net/quic/quic_data_stream.cc - platform/external/chromium_org - Git at Google

 // Copyright 2013 The Chromium 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 "net/quic/quic_data_stream.h"

 #include "base/logging.h"
 #include "net/quic/quic_session.h"
 #include "net/quic/quic_spdy_decompressor.h"
 #include "net/spdy/write_blocked_list.h"

 using base::StringPiece;
 using std::min;

 namespace net {

 #define ENDPOINT (session()->is_server() ? "Server: " : " Client: ")

 namespace {

 // This is somewhat arbitrary.  It's possible, but unlikely, we will either fail
 // to set a priority client-side, or cancel a stream before stripping the
 // priority from the wire server-side.  In either case, start out with a
 // priority in the middle.
 QuicPriority kDefaultPriority = 3;

 // Appends bytes from data into partial_data_buffer.  Once partial_data_buffer
 // reaches 4 bytes, copies the data into 'result' and clears
 // partial_data_buffer.
 // Returns the number of bytes consumed.
 uint32 StripUint32(const char* data, uint32 data_len,
                    string* partial_data_buffer,
                    uint32* result) {
   DCHECK_GT(4u, partial_data_buffer->length());
   size_t missing_size = 4 - partial_data_buffer->length();
   if (data_len < missing_size) {
     StringPiece(data, data_len).AppendToString(partial_data_buffer);
     return data_len;
   }
   StringPiece(data, missing_size).AppendToString(partial_data_buffer);
   DCHECK_EQ(4u, partial_data_buffer->length());
   memcpy(result, partial_data_buffer->data(), 4);
   partial_data_buffer->clear();
   return missing_size;
 }

 }  // namespace

 QuicDataStream::QuicDataStream(QuicStreamId id,
                                QuicSession* session)
     : ReliableQuicStream(id, session),
       visitor_(NULL),
       headers_decompressed_(false),
       priority_(kDefaultPriority),
       headers_id_(0),
       decompression_failed_(false),
       priority_parsed_(false) {
   DCHECK_NE(kCryptoStreamId, id);
 }

 QuicDataStream::~QuicDataStream() {
 }

 size_t QuicDataStream::Readv(const struct iovec* iov, size_t iov_len) {
   if (FinishedReadingHeaders()) {
     // If the headers have been read, simply delegate to the sequencer's
     // Readv method.
     return sequencer()->Readv(iov, iov_len);
   }
   // Otherwise, copy decompressed header data into |iov|.
   size_t bytes_consumed = 0;
   size_t iov_index = 0;
   while (iov_index < iov_len &&
          decompressed_headers_.length() > bytes_consumed) {
     size_t bytes_to_read = min(iov[iov_index].iov_len,
                                decompressed_headers_.length() - bytes_consumed);
     char* iov_ptr = static_cast<char*>(iov[iov_index].iov_base);
     memcpy(iov_ptr,
            decompressed_headers_.data() + bytes_consumed, bytes_to_read);
     bytes_consumed += bytes_to_read;
     ++iov_index;
   }
   decompressed_headers_.erase(0, bytes_consumed);
   return bytes_consumed;
 }

 int QuicDataStream::GetReadableRegions(iovec* iov, size_t iov_len) {
   if (FinishedReadingHeaders()) {
     return sequencer()->GetReadableRegions(iov, iov_len);
   }
   if (iov_len == 0) {
     return 0;
   }
   iov[0].iov_base = static_cast<void*>(
       const_cast<char*>(decompressed_headers_.data()));
   iov[0].iov_len = decompressed_headers_.length();
   return 1;
 }

 bool QuicDataStream::IsDoneReading() const {
   if (!headers_decompressed_ || !decompressed_headers_.empty()) {
     return false;
   }
   return sequencer()->IsClosed();
 }

 bool QuicDataStream::HasBytesToRead() const {
   return !decompressed_headers_.empty() || sequencer()->HasBytesToRead();
 }

 void QuicDataStream::set_priority(QuicPriority priority) {
   DCHECK_EQ(0u, stream_bytes_written());
   priority_ = priority;
 }

 QuicPriority QuicDataStream::EffectivePriority() const {
   return priority();
 }

 uint32 QuicDataStream::ProcessRawData(const char* data, uint32 data_len) {
   DCHECK_NE(0u, data_len);

   uint32 total_bytes_consumed = 0;
   if (headers_id_ == 0u) {
     total_bytes_consumed += StripPriorityAndHeaderId(data, data_len);
     data += total_bytes_consumed;
     data_len -= total_bytes_consumed;
     if (data_len == 0 || total_bytes_consumed == 0) {
       return total_bytes_consumed;
     }
   }
   DCHECK_NE(0u, headers_id_);

   // Once the headers are finished, we simply pass the data through.
   if (headers_decompressed_) {
     // Some buffered header data remains.
     if (!decompressed_headers_.empty()) {
       ProcessHeaderData();
     }
     if (decompressed_headers_.empty()) {
       DVLOG(1) << "Delegating procesing to ProcessData";
       total_bytes_consumed += ProcessData(data, data_len);
     }
     return total_bytes_consumed;
   }

   QuicHeaderId current_header_id =
       session()->decompressor()->current_header_id();
   // Ensure that this header id looks sane.
   if (headers_id_ < current_header_id ||
       headers_id_ > kMaxHeaderIdDelta + current_header_id) {
     DVLOG(1) << ENDPOINT
              << "Invalid headers for stream: " << id()
              << " header_id: " << headers_id_
              << " current_header_id: " << current_header_id;
     session()->connection()->SendConnectionClose(QUIC_INVALID_HEADER_ID);
     return total_bytes_consumed;
   }

   // If we are head-of-line blocked on decompression, then back up.
   if (current_header_id != headers_id_) {
     session()->MarkDecompressionBlocked(headers_id_, id());
     DVLOG(1) << ENDPOINT
              << "Unable to decompress header data for stream: " << id()
              << " header_id: " << headers_id_;
     return total_bytes_consumed;
   }

   // Decompressed data will be delivered to decompressed_headers_.
   size_t bytes_consumed = session()->decompressor()->DecompressData(
       StringPiece(data, data_len), this);
   DCHECK_NE(0u, bytes_consumed);
   if (bytes_consumed > data_len) {
     DCHECK(false) << "DecompressData returned illegal value";
     OnDecompressionError();
     return total_bytes_consumed;
   }
   total_bytes_consumed += bytes_consumed;
   data += bytes_consumed;
   data_len -= bytes_consumed;

   if (decompression_failed_) {
     // The session will have been closed in OnDecompressionError.
     return total_bytes_consumed;
   }

   // Headers are complete if the decompressor has moved on to the
   // next stream.
   headers_decompressed_ =
       session()->decompressor()->current_header_id() != headers_id_;
   if (!headers_decompressed_) {
     DCHECK_EQ(0u, data_len);
   }

   ProcessHeaderData();

   if (!headers_decompressed_ || !decompressed_headers_.empty()) {
     return total_bytes_consumed;
   }

   // We have processed all of the decompressed data but we might
   // have some more raw data to process.
   if (data_len > 0) {
     total_bytes_consumed += ProcessData(data, data_len);
   }

   // The sequencer will push any additional buffered frames if this data
   // has been completely consumed.
   return total_bytes_consumed;
 }

 const IPEndPoint& QuicDataStream::GetPeerAddress() {
   return session()->peer_address();
 }

 QuicSpdyCompressor* QuicDataStream::compressor() {
   return session()->compressor();
 }

 bool QuicDataStream::GetSSLInfo(SSLInfo* ssl_info) {
   return session()->GetSSLInfo(ssl_info);
 }

 uint32 QuicDataStream::ProcessHeaderData() {
   if (decompressed_headers_.empty()) {
     return 0;
   }

   size_t bytes_processed = ProcessData(decompressed_headers_.data(),
                                        decompressed_headers_.length());
   if (bytes_processed == decompressed_headers_.length()) {
     decompressed_headers_.clear();
   } else {
     decompressed_headers_ = decompressed_headers_.erase(0, bytes_processed);
   }
   return bytes_processed;
 }

 void QuicDataStream::OnDecompressorAvailable() {
   DCHECK_EQ(headers_id_,
             session()->decompressor()->current_header_id());
   DCHECK(!headers_decompressed_);
   DCHECK(!decompression_failed_);
   DCHECK_EQ(0u, decompressed_headers_.length());

   while (!headers_decompressed_) {
     struct iovec iovec;
     if (sequencer()->GetReadableRegions(&iovec, 1) == 0) {
       return;
     }

     size_t bytes_consumed = session()->decompressor()->DecompressData(
         StringPiece(static_cast<char*>(iovec.iov_base),
                     iovec.iov_len),
         this);
     DCHECK_LE(bytes_consumed, iovec.iov_len);
     if (decompression_failed_) {
       return;
     }
     sequencer()->MarkConsumed(bytes_consumed);

     headers_decompressed_ =
         session()->decompressor()->current_header_id() != headers_id_;
   }

   // Either the headers are complete, or the all data as been consumed.
   ProcessHeaderData();  // Unprocessed headers remain in decompressed_headers_.
   if (IsDoneReading()) {
     OnFinRead();
   } else if (FinishedReadingHeaders()) {
     sequencer()->FlushBufferedFrames();
   }
 }

 bool QuicDataStream::OnDecompressedData(StringPiece data) {
   data.AppendToString(&decompressed_headers_);
   return true;
 }

 void QuicDataStream::OnDecompressionError() {
   DCHECK(!decompression_failed_);
   decompression_failed_ = true;
   session()->connection()->SendConnectionClose(QUIC_DECOMPRESSION_FAILURE);
 }

 void QuicDataStream::OnClose() {
   ReliableQuicStream::OnClose();

   if (visitor_) {
     Visitor* visitor = visitor_;
     // Calling Visitor::OnClose() may result the destruction of the visitor,
     // so we need to ensure we don't call it again.
     visitor_ = NULL;
     visitor->OnClose(this);
   }
 }

 uint32 QuicDataStream::StripPriorityAndHeaderId(
     const char* data, uint32 data_len) {
   uint32 total_bytes_parsed = 0;

   if (!priority_parsed_ && session()->connection()->is_server()) {
     QuicPriority temporary_priority = priority_;
     total_bytes_parsed = StripUint32(
         data, data_len, &headers_id_and_priority_buffer_, &temporary_priority);
     if (total_bytes_parsed > 0 && headers_id_and_priority_buffer_.size() == 0) {
       priority_parsed_ = true;

       // Spdy priorities are inverted, so the highest numerical value is the
       // lowest legal priority.
       if (temporary_priority > QuicUtils::LowestPriority()) {
         session()->connection()->SendConnectionClose(QUIC_INVALID_PRIORITY);
         return 0;
       }
       priority_ = temporary_priority;
     }
     data += total_bytes_parsed;
     data_len -= total_bytes_parsed;
   }
   if (data_len > 0 && headers_id_ == 0u) {
     // The headers ID has not yet been read.  Strip it from the beginning of
     // the data stream.
     total_bytes_parsed += StripUint32(
         data, data_len, &headers_id_and_priority_buffer_, &headers_id_);
   }
   return total_bytes_parsed;
 }

 bool QuicDataStream::FinishedReadingHeaders() {
   return headers_decompressed_ && decompressed_headers_.empty();
 }

 }  // namespace net
	// Copyright 2013 The Chromium 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 "net/quic/quic_data_stream.h"

	#include "base/logging.h"
	#include "net/quic/quic_session.h"
	#include "net/quic/quic_spdy_decompressor.h"
	#include "net/spdy/write_blocked_list.h"

	using base::StringPiece;
	using std::min;

	namespace net {

	#define ENDPOINT (session()->is_server() ? "Server: " : " Client: ")

	namespace {

	// This is somewhat arbitrary. It's possible, but unlikely, we will either fail
	// to set a priority client-side, or cancel a stream before stripping the
	// priority from the wire server-side. In either case, start out with a
	// priority in the middle.
	QuicPriority kDefaultPriority = 3;

	// Appends bytes from data into partial_data_buffer. Once partial_data_buffer
	// reaches 4 bytes, copies the data into 'result' and clears
	// partial_data_buffer.
	// Returns the number of bytes consumed.
	uint32 StripUint32(const char* data, uint32 data_len,
	string* partial_data_buffer,
	uint32* result) {
	DCHECK_GT(4u, partial_data_buffer->length());
	size_t missing_size = 4 - partial_data_buffer->length();
	if (data_len < missing_size) {
	StringPiece(data, data_len).AppendToString(partial_data_buffer);
	return data_len;
	}
	StringPiece(data, missing_size).AppendToString(partial_data_buffer);
	DCHECK_EQ(4u, partial_data_buffer->length());
	memcpy(result, partial_data_buffer->data(), 4);
	partial_data_buffer->clear();
	return missing_size;
	}

	} // namespace

	QuicDataStream::QuicDataStream(QuicStreamId id,
	QuicSession* session)
	: ReliableQuicStream(id, session),
	visitor_(NULL),
	headers_decompressed_(false),
	priority_(kDefaultPriority),
	headers_id_(0),
	decompression_failed_(false),
	priority_parsed_(false) {
	DCHECK_NE(kCryptoStreamId, id);
	}

	QuicDataStream::~QuicDataStream() {
	}

	size_t QuicDataStream::Readv(const struct iovec* iov, size_t iov_len) {
	if (FinishedReadingHeaders()) {
	// If the headers have been read, simply delegate to the sequencer's
	// Readv method.
	return sequencer()->Readv(iov, iov_len);
	}
	// Otherwise, copy decompressed header data into \|iov\|.
	size_t bytes_consumed = 0;
	size_t iov_index = 0;
	while (iov_index < iov_len &&
	decompressed_headers_.length() > bytes_consumed) {
	size_t bytes_to_read = min(iov[iov_index].iov_len,
	decompressed_headers_.length() - bytes_consumed);
	char* iov_ptr = static_cast<char*>(iov[iov_index].iov_base);
	memcpy(iov_ptr,
	decompressed_headers_.data() + bytes_consumed, bytes_to_read);
	bytes_consumed += bytes_to_read;
	++iov_index;
	}
	decompressed_headers_.erase(0, bytes_consumed);
	return bytes_consumed;
	}

	int QuicDataStream::GetReadableRegions(iovec* iov, size_t iov_len) {
	if (FinishedReadingHeaders()) {
	return sequencer()->GetReadableRegions(iov, iov_len);
	}
	if (iov_len == 0) {
	return 0;
	}
	iov[0].iov_base = static_cast<void*>(
	const_cast<char*>(decompressed_headers_.data()));
	iov[0].iov_len = decompressed_headers_.length();
	return 1;
	}

	bool QuicDataStream::IsDoneReading() const {
	if (!headers_decompressed_ \|\| !decompressed_headers_.empty()) {
	return false;
	}
	return sequencer()->IsClosed();
	}

	bool QuicDataStream::HasBytesToRead() const {
	return !decompressed_headers_.empty() \|\| sequencer()->HasBytesToRead();
	}

	void QuicDataStream::set_priority(QuicPriority priority) {
	DCHECK_EQ(0u, stream_bytes_written());
	priority_ = priority;
	}

	QuicPriority QuicDataStream::EffectivePriority() const {
	return priority();
	}

	uint32 QuicDataStream::ProcessRawData(const char* data, uint32 data_len) {
	DCHECK_NE(0u, data_len);

	uint32 total_bytes_consumed = 0;
	if (headers_id_ == 0u) {
	total_bytes_consumed += StripPriorityAndHeaderId(data, data_len);
	data += total_bytes_consumed;
	data_len -= total_bytes_consumed;
	if (data_len == 0 \|\| total_bytes_consumed == 0) {
	return total_bytes_consumed;
	}
	}
	DCHECK_NE(0u, headers_id_);

	// Once the headers are finished, we simply pass the data through.
	if (headers_decompressed_) {
	// Some buffered header data remains.
	if (!decompressed_headers_.empty()) {
	ProcessHeaderData();
	}
	if (decompressed_headers_.empty()) {
	DVLOG(1) << "Delegating procesing to ProcessData";
	total_bytes_consumed += ProcessData(data, data_len);
	}
	return total_bytes_consumed;
	}

	QuicHeaderId current_header_id =
	session()->decompressor()->current_header_id();
	// Ensure that this header id looks sane.
	if (headers_id_ < current_header_id \|\|
	headers_id_ > kMaxHeaderIdDelta + current_header_id) {
	DVLOG(1) << ENDPOINT
	<< "Invalid headers for stream: " << id()
	<< " header_id: " << headers_id_
	<< " current_header_id: " << current_header_id;
	session()->connection()->SendConnectionClose(QUIC_INVALID_HEADER_ID);
	return total_bytes_consumed;
	}

	// If we are head-of-line blocked on decompression, then back up.
	if (current_header_id != headers_id_) {
	session()->MarkDecompressionBlocked(headers_id_, id());
	DVLOG(1) << ENDPOINT
	<< "Unable to decompress header data for stream: " << id()
	<< " header_id: " << headers_id_;
	return total_bytes_consumed;
	}

	// Decompressed data will be delivered to decompressed_headers_.
	size_t bytes_consumed = session()->decompressor()->DecompressData(
	StringPiece(data, data_len), this);
	DCHECK_NE(0u, bytes_consumed);
	if (bytes_consumed > data_len) {
	DCHECK(false) << "DecompressData returned illegal value";
	OnDecompressionError();
	return total_bytes_consumed;
	}
	total_bytes_consumed += bytes_consumed;
	data += bytes_consumed;
	data_len -= bytes_consumed;

	if (decompression_failed_) {
	// The session will have been closed in OnDecompressionError.
	return total_bytes_consumed;
	}

	// Headers are complete if the decompressor has moved on to the
	// next stream.
	headers_decompressed_ =
	session()->decompressor()->current_header_id() != headers_id_;
	if (!headers_decompressed_) {
	DCHECK_EQ(0u, data_len);
	}

	ProcessHeaderData();

	if (!headers_decompressed_ \|\| !decompressed_headers_.empty()) {
	return total_bytes_consumed;
	}

	// We have processed all of the decompressed data but we might
	// have some more raw data to process.
	if (data_len > 0) {
	total_bytes_consumed += ProcessData(data, data_len);
	}

	// The sequencer will push any additional buffered frames if this data
	// has been completely consumed.
	return total_bytes_consumed;
	}

	const IPEndPoint& QuicDataStream::GetPeerAddress() {
	return session()->peer_address();
	}

	QuicSpdyCompressor* QuicDataStream::compressor() {
	return session()->compressor();
	}

	bool QuicDataStream::GetSSLInfo(SSLInfo* ssl_info) {
	return session()->GetSSLInfo(ssl_info);
	}

	uint32 QuicDataStream::ProcessHeaderData() {
	if (decompressed_headers_.empty()) {
	return 0;
	}

	size_t bytes_processed = ProcessData(decompressed_headers_.data(),
	decompressed_headers_.length());
	if (bytes_processed == decompressed_headers_.length()) {
	decompressed_headers_.clear();
	} else {
	decompressed_headers_ = decompressed_headers_.erase(0, bytes_processed);
	}
	return bytes_processed;
	}

	void QuicDataStream::OnDecompressorAvailable() {
	DCHECK_EQ(headers_id_,
	session()->decompressor()->current_header_id());
	DCHECK(!headers_decompressed_);
	DCHECK(!decompression_failed_);
	DCHECK_EQ(0u, decompressed_headers_.length());

	while (!headers_decompressed_) {
	struct iovec iovec;
	if (sequencer()->GetReadableRegions(&iovec, 1) == 0) {
	return;
	}

	size_t bytes_consumed = session()->decompressor()->DecompressData(
	StringPiece(static_cast<char*>(iovec.iov_base),
	iovec.iov_len),
	this);
	DCHECK_LE(bytes_consumed, iovec.iov_len);
	if (decompression_failed_) {
	return;
	}
	sequencer()->MarkConsumed(bytes_consumed);

	headers_decompressed_ =
	session()->decompressor()->current_header_id() != headers_id_;
	}

	// Either the headers are complete, or the all data as been consumed.
	ProcessHeaderData(); // Unprocessed headers remain in decompressed_headers_.
	if (IsDoneReading()) {
	OnFinRead();
	} else if (FinishedReadingHeaders()) {
	sequencer()->FlushBufferedFrames();
	}
	}

	bool QuicDataStream::OnDecompressedData(StringPiece data) {
	data.AppendToString(&decompressed_headers_);
	return true;
	}

	void QuicDataStream::OnDecompressionError() {
	DCHECK(!decompression_failed_);
	decompression_failed_ = true;
	session()->connection()->SendConnectionClose(QUIC_DECOMPRESSION_FAILURE);
	}

	void QuicDataStream::OnClose() {
	ReliableQuicStream::OnClose();

	if (visitor_) {
	Visitor* visitor = visitor_;
	// Calling Visitor::OnClose() may result the destruction of the visitor,
	// so we need to ensure we don't call it again.
	visitor_ = NULL;
	visitor->OnClose(this);
	}
	}

	uint32 QuicDataStream::StripPriorityAndHeaderId(
	const char* data, uint32 data_len) {
	uint32 total_bytes_parsed = 0;

	if (!priority_parsed_ && session()->connection()->is_server()) {
	QuicPriority temporary_priority = priority_;
	total_bytes_parsed = StripUint32(
	data, data_len, &headers_id_and_priority_buffer_, &temporary_priority);
	if (total_bytes_parsed > 0 && headers_id_and_priority_buffer_.size() == 0) {
	priority_parsed_ = true;

	// Spdy priorities are inverted, so the highest numerical value is the
	// lowest legal priority.
	if (temporary_priority > QuicUtils::LowestPriority()) {
	session()->connection()->SendConnectionClose(QUIC_INVALID_PRIORITY);
	return 0;
	}
	priority_ = temporary_priority;
	}
	data += total_bytes_parsed;
	data_len -= total_bytes_parsed;
	}
	if (data_len > 0 && headers_id_ == 0u) {
	// The headers ID has not yet been read. Strip it from the beginning of
	// the data stream.
	total_bytes_parsed += StripUint32(
	data, data_len, &headers_id_and_priority_buffer_, &headers_id_);
	}
	return total_bytes_parsed;
	}

	bool QuicDataStream::FinishedReadingHeaders() {
	return headers_decompressed_ && decompressed_headers_.empty();
	}

	} // namespace net