
    Return on success, or return -1 if the domain is unknown. */
 PyAPI_FUNC(int) _PyMem_SetDefaultAllocator(
     PyMemAllocatorDomain domain,
     PyMemAllocatorEx *old_alloc);

 /* Special bytes broadcast into debug memory blocks at appropriate times.
    Strings of these are unlikely to be valid addresses, floats, ints or
    7-bit ASCII.

    - PYMEM_CLEANBYTE: clean (newly allocated) memory
    - PYMEM_DEADBYTE dead (newly freed) memory
    - PYMEM_FORBIDDENBYTE: untouchable bytes at each end of a block

    Byte patterns 0xCB, 0xDB and 0xFB have been replaced with 0xCD, 0xDD and
    0xFD to use the same values than Windows CRT debug malloc() and free().
    If modified, _PyMem_IsPtrFreed() should be updated as well. */
 #define PYMEM_CLEANBYTE      0xCD
 #define PYMEM_DEADBYTE       0xDD
 #define PYMEM_FORBIDDENBYTE  0xFD

 /* Heuristic checking if a pointer value is newly allocated
    (uninitialized), newly freed or NULL (is equal to zero).

    The pointer is not dereferenced, only the pointer value is checked.

    The heuristic relies on the debug hooks on Python memory allocators which
    fills newly allocated memory with CLEANBYTE (0xCD) and newly freed memory
    with DEADBYTE (0xDD). Detect also "untouchable bytes" marked
    with FORBIDDENBYTE (0xFD). */
 static inline int _PyMem_IsPtrFreed(void *ptr)
 {
     uintptr_t value = (uintptr_t)ptr;
 #if SIZEOF_VOID_P == 8
     return (value == 0
             || value == (uintptr_t)0xCDCDCDCDCDCDCDCD
             || value == (uintptr_t)0xDDDDDDDDDDDDDDDD
             || value == (uintptr_t)0xFDFDFDFDFDFDFDFD);
 #elif SIZEOF_VOID_P == 4
     return (value == 0
             || value == (uintptr_t)0xCDCDCDCD
             || value == (uintptr_t)0xDDDDDDDD
             || value == (uintptr_t)0xFDFDFDFD);
 #else
 #  error "unknown pointer size"
 #endif
 }

 PyAPI_FUNC(int) _PyMem_GetAllocatorName(
     const char *name,
     PyMemAllocatorName *allocator);

 /* Configure the Python memory allocators.
    Pass PYMEM_ALLOCATOR_DEFAULT to use default allocators.
    PYMEM_ALLOCATOR_NOT_SET does nothing. */
 PyAPI_FUNC(int) _PyMem_SetupAllocators(PyMemAllocatorName allocator);

 #ifdef __cplusplus
 }
 #endif
 #endif /* !Py_INTERNAL_PYMEM_H */
	#ifndef Py_INTERNAL_PYMEM_H
	#define Py_INTERNAL_PYMEM_H
	#ifdef __cplusplus
	extern "C" {
	#endif

	#ifndef Py_BUILD_CORE
	# error "this header requires Py_BUILD_CORE define"
	#endif

	#include "objimpl.h"
	#include "pymem.h"


	/* GC runtime state */

	/* If we change this, we need to change the default value in the
	signature of gc.collect. */
	#define NUM_GENERATIONS 3

	/*
	NOTE: about the counting of long-lived objects.

	To limit the cost of garbage collection, there are two strategies;
	- make each collection faster, e.g. by scanning fewer objects
	- do less collections
	This heuristic is about the latter strategy.

	In addition to the various configurable thresholds, we only trigger a
	full collection if the ratio
	long_lived_pending / long_lived_total
	is above a given value (hardwired to 25%).

	The reason is that, while "non-full" collections (i.e., collections of
	the young and middle generations) will always examine roughly the same
	number of objects -- determined by the aforementioned thresholds --,
	the cost of a full collection is proportional to the total number of
	long-lived objects, which is virtually unbounded.

	Indeed, it has been remarked that doing a full collection every
	<constant number> of object creations entails a dramatic performance
	degradation in workloads which consist in creating and storing lots of
	long-lived objects (e.g. building a large list of GC-tracked objects would
	show quadratic performance, instead of linear as expected: see issue #4074).

	Using the above ratio, instead, yields amortized linear performance in
	the total number of objects (the effect of which can be summarized
	thusly: "each full garbage collection is more and more costly as the
	number of objects grows, but we do fewer and fewer of them").

	This heuristic was suggested by Martin von Löwis on python-dev in
	June 2008. His original analysis and proposal can be found at:
	http://mail.python.org/pipermail/python-dev/2008-June/080579.html
	*/

	/*
	NOTE: about untracking of mutable objects.

	Certain types of container cannot participate in a reference cycle, and
	so do not need to be tracked by the garbage collector. Untracking these
	objects reduces the cost of garbage collections. However, determining
	which objects may be untracked is not free, and the costs must be
	weighed against the benefits for garbage collection.

	There are two possible strategies for when to untrack a container:

	i) When the container is created.
	ii) When the container is examined by the garbage collector.

	Tuples containing only immutable objects (integers, strings etc, and
	recursively, tuples of immutable objects) do not need to be tracked.
	The interpreter creates a large number of tuples, many of which will
	not survive until garbage collection. It is therefore not worthwhile
	to untrack eligible tuples at creation time.

	Instead, all tuples except the empty tuple are tracked when created.
	During garbage collection it is determined whether any surviving tuples
	can be untracked. A tuple can be untracked if all of its contents are
	already not tracked. Tuples are examined for untracking in all garbage
	collection cycles. It may take more than one cycle to untrack a tuple.

	Dictionaries containing only immutable objects also do not need to be
	tracked. Dictionaries are untracked when created. If a tracked item is
	inserted into a dictionary (either as a key or value), the dictionary
	becomes tracked. During a full garbage collection (all generations),
	the collector will untrack any dictionaries whose contents are not
	tracked.

	The module provides the python function is_tracked(obj), which returns
	the CURRENT tracking status of the object. Subsequent garbage
	collections may change the tracking status of the object.

	Untracking of certain containers was introduced in issue #4688, and
	the algorithm was refined in response to issue #14775.
	*/

	struct gc_generation {
	PyGC_Head head;
	int threshold; /* collection threshold */
	int count; /* count of allocations or collections of younger
	generations */
	};

	/* Running stats per generation */
	struct gc_generation_stats {
	/* total number of collections */
	Py_ssize_t collections;
	/* total number of collected objects */
	Py_ssize_t collected;
	/* total number of uncollectable objects (put into gc.garbage) */
	Py_ssize_t uncollectable;
	};

	struct _gc_runtime_state {
	/* List of objects that still need to be cleaned up, singly linked
	* via their gc headers' gc_prev pointers. */
	PyObject *trash_delete_later;
	/* Current call-stack depth of tp_dealloc calls. */
	int trash_delete_nesting;

	int enabled;
	int debug;
	/* linked lists of container objects */
	struct gc_generation generations[NUM_GENERATIONS];
	PyGC_Head *generation0;
	/* a permanent generation which won't be collected */
	struct gc_generation permanent_generation;
	struct gc_generation_stats generation_stats[NUM_GENERATIONS];
	/* true if we are currently running the collector */
	int collecting;
	/* list of uncollectable objects */
	PyObject *garbage;
	/* a list of callbacks to be invoked when collection is performed */
	PyObject *callbacks;
	/* This is the number of objects that survived the last full
	collection. It approximates the number of long lived objects
	tracked by the GC.

	(by "full collection", we mean a collection of the oldest
	generation). */
	Py_ssize_t long_lived_total;
	/* This is the number of objects that survived all "non-full"
	collections, and are awaiting to undergo a full collection for
	the first time. */
	Py_ssize_t long_lived_pending;
	};

	PyAPI_FUNC(void) _PyGC_Initialize(struct _gc_runtime_state *);


	/* Set the memory allocator of the specified domain to the default.
	Save the old allocator into *old_alloc if it's non-NULL.
	Return on success, or return -1 if the domain is unknown. */
	PyAPI_FUNC(int) _PyMem_SetDefaultAllocator(
	PyMemAllocatorDomain domain,
	PyMemAllocatorEx *old_alloc);

	/* Special bytes broadcast into debug memory blocks at appropriate times.
	Strings of these are unlikely to be valid addresses, floats, ints or
	7-bit ASCII.

	- PYMEM_CLEANBYTE: clean (newly allocated) memory
	- PYMEM_DEADBYTE dead (newly freed) memory
	- PYMEM_FORBIDDENBYTE: untouchable bytes at each end of a block

	Byte patterns 0xCB, 0xDB and 0xFB have been replaced with 0xCD, 0xDD and
	0xFD to use the same values than Windows CRT debug malloc() and free().
	If modified, _PyMem_IsPtrFreed() should be updated as well. */
	#define PYMEM_CLEANBYTE 0xCD
	#define PYMEM_DEADBYTE 0xDD
	#define PYMEM_FORBIDDENBYTE 0xFD

	/* Heuristic checking if a pointer value is newly allocated
	(uninitialized), newly freed or NULL (is equal to zero).

	The pointer is not dereferenced, only the pointer value is checked.

	The heuristic relies on the debug hooks on Python memory allocators which
	fills newly allocated memory with CLEANBYTE (0xCD) and newly freed memory
	with DEADBYTE (0xDD). Detect also "untouchable bytes" marked
	with FORBIDDENBYTE (0xFD). */
	static inline int _PyMem_IsPtrFreed(void *ptr)
	{
	uintptr_t value = (uintptr_t)ptr;
	#if SIZEOF_VOID_P == 8
	return (value == 0
	\|\| value == (uintptr_t)0xCDCDCDCDCDCDCDCD
	\|\| value == (uintptr_t)0xDDDDDDDDDDDDDDDD
	\|\| value == (uintptr_t)0xFDFDFDFDFDFDFDFD);
	#elif SIZEOF_VOID_P == 4
	return (value == 0
	\|\| value == (uintptr_t)0xCDCDCDCD
	\|\| value == (uintptr_t)0xDDDDDDDD
	\|\| value == (uintptr_t)0xFDFDFDFD);
	#else
	# error "unknown pointer size"
	#endif
	}

	PyAPI_FUNC(int) _PyMem_GetAllocatorName(
	const char *name,
	PyMemAllocatorName *allocator);

	/* Configure the Python memory allocators.
	Pass PYMEM_ALLOCATOR_DEFAULT to use default allocators.
	PYMEM_ALLOCATOR_NOT_SET does nothing. */
	PyAPI_FUNC(int) _PyMem_SetupAllocators(PyMemAllocatorName allocator);

	#ifdef __cplusplus
	}
	#endif
	#endif /* !Py_INTERNAL_PYMEM_H */