package frames import ( "bytes" "errors" "time" "github.com/lucas-clemente/quic-go/internal/utils" "github.com/lucas-clemente/quic-go/protocol" ) var ( // ErrInvalidAckRanges occurs when a client sends inconsistent ACK ranges ErrInvalidAckRanges = errors.New("AckFrame: ACK frame contains invalid ACK ranges") // ErrInvalidFirstAckRange occurs when the first ACK range contains no packets ErrInvalidFirstAckRange = errors.New("AckFrame: ACK frame has invalid first ACK range") ) var ( errInconsistentAckLargestAcked = errors.New("internal inconsistency: LargestAcked does not match ACK ranges") errInconsistentAckLowestAcked = errors.New("internal inconsistency: LowestAcked does not match ACK ranges") ) // An AckFrame is an ACK frame in QUIC type AckFrame struct { LargestAcked protocol.PacketNumber LowestAcked protocol.PacketNumber AckRanges []AckRange // has to be ordered. The ACK range with the highest FirstPacketNumber goes first, the ACK range with the lowest FirstPacketNumber goes last // time when the LargestAcked was receiveid // this field Will not be set for received ACKs frames PacketReceivedTime time.Time DelayTime time.Duration } // ParseAckFrame reads an ACK frame func ParseAckFrame(r *bytes.Reader, version protocol.VersionNumber) (*AckFrame, error) { frame := &AckFrame{} typeByte, err := r.ReadByte() if err != nil { return nil, err } hasMissingRanges := false if typeByte&0x20 == 0x20 { hasMissingRanges = true } largestAckedLen := 2 * ((typeByte & 0x0C) >> 2) if largestAckedLen == 0 { largestAckedLen = 1 } missingSequenceNumberDeltaLen := 2 * (typeByte & 0x03) if missingSequenceNumberDeltaLen == 0 { missingSequenceNumberDeltaLen = 1 } largestAcked, err := utils.ReadUintN(r, largestAckedLen) if err != nil { return nil, err } frame.LargestAcked = protocol.PacketNumber(largestAcked) delay, err := utils.ReadUfloat16(r) if err != nil { return nil, err } frame.DelayTime = time.Duration(delay) * time.Microsecond var numAckBlocks uint8 if hasMissingRanges { numAckBlocks, err = r.ReadByte() if err != nil { return nil, err } } if hasMissingRanges && numAckBlocks == 0 { return nil, ErrInvalidAckRanges } ackBlockLength, err := utils.ReadUintN(r, missingSequenceNumberDeltaLen) if err != nil { return nil, err } if frame.LargestAcked > 0 && ackBlockLength < 1 { return nil, ErrInvalidFirstAckRange } if ackBlockLength > largestAcked { return nil, ErrInvalidAckRanges } if hasMissingRanges { ackRange := AckRange{ FirstPacketNumber: protocol.PacketNumber(largestAcked-ackBlockLength) + 1, LastPacketNumber: frame.LargestAcked, } frame.AckRanges = append(frame.AckRanges, ackRange) var inLongBlock bool var lastRangeComplete bool for i := uint8(0); i < numAckBlocks; i++ { var gap uint8 gap, err = r.ReadByte() if err != nil { return nil, err } ackBlockLength, err = utils.ReadUintN(r, missingSequenceNumberDeltaLen) if err != nil { return nil, err } length := protocol.PacketNumber(ackBlockLength) if inLongBlock { frame.AckRanges[len(frame.AckRanges)-1].FirstPacketNumber -= protocol.PacketNumber(gap) + length frame.AckRanges[len(frame.AckRanges)-1].LastPacketNumber -= protocol.PacketNumber(gap) } else { lastRangeComplete = false ackRange := AckRange{ LastPacketNumber: frame.AckRanges[len(frame.AckRanges)-1].FirstPacketNumber - protocol.PacketNumber(gap) - 1, } ackRange.FirstPacketNumber = ackRange.LastPacketNumber - length + 1 frame.AckRanges = append(frame.AckRanges, ackRange) } if length > 0 { lastRangeComplete = true } inLongBlock = (ackBlockLength == 0) } // if the last range was not complete, FirstPacketNumber and LastPacketNumber make no sense // remove the range from frame.AckRanges if !lastRangeComplete { frame.AckRanges = frame.AckRanges[:len(frame.AckRanges)-1] } frame.LowestAcked = frame.AckRanges[len(frame.AckRanges)-1].FirstPacketNumber } else { if frame.LargestAcked == 0 { frame.LowestAcked = 0 } else { frame.LowestAcked = protocol.PacketNumber(largestAcked + 1 - ackBlockLength) } } if !frame.validateAckRanges() { return nil, ErrInvalidAckRanges } var numTimestamp byte numTimestamp, err = r.ReadByte() if err != nil { return nil, err } if numTimestamp > 0 { // Delta Largest acked _, err = r.ReadByte() if err != nil { return nil, err } // First Timestamp _, err = utils.ReadUint32(r) if err != nil { return nil, err } for i := 0; i < int(numTimestamp)-1; i++ { // Delta Largest acked _, err = r.ReadByte() if err != nil { return nil, err } // Time Since Previous Timestamp _, err = utils.ReadUint16(r) if err != nil { return nil, err } } } return frame, nil } // Write writes an ACK frame. func (f *AckFrame) Write(b *bytes.Buffer, version protocol.VersionNumber) error { largestAckedLen := protocol.GetPacketNumberLength(f.LargestAcked) typeByte := uint8(0x40) if largestAckedLen != protocol.PacketNumberLen1 { typeByte ^= (uint8(largestAckedLen / 2)) << 2 } missingSequenceNumberDeltaLen := f.getMissingSequenceNumberDeltaLen() if missingSequenceNumberDeltaLen != protocol.PacketNumberLen1 { typeByte ^= (uint8(missingSequenceNumberDeltaLen / 2)) } if f.HasMissingRanges() { typeByte |= 0x20 } b.WriteByte(typeByte) switch largestAckedLen { case protocol.PacketNumberLen1: b.WriteByte(uint8(f.LargestAcked)) case protocol.PacketNumberLen2: utils.WriteUint16(b, uint16(f.LargestAcked)) case protocol.PacketNumberLen4: utils.WriteUint32(b, uint32(f.LargestAcked)) case protocol.PacketNumberLen6: utils.WriteUint48(b, uint64(f.LargestAcked)) } f.DelayTime = time.Since(f.PacketReceivedTime) utils.WriteUfloat16(b, uint64(f.DelayTime/time.Microsecond)) var numRanges uint64 var numRangesWritten uint64 if f.HasMissingRanges() { numRanges = f.numWritableNackRanges() if numRanges > 0xFF { panic("AckFrame: Too many ACK ranges") } b.WriteByte(uint8(numRanges - 1)) } var firstAckBlockLength protocol.PacketNumber if !f.HasMissingRanges() { firstAckBlockLength = f.LargestAcked - f.LowestAcked + 1 } else { if f.LargestAcked != f.AckRanges[0].LastPacketNumber { return errInconsistentAckLargestAcked } if f.LowestAcked != f.AckRanges[len(f.AckRanges)-1].FirstPacketNumber { return errInconsistentAckLowestAcked } firstAckBlockLength = f.LargestAcked - f.AckRanges[0].FirstPacketNumber + 1 numRangesWritten++ } switch missingSequenceNumberDeltaLen { case protocol.PacketNumberLen1: b.WriteByte(uint8(firstAckBlockLength)) case protocol.PacketNumberLen2: utils.WriteUint16(b, uint16(firstAckBlockLength)) case protocol.PacketNumberLen4: utils.WriteUint32(b, uint32(firstAckBlockLength)) case protocol.PacketNumberLen6: utils.WriteUint48(b, uint64(firstAckBlockLength)) } for i, ackRange := range f.AckRanges { if i == 0 { continue } length := ackRange.LastPacketNumber - ackRange.FirstPacketNumber + 1 gap := f.AckRanges[i-1].FirstPacketNumber - ackRange.LastPacketNumber - 1 num := gap/0xFF + 1 if gap%0xFF == 0 { num-- } if num == 1 { b.WriteByte(uint8(gap)) switch missingSequenceNumberDeltaLen { case protocol.PacketNumberLen1: b.WriteByte(uint8(length)) case protocol.PacketNumberLen2: utils.WriteUint16(b, uint16(length)) case protocol.PacketNumberLen4: utils.WriteUint32(b, uint32(length)) case protocol.PacketNumberLen6: utils.WriteUint48(b, uint64(length)) } numRangesWritten++ } else { for i := 0; i < int(num); i++ { var lengthWritten uint64 var gapWritten uint8 if i == int(num)-1 { // last block lengthWritten = uint64(length) gapWritten = uint8(1 + ((gap - 1) % 255)) } else { lengthWritten = 0 gapWritten = 0xFF } b.WriteByte(gapWritten) switch missingSequenceNumberDeltaLen { case protocol.PacketNumberLen1: b.WriteByte(uint8(lengthWritten)) case protocol.PacketNumberLen2: utils.WriteUint16(b, uint16(lengthWritten)) case protocol.PacketNumberLen4: utils.WriteUint32(b, uint32(lengthWritten)) case protocol.PacketNumberLen6: utils.WriteUint48(b, lengthWritten) } numRangesWritten++ } } // this is needed if not all AckRanges can be written to the ACK frame (if there are more than 0xFF) if numRangesWritten >= numRanges { break } } if numRanges != numRangesWritten { return errors.New("BUG: Inconsistent number of ACK ranges written") } b.WriteByte(0) // no timestamps return nil } // MinLength of a written frame func (f *AckFrame) MinLength(version protocol.VersionNumber) (protocol.ByteCount, error) { length := protocol.ByteCount(1 + 2 + 1) // 1 TypeByte, 2 ACK delay time, 1 Num Timestamp length += protocol.ByteCount(protocol.GetPacketNumberLength(f.LargestAcked)) missingSequenceNumberDeltaLen := protocol.ByteCount(f.getMissingSequenceNumberDeltaLen()) if f.HasMissingRanges() { length += (1 + missingSequenceNumberDeltaLen) * protocol.ByteCount(f.numWritableNackRanges()) } else { length += missingSequenceNumberDeltaLen } length += (1 + 2) * 0 /* TODO: num_timestamps */ return length, nil } // HasMissingRanges returns if this frame reports any missing packets func (f *AckFrame) HasMissingRanges() bool { return len(f.AckRanges) > 0 } func (f *AckFrame) validateAckRanges() bool { if len(f.AckRanges) == 0 { return true } // if there are missing packets, there will always be at least 2 ACK ranges if len(f.AckRanges) == 1 { return false } if f.AckRanges[0].LastPacketNumber != f.LargestAcked { return false } // check the validity of every single ACK range for _, ackRange := range f.AckRanges { if ackRange.FirstPacketNumber > ackRange.LastPacketNumber { return false } } // check the consistency for ACK with multiple NACK ranges for i, ackRange := range f.AckRanges { if i == 0 { continue } lastAckRange := f.AckRanges[i-1] if lastAckRange.FirstPacketNumber <= ackRange.FirstPacketNumber { return false } if lastAckRange.FirstPacketNumber <= ackRange.LastPacketNumber+1 { return false } } return true } // numWritableNackRanges calculates the number of ACK blocks that are about to be written // this number is different from len(f.AckRanges) for the case of long gaps (> 255 packets) func (f *AckFrame) numWritableNackRanges() uint64 { if len(f.AckRanges) == 0 { return 0 } var numRanges uint64 for i, ackRange := range f.AckRanges { if i == 0 { continue } lastAckRange := f.AckRanges[i-1] gap := lastAckRange.FirstPacketNumber - ackRange.LastPacketNumber - 1 rangeLength := 1 + uint64(gap)/0xFF if uint64(gap)%0xFF == 0 { rangeLength-- } if numRanges+rangeLength < 0xFF { numRanges += rangeLength } else { break } } return numRanges + 1 } func (f *AckFrame) getMissingSequenceNumberDeltaLen() protocol.PacketNumberLen { var maxRangeLength protocol.PacketNumber if f.HasMissingRanges() { for _, ackRange := range f.AckRanges { rangeLength := ackRange.LastPacketNumber - ackRange.FirstPacketNumber + 1 if rangeLength > maxRangeLength { maxRangeLength = rangeLength } } } else { maxRangeLength = f.LargestAcked - f.LowestAcked + 1 } if maxRangeLength <= 0xFF { return protocol.PacketNumberLen1 } if maxRangeLength <= 0xFFFF { return protocol.PacketNumberLen2 } if maxRangeLength <= 0xFFFFFFFF { return protocol.PacketNumberLen4 } return protocol.PacketNumberLen6 } // AcksPacket determines if this ACK frame acks a certain packet number func (f *AckFrame) AcksPacket(p protocol.PacketNumber) bool { if p < f.LowestAcked || p > f.LargestAcked { // this is just a performance optimization return false } if f.HasMissingRanges() { // TODO: this could be implemented as a binary search for _, ackRange := range f.AckRanges { if p >= ackRange.FirstPacketNumber && p <= ackRange.LastPacketNumber { return true } } return false } // if packet doesn't have missing ranges return (p >= f.LowestAcked && p <= f.LargestAcked) }