// Copyright 2006-2008 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. // The common functionality when building with or without snapshots. #include "src/snapshot/snapshot.h" #include "src/api.h" #include "src/base/platform/platform.h" #include "src/full-codegen/full-codegen.h" namespace v8 { namespace internal { #ifdef DEBUG bool Snapshot::SnapshotIsValid(v8::StartupData* snapshot_blob) { return !Snapshot::ExtractStartupData(snapshot_blob).is_empty() && !Snapshot::ExtractContextData(snapshot_blob).is_empty(); } #endif // DEBUG bool Snapshot::HaveASnapshotToStartFrom(Isolate* isolate) { // Do not use snapshots if the isolate is used to create snapshots. return isolate->snapshot_blob() != NULL && isolate->snapshot_blob()->data != NULL; } bool Snapshot::EmbedsScript(Isolate* isolate) { if (!isolate->snapshot_available()) return false; return ExtractMetadata(isolate->snapshot_blob()).embeds_script(); } uint32_t Snapshot::SizeOfFirstPage(Isolate* isolate, AllocationSpace space) { DCHECK(space >= FIRST_PAGED_SPACE && space <= LAST_PAGED_SPACE); if (!isolate->snapshot_available()) { return static_cast<uint32_t>(MemoryAllocator::PageAreaSize(space)); } uint32_t size; int offset = kFirstPageSizesOffset + (space - FIRST_PAGED_SPACE) * kInt32Size; memcpy(&size, isolate->snapshot_blob()->data + offset, kInt32Size); return size; } bool Snapshot::Initialize(Isolate* isolate) { if (!isolate->snapshot_available()) return false; base::ElapsedTimer timer; if (FLAG_profile_deserialization) timer.Start(); const v8::StartupData* blob = isolate->snapshot_blob(); Vector<const byte> startup_data = ExtractStartupData(blob); SnapshotData snapshot_data(startup_data); Deserializer deserializer(&snapshot_data); bool success = isolate->Init(&deserializer); if (FLAG_profile_deserialization) { double ms = timer.Elapsed().InMillisecondsF(); int bytes = startup_data.length(); PrintF("[Deserializing isolate (%d bytes) took %0.3f ms]\n", bytes, ms); } return success; } MaybeHandle<Context> Snapshot::NewContextFromSnapshot( Isolate* isolate, Handle<JSGlobalProxy> global_proxy) { if (!isolate->snapshot_available()) return Handle<Context>(); base::ElapsedTimer timer; if (FLAG_profile_deserialization) timer.Start(); const v8::StartupData* blob = isolate->snapshot_blob(); Vector<const byte> context_data = ExtractContextData(blob); SnapshotData snapshot_data(context_data); Deserializer deserializer(&snapshot_data); MaybeHandle<Object> maybe_context = deserializer.DeserializePartial(isolate, global_proxy); Handle<Object> result; if (!maybe_context.ToHandle(&result)) return MaybeHandle<Context>(); CHECK(result->IsContext()); if (FLAG_profile_deserialization) { double ms = timer.Elapsed().InMillisecondsF(); int bytes = context_data.length(); PrintF("[Deserializing context (%d bytes) took %0.3f ms]\n", bytes, ms); } return Handle<Context>::cast(result); } void CalculateFirstPageSizes(bool is_default_snapshot, const SnapshotData& startup_snapshot, const SnapshotData& context_snapshot, uint32_t* sizes_out) { Vector<const SerializedData::Reservation> startup_reservations = startup_snapshot.Reservations(); Vector<const SerializedData::Reservation> context_reservations = context_snapshot.Reservations(); int startup_index = 0; int context_index = 0; if (FLAG_profile_deserialization) { int startup_total = 0; int context_total = 0; for (auto& reservation : startup_reservations) { startup_total += reservation.chunk_size(); } for (auto& reservation : context_reservations) { context_total += reservation.chunk_size(); } PrintF( "Deserialization will reserve:\n" "%10d bytes per isolate\n" "%10d bytes per context\n", startup_total, context_total); } for (int space = 0; space < i::Serializer::kNumberOfSpaces; space++) { bool single_chunk = true; while (!startup_reservations[startup_index].is_last()) { single_chunk = false; startup_index++; } while (!context_reservations[context_index].is_last()) { single_chunk = false; context_index++; } uint32_t required = kMaxUInt32; if (single_chunk) { // If both the startup snapshot data and the context snapshot data on // this space fit in a single page, then we consider limiting the size // of the first page. For this, we add the chunk sizes and some extra // allowance. This way we achieve a smaller startup memory footprint. required = (startup_reservations[startup_index].chunk_size() + 2 * context_reservations[context_index].chunk_size()) + Page::kObjectStartOffset; // Add a small allowance to the code space for small scripts. if (space == CODE_SPACE) required += 32 * KB; } else { // We expect the vanilla snapshot to only require on page per space. DCHECK(!is_default_snapshot); } if (space >= FIRST_PAGED_SPACE && space <= LAST_PAGED_SPACE) { uint32_t max_size = MemoryAllocator::PageAreaSize(static_cast<AllocationSpace>(space)); sizes_out[space - FIRST_PAGED_SPACE] = Min(required, max_size); } else { DCHECK(single_chunk); } startup_index++; context_index++; } DCHECK_EQ(startup_reservations.length(), startup_index); DCHECK_EQ(context_reservations.length(), context_index); } v8::StartupData Snapshot::CreateSnapshotBlob( const i::StartupSerializer& startup_ser, const i::PartialSerializer& context_ser, Snapshot::Metadata metadata) { SnapshotData startup_snapshot(startup_ser); SnapshotData context_snapshot(context_ser); Vector<const byte> startup_data = startup_snapshot.RawData(); Vector<const byte> context_data = context_snapshot.RawData(); uint32_t first_page_sizes[kNumPagedSpaces]; CalculateFirstPageSizes(!metadata.embeds_script(), startup_snapshot, context_snapshot, first_page_sizes); int startup_length = startup_data.length(); int context_length = context_data.length(); int context_offset = ContextOffset(startup_length); int length = context_offset + context_length; char* data = new char[length]; memcpy(data + kMetadataOffset, &metadata.RawValue(), kInt32Size); memcpy(data + kFirstPageSizesOffset, first_page_sizes, kNumPagedSpaces * kInt32Size); memcpy(data + kStartupLengthOffset, &startup_length, kInt32Size); memcpy(data + kStartupDataOffset, startup_data.begin(), startup_length); memcpy(data + context_offset, context_data.begin(), context_length); v8::StartupData result = {data, length}; if (FLAG_profile_deserialization) { PrintF( "Snapshot blob consists of:\n" "%10d bytes for startup\n" "%10d bytes for context\n", startup_length, context_length); } return result; } Snapshot::Metadata Snapshot::ExtractMetadata(const v8::StartupData* data) { uint32_t raw; memcpy(&raw, data->data + kMetadataOffset, kInt32Size); return Metadata(raw); } Vector<const byte> Snapshot::ExtractStartupData(const v8::StartupData* data) { DCHECK_LT(kIntSize, data->raw_size); int startup_length; memcpy(&startup_length, data->data + kStartupLengthOffset, kInt32Size); DCHECK_LT(startup_length, data->raw_size); const byte* startup_data = reinterpret_cast<const byte*>(data->data + kStartupDataOffset); return Vector<const byte>(startup_data, startup_length); } Vector<const byte> Snapshot::ExtractContextData(const v8::StartupData* data) { DCHECK_LT(kIntSize, data->raw_size); int startup_length; memcpy(&startup_length, data->data + kStartupLengthOffset, kIntSize); int context_offset = ContextOffset(startup_length); const byte* context_data = reinterpret_cast<const byte*>(data->data + context_offset); DCHECK_LT(context_offset, data->raw_size); int context_length = data->raw_size - context_offset; return Vector<const byte>(context_data, context_length); } } // namespace internal } // namespace v8