mirror of https://github.com/python/cpython
[3.13] GH-124567: Revert the Incremental GC in 3.13 (#124770)
Revert the incremental GC in 3.13, since it's not clear that without further turning, the benefits outweigh the costs. Co-authored-by: Adam Turner <9087854+AA-Turner@users.noreply.github.com>
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@ -40,18 +40,11 @@ The :mod:`gc` module provides the following functions:
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.. function:: collect(generation=2)
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Perform a collection. The optional argument *generation*
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With no arguments, run a full collection. The optional argument *generation*
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may be an integer specifying which generation to collect (from 0 to 2). A
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:exc:`ValueError` is raised if the generation number is invalid. The sum of
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collected objects and uncollectable objects is returned.
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Calling ``gc.collect(0)`` will perform a GC collection on the young generation.
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Calling ``gc.collect(1)`` will perform a GC collection on the young generation
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and an increment of the old generation.
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Calling ``gc.collect(2)`` or ``gc.collect()`` performs a full collection
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The free lists maintained for a number of built-in types are cleared
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whenever a full collection or collection of the highest generation (2)
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is run. Not all items in some free lists may be freed due to the
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@ -60,9 +53,6 @@ The :mod:`gc` module provides the following functions:
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The effect of calling ``gc.collect()`` while the interpreter is already
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performing a collection is undefined.
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.. versionchanged:: 3.13
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``generation=1`` performs an increment of collection.
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.. function:: set_debug(flags)
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@ -78,20 +68,13 @@ The :mod:`gc` module provides the following functions:
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.. function:: get_objects(generation=None)
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Returns a list of all objects tracked by the collector, excluding the list
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returned. If *generation* is not ``None``, return only the objects as follows:
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* 0: All objects in the young generation
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* 1: No objects, as there is no generation 1 (as of Python 3.13)
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* 2: All objects in the old generation
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returned. If *generation* is not ``None``, return only the objects tracked by
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the collector that are in that generation.
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.. versionchanged:: 3.8
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New *generation* parameter.
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.. versionchanged:: 3.13
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Generation 1 is removed
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.. audit-event:: gc.get_objects generation gc.get_objects
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.. function:: get_stats()
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@ -118,27 +101,19 @@ The :mod:`gc` module provides the following functions:
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Set the garbage collection thresholds (the collection frequency). Setting
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*threshold0* to zero disables collection.
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The GC classifies objects into two generations depending on whether they have
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survived a collection. New objects are placed in the young generation. If an
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object survives a collection it is moved into the old generation.
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In order to decide when to run, the collector keeps track of the number of object
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The GC classifies objects into three generations depending on how many
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collection sweeps they have survived. New objects are placed in the youngest
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generation (generation ``0``). If an object survives a collection it is moved
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into the next older generation. Since generation ``2`` is the oldest
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generation, objects in that generation remain there after a collection. In
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order to decide when to run, the collector keeps track of the number object
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allocations and deallocations since the last collection. When the number of
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allocations minus the number of deallocations exceeds *threshold0*, collection
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starts. For each collection, all the objects in the young generation and some
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fraction of the old generation is collected.
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The fraction of the old generation that is collected is **inversely** proportional
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to *threshold1*. The larger *threshold1* is, the slower objects in the old generation
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are collected.
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For the default value of 10, 1% of the old generation is scanned during each collection.
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*threshold2* is ignored.
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See `Garbage collector design <https://devguide.python.org/garbage_collector>`_ for more information.
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.. versionchanged:: 3.13
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*threshold2* is ignored
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starts. Initially only generation ``0`` is examined. If generation ``0`` has
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been examined more than *threshold1* times since generation ``1`` has been
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examined, then generation ``1`` is examined as well.
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With the third generation, things are a bit more complicated,
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see `Collecting the oldest generation <https://devguide.python.org/garbage_collector/#collecting-the-oldest-generation>`_ for more information.
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.. function:: get_count()
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@ -501,30 +501,6 @@ are not tier 3 supported platforms, but will have best-effort support.
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.. seealso:: :pep:`730`, :pep:`738`
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.. _whatsnew313-incremental-gc:
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Incremental garbage collection
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------------------------------
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The cycle garbage collector is now incremental.
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This means that maximum pause times are reduced
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by an order of magnitude or more for larger heaps.
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There are now only two generations: young and old.
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When :func:`gc.collect` is not called directly, the
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GC is invoked a little less frequently. When invoked, it
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collects the young generation and an increment of the
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old generation, instead of collecting one or more generations.
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The behavior of :func:`!gc.collect` changes slightly:
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* ``gc.collect(1)``: Performs an increment of garbage collection,
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rather than collecting generation 1.
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* Other calls to :func:`!gc.collect` are unchanged.
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(Contributed by Mark Shannon in :gh:`108362`.)
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Other Language Changes
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======================
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@ -921,36 +897,6 @@ fractions
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(Contributed by Mark Dickinson in :gh:`111320`.)
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gc
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--
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The cyclic garbage collector is now incremental,
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which changes the meaning of the results of
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:meth:`~gc.get_threshold` and :meth:`~gc.set_threshold`
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as well as :meth:`~gc.get_count` and :meth:`~gc.get_stats`.
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* For backwards compatibility, :meth:`~gc.get_threshold` continues to return
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a three-item tuple.
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The first value is the threshold for young collections, as before;
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the second value determines the rate at which the old collection is scanned
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(the default is 10, and higher values mean that the old collection
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is scanned more slowly).
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The third value is meaningless and is always zero.
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* :meth:`~gc.set_threshold` ignores any items after the second.
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* :meth:`~gc.get_count` and :meth:`~gc.get_stats` continue to return
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the same format of results.
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The only difference is that instead of the results referring to
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the young, aging and old generations,
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the results refer to the young generation
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and the aging and collecting spaces of the old generation.
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In summary, code that attempted to manipulate the behavior of the cycle GC
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may not work exactly as intended, but it is very unlikely to be harmful.
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All other code will work just fine.
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glob
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----
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@ -1515,11 +1461,6 @@ zipimport
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Optimizations
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=============
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* The new :ref:`incremental garbage collector <whatsnew313-incremental-gc>`
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means that maximum pause times are reduced
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by an order of magnitude or more for larger heaps.
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(Contributed by Mark Shannon in :gh:`108362`.)
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* Several standard library modules have had
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their import times significantly improved.
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For example, the import time of the :mod:`typing` module
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@ -2632,13 +2573,6 @@ Changes in the Python API
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Wrap it in :func:`staticmethod` if you want to preserve the old behavior.
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(Contributed by Serhiy Storchaka in :gh:`121027`.)
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* The :ref:`garbage collector is now incremental <whatsnew313-incremental-gc>`,
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which means that the behavior of :func:`gc.collect` changes slightly:
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* ``gc.collect(1)``: Performs an increment of garbage collection,
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rather than collecting generation 1.
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* Other calls to :func:`!gc.collect` are unchanged.
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* An :exc:`OSError` is now raised by :func:`getpass.getuser`
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for any failure to retrieve a username,
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instead of :exc:`ImportError` on non-Unix platforms
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@ -142,26 +142,11 @@ static inline void _PyObject_GC_SET_SHARED_INLINE(PyObject *op) {
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/* Bit flags for _gc_prev */
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/* Bit 0 is set when tp_finalize is called */
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#define _PyGC_PREV_MASK_FINALIZED 1
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#define _PyGC_PREV_MASK_FINALIZED (1)
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/* Bit 1 is set when the object is in generation which is GCed currently. */
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#define _PyGC_PREV_MASK_COLLECTING 2
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/* Bit 0 in _gc_next is the old space bit.
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* It is set as follows:
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* Young: gcstate->visited_space
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* old[0]: 0
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* old[1]: 1
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* permanent: 0
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*
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* During a collection all objects handled should have the bit set to
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* gcstate->visited_space, as objects are moved from the young gen
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* and the increment into old[gcstate->visited_space].
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* When object are moved from the pending space, old[gcstate->visited_space^1]
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* into the increment, the old space bit is flipped.
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*/
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#define _PyGC_NEXT_MASK_OLD_SPACE_1 1
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#define _PyGC_PREV_SHIFT 2
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#define _PyGC_PREV_MASK_COLLECTING (2)
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/* The (N-2) most significant bits contain the real address. */
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#define _PyGC_PREV_SHIFT (2)
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#define _PyGC_PREV_MASK (((uintptr_t) -1) << _PyGC_PREV_SHIFT)
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/* set for debugging information */
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@ -187,13 +172,11 @@ typedef enum {
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// Lowest bit of _gc_next is used for flags only in GC.
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// But it is always 0 for normal code.
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static inline PyGC_Head* _PyGCHead_NEXT(PyGC_Head *gc) {
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uintptr_t next = gc->_gc_next & _PyGC_PREV_MASK;
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uintptr_t next = gc->_gc_next;
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return (PyGC_Head*)next;
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}
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static inline void _PyGCHead_SET_NEXT(PyGC_Head *gc, PyGC_Head *next) {
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uintptr_t unext = (uintptr_t)next;
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assert((unext & ~_PyGC_PREV_MASK) == 0);
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gc->_gc_next = (gc->_gc_next & ~_PyGC_PREV_MASK) | unext;
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gc->_gc_next = (uintptr_t)next;
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}
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// Lowest two bits of _gc_prev is used for _PyGC_PREV_MASK_* flags.
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@ -201,7 +184,6 @@ static inline PyGC_Head* _PyGCHead_PREV(PyGC_Head *gc) {
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uintptr_t prev = (gc->_gc_prev & _PyGC_PREV_MASK);
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return (PyGC_Head*)prev;
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}
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static inline void _PyGCHead_SET_PREV(PyGC_Head *gc, PyGC_Head *prev) {
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uintptr_t uprev = (uintptr_t)prev;
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assert((uprev & ~_PyGC_PREV_MASK) == 0);
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@ -287,13 +269,6 @@ struct gc_generation {
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generations */
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};
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struct gc_collection_stats {
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/* 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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/* Running stats per generation */
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struct gc_generation_stats {
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/* total number of collections */
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@ -315,8 +290,8 @@ struct _gc_runtime_state {
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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 young;
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struct gc_generation old[2];
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struct gc_generation generations[NUM_GENERATIONS];
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PyGC_Head *generation0;
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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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struct gc_generation_stats generation_stats[NUM_GENERATIONS];
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@ -327,12 +302,6 @@ struct _gc_runtime_state {
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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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Py_ssize_t heap_size;
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Py_ssize_t work_to_do;
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/* Which of the old spaces is the visited space */
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int visited_space;
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#ifdef Py_GIL_DISABLED
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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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@ -345,6 +314,7 @@ struct _gc_runtime_state {
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the first time. */
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Py_ssize_t long_lived_pending;
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#ifdef Py_GIL_DISABLED
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/* gh-117783: Deferred reference counting is not fully implemented yet, so
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as a temporary measure we treat objects using deferred reference
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counting as immortal. The value may be zero, one, or a negative number:
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@ -365,7 +335,8 @@ struct _gc_thread_state {
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extern void _PyGC_InitState(struct _gc_runtime_state *);
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extern Py_ssize_t _PyGC_Collect(PyThreadState *tstate, int generation, _PyGC_Reason reason);
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extern Py_ssize_t _PyGC_Collect(PyThreadState *tstate, int generation,
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_PyGC_Reason reason);
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extern void _PyGC_CollectNoFail(PyThreadState *tstate);
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/* Freeze objects tracked by the GC and ignore them in future collections. */
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@ -353,12 +353,11 @@ static inline void _PyObject_GC_TRACK(
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filename, lineno, __func__);
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PyInterpreterState *interp = _PyInterpreterState_GET();
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PyGC_Head *generation0 = &interp->gc.young.head;
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PyGC_Head *generation0 = interp->gc.generation0;
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PyGC_Head *last = (PyGC_Head*)(generation0->_gc_prev);
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_PyGCHead_SET_NEXT(last, gc);
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_PyGCHead_SET_PREV(gc, last);
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/* Young objects will be moved into the visited space during GC, so set the bit here */
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gc->_gc_next = ((uintptr_t)generation0) | interp->gc.visited_space;
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_PyGCHead_SET_NEXT(gc, generation0);
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generation0->_gc_prev = (uintptr_t)gc;
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#endif
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}
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@ -228,12 +228,12 @@ extern PyTypeObject _PyExc_MemoryError;
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}, \
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.gc = { \
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.enabled = 1, \
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.young = { .threshold = 2000, }, \
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.old = { \
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.generations = { \
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/* .head is set in _PyGC_InitState(). */ \
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{ .threshold = 2000, }, \
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{ .threshold = 10, }, \
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{ .threshold = 10, }, \
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{ .threshold = 0, }, \
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}, \
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.work_to_do = -5000, \
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}, \
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.qsbr = { \
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.wr_seq = QSBR_INITIAL, \
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@ -392,11 +392,19 @@ class GCTests(unittest.TestCase):
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# each call to collect(N)
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x = []
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gc.collect(0)
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# x is now in the old gen
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# x is now in gen 1
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a, b, c = gc.get_count()
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# We don't check a since its exact values depends on
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gc.collect(1)
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# x is now in gen 2
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d, e, f = gc.get_count()
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gc.collect(2)
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# x is now in gen 3
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g, h, i = gc.get_count()
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# We don't check a, d, g since their exact values depends on
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# internal implementation details of the interpreter.
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self.assertEqual((b, c), (1, 0))
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self.assertEqual((e, f), (0, 1))
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self.assertEqual((h, i), (0, 0))
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def test_trashcan(self):
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class Ouch:
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@ -835,10 +843,42 @@ class GCTests(unittest.TestCase):
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self.assertTrue(
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any(l is element for element in gc.get_objects(generation=0))
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)
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gc.collect()
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self.assertFalse(
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any(l is element for element in gc.get_objects(generation=1))
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)
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self.assertFalse(
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any(l is element for element in gc.get_objects(generation=2))
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)
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gc.collect(generation=0)
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self.assertFalse(
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any(l is element for element in gc.get_objects(generation=0))
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)
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self.assertTrue(
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any(l is element for element in gc.get_objects(generation=1))
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)
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self.assertFalse(
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any(l is element for element in gc.get_objects(generation=2))
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)
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gc.collect(generation=1)
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self.assertFalse(
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any(l is element for element in gc.get_objects(generation=0))
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)
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self.assertFalse(
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any(l is element for element in gc.get_objects(generation=1))
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)
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self.assertTrue(
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any(l is element for element in gc.get_objects(generation=2))
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)
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gc.collect(generation=2)
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self.assertFalse(
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any(l is element for element in gc.get_objects(generation=0))
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)
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self.assertFalse(
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any(l is element for element in gc.get_objects(generation=1))
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)
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self.assertTrue(
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any(l is element for element in gc.get_objects(generation=2))
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)
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del l
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gc.collect()
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@ -1066,72 +1106,6 @@ class GCTests(unittest.TestCase):
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gc.get_referents(tracked_capsule)
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class IncrementalGCTests(unittest.TestCase):
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def setUp(self):
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# Reenable GC as it is disabled module-wide
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gc.enable()
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def tearDown(self):
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gc.disable()
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@requires_gil_enabled("Free threading does not support incremental GC")
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# Use small increments to emulate longer running process in a shorter time
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@gc_threshold(200, 10)
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def test_incremental_gc_handles_fast_cycle_creation(self):
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class LinkedList:
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#Use slots to reduce number of implicit objects
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__slots__ = "next", "prev", "surprise"
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def __init__(self, next=None, prev=None):
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self.next = next
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if next is not None:
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next.prev = self
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self.prev = prev
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if prev is not None:
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prev.next = self
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def make_ll(depth):
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head = LinkedList()
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for i in range(depth):
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head = LinkedList(head, head.prev)
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return head
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head = make_ll(1000)
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count = 1000
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# There will be some objects we aren't counting,
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# e.g. the gc stats dicts. This test checks
|
||||
# that the counts don't grow, so we try to
|
||||
# correct for the uncounted objects
|
||||
# This is just an estimate.
|
||||
CORRECTION = 20
|
||||
|
||||
enabled = gc.isenabled()
|
||||
gc.enable()
|
||||
olds = []
|
||||
for i in range(20_000):
|
||||
newhead = make_ll(20)
|
||||
count += 20
|
||||
newhead.surprise = head
|
||||
olds.append(newhead)
|
||||
if len(olds) == 20:
|
||||
stats = gc.get_stats()
|
||||
young = stats[0]
|
||||
incremental = stats[1]
|
||||
old = stats[2]
|
||||
collected = young['collected'] + incremental['collected'] + old['collected']
|
||||
count += CORRECTION
|
||||
live = count - collected
|
||||
self.assertLess(live, 25000)
|
||||
del olds[:]
|
||||
if not enabled:
|
||||
gc.disable()
|
||||
|
||||
|
||||
class GCCallbackTests(unittest.TestCase):
|
||||
def setUp(self):
|
||||
# Save gc state and disable it.
|
||||
|
|
|
@ -0,0 +1 @@
|
|||
Revert the incremental GC (in 3.13), since it's not clear the benefits outweigh the costs at this point.
|
|
@ -158,12 +158,17 @@ gc_set_threshold_impl(PyObject *module, int threshold0, int group_right_1,
|
|||
{
|
||||
GCState *gcstate = get_gc_state();
|
||||
|
||||
gcstate->young.threshold = threshold0;
|
||||
gcstate->generations[0].threshold = threshold0;
|
||||
if (group_right_1) {
|
||||
gcstate->old[0].threshold = threshold1;
|
||||
gcstate->generations[1].threshold = threshold1;
|
||||
}
|
||||
if (group_right_2) {
|
||||
gcstate->old[1].threshold = threshold2;
|
||||
gcstate->generations[2].threshold = threshold2;
|
||||
|
||||
/* generations higher than 2 get the same threshold */
|
||||
for (int i = 3; i < NUM_GENERATIONS; i++) {
|
||||
gcstate->generations[i].threshold = gcstate->generations[2].threshold;
|
||||
}
|
||||
}
|
||||
Py_RETURN_NONE;
|
||||
}
|
||||
|
@ -180,9 +185,9 @@ gc_get_threshold_impl(PyObject *module)
|
|||
{
|
||||
GCState *gcstate = get_gc_state();
|
||||
return Py_BuildValue("(iii)",
|
||||
gcstate->young.threshold,
|
||||
gcstate->old[0].threshold,
|
||||
0);
|
||||
gcstate->generations[0].threshold,
|
||||
gcstate->generations[1].threshold,
|
||||
gcstate->generations[2].threshold);
|
||||
}
|
||||
|
||||
/*[clinic input]
|
||||
|
@ -202,14 +207,14 @@ gc_get_count_impl(PyObject *module)
|
|||
struct _gc_thread_state *gc = &tstate->gc;
|
||||
|
||||
// Flush the local allocation count to the global count
|
||||
_Py_atomic_add_int(&gcstate->young.count, (int)gc->alloc_count);
|
||||
_Py_atomic_add_int(&gcstate->generations[0].count, (int)gc->alloc_count);
|
||||
gc->alloc_count = 0;
|
||||
#endif
|
||||
|
||||
return Py_BuildValue("(iii)",
|
||||
gcstate->young.count,
|
||||
gcstate->old[gcstate->visited_space].count,
|
||||
gcstate->old[gcstate->visited_space^1].count);
|
||||
gcstate->generations[0].count,
|
||||
gcstate->generations[1].count,
|
||||
gcstate->generations[2].count);
|
||||
}
|
||||
|
||||
/*[clinic input]
|
||||
|
|
994
Python/gc.c
994
Python/gc.c
File diff suppressed because it is too large
Load Diff
|
@ -744,7 +744,7 @@ void
|
|||
_PyGC_InitState(GCState *gcstate)
|
||||
{
|
||||
// TODO: move to pycore_runtime_init.h once the incremental GC lands.
|
||||
gcstate->young.threshold = 2000;
|
||||
gcstate->generations[0].threshold = 2000;
|
||||
}
|
||||
|
||||
|
||||
|
@ -1042,8 +1042,8 @@ cleanup_worklist(struct worklist *worklist)
|
|||
static bool
|
||||
gc_should_collect(GCState *gcstate)
|
||||
{
|
||||
int count = _Py_atomic_load_int_relaxed(&gcstate->young.count);
|
||||
int threshold = gcstate->young.threshold;
|
||||
int count = _Py_atomic_load_int_relaxed(&gcstate->generations[0].count);
|
||||
int threshold = gcstate->generations[0].threshold;
|
||||
if (count <= threshold || threshold == 0 || !gcstate->enabled) {
|
||||
return false;
|
||||
}
|
||||
|
@ -1051,7 +1051,7 @@ gc_should_collect(GCState *gcstate)
|
|||
// objects. A few tests rely on immediate scheduling of the GC so we ignore
|
||||
// the scaled threshold if generations[1].threshold is set to zero.
|
||||
return (count > gcstate->long_lived_total / 4 ||
|
||||
gcstate->old[0].threshold == 0);
|
||||
gcstate->generations[1].threshold == 0);
|
||||
}
|
||||
|
||||
static void
|
||||
|
@ -1065,7 +1065,7 @@ record_allocation(PyThreadState *tstate)
|
|||
if (gc->alloc_count >= LOCAL_ALLOC_COUNT_THRESHOLD) {
|
||||
// TODO: Use Py_ssize_t for the generation count.
|
||||
GCState *gcstate = &tstate->interp->gc;
|
||||
_Py_atomic_add_int(&gcstate->young.count, (int)gc->alloc_count);
|
||||
_Py_atomic_add_int(&gcstate->generations[0].count, (int)gc->alloc_count);
|
||||
gc->alloc_count = 0;
|
||||
|
||||
if (gc_should_collect(gcstate) &&
|
||||
|
@ -1084,7 +1084,7 @@ record_deallocation(PyThreadState *tstate)
|
|||
gc->alloc_count--;
|
||||
if (gc->alloc_count <= -LOCAL_ALLOC_COUNT_THRESHOLD) {
|
||||
GCState *gcstate = &tstate->interp->gc;
|
||||
_Py_atomic_add_int(&gcstate->young.count, (int)gc->alloc_count);
|
||||
_Py_atomic_add_int(&gcstate->generations[0].count, (int)gc->alloc_count);
|
||||
gc->alloc_count = 0;
|
||||
}
|
||||
}
|
||||
|
@ -1096,12 +1096,10 @@ gc_collect_internal(PyInterpreterState *interp, struct collection_state *state,
|
|||
|
||||
// update collection and allocation counters
|
||||
if (generation+1 < NUM_GENERATIONS) {
|
||||
state->gcstate->old[generation].count += 1;
|
||||
state->gcstate->generations[generation+1].count += 1;
|
||||
}
|
||||
|
||||
state->gcstate->young.count = 0;
|
||||
for (int i = 1; i <= generation; ++i) {
|
||||
state->gcstate->old[i-1].count = 0;
|
||||
for (int i = 0; i <= generation; i++) {
|
||||
state->gcstate->generations[i].count = 0;
|
||||
}
|
||||
|
||||
// merge refcounts for all queued objects
|
||||
|
|
Loading…
Reference in New Issue