void sweep(){ // puts( "bbGC::sweep()" );fflush( stdout ); markFrames(); markQueued(); if( unmarkedList->succ!=unmarkedList ){ //append unmarked to end of free queue unmarkedList->succ->pred=freeList.pred; unmarkedList->pred->succ=&freeList; freeList.pred->succ=unmarkedList->succ; freeList.pred=unmarkedList->pred; //clear unmarkedmpor unmarkedList->succ=unmarkedList->pred=unmarkedList; } std::swap( markedList,unmarkedList ); std::swap( markedBit,unmarkedBit ); unmarkedBytes=markedBytes; markedBytes=0; allocedBytes=0; markRoots(); }
void Heap::collect(SweepToggle sweepToggle) { ASSERT(globalData()->identifierTable == wtfThreadData().currentIdentifierTable()); JAVASCRIPTCORE_GC_BEGIN(); markRoots(); m_handleHeap.finalizeWeakHandles(); m_globalData->smallStrings.finalizeSmallStrings(); JAVASCRIPTCORE_GC_MARKED(); resetAllocator(); #if ENABLE(JSC_ZOMBIES) sweepToggle = DoSweep; #endif if (sweepToggle == DoSweep) { sweep(); shrink(); } // To avoid pathological GC churn in large heaps, we set the allocation high // water mark to be proportional to the current size of the heap. The exact // proportion is a bit arbitrary. A 2X multiplier gives a 1:1 (heap size : // new bytes allocated) proportion, and seems to work well in benchmarks. size_t proportionalBytes = 2 * size(); m_newSpace.setHighWaterMark(max(proportionalBytes, minBytesPerCycle)); JAVASCRIPTCORE_GC_END(); (*m_activityCallback)(); }
void Heap::collect(SweepToggle sweepToggle) { GCPHASE(Collect); ASSERT(globalData()->identifierTable == wtfThreadData().currentIdentifierTable()); ASSERT(m_isSafeToCollect); JAVASCRIPTCORE_GC_BEGIN(); #if ENABLE(GGC) bool fullGC = sweepToggle == DoSweep; if (!fullGC) fullGC = (capacity() > 4 * m_lastFullGCSize); #else bool fullGC = true; #endif { GCPHASE(Canonicalize); canonicalizeCellLivenessData(); } markRoots(fullGC); { GCPHASE(HarvestWeakReferences); harvestWeakReferences(); m_handleHeap.finalizeWeakHandles(); m_globalData->smallStrings.finalizeSmallStrings(); } JAVASCRIPTCORE_GC_MARKED(); { GCPHASE(ResetAllocator); resetAllocator(); } if (sweepToggle == DoSweep) { GCPHASE(Sweeping); sweep(); shrink(); } // To avoid pathological GC churn in large heaps, we set the allocation high // water mark to be proportional to the current size of the heap. The exact // proportion is a bit arbitrary. A 2X multiplier gives a 1:1 (heap size : // new bytes allocated) proportion, and seems to work well in benchmarks. size_t newSize = size(); size_t proportionalBytes = 2 * newSize; if (fullGC) { m_lastFullGCSize = newSize; m_objectSpace.setHighWaterMark(max(proportionalBytes, m_minBytesPerCycle)); } JAVASCRIPTCORE_GC_END(); (*m_activityCallback)(); }
void Heap::collect(SweepToggle sweepToggle) { #if ENABLE(ALLOCATION_LOGGING) dataLogF("JSC GC starting collection.\n"); #endif double before = 0; if (Options::logGC()) { dataLog("[GC", sweepToggle == DoSweep ? " (eager sweep)" : "", ": "); before = currentTimeMS(); } SamplingRegion samplingRegion("Garbage Collection"); RELEASE_ASSERT(!m_deferralDepth); GCPHASE(Collect); ASSERT(vm()->currentThreadIsHoldingAPILock()); RELEASE_ASSERT(vm()->identifierTable == wtfThreadData().currentIdentifierTable()); ASSERT(m_isSafeToCollect); JAVASCRIPTCORE_GC_BEGIN(); RELEASE_ASSERT(m_operationInProgress == NoOperation); m_deferralDepth++; // Make sure that we don't GC in this call. m_vm->prepareToDiscardCode(); m_deferralDepth--; // Decrement deferal manually, so we don't GC when we do so, since we are already GCing!. m_operationInProgress = Collection; m_extraMemoryUsage = 0; if (m_activityCallback) m_activityCallback->willCollect(); double lastGCStartTime = WTF::monotonicallyIncreasingTime(); if (lastGCStartTime - m_lastCodeDiscardTime > minute) { deleteAllCompiledCode(); m_lastCodeDiscardTime = WTF::monotonicallyIncreasingTime(); } { GCPHASE(StopAllocation); m_objectSpace.stopAllocating(); } markRoots(); { GCPHASE(ReapingWeakHandles); m_objectSpace.reapWeakSets(); } JAVASCRIPTCORE_GC_MARKED(); { GCPHASE(SweepingArrayBuffers); m_arrayBuffers.sweep(); } { m_blockSnapshot.resize(m_objectSpace.blocks().set().size()); MarkedBlockSnapshotFunctor functor(m_blockSnapshot); m_objectSpace.forEachBlock(functor); } copyBackingStores(); { GCPHASE(FinalizeUnconditionalFinalizers); finalizeUnconditionalFinalizers(); } { GCPHASE(DeleteCodeBlocks); deleteUnmarkedCompiledCode(); } { GCPHASE(DeleteSourceProviderCaches); m_vm->clearSourceProviderCaches(); } if (sweepToggle == DoSweep) { SamplingRegion samplingRegion("Garbage Collection: Sweeping"); GCPHASE(Sweeping); m_objectSpace.sweep(); m_objectSpace.shrink(); } m_sweeper->startSweeping(m_blockSnapshot); m_bytesAbandoned = 0; { GCPHASE(ResetAllocators); m_objectSpace.resetAllocators(); } size_t currentHeapSize = sizeAfterCollect(); if (Options::gcMaxHeapSize() && currentHeapSize > Options::gcMaxHeapSize()) HeapStatistics::exitWithFailure(); m_sizeAfterLastCollect = currentHeapSize; // To avoid pathological GC churn in very small and very large heaps, we set // the new allocation limit based on the current size of the heap, with a // fixed minimum. size_t maxHeapSize = max(minHeapSize(m_heapType, m_ramSize), proportionalHeapSize(currentHeapSize, m_ramSize)); m_bytesAllocatedLimit = maxHeapSize - currentHeapSize; m_bytesAllocated = 0; double lastGCEndTime = WTF::monotonicallyIncreasingTime(); m_lastGCLength = lastGCEndTime - lastGCStartTime; if (Options::recordGCPauseTimes()) HeapStatistics::recordGCPauseTime(lastGCStartTime, lastGCEndTime); RELEASE_ASSERT(m_operationInProgress == Collection); m_operationInProgress = NoOperation; JAVASCRIPTCORE_GC_END(); if (Options::useZombieMode()) zombifyDeadObjects(); if (Options::objectsAreImmortal()) markDeadObjects(); if (Options::showObjectStatistics()) HeapStatistics::showObjectStatistics(this); if (Options::logGC()) { double after = currentTimeMS(); dataLog(after - before, " ms, ", currentHeapSize / 1024, " kb]\n"); } #if ENABLE(ALLOCATION_LOGGING) dataLogF("JSC GC finishing collection.\n"); #endif }
void Heap::collect(SweepToggle sweepToggle) { SamplingRegion samplingRegion("Garbage Collection"); GCPHASE(Collect); ASSERT(globalData()->apiLock().currentThreadIsHoldingLock()); RELEASE_ASSERT(globalData()->identifierTable == wtfThreadData().currentIdentifierTable()); ASSERT(m_isSafeToCollect); JAVASCRIPTCORE_GC_BEGIN(); RELEASE_ASSERT(m_operationInProgress == NoOperation); m_operationInProgress = Collection; m_activityCallback->willCollect(); double lastGCStartTime = WTF::currentTime(); if (lastGCStartTime - m_lastCodeDiscardTime > minute) { deleteAllCompiledCode(); m_lastCodeDiscardTime = WTF::currentTime(); } { GCPHASE(Canonicalize); m_objectSpace.canonicalizeCellLivenessData(); } markRoots(); { GCPHASE(ReapingWeakHandles); m_objectSpace.reapWeakSets(); } JAVASCRIPTCORE_GC_MARKED(); { m_blockSnapshot.resize(m_objectSpace.blocks().set().size()); MarkedBlockSnapshotFunctor functor(m_blockSnapshot); m_objectSpace.forEachBlock(functor); } copyBackingStores(); { GCPHASE(FinalizeUnconditionalFinalizers); finalizeUnconditionalFinalizers(); } { GCPHASE(finalizeSmallStrings); m_globalData->smallStrings.finalizeSmallStrings(); } { GCPHASE(DeleteCodeBlocks); deleteUnmarkedCompiledCode(); } { GCPHASE(DeleteSourceProviderCaches); m_globalData->clearSourceProviderCaches(); } if (sweepToggle == DoSweep) { SamplingRegion samplingRegion("Garbage Collection: Sweeping"); GCPHASE(Sweeping); m_objectSpace.sweep(); m_objectSpace.shrink(); } m_sweeper->startSweeping(m_blockSnapshot); m_bytesAbandoned = 0; { GCPHASE(ResetAllocators); m_objectSpace.resetAllocators(); } size_t currentHeapSize = size(); if (Options::gcMaxHeapSize() && currentHeapSize > Options::gcMaxHeapSize()) HeapStatistics::exitWithFailure(); m_sizeAfterLastCollect = currentHeapSize; // To avoid pathological GC churn in very small and very large heaps, we set // the new allocation limit based on the current size of the heap, with a // fixed minimum. size_t maxHeapSize = max(minHeapSize(m_heapType, m_ramSize), proportionalHeapSize(currentHeapSize, m_ramSize)); m_bytesAllocatedLimit = maxHeapSize - currentHeapSize; m_bytesAllocated = 0; double lastGCEndTime = WTF::currentTime(); m_lastGCLength = lastGCEndTime - lastGCStartTime; if (Options::recordGCPauseTimes()) HeapStatistics::recordGCPauseTime(lastGCStartTime, lastGCEndTime); RELEASE_ASSERT(m_operationInProgress == Collection); m_operationInProgress = NoOperation; JAVASCRIPTCORE_GC_END(); if (Options::useZombieMode()) zombifyDeadObjects(); if (Options::objectsAreImmortal()) markDeadObjects(); if (Options::showObjectStatistics()) HeapStatistics::showObjectStatistics(this); }
void Heap::collect(SweepToggle sweepToggle) { SamplingRegion samplingRegion("Garbage Collection"); GCPHASE(Collect); ASSERT(globalData()->identifierTable == wtfThreadData().currentIdentifierTable()); ASSERT(m_isSafeToCollect); JAVASCRIPTCORE_GC_BEGIN(); m_activityCallback->willCollect(); double lastGCStartTime = WTF::currentTime(); if (lastGCStartTime - m_lastCodeDiscardTime > minute) { discardAllCompiledCode(); m_lastCodeDiscardTime = WTF::currentTime(); } #if ENABLE(GGC) bool fullGC = sweepToggle == DoSweep; if (!fullGC) fullGC = (capacity() > 4 * m_sizeAfterLastCollect); #else bool fullGC = true; #endif { GCPHASE(Canonicalize); canonicalizeCellLivenessData(); } markRoots(fullGC); { GCPHASE(FinalizeUnconditionalFinalizers); finalizeUnconditionalFinalizers(); } { GCPHASE(FinalizeWeakHandles); m_weakSet.sweep(); m_globalData->smallStrings.finalizeSmallStrings(); } JAVASCRIPTCORE_GC_MARKED(); { GCPHASE(ResetAllocator); resetAllocators(); } { GCPHASE(DeleteCodeBlocks); m_dfgCodeBlocks.deleteUnmarkedJettisonedCodeBlocks(); } if (sweepToggle == DoSweep) { SamplingRegion samplingRegion("Garbage Collection: Sweeping"); GCPHASE(Sweeping); sweep(); m_objectSpace.shrink(); m_weakSet.shrink(); } // To avoid pathological GC churn in large heaps, we set the new allocation // limit to be the current size of the heap. This heuristic // is a bit arbitrary. Using the current size of the heap after this // collection gives us a 2X multiplier, which is a 1:1 (heap size : // new bytes allocated) proportion, and seems to work well in benchmarks. size_t newSize = size(); if (fullGC) { m_sizeAfterLastCollect = newSize; m_bytesAllocatedLimit = max(newSize, m_minBytesPerCycle); } m_bytesAllocated = 0; double lastGCEndTime = WTF::currentTime(); m_lastGCLength = lastGCEndTime - lastGCStartTime; JAVASCRIPTCORE_GC_END(); }
NEVER_INLINE void Heap::collectImpl(HeapOperation collectionType, void* stackOrigin, void* stackTop, MachineThreads::RegisterState& calleeSavedRegisters) { #if ENABLE(ALLOCATION_LOGGING) dataLogF("JSC GC starting collection.\n"); #endif double before = 0; if (Options::logGC()) { dataLog("[GC: "); before = currentTimeMS(); } SamplingRegion samplingRegion("Garbage Collection"); if (vm()->typeProfiler()) { DeferGCForAWhile awhile(*this); vm()->typeProfilerLog()->processLogEntries(ASCIILiteral("GC")); } RELEASE_ASSERT(!m_deferralDepth); ASSERT(vm()->currentThreadIsHoldingAPILock()); RELEASE_ASSERT(vm()->atomicStringTable() == wtfThreadData().atomicStringTable()); ASSERT(m_isSafeToCollect); JAVASCRIPTCORE_GC_BEGIN(); RELEASE_ASSERT(m_operationInProgress == NoOperation); suspendCompilerThreads(); willStartCollection(collectionType); GCPHASE(Collect); double gcStartTime = WTF::monotonicallyIncreasingTime(); if (m_verifier) { // Verify that live objects from the last GC cycle haven't been corrupted by // mutators before we begin this new GC cycle. m_verifier->verify(HeapVerifier::Phase::BeforeGC); m_verifier->initializeGCCycle(); m_verifier->gatherLiveObjects(HeapVerifier::Phase::BeforeMarking); } flushOldStructureIDTables(); stopAllocation(); flushWriteBarrierBuffer(); markRoots(gcStartTime, stackOrigin, stackTop, calleeSavedRegisters); if (m_verifier) { m_verifier->gatherLiveObjects(HeapVerifier::Phase::AfterMarking); m_verifier->verify(HeapVerifier::Phase::AfterMarking); } JAVASCRIPTCORE_GC_MARKED(); if (vm()->typeProfiler()) vm()->typeProfiler()->invalidateTypeSetCache(); reapWeakHandles(); pruneStaleEntriesFromWeakGCMaps(); sweepArrayBuffers(); snapshotMarkedSpace(); copyBackingStores(); finalizeUnconditionalFinalizers(); removeDeadCompilerWorklistEntries(); deleteUnmarkedCompiledCode(); deleteSourceProviderCaches(); notifyIncrementalSweeper(); rememberCurrentlyExecutingCodeBlocks(); resetAllocators(); updateAllocationLimits(); didFinishCollection(gcStartTime); resumeCompilerThreads(); if (m_verifier) { m_verifier->trimDeadObjects(); m_verifier->verify(HeapVerifier::Phase::AfterGC); } if (Options::logGC()) { double after = currentTimeMS(); dataLog(after - before, " ms]\n"); } }