# nim-eth - Node Discovery Protocol v5 # Copyright (c) 2020-2021 Status Research & Development GmbH # Licensed and distributed under either of # * MIT license (license terms in the root directory or at https://opensource.org/licenses/MIT). # * Apache v2 license (license terms in the root directory or at https://www.apache.org/licenses/LICENSE-2.0). # at your option. This file may not be copied, modified, or distributed except according to those terms. # ## ENR implementation according to specification in EIP-778: ## https://github.com/ethereum/EIPs/blob/master/EIPS/eip-778.md {.push raises: [Defect].} import std/[strutils, macros, algorithm, options], stew/shims/net, stew/base64, nimcrypto, ".."/../[rlp, keys] export options const maxEnrSize = 300 ## Maximum size of an encoded node record, in bytes. minRlpListLen = 4 ## Minimum node record RLP list has: signature, seqId, ## "id" key and value. type FieldPair* = (string, Field) Record* = object seqNum*: uint64 # signature: seq[byte] raw*: seq[byte] # RLP encoded record pairs: seq[FieldPair] # sorted list of all key/value pairs EnrUri* = distinct string TypedRecord* = object id*: string secp256k1*: Option[array[33, byte]] ip*: Option[array[4, byte]] ip6*: Option[array[16, byte]] tcp*: Option[int] udp*: Option[int] tcp6*: Option[int] udp6*: Option[int] FieldKind = enum kString, kNum, kBytes, kList Field = object case kind: FieldKind of kString: str: string of kNum: num: BiggestUInt of kBytes: bytes: seq[byte] of kList: listRaw: seq[byte] ## Differently from the other kinds, this is is stored ## as raw (encoded) RLP data, and thus treated as such further on. EnrResult*[T] = Result[T, cstring] template toField[T](v: T): Field = when T is string: Field(kind: kString, str: v) elif T is array: Field(kind: kBytes, bytes: @v) elif T is seq[byte]: Field(kind: kBytes, bytes: v) elif T is SomeUnsignedInt: Field(kind: kNum, num: BiggestUInt(v)) elif T is object|tuple: Field(kind: kList, listRaw: rlp.encode(v)) else: {.error: "Unsupported field type".} proc `==`(a, b: Field): bool = if a.kind == b.kind: case a.kind of kString: return a.str == b.str of kNum: return a.num == b.num of kBytes: return a.bytes == b.bytes of kList: return a.listRaw == b.listRaw else: return false proc cmp(a, b: FieldPair): int = cmp(a[0], b[0]) proc makeEnrRaw(seqNum: uint64, pk: PrivateKey, pairs: openarray[FieldPair]): EnrResult[seq[byte]] = proc append(w: var RlpWriter, seqNum: uint64, pairs: openarray[FieldPair]): seq[byte] = w.append(seqNum) for (k, v) in pairs: w.append(k) case v.kind of kString: w.append(v.str) of kNum: w.append(v.num) of kBytes: w.append(v.bytes) of kList: w.appendRawBytes(v.listRaw) # No encoding needs to happen w.finish() let toSign = block: var w = initRlpList(pairs.len * 2 + 1) w.append(seqNum, pairs) let sig = signNR(pk, toSign) var raw = block: var w = initRlpList(pairs.len * 2 + 2) w.append(sig.toRaw()) w.append(seqNum, pairs) if raw.len > maxEnrSize: err("Record exceeds maximum size") else: ok(raw) proc makeEnrAux(seqNum: uint64, pk: PrivateKey, pairs: openarray[FieldPair]): EnrResult[Record] = var record: Record record.pairs = @pairs record.seqNum = seqNum let pubkey = pk.toPublicKey() record.pairs.add(("id", Field(kind: kString, str: "v4"))) record.pairs.add(("secp256k1", Field(kind: kBytes, bytes: @(pubkey.toRawCompressed())))) # Sort by key record.pairs.sort(cmp) # TODO: Should deduplicate on keys here also. Should we error on that or just # deal with it? record.raw = ? makeEnrRaw(seqNum, pk, record.pairs) ok(record) macro initRecord*(seqNum: uint64, pk: PrivateKey, pairs: untyped{nkTableConstr}): untyped = ## Initialize a `Record` with given sequence number, private key and k:v ## pairs. ## ## Can fail in case the record exceeds the `maxEnrSize`. for c in pairs: c.expectKind(nnkExprColonExpr) c[1] = newCall(bindSym"toField", c[1]) result = quote do: makeEnrAux(`seqNum`, `pk`, `pairs`) template toFieldPair*(key: string, value: auto): FieldPair = (key, toField(value)) proc addAddress(fields: var seq[FieldPair], ip: Option[ValidIpAddress], tcpPort, udpPort: Option[Port]) = ## Add address information in new fields. Incomplete address ## information is allowed (example: Port but not IP) as that information ## might be already in the ENR or added later. if ip.isSome(): let ipExt = ip.get() isV6 = ipExt.family == IPv6 fields.add(if isV6: ("ip6", ipExt.address_v6.toField) else: ("ip", ipExt.address_v4.toField)) if tcpPort.isSome(): fields.add(((if isV6: "tcp6" else: "tcp"), tcpPort.get().uint16.toField)) if udpPort.isSome(): fields.add(((if isV6: "udp6" else: "udp"), udpPort.get().uint16.toField)) else: if tcpPort.isSome(): fields.add(("tcp", tcpPort.get().uint16.toField)) if udpPort.isSome(): fields.add(("udp", udpPort.get().uint16.toField)) proc init*(T: type Record, seqNum: uint64, pk: PrivateKey, ip: Option[ValidIpAddress], tcpPort, udpPort: Option[Port], extraFields: openarray[FieldPair] = []): EnrResult[T] = ## Initialize a `Record` with given sequence number, private key, optional ## ip address, tcp port, udp port, and optional custom k:v pairs. ## ## Can fail in case the record exceeds the `maxEnrSize`. var fields = newSeq[FieldPair]() # TODO: Allow for initializing ENR with both ip4 and ipv6 address. fields.addAddress(ip, tcpPort, udpPort) fields.add extraFields makeEnrAux(seqNum, pk, fields) proc getField(r: Record, name: string, field: var Field): bool = # It might be more correct to do binary search, # as the fields are sorted, but it's unlikely to # make any difference in reality. for (k, v) in r.pairs: if k == name: field = v return true proc requireKind(f: Field, kind: FieldKind) {.raises: [ValueError].} = if f.kind != kind: raise newException(ValueError, "Wrong field kind") proc get*(r: Record, key: string, T: type): T {.raises: [ValueError, Defect].} = ## Get the value from the provided key. ## Throw `KeyError` if key does not exist. ## Throw `ValueError` if the value is invalid according to type `T`. var f: Field if r.getField(key, f): when T is SomeInteger: requireKind(f, kNum) return T(f.num) elif T is seq[byte]: requireKind(f, kBytes) return f.bytes elif T is string: requireKind(f, kString) return f.str elif T is PublicKey: requireKind(f, kBytes) let pk = PublicKey.fromRaw(f.bytes) if pk.isErr: raise newException(ValueError, "Invalid public key") return pk[] elif T is array: when type(result[0]) is byte: requireKind(f, kBytes) if f.bytes.len != result.len: raise newException(ValueError, "Invalid byte blob length") copyMem(addr result[0], addr f.bytes[0], result.len) else: {.fatal: "Unsupported output type in enr.get".} else: {.fatal: "Unsupported output type in enr.get".} else: raise newException(KeyError, "Key not found in ENR: " & key) proc get*(r: Record, T: type PublicKey): Option[T] = ## Get the `PublicKey` from provided `Record`. Return `none` when there is ## no `PublicKey` in the record. var pubkeyField: Field if r.getField("secp256k1", pubkeyField) and pubkeyField.kind == kBytes: let pk = PublicKey.fromRaw(pubkeyField.bytes) if pk.isOk: return some pk[] proc find(r: Record, key: string): Option[int] = ## Search for key in record key:value pairs. ## ## Returns some(index of key) if key is found in record. Else return none. for i, (k, v) in r.pairs: if k == key: return some(i) proc update*(record: var Record, pk: PrivateKey, fieldPairs: openarray[FieldPair]): EnrResult[void] = ## Update a `Record` k:v pairs. ## ## In case any of the k:v pairs is updated or added (new), the sequence number ## of the `Record` will be incremented and a new signature will be applied. ## ## Can fail in case of wrong `PrivateKey`, if the size of the resulting record ## exceeds `maxEnrSize` or if maximum sequence number is reached. The `Record` ## will not be altered in these cases. var r = record let pubkey = r.get(PublicKey) if pubkey.isNone() or pubkey.get() != pk.toPublicKey(): return err("Public key does not correspond with given private key") var updated = false for fieldPair in fieldPairs: let index = r.find(fieldPair[0]) if(index.isSome()): if r.pairs[index.get()][1] == fieldPair[1]: # Exact k:v pair is already in record, nothing to do here. continue else: # Need to update the value. r.pairs[index.get()] = fieldPair updated = true else: # Add new k:v pair. r.pairs.insert(fieldPair, lowerBound(r.pairs, fieldPair, cmp)) updated = true if updated: if r.seqNum == high(r.seqNum): # highly unlikely return err("Maximum sequence number reached") r.seqNum.inc() r.raw = ? makeEnrRaw(r.seqNum, pk, r.pairs) record = r ok() proc update*(r: var Record, pk: PrivateKey, ip: Option[ValidIpAddress], tcpPort, udpPort: Option[Port] = none[Port](), extraFields: openarray[FieldPair] = []): EnrResult[void] = ## Update a `Record` with given ip address, tcp port, udp port and optional ## custom k:v pairs. ## ## In case any of the k:v pairs is updated or added (new), the sequence number ## of the `Record` will be incremented and a new signature will be applied. ## ## Can fail in case of wrong `PrivateKey`, if the size of the resulting record ## exceeds `maxEnrSize` or if maximum sequence number is reached. The `Record` ## will not be altered in these cases. var fields = newSeq[FieldPair]() # TODO: Make updating of both ipv4 and ipv6 address in ENR more convenient. fields.addAddress(ip, tcpPort, udpPort) fields.add extraFields r.update(pk, fields) proc tryGet*(r: Record, key: string, T: type): Option[T] = ## Get the value from the provided key. ## Return `none` if the key does not exist or if the value is invalid ## according to type `T`. try: return some get(r, key, T) except ValueError: discard proc toTypedRecord*(r: Record): EnrResult[TypedRecord] = let id = r.tryGet("id", string) if id.isSome: var tr: TypedRecord tr.id = id.get template readField(fieldName: untyped) {.dirty.} = tr.fieldName = tryGet(r, astToStr(fieldName), type(tr.fieldName.get)) readField secp256k1 readField ip readField ip6 readField tcp readField tcp6 readField udp readField udp6 ok(tr) else: err("Record without id field") proc contains*(r: Record, fp: (string, seq[byte])): bool = # TODO: use FieldPair for this, but that is a bit cumbersome. Perhaps the # `get` call can be improved to make this easier. let field = r.tryGet(fp[0], seq[byte]) if field.isSome(): if field.get() == fp[1]: return true proc verifySignatureV4(r: Record, sigData: openarray[byte], content: seq[byte]): bool = let publicKey = r.get(PublicKey) if publicKey.isSome: let sig = SignatureNR.fromRaw(sigData) if sig.isOk: var h = keccak256.digest(content) return verify(sig[], SkMessage(h.data), publicKey.get) proc verifySignature(r: Record): bool {.raises: [RlpError, Defect].} = var rlp = rlpFromBytes(r.raw) let sz = rlp.listLen if not rlp.enterList: return false let sigData = rlp.read(seq[byte]) let content = block: var writer = initRlpList(sz - 1) var reader = rlp for i in 1 ..< sz: writer.appendRawBytes(reader.rawData) reader.skipElem writer.finish() var id: Field if r.getField("id", id) and id.kind == kString: case id.str of "v4": result = verifySignatureV4(r, sigData, content) else: # Unknown Identity Scheme discard proc fromBytesAux(r: var Record): bool {.raises: [RlpError, Defect].} = if r.raw.len > maxEnrSize: return false var rlp = rlpFromBytes(r.raw) if not rlp.isList: return false let sz = rlp.listLen if sz < minRlpListLen or sz mod 2 != 0: # Wrong rlp object return false # We already know we are working with a list doAssert rlp.enterList() rlp.skipElem() # Skip signature r.seqNum = rlp.read(uint64) let numPairs = (sz - 2) div 2 for i in 0 ..< numPairs: let k = rlp.read(string) case k of "id": let id = rlp.read(string) r.pairs.add((k, Field(kind: kString, str: id))) of "secp256k1": let pubkeyData = rlp.read(seq[byte]) r.pairs.add((k, Field(kind: kBytes, bytes: pubkeyData))) of "tcp", "udp", "tcp6", "udp6": let v = rlp.read(uint16) r.pairs.add((k, Field(kind: kNum, num: v))) else: # Don't know really what this is supposed to represent so drop it in # `kBytes` field pair when a single byte or blob. if rlp.isSingleByte() or rlp.isBlob(): r.pairs.add((k, Field(kind: kBytes, bytes: rlp.read(seq[byte])))) elif rlp.isList(): # Not supporting decoding lists as value (especially unknown ones), # just drop the raw RLP value in there. r.pairs.add((k, Field(kind: kList, listRaw: @(rlp.rawData())))) # Need to skip the element still. rlp.skipElem() verifySignature(r) proc fromBytes*(r: var Record, s: openarray[byte]): bool = ## Loads ENR from rlp-encoded bytes, and validates the signature. r.raw = @s try: result = fromBytesAux(r) except RlpError: discard proc fromBase64*(r: var Record, s: string): bool = ## Loads ENR from base64-encoded rlp-encoded bytes, and validates the ## signature. try: r.raw = Base64Url.decode(s) result = fromBytesAux(r) except RlpError, Base64Error: discard proc fromURI*(r: var Record, s: string): bool = ## Loads ENR from its text encoding: base64-encoded rlp-encoded bytes, ## prefixed with "enr:". Validates the signature. const prefix = "enr:" if s.startsWith(prefix): result = r.fromBase64(s[prefix.len .. ^1]) template fromURI*(r: var Record, url: EnrUri): bool = fromURI(r, string(url)) proc toBase64*(r: Record): string = result = Base64Url.encode(r.raw) proc toURI*(r: Record): string = "enr:" & r.toBase64 proc `$`(f: Field): string = case f.kind of kNum: $f.num of kBytes: "0x" & f.bytes.toHex of kString: "\"" & f.str & "\"" of kList: "(Raw RLP list) " & "0x" & f.listRaw.toHex proc `$`*(r: Record): string = result = "(" result &= $r.seqNum for (k, v) in r.pairs: result &= ", " result &= k result &= ": " # For IP addresses we print something prettier than the default kinds # Note: Could disallow for invalid IPs in ENR also. if k == "ip": let ip = r.tryGet("ip", array[4, byte]) if ip.isSome(): result &= $ipv4(ip.get()) else: result &= "(Invalid) " & $v elif k == "ip6": let ip = r.tryGet("ip6", array[16, byte]) if ip.isSome(): result &= $ipv6(ip.get()) else: result &= "(Invalid) " & $v else: result &= $v result &= ')' proc `==`*(a, b: Record): bool = a.raw == b.raw proc read*(rlp: var Rlp, T: typedesc[Record]): T {.raises: [RlpError, ValueError, Defect].} = if not rlp.hasData() or not result.fromBytes(rlp.rawData): # TODO: This could also just be an invalid signature, would be cleaner to # split of RLP deserialisation errors from this. raise newException(ValueError, "Could not deserialize") rlp.skipElem() proc append*(rlpWriter: var RlpWriter, value: Record) = rlpWriter.appendRawBytes(value.raw)