package quic import ( "context" "fmt" "sync" "time" "github.com/lucas-clemente/quic-go/internal/flowcontrol" "github.com/lucas-clemente/quic-go/internal/protocol" "github.com/lucas-clemente/quic-go/internal/utils" "github.com/lucas-clemente/quic-go/internal/wire" ) type sendStreamI interface { SendStream handleStopSendingFrame(*wire.StopSendingFrame) popStreamFrame(maxBytes protocol.ByteCount) (*wire.StreamFrame, bool) closeForShutdown(error) handleMaxStreamDataFrame(*wire.MaxStreamDataFrame) } type sendStream struct { mutex sync.Mutex ctx context.Context ctxCancel context.CancelFunc streamID protocol.StreamID sender streamSender writeOffset protocol.ByteCount cancelWriteErr error closeForShutdownErr error closedForShutdown bool // set when CloseForShutdown() is called finishedWriting bool // set once Close() is called canceledWrite bool // set when CancelWrite() is called, or a STOP_SENDING frame is received finSent bool // set when a STREAM_FRAME with FIN bit has b dataForWriting []byte writeChan chan struct{} writeDeadline time.Time flowController flowcontrol.StreamFlowController version protocol.VersionNumber } var _ SendStream = &sendStream{} var _ sendStreamI = &sendStream{} func newSendStream( streamID protocol.StreamID, sender streamSender, flowController flowcontrol.StreamFlowController, version protocol.VersionNumber, ) *sendStream { s := &sendStream{ streamID: streamID, sender: sender, flowController: flowController, writeChan: make(chan struct{}, 1), version: version, } s.ctx, s.ctxCancel = context.WithCancel(context.Background()) return s } func (s *sendStream) StreamID() protocol.StreamID { return s.streamID // same for receiveStream and sendStream } func (s *sendStream) Write(p []byte) (int, error) { s.mutex.Lock() defer s.mutex.Unlock() if s.finishedWriting { return 0, fmt.Errorf("write on closed stream %d", s.streamID) } if s.canceledWrite { return 0, s.cancelWriteErr } if s.closeForShutdownErr != nil { return 0, s.closeForShutdownErr } if !s.writeDeadline.IsZero() && !time.Now().Before(s.writeDeadline) { return 0, errDeadline } if len(p) == 0 { return 0, nil } s.dataForWriting = make([]byte, len(p)) copy(s.dataForWriting, p) s.sender.onHasStreamData(s.streamID) var bytesWritten int var err error for { bytesWritten = len(p) - len(s.dataForWriting) deadline := s.writeDeadline if !deadline.IsZero() && !time.Now().Before(deadline) { s.dataForWriting = nil err = errDeadline break } if s.dataForWriting == nil || s.canceledWrite || s.closedForShutdown { break } s.mutex.Unlock() if deadline.IsZero() { <-s.writeChan } else { select { case <-s.writeChan: case <-time.After(deadline.Sub(time.Now())): } } s.mutex.Lock() } if s.closeForShutdownErr != nil { err = s.closeForShutdownErr } else if s.cancelWriteErr != nil { err = s.cancelWriteErr } return bytesWritten, err } // popStreamFrame returns the next STREAM frame that is supposed to be sent on this stream // maxBytes is the maximum length this frame (including frame header) will have. func (s *sendStream) popStreamFrame(maxBytes protocol.ByteCount) (*wire.StreamFrame, bool /* has more data to send */) { s.mutex.Lock() defer s.mutex.Unlock() if s.closeForShutdownErr != nil { return nil, false } frame := &wire.StreamFrame{ StreamID: s.streamID, Offset: s.writeOffset, DataLenPresent: true, } frameLen := frame.MinLength(s.version) if frameLen >= maxBytes { // a STREAM frame must have at least one byte of data return nil, s.dataForWriting != nil } frame.Data, frame.FinBit = s.getDataForWriting(maxBytes - frameLen) if len(frame.Data) == 0 && !frame.FinBit { // this can happen if: // - popStreamFrame is called but there's no data for writing // - there's data for writing, but the stream is stream-level flow control blocked // - there's data for writing, but the stream is connection-level flow control blocked if s.dataForWriting == nil { return nil, false } isBlocked, _ := s.flowController.IsBlocked() return nil, !isBlocked } if frame.FinBit { s.finSent = true s.sender.onStreamCompleted(s.streamID) } else if s.streamID != s.version.CryptoStreamID() { // TODO(#657): Flow control for the crypto stream if isBlocked, offset := s.flowController.IsBlocked(); isBlocked { s.sender.queueControlFrame(&wire.StreamBlockedFrame{ StreamID: s.streamID, Offset: offset, }) return frame, false } } return frame, s.dataForWriting != nil } func (s *sendStream) getDataForWriting(maxBytes protocol.ByteCount) ([]byte, bool /* should send FIN */) { if s.dataForWriting == nil { return nil, s.finishedWriting && !s.finSent } // TODO(#657): Flow control for the crypto stream if s.streamID != s.version.CryptoStreamID() { maxBytes = utils.MinByteCount(maxBytes, s.flowController.SendWindowSize()) } if maxBytes == 0 { return nil, false } var ret []byte if protocol.ByteCount(len(s.dataForWriting)) > maxBytes { ret = s.dataForWriting[:maxBytes] s.dataForWriting = s.dataForWriting[maxBytes:] } else { ret = s.dataForWriting s.dataForWriting = nil s.signalWrite() } s.writeOffset += protocol.ByteCount(len(ret)) s.flowController.AddBytesSent(protocol.ByteCount(len(ret))) return ret, s.finishedWriting && s.dataForWriting == nil && !s.finSent } func (s *sendStream) Close() error { s.mutex.Lock() defer s.mutex.Unlock() if s.canceledWrite { return fmt.Errorf("Close called for canceled stream %d", s.streamID) } s.finishedWriting = true s.sender.onHasStreamData(s.streamID) // need to send the FIN s.ctxCancel() return nil } func (s *sendStream) CancelWrite(errorCode protocol.ApplicationErrorCode) error { s.mutex.Lock() defer s.mutex.Unlock() return s.cancelWriteImpl(errorCode, fmt.Errorf("Write on stream %d canceled with error code %d", s.streamID, errorCode)) } // must be called after locking the mutex func (s *sendStream) cancelWriteImpl(errorCode protocol.ApplicationErrorCode, writeErr error) error { if s.canceledWrite { return nil } if s.finishedWriting { return fmt.Errorf("CancelWrite for closed stream %d", s.streamID) } s.canceledWrite = true s.cancelWriteErr = writeErr s.signalWrite() s.sender.queueControlFrame(&wire.RstStreamFrame{ StreamID: s.streamID, ByteOffset: s.writeOffset, ErrorCode: errorCode, }) // TODO(#991): cancel retransmissions for this stream s.ctxCancel() s.sender.onStreamCompleted(s.streamID) return nil } func (s *sendStream) handleStopSendingFrame(frame *wire.StopSendingFrame) { s.mutex.Lock() defer s.mutex.Unlock() s.handleStopSendingFrameImpl(frame) } func (s *sendStream) handleMaxStreamDataFrame(frame *wire.MaxStreamDataFrame) { s.flowController.UpdateSendWindow(frame.ByteOffset) s.mutex.Lock() if s.dataForWriting != nil { s.sender.onHasStreamData(s.streamID) } s.mutex.Unlock() } // must be called after locking the mutex func (s *sendStream) handleStopSendingFrameImpl(frame *wire.StopSendingFrame) { writeErr := streamCanceledError{ errorCode: frame.ErrorCode, error: fmt.Errorf("Stream %d was reset with error code %d", s.streamID, frame.ErrorCode), } errorCode := errorCodeStopping if !s.version.UsesIETFFrameFormat() { errorCode = errorCodeStoppingGQUIC } s.cancelWriteImpl(errorCode, writeErr) } func (s *sendStream) Context() context.Context { return s.ctx } func (s *sendStream) SetWriteDeadline(t time.Time) error { s.mutex.Lock() oldDeadline := s.writeDeadline s.writeDeadline = t s.mutex.Unlock() if t.Before(oldDeadline) { s.signalWrite() } return nil } // CloseForShutdown closes a stream abruptly. // It makes Write unblock (and return the error) immediately. // The peer will NOT be informed about this: the stream is closed without sending a FIN or RST. func (s *sendStream) closeForShutdown(err error) { s.mutex.Lock() s.closedForShutdown = true s.closeForShutdownErr = err s.mutex.Unlock() s.signalWrite() s.ctxCancel() } func (s *sendStream) getWriteOffset() protocol.ByteCount { return s.writeOffset } // signalWrite performs a non-blocking send on the writeChan func (s *sendStream) signalWrite() { select { case s.writeChan <- struct{}{}: default: } }