425 lines
13 KiB
Text
425 lines
13 KiB
Text
/**
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* PANDA 3D SOFTWARE
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* Copyright (c) Carnegie Mellon University. All rights reserved.
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*
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* All use of this software is subject to the terms of the revised BSD
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* license. You should have received a copy of this license along
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* with this source code in a file named "LICENSE."
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*
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* @file referenceCount.I
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* @author drose
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* @date 1998-10-23
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*/
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template<class Base>
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TypeHandle RefCountProxy<Base>::_type_handle;
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template<class Base>
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TypeHandle RefCountObj<Base>::_type_handle;
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/**
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* The ReferenceCount constructor is protected because you almost never want
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* to create just a ReferenceCount object by itself, and it's probably a
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* mistake if you try.
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*
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* ReferenceCount doesn't store any useful information in its own right; its
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* only purpose is to add reference-counting to some other class via
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* inheritance.
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*/
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INLINE ReferenceCount::
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ReferenceCount() {
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_weak_list = nullptr;
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_ref_count = 0;
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#ifdef DO_MEMORY_USAGE
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MemoryUsage::record_pointer(this);
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#endif
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}
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/**
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* The copies of reference-counted objects do not themselves inherit the
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* reference count!
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*
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* This copy constructor is protected because you almost never want to create
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* just a ReferenceCount object by itself, and it's probably a mistake if you
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* try.
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*/
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INLINE ReferenceCount::
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ReferenceCount(const ReferenceCount &) {
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_weak_list = nullptr;
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_ref_count = 0;
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#ifdef DO_MEMORY_USAGE
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MemoryUsage::record_pointer(this);
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#endif
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}
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/**
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* The copies of reference-counted objects do not themselves inherit the
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* reference count!
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*
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* This copy assignment operator is protected because you almost never want to
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* copy just a ReferenceCount object by itself, and it's probably a mistake if
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* you try. Instead, this should only be called from a derived class that
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* implements this operator and then calls up the inheritance chain.
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*/
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INLINE void ReferenceCount::
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operator = (const ReferenceCount &) {
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// If this assertion fails, our own pointer was recently deleted. Possibly
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// you used a real pointer instead of a PointerTo at some point, and the
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// object was deleted when the PointerTo went out of scope. Maybe you tried
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// to create an automatic (local variable) instance of a class that derives
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// from ReferenceCount. Or maybe your headers are out of sync, and you need
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// to make clean in direct or some higher tree.
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nassertv(_ref_count != deleted_ref_count);
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}
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/**
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*
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*/
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ReferenceCount::
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~ReferenceCount() {
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TAU_PROFILE("ReferenceCount::~ReferenceCount()", " ", TAU_USER);
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// If this assertion fails, we're trying to delete an object that was just
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// deleted. Possibly you used a real pointer instead of a PointerTo at some
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// point, and the object was deleted when the PointerTo went out of scope.
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// Maybe you tried to create an automatic (local variable) instance of a
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// class that derives from ReferenceCount. Or maybe your headers are out of
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// sync, and you need to make clean in direct or some higher tree.
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nassertv(_ref_count != deleted_ref_count);
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// If this assertion fails, we're trying to delete a static object that
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// still has an outstanding reference count. You should make sure that all
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// references to your static objects are gone by the time the object itself
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// destructs.
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nassertv(_ref_count <= local_ref_count);
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// If this assertion fails, the reference counts are all screwed up
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// altogether. Maybe some errant code stomped all over memory somewhere.
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nassertv(_ref_count >= 0);
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// If this assertion fails, someone tried to delete this object while its
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// reference count was still positive. Maybe you tried to point a PointerTo
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// at a static object (a local variable, instead of one allocated via new)?
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// The test below against 0x7f is supposed to check for that, but it's a
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// pretty hokey test.
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// Another possibility is you inadvertently omitted a copy constructor for a
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// ReferenceCount object, and then bitwise copied a dynamically allocated
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// value--reference count and all--onto a locally allocated one.
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nassertv(_ref_count == 0 || _ref_count == local_ref_count);
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// Tell our weak reference holders that we're going away now.
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if (_weak_list != nullptr) {
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((WeakReferenceList *)_weak_list)->mark_deleted();
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_weak_list = nullptr;
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}
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#ifndef NDEBUG
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// Ok, all clear to delete. Now set the reference count to
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// deleted_ref_count, so we'll have a better chance of noticing if we happen
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// to have a stray pointer to it still out there.
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_ref_count = deleted_ref_count;
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#endif
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#ifdef DO_MEMORY_USAGE
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MemoryUsage::remove_pointer(this);
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#endif
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}
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/**
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* Returns the current reference count.
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*/
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INLINE int ReferenceCount::
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get_ref_count() const {
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#ifdef _DEBUG
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test_ref_count_integrity();
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#endif
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return (int)AtomicAdjust::get(_ref_count);
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}
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/**
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* Explicitly increments the reference count. User code should avoid using
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* ref() and unref() directly, which can result in missed reference counts.
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* Instead, let a PointerTo object manage the reference counting
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* automatically.
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*
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* This function is const, even though it changes the object, because
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* generally fiddling with an object's reference count isn't considered part
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* of fiddling with the object. An object might be const in other ways, but
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* we still need to accurately count the number of references to it.
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*/
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INLINE void ReferenceCount::
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ref() const {
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TAU_PROFILE("void ReferenceCount::ref()", " ", TAU_USER);
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#ifdef _DEBUG
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nassertv(test_ref_count_integrity());
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#endif
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AtomicAdjust::inc(_ref_count);
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}
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/**
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* Explicitly decrements the reference count. Note that the object will not
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* be implicitly deleted by unref() simply because the reference count drops
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* to zero. (Having a member function delete itself is problematic.) However,
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* see the helper function unref_delete().
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*
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* User code should avoid using ref() and unref() directly, which can result
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* in missed reference counts. Instead, let a PointerTo object manage the
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* reference counting automatically.
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*
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* This function is const, even though it changes the object, because
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* generally fiddling with an object's reference count isn't considered part
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* of fiddling with the object. An object might be const in other ways, but
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* we still need to accurately count the number of references to it.
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*
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* The return value is true if the new reference count is nonzero, false if it
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* is zero.
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*/
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INLINE bool ReferenceCount::
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unref() const {
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TAU_PROFILE("void ReferenceCount::unref()", " ", TAU_USER);
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#ifdef _DEBUG
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nassertr(test_ref_count_integrity(), 0);
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// If this assertion fails, you tried to unref an object with a zero
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// reference count. Are you using ref() and unref() directly? Are you sure
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// you can't use PointerTo's?
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nassertr(_ref_count > 0, 0);
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#endif
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return AtomicAdjust::dec(_ref_count);
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}
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/**
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* Does some easy checks to make sure that the reference count isn't
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* completely bogus. Returns true if ok, false otherwise.
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*/
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INLINE bool ReferenceCount::
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test_ref_count_integrity() const {
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#ifndef NDEBUG
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return do_test_ref_count_integrity();
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#else
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return true;
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#endif
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}
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/**
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* Does some easy checks to make sure that the reference count isn't zero, or
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* completely bogus. Returns true if ok, false otherwise.
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*/
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INLINE bool ReferenceCount::
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test_ref_count_nonzero() const {
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#ifndef NDEBUG
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return do_test_ref_count_nonzero();
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#else
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return true;
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#endif
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}
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/**
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* This function should be called, once, immediately after creating a new
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* instance of some ReferenceCount-derived object on the stack.
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*
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* This allows the object to be passed to functions that will increment and
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* decrement the object's reference count temporarily, and it will prevent the
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* object from being deleted (inappropriately), when the reference count
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* returns to zero. It actually achieves this by setting a large positive
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* value in the reference count field.
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*/
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INLINE void ReferenceCount::
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local_object() {
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// If this assertion fails, you didn't call this immediately after creating
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// a local object.
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nassertv(_ref_count == 0);
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_ref_count = local_ref_count;
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}
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/**
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* Returns true if this particular ReferenceCount object has a
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* WeakReferenceList created, false otherwise. In general, this will be true
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* if there was ever a WeakPointerTo created for this object (even if there is
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* not any for it now).
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*/
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INLINE bool ReferenceCount::
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has_weak_list() const {
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return _weak_list != nullptr;
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}
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/**
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* Returns the WeakReferenceList associated with this ReferenceCount object.
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* If there has never been a WeakReferenceList associated with this object,
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* creates one now.
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*
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* The returned object will be deleted automatically when all weak and strong
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* references to the object have gone.
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*/
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INLINE WeakReferenceList *ReferenceCount::
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get_weak_list() const {
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if (AtomicAdjust::get_ptr(_weak_list) == nullptr) {
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((ReferenceCount *)this)->create_weak_list();
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}
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return (WeakReferenceList *)AtomicAdjust::get_ptr(_weak_list);
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}
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/**
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* Adds the indicated PointerToVoid as a weak reference to this object.
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* Returns an object that will persist as long as any reference (strong or
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* weak) exists, for calling unref() or checking whether the object still
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* exists.
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*/
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INLINE WeakReferenceList *ReferenceCount::
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weak_ref() {
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TAU_PROFILE("void ReferenceCount::weak_ref()", " ", TAU_USER);
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#ifdef _DEBUG
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nassertr(test_ref_count_integrity(), nullptr);
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#else
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nassertr(_ref_count != deleted_ref_count, nullptr);
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#endif
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WeakReferenceList *weak_ref = get_weak_list();
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weak_ref->ref();
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return weak_ref;
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}
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/**
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* Removes the indicated PointerToVoid as a weak reference to this object. It
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* must have previously been added via a call to weak_ref().
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*/
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INLINE void ReferenceCount::
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weak_unref() {
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TAU_PROFILE("void ReferenceCount::weak_unref()", " ", TAU_USER);
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#ifdef _DEBUG
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nassertv(test_ref_count_integrity());
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#endif
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WeakReferenceList *weak_list = (WeakReferenceList *)_weak_list;
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nassertv(weak_list != nullptr);
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bool nonzero = weak_list->unref();
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nassertv(nonzero);
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}
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/**
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* Atomically increases the reference count of this object if it is not zero.
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* Do not use this. This exists only to implement a special case for weak
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* pointers.
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* @return true if the reference count was incremented, false if it was zero.
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*/
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INLINE bool ReferenceCount::
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ref_if_nonzero() const {
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#ifdef _DEBUG
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test_ref_count_integrity();
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#endif
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AtomicAdjust::Integer ref_count;
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do {
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ref_count = AtomicAdjust::get(_ref_count);
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if (ref_count <= 0) {
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return false;
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}
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} while (ref_count != AtomicAdjust::compare_and_exchange(_ref_count, ref_count, ref_count + 1));
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return true;
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}
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/**
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* This global helper function will unref the given ReferenceCount object, and
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* if the reference count reaches zero, automatically delete it. It can't be
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* a member function because it's usually a bad idea to delete an object from
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* within its own member function. It's a template function so the destructor
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* doesn't have to be virtual.
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*/
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template<class RefCountType>
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INLINE void
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unref_delete(RefCountType *ptr) {
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TAU_PROFILE("void unref_delete(RefCountType *)", " ", TAU_USER);
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// Although it may be tempting to try to upcast ptr to a ReferenceCount
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// object (particularly to get around inheritance issues), resist that
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// temptation, since some classes (in particular, TransformState and
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// RenderState) rely on a non-virtual overloading of the unref() method.
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if (!ptr->unref()) {
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// If the reference count has gone to zero, delete the object.
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delete ptr;
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}
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}
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/**
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*
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*/
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template<class Base>
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INLINE RefCountProxy<Base>::
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RefCountProxy() {
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}
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/**
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*
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*/
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template<class Base>
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INLINE RefCountProxy<Base>::
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RefCountProxy(const Base ©) : _base(copy) {
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}
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/**
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*
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*/
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template<class Base>
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INLINE RefCountProxy<Base>::
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operator Base &() {
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return _base;
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}
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/**
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*
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*/
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template<class Base>
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INLINE RefCountProxy<Base>::
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operator const Base &() const {
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return _base;
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}
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/**
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*
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*/
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template<class Base>
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void RefCountProxy<Base>::
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init_type() {
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do_init_type(Base);
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register_type(_type_handle,
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"RefCountProxy<" + get_type_handle(Base).get_name() + ">",
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get_type_handle(Base));
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}
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/**
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*
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*/
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template<class Base>
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INLINE RefCountObj<Base>::
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RefCountObj() {
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}
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/**
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*
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*/
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template<class Base>
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INLINE RefCountObj<Base>::
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RefCountObj(const Base ©) : Base(copy) {
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}
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/**
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*
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*/
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template<class Base>
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void RefCountObj<Base>::
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init_type() {
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#if defined(HAVE_RTTI) && !defined(__EDG__)
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// If we have RTTI, we can determine the name of the base type.
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std::string base_name = typeid(Base).name();
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#else
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std::string base_name = "unknown";
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#endif
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TypeHandle base_type = register_dynamic_type(base_name);
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ReferenceCount::init_type();
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_type_handle =
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register_dynamic_type("RefCountObj<" + base_name + ">",
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base_type, ReferenceCount::get_class_type());
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}
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