// ResolveUnspecifiedAddress expands an unspecified ip addresses (/ip4/0.0.0.0, /ip6/::) to // use the known local interfaces. If ifaceAddr is nil, we request interface addresses // from the network stack. (this is so you can provide a cached value if resolving many addrs) func ResolveUnspecifiedAddress(resolve ma.Multiaddr, ifaceAddrs []ma.Multiaddr) ([]ma.Multiaddr, error) { // split address into its components split := ma.Split(resolve) // if first component (ip) is not unspecified, use it as is. if !manet.IsIPUnspecified(split[0]) { return []ma.Multiaddr{resolve}, nil } out := make([]ma.Multiaddr, 0, len(ifaceAddrs)) for _, ia := range ifaceAddrs { // must match the first protocol to be resolve. if ia.Protocols()[0].Code != resolve.Protocols()[0].Code { continue } split[0] = ia joined := ma.Join(split...) out = append(out, joined) log.Debug("adding resolved addr:", resolve, joined, out) } if len(out) < 1 { return nil, fmt.Errorf("failed to resolve: %s", resolve) } return out, nil }
// AddrMatch returns the Multiaddrs that match the protocol stack on addr func AddrMatch(match ma.Multiaddr, addrs []ma.Multiaddr) []ma.Multiaddr { // we should match transports entirely. p1s := match.Protocols() out := make([]ma.Multiaddr, 0, len(addrs)) for _, a := range addrs { p2s := a.Protocols() if len(p1s) != len(p2s) { continue } match := true for i, p2 := range p2s { if p1s[i].Code != p2.Code { match = false break } } if match { out = append(out, a) } } return out }
// MultiaddrProtocolsMatch returns whether two multiaddrs match in protocol stacks. func MultiaddrProtocolsMatch(a, b ma.Multiaddr) bool { ap := a.Protocols() bp := b.Protocols() if len(ap) != len(bp) { return false } for i, api := range ap { if api.Code != bp[i].Code { return false } } return true }
// AddrUsable returns whether our network can use this addr. // We only use the transports in SupportedTransportStrings, // and we do not link local addresses. Loopback is ok // as we need to be able to connect to multiple ipfs nodes // in the same machine. func AddrUsable(a ma.Multiaddr, partial bool) bool { if a == nil { return false } if !AddrOverNonLocalIP(a) { return false } // test the address protocol list is in SupportedTransportProtocols matches := func(supported, test []ma.Protocol) bool { if len(test) > len(supported) { return false } // when partial, it's ok if test < supported. if !partial && len(supported) != len(test) { return false } for i := range test { if supported[i].Code != test[i].Code { return false } } return true } transport := a.Protocols() for _, supported := range SupportedTransportProtocols { if matches(supported, transport) { return true } } return false }
// IsThinWaist returns whether a Multiaddr starts with "Thin Waist" Protocols. // This means: /{IP4, IP6}[/{TCP, UDP}] func IsThinWaist(m ma.Multiaddr) bool { p := m.Protocols() // nothing? not even a waist. if len(p) == 0 { return false } if p[0].Code != ma.P_IP4 && p[0].Code != ma.P_IP6 { return false } // only IP? still counts. if len(p) == 1 { return true } switch p[1].Code { case ma.P_TCP, ma.P_UDP, ma.P_IP4, ma.P_IP6: return true default: return false } }
func IsUtpMultiaddr(a ma.Multiaddr) bool { p := a.Protocols() return len(p) == 3 && p[2].Name == "utp" }
func IsTcpMultiaddr(a ma.Multiaddr) bool { p := a.Protocols() return len(p) == 2 && (p[0].Name == "ip4" || p[0].Name == "ip6") && p[1].Name == "tcp" }
func (d *UtpTransport) Matches(a ma.Multiaddr) bool { p := a.Protocols() return len(p) == 3 && p[2].Name == "utp" }
func (s *UtpSocket) Matches(a ma.Multiaddr) bool { p := a.Protocols() return len(p) == 3 && p[2].Name == "utp" }