package dht import ( "bytes" "net" "sort" "strconv" "github.com/lbryio/lbry.go/dht/bits" "github.com/lbryio/lbry.go/extras/errors" "github.com/lyoshenka/bencode" ) // TODO: if routing table is ever empty (aka the node is isolated), it should re-bootstrap // Contact contains information for contacting another node on the network type Contact struct { ID bits.Bitmap IP net.IP Port int // the udp port used for the dht PeerPort int // the tcp port a peer can be contacted on for blob requests } // Equals returns true if two contacts are the same. func (c Contact) Equals(other Contact, checkID bool) bool { return c.IP.Equal(other.IP) && c.Port == other.Port && (!checkID || c.ID == other.ID) } // Addr returns the address of the contact. func (c Contact) Addr() *net.UDPAddr { return &net.UDPAddr{IP: c.IP, Port: c.Port} } // String returns a short string representation of the contact func (c Contact) String() string { str := c.ID.HexShort() + "@" + c.Addr().String() if c.PeerPort != 0 { str += "(" + strconv.Itoa(c.PeerPort) + ")" } return str } // MarshalCompact returns a compact byteslice representation of the contact // NOTE: The compact representation always uses the tcp PeerPort, not the udp Port. This is dumb, but that's how the python daemon does it func (c Contact) MarshalCompact() ([]byte, error) { if c.IP.To4() == nil { return nil, errors.Err("ip not set") } if c.PeerPort < 0 || c.PeerPort > 65535 { return nil, errors.Err("invalid port") } var buf bytes.Buffer buf.Write(c.IP.To4()) buf.WriteByte(byte(c.PeerPort >> 8)) buf.WriteByte(byte(c.PeerPort)) buf.Write(c.ID[:]) if buf.Len() != compactNodeInfoLength { return nil, errors.Err("i dont know how this happened") } return buf.Bytes(), nil } // UnmarshalCompact unmarshals the compact byteslice representation of a contact. // NOTE: The compact representation always uses the tcp PeerPort, not the udp Port. This is dumb, but that's how the python daemon does it func (c *Contact) UnmarshalCompact(b []byte) error { if len(b) != compactNodeInfoLength { return errors.Err("invalid compact length") } c.IP = net.IPv4(b[0], b[1], b[2], b[3]).To4() c.PeerPort = int(uint16(b[5]) | uint16(b[4])<<8) c.ID = bits.FromBytesP(b[6:]) return nil } // MarshalBencode returns the serialized byte slice representation of a contact. func (c Contact) MarshalBencode() ([]byte, error) { return bencode.EncodeBytes([]interface{}{c.ID, c.IP.String(), c.Port}) } // UnmarshalBencode unmarshals the serialized byte slice into the appropriate fields of the contact. func (c *Contact) UnmarshalBencode(b []byte) error { var raw []bencode.RawMessage err := bencode.DecodeBytes(b, &raw) if err != nil { return err } if len(raw) != 3 { return errors.Err("contact must have 3 elements; got %d", len(raw)) } err = bencode.DecodeBytes(raw[0], &c.ID) if err != nil { return err } var ipStr string err = bencode.DecodeBytes(raw[1], &ipStr) if err != nil { return err } c.IP = net.ParseIP(ipStr).To4() if c.IP == nil { return errors.Err("invalid IP") } return bencode.DecodeBytes(raw[2], &c.Port) } func sortByDistance(contacts []Contact, target bits.Bitmap) { sort.Slice(contacts, func(i, j int) bool { return contacts[i].ID.Xor(target).Cmp(contacts[j].ID.Xor(target)) < 0 }) }