// Copyright 2013 the V8 project authors. All rights reserved. // Use of this source code is governed by a BSD-style license that can be // found in the LICENSE file. #include "src/deoptimizer.h" #include "src/accessors.h" #include "src/ast/prettyprinter.h" #include "src/codegen.h" #include "src/disasm.h" #include "src/frames-inl.h" #include "src/full-codegen/full-codegen.h" #include "src/global-handles.h" #include "src/macro-assembler.h" #include "src/profiler/cpu-profiler.h" #include "src/v8.h" namespace v8 { namespace internal { static MemoryChunk* AllocateCodeChunk(MemoryAllocator* allocator) { return allocator->AllocateChunk(Deoptimizer::GetMaxDeoptTableSize(), base::OS::CommitPageSize(), #if defined(__native_client__) // The Native Client port of V8 uses an interpreter, // so code pages don't need PROT_EXEC. NOT_EXECUTABLE, #else EXECUTABLE, #endif NULL); } DeoptimizerData::DeoptimizerData(MemoryAllocator* allocator) : allocator_(allocator), deoptimized_frame_info_(NULL), current_(NULL) { for (int i = 0; i < Deoptimizer::kBailoutTypesWithCodeEntry; ++i) { deopt_entry_code_entries_[i] = -1; deopt_entry_code_[i] = AllocateCodeChunk(allocator); } } DeoptimizerData::~DeoptimizerData() { for (int i = 0; i < Deoptimizer::kBailoutTypesWithCodeEntry; ++i) { allocator_->Free(deopt_entry_code_[i]); deopt_entry_code_[i] = NULL; } } void DeoptimizerData::Iterate(ObjectVisitor* v) { if (deoptimized_frame_info_ != NULL) { deoptimized_frame_info_->Iterate(v); } } Code* Deoptimizer::FindDeoptimizingCode(Address addr) { if (function_->IsHeapObject()) { // Search all deoptimizing code in the native context of the function. Context* native_context = function_->context()->native_context(); Object* element = native_context->DeoptimizedCodeListHead(); while (!element->IsUndefined()) { Code* code = Code::cast(element); CHECK(code->kind() == Code::OPTIMIZED_FUNCTION); if (code->contains(addr)) return code; element = code->next_code_link(); } } return NULL; } // We rely on this function not causing a GC. It is called from generated code // without having a real stack frame in place. Deoptimizer* Deoptimizer::New(JSFunction* function, BailoutType type, unsigned bailout_id, Address from, int fp_to_sp_delta, Isolate* isolate) { Deoptimizer* deoptimizer = new Deoptimizer(isolate, function, type, bailout_id, from, fp_to_sp_delta, NULL); CHECK(isolate->deoptimizer_data()->current_ == NULL); isolate->deoptimizer_data()->current_ = deoptimizer; return deoptimizer; } // No larger than 2K on all platforms static const int kDeoptTableMaxEpilogueCodeSize = 2 * KB; size_t Deoptimizer::GetMaxDeoptTableSize() { int entries_size = Deoptimizer::kMaxNumberOfEntries * Deoptimizer::table_entry_size_; int commit_page_size = static_cast<int>(base::OS::CommitPageSize()); int page_count = ((kDeoptTableMaxEpilogueCodeSize + entries_size - 1) / commit_page_size) + 1; return static_cast<size_t>(commit_page_size * page_count); } Deoptimizer* Deoptimizer::Grab(Isolate* isolate) { Deoptimizer* result = isolate->deoptimizer_data()->current_; CHECK_NOT_NULL(result); result->DeleteFrameDescriptions(); isolate->deoptimizer_data()->current_ = NULL; return result; } int Deoptimizer::ConvertJSFrameIndexToFrameIndex(int jsframe_index) { if (jsframe_index == 0) return 0; int frame_index = 0; while (jsframe_index >= 0) { FrameDescription* frame = output_[frame_index]; if (frame->GetFrameType() == StackFrame::JAVA_SCRIPT) { jsframe_index--; } frame_index++; } return frame_index - 1; } DeoptimizedFrameInfo* Deoptimizer::DebuggerInspectableFrame( JavaScriptFrame* frame, int jsframe_index, Isolate* isolate) { CHECK(frame->is_optimized()); CHECK(isolate->deoptimizer_data()->deoptimized_frame_info_ == NULL); // Get the function and code from the frame. JSFunction* function = frame->function(); Code* code = frame->LookupCode(); // Locate the deoptimization point in the code. As we are at a call the // return address must be at a place in the code with deoptimization support. SafepointEntry safepoint_entry = code->GetSafepointEntry(frame->pc()); int deoptimization_index = safepoint_entry.deoptimization_index(); CHECK_NE(deoptimization_index, Safepoint::kNoDeoptimizationIndex); // Always use the actual stack slots when calculating the fp to sp // delta adding two for the function and context. unsigned stack_slots = code->stack_slots(); unsigned arguments_stack_height = Deoptimizer::ComputeOutgoingArgumentSize(code, deoptimization_index); unsigned fp_to_sp_delta = (stack_slots * kPointerSize) + StandardFrameConstants::kFixedFrameSizeFromFp + arguments_stack_height; Deoptimizer* deoptimizer = new Deoptimizer(isolate, function, Deoptimizer::DEBUGGER, deoptimization_index, frame->pc(), fp_to_sp_delta, code); Address tos = frame->fp() - fp_to_sp_delta; deoptimizer->FillInputFrame(tos, frame); // Calculate the output frames. Deoptimizer::ComputeOutputFrames(deoptimizer); // Create the GC safe output frame information and register it for GC // handling. CHECK_LT(jsframe_index, deoptimizer->jsframe_count()); // Convert JS frame index into frame index. int frame_index = deoptimizer->ConvertJSFrameIndexToFrameIndex(jsframe_index); bool has_arguments_adaptor = frame_index > 0 && deoptimizer->output_[frame_index - 1]->GetFrameType() == StackFrame::ARGUMENTS_ADAPTOR; int construct_offset = has_arguments_adaptor ? 2 : 1; bool has_construct_stub = frame_index >= construct_offset && deoptimizer->output_[frame_index - construct_offset]->GetFrameType() == StackFrame::CONSTRUCT; DeoptimizedFrameInfo* info = new DeoptimizedFrameInfo(deoptimizer, frame_index, has_arguments_adaptor, has_construct_stub); isolate->deoptimizer_data()->deoptimized_frame_info_ = info; // Done with the GC-unsafe frame descriptions. This re-enables allocation. deoptimizer->DeleteFrameDescriptions(); // Allocate a heap number for the doubles belonging to this frame. deoptimizer->MaterializeHeapNumbersForDebuggerInspectableFrame( frame_index, info->parameters_count(), info->expression_count(), info); // Finished using the deoptimizer instance. delete deoptimizer; return info; } void Deoptimizer::DeleteDebuggerInspectableFrame(DeoptimizedFrameInfo* info, Isolate* isolate) { CHECK_EQ(isolate->deoptimizer_data()->deoptimized_frame_info_, info); delete info; isolate->deoptimizer_data()->deoptimized_frame_info_ = NULL; } void Deoptimizer::GenerateDeoptimizationEntries(MacroAssembler* masm, int count, BailoutType type) { TableEntryGenerator generator(masm, type, count); generator.Generate(); } void Deoptimizer::VisitAllOptimizedFunctionsForContext( Context* context, OptimizedFunctionVisitor* visitor) { DisallowHeapAllocation no_allocation; CHECK(context->IsNativeContext()); visitor->EnterContext(context); // Visit the list of optimized functions, removing elements that // no longer refer to optimized code. JSFunction* prev = NULL; Object* element = context->OptimizedFunctionsListHead(); while (!element->IsUndefined()) { JSFunction* function = JSFunction::cast(element); Object* next = function->next_function_link(); if (function->code()->kind() != Code::OPTIMIZED_FUNCTION || (visitor->VisitFunction(function), function->code()->kind() != Code::OPTIMIZED_FUNCTION)) { // The function no longer refers to optimized code, or the visitor // changed the code to which it refers to no longer be optimized code. // Remove the function from this list. if (prev != NULL) { prev->set_next_function_link(next, UPDATE_WEAK_WRITE_BARRIER); } else { context->SetOptimizedFunctionsListHead(next); } // The visitor should not alter the link directly. CHECK_EQ(function->next_function_link(), next); // Set the next function link to undefined to indicate it is no longer // in the optimized functions list. function->set_next_function_link(context->GetHeap()->undefined_value(), SKIP_WRITE_BARRIER); } else { // The visitor should not alter the link directly. CHECK_EQ(function->next_function_link(), next); // preserve this element. prev = function; } element = next; } visitor->LeaveContext(context); } void Deoptimizer::VisitAllOptimizedFunctions( Isolate* isolate, OptimizedFunctionVisitor* visitor) { DisallowHeapAllocation no_allocation; // Run through the list of all native contexts. Object* context = isolate->heap()->native_contexts_list(); while (!context->IsUndefined()) { VisitAllOptimizedFunctionsForContext(Context::cast(context), visitor); context = Context::cast(context)->get(Context::NEXT_CONTEXT_LINK); } } // Unlink functions referring to code marked for deoptimization, then move // marked code from the optimized code list to the deoptimized code list, // and patch code for lazy deopt. void Deoptimizer::DeoptimizeMarkedCodeForContext(Context* context) { DisallowHeapAllocation no_allocation; // A "closure" that unlinks optimized code that is going to be // deoptimized from the functions that refer to it. class SelectedCodeUnlinker: public OptimizedFunctionVisitor { public: virtual void EnterContext(Context* context) { } // Don't care. virtual void LeaveContext(Context* context) { } // Don't care. virtual void VisitFunction(JSFunction* function) { Code* code = function->code(); if (!code->marked_for_deoptimization()) return; // Unlink this function and evict from optimized code map. SharedFunctionInfo* shared = function->shared(); function->set_code(shared->code()); if (FLAG_trace_deopt) { CodeTracer::Scope scope(code->GetHeap()->isolate()->GetCodeTracer()); PrintF(scope.file(), "[deoptimizer unlinked: "); function->PrintName(scope.file()); PrintF(scope.file(), " / %" V8PRIxPTR "]\n", reinterpret_cast<intptr_t>(function)); } } }; // Unlink all functions that refer to marked code. SelectedCodeUnlinker unlinker; VisitAllOptimizedFunctionsForContext(context, &unlinker); Isolate* isolate = context->GetHeap()->isolate(); #ifdef DEBUG Code* topmost_optimized_code = NULL; bool safe_to_deopt_topmost_optimized_code = false; // Make sure all activations of optimized code can deopt at their current PC. // The topmost optimized code has special handling because it cannot be // deoptimized due to weak object dependency. for (StackFrameIterator it(isolate, isolate->thread_local_top()); !it.done(); it.Advance()) { StackFrame::Type type = it.frame()->type(); if (type == StackFrame::OPTIMIZED) { Code* code = it.frame()->LookupCode(); JSFunction* function = static_cast<OptimizedFrame*>(it.frame())->function(); if (FLAG_trace_deopt) { CodeTracer::Scope scope(isolate->GetCodeTracer()); PrintF(scope.file(), "[deoptimizer found activation of function: "); function->PrintName(scope.file()); PrintF(scope.file(), " / %" V8PRIxPTR "]\n", reinterpret_cast<intptr_t>(function)); } SafepointEntry safepoint = code->GetSafepointEntry(it.frame()->pc()); int deopt_index = safepoint.deoptimization_index(); // Turbofan deopt is checked when we are patching addresses on stack. bool turbofanned = code->is_turbofanned() && function->shared()->asm_function() && !FLAG_turbo_asm_deoptimization; bool safe_to_deopt = deopt_index != Safepoint::kNoDeoptimizationIndex || turbofanned; CHECK(topmost_optimized_code == NULL || safe_to_deopt || turbofanned); if (topmost_optimized_code == NULL) { topmost_optimized_code = code; safe_to_deopt_topmost_optimized_code = safe_to_deopt; } } } #endif // Move marked code from the optimized code list to the deoptimized // code list, collecting them into a ZoneList. Zone zone; ZoneList<Code*> codes(10, &zone); // Walk over all optimized code objects in this native context. Code* prev = NULL; Object* element = context->OptimizedCodeListHead(); while (!element->IsUndefined()) { Code* code = Code::cast(element); CHECK_EQ(code->kind(), Code::OPTIMIZED_FUNCTION); Object* next = code->next_code_link(); if (code->marked_for_deoptimization()) { // Put the code into the list for later patching. codes.Add(code, &zone); if (prev != NULL) { // Skip this code in the optimized code list. prev->set_next_code_link(next); } else { // There was no previous node, the next node is the new head. context->SetOptimizedCodeListHead(next); } // Move the code to the _deoptimized_ code list. code->set_next_code_link(context->DeoptimizedCodeListHead()); context->SetDeoptimizedCodeListHead(code); } else { // Not marked; preserve this element. prev = code; } element = next; } // TODO(titzer): we need a handle scope only because of the macro assembler, // which is only used in EnsureCodeForDeoptimizationEntry. HandleScope scope(isolate); // Now patch all the codes for deoptimization. for (int i = 0; i < codes.length(); i++) { #ifdef DEBUG if (codes[i] == topmost_optimized_code) { DCHECK(safe_to_deopt_topmost_optimized_code); } #endif // It is finally time to die, code object. // Remove the code from optimized code map. DeoptimizationInputData* deopt_data = DeoptimizationInputData::cast(codes[i]->deoptimization_data()); SharedFunctionInfo* shared = SharedFunctionInfo::cast(deopt_data->SharedFunctionInfo()); shared->EvictFromOptimizedCodeMap(codes[i], "deoptimized code"); // Do platform-specific patching to force any activations to lazy deopt. PatchCodeForDeoptimization(isolate, codes[i]); // We might be in the middle of incremental marking with compaction. // Tell collector to treat this code object in a special way and // ignore all slots that might have been recorded on it. isolate->heap()->mark_compact_collector()->InvalidateCode(codes[i]); } } void Deoptimizer::DeoptimizeAll(Isolate* isolate) { if (FLAG_trace_deopt) { CodeTracer::Scope scope(isolate->GetCodeTracer()); PrintF(scope.file(), "[deoptimize all code in all contexts]\n"); } DisallowHeapAllocation no_allocation; // For all contexts, mark all code, then deoptimize. Object* context = isolate->heap()->native_contexts_list(); while (!context->IsUndefined()) { Context* native_context = Context::cast(context); MarkAllCodeForContext(native_context); DeoptimizeMarkedCodeForContext(native_context); context = native_context->get(Context::NEXT_CONTEXT_LINK); } } void Deoptimizer::DeoptimizeMarkedCode(Isolate* isolate) { if (FLAG_trace_deopt) { CodeTracer::Scope scope(isolate->GetCodeTracer()); PrintF(scope.file(), "[deoptimize marked code in all contexts]\n"); } DisallowHeapAllocation no_allocation; // For all contexts, deoptimize code already marked. Object* context = isolate->heap()->native_contexts_list(); while (!context->IsUndefined()) { Context* native_context = Context::cast(context); DeoptimizeMarkedCodeForContext(native_context); context = native_context->get(Context::NEXT_CONTEXT_LINK); } } void Deoptimizer::MarkAllCodeForContext(Context* context) { Object* element = context->OptimizedCodeListHead(); while (!element->IsUndefined()) { Code* code = Code::cast(element); CHECK_EQ(code->kind(), Code::OPTIMIZED_FUNCTION); code->set_marked_for_deoptimization(true); element = code->next_code_link(); } } void Deoptimizer::DeoptimizeFunction(JSFunction* function) { Code* code = function->code(); if (code->kind() == Code::OPTIMIZED_FUNCTION) { // Mark the code for deoptimization and unlink any functions that also // refer to that code. The code cannot be shared across native contexts, // so we only need to search one. code->set_marked_for_deoptimization(true); DeoptimizeMarkedCodeForContext(function->context()->native_context()); } } void Deoptimizer::ComputeOutputFrames(Deoptimizer* deoptimizer) { deoptimizer->DoComputeOutputFrames(); } bool Deoptimizer::TraceEnabledFor(BailoutType deopt_type, StackFrame::Type frame_type) { switch (deopt_type) { case EAGER: case SOFT: case LAZY: case DEBUGGER: return (frame_type == StackFrame::STUB) ? FLAG_trace_stub_failures : FLAG_trace_deopt; } FATAL("Unsupported deopt type"); return false; } const char* Deoptimizer::MessageFor(BailoutType type) { switch (type) { case EAGER: return "eager"; case SOFT: return "soft"; case LAZY: return "lazy"; case DEBUGGER: return "debugger"; } FATAL("Unsupported deopt type"); return NULL; } Deoptimizer::Deoptimizer(Isolate* isolate, JSFunction* function, BailoutType type, unsigned bailout_id, Address from, int fp_to_sp_delta, Code* optimized_code) : isolate_(isolate), function_(function), bailout_id_(bailout_id), bailout_type_(type), from_(from), fp_to_sp_delta_(fp_to_sp_delta), has_alignment_padding_(0), input_(nullptr), output_count_(0), jsframe_count_(0), output_(nullptr), trace_scope_(nullptr) { // For COMPILED_STUBs called from builtins, the function pointer is a SMI // indicating an internal frame. if (function->IsSmi()) { function = nullptr; } DCHECK(from != nullptr); if (function != nullptr && function->IsOptimized()) { function->shared()->increment_deopt_count(); if (bailout_type_ == Deoptimizer::SOFT) { isolate->counters()->soft_deopts_executed()->Increment(); // Soft deopts shouldn't count against the overall re-optimization count // that can eventually lead to disabling optimization for a function. int opt_count = function->shared()->opt_count(); if (opt_count > 0) opt_count--; function->shared()->set_opt_count(opt_count); } } compiled_code_ = FindOptimizedCode(function, optimized_code); #if DEBUG DCHECK(compiled_code_ != NULL); if (type == EAGER || type == SOFT || type == LAZY) { DCHECK(compiled_code_->kind() != Code::FUNCTION); } #endif StackFrame::Type frame_type = function == NULL ? StackFrame::STUB : StackFrame::JAVA_SCRIPT; trace_scope_ = TraceEnabledFor(type, frame_type) ? new CodeTracer::Scope(isolate->GetCodeTracer()) : NULL; #ifdef DEBUG CHECK(AllowHeapAllocation::IsAllowed()); disallow_heap_allocation_ = new DisallowHeapAllocation(); #endif // DEBUG if (compiled_code_->kind() == Code::OPTIMIZED_FUNCTION) { PROFILE(isolate_, CodeDeoptEvent(compiled_code_, from_, fp_to_sp_delta_)); } unsigned size = ComputeInputFrameSize(); input_ = new(size) FrameDescription(size, function); input_->SetFrameType(frame_type); } Code* Deoptimizer::FindOptimizedCode(JSFunction* function, Code* optimized_code) { switch (bailout_type_) { case Deoptimizer::SOFT: case Deoptimizer::EAGER: case Deoptimizer::LAZY: { Code* compiled_code = FindDeoptimizingCode(from_); return (compiled_code == NULL) ? static_cast<Code*>(isolate_->FindCodeObject(from_)) : compiled_code; } case Deoptimizer::DEBUGGER: DCHECK(optimized_code->contains(from_)); return optimized_code; } FATAL("Could not find code for optimized function"); return NULL; } void Deoptimizer::PrintFunctionName() { if (function_->IsJSFunction()) { function_->ShortPrint(trace_scope_->file()); } else { PrintF(trace_scope_->file(), "%s", Code::Kind2String(compiled_code_->kind())); } } Deoptimizer::~Deoptimizer() { DCHECK(input_ == NULL && output_ == NULL); DCHECK(disallow_heap_allocation_ == NULL); delete trace_scope_; } void Deoptimizer::DeleteFrameDescriptions() { delete input_; for (int i = 0; i < output_count_; ++i) { if (output_[i] != input_) delete output_[i]; } delete[] output_; input_ = NULL; output_ = NULL; #ifdef DEBUG CHECK(!AllowHeapAllocation::IsAllowed()); CHECK(disallow_heap_allocation_ != NULL); delete disallow_heap_allocation_; disallow_heap_allocation_ = NULL; #endif // DEBUG } Address Deoptimizer::GetDeoptimizationEntry(Isolate* isolate, int id, BailoutType type, GetEntryMode mode) { CHECK_GE(id, 0); if (id >= kMaxNumberOfEntries) return NULL; if (mode == ENSURE_ENTRY_CODE) { EnsureCodeForDeoptimizationEntry(isolate, type, id); } else { CHECK_EQ(mode, CALCULATE_ENTRY_ADDRESS); } DeoptimizerData* data = isolate->deoptimizer_data(); CHECK_LT(type, kBailoutTypesWithCodeEntry); MemoryChunk* base = data->deopt_entry_code_[type]; return base->area_start() + (id * table_entry_size_); } int Deoptimizer::GetDeoptimizationId(Isolate* isolate, Address addr, BailoutType type) { DeoptimizerData* data = isolate->deoptimizer_data(); MemoryChunk* base = data->deopt_entry_code_[type]; Address start = base->area_start(); if (addr < start || addr >= start + (kMaxNumberOfEntries * table_entry_size_)) { return kNotDeoptimizationEntry; } DCHECK_EQ(0, static_cast<int>(addr - start) % table_entry_size_); return static_cast<int>(addr - start) / table_entry_size_; } int Deoptimizer::GetOutputInfo(DeoptimizationOutputData* data, BailoutId id, SharedFunctionInfo* shared) { // TODO(kasperl): For now, we do a simple linear search for the PC // offset associated with the given node id. This should probably be // changed to a binary search. int length = data->DeoptPoints(); for (int i = 0; i < length; i++) { if (data->AstId(i) == id) { return data->PcAndState(i)->value(); } } OFStream os(stderr); os << "[couldn't find pc offset for node=" << id.ToInt() << "]\n" << "[method: " << shared->DebugName()->ToCString().get() << "]\n" << "[source:\n" << SourceCodeOf(shared) << "\n]" << std::endl; shared->GetHeap()->isolate()->PushStackTraceAndDie(0xfefefefe, data, shared, 0xfefefeff); FATAL("unable to find pc offset during deoptimization"); return -1; } int Deoptimizer::GetDeoptimizedCodeCount(Isolate* isolate) { int length = 0; // Count all entries in the deoptimizing code list of every context. Object* context = isolate->heap()->native_contexts_list(); while (!context->IsUndefined()) { Context* native_context = Context::cast(context); Object* element = native_context->DeoptimizedCodeListHead(); while (!element->IsUndefined()) { Code* code = Code::cast(element); DCHECK(code->kind() == Code::OPTIMIZED_FUNCTION); length++; element = code->next_code_link(); } context = Context::cast(context)->get(Context::NEXT_CONTEXT_LINK); } return length; } // We rely on this function not causing a GC. It is called from generated code // without having a real stack frame in place. void Deoptimizer::DoComputeOutputFrames() { base::ElapsedTimer timer; // Determine basic deoptimization information. The optimized frame is // described by the input data. DeoptimizationInputData* input_data = DeoptimizationInputData::cast(compiled_code_->deoptimization_data()); if (trace_scope_ != NULL) { timer.Start(); PrintF(trace_scope_->file(), "[deoptimizing (DEOPT %s): begin ", MessageFor(bailout_type_)); PrintFunctionName(); PrintF(trace_scope_->file(), " (opt #%d) @%d, FP to SP delta: %d]\n", input_data->OptimizationId()->value(), bailout_id_, fp_to_sp_delta_); if (bailout_type_ == EAGER || bailout_type_ == SOFT || (compiled_code_->is_hydrogen_stub())) { compiled_code_->PrintDeoptLocation(trace_scope_->file(), from_); } } BailoutId node_id = input_data->AstId(bailout_id_); ByteArray* translations = input_data->TranslationByteArray(); unsigned translation_index = input_data->TranslationIndex(bailout_id_)->value(); TranslationIterator state_iterator(translations, translation_index); translated_state_.Init( input_->GetFramePointerAddress(), &state_iterator, input_data->LiteralArray(), input_->GetRegisterValues(), trace_scope_ == nullptr ? nullptr : trace_scope_->file()); // Do the input frame to output frame(s) translation. size_t count = translated_state_.frames().size(); DCHECK(output_ == NULL); output_ = new FrameDescription*[count]; for (size_t i = 0; i < count; ++i) { output_[i] = NULL; } output_count_ = static_cast<int>(count); Register fp_reg = JavaScriptFrame::fp_register(); stack_fp_ = reinterpret_cast<Address>( input_->GetRegister(fp_reg.code()) + has_alignment_padding_ * kPointerSize); // Translate each output frame. for (size_t i = 0; i < count; ++i) { // Read the ast node id, function, and frame height for this output frame. int frame_index = static_cast<int>(i); switch (translated_state_.frames()[i].kind()) { case TranslatedFrame::kFunction: DoComputeJSFrame(frame_index); jsframe_count_++; break; case TranslatedFrame::kInterpretedFunction: DoComputeInterpretedFrame(frame_index); jsframe_count_++; break; case TranslatedFrame::kArgumentsAdaptor: DoComputeArgumentsAdaptorFrame(frame_index); break; case TranslatedFrame::kConstructStub: DoComputeConstructStubFrame(frame_index); break; case TranslatedFrame::kGetter: DoComputeAccessorStubFrame(frame_index, false); break; case TranslatedFrame::kSetter: DoComputeAccessorStubFrame(frame_index, true); break; case TranslatedFrame::kCompiledStub: DoComputeCompiledStubFrame(frame_index); break; case TranslatedFrame::kInvalid: FATAL("invalid frame"); break; } } // Print some helpful diagnostic information. if (trace_scope_ != NULL) { double ms = timer.Elapsed().InMillisecondsF(); int index = output_count_ - 1; // Index of the topmost frame. PrintF(trace_scope_->file(), "[deoptimizing (%s): end ", MessageFor(bailout_type_)); PrintFunctionName(); PrintF(trace_scope_->file(), " @%d => node=%d, pc=0x%08" V8PRIxPTR ", state=%s, alignment=%s," " took %0.3f ms]\n", bailout_id_, node_id.ToInt(), output_[index]->GetPc(), FullCodeGenerator::State2String( static_cast<FullCodeGenerator::State>( output_[index]->GetState()->value())), has_alignment_padding_ ? "with padding" : "no padding", ms); } } void Deoptimizer::DoComputeJSFrame(int frame_index) { TranslatedFrame* translated_frame = &(translated_state_.frames()[frame_index]); TranslatedFrame::iterator value_iterator = translated_frame->begin(); int input_index = 0; BailoutId node_id = translated_frame->node_id(); unsigned height = translated_frame->height() - 1; // Do not count the context. unsigned height_in_bytes = height * kPointerSize; JSFunction* function = JSFunction::cast(value_iterator->GetRawValue()); value_iterator++; input_index++; if (trace_scope_ != NULL) { PrintF(trace_scope_->file(), " translating frame "); function->PrintName(trace_scope_->file()); PrintF(trace_scope_->file(), " => node=%d, height=%d\n", node_id.ToInt(), height_in_bytes); } // The 'fixed' part of the frame consists of the incoming parameters and // the part described by JavaScriptFrameConstants. unsigned fixed_frame_size = ComputeJavascriptFixedSize(function); unsigned input_frame_size = input_->GetFrameSize(); unsigned output_frame_size = height_in_bytes + fixed_frame_size; // Allocate and store the output frame description. FrameDescription* output_frame = new(output_frame_size) FrameDescription(output_frame_size, function); output_frame->SetFrameType(StackFrame::JAVA_SCRIPT); bool is_bottommost = (0 == frame_index); bool is_topmost = (output_count_ - 1 == frame_index); CHECK(frame_index >= 0 && frame_index < output_count_); CHECK_NULL(output_[frame_index]); output_[frame_index] = output_frame; // The top address for the bottommost output frame can be computed from // the input frame pointer and the output frame's height. For all // subsequent output frames, it can be computed from the previous one's // top address and the current frame's size. Register fp_reg = JavaScriptFrame::fp_register(); intptr_t top_address; if (is_bottommost) { // Determine whether the input frame contains alignment padding. has_alignment_padding_ = (!compiled_code_->is_turbofanned() && HasAlignmentPadding(function)) ? 1 : 0; // 2 = context and function in the frame. // If the optimized frame had alignment padding, adjust the frame pointer // to point to the new position of the old frame pointer after padding // is removed. Subtract 2 * kPointerSize for the context and function slots. top_address = input_->GetRegister(fp_reg.code()) - StandardFrameConstants::kFixedFrameSizeFromFp - height_in_bytes + has_alignment_padding_ * kPointerSize; } else { top_address = output_[frame_index - 1]->GetTop() - output_frame_size; } output_frame->SetTop(top_address); // Compute the incoming parameter translation. int parameter_count = function->shared()->internal_formal_parameter_count() + 1; unsigned output_offset = output_frame_size; unsigned input_offset = input_frame_size; for (int i = 0; i < parameter_count; ++i) { output_offset -= kPointerSize; WriteTranslatedValueToOutput(&value_iterator, &input_index, frame_index, output_offset); } input_offset -= (parameter_count * kPointerSize); // There are no translation commands for the caller's pc and fp, the // context, and the function. Synthesize their values and set them up // explicitly. // // The caller's pc for the bottommost output frame is the same as in the // input frame. For all subsequent output frames, it can be read from the // previous one. This frame's pc can be computed from the non-optimized // function code and AST id of the bailout. output_offset -= kPCOnStackSize; input_offset -= kPCOnStackSize; intptr_t value; if (is_bottommost) { value = input_->GetFrameSlot(input_offset); } else { value = output_[frame_index - 1]->GetPc(); } output_frame->SetCallerPc(output_offset, value); DebugPrintOutputSlot(value, frame_index, output_offset, "caller's pc\n"); // The caller's frame pointer for the bottommost output frame is the same // as in the input frame. For all subsequent output frames, it can be // read from the previous one. Also compute and set this frame's frame // pointer. output_offset -= kFPOnStackSize; input_offset -= kFPOnStackSize; if (is_bottommost) { value = input_->GetFrameSlot(input_offset); } else { value = output_[frame_index - 1]->GetFp(); } output_frame->SetCallerFp(output_offset, value); intptr_t fp_value = top_address + output_offset; DCHECK(!is_bottommost || (input_->GetRegister(fp_reg.code()) + has_alignment_padding_ * kPointerSize) == fp_value); output_frame->SetFp(fp_value); if (is_topmost) output_frame->SetRegister(fp_reg.code(), fp_value); DebugPrintOutputSlot(value, frame_index, output_offset, "caller's fp\n"); DCHECK(!is_bottommost || !has_alignment_padding_ || (fp_value & kPointerSize) != 0); if (FLAG_enable_embedded_constant_pool) { // For the bottommost output frame the constant pool pointer can be gotten // from the input frame. For subsequent output frames, it can be read from // the previous frame. output_offset -= kPointerSize; input_offset -= kPointerSize; if (is_bottommost) { value = input_->GetFrameSlot(input_offset); } else { value = output_[frame_index - 1]->GetConstantPool(); } output_frame->SetCallerConstantPool(output_offset, value); DebugPrintOutputSlot(value, frame_index, output_offset, "caller's constant_pool\n"); } // For the bottommost output frame the context can be gotten from the input // frame. For all subsequent output frames it can be gotten from the function // so long as we don't inline functions that need local contexts. Register context_reg = JavaScriptFrame::context_register(); output_offset -= kPointerSize; input_offset -= kPointerSize; // Read the context from the translations. Object* context = value_iterator->GetRawValue(); if (context == isolate_->heap()->undefined_value()) { // If the context was optimized away, just use the context from // the activation. This should only apply to Crankshaft code. CHECK(!compiled_code_->is_turbofanned()); context = is_bottommost ? reinterpret_cast<Object*>(input_->GetFrameSlot(input_offset)) : function->context(); } value = reinterpret_cast<intptr_t>(context); output_frame->SetContext(value); if (is_topmost) output_frame->SetRegister(context_reg.code(), value); WriteValueToOutput(context, input_index, frame_index, output_offset, "context "); if (context == isolate_->heap()->arguments_marker()) { Address output_address = reinterpret_cast<Address>(output_[frame_index]->GetTop()) + output_offset; values_to_materialize_.push_back({output_address, value_iterator}); } value_iterator++; input_index++; // The function was mentioned explicitly in the BEGIN_FRAME. output_offset -= kPointerSize; input_offset -= kPointerSize; value = reinterpret_cast<intptr_t>(function); // The function for the bottommost output frame should also agree with the // input frame. DCHECK(!is_bottommost || input_->GetFrameSlot(input_offset) == value); WriteValueToOutput(function, 0, frame_index, output_offset, "function "); // Translate the rest of the frame. for (unsigned i = 0; i < height; ++i) { output_offset -= kPointerSize; WriteTranslatedValueToOutput(&value_iterator, &input_index, frame_index, output_offset); } CHECK_EQ(0u, output_offset); // Compute this frame's PC, state, and continuation. Code* non_optimized_code = function->shared()->code(); FixedArray* raw_data = non_optimized_code->deoptimization_data(); DeoptimizationOutputData* data = DeoptimizationOutputData::cast(raw_data); Address start = non_optimized_code->instruction_start(); unsigned pc_and_state = GetOutputInfo(data, node_id, function->shared()); unsigned pc_offset = FullCodeGenerator::PcField::decode(pc_and_state); intptr_t pc_value = reinterpret_cast<intptr_t>(start + pc_offset); output_frame->SetPc(pc_value); // Update constant pool. if (FLAG_enable_embedded_constant_pool) { intptr_t constant_pool_value = reinterpret_cast<intptr_t>(non_optimized_code->constant_pool()); output_frame->SetConstantPool(constant_pool_value); if (is_topmost) { Register constant_pool_reg = JavaScriptFrame::constant_pool_pointer_register(); output_frame->SetRegister(constant_pool_reg.code(), constant_pool_value); } } FullCodeGenerator::State state = FullCodeGenerator::StateField::decode(pc_and_state); output_frame->SetState(Smi::FromInt(state)); // Set the continuation for the topmost frame. if (is_topmost && bailout_type_ != DEBUGGER) { Builtins* builtins = isolate_->builtins(); Code* continuation = builtins->builtin(Builtins::kNotifyDeoptimized); if (bailout_type_ == LAZY) { continuation = builtins->builtin(Builtins::kNotifyLazyDeoptimized); } else if (bailout_type_ == SOFT) { continuation = builtins->builtin(Builtins::kNotifySoftDeoptimized); } else { CHECK_EQ(bailout_type_, EAGER); } output_frame->SetContinuation( reinterpret_cast<intptr_t>(continuation->entry())); } } void Deoptimizer::DoComputeInterpretedFrame(int frame_index) { TranslatedFrame* translated_frame = &(translated_state_.frames()[frame_index]); TranslatedFrame::iterator value_iterator = translated_frame->begin(); int input_index = 0; BailoutId bytecode_offset = translated_frame->node_id(); unsigned height = translated_frame->height(); unsigned height_in_bytes = height * kPointerSize; JSFunction* function = JSFunction::cast(value_iterator->GetRawValue()); value_iterator++; input_index++; if (trace_scope_ != NULL) { PrintF(trace_scope_->file(), " translating interpreted frame "); function->PrintName(trace_scope_->file()); PrintF(trace_scope_->file(), " => bytecode_offset=%d, height=%d\n", bytecode_offset.ToInt(), height_in_bytes); } // The 'fixed' part of the frame consists of the incoming parameters and // the part described by InterpreterFrameConstants. unsigned fixed_frame_size = ComputeInterpretedFixedSize(function); unsigned input_frame_size = input_->GetFrameSize(); unsigned output_frame_size = height_in_bytes + fixed_frame_size; // Allocate and store the output frame description. FrameDescription* output_frame = new (output_frame_size) FrameDescription(output_frame_size, function); output_frame->SetFrameType(StackFrame::INTERPRETED); bool is_bottommost = (0 == frame_index); bool is_topmost = (output_count_ - 1 == frame_index); CHECK(frame_index >= 0 && frame_index < output_count_); CHECK_NULL(output_[frame_index]); output_[frame_index] = output_frame; // The top address for the bottommost output frame can be computed from // the input frame pointer and the output frame's height. For all // subsequent output frames, it can be computed from the previous one's // top address and the current frame's size. Register fp_reg = InterpretedFrame::fp_register(); intptr_t top_address; if (is_bottommost) { // Subtract interpreter fixed frame size for the context function slots, // new,target and bytecode offset. top_address = input_->GetRegister(fp_reg.code()) - InterpreterFrameConstants::kFixedFrameSizeFromFp - height_in_bytes; } else { top_address = output_[frame_index - 1]->GetTop() - output_frame_size; } output_frame->SetTop(top_address); // Compute the incoming parameter translation. int parameter_count = function->shared()->internal_formal_parameter_count() + 1; unsigned output_offset = output_frame_size; unsigned input_offset = input_frame_size; for (int i = 0; i < parameter_count; ++i) { output_offset -= kPointerSize; WriteTranslatedValueToOutput(&value_iterator, &input_index, frame_index, output_offset); } input_offset -= (parameter_count * kPointerSize); // There are no translation commands for the caller's pc and fp, the // context, the function, new.target and the bytecode offset. Synthesize // their values and set them up // explicitly. // // The caller's pc for the bottommost output frame is the same as in the // input frame. For all subsequent output frames, it can be read from the // previous one. This frame's pc can be computed from the non-optimized // function code and AST id of the bailout. output_offset -= kPCOnStackSize; input_offset -= kPCOnStackSize; intptr_t value; if (is_bottommost) { value = input_->GetFrameSlot(input_offset); } else { value = output_[frame_index - 1]->GetPc(); } output_frame->SetCallerPc(output_offset, value); DebugPrintOutputSlot(value, frame_index, output_offset, "caller's pc\n"); // The caller's frame pointer for the bottommost output frame is the same // as in the input frame. For all subsequent output frames, it can be // read from the previous one. Also compute and set this frame's frame // pointer. output_offset -= kFPOnStackSize; input_offset -= kFPOnStackSize; if (is_bottommost) { value = input_->GetFrameSlot(input_offset); } else { value = output_[frame_index - 1]->GetFp(); } output_frame->SetCallerFp(output_offset, value); intptr_t fp_value = top_address + output_offset; DCHECK(!is_bottommost || (input_->GetRegister(fp_reg.code()) + has_alignment_padding_ * kPointerSize) == fp_value); output_frame->SetFp(fp_value); if (is_topmost) output_frame->SetRegister(fp_reg.code(), fp_value); DebugPrintOutputSlot(value, frame_index, output_offset, "caller's fp\n"); DCHECK(!is_bottommost || !has_alignment_padding_ || (fp_value & kPointerSize) != 0); if (FLAG_enable_embedded_constant_pool) { // For the bottommost output frame the constant pool pointer can be gotten // from the input frame. For subsequent output frames, it can be read from // the previous frame. output_offset -= kPointerSize; input_offset -= kPointerSize; if (is_bottommost) { value = input_->GetFrameSlot(input_offset); } else { value = output_[frame_index - 1]->GetConstantPool(); } output_frame->SetCallerConstantPool(output_offset, value); DebugPrintOutputSlot(value, frame_index, output_offset, "caller's constant_pool\n"); } // For the bottommost output frame the context can be gotten from the input // frame. For all subsequent output frames it can be gotten from the function // so long as we don't inline functions that need local contexts. Register context_reg = InterpretedFrame::context_register(); output_offset -= kPointerSize; input_offset -= kPointerSize; // Read the context from the translations. Object* context = value_iterator->GetRawValue(); // The context should not be a placeholder for a materialized object. CHECK(context != isolate_->heap()->arguments_marker()); value = reinterpret_cast<intptr_t>(context); output_frame->SetContext(value); if (is_topmost) output_frame->SetRegister(context_reg.code(), value); WriteValueToOutput(context, input_index, frame_index, output_offset, "context "); value_iterator++; input_index++; // The function was mentioned explicitly in the BEGIN_FRAME. output_offset -= kPointerSize; input_offset -= kPointerSize; value = reinterpret_cast<intptr_t>(function); // The function for the bottommost output frame should also agree with the // input frame. DCHECK(!is_bottommost || input_->GetFrameSlot(input_offset) == value); WriteValueToOutput(function, 0, frame_index, output_offset, "function "); // TODO(rmcilroy): Deal with new.target correctly - currently just set it to // undefined. output_offset -= kPointerSize; input_offset -= kPointerSize; Object* new_target = isolate_->heap()->undefined_value(); WriteValueToOutput(new_target, 0, frame_index, output_offset, "new_target "); // The bytecode offset was mentioned explicitly in the BEGIN_FRAME. output_offset -= kPointerSize; input_offset -= kPointerSize; int raw_bytecode_offset = BytecodeArray::kHeaderSize - kHeapObjectTag + bytecode_offset.ToInt(); Smi* smi_bytecode_offset = Smi::FromInt(raw_bytecode_offset); WriteValueToOutput(smi_bytecode_offset, 0, frame_index, output_offset, "bytecode offset "); // Translate the rest of the interpreter registers in the frame. for (unsigned i = 0; i < height; ++i) { output_offset -= kPointerSize; WriteTranslatedValueToOutput(&value_iterator, &input_index, frame_index, output_offset); } CHECK_EQ(0u, output_offset); // Set the accumulator register. output_frame->SetRegister( kInterpreterAccumulatorRegister.code(), reinterpret_cast<intptr_t>(value_iterator->GetRawValue())); value_iterator++; Builtins* builtins = isolate_->builtins(); Code* trampoline = builtins->builtin(Builtins::kInterpreterEntryTrampoline); output_frame->SetPc(reinterpret_cast<intptr_t>(trampoline->entry())); output_frame->SetState(0); // Update constant pool. if (FLAG_enable_embedded_constant_pool) { intptr_t constant_pool_value = reinterpret_cast<intptr_t>(trampoline->constant_pool()); output_frame->SetConstantPool(constant_pool_value); if (is_topmost) { Register constant_pool_reg = InterpretedFrame::constant_pool_pointer_register(); output_frame->SetRegister(constant_pool_reg.code(), constant_pool_value); } } // Set the continuation for the topmost frame. if (is_topmost && bailout_type_ != DEBUGGER) { Code* continuation = builtins->builtin(Builtins::kInterpreterNotifyDeoptimized); if (bailout_type_ == LAZY) { continuation = builtins->builtin(Builtins::kInterpreterNotifyLazyDeoptimized); } else if (bailout_type_ == SOFT) { continuation = builtins->builtin(Builtins::kInterpreterNotifySoftDeoptimized); } else { CHECK_EQ(bailout_type_, EAGER); } output_frame->SetContinuation( reinterpret_cast<intptr_t>(continuation->entry())); } } void Deoptimizer::DoComputeArgumentsAdaptorFrame(int frame_index) { TranslatedFrame* translated_frame = &(translated_state_.frames()[frame_index]); TranslatedFrame::iterator value_iterator = translated_frame->begin(); int input_index = 0; unsigned height = translated_frame->height(); unsigned height_in_bytes = height * kPointerSize; JSFunction* function = JSFunction::cast(value_iterator->GetRawValue()); value_iterator++; input_index++; if (trace_scope_ != NULL) { PrintF(trace_scope_->file(), " translating arguments adaptor => height=%d\n", height_in_bytes); } unsigned fixed_frame_size = ArgumentsAdaptorFrameConstants::kFrameSize; unsigned output_frame_size = height_in_bytes + fixed_frame_size; // Allocate and store the output frame description. FrameDescription* output_frame = new(output_frame_size) FrameDescription(output_frame_size, function); output_frame->SetFrameType(StackFrame::ARGUMENTS_ADAPTOR); // Arguments adaptor can not be topmost or bottommost. CHECK(frame_index > 0 && frame_index < output_count_ - 1); CHECK(output_[frame_index] == NULL); output_[frame_index] = output_frame; // The top address of the frame is computed from the previous // frame's top and this frame's size. intptr_t top_address; top_address = output_[frame_index - 1]->GetTop() - output_frame_size; output_frame->SetTop(top_address); // Compute the incoming parameter translation. int parameter_count = height; unsigned output_offset = output_frame_size; for (int i = 0; i < parameter_count; ++i) { output_offset -= kPointerSize; WriteTranslatedValueToOutput(&value_iterator, &input_index, frame_index, output_offset); } // Read caller's PC from the previous frame. output_offset -= kPCOnStackSize; intptr_t callers_pc = output_[frame_index - 1]->GetPc(); output_frame->SetCallerPc(output_offset, callers_pc); DebugPrintOutputSlot(callers_pc, frame_index, output_offset, "caller's pc\n"); // Read caller's FP from the previous frame, and set this frame's FP. output_offset -= kFPOnStackSize; intptr_t value = output_[frame_index - 1]->GetFp(); output_frame->SetCallerFp(output_offset, value); intptr_t fp_value = top_address + output_offset; output_frame->SetFp(fp_value); DebugPrintOutputSlot(value, frame_index, output_offset, "caller's fp\n"); if (FLAG_enable_embedded_constant_pool) { // Read the caller's constant pool from the previous frame. output_offset -= kPointerSize; value = output_[frame_index - 1]->GetConstantPool(); output_frame->SetCallerConstantPool(output_offset, value); DebugPrintOutputSlot(value, frame_index, output_offset, "caller's constant_pool\n"); } // A marker value is used in place of the context. output_offset -= kPointerSize; intptr_t context = reinterpret_cast<intptr_t>( Smi::FromInt(StackFrame::ARGUMENTS_ADAPTOR)); output_frame->SetFrameSlot(output_offset, context); DebugPrintOutputSlot(context, frame_index, output_offset, "context (adaptor sentinel)\n"); // The function was mentioned explicitly in the ARGUMENTS_ADAPTOR_FRAME. output_offset -= kPointerSize; value = reinterpret_cast<intptr_t>(function); WriteValueToOutput(function, 0, frame_index, output_offset, "function "); // Number of incoming arguments. output_offset -= kPointerSize; value = reinterpret_cast<intptr_t>(Smi::FromInt(height - 1)); output_frame->SetFrameSlot(output_offset, value); DebugPrintOutputSlot(value, frame_index, output_offset, "argc "); if (trace_scope_ != nullptr) { PrintF(trace_scope_->file(), "(%d)\n", height - 1); } DCHECK(0 == output_offset); Builtins* builtins = isolate_->builtins(); Code* adaptor_trampoline = builtins->builtin(Builtins::kArgumentsAdaptorTrampoline); intptr_t pc_value = reinterpret_cast<intptr_t>( adaptor_trampoline->instruction_start() + isolate_->heap()->arguments_adaptor_deopt_pc_offset()->value()); output_frame->SetPc(pc_value); if (FLAG_enable_embedded_constant_pool) { intptr_t constant_pool_value = reinterpret_cast<intptr_t>(adaptor_trampoline->constant_pool()); output_frame->SetConstantPool(constant_pool_value); } } void Deoptimizer::DoComputeConstructStubFrame(int frame_index) { TranslatedFrame* translated_frame = &(translated_state_.frames()[frame_index]); TranslatedFrame::iterator value_iterator = translated_frame->begin(); int input_index = 0; Builtins* builtins = isolate_->builtins(); Code* construct_stub = builtins->builtin(Builtins::kJSConstructStubGeneric); unsigned height = translated_frame->height(); unsigned height_in_bytes = height * kPointerSize; JSFunction* function = JSFunction::cast(value_iterator->GetRawValue()); value_iterator++; input_index++; if (trace_scope_ != NULL) { PrintF(trace_scope_->file(), " translating construct stub => height=%d\n", height_in_bytes); } unsigned fixed_frame_size = ConstructFrameConstants::kFrameSize; unsigned output_frame_size = height_in_bytes + fixed_frame_size; // Allocate and store the output frame description. FrameDescription* output_frame = new(output_frame_size) FrameDescription(output_frame_size, function); output_frame->SetFrameType(StackFrame::CONSTRUCT); // Construct stub can not be topmost or bottommost. DCHECK(frame_index > 0 && frame_index < output_count_ - 1); DCHECK(output_[frame_index] == NULL); output_[frame_index] = output_frame; // The top address of the frame is computed from the previous // frame's top and this frame's size. intptr_t top_address; top_address = output_[frame_index - 1]->GetTop() - output_frame_size; output_frame->SetTop(top_address); // Compute the incoming parameter translation. int parameter_count = height; unsigned output_offset = output_frame_size; for (int i = 0; i < parameter_count; ++i) { output_offset -= kPointerSize; // The allocated receiver of a construct stub frame is passed as the // receiver parameter through the translation. It might be encoding // a captured object, override the slot address for a captured object. WriteTranslatedValueToOutput( &value_iterator, &input_index, frame_index, output_offset, nullptr, (i == 0) ? reinterpret_cast<Address>(top_address) : nullptr); } // Read caller's PC from the previous frame. output_offset -= kPCOnStackSize; intptr_t callers_pc = output_[frame_index - 1]->GetPc(); output_frame->SetCallerPc(output_offset, callers_pc); DebugPrintOutputSlot(callers_pc, frame_index, output_offset, "caller's pc\n"); // Read caller's FP from the previous frame, and set this frame's FP. output_offset -= kFPOnStackSize; intptr_t value = output_[frame_index - 1]->GetFp(); output_frame->SetCallerFp(output_offset, value); intptr_t fp_value = top_address + output_offset; output_frame->SetFp(fp_value); DebugPrintOutputSlot(value, frame_index, output_offset, "caller's fp\n"); if (FLAG_enable_embedded_constant_pool) { // Read the caller's constant pool from the previous frame. output_offset -= kPointerSize; value = output_[frame_index - 1]->GetConstantPool(); output_frame->SetCallerConstantPool(output_offset, value); DebugPrintOutputSlot(value, frame_index, output_offset, "caller's constant_pool\n"); } // The context can be gotten from the previous frame. output_offset -= kPointerSize; value = output_[frame_index - 1]->GetContext(); output_frame->SetFrameSlot(output_offset, value); DebugPrintOutputSlot(value, frame_index, output_offset, "context\n"); // A marker value is used in place of the function. output_offset -= kPointerSize; value = reinterpret_cast<intptr_t>(Smi::FromInt(StackFrame::CONSTRUCT)); output_frame->SetFrameSlot(output_offset, value); DebugPrintOutputSlot(value, frame_index, output_offset, "function (construct sentinel)\n"); // The output frame reflects a JSConstructStubGeneric frame. output_offset -= kPointerSize; value = reinterpret_cast<intptr_t>(construct_stub); output_frame->SetFrameSlot(output_offset, value); DebugPrintOutputSlot(value, frame_index, output_offset, "code object\n"); // The allocation site. output_offset -= kPointerSize; value = reinterpret_cast<intptr_t>(isolate_->heap()->undefined_value()); output_frame->SetFrameSlot(output_offset, value); DebugPrintOutputSlot(value, frame_index, output_offset, "allocation site\n"); // Number of incoming arguments. output_offset -= kPointerSize; value = reinterpret_cast<intptr_t>(Smi::FromInt(height - 1)); output_frame->SetFrameSlot(output_offset, value); DebugPrintOutputSlot(value, frame_index, output_offset, "argc "); if (trace_scope_ != nullptr) { PrintF(trace_scope_->file(), "(%d)\n", height - 1); } // The newly allocated object was passed as receiver in the artificial // constructor stub environment created by HEnvironment::CopyForInlining(). output_offset -= kPointerSize; value = output_frame->GetFrameSlot(output_frame_size - kPointerSize); output_frame->SetFrameSlot(output_offset, value); DebugPrintOutputSlot(value, frame_index, output_offset, "allocated receiver\n"); CHECK_EQ(0u, output_offset); intptr_t pc = reinterpret_cast<intptr_t>( construct_stub->instruction_start() + isolate_->heap()->construct_stub_deopt_pc_offset()->value()); output_frame->SetPc(pc); if (FLAG_enable_embedded_constant_pool) { intptr_t constant_pool_value = reinterpret_cast<intptr_t>(construct_stub->constant_pool()); output_frame->SetConstantPool(constant_pool_value); } } void Deoptimizer::DoComputeAccessorStubFrame(int frame_index, bool is_setter_stub_frame) { TranslatedFrame* translated_frame = &(translated_state_.frames()[frame_index]); TranslatedFrame::iterator value_iterator = translated_frame->begin(); int input_index = 0; JSFunction* accessor = JSFunction::cast(value_iterator->GetRawValue()); value_iterator++; input_index++; // The receiver (and the implicit return value, if any) are expected in // registers by the LoadIC/StoreIC, so they don't belong to the output stack // frame. This means that we have to use a height of 0. unsigned height = 0; unsigned height_in_bytes = height * kPointerSize; const char* kind = is_setter_stub_frame ? "setter" : "getter"; if (trace_scope_ != NULL) { PrintF(trace_scope_->file(), " translating %s stub => height=%u\n", kind, height_in_bytes); } // We need 1 stack entry for the return address and enough entries for the // StackFrame::INTERNAL (FP, context, frame type, code object and constant // pool (if enabled)- see MacroAssembler::EnterFrame). // For a setter stub frame we need one additional entry for the implicit // return value, see StoreStubCompiler::CompileStoreViaSetter. unsigned fixed_frame_entries = (StandardFrameConstants::kFixedFrameSize / kPointerSize) + 1 + (is_setter_stub_frame ? 1 : 0); unsigned fixed_frame_size = fixed_frame_entries * kPointerSize; unsigned output_frame_size = height_in_bytes + fixed_frame_size; // Allocate and store the output frame description. FrameDescription* output_frame = new(output_frame_size) FrameDescription(output_frame_size, accessor); output_frame->SetFrameType(StackFrame::INTERNAL); // A frame for an accessor stub can not be the topmost or bottommost one. CHECK(frame_index > 0 && frame_index < output_count_ - 1); CHECK_NULL(output_[frame_index]); output_[frame_index] = output_frame; // The top address of the frame is computed from the previous frame's top and // this frame's size. intptr_t top_address = output_[frame_index - 1]->GetTop() - output_frame_size; output_frame->SetTop(top_address); unsigned output_offset = output_frame_size; // Read caller's PC from the previous frame. output_offset -= kPCOnStackSize; intptr_t callers_pc = output_[frame_index - 1]->GetPc(); output_frame->SetCallerPc(output_offset, callers_pc); DebugPrintOutputSlot(callers_pc, frame_index, output_offset, "caller's pc\n"); // Read caller's FP from the previous frame, and set this frame's FP. output_offset -= kFPOnStackSize; intptr_t value = output_[frame_index - 1]->GetFp(); output_frame->SetCallerFp(output_offset, value); intptr_t fp_value = top_address + output_offset; output_frame->SetFp(fp_value); DebugPrintOutputSlot(value, frame_index, output_offset, "caller's fp\n"); if (FLAG_enable_embedded_constant_pool) { // Read the caller's constant pool from the previous frame. output_offset -= kPointerSize; value = output_[frame_index - 1]->GetConstantPool(); output_frame->SetCallerConstantPool(output_offset, value); DebugPrintOutputSlot(value, frame_index, output_offset, "caller's constant_pool\n"); } // The context can be gotten from the previous frame. output_offset -= kPointerSize; value = output_[frame_index - 1]->GetContext(); output_frame->SetFrameSlot(output_offset, value); DebugPrintOutputSlot(value, frame_index, output_offset, "context\n"); // A marker value is used in place of the function. output_offset -= kPointerSize; value = reinterpret_cast<intptr_t>(Smi::FromInt(StackFrame::INTERNAL)); output_frame->SetFrameSlot(output_offset, value); DebugPrintOutputSlot(value, frame_index, output_offset, "function "); if (trace_scope_ != nullptr) { PrintF(trace_scope_->file(), "(%s sentinel)\n", kind); } // Get Code object from accessor stub. output_offset -= kPointerSize; Builtins::Name name = is_setter_stub_frame ? Builtins::kStoreIC_Setter_ForDeopt : Builtins::kLoadIC_Getter_ForDeopt; Code* accessor_stub = isolate_->builtins()->builtin(name); value = reinterpret_cast<intptr_t>(accessor_stub); output_frame->SetFrameSlot(output_offset, value); DebugPrintOutputSlot(value, frame_index, output_offset, "code object\n"); // Skip receiver. value_iterator++; input_index++; if (is_setter_stub_frame) { // The implicit return value was part of the artificial setter stub // environment. output_offset -= kPointerSize; WriteTranslatedValueToOutput(&value_iterator, &input_index, frame_index, output_offset); } CHECK_EQ(0u, output_offset); Smi* offset = is_setter_stub_frame ? isolate_->heap()->setter_stub_deopt_pc_offset() : isolate_->heap()->getter_stub_deopt_pc_offset(); intptr_t pc = reinterpret_cast<intptr_t>( accessor_stub->instruction_start() + offset->value()); output_frame->SetPc(pc); if (FLAG_enable_embedded_constant_pool) { intptr_t constant_pool_value = reinterpret_cast<intptr_t>(accessor_stub->constant_pool()); output_frame->SetConstantPool(constant_pool_value); } } void Deoptimizer::DoComputeCompiledStubFrame(int frame_index) { // // FROM TO // | .... | | .... | // +-------------------------+ +-------------------------+ // | JSFunction continuation | | JSFunction continuation | // +-------------------------+ +-------------------------+ // | | saved frame (FP) | | saved frame (FP) | // | +=========================+<-fpreg +=========================+<-fpreg // | |constant pool (if ool_cp)| |constant pool (if ool_cp)| // | +-------------------------+ +-------------------------| // | | JSFunction context | | JSFunction context | // v +-------------------------+ +-------------------------| // | COMPILED_STUB marker | | STUB_FAILURE marker | // +-------------------------+ +-------------------------+ // | | | caller args.arguments_ | // | ... | +-------------------------+ // | | | caller args.length_ | // |-------------------------|<-spreg +-------------------------+ // | caller args pointer | // +-------------------------+ // | caller stack param 1 | // parameters in registers +-------------------------+ // and spilled to stack | .... | // +-------------------------+ // | caller stack param n | // +-------------------------+<-spreg // reg = number of parameters // reg = failure handler address // reg = saved frame // reg = JSFunction context // // Caller stack params contain the register parameters to the stub first, // and then, if the descriptor specifies a constant number of stack // parameters, the stack parameters as well. TranslatedFrame* translated_frame = &(translated_state_.frames()[frame_index]); TranslatedFrame::iterator value_iterator = translated_frame->begin(); int input_index = 0; CHECK(compiled_code_->is_hydrogen_stub()); int major_key = CodeStub::GetMajorKey(compiled_code_); CodeStubDescriptor descriptor(isolate_, compiled_code_->stub_key()); // The output frame must have room for all pushed register parameters // and the standard stack frame slots. Include space for an argument // object to the callee and optionally the space to pass the argument // object to the stub failure handler. int param_count = descriptor.GetRegisterParameterCount(); int stack_param_count = descriptor.GetStackParameterCount(); CHECK_EQ(translated_frame->height(), param_count); CHECK_GE(param_count, 0); int height_in_bytes = kPointerSize * (param_count + stack_param_count) + sizeof(Arguments) + kPointerSize; int fixed_frame_size = StandardFrameConstants::kFixedFrameSize; int input_frame_size = input_->GetFrameSize(); int output_frame_size = height_in_bytes + fixed_frame_size; if (trace_scope_ != NULL) { PrintF(trace_scope_->file(), " translating %s => StubFailureTrampolineStub, height=%d\n", CodeStub::MajorName(static_cast<CodeStub::Major>(major_key)), height_in_bytes); } // The stub failure trampoline is a single frame. FrameDescription* output_frame = new(output_frame_size) FrameDescription(output_frame_size, NULL); output_frame->SetFrameType(StackFrame::STUB_FAILURE_TRAMPOLINE); CHECK_EQ(frame_index, 0); output_[frame_index] = output_frame; // The top address for the output frame can be computed from the input // frame pointer and the output frame's height. Subtract space for the // context and function slots. Register fp_reg = StubFailureTrampolineFrame::fp_register(); intptr_t top_address = input_->GetRegister(fp_reg.code()) - StandardFrameConstants::kFixedFrameSizeFromFp - height_in_bytes; output_frame->SetTop(top_address); // Read caller's PC (JSFunction continuation) from the input frame. unsigned input_frame_offset = input_frame_size - kPCOnStackSize; unsigned output_frame_offset = output_frame_size - kFPOnStackSize; intptr_t value = input_->GetFrameSlot(input_frame_offset); output_frame->SetCallerPc(output_frame_offset, value); DebugPrintOutputSlot(value, frame_index, output_frame_offset, "caller's pc\n"); // Read caller's FP from the input frame, and set this frame's FP. input_frame_offset -= kFPOnStackSize; value = input_->GetFrameSlot(input_frame_offset); output_frame_offset -= kFPOnStackSize; output_frame->SetCallerFp(output_frame_offset, value); intptr_t frame_ptr = input_->GetRegister(fp_reg.code()); output_frame->SetRegister(fp_reg.code(), frame_ptr); output_frame->SetFp(frame_ptr); DebugPrintOutputSlot(value, frame_index, output_frame_offset, "caller's fp\n"); if (FLAG_enable_embedded_constant_pool) { // Read the caller's constant pool from the input frame. input_frame_offset -= kPointerSize; value = input_->GetFrameSlot(input_frame_offset); output_frame_offset -= kPointerSize; output_frame->SetCallerConstantPool(output_frame_offset, value); DebugPrintOutputSlot(value, frame_index, output_frame_offset, "caller's constant_pool\n"); } // The context can be gotten from the input frame. Register context_reg = StubFailureTrampolineFrame::context_register(); input_frame_offset -= kPointerSize; value = input_->GetFrameSlot(input_frame_offset); output_frame->SetRegister(context_reg.code(), value); output_frame_offset -= kPointerSize; output_frame->SetFrameSlot(output_frame_offset, value); CHECK(reinterpret_cast<Object*>(value)->IsContext()); DebugPrintOutputSlot(value, frame_index, output_frame_offset, "context\n"); // A marker value is used in place of the function. output_frame_offset -= kPointerSize; value = reinterpret_cast<intptr_t>( Smi::FromInt(StackFrame::STUB_FAILURE_TRAMPOLINE)); output_frame->SetFrameSlot(output_frame_offset, value); DebugPrintOutputSlot(value, frame_index, output_frame_offset, "function (stub failure sentinel)\n"); intptr_t caller_arg_count = stack_param_count; bool arg_count_known = !descriptor.stack_parameter_count().is_valid(); // Build the Arguments object for the caller's parameters and a pointer to it. output_frame_offset -= kPointerSize; int args_arguments_offset = output_frame_offset; intptr_t the_hole = reinterpret_cast<intptr_t>( isolate_->heap()->the_hole_value()); if (arg_count_known) { value = frame_ptr + StandardFrameConstants::kCallerSPOffset + (caller_arg_count - 1) * kPointerSize; } else { value = the_hole; } output_frame->SetFrameSlot(args_arguments_offset, value); DebugPrintOutputSlot( value, frame_index, args_arguments_offset, arg_count_known ? "args.arguments\n" : "args.arguments (the hole)\n"); output_frame_offset -= kPointerSize; int length_frame_offset = output_frame_offset; value = arg_count_known ? caller_arg_count : the_hole; output_frame->SetFrameSlot(length_frame_offset, value); DebugPrintOutputSlot( value, frame_index, length_frame_offset, arg_count_known ? "args.length\n" : "args.length (the hole)\n"); output_frame_offset -= kPointerSize; value = frame_ptr + StandardFrameConstants::kCallerSPOffset - (output_frame_size - output_frame_offset) + kPointerSize; output_frame->SetFrameSlot(output_frame_offset, value); DebugPrintOutputSlot(value, frame_index, output_frame_offset, "args*\n"); // Copy the register parameters to the failure frame. int arguments_length_offset = -1; for (int i = 0; i < param_count; ++i) { output_frame_offset -= kPointerSize; WriteTranslatedValueToOutput(&value_iterator, &input_index, 0, output_frame_offset); if (!arg_count_known && descriptor.GetRegisterParameter(i) .is(descriptor.stack_parameter_count())) { arguments_length_offset = output_frame_offset; } } // Copy constant stack parameters to the failure frame. If the number of stack // parameters is not known in the descriptor, the arguments object is the way // to access them. for (int i = 0; i < stack_param_count; i++) { output_frame_offset -= kPointerSize; Object** stack_parameter = reinterpret_cast<Object**>( frame_ptr + StandardFrameConstants::kCallerSPOffset + (stack_param_count - i - 1) * kPointerSize); value = reinterpret_cast<intptr_t>(*stack_parameter); output_frame->SetFrameSlot(output_frame_offset, value); DebugPrintOutputSlot(value, frame_index, output_frame_offset, "stack parameter\n"); } CHECK_EQ(0u, output_frame_offset); if (!arg_count_known) { CHECK_GE(arguments_length_offset, 0); // We know it's a smi because 1) the code stub guarantees the stack // parameter count is in smi range, and 2) the DoTranslateCommand in the // parameter loop above translated that to a tagged value. Smi* smi_caller_arg_count = reinterpret_cast<Smi*>( output_frame->GetFrameSlot(arguments_length_offset)); caller_arg_count = smi_caller_arg_count->value(); output_frame->SetFrameSlot(length_frame_offset, caller_arg_count); DebugPrintOutputSlot(caller_arg_count, frame_index, length_frame_offset, "args.length\n"); value = frame_ptr + StandardFrameConstants::kCallerSPOffset + (caller_arg_count - 1) * kPointerSize; output_frame->SetFrameSlot(args_arguments_offset, value); DebugPrintOutputSlot(value, frame_index, args_arguments_offset, "args.arguments"); } // Copy the double registers from the input into the output frame. CopyDoubleRegisters(output_frame); // Fill registers containing handler and number of parameters. SetPlatformCompiledStubRegisters(output_frame, &descriptor); // Compute this frame's PC, state, and continuation. Code* trampoline = NULL; StubFunctionMode function_mode = descriptor.function_mode(); StubFailureTrampolineStub(isolate_, function_mode) .FindCodeInCache(&trampoline); DCHECK(trampoline != NULL); output_frame->SetPc(reinterpret_cast<intptr_t>( trampoline->instruction_start())); if (FLAG_enable_embedded_constant_pool) { Register constant_pool_reg = StubFailureTrampolineFrame::constant_pool_pointer_register(); intptr_t constant_pool_value = reinterpret_cast<intptr_t>(trampoline->constant_pool()); output_frame->SetConstantPool(constant_pool_value); output_frame->SetRegister(constant_pool_reg.code(), constant_pool_value); } output_frame->SetState(Smi::FromInt(FullCodeGenerator::NO_REGISTERS)); Code* notify_failure = isolate_->builtins()->builtin(Builtins::kNotifyStubFailureSaveDoubles); output_frame->SetContinuation( reinterpret_cast<intptr_t>(notify_failure->entry())); } void Deoptimizer::MaterializeHeapObjects(JavaScriptFrameIterator* it) { DCHECK_NE(DEBUGGER, bailout_type_); // Walk to the last JavaScript output frame to find out if it has // adapted arguments. for (int frame_index = 0; frame_index < jsframe_count(); ++frame_index) { if (frame_index != 0) it->Advance(); } translated_state_.Prepare(it->frame()->has_adapted_arguments(), stack_fp_); for (auto& materialization : values_to_materialize_) { Handle<Object> value = materialization.value_->GetValue(); if (trace_scope_ != nullptr) { PrintF("Materialization [0x%08" V8PRIxPTR "] <- 0x%08" V8PRIxPTR " ; ", reinterpret_cast<intptr_t>(materialization.output_slot_address_), reinterpret_cast<intptr_t>(*value)); value->ShortPrint(trace_scope_->file()); PrintF(trace_scope_->file(), "\n"); } *(reinterpret_cast<intptr_t*>(materialization.output_slot_address_)) = reinterpret_cast<intptr_t>(*value); } isolate_->materialized_object_store()->Remove(stack_fp_); } void Deoptimizer::MaterializeHeapNumbersForDebuggerInspectableFrame( int frame_index, int parameter_count, int expression_count, DeoptimizedFrameInfo* info) { CHECK_EQ(DEBUGGER, bailout_type_); translated_state_.Prepare(false, nullptr); TranslatedFrame* frame = &(translated_state_.frames()[frame_index]); CHECK(frame->kind() == TranslatedFrame::kFunction); int frame_arg_count = frame->shared_info()->internal_formal_parameter_count(); // The height is #expressions + 1 for context. CHECK_EQ(expression_count + 1, frame->height()); TranslatedFrame* argument_frame = frame; if (frame_index > 0) { TranslatedFrame* previous_frame = &(translated_state_.frames()[frame_index - 1]); if (previous_frame->kind() == TranslatedFrame::kArgumentsAdaptor) { argument_frame = previous_frame; CHECK_EQ(parameter_count, argument_frame->height() - 1); } else { CHECK_EQ(frame_arg_count, parameter_count); } } else { CHECK_EQ(frame_arg_count, parameter_count); } TranslatedFrame::iterator arg_iter = argument_frame->begin(); arg_iter++; // Skip the function. arg_iter++; // Skip the receiver. for (int i = 0; i < parameter_count; i++, arg_iter++) { if (!arg_iter->IsMaterializedObject()) { info->SetParameter(i, *(arg_iter->GetValue())); } } TranslatedFrame::iterator iter = frame->begin(); // Skip the function, receiver, context and arguments. for (int i = 0; i < frame_arg_count + 3; i++, iter++) { } for (int i = 0; i < expression_count; i++, iter++) { if (!iter->IsMaterializedObject()) { info->SetExpression(i, *(iter->GetValue())); } } } void Deoptimizer::WriteTranslatedValueToOutput( TranslatedFrame::iterator* iterator, int* input_index, int frame_index, unsigned output_offset, const char* debug_hint_string, Address output_address_for_materialization) { Object* value = (*iterator)->GetRawValue(); WriteValueToOutput(value, *input_index, frame_index, output_offset, debug_hint_string); if (value == isolate_->heap()->arguments_marker()) { Address output_address = reinterpret_cast<Address>(output_[frame_index]->GetTop()) + output_offset; if (output_address_for_materialization == nullptr) { output_address_for_materialization = output_address; } values_to_materialize_.push_back( {output_address_for_materialization, *iterator}); } (*iterator)++; (*input_index)++; } void Deoptimizer::WriteValueToOutput(Object* value, int input_index, int frame_index, unsigned output_offset, const char* debug_hint_string) { output_[frame_index]->SetFrameSlot(output_offset, reinterpret_cast<intptr_t>(value)); if (trace_scope_ != nullptr) { DebugPrintOutputSlot(reinterpret_cast<intptr_t>(value), frame_index, output_offset, debug_hint_string); value->ShortPrint(trace_scope_->file()); PrintF(trace_scope_->file(), " (input #%d)\n", input_index); } } void Deoptimizer::DebugPrintOutputSlot(intptr_t value, int frame_index, unsigned output_offset, const char* debug_hint_string) { if (trace_scope_ != nullptr) { Address output_address = reinterpret_cast<Address>(output_[frame_index]->GetTop()) + output_offset; PrintF(trace_scope_->file(), " 0x%08" V8PRIxPTR ": [top + %d] <- 0x%08" V8PRIxPTR " ; %s", reinterpret_cast<intptr_t>(output_address), output_offset, value, debug_hint_string == nullptr ? "" : debug_hint_string); } } unsigned Deoptimizer::ComputeInputFrameSize() const { unsigned fixed_size = ComputeJavascriptFixedSize(function_); // The fp-to-sp delta already takes the context, constant pool pointer and the // function into account so we have to avoid double counting them. unsigned result = fixed_size + fp_to_sp_delta_ - StandardFrameConstants::kFixedFrameSizeFromFp; if (compiled_code_->kind() == Code::OPTIMIZED_FUNCTION) { unsigned stack_slots = compiled_code_->stack_slots(); unsigned outgoing_size = ComputeOutgoingArgumentSize(compiled_code_, bailout_id_); CHECK(result == fixed_size + (stack_slots * kPointerSize) + outgoing_size); } return result; } unsigned Deoptimizer::ComputeJavascriptFixedSize(JSFunction* function) const { // The fixed part of the frame consists of the return address, frame // pointer, function, context, and all the incoming arguments. return ComputeIncomingArgumentSize(function) + StandardFrameConstants::kFixedFrameSize; } unsigned Deoptimizer::ComputeInterpretedFixedSize(JSFunction* function) const { // The fixed part of the frame consists of the return address, frame // pointer, function, context, new.target, bytecode offset and all the // incoming arguments. return ComputeIncomingArgumentSize(function) + InterpreterFrameConstants::kFixedFrameSize; } unsigned Deoptimizer::ComputeIncomingArgumentSize(JSFunction* function) const { // The incoming arguments is the values for formal parameters and // the receiver. Every slot contains a pointer. if (function->IsSmi()) { CHECK_EQ(Smi::cast(function), Smi::FromInt(StackFrame::STUB)); return 0; } unsigned arguments = function->shared()->internal_formal_parameter_count() + 1; return arguments * kPointerSize; } // static unsigned Deoptimizer::ComputeOutgoingArgumentSize(Code* code, unsigned bailout_id) { DeoptimizationInputData* data = DeoptimizationInputData::cast(code->deoptimization_data()); unsigned height = data->ArgumentsStackHeight(bailout_id)->value(); return height * kPointerSize; } Object* Deoptimizer::ComputeLiteral(int index) const { DeoptimizationInputData* data = DeoptimizationInputData::cast(compiled_code_->deoptimization_data()); FixedArray* literals = data->LiteralArray(); return literals->get(index); } void Deoptimizer::EnsureCodeForDeoptimizationEntry(Isolate* isolate, BailoutType type, int max_entry_id) { // We cannot run this if the serializer is enabled because this will // cause us to emit relocation information for the external // references. This is fine because the deoptimizer's code section // isn't meant to be serialized at all. CHECK(type == EAGER || type == SOFT || type == LAZY); DeoptimizerData* data = isolate->deoptimizer_data(); int entry_count = data->deopt_entry_code_entries_[type]; if (max_entry_id < entry_count) return; entry_count = Max(entry_count, Deoptimizer::kMinNumberOfEntries); while (max_entry_id >= entry_count) entry_count *= 2; CHECK(entry_count <= Deoptimizer::kMaxNumberOfEntries); MacroAssembler masm(isolate, NULL, 16 * KB, CodeObjectRequired::kYes); masm.set_emit_debug_code(false); GenerateDeoptimizationEntries(&masm, entry_count, type); CodeDesc desc; masm.GetCode(&desc); DCHECK(!RelocInfo::RequiresRelocation(desc)); MemoryChunk* chunk = data->deopt_entry_code_[type]; CHECK(static_cast<int>(Deoptimizer::GetMaxDeoptTableSize()) >= desc.instr_size); if (!chunk->CommitArea(desc.instr_size)) { V8::FatalProcessOutOfMemory( "Deoptimizer::EnsureCodeForDeoptimizationEntry"); } CopyBytes(chunk->area_start(), desc.buffer, static_cast<size_t>(desc.instr_size)); Assembler::FlushICache(isolate, chunk->area_start(), desc.instr_size); data->deopt_entry_code_entries_[type] = entry_count; } FrameDescription::FrameDescription(uint32_t frame_size, JSFunction* function) : frame_size_(frame_size), function_(function), top_(kZapUint32), pc_(kZapUint32), fp_(kZapUint32), context_(kZapUint32), constant_pool_(kZapUint32) { // Zap all the registers. for (int r = 0; r < Register::kNumRegisters; r++) { // TODO(jbramley): It isn't safe to use kZapUint32 here. If the register // isn't used before the next safepoint, the GC will try to scan it as a // tagged value. kZapUint32 looks like a valid tagged pointer, but it isn't. SetRegister(r, kZapUint32); } // Zap all the slots. for (unsigned o = 0; o < frame_size; o += kPointerSize) { SetFrameSlot(o, kZapUint32); } } int FrameDescription::ComputeFixedSize() { if (type_ == StackFrame::INTERPRETED) { return InterpreterFrameConstants::kFixedFrameSize + (ComputeParametersCount() + 1) * kPointerSize; } else { return StandardFrameConstants::kFixedFrameSize + (ComputeParametersCount() + 1) * kPointerSize; } } unsigned FrameDescription::GetOffsetFromSlotIndex(int slot_index) { if (slot_index >= 0) { // Local or spill slots. Skip the fixed part of the frame // including all arguments. unsigned base = GetFrameSize() - ComputeFixedSize(); return base - ((slot_index + 1) * kPointerSize); } else { // Incoming parameter. int arg_size = (ComputeParametersCount() + 1) * kPointerSize; unsigned base = GetFrameSize() - arg_size; return base - ((slot_index + 1) * kPointerSize); } } int FrameDescription::ComputeParametersCount() { switch (type_) { case StackFrame::JAVA_SCRIPT: return function_->shared()->internal_formal_parameter_count(); case StackFrame::ARGUMENTS_ADAPTOR: { // Last slot contains number of incomming arguments as a smi. // Can't use GetExpression(0) because it would cause infinite recursion. return reinterpret_cast<Smi*>(*GetFrameSlotPointer(0))->value(); } case StackFrame::STUB: return -1; // Minus receiver. default: FATAL("Unexpected stack frame type"); return 0; } } Object* FrameDescription::GetParameter(int index) { CHECK_GE(index, 0); CHECK_LT(index, ComputeParametersCount()); // The slot indexes for incoming arguments are negative. unsigned offset = GetOffsetFromSlotIndex(index - ComputeParametersCount()); return reinterpret_cast<Object*>(*GetFrameSlotPointer(offset)); } unsigned FrameDescription::GetExpressionCount() { CHECK_EQ(StackFrame::JAVA_SCRIPT, type_); unsigned size = GetFrameSize() - ComputeFixedSize(); return size / kPointerSize; } Object* FrameDescription::GetExpression(int index) { DCHECK_EQ(StackFrame::JAVA_SCRIPT, type_); unsigned offset = GetOffsetFromSlotIndex(index); return reinterpret_cast<Object*>(*GetFrameSlotPointer(offset)); } void TranslationBuffer::Add(int32_t value, Zone* zone) { // This wouldn't handle kMinInt correctly if it ever encountered it. DCHECK(value != kMinInt); // Encode the sign bit in the least significant bit. bool is_negative = (value < 0); uint32_t bits = ((is_negative ? -value : value) << 1) | static_cast<int32_t>(is_negative); // Encode the individual bytes using the least significant bit of // each byte to indicate whether or not more bytes follow. do { uint32_t next = bits >> 7; contents_.Add(((bits << 1) & 0xFF) | (next != 0), zone); bits = next; } while (bits != 0); } int32_t TranslationIterator::Next() { // Run through the bytes until we reach one with a least significant // bit of zero (marks the end). uint32_t bits = 0; for (int i = 0; true; i += 7) { DCHECK(HasNext()); uint8_t next = buffer_->get(index_++); bits |= (next >> 1) << i; if ((next & 1) == 0) break; } // The bits encode the sign in the least significant bit. bool is_negative = (bits & 1) == 1; int32_t result = bits >> 1; return is_negative ? -result : result; } Handle<ByteArray> TranslationBuffer::CreateByteArray(Factory* factory) { int length = contents_.length(); Handle<ByteArray> result = factory->NewByteArray(length, TENURED); MemCopy(result->GetDataStartAddress(), contents_.ToVector().start(), length); return result; } void Translation::BeginConstructStubFrame(int literal_id, unsigned height) { buffer_->Add(CONSTRUCT_STUB_FRAME, zone()); buffer_->Add(literal_id, zone()); buffer_->Add(height, zone()); } void Translation::BeginGetterStubFrame(int literal_id) { buffer_->Add(GETTER_STUB_FRAME, zone()); buffer_->Add(literal_id, zone()); } void Translation::BeginSetterStubFrame(int literal_id) { buffer_->Add(SETTER_STUB_FRAME, zone()); buffer_->Add(literal_id, zone()); } void Translation::BeginArgumentsAdaptorFrame(int literal_id, unsigned height) { buffer_->Add(ARGUMENTS_ADAPTOR_FRAME, zone()); buffer_->Add(literal_id, zone()); buffer_->Add(height, zone()); } void Translation::BeginJSFrame(BailoutId node_id, int literal_id, unsigned height) { buffer_->Add(JS_FRAME, zone()); buffer_->Add(node_id.ToInt(), zone()); buffer_->Add(literal_id, zone()); buffer_->Add(height, zone()); } void Translation::BeginInterpretedFrame(BailoutId bytecode_offset, int literal_id, unsigned height) { buffer_->Add(INTERPRETED_FRAME, zone()); buffer_->Add(bytecode_offset.ToInt(), zone()); buffer_->Add(literal_id, zone()); buffer_->Add(height, zone()); } void Translation::BeginCompiledStubFrame(int height) { buffer_->Add(COMPILED_STUB_FRAME, zone()); buffer_->Add(height, zone()); } void Translation::BeginArgumentsObject(int args_length) { buffer_->Add(ARGUMENTS_OBJECT, zone()); buffer_->Add(args_length, zone()); } void Translation::BeginCapturedObject(int length) { buffer_->Add(CAPTURED_OBJECT, zone()); buffer_->Add(length, zone()); } void Translation::DuplicateObject(int object_index) { buffer_->Add(DUPLICATED_OBJECT, zone()); buffer_->Add(object_index, zone()); } void Translation::StoreRegister(Register reg) { buffer_->Add(REGISTER, zone()); buffer_->Add(reg.code(), zone()); } void Translation::StoreInt32Register(Register reg) { buffer_->Add(INT32_REGISTER, zone()); buffer_->Add(reg.code(), zone()); } void Translation::StoreUint32Register(Register reg) { buffer_->Add(UINT32_REGISTER, zone()); buffer_->Add(reg.code(), zone()); } void Translation::StoreBoolRegister(Register reg) { buffer_->Add(BOOL_REGISTER, zone()); buffer_->Add(reg.code(), zone()); } void Translation::StoreDoubleRegister(DoubleRegister reg) { buffer_->Add(DOUBLE_REGISTER, zone()); buffer_->Add(reg.code(), zone()); } void Translation::StoreStackSlot(int index) { buffer_->Add(STACK_SLOT, zone()); buffer_->Add(index, zone()); } void Translation::StoreInt32StackSlot(int index) { buffer_->Add(INT32_STACK_SLOT, zone()); buffer_->Add(index, zone()); } void Translation::StoreUint32StackSlot(int index) { buffer_->Add(UINT32_STACK_SLOT, zone()); buffer_->Add(index, zone()); } void Translation::StoreBoolStackSlot(int index) { buffer_->Add(BOOL_STACK_SLOT, zone()); buffer_->Add(index, zone()); } void Translation::StoreDoubleStackSlot(int index) { buffer_->Add(DOUBLE_STACK_SLOT, zone()); buffer_->Add(index, zone()); } void Translation::StoreLiteral(int literal_id) { buffer_->Add(LITERAL, zone()); buffer_->Add(literal_id, zone()); } void Translation::StoreArgumentsObject(bool args_known, int args_index, int args_length) { buffer_->Add(ARGUMENTS_OBJECT, zone()); buffer_->Add(args_known, zone()); buffer_->Add(args_index, zone()); buffer_->Add(args_length, zone()); } void Translation::StoreJSFrameFunction() { buffer_->Add(JS_FRAME_FUNCTION, zone()); } int Translation::NumberOfOperandsFor(Opcode opcode) { switch (opcode) { case JS_FRAME_FUNCTION: return 0; case GETTER_STUB_FRAME: case SETTER_STUB_FRAME: case DUPLICATED_OBJECT: case ARGUMENTS_OBJECT: case CAPTURED_OBJECT: case REGISTER: case INT32_REGISTER: case UINT32_REGISTER: case BOOL_REGISTER: case DOUBLE_REGISTER: case STACK_SLOT: case INT32_STACK_SLOT: case UINT32_STACK_SLOT: case BOOL_STACK_SLOT: case DOUBLE_STACK_SLOT: case LITERAL: case COMPILED_STUB_FRAME: return 1; case BEGIN: case ARGUMENTS_ADAPTOR_FRAME: case CONSTRUCT_STUB_FRAME: return 2; case JS_FRAME: case INTERPRETED_FRAME: return 3; } FATAL("Unexpected translation type"); return -1; } #if defined(OBJECT_PRINT) || defined(ENABLE_DISASSEMBLER) const char* Translation::StringFor(Opcode opcode) { #define TRANSLATION_OPCODE_CASE(item) case item: return #item; switch (opcode) { TRANSLATION_OPCODE_LIST(TRANSLATION_OPCODE_CASE) } #undef TRANSLATION_OPCODE_CASE UNREACHABLE(); return ""; } #endif Handle<FixedArray> MaterializedObjectStore::Get(Address fp) { int index = StackIdToIndex(fp); if (index == -1) { return Handle<FixedArray>::null(); } Handle<FixedArray> array = GetStackEntries(); CHECK_GT(array->length(), index); return Handle<FixedArray>::cast(Handle<Object>(array->get(index), isolate())); } void MaterializedObjectStore::Set(Address fp, Handle<FixedArray> materialized_objects) { int index = StackIdToIndex(fp); if (index == -1) { index = frame_fps_.length(); frame_fps_.Add(fp); } Handle<FixedArray> array = EnsureStackEntries(index + 1); array->set(index, *materialized_objects); } bool MaterializedObjectStore::Remove(Address fp) { int index = StackIdToIndex(fp); if (index == -1) { return false; } CHECK_GE(index, 0); frame_fps_.Remove(index); FixedArray* array = isolate()->heap()->materialized_objects(); CHECK_LT(index, array->length()); for (int i = index; i < frame_fps_.length(); i++) { array->set(i, array->get(i + 1)); } array->set(frame_fps_.length(), isolate()->heap()->undefined_value()); return true; } int MaterializedObjectStore::StackIdToIndex(Address fp) { for (int i = 0; i < frame_fps_.length(); i++) { if (frame_fps_[i] == fp) { return i; } } return -1; } Handle<FixedArray> MaterializedObjectStore::GetStackEntries() { return Handle<FixedArray>(isolate()->heap()->materialized_objects()); } Handle<FixedArray> MaterializedObjectStore::EnsureStackEntries(int length) { Handle<FixedArray> array = GetStackEntries(); if (array->length() >= length) { return array; } int new_length = length > 10 ? length : 10; if (new_length < 2 * array->length()) { new_length = 2 * array->length(); } Handle<FixedArray> new_array = isolate()->factory()->NewFixedArray(new_length, TENURED); for (int i = 0; i < array->length(); i++) { new_array->set(i, array->get(i)); } for (int i = array->length(); i < length; i++) { new_array->set(i, isolate()->heap()->undefined_value()); } isolate()->heap()->SetRootMaterializedObjects(*new_array); return new_array; } DeoptimizedFrameInfo::DeoptimizedFrameInfo(Deoptimizer* deoptimizer, int frame_index, bool has_arguments_adaptor, bool has_construct_stub) { FrameDescription* output_frame = deoptimizer->output_[frame_index]; function_ = output_frame->GetFunction(); context_ = reinterpret_cast<Object*>(output_frame->GetContext()); has_construct_stub_ = has_construct_stub; expression_count_ = output_frame->GetExpressionCount(); expression_stack_ = new Object* [expression_count_]; // Get the source position using the unoptimized code. Address pc = reinterpret_cast<Address>(output_frame->GetPc()); Code* code = Code::cast(deoptimizer->isolate()->FindCodeObject(pc)); source_position_ = code->SourcePosition(pc); for (int i = 0; i < expression_count_; i++) { Object* value = output_frame->GetExpression(i); // Replace materialization markers with the undefined value. if (value == deoptimizer->isolate()->heap()->arguments_marker()) { value = deoptimizer->isolate()->heap()->undefined_value(); } SetExpression(i, value); } if (has_arguments_adaptor) { output_frame = deoptimizer->output_[frame_index - 1]; CHECK_EQ(output_frame->GetFrameType(), StackFrame::ARGUMENTS_ADAPTOR); } parameters_count_ = output_frame->ComputeParametersCount(); parameters_ = new Object* [parameters_count_]; for (int i = 0; i < parameters_count_; i++) { Object* value = output_frame->GetParameter(i); // Replace materialization markers with the undefined value. if (value == deoptimizer->isolate()->heap()->arguments_marker()) { value = deoptimizer->isolate()->heap()->undefined_value(); } SetParameter(i, value); } } DeoptimizedFrameInfo::~DeoptimizedFrameInfo() { delete[] expression_stack_; delete[] parameters_; } void DeoptimizedFrameInfo::Iterate(ObjectVisitor* v) { v->VisitPointer(bit_cast<Object**>(&function_)); v->VisitPointer(&context_); v->VisitPointers(parameters_, parameters_ + parameters_count_); v->VisitPointers(expression_stack_, expression_stack_ + expression_count_); } const char* Deoptimizer::GetDeoptReason(DeoptReason deopt_reason) { DCHECK(deopt_reason < kLastDeoptReason); #define DEOPT_MESSAGES_TEXTS(C, T) T, static const char* deopt_messages_[] = { DEOPT_MESSAGES_LIST(DEOPT_MESSAGES_TEXTS)}; #undef DEOPT_MESSAGES_TEXTS return deopt_messages_[deopt_reason]; } Deoptimizer::DeoptInfo Deoptimizer::GetDeoptInfo(Code* code, Address pc) { SourcePosition last_position = SourcePosition::Unknown(); Deoptimizer::DeoptReason last_reason = Deoptimizer::kNoReason; int mask = RelocInfo::ModeMask(RelocInfo::DEOPT_REASON) | RelocInfo::ModeMask(RelocInfo::POSITION); for (RelocIterator it(code, mask); !it.done(); it.next()) { RelocInfo* info = it.rinfo(); if (info->pc() >= pc) return DeoptInfo(last_position, NULL, last_reason); if (info->rmode() == RelocInfo::POSITION) { int raw_position = static_cast<int>(info->data()); last_position = raw_position ? SourcePosition::FromRaw(raw_position) : SourcePosition::Unknown(); } else if (info->rmode() == RelocInfo::DEOPT_REASON) { last_reason = static_cast<Deoptimizer::DeoptReason>(info->data()); } } return DeoptInfo(SourcePosition::Unknown(), NULL, Deoptimizer::kNoReason); } // static TranslatedValue TranslatedValue::NewArgumentsObject(TranslatedState* container, int length, int object_index) { TranslatedValue slot(container, kArgumentsObject); slot.materialization_info_ = {object_index, length}; return slot; } // static TranslatedValue TranslatedValue::NewDeferredObject(TranslatedState* container, int length, int object_index) { TranslatedValue slot(container, kCapturedObject); slot.materialization_info_ = {object_index, length}; return slot; } // static TranslatedValue TranslatedValue::NewDuplicateObject(TranslatedState* container, int id) { TranslatedValue slot(container, kDuplicatedObject); slot.materialization_info_ = {id, -1}; return slot; } // static TranslatedValue TranslatedValue::NewDouble(TranslatedState* container, double value) { TranslatedValue slot(container, kDouble); slot.double_value_ = value; return slot; } // static TranslatedValue TranslatedValue::NewInt32(TranslatedState* container, int32_t value) { TranslatedValue slot(container, kInt32); slot.int32_value_ = value; return slot; } // static TranslatedValue TranslatedValue::NewUInt32(TranslatedState* container, uint32_t value) { TranslatedValue slot(container, kUInt32); slot.uint32_value_ = value; return slot; } // static TranslatedValue TranslatedValue::NewBool(TranslatedState* container, uint32_t value) { TranslatedValue slot(container, kBoolBit); slot.uint32_value_ = value; return slot; } // static TranslatedValue TranslatedValue::NewTagged(TranslatedState* container, Object* literal) { TranslatedValue slot(container, kTagged); slot.raw_literal_ = literal; return slot; } // static TranslatedValue TranslatedValue::NewInvalid(TranslatedState* container) { return TranslatedValue(container, kInvalid); } Isolate* TranslatedValue::isolate() const { return container_->isolate(); } Object* TranslatedValue::raw_literal() const { DCHECK_EQ(kTagged, kind()); return raw_literal_; } int32_t TranslatedValue::int32_value() const { DCHECK_EQ(kInt32, kind()); return int32_value_; } uint32_t TranslatedValue::uint32_value() const { DCHECK(kind() == kUInt32 || kind() == kBoolBit); return uint32_value_; } double TranslatedValue::double_value() const { DCHECK_EQ(kDouble, kind()); return double_value_; } int TranslatedValue::object_length() const { DCHECK(kind() == kArgumentsObject || kind() == kCapturedObject); return materialization_info_.length_; } int TranslatedValue::object_index() const { DCHECK(kind() == kArgumentsObject || kind() == kCapturedObject || kind() == kDuplicatedObject); return materialization_info_.id_; } Object* TranslatedValue::GetRawValue() const { // If we have a value, return it. Handle<Object> result_handle; if (value_.ToHandle(&result_handle)) { return *result_handle; } // Otherwise, do a best effort to get the value without allocation. switch (kind()) { case kTagged: return raw_literal(); case kInt32: { bool is_smi = Smi::IsValid(int32_value()); if (is_smi) { return Smi::FromInt(int32_value()); } break; } case kUInt32: { bool is_smi = (uint32_value() <= static_cast<uintptr_t>(Smi::kMaxValue)); if (is_smi) { return Smi::FromInt(static_cast<int32_t>(uint32_value())); } break; } case kBoolBit: { if (uint32_value() == 0) { return isolate()->heap()->false_value(); } else { CHECK_EQ(1U, uint32_value()); return isolate()->heap()->true_value(); } } default: break; } // If we could not get the value without allocation, return the arguments // marker. return isolate()->heap()->arguments_marker(); } Handle<Object> TranslatedValue::GetValue() { Handle<Object> result; // If we already have a value, then get it. if (value_.ToHandle(&result)) return result; // Otherwise we have to materialize. switch (kind()) { case TranslatedValue::kTagged: case TranslatedValue::kInt32: case TranslatedValue::kUInt32: case TranslatedValue::kBoolBit: case TranslatedValue::kDouble: { MaterializeSimple(); return value_.ToHandleChecked(); } case TranslatedValue::kArgumentsObject: case TranslatedValue::kCapturedObject: case TranslatedValue::kDuplicatedObject: return container_->MaterializeObjectAt(object_index()); case TranslatedValue::kInvalid: FATAL("unexpected case"); return Handle<Object>::null(); } FATAL("internal error: value missing"); return Handle<Object>::null(); } void TranslatedValue::MaterializeSimple() { // If we already have materialized, return. if (!value_.is_null()) return; Object* raw_value = GetRawValue(); if (raw_value != isolate()->heap()->arguments_marker()) { // We can get the value without allocation, just return it here. value_ = Handle<Object>(raw_value, isolate()); return; } switch (kind()) { case kInt32: { value_ = Handle<Object>(isolate()->factory()->NewNumber(int32_value())); return; } case kUInt32: value_ = Handle<Object>(isolate()->factory()->NewNumber(uint32_value())); return; case kDouble: value_ = Handle<Object>(isolate()->factory()->NewNumber(double_value())); return; case kCapturedObject: case kDuplicatedObject: case kArgumentsObject: case kInvalid: case kTagged: case kBoolBit: FATAL("internal error: unexpected materialization."); break; } } bool TranslatedValue::IsMaterializedObject() const { switch (kind()) { case kCapturedObject: case kDuplicatedObject: case kArgumentsObject: return true; default: return false; } } int TranslatedValue::GetChildrenCount() const { if (kind() == kCapturedObject || kind() == kArgumentsObject) { return object_length(); } else { return 0; } } uint32_t TranslatedState::GetUInt32Slot(Address fp, int slot_offset) { Address address = fp + slot_offset; #if V8_TARGET_BIG_ENDIAN && V8_HOST_ARCH_64_BIT return Memory::uint32_at(address + kIntSize); #else return Memory::uint32_at(address); #endif } void TranslatedValue::Handlify() { if (kind() == kTagged) { value_ = Handle<Object>(raw_literal(), isolate()); raw_literal_ = nullptr; } } TranslatedFrame TranslatedFrame::JSFrame(BailoutId node_id, SharedFunctionInfo* shared_info, int height) { TranslatedFrame frame(kFunction, shared_info->GetIsolate(), shared_info, height); frame.node_id_ = node_id; return frame; } TranslatedFrame TranslatedFrame::InterpretedFrame( BailoutId bytecode_offset, SharedFunctionInfo* shared_info, int height) { TranslatedFrame frame(kInterpretedFunction, shared_info->GetIsolate(), shared_info, height); frame.node_id_ = bytecode_offset; return frame; } TranslatedFrame TranslatedFrame::AccessorFrame( Kind kind, SharedFunctionInfo* shared_info) { DCHECK(kind == kSetter || kind == kGetter); return TranslatedFrame(kind, shared_info->GetIsolate(), shared_info); } TranslatedFrame TranslatedFrame::ArgumentsAdaptorFrame( SharedFunctionInfo* shared_info, int height) { return TranslatedFrame(kArgumentsAdaptor, shared_info->GetIsolate(), shared_info, height); } TranslatedFrame TranslatedFrame::ConstructStubFrame( SharedFunctionInfo* shared_info, int height) { return TranslatedFrame(kConstructStub, shared_info->GetIsolate(), shared_info, height); } int TranslatedFrame::GetValueCount() { switch (kind()) { case kFunction: { int parameter_count = raw_shared_info_->internal_formal_parameter_count() + 1; // + 1 for function. return height_ + parameter_count + 1; } case kInterpretedFunction: { int parameter_count = raw_shared_info_->internal_formal_parameter_count() + 1; // + 3 for function, context and accumulator. return height_ + parameter_count + 3; } case kGetter: return 2; // Function and receiver. case kSetter: return 3; // Function, receiver and the value to set. case kArgumentsAdaptor: case kConstructStub: return 1 + height_; case kCompiledStub: return height_; case kInvalid: UNREACHABLE(); break; } UNREACHABLE(); return -1; } void TranslatedFrame::Handlify() { if (raw_shared_info_ != nullptr) { shared_info_ = Handle<SharedFunctionInfo>(raw_shared_info_); raw_shared_info_ = nullptr; } for (auto& value : values_) { value.Handlify(); } } TranslatedFrame TranslatedState::CreateNextTranslatedFrame( TranslationIterator* iterator, FixedArray* literal_array, Address fp, FILE* trace_file) { Translation::Opcode opcode = static_cast<Translation::Opcode>(iterator->Next()); switch (opcode) { case Translation::JS_FRAME: { BailoutId node_id = BailoutId(iterator->Next()); SharedFunctionInfo* shared_info = SharedFunctionInfo::cast(literal_array->get(iterator->Next())); int height = iterator->Next(); if (trace_file != nullptr) { base::SmartArrayPointer<char> name = shared_info->DebugName()->ToCString(); PrintF(trace_file, " reading input frame %s", name.get()); int arg_count = shared_info->internal_formal_parameter_count() + 1; PrintF(trace_file, " => node=%d, args=%d, height=%d; inputs:\n", node_id.ToInt(), arg_count, height); } return TranslatedFrame::JSFrame(node_id, shared_info, height); } case Translation::INTERPRETED_FRAME: { BailoutId bytecode_offset = BailoutId(iterator->Next()); SharedFunctionInfo* shared_info = SharedFunctionInfo::cast(literal_array->get(iterator->Next())); int height = iterator->Next(); if (trace_file != nullptr) { base::SmartArrayPointer<char> name = shared_info->DebugName()->ToCString(); PrintF(trace_file, " reading input frame %s", name.get()); int arg_count = shared_info->internal_formal_parameter_count() + 1; PrintF(trace_file, " => bytecode_offset=%d, args=%d, height=%d; inputs:\n", bytecode_offset.ToInt(), arg_count, height); } return TranslatedFrame::InterpretedFrame(bytecode_offset, shared_info, height); } case Translation::ARGUMENTS_ADAPTOR_FRAME: { SharedFunctionInfo* shared_info = SharedFunctionInfo::cast(literal_array->get(iterator->Next())); int height = iterator->Next(); if (trace_file != nullptr) { base::SmartArrayPointer<char> name = shared_info->DebugName()->ToCString(); PrintF(trace_file, " reading arguments adaptor frame %s", name.get()); PrintF(trace_file, " => height=%d; inputs:\n", height); } return TranslatedFrame::ArgumentsAdaptorFrame(shared_info, height); } case Translation::CONSTRUCT_STUB_FRAME: { SharedFunctionInfo* shared_info = SharedFunctionInfo::cast(literal_array->get(iterator->Next())); int height = iterator->Next(); if (trace_file != nullptr) { base::SmartArrayPointer<char> name = shared_info->DebugName()->ToCString(); PrintF(trace_file, " reading construct stub frame %s", name.get()); PrintF(trace_file, " => height=%d; inputs:\n", height); } return TranslatedFrame::ConstructStubFrame(shared_info, height); } case Translation::GETTER_STUB_FRAME: { SharedFunctionInfo* shared_info = SharedFunctionInfo::cast(literal_array->get(iterator->Next())); if (trace_file != nullptr) { base::SmartArrayPointer<char> name = shared_info->DebugName()->ToCString(); PrintF(trace_file, " reading getter frame %s; inputs:\n", name.get()); } return TranslatedFrame::AccessorFrame(TranslatedFrame::kGetter, shared_info); } case Translation::SETTER_STUB_FRAME: { SharedFunctionInfo* shared_info = SharedFunctionInfo::cast(literal_array->get(iterator->Next())); if (trace_file != nullptr) { base::SmartArrayPointer<char> name = shared_info->DebugName()->ToCString(); PrintF(trace_file, " reading setter frame %s; inputs:\n", name.get()); } return TranslatedFrame::AccessorFrame(TranslatedFrame::kSetter, shared_info); } case Translation::COMPILED_STUB_FRAME: { int height = iterator->Next(); if (trace_file != nullptr) { PrintF(trace_file, " reading compiler stub frame => height=%d; inputs:\n", height); } return TranslatedFrame::CompiledStubFrame(height, literal_array->GetIsolate()); } case Translation::BEGIN: case Translation::DUPLICATED_OBJECT: case Translation::ARGUMENTS_OBJECT: case Translation::CAPTURED_OBJECT: case Translation::REGISTER: case Translation::INT32_REGISTER: case Translation::UINT32_REGISTER: case Translation::BOOL_REGISTER: case Translation::DOUBLE_REGISTER: case Translation::STACK_SLOT: case Translation::INT32_STACK_SLOT: case Translation::UINT32_STACK_SLOT: case Translation::BOOL_STACK_SLOT: case Translation::DOUBLE_STACK_SLOT: case Translation::LITERAL: case Translation::JS_FRAME_FUNCTION: break; } FATAL("We should never get here - unexpected deopt info."); return TranslatedFrame::InvalidFrame(); } // static void TranslatedFrame::AdvanceIterator( std::deque<TranslatedValue>::iterator* iter) { int values_to_skip = 1; while (values_to_skip > 0) { // Consume the current element. values_to_skip--; // Add all the children. values_to_skip += (*iter)->GetChildrenCount(); (*iter)++; } } // We can't intermix stack decoding and allocations because // deoptimization infrastracture is not GC safe. // Thus we build a temporary structure in malloced space. TranslatedValue TranslatedState::CreateNextTranslatedValue( int frame_index, int value_index, TranslationIterator* iterator, FixedArray* literal_array, Address fp, RegisterValues* registers, FILE* trace_file) { disasm::NameConverter converter; Translation::Opcode opcode = static_cast<Translation::Opcode>(iterator->Next()); switch (opcode) { case Translation::BEGIN: case Translation::JS_FRAME: case Translation::INTERPRETED_FRAME: case Translation::ARGUMENTS_ADAPTOR_FRAME: case Translation::CONSTRUCT_STUB_FRAME: case Translation::GETTER_STUB_FRAME: case Translation::SETTER_STUB_FRAME: case Translation::COMPILED_STUB_FRAME: // Peeled off before getting here. break; case Translation::DUPLICATED_OBJECT: { int object_id = iterator->Next(); if (trace_file != nullptr) { PrintF(trace_file, "duplicated object #%d", object_id); } object_positions_.push_back(object_positions_[object_id]); return TranslatedValue::NewDuplicateObject(this, object_id); } case Translation::ARGUMENTS_OBJECT: { int arg_count = iterator->Next(); int object_index = static_cast<int>(object_positions_.size()); if (trace_file != nullptr) { PrintF(trace_file, "argumets object #%d (length = %d)", object_index, arg_count); } object_positions_.push_back({frame_index, value_index}); return TranslatedValue::NewArgumentsObject(this, arg_count, object_index); } case Translation::CAPTURED_OBJECT: { int field_count = iterator->Next(); int object_index = static_cast<int>(object_positions_.size()); if (trace_file != nullptr) { PrintF(trace_file, "captured object #%d (length = %d)", object_index, field_count); } object_positions_.push_back({frame_index, value_index}); return TranslatedValue::NewDeferredObject(this, field_count, object_index); } case Translation::REGISTER: { int input_reg = iterator->Next(); if (registers == nullptr) return TranslatedValue::NewInvalid(this); intptr_t value = registers->GetRegister(input_reg); if (trace_file != nullptr) { PrintF(trace_file, "0x%08" V8PRIxPTR " ; %s ", value, converter.NameOfCPURegister(input_reg)); reinterpret_cast<Object*>(value)->ShortPrint(trace_file); } return TranslatedValue::NewTagged(this, reinterpret_cast<Object*>(value)); } case Translation::INT32_REGISTER: { int input_reg = iterator->Next(); if (registers == nullptr) return TranslatedValue::NewInvalid(this); intptr_t value = registers->GetRegister(input_reg); if (trace_file != nullptr) { PrintF(trace_file, "%" V8PRIdPTR " ; %s ", value, converter.NameOfCPURegister(input_reg)); } return TranslatedValue::NewInt32(this, static_cast<int32_t>(value)); } case Translation::UINT32_REGISTER: { int input_reg = iterator->Next(); if (registers == nullptr) return TranslatedValue::NewInvalid(this); intptr_t value = registers->GetRegister(input_reg); if (trace_file != nullptr) { PrintF(trace_file, "%" V8PRIuPTR " ; %s (uint)", value, converter.NameOfCPURegister(input_reg)); reinterpret_cast<Object*>(value)->ShortPrint(trace_file); } return TranslatedValue::NewUInt32(this, static_cast<uint32_t>(value)); } case Translation::BOOL_REGISTER: { int input_reg = iterator->Next(); if (registers == nullptr) return TranslatedValue::NewInvalid(this); intptr_t value = registers->GetRegister(input_reg); if (trace_file != nullptr) { PrintF(trace_file, "%" V8PRIdPTR " ; %s (bool)", value, converter.NameOfCPURegister(input_reg)); } return TranslatedValue::NewBool(this, static_cast<uint32_t>(value)); } case Translation::DOUBLE_REGISTER: { int input_reg = iterator->Next(); if (registers == nullptr) return TranslatedValue::NewInvalid(this); double value = registers->GetDoubleRegister(input_reg); if (trace_file != nullptr) { PrintF(trace_file, "%e ; %s (bool)", value, DoubleRegister::from_code(input_reg).ToString()); } return TranslatedValue::NewDouble(this, value); } case Translation::STACK_SLOT: { int slot_offset = OptimizedFrame::StackSlotOffsetRelativeToFp(iterator->Next()); intptr_t value = *(reinterpret_cast<intptr_t*>(fp + slot_offset)); if (trace_file != nullptr) { PrintF(trace_file, "0x%08" V8PRIxPTR " ; [fp %c %d] ", value, slot_offset < 0 ? '-' : '+', std::abs(slot_offset)); reinterpret_cast<Object*>(value)->ShortPrint(trace_file); } return TranslatedValue::NewTagged(this, reinterpret_cast<Object*>(value)); } case Translation::INT32_STACK_SLOT: { int slot_offset = OptimizedFrame::StackSlotOffsetRelativeToFp(iterator->Next()); uint32_t value = GetUInt32Slot(fp, slot_offset); if (trace_file != nullptr) { PrintF(trace_file, "%d ; (int) [fp %c %d] ", static_cast<int32_t>(value), slot_offset < 0 ? '-' : '+', std::abs(slot_offset)); } return TranslatedValue::NewInt32(this, value); } case Translation::UINT32_STACK_SLOT: { int slot_offset = OptimizedFrame::StackSlotOffsetRelativeToFp(iterator->Next()); uint32_t value = GetUInt32Slot(fp, slot_offset); if (trace_file != nullptr) { PrintF(trace_file, "%u ; (uint) [fp %c %d] ", value, slot_offset < 0 ? '-' : '+', std::abs(slot_offset)); } return TranslatedValue::NewUInt32(this, value); } case Translation::BOOL_STACK_SLOT: { int slot_offset = OptimizedFrame::StackSlotOffsetRelativeToFp(iterator->Next()); uint32_t value = GetUInt32Slot(fp, slot_offset); if (trace_file != nullptr) { PrintF(trace_file, "%u ; (bool) [fp %c %d] ", value, slot_offset < 0 ? '-' : '+', std::abs(slot_offset)); } return TranslatedValue::NewBool(this, value); } case Translation::DOUBLE_STACK_SLOT: { int slot_offset = OptimizedFrame::StackSlotOffsetRelativeToFp(iterator->Next()); double value = ReadDoubleValue(fp + slot_offset); if (trace_file != nullptr) { PrintF(trace_file, "%e ; (double) [fp %c %d] ", value, slot_offset < 0 ? '-' : '+', std::abs(slot_offset)); } return TranslatedValue::NewDouble(this, value); } case Translation::LITERAL: { int literal_index = iterator->Next(); Object* value = literal_array->get(literal_index); if (trace_file != nullptr) { PrintF(trace_file, "0x%08" V8PRIxPTR " ; (literal %d) ", reinterpret_cast<intptr_t>(value), literal_index); reinterpret_cast<Object*>(value)->ShortPrint(trace_file); } return TranslatedValue::NewTagged(this, value); } case Translation::JS_FRAME_FUNCTION: { int slot_offset = JavaScriptFrameConstants::kFunctionOffset; intptr_t value = *(reinterpret_cast<intptr_t*>(fp + slot_offset)); if (trace_file != nullptr) { PrintF(trace_file, "0x%08" V8PRIxPTR " ; (frame function) ", value); reinterpret_cast<Object*>(value)->ShortPrint(trace_file); } return TranslatedValue::NewTagged(this, reinterpret_cast<Object*>(value)); } } FATAL("We should never get here - unexpected deopt info."); return TranslatedValue(nullptr, TranslatedValue::kInvalid); } TranslatedState::TranslatedState(JavaScriptFrame* frame) : isolate_(nullptr), stack_frame_pointer_(nullptr), has_adapted_arguments_(false) { int deopt_index = Safepoint::kNoDeoptimizationIndex; DeoptimizationInputData* data = static_cast<OptimizedFrame*>(frame)->GetDeoptimizationData(&deopt_index); TranslationIterator it(data->TranslationByteArray(), data->TranslationIndex(deopt_index)->value()); Init(frame->fp(), &it, data->LiteralArray(), nullptr /* registers */, nullptr /* trace file */); } TranslatedState::TranslatedState() : isolate_(nullptr), stack_frame_pointer_(nullptr), has_adapted_arguments_(false) {} void TranslatedState::Init(Address input_frame_pointer, TranslationIterator* iterator, FixedArray* literal_array, RegisterValues* registers, FILE* trace_file) { DCHECK(frames_.empty()); isolate_ = literal_array->GetIsolate(); // Read out the 'header' translation. Translation::Opcode opcode = static_cast<Translation::Opcode>(iterator->Next()); CHECK(opcode == Translation::BEGIN); int count = iterator->Next(); iterator->Next(); // Drop JS frames count. frames_.reserve(count); std::stack<int> nested_counts; // Read the frames for (int i = 0; i < count; i++) { // Read the frame descriptor. frames_.push_back(CreateNextTranslatedFrame( iterator, literal_array, input_frame_pointer, trace_file)); TranslatedFrame& frame = frames_.back(); // Read the values. int values_to_process = frame.GetValueCount(); while (values_to_process > 0 || !nested_counts.empty()) { if (trace_file != nullptr) { if (nested_counts.empty()) { // For top level values, print the value number. PrintF(trace_file, " %3i: ", frame.GetValueCount() - values_to_process); } else { // Take care of indenting for nested values. PrintF(trace_file, " "); for (size_t j = 0; j < nested_counts.size(); j++) { PrintF(trace_file, " "); } } } TranslatedValue value = CreateNextTranslatedValue( i, static_cast<int>(frame.values_.size()), iterator, literal_array, input_frame_pointer, registers, trace_file); frame.Add(value); if (trace_file != nullptr) { PrintF(trace_file, "\n"); } // Update the value count and resolve the nesting. values_to_process--; int children_count = value.GetChildrenCount(); if (children_count > 0) { nested_counts.push(values_to_process); values_to_process = children_count; } else { while (values_to_process == 0 && !nested_counts.empty()) { values_to_process = nested_counts.top(); nested_counts.pop(); } } } } CHECK(!iterator->HasNext() || static_cast<Translation::Opcode>(iterator->Next()) == Translation::BEGIN); } void TranslatedState::Prepare(bool has_adapted_arguments, Address stack_frame_pointer) { for (auto& frame : frames_) frame.Handlify(); stack_frame_pointer_ = stack_frame_pointer; has_adapted_arguments_ = has_adapted_arguments; UpdateFromPreviouslyMaterializedObjects(); } Handle<Object> TranslatedState::MaterializeAt(int frame_index, int* value_index) { TranslatedFrame* frame = &(frames_[frame_index]); DCHECK(static_cast<size_t>(*value_index) < frame->values_.size()); TranslatedValue* slot = &(frame->values_[*value_index]); (*value_index)++; switch (slot->kind()) { case TranslatedValue::kTagged: case TranslatedValue::kInt32: case TranslatedValue::kUInt32: case TranslatedValue::kBoolBit: case TranslatedValue::kDouble: { slot->MaterializeSimple(); Handle<Object> value = slot->GetValue(); if (value->IsMutableHeapNumber()) { HeapNumber::cast(*value)->set_map(isolate()->heap()->heap_number_map()); } return value; } case TranslatedValue::kArgumentsObject: { int length = slot->GetChildrenCount(); Handle<JSObject> arguments; if (GetAdaptedArguments(&arguments, frame_index)) { // Store the materialized object and consume the nested values. for (int i = 0; i < length; ++i) { MaterializeAt(frame_index, value_index); } } else { Handle<JSFunction> function = Handle<JSFunction>::cast(frame->front().GetValue()); arguments = isolate_->factory()->NewArgumentsObject(function, length); Handle<FixedArray> array = isolate_->factory()->NewFixedArray(length); DCHECK_EQ(array->length(), length); arguments->set_elements(*array); for (int i = 0; i < length; ++i) { Handle<Object> value = MaterializeAt(frame_index, value_index); array->set(i, *value); } } slot->value_ = arguments; return arguments; } case TranslatedValue::kCapturedObject: { int length = slot->GetChildrenCount(); // The map must be a tagged object. CHECK(frame->values_[*value_index].kind() == TranslatedValue::kTagged); Handle<Object> result; if (slot->value_.ToHandle(&result)) { // This has been previously materialized, return the previous value. // We still need to skip all the nested objects. for (int i = 0; i < length; i++) { MaterializeAt(frame_index, value_index); } return result; } Handle<Object> map_object = MaterializeAt(frame_index, value_index); Handle<Map> map = Map::GeneralizeAllFieldRepresentations(Handle<Map>::cast(map_object)); switch (map->instance_type()) { case MUTABLE_HEAP_NUMBER_TYPE: case HEAP_NUMBER_TYPE: { // Reuse the HeapNumber value directly as it is already properly // tagged and skip materializing the HeapNumber explicitly. Handle<Object> object = MaterializeAt(frame_index, value_index); slot->value_ = object; // On 32-bit architectures, there is an extra slot there because // the escape analysis calculates the number of slots as // object-size/pointer-size. To account for this, we read out // any extra slots. for (int i = 0; i < length - 2; i++) { MaterializeAt(frame_index, value_index); } return object; } case JS_OBJECT_TYPE: { Handle<JSObject> object = isolate_->factory()->NewJSObjectFromMap(map, NOT_TENURED); slot->value_ = object; Handle<Object> properties = MaterializeAt(frame_index, value_index); Handle<Object> elements = MaterializeAt(frame_index, value_index); object->set_properties(FixedArray::cast(*properties)); object->set_elements(FixedArrayBase::cast(*elements)); for (int i = 0; i < length - 3; ++i) { Handle<Object> value = MaterializeAt(frame_index, value_index); FieldIndex index = FieldIndex::ForPropertyIndex(object->map(), i); object->FastPropertyAtPut(index, *value); } return object; } case JS_ARRAY_TYPE: { Handle<JSArray> object = isolate_->factory()->NewJSArray(0, map->elements_kind()); slot->value_ = object; Handle<Object> properties = MaterializeAt(frame_index, value_index); Handle<Object> elements = MaterializeAt(frame_index, value_index); Handle<Object> length = MaterializeAt(frame_index, value_index); object->set_properties(FixedArray::cast(*properties)); object->set_elements(FixedArrayBase::cast(*elements)); object->set_length(*length); return object; } case FIXED_ARRAY_TYPE: { Handle<Object> lengthObject = MaterializeAt(frame_index, value_index); int32_t length = 0; CHECK(lengthObject->ToInt32(&length)); Handle<FixedArray> object = isolate_->factory()->NewFixedArray(length); // We need to set the map, because the fixed array we are // materializing could be a context or an arguments object, // in which case we must retain that information. object->set_map(*map); slot->value_ = object; for (int i = 0; i < length; ++i) { Handle<Object> value = MaterializeAt(frame_index, value_index); object->set(i, *value); } return object; } case FIXED_DOUBLE_ARRAY_TYPE: { DCHECK_EQ(*map, isolate_->heap()->fixed_double_array_map()); Handle<Object> lengthObject = MaterializeAt(frame_index, value_index); int32_t length = 0; CHECK(lengthObject->ToInt32(&length)); Handle<FixedArrayBase> object = isolate_->factory()->NewFixedDoubleArray(length); slot->value_ = object; if (length > 0) { Handle<FixedDoubleArray> double_array = Handle<FixedDoubleArray>::cast(object); for (int i = 0; i < length; ++i) { Handle<Object> value = MaterializeAt(frame_index, value_index); CHECK(value->IsNumber()); double_array->set(i, value->Number()); } } return object; } default: PrintF(stderr, "[couldn't handle instance type %d]\n", map->instance_type()); FATAL("unreachable"); return Handle<Object>::null(); } UNREACHABLE(); break; } case TranslatedValue::kDuplicatedObject: { int object_index = slot->object_index(); TranslatedState::ObjectPosition pos = object_positions_[object_index]; // Make sure the duplicate is refering to a previous object. DCHECK(pos.frame_index_ < frame_index || (pos.frame_index_ == frame_index && pos.value_index_ < *value_index - 1)); Handle<Object> object = frames_[pos.frame_index_].values_[pos.value_index_].GetValue(); // The object should have a (non-sentinel) value. DCHECK(!object.is_null() && !object.is_identical_to(isolate_->factory()->arguments_marker())); slot->value_ = object; return object; } case TranslatedValue::kInvalid: UNREACHABLE(); break; } FATAL("We should never get here - unexpected deopt slot kind."); return Handle<Object>::null(); } Handle<Object> TranslatedState::MaterializeObjectAt(int object_index) { TranslatedState::ObjectPosition pos = object_positions_[object_index]; return MaterializeAt(pos.frame_index_, &(pos.value_index_)); } bool TranslatedState::GetAdaptedArguments(Handle<JSObject>* result, int frame_index) { if (frame_index == 0) { // Top level frame -> we need to go to the parent frame on the stack. if (!has_adapted_arguments_) return false; // This is top level frame, so we need to go to the stack to get // this function's argument. (Note that this relies on not inlining // recursive functions!) Handle<JSFunction> function = Handle<JSFunction>::cast(frames_[frame_index].front().GetValue()); *result = Handle<JSObject>::cast(Accessors::FunctionGetArguments(function)); return true; } else { TranslatedFrame* previous_frame = &(frames_[frame_index]); if (previous_frame->kind() != TranslatedFrame::kArgumentsAdaptor) { return false; } // We get the adapted arguments from the parent translation. int length = previous_frame->height(); Handle<JSFunction> function = Handle<JSFunction>::cast(previous_frame->front().GetValue()); Handle<JSObject> arguments = isolate_->factory()->NewArgumentsObject(function, length); Handle<FixedArray> array = isolate_->factory()->NewFixedArray(length); arguments->set_elements(*array); TranslatedFrame::iterator arg_iterator = previous_frame->begin(); arg_iterator++; // Skip function. for (int i = 0; i < length; ++i) { Handle<Object> value = arg_iterator->GetValue(); array->set(i, *value); arg_iterator++; } CHECK(arg_iterator == previous_frame->end()); *result = arguments; return true; } } TranslatedFrame* TranslatedState::GetArgumentsInfoFromJSFrameIndex( int jsframe_index, int* args_count) { for (size_t i = 0; i < frames_.size(); i++) { if (frames_[i].kind() == TranslatedFrame::kFunction) { if (jsframe_index > 0) { jsframe_index--; } else { // We have the JS function frame, now check if it has arguments adaptor. if (i > 0 && frames_[i - 1].kind() == TranslatedFrame::kArgumentsAdaptor) { *args_count = frames_[i - 1].height(); return &(frames_[i - 1]); } *args_count = frames_[i].shared_info()->internal_formal_parameter_count() + 1; return &(frames_[i]); } } } return nullptr; } void TranslatedState::StoreMaterializedValuesAndDeopt() { MaterializedObjectStore* materialized_store = isolate_->materialized_object_store(); Handle<FixedArray> previously_materialized_objects = materialized_store->Get(stack_frame_pointer_); Handle<Object> marker = isolate_->factory()->arguments_marker(); int length = static_cast<int>(object_positions_.size()); bool new_store = false; if (previously_materialized_objects.is_null()) { previously_materialized_objects = isolate_->factory()->NewFixedArray(length); for (int i = 0; i < length; i++) { previously_materialized_objects->set(i, *marker); } new_store = true; } DCHECK_EQ(length, previously_materialized_objects->length()); bool value_changed = false; for (int i = 0; i < length; i++) { TranslatedState::ObjectPosition pos = object_positions_[i]; TranslatedValue* value_info = &(frames_[pos.frame_index_].values_[pos.value_index_]); DCHECK(value_info->IsMaterializedObject()); Handle<Object> value(value_info->GetRawValue(), isolate_); if (!value.is_identical_to(marker)) { if (previously_materialized_objects->get(i) == *marker) { previously_materialized_objects->set(i, *value); value_changed = true; } else { DCHECK(previously_materialized_objects->get(i) == *value); } } } if (new_store && value_changed) { materialized_store->Set(stack_frame_pointer_, previously_materialized_objects); DCHECK_EQ(TranslatedFrame::kFunction, frames_[0].kind()); Object* const function = frames_[0].front().GetRawValue(); Deoptimizer::DeoptimizeFunction(JSFunction::cast(function)); } } void TranslatedState::UpdateFromPreviouslyMaterializedObjects() { MaterializedObjectStore* materialized_store = isolate_->materialized_object_store(); Handle<FixedArray> previously_materialized_objects = materialized_store->Get(stack_frame_pointer_); // If we have no previously materialized objects, there is nothing to do. if (previously_materialized_objects.is_null()) return; Handle<Object> marker = isolate_->factory()->arguments_marker(); int length = static_cast<int>(object_positions_.size()); DCHECK_EQ(length, previously_materialized_objects->length()); for (int i = 0; i < length; i++) { // For a previously materialized objects, inject their value into the // translated values. if (previously_materialized_objects->get(i) != *marker) { TranslatedState::ObjectPosition pos = object_positions_[i]; TranslatedValue* value_info = &(frames_[pos.frame_index_].values_[pos.value_index_]); DCHECK(value_info->IsMaterializedObject()); value_info->value_ = Handle<Object>(previously_materialized_objects->get(i), isolate_); } } } } // namespace internal } // namespace v8