2019-05-24 12:01:38 -03:00
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#ifndef Py_INTERNAL_PYMEM_H
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#define Py_INTERNAL_PYMEM_H
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2017-09-08 02:51:28 -03:00
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#ifdef __cplusplus
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extern "C" {
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#endif
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2019-04-17 18:02:26 -03:00
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#ifndef Py_BUILD_CORE
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# error "this header requires Py_BUILD_CORE define"
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2018-10-31 16:19:24 -03:00
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#endif
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2017-09-08 02:51:28 -03:00
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#include "objimpl.h"
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#include "pymem.h"
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/* GC runtime state */
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/* If we change this, we need to change the default value in the
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signature of gc.collect. */
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#define NUM_GENERATIONS 3
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/*
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NOTE: about the counting of long-lived objects.
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To limit the cost of garbage collection, there are two strategies;
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- make each collection faster, e.g. by scanning fewer objects
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- do less collections
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This heuristic is about the latter strategy.
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In addition to the various configurable thresholds, we only trigger a
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full collection if the ratio
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long_lived_pending / long_lived_total
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is above a given value (hardwired to 25%).
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The reason is that, while "non-full" collections (i.e., collections of
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the young and middle generations) will always examine roughly the same
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number of objects -- determined by the aforementioned thresholds --,
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the cost of a full collection is proportional to the total number of
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long-lived objects, which is virtually unbounded.
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Indeed, it has been remarked that doing a full collection every
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<constant number> of object creations entails a dramatic performance
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degradation in workloads which consist in creating and storing lots of
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long-lived objects (e.g. building a large list of GC-tracked objects would
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show quadratic performance, instead of linear as expected: see issue #4074).
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Using the above ratio, instead, yields amortized linear performance in
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the total number of objects (the effect of which can be summarized
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thusly: "each full garbage collection is more and more costly as the
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number of objects grows, but we do fewer and fewer of them").
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This heuristic was suggested by Martin von Löwis on python-dev in
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June 2008. His original analysis and proposal can be found at:
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http://mail.python.org/pipermail/python-dev/2008-June/080579.html
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*/
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/*
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NOTE: about untracking of mutable objects.
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Certain types of container cannot participate in a reference cycle, and
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so do not need to be tracked by the garbage collector. Untracking these
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objects reduces the cost of garbage collections. However, determining
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which objects may be untracked is not free, and the costs must be
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weighed against the benefits for garbage collection.
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There are two possible strategies for when to untrack a container:
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i) When the container is created.
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ii) When the container is examined by the garbage collector.
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Tuples containing only immutable objects (integers, strings etc, and
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recursively, tuples of immutable objects) do not need to be tracked.
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The interpreter creates a large number of tuples, many of which will
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not survive until garbage collection. It is therefore not worthwhile
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to untrack eligible tuples at creation time.
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Instead, all tuples except the empty tuple are tracked when created.
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During garbage collection it is determined whether any surviving tuples
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can be untracked. A tuple can be untracked if all of its contents are
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already not tracked. Tuples are examined for untracking in all garbage
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collection cycles. It may take more than one cycle to untrack a tuple.
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Dictionaries containing only immutable objects also do not need to be
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tracked. Dictionaries are untracked when created. If a tracked item is
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inserted into a dictionary (either as a key or value), the dictionary
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becomes tracked. During a full garbage collection (all generations),
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the collector will untrack any dictionaries whose contents are not
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tracked.
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The module provides the python function is_tracked(obj), which returns
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the CURRENT tracking status of the object. Subsequent garbage
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collections may change the tracking status of the object.
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Untracking of certain containers was introduced in issue #4688, and
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the algorithm was refined in response to issue #14775.
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*/
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struct gc_generation {
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PyGC_Head head;
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int threshold; /* collection threshold */
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int count; /* count of allocations or collections of younger
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generations */
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};
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/* Running stats per generation */
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struct gc_generation_stats {
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/* total number of collections */
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Py_ssize_t collections;
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/* total number of collected objects */
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Py_ssize_t collected;
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/* total number of uncollectable objects (put into gc.garbage) */
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Py_ssize_t uncollectable;
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};
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struct _gc_runtime_state {
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/* List of objects that still need to be cleaned up, singly linked
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* via their gc headers' gc_prev pointers. */
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PyObject *trash_delete_later;
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/* Current call-stack depth of tp_dealloc calls. */
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int trash_delete_nesting;
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int enabled;
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int debug;
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/* linked lists of container objects */
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struct gc_generation generations[NUM_GENERATIONS];
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PyGC_Head *generation0;
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2017-10-16 16:49:41 -03:00
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/* a permanent generation which won't be collected */
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struct gc_generation permanent_generation;
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2017-09-08 02:51:28 -03:00
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struct gc_generation_stats generation_stats[NUM_GENERATIONS];
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/* true if we are currently running the collector */
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int collecting;
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/* list of uncollectable objects */
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PyObject *garbage;
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/* a list of callbacks to be invoked when collection is performed */
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PyObject *callbacks;
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/* This is the number of objects that survived the last full
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collection. It approximates the number of long lived objects
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tracked by the GC.
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(by "full collection", we mean a collection of the oldest
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generation). */
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Py_ssize_t long_lived_total;
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/* This is the number of objects that survived all "non-full"
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collections, and are awaiting to undergo a full collection for
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the first time. */
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Py_ssize_t long_lived_pending;
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};
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PyAPI_FUNC(void) _PyGC_Initialize(struct _gc_runtime_state *);
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2018-10-31 16:19:24 -03:00
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/* Set the memory allocator of the specified domain to the default.
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Save the old allocator into *old_alloc if it's non-NULL.
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Return on success, or return -1 if the domain is unknown. */
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PyAPI_FUNC(int) _PyMem_SetDefaultAllocator(
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PyMemAllocatorDomain domain,
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PyMemAllocatorEx *old_alloc);
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2019-04-11 06:33:27 -03:00
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/* Heuristic checking if a pointer value is newly allocated
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(uninitialized) or newly freed. The pointer is not dereferenced, only the
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pointer value is checked.
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The heuristic relies on the debug hooks on Python memory allocators which
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2019-04-11 08:01:15 -03:00
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fills newly allocated memory with CLEANBYTE (0xCD) and newly freed memory
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with DEADBYTE (0xDD). Detect also "untouchable bytes" marked
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with FORBIDDENBYTE (0xFD). */
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2019-04-11 06:33:27 -03:00
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static inline int _PyMem_IsPtrFreed(void *ptr)
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{
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uintptr_t value = (uintptr_t)ptr;
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#if SIZEOF_VOID_P == 8
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return (value == (uintptr_t)0xCDCDCDCDCDCDCDCD
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|| value == (uintptr_t)0xDDDDDDDDDDDDDDDD
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|| value == (uintptr_t)0xFDFDFDFDFDFDFDFD);
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2019-04-11 06:33:27 -03:00
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#elif SIZEOF_VOID_P == 4
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return (value == (uintptr_t)0xCDCDCDCD
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|| value == (uintptr_t)0xDDDDDDDD
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|| value == (uintptr_t)0xFDFDFDFD);
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2019-04-11 06:33:27 -03:00
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#else
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# error "unknown pointer size"
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#endif
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}
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2019-05-17 10:20:52 -03:00
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PyAPI_FUNC(int) _PyMem_GetAllocatorName(
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const char *name,
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PyMemAllocatorName *allocator);
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/* Configure the Python memory allocators.
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Pass PYMEM_ALLOCATOR_DEFAULT to use default allocators.
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PYMEM_ALLOCATOR_NOT_SET does nothing. */
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PyAPI_FUNC(int) _PyMem_SetupAllocators(PyMemAllocatorName allocator);
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2017-09-08 02:51:28 -03:00
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#ifdef __cplusplus
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}
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#endif
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2019-05-24 12:01:38 -03:00
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#endif /* !Py_INTERNAL_PYMEM_H */
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