Python’s support for detecting and collecting garbage which involves circular references requires support from object types which are “containers” for other objects which may also be containers. Types which do not store references to other objects, or which only store references to atomic types (such as numbers or strings), do not need to provide any explicit support for garbage collection.
To create a container type, the
tp_flags
field of the type object must include the
Py_TPFLAGS_HAVE_GC
and provide an implementation of the
tp_traverse
handler. If instances of the type are mutable, a
tp_clear
implementation must also be provided.
Py_TPFLAGS_HAVE_GC
Objects with a type with this flag set must conform with the rules documented here. For convenience these objects will be referred to as container objects.
Constructors for container types must conform to two rules:
The memory for the object must be allocated using
PyObject_GC_New()
or
PyObject_GC_NewVar()
.
Once all the fields which may contain references to other containers are initialized, it must call
PyObject_GC_Track()
.
警告
If a type adds the Py_TPFLAGS_HAVE_GC, then it
must
implement at least a
tp_traverse
handler or explicitly use one from its subclass or subclasses.
When calling
PyType_Ready()
or some of the APIs that indirectly call it like
PyType_FromSpecWithBases()
or
PyType_FromSpec()
the interpreter will automatically populate the
tp_flags
,
tp_traverse
and
tp_clear
fields if the type inherits from a class that implements the garbage collector protocol and the child class does
not
include the
Py_TPFLAGS_HAVE_GC
标志。
PyObject_GC_New
(
TYPE,
PyTypeObject
*type
)
¶
Analogous to
PyObject_New()
but for container objects with the
Py_TPFLAGS_HAVE_GC
flag set.
PyObject_GC_NewVar
(
TYPE,
PyTypeObject
*type
, Py_ssize_t
size
)
¶
Analogous to
PyObject_NewVar()
but for container objects with the
Py_TPFLAGS_HAVE_GC
flag set.
PyObject_GC_Resize
(
TYPE,
PyVarObject
*op
, Py_ssize_t
newsize
)
¶
Resize an object allocated by
PyObject_NewVar()
. Returns the resized object or
NULL
当故障时。
op
must not be tracked by the collector yet.
PyObject_GC_Track
(
PyObject
*op
)
¶
Adds the object
op
to the set of container objects tracked by the collector. The collector can run at unexpected times so objects must be valid while being tracked. This should be called once all the fields followed by the
tp_traverse
handler become valid, usually near the end of the constructor.
PyObject_IS_GC
(
PyObject
*obj
)
¶
Returns non-zero if the object implements the garbage collector protocol, otherwise returns 0.
The object cannot be tracked by the garbage collector if this function returns 0.
PyObject_GC_IsTracked
(
PyObject
*op
)
¶
Returns 1 if the object type of op implements the GC protocol and op is being currently tracked by the garbage collector and 0 otherwise.
This is analogous to the Python function
gc.is_tracked()
.
3.9 版新增。
PyObject_GC_IsFinalized
(
PyObject
*op
)
¶
Returns 1 if the object type of op implements the GC protocol and op has been already finalized by the garbage collector and 0 otherwise.
This is analogous to the Python function
gc.is_finalized()
.
3.9 版新增。
Similarly, the deallocator for the object must conform to a similar pair of rules:
Before fields which refer to other containers are invalidated,
PyObject_GC_UnTrack()
must be called.
The object’s memory must be deallocated using
PyObject_GC_Del()
.
PyObject_GC_Del
(
void
*op
)
¶
Releases memory allocated to an object using
PyObject_GC_New()
or
PyObject_GC_NewVar()
.
PyObject_GC_UnTrack
(
void
*op
)
¶
Remove the object
op
from the set of container objects tracked by the collector. Note that
PyObject_GC_Track()
can be called again on this object to add it back to the set of tracked objects. The deallocator (
tp_dealloc
handler) should call this for the object before any of the fields used by the
tp_traverse
handler become invalid.
3.8 版改变:
_PyObject_GC_TRACK()
and
_PyObject_GC_UNTRACK()
macros have been removed from the public C API.
tp_traverse
handler accepts a function parameter of this type:
(*visitproc)
(
PyObject
*object
, void
*arg
)
¶
Type of the visitor function passed to the
tp_traverse
handler. The function should be called with an object to traverse as
object
and the third parameter to the
tp_traverse
handler as
arg
. The Python core uses several visitor functions to implement cyclic garbage detection; it’s not expected that users will need to write their own visitor functions.
tp_traverse
handler must have the following type:
(*traverseproc)
(
PyObject
*self
,
visitproc
visit
, void
*arg
)
¶
Traversal function for a container object. Implementations must call the
visit
function for each object directly contained by
self
, with the parameters to
visit
being the contained object and the
arg
value passed to the handler. The
visit
function must not be called with a
NULL
object argument. If
visit
returns a non-zero value that value should be returned immediately.
To simplify writing
tp_traverse
handlers, a
Py_VISIT()
macro is provided. In order to use this macro, the
tp_traverse
implementation must name its arguments exactly
visit
and
arg
:
Py_VISIT
(
PyObject
*o
)
¶
若
o
不是
NULL
, call the
visit
callback, with arguments
o
and
arg
。若
visit
returns a non-zero value, then return it. Using this macro,
tp_traverse
handlers look like:
static int
my_traverse(Noddy *self, visitproc visit, void *arg)
{
Py_VISIT(self->foo);
Py_VISIT(self->bar);
return 0;
}
tp_clear
handler must be of the
inquiry
type, or
NULL
if the object is immutable.
(*inquiry)
(
PyObject
*self
)
¶
Drop references that may have created reference cycles. Immutable objects do not have to define this method since they can never directly create reference cycles. Note that the object must still be valid after calling this method (don’t just call
Py_DECREF()
on a reference). The collector will call this method if it detects that this object is involved in a reference cycle.