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/*
* Copyright (C) 2013-2018 Apple Inc. All rights reserved.
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions
* are met:
* 1. Redistributions of source code must retain the above copyright
* notice, this list of conditions and the following disclaimer.
* 2. Redistributions in binary form must reproduce the above copyright
* notice, this list of conditions and the following disclaimer in the
* documentation and/or other materials provided with the distribution.
*
* THIS SOFTWARE IS PROVIDED BY APPLE INC. ``AS IS'' AND ANY
* EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
* IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR
* PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL APPLE INC. OR
* CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL,
* EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO,
* PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR
* PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY
* OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
* (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE
* OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
*/
#include "config.h"
#include "DFGPlan.h"
#if ENABLE(DFG_JIT)
#include "DFGArgumentsEliminationPhase.h"
#include "DFGBackwardsPropagationPhase.h"
#include "DFGByteCodeParser.h"
#include "DFGCFAPhase.h"
#include "DFGCFGSimplificationPhase.h"
#include "DFGCPSRethreadingPhase.h"
#include "DFGCSEPhase.h"
#include "DFGCleanUpPhase.h"
#include "DFGConstantFoldingPhase.h"
#include "DFGConstantHoistingPhase.h"
#include "DFGCriticalEdgeBreakingPhase.h"
#include "DFGDCEPhase.h"
#include "DFGFailedFinalizer.h"
#include "DFGFixupPhase.h"
#include "DFGGraphSafepoint.h"
#include "DFGIntegerCheckCombiningPhase.h"
#include "DFGIntegerRangeOptimizationPhase.h"
#include "DFGInvalidationPointInjectionPhase.h"
#include "DFGJITCompiler.h"
#include "DFGLICMPhase.h"
#include "DFGLiveCatchVariablePreservationPhase.h"
#include "DFGLivenessAnalysisPhase.h"
#include "DFGLoopPreHeaderCreationPhase.h"
#include "DFGMaximalFlushInsertionPhase.h"
#include "DFGMovHintRemovalPhase.h"
#include "DFGOSRAvailabilityAnalysisPhase.h"
#include "DFGOSREntrypointCreationPhase.h"
#include "DFGObjectAllocationSinkingPhase.h"
#include "DFGPhantomInsertionPhase.h"
#include "DFGPredictionInjectionPhase.h"
#include "DFGPredictionPropagationPhase.h"
#include "DFGPutStackSinkingPhase.h"
#include "DFGSSAConversionPhase.h"
#include "DFGSSALoweringPhase.h"
#include "DFGStackLayoutPhase.h"
#include "DFGStaticExecutionCountEstimationPhase.h"
#include "DFGStoreBarrierClusteringPhase.h"
#include "DFGStoreBarrierInsertionPhase.h"
#include "DFGStrengthReductionPhase.h"
#include "DFGTierUpCheckInjectionPhase.h"
#include "DFGTypeCheckHoistingPhase.h"
#include "DFGUnificationPhase.h"
#include "DFGValidate.h"
#include "DFGValueRepReductionPhase.h"
#include "DFGVarargsForwardingPhase.h"
#include "DFGVirtualRegisterAllocationPhase.h"
#include "DFGWatchpointCollectionPhase.h"
#include "JSCInlines.h"
#include "OperandsInlines.h"
#include "ProfilerDatabase.h"
#include "TrackedReferences.h"
#include "VMInlines.h"
#if ENABLE(FTL_JIT)
#include "FTLCapabilities.h"
#include "FTLCompile.h"
#include "FTLFail.h"
#include "FTLLink.h"
#include "FTLLowerDFGToB3.h"
#include "FTLState.h"
#endif
namespace JSC {
extern Seconds totalDFGCompileTime;
extern Seconds totalFTLCompileTime;
extern Seconds totalFTLDFGCompileTime;
extern Seconds totalFTLB3CompileTime;
}
namespace JSC { namespace DFG {
namespace {
void dumpAndVerifyGraph(Graph& graph, const char* text, bool forceDump = false)
{
GraphDumpMode modeForFinalValidate = DumpGraph;
if (verboseCompilationEnabled(graph.m_plan.mode()) || forceDump) {
dataLog(text, "\n");
graph.dump();
modeForFinalValidate = DontDumpGraph;
}
if (validationEnabled())
validate(graph, modeForFinalValidate);
}
Profiler::CompilationKind profilerCompilationKindForMode(CompilationMode mode)
{
switch (mode) {
case InvalidCompilationMode:
RELEASE_ASSERT_NOT_REACHED();
return Profiler::DFG;
case DFGMode:
return Profiler::DFG;
case FTLMode:
return Profiler::FTL;
case FTLForOSREntryMode:
return Profiler::FTLForOSREntry;
}
RELEASE_ASSERT_NOT_REACHED();
return Profiler::DFG;
}
} // anonymous namespace
Plan::Plan(CodeBlock* passedCodeBlock, CodeBlock* profiledDFGCodeBlock,
CompilationMode mode, unsigned osrEntryBytecodeIndex,
const Operands<Optional<JSValue>>& mustHandleValues)
: m_mode(mode)
, m_vm(passedCodeBlock->vm())
, m_codeBlock(passedCodeBlock)
, m_profiledDFGCodeBlock(profiledDFGCodeBlock)
, m_mustHandleValues(mustHandleValues)
, m_osrEntryBytecodeIndex(osrEntryBytecodeIndex)
, m_compilation(UNLIKELY(m_vm->m_perBytecodeProfiler) ? adoptRef(new Profiler::Compilation(m_vm->m_perBytecodeProfiler->ensureBytecodesFor(m_codeBlock), profilerCompilationKindForMode(mode))) : nullptr)
, m_inlineCallFrames(adoptRef(new InlineCallFrameSet()))
, m_identifiers(m_codeBlock)
, m_weakReferences(m_codeBlock)
, m_stage(Preparing)
{
RELEASE_ASSERT(m_codeBlock->alternative()->jitCode());
}
Plan::~Plan()
{
}
bool Plan::computeCompileTimes() const
{
return reportCompileTimes()
|| Options::reportTotalCompileTimes()
|| (m_vm && m_vm->m_perBytecodeProfiler);
}
bool Plan::reportCompileTimes() const
{
return Options::reportCompileTimes()
|| Options::reportDFGCompileTimes()
|| (Options::reportFTLCompileTimes() && isFTL());
}
void Plan::compileInThread(ThreadData* threadData)
{
m_threadData = threadData;
MonotonicTime before { };
CString codeBlockName;
if (UNLIKELY(computeCompileTimes()))
before = MonotonicTime::now();
if (UNLIKELY(reportCompileTimes()))
codeBlockName = toCString(*m_codeBlock);
CompilationScope compilationScope;
if (logCompilationChanges(m_mode) || Options::logPhaseTimes())
dataLog("DFG(Plan) compiling ", *m_codeBlock, " with ", m_mode, ", instructions size = ", m_codeBlock->instructionsSize(), "\n");
CompilationPath path = compileInThreadImpl();
RELEASE_ASSERT(path == CancelPath || m_finalizer);
RELEASE_ASSERT((path == CancelPath) == (m_stage == Cancelled));
MonotonicTime after { };
if (UNLIKELY(computeCompileTimes())) {
after = MonotonicTime::now();
if (Options::reportTotalCompileTimes()) {
if (isFTL()) {
totalFTLCompileTime += after - before;
totalFTLDFGCompileTime += m_timeBeforeFTL - before;
totalFTLB3CompileTime += after - m_timeBeforeFTL;
} else
totalDFGCompileTime += after - before;
}
}
const char* pathName = nullptr;
switch (path) {
case FailPath:
pathName = "N/A (fail)";
break;
case DFGPath:
pathName = "DFG";
break;
case FTLPath:
pathName = "FTL";
break;
case CancelPath:
pathName = "Cancelled";
break;
default:
RELEASE_ASSERT_NOT_REACHED();
break;
}
if (m_codeBlock) { // m_codeBlock will be null if the compilation was cancelled.
if (path == FTLPath)
CODEBLOCK_LOG_EVENT(m_codeBlock, "ftlCompile", ("took ", (after - before).milliseconds(), " ms (DFG: ", (m_timeBeforeFTL - before).milliseconds(), ", B3: ", (after - m_timeBeforeFTL).milliseconds(), ") with ", pathName));
else
CODEBLOCK_LOG_EVENT(m_codeBlock, "dfgCompile", ("took ", (after - before).milliseconds(), " ms with ", pathName));
}
if (UNLIKELY(reportCompileTimes())) {
dataLog("Optimized ", codeBlockName, " using ", m_mode, " with ", pathName, " into ", m_finalizer ? m_finalizer->codeSize() : 0, " bytes in ", (after - before).milliseconds(), " ms");
if (path == FTLPath)
dataLog(" (DFG: ", (m_timeBeforeFTL - before).milliseconds(), ", B3: ", (after - m_timeBeforeFTL).milliseconds(), ")");
dataLog(".\n");
}
}
Plan::CompilationPath Plan::compileInThreadImpl()
{
cleanMustHandleValuesIfNecessary();
if (verboseCompilationEnabled(m_mode) && m_osrEntryBytecodeIndex != UINT_MAX) {
dataLog("\n");
dataLog("Compiler must handle OSR entry from bc#", m_osrEntryBytecodeIndex, " with values: ", m_mustHandleValues, "\n");
dataLog("\n");
}
Graph dfg(*m_vm, *this);
parse(dfg);
m_codeBlock->setCalleeSaveRegisters(RegisterSet::dfgCalleeSaveRegisters());
bool changed = false;
#define RUN_PHASE(phase) \
do { \
if (Options::safepointBeforeEachPhase()) { \
Safepoint::Result safepointResult; \
{ \
GraphSafepoint safepoint(dfg, safepointResult); \
} \
if (safepointResult.didGetCancelled()) \
return CancelPath; \
} \
changed |= phase(dfg); \
} while (false); \
// By this point the DFG bytecode parser will have potentially mutated various tables
// in the CodeBlock. This is a good time to perform an early shrink, which is more
// powerful than a late one. It's safe to do so because we haven't generated any code
// that references any of the tables directly, yet.
m_codeBlock->shrinkToFit(CodeBlock::EarlyShrink);
if (validationEnabled())
validate(dfg);
if (Options::dumpGraphAfterParsing()) {
dataLog("Graph after parsing:\n");
dfg.dump();
}
RUN_PHASE(performLiveCatchVariablePreservationPhase);
if (Options::useMaximalFlushInsertionPhase())
RUN_PHASE(performMaximalFlushInsertion);
RUN_PHASE(performCPSRethreading);
RUN_PHASE(performUnification);
RUN_PHASE(performPredictionInjection);
RUN_PHASE(performStaticExecutionCountEstimation);
if (m_mode == FTLForOSREntryMode) {
bool result = performOSREntrypointCreation(dfg);
if (!result) {
m_finalizer = std::make_unique<FailedFinalizer>(*this);
return FailPath;
}
RUN_PHASE(performCPSRethreading);
}
if (validationEnabled())
validate(dfg);
RUN_PHASE(performBackwardsPropagation);
RUN_PHASE(performPredictionPropagation);
RUN_PHASE(performFixup);
RUN_PHASE(performInvalidationPointInjection);
RUN_PHASE(performTypeCheckHoisting);
dfg.m_fixpointState = FixpointNotConverged;
// For now we're back to avoiding a fixpoint. Note that we've ping-ponged on this decision
// many times. For maximum throughput, it's best to fixpoint. But the throughput benefit is
// small and not likely to show up in FTL anyway. On the other hand, not fixpointing means
// that the compiler compiles more quickly. We want the third tier to compile quickly, which
// not fixpointing accomplishes; and the fourth tier shouldn't need a fixpoint.
if (validationEnabled())
validate(dfg);
RUN_PHASE(performStrengthReduction);
RUN_PHASE(performCPSRethreading);
RUN_PHASE(performCFA);
RUN_PHASE(performConstantFolding);
changed = false;
RUN_PHASE(performCFGSimplification);
RUN_PHASE(performLocalCSE);
if (validationEnabled())
validate(dfg);
RUN_PHASE(performCPSRethreading);
if (!isFTL()) {
// Only run this if we're not FTLing, because currently for a LoadVarargs that is forwardable and
// in a non-varargs inlined call frame, this will generate ForwardVarargs while the FTL
// ArgumentsEliminationPhase will create a sequence of GetStack+PutStacks. The GetStack+PutStack
// sequence then gets sunk, eliminating anything that looks like an escape for subsequent phases,
// while the ForwardVarargs doesn't get simplified until later (or not at all) and looks like an
// escape for all of the arguments. This then disables object allocation sinking.
//
// So, for now, we just disable this phase for the FTL.
//
// If we wanted to enable it, we'd have to do any of the following:
// - Enable ForwardVarargs->GetStack+PutStack strength reduction, and have that run before
// PutStack sinking and object allocation sinking.
// - Make VarargsForwarding emit a GetLocal+SetLocal sequence, that we can later turn into
// GetStack+PutStack.
//
// But, it's not super valuable to enable those optimizations, since the FTL
// ArgumentsEliminationPhase does everything that this phase does, and it doesn't introduce this
// pathology.
RUN_PHASE(performVarargsForwarding); // Do this after CFG simplification and CPS rethreading.
}
if (changed) {
RUN_PHASE(performCFA);
RUN_PHASE(performConstantFolding);
}
// If we're doing validation, then run some analyses, to give them an opportunity
// to self-validate. Now is as good a time as any to do this.
if (validationEnabled()) {
dfg.ensureCPSDominators();
dfg.ensureCPSNaturalLoops();
}
switch (m_mode) {
case DFGMode: {
dfg.m_fixpointState = FixpointConverged;
RUN_PHASE(performTierUpCheckInjection);
RUN_PHASE(performFastStoreBarrierInsertion);
RUN_PHASE(performStoreBarrierClustering);
RUN_PHASE(performCleanUp);
RUN_PHASE(performCPSRethreading);
RUN_PHASE(performDCE);
RUN_PHASE(performPhantomInsertion);
RUN_PHASE(performStackLayout);
RUN_PHASE(performVirtualRegisterAllocation);
RUN_PHASE(performWatchpointCollection);
dumpAndVerifyGraph(dfg, "Graph after optimization:");
JITCompiler dataFlowJIT(dfg);
if (m_codeBlock->codeType() == FunctionCode)
dataFlowJIT.compileFunction();
else
dataFlowJIT.compile();
return DFGPath;
}
case FTLMode:
case FTLForOSREntryMode: {
#if ENABLE(FTL_JIT)
if (FTL::canCompile(dfg) == FTL::CannotCompile) {
m_finalizer = std::make_unique<FailedFinalizer>(*this);
return FailPath;
}
RUN_PHASE(performCleanUp); // Reduce the graph size a bit.
RUN_PHASE(performCriticalEdgeBreaking);
if (Options::createPreHeaders())
RUN_PHASE(performLoopPreHeaderCreation);
RUN_PHASE(performCPSRethreading);
RUN_PHASE(performSSAConversion);
RUN_PHASE(performSSALowering);
// Ideally, these would be run to fixpoint with the object allocation sinking phase.
RUN_PHASE(performArgumentsElimination);
if (Options::usePutStackSinking())
RUN_PHASE(performPutStackSinking);
RUN_PHASE(performConstantHoisting);
RUN_PHASE(performGlobalCSE);
RUN_PHASE(performLivenessAnalysis);
RUN_PHASE(performCFA);
RUN_PHASE(performConstantFolding);
RUN_PHASE(performCleanUp); // Reduce the graph size a lot.
changed = false;
RUN_PHASE(performStrengthReduction);
if (Options::useObjectAllocationSinking()) {
RUN_PHASE(performCriticalEdgeBreaking);
RUN_PHASE(performObjectAllocationSinking);
}
if (Options::useValueRepElimination())
RUN_PHASE(performValueRepReduction);
if (changed) {
// State-at-tail and state-at-head will be invalid if we did strength reduction since
// it might increase live ranges.
RUN_PHASE(performLivenessAnalysis);
RUN_PHASE(performCFA);
RUN_PHASE(performConstantFolding);
}
// Currently, this relies on pre-headers still being valid. That precludes running CFG
// simplification before it, unless we re-created the pre-headers. There wouldn't be anything
// wrong with running LICM earlier, if we wanted to put other CFG transforms above this point.
// Alternatively, we could run loop pre-header creation after SSA conversion - but if we did that
// then we'd need to do some simple SSA fix-up.
RUN_PHASE(performLivenessAnalysis);
RUN_PHASE(performCFA);
RUN_PHASE(performLICM);
// FIXME: Currently: IntegerRangeOptimization *must* be run after LICM.
//
// IntegerRangeOptimization makes changes on nodes based on preceding blocks
// and nodes. LICM moves nodes which can invalidates assumptions used
// by IntegerRangeOptimization.
//
// Ideally, the dependencies should be explicit. See https://bugs.webkit.org/show_bug.cgi?id=157534.
RUN_PHASE(performLivenessAnalysis);
RUN_PHASE(performIntegerRangeOptimization);
RUN_PHASE(performCleanUp);
RUN_PHASE(performIntegerCheckCombining);
RUN_PHASE(performGlobalCSE);
// At this point we're not allowed to do any further code motion because our reasoning
// about code motion assumes that it's OK to insert GC points in random places.
dfg.m_fixpointState = FixpointConverged;
RUN_PHASE(performLivenessAnalysis);
RUN_PHASE(performCFA);
RUN_PHASE(performGlobalStoreBarrierInsertion);
RUN_PHASE(performStoreBarrierClustering);
if (Options::useMovHintRemoval())
RUN_PHASE(performMovHintRemoval);
RUN_PHASE(performCleanUp);
RUN_PHASE(performDCE); // We rely on this to kill dead code that won't be recognized as dead by B3.
RUN_PHASE(performStackLayout);
RUN_PHASE(performLivenessAnalysis);
RUN_PHASE(performOSRAvailabilityAnalysis);
RUN_PHASE(performWatchpointCollection);
if (FTL::canCompile(dfg) == FTL::CannotCompile) {
m_finalizer = std::make_unique<FailedFinalizer>(*this);
return FailPath;
}
dumpAndVerifyGraph(dfg, "Graph just before FTL lowering:", shouldDumpDisassembly(m_mode));
// Flash a safepoint in case the GC wants some action.
Safepoint::Result safepointResult;
{
GraphSafepoint safepoint(dfg, safepointResult);
}
if (safepointResult.didGetCancelled())
return CancelPath;
FTL::State state(dfg);
FTL::lowerDFGToB3(state);
if (UNLIKELY(computeCompileTimes()))
m_timeBeforeFTL = MonotonicTime::now();
if (Options::b3AlwaysFailsBeforeCompile()) {
FTL::fail(state);
return FTLPath;
}
FTL::compile(state, safepointResult);
if (safepointResult.didGetCancelled())
return CancelPath;
if (Options::b3AlwaysFailsBeforeLink()) {
FTL::fail(state);
return FTLPath;
}
if (state.allocationFailed) {
FTL::fail(state);
return FTLPath;
}
FTL::link(state);
if (state.allocationFailed) {
FTL::fail(state);
return FTLPath;
}
return FTLPath;
#else
RELEASE_ASSERT_NOT_REACHED();
return FailPath;
#endif // ENABLE(FTL_JIT)
}
default:
RELEASE_ASSERT_NOT_REACHED();
return FailPath;
}
#undef RUN_PHASE
}
bool Plan::isStillValid()
{
CodeBlock* replacement = m_codeBlock->replacement();
if (!replacement)
return false;
// FIXME: This is almost certainly not necessary. There's no way for the baseline
// code to be replaced during a compilation, except if we delete the plan, in which
// case we wouldn't be here.
// https://bugs.webkit.org/show_bug.cgi?id=132707
if (m_codeBlock->alternative() != replacement->baselineVersion())
return false;
if (!m_watchpoints.areStillValid())
return false;
return true;
}
void Plan::reallyAdd(CommonData* commonData)
{
m_watchpoints.reallyAdd(m_codeBlock, *commonData);
m_identifiers.reallyAdd(*m_vm, commonData);
m_weakReferences.reallyAdd(*m_vm, commonData);
m_transitions.reallyAdd(*m_vm, commonData);
m_globalProperties.reallyAdd(m_codeBlock, m_identifiers, *commonData);
commonData->recordedStatuses = WTFMove(m_recordedStatuses);
}
void Plan::notifyCompiling()
{
m_stage = Compiling;
}
void Plan::notifyReady()
{
m_callback->compilationDidBecomeReadyAsynchronously(m_codeBlock, m_profiledDFGCodeBlock);
m_stage = Ready;
}
bool Plan::isStillValidOnMainThread()
{
return m_globalProperties.isStillValidOnMainThread(*m_vm, m_identifiers);
}
CompilationResult Plan::finalizeWithoutNotifyingCallback()
{
// We will establish new references from the code block to things. So, we need a barrier.
m_vm->heap.writeBarrier(m_codeBlock);
if (!isStillValidOnMainThread() || !isStillValid()) {
CODEBLOCK_LOG_EVENT(m_codeBlock, "dfgFinalize", ("invalidated"));
return CompilationInvalidated;
}
bool result;
if (m_codeBlock->codeType() == FunctionCode)
result = m_finalizer->finalizeFunction();
else
result = m_finalizer->finalize();
if (!result) {
CODEBLOCK_LOG_EVENT(m_codeBlock, "dfgFinalize", ("failed"));
return CompilationFailed;
}
reallyAdd(m_codeBlock->jitCode()->dfgCommon());
if (validationEnabled()) {
TrackedReferences trackedReferences;
for (WriteBarrier<JSCell>& reference : m_codeBlock->jitCode()->dfgCommon()->weakReferences)
trackedReferences.add(reference.get());
for (WriteBarrier<Structure>& reference : m_codeBlock->jitCode()->dfgCommon()->weakStructureReferences)
trackedReferences.add(reference.get());
for (WriteBarrier<Unknown>& constant : m_codeBlock->constants())
trackedReferences.add(constant.get());
for (auto* inlineCallFrame : *m_inlineCallFrames) {
ASSERT(inlineCallFrame->baselineCodeBlock.get());
trackedReferences.add(inlineCallFrame->baselineCodeBlock.get());
}
// Check that any other references that we have anywhere in the JITCode are also
// tracked either strongly or weakly.
m_codeBlock->jitCode()->validateReferences(trackedReferences);
}
CODEBLOCK_LOG_EVENT(m_codeBlock, "dfgFinalize", ("succeeded"));
return CompilationSuccessful;
}
void Plan::finalizeAndNotifyCallback()
{
m_callback->compilationDidComplete(m_codeBlock, m_profiledDFGCodeBlock, finalizeWithoutNotifyingCallback());
}
CompilationKey Plan::key()
{
return CompilationKey(m_codeBlock->alternative(), m_mode);
}
void Plan::checkLivenessAndVisitChildren(SlotVisitor& visitor)
{
if (!isKnownToBeLiveDuringGC())
return;
cleanMustHandleValuesIfNecessary();
for (unsigned i = m_mustHandleValues.size(); i--;) {
Optional<JSValue> value = m_mustHandleValues[i];
if (value)
visitor.appendUnbarriered(value.value());
}
m_recordedStatuses.markIfCheap(visitor);
visitor.appendUnbarriered(m_codeBlock);
visitor.appendUnbarriered(m_codeBlock->alternative());
visitor.appendUnbarriered(m_profiledDFGCodeBlock);
if (m_inlineCallFrames) {
for (auto* inlineCallFrame : *m_inlineCallFrames) {
ASSERT(inlineCallFrame->baselineCodeBlock.get());
visitor.appendUnbarriered(inlineCallFrame->baselineCodeBlock.get());
}
}
m_weakReferences.visitChildren(visitor);
m_transitions.visitChildren(visitor);
}
void Plan::finalizeInGC()
{
ASSERT(m_vm);
m_recordedStatuses.finalizeWithoutDeleting(*m_vm);
}
bool Plan::isKnownToBeLiveDuringGC()
{
if (m_stage == Cancelled)
return false;
if (!m_vm->heap.isMarked(m_codeBlock->ownerExecutable()))
return false;
if (!m_vm->heap.isMarked(m_codeBlock->alternative()))
return false;
if (!!m_profiledDFGCodeBlock && !m_vm->heap.isMarked(m_profiledDFGCodeBlock))
return false;
return true;
}
void Plan::cancel()
{
m_vm = nullptr;
m_codeBlock = nullptr;
m_profiledDFGCodeBlock = nullptr;
m_mustHandleValues.clear();
m_compilation = nullptr;
m_finalizer = nullptr;
m_inlineCallFrames = nullptr;
m_watchpoints = DesiredWatchpoints();
m_identifiers = DesiredIdentifiers();
m_globalProperties = DesiredGlobalProperties();
m_weakReferences = DesiredWeakReferences();
m_transitions = DesiredTransitions();
m_callback = nullptr;
m_stage = Cancelled;
}
void Plan::cleanMustHandleValuesIfNecessary()
{
LockHolder locker(m_mustHandleValueCleaningLock);
if (!m_mustHandleValuesMayIncludeGarbage)
return;
m_mustHandleValuesMayIncludeGarbage = false;
if (!m_codeBlock)
return;
if (!m_mustHandleValues.numberOfLocals())
return;
CodeBlock* alternative = m_codeBlock->alternative();
FastBitVector liveness = alternative->livenessAnalysis().getLivenessInfoAtBytecodeOffset(alternative, m_osrEntryBytecodeIndex);
for (unsigned local = m_mustHandleValues.numberOfLocals(); local--;) {
if (!liveness[local])
m_mustHandleValues.local(local) = WTF::nullopt;
}
}
} } // namespace JSC::DFG
#endif // ENABLE(DFG_JIT)