// SPDX-FileCopyrightText: 2023 The Pion community // SPDX-License-Identifier: MIT package ice import ( "context" "errors" "fmt" "hash/crc32" "io" "net" "strconv" "strings" "sync/atomic" "time" "github.com/pion/stun" ) type candidateBase struct { id string networkType NetworkType candidateType CandidateType component uint16 address string port int relatedAddress *CandidateRelatedAddress tcpType TCPType resolvedAddr net.Addr lastSent atomic.Int64 lastReceived atomic.Int64 conn net.PacketConn currAgent *Agent closeCh chan struct{} closedCh chan struct{} foundationOverride string priorityOverride uint32 remoteCandidateCaches map[AddrPort]Candidate } // Done implements context.Context func (c *candidateBase) Done() <-chan struct{} { return c.closeCh } // Err implements context.Context func (c *candidateBase) Err() error { select { case <-c.closedCh: return ErrRunCanceled default: return nil } } // Deadline implements context.Context func (c *candidateBase) Deadline() (deadline time.Time, ok bool) { return time.Time{}, false } // Value implements context.Context func (c *candidateBase) Value(interface{}) interface{} { return nil } // ID returns Candidate ID func (c *candidateBase) ID() string { return c.id } func (c *candidateBase) Foundation() string { if c.foundationOverride != "" { return c.foundationOverride } return fmt.Sprintf("%d", crc32.ChecksumIEEE([]byte(c.Type().String()+c.address+c.networkType.String()))) } // Address returns Candidate Address func (c *candidateBase) Address() string { return c.address } // Port returns Candidate Port func (c *candidateBase) Port() int { return c.port } // Type returns candidate type func (c *candidateBase) Type() CandidateType { return c.candidateType } // NetworkType returns candidate NetworkType func (c *candidateBase) NetworkType() NetworkType { return c.networkType } // Component returns candidate component func (c *candidateBase) Component() uint16 { return c.component } func (c *candidateBase) SetComponent(component uint16) { c.component = component } // LocalPreference returns the local preference for this candidate func (c *candidateBase) LocalPreference() uint16 { if c.NetworkType().IsTCP() { // RFC 6544, section 4.2 // // In Section 4.1.2.1 of [RFC5245], a recommended formula for UDP ICE // candidate prioritization is defined. For TCP candidates, the same // formula and candidate type preferences SHOULD be used, and the // RECOMMENDED type preferences for the new candidate types defined in // this document (see Section 5) are 105 for NAT-assisted candidates and // 75 for UDP-tunneled candidates. // // (...) // // With TCP candidates, the local preference part of the recommended // priority formula is updated to also include the directionality // (active, passive, or simultaneous-open) of the TCP connection. The // RECOMMENDED local preference is then defined as: // // local preference = (2^13) * direction-pref + other-pref // // The direction-pref MUST be between 0 and 7 (both inclusive), with 7 // being the most preferred. The other-pref MUST be between 0 and 8191 // (both inclusive), with 8191 being the most preferred. It is // RECOMMENDED that the host, UDP-tunneled, and relayed TCP candidates // have the direction-pref assigned as follows: 6 for active, 4 for // passive, and 2 for S-O. For the NAT-assisted and server reflexive // candidates, the RECOMMENDED values are: 6 for S-O, 4 for active, and // 2 for passive. // // (...) // // If any two candidates have the same type-preference and direction- // pref, they MUST have a unique other-pref. With this specification, // this usually only happens with multi-homed hosts, in which case // other-pref is the preference for the particular IP address from which // the candidate was obtained. When there is only a single IP address, // this value SHOULD be set to the maximum allowed value (8191). var otherPref uint16 = 8191 directionPref := func() uint16 { switch c.Type() { case CandidateTypeHost, CandidateTypeRelay: switch c.tcpType { case TCPTypeActive: return 6 case TCPTypePassive: return 4 case TCPTypeSimultaneousOpen: return 2 case TCPTypeUnspecified: return 0 } case CandidateTypePeerReflexive, CandidateTypeServerReflexive: switch c.tcpType { case TCPTypeSimultaneousOpen: return 6 case TCPTypeActive: return 4 case TCPTypePassive: return 2 case TCPTypeUnspecified: return 0 } case CandidateTypeUnspecified: return 0 } return 0 }() return (1<<13)*directionPref + otherPref } return defaultLocalPreference } // RelatedAddress returns *CandidateRelatedAddress func (c *candidateBase) RelatedAddress() *CandidateRelatedAddress { return c.relatedAddress } func (c *candidateBase) TCPType() TCPType { return c.tcpType } // start runs the candidate using the provided connection func (c *candidateBase) start(a *Agent, conn net.PacketConn, initializedCh <-chan struct{}) { if c.conn != nil { c.agent().log.Warn("Can't start already started candidateBase") return } c.currAgent = a c.conn = conn c.closeCh = make(chan struct{}) c.closedCh = make(chan struct{}) go c.recvLoop(initializedCh) } func (c *candidateBase) recvLoop(initializedCh <-chan struct{}) { a := c.agent() defer close(c.closedCh) select { case <-initializedCh: case <-c.closeCh: return } buf := make([]byte, receiveMTU) for { n, srcAddr, err := c.conn.ReadFrom(buf) if err != nil { if !(errors.Is(err, io.EOF) || errors.Is(err, net.ErrClosed)) { a.log.Warnf("Failed to read from candidate %s: %v", c, err) } return } c.handleInboundPacket(buf[:n], srcAddr) } } func (c *candidateBase) validateSTUNTrafficCache(addr net.Addr) bool { if candidate, ok := c.remoteCandidateCaches[toAddrPort(addr)]; ok { candidate.seen(false) return true } return false } func (c *candidateBase) addRemoteCandidateCache(candidate Candidate, srcAddr net.Addr) { if c.validateSTUNTrafficCache(srcAddr) { return } c.remoteCandidateCaches[toAddrPort(srcAddr)] = candidate } func (c *candidateBase) handleInboundPacket(buf []byte, srcAddr net.Addr) { a := c.agent() if stun.IsMessage(buf) { m := &stun.Message{ Raw: make([]byte, len(buf)), } // Explicitly copy raw buffer so Message can own the memory. copy(m.Raw, buf) if err := m.Decode(); err != nil { a.log.Warnf("Failed to handle decode ICE from %s to %s: %v", c.addr(), srcAddr, err) return } if err := a.run(c, func(ctx context.Context, a *Agent) { // nolint: contextcheck a.handleInbound(m, c, srcAddr) }); err != nil { a.log.Warnf("Failed to handle message: %v", err) } return } if !c.validateSTUNTrafficCache(srcAddr) { remoteCandidate, valid := a.validateNonSTUNTraffic(c, srcAddr) //nolint:contextcheck if !valid { a.log.Warnf("Discarded message from %s, not a valid remote candidate", c.addr()) return } c.addRemoteCandidateCache(remoteCandidate, srcAddr) } // Note: This will return packetio.ErrFull if the buffer ever manages to fill up. if _, err := a.buf.Write(buf); err != nil { a.log.Warnf("Failed to write packet: %s", err) return } } // close stops the recvLoop func (c *candidateBase) close() error { // If conn has never been started will be nil if c.Done() == nil { return nil } // Assert that conn has not already been closed select { case <-c.Done(): return nil default: } var firstErr error // Unblock recvLoop close(c.closeCh) if err := c.conn.SetDeadline(time.Now()); err != nil { firstErr = err } // Close the conn if err := c.conn.Close(); err != nil && firstErr == nil { firstErr = err } if firstErr != nil { return firstErr } // Wait until the recvLoop is closed <-c.closedCh return nil } func (c *candidateBase) writeTo(raw []byte, dst Candidate) (int, error) { n, err := c.conn.WriteTo(raw, dst.addr()) if err != nil { // If the connection is closed, we should return the error if errors.Is(err, io.ErrClosedPipe) { return n, err } c.agent().log.Infof("Failed to send packet: %v", err) return n, nil } c.seen(true) return n, nil } // TypePreference returns the type preference for this candidate func (c *candidateBase) TypePreference() uint16 { pref := c.Type().Preference() if pref == 0 { return 0 } if c.NetworkType().IsTCP() { var tcpPriorityOffset uint16 = defaultTCPPriorityOffset if c.agent() != nil { tcpPriorityOffset = c.agent().tcpPriorityOffset } pref -= tcpPriorityOffset } return pref } // Priority computes the priority for this ICE Candidate // See: https://www.rfc-editor.org/rfc/rfc8445#section-5.1.2.1 func (c *candidateBase) Priority() uint32 { if c.priorityOverride != 0 { return c.priorityOverride } // The local preference MUST be an integer from 0 (lowest preference) to // 65535 (highest preference) inclusive. When there is only a single IP // address, this value SHOULD be set to 65535. If there are multiple // candidates for a particular component for a particular data stream // that have the same type, the local preference MUST be unique for each // one. return (1<<24)*uint32(c.TypePreference()) + (1<<8)*uint32(c.LocalPreference()) + (1<<0)*uint32(256-c.Component()) } // Equal is used to compare two candidateBases func (c *candidateBase) Equal(other Candidate) bool { return c.NetworkType() == other.NetworkType() && c.Type() == other.Type() && c.Address() == other.Address() && c.Port() == other.Port() && c.TCPType() == other.TCPType() && c.RelatedAddress().Equal(other.RelatedAddress()) } // String makes the candidateBase printable func (c *candidateBase) String() string { return fmt.Sprintf("%s %s %s%s", c.NetworkType(), c.Type(), net.JoinHostPort(c.Address(), strconv.Itoa(c.Port())), c.relatedAddress) } // LastReceived returns a time.Time indicating the last time // this candidate was received func (c *candidateBase) LastReceived() time.Time { if lastReceived := c.lastReceived.Load(); lastReceived != 0 { return time.Unix(0, lastReceived) } return time.Time{} } func (c *candidateBase) setLastReceived(t time.Time) { c.lastReceived.Store(t.UnixNano()) } // LastSent returns a time.Time indicating the last time // this candidate was sent func (c *candidateBase) LastSent() time.Time { if lastSent := c.lastSent.Load(); lastSent != 0 { return time.Unix(0, lastSent) } return time.Time{} } func (c *candidateBase) setLastSent(t time.Time) { c.lastSent.Store(t.UnixNano()) } func (c *candidateBase) seen(outbound bool) { if outbound { c.setLastSent(time.Now()) } else { c.setLastReceived(time.Now()) } } func (c *candidateBase) addr() net.Addr { return c.resolvedAddr } func (c *candidateBase) agent() *Agent { return c.currAgent } func (c *candidateBase) context() context.Context { return c } func (c *candidateBase) copy() (Candidate, error) { return UnmarshalCandidate(c.Marshal()) } // Marshal returns the string representation of the ICECandidate func (c *candidateBase) Marshal() string { val := c.Foundation() if val == " " { val = "" } val = fmt.Sprintf("%s %d %s %d %s %d typ %s", val, c.Component(), c.NetworkType().NetworkShort(), c.Priority(), c.Address(), c.Port(), c.Type()) if c.tcpType != TCPTypeUnspecified { val += fmt.Sprintf(" tcptype %s", c.tcpType.String()) } if r := c.RelatedAddress(); r != nil && r.Address != "" && r.Port != 0 { val = fmt.Sprintf("%s raddr %s rport %d", val, r.Address, r.Port) } return val } // UnmarshalCandidate creates a Candidate from its string representation func UnmarshalCandidate(raw string) (Candidate, error) { split := strings.Fields(raw) // Foundation not specified: not RFC 8445 compliant but seen in the wild if len(raw) != 0 && raw[0] == ' ' { split = append([]string{" "}, split...) } if len(split) < 8 { return nil, fmt.Errorf("%w (%d)", errAttributeTooShortICECandidate, len(split)) } // Foundation foundation := split[0] // Component rawComponent, err := strconv.ParseUint(split[1], 10, 16) if err != nil { return nil, fmt.Errorf("%w: %v", errParseComponent, err) //nolint:errorlint } component := uint16(rawComponent) // Protocol protocol := split[2] // Priority priorityRaw, err := strconv.ParseUint(split[3], 10, 32) if err != nil { return nil, fmt.Errorf("%w: %v", errParsePriority, err) //nolint:errorlint } priority := uint32(priorityRaw) // Address address := split[4] // Port rawPort, err := strconv.ParseUint(split[5], 10, 16) if err != nil { return nil, fmt.Errorf("%w: %v", errParsePort, err) //nolint:errorlint } port := int(rawPort) typ := split[7] relatedAddress := "" relatedPort := 0 tcpType := TCPTypeUnspecified if len(split) > 8 { split = split[8:] if split[0] == "raddr" { if len(split) < 4 { return nil, fmt.Errorf("%w: incorrect length", errParseRelatedAddr) } // RelatedAddress relatedAddress = split[1] // RelatedPort rawRelatedPort, parseErr := strconv.ParseUint(split[3], 10, 16) if parseErr != nil { return nil, fmt.Errorf("%w: %v", errParsePort, parseErr) //nolint:errorlint } relatedPort = int(rawRelatedPort) } else if split[0] == "tcptype" { if len(split) < 2 { return nil, fmt.Errorf("%w: incorrect length", errParseTCPType) } tcpType = NewTCPType(split[1]) } } switch typ { case "host": return NewCandidateHost(&CandidateHostConfig{"", protocol, address, port, component, priority, foundation, tcpType}) case "srflx": return NewCandidateServerReflexive(&CandidateServerReflexiveConfig{"", protocol, address, port, component, priority, foundation, relatedAddress, relatedPort}) case "prflx": return NewCandidatePeerReflexive(&CandidatePeerReflexiveConfig{"", protocol, address, port, component, priority, foundation, relatedAddress, relatedPort}) case "relay": return NewCandidateRelay(&CandidateRelayConfig{"", protocol, address, port, component, priority, foundation, relatedAddress, relatedPort, "", nil}) default: } return nil, fmt.Errorf("%w (%s)", ErrUnknownCandidateTyp, typ) }