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webkit / WebKit / 7d8c1d87b684a5e193239744687c2c463e971f16 / . / Source / JavaScriptCore / dfg / DFGClobberize.h
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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.
*/
#pragma once
#if ENABLE(DFG_JIT)
#include "DFGAbstractHeap.h"
#include "DFGGraph.h"
#include "DFGHeapLocation.h"
#include "DFGLazyNode.h"
#include "DFGPureValue.h"
#include "DOMJITCallDOMGetterSnippet.h"
#include "DOMJITSignature.h"
#include "InlineCallFrame.h"
#include "JSImmutableButterfly.h"
namespace JSC { namespace DFG {
template<typename ReadFunctor, typename WriteFunctor, typename DefFunctor>
void clobberize(Graph& graph, Node* node, const ReadFunctor& read, const WriteFunctor& write, const DefFunctor& def)
{
// Some notes:
//
// - The canonical way of clobbering the world is to read world and write
// heap. This is because World subsumes Heap and Stack, and Stack can be
// read by anyone but only written to by explicit stack writing operations.
// Of course, claiming to also write World is not wrong; it'll just
// pessimise some important optimizations.
//
// - We cannot hoist, or sink, anything that has effects. This means that the
// easiest way of indicating that something cannot be hoisted is to claim
// that it side-effects some miscellaneous thing.
//
// - We cannot hoist forward-exiting nodes without some additional effort. I
// believe that what it comes down to is that forward-exiting generally have
// their NodeExitsForward cleared upon hoist, except for forward-exiting
// nodes that take bogus state as their input. Those are substantially
// harder. We disable it for now. In the future we could enable it by having
// versions of those nodes that backward-exit instead, but I'm not convinced
// of the soundness.
//
// - Some nodes lie, and claim that they do not read the JSCell_structureID,
// JSCell_typeInfoFlags, etc. These are nodes that use the structure in a way
// that does not depend on things that change under structure transitions.
//
// - It's implicitly understood that OSR exits read the world. This is why we
// generally don't move or eliminate stores. Every node can exit, so the
// read set does not reflect things that would be read if we exited.
// Instead, the read set reflects what the node will have to read if it
// *doesn't* exit.
//
// - Broadly, we don't say that we're reading something if that something is
// immutable.
//
// - This must be sound even prior to type inference. We use this as early as
// bytecode parsing to determine at which points in the program it's legal to
// OSR exit.
//
// - If you do read(Stack) or read(World), then make sure that readTop() in
// PreciseLocalClobberize is correct.
// While read() and write() are fairly self-explanatory - they track what sorts of things the
// node may read or write - the def() functor is more tricky. It tells you the heap locations
// (not just abstract heaps) that are defined by a node. A heap location comprises an abstract
// heap, some nodes, and a LocationKind. Briefly, a location defined by a node is a location
// whose value can be deduced from looking at the node itself. The locations returned must obey
// the following properties:
//
// - If someone wants to CSE a load from the heap, then a HeapLocation object should be
// sufficient to find a single matching node.
//
// - The abstract heap is the only abstract heap that could be clobbered to invalidate any such
// CSE attempt. I.e. if clobberize() reports that on every path between some node and a node
// that defines a HeapLocation that it wanted, there were no writes to any abstract heap that
// overlap the location's heap, then we have a sound match. Effectively, the semantics of
// write() and def() are intertwined such that for them to be sound they must agree on what
// is CSEable.
//
// read(), write(), and def() for heap locations is enough to do GCSE on effectful things. To
// keep things simple, this code will also def() pure things. def() must be overloaded to also
// accept PureValue. This way, a client of clobberize() can implement GCSE entirely using the
// information that clobberize() passes to write() and def(). Other clients of clobberize() can
// just ignore def() by using a NoOpClobberize functor.
// We allow the runtime to perform a stack scan at any time. We don't model which nodes get implemented
// by calls into the runtime. For debugging we might replace the implementation of any node with a call
// to the runtime, and that call may walk stack. Therefore, each node must read() anything that a stack
// scan would read. That's what this does.
for (InlineCallFrame* inlineCallFrame = node->origin.semantic.inlineCallFrame(); inlineCallFrame; inlineCallFrame = inlineCallFrame->directCaller.inlineCallFrame()) {
if (inlineCallFrame->isClosureCall)
read(AbstractHeap(Stack, VirtualRegister(inlineCallFrame->stackOffset + CallFrameSlot::callee)));
if (inlineCallFrame->isVarargs())
read(AbstractHeap(Stack, VirtualRegister(inlineCallFrame->stackOffset + CallFrameSlot::argumentCountIncludingThis)));
}
// We don't want to specifically account which nodes can read from the scope
// when the debugger is enabled. It's helpful to just claim all nodes do.
// Specifically, if a node allocates, this may call into the debugger's machinery.
// The debugger's machinery is free to take a stack trace and try to read from
// a scope which is expected to be flushed to the stack.
if (graph.hasDebuggerEnabled()) {
ASSERT(!node->origin.semantic.inlineCallFrame());
read(AbstractHeap(Stack, graph.m_codeBlock->scopeRegister()));
}
switch (node->op()) {
case JSConstant:
case DoubleConstant:
case Int52Constant:
def(PureValue(node, node->constant()));
return;
case Identity:
case IdentityWithProfile:
case Phantom:
case Check:
case CheckVarargs:
case ExtractOSREntryLocal:
case CheckStructureImmediate:
return;
case ExtractCatchLocal:
read(AbstractHeap(CatchLocals, node->catchOSREntryIndex()));
return;
case ClearCatchLocals:
write(CatchLocals);
return;
case LazyJSConstant:
// We should enable CSE of LazyJSConstant. It's a little annoying since LazyJSValue has
// more bits than we currently have in PureValue.
return;
case CompareEqPtr:
def(PureValue(node, node->cellOperand()->cell()));
return;
case ArithIMul:
case ArithMin:
case ArithMax:
case ArithPow:
case GetScope:
case SkipScope:
case GetGlobalObject:
case StringCharCodeAt:
case StringCodePointAt:
case CompareStrictEq:
case SameValue:
case IsEmpty:
case IsUndefined:
case IsUndefinedOrNull:
case IsBoolean:
case IsNumber:
case NumberIsInteger:
case IsObject:
case IsTypedArrayView:
case LogicalNot:
case CheckInBounds:
case DoubleRep:
case ValueRep:
case Int52Rep:
case BooleanToNumber:
case FiatInt52:
case MakeRope:
case StrCat:
case ValueToInt32:
case GetExecutable:
case BottomValue:
case TypeOf:
def(PureValue(node));
return;
case GetGlobalThis:
read(World);
return;
case AtomicsIsLockFree:
if (node->child1().useKind() == Int32Use)
def(PureValue(node));
else {
read(World);
write(Heap);
}
return;
case ArithUnary:
if (node->child1().useKind() == DoubleRepUse)
def(PureValue(node, static_cast<std::underlying_type<Arith::UnaryType>::type>(node->arithUnaryType())));
else {
read(World);
write(Heap);
}
return;
case ArithFRound:
case ArithSqrt:
if (node->child1().useKind() == DoubleRepUse)
def(PureValue(node));
else {
read(World);
write(Heap);
}
return;
case ArithAbs:
if (node->child1().useKind() == Int32Use || node->child1().useKind() == DoubleRepUse)
def(PureValue(node));
else {
read(World);
write(Heap);
}
return;
case ArithClz32:
if (node->child1().useKind() == Int32Use || node->child1().useKind() == KnownInt32Use)
def(PureValue(node));
else {
read(World);
write(Heap);
}
return;
case ArithNegate:
if (node->child1().useKind() == Int32Use
|| node->child1().useKind() == DoubleRepUse
|| node->child1().useKind() == Int52RepUse)
def(PureValue(node));
else {
read(World);
write(Heap);
}
return;
case IsCellWithType:
def(PureValue(node, node->queriedType()));
return;
case ValueBitNot:
if (node->child1().useKind() == BigIntUse) {
def(PureValue(node));
return;
}
read(World);
write(Heap);
return;
case ArithBitNot:
if (node->child1().useKind() == UntypedUse) {
read(World);
write(Heap);
return;
}
def(PureValue(node));
return;
case ArithBitAnd:
case ArithBitOr:
case ArithBitXor:
case ArithBitLShift:
case ArithBitRShift:
case BitURShift:
if (node->child1().useKind() == UntypedUse || node->child2().useKind() == UntypedUse) {
read(World);
write(Heap);
return;
}
def(PureValue(node));
return;
case ArithRandom:
read(MathDotRandomState);
write(MathDotRandomState);
return;
case GetEnumerableLength: {
read(Heap);
write(SideState);
return;
}
case ToIndexString:
case GetEnumeratorStructurePname:
case GetEnumeratorGenericPname: {
def(PureValue(node));
return;
}
case HasIndexedProperty: {
read(JSObject_butterfly);
ArrayMode mode = node->arrayMode();
switch (mode.type()) {
case Array::ForceExit: {
write(SideState);
return;
}
case Array::Int32: {
if (mode.isInBounds()) {
read(Butterfly_publicLength);
read(IndexedInt32Properties);
def(HeapLocation(HasIndexedPropertyLoc, IndexedInt32Properties, graph.varArgChild(node, 0), graph.varArgChild(node, 1)), LazyNode(node));
return;
}
read(Heap);
return;
}
case Array::Double: {
if (mode.isInBounds()) {
read(Butterfly_publicLength);
read(IndexedDoubleProperties);
def(HeapLocation(HasIndexedPropertyLoc, IndexedDoubleProperties, graph.varArgChild(node, 0), graph.varArgChild(node, 1)), LazyNode(node));
return;
}
read(Heap);
return;
}
case Array::Contiguous: {
if (mode.isInBounds()) {
read(Butterfly_publicLength);
read(IndexedContiguousProperties);
def(HeapLocation(HasIndexedPropertyLoc, IndexedContiguousProperties, graph.varArgChild(node, 0), graph.varArgChild(node, 1)), LazyNode(node));
return;
}
read(Heap);
return;
}
case Array::ArrayStorage: {
if (mode.isInBounds()) {
read(Butterfly_vectorLength);
read(IndexedArrayStorageProperties);
return;
}
read(Heap);
return;
}
default: {
read(World);
write(Heap);
return;
}
}
RELEASE_ASSERT_NOT_REACHED();
return;
}
case StringFromCharCode:
switch (node->child1().useKind()) {
case Int32Use:
def(PureValue(node));
return;
case UntypedUse:
read(World);
write(Heap);
return;
default:
DFG_CRASH(graph, node, "Bad use kind");
}
return;
case ArithAdd:
case ArithMod:
case DoubleAsInt32:
case UInt32ToNumber:
def(PureValue(node, node->arithMode()));
return;
case ArithDiv:
case ArithMul:
case ArithSub:
switch (node->binaryUseKind()) {
case Int32Use:
case Int52RepUse:
case DoubleRepUse:
def(PureValue(node, node->arithMode()));
return;
case UntypedUse:
read(World);
write(Heap);
return;
default:
DFG_CRASH(graph, node, "Bad use kind");
}
case ArithRound:
case ArithFloor:
case ArithCeil:
case ArithTrunc:
if (node->child1().useKind() == DoubleRepUse)
def(PureValue(node, static_cast<uintptr_t>(node->arithRoundingMode())));
else {
read(World);
write(Heap);
}
return;
case CheckCell:
def(PureValue(CheckCell, AdjacencyList(AdjacencyList::Fixed, node->child1()), node->cellOperand()));
return;
case CheckNotEmpty:
def(PureValue(CheckNotEmpty, AdjacencyList(AdjacencyList::Fixed, node->child1())));
return;
case AssertNotEmpty:
write(SideState);
return;
case CheckIdent:
def(PureValue(CheckIdent, AdjacencyList(AdjacencyList::Fixed, node->child1()), node->uidOperand()));
return;
case ConstantStoragePointer:
def(PureValue(node, node->storagePointer()));
return;
case KillStack:
write(AbstractHeap(Stack, node->unlinkedOperand()));
return;
case MovHint:
case ZombieHint:
case ExitOK:
case Upsilon:
case Phi:
case PhantomLocal:
case SetArgumentDefinitely:
case SetArgumentMaybe:
case Jump:
case Branch:
case Switch:
case EntrySwitch:
case ForceOSRExit:
case CPUIntrinsic:
case CheckBadCell:
case Return:
case Unreachable:
case CheckTierUpInLoop:
case CheckTierUpAtReturn:
case CheckTierUpAndOSREnter:
case LoopHint:
case ProfileType:
case ProfileControlFlow:
case PutHint:
case InitializeEntrypointArguments:
case FilterCallLinkStatus:
case FilterGetByStatus:
case FilterPutByIdStatus:
case FilterInByIdStatus:
write(SideState);
return;
case StoreBarrier:
read(JSCell_cellState);
write(JSCell_cellState);
return;
case FencedStoreBarrier:
read(Heap);
write(JSCell_cellState);
return;
case CheckTraps:
read(InternalState);
write(InternalState);
return;
case InvalidationPoint:
write(SideState);
def(HeapLocation(InvalidationPointLoc, Watchpoint_fire), LazyNode(node));
return;
case Flush:
read(AbstractHeap(Stack, node->operand()));
write(SideState);
return;
case NotifyWrite:
write(Watchpoint_fire);
write(SideState);
return;
case PushWithScope: {
read(World);
write(HeapObjectCount);
return;
}
case CreateActivation: {
SymbolTable* table = node->castOperand<SymbolTable*>();
if (table->singleton().isStillValid())
write(Watchpoint_fire);
read(HeapObjectCount);
write(HeapObjectCount);
return;
}
case CreateDirectArguments:
case CreateScopedArguments:
case CreateClonedArguments:
case CreateArgumentsButterfly:
read(Stack);
read(HeapObjectCount);
write(HeapObjectCount);
return;
case PhantomDirectArguments:
case PhantomClonedArguments:
// DFG backend requires that the locals that this reads are flushed. FTL backend can handle those
// locals being promoted.
if (!graph.m_plan.isFTL())
read(Stack);
// Even though it's phantom, it still has the property that one can't be replaced with another.
read(HeapObjectCount);
write(HeapObjectCount);
return;
case PhantomSpread:
case PhantomNewArrayWithSpread:
case PhantomNewArrayBuffer:
case PhantomCreateRest:
// Even though it's phantom, it still has the property that one can't be replaced with another.
read(HeapObjectCount);
write(HeapObjectCount);
return;
case CallObjectConstructor:
read(HeapObjectCount);
write(HeapObjectCount);
return;
case ToThis:
read(MiscFields);
read(HeapObjectCount);
write(HeapObjectCount);
return;
case IsObjectOrNull:
read(MiscFields);
def(HeapLocation(IsObjectOrNullLoc, MiscFields, node->child1()), LazyNode(node));
return;
case IsFunction:
read(MiscFields);
def(HeapLocation(IsFunctionLoc, MiscFields, node->child1()), LazyNode(node));
return;
case MatchStructure:
read(JSCell_structureID);
return;
case ArraySlice:
read(MiscFields);
read(JSCell_indexingType);
read(JSCell_structureID);
read(JSObject_butterfly);
read(Butterfly_publicLength);
read(IndexedDoubleProperties);
read(IndexedInt32Properties);
read(IndexedContiguousProperties);
read(HeapObjectCount);
write(HeapObjectCount);
return;
case ArrayIndexOf: {
// FIXME: Should support a CSE rule.
// https://bugs.webkit.org/show_bug.cgi?id=173173
read(MiscFields);
read(JSCell_indexingType);
read(JSCell_structureID);
read(JSObject_butterfly);
read(Butterfly_publicLength);
switch (node->arrayMode().type()) {
case Array::Double:
read(IndexedDoubleProperties);
return;
case Array::Int32:
read(IndexedInt32Properties);
return;
case Array::Contiguous:
read(IndexedContiguousProperties);
return;
default:
RELEASE_ASSERT_NOT_REACHED();
return;
}
return;
}
case GetById:
case GetByIdFlush:
case GetByIdWithThis:
case GetByIdDirect:
case GetByIdDirectFlush:
case GetByValWithThis:
case PutById:
case PutByIdWithThis:
case PutByValWithThis:
case PutByIdFlush:
case PutByIdDirect:
case PutGetterById:
case PutSetterById:
case PutGetterSetterById:
case PutGetterByVal:
case PutSetterByVal:
case DefineDataProperty:
case DefineAccessorProperty:
case DeleteById:
case DeleteByVal:
case ArrayPush:
case ArrayPop:
case Call:
case DirectCall:
case TailCallInlinedCaller:
case DirectTailCallInlinedCaller:
case Construct:
case DirectConstruct:
case CallVarargs:
case CallForwardVarargs:
case TailCallVarargsInlinedCaller:
case TailCallForwardVarargsInlinedCaller:
case ConstructVarargs:
case ConstructForwardVarargs:
case ToPrimitive:
case ToPropertyKey:
case InByVal:
case InById:
case HasOwnProperty:
case ValueNegate:
case SetFunctionName:
case GetDynamicVar:
case PutDynamicVar:
case ResolveScopeForHoistingFuncDeclInEval:
case ResolveScope:
case ToObject:
case HasGenericProperty:
case HasStructureProperty:
case GetPropertyEnumerator:
case GetDirectPname:
case InstanceOfCustom:
case ToNumber:
case ToNumeric:
case NumberToStringWithRadix:
case CreateThis:
case CreatePromise:
case CreateGenerator:
case CreateAsyncGenerator:
case InstanceOf:
case StringValueOf:
case ObjectKeys:
read(World);
write(Heap);
return;
case Inc:
case Dec:
switch (node->child1().useKind()) {
case Int32Use:
case Int52RepUse:
case DoubleRepUse:
case BigIntUse:
def(PureValue(node));
return;
case UntypedUse:
read(World);
write(Heap);
return;
default:
DFG_CRASH(graph, node, "Bad use kind");
}
case ValueBitAnd:
case ValueBitXor:
case ValueBitOr:
case ValueAdd:
case ValueSub:
case ValueMul:
case ValueDiv:
case ValueMod:
case ValuePow:
case ValueBitLShift:
case ValueBitRShift:
if (node->isBinaryUseKind(BigIntUse)) {
def(PureValue(node));
return;
}
read(World);
write(Heap);
return;
case AtomicsAdd:
case AtomicsAnd:
case AtomicsCompareExchange:
case AtomicsExchange:
case AtomicsLoad:
case AtomicsOr:
case AtomicsStore:
case AtomicsSub:
case AtomicsXor: {
unsigned numExtraArgs = numExtraAtomicsArgs(node->op());
Edge storageEdge = graph.child(node, 2 + numExtraArgs);
if (!storageEdge) {
read(World);
write(Heap);
return;
}
read(TypedArrayProperties);
read(MiscFields);
write(TypedArrayProperties);
return;
}
case CallEval:
ASSERT(!node->origin.semantic.inlineCallFrame());
read(AbstractHeap(Stack, graph.m_codeBlock->scopeRegister()));
read(AbstractHeap(Stack, virtualRegisterForArgumentIncludingThis(0)));
read(World);
write(Heap);
return;
case Throw:
case ThrowStaticError:
case TailCall:
case DirectTailCall:
case TailCallVarargs:
case TailCallForwardVarargs:
read(World);
write(SideState);
return;
case GetGetter:
read(GetterSetter_getter);
def(HeapLocation(GetterLoc, GetterSetter_getter, node->child1()), LazyNode(node));
return;
case GetSetter:
read(GetterSetter_setter);
def(HeapLocation(SetterLoc, GetterSetter_setter, node->child1()), LazyNode(node));
return;
case GetCallee:
read(AbstractHeap(Stack, VirtualRegister(CallFrameSlot::callee)));
def(HeapLocation(StackLoc, AbstractHeap(Stack, VirtualRegister(CallFrameSlot::callee))), LazyNode(node));
return;
case SetCallee:
write(AbstractHeap(Stack, VirtualRegister(CallFrameSlot::callee)));
return;
case GetArgumentCountIncludingThis: {
auto heap = AbstractHeap(Stack, remapOperand(node->argumentsInlineCallFrame(), VirtualRegister(CallFrameSlot::argumentCountIncludingThis)));
read(heap);
def(HeapLocation(StackPayloadLoc, heap), LazyNode(node));
return;
}
case SetArgumentCountIncludingThis:
write(AbstractHeap(Stack, VirtualRegister(CallFrameSlot::argumentCountIncludingThis)));
return;
case GetRestLength:
read(Stack);
return;
case GetLocal:
read(AbstractHeap(Stack, node->operand()));
def(HeapLocation(StackLoc, AbstractHeap(Stack, node->operand())), LazyNode(node));
return;
case SetLocal:
write(AbstractHeap(Stack, node->operand()));
def(HeapLocation(StackLoc, AbstractHeap(Stack, node->operand())), LazyNode(node->child1().node()));
return;
case GetStack: {
AbstractHeap heap(Stack, node->stackAccessData()->operand);
read(heap);
def(HeapLocation(StackLoc, heap), LazyNode(node));
return;
}
case PutStack: {
AbstractHeap heap(Stack, node->stackAccessData()->operand);
write(heap);
def(HeapLocation(StackLoc, heap), LazyNode(node->child1().node()));
return;
}
case VarargsLength: {
read(World);
write(Heap);
return;
}
case LoadVarargs: {
read(World);
write(Heap);
LoadVarargsData* data = node->loadVarargsData();
write(AbstractHeap(Stack, data->count));
for (unsigned i = data->limit; i--;)
write(AbstractHeap(Stack, data->start + static_cast<int>(i)));
return;
}
case ForwardVarargs: {
// We could be way more precise here.
read(Stack);
LoadVarargsData* data = node->loadVarargsData();
write(AbstractHeap(Stack, data->count));
for (unsigned i = data->limit; i--;)
write(AbstractHeap(Stack, data->start + static_cast<int>(i)));
return;
}
case GetByVal: {
ArrayMode mode = node->arrayMode();
LocationKind indexedPropertyLoc = indexedPropertyLocForResultType(node->result());
switch (mode.type()) {
case Array::SelectUsingPredictions:
case Array::Unprofiled:
case Array::SelectUsingArguments:
// Assume the worst since we don't have profiling yet.
read(World);
write(Heap);
return;
case Array::ForceExit:
write(SideState);
return;
case Array::Generic:
read(World);
write(Heap);
return;
case Array::String:
if (mode.isOutOfBounds()) {
read(World);
write(Heap);
return;
}
// This appears to read nothing because it's only reading immutable data.
def(PureValue(graph, node, mode.asWord()));
return;
case Array::DirectArguments:
if (mode.isInBounds()) {
read(DirectArgumentsProperties);
def(HeapLocation(indexedPropertyLoc, DirectArgumentsProperties, graph.varArgChild(node, 0), graph.varArgChild(node, 1)), LazyNode(node));
return;
}
read(World);
write(Heap);
return;
case Array::ScopedArguments:
read(ScopeProperties);
def(HeapLocation(indexedPropertyLoc, ScopeProperties, graph.varArgChild(node, 0), graph.varArgChild(node, 1)), LazyNode(node));
return;
case Array::Int32:
if (mode.isInBounds()) {
read(Butterfly_publicLength);
read(IndexedInt32Properties);
def(HeapLocation(indexedPropertyLoc, IndexedInt32Properties, graph.varArgChild(node, 0), graph.varArgChild(node, 1)), LazyNode(node));
return;
}
read(World);
write(Heap);
return;
case Array::Double:
if (mode.isInBounds()) {
read(Butterfly_publicLength);
read(IndexedDoubleProperties);
LocationKind kind = mode.isSaneChain() ? IndexedPropertyDoubleSaneChainLoc : IndexedPropertyDoubleLoc;
def(HeapLocation(kind, IndexedDoubleProperties, graph.varArgChild(node, 0), graph.varArgChild(node, 1)), LazyNode(node));
return;
}
read(World);
write(Heap);
return;
case Array::Contiguous:
if (mode.isInBounds()) {
read(Butterfly_publicLength);
read(IndexedContiguousProperties);
def(HeapLocation(indexedPropertyLoc, IndexedContiguousProperties, graph.varArgChild(node, 0), graph.varArgChild(node, 1)), LazyNode(node));
return;
}
read(World);
write(Heap);
return;
case Array::Undecided:
def(PureValue(graph, node));
return;
case Array::ArrayStorage:
case Array::SlowPutArrayStorage:
if (mode.isInBounds()) {
read(Butterfly_vectorLength);
read(IndexedArrayStorageProperties);
return;
}
read(World);
write(Heap);
return;
case Array::Int8Array:
case Array::Int16Array:
case Array::Int32Array:
case Array::Uint8Array:
case Array::Uint8ClampedArray:
case Array::Uint16Array:
case Array::Uint32Array:
case Array::Float32Array:
case Array::Float64Array:
read(TypedArrayProperties);
read(MiscFields);
def(HeapLocation(indexedPropertyLoc, TypedArrayProperties, graph.varArgChild(node, 0), graph.varArgChild(node, 1)), LazyNode(node));
return;
// We should not get an AnyTypedArray in a GetByVal as AnyTypedArray is only created from intrinsics, which
// are only added from Inline Caching a GetById.
case Array::AnyTypedArray:
DFG_CRASH(graph, node, "impossible array mode for get");
return;
}
RELEASE_ASSERT_NOT_REACHED();
return;
}
case GetMyArgumentByVal:
case GetMyArgumentByValOutOfBounds: {
read(Stack);
// FIXME: It would be trivial to have a def here.
// https://bugs.webkit.org/show_bug.cgi?id=143077
return;
}
case PutByValDirect:
case PutByVal:
case PutByValAlias: {
ArrayMode mode = node->arrayMode();
Node* base = graph.varArgChild(node, 0).node();
Node* index = graph.varArgChild(node, 1).node();
Node* value = graph.varArgChild(node, 2).node();
LocationKind indexedPropertyLoc = indexedPropertyLocForResultType(node->result());
switch (mode.modeForPut().type()) {
case Array::SelectUsingPredictions:
case Array::SelectUsingArguments:
case Array::Unprofiled:
case Array::Undecided:
// Assume the worst since we don't have profiling yet.
read(World);
write(Heap);
return;
case Array::ForceExit:
write(SideState);
return;
case Array::Generic:
read(World);
write(Heap);
return;
case Array::Int32:
if (node->arrayMode().isOutOfBounds()) {
read(World);
write(Heap);
return;
}
read(Butterfly_publicLength);
read(Butterfly_vectorLength);
read(IndexedInt32Properties);
write(IndexedInt32Properties);
if (node->arrayMode().mayStoreToHole())
write(Butterfly_publicLength);
def(HeapLocation(indexedPropertyLoc, IndexedInt32Properties, base, index), LazyNode(value));
return;
case Array::Double:
if (node->arrayMode().isOutOfBounds()) {
read(World);
write(Heap);
return;
}
read(Butterfly_publicLength);
read(Butterfly_vectorLength);
read(IndexedDoubleProperties);
write(IndexedDoubleProperties);
if (node->arrayMode().mayStoreToHole())
write(Butterfly_publicLength);
def(HeapLocation(IndexedPropertyDoubleLoc, IndexedDoubleProperties, base, index), LazyNode(value));
def(HeapLocation(IndexedPropertyDoubleSaneChainLoc, IndexedDoubleProperties, base, index), LazyNode(value));
return;
case Array::Contiguous:
if (node->arrayMode().isOutOfBounds()) {
read(World);
write(Heap);
return;
}
read(Butterfly_publicLength);
read(Butterfly_vectorLength);
read(IndexedContiguousProperties);
write(IndexedContiguousProperties);
if (node->arrayMode().mayStoreToHole())
write(Butterfly_publicLength);
def(HeapLocation(indexedPropertyLoc, IndexedContiguousProperties, base, index), LazyNode(value));
return;
case Array::ArrayStorage:
if (node->arrayMode().isOutOfBounds()) {
read(World);
write(Heap);
return;
}
read(Butterfly_publicLength);
read(Butterfly_vectorLength);
read(IndexedArrayStorageProperties);
write(IndexedArrayStorageProperties);
if (node->arrayMode().mayStoreToHole())
write(Butterfly_publicLength);
return;
case Array::SlowPutArrayStorage:
if (node->arrayMode().mayStoreToHole()) {
read(World);
write(Heap);
return;
}
read(Butterfly_publicLength);
read(Butterfly_vectorLength);
read(IndexedArrayStorageProperties);
write(IndexedArrayStorageProperties);
return;
case Array::Int8Array:
case Array::Int16Array:
case Array::Int32Array:
case Array::Uint8Array:
case Array::Uint8ClampedArray:
case Array::Uint16Array:
case Array::Uint32Array:
case Array::Float32Array:
case Array::Float64Array:
read(MiscFields);
write(TypedArrayProperties);
// FIXME: We can't def() anything here because these operations truncate their inputs.
// https://bugs.webkit.org/show_bug.cgi?id=134737
return;
case Array::AnyTypedArray:
case Array::String:
case Array::DirectArguments:
case Array::ScopedArguments:
DFG_CRASH(graph, node, "impossible array mode for put");
return;
}
RELEASE_ASSERT_NOT_REACHED();
return;
}
case CheckStructureOrEmpty:
case CheckStructure:
read(JSCell_structureID);
return;
case CheckArray:
read(JSCell_indexingType);
read(JSCell_typeInfoType);
read(JSCell_structureID);
return;
case CheckNeutered:
read(JSCell_typeInfoType);
read(JSCell_structureID);
read(MiscFields);
return;
case CheckTypeInfoFlags:
read(JSCell_typeInfoFlags);
def(HeapLocation(CheckTypeInfoFlagsLoc, JSCell_typeInfoFlags, node->child1()), LazyNode(node));
return;
case ParseInt:
// Note: We would have eliminated a ParseInt that has just a single child as an Int32Use inside fixup.
if (node->child1().useKind() == StringUse && (!node->child2() || node->child2().useKind() == Int32Use)) {
def(PureValue(node));
return;
}
read(World);
write(Heap);
return;
case OverridesHasInstance:
read(JSCell_typeInfoFlags);
def(HeapLocation(OverridesHasInstanceLoc, JSCell_typeInfoFlags, node->child1()), LazyNode(node));
return;
case PutStructure:
read(JSObject_butterfly);
write(JSCell_structureID);
write(JSCell_typeInfoType);
write(JSCell_typeInfoFlags);
write(JSCell_indexingType);
return;
case AllocatePropertyStorage:
case ReallocatePropertyStorage:
read(HeapObjectCount);
write(HeapObjectCount);
return;
case NukeStructureAndSetButterfly:
write(JSObject_butterfly);
write(JSCell_structureID);
def(HeapLocation(ButterflyLoc, JSObject_butterfly, node->child1()), LazyNode(node->child2().node()));
return;
case GetButterfly:
read(JSObject_butterfly);
def(HeapLocation(ButterflyLoc, JSObject_butterfly, node->child1()), LazyNode(node));
return;
case CheckSubClass:
def(PureValue(node, node->classInfo()));
return;
case CallDOMGetter: {
DOMJIT::CallDOMGetterSnippet* snippet = node->callDOMGetterData()->snippet;
if (!snippet) {
read(World);
write(Heap);
return;
}
DOMJIT::Effect effect = snippet->effect;
if (effect.reads) {
if (effect.reads == DOMJIT::HeapRange::top())
read(World);
else
read(AbstractHeap(DOMState, effect.reads.rawRepresentation()));
}
if (effect.writes) {
if (effect.writes == DOMJIT::HeapRange::top())
write(Heap);
else
write(AbstractHeap(DOMState, effect.writes.rawRepresentation()));
}
if (effect.def != DOMJIT::HeapRange::top()) {
DOMJIT::HeapRange range = effect.def;
if (range == DOMJIT::HeapRange::none())
def(PureValue(node, bitwise_cast<uintptr_t>(node->callDOMGetterData()->customAccessorGetter)));
else {
// Def with heap location. We do not include "GlobalObject" for that since this information is included in the base node.
// We only see the DOMJIT getter here. So just including "base" is ok.
def(HeapLocation(DOMStateLoc, AbstractHeap(DOMState, range.rawRepresentation()), node->child1()), LazyNode(node));
}
}
return;
}
case CallDOM: {
const DOMJIT::Signature* signature = node->signature();
DOMJIT::Effect effect = signature->effect;
if (effect.reads) {
if (effect.reads == DOMJIT::HeapRange::top())
read(World);
else
read(AbstractHeap(DOMState, effect.reads.rawRepresentation()));
}
if (effect.writes) {
if (effect.writes == DOMJIT::HeapRange::top())
write(Heap);
else
write(AbstractHeap(DOMState, effect.writes.rawRepresentation()));
}
ASSERT_WITH_MESSAGE(effect.def == DOMJIT::HeapRange::top(), "Currently, we do not accept any def for CallDOM.");
return;
}
case Arrayify:
case ArrayifyToStructure:
read(JSCell_structureID);
read(JSCell_indexingType);
read(JSObject_butterfly);
write(JSCell_structureID);
write(JSCell_indexingType);
write(JSObject_butterfly);
write(Watchpoint_fire);
return;
case GetIndexedPropertyStorage:
if (node->arrayMode().type() == Array::String) {
def(PureValue(node, node->arrayMode().asWord()));
return;
}
read(MiscFields);
def(HeapLocation(IndexedPropertyStorageLoc, MiscFields, node->child1()), LazyNode(node));
return;
case GetTypedArrayByteOffset:
read(MiscFields);
def(HeapLocation(TypedArrayByteOffsetLoc, MiscFields, node->child1()), LazyNode(node));
return;
case GetPrototypeOf: {
switch (node->child1().useKind()) {
case ArrayUse:
case FunctionUse:
case FinalObjectUse:
read(JSCell_structureID);
read(JSObject_butterfly);
read(NamedProperties); // Poly proto could load prototype from its slot.
def(HeapLocation(PrototypeLoc, NamedProperties, node->child1()), LazyNode(node));
return;
default:
read(World);
write(Heap);
return;
}
}
case GetByOffset:
case GetGetterSetterByOffset: {
unsigned identifierNumber = node->storageAccessData().identifierNumber;
AbstractHeap heap(NamedProperties, identifierNumber);
read(heap);
def(HeapLocation(NamedPropertyLoc, heap, node->child2()), LazyNode(node));
return;
}
case TryGetById: {
read(Heap);
return;
}
case MultiGetByOffset: {
read(JSCell_structureID);
read(JSObject_butterfly);
AbstractHeap heap(NamedProperties, node->multiGetByOffsetData().identifierNumber);
read(heap);
def(HeapLocation(NamedPropertyLoc, heap, node->child1()), LazyNode(node));
return;
}
case MultiPutByOffset: {
read(JSCell_structureID);
read(JSObject_butterfly);
AbstractHeap heap(NamedProperties, node->multiPutByOffsetData().identifierNumber);
write(heap);
if (node->multiPutByOffsetData().writesStructures())
write(JSCell_structureID);
if (node->multiPutByOffsetData().reallocatesStorage())
write(JSObject_butterfly);
def(HeapLocation(NamedPropertyLoc, heap, node->child1()), LazyNode(node->child2().node()));
return;
}
case PutByOffset: {
unsigned identifierNumber = node->storageAccessData().identifierNumber;
AbstractHeap heap(NamedProperties, identifierNumber);
write(heap);
def(HeapLocation(NamedPropertyLoc, heap, node->child2()), LazyNode(node->child3().node()));
return;
}
case GetArrayLength: {
ArrayMode mode = node->arrayMode();
switch (mode.type()) {
case Array::Undecided:
case Array::Int32:
case Array::Double:
case Array::Contiguous:
case Array::ArrayStorage:
case Array::SlowPutArrayStorage:
read(Butterfly_publicLength);
def(HeapLocation(ArrayLengthLoc, Butterfly_publicLength, node->child1()), LazyNode(node));
return;
case Array::String:
def(PureValue(node, mode.asWord()));
return;
case Array::DirectArguments:
case Array::ScopedArguments:
read(MiscFields);
def(HeapLocation(ArrayLengthLoc, MiscFields, node->child1()), LazyNode(node));
return;
default:
ASSERT(mode.isSomeTypedArrayView());
read(MiscFields);
def(HeapLocation(ArrayLengthLoc, MiscFields, node->child1()), LazyNode(node));
return;
}
}
case GetVectorLength: {
ArrayMode mode = node->arrayMode();
switch (mode.type()) {
case Array::ArrayStorage:
case Array::SlowPutArrayStorage:
read(Butterfly_vectorLength);
def(HeapLocation(VectorLengthLoc, Butterfly_vectorLength, node->child1()), LazyNode(node));
return;
default:
RELEASE_ASSERT_NOT_REACHED();
return;
}
}
case GetClosureVar:
read(AbstractHeap(ScopeProperties, node->scopeOffset().offset()));
def(HeapLocation(ClosureVariableLoc, AbstractHeap(ScopeProperties, node->scopeOffset().offset()), node->child1()), LazyNode(node));
return;
case PutClosureVar:
write(AbstractHeap(ScopeProperties, node->scopeOffset().offset()));
def(HeapLocation(ClosureVariableLoc, AbstractHeap(ScopeProperties, node->scopeOffset().offset()), node->child1()), LazyNode(node->child2().node()));
return;
case GetInternalField: {
AbstractHeap heap(JSPromiseFields, node->internalFieldIndex());
read(heap);
def(HeapLocation(InternalFieldObjectLoc, heap, node->child1()), LazyNode(node));
return;
}
case PutInternalField: {
AbstractHeap heap(JSPromiseFields, node->internalFieldIndex());
write(heap);
def(HeapLocation(InternalFieldObjectLoc, heap, node->child1()), LazyNode(node->child2().node()));
return;
}
case GetRegExpObjectLastIndex:
read(RegExpObject_lastIndex);
def(HeapLocation(RegExpObjectLastIndexLoc, RegExpObject_lastIndex, node->child1()), LazyNode(node));
return;
case SetRegExpObjectLastIndex:
write(RegExpObject_lastIndex);
def(HeapLocation(RegExpObjectLastIndexLoc, RegExpObject_lastIndex, node->child1()), LazyNode(node->child2().node()));
return;
case RecordRegExpCachedResult:
write(RegExpState);
return;
case GetFromArguments: {
AbstractHeap heap(DirectArgumentsProperties, node->capturedArgumentsOffset().offset());
read(heap);
def(HeapLocation(DirectArgumentsLoc, heap, node->child1()), LazyNode(node));
return;
}
case PutToArguments: {
AbstractHeap heap(DirectArgumentsProperties, node->capturedArgumentsOffset().offset());
write(heap);
def(HeapLocation(DirectArgumentsLoc, heap, node->child1()), LazyNode(node->child2().node()));
return;
}
case GetArgument: {
read(Stack);
// FIXME: It would be trivial to have a def here.
// https://bugs.webkit.org/show_bug.cgi?id=143077
return;
}
case GetGlobalVar:
case GetGlobalLexicalVariable:
read(AbstractHeap(Absolute, node->variablePointer()));
def(HeapLocation(GlobalVariableLoc, AbstractHeap(Absolute, node->variablePointer())), LazyNode(node));
return;
case PutGlobalVariable:
write(AbstractHeap(Absolute, node->variablePointer()));
def(HeapLocation(GlobalVariableLoc, AbstractHeap(Absolute, node->variablePointer())), LazyNode(node->child2().node()));
return;
case NewArrayWithSize:
read(HeapObjectCount);
write(HeapObjectCount);
return;
case NewTypedArray:
switch (node->child1().useKind()) {
case Int32Use:
read(HeapObjectCount);
write(HeapObjectCount);
return;
case UntypedUse:
read(World);
write(Heap);
return;
default:
DFG_CRASH(graph, node, "Bad use kind");
}
break;
case NewArrayWithSpread: {
read(HeapObjectCount);
// This appears to read nothing because it's only reading immutable butterfly data.
for (unsigned i = 0; i < node->numChildren(); i++) {
Node* child = graph.varArgChild(node, i).node();
if (child->op() == PhantomSpread) {
read(Stack);
break;
}
}
write(HeapObjectCount);
return;
}
case Spread: {
if (node->child1()->op() == PhantomNewArrayBuffer) {
read(MiscFields);
return;
}
if (node->child1()->op() == PhantomCreateRest) {
read(Stack);
write(HeapObjectCount);
return;
}
read(World);
write(Heap);
return;
}
case NewArray: {
read(HeapObjectCount);
write(HeapObjectCount);
unsigned numElements = node->numChildren();
def(HeapLocation(ArrayLengthLoc, Butterfly_publicLength, node),
LazyNode(graph.freeze(jsNumber(numElements))));
if (!numElements)
return;
AbstractHeap heap;
LocationKind indexedPropertyLoc;
switch (node->indexingType()) {
case ALL_DOUBLE_INDEXING_TYPES:
heap = IndexedDoubleProperties;
indexedPropertyLoc = IndexedPropertyDoubleLoc;
break;
case ALL_INT32_INDEXING_TYPES:
heap = IndexedInt32Properties;
indexedPropertyLoc = IndexedPropertyJSLoc;
break;
case ALL_CONTIGUOUS_INDEXING_TYPES:
heap = IndexedContiguousProperties;
indexedPropertyLoc = IndexedPropertyJSLoc;
break;
default:
return;
}
if (numElements < graph.m_uint32ValuesInUse.size()) {
for (unsigned operandIdx = 0; operandIdx < numElements; ++operandIdx) {
Edge use = graph.m_varArgChildren[node->firstChild() + operandIdx];
def(HeapLocation(indexedPropertyLoc, heap, node, LazyNode(graph.freeze(jsNumber(operandIdx)))),
LazyNode(use.node()));
}
} else {
for (uint32_t operandIdx : graph.m_uint32ValuesInUse) {
if (operandIdx >= numElements)
continue;
Edge use = graph.m_varArgChildren[node->firstChild() + operandIdx];
// operandIdx comes from graph.m_uint32ValuesInUse and thus is guaranteed to be already frozen
def(HeapLocation(indexedPropertyLoc, heap, node, LazyNode(graph.freeze(jsNumber(operandIdx)))),
LazyNode(use.node()));
}
}
return;
}
case NewArrayBuffer: {
read(HeapObjectCount);
write(HeapObjectCount);
auto* array = node->castOperand<JSImmutableButterfly*>();
unsigned numElements = array->length();
def(HeapLocation(ArrayLengthLoc, Butterfly_publicLength, node),
LazyNode(graph.freeze(jsNumber(numElements))));
AbstractHeap heap;
LocationKind indexedPropertyLoc;
NodeType op = JSConstant;
switch (node->indexingType()) {
case ALL_DOUBLE_INDEXING_TYPES:
heap = IndexedDoubleProperties;
indexedPropertyLoc = IndexedPropertyDoubleLoc;
op = DoubleConstant;
break;
case ALL_INT32_INDEXING_TYPES:
heap = IndexedInt32Properties;
indexedPropertyLoc = IndexedPropertyJSLoc;
break;
case ALL_CONTIGUOUS_INDEXING_TYPES:
heap = IndexedContiguousProperties;
indexedPropertyLoc = IndexedPropertyJSLoc;
break;
default:
return;
}
if (numElements < graph.m_uint32ValuesInUse.size()) {
for (unsigned index = 0; index < numElements; ++index) {
def(HeapLocation(indexedPropertyLoc, heap, node, LazyNode(graph.freeze(jsNumber(index)))),
LazyNode(graph.freeze(array->get(index)), op));
}
} else {
Vector<uint32_t> possibleIndices;
for (uint32_t index : graph.m_uint32ValuesInUse) {
if (index >= numElements)
continue;
possibleIndices.append(index);
}
for (uint32_t index : possibleIndices) {
def(HeapLocation(indexedPropertyLoc, heap, node, LazyNode(graph.freeze(jsNumber(index)))),
LazyNode(graph.freeze(array->get(index)), op));
}
}
return;
}
case CreateRest: {
if (!graph.isWatchingHavingABadTimeWatchpoint(node)) {
// This means we're already having a bad time.
read(World);
write(Heap);
return;
}
read(Stack);
read(HeapObjectCount);
write(HeapObjectCount);
return;
}
case ObjectCreate: {
switch (node->child1().useKind()) {
case ObjectUse:
read(HeapObjectCount);
write(HeapObjectCount);
return;
case UntypedUse:
read(World);
write(Heap);
return;
default:
RELEASE_ASSERT_NOT_REACHED();
return;
}
}
case NewObject:
case NewPromise:
case NewGenerator:
case NewAsyncGenerator:
case NewArrayIterator:
case NewRegexp:
case NewSymbol:
case NewStringObject:
case PhantomNewObject:
case MaterializeNewObject:
case PhantomNewFunction:
case PhantomNewGeneratorFunction:
case PhantomNewAsyncFunction:
case PhantomNewAsyncGeneratorFunction:
case PhantomNewArrayIterator:
case MaterializeNewInternalFieldObject:
case PhantomCreateActivation:
case MaterializeCreateActivation:
case PhantomNewRegexp:
read(HeapObjectCount);
write(HeapObjectCount);
return;
case NewFunction:
case NewGeneratorFunction:
case NewAsyncGeneratorFunction:
case NewAsyncFunction:
if (node->castOperand<FunctionExecutable*>()->singleton().isStillValid())
write(Watchpoint_fire);
read(HeapObjectCount);
write(HeapObjectCount);
return;
case RegExpExec:
case RegExpTest:
// Even if we've proven known input types as RegExpObject and String,
// accessing lastIndex is effectful if it's a global regexp.
read(World);
write(Heap);
return;
case RegExpMatchFast:
read(RegExpState);
read(RegExpObject_lastIndex);
write(RegExpState);
write(RegExpObject_lastIndex);
return;
case RegExpExecNonGlobalOrSticky:
case RegExpMatchFastGlobal:
read(RegExpState);
write(RegExpState);
return;
case StringReplace:
case StringReplaceRegExp:
if (node->child1().useKind() == StringUse
&& node->child2().useKind() == RegExpObjectUse
&& node->child3().useKind() == StringUse) {
read(RegExpState);
read(RegExpObject_lastIndex);
write(RegExpState);
write(RegExpObject_lastIndex);
return;
}
read(World);
write(Heap);
return;
case StringCharAt:
if (node->arrayMode().isOutOfBounds()) {
read(World);
write(Heap);
return;
}
def(PureValue(node));
return;
case CompareBelow:
case CompareBelowEq:
def(PureValue(node));
return;
case CompareEq:
case CompareLess:
case CompareLessEq:
case CompareGreater:
case CompareGreaterEq:
if (node->isBinaryUseKind(StringUse)) {
read(HeapObjectCount);
write(HeapObjectCount);
return;
}
if (node->isBinaryUseKind(UntypedUse)) {
read(World);
write(Heap);
return;
}
def(PureValue(node));
return;
case ToString:
case CallStringConstructor:
switch (node->child1().useKind()) {
case CellUse:
case UntypedUse:
read(World);
write(Heap);
return;
case StringObjectUse:
case StringOrStringObjectUse:
// These two StringObjectUse's are pure because if we emit this node with either
// of these UseKinds, we'll first emit a StructureCheck ensuring that we're the
// original String or StringObject structure. Therefore, we don't have an overridden
// valueOf, etc.
case Int32Use:
case Int52RepUse:
case DoubleRepUse:
case NotCellUse:
def(PureValue(node));
return;
default:
RELEASE_ASSERT_NOT_REACHED();
return;
}
case CountExecution:
case SuperSamplerBegin:
case SuperSamplerEnd:
read(InternalState);
write(InternalState);
return;
case LogShadowChickenPrologue:
case LogShadowChickenTail:
write(SideState);
return;
case MapHash:
def(PureValue(node));
return;
case NormalizeMapKey:
def(PureValue(node));
return;
case GetMapBucket: {
Edge& mapEdge = node->child1();
Edge& keyEdge = node->child2();
AbstractHeapKind heap = (mapEdge.useKind() == MapObjectUse) ? JSMapFields : JSSetFields;
read(heap);
def(HeapLocation(MapBucketLoc, heap, mapEdge, keyEdge), LazyNode(node));
return;
}
case GetMapBucketHead: {
Edge& mapEdge = node->child1();
AbstractHeapKind heap = (mapEdge.useKind() == MapObjectUse) ? JSMapFields : JSSetFields;
read(heap);
def(HeapLocation(MapBucketHeadLoc, heap, mapEdge), LazyNode(node));
return;
}
case GetMapBucketNext: {
AbstractHeapKind heap = (node->bucketOwnerType() == BucketOwnerType::Map) ? JSMapFields : JSSetFields;
read(heap);
Edge& bucketEdge = node->child1();
def(HeapLocation(MapBucketNextLoc, heap, bucketEdge), LazyNode(node));
return;
}
case LoadKeyFromMapBucket: {
AbstractHeapKind heap = (node->bucketOwnerType() == BucketOwnerType::Map) ? JSMapFields : JSSetFields;
read(heap);
Edge& bucketEdge = node->child1();
def(HeapLocation(MapBucketKeyLoc, heap, bucketEdge), LazyNode(node));
return;
}
case LoadValueFromMapBucket: {
AbstractHeapKind heap = (node->bucketOwnerType() == BucketOwnerType::Map) ? JSMapFields : JSSetFields;
read(heap);
Edge& bucketEdge = node->child1();
def(HeapLocation(MapBucketValueLoc, heap, bucketEdge), LazyNode(node));
return;
}
case WeakMapGet: {
Edge& mapEdge = node->child1();
Edge& keyEdge = node->child2();
AbstractHeapKind heap = (mapEdge.useKind() == WeakMapObjectUse) ? JSWeakMapFields : JSWeakSetFields;
read(heap);
def(HeapLocation(WeakMapGetLoc, heap, mapEdge, keyEdge), LazyNode(node));
return;
}
case SetAdd: {
Edge& mapEdge = node->child1();
Edge& keyEdge = node->child2();
write(JSSetFields);
def(HeapLocation(MapBucketLoc, JSSetFields, mapEdge, keyEdge), LazyNode(node));
return;
}
case MapSet: {
Edge& mapEdge = graph.varArgChild(node, 0);
Edge& keyEdge = graph.varArgChild(node, 1);
write(JSMapFields);
def(HeapLocation(MapBucketLoc, JSMapFields, mapEdge, keyEdge), LazyNode(node));
return;
}
case WeakSetAdd: {
Edge& mapEdge = node->child1();
Edge& keyEdge = node->child2();
write(JSWeakSetFields);
def(HeapLocation(WeakMapGetLoc, JSWeakSetFields, mapEdge, keyEdge), LazyNode(keyEdge.node()));
return;
}
case WeakMapSet: {
Edge& mapEdge = graph.varArgChild(node, 0);
Edge& keyEdge = graph.varArgChild(node, 1);
Edge& valueEdge = graph.varArgChild(node, 2);
write(JSWeakMapFields);
def(HeapLocation(WeakMapGetLoc, JSWeakMapFields, mapEdge, keyEdge), LazyNode(valueEdge.node()));
return;
}
case ExtractValueFromWeakMapGet:
def(PureValue(node));
return;
case StringSlice:
def(PureValue(node));
return;
case ToLowerCase:
def(PureValue(node));
return;
case NumberToStringWithValidRadixConstant:
def(PureValue(node, node->validRadixConstant()));
return;
case DateGetTime:
case DateGetInt32OrNaN: {
read(JSDateFields);
def(HeapLocation(DateFieldLoc, AbstractHeap(JSDateFields, static_cast<uint64_t>(node->intrinsic())), node->child1()), LazyNode(node));
return;
}
case DataViewGetFloat:
case DataViewGetInt: {
read(MiscFields);
read(TypedArrayProperties);
LocationKind indexedPropertyLoc = indexedPropertyLocForResultType(node->result());
def(HeapLocation(indexedPropertyLoc, AbstractHeap(TypedArrayProperties, node->dataViewData().asQuadWord),
node->child1(), node->child2(), node->child3()), LazyNode(node));
return;
}
case DataViewSet: {
read(MiscFields);
read(TypedArrayProperties);
write(TypedArrayProperties);
return;
}
case LastNodeType:
RELEASE_ASSERT_NOT_REACHED();
return;
}
DFG_CRASH(graph, node, toCString("Unrecognized node type: ", Graph::opName(node->op())).data());
}
class NoOpClobberize {
public:
NoOpClobberize() { }
template<typename... T>
void operator()(T...) const { }
};
class CheckClobberize {
public:
CheckClobberize()
: m_result(false)
{
}
template<typename... T>
void operator()(T...) const { m_result = true; }
bool result() const { return m_result; }
private:
mutable bool m_result;
};
bool doesWrites(Graph&, Node*);
class AbstractHeapOverlaps {
public:
AbstractHeapOverlaps(AbstractHeap heap)
: m_heap(heap)
, m_result(false)
{
}
void operator()(AbstractHeap otherHeap) const
{
if (m_result)
return;
m_result = m_heap.overlaps(otherHeap);
}
bool result() const { return m_result; }
private:
AbstractHeap m_heap;
mutable bool m_result;
};
bool accessesOverlap(Graph&, Node*, AbstractHeap);
bool writesOverlap(Graph&, Node*, AbstractHeap);
bool clobbersHeap(Graph&, Node*);
// We would have used bind() for these, but because of the overlaoding that we are doing,
// it's quite a bit of clearer to just write this out the traditional way.
template<typename T>
class ReadMethodClobberize {
public:
ReadMethodClobberize(T& value)
: m_value(value)
{
}
void operator()(AbstractHeap heap) const
{
m_value.read(heap);
}
private:
T& m_value;
};
template<typename T>
class WriteMethodClobberize {
public:
WriteMethodClobberize(T& value)
: m_value(value)
{
}
void operator()(AbstractHeap heap) const
{
m_value.write(heap);
}
private:
T& m_value;
};
template<typename T>
class DefMethodClobberize {
public:
DefMethodClobberize(T& value)
: m_value(value)
{
}
void operator()(PureValue value) const
{
m_value.def(value);
}
void operator()(HeapLocation location, LazyNode node) const
{
m_value.def(location, node);
}
private:
T& m_value;
};
template<typename Adaptor>
void clobberize(Graph& graph, Node* node, Adaptor& adaptor)
{
ReadMethodClobberize<Adaptor> read(adaptor);
WriteMethodClobberize<Adaptor> write(adaptor);
DefMethodClobberize<Adaptor> def(adaptor);
clobberize(graph, node, read, write, def);
}
} } // namespace JSC::DFG
#endif // ENABLE(DFG_JIT)