package multiaddr import ( "bytes" "encoding/json" "fmt" "log" "golang.org/x/exp/slices" ) // multiaddr is the data structure representing a Multiaddr type multiaddr struct { bytes []byte } // NewMultiaddr parses and validates an input string, returning a *Multiaddr func NewMultiaddr(s string) (a Multiaddr, err error) { defer func() { if e := recover(); e != nil { log.Printf("Panic in NewMultiaddr on input %q: %s", s, e) err = fmt.Errorf("%v", e) } }() b, err := stringToBytes(s) if err != nil { return nil, err } return &multiaddr{bytes: b}, nil } // NewMultiaddrBytes initializes a Multiaddr from a byte representation. // It validates it as an input string. func NewMultiaddrBytes(b []byte) (a Multiaddr, err error) { defer func() { if e := recover(); e != nil { log.Printf("Panic in NewMultiaddrBytes on input %q: %s", b, e) err = fmt.Errorf("%v", e) } }() if err := validateBytes(b); err != nil { return nil, err } return &multiaddr{bytes: b}, nil } // Equal tests whether two multiaddrs are equal func (m *multiaddr) Equal(m2 Multiaddr) bool { if m2 == nil { return false } return bytes.Equal(m.bytes, m2.Bytes()) } // Bytes returns the []byte representation of this Multiaddr // // Do not modify the returned buffer, it may be shared. func (m *multiaddr) Bytes() []byte { return m.bytes } // String returns the string representation of a Multiaddr func (m *multiaddr) String() string { s, err := bytesToString(m.bytes) if err != nil { panic(fmt.Errorf("multiaddr failed to convert back to string. corrupted? %s", err)) } return s } func (m *multiaddr) MarshalBinary() ([]byte, error) { return m.Bytes(), nil } func (m *multiaddr) UnmarshalBinary(data []byte) error { new, err := NewMultiaddrBytes(data) if err != nil { return err } *m = *(new.(*multiaddr)) return nil } func (m *multiaddr) MarshalText() ([]byte, error) { return []byte(m.String()), nil } func (m *multiaddr) UnmarshalText(data []byte) error { new, err := NewMultiaddr(string(data)) if err != nil { return err } *m = *(new.(*multiaddr)) return nil } func (m *multiaddr) MarshalJSON() ([]byte, error) { return json.Marshal(m.String()) } func (m *multiaddr) UnmarshalJSON(data []byte) error { var v string if err := json.Unmarshal(data, &v); err != nil { return err } new, err := NewMultiaddr(v) *m = *(new.(*multiaddr)) return err } // Protocols returns the list of protocols this Multiaddr has. // will panic in case we access bytes incorrectly. func (m *multiaddr) Protocols() []Protocol { ps := make([]Protocol, 0, 8) b := m.bytes for len(b) > 0 { code, n, err := ReadVarintCode(b) if err != nil { panic(err) } p := ProtocolWithCode(code) if p.Code == 0 { // this is a panic (and not returning err) because this should've been // caught on constructing the Multiaddr panic(fmt.Errorf("no protocol with code %d", b[0])) } ps = append(ps, p) b = b[n:] n, size, err := sizeForAddr(p, b) if err != nil { panic(err) } b = b[n+size:] } return ps } // Encapsulate wraps a given Multiaddr, returning the resulting joined Multiaddr func (m *multiaddr) Encapsulate(o Multiaddr) Multiaddr { if o == nil { return m } mb := m.bytes ob := o.Bytes() b := make([]byte, len(mb)+len(ob)) copy(b, mb) copy(b[len(mb):], ob) return &multiaddr{bytes: b} } // Decapsulate unwraps Multiaddr up until the given Multiaddr is found. func (m *multiaddr) Decapsulate(right Multiaddr) Multiaddr { if right == nil { return m } leftParts := Split(m) rightParts := Split(right) lastIndex := -1 for i := range leftParts { foundMatch := false for j, rightC := range rightParts { if len(leftParts) <= i+j { foundMatch = false break } foundMatch = rightC.Equal(leftParts[i+j]) if !foundMatch { break } } if foundMatch { lastIndex = i } } if lastIndex == 0 { return nil } if lastIndex < 0 { // if multiaddr not contained, returns a copy. cpy := make([]byte, len(m.bytes)) copy(cpy, m.bytes) return &multiaddr{bytes: cpy} } return Join(leftParts[:lastIndex]...) } var ErrProtocolNotFound = fmt.Errorf("protocol not found in multiaddr") func (m *multiaddr) ValueForProtocol(code int) (value string, err error) { err = ErrProtocolNotFound ForEach(m, func(c Component) bool { if c.Protocol().Code == code { value = c.Value() err = nil return false } return true }) return } // FilterAddrs is a filter that removes certain addresses, according to the given filters. // If all filters return true, the address is kept. func FilterAddrs(a []Multiaddr, filters ...func(Multiaddr) bool) []Multiaddr { b := make([]Multiaddr, 0, len(a)) addrloop: for _, addr := range a { for _, filter := range filters { if !filter(addr) { continue addrloop } } b = append(b, addr) } return b } // Contains reports whether addr is contained in addrs. func Contains(addrs []Multiaddr, addr Multiaddr) bool { for _, a := range addrs { if addr.Equal(a) { return true } } return false } // Unique deduplicates addresses in place, leave only unique addresses. // It doesn't allocate. func Unique(addrs []Multiaddr) []Multiaddr { if len(addrs) == 0 { return addrs } // Use the new slices package here, as the sort function doesn't allocate (sort.Slice does). slices.SortFunc(addrs, func(a, b Multiaddr) int { return bytes.Compare(a.Bytes(), b.Bytes()) }) idx := 1 for i := 1; i < len(addrs); i++ { if !addrs[i-1].Equal(addrs[i]) { addrs[idx] = addrs[i] idx++ } } for i := idx; i < len(addrs); i++ { addrs[i] = nil } return addrs[:idx] }