| /* |
| * 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 "FTLLowerDFGToB3.h" |
| |
| #if ENABLE(FTL_JIT) |
| |
| #include "AirCode.h" |
| #include "AirGenerationContext.h" |
| #include "AllowMacroScratchRegisterUsage.h" |
| #include "AllowMacroScratchRegisterUsageIf.h" |
| #include "AtomicsObject.h" |
| #include "B3CheckValue.h" |
| #include "B3FenceValue.h" |
| #include "B3PatchpointValue.h" |
| #include "B3SlotBaseValue.h" |
| #include "B3StackmapGenerationParams.h" |
| #include "B3ValueInlines.h" |
| #include "CallFrameShuffler.h" |
| #include "CodeBlockWithJITType.h" |
| #include "DFGAbstractInterpreterInlines.h" |
| #include "DFGCapabilities.h" |
| #include "DFGDominators.h" |
| #include "DFGInPlaceAbstractState.h" |
| #include "DFGOSRAvailabilityAnalysisPhase.h" |
| #include "DFGOSRExitFuzz.h" |
| #include "DirectArguments.h" |
| #include "FTLAbstractHeapRepository.h" |
| #include "FTLAvailableRecovery.h" |
| #include "FTLExceptionTarget.h" |
| #include "FTLForOSREntryJITCode.h" |
| #include "FTLFormattedValue.h" |
| #include "FTLLazySlowPathCall.h" |
| #include "FTLLoweredNodeValue.h" |
| #include "FTLOperations.h" |
| #include "FTLOutput.h" |
| #include "FTLPatchpointExceptionHandle.h" |
| #include "FTLSnippetParams.h" |
| #include "FTLThunks.h" |
| #include "FTLWeightedTarget.h" |
| #include "JITAddGenerator.h" |
| #include "JITBitAndGenerator.h" |
| #include "JITBitOrGenerator.h" |
| #include "JITBitXorGenerator.h" |
| #include "JITDivGenerator.h" |
| #include "JITInlineCacheGenerator.h" |
| #include "JITLeftShiftGenerator.h" |
| #include "JITMathIC.h" |
| #include "JITMulGenerator.h" |
| #include "JITRightShiftGenerator.h" |
| #include "JITSubGenerator.h" |
| #include "JSAsyncFunction.h" |
| #include "JSAsyncGeneratorFunction.h" |
| #include "JSCInlines.h" |
| #include "JSGeneratorFunction.h" |
| #include "JSLexicalEnvironment.h" |
| #include "JSMap.h" |
| #include "OperandsInlines.h" |
| #include "RegExpObject.h" |
| #include "ScopedArguments.h" |
| #include "ScopedArgumentsTable.h" |
| #include "ScratchRegisterAllocator.h" |
| #include "SetupVarargsFrame.h" |
| #include "ShadowChicken.h" |
| #include "StructureStubInfo.h" |
| #include "SuperSampler.h" |
| #include "ThunkGenerators.h" |
| #include "VirtualRegister.h" |
| #include "Watchdog.h" |
| #include <atomic> |
| #include <wtf/Box.h> |
| #include <wtf/Gigacage.h> |
| #include <wtf/RecursableLambda.h> |
| #include <wtf/StdUnorderedSet.h> |
| |
| #undef RELEASE_ASSERT |
| #define RELEASE_ASSERT(assertion) do { \ |
| if (!(assertion)) { \ |
| WTFReportAssertionFailure(__FILE__, __LINE__, WTF_PRETTY_FUNCTION, #assertion); \ |
| CRASH(); \ |
| } \ |
| } while (0) |
| |
| namespace JSC { namespace FTL { |
| |
| using namespace B3; |
| using namespace DFG; |
| |
| namespace { |
| |
| std::atomic<int> compileCounter; |
| |
| #if !ASSERT_DISABLED |
| NO_RETURN_DUE_TO_CRASH static void ftlUnreachable( |
| CodeBlock* codeBlock, BlockIndex blockIndex, unsigned nodeIndex) |
| { |
| dataLog("Crashing in thought-to-be-unreachable FTL-generated code for ", pointerDump(codeBlock), " at basic block #", blockIndex); |
| if (nodeIndex != UINT_MAX) |
| dataLog(", node @", nodeIndex); |
| dataLog(".\n"); |
| CRASH(); |
| } |
| #endif |
| |
| // Using this instead of typeCheck() helps to reduce the load on B3, by creating |
| // significantly less dead code. |
| #define FTL_TYPE_CHECK_WITH_EXIT_KIND(exitKind, lowValue, highValue, typesPassedThrough, failCondition) do { \ |
| FormattedValue _ftc_lowValue = (lowValue); \ |
| Edge _ftc_highValue = (highValue); \ |
| SpeculatedType _ftc_typesPassedThrough = (typesPassedThrough); \ |
| if (!m_interpreter.needsTypeCheck(_ftc_highValue, _ftc_typesPassedThrough)) \ |
| break; \ |
| typeCheck(_ftc_lowValue, _ftc_highValue, _ftc_typesPassedThrough, (failCondition), exitKind); \ |
| } while (false) |
| |
| #define FTL_TYPE_CHECK(lowValue, highValue, typesPassedThrough, failCondition) \ |
| FTL_TYPE_CHECK_WITH_EXIT_KIND(BadType, lowValue, highValue, typesPassedThrough, failCondition) |
| |
| class LowerDFGToB3 { |
| WTF_MAKE_NONCOPYABLE(LowerDFGToB3); |
| public: |
| LowerDFGToB3(State& state) |
| : m_graph(state.graph) |
| , m_ftlState(state) |
| , m_out(state) |
| , m_proc(*state.proc) |
| , m_availabilityCalculator(m_graph) |
| , m_state(state.graph) |
| , m_interpreter(state.graph, m_state) |
| , m_indexMaskingMode(Options::enableSpectreMitigations() ? IndexMaskingEnabled : IndexMaskingDisabled) |
| { |
| } |
| |
| void lower() |
| { |
| State* state = &m_ftlState; |
| |
| CString name; |
| if (verboseCompilationEnabled()) { |
| name = toCString( |
| "jsBody_", ++compileCounter, "_", codeBlock()->inferredName(), |
| "_", codeBlock()->hash()); |
| } else |
| name = "jsBody"; |
| |
| { |
| m_proc.setNumEntrypoints(m_graph.m_numberOfEntrypoints); |
| CodeBlock* codeBlock = m_graph.m_codeBlock; |
| |
| Ref<B3::Air::PrologueGenerator> catchPrologueGenerator = createSharedTask<B3::Air::PrologueGeneratorFunction>( |
| [codeBlock] (CCallHelpers& jit, B3::Air::Code& code) { |
| AllowMacroScratchRegisterUsage allowScratch(jit); |
| jit.addPtr(CCallHelpers::TrustedImm32(-code.frameSize()), GPRInfo::callFrameRegister, CCallHelpers::stackPointerRegister); |
| if (Options::zeroStackFrame()) |
| jit.clearStackFrame(GPRInfo::callFrameRegister, CCallHelpers::stackPointerRegister, GPRInfo::regT0, code.frameSize()); |
| |
| jit.emitSave(code.calleeSaveRegisterAtOffsetList()); |
| jit.emitPutToCallFrameHeader(codeBlock, CallFrameSlot::codeBlock); |
| }); |
| |
| for (unsigned catchEntrypointIndex : m_graph.m_entrypointIndexToCatchBytecodeOffset.keys()) { |
| RELEASE_ASSERT(catchEntrypointIndex != 0); |
| m_proc.code().setPrologueForEntrypoint(catchEntrypointIndex, catchPrologueGenerator.copyRef()); |
| } |
| |
| if (m_graph.m_maxLocalsForCatchOSREntry) { |
| uint32_t numberOfLiveLocals = std::max(*m_graph.m_maxLocalsForCatchOSREntry, 1u); // Make sure we always allocate a non-null catchOSREntryBuffer. |
| m_ftlState.jitCode->common.catchOSREntryBuffer = m_graph.m_vm.scratchBufferForSize(sizeof(JSValue) * numberOfLiveLocals); |
| } |
| } |
| |
| m_graph.ensureSSADominators(); |
| |
| if (verboseCompilationEnabled()) |
| dataLog("Function ready, beginning lowering.\n"); |
| |
| m_out.initialize(m_heaps); |
| |
| // We use prologue frequency for all of the initialization code. |
| m_out.setFrequency(1); |
| |
| bool hasMultipleEntrypoints = m_graph.m_numberOfEntrypoints > 1; |
| |
| LBasicBlock prologue = m_out.newBlock(); |
| LBasicBlock callEntrypointArgumentSpeculations = hasMultipleEntrypoints ? m_out.newBlock() : nullptr; |
| m_handleExceptions = m_out.newBlock(); |
| |
| for (BlockIndex blockIndex = 0; blockIndex < m_graph.numBlocks(); ++blockIndex) { |
| m_highBlock = m_graph.block(blockIndex); |
| if (!m_highBlock) |
| continue; |
| m_out.setFrequency(m_highBlock->executionCount); |
| m_blocks.add(m_highBlock, m_out.newBlock()); |
| } |
| |
| // Back to prologue frequency for any bocks that get sneakily created in the initialization code. |
| m_out.setFrequency(1); |
| |
| m_out.appendTo(prologue, hasMultipleEntrypoints ? callEntrypointArgumentSpeculations : m_handleExceptions); |
| m_out.initializeConstants(m_proc, prologue); |
| createPhiVariables(); |
| |
| size_t sizeOfCaptured = sizeof(JSValue) * m_graph.m_nextMachineLocal; |
| B3::SlotBaseValue* capturedBase = m_out.lockedStackSlot(sizeOfCaptured); |
| m_captured = m_out.add(capturedBase, m_out.constIntPtr(sizeOfCaptured)); |
| state->capturedValue = capturedBase->slot(); |
| |
| auto preOrder = m_graph.blocksInPreOrder(); |
| |
| m_callFrame = m_out.framePointer(); |
| m_tagTypeNumber = m_out.constInt64(TagTypeNumber); |
| m_tagMask = m_out.constInt64(TagMask); |
| |
| // Make sure that B3 knows that we really care about the mask registers. This forces the |
| // constants to be materialized in registers. |
| m_proc.addFastConstant(m_tagTypeNumber->key()); |
| m_proc.addFastConstant(m_tagMask->key()); |
| |
| // We don't want the CodeBlock to have a weak pointer to itself because |
| // that would cause it to always get collected. |
| m_out.storePtr(m_out.constIntPtr(bitwise_cast<intptr_t>(codeBlock())), addressFor(CallFrameSlot::codeBlock)); |
| |
| VM* vm = &this->vm(); |
| |
| // Stack Overflow Check. |
| unsigned exitFrameSize = m_graph.requiredRegisterCountForExit() * sizeof(Register); |
| MacroAssembler::AbsoluteAddress addressOfStackLimit(vm->addressOfSoftStackLimit()); |
| PatchpointValue* stackOverflowHandler = m_out.patchpoint(Void); |
| CallSiteIndex callSiteIndex = callSiteIndexForCodeOrigin(m_ftlState, CodeOrigin(0)); |
| stackOverflowHandler->appendSomeRegister(m_callFrame); |
| stackOverflowHandler->clobber(RegisterSet::macroScratchRegisters()); |
| stackOverflowHandler->numGPScratchRegisters = 1; |
| stackOverflowHandler->setGenerator( |
| [=] (CCallHelpers& jit, const StackmapGenerationParams& params) { |
| AllowMacroScratchRegisterUsage allowScratch(jit); |
| GPRReg fp = params[0].gpr(); |
| GPRReg scratch = params.gpScratch(0); |
| |
| unsigned ftlFrameSize = params.proc().frameSize(); |
| unsigned maxFrameSize = std::max(exitFrameSize, ftlFrameSize); |
| |
| jit.addPtr(MacroAssembler::TrustedImm32(-maxFrameSize), fp, scratch); |
| MacroAssembler::JumpList stackOverflow; |
| if (UNLIKELY(maxFrameSize > Options::reservedZoneSize())) |
| stackOverflow.append(jit.branchPtr(MacroAssembler::Above, scratch, fp)); |
| stackOverflow.append(jit.branchPtr(MacroAssembler::Above, addressOfStackLimit, scratch)); |
| |
| params.addLatePath([=] (CCallHelpers& jit) { |
| AllowMacroScratchRegisterUsage allowScratch(jit); |
| |
| stackOverflow.link(&jit); |
| |
| // FIXME: We would not have to do this if the stack check was part of the Air |
| // prologue. Then, we would know that there is no way for the callee-saves to |
| // get clobbered. |
| // https://bugs.webkit.org/show_bug.cgi?id=172456 |
| jit.emitRestore(params.proc().calleeSaveRegisterAtOffsetList()); |
| |
| jit.store32( |
| MacroAssembler::TrustedImm32(callSiteIndex.bits()), |
| CCallHelpers::tagFor(VirtualRegister(CallFrameSlot::argumentCount))); |
| jit.copyCalleeSavesToEntryFrameCalleeSavesBuffer(vm->topEntryFrame); |
| |
| jit.move(GPRInfo::callFrameRegister, GPRInfo::argumentGPR0); |
| jit.move(CCallHelpers::TrustedImmPtr(jit.codeBlock()), GPRInfo::argumentGPR1); |
| CCallHelpers::Call throwCall = jit.call(OperationPtrTag); |
| |
| jit.move(CCallHelpers::TrustedImmPtr(vm), GPRInfo::argumentGPR0); |
| jit.move(GPRInfo::callFrameRegister, GPRInfo::argumentGPR1); |
| CCallHelpers::Call lookupExceptionHandlerCall = jit.call(OperationPtrTag); |
| jit.jumpToExceptionHandler(*vm); |
| |
| jit.addLinkTask( |
| [=] (LinkBuffer& linkBuffer) { |
| linkBuffer.link(throwCall, FunctionPtr<OperationPtrTag>(operationThrowStackOverflowError)); |
| linkBuffer.link(lookupExceptionHandlerCall, FunctionPtr<OperationPtrTag>(lookupExceptionHandlerFromCallerFrame)); |
| }); |
| }); |
| }); |
| |
| LBasicBlock firstDFGBasicBlock = lowBlock(m_graph.block(0)); |
| |
| { |
| if (hasMultipleEntrypoints) { |
| Vector<LBasicBlock> successors(m_graph.m_numberOfEntrypoints); |
| successors[0] = callEntrypointArgumentSpeculations; |
| for (unsigned i = 1; i < m_graph.m_numberOfEntrypoints; ++i) { |
| // Currently, the only other entrypoint is an op_catch entrypoint. |
| // We do OSR entry at op_catch, and we prove argument formats before |
| // jumping to FTL code, so we don't need to check argument types here |
| // for these entrypoints. |
| successors[i] = firstDFGBasicBlock; |
| } |
| |
| m_out.entrySwitch(successors); |
| m_out.appendTo(callEntrypointArgumentSpeculations, m_handleExceptions); |
| } |
| |
| m_node = nullptr; |
| m_origin = NodeOrigin(CodeOrigin(0), CodeOrigin(0), true); |
| |
| // Check Arguments. |
| availabilityMap().clear(); |
| availabilityMap().m_locals = Operands<Availability>(codeBlock()->numParameters(), 0); |
| for (unsigned i = codeBlock()->numParameters(); i--;) { |
| availabilityMap().m_locals.argument(i) = |
| Availability(FlushedAt(FlushedJSValue, virtualRegisterForArgument(i))); |
| } |
| |
| for (unsigned i = codeBlock()->numParameters(); i--;) { |
| MethodOfGettingAValueProfile profile(&m_graph.m_profiledBlock->valueProfileForArgument(i)); |
| VirtualRegister operand = virtualRegisterForArgument(i); |
| LValue jsValue = m_out.load64(addressFor(operand)); |
| |
| switch (m_graph.m_argumentFormats[0][i]) { |
| case FlushedInt32: |
| speculate(BadType, jsValueValue(jsValue), profile, isNotInt32(jsValue)); |
| break; |
| case FlushedBoolean: |
| speculate(BadType, jsValueValue(jsValue), profile, isNotBoolean(jsValue)); |
| break; |
| case FlushedCell: |
| speculate(BadType, jsValueValue(jsValue), profile, isNotCell(jsValue)); |
| break; |
| case FlushedJSValue: |
| break; |
| default: |
| DFG_CRASH(m_graph, nullptr, "Bad flush format for argument"); |
| break; |
| } |
| } |
| m_out.jump(firstDFGBasicBlock); |
| } |
| |
| |
| m_out.appendTo(m_handleExceptions, firstDFGBasicBlock); |
| Box<CCallHelpers::Label> exceptionHandler = state->exceptionHandler; |
| m_out.patchpoint(Void)->setGenerator( |
| [=] (CCallHelpers& jit, const StackmapGenerationParams&) { |
| CCallHelpers::Jump jump = jit.jump(); |
| jit.addLinkTask( |
| [=] (LinkBuffer& linkBuffer) { |
| linkBuffer.link(jump, linkBuffer.locationOf<ExceptionHandlerPtrTag>(*exceptionHandler)); |
| }); |
| }); |
| m_out.unreachable(); |
| |
| for (DFG::BasicBlock* block : preOrder) |
| compileBlock(block); |
| |
| // Make sure everything is decorated. This does a bunch of deferred decorating. This has |
| // to happen last because our abstract heaps are generated lazily. They have to be |
| // generated lazily because we have an infinite number of numbered, indexed, and |
| // absolute heaps. We only become aware of the ones we actually mention while lowering. |
| m_heaps.computeRangesAndDecorateInstructions(); |
| |
| // We create all Phi's up front, but we may then decide not to compile the basic block |
| // that would have contained one of them. So this creates orphans, which triggers B3 |
| // validation failures. Calling this fixes the issue. |
| // |
| // Note that you should avoid the temptation to make this call conditional upon |
| // validation being enabled. B3 makes no guarantees of any kind of correctness when |
| // dealing with IR that would have failed validation. For example, it would be valid to |
| // write a B3 phase that so aggressively assumes the lack of orphans that it would crash |
| // if any orphans were around. We might even have such phases already. |
| m_proc.deleteOrphans(); |
| |
| // We put the blocks into the B3 procedure in a super weird order. Now we reorder them. |
| m_out.applyBlockOrder(); |
| } |
| |
| private: |
| |
| void createPhiVariables() |
| { |
| for (BlockIndex blockIndex = m_graph.numBlocks(); blockIndex--;) { |
| DFG::BasicBlock* block = m_graph.block(blockIndex); |
| if (!block) |
| continue; |
| for (unsigned nodeIndex = block->size(); nodeIndex--;) { |
| Node* node = block->at(nodeIndex); |
| if (node->op() != DFG::Phi) |
| continue; |
| LType type; |
| switch (node->flags() & NodeResultMask) { |
| case NodeResultDouble: |
| type = Double; |
| break; |
| case NodeResultInt32: |
| type = Int32; |
| break; |
| case NodeResultInt52: |
| type = Int64; |
| break; |
| case NodeResultBoolean: |
| type = Int32; |
| break; |
| case NodeResultJS: |
| type = Int64; |
| break; |
| default: |
| DFG_CRASH(m_graph, node, "Bad Phi node result type"); |
| break; |
| } |
| m_phis.add(node, m_proc.add<Value>(B3::Phi, type, Origin(node))); |
| } |
| } |
| } |
| |
| void compileBlock(DFG::BasicBlock* block) |
| { |
| if (!block) |
| return; |
| |
| if (verboseCompilationEnabled()) |
| dataLog("Compiling block ", *block, "\n"); |
| |
| m_highBlock = block; |
| |
| // Make sure that any blocks created while lowering code in the high block have the frequency of |
| // the high block. This is appropriate because B3 doesn't need precise frequencies. It just needs |
| // something roughly approximate for things like register allocation. |
| m_out.setFrequency(m_highBlock->executionCount); |
| |
| LBasicBlock lowBlock = m_blocks.get(m_highBlock); |
| |
| m_nextHighBlock = 0; |
| for (BlockIndex nextBlockIndex = m_highBlock->index + 1; nextBlockIndex < m_graph.numBlocks(); ++nextBlockIndex) { |
| m_nextHighBlock = m_graph.block(nextBlockIndex); |
| if (m_nextHighBlock) |
| break; |
| } |
| m_nextLowBlock = m_nextHighBlock ? m_blocks.get(m_nextHighBlock) : 0; |
| |
| // All of this effort to find the next block gives us the ability to keep the |
| // generated IR in roughly program order. This ought not affect the performance |
| // of the generated code (since we expect B3 to reorder things) but it will |
| // make IR dumps easier to read. |
| m_out.appendTo(lowBlock, m_nextLowBlock); |
| |
| if (Options::ftlCrashes()) |
| m_out.trap(); |
| |
| if (!m_highBlock->cfaHasVisited) { |
| if (verboseCompilationEnabled()) |
| dataLog("Bailing because CFA didn't reach.\n"); |
| crash(m_highBlock, nullptr); |
| return; |
| } |
| |
| m_availabilityCalculator.beginBlock(m_highBlock); |
| |
| m_state.reset(); |
| m_state.beginBasicBlock(m_highBlock); |
| |
| for (m_nodeIndex = 0; m_nodeIndex < m_highBlock->size(); ++m_nodeIndex) { |
| if (!compileNode(m_nodeIndex)) |
| break; |
| } |
| } |
| |
| void safelyInvalidateAfterTermination() |
| { |
| if (verboseCompilationEnabled()) |
| dataLog("Bailing.\n"); |
| crash(); |
| |
| // Invalidate dominated blocks. Under normal circumstances we would expect |
| // them to be invalidated already. But you can have the CFA become more |
| // precise over time because the structures of objects change on the main |
| // thread. Failing to do this would result in weird crashes due to a value |
| // being used but not defined. Race conditions FTW! |
| for (BlockIndex blockIndex = m_graph.numBlocks(); blockIndex--;) { |
| DFG::BasicBlock* target = m_graph.block(blockIndex); |
| if (!target) |
| continue; |
| if (m_graph.m_ssaDominators->dominates(m_highBlock, target)) { |
| if (verboseCompilationEnabled()) |
| dataLog("Block ", *target, " will bail also.\n"); |
| target->cfaHasVisited = false; |
| } |
| } |
| } |
| |
| bool compileNode(unsigned nodeIndex) |
| { |
| if (!m_state.isValid()) { |
| safelyInvalidateAfterTermination(); |
| return false; |
| } |
| |
| m_node = m_highBlock->at(nodeIndex); |
| m_origin = m_node->origin; |
| m_out.setOrigin(m_node); |
| |
| if (verboseCompilationEnabled()) |
| dataLog("Lowering ", m_node, "\n"); |
| |
| m_availableRecoveries.shrink(0); |
| |
| m_interpreter.startExecuting(); |
| m_interpreter.executeKnownEdgeTypes(m_node); |
| |
| switch (m_node->op()) { |
| case DFG::Upsilon: |
| compileUpsilon(); |
| break; |
| case DFG::Phi: |
| compilePhi(); |
| break; |
| case JSConstant: |
| break; |
| case DoubleConstant: |
| compileDoubleConstant(); |
| break; |
| case Int52Constant: |
| compileInt52Constant(); |
| break; |
| case LazyJSConstant: |
| compileLazyJSConstant(); |
| break; |
| case DoubleRep: |
| compileDoubleRep(); |
| break; |
| case DoubleAsInt32: |
| compileDoubleAsInt32(); |
| break; |
| case DFG::ValueRep: |
| compileValueRep(); |
| break; |
| case Int52Rep: |
| compileInt52Rep(); |
| break; |
| case ValueToInt32: |
| compileValueToInt32(); |
| break; |
| case BooleanToNumber: |
| compileBooleanToNumber(); |
| break; |
| case ExtractOSREntryLocal: |
| compileExtractOSREntryLocal(); |
| break; |
| case ExtractCatchLocal: |
| compileExtractCatchLocal(); |
| break; |
| case GetStack: |
| compileGetStack(); |
| break; |
| case PutStack: |
| compilePutStack(); |
| break; |
| case DFG::Check: |
| case CheckVarargs: |
| compileNoOp(); |
| break; |
| case ToObject: |
| case CallObjectConstructor: |
| compileToObjectOrCallObjectConstructor(); |
| break; |
| case ToThis: |
| compileToThis(); |
| break; |
| case ValueAdd: |
| compileValueAdd(); |
| break; |
| case StrCat: |
| compileStrCat(); |
| break; |
| case ArithAdd: |
| case ArithSub: |
| compileArithAddOrSub(); |
| break; |
| case ArithClz32: |
| compileArithClz32(); |
| break; |
| case ArithMul: |
| compileArithMul(); |
| break; |
| case ArithDiv: |
| compileArithDiv(); |
| break; |
| case ArithMod: |
| compileArithMod(); |
| break; |
| case ArithMin: |
| case ArithMax: |
| compileArithMinOrMax(); |
| break; |
| case ArithAbs: |
| compileArithAbs(); |
| break; |
| case ArithPow: |
| compileArithPow(); |
| break; |
| case ArithRandom: |
| compileArithRandom(); |
| break; |
| case ArithRound: |
| compileArithRound(); |
| break; |
| case ArithFloor: |
| compileArithFloor(); |
| break; |
| case ArithCeil: |
| compileArithCeil(); |
| break; |
| case ArithTrunc: |
| compileArithTrunc(); |
| break; |
| case ArithSqrt: |
| compileArithSqrt(); |
| break; |
| case ArithFRound: |
| compileArithFRound(); |
| break; |
| case ArithNegate: |
| compileArithNegate(); |
| break; |
| case ArithUnary: |
| compileArithUnary(); |
| break; |
| case DFG::BitAnd: |
| compileBitAnd(); |
| break; |
| case DFG::BitOr: |
| compileBitOr(); |
| break; |
| case DFG::BitXor: |
| compileBitXor(); |
| break; |
| case BitRShift: |
| compileBitRShift(); |
| break; |
| case BitLShift: |
| compileBitLShift(); |
| break; |
| case BitURShift: |
| compileBitURShift(); |
| break; |
| case UInt32ToNumber: |
| compileUInt32ToNumber(); |
| break; |
| case CheckStructure: |
| compileCheckStructure(); |
| break; |
| case CheckStructureOrEmpty: |
| compileCheckStructureOrEmpty(); |
| break; |
| case CheckCell: |
| compileCheckCell(); |
| break; |
| case CheckNotEmpty: |
| compileCheckNotEmpty(); |
| break; |
| case AssertNotEmpty: |
| compileAssertNotEmpty(); |
| break; |
| case CheckBadCell: |
| compileCheckBadCell(); |
| break; |
| case CheckStringIdent: |
| compileCheckStringIdent(); |
| break; |
| case GetExecutable: |
| compileGetExecutable(); |
| break; |
| case Arrayify: |
| case ArrayifyToStructure: |
| compileArrayify(); |
| break; |
| case PutStructure: |
| compilePutStructure(); |
| break; |
| case TryGetById: |
| compileGetById(AccessType::TryGet); |
| break; |
| case GetById: |
| case GetByIdFlush: |
| compileGetById(AccessType::Get); |
| break; |
| case GetByIdWithThis: |
| compileGetByIdWithThis(); |
| break; |
| case GetByIdDirect: |
| case GetByIdDirectFlush: |
| compileGetById(AccessType::GetDirect); |
| break; |
| case In: |
| compileIn(); |
| break; |
| case HasOwnProperty: |
| compileHasOwnProperty(); |
| break; |
| case PutById: |
| case PutByIdDirect: |
| case PutByIdFlush: |
| compilePutById(); |
| break; |
| case PutByIdWithThis: |
| compilePutByIdWithThis(); |
| break; |
| case PutGetterById: |
| case PutSetterById: |
| compilePutAccessorById(); |
| break; |
| case PutGetterSetterById: |
| compilePutGetterSetterById(); |
| break; |
| case PutGetterByVal: |
| case PutSetterByVal: |
| compilePutAccessorByVal(); |
| break; |
| case DeleteById: |
| compileDeleteById(); |
| break; |
| case DeleteByVal: |
| compileDeleteByVal(); |
| break; |
| case GetButterfly: |
| compileGetButterfly(); |
| break; |
| case ConstantStoragePointer: |
| compileConstantStoragePointer(); |
| break; |
| case GetIndexedPropertyStorage: |
| compileGetIndexedPropertyStorage(); |
| break; |
| case CheckArray: |
| compileCheckArray(); |
| break; |
| case GetArrayLength: |
| compileGetArrayLength(); |
| break; |
| case GetVectorLength: |
| compileGetVectorLength(); |
| break; |
| case CheckInBounds: |
| compileCheckInBounds(); |
| break; |
| case GetByVal: |
| compileGetByVal(); |
| break; |
| case GetMyArgumentByVal: |
| case GetMyArgumentByValOutOfBounds: |
| compileGetMyArgumentByVal(); |
| break; |
| case GetByValWithThis: |
| compileGetByValWithThis(); |
| break; |
| case PutByVal: |
| case PutByValAlias: |
| case PutByValDirect: |
| compilePutByVal(); |
| break; |
| case PutByValWithThis: |
| compilePutByValWithThis(); |
| break; |
| case AtomicsAdd: |
| case AtomicsAnd: |
| case AtomicsCompareExchange: |
| case AtomicsExchange: |
| case AtomicsLoad: |
| case AtomicsOr: |
| case AtomicsStore: |
| case AtomicsSub: |
| case AtomicsXor: |
| compileAtomicsReadModifyWrite(); |
| break; |
| case AtomicsIsLockFree: |
| compileAtomicsIsLockFree(); |
| break; |
| case DefineDataProperty: |
| compileDefineDataProperty(); |
| break; |
| case DefineAccessorProperty: |
| compileDefineAccessorProperty(); |
| break; |
| case ArrayPush: |
| compileArrayPush(); |
| break; |
| case ArrayPop: |
| compileArrayPop(); |
| break; |
| case ArraySlice: |
| compileArraySlice(); |
| break; |
| case ArrayIndexOf: |
| compileArrayIndexOf(); |
| break; |
| case CreateActivation: |
| compileCreateActivation(); |
| break; |
| case PushWithScope: |
| compilePushWithScope(); |
| break; |
| case NewFunction: |
| case NewGeneratorFunction: |
| case NewAsyncGeneratorFunction: |
| case NewAsyncFunction: |
| compileNewFunction(); |
| break; |
| case CreateDirectArguments: |
| compileCreateDirectArguments(); |
| break; |
| case CreateScopedArguments: |
| compileCreateScopedArguments(); |
| break; |
| case CreateClonedArguments: |
| compileCreateClonedArguments(); |
| break; |
| case NewObject: |
| compileNewObject(); |
| break; |
| case NewStringObject: |
| compileNewStringObject(); |
| break; |
| case NewArray: |
| compileNewArray(); |
| break; |
| case NewArrayWithSpread: |
| compileNewArrayWithSpread(); |
| break; |
| case Spread: |
| compileSpread(); |
| break; |
| case NewArrayBuffer: |
| compileNewArrayBuffer(); |
| break; |
| case NewArrayWithSize: |
| compileNewArrayWithSize(); |
| break; |
| case NewTypedArray: |
| compileNewTypedArray(); |
| break; |
| case GetTypedArrayByteOffset: |
| compileGetTypedArrayByteOffset(); |
| break; |
| case GetPrototypeOf: |
| compileGetPrototypeOf(); |
| break; |
| case AllocatePropertyStorage: |
| compileAllocatePropertyStorage(); |
| break; |
| case ReallocatePropertyStorage: |
| compileReallocatePropertyStorage(); |
| break; |
| case NukeStructureAndSetButterfly: |
| compileNukeStructureAndSetButterfly(); |
| break; |
| case ToNumber: |
| compileToNumber(); |
| break; |
| case ToString: |
| case CallStringConstructor: |
| compileToStringOrCallStringConstructor(); |
| break; |
| case ToPrimitive: |
| compileToPrimitive(); |
| break; |
| case MakeRope: |
| compileMakeRope(); |
| break; |
| case StringCharAt: |
| compileStringCharAt(); |
| break; |
| case StringCharCodeAt: |
| compileStringCharCodeAt(); |
| break; |
| case StringFromCharCode: |
| compileStringFromCharCode(); |
| break; |
| case GetByOffset: |
| case GetGetterSetterByOffset: |
| compileGetByOffset(); |
| break; |
| case GetGetter: |
| compileGetGetter(); |
| break; |
| case GetSetter: |
| compileGetSetter(); |
| break; |
| case MultiGetByOffset: |
| compileMultiGetByOffset(); |
| break; |
| case PutByOffset: |
| compilePutByOffset(); |
| break; |
| case MultiPutByOffset: |
| compileMultiPutByOffset(); |
| break; |
| case GetGlobalVar: |
| case GetGlobalLexicalVariable: |
| compileGetGlobalVariable(); |
| break; |
| case PutGlobalVariable: |
| compilePutGlobalVariable(); |
| break; |
| case NotifyWrite: |
| compileNotifyWrite(); |
| break; |
| case GetCallee: |
| compileGetCallee(); |
| break; |
| case GetArgumentCountIncludingThis: |
| compileGetArgumentCountIncludingThis(); |
| break; |
| case SetArgumentCountIncludingThis: |
| compileSetArgumentCountIncludingThis(); |
| break; |
| case GetScope: |
| compileGetScope(); |
| break; |
| case SkipScope: |
| compileSkipScope(); |
| break; |
| case GetGlobalObject: |
| compileGetGlobalObject(); |
| break; |
| case GetGlobalThis: |
| compileGetGlobalThis(); |
| break; |
| case GetClosureVar: |
| compileGetClosureVar(); |
| break; |
| case PutClosureVar: |
| compilePutClosureVar(); |
| break; |
| case GetFromArguments: |
| compileGetFromArguments(); |
| break; |
| case PutToArguments: |
| compilePutToArguments(); |
| break; |
| case GetArgument: |
| compileGetArgument(); |
| break; |
| case CompareEq: |
| compileCompareEq(); |
| break; |
| case CompareStrictEq: |
| compileCompareStrictEq(); |
| break; |
| case CompareLess: |
| compileCompareLess(); |
| break; |
| case CompareLessEq: |
| compileCompareLessEq(); |
| break; |
| case CompareGreater: |
| compileCompareGreater(); |
| break; |
| case CompareGreaterEq: |
| compileCompareGreaterEq(); |
| break; |
| case CompareBelow: |
| compileCompareBelow(); |
| break; |
| case CompareBelowEq: |
| compileCompareBelowEq(); |
| break; |
| case CompareEqPtr: |
| compileCompareEqPtr(); |
| break; |
| case LogicalNot: |
| compileLogicalNot(); |
| break; |
| case Call: |
| case TailCallInlinedCaller: |
| case Construct: |
| compileCallOrConstruct(); |
| break; |
| case DirectCall: |
| case DirectTailCallInlinedCaller: |
| case DirectConstruct: |
| case DirectTailCall: |
| compileDirectCallOrConstruct(); |
| break; |
| case TailCall: |
| compileTailCall(); |
| break; |
| case CallVarargs: |
| case CallForwardVarargs: |
| case TailCallVarargs: |
| case TailCallVarargsInlinedCaller: |
| case TailCallForwardVarargs: |
| case TailCallForwardVarargsInlinedCaller: |
| case ConstructVarargs: |
| case ConstructForwardVarargs: |
| compileCallOrConstructVarargs(); |
| break; |
| case CallEval: |
| compileCallEval(); |
| break; |
| case LoadVarargs: |
| compileLoadVarargs(); |
| break; |
| case ForwardVarargs: |
| compileForwardVarargs(); |
| break; |
| case DFG::Jump: |
| compileJump(); |
| break; |
| case DFG::Branch: |
| compileBranch(); |
| break; |
| case DFG::Switch: |
| compileSwitch(); |
| break; |
| case DFG::EntrySwitch: |
| compileEntrySwitch(); |
| break; |
| case DFG::Return: |
| compileReturn(); |
| break; |
| case ForceOSRExit: |
| compileForceOSRExit(); |
| break; |
| case CPUIntrinsic: |
| #if CPU(X86_64) |
| compileCPUIntrinsic(); |
| #else |
| RELEASE_ASSERT_NOT_REACHED(); |
| #endif |
| break; |
| case Throw: |
| compileThrow(); |
| break; |
| case ThrowStaticError: |
| compileThrowStaticError(); |
| break; |
| case InvalidationPoint: |
| compileInvalidationPoint(); |
| break; |
| case IsEmpty: |
| compileIsEmpty(); |
| break; |
| case IsUndefined: |
| compileIsUndefined(); |
| break; |
| case IsBoolean: |
| compileIsBoolean(); |
| break; |
| case IsNumber: |
| compileIsNumber(); |
| break; |
| case NumberIsInteger: |
| compileNumberIsInteger(); |
| break; |
| case IsCellWithType: |
| compileIsCellWithType(); |
| break; |
| case MapHash: |
| compileMapHash(); |
| break; |
| case NormalizeMapKey: |
| compileNormalizeMapKey(); |
| break; |
| case GetMapBucket: |
| compileGetMapBucket(); |
| break; |
| case GetMapBucketHead: |
| compileGetMapBucketHead(); |
| break; |
| case GetMapBucketNext: |
| compileGetMapBucketNext(); |
| break; |
| case LoadKeyFromMapBucket: |
| compileLoadKeyFromMapBucket(); |
| break; |
| case LoadValueFromMapBucket: |
| compileLoadValueFromMapBucket(); |
| break; |
| case ExtractValueFromWeakMapGet: |
| compileExtractValueFromWeakMapGet(); |
| break; |
| case SetAdd: |
| compileSetAdd(); |
| break; |
| case MapSet: |
| compileMapSet(); |
| break; |
| case WeakMapGet: |
| compileWeakMapGet(); |
| break; |
| case WeakSetAdd: |
| compileWeakSetAdd(); |
| break; |
| case WeakMapSet: |
| compileWeakMapSet(); |
| break; |
| case IsObject: |
| compileIsObject(); |
| break; |
| case IsObjectOrNull: |
| compileIsObjectOrNull(); |
| break; |
| case IsFunction: |
| compileIsFunction(); |
| break; |
| case IsTypedArrayView: |
| compileIsTypedArrayView(); |
| break; |
| case ParseInt: |
| compileParseInt(); |
| break; |
| case TypeOf: |
| compileTypeOf(); |
| break; |
| case CheckTypeInfoFlags: |
| compileCheckTypeInfoFlags(); |
| break; |
| case OverridesHasInstance: |
| compileOverridesHasInstance(); |
| break; |
| case InstanceOf: |
| compileInstanceOf(); |
| break; |
| case InstanceOfCustom: |
| compileInstanceOfCustom(); |
| break; |
| case CountExecution: |
| compileCountExecution(); |
| break; |
| case SuperSamplerBegin: |
| compileSuperSamplerBegin(); |
| break; |
| case SuperSamplerEnd: |
| compileSuperSamplerEnd(); |
| break; |
| case StoreBarrier: |
| case FencedStoreBarrier: |
| compileStoreBarrier(); |
| break; |
| case HasIndexedProperty: |
| compileHasIndexedProperty(); |
| break; |
| case HasGenericProperty: |
| compileHasGenericProperty(); |
| break; |
| case HasStructureProperty: |
| compileHasStructureProperty(); |
| break; |
| case GetDirectPname: |
| compileGetDirectPname(); |
| break; |
| case GetEnumerableLength: |
| compileGetEnumerableLength(); |
| break; |
| case GetPropertyEnumerator: |
| compileGetPropertyEnumerator(); |
| break; |
| case GetEnumeratorStructurePname: |
| compileGetEnumeratorStructurePname(); |
| break; |
| case GetEnumeratorGenericPname: |
| compileGetEnumeratorGenericPname(); |
| break; |
| case ToIndexString: |
| compileToIndexString(); |
| break; |
| case CheckStructureImmediate: |
| compileCheckStructureImmediate(); |
| break; |
| case MaterializeNewObject: |
| compileMaterializeNewObject(); |
| break; |
| case MaterializeCreateActivation: |
| compileMaterializeCreateActivation(); |
| break; |
| case CheckTraps: |
| if (Options::usePollingTraps()) |
| compileCheckTraps(); |
| break; |
| case CreateRest: |
| compileCreateRest(); |
| break; |
| case GetRestLength: |
| compileGetRestLength(); |
| break; |
| case RegExpExec: |
| compileRegExpExec(); |
| break; |
| case RegExpExecNonGlobalOrSticky: |
| compileRegExpExecNonGlobalOrSticky(); |
| break; |
| case RegExpTest: |
| compileRegExpTest(); |
| break; |
| case RegExpMatchFast: |
| compileRegExpMatchFast(); |
| break; |
| case RegExpMatchFastGlobal: |
| compileRegExpMatchFastGlobal(); |
| break; |
| case NewRegexp: |
| compileNewRegexp(); |
| break; |
| case SetFunctionName: |
| compileSetFunctionName(); |
| break; |
| case StringReplace: |
| case StringReplaceRegExp: |
| compileStringReplace(); |
| break; |
| case GetRegExpObjectLastIndex: |
| compileGetRegExpObjectLastIndex(); |
| break; |
| case SetRegExpObjectLastIndex: |
| compileSetRegExpObjectLastIndex(); |
| break; |
| case LogShadowChickenPrologue: |
| compileLogShadowChickenPrologue(); |
| break; |
| case LogShadowChickenTail: |
| compileLogShadowChickenTail(); |
| break; |
| case RecordRegExpCachedResult: |
| compileRecordRegExpCachedResult(); |
| break; |
| case ResolveScopeForHoistingFuncDeclInEval: |
| compileResolveScopeForHoistingFuncDeclInEval(); |
| break; |
| case ResolveScope: |
| compileResolveScope(); |
| break; |
| case GetDynamicVar: |
| compileGetDynamicVar(); |
| break; |
| case PutDynamicVar: |
| compilePutDynamicVar(); |
| break; |
| case Unreachable: |
| compileUnreachable(); |
| break; |
| case StringSlice: |
| compileStringSlice(); |
| break; |
| case ToLowerCase: |
| compileToLowerCase(); |
| break; |
| case NumberToStringWithRadix: |
| compileNumberToStringWithRadix(); |
| break; |
| case NumberToStringWithValidRadixConstant: |
| compileNumberToStringWithValidRadixConstant(); |
| break; |
| case CheckSubClass: |
| compileCheckSubClass(); |
| break; |
| case CallDOM: |
| compileCallDOM(); |
| break; |
| case CallDOMGetter: |
| compileCallDOMGetter(); |
| break; |
| |
| case PhantomLocal: |
| case LoopHint: |
| case MovHint: |
| case ZombieHint: |
| case ExitOK: |
| case PhantomNewObject: |
| case PhantomNewFunction: |
| case PhantomNewGeneratorFunction: |
| case PhantomNewAsyncGeneratorFunction: |
| case PhantomNewAsyncFunction: |
| case PhantomCreateActivation: |
| case PhantomDirectArguments: |
| case PhantomCreateRest: |
| case PhantomSpread: |
| case PhantomNewArrayWithSpread: |
| case PhantomNewArrayBuffer: |
| case PhantomClonedArguments: |
| case PhantomNewRegexp: |
| case PutHint: |
| case BottomValue: |
| case KillStack: |
| case InitializeEntrypointArguments: |
| break; |
| default: |
| DFG_CRASH(m_graph, m_node, "Unrecognized node in FTL backend"); |
| break; |
| } |
| |
| if (m_node->isTerminal()) |
| return false; |
| |
| if (!m_state.isValid()) { |
| safelyInvalidateAfterTermination(); |
| return false; |
| } |
| |
| m_availabilityCalculator.executeNode(m_node); |
| m_interpreter.executeEffects(nodeIndex); |
| |
| return true; |
| } |
| |
| void compileUpsilon() |
| { |
| LValue upsilonValue = nullptr; |
| switch (m_node->child1().useKind()) { |
| case DoubleRepUse: |
| upsilonValue = lowDouble(m_node->child1()); |
| break; |
| case Int32Use: |
| case KnownInt32Use: |
| upsilonValue = lowInt32(m_node->child1()); |
| break; |
| case Int52RepUse: |
| upsilonValue = lowInt52(m_node->child1()); |
| break; |
| case BooleanUse: |
| case KnownBooleanUse: |
| upsilonValue = lowBoolean(m_node->child1()); |
| break; |
| case CellUse: |
| case KnownCellUse: |
| upsilonValue = lowCell(m_node->child1()); |
| break; |
| case UntypedUse: |
| upsilonValue = lowJSValue(m_node->child1()); |
| break; |
| default: |
| DFG_CRASH(m_graph, m_node, "Bad use kind"); |
| break; |
| } |
| ValueFromBlock upsilon = m_out.anchor(upsilonValue); |
| LValue phiNode = m_phis.get(m_node->phi()); |
| m_out.addIncomingToPhi(phiNode, upsilon); |
| } |
| |
| void compilePhi() |
| { |
| LValue phi = m_phis.get(m_node); |
| m_out.m_block->append(phi); |
| |
| switch (m_node->flags() & NodeResultMask) { |
| case NodeResultDouble: |
| setDouble(phi); |
| break; |
| case NodeResultInt32: |
| setInt32(phi); |
| break; |
| case NodeResultInt52: |
| setInt52(phi); |
| break; |
| case NodeResultBoolean: |
| setBoolean(phi); |
| break; |
| case NodeResultJS: |
| setJSValue(phi); |
| break; |
| default: |
| DFG_CRASH(m_graph, m_node, "Bad use kind"); |
| break; |
| } |
| } |
| |
| void compileDoubleConstant() |
| { |
| setDouble(m_out.constDouble(m_node->asNumber())); |
| } |
| |
| void compileInt52Constant() |
| { |
| int64_t value = m_node->asAnyInt(); |
| |
| setInt52(m_out.constInt64(value << JSValue::int52ShiftAmount)); |
| setStrictInt52(m_out.constInt64(value)); |
| } |
| |
| void compileLazyJSConstant() |
| { |
| PatchpointValue* patchpoint = m_out.patchpoint(Int64); |
| LazyJSValue value = m_node->lazyJSValue(); |
| patchpoint->setGenerator( |
| [=] (CCallHelpers& jit, const StackmapGenerationParams& params) { |
| value.emit(jit, JSValueRegs(params[0].gpr())); |
| }); |
| patchpoint->effects = Effects::none(); |
| setJSValue(patchpoint); |
| } |
| |
| void compileDoubleRep() |
| { |
| switch (m_node->child1().useKind()) { |
| case RealNumberUse: { |
| LValue value = lowJSValue(m_node->child1(), ManualOperandSpeculation); |
| |
| LValue doubleValue = unboxDouble(value); |
| |
| LBasicBlock intCase = m_out.newBlock(); |
| LBasicBlock continuation = m_out.newBlock(); |
| |
| ValueFromBlock fastResult = m_out.anchor(doubleValue); |
| m_out.branch( |
| m_out.doubleEqual(doubleValue, doubleValue), |
| usually(continuation), rarely(intCase)); |
| |
| LBasicBlock lastNext = m_out.appendTo(intCase, continuation); |
| |
| FTL_TYPE_CHECK( |
| jsValueValue(value), m_node->child1(), SpecBytecodeRealNumber, |
| isNotInt32(value, provenType(m_node->child1()) & ~SpecDoubleReal)); |
| ValueFromBlock slowResult = m_out.anchor(m_out.intToDouble(unboxInt32(value))); |
| m_out.jump(continuation); |
| |
| m_out.appendTo(continuation, lastNext); |
| |
| setDouble(m_out.phi(Double, fastResult, slowResult)); |
| return; |
| } |
| |
| case NotCellUse: |
| case NumberUse: { |
| bool shouldConvertNonNumber = m_node->child1().useKind() == NotCellUse; |
| |
| LValue value = lowJSValue(m_node->child1(), ManualOperandSpeculation); |
| |
| LBasicBlock intCase = m_out.newBlock(); |
| LBasicBlock doubleTesting = m_out.newBlock(); |
| LBasicBlock doubleCase = m_out.newBlock(); |
| LBasicBlock nonDoubleCase = m_out.newBlock(); |
| LBasicBlock continuation = m_out.newBlock(); |
| |
| m_out.branch( |
| isNotInt32(value, provenType(m_node->child1())), |
| unsure(doubleTesting), unsure(intCase)); |
| |
| LBasicBlock lastNext = m_out.appendTo(intCase, doubleTesting); |
| |
| ValueFromBlock intToDouble = m_out.anchor( |
| m_out.intToDouble(unboxInt32(value))); |
| m_out.jump(continuation); |
| |
| m_out.appendTo(doubleTesting, doubleCase); |
| LValue valueIsNumber = isNumber(value, provenType(m_node->child1())); |
| m_out.branch(valueIsNumber, usually(doubleCase), rarely(nonDoubleCase)); |
| |
| m_out.appendTo(doubleCase, nonDoubleCase); |
| ValueFromBlock unboxedDouble = m_out.anchor(unboxDouble(value)); |
| m_out.jump(continuation); |
| |
| if (shouldConvertNonNumber) { |
| LBasicBlock undefinedCase = m_out.newBlock(); |
| LBasicBlock testNullCase = m_out.newBlock(); |
| LBasicBlock nullCase = m_out.newBlock(); |
| LBasicBlock testBooleanTrueCase = m_out.newBlock(); |
| LBasicBlock convertBooleanTrueCase = m_out.newBlock(); |
| LBasicBlock convertBooleanFalseCase = m_out.newBlock(); |
| |
| m_out.appendTo(nonDoubleCase, undefinedCase); |
| LValue valueIsUndefined = m_out.equal(value, m_out.constInt64(ValueUndefined)); |
| m_out.branch(valueIsUndefined, unsure(undefinedCase), unsure(testNullCase)); |
| |
| m_out.appendTo(undefinedCase, testNullCase); |
| ValueFromBlock convertedUndefined = m_out.anchor(m_out.constDouble(PNaN)); |
| m_out.jump(continuation); |
| |
| m_out.appendTo(testNullCase, nullCase); |
| LValue valueIsNull = m_out.equal(value, m_out.constInt64(ValueNull)); |
| m_out.branch(valueIsNull, unsure(nullCase), unsure(testBooleanTrueCase)); |
| |
| m_out.appendTo(nullCase, testBooleanTrueCase); |
| ValueFromBlock convertedNull = m_out.anchor(m_out.constDouble(0)); |
| m_out.jump(continuation); |
| |
| m_out.appendTo(testBooleanTrueCase, convertBooleanTrueCase); |
| LValue valueIsBooleanTrue = m_out.equal(value, m_out.constInt64(ValueTrue)); |
| m_out.branch(valueIsBooleanTrue, unsure(convertBooleanTrueCase), unsure(convertBooleanFalseCase)); |
| |
| m_out.appendTo(convertBooleanTrueCase, convertBooleanFalseCase); |
| ValueFromBlock convertedTrue = m_out.anchor(m_out.constDouble(1)); |
| m_out.jump(continuation); |
| |
| m_out.appendTo(convertBooleanFalseCase, continuation); |
| |
| LValue valueIsNotBooleanFalse = m_out.notEqual(value, m_out.constInt64(ValueFalse)); |
| FTL_TYPE_CHECK(jsValueValue(value), m_node->child1(), ~SpecCellCheck, valueIsNotBooleanFalse); |
| ValueFromBlock convertedFalse = m_out.anchor(m_out.constDouble(0)); |
| m_out.jump(continuation); |
| |
| m_out.appendTo(continuation, lastNext); |
| setDouble(m_out.phi(Double, intToDouble, unboxedDouble, convertedUndefined, convertedNull, convertedTrue, convertedFalse)); |
| return; |
| } |
| m_out.appendTo(nonDoubleCase, continuation); |
| FTL_TYPE_CHECK(jsValueValue(value), m_node->child1(), SpecBytecodeNumber, m_out.booleanTrue); |
| m_out.unreachable(); |
| |
| m_out.appendTo(continuation, lastNext); |
| |
| setDouble(m_out.phi(Double, intToDouble, unboxedDouble)); |
| return; |
| } |
| |
| case Int52RepUse: { |
| setDouble(strictInt52ToDouble(lowStrictInt52(m_node->child1()))); |
| return; |
| } |
| |
| default: |
| DFG_CRASH(m_graph, m_node, "Bad use kind"); |
| } |
| } |
| |
| void compileDoubleAsInt32() |
| { |
| LValue integerValue = convertDoubleToInt32(lowDouble(m_node->child1()), shouldCheckNegativeZero(m_node->arithMode())); |
| setInt32(integerValue); |
| } |
| |
| void compileValueRep() |
| { |
| switch (m_node->child1().useKind()) { |
| case DoubleRepUse: { |
| LValue value = lowDouble(m_node->child1()); |
| |
| if (m_interpreter.needsTypeCheck(m_node->child1(), ~SpecDoubleImpureNaN)) { |
| value = m_out.select( |
| m_out.doubleEqual(value, value), value, m_out.constDouble(PNaN)); |
| } |
| |
| setJSValue(boxDouble(value)); |
| return; |
| } |
| |
| case Int52RepUse: { |
| setJSValue(strictInt52ToJSValue(lowStrictInt52(m_node->child1()))); |
| return; |
| } |
| |
| default: |
| DFG_CRASH(m_graph, m_node, "Bad use kind"); |
| } |
| } |
| |
| void compileInt52Rep() |
| { |
| switch (m_node->child1().useKind()) { |
| case Int32Use: |
| setStrictInt52(m_out.signExt32To64(lowInt32(m_node->child1()))); |
| return; |
| |
| case AnyIntUse: |
| setStrictInt52( |
| jsValueToStrictInt52( |
| m_node->child1(), lowJSValue(m_node->child1(), ManualOperandSpeculation))); |
| return; |
| |
| case DoubleRepAnyIntUse: |
| setStrictInt52( |
| doubleToStrictInt52( |
| m_node->child1(), lowDouble(m_node->child1()))); |
| return; |
| |
| default: |
| RELEASE_ASSERT_NOT_REACHED(); |
| } |
| } |
| |
| void compileValueToInt32() |
| { |
| switch (m_node->child1().useKind()) { |
| case Int52RepUse: |
| setInt32(m_out.castToInt32(lowStrictInt52(m_node->child1()))); |
| break; |
| |
| case DoubleRepUse: |
| setInt32(doubleToInt32(lowDouble(m_node->child1()))); |
| break; |
| |
| case NumberUse: |
| case NotCellUse: { |
| LoweredNodeValue value = m_int32Values.get(m_node->child1().node()); |
| if (isValid(value)) { |
| setInt32(value.value()); |
| break; |
| } |
| |
| value = m_jsValueValues.get(m_node->child1().node()); |
| if (isValid(value)) { |
| setInt32(numberOrNotCellToInt32(m_node->child1(), value.value())); |
| break; |
| } |
| |
| // We'll basically just get here for constants. But it's good to have this |
| // catch-all since we often add new representations into the mix. |
| setInt32( |
| numberOrNotCellToInt32( |
| m_node->child1(), |
| lowJSValue(m_node->child1(), ManualOperandSpeculation))); |
| break; |
| } |
| |
| default: |
| DFG_CRASH(m_graph, m_node, "Bad use kind"); |
| break; |
| } |
| } |
| |
| void compileBooleanToNumber() |
| { |
| switch (m_node->child1().useKind()) { |
| case BooleanUse: { |
| setInt32(m_out.zeroExt(lowBoolean(m_node->child1()), Int32)); |
| return; |
| } |
| |
| case UntypedUse: { |
| LValue value = lowJSValue(m_node->child1()); |
| |
| if (!m_interpreter.needsTypeCheck(m_node->child1(), SpecBoolInt32 | SpecBoolean)) { |
| setInt32(m_out.bitAnd(m_out.castToInt32(value), m_out.int32One)); |
| return; |
| } |
| |
| LBasicBlock booleanCase = m_out.newBlock(); |
| LBasicBlock continuation = m_out.newBlock(); |
| |
| ValueFromBlock notBooleanResult = m_out.anchor(value); |
| m_out.branch( |
| isBoolean(value, provenType(m_node->child1())), |
| unsure(booleanCase), unsure(continuation)); |
| |
| LBasicBlock lastNext = m_out.appendTo(booleanCase, continuation); |
| ValueFromBlock booleanResult = m_out.anchor(m_out.bitOr( |
| m_out.zeroExt(unboxBoolean(value), Int64), m_tagTypeNumber)); |
| m_out.jump(continuation); |
| |
| m_out.appendTo(continuation, lastNext); |
| setJSValue(m_out.phi(Int64, booleanResult, notBooleanResult)); |
| return; |
| } |
| |
| default: |
| RELEASE_ASSERT_NOT_REACHED(); |
| return; |
| } |
| } |
| |
| void compileExtractOSREntryLocal() |
| { |
| EncodedJSValue* buffer = static_cast<EncodedJSValue*>( |
| m_ftlState.jitCode->ftlForOSREntry()->entryBuffer()->dataBuffer()); |
| setJSValue(m_out.load64(m_out.absolute(buffer + m_node->unlinkedLocal().toLocal()))); |
| } |
| |
| void compileExtractCatchLocal() |
| { |
| EncodedJSValue* buffer = static_cast<EncodedJSValue*>(m_ftlState.jitCode->common.catchOSREntryBuffer->dataBuffer()); |
| setJSValue(m_out.load64(m_out.absolute(buffer + m_node->catchOSREntryIndex()))); |
| } |
| |
| void compileGetStack() |
| { |
| StackAccessData* data = m_node->stackAccessData(); |
| AbstractValue& value = m_state.variables().operand(data->local); |
| |
| DFG_ASSERT(m_graph, m_node, isConcrete(data->format), data->format); |
| DFG_ASSERT(m_graph, m_node, data->format != FlushedDouble, data->format); // This just happens to not arise for GetStacks, right now. It would be trivial to support. |
| |
| if (isInt32Speculation(value.m_type)) |
| setInt32(m_out.load32(payloadFor(data->machineLocal))); |
| else |
| setJSValue(m_out.load64(addressFor(data->machineLocal))); |
| } |
| |
| void compilePutStack() |
| { |
| StackAccessData* data = m_node->stackAccessData(); |
| switch (data->format) { |
| case FlushedJSValue: { |
| LValue value = lowJSValue(m_node->child1()); |
| m_out.store64(value, addressFor(data->machineLocal)); |
| break; |
| } |
| |
| case FlushedDouble: { |
| LValue value = lowDouble(m_node->child1()); |
| m_out.storeDouble(value, addressFor(data->machineLocal)); |
| break; |
| } |
| |
| case FlushedInt32: { |
| LValue value = lowInt32(m_node->child1()); |
| m_out.store32(value, payloadFor(data->machineLocal)); |
| break; |
| } |
| |
| case FlushedInt52: { |
| LValue value = lowInt52(m_node->child1()); |
| m_out.store64(value, addressFor(data->machineLocal)); |
| break; |
| } |
| |
| case FlushedCell: { |
| LValue value = lowCell(m_node->child1()); |
| m_out.store64(value, addressFor(data->machineLocal)); |
| break; |
| } |
| |
| case FlushedBoolean: { |
| speculateBoolean(m_node->child1()); |
| m_out.store64( |
| lowJSValue(m_node->child1(), ManualOperandSpeculation), |
| addressFor(data->machineLocal)); |
| break; |
| } |
| |
| default: |
| DFG_CRASH(m_graph, m_node, "Bad flush format"); |
| break; |
| } |
| } |
| |
| void compileNoOp() |
| { |
| DFG_NODE_DO_TO_CHILDREN(m_graph, m_node, speculate); |
| } |
| |
| void compileToObjectOrCallObjectConstructor() |
| { |
| LValue value = lowJSValue(m_node->child1()); |
| |
| LBasicBlock isCellCase = m_out.newBlock(); |
| LBasicBlock slowCase = m_out.newBlock(); |
| LBasicBlock continuation = m_out.newBlock(); |
| |
| m_out.branch(isCell(value, provenType(m_node->child1())), usually(isCellCase), rarely(slowCase)); |
| |
| LBasicBlock lastNext = m_out.appendTo(isCellCase, slowCase); |
| ValueFromBlock fastResult = m_out.anchor(value); |
| m_out.branch(isObject(value), usually(continuation), rarely(slowCase)); |
| |
| m_out.appendTo(slowCase, continuation); |
| |
| ValueFromBlock slowResult; |
| if (m_node->op() == ToObject) { |
| auto* globalObject = m_graph.globalObjectFor(m_node->origin.semantic); |
| slowResult = m_out.anchor(vmCall(Int64, m_out.operation(operationToObject), m_callFrame, weakPointer(globalObject), value, m_out.constIntPtr(m_graph.identifiers()[m_node->identifierNumber()]))); |
| } else |
| slowResult = m_out.anchor(vmCall(Int64, m_out.operation(operationCallObjectConstructor), m_callFrame, frozenPointer(m_node->cellOperand()), value)); |
| m_out.jump(continuation); |
| |
| m_out.appendTo(continuation, lastNext); |
| setJSValue(m_out.phi(Int64, fastResult, slowResult)); |
| } |
| |
| void compileToThis() |
| { |
| LValue value = lowJSValue(m_node->child1()); |
| |
| LBasicBlock isCellCase = m_out.newBlock(); |
| LBasicBlock slowCase = m_out.newBlock(); |
| LBasicBlock continuation = m_out.newBlock(); |
| |
| m_out.branch( |
| isCell(value, provenType(m_node->child1())), usually(isCellCase), rarely(slowCase)); |
| |
| LBasicBlock lastNext = m_out.appendTo(isCellCase, slowCase); |
| ValueFromBlock fastResult = m_out.anchor(value); |
| m_out.branch( |
| m_out.testIsZero32( |
| m_out.load8ZeroExt32(value, m_heaps.JSCell_typeInfoFlags), |
| m_out.constInt32(OverridesToThis)), |
| usually(continuation), rarely(slowCase)); |
| |
| m_out.appendTo(slowCase, continuation); |
| J_JITOperation_EJ function; |
| if (m_graph.isStrictModeFor(m_node->origin.semantic)) |
| function = operationToThisStrict; |
| else |
| function = operationToThis; |
| ValueFromBlock slowResult = m_out.anchor( |
| vmCall(Int64, m_out.operation(function), m_callFrame, value)); |
| m_out.jump(continuation); |
| |
| m_out.appendTo(continuation, lastNext); |
| setJSValue(m_out.phi(Int64, fastResult, slowResult)); |
| } |
| |
| void compileValueAdd() |
| { |
| CodeBlock* baselineCodeBlock = m_ftlState.graph.baselineCodeBlockFor(m_node->origin.semantic); |
| ArithProfile* arithProfile = baselineCodeBlock->arithProfileForBytecodeOffset(m_node->origin.semantic.bytecodeIndex); |
| Instruction* instruction = &baselineCodeBlock->instructions()[m_node->origin.semantic.bytecodeIndex]; |
| auto repatchingFunction = operationValueAddOptimize; |
| auto nonRepatchingFunction = operationValueAdd; |
| compileBinaryMathIC<JITAddGenerator>(arithProfile, instruction, repatchingFunction, nonRepatchingFunction); |
| } |
| |
| template <typename Generator, typename Func1, typename Func2, |
| typename = std::enable_if_t<std::is_function<typename std::remove_pointer<Func1>::type>::value && std::is_function<typename std::remove_pointer<Func2>::type>::value>> |
| void compileUnaryMathIC(ArithProfile* arithProfile, Instruction* instruction, Func1 repatchingFunction, Func2 nonRepatchingFunction) |
| { |
| Node* node = m_node; |
| |
| LValue operand = lowJSValue(node->child1()); |
| |
| PatchpointValue* patchpoint = m_out.patchpoint(Int64); |
| patchpoint->appendSomeRegister(operand); |
| patchpoint->append(m_tagMask, ValueRep::lateReg(GPRInfo::tagMaskRegister)); |
| patchpoint->append(m_tagTypeNumber, ValueRep::lateReg(GPRInfo::tagTypeNumberRegister)); |
| RefPtr<PatchpointExceptionHandle> exceptionHandle = preparePatchpointForExceptions(patchpoint); |
| patchpoint->numGPScratchRegisters = 1; |
| patchpoint->clobber(RegisterSet::macroScratchRegisters()); |
| State* state = &m_ftlState; |
| patchpoint->setGenerator( |
| [=] (CCallHelpers& jit, const StackmapGenerationParams& params) { |
| AllowMacroScratchRegisterUsage allowScratch(jit); |
| |
| Box<CCallHelpers::JumpList> exceptions = |
| exceptionHandle->scheduleExitCreation(params)->jumps(jit); |
| |
| #if ENABLE(MATH_IC_STATS) |
| auto inlineStart = jit.label(); |
| #endif |
| |
| Box<MathICGenerationState> mathICGenerationState = Box<MathICGenerationState>::create(); |
| JITUnaryMathIC<Generator>* mathIC = jit.codeBlock()->addMathIC<Generator>(arithProfile, instruction); |
| mathIC->m_generator = Generator(JSValueRegs(params[0].gpr()), JSValueRegs(params[1].gpr()), params.gpScratch(0)); |
| |
| bool shouldEmitProfiling = false; |
| bool generatedInline = mathIC->generateInline(jit, *mathICGenerationState, shouldEmitProfiling); |
| |
| if (generatedInline) { |
| ASSERT(!mathICGenerationState->slowPathJumps.empty()); |
| auto done = jit.label(); |
| params.addLatePath([=] (CCallHelpers& jit) { |
| AllowMacroScratchRegisterUsage allowScratch(jit); |
| mathICGenerationState->slowPathJumps.link(&jit); |
| mathICGenerationState->slowPathStart = jit.label(); |
| #if ENABLE(MATH_IC_STATS) |
| auto slowPathStart = jit.label(); |
| #endif |
| |
| if (mathICGenerationState->shouldSlowPathRepatch) { |
| SlowPathCall call = callOperation(*state, params.unavailableRegisters(), jit, node->origin.semantic, exceptions.get(), |
| repatchingFunction, params[0].gpr(), params[1].gpr(), CCallHelpers::TrustedImmPtr(mathIC)); |
| mathICGenerationState->slowPathCall = call.call(); |
| } else { |
| SlowPathCall call = callOperation(*state, params.unavailableRegisters(), jit, node->origin.semantic, |
| exceptions.get(), nonRepatchingFunction, params[0].gpr(), params[1].gpr()); |
| mathICGenerationState->slowPathCall = call.call(); |
| } |
| jit.jump().linkTo(done, &jit); |
| |
| jit.addLinkTask([=] (LinkBuffer& linkBuffer) { |
| mathIC->finalizeInlineCode(*mathICGenerationState, linkBuffer); |
| }); |
| |
| #if ENABLE(MATH_IC_STATS) |
| auto slowPathEnd = jit.label(); |
| jit.addLinkTask([=] (LinkBuffer& linkBuffer) { |
| size_t size = linkBuffer.locationOf(slowPathEnd).executableAddress<char*>() - linkBuffer.locationOf(slowPathStart).executableAddress<char*>(); |
| mathIC->m_generatedCodeSize += size; |
| }); |
| #endif |
| }); |
| } else { |
| callOperation( |
| *state, params.unavailableRegisters(), jit, node->origin.semantic, exceptions.get(), |
| nonRepatchingFunction, params[0].gpr(), params[1].gpr()); |
| } |
| |
| #if ENABLE(MATH_IC_STATS) |
| auto inlineEnd = jit.label(); |
| jit.addLinkTask([=] (LinkBuffer& linkBuffer) { |
| size_t size = linkBuffer.locationOf(inlineEnd).executableAddress<char*>() - linkBuffer.locationOf(inlineStart).executableAddress<char*>(); |
| mathIC->m_generatedCodeSize += size; |
| }); |
| #endif |
| }); |
| |
| setJSValue(patchpoint); |
| } |
| |
| template <typename Generator, typename Func1, typename Func2, |
| typename = std::enable_if_t<std::is_function<typename std::remove_pointer<Func1>::type>::value && std::is_function<typename std::remove_pointer<Func2>::type>::value>> |
| void compileBinaryMathIC(ArithProfile* arithProfile, Instruction* instruction, Func1 repatchingFunction, Func2 nonRepatchingFunction) |
| { |
| Node* node = m_node; |
| |
| LValue left = lowJSValue(node->child1()); |
| LValue right = lowJSValue(node->child2()); |
| |
| SnippetOperand leftOperand(m_state.forNode(node->child1()).resultType()); |
| SnippetOperand rightOperand(m_state.forNode(node->child2()).resultType()); |
| |
| PatchpointValue* patchpoint = m_out.patchpoint(Int64); |
| patchpoint->appendSomeRegister(left); |
| patchpoint->appendSomeRegister(right); |
| patchpoint->append(m_tagMask, ValueRep::lateReg(GPRInfo::tagMaskRegister)); |
| patchpoint->append(m_tagTypeNumber, ValueRep::lateReg(GPRInfo::tagTypeNumberRegister)); |
| RefPtr<PatchpointExceptionHandle> exceptionHandle = |
| preparePatchpointForExceptions(patchpoint); |
| patchpoint->numGPScratchRegisters = 1; |
| patchpoint->numFPScratchRegisters = 2; |
| patchpoint->clobber(RegisterSet::macroScratchRegisters()); |
| State* state = &m_ftlState; |
| patchpoint->setGenerator( |
| [=] (CCallHelpers& jit, const StackmapGenerationParams& params) { |
| AllowMacroScratchRegisterUsage allowScratch(jit); |
| |
| |
| Box<CCallHelpers::JumpList> exceptions = |
| exceptionHandle->scheduleExitCreation(params)->jumps(jit); |
| |
| #if ENABLE(MATH_IC_STATS) |
| auto inlineStart = jit.label(); |
| #endif |
| |
| Box<MathICGenerationState> mathICGenerationState = Box<MathICGenerationState>::create(); |
| JITBinaryMathIC<Generator>* mathIC = jit.codeBlock()->addMathIC<Generator>(arithProfile, instruction); |
| mathIC->m_generator = Generator(leftOperand, rightOperand, JSValueRegs(params[0].gpr()), |
| JSValueRegs(params[1].gpr()), JSValueRegs(params[2].gpr()), params.fpScratch(0), |
| params.fpScratch(1), params.gpScratch(0), InvalidFPRReg); |
| |
| bool shouldEmitProfiling = false; |
| bool generatedInline = mathIC->generateInline(jit, *mathICGenerationState, shouldEmitProfiling); |
| |
| if (generatedInline) { |
| ASSERT(!mathICGenerationState->slowPathJumps.empty()); |
| auto done = jit.label(); |
| params.addLatePath([=] (CCallHelpers& jit) { |
| AllowMacroScratchRegisterUsage allowScratch(jit); |
| mathICGenerationState->slowPathJumps.link(&jit); |
| mathICGenerationState->slowPathStart = jit.label(); |
| #if ENABLE(MATH_IC_STATS) |
| auto slowPathStart = jit.label(); |
| #endif |
| |
| if (mathICGenerationState->shouldSlowPathRepatch) { |
| SlowPathCall call = callOperation(*state, params.unavailableRegisters(), jit, node->origin.semantic, exceptions.get(), |
| repatchingFunction, params[0].gpr(), params[1].gpr(), params[2].gpr(), CCallHelpers::TrustedImmPtr(mathIC)); |
| mathICGenerationState->slowPathCall = call.call(); |
| } else { |
| SlowPathCall call = callOperation(*state, params.unavailableRegisters(), jit, node->origin.semantic, |
| exceptions.get(), nonRepatchingFunction, params[0].gpr(), params[1].gpr(), params[2].gpr()); |
| mathICGenerationState->slowPathCall = call.call(); |
| } |
| jit.jump().linkTo(done, &jit); |
| |
| jit.addLinkTask([=] (LinkBuffer& linkBuffer) { |
| mathIC->finalizeInlineCode(*mathICGenerationState, linkBuffer); |
| }); |
| |
| #if ENABLE(MATH_IC_STATS) |
| auto slowPathEnd = jit.label(); |
| jit.addLinkTask([=] (LinkBuffer& linkBuffer) { |
| size_t size = linkBuffer.locationOf(slowPathEnd).executableAddress<char*>() - linkBuffer.locationOf(slowPathStart).executableAddress<char*>(); |
| mathIC->m_generatedCodeSize += size; |
| }); |
| #endif |
| }); |
| } else { |
| callOperation( |
| *state, params.unavailableRegisters(), jit, node->origin.semantic, exceptions.get(), |
| nonRepatchingFunction, params[0].gpr(), params[1].gpr(), params[2].gpr()); |
| } |
| |
| #if ENABLE(MATH_IC_STATS) |
| auto inlineEnd = jit.label(); |
| jit.addLinkTask([=] (LinkBuffer& linkBuffer) { |
| size_t size = linkBuffer.locationOf(inlineEnd).executableAddress<char*>() - linkBuffer.locationOf(inlineStart).executableAddress<char*>(); |
| mathIC->m_generatedCodeSize += size; |
| }); |
| #endif |
| }); |
| |
| setJSValue(patchpoint); |
| } |
| |
| void compileStrCat() |
| { |
| LValue result; |
| if (m_node->child3()) { |
| result = vmCall( |
| Int64, m_out.operation(operationStrCat3), m_callFrame, |
| lowJSValue(m_node->child1(), ManualOperandSpeculation), |
| lowJSValue(m_node->child2(), ManualOperandSpeculation), |
| lowJSValue(m_node->child3(), ManualOperandSpeculation)); |
| } else { |
| result = vmCall( |
| Int64, m_out.operation(operationStrCat2), m_callFrame, |
| lowJSValue(m_node->child1(), ManualOperandSpeculation), |
| lowJSValue(m_node->child2(), ManualOperandSpeculation)); |
| } |
| setJSValue(result); |
| } |
| |
| void compileArithAddOrSub() |
| { |
| bool isSub = m_node->op() == ArithSub; |
| switch (m_node->binaryUseKind()) { |
| case Int32Use: { |
| LValue left = lowInt32(m_node->child1()); |
| LValue right = lowInt32(m_node->child2()); |
| |
| if (!shouldCheckOverflow(m_node->arithMode())) { |
| setInt32(isSub ? m_out.sub(left, right) : m_out.add(left, right)); |
| break; |
| } |
| |
| CheckValue* result = |
| isSub ? m_out.speculateSub(left, right) : m_out.speculateAdd(left, right); |
| blessSpeculation(result, Overflow, noValue(), nullptr, m_origin); |
| setInt32(result); |
| break; |
| } |
| |
| case Int52RepUse: { |
| if (!abstractValue(m_node->child1()).couldBeType(SpecInt52Only) |
| && !abstractValue(m_node->child2()).couldBeType(SpecInt52Only)) { |
| Int52Kind kind; |
| LValue left = lowWhicheverInt52(m_node->child1(), kind); |
| LValue right = lowInt52(m_node->child2(), kind); |
| setInt52(isSub ? m_out.sub(left, right) : m_out.add(left, right), kind); |
| break; |
| } |
| |
| LValue left = lowInt52(m_node->child1()); |
| LValue right = lowInt52(m_node->child2()); |
| CheckValue* result = |
| isSub ? m_out.speculateSub(left, right) : m_out.speculateAdd(left, right); |
| blessSpeculation(result, Overflow, noValue(), nullptr, m_origin); |
| setInt52(result); |
| break; |
| } |
| |
| case DoubleRepUse: { |
| LValue C1 = lowDouble(m_node->child1()); |
| LValue C2 = lowDouble(m_node->child2()); |
| |
| setDouble(isSub ? m_out.doubleSub(C1, C2) : m_out.doubleAdd(C1, C2)); |
| break; |
| } |
| |
| case UntypedUse: { |
| if (!isSub) { |
| DFG_CRASH(m_graph, m_node, "Bad use kind"); |
| break; |
| } |
| |
| CodeBlock* baselineCodeBlock = m_ftlState.graph.baselineCodeBlockFor(m_node->origin.semantic); |
| ArithProfile* arithProfile = baselineCodeBlock->arithProfileForBytecodeOffset(m_node->origin.semantic.bytecodeIndex); |
| Instruction* instruction = &baselineCodeBlock->instructions()[m_node->origin.semantic.bytecodeIndex]; |
| auto repatchingFunction = operationValueSubOptimize; |
| auto nonRepatchingFunction = operationValueSub; |
| compileBinaryMathIC<JITSubGenerator>(arithProfile, instruction, repatchingFunction, nonRepatchingFunction); |
| break; |
| } |
| |
| default: |
| DFG_CRASH(m_graph, m_node, "Bad use kind"); |
| break; |
| } |
| } |
| |
| void compileArithClz32() |
| { |
| if (m_node->child1().useKind() == Int32Use || m_node->child1().useKind() == KnownInt32Use) { |
| LValue operand = lowInt32(m_node->child1()); |
| setInt32(m_out.ctlz32(operand)); |
| return; |
| } |
| DFG_ASSERT(m_graph, m_node, m_node->child1().useKind() == UntypedUse, m_node->child1().useKind()); |
| LValue argument = lowJSValue(m_node->child1()); |
| LValue result = vmCall(Int32, m_out.operation(operationArithClz32), m_callFrame, argument); |
| setInt32(result); |
| } |
| |
| void compileArithMul() |
| { |
| switch (m_node->binaryUseKind()) { |
| case Int32Use: { |
| LValue left = lowInt32(m_node->child1()); |
| LValue right = lowInt32(m_node->child2()); |
| |
| LValue result; |
| |
| if (!shouldCheckOverflow(m_node->arithMode())) |
| result = m_out.mul(left, right); |
| else { |
| CheckValue* speculation = m_out.speculateMul(left, right); |
| blessSpeculation(speculation, Overflow, noValue(), nullptr, m_origin); |
| result = speculation; |
| } |
| |
| if (shouldCheckNegativeZero(m_node->arithMode())) { |
| LBasicBlock slowCase = m_out.newBlock(); |
| LBasicBlock continuation = m_out.newBlock(); |
| |
| m_out.branch( |
| m_out.notZero32(result), usually(continuation), rarely(slowCase)); |
| |
| LBasicBlock lastNext = m_out.appendTo(slowCase, continuation); |
| speculate(NegativeZero, noValue(), nullptr, m_out.lessThan(left, m_out.int32Zero)); |
| speculate(NegativeZero, noValue(), nullptr, m_out.lessThan(right, m_out.int32Zero)); |
| m_out.jump(continuation); |
| m_out.appendTo(continuation, lastNext); |
| } |
| |
| setInt32(result); |
| break; |
| } |
| |
| case Int52RepUse: { |
| Int52Kind kind; |
| LValue left = lowWhicheverInt52(m_node->child1(), kind); |
| LValue right = lowInt52(m_node->child2(), opposite(kind)); |
| |
| CheckValue* result = m_out.speculateMul(left, right); |
| blessSpeculation(result, Overflow, noValue(), nullptr, m_origin); |
| |
| if (shouldCheckNegativeZero(m_node->arithMode())) { |
| LBasicBlock slowCase = m_out.newBlock(); |
| LBasicBlock continuation = m_out.newBlock(); |
| |
| m_out.branch( |
| m_out.notZero64(result), usually(continuation), rarely(slowCase)); |
| |
| LBasicBlock lastNext = m_out.appendTo(slowCase, continuation); |
| speculate(NegativeZero, noValue(), nullptr, m_out.lessThan(left, m_out.int64Zero)); |
| speculate(NegativeZero, noValue(), nullptr, m_out.lessThan(right, m_out.int64Zero)); |
| m_out.jump(continuation); |
| m_out.appendTo(continuation, lastNext); |
| } |
| |
| setInt52(result); |
| break; |
| } |
| |
| case DoubleRepUse: { |
| setDouble( |
| m_out.doubleMul(lowDouble(m_node->child1()), lowDouble(m_node->child2()))); |
| break; |
| } |
| |
| case UntypedUse: { |
| CodeBlock* baselineCodeBlock = m_ftlState.graph.baselineCodeBlockFor(m_node->origin.semantic); |
| ArithProfile* arithProfile = baselineCodeBlock->arithProfileForBytecodeOffset(m_node->origin.semantic.bytecodeIndex); |
| Instruction* instruction = &baselineCodeBlock->instructions()[m_node->origin.semantic.bytecodeIndex]; |
| auto repatchingFunction = operationValueMulOptimize; |
| auto nonRepatchingFunction = operationValueMul; |
| compileBinaryMathIC<JITMulGenerator>(arithProfile, instruction, repatchingFunction, nonRepatchingFunction); |
| break; |
| } |
| |
| default: |
| DFG_CRASH(m_graph, m_node, "Bad use kind"); |
| break; |
| } |
| } |
| |
| void compileArithDiv() |
| { |
| switch (m_node->binaryUseKind()) { |
| case Int32Use: { |
| LValue numerator = lowInt32(m_node->child1()); |
| LValue denominator = lowInt32(m_node->child2()); |
| |
| if (shouldCheckNegativeZero(m_node->arithMode())) { |
| LBasicBlock zeroNumerator = m_out.newBlock(); |
| LBasicBlock numeratorContinuation = m_out.newBlock(); |
| |
| m_out.branch( |
| m_out.isZero32(numerator), |
| rarely(zeroNumerator), usually(numeratorContinuation)); |
| |
| LBasicBlock innerLastNext = m_out.appendTo(zeroNumerator, numeratorContinuation); |
| |
| speculate( |
| NegativeZero, noValue(), 0, m_out.lessThan(denominator, m_out.int32Zero)); |
| |
| m_out.jump(numeratorContinuation); |
| |
| m_out.appendTo(numeratorContinuation, innerLastNext); |
| } |
| |
| if (shouldCheckOverflow(m_node->arithMode())) { |
| LBasicBlock unsafeDenominator = m_out.newBlock(); |
| LBasicBlock continuation = m_out.newBlock(); |
| |
| LValue adjustedDenominator = m_out.add(denominator, m_out.int32One); |
| m_out.branch( |
| m_out.above(adjustedDenominator, m_out.int32One), |
| usually(continuation), rarely(unsafeDenominator)); |
| |
| LBasicBlock lastNext = m_out.appendTo(unsafeDenominator, continuation); |
| LValue neg2ToThe31 = m_out.constInt32(-2147483647-1); |
| speculate(Overflow, noValue(), nullptr, m_out.isZero32(denominator)); |
| speculate(Overflow, noValue(), nullptr, m_out.equal(numerator, neg2ToThe31)); |
| m_out.jump(continuation); |
| |
| m_out.appendTo(continuation, lastNext); |
| LValue result = m_out.div(numerator, denominator); |
| speculate( |
| Overflow, noValue(), 0, |
| m_out.notEqual(m_out.mul(result, denominator), numerator)); |
| setInt32(result); |
| } else |
| setInt32(m_out.chillDiv(numerator, denominator)); |
| |
| break; |
| } |
| |
| case DoubleRepUse: { |
| setDouble(m_out.doubleDiv( |
| lowDouble(m_node->child1()), lowDouble(m_node->child2()))); |
| break; |
| } |
| |
| case UntypedUse: { |
| emitBinarySnippet<JITDivGenerator, NeedScratchFPR>(operationValueDiv); |
| break; |
| } |
| |
| default: |
| DFG_CRASH(m_graph, m_node, "Bad use kind"); |
| break; |
| } |
| } |
| |
| void compileArithMod() |
| { |
| switch (m_node->binaryUseKind()) { |
| case Int32Use: { |
| LValue numerator = lowInt32(m_node->child1()); |
| LValue denominator = lowInt32(m_node->child2()); |
| |
| LValue remainder; |
| if (shouldCheckOverflow(m_node->arithMode())) { |
| LBasicBlock unsafeDenominator = m_out.newBlock(); |
| LBasicBlock continuation = m_out.newBlock(); |
| |
| LValue adjustedDenominator = m_out.add(denominator, m_out.int32One); |
| m_out.branch( |
| m_out.above(adjustedDenominator, m_out.int32One), |
| usually(continuation), rarely(unsafeDenominator)); |
| |
| LBasicBlock lastNext = m_out.appendTo(unsafeDenominator, continuation); |
| LValue neg2ToThe31 = m_out.constInt32(-2147483647-1); |
| speculate(Overflow, noValue(), nullptr, m_out.isZero32(denominator)); |
| speculate(Overflow, noValue(), nullptr, m_out.equal(numerator, neg2ToThe31)); |
| m_out.jump(continuation); |
| |
| m_out.appendTo(continuation, lastNext); |
| LValue result = m_out.mod(numerator, denominator); |
| remainder = result; |
| } else |
| remainder = m_out.chillMod(numerator, denominator); |
| |
| if (shouldCheckNegativeZero(m_node->arithMode())) { |
| LBasicBlock negativeNumerator = m_out.newBlock(); |
| LBasicBlock numeratorContinuation = m_out.newBlock(); |
| |
| m_out.branch( |
| m_out.lessThan(numerator, m_out.int32Zero), |
| unsure(negativeNumerator), unsure(numeratorContinuation)); |
| |
| LBasicBlock innerLastNext = m_out.appendTo(negativeNumerator, numeratorContinuation); |
| |
| speculate(NegativeZero, noValue(), 0, m_out.isZero32(remainder)); |
| |
| m_out.jump(numeratorContinuation); |
| |
| m_out.appendTo(numeratorContinuation, innerLastNext); |
| } |
| |
| setInt32(remainder); |
| break; |
| } |
| |
| case DoubleRepUse: { |
| setDouble( |
| m_out.doubleMod(lowDouble(m_node->child1()), lowDouble(m_node->child2()))); |
| break; |
| } |
| |
| default: |
| DFG_CRASH(m_graph, m_node, "Bad use kind"); |
| break; |
| } |
| } |
| |
| void compileArithMinOrMax() |
| { |
| switch (m_node->binaryUseKind()) { |
| case Int32Use: { |
| LValue left = lowInt32(m_node->child1()); |
| LValue right = lowInt32(m_node->child2()); |
| |
| setInt32( |
| m_out.select( |
| m_node->op() == ArithMin |
| ? m_out.lessThan(left, right) |
| : m_out.lessThan(right, left), |
| left, right)); |
| break; |
| } |
| |
| case DoubleRepUse: { |
| LValue left = lowDouble(m_node->child1()); |
| LValue right = lowDouble(m_node->child2()); |
| |
| LBasicBlock notLessThan = m_out.newBlock(); |
| LBasicBlock continuation = m_out.newBlock(); |
| |
| Vector<ValueFromBlock, 2> results; |
| |
| results.append(m_out.anchor(left)); |
| m_out.branch( |
| m_node->op() == ArithMin |
| ? m_out.doubleLessThan(left, right) |
| : m_out.doubleGreaterThan(left, right), |
| unsure(continuation), unsure(notLessThan)); |
| |
| LBasicBlock lastNext = m_out.appendTo(notLessThan, continuation); |
| results.append(m_out.anchor(m_out.select( |
| m_node->op() == ArithMin |
| ? m_out.doubleGreaterThanOrEqual(left, right) |
| : m_out.doubleLessThanOrEqual(left, right), |
| right, m_out.constDouble(PNaN)))); |
| m_out.jump(continuation); |
| |
| m_out.appendTo(continuation, lastNext); |
| setDouble(m_out.phi(Double, results)); |
| break; |
| } |
| |
| default: |
| DFG_CRASH(m_graph, m_node, "Bad use kind"); |
| break; |
| } |
| } |
| |
| void compileArithAbs() |
| { |
| switch (m_node->child1().useKind()) { |
| case Int32Use: { |
| LValue value = lowInt32(m_node->child1()); |
| |
| LValue mask = m_out.aShr(value, m_out.constInt32(31)); |
| LValue result = m_out.bitXor(mask, m_out.add(mask, value)); |
| |
| if (shouldCheckOverflow(m_node->arithMode())) |
| speculate(Overflow, noValue(), 0, m_out.lessThan(result, m_out.int32Zero)); |
| |
| setInt32(result); |
| break; |
| } |
| |
| case DoubleRepUse: { |
| setDouble(m_out.doubleAbs(lowDouble(m_node->child1()))); |
| break; |
| } |
| |
| default: { |
| DFG_ASSERT(m_graph, m_node, m_node->child1().useKind() == UntypedUse, m_node->child1().useKind()); |
| LValue argument = lowJSValue(m_node->child1()); |
| LValue result = vmCall(Double, m_out.operation(operationArithAbs), m_callFrame, argument); |
| setDouble(result); |
| break; |
| } |
| } |
| } |
| |
| void compileArithUnary() |
| { |
| if (m_node->child1().useKind() == DoubleRepUse) { |
| setDouble(m_out.doubleUnary(m_node->arithUnaryType(), lowDouble(m_node->child1()))); |
| return; |
| } |
| LValue argument = lowJSValue(m_node->child1()); |
| LValue result = vmCall(Double, m_out.operation(DFG::arithUnaryOperation(m_node->arithUnaryType())), m_callFrame, argument); |
| setDouble(result); |
| } |
| |
| void compileArithPow() |
| { |
| if (m_node->child2().useKind() == Int32Use) |
| setDouble(m_out.doublePowi(lowDouble(m_node->child1()), lowInt32(m_node->child2()))); |
| else { |
| LValue base = lowDouble(m_node->child1()); |
| LValue exponent = lowDouble(m_node->child2()); |
| |
| LBasicBlock integerExponentIsSmallBlock = m_out.newBlock(); |
| LBasicBlock integerExponentPowBlock = m_out.newBlock(); |
| LBasicBlock doubleExponentPowBlockEntry = m_out.newBlock(); |
| LBasicBlock nanExceptionBaseIsOne = m_out.newBlock(); |
| LBasicBlock nanExceptionExponentIsInfinity = m_out.newBlock(); |
| LBasicBlock testExponentIsOneHalf = m_out.newBlock(); |
| LBasicBlock handleBaseZeroExponentIsOneHalf = m_out.newBlock(); |
| LBasicBlock handleInfinityForExponentIsOneHalf = m_out.newBlock(); |
| LBasicBlock exponentIsOneHalfNormal = m_out.newBlock(); |
| LBasicBlock exponentIsOneHalfInfinity = m_out.newBlock(); |
| LBasicBlock testExponentIsNegativeOneHalf = m_out.newBlock(); |
| LBasicBlock testBaseZeroExponentIsNegativeOneHalf = m_out.newBlock(); |
| LBasicBlock handleBaseZeroExponentIsNegativeOneHalf = m_out.newBlock(); |
| LBasicBlock handleInfinityForExponentIsNegativeOneHalf = m_out.newBlock(); |
| LBasicBlock exponentIsNegativeOneHalfNormal = m_out.newBlock(); |
| LBasicBlock exponentIsNegativeOneHalfInfinity = m_out.newBlock(); |
| LBasicBlock powBlock = m_out.newBlock(); |
| LBasicBlock nanExceptionResultIsNaN = m_out.newBlock(); |
| LBasicBlock continuation = m_out.newBlock(); |
| |
| LValue integerExponent = m_out.doubleToInt(exponent); |
| LValue integerExponentConvertedToDouble = m_out.intToDouble(integerExponent); |
| LValue exponentIsInteger = m_out.doubleEqual(exponent, integerExponentConvertedToDouble); |
| m_out.branch(exponentIsInteger, unsure(integerExponentIsSmallBlock), unsure(doubleExponentPowBlockEntry)); |
| |
| LBasicBlock lastNext = m_out.appendTo(integerExponentIsSmallBlock, integerExponentPowBlock); |
| LValue integerExponentBelowMax = m_out.belowOrEqual(integerExponent, m_out.constInt32(maxExponentForIntegerMathPow)); |
| m_out.branch(integerExponentBelowMax, usually(integerExponentPowBlock), rarely(doubleExponentPowBlockEntry)); |
| |
| m_out.appendTo(integerExponentPowBlock, doubleExponentPowBlockEntry); |
| ValueFromBlock powDoubleIntResult = m_out.anchor(m_out.doublePowi(base, integerExponent)); |
| m_out.jump(continuation); |
| |
| // If y is NaN, the result is NaN. |
| m_out.appendTo(doubleExponentPowBlockEntry, nanExceptionBaseIsOne); |
| LValue exponentIsNaN; |
| if (provenType(m_node->child2()) & SpecDoubleNaN) |
| exponentIsNaN = m_out.doubleNotEqualOrUnordered(exponent, exponent); |
| else |
| exponentIsNaN = m_out.booleanFalse; |
| m_out.branch(exponentIsNaN, rarely(nanExceptionResultIsNaN), usually(nanExceptionBaseIsOne)); |
| |
| // If abs(x) is 1 and y is +infinity, the result is NaN. |
| // If abs(x) is 1 and y is -infinity, the result is NaN. |
| |
| // Test if base == 1. |
| m_out.appendTo(nanExceptionBaseIsOne, nanExceptionExponentIsInfinity); |
| LValue absoluteBase = m_out.doubleAbs(base); |
| LValue absoluteBaseIsOne = m_out.doubleEqual(absoluteBase, m_out.constDouble(1)); |
| m_out.branch(absoluteBaseIsOne, rarely(nanExceptionExponentIsInfinity), usually(testExponentIsOneHalf)); |
| |
| // Test if abs(y) == Infinity. |
| m_out.appendTo(nanExceptionExponentIsInfinity, testExponentIsOneHalf); |
| LValue absoluteExponent = m_out.doubleAbs(exponent); |
| LValue absoluteExponentIsInfinity = m_out.doubleEqual(absoluteExponent, m_out.constDouble(std::numeric_limits<double>::infinity())); |
| m_out.branch(absoluteExponentIsInfinity, rarely(nanExceptionResultIsNaN), usually(testExponentIsOneHalf)); |
| |
| // If y == 0.5 or y == -0.5, handle it through SQRT. |
| // We have be carefuly with -0 and -Infinity. |
| |
| // Test if y == 0.5 |
| m_out.appendTo(testExponentIsOneHalf, handleBaseZeroExponentIsOneHalf); |
| LValue exponentIsOneHalf = m_out.doubleEqual(exponent, m_out.constDouble(0.5)); |
| m_out.branch(exponentIsOneHalf, rarely(handleBaseZeroExponentIsOneHalf), usually(testExponentIsNegativeOneHalf)); |
| |
| // Handle x == -0. |
| m_out.appendTo(handleBaseZeroExponentIsOneHalf, handleInfinityForExponentIsOneHalf); |
| LValue baseIsZeroExponentIsOneHalf = m_out.doubleEqual(base, m_out.doubleZero); |
| ValueFromBlock zeroResultExponentIsOneHalf = m_out.anchor(m_out.doubleZero); |
| m_out.branch(baseIsZeroExponentIsOneHalf, rarely(continuation), usually(handleInfinityForExponentIsOneHalf)); |
| |
| // Test if abs(x) == Infinity. |
| m_out.appendTo(handleInfinityForExponentIsOneHalf, exponentIsOneHalfNormal); |
| LValue absoluteBaseIsInfinityOneHalf = m_out.doubleEqual(absoluteBase, m_out.constDouble(std::numeric_limits<double>::infinity())); |
| m_out.branch(absoluteBaseIsInfinityOneHalf, rarely(exponentIsOneHalfInfinity), usually(exponentIsOneHalfNormal)); |
| |
| // The exponent is 0.5, the base is finite or NaN, we can use SQRT. |
| m_out.appendTo(exponentIsOneHalfNormal, exponentIsOneHalfInfinity); |
| ValueFromBlock sqrtResult = m_out.anchor(m_out.doubleSqrt(base)); |
| m_out.jump(continuation); |
| |
| // The exponent is 0.5, the base is infinite, the result is always infinite. |
| m_out.appendTo(exponentIsOneHalfInfinity, testExponentIsNegativeOneHalf); |
| ValueFromBlock sqrtInfinityResult = m_out.anchor(m_out.constDouble(std::numeric_limits<double>::infinity())); |
| m_out.jump(continuation); |
| |
| // Test if y == -0.5 |
| m_out.appendTo(testExponentIsNegativeOneHalf, testBaseZeroExponentIsNegativeOneHalf); |
| LValue exponentIsNegativeOneHalf = m_out.doubleEqual(exponent, m_out.constDouble(-0.5)); |
| m_out.branch(exponentIsNegativeOneHalf, rarely(testBaseZeroExponentIsNegativeOneHalf), usually(powBlock)); |
| |
| // Handle x == -0. |
| m_out.appendTo(testBaseZeroExponentIsNegativeOneHalf, handleBaseZeroExponentIsNegativeOneHalf); |
| LValue baseIsZeroExponentIsNegativeOneHalf = m_out.doubleEqual(base, m_out.doubleZero); |
| m_out.branch(baseIsZeroExponentIsNegativeOneHalf, rarely(handleBaseZeroExponentIsNegativeOneHalf), usually(handleInfinityForExponentIsNegativeOneHalf)); |
| |
| m_out.appendTo(handleBaseZeroExponentIsNegativeOneHalf, handleInfinityForExponentIsNegativeOneHalf); |
| ValueFromBlock oneOverSqrtZeroResult = m_out.anchor(m_out.constDouble(std::numeric_limits<double>::infinity())); |
| m_out.jump(continuation); |
| |
| // Test if abs(x) == Infinity. |
| m_out.appendTo(handleInfinityForExponentIsNegativeOneHalf, exponentIsNegativeOneHalfNormal); |
| LValue absoluteBaseIsInfinityNegativeOneHalf = m_out.doubleEqual(absoluteBase, m_out.constDouble(std::numeric_limits<double>::infinity())); |
| m_out.branch(absoluteBaseIsInfinityNegativeOneHalf, rarely(exponentIsNegativeOneHalfInfinity), usually(exponentIsNegativeOneHalfNormal)); |
| |
| // The exponent is -0.5, the base is finite or NaN, we can use 1/SQRT. |
| m_out.appendTo(exponentIsNegativeOneHalfNormal, exponentIsNegativeOneHalfInfinity); |
| LValue sqrtBase = m_out.doubleSqrt(base); |
| ValueFromBlock oneOverSqrtResult = m_out.anchor(m_out.div(m_out.constDouble(1.), sqrtBase)); |
| m_out.jump(continuation); |
| |
| // The exponent is -0.5, the base is infinite, the result is always zero. |
| m_out.appendTo(exponentIsNegativeOneHalfInfinity, powBlock); |
| ValueFromBlock oneOverSqrtInfinityResult = m_out.anchor(m_out.doubleZero); |
| m_out.jump(continuation); |
| |
| m_out.appendTo(powBlock, nanExceptionResultIsNaN); |
| ValueFromBlock powResult = m_out.anchor(m_out.doublePow(base, exponent)); |
| m_out.jump(continuation); |
| |
| m_out.appendTo(nanExceptionResultIsNaN, continuation); |
| ValueFromBlock pureNan = m_out.anchor(m_out.constDouble(PNaN)); |
| m_out.jump(continuation); |
| |
| m_out.appendTo(continuation, lastNext); |
| setDouble(m_out.phi(Double, powDoubleIntResult, zeroResultExponentIsOneHalf, sqrtResult, sqrtInfinityResult, oneOverSqrtZeroResult, oneOverSqrtResult, oneOverSqrtInfinityResult, powResult, pureNan)); |
| } |
| } |
| |
| void compileArithRandom() |
| { |
| JSGlobalObject* globalObject = m_graph.globalObjectFor(m_node->origin.semantic); |
| |
| // Inlined WeakRandom::advance(). |
| // uint64_t x = m_low; |
| void* lowAddress = reinterpret_cast<uint8_t*>(globalObject) + JSGlobalObject::weakRandomOffset() + WeakRandom::lowOffset(); |
| LValue low = m_out.load64(m_out.absolute(lowAddress)); |
| // uint64_t y = m_high; |
| void* highAddress = reinterpret_cast<uint8_t*>(globalObject) + JSGlobalObject::weakRandomOffset() + WeakRandom::highOffset(); |
| LValue high = m_out.load64(m_out.absolute(highAddress)); |
| // m_low = y; |
| m_out.store64(high, m_out.absolute(lowAddress)); |
| |
| // x ^= x << 23; |
| LValue phase1 = m_out.bitXor(m_out.shl(low, m_out.constInt64(23)), low); |
| |
| // x ^= x >> 17; |
| LValue phase2 = m_out.bitXor(m_out.lShr(phase1, m_out.constInt64(17)), phase1); |
| |
| // x ^= y ^ (y >> 26); |
| LValue phase3 = m_out.bitXor(m_out.bitXor(high, m_out.lShr(high, m_out.constInt64(26))), phase2); |
| |
| // m_high = x; |
| m_out.store64(phase3, m_out.absolute(highAddress)); |
| |
| // return x + y; |
| LValue random64 = m_out.add(phase3, high); |
| |
| // Extract random 53bit. [0, 53] bit is safe integer number ranges in double representation. |
| LValue random53 = m_out.bitAnd(random64, m_out.constInt64((1ULL << 53) - 1)); |
| |
| LValue double53Integer = m_out.intToDouble(random53); |
| |
| // Convert `(53bit double integer value) / (1 << 53)` to `(53bit double integer value) * (1.0 / (1 << 53))`. |
| // In latter case, `1.0 / (1 << 53)` will become a double value represented as (mantissa = 0 & exp = 970, it means 1e-(2**54)). |
| static const double scale = 1.0 / (1ULL << 53); |
| |
| // Multiplying 1e-(2**54) with the double integer does not change anything of the mantissa part of the double integer. |
| // It just reduces the exp part of the given 53bit double integer. |
| // (Except for 0.0. This is specially handled and in this case, exp just becomes 0.) |
| // Now we get 53bit precision random double value in [0, 1). |
| LValue result = m_out.doubleMul(double53Integer, m_out.constDouble(scale)); |
| |
| setDouble(result); |
| } |
| |
| void compileArithRound() |
| { |
| if (m_node->child1().useKind() == DoubleRepUse) { |
| LValue result = nullptr; |
| if (producesInteger(m_node->arithRoundingMode()) && !shouldCheckNegativeZero(m_node->arithRoundingMode())) { |
| LValue value = lowDouble(m_node->child1()); |
| result = m_out.doubleFloor(m_out.doubleAdd(value, m_out.constDouble(0.5))); |
| } else { |
| LBasicBlock realPartIsMoreThanHalf = m_out.newBlock(); |
| LBasicBlock continuation = m_out.newBlock(); |
| |
| LValue value = lowDouble(m_node->child1()); |
| LValue integerValue = m_out.doubleCeil(value); |
| ValueFromBlock integerValueResult = m_out.anchor(integerValue); |
| |
| LValue realPart = m_out.doubleSub(integerValue, value); |
| |
| m_out.branch(m_out.doubleGreaterThanOrUnordered(realPart, m_out.constDouble(0.5)), unsure(realPartIsMoreThanHalf), unsure(continuation)); |
| |
| LBasicBlock lastNext = m_out.appendTo(realPartIsMoreThanHalf, continuation); |
| LValue integerValueRoundedDown = m_out.doubleSub(integerValue, m_out.constDouble(1)); |
| ValueFromBlock integerValueRoundedDownResult = m_out.anchor(integerValueRoundedDown); |
| m_out.jump(continuation); |
| m_out.appendTo(continuation, lastNext); |
| |
| result = m_out.phi(Double, integerValueResult, integerValueRoundedDownResult); |
| } |
| |
| if (producesInteger(m_node->arithRoundingMode())) { |
| LValue integerValue = convertDoubleToInt32(result, shouldCheckNegativeZero(m_node->arithRoundingMode())); |
| setInt32(integerValue); |
| } else |
| setDouble(result); |
| return; |
| } |
| |
| DFG_ASSERT(m_graph, m_node, m_node->child1().useKind() == UntypedUse, m_node->child1().useKind()); |
| LValue argument = lowJSValue(m_node->child1()); |
| setJSValue(vmCall(Int64, m_out.operation(operationArithRound), m_callFrame, argument)); |
| } |
| |
| void compileArithFloor() |
| { |
| if (m_node->child1().useKind() == DoubleRepUse) { |
| LValue value = lowDouble(m_node->child1()); |
| LValue integerValue = m_out.doubleFloor(value); |
| if (producesInteger(m_node->arithRoundingMode())) |
| setInt32(convertDoubleToInt32(integerValue, shouldCheckNegativeZero(m_node->arithRoundingMode()))); |
| else |
| setDouble(integerValue); |
| return; |
| } |
| DFG_ASSERT(m_graph, m_node, m_node->child1().useKind() == UntypedUse, m_node->child1().useKind()); |
| LValue argument = lowJSValue(m_node->child1()); |
| setJSValue(vmCall(Int64, m_out.operation(operationArithFloor), m_callFrame, argument)); |
| } |
| |
| void compileArithCeil() |
| { |
| if (m_node->child1().useKind() == DoubleRepUse) { |
| LValue value = lowDouble(m_node->child1()); |
| LValue integerValue = m_out.doubleCeil(value); |
| if (producesInteger(m_node->arithRoundingMode())) |
| setInt32(convertDoubleToInt32(integerValue, shouldCheckNegativeZero(m_node->arithRoundingMode()))); |
| else |
| setDouble(integerValue); |
| return; |
| } |
| DFG_ASSERT(m_graph, m_node, m_node->child1().useKind() == UntypedUse, m_node->child1().useKind()); |
| LValue argument = lowJSValue(m_node->child1()); |
| setJSValue(vmCall(Int64, m_out.operation(operationArithCeil), m_callFrame, argument)); |
| } |
| |
| void compileArithTrunc() |
| { |
| if (m_node->child1().useKind() == DoubleRepUse) { |
| LValue value = lowDouble(m_node->child1()); |
| LValue result = m_out.doubleTrunc(value); |
| if (producesInteger(m_node->arithRoundingMode())) |
| setInt32(convertDoubleToInt32(result, shouldCheckNegativeZero(m_node->arithRoundingMode()))); |
| else |
| setDouble(result); |
| return; |
| } |
| DFG_ASSERT(m_graph, m_node, m_node->child1().useKind() == UntypedUse, m_node->child1().useKind()); |
| LValue argument = lowJSValue(m_node->child1()); |
| setJSValue(vmCall(Int64, m_out.operation(operationArithTrunc), m_callFrame, argument)); |
| } |
| |
| void compileArithSqrt() |
| { |
| if (m_node->child1().useKind() == DoubleRepUse) { |
| setDouble(m_out.doubleSqrt(lowDouble(m_node->child1()))); |
| return; |
| } |
| LValue argument = lowJSValue(m_node->child1()); |
| LValue result = vmCall(Double, m_out.operation(operationArithSqrt), m_callFrame, argument); |
| setDouble(result); |
| } |
| |
| void compileArithFRound() |
| { |
| if (m_node->child1().useKind() == DoubleRepUse) { |
| setDouble(m_out.fround(lowDouble(m_node->child1()))); |
| return; |
| } |
| LValue argument = lowJSValue(m_node->child1()); |
| LValue result = vmCall(Double, m_out.operation(operationArithFRound), m_callFrame, argument); |
| setDouble(result); |
| } |
| |
| void compileArithNegate() |
| { |
| switch (m_node->child1().useKind()) { |
| case Int32Use: { |
| LValue value = lowInt32(m_node->child1()); |
| |
| LValue result; |
| if (!shouldCheckOverflow(m_node->arithMode())) |
| result = m_out.neg(value); |
| else if (!shouldCheckNegativeZero(m_node->arithMode())) { |
| CheckValue* check = m_out.speculateSub(m_out.int32Zero, value); |
| blessSpeculation(check, Overflow, noValue(), nullptr, m_origin); |
| result = check; |
| } else { |
| speculate(Overflow, noValue(), 0, m_out.testIsZero32(value, m_out.constInt32(0x7fffffff))); |
| result = m_out.neg(value); |
| } |
| |
| setInt32(result); |
| break; |
| } |
| |
| case Int52RepUse: { |
| if (!abstractValue(m_node->child1()).couldBeType(SpecInt52Only)) { |
| Int52Kind kind; |
| LValue value = lowWhicheverInt52(m_node->child1(), kind); |
| LValue result = m_out.neg(value); |
| if (shouldCheckNegativeZero(m_node->arithMode())) |
| speculate(NegativeZero, noValue(), 0, m_out.isZero64(result)); |
| setInt52(result, kind); |
| break; |
| } |
| |
| LValue value = lowInt52(m_node->child1()); |
| CheckValue* result = m_out.speculateSub(m_out.int64Zero, value); |
| blessSpeculation(result, Int52Overflow, noValue(), nullptr, m_origin); |
| if (shouldCheckNegativeZero(m_node->arithMode())) |
| speculate(NegativeZero, noValue(), 0, m_out.isZero64(result)); |
| setInt52(result); |
| break; |
| } |
| |
| case DoubleRepUse: { |
| setDouble(m_out.doubleNeg(lowDouble(m_node->child1()))); |
| break; |
| } |
| |
| default: |
| DFG_ASSERT(m_graph, m_node, m_node->child1().useKind() == UntypedUse, m_node->child1().useKind()); |
| CodeBlock* baselineCodeBlock = m_ftlState.graph.baselineCodeBlockFor(m_node->origin.semantic); |
| ArithProfile* arithProfile = baselineCodeBlock->arithProfileForBytecodeOffset(m_node->origin.semantic.bytecodeIndex); |
| Instruction* instruction = &baselineCodeBlock->instructions()[m_node->origin.semantic.bytecodeIndex]; |
| auto repatchingFunction = operationArithNegateOptimize; |
| auto nonRepatchingFunction = operationArithNegate; |
| compileUnaryMathIC<JITNegGenerator>(arithProfile, instruction, repatchingFunction, nonRepatchingFunction); |
| break; |
| } |
| } |
| |
| void compileBitAnd() |
| { |
| if (m_node->isBinaryUseKind(UntypedUse)) { |
| emitBinaryBitOpSnippet<JITBitAndGenerator>(operationValueBitAnd); |
| return; |
| } |
| setInt32(m_out.bitAnd(lowInt32(m_node->child1()), lowInt32(m_node->child2()))); |
| } |
| |
| void compileBitOr() |
| { |
| if (m_node->isBinaryUseKind(UntypedUse)) { |
| emitBinaryBitOpSnippet<JITBitOrGenerator>(operationValueBitOr); |
| return; |
| } |
| setInt32(m_out.bitOr(lowInt32(m_node->child1()), lowInt32(m_node->child2()))); |
| } |
| |
| void compileBitXor() |
| { |
| if (m_node->isBinaryUseKind(UntypedUse)) { |
| emitBinaryBitOpSnippet<JITBitXorGenerator>(operationValueBitXor); |
| return; |
| } |
| setInt32(m_out.bitXor(lowInt32(m_node->child1()), lowInt32(m_node->child2()))); |
| } |
| |
| void compileBitRShift() |
| { |
| if (m_node->isBinaryUseKind(UntypedUse)) { |
| emitRightShiftSnippet(JITRightShiftGenerator::SignedShift); |
| return; |
| } |
| setInt32(m_out.aShr( |
| lowInt32(m_node->child1()), |
| m_out.bitAnd(lowInt32(m_node->child2()), m_out.constInt32(31)))); |
| } |
| |
| void compileBitLShift() |
| { |
| if (m_node->isBinaryUseKind(UntypedUse)) { |
| emitBinaryBitOpSnippet<JITLeftShiftGenerator>(operationValueBitLShift); |
| return; |
| } |
| setInt32(m_out.shl( |
| lowInt32(m_node->child1()), |
| m_out.bitAnd(lowInt32(m_node->child2()), m_out.constInt32(31)))); |
| } |
| |
| void compileBitURShift() |
| { |
| if (m_node->isBinaryUseKind(UntypedUse)) { |
| emitRightShiftSnippet(JITRightShiftGenerator::UnsignedShift); |
| return; |
| } |
| setInt32(m_out.lShr( |
| lowInt32(m_node->child1()), |
| m_out.bitAnd(lowInt32(m_node->child2()), m_out.constInt32(31)))); |
| } |
| |
| void compileUInt32ToNumber() |
| { |
| LValue value = lowInt32(m_node->child1()); |
| |
| if (doesOverflow(m_node->arithMode())) { |
| setStrictInt52(m_out.zeroExtPtr(value)); |
| return; |
| } |
| |
| speculate(Overflow, noValue(), 0, m_out.lessThan(value, m_out.int32Zero)); |
| setInt32(value); |
| } |
| |
| void compileCheckStructure() |
| { |
| ExitKind exitKind; |
| if (m_node->child1()->hasConstant()) |
| exitKind = BadConstantCache; |
| else |
| exitKind = BadCache; |
| |
| switch (m_node->child1().useKind()) { |
| case CellUse: |
| case KnownCellUse: { |
| LValue cell = lowCell(m_node->child1()); |
| |
| checkStructure( |
| m_out.load32(cell, m_heaps.JSCell_structureID), jsValueValue(cell), |
| exitKind, m_node->structureSet(), |
| [&] (RegisteredStructure structure) { |
| return weakStructureID(structure); |
| }); |
| return; |
| } |
| |
| case CellOrOtherUse: { |
| LValue value = lowJSValue(m_node->child1(), ManualOperandSpeculation); |
| |
| LBasicBlock cellCase = m_out.newBlock(); |
| LBasicBlock notCellCase = m_out.newBlock(); |
| LBasicBlock continuation = m_out.newBlock(); |
| |
| m_out.branch( |
| isCell(value, provenType(m_node->child1())), unsure(cellCase), unsure(notCellCase)); |
| |
| LBasicBlock lastNext = m_out.appendTo(cellCase, notCellCase); |
| checkStructure( |
| m_out.load32(value, m_heaps.JSCell_structureID), jsValueValue(value), |
| exitKind, m_node->structureSet(), |
| [&] (RegisteredStructure structure) { |
| return weakStructureID(structure); |
| }); |
| m_out.jump(continuation); |
| |
| m_out.appendTo(notCellCase, continuation); |
| FTL_TYPE_CHECK(jsValueValue(value), m_node->child1(), SpecCell | SpecOther, isNotOther(value)); |
| m_out.jump(continuation); |
| |
| m_out.appendTo(continuation, lastNext); |
| return; |
| } |
| |
| default: |
| DFG_CRASH(m_graph, m_node, "Bad use kind"); |
| return; |
| } |
| } |
| |
| void compileCheckStructureOrEmpty() |
| { |
| ExitKind exitKind; |
| if (m_node->child1()->hasConstant()) |
| exitKind = BadConstantCache; |
| else |
| exitKind = BadCache; |
| |
| LValue cell = lowCell(m_node->child1()); |
| bool maySeeEmptyValue = m_interpreter.forNode(m_node->child1()).m_type & SpecEmpty; |
| LBasicBlock notEmpty; |
| LBasicBlock continuation; |
| LBasicBlock lastNext; |
| if (maySeeEmptyValue) { |
| notEmpty = m_out.newBlock(); |
| continuation = m_out.newBlock(); |
| m_out.branch(m_out.isZero64(cell), unsure(continuation), unsure(notEmpty)); |
| lastNext = m_out.appendTo(notEmpty, continuation); |
| } |
| |
| checkStructure( |
| m_out.load32(cell, m_heaps.JSCell_structureID), jsValueValue(cell), |
| exitKind, m_node->structureSet(), |
| [&] (RegisteredStructure structure) { |
| return weakStructureID(structure); |
| }); |
| |
| if (maySeeEmptyValue) { |
| m_out.jump(continuation); |
| m_out.appendTo(continuation, lastNext); |
| } |
| } |
| |
| void compileCheckCell() |
| { |
| LValue cell = lowCell(m_node->child1()); |
| |
| speculate( |
| BadCell, jsValueValue(cell), m_node->child1().node(), |
| m_out.notEqual(cell, weakPointer(m_node->cellOperand()->cell()))); |
| } |
| |
| void compileCheckBadCell() |
| { |
| terminate(BadCell); |
| } |
| |
| void compileCheckNotEmpty() |
| { |
| speculate(TDZFailure, noValue(), nullptr, m_out.isZero64(lowJSValue(m_node->child1()))); |
| } |
| |
| void compileAssertNotEmpty() |
| { |
| if (!validationEnabled()) |
| return; |
| |
| B3::PatchpointValue* patchpoint = m_out.patchpoint(Void); |
| patchpoint->appendSomeRegister(lowJSValue(m_node->child1())); |
| patchpoint->setGenerator( |
| [=] (CCallHelpers& jit, const StackmapGenerationParams& params) { |
| AllowMacroScratchRegisterUsage allowScratch(jit); |
| GPRReg input = params[0].gpr(); |
| CCallHelpers::Jump done = jit.branchTest64(CCallHelpers::NonZero, input); |
| jit.breakpoint(); |
| done.link(&jit); |
| }); |
| } |
| |
| void compileCheckStringIdent() |
| { |
| UniquedStringImpl* uid = m_node->uidOperand(); |
| LValue stringImpl = lowStringIdent(m_node->child1()); |
| speculate(BadIdent, noValue(), nullptr, m_out.notEqual(stringImpl, m_out.constIntPtr(uid))); |
| } |
| |
| void compileGetExecutable() |
| { |
| LValue cell = lowCell(m_node->child1()); |
| speculateFunction(m_node->child1(), cell); |
| setJSValue( |
| m_out.bitXor( |
| m_out.loadPtr(cell, m_heaps.JSFunction_executable), |
| m_out.constIntPtr(JSFunctionPoison::key()))); |
| } |
| |
| void compileArrayify() |
| { |
| LValue cell = lowCell(m_node->child1()); |
| LValue property = !!m_node->child2() ? lowInt32(m_node->child2()) : 0; |
| |
| LBasicBlock unexpectedStructure = m_out.newBlock(); |
| LBasicBlock continuation = m_out.newBlock(); |
| |
| auto isUnexpectedArray = [&] (LValue cell) { |
| if (m_node->op() == Arrayify) |
| return m_out.logicalNot(isArrayTypeForArrayify(cell, m_node->arrayMode())); |
| |
| ASSERT(m_node->op() == ArrayifyToStructure); |
| return m_out.notEqual(m_out.load32(cell, m_heaps.JSCell_structureID), weakStructureID(m_node->structure())); |
| }; |
| |
| m_out.branch(isUnexpectedArray(cell), rarely(unexpectedStructure), usually(continuation)); |
| |
| LBasicBlock lastNext = m_out.appendTo(unexpectedStructure, continuation); |
| |
| if (property) { |
| switch (m_node->arrayMode().type()) { |
| case Array::Int32: |
| case Array::Double: |
| case Array::Contiguous: |
| speculate( |
| Uncountable, noValue(), 0, |
| m_out.aboveOrEqual(property, m_out.constInt32(MIN_SPARSE_ARRAY_INDEX))); |
| break; |
| default: |
| break; |
| } |
| } |
| |
| switch (m_node->arrayMode().type()) { |
| case Array::Int32: |
| vmCall(Void, m_out.operation(operationEnsureInt32), m_callFrame, cell); |
| break; |
| case Array::Double: |
| vmCall(Void, m_out.operation(operationEnsureDouble), m_callFrame, cell); |
| break; |
| case Array::Contiguous: |
| vmCall(Void, m_out.operation(operationEnsureContiguous), m_callFrame, cell); |
| break; |
| case Array::ArrayStorage: |
| case Array::SlowPutArrayStorage: |
| vmCall(Void, m_out.operation(operationEnsureArrayStorage), m_callFrame, cell); |
| break; |
| default: |
| DFG_CRASH(m_graph, m_node, "Bad array type"); |
| break; |
| } |
| |
| speculate(BadIndexingType, jsValueValue(cell), 0, isUnexpectedArray(cell)); |
| m_out.jump(continuation); |
| |
| m_out.appendTo(continuation, lastNext); |
| } |
| |
| void compilePutStructure() |
| { |
| m_ftlState.jitCode->common.notifyCompilingStructureTransition(m_graph.m_plan, codeBlock(), m_node); |
| |
| RegisteredStructure oldStructure = m_node->transition()->previous; |
| RegisteredStructure newStructure = m_node->transition()->next; |
| ASSERT_UNUSED(oldStructure, oldStructure->indexingType() == newStructure->indexingType()); |
| ASSERT(oldStructure->typeInfo().inlineTypeFlags() == newStructure->typeInfo().inlineTypeFlags()); |
| ASSERT(oldStructure->typeInfo().type() == newStructure->typeInfo().type()); |
| |
| LValue cell = lowCell(m_node->child1()); |
| m_out.store32( |
| weakStructureID(newStructure), |
| cell, m_heaps.JSCell_structureID); |
| } |
| |
| void compileGetById(AccessType type) |
| { |
| ASSERT(type == AccessType::Get || type == AccessType::TryGet || type == AccessType::GetDirect); |
| switch (m_node->child1().useKind()) { |
| case CellUse: { |
| setJSValue(getById(lowCell(m_node->child1()), type)); |
| return; |
| } |
| |
| case UntypedUse: { |
| // This is pretty weird, since we duplicate the slow path both here and in the |
| // code generated by the IC. We should investigate making this less bad. |
| // https://bugs.webkit.org/show_bug.cgi?id=127830 |
| LValue value = lowJSValue(m_node->child1()); |
| |
| LBasicBlock cellCase = m_out.newBlock(); |
| LBasicBlock notCellCase = m_out.newBlock(); |
| LBasicBlock continuation = m_out.newBlock(); |
| |
| m_out.branch( |
| isCell(value, provenType(m_node->child1())), unsure(cellCase), unsure(notCellCase)); |
| |
| LBasicBlock lastNext = m_out.appendTo(cellCase, notCellCase); |
| ValueFromBlock cellResult = m_out.anchor(getById(value, type)); |
| m_out.jump(continuation); |
| |
| J_JITOperation_EJI getByIdFunction = appropriateGenericGetByIdFunction(type); |
| |
| m_out.appendTo(notCellCase, continuation); |
| ValueFromBlock notCellResult = m_out.anchor(vmCall( |
| Int64, m_out.operation(getByIdFunction), |
| m_callFrame, value, |
| m_out.constIntPtr(m_graph.identifiers()[m_node->identifierNumber()]))); |
| m_out.jump(continuation); |
| |
| m_out.appendTo(continuation, lastNext); |
| setJSValue(m_out.phi(Int64, cellResult, notCellResult)); |
| return; |
| } |
| |
| default: |
| DFG_CRASH(m_graph, m_node, "Bad use kind"); |
| return; |
| } |
| } |
| |
| void compileGetByIdWithThis() |
| { |
| if (m_node->child1().useKind() == CellUse && m_node->child2().useKind() == CellUse) |
| setJSValue(getByIdWithThis(lowCell(m_node->child1()), lowCell(m_node->child2()))); |
| else { |
| LValue base = lowJSValue(m_node->child1()); |
| LValue thisValue = lowJSValue(m_node->child2()); |
| |
| LBasicBlock baseCellCase = m_out.newBlock(); |
| LBasicBlock notCellCase = m_out.newBlock(); |
| LBasicBlock thisValueCellCase = m_out.newBlock(); |
| LBasicBlock continuation = m_out.newBlock(); |
| |
| m_out.branch( |
| isCell(base, provenType(m_node->child1())), unsure(baseCellCase), unsure(notCellCase)); |
| |
| LBasicBlock lastNext = m_out.appendTo(baseCellCase, thisValueCellCase); |
| |
| m_out.branch( |
| isCell(thisValue, provenType(m_node->child2())), unsure(thisValueCellCase), unsure(notCellCase)); |
| |
| m_out.appendTo(thisValueCellCase, notCellCase); |
| ValueFromBlock cellResult = m_out.anchor(getByIdWithThis(base, thisValue)); |
| m_out.jump(continuation); |
| |
| m_out.appendTo(notCellCase, continuation); |
| ValueFromBlock notCellResult = m_out.anchor(vmCall( |
| Int64, m_out.operation(operationGetByIdWithThisGeneric), |
| m_callFrame, base, thisValue, |
| m_out.constIntPtr(m_graph.identifiers()[m_node->identifierNumber()]))); |
| m_out.jump(continuation); |
| |
| m_out.appendTo(continuation, lastNext); |
| setJSValue(m_out.phi(Int64, cellResult, notCellResult)); |
| } |
| |
| } |
| |
| void compileGetByValWithThis() |
| { |
| LValue base = lowJSValue(m_node->child1()); |
| LValue thisValue = lowJSValue(m_node->child2()); |
| LValue subscript = lowJSValue(m_node->child3()); |
| |
| LValue result = vmCall(Int64, m_out.operation(operationGetByValWithThis), m_callFrame, base, thisValue, subscript); |
| setJSValue(result); |
| } |
| |
| void compilePutByIdWithThis() |
| { |
| LValue base = lowJSValue(m_node->child1()); |
| LValue thisValue = lowJSValue(m_node->child2()); |
| LValue value = lowJSValue(m_node->child3()); |
| |
| vmCall(Void, m_out.operation(m_graph.isStrictModeFor(m_node->origin.semantic) ? operationPutByIdWithThisStrict : operationPutByIdWithThis), |
| m_callFrame, base, thisValue, value, m_out.constIntPtr(m_graph.identifiers()[m_node->identifierNumber()])); |
| } |
| |
| void compilePutByValWithThis() |
| { |
| LValue base = lowJSValue(m_graph.varArgChild(m_node, 0)); |
| LValue thisValue = lowJSValue(m_graph.varArgChild(m_node, 1)); |
| LValue property = lowJSValue(m_graph.varArgChild(m_node, 2)); |
| LValue value = lowJSValue(m_graph.varArgChild(m_node, 3)); |
| |
| vmCall(Void, m_out.operation(m_graph.isStrictModeFor(m_node->origin.semantic) ? operationPutByValWithThisStrict : operationPutByValWithThis), |
| m_callFrame, base, thisValue, property, value); |
| } |
| |
| void compileAtomicsReadModifyWrite() |
| { |
| TypedArrayType type = m_node->arrayMode().typedArrayType(); |
| unsigned numExtraArgs = numExtraAtomicsArgs(m_node->op()); |
| Edge baseEdge = m_graph.child(m_node, 0); |
| Edge indexEdge = m_graph.child(m_node, 1); |
| Edge argEdges[maxNumExtraAtomicsArgs]; |
| for (unsigned i = numExtraArgs; i--;) |
| argEdges[i] = m_graph.child(m_node, 2 + i); |
| Edge storageEdge = m_graph.child(m_node, 2 + numExtraArgs); |
| |
| auto operation = [&] () -> LValue { |
| switch (m_node->op()) { |
| case AtomicsAdd: |
| return m_out.operation(operationAtomicsAdd); |
| case AtomicsAnd: |
| return m_out.operation(operationAtomicsAnd); |
| case AtomicsCompareExchange: |
| return m_out.operation(operationAtomicsCompareExchange); |
| case AtomicsExchange: |
| return m_out.operation(operationAtomicsExchange); |
| case AtomicsLoad: |
| return m_out.operation(operationAtomicsLoad); |
| case AtomicsOr: |
| return m_out.operation(operationAtomicsOr); |
| case AtomicsStore: |
| return m_out.operation(operationAtomicsStore); |
| case AtomicsSub: |
| return m_out.operation(operationAtomicsSub); |
| case AtomicsXor: |
| return m_out.operation(operationAtomicsXor); |
| default: |
| RELEASE_ASSERT_NOT_REACHED(); |
| break; |
| } |
| }; |
| |
| if (!storageEdge) { |
| Vector<LValue> args; |
| args.append(m_callFrame); |
| args.append(lowJSValue(baseEdge)); |
| args.append(lowJSValue(indexEdge)); |
| for (unsigned i = 0; i < numExtraArgs; ++i) |
| args.append(lowJSValue(argEdges[i])); |
| LValue result = vmCall(Int64, operation(), args); |
| setJSValue(result); |
| return; |
| } |
| |
| LValue index = lowInt32(indexEdge); |
| LValue args[2]; |
| for (unsigned i = numExtraArgs; i--;) |
| args[i] = getIntTypedArrayStoreOperand(argEdges[i]); |
| LValue storage = lowStorage(storageEdge); |
| |
| TypedPointer pointer = pointerIntoTypedArray(storage, index, type); |
| Width width = widthForBytes(elementSize(type)); |
| |
| LValue atomicValue; |
| LValue result; |
| |
| auto sanitizeResult = [&] (LValue value) -> LValue { |
| if (isSigned(type)) { |
| switch (elementSize(type)) { |
| case 1: |
| value = m_out.bitAnd(value, m_out.constInt32(0xff)); |
| break; |
| case 2: |
| value = m_out.bitAnd(value, m_out.constInt32(0xffff)); |
| break; |
| case 4: |
| break; |
| default: |
| RELEASE_ASSERT_NOT_REACHED(); |
| break; |
| } |
| } |
| return value; |
| }; |
| |
| switch (m_node->op()) { |
| case AtomicsAdd: |
| atomicValue = m_out.atomicXchgAdd(args[0], pointer, width); |
| result = sanitizeResult(atomicValue); |
| break; |
| case AtomicsAnd: |
| atomicValue = m_out.atomicXchgAnd(args[0], pointer, width); |
| result = sanitizeResult(atomicValue); |
| break; |
| case AtomicsCompareExchange: |
| atomicValue = m_out.atomicStrongCAS(args[0], args[1], pointer, width); |
| result = sanitizeResult(atomicValue); |
| break; |
| case AtomicsExchange: |
| atomicValue = m_out.atomicXchg(args[0], pointer, width); |
| result = sanitizeResult(atomicValue); |
| break; |
| case AtomicsLoad: |
| atomicValue = m_out.atomicXchgAdd(m_out.int32Zero, pointer, width); |
| result = sanitizeResult(atomicValue); |
| break; |
| case AtomicsOr: |
| atomicValue = m_out.atomicXchgOr(args[0], pointer, width); |
| result = sanitizeResult(atomicValue); |
| break; |
| case AtomicsStore: |
| atomicValue = m_out.atomicXchg(args[0], pointer, width); |
| result = args[0]; |
| break; |
| case AtomicsSub: |
| atomicValue = m_out.atomicXchgSub(args[0], pointer, width); |
| result = sanitizeResult(atomicValue); |
| break; |
| case AtomicsXor: |
| atomicValue = m_out.atomicXchgXor(args[0], pointer, width); |
| result = sanitizeResult(atomicValue); |
| break; |
| default: |
| RELEASE_ASSERT_NOT_REACHED(); |
| break; |
| } |
| // Signify that the state against which the atomic operations are serialized is confined to just |
| // the typed array storage, since that's as precise of an abstraction as we can have of shared |
| // array buffer storage. |
| m_heaps.decorateFencedAccess(&m_heaps.typedArrayProperties, atomicValue); |
| |
| setIntTypedArrayLoadResult(result, type); |
| } |
| |
| void compileAtomicsIsLockFree() |
| { |
| if (m_node->child1().useKind() != Int32Use) { |
| setJSValue(vmCall(Int64, m_out.operation(operationAtomicsIsLockFree), m_callFrame, lowJSValue(m_node->child1()))); |
| return; |
| } |
| |
| LValue bytes = lowInt32(m_node->child1()); |
| |
| LBasicBlock trueCase = m_out.newBlock(); |
| LBasicBlock falseCase = m_out.newBlock(); |
| LBasicBlock continuation = m_out.newBlock(); |
| |
| LBasicBlock lastNext = m_out.insertNewBlocksBefore(trueCase); |
| |
| Vector<SwitchCase> cases; |
| cases.append(SwitchCase(m_out.constInt32(1), trueCase, Weight())); |
| cases.append(SwitchCase(m_out.constInt32(2), trueCase, Weight())); |
| cases.append(SwitchCase(m_out.constInt32(4), trueCase, Weight())); |
| m_out.switchInstruction(bytes, cases, falseCase, Weight()); |
| |
| m_out.appendTo(trueCase, falseCase); |
| ValueFromBlock trueValue = m_out.anchor(m_out.booleanTrue); |
| m_out.jump(continuation); |
| m_out.appendTo(falseCase, continuation); |
| ValueFromBlock falseValue = m_out.anchor(m_out.booleanFalse); |
| m_out.jump(continuation); |
| |
| m_out.appendTo(continuation, lastNext); |
| setBoolean(m_out.phi(Int32, trueValue, falseValue)); |
| } |
| |
| void compileDefineDataProperty() |
| { |
| LValue base = lowCell(m_graph.varArgChild(m_node, 0)); |
| LValue value = lowJSValue(m_graph.varArgChild(m_node, 2)); |
| LValue attributes = lowInt32(m_graph.varArgChild(m_node, 3)); |
| Edge& propertyEdge = m_graph.varArgChild(m_node, 1); |
| switch (propertyEdge.useKind()) { |
| case StringUse: { |
| LValue property = lowString(propertyEdge); |
| vmCall(Void, m_out.operation(operationDefineDataPropertyString), m_callFrame, base, property, value, attributes); |
| break; |
| } |
| case StringIdentUse: { |
| LValue property = lowStringIdent(propertyEdge); |
| vmCall(Void, m_out.operation(operationDefineDataPropertyStringIdent), m_callFrame, base, property, value, attributes); |
| break; |
| } |
| case SymbolUse: { |
| LValue property = lowSymbol(propertyEdge); |
| vmCall(Void, m_out.operation(operationDefineDataPropertySymbol), m_callFrame, base, property, value, attributes); |
| break; |
| } |
| case UntypedUse: { |
| LValue property = lowJSValue(propertyEdge); |
| vmCall(Void, m_out.operation(operationDefineDataProperty), m_callFrame, base, property, value, attributes); |
| break; |
| } |
| default: |
| RELEASE_ASSERT_NOT_REACHED(); |
| } |
| } |
| |
| void compileDefineAccessorProperty() |
| { |
| LValue base = lowCell(m_graph.varArgChild(m_node, 0)); |
| LValue getter = lowCell(m_graph.varArgChild(m_node, 2)); |
| LValue setter = lowCell(m_graph.varArgChild(m_node, 3)); |
| LValue attributes = lowInt32(m_graph.varArgChild(m_node, 4)); |
| Edge& propertyEdge = m_graph.varArgChild(m_node, 1); |
| switch (propertyEdge.useKind()) { |
| case StringUse: { |
| LValue property = lowString(propertyEdge); |
| vmCall(Void, m_out.operation(operationDefineAccessorPropertyString), m_callFrame, base, property, getter, setter, attributes); |
| break; |
| } |
| case StringIdentUse: { |
| LValue property = lowStringIdent(propertyEdge); |
| vmCall(Void, m_out.operation(operationDefineAccessorPropertyStringIdent), m_callFrame, base, property, getter, setter, attributes); |
| break; |
| } |
| case SymbolUse: { |
| LValue property = lowSymbol(propertyEdge); |
| vmCall(Void, m_out.operation(operationDefineAccessorPropertySymbol), m_callFrame, base, property, getter, setter, attributes); |
| break; |
| } |
| case UntypedUse: { |
| LValue property = lowJSValue(propertyEdge); |
| vmCall(Void, m_out.operation(operationDefineAccessorProperty), m_callFrame, base, property, getter, setter, attributes); |
| break; |
| } |
| default: |
| RELEASE_ASSERT_NOT_REACHED(); |
| } |
| } |
| |
| void compilePutById() |
| { |
| DFG_ASSERT(m_graph, m_node, m_node->child1().useKind() == CellUse, m_node->child1().useKind()); |
| |
| Node* node = m_node; |
| LValue base = lowCell(node->child1()); |
| LValue value = lowJSValue(node->child2()); |
| auto uid = m_graph.identifiers()[node->identifierNumber()]; |
| |
| B3::PatchpointValue* patchpoint = m_out.patchpoint(Void); |
| patchpoint->appendSomeRegister(base); |
| patchpoint->appendSomeRegister(value); |
| patchpoint->append(m_tagMask, ValueRep::reg(GPRInfo::tagMaskRegister)); |
| patchpoint->append(m_tagTypeNumber, ValueRep::reg(GPRInfo::tagTypeNumberRegister)); |
| patchpoint->clobber(RegisterSet::macroScratchRegisters()); |
| |
| // FIXME: If this is a PutByIdFlush, we might want to late-clobber volatile registers. |
| // https://bugs.webkit.org/show_bug.cgi?id=152848 |
| |
| RefPtr<PatchpointExceptionHandle> exceptionHandle = |
| preparePatchpointForExceptions(patchpoint); |
| |
| State* state = &m_ftlState; |
| ECMAMode ecmaMode = m_graph.executableFor(node->origin.semantic)->ecmaMode(); |
| |
| patchpoint->setGenerator( |
| [=] (CCallHelpers& jit, const StackmapGenerationParams& params) { |
| AllowMacroScratchRegisterUsage allowScratch(jit); |
| |
| CallSiteIndex callSiteIndex = |
| state->jitCode->common.addUniqueCallSiteIndex(node->origin.semantic); |
| |
| Box<CCallHelpers::JumpList> exceptions = |
| exceptionHandle->scheduleExitCreation(params)->jumps(jit); |
| |
| // JS setter call ICs generated by the PutById IC will need this. |
| exceptionHandle->scheduleExitCreationForUnwind(params, callSiteIndex); |
| |
| auto generator = Box<JITPutByIdGenerator>::create( |
| jit.codeBlock(), node->origin.semantic, callSiteIndex, |
| params.unavailableRegisters(), JSValueRegs(params[0].gpr()), |
| JSValueRegs(params[1].gpr()), GPRInfo::patchpointScratchRegister, ecmaMode, |
| node->op() == PutByIdDirect ? Direct : NotDirect); |
| |
| generator->generateFastPath(jit); |
| CCallHelpers::Label done = jit.label(); |
| |
| params.addLatePath( |
| [=] (CCallHelpers& jit) { |
| AllowMacroScratchRegisterUsage allowScratch(jit); |
| |
| generator->slowPathJump().link(&jit); |
| CCallHelpers::Label slowPathBegin = jit.label(); |
| CCallHelpers::Call slowPathCall = callOperation( |
| *state, params.unavailableRegisters(), jit, node->origin.semantic, |
| exceptions.get(), generator->slowPathFunction(), InvalidGPRReg, |
| CCallHelpers::TrustedImmPtr(generator->stubInfo()), params[1].gpr(), |
| params[0].gpr(), CCallHelpers::TrustedImmPtr(uid)).call(); |
| jit.jump().linkTo(done, &jit); |
| |
| generator->reportSlowPathCall(slowPathBegin, slowPathCall); |
| |
| jit.addLinkTask( |
| [=] (LinkBuffer& linkBuffer) { |
| generator->finalize(linkBuffer); |
| }); |
| }); |
| }); |
| } |
| |
| void compileGetButterfly() |
| { |
| LValue butterfly = m_out.loadPtr(lowCell(m_node->child1()), m_heaps.JSObject_butterfly); |
| setStorage(butterfly); |
| } |
| |
| void compileConstantStoragePointer() |
| { |
| setStorage(m_out.constIntPtr(m_node->storagePointer())); |
| } |
| |
| void compileGetIndexedPropertyStorage() |
| { |
| LValue cell = lowCell(m_node->child1()); |
| |
| if (m_node->arrayMode().type() == Array::String) { |
| LBasicBlock slowPath = m_out.newBlock(); |
| LBasicBlock continuation = m_out.newBlock(); |
| |
| LValue fastResultValue = m_out.loadPtr(cell, m_heaps.JSString_value); |
| ValueFromBlock fastResult = m_out.anchor(fastResultValue); |
| |
| m_out.branch( |
| m_out.notNull(fastResultValue), usually(continuation), rarely(slowPath)); |
| |
| LBasicBlock lastNext = m_out.appendTo(slowPath, continuation); |
| |
| ValueFromBlock slowResult = m_out.anchor( |
| vmCall(pointerType(), m_out.operation(operationResolveRope), m_callFrame, cell)); |
| |
| m_out.jump(continuation); |
| |
| m_out.appendTo(continuation, lastNext); |
| |
| setStorage(m_out.loadPtr(m_out.phi(pointerType(), fastResult, slowResult), m_heaps.StringImpl_data)); |
| return; |
| } |
| |
| DFG_ASSERT(m_graph, m_node, isTypedView(m_node->arrayMode().typedArrayType()), m_node->arrayMode().typedArrayType()); |
| LValue vector = m_out.loadPtr(cell, m_heaps.JSArrayBufferView_vector); |
| setStorage(caged(Gigacage::Primitive, vector)); |
| } |
| |
| void compileCheckArray() |
| { |
| Edge edge = m_node->child1(); |
| LValue cell = lowCell(edge); |
| |
| if (m_node->arrayMode().alreadyChecked(m_graph, m_node, abstractValue(edge))) |
| return; |
| |
| speculate( |
| BadIndexingType, jsValueValue(cell), 0, |
| m_out.logicalNot(isArrayTypeForCheckArray(cell, m_node->arrayMode()))); |
| } |
| |
| void compileGetTypedArrayByteOffset() |
| { |
| LValue basePtr = lowCell(m_node->child1()); |
| |
| LBasicBlock simpleCase = m_out.newBlock(); |
| LBasicBlock wastefulCase = m_out.newBlock(); |
| LBasicBlock notNull = m_out.newBlock(); |
| LBasicBlock continuation = m_out.newBlock(); |
| |
| LValue mode = m_out.load32(basePtr, m_heaps.JSArrayBufferView_mode); |
| m_out.branch( |
| m_out.notEqual(mode, m_out.constInt32(WastefulTypedArray)), |
| unsure(simpleCase), unsure(wastefulCase)); |
| |
| LBasicBlock lastNext = m_out.appendTo(simpleCase, wastefulCase); |
| |
| ValueFromBlock simpleOut = m_out.anchor(m_out.constIntPtr(0)); |
| |
| m_out.jump(continuation); |
| |
| m_out.appendTo(wastefulCase, notNull); |
| |
| LValue vector = m_out.loadPtr(basePtr, m_heaps.JSArrayBufferView_vector); |
| ValueFromBlock nullVectorOut = m_out.anchor(vector); |
| m_out.branch(vector, unsure(notNull), unsure(continuation)); |
| |
| m_out.appendTo(notNull, continuation); |
| |
| LValue butterflyPtr = caged(Gigacage::JSValue, m_out.loadPtr(basePtr, m_heaps.JSObject_butterfly)); |
| LValue arrayBufferPtr = m_out.loadPtr(butterflyPtr, m_heaps.Butterfly_arrayBuffer); |
| |
| LValue vectorPtr = caged(Gigacage::Primitive, vector); |
| |
| // FIXME: This needs caging. |
| // https://bugs.webkit.org/show_bug.cgi?id=175515 |
| LValue dataPtr = m_out.loadPtr(arrayBufferPtr, m_heaps.ArrayBuffer_data); |
| |
| ValueFromBlock wastefulOut = m_out.anchor(m_out.sub(vectorPtr, dataPtr)); |
| |
| m_out.jump(continuation); |
| m_out.appendTo(continuation, lastNext); |
| |
| setInt32(m_out.castToInt32(m_out.phi(pointerType(), simpleOut, nullVectorOut, wastefulOut))); |
| } |
| |
| void compileGetPrototypeOf() |
| { |
| switch (m_node->child1().useKind()) { |
| case ArrayUse: |
| case FunctionUse: |
| case FinalObjectUse: { |
| LValue object = lowCell(m_node->child1()); |
| switch (m_node->child1().useKind()) { |
| case ArrayUse: |
| speculateArray(m_node->child1(), object); |
| break; |
| case FunctionUse: |
| speculateFunction(m_node->child1(), object); |
| break; |
| case FinalObjectUse: |
| speculateFinalObject(m_node->child1(), object); |
| break; |
| default: |
| RELEASE_ASSERT_NOT_REACHED(); |
| break; |
| } |
| |
| LValue structure = loadStructure(object); |
| |
| AbstractValue& value = m_state.forNode(m_node->child1()); |
| if ((value.m_type && !(value.m_type & ~SpecObject)) && value.m_structure.isFinite()) { |
| bool hasPolyProto = false; |
| bool hasMonoProto = false; |
| value.m_structure.forEach([&] (RegisteredStructure structure) { |
| if (structure->hasPolyProto()) |
| hasPolyProto = true; |
| else |
| hasMonoProto = true; |
| }); |
| |
| if (hasMonoProto && !hasPolyProto) { |
| setJSValue(m_out.load64(structure, m_heaps.Structure_prototype)); |
| return; |
| } |
| |
| if (hasPolyProto && !hasMonoProto) { |
| setJSValue(m_out.load64(m_out.baseIndex(m_heaps.properties.atAnyNumber(), object, m_out.constInt64(knownPolyProtoOffset), ScaleEight, JSObject::offsetOfInlineStorage()))); |
| return; |
| } |
| } |
| |
| LBasicBlock continuation = m_out.newBlock(); |
| LBasicBlock loadPolyProto = m_out.newBlock(); |
| |
| LValue prototypeBits = m_out.load64(structure, m_heaps.Structure_prototype); |
| ValueFromBlock directPrototype = m_out.anchor(prototypeBits); |
| m_out.branch(m_out.isZero64(prototypeBits), unsure(loadPolyProto), unsure(continuation)); |
| |
| LBasicBlock lastNext = m_out.appendTo(loadPolyProto, continuation); |
| ValueFromBlock polyProto = m_out.anchor( |
| m_out.load64(m_out.baseIndex(m_heaps.properties.atAnyNumber(), object, m_out.constInt64(knownPolyProtoOffset), ScaleEight, JSObject::offsetOfInlineStorage()))); |
| m_out.jump(continuation); |
| |
| m_out.appendTo(continuation, lastNext); |
| setJSValue(m_out.phi(Int64, directPrototype, polyProto)); |
| return; |
| } |
| case ObjectUse: { |
| setJSValue(vmCall(Int64, m_out.operation(operationGetPrototypeOfObject), m_callFrame, lowObject(m_node->child1()))); |
| return; |
| } |
| default: { |
| setJSValue(vmCall(Int64, m_out.operation(operationGetPrototypeOf), m_callFrame, lowJSValue(m_node->child1()))); |
| return; |
| } |
| } |
| } |
| |
| void compileGetArrayLength() |
| { |
| switch (m_node->arrayMode().type()) { |
| case Array::Undecided: |
| case Array::Int32: |
| case Array::Double: |
| case Array::Contiguous: { |
| setInt32(m_out.load32NonNegative(lowStorage(m_node->child2()), m_heaps.Butterfly_publicLength)); |
| return; |
| } |
| |
| case Array::ArrayStorage: |
| case Array::SlowPutArrayStorage: { |
| LValue length = m_out.load32(lowStorage(m_node->child2()), m_heaps.ArrayStorage_publicLength); |
| speculate(Uncountable, noValue(), nullptr, m_out.lessThan(length, m_out.int32Zero)); |
| setInt32(length); |
| return; |
| } |
| |
| case Array::String: { |
| LValue string = lowCell(m_node->child1()); |
| setInt32(m_out.load32NonNegative(string, m_heaps.JSString_length)); |
| return; |
| } |
| |
| case Array::DirectArguments: { |
| LValue arguments = lowCell(m_node->child1()); |
| speculate( |
| ExoticObjectMode, noValue(), nullptr, |
| m_out.notNull(m_out.loadPtr(arguments, m_heaps.DirectArguments_mappedArguments))); |
| setInt32(m_out.load32NonNegative(arguments, m_heaps.DirectArguments_length)); |
| return; |
| } |
| |
| case Array::ScopedArguments: { |
| LValue arguments = lowCell(m_node->child1()); |
| LValue storage = m_out.bitXor( |
| m_out.loadPtr(arguments, m_heaps.ScopedArguments_storage), |
| m_out.constIntPtr(ScopedArgumentsPoison::key())); |
| speculate( |
| ExoticObjectMode, noValue(), nullptr, |
| m_out.notZero32(m_out.load8ZeroExt32(storage, m_heaps.ScopedArguments_Storage_overrodeThings))); |
| setInt32(m_out.load32NonNegative(storage, m_heaps.ScopedArguments_Storage_totalLength)); |
| return; |
| } |
| |
| default: |
| if (m_node->arrayMode().isSomeTypedArrayView()) { |
| setInt32( |
| m_out.load32NonNegative(lowCell(m_node->child1()), m_heaps.JSArrayBufferView_length)); |
| return; |
| } |
| |
| DFG_CRASH(m_graph, m_node, "Bad array type"); |
| return; |
| } |
| } |
| |
| void compileGetVectorLength() |
| { |
| switch (m_node->arrayMode().type()) { |
| case Array::ArrayStorage: |
| case Array::SlowPutArrayStorage: |
| setInt32(m_out.load32NonNegative(lowStorage(m_node->child2()), m_heaps.ArrayStorage_vectorLength)); |
| return; |
| default: |
| return; |
| } |
| } |
| |
| void compileCheckInBounds() |
| { |
| speculate( |
| OutOfBounds, noValue(), 0, |
| m_out.aboveOrEqual(lowInt32(m_node->child1()), lowInt32(m_node->child2()))); |
| } |
| |
| void compileGetByVal() |
| { |
| switch (m_node->arrayMode().type()) { |
| case Array::Int32: |
| case Array::Contiguous: { |
| LValue index = lowInt32(m_graph.varArgChild(m_node, 1)); |
| LValue storage = lowStorage(m_graph.varArgChild(m_node, 2)); |
| |
| IndexedAbstractHeap& heap = m_node->arrayMode().type() == Array::Int32 ? |
| m_heaps.indexedInt32Properties : m_heaps.indexedContiguousProperties; |
| |
| LValue base = lowCell(m_graph.varArgChild(m_node, 0)); |
| |
| if (m_node->arrayMode().isInBounds()) { |
| LValue result = m_out.load64(baseIndex(heap, storage, index, m_graph.varArgChild(m_node, 1))); |
| LValue isHole = m_out.isZero64(result); |
| if (m_node->arrayMode().isSaneChain()) { |
| DFG_ASSERT( |
| m_graph, m_node, m_node->arrayMode().type() == Array::Contiguous, m_node->arrayMode().type()); |
| result = m_out.select( |
| isHole, m_out.constInt64(JSValue::encode(jsUndefined())), result); |
| } else |
| speculate(LoadFromHole, noValue(), 0, isHole); |
| setJSValue(result); |
| return; |
| } |
| |
| LBasicBlock fastCase = m_out.newBlock(); |
| LBasicBlock slowCase = m_out.newBlock(); |
| LBasicBlock continuation = m_out.newBlock(); |
| |
| m_out.branch( |
| m_out.aboveOrEqual( |
| index, m_out.load32NonNegative(storage, m_heaps.Butterfly_publicLength)), |
| rarely(slowCase), usually(fastCase)); |
| |
| LBasicBlock lastNext = m_out.appendTo(fastCase, slowCase); |
| |
| LValue fastResultValue = m_out.load64(baseIndex(heap, storage, index, m_graph.varArgChild(m_node, 1))); |
| ValueFromBlock fastResult = m_out.anchor(fastResultValue); |
| m_out.branch( |
| m_out.isZero64(fastResultValue), rarely(slowCase), usually(continuation)); |
| |
| m_out.appendTo(slowCase, continuation); |
| ValueFromBlock slowResult = m_out.anchor( |
| vmCall(Int64, m_out.operation(operationGetByValObjectInt), m_callFrame, base, index)); |
| m_out.jump(continuation); |
| |
| m_out.appendTo(continuation, lastNext); |
| setJSValue(m_out.phi(Int64, fastResult, slowResult)); |
| return; |
| } |
| |
| case Array::Double: { |
| LValue base = lowCell(m_graph.varArgChild(m_node, 0)); |
| LValue index = lowInt32(m_graph.varArgChild(m_node, 1)); |
| LValue storage = lowStorage(m_graph.varArgChild(m_node, 2)); |
| |
| IndexedAbstractHeap& heap = m_heaps.indexedDoubleProperties; |
| |
| if (m_node->arrayMode().isInBounds()) { |
| LValue result = m_out.loadDouble( |
| baseIndex(heap, storage, index, m_graph.varArgChild(m_node, 1))); |
| |
| if (!m_node->arrayMode().isSaneChain()) { |
| speculate( |
| LoadFromHole, noValue(), 0, |
| m_out.doubleNotEqualOrUnordered(result, result)); |
| } |
| setDouble(result); |
| break; |
| } |
| |
| LBasicBlock inBounds = m_out.newBlock(); |
| LBasicBlock boxPath = m_out.newBlock(); |
| LBasicBlock slowCase = m_out.newBlock(); |
| LBasicBlock continuation = m_out.newBlock(); |
| |
| m_out.branch( |
| m_out.aboveOrEqual( |
| index, m_out.load32NonNegative(storage, m_heaps.Butterfly_publicLength)), |
| rarely(slowCase), usually(inBounds)); |
| |
| LBasicBlock lastNext = m_out.appendTo(inBounds, boxPath); |
| LValue doubleValue = m_out.loadDouble( |
| baseIndex(heap, storage, index, m_graph.varArgChild(m_node, 1))); |
| m_out.branch( |
| m_out.doubleNotEqualOrUnordered(doubleValue, doubleValue), |
| rarely(slowCase), usually(boxPath)); |
| |
| m_out.appendTo(boxPath, slowCase); |
| ValueFromBlock fastResult = m_out.anchor(boxDouble(doubleValue)); |
| m_out.jump(continuation); |
| |
| m_out.appendTo(slowCase, continuation); |
| ValueFromBlock slowResult = m_out.anchor( |
| vmCall(Int64, m_out.operation(operationGetByValObjectInt), m_callFrame, base, index)); |
| m_out.jump(continuation); |
| |
| m_out.appendTo(continuation, lastNext); |
| setJSValue(m_out.phi(Int64, fastResult, slowResult)); |
| return; |
| } |
| |
| case Array::Undecided: { |
| LValue index = lowInt32(m_graph.varArgChild(m_node, 1)); |
| |
| speculate(OutOfBounds, noValue(), m_node, m_out.lessThan(index, m_out.int32Zero)); |
| setJSValue(m_out.constInt64(ValueUndefined)); |
| return; |
| } |
| |
| case Array::DirectArguments: { |
| LValue base = lowCell(m_graph.varArgChild(m_node, 0)); |
| LValue index = lowInt32(m_graph.varArgChild(m_node, 1)); |
| |
| speculate( |
| ExoticObjectMode, noValue(), nullptr, |
| m_out.notNull(m_out.loadPtr(base, m_heaps.DirectArguments_mappedArguments))); |
| |
| LValue length = m_out.load32NonNegative(base, m_heaps.DirectArguments_length); |
| auto isOutOfBounds = m_out.aboveOrEqual(index, length); |
| if (m_node->arrayMode().isInBounds()) { |
| speculate(OutOfBounds, noValue(), nullptr, isOutOfBounds); |
| TypedPointer address = m_out.baseIndex( |
| m_heaps.DirectArguments_storage, base, m_out.zeroExtPtr(index)); |
| setJSValue(m_out.load64(address)); |
| return; |
| } |
| |
| LBasicBlock inBounds = m_out.newBlock(); |
| LBasicBlock slowCase = m_out.newBlock(); |
| LBasicBlock continuation = m_out.newBlock(); |
| |
| m_out.branch(isOutOfBounds, rarely(slowCase), usually(inBounds)); |
| |
| LBasicBlock lastNext = m_out.appendTo(inBounds, slowCase); |
| TypedPointer address = m_out.baseIndex( |
| m_heaps.DirectArguments_storage, |
| base, |
| m_out.zeroExt(index, pointerType())); |
| ValueFromBlock fastResult = m_out.anchor(m_out.load64(address)); |
| m_out.jump(continuation); |
| |
| m_out.appendTo(slowCase, continuation); |
| ValueFromBlock slowResult = m_out.anchor( |
| vmCall(Int64, m_out.operation(operationGetByValObjectInt), m_callFrame, base, index)); |
| m_out.jump(continuation); |
| |
| m_out.appendTo(continuation, lastNext); |
| setJSValue(m_out.phi(Int64, fastResult, slowResult)); |
| return; |
| } |
| |
| case Array::ScopedArguments: { |
| LValue base = lowCell(m_graph.varArgChild(m_node, 0)); |
| LValue index = lowInt32(m_graph.varArgChild(m_node, 1)); |
| |
| LValue storage = m_out.loadPtr(base, m_heaps.ScopedArguments_storage); |
| storage = m_out.bitXor(storage, m_out.constIntPtr(ScopedArgumentsPoison::key())); |
| |
| LValue totalLength = m_out.load32NonNegative( |
| storage, m_heaps.ScopedArguments_Storage_totalLength); |
| speculate( |
| ExoticObjectMode, noValue(), nullptr, |
| m_out.aboveOrEqual(index, totalLength)); |
| |
| LValue table = m_out.loadPtr(base, m_heaps.ScopedArguments_table); |
| table = m_out.bitXor(table, m_out.constIntPtr(ScopedArgumentsPoison::key())); |
| |
| LValue namedLength = m_out.load32(table, m_heaps.ScopedArgumentsTable_length); |
| |
| LBasicBlock namedCase = m_out.newBlock(); |
| LBasicBlock overflowCase = m_out.newBlock(); |
| LBasicBlock continuation = m_out.newBlock(); |
| |
| m_out.branch( |
| m_out.aboveOrEqual(index, namedLength), unsure(overflowCase), unsure(namedCase)); |
| |
| LBasicBlock lastNext = m_out.appendTo(namedCase, overflowCase); |
| |
| LValue scope = m_out.loadPtr(base, m_heaps.ScopedArguments_scope); |
| scope = m_out.bitXor(scope, m_out.constIntPtr(ScopedArgumentsPoison::key())); |
| |
| LValue arguments = m_out.loadPtr(table, m_heaps.ScopedArgumentsTable_arguments); |
| |
| TypedPointer address = m_out.baseIndex( |
| m_heaps.scopedArgumentsTableArguments, arguments, m_out.zeroExtPtr(index)); |
| LValue scopeOffset = m_out.load32(address); |
| |
| speculate( |
| ExoticObjectMode, noValue(), nullptr, |
| m_out.equal(scopeOffset, m_out.constInt32(ScopeOffset::invalidOffset))); |
| |
| address = m_out.baseIndex( |
| m_heaps.JSLexicalEnvironment_variables, scope, m_out.zeroExtPtr(scopeOffset)); |
| ValueFromBlock namedResult = m_out.anchor(m_out.load64(address)); |
| m_out.jump(continuation); |
| |
| m_out.appendTo(overflowCase, continuation); |
| |
| address = m_out.baseIndex( |
| m_heaps.ScopedArguments_Storage_storage, storage, |
| m_out.zeroExtPtr(m_out.sub(index, namedLength))); |
| LValue overflowValue = m_out.load64(address); |
| speculate(ExoticObjectMode, noValue(), nullptr, m_out.isZero64(overflowValue)); |
| ValueFromBlock overflowResult = m_out.anchor(overflowValue); |
| m_out.jump(continuation); |
| |
| m_out.appendTo(continuation, lastNext); |
| |
| LValue result = m_out.phi(Int64, namedResult, overflowResult); |
| result = preciseIndexMask32(result, index, totalLength); |
| |
| setJSValue(result); |
| return; |
| } |
| |
| case Array::Generic: { |
| if (m_graph.varArgChild(m_node, 0).useKind() == ObjectUse) { |
| if (m_graph.varArgChild(m_node, 1).useKind() == StringUse) { |
| setJSValue(vmCall( |
| Int64, m_out.operation(operationGetByValObjectString), m_callFrame, |
| lowObject(m_graph.varArgChild(m_node, 0)), lowString(m_graph.varArgChild(m_node, 1)))); |
| return; |
| } |
| |
| if (m_graph.varArgChild(m_node, 1).useKind() == SymbolUse) { |
| setJSValue(vmCall( |
| Int64, m_out.operation(operationGetByValObjectSymbol), m_callFrame, |
| lowObject(m_graph.varArgChild(m_node, 0)), lowSymbol(m_graph.varArgChild(m_node, 1)))); |
| return; |
| } |
| } |
| setJSValue(vmCall( |
| Int64, m_out.operation(operationGetByVal), m_callFrame, |
| lowJSValue(m_graph.varArgChild(m_node, 0)), lowJSValue(m_graph.varArgChild(m_node, 1)))); |
| return; |
| } |
| |
| case Array::ArrayStorage: |
| case Array::SlowPutArrayStorage: { |
| LValue base = lowCell(m_graph.varArgChild(m_node, 0)); |
| LValue index = lowInt32(m_graph.varArgChild(m_node, 1)); |
| LValue storage = lowStorage(m_graph.varArgChild(m_node, 2)); |
| |
| IndexedAbstractHeap& heap = m_heaps.ArrayStorage_vector; |
| |
| if (m_node->arrayMode().isInBounds()) { |
| LValue result = m_out.load64(baseIndex(heap, storage, index, m_graph.varArgChild(m_node, 1))); |
| speculate(LoadFromHole, noValue(), 0, m_out.isZero64(result)); |
| setJSValue(result); |
| break; |
| } |
| |
| LBasicBlock inBounds = m_out.newBlock(); |
| LBasicBlock slowCase = m_out.newBlock(); |
| LBasicBlock continuation = m_out.newBlock(); |
| |
| m_out.branch( |
| m_out.aboveOrEqual(index, m_out.load32NonNegative(storage, m_heaps.ArrayStorage_vectorLength)), |
| rarely(slowCase), usually(inBounds)); |
| |
| LBasicBlock lastNext = m_out.appendTo(inBounds, slowCase); |
| LValue result = m_out.load64(baseIndex(heap, storage, index, m_graph.varArgChild(m_node, 1))); |
| ValueFromBlock fastResult = m_out.anchor(result); |
| m_out.branch( |
| m_out.isZero64(result), |
| rarely(slowCase), usually(continuation)); |
| |
| m_out.appendTo(slowCase, continuation); |
| ValueFromBlock slowResult = m_out.anchor( |
| vmCall(Int64, m_out.operation(operationGetByValObjectInt), m_callFrame, base, index)); |
| m_out.jump(continuation); |
| |
| m_out.appendTo(continuation, lastNext); |
| setJSValue(m_out.phi(Int64, fastResult, slowResult)); |
| return; |
| } |
| |
| case Array::String: { |
| compileStringCharAt(); |
| return; |
| } |
| |
| default: { |
| LValue index = lowInt32(m_graph.varArgChild(m_node, 1)); |
| LValue storage = lowStorage(m_graph.varArgChild(m_node, 2)); |
| |
| TypedArrayType type = m_node->arrayMode().typedArrayType(); |
| |
| if (isTypedView(type)) { |
| TypedPointer pointer = pointerIntoTypedArray(storage, index, type); |
| |
| if (isInt(type)) { |
| LValue result = loadFromIntTypedArray(pointer, type); |
| bool canSpeculate = true; |
| setIntTypedArrayLoadResult(result, type, canSpeculate); |
| return; |
| } |
| |
| ASSERT(isFloat(type)); |
| |
| LValue result; |
| switch (type) { |
| case TypeFloat32: |
| result = m_out.floatToDouble(m_out.loadFloat(pointer)); |
| break; |
| case TypeFloat64: |
| result = m_out.loadDouble(pointer); |
| break; |
| default: |
| DFG_CRASH(m_graph, m_node, "Bad typed array type"); |
| } |
| |
| setDouble(result); |
| return; |
| } |
| |
| DFG_CRASH(m_graph, m_node, "Bad array type"); |
| return; |
| } } |
| } |
| |
| void compileGetMyArgumentByVal() |
| { |
| InlineCallFrame* inlineCallFrame = m_node->child1()->origin.semantic.inlineCallFrame; |
| |
| LValue originalIndex = lowInt32(m_node->child2()); |
| |
| LValue numberOfArgsIncludingThis; |
| if (inlineCallFrame && !inlineCallFrame->isVarargs()) |
| numberOfArgsIncludingThis = m_out.constInt32(inlineCallFrame->argumentCountIncludingThis); |
| else { |
| VirtualRegister argumentCountRegister = AssemblyHelpers::argumentCount(inlineCallFrame); |
| numberOfArgsIncludingThis = m_out.load32(payloadFor(argumentCountRegister)); |
| } |
| |
| LValue numberOfArgs = m_out.sub(numberOfArgsIncludingThis, m_out.int32One); |
| LValue indexToCheck = originalIndex; |
| if (m_node->numberOfArgumentsToSkip()) { |
| CheckValue* check = m_out.speculateAdd(indexToCheck, m_out.constInt32(m_node->numberOfArgumentsToSkip())); |
| blessSpeculation(check, Overflow, noValue(), nullptr, m_origin); |
| indexToCheck = check; |
| } |
| |
| LValue isOutOfBounds = m_out.aboveOrEqual(indexToCheck, numberOfArgs); |
| LBasicBlock continuation = nullptr; |
| LBasicBlock lastNext = nullptr; |
| ValueFromBlock slowResult; |
| if (m_node->op() == GetMyArgumentByValOutOfBounds) { |
| LBasicBlock normalCase = m_out.newBlock(); |
| continuation = m_out.newBlock(); |
| |
| slowResult = m_out.anchor(m_out.constInt64(JSValue::encode(jsUndefined()))); |
| m_out.branch(isOutOfBounds, unsure(continuation), unsure(normalCase)); |
| |
| lastNext = m_out.appendTo(normalCase, continuation); |
| } else |
| speculate(OutOfBounds, noValue(), nullptr, isOutOfBounds); |
| |
| LValue index = m_out.add(indexToCheck, m_out.int32One); |
| |
| TypedPointer base; |
| if (inlineCallFrame) { |
| if (inlineCallFrame->argumentCountIncludingThis > 1) |
| base = addressFor(inlineCallFrame->argumentsWithFixup[0].virtualRegister()); |
| } else |
| base = addressFor(virtualRegisterForArgument(0)); |
| |
| LValue result; |
| if (base) { |
| LValue pointer = m_out.baseIndex( |
| base.value(), m_out.zeroExt(index, pointerType()), ScaleEight); |
| result = m_out.load64(TypedPointer(m_heaps.variables.atAnyIndex(), pointer)); |
| result = preciseIndexMask32(result, indexToCheck, numberOfArgs); |
| } else |
| result = m_out.constInt64(JSValue::encode(jsUndefined())); |
| |
| if (m_node->op() == GetMyArgumentByValOutOfBounds) { |
| ValueFromBlock normalResult = m_out.anchor(result); |
| m_out.jump(continuation); |
| |
| m_out.appendTo(continuation, lastNext); |
| result = m_out.phi(Int64, slowResult, normalResult); |
| } |
| |
| setJSValue(result); |
| } |
| |
| void compilePutByVal() |
| { |
| Edge child1 = m_graph.varArgChild(m_node, 0); |
| Edge child2 = m_graph.varArgChild(m_node, 1); |
| Edge child3 = m_graph.varArgChild(m_node, 2); |
| Edge child4 = m_graph.varArgChild(m_node, 3); |
| Edge child5 = m_graph.varArgChild(m_node, 4); |
| |
| ArrayMode arrayMode = m_node->arrayMode().modeForPut(); |
| switch (arrayMode.type()) { |
| case Array::Generic: { |
| if (child1.useKind() == CellUse) { |
| V_JITOperation_ECCJ operation = nullptr; |
| if (child2.useKind() == StringUse) { |
| if (m_node->op() == PutByValDirect) { |
| if (m_graph.isStrictModeFor(m_node->origin.semantic)) |
| operation = operationPutByValDirectCellStringStrict; |
| else |
| operation = operationPutByValDirectCellStringNonStrict; |
| } else { |
| if (m_graph.isStrictModeFor(m_node->origin.semantic)) |
| operation = operationPutByValCellStringStrict; |
| else |
| operation = operationPutByValCellStringNonStrict; |
| } |
| vmCall(Void, m_out.operation(operation), m_callFrame, lowCell(child1), lowString(child2), lowJSValue(child3)); |
| return; |
| } |
| |
| if (child2.useKind() == SymbolUse) { |
| if (m_node->op() == PutByValDirect) { |
| if (m_graph.isStrictModeFor(m_node->origin.semantic)) |
| operation = operationPutByValDirectCellSymbolStrict; |
| else |
| operation = operationPutByValDirectCellSymbolNonStrict; |
| } else { |
| if (m_graph.isStrictModeFor(m_node->origin.semantic)) |
| operation = operationPutByValCellSymbolStrict; |
| else |
| operation = operationPutByValCellSymbolNonStrict; |
| } |
| vmCall(Void, m_out.operation(operation), m_callFrame, lowCell(child1), lowSymbol(child2), lowJSValue(child3)); |
| return; |
| } |
| } |
| |
| V_JITOperation_EJJJ operation; |
| if (m_node->op() == PutByValDirect) { |
| if (m_graph.isStrictModeFor(m_node->origin.semantic)) |
| operation = operationPutByValDirectStrict; |
| else |
| operation = operationPutByValDirectNonStrict; |
| } else { |
| if (m_graph.isStrictModeFor(m_node->origin.semantic)) |
| operation = operationPutByValStrict; |
| else |
| operation = operationPutByValNonStrict; |
| } |
| |
| vmCall( |
| Void, m_out.operation(operation), m_callFrame, |
| lowJSValue(child1), lowJSValue(child2), lowJSValue(child3)); |
| return; |
| } |
| |
| default: |
| break; |
| } |
| |
| LValue base = lowCell(child1); |
| LValue index = lowInt32(child2); |
| LValue storage = lowStorage(child4); |
| |
| switch (arrayMode.type()) { |
| case Array::Int32: |
| case Array::Double: |
| case Array::Contiguous: { |
| LBasicBlock continuation = m_out.newBlock(); |
| LBasicBlock outerLastNext = m_out.appendTo(m_out.m_block, continuation); |
| |
| switch (arrayMode.type()) { |
| case Array::Int32: |
| case Array::Contiguous: { |
| LValue value = lowJSValue(child3, ManualOperandSpeculation); |
| |
| if (arrayMode.type() == Array::Int32) |
| FTL_TYPE_CHECK(jsValueValue(value), child3, SpecInt32Only, isNotInt32(value)); |
| |
| TypedPointer elementPointer = m_out.baseIndex( |
| arrayMode.type() == Array::Int32 ? |
| m_heaps.indexedInt32Properties : m_heaps.indexedContiguousProperties, |
| storage, m_out.zeroExtPtr(index), provenValue(child2)); |
| |
| if (m_node->op() == PutByValAlias) { |
| m_out.store64(value, elementPointer); |
| break; |
| } |
| |
| contiguousPutByValOutOfBounds( |
| codeBlock()->isStrictMode() |
| ? (m_node->op() == PutByValDirect ? operationPutByValDirectBeyondArrayBoundsStrict : operationPutByValBeyondArrayBoundsStrict) |
| : (m_node->op() == PutByValDirect ? operationPutByValDirectBeyondArrayBoundsNonStrict : operationPutByValBeyondArrayBoundsNonStrict), |
| base, storage, index, value, continuation); |
| |
| m_out.store64(value, elementPointer); |
| break; |
| } |
| |
| case Array::Double: { |
| LValue value = lowDouble(child3); |
| |
| FTL_TYPE_CHECK( |
| doubleValue(value), child3, SpecDoubleReal, |
| m_out.doubleNotEqualOrUnordered(value, value)); |
| |
| TypedPointer elementPointer = m_out.baseIndex( |
| m_heaps.indexedDoubleProperties, storage, m_out.zeroExtPtr(index), |
| provenValue(child2)); |
| |
| if (m_node->op() == PutByValAlias) { |
| m_out.storeDouble(value, elementPointer); |
| break; |
| } |
| |
| contiguousPutByValOutOfBounds( |
| codeBlock()->isStrictMode() |
| ? (m_node->op() == PutByValDirect ? operationPutDoubleByValDirectBeyondArrayBoundsStrict : operationPutDoubleByValBeyondArrayBoundsStrict) |
| : (m_node->op() == PutByValDirect ? operationPutDoubleByValDirectBeyondArrayBoundsNonStrict : operationPutDoubleByValBeyondArrayBoundsNonStrict), |
| base, storage, index, value, continuation); |
| |
| m_out.storeDouble(value, elementPointer); |
| break; |
| } |
| |
| default: |
| DFG_CRASH(m_graph, m_node, "Bad array type"); |
| } |
| |
| m_out.jump(continuation); |
| m_out.appendTo(continuation, outerLastNext); |
| return; |
| } |
| |
| case Array::ArrayStorage: |
| case Array::SlowPutArrayStorage: { |
| LValue value = lowJSValue(child3); |
| |
| TypedPointer elementPointer = m_out.baseIndex( |
| m_heaps.ArrayStorage_vector, storage, m_out.zeroExtPtr(index), |
| provenValue(child2)); |
| |
| if (m_node->op() == PutByValAlias) { |
| m_out.store64(value, elementPointer); |
| return; |
| } |
| |
| if (arrayMode.isInBounds()) { |
| speculate(StoreToHole, noValue(), 0, m_out.isZero64(m_out.load64(elementPointer))); |
| m_out.store64(value, elementPointer); |
| return; |
| } |
| |
| LValue isOutOfBounds = m_out.aboveOrEqual( |
| index, m_out.load32NonNegative(storage, m_heaps.ArrayStorage_vectorLength)); |
| |
| auto slowPathFunction = codeBlock()->isStrictMode() |
| ? (m_node->op() == PutByValDirect ? operationPutByValDirectBeyondArrayBoundsStrict : operationPutByValBeyondArrayBoundsStrict) |
| : (m_node->op() == PutByValDirect ? operationPutByValDirectBeyondArrayBoundsNonStrict : operationPutByValBeyondArrayBoundsNonStrict); |
| if (!arrayMode.isOutOfBounds()) { |
| speculate(OutOfBounds, noValue(), 0, isOutOfBounds); |
| isOutOfBounds = m_out.booleanFalse; |
| } |
| |
| LBasicBlock inBoundCase = m_out.newBlock(); |
| LBasicBlock slowCase = m_out.newBlock(); |
| LBasicBlock holeCase = m_out.newBlock(); |
| LBasicBlock doStoreCase = m_out.newBlock(); |
| LBasicBlock lengthUpdateCase = m_out.newBlock(); |
| LBasicBlock continuation = m_out.newBlock(); |
| |
| m_out.branch(isOutOfBounds, rarely(slowCase), usually(inBoundCase)); |
| |
| LBasicBlock lastNext = m_out.appendTo(slowCase, inBoundCase); |
| vmCall( |
| Void, m_out.operation(slowPathFunction), |
| m_callFrame, base, index, value); |
| m_out.jump(continuation); |
| |
| |
| if (arrayMode.isSlowPut()) { |
| m_out.appendTo(inBoundCase, doStoreCase); |
| m_out.branch(m_out.isZero64(m_out.load64(elementPointer)), rarely(slowCase), usually(doStoreCase)); |
| } else { |
| m_out.appendTo(inBoundCase, holeCase); |
| m_out.branch(m_out.isZero64(m_out.load64(elementPointer)), rarely(holeCase), usually(doStoreCase)); |
| |
| m_out.appendTo(holeCase, lengthUpdateCase); |
| m_out.store32( |
| m_out.add(m_out.load32(storage, m_heaps.ArrayStorage_numValuesInVector), m_out.int32One), |
| storage, m_heaps.ArrayStorage_numValuesInVector); |
| m_out.branch( |
| m_out.below( |
| index, m_out.load32NonNegative(storage, m_heaps.ArrayStorage_publicLength)), |
| unsure(doStoreCase), unsure(lengthUpdateCase)); |
| |
| m_out.appendTo(lengthUpdateCase, doStoreCase); |
| m_out.store32( |
| m_out.add(index, m_out.int32One), |
| storage, m_heaps.ArrayStorage_publicLength); |
| m_out.jump(doStoreCase); |
| } |
| |
| m_out.appendTo(doStoreCase, continuation); |
| m_out.store64(value, elementPointer); |
| m_out.jump(continuation); |
| |
| m_out.appendTo(continuation, lastNext); |
| return; |
| } |
| |
| default: { |
| TypedArrayType type = arrayMode.typedArrayType(); |
| |
| if (isTypedView(type)) { |
| TypedPointer pointer = TypedPointer( |
| m_heaps.typedArrayProperties, |
| m_out.add( |
| storage, |
| m_out.shl( |
| m_out.zeroExt(index, pointerType()), |
| m_out.constIntPtr(logElementSize(type))))); |
| |
| LValue valueToStore; |
| |
| if (isInt(type)) { |
| LValue intValue = getIntTypedArrayStoreOperand(child3, isClamped(type)); |
| |
| valueToStore = intValue; |
| } else /* !isInt(type) */ { |
| LValue value = lowDouble(child3); |
| switch (type) { |
| case TypeFloat32: |
| valueToStore = m_out.doubleToFloat(value); |
| break; |
| case TypeFloat64: |
| valueToStore = value; |
| break; |
| default: |
| DFG_CRASH(m_graph, m_node, "Bad typed array type"); |
| } |
| } |
| |
| if (arrayMode.isInBounds() || m_node->op() == PutByValAlias) |
| m_out.store(valueToStore, pointer, storeType(type)); |
| else { |
| LBasicBlock isInBounds = m_out.newBlock(); |
| LBasicBlock isOutOfBounds = m_out.newBlock(); |
| LBasicBlock continuation = m_out.newBlock(); |
| |
| m_out.branch( |
| m_out.aboveOrEqual(index, lowInt32(child5)), |
| unsure(isOutOfBounds), unsure(isInBounds)); |
| |
| LBasicBlock lastNext = m_out.appendTo(isInBounds, isOutOfBounds); |
| m_out.store(valueToStore, pointer, storeType(type)); |
| m_out.jump(continuation); |
| |
| m_out.appendTo(isOutOfBounds, continuation); |
| speculateTypedArrayIsNotNeutered(base); |
| m_out.jump(continuation); |
| |
| m_out.appendTo(continuation, lastNext); |
| } |
| |
| return; |
| } |
| |
| DFG_CRASH(m_graph, m_node, "Bad array type"); |
| break; |
| } |
| } |
| } |
| |
| void compilePutAccessorById() |
| { |
| LValue base = lowCell(m_node->child1()); |
| LValue accessor = lowCell(m_node->child2()); |
| auto uid = m_graph.identifiers()[m_node->identifierNumber()]; |
| vmCall( |
| Void, |
| m_out.operation(m_node->op() == PutGetterById ? operationPutGetterById : operationPutSetterById), |
| m_callFrame, base, m_out.constIntPtr(uid), m_out.constInt32(m_node->accessorAttributes()), accessor); |
| } |
| |
| void compilePutGetterSetterById() |
| { |
| LValue base = lowCell(m_node->child1()); |
| LValue getter = lowJSValue(m_node->child2()); |
| LValue setter = lowJSValue(m_node->child3()); |
| auto uid = m_graph.identifiers()[m_node->identifierNumber()]; |
| vmCall( |
| Void, m_out.operation(operationPutGetterSetter), |
| m_callFrame, base, m_out.constIntPtr(uid), m_out.constInt32(m_node->accessorAttributes()), getter, setter); |
| |
| } |
| |
| void compilePutAccessorByVal() |
| { |
| LValue base = lowCell(m_node->child1()); |
| LValue subscript = lowJSValue(m_node->child2()); |
| LValue accessor = lowCell(m_node->child3()); |
| vmCall( |
| Void, |
| m_out.operation(m_node->op() == PutGetterByVal ? operationPutGetterByVal : operationPutSetterByVal), |
| m_callFrame, base, subscript, m_out.constInt32(m_node->accessorAttributes()), accessor); |
| } |
| |
| void compileDeleteById() |
| { |
| LValue base = lowJSValue(m_node->child1()); |
| auto uid = m_graph.identifiers()[m_node->identifierNumber()]; |
| setBoolean(m_out.notZero64(vmCall(Int64, m_out.operation(operationDeleteById), m_callFrame, base, m_out.constIntPtr(uid)))); |
| } |
| |
| void compileDeleteByVal() |
| { |
| LValue base = lowJSValue(m_node->child1()); |
| LValue subscript = lowJSValue(m_node->child2()); |
| setBoolean(m_out.notZero64(vmCall(Int64, m_out.operation(operationDeleteByVal), m_callFrame, base, subscript))); |
| } |
| |
| void compileArrayPush() |
| { |
| LValue base = lowCell(m_graph.varArgChild(m_node, 1)); |
| LValue storage = lowStorage(m_graph.varArgChild(m_node, 0)); |
| unsigned elementOffset = 2; |
| unsigned elementCount = m_node->numChildren() - elementOffset; |
| |
| switch (m_node->arrayMode().type()) { |
| case Array::Int32: |
| case Array::Contiguous: |
| case Array::Double: { |
| IndexedAbstractHeap& heap = m_heaps.forArrayType(m_node->arrayMode().type()); |
| |
| if (elementCount == 1) { |
| LValue value; |
| Output::StoreType storeType; |
| |
| Edge& element = m_graph.varArgChild(m_node, elementOffset); |
| if (m_node->arrayMode().type() != Array::Double) { |
| value = lowJSValue(element, ManualOperandSpeculation); |
| if (m_node->arrayMode().type() == Array::Int32) |
| DFG_ASSERT(m_graph, m_node, !m_interpreter.needsTypeCheck(element, SpecInt32Only)); |
| storeType = Output::Store64; |
| } else { |
| value = lowDouble(element); |
| DFG_ASSERT(m_graph, m_node, !m_interpreter.needsTypeCheck(element, SpecDoubleReal)); |
| storeType = Output::StoreDouble; |
| } |
| |
| LValue prevLength = m_out.load32(storage, m_heaps.Butterfly_publicLength); |
| |
| LBasicBlock fastPath = m_out.newBlock(); |
| LBasicBlock slowPath = m_out.newBlock(); |
| LBasicBlock continuation = m_out.newBlock(); |
| |
| m_out.branch( |
| m_out.aboveOrEqual( |
| prevLength, m_out.load32(storage, m_heaps.Butterfly_vectorLength)), |
| unsure(slowPath), unsure(fastPath)); |
| |
| LBasicBlock lastNext = m_out.appendTo(fastPath, slowPath); |
| m_out.store( |
| value, m_out.baseIndex(heap, storage, m_out.zeroExtPtr(prevLength)), storeType); |
| LValue newLength = m_out.add(prevLength, m_out.int32One); |
| m_out.store32(newLength, storage, m_heaps.Butterfly_publicLength); |
| |
| ValueFromBlock fastResult = m_out.anchor(boxInt32(newLength)); |
| m_out.jump(continuation); |
| |
| m_out.appendTo(slowPath, continuation); |
| LValue operation; |
| if (m_node->arrayMode().type() != Array::Double) |
| operation = m_out.operation(operationArrayPush); |
| else |
| operation = m_out.operation(operationArrayPushDouble); |
| ValueFromBlock slowResult = m_out.anchor( |
| vmCall(Int64, operation, m_callFrame, value, base)); |
| m_out.jump(continuation); |
| |
| m_out.appendTo(continuation, lastNext); |
| setJSValue(m_out.phi(Int64, fastResult, slowResult)); |
| return; |
| } |
| |
| LValue prevLength = m_out.load32(storage, m_heaps.Butterfly_publicLength); |
| LValue newLength = m_out.add(prevLength, m_out.constInt32(elementCount)); |
| |
| LBasicBlock fastPath = m_out.newBlock(); |
| LBasicBlock slowPath = m_out.newBlock(); |
| LBasicBlock setup = m_out.newBlock(); |
| LBasicBlock slowCallPath = m_out.newBlock(); |
| LBasicBlock continuation = m_out.newBlock(); |
| |
| LValue beyondVectorLength = m_out.above(newLength, m_out.load32(storage, m_heaps.Butterfly_vectorLength)); |
| |
| m_out.branch(beyondVectorLength, unsure(slowPath), unsure(fastPath)); |
| |
| LBasicBlock lastNext = m_out.appendTo(fastPath, slowPath); |
| m_out.store32(newLength, storage, m_heaps.Butterfly_publicLength); |
| ValueFromBlock fastBufferResult = m_out.anchor(m_out.baseIndex(storage, m_out.zeroExtPtr(prevLength), ScaleEight)); |
| m_out.jump(setup); |
| |
| m_out.appendTo(slowPath, setup); |
| size_t scratchSize = sizeof(EncodedJSValue) * elementCount; |
| static_assert(sizeof(EncodedJSValue) == sizeof(double), ""); |
| ASSERT(scratchSize); |
| ScratchBuffer* scratchBuffer = vm().scratchBufferForSize(scratchSize); |
| m_out.storePtr(m_out.constIntPtr(scratchSize), m_out.absolute(scratchBuffer->addressOfActiveLength())); |
| ValueFromBlock slowBufferResult = m_out.anchor(m_out.constIntPtr(static_cast<EncodedJSValue*>(scratchBuffer->dataBuffer()))); |
| m_out.jump(setup); |
| |
| m_out.appendTo(setup, slowCallPath); |
| LValue buffer = m_out.phi(pointerType(), fastBufferResult, slowBufferResult); |
| for (unsigned elementIndex = 0; elementIndex < elementCount; ++elementIndex) { |
| Edge& element = m_graph.varArgChild(m_node, elementIndex + elementOffset); |
| |
| LValue value; |
| Output::StoreType storeType; |
| if (m_node->arrayMode().type() != Array::Double) { |
| value = lowJSValue(element, ManualOperandSpeculation); |
| if (m_node->arrayMode().type() == Array::Int32) |
| DFG_ASSERT(m_graph, m_node, !m_interpreter.needsTypeCheck(element, SpecInt32Only)); |
| storeType = Output::Store64; |
| } else { |
| value = lowDouble(element); |
| DFG_ASSERT(m_graph, m_node, !m_interpreter.needsTypeCheck(element, SpecDoubleReal)); |
| storeType = Output::StoreDouble; |
| } |
| |
| m_out.store(value, m_out.baseIndex(heap, buffer, m_out.constInt32(elementIndex), jsNumber(elementIndex)), storeType); |
| } |
| ValueFromBlock fastResult = m_out.anchor(boxInt32(newLength)); |
| |
| m_out.branch(beyondVectorLength, unsure(slowCallPath), unsure(continuation)); |
| |
| m_out.appendTo(slowCallPath, continuation); |
| LValue operation; |
| if (m_node->arrayMode().type() != Array::Double) |
| operation = m_out.operation(operationArrayPushMultiple); |
| else |
| operation = m_out.operation(operationArrayPushDoubleMultiple); |
| ValueFromBlock slowResult = m_out.anchor(vmCall(Int64, operation, m_callFrame, base, buffer, m_out.constInt32(elementCount))); |
| m_out.storePtr(m_out.constIntPtr(0), m_out.absolute(scratchBuffer->addressOfActiveLength())); |
| m_out.jump(continuation); |
| |
| m_out.appendTo(continuation, lastNext); |
| setJSValue(m_out.phi(Int64, fastResult, slowResult)); |
| return; |
| } |
| |
| case Array::ArrayStorage: { |
| // This ensures that the result of ArrayPush is Int32 in AI. |
| int32_t largestPositiveInt32Length = 0x7fffffff - elementCount; |
| |
| LValue prevLength = m_out.load32(storage, m_heaps.ArrayStorage_publicLength); |
| // Refuse to handle bizarre lengths. |
| speculate(Uncountable, noValue(), nullptr, m_out.above(prevLength, m_out.constInt32(largestPositiveInt32Length))); |
| |
| if (elementCount == 1) { |
| Edge& element = m_graph.varArgChild(m_node, elementOffset); |
| |
| LValue value = lowJSValue(element); |
| |
| LBasicBlock fastPath = m_out.newBlock(); |
| LBasicBlock slowPath = m_out.newBlock(); |
| LBasicBlock continuation = m_out.newBlock(); |
| |
| m_out.branch( |
| m_out.aboveOrEqual( |
| prevLength, m_out.load32(storage, m_heaps.ArrayStorage_vectorLength)), |
| rarely(slowPath), usually(fastPath)); |
| |
| LBasicBlock lastNext = m_out.appendTo(fastPath, slowPath); |
| m_out.store64( |
| value, m_out.baseIndex(m_heaps.ArrayStorage_vector, storage, m_out.zeroExtPtr(prevLength))); |
| LValue newLength = m_out.add(prevLength, m_out.int32One); |
| m_out.store32(newLength, storage, m_heaps.ArrayStorage_publicLength); |
| m_out.store32( |
| m_out.add(m_out.load32(storage, m_heaps.ArrayStorage_numValuesInVector), m_out.int32One), |
| storage, m_heaps.ArrayStorage_numValuesInVector); |
| |
| ValueFromBlock fastResult = m_out.anchor(boxInt32(newLength)); |
| m_out.jump(continuation); |
| |
| m_out.appendTo(slowPath, continuation); |
| ValueFromBlock slowResult = m_out.anchor( |
| vmCall(Int64, m_out.operation(operationArrayPush), m_callFrame, value, base)); |
| m_out.jump(continuation); |
| |
| m_out.appendTo(continuation, lastNext); |
| setJSValue(m_out.phi(Int64, fastResult, slowResult)); |
| return; |
| } |
| |
| LValue newLength = m_out.add(prevLength, m_out.constInt32(elementCount)); |
| |
| LBasicBlock fastPath = m_out.newBlock(); |
| LBasicBlock slowPath = m_out.newBlock(); |
| LBasicBlock setup = m_out.newBlock(); |
| LBasicBlock slowCallPath = m_out.newBlock(); |
| LBasicBlock continuation = m_out.newBlock(); |
| |
| LValue beyondVectorLength = m_out.above(newLength, m_out.load32(storage, m_heaps.ArrayStorage_vectorLength)); |
| |
| m_out.branch(beyondVectorLength, rarely(slowPath), usually(fastPath)); |
| |
| LBasicBlock lastNext = m_out.appendTo(fastPath, slowPath); |
| m_out.store32(newLength, storage, m_heaps.ArrayStorage_publicLength); |
| m_out.store32( |
| m_out.add(m_out.load32(storage, m_heaps.ArrayStorage_numValuesInVector), m_out.constInt32(elementCount)), |
| storage, m_heaps.ArrayStorage_numValuesInVector); |
| ValueFromBlock fastBufferResult = m_out.anchor(m_out.baseIndex(storage, m_out.zeroExtPtr(prevLength), ScaleEight, ArrayStorage::vectorOffset())); |
| m_out.jump(setup); |
| |
| m_out.appendTo(slowPath, setup); |
| size_t scratchSize = sizeof(EncodedJSValue) * elementCount; |
| ASSERT(scratchSize); |
| ScratchBuffer* scratchBuffer = vm().scratchBufferForSize(scratchSize); |
| m_out.storePtr(m_out.constIntPtr(scratchSize), m_out.absolute(scratchBuffer->addressOfActiveLength())); |
| ValueFromBlock slowBufferResult = m_out.anchor(m_out.constIntPtr(static_cast<EncodedJSValue*>(scratchBuffer->dataBuffer()))); |
| m_out.jump(setup); |
| |
| m_out.appendTo(setup, slowCallPath); |
| LValue buffer = m_out.phi(pointerType(), fastBufferResult, slowBufferResult); |
| for (unsigned elementIndex = 0; elementIndex < elementCount; ++elementIndex) { |
| Edge& element = m_graph.varArgChild(m_node, elementIndex + elementOffset); |
| |
| LValue value = lowJSValue(element); |
| m_out.store64(value, m_out.baseIndex(m_heaps.ArrayStorage_vector.atAnyIndex(), buffer, m_out.constIntPtr(elementIndex), ScaleEight)); |
| } |
| ValueFromBlock fastResult = m_out.anchor(boxInt32(newLength)); |
| |
| m_out.branch(beyondVectorLength, rarely(slowCallPath), usually(continuation)); |
| |
| m_out.appendTo(slowCallPath, continuation); |
| ValueFromBlock slowResult = m_out.anchor(vmCall(Int64, m_out.operation(operationArrayPushMultiple), m_callFrame, base, buffer, m_out.constInt32(elementCount))); |
| m_out.storePtr(m_out.constIntPtr(0), m_out.absolute(scratchBuffer->addressOfActiveLength())); |
| m_out.jump(continuation); |
| |
| m_out.appendTo(continuation, lastNext); |
| setJSValue(m_out.phi(Int64, fastResult, slowResult)); |
| return; |
| } |
| |
| default: |
| DFG_CRASH(m_graph, m_node, "Bad array type"); |
| return; |
| } |
| } |
| |
| std::pair<LValue, LValue> populateSliceRange(LValue start, LValue end, LValue length) |
| { |
| // end can be nullptr. |
| ASSERT(start); |
| ASSERT(length); |
| |
| auto pickIndex = [&] (LValue index) { |
| return m_out.select(m_out.greaterThanOrEqual(index, m_out.int32Zero), |
| m_out.select(m_out.above(index, length), length, index), |
| m_out.select(m_out.lessThan(m_out.add(length, index), m_out.int32Zero), m_out.int32Zero, m_out.add(length, index))); |
| }; |
| |
| LValue endBoundary = length; |
| if (end) |
| endBoundary = pickIndex(end); |
| LValue startIndex = pickIndex(start); |
| return std::make_pair(startIndex, endBoundary); |
| } |
| |
| void compileArraySlice() |
| { |
| JSGlobalObject* globalObject = m_graph.globalObjectFor(m_node->origin.semantic); |
| |
| LValue sourceStorage = lowStorage(m_graph.varArgChild(m_node, m_node->numChildren() - 1)); |
| LValue inputLength = m_out.load32(sourceStorage, m_heaps.Butterfly_publicLength); |
| |
| LValue startIndex = nullptr; |
| LValue resultLength = nullptr; |
| if (m_node->numChildren() == 2) { |
| startIndex = m_out.constInt32(0); |
| resultLength = inputLength; |
| } else { |
| LValue start = lowInt32(m_graph.varArgChild(m_node, 1)); |
| LValue end = nullptr; |
| if (m_node->numChildren() != 3) |
| end = lowInt32(m_graph.varArgChild(m_node, 2)); |
| |
| auto range = populateSliceRange(start, end, inputLength); |
| startIndex = range.first; |
| LValue endBoundary = range.second; |
| |
| resultLength = m_out.select(m_out.belowOrEqual(startIndex, endBoundary), |
| m_out.sub(endBoundary, startIndex), |
| m_out.constInt32(0)); |
| } |
| |
| ArrayValues arrayResult; |
| { |
| LValue indexingType = m_out.load8ZeroExt32(lowCell(m_graph.varArgChild(m_node, 0)), m_heaps.JSCell_indexingTypeAndMisc); |
| indexingType = m_out.bitAnd(indexingType, m_out.constInt32(AllArrayTypesAndHistory)); |
| // When we emit an ArraySlice, we dominate the use of the array by a CheckStructure |
| // to ensure the incoming array is one to be one of the original array structures |
| // with one of the following indexing shapes: Int32, Contiguous, Double. |
| LValue structure = m_out.select( |
| m_out.equal(indexingType, m_out.constInt32(ArrayWithInt32)), |
| weakStructure(m_graph.registerStructure(globalObject->arrayStructureForIndexingTypeDuringAllocation(ArrayWithInt32))), |
| m_out.select(m_out.equal(indexingType, m_out.constInt32(ArrayWithContiguous)), |
| weakStructure(m_graph.registerStructure(globalObject->arrayStructureForIndexingTypeDuringAllocation(ArrayWithContiguous))), |
| weakStructure(m_graph.registerStructure(globalObject->arrayStructureForIndexingTypeDuringAllocation(ArrayWithDouble))))); |
| arrayResult = allocateJSArray(resultLength, resultLength, structure, indexingType, false, false); |
| } |
| |
| LBasicBlock loop = m_out.newBlock(); |
| LBasicBlock continuation = m_out.newBlock(); |
| |
| resultLength = m_out.zeroExtPtr(resultLength); |
| ValueFromBlock startLoadIndex = m_out.anchor(m_out.zeroExtPtr(startIndex)); |
| ValueFromBlock startStoreIndex = m_out.anchor(m_out.constIntPtr(0)); |
| |
| m_out.branch( |
| m_out.below(m_out.constIntPtr(0), resultLength), unsure(loop), unsure(continuation)); |
| |
| LBasicBlock lastNext = m_out.appendTo(loop, continuation); |
| LValue storeIndex = m_out.phi(pointerType(), startStoreIndex); |
| LValue loadIndex = m_out.phi(pointerType(), startLoadIndex); |
| LValue value = m_out.load64(m_out.baseIndex(m_heaps.root, sourceStorage, loadIndex, ScaleEight)); |
| m_out.store64(value, m_out.baseIndex(m_heaps.root, arrayResult.butterfly, storeIndex, ScaleEight)); |
| LValue nextStoreIndex = m_out.add(storeIndex, m_out.constIntPtr(1)); |
| m_out.addIncomingToPhi(storeIndex, m_out.anchor(nextStoreIndex)); |
| m_out.addIncomingToPhi(loadIndex, m_out.anchor(m_out.add(loadIndex, m_out.constIntPtr(1)))); |
| m_out.branch( |
| m_out.below(nextStoreIndex, resultLength), unsure(loop), unsure(continuation)); |
| |
| m_out.appendTo(continuation, lastNext); |
| |
| mutatorFence(); |
| setJSValue(arrayResult.array); |
| } |
| |
| void compileArrayIndexOf() |
| { |
| LValue storage = lowStorage(m_node->numChildren() == 3 ? m_graph.varArgChild(m_node, 2) : m_graph.varArgChild(m_node, 3)); |
| LValue length = m_out.load32(storage, m_heaps.Butterfly_publicLength); |
| |
| LValue startIndex; |
| if (m_node->numChildren() == 4) { |
| startIndex = lowInt32(m_graph.varArgChild(m_node, 2)); |
| startIndex = m_out.select(m_out.greaterThanOrEqual(startIndex, m_out.int32Zero), |
| m_out.select(m_out.above(startIndex, length), length, startIndex), |
| m_out.select(m_out.lessThan(m_out.add(length, startIndex), m_out.int32Zero), m_out.int32Zero, m_out.add(length, startIndex))); |
| } else |
| startIndex = m_out.int32Zero; |
| |
| Edge& searchElementEdge = m_graph.varArgChild(m_node, 1); |
| switch (searchElementEdge.useKind()) { |
| case Int32Use: |
| case ObjectUse: |
| case SymbolUse: |
| case OtherUse: |
| case DoubleRepUse: { |
| LBasicBlock loopHeader = m_out.newBlock(); |
| LBasicBlock loopBody = m_out.newBlock(); |
| LBasicBlock loopNext = m_out.newBlock(); |
| LBasicBlock notFound = m_out.newBlock(); |
| LBasicBlock continuation = m_out.newBlock(); |
| |
| LValue searchElement; |
| switch (searchElementEdge.useKind()) { |
| case Int32Use: |
| ASSERT(m_node->arrayMode().type() == Array::Int32); |
| speculate(searchElementEdge); |
| searchElement = lowJSValue(searchElementEdge, ManualOperandSpeculation); |
| break; |
| case ObjectUse: |
| ASSERT(m_node->arrayMode().type() == Array::Contiguous); |
| searchElement = lowObject(searchElementEdge); |
| break; |
| case SymbolUse: |
| ASSERT(m_node->arrayMode().type() == Array::Contiguous); |
| searchElement = lowSymbol(searchElementEdge); |
| break; |
| case OtherUse: |
| ASSERT(m_node->arrayMode().type() == Array::Contiguous); |
| speculate(searchElementEdge); |
| searchElement = lowJSValue(searchElementEdge, ManualOperandSpeculation); |
| break; |
| case DoubleRepUse: |
| ASSERT(m_node->arrayMode().type() == Array::Double); |
| searchElement = lowDouble(searchElementEdge); |
| break; |
| default: |
| RELEASE_ASSERT_NOT_REACHED(); |
| break; |
| } |
| |
| startIndex = m_out.zeroExtPtr(startIndex); |
| length = m_out.zeroExtPtr(length); |
| |
| ValueFromBlock initialStartIndex = m_out.anchor(startIndex); |
| m_out.jump(loopHeader); |
| |
| LBasicBlock lastNext = m_out.appendTo(loopHeader, loopBody); |
| LValue index = m_out.phi(pointerType(), initialStartIndex); |
| m_out.branch(m_out.notEqual(index, length), unsure(loopBody), unsure(notFound)); |
| |
| m_out.appendTo(loopBody, loopNext); |
| ValueFromBlock foundResult = m_out.anchor(index); |
| switch (searchElementEdge.useKind()) { |
| case Int32Use: { |
| // Empty value is ignored because of TagTypeNumber. |
| LValue value = m_out.load64(m_out.baseIndex(m_heaps.indexedInt32Properties, storage, index)); |
| m_out.branch(m_out.equal(value, searchElement), unsure(continuation), unsure(loopNext)); |
| break; |
| } |
| case ObjectUse: |
| case SymbolUse: |
| case OtherUse: { |
| // Empty value never matches against non-empty JS values. |
| LValue value = m_out.load64(m_out.baseIndex(m_heaps.indexedContiguousProperties, storage, index)); |
| m_out.branch(m_out.equal(value, searchElement), unsure(continuation), unsure(loopNext)); |
| break; |
| } |
| case DoubleRepUse: { |
| // Empty value is ignored because of NaN. |
| LValue value = m_out.loadDouble(m_out.baseIndex(m_heaps.indexedDoubleProperties, storage, index)); |
| m_out.branch(m_out.doubleEqual(value, searchElement), unsure(continuation), unsure(loopNext)); |
| break; |
| } |
| default: |
| RELEASE_ASSERT_NOT_REACHED(); |
| break; |
| } |
| |
| m_out.appendTo(loopNext, notFound); |
| LValue nextIndex = m_out.add(index, m_out.intPtrOne); |
| m_out.addIncomingToPhi(index, m_out.anchor(nextIndex)); |
| m_out.jump(loopHeader); |
| |
| m_out.appendTo(notFound, continuation); |
| ValueFromBlock notFoundResult = m_out.anchor(m_out.constIntPtr(-1)); |
| m_out.jump(continuation); |
| |
| m_out.appendTo(continuation, lastNext); |
| setInt32(m_out.castToInt32(m_out.phi(pointerType(), notFoundResult, foundResult))); |
| break; |
| } |
| |
| case StringUse: |
| ASSERT(m_node->arrayMode().type() == Array::Contiguous); |
| setInt32(vmCall(Int32, m_out.operation(operationArrayIndexOfString), m_callFrame, storage, lowString(searchElementEdge), startIndex)); |
| break; |
| |
| case UntypedUse: |
| switch (m_node->arrayMode().type()) { |
| case Array::Double: |
| setInt32(vmCall(Int32, m_out.operation(operationArrayIndexOfValueDouble), m_callFrame, storage, lowJSValue(searchElementEdge), startIndex)); |
| break; |
| case Array::Int32: |
| case Array::Contiguous: |
| setInt32(vmCall(Int32, m_out.operation(operationArrayIndexOfValueInt32OrContiguous), m_callFrame, storage, lowJSValue(searchElementEdge), startIndex)); |
| break; |
| default: |
| RELEASE_ASSERT_NOT_REACHED(); |
| break; |
| } |
| break; |
| |
| default: |
| RELEASE_ASSERT_NOT_REACHED(); |
| break; |
| } |
| } |
| |
| |
| void compileArrayPop() |
| { |
| LValue base = lowCell(m_node->child1()); |
| LValue storage = lowStorage(m_node->child2()); |
| |
| switch (m_node->arrayMode().type()) { |
| case Array::Int32: |
| case Array::Double: |
| case Array::Contiguous: { |
| IndexedAbstractHeap& heap = m_heaps.forArrayType(m_node->arrayMode().type()); |
| |
| LBasicBlock fastCase = m_out.newBlock(); |
| LBasicBlock slowCase = m_out.newBlock(); |
| LBasicBlock continuation = m_out.newBlock(); |
| |
| LValue prevLength = m_out.load32(storage, m_heaps.Butterfly_publicLength); |
| |
| Vector<ValueFromBlock, 3> results; |
| results.append(m_out.anchor(m_out.constInt64(JSValue::encode(jsUndefined())))); |
| m_out.branch( |
| m_out.isZero32(prevLength), rarely(continuation), usually(fastCase)); |
| |
| LBasicBlock lastNext = m_out.appendTo(fastCase, slowCase); |
| LValue newLength = m_out.sub(prevLength, m_out.int32One); |
| m_out.store32(newLength, storage, m_heaps.Butterfly_publicLength); |
| TypedPointer pointer = m_out.baseIndex(heap, storage, m_out.zeroExtPtr(newLength)); |
| if (m_node->arrayMode().type() != Array::Double) { |
| LValue result = m_out.load64(pointer); |
| m_out.store64(m_out.int64Zero, pointer); |
| results.append(m_out.anchor(result)); |
| m_out.branch( |
| m_out.notZero64(result), usually(continuation), rarely(slowCase)); |
| } else { |
| LValue result = m_out.loadDouble(pointer); |
| m_out.store64(m_out.constInt64(bitwise_cast<int64_t>(PNaN)), pointer); |
| results.append(m_out.anchor(boxDouble(result))); |
| m_out.branch( |
| m_out.doubleEqual(result, result), |
| usually(continuation), rarely(slowCase)); |
| } |
| |
| m_out.appendTo(slowCase, continuation); |
| results.append(m_out.anchor(vmCall( |
| Int64, m_out.operation(operationArrayPopAndRecoverLength), m_callFrame, base))); |
| m_out.jump(continuation); |
| |
| m_out.appendTo(continuation, lastNext); |
| setJSValue(m_out.phi(Int64, results)); |
| return; |
| } |
| |
| case Array::ArrayStorage: { |
| LBasicBlock vectorLengthCheckCase = m_out.newBlock(); |
| LBasicBlock popCheckCase = m_out.newBlock(); |
| LBasicBlock fastCase = m_out.newBlock(); |
| LBasicBlock slowCase = m_out.newBlock(); |
| LBasicBlock continuation = m_out.newBlock(); |
| |
| LValue prevLength = m_out.load32(storage, m_heaps.ArrayStorage_publicLength); |
| |
| Vector<ValueFromBlock, 3> results; |
| results.append(m_out.anchor(m_out.constInt64(JSValue::encode(jsUndefined())))); |
| m_out.branch( |
| m_out.isZero32(prevLength), rarely(continuation), usually(vectorLengthCheckCase)); |
| |
| LBasicBlock lastNext = m_out.appendTo(vectorLengthCheckCase, popCheckCase); |
| LValue newLength = m_out.sub(prevLength, m_out.int32One); |
| m_out.branch( |
| m_out.aboveOrEqual(newLength, m_out.load32(storage, m_heaps.ArrayStorage_vectorLength)), rarely(slowCase), usually(popCheckCase)); |
| |
| m_out.appendTo(popCheckCase, fastCase); |
| TypedPointer pointer = m_out.baseIndex(m_heaps.ArrayStorage_vector, storage, m_out.zeroExtPtr(newLength)); |
| LValue result = m_out.load64(pointer); |
| m_out.branch(m_out.notZero64(result), usually(fastCase), rarely(slowCase)); |
| |
| m_out.appendTo(fastCase, slowCase); |
| m_out.store32(newLength, storage, m_heaps.ArrayStorage_publicLength); |
| m_out.store64(m_out.int64Zero, pointer); |
| m_out.store32( |
| m_out.sub(m_out.load32(storage, m_heaps.ArrayStorage_numValuesInVector), m_out.int32One), |
| storage, m_heaps.ArrayStorage_numValuesInVector); |
| results.append(m_out.anchor(result)); |
| m_out.jump(continuation); |
| |
| m_out.appendTo(slowCase, continuation); |
| results.append(m_out.anchor(vmCall( |
| Int64, m_out.operation(operationArrayPop), m_callFrame, base))); |
| m_out.jump(continuation); |
| |
| m_out.appendTo(continuation, lastNext); |
| setJSValue(m_out.phi(Int64, results)); |
| return; |
| } |
| |
| default: |
| DFG_CRASH(m_graph, m_node, "Bad array type"); |
| return; |
| } |
| } |
| |
| void compilePushWithScope() |
| { |
| LValue parentScope = lowCell(m_node->child1()); |
| auto objectEdge = m_node->child2(); |
| if (objectEdge.useKind() == ObjectUse) { |
| LValue object = lowNonNullObject(objectEdge); |
| LValue result = vmCall(Int64, m_out.operation(operationPushWithScopeObject), m_callFrame, parentScope, object); |
| setJSValue(result); |
| } else { |
| ASSERT(objectEdge.useKind() == UntypedUse); |
| LValue object = lowJSValue(m_node->child2()); |
| LValue result = vmCall(Int64, m_out.operation(operationPushWithScope), m_callFrame, parentScope, object); |
| setJSValue(result); |
| } |
| } |
| |
| void compileCreateActivation() |
| { |
| LValue scope = lowCell(m_node->child1()); |
| SymbolTable* table = m_node->castOperand<SymbolTable*>(); |
| RegisteredStructure structure = m_graph.registerStructure(m_graph.globalObjectFor(m_node->origin.semantic)->activationStructure()); |
| JSValue initializationValue = m_node->initializationValueForActivation(); |
| ASSERT(initializationValue.isUndefined() || initializationValue == jsTDZValue()); |
| if (table->singletonScope()->isStillValid()) { |
| LValue callResult = vmCall( |
| Int64, |
| m_out.operation(operationCreateActivationDirect), m_callFrame, weakStructure(structure), |
| scope, weakPointer(table), m_out.constInt64(JSValue::encode(initializationValue))); |
| setJSValue(callResult); |
| return; |
| } |
| |
| LBasicBlock slowPath = m_out.newBlock(); |
| LBasicBlock continuation = m_out.newBlock(); |
| |
| LBasicBlock lastNext = m_out.insertNewBlocksBefore(slowPath); |
| |
| LValue fastObject = allocateObject<JSLexicalEnvironment>( |
| JSLexicalEnvironment::allocationSize(table), structure, m_out.intPtrZero, slowPath); |
| |
| // We don't need memory barriers since we just fast-created the activation, so the |
| // activation must be young. |
| m_out.storePtr(scope, fastObject, m_heaps.JSScope_next); |
| m_out.storePtr(weakPointer(table), fastObject, m_heaps.JSSymbolTableObject_symbolTable); |
| |
| for (unsigned i = 0; i < table->scopeSize(); ++i) { |
| m_out.store64( |
| m_out.constInt64(JSValue::encode(initializationValue)), |
| fastObject, m_heaps.JSLexicalEnvironment_variables[i]); |
| } |
| |
| mutatorFence(); |
| |
| ValueFromBlock fastResult = m_out.anchor(fastObject); |
| m_out.jump(continuation); |
| |
| m_out.appendTo(slowPath, continuation); |
| VM& vm = this->vm(); |
| LValue callResult = lazySlowPath( |
| [=, &vm] (const Vector<Location>& locations) -> RefPtr<LazySlowPath::Generator> { |
| return createLazyCallGenerator(vm, |
| operationCreateActivationDirect, locations[0].directGPR(), |
| CCallHelpers::TrustedImmPtr(structure.get()), locations[1].directGPR(), |
| CCallHelpers::TrustedImmPtr(table), |
| CCallHelpers::TrustedImm64(JSValue::encode(initializationValue))); |
| }, |
| scope); |
| ValueFromBlock slowResult = m_out.anchor(callResult); |
| m_out.jump(continuation); |
| |
| m_out.appendTo(continuation, lastNext); |
| setJSValue(m_out.phi(pointerType(), fastResult, slowResult)); |
| } |
| |
| void compileNewFunction() |
| { |
| ASSERT(m_node->op() == NewFunction || m_node->op() == NewGeneratorFunction || m_node->op() == NewAsyncGeneratorFunction || m_node->op() == NewAsyncFunction); |
| bool isGeneratorFunction = m_node->op() == NewGeneratorFunction; |
| bool isAsyncFunction = m_node->op() == NewAsyncFunction; |
| bool isAsyncGeneratorFunction = m_node->op() == NewAsyncGeneratorFunction; |
| |
| LValue scope = lowCell(m_node->child1()); |
| |
| FunctionExecutable* executable = m_node->castOperand<FunctionExecutable*>(); |
| if (executable->singletonFunction()->isStillValid()) { |
| LValue callResult = |
| isGeneratorFunction ? vmCall(Int64, m_out.operation(operationNewGeneratorFunction), m_callFrame, scope, weakPointer(executable)) : |
| isAsyncFunction ? vmCall(Int64, m_out.operation(operationNewAsyncFunction), m_callFrame, scope, weakPointer(executable)) : |
| isAsyncGeneratorFunction ? vmCall(Int64, m_out.operation(operationNewAsyncGeneratorFunction), m_callFrame, scope, weakPointer(executable)) : |
| vmCall(Int64, m_out.operation(operationNewFunction), m_callFrame, scope, weakPointer(executable)); |
| setJSValue(callResult); |
| return; |
| } |
| |
| RegisteredStructure structure = m_graph.registerStructure( |
| [&] () { |
| JSGlobalObject* globalObject = m_graph.globalObjectFor(m_node->origin.semantic); |
| switch (m_node->op()) { |
| case NewGeneratorFunction: |
| return globalObject->generatorFunctionStructure(); |
| case NewAsyncFunction: |
| return globalObject->asyncFunctionStructure(); |
| case NewAsyncGeneratorFunction: |
| return globalObject->asyncGeneratorFunctionStructure(); |
| case NewFunction: |
| return JSFunction::selectStructureForNewFuncExp(globalObject, m_node->castOperand<FunctionExecutable*>()); |
| default: |
| RELEASE_ASSERT_NOT_REACHED(); |
| } |
| }()); |
| |
| LBasicBlock slowPath = m_out.newBlock(); |
| LBasicBlock continuation = m_out.newBlock(); |
| |
| LBasicBlock lastNext = m_out.insertNewBlocksBefore(slowPath); |
| |
| LValue fastObject = |
| isGeneratorFunction ? allocateObject<JSGeneratorFunction>(structure, m_out.intPtrZero, slowPath) : |
| isAsyncFunction ? allocateObject<JSAsyncFunction>(structure, m_out.intPtrZero, slowPath) : |
| isAsyncGeneratorFunction ? allocateObject<JSAsyncGeneratorFunction>(structure, m_out.intPtrZero, slowPath) : |
| allocateObject<JSFunction>(structure, m_out.intPtrZero, slowPath); |
| |
| |
| // We don't need memory barriers since we just fast-created the function, so it |
| // must be young. |
| m_out.storePtr(scope, fastObject, m_heaps.JSFunction_scope); |
| m_out.storePtr(weakPoisonedPointer<JSFunctionPoison>(executable), fastObject, m_heaps.JSFunction_executable); |
| m_out.storePtr(m_out.intPtrZero, fastObject, m_heaps.JSFunction_rareData); |
| |
| mutatorFence(); |
| |
| ValueFromBlock fastResult = m_out.anchor(fastObject); |
| m_out.jump(continuation); |
| |
| m_out.appendTo(slowPath, continuation); |
| |
| Vector<LValue> slowPathArguments; |
| slowPathArguments.append(scope); |
| VM& vm = this->vm(); |
| LValue callResult = lazySlowPath( |
| [=, &vm] (const Vector<Location>& locations) -> RefPtr<LazySlowPath::Generator> { |
| auto* operation = operationNewFunctionWithInvalidatedReallocationWatchpoint; |
| if (isGeneratorFunction) |
| operation = operationNewGeneratorFunctionWithInvalidatedReallocationWatchpoint; |
| else if (isAsyncFunction) |
| operation = operationNewAsyncFunctionWithInvalidatedReallocationWatchpoint; |
| else if (isAsyncGeneratorFunction) |
| operation = operationNewAsyncGeneratorFunctionWithInvalidatedReallocationWatchpoint; |
| |
| return createLazyCallGenerator(vm, operation, |
| locations[0].directGPR(), locations[1].directGPR(), |
| CCallHelpers::TrustedImmPtr(executable)); |
| }, |
| slowPathArguments); |
| ValueFromBlock slowResult = m_out.anchor(callResult); |
| m_out.jump(continuation); |
| |
| m_out.appendTo(continuation, lastNext); |
| setJSValue(m_out.phi(pointerType(), fastResult, slowResult)); |
| } |
| |
| void compileCreateDirectArguments() |
| { |
| // FIXME: A more effective way of dealing with the argument count and callee is to have |
| // them be explicit arguments to this node. |
| // https://bugs.webkit.org/show_bug.cgi?id=142207 |
| |
| RegisteredStructure structure = |
| m_graph.registerStructure(m_graph.globalObjectFor(m_node->origin.semantic)->directArgumentsStructure()); |
| |
| unsigned minCapacity = m_graph.baselineCodeBlockFor(m_node->origin.semantic)->numParameters() - 1; |
| |
| LBasicBlock slowPath = m_out.newBlock(); |
| LBasicBlock continuation = m_out.newBlock(); |
| |
| LBasicBlock lastNext = m_out.insertNewBlocksBefore(slowPath); |
| |
| ArgumentsLength length = getArgumentsLength(); |
| |
| LValue fastObject; |
| if (length.isKnown) { |
| fastObject = allocateObject<DirectArguments>( |
| DirectArguments::allocationSize(std::max(length.known, minCapacity)), structure, |
| m_out.intPtrZero, slowPath); |
| } else { |
| LValue size = m_out.add( |
| m_out.shl(length.value, m_out.constInt32(3)), |
| m_out.constInt32(DirectArguments::storageOffset())); |
| |
| size = m_out.select( |
| m_out.aboveOrEqual(length.value, m_out.constInt32(minCapacity)), |
| size, m_out.constInt32(DirectArguments::allocationSize(minCapacity))); |
| |
| fastObject = allocateVariableSizedObject<DirectArguments>( |
| m_out.zeroExtPtr(size), structure, m_out.intPtrZero, slowPath); |
| } |
| |
| m_out.store32(length.value, fastObject, m_heaps.DirectArguments_length); |
| m_out.store32(m_out.constInt32(minCapacity), fastObject, m_heaps.DirectArguments_minCapacity); |
| m_out.storePtr(m_out.intPtrZero, fastObject, m_heaps.DirectArguments_mappedArguments); |
| m_out.storePtr(m_out.intPtrZero, fastObject, m_heaps.DirectArguments_modifiedArgumentsDescriptor); |
| |
| ValueFromBlock fastResult = m_out.anchor(fastObject); |
| m_out.jump(continuation); |
| |
| m_out.appendTo(slowPath, continuation); |
| VM& vm = this->vm(); |
| LValue callResult = lazySlowPath( |
| [=, &vm] (const Vector<Location>& locations) -> RefPtr<LazySlowPath::Generator> { |
| return createLazyCallGenerator(vm, |
| operationCreateDirectArguments, locations[0].directGPR(), |
| CCallHelpers::TrustedImmPtr(structure.get()), locations[1].directGPR(), |
| CCallHelpers::TrustedImm32(minCapacity)); |
| }, length.value); |
| ValueFromBlock slowResult = m_out.anchor(callResult); |
| m_out.jump(continuation); |
| |
| m_out.appendTo(continuation, lastNext); |
| LValue result = m_out.phi(pointerType(), fastResult, slowResult); |
| |
| m_out.storePtr(getCurrentCallee(), result, m_heaps.DirectArguments_callee); |
| |
| if (length.isKnown) { |
| VirtualRegister start = AssemblyHelpers::argumentsStart(m_node->origin.semantic); |
| for (unsigned i = 0; i < std::max(length.known, minCapacity); ++i) { |
| m_out.store64( |
| m_out.load64(addressFor(start + i)), |
| result, m_heaps.DirectArguments_storage[i]); |
| } |
| } else { |
| LValue stackBase = getArgumentsStart(); |
| |
| LBasicBlock loop = m_out.newBlock(); |
| LBasicBlock end = m_out.newBlock(); |
| |
| ValueFromBlock originalLength; |
| if (minCapacity) { |
| LValue capacity = m_out.select( |
| m_out.aboveOrEqual(length.value, m_out.constInt32(minCapacity)), |
| length.value, |
| m_out.constInt32(minCapacity)); |
| LValue originalLengthValue = m_out.zeroExtPtr(capacity); |
| originalLength = m_out.anchor(originalLengthValue); |
| m_out.jump(loop); |
| } else { |
| LValue originalLengthValue = m_out.zeroExtPtr(length.value); |
| originalLength = m_out.anchor(originalLengthValue); |
| m_out.branch(m_out.isNull(originalLengthValue), unsure(end), unsure(loop)); |
| } |
| |
| lastNext = m_out.appendTo(loop, end); |
| LValue previousIndex = m_out.phi(pointerType(), originalLength); |
| LValue index = m_out.sub(previousIndex, m_out.intPtrOne); |
| m_out.store64( |
| m_out.load64(m_out.baseIndex(m_heaps.variables, stackBase, index)), |
| m_out.baseIndex(m_heaps.DirectArguments_storage, result, index)); |
| ValueFromBlock nextIndex = m_out.anchor(index); |
| m_out.addIncomingToPhi(previousIndex, nextIndex); |
| m_out.branch(m_out.isNull(index), unsure(end), unsure(loop)); |
| |
| m_out.appendTo(end, lastNext); |
| } |
| |
| mutatorFence(); |
| |
| setJSValue(result); |
| } |
| |
| void compileCreateScopedArguments() |
| { |
| LValue scope = lowCell(m_node->child1()); |
| |
| LValue result = vmCall( |
| Int64, m_out.operation(operationCreateScopedArguments), m_callFrame, |
| weakPointer( |
| m_graph.globalObjectFor(m_node->origin.semantic)->scopedArgumentsStructure()), |
| getArgumentsStart(), getArgumentsLength().value, getCurrentCallee(), scope); |
| |
| setJSValue(result); |
| } |
| |
| void compileCreateClonedArguments() |
| { |
| LValue result = vmCall( |
| Int64, m_out.operation(operationCreateClonedArguments), m_callFrame, |
| weakPointer( |
| m_graph.globalObjectFor(m_node->origin.semantic)->clonedArgumentsStructure()), |
| getArgumentsStart(), getArgumentsLength().value, getCurrentCallee()); |
| |
| setJSValue(result); |
| } |
| |
| void compileCreateRest() |
| { |
| if (m_graph.isWatchingHavingABadTimeWatchpoint(m_node)) { |
| LBasicBlock continuation = m_out.newBlock(); |
| LValue arrayLength = lowInt32(m_node->child1()); |
| LBasicBlock loopStart = m_out.newBlock(); |
| JSGlobalObject* globalObject = m_graph.globalObjectFor(m_node->origin.semantic); |
| RegisteredStructure structure = m_graph.registerStructure(globalObject->originalRestParameterStructure()); |
| ArrayValues arrayValues = allocateUninitializedContiguousJSArray(arrayLength, structure); |
| LValue array = arrayValues.array; |
| LValue butterfly = arrayValues.butterfly; |
| ValueFromBlock startLength = m_out.anchor(arrayLength); |
| LValue argumentRegion = m_out.add(getArgumentsStart(), m_out.constInt64(sizeof(Register) * m_node->numberOfArgumentsToSkip())); |
| m_out.branch(m_out.equal(arrayLength, m_out.constInt32(0)), |
| unsure(continuation), unsure(loopStart)); |
| |
| LBasicBlock lastNext = m_out.appendTo(loopStart, continuation); |
| LValue phiOffset = m_out.phi(Int32, startLength); |
| LValue currentOffset = m_out.sub(phiOffset, m_out.int32One); |
| m_out.addIncomingToPhi(phiOffset, m_out.anchor(currentOffset)); |
| LValue loadedValue = m_out.load64(m_out.baseIndex(m_heaps.variables, argumentRegion, m_out.zeroExtPtr(currentOffset))); |
| IndexedAbstractHeap& heap = m_heaps.indexedContiguousProperties; |
| m_out.store64(loadedValue, m_out.baseIndex(heap, butterfly, m_out.zeroExtPtr(currentOffset))); |
| m_out.branch(m_out.equal(currentOffset, m_out.constInt32(0)), unsure(continuation), unsure(loopStart)); |
| |
| m_out.appendTo(continuation, lastNext); |
| mutatorFence(); |
| setJSValue(array); |
| return; |
| } |
| |
| LValue arrayLength = lowInt32(m_node->child1()); |
| LValue argumentStart = getArgumentsStart(); |
| LValue numberOfArgumentsToSkip = m_out.constInt32(m_node->numberOfArgumentsToSkip()); |
| setJSValue(vmCall( |
| Int64, m_out.operation(operationCreateRest), m_callFrame, argumentStart, numberOfArgumentsToSkip, arrayLength)); |
| } |
| |
| void compileGetRestLength() |
| { |
| LBasicBlock nonZeroLength = m_out.newBlock(); |
| LBasicBlock continuation = m_out.newBlock(); |
| |
| ValueFromBlock zeroLengthResult = m_out.anchor(m_out.constInt32(0)); |
| |
| LValue numberOfArgumentsToSkip = m_out.constInt32(m_node->numberOfArgumentsToSkip()); |
| LValue argumentsLength = getArgumentsLength().value; |
| m_out.branch(m_out.above(argumentsLength, numberOfArgumentsToSkip), |
| unsure(nonZeroLength), unsure(continuation)); |
| |
| LBasicBlock lastNext = m_out.appendTo(nonZeroLength, continuation); |
| ValueFromBlock nonZeroLengthResult = m_out.anchor(m_out.sub(argumentsLength, numberOfArgumentsToSkip)); |
| m_out.jump(continuation); |
| |
| m_out.appendTo(continuation, lastNext); |
| setInt32(m_out.phi(Int32, zeroLengthResult, nonZeroLengthResult)); |
| } |
| |
| void compileNewObject() |
| { |
| setJSValue(allocateObject(m_node->structure())); |
| mutatorFence(); |
| } |
| |
| void compileNewStringObject() |
| { |
| RegisteredStructure structure = m_node->structure(); |
| LValue string = lowString(m_node->child1()); |
| |
| LBasicBlock slowCase = m_out.newBlock(); |
| LBasicBlock continuation = m_out.newBlock(); |
| |
| LBasicBlock lastNext = m_out.insertNewBlocksBefore(slowCase); |
| |
| LValue fastResultValue = allocateObject<StringObject>(structure, m_out.intPtrZero, slowCase); |
| m_out.storePtr(m_out.constIntPtr(PoisonedClassInfoPtr(StringObject::info()).bits()), fastResultValue, m_heaps.JSDestructibleObject_classInfo); |
| m_out.store64(string, fastResultValue, m_heaps.JSWrapperObject_internalValue); |
| mutatorFence(); |
| ValueFromBlock fastResult = m_out.anchor(fastResultValue); |
| m_out.jump(continuation); |
| |
| m_out.appendTo(slowCase, continuation); |
| VM& vm = this->vm(); |
| LValue slowResultValue = lazySlowPath( |
| [=, &vm] (const Vector<Location>& locations) -> RefPtr<LazySlowPath::Generator> { |
| return createLazyCallGenerator(vm, |
| operationNewStringObject, locations[0].directGPR(), locations[1].directGPR(), |
| CCallHelpers::TrustedImmPtr(structure.get())); |
| }, |
| string); |
| ValueFromBlock slowResult = m_out.anchor(slowResultValue); |
| m_out.jump(continuation); |
| |
| m_out.appendTo(continuation, lastNext); |
| setJSValue(m_out.phi(pointerType(), fastResult, slowResult)); |
| } |
| |
| void compileNewArray() |
| { |
| // First speculate appropriately on all of the children. Do this unconditionally up here |
| // because some of the slow paths may otherwise forget to do it. It's sort of arguable |
| // that doing the speculations up here might be unprofitable for RA - so we can consider |
| // sinking this to below the allocation fast path if we find that this has a lot of |
| // register pressure. |
| for (unsigned operandIndex = 0; operandIndex < m_node->numChildren(); ++operandIndex) |
| speculate(m_graph.varArgChild(m_node, operandIndex)); |
| |
| JSGlobalObject* globalObject = m_graph.globalObjectFor(m_node->origin.semantic); |
| RegisteredStructure structure = m_graph.registerStructure(globalObject->arrayStructureForIndexingTypeDuringAllocation( |
| m_node->indexingType())); |
| |
| if (!globalObject->isHavingABadTime() && !hasAnyArrayStorage(m_node->indexingType())) { |
| unsigned numElements = m_node->numChildren(); |
| unsigned vectorLengthHint = m_node->vectorLengthHint(); |
| ASSERT(vectorLengthHint >= numElements); |
| |
| ArrayValues arrayValues = |
| allocateUninitializedContiguousJSArray(numElements, vectorLengthHint, structure); |
| |
| for (unsigned operandIndex = 0; operandIndex < m_node->numChildren(); ++operandIndex) { |
| Edge edge = m_graph.varArgChild(m_node, operandIndex); |
| |
| switch (m_node->indexingType()) { |
| case ALL_BLANK_INDEXING_TYPES: |
| case ALL_UNDECIDED_INDEXING_TYPES: |
| DFG_CRASH(m_graph, m_node, "Bad indexing type"); |
| break; |
| |
| case ALL_DOUBLE_INDEXING_TYPES: |
| m_out.storeDouble( |
| lowDouble(edge), |
| arrayValues.butterfly, m_heaps.indexedDoubleProperties[operandIndex]); |
| break; |
| |
| case ALL_INT32_INDEXING_TYPES: |
| case ALL_CONTIGUOUS_INDEXING_TYPES: |
| m_out.store64( |
| lowJSValue(edge, ManualOperandSpeculation), |
| arrayValues.butterfly, |
| m_heaps.forIndexingType(m_node->indexingType())->at(operandIndex)); |
| break; |
| |
| default: |
| DFG_CRASH(m_graph, m_node, "Corrupt indexing type"); |
| break; |
| } |
| } |
| |
| setJSValue(arrayValues.array); |
| mutatorFence(); |
| return; |
| } |
| |
| if (!m_node->numChildren()) { |
| setJSValue(vmCall( |
| Int64, m_out.operation(operationNewEmptyArray), m_callFrame, |
| weakStructure(structure))); |
| return; |
| } |
| |
| size_t scratchSize = sizeof(EncodedJSValue) * m_node->numChildren(); |
| ASSERT(scratchSize); |
| ScratchBuffer* scratchBuffer = vm().scratchBufferForSize(scratchSize); |
| EncodedJSValue* buffer = static_cast<EncodedJSValue*>(scratchBuffer->dataBuffer()); |
| |
| for (unsigned operandIndex = 0; operandIndex < m_node->numChildren(); ++operandIndex) { |
| Edge edge = m_graph.varArgChild(m_node, operandIndex); |
| LValue valueToStore; |
| switch (m_node->indexingType()) { |
| case ALL_DOUBLE_INDEXING_TYPES: |
| valueToStore = boxDouble(lowDouble(edge)); |
| break; |
| default: |
| valueToStore = lowJSValue(edge, ManualOperandSpeculation); |
| break; |
| } |
| m_out.store64(valueToStore, m_out.absolute(buffer + operandIndex)); |
| } |
| |
| m_out.storePtr( |
| m_out.constIntPtr(scratchSize), m_out.absolute(scratchBuffer->addressOfActiveLength())); |
| |
| LValue result = vmCall( |
| Int64, m_out.operation(operationNewArray), m_callFrame, |
| weakStructure(structure), m_out.constIntPtr(buffer), |
| m_out.constIntPtr(m_node->numChildren())); |
| |
| m_out.storePtr(m_out.intPtrZero, m_out.absolute(scratchBuffer->addressOfActiveLength())); |
| |
| setJSValue(result); |
| } |
| |
| void compileNewArrayWithSpread() |
| { |
| if (m_graph.isWatchingHavingABadTimeWatchpoint(m_node)) { |
| CheckedInt32 startLength = 0; |
| BitVector* bitVector = m_node->bitVector(); |
| HashMap<InlineCallFrame*, LValue, WTF::DefaultHash<InlineCallFrame*>::Hash, WTF::NullableHashTraits<InlineCallFrame*>> cachedSpreadLengths; |
| |
| for (unsigned i = 0; i < m_node->numChildren(); ++i) { |
| if (!bitVector->get(i)) |
| ++startLength; |
| else { |
| Edge& child = m_graph.varArgChild(m_node, i); |
| if (child->op() == PhantomSpread && child->child1()->op() == PhantomNewArrayBuffer) |
| startLength += child->child1()->castOperand<JSFixedArray*>()->length(); |
| } |
| } |
| |
| if (startLength.hasOverflowed()) { |
| terminate(Overflow); |
| return; |
| } |
| |
| LValue length = m_out.constInt32(startLength.unsafeGet()); |
| |
| for (unsigned i = 0; i < m_node->numChildren(); ++i) { |
| if (bitVector->get(i)) { |
| Edge use = m_graph.varArgChild(m_node, i); |
| CheckValue* lengthCheck = nullptr; |
| if (use->op() == PhantomSpread) { |
| if (use->child1()->op() == PhantomCreateRest) { |
| InlineCallFrame* inlineCallFrame = use->child1()->origin.semantic.inlineCallFrame; |
| unsigned numberOfArgumentsToSkip = use->child1()->numberOfArgumentsToSkip(); |
| LValue spreadLength = cachedSpreadLengths.ensure(inlineCallFrame, [&] () { |
| return getSpreadLengthFromInlineCallFrame(inlineCallFrame, numberOfArgumentsToSkip); |
| }).iterator->value; |
| lengthCheck = m_out.speculateAdd(length, spreadLength); |
| } |
| } else { |
| LValue fixedArray = lowCell(use); |
| lengthCheck = m_out.speculateAdd(length, m_out.load32(fixedArray, m_heaps.JSFixedArray_size)); |
| } |
| |
| if (lengthCheck) { |
| blessSpeculation(lengthCheck, Overflow, noValue(), nullptr, m_origin); |
| length = lengthCheck; |
| } |
| } |
| } |
| |
| RegisteredStructure structure = m_graph.registerStructure(m_graph.globalObjectFor(m_node->origin.semantic)->originalArrayStructureForIndexingType(ArrayWithContiguous)); |
| ArrayValues arrayValues = allocateUninitializedContiguousJSArray(length, structure); |
| LValue result = arrayValues.array; |
| LValue storage = arrayValues.butterfly; |
| LValue index = m_out.constIntPtr(0); |
| |
| for (unsigned i = 0; i < m_node->numChildren(); ++i) { |
| Edge use = m_graph.varArgChild(m_node, i); |
| if (bitVector->get(i)) { |
| if (use->op() == PhantomSpread) { |
| if (use->child1()->op() == PhantomNewArrayBuffer) { |
| IndexedAbstractHeap& heap = m_heaps.indexedContiguousProperties; |
| auto* array = use->child1()->castOperand<JSFixedArray*>(); |
| for (unsigned i = 0; i < array->length(); ++i) { |
| // Because resulted array from NewArrayWithSpread is always contiguous, we should not generate value |
| // in Double form even if PhantomNewArrayBuffer's indexingType is ArrayWithDouble. |
| int64_t value = JSValue::encode(array->get(i)); |
| m_out.store64(m_out.constInt64(value), m_out.baseIndex(heap, storage, index, JSValue(), (Checked<int32_t>(sizeof(JSValue)) * i).unsafeGet())); |
| } |
| index = m_out.add(index, m_out.constIntPtr(array->length())); |
| } else { |
| RELEASE_ASSERT(use->child1()->op() == PhantomCreateRest); |
| InlineCallFrame* inlineCallFrame = use->child1()->origin.semantic.inlineCallFrame; |
| unsigned numberOfArgumentsToSkip = use->child1()->numberOfArgumentsToSkip(); |
| |
| LValue length = m_out.zeroExtPtr(cachedSpreadLengths.get(inlineCallFrame)); |
| LValue sourceStart = getArgumentsStart(inlineCallFrame, numberOfArgumentsToSkip); |
| |
| LBasicBlock loopStart = m_out.newBlock(); |
| LBasicBlock continuation = m_out.newBlock(); |
| |
| ValueFromBlock loadIndexStart = m_out.anchor(m_out.constIntPtr(0)); |
| ValueFromBlock arrayIndexStart = m_out.anchor(index); |
| ValueFromBlock arrayIndexStartForFinish = m_out.anchor(index); |
| |
| m_out.branch( |
| m_out.isZero64(length), |
| unsure(continuation), unsure(loopStart)); |
| |
| LBasicBlock lastNext = m_out.appendTo(loopStart, continuation); |
| |
| LValue arrayIndex = m_out.phi(pointerType(), arrayIndexStart); |
| LValue loadIndex = m_out.phi(pointerType(), loadIndexStart); |
| |
| LValue item = m_out.load64(m_out.baseIndex(m_heaps.variables, sourceStart, loadIndex)); |
| m_out.store64(item, m_out.baseIndex(m_heaps.indexedContiguousProperties, storage, arrayIndex)); |
| |
| LValue nextArrayIndex = m_out.add(arrayIndex, m_out.constIntPtr(1)); |
| LValue nextLoadIndex = m_out.add(loadIndex, m_out.constIntPtr(1)); |
| ValueFromBlock arrayIndexLoopForFinish = m_out.anchor(nextArrayIndex); |
| |
| m_out.addIncomingToPhi(loadIndex, m_out.anchor(nextLoadIndex)); |
| m_out.addIncomingToPhi(arrayIndex, m_out.anchor(nextArrayIndex)); |
| |
| m_out.branch( |
| m_out.below(nextLoadIndex, length), |
| unsure(loopStart), unsure(continuation)); |
| |
| m_out.appendTo(continuation, lastNext); |
| index = m_out.phi(pointerType(), arrayIndexStartForFinish, arrayIndexLoopForFinish); |
| } |
| } else { |
| LBasicBlock loopStart = m_out.newBlock(); |
| LBasicBlock continuation = m_out.newBlock(); |
| |
| LValue fixedArray = lowCell(use); |
| |
| ValueFromBlock fixedIndexStart = m_out.anchor(m_out.constIntPtr(0)); |
| ValueFromBlock arrayIndexStart = m_out.anchor(index); |
| ValueFromBlock arrayIndexStartForFinish = m_out.anchor(index); |
| |
| LValue fixedArraySize = m_out.zeroExtPtr(m_out.load32(fixedArray, m_heaps.JSFixedArray_size)); |
| |
| m_out.branch( |
| m_out.isZero64(fixedArraySize), |
| unsure(continuation), unsure(loopStart)); |
| |
| LBasicBlock lastNext = m_out.appendTo(loopStart, continuation); |
| |
| LValue arrayIndex = m_out.phi(pointerType(), arrayIndexStart); |
| LValue fixedArrayIndex = m_out.phi(pointerType(), fixedIndexStart); |
| |
| LValue item = m_out.load64(m_out.baseIndex(m_heaps.JSFixedArray_buffer, fixedArray, fixedArrayIndex)); |
| m_out.store64(item, m_out.baseIndex(m_heaps.indexedContiguousProperties, storage, arrayIndex)); |
| |
| LValue nextArrayIndex = m_out.add(arrayIndex, m_out.constIntPtr(1)); |
| LValue nextFixedArrayIndex = m_out.add(fixedArrayIndex, m_out.constIntPtr(1)); |
| ValueFromBlock arrayIndexLoopForFinish = m_out.anchor(nextArrayIndex); |
| |
| m_out.addIncomingToPhi(fixedArrayIndex, m_out.anchor(nextFixedArrayIndex)); |
| m_out.addIncomingToPhi(arrayIndex, m_out.anchor(nextArrayIndex)); |
| |
| m_out.branch( |
| m_out.below(nextFixedArrayIndex, fixedArraySize), |
| unsure(loopStart), unsure(continuation)); |
| |
| m_out.appendTo(continuation, lastNext); |
| index = m_out.phi(pointerType(), arrayIndexStartForFinish, arrayIndexLoopForFinish); |
| } |
| } else { |
| IndexedAbstractHeap& heap = m_heaps.indexedContiguousProperties; |
| LValue item = lowJSValue(use); |
| m_out.store64(item, m_out.baseIndex(heap, storage, index)); |
| index = m_out.add(index, m_out.constIntPtr(1)); |
| } |
| } |
| |
| mutatorFence(); |
| setJSValue(result); |
| return; |
| } |
| |
| ASSERT(m_node->numChildren()); |
| size_t scratchSize = sizeof(EncodedJSValue) * m_node->numChildren(); |
| ScratchBuffer* scratchBuffer = vm().scratchBufferForSize(scratchSize); |
| EncodedJSValue* buffer = static_cast<EncodedJSValue*>(scratchBuffer->dataBuffer()); |
| BitVector* bitVector = m_node->bitVector(); |
| for (unsigned i = 0; i < m_node->numChildren(); ++i) { |
| Edge use = m_graph.m_varArgChildren[m_node->firstChild() + i]; |
| LValue value; |
| if (bitVector->get(i)) |
| value = lowCell(use); |
| else |
| value = lowJSValue(use); |
| m_out.store64(value, m_out.absolute(&buffer[i])); |
| } |
| |
| m_out.storePtr(m_out.constIntPtr(scratchSize), m_out.absolute(scratchBuffer->addressOfActiveLength())); |
| LValue result = vmCall(Int64, m_out.operation(operationNewArrayWithSpreadSlow), m_callFrame, m_out.constIntPtr(buffer), m_out.constInt32(m_node->numChildren())); |
| m_out.storePtr(m_out.constIntPtr(0), m_out.absolute(scratchBuffer->addressOfActiveLength())); |
| |
| setJSValue(result); |
| } |
| |
| void compileSpread() |
| { |
| if (m_node->child1()->op() == PhantomNewArrayBuffer) { |
| setJSValue(frozenPointer(m_node->child1()->cellOperand())); |
| return; |
| } |
| |
| if (m_node->child1()->op() == PhantomCreateRest) { |
| // This IR is rare to generate since it requires escaping the Spread |
| // but not the CreateRest. In bytecode, we have only few operations that |
| // accept Spread's result as input. This usually leads to the Spread node not |
| // escaping. However, this can happen if for example we generate a PutStack on |
| // the Spread but nothing escapes the CreateRest. |
| LBasicBlock loopHeader = m_out.newBlock(); |
| LBasicBlock loopBody = m_out.newBlock(); |
| LBasicBlock slowAllocation = m_out.newBlock(); |
| LBasicBlock continuation = m_out.newBlock(); |
| LBasicBlock lastNext = m_out.insertNewBlocksBefore(loopHeader); |
| |
| InlineCallFrame* inlineCallFrame = m_node->child1()->origin.semantic.inlineCallFrame; |
| unsigned numberOfArgumentsToSkip = m_node->child1()->numberOfArgumentsToSkip(); |
| LValue sourceStart = getArgumentsStart(inlineCallFrame, numberOfArgumentsToSkip); |
| LValue length = getSpreadLengthFromInlineCallFrame(inlineCallFrame, numberOfArgumentsToSkip); |
| static_assert(sizeof(JSValue) == 8 && 1 << 3 == 8, "Assumed in the code below."); |
| LValue size = m_out.add( |
| m_out.shl(m_out.zeroExtPtr(length), m_out.constInt32(3)), |
| m_out.constIntPtr(JSFixedArray::offsetOfData())); |
| |
| LValue fastArrayValue = allocateVariableSizedCell<JSFixedArray>(size, m_graph.m_vm.fixedArrayStructure.get(), slowAllocation); |
| m_out.store32(length, fastArrayValue, m_heaps.JSFixedArray_size); |
| ValueFromBlock fastArray = m_out.anchor(fastArrayValue); |
| m_out.jump(loopHeader); |
| |
| m_out.appendTo(slowAllocation, loopHeader); |
| ValueFromBlock slowArray = m_out.anchor(vmCall(Int64, m_out.operation(operationCreateFixedArray), m_callFrame, length)); |
| m_out.jump(loopHeader); |
| |
| m_out.appendTo(loopHeader, loopBody); |
| LValue fixedArray = m_out.phi(Int64, fastArray, slowArray); |
| ValueFromBlock startIndex = m_out.anchor(m_out.constIntPtr(0)); |
| m_out.branch(m_out.isZero32(length), unsure(continuation), unsure(loopBody)); |
| |
| m_out.appendTo(loopBody, continuation); |
| LValue index = m_out.phi(pointerType(), startIndex); |
| LValue value = m_out.load64( |
| m_out.baseIndex(m_heaps.variables, sourceStart, index)); |
| m_out.store64(value, m_out.baseIndex(m_heaps.JSFixedArray_buffer, fixedArray, index)); |
| LValue nextIndex = m_out.add(m_out.constIntPtr(1), index); |
| m_out.addIncomingToPhi(index, m_out.anchor(nextIndex)); |
| m_out.branch(m_out.below(nextIndex, m_out.zeroExtPtr(length)), unsure(loopBody), unsure(continuation)); |
| |
| m_out.appendTo(continuation, lastNext); |
| mutatorFence(); |
| setJSValue(fixedArray); |
| return; |
| } |
| |
| LValue argument = lowCell(m_node->child1()); |
| |
| LValue result; |
| |
| if (m_node->child1().useKind() == ArrayUse) |
| speculateArray(m_node->child1()); |
| |
| if (m_graph.canDoFastSpread(m_node, m_state.forNode(m_node->child1()))) { |
| LBasicBlock preLoop = m_out.newBlock(); |
| LBasicBlock loopSelection = m_out.newBlock(); |
| LBasicBlock contiguousLoopStart = m_out.newBlock(); |
| LBasicBlock doubleLoopStart = m_out.newBlock(); |
| LBasicBlock slowPath = m_out.newBlock(); |
| LBasicBlock continuation = m_out.newBlock(); |
| |
| LValue indexingShape = m_out.load8ZeroExt32(argument, m_heaps.JSCell_indexingTypeAndMisc); |
| indexingShape = m_out.bitAnd(indexingShape, m_out.constInt32(IndexingShapeMask)); |
| LValue isOKIndexingType = m_out.belowOrEqual( |
| m_out.sub(indexingShape, m_out.constInt32(Int32Shape)), |
| m_out.constInt32(ContiguousShape - Int32Shape)); |
| |
| m_out.branch(isOKIndexingType, unsure(preLoop), unsure(slowPath)); |
| LBasicBlock lastNext = m_out.appendTo(preLoop, loopSelection); |
| |
| LValue butterfly = m_out.loadPtr(argument, m_heaps.JSObject_butterfly); |
| LValue length = m_out.load32NonNegative(butterfly, m_heaps.Butterfly_publicLength); |
| static_assert(sizeof(JSValue) == 8 && 1 << 3 == 8, "Assumed in the code below."); |
| LValue size = m_out.add( |
| m_out.shl(m_out.zeroExtPtr(length), m_out.constInt32(3)), |
| m_out.constIntPtr(JSFixedArray::offsetOfData())); |
| |
| LValue fastAllocation = allocateVariableSizedCell<JSFixedArray>(size, m_graph.m_vm.fixedArrayStructure.get(), slowPath); |
| ValueFromBlock fastResult = m_out.anchor(fastAllocation); |
| m_out.store32(length, fastAllocation, m_heaps.JSFixedArray_size); |
| |
| ValueFromBlock startIndexForContiguous = m_out.anchor(m_out.constIntPtr(0)); |
| ValueFromBlock startIndexForDouble = m_out.anchor(m_out.constIntPtr(0)); |
| |
| m_out.branch(m_out.isZero32(length), unsure(continuation), unsure(loopSelection)); |
| |
| m_out.appendTo(loopSelection, contiguousLoopStart); |
| m_out.branch(m_out.equal(indexingShape, m_out.constInt32(DoubleShape)), |
| unsure(doubleLoopStart), unsure(contiguousLoopStart)); |
| |
| { |
| m_out.appendTo(contiguousLoopStart, doubleLoopStart); |
| LValue index = m_out.phi(pointerType(), startIndexForContiguous); |
| |
| TypedPointer loadSite = m_out.baseIndex(m_heaps.root, butterfly, index, ScaleEight); // We read TOP here since we can be reading either int32 or contiguous properties. |
| LValue value = m_out.load64(loadSite); |
| value = m_out.select(m_out.isZero64(value), m_out.constInt64(JSValue::encode(jsUndefined())), value); |
| m_out.store64(value, m_out.baseIndex(m_heaps.JSFixedArray_buffer, fastAllocation, index)); |
| |
| LValue nextIndex = m_out.add(index, m_out.constIntPtr(1)); |
| m_out.addIncomingToPhi(index, m_out.anchor(nextIndex)); |
| |
| m_out.branch(m_out.below(nextIndex, m_out.zeroExtPtr(length)), |
| unsure(contiguousLoopStart), unsure(continuation)); |
| } |
| |
| { |
| m_out.appendTo(doubleLoopStart, slowPath); |
| LValue index = m_out.phi(pointerType(), startIndexForDouble); |
| |
| LValue value = m_out.loadDouble(m_out.baseIndex(m_heaps.indexedDoubleProperties, butterfly, index)); |
| LValue isNaN = m_out.doubleNotEqualOrUnordered(value, value); |
| LValue holeResult = m_out.constInt64(JSValue::encode(jsUndefined())); |
| LValue normalResult = boxDouble(value); |
| value = m_out.select(isNaN, holeResult, normalResult); |
| m_out.store64(value, m_out.baseIndex(m_heaps.JSFixedArray_buffer, fastAllocation, index)); |
| |
| LValue nextIndex = m_out.add(index, m_out.constIntPtr(1)); |
| m_out.addIncomingToPhi(index, m_out.anchor(nextIndex)); |
| |
| m_out.branch(m_out.below(nextIndex, m_out.zeroExtPtr(length)), |
| unsure(doubleLoopStart), unsure(continuation)); |
| } |
| |
| m_out.appendTo(slowPath, continuation); |
| ValueFromBlock slowResult = m_out.anchor(vmCall(Int64, m_out.operation(operationSpreadFastArray), m_callFrame, argument)); |
| m_out.jump(continuation); |
| |
| m_out.appendTo(continuation, lastNext); |
| result = m_out.phi(Int64, fastResult, slowResult); |
| mutatorFence(); |
| } else |
| result = vmCall(Int64, m_out.operation(operationSpreadGeneric), m_callFrame, argument); |
| |
| setJSValue(result); |
| } |
| |
| void compileNewArrayBuffer() |
| { |
| JSGlobalObject* globalObject = m_graph.globalObjectFor(m_node->origin.semantic); |
| RegisteredStructure structure = m_graph.registerStructure(globalObject->arrayStructureForIndexingTypeDuringAllocation( |
| m_node->indexingType())); |
| JSFixedArray* array = m_node->castOperand<JSFixedArray*>(); |
| unsigned numElements = array->length(); |
| |
| if (!globalObject->isHavingABadTime() && !hasAnyArrayStorage(m_node->indexingType())) { |
| unsigned vectorLengthHint = m_node->vectorLengthHint(); |
| |
| ASSERT(vectorLengthHint >= numElements); |
| ArrayValues arrayValues = |
| allocateUninitializedContiguousJSArray(numElements, vectorLengthHint, structure); |
| |
| for (unsigned index = 0; index < numElements; ++index) { |
| int64_t value; |
| if (hasDouble(m_node->indexingType())) |
| value = bitwise_cast<int64_t>(array->get(index).asNumber()); |
| else |
| value = JSValue::encode(array->get(index)); |
| |
| m_out.store64( |
| m_out.constInt64(value), |
| arrayValues.butterfly, |
| m_heaps.forIndexingType(m_node->indexingType())->at(index)); |
| } |
| |
| mutatorFence(); |
| setJSValue(arrayValues.array); |
| return; |
| } |
| |
| setJSValue(vmCall( |
| Int64, m_out.operation(operationNewArrayBuffer), m_callFrame, |
| weakStructure(structure), m_out.weakPointer(m_node->cellOperand()), |
| m_out.constIntPtr(numElements))); |
| } |
| |
| void compileNewArrayWithSize() |
| { |
| LValue publicLength = lowInt32(m_node->child1()); |
| |
| JSGlobalObject* globalObject = m_graph.globalObjectFor(m_node->origin.semantic); |
| RegisteredStructure structure = m_graph.registerStructure(globalObject->arrayStructureForIndexingTypeDuringAllocation( |
| m_node->indexingType())); |
| |
| if (!globalObject->isHavingABadTime() && !hasAnyArrayStorage(m_node->indexingType())) { |
| IndexingType indexingType = m_node->indexingType(); |
| setJSValue( |
| allocateJSArray( |
| publicLength, publicLength, weakPointer(globalObject->arrayStructureForIndexingTypeDuringAllocation(indexingType)), m_out.constInt32(indexingType)).array); |
| mutatorFence(); |
| return; |
| } |
| |
| LValue structureValue = m_out.select( |
| m_out.aboveOrEqual(publicLength, m_out.constInt32(MIN_ARRAY_STORAGE_CONSTRUCTION_LENGTH)), |
| weakStructure(m_graph.registerStructure(globalObject->arrayStructureForIndexingTypeDuringAllocation(ArrayWithArrayStorage))), |
| weakStructure(structure)); |
| setJSValue(vmCall(Int64, m_out.operation(operationNewArrayWithSize), m_callFrame, structureValue, publicLength, m_out.intPtrZero)); |
| } |
| |
| void compileNewTypedArray() |
| { |
| TypedArrayType typedArrayType = m_node->typedArrayType(); |
| JSGlobalObject* globalObject = m_graph.globalObjectFor(m_node->origin.semantic); |
| |
| switch (m_node->child1().useKind()) { |
| case Int32Use: { |
| RegisteredStructure structure = m_graph.registerStructure(globalObject->typedArrayStructureConcurrently(typedArrayType)); |
| |
| LValue size = lowInt32(m_node->child1()); |
| |
| LBasicBlock smallEnoughCase = m_out.newBlock(); |
| LBasicBlock nonZeroCase = m_out.newBlock(); |
| LBasicBlock slowCase = m_out.newBlock(); |
| LBasicBlock continuation = m_out.newBlock(); |
| |
| ValueFromBlock noStorage = m_out.anchor(m_out.intPtrZero); |
| |
| m_out.branch( |
| m_out.above(size, m_out.constInt32(JSArrayBufferView::fastSizeLimit)), |
| rarely(slowCase), usually(smallEnoughCase)); |
| |
| LBasicBlock lastNext = m_out.appendTo(smallEnoughCase, nonZeroCase); |
| |
| m_out.branch(m_out.notZero32(size), usually(nonZeroCase), rarely(slowCase)); |
| |
| m_out.appendTo(nonZeroCase, slowCase); |
| |
| LValue byteSize = |
| m_out.shl(m_out.zeroExtPtr(size), m_out.constInt32(logElementSize(typedArrayType))); |
| if (elementSize(typedArrayType) < 8) { |
| byteSize = m_out.bitAnd( |
| m_out.add(byteSize, m_out.constIntPtr(7)), |
| m_out.constIntPtr(~static_cast<intptr_t>(7))); |
| } |
| |
| LValue allocator = allocatorForSize(vm().primitiveGigacageAuxiliarySpace, byteSize, slowCase); |
| LValue storage = allocateHeapCell(allocator, slowCase); |
| |
| splatWords( |
| storage, |
| m_out.int32Zero, |
| m_out.castToInt32(m_out.lShr(byteSize, m_out.constIntPtr(3))), |
| m_out.int64Zero, |
| m_heaps.typedArrayProperties); |
| |
| ValueFromBlock haveStorage = m_out.anchor(storage); |
| |
| LValue fastResultValue = |
| allocateObject<JSArrayBufferView>(structure, m_out.intPtrZero, slowCase); |
| |
| m_out.storePtr(storage, fastResultValue, m_heaps.JSArrayBufferView_vector); |
| m_out.store32(size, fastResultValue, m_heaps.JSArrayBufferView_length); |
| m_out.store32(m_out.constInt32(FastTypedArray), fastResultValue, m_heaps.JSArrayBufferView_mode); |
| |
| mutatorFence(); |
| ValueFromBlock fastResult = m_out.anchor(fastResultValue); |
| m_out.jump(continuation); |
| |
| m_out.appendTo(slowCase, continuation); |
| LValue storageValue = m_out.phi(pointerType(), noStorage, haveStorage); |
| |
| VM& vm = this->vm(); |
| LValue slowResultValue = lazySlowPath( |
| [=, &vm] (const Vector<Location>& locations) -> RefPtr<LazySlowPath::Generator> { |
| return createLazyCallGenerator(vm, |
| operationNewTypedArrayWithSizeForType(typedArrayType), locations[0].directGPR(), |
| CCallHelpers::TrustedImmPtr(structure.get()), locations[1].directGPR(), |
| locations[2].directGPR()); |
| }, |
| size, storageValue); |
| ValueFromBlock slowResult = m_out.anchor(slowResultValue); |
| m_out.jump(continuation); |
| |
| m_out.appendTo(continuation, lastNext); |
| setJSValue(m_out.phi(pointerType(), fastResult, slowResult)); |
| return; |
| } |
| |
| case UntypedUse: { |
| LValue argument = lowJSValue(m_node->child1()); |
| |
| LValue result = vmCall( |
| pointerType(), m_out.operation(operationNewTypedArrayWithOneArgumentForType(typedArrayType)), |
| m_callFrame, weakPointer(globalObject->typedArrayStructureConcurrently(typedArrayType)), argument); |
| |
| setJSValue(result); |
| return; |
| } |
| |
| default: |
| DFG_CRASH(m_graph, m_node, "Bad use kind"); |
| return; |
| } |
| } |
| |
| void compileAllocatePropertyStorage() |
| { |
| LValue object = lowCell(m_node->child1()); |
| setStorage(allocatePropertyStorage(object, m_node->transition()->previous.get())); |
| } |
| |
| void compileReallocatePropertyStorage() |
| { |
| Transition* transition = m_node->transition(); |
| LValue object = lowCell(m_node->child1()); |
| LValue oldStorage = lowStorage(m_node->child2()); |
| |
| setStorage( |
| reallocatePropertyStorage( |
| object, oldStorage, transition->previous.get(), transition->next.get())); |
| } |
| |
| void compileNukeStructureAndSetButterfly() |
| { |
| nukeStructureAndSetButterfly(lowStorage(m_node->child2()), lowCell(m_node->child1())); |
| } |
| |
| void compileToNumber() |
| { |
| LValue value = lowJSValue(m_node->child1()); |
| |
| if (!(abstractValue(m_node->child1()).m_type & SpecBytecodeNumber)) |
| setJSValue(vmCall(Int64, m_out.operation(operationToNumber), m_callFrame, value)); |
| else { |
| LBasicBlock notNumber = m_out.newBlock(); |
| LBasicBlock continuation = m_out.newBlock(); |
| |
| ValueFromBlock fastResult = m_out.anchor(value); |
| m_out.branch(isNumber(value, provenType(m_node->child1())), unsure(continuation), unsure(notNumber)); |
| |
| // notNumber case. |
| LBasicBlock lastNext = m_out.appendTo(notNumber, continuation); |
| // We have several attempts to remove ToNumber. But ToNumber still exists. |
| // It means that converting non-numbers to numbers by this ToNumber is not rare. |
| // Instead of the lazy slow path generator, we call the operation here. |
| ValueFromBlock slowResult = m_out.anchor(vmCall(Int64, m_out.operation(operationToNumber), m_callFrame, value)); |
| m_out.jump(continuation); |
| |
| // continuation case. |
| m_out.appendTo(continuation, lastNext); |
| setJSValue(m_out.phi(Int64, fastResult, slowResult)); |
| } |
| } |
| |
| void compileToStringOrCallStringConstructor() |
| { |
| switch (m_node->child1().useKind()) { |
| case StringObjectUse: { |
| LValue cell = lowCell(m_node->child1()); |
| speculateStringObjectForCell(m_node->child1(), cell); |
| m_interpreter.filter(m_node->child1(), SpecStringObject); |
| |
| setJSValue(m_out.loadPtr(cell, m_heaps.JSWrapperObject_internalValue)); |
| return; |
| } |
| |
| case StringOrStringObjectUse: { |
| LValue cell = lowCell(m_node->child1()); |
| LValue structureID = m_out.load32(cell, m_heaps.JSCell_structureID); |
| |
| LBasicBlock notString = m_out.newBlock(); |
| LBasicBlock continuation = m_out.newBlock(); |
| |
| ValueFromBlock simpleResult = m_out.anchor(cell); |
| m_out.branch( |
| m_out.equal(structureID, m_out.constInt32(vm().stringStructure->id())), |
| unsure(continuation), unsure(notString)); |
| |
| LBasicBlock lastNext = m_out.appendTo(notString, continuation); |
| speculateStringObjectForStructureID(m_node->child1(), structureID); |
| ValueFromBlock unboxedResult = m_out.anchor( |
| m_out.loadPtr(cell, m_heaps.JSWrapperObject_internalValue)); |
| m_out.jump(continuation); |
| |
| m_out.appendTo(continuation, lastNext); |
| setJSValue(m_out.phi(Int64, simpleResult, unboxedResult)); |
| |
| m_interpreter.filter(m_node->child1(), SpecString | SpecStringObject); |
| return; |
| } |
| |
| case CellUse: |
| case NotCellUse: |
| case UntypedUse: { |
| LValue value; |
| if (m_node->child1().useKind() == CellUse) |
| value = lowCell(m_node->child1()); |
| else if (m_node->child1().useKind() == NotCellUse) |
| value = lowNotCell(m_node->child1()); |
| else |
| value = lowJSValue(m_node->child1()); |
| |
| LBasicBlock isCell = m_out.newBlock(); |
| LBasicBlock notString = m_out.newBlock(); |
| LBasicBlock continuation = m_out.newBlock(); |
| |
| LValue isCellPredicate; |
| if (m_node->child1().useKind() == CellUse) |
| isCellPredicate = m_out.booleanTrue; |
| else if (m_node->child1().useKind() == NotCellUse) |
| isCellPredicate = m_out.booleanFalse; |
| else |
| isCellPredicate = this->isCell(value, provenType(m_node->child1())); |
| m_out.branch(isCellPredicate, unsure(isCell), unsure(notString)); |
| |
| LBasicBlock lastNext = m_out.appendTo(isCell, notString); |
| ValueFromBlock simpleResult = m_out.anchor(value); |
| LValue isStringPredicate; |
| if (m_node->child1()->prediction() & SpecString) { |
| isStringPredicate = isString(value, provenType(m_node->child1())); |
| } else |
| isStringPredicate = m_out.booleanFalse; |
| m_out.branch(isStringPredicate, unsure(continuation), unsure(notString)); |
| |
| m_out.appendTo(notString, continuation); |
| LValue operation; |
| if (m_node->child1().useKind() == CellUse) |
| operation = m_out.operation(m_node->op() == ToString ? operationToStringOnCell : operationCallStringConstructorOnCell); |
| else |
| operation = m_out.operation(m_node->op() == ToString ? operationToString : operationCallStringConstructor); |
| ValueFromBlock convertedResult = m_out.anchor(vmCall(Int64, operation, m_callFrame, value)); |
| m_out.jump(continuation); |
| |
| m_out.appendTo(continuation, lastNext); |
| setJSValue(m_out.phi(Int64, simpleResult, convertedResult)); |
| return; |
| } |
| |
| case Int32Use: |
| setJSValue(vmCall(Int64, m_out.operation(operationInt32ToStringWithValidRadix), m_callFrame, lowInt32(m_node->child1()), m_out.constInt32(10))); |
| return; |
| |
| case Int52RepUse: |
| setJSValue(vmCall(Int64, m_out.operation(operationInt52ToStringWithValidRadix), m_callFrame, lowStrictInt52(m_node->child1()), m_out.constInt32(10))); |
| return; |
| |
| case DoubleRepUse: |
| setJSValue(vmCall(Int64, m_out.operation(operationDoubleToStringWithValidRadix), m_callFrame, lowDouble(m_node->child1()), m_out.constInt32(10))); |
| return; |
| |
| default: |
| DFG_CRASH(m_graph, m_node, "Bad use kind"); |
| break; |
| } |
| } |
| |
| void compileToPrimitive() |
| { |
| LValue value = lowJSValue(m_node->child1()); |
| |
| LBasicBlock isCellCase = m_out.newBlock(); |
| LBasicBlock isObjectCase = m_out.newBlock(); |
| LBasicBlock continuation = m_out.newBlock(); |
| |
| Vector<ValueFromBlock, 3> results; |
| |
| results.append(m_out.anchor(value)); |
| m_out.branch( |
| isCell(value, provenType(m_node->child1())), unsure(isCellCase), unsure(continuation)); |
| |
| LBasicBlock lastNext = m_out.appendTo(isCellCase, isObjectCase); |
| results.append(m_out.anchor(value)); |
| m_out.branch( |
| isObject(value, provenType(m_node->child1())), |
| unsure(isObjectCase), unsure(continuation)); |
| |
| m_out.appendTo(isObjectCase, continuation); |
| results.append(m_out.anchor(vmCall( |
| Int64, m_out.operation(operationToPrimitive), m_callFrame, value))); |
| m_out.jump(continuation); |
| |
| m_out.appendTo(continuation, lastNext); |
| setJSValue(m_out.phi(Int64, results)); |
| } |
| |
| void compileMakeRope() |
| { |
| LValue kids[3]; |
| unsigned numKids; |
| kids[0] = lowCell(m_node->child1()); |
| kids[1] = lowCell(m_node->child2()); |
| if (m_node->child3()) { |
| kids[2] = lowCell(m_node->child3()); |
| numKids = 3; |
| } else { |
| kids[2] = 0; |
| numKids = 2; |
| } |
| |
| LBasicBlock slowPath = m_out.newBlock(); |
| LBasicBlock continuation = m_out.newBlock(); |
| |
| LBasicBlock lastNext = m_out.insertNewBlocksBefore(slowPath); |
| |
| Allocator allocator = subspaceFor<JSRopeString>(vm())->allocatorForNonVirtual(sizeof(JSRopeString), AllocatorForMode::AllocatorIfExists); |
| |
| LValue result = allocateCell( |
| m_out.constInt32(allocator.offset()), vm().stringStructure.get(), slowPath); |
| |
| m_out.storePtr(m_out.intPtrZero, result, m_heaps.JSString_value); |
| for (unsigned i = 0; i < numKids; ++i) |
| m_out.storePtr(kids[i], result, m_heaps.JSRopeString_fibers[i]); |
| for (unsigned i = numKids; i < JSRopeString::s_maxInternalRopeLength; ++i) |
| m_out.storePtr(m_out.intPtrZero, result, m_heaps.JSRopeString_fibers[i]); |
| LValue flags = m_out.load16ZeroExt32(kids[0], m_heaps.JSString_flags); |
| LValue length = m_out.load32(kids[0], m_heaps.JSString_length); |
| for (unsigned i = 1; i < numKids; ++i) { |
| flags = m_out.bitAnd(flags, m_out.load16ZeroExt32(kids[i], m_heaps.JSString_flags)); |
| CheckValue* lengthCheck = m_out.speculateAdd( |
| length, m_out.load32(kids[i], m_heaps.JSString_length)); |
| blessSpeculation(lengthCheck, Uncountable, noValue(), nullptr, m_origin); |
| length = lengthCheck; |
| } |
| m_out.store32As16( |
| m_out.bitAnd(m_out.constInt32(JSString::Is8Bit), flags), |
| result, m_heaps.JSString_flags); |
| m_out.store32(length, result, m_heaps.JSString_length); |
| |
| mutatorFence(); |
| ValueFromBlock fastResult = m_out.anchor(result); |
| m_out.jump(continuation); |
| |
| m_out.appendTo(slowPath, continuation); |
| LValue slowResultValue; |
| VM& vm = this->vm(); |
| switch (numKids) { |
| case 2: |
| slowResultValue = lazySlowPath( |
| [=, &vm] (const Vector<Location>& locations) -> RefPtr<LazySlowPath::Generator> { |
| return createLazyCallGenerator(vm, |
| operationMakeRope2, locations[0].directGPR(), locations[1].directGPR(), |
| locations[2].directGPR()); |
| }, kids[0], kids[1]); |
| break; |
| case 3: |
| slowResultValue = lazySlowPath( |
| [=, &vm] (const Vector<Location>& locations) -> RefPtr<LazySlowPath::Generator> { |
| return createLazyCallGenerator(vm, |
| operationMakeRope3, locations[0].directGPR(), locations[1].directGPR(), |
| locations[2].directGPR(), locations[3].directGPR()); |
| }, kids[0], kids[1], kids[2]); |
| break; |
| default: |
| DFG_CRASH(m_graph, m_node, "Bad number of children"); |
| break; |
| } |
| ValueFromBlock slowResult = m_out.anchor(slowResultValue); |
| m_out.jump(continuation); |
| |
| m_out.appendTo(continuation, lastNext); |
| setJSValue(m_out.phi(Int64, fastResult, slowResult)); |
| } |
| |
| void compileStringCharAt() |
| { |
| LValue base = lowCell(m_graph.child(m_node, 0)); |
| LValue index = lowInt32(m_graph.child(m_node, 1)); |
| LValue storage = lowStorage(m_graph.child(m_node, 2)); |
| |
| LBasicBlock fastPath = m_out.newBlock(); |
| LBasicBlock slowPath = m_out.newBlock(); |
| LBasicBlock continuation = m_out.newBlock(); |
| |
| m_out.branch( |
| m_out.aboveOrEqual( |
| index, m_out.load32NonNegative(base, m_heaps.JSString_length)), |
| rarely(slowPath), usually(fastPath)); |
| |
| LBasicBlock lastNext = m_out.appendTo(fastPath, slowPath); |
| |
| LValue stringImpl = m_out.loadPtr(base, m_heaps.JSString_value); |
| |
| LBasicBlock is8Bit = m_out.newBlock(); |
| LBasicBlock is16Bit = m_out.newBlock(); |
| LBasicBlock bitsContinuation = m_out.newBlock(); |
| LBasicBlock bigCharacter = m_out.newBlock(); |
| |
| m_out.branch( |
| m_out.testIsZero32( |
| m_out.load32(stringImpl, m_heaps.StringImpl_hashAndFlags), |
| m_out.constInt32(StringImpl::flagIs8Bit())), |
| unsure(is16Bit), unsure(is8Bit)); |
| |
| m_out.appendTo(is8Bit, is16Bit); |
| |
| // FIXME: Need to cage strings! |
| // https://bugs.webkit.org/show_bug.cgi?id=174924 |
| ValueFromBlock char8Bit = m_out.anchor( |
| m_out.load8ZeroExt32(m_out.baseIndex( |
| m_heaps.characters8, storage, m_out.zeroExtPtr(index), |
| provenValue(m_graph.child(m_node, 1))))); |
| m_out.jump(bitsContinuation); |
| |
| m_out.appendTo(is16Bit, bigCharacter); |
| |
| LValue char16BitValue = m_out.load16ZeroExt32( |
| m_out.baseIndex( |
| m_heaps.characters16, storage, m_out.zeroExtPtr(index), |
| provenValue(m_graph.child(m_node, 1)))); |
| ValueFromBlock char16Bit = m_out.anchor(char16BitValue); |
| m_out.branch( |
| m_out.aboveOrEqual(char16BitValue, m_out.constInt32(0x100)), |
| rarely(bigCharacter), usually(bitsContinuation)); |
| |
| m_out.appendTo(bigCharacter, bitsContinuation); |
| |
| Vector<ValueFromBlock, 4> results; |
| results.append(m_out.anchor(vmCall( |
| Int64, m_out.operation(operationSingleCharacterString), |
| m_callFrame, char16BitValue))); |
| m_out.jump(continuation); |
| |
| m_out.appendTo(bitsContinuation, slowPath); |
| |
| LValue character = m_out.phi(Int32, char8Bit, char16Bit); |
| |
| LValue smallStrings = m_out.constIntPtr(vm().smallStrings.singleCharacterStrings()); |
| |
| results.append(m_out.anchor(m_out.loadPtr(m_out.baseIndex( |
| m_heaps.singleCharacterStrings, smallStrings, m_out.zeroExtPtr(character))))); |
| m_out.jump(continuation); |
| |
| m_out.appendTo(slowPath, continuation); |
| |
| if (m_node->arrayMode().isInBounds()) { |
| speculate(OutOfBounds, noValue(), 0, m_out.booleanTrue); |
| results.append(m_out.anchor(m_out.intPtrZero)); |
| } else { |
| JSGlobalObject* globalObject = m_graph.globalObjectFor(m_node->origin.semantic); |
| |
| bool prototypeChainIsSane = false; |
| if (globalObject->stringPrototypeChainIsSane()) { |
| // FIXME: This could be captured using a Speculation mode that means |
| // "out-of-bounds loads return a trivial value", something like |
| // SaneChainOutOfBounds. |
| // https://bugs.webkit.org/show_bug.cgi?id=144668 |
| |
| m_graph.registerAndWatchStructureTransition(globalObject->stringPrototype()->structure()); |
| m_graph.registerAndWatchStructureTransition(globalObject->objectPrototype()->structure()); |
| |
| prototypeChainIsSane = globalObject->stringPrototypeChainIsSane(); |
| } |
| if (prototypeChainIsSane) { |
| LBasicBlock negativeIndex = m_out.newBlock(); |
| |
| results.append(m_out.anchor(m_out.constInt64(JSValue::encode(jsUndefined())))); |
| m_out.branch( |
| m_out.lessThan(index, m_out.int32Zero), |
| rarely(negativeIndex), usually(continuation)); |
| |
| m_out.appendTo(negativeIndex, continuation); |
| } |
| |
| results.append(m_out.anchor(vmCall( |
| Int64, m_out.operation(operationGetByValStringInt), m_callFrame, base, index))); |
| } |
| |
| m_out.jump(continuation); |
| |
| m_out.appendTo(continuation, lastNext); |
| setJSValue(m_out.phi(Int64, results)); |
| } |
| |
| void compileStringCharCodeAt() |
| { |
| LBasicBlock is8Bit = m_out.newBlock(); |
| LBasicBlock is16Bit = m_out.newBlock(); |
| LBasicBlock continuation = m_out.newBlock(); |
| |
| LValue base = lowCell(m_node->child1()); |
| LValue index = lowInt32(m_node->child2()); |
| LValue storage = lowStorage(m_node->child3()); |
| |
| speculate( |
| Uncountable, noValue(), 0, |
| m_out.aboveOrEqual( |
| index, m_out.load32NonNegative(base, m_heaps.JSString_length))); |
| |
| LValue stringImpl = m_out.loadPtr(base, m_heaps.JSString_value); |
| |
| m_out.branch( |
| m_out.testIsZero32( |
| m_out.load32(stringImpl, m_heaps.StringImpl_hashAndFlags), |
| m_out.constInt32(StringImpl::flagIs8Bit())), |
| unsure(is16Bit), unsure(is8Bit)); |
| |
| LBasicBlock lastNext = m_out.appendTo(is8Bit, is16Bit); |
| |
| // FIXME: need to cage strings! |
| // https://bugs.webkit.org/show_bug.cgi?id=174924 |
| ValueFromBlock char8Bit = m_out.anchor( |
| m_out.load8ZeroExt32(m_out.baseIndex( |
| m_heaps.characters8, storage, m_out.zeroExtPtr(index), |
| provenValue(m_node->child2())))); |
| m_out.jump(continuation); |
| |
| m_out.appendTo(is16Bit, continuation); |
| |
| ValueFromBlock char16Bit = m_out.anchor( |
| m_out.load16ZeroExt32(m_out.baseIndex( |
| m_heaps.characters16, storage, m_out.zeroExtPtr(index), |
| provenValue(m_node->child2())))); |
| m_out.jump(continuation); |
| |
| m_out.appendTo(continuation, lastNext); |
| |
| setInt32(m_out.phi(Int32, char8Bit, char16Bit)); |
| } |
| |
| void compileStringFromCharCode() |
| { |
| Edge childEdge = m_node->child1(); |
| |
| if (childEdge.useKind() == UntypedUse) { |
| LValue result = vmCall( |
| Int64, m_out.operation(operationStringFromCharCodeUntyped), m_callFrame, |
| lowJSValue(childEdge)); |
| setJSValue(result); |
| return; |
| } |
| |
| DFG_ASSERT(m_graph, m_node, childEdge.useKind() == Int32Use, childEdge.useKind()); |
| |
| LValue value = lowInt32(childEdge); |
| |
| LBasicBlock smallIntCase = m_out.newBlock(); |
| LBasicBlock slowCase = m_out.newBlock(); |
| LBasicBlock continuation = m_out.newBlock(); |
| |
| m_out.branch( |
| m_out.aboveOrEqual(value, m_out.constInt32(0xff)), |
| rarely(slowCase), usually(smallIntCase)); |
| |
| LBasicBlock lastNext = m_out.appendTo(smallIntCase, slowCase); |
| |
| LValue smallStrings = m_out.constIntPtr(vm().smallStrings.singleCharacterStrings()); |
| LValue fastResultValue = m_out.loadPtr( |
| m_out.baseIndex(m_heaps.singleCharacterStrings, smallStrings, m_out.zeroExtPtr(value))); |
| ValueFromBlock fastResult = m_out.anchor(fastResultValue); |
| m_out.jump(continuation); |
| |
| m_out.appendTo(slowCase, continuation); |
| |
| LValue slowResultValue = vmCall( |
| pointerType(), m_out.operation(operationStringFromCharCode), m_callFrame, value); |
| ValueFromBlock slowResult = m_out.anchor(slowResultValue); |
| m_out.jump(continuation); |
| |
| m_out.appendTo(continuation, lastNext); |
| |
| setJSValue(m_out.phi(Int64, fastResult, slowResult)); |
| } |
| |
| void compileGetByOffset() |
| { |
| StorageAccessData& data = m_node->storageAccessData(); |
| |
| setJSValue(loadProperty( |
| lowStorage(m_node->child1()), data.identifierNumber, data.offset)); |
| } |
| |
| void compileGetGetter() |
| { |
| setJSValue(m_out.loadPtr(lowCell(m_node->child1()), m_heaps.GetterSetter_getter)); |
| } |
| |
| void compileGetSetter() |
| { |
| setJSValue(m_out.loadPtr(lowCell(m_node->child1()), m_heaps.GetterSetter_setter)); |
| } |
| |
| void compileMultiGetByOffset() |
| { |
| LValue base = lowCell(m_node->child1()); |
| |
| MultiGetByOffsetData& data = m_node->multiGetByOffsetData(); |
| |
| Vector<LBasicBlock, 2> blocks(data.cases.size()); |
| for (unsigned i = data.cases.size(); i--;) |
| blocks[i] = m_out.newBlock(); |
| LBasicBlock exit = m_out.newBlock(); |
| LBasicBlock continuation = m_out.newBlock(); |
| |
| Vector<SwitchCase, 2> cases; |
| RegisteredStructureSet baseSet; |
| for (unsigned i = data.cases.size(); i--;) { |
| MultiGetByOffsetCase getCase = data.cases[i]; |
| for (unsigned j = getCase.set().size(); j--;) { |
| RegisteredStructure structure = getCase.set()[j]; |
| baseSet.add(structure); |
| cases.append(SwitchCase(weakStructureID(structure), blocks[i], Weight(1))); |
| } |
| } |
| bool structuresChecked = m_interpreter.forNode(m_node->child1()).m_structure.isSubsetOf(baseSet); |
| emitSwitchForMultiByOffset(base, structuresChecked, cases, exit); |
| |
| LBasicBlock lastNext = m_out.m_nextBlock; |
| |
| Vector<ValueFromBlock, 2> results; |
| for (unsigned i = data.cases.size(); i--;) { |
| MultiGetByOffsetCase getCase = data.cases[i]; |
| GetByOffsetMethod method = getCase.method(); |
| |
| m_out.appendTo(blocks[i], i + 1 < data.cases.size() ? blocks[i + 1] : exit); |
| |
| LValue result; |
| |
| switch (method.kind()) { |
| case GetByOffsetMethod::Invalid: |
| RELEASE_ASSERT_NOT_REACHED(); |
| break; |
| |
| case GetByOffsetMethod::Constant: |
| result = m_out.constInt64(JSValue::encode(method.constant()->value())); |
| break; |
| |
| case GetByOffsetMethod::Load: |
| case GetByOffsetMethod::LoadFromPrototype: { |
| LValue propertyBase; |
| if (method.kind() == GetByOffsetMethod::Load) |
| propertyBase = base; |
| else |
| propertyBase = weakPointer(method.prototype()->value().asCell()); |
| if (!isInlineOffset(method.offset())) |
| propertyBase = m_out.loadPtr(propertyBase, m_heaps.JSObject_butterfly); |
| result = loadProperty( |
| propertyBase, data.identifierNumber, method.offset()); |
| break; |
| } } |
| |
| results.append(m_out.anchor(result)); |
| m_out.jump(continuation); |
| } |
| |
| m_out.appendTo(exit, continuation); |
| if (!structuresChecked) |
| speculate(BadCache, noValue(), nullptr, m_out.booleanTrue); |
| m_out.unreachable(); |
| |
| m_out.appendTo(continuation, lastNext); |
| setJSValue(m_out.phi(Int64, results)); |
| } |
| |
| void compilePutByOffset() |
| { |
| StorageAccessData& data = m_node->storageAccessData(); |
| |
| storeProperty( |
| lowJSValue(m_node->child3()), |
| lowStorage(m_node->child1()), data.identifierNumber, data.offset); |
| } |
| |
| void compileMultiPutByOffset() |
| { |
| LValue base = lowCell(m_node->child1()); |
| LValue value = lowJSValue(m_node->child2()); |
| |
| MultiPutByOffsetData& data = m_node->multiPutByOffsetData(); |
| |
| Vector<LBasicBlock, 2> blocks(data.variants.size()); |
| for (unsigned i = data.variants.size(); i--;) |
| blocks[i] = m_out.newBlock(); |
| LBasicBlock exit = m_out.newBlock(); |
| LBasicBlock continuation = m_out.newBlock(); |
| |
| Vector<SwitchCase, 2> cases; |
| RegisteredStructureSet baseSet; |
| for (unsigned i = data.variants.size(); i--;) { |
| PutByIdVariant variant = data.variants[i]; |
| for (unsigned j = variant.oldStructure().size(); j--;) { |
| RegisteredStructure structure = m_graph.registerStructure(variant.oldStructure()[j]); |
| baseSet.add(structure); |
| cases.append(SwitchCase(weakStructureID(structure), blocks[i], Weight(1))); |
| } |
| } |
| bool structuresChecked = m_interpreter.forNode(m_node->child1()).m_structure.isSubsetOf(baseSet); |
| emitSwitchForMultiByOffset(base, structuresChecked, cases, exit); |
| |
| LBasicBlock lastNext = m_out.m_nextBlock; |
| |
| for (unsigned i = data.variants.size(); i--;) { |
| m_out.appendTo(blocks[i], i + 1 < data.variants.size() ? blocks[i + 1] : exit); |
| |
| PutByIdVariant variant = data.variants[i]; |
| |
| checkInferredType(m_node->child2(), value, variant.requiredType()); |
| |
| LValue storage; |
| if (variant.kind() == PutByIdVariant::Replace) { |
| if (isInlineOffset(variant.offset())) |
| storage = base; |
| else |
| storage = m_out.loadPtr(base, m_heaps.JSObject_butterfly); |
| } else { |
| DFG_ASSERT(m_graph, m_node, variant.kind() == PutByIdVariant::Transition, variant.kind()); |
| m_graph.m_plan.transitions.addLazily( |
| codeBlock(), m_node->origin.semantic.codeOriginOwner(), |
| variant.oldStructureForTransition(), variant.newStructure()); |
| |
| storage = storageForTransition( |
| base, variant.offset(), |
| variant.oldStructureForTransition(), variant.newStructure()); |
| } |
| |
| storeProperty(value, storage, data.identifierNumber, variant.offset()); |
| |
| if (variant.kind() == PutByIdVariant::Transition) { |
| ASSERT(variant.oldStructureForTransition()->indexingType() == variant.newStructure()->indexingType()); |
| ASSERT(variant.oldStructureForTransition()->typeInfo().inlineTypeFlags() == variant.newStructure()->typeInfo().inlineTypeFlags()); |
| ASSERT(variant.oldStructureForTransition()->typeInfo().type() == variant.newStructure()->typeInfo().type()); |
| m_out.store32( |
| weakStructureID(m_graph.registerStructure(variant.newStructure())), base, m_heaps.JSCell_structureID); |
| } |
| |
| m_out.jump(continuation); |
| } |
| |
| m_out.appendTo(exit, continuation); |
| if (!structuresChecked) |
| speculate(BadCache, noValue(), nullptr, m_out.booleanTrue); |
| m_out.unreachable(); |
| |
| m_out.appendTo(continuation, lastNext); |
| } |
| |
| void compileGetGlobalVariable() |
| { |
| setJSValue(m_out.load64(m_out.absolute(m_node->variablePointer()))); |
| } |
| |
| void compilePutGlobalVariable() |
| { |
| m_out.store64( |
| lowJSValue(m_node->child2()), m_out.absolute(m_node->variablePointer())); |
| } |
| |
| void compileNotifyWrite() |
| { |
| WatchpointSet* set = m_node->watchpointSet(); |
| |
| LBasicBlock isNotInvalidated = m_out.newBlock(); |
| LBasicBlock continuation = m_out.newBlock(); |
| |
| LValue state = m_out.load8ZeroExt32(m_out.absolute(set->addressOfState())); |
| m_out.branch( |
| m_out.equal(state, m_out.constInt32(IsInvalidated)), |
| usually(continuation), rarely(isNotInvalidated)); |
| |
| LBasicBlock lastNext = m_out.appendTo(isNotInvalidated, continuation); |
| |
| VM& vm = this->vm(); |
| lazySlowPath( |
| [=, &vm] (const Vector<Location>&) -> RefPtr<LazySlowPath::Generator> { |
| return createLazyCallGenerator(vm, |
| operationNotifyWrite, InvalidGPRReg, CCallHelpers::TrustedImmPtr(set)); |
| }); |
| m_out.jump(continuation); |
| |
| m_out.appendTo(continuation, lastNext); |
| } |
| |
| void compileGetCallee() |
| { |
| setJSValue(m_out.loadPtr(addressFor(CallFrameSlot::callee))); |
| } |
| |
| void compileGetArgumentCountIncludingThis() |
| { |
| VirtualRegister argumentCountRegister; |
| if (InlineCallFrame* inlineCallFrame = m_node->argumentsInlineCallFrame()) |
| argumentCountRegister = inlineCallFrame->argumentCountRegister; |
| else |
| argumentCountRegister = VirtualRegister(CallFrameSlot::argumentCount); |
| setInt32(m_out.load32(payloadFor(argumentCountRegister))); |
| } |
| |
| void compileSetArgumentCountIncludingThis() |
| { |
| m_out.store32(m_out.constInt32(m_node->argumentCountIncludingThis()), payloadFor(CallFrameSlot::argumentCount)); |
| } |
| |
| void compileGetScope() |
| { |
| setJSValue(m_out.loadPtr(lowCell(m_node->child1()), m_heaps.JSFunction_scope)); |
| } |
| |
| void compileSkipScope() |
| { |
| setJSValue(m_out.loadPtr(lowCell(m_node->child1()), m_heaps.JSScope_next)); |
| } |
| |
| void compileGetGlobalObject() |
| { |
| LValue structure = loadStructure(lowCell(m_node->child1())); |
| setJSValue(m_out.loadPtr(structure, m_heaps.Structure_globalObject)); |
| } |
| |
| void compileGetGlobalThis() |
| { |
| auto* globalObject = m_graph.globalObjectFor(m_node->origin.semantic); |
| setJSValue(m_out.loadPtr(m_out.absolute(globalObject->addressOfGlobalThis()))); |
| } |
| |
| void compileGetClosureVar() |
| { |
| setJSValue( |
| m_out.load64( |
| lowCell(m_node->child1()), |
| m_heaps.JSLexicalEnvironment_variables[m_node->scopeOffset().offset()])); |
| } |
| |
| void compilePutClosureVar() |
| { |
| m_out.store64( |
| lowJSValue(m_node->child2()), |
| lowCell(m_node->child1()), |
| m_heaps.JSLexicalEnvironment_variables[m_node->scopeOffset().offset()]); |
| } |
| |
| void compileGetFromArguments() |
| { |
| setJSValue( |
| m_out.load64( |
| lowCell(m_node->child1()), |
| m_heaps.DirectArguments_storage[m_node->capturedArgumentsOffset().offset()])); |
| } |
| |
| void compilePutToArguments() |
| { |
| m_out.store64( |
| lowJSValue(m_node->child2()), |
| lowCell(m_node->child1()), |
| m_heaps.DirectArguments_storage[m_node->capturedArgumentsOffset().offset()]); |
| } |
| |
| void compileGetArgument() |
| { |
| LValue argumentCount = m_out.load32(payloadFor(AssemblyHelpers::argumentCount(m_node->origin.semantic))); |
| |
| LBasicBlock inBounds = m_out.newBlock(); |
| LBasicBlock outOfBounds = m_out.newBlock(); |
| LBasicBlock continuation = m_out.newBlock(); |
| |
| m_out.branch(m_out.lessThanOrEqual(argumentCount, m_out.constInt32(m_node->argumentIndex())), unsure(outOfBounds), unsure(inBounds)); |
| |
| LBasicBlock lastNext = m_out.appendTo(inBounds, outOfBounds); |
| VirtualRegister arg = AssemblyHelpers::argumentsStart(m_node->origin.semantic) + m_node->argumentIndex() - 1; |
| ValueFromBlock inBoundsResult = m_out.anchor(m_out.load64(addressFor(arg))); |
| m_out.jump(continuation); |
| |
| m_out.appendTo(outOfBounds, continuation); |
| ValueFromBlock outOfBoundsResult = m_out.anchor(m_out.constInt64(ValueUndefined)); |
| m_out.jump(continuation); |
| |
| m_out.appendTo(continuation, lastNext); |
| setJSValue(m_out.phi(Int64, inBoundsResult, outOfBoundsResult)); |
| } |
| |
| void compileCompareEq() |
| { |
| if (m_node->isBinaryUseKind(Int32Use) |
| || m_node->isBinaryUseKind(Int52RepUse) |
| || m_node->isBinaryUseKind(DoubleRepUse) |
| || m_node->isBinaryUseKind(ObjectUse) |
| || m_node->isBinaryUseKind(BooleanUse) |
| || m_node->isBinaryUseKind(SymbolUse) |
| || m_node->isBinaryUseKind(StringIdentUse) |
| || m_node->isBinaryUseKind(StringUse)) { |
| compileCompareStrictEq(); |
| return; |
| } |
| |
| if (m_node->isBinaryUseKind(ObjectUse, ObjectOrOtherUse)) { |
| compareEqObjectOrOtherToObject(m_node->child2(), m_node->child1()); |
| return; |
| } |
| |
| if (m_node->isBinaryUseKind(ObjectOrOtherUse, ObjectUse)) { |
| compareEqObjectOrOtherToObject(m_node->child1(), m_node->child2()); |
| return; |
| } |
| |
| if (m_node->child1().useKind() == OtherUse) { |
| ASSERT(!m_interpreter.needsTypeCheck(m_node->child1(), SpecOther)); |
| setBoolean(equalNullOrUndefined(m_node->child2(), AllCellsAreFalse, EqualNullOrUndefined, ManualOperandSpeculation)); |
| return; |
| } |
| |
| if (m_node->child2().useKind() == OtherUse) { |
| ASSERT(!m_interpreter.needsTypeCheck(m_node->child2(), SpecOther)); |
| setBoolean(equalNullOrUndefined(m_node->child1(), AllCellsAreFalse, EqualNullOrUndefined, ManualOperandSpeculation)); |
| return; |
| } |
| |
| DFG_ASSERT(m_graph, m_node, m_node->isBinaryUseKind(UntypedUse), m_node->child1().useKind(), m_node->child2().useKind()); |
| nonSpeculativeCompare( |
| [&] (LValue left, LValue right) { |
| return m_out.equal(left, right); |
| }, |
| operationCompareEq); |
| } |
| |
| void compileCompareStrictEq() |
| { |
| if (m_node->isBinaryUseKind(Int32Use)) { |
| setBoolean( |
| m_out.equal(lowInt32(m_node->child1()), lowInt32(m_node->child2()))); |
| return; |
| } |
| |
| if (m_node->isBinaryUseKind(Int52RepUse)) { |
| Int52Kind kind; |
| LValue left = lowWhicheverInt52(m_node->child1(), kind); |
| LValue right = lowInt52(m_node->child2(), kind); |
| setBoolean(m_out.equal(left, right)); |
| return; |
| } |
| |
| if (m_node->isBinaryUseKind(DoubleRepUse)) { |
| setBoolean( |
| m_out.doubleEqual(lowDouble(m_node->child1()), lowDouble(m_node->child2()))); |
| return; |
| } |
| |
| if (m_node->isBinaryUseKind(StringIdentUse)) { |
| setBoolean( |
| m_out.equal(lowStringIdent(m_node->child1()), lowStringIdent(m_node->child2()))); |
| return; |
| } |
| |
| if (m_node->isBinaryUseKind(StringUse)) { |
| LValue left = lowCell(m_node->child1()); |
| LValue right = lowCell(m_node->child2()); |
| |
| LBasicBlock notTriviallyEqualCase = m_out.newBlock(); |
| LBasicBlock continuation = m_out.newBlock(); |
| |
| speculateString(m_node->child1(), left); |
| |
| ValueFromBlock fastResult = m_out.anchor(m_out.booleanTrue); |
| m_out.branch( |
| m_out.equal(left, right), unsure(continuation), unsure(notTriviallyEqualCase)); |
| |
| LBasicBlock lastNext = m_out.appendTo(notTriviallyEqualCase, continuation); |
| |
| speculateString(m_node->child2(), right); |
| |
| ValueFromBlock slowResult = m_out.anchor(stringsEqual(left, right)); |
| m_out.jump(continuation); |
| |
| m_out.appendTo(continuation, lastNext); |
| setBoolean(m_out.phi(Int32, fastResult, slowResult)); |
| return; |
| } |
| |
| if (m_node->isBinaryUseKind(ObjectUse, UntypedUse)) { |
| setBoolean( |
| m_out.equal( |
| lowNonNullObject(m_node->child1()), |
| lowJSValue(m_node->child2()))); |
| return; |
| } |
| |
| if (m_node->isBinaryUseKind(UntypedUse, ObjectUse)) { |
| setBoolean( |
| m_out.equal( |
| lowNonNullObject(m_node->child2()), |
| lowJSValue(m_node->child1()))); |
| return; |
| } |
| |
| if (m_node->isBinaryUseKind(ObjectUse)) { |
| setBoolean( |
| m_out.equal( |
| lowNonNullObject(m_node->child1()), |
| lowNonNullObject(m_node->child2()))); |
| return; |
| } |
| |
| if (m_node->isBinaryUseKind(BooleanUse)) { |
| setBoolean( |
| m_out.equal(lowBoolean(m_node->child1()), lowBoolean(m_node->child2()))); |
| return; |
| } |
| |
| if (m_node->isBinaryUseKind(SymbolUse)) { |
| LValue leftSymbol = lowSymbol(m_node->child1()); |
| LValue rightSymbol = lowSymbol(m_node->child2()); |
| setBoolean(m_out.equal(leftSymbol, rightSymbol)); |
| return; |
| } |
| |
| if (m_node->isBinaryUseKind(BigIntUse)) { |
| // FIXME: [ESNext][BigInt] Create specialized version of strict equals for BigIntUse |
| // https://bugs.webkit.org/show_bug.cgi?id=182895 |
| LValue left = lowBigInt(m_node->child1()); |
| LValue right = lowBigInt(m_node->child2()); |
| |
| LBasicBlock notTriviallyEqualCase = m_out.newBlock(); |
| LBasicBlock continuation = m_out.newBlock(); |
| |
| ValueFromBlock fastResult = m_out.anchor(m_out.booleanTrue); |
| m_out.branch(m_out.equal(left, right), rarely(continuation), usually(notTriviallyEqualCase)); |
| |
| LBasicBlock lastNext = m_out.appendTo(notTriviallyEqualCase, continuation); |
| |
| ValueFromBlock slowResult = m_out.anchor(m_out.notNull(vmCall( |
| pointerType(), m_out.operation(operationCompareStrictEq), m_callFrame, left, right))); |
| m_out.jump(continuation); |
| |
| m_out.appendTo(continuation, lastNext); |
| setBoolean(m_out.phi(Int32, fastResult, slowResult)); |
| return; |
| } |
| |
| if (m_node->isBinaryUseKind(SymbolUse, UntypedUse) |
| || m_node->isBinaryUseKind(UntypedUse, SymbolUse)) { |
| Edge symbolEdge = m_node->child1(); |
| Edge untypedEdge = m_node->child2(); |
| if (symbolEdge.useKind() != SymbolUse) |
| std::swap(symbolEdge, untypedEdge); |
| |
| LValue leftSymbol = lowSymbol(symbolEdge); |
| LValue untypedValue = lowJSValue(untypedEdge); |
| |
| setBoolean(m_out.equal(leftSymbol, untypedValue)); |
| return; |
| } |
| |
| if (m_node->isBinaryUseKind(MiscUse, UntypedUse) |
| || m_node->isBinaryUseKind(UntypedUse, MiscUse)) { |
| speculate(m_node->child1()); |
| speculate(m_node->child2()); |
| LValue left = lowJSValue(m_node->child1(), ManualOperandSpeculation); |
| LValue right = lowJSValue(m_node->child2(), ManualOperandSpeculation); |
| setBoolean(m_out.equal(left, right)); |
| return; |
| } |
| |
| if (m_node->isBinaryUseKind(StringIdentUse, NotStringVarUse) |
| || m_node->isBinaryUseKind(NotStringVarUse, StringIdentUse)) { |
| Edge leftEdge = m_node->childFor(StringIdentUse); |
| Edge rightEdge = m_node->childFor(NotStringVarUse); |
| |
| LValue left = lowStringIdent(leftEdge); |
| LValue rightValue = lowJSValue(rightEdge, ManualOperandSpeculation); |
| |
| LBasicBlock isCellCase = m_out.newBlock(); |
| LBasicBlock isStringCase = m_out.newBlock(); |
| LBasicBlock continuation = m_out.newBlock(); |
| |
| ValueFromBlock notCellResult = m_out.anchor(m_out.booleanFalse); |
| m_out.branch( |
| isCell(rightValue, provenType(rightEdge)), |
| unsure(isCellCase), unsure(continuation)); |
| |
| LBasicBlock lastNext = m_out.appendTo(isCellCase, isStringCase); |
| ValueFromBlock notStringResult = m_out.anchor(m_out.booleanFalse); |
| m_out.branch( |
| isString(rightValue, provenType(rightEdge)), |
| unsure(isStringCase), unsure(continuation)); |
| |
| m_out.appendTo(isStringCase, continuation); |
| LValue right = m_out.loadPtr(rightValue, m_heaps.JSString_value); |
| speculateStringIdent(rightEdge, rightValue, right); |
| ValueFromBlock isStringResult = m_out.anchor(m_out.equal(left, right)); |
| m_out.jump(continuation); |
| |
| m_out.appendTo(continuation, lastNext); |
| setBoolean(m_out.phi(Int32, notCellResult, notStringResult, isStringResult)); |
| return; |
| } |
| |
| if (m_node->isBinaryUseKind(StringUse, UntypedUse)) { |
| compileStringToUntypedStrictEquality(m_node->child1(), m_node->child2()); |
| return; |
| } |
| if (m_node->isBinaryUseKind(UntypedUse, StringUse)) { |
| compileStringToUntypedStrictEquality(m_node->child2(), m_node->child1()); |
| return; |
| } |
| |
| DFG_ASSERT(m_graph, m_node, m_node->isBinaryUseKind(UntypedUse), m_node->child1().useKind(), m_node->child2().useKind()); |
| nonSpeculativeCompare( |
| [&] (LValue left, LValue right) { |
| return m_out.equal(left, right); |
| }, |
| operationCompareStrictEq); |
| } |
| |
| void compileStringToUntypedStrictEquality(Edge stringEdge, Edge untypedEdge) |
| { |
| ASSERT(stringEdge.useKind() == StringUse); |
| ASSERT(untypedEdge.useKind() == UntypedUse); |
| |
| LValue leftString = lowCell(stringEdge); |
| LValue rightValue = lowJSValue(untypedEdge); |
| SpeculatedType rightValueType = provenType(untypedEdge); |
| |
| // Verify left is string. |
| speculateString(stringEdge, leftString); |
| |
| LBasicBlock testUntypedEdgeIsCell = m_out.newBlock(); |
| LBasicBlock testUntypedEdgeIsString = m_out.newBlock(); |
| LBasicBlock testStringEquality = m_out.newBlock(); |
| LBasicBlock continuation = m_out.newBlock(); |
| |
| // Given left is string. If the value are strictly equal, rightValue has to be the same string. |
| ValueFromBlock fastTrue = m_out.anchor(m_out.booleanTrue); |
| m_out.branch(m_out.equal(leftString, rightValue), unsure(continuation), unsure(testUntypedEdgeIsCell)); |
| |
| LBasicBlock lastNext = m_out.appendTo(testUntypedEdgeIsCell, testUntypedEdgeIsString); |
| ValueFromBlock fastFalse = m_out.anchor(m_out.booleanFalse); |
| m_out.branch(isNotCell(rightValue, rightValueType), unsure(continuation), unsure(testUntypedEdgeIsString)); |
| |
| // Check if the untyped edge is a string. |
| m_out.appendTo(testUntypedEdgeIsString, testStringEquality); |
| m_out.branch(isNotString(rightValue, rightValueType), unsure(continuation), unsure(testStringEquality)); |
| |
| // Full String compare. |
| m_out.appendTo(testStringEquality, continuation); |
| ValueFromBlock slowResult = m_out.anchor(stringsEqual(leftString, rightValue)); |
| m_out.jump(continuation); |
| |
| // Continuation. |
| m_out.appendTo(continuation, lastNext); |
| setBoolean(m_out.phi(Int32, fastTrue, fastFalse, slowResult)); |
| } |
| |
| void compileCompareEqPtr() |
| { |
| setBoolean( |
| m_out.equal( |
| lowJSValue(m_node->child1()), |
| weakPointer(m_node->cellOperand()->cell()))); |
| } |
| |
| void compileCompareLess() |
| { |
| compare( |
| [&] (LValue left, LValue right) { |
| return m_out.lessThan(left, right); |
| }, |
| [&] (LValue left, LValue right) { |
| return m_out.doubleLessThan(left, right); |
| }, |
| operationCompareStringImplLess, |
| operationCompareStringLess, |
| operationCompareLess); |
| } |
| |
| void compileCompareLessEq() |
| { |
| compare( |
| [&] (LValue left, LValue right) { |
| return m_out.lessThanOrEqual(left, right); |
| }, |
| [&] (LValue left, LValue right) { |
| return m_out.doubleLessThanOrEqual(left, right); |
| }, |
| operationCompareStringImplLessEq, |
| operationCompareStringLessEq, |
| operationCompareLessEq); |
| } |
| |
| void compileCompareGreater() |
| { |
| compare( |
| [&] (LValue left, LValue right) { |
| return m_out.greaterThan(left, right); |
| }, |
| [&] (LValue left, LValue right) { |
| return m_out.doubleGreaterThan(left, right); |
| }, |
| operationCompareStringImplGreater, |
| operationCompareStringGreater, |
| operationCompareGreater); |
| } |
| |
| void compileCompareGreaterEq() |
| { |
| compare( |
| [&] (LValue left, LValue right) { |
| return m_out.greaterThanOrEqual(left, right); |
| }, |
| [&] (LValue left, LValue right) { |
| return m_out.doubleGreaterThanOrEqual(left, right); |
| }, |
| operationCompareStringImplGreaterEq, |
| operationCompareStringGreaterEq, |
| operationCompareGreaterEq); |
| } |
| |
| void compileCompareBelow() |
| { |
| setBoolean(m_out.below(lowInt32(m_node->child1()), lowInt32(m_node->child2()))); |
| } |
| |
| void compileCompareBelowEq() |
| { |
| setBoolean(m_out.belowOrEqual(lowInt32(m_node->child1()), lowInt32(m_node->child2()))); |
| } |
| |
| void compileLogicalNot() |
| { |
| setBoolean(m_out.logicalNot(boolify(m_node->child1()))); |
| } |
| |
| void compileCallOrConstruct() |
| { |
| Node* node = m_node; |
| unsigned numArgs = node->numChildren() - 1; |
| |
| LValue jsCallee = lowJSValue(m_graph.varArgChild(node, 0)); |
| |
| unsigned frameSize = (CallFrame::headerSizeInRegisters + numArgs) * sizeof(EncodedJSValue); |
| unsigned alignedFrameSize = WTF::roundUpToMultipleOf(stackAlignmentBytes(), frameSize); |
| |
| // JS->JS calling convention requires that the caller allows this much space on top of stack to |
| // get trashed by the callee, even if not all of that space is used to pass arguments. We tell |
| // B3 this explicitly for two reasons: |
| // |
| // - We will only pass frameSize worth of stuff. |
| // - The trashed stack guarantee is logically separate from the act of passing arguments, so we |
| // shouldn't rely on Air to infer the trashed stack property based on the arguments it ends |
| // up seeing. |
| m_proc.requestCallArgAreaSizeInBytes(alignedFrameSize); |
| |
| // Collect the arguments, since this can generate code and we want to generate it before we emit |
| // the call. |
| Vector<ConstrainedValue> arguments; |
| |
| // Make sure that the callee goes into GPR0 because that's where the slow path thunks expect the |
| // callee to be. |
| arguments.append(ConstrainedValue(jsCallee, ValueRep::reg(GPRInfo::regT0))); |
| |
| auto addArgument = [&] (LValue value, VirtualRegister reg, int offset) { |
| intptr_t offsetFromSP = |
| (reg.offset() - CallerFrameAndPC::sizeInRegisters) * sizeof(EncodedJSValue) + offset; |
| arguments.append(ConstrainedValue(value, ValueRep::stackArgument(offsetFromSP))); |
| }; |
| |
| addArgument(jsCallee, VirtualRegister(CallFrameSlot::callee), 0); |
| addArgument(m_out.constInt32(numArgs), VirtualRegister(CallFrameSlot::argumentCount), PayloadOffset); |
| for (unsigned i = 0; i < numArgs; ++i) |
| addArgument(lowJSValue(m_graph.varArgChild(node, 1 + i)), virtualRegisterForArgument(i), 0); |
| |
| PatchpointValue* patchpoint = m_out.patchpoint(Int64); |
| patchpoint->appendVector(arguments); |
| |
| RefPtr<PatchpointExceptionHandle> exceptionHandle = |
| preparePatchpointForExceptions(patchpoint); |
| |
| patchpoint->append(m_tagMask, ValueRep::reg(GPRInfo::tagMaskRegister)); |
| patchpoint->append(m_tagTypeNumber, ValueRep::reg(GPRInfo::tagTypeNumberRegister)); |
| patchpoint->clobber(RegisterSet::macroScratchRegisters()); |
| patchpoint->clobberLate(RegisterSet::volatileRegistersForJSCall()); |
| patchpoint->resultConstraint = ValueRep::reg(GPRInfo::returnValueGPR); |
| |
| CodeOrigin codeOrigin = codeOriginDescriptionOfCallSite(); |
| State* state = &m_ftlState; |
| VM* vm = &this->vm(); |
| patchpoint->setGenerator( |
| [=] (CCallHelpers& jit, const StackmapGenerationParams& params) { |
| AllowMacroScratchRegisterUsage allowScratch(jit); |
| CallSiteIndex callSiteIndex = state->jitCode->common.addUniqueCallSiteIndex(codeOrigin); |
| |
| exceptionHandle->scheduleExitCreationForUnwind(params, callSiteIndex); |
| |
| jit.store32( |
| CCallHelpers::TrustedImm32(callSiteIndex.bits()), |
| CCallHelpers::tagFor(VirtualRegister(CallFrameSlot::argumentCount))); |
| |
| CallLinkInfo* callLinkInfo = jit.codeBlock()->addCallLinkInfo(); |
| |
| CCallHelpers::DataLabelPtr targetToCheck; |
| CCallHelpers::Jump slowPath = jit.branchPtrWithPatch( |
| CCallHelpers::NotEqual, GPRInfo::regT0, targetToCheck, |
| CCallHelpers::TrustedImmPtr(nullptr)); |
| |
| CCallHelpers::Call fastCall = jit.nearCall(); |
| CCallHelpers::Jump done = jit.jump(); |
| |
| slowPath.link(&jit); |
| |
| jit.move(CCallHelpers::TrustedImmPtr(callLinkInfo), GPRInfo::regT2); |
| CCallHelpers::Call slowCall = jit.nearCall(); |
| done.link(&jit); |
| |
| callLinkInfo->setUpCall( |
| node->op() == Construct ? CallLinkInfo::Construct : CallLinkInfo::Call, |
| node->origin.semantic, GPRInfo::regT0); |
| |
| jit.addPtr( |
| CCallHelpers::TrustedImm32(-params.proc().frameSize()), |
| GPRInfo::callFrameRegister, CCallHelpers::stackPointerRegister); |
| |
| jit.addLinkTask( |
| [=] (LinkBuffer& linkBuffer) { |
| MacroAssemblerCodePtr<JITThunkPtrTag> linkCall = vm->getCTIStub(linkCallThunkGenerator).code(); |
| linkBuffer.link(slowCall, FunctionPtr<JITThunkPtrTag>(linkCall)); |
| |
| callLinkInfo->setCallLocations( |
| CodeLocationLabel<JSInternalPtrTag>(linkBuffer.locationOfNearCall<JSInternalPtrTag>(slowCall)), |
| CodeLocationLabel<JSInternalPtrTag>(linkBuffer.locationOf<JSInternalPtrTag>(targetToCheck)), |
| linkBuffer.locationOfNearCall<JSInternalPtrTag>(fastCall)); |
| }); |
| }); |
| |
| setJSValue(patchpoint); |
| } |
| |
| void compileDirectCallOrConstruct() |
| { |
| Node* node = m_node; |
| bool isTail = node->op() == DirectTailCall; |
| bool isConstruct = node->op() == DirectConstruct; |
| |
| ExecutableBase* executable = node->castOperand<ExecutableBase*>(); |
| FunctionExecutable* functionExecutable = jsDynamicCast<FunctionExecutable*>(vm(), executable); |
| |
| unsigned numPassedArgs = node->numChildren() - 1; |
| unsigned numAllocatedArgs = numPassedArgs; |
| |
| if (functionExecutable) { |
| numAllocatedArgs = std::max( |
| numAllocatedArgs, |
| std::min( |
| static_cast<unsigned>(functionExecutable->parameterCount()) + 1, |
| Options::maximumDirectCallStackSize())); |
| } |
| |
| LValue jsCallee = lowJSValue(m_graph.varArgChild(node, 0)); |
| |
| if (!isTail) { |
| unsigned frameSize = (CallFrame::headerSizeInRegisters + numAllocatedArgs) * sizeof(EncodedJSValue); |
| unsigned alignedFrameSize = WTF::roundUpToMultipleOf(stackAlignmentBytes(), frameSize); |
| |
| m_proc.requestCallArgAreaSizeInBytes(alignedFrameSize); |
| } |
| |
| Vector<ConstrainedValue> arguments; |
| |
| arguments.append(ConstrainedValue(jsCallee, ValueRep::SomeRegister)); |
| if (!isTail) { |
| auto addArgument = [&] (LValue value, VirtualRegister reg, int offset) { |
| intptr_t offsetFromSP = |
| (reg.offset() - CallerFrameAndPC::sizeInRegisters) * sizeof(EncodedJSValue) + offset; |
| arguments.append(ConstrainedValue(value, ValueRep::stackArgument(offsetFromSP))); |
| }; |
| |
| addArgument(jsCallee, VirtualRegister(CallFrameSlot::callee), 0); |
| addArgument(m_out.constInt32(numPassedArgs), VirtualRegister(CallFrameSlot::argumentCount), PayloadOffset); |
| for (unsigned i = 0; i < numPassedArgs; ++i) |
| addArgument(lowJSValue(m_graph.varArgChild(node, 1 + i)), virtualRegisterForArgument(i), 0); |
| for (unsigned i = numPassedArgs; i < numAllocatedArgs; ++i) |
| addArgument(m_out.constInt64(JSValue::encode(jsUndefined())), virtualRegisterForArgument(i), 0); |
| } else { |
| for (unsigned i = 0; i < numPassedArgs; ++i) |
| arguments.append(ConstrainedValue(lowJSValue(m_graph.varArgChild(node, 1 + i)), ValueRep::WarmAny)); |
| } |
| |
| PatchpointValue* patchpoint = m_out.patchpoint(isTail ? Void : Int64); |
| patchpoint->appendVector(arguments); |
| |
| RefPtr<PatchpointExceptionHandle> exceptionHandle = preparePatchpointForExceptions(patchpoint); |
| |
| if (isTail) { |
| // The shuffler needs tags. |
| patchpoint->append(m_tagMask, ValueRep::reg(GPRInfo::tagMaskRegister)); |
| patchpoint->append(m_tagTypeNumber, ValueRep::reg(GPRInfo::tagTypeNumberRegister)); |
| } |
| |
| patchpoint->clobber(RegisterSet::macroScratchRegisters()); |
| if (!isTail) { |
| patchpoint->clobberLate(RegisterSet::volatileRegistersForJSCall()); |
| patchpoint->resultConstraint = ValueRep::reg(GPRInfo::returnValueGPR); |
| } |
| |
| CodeOrigin codeOrigin = codeOriginDescriptionOfCallSite(); |
| State* state = &m_ftlState; |
| patchpoint->setGenerator( |
| [=] (CCallHelpers& jit, const StackmapGenerationParams& params) { |
| AllowMacroScratchRegisterUsage allowScratch(jit); |
| CallSiteIndex callSiteIndex = state->jitCode->common.addUniqueCallSiteIndex(codeOrigin); |
| |
| GPRReg calleeGPR = params[!isTail].gpr(); |
| |
| exceptionHandle->scheduleExitCreationForUnwind(params, callSiteIndex); |
| |
| Box<CCallHelpers::JumpList> exceptions = |
| exceptionHandle->scheduleExitCreation(params)->jumps(jit); |
| |
| if (isTail) { |
| CallFrameShuffleData shuffleData; |
| shuffleData.numLocals = state->jitCode->common.frameRegisterCount; |
| |
| RegisterSet toSave = params.unavailableRegisters(); |
| shuffleData.callee = ValueRecovery::inGPR(calleeGPR, DataFormatCell); |
| toSave.set(calleeGPR); |
| for (unsigned i = 0; i < numPassedArgs; ++i) { |
| ValueRecovery recovery = params[1 + i].recoveryForJSValue(); |
| shuffleData.args.append(recovery); |
| recovery.forEachReg( |
| [&] (Reg reg) { |
| toSave.set(reg); |
| }); |
| } |
| for (unsigned i = numPassedArgs; i < numAllocatedArgs; ++i) |
| shuffleData.args.append(ValueRecovery::constant(jsUndefined())); |
| shuffleData.numPassedArgs = numPassedArgs; |
| shuffleData.setupCalleeSaveRegisters(jit.codeBlock()); |
| |
| CallLinkInfo* callLinkInfo = jit.codeBlock()->addCallLinkInfo(); |
| |
| CCallHelpers::PatchableJump patchableJump = jit.patchableJump(); |
| CCallHelpers::Label mainPath = jit.label(); |
| |
| jit.store32( |
| CCallHelpers::TrustedImm32(callSiteIndex.bits()), |
| CCallHelpers::tagFor(VirtualRegister(CallFrameSlot::argumentCount))); |
| |
| callLinkInfo->setFrameShuffleData(shuffleData); |
| CallFrameShuffler(jit, shuffleData).prepareForTailCall(); |
| |
| CCallHelpers::Call call = jit.nearTailCall(); |
| |
| jit.abortWithReason(JITDidReturnFromTailCall); |
| |
| CCallHelpers::Label slowPath = jit.label(); |
| patchableJump.m_jump.linkTo(slowPath, &jit); |
| callOperation( |
| *state, toSave, jit, |
| node->origin.semantic, exceptions.get(), operationLinkDirectCall, |
| InvalidGPRReg, CCallHelpers::TrustedImmPtr(callLinkInfo), calleeGPR).call(); |
| jit.jump().linkTo(mainPath, &jit); |
| |
| callLinkInfo->setUpCall( |
| CallLinkInfo::DirectTailCall, node->origin.semantic, InvalidGPRReg); |
| callLinkInfo->setExecutableDuringCompilation(executable); |
| if (numAllocatedArgs > numPassedArgs) |
| callLinkInfo->setMaxNumArguments(numAllocatedArgs); |
| |
| jit.addLinkTask( |
| [=] (LinkBuffer& linkBuffer) { |
| CodeLocationLabel<JSInternalPtrTag> patchableJumpLocation = linkBuffer.locationOf<JSInternalPtrTag>(patchableJump); |
| CodeLocationNearCall<JSInternalPtrTag> callLocation = linkBuffer.locationOfNearCall<JSInternalPtrTag>(call); |
| CodeLocationLabel<JSInternalPtrTag> slowPathLocation = linkBuffer.locationOf<JSInternalPtrTag>(slowPath); |
| |
| callLinkInfo->setCallLocations( |
| patchableJumpLocation, |
| slowPathLocation, |
| callLocation); |
| }); |
| return; |
| } |
| |
| CallLinkInfo* callLinkInfo = jit.codeBlock()->addCallLinkInfo(); |
| |
| CCallHelpers::Label mainPath = jit.label(); |
| |
| jit.store32( |
| CCallHelpers::TrustedImm32(callSiteIndex.bits()), |
| CCallHelpers::tagFor(VirtualRegister(CallFrameSlot::argumentCount))); |
| |
| CCallHelpers::Call call = jit.nearCall(); |
| jit.addPtr( |
| CCallHelpers::TrustedImm32(-params.proc().frameSize()), |
| GPRInfo::callFrameRegister, CCallHelpers::stackPointerRegister); |
| |
| callLinkInfo->setUpCall( |
| isConstruct ? CallLinkInfo::DirectConstruct : CallLinkInfo::DirectCall, |
| node->origin.semantic, InvalidGPRReg); |
| callLinkInfo->setExecutableDuringCompilation(executable); |
| if (numAllocatedArgs > numPassedArgs) |
| callLinkInfo->setMaxNumArguments(numAllocatedArgs); |
| |
| params.addLatePath( |
| [=] (CCallHelpers& jit) { |
| AllowMacroScratchRegisterUsage allowScratch(jit); |
| |
| CCallHelpers::Label slowPath = jit.label(); |
| if (isX86()) |
| jit.pop(CCallHelpers::selectScratchGPR(calleeGPR)); |
| |
| callOperation( |
| *state, params.unavailableRegisters(), jit, |
| node->origin.semantic, exceptions.get(), operationLinkDirectCall, |
| InvalidGPRReg, CCallHelpers::TrustedImmPtr(callLinkInfo), |
| calleeGPR).call(); |
| jit.jump().linkTo(mainPath, &jit); |
| |
| jit.addLinkTask( |
| [=] (LinkBuffer& linkBuffer) { |
| CodeLocationNearCall<JSInternalPtrTag> callLocation = linkBuffer.locationOfNearCall<JSInternalPtrTag>(call); |
| CodeLocationLabel<JSInternalPtrTag> slowPathLocation = linkBuffer.locationOf<JSInternalPtrTag>(slowPath); |
| |
| linkBuffer.link(call, slowPathLocation); |
| |
| callLinkInfo->setCallLocations( |
| CodeLocationLabel<JSInternalPtrTag>(), |
| slowPathLocation, |
| callLocation); |
| }); |
| }); |
| }); |
| |
| if (isTail) |
| patchpoint->effects.terminal = true; |
| else |
| setJSValue(patchpoint); |
| } |
| |
| void compileTailCall() |
| { |
| Node* node = m_node; |
| unsigned numArgs = node->numChildren() - 1; |
| |
| // It seems counterintuitive that this is needed given that tail calls don't create a new frame |
| // on the stack. However, the tail call slow path builds the frame at SP instead of FP before |
| // calling into the slow path C code. This slow path may decide to throw an exception because |
| // the callee we're trying to call is not callable. Throwing an exception will cause us to walk |
| // the stack, which may read, for the sake of the correctness of this code, arbitrary slots on the |
| // stack to recover state. This call arg area ensures the call frame shuffler does not overwrite |
| // any of the slots the stack walking code requires when on the slow path. |
| m_proc.requestCallArgAreaSizeInBytes( |
| WTF::roundUpToMultipleOf(stackAlignmentBytes(), (CallFrame::headerSizeInRegisters + numArgs) * sizeof(EncodedJSValue))); |
| |
| LValue jsCallee = lowJSValue(m_graph.varArgChild(node, 0)); |
| |
| // We want B3 to give us all of the arguments using whatever mechanism it thinks is |
| // convenient. The generator then shuffles those arguments into our own call frame, |
| // destroying our frame in the process. |
| |
| // Note that we don't have to do anything special for exceptions. A tail call is only a |
| // tail call if it is not inside a try block. |
| |
| Vector<ConstrainedValue> arguments; |
| |
| arguments.append(ConstrainedValue(jsCallee, ValueRep::reg(GPRInfo::regT0))); |
| |
| for (unsigned i = 0; i < numArgs; ++i) { |
| // Note: we could let the shuffler do boxing for us, but it's not super clear that this |
| // would be better. Also, if we wanted to do that, then we'd have to teach the shuffler |
| // that 32-bit values could land at 4-byte alignment but not 8-byte alignment. |
| |
| ConstrainedValue constrainedValue( |
| lowJSValue(m_graph.varArgChild(node, 1 + i)), |
| ValueRep::WarmAny); |
| arguments.append(constrainedValue); |
| } |
| |
| PatchpointValue* patchpoint = m_out.patchpoint(Void); |
| patchpoint->appendVector(arguments); |
| |
| patchpoint->append(m_tagMask, ValueRep::reg(GPRInfo::tagMaskRegister)); |
| patchpoint->append(m_tagTypeNumber, ValueRep::reg(GPRInfo::tagTypeNumberRegister)); |
| |
| // Prevent any of the arguments from using the scratch register. |
| patchpoint->clobberEarly(RegisterSet::macroScratchRegisters()); |
| |
| patchpoint->effects.terminal = true; |
| |
| // We don't have to tell the patchpoint that we will clobber registers, since we won't return |
| // anyway. |
| |
| CodeOrigin codeOrigin = codeOriginDescriptionOfCallSite(); |
| State* state = &m_ftlState; |
| VM* vm = &this->vm(); |
| patchpoint->setGenerator( |
| [=] (CCallHelpers& jit, const StackmapGenerationParams& params) { |
| AllowMacroScratchRegisterUsage allowScratch(jit); |
| CallSiteIndex callSiteIndex = state->jitCode->common.addUniqueCallSiteIndex(codeOrigin); |
| |
| // Yes, this is really necessary. You could throw an exception in a host call on the |
| // slow path. That'll route us to lookupExceptionHandler(), which unwinds starting |
| // with the call site index of our frame. Bad things happen if it's not set. |
| jit.store32( |
| CCallHelpers::TrustedImm32(callSiteIndex.bits()), |
| CCallHelpers::tagFor(VirtualRegister(CallFrameSlot::argumentCount))); |
| |
| CallFrameShuffleData shuffleData; |
| shuffleData.numLocals = state->jitCode->common.frameRegisterCount; |
| shuffleData.callee = ValueRecovery::inGPR(GPRInfo::regT0, DataFormatJS); |
| |
| for (unsigned i = 0; i < numArgs; ++i) |
| shuffleData.args.append(params[1 + i].recoveryForJSValue()); |
| |
| shuffleData.numPassedArgs = numArgs; |
| |
| shuffleData.setupCalleeSaveRegisters(jit.codeBlock()); |
| |
| CallLinkInfo* callLinkInfo = jit.codeBlock()->addCallLinkInfo(); |
| |
| CCallHelpers::DataLabelPtr targetToCheck; |
| CCallHelpers::Jump slowPath = jit.branchPtrWithPatch( |
| CCallHelpers::NotEqual, GPRInfo::regT0, targetToCheck, |
| CCallHelpers::TrustedImmPtr(nullptr)); |
| |
| callLinkInfo->setFrameShuffleData(shuffleData); |
| CallFrameShuffler(jit, shuffleData).prepareForTailCall(); |
| |
| CCallHelpers::Call fastCall = jit.nearTailCall(); |
| |
| slowPath.link(&jit); |
| |
| CallFrameShuffler slowPathShuffler(jit, shuffleData); |
| slowPathShuffler.setCalleeJSValueRegs(JSValueRegs(GPRInfo::regT0)); |
| slowPathShuffler.prepareForSlowPath(); |
| |
| jit.move(CCallHelpers::TrustedImmPtr(callLinkInfo), GPRInfo::regT2); |
| CCallHelpers::Call slowCall = jit.nearCall(); |
| |
| jit.abortWithReason(JITDidReturnFromTailCall); |
| |
| callLinkInfo->setUpCall(CallLinkInfo::TailCall, codeOrigin, GPRInfo::regT0); |
| |
| jit.addLinkTask( |
| [=] (LinkBuffer& linkBuffer) { |
| MacroAssemblerCodePtr<JITThunkPtrTag> linkCall = vm->getCTIStub(linkCallThunkGenerator).code(); |
| linkBuffer.link(slowCall, FunctionPtr<JITThunkPtrTag>(linkCall)); |
| |
| callLinkInfo->setCallLocations( |
| CodeLocationLabel<JSInternalPtrTag>(linkBuffer.locationOfNearCall<JSInternalPtrTag>(slowCall)), |
| CodeLocationLabel<JSInternalPtrTag>(linkBuffer.locationOf<JSInternalPtrTag>(targetToCheck)), |
| linkBuffer.locationOfNearCall<JSInternalPtrTag>(fastCall)); |
| }); |
| }); |
| } |
| |
| void compileCallOrConstructVarargsSpread() |
| { |
| Node* node = m_node; |
| Node* arguments = node->child3().node(); |
| |
| LValue jsCallee = lowJSValue(m_node->child1()); |
| LValue thisArg = lowJSValue(m_node->child2()); |
| |
| RELEASE_ASSERT(arguments->op() == PhantomNewArrayWithSpread || arguments->op() == PhantomSpread || arguments->op() == PhantomNewArrayBuffer); |
| |
| unsigned staticArgumentCount = 0; |
| Vector<LValue, 2> spreadLengths; |
| Vector<LValue, 8> patchpointArguments; |
| HashMap<InlineCallFrame*, LValue, WTF::DefaultHash<InlineCallFrame*>::Hash, WTF::NullableHashTraits<InlineCallFrame*>> cachedSpreadLengths; |
| auto pushAndCountArgumentsFromRightToLeft = recursableLambda([&](auto self, Node* target) -> void { |
| if (target->op() == PhantomSpread) { |
| self(target->child1().node()); |
| return; |
| } |
| |
| if (target->op() == PhantomNewArrayWithSpread) { |
| BitVector* bitVector = target->bitVector(); |
| for (unsigned i = target->numChildren(); i--; ) { |
| if (bitVector->get(i)) |
| self(m_graph.varArgChild(target, i).node()); |
| else { |
| ++staticArgumentCount; |
| LValue argument = this->lowJSValue(m_graph.varArgChild(target, i)); |
| patchpointArguments.append(argument); |
| } |
| } |
| return; |
| } |
| |
| if (target->op() == PhantomNewArrayBuffer) { |
| staticArgumentCount += target->castOperand<JSFixedArray*>()->length(); |
| return; |
| } |
| |
| RELEASE_ASSERT(target->op() == PhantomCreateRest); |
| InlineCallFrame* inlineCallFrame = target->origin.semantic.inlineCallFrame; |
| unsigned numberOfArgumentsToSkip = target->numberOfArgumentsToSkip(); |
| LValue length = cachedSpreadLengths.ensure(inlineCallFrame, [&] () { |
| return m_out.zeroExtPtr(this->getSpreadLengthFromInlineCallFrame(inlineCallFrame, numberOfArgumentsToSkip)); |
| }).iterator->value; |
| patchpointArguments.append(length); |
| spreadLengths.append(length); |
| }); |
| |
| pushAndCountArgumentsFromRightToLeft(arguments); |
| LValue argumentCountIncludingThis = m_out.constIntPtr(staticArgumentCount + 1); |
| for (LValue length : spreadLengths) |
| argumentCountIncludingThis = m_out.add(length, argumentCountIncludingThis); |
| |
| PatchpointValue* patchpoint = m_out.patchpoint(Int64); |
| |
| patchpoint->append(jsCallee, ValueRep::reg(GPRInfo::regT0)); |
| patchpoint->append(thisArg, ValueRep::WarmAny); |
| patchpoint->append(argumentCountIncludingThis, ValueRep::WarmAny); |
| patchpoint->appendVectorWithRep(patchpointArguments, ValueRep::WarmAny); |
| patchpoint->append(m_tagMask, ValueRep::reg(GPRInfo::tagMaskRegister)); |
| patchpoint->append(m_tagTypeNumber, ValueRep::reg(GPRInfo::tagTypeNumberRegister)); |
| |
| RefPtr<PatchpointExceptionHandle> exceptionHandle = preparePatchpointForExceptions(patchpoint); |
| |
| patchpoint->clobber(RegisterSet::macroScratchRegisters()); |
| patchpoint->clobber(RegisterSet::volatileRegistersForJSCall()); // No inputs will be in a volatile register. |
| patchpoint->resultConstraint = ValueRep::reg(GPRInfo::returnValueGPR); |
| |
| patchpoint->numGPScratchRegisters = 0; |
| |
| // This is the minimum amount of call arg area stack space that all JS->JS calls always have. |
| unsigned minimumJSCallAreaSize = |
| sizeof(CallerFrameAndPC) + |
| WTF::roundUpToMultipleOf(stackAlignmentBytes(), 5 * sizeof(EncodedJSValue)); |
| |
| m_proc.requestCallArgAreaSizeInBytes(minimumJSCallAreaSize); |
| |
| CodeOrigin codeOrigin = codeOriginDescriptionOfCallSite(); |
| State* state = &m_ftlState; |
| VM* vm = &this->vm(); |
| patchpoint->setGenerator( |
| [=] (CCallHelpers& jit, const StackmapGenerationParams& params) { |
| AllowMacroScratchRegisterUsage allowScratch(jit); |
| CallSiteIndex callSiteIndex = |
| state->jitCode->common.addUniqueCallSiteIndex(codeOrigin); |
| |
| Box<CCallHelpers::JumpList> exceptions = |
| exceptionHandle->scheduleExitCreation(params)->jumps(jit); |
| |
| exceptionHandle->scheduleExitCreationForUnwind(params, callSiteIndex); |
| |
| jit.store32( |
| CCallHelpers::TrustedImm32(callSiteIndex.bits()), |
| CCallHelpers::tagFor(VirtualRegister(CallFrameSlot::argumentCount))); |
| |
| CallLinkInfo* callLinkInfo = jit.codeBlock()->addCallLinkInfo(); |
| |
| RegisterSet usedRegisters = RegisterSet::allRegisters(); |
| usedRegisters.exclude(RegisterSet::volatileRegistersForJSCall()); |
| GPRReg calleeGPR = params[1].gpr(); |
| usedRegisters.set(calleeGPR); |
| |
| ScratchRegisterAllocator allocator(usedRegisters); |
| GPRReg scratchGPR1 = allocator.allocateScratchGPR(); |
| GPRReg scratchGPR2 = allocator.allocateScratchGPR(); |
| GPRReg scratchGPR3 = allocator.allocateScratchGPR(); |
| GPRReg scratchGPR4 = allocator.allocateScratchGPR(); |
| RELEASE_ASSERT(!allocator.numberOfReusedRegisters()); |
| |
| auto getValueFromRep = [&] (B3::ValueRep rep, GPRReg result) { |
| ASSERT(!usedRegisters.get(result)); |
| |
| if (rep.isConstant()) { |
| jit.move(CCallHelpers::Imm64(rep.value()), result); |
| return; |
| } |
| |
| // Note: in this function, we only request 64 bit values. |
| if (rep.isStack()) { |
| jit.load64( |
| CCallHelpers::Address(GPRInfo::callFrameRegister, rep.offsetFromFP()), |
| result); |
| return; |
| } |
| |
| RELEASE_ASSERT(rep.isGPR()); |
| ASSERT(usedRegisters.get(rep.gpr())); |
| jit.move(rep.gpr(), result); |
| }; |
| |
| auto callWithExceptionCheck = [&] (void* callee) { |
| jit.move(CCallHelpers::TrustedImmPtr(tagCFunctionPtr<OperationPtrTag>(callee)), GPRInfo::nonPreservedNonArgumentGPR0); |
| jit.call(GPRInfo::nonPreservedNonArgumentGPR0, OperationPtrTag); |
| exceptions->append(jit.emitExceptionCheck(*vm, AssemblyHelpers::NormalExceptionCheck, AssemblyHelpers::FarJumpWidth)); |
| }; |
| |
| CCallHelpers::JumpList slowCase; |
| unsigned originalStackHeight = params.proc().frameSize(); |
| |
| { |
| unsigned numUsedSlots = WTF::roundUpToMultipleOf(stackAlignmentRegisters(), originalStackHeight / sizeof(EncodedJSValue)); |
| B3::ValueRep argumentCountIncludingThisRep = params[3]; |
| getValueFromRep(argumentCountIncludingThisRep, scratchGPR2); |
| slowCase.append(jit.branch32(CCallHelpers::Above, scratchGPR2, CCallHelpers::TrustedImm32(JSC::maxArguments + 1))); |
| |
| jit.move(scratchGPR2, scratchGPR1); |
| jit.addPtr(CCallHelpers::TrustedImmPtr(static_cast<size_t>(numUsedSlots + CallFrame::headerSizeInRegisters)), scratchGPR1); |
| // scratchGPR1 now has the required frame size in Register units |
| // Round scratchGPR1 to next multiple of stackAlignmentRegisters() |
| jit.addPtr(CCallHelpers::TrustedImm32(stackAlignmentRegisters() - 1), scratchGPR1); |
| jit.andPtr(CCallHelpers::TrustedImm32(~(stackAlignmentRegisters() - 1)), scratchGPR1); |
| jit.negPtr(scratchGPR1); |
| jit.getEffectiveAddress(CCallHelpers::BaseIndex(GPRInfo::callFrameRegister, scratchGPR1, CCallHelpers::TimesEight), scratchGPR1); |
| |
| // Before touching stack values, we should update the stack pointer to protect them from signal stack. |
| jit.addPtr(CCallHelpers::TrustedImm32(sizeof(CallerFrameAndPC)), scratchGPR1, CCallHelpers::stackPointerRegister); |
| |
| jit.store32(scratchGPR2, CCallHelpers::Address(scratchGPR1, CallFrameSlot::argumentCount * static_cast<int>(sizeof(Register)) + PayloadOffset)); |
| |
| int storeOffset = CallFrame::thisArgumentOffset() * static_cast<int>(sizeof(Register)); |
| |
| unsigned paramsOffset = 4; |
| unsigned index = 0; |
| auto emitArgumentsFromRightToLeft = recursableLambda([&](auto self, Node* target) -> void { |
| if (target->op() == PhantomSpread) { |
| self(target->child1().node()); |
| return; |
| } |
| |
| if (target->op() == PhantomNewArrayWithSpread) { |
| BitVector* bitVector = target->bitVector(); |
| for (unsigned i = target->numChildren(); i--; ) { |
| if (bitVector->get(i)) |
| self(state->graph.varArgChild(target, i).node()); |
| else { |
| jit.subPtr(CCallHelpers::TrustedImmPtr(static_cast<size_t>(1)), scratchGPR2); |
| getValueFromRep(params[paramsOffset + (index++)], scratchGPR3); |
| jit.store64(scratchGPR3, |
| CCallHelpers::BaseIndex(scratchGPR1, scratchGPR2, CCallHelpers::TimesEight, storeOffset)); |
| } |
| } |
| return; |
| } |
| |
| if (target->op() == PhantomNewArrayBuffer) { |
| auto* array = target->castOperand<JSFixedArray*>(); |
| Checked<int32_t> offsetCount { 1 }; |
| for (unsigned i = array->length(); i--; ++offsetCount) { |
| // Because varargs values are drained as JSValue, we should not generate value |
| // in Double form even if PhantomNewArrayBuffer's indexingType is ArrayWithDouble. |
| int64_t value = JSValue::encode(array->get(i)); |
| jit.move(CCallHelpers::TrustedImm64(value), scratchGPR3); |
| Checked<int32_t> currentStoreOffset { storeOffset }; |
| currentStoreOffset -= (offsetCount * static_cast<int32_t>(sizeof(Register))); |
| jit.store64(scratchGPR3, |
| CCallHelpers::BaseIndex(scratchGPR1, scratchGPR2, CCallHelpers::TimesEight, currentStoreOffset.unsafeGet())); |
| } |
| jit.subPtr(CCallHelpers::TrustedImmPtr(static_cast<size_t>(array->length())), scratchGPR2); |
| return; |
| } |
| |
| RELEASE_ASSERT(target->op() == PhantomCreateRest); |
| InlineCallFrame* inlineCallFrame = target->origin.semantic.inlineCallFrame; |
| |
| unsigned numberOfArgumentsToSkip = target->numberOfArgumentsToSkip(); |
| |
| B3::ValueRep numArgumentsToCopy = params[paramsOffset + (index++)]; |
| getValueFromRep(numArgumentsToCopy, scratchGPR3); |
| int loadOffset = (AssemblyHelpers::argumentsStart(inlineCallFrame).offset() + numberOfArgumentsToSkip) * static_cast<int>(sizeof(Register)); |
| |
| auto done = jit.branchTestPtr(MacroAssembler::Zero, scratchGPR3); |
| auto loopStart = jit.label(); |
| jit.subPtr(CCallHelpers::TrustedImmPtr(static_cast<size_t>(1)), scratchGPR3); |
| jit.subPtr(CCallHelpers::TrustedImmPtr(static_cast<size_t>(1)), scratchGPR2); |
| jit.load64(CCallHelpers::BaseIndex(GPRInfo::callFrameRegister, scratchGPR3, CCallHelpers::TimesEight, loadOffset), scratchGPR4); |
| jit.store64(scratchGPR4, |
| CCallHelpers::BaseIndex(scratchGPR1, scratchGPR2, CCallHelpers::TimesEight, storeOffset)); |
| jit.branchTestPtr(CCallHelpers::NonZero, scratchGPR3).linkTo(loopStart, &jit); |
| done.link(&jit); |
| }); |
| emitArgumentsFromRightToLeft(arguments); |
| } |
| |
| { |
| CCallHelpers::Jump dontThrow = jit.jump(); |
| slowCase.link(&jit); |
| jit.setupArguments<decltype(operationThrowStackOverflowForVarargs)>(); |
| callWithExceptionCheck(bitwise_cast<void*>(operationThrowStackOverflowForVarargs)); |
| jit.abortWithReason(DFGVarargsThrowingPathDidNotThrow); |
| |
| dontThrow.link(&jit); |
| } |
| |
| ASSERT(calleeGPR == GPRInfo::regT0); |
| jit.store64(calleeGPR, CCallHelpers::calleeFrameSlot(CallFrameSlot::callee)); |
| getValueFromRep(params[2], scratchGPR3); |
| jit.store64(scratchGPR3, CCallHelpers::calleeArgumentSlot(0)); |
| |
| CallLinkInfo::CallType callType; |
| if (node->op() == ConstructVarargs || node->op() == ConstructForwardVarargs) |
| callType = CallLinkInfo::ConstructVarargs; |
| else if (node->op() == TailCallVarargs || node->op() == TailCallForwardVarargs) |
| callType = CallLinkInfo::TailCallVarargs; |
| else |
| callType = CallLinkInfo::CallVarargs; |
| |
| bool isTailCall = CallLinkInfo::callModeFor(callType) == CallMode::Tail; |
| |
| CCallHelpers::DataLabelPtr targetToCheck; |
| CCallHelpers::Jump slowPath = jit.branchPtrWithPatch( |
| CCallHelpers::NotEqual, GPRInfo::regT0, targetToCheck, |
| CCallHelpers::TrustedImmPtr(nullptr)); |
| |
| CCallHelpers::Call fastCall; |
| CCallHelpers::Jump done; |
| |
| if (isTailCall) { |
| jit.emitRestoreCalleeSaves(); |
| jit.prepareForTailCallSlow(); |
| fastCall = jit.nearTailCall(); |
| } else { |
| fastCall = jit.nearCall(); |
| done = jit.jump(); |
| } |
| |
| slowPath.link(&jit); |
| |
| if (isTailCall) |
| jit.emitRestoreCalleeSaves(); |
| ASSERT(!usedRegisters.get(GPRInfo::regT2)); |
| jit.move(CCallHelpers::TrustedImmPtr(callLinkInfo), GPRInfo::regT2); |
| CCallHelpers::Call slowCall = jit.nearCall(); |
| |
| if (isTailCall) |
| jit.abortWithReason(JITDidReturnFromTailCall); |
| else |
| done.link(&jit); |
| |
| callLinkInfo->setUpCall(callType, node->origin.semantic, GPRInfo::regT0); |
| |
| jit.addPtr( |
| CCallHelpers::TrustedImm32(-originalStackHeight), |
| GPRInfo::callFrameRegister, CCallHelpers::stackPointerRegister); |
| |
| jit.addLinkTask( |
| [=] (LinkBuffer& linkBuffer) { |
| MacroAssemblerCodePtr<JITThunkPtrTag> linkCall = vm->getCTIStub(linkCallThunkGenerator).code(); |
| linkBuffer.link(slowCall, FunctionPtr<JITThunkPtrTag>(linkCall)); |
| |
| callLinkInfo->setCallLocations( |
| CodeLocationLabel<JSInternalPtrTag>(linkBuffer.locationOfNearCall<JSInternalPtrTag>(slowCall)), |
| CodeLocationLabel<JSInternalPtrTag>(linkBuffer.locationOf<JSInternalPtrTag>(targetToCheck)), |
| linkBuffer.locationOfNearCall<JSInternalPtrTag>(fastCall)); |
| }); |
| }); |
| |
| switch (node->op()) { |
| case TailCallForwardVarargs: |
| m_out.unreachable(); |
| break; |
| |
| default: |
| setJSValue(patchpoint); |
| break; |
| } |
| } |
| |
| void compileCallOrConstructVarargs() |
| { |
| Node* node = m_node; |
| LValue jsCallee = lowJSValue(m_node->child1()); |
| LValue thisArg = lowJSValue(m_node->child2()); |
| |
| LValue jsArguments = nullptr; |
| bool forwarding = false; |
| |
| switch (node->op()) { |
| case CallVarargs: |
| case TailCallVarargs: |
| case TailCallVarargsInlinedCaller: |
| case ConstructVarargs: |
| jsArguments = lowJSValue(node->child3()); |
| break; |
| case CallForwardVarargs: |
| case TailCallForwardVarargs: |
| case TailCallForwardVarargsInlinedCaller: |
| case ConstructForwardVarargs: |
| forwarding = true; |
| break; |
| default: |
| DFG_CRASH(m_graph, node, "bad node type"); |
| break; |
| } |
| |
| if (forwarding && m_node->child3()) { |
| Node* arguments = m_node->child3().node(); |
| if (arguments->op() == PhantomNewArrayWithSpread || arguments->op() == PhantomNewArrayBuffer || arguments->op() == PhantomSpread) { |
| compileCallOrConstructVarargsSpread(); |
| return; |
| } |
| } |
| |
| |
| PatchpointValue* patchpoint = m_out.patchpoint(Int64); |
| |
| // Append the forms of the arguments that we will use before any clobbering happens. |
| patchpoint->append(jsCallee, ValueRep::reg(GPRInfo::regT0)); |
| if (jsArguments) |
| patchpoint->appendSomeRegister(jsArguments); |
| patchpoint->appendSomeRegister(thisArg); |
| |
| if (!forwarding) { |
| // Now append them again for after clobbering. Note that the compiler may ask us to use a |
| // different register for the late for the post-clobbering version of the value. This gives |
| // the compiler a chance to spill these values without having to burn any callee-saves. |
| patchpoint->append(jsCallee, ValueRep::LateColdAny); |
| patchpoint->append(jsArguments, ValueRep::LateColdAny); |
| patchpoint->append(thisArg, ValueRep::LateColdAny); |
| } |
| |
| RefPtr<PatchpointExceptionHandle> exceptionHandle = |
| preparePatchpointForExceptions(patchpoint); |
| |
| patchpoint->append(m_tagMask, ValueRep::reg(GPRInfo::tagMaskRegister)); |
| patchpoint->append(m_tagTypeNumber, ValueRep::reg(GPRInfo::tagTypeNumberRegister)); |
| |
| patchpoint->clobber(RegisterSet::macroScratchRegisters()); |
| patchpoint->clobberLate(RegisterSet::volatileRegistersForJSCall()); |
| patchpoint->resultConstraint = ValueRep::reg(GPRInfo::returnValueGPR); |
| |
| // This is the minimum amount of call arg area stack space that all JS->JS calls always have. |
| unsigned minimumJSCallAreaSize = |
| sizeof(CallerFrameAndPC) + |
| WTF::roundUpToMultipleOf(stackAlignmentBytes(), 5 * sizeof(EncodedJSValue)); |
| |
| m_proc.requestCallArgAreaSizeInBytes(minimumJSCallAreaSize); |
| |
| CodeOrigin codeOrigin = codeOriginDescriptionOfCallSite(); |
| State* state = &m_ftlState; |
| VM* vm = &this->vm(); |
| patchpoint->setGenerator( |
| [=] (CCallHelpers& jit, const StackmapGenerationParams& params) { |
| AllowMacroScratchRegisterUsage allowScratch(jit); |
| CallSiteIndex callSiteIndex = |
| state->jitCode->common.addUniqueCallSiteIndex(codeOrigin); |
| |
| Box<CCallHelpers::JumpList> exceptions = |
| exceptionHandle->scheduleExitCreation(params)->jumps(jit); |
| |
| exceptionHandle->scheduleExitCreationForUnwind(params, callSiteIndex); |
| |
| jit.store32( |
| CCallHelpers::TrustedImm32(callSiteIndex.bits()), |
| CCallHelpers::tagFor(VirtualRegister(CallFrameSlot::argumentCount))); |
| |
| CallLinkInfo* callLinkInfo = jit.codeBlock()->addCallLinkInfo(); |
| CallVarargsData* data = node->callVarargsData(); |
| |
| unsigned argIndex = 1; |
| GPRReg calleeGPR = params[argIndex++].gpr(); |
| ASSERT(calleeGPR == GPRInfo::regT0); |
| GPRReg argumentsGPR = jsArguments ? params[argIndex++].gpr() : InvalidGPRReg; |
| GPRReg thisGPR = params[argIndex++].gpr(); |
| |
| B3::ValueRep calleeLateRep; |
| B3::ValueRep argumentsLateRep; |
| B3::ValueRep thisLateRep; |
| if (!forwarding) { |
| // If we're not forwarding then we'll need callee, arguments, and this after we |
| // have potentially clobbered calleeGPR, argumentsGPR, and thisGPR. Our technique |
| // for this is to supply all of those operands as late uses in addition to |
| // specifying them as early uses. It's possible that the late use uses a spill |
| // while the early use uses a register, and it's possible for the late and early |
| // uses to use different registers. We do know that the late uses interfere with |
| // all volatile registers and so won't use those, but the early uses may use |
| // volatile registers and in the case of calleeGPR, it's pinned to regT0 so it |
| // definitely will. |
| // |
| // Note that we have to be super careful with these. It's possible that these |
| // use a shuffling of the registers used for calleeGPR, argumentsGPR, and |
| // thisGPR. If that happens and we do for example: |
| // |
| // calleeLateRep.emitRestore(jit, calleeGPR); |
| // argumentsLateRep.emitRestore(jit, calleeGPR); |
| // |
| // Then we might end up with garbage if calleeLateRep.gpr() == argumentsGPR and |
| // argumentsLateRep.gpr() == calleeGPR. |
| // |
| // We do a variety of things to prevent this from happening. For example, we use |
| // argumentsLateRep before needing the other two and after we've already stopped |
| // using the *GPRs. Also, we pin calleeGPR to regT0, and rely on the fact that |
| // the *LateReps cannot use volatile registers (so they cannot be regT0, so |
| // calleeGPR != argumentsLateRep.gpr() and calleeGPR != thisLateRep.gpr()). |
| // |
| // An alternative would have been to just use early uses and early-clobber all |
| // volatile registers. But that would force callee, arguments, and this into |
| // callee-save registers even if we have to spill them. We don't want spilling to |
| // use up three callee-saves. |
| // |
| // TL;DR: The way we use LateReps here is dangerous and barely works but achieves |
| // some desirable performance properties, so don't mistake the cleverness for |
| // elegance. |
| calleeLateRep = params[argIndex++]; |
| argumentsLateRep = params[argIndex++]; |
| thisLateRep = params[argIndex++]; |
| } |
| |
| // Get some scratch registers. |
| RegisterSet usedRegisters; |
| usedRegisters.merge(RegisterSet::stackRegisters()); |
| usedRegisters.merge(RegisterSet::reservedHardwareRegisters()); |
| usedRegisters.merge(RegisterSet::calleeSaveRegisters()); |
| usedRegisters.set(calleeGPR); |
| if (argumentsGPR != InvalidGPRReg) |
| usedRegisters.set(argumentsGPR); |
| usedRegisters.set(thisGPR); |
| if (calleeLateRep.isReg()) |
| usedRegisters.set(calleeLateRep.reg()); |
| if (argumentsLateRep.isReg()) |
| usedRegisters.set(argumentsLateRep.reg()); |
| if (thisLateRep.isReg()) |
| usedRegisters.set(thisLateRep.reg()); |
| ScratchRegisterAllocator allocator(usedRegisters); |
| GPRReg scratchGPR1 = allocator.allocateScratchGPR(); |
| GPRReg scratchGPR2 = allocator.allocateScratchGPR(); |
| GPRReg scratchGPR3 = forwarding ? allocator.allocateScratchGPR() : InvalidGPRReg; |
| RELEASE_ASSERT(!allocator.numberOfReusedRegisters()); |
| |
| auto callWithExceptionCheck = [&] (void* callee) { |
| jit.move(CCallHelpers::TrustedImmPtr(tagCFunctionPtr<OperationPtrTag>(callee)), GPRInfo::nonPreservedNonArgumentGPR0); |
| jit.call(GPRInfo::nonPreservedNonArgumentGPR0, OperationPtrTag); |
| exceptions->append(jit.emitExceptionCheck(*vm, AssemblyHelpers::NormalExceptionCheck, AssemblyHelpers::FarJumpWidth)); |
| }; |
| |
| unsigned originalStackHeight = params.proc().frameSize(); |
| |
| if (forwarding) { |
| jit.move(CCallHelpers::TrustedImm32(originalStackHeight / sizeof(EncodedJSValue)), scratchGPR2); |
| |
| CCallHelpers::JumpList slowCase; |
| InlineCallFrame* inlineCallFrame; |
| if (node->child3()) |
| inlineCallFrame = node->child3()->origin.semantic.inlineCallFrame; |
| else |
| inlineCallFrame = node->origin.semantic.inlineCallFrame; |
| |
| // emitSetupVarargsFrameFastCase modifies the stack pointer if it succeeds. |
| emitSetupVarargsFrameFastCase(*vm, jit, scratchGPR2, scratchGPR1, scratchGPR2, scratchGPR3, inlineCallFrame, data->firstVarArgOffset, slowCase); |
| |
| CCallHelpers::Jump done = jit.jump(); |
| slowCase.link(&jit); |
| jit.setupArguments<decltype(operationThrowStackOverflowForVarargs)>(); |
| callWithExceptionCheck(bitwise_cast<void*>(operationThrowStackOverflowForVarargs)); |
| jit.abortWithReason(DFGVarargsThrowingPathDidNotThrow); |
| |
| done.link(&jit); |
| } else { |
| jit.move(CCallHelpers::TrustedImm32(originalStackHeight / sizeof(EncodedJSValue)), scratchGPR1); |
| jit.setupArguments<decltype(operationSizeFrameForVarargs)>(argumentsGPR, scratchGPR1, CCallHelpers::TrustedImm32(data->firstVarArgOffset)); |
| callWithExceptionCheck(bitwise_cast<void*>(operationSizeFrameForVarargs)); |
| |
| jit.move(GPRInfo::returnValueGPR, scratchGPR1); |
| jit.move(CCallHelpers::TrustedImm32(originalStackHeight / sizeof(EncodedJSValue)), scratchGPR2); |
| argumentsLateRep.emitRestore(jit, argumentsGPR); |
| emitSetVarargsFrame(jit, scratchGPR1, false, scratchGPR2, scratchGPR2); |
| jit.addPtr(CCallHelpers::TrustedImm32(-minimumJSCallAreaSize), scratchGPR2, CCallHelpers::stackPointerRegister); |
| jit.setupArguments<decltype(operationSetupVarargsFrame)>(scratchGPR2, argumentsGPR, CCallHelpers::TrustedImm32(data->firstVarArgOffset), scratchGPR1); |
| callWithExceptionCheck(bitwise_cast<void*>(operationSetupVarargsFrame)); |
| |
| jit.addPtr(CCallHelpers::TrustedImm32(sizeof(CallerFrameAndPC)), GPRInfo::returnValueGPR, CCallHelpers::stackPointerRegister); |
| |
| calleeLateRep.emitRestore(jit, GPRInfo::regT0); |
| |
| // This may not emit code if thisGPR got a callee-save. Also, we're guaranteed |
| // that thisGPR != GPRInfo::regT0 because regT0 interferes with it. |
| thisLateRep.emitRestore(jit, thisGPR); |
| } |
| |
| jit.store64(GPRInfo::regT0, CCallHelpers::calleeFrameSlot(CallFrameSlot::callee)); |
| jit.store64(thisGPR, CCallHelpers::calleeArgumentSlot(0)); |
| |
| CallLinkInfo::CallType callType; |
| if (node->op() == ConstructVarargs || node->op() == ConstructForwardVarargs) |
| callType = CallLinkInfo::ConstructVarargs; |
| else if (node->op() == TailCallVarargs || node->op() == TailCallForwardVarargs) |
| callType = CallLinkInfo::TailCallVarargs; |
| else |
| callType = CallLinkInfo::CallVarargs; |
| |
| bool isTailCall = CallLinkInfo::callModeFor(callType) == CallMode::Tail; |
| |
| CCallHelpers::DataLabelPtr targetToCheck; |
| CCallHelpers::Jump slowPath = jit.branchPtrWithPatch( |
| CCallHelpers::NotEqual, GPRInfo::regT0, targetToCheck, |
| CCallHelpers::TrustedImmPtr(nullptr)); |
| |
| CCallHelpers::Call fastCall; |
| CCallHelpers::Jump done; |
| |
| if (isTailCall) { |
| jit.emitRestoreCalleeSaves(); |
| jit.prepareForTailCallSlow(); |
| fastCall = jit.nearTailCall(); |
| } else { |
| fastCall = jit.nearCall(); |
| done = jit.jump(); |
| } |
| |
| slowPath.link(&jit); |
| |
| if (isTailCall) |
| jit.emitRestoreCalleeSaves(); |
| jit.move(CCallHelpers::TrustedImmPtr(callLinkInfo), GPRInfo::regT2); |
| CCallHelpers::Call slowCall = jit.nearCall(); |
| |
| if (isTailCall) |
| jit.abortWithReason(JITDidReturnFromTailCall); |
| else |
| done.link(&jit); |
| |
| callLinkInfo->setUpCall(callType, node->origin.semantic, GPRInfo::regT0); |
| |
| jit.addPtr( |
| CCallHelpers::TrustedImm32(-originalStackHeight), |
| GPRInfo::callFrameRegister, CCallHelpers::stackPointerRegister); |
| |
| jit.addLinkTask( |
| [=] (LinkBuffer& linkBuffer) { |
| MacroAssemblerCodePtr<JITThunkPtrTag> linkCall = vm->getCTIStub(linkCallThunkGenerator).code(); |
| linkBuffer.link(slowCall, FunctionPtr<JITThunkPtrTag>(linkCall)); |
| |
| callLinkInfo->setCallLocations( |
| CodeLocationLabel<JSInternalPtrTag>(linkBuffer.locationOfNearCall<JSInternalPtrTag>(slowCall)), |
| CodeLocationLabel<JSInternalPtrTag>(linkBuffer.locationOf<JSInternalPtrTag>(targetToCheck)), |
| linkBuffer.locationOfNearCall<JSInternalPtrTag>(fastCall)); |
| }); |
| }); |
| |
| switch (node->op()) { |
| case TailCallVarargs: |
| case TailCallForwardVarargs: |
| m_out.unreachable(); |
| break; |
| |
| default: |
| setJSValue(patchpoint); |
| break; |
| } |
| } |
| |
| void compileCallEval() |
| { |
| Node* node = m_node; |
| unsigned numArgs = node->numChildren() - 1; |
| |
| LValue jsCallee = lowJSValue(m_graph.varArgChild(node, 0)); |
| |
| unsigned frameSize = (CallFrame::headerSizeInRegisters + numArgs) * sizeof(EncodedJSValue); |
| unsigned alignedFrameSize = WTF::roundUpToMultipleOf(stackAlignmentBytes(), frameSize); |
| |
| m_proc.requestCallArgAreaSizeInBytes(alignedFrameSize); |
| |
| Vector<ConstrainedValue> arguments; |
| arguments.append(ConstrainedValue(jsCallee, ValueRep::reg(GPRInfo::regT0))); |
| |
| auto addArgument = [&] (LValue value, VirtualRegister reg, int offset) { |
| intptr_t offsetFromSP = |
| (reg.offset() - CallerFrameAndPC::sizeInRegisters) * sizeof(EncodedJSValue) + offset; |
| arguments.append(ConstrainedValue(value, ValueRep::stackArgument(offsetFromSP))); |
| }; |
| |
| addArgument(jsCallee, VirtualRegister(CallFrameSlot::callee), 0); |
| addArgument(m_out.constInt32(numArgs), VirtualRegister(CallFrameSlot::argumentCount), PayloadOffset); |
| for (unsigned i = 0; i < numArgs; ++i) |
| addArgument(lowJSValue(m_graph.varArgChild(node, 1 + i)), virtualRegisterForArgument(i), 0); |
| |
| PatchpointValue* patchpoint = m_out.patchpoint(Int64); |
| patchpoint->appendVector(arguments); |
| |
| RefPtr<PatchpointExceptionHandle> exceptionHandle = preparePatchpointForExceptions(patchpoint); |
| |
| patchpoint->append(m_tagMask, ValueRep::reg(GPRInfo::tagMaskRegister)); |
| patchpoint->append(m_tagTypeNumber, ValueRep::reg(GPRInfo::tagTypeNumberRegister)); |
| patchpoint->clobber(RegisterSet::macroScratchRegisters()); |
| patchpoint->clobberLate(RegisterSet::volatileRegistersForJSCall()); |
| patchpoint->resultConstraint = ValueRep::reg(GPRInfo::returnValueGPR); |
| |
| CodeOrigin codeOrigin = codeOriginDescriptionOfCallSite(); |
| State* state = &m_ftlState; |
| VM& vm = this->vm(); |
| patchpoint->setGenerator( |
| [=, &vm] (CCallHelpers& jit, const StackmapGenerationParams& params) { |
| AllowMacroScratchRegisterUsage allowScratch(jit); |
| CallSiteIndex callSiteIndex = state->jitCode->common.addUniqueCallSiteIndex(codeOrigin); |
| |
| Box<CCallHelpers::JumpList> exceptions = exceptionHandle->scheduleExitCreation(params)->jumps(jit); |
| |
| exceptionHandle->scheduleExitCreationForUnwind(params, callSiteIndex); |
| |
| jit.store32( |
| CCallHelpers::TrustedImm32(callSiteIndex.bits()), |
| CCallHelpers::tagFor(VirtualRegister(CallFrameSlot::argumentCount))); |
| |
| CallLinkInfo* callLinkInfo = jit.codeBlock()->addCallLinkInfo(); |
| callLinkInfo->setUpCall(CallLinkInfo::Call, node->origin.semantic, GPRInfo::regT0); |
| |
| jit.addPtr(CCallHelpers::TrustedImm32(-static_cast<ptrdiff_t>(sizeof(CallerFrameAndPC))), CCallHelpers::stackPointerRegister, GPRInfo::regT1); |
| jit.storePtr(GPRInfo::callFrameRegister, CCallHelpers::Address(GPRInfo::regT1, CallFrame::callerFrameOffset())); |
| |
| // Now we need to make room for: |
| // - The caller frame and PC for a call to operationCallEval. |
| // - Potentially two arguments on the stack. |
| unsigned requiredBytes = sizeof(CallerFrameAndPC) + sizeof(ExecState*) * 2; |
| requiredBytes = WTF::roundUpToMultipleOf(stackAlignmentBytes(), requiredBytes); |
| jit.subPtr(CCallHelpers::TrustedImm32(requiredBytes), CCallHelpers::stackPointerRegister); |
| jit.setupArguments<decltype(operationCallEval)>(GPRInfo::regT1); |
| jit.move(CCallHelpers::TrustedImmPtr(tagCFunctionPtr<OperationPtrTag>(operationCallEval)), GPRInfo::nonPreservedNonArgumentGPR0); |
| jit.call(GPRInfo::nonPreservedNonArgumentGPR0, OperationPtrTag); |
| exceptions->append(jit.emitExceptionCheck(state->vm(), AssemblyHelpers::NormalExceptionCheck, AssemblyHelpers::FarJumpWidth)); |
| |
| CCallHelpers::Jump done = jit.branchTest64(CCallHelpers::NonZero, GPRInfo::returnValueGPR); |
| |
| jit.addPtr(CCallHelpers::TrustedImm32(requiredBytes), CCallHelpers::stackPointerRegister); |
| jit.load64(CCallHelpers::calleeFrameSlot(CallFrameSlot::callee), GPRInfo::regT0); |
| jit.emitDumbVirtualCall(vm, callLinkInfo); |
| |
| done.link(&jit); |
| jit.addPtr( |
| CCallHelpers::TrustedImm32(-params.proc().frameSize()), |
| GPRInfo::callFrameRegister, CCallHelpers::stackPointerRegister); |
| }); |
| |
| setJSValue(patchpoint); |
| } |
| |
| void compileLoadVarargs() |
| { |
| LoadVarargsData* data = m_node->loadVarargsData(); |
| LValue jsArguments = lowJSValue(m_node->child1()); |
| |
| LValue length = vmCall( |
| Int32, m_out.operation(operationSizeOfVarargs), m_callFrame, jsArguments, |
| m_out.constInt32(data->offset)); |
| |
| // FIXME: There is a chance that we will call an effectful length property twice. This is safe |
| // from the standpoint of the VM's integrity, but it's subtly wrong from a spec compliance |
| // standpoint. The best solution would be one where we can exit *into* the op_call_varargs right |
| // past the sizing. |
| // https://bugs.webkit.org/show_bug.cgi?id=141448 |
| |
| LValue lengthIncludingThis = m_out.add(length, m_out.int32One); |
| |
| speculate( |
| VarargsOverflow, noValue(), nullptr, |
| m_out.above(length, lengthIncludingThis)); |
| |
| speculate( |
| VarargsOverflow, noValue(), nullptr, |
| m_out.above(lengthIncludingThis, m_out.constInt32(data->limit))); |
| |
| m_out.store32(lengthIncludingThis, payloadFor(data->machineCount)); |
| |
| // FIXME: This computation is rather silly. If operationLaodVarargs just took a pointer instead |
| // of a VirtualRegister, we wouldn't have to do this. |
| // https://bugs.webkit.org/show_bug.cgi?id=141660 |
| LValue machineStart = m_out.lShr( |
| m_out.sub(addressFor(data->machineStart.offset()).value(), m_callFrame), |
| m_out.constIntPtr(3)); |
| |
| vmCall( |
| Void, m_out.operation(operationLoadVarargs), m_callFrame, |
| m_out.castToInt32(machineStart), jsArguments, m_out.constInt32(data->offset), |
| length, m_out.constInt32(data->mandatoryMinimum)); |
| } |
| |
| void compileForwardVarargs() |
| { |
| if (m_node->child1()) { |
| Node* arguments = m_node->child1().node(); |
| if (arguments->op() == PhantomNewArrayWithSpread || arguments->op() == PhantomNewArrayBuffer || arguments->op() == PhantomSpread) { |
| compileForwardVarargsWithSpread(); |
| return; |
| } |
| } |
| |
| LoadVarargsData* data = m_node->loadVarargsData(); |
| InlineCallFrame* inlineCallFrame; |
| if (m_node->child1()) |
| inlineCallFrame = m_node->child1()->origin.semantic.inlineCallFrame; |
| else |
| inlineCallFrame = m_node->origin.semantic.inlineCallFrame; |
| |
| LValue length = nullptr; |
| LValue lengthIncludingThis = nullptr; |
| ArgumentsLength argumentsLength = getArgumentsLength(inlineCallFrame); |
| if (argumentsLength.isKnown) { |
| unsigned knownLength = argumentsLength.known; |
| if (knownLength >= data->offset) |
| knownLength = knownLength - data->offset; |
| else |
| knownLength = 0; |
| length = m_out.constInt32(knownLength); |
| lengthIncludingThis = m_out.constInt32(knownLength + 1); |
| } else { |
| // We need to perform the same logical operation as the code above, but through dynamic operations. |
| if (!data->offset) |
| length = argumentsLength.value; |
| else { |
| LBasicBlock isLarger = m_out.newBlock(); |
| LBasicBlock continuation = m_out.newBlock(); |
| |
| ValueFromBlock smallerOrEqualLengthResult = m_out.anchor(m_out.constInt32(0)); |
| m_out.branch( |
| m_out.above(argumentsLength.value, m_out.constInt32(data->offset)), unsure(isLarger), unsure(continuation)); |
| LBasicBlock lastNext = m_out.appendTo(isLarger, continuation); |
| ValueFromBlock largerLengthResult = m_out.anchor(m_out.sub(argumentsLength.value, m_out.constInt32(data->offset))); |
| m_out.jump(continuation); |
| |
| m_out.appendTo(continuation, lastNext); |
| length = m_out.phi(Int32, smallerOrEqualLengthResult, largerLengthResult); |
| } |
| lengthIncludingThis = m_out.add(length, m_out.constInt32(1)); |
| } |
| |
| speculate( |
| VarargsOverflow, noValue(), nullptr, |
| m_out.above(lengthIncludingThis, m_out.constInt32(data->limit))); |
| |
| m_out.store32(lengthIncludingThis, payloadFor(data->machineCount)); |
| |
| unsigned numberOfArgumentsToSkip = data->offset; |
| LValue sourceStart = getArgumentsStart(inlineCallFrame, numberOfArgumentsToSkip); |
| LValue targetStart = addressFor(data->machineStart).value(); |
| |
| LBasicBlock undefinedLoop = m_out.newBlock(); |
| LBasicBlock mainLoopEntry = m_out.newBlock(); |
| LBasicBlock mainLoop = m_out.newBlock(); |
| LBasicBlock continuation = m_out.newBlock(); |
| |
| LValue lengthAsPtr = m_out.zeroExtPtr(length); |
| LValue loopBoundValue = m_out.constIntPtr(data->mandatoryMinimum); |
| ValueFromBlock loopBound = m_out.anchor(loopBoundValue); |
| m_out.branch( |
| m_out.above(loopBoundValue, lengthAsPtr), unsure(undefinedLoop), unsure(mainLoopEntry)); |
| |
| LBasicBlock lastNext = m_out.appendTo(undefinedLoop, mainLoopEntry); |
| LValue previousIndex = m_out.phi(pointerType(), loopBound); |
| LValue currentIndex = m_out.sub(previousIndex, m_out.intPtrOne); |
| m_out.store64( |
| m_out.constInt64(JSValue::encode(jsUndefined())), |
| m_out.baseIndex(m_heaps.variables, targetStart, currentIndex)); |
| ValueFromBlock nextIndex = m_out.anchor(currentIndex); |
| m_out.addIncomingToPhi(previousIndex, nextIndex); |
| m_out.branch( |
| m_out.above(currentIndex, lengthAsPtr), unsure(undefinedLoop), unsure(mainLoopEntry)); |
| |
| m_out.appendTo(mainLoopEntry, mainLoop); |
| loopBound = m_out.anchor(lengthAsPtr); |
| m_out.branch(m_out.notNull(lengthAsPtr), unsure(mainLoop), unsure(continuation)); |
| |
| m_out.appendTo(mainLoop, continuation); |
| previousIndex = m_out.phi(pointerType(), loopBound); |
| currentIndex = m_out.sub(previousIndex, m_out.intPtrOne); |
| LValue value = m_out.load64( |
| m_out.baseIndex(m_heaps.variables, sourceStart, currentIndex)); |
| m_out.store64(value, m_out.baseIndex(m_heaps.variables, targetStart, currentIndex)); |
| nextIndex = m_out.anchor(currentIndex); |
| m_out.addIncomingToPhi(previousIndex, nextIndex); |
| m_out.branch(m_out.isNull(currentIndex), unsure(continuation), unsure(mainLoop)); |
| |
| m_out.appendTo(continuation, lastNext); |
| } |
| |
| LValue getSpreadLengthFromInlineCallFrame(InlineCallFrame* inlineCallFrame, unsigned numberOfArgumentsToSkip) |
| { |
| ArgumentsLength argumentsLength = getArgumentsLength(inlineCallFrame); |
| if (argumentsLength.isKnown) { |
| unsigned knownLength = argumentsLength.known; |
| if (knownLength >= numberOfArgumentsToSkip) |
| knownLength = knownLength - numberOfArgumentsToSkip; |
| else |
| knownLength = 0; |
| return m_out.constInt32(knownLength); |
| } |
| |
| |
| // We need to perform the same logical operation as the code above, but through dynamic operations. |
| if (!numberOfArgumentsToSkip) |
| return argumentsLength.value; |
| |
| LBasicBlock isLarger = m_out.newBlock(); |
| LBasicBlock continuation = m_out.newBlock(); |
| |
| ValueFromBlock smallerOrEqualLengthResult = m_out.anchor(m_out.constInt32(0)); |
| m_out.branch( |
| m_out.above(argumentsLength.value, m_out.constInt32(numberOfArgumentsToSkip)), unsure(isLarger), unsure(continuation)); |
| LBasicBlock lastNext = m_out.appendTo(isLarger, continuation); |
| ValueFromBlock largerLengthResult = m_out.anchor(m_out.sub(argumentsLength.value, m_out.constInt32(numberOfArgumentsToSkip))); |
| m_out.jump(continuation); |
| |
| m_out.appendTo(continuation, lastNext); |
| return m_out.phi(Int32, smallerOrEqualLengthResult, largerLengthResult); |
| } |
| |
| void compileForwardVarargsWithSpread() |
| { |
| HashMap<InlineCallFrame*, LValue, WTF::DefaultHash<InlineCallFrame*>::Hash, WTF::NullableHashTraits<InlineCallFrame*>> cachedSpreadLengths; |
| |
| Node* arguments = m_node->child1().node(); |
| RELEASE_ASSERT(arguments->op() == PhantomNewArrayWithSpread || arguments->op() == PhantomNewArrayBuffer || arguments->op() == PhantomSpread); |
| |
| unsigned numberOfStaticArguments = 0; |
| Vector<LValue, 2> spreadLengths; |
| |
| auto collectArgumentCount = recursableLambda([&](auto self, Node* target) -> void { |
| if (target->op() == PhantomSpread) { |
| self(target->child1().node()); |
| return; |
| } |
| |
| if (target->op() == PhantomNewArrayWithSpread) { |
| BitVector* bitVector = target->bitVector(); |
| for (unsigned i = 0; i < target->numChildren(); i++) { |
| if (bitVector->get(i)) |
| self(m_graph.varArgChild(target, i).node()); |
| else |
| ++numberOfStaticArguments; |
| } |
| return; |
| } |
| |
| if (target->op() == PhantomNewArrayBuffer) { |
| numberOfStaticArguments += target->castOperand<JSFixedArray*>()->length(); |
| return; |
| } |
| |
| ASSERT(target->op() == PhantomCreateRest); |
| InlineCallFrame* inlineCallFrame = target->origin.semantic.inlineCallFrame; |
| unsigned numberOfArgumentsToSkip = target->numberOfArgumentsToSkip(); |
| spreadLengths.append(cachedSpreadLengths.ensure(inlineCallFrame, [&] () { |
| return this->getSpreadLengthFromInlineCallFrame(inlineCallFrame, numberOfArgumentsToSkip); |
| }).iterator->value); |
| }); |
| |
| collectArgumentCount(arguments); |
| LValue lengthIncludingThis = m_out.constInt32(1 + numberOfStaticArguments); |
| for (LValue length : spreadLengths) |
| lengthIncludingThis = m_out.add(lengthIncludingThis, length); |
| |
| LoadVarargsData* data = m_node->loadVarargsData(); |
| speculate( |
| VarargsOverflow, noValue(), nullptr, |
| m_out.above(lengthIncludingThis, m_out.constInt32(data->limit))); |
| |
| m_out.store32(lengthIncludingThis, payloadFor(data->machineCount)); |
| |
| LValue targetStart = addressFor(data->machineStart).value(); |
| |
| auto forwardSpread = recursableLambda([this, &cachedSpreadLengths, &targetStart](auto self, Node* target, LValue storeIndex) -> LValue { |
| if (target->op() == PhantomSpread) |
| return self(target->child1().node(), storeIndex); |
| |
| if (target->op() == PhantomNewArrayWithSpread) { |
| BitVector* bitVector = target->bitVector(); |
| for (unsigned i = 0; i < target->numChildren(); i++) { |
| if (bitVector->get(i)) |
| storeIndex = self(m_graph.varArgChild(target, i).node(), storeIndex); |
| else { |
| LValue value = this->lowJSValue(m_graph.varArgChild(target, i)); |
| m_out.store64(value, m_out.baseIndex(m_heaps.variables, targetStart, storeIndex)); |
| storeIndex = m_out.add(m_out.constIntPtr(1), storeIndex); |
| } |
| } |
| return storeIndex; |
| } |
| |
| if (target->op() == PhantomNewArrayBuffer) { |
| auto* array = target->castOperand<JSFixedArray*>(); |
| for (unsigned i = 0; i < array->length(); i++) { |
| // Because forwarded values are drained as JSValue, we should not generate value |
| // in Double form even if PhantomNewArrayBuffer's indexingType is ArrayWithDouble. |
| int64_t value = JSValue::encode(array->get(i)); |
| m_out.store64(m_out.constInt64(value), m_out.baseIndex(m_heaps.variables, targetStart, storeIndex, JSValue(), (Checked<int32_t>(sizeof(Register)) * i).unsafeGet())); |
| } |
| return m_out.add(m_out.constIntPtr(array->length()), storeIndex); |
| } |
| |
| RELEASE_ASSERT(target->op() == PhantomCreateRest); |
| InlineCallFrame* inlineCallFrame = target->origin.semantic.inlineCallFrame; |
| |
| LValue sourceStart = this->getArgumentsStart(inlineCallFrame, target->numberOfArgumentsToSkip()); |
| LValue spreadLength = m_out.zeroExtPtr(cachedSpreadLengths.get(inlineCallFrame)); |
| |
| LBasicBlock loop = m_out.newBlock(); |
| LBasicBlock continuation = m_out.newBlock(); |
| ValueFromBlock startLoadIndex = m_out.anchor(m_out.constIntPtr(0)); |
| ValueFromBlock startStoreIndex = m_out.anchor(storeIndex); |
| ValueFromBlock startStoreIndexForEnd = m_out.anchor(storeIndex); |
| |
| m_out.branch(m_out.isZero64(spreadLength), unsure(continuation), unsure(loop)); |
| |
| LBasicBlock lastNext = m_out.appendTo(loop, continuation); |
| LValue loopStoreIndex = m_out.phi(Int64, startStoreIndex); |
| LValue loadIndex = m_out.phi(Int64, startLoadIndex); |
| LValue value = m_out.load64( |
| m_out.baseIndex(m_heaps.variables, sourceStart, loadIndex)); |
| m_out.store64(value, m_out.baseIndex(m_heaps.variables, targetStart, loopStoreIndex)); |
| LValue nextLoadIndex = m_out.add(m_out.constIntPtr(1), loadIndex); |
| m_out.addIncomingToPhi(loadIndex, m_out.anchor(nextLoadIndex)); |
| LValue nextStoreIndex = m_out.add(m_out.constIntPtr(1), loopStoreIndex); |
| m_out.addIncomingToPhi(loopStoreIndex, m_out.anchor(nextStoreIndex)); |
| ValueFromBlock loopStoreIndexForEnd = m_out.anchor(nextStoreIndex); |
| m_out.branch(m_out.below(nextLoadIndex, spreadLength), unsure(loop), unsure(continuation)); |
| |
| m_out.appendTo(continuation, lastNext); |
| return m_out.phi(Int64, startStoreIndexForEnd, loopStoreIndexForEnd); |
| }); |
| |
| LValue storeIndex = forwardSpread(arguments, m_out.constIntPtr(0)); |
| |
| LBasicBlock undefinedLoop = m_out.newBlock(); |
| LBasicBlock continuation = m_out.newBlock(); |
| |
| ValueFromBlock startStoreIndex = m_out.anchor(storeIndex); |
| LValue loopBoundValue = m_out.constIntPtr(data->mandatoryMinimum); |
| m_out.branch(m_out.below(storeIndex, loopBoundValue), |
| unsure(undefinedLoop), unsure(continuation)); |
| |
| LBasicBlock lastNext = m_out.appendTo(undefinedLoop, continuation); |
| LValue loopStoreIndex = m_out.phi(Int64, startStoreIndex); |
| m_out.store64( |
| m_out.constInt64(JSValue::encode(jsUndefined())), |
| m_out.baseIndex(m_heaps.variables, targetStart, loopStoreIndex)); |
| LValue nextIndex = m_out.add(loopStoreIndex, m_out.constIntPtr(1)); |
| m_out.addIncomingToPhi(loopStoreIndex, m_out.anchor(nextIndex)); |
| m_out.branch( |
| m_out.below(nextIndex, loopBoundValue), unsure(undefinedLoop), unsure(continuation)); |
| |
| m_out.appendTo(continuation, lastNext); |
| } |
| |
| void compileJump() |
| { |
| m_out.jump(lowBlock(m_node->targetBlock())); |
| } |
| |
| void compileBranch() |
| { |
| m_out.branch( |
| boolify(m_node->child1()), |
| WeightedTarget( |
| lowBlock(m_node->branchData()->taken.block), |
| m_node->branchData()->taken.count), |
| WeightedTarget( |
| lowBlock(m_node->branchData()->notTaken.block), |
| m_node->branchData()->notTaken.count)); |
| } |
| |
| void compileSwitch() |
| { |
| SwitchData* data = m_node->switchData(); |
| switch (data->kind) { |
| case SwitchImm: { |
| Vector<ValueFromBlock, 2> intValues; |
| LBasicBlock switchOnInts = m_out.newBlock(); |
| |
| LBasicBlock lastNext = m_out.appendTo(m_out.m_block, switchOnInts); |
| |
| switch (m_node->child1().useKind()) { |
| case Int32Use: { |
| intValues.append(m_out.anchor(lowInt32(m_node->child1()))); |
| m_out.jump(switchOnInts); |
| break; |
| } |
| |
| case UntypedUse: { |
| LBasicBlock isInt = m_out.newBlock(); |
| LBasicBlock isNotInt = m_out.newBlock(); |
| LBasicBlock isDouble = m_out.newBlock(); |
| |
| LValue boxedValue = lowJSValue(m_node->child1()); |
| m_out.branch(isNotInt32(boxedValue), unsure(isNotInt), unsure(isInt)); |
| |
| LBasicBlock innerLastNext = m_out.appendTo(isInt, isNotInt); |
| |
| intValues.append(m_out.anchor(unboxInt32(boxedValue))); |
| m_out.jump(switchOnInts); |
| |
| m_out.appendTo(isNotInt, isDouble); |
| m_out.branch( |
| isCellOrMisc(boxedValue, provenType(m_node->child1())), |
| usually(lowBlock(data->fallThrough.block)), rarely(isDouble)); |
| |
| m_out.appendTo(isDouble, innerLastNext); |
| LValue doubleValue = unboxDouble(boxedValue); |
| LValue intInDouble = m_out.doubleToInt(doubleValue); |
| intValues.append(m_out.anchor(intInDouble)); |
| m_out.branch( |
| m_out.doubleEqual(m_out.intToDouble(intInDouble), doubleValue), |
| unsure(switchOnInts), unsure(lowBlock(data->fallThrough.block))); |
| break; |
| } |
| |
| default: |
| DFG_CRASH(m_graph, m_node, "Bad use kind"); |
| break; |
| } |
| |
| m_out.appendTo(switchOnInts, lastNext); |
| buildSwitch(data, Int32, m_out.phi(Int32, intValues)); |
| return; |
| } |
| |
| case SwitchChar: { |
| LValue stringValue; |
| |
| // FIXME: We should use something other than unsure() for the branch weight |
| // of the fallThrough block. The main challenge is just that we have multiple |
| // branches to fallThrough but a single count, so we would need to divvy it up |
| // among the different lowered branches. |
| // https://bugs.webkit.org/show_bug.cgi?id=129082 |
| |
| switch (m_node->child1().useKind()) { |
| case StringUse: { |
| stringValue = lowString(m_node->child1()); |
| break; |
| } |
| |
| case UntypedUse: { |
| LValue unboxedValue = lowJSValue(m_node->child1()); |
| |
| LBasicBlock isCellCase = m_out.newBlock(); |
| LBasicBlock isStringCase = m_out.newBlock(); |
| |
| m_out.branch( |
| isNotCell(unboxedValue, provenType(m_node->child1())), |
| unsure(lowBlock(data->fallThrough.block)), unsure(isCellCase)); |
| |
| LBasicBlock lastNext = m_out.appendTo(isCellCase, isStringCase); |
| LValue cellValue = unboxedValue; |
| m_out.branch( |
| isNotString(cellValue, provenType(m_node->child1())), |
| unsure(lowBlock(data->fallThrough.block)), unsure(isStringCase)); |
| |
| m_out.appendTo(isStringCase, lastNext); |
| stringValue = cellValue; |
| break; |
| } |
| |
| default: |
| DFG_CRASH(m_graph, m_node, "Bad use kind"); |
| break; |
| } |
| |
| LBasicBlock lengthIs1 = m_out.newBlock(); |
| LBasicBlock needResolution = m_out.newBlock(); |
| LBasicBlock resolved = m_out.newBlock(); |
| LBasicBlock is8Bit = m_out.newBlock(); |
| LBasicBlock is16Bit = m_out.newBlock(); |
| LBasicBlock continuation = m_out.newBlock(); |
| |
| m_out.branch( |
| m_out.notEqual( |
| m_out.load32NonNegative(stringValue, m_heaps.JSString_length), |
| m_out.int32One), |
| unsure(lowBlock(data->fallThrough.block)), unsure(lengthIs1)); |
| |
| LBasicBlock lastNext = m_out.appendTo(lengthIs1, needResolution); |
| Vector<ValueFromBlock, 2> values; |
| LValue fastValue = m_out.loadPtr(stringValue, m_heaps.JSString_value); |
| values.append(m_out.anchor(fastValue)); |
| m_out.branch(m_out.isNull(fastValue), rarely(needResolution), usually(resolved)); |
| |
| m_out.appendTo(needResolution, resolved); |
| values.append(m_out.anchor( |
| vmCall(pointerType(), m_out.operation(operationResolveRope), m_callFrame, stringValue))); |
| m_out.jump(resolved); |
| |
| m_out.appendTo(resolved, is8Bit); |
| LValue value = m_out.phi(pointerType(), values); |
| LValue characterData = m_out.loadPtr(value, m_heaps.StringImpl_data); |
| m_out.branch( |
| m_out.testNonZero32( |
| m_out.load32(value, m_heaps.StringImpl_hashAndFlags), |
| m_out.constInt32(StringImpl::flagIs8Bit())), |
| unsure(is8Bit), unsure(is16Bit)); |
| |
| Vector<ValueFromBlock, 2> characters; |
| m_out.appendTo(is8Bit, is16Bit); |
| characters.append(m_out.anchor(m_out.load8ZeroExt32(characterData, m_heaps.characters8[0]))); |
| m_out.jump(continuation); |
| |
| m_out.appendTo(is16Bit, continuation); |
| characters.append(m_out.anchor(m_out.load16ZeroExt32(characterData, m_heaps.characters16[0]))); |
| m_out.jump(continuation); |
| |
| m_out.appendTo(continuation, lastNext); |
| buildSwitch(data, Int32, m_out.phi(Int32, characters)); |
| return; |
| } |
| |
| case SwitchString: { |
| switch (m_node->child1().useKind()) { |
| case StringIdentUse: { |
| LValue stringImpl = lowStringIdent(m_node->child1()); |
| |
| Vector<SwitchCase> cases; |
| for (unsigned i = 0; i < data->cases.size(); ++i) { |
| LValue value = m_out.constIntPtr(data->cases[i].value.stringImpl()); |
| LBasicBlock block = lowBlock(data->cases[i].target.block); |
| Weight weight = Weight(data->cases[i].target.count); |
| cases.append(SwitchCase(value, block, weight)); |
| } |
| |
| m_out.switchInstruction( |
| stringImpl, cases, lowBlock(data->fallThrough.block), |
| Weight(data->fallThrough.count)); |
| return; |
| } |
| |
| case StringUse: { |
| switchString(data, lowString(m_node->child1())); |
| return; |
| } |
| |
| case UntypedUse: { |
| LValue value = lowJSValue(m_node->child1()); |
| |
| LBasicBlock isCellBlock = m_out.newBlock(); |
| LBasicBlock isStringBlock = m_out.newBlock(); |
| |
| m_out.branch( |
| isCell(value, provenType(m_node->child1())), |
| unsure(isCellBlock), unsure(lowBlock(data->fallThrough.block))); |
| |
| LBasicBlock lastNext = m_out.appendTo(isCellBlock, isStringBlock); |
| |
| m_out.branch( |
| isString(value, provenType(m_node->child1())), |
| unsure(isStringBlock), unsure(lowBlock(data->fallThrough.block))); |
| |
| m_out.appendTo(isStringBlock, lastNext); |
| |
| switchString(data, value); |
| return; |
| } |
| |
| default: |
| DFG_CRASH(m_graph, m_node, "Bad use kind"); |
| return; |
| } |
| return; |
| } |
| |
| case SwitchCell: { |
| LValue cell; |
| switch (m_node->child1().useKind()) { |
| case CellUse: { |
| cell = lowCell(m_node->child1()); |
| break; |
| } |
| |
| case UntypedUse: { |
| LValue value = lowJSValue(m_node->child1()); |
| LBasicBlock cellCase = m_out.newBlock(); |
| m_out.branch( |
| isCell(value, provenType(m_node->child1())), |
| unsure(cellCase), unsure(lowBlock(data->fallThrough.block))); |
| m_out.appendTo(cellCase); |
| cell = value; |
| break; |
| } |
| |
| default: |
| DFG_CRASH(m_graph, m_node, "Bad use kind"); |
| return; |
| } |
| |
| buildSwitch(m_node->switchData(), pointerType(), cell); |
| return; |
| } } |
| |
| DFG_CRASH(m_graph, m_node, "Bad switch kind"); |
| } |
| |
| void compileEntrySwitch() |
| { |
| Vector<LBasicBlock> successors; |
| for (DFG::BasicBlock* successor : m_node->entrySwitchData()->cases) |
| successors.append(lowBlock(successor)); |
| m_out.entrySwitch(successors); |
| } |
| |
| void compileReturn() |
| { |
| m_out.ret(lowJSValue(m_node->child1())); |
| } |
| |
| void compileForceOSRExit() |
| { |
| terminate(InadequateCoverage); |
| } |
| |
| void compileCPUIntrinsic() |
| { |
| #if CPU(X86_64) |
| Intrinsic intrinsic = m_node->intrinsic(); |
| switch (intrinsic) { |
| case CPUMfenceIntrinsic: |
| case CPUCpuidIntrinsic: |
| case CPUPauseIntrinsic: { |
| PatchpointValue* patchpoint = m_out.patchpoint(Void); |
| patchpoint->effects = Effects::forCall(); |
| if (intrinsic == CPUCpuidIntrinsic) |
| patchpoint->clobber(RegisterSet { X86Registers::eax, X86Registers::ebx, X86Registers::ecx, X86Registers::edx }); |
| |
| patchpoint->setGenerator([=] (CCallHelpers& jit, const B3::StackmapGenerationParams&) { |
| switch (intrinsic) { |
| case CPUMfenceIntrinsic: |
| jit.mfence(); |
| break; |
| case CPUCpuidIntrinsic: |
| jit.cpuid(); |
| break; |
| case CPUPauseIntrinsic: |
| jit.pause(); |
| break; |
| default: |
| RELEASE_ASSERT_NOT_REACHED(); |
| } |
| }); |
| setJSValue(m_out.constInt64(JSValue::encode(jsUndefined()))); |
| break; |
| } |
| case CPURdtscIntrinsic: { |
| PatchpointValue* patchpoint = m_out.patchpoint(Int32); |
| patchpoint->effects = Effects::forCall(); |
| patchpoint->clobber(RegisterSet { X86Registers::eax, X86Registers::edx }); |
| // The low 32-bits of rdtsc go into rax. |
| patchpoint->resultConstraint = ValueRep::reg(X86Registers::eax); |
| patchpoint->setGenerator( [=] (CCallHelpers& jit, const B3::StackmapGenerationParams&) { |
| jit.rdtsc(); |
| }); |
| setJSValue(boxInt32(patchpoint)); |
| break; |
| } |
| default: |
| RELEASE_ASSERT_NOT_REACHED(); |
| |
| } |
| #endif |
| } |
| |
| void compileThrow() |
| { |
| LValue error = lowJSValue(m_node->child1()); |
| vmCall(Void, m_out.operation(operationThrowDFG), m_callFrame, error); |
| // vmCall() does an exception check so we should never reach this. |
| m_out.unreachable(); |
| } |
| |
| void compileThrowStaticError() |
| { |
| LValue errorMessage = lowString(m_node->child1()); |
| LValue errorType = m_out.constInt32(m_node->errorType()); |
| vmCall(Void, m_out.operation(operationThrowStaticError), m_callFrame, errorMessage, errorType); |
| // vmCall() does an exception check so we should never reach this. |
| m_out.unreachable(); |
| } |
| |
| void compileInvalidationPoint() |
| { |
| if (verboseCompilationEnabled()) |
| dataLog(" Invalidation point with availability: ", availabilityMap(), "\n"); |
| |
| DFG_ASSERT(m_graph, m_node, m_origin.exitOK); |
| |
| PatchpointValue* patchpoint = m_out.patchpoint(Void); |
| OSRExitDescriptor* descriptor = appendOSRExitDescriptor(noValue(), nullptr); |
| NodeOrigin origin = m_origin; |
| patchpoint->appendColdAnys(buildExitArguments(descriptor, origin.forExit, noValue())); |
| |
| State* state = &m_ftlState; |
| |
| patchpoint->setGenerator( |
| [=] (CCallHelpers& jit, const B3::StackmapGenerationParams& params) { |
| // The MacroAssembler knows more about this than B3 does. The watchpointLabel() method |
| // will ensure that this is followed by a nop shadow but only when this is actually |
| // necessary. |
| CCallHelpers::Label label = jit.watchpointLabel(); |
| |
| RefPtr<OSRExitHandle> handle = descriptor->emitOSRExitLater( |
| *state, UncountableInvalidation, origin, params); |
| |
| RefPtr<JITCode> jitCode = state->jitCode.get(); |
| |
| jit.addLinkTask( |
| [=] (LinkBuffer& linkBuffer) { |
| JumpReplacement jumpReplacement( |
| linkBuffer.locationOf<JSInternalPtrTag>(label), |
| linkBuffer.locationOf<OSRExitPtrTag>(handle->label)); |
| jitCode->common.jumpReplacements.append(jumpReplacement); |
| }); |
| }); |
| |
| // Set some obvious things. |
| patchpoint->effects.terminal = false; |
| patchpoint->effects.writesLocalState = false; |
| patchpoint->effects.readsLocalState = false; |
| |
| // This is how we tell B3 about the possibility of jump replacement. |
| patchpoint->effects.exitsSideways = true; |
| |
| // It's not possible for some prior branch to determine the safety of this operation. It's always |
| // fine to execute this on some path that wouldn't have originally executed it before |
| // optimization. |
| patchpoint->effects.controlDependent = false; |
| |
| // If this falls through then it won't write anything. |
| patchpoint->effects.writes = HeapRange(); |
| |
| // When this abruptly terminates, it could read any heap location. |
| patchpoint->effects.reads = HeapRange::top(); |
| } |
| |
| void compileIsEmpty() |
| { |
| setBoolean(m_out.isZero64(lowJSValue(m_node->child1()))); |
| } |
| |
| void compileIsUndefined() |
| { |
| setBoolean(equalNullOrUndefined(m_node->child1(), AllCellsAreFalse, EqualUndefined)); |
| } |
| |
| void compileIsBoolean() |
| { |
| setBoolean(isBoolean(lowJSValue(m_node->child1()), provenType(m_node->child1()))); |
| } |
| |
| void compileIsNumber() |
| { |
| setBoolean(isNumber(lowJSValue(m_node->child1()), provenType(m_node->child1()))); |
| } |
| |
| void compileNumberIsInteger() |
| { |
| LBasicBlock notInt32 = m_out.newBlock(); |
| LBasicBlock doubleCase = m_out.newBlock(); |
| LBasicBlock doubleNotNanOrInf = m_out.newBlock(); |
| LBasicBlock continuation = m_out.newBlock(); |
| |
| LValue input = lowJSValue(m_node->child1()); |
| |
| ValueFromBlock trueResult = m_out.anchor(m_out.booleanTrue); |
| m_out.branch( |
| isInt32(input, provenType(m_node->child1())), unsure(continuation), unsure(notInt32)); |
| |
| LBasicBlock lastNext = m_out.appendTo(notInt32, doubleCase); |
| ValueFromBlock falseResult = m_out.anchor(m_out.booleanFalse); |
| m_out.branch( |
| isNotNumber(input, provenType(m_node->child1())), unsure(continuation), unsure(doubleCase)); |
| |
| m_out.appendTo(doubleCase, doubleNotNanOrInf); |
| LValue doubleAsInt; |
| LValue asDouble = unboxDouble(input, &doubleAsInt); |
| LValue expBits = m_out.bitAnd(m_out.lShr(doubleAsInt, m_out.constInt32(52)), m_out.constInt64(0x7ff)); |
| m_out.branch( |
| m_out.equal(expBits, m_out.constInt64(0x7ff)), |
| unsure(continuation), unsure(doubleNotNanOrInf)); |
| |
| m_out.appendTo(doubleNotNanOrInf, continuation); |
| B3::PatchpointValue* patchpoint = m_out.patchpoint(Int32); |
| patchpoint->appendSomeRegister(asDouble); |
| patchpoint->numFPScratchRegisters = 1; |
| patchpoint->effects = Effects::none(); |
| patchpoint->setGenerator([=] (CCallHelpers& jit, const StackmapGenerationParams& params) { |
| GPRReg result = params[0].gpr(); |
| FPRReg input = params[1].fpr(); |
| FPRReg temp = params.fpScratch(0); |
| jit.roundTowardZeroDouble(input, temp); |
| jit.compareDouble(MacroAssembler::DoubleEqual, input, temp, result); |
| }); |
| ValueFromBlock patchpointResult = m_out.anchor(patchpoint); |
| m_out.jump(continuation); |
| |
| m_out.appendTo(continuation, lastNext); |
| setBoolean(m_out.phi(Int32, trueResult, falseResult, patchpointResult)); |
| } |
| |
| void compileIsCellWithType() |
| { |
| if (m_node->child1().useKind() == UntypedUse) { |
| LValue value = lowJSValue(m_node->child1()); |
| |
| LBasicBlock isCellCase = m_out.newBlock(); |
| LBasicBlock continuation = m_out.newBlock(); |
| |
| ValueFromBlock notCellResult = m_out.anchor(m_out.booleanFalse); |
| m_out.branch( |
| isCell(value, provenType(m_node->child1())), unsure(isCellCase), unsure(continuation)); |
| |
| LBasicBlock lastNext = m_out.appendTo(isCellCase, continuation); |
| ValueFromBlock cellResult = m_out.anchor(isCellWithType(value, m_node->queriedType(), m_node->speculatedTypeForQuery(), provenType(m_node->child1()))); |
| m_out.jump(continuation); |
| |
| m_out.appendTo(continuation, lastNext); |
| setBoolean(m_out.phi(Int32, notCellResult, cellResult)); |
| } else { |
| ASSERT(m_node->child1().useKind() == CellUse); |
| setBoolean(isCellWithType(lowCell(m_node->child1()), m_node->queriedType(), m_node->speculatedTypeForQuery(), provenType(m_node->child1()))); |
| } |
| } |
| |
| void compileIsObject() |
| { |
| LValue value = lowJSValue(m_node->child1()); |
| |
| LBasicBlock isCellCase = m_out.newBlock(); |
| LBasicBlock continuation = m_out.newBlock(); |
| |
| ValueFromBlock notCellResult = m_out.anchor(m_out.booleanFalse); |
| m_out.branch( |
| isCell(value, provenType(m_node->child1())), unsure(isCellCase), unsure(continuation)); |
| |
| LBasicBlock lastNext = m_out.appendTo(isCellCase, continuation); |
| ValueFromBlock cellResult = m_out.anchor(isObject(value, provenType(m_node->child1()))); |
| m_out.jump(continuation); |
| |
| m_out.appendTo(continuation, lastNext); |
| setBoolean(m_out.phi(Int32, notCellResult, cellResult)); |
| } |
| |
| LValue wangsInt64Hash(LValue input) |
| { |
| // key += ~(key << 32); |
| LValue key = input; |
| LValue temp = key; |
| temp = m_out.shl(temp, m_out.constInt32(32)); |
| temp = m_out.bitNot(temp); |
| key = m_out.add(key, temp); |
| // key ^= (key >> 22); |
| temp = key; |
| temp = m_out.lShr(temp, m_out.constInt32(22)); |
| key = m_out.bitXor(key, temp); |
| // key += ~(key << 13); |
| temp = key; |
| temp = m_out.shl(temp, m_out.constInt32(13)); |
| temp = m_out.bitNot(temp); |
| key = m_out.add(key, temp); |
| // key ^= (key >> 8); |
| temp = key; |
| temp = m_out.lShr(temp, m_out.constInt32(8)); |
| key = m_out.bitXor(key, temp); |
| // key += (key << 3); |
| temp = key; |
| temp = m_out.shl(temp, m_out.constInt32(3)); |
| key = m_out.add(key, temp); |
| // key ^= (key >> 15); |
| temp = key; |
| temp = m_out.lShr(temp, m_out.constInt32(15)); |
| key = m_out.bitXor(key, temp); |
| // key += ~(key << 27); |
| temp = key; |
| temp = m_out.shl(temp, m_out.constInt32(27)); |
| temp = m_out.bitNot(temp); |
| key = m_out.add(key, temp); |
| // key ^= (key >> 31); |
| temp = key; |
| temp = m_out.lShr(temp, m_out.constInt32(31)); |
| key = m_out.bitXor(key, temp); |
| key = m_out.castToInt32(key); |
| |
| return key; |
| } |
| |
| LValue mapHashString(LValue string) |
| { |
| LBasicBlock nonEmptyStringCase = m_out.newBlock(); |
| LBasicBlock slowCase = m_out.newBlock(); |
| LBasicBlock continuation = m_out.newBlock(); |
| |
| LValue stringImpl = m_out.loadPtr(string, m_heaps.JSString_value); |
| m_out.branch( |
| m_out.equal(stringImpl, m_out.constIntPtr(0)), unsure(slowCase), unsure(nonEmptyStringCase)); |
| |
| LBasicBlock lastNext = m_out.appendTo(nonEmptyStringCase, slowCase); |
| LValue hash = m_out.lShr(m_out.load32(stringImpl, m_heaps.StringImpl_hashAndFlags), m_out.constInt32(StringImpl::s_flagCount)); |
| ValueFromBlock nonEmptyStringHashResult = m_out.anchor(hash); |
| m_out.branch(m_out.equal(hash, m_out.constInt32(0)), |
| unsure(slowCase), unsure(continuation)); |
| |
| m_out.appendTo(slowCase, continuation); |
| ValueFromBlock slowResult = m_out.anchor( |
| vmCall(Int32, m_out.operation(operationMapHash), m_callFrame, string)); |
| m_out.jump(continuation); |
| |
| m_out.appendTo(continuation, lastNext); |
| return m_out.phi(Int32, slowResult, nonEmptyStringHashResult); |
| } |
| |
| void compileMapHash() |
| { |
| switch (m_node->child1().useKind()) { |
| case BooleanUse: |
| case Int32Use: |
| case SymbolUse: |
| case ObjectUse: { |
| LValue key = lowJSValue(m_node->child1(), ManualOperandSpeculation); |
| speculate(m_node->child1()); |
| setInt32(wangsInt64Hash(key)); |
| return; |
| } |
| |
| case CellUse: { |
| LBasicBlock isString = m_out.newBlock(); |
| LBasicBlock notString = m_out.newBlock(); |
| LBasicBlock continuation = m_out.newBlock(); |
| |
| LValue value = lowCell(m_node->child1()); |
| LValue isStringValue = m_out.equal(m_out.load8ZeroExt32(value, m_heaps.JSCell_typeInfoType), m_out.constInt32(StringType)); |
| m_out.branch( |
| isStringValue, unsure(isString), unsure(notString)); |
| |
| LBasicBlock lastNext = m_out.appendTo(isString, notString); |
| ValueFromBlock stringResult = m_out.anchor(mapHashString(value)); |
| m_out.jump(continuation); |
| |
| m_out.appendTo(notString, continuation); |
| ValueFromBlock notStringResult = m_out.anchor(wangsInt64Hash(value)); |
| m_out.jump(continuation); |
| |
| m_out.appendTo(continuation, lastNext); |
| setInt32(m_out.phi(Int32, stringResult, notStringResult)); |
| return; |
| } |
| |
| case StringUse: { |
| LValue string = lowString(m_node->child1()); |
| setInt32(mapHashString(string)); |
| return; |
| } |
| |
| default: |
| RELEASE_ASSERT(m_node->child1().useKind() == UntypedUse); |
| break; |
| } |
| |
| LValue value = lowJSValue(m_node->child1()); |
| |
| LBasicBlock isCellCase = m_out.newBlock(); |
| LBasicBlock slowCase = m_out.newBlock(); |
| LBasicBlock straightHash = m_out.newBlock(); |
| LBasicBlock isStringCase = m_out.newBlock(); |
| LBasicBlock nonEmptyStringCase = m_out.newBlock(); |
| LBasicBlock continuation = m_out.newBlock(); |
| |
| m_out.branch( |
| isCell(value, provenType(m_node->child1())), unsure(isCellCase), unsure(straightHash)); |
| |
| LBasicBlock lastNext = m_out.appendTo(isCellCase, isStringCase); |
| LValue isString = m_out.equal(m_out.load8ZeroExt32(value, m_heaps.JSCell_typeInfoType), m_out.constInt32(StringType)); |
| m_out.branch( |
| isString, unsure(isStringCase), unsure(straightHash)); |
| |
| m_out.appendTo(isStringCase, nonEmptyStringCase); |
| LValue stringImpl = m_out.loadPtr(value, m_heaps.JSString_value); |
| m_out.branch( |
| m_out.equal(stringImpl, m_out.constIntPtr(0)), rarely(slowCase), usually(nonEmptyStringCase)); |
| |
| m_out.appendTo(nonEmptyStringCase, straightHash); |
| LValue hash = m_out.lShr(m_out.load32(stringImpl, m_heaps.StringImpl_hashAndFlags), m_out.constInt32(StringImpl::s_flagCount)); |
| ValueFromBlock nonEmptyStringHashResult = m_out.anchor(hash); |
| m_out.branch(m_out.equal(hash, m_out.constInt32(0)), |
| unsure(slowCase), unsure(continuation)); |
| |
| m_out.appendTo(straightHash, slowCase); |
| ValueFromBlock fastResult = m_out.anchor(wangsInt64Hash(value)); |
| m_out.jump(continuation); |
| |
| m_out.appendTo(slowCase, continuation); |
| ValueFromBlock slowResult = m_out.anchor( |
| vmCall(Int32, m_out.operation(operationMapHash), m_callFrame, value)); |
| m_out.jump(continuation); |
| |
| m_out.appendTo(continuation, lastNext); |
| setInt32(m_out.phi(Int32, fastResult, slowResult, nonEmptyStringHashResult)); |
| } |
| |
| void compileNormalizeMapKey() |
| { |
| ASSERT(m_node->child1().useKind() == UntypedUse); |
| |
| LBasicBlock isNumberCase = m_out.newBlock(); |
| LBasicBlock notInt32NumberCase = m_out.newBlock(); |
| LBasicBlock notNaNCase = m_out.newBlock(); |
| LBasicBlock convertibleCase = m_out.newBlock(); |
| LBasicBlock continuation = m_out.newBlock(); |
| |
| LBasicBlock lastNext = m_out.insertNewBlocksBefore(isNumberCase); |
| |
| LValue key = lowJSValue(m_node->child1()); |
| ValueFromBlock fastResult = m_out.anchor(key); |
| m_out.branch(isNotNumber(key), unsure(continuation), unsure(isNumberCase)); |
| |
| m_out.appendTo(isNumberCase, notInt32NumberCase); |
| m_out.branch(isInt32(key), unsure(continuation), unsure(notInt32NumberCase)); |
| |
| m_out.appendTo(notInt32NumberCase, notNaNCase); |
| LValue doubleValue = unboxDouble(key); |
| m_out.branch(m_out.doubleNotEqualOrUnordered(doubleValue, doubleValue), unsure(continuation), unsure(notNaNCase)); |
| |
| m_out.appendTo(notNaNCase, convertibleCase); |
| LValue integerValue = m_out.doubleToInt(doubleValue); |
| LValue integerValueConvertedToDouble = m_out.intToDouble(integerValue); |
| m_out.branch(m_out.doubleNotEqualOrUnordered(doubleValue, integerValueConvertedToDouble), unsure(continuation), unsure(convertibleCase)); |
| |
| m_out.appendTo(convertibleCase, continuation); |
| ValueFromBlock slowResult = m_out.anchor(boxInt32(integerValue)); |
| m_out.jump(continuation); |
| |
| m_out.appendTo(continuation, lastNext); |
| setJSValue(m_out.phi(Int64, fastResult, slowResult)); |
| } |
| |
| void compileGetMapBucket() |
| { |
| LBasicBlock loopStart = m_out.newBlock(); |
| LBasicBlock loopAround = m_out.newBlock(); |
| LBasicBlock slowPath = m_out.newBlock(); |
| LBasicBlock notPresentInTable = m_out.newBlock(); |
| LBasicBlock notEmptyValue = m_out.newBlock(); |
| LBasicBlock notDeletedValue = m_out.newBlock(); |
| LBasicBlock continuation = m_out.newBlock(); |
| |
| LBasicBlock lastNext = m_out.insertNewBlocksBefore(loopStart); |
| |
| LValue map; |
| if (m_node->child1().useKind() == MapObjectUse) |
| map = lowMapObject(m_node->child1()); |
| else if (m_node->child1().useKind() == SetObjectUse) |
| map = lowSetObject(m_node->child1()); |
| else |
| RELEASE_ASSERT_NOT_REACHED(); |
| |
| LValue key = lowJSValue(m_node->child2(), ManualOperandSpeculation); |
| if (m_node->child2().useKind() != UntypedUse) |
| speculate(m_node->child2()); |
| |
| LValue hash = lowInt32(m_node->child3()); |
| |
| LValue buffer = m_out.loadPtr(map, m_heaps.HashMapImpl_buffer); |
| LValue mask = m_out.sub(m_out.load32(map, m_heaps.HashMapImpl_capacity), m_out.int32One); |
| |
| ValueFromBlock indexStart = m_out.anchor(hash); |
| m_out.jump(loopStart); |
| |
| m_out.appendTo(loopStart, notEmptyValue); |
| LValue unmaskedIndex = m_out.phi(Int32, indexStart); |
| LValue index = m_out.bitAnd(mask, unmaskedIndex); |
| // FIXME: I think these buffers are caged? |
| // https://bugs.webkit.org/show_bug.cgi?id=174925 |
| LValue hashMapBucket = m_out.load64(m_out.baseIndex(m_heaps.properties.atAnyNumber(), buffer, m_out.zeroExt(index, Int64), ScaleEight)); |
| ValueFromBlock bucketResult = m_out.anchor(hashMapBucket); |
| m_out.branch(m_out.equal(hashMapBucket, m_out.constIntPtr(bitwise_cast<intptr_t>(HashMapImpl<HashMapBucket<HashMapBucketDataKey>>::emptyValue()))), |
| unsure(notPresentInTable), unsure(notEmptyValue)); |
| |
| m_out.appendTo(notEmptyValue, notDeletedValue); |
| m_out.branch(m_out.equal(hashMapBucket, m_out.constIntPtr(bitwise_cast<intptr_t>(HashMapImpl<HashMapBucket<HashMapBucketDataKey>>::deletedValue()))), |
| unsure(loopAround), unsure(notDeletedValue)); |
| |
| m_out.appendTo(notDeletedValue, loopAround); |
| LValue bucketKey = m_out.load64(hashMapBucket, m_heaps.HashMapBucket_key); |
| |
| // Perform Object.is() |
| switch (m_node->child2().useKind()) { |
| case BooleanUse: |
| case Int32Use: |
| case SymbolUse: |
| case ObjectUse: { |
| m_out.branch(m_out.equal(key, bucketKey), |
| unsure(continuation), unsure(loopAround)); |
| break; |
| } |
| case StringUse: { |
| LBasicBlock notBitEqual = m_out.newBlock(); |
| LBasicBlock bucketKeyIsCell = m_out.newBlock(); |
| |
| m_out.branch(m_out.equal(key, bucketKey), |
| unsure(continuation), unsure(notBitEqual)); |
| |
| m_out.appendTo(notBitEqual, bucketKeyIsCell); |
| m_out.branch(isCell(bucketKey), |
| unsure(bucketKeyIsCell), unsure(loopAround)); |
| |
| m_out.appendTo(bucketKeyIsCell, loopAround); |
| m_out.branch(isString(bucketKey), |
| unsure(slowPath), unsure(loopAround)); |
| break; |
| } |
| case CellUse: { |
| LBasicBlock notBitEqual = m_out.newBlock(); |
| LBasicBlock bucketKeyIsCell = m_out.newBlock(); |
| LBasicBlock bucketKeyIsString = m_out.newBlock(); |
| |
| m_out.branch(m_out.equal(key, bucketKey), |
| unsure(continuation), unsure(notBitEqual)); |
| |
| m_out.appendTo(notBitEqual, bucketKeyIsCell); |
| m_out.branch(isCell(bucketKey), |
| unsure(bucketKeyIsCell), unsure(loopAround)); |
| |
| m_out.appendTo(bucketKeyIsCell, bucketKeyIsString); |
| m_out.branch(isString(bucketKey), |
| unsure(bucketKeyIsString), unsure(loopAround)); |
| |
| m_out.appendTo(bucketKeyIsString, loopAround); |
| m_out.branch(isString(key), |
| unsure(slowPath), unsure(loopAround)); |
| break; |
| } |
| case UntypedUse: { |
| LBasicBlock notBitEqual = m_out.newBlock(); |
| LBasicBlock bucketKeyIsCell = m_out.newBlock(); |
| LBasicBlock bothAreCells = m_out.newBlock(); |
| LBasicBlock bucketKeyIsString = m_out.newBlock(); |
| |
| m_out.branch(m_out.equal(key, bucketKey), |
| unsure(continuation), unsure(notBitEqual)); |
| |
| m_out.appendTo(notBitEqual, bucketKeyIsCell); |
| m_out.branch(isCell(bucketKey), |
| unsure(bucketKeyIsCell), unsure(loopAround)); |
| |
| m_out.appendTo(bucketKeyIsCell, bothAreCells); |
| m_out.branch(isCell(key), |
| unsure(bothAreCells), unsure(loopAround)); |
| |
| m_out.appendTo(bothAreCells, bucketKeyIsString); |
| m_out.branch(isString(bucketKey), |
| unsure(bucketKeyIsString), unsure(loopAround)); |
| |
| m_out.appendTo(bucketKeyIsString, loopAround); |
| m_out.branch(isString(key), |
| unsure(slowPath), unsure(loopAround)); |
| break; |
| } |
| default: |
| RELEASE_ASSERT_NOT_REACHED(); |
| } |
| |
| m_out.appendTo(loopAround, slowPath); |
| m_out.addIncomingToPhi(unmaskedIndex, m_out.anchor(m_out.add(index, m_out.int32One))); |
| m_out.jump(loopStart); |
| |
| m_out.appendTo(slowPath, notPresentInTable); |
| ValueFromBlock slowPathResult = m_out.anchor(vmCall(pointerType(), |
| m_out.operation(m_node->child1().useKind() == MapObjectUse ? operationJSMapFindBucket : operationJSSetFindBucket), m_callFrame, map, key, hash)); |
| m_out.jump(continuation); |
| |
| m_out.appendTo(notPresentInTable, continuation); |
| ValueFromBlock notPresentResult; |
| if (m_node->child1().useKind() == MapObjectUse) |
| notPresentResult = m_out.anchor(weakPointer(vm().sentinelMapBucket.get())); |
| else if (m_node->child1().useKind() == SetObjectUse) |
| notPresentResult = m_out.anchor(weakPointer(vm().sentinelSetBucket.get())); |
| else |
| RELEASE_ASSERT_NOT_REACHED(); |
| m_out.jump(continuation); |
| |
| m_out.appendTo(continuation, lastNext); |
| setJSValue(m_out.phi(pointerType(), bucketResult, slowPathResult, notPresentResult)); |
| } |
| |
| void compileGetMapBucketHead() |
| { |
| LValue map; |
| if (m_node->child1().useKind() == MapObjectUse) |
| map = lowMapObject(m_node->child1()); |
| else if (m_node->child1().useKind() == SetObjectUse) |
| map = lowSetObject(m_node->child1()); |
| else |
| RELEASE_ASSERT_NOT_REACHED(); |
| |
| ASSERT(HashMapImpl<HashMapBucket<HashMapBucketDataKey>>::offsetOfHead() == HashMapImpl<HashMapBucket<HashMapBucketDataKeyValue>>::offsetOfHead()); |
| setJSValue(m_out.loadPtr(map, m_heaps.HashMapImpl_head)); |
| } |
| |
| void compileGetMapBucketNext() |
| { |
| LBasicBlock loopStart = m_out.newBlock(); |
| LBasicBlock continuation = m_out.newBlock(); |
| LBasicBlock noBucket = m_out.newBlock(); |
| LBasicBlock hasBucket = m_out.newBlock(); |
| LBasicBlock nextBucket = m_out.newBlock(); |
| |
| LBasicBlock lastNext = m_out.insertNewBlocksBefore(loopStart); |
| |
| ASSERT(HashMapBucket<HashMapBucketDataKey>::offsetOfNext() == HashMapBucket<HashMapBucketDataKeyValue>::offsetOfNext()); |
| ASSERT(HashMapBucket<HashMapBucketDataKey>::offsetOfKey() == HashMapBucket<HashMapBucketDataKeyValue>::offsetOfKey()); |
| LValue mapBucketPrev = lowCell(m_node->child1()); |
| ValueFromBlock mapBucketStart = m_out.anchor(m_out.loadPtr(mapBucketPrev, m_heaps.HashMapBucket_next)); |
| m_out.jump(loopStart); |
| |
| m_out.appendTo(loopStart, noBucket); |
| LValue mapBucket = m_out.phi(pointerType(), mapBucketStart); |
| m_out.branch(m_out.isNull(mapBucket), unsure(noBucket), unsure(hasBucket)); |
| |
| m_out.appendTo(noBucket, hasBucket); |
| ValueFromBlock noBucketResult; |
| if (m_node->bucketOwnerType() == BucketOwnerType::Map) |
| noBucketResult = m_out.anchor(weakPointer(vm().sentinelMapBucket.get())); |
| else { |
| ASSERT(m_node->bucketOwnerType() == BucketOwnerType::Set); |
| noBucketResult = m_out.anchor(weakPointer(vm().sentinelSetBucket.get())); |
| } |
| m_out.jump(continuation); |
| |
| m_out.appendTo(hasBucket, nextBucket); |
| ValueFromBlock bucketResult = m_out.anchor(mapBucket); |
| m_out.branch(m_out.isZero64(m_out.load64(mapBucket, m_heaps.HashMapBucket_key)), unsure(nextBucket), unsure(continuation)); |
| |
| m_out.appendTo(nextBucket, continuation); |
| m_out.addIncomingToPhi(mapBucket, m_out.anchor(m_out.loadPtr(mapBucket, m_heaps.HashMapBucket_next))); |
| m_out.jump(loopStart); |
| |
| m_out.appendTo(continuation, lastNext); |
| setJSValue(m_out.phi(pointerType(), noBucketResult, bucketResult)); |
| } |
| |
| void compileLoadValueFromMapBucket() |
| { |
| LValue mapBucket = lowCell(m_node->child1()); |
| setJSValue(m_out.load64(mapBucket, m_heaps.HashMapBucket_value)); |
| } |
| |
| void compileExtractValueFromWeakMapGet() |
| { |
| LValue value = lowJSValue(m_node->child1()); |
| setJSValue(m_out.select(m_out.isZero64(value), |
| m_out.constInt64(JSValue::encode(jsUndefined())), |
| value)); |
| } |
| |
| void compileLoadKeyFromMapBucket() |
| { |
| LValue mapBucket = lowCell(m_node->child1()); |
| setJSValue(m_out.load64(mapBucket, m_heaps.HashMapBucket_key)); |
| } |
| |
| void compileSetAdd() |
| { |
| LValue set = lowSetObject(m_node->child1()); |
| LValue key = lowJSValue(m_node->child2()); |
| LValue hash = lowInt32(m_node->child3()); |
| |
| setJSValue(vmCall(pointerType(), m_out.operation(operationSetAdd), m_callFrame, set, key, hash)); |
| } |
| |
| void compileMapSet() |
| { |
| LValue map = lowMapObject(m_graph.varArgChild(m_node, 0)); |
| LValue key = lowJSValue(m_graph.varArgChild(m_node, 1)); |
| LValue value = lowJSValue(m_graph.varArgChild(m_node, 2)); |
| LValue hash = lowInt32(m_graph.varArgChild(m_node, 3)); |
| |
| setJSValue(vmCall(pointerType(), m_out.operation(operationMapSet), m_callFrame, map, key, value, hash)); |
| } |
| |
| void compileWeakMapGet() |
| { |
| LBasicBlock loopStart = m_out.newBlock(); |
| LBasicBlock loopAround = m_out.newBlock(); |
| LBasicBlock notEqualValue = m_out.newBlock(); |
| LBasicBlock continuation = m_out.newBlock(); |
| |
| LBasicBlock lastNext = m_out.insertNewBlocksBefore(loopStart); |
| |
| LValue weakMap; |
| if (m_node->child1().useKind() == WeakMapObjectUse) |
| weakMap = lowWeakMapObject(m_node->child1()); |
| else if (m_node->child1().useKind() == WeakSetObjectUse) |
| weakMap = lowWeakSetObject(m_node->child1()); |
| else |
| RELEASE_ASSERT_NOT_REACHED(); |
| LValue key = lowObject(m_node->child2()); |
| LValue hash = lowInt32(m_node->child3()); |
| |
| LValue buffer = m_out.loadPtr(weakMap, m_heaps.WeakMapImpl_buffer); |
| LValue mask = m_out.sub(m_out.load32(weakMap, m_heaps.WeakMapImpl_capacity), m_out.int32One); |
| |
| ValueFromBlock indexStart = m_out.anchor(hash); |
| m_out.jump(loopStart); |
| |
| m_out.appendTo(loopStart, notEqualValue); |
| LValue unmaskedIndex = m_out.phi(Int32, indexStart); |
| LValue index = m_out.bitAnd(mask, unmaskedIndex); |
| |
| LValue bucket; |
| if (m_node->child1().useKind() == WeakMapObjectUse) { |
| static_assert(sizeof(WeakMapBucket<WeakMapBucketDataKeyValue>) == 16, ""); |
| bucket = m_out.add(buffer, m_out.shl(m_out.zeroExt(index, Int64), m_out.constInt32(4))); |
| } else { |
| static_assert(sizeof(WeakMapBucket<WeakMapBucketDataKey>) == 8, ""); |
| bucket = m_out.add(buffer, m_out.shl(m_out.zeroExt(index, Int64), m_out.constInt32(3))); |
| } |
| |
| LValue bucketKey = m_out.load64(bucket, m_heaps.WeakMapBucket_key); |
| m_out.branch(m_out.equal(key, bucketKey), unsure(continuation), unsure(notEqualValue)); |
| |
| m_out.appendTo(notEqualValue, loopAround); |
| m_out.branch(m_out.isNull(bucketKey), unsure(continuation), unsure(loopAround)); |
| |
| m_out.appendTo(loopAround, continuation); |
| m_out.addIncomingToPhi(unmaskedIndex, m_out.anchor(m_out.add(index, m_out.int32One))); |
| m_out.jump(loopStart); |
| |
| m_out.appendTo(continuation, lastNext); |
| LValue result; |
| if (m_node->child1().useKind() == WeakMapObjectUse) |
| result = m_out.load64(bucket, m_heaps.WeakMapBucket_value); |
| else |
| result = bucketKey; |
| setJSValue(result); |
| } |
| |
| void compileWeakSetAdd() |
| { |
| LValue set = lowWeakSetObject(m_node->child1()); |
| LValue key = lowObject(m_node->child2()); |
| LValue hash = lowInt32(m_node->child3()); |
| |
| vmCall(Void, m_out.operation(operationWeakSetAdd), m_callFrame, set, key, hash); |
| } |
| |
| void compileWeakMapSet() |
| { |
| LValue map = lowWeakMapObject(m_graph.varArgChild(m_node, 0)); |
| LValue key = lowObject(m_graph.varArgChild(m_node, 1)); |
| LValue value = lowJSValue(m_graph.varArgChild(m_node, 2)); |
| LValue hash = lowInt32(m_graph.varArgChild(m_node, 3)); |
| |
| vmCall(Void, m_out.operation(operationWeakMapSet), m_callFrame, map, key, value, hash); |
| } |
| |
| void compileIsObjectOrNull() |
| { |
| JSGlobalObject* globalObject = m_graph.globalObjectFor(m_node->origin.semantic); |
| |
| Edge child = m_node->child1(); |
| LValue value = lowJSValue(child); |
| |
| LBasicBlock cellCase = m_out.newBlock(); |
| LBasicBlock notFunctionCase = m_out.newBlock(); |
| LBasicBlock objectCase = m_out.newBlock(); |
| LBasicBlock slowPath = m_out.newBlock(); |
| LBasicBlock notCellCase = m_out.newBlock(); |
| LBasicBlock continuation = m_out.newBlock(); |
| |
| m_out.branch(isCell(value, provenType(child)), unsure(cellCase), unsure(notCellCase)); |
| |
| LBasicBlock lastNext = m_out.appendTo(cellCase, notFunctionCase); |
| ValueFromBlock isFunctionResult = m_out.anchor(m_out.booleanFalse); |
| m_out.branch( |
| isFunction(value, provenType(child)), |
| unsure(continuation), unsure(notFunctionCase)); |
| |
| m_out.appendTo(notFunctionCase, objectCase); |
| ValueFromBlock notObjectResult = m_out.anchor(m_out.booleanFalse); |
| m_out.branch( |
| isObject(value, provenType(child)), |
| unsure(objectCase), unsure(continuation)); |
| |
| m_out.appendTo(objectCase, slowPath); |
| ValueFromBlock objectResult = m_out.anchor(m_out.booleanTrue); |
| m_out.branch( |
| isExoticForTypeof(value, provenType(child)), |
| rarely(slowPath), usually(continuation)); |
| |
| m_out.appendTo(slowPath, notCellCase); |
| VM& vm = this->vm(); |
| LValue slowResultValue = lazySlowPath( |
| [=, &vm] (const Vector<Location>& locations) -> RefPtr<LazySlowPath::Generator> { |
| return createLazyCallGenerator(vm, |
| operationObjectIsObject, locations[0].directGPR(), |
| CCallHelpers::TrustedImmPtr(globalObject), locations[1].directGPR()); |
| }, value); |
| ValueFromBlock slowResult = m_out.anchor(m_out.notZero64(slowResultValue)); |
| m_out.jump(continuation); |
| |
| m_out.appendTo(notCellCase, continuation); |
| LValue notCellResultValue = m_out.equal(value, m_out.constInt64(JSValue::encode(jsNull()))); |
| ValueFromBlock notCellResult = m_out.anchor(notCellResultValue); |
| m_out.jump(continuation); |
| |
| m_out.appendTo(continuation, lastNext); |
| LValue result = m_out.phi( |
| Int32, |
| isFunctionResult, notObjectResult, objectResult, slowResult, notCellResult); |
| setBoolean(result); |
| } |
| |
| void compileIsFunction() |
| { |
| JSGlobalObject* globalObject = m_graph.globalObjectFor(m_node->origin.semantic); |
| |
| Edge child = m_node->child1(); |
| LValue value = lowJSValue(child); |
| |
| LBasicBlock cellCase = m_out.newBlock(); |
| LBasicBlock notFunctionCase = m_out.newBlock(); |
| LBasicBlock slowPath = m_out.newBlock(); |
| LBasicBlock continuation = m_out.newBlock(); |
| |
| ValueFromBlock notCellResult = m_out.anchor(m_out.booleanFalse); |
| m_out.branch( |
| isCell(value, provenType(child)), unsure(cellCase), unsure(continuation)); |
| |
| LBasicBlock lastNext = m_out.appendTo(cellCase, notFunctionCase); |
| ValueFromBlock functionResult = m_out.anchor(m_out.booleanTrue); |
| m_out.branch( |
| isFunction(value, provenType(child)), |
| unsure(continuation), unsure(notFunctionCase)); |
| |
| m_out.appendTo(notFunctionCase, slowPath); |
| ValueFromBlock objectResult = m_out.anchor(m_out.booleanFalse); |
| m_out.branch( |
| isExoticForTypeof(value, provenType(child)), |
| rarely(slowPath), usually(continuation)); |
| |
| m_out.appendTo(slowPath, continuation); |
| VM& vm = this->vm(); |
| LValue slowResultValue = lazySlowPath( |
| [=, &vm] (const Vector<Location>& locations) -> RefPtr<LazySlowPath::Generator> { |
| return createLazyCallGenerator(vm, |
| operationObjectIsFunction, locations[0].directGPR(), |
| CCallHelpers::TrustedImmPtr(globalObject), locations[1].directGPR()); |
| }, value); |
| ValueFromBlock slowResult = m_out.anchor(m_out.notNull(slowResultValue)); |
| m_out.jump(continuation); |
| |
| m_out.appendTo(continuation, lastNext); |
| LValue result = m_out.phi( |
| Int32, notCellResult, functionResult, objectResult, slowResult); |
| setBoolean(result); |
| } |
| |
| void compileIsTypedArrayView() |
| { |
| LValue value = lowJSValue(m_node->child1()); |
| |
| LBasicBlock isCellCase = m_out.newBlock(); |
| LBasicBlock continuation = m_out.newBlock(); |
| |
| ValueFromBlock notCellResult = m_out.anchor(m_out.booleanFalse); |
| m_out.branch(isCell(value, provenType(m_node->child1())), unsure(isCellCase), unsure(continuation)); |
| |
| LBasicBlock lastNext = m_out.appendTo(isCellCase, continuation); |
| ValueFromBlock cellResult = m_out.anchor(isTypedArrayView(value, provenType(m_node->child1()))); |
| m_out.jump(continuation); |
| |
| m_out.appendTo(continuation, lastNext); |
| setBoolean(m_out.phi(Int32, notCellResult, cellResult)); |
| } |
| |
| void compileTypeOf() |
| { |
| Edge child = m_node->child1(); |
| LValue value = lowJSValue(child); |
| |
| LBasicBlock continuation = m_out.newBlock(); |
| LBasicBlock lastNext = m_out.insertNewBlocksBefore(continuation); |
| |
| Vector<ValueFromBlock> results; |
| |
| buildTypeOf( |
| child, value, |
| [&] (TypeofType type) { |
| results.append(m_out.anchor(weakPointer(vm().smallStrings.typeString(type)))); |
| m_out.jump(continuation); |
| }); |
| |
| m_out.appendTo(continuation, lastNext); |
| setJSValue(m_out.phi(Int64, results)); |
| } |
| |
| void compileIn() |
| { |
| DFG_ASSERT(m_graph, m_node, m_node->child1().useKind() == CellUse, m_node->child1().useKind()); |
| |
| Node* node = m_node; |
| Edge base = node->child1(); |
| LValue cell = lowCell(base); |
| if (JSString* string = node->child2()->dynamicCastConstant<JSString*>(vm())) { |
| if (string->tryGetValueImpl() && string->tryGetValueImpl()->isAtomic()) { |
| UniquedStringImpl* str = bitwise_cast<UniquedStringImpl*>(string->tryGetValueImpl()); |
| B3::PatchpointValue* patchpoint = m_out.patchpoint(Int64); |
| patchpoint->appendSomeRegister(cell); |
| patchpoint->append(m_tagMask, ValueRep::lateReg(GPRInfo::tagMaskRegister)); |
| patchpoint->append(m_tagTypeNumber, ValueRep::lateReg(GPRInfo::tagTypeNumberRegister)); |
| patchpoint->clobber(RegisterSet::macroScratchRegisters()); |
| |
| RefPtr<PatchpointExceptionHandle> exceptionHandle = preparePatchpointForExceptions(patchpoint); |
| |
| State* state = &m_ftlState; |
| patchpoint->setGenerator( |
| [=] (CCallHelpers& jit, const StackmapGenerationParams& params) { |
| AllowMacroScratchRegisterUsage allowScratch(jit); |
| |
| // This is the direct exit target for operation calls. We don't need a JS exceptionHandle because we don't |
| // cache Proxy objects. |
| Box<CCallHelpers::JumpList> exceptions = exceptionHandle->scheduleExitCreation(params)->jumps(jit); |
| |
| GPRReg baseGPR = params[1].gpr(); |
| GPRReg resultGPR = params[0].gpr(); |
| |
| StructureStubInfo* stubInfo = |
| jit.codeBlock()->addStubInfo(AccessType::In); |
| stubInfo->callSiteIndex = |
| state->jitCode->common.addCodeOrigin(node->origin.semantic); |
| stubInfo->codeOrigin = node->origin.semantic; |
| stubInfo->patch.baseGPR = static_cast<int8_t>(baseGPR); |
| stubInfo->patch.valueGPR = static_cast<int8_t>(resultGPR); |
| stubInfo->patch.thisGPR = static_cast<int8_t>(InvalidGPRReg); |
| stubInfo->patch.usedRegisters = params.unavailableRegisters(); |
| |
| CCallHelpers::PatchableJump jump = jit.patchableJump(); |
| CCallHelpers::Label done = jit.label(); |
| |
| params.addLatePath( |
| [=] (CCallHelpers& jit) { |
| AllowMacroScratchRegisterUsage allowScratch(jit); |
| |
| jump.m_jump.link(&jit); |
| CCallHelpers::Label slowPathBegin = jit.label(); |
| CCallHelpers::Call slowPathCall = callOperation( |
| *state, params.unavailableRegisters(), jit, |
| node->origin.semantic, exceptions.get(), operationInOptimize, |
| resultGPR, CCallHelpers::TrustedImmPtr(stubInfo), baseGPR, |
| CCallHelpers::TrustedImmPtr(str)).call(); |
| jit.jump().linkTo(done, &jit); |
| |
| jit.addLinkTask( |
| [=] (LinkBuffer& linkBuffer) { |
| CodeLocationLabel<JITStubRoutinePtrTag> start = linkBuffer.locationOf<JITStubRoutinePtrTag>(jump); |
| stubInfo->patch.start = start; |
| ptrdiff_t inlineSize = MacroAssembler::differenceBetweenCodePtr( |
| start, linkBuffer.locationOf<NoPtrTag>(done)); |
| RELEASE_ASSERT(inlineSize >= 0); |
| stubInfo->patch.inlineSize = inlineSize; |
| |
| stubInfo->patch.deltaFromStartToSlowPathCallLocation = MacroAssembler::differenceBetweenCodePtr( |
| start, linkBuffer.locationOf<NoPtrTag>(slowPathCall)); |
| |
| stubInfo->patch.deltaFromStartToSlowPathStart = MacroAssembler::differenceBetweenCodePtr( |
| start, linkBuffer.locationOf<NoPtrTag>(slowPathBegin)); |
| |
| }); |
| }); |
| }); |
| |
| setJSValue(patchpoint); |
| return; |
| } |
| } |
| |
| setJSValue(vmCall(Int64, m_out.operation(operationGenericIn), m_callFrame, cell, lowJSValue(m_node->child2()))); |
| } |
| |
| void compileHasOwnProperty() |
| { |
| LBasicBlock slowCase = m_out.newBlock(); |
| LBasicBlock continuation = m_out.newBlock(); |
| LBasicBlock lastNext = nullptr; |
| |
| LValue object = lowObject(m_node->child1()); |
| LValue uniquedStringImpl; |
| LValue keyAsValue = nullptr; |
| switch (m_node->child2().useKind()) { |
| case StringUse: { |
| LBasicBlock isNonEmptyString = m_out.newBlock(); |
| LBasicBlock isAtomicString = m_out.newBlock(); |
| |
| keyAsValue = lowString(m_node->child2()); |
| uniquedStringImpl = m_out.loadPtr(keyAsValue, m_heaps.JSString_value); |
| m_out.branch(m_out.notNull(uniquedStringImpl), usually(isNonEmptyString), rarely(slowCase)); |
| |
| lastNext = m_out.appendTo(isNonEmptyString, isAtomicString); |
| LValue isNotAtomic = m_out.testIsZero32(m_out.load32(uniquedStringImpl, m_heaps.StringImpl_hashAndFlags), m_out.constInt32(StringImpl::flagIsAtomic())); |
| m_out.branch(isNotAtomic, rarely(slowCase), usually(isAtomicString)); |
| |
| m_out.appendTo(isAtomicString, slowCase); |
| break; |
| } |
| case SymbolUse: { |
| keyAsValue = lowSymbol(m_node->child2()); |
| uniquedStringImpl = m_out.loadPtr(keyAsValue, m_heaps.Symbol_symbolImpl); |
| lastNext = m_out.insertNewBlocksBefore(slowCase); |
| break; |
| } |
| case UntypedUse: { |
| LBasicBlock isCellCase = m_out.newBlock(); |
| LBasicBlock isStringCase = m_out.newBlock(); |
| LBasicBlock notStringCase = m_out.newBlock(); |
| LBasicBlock isNonEmptyString = m_out.newBlock(); |
| LBasicBlock isSymbolCase = m_out.newBlock(); |
| LBasicBlock hasUniquedStringImpl = m_out.newBlock(); |
| |
| keyAsValue = lowJSValue(m_node->child2()); |
| m_out.branch(isCell(keyAsValue), usually(isCellCase), rarely(slowCase)); |
| |
| lastNext = m_out.appendTo(isCellCase, isStringCase); |
| m_out.branch(isString(keyAsValue), unsure(isStringCase), unsure(notStringCase)); |
| |
| m_out.appendTo(isStringCase, isNonEmptyString); |
| LValue implFromString = m_out.loadPtr(keyAsValue, m_heaps.JSString_value); |
| ValueFromBlock stringResult = m_out.anchor(implFromString); |
| m_out.branch(m_out.notNull(implFromString), usually(isNonEmptyString), rarely(slowCase)); |
| |
| m_out.appendTo(isNonEmptyString, notStringCase); |
| LValue isNotAtomic = m_out.testIsZero32(m_out.load32(implFromString, m_heaps.StringImpl_hashAndFlags), m_out.constInt32(StringImpl::flagIsAtomic())); |
| m_out.branch(isNotAtomic, rarely(slowCase), usually(hasUniquedStringImpl)); |
| |
| m_out.appendTo(notStringCase, isSymbolCase); |
| m_out.branch(isSymbol(keyAsValue), unsure(isSymbolCase), unsure(slowCase)); |
| |
| m_out.appendTo(isSymbolCase, hasUniquedStringImpl); |
| ValueFromBlock symbolResult = m_out.anchor(m_out.loadPtr(keyAsValue, m_heaps.Symbol_symbolImpl)); |
| m_out.jump(hasUniquedStringImpl); |
| |
| m_out.appendTo(hasUniquedStringImpl, slowCase); |
| uniquedStringImpl = m_out.phi(pointerType(), stringResult, symbolResult); |
| break; |
| } |
| default: |
| RELEASE_ASSERT_NOT_REACHED(); |
| } |
| |
| ASSERT(keyAsValue); |
| |
| // Note that we don't test if the hash is zero here. AtomicStringImpl's can't have a zero |
| // hash, however, a SymbolImpl may. But, because this is a cache, we don't care. We only |
| // ever load the result from the cache if the cache entry matches what we are querying for. |
| // So we either get super lucky and use zero for the hash and somehow collide with the entity |
| // we're looking for, or we realize we're comparing against another entity, and go to the |
| // slow path anyways. |
| LValue hash = m_out.lShr(m_out.load32(uniquedStringImpl, m_heaps.StringImpl_hashAndFlags), m_out.constInt32(StringImpl::s_flagCount)); |
| |
| LValue structureID = m_out.load32(object, m_heaps.JSCell_structureID); |
| LValue index = m_out.add(hash, structureID); |
| index = m_out.zeroExtPtr(m_out.bitAnd(index, m_out.constInt32(HasOwnPropertyCache::mask))); |
| ASSERT(vm().hasOwnPropertyCache()); |
| LValue cache = m_out.constIntPtr(vm().hasOwnPropertyCache()); |
| |
| IndexedAbstractHeap& heap = m_heaps.HasOwnPropertyCache; |
| LValue sameStructureID = m_out.equal(structureID, m_out.load32(m_out.baseIndex(heap, cache, index, JSValue(), HasOwnPropertyCache::Entry::offsetOfStructureID()))); |
| LValue sameImpl = m_out.equal(uniquedStringImpl, m_out.loadPtr(m_out.baseIndex(heap, cache, index, JSValue(), HasOwnPropertyCache::Entry::offsetOfImpl()))); |
| ValueFromBlock fastResult = m_out.anchor(m_out.load8ZeroExt32(m_out.baseIndex(heap, cache, index, JSValue(), HasOwnPropertyCache::Entry::offsetOfResult()))); |
| LValue cacheHit = m_out.bitAnd(sameStructureID, sameImpl); |
| |
| m_out.branch(m_out.notZero32(cacheHit), usually(continuation), rarely(slowCase)); |
| |
| m_out.appendTo(slowCase, continuation); |
| ValueFromBlock slowResult; |
| slowResult = m_out.anchor(vmCall(Int32, m_out.operation(operationHasOwnProperty), m_callFrame, object, keyAsValue)); |
| m_out.jump(continuation); |
| |
| m_out.appendTo(continuation, lastNext); |
| setBoolean(m_out.phi(Int32, fastResult, slowResult)); |
| } |
| |
| void compileParseInt() |
| { |
| RELEASE_ASSERT(m_node->child1().useKind() == UntypedUse || m_node->child1().useKind() == StringUse); |
| LValue result; |
| if (m_node->child2()) { |
| LValue radix = lowInt32(m_node->child2()); |
| if (m_node->child1().useKind() == UntypedUse) |
| result = vmCall(Int64, m_out.operation(operationParseIntGeneric), m_callFrame, lowJSValue(m_node->child1()), radix); |
| else |
| result = vmCall(Int64, m_out.operation(operationParseIntString), m_callFrame, lowString(m_node->child1()), radix); |
| } else { |
| if (m_node->child1().useKind() == UntypedUse) |
| result = vmCall(Int64, m_out.operation(operationParseIntNoRadixGeneric), m_callFrame, lowJSValue(m_node->child1())); |
| else |
| result = vmCall(Int64, m_out.operation(operationParseIntStringNoRadix), m_callFrame, lowString(m_node->child1())); |
| } |
| setJSValue(result); |
| } |
| |
| void compileOverridesHasInstance() |
| { |
| FrozenValue* defaultHasInstanceFunction = m_node->cellOperand(); |
| ASSERT(defaultHasInstanceFunction->cell()->inherits<JSFunction>(vm())); |
| |
| LValue constructor = lowCell(m_node->child1()); |
| LValue hasInstance = lowJSValue(m_node->child2()); |
| |
| LBasicBlock defaultHasInstance = m_out.newBlock(); |
| LBasicBlock continuation = m_out.newBlock(); |
| |
| // Unlike in the DFG, we don't worry about cleaning this code up for the case where we have proven the hasInstanceValue is a constant as B3 should fix it for us. |
| |
| ValueFromBlock notDefaultHasInstanceResult = m_out.anchor(m_out.booleanTrue); |
| m_out.branch(m_out.notEqual(hasInstance, frozenPointer(defaultHasInstanceFunction)), unsure(continuation), unsure(defaultHasInstance)); |
| |
| LBasicBlock lastNext = m_out.appendTo(defaultHasInstance, continuation); |
| ValueFromBlock implementsDefaultHasInstanceResult = m_out.anchor(m_out.testIsZero32( |
| m_out.load8ZeroExt32(constructor, m_heaps.JSCell_typeInfoFlags), |
| m_out.constInt32(ImplementsDefaultHasInstance))); |
| m_out.jump(continuation); |
| |
| m_out.appendTo(continuation, lastNext); |
| setBoolean(m_out.phi(Int32, implementsDefaultHasInstanceResult, notDefaultHasInstanceResult)); |
| } |
| |
| void compileCheckTypeInfoFlags() |
| { |
| speculate( |
| BadTypeInfoFlags, noValue(), 0, |
| m_out.testIsZero32( |
| m_out.load8ZeroExt32(lowCell(m_node->child1()), m_heaps.JSCell_typeInfoFlags), |
| m_out.constInt32(m_node->typeInfoOperand()))); |
| } |
| |
| void compileInstanceOf() |
| { |
| LValue cell; |
| |
| if (m_node->child1().useKind() == UntypedUse) |
| cell = lowJSValue(m_node->child1()); |
| else |
| cell = lowCell(m_node->child1()); |
| |
| LValue prototype = lowCell(m_node->child2()); |
| |
| LBasicBlock isCellCase = m_out.newBlock(); |
| LBasicBlock loop = m_out.newBlock(); |
| LBasicBlock loadPrototypeBits = m_out.newBlock(); |
| LBasicBlock loadPolyProto = m_out.newBlock(); |
| LBasicBlock comparePrototype = m_out.newBlock(); |
| LBasicBlock notYetInstance = m_out.newBlock(); |
| LBasicBlock defaultHasInstanceSlow = m_out.newBlock(); |
| LBasicBlock continuation = m_out.newBlock(); |
| |
| LValue condition; |
| if (m_node->child1().useKind() == UntypedUse) |
| condition = isCell(cell, provenType(m_node->child1())); |
| else |
| condition = m_out.booleanTrue; |
| |
| ValueFromBlock notCellResult = m_out.anchor(m_out.booleanFalse); |
| m_out.branch(condition, unsure(isCellCase), unsure(continuation)); |
| |
| LBasicBlock lastNext = m_out.appendTo(isCellCase, loop); |
| |
| speculate(BadType, noValue(), 0, isNotObject(prototype, provenType(m_node->child2()))); |
| |
| ValueFromBlock originalValue = m_out.anchor(cell); |
| m_out.jump(loop); |
| |
| m_out.appendTo(loop, loadPrototypeBits); |
| LValue value = m_out.phi(Int64, originalValue); |
| LValue type = m_out.load8ZeroExt32(value, m_heaps.JSCell_typeInfoType); |
| m_out.branch( |
| m_out.notEqual(type, m_out.constInt32(ProxyObjectType)), |
| usually(loadPrototypeBits), rarely(defaultHasInstanceSlow)); |
| |
| m_out.appendTo(loadPrototypeBits, loadPolyProto); |
| LValue structure = loadStructure(value); |
| |
| LValue prototypeBits = m_out.load64(structure, m_heaps.Structure_prototype); |
| ValueFromBlock directPrototype = m_out.anchor(prototypeBits); |
| m_out.branch(m_out.isZero64(prototypeBits), unsure(loadPolyProto), unsure(comparePrototype)); |
| |
| m_out.appendTo(loadPolyProto, comparePrototype); |
| ValueFromBlock polyProto = m_out.anchor( |
| m_out.load64(m_out.baseIndex(m_heaps.properties.atAnyNumber(), value, m_out.constInt64(knownPolyProtoOffset), ScaleEight, JSObject::offsetOfInlineStorage()))); |
| m_out.jump(comparePrototype); |
| |
| m_out.appendTo(comparePrototype, notYetInstance); |
| LValue currentPrototype = m_out.phi(Int64, directPrototype, polyProto); |
| ValueFromBlock isInstanceResult = m_out.anchor(m_out.booleanTrue); |
| m_out.branch( |
| m_out.equal(currentPrototype, prototype), |
| unsure(continuation), unsure(notYetInstance)); |
| |
| m_out.appendTo(notYetInstance, defaultHasInstanceSlow); |
| ValueFromBlock notInstanceResult = m_out.anchor(m_out.booleanFalse); |
| m_out.addIncomingToPhi(value, m_out.anchor(currentPrototype)); |
| m_out.branch(isCell(currentPrototype), unsure(loop), unsure(continuation)); |
| |
| m_out.appendTo(defaultHasInstanceSlow, continuation); |
| // We can use the value that we're looping with because we |
| // can just continue off from wherever we bailed from the |
| // loop. |
| ValueFromBlock defaultHasInstanceResult = m_out.anchor( |
| vmCall(Int32, m_out.operation(operationDefaultHasInstance), m_callFrame, value, prototype)); |
| m_out.jump(continuation); |
| |
| m_out.appendTo(continuation, lastNext); |
| setBoolean( |
| m_out.phi(Int32, notCellResult, isInstanceResult, notInstanceResult, defaultHasInstanceResult)); |
| } |
| |
| void compileInstanceOfCustom() |
| { |
| LValue value = lowJSValue(m_node->child1()); |
| LValue constructor = lowCell(m_node->child2()); |
| LValue hasInstance = lowJSValue(m_node->child3()); |
| |
| setBoolean(m_out.logicalNot(m_out.equal(m_out.constInt32(0), vmCall(Int32, m_out.operation(operationInstanceOfCustom), m_callFrame, value, constructor, hasInstance)))); |
| } |
| |
| void compileCountExecution() |
| { |
| TypedPointer counter = m_out.absolute(m_node->executionCounter()->address()); |
| m_out.store64(m_out.add(m_out.load64(counter), m_out.constInt64(1)), counter); |
| } |
| |
| void compileSuperSamplerBegin() |
| { |
| TypedPointer counter = m_out.absolute(bitwise_cast<void*>(&g_superSamplerCount)); |
| m_out.store32(m_out.add(m_out.load32(counter), m_out.constInt32(1)), counter); |
| } |
| |
| void compileSuperSamplerEnd() |
| { |
| TypedPointer counter = m_out.absolute(bitwise_cast<void*>(&g_superSamplerCount)); |
| m_out.store32(m_out.sub(m_out.load32(counter), m_out.constInt32(1)), counter); |
| } |
| |
| void compileStoreBarrier() |
| { |
| emitStoreBarrier(lowCell(m_node->child1()), m_node->op() == FencedStoreBarrier); |
| } |
| |
| void compileHasIndexedProperty() |
| { |
| switch (m_node->arrayMode().type()) { |
| case Array::Int32: |
| case Array::Contiguous: { |
| LValue base = lowCell(m_node->child1()); |
| LValue index = lowInt32(m_node->child2()); |
| LValue storage = lowStorage(m_node->child3()); |
| LValue internalMethodType = m_out.constInt32(static_cast<int32_t>(m_node->internalMethodType())); |
| |
| IndexedAbstractHeap& heap = m_node->arrayMode().type() == Array::Int32 ? |
| m_heaps.indexedInt32Properties : m_heaps.indexedContiguousProperties; |
| |
| LBasicBlock slowCase = m_out.newBlock(); |
| LBasicBlock continuation = m_out.newBlock(); |
| LBasicBlock lastNext = nullptr; |
| |
| if (!m_node->arrayMode().isInBounds()) { |
| LBasicBlock checkHole = m_out.newBlock(); |
| m_out.branch( |
| m_out.aboveOrEqual( |
| index, m_out.load32NonNegative(storage, m_heaps.Butterfly_publicLength)), |
| rarely(slowCase), usually(checkHole)); |
| lastNext = m_out.appendTo(checkHole, slowCase); |
| } else |
| lastNext = m_out.insertNewBlocksBefore(slowCase); |
| |
| LValue checkHoleResultValue = |
| m_out.notZero64(m_out.load64(baseIndex(heap, storage, index, m_node->child2()))); |
| ValueFromBlock checkHoleResult = m_out.anchor(checkHoleResultValue); |
| m_out.branch(checkHoleResultValue, usually(continuation), rarely(slowCase)); |
| |
| m_out.appendTo(slowCase, continuation); |
| ValueFromBlock slowResult = m_out.anchor( |
| m_out.notZero64(vmCall(Int64, m_out.operation(operationHasIndexedPropertyByInt), m_callFrame, base, index, internalMethodType))); |
| m_out.jump(continuation); |
| |
| m_out.appendTo(continuation, lastNext); |
| setBoolean(m_out.phi(Int32, checkHoleResult, slowResult)); |
| return; |
| } |
| case Array::Double: { |
| LValue base = lowCell(m_node->child1()); |
| LValue index = lowInt32(m_node->child2()); |
| LValue storage = lowStorage(m_node->child3()); |
| LValue internalMethodType = m_out.constInt32(static_cast<int32_t>(m_node->internalMethodType())); |
| |
| IndexedAbstractHeap& heap = m_heaps.indexedDoubleProperties; |
| |
| LBasicBlock slowCase = m_out.newBlock(); |
| LBasicBlock continuation = m_out.newBlock(); |
| LBasicBlock lastNext = nullptr; |
| |
| if (!m_node->arrayMode().isInBounds()) { |
| LBasicBlock checkHole = m_out.newBlock(); |
| m_out.branch( |
| m_out.aboveOrEqual( |
| index, m_out.load32NonNegative(storage, m_heaps.Butterfly_publicLength)), |
| rarely(slowCase), usually(checkHole)); |
| lastNext = m_out.appendTo(checkHole, slowCase); |
| } else |
| lastNext = m_out.insertNewBlocksBefore(slowCase); |
| |
| LValue doubleValue = m_out.loadDouble(baseIndex(heap, storage, index, m_node->child2())); |
| LValue checkHoleResultValue = m_out.doubleEqual(doubleValue, doubleValue); |
| ValueFromBlock checkHoleResult = m_out.anchor(checkHoleResultValue); |
| m_out.branch(checkHoleResultValue, usually(continuation), rarely(slowCase)); |
| |
| m_out.appendTo(slowCase, continuation); |
| ValueFromBlock slowResult = m_out.anchor( |
| m_out.notZero64(vmCall(Int64, m_out.operation(operationHasIndexedPropertyByInt), m_callFrame, base, index, internalMethodType))); |
| m_out.jump(continuation); |
| |
| m_out.appendTo(continuation, lastNext); |
| setBoolean(m_out.phi(Int32, checkHoleResult, slowResult)); |
| return; |
| } |
| |
| case Array::ArrayStorage: { |
| LValue base = lowCell(m_node->child1()); |
| LValue index = lowInt32(m_node->child2()); |
| LValue storage = lowStorage(m_node->child3()); |
| LValue internalMethodType = m_out.constInt32(static_cast<int32_t>(m_node->internalMethodType())); |
| |
| LBasicBlock slowCase = m_out.newBlock(); |
| LBasicBlock continuation = m_out.newBlock(); |
| LBasicBlock lastNext = nullptr; |
| |
| if (!m_node->arrayMode().isInBounds()) { |
| LBasicBlock checkHole = m_out.newBlock(); |
| m_out.branch( |
| m_out.aboveOrEqual( |
| index, m_out.load32NonNegative(storage, m_heaps.ArrayStorage_vectorLength)), |
| rarely(slowCase), usually(checkHole)); |
| lastNext = m_out.appendTo(checkHole, slowCase); |
| } else |
| lastNext = m_out.insertNewBlocksBefore(slowCase); |
| |
| LValue checkHoleResultValue = |
| m_out.notZero64(m_out.load64(baseIndex(m_heaps.ArrayStorage_vector, storage, index, m_node->child2()))); |
| ValueFromBlock checkHoleResult = m_out.anchor(checkHoleResultValue); |
| m_out.branch(checkHoleResultValue, usually(continuation), rarely(slowCase)); |
| |
| m_out.appendTo(slowCase, continuation); |
| ValueFromBlock slowResult = m_out.anchor( |
| m_out.notZero64(vmCall(Int64, m_out.operation(operationHasIndexedPropertyByInt), m_callFrame, base, index, internalMethodType))); |
| m_out.jump(continuation); |
| |
| m_out.appendTo(continuation, lastNext); |
| setBoolean(m_out.phi(Int32, checkHoleResult, slowResult)); |
| break; |
| } |
| |
| default: { |
| LValue base = lowCell(m_node->child1()); |
| LValue index = lowInt32(m_node->child2()); |
| LValue internalMethodType = m_out.constInt32(static_cast<int32_t>(m_node->internalMethodType())); |
| setBoolean(m_out.notZero64(vmCall(Int64, m_out.operation(operationHasIndexedPropertyByInt), m_callFrame, base, index, internalMethodType))); |
| break; |
| } |
| } |
| } |
| |
| void compileHasGenericProperty() |
| { |
| LValue base = lowJSValue(m_node->child1()); |
| LValue property = lowCell(m_node->child2()); |
| setJSValue(vmCall(Int64, m_out.operation(operationHasGenericProperty), m_callFrame, base, property)); |
| } |
| |
| void compileHasStructureProperty() |
| { |
| LValue base = lowJSValue(m_node->child1()); |
| LValue property = lowString(m_node->child2()); |
| LValue enumerator = lowCell(m_node->child3()); |
| |
| LBasicBlock correctStructure = m_out.newBlock(); |
| LBasicBlock wrongStructure = m_out.newBlock(); |
| LBasicBlock continuation = m_out.newBlock(); |
| |
| m_out.branch(m_out.notEqual( |
| m_out.load32(base, m_heaps.JSCell_structureID), |
| m_out.load32(enumerator, m_heaps.JSPropertyNameEnumerator_cachedStructureID)), |
| rarely(wrongStructure), usually(correctStructure)); |
| |
| LBasicBlock lastNext = m_out.appendTo(correctStructure, wrongStructure); |
| ValueFromBlock correctStructureResult = m_out.anchor(m_out.booleanTrue); |
| m_out.jump(continuation); |
| |
| m_out.appendTo(wrongStructure, continuation); |
| ValueFromBlock wrongStructureResult = m_out.anchor( |
| m_out.equal( |
| m_out.constInt64(JSValue::encode(jsBoolean(true))), |
| vmCall(Int64, m_out.operation(operationHasGenericProperty), m_callFrame, base, property))); |
| m_out.jump(continuation); |
| |
| m_out.appendTo(continuation, lastNext); |
| setBoolean(m_out.phi(Int32, correctStructureResult, wrongStructureResult)); |
| } |
| |
| void compileGetDirectPname() |
| { |
| LValue base = lowCell(m_graph.varArgChild(m_node, 0)); |
| LValue property = lowCell(m_graph.varArgChild(m_node, 1)); |
| LValue index = lowInt32(m_graph.varArgChild(m_node, 2)); |
| LValue enumerator = lowCell(m_graph.varArgChild(m_node, 3)); |
| |
| LBasicBlock checkOffset = m_out.newBlock(); |
| LBasicBlock inlineLoad = m_out.newBlock(); |
| LBasicBlock outOfLineLoad = m_out.newBlock(); |
| LBasicBlock slowCase = m_out.newBlock(); |
| LBasicBlock continuation = m_out.newBlock(); |
| |
| m_out.branch(m_out.notEqual( |
| m_out.load32(base, m_heaps.JSCell_structureID), |
| m_out.load32(enumerator, m_heaps.JSPropertyNameEnumerator_cachedStructureID)), |
| rarely(slowCase), usually(checkOffset)); |
| |
| LBasicBlock lastNext = m_out.appendTo(checkOffset, inlineLoad); |
| m_out.branch(m_out.aboveOrEqual(index, m_out.load32(enumerator, m_heaps.JSPropertyNameEnumerator_cachedInlineCapacity)), |
| unsure(outOfLineLoad), unsure(inlineLoad)); |
| |
| m_out.appendTo(inlineLoad, outOfLineLoad); |
| ValueFromBlock inlineResult = m_out.anchor( |
| m_out.load64(m_out.baseIndex(m_heaps.properties.atAnyNumber(), |
| base, m_out.zeroExt(index, Int64), ScaleEight, JSObject::offsetOfInlineStorage()))); |
| m_out.jump(continuation); |
| |
| m_out.appendTo(outOfLineLoad, slowCase); |
| LValue storage = m_out.loadPtr(base, m_heaps.JSObject_butterfly); |
| LValue realIndex = m_out.signExt32To64( |
| m_out.neg(m_out.sub(index, m_out.load32(enumerator, m_heaps.JSPropertyNameEnumerator_cachedInlineCapacity)))); |
| int32_t offsetOfFirstProperty = static_cast<int32_t>(offsetInButterfly(firstOutOfLineOffset)) * sizeof(EncodedJSValue); |
| ValueFromBlock outOfLineResult = m_out.anchor( |
| m_out.load64(m_out.baseIndex(m_heaps.properties.atAnyNumber(), storage, realIndex, ScaleEight, offsetOfFirstProperty))); |
| m_out.jump(continuation); |
| |
| m_out.appendTo(slowCase, continuation); |
| ValueFromBlock slowCaseResult = m_out.anchor( |
| vmCall(Int64, m_out.operation(operationGetByVal), m_callFrame, base, property)); |
| m_out.jump(continuation); |
| |
| m_out.appendTo(continuation, lastNext); |
| setJSValue(m_out.phi(Int64, inlineResult, outOfLineResult, slowCaseResult)); |
| } |
| |
| void compileGetEnumerableLength() |
| { |
| LValue enumerator = lowCell(m_node->child1()); |
| setInt32(m_out.load32(enumerator, m_heaps.JSPropertyNameEnumerator_indexLength)); |
| } |
| |
| void compileGetPropertyEnumerator() |
| { |
| if (m_node->child1().useKind() == CellUse) |
| setJSValue(vmCall(Int64, m_out.operation(operationGetPropertyEnumeratorCell), m_callFrame, lowCell(m_node->child1()))); |
| else |
| setJSValue(vmCall(Int64, m_out.operation(operationGetPropertyEnumerator), m_callFrame, lowJSValue(m_node->child1()))); |
| } |
| |
| void compileGetEnumeratorStructurePname() |
| { |
| LValue enumerator = lowCell(m_node->child1()); |
| LValue index = lowInt32(m_node->child2()); |
| |
| LBasicBlock inBounds = m_out.newBlock(); |
| LBasicBlock outOfBounds = m_out.newBlock(); |
| LBasicBlock continuation = m_out.newBlock(); |
| |
| m_out.branch(m_out.below(index, m_out.load32(enumerator, m_heaps.JSPropertyNameEnumerator_endStructurePropertyIndex)), |
| usually(inBounds), rarely(outOfBounds)); |
| |
| LBasicBlock lastNext = m_out.appendTo(inBounds, outOfBounds); |
| LValue storage = m_out.loadPtr(enumerator, m_heaps.JSPropertyNameEnumerator_cachedPropertyNamesVector); |
| ValueFromBlock inBoundsResult = m_out.anchor( |
| m_out.loadPtr(m_out.baseIndex(m_heaps.JSPropertyNameEnumerator_cachedPropertyNamesVectorContents, storage, m_out.zeroExtPtr(index)))); |
| m_out.jump(continuation); |
| |
| m_out.appendTo(outOfBounds, continuation); |
| ValueFromBlock outOfBoundsResult = m_out.anchor(m_out.constInt64(ValueNull)); |
| m_out.jump(continuation); |
| |
| m_out.appendTo(continuation, lastNext); |
| setJSValue(m_out.phi(Int64, inBoundsResult, outOfBoundsResult)); |
| } |
| |
| void compileGetEnumeratorGenericPname() |
| { |
| LValue enumerator = lowCell(m_node->child1()); |
| LValue index = lowInt32(m_node->child2()); |
| |
| LBasicBlock inBounds = m_out.newBlock(); |
| LBasicBlock outOfBounds = m_out.newBlock(); |
| LBasicBlock continuation = m_out.newBlock(); |
| |
| m_out.branch(m_out.below(index, m_out.load32(enumerator, m_heaps.JSPropertyNameEnumerator_endGenericPropertyIndex)), |
| usually(inBounds), rarely(outOfBounds)); |
| |
| LBasicBlock lastNext = m_out.appendTo(inBounds, outOfBounds); |
| LValue storage = m_out.loadPtr(enumerator, m_heaps.JSPropertyNameEnumerator_cachedPropertyNamesVector); |
| ValueFromBlock inBoundsResult = m_out.anchor( |
| m_out.loadPtr(m_out.baseIndex(m_heaps.JSPropertyNameEnumerator_cachedPropertyNamesVectorContents, storage, m_out.zeroExtPtr(index)))); |
| m_out.jump(continuation); |
| |
| m_out.appendTo(outOfBounds, continuation); |
| ValueFromBlock outOfBoundsResult = m_out.anchor(m_out.constInt64(ValueNull)); |
| m_out.jump(continuation); |
| |
| m_out.appendTo(continuation, lastNext); |
| setJSValue(m_out.phi(Int64, inBoundsResult, outOfBoundsResult)); |
| } |
| |
| void compileToIndexString() |
| { |
| LValue index = lowInt32(m_node->child1()); |
| setJSValue(vmCall(Int64, m_out.operation(operationToIndexString), m_callFrame, index)); |
| } |
| |
| void compileCheckStructureImmediate() |
| { |
| LValue structure = lowCell(m_node->child1()); |
| checkStructure( |
| structure, noValue(), BadCache, m_node->structureSet(), |
| [this] (RegisteredStructure structure) { |
| return weakStructure(structure); |
| }); |
| } |
| |
| void compileMaterializeNewObject() |
| { |
| ObjectMaterializationData& data = m_node->objectMaterializationData(); |
| |
| // Lower the values first, to avoid creating values inside a control flow diamond. |
| |
| Vector<LValue, 8> values; |
| for (unsigned i = 0; i < data.m_properties.size(); ++i) { |
| Edge edge = m_graph.varArgChild(m_node, 1 + i); |
| switch (data.m_properties[i].kind()) { |
| case PublicLengthPLoc: |
| case VectorLengthPLoc: |
| values.append(lowInt32(edge)); |
| break; |
| default: |
| values.append(lowJSValue(edge)); |
| break; |
| } |
| } |
| |
| RegisteredStructureSet set = m_node->structureSet(); |
| |
| Vector<LBasicBlock, 1> blocks(set.size()); |
| for (unsigned i = set.size(); i--;) |
| blocks[i] = m_out.newBlock(); |
| LBasicBlock dummyDefault = m_out.newBlock(); |
| LBasicBlock outerContinuation = m_out.newBlock(); |
| |
| Vector<SwitchCase, 1> cases(set.size()); |
| for (unsigned i = set.size(); i--;) |
| cases[i] = SwitchCase(weakStructure(set.at(i)), blocks[i], Weight(1)); |
| m_out.switchInstruction( |
| lowCell(m_graph.varArgChild(m_node, 0)), cases, dummyDefault, Weight(0)); |
| |
| LBasicBlock outerLastNext = m_out.m_nextBlock; |
| |
| Vector<ValueFromBlock, 1> results; |
| |
| for (unsigned i = set.size(); i--;) { |
| m_out.appendTo(blocks[i], i + 1 < set.size() ? blocks[i + 1] : dummyDefault); |
| |
| RegisteredStructure structure = set.at(i); |
| |
| LValue object; |
| LValue butterfly; |
| |
| if (structure->outOfLineCapacity() || hasIndexedProperties(structure->indexingType())) { |
| size_t allocationSize = JSFinalObject::allocationSize(structure->inlineCapacity()); |
| Allocator cellAllocator = subspaceFor<JSFinalObject>(vm())->allocatorForNonVirtual(allocationSize, AllocatorForMode::AllocatorIfExists); |
| |
| bool hasIndexingHeader = hasIndexedProperties(structure->indexingType()); |
| unsigned indexingHeaderSize = 0; |
| LValue indexingPayloadSizeInBytes = m_out.intPtrZero; |
| LValue vectorLength = m_out.int32Zero; |
| LValue publicLength = m_out.int32Zero; |
| if (hasIndexingHeader) { |
| indexingHeaderSize = sizeof(IndexingHeader); |
| for (unsigned i = data.m_properties.size(); i--;) { |
| PromotedLocationDescriptor descriptor = data.m_properties[i]; |
| switch (descriptor.kind()) { |
| case PublicLengthPLoc: |
| publicLength = values[i]; |
| break; |
| case VectorLengthPLoc: |
| vectorLength = values[i]; |
| break; |
| default: |
| break; |
| } |
| } |
| indexingPayloadSizeInBytes = |
| m_out.mul(m_out.zeroExtPtr(vectorLength), m_out.intPtrEight); |
| } |
| |
| LValue butterflySize = m_out.add( |
| m_out.constIntPtr( |
| structure->outOfLineCapacity() * sizeof(JSValue) + indexingHeaderSize), |
| indexingPayloadSizeInBytes); |
| |
| LBasicBlock slowPath = m_out.newBlock(); |
| LBasicBlock continuation = m_out.newBlock(); |
| |
| LBasicBlock lastNext = m_out.insertNewBlocksBefore(slowPath); |
| |
| ValueFromBlock noButterfly = m_out.anchor(m_out.intPtrZero); |
| |
| LValue startOfStorage = allocateHeapCell( |
| allocatorForSize(vm().jsValueGigacageAuxiliarySpace, butterflySize, slowPath), |
| slowPath); |
| |
| LValue fastButterflyValue = m_out.add( |
| startOfStorage, |
| m_out.constIntPtr( |
| structure->outOfLineCapacity() * sizeof(JSValue) + sizeof(IndexingHeader))); |
| |
| ValueFromBlock haveButterfly = m_out.anchor(fastButterflyValue); |
| |
| splatWords( |
| fastButterflyValue, |
| m_out.constInt32(-structure->outOfLineCapacity() - 1), |
| m_out.constInt32(-1), |
| m_out.int64Zero, m_heaps.properties.atAnyNumber()); |
| |
| m_out.store32(vectorLength, fastButterflyValue, m_heaps.Butterfly_vectorLength); |
| |
| LValue fastObjectValue = allocateObject( |
| m_out.constInt32(cellAllocator.offset()), structure, fastButterflyValue, slowPath); |
| |
| ValueFromBlock fastObject = m_out.anchor(fastObjectValue); |
| ValueFromBlock fastButterfly = m_out.anchor(fastButterflyValue); |
| m_out.jump(continuation); |
| |
| m_out.appendTo(slowPath, continuation); |
| |
| LValue butterflyValue = m_out.phi(pointerType(), noButterfly, haveButterfly); |
| |
| VM& vm = this->vm(); |
| LValue slowObjectValue; |
| if (hasIndexingHeader) { |
| slowObjectValue = lazySlowPath( |
| [=, &vm] (const Vector<Location>& locations) -> RefPtr<LazySlowPath::Generator> { |
| return createLazyCallGenerator(vm, |
| operationNewObjectWithButterflyWithIndexingHeaderAndVectorLength, |
| locations[0].directGPR(), CCallHelpers::TrustedImmPtr(structure.get()), |
| locations[1].directGPR(), locations[2].directGPR()); |
| }, |
| vectorLength, butterflyValue); |
| } else { |
| slowObjectValue = lazySlowPath( |
| [=, &vm] (const Vector<Location>& locations) -> RefPtr<LazySlowPath::Generator> { |
| return createLazyCallGenerator(vm, |
| operationNewObjectWithButterfly, locations[0].directGPR(), |
| CCallHelpers::TrustedImmPtr(structure.get()), locations[1].directGPR()); |
| }, |
| butterflyValue); |
| } |
| ValueFromBlock slowObject = m_out.anchor(slowObjectValue); |
| ValueFromBlock slowButterfly = m_out.anchor( |
| m_out.loadPtr(slowObjectValue, m_heaps.JSObject_butterfly)); |
| |
| m_out.jump(continuation); |
| |
| m_out.appendTo(continuation, lastNext); |
| |
| object = m_out.phi(pointerType(), fastObject, slowObject); |
| butterfly = m_out.phi(pointerType(), fastButterfly, slowButterfly); |
| |
| m_out.store32(publicLength, butterfly, m_heaps.Butterfly_publicLength); |
| |
| initializeArrayElements(m_out.constInt32(structure->indexingType()), m_out.int32Zero, vectorLength, butterfly); |
| |
| HashMap<int32_t, LValue, DefaultHash<int32_t>::Hash, WTF::UnsignedWithZeroKeyHashTraits<int32_t>> indexMap; |
| Vector<int32_t> indices; |
| for (unsigned i = data.m_properties.size(); i--;) { |
| PromotedLocationDescriptor descriptor = data.m_properties[i]; |
| if (descriptor.kind() != IndexedPropertyPLoc) |
| continue; |
| int32_t index = static_cast<int32_t>(descriptor.info()); |
| |
| auto result = indexMap.add(index, values[i]); |
| DFG_ASSERT(m_graph, m_node, result); // Duplicates are illegal. |
| |
| indices.append(index); |
| } |
| |
| if (!indices.isEmpty()) { |
| std::sort(indices.begin(), indices.end()); |
| |
| Vector<LBasicBlock> blocksWithStores(indices.size()); |
| Vector<LBasicBlock> blocksWithChecks(indices.size()); |
| |
| for (unsigned i = indices.size(); i--;) { |
| blocksWithStores[i] = m_out.newBlock(); |
| blocksWithChecks[i] = m_out.newBlock(); // blocksWithChecks[0] is the continuation. |
| } |
| |
| LBasicBlock indexLastNext = m_out.m_nextBlock; |
| |
| for (unsigned i = indices.size(); i--;) { |
| int32_t index = indices[i]; |
| LValue value = indexMap.get(index); |
| |
| m_out.branch( |
| m_out.below(m_out.constInt32(index), publicLength), |
| unsure(blocksWithStores[i]), unsure(blocksWithChecks[i])); |
| |
| m_out.appendTo(blocksWithStores[i], blocksWithChecks[i]); |
| |
| // This has to type-check and convert its inputs, but it cannot do so in a |
| // way that updates AI. That's a bit annoying, but if you think about how |
| // sinking works, it's actually not a bad thing. We are virtually guaranteed |
| // that these type checks will not fail, since the type checks that guarded |
| // the original stores to the array are still somewhere above this point. |
| Output::StoreType storeType; |
| IndexedAbstractHeap* heap; |
| switch (structure->indexingType()) { |
| case ALL_INT32_INDEXING_TYPES: |
| // FIXME: This could use the proven type if we had the Edge for the |
| // value. https://bugs.webkit.org/show_bug.cgi?id=155311 |
| speculate(BadType, noValue(), nullptr, isNotInt32(value)); |
| storeType = Output::Store64; |
| heap = &m_heaps.indexedInt32Properties; |
| break; |
| |
| case ALL_DOUBLE_INDEXING_TYPES: { |
| // FIXME: If the source is ValueRep, we should avoid emitting any |
| // checks. We could also avoid emitting checks if we had the Edge of |
| // this value. https://bugs.webkit.org/show_bug.cgi?id=155311 |
| |
| LBasicBlock intCase = m_out.newBlock(); |
| LBasicBlock doubleCase = m_out.newBlock(); |
| LBasicBlock continuation = m_out.newBlock(); |
| |
| m_out.branch(isInt32(value), unsure(intCase), unsure(doubleCase)); |
| |
| LBasicBlock lastNext = m_out.appendTo(intCase, doubleCase); |
| |
| ValueFromBlock intResult = |
| m_out.anchor(m_out.intToDouble(unboxInt32(value))); |
| m_out.jump(continuation); |
| |
| m_out.appendTo(doubleCase, continuation); |
| |
| speculate(BadType, noValue(), nullptr, isNumber(value)); |
| ValueFromBlock doubleResult = m_out.anchor(unboxDouble(value)); |
| m_out.jump(continuation); |
| |
| m_out.appendTo(continuation, lastNext); |
| value = m_out.phi(Double, intResult, doubleResult); |
| storeType = Output::StoreDouble; |
| heap = &m_heaps.indexedDoubleProperties; |
| break; |
| } |
| |
| case ALL_CONTIGUOUS_INDEXING_TYPES: |
| storeType = Output::Store64; |
| heap = &m_heaps.indexedContiguousProperties; |
| break; |
| |
| default: |
| DFG_CRASH(m_graph, m_node, "Invalid indexing type"); |
| break; |
| } |
| |
| m_out.store(value, m_out.address(butterfly, heap->at(index)), storeType); |
| |
| m_out.jump(blocksWithChecks[i]); |
| m_out.appendTo( |
| blocksWithChecks[i], i ? blocksWithStores[i - 1] : indexLastNext); |
| } |
| } |
| } else { |
| // In the easy case where we can do a one-shot allocation, we simply allocate the |
| // object to directly have the desired structure. |
| object = allocateObject(structure); |
| butterfly = nullptr; // Don't have one, don't need one. |
| } |
| |
| BitVector setInlineOffsets; |
| for (PropertyMapEntry entry : structure->getPropertiesConcurrently()) { |
| for (unsigned i = data.m_properties.size(); i--;) { |
| PromotedLocationDescriptor descriptor = data.m_properties[i]; |
| if (descriptor.kind() != NamedPropertyPLoc) |
| continue; |
| if (m_graph.identifiers()[descriptor.info()] != entry.key) |
| continue; |
| |
| LValue base; |
| if (isInlineOffset(entry.offset)) { |
| setInlineOffsets.set(entry.offset); |
| base = object; |
| } else |
| base = butterfly; |
| storeProperty(values[i], base, descriptor.info(), entry.offset); |
| break; |
| } |
| } |
| for (unsigned i = structure->inlineCapacity(); i--;) { |
| if (!setInlineOffsets.get(i)) |
| m_out.store64(m_out.int64Zero, m_out.address(m_heaps.properties.atAnyNumber(), object, offsetRelativeToBase(i))); |
| } |
| |
| results.append(m_out.anchor(object)); |
| m_out.jump(outerContinuation); |
| } |
| |
| m_out.appendTo(dummyDefault, outerContinuation); |
| m_out.unreachable(); |
| |
| m_out.appendTo(outerContinuation, outerLastNext); |
| setJSValue(m_out.phi(pointerType(), results)); |
| mutatorFence(); |
| } |
| |
| void compileMaterializeCreateActivation() |
| { |
| ObjectMaterializationData& data = m_node->objectMaterializationData(); |
| |
| Vector<LValue, 8> values; |
| for (unsigned i = 0; i < data.m_properties.size(); ++i) |
| values.append(lowJSValue(m_graph.varArgChild(m_node, 2 + i))); |
| |
| LValue scope = lowCell(m_graph.varArgChild(m_node, 1)); |
| SymbolTable* table = m_node->castOperand<SymbolTable*>(); |
| ASSERT(table == m_graph.varArgChild(m_node, 0)->castConstant<SymbolTable*>(vm())); |
| RegisteredStructure structure = m_graph.registerStructure(m_graph.globalObjectFor(m_node->origin.semantic)->activationStructure()); |
| |
| LBasicBlock slowPath = m_out.newBlock(); |
| LBasicBlock continuation = m_out.newBlock(); |
| |
| LBasicBlock lastNext = m_out.insertNewBlocksBefore(slowPath); |
| |
| LValue fastObject = allocateObject<JSLexicalEnvironment>( |
| JSLexicalEnvironment::allocationSize(table), structure, m_out.intPtrZero, slowPath); |
| |
| m_out.storePtr(scope, fastObject, m_heaps.JSScope_next); |
| m_out.storePtr(weakPointer(table), fastObject, m_heaps.JSSymbolTableObject_symbolTable); |
| |
| |
| ValueFromBlock fastResult = m_out.anchor(fastObject); |
| m_out.jump(continuation); |
| |
| m_out.appendTo(slowPath, continuation); |
| // We ensure allocation sinking explictly sets bottom values for all field members. |
| // Therefore, it doesn't matter what JSValue we pass in as the initialization value |
| // because all fields will be overwritten. |
| // FIXME: It may be worth creating an operation that calls a constructor on JSLexicalEnvironment that |
| // doesn't initialize every slot because we are guaranteed to do that here. |
| VM& vm = this->vm(); |
| LValue callResult = lazySlowPath( |
| [=, &vm] (const Vector<Location>& locations) -> RefPtr<LazySlowPath::Generator> { |
| return createLazyCallGenerator(vm, |
| operationCreateActivationDirect, locations[0].directGPR(), |
| CCallHelpers::TrustedImmPtr(structure.get()), locations[1].directGPR(), |
| CCallHelpers::TrustedImmPtr(table), |
| CCallHelpers::TrustedImm64(JSValue::encode(jsUndefined()))); |
| }, scope); |
| ValueFromBlock slowResult = m_out.anchor(callResult); |
| m_out.jump(continuation); |
| |
| m_out.appendTo(continuation, lastNext); |
| LValue activation = m_out.phi(pointerType(), fastResult, slowResult); |
| RELEASE_ASSERT(data.m_properties.size() == table->scopeSize()); |
| for (unsigned i = 0; i < data.m_properties.size(); ++i) { |
| PromotedLocationDescriptor descriptor = data.m_properties[i]; |
| ASSERT(descriptor.kind() == ClosureVarPLoc); |
| m_out.store64( |
| values[i], activation, |
| m_heaps.JSLexicalEnvironment_variables[descriptor.info()]); |
| } |
| |
| if (validationEnabled()) { |
| // Validate to make sure every slot in the scope has one value. |
| ConcurrentJSLocker locker(table->m_lock); |
| for (auto iter = table->begin(locker), end = table->end(locker); iter != end; ++iter) { |
| bool found = false; |
| for (unsigned i = 0; i < data.m_properties.size(); ++i) { |
| PromotedLocationDescriptor descriptor = data.m_properties[i]; |
| ASSERT(descriptor.kind() == ClosureVarPLoc); |
| if (iter->value.scopeOffset().offset() == descriptor.info()) { |
| found = true; |
| break; |
| } |
| } |
| ASSERT_UNUSED(found, found); |
| } |
| } |
| |
| mutatorFence(); |
| setJSValue(activation); |
| } |
| |
| void compileCheckTraps() |
| { |
| ASSERT(Options::usePollingTraps()); |
| LBasicBlock needTrapHandling = m_out.newBlock(); |
| LBasicBlock continuation = m_out.newBlock(); |
| |
| LValue state = m_out.load8ZeroExt32(m_out.absolute(vm().needTrapHandlingAddress())); |
| m_out.branch(m_out.isZero32(state), |
| usually(continuation), rarely(needTrapHandling)); |
| |
| LBasicBlock lastNext = m_out.appendTo(needTrapHandling, continuation); |
| |
| VM& vm = this->vm(); |
| lazySlowPath( |
| [=, &vm] (const Vector<Location>&) -> RefPtr<LazySlowPath::Generator> { |
| return createLazyCallGenerator(vm, operationHandleTraps, InvalidGPRReg); |
| }); |
| m_out.jump(continuation); |
| |
| m_out.appendTo(continuation, lastNext); |
| } |
| |
| void compileRegExpExec() |
| { |
| LValue globalObject = lowCell(m_node->child1()); |
| |
| if (m_node->child2().useKind() == RegExpObjectUse) { |
| LValue base = lowRegExpObject(m_node->child2()); |
| |
| if (m_node->child3().useKind() == StringUse) { |
| LValue argument = lowString(m_node->child3()); |
| LValue result = vmCall( |
| Int64, m_out.operation(operationRegExpExecString), m_callFrame, globalObject, |
| base, argument); |
| setJSValue(result); |
| return; |
| } |
| |
| LValue argument = lowJSValue(m_node->child3()); |
| LValue result = vmCall( |
| Int64, m_out.operation(operationRegExpExec), m_callFrame, globalObject, base, |
| argument); |
| setJSValue(result); |
| return; |
| } |
| |
| LValue base = lowJSValue(m_node->child2()); |
| LValue argument = lowJSValue(m_node->child3()); |
| LValue result = vmCall( |
| Int64, m_out.operation(operationRegExpExecGeneric), m_callFrame, globalObject, base, |
| argument); |
| setJSValue(result); |
| } |
| |
| void compileRegExpExecNonGlobalOrSticky() |
| { |
| LValue globalObject = lowCell(m_node->child1()); |
| LValue argument = lowString(m_node->child2()); |
| LValue result = vmCall( |
| Int64, m_out.operation(operationRegExpExecNonGlobalOrSticky), m_callFrame, globalObject, frozenPointer(m_node->cellOperand()), argument); |
| setJSValue(result); |
| } |
| |
| void compileRegExpMatchFastGlobal() |
| { |
| LValue globalObject = lowCell(m_node->child1()); |
| LValue argument = lowString(m_node->child2()); |
| LValue result = vmCall( |
| Int64, m_out.operation(operationRegExpMatchFastGlobalString), m_callFrame, globalObject, frozenPointer(m_node->cellOperand()), argument); |
| setJSValue(result); |
| } |
| |
| void compileRegExpTest() |
| { |
| LValue globalObject = lowCell(m_node->child1()); |
| |
| if (m_node->child2().useKind() == RegExpObjectUse) { |
| LValue base = lowRegExpObject(m_node->child2()); |
| |
| if (m_node->child3().useKind() == StringUse) { |
| LValue argument = lowString(m_node->child3()); |
| LValue result = vmCall( |
| Int32, m_out.operation(operationRegExpTestString), m_callFrame, globalObject, |
| base, argument); |
| setBoolean(result); |
| return; |
| } |
| |
| LValue argument = lowJSValue(m_node->child3()); |
| LValue result = vmCall( |
| Int32, m_out.operation(operationRegExpTest), m_callFrame, globalObject, base, |
| argument); |
| setBoolean(result); |
| return; |
| } |
| |
| LValue base = lowJSValue(m_node->child2()); |
| LValue argument = lowJSValue(m_node->child3()); |
| LValue result = vmCall( |
| Int32, m_out.operation(operationRegExpTestGeneric), m_callFrame, globalObject, base, |
| argument); |
| setBoolean(result); |
| } |
| |
| void compileRegExpMatchFast() |
| { |
| LValue globalObject = lowCell(m_node->child1()); |
| LValue base = lowRegExpObject(m_node->child2()); |
| LValue argument = lowString(m_node->child3()); |
| LValue result = vmCall( |
| Int64, m_out.operation(operationRegExpMatchFastString), m_callFrame, globalObject, |
| base, argument); |
| setJSValue(result); |
| } |
| |
| void compileNewRegexp() |
| { |
| FrozenValue* regexp = m_node->cellOperand(); |
| LValue lastIndex = lowJSValue(m_node->child1()); |
| ASSERT(regexp->cell()->inherits<RegExp>(vm())); |
| ASSERT(m_node->castOperand<RegExp*>()->isValid()); |
| |
| LBasicBlock slowCase = m_out.newBlock(); |
| LBasicBlock continuation = m_out.newBlock(); |
| |
| LBasicBlock lastNext = m_out.insertNewBlocksBefore(slowCase); |
| |
| auto structure = m_graph.registerStructure(m_graph.globalObjectFor(m_node->origin.semantic)->regExpStructure()); |
| LValue fastResultValue = allocateObject<RegExpObject>(structure, m_out.intPtrZero, slowCase); |
| m_out.storePtr(frozenPointer(regexp), fastResultValue, m_heaps.RegExpObject_regExp); |
| m_out.store64(lastIndex, fastResultValue, m_heaps.RegExpObject_lastIndex); |
| m_out.store32As8(m_out.constInt32(true), m_out.address(fastResultValue, m_heaps.RegExpObject_lastIndexIsWritable)); |
| mutatorFence(); |
| ValueFromBlock fastResult = m_out.anchor(fastResultValue); |
| m_out.jump(continuation); |
| |
| m_out.appendTo(slowCase, continuation); |
| VM& vm = this->vm(); |
| RegExp* regexpCell = regexp->cast<RegExp*>(); |
| LValue slowResultValue = lazySlowPath( |
| [=, &vm] (const Vector<Location>& locations) -> RefPtr<LazySlowPath::Generator> { |
| return createLazyCallGenerator(vm, |
| operationNewRegexpWithLastIndex, locations[0].directGPR(), |
| CCallHelpers::TrustedImmPtr(regexpCell), locations[1].directGPR()); |
| }, lastIndex); |
| ValueFromBlock slowResult = m_out.anchor(slowResultValue); |
| m_out.jump(continuation); |
| |
| m_out.appendTo(continuation, lastNext); |
| setJSValue(m_out.phi(pointerType(), fastResult, slowResult)); |
| } |
| |
| void compileSetFunctionName() |
| { |
| vmCall(Void, m_out.operation(operationSetFunctionName), m_callFrame, |
| lowCell(m_node->child1()), lowJSValue(m_node->child2())); |
| } |
| |
| void compileStringReplace() |
| { |
| if (m_node->child1().useKind() == StringUse |
| && m_node->child2().useKind() == RegExpObjectUse |
| && m_node->child3().useKind() == StringUse) { |
| |
| if (JSString* replace = m_node->child3()->dynamicCastConstant<JSString*>(vm())) { |
| if (!replace->length()) { |
| LValue string = lowString(m_node->child1()); |
| LValue regExp = lowRegExpObject(m_node->child2()); |
| |
| LValue result = vmCall( |
| pointerType(), m_out.operation(operationStringProtoFuncReplaceRegExpEmptyStr), |
| m_callFrame, string, regExp); |
| |
| setJSValue(result); |
| return; |
| } |
| } |
| |
| LValue string = lowString(m_node->child1()); |
| LValue regExp = lowRegExpObject(m_node->child2()); |
| LValue replace = lowString(m_node->child3()); |
| |
| LValue result = vmCall( |
| pointerType(), m_out.operation(operationStringProtoFuncReplaceRegExpString), |
| m_callFrame, string, regExp, replace); |
| |
| setJSValue(result); |
| return; |
| } |
| |
| LValue search; |
| if (m_node->child2().useKind() == StringUse) |
| search = lowString(m_node->child2()); |
| else |
| search = lowJSValue(m_node->child2()); |
| |
| LValue result = vmCall( |
| pointerType(), m_out.operation(operationStringProtoFuncReplaceGeneric), m_callFrame, |
| lowJSValue(m_node->child1()), search, |
| lowJSValue(m_node->child3())); |
| |
| setJSValue(result); |
| } |
| |
| void compileGetRegExpObjectLastIndex() |
| { |
| setJSValue(m_out.load64(lowRegExpObject(m_node->child1()), m_heaps.RegExpObject_lastIndex)); |
| } |
| |
| void compileSetRegExpObjectLastIndex() |
| { |
| if (!m_node->ignoreLastIndexIsWritable()) { |
| LValue regExp = lowRegExpObject(m_node->child1()); |
| LValue value = lowJSValue(m_node->child2()); |
| |
| speculate( |
| ExoticObjectMode, noValue(), nullptr, |
| m_out.isZero32(m_out.load8ZeroExt32(regExp, m_heaps.RegExpObject_lastIndexIsWritable))); |
| |
| m_out.store64(value, regExp, m_heaps.RegExpObject_lastIndex); |
| return; |
| } |
| |
| m_out.store64(lowJSValue(m_node->child2()), lowCell(m_node->child1()), m_heaps.RegExpObject_lastIndex); |
| } |
| |
| void compileLogShadowChickenPrologue() |
| { |
| LValue packet = ensureShadowChickenPacket(); |
| LValue scope = lowCell(m_node->child1()); |
| |
| m_out.storePtr(m_callFrame, packet, m_heaps.ShadowChicken_Packet_frame); |
| m_out.storePtr(m_out.loadPtr(addressFor(0)), packet, m_heaps.ShadowChicken_Packet_callerFrame); |
| m_out.storePtr(m_out.loadPtr(payloadFor(CallFrameSlot::callee)), packet, m_heaps.ShadowChicken_Packet_callee); |
| m_out.storePtr(scope, packet, m_heaps.ShadowChicken_Packet_scope); |
| } |
| |
| void compileLogShadowChickenTail() |
| { |
| LValue packet = ensureShadowChickenPacket(); |
| LValue thisValue = lowJSValue(m_node->child1()); |
| LValue scope = lowCell(m_node->child2()); |
| CallSiteIndex callSiteIndex = m_ftlState.jitCode->common.addCodeOrigin(m_node->origin.semantic); |
| |
| m_out.storePtr(m_callFrame, packet, m_heaps.ShadowChicken_Packet_frame); |
| m_out.storePtr(m_out.constIntPtr(bitwise_cast<intptr_t>(ShadowChicken::Packet::tailMarker())), packet, m_heaps.ShadowChicken_Packet_callee); |
| m_out.store64(thisValue, packet, m_heaps.ShadowChicken_Packet_thisValue); |
| m_out.storePtr(scope, packet, m_heaps.ShadowChicken_Packet_scope); |
| // We don't want the CodeBlock to have a weak pointer to itself because |
| // that would cause it to always get collected. |
| m_out.storePtr(m_out.constIntPtr(bitwise_cast<intptr_t>(codeBlock())), packet, m_heaps.ShadowChicken_Packet_codeBlock); |
| m_out.store32(m_out.constInt32(callSiteIndex.bits()), packet, m_heaps.ShadowChicken_Packet_callSiteIndex); |
| } |
| |
| void compileRecordRegExpCachedResult() |
| { |
| Edge constructorEdge = m_graph.varArgChild(m_node, 0); |
| Edge regExpEdge = m_graph.varArgChild(m_node, 1); |
| Edge stringEdge = m_graph.varArgChild(m_node, 2); |
| Edge startEdge = m_graph.varArgChild(m_node, 3); |
| Edge endEdge = m_graph.varArgChild(m_node, 4); |
| |
| LValue constructor = lowCell(constructorEdge); |
| LValue regExp = lowCell(regExpEdge); |
| LValue string = lowCell(stringEdge); |
| LValue start = lowInt32(startEdge); |
| LValue end = lowInt32(endEdge); |
| |
| m_out.storePtr(regExp, constructor, m_heaps.RegExpConstructor_cachedResult_lastRegExp); |
| m_out.storePtr(string, constructor, m_heaps.RegExpConstructor_cachedResult_lastInput); |
| m_out.store32(start, constructor, m_heaps.RegExpConstructor_cachedResult_result_start); |
| m_out.store32(end, constructor, m_heaps.RegExpConstructor_cachedResult_result_end); |
| m_out.store32As8( |
| m_out.constInt32(0), |
| m_out.address(constructor, m_heaps.RegExpConstructor_cachedResult_reified)); |
| } |
| |
| struct ArgumentsLength { |
| ArgumentsLength() |
| : isKnown(false) |
| , known(UINT_MAX) |
| , value(nullptr) |
| { |
| } |
| |
| bool isKnown; |
| unsigned known; |
| LValue value; |
| }; |
| ArgumentsLength getArgumentsLength(InlineCallFrame* inlineCallFrame) |
| { |
| ArgumentsLength length; |
| |
| if (inlineCallFrame && !inlineCallFrame->isVarargs()) { |
| length.known = inlineCallFrame->argumentCountIncludingThis - 1; |
| length.isKnown = true; |
| length.value = m_out.constInt32(length.known); |
| } else { |
| length.known = UINT_MAX; |
| length.isKnown = false; |
| |
| VirtualRegister argumentCountRegister; |
| if (!inlineCallFrame) |
| argumentCountRegister = VirtualRegister(CallFrameSlot::argumentCount); |
| else |
| argumentCountRegister = inlineCallFrame->argumentCountRegister; |
| length.value = m_out.sub(m_out.load32(payloadFor(argumentCountRegister)), m_out.int32One); |
| } |
| |
| return length; |
| } |
| |
| ArgumentsLength getArgumentsLength() |
| { |
| return getArgumentsLength(m_node->origin.semantic.inlineCallFrame); |
| } |
| |
| LValue getCurrentCallee() |
| { |
| if (InlineCallFrame* frame = m_node->origin.semantic.inlineCallFrame) { |
| if (frame->isClosureCall) |
| return m_out.loadPtr(addressFor(frame->calleeRecovery.virtualRegister())); |
| return weakPointer(frame->calleeRecovery.constant().asCell()); |
| } |
| return m_out.loadPtr(addressFor(CallFrameSlot::callee)); |
| } |
| |
| LValue getArgumentsStart(InlineCallFrame* inlineCallFrame, unsigned offset = 0) |
| { |
| VirtualRegister start = AssemblyHelpers::argumentsStart(inlineCallFrame) + offset; |
| return addressFor(start).value(); |
| } |
| |
| LValue getArgumentsStart() |
| { |
| return getArgumentsStart(m_node->origin.semantic.inlineCallFrame); |
| } |
| |
| template<typename Functor> |
| void checkStructure( |
| LValue structureDiscriminant, const FormattedValue& formattedValue, ExitKind exitKind, |
| RegisteredStructureSet set, const Functor& weakStructureDiscriminant) |
| { |
| if (set.isEmpty()) { |
| terminate(exitKind); |
| return; |
| } |
| |
| if (set.size() == 1) { |
| speculate( |
| exitKind, formattedValue, 0, |
| m_out.notEqual(structureDiscriminant, weakStructureDiscriminant(set[0]))); |
| return; |
| } |
| |
| LBasicBlock continuation = m_out.newBlock(); |
| |
| LBasicBlock lastNext = m_out.insertNewBlocksBefore(continuation); |
| for (unsigned i = 0; i < set.size() - 1; ++i) { |
| LBasicBlock nextStructure = m_out.newBlock(); |
| m_out.branch( |
| m_out.equal(structureDiscriminant, weakStructureDiscriminant(set[i])), |
| unsure(continuation), unsure(nextStructure)); |
| m_out.appendTo(nextStructure); |
| } |
| |
| speculate( |
| exitKind, formattedValue, 0, |
| m_out.notEqual(structureDiscriminant, weakStructureDiscriminant(set.last()))); |
| |
| m_out.jump(continuation); |
| m_out.appendTo(continuation, lastNext); |
| } |
| |
| LValue numberOrNotCellToInt32(Edge edge, LValue value) |
| { |
| LBasicBlock intCase = m_out.newBlock(); |
| LBasicBlock notIntCase = m_out.newBlock(); |
| LBasicBlock doubleCase = 0; |
| LBasicBlock notNumberCase = 0; |
| if (edge.useKind() == NotCellUse) { |
| doubleCase = m_out.newBlock(); |
| notNumberCase = m_out.newBlock(); |
| } |
| LBasicBlock continuation = m_out.newBlock(); |
| |
| Vector<ValueFromBlock> results; |
| |
| m_out.branch(isNotInt32(value), unsure(notIntCase), unsure(intCase)); |
| |
| LBasicBlock lastNext = m_out.appendTo(intCase, notIntCase); |
| results.append(m_out.anchor(unboxInt32(value))); |
| m_out.jump(continuation); |
| |
| if (edge.useKind() == NumberUse) { |
| m_out.appendTo(notIntCase, continuation); |
| FTL_TYPE_CHECK(jsValueValue(value), edge, SpecBytecodeNumber, isCellOrMisc(value)); |
| results.append(m_out.anchor(doubleToInt32(unboxDouble(value)))); |
| m_out.jump(continuation); |
| } else { |
| m_out.appendTo(notIntCase, doubleCase); |
| m_out.branch( |
| isCellOrMisc(value, provenType(edge)), unsure(notNumberCase), unsure(doubleCase)); |
| |
| m_out.appendTo(doubleCase, notNumberCase); |
| results.append(m_out.anchor(doubleToInt32(unboxDouble(value)))); |
| m_out.jump(continuation); |
| |
| m_out.appendTo(notNumberCase, continuation); |
| |
| FTL_TYPE_CHECK(jsValueValue(value), edge, ~SpecCellCheck, isCell(value)); |
| |
| LValue specialResult = m_out.select( |
| m_out.equal(value, m_out.constInt64(JSValue::encode(jsBoolean(true)))), |
| m_out.int32One, m_out.int32Zero); |
| results.append(m_out.anchor(specialResult)); |
| m_out.jump(continuation); |
| } |
| |
| m_out.appendTo(continuation, lastNext); |
| return m_out.phi(Int32, results); |
| } |
| |
| void checkInferredType(Edge edge, LValue value, const InferredType::Descriptor& type) |
| { |
| // This cannot use FTL_TYPE_CHECK or typeCheck() because it is called partially, as in a node like: |
| // |
| // MultiPutByOffset(...) |
| // |
| // may be lowered to: |
| // |
| // switch (object->structure) { |
| // case 42: |
| // checkInferredType(..., type1); |
| // ... |
| // break; |
| // case 43: |
| // checkInferredType(..., type2); |
| // ... |
| // break; |
| // } |
| // |
| // where type1 and type2 are different. Using typeCheck() would mean that the edge would be |
| // filtered by type1 & type2, instead of type1 | type2. |
| |
| switch (type.kind()) { |
| case InferredType::Bottom: |
| speculate(BadType, jsValueValue(value), edge.node(), m_out.booleanTrue); |
| return; |
| |
| case InferredType::Boolean: |
| speculate(BadType, jsValueValue(value), edge.node(), isNotBoolean(value, provenType(edge))); |
| return; |
| |
| case InferredType::Other: |
| speculate(BadType, jsValueValue(value), edge.node(), isNotOther(value, provenType(edge))); |
| return; |
| |
| case InferredType::Int32: |
| speculate(BadType, jsValueValue(value), edge.node(), isNotInt32(value, provenType(edge))); |
| return; |
| |
| case InferredType::Number: |
| speculate(BadType, jsValueValue(value), edge.node(), isNotNumber(value, provenType(edge))); |
| return; |
| |
| case InferredType::String: |
| speculate(BadType, jsValueValue(value), edge.node(), isNotCell(value, provenType(edge))); |
| speculate(BadType, jsValueValue(value), edge.node(), isNotString(value, provenType(edge))); |
| return; |
| |
| case InferredType::Symbol: |
| speculate(BadType, jsValueValue(value), edge.node(), isNotCell(value, provenType(edge))); |
| speculate(BadType, jsValueValue(value), edge.node(), isNotSymbol(value, provenType(edge))); |
| return; |
| |
| case InferredType::BigInt: |
| speculate(BadType, jsValueValue(value), edge.node(), isNotCell(value, provenType(edge))); |
| speculate(BadType, jsValueValue(value), edge.node(), isNotBigInt(value, provenType(edge))); |
| return; |
| |
| case InferredType::ObjectWithStructure: { |
| RegisteredStructure structure = m_graph.registerStructure(type.structure()); |
| speculate(BadType, jsValueValue(value), edge.node(), isNotCell(value, provenType(edge))); |
| if (!abstractValue(edge).m_structure.isSubsetOf(RegisteredStructureSet(structure))) { |
| speculate( |
| BadType, jsValueValue(value), edge.node(), |
| m_out.notEqual( |
| m_out.load32(value, m_heaps.JSCell_structureID), |
| weakStructureID(structure))); |
| } |
| return; |
| } |
| |
| case InferredType::ObjectWithStructureOrOther: { |
| LBasicBlock cellCase = m_out.newBlock(); |
| LBasicBlock notCellCase = m_out.newBlock(); |
| LBasicBlock continuation = m_out.newBlock(); |
| |
| m_out.branch(isCell(value, provenType(edge)), unsure(cellCase), unsure(notCellCase)); |
| |
| LBasicBlock lastNext = m_out.appendTo(cellCase, notCellCase); |
| |
| RegisteredStructure structure = m_graph.registerStructure(type.structure()); |
| if (!abstractValue(edge).m_structure.isSubsetOf(RegisteredStructureSet(structure))) { |
| speculate( |
| BadType, jsValueValue(value), edge.node(), |
| m_out.notEqual( |
| m_out.load32(value, m_heaps.JSCell_structureID), |
| weakStructureID(structure))); |
| } |
| |
| m_out.jump(continuation); |
| |
| m_out.appendTo(notCellCase, continuation); |
| |
| speculate( |
| BadType, jsValueValue(value), edge.node(), |
| isNotOther(value, provenType(edge) & ~SpecCell)); |
| |
| m_out.jump(continuation); |
| |
| m_out.appendTo(continuation, lastNext); |
| return; |
| } |
| |
| case InferredType::Object: |
| speculate(BadType, jsValueValue(value), edge.node(), isNotCell(value, provenType(edge))); |
| speculate(BadType, jsValueValue(value), edge.node(), isNotObject(value, provenType(edge))); |
| return; |
| |
| case InferredType::ObjectOrOther: { |
| LBasicBlock cellCase = m_out.newBlock(); |
| LBasicBlock notCellCase = m_out.newBlock(); |
| LBasicBlock continuation = m_out.newBlock(); |
| |
| m_out.branch(isCell(value, provenType(edge)), unsure(cellCase), unsure(notCellCase)); |
| |
| LBasicBlock lastNext = m_out.appendTo(cellCase, notCellCase); |
| |
| speculate( |
| BadType, jsValueValue(value), edge.node(), |
| isNotObject(value, provenType(edge) & SpecCell)); |
| |
| m_out.jump(continuation); |
| |
| m_out.appendTo(notCellCase, continuation); |
| |
| speculate( |
| BadType, jsValueValue(value), edge.node(), |
| isNotOther(value, provenType(edge) & ~SpecCell)); |
| |
| m_out.jump(continuation); |
| |
| m_out.appendTo(continuation, lastNext); |
| return; |
| } |
| |
| case InferredType::Top: |
| return; |
| } |
| |
| DFG_CRASH(m_graph, m_node, "Bad inferred type"); |
| } |
| |
| LValue loadProperty(LValue storage, unsigned identifierNumber, PropertyOffset offset) |
| { |
| return m_out.load64(addressOfProperty(storage, identifierNumber, offset)); |
| } |
| |
| void storeProperty( |
| LValue value, LValue storage, unsigned identifierNumber, PropertyOffset offset) |
| { |
| m_out.store64(value, addressOfProperty(storage, identifierNumber, offset)); |
| } |
| |
| TypedPointer addressOfProperty( |
| LValue storage, unsigned identifierNumber, PropertyOffset offset) |
| { |
| return m_out.address( |
| m_heaps.properties[identifierNumber], storage, offsetRelativeToBase(offset)); |
| } |
| |
| LValue storageForTransition( |
| LValue object, PropertyOffset offset, |
| Structure* previousStructure, Structure* nextStructure) |
| { |
| if (isInlineOffset(offset)) |
| return object; |
| |
| if (previousStructure->outOfLineCapacity() == nextStructure->outOfLineCapacity()) |
| return m_out.loadPtr(object, m_heaps.JSObject_butterfly); |
| |
| LValue result; |
| if (!previousStructure->outOfLineCapacity()) |
| result = allocatePropertyStorage(object, previousStructure); |
| else { |
| result = reallocatePropertyStorage( |
| object, m_out.loadPtr(object, m_heaps.JSObject_butterfly), |
| previousStructure, nextStructure); |
| } |
| |
| nukeStructureAndSetButterfly(result, object); |
| return result; |
| } |
| |
| void initializeArrayElements(LValue indexingType, LValue begin, LValue end, LValue butterfly) |
| { |
| |
| if (begin == end) |
| return; |
| |
| if (indexingType->hasInt32()) { |
| IndexingType rawIndexingType = static_cast<IndexingType>(indexingType->asInt32()); |
| if (hasUndecided(rawIndexingType)) |
| return; |
| IndexedAbstractHeap* heap = m_heaps.forIndexingType(rawIndexingType); |
| DFG_ASSERT(m_graph, m_node, heap); |
| |
| LValue hole; |
| if (hasDouble(rawIndexingType)) |
| hole = m_out.constInt64(bitwise_cast<int64_t>(PNaN)); |
| else |
| hole = m_out.constInt64(JSValue::encode(JSValue())); |
| |
| splatWords(butterfly, begin, end, hole, heap->atAnyIndex()); |
| } else { |
| LValue hole = m_out.select( |
| m_out.equal(m_out.bitAnd(indexingType, m_out.constInt32(IndexingShapeMask)), m_out.constInt32(DoubleShape)), |
| m_out.constInt64(bitwise_cast<int64_t>(PNaN)), |
| m_out.constInt64(JSValue::encode(JSValue()))); |
| splatWords(butterfly, begin, end, hole, m_heaps.root); |
| } |
| } |
| |
| void splatWords(LValue base, LValue begin, LValue end, LValue value, const AbstractHeap& heap) |
| { |
| const uint64_t unrollingLimit = 10; |
| if (begin->hasInt() && end->hasInt()) { |
| uint64_t beginConst = static_cast<uint64_t>(begin->asInt()); |
| uint64_t endConst = static_cast<uint64_t>(end->asInt()); |
| |
| if (endConst - beginConst <= unrollingLimit) { |
| for (uint64_t i = beginConst; i < endConst; ++i) { |
| LValue pointer = m_out.add(base, m_out.constIntPtr(i * sizeof(uint64_t))); |
| m_out.store64(value, TypedPointer(heap, pointer)); |
| } |
| return; |
| } |
| } |
| |
| LBasicBlock initLoop = m_out.newBlock(); |
| LBasicBlock initDone = m_out.newBlock(); |
| |
| LBasicBlock lastNext = m_out.insertNewBlocksBefore(initLoop); |
| |
| ValueFromBlock originalIndex = m_out.anchor(end); |
| ValueFromBlock originalPointer = m_out.anchor( |
| m_out.add(base, m_out.shl(m_out.signExt32ToPtr(begin), m_out.constInt32(3)))); |
| m_out.branch(m_out.notEqual(end, begin), unsure(initLoop), unsure(initDone)); |
| |
| m_out.appendTo(initLoop, initDone); |
| LValue index = m_out.phi(Int32, originalIndex); |
| LValue pointer = m_out.phi(pointerType(), originalPointer); |
| |
| m_out.store64(value, TypedPointer(heap, pointer)); |
| |
| LValue nextIndex = m_out.sub(index, m_out.int32One); |
| m_out.addIncomingToPhi(index, m_out.anchor(nextIndex)); |
| m_out.addIncomingToPhi(pointer, m_out.anchor(m_out.add(pointer, m_out.intPtrEight))); |
| m_out.branch( |
| m_out.notEqual(nextIndex, begin), unsure(initLoop), unsure(initDone)); |
| |
| m_out.appendTo(initDone, lastNext); |
| } |
| |
| LValue allocatePropertyStorage(LValue object, Structure* previousStructure) |
| { |
| if (previousStructure->couldHaveIndexingHeader()) { |
| return vmCall( |
| pointerType(), |
| m_out.operation(operationAllocateComplexPropertyStorageWithInitialCapacity), |
| m_callFrame, object); |
| } |
| |
| LValue result = allocatePropertyStorageWithSizeImpl(initialOutOfLineCapacity); |
| |
| splatWords( |
| result, |
| m_out.constInt32(-initialOutOfLineCapacity - 1), m_out.constInt32(-1), |
| m_out.int64Zero, m_heaps.properties.atAnyNumber()); |
| |
| return result; |
| } |
| |
| LValue reallocatePropertyStorage( |
| LValue object, LValue oldStorage, Structure* previous, Structure* next) |
| { |
| size_t oldSize = previous->outOfLineCapacity(); |
| size_t newSize = oldSize * outOfLineGrowthFactor; |
| |
| ASSERT_UNUSED(next, newSize == next->outOfLineCapacity()); |
| |
| if (previous->couldHaveIndexingHeader()) { |
| LValue newAllocSize = m_out.constIntPtr(newSize); |
| return vmCall(pointerType(), m_out.operation(operationAllocateComplexPropertyStorage), m_callFrame, object, newAllocSize); |
| } |
| |
| LValue result = allocatePropertyStorageWithSizeImpl(newSize); |
| |
| ptrdiff_t headerSize = -sizeof(IndexingHeader) - sizeof(void*); |
| ptrdiff_t endStorage = headerSize - static_cast<ptrdiff_t>(oldSize * sizeof(JSValue)); |
| |
| for (ptrdiff_t offset = headerSize; offset > endStorage; offset -= sizeof(void*)) { |
| LValue loaded = |
| m_out.loadPtr(m_out.address(m_heaps.properties.atAnyNumber(), oldStorage, offset)); |
| m_out.storePtr(loaded, m_out.address(m_heaps.properties.atAnyNumber(), result, offset)); |
| } |
| |
| splatWords( |
| result, |
| m_out.constInt32(-newSize - 1), m_out.constInt32(-oldSize - 1), |
| m_out.int64Zero, m_heaps.properties.atAnyNumber()); |
| |
| return result; |
| } |
| |
| LValue allocatePropertyStorageWithSizeImpl(size_t sizeInValues) |
| { |
| LBasicBlock slowPath = m_out.newBlock(); |
| LBasicBlock continuation = m_out.newBlock(); |
| |
| LBasicBlock lastNext = m_out.insertNewBlocksBefore(slowPath); |
| |
| size_t sizeInBytes = sizeInValues * sizeof(JSValue); |
| Allocator allocator = vm().jsValueGigacageAuxiliarySpace.allocatorForNonVirtual(sizeInBytes, AllocatorForMode::AllocatorIfExists); |
| LValue startOfStorage = allocateHeapCell(m_out.constInt32(allocator.offset()), slowPath); |
| ValueFromBlock fastButterfly = m_out.anchor( |
| m_out.add(m_out.constIntPtr(sizeInBytes + sizeof(IndexingHeader)), startOfStorage)); |
| m_out.jump(continuation); |
| |
| m_out.appendTo(slowPath, continuation); |
| |
| LValue slowButterflyValue; |
| VM& vm = this->vm(); |
| if (sizeInValues == initialOutOfLineCapacity) { |
| slowButterflyValue = lazySlowPath( |
| [=, &vm] (const Vector<Location>& locations) -> RefPtr<LazySlowPath::Generator> { |
| return createLazyCallGenerator(vm, |
| operationAllocateSimplePropertyStorageWithInitialCapacity, |
| locations[0].directGPR()); |
| }); |
| } else { |
| slowButterflyValue = lazySlowPath( |
| [=, &vm] (const Vector<Location>& locations) -> RefPtr<LazySlowPath::Generator> { |
| return createLazyCallGenerator(vm, |
| operationAllocateSimplePropertyStorage, locations[0].directGPR(), |
| CCallHelpers::TrustedImmPtr(sizeInValues)); |
| }); |
| } |
| ValueFromBlock slowButterfly = m_out.anchor(slowButterflyValue); |
| |
| m_out.jump(continuation); |
| |
| m_out.appendTo(continuation, lastNext); |
| |
| return m_out.phi(pointerType(), fastButterfly, slowButterfly); |
| } |
| |
| LValue getById(LValue base, AccessType type) |
| { |
| Node* node = m_node; |
| UniquedStringImpl* uid = m_graph.identifiers()[node->identifierNumber()]; |
| |
| B3::PatchpointValue* patchpoint = m_out.patchpoint(Int64); |
| patchpoint->appendSomeRegister(base); |
| patchpoint->append(m_tagMask, ValueRep::lateReg(GPRInfo::tagMaskRegister)); |
| patchpoint->append(m_tagTypeNumber, ValueRep::lateReg(GPRInfo::tagTypeNumberRegister)); |
| |
| // FIXME: If this is a GetByIdFlush/GetByIdDirectFlush, we might get some performance boost if we claim that it |
| // clobbers volatile registers late. It's not necessary for correctness, though, since the |
| // IC code is super smart about saving registers. |
| // https://bugs.webkit.org/show_bug.cgi?id=152848 |
| |
| patchpoint->clobber(RegisterSet::macroScratchRegisters()); |
| |
| RefPtr<PatchpointExceptionHandle> exceptionHandle = |
| preparePatchpointForExceptions(patchpoint); |
| |
| State* state = &m_ftlState; |
| patchpoint->setGenerator( |
| [=] (CCallHelpers& jit, const StackmapGenerationParams& params) { |
| AllowMacroScratchRegisterUsage allowScratch(jit); |
| |
| CallSiteIndex callSiteIndex = |
| state->jitCode->common.addUniqueCallSiteIndex(node->origin.semantic); |
| |
| // This is the direct exit target for operation calls. |
| Box<CCallHelpers::JumpList> exceptions = |
| exceptionHandle->scheduleExitCreation(params)->jumps(jit); |
| |
| // This is the exit for call IC's created by the getById for getters. We don't have |
| // to do anything weird other than call this, since it will associate the exit with |
| // the callsite index. |
| exceptionHandle->scheduleExitCreationForUnwind(params, callSiteIndex); |
| |
| auto generator = Box<JITGetByIdGenerator>::create( |
| jit.codeBlock(), node->origin.semantic, callSiteIndex, |
| params.unavailableRegisters(), uid, JSValueRegs(params[1].gpr()), |
| JSValueRegs(params[0].gpr()), type); |
| |
| generator->generateFastPath(jit); |
| CCallHelpers::Label done = jit.label(); |
| |
| params.addLatePath( |
| [=] (CCallHelpers& jit) { |
| AllowMacroScratchRegisterUsage allowScratch(jit); |
| |
| J_JITOperation_ESsiJI optimizationFunction = appropriateOptimizingGetByIdFunction(type); |
| |
| generator->slowPathJump().link(&jit); |
| CCallHelpers::Label slowPathBegin = jit.label(); |
| CCallHelpers::Call slowPathCall = callOperation( |
| *state, params.unavailableRegisters(), jit, node->origin.semantic, |
| exceptions.get(), optimizationFunction, params[0].gpr(), |
| CCallHelpers::TrustedImmPtr(generator->stubInfo()), params[1].gpr(), |
| CCallHelpers::TrustedImmPtr(uid)).call(); |
| jit.jump().linkTo(done, &jit); |
| |
| generator->reportSlowPathCall(slowPathBegin, slowPathCall); |
| |
| jit.addLinkTask( |
| [=] (LinkBuffer& linkBuffer) { |
| generator->finalize(linkBuffer); |
| }); |
| }); |
| }); |
| |
| return patchpoint; |
| } |
| |
| LValue getByIdWithThis(LValue base, LValue thisValue) |
| { |
| Node* node = m_node; |
| UniquedStringImpl* uid = m_graph.identifiers()[node->identifierNumber()]; |
| |
| B3::PatchpointValue* patchpoint = m_out.patchpoint(Int64); |
| patchpoint->appendSomeRegister(base); |
| patchpoint->appendSomeRegister(thisValue); |
| patchpoint->append(m_tagMask, ValueRep::lateReg(GPRInfo::tagMaskRegister)); |
| patchpoint->append(m_tagTypeNumber, ValueRep::lateReg(GPRInfo::tagTypeNumberRegister)); |
| |
| patchpoint->clobber(RegisterSet::macroScratchRegisters()); |
| |
| RefPtr<PatchpointExceptionHandle> exceptionHandle = |
| preparePatchpointForExceptions(patchpoint); |
| |
| State* state = &m_ftlState; |
| patchpoint->setGenerator( |
| [=] (CCallHelpers& jit, const StackmapGenerationParams& params) { |
| AllowMacroScratchRegisterUsage allowScratch(jit); |
| |
| CallSiteIndex callSiteIndex = |
| state->jitCode->common.addUniqueCallSiteIndex(node->origin.semantic); |
| |
| // This is the direct exit target for operation calls. |
| Box<CCallHelpers::JumpList> exceptions = |
| exceptionHandle->scheduleExitCreation(params)->jumps(jit); |
| |
| // This is the exit for call IC's created by the getById for getters. We don't have |
| // to do anything weird other than call this, since it will associate the exit with |
| // the callsite index. |
| exceptionHandle->scheduleExitCreationForUnwind(params, callSiteIndex); |
| |
| auto generator = Box<JITGetByIdWithThisGenerator>::create( |
| jit.codeBlock(), node->origin.semantic, callSiteIndex, |
| params.unavailableRegisters(), uid, JSValueRegs(params[0].gpr()), |
| JSValueRegs(params[1].gpr()), JSValueRegs(params[2].gpr()), AccessType::GetWithThis); |
| |
| generator->generateFastPath(jit); |
| CCallHelpers::Label done = jit.label(); |
| |
| params.addLatePath( |
| [=] (CCallHelpers& jit) { |
| AllowMacroScratchRegisterUsage allowScratch(jit); |
| |
| J_JITOperation_ESsiJJI optimizationFunction = operationGetByIdWithThisOptimize; |
| |
| generator->slowPathJump().link(&jit); |
| CCallHelpers::Label slowPathBegin = jit.label(); |
| CCallHelpers::Call slowPathCall = callOperation( |
| *state, params.unavailableRegisters(), jit, node->origin.semantic, |
| exceptions.get(), optimizationFunction, params[0].gpr(), |
| CCallHelpers::TrustedImmPtr(generator->stubInfo()), params[1].gpr(), |
| params[2].gpr(), CCallHelpers::TrustedImmPtr(uid)).call(); |
| jit.jump().linkTo(done, &jit); |
| |
| generator->reportSlowPathCall(slowPathBegin, slowPathCall); |
| |
| jit.addLinkTask( |
| [=] (LinkBuffer& linkBuffer) { |
| generator->finalize(linkBuffer); |
| }); |
| }); |
| }); |
| |
| return patchpoint; |
| } |
| |
| LValue isFastTypedArray(LValue object) |
| { |
| return m_out.equal( |
| m_out.load32(object, m_heaps.JSArrayBufferView_mode), |
| m_out.constInt32(FastTypedArray)); |
| } |
| |
| TypedPointer baseIndex(IndexedAbstractHeap& heap, LValue storage, LValue index, Edge edge, ptrdiff_t offset = 0) |
| { |
| return m_out.baseIndex( |
| heap, storage, m_out.zeroExtPtr(index), provenValue(edge), offset); |
| } |
| |
| template<typename IntFunctor, typename DoubleFunctor> |
| void compare( |
| const IntFunctor& intFunctor, const DoubleFunctor& doubleFunctor, |
| C_JITOperation_TT stringIdentFunction, |
| C_JITOperation_B_EJssJss stringFunction, |
| S_JITOperation_EJJ fallbackFunction) |
| { |
| if (m_node->isBinaryUseKind(Int32Use)) { |
| LValue left = lowInt32(m_node->child1()); |
| LValue right = lowInt32(m_node->child2()); |
| setBoolean(intFunctor(left, right)); |
| return; |
| } |
| |
| if (m_node->isBinaryUseKind(Int52RepUse)) { |
| Int52Kind kind; |
| LValue left = lowWhicheverInt52(m_node->child1(), kind); |
| LValue right = lowInt52(m_node->child2(), kind); |
| setBoolean(intFunctor(left, right)); |
| return; |
| } |
| |
| if (m_node->isBinaryUseKind(DoubleRepUse)) { |
| LValue left = lowDouble(m_node->child1()); |
| LValue right = lowDouble(m_node->child2()); |
| setBoolean(doubleFunctor(left, right)); |
| return; |
| } |
| |
| if (m_node->isBinaryUseKind(StringIdentUse)) { |
| LValue left = lowStringIdent(m_node->child1()); |
| LValue right = lowStringIdent(m_node->child2()); |
| setBoolean(m_out.callWithoutSideEffects(Int32, stringIdentFunction, left, right)); |
| return; |
| } |
| |
| if (m_node->isBinaryUseKind(StringUse)) { |
| LValue left = lowCell(m_node->child1()); |
| LValue right = lowCell(m_node->child2()); |
| speculateString(m_node->child1(), left); |
| speculateString(m_node->child2(), right); |
| |
| LValue result = vmCall( |
| Int32, m_out.operation(stringFunction), |
| m_callFrame, left, right); |
| setBoolean(result); |
| return; |
| } |
| |
| DFG_ASSERT(m_graph, m_node, m_node->isBinaryUseKind(UntypedUse), m_node->child1().useKind(), m_node->child2().useKind()); |
| nonSpeculativeCompare(intFunctor, fallbackFunction); |
| } |
| |
| void compileStringSlice() |
| { |
| LBasicBlock emptyCase = m_out.newBlock(); |
| LBasicBlock notEmptyCase = m_out.newBlock(); |
| LBasicBlock oneCharCase = m_out.newBlock(); |
| LBasicBlock bitCheckCase = m_out.newBlock(); |
| LBasicBlock is8Bit = m_out.newBlock(); |
| LBasicBlock is16Bit = m_out.newBlock(); |
| LBasicBlock bitsContinuation = m_out.newBlock(); |
| LBasicBlock bigCharacter = m_out.newBlock(); |
| LBasicBlock slowCase = m_out.newBlock(); |
| LBasicBlock continuation = m_out.newBlock(); |
| |
| LValue string = lowString(m_node->child1()); |
| LValue length = m_out.load32NonNegative(string, m_heaps.JSString_length); |
| LValue start = lowInt32(m_node->child2()); |
| LValue end = nullptr; |
| if (m_node->child3()) |
| end = lowInt32(m_node->child3()); |
| |
| auto range = populateSliceRange(start, end, length); |
| LValue from = range.first; |
| LValue to = range.second; |
| |
| LValue span = m_out.sub(to, from); |
| m_out.branch(m_out.lessThanOrEqual(span, m_out.int32Zero), unsure(emptyCase), unsure(notEmptyCase)); |
| |
| Vector<ValueFromBlock, 4> results; |
| |
| LBasicBlock lastNext = m_out.appendTo(emptyCase, notEmptyCase); |
| results.append(m_out.anchor(weakPointer(jsEmptyString(&vm())))); |
| m_out.jump(continuation); |
| |
| m_out.appendTo(notEmptyCase, oneCharCase); |
| m_out.branch(m_out.equal(span, m_out.int32One), unsure(oneCharCase), unsure(slowCase)); |
| |
| m_out.appendTo(oneCharCase, bitCheckCase); |
| LValue stringImpl = m_out.loadPtr(string, m_heaps.JSString_value); |
| m_out.branch(m_out.isNull(stringImpl), unsure(slowCase), unsure(bitCheckCase)); |
| |
| m_out.appendTo(bitCheckCase, is8Bit); |
| LValue storage = m_out.loadPtr(stringImpl, m_heaps.StringImpl_data); |
| m_out.branch( |
| m_out.testIsZero32( |
| m_out.load32(stringImpl, m_heaps.StringImpl_hashAndFlags), |
| m_out.constInt32(StringImpl::flagIs8Bit())), |
| unsure(is16Bit), unsure(is8Bit)); |
| |
| m_out.appendTo(is8Bit, is16Bit); |
| // FIXME: Need to cage strings! |
| // https://bugs.webkit.org/show_bug.cgi?id=174924 |
| ValueFromBlock char8Bit = m_out.anchor(m_out.load8ZeroExt32(m_out.baseIndex(m_heaps.characters8, storage, m_out.zeroExtPtr(from)))); |
| m_out.jump(bitsContinuation); |
| |
| m_out.appendTo(is16Bit, bigCharacter); |
| LValue char16BitValue = m_out.load16ZeroExt32(m_out.baseIndex(m_heaps.characters16, storage, m_out.zeroExtPtr(from))); |
| ValueFromBlock char16Bit = m_out.anchor(char16BitValue); |
| m_out.branch( |
| m_out.aboveOrEqual(char16BitValue, m_out.constInt32(0x100)), |
| rarely(bigCharacter), usually(bitsContinuation)); |
| |
| m_out.appendTo(bigCharacter, bitsContinuation); |
| results.append(m_out.anchor(vmCall( |
| Int64, m_out.operation(operationSingleCharacterString), |
| m_callFrame, char16BitValue))); |
| m_out.jump(continuation); |
| |
| m_out.appendTo(bitsContinuation, slowCase); |
| LValue character = m_out.phi(Int32, char8Bit, char16Bit); |
| LValue smallStrings = m_out.constIntPtr(vm().smallStrings.singleCharacterStrings()); |
| results.append(m_out.anchor(m_out.loadPtr(m_out.baseIndex( |
| m_heaps.singleCharacterStrings, smallStrings, m_out.zeroExtPtr(character))))); |
| m_out.jump(continuation); |
| |
| m_out.appendTo(slowCase, continuation); |
| results.append(m_out.anchor(vmCall(pointerType(), m_out.operation(operationStringSubstr), m_callFrame, string, from, span))); |
| m_out.jump(continuation); |
| |
| m_out.appendTo(continuation, lastNext); |
| setJSValue(m_out.phi(pointerType(), results)); |
| } |
| |
| void compileToLowerCase() |
| { |
| LBasicBlock notRope = m_out.newBlock(); |
| LBasicBlock is8Bit = m_out.newBlock(); |
| LBasicBlock loopTop = m_out.newBlock(); |
| LBasicBlock loopBody = m_out.newBlock(); |
| LBasicBlock slowPath = m_out.newBlock(); |
| LBasicBlock continuation = m_out.newBlock(); |
| |
| LValue string = lowString(m_node->child1()); |
| ValueFromBlock startIndex = m_out.anchor(m_out.constInt32(0)); |
| ValueFromBlock startIndexForCall = m_out.anchor(m_out.constInt32(0)); |
| LValue impl = m_out.loadPtr(string, m_heaps.JSString_value); |
| m_out.branch(m_out.isZero64(impl), |
| unsure(slowPath), unsure(notRope)); |
| |
| LBasicBlock lastNext = m_out.appendTo(notRope, is8Bit); |
| |
| m_out.branch( |
| m_out.testIsZero32( |
| m_out.load32(impl, m_heaps.StringImpl_hashAndFlags), |
| m_out.constInt32(StringImpl::flagIs8Bit())), |
| unsure(slowPath), unsure(is8Bit)); |
| |
| m_out.appendTo(is8Bit, loopTop); |
| LValue length = m_out.load32(impl, m_heaps.StringImpl_length); |
| LValue buffer = m_out.loadPtr(impl, m_heaps.StringImpl_data); |
| ValueFromBlock fastResult = m_out.anchor(string); |
| m_out.jump(loopTop); |
| |
| m_out.appendTo(loopTop, loopBody); |
| LValue index = m_out.phi(Int32, startIndex); |
| ValueFromBlock indexFromBlock = m_out.anchor(index); |
| m_out.branch(m_out.below(index, length), |
| unsure(loopBody), unsure(continuation)); |
| |
| m_out.appendTo(loopBody, slowPath); |
| |
| // FIXME: Strings needs to be caged. |
| // https://bugs.webkit.org/show_bug.cgi?id=174924 |
| LValue byte = m_out.load8ZeroExt32(m_out.baseIndex(m_heaps.characters8, buffer, m_out.zeroExtPtr(index))); |
| LValue isInvalidAsciiRange = m_out.bitAnd(byte, m_out.constInt32(~0x7F)); |
| LValue isUpperCase = m_out.belowOrEqual(m_out.sub(byte, m_out.constInt32('A')), m_out.constInt32('Z' - 'A')); |
| LValue isBadCharacter = m_out.bitOr(isInvalidAsciiRange, isUpperCase); |
| m_out.addIncomingToPhi(index, m_out.anchor(m_out.add(index, m_out.int32One))); |
| m_out.branch(isBadCharacter, unsure(slowPath), unsure(loopTop)); |
| |
| m_out.appendTo(slowPath, continuation); |
| LValue slowPathIndex = m_out.phi(Int32, startIndexForCall, indexFromBlock); |
| ValueFromBlock slowResult = m_out.anchor(vmCall(pointerType(), m_out.operation(operationToLowerCase), m_callFrame, string, slowPathIndex)); |
| m_out.jump(continuation); |
| |
| m_out.appendTo(continuation, lastNext); |
| setJSValue(m_out.phi(pointerType(), fastResult, slowResult)); |
| } |
| |
| void compileNumberToStringWithRadix() |
| { |
| bool validRadixIsGuaranteed = false; |
| if (m_node->child2()->isInt32Constant()) { |
| int32_t radix = m_node->child2()->asInt32(); |
| if (radix >= 2 && radix <= 36) |
| validRadixIsGuaranteed = true; |
| } |
| |
| switch (m_node->child1().useKind()) { |
| case Int32Use: |
| setJSValue(vmCall(pointerType(), m_out.operation(validRadixIsGuaranteed ? operationInt32ToStringWithValidRadix : operationInt32ToString), m_callFrame, lowInt32(m_node->child1()), lowInt32(m_node->child2()))); |
| break; |
| case Int52RepUse: |
| setJSValue(vmCall(pointerType(), m_out.operation(validRadixIsGuaranteed ? operationInt52ToStringWithValidRadix : operationInt52ToString), m_callFrame, lowStrictInt52(m_node->child1()), lowInt32(m_node->child2()))); |
| break; |
| case DoubleRepUse: |
| setJSValue(vmCall(pointerType(), m_out.operation(validRadixIsGuaranteed ? operationDoubleToStringWithValidRadix : operationDoubleToString), m_callFrame, lowDouble(m_node->child1()), lowInt32(m_node->child2()))); |
| break; |
| default: |
| RELEASE_ASSERT_NOT_REACHED(); |
| } |
| } |
| |
| void compileNumberToStringWithValidRadixConstant() |
| { |
| switch (m_node->child1().useKind()) { |
| case Int32Use: |
| setJSValue(vmCall(pointerType(), m_out.operation(operationInt32ToStringWithValidRadix), m_callFrame, lowInt32(m_node->child1()), m_out.constInt32(m_node->validRadixConstant()))); |
| break; |
| case Int52RepUse: |
| setJSValue(vmCall(pointerType(), m_out.operation(operationInt52ToStringWithValidRadix), m_callFrame, lowStrictInt52(m_node->child1()), m_out.constInt32(m_node->validRadixConstant()))); |
| break; |
| case DoubleRepUse: |
| setJSValue(vmCall(pointerType(), m_out.operation(operationDoubleToStringWithValidRadix), m_callFrame, lowDouble(m_node->child1()), m_out.constInt32(m_node->validRadixConstant()))); |
| break; |
| default: |
| RELEASE_ASSERT_NOT_REACHED(); |
| } |
| } |
| |
| void compileResolveScopeForHoistingFuncDeclInEval() |
| { |
| UniquedStringImpl* uid = m_graph.identifiers()[m_node->identifierNumber()]; |
| setJSValue(vmCall(pointerType(), m_out.operation(operationResolveScopeForHoistingFuncDeclInEval), m_callFrame, lowCell(m_node->child1()), m_out.constIntPtr(uid))); |
| } |
| |
| void compileResolveScope() |
| { |
| UniquedStringImpl* uid = m_graph.identifiers()[m_node->identifierNumber()]; |
| setJSValue(vmCall(pointerType(), m_out.operation(operationResolveScope), |
| m_callFrame, lowCell(m_node->child1()), m_out.constIntPtr(uid))); |
| } |
| |
| void compileGetDynamicVar() |
| { |
| UniquedStringImpl* uid = m_graph.identifiers()[m_node->identifierNumber()]; |
| setJSValue(vmCall(Int64, m_out.operation(operationGetDynamicVar), |
| m_callFrame, lowCell(m_node->child1()), m_out.constIntPtr(uid), m_out.constInt32(m_node->getPutInfo()))); |
| } |
| |
| void compilePutDynamicVar() |
| { |
| UniquedStringImpl* uid = m_graph.identifiers()[m_node->identifierNumber()]; |
| setJSValue(vmCall(Void, m_out.operation(operationPutDynamicVar), |
| m_callFrame, lowCell(m_node->child1()), lowJSValue(m_node->child2()), m_out.constIntPtr(uid), m_out.constInt32(m_node->getPutInfo()))); |
| } |
| |
| void compileUnreachable() |
| { |
| // It's so tempting to assert that AI has proved that this is unreachable. But that's |
| // simply not a requirement of the Unreachable opcode at all. If you emit an opcode that |
| // *you* know will not return, then it's fine to end the basic block with Unreachable |
| // after that opcode. You don't have to also prove to AI that your opcode does not return. |
| // Hence, there is nothing to do here but emit code that will crash, so that we catch |
| // cases where you said Unreachable but you lied. |
| // |
| // It's also also worth noting that some clients emit this opcode because they're not 100% sure |
| // if the code is unreachable, but they would really prefer if we crashed rather than kept going |
| // if it did turn out to be reachable. Hence, this needs to deterministically crash. |
| |
| crash(); |
| } |
| |
| void compileCheckSubClass() |
| { |
| LValue cell = lowCell(m_node->child1()); |
| |
| const ClassInfo* classInfo = m_node->classInfo(); |
| if (!classInfo->checkSubClassSnippet) { |
| LBasicBlock loop = m_out.newBlock(); |
| LBasicBlock parentClass = m_out.newBlock(); |
| LBasicBlock continuation = m_out.newBlock(); |
| |
| LValue structure = loadStructure(cell); |
| LValue poisonedClassInfo = m_out.loadPtr(structure, m_heaps.Structure_classInfo); |
| LValue classInfo = m_out.bitXor(poisonedClassInfo, m_out.constInt64(GlobalDataPoison::key())); |
| ValueFromBlock otherAtStart = m_out.anchor(classInfo); |
| m_out.jump(loop); |
| |
| LBasicBlock lastNext = m_out.appendTo(loop, parentClass); |
| LValue other = m_out.phi(pointerType(), otherAtStart); |
| m_out.branch(m_out.equal(other, m_out.constIntPtr(classInfo)), unsure(continuation), unsure(parentClass)); |
| |
| m_out.appendTo(parentClass, continuation); |
| LValue parent = m_out.loadPtr(other, m_heaps.ClassInfo_parentClass); |
| speculate(BadType, jsValueValue(cell), m_node->child1().node(), m_out.isNull(parent)); |
| m_out.addIncomingToPhi(other, m_out.anchor(parent)); |
| m_out.jump(loop); |
| |
| m_out.appendTo(continuation, lastNext); |
| return; |
| } |
| |
| RefPtr<Snippet> domJIT = classInfo->checkSubClassSnippet(); |
| PatchpointValue* patchpoint = m_out.patchpoint(Void); |
| patchpoint->appendSomeRegister(cell); |
| patchpoint->append(m_tagMask, ValueRep::reg(GPRInfo::tagMaskRegister)); |
| patchpoint->append(m_tagTypeNumber, ValueRep::reg(GPRInfo::tagTypeNumberRegister)); |
| |
| NodeOrigin origin = m_origin; |
| unsigned osrExitArgumentOffset = patchpoint->numChildren(); |
| OSRExitDescriptor* exitDescriptor = appendOSRExitDescriptor(jsValueValue(cell), m_node->child1().node()); |
| patchpoint->appendColdAnys(buildExitArguments(exitDescriptor, origin.forExit, jsValueValue(cell))); |
| |
| patchpoint->numGPScratchRegisters = domJIT->numGPScratchRegisters; |
| patchpoint->numFPScratchRegisters = domJIT->numFPScratchRegisters; |
| patchpoint->clobber(RegisterSet::macroScratchRegisters()); |
| |
| State* state = &m_ftlState; |
| Node* node = m_node; |
| JSValue child1Constant = m_state.forNode(m_node->child1()).value(); |
| |
| patchpoint->setGenerator( |
| [=] (CCallHelpers& jit, const StackmapGenerationParams& params) { |
| AllowMacroScratchRegisterUsage allowScratch(jit); |
| |
| Vector<GPRReg> gpScratch; |
| Vector<FPRReg> fpScratch; |
| Vector<SnippetParams::Value> regs; |
| |
| regs.append(SnippetParams::Value(params[0].gpr(), child1Constant)); |
| |
| for (unsigned i = 0; i < domJIT->numGPScratchRegisters; ++i) |
| gpScratch.append(params.gpScratch(i)); |
| |
| for (unsigned i = 0; i < domJIT->numFPScratchRegisters; ++i) |
| fpScratch.append(params.fpScratch(i)); |
| |
| RefPtr<OSRExitHandle> handle = exitDescriptor->emitOSRExitLater(*state, BadType, origin, params, osrExitArgumentOffset); |
| |
| SnippetParams domJITParams(*state, params, node, nullptr, WTFMove(regs), WTFMove(gpScratch), WTFMove(fpScratch)); |
| CCallHelpers::JumpList failureCases = domJIT->generator()->run(jit, domJITParams); |
| |
| jit.addLinkTask([=] (LinkBuffer& linkBuffer) { |
| linkBuffer.link(failureCases, linkBuffer.locationOf<NoPtrTag>(handle->label)); |
| }); |
| }); |
| patchpoint->effects = Effects::forCheck(); |
| } |
| |
| void compileCallDOM() |
| { |
| const DOMJIT::Signature* signature = m_node->signature(); |
| |
| // FIXME: We should have a way to call functions with the vector of registers. |
| // https://bugs.webkit.org/show_bug.cgi?id=163099 |
| Vector<LValue, JSC_DOMJIT_SIGNATURE_MAX_ARGUMENTS_INCLUDING_THIS> operands; |
| |
| unsigned index = 0; |
| DFG_NODE_DO_TO_CHILDREN(m_graph, m_node, [&](Node*, Edge edge) { |
| if (!index) |
| operands.append(lowCell(edge)); |
| else { |
| switch (signature->arguments[index - 1]) { |
| case SpecString: |
| operands.append(lowString(edge)); |
| break; |
| case SpecInt32Only: |
| operands.append(lowInt32(edge)); |
| break; |
| case SpecBoolean: |
| operands.append(lowBoolean(edge)); |
| break; |
| default: |
| RELEASE_ASSERT_NOT_REACHED(); |
| break; |
| } |
| } |
| ++index; |
| }); |
| |
| unsigned argumentCountIncludingThis = signature->argumentCount + 1; |
| LValue result; |
| assertIsTaggedWith(reinterpret_cast<void*>(signature->unsafeFunction), CFunctionPtrTag); |
| switch (argumentCountIncludingThis) { |
| case 1: |
| result = vmCall(Int64, m_out.operation(reinterpret_cast<J_JITOperation_EP>(signature->unsafeFunction)), m_callFrame, operands[0]); |
| break; |
| case 2: |
| result = vmCall(Int64, m_out.operation(reinterpret_cast<J_JITOperation_EPP>(signature->unsafeFunction)), m_callFrame, operands[0], operands[1]); |
| break; |
| case 3: |
| result = vmCall(Int64, m_out.operation(reinterpret_cast<J_JITOperation_EPPP>(signature->unsafeFunction)), m_callFrame, operands[0], operands[1], operands[2]); |
| break; |
| default: |
| RELEASE_ASSERT_NOT_REACHED(); |
| break; |
| } |
| |
| setJSValue(result); |
| } |
| |
| void compileCallDOMGetter() |
| { |
| DOMJIT::CallDOMGetterSnippet* domJIT = m_node->callDOMGetterData()->snippet; |
| if (!domJIT) { |
| // The following function is not an operation: we directly call a custom accessor getter. |
| // Since the getter does not have code setting topCallFrame, As is the same to IC, we should set topCallFrame in caller side. |
| m_out.storePtr(m_callFrame, m_out.absolute(&vm().topCallFrame)); |
| setJSValue( |
| vmCall(Int64, m_out.operation(m_node->callDOMGetterData()->customAccessorGetter.retaggedExecutableAddress<CFunctionPtrTag>()), |
| m_callFrame, lowCell(m_node->child1()), m_out.constIntPtr(m_graph.identifiers()[m_node->callDOMGetterData()->identifierNumber]))); |
| return; |
| } |
| |
| Edge& baseEdge = m_node->child1(); |
| LValue base = lowCell(baseEdge); |
| JSValue baseConstant = m_state.forNode(baseEdge).value(); |
| |
| LValue globalObject; |
| JSValue globalObjectConstant; |
| if (domJIT->requireGlobalObject) { |
| Edge& globalObjectEdge = m_node->child2(); |
| globalObject = lowCell(globalObjectEdge); |
| globalObjectConstant = m_state.forNode(globalObjectEdge).value(); |
| } |
| |
| PatchpointValue* patchpoint = m_out.patchpoint(Int64); |
| patchpoint->appendSomeRegister(base); |
| if (domJIT->requireGlobalObject) |
| patchpoint->appendSomeRegister(globalObject); |
| patchpoint->append(m_tagMask, ValueRep::reg(GPRInfo::tagMaskRegister)); |
| patchpoint->append(m_tagTypeNumber, ValueRep::reg(GPRInfo::tagTypeNumberRegister)); |
| RefPtr<PatchpointExceptionHandle> exceptionHandle = preparePatchpointForExceptions(patchpoint); |
| patchpoint->clobber(RegisterSet::macroScratchRegisters()); |
| patchpoint->numGPScratchRegisters = domJIT->numGPScratchRegisters; |
| patchpoint->numFPScratchRegisters = domJIT->numFPScratchRegisters; |
| patchpoint->resultConstraint = ValueRep::SomeEarlyRegister; |
| |
| State* state = &m_ftlState; |
| Node* node = m_node; |
| patchpoint->setGenerator( |
| [=] (CCallHelpers& jit, const StackmapGenerationParams& params) { |
| AllowMacroScratchRegisterUsage allowScratch(jit); |
| |
| Vector<GPRReg> gpScratch; |
| Vector<FPRReg> fpScratch; |
| Vector<SnippetParams::Value> regs; |
| |
| regs.append(JSValueRegs(params[0].gpr())); |
| regs.append(SnippetParams::Value(params[1].gpr(), baseConstant)); |
| if (domJIT->requireGlobalObject) |
| regs.append(SnippetParams::Value(params[2].gpr(), globalObjectConstant)); |
| |
| for (unsigned i = 0; i < domJIT->numGPScratchRegisters; ++i) |
| gpScratch.append(params.gpScratch(i)); |
| |
| for (unsigned i = 0; i < domJIT->numFPScratchRegisters; ++i) |
| fpScratch.append(params.fpScratch(i)); |
| |
| Box<CCallHelpers::JumpList> exceptions = exceptionHandle->scheduleExitCreation(params)->jumps(jit); |
| |
| SnippetParams domJITParams(*state, params, node, exceptions, WTFMove(regs), WTFMove(gpScratch), WTFMove(fpScratch)); |
| domJIT->generator()->run(jit, domJITParams); |
| }); |
| patchpoint->effects = Effects::forCall(); |
| setJSValue(patchpoint); |
| } |
| |
| void emitSwitchForMultiByOffset(LValue base, bool structuresChecked, Vector<SwitchCase, 2>& cases, LBasicBlock exit) |
| { |
| if (cases.isEmpty()) { |
| m_out.jump(exit); |
| return; |
| } |
| |
| if (structuresChecked) { |
| std::sort( |
| cases.begin(), cases.end(), |
| [&] (const SwitchCase& a, const SwitchCase& b) -> bool { |
| return a.value()->asInt() < b.value()->asInt(); |
| }); |
| SwitchCase last = cases.takeLast(); |
| m_out.switchInstruction( |
| m_out.load32(base, m_heaps.JSCell_structureID), cases, last.target(), Weight(0)); |
| return; |
| } |
| |
| m_out.switchInstruction( |
| m_out.load32(base, m_heaps.JSCell_structureID), cases, exit, Weight(0)); |
| } |
| |
| void compareEqObjectOrOtherToObject(Edge leftChild, Edge rightChild) |
| { |
| LValue rightCell = lowCell(rightChild); |
| LValue leftValue = lowJSValue(leftChild, ManualOperandSpeculation); |
| |
| speculateTruthyObject(rightChild, rightCell, SpecObject); |
| |
| LBasicBlock leftCellCase = m_out.newBlock(); |
| LBasicBlock leftNotCellCase = m_out.newBlock(); |
| LBasicBlock continuation = m_out.newBlock(); |
| |
| m_out.branch( |
| isCell(leftValue, provenType(leftChild)), |
| unsure(leftCellCase), unsure(leftNotCellCase)); |
| |
| LBasicBlock lastNext = m_out.appendTo(leftCellCase, leftNotCellCase); |
| speculateTruthyObject(leftChild, leftValue, SpecObject | (~SpecCellCheck)); |
| ValueFromBlock cellResult = m_out.anchor(m_out.equal(rightCell, leftValue)); |
| m_out.jump(continuation); |
| |
| m_out.appendTo(leftNotCellCase, continuation); |
| FTL_TYPE_CHECK( |
| jsValueValue(leftValue), leftChild, SpecOther | SpecCellCheck, isNotOther(leftValue)); |
| ValueFromBlock notCellResult = m_out.anchor(m_out.booleanFalse); |
| m_out.jump(continuation); |
| |
| m_out.appendTo(continuation, lastNext); |
| setBoolean(m_out.phi(Int32, cellResult, notCellResult)); |
| } |
| |
| void speculateTruthyObject(Edge edge, LValue cell, SpeculatedType filter) |
| { |
| if (masqueradesAsUndefinedWatchpointIsStillValid()) { |
| FTL_TYPE_CHECK(jsValueValue(cell), edge, filter, isNotObject(cell)); |
| return; |
| } |
| |
| FTL_TYPE_CHECK(jsValueValue(cell), edge, filter, isNotObject(cell)); |
| speculate( |
| BadType, jsValueValue(cell), edge.node(), |
| m_out.testNonZero32( |
| m_out.load8ZeroExt32(cell, m_heaps.JSCell_typeInfoFlags), |
| m_out.constInt32(MasqueradesAsUndefined))); |
| } |
| |
| template<typename IntFunctor> |
| void nonSpeculativeCompare(const IntFunctor& intFunctor, S_JITOperation_EJJ helperFunction) |
| { |
| LValue left = lowJSValue(m_node->child1()); |
| LValue right = lowJSValue(m_node->child2()); |
| |
| LBasicBlock leftIsInt = m_out.newBlock(); |
| LBasicBlock fastPath = m_out.newBlock(); |
| LBasicBlock slowPath = m_out.newBlock(); |
| LBasicBlock continuation = m_out.newBlock(); |
| |
| m_out.branch(isNotInt32(left, provenType(m_node->child1())), rarely(slowPath), usually(leftIsInt)); |
| |
| LBasicBlock lastNext = m_out.appendTo(leftIsInt, fastPath); |
| m_out.branch(isNotInt32(right, provenType(m_node->child2())), rarely(slowPath), usually(fastPath)); |
| |
| m_out.appendTo(fastPath, slowPath); |
| ValueFromBlock fastResult = m_out.anchor(intFunctor(unboxInt32(left), unboxInt32(right))); |
| m_out.jump(continuation); |
| |
| m_out.appendTo(slowPath, continuation); |
| ValueFromBlock slowResult = m_out.anchor(m_out.notNull(vmCall( |
| pointerType(), m_out.operation(helperFunction), m_callFrame, left, right))); |
| m_out.jump(continuation); |
| |
| m_out.appendTo(continuation, lastNext); |
| setBoolean(m_out.phi(Int32, fastResult, slowResult)); |
| } |
| |
| LValue stringsEqual(LValue leftJSString, LValue rightJSString) |
| { |
| LBasicBlock notTriviallyUnequalCase = m_out.newBlock(); |
| LBasicBlock notEmptyCase = m_out.newBlock(); |
| LBasicBlock leftReadyCase = m_out.newBlock(); |
| LBasicBlock rightReadyCase = m_out.newBlock(); |
| LBasicBlock left8BitCase = m_out.newBlock(); |
| LBasicBlock right8BitCase = m_out.newBlock(); |
| LBasicBlock loop = m_out.newBlock(); |
| LBasicBlock bytesEqual = m_out.newBlock(); |
| LBasicBlock trueCase = m_out.newBlock(); |
| LBasicBlock falseCase = m_out.newBlock(); |
| LBasicBlock slowCase = m_out.newBlock(); |
| LBasicBlock continuation = m_out.newBlock(); |
| |
| LValue length = m_out.load32(leftJSString, m_heaps.JSString_length); |
| |
| m_out.branch( |
| m_out.notEqual(length, m_out.load32(rightJSString, m_heaps.JSString_length)), |
| unsure(falseCase), unsure(notTriviallyUnequalCase)); |
| |
| LBasicBlock lastNext = m_out.appendTo(notTriviallyUnequalCase, notEmptyCase); |
| |
| m_out.branch(m_out.isZero32(length), unsure(trueCase), unsure(notEmptyCase)); |
| |
| m_out.appendTo(notEmptyCase, leftReadyCase); |
| |
| LValue left = m_out.loadPtr(leftJSString, m_heaps.JSString_value); |
| LValue right = m_out.loadPtr(rightJSString, m_heaps.JSString_value); |
| |
| m_out.branch(m_out.notNull(left), usually(leftReadyCase), rarely(slowCase)); |
| |
| m_out.appendTo(leftReadyCase, rightReadyCase); |
| |
| m_out.branch(m_out.notNull(right), usually(rightReadyCase), rarely(slowCase)); |
| |
| m_out.appendTo(rightReadyCase, left8BitCase); |
| |
| m_out.branch( |
| m_out.testIsZero32( |
| m_out.load32(left, m_heaps.StringImpl_hashAndFlags), |
| m_out.constInt32(StringImpl::flagIs8Bit())), |
| unsure(slowCase), unsure(left8BitCase)); |
| |
| m_out.appendTo(left8BitCase, right8BitCase); |
| |
| m_out.branch( |
| m_out.testIsZero32( |
| m_out.load32(right, m_heaps.StringImpl_hashAndFlags), |
| m_out.constInt32(StringImpl::flagIs8Bit())), |
| unsure(slowCase), unsure(right8BitCase)); |
| |
| m_out.appendTo(right8BitCase, loop); |
| |
| LValue leftData = m_out.loadPtr(left, m_heaps.StringImpl_data); |
| LValue rightData = m_out.loadPtr(right, m_heaps.StringImpl_data); |
| |
| ValueFromBlock indexAtStart = m_out.anchor(length); |
| |
| m_out.jump(loop); |
| |
| m_out.appendTo(loop, bytesEqual); |
| |
| LValue indexAtLoopTop = m_out.phi(Int32, indexAtStart); |
| LValue indexInLoop = m_out.sub(indexAtLoopTop, m_out.int32One); |
| |
| LValue leftByte = m_out.load8ZeroExt32( |
| m_out.baseIndex(m_heaps.characters8, leftData, m_out.zeroExtPtr(indexInLoop))); |
| LValue rightByte = m_out.load8ZeroExt32( |
| m_out.baseIndex(m_heaps.characters8, rightData, m_out.zeroExtPtr(indexInLoop))); |
| |
| m_out.branch(m_out.notEqual(leftByte, rightByte), unsure(falseCase), unsure(bytesEqual)); |
| |
| m_out.appendTo(bytesEqual, trueCase); |
| |
| ValueFromBlock indexForNextIteration = m_out.anchor(indexInLoop); |
| m_out.addIncomingToPhi(indexAtLoopTop, indexForNextIteration); |
| m_out.branch(m_out.notZero32(indexInLoop), unsure(loop), unsure(trueCase)); |
| |
| m_out.appendTo(trueCase, falseCase); |
| |
| ValueFromBlock trueResult = m_out.anchor(m_out.booleanTrue); |
| m_out.jump(continuation); |
| |
| m_out.appendTo(falseCase, slowCase); |
| |
| ValueFromBlock falseResult = m_out.anchor(m_out.booleanFalse); |
| m_out.jump(continuation); |
| |
| m_out.appendTo(slowCase, continuation); |
| |
| LValue slowResultValue = vmCall( |
| Int64, m_out.operation(operationCompareStringEq), m_callFrame, |
| leftJSString, rightJSString); |
| ValueFromBlock slowResult = m_out.anchor(unboxBoolean(slowResultValue)); |
| m_out.jump(continuation); |
| |
| m_out.appendTo(continuation, lastNext); |
| return m_out.phi(Int32, trueResult, falseResult, slowResult); |
| } |
| |
| enum ScratchFPRUsage { |
| DontNeedScratchFPR, |
| NeedScratchFPR |
| }; |
| template<typename BinaryArithOpGenerator, ScratchFPRUsage scratchFPRUsage = DontNeedScratchFPR> |
| void emitBinarySnippet(J_JITOperation_EJJ slowPathFunction) |
| { |
| Node* node = m_node; |
| |
| LValue left = lowJSValue(node->child1()); |
| LValue right = lowJSValue(node->child2()); |
| |
| SnippetOperand leftOperand(m_state.forNode(node->child1()).resultType()); |
| SnippetOperand rightOperand(m_state.forNode(node->child2()).resultType()); |
| |
| PatchpointValue* patchpoint = m_out.patchpoint(Int64); |
| patchpoint->appendSomeRegister(left); |
| patchpoint->appendSomeRegister(right); |
| patchpoint->append(m_tagMask, ValueRep::lateReg(GPRInfo::tagMaskRegister)); |
| patchpoint->append(m_tagTypeNumber, ValueRep::lateReg(GPRInfo::tagTypeNumberRegister)); |
| RefPtr<PatchpointExceptionHandle> exceptionHandle = |
| preparePatchpointForExceptions(patchpoint); |
| patchpoint->numGPScratchRegisters = 1; |
| patchpoint->numFPScratchRegisters = 2; |
| if (scratchFPRUsage == NeedScratchFPR) |
| patchpoint->numFPScratchRegisters++; |
| patchpoint->clobber(RegisterSet::macroScratchRegisters()); |
| patchpoint->resultConstraint = ValueRep::SomeEarlyRegister; |
| State* state = &m_ftlState; |
| patchpoint->setGenerator( |
| [=] (CCallHelpers& jit, const StackmapGenerationParams& params) { |
| AllowMacroScratchRegisterUsage allowScratch(jit); |
| |
| Box<CCallHelpers::JumpList> exceptions = |
| exceptionHandle->scheduleExitCreation(params)->jumps(jit); |
| |
| auto generator = Box<BinaryArithOpGenerator>::create( |
| leftOperand, rightOperand, JSValueRegs(params[0].gpr()), |
| JSValueRegs(params[1].gpr()), JSValueRegs(params[2].gpr()), |
| params.fpScratch(0), params.fpScratch(1), params.gpScratch(0), |
| scratchFPRUsage == NeedScratchFPR ? params.fpScratch(2) : InvalidFPRReg); |
| |
| generator->generateFastPath(jit); |
| |
| if (generator->didEmitFastPath()) { |
| generator->endJumpList().link(&jit); |
| CCallHelpers::Label done = jit.label(); |
| |
| params.addLatePath( |
| [=] (CCallHelpers& jit) { |
| AllowMacroScratchRegisterUsage allowScratch(jit); |
| |
| generator->slowPathJumpList().link(&jit); |
| callOperation( |
| *state, params.unavailableRegisters(), jit, node->origin.semantic, |
| exceptions.get(), slowPathFunction, params[0].gpr(), |
| params[1].gpr(), params[2].gpr()); |
| jit.jump().linkTo(done, &jit); |
| }); |
| } else { |
| callOperation( |
| *state, params.unavailableRegisters(), jit, node->origin.semantic, |
| exceptions.get(), slowPathFunction, params[0].gpr(), params[1].gpr(), |
| params[2].gpr()); |
| } |
| }); |
| |
| setJSValue(patchpoint); |
| } |
| |
| template<typename BinaryBitOpGenerator> |
| void emitBinaryBitOpSnippet(J_JITOperation_EJJ slowPathFunction) |
| { |
| Node* node = m_node; |
| |
| LValue left = lowJSValue(node->child1()); |
| LValue right = lowJSValue(node->child2()); |
| |
| SnippetOperand leftOperand(m_state.forNode(node->child1()).resultType()); |
| SnippetOperand rightOperand(m_state.forNode(node->child2()).resultType()); |
| |
| PatchpointValue* patchpoint = m_out.patchpoint(Int64); |
| patchpoint->appendSomeRegister(left); |
| patchpoint->appendSomeRegister(right); |
| patchpoint->append(m_tagMask, ValueRep::lateReg(GPRInfo::tagMaskRegister)); |
| patchpoint->append(m_tagTypeNumber, ValueRep::lateReg(GPRInfo::tagTypeNumberRegister)); |
| RefPtr<PatchpointExceptionHandle> exceptionHandle = |
| preparePatchpointForExceptions(patchpoint); |
| patchpoint->numGPScratchRegisters = 1; |
| patchpoint->clobber(RegisterSet::macroScratchRegisters()); |
| patchpoint->resultConstraint = ValueRep::SomeEarlyRegister; |
| State* state = &m_ftlState; |
| patchpoint->setGenerator( |
| [=] (CCallHelpers& jit, const StackmapGenerationParams& params) { |
| AllowMacroScratchRegisterUsage allowScratch(jit); |
| |
| Box<CCallHelpers::JumpList> exceptions = |
| exceptionHandle->scheduleExitCreation(params)->jumps(jit); |
| |
| auto generator = Box<BinaryBitOpGenerator>::create( |
| leftOperand, rightOperand, JSValueRegs(params[0].gpr()), |
| JSValueRegs(params[1].gpr()), JSValueRegs(params[2].gpr()), params.gpScratch(0)); |
| |
| generator->generateFastPath(jit); |
| generator->endJumpList().link(&jit); |
| CCallHelpers::Label done = jit.label(); |
| |
| params.addLatePath( |
| [=] (CCallHelpers& jit) { |
| AllowMacroScratchRegisterUsage allowScratch(jit); |
| |
| generator->slowPathJumpList().link(&jit); |
| callOperation( |
| *state, params.unavailableRegisters(), jit, node->origin.semantic, |
| exceptions.get(), slowPathFunction, params[0].gpr(), |
| params[1].gpr(), params[2].gpr()); |
| jit.jump().linkTo(done, &jit); |
| }); |
| }); |
| |
| setJSValue(patchpoint); |
| } |
| |
| void emitRightShiftSnippet(JITRightShiftGenerator::ShiftType shiftType) |
| { |
| Node* node = m_node; |
| |
| // FIXME: Make this do exceptions. |
| // https://bugs.webkit.org/show_bug.cgi?id=151686 |
| |
| LValue left = lowJSValue(node->child1()); |
| LValue right = lowJSValue(node->child2()); |
| |
| SnippetOperand leftOperand(m_state.forNode(node->child1()).resultType()); |
| SnippetOperand rightOperand(m_state.forNode(node->child2()).resultType()); |
| |
| PatchpointValue* patchpoint = m_out.patchpoint(Int64); |
| patchpoint->appendSomeRegister(left); |
| patchpoint->appendSomeRegister(right); |
| patchpoint->append(m_tagMask, ValueRep::lateReg(GPRInfo::tagMaskRegister)); |
| patchpoint->append(m_tagTypeNumber, ValueRep::lateReg(GPRInfo::tagTypeNumberRegister)); |
| RefPtr<PatchpointExceptionHandle> exceptionHandle = |
| preparePatchpointForExceptions(patchpoint); |
| patchpoint->numGPScratchRegisters = 1; |
| patchpoint->numFPScratchRegisters = 1; |
| patchpoint->clobber(RegisterSet::macroScratchRegisters()); |
| patchpoint->resultConstraint = ValueRep::SomeEarlyRegister; |
| State* state = &m_ftlState; |
| patchpoint->setGenerator( |
| [=] (CCallHelpers& jit, const StackmapGenerationParams& params) { |
| AllowMacroScratchRegisterUsage allowScratch(jit); |
| |
| Box<CCallHelpers::JumpList> exceptions = |
| exceptionHandle->scheduleExitCreation(params)->jumps(jit); |
| |
| auto generator = Box<JITRightShiftGenerator>::create( |
| leftOperand, rightOperand, JSValueRegs(params[0].gpr()), |
| JSValueRegs(params[1].gpr()), JSValueRegs(params[2].gpr()), |
| params.fpScratch(0), params.gpScratch(0), InvalidFPRReg, shiftType); |
| |
| generator->generateFastPath(jit); |
| generator->endJumpList().link(&jit); |
| CCallHelpers::Label done = jit.label(); |
| |
| params.addLatePath( |
| [=] (CCallHelpers& jit) { |
| AllowMacroScratchRegisterUsage allowScratch(jit); |
| |
| generator->slowPathJumpList().link(&jit); |
| |
| J_JITOperation_EJJ slowPathFunction = |
| shiftType == JITRightShiftGenerator::SignedShift |
| ? operationValueBitRShift : operationValueBitURShift; |
| |
| callOperation( |
| *state, params.unavailableRegisters(), jit, node->origin.semantic, |
| exceptions.get(), slowPathFunction, params[0].gpr(), |
| params[1].gpr(), params[2].gpr()); |
| jit.jump().linkTo(done, &jit); |
| }); |
| }); |
| |
| setJSValue(patchpoint); |
| } |
| |
| LValue allocateHeapCell(LValue allocator, LBasicBlock slowPath) |
| { |
| JITAllocator actualAllocator; |
| if (allocator->hasInt32()) |
| actualAllocator = JITAllocator::constant(Allocator(allocator->asInt32())); |
| else |
| actualAllocator = JITAllocator::variable(); |
| |
| if (actualAllocator.isConstant()) { |
| if (!actualAllocator.allocator()) { |
| LBasicBlock haveAllocator = m_out.newBlock(); |
| LBasicBlock lastNext = m_out.insertNewBlocksBefore(haveAllocator); |
| m_out.jump(slowPath); |
| m_out.appendTo(haveAllocator, lastNext); |
| return m_out.intPtrZero; |
| } |
| } else { |
| // This means that either we know that the allocator is null or we don't know what the |
| // allocator is. In either case, we need the null check. |
| LBasicBlock haveAllocator = m_out.newBlock(); |
| LBasicBlock lastNext = m_out.insertNewBlocksBefore(haveAllocator); |
| m_out.branch( |
| m_out.notEqual(allocator, m_out.constInt32(Allocator().offset())), |
| usually(haveAllocator), rarely(slowPath)); |
| m_out.appendTo(haveAllocator, lastNext); |
| } |
| |
| LBasicBlock continuation = m_out.newBlock(); |
| |
| LBasicBlock lastNext = m_out.insertNewBlocksBefore(continuation); |
| |
| PatchpointValue* patchpoint = m_out.patchpoint(pointerType()); |
| if (isARM64()) { |
| // emitAllocateWithNonNullAllocator uses the scratch registers on ARM. |
| patchpoint->clobber(RegisterSet::macroScratchRegisters()); |
| } |
| patchpoint->effects.terminal = true; |
| if (actualAllocator.isConstant()) |
| patchpoint->numGPScratchRegisters++; |
| else |
| patchpoint->appendSomeRegisterWithClobber(allocator); |
| patchpoint->numGPScratchRegisters++; |
| patchpoint->resultConstraint = ValueRep::SomeEarlyRegister; |
| |
| m_out.appendSuccessor(usually(continuation)); |
| m_out.appendSuccessor(rarely(slowPath)); |
| |
| patchpoint->setGenerator( |
| [=] (CCallHelpers& jit, const StackmapGenerationParams& params) { |
| AllowMacroScratchRegisterUsageIf allowScratchIf(jit, isARM64()); |
| CCallHelpers::JumpList jumpToSlowPath; |
| |
| GPRReg allocatorGPR; |
| if (actualAllocator.isConstant()) |
| allocatorGPR = params.gpScratch(1); |
| else |
| allocatorGPR = params[1].gpr(); |
| |
| // We use a patchpoint to emit the allocation path because whenever we mess with |
| // allocation paths, we already reason about them at the machine code level. We know |
| // exactly what instruction sequence we want. We're confident that no compiler |
| // optimization could make this code better. So, it's best to have the code in |
| // AssemblyHelpers::emitAllocate(). That way, the same optimized path is shared by |
| // all of the compiler tiers. |
| jit.emitAllocateWithNonNullAllocator( |
| params[0].gpr(), actualAllocator, allocatorGPR, params.gpScratch(0), |
| jumpToSlowPath); |
| |
| CCallHelpers::Jump jumpToSuccess; |
| if (!params.fallsThroughToSuccessor(0)) |
| jumpToSuccess = jit.jump(); |
| |
| Vector<Box<CCallHelpers::Label>> labels = params.successorLabels(); |
| |
| params.addLatePath( |
| [=] (CCallHelpers& jit) { |
| jumpToSlowPath.linkTo(*labels[1], &jit); |
| if (jumpToSuccess.isSet()) |
| jumpToSuccess.linkTo(*labels[0], &jit); |
| }); |
| }); |
| |
| m_out.appendTo(continuation, lastNext); |
| return patchpoint; |
| } |
| |
| void storeStructure(LValue object, Structure* structure) |
| { |
| m_out.store32(m_out.constInt32(structure->id()), object, m_heaps.JSCell_structureID); |
| m_out.store32( |
| m_out.constInt32(structure->objectInitializationBlob()), |
| object, m_heaps.JSCell_usefulBytes); |
| } |
| |
| void storeStructure(LValue object, LValue structure) |
| { |
| if (structure->hasIntPtr()) { |
| storeStructure(object, bitwise_cast<Structure*>(structure->asIntPtr())); |
| return; |
| } |
| |
| LValue id = m_out.load32(structure, m_heaps.Structure_structureID); |
| m_out.store32(id, object, m_heaps.JSCell_structureID); |
| |
| LValue blob = m_out.load32(structure, m_heaps.Structure_indexingTypeIncludingHistory); |
| m_out.store32(blob, object, m_heaps.JSCell_usefulBytes); |
| } |
| |
| template <typename StructureType> |
| LValue allocateCell(LValue allocator, StructureType structure, LBasicBlock slowPath) |
| { |
| LValue result = allocateHeapCell(allocator, slowPath); |
| storeStructure(result, structure); |
| return result; |
| } |
| |
| LValue allocateObject(LValue allocator, RegisteredStructure structure, LValue butterfly, LBasicBlock slowPath) |
| { |
| return allocateObject(allocator, weakStructure(structure), butterfly, slowPath); |
| } |
| |
| LValue allocateObject(LValue allocator, LValue structure, LValue butterfly, LBasicBlock slowPath) |
| { |
| LValue result = allocateCell(allocator, structure, slowPath); |
| if (structure->hasIntPtr()) { |
| splatWords( |
| result, |
| m_out.constInt32(JSFinalObject::offsetOfInlineStorage() / 8), |
| m_out.constInt32(JSFinalObject::offsetOfInlineStorage() / 8 + bitwise_cast<Structure*>(structure->asIntPtr())->inlineCapacity()), |
| m_out.int64Zero, |
| m_heaps.properties.atAnyNumber()); |
| } else { |
| LValue end = m_out.add( |
| m_out.constInt32(JSFinalObject::offsetOfInlineStorage() / 8), |
| m_out.load8ZeroExt32(structure, m_heaps.Structure_inlineCapacity)); |
| splatWords( |
| result, |
| m_out.constInt32(JSFinalObject::offsetOfInlineStorage() / 8), |
| end, |
| m_out.int64Zero, |
| m_heaps.properties.atAnyNumber()); |
| } |
| |
| m_out.storePtr(butterfly, result, m_heaps.JSObject_butterfly); |
| return result; |
| } |
| |
| template<typename ClassType, typename StructureType> |
| LValue allocateObject( |
| size_t size, StructureType structure, LValue butterfly, LBasicBlock slowPath) |
| { |
| Allocator allocator = subspaceFor<ClassType>(vm())->allocatorForNonVirtual(size, AllocatorForMode::AllocatorIfExists); |
| return allocateObject(m_out.constInt32(allocator.offset()), structure, butterfly, slowPath); |
| } |
| |
| template<typename ClassType, typename StructureType> |
| LValue allocateObject(StructureType structure, LValue butterfly, LBasicBlock slowPath) |
| { |
| return allocateObject<ClassType>( |
| ClassType::allocationSize(0), structure, butterfly, slowPath); |
| } |
| |
| LValue allocatorForSize(LValue subspace, LValue size, LBasicBlock slowPath) |
| { |
| static_assert(!(MarkedSpace::sizeStep & (MarkedSpace::sizeStep - 1)), "MarkedSpace::sizeStep must be a power of two."); |
| |
| // Try to do some constant-folding here. |
| if (subspace->hasIntPtr() && size->hasIntPtr()) { |
| CompleteSubspace* actualSubspace = bitwise_cast<CompleteSubspace*>(subspace->asIntPtr()); |
| size_t actualSize = size->asIntPtr(); |
| |
| Allocator actualAllocator = actualSubspace->allocatorForNonVirtual(actualSize, AllocatorForMode::AllocatorIfExists); |
| if (!actualAllocator) { |
| LBasicBlock continuation = m_out.newBlock(); |
| LBasicBlock lastNext = m_out.insertNewBlocksBefore(continuation); |
| m_out.jump(slowPath); |
| m_out.appendTo(continuation, lastNext); |
| return m_out.int32Zero; |
| } |
| |
| return m_out.constInt32(actualAllocator.offset()); |
| } |
| |
| unsigned stepShift = getLSBSet(MarkedSpace::sizeStep); |
| |
| LBasicBlock continuation = m_out.newBlock(); |
| |
| LBasicBlock lastNext = m_out.insertNewBlocksBefore(continuation); |
| |
| LValue sizeClassIndex = m_out.lShr( |
| m_out.add(size, m_out.constIntPtr(MarkedSpace::sizeStep - 1)), |
| m_out.constInt32(stepShift)); |
| |
| m_out.branch( |
| m_out.above(sizeClassIndex, m_out.constIntPtr(MarkedSpace::largeCutoff >> stepShift)), |
| rarely(slowPath), usually(continuation)); |
| |
| m_out.appendTo(continuation, lastNext); |
| |
| return m_out.load32( |
| m_out.baseIndex( |
| m_heaps.CompleteSubspace_allocatorForSizeStep, |
| subspace, m_out.sub(sizeClassIndex, m_out.intPtrOne))); |
| } |
| |
| LValue allocatorForSize(CompleteSubspace& subspace, LValue size, LBasicBlock slowPath) |
| { |
| return allocatorForSize(m_out.constIntPtr(&subspace), size, slowPath); |
| } |
| |
| template<typename ClassType> |
| LValue allocateVariableSizedObject( |
| LValue size, RegisteredStructure structure, LValue butterfly, LBasicBlock slowPath) |
| { |
| LValue allocator = allocatorForSize(*subspaceFor<ClassType>(vm()), size, slowPath); |
| return allocateObject(allocator, structure, butterfly, slowPath); |
| } |
| |
| template<typename ClassType> |
| LValue allocateVariableSizedCell( |
| LValue size, Structure* structure, LBasicBlock slowPath) |
| { |
| LValue allocator = allocatorForSize(*subspaceFor<ClassType>(vm()), size, slowPath); |
| return allocateCell(allocator, structure, slowPath); |
| } |
| |
| LValue allocateObject(RegisteredStructure structure) |
| { |
| size_t allocationSize = JSFinalObject::allocationSize(structure.get()->inlineCapacity()); |
| Allocator allocator = subspaceFor<JSFinalObject>(vm())->allocatorForNonVirtual(allocationSize, AllocatorForMode::AllocatorIfExists); |
| |
| // FIXME: If the allocator is null, we could simply emit a normal C call to the allocator |
| // instead of putting it on the slow path. |
| // https://bugs.webkit.org/show_bug.cgi?id=161062 |
| |
| LBasicBlock slowPath = m_out.newBlock(); |
| LBasicBlock continuation = m_out.newBlock(); |
| |
| LBasicBlock lastNext = m_out.insertNewBlocksBefore(slowPath); |
| |
| ValueFromBlock fastResult = m_out.anchor(allocateObject( |
| m_out.constInt32(allocator.offset()), structure, m_out.intPtrZero, slowPath)); |
| |
| m_out.jump(continuation); |
| |
| m_out.appendTo(slowPath, continuation); |
| |
| VM& vm = this->vm(); |
| LValue slowResultValue = lazySlowPath( |
| [=, &vm] (const Vector<Location>& locations) -> RefPtr<LazySlowPath::Generator> { |
| return createLazyCallGenerator(vm, |
| operationNewObject, locations[0].directGPR(), |
| CCallHelpers::TrustedImmPtr(structure.get())); |
| }); |
| ValueFromBlock slowResult = m_out.anchor(slowResultValue); |
| m_out.jump(continuation); |
| |
| m_out.appendTo(continuation, lastNext); |
| return m_out.phi(pointerType(), fastResult, slowResult); |
| } |
| |
| struct ArrayValues { |
| ArrayValues() |
| : array(0) |
| , butterfly(0) |
| { |
| } |
| |
| ArrayValues(LValue array, LValue butterfly) |
| : array(array) |
| , butterfly(butterfly) |
| { |
| } |
| |
| LValue array; |
| LValue butterfly; |
| }; |
| |
| ArrayValues allocateJSArray(LValue publicLength, LValue vectorLength, LValue structure, LValue indexingType, bool shouldInitializeElements = true, bool shouldLargeArraySizeCreateArrayStorage = true) |
| { |
| JSGlobalObject* globalObject = m_graph.globalObjectFor(m_node->origin.semantic); |
| if (indexingType->hasInt32()) { |
| IndexingType type = static_cast<IndexingType>(indexingType->asInt32()); |
| ASSERT_UNUSED(type, |
| hasUndecided(type) |
| || hasInt32(type) |
| || hasDouble(type) |
| || hasContiguous(type)); |
| } |
| |
| LBasicBlock fastCase = m_out.newBlock(); |
| LBasicBlock largeCase = m_out.newBlock(); |
| LBasicBlock failCase = m_out.newBlock(); |
| LBasicBlock continuation = m_out.newBlock(); |
| LBasicBlock slowCase = m_out.newBlock(); |
| |
| LBasicBlock lastNext = m_out.insertNewBlocksBefore(fastCase); |
| |
| std::optional<unsigned> staticVectorLength; |
| std::optional<unsigned> staticVectorLengthFromPublicLength; |
| if (structure->hasIntPtr()) { |
| if (publicLength->hasInt32()) { |
| unsigned publicLengthConst = static_cast<unsigned>(publicLength->asInt32()); |
| if (publicLengthConst <= MAX_STORAGE_VECTOR_LENGTH) { |
| publicLengthConst = Butterfly::optimalContiguousVectorLength( |
| bitwise_cast<Structure*>(structure->asIntPtr())->outOfLineCapacity(), publicLengthConst); |
| staticVectorLengthFromPublicLength = publicLengthConst; |
| } |
| |
| } |
| if (vectorLength->hasInt32()) { |
| unsigned vectorLengthConst = static_cast<unsigned>(vectorLength->asInt32()); |
| if (vectorLengthConst <= MAX_STORAGE_VECTOR_LENGTH) { |
| vectorLengthConst = Butterfly::optimalContiguousVectorLength( |
| bitwise_cast<Structure*>(structure->asIntPtr())->outOfLineCapacity(), vectorLengthConst); |
| vectorLength = m_out.constInt32(vectorLengthConst); |
| staticVectorLength = vectorLengthConst; |
| } |
| } |
| } else { |
| // We don't compute the optimal vector length for new Array(blah) where blah is not |
| // statically known, since the compute effort of doing it here is probably not worth it. |
| } |
| |
| ValueFromBlock noButterfly = m_out.anchor(m_out.intPtrZero); |
| |
| LValue predicate; |
| if (shouldLargeArraySizeCreateArrayStorage) |
| predicate = m_out.aboveOrEqual(publicLength, m_out.constInt32(MIN_ARRAY_STORAGE_CONSTRUCTION_LENGTH)); |
| else |
| predicate = m_out.booleanFalse; |
| |
| m_out.branch(predicate, rarely(largeCase), usually(fastCase)); |
| |
| m_out.appendTo(fastCase, largeCase); |
| |
| LValue payloadSize = |
| m_out.shl(m_out.zeroExt(vectorLength, pointerType()), m_out.constIntPtr(3)); |
| |
| LValue butterflySize = m_out.add( |
| payloadSize, m_out.constIntPtr(sizeof(IndexingHeader))); |
| |
| LValue allocator = allocatorForSize(vm().jsValueGigacageAuxiliarySpace, butterflySize, failCase); |
| LValue startOfStorage = allocateHeapCell(allocator, failCase); |
| |
| LValue butterfly = m_out.add(startOfStorage, m_out.constIntPtr(sizeof(IndexingHeader))); |
| |
| m_out.store32(publicLength, butterfly, m_heaps.Butterfly_publicLength); |
| m_out.store32(vectorLength, butterfly, m_heaps.Butterfly_vectorLength); |
| |
| initializeArrayElements( |
| indexingType, |
| shouldInitializeElements ? m_out.int32Zero : publicLength, vectorLength, |
| butterfly); |
| |
| ValueFromBlock haveButterfly = m_out.anchor(butterfly); |
| |
| LValue object = allocateObject<JSArray>(structure, butterfly, failCase); |
| |
| ValueFromBlock fastResult = m_out.anchor(object); |
| ValueFromBlock fastButterfly = m_out.anchor(butterfly); |
| m_out.jump(continuation); |
| |
| m_out.appendTo(largeCase, failCase); |
| ValueFromBlock largeStructure = m_out.anchor( |
| weakStructure(m_graph.registerStructure(globalObject->arrayStructureForIndexingTypeDuringAllocation(ArrayWithArrayStorage)))); |
| m_out.jump(slowCase); |
| |
| m_out.appendTo(failCase, slowCase); |
| ValueFromBlock failStructure = m_out.anchor(structure); |
| m_out.jump(slowCase); |
| |
| m_out.appendTo(slowCase, continuation); |
| LValue structureValue = m_out.phi(pointerType(), largeStructure, failStructure); |
| LValue butterflyValue = m_out.phi(pointerType(), noButterfly, haveButterfly); |
| |
| VM& vm = this->vm(); |
| LValue slowResultValue = nullptr; |
| if (vectorLength == publicLength |
| || (staticVectorLengthFromPublicLength && staticVectorLength && staticVectorLength.value() == staticVectorLengthFromPublicLength.value())) { |
| slowResultValue = lazySlowPath( |
| [=, &vm] (const Vector<Location>& locations) -> RefPtr<LazySlowPath::Generator> { |
| return createLazyCallGenerator(vm, |
| operationNewArrayWithSize, locations[0].directGPR(), |
| locations[1].directGPR(), locations[2].directGPR(), locations[3].directGPR()); |
| }, |
| structureValue, publicLength, butterflyValue); |
| } else { |
| slowResultValue = lazySlowPath( |
| [=, &vm] (const Vector<Location>& locations) -> RefPtr<LazySlowPath::Generator> { |
| return createLazyCallGenerator(vm, |
| operationNewArrayWithSizeAndHint, locations[0].directGPR(), |
| locations[1].directGPR(), locations[2].directGPR(), locations[3].directGPR(), locations[4].directGPR()); |
| }, |
| structureValue, publicLength, vectorLength, butterflyValue); |
| } |
| |
| ValueFromBlock slowResult = m_out.anchor(slowResultValue); |
| ValueFromBlock slowButterfly = m_out.anchor( |
| m_out.loadPtr(slowResultValue, m_heaps.JSObject_butterfly)); |
| m_out.jump(continuation); |
| |
| m_out.appendTo(continuation, lastNext); |
| return ArrayValues( |
| m_out.phi(pointerType(), fastResult, slowResult), |
| m_out.phi(pointerType(), fastButterfly, slowButterfly)); |
| } |
| |
| ArrayValues allocateUninitializedContiguousJSArrayInternal(LValue publicLength, LValue vectorLength, RegisteredStructure structure) |
| { |
| bool shouldInitializeElements = false; |
| bool shouldLargeArraySizeCreateArrayStorage = false; |
| return allocateJSArray( |
| publicLength, vectorLength, weakStructure(structure), m_out.constInt32(structure->indexingType()), shouldInitializeElements, |
| shouldLargeArraySizeCreateArrayStorage); |
| } |
| |
| ArrayValues allocateUninitializedContiguousJSArray(LValue publicLength, RegisteredStructure structure) |
| { |
| return allocateUninitializedContiguousJSArrayInternal(publicLength, publicLength, structure); |
| } |
| |
| ArrayValues allocateUninitializedContiguousJSArray(unsigned publicLength, unsigned vectorLength, RegisteredStructure structure) |
| { |
| ASSERT(vectorLength >= publicLength); |
| return allocateUninitializedContiguousJSArrayInternal(m_out.constInt32(publicLength), m_out.constInt32(vectorLength), structure); |
| } |
| |
| LValue ensureShadowChickenPacket() |
| { |
| LBasicBlock slowCase = m_out.newBlock(); |
| LBasicBlock continuation = m_out.newBlock(); |
| |
| TypedPointer addressOfLogCursor = m_out.absolute(vm().shadowChicken().addressOfLogCursor()); |
| LValue logCursor = m_out.loadPtr(addressOfLogCursor); |
| |
| ValueFromBlock fastResult = m_out.anchor(logCursor); |
| |
| m_out.branch( |
| m_out.below(logCursor, m_out.constIntPtr(vm().shadowChicken().logEnd())), |
| usually(continuation), rarely(slowCase)); |
| |
| LBasicBlock lastNext = m_out.appendTo(slowCase, continuation); |
| |
| vmCall(Void, m_out.operation(operationProcessShadowChickenLog), m_callFrame); |
| |
| ValueFromBlock slowResult = m_out.anchor(m_out.loadPtr(addressOfLogCursor)); |
| m_out.jump(continuation); |
| |
| m_out.appendTo(continuation, lastNext); |
| LValue result = m_out.phi(pointerType(), fastResult, slowResult); |
| |
| m_out.storePtr( |
| m_out.add(result, m_out.constIntPtr(sizeof(ShadowChicken::Packet))), |
| addressOfLogCursor); |
| |
| return result; |
| } |
| |
| LValue boolify(Edge edge) |
| { |
| switch (edge.useKind()) { |
| case BooleanUse: |
| case KnownBooleanUse: |
| return lowBoolean(edge); |
| case Int32Use: |
| return m_out.notZero32(lowInt32(edge)); |
| case DoubleRepUse: |
| return m_out.doubleNotEqualAndOrdered(lowDouble(edge), m_out.doubleZero); |
| case ObjectOrOtherUse: |
| return m_out.logicalNot( |
| equalNullOrUndefined( |
| edge, CellCaseSpeculatesObject, SpeculateNullOrUndefined, |
| ManualOperandSpeculation)); |
| case StringUse: { |
| LValue stringValue = lowString(edge); |
| LValue length = m_out.load32NonNegative(stringValue, m_heaps.JSString_length); |
| return m_out.notEqual(length, m_out.int32Zero); |
| } |
| case StringOrOtherUse: { |
| LValue value = lowJSValue(edge, ManualOperandSpeculation); |
| |
| LBasicBlock cellCase = m_out.newBlock(); |
| LBasicBlock notCellCase = m_out.newBlock(); |
| LBasicBlock continuation = m_out.newBlock(); |
| |
| m_out.branch(isCell(value, provenType(edge)), unsure(cellCase), unsure(notCellCase)); |
| |
| LBasicBlock lastNext = m_out.appendTo(cellCase, notCellCase); |
| |
| FTL_TYPE_CHECK(jsValueValue(value), edge, (~SpecCellCheck) | SpecString, isNotString(value)); |
| LValue length = m_out.load32NonNegative(value, m_heaps.JSString_length); |
| ValueFromBlock cellResult = m_out.anchor(m_out.notEqual(length, m_out.int32Zero)); |
| m_out.jump(continuation); |
| |
| m_out.appendTo(notCellCase, continuation); |
| |
| FTL_TYPE_CHECK(jsValueValue(value), edge, SpecCellCheck | SpecOther, isNotOther(value)); |
| ValueFromBlock notCellResult = m_out.anchor(m_out.booleanFalse); |
| m_out.jump(continuation); |
| m_out.appendTo(continuation, lastNext); |
| |
| return m_out.phi(Int32, cellResult, notCellResult); |
| } |
| case UntypedUse: { |
| LValue value = lowJSValue(edge); |
| |
| // Implements the following control flow structure: |
| // if (value is cell) { |
| // if (value is string) |
| // result = !!value->length |
| // else { |
| // do evil things for masquerades-as-undefined |
| // result = true |
| // } |
| // } else if (value is int32) { |
| // result = !!unboxInt32(value) |
| // } else if (value is number) { |
| // result = !!unboxDouble(value) |
| // } else { |
| // result = value == jsTrue |
| // } |
| |
| LBasicBlock cellCase = m_out.newBlock(); |
| LBasicBlock stringCase = m_out.newBlock(); |
| LBasicBlock notStringCase = m_out.newBlock(); |
| LBasicBlock notCellCase = m_out.newBlock(); |
| LBasicBlock int32Case = m_out.newBlock(); |
| LBasicBlock notInt32Case = m_out.newBlock(); |
| LBasicBlock doubleCase = m_out.newBlock(); |
| LBasicBlock notDoubleCase = m_out.newBlock(); |
| LBasicBlock continuation = m_out.newBlock(); |
| |
| Vector<ValueFromBlock> results; |
| |
| m_out.branch(isCell(value, provenType(edge)), unsure(cellCase), unsure(notCellCase)); |
| |
| LBasicBlock lastNext = m_out.appendTo(cellCase, stringCase); |
| m_out.branch( |
| isString(value, provenType(edge) & SpecCell), |
| unsure(stringCase), unsure(notStringCase)); |
| |
| m_out.appendTo(stringCase, notStringCase); |
| LValue nonEmptyString = m_out.notZero32( |
| m_out.load32NonNegative(value, m_heaps.JSString_length)); |
| results.append(m_out.anchor(nonEmptyString)); |
| m_out.jump(continuation); |
| |
| m_out.appendTo(notStringCase, notCellCase); |
| LValue isTruthyObject; |
| if (masqueradesAsUndefinedWatchpointIsStillValid()) |
| isTruthyObject = m_out.booleanTrue; |
| else { |
| LBasicBlock masqueradesCase = m_out.newBlock(); |
| |
| results.append(m_out.anchor(m_out.booleanTrue)); |
| |
| m_out.branch( |
| m_out.testIsZero32( |
| m_out.load8ZeroExt32(value, m_heaps.JSCell_typeInfoFlags), |
| m_out.constInt32(MasqueradesAsUndefined)), |
| usually(continuation), rarely(masqueradesCase)); |
| |
| m_out.appendTo(masqueradesCase); |
| |
| isTruthyObject = m_out.notEqual( |
| weakPointer(m_graph.globalObjectFor(m_node->origin.semantic)), |
| m_out.loadPtr(loadStructure(value), m_heaps.Structure_globalObject)); |
| } |
| results.append(m_out.anchor(isTruthyObject)); |
| m_out.jump(continuation); |
| |
| m_out.appendTo(notCellCase, int32Case); |
| m_out.branch( |
| isInt32(value, provenType(edge) & ~SpecCell), |
| unsure(int32Case), unsure(notInt32Case)); |
| |
| m_out.appendTo(int32Case, notInt32Case); |
| results.append(m_out.anchor(m_out.notZero32(unboxInt32(value)))); |
| m_out.jump(continuation); |
| |
| m_out.appendTo(notInt32Case, doubleCase); |
| m_out.branch( |
| isNumber(value, provenType(edge) & ~SpecCell), |
| unsure(doubleCase), unsure(notDoubleCase)); |
| |
| m_out.appendTo(doubleCase, notDoubleCase); |
| LValue doubleIsTruthy = m_out.doubleNotEqualAndOrdered( |
| unboxDouble(value), m_out.constDouble(0)); |
| results.append(m_out.anchor(doubleIsTruthy)); |
| m_out.jump(continuation); |
| |
| m_out.appendTo(notDoubleCase, continuation); |
| LValue miscIsTruthy = m_out.equal( |
| value, m_out.constInt64(JSValue::encode(jsBoolean(true)))); |
| results.append(m_out.anchor(miscIsTruthy)); |
| m_out.jump(continuation); |
| |
| m_out.appendTo(continuation, lastNext); |
| return m_out.phi(Int32, results); |
| } |
| default: |
| DFG_CRASH(m_graph, m_node, "Bad use kind"); |
| return 0; |
| } |
| } |
| |
| enum StringOrObjectMode { |
| AllCellsAreFalse, |
| CellCaseSpeculatesObject |
| }; |
| enum EqualNullOrUndefinedMode { |
| EqualNull, |
| EqualUndefined, |
| EqualNullOrUndefined, |
| SpeculateNullOrUndefined |
| }; |
| LValue equalNullOrUndefined( |
| Edge edge, StringOrObjectMode cellMode, EqualNullOrUndefinedMode primitiveMode, |
| OperandSpeculationMode operandMode = AutomaticOperandSpeculation) |
| { |
| bool validWatchpoint = masqueradesAsUndefinedWatchpointIsStillValid(); |
| |
| LValue value = lowJSValue(edge, operandMode); |
| |
| LBasicBlock cellCase = m_out.newBlock(); |
| LBasicBlock primitiveCase = m_out.newBlock(); |
| LBasicBlock continuation = m_out.newBlock(); |
| |
| m_out.branch(isNotCell(value, provenType(edge)), unsure(primitiveCase), unsure(cellCase)); |
| |
| LBasicBlock lastNext = m_out.appendTo(cellCase, primitiveCase); |
| |
| Vector<ValueFromBlock, 3> results; |
| |
| switch (cellMode) { |
| case AllCellsAreFalse: |
| break; |
| case CellCaseSpeculatesObject: |
| FTL_TYPE_CHECK( |
| jsValueValue(value), edge, (~SpecCellCheck) | SpecObject, isNotObject(value)); |
| break; |
| } |
| |
| if (validWatchpoint) { |
| results.append(m_out.anchor(m_out.booleanFalse)); |
| m_out.jump(continuation); |
| } else { |
| LBasicBlock masqueradesCase = |
| m_out.newBlock(); |
| |
| results.append(m_out.anchor(m_out.booleanFalse)); |
| |
| m_out.branch( |
| m_out.testNonZero32( |
| m_out.load8ZeroExt32(value, m_heaps.JSCell_typeInfoFlags), |
| m_out.constInt32(MasqueradesAsUndefined)), |
| rarely(masqueradesCase), usually(continuation)); |
| |
| m_out.appendTo(masqueradesCase, primitiveCase); |
| |
| LValue structure = loadStructure(value); |
| |
| results.append(m_out.anchor( |
| m_out.equal( |
| weakPointer(m_graph.globalObjectFor(m_node->origin.semantic)), |
| m_out.loadPtr(structure, m_heaps.Structure_globalObject)))); |
| m_out.jump(continuation); |
| } |
| |
| m_out.appendTo(primitiveCase, continuation); |
| |
| LValue primitiveResult; |
| switch (primitiveMode) { |
| case EqualNull: |
| primitiveResult = m_out.equal(value, m_out.constInt64(ValueNull)); |
| break; |
| case EqualUndefined: |
| primitiveResult = m_out.equal(value, m_out.constInt64(ValueUndefined)); |
| break; |
| case EqualNullOrUndefined: |
| primitiveResult = isOther(value, provenType(edge)); |
| break; |
| case SpeculateNullOrUndefined: |
| FTL_TYPE_CHECK( |
| jsValueValue(value), edge, SpecCellCheck | SpecOther, isNotOther(value)); |
| primitiveResult = m_out.booleanTrue; |
| break; |
| } |
| results.append(m_out.anchor(primitiveResult)); |
| m_out.jump(continuation); |
| |
| m_out.appendTo(continuation, lastNext); |
| |
| return m_out.phi(Int32, results); |
| } |
| |
| template<typename FunctionType> |
| void contiguousPutByValOutOfBounds( |
| FunctionType slowPathFunction, LValue base, LValue storage, LValue index, LValue value, |
| LBasicBlock continuation) |
| { |
| if (!m_node->arrayMode().isInBounds()) { |
| LBasicBlock notInBoundsCase = |
| m_out.newBlock(); |
| LBasicBlock performStore = |
| m_out.newBlock(); |
| |
| LValue isNotInBounds = m_out.aboveOrEqual( |
| index, m_out.load32NonNegative(storage, m_heaps.Butterfly_publicLength)); |
| m_out.branch(isNotInBounds, unsure(notInBoundsCase), unsure(performStore)); |
| |
| LBasicBlock lastNext = m_out.appendTo(notInBoundsCase, performStore); |
| |
| LValue isOutOfBounds = m_out.aboveOrEqual( |
| index, m_out.load32NonNegative(storage, m_heaps.Butterfly_vectorLength)); |
| |
| if (!m_node->arrayMode().isOutOfBounds()) |
| speculate(OutOfBounds, noValue(), 0, isOutOfBounds); |
| else { |
| LBasicBlock outOfBoundsCase = |
| m_out.newBlock(); |
| LBasicBlock holeCase = |
| m_out.newBlock(); |
| |
| m_out.branch(isOutOfBounds, rarely(outOfBoundsCase), usually(holeCase)); |
| |
| LBasicBlock innerLastNext = m_out.appendTo(outOfBoundsCase, holeCase); |
| |
| vmCall( |
| Void, m_out.operation(slowPathFunction), |
| m_callFrame, base, index, value); |
| |
| m_out.jump(continuation); |
| |
| m_out.appendTo(holeCase, innerLastNext); |
| } |
| |
| m_out.store32( |
| m_out.add(index, m_out.int32One), |
| storage, m_heaps.Butterfly_publicLength); |
| |
| m_out.jump(performStore); |
| m_out.appendTo(performStore, lastNext); |
| } |
| } |
| |
| LValue caged(Gigacage::Kind kind, LValue ptr) |
| { |
| if (!Gigacage::isEnabled(kind)) |
| return ptr; |
| |
| if (kind == Gigacage::Primitive && Gigacage::canPrimitiveGigacageBeDisabled()) { |
| if (vm().primitiveGigacageEnabled().isStillValid()) |
| m_graph.watchpoints().addLazily(vm().primitiveGigacageEnabled()); |
| else |
| return ptr; |
| } |
| |
| LValue basePtr = m_out.constIntPtr(Gigacage::basePtr(kind)); |
| LValue mask = m_out.constIntPtr(Gigacage::mask(kind)); |
| |
| LValue masked = m_out.bitAnd(ptr, mask); |
| LValue result = m_out.add(masked, basePtr); |
| |
| // Make sure that B3 doesn't try to do smart reassociation of these pointer bits. |
| // FIXME: In an ideal world, B3 would not do harmful reassociations, and if it did, it would be able |
| // to undo them during constant hoisting and regalloc. As it stands, if you remove this then Octane |
| // gets 1.6% slower and Kraken gets 5% slower. It's all because the basePtr, which is a constant, |
| // gets reassociated out of the add above and into the address arithmetic. This disables hoisting of |
| // the basePtr constant. Hoisting that constant is worth a lot more perf than the reassociation. One |
| // way to make this all work happily is to combine offset legalization with constant hoisting, and |
| // then teach it reassociation. So, Add(Add(a, b), const) where a is loop-invariant while b isn't |
| // will turn into Add(Add(a, const), b) by the constant hoister. We would have to teach B3 to do this |
| // and possibly other smart things if we want to be able to remove this opaque. |
| // https://bugs.webkit.org/show_bug.cgi?id=175493 |
| return m_out.opaque(result); |
| } |
| |
| void buildSwitch(SwitchData* data, LType type, LValue switchValue) |
| { |
| ASSERT(type == pointerType() || type == Int32); |
| |
| Vector<SwitchCase> cases; |
| for (unsigned i = 0; i < data->cases.size(); ++i) { |
| SwitchCase newCase; |
| |
| if (type == pointerType()) { |
| newCase = SwitchCase(m_out.constIntPtr(data->cases[i].value.switchLookupValue(data->kind)), |
| lowBlock(data->cases[i].target.block), Weight(data->cases[i].target.count)); |
| } else if (type == Int32) { |
| newCase = SwitchCase(m_out.constInt32(data->cases[i].value.switchLookupValue(data->kind)), |
| lowBlock(data->cases[i].target.block), Weight(data->cases[i].target.count)); |
| } else |
| CRASH(); |
| |
| cases.append(newCase); |
| } |
| |
| m_out.switchInstruction( |
| switchValue, cases, |
| lowBlock(data->fallThrough.block), Weight(data->fallThrough.count)); |
| } |
| |
| void switchString(SwitchData* data, LValue string) |
| { |
| bool canDoBinarySwitch = true; |
| unsigned totalLength = 0; |
| |
| for (DFG::SwitchCase myCase : data->cases) { |
| StringImpl* string = myCase.value.stringImpl(); |
| if (!string->is8Bit()) { |
| canDoBinarySwitch = false; |
| break; |
| } |
| if (string->length() > Options::maximumBinaryStringSwitchCaseLength()) { |
| canDoBinarySwitch = false; |
| break; |
| } |
| totalLength += string->length(); |
| } |
| |
| if (!canDoBinarySwitch || totalLength > Options::maximumBinaryStringSwitchTotalLength()) { |
| switchStringSlow(data, string); |
| return; |
| } |
| |
| LValue stringImpl = m_out.loadPtr(string, m_heaps.JSString_value); |
| LValue length = m_out.load32(string, m_heaps.JSString_length); |
| |
| LBasicBlock hasImplBlock = m_out.newBlock(); |
| LBasicBlock is8BitBlock = m_out.newBlock(); |
| LBasicBlock slowBlock = m_out.newBlock(); |
| |
| m_out.branch(m_out.isNull(stringImpl), unsure(slowBlock), unsure(hasImplBlock)); |
| |
| LBasicBlock lastNext = m_out.appendTo(hasImplBlock, is8BitBlock); |
| |
| m_out.branch( |
| m_out.testIsZero32( |
| m_out.load32(stringImpl, m_heaps.StringImpl_hashAndFlags), |
| m_out.constInt32(StringImpl::flagIs8Bit())), |
| unsure(slowBlock), unsure(is8BitBlock)); |
| |
| m_out.appendTo(is8BitBlock, slowBlock); |
| |
| LValue buffer = m_out.loadPtr(stringImpl, m_heaps.StringImpl_data); |
| |
| // FIXME: We should propagate branch weight data to the cases of this switch. |
| // https://bugs.webkit.org/show_bug.cgi?id=144368 |
| |
| Vector<StringSwitchCase> cases; |
| for (DFG::SwitchCase myCase : data->cases) |
| cases.append(StringSwitchCase(myCase.value.stringImpl(), lowBlock(myCase.target.block))); |
| std::sort(cases.begin(), cases.end()); |
| switchStringRecurse(data, buffer, length, cases, 0, 0, cases.size(), 0, false); |
| |
| m_out.appendTo(slowBlock, lastNext); |
| switchStringSlow(data, string); |
| } |
| |
| // The code for string switching is based closely on the same code in the DFG backend. While it |
| // would be nice to reduce the amount of similar-looking code, it seems like this is one of |
| // those algorithms where factoring out the common bits would result in more code than just |
| // duplicating. |
| |
| struct StringSwitchCase { |
| StringSwitchCase() { } |
| |
| StringSwitchCase(StringImpl* string, LBasicBlock target) |
| : string(string) |
| , target(target) |
| { |
| } |
| |
| bool operator<(const StringSwitchCase& other) const |
| { |
| return stringLessThan(*string, *other.string); |
| } |
| |
| StringImpl* string; |
| LBasicBlock target; |
| }; |
| |
| struct CharacterCase { |
| CharacterCase() |
| : character(0) |
| , begin(0) |
| , end(0) |
| { |
| } |
| |
| CharacterCase(LChar character, unsigned begin, unsigned end) |
| : character(character) |
| , begin(begin) |
| , end(end) |
| { |
| } |
| |
| bool operator<(const CharacterCase& other) const |
| { |
| return character < other.character; |
| } |
| |
| LChar character; |
| unsigned begin; |
| unsigned end; |
| }; |
| |
| void switchStringRecurse( |
| SwitchData* data, LValue buffer, LValue length, const Vector<StringSwitchCase>& cases, |
| unsigned numChecked, unsigned begin, unsigned end, unsigned alreadyCheckedLength, |
| unsigned checkedExactLength) |
| { |
| LBasicBlock fallThrough = lowBlock(data->fallThrough.block); |
| |
| if (begin == end) { |
| m_out.jump(fallThrough); |
| return; |
| } |
| |
| unsigned minLength = cases[begin].string->length(); |
| unsigned commonChars = minLength; |
| bool allLengthsEqual = true; |
| for (unsigned i = begin + 1; i < end; ++i) { |
| unsigned myCommonChars = numChecked; |
| unsigned limit = std::min(cases[begin].string->length(), cases[i].string->length()); |
| for (unsigned j = numChecked; j < limit; ++j) { |
| if (cases[begin].string->at(j) != cases[i].string->at(j)) |
| break; |
| myCommonChars++; |
| } |
| commonChars = std::min(commonChars, myCommonChars); |
| if (minLength != cases[i].string->length()) |
| allLengthsEqual = false; |
| minLength = std::min(minLength, cases[i].string->length()); |
| } |
| |
| if (checkedExactLength) { |
| DFG_ASSERT(m_graph, m_node, alreadyCheckedLength == minLength, alreadyCheckedLength, minLength); |
| DFG_ASSERT(m_graph, m_node, allLengthsEqual); |
| } |
| |
| DFG_ASSERT(m_graph, m_node, minLength >= commonChars, minLength, commonChars); |
| |
| if (!allLengthsEqual && alreadyCheckedLength < minLength) |
| m_out.check(m_out.below(length, m_out.constInt32(minLength)), unsure(fallThrough)); |
| if (allLengthsEqual && (alreadyCheckedLength < minLength || !checkedExactLength)) |
| m_out.check(m_out.notEqual(length, m_out.constInt32(minLength)), unsure(fallThrough)); |
| |
| for (unsigned i = numChecked; i < commonChars; ++i) { |
| m_out.check( |
| m_out.notEqual( |
| m_out.load8ZeroExt32(buffer, m_heaps.characters8[i]), |
| m_out.constInt32(static_cast<uint16_t>(cases[begin].string->at(i)))), |
| unsure(fallThrough)); |
| } |
| |
| if (minLength == commonChars) { |
| // This is the case where one of the cases is a prefix of all of the other cases. |
| // We've already checked that the input string is a prefix of all of the cases, |
| // so we just check length to jump to that case. |
| |
| DFG_ASSERT(m_graph, m_node, cases[begin].string->length() == commonChars, cases[begin].string->length(), commonChars); |
| for (unsigned i = begin + 1; i < end; ++i) |
| DFG_ASSERT(m_graph, m_node, cases[i].string->length() > commonChars, cases[i].string->length(), commonChars); |
| |
| if (allLengthsEqual) { |
| DFG_ASSERT(m_graph, m_node, end == begin + 1, end, begin); |
| m_out.jump(cases[begin].target); |
| return; |
| } |
| |
| m_out.check( |
| m_out.equal(length, m_out.constInt32(commonChars)), |
| unsure(cases[begin].target)); |
| |
| // We've checked if the length is >= minLength, and then we checked if the length is |
| // == commonChars. We get to this point if it is >= minLength but not == commonChars. |
| // Hence we know that it now must be > minLength, i.e. that it's >= minLength + 1. |
| switchStringRecurse( |
| data, buffer, length, cases, commonChars, begin + 1, end, minLength + 1, false); |
| return; |
| } |
| |
| // At this point we know that the string is longer than commonChars, and we've only verified |
| // commonChars. Use a binary switch on the next unchecked character, i.e. |
| // string[commonChars]. |
| |
| DFG_ASSERT(m_graph, m_node, end >= begin + 2, end, begin); |
| |
| LValue uncheckedChar = m_out.load8ZeroExt32(buffer, m_heaps.characters8[commonChars]); |
| |
| Vector<CharacterCase> characterCases; |
| CharacterCase currentCase(cases[begin].string->at(commonChars), begin, begin + 1); |
| for (unsigned i = begin + 1; i < end; ++i) { |
| LChar currentChar = cases[i].string->at(commonChars); |
| if (currentChar != currentCase.character) { |
| currentCase.end = i; |
| characterCases.append(currentCase); |
| currentCase = CharacterCase(currentChar, i, i + 1); |
| } else |
| currentCase.end = i + 1; |
| } |
| characterCases.append(currentCase); |
| |
| Vector<LBasicBlock> characterBlocks; |
| for (unsigned i = characterCases.size(); i--;) |
| characterBlocks.append(m_out.newBlock()); |
| |
| Vector<SwitchCase> switchCases; |
| for (unsigned i = 0; i < characterCases.size(); ++i) { |
| if (i) |
| DFG_ASSERT(m_graph, m_node, characterCases[i - 1].character < characterCases[i].character); |
| switchCases.append(SwitchCase( |
| m_out.constInt32(characterCases[i].character), characterBlocks[i], Weight())); |
| } |
| m_out.switchInstruction(uncheckedChar, switchCases, fallThrough, Weight()); |
| |
| LBasicBlock lastNext = m_out.m_nextBlock; |
| characterBlocks.append(lastNext); // Makes it convenient to set nextBlock. |
| for (unsigned i = 0; i < characterCases.size(); ++i) { |
| m_out.appendTo(characterBlocks[i], characterBlocks[i + 1]); |
| switchStringRecurse( |
| data, buffer, length, cases, commonChars + 1, |
| characterCases[i].begin, characterCases[i].end, minLength, allLengthsEqual); |
| } |
| |
| DFG_ASSERT(m_graph, m_node, m_out.m_nextBlock == lastNext); |
| } |
| |
| void switchStringSlow(SwitchData* data, LValue string) |
| { |
| // FIXME: We ought to be able to use computed gotos here. We would save the labels of the |
| // blocks we want to jump to, and then request their addresses after compilation completes. |
| // https://bugs.webkit.org/show_bug.cgi?id=144369 |
| |
| LValue branchOffset = vmCall( |
| Int32, m_out.operation(operationSwitchStringAndGetBranchOffset), |
| m_callFrame, m_out.constIntPtr(data->switchTableIndex), string); |
| |
| StringJumpTable& table = codeBlock()->stringSwitchJumpTable(data->switchTableIndex); |
| |
| Vector<SwitchCase> cases; |
| // These may be negative, or zero, or probably other stuff, too. We don't want to mess with HashSet's corner cases and we don't really care about throughput here. |
| StdUnorderedSet<int32_t> alreadyHandled; |
| for (unsigned i = 0; i < data->cases.size(); ++i) { |
| // FIXME: The fact that we're using the bytecode's switch table means that the |
| // following DFG IR transformation would be invalid. |
| // |
| // Original code: |
| // switch (v) { |
| // case "foo": |
| // case "bar": |
| // things(); |
| // break; |
| // default: |
| // break; |
| // } |
| // |
| // New code: |
| // switch (v) { |
| // case "foo": |
| // instrumentFoo(); |
| // goto _things; |
| // case "bar": |
| // instrumentBar(); |
| // _things: |
| // things(); |
| // break; |
| // default: |
| // break; |
| // } |
| // |
| // Luckily, we don't currently do any such transformation. But it's kind of silly that |
| // this is an issue. |
| // https://bugs.webkit.org/show_bug.cgi?id=144635 |
| |
| DFG::SwitchCase myCase = data->cases[i]; |
| StringJumpTable::StringOffsetTable::iterator iter = |
| table.offsetTable.find(myCase.value.stringImpl()); |
| DFG_ASSERT(m_graph, m_node, iter != table.offsetTable.end()); |
| |
| if (!alreadyHandled.insert(iter->value.branchOffset).second) |
| continue; |
| |
| cases.append(SwitchCase( |
| m_out.constInt32(iter->value.branchOffset), |
| lowBlock(myCase.target.block), Weight(myCase.target.count))); |
| } |
| |
| m_out.switchInstruction( |
| branchOffset, cases, lowBlock(data->fallThrough.block), |
| Weight(data->fallThrough.count)); |
| } |
| |
| // Calls the functor at the point of code generation where we know what the result type is. |
| // You can emit whatever code you like at that point. Expects you to terminate the basic block. |
| // When buildTypeOf() returns, it will have terminated all basic blocks that it created. So, if |
| // you aren't using this as the terminator of a high-level block, you should create your own |
| // contination and set it as the nextBlock (m_out.insertNewBlocksBefore(continuation)) before |
| // calling this. For example: |
| // |
| // LBasicBlock continuation = m_out.newBlock(); |
| // LBasicBlock lastNext = m_out.insertNewBlocksBefore(continuation); |
| // buildTypeOf( |
| // child, value, |
| // [&] (TypeofType type) { |
| // do things; |
| // m_out.jump(continuation); |
| // }); |
| // m_out.appendTo(continuation, lastNext); |
| template<typename Functor> |
| void buildTypeOf(Edge child, LValue value, const Functor& functor) |
| { |
| JSGlobalObject* globalObject = m_graph.globalObjectFor(m_node->origin.semantic); |
| |
| // Implements the following branching structure: |
| // |
| // if (is cell) { |
| // if (is object) { |
| // if (is function) { |
| // return function; |
| // } else if (doesn't have call trap and doesn't masquerade as undefined) { |
| // return object |
| // } else { |
| // return slowPath(); |
| // } |
| // } else if (is string) { |
| // return string |
| // } else { |
| // return symbol |
| // } |
| // } else if (is number) { |
| // return number |
| // } else if (is null) { |
| // return object |
| // } else if (is boolean) { |
| // return boolean |
| // } else { |
| // return undefined |
| // } |
| |
| LBasicBlock cellCase = m_out.newBlock(); |
| LBasicBlock objectCase = m_out.newBlock(); |
| LBasicBlock functionCase = m_out.newBlock(); |
| LBasicBlock notFunctionCase = m_out.newBlock(); |
| LBasicBlock reallyObjectCase = m_out.newBlock(); |
| LBasicBlock slowPath = m_out.newBlock(); |
| LBasicBlock unreachable = m_out.newBlock(); |
| LBasicBlock notObjectCase = m_out.newBlock(); |
| LBasicBlock stringCase = m_out.newBlock(); |
| LBasicBlock symbolCase = m_out.newBlock(); |
| LBasicBlock notCellCase = m_out.newBlock(); |
| LBasicBlock numberCase = m_out.newBlock(); |
| LBasicBlock notNumberCase = m_out.newBlock(); |
| LBasicBlock notNullCase = m_out.newBlock(); |
| LBasicBlock booleanCase = m_out.newBlock(); |
| LBasicBlock undefinedCase = m_out.newBlock(); |
| |
| m_out.branch(isCell(value, provenType(child)), unsure(cellCase), unsure(notCellCase)); |
| |
| LBasicBlock lastNext = m_out.appendTo(cellCase, objectCase); |
| m_out.branch(isObject(value, provenType(child)), unsure(objectCase), unsure(notObjectCase)); |
| |
| m_out.appendTo(objectCase, functionCase); |
| m_out.branch( |
| isFunction(value, provenType(child) & SpecObject), |
| unsure(functionCase), unsure(notFunctionCase)); |
| |
| m_out.appendTo(functionCase, notFunctionCase); |
| functor(TypeofType::Function); |
| |
| m_out.appendTo(notFunctionCase, reallyObjectCase); |
| m_out.branch( |
| isExoticForTypeof(value, provenType(child) & (SpecObject - SpecFunction)), |
| rarely(slowPath), usually(reallyObjectCase)); |
| |
| m_out.appendTo(reallyObjectCase, slowPath); |
| functor(TypeofType::Object); |
| |
| m_out.appendTo(slowPath, unreachable); |
| VM& vm = this->vm(); |
| LValue result = lazySlowPath( |
| [=, &vm] (const Vector<Location>& locations) -> RefPtr<LazySlowPath::Generator> { |
| return createLazyCallGenerator(vm, |
| operationTypeOfObjectAsTypeofType, locations[0].directGPR(), |
| CCallHelpers::TrustedImmPtr(globalObject), locations[1].directGPR()); |
| }, value); |
| Vector<SwitchCase, 3> cases; |
| cases.append(SwitchCase(m_out.constInt32(static_cast<int32_t>(TypeofType::Undefined)), undefinedCase)); |
| cases.append(SwitchCase(m_out.constInt32(static_cast<int32_t>(TypeofType::Object)), reallyObjectCase)); |
| cases.append(SwitchCase(m_out.constInt32(static_cast<int32_t>(TypeofType::Function)), functionCase)); |
| m_out.switchInstruction(m_out.castToInt32(result), cases, unreachable, Weight()); |
| |
| m_out.appendTo(unreachable, notObjectCase); |
| m_out.unreachable(); |
| |
| m_out.appendTo(notObjectCase, stringCase); |
| m_out.branch( |
| isString(value, provenType(child) & (SpecCell - SpecObject)), |
| unsure(stringCase), unsure(symbolCase)); |
| |
| m_out.appendTo(stringCase, symbolCase); |
| functor(TypeofType::String); |
| |
| m_out.appendTo(symbolCase, notCellCase); |
| functor(TypeofType::Symbol); |
| |
| m_out.appendTo(notCellCase, numberCase); |
| m_out.branch( |
| isNumber(value, provenType(child) & ~SpecCell), |
| unsure(numberCase), unsure(notNumberCase)); |
| |
| m_out.appendTo(numberCase, notNumberCase); |
| functor(TypeofType::Number); |
| |
| m_out.appendTo(notNumberCase, notNullCase); |
| LValue isNull; |
| if (provenType(child) & SpecOther) |
| isNull = m_out.equal(value, m_out.constInt64(ValueNull)); |
| else |
| isNull = m_out.booleanFalse; |
| m_out.branch(isNull, unsure(reallyObjectCase), unsure(notNullCase)); |
| |
| m_out.appendTo(notNullCase, booleanCase); |
| m_out.branch( |
| isBoolean(value, provenType(child) & ~(SpecCell | SpecFullNumber)), |
| unsure(booleanCase), unsure(undefinedCase)); |
| |
| m_out.appendTo(booleanCase, undefinedCase); |
| functor(TypeofType::Boolean); |
| |
| m_out.appendTo(undefinedCase, lastNext); |
| functor(TypeofType::Undefined); |
| } |
| |
| TypedPointer pointerIntoTypedArray(LValue storage, LValue index, TypedArrayType type) |
| { |
| LValue offset = m_out.shl(m_out.zeroExtPtr(index), m_out.constIntPtr(logElementSize(type))); |
| |
| return TypedPointer( |
| m_heaps.typedArrayProperties, |
| m_out.add( |
| storage, |
| offset |
| )); |
| } |
| |
| LValue loadFromIntTypedArray(TypedPointer pointer, TypedArrayType type) |
| { |
| switch (elementSize(type)) { |
| case 1: |
| return isSigned(type) ? m_out.load8SignExt32(pointer) : m_out.load8ZeroExt32(pointer); |
| case 2: |
| return isSigned(type) ? m_out.load16SignExt32(pointer) : m_out.load16ZeroExt32(pointer); |
| case 4: |
| return m_out.load32(pointer); |
| default: |
| DFG_CRASH(m_graph, m_node, "Bad element size"); |
| } |
| } |
| |
| Output::StoreType storeType(TypedArrayType type) |
| { |
| if (isInt(type)) { |
| switch (elementSize(type)) { |
| case 1: |
| return Output::Store32As8; |
| case 2: |
| return Output::Store32As16; |
| case 4: |
| return Output::Store32; |
| default: |
| DFG_CRASH(m_graph, m_node, "Bad element size"); |
| return Output::Store32; |
| } |
| } |
| switch (type) { |
| case TypeFloat32: |
| return Output::StoreFloat; |
| case TypeFloat64: |
| return Output::StoreDouble; |
| default: |
| DFG_CRASH(m_graph, m_node, "Bad typed array type"); |
| } |
| } |
| |
| void setIntTypedArrayLoadResult(LValue result, TypedArrayType type, bool canSpeculate = false) |
| { |
| if (elementSize(type) < 4 || isSigned(type)) { |
| setInt32(result); |
| return; |
| } |
| |
| if (m_node->shouldSpeculateInt32() && canSpeculate) { |
| speculate( |
| Overflow, noValue(), 0, m_out.lessThan(result, m_out.int32Zero)); |
| setInt32(result); |
| return; |
| } |
| |
| if (m_node->shouldSpeculateAnyInt()) { |
| setStrictInt52(m_out.zeroExt(result, Int64)); |
| return; |
| } |
| |
| setDouble(m_out.unsignedToDouble(result)); |
| } |
| |
| LValue getIntTypedArrayStoreOperand(Edge edge, bool isClamped = false) |
| { |
| LValue intValue; |
| switch (edge.useKind()) { |
| case Int52RepUse: |
| case Int32Use: { |
| if (edge.useKind() == Int32Use) |
| intValue = lowInt32(edge); |
| else |
| intValue = m_out.castToInt32(lowStrictInt52(edge)); |
| |
| if (isClamped) { |
| LBasicBlock atLeastZero = m_out.newBlock(); |
| LBasicBlock continuation = m_out.newBlock(); |
| |
| Vector<ValueFromBlock, 2> intValues; |
| intValues.append(m_out.anchor(m_out.int32Zero)); |
| m_out.branch( |
| m_out.lessThan(intValue, m_out.int32Zero), |
| unsure(continuation), unsure(atLeastZero)); |
| |
| LBasicBlock lastNext = m_out.appendTo(atLeastZero, continuation); |
| |
| intValues.append(m_out.anchor(m_out.select( |
| m_out.greaterThan(intValue, m_out.constInt32(255)), |
| m_out.constInt32(255), |
| intValue))); |
| m_out.jump(continuation); |
| |
| m_out.appendTo(continuation, lastNext); |
| intValue = m_out.phi(Int32, intValues); |
| } |
| break; |
| } |
| |
| case DoubleRepUse: { |
| LValue doubleValue = lowDouble(edge); |
| |
| if (isClamped) { |
| LBasicBlock atLeastZero = m_out.newBlock(); |
| LBasicBlock withinRange = m_out.newBlock(); |
| LBasicBlock continuation = m_out.newBlock(); |
| |
| Vector<ValueFromBlock, 3> intValues; |
| intValues.append(m_out.anchor(m_out.int32Zero)); |
| m_out.branch( |
| m_out.doubleLessThanOrUnordered(doubleValue, m_out.doubleZero), |
| unsure(continuation), unsure(atLeastZero)); |
| |
| LBasicBlock lastNext = m_out.appendTo(atLeastZero, withinRange); |
| intValues.append(m_out.anchor(m_out.constInt32(255))); |
| m_out.branch( |
| m_out.doubleGreaterThan(doubleValue, m_out.constDouble(255)), |
| unsure(continuation), unsure(withinRange)); |
| |
| m_out.appendTo(withinRange, continuation); |
| intValues.append(m_out.anchor(m_out.doubleToInt(doubleValue))); |
| m_out.jump(continuation); |
| |
| m_out.appendTo(continuation, lastNext); |
| intValue = m_out.phi(Int32, intValues); |
| } else |
| intValue = doubleToInt32(doubleValue); |
| break; |
| } |
| |
| default: |
| DFG_CRASH(m_graph, m_node, "Bad use kind"); |
| } |
| |
| return intValue; |
| } |
| |
| LValue doubleToInt32(LValue doubleValue, double low, double high, bool isSigned = true) |
| { |
| LBasicBlock greatEnough = m_out.newBlock(); |
| LBasicBlock withinRange = m_out.newBlock(); |
| LBasicBlock slowPath = m_out.newBlock(); |
| LBasicBlock continuation = m_out.newBlock(); |
| |
| Vector<ValueFromBlock, 2> results; |
| |
| m_out.branch( |
| m_out.doubleGreaterThanOrEqual(doubleValue, m_out.constDouble(low)), |
| unsure(greatEnough), unsure(slowPath)); |
| |
| LBasicBlock lastNext = m_out.appendTo(greatEnough, withinRange); |
| m_out.branch( |
| m_out.doubleLessThanOrEqual(doubleValue, m_out.constDouble(high)), |
| unsure(withinRange), unsure(slowPath)); |
| |
| m_out.appendTo(withinRange, slowPath); |
| LValue fastResult; |
| if (isSigned) |
| fastResult = m_out.doubleToInt(doubleValue); |
| else |
| fastResult = m_out.doubleToUInt(doubleValue); |
| results.append(m_out.anchor(fastResult)); |
| m_out.jump(continuation); |
| |
| m_out.appendTo(slowPath, continuation); |
| results.append(m_out.anchor(m_out.call(Int32, m_out.operation(operationToInt32), doubleValue))); |
| m_out.jump(continuation); |
| |
| m_out.appendTo(continuation, lastNext); |
| return m_out.phi(Int32, results); |
| } |
| |
| LValue doubleToInt32(LValue doubleValue) |
| { |
| if (hasSensibleDoubleToInt()) |
| return sensibleDoubleToInt32(doubleValue); |
| |
| double limit = pow(2, 31) - 1; |
| return doubleToInt32(doubleValue, -limit, limit); |
| } |
| |
| LValue sensibleDoubleToInt32(LValue doubleValue) |
| { |
| LBasicBlock slowPath = m_out.newBlock(); |
| LBasicBlock continuation = m_out.newBlock(); |
| |
| LValue fastResultValue = m_out.doubleToInt(doubleValue); |
| ValueFromBlock fastResult = m_out.anchor(fastResultValue); |
| m_out.branch( |
| m_out.equal(fastResultValue, m_out.constInt32(0x80000000)), |
| rarely(slowPath), usually(continuation)); |
| |
| LBasicBlock lastNext = m_out.appendTo(slowPath, continuation); |
| ValueFromBlock slowResult = m_out.anchor( |
| m_out.call(Int32, m_out.operation(operationToInt32SensibleSlow), doubleValue)); |
| m_out.jump(continuation); |
| |
| m_out.appendTo(continuation, lastNext); |
| return m_out.phi(Int32, fastResult, slowResult); |
| } |
| |
| // This is a mechanism for creating a code generator that fills in a gap in the code using our |
| // own MacroAssembler. This is useful for slow paths that involve a lot of code and we don't want |
| // to pay the price of B3 optimizing it. A lazy slow path will only be generated if it actually |
| // executes. On the other hand, a lazy slow path always incurs the cost of two additional jumps. |
| // Also, the lazy slow path's register allocation state is slaved to whatever B3 did, so you |
| // have to use a ScratchRegisterAllocator to try to use some unused registers and you may have |
| // to spill to top of stack if there aren't enough registers available. |
| // |
| // Lazy slow paths involve three different stages of execution. Each stage has unique |
| // capabilities and knowledge. The stages are: |
| // |
| // 1) DFG->B3 lowering, i.e. code that runs in this phase. Lowering is the last time you will |
| // have access to LValues. If there is an LValue that needs to be fed as input to a lazy slow |
| // path, then you must pass it as an argument here (as one of the varargs arguments after the |
| // functor). But, lowering doesn't know which registers will be used for those LValues. Hence |
| // you pass a lambda to lazySlowPath() and that lambda will run during stage (2): |
| // |
| // 2) FTLCompile.cpp's fixFunctionBasedOnStackMaps. This code is the only stage at which we know |
| // the mapping from arguments passed to this method in (1) and the registers that B3 |
| // selected for those arguments. You don't actually want to generate any code here, since then |
| // the slow path wouldn't actually be lazily generated. Instead, you want to save the |
| // registers being used for the arguments and defer code generation to stage (3) by creating |
| // and returning a LazySlowPath::Generator: |
| // |
| // 3) LazySlowPath's generate() method. This code runs in response to the lazy slow path |
| // executing for the first time. It will call the generator you created in stage (2). |
| // |
| // Note that each time you invoke stage (1), stage (2) may be invoked zero, one, or many times. |
| // Stage (2) will usually be invoked once for stage (1). But, B3 may kill the code, in which |
| // case stage (2) won't run. B3 may duplicate the code (for example via tail duplication), |
| // leading to many calls to your stage (2) lambda. Stage (3) may be called zero or once for each |
| // stage (2). It will be called zero times if the slow path never runs. This is what you hope for |
| // whenever you use the lazySlowPath() mechanism. |
| // |
| // A typical use of lazySlowPath() will look like the example below, which just creates a slow |
| // path that adds some value to the input and returns it. |
| // |
| // // Stage (1) is here. This is your last chance to figure out which LValues to use as inputs. |
| // // Notice how we pass "input" as an argument to lazySlowPath(). |
| // LValue input = ...; |
| // int addend = ...; |
| // LValue output = lazySlowPath( |
| // [=] (const Vector<Location>& locations) -> RefPtr<LazySlowPath::Generator> { |
| // // Stage (2) is here. This is your last chance to figure out which registers are used |
| // // for which values. Location zero is always the return value. You can ignore it if |
| // // you don't want to return anything. Location 1 is the register for the first |
| // // argument to the lazySlowPath(), i.e. "input". Note that the Location object could |
| // // also hold an FPR, if you are passing a double. |
| // GPRReg outputGPR = locations[0].directGPR(); |
| // GPRReg inputGPR = locations[1].directGPR(); |
| // return LazySlowPath::createGenerator( |
| // [=] (CCallHelpers& jit, LazySlowPath::GenerationParams& params) { |
| // // Stage (3) is here. This is when you generate code. You have access to the |
| // // registers you collected in stage (2) because this lambda closes over those |
| // // variables (outputGPR and inputGPR). You also have access to whatever extra |
| // // data you collected in stage (1), such as the addend in this case. |
| // jit.add32(TrustedImm32(addend), inputGPR, outputGPR); |
| // // You have to end by jumping to done. There is nothing to fall through to. |
| // // You can also jump to the exception handler (see LazySlowPath.h for more |
| // // info). Note that currently you cannot OSR exit. |
| // params.doneJumps.append(jit.jump()); |
| // }); |
| // }, |
| // input); |
| // |
| // You can basically pass as many inputs as you like, either using this varargs form, or by |
| // passing a Vector of LValues. |
| // |
| // Note that if your slow path is only doing a call, you can use the createLazyCallGenerator() |
| // helper. For example: |
| // |
| // LValue input = ...; |
| // LValue output = lazySlowPath( |
| // [=] (const Vector<Location>& locations) -> RefPtr<LazySlowPath::Generator> { |
| // return createLazyCallGenerator( |
| // operationDoThings, locations[0].directGPR(), locations[1].directGPR()); |
| // }, input); |
| // |
| // Finally, note that all of the lambdas - both the stage (2) lambda and the stage (3) lambda - |
| // run after the function that created them returns. Hence, you should not use by-reference |
| // capture (i.e. [&]) in any of these lambdas. |
| template<typename Functor, typename... ArgumentTypes> |
| PatchpointValue* lazySlowPath(const Functor& functor, ArgumentTypes... arguments) |
| { |
| return lazySlowPath(functor, Vector<LValue>{ arguments... }); |
| } |
| |
| template<typename Functor> |
| PatchpointValue* lazySlowPath(const Functor& functor, const Vector<LValue>& userArguments) |
| { |
| CodeOrigin origin = m_node->origin.semantic; |
| |
| PatchpointValue* result = m_out.patchpoint(B3::Int64); |
| for (LValue arg : userArguments) |
| result->append(ConstrainedValue(arg, B3::ValueRep::SomeRegister)); |
| |
| RefPtr<PatchpointExceptionHandle> exceptionHandle = |
| preparePatchpointForExceptions(result); |
| |
| result->clobber(RegisterSet::macroScratchRegisters()); |
| State* state = &m_ftlState; |
| |
| result->setGenerator( |
| [=] (CCallHelpers& jit, const StackmapGenerationParams& params) { |
| Vector<Location> locations; |
| for (const B3::ValueRep& rep : params) |
| locations.append(Location::forValueRep(rep)); |
| |
| RefPtr<LazySlowPath::Generator> generator = functor(locations); |
| |
| CCallHelpers::PatchableJump patchableJump = jit.patchableJump(); |
| CCallHelpers::Label done = jit.label(); |
| |
| RegisterSet usedRegisters = params.unavailableRegisters(); |
| |
| RefPtr<ExceptionTarget> exceptionTarget = |
| exceptionHandle->scheduleExitCreation(params); |
| |
| // FIXME: As part of handling exceptions, we need to create a concrete OSRExit here. |
| // Doing so should automagically register late paths that emit exit thunks. |
| |
| params.addLatePath( |
| [=] (CCallHelpers& jit) { |
| AllowMacroScratchRegisterUsage allowScratch(jit); |
| patchableJump.m_jump.link(&jit); |
| unsigned index = state->jitCode->lazySlowPaths.size(); |
| state->jitCode->lazySlowPaths.append(nullptr); |
| jit.pushToSaveImmediateWithoutTouchingRegisters( |
| CCallHelpers::TrustedImm32(index)); |
| CCallHelpers::Jump generatorJump = jit.jump(); |
| |
| // Note that so long as we're here, we don't really know if our late path |
| // runs before or after any other late paths that we might depend on, like |
| // the exception thunk. |
| |
| RefPtr<JITCode> jitCode = state->jitCode; |
| VM* vm = &state->graph.m_vm; |
| |
| jit.addLinkTask( |
| [=] (LinkBuffer& linkBuffer) { |
| linkBuffer.link(generatorJump, |
| CodeLocationLabel<JITThunkPtrTag>(vm->getCTIStub(lazySlowPathGenerationThunkGenerator).code())); |
| |
| std::unique_ptr<LazySlowPath> lazySlowPath = std::make_unique<LazySlowPath>(); |
| |
| auto linkedPatchableJump = CodeLocationJump<JSInternalPtrTag>(linkBuffer.locationOf<JSInternalPtrTag>(patchableJump)); |
| |
| CodeLocationLabel<JSInternalPtrTag> linkedDone = linkBuffer.locationOf<JSInternalPtrTag>(done); |
| |
| CallSiteIndex callSiteIndex = |
| jitCode->common.addUniqueCallSiteIndex(origin); |
| |
| lazySlowPath->initialize( |
| linkedPatchableJump, linkedDone, |
| exceptionTarget->label(linkBuffer), usedRegisters, |
| callSiteIndex, generator); |
| |
| jitCode->lazySlowPaths[index] = WTFMove(lazySlowPath); |
| }); |
| }); |
| }); |
| return result; |
| } |
| |
| void speculate( |
| ExitKind kind, FormattedValue lowValue, Node* highValue, LValue failCondition) |
| { |
| appendOSRExit(kind, lowValue, highValue, failCondition, m_origin); |
| } |
| |
| void speculate( |
| ExitKind kind, FormattedValue lowValue, const MethodOfGettingAValueProfile& profile, LValue failCondition) |
| { |
| appendOSRExit(kind, lowValue, profile, failCondition, m_origin); |
| } |
| |
| void terminate(ExitKind kind) |
| { |
| speculate(kind, noValue(), nullptr, m_out.booleanTrue); |
| didAlreadyTerminate(); |
| } |
| |
| void didAlreadyTerminate() |
| { |
| m_state.setIsValid(false); |
| } |
| |
| void typeCheck( |
| FormattedValue lowValue, Edge highValue, SpeculatedType typesPassedThrough, |
| LValue failCondition, ExitKind exitKind = BadType) |
| { |
| appendTypeCheck(lowValue, highValue, typesPassedThrough, failCondition, exitKind); |
| } |
| |
| void appendTypeCheck( |
| FormattedValue lowValue, Edge highValue, SpeculatedType typesPassedThrough, |
| LValue failCondition, ExitKind exitKind) |
| { |
| if (!m_interpreter.needsTypeCheck(highValue, typesPassedThrough)) |
| return; |
| ASSERT(mayHaveTypeCheck(highValue.useKind())); |
| appendOSRExit(exitKind, lowValue, highValue.node(), failCondition, m_origin); |
| m_interpreter.filter(highValue, typesPassedThrough); |
| } |
| |
| LValue lowInt32(Edge edge, OperandSpeculationMode mode = AutomaticOperandSpeculation) |
| { |
| ASSERT_UNUSED(mode, mode == ManualOperandSpeculation || (edge.useKind() == Int32Use || edge.useKind() == KnownInt32Use)); |
| |
| if (edge->hasConstant()) { |
| JSValue value = edge->asJSValue(); |
| if (!value.isInt32()) { |
| if (mayHaveTypeCheck(edge.useKind())) |
| terminate(Uncountable); |
| return m_out.int32Zero; |
| } |
| LValue result = m_out.constInt32(value.asInt32()); |
| result->setOrigin(B3::Origin(edge.node())); |
| return result; |
| } |
| |
| LoweredNodeValue value = m_int32Values.get(edge.node()); |
| if (isValid(value)) |
| return value.value(); |
| |
| value = m_strictInt52Values.get(edge.node()); |
| if (isValid(value)) |
| return strictInt52ToInt32(edge, value.value()); |
| |
| value = m_int52Values.get(edge.node()); |
| if (isValid(value)) |
| return strictInt52ToInt32(edge, int52ToStrictInt52(value.value())); |
| |
| value = m_jsValueValues.get(edge.node()); |
| if (isValid(value)) { |
| LValue boxedResult = value.value(); |
| FTL_TYPE_CHECK( |
| jsValueValue(boxedResult), edge, SpecInt32Only, isNotInt32(boxedResult)); |
| LValue result = unboxInt32(boxedResult); |
| setInt32(edge.node(), result); |
| return result; |
| } |
| |
| DFG_ASSERT(m_graph, m_node, !(provenType(edge) & SpecInt32Only), provenType(edge)); |
| if (mayHaveTypeCheck(edge.useKind())) |
| terminate(Uncountable); |
| return m_out.int32Zero; |
| } |
| |
| enum Int52Kind { StrictInt52, Int52 }; |
| LValue lowInt52(Edge edge, Int52Kind kind) |
| { |
| DFG_ASSERT(m_graph, m_node, edge.useKind() == Int52RepUse, edge.useKind()); |
| |
| LoweredNodeValue value; |
| |
| switch (kind) { |
| case Int52: |
| value = m_int52Values.get(edge.node()); |
| if (isValid(value)) |
| return value.value(); |
| |
| value = m_strictInt52Values.get(edge.node()); |
| if (isValid(value)) |
| return strictInt52ToInt52(value.value()); |
| break; |
| |
| case StrictInt52: |
| value = m_strictInt52Values.get(edge.node()); |
| if (isValid(value)) |
| return value.value(); |
| |
| value = m_int52Values.get(edge.node()); |
| if (isValid(value)) |
| return int52ToStrictInt52(value.value()); |
| break; |
| } |
| |
| DFG_ASSERT(m_graph, m_node, !provenType(edge), provenType(edge)); |
| if (mayHaveTypeCheck(edge.useKind())) |
| terminate(Uncountable); |
| return m_out.int64Zero; |
| } |
| |
| LValue lowInt52(Edge edge) |
| { |
| return lowInt52(edge, Int52); |
| } |
| |
| LValue lowStrictInt52(Edge edge) |
| { |
| return lowInt52(edge, StrictInt52); |
| } |
| |
| bool betterUseStrictInt52(Node* node) |
| { |
| return !isValid(m_int52Values.get(node)); |
| } |
| bool betterUseStrictInt52(Edge edge) |
| { |
| return betterUseStrictInt52(edge.node()); |
| } |
| template<typename T> |
| Int52Kind bestInt52Kind(T node) |
| { |
| return betterUseStrictInt52(node) ? StrictInt52 : Int52; |
| } |
| Int52Kind opposite(Int52Kind kind) |
| { |
| switch (kind) { |
| case Int52: |
| return StrictInt52; |
| case StrictInt52: |
| return Int52; |
| } |
| DFG_CRASH(m_graph, m_node, "Bad use kind"); |
| return Int52; |
| } |
| |
| LValue lowWhicheverInt52(Edge edge, Int52Kind& kind) |
| { |
| kind = bestInt52Kind(edge); |
| return lowInt52(edge, kind); |
| } |
| |
| LValue lowCell(Edge edge, OperandSpeculationMode mode = AutomaticOperandSpeculation) |
| { |
| DFG_ASSERT(m_graph, m_node, mode == ManualOperandSpeculation || DFG::isCell(edge.useKind()), edge.useKind()); |
| |
| if (edge->op() == JSConstant) { |
| FrozenValue* value = edge->constant(); |
| if (!value->value().isCell()) { |
| if (mayHaveTypeCheck(edge.useKind())) |
| terminate(Uncountable); |
| return m_out.intPtrZero; |
| } |
| LValue result = frozenPointer(value); |
| result->setOrigin(B3::Origin(edge.node())); |
| return result; |
| } |
| |
| LoweredNodeValue value = m_jsValueValues.get(edge.node()); |
| if (isValid(value)) { |
| LValue uncheckedValue = value.value(); |
| FTL_TYPE_CHECK( |
| jsValueValue(uncheckedValue), edge, SpecCellCheck, isNotCell(uncheckedValue)); |
| return uncheckedValue; |
| } |
| |
| DFG_ASSERT(m_graph, m_node, !(provenType(edge) & SpecCellCheck), provenType(edge)); |
| if (mayHaveTypeCheck(edge.useKind())) |
| terminate(Uncountable); |
| return m_out.intPtrZero; |
| } |
| |
| LValue lowObject(Edge edge, OperandSpeculationMode mode = AutomaticOperandSpeculation) |
| { |
| ASSERT_UNUSED(mode, mode == ManualOperandSpeculation || edge.useKind() == ObjectUse); |
| |
| LValue result = lowCell(edge, mode); |
| speculateObject(edge, result); |
| return result; |
| } |
| |
| LValue lowRegExpObject(Edge edge) |
| { |
| LValue result = lowCell(edge); |
| speculateRegExpObject(edge, result); |
| return result; |
| } |
| |
| LValue lowMapObject(Edge edge) |
| { |
| LValue result = lowCell(edge); |
| speculateMapObject(edge, result); |
| return result; |
| } |
| |
| LValue lowSetObject(Edge edge) |
| { |
| LValue result = lowCell(edge); |
| speculateSetObject(edge, result); |
| return result; |
| } |
| |
| LValue lowWeakMapObject(Edge edge) |
| { |
| LValue result = lowCell(edge); |
| speculateWeakMapObject(edge, result); |
| return result; |
| } |
| |
| LValue lowWeakSetObject(Edge edge) |
| { |
| LValue result = lowCell(edge); |
| speculateWeakSetObject(edge, result); |
| return result; |
| } |
| |
| LValue lowString(Edge edge, OperandSpeculationMode mode = AutomaticOperandSpeculation) |
| { |
| ASSERT_UNUSED(mode, mode == ManualOperandSpeculation || edge.useKind() == StringUse || edge.useKind() == KnownStringUse || edge.useKind() == StringIdentUse); |
| |
| LValue result = lowCell(edge, mode); |
| speculateString(edge, result); |
| return result; |
| } |
| |
| LValue lowStringIdent(Edge edge, OperandSpeculationMode mode = AutomaticOperandSpeculation) |
| { |
| ASSERT_UNUSED(mode, mode == ManualOperandSpeculation || edge.useKind() == StringIdentUse); |
| |
| LValue string = lowString(edge, mode); |
| LValue stringImpl = m_out.loadPtr(string, m_heaps.JSString_value); |
| speculateStringIdent(edge, string, stringImpl); |
| return stringImpl; |
| } |
| |
| LValue lowSymbol(Edge edge, OperandSpeculationMode mode = AutomaticOperandSpeculation) |
| { |
| ASSERT_UNUSED(mode, mode == ManualOperandSpeculation || edge.useKind() == SymbolUse); |
| |
| LValue result = lowCell(edge, mode); |
| speculateSymbol(edge, result); |
| return result; |
| } |
| |
| LValue lowBigInt(Edge edge, OperandSpeculationMode mode = AutomaticOperandSpeculation) |
| { |
| ASSERT_UNUSED(mode, mode == ManualOperandSpeculation || edge.useKind() == BigIntUse); |
| |
| LValue result = lowCell(edge, mode); |
| speculateBigInt(edge, result); |
| return result; |
| } |
| |
| LValue lowNonNullObject(Edge edge, OperandSpeculationMode mode = AutomaticOperandSpeculation) |
| { |
| ASSERT_UNUSED(mode, mode == ManualOperandSpeculation || edge.useKind() == ObjectUse); |
| |
| LValue result = lowCell(edge, mode); |
| speculateNonNullObject(edge, result); |
| return result; |
| } |
| |
| LValue lowBoolean(Edge edge, OperandSpeculationMode mode = AutomaticOperandSpeculation) |
| { |
| ASSERT_UNUSED(mode, mode == ManualOperandSpeculation || edge.useKind() == BooleanUse || edge.useKind() == KnownBooleanUse); |
| |
| if (edge->hasConstant()) { |
| JSValue value = edge->asJSValue(); |
| if (!value.isBoolean()) { |
| if (mayHaveTypeCheck(edge.useKind())) |
| terminate(Uncountable); |
| return m_out.booleanFalse; |
| } |
| LValue result = m_out.constBool(value.asBoolean()); |
| result->setOrigin(B3::Origin(edge.node())); |
| return result; |
| } |
| |
| LoweredNodeValue value = m_booleanValues.get(edge.node()); |
| if (isValid(value)) |
| return value.value(); |
| |
| value = m_jsValueValues.get(edge.node()); |
| if (isValid(value)) { |
| LValue unboxedResult = value.value(); |
| FTL_TYPE_CHECK( |
| jsValueValue(unboxedResult), edge, SpecBoolean, isNotBoolean(unboxedResult)); |
| LValue result = unboxBoolean(unboxedResult); |
| setBoolean(edge.node(), result); |
| return result; |
| } |
| |
| DFG_ASSERT(m_graph, m_node, !(provenType(edge) & SpecBoolean), provenType(edge)); |
| if (mayHaveTypeCheck(edge.useKind())) |
| terminate(Uncountable); |
| return m_out.booleanFalse; |
| } |
| |
| LValue lowDouble(Edge edge) |
| { |
| DFG_ASSERT(m_graph, m_node, isDouble(edge.useKind()), edge.useKind()); |
| |
| LoweredNodeValue value = m_doubleValues.get(edge.node()); |
| if (isValid(value)) |
| return value.value(); |
| DFG_ASSERT(m_graph, m_node, !provenType(edge), provenType(edge)); |
| if (mayHaveTypeCheck(edge.useKind())) |
| terminate(Uncountable); |
| return m_out.doubleZero; |
| } |
| |
| LValue lowJSValue(Edge edge, OperandSpeculationMode mode = AutomaticOperandSpeculation) |
| { |
| DFG_ASSERT(m_graph, m_node, mode == ManualOperandSpeculation || edge.useKind() == UntypedUse, m_node->op(), edge.useKind()); |
| DFG_ASSERT(m_graph, m_node, !isDouble(edge.useKind()), m_node->op(), edge.useKind()); |
| DFG_ASSERT(m_graph, m_node, edge.useKind() != Int52RepUse, m_node->op(), edge.useKind()); |
| |
| if (edge->hasConstant()) { |
| LValue result = m_out.constInt64(JSValue::encode(edge->asJSValue())); |
| result->setOrigin(B3::Origin(edge.node())); |
| return result; |
| } |
| |
| LoweredNodeValue value = m_jsValueValues.get(edge.node()); |
| if (isValid(value)) |
| return value.value(); |
| |
| value = m_int32Values.get(edge.node()); |
| if (isValid(value)) { |
| LValue result = boxInt32(value.value()); |
| setJSValue(edge.node(), result); |
| return result; |
| } |
| |
| value = m_booleanValues.get(edge.node()); |
| if (isValid(value)) { |
| LValue result = boxBoolean(value.value()); |
| setJSValue(edge.node(), result); |
| return result; |
| } |
| |
| DFG_CRASH(m_graph, m_node, "Value not defined"); |
| return 0; |
| } |
| |
| LValue lowNotCell(Edge edge) |
| { |
| LValue result = lowJSValue(edge, ManualOperandSpeculation); |
| FTL_TYPE_CHECK(jsValueValue(result), edge, ~SpecCellCheck, isCell(result)); |
| return result; |
| } |
| |
| LValue lowStorage(Edge edge) |
| { |
| LoweredNodeValue value = m_storageValues.get(edge.node()); |
| if (isValid(value)) |
| return value.value(); |
| |
| LValue result = lowCell(edge); |
| setStorage(edge.node(), result); |
| return result; |
| } |
| |
| LValue strictInt52ToInt32(Edge edge, LValue value) |
| { |
| LValue result = m_out.castToInt32(value); |
| FTL_TYPE_CHECK( |
| noValue(), edge, SpecInt32Only, |
| m_out.notEqual(m_out.signExt32To64(result), value)); |
| setInt32(edge.node(), result); |
| return result; |
| } |
| |
| LValue strictInt52ToDouble(LValue value) |
| { |
| return m_out.intToDouble(value); |
| } |
| |
| LValue strictInt52ToJSValue(LValue value) |
| { |
| LBasicBlock isInt32 = m_out.newBlock(); |
| LBasicBlock isDouble = m_out.newBlock(); |
| LBasicBlock continuation = m_out.newBlock(); |
| |
| Vector<ValueFromBlock, 2> results; |
| |
| LValue int32Value = m_out.castToInt32(value); |
| m_out.branch( |
| m_out.equal(m_out.signExt32To64(int32Value), value), |
| unsure(isInt32), unsure(isDouble)); |
| |
| LBasicBlock lastNext = m_out.appendTo(isInt32, isDouble); |
| |
| results.append(m_out.anchor(boxInt32(int32Value))); |
| m_out.jump(continuation); |
| |
| m_out.appendTo(isDouble, continuation); |
| |
| results.append(m_out.anchor(boxDouble(m_out.intToDouble(value)))); |
| m_out.jump(continuation); |
| |
| m_out.appendTo(continuation, lastNext); |
| return m_out.phi(Int64, results); |
| } |
| |
| LValue strictInt52ToInt52(LValue value) |
| { |
| return m_out.shl(value, m_out.constInt64(JSValue::int52ShiftAmount)); |
| } |
| |
| LValue int52ToStrictInt52(LValue value) |
| { |
| return m_out.aShr(value, m_out.constInt64(JSValue::int52ShiftAmount)); |
| } |
| |
| LValue isInt32(LValue jsValue, SpeculatedType type = SpecFullTop) |
| { |
| if (LValue proven = isProvenValue(type, SpecInt32Only)) |
| return proven; |
| return m_out.aboveOrEqual(jsValue, m_tagTypeNumber); |
| } |
| LValue isNotInt32(LValue jsValue, SpeculatedType type = SpecFullTop) |
| { |
| if (LValue proven = isProvenValue(type, ~SpecInt32Only)) |
| return proven; |
| return m_out.below(jsValue, m_tagTypeNumber); |
| } |
| LValue unboxInt32(LValue jsValue) |
| { |
| return m_out.castToInt32(jsValue); |
| } |
| LValue boxInt32(LValue value) |
| { |
| return m_out.add(m_out.zeroExt(value, Int64), m_tagTypeNumber); |
| } |
| |
| LValue isCellOrMisc(LValue jsValue, SpeculatedType type = SpecFullTop) |
| { |
| if (LValue proven = isProvenValue(type, SpecCellCheck | SpecMisc)) |
| return proven; |
| return m_out.testIsZero64(jsValue, m_tagTypeNumber); |
| } |
| LValue isNotCellOrMisc(LValue jsValue, SpeculatedType type = SpecFullTop) |
| { |
| if (LValue proven = isProvenValue(type, ~(SpecCellCheck | SpecMisc))) |
| return proven; |
| return m_out.testNonZero64(jsValue, m_tagTypeNumber); |
| } |
| |
| LValue unboxDouble(LValue jsValue, LValue* unboxedAsInt = nullptr) |
| { |
| LValue asInt = m_out.add(jsValue, m_tagTypeNumber); |
| if (unboxedAsInt) |
| *unboxedAsInt = asInt; |
| return m_out.bitCast(asInt, Double); |
| } |
| LValue boxDouble(LValue doubleValue) |
| { |
| return m_out.sub(m_out.bitCast(doubleValue, Int64), m_tagTypeNumber); |
| } |
| |
| LValue jsValueToStrictInt52(Edge edge, LValue boxedValue) |
| { |
| LBasicBlock intCase = m_out.newBlock(); |
| LBasicBlock doubleCase = m_out.newBlock(); |
| LBasicBlock continuation = m_out.newBlock(); |
| |
| LValue isNotInt32; |
| if (!m_interpreter.needsTypeCheck(edge, SpecInt32Only)) |
| isNotInt32 = m_out.booleanFalse; |
| else if (!m_interpreter.needsTypeCheck(edge, ~SpecInt32Only)) |
| isNotInt32 = m_out.booleanTrue; |
| else |
| isNotInt32 = this->isNotInt32(boxedValue); |
| m_out.branch(isNotInt32, unsure(doubleCase), unsure(intCase)); |
| |
| LBasicBlock lastNext = m_out.appendTo(intCase, doubleCase); |
| |
| ValueFromBlock intToInt52 = m_out.anchor( |
| m_out.signExt32To64(unboxInt32(boxedValue))); |
| m_out.jump(continuation); |
| |
| m_out.appendTo(doubleCase, continuation); |
| |
| LValue possibleResult = m_out.call( |
| Int64, m_out.operation(operationConvertBoxedDoubleToInt52), boxedValue); |
| FTL_TYPE_CHECK( |
| jsValueValue(boxedValue), edge, SpecInt32Only | SpecAnyIntAsDouble, |
| m_out.equal(possibleResult, m_out.constInt64(JSValue::notInt52))); |
| |
| ValueFromBlock doubleToInt52 = m_out.anchor(possibleResult); |
| m_out.jump(continuation); |
| |
| m_out.appendTo(continuation, lastNext); |
| |
| return m_out.phi(Int64, intToInt52, doubleToInt52); |
| } |
| |
| LValue doubleToStrictInt52(Edge edge, LValue value) |
| { |
| LValue possibleResult = m_out.call( |
| Int64, m_out.operation(operationConvertDoubleToInt52), value); |
| FTL_TYPE_CHECK_WITH_EXIT_KIND(Int52Overflow, |
| doubleValue(value), edge, SpecAnyIntAsDouble, |
| m_out.equal(possibleResult, m_out.constInt64(JSValue::notInt52))); |
| |
| return possibleResult; |
| } |
| |
| LValue convertDoubleToInt32(LValue value, bool shouldCheckNegativeZero) |
| { |
| LValue integerValue = m_out.doubleToInt(value); |
| LValue integerValueConvertedToDouble = m_out.intToDouble(integerValue); |
| LValue valueNotConvertibleToInteger = m_out.doubleNotEqualOrUnordered(value, integerValueConvertedToDouble); |
| speculate(Overflow, FormattedValue(DataFormatDouble, value), m_node, valueNotConvertibleToInteger); |
| |
| if (shouldCheckNegativeZero) { |
| LBasicBlock valueIsZero = m_out.newBlock(); |
| LBasicBlock continuation = m_out.newBlock(); |
| m_out.branch(m_out.isZero32(integerValue), unsure(valueIsZero), unsure(continuation)); |
| |
| LBasicBlock lastNext = m_out.appendTo(valueIsZero, continuation); |
| |
| LValue doubleBitcastToInt64 = m_out.bitCast(value, Int64); |
| LValue signBitSet = m_out.lessThan(doubleBitcastToInt64, m_out.constInt64(0)); |
| |
| speculate(NegativeZero, FormattedValue(DataFormatDouble, value), m_node, signBitSet); |
| m_out.jump(continuation); |
| m_out.appendTo(continuation, lastNext); |
| } |
| return integerValue; |
| } |
| |
| LValue isNumber(LValue jsValue, SpeculatedType type = SpecFullTop) |
| { |
| if (LValue proven = isProvenValue(type, SpecFullNumber)) |
| return proven; |
| return isNotCellOrMisc(jsValue); |
| } |
| LValue isNotNumber(LValue jsValue, SpeculatedType type = SpecFullTop) |
| { |
| if (LValue proven = isProvenValue(type, ~SpecFullNumber)) |
| return proven; |
| return isCellOrMisc(jsValue); |
| } |
| |
| LValue isNotCell(LValue jsValue, SpeculatedType type = SpecFullTop) |
| { |
| if (LValue proven = isProvenValue(type, ~SpecCellCheck)) |
| return proven; |
| return m_out.testNonZero64(jsValue, m_tagMask); |
| } |
| |
| LValue isCell(LValue jsValue, SpeculatedType type = SpecFullTop) |
| { |
| if (LValue proven = isProvenValue(type, SpecCellCheck)) |
| return proven; |
| return m_out.testIsZero64(jsValue, m_tagMask); |
| } |
| |
| LValue isNotMisc(LValue value, SpeculatedType type = SpecFullTop) |
| { |
| if (LValue proven = isProvenValue(type, ~SpecMisc)) |
| return proven; |
| return m_out.above(value, m_out.constInt64(TagBitTypeOther | TagBitBool | TagBitUndefined)); |
| } |
| |
| LValue isMisc(LValue value, SpeculatedType type = SpecFullTop) |
| { |
| if (LValue proven = isProvenValue(type, SpecMisc)) |
| return proven; |
| return m_out.logicalNot(isNotMisc(value)); |
| } |
| |
| LValue isNotBoolean(LValue jsValue, SpeculatedType type = SpecFullTop) |
| { |
| if (LValue proven = isProvenValue(type, ~SpecBoolean)) |
| return proven; |
| return m_out.testNonZero64( |
| m_out.bitXor(jsValue, m_out.constInt64(ValueFalse)), |
| m_out.constInt64(~1)); |
| } |
| LValue isBoolean(LValue jsValue, SpeculatedType type = SpecFullTop) |
| { |
| if (LValue proven = isProvenValue(type, SpecBoolean)) |
| return proven; |
| return m_out.logicalNot(isNotBoolean(jsValue)); |
| } |
| LValue unboxBoolean(LValue jsValue) |
| { |
| // We want to use a cast that guarantees that B3 knows that even the integer |
| // value is just 0 or 1. But for now we do it the dumb way. |
| return m_out.notZero64(m_out.bitAnd(jsValue, m_out.constInt64(1))); |
| } |
| LValue boxBoolean(LValue value) |
| { |
| return m_out.select( |
| value, m_out.constInt64(ValueTrue), m_out.constInt64(ValueFalse)); |
| } |
| |
| LValue isNotOther(LValue value, SpeculatedType type = SpecFullTop) |
| { |
| if (LValue proven = isProvenValue(type, ~SpecOther)) |
| return proven; |
| return m_out.notEqual( |
| m_out.bitAnd(value, m_out.constInt64(~TagBitUndefined)), |
| m_out.constInt64(ValueNull)); |
| } |
| LValue isOther(LValue value, SpeculatedType type = SpecFullTop) |
| { |
| if (LValue proven = isProvenValue(type, SpecOther)) |
| return proven; |
| return m_out.equal( |
| m_out.bitAnd(value, m_out.constInt64(~TagBitUndefined)), |
| m_out.constInt64(ValueNull)); |
| } |
| |
| LValue isProvenValue(SpeculatedType provenType, SpeculatedType wantedType) |
| { |
| if (!(provenType & ~wantedType)) |
| return m_out.booleanTrue; |
| if (!(provenType & wantedType)) |
| return m_out.booleanFalse; |
| return nullptr; |
| } |
| |
| void speculate(Edge edge) |
| { |
| switch (edge.useKind()) { |
| case UntypedUse: |
| break; |
| case KnownInt32Use: |
| case KnownStringUse: |
| case KnownPrimitiveUse: |
| case DoubleRepUse: |
| case Int52RepUse: |
| ASSERT(!m_interpreter.needsTypeCheck(edge)); |
| break; |
| case Int32Use: |
| speculateInt32(edge); |
| break; |
| case CellUse: |
| speculateCell(edge); |
| break; |
| case CellOrOtherUse: |
| speculateCellOrOther(edge); |
| break; |
| case KnownCellUse: |
| ASSERT(!m_interpreter.needsTypeCheck(edge)); |
| break; |
| case AnyIntUse: |
| speculateAnyInt(edge); |
| break; |
| case ObjectUse: |
| speculateObject(edge); |
| break; |
| case ArrayUse: |
| speculateArray(edge); |
| break; |
| case FunctionUse: |
| speculateFunction(edge); |
| break; |
| case ObjectOrOtherUse: |
| speculateObjectOrOther(edge); |
| break; |
| case FinalObjectUse: |
| speculateFinalObject(edge); |
| break; |
| case RegExpObjectUse: |
| speculateRegExpObject(edge); |
| break; |
| case ProxyObjectUse: |
| speculateProxyObject(edge); |
| break; |
| case DerivedArrayUse: |
| speculateDerivedArray(edge); |
| break; |
| case MapObjectUse: |
| speculateMapObject(edge); |
| break; |
| case SetObjectUse: |
| speculateSetObject(edge); |
| break; |
| case WeakMapObjectUse: |
| speculateWeakMapObject(edge); |
| break; |
| case WeakSetObjectUse: |
| speculateWeakSetObject(edge); |
| break; |
| case StringUse: |
| speculateString(edge); |
| break; |
| case StringOrOtherUse: |
| speculateStringOrOther(edge); |
| break; |
| case StringIdentUse: |
| speculateStringIdent(edge); |
| break; |
| case SymbolUse: |
| speculateSymbol(edge); |
| break; |
| case StringObjectUse: |
| speculateStringObject(edge); |
| break; |
| case StringOrStringObjectUse: |
| speculateStringOrStringObject(edge); |
| break; |
| case NumberUse: |
| speculateNumber(edge); |
| break; |
| case RealNumberUse: |
| speculateRealNumber(edge); |
| break; |
| case DoubleRepRealUse: |
| speculateDoubleRepReal(edge); |
| break; |
| case DoubleRepAnyIntUse: |
| speculateDoubleRepAnyInt(edge); |
| break; |
| case BooleanUse: |
| speculateBoolean(edge); |
| break; |
| case BigIntUse: |
| speculateBigInt(edge); |
| break; |
| case NotStringVarUse: |
| speculateNotStringVar(edge); |
| break; |
| case NotSymbolUse: |
| speculateNotSymbol(edge); |
| break; |
| case NotCellUse: |
| speculateNotCell(edge); |
| break; |
| case OtherUse: |
| speculateOther(edge); |
| break; |
| case MiscUse: |
| speculateMisc(edge); |
| break; |
| default: |
| DFG_CRASH(m_graph, m_node, "Unsupported speculation use kind"); |
| } |
| } |
| |
| void speculate(Node*, Edge edge) |
| { |
| speculate(edge); |
| } |
| |
| void speculateInt32(Edge edge) |
| { |
| lowInt32(edge); |
| } |
| |
| void speculateCell(Edge edge) |
| { |
| lowCell(edge); |
| } |
| |
| void speculateNotCell(Edge edge) |
| { |
| if (!m_interpreter.needsTypeCheck(edge)) |
| return; |
| lowNotCell(edge); |
| } |
| |
| void speculateCellOrOther(Edge edge) |
| { |
| if (shouldNotHaveTypeCheck(edge.useKind())) |
| return; |
| |
| LValue value = lowJSValue(edge, ManualOperandSpeculation); |
| |
| LBasicBlock isNotCell = m_out.newBlock(); |
| LBasicBlock continuation = m_out.newBlock(); |
| |
| m_out.branch(isCell(value, provenType(edge)), unsure(continuation), unsure(isNotCell)); |
| |
| LBasicBlock lastNext = m_out.appendTo(isNotCell, continuation); |
| FTL_TYPE_CHECK(jsValueValue(value), edge, SpecCellCheck | SpecOther, isNotOther(value)); |
| m_out.jump(continuation); |
| |
| m_out.appendTo(continuation, lastNext); |
| } |
| |
| void speculateAnyInt(Edge edge) |
| { |
| if (!m_interpreter.needsTypeCheck(edge)) |
| return; |
| |
| jsValueToStrictInt52(edge, lowJSValue(edge, ManualOperandSpeculation)); |
| } |
| |
| LValue isCellWithType(LValue cell, JSType queriedType, SpeculatedType speculatedTypeForQuery, SpeculatedType type = SpecFullTop) |
| { |
| if (LValue proven = isProvenValue(type & SpecCell, speculatedTypeForQuery)) |
| return proven; |
| return m_out.equal( |
| m_out.load8ZeroExt32(cell, m_heaps.JSCell_typeInfoType), |
| m_out.constInt32(queriedType)); |
| } |
| |
| LValue isTypedArrayView(LValue cell, SpeculatedType type = SpecFullTop) |
| { |
| if (LValue proven = isProvenValue(type & SpecCell, SpecTypedArrayView)) |
| return proven; |
| LValue jsType = m_out.sub( |
| m_out.load8ZeroExt32(cell, m_heaps.JSCell_typeInfoType), |
| m_out.constInt32(FirstTypedArrayType)); |
| return m_out.below( |
| jsType, |
| m_out.constInt32(NumberOfTypedArrayTypesExcludingDataView)); |
| } |
| |
| LValue isObject(LValue cell, SpeculatedType type = SpecFullTop) |
| { |
| if (LValue proven = isProvenValue(type & SpecCell, SpecObject)) |
| return proven; |
| return m_out.aboveOrEqual( |
| m_out.load8ZeroExt32(cell, m_heaps.JSCell_typeInfoType), |
| m_out.constInt32(ObjectType)); |
| } |
| |
| LValue isNotObject(LValue cell, SpeculatedType type = SpecFullTop) |
| { |
| if (LValue proven = isProvenValue(type & SpecCell, ~SpecObject)) |
| return proven; |
| return m_out.below( |
| m_out.load8ZeroExt32(cell, m_heaps.JSCell_typeInfoType), |
| m_out.constInt32(ObjectType)); |
| } |
| |
| LValue isNotString(LValue cell, SpeculatedType type = SpecFullTop) |
| { |
| if (LValue proven = isProvenValue(type & SpecCell, ~SpecString)) |
| return proven; |
| return m_out.notEqual( |
| m_out.load32(cell, m_heaps.JSCell_structureID), |
| m_out.constInt32(vm().stringStructure->id())); |
| } |
| |
| LValue isString(LValue cell, SpeculatedType type = SpecFullTop) |
| { |
| if (LValue proven = isProvenValue(type & SpecCell, SpecString)) |
| return proven; |
| return m_out.equal( |
| m_out.load32(cell, m_heaps.JSCell_structureID), |
| m_out.constInt32(vm().stringStructure->id())); |
| } |
| |
| LValue isNotSymbol(LValue cell, SpeculatedType type = SpecFullTop) |
| { |
| if (LValue proven = isProvenValue(type & SpecCell, ~SpecSymbol)) |
| return proven; |
| return m_out.notEqual( |
| m_out.load32(cell, m_heaps.JSCell_structureID), |
| m_out.constInt32(vm().symbolStructure->id())); |
| } |
| |
| LValue isSymbol(LValue cell, SpeculatedType type = SpecFullTop) |
| { |
| if (LValue proven = isProvenValue(type & SpecCell, SpecSymbol)) |
| return proven; |
| return m_out.equal( |
| m_out.load32(cell, m_heaps.JSCell_structureID), |
| m_out.constInt32(vm().symbolStructure->id())); |
| } |
| |
| LValue isNotBigInt(LValue cell, SpeculatedType type = SpecFullTop) |
| { |
| if (LValue proven = isProvenValue(type & SpecCell, ~SpecBigInt)) |
| return proven; |
| return m_out.notEqual( |
| m_out.load32(cell, m_heaps.JSCell_structureID), |
| m_out.constInt32(vm().bigIntStructure->id())); |
| } |
| |
| LValue isArrayTypeForArrayify(LValue cell, ArrayMode arrayMode) |
| { |
| switch (arrayMode.type()) { |
| case Array::Int32: |
| case Array::Double: |
| case Array::Contiguous: |
| case Array::Undecided: |
| case Array::ArrayStorage: { |
| IndexingType shape = arrayMode.shapeMask(); |
| LValue indexingType = m_out.load8ZeroExt32(cell, m_heaps.JSCell_indexingTypeAndMisc); |
| |
| switch (arrayMode.arrayClass()) { |
| case Array::OriginalArray: |
| DFG_CRASH(m_graph, m_node, "Unexpected original array"); |
| return nullptr; |
| |
| case Array::Array: |
| return m_out.equal( |
| m_out.bitAnd(indexingType, m_out.constInt32(IsArray | IndexingShapeMask)), |
| m_out.constInt32(IsArray | shape)); |
| |
| case Array::NonArray: |
| case Array::OriginalNonArray: |
| return m_out.equal( |
| m_out.bitAnd(indexingType, m_out.constInt32(IsArray | IndexingShapeMask)), |
| m_out.constInt32(shape)); |
| |
| case Array::PossiblyArray: |
| return m_out.equal( |
| m_out.bitAnd(indexingType, m_out.constInt32(IndexingShapeMask)), |
| m_out.constInt32(shape)); |
| } |
| break; |
| } |
| |
| case Array::SlowPutArrayStorage: { |
| ASSERT(!arrayMode.isJSArrayWithOriginalStructure()); |
| LValue indexingType = m_out.load8ZeroExt32(cell, m_heaps.JSCell_indexingTypeAndMisc); |
| |
| LBasicBlock trueCase = m_out.newBlock(); |
| LBasicBlock checkCase = m_out.newBlock(); |
| LBasicBlock continuation = m_out.newBlock(); |
| |
| ValueFromBlock falseValue = m_out.anchor(m_out.booleanFalse); |
| LValue isAnArrayStorageShape = m_out.belowOrEqual( |
| m_out.sub( |
| m_out.bitAnd(indexingType, m_out.constInt32(IndexingShapeMask)), |
| m_out.constInt32(ArrayStorageShape)), |
| m_out.constInt32(SlowPutArrayStorageShape - ArrayStorageShape)); |
| m_out.branch(isAnArrayStorageShape, unsure(checkCase), unsure(continuation)); |
| |
| LBasicBlock lastNext = m_out.appendTo(checkCase, trueCase); |
| switch (arrayMode.arrayClass()) { |
| case Array::OriginalArray: |
| DFG_CRASH(m_graph, m_node, "Unexpected original array"); |
| return nullptr; |
| |
| case Array::Array: |
| m_out.branch( |
| m_out.testNonZero32(indexingType, m_out.constInt32(IsArray)), |
| unsure(trueCase), unsure(continuation)); |
| break; |
| |
| case Array::NonArray: |
| case Array::OriginalNonArray: |
| m_out.branch( |
| m_out.testIsZero32(indexingType, m_out.constInt32(IsArray)), |
| unsure(trueCase), unsure(continuation)); |
| break; |
| |
| case Array::PossiblyArray: |
| m_out.jump(trueCase); |
| break; |
| } |
| |
| m_out.appendTo(trueCase, continuation); |
| ValueFromBlock trueValue = m_out.anchor(m_out.booleanTrue); |
| m_out.jump(continuation); |
| |
| m_out.appendTo(continuation, lastNext); |
| return m_out.phi(Int32, falseValue, trueValue); |
| } |
| |
| default: |
| break; |
| } |
| DFG_CRASH(m_graph, m_node, "Corrupt array class"); |
| } |
| |
| LValue isArrayTypeForCheckArray(LValue cell, ArrayMode arrayMode) |
| { |
| switch (arrayMode.type()) { |
| case Array::Int32: |
| case Array::Double: |
| case Array::Contiguous: |
| case Array::Undecided: |
| case Array::ArrayStorage: |
| case Array::SlowPutArrayStorage: |
| return isArrayTypeForArrayify(cell, arrayMode); |
| |
| case Array::DirectArguments: |
| return m_out.equal( |
| m_out.load8ZeroExt32(cell, m_heaps.JSCell_typeInfoType), |
| m_out.constInt32(DirectArgumentsType)); |
| |
| case Array::ScopedArguments: |
| return m_out.equal( |
| m_out.load8ZeroExt32(cell, m_heaps.JSCell_typeInfoType), |
| m_out.constInt32(ScopedArgumentsType)); |
| |
| default: |
| return m_out.equal( |
| m_out.load8ZeroExt32(cell, m_heaps.JSCell_typeInfoType), |
| m_out.constInt32(typeForTypedArrayType(arrayMode.typedArrayType()))); |
| } |
| } |
| |
| LValue isFunction(LValue cell, SpeculatedType type = SpecFullTop) |
| { |
| if (LValue proven = isProvenValue(type & SpecCell, SpecFunction)) |
| return proven; |
| return isType(cell, JSFunctionType); |
| } |
| LValue isNotFunction(LValue cell, SpeculatedType type = SpecFullTop) |
| { |
| if (LValue proven = isProvenValue(type & SpecCell, ~SpecFunction)) |
| return proven; |
| return isNotType(cell, JSFunctionType); |
| } |
| |
| LValue isExoticForTypeof(LValue cell, SpeculatedType type = SpecFullTop) |
| { |
| if (!(type & SpecObjectOther)) |
| return m_out.booleanFalse; |
| return m_out.testNonZero32( |
| m_out.load8ZeroExt32(cell, m_heaps.JSCell_typeInfoFlags), |
| m_out.constInt32(MasqueradesAsUndefined | TypeOfShouldCallGetCallData)); |
| } |
| |
| LValue isType(LValue cell, JSType type) |
| { |
| return m_out.equal( |
| m_out.load8ZeroExt32(cell, m_heaps.JSCell_typeInfoType), |
| m_out.constInt32(type)); |
| } |
| |
| LValue isNotType(LValue cell, JSType type) |
| { |
| return m_out.logicalNot(isType(cell, type)); |
| } |
| |
| void speculateObject(Edge edge, LValue cell) |
| { |
| FTL_TYPE_CHECK(jsValueValue(cell), edge, SpecObject, isNotObject(cell)); |
| } |
| |
| void speculateObject(Edge edge) |
| { |
| speculateObject(edge, lowCell(edge)); |
| } |
| |
| void speculateArray(Edge edge, LValue cell) |
| { |
| FTL_TYPE_CHECK( |
| jsValueValue(cell), edge, SpecArray, isNotType(cell, ArrayType)); |
| } |
| |
| void speculateArray(Edge edge) |
| { |
| speculateArray(edge, lowCell(edge)); |
| } |
| |
| void speculateFunction(Edge edge, LValue cell) |
| { |
| FTL_TYPE_CHECK(jsValueValue(cell), edge, SpecFunction, isNotFunction(cell)); |
| } |
| |
| void speculateFunction(Edge edge) |
| { |
| speculateFunction(edge, lowCell(edge)); |
| } |
| |
| void speculateObjectOrOther(Edge edge) |
| { |
| if (!m_interpreter.needsTypeCheck(edge)) |
| return; |
| |
| LValue value = lowJSValue(edge, ManualOperandSpeculation); |
| |
| LBasicBlock cellCase = m_out.newBlock(); |
| LBasicBlock primitiveCase = m_out.newBlock(); |
| LBasicBlock continuation = m_out.newBlock(); |
| |
| m_out.branch(isNotCell(value, provenType(edge)), unsure(primitiveCase), unsure(cellCase)); |
| |
| LBasicBlock lastNext = m_out.appendTo(cellCase, primitiveCase); |
| |
| FTL_TYPE_CHECK( |
| jsValueValue(value), edge, (~SpecCellCheck) | SpecObject, isNotObject(value)); |
| |
| m_out.jump(continuation); |
| |
| m_out.appendTo(primitiveCase, continuation); |
| |
| FTL_TYPE_CHECK( |
| jsValueValue(value), edge, SpecCellCheck | SpecOther, isNotOther(value)); |
| |
| m_out.jump(continuation); |
| |
| m_out.appendTo(continuation, lastNext); |
| } |
| |
| void speculateFinalObject(Edge edge, LValue cell) |
| { |
| FTL_TYPE_CHECK( |
| jsValueValue(cell), edge, SpecFinalObject, isNotType(cell, FinalObjectType)); |
| } |
| |
| void speculateFinalObject(Edge edge) |
| { |
| speculateFinalObject(edge, lowCell(edge)); |
| } |
| |
| void speculateRegExpObject(Edge edge, LValue cell) |
| { |
| FTL_TYPE_CHECK( |
| jsValueValue(cell), edge, SpecRegExpObject, isNotType(cell, RegExpObjectType)); |
| } |
| |
| void speculateRegExpObject(Edge edge) |
| { |
| speculateRegExpObject(edge, lowCell(edge)); |
| } |
| |
| void speculateProxyObject(Edge edge, LValue cell) |
| { |
| FTL_TYPE_CHECK( |
| jsValueValue(cell), edge, SpecProxyObject, isNotType(cell, ProxyObjectType)); |
| } |
| |
| void speculateProxyObject(Edge edge) |
| { |
| speculateProxyObject(edge, lowCell(edge)); |
| } |
| |
| void speculateDerivedArray(Edge edge, LValue cell) |
| { |
| FTL_TYPE_CHECK( |
| jsValueValue(cell), edge, SpecDerivedArray, isNotType(cell, DerivedArrayType)); |
| } |
| |
| void speculateDerivedArray(Edge edge) |
| { |
| speculateDerivedArray(edge, lowCell(edge)); |
| } |
| |
| void speculateMapObject(Edge edge, LValue cell) |
| { |
| FTL_TYPE_CHECK( |
| jsValueValue(cell), edge, SpecMapObject, isNotType(cell, JSMapType)); |
| } |
| |
| void speculateMapObject(Edge edge) |
| { |
| speculateMapObject(edge, lowCell(edge)); |
| } |
| |
| void speculateSetObject(Edge edge, LValue cell) |
| { |
| FTL_TYPE_CHECK( |
| jsValueValue(cell), edge, SpecSetObject, isNotType(cell, JSSetType)); |
| } |
| |
| void speculateSetObject(Edge edge) |
| { |
| speculateSetObject(edge, lowCell(edge)); |
| } |
| |
| void speculateWeakMapObject(Edge edge, LValue cell) |
| { |
| FTL_TYPE_CHECK( |
| jsValueValue(cell), edge, SpecWeakMapObject, isNotType(cell, JSWeakMapType)); |
| } |
| |
| void speculateWeakMapObject(Edge edge) |
| { |
| speculateWeakMapObject(edge, lowCell(edge)); |
| } |
| |
| void speculateWeakSetObject(Edge edge, LValue cell) |
| { |
| FTL_TYPE_CHECK( |
| jsValueValue(cell), edge, SpecWeakSetObject, isNotType(cell, JSWeakSetType)); |
| } |
| |
| void speculateWeakSetObject(Edge edge) |
| { |
| speculateWeakSetObject(edge, lowCell(edge)); |
| } |
| |
| void speculateString(Edge edge, LValue cell) |
| { |
| FTL_TYPE_CHECK(jsValueValue(cell), edge, SpecString, isNotString(cell)); |
| } |
| |
| void speculateString(Edge edge) |
| { |
| speculateString(edge, lowCell(edge)); |
| } |
| |
| void speculateStringOrOther(Edge edge, LValue value) |
| { |
| if (!m_interpreter.needsTypeCheck(edge)) |
| return; |
| |
| LBasicBlock cellCase = m_out.newBlock(); |
| LBasicBlock notCellCase = m_out.newBlock(); |
| LBasicBlock continuation = m_out.newBlock(); |
| |
| m_out.branch(isCell(value, provenType(edge)), unsure(cellCase), unsure(notCellCase)); |
| |
| LBasicBlock lastNext = m_out.appendTo(cellCase, notCellCase); |
| |
| FTL_TYPE_CHECK(jsValueValue(value), edge, (~SpecCellCheck) | SpecString, isNotString(value)); |
| |
| m_out.jump(continuation); |
| m_out.appendTo(notCellCase, continuation); |
| |
| FTL_TYPE_CHECK(jsValueValue(value), edge, SpecCellCheck | SpecOther, isNotOther(value)); |
| |
| m_out.jump(continuation); |
| m_out.appendTo(continuation, lastNext); |
| } |
| |
| void speculateStringOrOther(Edge edge) |
| { |
| speculateStringOrOther(edge, lowJSValue(edge, ManualOperandSpeculation)); |
| } |
| |
| void speculateStringIdent(Edge edge, LValue string, LValue stringImpl) |
| { |
| if (!m_interpreter.needsTypeCheck(edge, SpecStringIdent | ~SpecString)) |
| return; |
| |
| speculate(BadType, jsValueValue(string), edge.node(), m_out.isNull(stringImpl)); |
| speculate( |
| BadType, jsValueValue(string), edge.node(), |
| m_out.testIsZero32( |
| m_out.load32(stringImpl, m_heaps.StringImpl_hashAndFlags), |
| m_out.constInt32(StringImpl::flagIsAtomic()))); |
| m_interpreter.filter(edge, SpecStringIdent | ~SpecString); |
| } |
| |
| void speculateStringIdent(Edge edge) |
| { |
| lowStringIdent(edge); |
| } |
| |
| void speculateStringObject(Edge edge) |
| { |
| if (!m_interpreter.needsTypeCheck(edge, SpecStringObject)) |
| return; |
| |
| speculateStringObjectForCell(edge, lowCell(edge)); |
| m_interpreter.filter(edge, SpecStringObject); |
| } |
| |
| void speculateStringOrStringObject(Edge edge) |
| { |
| if (!m_interpreter.needsTypeCheck(edge, SpecString | SpecStringObject)) |
| return; |
| |
| LBasicBlock notString = m_out.newBlock(); |
| LBasicBlock continuation = m_out.newBlock(); |
| |
| LValue structureID = m_out.load32(lowCell(edge), m_heaps.JSCell_structureID); |
| m_out.branch( |
| m_out.equal(structureID, m_out.constInt32(vm().stringStructure->id())), |
| unsure(continuation), unsure(notString)); |
| |
| LBasicBlock lastNext = m_out.appendTo(notString, continuation); |
| speculateStringObjectForStructureID(edge, structureID); |
| m_out.jump(continuation); |
| |
| m_out.appendTo(continuation, lastNext); |
| |
| m_interpreter.filter(edge, SpecString | SpecStringObject); |
| } |
| |
| void speculateStringObjectForCell(Edge edge, LValue cell) |
| { |
| speculateStringObjectForStructureID(edge, m_out.load32(cell, m_heaps.JSCell_structureID)); |
| } |
| |
| void speculateStringObjectForStructureID(Edge edge, LValue structureID) |
| { |
| RegisteredStructure stringObjectStructure = |
| m_graph.registerStructure(m_graph.globalObjectFor(m_node->origin.semantic)->stringObjectStructure()); |
| |
| if (abstractStructure(edge).isSubsetOf(RegisteredStructureSet(stringObjectStructure))) |
| return; |
| |
| speculate( |
| NotStringObject, noValue(), 0, |
| m_out.notEqual(structureID, weakStructureID(stringObjectStructure))); |
| } |
| |
| void speculateSymbol(Edge edge, LValue cell) |
| { |
| FTL_TYPE_CHECK(jsValueValue(cell), edge, SpecSymbol, isNotSymbol(cell)); |
| } |
| |
| void speculateSymbol(Edge edge) |
| { |
| speculateSymbol(edge, lowCell(edge)); |
| } |
| |
| void speculateBigInt(Edge edge, LValue cell) |
| { |
| FTL_TYPE_CHECK(jsValueValue(cell), edge, SpecBigInt, isNotBigInt(cell)); |
| } |
| |
| void speculateBigInt(Edge edge) |
| { |
| speculateBigInt(edge, lowCell(edge)); |
| } |
| |
| void speculateNonNullObject(Edge edge, LValue cell) |
| { |
| FTL_TYPE_CHECK(jsValueValue(cell), edge, SpecObject, isNotObject(cell)); |
| if (masqueradesAsUndefinedWatchpointIsStillValid()) |
| return; |
| |
| speculate( |
| BadType, jsValueValue(cell), edge.node(), |
| m_out.testNonZero32( |
| m_out.load8ZeroExt32(cell, m_heaps.JSCell_typeInfoFlags), |
| m_out.constInt32(MasqueradesAsUndefined))); |
| } |
| |
| void speculateNumber(Edge edge) |
| { |
| LValue value = lowJSValue(edge, ManualOperandSpeculation); |
| FTL_TYPE_CHECK(jsValueValue(value), edge, SpecBytecodeNumber, isNotNumber(value)); |
| } |
| |
| void speculateRealNumber(Edge edge) |
| { |
| // Do an early return here because lowDouble() can create a lot of control flow. |
| if (!m_interpreter.needsTypeCheck(edge)) |
| return; |
| |
| LValue value = lowJSValue(edge, ManualOperandSpeculation); |
| LValue doubleValue = unboxDouble(value); |
| |
| LBasicBlock intCase = m_out.newBlock(); |
| LBasicBlock continuation = m_out.newBlock(); |
| |
| m_out.branch( |
| m_out.doubleEqual(doubleValue, doubleValue), |
| usually(continuation), rarely(intCase)); |
| |
| LBasicBlock lastNext = m_out.appendTo(intCase, continuation); |
| |
| typeCheck( |
| jsValueValue(value), m_node->child1(), SpecBytecodeRealNumber, |
| isNotInt32(value, provenType(m_node->child1()) & ~SpecFullDouble)); |
| m_out.jump(continuation); |
| |
| m_out.appendTo(continuation, lastNext); |
| } |
| |
| void speculateDoubleRepReal(Edge edge) |
| { |
| // Do an early return here because lowDouble() can create a lot of control flow. |
| if (!m_interpreter.needsTypeCheck(edge)) |
| return; |
| |
| LValue value = lowDouble(edge); |
| FTL_TYPE_CHECK( |
| doubleValue(value), edge, SpecDoubleReal, |
| m_out.doubleNotEqualOrUnordered(value, value)); |
| } |
| |
| void speculateDoubleRepAnyInt(Edge edge) |
| { |
| if (!m_interpreter.needsTypeCheck(edge)) |
| return; |
| |
| doubleToStrictInt52(edge, lowDouble(edge)); |
| } |
| |
| void speculateBoolean(Edge edge) |
| { |
| lowBoolean(edge); |
| } |
| |
| void speculateNotStringVar(Edge edge) |
| { |
| if (!m_interpreter.needsTypeCheck(edge, ~SpecStringVar)) |
| return; |
| |
| LValue value = lowJSValue(edge, ManualOperandSpeculation); |
| |
| LBasicBlock isCellCase = m_out.newBlock(); |
| LBasicBlock isStringCase = m_out.newBlock(); |
| LBasicBlock continuation = m_out.newBlock(); |
| |
| m_out.branch(isCell(value, provenType(edge)), unsure(isCellCase), unsure(continuation)); |
| |
| LBasicBlock lastNext = m_out.appendTo(isCellCase, isStringCase); |
| m_out.branch(isString(value, provenType(edge)), unsure(isStringCase), unsure(continuation)); |
| |
| m_out.appendTo(isStringCase, continuation); |
| speculateStringIdent(edge, value, m_out.loadPtr(value, m_heaps.JSString_value)); |
| m_out.jump(continuation); |
| |
| m_out.appendTo(continuation, lastNext); |
| } |
| |
| void speculateNotSymbol(Edge edge) |
| { |
| if (!m_interpreter.needsTypeCheck(edge, ~SpecSymbol)) |
| return; |
| |
| ASSERT(mayHaveTypeCheck(edge.useKind())); |
| LValue value = lowJSValue(edge, ManualOperandSpeculation); |
| |
| LBasicBlock isCellCase = m_out.newBlock(); |
| LBasicBlock continuation = m_out.newBlock(); |
| |
| m_out.branch(isCell(value, provenType(edge)), unsure(isCellCase), unsure(continuation)); |
| |
| LBasicBlock lastNext = m_out.appendTo(isCellCase, continuation); |
| speculate(BadType, jsValueValue(value), edge.node(), isSymbol(value)); |
| m_out.jump(continuation); |
| |
| m_out.appendTo(continuation, lastNext); |
| |
| m_interpreter.filter(edge, ~SpecSymbol); |
| } |
| |
| void speculateOther(Edge edge) |
| { |
| if (!m_interpreter.needsTypeCheck(edge)) |
| return; |
| |
| LValue value = lowJSValue(edge, ManualOperandSpeculation); |
| typeCheck(jsValueValue(value), edge, SpecOther, isNotOther(value)); |
| } |
| |
| void speculateMisc(Edge edge) |
| { |
| if (!m_interpreter.needsTypeCheck(edge)) |
| return; |
| |
| LValue value = lowJSValue(edge, ManualOperandSpeculation); |
| typeCheck(jsValueValue(value), edge, SpecMisc, isNotMisc(value)); |
| } |
| |
| void speculateTypedArrayIsNotNeutered(LValue base) |
| { |
| LBasicBlock isWasteful = m_out.newBlock(); |
| LBasicBlock continuation = m_out.newBlock(); |
| |
| LValue mode = m_out.load32(base, m_heaps.JSArrayBufferView_mode); |
| m_out.branch(m_out.equal(mode, m_out.constInt32(WastefulTypedArray)), |
| unsure(isWasteful), unsure(continuation)); |
| |
| LBasicBlock lastNext = m_out.appendTo(isWasteful, continuation); |
| LValue vector = m_out.loadPtr(base, m_heaps.JSArrayBufferView_vector); |
| speculate(Uncountable, jsValueValue(vector), m_node, m_out.isZero64(vector)); |
| m_out.jump(continuation); |
| |
| m_out.appendTo(continuation, lastNext); |
| } |
| |
| bool masqueradesAsUndefinedWatchpointIsStillValid() |
| { |
| return m_graph.masqueradesAsUndefinedWatchpointIsStillValid(m_node->origin.semantic); |
| } |
| |
| LValue loadCellState(LValue base) |
| { |
| return m_out.load8ZeroExt32(base, m_heaps.JSCell_cellState); |
| } |
| |
| void emitStoreBarrier(LValue base, bool isFenced) |
| { |
| LBasicBlock recheckPath = nullptr; |
| if (isFenced) |
| recheckPath = m_out.newBlock(); |
| LBasicBlock slowPath = m_out.newBlock(); |
| LBasicBlock continuation = m_out.newBlock(); |
| |
| LBasicBlock lastNext = m_out.insertNewBlocksBefore(isFenced ? recheckPath : slowPath); |
| |
| LValue threshold; |
| if (isFenced) |
| threshold = m_out.load32(m_out.absolute(vm().heap.addressOfBarrierThreshold())); |
| else |
| threshold = m_out.constInt32(blackThreshold); |
| |
| m_out.branch( |
| m_out.above(loadCellState(base), threshold), |
| usually(continuation), rarely(isFenced ? recheckPath : slowPath)); |
| |
| if (isFenced) { |
| m_out.appendTo(recheckPath, slowPath); |
| |
| m_out.fence(&m_heaps.root, &m_heaps.JSCell_cellState); |
| |
| m_out.branch( |
| m_out.above(loadCellState(base), m_out.constInt32(blackThreshold)), |
| usually(continuation), rarely(slowPath)); |
| } |
| |
| m_out.appendTo(slowPath, continuation); |
| |
| LValue call = vmCall(Void, m_out.operation(operationWriteBarrierSlowPath), m_callFrame, base); |
| m_heaps.decorateCCallRead(&m_heaps.root, call); |
| m_heaps.decorateCCallWrite(&m_heaps.JSCell_cellState, call); |
| |
| m_out.jump(continuation); |
| |
| m_out.appendTo(continuation, lastNext); |
| } |
| |
| void mutatorFence() |
| { |
| if (isX86()) { |
| m_out.fence(&m_heaps.root, nullptr); |
| return; |
| } |
| |
| LBasicBlock slowPath = m_out.newBlock(); |
| LBasicBlock continuation = m_out.newBlock(); |
| |
| LBasicBlock lastNext = m_out.insertNewBlocksBefore(slowPath); |
| |
| m_out.branch( |
| m_out.load8ZeroExt32(m_out.absolute(vm().heap.addressOfMutatorShouldBeFenced())), |
| rarely(slowPath), usually(continuation)); |
| |
| m_out.appendTo(slowPath, continuation); |
| |
| m_out.fence(&m_heaps.root, nullptr); |
| m_out.jump(continuation); |
| |
| m_out.appendTo(continuation, lastNext); |
| } |
| |
| void nukeStructureAndSetButterfly(LValue butterfly, LValue object) |
| { |
| if (isX86()) { |
| m_out.store32( |
| m_out.bitOr( |
| m_out.load32(object, m_heaps.JSCell_structureID), |
| m_out.constInt32(nukedStructureIDBit())), |
| object, m_heaps.JSCell_structureID); |
| m_out.fence(&m_heaps.root, nullptr); |
| m_out.storePtr(butterfly, object, m_heaps.JSObject_butterfly); |
| m_out.fence(&m_heaps.root, nullptr); |
| return; |
| } |
| |
| LBasicBlock fastPath = m_out.newBlock(); |
| LBasicBlock slowPath = m_out.newBlock(); |
| LBasicBlock continuation = m_out.newBlock(); |
| |
| LBasicBlock lastNext = m_out.insertNewBlocksBefore(fastPath); |
| |
| m_out.branch( |
| m_out.load8ZeroExt32(m_out.absolute(vm().heap.addressOfMutatorShouldBeFenced())), |
| rarely(slowPath), usually(fastPath)); |
| |
| m_out.appendTo(fastPath, slowPath); |
| |
| m_out.storePtr(butterfly, object, m_heaps.JSObject_butterfly); |
| m_out.jump(continuation); |
| |
| m_out.appendTo(slowPath, continuation); |
| |
| m_out.store32( |
| m_out.bitOr( |
| m_out.load32(object, m_heaps.JSCell_structureID), |
| m_out.constInt32(nukedStructureIDBit())), |
| object, m_heaps.JSCell_structureID); |
| m_out.fence(&m_heaps.root, nullptr); |
| m_out.storePtr(butterfly, object, m_heaps.JSObject_butterfly); |
| m_out.fence(&m_heaps.root, nullptr); |
| m_out.jump(continuation); |
| |
| m_out.appendTo(continuation, lastNext); |
| } |
| |
| LValue preciseIndexMask64(LValue value, LValue index, LValue limit) |
| { |
| return m_out.bitAnd( |
| value, |
| m_out.aShr( |
| m_out.sub( |
| index, |
| m_out.opaque(limit)), |
| m_out.constInt32(63))); |
| } |
| |
| LValue preciseIndexMask32(LValue value, LValue index, LValue limit) |
| { |
| return preciseIndexMask64(value, m_out.zeroExt(index, Int64), m_out.zeroExt(limit, Int64)); |
| } |
| |
| LValue dynamicPoison(LValue value, LValue poison) |
| { |
| return m_out.add( |
| value, |
| m_out.shl( |
| m_out.zeroExt(poison, pointerType()), |
| m_out.constInt32(40))); |
| } |
| |
| LValue dynamicPoisonOnLoadedType(LValue value, LValue actualType, JSType expectedType) |
| { |
| return dynamicPoison( |
| value, |
| m_out.bitXor( |
| m_out.opaque(actualType), |
| m_out.constInt32(expectedType))); |
| } |
| |
| LValue dynamicPoisonOnType(LValue value, JSType expectedType) |
| { |
| return dynamicPoisonOnLoadedType( |
| value, |
| m_out.load8ZeroExt32(value, m_heaps.JSCell_typeInfoType), |
| expectedType); |
| } |
| |
| template<typename... Args> |
| LValue vmCall(LType type, LValue function, Args&&... args) |
| { |
| callPreflight(); |
| LValue result = m_out.call(type, function, std::forward<Args>(args)...); |
| callCheck(); |
| return result; |
| } |
| |
| void callPreflight(CodeOrigin codeOrigin) |
| { |
| CallSiteIndex callSiteIndex = m_ftlState.jitCode->common.addCodeOrigin(codeOrigin); |
| m_out.store32( |
| m_out.constInt32(callSiteIndex.bits()), |
| tagFor(CallFrameSlot::argumentCount)); |
| } |
| |
| void callPreflight() |
| { |
| callPreflight(codeOriginDescriptionOfCallSite()); |
| } |
| |
| CodeOrigin codeOriginDescriptionOfCallSite() const |
| { |
| CodeOrigin codeOrigin = m_node->origin.semantic; |
| if (m_node->op() == TailCallInlinedCaller |
| || m_node->op() == TailCallVarargsInlinedCaller |
| || m_node->op() == TailCallForwardVarargsInlinedCaller |
| || m_node->op() == DirectTailCallInlinedCaller) { |
| // This case arises when you have a situation like this: |
| // foo makes a call to bar, bar is inlined in foo. bar makes a call |
| // to baz and baz is inlined in bar. And then baz makes a tail-call to jaz, |
| // and jaz is inlined in baz. We want the callframe for jaz to appear to |
| // have caller be bar. |
| codeOrigin = *codeOrigin.inlineCallFrame->getCallerSkippingTailCalls(); |
| } |
| |
| return codeOrigin; |
| } |
| |
| void callCheck() |
| { |
| if (Options::useExceptionFuzz()) |
| m_out.call(Void, m_out.operation(operationExceptionFuzz), m_callFrame); |
| |
| LValue exception = m_out.load64(m_out.absolute(vm().addressOfException())); |
| LValue hadException = m_out.notZero64(exception); |
| |
| CodeOrigin opCatchOrigin; |
| HandlerInfo* exceptionHandler; |
| if (m_graph.willCatchExceptionInMachineFrame(m_origin.forExit, opCatchOrigin, exceptionHandler)) { |
| bool exitOK = true; |
| bool isExceptionHandler = true; |
| appendOSRExit( |
| ExceptionCheck, noValue(), nullptr, hadException, |
| m_origin.withForExitAndExitOK(opCatchOrigin, exitOK), isExceptionHandler); |
| return; |
| } |
| |
| LBasicBlock continuation = m_out.newBlock(); |
| |
| m_out.branch( |
| hadException, rarely(m_handleExceptions), usually(continuation)); |
| |
| m_out.appendTo(continuation); |
| } |
| |
| RefPtr<PatchpointExceptionHandle> preparePatchpointForExceptions(PatchpointValue* value) |
| { |
| CodeOrigin opCatchOrigin; |
| HandlerInfo* exceptionHandler; |
| bool willCatchException = m_graph.willCatchExceptionInMachineFrame(m_origin.forExit, opCatchOrigin, exceptionHandler); |
| if (!willCatchException) |
| return PatchpointExceptionHandle::defaultHandle(m_ftlState); |
| |
| if (verboseCompilationEnabled()) { |
| dataLog(" Patchpoint exception OSR exit #", m_ftlState.jitCode->osrExitDescriptors.size(), " with availability: ", availabilityMap(), "\n"); |
| if (!m_availableRecoveries.isEmpty()) |
| dataLog(" Available recoveries: ", listDump(m_availableRecoveries), "\n"); |
| } |
| |
| bool exitOK = true; |
| NodeOrigin origin = m_origin.withForExitAndExitOK(opCatchOrigin, exitOK); |
| |
| OSRExitDescriptor* exitDescriptor = appendOSRExitDescriptor(noValue(), nullptr); |
| |
| // Compute the offset into the StackmapGenerationParams where we will find the exit arguments |
| // we are about to append. We need to account for both the children we've already added, and |
| // for the possibility of a result value if the patchpoint is not void. |
| unsigned offset = value->numChildren(); |
| if (value->type() != Void) |
| offset++; |
| |
| // Use LateColdAny to ensure that the stackmap arguments interfere with the patchpoint's |
| // result and with any late-clobbered registers. |
| value->appendVectorWithRep( |
| buildExitArguments(exitDescriptor, opCatchOrigin, noValue()), |
| ValueRep::LateColdAny); |
| |
| return PatchpointExceptionHandle::create( |
| m_ftlState, exitDescriptor, origin, offset, *exceptionHandler); |
| } |
| |
| LBasicBlock lowBlock(DFG::BasicBlock* block) |
| { |
| return m_blocks.get(block); |
| } |
| |
| OSRExitDescriptor* appendOSRExitDescriptor(FormattedValue lowValue, Node* highValue) |
| { |
| return appendOSRExitDescriptor(lowValue, m_graph.methodOfGettingAValueProfileFor(m_node, highValue)); |
| } |
| |
| OSRExitDescriptor* appendOSRExitDescriptor(FormattedValue lowValue, const MethodOfGettingAValueProfile& profile) |
| { |
| return &m_ftlState.jitCode->osrExitDescriptors.alloc( |
| lowValue.format(), profile, |
| availabilityMap().m_locals.numberOfArguments(), |
| availabilityMap().m_locals.numberOfLocals()); |
| } |
| |
| void appendOSRExit( |
| ExitKind kind, FormattedValue lowValue, Node* highValue, LValue failCondition, |
| NodeOrigin origin, bool isExceptionHandler = false) |
| { |
| return appendOSRExit(kind, lowValue, m_graph.methodOfGettingAValueProfileFor(m_node, highValue), |
| failCondition, origin, isExceptionHandler); |
| } |
| |
| void appendOSRExit( |
| ExitKind kind, FormattedValue lowValue, const MethodOfGettingAValueProfile& profile, LValue failCondition, |
| NodeOrigin origin, bool isExceptionHandler = false) |
| { |
| if (verboseCompilationEnabled()) { |
| dataLog(" OSR exit #", m_ftlState.jitCode->osrExitDescriptors.size(), " with availability: ", availabilityMap(), "\n"); |
| if (!m_availableRecoveries.isEmpty()) |
| dataLog(" Available recoveries: ", listDump(m_availableRecoveries), "\n"); |
| } |
| |
| DFG_ASSERT(m_graph, m_node, origin.exitOK); |
| |
| if (!isExceptionHandler |
| && Options::useOSRExitFuzz() |
| && canUseOSRExitFuzzing(m_graph.baselineCodeBlockFor(m_node->origin.semantic)) |
| && doOSRExitFuzzing()) { |
| LValue numberOfFuzzChecks = m_out.add( |
| m_out.load32(m_out.absolute(&g_numberOfOSRExitFuzzChecks)), |
| m_out.int32One); |
| |
| m_out.store32(numberOfFuzzChecks, m_out.absolute(&g_numberOfOSRExitFuzzChecks)); |
| |
| if (unsigned atOrAfter = Options::fireOSRExitFuzzAtOrAfter()) { |
| failCondition = m_out.bitOr( |
| failCondition, |
| m_out.aboveOrEqual(numberOfFuzzChecks, m_out.constInt32(atOrAfter))); |
| } |
| if (unsigned at = Options::fireOSRExitFuzzAt()) { |
| failCondition = m_out.bitOr( |
| failCondition, |
| m_out.equal(numberOfFuzzChecks, m_out.constInt32(at))); |
| } |
| } |
| |
| if (failCondition == m_out.booleanFalse) |
| return; |
| |
| blessSpeculation( |
| m_out.speculate(failCondition), kind, lowValue, profile, origin); |
| } |
| |
| void blessSpeculation(CheckValue* value, ExitKind kind, FormattedValue lowValue, Node* highValue, NodeOrigin origin) |
| { |
| blessSpeculation(value, kind, lowValue, m_graph.methodOfGettingAValueProfileFor(m_node, highValue), origin); |
| } |
| |
| void blessSpeculation(CheckValue* value, ExitKind kind, FormattedValue lowValue, const MethodOfGettingAValueProfile& profile, NodeOrigin origin) |
| { |
| OSRExitDescriptor* exitDescriptor = appendOSRExitDescriptor(lowValue, profile); |
| |
| value->appendColdAnys(buildExitArguments(exitDescriptor, origin.forExit, lowValue)); |
| |
| State* state = &m_ftlState; |
| value->setGenerator( |
| [=] (CCallHelpers& jit, const B3::StackmapGenerationParams& params) { |
| exitDescriptor->emitOSRExit( |
| *state, kind, origin, jit, params, 0); |
| }); |
| } |
| |
| StackmapArgumentList buildExitArguments( |
| OSRExitDescriptor* exitDescriptor, CodeOrigin exitOrigin, FormattedValue lowValue, |
| unsigned offsetOfExitArgumentsInStackmapLocations = 0) |
| { |
| StackmapArgumentList result; |
| buildExitArguments( |
| exitDescriptor, exitOrigin, result, lowValue, offsetOfExitArgumentsInStackmapLocations); |
| return result; |
| } |
| |
| void buildExitArguments( |
| OSRExitDescriptor* exitDescriptor, CodeOrigin exitOrigin, StackmapArgumentList& arguments, FormattedValue lowValue, |
| unsigned offsetOfExitArgumentsInStackmapLocations = 0) |
| { |
| if (!!lowValue) |
| arguments.append(lowValue.value()); |
| |
| AvailabilityMap availabilityMap = this->availabilityMap(); |
| availabilityMap.pruneByLiveness(m_graph, exitOrigin); |
| |
| HashMap<Node*, ExitTimeObjectMaterialization*> map; |
| availabilityMap.forEachAvailability( |
| [&] (Availability availability) { |
| if (!availability.shouldUseNode()) |
| return; |
| |
| Node* node = availability.node(); |
| if (!node->isPhantomAllocation()) |
| return; |
| |
| auto result = map.add(node, nullptr); |
| if (result.isNewEntry) { |
| result.iterator->value = |
| exitDescriptor->m_materializations.add(node->op(), node->origin.semantic); |
| } |
| }); |
| |
| for (unsigned i = 0; i < exitDescriptor->m_values.size(); ++i) { |
| int operand = exitDescriptor->m_values.operandForIndex(i); |
| |
| Availability availability = availabilityMap.m_locals[i]; |
| |
| if (Options::validateFTLOSRExitLiveness() |
| && m_graph.m_plan.mode != FTLForOSREntryMode) { |
| |
| if (availability.isDead() && m_graph.isLiveInBytecode(VirtualRegister(operand), exitOrigin)) |
| DFG_CRASH(m_graph, m_node, toCString("Live bytecode local not available: operand = ", VirtualRegister(operand), ", availability = ", availability, ", origin = ", exitOrigin).data()); |
| } |
| ExitValue exitValue = exitValueForAvailability(arguments, map, availability); |
| if (exitValue.hasIndexInStackmapLocations()) |
| exitValue.adjustStackmapLocationsIndexByOffset(offsetOfExitArgumentsInStackmapLocations); |
| exitDescriptor->m_values[i] = exitValue; |
| } |
| |
| for (auto heapPair : availabilityMap.m_heap) { |
| Node* node = heapPair.key.base(); |
| ExitTimeObjectMaterialization* materialization = map.get(node); |
| if (!materialization) |
| DFG_CRASH(m_graph, m_node, toCString("Could not find materialization for ", node, " in ", availabilityMap).data()); |
| ExitValue exitValue = exitValueForAvailability(arguments, map, heapPair.value); |
| if (exitValue.hasIndexInStackmapLocations()) |
| exitValue.adjustStackmapLocationsIndexByOffset(offsetOfExitArgumentsInStackmapLocations); |
| materialization->add( |
| heapPair.key.descriptor(), |
| exitValue); |
| } |
| |
| if (verboseCompilationEnabled()) { |
| dataLog(" Exit values: ", exitDescriptor->m_values, "\n"); |
| if (!exitDescriptor->m_materializations.isEmpty()) { |
| dataLog(" Materializations: \n"); |
| for (ExitTimeObjectMaterialization* materialization : exitDescriptor->m_materializations) |
| dataLog(" ", pointerDump(materialization), "\n"); |
| } |
| } |
| } |
| |
| ExitValue exitValueForAvailability( |
| StackmapArgumentList& arguments, const HashMap<Node*, ExitTimeObjectMaterialization*>& map, |
| Availability availability) |
| { |
| FlushedAt flush = availability.flushedAt(); |
| switch (flush.format()) { |
| case DeadFlush: |
| case ConflictingFlush: |
| if (availability.hasNode()) |
| return exitValueForNode(arguments, map, availability.node()); |
| |
| // This means that the value is dead. It could be dead in bytecode or it could have |
| // been killed by our DCE, which can sometimes kill things even if they were live in |
| // bytecode. |
| return ExitValue::dead(); |
| |
| case FlushedJSValue: |
| case FlushedCell: |
| case FlushedBoolean: |
| return ExitValue::inJSStack(flush.virtualRegister()); |
| |
| case FlushedInt32: |
| return ExitValue::inJSStackAsInt32(flush.virtualRegister()); |
| |
| case FlushedInt52: |
| return ExitValue::inJSStackAsInt52(flush.virtualRegister()); |
| |
| case FlushedDouble: |
| return ExitValue::inJSStackAsDouble(flush.virtualRegister()); |
| } |
| |
| DFG_CRASH(m_graph, m_node, "Invalid flush format"); |
| return ExitValue::dead(); |
| } |
| |
| ExitValue exitValueForNode( |
| StackmapArgumentList& arguments, const HashMap<Node*, ExitTimeObjectMaterialization*>& map, |
| Node* node) |
| { |
| // NOTE: In FTL->B3, we cannot generate code here, because m_output is positioned after the |
| // stackmap value. Like all values, the stackmap value cannot use a child that is defined after |
| // it. |
| |
| ASSERT(node->shouldGenerate()); |
| ASSERT(node->hasResult()); |
| |
| if (node) { |
| switch (node->op()) { |
| case BottomValue: |
| // This might arise in object materializations. I actually doubt that it would, |
| // but it seems worthwhile to be conservative. |
| return ExitValue::dead(); |
| |
| case JSConstant: |
| case Int52Constant: |
| case DoubleConstant: |
| return ExitValue::constant(node->asJSValue()); |
| |
| default: |
| if (node->isPhantomAllocation()) |
| return ExitValue::materializeNewObject(map.get(node)); |
| break; |
| } |
| } |
| |
| for (unsigned i = 0; i < m_availableRecoveries.size(); ++i) { |
| AvailableRecovery recovery = m_availableRecoveries[i]; |
| if (recovery.node() != node) |
| continue; |
| ExitValue result = ExitValue::recovery( |
| recovery.opcode(), arguments.size(), arguments.size() + 1, |
| recovery.format()); |
| arguments.append(recovery.left()); |
| arguments.append(recovery.right()); |
| return result; |
| } |
| |
| LoweredNodeValue value = m_int32Values.get(node); |
| if (isValid(value)) |
| return exitArgument(arguments, DataFormatInt32, value.value()); |
| |
| value = m_int52Values.get(node); |
| if (isValid(value)) |
| return exitArgument(arguments, DataFormatInt52, value.value()); |
| |
| value = m_strictInt52Values.get(node); |
| if (isValid(value)) |
| return exitArgument(arguments, DataFormatStrictInt52, value.value()); |
| |
| value = m_booleanValues.get(node); |
| if (isValid(value)) |
| return exitArgument(arguments, DataFormatBoolean, value.value()); |
| |
| value = m_jsValueValues.get(node); |
| if (isValid(value)) |
| return exitArgument(arguments, DataFormatJS, value.value()); |
| |
| value = m_doubleValues.get(node); |
| if (isValid(value)) |
| return exitArgument(arguments, DataFormatDouble, value.value()); |
| |
| DFG_CRASH(m_graph, m_node, toCString("Cannot find value for node: ", node).data()); |
| return ExitValue::dead(); |
| } |
| |
| ExitValue exitArgument(StackmapArgumentList& arguments, DataFormat format, LValue value) |
| { |
| ExitValue result = ExitValue::exitArgument(ExitArgument(format, arguments.size())); |
| arguments.append(value); |
| return result; |
| } |
| |
| ExitValue exitValueForTailCall(StackmapArgumentList& arguments, Node* node) |
| { |
| ASSERT(node->shouldGenerate()); |
| ASSERT(node->hasResult()); |
| |
| switch (node->op()) { |
| case JSConstant: |
| case Int52Constant: |
| case DoubleConstant: |
| return ExitValue::constant(node->asJSValue()); |
| |
| default: |
| break; |
| } |
| |
| LoweredNodeValue value = m_jsValueValues.get(node); |
| if (isValid(value)) |
| return exitArgument(arguments, DataFormatJS, value.value()); |
| |
| value = m_int32Values.get(node); |
| if (isValid(value)) |
| return exitArgument(arguments, DataFormatJS, boxInt32(value.value())); |
| |
| value = m_booleanValues.get(node); |
| if (isValid(value)) |
| return exitArgument(arguments, DataFormatJS, boxBoolean(value.value())); |
| |
| // Doubles and Int52 have been converted by ValueRep() |
| DFG_CRASH(m_graph, m_node, toCString("Cannot find value for node: ", node).data()); |
| } |
| |
| void addAvailableRecovery( |
| Node* node, RecoveryOpcode opcode, LValue left, LValue right, DataFormat format) |
| { |
| m_availableRecoveries.append(AvailableRecovery(node, opcode, left, right, format)); |
| } |
| |
| void addAvailableRecovery( |
| Edge edge, RecoveryOpcode opcode, LValue left, LValue right, DataFormat format) |
| { |
| addAvailableRecovery(edge.node(), opcode, left, right, format); |
| } |
| |
| void setInt32(Node* node, LValue value) |
| { |
| m_int32Values.set(node, LoweredNodeValue(value, m_highBlock)); |
| } |
| void setInt52(Node* node, LValue value) |
| { |
| m_int52Values.set(node, LoweredNodeValue(value, m_highBlock)); |
| } |
| void setStrictInt52(Node* node, LValue value) |
| { |
| m_strictInt52Values.set(node, LoweredNodeValue(value, m_highBlock)); |
| } |
| void setInt52(Node* node, LValue value, Int52Kind kind) |
| { |
| switch (kind) { |
| case Int52: |
| setInt52(node, value); |
| return; |
| |
| case StrictInt52: |
| setStrictInt52(node, value); |
| return; |
| } |
| |
| DFG_CRASH(m_graph, m_node, "Corrupt int52 kind"); |
| } |
| void setJSValue(Node* node, LValue value) |
| { |
| m_jsValueValues.set(node, LoweredNodeValue(value, m_highBlock)); |
| } |
| void setBoolean(Node* node, LValue value) |
| { |
| m_booleanValues.set(node, LoweredNodeValue(value, m_highBlock)); |
| } |
| void setStorage(Node* node, LValue value) |
| { |
| m_storageValues.set(node, LoweredNodeValue(value, m_highBlock)); |
| } |
| void setDouble(Node* node, LValue value) |
| { |
| m_doubleValues.set(node, LoweredNodeValue(value, m_highBlock)); |
| } |
| |
| void setInt32(LValue value) |
| { |
| setInt32(m_node, value); |
| } |
| void setInt52(LValue value) |
| { |
| setInt52(m_node, value); |
| } |
| void setStrictInt52(LValue value) |
| { |
| setStrictInt52(m_node, value); |
| } |
| void setInt52(LValue value, Int52Kind kind) |
| { |
| setInt52(m_node, value, kind); |
| } |
| void setJSValue(LValue value) |
| { |
| setJSValue(m_node, value); |
| } |
| void setBoolean(LValue value) |
| { |
| setBoolean(m_node, value); |
| } |
| void setStorage(LValue value) |
| { |
| setStorage(m_node, value); |
| } |
| void setDouble(LValue value) |
| { |
| setDouble(m_node, value); |
| } |
| |
| bool isValid(const LoweredNodeValue& value) |
| { |
| if (!value) |
| return false; |
| if (!m_graph.m_ssaDominators->dominates(value.block(), m_highBlock)) |
| return false; |
| return true; |
| } |
| |
| void addWeakReference(JSCell* target) |
| { |
| m_graph.m_plan.weakReferences.addLazily(target); |
| } |
| |
| LValue loadStructure(LValue value) |
| { |
| LValue tableIndex = m_out.load32(value, m_heaps.JSCell_structureID); |
| LValue tableBase = m_out.loadPtr( |
| m_out.absolute(vm().heap.structureIDTable().base())); |
| TypedPointer address = m_out.baseIndex( |
| m_heaps.structureTable, tableBase, m_out.zeroExtPtr(tableIndex)); |
| return m_out.loadPtr(address); |
| } |
| |
| LValue weakPointer(JSCell* pointer) |
| { |
| addWeakReference(pointer); |
| return m_out.weakPointer(m_graph, pointer); |
| } |
| |
| template<typename Key> |
| LValue weakPoisonedPointer(JSCell* pointer) |
| { |
| addWeakReference(pointer); |
| return m_out.weakPoisonedPointer<Key>(m_graph, pointer); |
| } |
| |
| LValue frozenPointer(FrozenValue* value) |
| { |
| return m_out.weakPointer(value); |
| } |
| |
| LValue weakStructureID(RegisteredStructure structure) |
| { |
| return m_out.constInt32(structure->id()); |
| } |
| |
| LValue weakStructure(RegisteredStructure structure) |
| { |
| ASSERT(!!structure.get()); |
| return m_out.weakPointer(m_graph, structure.get()); |
| } |
| |
| TypedPointer addressFor(LValue base, int operand, ptrdiff_t offset = 0) |
| { |
| return m_out.address(base, m_heaps.variables[operand], offset); |
| } |
| TypedPointer payloadFor(LValue base, int operand) |
| { |
| return addressFor(base, operand, PayloadOffset); |
| } |
| TypedPointer tagFor(LValue base, int operand) |
| { |
| return addressFor(base, operand, TagOffset); |
| } |
| TypedPointer addressFor(int operand, ptrdiff_t offset = 0) |
| { |
| return addressFor(VirtualRegister(operand), offset); |
| } |
| TypedPointer addressFor(VirtualRegister operand, ptrdiff_t offset = 0) |
| { |
| if (operand.isLocal()) |
| return addressFor(m_captured, operand.offset(), offset); |
| return addressFor(m_callFrame, operand.offset(), offset); |
| } |
| TypedPointer payloadFor(int operand) |
| { |
| return payloadFor(VirtualRegister(operand)); |
| } |
| TypedPointer payloadFor(VirtualRegister operand) |
| { |
| return addressFor(operand, PayloadOffset); |
| } |
| TypedPointer tagFor(int operand) |
| { |
| return tagFor(VirtualRegister(operand)); |
| } |
| TypedPointer tagFor(VirtualRegister operand) |
| { |
| return addressFor(operand, TagOffset); |
| } |
| |
| AbstractValue abstractValue(Node* node) |
| { |
| return m_state.forNode(node); |
| } |
| AbstractValue abstractValue(Edge edge) |
| { |
| return abstractValue(edge.node()); |
| } |
| |
| SpeculatedType provenType(Node* node) |
| { |
| return abstractValue(node).m_type; |
| } |
| SpeculatedType provenType(Edge edge) |
| { |
| return provenType(edge.node()); |
| } |
| |
| JSValue provenValue(Node* node) |
| { |
| return abstractValue(node).m_value; |
| } |
| JSValue provenValue(Edge edge) |
| { |
| return provenValue(edge.node()); |
| } |
| |
| StructureAbstractValue abstractStructure(Node* node) |
| { |
| return abstractValue(node).m_structure; |
| } |
| StructureAbstractValue abstractStructure(Edge edge) |
| { |
| return abstractStructure(edge.node()); |
| } |
| |
| void crash() |
| { |
| crash(m_highBlock, m_node); |
| } |
| void crash(DFG::BasicBlock* block, Node* node) |
| { |
| BlockIndex blockIndex = block->index; |
| unsigned nodeIndex = node ? node->index() : UINT_MAX; |
| #if ASSERT_DISABLED |
| m_out.patchpoint(Void)->setGenerator( |
| [=] (CCallHelpers& jit, const StackmapGenerationParams&) { |
| AllowMacroScratchRegisterUsage allowScratch(jit); |
| |
| jit.move(CCallHelpers::TrustedImm32(blockIndex), GPRInfo::regT0); |
| jit.move(CCallHelpers::TrustedImm32(nodeIndex), GPRInfo::regT1); |
| if (node) |
| jit.move(CCallHelpers::TrustedImm32(node->op()), GPRInfo::regT2); |
| jit.abortWithReason(FTLCrash); |
| }); |
| #else |
| m_out.call( |
| Void, |
| m_out.constIntPtr(ftlUnreachable), |
| // We don't want the CodeBlock to have a weak pointer to itself because |
| // that would cause it to always get collected. |
| m_out.constIntPtr(bitwise_cast<intptr_t>(codeBlock())), m_out.constInt32(blockIndex), |
| m_out.constInt32(nodeIndex)); |
| #endif |
| m_out.unreachable(); |
| } |
| |
| AvailabilityMap& availabilityMap() { return m_availabilityCalculator.m_availability; } |
| |
| VM& vm() { return m_graph.m_vm; } |
| CodeBlock* codeBlock() { return m_graph.m_codeBlock; } |
| |
| Graph& m_graph; |
| State& m_ftlState; |
| AbstractHeapRepository m_heaps; |
| Output m_out; |
| Procedure& m_proc; |
| |
| LBasicBlock m_handleExceptions; |
| HashMap<DFG::BasicBlock*, LBasicBlock> m_blocks; |
| |
| LValue m_callFrame; |
| LValue m_captured; |
| LValue m_tagTypeNumber; |
| LValue m_tagMask; |
| |
| HashMap<Node*, LoweredNodeValue> m_int32Values; |
| HashMap<Node*, LoweredNodeValue> m_strictInt52Values; |
| HashMap<Node*, LoweredNodeValue> m_int52Values; |
| HashMap<Node*, LoweredNodeValue> m_jsValueValues; |
| HashMap<Node*, LoweredNodeValue> m_booleanValues; |
| HashMap<Node*, LoweredNodeValue> m_storageValues; |
| HashMap<Node*, LoweredNodeValue> m_doubleValues; |
| |
| HashMap<Node*, LValue> m_phis; |
| |
| LocalOSRAvailabilityCalculator m_availabilityCalculator; |
| |
| Vector<AvailableRecovery, 3> m_availableRecoveries; |
| |
| InPlaceAbstractState m_state; |
| AbstractInterpreter<InPlaceAbstractState> m_interpreter; |
| DFG::BasicBlock* m_highBlock; |
| DFG::BasicBlock* m_nextHighBlock; |
| LBasicBlock m_nextLowBlock; |
| |
| enum IndexMaskingMode { IndexMaskingDisabled, IndexMaskingEnabled }; |
| |
| IndexMaskingMode m_indexMaskingMode; |
| |
| NodeOrigin m_origin; |
| unsigned m_nodeIndex; |
| Node* m_node; |
| }; |
| |
| } // anonymous namespace |
| |
| void lowerDFGToB3(State& state) |
| { |
| LowerDFGToB3 lowering(state); |
| lowering.lower(); |
| } |
| |
| } } // namespace JSC::FTL |
| |
| #endif // ENABLE(FTL_JIT) |
| |