/* -*- Mode: C++; tab-width: 8; indent-tabs-mode: nil; c-basic-offset: 4 -*- * vim: set ts=8 sts=4 et sw=4 tw=99: * 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/VMFunctions.h" #include "jsgc.h" #include "builtin/TypedObject.h" #include "frontend/BytecodeCompiler.h" #include "jit/arm/Simulator-arm.h" #include "jit/BaselineIC.h" #include "jit/JitCompartment.h" #include "jit/JitFrames.h" #include "jit/mips32/Simulator-mips32.h" #include "jit/mips64/Simulator-mips64.h" #include "vm/ArrayObject.h" #include "vm/Debugger.h" #include "vm/Interpreter.h" #include "vm/TraceLogging.h" #include "jit/BaselineFrame-inl.h" #include "jit/JitFrames-inl.h" #include "vm/Debugger-inl.h" #include "vm/Interpreter-inl.h" #include "vm/NativeObject-inl.h" #include "vm/StringObject-inl.h" #include "vm/TypeInference-inl.h" #include "vm/UnboxedObject-inl.h" using namespace js; using namespace js::jit; namespace js { namespace jit { // Statics are initialized to null. /* static */ VMFunction* VMFunction::functions; AutoDetectInvalidation::AutoDetectInvalidation(JSContext* cx, MutableHandleValue rval) : cx_(cx), ionScript_(GetTopJitJSScript(cx)->ionScript()), rval_(rval), disabled_(false) { } void VMFunction::addToFunctions() { this->next = functions; functions = this; } bool InvokeFunction(JSContext* cx, HandleObject obj, bool constructing, uint32_t argc, Value* argv, MutableHandleValue rval) { TraceLoggerThread* logger = TraceLoggerForMainThread(cx->runtime()); TraceLogStartEvent(logger, TraceLogger_Call); AutoArrayRooter argvRoot(cx, argc + 1 + constructing, argv); // Data in the argument vector is arranged for a JIT -> JIT call. RootedValue thisv(cx, argv[0]); Value* argvWithoutThis = argv + 1; RootedValue fval(cx, ObjectValue(*obj)); if (constructing) { if (!IsConstructor(fval)) { ReportValueError(cx, JSMSG_NOT_CONSTRUCTOR, JSDVG_IGNORE_STACK, fval, nullptr); return false; } ConstructArgs cargs(cx); if (!cargs.init(cx, argc)) return false; for (uint32_t i = 0; i < argc; i++) cargs[i].set(argvWithoutThis[i]); RootedValue newTarget(cx, argvWithoutThis[argc]); // If |this| hasn't been created, or is JS_UNINITIALIZED_LEXICAL, // we can use normal construction code without creating an extraneous // object. if (thisv.isMagic()) { MOZ_ASSERT(thisv.whyMagic() == JS_IS_CONSTRUCTING || thisv.whyMagic() == JS_UNINITIALIZED_LEXICAL); RootedObject obj(cx); if (!Construct(cx, fval, cargs, newTarget, &obj)) return false; rval.setObject(*obj); return true; } // Otherwise the default |this| has already been created. We could // almost perform a *call* at this point, but we'd break |new.target| // in the function. So in this one weird case we call a one-off // construction path that *won't* set |this| to JS_IS_CONSTRUCTING. return InternalConstructWithProvidedThis(cx, fval, thisv, cargs, newTarget, rval); } InvokeArgs args(cx); if (!args.init(cx, argc)) return false; for (size_t i = 0; i < argc; i++) args[i].set(argvWithoutThis[i]); return Call(cx, fval, thisv, args, rval); } bool InvokeFunctionShuffleNewTarget(JSContext* cx, HandleObject obj, uint32_t numActualArgs, uint32_t numFormalArgs, Value* argv, MutableHandleValue rval) { MOZ_ASSERT(numFormalArgs > numActualArgs); argv[1 + numActualArgs] = argv[1 + numFormalArgs]; return InvokeFunction(cx, obj, true, numActualArgs, argv, rval); } bool CheckOverRecursed(JSContext* cx) { // We just failed the jitStackLimit check. There are two possible reasons: // - jitStackLimit was the real stack limit and we're over-recursed // - jitStackLimit was set to UINTPTR_MAX by JSRuntime::requestInterrupt // and we need to call JSRuntime::handleInterrupt. #ifdef JS_SIMULATOR JS_CHECK_SIMULATOR_RECURSION_WITH_EXTRA(cx, 0, return false); #else JS_CHECK_RECURSION(cx, return false); #endif return cx->runtime()->handleInterrupt(cx); } // This function can get called in two contexts. In the usual context, it's // called with earlyCheck=false, after the env chain has been initialized on // a baseline frame. In this case, it's ok to throw an exception, so a failed // stack check returns false, and a successful stack check promps a check for // an interrupt from the runtime, which may also cause a false return. // // In the second case, it's called with earlyCheck=true, prior to frame // initialization. An exception cannot be thrown in this instance, so instead // an error flag is set on the frame and true returned. bool CheckOverRecursedWithExtra(JSContext* cx, BaselineFrame* frame, uint32_t extra, uint32_t earlyCheck) { MOZ_ASSERT_IF(earlyCheck, !frame->overRecursed()); // See |CheckOverRecursed| above. This is a variant of that function which // accepts an argument holding the extra stack space needed for the Baseline // frame that's about to be pushed. uint8_t spDummy; uint8_t* checkSp = (&spDummy) - extra; if (earlyCheck) { #ifdef JS_SIMULATOR (void)checkSp; JS_CHECK_SIMULATOR_RECURSION_WITH_EXTRA(cx, extra, frame->setOverRecursed()); #else JS_CHECK_RECURSION_WITH_SP(cx, checkSp, frame->setOverRecursed()); #endif return true; } // The OVERRECURSED flag may have already been set on the frame by an // early over-recursed check. If so, throw immediately. if (frame->overRecursed()) return false; #ifdef JS_SIMULATOR JS_CHECK_SIMULATOR_RECURSION_WITH_EXTRA(cx, extra, return false); #else JS_CHECK_RECURSION_WITH_SP(cx, checkSp, return false); #endif return cx->runtime()->handleInterrupt(cx); } JSObject* BindVar(JSContext* cx, HandleObject envChain) { JSObject* obj = envChain; while (!obj->isQualifiedVarObj()) obj = obj->enclosingEnvironment(); MOZ_ASSERT(obj); return obj; } bool DefVar(JSContext* cx, HandlePropertyName dn, unsigned attrs, HandleObject envChain) { // Given the ScopeChain, extract the VarObj. RootedObject obj(cx, BindVar(cx, envChain)); return DefVarOperation(cx, obj, dn, attrs); } bool DefLexical(JSContext* cx, HandlePropertyName dn, unsigned attrs, HandleObject envChain) { // Find the extensible lexical scope. Rooted lexicalEnv(cx, &NearestEnclosingExtensibleLexicalEnvironment(envChain)); // Find the variables object. RootedObject varObj(cx, BindVar(cx, envChain)); return DefLexicalOperation(cx, lexicalEnv, varObj, dn, attrs); } bool DefGlobalLexical(JSContext* cx, HandlePropertyName dn, unsigned attrs) { Rooted globalLexical(cx, &cx->global()->lexicalEnvironment()); return DefLexicalOperation(cx, globalLexical, cx->global(), dn, attrs); } bool MutatePrototype(JSContext* cx, HandlePlainObject obj, HandleValue value) { if (!value.isObjectOrNull()) return true; RootedObject newProto(cx, value.toObjectOrNull()); return SetPrototype(cx, obj, newProto); } bool InitProp(JSContext* cx, HandleObject obj, HandlePropertyName name, HandleValue value, jsbytecode* pc) { RootedId id(cx, NameToId(name)); return InitPropertyOperation(cx, JSOp(*pc), obj, id, value); } template bool LooselyEqual(JSContext* cx, MutableHandleValue lhs, MutableHandleValue rhs, bool* res) { if (!js::LooselyEqual(cx, lhs, rhs, res)) return false; if (!Equal) *res = !*res; return true; } template bool LooselyEqual(JSContext* cx, MutableHandleValue lhs, MutableHandleValue rhs, bool* res); template bool LooselyEqual(JSContext* cx, MutableHandleValue lhs, MutableHandleValue rhs, bool* res); template bool StrictlyEqual(JSContext* cx, MutableHandleValue lhs, MutableHandleValue rhs, bool* res) { if (!js::StrictlyEqual(cx, lhs, rhs, res)) return false; if (!Equal) *res = !*res; return true; } template bool StrictlyEqual(JSContext* cx, MutableHandleValue lhs, MutableHandleValue rhs, bool* res); template bool StrictlyEqual(JSContext* cx, MutableHandleValue lhs, MutableHandleValue rhs, bool* res); bool LessThan(JSContext* cx, MutableHandleValue lhs, MutableHandleValue rhs, bool* res) { return LessThanOperation(cx, lhs, rhs, res); } bool LessThanOrEqual(JSContext* cx, MutableHandleValue lhs, MutableHandleValue rhs, bool* res) { return LessThanOrEqualOperation(cx, lhs, rhs, res); } bool GreaterThan(JSContext* cx, MutableHandleValue lhs, MutableHandleValue rhs, bool* res) { return GreaterThanOperation(cx, lhs, rhs, res); } bool GreaterThanOrEqual(JSContext* cx, MutableHandleValue lhs, MutableHandleValue rhs, bool* res) { return GreaterThanOrEqualOperation(cx, lhs, rhs, res); } template bool StringsEqual(JSContext* cx, HandleString lhs, HandleString rhs, bool* res) { if (!js::EqualStrings(cx, lhs, rhs, res)) return false; if (!Equal) *res = !*res; return true; } template bool StringsEqual(JSContext* cx, HandleString lhs, HandleString rhs, bool* res); template bool StringsEqual(JSContext* cx, HandleString lhs, HandleString rhs, bool* res); bool ArraySpliceDense(JSContext* cx, HandleObject obj, uint32_t start, uint32_t deleteCount) { JS::AutoValueArray<4> argv(cx); argv[0].setUndefined(); argv[1].setObject(*obj); argv[2].set(Int32Value(start)); argv[3].set(Int32Value(deleteCount)); return js::array_splice_impl(cx, 2, argv.begin(), false); } bool ArrayPopDense(JSContext* cx, HandleObject obj, MutableHandleValue rval) { MOZ_ASSERT(obj->is() || obj->is()); AutoDetectInvalidation adi(cx, rval); JS::AutoValueArray<2> argv(cx); argv[0].setUndefined(); argv[1].setObject(*obj); if (!js::array_pop(cx, 0, argv.begin())) return false; // If the result is |undefined|, the array was probably empty and we // have to monitor the return value. rval.set(argv[0]); if (rval.isUndefined()) TypeScript::Monitor(cx, rval); return true; } bool ArrayPushDense(JSContext* cx, HandleObject obj, HandleValue v, uint32_t* length) { *length = GetAnyBoxedOrUnboxedArrayLength(obj); DenseElementResult result = SetOrExtendAnyBoxedOrUnboxedDenseElements(cx, obj, *length, v.address(), 1, ShouldUpdateTypes::DontUpdate); if (result != DenseElementResult::Incomplete) { (*length)++; return result == DenseElementResult::Success; } JS::AutoValueArray<3> argv(cx); argv[0].setUndefined(); argv[1].setObject(*obj); argv[2].set(v); if (!js::array_push(cx, 1, argv.begin())) return false; *length = argv[0].toInt32(); return true; } bool ArrayShiftDense(JSContext* cx, HandleObject obj, MutableHandleValue rval) { MOZ_ASSERT(obj->is() || obj->is()); AutoDetectInvalidation adi(cx, rval); JS::AutoValueArray<2> argv(cx); argv[0].setUndefined(); argv[1].setObject(*obj); if (!js::array_shift(cx, 0, argv.begin())) return false; // If the result is |undefined|, the array was probably empty and we // have to monitor the return value. rval.set(argv[0]); if (rval.isUndefined()) TypeScript::Monitor(cx, rval); return true; } JSString* ArrayJoin(JSContext* cx, HandleObject array, HandleString sep) { JS::AutoValueArray<3> argv(cx); argv[0].setUndefined(); argv[1].setObject(*array); argv[2].setString(sep); if (!js::array_join(cx, 1, argv.begin())) return nullptr; return argv[0].toString(); } bool CharCodeAt(JSContext* cx, HandleString str, int32_t index, uint32_t* code) { char16_t c; if (!str->getChar(cx, index, &c)) return false; *code = c; return true; } JSFlatString* StringFromCharCode(JSContext* cx, int32_t code) { char16_t c = char16_t(code); if (StaticStrings::hasUnit(c)) return cx->staticStrings().getUnit(c); return NewStringCopyN(cx, &c, 1); } JSString* StringFromCodePoint(JSContext* cx, int32_t codePoint) { RootedValue rval(cx, Int32Value(codePoint)); if (!str_fromCodePoint_one_arg(cx, rval, &rval)) return nullptr; return rval.toString(); } bool SetProperty(JSContext* cx, HandleObject obj, HandlePropertyName name, HandleValue value, bool strict, jsbytecode* pc) { RootedId id(cx, NameToId(name)); JSOp op = JSOp(*pc); if (op == JSOP_SETALIASEDVAR || op == JSOP_INITALIASEDLEXICAL) { // Aliased var assigns ignore readonly attributes on the property, as // required for initializing 'const' closure variables. Shape* shape = obj->as().lookup(cx, name); MOZ_ASSERT(shape && shape->hasSlot()); obj->as().setSlotWithType(cx, shape, value); return true; } RootedValue receiver(cx, ObjectValue(*obj)); ObjectOpResult result; if (MOZ_LIKELY(!obj->getOpsSetProperty())) { if (!NativeSetProperty( cx, obj.as(), id, value, receiver, (op == JSOP_SETNAME || op == JSOP_STRICTSETNAME || op == JSOP_SETGNAME || op == JSOP_STRICTSETGNAME) ? Unqualified : Qualified, result)) { return false; } } else { if (!SetProperty(cx, obj, id, value, receiver, result)) return false; } return result.checkStrictErrorOrWarning(cx, obj, id, strict); } bool InterruptCheck(JSContext* cx) { { JSRuntime* rt = cx->runtime(); JitRuntime::AutoPreventBackedgePatching apbp(rt); rt->jitRuntime()->patchIonBackedges(rt, JitRuntime::BackedgeLoopHeader); } return CheckForInterrupt(cx); } void* MallocWrapper(JSRuntime* rt, size_t nbytes) { return rt->pod_malloc(nbytes); } JSObject* NewCallObject(JSContext* cx, HandleShape shape, HandleObjectGroup group) { JSObject* obj = CallObject::create(cx, shape, group); if (!obj) return nullptr; // The JIT creates call objects in the nursery, so elides barriers for // the initializing writes. The interpreter, however, may have allocated // the call object tenured, so barrier as needed before re-entering. if (!IsInsideNursery(obj)) cx->runtime()->gc.storeBuffer.putWholeCell(obj); return obj; } JSObject* NewSingletonCallObject(JSContext* cx, HandleShape shape) { JSObject* obj = CallObject::createSingleton(cx, shape); if (!obj) return nullptr; // The JIT creates call objects in the nursery, so elides barriers for // the initializing writes. The interpreter, however, may have allocated // the call object tenured, so barrier as needed before re-entering. MOZ_ASSERT(!IsInsideNursery(obj), "singletons are created in the tenured heap"); cx->runtime()->gc.storeBuffer.putWholeCell(obj); return obj; } JSObject* NewStringObject(JSContext* cx, HandleString str) { return StringObject::create(cx, str); } bool OperatorIn(JSContext* cx, HandleValue key, HandleObject obj, bool* out) { RootedId id(cx); return ToPropertyKey(cx, key, &id) && HasProperty(cx, obj, id, out); } bool OperatorInI(JSContext* cx, uint32_t index, HandleObject obj, bool* out) { RootedValue key(cx, Int32Value(index)); return OperatorIn(cx, key, obj, out); } bool GetIntrinsicValue(JSContext* cx, HandlePropertyName name, MutableHandleValue rval) { if (!GlobalObject::getIntrinsicValue(cx, cx->global(), name, rval)) return false; // This function is called when we try to compile a cold getintrinsic // op. MCallGetIntrinsicValue has an AliasSet of None for optimization // purposes, as its side effect is not observable from JS. We are // guaranteed to bail out after this function, but because of its AliasSet, // type info will not be reflowed. Manually monitor here. TypeScript::Monitor(cx, rval); return true; } bool CreateThis(JSContext* cx, HandleObject callee, HandleObject newTarget, MutableHandleValue rval) { rval.set(MagicValue(JS_IS_CONSTRUCTING)); if (callee->is()) { RootedFunction fun(cx, &callee->as()); if (fun->isInterpreted() && fun->isConstructor()) { JSScript* script = fun->getOrCreateScript(cx); if (!script || !script->ensureHasTypes(cx)) return false; if (fun->isBoundFunction() || script->isDerivedClassConstructor()) { rval.set(MagicValue(JS_UNINITIALIZED_LEXICAL)); } else { JSObject* thisObj = CreateThisForFunction(cx, callee, newTarget, GenericObject); if (!thisObj) return false; rval.set(ObjectValue(*thisObj)); } } } return true; } void GetDynamicName(JSContext* cx, JSObject* envChain, JSString* str, Value* vp) { // Lookup a string on the env chain, returning either the value found or // undefined through rval. This function is infallible, and cannot GC or // invalidate. JSAtom* atom; if (str->isAtom()) { atom = &str->asAtom(); } else { atom = AtomizeString(cx, str); if (!atom) { vp->setUndefined(); return; } } if (!frontend::IsIdentifier(atom) || frontend::IsKeyword(atom)) { vp->setUndefined(); return; } Shape* shape = nullptr; JSObject* scope = nullptr; JSObject* pobj = nullptr; if (LookupNameNoGC(cx, atom->asPropertyName(), envChain, &scope, &pobj, &shape)) { if (FetchNameNoGC(pobj, shape, MutableHandleValue::fromMarkedLocation(vp))) return; } vp->setUndefined(); } void PostWriteBarrier(JSRuntime* rt, JSObject* obj) { MOZ_ASSERT(!IsInsideNursery(obj)); rt->gc.storeBuffer.putWholeCell(obj); } static const size_t MAX_WHOLE_CELL_BUFFER_SIZE = 4096; void PostWriteElementBarrier(JSRuntime* rt, JSObject* obj, int32_t index) { MOZ_ASSERT(!IsInsideNursery(obj)); if (obj->is() && !obj->as().isInWholeCellBuffer() && uint32_t(index) < obj->as().getDenseInitializedLength() && (obj->as().getDenseInitializedLength() > MAX_WHOLE_CELL_BUFFER_SIZE)) { rt->gc.storeBuffer.putSlot(&obj->as(), HeapSlot::Element, index, 1); return; } rt->gc.storeBuffer.putWholeCell(obj); } void PostGlobalWriteBarrier(JSRuntime* rt, JSObject* obj) { MOZ_ASSERT(obj->is()); if (!obj->compartment()->globalWriteBarriered) { PostWriteBarrier(rt, obj); obj->compartment()->globalWriteBarriered = 1; } } uint32_t GetIndexFromString(JSString* str) { // Masks the return value UINT32_MAX as failure to get the index. // I.e. it is impossible to distinguish between failing to get the index // or the actual index UINT32_MAX. if (!str->isAtom()) return UINT32_MAX; uint32_t index; JSAtom* atom = &str->asAtom(); if (!atom->isIndex(&index)) return UINT32_MAX; return index; } bool DebugPrologue(JSContext* cx, BaselineFrame* frame, jsbytecode* pc, bool* mustReturn) { *mustReturn = false; switch (Debugger::onEnterFrame(cx, frame)) { case JSTRAP_CONTINUE: return true; case JSTRAP_RETURN: // The script is going to return immediately, so we have to call the // debug epilogue handler as well. MOZ_ASSERT(frame->hasReturnValue()); *mustReturn = true; return jit::DebugEpilogue(cx, frame, pc, true); case JSTRAP_THROW: case JSTRAP_ERROR: return false; default: MOZ_CRASH("bad Debugger::onEnterFrame status"); } } bool DebugEpilogueOnBaselineReturn(JSContext* cx, BaselineFrame* frame, jsbytecode* pc) { if (!DebugEpilogue(cx, frame, pc, true)) { // DebugEpilogue popped the frame by updating jitTop, so run the stop event // here before we enter the exception handler. TraceLoggerThread* logger = TraceLoggerForMainThread(cx->runtime()); TraceLogStopEvent(logger, TraceLogger_Baseline); TraceLogStopEvent(logger, TraceLogger_Scripts); return false; } return true; } bool DebugEpilogue(JSContext* cx, BaselineFrame* frame, jsbytecode* pc, bool ok) { // If Debugger::onLeaveFrame returns |true| we have to return the frame's // return value. If it returns |false|, the debugger threw an exception. // In both cases we have to pop debug scopes. ok = Debugger::onLeaveFrame(cx, frame, pc, ok); // Unwind to the outermost environment and set pc to the end of the // script, regardless of error. EnvironmentIter ei(cx, frame, pc); UnwindAllEnvironmentsInFrame(cx, ei); JSScript* script = frame->script(); frame->setOverridePc(script->lastPC()); if (!ok) { // Pop this frame by updating jitTop, so that the exception handling // code will start at the previous frame. JitFrameLayout* prefix = frame->framePrefix(); EnsureBareExitFrame(cx, prefix); return false; } // Clear the override pc. This is not necessary for correctness: the frame // will return immediately, but this simplifies the check we emit in debug // builds after each callVM, to ensure this flag is not set. frame->clearOverridePc(); return true; } void FrameIsDebuggeeCheck(BaselineFrame* frame) { if (frame->script()->isDebuggee()) frame->setIsDebuggee(); } JSObject* CreateGenerator(JSContext* cx, BaselineFrame* frame) { return GeneratorObject::create(cx, frame); } bool NormalSuspend(JSContext* cx, HandleObject obj, BaselineFrame* frame, jsbytecode* pc, uint32_t stackDepth) { MOZ_ASSERT(*pc == JSOP_YIELD); // Return value is still on the stack. MOZ_ASSERT(stackDepth >= 1); // The expression stack slots are stored on the stack in reverse order, so // we copy them to a Vector and pass a pointer to that instead. We use // stackDepth - 1 because we don't want to include the return value. AutoValueVector exprStack(cx); if (!exprStack.reserve(stackDepth - 1)) return false; size_t firstSlot = frame->numValueSlots() - stackDepth; for (size_t i = 0; i < stackDepth - 1; i++) exprStack.infallibleAppend(*frame->valueSlot(firstSlot + i)); MOZ_ASSERT(exprStack.length() == stackDepth - 1); return GeneratorObject::normalSuspend(cx, obj, frame, pc, exprStack.begin(), stackDepth - 1); } bool FinalSuspend(JSContext* cx, HandleObject obj, BaselineFrame* frame, jsbytecode* pc) { MOZ_ASSERT(*pc == JSOP_FINALYIELDRVAL); if (!GeneratorObject::finalSuspend(cx, obj)) { TraceLoggerThread* logger = TraceLoggerForMainThread(cx->runtime()); TraceLogStopEvent(logger, TraceLogger_Engine); TraceLogStopEvent(logger, TraceLogger_Scripts); // Leave this frame and propagate the exception to the caller. return DebugEpilogue(cx, frame, pc, /* ok = */ false); } return true; } bool InterpretResume(JSContext* cx, HandleObject obj, HandleValue val, HandlePropertyName kind, MutableHandleValue rval) { MOZ_ASSERT(obj->is()); RootedValue selfHostedFun(cx); if (!GlobalObject::getIntrinsicValue(cx, cx->global(), cx->names().InterpretGeneratorResume, &selfHostedFun)) { return false; } MOZ_ASSERT(selfHostedFun.toObject().is()); FixedInvokeArgs<3> args(cx); args[0].setObject(*obj); args[1].set(val); args[2].setString(kind); return Call(cx, selfHostedFun, UndefinedHandleValue, args, rval); } bool DebugAfterYield(JSContext* cx, BaselineFrame* frame) { // The BaselineFrame has just been constructed by JSOP_RESUME in the // caller. We need to set its debuggee flag as necessary. if (frame->script()->isDebuggee()) frame->setIsDebuggee(); return true; } bool GeneratorThrowOrClose(JSContext* cx, BaselineFrame* frame, Handle genObj, HandleValue arg, uint32_t resumeKind) { // Set the frame's pc to the current resume pc, so that frame iterators // work. This function always returns false, so we're guaranteed to enter // the exception handler where we will clear the pc. JSScript* script = frame->script(); uint32_t offset = script->yieldOffsets()[genObj->yieldIndex()]; frame->setOverridePc(script->offsetToPC(offset)); MOZ_ALWAYS_TRUE(DebugAfterYield(cx, frame)); MOZ_ALWAYS_FALSE(js::GeneratorThrowOrClose(cx, frame, genObj, arg, resumeKind)); return false; } bool CheckGlobalOrEvalDeclarationConflicts(JSContext* cx, BaselineFrame* frame) { RootedScript script(cx, frame->script()); RootedObject envChain(cx, frame->environmentChain()); RootedObject varObj(cx, BindVar(cx, envChain)); if (script->isForEval()) { // Strict eval and eval in parameter default expressions have their // own call objects. // // Non-strict eval may introduce 'var' bindings that conflict with // lexical bindings in an enclosing lexical scope. if (!script->bodyScope()->hasEnvironment()) { MOZ_ASSERT(!script->strict() && (!script->enclosingScope()->is() || !script->enclosingScope()->as().hasParameterExprs())); if (!CheckEvalDeclarationConflicts(cx, script, envChain, varObj)) return false; } } else { Rooted lexicalEnv(cx, &NearestEnclosingExtensibleLexicalEnvironment(envChain)); if (!CheckGlobalDeclarationConflicts(cx, script, lexicalEnv, varObj)) return false; } return true; } bool GlobalNameConflictsCheckFromIon(JSContext* cx, HandleScript script) { Rooted globalLexical(cx, &cx->global()->lexicalEnvironment()); return CheckGlobalDeclarationConflicts(cx, script, globalLexical, cx->global()); } bool InitFunctionEnvironmentObjects(JSContext* cx, BaselineFrame* frame) { return frame->initFunctionEnvironmentObjects(cx); } bool NewArgumentsObject(JSContext* cx, BaselineFrame* frame, MutableHandleValue res) { ArgumentsObject* obj = ArgumentsObject::createExpected(cx, frame); if (!obj) return false; res.setObject(*obj); return true; } JSObject* InitRestParameter(JSContext* cx, uint32_t length, Value* rest, HandleObject templateObj, HandleObject objRes) { if (objRes) { Rooted arrRes(cx, &objRes->as()); MOZ_ASSERT(!arrRes->getDenseInitializedLength()); MOZ_ASSERT(arrRes->group() == templateObj->group()); // Fast path: we managed to allocate the array inline; initialize the // slots. if (length > 0) { if (!arrRes->ensureElements(cx, length)) return nullptr; arrRes->setDenseInitializedLength(length); arrRes->initDenseElements(0, rest, length); arrRes->setLengthInt32(length); } return arrRes; } NewObjectKind newKind = templateObj->group()->shouldPreTenure() ? TenuredObject : GenericObject; ArrayObject* arrRes = NewDenseCopiedArray(cx, length, rest, nullptr, newKind); if (arrRes) arrRes->setGroup(templateObj->group()); return arrRes; } bool HandleDebugTrap(JSContext* cx, BaselineFrame* frame, uint8_t* retAddr, bool* mustReturn) { *mustReturn = false; RootedScript script(cx, frame->script()); jsbytecode* pc = script->baselineScript()->icEntryFromReturnAddress(retAddr).pc(script); MOZ_ASSERT(frame->isDebuggee()); MOZ_ASSERT(script->stepModeEnabled() || script->hasBreakpointsAt(pc)); RootedValue rval(cx); JSTrapStatus status = JSTRAP_CONTINUE; if (script->stepModeEnabled()) status = Debugger::onSingleStep(cx, &rval); if (status == JSTRAP_CONTINUE && script->hasBreakpointsAt(pc)) status = Debugger::onTrap(cx, &rval); switch (status) { case JSTRAP_CONTINUE: break; case JSTRAP_ERROR: return false; case JSTRAP_RETURN: *mustReturn = true; frame->setReturnValue(rval); return jit::DebugEpilogue(cx, frame, pc, true); case JSTRAP_THROW: cx->setPendingException(rval); return false; default: MOZ_CRASH("Invalid trap status"); } return true; } bool OnDebuggerStatement(JSContext* cx, BaselineFrame* frame, jsbytecode* pc, bool* mustReturn) { *mustReturn = false; switch (Debugger::onDebuggerStatement(cx, frame)) { case JSTRAP_ERROR: return false; case JSTRAP_CONTINUE: return true; case JSTRAP_RETURN: *mustReturn = true; return jit::DebugEpilogue(cx, frame, pc, true); case JSTRAP_THROW: return false; default: MOZ_CRASH("Invalid trap status"); } } bool GlobalHasLiveOnDebuggerStatement(JSContext* cx) { return cx->compartment()->isDebuggee() && Debugger::hasLiveHook(cx->global(), Debugger::OnDebuggerStatement); } bool PushLexicalEnv(JSContext* cx, BaselineFrame* frame, Handle scope) { return frame->pushLexicalEnvironment(cx, scope); } bool PopLexicalEnv(JSContext* cx, BaselineFrame* frame) { frame->popOffEnvironmentChain(); return true; } bool DebugLeaveThenPopLexicalEnv(JSContext* cx, BaselineFrame* frame, jsbytecode* pc) { MOZ_ALWAYS_TRUE(DebugLeaveLexicalEnv(cx, frame, pc)); frame->popOffEnvironmentChain(); return true; } bool FreshenLexicalEnv(JSContext* cx, BaselineFrame* frame) { return frame->freshenLexicalEnvironment(cx); } bool DebugLeaveThenFreshenLexicalEnv(JSContext* cx, BaselineFrame* frame, jsbytecode* pc) { MOZ_ALWAYS_TRUE(DebugLeaveLexicalEnv(cx, frame, pc)); return frame->freshenLexicalEnvironment(cx); } bool RecreateLexicalEnv(JSContext* cx, BaselineFrame* frame) { return frame->recreateLexicalEnvironment(cx); } bool DebugLeaveThenRecreateLexicalEnv(JSContext* cx, BaselineFrame* frame, jsbytecode* pc) { MOZ_ALWAYS_TRUE(DebugLeaveLexicalEnv(cx, frame, pc)); return frame->recreateLexicalEnvironment(cx); } bool DebugLeaveLexicalEnv(JSContext* cx, BaselineFrame* frame, jsbytecode* pc) { MOZ_ASSERT(frame->script()->baselineScript()->hasDebugInstrumentation()); if (cx->compartment()->isDebuggee()) DebugEnvironments::onPopLexical(cx, frame, pc); return true; } bool PushVarEnv(JSContext* cx, BaselineFrame* frame, HandleScope scope) { return frame->pushVarEnvironment(cx, scope); } bool PopVarEnv(JSContext* cx, BaselineFrame* frame) { frame->popOffEnvironmentChain(); return true; } bool EnterWith(JSContext* cx, BaselineFrame* frame, HandleValue val, Handle templ) { return EnterWithOperation(cx, frame, val, templ); } bool LeaveWith(JSContext* cx, BaselineFrame* frame) { if (MOZ_UNLIKELY(frame->isDebuggee())) DebugEnvironments::onPopWith(frame); frame->popOffEnvironmentChain(); return true; } bool InitBaselineFrameForOsr(BaselineFrame* frame, InterpreterFrame* interpFrame, uint32_t numStackValues) { return frame->initForOsr(interpFrame, numStackValues); } JSObject* CreateDerivedTypedObj(JSContext* cx, HandleObject descr, HandleObject owner, int32_t offset) { MOZ_ASSERT(descr->is()); MOZ_ASSERT(owner->is()); Rooted descr1(cx, &descr->as()); Rooted owner1(cx, &owner->as()); return OutlineTypedObject::createDerived(cx, descr1, owner1, offset); } JSString* StringReplace(JSContext* cx, HandleString string, HandleString pattern, HandleString repl) { MOZ_ASSERT(string); MOZ_ASSERT(pattern); MOZ_ASSERT(repl); return str_replace_string_raw(cx, string, pattern, repl); } bool RecompileImpl(JSContext* cx, bool force) { MOZ_ASSERT(cx->currentlyRunningInJit()); JitActivationIterator activations(cx->runtime()); JitFrameIterator iter(activations); MOZ_ASSERT(iter.type() == JitFrame_Exit); ++iter; RootedScript script(cx, iter.script()); MOZ_ASSERT(script->hasIonScript()); if (!IsIonEnabled(cx)) return true; MethodStatus status = Recompile(cx, script, nullptr, nullptr, force); if (status == Method_Error) return false; return true; } bool ForcedRecompile(JSContext* cx) { return RecompileImpl(cx, /* force = */ true); } bool Recompile(JSContext* cx) { return RecompileImpl(cx, /* force = */ false); } bool SetDenseOrUnboxedArrayElement(JSContext* cx, HandleObject obj, int32_t index, HandleValue value, bool strict) { // This function is called from Ion code for StoreElementHole's OOL path. // In this case we know the object is native or an unboxed array and that // no type changes are needed. DenseElementResult result = SetOrExtendAnyBoxedOrUnboxedDenseElements(cx, obj, index, value.address(), 1, ShouldUpdateTypes::DontUpdate); if (result != DenseElementResult::Incomplete) return result == DenseElementResult::Success; RootedValue indexVal(cx, Int32Value(index)); return SetObjectElement(cx, obj, indexVal, value, strict); } void AutoDetectInvalidation::setReturnOverride() { cx_->runtime()->jitRuntime()->setIonReturnOverride(rval_.get()); } void AssertValidObjectPtr(JSContext* cx, JSObject* obj) { #ifdef DEBUG // Check what we can, so that we'll hopefully assert/crash if we get a // bogus object (pointer). MOZ_ASSERT(obj->compartment() == cx->compartment()); MOZ_ASSERT(obj->runtimeFromMainThread() == cx->runtime()); MOZ_ASSERT_IF(!obj->hasLazyGroup() && obj->maybeShape(), obj->group()->clasp() == obj->maybeShape()->getObjectClass()); if (obj->isTenured()) { MOZ_ASSERT(obj->isAligned()); gc::AllocKind kind = obj->asTenured().getAllocKind(); MOZ_ASSERT(gc::IsObjectAllocKind(kind)); MOZ_ASSERT(obj->asTenured().zone() == cx->zone()); } #endif } void AssertValidObjectOrNullPtr(JSContext* cx, JSObject* obj) { if (obj) AssertValidObjectPtr(cx, obj); } void AssertValidStringPtr(JSContext* cx, JSString* str) { #ifdef DEBUG // We can't closely inspect strings from another runtime. if (str->runtimeFromAnyThread() != cx->runtime()) { MOZ_ASSERT(str->isPermanentAtom()); return; } if (str->isAtom()) MOZ_ASSERT(str->zone()->isAtomsZone()); else MOZ_ASSERT(str->zone() == cx->zone()); MOZ_ASSERT(str->isAligned()); MOZ_ASSERT(str->length() <= JSString::MAX_LENGTH); gc::AllocKind kind = str->getAllocKind(); if (str->isFatInline()) { MOZ_ASSERT(kind == gc::AllocKind::FAT_INLINE_STRING || kind == gc::AllocKind::FAT_INLINE_ATOM); } else if (str->isExternal()) { MOZ_ASSERT(kind == gc::AllocKind::EXTERNAL_STRING); } else if (str->isAtom()) { MOZ_ASSERT(kind == gc::AllocKind::ATOM); } else if (str->isFlat()) { MOZ_ASSERT(kind == gc::AllocKind::STRING || kind == gc::AllocKind::FAT_INLINE_STRING || kind == gc::AllocKind::EXTERNAL_STRING); } else { MOZ_ASSERT(kind == gc::AllocKind::STRING); } #endif } void AssertValidSymbolPtr(JSContext* cx, JS::Symbol* sym) { // We can't closely inspect symbols from another runtime. if (sym->runtimeFromAnyThread() != cx->runtime()) { MOZ_ASSERT(sym->isWellKnownSymbol()); return; } MOZ_ASSERT(sym->zone()->isAtomsZone()); MOZ_ASSERT(sym->isAligned()); if (JSString* desc = sym->description()) { MOZ_ASSERT(desc->isAtom()); AssertValidStringPtr(cx, desc); } MOZ_ASSERT(sym->getAllocKind() == gc::AllocKind::SYMBOL); } void AssertValidValue(JSContext* cx, Value* v) { if (v->isObject()) AssertValidObjectPtr(cx, &v->toObject()); else if (v->isString()) AssertValidStringPtr(cx, v->toString()); else if (v->isSymbol()) AssertValidSymbolPtr(cx, v->toSymbol()); } bool ObjectIsCallable(JSObject* obj) { return obj->isCallable(); } bool ObjectIsConstructor(JSObject* obj) { return obj->isConstructor(); } void MarkValueFromIon(JSRuntime* rt, Value* vp) { TraceManuallyBarrieredEdge(&rt->gc.marker, vp, "write barrier"); } void MarkStringFromIon(JSRuntime* rt, JSString** stringp) { if (*stringp) TraceManuallyBarrieredEdge(&rt->gc.marker, stringp, "write barrier"); } void MarkObjectFromIon(JSRuntime* rt, JSObject** objp) { if (*objp) TraceManuallyBarrieredEdge(&rt->gc.marker, objp, "write barrier"); } void MarkShapeFromIon(JSRuntime* rt, Shape** shapep) { TraceManuallyBarrieredEdge(&rt->gc.marker, shapep, "write barrier"); } void MarkObjectGroupFromIon(JSRuntime* rt, ObjectGroup** groupp) { TraceManuallyBarrieredEdge(&rt->gc.marker, groupp, "write barrier"); } bool ThrowRuntimeLexicalError(JSContext* cx, unsigned errorNumber) { ScriptFrameIter iter(cx); RootedScript script(cx, iter.script()); ReportRuntimeLexicalError(cx, errorNumber, script, iter.pc()); return false; } bool ThrowReadOnlyError(JSContext* cx, int32_t index) { RootedValue val(cx, Int32Value(index)); ReportValueError(cx, JSMSG_READ_ONLY, JSDVG_IGNORE_STACK, val, nullptr); return false; } bool ThrowBadDerivedReturn(JSContext* cx, HandleValue v) { ReportValueError(cx, JSMSG_BAD_DERIVED_RETURN, JSDVG_IGNORE_STACK, v, nullptr); return false; } bool BaselineThrowUninitializedThis(JSContext* cx, BaselineFrame* frame) { return ThrowUninitializedThis(cx, frame); } bool ThrowObjectCoercible(JSContext* cx, HandleValue v) { MOZ_ASSERT(v.isUndefined() || v.isNull()); MOZ_ALWAYS_FALSE(ToObjectSlow(cx, v, true)); return false; } bool BaselineGetFunctionThis(JSContext* cx, BaselineFrame* frame, MutableHandleValue res) { return GetFunctionThis(cx, frame, res); } } // namespace jit } // namespace js