/* * Copyright 2011 Google Inc. * * Use of this source code is governed by a BSD-style license that can be * found in the LICENSE file. */ #include "GrGpuResource.h" #include "GrContext.h" #include "GrResourceCache.h" #include "GrGpu.h" #include "GrGpuResourcePriv.h" #include "SkTraceMemoryDump.h" static inline GrResourceCache* get_resource_cache(GrGpu* gpu) { SkASSERT(gpu); SkASSERT(gpu->getContext()); SkASSERT(gpu->getContext()->getResourceCache()); return gpu->getContext()->getResourceCache(); } GrGpuResource::GrGpuResource(GrGpu* gpu) : fExternalFlushCntWhenBecamePurgeable(0) , fGpu(gpu) , fGpuMemorySize(kInvalidGpuMemorySize) , fBudgeted(SkBudgeted::kNo) , fRefsWrappedObjects(false) , fUniqueID(CreateUniqueID()) { SkDEBUGCODE(fCacheArrayIndex = -1); } void GrGpuResource::registerWithCache(SkBudgeted budgeted) { SkASSERT(fBudgeted == SkBudgeted::kNo); fBudgeted = budgeted; this->computeScratchKey(&fScratchKey); get_resource_cache(fGpu)->resourceAccess().insertResource(this); } void GrGpuResource::registerWithCacheWrapped() { SkASSERT(fBudgeted == SkBudgeted::kNo); // Currently resources referencing wrapped objects are not budgeted. fRefsWrappedObjects = true; get_resource_cache(fGpu)->resourceAccess().insertResource(this); } GrGpuResource::~GrGpuResource() { // The cache should have released or destroyed this resource. SkASSERT(this->wasDestroyed()); } void GrGpuResource::release() { SkASSERT(fGpu); this->onRelease(); get_resource_cache(fGpu)->resourceAccess().removeResource(this); fGpu = nullptr; fGpuMemorySize = 0; } void GrGpuResource::abandon() { if (this->wasDestroyed()) { return; } SkASSERT(fGpu); this->onAbandon(); get_resource_cache(fGpu)->resourceAccess().removeResource(this); fGpu = nullptr; fGpuMemorySize = 0; } void GrGpuResource::dumpMemoryStatistics(SkTraceMemoryDump* traceMemoryDump) const { // Dump resource as "skia/gpu_resources/resource_#". SkString dumpName("skia/gpu_resources/resource_"); dumpName.appendS32(this->uniqueID()); traceMemoryDump->dumpNumericValue(dumpName.c_str(), "size", "bytes", this->gpuMemorySize()); if (this->isPurgeable()) { traceMemoryDump->dumpNumericValue(dumpName.c_str(), "purgeable_size", "bytes", this->gpuMemorySize()); } // Call setMemoryBacking to allow sub-classes with implementation specific backings (such as GL // objects) to provide additional information. this->setMemoryBacking(traceMemoryDump, dumpName); } const GrContext* GrGpuResource::getContext() const { if (fGpu) { return fGpu->getContext(); } else { return nullptr; } } GrContext* GrGpuResource::getContext() { if (fGpu) { return fGpu->getContext(); } else { return nullptr; } } void GrGpuResource::didChangeGpuMemorySize() const { if (this->wasDestroyed()) { return; } size_t oldSize = fGpuMemorySize; SkASSERT(kInvalidGpuMemorySize != oldSize); fGpuMemorySize = kInvalidGpuMemorySize; get_resource_cache(fGpu)->resourceAccess().didChangeGpuMemorySize(this, oldSize); } void GrGpuResource::removeUniqueKey() { if (this->wasDestroyed()) { return; } SkASSERT(fUniqueKey.isValid()); get_resource_cache(fGpu)->resourceAccess().removeUniqueKey(this); } void GrGpuResource::setUniqueKey(const GrUniqueKey& key) { SkASSERT(this->internalHasRef()); SkASSERT(key.isValid()); // Wrapped and uncached resources can never have a unique key. if (SkBudgeted::kNo == this->resourcePriv().isBudgeted()) { return; } if (this->wasDestroyed()) { return; } get_resource_cache(fGpu)->resourceAccess().changeUniqueKey(this, key); } void GrGpuResource::notifyAllCntsAreZero(CntType lastCntTypeToReachZero) const { if (this->wasDestroyed()) { // We've already been removed from the cache. Goodbye cruel world! delete this; return; } // We should have already handled this fully in notifyRefCntIsZero(). SkASSERT(kRef_CntType != lastCntTypeToReachZero); GrGpuResource* mutableThis = const_cast(this); static const uint32_t kFlag = GrResourceCache::ResourceAccess::kAllCntsReachedZero_RefNotificationFlag; get_resource_cache(fGpu)->resourceAccess().notifyCntReachedZero(mutableThis, kFlag); } bool GrGpuResource::notifyRefCountIsZero() const { if (this->wasDestroyed()) { // handle this in notifyAllCntsAreZero(). return true; } GrGpuResource* mutableThis = const_cast(this); uint32_t flags = GrResourceCache::ResourceAccess::kRefCntReachedZero_RefNotificationFlag; if (!this->internalHasPendingIO()) { flags |= GrResourceCache::ResourceAccess::kAllCntsReachedZero_RefNotificationFlag; } get_resource_cache(fGpu)->resourceAccess().notifyCntReachedZero(mutableThis, flags); // There is no need to call our notifyAllCntsAreZero function at this point since we already // told the cache about the state of cnts. return false; } void GrGpuResource::removeScratchKey() { if (!this->wasDestroyed() && fScratchKey.isValid()) { get_resource_cache(fGpu)->resourceAccess().willRemoveScratchKey(this); fScratchKey.reset(); } } void GrGpuResource::makeBudgeted() { if (!this->wasDestroyed() && SkBudgeted::kNo == fBudgeted) { // Currently resources referencing wrapped objects are not budgeted. SkASSERT(!fRefsWrappedObjects); fBudgeted = SkBudgeted::kYes; get_resource_cache(fGpu)->resourceAccess().didChangeBudgetStatus(this); } } void GrGpuResource::makeUnbudgeted() { if (!this->wasDestroyed() && SkBudgeted::kYes == fBudgeted && !fUniqueKey.isValid()) { fBudgeted = SkBudgeted::kNo; get_resource_cache(fGpu)->resourceAccess().didChangeBudgetStatus(this); } } uint32_t GrGpuResource::CreateUniqueID() { static int32_t gUniqueID = SK_InvalidUniqueID; uint32_t id; do { id = static_cast(sk_atomic_inc(&gUniqueID) + 1); } while (id == SK_InvalidUniqueID); return id; }