// Copyright 2016 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/snapshot/deserializer.h" #include "src/assembler-inl.h" #include "src/heap/heap-write-barrier-inl.h" #include "src/isolate.h" #include "src/objects/api-callbacks.h" #include "src/objects/hash-table.h" #include "src/objects/js-array-buffer-inl.h" #include "src/objects/js-array-inl.h" #include "src/objects/maybe-object.h" #include "src/objects/string.h" #include "src/snapshot/builtin-deserializer-allocator.h" #include "src/snapshot/natives.h" #include "src/snapshot/snapshot.h" namespace v8 { namespace internal { template void Deserializer::Initialize(Isolate* isolate) { DCHECK_NULL(isolate_); DCHECK_NOT_NULL(isolate); isolate_ = isolate; DCHECK_NULL(external_reference_table_); external_reference_table_ = isolate->heap()->external_reference_table(); #ifdef DEBUG // Count the number of external references registered through the API. num_api_references_ = 0; if (isolate_->api_external_references() != nullptr) { while (isolate_->api_external_references()[num_api_references_] != 0) { num_api_references_++; } } #endif // DEBUG CHECK_EQ(magic_number_, SerializedData::ComputeMagicNumber(external_reference_table_)); } template bool Deserializer::IsLazyDeserializationEnabled() const { return FLAG_lazy_deserialization && !isolate()->serializer_enabled(); } template void Deserializer::Rehash() { DCHECK(can_rehash() || deserializing_user_code()); for (const auto& item : to_rehash_) item->RehashBasedOnMap(isolate()); } template Deserializer::~Deserializer() { #ifdef DEBUG // Do not perform checks if we aborted deserialization. if (source_.position() == 0) return; // Check that we only have padding bytes remaining. while (source_.HasMore()) DCHECK_EQ(kNop, source_.Get()); // Check that we've fully used all reserved space. DCHECK(allocator()->ReservationsAreFullyUsed()); #endif // DEBUG } // This is called on the roots. It is the driver of the deserialization // process. It is also called on the body of each function. template void Deserializer::VisitRootPointers(Root root, const char* description, Object** start, Object** end) { // Builtins and bytecode handlers are deserialized in a separate pass by the // BuiltinDeserializer. if (root == Root::kBuiltins || root == Root::kDispatchTable) return; // The space must be new space. Any other space would cause ReadChunk to try // to update the remembered using nullptr as the address. ReadData(reinterpret_cast(start), reinterpret_cast(end), NEW_SPACE, kNullAddress); } template void Deserializer::Synchronize( VisitorSynchronization::SyncTag tag) { static const byte expected = kSynchronize; CHECK_EQ(expected, source_.Get()); } template void Deserializer::DeserializeDeferredObjects() { for (int code = source_.Get(); code != kSynchronize; code = source_.Get()) { switch (code) { case kAlignmentPrefix: case kAlignmentPrefix + 1: case kAlignmentPrefix + 2: { int alignment = code - (SerializerDeserializer::kAlignmentPrefix - 1); allocator()->SetAlignment(static_cast(alignment)); break; } default: { int space = code & kSpaceMask; DCHECK_LE(space, kNumberOfSpaces); DCHECK_EQ(code - space, kNewObject); HeapObject* object = GetBackReferencedObject(space); int size = source_.GetInt() << kPointerSizeLog2; Address obj_address = object->address(); MaybeObject** start = reinterpret_cast(obj_address + kPointerSize); MaybeObject** end = reinterpret_cast(obj_address + size); bool filled = ReadData(start, end, space, obj_address); CHECK(filled); DCHECK(CanBeDeferred(object)); PostProcessNewObject(object, space); } } } } StringTableInsertionKey::StringTableInsertionKey(String* string) : StringTableKey(ComputeHashField(string)), string_(string) { DCHECK(string->IsInternalizedString()); } bool StringTableInsertionKey::IsMatch(Object* string) { // We know that all entries in a hash table had their hash keys created. // Use that knowledge to have fast failure. if (Hash() != String::cast(string)->Hash()) return false; // We want to compare the content of two internalized strings here. return string_->SlowEquals(String::cast(string)); } Handle StringTableInsertionKey::AsHandle(Isolate* isolate) { return handle(string_, isolate); } uint32_t StringTableInsertionKey::ComputeHashField(String* string) { // Make sure hash_field() is computed. string->Hash(); return string->hash_field(); } template HeapObject* Deserializer::PostProcessNewObject(HeapObject* obj, int space) { if ((FLAG_rehash_snapshot && can_rehash_) || deserializing_user_code()) { if (obj->IsString()) { // Uninitialize hash field as we need to recompute the hash. String* string = String::cast(obj); string->set_hash_field(String::kEmptyHashField); } else if (obj->NeedsRehashing()) { to_rehash_.push_back(obj); } } if (deserializing_user_code()) { if (obj->IsString()) { String* string = String::cast(obj); if (string->IsInternalizedString()) { // Canonicalize the internalized string. If it already exists in the // string table, set it to forward to the existing one. StringTableInsertionKey key(string); String* canonical = StringTable::ForwardStringIfExists(isolate_, &key, string); if (canonical != nullptr) return canonical; new_internalized_strings_.push_back(handle(string, isolate_)); return string; } } else if (obj->IsScript()) { new_scripts_.push_back(handle(Script::cast(obj), isolate_)); } else { DCHECK(CanBeDeferred(obj)); } } else if (obj->IsScript()) { LOG(isolate_, ScriptEvent(Logger::ScriptEventType::kDeserialize, Script::cast(obj)->id())); LOG(isolate_, ScriptDetails(Script::cast(obj))); } if (obj->IsAllocationSite()) { // Allocation sites are present in the snapshot, and must be linked into // a list at deserialization time. AllocationSite* site = AllocationSite::cast(obj); // TODO(mvstanton): consider treating the heap()->allocation_sites_list() // as a (weak) root. If this root is relocated correctly, this becomes // unnecessary. if (isolate_->heap()->allocation_sites_list() == Smi::kZero) { site->set_weak_next(ReadOnlyRoots(isolate_).undefined_value()); } else { site->set_weak_next(isolate_->heap()->allocation_sites_list()); } isolate_->heap()->set_allocation_sites_list(site); } else if (obj->IsCode()) { // We flush all code pages after deserializing the startup snapshot. In that // case, we only need to remember code objects in the large object space. // When deserializing user code, remember each individual code object. if (deserializing_user_code() || space == LO_SPACE) { new_code_objects_.push_back(Code::cast(obj)); } } else if (obj->IsAccessorInfo()) { #ifdef USE_SIMULATOR accessor_infos_.push_back(AccessorInfo::cast(obj)); #endif } else if (obj->IsCallHandlerInfo()) { #ifdef USE_SIMULATOR call_handler_infos_.push_back(CallHandlerInfo::cast(obj)); #endif } else if (obj->IsExternalString()) { if (obj->map() == ReadOnlyRoots(isolate_).native_source_string_map()) { ExternalOneByteString* string = ExternalOneByteString::cast(obj); DCHECK(string->is_short()); string->SetResource( isolate_, NativesExternalStringResource::DecodeForDeserialization( string->resource())); } else { ExternalString* string = ExternalString::cast(obj); uint32_t index = string->resource_as_uint32(); Address address = static_cast
(isolate_->api_external_references()[index]); string->set_address_as_resource(address); isolate_->heap()->UpdateExternalString(string, 0, string->ExternalPayloadSize()); } isolate_->heap()->RegisterExternalString(String::cast(obj)); } else if (obj->IsJSTypedArray()) { JSTypedArray* typed_array = JSTypedArray::cast(obj); CHECK(typed_array->byte_offset()->IsSmi()); int32_t byte_offset = NumberToInt32(typed_array->byte_offset()); if (byte_offset > 0) { FixedTypedArrayBase* elements = FixedTypedArrayBase::cast(typed_array->elements()); // Must be off-heap layout. DCHECK(!typed_array->is_on_heap()); void* pointer_with_offset = reinterpret_cast( reinterpret_cast(elements->external_pointer()) + byte_offset); elements->set_external_pointer(pointer_with_offset); } } else if (obj->IsJSArrayBuffer()) { JSArrayBuffer* buffer = JSArrayBuffer::cast(obj); // Only fixup for the off-heap case. if (buffer->backing_store() != nullptr) { Smi* store_index = reinterpret_cast(buffer->backing_store()); void* backing_store = off_heap_backing_stores_[store_index->value()]; buffer->set_backing_store(backing_store); isolate_->heap()->RegisterNewArrayBuffer(buffer); } } else if (obj->IsFixedTypedArrayBase()) { FixedTypedArrayBase* fta = FixedTypedArrayBase::cast(obj); // Only fixup for the off-heap case. if (fta->base_pointer() == nullptr) { Smi* store_index = reinterpret_cast(fta->external_pointer()); void* backing_store = off_heap_backing_stores_[store_index->value()]; fta->set_external_pointer(backing_store); } } else if (obj->IsBytecodeArray()) { // TODO(mythria): Remove these once we store the default values for these // fields in the serializer. BytecodeArray* bytecode_array = BytecodeArray::cast(obj); bytecode_array->set_interrupt_budget( interpreter::Interpreter::InterruptBudget()); bytecode_array->set_osr_loop_nesting_level(0); } // Check alignment. DCHECK_EQ(0, Heap::GetFillToAlign(obj->address(), HeapObject::RequiredAlignment(obj->map()))); return obj; } template int Deserializer::MaybeReplaceWithDeserializeLazy(int builtin_id) { DCHECK(Builtins::IsBuiltinId(builtin_id)); return IsLazyDeserializationEnabled() && Builtins::IsLazy(builtin_id) ? Builtins::kDeserializeLazy : builtin_id; } template HeapObject* Deserializer::GetBackReferencedObject(int space) { HeapObject* obj; switch (space) { case LO_SPACE: obj = allocator()->GetLargeObject(source_.GetInt()); break; case MAP_SPACE: obj = allocator()->GetMap(source_.GetInt()); break; case RO_SPACE: { uint32_t chunk_index = source_.GetInt(); uint32_t chunk_offset = source_.GetInt(); if (isolate()->heap()->deserialization_complete()) { PagedSpace* read_only_space = isolate()->heap()->read_only_space(); Page* page = read_only_space->first_page(); for (uint32_t i = 0; i < chunk_index; ++i) { page = page->next_page(); } Address address = page->OffsetToAddress(chunk_offset); obj = HeapObject::FromAddress(address); } else { obj = allocator()->GetObject(static_cast(space), chunk_index, chunk_offset); } break; } default: { uint32_t chunk_index = source_.GetInt(); uint32_t chunk_offset = source_.GetInt(); obj = allocator()->GetObject(static_cast(space), chunk_index, chunk_offset); break; } } if (deserializing_user_code() && obj->IsThinString()) { obj = ThinString::cast(obj)->actual(); } hot_objects_.Add(obj); DCHECK(!HasWeakHeapObjectTag(obj)); return obj; } // This routine writes the new object into the pointer provided. // The reason for this strange interface is that otherwise the object is // written very late, which means the FreeSpace map is not set up by the // time we need to use it to mark the space at the end of a page free. template void Deserializer::ReadObject( int space_number, MaybeObject** write_back, HeapObjectReferenceType reference_type) { const int size = source_.GetInt() << kObjectAlignmentBits; Address address = allocator()->Allocate(static_cast(space_number), size); HeapObject* obj = HeapObject::FromAddress(address); isolate_->heap()->OnAllocationEvent(obj, size); MaybeObject** current = reinterpret_cast(address); MaybeObject** limit = current + (size >> kPointerSizeLog2); if (ReadData(current, limit, space_number, address)) { // Only post process if object content has not been deferred. obj = PostProcessNewObject(obj, space_number); } MaybeObject* write_back_obj = reference_type == HeapObjectReferenceType::STRONG ? HeapObjectReference::Strong(obj) : HeapObjectReference::Weak(obj); UnalignedCopy(write_back, &write_back_obj); #ifdef DEBUG if (obj->IsCode()) { DCHECK(space_number == CODE_SPACE || space_number == LO_SPACE); } else { DCHECK(space_number != CODE_SPACE); } #endif // DEBUG } template Object* Deserializer::ReadDataSingle() { MaybeObject* o; MaybeObject** start = &o; MaybeObject** end = start + 1; int source_space = NEW_SPACE; Address current_object = kNullAddress; CHECK(ReadData(start, end, source_space, current_object)); HeapObject* heap_object; bool success = o->ToStrongHeapObject(&heap_object); DCHECK(success); USE(success); return heap_object; } static void NoExternalReferencesCallback() { // The following check will trigger if a function or object template // with references to native functions have been deserialized from // snapshot, but no actual external references were provided when the // isolate was created. CHECK_WITH_MSG(false, "No external references provided via API"); } template bool Deserializer::ReadData(MaybeObject** current, MaybeObject** limit, int source_space, Address current_object_address) { Isolate* const isolate = isolate_; // Write barrier support costs around 1% in startup time. In fact there // are no new space objects in current boot snapshots, so it's not needed, // but that may change. bool write_barrier_needed = (current_object_address != kNullAddress && source_space != NEW_SPACE && source_space != CODE_SPACE); while (current < limit) { byte data = source_.Get(); switch (data) { #define CASE_STATEMENT(where, how, within, space_number) \ case where + how + within + space_number: \ STATIC_ASSERT((where & ~kWhereMask) == 0); \ STATIC_ASSERT((how & ~kHowToCodeMask) == 0); \ STATIC_ASSERT((within & ~kWhereToPointMask) == 0); \ STATIC_ASSERT((space_number & ~kSpaceMask) == 0); #define CASE_BODY(where, how, within, space_number_if_any) \ current = ReadDataCase( \ isolate, current, current_object_address, data, write_barrier_needed); \ break; // This generates a case and a body for the new space (which has to do extra // write barrier handling) and handles the other spaces with fall-through cases // and one body. #define ALL_SPACES(where, how, within) \ CASE_STATEMENT(where, how, within, NEW_SPACE) \ CASE_BODY(where, how, within, NEW_SPACE) \ CASE_STATEMENT(where, how, within, OLD_SPACE) \ V8_FALLTHROUGH; \ CASE_STATEMENT(where, how, within, CODE_SPACE) \ V8_FALLTHROUGH; \ CASE_STATEMENT(where, how, within, MAP_SPACE) \ V8_FALLTHROUGH; \ CASE_STATEMENT(where, how, within, LO_SPACE) \ V8_FALLTHROUGH; \ CASE_STATEMENT(where, how, within, RO_SPACE) \ CASE_BODY(where, how, within, kAnyOldSpace) #define FOUR_CASES(byte_code) \ case byte_code: \ case byte_code + 1: \ case byte_code + 2: \ case byte_code + 3: #define SIXTEEN_CASES(byte_code) \ FOUR_CASES(byte_code) \ FOUR_CASES(byte_code + 4) \ FOUR_CASES(byte_code + 8) \ FOUR_CASES(byte_code + 12) #define SINGLE_CASE(where, how, within, space) \ CASE_STATEMENT(where, how, within, space) \ CASE_BODY(where, how, within, space) // Deserialize a new object and write a pointer to it to the current // object. ALL_SPACES(kNewObject, kPlain, kStartOfObject) // Deserialize a new code object and write a pointer to its first // instruction to the current code object. ALL_SPACES(kNewObject, kFromCode, kInnerPointer) // Find a recently deserialized object using its offset from the current // allocation point and write a pointer to it to the current object. ALL_SPACES(kBackref, kPlain, kStartOfObject) ALL_SPACES(kBackrefWithSkip, kPlain, kStartOfObject) #if V8_CODE_EMBEDS_OBJECT_POINTER // Deserialize a new object from pointer found in code and write // a pointer to it to the current object. Required only for MIPS, PPC, ARM // or S390 with embedded constant pool, and omitted on the other // architectures because it is fully unrolled and would cause bloat. ALL_SPACES(kNewObject, kFromCode, kStartOfObject) // Find a recently deserialized code object using its offset from the // current allocation point and write a pointer to it to the current // object. Required only for MIPS, PPC, ARM or S390 with embedded // constant pool. ALL_SPACES(kBackref, kFromCode, kStartOfObject) ALL_SPACES(kBackrefWithSkip, kFromCode, kStartOfObject) #endif // Find a recently deserialized code object using its offset from the // current allocation point and write a pointer to its first instruction // to the current code object or the instruction pointer in a function // object. ALL_SPACES(kBackref, kFromCode, kInnerPointer) ALL_SPACES(kBackrefWithSkip, kFromCode, kInnerPointer) // Find an object in the roots array and write a pointer to it to the // current object. SINGLE_CASE(kRootArray, kPlain, kStartOfObject, 0) #if V8_CODE_EMBEDS_OBJECT_POINTER // Find an object in the roots array and write a pointer to it to in code. SINGLE_CASE(kRootArray, kFromCode, kStartOfObject, 0) #endif // Find an object in the partial snapshots cache and write a pointer to it // to the current object. SINGLE_CASE(kPartialSnapshotCache, kPlain, kStartOfObject, 0) SINGLE_CASE(kPartialSnapshotCache, kFromCode, kStartOfObject, 0) SINGLE_CASE(kPartialSnapshotCache, kFromCode, kInnerPointer, 0) // Find an object in the attached references and write a pointer to it to // the current object. SINGLE_CASE(kAttachedReference, kPlain, kStartOfObject, 0) SINGLE_CASE(kAttachedReference, kFromCode, kStartOfObject, 0) SINGLE_CASE(kAttachedReference, kFromCode, kInnerPointer, 0) // Find a builtin and write a pointer to it to the current object. SINGLE_CASE(kBuiltin, kPlain, kStartOfObject, 0) SINGLE_CASE(kBuiltin, kFromCode, kStartOfObject, 0) SINGLE_CASE(kBuiltin, kFromCode, kInnerPointer, 0) #undef CASE_STATEMENT #undef CASE_BODY #undef ALL_SPACES case kSkip: { int size = source_.GetInt(); current = reinterpret_cast( reinterpret_cast
(current) + size); break; } // Find an external reference and write a pointer to it to the current // object. case kExternalReference + kPlain + kStartOfObject: current = reinterpret_cast(ReadExternalReferenceCase( kPlain, reinterpret_cast(current), current_object_address)); break; // Find an external reference and write a pointer to it in the current // code object. case kExternalReference + kFromCode + kStartOfObject: current = reinterpret_cast(ReadExternalReferenceCase( kFromCode, reinterpret_cast(current), current_object_address)); break; case kInternalReferenceEncoded: case kInternalReference: { // Internal reference address is not encoded via skip, but by offset // from code entry. int pc_offset = source_.GetInt(); int target_offset = source_.GetInt(); Code* code = Code::cast(HeapObject::FromAddress(current_object_address)); DCHECK(0 <= pc_offset && pc_offset <= code->raw_instruction_size()); DCHECK(0 <= target_offset && target_offset <= code->raw_instruction_size()); Address pc = code->entry() + pc_offset; Address target = code->entry() + target_offset; Assembler::deserialization_set_target_internal_reference_at( pc, target, data == kInternalReference ? RelocInfo::INTERNAL_REFERENCE : RelocInfo::INTERNAL_REFERENCE_ENCODED); break; } case kOffHeapTarget: { DCHECK(FLAG_embedded_builtins); int skip = source_.GetInt(); int builtin_index = source_.GetInt(); DCHECK(Builtins::IsBuiltinId(builtin_index)); current = reinterpret_cast( reinterpret_cast
(current) + skip); CHECK_NOT_NULL(isolate->embedded_blob()); EmbeddedData d = EmbeddedData::FromBlob(); Address address = d.InstructionStartOfBuiltin(builtin_index); CHECK_NE(kNullAddress, address); if (RelocInfo::OffHeapTargetIsCodedSpecially()) { Address location_of_branch_data = reinterpret_cast
(current); int skip = Assembler::deserialization_special_target_size( location_of_branch_data); Assembler::deserialization_set_special_target_at( location_of_branch_data, Code::cast(HeapObject::FromAddress(current_object_address)), address); location_of_branch_data += skip; current = reinterpret_cast(location_of_branch_data); } else { MaybeObject* o = reinterpret_cast(address); UnalignedCopy(current, &o); current++; } break; } case kNop: break; case kNextChunk: { int space = source_.Get(); allocator()->MoveToNextChunk(static_cast(space)); break; } case kDeferred: { // Deferred can only occur right after the heap object header. DCHECK_EQ(current, reinterpret_cast( current_object_address + kPointerSize)); HeapObject* obj = HeapObject::FromAddress(current_object_address); // If the deferred object is a map, its instance type may be used // during deserialization. Initialize it with a temporary value. if (obj->IsMap()) Map::cast(obj)->set_instance_type(FILLER_TYPE); current = limit; return false; } case kSynchronize: // If we get here then that indicates that you have a mismatch between // the number of GC roots when serializing and deserializing. UNREACHABLE(); // Deserialize raw data of variable length. case kVariableRawData: { int size_in_bytes = source_.GetInt(); byte* raw_data_out = reinterpret_cast(current); source_.CopyRaw(raw_data_out, size_in_bytes); current = reinterpret_cast( reinterpret_cast(current) + size_in_bytes); break; } // Deserialize raw code directly into the body of the code object. // Do not move current. case kVariableRawCode: { int size_in_bytes = source_.GetInt(); source_.CopyRaw( reinterpret_cast(current_object_address + Code::kDataStart), size_in_bytes); break; } case kVariableRepeat: { int repeats = source_.GetInt(); MaybeObject* object = current[-1]; DCHECK(!Heap::InNewSpace(object)); DCHECK(!allocator()->next_reference_is_weak()); for (int i = 0; i < repeats; i++) UnalignedCopy(current++, &object); break; } case kOffHeapBackingStore: { int byte_length = source_.GetInt(); byte* backing_store = static_cast( isolate->array_buffer_allocator()->AllocateUninitialized( byte_length)); CHECK_NOT_NULL(backing_store); source_.CopyRaw(backing_store, byte_length); off_heap_backing_stores_.push_back(backing_store); break; } case kApiReference: { int skip = source_.GetInt(); current = reinterpret_cast( reinterpret_cast
(current) + skip); uint32_t reference_id = static_cast(source_.GetInt()); Address address; if (isolate->api_external_references()) { DCHECK_WITH_MSG( reference_id < num_api_references_, "too few external references provided through the API"); address = static_cast
( isolate->api_external_references()[reference_id]); } else { address = reinterpret_cast
(NoExternalReferencesCallback); } memcpy(current, &address, kPointerSize); current++; break; } case kWeakPrefix: DCHECK(!allocator()->next_reference_is_weak()); allocator()->set_next_reference_is_weak(true); break; case kAlignmentPrefix: case kAlignmentPrefix + 1: case kAlignmentPrefix + 2: { int alignment = data - (SerializerDeserializer::kAlignmentPrefix - 1); allocator()->SetAlignment(static_cast(alignment)); break; } STATIC_ASSERT(kNumberOfRootArrayConstants == Heap::kOldSpaceRoots); STATIC_ASSERT(kNumberOfRootArrayConstants == 32); SIXTEEN_CASES(kRootArrayConstantsWithSkip) SIXTEEN_CASES(kRootArrayConstantsWithSkip + 16) { int skip = source_.GetInt(); current = reinterpret_cast( reinterpret_cast(current) + skip); V8_FALLTHROUGH; } SIXTEEN_CASES(kRootArrayConstants) SIXTEEN_CASES(kRootArrayConstants + 16) { int id = data & kRootArrayConstantsMask; Heap::RootListIndex root_index = static_cast(id); MaybeObject* object = MaybeObject::FromObject(isolate->heap()->root(root_index)); DCHECK(!Heap::InNewSpace(object)); DCHECK(!allocator()->next_reference_is_weak()); UnalignedCopy(current++, &object); break; } STATIC_ASSERT(kNumberOfHotObjects == 8); FOUR_CASES(kHotObjectWithSkip) FOUR_CASES(kHotObjectWithSkip + 4) { int skip = source_.GetInt(); current = reinterpret_cast( reinterpret_cast
(current) + skip); V8_FALLTHROUGH; } FOUR_CASES(kHotObject) FOUR_CASES(kHotObject + 4) { int index = data & kHotObjectMask; Object* hot_object = hot_objects_.Get(index); MaybeObject* hot_maybe_object = MaybeObject::FromObject(hot_object); if (allocator()->GetAndClearNextReferenceIsWeak()) { hot_maybe_object = MaybeObject::MakeWeak(hot_maybe_object); } UnalignedCopy(current, &hot_maybe_object); if (write_barrier_needed && Heap::InNewSpace(hot_object)) { Address current_address = reinterpret_cast
(current); GenerationalBarrier(HeapObject::FromAddress(current_object_address), reinterpret_cast(current_address), hot_maybe_object); } current++; break; } // Deserialize raw data of fixed length from 1 to 32 words. STATIC_ASSERT(kNumberOfFixedRawData == 32); SIXTEEN_CASES(kFixedRawData) SIXTEEN_CASES(kFixedRawData + 16) { byte* raw_data_out = reinterpret_cast(current); int size_in_bytes = (data - kFixedRawDataStart) << kPointerSizeLog2; source_.CopyRaw(raw_data_out, size_in_bytes); current = reinterpret_cast(raw_data_out + size_in_bytes); break; } STATIC_ASSERT(kNumberOfFixedRepeat == 16); SIXTEEN_CASES(kFixedRepeat) { int repeats = data - kFixedRepeatStart; MaybeObject* object; DCHECK(!allocator()->next_reference_is_weak()); UnalignedCopy(&object, current - 1); DCHECK(!Heap::InNewSpace(object)); for (int i = 0; i < repeats; i++) UnalignedCopy(current++, &object); break; } #ifdef DEBUG #define UNUSED_CASE(byte_code) \ case byte_code: \ UNREACHABLE(); UNUSED_SERIALIZER_BYTE_CODES(UNUSED_CASE) #endif #undef UNUSED_CASE #undef SIXTEEN_CASES #undef FOUR_CASES #undef SINGLE_CASE } } CHECK_EQ(limit, current); return true; } template void** Deserializer::ReadExternalReferenceCase( HowToCode how, void** current, Address current_object_address) { int skip = source_.GetInt(); current = reinterpret_cast(reinterpret_cast
(current) + skip); uint32_t reference_id = static_cast(source_.GetInt()); Address address = external_reference_table_->address(reference_id); if (how == kFromCode) { Address location_of_branch_data = reinterpret_cast
(current); int skip = Assembler::deserialization_special_target_size(location_of_branch_data); Assembler::deserialization_set_special_target_at( location_of_branch_data, Code::cast(HeapObject::FromAddress(current_object_address)), address); location_of_branch_data += skip; current = reinterpret_cast(location_of_branch_data); } else { void* new_current = reinterpret_cast(address); UnalignedCopy(current, &new_current); ++current; } return current; } template template MaybeObject** Deserializer::ReadDataCase( Isolate* isolate, MaybeObject** current, Address current_object_address, byte data, bool write_barrier_needed) { bool emit_write_barrier = false; bool current_was_incremented = false; int space_number = space_number_if_any == kAnyOldSpace ? (data & kSpaceMask) : space_number_if_any; HeapObjectReferenceType reference_type = HeapObjectReferenceType::STRONG; if (where == kNewObject && how == kPlain && within == kStartOfObject) { if (allocator()->GetAndClearNextReferenceIsWeak()) { reference_type = HeapObjectReferenceType::WEAK; } ReadObject(space_number, current, reference_type); emit_write_barrier = (space_number == NEW_SPACE); } else { Object* new_object = nullptr; /* May not be a real Object pointer. */ if (where == kNewObject) { ReadObject(space_number, reinterpret_cast(&new_object), HeapObjectReferenceType::STRONG); } else if (where == kBackref) { emit_write_barrier = (space_number == NEW_SPACE); new_object = GetBackReferencedObject(data & kSpaceMask); } else if (where == kBackrefWithSkip) { int skip = source_.GetInt(); current = reinterpret_cast( reinterpret_cast
(current) + skip); emit_write_barrier = (space_number == NEW_SPACE); new_object = GetBackReferencedObject(data & kSpaceMask); } else if (where == kRootArray) { int id = source_.GetInt(); Heap::RootListIndex root_index = static_cast(id); new_object = isolate->heap()->root(root_index); emit_write_barrier = Heap::InNewSpace(new_object); hot_objects_.Add(HeapObject::cast(new_object)); } else if (where == kPartialSnapshotCache) { int cache_index = source_.GetInt(); new_object = isolate->partial_snapshot_cache()->at(cache_index); emit_write_barrier = Heap::InNewSpace(new_object); } else if (where == kAttachedReference) { int index = source_.GetInt(); new_object = *attached_objects_[index]; emit_write_barrier = Heap::InNewSpace(new_object); } else { DCHECK_EQ(where, kBuiltin); int builtin_id = MaybeReplaceWithDeserializeLazy(source_.GetInt()); new_object = isolate->builtins()->builtin(builtin_id); emit_write_barrier = false; } if (within == kInnerPointer) { DCHECK_EQ(how, kFromCode); if (where == kBuiltin) { // At this point, new_object may still be uninitialized, thus the // unchecked Code cast. new_object = reinterpret_cast( reinterpret_cast(new_object)->raw_instruction_start()); } else if (new_object->IsCode()) { new_object = reinterpret_cast( Code::cast(new_object)->raw_instruction_start()); } else { Cell* cell = Cell::cast(new_object); new_object = reinterpret_cast(cell->ValueAddress()); } } if (how == kFromCode) { DCHECK(!allocator()->next_reference_is_weak()); Address location_of_branch_data = reinterpret_cast
(current); int skip = Assembler::deserialization_special_target_size( location_of_branch_data); Assembler::deserialization_set_special_target_at( location_of_branch_data, Code::cast(HeapObject::FromAddress(current_object_address)), reinterpret_cast
(new_object)); location_of_branch_data += skip; current = reinterpret_cast(location_of_branch_data); current_was_incremented = true; } else { MaybeObject* new_maybe_object = MaybeObject::FromObject(new_object); if (allocator()->GetAndClearNextReferenceIsWeak()) { new_maybe_object = MaybeObject::MakeWeak(new_maybe_object); } UnalignedCopy(current, &new_maybe_object); } } if (emit_write_barrier && write_barrier_needed) { Address current_address = reinterpret_cast
(current); SLOW_DCHECK(isolate->heap()->ContainsSlow(current_object_address)); GenerationalBarrier(HeapObject::FromAddress(current_object_address), reinterpret_cast(current_address), *reinterpret_cast(current_address)); } if (!current_was_incremented) { current++; } return current; } // Explicit instantiation. template class Deserializer; template class Deserializer; } // namespace internal } // namespace v8