src/v8/src/wasm/streaming-decoder.cc - cobalt - Git at Google

 // Copyright 2017 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/wasm/streaming-decoder.h"

 #include "src/base/template-utils.h"
 #include "src/handles.h"
 #include "src/objects-inl.h"
 #include "src/objects/descriptor-array.h"
 #include "src/objects/dictionary.h"
 #include "src/wasm/decoder.h"
 #include "src/wasm/leb-helper.h"
 #include "src/wasm/module-decoder.h"
 #include "src/wasm/wasm-objects.h"
 #include "src/wasm/wasm-result.h"

 #define TRACE_STREAMING(...)                            \
   do {                                                  \
     if (FLAG_trace_wasm_streaming) PrintF(__VA_ARGS__); \
   } while (false)

 namespace v8 {
 namespace internal {
 namespace wasm {

 void StreamingDecoder::OnBytesReceived(Vector<const uint8_t> bytes) {
   TRACE_STREAMING("OnBytesReceived(%zu bytes)\n", bytes.size());
   size_t current = 0;
   while (ok() && current < bytes.size()) {
     size_t num_bytes =
         state_->ReadBytes(this, bytes.SubVector(current, bytes.size()));
     current += num_bytes;
     module_offset_ += num_bytes;
     if (state_->is_finished()) {
       state_ = state_->Next(this);
     }
   }
   total_size_ += bytes.size();
   if (ok()) {
     processor_->OnFinishedChunk();
   }
 }

 size_t StreamingDecoder::DecodingState::ReadBytes(StreamingDecoder* streaming,
                                                   Vector<const uint8_t> bytes) {
   size_t num_bytes = std::min(bytes.size(), remaining());
   TRACE_STREAMING("ReadBytes(%zu bytes)\n", num_bytes);
   memcpy(buffer() + offset(), &bytes.first(), num_bytes);
   set_offset(offset() + num_bytes);
   return num_bytes;
 }

 void StreamingDecoder::Finish() {
   TRACE_STREAMING("Finish\n");
   if (!ok()) {
     return;
   }

   if (!state_->is_finishing_allowed()) {
     // The byte stream ended too early, we report an error.
     Error("unexpected end of stream");
     return;
   }

   std::unique_ptr<uint8_t[]> bytes(new uint8_t[total_size_]);
   uint8_t* cursor = bytes.get();
   {
 #define BYTES(x) (x & 0xFF), (x >> 8) & 0xFF, (x >> 16) & 0xFF, (x >> 24) & 0xFF
     uint8_t module_header[]{BYTES(kWasmMagic), BYTES(kWasmVersion)};
 #undef BYTES
     memcpy(cursor, module_header, arraysize(module_header));
     cursor += arraysize(module_header);
   }
   for (auto&& buffer : section_buffers_) {
     DCHECK_LE(cursor - bytes.get() + buffer->length(), total_size_);
     memcpy(cursor, buffer->bytes(), buffer->length());
     cursor += buffer->length();
   }
   processor_->OnFinishedStream(std::move(bytes), total_size_);
 }

 void StreamingDecoder::Abort() {
   TRACE_STREAMING("Abort\n");
   if (ok()) processor_->OnAbort();
 }

 // An abstract class to share code among the states which decode VarInts. This
 // class takes over the decoding of the VarInt and then calls the actual decode
 // code with the decoded value.
 class StreamingDecoder::DecodeVarInt32 : public DecodingState {
  public:
   explicit DecodeVarInt32(size_t max_value, const char* field_name)
       : max_value_(max_value), field_name_(field_name) {}

   uint8_t* buffer() override { return byte_buffer_; }

   size_t size() const override { return kMaxVarInt32Size; }

   size_t ReadBytes(StreamingDecoder* streaming,
                    Vector<const uint8_t> bytes) override;

   std::unique_ptr<DecodingState> Next(StreamingDecoder* streaming) override;

   virtual std::unique_ptr<DecodingState> NextWithValue(
       StreamingDecoder* streaming) = 0;

  protected:
   uint8_t byte_buffer_[kMaxVarInt32Size];
   // The maximum valid value decoded in this state. {Next} returns an error if
   // this value is exceeded.
   size_t max_value_;
   const char* field_name_;
   size_t value_ = 0;
   size_t bytes_consumed_ = 0;
 };

 class StreamingDecoder::DecodeModuleHeader : public DecodingState {
  public:
   size_t size() const override { return kModuleHeaderSize; }
   uint8_t* buffer() override { return byte_buffer_; }

   std::unique_ptr<DecodingState> Next(StreamingDecoder* streaming) override;

  private:
   // Checks if the magic bytes of the module header are correct.
   void CheckHeader(Decoder* decoder);

   // The size of the module header.
   static constexpr size_t kModuleHeaderSize = 8;
   uint8_t byte_buffer_[kModuleHeaderSize];
 };

 class StreamingDecoder::DecodeSectionID : public DecodingState {
  public:
   explicit DecodeSectionID(uint32_t module_offset)
       : module_offset_(module_offset) {}

   size_t size() const override { return 1; }
   uint8_t* buffer() override { return &id_; }
   bool is_finishing_allowed() const override { return true; }

   std::unique_ptr<DecodingState> Next(StreamingDecoder* streaming) override;

  private:
   uint8_t id_ = 0;
   // The start offset of this section in the module.
   uint32_t module_offset_;
 };

 class StreamingDecoder::DecodeSectionLength : public DecodeVarInt32 {
  public:
   explicit DecodeSectionLength(uint8_t id, uint32_t module_offset)
       : DecodeVarInt32(kV8MaxWasmModuleSize, "section length"),
         section_id_(id),
         module_offset_(module_offset) {}

   std::unique_ptr<DecodingState> NextWithValue(
       StreamingDecoder* streaming) override;

  private:
   uint8_t section_id_;
   // The start offset of this section in the module.
   uint32_t module_offset_;
 };

 class StreamingDecoder::DecodeSectionPayload : public DecodingState {
  public:
   explicit DecodeSectionPayload(SectionBuffer* section_buffer)
       : section_buffer_(section_buffer) {}

   size_t size() const override { return section_buffer_->payload_length(); }

   uint8_t* buffer() override {
     return section_buffer_->bytes() + section_buffer_->payload_offset();
   }

   std::unique_ptr<DecodingState> Next(StreamingDecoder* streaming) override;

  private:
   SectionBuffer* section_buffer_;
 };

 class StreamingDecoder::DecodeNumberOfFunctions : public DecodeVarInt32 {
  public:
   explicit DecodeNumberOfFunctions(SectionBuffer* section_buffer)
       : DecodeVarInt32(kV8MaxWasmFunctions, "functions count"),
         section_buffer_(section_buffer) {}

   std::unique_ptr<DecodingState> NextWithValue(
       StreamingDecoder* streaming) override;

  private:
   SectionBuffer* section_buffer_;
 };

 class StreamingDecoder::DecodeFunctionLength : public DecodeVarInt32 {
  public:
   explicit DecodeFunctionLength(SectionBuffer* section_buffer,
                                 size_t buffer_offset,
                                 size_t num_remaining_functions)
       : DecodeVarInt32(kV8MaxWasmFunctionSize, "body size"),
         section_buffer_(section_buffer),
         buffer_offset_(buffer_offset),
         // We are reading a new function, so one function less is remaining.
         num_remaining_functions_(num_remaining_functions - 1) {
     DCHECK_GT(num_remaining_functions, 0);
   }

   std::unique_ptr<DecodingState> NextWithValue(
       StreamingDecoder* streaming) override;

  private:
   SectionBuffer* section_buffer_;
   size_t buffer_offset_;
   size_t num_remaining_functions_;
 };

 class StreamingDecoder::DecodeFunctionBody : public DecodingState {
  public:
   explicit DecodeFunctionBody(SectionBuffer* section_buffer,
                               size_t buffer_offset, size_t function_length,
                               size_t num_remaining_functions,
                               uint32_t module_offset)
       : section_buffer_(section_buffer),
         buffer_offset_(buffer_offset),
         size_(function_length),
         num_remaining_functions_(num_remaining_functions),
         module_offset_(module_offset) {}

   size_t size() const override { return size_; }

   uint8_t* buffer() override {
     return section_buffer_->bytes() + buffer_offset_;
   }

   std::unique_ptr<DecodingState> Next(StreamingDecoder* streaming) override;

  private:
   SectionBuffer* section_buffer_;
   size_t buffer_offset_;
   size_t size_;
   size_t num_remaining_functions_;
   uint32_t module_offset_;
 };

 size_t StreamingDecoder::DecodeVarInt32::ReadBytes(
     StreamingDecoder* streaming, Vector<const uint8_t> bytes) {
   size_t bytes_read = std::min(bytes.size(), remaining());
   TRACE_STREAMING("ReadBytes of a VarInt\n");
   memcpy(buffer() + offset(), &bytes.first(), bytes_read);
   Decoder decoder(buffer(), buffer() + offset() + bytes_read,
                   streaming->module_offset());
   value_ = decoder.consume_u32v(field_name_);
   // The number of bytes we actually needed to read.
   DCHECK_GT(decoder.pc(), buffer());
   bytes_consumed_ = static_cast<size_t>(decoder.pc() - buffer());
   TRACE_STREAMING("  ==> %zu bytes consumed\n", bytes_consumed_);

   if (decoder.failed()) {
     if (offset() + bytes_read == size()) {
       // We only report an error if we read all bytes.
       streaming->Error(decoder.toResult(nullptr));
     }
     set_offset(offset() + bytes_read);
     return bytes_read;
   } else {
     DCHECK_GT(bytes_consumed_, offset());
     size_t result = bytes_consumed_ - offset();
     // We read all the bytes we needed.
     set_offset(size());
     return result;
   }
 }

 std::unique_ptr<StreamingDecoder::DecodingState>
 StreamingDecoder::DecodeVarInt32::Next(StreamingDecoder* streaming) {
   if (!streaming->ok()) {
     return nullptr;
   }
   if (value_ > max_value_) {
     std::ostringstream oss;
     oss << "function size > maximum function size: " << value_ << " < "
         << max_value_;
     return streaming->Error(oss.str());
   }

   return NextWithValue(streaming);
 }

 std::unique_ptr<StreamingDecoder::DecodingState>
 StreamingDecoder::DecodeModuleHeader::Next(StreamingDecoder* streaming) {
   TRACE_STREAMING("DecodeModuleHeader\n");
   streaming->ProcessModuleHeader();
   if (streaming->ok()) {
     return base::make_unique<DecodeSectionID>(streaming->module_offset());
   }
   return nullptr;
 }

 std::unique_ptr<StreamingDecoder::DecodingState>
 StreamingDecoder::DecodeSectionID::Next(StreamingDecoder* streaming) {
   TRACE_STREAMING("DecodeSectionID: %s section\n",
                   SectionName(static_cast<SectionCode>(id_)));
   return base::make_unique<DecodeSectionLength>(id_, module_offset_);
 }

 std::unique_ptr<StreamingDecoder::DecodingState>
 StreamingDecoder::DecodeSectionLength::NextWithValue(
     StreamingDecoder* streaming) {
   TRACE_STREAMING("DecodeSectionLength(%zu)\n", value_);
   SectionBuffer* buf = streaming->CreateNewBuffer(
       module_offset_, section_id_, value_,
       Vector<const uint8_t>(buffer(), static_cast<int>(bytes_consumed_)));
   if (!buf) return nullptr;
   if (value_ == 0) {
     if (section_id_ == SectionCode::kCodeSectionCode) {
       return streaming->Error("Code section cannot have size 0");
     } else {
       streaming->ProcessSection(buf);
       if (streaming->ok()) {
         // There is no payload, we go to the next section immediately.
         return base::make_unique<DecodeSectionID>(streaming->module_offset_);
       } else {
         return nullptr;
       }
     }
   } else {
     if (section_id_ == SectionCode::kCodeSectionCode) {
       // We reached the code section. All functions of the code section are put
       // into the same SectionBuffer.
       return base::make_unique<DecodeNumberOfFunctions>(buf);
     } else {
       return base::make_unique<DecodeSectionPayload>(buf);
     }
   }
 }

 std::unique_ptr<StreamingDecoder::DecodingState>
 StreamingDecoder::DecodeSectionPayload::Next(StreamingDecoder* streaming) {
   TRACE_STREAMING("DecodeSectionPayload\n");
   streaming->ProcessSection(section_buffer_);
   if (streaming->ok()) {
     return base::make_unique<DecodeSectionID>(streaming->module_offset());
   }
   return nullptr;
 }

 std::unique_ptr<StreamingDecoder::DecodingState>
 StreamingDecoder::DecodeNumberOfFunctions::NextWithValue(
     StreamingDecoder* streaming) {
   TRACE_STREAMING("DecodeNumberOfFunctions(%zu)\n", value_);
   // Copy the bytes we read into the section buffer.
   if (section_buffer_->payload_length() >= bytes_consumed_) {
     memcpy(section_buffer_->bytes() + section_buffer_->payload_offset(),
            buffer(), bytes_consumed_);
   } else {
     return streaming->Error("Invalid code section length");
   }

   // {value} is the number of functions.
   if (value_ > 0) {
     streaming->StartCodeSection(value_);
     if (!streaming->ok()) return nullptr;
     return base::make_unique<DecodeFunctionLength>(
         section_buffer_, section_buffer_->payload_offset() + bytes_consumed_,
         value_);
   } else {
     if (section_buffer_->payload_length() != bytes_consumed_) {
       return streaming->Error("not all code section bytes were consumed");
     }
     return base::make_unique<DecodeSectionID>(streaming->module_offset());
   }
 }

 std::unique_ptr<StreamingDecoder::DecodingState>
 StreamingDecoder::DecodeFunctionLength::NextWithValue(
     StreamingDecoder* streaming) {
   TRACE_STREAMING("DecodeFunctionLength(%zu)\n", value_);
   // Copy the bytes we consumed into the section buffer.
   if (section_buffer_->length() >= buffer_offset_ + bytes_consumed_) {
     memcpy(section_buffer_->bytes() + buffer_offset_, buffer(),
            bytes_consumed_);
   } else {
     return streaming->Error("Invalid code section length");
   }

   // {value} is the length of the function.
   if (value_ == 0) {
     return streaming->Error("Invalid function length (0)");
   } else if (buffer_offset_ + bytes_consumed_ + value_ >
              section_buffer_->length()) {
     streaming->Error("not enough code section bytes");
     return nullptr;
   }

   return base::make_unique<DecodeFunctionBody>(
       section_buffer_, buffer_offset_ + bytes_consumed_, value_,
       num_remaining_functions_, streaming->module_offset());
 }

 std::unique_ptr<StreamingDecoder::DecodingState>
 StreamingDecoder::DecodeFunctionBody::Next(StreamingDecoder* streaming) {
   TRACE_STREAMING("DecodeFunctionBody\n");
   streaming->ProcessFunctionBody(
       Vector<const uint8_t>(buffer(), static_cast<int>(size())),
       module_offset_);
   if (!streaming->ok()) {
     return nullptr;
   }
   if (num_remaining_functions_ != 0) {
     return base::make_unique<DecodeFunctionLength>(
         section_buffer_, buffer_offset_ + size(), num_remaining_functions_);
   } else {
     if (buffer_offset_ + size() != section_buffer_->length()) {
       return streaming->Error("not all code section bytes were used");
     }
     return base::make_unique<DecodeSectionID>(streaming->module_offset());
   }
 }

 StreamingDecoder::StreamingDecoder(
     std::unique_ptr<StreamingProcessor> processor)
     : processor_(std::move(processor)),
       // A module always starts with a module header.
       state_(new DecodeModuleHeader()) {}
 }  // namespace wasm
 }  // namespace internal
 }  // namespace v8

 #undef TRACE_STREAMING
	// Copyright 2017 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/wasm/streaming-decoder.h"

	#include "src/base/template-utils.h"
	#include "src/handles.h"
	#include "src/objects-inl.h"
	#include "src/objects/descriptor-array.h"
	#include "src/objects/dictionary.h"
	#include "src/wasm/decoder.h"
	#include "src/wasm/leb-helper.h"
	#include "src/wasm/module-decoder.h"
	#include "src/wasm/wasm-objects.h"
	#include "src/wasm/wasm-result.h"

	#define TRACE_STREAMING(...) \
	do { \
	if (FLAG_trace_wasm_streaming) PrintF(__VA_ARGS__); \
	} while (false)

	namespace v8 {
	namespace internal {
	namespace wasm {

	void StreamingDecoder::OnBytesReceived(Vector<const uint8_t> bytes) {
	TRACE_STREAMING("OnBytesReceived(%zu bytes)\n", bytes.size());
	size_t current = 0;
	while (ok() && current < bytes.size()) {
	size_t num_bytes =
	state_->ReadBytes(this, bytes.SubVector(current, bytes.size()));
	current += num_bytes;
	module_offset_ += num_bytes;
	if (state_->is_finished()) {
	state_ = state_->Next(this);
	}
	}
	total_size_ += bytes.size();
	if (ok()) {
	processor_->OnFinishedChunk();
	}
	}

	size_t StreamingDecoder::DecodingState::ReadBytes(StreamingDecoder* streaming,
	Vector<const uint8_t> bytes) {
	size_t num_bytes = std::min(bytes.size(), remaining());
	TRACE_STREAMING("ReadBytes(%zu bytes)\n", num_bytes);
	memcpy(buffer() + offset(), &bytes.first(), num_bytes);
	set_offset(offset() + num_bytes);
	return num_bytes;
	}

	void StreamingDecoder::Finish() {
	TRACE_STREAMING("Finish\n");
	if (!ok()) {
	return;
	}

	if (!state_->is_finishing_allowed()) {
	// The byte stream ended too early, we report an error.
	Error("unexpected end of stream");
	return;
	}

	std::unique_ptr<uint8_t[]> bytes(new uint8_t[total_size_]);
	uint8_t* cursor = bytes.get();
	{
	#define BYTES(x) (x & 0xFF), (x >> 8) & 0xFF, (x >> 16) & 0xFF, (x >> 24) & 0xFF
	uint8_t module_header[]{BYTES(kWasmMagic), BYTES(kWasmVersion)};
	#undef BYTES
	memcpy(cursor, module_header, arraysize(module_header));
	cursor += arraysize(module_header);
	}
	for (auto&& buffer : section_buffers_) {
	DCHECK_LE(cursor - bytes.get() + buffer->length(), total_size_);
	memcpy(cursor, buffer->bytes(), buffer->length());
	cursor += buffer->length();
	}
	processor_->OnFinishedStream(std::move(bytes), total_size_);
	}

	void StreamingDecoder::Abort() {
	TRACE_STREAMING("Abort\n");
	if (ok()) processor_->OnAbort();
	}

	// An abstract class to share code among the states which decode VarInts. This
	// class takes over the decoding of the VarInt and then calls the actual decode
	// code with the decoded value.
	class StreamingDecoder::DecodeVarInt32 : public DecodingState {
	public:
	explicit DecodeVarInt32(size_t max_value, const char* field_name)
	: max_value_(max_value), field_name_(field_name) {}

	uint8_t* buffer() override { return byte_buffer_; }

	size_t size() const override { return kMaxVarInt32Size; }

	size_t ReadBytes(StreamingDecoder* streaming,
	Vector<const uint8_t> bytes) override;

	std::unique_ptr<DecodingState> Next(StreamingDecoder* streaming) override;

	virtual std::unique_ptr<DecodingState> NextWithValue(
	StreamingDecoder* streaming) = 0;

	protected:
	uint8_t byte_buffer_[kMaxVarInt32Size];
	// The maximum valid value decoded in this state. {Next} returns an error if
	// this value is exceeded.
	size_t max_value_;
	const char* field_name_;
	size_t value_ = 0;
	size_t bytes_consumed_ = 0;
	};

	class StreamingDecoder::DecodeModuleHeader : public DecodingState {
	public:
	size_t size() const override { return kModuleHeaderSize; }
	uint8_t* buffer() override { return byte_buffer_; }

	std::unique_ptr<DecodingState> Next(StreamingDecoder* streaming) override;

	private:
	// Checks if the magic bytes of the module header are correct.
	void CheckHeader(Decoder* decoder);

	// The size of the module header.
	static constexpr size_t kModuleHeaderSize = 8;
	uint8_t byte_buffer_[kModuleHeaderSize];
	};

	class StreamingDecoder::DecodeSectionID : public DecodingState {
	public:
	explicit DecodeSectionID(uint32_t module_offset)
	: module_offset_(module_offset) {}

	size_t size() const override { return 1; }
	uint8_t* buffer() override { return &id_; }
	bool is_finishing_allowed() const override { return true; }

	std::unique_ptr<DecodingState> Next(StreamingDecoder* streaming) override;

	private:
	uint8_t id_ = 0;
	// The start offset of this section in the module.
	uint32_t module_offset_;
	};

	class StreamingDecoder::DecodeSectionLength : public DecodeVarInt32 {
	public:
	explicit DecodeSectionLength(uint8_t id, uint32_t module_offset)
	: DecodeVarInt32(kV8MaxWasmModuleSize, "section length"),
	section_id_(id),
	module_offset_(module_offset) {}

	std::unique_ptr<DecodingState> NextWithValue(
	StreamingDecoder* streaming) override;

	private:
	uint8_t section_id_;
	// The start offset of this section in the module.
	uint32_t module_offset_;
	};

	class StreamingDecoder::DecodeSectionPayload : public DecodingState {
	public:
	explicit DecodeSectionPayload(SectionBuffer* section_buffer)
	: section_buffer_(section_buffer) {}

	size_t size() const override { return section_buffer_->payload_length(); }

	uint8_t* buffer() override {
	return section_buffer_->bytes() + section_buffer_->payload_offset();
	}

	std::unique_ptr<DecodingState> Next(StreamingDecoder* streaming) override;

	private:
	SectionBuffer* section_buffer_;
	};

	class StreamingDecoder::DecodeNumberOfFunctions : public DecodeVarInt32 {
	public:
	explicit DecodeNumberOfFunctions(SectionBuffer* section_buffer)
	: DecodeVarInt32(kV8MaxWasmFunctions, "functions count"),
	section_buffer_(section_buffer) {}

	std::unique_ptr<DecodingState> NextWithValue(
	StreamingDecoder* streaming) override;

	private:
	SectionBuffer* section_buffer_;
	};

	class StreamingDecoder::DecodeFunctionLength : public DecodeVarInt32 {
	public:
	explicit DecodeFunctionLength(SectionBuffer* section_buffer,
	size_t buffer_offset,
	size_t num_remaining_functions)
	: DecodeVarInt32(kV8MaxWasmFunctionSize, "body size"),
	section_buffer_(section_buffer),
	buffer_offset_(buffer_offset),
	// We are reading a new function, so one function less is remaining.
	num_remaining_functions_(num_remaining_functions - 1) {
	DCHECK_GT(num_remaining_functions, 0);
	}

	std::unique_ptr<DecodingState> NextWithValue(
	StreamingDecoder* streaming) override;

	private:
	SectionBuffer* section_buffer_;
	size_t buffer_offset_;
	size_t num_remaining_functions_;
	};

	class StreamingDecoder::DecodeFunctionBody : public DecodingState {
	public:
	explicit DecodeFunctionBody(SectionBuffer* section_buffer,
	size_t buffer_offset, size_t function_length,
	size_t num_remaining_functions,
	uint32_t module_offset)
	: section_buffer_(section_buffer),
	buffer_offset_(buffer_offset),
	size_(function_length),
	num_remaining_functions_(num_remaining_functions),
	module_offset_(module_offset) {}

	size_t size() const override { return size_; }

	uint8_t* buffer() override {
	return section_buffer_->bytes() + buffer_offset_;
	}

	std::unique_ptr<DecodingState> Next(StreamingDecoder* streaming) override;

	private:
	SectionBuffer* section_buffer_;
	size_t buffer_offset_;
	size_t size_;
	size_t num_remaining_functions_;
	uint32_t module_offset_;
	};

	size_t StreamingDecoder::DecodeVarInt32::ReadBytes(
	StreamingDecoder* streaming, Vector<const uint8_t> bytes) {
	size_t bytes_read = std::min(bytes.size(), remaining());
	TRACE_STREAMING("ReadBytes of a VarInt\n");
	memcpy(buffer() + offset(), &bytes.first(), bytes_read);
	Decoder decoder(buffer(), buffer() + offset() + bytes_read,
	streaming->module_offset());
	value_ = decoder.consume_u32v(field_name_);
	// The number of bytes we actually needed to read.
	DCHECK_GT(decoder.pc(), buffer());
	bytes_consumed_ = static_cast<size_t>(decoder.pc() - buffer());
	TRACE_STREAMING(" ==> %zu bytes consumed\n", bytes_consumed_);

	if (decoder.failed()) {
	if (offset() + bytes_read == size()) {
	// We only report an error if we read all bytes.
	streaming->Error(decoder.toResult(nullptr));
	}
	set_offset(offset() + bytes_read);
	return bytes_read;
	} else {
	DCHECK_GT(bytes_consumed_, offset());
	size_t result = bytes_consumed_ - offset();
	// We read all the bytes we needed.
	set_offset(size());
	return result;
	}
	}

	std::unique_ptr<StreamingDecoder::DecodingState>
	StreamingDecoder::DecodeVarInt32::Next(StreamingDecoder* streaming) {
	if (!streaming->ok()) {
	return nullptr;
	}
	if (value_ > max_value_) {
	std::ostringstream oss;
	oss << "function size > maximum function size: " << value_ << " < "
	<< max_value_;
	return streaming->Error(oss.str());
	}

	return NextWithValue(streaming);
	}

	std::unique_ptr<StreamingDecoder::DecodingState>
	StreamingDecoder::DecodeModuleHeader::Next(StreamingDecoder* streaming) {
	TRACE_STREAMING("DecodeModuleHeader\n");
	streaming->ProcessModuleHeader();
	if (streaming->ok()) {
	return base::make_unique<DecodeSectionID>(streaming->module_offset());
	}
	return nullptr;
	}

	std::unique_ptr<StreamingDecoder::DecodingState>
	StreamingDecoder::DecodeSectionID::Next(StreamingDecoder* streaming) {
	TRACE_STREAMING("DecodeSectionID: %s section\n",
	SectionName(static_cast<SectionCode>(id_)));
	return base::make_unique<DecodeSectionLength>(id_, module_offset_);
	}

	std::unique_ptr<StreamingDecoder::DecodingState>
	StreamingDecoder::DecodeSectionLength::NextWithValue(
	StreamingDecoder* streaming) {
	TRACE_STREAMING("DecodeSectionLength(%zu)\n", value_);
	SectionBuffer* buf = streaming->CreateNewBuffer(
	module_offset_, section_id_, value_,
	Vector<const uint8_t>(buffer(), static_cast<int>(bytes_consumed_)));
	if (!buf) return nullptr;
	if (value_ == 0) {
	if (section_id_ == SectionCode::kCodeSectionCode) {
	return streaming->Error("Code section cannot have size 0");
	} else {
	streaming->ProcessSection(buf);
	if (streaming->ok()) {
	// There is no payload, we go to the next section immediately.
	return base::make_unique<DecodeSectionID>(streaming->module_offset_);
	} else {
	return nullptr;
	}
	}
	} else {
	if (section_id_ == SectionCode::kCodeSectionCode) {
	// We reached the code section. All functions of the code section are put
	// into the same SectionBuffer.
	return base::make_unique<DecodeNumberOfFunctions>(buf);
	} else {
	return base::make_unique<DecodeSectionPayload>(buf);
	}
	}
	}

	std::unique_ptr<StreamingDecoder::DecodingState>
	StreamingDecoder::DecodeSectionPayload::Next(StreamingDecoder* streaming) {
	TRACE_STREAMING("DecodeSectionPayload\n");
	streaming->ProcessSection(section_buffer_);
	if (streaming->ok()) {
	return base::make_unique<DecodeSectionID>(streaming->module_offset());
	}
	return nullptr;
	}

	std::unique_ptr<StreamingDecoder::DecodingState>
	StreamingDecoder::DecodeNumberOfFunctions::NextWithValue(
	StreamingDecoder* streaming) {
	TRACE_STREAMING("DecodeNumberOfFunctions(%zu)\n", value_);
	// Copy the bytes we read into the section buffer.
	if (section_buffer_->payload_length() >= bytes_consumed_) {
	memcpy(section_buffer_->bytes() + section_buffer_->payload_offset(),
	buffer(), bytes_consumed_);
	} else {
	return streaming->Error("Invalid code section length");
	}

	// {value} is the number of functions.
	if (value_ > 0) {
	streaming->StartCodeSection(value_);
	if (!streaming->ok()) return nullptr;
	return base::make_unique<DecodeFunctionLength>(
	section_buffer_, section_buffer_->payload_offset() + bytes_consumed_,
	value_);
	} else {
	if (section_buffer_->payload_length() != bytes_consumed_) {
	return streaming->Error("not all code section bytes were consumed");
	}
	return base::make_unique<DecodeSectionID>(streaming->module_offset());
	}
	}

	std::unique_ptr<StreamingDecoder::DecodingState>
	StreamingDecoder::DecodeFunctionLength::NextWithValue(
	StreamingDecoder* streaming) {
	TRACE_STREAMING("DecodeFunctionLength(%zu)\n", value_);
	// Copy the bytes we consumed into the section buffer.
	if (section_buffer_->length() >= buffer_offset_ + bytes_consumed_) {
	memcpy(section_buffer_->bytes() + buffer_offset_, buffer(),
	bytes_consumed_);
	} else {
	return streaming->Error("Invalid code section length");
	}

	// {value} is the length of the function.
	if (value_ == 0) {
	return streaming->Error("Invalid function length (0)");
	} else if (buffer_offset_ + bytes_consumed_ + value_ >
	section_buffer_->length()) {
	streaming->Error("not enough code section bytes");
	return nullptr;
	}

	return base::make_unique<DecodeFunctionBody>(
	section_buffer_, buffer_offset_ + bytes_consumed_, value_,
	num_remaining_functions_, streaming->module_offset());
	}

	std::unique_ptr<StreamingDecoder::DecodingState>
	StreamingDecoder::DecodeFunctionBody::Next(StreamingDecoder* streaming) {
	TRACE_STREAMING("DecodeFunctionBody\n");
	streaming->ProcessFunctionBody(
	Vector<const uint8_t>(buffer(), static_cast<int>(size())),
	module_offset_);
	if (!streaming->ok()) {
	return nullptr;
	}
	if (num_remaining_functions_ != 0) {
	return base::make_unique<DecodeFunctionLength>(
	section_buffer_, buffer_offset_ + size(), num_remaining_functions_);
	} else {
	if (buffer_offset_ + size() != section_buffer_->length()) {
	return streaming->Error("not all code section bytes were used");
	}
	return base::make_unique<DecodeSectionID>(streaming->module_offset());
	}
	}

	StreamingDecoder::StreamingDecoder(
	std::unique_ptr<StreamingProcessor> processor)
	: processor_(std::move(processor)),
	// A module always starts with a module header.
	state_(new DecodeModuleHeader()) {}
	} // namespace wasm
	} // namespace internal
	} // namespace v8

	#undef TRACE_STREAMING