mirror of https://github.com/python/cpython
302 lines
11 KiB
C
302 lines
11 KiB
C
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#ifndef Py_OBJIMPL_H
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#define Py_OBJIMPL_H
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#include "pymem.h"
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#ifdef __cplusplus
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extern "C" {
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#endif
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/*
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Functions and macros for modules that implement new object types.
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You must first include "object.h".
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- PyObject_New(type, typeobj) allocates memory for a new object of
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the given type; here 'type' must be the C structure type used to
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represent the object and 'typeobj' the address of the corresponding
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type object. Reference count and type pointer are filled in; the
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rest of the bytes of the object are *undefined*! The resulting
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expression type is 'type *'. The size of the object is actually
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determined by the tp_basicsize field of the type object.
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- PyObject_NewVar(type, typeobj, n) is similar but allocates a
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variable-size object with n extra items. The size is computed as
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tp_basicsize plus n * tp_itemsize. This fills in the ob_size field
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as well.
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- PyObject_Del(op) releases the memory allocated for an object.
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- PyObject_Init(op, typeobj) and PyObject_InitVar(op, typeobj, n) are
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similar to PyObject_{New, NewVar} except that they don't allocate
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the memory needed for an object. Instead of the 'type' parameter,
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they accept the pointer of a new object (allocated by an arbitrary
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allocator) and initialize its object header fields.
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Note that objects created with PyObject_{New, NewVar} are allocated
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within the Python heap by the raw memory allocator (usually the system
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malloc). If you want to use the specialized Python allocator use
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PyMalloc_New and PyMalloc_NewVar to allocate the objects and
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PyMalloc_Del to free them.
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In case a specific form of memory management is needed, implying that
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the objects would not reside in the Python heap (for example standard
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malloc heap(s) are mandatory, use of shared memory, C++ local storage
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or operator new), you must first allocate the object with your custom
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allocator, then pass its pointer to PyObject_{Init, InitVar} for
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filling in its Python-specific fields: reference count, type pointer,
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possibly others. You should be aware that Python has very limited
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control over these objects because they don't cooperate with the
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Python memory manager. Such objects may not be eligible for automatic
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garbage collection and you have to make sure that they are released
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accordingly whenever their destructor gets called (cf. the specific
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form of memory management you're using).
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Unless you have specific memory management requirements, it is
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recommended to use PyObject_{New, NewVar, Del}. */
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/*
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* Raw object memory interface
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* ===========================
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*/
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/* The use of this API should be avoided, unless a builtin object
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constructor inlines PyObject_{New, NewVar}, either because the
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latter functions cannot allocate the exact amount of needed memory,
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either for speed. This situation is exceptional, but occurs for
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some object constructors (PyBuffer_New, PyList_New...). Inlining
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PyObject_{New, NewVar} for objects that are supposed to belong to
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the Python heap is discouraged. If you really have to, make sure
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the object is initialized with PyObject_{Init, InitVar}. Do *not*
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inline PyObject_{Init, InitVar} for user-extension types or you
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might seriously interfere with Python's memory management. */
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/* Functions */
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/* Wrappers that useful if you need to be sure that you are using the
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same object memory allocator as Python. These wrappers *do not* make
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sure that allocating 0 bytes returns a non-NULL pointer. Returned
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pointers must be checked for NULL explicitly; no action is performed
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on failure. */
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extern DL_IMPORT(void *) PyObject_Malloc(size_t);
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extern DL_IMPORT(void *) PyObject_Realloc(void *, size_t);
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extern DL_IMPORT(void) PyObject_Free(void *);
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/* Macros */
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#define PyObject_MALLOC(n) PyMem_MALLOC(n)
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#define PyObject_REALLOC(op, n) PyMem_REALLOC((void *)(op), (n))
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#define PyObject_FREE(op) PyMem_FREE((void *)(op))
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/*
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* Generic object allocator interface
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* ==================================
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*/
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/* Functions */
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extern DL_IMPORT(PyObject *) PyObject_Init(PyObject *, PyTypeObject *);
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extern DL_IMPORT(PyVarObject *) PyObject_InitVar(PyVarObject *,
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PyTypeObject *, int);
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extern DL_IMPORT(PyObject *) _PyObject_New(PyTypeObject *);
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extern DL_IMPORT(PyVarObject *) _PyObject_NewVar(PyTypeObject *, int);
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extern DL_IMPORT(void) _PyObject_Del(PyObject *);
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#define PyObject_New(type, typeobj) \
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( (type *) _PyObject_New(typeobj) )
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#define PyObject_NewVar(type, typeobj, n) \
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( (type *) _PyObject_NewVar((typeobj), (n)) )
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#define PyObject_Del(op) _PyObject_Del((PyObject *)(op))
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/* Macros trading binary compatibility for speed. See also pymem.h.
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Note that these macros expect non-NULL object pointers.*/
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#define PyObject_INIT(op, typeobj) \
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( (op)->ob_type = (typeobj), _Py_NewReference((PyObject *)(op)), (op) )
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#define PyObject_INIT_VAR(op, typeobj, size) \
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( (op)->ob_size = (size), PyObject_INIT((op), (typeobj)) )
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#define _PyObject_SIZE(typeobj) ( (typeobj)->tp_basicsize )
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/* _PyObject_VAR_SIZE returns the number of bytes (as size_t) allocated for a
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vrbl-size object with nitems items, exclusive of gc overhead (if any). The
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value is rounded up to the closest multiple of sizeof(void *), in order to
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ensure that pointer fields at the end of the object are correctly aligned
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for the platform (this is of special importance for subclasses of, e.g.,
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str or long, so that pointers can be stored after the embedded data).
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Note that there's no memory wastage in doing this, as malloc has to
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return (at worst) pointer-aligned memory anyway.
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*/
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#if ((SIZEOF_VOID_P - 1) & SIZEOF_VOID_P) != 0
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# error "_PyObject_VAR_SIZE requires SIZEOF_VOID_P be a power of 2"
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#endif
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#define _PyObject_VAR_SIZE(typeobj, nitems) \
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(size_t) \
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( ( (typeobj)->tp_basicsize + \
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(nitems)*(typeobj)->tp_itemsize + \
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(SIZEOF_VOID_P - 1) \
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) & ~(SIZEOF_VOID_P - 1) \
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)
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#define PyObject_NEW(type, typeobj) \
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( (type *) PyObject_Init( \
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(PyObject *) PyObject_MALLOC( _PyObject_SIZE(typeobj) ), (typeobj)) )
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#define PyObject_NEW_VAR(type, typeobj, n) \
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( (type *) PyObject_InitVar( \
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(PyVarObject *) PyObject_MALLOC(_PyObject_VAR_SIZE((typeobj),(n)) ),\
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(typeobj), (n)) )
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#define PyObject_DEL(op) PyObject_FREE(op)
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/* This example code implements an object constructor with a custom
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allocator, where PyObject_New is inlined, and shows the important
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distinction between two steps (at least):
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1) the actual allocation of the object storage;
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2) the initialization of the Python specific fields
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in this storage with PyObject_{Init, InitVar}.
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PyObject *
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YourObject_New(...)
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{
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PyObject *op;
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op = (PyObject *) Your_Allocator(_PyObject_SIZE(YourTypeStruct));
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if (op == NULL)
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return PyErr_NoMemory();
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op = PyObject_Init(op, &YourTypeStruct);
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if (op == NULL)
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return NULL;
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op->ob_field = value;
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...
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return op;
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}
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Note that in C++, the use of the new operator usually implies that
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the 1st step is performed automatically for you, so in a C++ class
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constructor you would start directly with PyObject_Init/InitVar. */
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/*
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* The PyMalloc Object Allocator
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* =============================
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*/
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extern DL_IMPORT(PyObject *) _PyMalloc_New(PyTypeObject *);
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extern DL_IMPORT(PyVarObject *) _PyMalloc_NewVar(PyTypeObject *, int);
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extern DL_IMPORT(void) _PyMalloc_Del(PyObject *);
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#define PyMalloc_New(type, typeobj) \
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( (type *) _PyMalloc_New(typeobj) )
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#define PyMalloc_NewVar(type, typeobj, n) \
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( (type *) _PyMalloc_NewVar((typeobj), (n)) )
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#define PyMalloc_Del(op) _PyMalloc_Del((PyObject *)(op))
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/*
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* Garbage Collection Support
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* ==========================
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*
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* Some of the functions and macros below are always defined; when
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* WITH_CYCLE_GC is undefined, they simply don't do anything different
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* than their non-GC counterparts.
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*/
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/* Test if a type has a GC head */
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#define PyType_IS_GC(t) PyType_HasFeature((t), Py_TPFLAGS_HAVE_GC)
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/* Test if an object has a GC head */
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#define PyObject_IS_GC(o) (PyType_IS_GC((o)->ob_type) && \
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((o)->ob_type->tp_is_gc == NULL || (o)->ob_type->tp_is_gc(o)))
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extern DL_IMPORT(PyObject *) _PyObject_GC_Malloc(PyTypeObject *, int);
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extern DL_IMPORT(PyVarObject *) _PyObject_GC_Resize(PyVarObject *, int);
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#define PyObject_GC_Resize(type, op, n) \
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( (type *) _PyObject_GC_Resize((PyVarObject *)(op), (n)) )
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extern DL_IMPORT(PyObject *) _PyObject_GC_New(PyTypeObject *);
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extern DL_IMPORT(PyVarObject *) _PyObject_GC_NewVar(PyTypeObject *, int);
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extern DL_IMPORT(void) _PyObject_GC_Del(PyObject *);
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extern DL_IMPORT(void) _PyObject_GC_Track(PyObject *);
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extern DL_IMPORT(void) _PyObject_GC_UnTrack(PyObject *);
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#ifdef WITH_CYCLE_GC
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/* GC information is stored BEFORE the object structure */
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typedef union _gc_head {
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struct {
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union _gc_head *gc_next; /* not NULL if object is tracked */
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union _gc_head *gc_prev;
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int gc_refs;
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} gc;
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long double dummy; /* force worst-case alignment */
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} PyGC_Head;
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extern PyGC_Head _PyGC_generation0;
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/* Tell the GC to track this object. NB: While the object is tracked the
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* collector it must be safe to call the ob_traverse method. */
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#define _PyObject_GC_TRACK(o) do { \
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PyGC_Head *g = (PyGC_Head *)(o)-1; \
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if (g->gc.gc_next != NULL) \
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Py_FatalError("GC object already in linked list"); \
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g->gc.gc_next = &_PyGC_generation0; \
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g->gc.gc_prev = _PyGC_generation0.gc.gc_prev; \
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g->gc.gc_prev->gc.gc_next = g; \
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_PyGC_generation0.gc.gc_prev = g; \
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} while (0);
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/* Tell the GC to stop tracking this object. */
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#define _PyObject_GC_UNTRACK(o) do { \
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PyGC_Head *g = (PyGC_Head *)(o)-1; \
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g->gc.gc_prev->gc.gc_next = g->gc.gc_next; \
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g->gc.gc_next->gc.gc_prev = g->gc.gc_prev; \
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g->gc.gc_next = NULL; \
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} while (0);
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#define PyObject_GC_Track(op) _PyObject_GC_Track((PyObject *)op)
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#define PyObject_GC_UnTrack(op) _PyObject_GC_UnTrack((PyObject *)op)
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#define PyObject_GC_New(type, typeobj) \
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( (type *) _PyObject_GC_New(typeobj) )
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#define PyObject_GC_NewVar(type, typeobj, n) \
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( (type *) _PyObject_GC_NewVar((typeobj), (n)) )
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#define PyObject_GC_Del(op) _PyObject_GC_Del((PyObject *)(op))
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#else /* !WITH_CYCLE_GC */
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#define PyObject_GC_New PyObject_New
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#define PyObject_GC_NewVar PyObject_NewVar
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#define PyObject_GC_Del PyObject_Del
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#define _PyObject_GC_TRACK(op)
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#define _PyObject_GC_UNTRACK(op)
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#define PyObject_GC_Track(op)
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#define PyObject_GC_UnTrack(op)
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#endif
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/* This is here for the sake of backwards compatibility. Extensions that
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* use the old GC API will still compile but the objects will not be
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* tracked by the GC. */
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#define PyGC_HEAD_SIZE 0
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#define PyObject_GC_Init(op)
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#define PyObject_GC_Fini(op)
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#define PyObject_AS_GC(op) (op)
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#define PyObject_FROM_GC(op) (op)
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/* Test if a type supports weak references */
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#define PyType_SUPPORTS_WEAKREFS(t) \
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(PyType_HasFeature((t), Py_TPFLAGS_HAVE_WEAKREFS) \
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&& ((t)->tp_weaklistoffset > 0))
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#define PyObject_GET_WEAKREFS_LISTPTR(o) \
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((PyObject **) (((char *) (o)) + (o)->ob_type->tp_weaklistoffset))
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#ifdef __cplusplus
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}
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#endif
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#endif /* !Py_OBJIMPL_H */
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