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

 // Copyright (c) 2012 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_stream_sequencer.h"

 #include <algorithm>
 #include <limits>

 #include "base/logging.h"
 #include "net/quic/reliable_quic_stream.h"

 using std::min;
 using std::numeric_limits;

 namespace net {

 QuicStreamSequencer::QuicStreamSequencer(ReliableQuicStream* quic_stream)
     : stream_(quic_stream),
       num_bytes_consumed_(0),
       max_frame_memory_(numeric_limits<size_t>::max()),
       close_offset_(numeric_limits<QuicStreamOffset>::max()) {
 }

 QuicStreamSequencer::QuicStreamSequencer(size_t max_frame_memory,
                                          ReliableQuicStream* quic_stream)
     : stream_(quic_stream),
       num_bytes_consumed_(0),
       max_frame_memory_(max_frame_memory),
       close_offset_(numeric_limits<QuicStreamOffset>::max()) {
   if (max_frame_memory < kMaxPacketSize) {
     LOG(DFATAL) << "Setting max frame memory to " << max_frame_memory
                 << ".  Some frames will be impossible to handle.";
   }
 }

 QuicStreamSequencer::~QuicStreamSequencer() {
 }

 bool QuicStreamSequencer::WillAcceptStreamFrame(
     const QuicStreamFrame& frame) const {
   size_t data_len = frame.data.TotalBufferSize();
   DCHECK_LE(data_len, max_frame_memory_);

   if (IsDuplicate(frame)) {
     return true;
   }
   QuicStreamOffset byte_offset = frame.offset;
   if (data_len > max_frame_memory_) {
     // We're never going to buffer this frame and we can't pass it up.
     // The stream might only consume part of it and we'd need a partial ack.
     //
     // Ideally this should never happen, as we check that
     // max_frame_memory_ > kMaxPacketSize and lower levels should reject
     // frames larger than that.
     return false;
   }
   if (byte_offset + data_len - num_bytes_consumed_ > max_frame_memory_) {
     // We can buffer this but not right now.  Toss it.
     // It might be worth trying an experiment where we try best-effort buffering
     return false;
   }
   return true;
 }

 bool QuicStreamSequencer::OnStreamFrame(const QuicStreamFrame& frame) {
   if (!WillAcceptStreamFrame(frame)) {
     // This should not happen, as WillAcceptFrame should be called before
     // OnStreamFrame.  Error handling should be done by the caller.
     return false;
   }
   if (IsDuplicate(frame)) {
     // Silently ignore duplicates.
     return true;
   }

   QuicStreamOffset byte_offset = frame.offset;
   size_t data_len = frame.data.TotalBufferSize();
   if (data_len == 0 && !frame.fin) {
     // Stream frames must have data or a fin flag.
     stream_->CloseConnectionWithDetails(QUIC_INVALID_STREAM_FRAME,
                                         "Empty stream frame without FIN set.");
     return false;
   }

   if (frame.fin) {
     CloseStreamAtOffset(frame.offset + data_len);
     if (data_len == 0) {
       return true;
     }
   }

   IOVector data;
   data.AppendIovec(frame.data.iovec(), frame.data.Size());
   if (byte_offset == num_bytes_consumed_) {
     DVLOG(1) << "Processing byte offset " << byte_offset;
     size_t bytes_consumed = 0;
     for (size_t i = 0; i < data.Size(); ++i) {
       bytes_consumed += stream_->ProcessRawData(
           static_cast<char*>(data.iovec()[i].iov_base),
           data.iovec()[i].iov_len);
     }
     num_bytes_consumed_ += bytes_consumed;
     if (MaybeCloseStream()) {
       return true;
     }
     if (bytes_consumed > data_len) {
       stream_->Reset(QUIC_ERROR_PROCESSING_STREAM);
       return false;
     } else if (bytes_consumed == data_len) {
       FlushBufferedFrames();
       return true;  // it's safe to ack this frame.
     } else {
       // Set ourselves up to buffer what's left
       data_len -= bytes_consumed;
       data.Consume(bytes_consumed);
       byte_offset += bytes_consumed;
     }
   }
   for (size_t i = 0; i < data.Size(); ++i) {
     DVLOG(1) << "Buffering stream data at offset " << byte_offset;
     frames_.insert(make_pair(byte_offset, string(
         static_cast<char*>(data.iovec()[i].iov_base),
         data.iovec()[i].iov_len)));
     byte_offset += data.iovec()[i].iov_len;
   }
   return true;
 }

 void QuicStreamSequencer::CloseStreamAtOffset(QuicStreamOffset offset) {
   const QuicStreamOffset kMaxOffset = numeric_limits<QuicStreamOffset>::max();

   // If we have a scheduled termination or close, any new offset should match
   // it.
   if (close_offset_ != kMaxOffset && offset != close_offset_) {
     stream_->Reset(QUIC_MULTIPLE_TERMINATION_OFFSETS);
     return;
   }

   close_offset_ = offset;

   MaybeCloseStream();
 }

 bool QuicStreamSequencer::MaybeCloseStream() {
   if (IsClosed()) {
     DVLOG(1) << "Passing up termination, as we've processed "
              << num_bytes_consumed_ << " of " << close_offset_
              << " bytes.";
     // Technically it's an error if num_bytes_consumed isn't exactly
     // equal, but error handling seems silly at this point.
     stream_->OnFinRead();
     return true;
   }
   return false;
 }

 int QuicStreamSequencer::GetReadableRegions(iovec* iov, size_t iov_len) {
   FrameMap::iterator it = frames_.begin();
   size_t index = 0;
   QuicStreamOffset offset = num_bytes_consumed_;
   while (it != frames_.end() && index < iov_len) {
     if (it->first != offset) return index;

     iov[index].iov_base = static_cast<void*>(
         const_cast<char*>(it->second.data()));
     iov[index].iov_len = it->second.size();
     offset += it->second.size();

     ++index;
     ++it;
   }
   return index;
 }

 int QuicStreamSequencer::Readv(const struct iovec* iov, size_t iov_len) {
   FrameMap::iterator it = frames_.begin();
   size_t iov_index = 0;
   size_t iov_offset = 0;
   size_t frame_offset = 0;
   size_t initial_bytes_consumed = num_bytes_consumed_;

   while (iov_index < iov_len &&
          it != frames_.end() &&
          it->first == num_bytes_consumed_) {
     int bytes_to_read = min(iov[iov_index].iov_len - iov_offset,
                             it->second.size() - frame_offset);

     char* iov_ptr = static_cast<char*>(iov[iov_index].iov_base) + iov_offset;
     memcpy(iov_ptr,
            it->second.data() + frame_offset, bytes_to_read);
     frame_offset += bytes_to_read;
     iov_offset += bytes_to_read;

     if (iov[iov_index].iov_len == iov_offset) {
       // We've filled this buffer.
       iov_offset = 0;
       ++iov_index;
     }
     if (it->second.size() == frame_offset) {
       // We've copied this whole frame
       num_bytes_consumed_ += it->second.size();
       frames_.erase(it);
       it = frames_.begin();
       frame_offset = 0;
     }
   }
   // We've finished copying.  If we have a partial frame, update it.
   if (frame_offset != 0) {
     frames_.insert(make_pair(it->first + frame_offset,
                              it->second.substr(frame_offset)));
     frames_.erase(frames_.begin());
     num_bytes_consumed_ += frame_offset;
   }
   return num_bytes_consumed_ - initial_bytes_consumed;
 }

 void QuicStreamSequencer::MarkConsumed(size_t num_bytes_consumed) {
   size_t end_offset = num_bytes_consumed_ + num_bytes_consumed;
   while (!frames_.empty() && end_offset != num_bytes_consumed_) {
     FrameMap::iterator it = frames_.begin();
     if (it->first != num_bytes_consumed_) {
       LOG(DFATAL) << "Invalid argument to MarkConsumed. "
                   << " num_bytes_consumed_: " << num_bytes_consumed_
                   << " end_offset: " << end_offset
                   << " offset: " << it->first
                   << " length: " << it->second.length();
       stream_->Reset(QUIC_ERROR_PROCESSING_STREAM);
       return;
     }

     if (it->first + it->second.length() <= end_offset) {
       num_bytes_consumed_ += it->second.length();
       // This chunk is entirely consumed.
       frames_.erase(it);
       continue;
     }

     // Partially consume this frame.
     size_t delta = end_offset - it->first;
     num_bytes_consumed_ += delta;
     frames_.insert(make_pair(end_offset, it->second.substr(delta)));
     frames_.erase(it);
     break;
   }
 }

 bool QuicStreamSequencer::HasBytesToRead() const {
   FrameMap::const_iterator it = frames_.begin();

   return it != frames_.end() && it->first == num_bytes_consumed_;
 }

 bool QuicStreamSequencer::IsClosed() const {
   return num_bytes_consumed_ >= close_offset_;
 }

 bool QuicStreamSequencer::IsDuplicate(const QuicStreamFrame& frame) const {
   // A frame is duplicate if the frame offset is smaller than our bytes consumed
   // or we have stored the frame in our map.
   // TODO(pwestin): Is it possible that a new frame contain more data even if
   // the offset is the same?
   return frame.offset < num_bytes_consumed_ ||
       frames_.find(frame.offset) != frames_.end();
 }

 void QuicStreamSequencer::FlushBufferedFrames() {
   FrameMap::iterator it = frames_.find(num_bytes_consumed_);
   while (it != frames_.end()) {
     DVLOG(1) << "Flushing buffered packet at offset " << it->first;
     string* data = &it->second;
     size_t bytes_consumed = stream_->ProcessRawData(data->c_str(),
                                                     data->size());
     num_bytes_consumed_ += bytes_consumed;
     if (MaybeCloseStream()) {
       return;
     }
     if (bytes_consumed > data->size()) {
       stream_->Reset(QUIC_ERROR_PROCESSING_STREAM);  // Programming error
       return;
     } else if (bytes_consumed == data->size()) {
       frames_.erase(it);
       it = frames_.find(num_bytes_consumed_);
     } else {
       string new_data = it->second.substr(bytes_consumed);
       frames_.erase(it);
       frames_.insert(make_pair(num_bytes_consumed_, new_data));
       return;
     }
   }
 }

 }  // namespace net
	// Copyright (c) 2012 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_stream_sequencer.h"

	#include <algorithm>
	#include <limits>

	#include "base/logging.h"
	#include "net/quic/reliable_quic_stream.h"

	using std::min;
	using std::numeric_limits;

	namespace net {

	QuicStreamSequencer::QuicStreamSequencer(ReliableQuicStream* quic_stream)
	: stream_(quic_stream),
	num_bytes_consumed_(0),
	max_frame_memory_(numeric_limits<size_t>::max()),
	close_offset_(numeric_limits<QuicStreamOffset>::max()) {
	}

	QuicStreamSequencer::QuicStreamSequencer(size_t max_frame_memory,
	ReliableQuicStream* quic_stream)
	: stream_(quic_stream),
	num_bytes_consumed_(0),
	max_frame_memory_(max_frame_memory),
	close_offset_(numeric_limits<QuicStreamOffset>::max()) {
	if (max_frame_memory < kMaxPacketSize) {
	LOG(DFATAL) << "Setting max frame memory to " << max_frame_memory
	<< ". Some frames will be impossible to handle.";
	}
	}

	QuicStreamSequencer::~QuicStreamSequencer() {
	}

	bool QuicStreamSequencer::WillAcceptStreamFrame(
	const QuicStreamFrame& frame) const {
	size_t data_len = frame.data.TotalBufferSize();
	DCHECK_LE(data_len, max_frame_memory_);

	if (IsDuplicate(frame)) {
	return true;
	}
	QuicStreamOffset byte_offset = frame.offset;
	if (data_len > max_frame_memory_) {
	// We're never going to buffer this frame and we can't pass it up.
	// The stream might only consume part of it and we'd need a partial ack.
	//
	// Ideally this should never happen, as we check that
	// max_frame_memory_ > kMaxPacketSize and lower levels should reject
	// frames larger than that.
	return false;
	}
	if (byte_offset + data_len - num_bytes_consumed_ > max_frame_memory_) {
	// We can buffer this but not right now. Toss it.
	// It might be worth trying an experiment where we try best-effort buffering
	return false;
	}
	return true;
	}

	bool QuicStreamSequencer::OnStreamFrame(const QuicStreamFrame& frame) {
	if (!WillAcceptStreamFrame(frame)) {
	// This should not happen, as WillAcceptFrame should be called before
	// OnStreamFrame. Error handling should be done by the caller.
	return false;
	}
	if (IsDuplicate(frame)) {
	// Silently ignore duplicates.
	return true;
	}

	QuicStreamOffset byte_offset = frame.offset;
	size_t data_len = frame.data.TotalBufferSize();
	if (data_len == 0 && !frame.fin) {
	// Stream frames must have data or a fin flag.
	stream_->CloseConnectionWithDetails(QUIC_INVALID_STREAM_FRAME,
	"Empty stream frame without FIN set.");
	return false;
	}

	if (frame.fin) {
	CloseStreamAtOffset(frame.offset + data_len);
	if (data_len == 0) {
	return true;
	}
	}

	IOVector data;
	data.AppendIovec(frame.data.iovec(), frame.data.Size());
	if (byte_offset == num_bytes_consumed_) {
	DVLOG(1) << "Processing byte offset " << byte_offset;
	size_t bytes_consumed = 0;
	for (size_t i = 0; i < data.Size(); ++i) {
	bytes_consumed += stream_->ProcessRawData(
	static_cast<char*>(data.iovec()[i].iov_base),
	data.iovec()[i].iov_len);
	}
	num_bytes_consumed_ += bytes_consumed;
	if (MaybeCloseStream()) {
	return true;
	}
	if (bytes_consumed > data_len) {
	stream_->Reset(QUIC_ERROR_PROCESSING_STREAM);
	return false;
	} else if (bytes_consumed == data_len) {
	FlushBufferedFrames();
	return true; // it's safe to ack this frame.
	} else {
	// Set ourselves up to buffer what's left
	data_len -= bytes_consumed;
	data.Consume(bytes_consumed);
	byte_offset += bytes_consumed;
	}
	}
	for (size_t i = 0; i < data.Size(); ++i) {
	DVLOG(1) << "Buffering stream data at offset " << byte_offset;
	frames_.insert(make_pair(byte_offset, string(
	static_cast<char*>(data.iovec()[i].iov_base),
	data.iovec()[i].iov_len)));
	byte_offset += data.iovec()[i].iov_len;
	}
	return true;
	}

	void QuicStreamSequencer::CloseStreamAtOffset(QuicStreamOffset offset) {
	const QuicStreamOffset kMaxOffset = numeric_limits<QuicStreamOffset>::max();

	// If we have a scheduled termination or close, any new offset should match
	// it.
	if (close_offset_ != kMaxOffset && offset != close_offset_) {
	stream_->Reset(QUIC_MULTIPLE_TERMINATION_OFFSETS);
	return;
	}

	close_offset_ = offset;

	MaybeCloseStream();
	}

	bool QuicStreamSequencer::MaybeCloseStream() {
	if (IsClosed()) {
	DVLOG(1) << "Passing up termination, as we've processed "
	<< num_bytes_consumed_ << " of " << close_offset_
	<< " bytes.";
	// Technically it's an error if num_bytes_consumed isn't exactly
	// equal, but error handling seems silly at this point.
	stream_->OnFinRead();
	return true;
	}
	return false;
	}

	int QuicStreamSequencer::GetReadableRegions(iovec* iov, size_t iov_len) {
	FrameMap::iterator it = frames_.begin();
	size_t index = 0;
	QuicStreamOffset offset = num_bytes_consumed_;
	while (it != frames_.end() && index < iov_len) {
	if (it->first != offset) return index;

	iov[index].iov_base = static_cast<void*>(
	const_cast<char*>(it->second.data()));
	iov[index].iov_len = it->second.size();
	offset += it->second.size();

	++index;
	++it;
	}
	return index;
	}

	int QuicStreamSequencer::Readv(const struct iovec* iov, size_t iov_len) {
	FrameMap::iterator it = frames_.begin();
	size_t iov_index = 0;
	size_t iov_offset = 0;
	size_t frame_offset = 0;
	size_t initial_bytes_consumed = num_bytes_consumed_;

	while (iov_index < iov_len &&
	it != frames_.end() &&
	it->first == num_bytes_consumed_) {
	int bytes_to_read = min(iov[iov_index].iov_len - iov_offset,
	it->second.size() - frame_offset);

	char* iov_ptr = static_cast<char*>(iov[iov_index].iov_base) + iov_offset;
	memcpy(iov_ptr,
	it->second.data() + frame_offset, bytes_to_read);
	frame_offset += bytes_to_read;
	iov_offset += bytes_to_read;

	if (iov[iov_index].iov_len == iov_offset) {
	// We've filled this buffer.
	iov_offset = 0;
	++iov_index;
	}
	if (it->second.size() == frame_offset) {
	// We've copied this whole frame
	num_bytes_consumed_ += it->second.size();
	frames_.erase(it);
	it = frames_.begin();
	frame_offset = 0;
	}
	}
	// We've finished copying. If we have a partial frame, update it.
	if (frame_offset != 0) {
	frames_.insert(make_pair(it->first + frame_offset,
	it->second.substr(frame_offset)));
	frames_.erase(frames_.begin());
	num_bytes_consumed_ += frame_offset;
	}
	return num_bytes_consumed_ - initial_bytes_consumed;
	}

	void QuicStreamSequencer::MarkConsumed(size_t num_bytes_consumed) {
	size_t end_offset = num_bytes_consumed_ + num_bytes_consumed;
	while (!frames_.empty() && end_offset != num_bytes_consumed_) {
	FrameMap::iterator it = frames_.begin();
	if (it->first != num_bytes_consumed_) {
	LOG(DFATAL) << "Invalid argument to MarkConsumed. "
	<< " num_bytes_consumed_: " << num_bytes_consumed_
	<< " end_offset: " << end_offset
	<< " offset: " << it->first
	<< " length: " << it->second.length();
	stream_->Reset(QUIC_ERROR_PROCESSING_STREAM);
	return;
	}

	if (it->first + it->second.length() <= end_offset) {
	num_bytes_consumed_ += it->second.length();
	// This chunk is entirely consumed.
	frames_.erase(it);
	continue;
	}

	// Partially consume this frame.
	size_t delta = end_offset - it->first;
	num_bytes_consumed_ += delta;
	frames_.insert(make_pair(end_offset, it->second.substr(delta)));
	frames_.erase(it);
	break;
	}
	}

	bool QuicStreamSequencer::HasBytesToRead() const {
	FrameMap::const_iterator it = frames_.begin();

	return it != frames_.end() && it->first == num_bytes_consumed_;
	}

	bool QuicStreamSequencer::IsClosed() const {
	return num_bytes_consumed_ >= close_offset_;
	}

	bool QuicStreamSequencer::IsDuplicate(const QuicStreamFrame& frame) const {
	// A frame is duplicate if the frame offset is smaller than our bytes consumed
	// or we have stored the frame in our map.
	// TODO(pwestin): Is it possible that a new frame contain more data even if
	// the offset is the same?
	return frame.offset < num_bytes_consumed_ \|\|
	frames_.find(frame.offset) != frames_.end();
	}

	void QuicStreamSequencer::FlushBufferedFrames() {
	FrameMap::iterator it = frames_.find(num_bytes_consumed_);
	while (it != frames_.end()) {
	DVLOG(1) << "Flushing buffered packet at offset " << it->first;
	string* data = &it->second;
	size_t bytes_consumed = stream_->ProcessRawData(data->c_str(),
	data->size());
	num_bytes_consumed_ += bytes_consumed;
	if (MaybeCloseStream()) {
	return;
	}
	if (bytes_consumed > data->size()) {
	stream_->Reset(QUIC_ERROR_PROCESSING_STREAM); // Programming error
	return;
	} else if (bytes_consumed == data->size()) {
	frames_.erase(it);
	it = frames_.find(num_bytes_consumed_);
	} else {
	string new_data = it->second.substr(bytes_consumed);
	frames_.erase(it);
	frames_.insert(make_pair(num_bytes_consumed_, new_data));
	return;
	}
	}
	}

	} // namespace net