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stream_framer.go
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package quic
import (
"github.com/lucas-clemente/quic-go/internal/flowcontrol"
"github.com/lucas-clemente/quic-go/internal/protocol"
"github.com/lucas-clemente/quic-go/internal/wire"
)
type streamFramer struct {
streamsMap *streamsMap
cryptoStream streamI
connFlowController flowcontrol.ConnectionFlowController
retransmissionQueue []*wire.StreamFrame
blockedFrameQueue []wire.Frame
}
func newStreamFramer(
cryptoStream streamI,
streamsMap *streamsMap,
cfc flowcontrol.ConnectionFlowController,
) *streamFramer {
return &streamFramer{
streamsMap: streamsMap,
cryptoStream: cryptoStream,
connFlowController: cfc,
}
}
func (f *streamFramer) AddFrameForRetransmission(frame *wire.StreamFrame) {
f.retransmissionQueue = append(f.retransmissionQueue, frame)
}
func (f *streamFramer) PopStreamFrames(maxLen protocol.ByteCount) []*wire.StreamFrame {
fs, currentLen := f.maybePopFramesForRetransmission(maxLen)
return append(fs, f.maybePopNormalFrames(maxLen-currentLen)...)
}
func (f *streamFramer) PopBlockedFrame() wire.Frame {
if len(f.blockedFrameQueue) == 0 {
return nil
}
frame := f.blockedFrameQueue[0]
f.blockedFrameQueue = f.blockedFrameQueue[1:]
return frame
}
func (f *streamFramer) HasFramesForRetransmission() bool {
return len(f.retransmissionQueue) > 0
}
func (f *streamFramer) HasCryptoStreamFrame() bool {
return f.cryptoStream.LenOfDataForWriting() > 0
}
// TODO(lclemente): This is somewhat duplicate with the normal path for generating frames.
func (f *streamFramer) PopCryptoStreamFrame(maxLen protocol.ByteCount) *wire.StreamFrame {
if !f.HasCryptoStreamFrame() {
return nil
}
frame := &wire.StreamFrame{
StreamID: f.cryptoStream.StreamID(),
Offset: f.cryptoStream.GetWriteOffset(),
}
frameHeaderBytes, _ := frame.MinLength(protocol.VersionWhatever) // can never error
frame.Data = f.cryptoStream.GetDataForWriting(maxLen - frameHeaderBytes)
return frame
}
func (f *streamFramer) maybePopFramesForRetransmission(maxLen protocol.ByteCount) (res []*wire.StreamFrame, currentLen protocol.ByteCount) {
for len(f.retransmissionQueue) > 0 {
frame := f.retransmissionQueue[0]
frame.DataLenPresent = true
frameHeaderLen, _ := frame.MinLength(protocol.VersionWhatever) // can never error
if currentLen+frameHeaderLen >= maxLen {
break
}
currentLen += frameHeaderLen
splitFrame := maybeSplitOffFrame(frame, maxLen-currentLen)
if splitFrame != nil { // StreamFrame was split
res = append(res, splitFrame)
currentLen += splitFrame.DataLen()
break
}
f.retransmissionQueue = f.retransmissionQueue[1:]
res = append(res, frame)
currentLen += frame.DataLen()
}
return
}
func (f *streamFramer) maybePopNormalFrames(maxBytes protocol.ByteCount) (res []*wire.StreamFrame) {
frame := &wire.StreamFrame{DataLenPresent: true}
var currentLen protocol.ByteCount
fn := func(s streamI) (bool, error) {
if s == nil {
return true, nil
}
frame.StreamID = s.StreamID()
frame.Offset = s.GetWriteOffset()
// not perfect, but thread-safe since writeOffset is only written when getting data
frameHeaderBytes, _ := frame.MinLength(protocol.VersionWhatever) // can never error
if currentLen+frameHeaderBytes > maxBytes {
return false, nil // theoretically, we could find another stream that fits, but this is quite unlikely, so we stop here
}
maxLen := maxBytes - currentLen - frameHeaderBytes
var data []byte
if s.LenOfDataForWriting() > 0 {
data = s.GetDataForWriting(maxLen)
}
// This is unlikely, but check it nonetheless, the scheduler might have jumped in. Seems to happen in ~20% of cases in the tests.
shouldSendFin := s.ShouldSendFin()
if data == nil && !shouldSendFin {
return true, nil
}
if shouldSendFin {
frame.FinBit = true
s.SentFin()
}
frame.Data = data
// Finally, check if we are now FC blocked and should queue a BLOCKED frame
if !frame.FinBit && s.IsFlowControlBlocked() {
f.blockedFrameQueue = append(f.blockedFrameQueue, &wire.StreamBlockedFrame{StreamID: s.StreamID()})
}
if f.connFlowController.IsBlocked() {
f.blockedFrameQueue = append(f.blockedFrameQueue, &wire.BlockedFrame{})
}
res = append(res, frame)
currentLen += frameHeaderBytes + frame.DataLen()
if currentLen == maxBytes {
return false, nil
}
frame = &wire.StreamFrame{DataLenPresent: true}
return true, nil
}
f.streamsMap.RoundRobinIterate(fn)
return
}
// maybeSplitOffFrame removes the first n bytes and returns them as a separate frame. If n >= len(frame), nil is returned and nothing is modified.
func maybeSplitOffFrame(frame *wire.StreamFrame, n protocol.ByteCount) *wire.StreamFrame {
if n >= frame.DataLen() {
return nil
}
defer func() {
frame.Data = frame.Data[n:]
frame.Offset += n
}()
return &wire.StreamFrame{
FinBit: false,
StreamID: frame.StreamID,
Offset: frame.Offset,
Data: frame.Data[:n],
DataLenPresent: frame.DataLenPresent,
}
}