/** * PANDA 3D SOFTWARE * Copyright (c) Carnegie Mellon University. All rights reserved. * * All use of this software is subject to the terms of the revised BSD * license. You should have received a copy of this license along * with this source code in a file named "LICENSE." * * @file pipelineCyclerDummyImpl.I * @author drose * @date 2006-01-31 */ /** * */ INLINE PipelineCyclerDummyImpl:: PipelineCyclerDummyImpl(CycleData *initial_data, Pipeline *pipeline) : _data(initial_data), _pipeline(pipeline), _read_count(0), _write_count(0), _locked(false) { if (_pipeline == nullptr) { _pipeline = Pipeline::get_render_pipeline(); } } /** * */ INLINE PipelineCyclerDummyImpl:: PipelineCyclerDummyImpl(const PipelineCyclerDummyImpl ©) : _data(copy._data->make_copy()), _pipeline(copy._pipeline), _read_count(0), _write_count(0), _locked(false) { } /** * */ INLINE void PipelineCyclerDummyImpl:: operator = (const PipelineCyclerDummyImpl ©) { nassertv(_read_count == 0 && _write_count == 0); _data = copy._data->make_copy(); _pipeline = copy._pipeline; } /** * */ INLINE PipelineCyclerDummyImpl:: ~PipelineCyclerDummyImpl() { nassertv(_read_count == 0 && _write_count == 0 && !_locked); } /** * Grabs an overall lock on the cycler. Release it with a call to release(). * This lock should be held while walking the list of stages. */ INLINE void PipelineCyclerDummyImpl:: acquire(Thread *) { TAU_PROFILE("void PipelineCyclerDummyImpl::acquire(Thread *)", " ", TAU_USER); nassertv(!_locked); _locked = true; } /** * Release the overall lock on the cycler that was grabbed via acquire(). */ INLINE void PipelineCyclerDummyImpl:: release() { TAU_PROFILE("void PipelineCyclerDummyImpl::release()", " ", TAU_USER); nassertv(_locked); _locked = false; } /** * Returns a const CycleData pointer, filled with the data for the current * stage of the pipeline as seen by this thread. No lock is made on the * contents; there is no guarantee that some other thread won't modify this * object's data while you are working on it. (However, the data within the * returned CycleData object itself is safe from modification; if another * thread modifies the data, it will perform a copy-on-write, and thereby * change the pointer stored within the object.) */ INLINE const CycleData *PipelineCyclerDummyImpl:: read_unlocked(Thread *current_thread) const { TAU_PROFILE("const CycleData *PipelineCyclerDummyImpl::read_unlocked()", " ", TAU_USER); return _data; } /** * Returns a const CycleData pointer, filled with the data for the current * stage of the pipeline as seen by this thread. This pointer should * eventually be released by calling release_read(). * * There should be no outstanding write pointers on the data when this * function is called. */ INLINE const CycleData *PipelineCyclerDummyImpl:: read(Thread *) const { TAU_PROFILE("const CycleData *PipelineCyclerDummyImpl::read()", " ", TAU_USER); // This function isn't truly const, but it doesn't change the data in any // meaningful way, so we pretend it is. ((PipelineCyclerDummyImpl *)this)->_read_count++; // It's not an error to grab a read pointer while someone else holds a read // or a write pointer. return _data; } /** * Increments the count on a pointer previously retrieved by read(); now the * pointer will need to be released twice. */ INLINE void PipelineCyclerDummyImpl:: increment_read(const CycleData *pointer) const { TAU_PROFILE("void PipelineCyclerDummyImpl::increment_read(const CycleData *)", " ", TAU_USER); // This function isn't truly const, but it doesn't change the data in any // meaningful way, so we pretend it is. nassertv(pointer == _data); nassertv(_read_count > 0); ((PipelineCyclerDummyImpl *)this)->_read_count++; } /** * Releases a pointer previously obtained via a call to read(). */ INLINE void PipelineCyclerDummyImpl:: release_read(const CycleData *pointer) const { TAU_PROFILE("void PipelineCyclerDummyImpl::release_read(const CycleData *)", " ", TAU_USER); // This function isn't truly const, but it doesn't change the data in any // meaningful way, so we pretend it is. nassertv(pointer == _data); nassertv(_read_count > 0); ((PipelineCyclerDummyImpl *)this)->_read_count--; } /** * Returns a non-const CycleData pointer, filled with a unique copy of the * data for the current stage of the pipeline as seen by this thread. This * pointer may now be used to write to the data, and that copy of the data * will be propagated to all later stages of the pipeline. This pointer * should eventually be released by calling release_write(). * * There may only be one outstanding write pointer on a given stage at a time, * and if there is a write pointer there may be no read pointers on the same * stage (but see elevate_read). */ INLINE CycleData *PipelineCyclerDummyImpl:: write(Thread *current_thread) { TAU_PROFILE("CycleData *PipelineCyclerDummyImpl::write()", " ", TAU_USER); _write_count++; // It's an error to grab a write pointer while someone else holds a read // pointer, because doing so may invalidate the read pointer. nassertr(_read_count == 0, _data); // It's not an error to do this while someone else holds a write pointer, // however. return _data; } /** * This special variant on write() will automatically propagate changes back * to upstream pipeline stages. If force_to_0 is false, then it propagates * back only as long as the CycleData pointers are equivalent, guaranteeing * that it does not modify upstream data (other than the modification that * will be performed by the code that returns this pointer). This is * particularly appropriate for minor updates, where it doesn't matter much if * the update is lost, such as storing a cached value. * * If force_to_0 is dummy, then the CycleData pointer for the current pipeline * stage is propagated all the way back up to stage 0; after this call, there * will be only one CycleData pointer that is duplicated in all stages between * stage 0 and the current stage. This may undo some recent changes that were * made independently at pipeline stage 0 (or any other upstream stage). * However, it guarantees that the change that is to be applied at this * pipeline stage will stick. This is slightly dangerous because of the risk * of losing upstream changes; generally, this should only be done when you * are confident that there are no upstream changes to be lost (for instance, * for an object that has been recently created). */ CycleData *PipelineCyclerDummyImpl:: write_upstream(bool, Thread *) { TAU_PROFILE("CycleData *PipelineCyclerDummyImpl::write_upstream(bool)", " ", TAU_USER); _write_count++; return _data; } /** * Elevates a currently-held read pointer into a write pointer. This may or * may not change the value of the pointer. It is only valid to do this if * this is the only currently-outstanding read pointer on the current stage. */ INLINE CycleData *PipelineCyclerDummyImpl:: elevate_read(const CycleData *pointer, Thread *current_thread) { TAU_PROFILE("CycleData *PipelineCyclerDummyImpl::elevate_read(const CycleData *)", " ", TAU_USER); release_read(pointer); return write(current_thread); } /** * Elevates a currently-held read pointer into a write pointer, like * elevate_read(), but also propagates the pointer back to upstream stages, * like write_upstream(). */ INLINE CycleData *PipelineCyclerDummyImpl:: elevate_read_upstream(const CycleData *pointer, bool force_to_0, Thread *current_thread) { TAU_PROFILE("CycleData *PipelineCyclerDummyImpl::elevate_read_upstream(const CycleData *, bool)", " ", TAU_USER); release_read(pointer); return write_upstream(force_to_0, current_thread); } /** * Increments the count on a pointer previously retrieved by write(); now the * pointer will need to be released twice. */ INLINE void PipelineCyclerDummyImpl:: increment_write(CycleData *pointer) const { TAU_PROFILE("void PipelineCyclerDummyImpl::increment_write(CycleData *)", " ", TAU_USER); // This function isn't truly const, but it doesn't change the data in any // meaningful way, so we pretend it is. nassertv(pointer == _data); nassertv(_write_count > 0); ((PipelineCyclerDummyImpl *)this)->_write_count++; } /** * Releases a pointer previously obtained via a call to write(). */ INLINE void PipelineCyclerDummyImpl:: release_write(CycleData *pointer) { TAU_PROFILE("void PipelineCyclerDummyImpl::release_write(CycleData *)", " ", TAU_USER); nassertv(pointer == _data); nassertv(_write_count > 0); _write_count--; } /** * Returns the number of stages in the pipeline. */ INLINE int PipelineCyclerDummyImpl:: get_num_stages() { return 1; } /** * Returns a const CycleData pointer, filled with the data for the indicated * stage of the pipeline. As in read_unlocked(), no lock is held on the * returned pointer. */ INLINE const CycleData *PipelineCyclerDummyImpl:: read_stage_unlocked(int pipeline_stage) const { TAU_PROFILE("const CycleData *PipelineCyclerDummyImpl::read_stage_unlocked(int)", " ", TAU_USER); nassertr(pipeline_stage == 0, nullptr); return _data; } /** * Returns a const CycleData pointer, filled with the data for the indicated * stage of the pipeline. This pointer should eventually be released by * calling release_read_stage(). * * There should be no outstanding write pointers on the data when this * function is called. */ INLINE const CycleData *PipelineCyclerDummyImpl:: read_stage(int pipeline_stage, Thread *) const { TAU_PROFILE("const CycleData *PipelineCyclerDummyImpl::read_stage(int, Thread *)", " ", TAU_USER); // This function isn't truly const, but it doesn't change the data in any // meaningful way, so we pretend it is. nassertr(pipeline_stage == 0, nullptr); ((PipelineCyclerDummyImpl *)this)->_read_count++; // It's not an error to grab a read pointer while someone else holds a read // or a write pointer. return _data; } /** * Releases a pointer previously obtained via a call to read_stage(). */ INLINE void PipelineCyclerDummyImpl:: release_read_stage(int pipeline_stage, const CycleData *pointer) const { TAU_PROFILE("void PipelineCyclerDummyImpl::release_read_stage(int, const CycleData *)", " ", TAU_USER); // This function isn't truly const, but it doesn't change the data in any // meaningful way, so we pretend it is. nassertv(pipeline_stage == 0); nassertv(pointer == _data); nassertv(_read_count > 0); ((PipelineCyclerDummyImpl *)this)->_read_count--; } /** * Returns a pointer suitable for writing to the nth stage of the pipeline. * This is for special applications that need to update the entire pipeline at * once (for instance, to remove an invalid pointer). This pointer should * later be released with release_write_stage(). */ INLINE CycleData *PipelineCyclerDummyImpl:: write_stage(int pipeline_stage, Thread *) { TAU_PROFILE("CycleData *PipelineCyclerDummyImpl::write_stage(int)", " ", TAU_USER); nassertr(pipeline_stage == 0, nullptr); _write_count++; return _data; } /** * Returns a pointer suitable for writing to the nth stage of the pipeline. * This is for special applications that need to update the entire pipeline at * once (for instance, to remove an invalid pointer). This pointer should * later be released with release_write_stage(). */ INLINE CycleData *PipelineCyclerDummyImpl:: write_stage_upstream(int pipeline_stage, bool, Thread *) { TAU_PROFILE("CycleData *PipelineCyclerDummyImpl::write_stage_upstream(int)", " ", TAU_USER); nassertr(pipeline_stage == 0, nullptr); _write_count++; return _data; } /** * Elevates a currently-held read pointer into a write pointer. This may or * may not change the value of the pointer. It is only valid to do this if * this is the only currently-outstanding read pointer on the current stage. */ INLINE CycleData *PipelineCyclerDummyImpl:: elevate_read_stage(int pipeline_stage, const CycleData *pointer, Thread *current_thread) { TAU_PROFILE("CycleData *PipelineCyclerDummyImpl::elevate_read_stage(int, CycleData *)", " ", TAU_USER); nassertr(pipeline_stage == 0, nullptr); release_read(pointer); return write(current_thread); } /** * Elevates a currently-held read pointer into a write pointer. This may or * may not change the value of the pointer. It is only valid to do this if * this is the only currently-outstanding read pointer on the current stage. */ INLINE CycleData *PipelineCyclerDummyImpl:: elevate_read_stage_upstream(int pipeline_stage, const CycleData *pointer, bool, Thread *current_thread) { TAU_PROFILE("CycleData *PipelineCyclerDummyImpl::elevate_read_stage(int, CycleData *)", " ", TAU_USER); nassertr(pipeline_stage == 0, nullptr); release_read(pointer); return write(current_thread); } /** * Releases a pointer previously obtained via a call to write_stage(). */ INLINE void PipelineCyclerDummyImpl:: release_write_stage(int pipeline_stage, CycleData *pointer) { TAU_PROFILE("void PipelineCyclerDummyImpl::release_write_stage(int, CycleData *)", " ", TAU_USER); nassertv(pipeline_stage == 0 && pointer == _data); nassertv(_write_count > 0); _write_count--; } /** * Returns the type of object that owns this cycler, as reported by * CycleData::get_parent_type(). */ INLINE TypeHandle PipelineCyclerDummyImpl:: get_parent_type() const { return _data->get_parent_type(); } /** * Returns a pointer without counting it. This is only intended for use as * the return value for certain nassertr() functions, so the application can * recover after a failure to manage the read and write pointers correctly. * You should never call this function directly. */ INLINE CycleData *PipelineCyclerDummyImpl:: cheat() const { return _data; } /** * Returns the number of handles currently outstanding to read the current * stage of the data. This should only be used for debugging purposes. */ INLINE int PipelineCyclerDummyImpl:: get_read_count() const { return _read_count; } /** * Returns the number of handles currently outstanding to read the current * stage of the data. This will normally only be either 0 or 1. This should * only be used for debugging purposes. */ INLINE int PipelineCyclerDummyImpl:: get_write_count() const { return _write_count; }