/* -*- Mode: C++; tab-width: 8; indent-tabs-mode: nil; c-basic-offset: 2 -*- * vim: set ts=8 sts=2 et sw=2 tw=80: * This Source Code Form is subject to the terms of the Mozilla Public * License, v. 2.0. If a copy of the MPL was not distributed with this * file, You can obtain one at http://mozilla.org/MPL/2.0/. */ #include "jit/BaselineIC.h" #include "mozilla/DebugOnly.h" #include "mozilla/Sprintf.h" #include "jstypes.h" #include "builtin/Eval.h" #include "jit/BaselineCacheIRCompiler.h" #include "jit/CacheIRGenerator.h" #include "jit/CacheIRHealth.h" #include "jit/JitFrames.h" #include "jit/JitRuntime.h" #include "jit/JitSpewer.h" #include "jit/Linker.h" #include "jit/PerfSpewer.h" #include "jit/SharedICHelpers.h" #include "jit/SharedICRegisters.h" #include "jit/VMFunctions.h" #include "js/Conversions.h" #include "js/friend/ErrorMessages.h" // JSMSG_* #include "vm/BytecodeIterator.h" #include "vm/BytecodeLocation.h" #include "vm/BytecodeUtil.h" #include "vm/EqualityOperations.h" #include "vm/JSFunction.h" #include "vm/JSScript.h" #include "vm/Opcodes.h" #ifdef MOZ_VTUNE # include "vtune/VTuneWrapper.h" #endif #include "jit/MacroAssembler-inl.h" #include "jit/SharedICHelpers-inl.h" #include "jit/VMFunctionList-inl.h" #include "vm/BytecodeIterator-inl.h" #include "vm/BytecodeLocation-inl.h" #include "vm/EnvironmentObject-inl.h" #include "vm/Interpreter-inl.h" #include "vm/JSScript-inl.h" using mozilla::DebugOnly; namespace js { namespace jit { // Class used to emit all Baseline IC fallback code when initializing the // JitRuntime. class MOZ_RAII FallbackICCodeCompiler final { BaselineICFallbackCode& code; MacroAssembler& masm; JSContext* cx; bool inStubFrame_ = false; #ifdef DEBUG bool entersStubFrame_ = false; uint32_t framePushedAtEnterStubFrame_ = 0; #endif [[nodiscard]] bool emitCall(bool isSpread, bool isConstructing); [[nodiscard]] bool emitGetElem(bool hasReceiver); [[nodiscard]] bool emitGetProp(bool hasReceiver); public: FallbackICCodeCompiler(JSContext* cx, BaselineICFallbackCode& code, MacroAssembler& masm) : code(code), masm(masm), cx(cx) {} #define DEF_METHOD(kind) [[nodiscard]] bool emit_##kind(); IC_BASELINE_FALLBACK_CODE_KIND_LIST(DEF_METHOD) #undef DEF_METHOD void pushCallArguments(MacroAssembler& masm, AllocatableGeneralRegisterSet regs, Register argcReg, bool isConstructing); // Push a payload specialized per compiler needed to execute stubs. void PushStubPayload(MacroAssembler& masm, Register scratch); void pushStubPayload(MacroAssembler& masm, Register scratch); // Emits a tail call to a VMFunction wrapper. [[nodiscard]] bool tailCallVMInternal(MacroAssembler& masm, TailCallVMFunctionId id); template [[nodiscard]] bool tailCallVM(MacroAssembler& masm); // Emits a normal (non-tail) call to a VMFunction wrapper. [[nodiscard]] bool callVMInternal(MacroAssembler& masm, VMFunctionId id); template [[nodiscard]] bool callVM(MacroAssembler& masm); // A stub frame is used when a stub wants to call into the VM without // performing a tail call. This is required for the return address // to pc mapping to work. void enterStubFrame(MacroAssembler& masm, Register scratch); void assumeStubFrame(); void leaveStubFrame(MacroAssembler& masm); }; AllocatableGeneralRegisterSet BaselineICAvailableGeneralRegs(size_t numInputs) { AllocatableGeneralRegisterSet regs(GeneralRegisterSet::All()); MOZ_ASSERT(!regs.has(FramePointer)); #if defined(JS_CODEGEN_ARM) MOZ_ASSERT(!regs.has(ICTailCallReg)); regs.take(BaselineSecondScratchReg); #elif defined(JS_CODEGEN_MIPS32) || defined(JS_CODEGEN_MIPS64) MOZ_ASSERT(!regs.has(ICTailCallReg)); MOZ_ASSERT(!regs.has(BaselineSecondScratchReg)); #elif defined(JS_CODEGEN_ARM64) MOZ_ASSERT(!regs.has(PseudoStackPointer)); MOZ_ASSERT(!regs.has(RealStackPointer)); MOZ_ASSERT(!regs.has(ICTailCallReg)); #endif regs.take(ICStubReg); switch (numInputs) { case 0: break; case 1: regs.take(R0); break; case 2: regs.take(R0); regs.take(R1); break; default: MOZ_CRASH("Invalid numInputs"); } return regs; } static jsbytecode* StubOffsetToPc(const ICFallbackStub* stub, const JSScript* script) { return script->offsetToPC(stub->pcOffset()); } #ifdef JS_JITSPEW void FallbackICSpew(JSContext* cx, ICFallbackStub* stub, const char* fmt, ...) { if (JitSpewEnabled(JitSpew_BaselineICFallback)) { RootedScript script(cx, GetTopJitJSScript(cx)); jsbytecode* pc = StubOffsetToPc(stub, script); char fmtbuf[100]; va_list args; va_start(args, fmt); (void)VsprintfLiteral(fmtbuf, fmt, args); va_end(args); JitSpew( JitSpew_BaselineICFallback, "Fallback hit for (%s:%u:%u) (pc=%zu,line=%u,uses=%u,stubs=%zu): %s", script->filename(), script->lineno(), script->column(), script->pcToOffset(pc), PCToLineNumber(script, pc), script->getWarmUpCount(), stub->numOptimizedStubs(), fmtbuf); } } #endif // JS_JITSPEW void ICEntry::trace(JSTracer* trc) { ICStub* stub = firstStub(); // Trace CacheIR stubs. while (!stub->isFallback()) { stub->toCacheIRStub()->trace(trc); stub = stub->toCacheIRStub()->next(); } // Fallback stubs use runtime-wide trampoline code we don't need to trace. MOZ_ASSERT(stub->usesTrampolineCode()); } // constexpr table mapping JSOp to BaselineICFallbackKind. Each value in the // table is either a fallback kind or a sentinel value (NoICValue) indicating // the JSOp is not a JOF_IC op. class MOZ_STATIC_CLASS OpToFallbackKindTable { static_assert(sizeof(BaselineICFallbackKind) == sizeof(uint8_t)); uint8_t table_[JSOP_LIMIT] = {}; constexpr void setKind(JSOp op, BaselineICFallbackKind kind) { MOZ_ASSERT(uint8_t(kind) != NoICValue); table_[size_t(op)] = uint8_t(kind); } public: static constexpr uint8_t NoICValue = uint8_t(BaselineICFallbackKind::Count); uint8_t lookup(JSOp op) const { return table_[size_t(op)]; } constexpr OpToFallbackKindTable() { for (size_t i = 0; i < JSOP_LIMIT; i++) { table_[i] = NoICValue; } setKind(JSOp::Not, BaselineICFallbackKind::ToBool); setKind(JSOp::And, BaselineICFallbackKind::ToBool); setKind(JSOp::Or, BaselineICFallbackKind::ToBool); setKind(JSOp::JumpIfTrue, BaselineICFallbackKind::ToBool); setKind(JSOp::JumpIfFalse, BaselineICFallbackKind::ToBool); setKind(JSOp::BitNot, BaselineICFallbackKind::UnaryArith); setKind(JSOp::Pos, BaselineICFallbackKind::UnaryArith); setKind(JSOp::Neg, BaselineICFallbackKind::UnaryArith); setKind(JSOp::Inc, BaselineICFallbackKind::UnaryArith); setKind(JSOp::Dec, BaselineICFallbackKind::UnaryArith); setKind(JSOp::ToNumeric, BaselineICFallbackKind::UnaryArith); setKind(JSOp::BitOr, BaselineICFallbackKind::BinaryArith); setKind(JSOp::BitXor, BaselineICFallbackKind::BinaryArith); setKind(JSOp::BitAnd, BaselineICFallbackKind::BinaryArith); setKind(JSOp::Lsh, BaselineICFallbackKind::BinaryArith); setKind(JSOp::Rsh, BaselineICFallbackKind::BinaryArith); setKind(JSOp::Ursh, BaselineICFallbackKind::BinaryArith); setKind(JSOp::Add, BaselineICFallbackKind::BinaryArith); setKind(JSOp::Sub, BaselineICFallbackKind::BinaryArith); setKind(JSOp::Mul, BaselineICFallbackKind::BinaryArith); setKind(JSOp::Div, BaselineICFallbackKind::BinaryArith); setKind(JSOp::Mod, BaselineICFallbackKind::BinaryArith); setKind(JSOp::Pow, BaselineICFallbackKind::BinaryArith); setKind(JSOp::Eq, BaselineICFallbackKind::Compare); setKind(JSOp::Ne, BaselineICFallbackKind::Compare); setKind(JSOp::Lt, BaselineICFallbackKind::Compare); setKind(JSOp::Le, BaselineICFallbackKind::Compare); setKind(JSOp::Gt, BaselineICFallbackKind::Compare); setKind(JSOp::Ge, BaselineICFallbackKind::Compare); setKind(JSOp::StrictEq, BaselineICFallbackKind::Compare); setKind(JSOp::StrictNe, BaselineICFallbackKind::Compare); setKind(JSOp::NewArray, BaselineICFallbackKind::NewArray); setKind(JSOp::NewObject, BaselineICFallbackKind::NewObject); setKind(JSOp::NewInit, BaselineICFallbackKind::NewObject); setKind(JSOp::InitElem, BaselineICFallbackKind::SetElem); setKind(JSOp::InitHiddenElem, BaselineICFallbackKind::SetElem); setKind(JSOp::InitLockedElem, BaselineICFallbackKind::SetElem); setKind(JSOp::InitElemInc, BaselineICFallbackKind::SetElem); setKind(JSOp::SetElem, BaselineICFallbackKind::SetElem); setKind(JSOp::StrictSetElem, BaselineICFallbackKind::SetElem); setKind(JSOp::InitProp, BaselineICFallbackKind::SetProp); setKind(JSOp::InitLockedProp, BaselineICFallbackKind::SetProp); setKind(JSOp::InitHiddenProp, BaselineICFallbackKind::SetProp); setKind(JSOp::InitGLexical, BaselineICFallbackKind::SetProp); setKind(JSOp::SetProp, BaselineICFallbackKind::SetProp); setKind(JSOp::StrictSetProp, BaselineICFallbackKind::SetProp); setKind(JSOp::SetName, BaselineICFallbackKind::SetProp); setKind(JSOp::StrictSetName, BaselineICFallbackKind::SetProp); setKind(JSOp::SetGName, BaselineICFallbackKind::SetProp); setKind(JSOp::StrictSetGName, BaselineICFallbackKind::SetProp); setKind(JSOp::GetProp, BaselineICFallbackKind::GetProp); setKind(JSOp::GetBoundName, BaselineICFallbackKind::GetProp); setKind(JSOp::GetPropSuper, BaselineICFallbackKind::GetPropSuper); setKind(JSOp::GetElem, BaselineICFallbackKind::GetElem); setKind(JSOp::GetElemSuper, BaselineICFallbackKind::GetElemSuper); setKind(JSOp::In, BaselineICFallbackKind::In); setKind(JSOp::HasOwn, BaselineICFallbackKind::HasOwn); setKind(JSOp::CheckPrivateField, BaselineICFallbackKind::CheckPrivateField); setKind(JSOp::GetName, BaselineICFallbackKind::GetName); setKind(JSOp::GetGName, BaselineICFallbackKind::GetName); setKind(JSOp::BindName, BaselineICFallbackKind::BindName); setKind(JSOp::BindGName, BaselineICFallbackKind::BindName); setKind(JSOp::GetIntrinsic, BaselineICFallbackKind::GetIntrinsic); setKind(JSOp::Call, BaselineICFallbackKind::Call); setKind(JSOp::CallContent, BaselineICFallbackKind::Call); setKind(JSOp::CallIgnoresRv, BaselineICFallbackKind::Call); setKind(JSOp::CallIter, BaselineICFallbackKind::Call); setKind(JSOp::CallContentIter, BaselineICFallbackKind::Call); setKind(JSOp::Eval, BaselineICFallbackKind::Call); setKind(JSOp::StrictEval, BaselineICFallbackKind::Call); setKind(JSOp::SuperCall, BaselineICFallbackKind::CallConstructing); setKind(JSOp::New, BaselineICFallbackKind::CallConstructing); setKind(JSOp::NewContent, BaselineICFallbackKind::CallConstructing); setKind(JSOp::SpreadCall, BaselineICFallbackKind::SpreadCall); setKind(JSOp::SpreadEval, BaselineICFallbackKind::SpreadCall); setKind(JSOp::StrictSpreadEval, BaselineICFallbackKind::SpreadCall); setKind(JSOp::SpreadSuperCall, BaselineICFallbackKind::SpreadCallConstructing); setKind(JSOp::SpreadNew, BaselineICFallbackKind::SpreadCallConstructing); setKind(JSOp::Instanceof, BaselineICFallbackKind::InstanceOf); setKind(JSOp::Typeof, BaselineICFallbackKind::TypeOf); setKind(JSOp::TypeofExpr, BaselineICFallbackKind::TypeOf); setKind(JSOp::ToPropertyKey, BaselineICFallbackKind::ToPropertyKey); setKind(JSOp::Iter, BaselineICFallbackKind::GetIterator); setKind(JSOp::OptimizeSpreadCall, BaselineICFallbackKind::OptimizeSpreadCall); setKind(JSOp::Rest, BaselineICFallbackKind::Rest); setKind(JSOp::CloseIter, BaselineICFallbackKind::CloseIter); } }; static constexpr OpToFallbackKindTable FallbackKindTable; void ICScript::initICEntries(JSContext* cx, JSScript* script) { MOZ_ASSERT(cx->realm()->jitRealm()); MOZ_ASSERT(jit::IsBaselineInterpreterEnabled()); MOZ_ASSERT(numICEntries() == script->numICEntries()); // Index of the next ICEntry to initialize. uint32_t icEntryIndex = 0; const BaselineICFallbackCode& fallbackCode = cx->runtime()->jitRuntime()->baselineICFallbackCode(); // For JOF_IC ops: initialize ICEntries and fallback stubs. for (BytecodeLocation loc : js::AllBytecodesIterable(script)) { JSOp op = loc.getOp(); // Assert the frontend stored the correct IC index in jump target ops. MOZ_ASSERT_IF(BytecodeIsJumpTarget(op), loc.icIndex() == icEntryIndex); uint8_t tableValue = FallbackKindTable.lookup(op); if (tableValue == OpToFallbackKindTable::NoICValue) { MOZ_ASSERT(!BytecodeOpHasIC(op), "Missing entry in OpToFallbackKindTable for JOF_IC op"); continue; } MOZ_ASSERT(BytecodeOpHasIC(op), "Unexpected fallback kind for non-JOF_IC op"); BaselineICFallbackKind kind = BaselineICFallbackKind(tableValue); TrampolinePtr stubCode = fallbackCode.addr(kind); // Initialize the ICEntry and ICFallbackStub. uint32_t offset = loc.bytecodeToOffset(script); ICEntry& entryRef = this->icEntry(icEntryIndex); ICFallbackStub* stub = fallbackStub(icEntryIndex); icEntryIndex++; new (&entryRef) ICEntry(stub); new (stub) ICFallbackStub(offset, stubCode); } // Assert all ICEntries have been initialized. MOZ_ASSERT(icEntryIndex == numICEntries()); } bool ICSupportsPolymorphicTypeData(JSOp op) { MOZ_ASSERT(BytecodeOpHasIC(op)); BaselineICFallbackKind kind = BaselineICFallbackKind(FallbackKindTable.lookup(op)); switch (kind) { case BaselineICFallbackKind::ToBool: case BaselineICFallbackKind::TypeOf: return true; default: return false; } } bool ICCacheIRStub::makesGCCalls() const { return stubInfo()->makesGCCalls(); } void ICFallbackStub::trackNotAttached() { state().trackNotAttached(); } // When we enter a baseline fallback stub, if a Warp compilation // exists that transpiled that IC, we notify that compilation. This // helps the bailout code tell whether a bailing instruction hoisted // by LICM would have been executed anyway. static void MaybeNotifyWarp(JSScript* script, ICFallbackStub* stub) { if (stub->state().usedByTranspiler() && script->hasIonScript()) { script->ionScript()->noteBaselineFallback(); } } void ICCacheIRStub::trace(JSTracer* trc) { JitCode* stubJitCode = jitCode(); TraceManuallyBarrieredEdge(trc, &stubJitCode, "baseline-ic-stub-code"); TraceCacheIRStub(trc, this, stubInfo()); } static void MaybeTransition(JSContext* cx, BaselineFrame* frame, ICFallbackStub* stub) { if (stub->state().shouldTransition()) { if (!TryFoldingStubs(cx, stub, frame->script(), frame->icScript())) { cx->recoverFromOutOfMemory(); } if (stub->state().maybeTransition()) { ICEntry* icEntry = frame->icScript()->icEntryForStub(stub); #ifdef JS_CACHEIR_SPEW if (cx->spewer().enabled(cx, frame->script(), SpewChannel::CacheIRHealthReport)) { CacheIRHealth cih; RootedScript script(cx, frame->script()); cih.healthReportForIC(cx, icEntry, stub, script, SpewContext::Transition); } #endif stub->discardStubs(cx, icEntry); } } } // This helper handles ICState updates/transitions while attaching CacheIR // stubs. template static void TryAttachStub(const char* name, JSContext* cx, BaselineFrame* frame, ICFallbackStub* stub, Args&&... args) { MaybeTransition(cx, frame, stub); if (stub->state().canAttachStub()) { RootedScript script(cx, frame->script()); ICScript* icScript = frame->icScript(); jsbytecode* pc = StubOffsetToPc(stub, script); bool attached = false; IRGenerator gen(cx, script, pc, stub->state(), std::forward(args)...); switch (gen.tryAttachStub()) { case AttachDecision::Attach: { ICAttachResult result = AttachBaselineCacheIRStub(cx, gen.writerRef(), gen.cacheKind(), script, icScript, stub, gen.stubName()); if (result == ICAttachResult::Attached) { attached = true; JitSpew(JitSpew_BaselineIC, " Attached %s CacheIR stub", name); } } break; case AttachDecision::NoAction: break; case AttachDecision::TemporarilyUnoptimizable: case AttachDecision::Deferred: MOZ_ASSERT_UNREACHABLE("Not expected in generic TryAttachStub"); break; } if (!attached) { stub->trackNotAttached(); } } } void ICFallbackStub::unlinkStub(Zone* zone, ICEntry* icEntry, ICCacheIRStub* prev, ICCacheIRStub* stub) { if (prev) { MOZ_ASSERT(prev->next() == stub); prev->setNext(stub->next()); } else { MOZ_ASSERT(icEntry->firstStub() == stub); icEntry->setFirstStub(stub->next()); } state_.trackUnlinkedStub(); // We are removing edges from ICStub to gcthings. Perform a barrier to let the // GC know about those edges. PreWriteBarrier(zone, stub); #ifdef DEBUG // Poison stub code to ensure we don't call this stub again. However, if // this stub can make calls, a pointer to it may be stored in a stub frame // on the stack, so we can't touch the stubCode_ or GC will crash when // tracing this pointer. if (!stub->makesGCCalls()) { stub->stubCode_ = (uint8_t*)0xbad; } #endif } void ICFallbackStub::discardStubs(JSContext* cx, ICEntry* icEntry) { ICStub* stub = icEntry->firstStub(); while (stub != this) { unlinkStub(cx->zone(), icEntry, /* prev = */ nullptr, stub->toCacheIRStub()); stub = stub->toCacheIRStub()->next(); } clearHasFoldedStub(); } static void InitMacroAssemblerForICStub(StackMacroAssembler& masm) { #ifndef JS_USE_LINK_REGISTER // The first value contains the return addres, // which we pull into ICTailCallReg for tail calls. masm.adjustFrame(sizeof(intptr_t)); #endif #ifdef JS_CODEGEN_ARM masm.setSecondScratchReg(BaselineSecondScratchReg); #endif } bool FallbackICCodeCompiler::tailCallVMInternal(MacroAssembler& masm, TailCallVMFunctionId id) { TrampolinePtr code = cx->runtime()->jitRuntime()->getVMWrapper(id); const VMFunctionData& fun = GetVMFunction(id); MOZ_ASSERT(fun.expectTailCall == TailCall); uint32_t argSize = fun.explicitStackSlots() * sizeof(void*); EmitBaselineTailCallVM(code, masm, argSize); return true; } bool FallbackICCodeCompiler::callVMInternal(MacroAssembler& masm, VMFunctionId id) { MOZ_ASSERT(inStubFrame_); TrampolinePtr code = cx->runtime()->jitRuntime()->getVMWrapper(id); MOZ_ASSERT(GetVMFunction(id).expectTailCall == NonTailCall); EmitBaselineCallVM(code, masm); return true; } template bool FallbackICCodeCompiler::callVM(MacroAssembler& masm) { VMFunctionId id = VMFunctionToId::id; return callVMInternal(masm, id); } template bool FallbackICCodeCompiler::tailCallVM(MacroAssembler& masm) { TailCallVMFunctionId id = TailCallVMFunctionToId::id; return tailCallVMInternal(masm, id); } void FallbackICCodeCompiler::enterStubFrame(MacroAssembler& masm, Register scratch) { EmitBaselineEnterStubFrame(masm, scratch); #ifdef DEBUG framePushedAtEnterStubFrame_ = masm.framePushed(); #endif MOZ_ASSERT(!inStubFrame_); inStubFrame_ = true; #ifdef DEBUG entersStubFrame_ = true; #endif } void FallbackICCodeCompiler::assumeStubFrame() { MOZ_ASSERT(!inStubFrame_); inStubFrame_ = true; #ifdef DEBUG entersStubFrame_ = true; // |framePushed| isn't tracked precisely in ICStubs, so simply assume it to // be the stub frame layout and the pushed ICStub* so that assertions don't // fail in leaveStubFrame framePushedAtEnterStubFrame_ = BaselineStubFrameLayout::Size() + sizeof(ICStub*); #endif } void FallbackICCodeCompiler::leaveStubFrame(MacroAssembler& masm) { MOZ_ASSERT(entersStubFrame_ && inStubFrame_); inStubFrame_ = false; #ifdef DEBUG masm.setFramePushed(framePushedAtEnterStubFrame_); #endif EmitBaselineLeaveStubFrame(masm); } void FallbackICCodeCompiler::pushStubPayload(MacroAssembler& masm, Register scratch) { if (inStubFrame_) { masm.loadPtr(Address(FramePointer, 0), scratch); masm.pushBaselineFramePtr(scratch, scratch); } else { masm.pushBaselineFramePtr(FramePointer, scratch); } } void FallbackICCodeCompiler::PushStubPayload(MacroAssembler& masm, Register scratch) { pushStubPayload(masm, scratch); masm.adjustFrame(sizeof(intptr_t)); } // // ToBool_Fallback // bool DoToBoolFallback(JSContext* cx, BaselineFrame* frame, ICFallbackStub* stub, HandleValue arg, MutableHandleValue ret) { stub->incrementEnteredCount(); MaybeNotifyWarp(frame->outerScript(), stub); FallbackICSpew(cx, stub, "ToBool"); TryAttachStub("ToBool", cx, frame, stub, arg); bool cond = ToBoolean(arg); ret.setBoolean(cond); return true; } bool FallbackICCodeCompiler::emit_ToBool() { static_assert(R0 == JSReturnOperand); // Restore the tail call register. EmitRestoreTailCallReg(masm); // Push arguments. masm.pushValue(R0); masm.push(ICStubReg); pushStubPayload(masm, R0.scratchReg()); using Fn = bool (*)(JSContext*, BaselineFrame*, ICFallbackStub*, HandleValue, MutableHandleValue); return tailCallVM(masm); } // // GetElem_Fallback // bool DoGetElemFallback(JSContext* cx, BaselineFrame* frame, ICFallbackStub* stub, HandleValue lhs, HandleValue rhs, MutableHandleValue res) { stub->incrementEnteredCount(); MaybeNotifyWarp(frame->outerScript(), stub); FallbackICSpew(cx, stub, "GetElem"); #ifdef DEBUG jsbytecode* pc = StubOffsetToPc(stub, frame->script()); MOZ_ASSERT(JSOp(*pc) == JSOp::GetElem); #endif TryAttachStub("GetElem", cx, frame, stub, CacheKind::GetElem, lhs, rhs); if (!GetElementOperation(cx, lhs, rhs, res)) { return false; } return true; } bool DoGetElemSuperFallback(JSContext* cx, BaselineFrame* frame, ICFallbackStub* stub, HandleValue lhs, HandleValue rhs, HandleValue receiver, MutableHandleValue res) { stub->incrementEnteredCount(); MaybeNotifyWarp(frame->outerScript(), stub); jsbytecode* pc = StubOffsetToPc(stub, frame->script()); JSOp op = JSOp(*pc); FallbackICSpew(cx, stub, "GetElemSuper(%s)", CodeName(op)); MOZ_ASSERT(op == JSOp::GetElemSuper); // |lhs| is [[HomeObject]].[[Prototype]] which must be an Object or null. MOZ_ASSERT(lhs.isObjectOrNull()); int lhsIndex = -1; RootedObject lhsObj( cx, ToObjectFromStackForPropertyAccess(cx, lhs, lhsIndex, rhs)); if (!lhsObj) { return false; } TryAttachStub("GetElemSuper", cx, frame, stub, CacheKind::GetElemSuper, lhs, rhs); return GetObjectElementOperation(cx, op, lhsObj, receiver, rhs, res); } bool FallbackICCodeCompiler::emitGetElem(bool hasReceiver) { static_assert(R0 == JSReturnOperand); // Restore the tail call register. EmitRestoreTailCallReg(masm); // Super property getters use a |this| that differs from base object if (hasReceiver) { // State: receiver in R0, index in R1, obj on the stack // Ensure stack is fully synced for the expression decompiler. // We need: receiver, index, obj masm.pushValue(R0); masm.pushValue(R1); masm.pushValue(Address(masm.getStackPointer(), sizeof(Value) * 2)); // Push arguments. masm.pushValue(R0); // Receiver masm.pushValue(R1); // Index masm.pushValue(Address(masm.getStackPointer(), sizeof(Value) * 5)); // Obj masm.push(ICStubReg); masm.pushBaselineFramePtr(FramePointer, R0.scratchReg()); using Fn = bool (*)(JSContext*, BaselineFrame*, ICFallbackStub*, HandleValue, HandleValue, HandleValue, MutableHandleValue); if (!tailCallVM(masm)) { return false; } } else { // Ensure stack is fully synced for the expression decompiler. masm.pushValue(R0); masm.pushValue(R1); // Push arguments. masm.pushValue(R1); masm.pushValue(R0); masm.push(ICStubReg); masm.pushBaselineFramePtr(FramePointer, R0.scratchReg()); using Fn = bool (*)(JSContext*, BaselineFrame*, ICFallbackStub*, HandleValue, HandleValue, MutableHandleValue); if (!tailCallVM(masm)) { return false; } } // This is the resume point used when bailout rewrites call stack to undo // Ion inlined frames. The return address pushed onto reconstructed stack // will point here. assumeStubFrame(); if (hasReceiver) { code.initBailoutReturnOffset(BailoutReturnKind::GetElemSuper, masm.currentOffset()); } else { code.initBailoutReturnOffset(BailoutReturnKind::GetElem, masm.currentOffset()); } leaveStubFrame(masm); EmitReturnFromIC(masm); return true; } bool FallbackICCodeCompiler::emit_GetElem() { return emitGetElem(/* hasReceiver = */ false); } bool FallbackICCodeCompiler::emit_GetElemSuper() { return emitGetElem(/* hasReceiver = */ true); } bool DoSetElemFallback(JSContext* cx, BaselineFrame* frame, ICFallbackStub* stub, Value* stack, HandleValue objv, HandleValue index, HandleValue rhs) { using DeferType = SetPropIRGenerator::DeferType; stub->incrementEnteredCount(); MaybeNotifyWarp(frame->outerScript(), stub); RootedScript script(cx, frame->script()); RootedScript outerScript(cx, script); jsbytecode* pc = StubOffsetToPc(stub, script); JSOp op = JSOp(*pc); FallbackICSpew(cx, stub, "SetElem(%s)", CodeName(JSOp(*pc))); MOZ_ASSERT(op == JSOp::SetElem || op == JSOp::StrictSetElem || op == JSOp::InitElem || op == JSOp::InitHiddenElem || op == JSOp::InitLockedElem || op == JSOp::InitElemInc); int objvIndex = -3; RootedObject obj( cx, ToObjectFromStackForPropertyAccess(cx, objv, objvIndex, index)); if (!obj) { return false; } Rooted oldShape(cx, obj->shape()); DeferType deferType = DeferType::None; bool attached = false; MaybeTransition(cx, frame, stub); if (stub->state().canAttachStub()) { ICScript* icScript = frame->icScript(); SetPropIRGenerator gen(cx, script, pc, CacheKind::SetElem, stub->state(), objv, index, rhs); switch (gen.tryAttachStub()) { case AttachDecision::Attach: { ICAttachResult result = AttachBaselineCacheIRStub( cx, gen.writerRef(), gen.cacheKind(), frame->script(), icScript, stub, gen.stubName()); if (result == ICAttachResult::Attached) { attached = true; JitSpew(JitSpew_BaselineIC, " Attached SetElem CacheIR stub"); } } break; case AttachDecision::NoAction: break; case AttachDecision::TemporarilyUnoptimizable: attached = true; break; case AttachDecision::Deferred: deferType = gen.deferType(); MOZ_ASSERT(deferType != DeferType::None); break; } } if (op == JSOp::InitElem || op == JSOp::InitHiddenElem || op == JSOp::InitLockedElem) { if (!InitElemOperation(cx, pc, obj, index, rhs)) { return false; } } else if (op == JSOp::InitElemInc) { if (!InitElemIncOperation(cx, obj.as(), index.toInt32(), rhs)) { return false; } } else { if (!SetObjectElementWithReceiver(cx, obj, index, rhs, objv, JSOp(*pc) == JSOp::StrictSetElem)) { return false; } } // Overwrite the object on the stack (pushed for the decompiler) with the rhs. MOZ_ASSERT(stack[2] == objv); stack[2] = rhs; if (attached) { return true; } // The SetObjectElement call might have entered this IC recursively, so try // to transition. MaybeTransition(cx, frame, stub); bool canAttachStub = stub->state().canAttachStub(); if (deferType != DeferType::None && canAttachStub) { SetPropIRGenerator gen(cx, script, pc, CacheKind::SetElem, stub->state(), objv, index, rhs); MOZ_ASSERT(deferType == DeferType::AddSlot); AttachDecision decision = gen.tryAttachAddSlotStub(oldShape); switch (decision) { case AttachDecision::Attach: { ICScript* icScript = frame->icScript(); ICAttachResult result = AttachBaselineCacheIRStub( cx, gen.writerRef(), gen.cacheKind(), frame->script(), icScript, stub, gen.stubName()); if (result == ICAttachResult::Attached) { attached = true; JitSpew(JitSpew_BaselineIC, " Attached SetElem CacheIR stub"); } } break; case AttachDecision::NoAction: gen.trackAttached(IRGenerator::NotAttached); break; case AttachDecision::TemporarilyUnoptimizable: case AttachDecision::Deferred: MOZ_ASSERT_UNREACHABLE("Invalid attach result"); break; } } if (!attached && canAttachStub) { stub->trackNotAttached(); } return true; } bool FallbackICCodeCompiler::emit_SetElem() { static_assert(R0 == JSReturnOperand); EmitRestoreTailCallReg(masm); // State: R0: object, R1: index, stack: rhs. // For the decompiler, the stack has to be: object, index, rhs, // so we push the index, then overwrite the rhs Value with R0 // and push the rhs value. masm.pushValue(R1); masm.loadValue(Address(masm.getStackPointer(), sizeof(Value)), R1); masm.storeValue(R0, Address(masm.getStackPointer(), sizeof(Value))); masm.pushValue(R1); // Push arguments. masm.pushValue(R1); // RHS // Push index. On x86 and ARM two push instructions are emitted so use a // separate register to store the old stack pointer. masm.moveStackPtrTo(R1.scratchReg()); masm.pushValue(Address(R1.scratchReg(), 2 * sizeof(Value))); masm.pushValue(R0); // Object. // Push pointer to stack values, so that the stub can overwrite the object // (pushed for the decompiler) with the rhs. masm.computeEffectiveAddress( Address(masm.getStackPointer(), 3 * sizeof(Value)), R0.scratchReg()); masm.push(R0.scratchReg()); masm.push(ICStubReg); pushStubPayload(masm, R0.scratchReg()); using Fn = bool (*)(JSContext*, BaselineFrame*, ICFallbackStub*, Value*, HandleValue, HandleValue, HandleValue); return tailCallVM(masm); } // // In_Fallback // bool DoInFallback(JSContext* cx, BaselineFrame* frame, ICFallbackStub* stub, HandleValue key, HandleValue objValue, MutableHandleValue res) { stub->incrementEnteredCount(); MaybeNotifyWarp(frame->outerScript(), stub); FallbackICSpew(cx, stub, "In"); if (!objValue.isObject()) { ReportInNotObjectError(cx, key, objValue); return false; } TryAttachStub("In", cx, frame, stub, CacheKind::In, key, objValue); RootedObject obj(cx, &objValue.toObject()); bool cond = false; if (!OperatorIn(cx, key, obj, &cond)) { return false; } res.setBoolean(cond); return true; } bool FallbackICCodeCompiler::emit_In() { EmitRestoreTailCallReg(masm); // Sync for the decompiler. masm.pushValue(R0); masm.pushValue(R1); // Push arguments. masm.pushValue(R1); masm.pushValue(R0); masm.push(ICStubReg); pushStubPayload(masm, R0.scratchReg()); using Fn = bool (*)(JSContext*, BaselineFrame*, ICFallbackStub*, HandleValue, HandleValue, MutableHandleValue); return tailCallVM(masm); } // // HasOwn_Fallback // bool DoHasOwnFallback(JSContext* cx, BaselineFrame* frame, ICFallbackStub* stub, HandleValue keyValue, HandleValue objValue, MutableHandleValue res) { stub->incrementEnteredCount(); MaybeNotifyWarp(frame->outerScript(), stub); FallbackICSpew(cx, stub, "HasOwn"); TryAttachStub("HasOwn", cx, frame, stub, CacheKind::HasOwn, keyValue, objValue); bool found; if (!HasOwnProperty(cx, objValue, keyValue, &found)) { return false; } res.setBoolean(found); return true; } bool FallbackICCodeCompiler::emit_HasOwn() { EmitRestoreTailCallReg(masm); // Sync for the decompiler. masm.pushValue(R0); masm.pushValue(R1); // Push arguments. masm.pushValue(R1); masm.pushValue(R0); masm.push(ICStubReg); pushStubPayload(masm, R0.scratchReg()); using Fn = bool (*)(JSContext*, BaselineFrame*, ICFallbackStub*, HandleValue, HandleValue, MutableHandleValue); return tailCallVM(masm); } // // CheckPrivate_Fallback // bool DoCheckPrivateFieldFallback(JSContext* cx, BaselineFrame* frame, ICFallbackStub* stub, HandleValue objValue, HandleValue keyValue, MutableHandleValue res) { stub->incrementEnteredCount(); MaybeNotifyWarp(frame->outerScript(), stub); jsbytecode* pc = StubOffsetToPc(stub, frame->script()); FallbackICSpew(cx, stub, "CheckPrivateField"); MOZ_ASSERT(keyValue.isSymbol() && keyValue.toSymbol()->isPrivateName()); TryAttachStub("CheckPrivate", cx, frame, stub, CacheKind::CheckPrivateField, keyValue, objValue); bool result; if (!CheckPrivateFieldOperation(cx, pc, objValue, keyValue, &result)) { return false; } res.setBoolean(result); return true; } bool FallbackICCodeCompiler::emit_CheckPrivateField() { EmitRestoreTailCallReg(masm); // Sync for the decompiler. masm.pushValue(R0); masm.pushValue(R1); // Push arguments. masm.pushValue(R1); masm.pushValue(R0); masm.push(ICStubReg); pushStubPayload(masm, R0.scratchReg()); using Fn = bool (*)(JSContext*, BaselineFrame*, ICFallbackStub*, HandleValue, HandleValue, MutableHandleValue); return tailCallVM(masm); } // // GetName_Fallback // bool DoGetNameFallback(JSContext* cx, BaselineFrame* frame, ICFallbackStub* stub, HandleObject envChain, MutableHandleValue res) { stub->incrementEnteredCount(); MaybeNotifyWarp(frame->outerScript(), stub); RootedScript script(cx, frame->script()); jsbytecode* pc = StubOffsetToPc(stub, script); mozilla::DebugOnly op = JSOp(*pc); FallbackICSpew(cx, stub, "GetName(%s)", CodeName(JSOp(*pc))); MOZ_ASSERT(op == JSOp::GetName || op == JSOp::GetGName); Rooted name(cx, script->getName(pc)); TryAttachStub("GetName", cx, frame, stub, envChain, name); static_assert(JSOpLength_GetGName == JSOpLength_GetName, "Otherwise our check for JSOp::Typeof isn't ok"); if (JSOp(pc[JSOpLength_GetGName]) == JSOp::Typeof) { if (!GetEnvironmentName(cx, envChain, name, res)) { return false; } } else { if (!GetEnvironmentName(cx, envChain, name, res)) { return false; } } return true; } bool FallbackICCodeCompiler::emit_GetName() { static_assert(R0 == JSReturnOperand); EmitRestoreTailCallReg(masm); masm.push(R0.scratchReg()); masm.push(ICStubReg); pushStubPayload(masm, R0.scratchReg()); using Fn = bool (*)(JSContext*, BaselineFrame*, ICFallbackStub*, HandleObject, MutableHandleValue); return tailCallVM(masm); } // // BindName_Fallback // bool DoBindNameFallback(JSContext* cx, BaselineFrame* frame, ICFallbackStub* stub, HandleObject envChain, MutableHandleValue res) { stub->incrementEnteredCount(); MaybeNotifyWarp(frame->outerScript(), stub); jsbytecode* pc = StubOffsetToPc(stub, frame->script()); mozilla::DebugOnly op = JSOp(*pc); FallbackICSpew(cx, stub, "BindName(%s)", CodeName(JSOp(*pc))); MOZ_ASSERT(op == JSOp::BindName || op == JSOp::BindGName); Rooted name(cx, frame->script()->getName(pc)); TryAttachStub("BindName", cx, frame, stub, envChain, name); RootedObject scope(cx); if (!LookupNameUnqualified(cx, name, envChain, &scope)) { return false; } res.setObject(*scope); return true; } bool FallbackICCodeCompiler::emit_BindName() { static_assert(R0 == JSReturnOperand); EmitRestoreTailCallReg(masm); masm.push(R0.scratchReg()); masm.push(ICStubReg); pushStubPayload(masm, R0.scratchReg()); using Fn = bool (*)(JSContext*, BaselineFrame*, ICFallbackStub*, HandleObject, MutableHandleValue); return tailCallVM(masm); } // // GetIntrinsic_Fallback // bool DoGetIntrinsicFallback(JSContext* cx, BaselineFrame* frame, ICFallbackStub* stub, MutableHandleValue res) { stub->incrementEnteredCount(); MaybeNotifyWarp(frame->outerScript(), stub); RootedScript script(cx, frame->script()); jsbytecode* pc = StubOffsetToPc(stub, script); mozilla::DebugOnly op = JSOp(*pc); FallbackICSpew(cx, stub, "GetIntrinsic(%s)", CodeName(JSOp(*pc))); MOZ_ASSERT(op == JSOp::GetIntrinsic); if (!GetIntrinsicOperation(cx, script, pc, res)) { return false; } TryAttachStub("GetIntrinsic", cx, frame, stub, res); return true; } bool FallbackICCodeCompiler::emit_GetIntrinsic() { EmitRestoreTailCallReg(masm); masm.push(ICStubReg); pushStubPayload(masm, R0.scratchReg()); using Fn = bool (*)(JSContext*, BaselineFrame*, ICFallbackStub*, MutableHandleValue); return tailCallVM(masm); } // // GetProp_Fallback // bool DoGetPropFallback(JSContext* cx, BaselineFrame* frame, ICFallbackStub* stub, MutableHandleValue val, MutableHandleValue res) { stub->incrementEnteredCount(); MaybeNotifyWarp(frame->outerScript(), stub); RootedScript script(cx, frame->script()); jsbytecode* pc = StubOffsetToPc(stub, script); JSOp op = JSOp(*pc); FallbackICSpew(cx, stub, "GetProp(%s)", CodeName(op)); MOZ_ASSERT(op == JSOp::GetProp || op == JSOp::GetBoundName); Rooted name(cx, script->getName(pc)); RootedValue idVal(cx, StringValue(name)); TryAttachStub("GetProp", cx, frame, stub, CacheKind::GetProp, val, idVal); if (op == JSOp::GetBoundName) { RootedObject env(cx, &val.toObject()); RootedId id(cx, NameToId(name)); return GetNameBoundInEnvironment(cx, env, id, res); } MOZ_ASSERT(op == JSOp::GetProp); if (!GetProperty(cx, val, name, res)) { return false; } return true; } bool DoGetPropSuperFallback(JSContext* cx, BaselineFrame* frame, ICFallbackStub* stub, HandleValue receiver, MutableHandleValue val, MutableHandleValue res) { stub->incrementEnteredCount(); MaybeNotifyWarp(frame->outerScript(), stub); RootedScript script(cx, frame->script()); jsbytecode* pc = StubOffsetToPc(stub, script); FallbackICSpew(cx, stub, "GetPropSuper(%s)", CodeName(JSOp(*pc))); MOZ_ASSERT(JSOp(*pc) == JSOp::GetPropSuper); Rooted name(cx, script->getName(pc)); RootedValue idVal(cx, StringValue(name)); // |val| is [[HomeObject]].[[Prototype]] which must be an Object or null. MOZ_ASSERT(val.isObjectOrNull()); int valIndex = -1; RootedObject valObj( cx, ToObjectFromStackForPropertyAccess(cx, val, valIndex, name)); if (!valObj) { return false; } TryAttachStub("GetPropSuper", cx, frame, stub, CacheKind::GetPropSuper, val, idVal); if (!GetProperty(cx, valObj, receiver, name, res)) { return false; } return true; } bool FallbackICCodeCompiler::emitGetProp(bool hasReceiver) { static_assert(R0 == JSReturnOperand); EmitRestoreTailCallReg(masm); // Super property getters use a |this| that differs from base object if (hasReceiver) { // Push arguments. masm.pushValue(R0); masm.pushValue(R1); masm.push(ICStubReg); masm.pushBaselineFramePtr(FramePointer, R0.scratchReg()); using Fn = bool (*)(JSContext*, BaselineFrame*, ICFallbackStub*, HandleValue, MutableHandleValue, MutableHandleValue); if (!tailCallVM(masm)) { return false; } } else { // Ensure stack is fully synced for the expression decompiler. masm.pushValue(R0); // Push arguments. masm.pushValue(R0); masm.push(ICStubReg); masm.pushBaselineFramePtr(FramePointer, R0.scratchReg()); using Fn = bool (*)(JSContext*, BaselineFrame*, ICFallbackStub*, MutableHandleValue, MutableHandleValue); if (!tailCallVM(masm)) { return false; } } // This is the resume point used when bailout rewrites call stack to undo // Ion inlined frames. The return address pushed onto reconstructed stack // will point here. assumeStubFrame(); if (hasReceiver) { code.initBailoutReturnOffset(BailoutReturnKind::GetPropSuper, masm.currentOffset()); } else { code.initBailoutReturnOffset(BailoutReturnKind::GetProp, masm.currentOffset()); } leaveStubFrame(masm); EmitReturnFromIC(masm); return true; } bool FallbackICCodeCompiler::emit_GetProp() { return emitGetProp(/* hasReceiver = */ false); } bool FallbackICCodeCompiler::emit_GetPropSuper() { return emitGetProp(/* hasReceiver = */ true); } // // SetProp_Fallback // bool DoSetPropFallback(JSContext* cx, BaselineFrame* frame, ICFallbackStub* stub, Value* stack, HandleValue lhs, HandleValue rhs) { using DeferType = SetPropIRGenerator::DeferType; stub->incrementEnteredCount(); MaybeNotifyWarp(frame->outerScript(), stub); RootedScript script(cx, frame->script()); jsbytecode* pc = StubOffsetToPc(stub, script); JSOp op = JSOp(*pc); FallbackICSpew(cx, stub, "SetProp(%s)", CodeName(op)); MOZ_ASSERT(op == JSOp::SetProp || op == JSOp::StrictSetProp || op == JSOp::SetName || op == JSOp::StrictSetName || op == JSOp::SetGName || op == JSOp::StrictSetGName || op == JSOp::InitProp || op == JSOp::InitLockedProp || op == JSOp::InitHiddenProp || op == JSOp::InitGLexical); Rooted name(cx, script->getName(pc)); RootedId id(cx, NameToId(name)); int lhsIndex = -2; RootedObject obj(cx, ToObjectFromStackForPropertyAccess(cx, lhs, lhsIndex, id)); if (!obj) { return false; } Rooted oldShape(cx, obj->shape()); DeferType deferType = DeferType::None; bool attached = false; MaybeTransition(cx, frame, stub); if (stub->state().canAttachStub()) { RootedValue idVal(cx, StringValue(name)); SetPropIRGenerator gen(cx, script, pc, CacheKind::SetProp, stub->state(), lhs, idVal, rhs); switch (gen.tryAttachStub()) { case AttachDecision::Attach: { ICScript* icScript = frame->icScript(); ICAttachResult result = AttachBaselineCacheIRStub( cx, gen.writerRef(), gen.cacheKind(), frame->script(), icScript, stub, gen.stubName()); if (result == ICAttachResult::Attached) { attached = true; JitSpew(JitSpew_BaselineIC, " Attached SetProp CacheIR stub"); } } break; case AttachDecision::NoAction: break; case AttachDecision::TemporarilyUnoptimizable: attached = true; break; case AttachDecision::Deferred: deferType = gen.deferType(); MOZ_ASSERT(deferType != DeferType::None); break; } } if (op == JSOp::InitProp || op == JSOp::InitLockedProp || op == JSOp::InitHiddenProp) { if (!InitPropertyOperation(cx, pc, obj, name, rhs)) { return false; } } else if (op == JSOp::SetName || op == JSOp::StrictSetName || op == JSOp::SetGName || op == JSOp::StrictSetGName) { if (!SetNameOperation(cx, script, pc, obj, rhs)) { return false; } } else if (op == JSOp::InitGLexical) { ExtensibleLexicalEnvironmentObject* lexicalEnv; if (script->hasNonSyntacticScope()) { lexicalEnv = &NearestEnclosingExtensibleLexicalEnvironment( frame->environmentChain()); } else { lexicalEnv = &cx->global()->lexicalEnvironment(); } InitGlobalLexicalOperation(cx, lexicalEnv, script, pc, rhs); } else { MOZ_ASSERT(op == JSOp::SetProp || op == JSOp::StrictSetProp); ObjectOpResult result; if (!SetProperty(cx, obj, id, rhs, lhs, result) || !result.checkStrictModeError(cx, obj, id, op == JSOp::StrictSetProp)) { return false; } } // Overwrite the LHS on the stack (pushed for the decompiler) with the RHS. MOZ_ASSERT(stack[1] == lhs); stack[1] = rhs; if (attached) { return true; } // The SetProperty call might have entered this IC recursively, so try // to transition. MaybeTransition(cx, frame, stub); bool canAttachStub = stub->state().canAttachStub(); if (deferType != DeferType::None && canAttachStub) { RootedValue idVal(cx, StringValue(name)); SetPropIRGenerator gen(cx, script, pc, CacheKind::SetProp, stub->state(), lhs, idVal, rhs); MOZ_ASSERT(deferType == DeferType::AddSlot); AttachDecision decision = gen.tryAttachAddSlotStub(oldShape); switch (decision) { case AttachDecision::Attach: { ICScript* icScript = frame->icScript(); ICAttachResult result = AttachBaselineCacheIRStub( cx, gen.writerRef(), gen.cacheKind(), frame->script(), icScript, stub, gen.stubName()); if (result == ICAttachResult::Attached) { attached = true; JitSpew(JitSpew_BaselineIC, " Attached SetElem CacheIR stub"); } } break; case AttachDecision::NoAction: gen.trackAttached(IRGenerator::NotAttached); break; case AttachDecision::TemporarilyUnoptimizable: case AttachDecision::Deferred: MOZ_ASSERT_UNREACHABLE("Invalid attach result"); break; } } if (!attached && canAttachStub) { stub->trackNotAttached(); } return true; } bool FallbackICCodeCompiler::emit_SetProp() { static_assert(R0 == JSReturnOperand); EmitRestoreTailCallReg(masm); // Ensure stack is fully synced for the expression decompiler. // Overwrite the RHS value on top of the stack with the object, then push // the RHS in R1 on top of that. masm.storeValue(R0, Address(masm.getStackPointer(), 0)); masm.pushValue(R1); // Push arguments. masm.pushValue(R1); masm.pushValue(R0); // Push pointer to stack values, so that the stub can overwrite the object // (pushed for the decompiler) with the RHS. masm.computeEffectiveAddress( Address(masm.getStackPointer(), 2 * sizeof(Value)), R0.scratchReg()); masm.push(R0.scratchReg()); masm.push(ICStubReg); pushStubPayload(masm, R0.scratchReg()); using Fn = bool (*)(JSContext*, BaselineFrame*, ICFallbackStub*, Value*, HandleValue, HandleValue); if (!tailCallVM(masm)) { return false; } // This is the resume point used when bailout rewrites call stack to undo // Ion inlined frames. The return address pushed onto reconstructed stack // will point here. assumeStubFrame(); code.initBailoutReturnOffset(BailoutReturnKind::SetProp, masm.currentOffset()); leaveStubFrame(masm); EmitReturnFromIC(masm); return true; } // // Call_Fallback // bool DoCallFallback(JSContext* cx, BaselineFrame* frame, ICFallbackStub* stub, uint32_t argc, Value* vp, MutableHandleValue res) { stub->incrementEnteredCount(); MaybeNotifyWarp(frame->outerScript(), stub); RootedScript script(cx, frame->script()); jsbytecode* pc = StubOffsetToPc(stub, script); JSOp op = JSOp(*pc); FallbackICSpew(cx, stub, "Call(%s)", CodeName(op)); MOZ_ASSERT(argc == GET_ARGC(pc)); bool constructing = (op == JSOp::New || op == JSOp::NewContent || op == JSOp::SuperCall); bool ignoresReturnValue = (op == JSOp::CallIgnoresRv); // Ensure vp array is rooted - we may GC in here. size_t numValues = argc + 2 + constructing; RootedExternalValueArray vpRoot(cx, numValues, vp); CallArgs callArgs = CallArgsFromSp(argc + constructing, vp + numValues, constructing, ignoresReturnValue); RootedValue callee(cx, vp[0]); RootedValue newTarget(cx, constructing ? callArgs.newTarget() : NullValue()); // Transition stub state to megamorphic or generic if warranted. MaybeTransition(cx, frame, stub); bool canAttachStub = stub->state().canAttachStub(); bool handled = false; // Only bother to try optimizing JSOp::Call with CacheIR if the chain is still // allowed to attach stubs. if (canAttachStub) { HandleValueArray args = HandleValueArray::fromMarkedLocation(argc, vp + 2); CallIRGenerator gen(cx, script, pc, op, stub->state(), argc, callee, callArgs.thisv(), newTarget, args); switch (gen.tryAttachStub()) { case AttachDecision::NoAction: break; case AttachDecision::Attach: { ICScript* icScript = frame->icScript(); ICAttachResult result = AttachBaselineCacheIRStub(cx, gen.writerRef(), gen.cacheKind(), script, icScript, stub, gen.stubName()); if (result == ICAttachResult::Attached) { handled = true; JitSpew(JitSpew_BaselineIC, " Attached Call CacheIR stub"); } } break; case AttachDecision::TemporarilyUnoptimizable: handled = true; break; case AttachDecision::Deferred: MOZ_CRASH("No deferred Call stubs"); } if (!handled) { stub->trackNotAttached(); } } if (constructing) { if (!ConstructFromStack(cx, callArgs)) { return false; } res.set(callArgs.rval()); } else if ((op == JSOp::Eval || op == JSOp::StrictEval) && cx->global()->valueIsEval(callee)) { if (!DirectEval(cx, callArgs.get(0), res)) { return false; } } else { MOZ_ASSERT(op == JSOp::Call || op == JSOp::CallContent || op == JSOp::CallIgnoresRv || op == JSOp::CallIter || op == JSOp::CallContentIter || op == JSOp::Eval || op == JSOp::StrictEval); if ((op == JSOp::CallIter || op == JSOp::CallContentIter) && callee.isPrimitive()) { MOZ_ASSERT(argc == 0, "thisv must be on top of the stack"); ReportValueError(cx, JSMSG_NOT_ITERABLE, -1, callArgs.thisv(), nullptr); return false; } if (!CallFromStack(cx, callArgs)) { return false; } res.set(callArgs.rval()); } return true; } bool DoSpreadCallFallback(JSContext* cx, BaselineFrame* frame, ICFallbackStub* stub, Value* vp, MutableHandleValue res) { stub->incrementEnteredCount(); MaybeNotifyWarp(frame->outerScript(), stub); RootedScript script(cx, frame->script()); jsbytecode* pc = StubOffsetToPc(stub, script); JSOp op = JSOp(*pc); bool constructing = (op == JSOp::SpreadNew || op == JSOp::SpreadSuperCall); FallbackICSpew(cx, stub, "SpreadCall(%s)", CodeName(op)); // Ensure vp array is rooted - we may GC in here. RootedExternalValueArray vpRoot(cx, 3 + constructing, vp); RootedValue callee(cx, vp[0]); RootedValue thisv(cx, vp[1]); RootedValue arr(cx, vp[2]); RootedValue newTarget(cx, constructing ? vp[3] : NullValue()); // Transition stub state to megamorphic or generic if warranted. MaybeTransition(cx, frame, stub); // Try attaching a call stub. bool handled = false; if (op != JSOp::SpreadEval && op != JSOp::StrictSpreadEval && stub->state().canAttachStub()) { // Try CacheIR first: Rooted aobj(cx, &arr.toObject().as()); MOZ_ASSERT(IsPackedArray(aobj)); HandleValueArray args = HandleValueArray::fromMarkedLocation( aobj->length(), aobj->getDenseElements()); CallIRGenerator gen(cx, script, pc, op, stub->state(), 1, callee, thisv, newTarget, args); switch (gen.tryAttachStub()) { case AttachDecision::NoAction: break; case AttachDecision::Attach: { ICScript* icScript = frame->icScript(); ICAttachResult result = AttachBaselineCacheIRStub(cx, gen.writerRef(), gen.cacheKind(), script, icScript, stub, gen.stubName()); if (result == ICAttachResult::Attached) { handled = true; JitSpew(JitSpew_BaselineIC, " Attached Spread Call CacheIR stub"); } } break; case AttachDecision::TemporarilyUnoptimizable: handled = true; break; case AttachDecision::Deferred: MOZ_ASSERT_UNREACHABLE("No deferred optimizations for spread calls"); break; } if (!handled) { stub->trackNotAttached(); } } return SpreadCallOperation(cx, script, pc, thisv, callee, arr, newTarget, res); } void FallbackICCodeCompiler::pushCallArguments( MacroAssembler& masm, AllocatableGeneralRegisterSet regs, Register argcReg, bool isConstructing) { MOZ_ASSERT(!regs.has(argcReg)); // argPtr initially points to the last argument. Register argPtr = regs.takeAny(); masm.mov(FramePointer, argPtr); // Skip 3 pointers pushed on top of the arguments: the frame descriptor, // return address, and old frame pointer. size_t valueOffset = BaselineStubFrameLayout::Size(); // We have to push |this|, callee, new.target (if constructing) and argc // arguments. Handle the number of Values we know statically first. size_t numNonArgValues = 2 + isConstructing; for (size_t i = 0; i < numNonArgValues; i++) { masm.pushValue(Address(argPtr, valueOffset)); valueOffset += sizeof(Value); } // If there are no arguments we're done. Label done; masm.branchTest32(Assembler::Zero, argcReg, argcReg, &done); // Push argc Values. Label loop; Register count = regs.takeAny(); masm.addPtr(Imm32(valueOffset), argPtr); masm.move32(argcReg, count); masm.bind(&loop); { masm.pushValue(Address(argPtr, 0)); masm.addPtr(Imm32(sizeof(Value)), argPtr); masm.branchSub32(Assembler::NonZero, Imm32(1), count, &loop); } masm.bind(&done); } bool FallbackICCodeCompiler::emitCall(bool isSpread, bool isConstructing) { static_assert(R0 == JSReturnOperand); // Values are on the stack left-to-right. Calling convention wants them // right-to-left so duplicate them on the stack in reverse order. // |this| and callee are pushed last. AllocatableGeneralRegisterSet regs = BaselineICAvailableGeneralRegs(0); if (MOZ_UNLIKELY(isSpread)) { // Push a stub frame so that we can perform a non-tail call. enterStubFrame(masm, R1.scratchReg()); // Use FramePointer instead of StackPointer because it's not affected by // the stack pushes below. // newTarget uint32_t valueOffset = BaselineStubFrameLayout::Size(); if (isConstructing) { masm.pushValue(Address(FramePointer, valueOffset)); valueOffset += sizeof(Value); } // array masm.pushValue(Address(FramePointer, valueOffset)); valueOffset += sizeof(Value); // this masm.pushValue(Address(FramePointer, valueOffset)); valueOffset += sizeof(Value); // callee masm.pushValue(Address(FramePointer, valueOffset)); valueOffset += sizeof(Value); masm.push(masm.getStackPointer()); masm.push(ICStubReg); PushStubPayload(masm, R0.scratchReg()); using Fn = bool (*)(JSContext*, BaselineFrame*, ICFallbackStub*, Value*, MutableHandleValue); if (!callVM(masm)) { return false; } leaveStubFrame(masm); EmitReturnFromIC(masm); // SpreadCall is not yet supported in Ion, so do not generate asmcode for // bailout. return true; } // Push a stub frame so that we can perform a non-tail call. enterStubFrame(masm, R1.scratchReg()); regs.take(R0.scratchReg()); // argc. pushCallArguments(masm, regs, R0.scratchReg(), isConstructing); masm.push(masm.getStackPointer()); masm.push(R0.scratchReg()); masm.push(ICStubReg); PushStubPayload(masm, R0.scratchReg()); using Fn = bool (*)(JSContext*, BaselineFrame*, ICFallbackStub*, uint32_t, Value*, MutableHandleValue); if (!callVM(masm)) { return false; } leaveStubFrame(masm); EmitReturnFromIC(masm); // This is the resume point used when bailout rewrites call stack to undo // Ion inlined frames. The return address pushed onto reconstructed stack // will point here. assumeStubFrame(); MOZ_ASSERT(!isSpread); if (isConstructing) { code.initBailoutReturnOffset(BailoutReturnKind::New, masm.currentOffset()); } else { code.initBailoutReturnOffset(BailoutReturnKind::Call, masm.currentOffset()); } // Load passed-in ThisV into R1 just in case it's needed. Need to do this // before we leave the stub frame since that info will be lost. // Current stack: [...., ThisV, CalleeToken, Descriptor ] size_t thisvOffset = JitFrameLayout::offsetOfThis() - JitFrameLayout::bytesPoppedAfterCall(); masm.loadValue(Address(masm.getStackPointer(), thisvOffset), R1); leaveStubFrame(masm); // If this is a |constructing| call, if the callee returns a non-object, we // replace it with the |this| object passed in. if (isConstructing) { static_assert(JSReturnOperand == R0); Label skipThisReplace; masm.branchTestObject(Assembler::Equal, JSReturnOperand, &skipThisReplace); masm.moveValue(R1, R0); #ifdef DEBUG masm.branchTestObject(Assembler::Equal, JSReturnOperand, &skipThisReplace); masm.assumeUnreachable("Failed to return object in constructing call."); #endif masm.bind(&skipThisReplace); } EmitReturnFromIC(masm); return true; } bool FallbackICCodeCompiler::emit_Call() { return emitCall(/* isSpread = */ false, /* isConstructing = */ false); } bool FallbackICCodeCompiler::emit_CallConstructing() { return emitCall(/* isSpread = */ false, /* isConstructing = */ true); } bool FallbackICCodeCompiler::emit_SpreadCall() { return emitCall(/* isSpread = */ true, /* isConstructing = */ false); } bool FallbackICCodeCompiler::emit_SpreadCallConstructing() { return emitCall(/* isSpread = */ true, /* isConstructing = */ true); } // // GetIterator_Fallback // bool DoGetIteratorFallback(JSContext* cx, BaselineFrame* frame, ICFallbackStub* stub, HandleValue value, MutableHandleValue res) { stub->incrementEnteredCount(); MaybeNotifyWarp(frame->outerScript(), stub); FallbackICSpew(cx, stub, "GetIterator"); TryAttachStub("GetIterator", cx, frame, stub, value); PropertyIteratorObject* iterObj = ValueToIterator(cx, value); if (!iterObj) { return false; } res.setObject(*iterObj); return true; } bool FallbackICCodeCompiler::emit_GetIterator() { EmitRestoreTailCallReg(masm); // Sync stack for the decompiler. masm.pushValue(R0); masm.pushValue(R0); masm.push(ICStubReg); pushStubPayload(masm, R0.scratchReg()); using Fn = bool (*)(JSContext*, BaselineFrame*, ICFallbackStub*, HandleValue, MutableHandleValue); return tailCallVM(masm); } // // OptimizeSpreadCall_Fallback // bool DoOptimizeSpreadCallFallback(JSContext* cx, BaselineFrame* frame, ICFallbackStub* stub, HandleValue value, MutableHandleValue res) { stub->incrementEnteredCount(); MaybeNotifyWarp(frame->outerScript(), stub); FallbackICSpew(cx, stub, "OptimizeSpreadCall"); TryAttachStub("OptimizeSpreadCall", cx, frame, stub, value); return OptimizeSpreadCall(cx, value, res); } bool FallbackICCodeCompiler::emit_OptimizeSpreadCall() { EmitRestoreTailCallReg(masm); masm.pushValue(R0); masm.push(ICStubReg); pushStubPayload(masm, R0.scratchReg()); using Fn = bool (*)(JSContext*, BaselineFrame*, ICFallbackStub*, HandleValue, MutableHandleValue); return tailCallVM(masm); } // // InstanceOf_Fallback // bool DoInstanceOfFallback(JSContext* cx, BaselineFrame* frame, ICFallbackStub* stub, HandleValue lhs, HandleValue rhs, MutableHandleValue res) { stub->incrementEnteredCount(); MaybeNotifyWarp(frame->outerScript(), stub); FallbackICSpew(cx, stub, "InstanceOf"); if (!rhs.isObject()) { ReportValueError(cx, JSMSG_BAD_INSTANCEOF_RHS, -1, rhs, nullptr); return false; } RootedObject obj(cx, &rhs.toObject()); bool cond = false; if (!InstanceofOperator(cx, obj, lhs, &cond)) { return false; } res.setBoolean(cond); if (!obj->is()) { // ensure we've recorded at least one failure, so we can detect there was a // non-optimizable case if (!stub->state().hasFailures()) { stub->trackNotAttached(); } return true; } TryAttachStub("InstanceOf", cx, frame, stub, lhs, obj); return true; } bool FallbackICCodeCompiler::emit_InstanceOf() { EmitRestoreTailCallReg(masm); // Sync stack for the decompiler. masm.pushValue(R0); masm.pushValue(R1); masm.pushValue(R1); masm.pushValue(R0); masm.push(ICStubReg); pushStubPayload(masm, R0.scratchReg()); using Fn = bool (*)(JSContext*, BaselineFrame*, ICFallbackStub*, HandleValue, HandleValue, MutableHandleValue); return tailCallVM(masm); } // // TypeOf_Fallback // bool DoTypeOfFallback(JSContext* cx, BaselineFrame* frame, ICFallbackStub* stub, HandleValue val, MutableHandleValue res) { stub->incrementEnteredCount(); MaybeNotifyWarp(frame->outerScript(), stub); FallbackICSpew(cx, stub, "TypeOf"); TryAttachStub("TypeOf", cx, frame, stub, val); JSType type = js::TypeOfValue(val); RootedString string(cx, TypeName(type, cx->names())); res.setString(string); return true; } bool FallbackICCodeCompiler::emit_TypeOf() { EmitRestoreTailCallReg(masm); masm.pushValue(R0); masm.push(ICStubReg); pushStubPayload(masm, R0.scratchReg()); using Fn = bool (*)(JSContext*, BaselineFrame*, ICFallbackStub*, HandleValue, MutableHandleValue); return tailCallVM(masm); } // // ToPropertyKey_Fallback // bool DoToPropertyKeyFallback(JSContext* cx, BaselineFrame* frame, ICFallbackStub* stub, HandleValue val, MutableHandleValue res) { stub->incrementEnteredCount(); MaybeNotifyWarp(frame->outerScript(), stub); FallbackICSpew(cx, stub, "ToPropertyKey"); TryAttachStub("ToPropertyKey", cx, frame, stub, val); return ToPropertyKeyOperation(cx, val, res); } bool FallbackICCodeCompiler::emit_ToPropertyKey() { EmitRestoreTailCallReg(masm); masm.pushValue(R0); masm.push(ICStubReg); pushStubPayload(masm, R0.scratchReg()); using Fn = bool (*)(JSContext*, BaselineFrame*, ICFallbackStub*, HandleValue, MutableHandleValue); return tailCallVM(masm); } // // Rest_Fallback // bool DoRestFallback(JSContext* cx, BaselineFrame* frame, ICFallbackStub* stub, MutableHandleValue res) { unsigned numFormals = frame->numFormalArgs() - 1; unsigned numActuals = frame->numActualArgs(); unsigned numRest = numActuals > numFormals ? numActuals - numFormals : 0; Value* rest = frame->argv() + numFormals; ArrayObject* obj = NewDenseCopiedArray(cx, numRest, rest); if (!obj) { return false; } res.setObject(*obj); return true; } bool FallbackICCodeCompiler::emit_Rest() { EmitRestoreTailCallReg(masm); masm.push(ICStubReg); pushStubPayload(masm, R0.scratchReg()); using Fn = bool (*)(JSContext*, BaselineFrame*, ICFallbackStub*, MutableHandleValue); return tailCallVM(masm); } // // UnaryArith_Fallback // bool DoUnaryArithFallback(JSContext* cx, BaselineFrame* frame, ICFallbackStub* stub, HandleValue val, MutableHandleValue res) { stub->incrementEnteredCount(); MaybeNotifyWarp(frame->outerScript(), stub); jsbytecode* pc = StubOffsetToPc(stub, frame->script()); JSOp op = JSOp(*pc); FallbackICSpew(cx, stub, "UnaryArith(%s)", CodeName(op)); switch (op) { case JSOp::BitNot: { res.set(val); if (!BitNot(cx, res, res)) { return false; } break; } case JSOp::Pos: { res.set(val); if (!ToNumber(cx, res)) { return false; } break; } case JSOp::Neg: { res.set(val); if (!NegOperation(cx, res, res)) { return false; } break; } case JSOp::Inc: { if (!IncOperation(cx, val, res)) { return false; } break; } case JSOp::Dec: { if (!DecOperation(cx, val, res)) { return false; } break; } case JSOp::ToNumeric: { res.set(val); if (!ToNumeric(cx, res)) { return false; } break; } default: MOZ_CRASH("Unexpected op"); } MOZ_ASSERT(res.isNumeric()); TryAttachStub("UnaryArith", cx, frame, stub, op, val, res); return true; } bool FallbackICCodeCompiler::emit_UnaryArith() { static_assert(R0 == JSReturnOperand); // Restore the tail call register. EmitRestoreTailCallReg(masm); // Ensure stack is fully synced for the expression decompiler. masm.pushValue(R0); // Push arguments. masm.pushValue(R0); masm.push(ICStubReg); pushStubPayload(masm, R0.scratchReg()); using Fn = bool (*)(JSContext*, BaselineFrame*, ICFallbackStub*, HandleValue, MutableHandleValue); return tailCallVM(masm); } // // BinaryArith_Fallback // bool DoBinaryArithFallback(JSContext* cx, BaselineFrame* frame, ICFallbackStub* stub, HandleValue lhs, HandleValue rhs, MutableHandleValue ret) { stub->incrementEnteredCount(); MaybeNotifyWarp(frame->outerScript(), stub); jsbytecode* pc = StubOffsetToPc(stub, frame->script()); JSOp op = JSOp(*pc); FallbackICSpew( cx, stub, "CacheIRBinaryArith(%s,%d,%d)", CodeName(op), int(lhs.isDouble() ? JSVAL_TYPE_DOUBLE : lhs.extractNonDoubleType()), int(rhs.isDouble() ? JSVAL_TYPE_DOUBLE : rhs.extractNonDoubleType())); // Don't pass lhs/rhs directly, we need the original values when // generating stubs. RootedValue lhsCopy(cx, lhs); RootedValue rhsCopy(cx, rhs); // Perform the arith operation. switch (op) { case JSOp::Add: // Do an add. if (!AddValues(cx, &lhsCopy, &rhsCopy, ret)) { return false; } break; case JSOp::Sub: if (!SubValues(cx, &lhsCopy, &rhsCopy, ret)) { return false; } break; case JSOp::Mul: if (!MulValues(cx, &lhsCopy, &rhsCopy, ret)) { return false; } break; case JSOp::Div: if (!DivValues(cx, &lhsCopy, &rhsCopy, ret)) { return false; } break; case JSOp::Mod: if (!ModValues(cx, &lhsCopy, &rhsCopy, ret)) { return false; } break; case JSOp::Pow: if (!PowValues(cx, &lhsCopy, &rhsCopy, ret)) { return false; } break; case JSOp::BitOr: { if (!BitOr(cx, &lhsCopy, &rhsCopy, ret)) { return false; } break; } case JSOp::BitXor: { if (!BitXor(cx, &lhsCopy, &rhsCopy, ret)) { return false; } break; } case JSOp::BitAnd: { if (!BitAnd(cx, &lhsCopy, &rhsCopy, ret)) { return false; } break; } case JSOp::Lsh: { if (!BitLsh(cx, &lhsCopy, &rhsCopy, ret)) { return false; } break; } case JSOp::Rsh: { if (!BitRsh(cx, &lhsCopy, &rhsCopy, ret)) { return false; } break; } case JSOp::Ursh: { if (!UrshValues(cx, &lhsCopy, &rhsCopy, ret)) { return false; } break; } default: MOZ_CRASH("Unhandled baseline arith op"); } TryAttachStub("BinaryArith", cx, frame, stub, op, lhs, rhs, ret); return true; } bool FallbackICCodeCompiler::emit_BinaryArith() { static_assert(R0 == JSReturnOperand); // Restore the tail call register. EmitRestoreTailCallReg(masm); // Ensure stack is fully synced for the expression decompiler. masm.pushValue(R0); masm.pushValue(R1); // Push arguments. masm.pushValue(R1); masm.pushValue(R0); masm.push(ICStubReg); pushStubPayload(masm, R0.scratchReg()); using Fn = bool (*)(JSContext*, BaselineFrame*, ICFallbackStub*, HandleValue, HandleValue, MutableHandleValue); return tailCallVM(masm); } // // Compare_Fallback // bool DoCompareFallback(JSContext* cx, BaselineFrame* frame, ICFallbackStub* stub, HandleValue lhs, HandleValue rhs, MutableHandleValue ret) { stub->incrementEnteredCount(); MaybeNotifyWarp(frame->outerScript(), stub); jsbytecode* pc = StubOffsetToPc(stub, frame->script()); JSOp op = JSOp(*pc); FallbackICSpew(cx, stub, "Compare(%s)", CodeName(op)); // Don't pass lhs/rhs directly, we need the original values when // generating stubs. RootedValue lhsCopy(cx, lhs); RootedValue rhsCopy(cx, rhs); // Perform the compare operation. bool out; switch (op) { case JSOp::Lt: if (!LessThan(cx, &lhsCopy, &rhsCopy, &out)) { return false; } break; case JSOp::Le: if (!LessThanOrEqual(cx, &lhsCopy, &rhsCopy, &out)) { return false; } break; case JSOp::Gt: if (!GreaterThan(cx, &lhsCopy, &rhsCopy, &out)) { return false; } break; case JSOp::Ge: if (!GreaterThanOrEqual(cx, &lhsCopy, &rhsCopy, &out)) { return false; } break; case JSOp::Eq: if (!js::LooselyEqual(cx, lhsCopy, rhsCopy, &out)) { return false; } break; case JSOp::Ne: if (!js::LooselyEqual(cx, lhsCopy, rhsCopy, &out)) { return false; } out = !out; break; case JSOp::StrictEq: if (!js::StrictlyEqual(cx, lhsCopy, rhsCopy, &out)) { return false; } break; case JSOp::StrictNe: if (!js::StrictlyEqual(cx, lhsCopy, rhsCopy, &out)) { return false; } out = !out; break; default: MOZ_ASSERT_UNREACHABLE("Unhandled baseline compare op"); return false; } ret.setBoolean(out); TryAttachStub("Compare", cx, frame, stub, op, lhs, rhs); return true; } bool FallbackICCodeCompiler::emit_Compare() { static_assert(R0 == JSReturnOperand); // Restore the tail call register. EmitRestoreTailCallReg(masm); // Ensure stack is fully synced for the expression decompiler. masm.pushValue(R0); masm.pushValue(R1); // Push arguments. masm.pushValue(R1); masm.pushValue(R0); masm.push(ICStubReg); pushStubPayload(masm, R0.scratchReg()); using Fn = bool (*)(JSContext*, BaselineFrame*, ICFallbackStub*, HandleValue, HandleValue, MutableHandleValue); return tailCallVM(masm); } // // NewArray_Fallback // bool DoNewArrayFallback(JSContext* cx, BaselineFrame* frame, ICFallbackStub* stub, MutableHandleValue res) { stub->incrementEnteredCount(); MaybeNotifyWarp(frame->outerScript(), stub); FallbackICSpew(cx, stub, "NewArray"); jsbytecode* pc = StubOffsetToPc(stub, frame->script()); uint32_t length = GET_UINT32(pc); MOZ_ASSERT(length <= INT32_MAX, "the bytecode emitter must fail to compile code that would " "produce a length exceeding int32_t range"); Rooted array(cx, NewArrayOperation(cx, length)); if (!array) { return false; } TryAttachStub("NewArray", cx, frame, stub, JSOp(*pc), array, frame); res.setObject(*array); return true; } bool FallbackICCodeCompiler::emit_NewArray() { EmitRestoreTailCallReg(masm); masm.push(ICStubReg); // stub. masm.pushBaselineFramePtr(FramePointer, R0.scratchReg()); using Fn = bool (*)(JSContext*, BaselineFrame*, ICFallbackStub*, MutableHandleValue); return tailCallVM(masm); } // // NewObject_Fallback // bool DoNewObjectFallback(JSContext* cx, BaselineFrame* frame, ICFallbackStub* stub, MutableHandleValue res) { stub->incrementEnteredCount(); MaybeNotifyWarp(frame->outerScript(), stub); FallbackICSpew(cx, stub, "NewObject"); RootedScript script(cx, frame->script()); jsbytecode* pc = StubOffsetToPc(stub, script); RootedObject obj(cx, NewObjectOperation(cx, script, pc)); if (!obj) { return false; } TryAttachStub("NewObject", cx, frame, stub, JSOp(*pc), obj, frame); res.setObject(*obj); return true; } bool FallbackICCodeCompiler::emit_NewObject() { EmitRestoreTailCallReg(masm); masm.push(ICStubReg); // stub. pushStubPayload(masm, R0.scratchReg()); using Fn = bool (*)(JSContext*, BaselineFrame*, ICFallbackStub*, MutableHandleValue); return tailCallVM(masm); } // // CloseIter_Fallback // bool DoCloseIterFallback(JSContext* cx, BaselineFrame* frame, ICFallbackStub* stub, HandleObject iter) { stub->incrementEnteredCount(); MaybeNotifyWarp(frame->outerScript(), stub); FallbackICSpew(cx, stub, "CloseIter"); jsbytecode* pc = StubOffsetToPc(stub, frame->script()); CompletionKind kind = CompletionKind(GET_UINT8(pc)); TryAttachStub("CloseIter", cx, frame, stub, iter, kind); return CloseIterOperation(cx, iter, kind); } bool FallbackICCodeCompiler::emit_CloseIter() { EmitRestoreTailCallReg(masm); masm.push(R0.scratchReg()); masm.push(ICStubReg); pushStubPayload(masm, R0.scratchReg()); using Fn = bool (*)(JSContext*, BaselineFrame*, ICFallbackStub*, HandleObject); return tailCallVM(masm); } bool JitRuntime::generateBaselineICFallbackCode(JSContext* cx) { TempAllocator temp(&cx->tempLifoAlloc()); StackMacroAssembler masm(cx, temp); PerfSpewerRangeRecorder rangeRecorder(masm); AutoCreatedBy acb(masm, "JitRuntime::generateBaselineICFallbackCode"); BaselineICFallbackCode& fallbackCode = baselineICFallbackCode_.ref(); FallbackICCodeCompiler compiler(cx, fallbackCode, masm); JitSpew(JitSpew_Codegen, "# Emitting Baseline IC fallback code"); #define EMIT_CODE(kind) \ { \ AutoCreatedBy acb(masm, "kind=" #kind); \ uint32_t offset = startTrampolineCode(masm); \ InitMacroAssemblerForICStub(masm); \ if (!compiler.emit_##kind()) { \ return false; \ } \ fallbackCode.initOffset(BaselineICFallbackKind::kind, offset); \ rangeRecorder.recordOffset("BaselineICFallback: " #kind); \ } IC_BASELINE_FALLBACK_CODE_KIND_LIST(EMIT_CODE) #undef EMIT_CODE Linker linker(masm); JitCode* code = linker.newCode(cx, CodeKind::Other); if (!code) { return false; } rangeRecorder.collectRangesForJitCode(code); #ifdef MOZ_VTUNE vtune::MarkStub(code, "BaselineICFallback"); #endif fallbackCode.initCode(code); return true; } } // namespace jit } // namespace js