// Copyright 2017 The go-ethereum Authors // This file is part of the go-ethereum library. // // The go-ethereum library is free software: you can redistribute it and/or modify // it under the terms of the GNU Lesser General Public License as published by // the Free Software Foundation, either version 3 of the License, or // (at your option) any later version. // // The go-ethereum library is distributed in the hope that it will be useful, // but WITHOUT ANY WARRANTY; without even the implied warranty of // MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the // GNU Lesser General Public License for more details. // // You should have received a copy of the GNU Lesser General Public License // along with the go-ethereum library. If not, see . // Package enr implements Ethereum Node Records as defined in EIP-778. A node record holds // arbitrary information about a node on the peer-to-peer network. Node information is // stored in key/value pairs. To store and retrieve key/values in a record, use the Entry // interface. // // # Signature Handling // // Records must be signed before transmitting them to another node. // // Decoding a record doesn't check its signature. Code working with records from an // untrusted source must always verify two things: that the record uses an identity scheme // deemed secure, and that the signature is valid according to the declared scheme. // // When creating a record, set the entries you want and use a signing function provided by // the identity scheme to add the signature. Modifying a record invalidates the signature. // // Package enr supports the "secp256k1-keccak" identity scheme. package enr import ( "bytes" "errors" "fmt" "io" "sort" "github.com/ledgerwatch/erigon/rlp" ) const SizeLimit = 300 // maximum encoded size of a node record in bytes var ( ErrInvalidSig = errors.New("invalid signature on node record") errNotSorted = errors.New("record key/value pairs are not sorted by key") errDuplicateKey = errors.New("record contains duplicate key") errIncompletePair = errors.New("record contains incomplete k/v pair") errTooBig = fmt.Errorf("record bigger than %d bytes", SizeLimit) errEncodeUnsigned = errors.New("can't encode unsigned record") errNotFound = errors.New("no such key in record") ) // An IdentityScheme is capable of verifying record signatures and // deriving node addresses. type IdentityScheme interface { Verify(r *Record, sig []byte) error NodeAddr(r *Record) []byte } // SchemeMap is a registry of named identity schemes. type SchemeMap map[string]IdentityScheme func (m SchemeMap) Verify(r *Record, sig []byte) error { s := m[r.IdentityScheme()] if s == nil { return ErrInvalidSig } return s.Verify(r, sig) } func (m SchemeMap) NodeAddr(r *Record) []byte { s := m[r.IdentityScheme()] if s == nil { return nil } return s.NodeAddr(r) } // Record represents a node record. The zero value is an empty record. type Record struct { seq uint64 // sequence number signature []byte // the signature raw []byte // RLP encoded record pairs []pair // sorted list of all key/value pairs } // pair is a key/value pair in a record. type pair struct { k string v rlp.RawValue } // Seq returns the sequence number. func (r *Record) Seq() uint64 { return r.seq } // SetSeq updates the record sequence number. This invalidates any signature on the record. // Calling SetSeq is usually not required because setting any key in a signed record // increments the sequence number. func (r *Record) SetSeq(s uint64) { r.signature = nil r.raw = nil r.seq = s } // Load retrieves the value of a key/value pair. The given Entry must be a pointer and will // be set to the value of the entry in the record. // // Errors returned by Load are wrapped in KeyError. You can distinguish decoding errors // from missing keys using the IsNotFound function. func (r *Record) Load(e Entry) error { i := sort.Search(len(r.pairs), func(i int) bool { return r.pairs[i].k >= e.ENRKey() }) if i < len(r.pairs) && r.pairs[i].k == e.ENRKey() { if err := rlp.DecodeBytes(r.pairs[i].v, e); err != nil { return &KeyError{Key: e.ENRKey(), Err: err} } return nil } return &KeyError{Key: e.ENRKey(), Err: errNotFound} } // Set adds or updates the given entry in the record. It panics if the value can't be // encoded. If the record is signed, Set increments the sequence number and invalidates // the sequence number. func (r *Record) Set(e Entry) { blob, err := rlp.EncodeToBytes(e) if err != nil { panic(fmt.Errorf("enr: can't encode %s: %w", e.ENRKey(), err)) } r.invalidate() pairs := make([]pair, len(r.pairs)) copy(pairs, r.pairs) i := sort.Search(len(pairs), func(i int) bool { return pairs[i].k >= e.ENRKey() }) switch { case i < len(pairs) && pairs[i].k == e.ENRKey(): // element is present at r.pairs[i] pairs[i].v = blob case i < len(r.pairs): // insert pair before i-th elem el := pair{e.ENRKey(), blob} pairs = append(pairs, pair{}) copy(pairs[i+1:], pairs[i:]) pairs[i] = el default: // element should be placed at the end of r.pairs pairs = append(pairs, pair{e.ENRKey(), blob}) } r.pairs = pairs } func (r *Record) invalidate() { if r.signature != nil { r.seq++ } r.signature = nil r.raw = nil } // Signature returns the signature of the record. func (r *Record) Signature() []byte { if r.signature == nil { return nil } cpy := make([]byte, len(r.signature)) copy(cpy, r.signature) return cpy } // EncodeRLP implements rlp.Encoder. Encoding fails if // the record is unsigned. func (r Record) EncodeRLP(w io.Writer) error { if r.signature == nil { return errEncodeUnsigned } _, err := w.Write(r.raw) return err } // DecodeRLP implements rlp.Decoder. Decoding doesn't verify the signature. func (r *Record) DecodeRLP(s *rlp.Stream) error { dec, raw, err := decodeRecord(s) if err != nil { return err } *r = dec r.raw = raw return nil } func decodeRecord(s *rlp.Stream) (dec Record, raw []byte, err error) { raw, err = s.Raw() if err != nil { return dec, raw, err } if len(raw) > SizeLimit { return dec, raw, errTooBig } // Decode the RLP container. s = rlp.NewStream(bytes.NewReader(raw), 0) if _, e := s.List(); e != nil { return dec, raw, e } if e := s.Decode(&dec.signature); e != nil { return dec, raw, e } if e := s.Decode(&dec.seq); e != nil { return dec, raw, e } // The rest of the record contains sorted k/v pairs. var prevkey string for i := 0; ; i++ { var kv pair if err := s.Decode(&kv.k); err != nil { if err == rlp.EOL { break } return dec, raw, err } if err := s.Decode(&kv.v); err != nil { if err == rlp.EOL { return dec, raw, errIncompletePair } return dec, raw, err } if i > 0 { if kv.k == prevkey { return dec, raw, errDuplicateKey } if kv.k < prevkey { return dec, raw, errNotSorted } } dec.pairs = append(dec.pairs, kv) prevkey = kv.k } return dec, raw, s.ListEnd() } // IdentityScheme returns the name of the identity scheme in the record. func (r *Record) IdentityScheme() string { var id ID r.Load(&id) return string(id) } // VerifySignature checks whether the record is signed using the given identity scheme. func (r *Record) VerifySignature(s IdentityScheme) error { return s.Verify(r, r.signature) } // SetSig sets the record signature. It returns an error if the encoded record is larger // than the size limit or if the signature is invalid according to the passed scheme. // // You can also use SetSig to remove the signature explicitly by passing a nil scheme // and signature. // // SetSig panics when either the scheme or the signature (but not both) are nil. func (r *Record) SetSig(s IdentityScheme, sig []byte) error { switch { // Prevent storing invalid data. case s == nil && sig != nil: panic("enr: invalid call to SetSig with non-nil signature but nil scheme") case s != nil && sig == nil: panic("enr: invalid call to SetSig with nil signature but non-nil scheme") // Verify if we have a scheme. case s != nil: if err := s.Verify(r, sig); err != nil { return err } raw, err := r.encode(sig) if err != nil { return err } r.signature, r.raw = sig, raw // Reset otherwise. default: r.signature, r.raw = nil, nil } return nil } // AppendElements appends the sequence number and entries to the given slice. func (r *Record) AppendElements(list []interface{}) []interface{} { list = append(list, r.seq) for _, p := range r.pairs { list = append(list, p.k, p.v) } return list } func (r *Record) encode(sig []byte) (raw []byte, err error) { list := make([]interface{}, 1, 2*len(r.pairs)+1) list[0] = sig list = r.AppendElements(list) if raw, err = rlp.EncodeToBytes(list); err != nil { return nil, err } if len(raw) > SizeLimit { return nil, errTooBig } return raw, nil }