// Copyright 2018 The gVisor Authors. // // Licensed under the Apache License, Version 2.0 (the "License"); // you may not use this file except in compliance with the License. // You may obtain a copy of the License at // // http://www.apache.org/licenses/LICENSE-2.0 // // Unless required by applicable law or agreed to in writing, software // distributed under the License is distributed on an "AS IS" BASIS, // WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. // See the License for the specific language governing permissions and // limitations under the License. package tcp import ( "fmt" "sync/atomic" "time" "gvisor.dev/gvisor/pkg/tcpip" "gvisor.dev/gvisor/pkg/tcpip/buffer" "gvisor.dev/gvisor/pkg/tcpip/header" "gvisor.dev/gvisor/pkg/tcpip/seqnum" "gvisor.dev/gvisor/pkg/tcpip/stack" ) // queueFlags are used to indicate which queue of an endpoint a particular segment // belongs to. This is used to track memory accounting correctly. type queueFlags uint8 const ( recvQ queueFlags = 1 << iota sendQ ) // segment represents a TCP segment. It holds the payload and parsed TCP segment // information, and can be added to intrusive lists. // segment is mostly immutable, the only field allowed to change is data. // // +stateify savable type segment struct { segmentEntry refCnt int32 ep *endpoint qFlags queueFlags id stack.TransportEndpointID `state:"manual"` // TODO(gvisor.dev/issue/4417): Hold a stack.PacketBuffer instead of // individual members for link/network packet info. srcAddr tcpip.Address dstAddr tcpip.Address netProto tcpip.NetworkProtocolNumber nicID tcpip.NICID remoteLinkAddr tcpip.LinkAddress data buffer.VectorisedView `state:".(buffer.VectorisedView)"` hdr header.TCP // views is used as buffer for data when its length is large // enough to store a VectorisedView. views [8]buffer.View `state:"nosave"` sequenceNumber seqnum.Value ackNumber seqnum.Value flags uint8 window seqnum.Size // csum is only populated for received segments. csum uint16 // csumValid is true if the csum in the received segment is valid. csumValid bool // parsedOptions stores the parsed values from the options in the segment. parsedOptions header.TCPOptions options []byte `state:".([]byte)"` hasNewSACKInfo bool rcvdTime time.Time `state:".(unixTime)"` // xmitTime is the last transmit time of this segment. xmitTime time.Time `state:".(unixTime)"` xmitCount uint32 // acked indicates if the segment has already been SACKed. acked bool // dataMemSize is the memory used by data initially. dataMemSize int } func newIncomingSegment(id stack.TransportEndpointID, pkt *stack.PacketBuffer) *segment { netHdr := pkt.Network() s := &segment{ refCnt: 1, id: id, srcAddr: netHdr.SourceAddress(), dstAddr: netHdr.DestinationAddress(), netProto: pkt.NetworkProtocolNumber, nicID: pkt.NICID, remoteLinkAddr: pkt.SourceLinkAddress(), } s.data = pkt.Data.Clone(s.views[:]) s.hdr = header.TCP(pkt.TransportHeader().View()) s.rcvdTime = time.Now() s.dataMemSize = s.data.Size() return s } func newOutgoingSegment(id stack.TransportEndpointID, v buffer.View) *segment { s := &segment{ refCnt: 1, id: id, } s.rcvdTime = time.Now() if len(v) != 0 { s.views[0] = v s.data = buffer.NewVectorisedView(len(v), s.views[:1]) } s.dataMemSize = s.data.Size() return s } func (s *segment) clone() *segment { t := &segment{ refCnt: 1, id: s.id, sequenceNumber: s.sequenceNumber, ackNumber: s.ackNumber, flags: s.flags, window: s.window, netProto: s.netProto, nicID: s.nicID, remoteLinkAddr: s.remoteLinkAddr, rcvdTime: s.rcvdTime, xmitTime: s.xmitTime, xmitCount: s.xmitCount, ep: s.ep, qFlags: s.qFlags, dataMemSize: s.dataMemSize, } t.data = s.data.Clone(t.views[:]) return t } // flagIsSet checks if at least one flag in flags is set in s.flags. func (s *segment) flagIsSet(flags uint8) bool { return s.flags&flags != 0 } // flagsAreSet checks if all flags in flags are set in s.flags. func (s *segment) flagsAreSet(flags uint8) bool { return s.flags&flags == flags } // setOwner sets the owning endpoint for this segment. Its required // to be called to ensure memory accounting for receive/send buffer // queues is done properly. func (s *segment) setOwner(ep *endpoint, qFlags queueFlags) { switch qFlags { case recvQ: ep.updateReceiveMemUsed(s.segMemSize()) case sendQ: // no memory account for sendQ yet. default: panic(fmt.Sprintf("unexpected queue flag %b", qFlags)) } s.ep = ep s.qFlags = qFlags } func (s *segment) decRef() { if atomic.AddInt32(&s.refCnt, -1) == 0 { if s.ep != nil { switch s.qFlags { case recvQ: s.ep.updateReceiveMemUsed(-s.segMemSize()) case sendQ: // no memory accounting for sendQ yet. default: panic(fmt.Sprintf("unexpected queue flag %b set for segment", s.qFlags)) } } } } func (s *segment) incRef() { atomic.AddInt32(&s.refCnt, 1) } // logicalLen is the segment length in the sequence number space. It's defined // as the data length plus one for each of the SYN and FIN bits set. func (s *segment) logicalLen() seqnum.Size { l := seqnum.Size(s.data.Size()) if s.flagIsSet(header.TCPFlagSyn) { l++ } if s.flagIsSet(header.TCPFlagFin) { l++ } return l } // payloadSize is the size of s.data. func (s *segment) payloadSize() int { return s.data.Size() } // segMemSize is the amount of memory used to hold the segment data and // the associated metadata. func (s *segment) segMemSize() int { return SegSize + s.dataMemSize } // parse populates the sequence & ack numbers, flags, and window fields of the // segment from the TCP header stored in the data. It then updates the view to // skip the header. // // Returns boolean indicating if the parsing was successful. // // If checksum verification may not be skipped, parse also verifies the // TCP checksum and stores the checksum and result of checksum verification in // the csum and csumValid fields of the segment. func (s *segment) parse(skipChecksumValidation bool) bool { // h is the header followed by the payload. We check that the offset to // the data respects the following constraints: // 1. That it's at least the minimum header size; if we don't do this // then part of the header would be delivered to user. // 2. That the header fits within the buffer; if we don't do this, we // would panic when we tried to access data beyond the buffer. // // N.B. The segment has already been validated as having at least the // minimum TCP size before reaching here, so it's safe to read the // fields. offset := int(s.hdr.DataOffset()) if offset < header.TCPMinimumSize || offset > len(s.hdr) { return false } s.options = []byte(s.hdr[header.TCPMinimumSize:]) s.parsedOptions = header.ParseTCPOptions(s.options) verifyChecksum := true if skipChecksumValidation { s.csumValid = true verifyChecksum = false } if verifyChecksum { s.csum = s.hdr.Checksum() xsum := header.PseudoHeaderChecksum(ProtocolNumber, s.srcAddr, s.dstAddr, uint16(s.data.Size()+len(s.hdr))) xsum = s.hdr.CalculateChecksum(xsum) xsum = header.ChecksumVV(s.data, xsum) s.csumValid = xsum == 0xffff } s.sequenceNumber = seqnum.Value(s.hdr.SequenceNumber()) s.ackNumber = seqnum.Value(s.hdr.AckNumber()) s.flags = s.hdr.Flags() s.window = seqnum.Size(s.hdr.WindowSize()) return true } // sackBlock returns a header.SACKBlock that represents this segment. func (s *segment) sackBlock() header.SACKBlock { return header.SACKBlock{s.sequenceNumber, s.sequenceNumber.Add(s.logicalLen())} }