// 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/code-serializer.h" #include #include "src/code-stubs.h" #include "src/counters.h" #include "src/log.h" #include "src/macro-assembler.h" #include "src/objects-inl.h" #include "src/snapshot/deserializer.h" #include "src/snapshot/snapshot.h" #include "src/version.h" #include "src/visitors.h" #include "src/wasm/wasm-module.h" #include "src/wasm/wasm-objects.h" namespace v8 { namespace internal { ScriptData* CodeSerializer::Serialize(Isolate* isolate, Handle info, Handle source) { base::ElapsedTimer timer; if (FLAG_profile_deserialization) timer.Start(); if (FLAG_trace_serializer) { PrintF("[Serializing from"); Object* script = info->script(); if (script->IsScript()) Script::cast(script)->name()->ShortPrint(); PrintF("]\n"); } // Serialize code object. CodeSerializer cs(isolate, SerializedCodeData::SourceHash(source)); DisallowHeapAllocation no_gc; cs.reference_map()->AddAttachedReference(*source); ScriptData* ret = cs.Serialize(info); if (FLAG_profile_deserialization) { double ms = timer.Elapsed().InMillisecondsF(); int length = ret->length(); PrintF("[Serializing to %d bytes took %0.3f ms]\n", length, ms); } return ret; } ScriptData* CodeSerializer::Serialize(Handle obj) { DisallowHeapAllocation no_gc; VisitRootPointer(Root::kHandleScope, Handle::cast(obj).location()); SerializeDeferredObjects(); Pad(); SerializedCodeData data(sink()->data(), this); return data.GetScriptData(); } void CodeSerializer::SerializeObject(HeapObject* obj, HowToCode how_to_code, WhereToPoint where_to_point, int skip) { if (SerializeHotObject(obj, how_to_code, where_to_point, skip)) return; int root_index = root_index_map_.Lookup(obj); if (root_index != RootIndexMap::kInvalidRootIndex) { PutRoot(root_index, obj, how_to_code, where_to_point, skip); return; } if (SerializeBackReference(obj, how_to_code, where_to_point, skip)) return; FlushSkip(skip); if (obj->IsCode()) { Code* code_object = Code::cast(obj); switch (code_object->kind()) { case Code::OPTIMIZED_FUNCTION: // No optimized code compiled yet. case Code::HANDLER: // No handlers patched in yet. case Code::REGEXP: // No regexp literals initialized yet. case Code::NUMBER_OF_KINDS: // Pseudo enum value. case Code::BYTECODE_HANDLER: // No direct references to handlers. CHECK(false); case Code::BUILTIN: SerializeBuiltin(code_object->builtin_index(), how_to_code, where_to_point); return; case Code::STUB: #define IC_KIND_CASE(KIND) case Code::KIND: IC_KIND_LIST(IC_KIND_CASE) #undef IC_KIND_CASE if (code_object->builtin_index() == -1) { SerializeCodeStub(code_object, how_to_code, where_to_point); } else { SerializeBuiltin(code_object->builtin_index(), how_to_code, where_to_point); } return; case Code::FUNCTION: DCHECK(code_object->has_reloc_info_for_serialization()); SerializeGeneric(code_object, how_to_code, where_to_point); return; default: return SerializeCodeObject(code_object, how_to_code, where_to_point); } UNREACHABLE(); } if (ElideObject(obj)) { return SerializeObject(isolate()->heap()->undefined_value(), how_to_code, where_to_point, skip); } if (obj->IsScript()) { // Wrapper object is a context-dependent JSValue. Reset it here. Script::cast(obj)->set_wrapper(isolate()->heap()->undefined_value()); } // Past this point we should not see any (context-specific) maps anymore. CHECK(!obj->IsMap()); // There should be no references to the global object embedded. CHECK(!obj->IsJSGlobalProxy() && !obj->IsJSGlobalObject()); // There should be no hash table embedded. They would require rehashing. CHECK(!obj->IsHashTable()); // We expect no instantiated function objects or contexts. CHECK(!obj->IsJSFunction() && !obj->IsContext()); SerializeGeneric(obj, how_to_code, where_to_point); } void CodeSerializer::SerializeGeneric(HeapObject* heap_object, HowToCode how_to_code, WhereToPoint where_to_point) { // Object has not yet been serialized. Serialize it here. ObjectSerializer serializer(this, heap_object, &sink_, how_to_code, where_to_point); serializer.Serialize(); } void CodeSerializer::SerializeBuiltin(int builtin_index, HowToCode how_to_code, WhereToPoint where_to_point) { DCHECK((how_to_code == kPlain && where_to_point == kStartOfObject) || (how_to_code == kPlain && where_to_point == kInnerPointer) || (how_to_code == kFromCode && where_to_point == kInnerPointer)); DCHECK_LT(builtin_index, Builtins::builtin_count); DCHECK_LE(0, builtin_index); if (FLAG_trace_serializer) { PrintF(" Encoding builtin: %s\n", isolate()->builtins()->name(builtin_index)); } sink_.Put(kBuiltin + how_to_code + where_to_point, "Builtin"); sink_.PutInt(builtin_index, "builtin_index"); } void CodeSerializer::SerializeCodeStub(Code* code_stub, HowToCode how_to_code, WhereToPoint where_to_point) { // We only arrive here if we have not encountered this code stub before. DCHECK(!reference_map()->Lookup(code_stub).is_valid()); uint32_t stub_key = code_stub->stub_key(); DCHECK(CodeStub::MajorKeyFromKey(stub_key) != CodeStub::NoCache); DCHECK(!CodeStub::GetCode(isolate(), stub_key).is_null()); stub_keys_.Add(stub_key); SerializerReference reference = reference_map()->AddAttachedReference(code_stub); if (FLAG_trace_serializer) { PrintF(" Encoding code stub %s as attached reference %d\n", CodeStub::MajorName(CodeStub::MajorKeyFromKey(stub_key)), reference.attached_reference_index()); } PutAttachedReference(reference, how_to_code, where_to_point); } MaybeHandle CodeSerializer::Deserialize( Isolate* isolate, ScriptData* cached_data, Handle source) { base::ElapsedTimer timer; if (FLAG_profile_deserialization) timer.Start(); HandleScope scope(isolate); SerializedCodeData::SanityCheckResult sanity_check_result = SerializedCodeData::CHECK_SUCCESS; const SerializedCodeData scd = SerializedCodeData::FromCachedData( isolate, cached_data, SerializedCodeData::SourceHash(source), &sanity_check_result); if (sanity_check_result != SerializedCodeData::CHECK_SUCCESS) { if (FLAG_profile_deserialization) PrintF("[Cached code failed check]\n"); DCHECK(cached_data->rejected()); source->GetIsolate()->counters()->code_cache_reject_reason()->AddSample( sanity_check_result); return MaybeHandle(); } Deserializer deserializer(&scd); deserializer.AddAttachedObject(source); Vector code_stub_keys = scd.CodeStubKeys(); for (int i = 0; i < code_stub_keys.length(); i++) { deserializer.AddAttachedObject( CodeStub::GetCode(isolate, code_stub_keys[i]).ToHandleChecked()); } // Deserialize. Handle as_heap_object; if (!deserializer.DeserializeObject(isolate).ToHandle(&as_heap_object)) { // Deserializing may fail if the reservations cannot be fulfilled. if (FLAG_profile_deserialization) PrintF("[Deserializing failed]\n"); return MaybeHandle(); } Handle result = Handle::cast(as_heap_object); if (FLAG_profile_deserialization) { double ms = timer.Elapsed().InMillisecondsF(); int length = cached_data->length(); PrintF("[Deserializing from %d bytes took %0.3f ms]\n", length, ms); } result->set_deserialized(true); if (isolate->logger()->is_logging_code_events() || isolate->is_profiling()) { String* name = isolate->heap()->empty_string(); if (result->script()->IsScript()) { Script* script = Script::cast(result->script()); if (script->name()->IsString()) name = String::cast(script->name()); } PROFILE(isolate, CodeCreateEvent(CodeEventListener::SCRIPT_TAG, result->abstract_code(), *result, name)); } return scope.CloseAndEscape(result); } WasmCompiledModuleSerializer::WasmCompiledModuleSerializer( Isolate* isolate, uint32_t source_hash, Handle native_context, Handle module_bytes) : CodeSerializer(isolate, source_hash) { reference_map()->AddAttachedReference(*isolate->native_context()); reference_map()->AddAttachedReference(*module_bytes); } std::unique_ptr WasmCompiledModuleSerializer::SerializeWasmModule( Isolate* isolate, Handle input) { Handle compiled_module = Handle::cast(input); WasmCompiledModuleSerializer wasm_cs(isolate, 0, isolate->native_context(), handle(compiled_module->module_bytes())); ScriptData* data = wasm_cs.Serialize(compiled_module); return std::unique_ptr(data); } MaybeHandle WasmCompiledModuleSerializer::DeserializeWasmModule( Isolate* isolate, ScriptData* data, Vector wire_bytes) { MaybeHandle nothing; if (!wasm::IsWasmCodegenAllowed(isolate, isolate->native_context())) { return nothing; } SerializedCodeData::SanityCheckResult sanity_check_result = SerializedCodeData::CHECK_SUCCESS; const SerializedCodeData scd = SerializedCodeData::FromCachedData( isolate, data, 0, &sanity_check_result); if (sanity_check_result != SerializedCodeData::CHECK_SUCCESS) { return nothing; } Deserializer deserializer(&scd, true); deserializer.AddAttachedObject(isolate->native_context()); MaybeHandle maybe_wire_bytes_as_string = isolate->factory()->NewStringFromOneByte(wire_bytes, TENURED); Handle wire_bytes_as_string; if (!maybe_wire_bytes_as_string.ToHandle(&wire_bytes_as_string)) { return nothing; } deserializer.AddAttachedObject( handle(SeqOneByteString::cast(*wire_bytes_as_string))); Vector stub_keys = scd.CodeStubKeys(); for (int i = 0; i < stub_keys.length(); ++i) { deserializer.AddAttachedObject( CodeStub::GetCode(isolate, stub_keys[i]).ToHandleChecked()); } MaybeHandle obj = deserializer.DeserializeObject(isolate); if (obj.is_null() || !obj.ToHandleChecked()->IsFixedArray()) return nothing; // Cast without type checks, as the module wrapper is not there yet. Handle compiled_module( static_cast(*obj.ToHandleChecked()), isolate); WasmCompiledModule::ReinitializeAfterDeserialization(isolate, compiled_module); DCHECK(WasmCompiledModule::IsWasmCompiledModule(*compiled_module)); return compiled_module; } void WasmCompiledModuleSerializer::SerializeCodeObject( Code* code_object, HowToCode how_to_code, WhereToPoint where_to_point) { Code::Kind kind = code_object->kind(); switch (kind) { case Code::WASM_FUNCTION: case Code::JS_TO_WASM_FUNCTION: // Just serialize the code_object. SerializeGeneric(code_object, how_to_code, where_to_point); break; case Code::WASM_INTERPRETER_ENTRY: case Code::WASM_TO_JS_FUNCTION: // Serialize the illegal builtin instead. On instantiation of a // deserialized module, these will be replaced again. SerializeBuiltin(Builtins::kIllegal, how_to_code, where_to_point); break; default: UNREACHABLE(); } } bool WasmCompiledModuleSerializer::ElideObject(Object* obj) { return obj->IsWeakCell() || obj->IsForeign() || obj->IsBreakPointInfo(); } class Checksum { public: explicit Checksum(Vector payload) { #ifdef MEMORY_SANITIZER // Computing the checksum includes padding bytes for objects like strings. // Mark every object as initialized in the code serializer. MSAN_MEMORY_IS_INITIALIZED(payload.start(), payload.length()); #endif // MEMORY_SANITIZER // Fletcher's checksum. Modified to reduce 64-bit sums to 32-bit. uintptr_t a = 1; uintptr_t b = 0; const uintptr_t* cur = reinterpret_cast(payload.start()); DCHECK(IsAligned(payload.length(), kIntptrSize)); const uintptr_t* end = cur + payload.length() / kIntptrSize; while (cur < end) { // Unsigned overflow expected and intended. a += *cur++; b += a; } #if V8_HOST_ARCH_64_BIT a ^= a >> 32; b ^= b >> 32; #endif // V8_HOST_ARCH_64_BIT a_ = static_cast(a); b_ = static_cast(b); } bool Check(uint32_t a, uint32_t b) const { return a == a_ && b == b_; } uint32_t a() const { return a_; } uint32_t b() const { return b_; } private: uint32_t a_; uint32_t b_; DISALLOW_COPY_AND_ASSIGN(Checksum); }; SerializedCodeData::SerializedCodeData(const List* payload, const CodeSerializer* cs) { DisallowHeapAllocation no_gc; const List* stub_keys = cs->stub_keys(); List reservations; cs->EncodeReservations(&reservations); // Calculate sizes. int reservation_size = reservations.length() * kInt32Size; int num_stub_keys = stub_keys->length(); int stub_keys_size = stub_keys->length() * kInt32Size; int payload_offset = kHeaderSize + reservation_size + stub_keys_size; int padded_payload_offset = POINTER_SIZE_ALIGN(payload_offset); int size = padded_payload_offset + payload->length(); // Allocate backing store and create result data. AllocateData(size); // Set header values. SetMagicNumber(cs->isolate()); SetHeaderValue(kVersionHashOffset, Version::Hash()); SetHeaderValue(kSourceHashOffset, cs->source_hash()); SetHeaderValue(kCpuFeaturesOffset, static_cast(CpuFeatures::SupportedFeatures())); SetHeaderValue(kFlagHashOffset, FlagList::Hash()); SetHeaderValue(kNumReservationsOffset, reservations.length()); SetHeaderValue(kNumCodeStubKeysOffset, num_stub_keys); SetHeaderValue(kPayloadLengthOffset, payload->length()); // Zero out any padding in the header. memset(data_ + kUnalignedHeaderSize, 0, kHeaderSize - kUnalignedHeaderSize); // Copy reservation chunk sizes. CopyBytes(data_ + kHeaderSize, reinterpret_cast(reservations.begin()), reservation_size); // Copy code stub keys. CopyBytes(data_ + kHeaderSize + reservation_size, reinterpret_cast(stub_keys->begin()), stub_keys_size); // Zero out any padding before the payload. memset(data_ + payload_offset, 0, padded_payload_offset - payload_offset); // Copy serialized data. CopyBytes(data_ + padded_payload_offset, payload->begin(), static_cast(payload->length())); Checksum checksum(DataWithoutHeader()); SetHeaderValue(kChecksum1Offset, checksum.a()); SetHeaderValue(kChecksum2Offset, checksum.b()); } SerializedCodeData::SanityCheckResult SerializedCodeData::SanityCheck( Isolate* isolate, uint32_t expected_source_hash) const { if (this->size_ < kHeaderSize) return INVALID_HEADER; uint32_t magic_number = GetMagicNumber(); if (magic_number != ComputeMagicNumber(isolate)) return MAGIC_NUMBER_MISMATCH; if (GetExtraReferences() > GetExtraReferences(isolate)) { return MAGIC_NUMBER_MISMATCH; } uint32_t version_hash = GetHeaderValue(kVersionHashOffset); uint32_t source_hash = GetHeaderValue(kSourceHashOffset); uint32_t cpu_features = GetHeaderValue(kCpuFeaturesOffset); uint32_t flags_hash = GetHeaderValue(kFlagHashOffset); uint32_t payload_length = GetHeaderValue(kPayloadLengthOffset); uint32_t c1 = GetHeaderValue(kChecksum1Offset); uint32_t c2 = GetHeaderValue(kChecksum2Offset); if (version_hash != Version::Hash()) return VERSION_MISMATCH; if (source_hash != expected_source_hash) return SOURCE_MISMATCH; if (cpu_features != static_cast(CpuFeatures::SupportedFeatures())) { return CPU_FEATURES_MISMATCH; } if (flags_hash != FlagList::Hash()) return FLAGS_MISMATCH; uint32_t max_payload_length = this->size_ - POINTER_SIZE_ALIGN(kHeaderSize + GetHeaderValue(kNumReservationsOffset) * kInt32Size + GetHeaderValue(kNumCodeStubKeysOffset) * kInt32Size); if (payload_length > max_payload_length) return LENGTH_MISMATCH; if (!Checksum(DataWithoutHeader()).Check(c1, c2)) return CHECKSUM_MISMATCH; return CHECK_SUCCESS; } uint32_t SerializedCodeData::SourceHash(Handle source) { return source->length(); } // Return ScriptData object and relinquish ownership over it to the caller. ScriptData* SerializedCodeData::GetScriptData() { DCHECK(owns_data_); ScriptData* result = new ScriptData(data_, size_); result->AcquireDataOwnership(); owns_data_ = false; data_ = NULL; return result; } Vector SerializedCodeData::Reservations() const { return Vector( reinterpret_cast(data_ + kHeaderSize), GetHeaderValue(kNumReservationsOffset)); } Vector SerializedCodeData::Payload() const { int reservations_size = GetHeaderValue(kNumReservationsOffset) * kInt32Size; int code_stubs_size = GetHeaderValue(kNumCodeStubKeysOffset) * kInt32Size; int payload_offset = kHeaderSize + reservations_size + code_stubs_size; int padded_payload_offset = POINTER_SIZE_ALIGN(payload_offset); const byte* payload = data_ + padded_payload_offset; DCHECK(IsAligned(reinterpret_cast(payload), kPointerAlignment)); int length = GetHeaderValue(kPayloadLengthOffset); DCHECK_EQ(data_ + size_, payload + length); return Vector(payload, length); } Vector SerializedCodeData::CodeStubKeys() const { int reservations_size = GetHeaderValue(kNumReservationsOffset) * kInt32Size; const byte* start = data_ + kHeaderSize + reservations_size; return Vector(reinterpret_cast(start), GetHeaderValue(kNumCodeStubKeysOffset)); } SerializedCodeData::SerializedCodeData(ScriptData* data) : SerializedData(const_cast(data->data()), data->length()) {} SerializedCodeData SerializedCodeData::FromCachedData( Isolate* isolate, ScriptData* cached_data, uint32_t expected_source_hash, SanityCheckResult* rejection_result) { DisallowHeapAllocation no_gc; SerializedCodeData scd(cached_data); *rejection_result = scd.SanityCheck(isolate, expected_source_hash); if (*rejection_result != CHECK_SUCCESS) { cached_data->Reject(); return SerializedCodeData(nullptr, 0); } return scd; } } // namespace internal } // namespace v8