/* -*- 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 "mozilla/ScopeExit.h" #include "mozilla/SizePrintfMacros.h" #include "jsprf.h" #include "jsutil.h" #include "jit/arm/Simulator-arm.h" #include "jit/BaselineIC.h" #include "jit/BaselineJIT.h" #include "jit/CompileInfo.h" #include "jit/JitSpewer.h" #include "jit/mips32/Simulator-mips32.h" #include "jit/mips64/Simulator-mips64.h" #include "jit/Recover.h" #include "jit/RematerializedFrame.h" #include "vm/ArgumentsObject.h" #include "vm/Debugger.h" #include "vm/TraceLogging.h" #include "jsscriptinlines.h" #include "jit/JitFrames-inl.h" using namespace js; using namespace js::jit; // BaselineStackBuilder may reallocate its buffer if the current one is too // small. To avoid dangling pointers, BufferPointer represents a pointer into // this buffer as a pointer to the header and a fixed offset. template class BufferPointer { BaselineBailoutInfo** header_; size_t offset_; bool heap_; public: BufferPointer(BaselineBailoutInfo** header, size_t offset, bool heap) : header_(header), offset_(offset), heap_(heap) { } T* get() const { BaselineBailoutInfo* header = *header_; if (!heap_) return (T*)(header->incomingStack + offset_); uint8_t* p = header->copyStackTop - offset_; MOZ_ASSERT(p >= header->copyStackBottom && p < header->copyStackTop); return (T*)p; } void set(const T& value) { *get() = value; } // Note: we return a copy instead of a reference, to avoid potential memory // safety hazards when the underlying buffer gets resized. const T operator*() const { return *get(); } T* operator->() const { return get(); } }; /** * BaselineStackBuilder helps abstract the process of rebuilding the C stack on the heap. * It takes a bailout iterator and keeps track of the point on the C stack from which * the reconstructed frames will be written. * * It exposes methods to write data into the heap memory storing the reconstructed * stack. It also exposes method to easily calculate addresses. This includes both the * virtual address that a particular value will be at when it's eventually copied onto * the stack, as well as the current actual address of that value (whether on the heap * allocated portion being constructed or the existing stack). * * The abstraction handles transparent re-allocation of the heap memory when it * needs to be enlarged to accommodate new data. Similarly to the C stack, the * data that's written to the reconstructed stack grows from high to low in memory. * * The lowest region of the allocated memory contains a BaselineBailoutInfo structure that * points to the start and end of the written data. */ struct BaselineStackBuilder { JitFrameIterator& iter_; JitFrameLayout* frame_; static size_t HeaderSize() { return AlignBytes(sizeof(BaselineBailoutInfo), sizeof(void*)); } size_t bufferTotal_; size_t bufferAvail_; size_t bufferUsed_; uint8_t* buffer_; BaselineBailoutInfo* header_; size_t framePushed_; BaselineStackBuilder(JitFrameIterator& iter, size_t initialSize) : iter_(iter), frame_(static_cast(iter.current())), bufferTotal_(initialSize), bufferAvail_(0), bufferUsed_(0), buffer_(nullptr), header_(nullptr), framePushed_(0) { MOZ_ASSERT(bufferTotal_ >= HeaderSize()); MOZ_ASSERT(iter.isBailoutJS()); } ~BaselineStackBuilder() { js_free(buffer_); } MOZ_MUST_USE bool init() { MOZ_ASSERT(!buffer_); MOZ_ASSERT(bufferUsed_ == 0); buffer_ = reinterpret_cast(js_calloc(bufferTotal_)); if (!buffer_) return false; bufferAvail_ = bufferTotal_ - HeaderSize(); bufferUsed_ = 0; header_ = reinterpret_cast(buffer_); header_->incomingStack = reinterpret_cast(frame_); header_->copyStackTop = buffer_ + bufferTotal_; header_->copyStackBottom = header_->copyStackTop; header_->setR0 = 0; header_->valueR0 = UndefinedValue(); header_->setR1 = 0; header_->valueR1 = UndefinedValue(); header_->resumeFramePtr = nullptr; header_->resumeAddr = nullptr; header_->resumePC = nullptr; header_->monitorStub = nullptr; header_->numFrames = 0; header_->checkGlobalDeclarationConflicts = false; return true; } MOZ_MUST_USE bool enlarge() { MOZ_ASSERT(buffer_ != nullptr); if (bufferTotal_ & mozilla::tl::MulOverflowMask<2>::value) return false; size_t newSize = bufferTotal_ * 2; uint8_t* newBuffer = reinterpret_cast(js_calloc(newSize)); if (!newBuffer) return false; memcpy((newBuffer + newSize) - bufferUsed_, header_->copyStackBottom, bufferUsed_); memcpy(newBuffer, header_, sizeof(BaselineBailoutInfo)); js_free(buffer_); buffer_ = newBuffer; bufferTotal_ = newSize; bufferAvail_ = newSize - (HeaderSize() + bufferUsed_); header_ = reinterpret_cast(buffer_); header_->copyStackTop = buffer_ + bufferTotal_; header_->copyStackBottom = header_->copyStackTop - bufferUsed_; return true; } BaselineBailoutInfo* info() { MOZ_ASSERT(header_ == reinterpret_cast(buffer_)); return header_; } BaselineBailoutInfo* takeBuffer() { MOZ_ASSERT(header_ == reinterpret_cast(buffer_)); buffer_ = nullptr; return header_; } void resetFramePushed() { framePushed_ = 0; } size_t framePushed() const { return framePushed_; } MOZ_MUST_USE bool subtract(size_t size, const char* info = nullptr) { // enlarge the buffer if need be. while (size > bufferAvail_) { if (!enlarge()) return false; } // write out element. header_->copyStackBottom -= size; bufferAvail_ -= size; bufferUsed_ += size; framePushed_ += size; if (info) { JitSpew(JitSpew_BaselineBailouts, " SUB_%03d %p/%p %-15s", (int) size, header_->copyStackBottom, virtualPointerAtStackOffset(0), info); } return true; } template MOZ_MUST_USE bool write(const T& t) { MOZ_ASSERT(!(uintptr_t(&t) >= uintptr_t(header_->copyStackBottom) && uintptr_t(&t) < uintptr_t(header_->copyStackTop)), "Should not reference memory that can be freed"); if (!subtract(sizeof(T))) return false; memcpy(header_->copyStackBottom, &t, sizeof(T)); return true; } template MOZ_MUST_USE bool writePtr(T* t, const char* info) { if (!write(t)) return false; if (info) JitSpew(JitSpew_BaselineBailouts, " WRITE_PTR %p/%p %-15s %p", header_->copyStackBottom, virtualPointerAtStackOffset(0), info, t); return true; } MOZ_MUST_USE bool writeWord(size_t w, const char* info) { if (!write(w)) return false; if (info) { if (sizeof(size_t) == 4) { JitSpew(JitSpew_BaselineBailouts, " WRITE_WRD %p/%p %-15s %08" PRIxSIZE, header_->copyStackBottom, virtualPointerAtStackOffset(0), info, w); } else { JitSpew(JitSpew_BaselineBailouts, " WRITE_WRD %p/%p %-15s %016" PRIxSIZE, header_->copyStackBottom, virtualPointerAtStackOffset(0), info, w); } } return true; } MOZ_MUST_USE bool writeValue(const Value& val, const char* info) { if (!write(val)) return false; if (info) { JitSpew(JitSpew_BaselineBailouts, " WRITE_VAL %p/%p %-15s %016" PRIx64, header_->copyStackBottom, virtualPointerAtStackOffset(0), info, *((uint64_t*) &val)); } return true; } MOZ_MUST_USE bool maybeWritePadding(size_t alignment, size_t after, const char* info) { MOZ_ASSERT(framePushed_ % sizeof(Value) == 0); MOZ_ASSERT(after % sizeof(Value) == 0); size_t offset = ComputeByteAlignment(after, alignment); while (framePushed_ % alignment != offset) { if (!writeValue(MagicValue(JS_ARG_POISON), info)) return false; } return true; } Value popValue() { MOZ_ASSERT(bufferUsed_ >= sizeof(Value)); MOZ_ASSERT(framePushed_ >= sizeof(Value)); bufferAvail_ += sizeof(Value); bufferUsed_ -= sizeof(Value); framePushed_ -= sizeof(Value); Value result = *((Value*) header_->copyStackBottom); header_->copyStackBottom += sizeof(Value); return result; } void popValueInto(PCMappingSlotInfo::SlotLocation loc) { MOZ_ASSERT(PCMappingSlotInfo::ValidSlotLocation(loc)); switch(loc) { case PCMappingSlotInfo::SlotInR0: header_->setR0 = 1; header_->valueR0 = popValue(); break; case PCMappingSlotInfo::SlotInR1: header_->setR1 = 1; header_->valueR1 = popValue(); break; default: MOZ_ASSERT(loc == PCMappingSlotInfo::SlotIgnore); popValue(); break; } } void setResumeFramePtr(void* resumeFramePtr) { header_->resumeFramePtr = resumeFramePtr; } void setResumeAddr(void* resumeAddr) { header_->resumeAddr = resumeAddr; } void setResumePC(jsbytecode* pc) { header_->resumePC = pc; } void setMonitorStub(ICStub* stub) { header_->monitorStub = stub; } template BufferPointer pointerAtStackOffset(size_t offset) { if (offset < bufferUsed_) { // Calculate offset from copyStackTop. offset = header_->copyStackTop - (header_->copyStackBottom + offset); return BufferPointer(&header_, offset, /* heap = */ true); } return BufferPointer(&header_, offset - bufferUsed_, /* heap = */ false); } BufferPointer valuePointerAtStackOffset(size_t offset) { return pointerAtStackOffset(offset); } inline uint8_t* virtualPointerAtStackOffset(size_t offset) { if (offset < bufferUsed_) return reinterpret_cast(frame_) - (bufferUsed_ - offset); return reinterpret_cast(frame_) + (offset - bufferUsed_); } inline JitFrameLayout* startFrame() { return frame_; } BufferPointer topFrameAddress() { return pointerAtStackOffset(0); } // // This method should only be called when the builder is in a state where it is // starting to construct the stack frame for the next callee. This means that // the lowest value on the constructed stack is the return address for the previous // caller frame. // // This method is used to compute the value of the frame pointer (e.g. ebp on x86) // that would have been saved by the baseline jitcode when it was entered. In some // cases, this value can be bogus since we can ensure that the caller would have saved // it anyway. // void* calculatePrevFramePtr() { // Get the incoming frame. BufferPointer topFrame = topFrameAddress(); FrameType type = topFrame->prevType(); // For IonJS, IonAccessorIC and Entry frames, the "saved" frame pointer // in the baseline frame is meaningless, since Ion saves all registers // before calling other ion frames, and the entry frame saves all // registers too. if (type == JitFrame_IonJS || type == JitFrame_Entry || type == JitFrame_IonAccessorIC) return nullptr; // BaselineStub - Baseline calling into Ion. // PrevFramePtr needs to point to the BaselineStubFrame's saved frame pointer. // STACK_START_ADDR + JitFrameLayout::Size() + PREV_FRAME_SIZE // - BaselineStubFrameLayout::reverseOffsetOfSavedFramePtr() if (type == JitFrame_BaselineStub) { size_t offset = JitFrameLayout::Size() + topFrame->prevFrameLocalSize() + BaselineStubFrameLayout::reverseOffsetOfSavedFramePtr(); return virtualPointerAtStackOffset(offset); } MOZ_ASSERT(type == JitFrame_Rectifier); // Rectifier - behaviour depends on the frame preceding the rectifier frame, and // whether the arch is x86 or not. The x86 rectifier frame saves the frame pointer, // so we can calculate it directly. For other archs, the previous frame pointer // is stored on the stack in the frame that precedes the rectifier frame. size_t priorOffset = JitFrameLayout::Size() + topFrame->prevFrameLocalSize(); #if defined(JS_CODEGEN_X86) // On X86, the FramePointer is pushed as the first value in the Rectifier frame. MOZ_ASSERT(BaselineFrameReg == FramePointer); priorOffset -= sizeof(void*); return virtualPointerAtStackOffset(priorOffset); #elif defined(JS_CODEGEN_ARM) || defined(JS_CODEGEN_ARM64) || \ defined(JS_CODEGEN_MIPS32) || defined(JS_CODEGEN_MIPS64) || \ defined(JS_CODEGEN_X64) // On X64, ARM, ARM64, and MIPS, the frame pointer save location depends on // the caller of the rectifier frame. BufferPointer priorFrame = pointerAtStackOffset(priorOffset); FrameType priorType = priorFrame->prevType(); MOZ_ASSERT(priorType == JitFrame_IonJS || priorType == JitFrame_BaselineStub); // If the frame preceding the rectifier is an IonJS frame, then once again // the frame pointer does not matter. if (priorType == JitFrame_IonJS) return nullptr; // Otherwise, the frame preceding the rectifier is a BaselineStub frame. // let X = STACK_START_ADDR + JitFrameLayout::Size() + PREV_FRAME_SIZE // X + RectifierFrameLayout::Size() // + ((RectifierFrameLayout*) X)->prevFrameLocalSize() // - BaselineStubFrameLayout::reverseOffsetOfSavedFramePtr() size_t extraOffset = RectifierFrameLayout::Size() + priorFrame->prevFrameLocalSize() + BaselineStubFrameLayout::reverseOffsetOfSavedFramePtr(); return virtualPointerAtStackOffset(priorOffset + extraOffset); #elif defined(JS_CODEGEN_NONE) MOZ_CRASH(); #else # error "Bad architecture!" #endif } void setCheckGlobalDeclarationConflicts() { header_->checkGlobalDeclarationConflicts = true; } }; // Ensure that all value locations are readable from the SnapshotIterator. // Remove RInstructionResults from the JitActivation if the frame got recovered // ahead of the bailout. class SnapshotIteratorForBailout : public SnapshotIterator { JitActivation* activation_; JitFrameIterator& iter_; public: SnapshotIteratorForBailout(JitActivation* activation, JitFrameIterator& iter) : SnapshotIterator(iter, activation->bailoutData()->machineState()), activation_(activation), iter_(iter) { MOZ_ASSERT(iter.isBailoutJS()); } ~SnapshotIteratorForBailout() { // The bailout is complete, we no longer need the recover instruction // results. activation_->removeIonFrameRecovery(fp_); } // Take previously computed result out of the activation, or compute the // results of all recover instructions contained in the snapshot. MOZ_MUST_USE bool init(JSContext* cx) { // Under a bailout, there is no need to invalidate the frame after // evaluating the recover instruction, as the invalidation is only // needed to cause of the frame which has been introspected. MaybeReadFallback recoverBailout(cx, activation_, &iter_, MaybeReadFallback::Fallback_DoNothing); return initInstructionResults(recoverBailout); } }; #ifdef DEBUG static inline bool IsInlinableFallback(ICFallbackStub* icEntry) { return icEntry->isCall_Fallback() || icEntry->isGetProp_Fallback() || icEntry->isSetProp_Fallback(); } #endif static inline void* GetStubReturnAddress(JSContext* cx, jsbytecode* pc) { if (IsGetPropPC(pc)) return cx->compartment()->jitCompartment()->baselineGetPropReturnAddr(); if (IsSetPropPC(pc)) return cx->compartment()->jitCompartment()->baselineSetPropReturnAddr(); // This should be a call op of some kind, now. MOZ_ASSERT(IsCallPC(pc)); return cx->compartment()->jitCompartment()->baselineCallReturnAddr(JSOp(*pc) == JSOP_NEW); } static inline jsbytecode* GetNextNonLoopEntryPc(jsbytecode* pc) { JSOp op = JSOp(*pc); if (op == JSOP_GOTO) return pc + GET_JUMP_OFFSET(pc); if (op == JSOP_LOOPENTRY || op == JSOP_NOP || op == JSOP_LOOPHEAD) return GetNextPc(pc); return pc; } static bool HasLiveIteratorAtStackDepth(JSScript* script, jsbytecode* pc, uint32_t stackDepth) { if (!script->hasTrynotes()) return false; JSTryNote* tn = script->trynotes()->vector; JSTryNote* tnEnd = tn + script->trynotes()->length; uint32_t pcOffset = uint32_t(pc - script->main()); for (; tn != tnEnd; ++tn) { if (pcOffset < tn->start) continue; if (pcOffset >= tn->start + tn->length) continue; // For-in loops have only the iterator on stack. if (tn->kind == JSTRY_FOR_IN && stackDepth == tn->stackDepth) return true; // For-of loops have both the iterator and the result object on // stack. The iterator is below the result object. if (tn->kind == JSTRY_FOR_OF && stackDepth == tn->stackDepth - 1) return true; } return false; } static bool IsPrologueBailout(const SnapshotIterator& iter, const ExceptionBailoutInfo* excInfo) { // If we are propagating an exception for debug mode, we will not resume // into baseline code, but instead into HandleExceptionBaseline (i.e., // never before the prologue). return iter.pcOffset() == 0 && !iter.resumeAfter() && (!excInfo || !excInfo->propagatingIonExceptionForDebugMode()); } // For every inline frame, we write out the following data: // // | ... | // +---------------+ // | Descr(???) | --- Descr size here is (PREV_FRAME_SIZE) // +---------------+ // | ReturnAddr | // -- +===============+ --- OVERWRITE STARTS HERE (START_STACK_ADDR) // | | PrevFramePtr | // | +-> +---------------+ // | | | Baseline | // | | | Frame | // | | +---------------+ // | | | Fixed0 | // | | +---------------+ // +--< | | ... | // | | | +---------------+ // | | | | FixedF | // | | | +---------------+ // | | | | Stack0 | // | | | +---------------+ // | | | | ... | // | | | +---------------+ // | | | | StackS | // | -- | +---------------+ --- IF NOT LAST INLINE FRAME, // +------------| Descr(BLJS) | --- CALLING INFO STARTS HERE // | +---------------+ // | | ReturnAddr | <-- return into main jitcode after IC // -- | +===============+ // | | | StubPtr | // | | +---------------+ // | +---| FramePtr | // | +---------------+ --- The inlined frame might OSR in Ion // | | Padding? | --- Thus the return address should be aligned. // | +---------------+ // +--< | ArgA | // | | +---------------+ // | | | ... | // | | +---------------+ // | | | Arg0 | // | | +---------------+ // | | | ThisV | // | -- +---------------+ // | | ActualArgC | // | +---------------+ // | | CalleeToken | // | +---------------+ // +------------| Descr(BLStub) | // +---------------+ // | ReturnAddr | <-- return into ICCall_Scripted IC // -- +===============+ --- IF CALLEE FORMAL ARGS > ActualArgC // | | Padding? | // | +---------------+ // | | UndefinedU | // | +---------------+ // | | ... | // | +---------------+ // | | Undefined0 | // +--< +---------------+ // | | | ArgA | // | | +---------------+ // | | | ... | // | | +---------------+ // | | | Arg0 | // | | +---------------+ // | | | ThisV | // | -- +---------------+ // | | ActualArgC | // | +---------------+ // | | CalleeToken | // | +---------------+ // +------------| Descr(Rect) | // +---------------+ // | ReturnAddr | <-- return into ArgumentsRectifier after call // +===============+ // static bool InitFromBailout(JSContext* cx, HandleScript caller, jsbytecode* callerPC, HandleFunction fun, HandleScript script, IonScript* ionScript, SnapshotIterator& iter, bool invalidate, BaselineStackBuilder& builder, MutableHandle> startFrameFormals, MutableHandleFunction nextCallee, jsbytecode** callPC, const ExceptionBailoutInfo* excInfo) { // The Baseline frames we will reconstruct on the heap are not rooted, so GC // must be suppressed here. MOZ_ASSERT(cx->mainThread().suppressGC); MOZ_ASSERT(script->hasBaselineScript()); // Are we catching an exception? bool catchingException = excInfo && excInfo->catchingException(); // If we are catching an exception, we are bailing out to a catch or // finally block and this is the frame where we will resume. Usually the // expression stack should be empty in this case but there can be // iterators on the stack. uint32_t exprStackSlots; if (catchingException) exprStackSlots = excInfo->numExprSlots(); else exprStackSlots = iter.numAllocations() - (script->nfixed() + CountArgSlots(script, fun)); builder.resetFramePushed(); // Build first baseline frame: // +===============+ // | PrevFramePtr | // +---------------+ // | Baseline | // | Frame | // +---------------+ // | Fixed0 | // +---------------+ // | ... | // +---------------+ // | FixedF | // +---------------+ // | Stack0 | // +---------------+ // | ... | // +---------------+ // | StackS | // +---------------+ --- IF NOT LAST INLINE FRAME, // | Descr(BLJS) | --- CALLING INFO STARTS HERE // +---------------+ // | ReturnAddr | <-- return into main jitcode after IC // +===============+ JitSpew(JitSpew_BaselineBailouts, " Unpacking %s:%" PRIuSIZE, script->filename(), script->lineno()); JitSpew(JitSpew_BaselineBailouts, " [BASELINE-JS FRAME]"); // Calculate and write the previous frame pointer value. // Record the virtual stack offset at this location. Later on, if we end up // writing out a BaselineStub frame for the next callee, we'll need to save the // address. void* prevFramePtr = builder.calculatePrevFramePtr(); if (!builder.writePtr(prevFramePtr, "PrevFramePtr")) return false; prevFramePtr = builder.virtualPointerAtStackOffset(0); // Write struct BaselineFrame. if (!builder.subtract(BaselineFrame::Size(), "BaselineFrame")) return false; BufferPointer blFrame = builder.pointerAtStackOffset(0); uint32_t flags = 0; // If we are bailing to a script whose execution is observed, mark the // baseline frame as a debuggee frame. This is to cover the case where we // don't rematerialize the Ion frame via the Debugger. if (script->isDebuggee()) flags |= BaselineFrame::DEBUGGEE; // Initialize BaselineFrame's envChain and argsObj JSObject* envChain = nullptr; Value returnValue; ArgumentsObject* argsObj = nullptr; BailoutKind bailoutKind = iter.bailoutKind(); if (bailoutKind == Bailout_ArgumentCheck) { // Temporary hack -- skip the (unused) envChain, because it could be // bogus (we can fail before the env chain slot is set). Strip the // hasEnvironmentChain flag and this will be fixed up later in // |FinishBailoutToBaseline|, which calls // |EnsureHasEnvironmentObjects|. JitSpew(JitSpew_BaselineBailouts, " Bailout_ArgumentCheck! (no valid envChain)"); iter.skip(); // skip |return value| iter.skip(); returnValue = UndefinedValue(); // Scripts with |argumentsHasVarBinding| have an extra slot. if (script->argumentsHasVarBinding()) { JitSpew(JitSpew_BaselineBailouts, " Bailout_ArgumentCheck for script with argumentsHasVarBinding!" "Using empty arguments object"); iter.skip(); } } else { Value v = iter.read(); if (v.isObject()) { envChain = &v.toObject(); if (fun && ((fun->needsCallObject() && envChain->is()) || (fun->needsNamedLambdaEnvironment() && !fun->needsCallObject() && envChain->is() && &envChain->as().scope() == script->maybeNamedLambdaScope()))) { MOZ_ASSERT(!fun->needsExtraBodyVarEnvironment()); flags |= BaselineFrame::HAS_INITIAL_ENV; } } else { MOZ_ASSERT(v.isUndefined() || v.isMagic(JS_OPTIMIZED_OUT)); // Get env chain from function or script. if (fun) { // If pcOffset == 0, we may have to push a new call object, so // we leave envChain nullptr and enter baseline code before // the prologue. if (!IsPrologueBailout(iter, excInfo)) envChain = fun->environment(); } else if (script->module()) { envChain = script->module()->environment(); } else { // For global scripts without a non-syntactic env the env // chain is the script's global lexical environment (Ion does // not compile scripts with a non-syntactic global scope). // Also note that it's invalid to resume into the prologue in // this case because the prologue expects the env chain in R1 // for eval and global scripts. MOZ_ASSERT(!script->isForEval()); MOZ_ASSERT(!script->hasNonSyntacticScope()); envChain = &(script->global().lexicalEnvironment()); // We have possibly bailed out before Ion could do the global // declaration conflicts check. Since it's invalid to resume // into the prologue, set a flag so FinishBailoutToBaseline // can do the conflict check. if (IsPrologueBailout(iter, excInfo)) builder.setCheckGlobalDeclarationConflicts(); } } // Make sure to add HAS_RVAL to flags here because setFlags() below // will clobber it. returnValue = iter.read(); flags |= BaselineFrame::HAS_RVAL; // If script maybe has an arguments object, the third slot will hold it. if (script->argumentsHasVarBinding()) { v = iter.read(); MOZ_ASSERT(v.isObject() || v.isUndefined() || v.isMagic(JS_OPTIMIZED_OUT)); if (v.isObject()) argsObj = &v.toObject().as(); } } JitSpew(JitSpew_BaselineBailouts, " EnvChain=%p", envChain); blFrame->setEnvironmentChain(envChain); JitSpew(JitSpew_BaselineBailouts, " ReturnValue=%016" PRIx64, *((uint64_t*) &returnValue)); blFrame->setReturnValue(returnValue); // Do not need to initialize scratchValue field in BaselineFrame. blFrame->setFlags(flags); // initArgsObjUnchecked modifies the frame's flags, so call it after setFlags. if (argsObj) blFrame->initArgsObjUnchecked(*argsObj); if (fun) { // The unpacked thisv and arguments should overwrite the pushed args present // in the calling frame. Value thisv = iter.read(); JitSpew(JitSpew_BaselineBailouts, " Is function!"); JitSpew(JitSpew_BaselineBailouts, " thisv=%016" PRIx64, *((uint64_t*) &thisv)); size_t thisvOffset = builder.framePushed() + JitFrameLayout::offsetOfThis(); builder.valuePointerAtStackOffset(thisvOffset).set(thisv); MOZ_ASSERT(iter.numAllocations() >= CountArgSlots(script, fun)); JitSpew(JitSpew_BaselineBailouts, " frame slots %u, nargs %" PRIuSIZE ", nfixed %" PRIuSIZE, iter.numAllocations(), fun->nargs(), script->nfixed()); if (!callerPC) { // This is the first frame. Store the formals in a Vector until we // are done. Due to UCE and phi elimination, we could store an // UndefinedValue() here for formals we think are unused, but // locals may still reference the original argument slot // (MParameter/LArgument) and expect the original Value. MOZ_ASSERT(startFrameFormals.empty()); if (!startFrameFormals.resize(fun->nargs())) return false; } for (uint32_t i = 0; i < fun->nargs(); i++) { Value arg = iter.read(); JitSpew(JitSpew_BaselineBailouts, " arg %d = %016" PRIx64, (int) i, *((uint64_t*) &arg)); if (callerPC) { size_t argOffset = builder.framePushed() + JitFrameLayout::offsetOfActualArg(i); builder.valuePointerAtStackOffset(argOffset).set(arg); } else { startFrameFormals[i].set(arg); } } } for (uint32_t i = 0; i < script->nfixed(); i++) { Value slot = iter.read(); if (!builder.writeValue(slot, "FixedValue")) return false; } // Get the pc. If we are handling an exception, resume at the pc of the // catch or finally block. jsbytecode* pc = catchingException ? excInfo->resumePC() : script->offsetToPC(iter.pcOffset()); bool resumeAfter = catchingException ? false : iter.resumeAfter(); // When pgo is enabled, increment the counter of the block in which we // resume, as Ion does not keep track of the code coverage. // // We need to do that when pgo is enabled, as after a specific number of // FirstExecution bailouts, we invalidate and recompile the script with // IonMonkey. Failing to increment the counter of the current basic block // might lead to repeated bailouts and invalidations. if (!JitOptions.disablePgo && script->hasScriptCounts()) script->incHitCount(pc); JSOp op = JSOp(*pc); // Fixup inlined JSOP_FUNCALL, JSOP_FUNAPPLY, and accessors on the caller side. // On the caller side this must represent like the function wasn't inlined. uint32_t pushedSlots = 0; AutoValueVector savedCallerArgs(cx); bool needToSaveArgs = op == JSOP_FUNAPPLY || IsGetPropPC(pc) || IsSetPropPC(pc); if (iter.moreFrames() && (op == JSOP_FUNCALL || needToSaveArgs)) { uint32_t inlined_args = 0; if (op == JSOP_FUNCALL) inlined_args = 2 + GET_ARGC(pc) - 1; else if (op == JSOP_FUNAPPLY) inlined_args = 2 + blFrame->numActualArgs(); else inlined_args = 2 + IsSetPropPC(pc); MOZ_ASSERT(exprStackSlots >= inlined_args); pushedSlots = exprStackSlots - inlined_args; JitSpew(JitSpew_BaselineBailouts, " pushing %u expression stack slots before fixup", pushedSlots); for (uint32_t i = 0; i < pushedSlots; i++) { Value v = iter.read(); if (!builder.writeValue(v, "StackValue")) return false; } if (op == JSOP_FUNCALL) { // When funcall got inlined and the native js_fun_call was bypassed, // the stack state is incorrect. To restore correctly it must look like // js_fun_call was actually called. This means transforming the stack // from |target, this, args| to |js_fun_call, target, this, args| // The js_fun_call is never read, so just pushing undefined now. JitSpew(JitSpew_BaselineBailouts, " pushing undefined to fixup funcall"); if (!builder.writeValue(UndefinedValue(), "StackValue")) return false; } if (needToSaveArgs) { // When an accessor is inlined, the whole thing is a lie. There // should never have been a call there. Fix the caller's stack to // forget it ever happened. // When funapply gets inlined we take all arguments out of the // arguments array. So the stack state is incorrect. To restore // correctly it must look like js_fun_apply was actually called. // This means transforming the stack from |target, this, arg1, ...| // to |js_fun_apply, target, this, argObject|. // Since the information is never read, we can just push undefined // for all values. if (op == JSOP_FUNAPPLY) { JitSpew(JitSpew_BaselineBailouts, " pushing 4x undefined to fixup funapply"); if (!builder.writeValue(UndefinedValue(), "StackValue")) return false; if (!builder.writeValue(UndefinedValue(), "StackValue")) return false; if (!builder.writeValue(UndefinedValue(), "StackValue")) return false; if (!builder.writeValue(UndefinedValue(), "StackValue")) return false; } // Save the actual arguments. They are needed on the callee side // as the arguments. Else we can't recover them. if (!savedCallerArgs.resize(inlined_args)) return false; for (uint32_t i = 0; i < inlined_args; i++) savedCallerArgs[i].set(iter.read()); if (IsSetPropPC(pc)) { // We would love to just save all the arguments and leave them // in the stub frame pushed below, but we will lose the inital // argument which the function was called with, which we must // return to the caller, even if the setter internally modifies // its arguments. Stash the initial argument on the stack, to be // later retrieved by the SetProp_Fallback stub. Value initialArg = savedCallerArgs[inlined_args - 1]; JitSpew(JitSpew_BaselineBailouts, " pushing setter's initial argument"); if (!builder.writeValue(initialArg, "StackValue")) return false; } pushedSlots = exprStackSlots; } } JitSpew(JitSpew_BaselineBailouts, " pushing %u expression stack slots", exprStackSlots - pushedSlots); for (uint32_t i = pushedSlots; i < exprStackSlots; i++) { Value v; if (!iter.moreFrames() && i == exprStackSlots - 1 && cx->runtime()->jitRuntime()->hasIonReturnOverride()) { // If coming from an invalidation bailout, and this is the topmost // value, and a value override has been specified, don't read from the // iterator. Otherwise, we risk using a garbage value. MOZ_ASSERT(invalidate); iter.skip(); JitSpew(JitSpew_BaselineBailouts, " [Return Override]"); v = cx->runtime()->jitRuntime()->takeIonReturnOverride(); } else if (excInfo && excInfo->propagatingIonExceptionForDebugMode()) { // If we are in the middle of propagating an exception from Ion by // bailing to baseline due to debug mode, we might not have all // the stack if we are at the newest frame. // // For instance, if calling |f()| pushed an Ion frame which threw, // the snapshot expects the return value to be pushed, but it's // possible nothing was pushed before we threw. We can't drop // iterators, however, so read them out. They will be closed by // HandleExceptionBaseline. MOZ_ASSERT(cx->compartment()->isDebuggee()); if (iter.moreFrames() || HasLiveIteratorAtStackDepth(script, pc, i + 1)) { v = iter.read(); } else { iter.skip(); v = MagicValue(JS_OPTIMIZED_OUT); } } else { v = iter.read(); } if (!builder.writeValue(v, "StackValue")) return false; } // BaselineFrame::frameSize is the size of everything pushed since // the builder.resetFramePushed() call. uint32_t frameSize = builder.framePushed(); blFrame->setFrameSize(frameSize); JitSpew(JitSpew_BaselineBailouts, " FrameSize=%u", frameSize); // numValueSlots() is based on the frame size, do some sanity checks. MOZ_ASSERT(blFrame->numValueSlots() >= script->nfixed()); MOZ_ASSERT(blFrame->numValueSlots() <= script->nslots()); // If we are resuming at a LOOPENTRY op, resume at the next op to avoid // a bailout -> enter Ion -> bailout loop with --ion-eager. See also // ThunkToInterpreter. // // The algorithm below is the "tortoise and the hare" algorithm. See bug // 994444 for more explanation. if (!resumeAfter) { jsbytecode* fasterPc = pc; while (true) { pc = GetNextNonLoopEntryPc(pc); fasterPc = GetNextNonLoopEntryPc(GetNextNonLoopEntryPc(fasterPc)); if (fasterPc == pc) break; } op = JSOp(*pc); } uint32_t pcOff = script->pcToOffset(pc); bool isCall = IsCallPC(pc); BaselineScript* baselineScript = script->baselineScript(); #ifdef DEBUG uint32_t expectedDepth; bool reachablePC; if (!ReconstructStackDepth(cx, script, resumeAfter ? GetNextPc(pc) : pc, &expectedDepth, &reachablePC)) return false; if (reachablePC) { if (op != JSOP_FUNAPPLY || !iter.moreFrames() || resumeAfter) { if (op == JSOP_FUNCALL) { // For fun.call(this, ...); the reconstructStackDepth will // include the this. When inlining that is not included. // So the exprStackSlots will be one less. MOZ_ASSERT(expectedDepth - exprStackSlots <= 1); } else if (iter.moreFrames() && (IsGetPropPC(pc) || IsSetPropPC(pc))) { // Accessors coming out of ion are inlined via a complete // lie perpetrated by the compiler internally. Ion just rearranges // the stack, and pretends that it looked like a call all along. // This means that the depth is actually one *more* than expected // by the interpreter, as there is now a JSFunction, |this| and [arg], // rather than the expected |this| and [arg] // Note that none of that was pushed, but it's still reflected // in exprStackSlots. MOZ_ASSERT(exprStackSlots - expectedDepth == 1); } else { // For fun.apply({}, arguments) the reconstructStackDepth will // have stackdepth 4, but it could be that we inlined the // funapply. In that case exprStackSlots, will have the real // arguments in the slots and not be 4. MOZ_ASSERT(exprStackSlots == expectedDepth); } } } #endif #ifdef JS_JITSPEW JitSpew(JitSpew_BaselineBailouts, " Resuming %s pc offset %d (op %s) (line %d) of %s:%" PRIuSIZE, resumeAfter ? "after" : "at", (int) pcOff, CodeName[op], PCToLineNumber(script, pc), script->filename(), script->lineno()); JitSpew(JitSpew_BaselineBailouts, " Bailout kind: %s", BailoutKindString(bailoutKind)); #endif bool pushedNewTarget = op == JSOP_NEW; // If this was the last inline frame, or we are bailing out to a catch or // finally block in this frame, then unpacking is almost done. if (!iter.moreFrames() || catchingException) { // Last frame, so PC for call to next frame is set to nullptr. *callPC = nullptr; // If the bailout was a resumeAfter, and the opcode is monitored, // then the bailed out state should be in a position to enter // into the ICTypeMonitor chain for the op. bool enterMonitorChain = false; if (resumeAfter && (CodeSpec[op].format & JOF_TYPESET)) { // Not every monitored op has a monitored fallback stub, e.g. // JSOP_NEWOBJECT, which always returns the same type for a // particular script/pc location. BaselineICEntry& icEntry = baselineScript->icEntryFromPCOffset(pcOff); ICFallbackStub* fallbackStub = icEntry.firstStub()->getChainFallback(); if (fallbackStub->isMonitoredFallback()) enterMonitorChain = true; } uint32_t numCallArgs = isCall ? GET_ARGC(pc) : 0; if (resumeAfter && !enterMonitorChain) pc = GetNextPc(pc); builder.setResumePC(pc); builder.setResumeFramePtr(prevFramePtr); if (enterMonitorChain) { BaselineICEntry& icEntry = baselineScript->icEntryFromPCOffset(pcOff); ICFallbackStub* fallbackStub = icEntry.firstStub()->getChainFallback(); MOZ_ASSERT(fallbackStub->isMonitoredFallback()); JitSpew(JitSpew_BaselineBailouts, " [TYPE-MONITOR CHAIN]"); ICMonitoredFallbackStub* monFallbackStub = fallbackStub->toMonitoredFallbackStub(); ICStub* firstMonStub = monFallbackStub->fallbackMonitorStub()->firstMonitorStub(); // To enter a monitoring chain, we load the top stack value into R0 JitSpew(JitSpew_BaselineBailouts, " Popping top stack value into R0."); builder.popValueInto(PCMappingSlotInfo::SlotInR0); // Need to adjust the frameSize for the frame to match the values popped // into registers. frameSize -= sizeof(Value); blFrame->setFrameSize(frameSize); JitSpew(JitSpew_BaselineBailouts, " Adjusted framesize -= %d: %d", (int) sizeof(Value), (int) frameSize); // If resuming into a JSOP_CALL, baseline keeps the arguments on the // stack and pops them only after returning from the call IC. // Push undefs onto the stack in anticipation of the popping of the // callee, thisv, and actual arguments passed from the caller's frame. if (isCall) { if (!builder.writeValue(UndefinedValue(), "CallOp FillerCallee")) return false; if (!builder.writeValue(UndefinedValue(), "CallOp FillerThis")) return false; for (uint32_t i = 0; i < numCallArgs; i++) { if (!builder.writeValue(UndefinedValue(), "CallOp FillerArg")) return false; } if (pushedNewTarget) { if (!builder.writeValue(UndefinedValue(), "CallOp FillerNewTarget")) return false; } frameSize += (numCallArgs + 2 + pushedNewTarget) * sizeof(Value); blFrame->setFrameSize(frameSize); JitSpew(JitSpew_BaselineBailouts, " Adjusted framesize += %d: %d", (int) ((numCallArgs + 2 + pushedNewTarget) * sizeof(Value)), (int) frameSize); } // Set the resume address to the return point from the IC, and set // the monitor stub addr. builder.setResumeAddr(baselineScript->returnAddressForIC(icEntry)); builder.setMonitorStub(firstMonStub); JitSpew(JitSpew_BaselineBailouts, " Set resumeAddr=%p monitorStub=%p", baselineScript->returnAddressForIC(icEntry), firstMonStub); } else { // If needed, initialize BaselineBailoutInfo's valueR0 and/or valueR1 with the // top stack values. // // Note that we use the 'maybe' variant of nativeCodeForPC because // of exception propagation for debug mode. See note below. PCMappingSlotInfo slotInfo; uint8_t* nativeCodeForPC; if (excInfo && excInfo->propagatingIonExceptionForDebugMode()) { // When propagating an exception for debug mode, set the // resume pc to the throwing pc, so that Debugger hooks report // the correct pc offset of the throwing op instead of its // successor (this pc will be used as the BaselineFrame's // override pc). // // Note that we never resume at this pc, it is set for the sake // of frame iterators giving the correct answer. jsbytecode* throwPC = script->offsetToPC(iter.pcOffset()); builder.setResumePC(throwPC); nativeCodeForPC = baselineScript->nativeCodeForPC(script, throwPC); } else { nativeCodeForPC = baselineScript->nativeCodeForPC(script, pc, &slotInfo); } MOZ_ASSERT(nativeCodeForPC); unsigned numUnsynced = slotInfo.numUnsynced(); MOZ_ASSERT(numUnsynced <= 2); PCMappingSlotInfo::SlotLocation loc1, loc2; if (numUnsynced > 0) { loc1 = slotInfo.topSlotLocation(); JitSpew(JitSpew_BaselineBailouts, " Popping top stack value into %d.", (int) loc1); builder.popValueInto(loc1); } if (numUnsynced > 1) { loc2 = slotInfo.nextSlotLocation(); JitSpew(JitSpew_BaselineBailouts, " Popping next stack value into %d.", (int) loc2); MOZ_ASSERT_IF(loc1 != PCMappingSlotInfo::SlotIgnore, loc1 != loc2); builder.popValueInto(loc2); } // Need to adjust the frameSize for the frame to match the values popped // into registers. frameSize -= sizeof(Value) * numUnsynced; blFrame->setFrameSize(frameSize); JitSpew(JitSpew_BaselineBailouts, " Adjusted framesize -= %d: %d", int(sizeof(Value) * numUnsynced), int(frameSize)); // If envChain is nullptr, then bailout is occurring during argument check. // In this case, resume into the prologue. uint8_t* opReturnAddr; if (envChain == nullptr) { // Global and eval scripts expect the env chain in R1, so only // resume into the prologue for function scripts. MOZ_ASSERT(fun); MOZ_ASSERT(numUnsynced == 0); opReturnAddr = baselineScript->prologueEntryAddr(); JitSpew(JitSpew_BaselineBailouts, " Resuming into prologue."); } else { opReturnAddr = nativeCodeForPC; } builder.setResumeAddr(opReturnAddr); JitSpew(JitSpew_BaselineBailouts, " Set resumeAddr=%p", opReturnAddr); } if (cx->runtime()->spsProfiler.enabled()) { // Register bailout with profiler. const char* filename = script->filename(); if (filename == nullptr) filename = ""; unsigned len = strlen(filename) + 200; char* buf = js_pod_malloc(len); if (buf == nullptr) { ReportOutOfMemory(cx); return false; } snprintf(buf, len, "%s %s %s on line %u of %s:%" PRIuSIZE, BailoutKindString(bailoutKind), resumeAfter ? "after" : "at", CodeName[op], PCToLineNumber(script, pc), filename, script->lineno()); cx->runtime()->spsProfiler.markEvent(buf); js_free(buf); } return true; } *callPC = pc; // Write out descriptor of BaselineJS frame. size_t baselineFrameDescr = MakeFrameDescriptor((uint32_t) builder.framePushed(), JitFrame_BaselineJS, BaselineStubFrameLayout::Size()); if (!builder.writeWord(baselineFrameDescr, "Descriptor")) return false; // Calculate and write out return address. // The icEntry in question MUST have an inlinable fallback stub. BaselineICEntry& icEntry = baselineScript->icEntryFromPCOffset(pcOff); MOZ_ASSERT(IsInlinableFallback(icEntry.firstStub()->getChainFallback())); if (!builder.writePtr(baselineScript->returnAddressForIC(icEntry), "ReturnAddr")) return false; // Build baseline stub frame: // +===============+ // | StubPtr | // +---------------+ // | FramePtr | // +---------------+ // | Padding? | // +---------------+ // | ArgA | // +---------------+ // | ... | // +---------------+ // | Arg0 | // +---------------+ // | ThisV | // +---------------+ // | ActualArgC | // +---------------+ // | CalleeToken | // +---------------+ // | Descr(BLStub) | // +---------------+ // | ReturnAddr | // +===============+ JitSpew(JitSpew_BaselineBailouts, " [BASELINE-STUB FRAME]"); size_t startOfBaselineStubFrame = builder.framePushed(); // Write stub pointer. MOZ_ASSERT(IsInlinableFallback(icEntry.fallbackStub())); if (!builder.writePtr(icEntry.fallbackStub(), "StubPtr")) return false; // Write previous frame pointer (saved earlier). if (!builder.writePtr(prevFramePtr, "PrevFramePtr")) return false; prevFramePtr = builder.virtualPointerAtStackOffset(0); // Write out actual arguments (and thisv), copied from unpacked stack of BaselineJS frame. // Arguments are reversed on the BaselineJS frame's stack values. MOZ_ASSERT(IsIonInlinablePC(pc)); unsigned actualArgc; Value callee; if (needToSaveArgs) { // For FUNAPPLY or an accessor, the arguments are not on the stack anymore, // but they are copied in a vector and are written here. if (op == JSOP_FUNAPPLY) actualArgc = blFrame->numActualArgs(); else actualArgc = IsSetPropPC(pc); callee = savedCallerArgs[0]; // Align the stack based on the number of arguments. size_t afterFrameSize = (actualArgc + 1) * sizeof(Value) + JitFrameLayout::Size(); if (!builder.maybeWritePadding(JitStackAlignment, afterFrameSize, "Padding")) return false; // Push arguments. MOZ_ASSERT(actualArgc + 2 <= exprStackSlots); MOZ_ASSERT(savedCallerArgs.length() == actualArgc + 2); for (unsigned i = 0; i < actualArgc + 1; i++) { size_t arg = savedCallerArgs.length() - (i + 1); if (!builder.writeValue(savedCallerArgs[arg], "ArgVal")) return false; } } else { actualArgc = GET_ARGC(pc); if (op == JSOP_FUNCALL) { MOZ_ASSERT(actualArgc > 0); actualArgc--; } // Align the stack based on the number of arguments. size_t afterFrameSize = (actualArgc + 1 + pushedNewTarget) * sizeof(Value) + JitFrameLayout::Size(); if (!builder.maybeWritePadding(JitStackAlignment, afterFrameSize, "Padding")) return false; // Copy the arguments and |this| from the BaselineFrame, in reverse order. size_t valueSlot = blFrame->numValueSlots() - 1; size_t calleeSlot = valueSlot - actualArgc - 1 - pushedNewTarget; for (size_t i = valueSlot; i > calleeSlot; i--) { Value v = *blFrame->valueSlot(i); if (!builder.writeValue(v, "ArgVal")) return false; } callee = *blFrame->valueSlot(calleeSlot); } // In case these arguments need to be copied on the stack again for a rectifier frame, // save the framePushed values here for later use. size_t endOfBaselineStubArgs = builder.framePushed(); // Calculate frame size for descriptor. size_t baselineStubFrameSize = builder.framePushed() - startOfBaselineStubFrame; size_t baselineStubFrameDescr = MakeFrameDescriptor((uint32_t) baselineStubFrameSize, JitFrame_BaselineStub, JitFrameLayout::Size()); // Push actual argc if (!builder.writeWord(actualArgc, "ActualArgc")) return false; // Push callee token (must be a JS Function) JitSpew(JitSpew_BaselineBailouts, " Callee = %016" PRIx64, callee.asRawBits()); JSFunction* calleeFun = &callee.toObject().as(); if (!builder.writePtr(CalleeToToken(calleeFun, JSOp(*pc) == JSOP_NEW), "CalleeToken")) return false; nextCallee.set(calleeFun); // Push BaselineStub frame descriptor if (!builder.writeWord(baselineStubFrameDescr, "Descriptor")) return false; // Push return address into ICCall_Scripted stub, immediately after the call. void* baselineCallReturnAddr = GetStubReturnAddress(cx, pc); MOZ_ASSERT(baselineCallReturnAddr); if (!builder.writePtr(baselineCallReturnAddr, "ReturnAddr")) return false; MOZ_ASSERT(builder.framePushed() % JitStackAlignment == 0); // If actualArgc >= fun->nargs, then we are done. Otherwise, we need to push on // a reconstructed rectifier frame. if (actualArgc >= calleeFun->nargs()) return true; // Push a reconstructed rectifier frame. // +===============+ // | Padding? | // +---------------+ // | UndefinedU | // +---------------+ // | ... | // +---------------+ // | Undefined0 | // +---------------+ // | ArgA | // +---------------+ // | ... | // +---------------+ // | Arg0 | // +---------------+ // | ThisV | // +---------------+ // | ActualArgC | // +---------------+ // | CalleeToken | // +---------------+ // | Descr(Rect) | // +---------------+ // | ReturnAddr | // +===============+ JitSpew(JitSpew_BaselineBailouts, " [RECTIFIER FRAME]"); size_t startOfRectifierFrame = builder.framePushed(); // On x86-only, the frame pointer is saved again in the rectifier frame. #if defined(JS_CODEGEN_X86) if (!builder.writePtr(prevFramePtr, "PrevFramePtr-X86Only")) return false; // Follow the same logic as in JitRuntime::generateArgumentsRectifier. prevFramePtr = builder.virtualPointerAtStackOffset(0); if (!builder.writePtr(prevFramePtr, "Padding-X86Only")) return false; #endif // Align the stack based on the number of arguments. size_t afterFrameSize = (calleeFun->nargs() + 1 + pushedNewTarget) * sizeof(Value) + RectifierFrameLayout::Size(); if (!builder.maybeWritePadding(JitStackAlignment, afterFrameSize, "Padding")) return false; // Copy new.target, if necessary. if (pushedNewTarget) { size_t newTargetOffset = (builder.framePushed() - endOfBaselineStubArgs) + (actualArgc + 1) * sizeof(Value); Value newTargetValue = *builder.valuePointerAtStackOffset(newTargetOffset); if (!builder.writeValue(newTargetValue, "CopiedNewTarget")) return false; } // Push undefined for missing arguments. for (unsigned i = 0; i < (calleeFun->nargs() - actualArgc); i++) { if (!builder.writeValue(UndefinedValue(), "FillerVal")) return false; } // Copy arguments + thisv from BaselineStub frame. if (!builder.subtract((actualArgc + 1) * sizeof(Value), "CopiedArgs")) return false; BufferPointer stubArgsEnd = builder.pointerAtStackOffset(builder.framePushed() - endOfBaselineStubArgs); JitSpew(JitSpew_BaselineBailouts, " MemCpy from %p", stubArgsEnd.get()); memcpy(builder.pointerAtStackOffset(0).get(), stubArgsEnd.get(), (actualArgc + 1) * sizeof(Value)); // Calculate frame size for descriptor. size_t rectifierFrameSize = builder.framePushed() - startOfRectifierFrame; size_t rectifierFrameDescr = MakeFrameDescriptor((uint32_t) rectifierFrameSize, JitFrame_Rectifier, JitFrameLayout::Size()); // Push actualArgc if (!builder.writeWord(actualArgc, "ActualArgc")) return false; // Push calleeToken again. if (!builder.writePtr(CalleeToToken(calleeFun, JSOp(*pc) == JSOP_NEW), "CalleeToken")) return false; // Push rectifier frame descriptor if (!builder.writeWord(rectifierFrameDescr, "Descriptor")) return false; // Push return address into the ArgumentsRectifier code, immediately after the ioncode // call. void* rectReturnAddr = cx->runtime()->jitRuntime()->getArgumentsRectifierReturnAddr(); MOZ_ASSERT(rectReturnAddr); if (!builder.writePtr(rectReturnAddr, "ReturnAddr")) return false; MOZ_ASSERT(builder.framePushed() % JitStackAlignment == 0); return true; } uint32_t jit::BailoutIonToBaseline(JSContext* cx, JitActivation* activation, JitFrameIterator& iter, bool invalidate, BaselineBailoutInfo** bailoutInfo, const ExceptionBailoutInfo* excInfo) { MOZ_ASSERT(bailoutInfo != nullptr); MOZ_ASSERT(*bailoutInfo == nullptr); TraceLoggerThread* logger = TraceLoggerForMainThread(cx->runtime()); TraceLogStopEvent(logger, TraceLogger_IonMonkey); TraceLogStartEvent(logger, TraceLogger_Baseline); // Ion bailout can fail due to overrecursion and OOM. In such cases we // cannot honor any further Debugger hooks on the frame, and need to // ensure that its Debugger.Frame entry is cleaned up. auto guardRemoveRematerializedFramesFromDebugger = mozilla::MakeScopeExit([&] { activation->removeRematerializedFramesFromDebugger(cx, iter.fp()); }); // The caller of the top frame must be one of the following: // IonJS - Ion calling into Ion. // BaselineStub - Baseline calling into Ion. // Entry - Interpreter or other calling into Ion. // Rectifier - Arguments rectifier calling into Ion. MOZ_ASSERT(iter.isBailoutJS()); #if defined(DEBUG) || defined(JS_JITSPEW) FrameType prevFrameType = iter.prevType(); MOZ_ASSERT(prevFrameType == JitFrame_IonJS || prevFrameType == JitFrame_BaselineStub || prevFrameType == JitFrame_Entry || prevFrameType == JitFrame_Rectifier || prevFrameType == JitFrame_IonAccessorIC); #endif // All incoming frames are going to look like this: // // +---------------+ // | ... | // +---------------+ // | Args | // | ... | // +---------------+ // | ThisV | // +---------------+ // | ActualArgC | // +---------------+ // | CalleeToken | // +---------------+ // | Descriptor | // +---------------+ // | ReturnAddr | // +---------------+ // | ||||| | <---- Overwrite starting here. // | ||||| | // | ||||| | // +---------------+ JitSpew(JitSpew_BaselineBailouts, "Bailing to baseline %s:%" PRIuSIZE " (IonScript=%p) (FrameType=%d)", iter.script()->filename(), iter.script()->lineno(), (void*) iter.ionScript(), (int) prevFrameType); bool catchingException; bool propagatingExceptionForDebugMode; if (excInfo) { catchingException = excInfo->catchingException(); propagatingExceptionForDebugMode = excInfo->propagatingIonExceptionForDebugMode(); if (catchingException) JitSpew(JitSpew_BaselineBailouts, "Resuming in catch or finally block"); if (propagatingExceptionForDebugMode) JitSpew(JitSpew_BaselineBailouts, "Resuming in-place for debug mode"); } else { catchingException = false; propagatingExceptionForDebugMode = false; } JitSpew(JitSpew_BaselineBailouts, " Reading from snapshot offset %u size %" PRIuSIZE, iter.snapshotOffset(), iter.ionScript()->snapshotsListSize()); if (!excInfo) iter.ionScript()->incNumBailouts(); iter.script()->updateBaselineOrIonRaw(cx->runtime()); // Allocate buffer to hold stack replacement data. BaselineStackBuilder builder(iter, 1024); if (!builder.init()) { ReportOutOfMemory(cx); return BAILOUT_RETURN_FATAL_ERROR; } JitSpew(JitSpew_BaselineBailouts, " Incoming frame ptr = %p", builder.startFrame()); SnapshotIteratorForBailout snapIter(activation, iter); if (!snapIter.init(cx)) return BAILOUT_RETURN_FATAL_ERROR; #ifdef TRACK_SNAPSHOTS snapIter.spewBailingFrom(); #endif RootedFunction callee(cx, iter.maybeCallee()); RootedScript scr(cx, iter.script()); if (callee) { JitSpew(JitSpew_BaselineBailouts, " Callee function (%s:%" PRIuSIZE ")", scr->filename(), scr->lineno()); } else { JitSpew(JitSpew_BaselineBailouts, " No callee!"); } if (iter.isConstructing()) JitSpew(JitSpew_BaselineBailouts, " Constructing!"); else JitSpew(JitSpew_BaselineBailouts, " Not constructing!"); JitSpew(JitSpew_BaselineBailouts, " Restoring frames:"); size_t frameNo = 0; // Reconstruct baseline frames using the builder. RootedScript caller(cx); jsbytecode* callerPC = nullptr; RootedFunction fun(cx, callee); Rooted> startFrameFormals(cx, GCVector(cx)); gc::AutoSuppressGC suppress(cx); while (true) { // Skip recover instructions as they are already recovered by |initInstructionResults|. snapIter.settleOnFrame(); if (frameNo > 0) { // TraceLogger doesn't create entries for inlined frames. But we // see them in Baseline. Here we create the start events of those // entries. So they correspond to what we will see in Baseline. TraceLoggerEvent scriptEvent(logger, TraceLogger_Scripts, scr); TraceLogStartEvent(logger, scriptEvent); TraceLogStartEvent(logger, TraceLogger_Baseline); } JitSpew(JitSpew_BaselineBailouts, " FrameNo %" PRIuSIZE, frameNo); // If we are bailing out to a catch or finally block in this frame, // pass excInfo to InitFromBailout and don't unpack any other frames. bool handleException = (catchingException && excInfo->frameNo() == frameNo); // We also need to pass excInfo if we're bailing out in place for // debug mode. bool passExcInfo = handleException || propagatingExceptionForDebugMode; jsbytecode* callPC = nullptr; RootedFunction nextCallee(cx, nullptr); if (!InitFromBailout(cx, caller, callerPC, fun, scr, iter.ionScript(), snapIter, invalidate, builder, &startFrameFormals, &nextCallee, &callPC, passExcInfo ? excInfo : nullptr)) { return BAILOUT_RETURN_FATAL_ERROR; } if (!snapIter.moreFrames()) { MOZ_ASSERT(!callPC); break; } if (handleException) break; MOZ_ASSERT(nextCallee); MOZ_ASSERT(callPC); caller = scr; callerPC = callPC; fun = nextCallee; scr = fun->existingScript(); frameNo++; snapIter.nextInstruction(); } JitSpew(JitSpew_BaselineBailouts, " Done restoring frames"); BailoutKind bailoutKind = snapIter.bailoutKind(); if (!startFrameFormals.empty()) { // Set the first frame's formals, see the comment in InitFromBailout. Value* argv = builder.startFrame()->argv() + 1; // +1 to skip |this|. mozilla::PodCopy(argv, startFrameFormals.begin(), startFrameFormals.length()); } // Do stack check. bool overRecursed = false; BaselineBailoutInfo *info = builder.info(); uint8_t* newsp = info->incomingStack - (info->copyStackTop - info->copyStackBottom); #ifdef JS_SIMULATOR if (Simulator::Current()->overRecursed(uintptr_t(newsp))) overRecursed = true; #else JS_CHECK_RECURSION_WITH_SP_DONT_REPORT(cx, newsp, overRecursed = true); #endif if (overRecursed) { JitSpew(JitSpew_BaselineBailouts, " Overrecursion check failed!"); return BAILOUT_RETURN_OVERRECURSED; } // Take the reconstructed baseline stack so it doesn't get freed when builder destructs. info = builder.takeBuffer(); info->numFrames = frameNo + 1; info->bailoutKind = bailoutKind; *bailoutInfo = info; guardRemoveRematerializedFramesFromDebugger.release(); return BAILOUT_RETURN_OK; } static void InvalidateAfterBailout(JSContext* cx, HandleScript outerScript, const char* reason) { // In some cases, the computation of recover instruction can invalidate the // Ion script before we reach the end of the bailout. Thus, if the outer // script no longer have any Ion script attached, then we just skip the // invalidation. // // For example, such case can happen if the template object for an unboxed // objects no longer match the content of its properties (see Bug 1174547) if (!outerScript->hasIonScript()) { JitSpew(JitSpew_BaselineBailouts, "Ion script is already invalidated"); return; } MOZ_ASSERT(!outerScript->ionScript()->invalidated()); JitSpew(JitSpew_BaselineBailouts, "Invalidating due to %s", reason); Invalidate(cx, outerScript); } static void HandleBoundsCheckFailure(JSContext* cx, HandleScript outerScript, HandleScript innerScript) { JitSpew(JitSpew_IonBailouts, "Bounds check failure %s:%" PRIuSIZE ", inlined into %s:%" PRIuSIZE, innerScript->filename(), innerScript->lineno(), outerScript->filename(), outerScript->lineno()); if (!innerScript->failedBoundsCheck()) innerScript->setFailedBoundsCheck(); InvalidateAfterBailout(cx, outerScript, "bounds check failure"); if (innerScript->hasIonScript()) Invalidate(cx, innerScript); } static void HandleShapeGuardFailure(JSContext* cx, HandleScript outerScript, HandleScript innerScript) { JitSpew(JitSpew_IonBailouts, "Shape guard failure %s:%" PRIuSIZE ", inlined into %s:%" PRIuSIZE, innerScript->filename(), innerScript->lineno(), outerScript->filename(), outerScript->lineno()); // TODO: Currently this mimic's Ion's handling of this case. Investigate setting // the flag on innerScript as opposed to outerScript, and maybe invalidating both // inner and outer scripts, instead of just the outer one. outerScript->setFailedShapeGuard(); InvalidateAfterBailout(cx, outerScript, "shape guard failure"); } static void HandleBaselineInfoBailout(JSContext* cx, HandleScript outerScript, HandleScript innerScript) { JitSpew(JitSpew_IonBailouts, "Baseline info failure %s:%" PRIuSIZE ", inlined into %s:%" PRIuSIZE, innerScript->filename(), innerScript->lineno(), outerScript->filename(), outerScript->lineno()); InvalidateAfterBailout(cx, outerScript, "invalid baseline info"); } static void HandleLexicalCheckFailure(JSContext* cx, HandleScript outerScript, HandleScript innerScript) { JitSpew(JitSpew_IonBailouts, "Lexical check failure %s:%" PRIuSIZE ", inlined into %s:%" PRIuSIZE, innerScript->filename(), innerScript->lineno(), outerScript->filename(), outerScript->lineno()); if (!innerScript->failedLexicalCheck()) innerScript->setFailedLexicalCheck(); InvalidateAfterBailout(cx, outerScript, "lexical check failure"); if (innerScript->hasIonScript()) Invalidate(cx, innerScript); } static bool CopyFromRematerializedFrame(JSContext* cx, JitActivation* act, uint8_t* fp, size_t inlineDepth, BaselineFrame* frame) { RematerializedFrame* rematFrame = act->lookupRematerializedFrame(fp, inlineDepth); // We might not have rematerialized a frame if the user never requested a // Debugger.Frame for it. if (!rematFrame) return true; MOZ_ASSERT(rematFrame->script() == frame->script()); MOZ_ASSERT(rematFrame->numActualArgs() == frame->numActualArgs()); frame->setEnvironmentChain(rematFrame->environmentChain()); if (frame->isFunctionFrame()) frame->thisArgument() = rematFrame->thisArgument(); for (unsigned i = 0; i < frame->numActualArgs(); i++) frame->argv()[i] = rematFrame->argv()[i]; for (size_t i = 0; i < frame->script()->nfixed(); i++) *frame->valueSlot(i) = rematFrame->locals()[i]; frame->setReturnValue(rematFrame->returnValue()); if (rematFrame->hasCachedSavedFrame()) frame->setHasCachedSavedFrame(); JitSpew(JitSpew_BaselineBailouts, " Copied from rematerialized frame at (%p,%" PRIuSIZE ")", fp, inlineDepth); // Propagate the debuggee frame flag. For the case where the Debugger did // not rematerialize an Ion frame, the baseline frame has its debuggee // flag set iff its script is considered a debuggee. See the debuggee case // in InitFromBailout. if (rematFrame->isDebuggee()) { frame->setIsDebuggee(); return Debugger::handleIonBailout(cx, rematFrame, frame); } return true; } uint32_t jit::FinishBailoutToBaseline(BaselineBailoutInfo* bailoutInfo) { // The caller pushes R0 and R1 on the stack without rooting them. // Since GC here is very unlikely just suppress it. JSContext* cx = GetJSContextFromMainThread(); js::gc::AutoSuppressGC suppressGC(cx); JitSpew(JitSpew_BaselineBailouts, " Done restoring frames"); // The current native code pc may not have a corresponding ICEntry, so we // store the bytecode pc in the frame for frame iterators. This pc is // cleared at the end of this function. If we return false, we don't clear // it: the exception handler also needs it and will clear it for us. BaselineFrame* topFrame = GetTopBaselineFrame(cx); topFrame->setOverridePc(bailoutInfo->resumePC); uint32_t numFrames = bailoutInfo->numFrames; MOZ_ASSERT(numFrames > 0); BailoutKind bailoutKind = bailoutInfo->bailoutKind; bool checkGlobalDeclarationConflicts = bailoutInfo->checkGlobalDeclarationConflicts; // Free the bailout buffer. js_free(bailoutInfo); bailoutInfo = nullptr; if (topFrame->environmentChain()) { // Ensure the frame has a call object if it needs one. If the env chain // is nullptr, we will enter baseline code at the prologue so no need to do // anything in that case. if (!EnsureHasEnvironmentObjects(cx, topFrame)) return false; // If we bailed out before Ion could do the global declaration // conflicts check, because we resume in the body instead of the // prologue for global frames. if (checkGlobalDeclarationConflicts) { Rooted lexicalEnv(cx, &cx->global()->lexicalEnvironment()); RootedScript script(cx, topFrame->script()); if (!CheckGlobalDeclarationConflicts(cx, script, lexicalEnv, cx->global())) return false; } } // Create arguments objects for bailed out frames, to maintain the invariant // that script->needsArgsObj() implies frame->hasArgsObj(). RootedScript innerScript(cx, nullptr); RootedScript outerScript(cx, nullptr); MOZ_ASSERT(cx->currentlyRunningInJit()); JitFrameIterator iter(cx); uint8_t* outerFp = nullptr; // Iter currently points at the exit frame. Get the previous frame // (which must be a baseline frame), and set it as the last profiling // frame. if (cx->runtime()->jitRuntime()->isProfilerInstrumentationEnabled(cx->runtime())) cx->runtime()->jitActivation->setLastProfilingFrame(iter.prevFp()); uint32_t frameno = 0; while (frameno < numFrames) { MOZ_ASSERT(!iter.isIonJS()); if (iter.isBaselineJS()) { BaselineFrame* frame = iter.baselineFrame(); MOZ_ASSERT(frame->script()->hasBaselineScript()); // If the frame doesn't even have a env chain set yet, then it's resuming // into the the prologue before the env chain is initialized. Any // necessary args object will also be initialized there. if (frame->environmentChain() && frame->script()->needsArgsObj()) { ArgumentsObject* argsObj; if (frame->hasArgsObj()) { argsObj = &frame->argsObj(); } else { argsObj = ArgumentsObject::createExpected(cx, frame); if (!argsObj) return false; } // The arguments is a local binding and needsArgsObj does not // check if it is clobbered. Ensure that the local binding // restored during bailout before storing the arguments object // to the slot. RootedScript script(cx, frame->script()); SetFrameArgumentsObject(cx, frame, script, argsObj); } if (frameno == 0) innerScript = frame->script(); if (frameno == numFrames - 1) { outerScript = frame->script(); outerFp = iter.fp(); } frameno++; } ++iter; } MOZ_ASSERT(innerScript); MOZ_ASSERT(outerScript); MOZ_ASSERT(outerFp); // If we rematerialized Ion frames due to debug mode toggling, copy their // values into the baseline frame. We need to do this even when debug mode // is off, as we should respect the mutations made while debug mode was // on. JitActivation* act = cx->runtime()->activation()->asJit(); if (act->hasRematerializedFrame(outerFp)) { JitFrameIterator iter(cx); size_t inlineDepth = numFrames; bool ok = true; while (inlineDepth > 0) { if (iter.isBaselineJS()) { // We must attempt to copy all rematerialized frames over, // even if earlier ones failed, to invoke the proper frame // cleanup in the Debugger. ok = CopyFromRematerializedFrame(cx, act, outerFp, --inlineDepth, iter.baselineFrame()); } ++iter; } // After copying from all the rematerialized frames, remove them from // the table to keep the table up to date. act->removeRematerializedFrame(outerFp); if (!ok) return false; } JitSpew(JitSpew_BaselineBailouts, " Restored outerScript=(%s:%" PRIuSIZE ",%u) innerScript=(%s:%" PRIuSIZE ",%u) (bailoutKind=%u)", outerScript->filename(), outerScript->lineno(), outerScript->getWarmUpCount(), innerScript->filename(), innerScript->lineno(), innerScript->getWarmUpCount(), (unsigned) bailoutKind); switch (bailoutKind) { // Normal bailouts. case Bailout_Inevitable: case Bailout_DuringVMCall: case Bailout_NonJSFunctionCallee: case Bailout_DynamicNameNotFound: case Bailout_StringArgumentsEval: case Bailout_Overflow: case Bailout_Round: case Bailout_NonPrimitiveInput: case Bailout_PrecisionLoss: case Bailout_TypeBarrierO: case Bailout_TypeBarrierV: case Bailout_MonitorTypes: case Bailout_Hole: case Bailout_NegativeIndex: case Bailout_NonInt32Input: case Bailout_NonNumericInput: case Bailout_NonBooleanInput: case Bailout_NonObjectInput: case Bailout_NonStringInput: case Bailout_NonSymbolInput: case Bailout_UnexpectedSimdInput: case Bailout_NonSharedTypedArrayInput: case Bailout_Debugger: case Bailout_UninitializedThis: case Bailout_BadDerivedConstructorReturn: // Do nothing. break; case Bailout_FirstExecution: // Do not return directly, as this was not frequent in the first place, // thus rely on the check for frequent bailouts to recompile the current // script. break; // Invalid assumption based on baseline code. case Bailout_OverflowInvalidate: outerScript->setHadOverflowBailout(); MOZ_FALLTHROUGH; case Bailout_NonStringInputInvalidate: case Bailout_DoubleOutput: case Bailout_ObjectIdentityOrTypeGuard: HandleBaselineInfoBailout(cx, outerScript, innerScript); break; case Bailout_ArgumentCheck: // Do nothing, bailout will resume before the argument monitor ICs. break; case Bailout_BoundsCheck: case Bailout_Detached: HandleBoundsCheckFailure(cx, outerScript, innerScript); break; case Bailout_ShapeGuard: HandleShapeGuardFailure(cx, outerScript, innerScript); break; case Bailout_UninitializedLexical: HandleLexicalCheckFailure(cx, outerScript, innerScript); break; case Bailout_IonExceptionDebugMode: // Return false to resume in HandleException with reconstructed // baseline frame. return false; default: MOZ_CRASH("Unknown bailout kind!"); } CheckFrequentBailouts(cx, outerScript, bailoutKind); // We're returning to JIT code, so we should clear the override pc. topFrame->clearOverridePc(); return true; }