# Nim-Libp2p # Copyright (c) 2023 Status Research & Development GmbH # Licensed under either of # * Apache License, version 2.0, ([LICENSE-APACHE](LICENSE-APACHE)) # * MIT license ([LICENSE-MIT](LICENSE-MIT)) # at your option. # This file may not be copied, modified, or distributed except according to # those terms. ## This module implements MultiAddress. when (NimMajor, NimMinor) < (1, 4): {.push raises: [Defect].} else: {.push raises: [].} {.push public.} import pkg/chronos, chronicles import std/[nativesockets, hashes] import tables, strutils, sets, stew/shims/net import multicodec, multihash, multibase, transcoder, vbuffer, peerid, protobuf/minprotobuf, errors, utility import stew/[base58, base32, endians2, results] export results, minprotobuf, vbuffer, utility logScope: topics = "libp2p multiaddress" type MAKind* = enum None, Fixed, Length, Path, Marker MAProtocol* = object mcodec*: MultiCodec size*: int kind: MAKind coder*: Transcoder MultiAddress* = object data: VBuffer MaPatternOp* = enum Eq, Or, And MaPattern* = object operator*: MaPatternOp args*: seq[MaPattern] value*: MultiCodec MaPatResult* = object flag*: bool rem*: seq[MultiCodec] MaResult*[T] = Result[T, string] MaError* = object of LPError MaInvalidAddress* = object of MaError IpTransportProtocol* = enum tcpProtocol udpProtocol const # These are needed in order to avoid an ambiguity error stemming from # some cint constants with the same name defined in the posix modules IPPROTO_TCP = Protocol.IPPROTO_TCP IPPROTO_UDP = Protocol.IPPROTO_UDP proc data*(ma: MultiAddress): VBuffer = ## Returns the data buffer of the MultiAddress. return ma.data proc hash*(a: MultiAddress): Hash = var h: Hash = 0 h = h !& hash(a.data.buffer) h = h !& hash(a.data.offset) !$h proc ip4StB(s: string, vb: var VBuffer): bool = ## IPv4 stringToBuffer() implementation. try: var a = parseIpAddress(s) if a.family == IpAddressFamily.IPv4: vb.writeArray(a.address_v4) result = true except CatchableError: discard proc ip4BtS(vb: var VBuffer, s: var string): bool = ## IPv4 bufferToString() implementation. var a = IpAddress(family: IpAddressFamily.IPv4) if vb.readArray(a.address_v4) == 4: s = $a result = true proc ip4VB(vb: var VBuffer): bool = ## IPv4 validateBuffer() implementation. var a = IpAddress(family: IpAddressFamily.IPv4) if vb.readArray(a.address_v4) == 4: result = true proc ip6StB(s: string, vb: var VBuffer): bool = ## IPv6 stringToBuffer() implementation. try: var a = parseIpAddress(s) if a.family == IpAddressFamily.IPv6: vb.writeArray(a.address_v6) result = true except CatchableError: discard proc ip6BtS(vb: var VBuffer, s: var string): bool = ## IPv6 bufferToString() implementation. var a = IpAddress(family: IpAddressFamily.IPv6) if vb.readArray(a.address_v6) == 16: s = $a result = true proc ip6VB(vb: var VBuffer): bool = ## IPv6 validateBuffer() implementation. var a = IpAddress(family: IpAddressFamily.IPv6) if vb.readArray(a.address_v6) == 16: result = true proc ip6zoneStB(s: string, vb: var VBuffer): bool = ## IPv6 stringToBuffer() implementation. if len(s) > 0: vb.writeSeq(s) result = true proc ip6zoneBtS(vb: var VBuffer, s: var string): bool = ## IPv6 bufferToString() implementation. if vb.readSeq(s) > 0: result = true proc ip6zoneVB(vb: var VBuffer): bool = ## IPv6 validateBuffer() implementation. var s = "" if vb.readSeq(s) > 0: if s.find('/') == -1: result = true proc portStB(s: string, vb: var VBuffer): bool = ## Port number stringToBuffer() implementation. var port: array[2, byte] try: var nport = parseInt(s) if (nport >= 0) and (nport < 65536): port[0] = cast[byte]((nport shr 8) and 0xFF) port[1] = cast[byte](nport and 0xFF) vb.writeArray(port) result = true except CatchableError: discard proc portBtS(vb: var VBuffer, s: var string): bool = ## Port number bufferToString() implementation. var port: array[2, byte] if vb.readArray(port) == 2: var nport = (safeConvert[uint16](port[0]) shl 8) or safeConvert[uint16](port[1]) s = $nport result = true proc portVB(vb: var VBuffer): bool = ## Port number validateBuffer() implementation. var port: array[2, byte] if vb.readArray(port) == 2: result = true proc p2pStB(s: string, vb: var VBuffer): bool = ## P2P address stringToBuffer() implementation. try: var data = Base58.decode(s) var mh: MultiHash if MultiHash.decode(data, mh).isOk: vb.writeSeq(data) result = true except CatchableError: discard proc p2pBtS(vb: var VBuffer, s: var string): bool = ## P2P address bufferToString() implementation. var address = newSeq[byte]() if vb.readSeq(address) > 0: var mh: MultiHash if MultiHash.decode(address, mh).isOk: s = Base58.encode(address) result = true proc p2pVB(vb: var VBuffer): bool = ## P2P address validateBuffer() implementation. var address = newSeq[byte]() if vb.readSeq(address) > 0: var mh: MultiHash if MultiHash.decode(address, mh).isOk: result = true proc onionStB(s: string, vb: var VBuffer): bool = try: var parts = s.split(':') if len(parts) != 2: return false if len(parts[0]) != 16: return false var address = Base32Lower.decode(parts[0].toLowerAscii()) var nport = parseInt(parts[1]) if (nport > 0 and nport < 65536) and len(address) == 10: address.setLen(12) address[10] = cast[byte]((nport shr 8) and 0xFF) address[11] = cast[byte](nport and 0xFF) vb.writeArray(address) result = true except CatchableError: discard proc onionBtS(vb: var VBuffer, s: var string): bool = ## ONION address bufferToString() implementation. var buf: array[12, byte] if vb.readArray(buf) == 12: var nport = (safeConvert[uint16](buf[10]) shl 8) or safeConvert[uint16](buf[11]) s = Base32Lower.encode(buf.toOpenArray(0, 9)) s.add(":") s.add($nport) result = true proc onionVB(vb: var VBuffer): bool = ## ONION address validateBuffer() implementation. var buf: array[12, byte] if vb.readArray(buf) == 12: result = true proc onion3StB(s: string, vb: var VBuffer): bool = try: var parts = s.split(':') if len(parts) != 2: return false if len(parts[0]) != 56: return false var address = Base32Lower.decode(parts[0].toLowerAscii()) var nport = parseInt(parts[1]) if (nport > 0 and nport < 65536) and len(address) == 35: address.setLen(37) address[35] = cast[byte]((nport shr 8) and 0xFF) address[36] = cast[byte](nport and 0xFF) vb.writeArray(address) result = true except CatchableError: discard proc onion3BtS(vb: var VBuffer, s: var string): bool = ## ONION address bufferToString() implementation. var buf: array[37, byte] if vb.readArray(buf) == 37: var nport = (safeConvert[uint16](buf[35]) shl 8) or safeConvert[uint16](buf[36]) s = Base32Lower.encode(buf.toOpenArray(0, 34)) s.add(":") s.add($nport) result = true proc onion3VB(vb: var VBuffer): bool = ## ONION address validateBuffer() implementation. var buf: array[37, byte] if vb.readArray(buf) == 37: result = true proc unixStB(s: string, vb: var VBuffer): bool = ## Unix socket name stringToBuffer() implementation. if len(s) > 0: vb.writeSeq(s) result = true proc unixBtS(vb: var VBuffer, s: var string): bool = ## Unix socket name bufferToString() implementation. s = "" if vb.readSeq(s) > 0: result = true proc unixVB(vb: var VBuffer): bool = ## Unix socket name validateBuffer() implementation. var s = "" if vb.readSeq(s) > 0: result = true proc dnsStB(s: string, vb: var VBuffer): bool = ## DNS name stringToBuffer() implementation. if len(s) > 0: vb.writeSeq(s) result = true proc dnsBtS(vb: var VBuffer, s: var string): bool = ## DNS name bufferToString() implementation. s = "" if vb.readSeq(s) > 0: result = true proc dnsVB(vb: var VBuffer): bool = ## DNS name validateBuffer() implementation. var s = "" if vb.readSeq(s) > 0: if s.find('/') == -1: result = true proc mapEq*(codec: string): MaPattern = ## ``Equal`` operator for pattern result.operator = Eq result.value = multiCodec(codec) proc mapOr*(args: varargs[MaPattern]): MaPattern = ## ``Or`` operator for pattern result.operator = Or result.args = @args proc mapAnd*(args: varargs[MaPattern]): MaPattern = ## ``And`` operator for pattern result.operator = And result.args = @args const TranscoderIP4* = Transcoder( stringToBuffer: ip4StB, bufferToString: ip4BtS, validateBuffer: ip4VB ) TranscoderIP6* = Transcoder( stringToBuffer: ip6StB, bufferToString: ip6BtS, validateBuffer: ip6VB ) TranscoderIP6Zone* = Transcoder( stringToBuffer: ip6zoneStB, bufferToString: ip6zoneBtS, validateBuffer: ip6zoneVB ) TranscoderUnix* = Transcoder( stringToBuffer: unixStB, bufferToString: unixBtS, validateBuffer: unixVB ) TranscoderP2P* = Transcoder( stringToBuffer: p2pStB, bufferToString: p2pBtS, validateBuffer: p2pVB ) TranscoderPort* = Transcoder( stringToBuffer: portStB, bufferToString: portBtS, validateBuffer: portVB ) TranscoderOnion* = Transcoder( stringToBuffer: onionStB, bufferToString: onionBtS, validateBuffer: onionVB ) TranscoderOnion3* = Transcoder( stringToBuffer: onion3StB, bufferToString: onion3BtS, validateBuffer: onion3VB ) TranscoderDNS* = Transcoder( stringToBuffer: dnsStB, bufferToString: dnsBtS, validateBuffer: dnsVB ) ProtocolsList = [ MAProtocol( mcodec: multiCodec("ip4"), kind: Fixed, size: 4, coder: TranscoderIP4 ), MAProtocol( mcodec: multiCodec("tcp"), kind: Fixed, size: 2, coder: TranscoderPort ), MAProtocol( mcodec: multiCodec("udp"), kind: Fixed, size: 2, coder: TranscoderPort ), MAProtocol( mcodec: multiCodec("ip6"), kind: Fixed, size: 16, coder: TranscoderIP6 ), MAProtocol( mcodec: multiCodec("dccp"), kind: Fixed, size: 2, coder: TranscoderPort ), MAProtocol( mcodec: multiCodec("sctp"), kind: Fixed, size: 2, coder: TranscoderPort ), MAProtocol( mcodec: multiCodec("udt"), kind: Marker, size: 0 ), MAProtocol( mcodec: multiCodec("utp"), kind: Marker, size: 0 ), MAProtocol( mcodec: multiCodec("http"), kind: Marker, size: 0 ), MAProtocol( mcodec: multiCodec("https"), kind: Marker, size: 0 ), MAProtocol( mcodec: multiCodec("quic"), kind: Marker, size: 0 ), MAProtocol( mcodec: multiCodec("ip6zone"), kind: Length, size: 0, coder: TranscoderIP6Zone ), MAProtocol( mcodec: multiCodec("onion"), kind: Fixed, size: 10, coder: TranscoderOnion ), MAProtocol( mcodec: multiCodec("onion3"), kind: Fixed, size: 37, coder: TranscoderOnion3 ), MAProtocol( mcodec: multiCodec("ws"), kind: Marker, size: 0 ), MAProtocol( mcodec: multiCodec("wss"), kind: Marker, size: 0 ), MAProtocol( mcodec: multiCodec("ipfs"), kind: Length, size: 0, coder: TranscoderP2P ), MAProtocol( mcodec: multiCodec("p2p"), kind: Length, size: 0, coder: TranscoderP2P ), MAProtocol( mcodec: multiCodec("unix"), kind: Path, size: 0, coder: TranscoderUnix ), MAProtocol( mcodec: multiCodec("dns"), kind: Length, size: 0, coder: TranscoderDNS ), MAProtocol( mcodec: multiCodec("dns4"), kind: Length, size: 0, coder: TranscoderDNS ), MAProtocol( mcodec: multiCodec("dns6"), kind: Length, size: 0, coder: TranscoderDNS ), MAProtocol( mcodec: multiCodec("dnsaddr"), kind: Length, size: 0, coder: TranscoderDNS ), MAProtocol( mcodec: multiCodec("p2p-circuit"), kind: Marker, size: 0 ), MAProtocol( mcodec: multiCodec("p2p-websocket-star"), kind: Marker, size: 0 ), MAProtocol( mcodec: multiCodec("p2p-webrtc-star"), kind: Marker, size: 0 ), MAProtocol( mcodec: multiCodec("p2p-webrtc-direct"), kind: Marker, size: 0 ) ] DNSANY* = mapEq("dns") DNS4* = mapEq("dns4") DNS6* = mapEq("dns6") DNSADDR* = mapEq("dnsaddr") IP4* = mapEq("ip4") IP6* = mapEq("ip6") DNS* = mapOr(DNSANY, DNS4, DNS6, DNSADDR) IP* = mapOr(IP4, IP6) DNS_OR_IP* = mapOr(DNS, IP) TCP_DNS* = mapAnd(DNS, mapEq("tcp")) TCP_IP* =mapAnd(IP, mapEq("tcp")) TCP* = mapOr(TCP_DNS, TCP_IP) UDP_DNS* = mapAnd(DNS, mapEq("udp")) UDP_IP* = mapAnd(IP, mapEq("udp")) UDP* = mapOr(UDP_DNS, UDP_IP) UTP* = mapAnd(UDP, mapEq("utp")) QUIC* = mapAnd(UDP, mapEq("quic")) UNIX* = mapEq("unix") WS_DNS* = mapAnd(TCP_DNS, mapEq("ws")) WS_IP* = mapAnd(TCP_IP, mapEq("ws")) WS* = mapAnd(TCP, mapEq("ws")) WSS_DNS* = mapAnd(TCP_DNS, mapEq("wss")) WSS_IP* = mapAnd(TCP_IP, mapEq("wss")) WSS* = mapAnd(TCP, mapEq("wss")) WebSockets_DNS* = mapOr(WS_DNS, WSS_DNS) WebSockets_IP* = mapOr(WS_IP, WSS_IP) WebSockets* = mapOr(WS, WSS) Onion3* = mapEq("onion3") TcpOnion3* = mapAnd(TCP, Onion3) Unreliable* = mapOr(UDP) Reliable* = mapOr(TCP, UTP, QUIC, WebSockets) P2PPattern* = mapEq("p2p") IPFS* = mapAnd(Reliable, P2PPattern) HTTP* = mapOr( mapAnd(TCP, mapEq("http")), mapAnd(IP, mapEq("http")), mapAnd(DNS, mapEq("http")) ) HTTPS* = mapOr( mapAnd(TCP, mapEq("https")), mapAnd(IP, mapEq("https")), mapAnd(DNS, mapEq("https")) ) WebRTCDirect* = mapOr( mapAnd(HTTP, mapEq("p2p-webrtc-direct")), mapAnd(HTTPS, mapEq("p2p-webrtc-direct")) ) CircuitRelay* = mapEq("p2p-circuit") proc initMultiAddressCodeTable(): Table[MultiCodec, MAProtocol] {.compileTime.} = for item in ProtocolsList: result[item.mcodec] = item const CodeAddresses = initMultiAddressCodeTable() proc trimRight(s: string, ch: char): string = ## Consume trailing characters ``ch`` from string ``s`` and return result. var m = 0 for i in countdown(s.high, 0): if s[i] == ch: inc(m) else: break result = s[0..(s.high - m)] proc protoCode*(ma: MultiAddress): MaResult[MultiCodec] = ## Returns MultiAddress ``ma`` protocol code. var header: uint64 var vb = ma if vb.data.readVarint(header) == -1: err("multiaddress: Malformed binary address!") else: let proto = CodeAddresses.getOrDefault(MultiCodec(header)) if proto.kind == None: err("multiaddress: Unsupported protocol '" & $header & "'") else: ok(proto.mcodec) proc protoName*(ma: MultiAddress): MaResult[string] = ## Returns MultiAddress ``ma`` protocol name. var header: uint64 var vb = ma if vb.data.readVarint(header) == -1: err("multiaddress: Malformed binary address!") else: let proto = CodeAddresses.getOrDefault(MultiCodec(header)) if proto.kind == None: err("multiaddress: Unsupported protocol '" & $header & "'") else: ok($(proto.mcodec)) proc protoArgument*(ma: MultiAddress, value: var openArray[byte]): MaResult[int] = ## Returns MultiAddress ``ma`` protocol argument value. ## ## If current MultiAddress do not have argument value, then result will be ## ``0``. var header: uint64 var vb = ma var buffer: seq[byte] if vb.data.readVarint(header) == -1: err("multiaddress: Malformed binary address!") else: let proto = CodeAddresses.getOrDefault(MultiCodec(header)) if proto.kind == None: err("multiaddress: Unsupported protocol '" & $header & "'") else: var res: int if proto.kind == Fixed: res = proto.size if len(value) >= res and vb.data.readArray(value.toOpenArray(0, proto.size - 1)) != proto.size: err("multiaddress: Decoding protocol error") else: ok(res) elif proto.kind in {MAKind.Length, Path}: if vb.data.readSeq(buffer) == -1: err("multiaddress: Decoding protocol error") else: res = len(buffer) if len(value) >= res: copyMem(addr value[0], addr buffer[0], res) ok(res) else: ok(res) proc protoAddress*(ma: MultiAddress): MaResult[seq[byte]] = ## Returns MultiAddress ``ma`` protocol address binary blob. ## ## If current MultiAddress do not have argument value, then result array will ## be empty. var buffer = newSeq[byte](len(ma.data.buffer)) let res = ? protoArgument(ma, buffer) buffer.setLen(res) ok(buffer) proc protoArgument*(ma: MultiAddress): MaResult[seq[byte]] = ## Returns MultiAddress ``ma`` protocol address binary blob. ## ## If current MultiAddress do not have argument value, then result array will ## be empty. ma.protoAddress() proc getPart(ma: MultiAddress, index: int): MaResult[MultiAddress] = var header: uint64 var data = newSeq[byte]() var offset = 0 var vb = ma var res: MultiAddress res.data = initVBuffer() if index < 0: return err("multiaddress: negative index gived to getPart") while offset <= index: if vb.data.readVarint(header) == -1: return err("multiaddress: Malformed binary address!") let proto = CodeAddresses.getOrDefault(MultiCodec(header)) if proto.kind == None: return err("multiaddress: Unsupported protocol '" & $header & "'") elif proto.kind == Fixed: data.setLen(proto.size) if vb.data.readArray(data) != proto.size: return err("multiaddress: Decoding protocol error") if offset == index: res.data.writeVarint(header) res.data.writeArray(data) res.data.finish() elif proto.kind in {MAKind.Length, Path}: if vb.data.readSeq(data) == -1: return err("multiaddress: Decoding protocol error") if offset == index: res.data.writeVarint(header) res.data.writeSeq(data) res.data.finish() elif proto.kind == Marker: if offset == index: res.data.writeVarint(header) res.data.finish() inc(offset) ok(res) proc getParts[U, V](ma: MultiAddress, slice: HSlice[U, V]): MaResult[MultiAddress] = when slice.a is BackwardsIndex or slice.b is BackwardsIndex: let maLength = ? len(ma) template normalizeIndex(index): int = when index is BackwardsIndex: maLength - int(index) else: int(index) let indexStart = normalizeIndex(slice.a) indexEnd = normalizeIndex(slice.b) var res: MultiAddress for i in indexStart..indexEnd: ? res.append(? ma[i]) ok(res) proc `[]`*(ma: MultiAddress, i: int | BackwardsIndex): MaResult[MultiAddress] {.inline.} = ## Returns part with index ``i`` of MultiAddress ``ma``. when i is BackwardsIndex: let maLength = ? len(ma) ma.getPart(maLength - int(i)) else: ma.getPart(i) proc `[]`*(ma: MultiAddress, slice: HSlice): MaResult[MultiAddress] {.inline.} = ## Returns parts with slice ``slice`` of MultiAddress ``ma``. ma.getParts(slice) iterator items*(ma: MultiAddress): MaResult[MultiAddress] = ## Iterates over all addresses inside of MultiAddress ``ma``. var header: uint64 var data = newSeq[byte]() var vb = ma while true: if vb.data.isEmpty(): break var res = MultiAddress(data: initVBuffer()) if vb.data.readVarint(header) == -1: yield err(MaResult[MultiAddress], "Malformed binary address!") let proto = CodeAddresses.getOrDefault(MultiCodec(header)) if proto.kind == None: yield err(MaResult[MultiAddress], "Unsupported protocol '" & $header & "'") elif proto.kind == Fixed: data.setLen(proto.size) if vb.data.readArray(data) != proto.size: yield err(MaResult[MultiAddress], "Decoding protocol error") res.data.writeVarint(header) res.data.writeArray(data) elif proto.kind in {MAKind.Length, Path}: if vb.data.readSeq(data) == -1: yield err(MaResult[MultiAddress], "Decoding protocol error") res.data.writeVarint(header) res.data.writeSeq(data) elif proto.kind == Marker: res.data.writeVarint(header) res.data.finish() yield ok(MaResult[MultiAddress], res) proc len*(ma: MultiAddress): MaResult[int] = var counter: int for part in ma: if part.isErr: return err(part.error) counter.inc() ok(counter) proc contains*(ma: MultiAddress, codec: MultiCodec): MaResult[bool] {.inline.} = ## Returns ``true``, if address with MultiCodec ``codec`` present in ## MultiAddress ``ma``. for item in ma.items: let code = ?(?item).protoCode() if code == codec: return ok(true) ok(false) proc `[]`*(ma: MultiAddress, codec: MultiCodec): MaResult[MultiAddress] {.inline.} = ## Returns partial MultiAddress with MultiCodec ``codec`` and present in ## MultiAddress ``ma``. for item in ma.items: if ?(?item).protoCode == codec: return item err("multiaddress: Codec is not present in address") proc toString*(value: MultiAddress): MaResult[string] = ## Return string representation of MultiAddress ``value``. var header: uint64 var vb = value var parts = newSeq[string]() var part: string var res: string while true: if vb.data.isEmpty(): break if vb.data.readVarint(header) == -1: return err("multiaddress: Malformed binary address!") let proto = CodeAddresses.getOrDefault(MultiCodec(header)) if proto.kind == None: return err("multiaddress: Unsupported protocol '" & $header & "'") if proto.kind in {Fixed, Length, Path}: if isNil(proto.coder.bufferToString): return err("multiaddress: Missing protocol '" & $(proto.mcodec) & "' coder") if not proto.coder.bufferToString(vb.data, part): return err("multiaddress: Decoding protocol error") parts.add($(proto.mcodec)) if proto.kind == Path and part[0] == '/': parts.add(part[1..^1]) else: parts.add(part) elif proto.kind == Marker: parts.add($(proto.mcodec)) if len(parts) > 0: res = "/" & parts.join("/") ok(res) proc `$`*(value: MultiAddress): string {.raises: [Defect].} = ## Return string representation of MultiAddress ``value``. let s = value.toString() if s.isErr: s.error else: s[] proc protocols*(value: MultiAddress): MaResult[seq[MultiCodec]] = ## Returns list of protocol codecs inside of MultiAddress ``value``. var res = newSeq[MultiCodec]() for item in value.items(): res.add(?(?item).protoCode()) ok(res) proc hex*(value: MultiAddress): string = ## Return hexadecimal string representation of MultiAddress ``value``. $(value.data) proc write*(vb: var VBuffer, ma: MultiAddress) {.inline.} = ## Write MultiAddress value ``ma`` to buffer ``vb``. vb.writeArray(ma.data.buffer) proc encode*(mbtype: typedesc[MultiBase], encoding: string, ma: MultiAddress): string {.inline.} = ## Get MultiBase encoded representation of ``ma`` using encoding ## ``encoding``. result = MultiBase.encode(encoding, ma.data.buffer) proc validate*(ma: MultiAddress): bool = ## Returns ``true`` if MultiAddress ``ma`` is valid. var header: uint64 var vb = ma while true: if vb.data.isEmpty(): break if vb.data.readVarint(header) == -1: return false let proto = CodeAddresses.getOrDefault(MultiCodec(header)) if proto.kind == None: return false if proto.kind in {Fixed, Length, Path}: if isNil(proto.coder.validateBuffer): return false if not proto.coder.validateBuffer(vb.data): return false else: discard result = true proc init*( mtype: typedesc[MultiAddress], protocol: MultiCodec, value: openArray[byte] = []): MaResult[MultiAddress] = ## Initialize MultiAddress object from protocol id ``protocol`` and array ## of bytes ``value``. let proto = CodeAddresses.getOrDefault(protocol) if proto.kind == None: err("multiaddress: Protocol not found") else: var res: MultiAddress res.data = initVBuffer() res.data.writeVarint(cast[uint64](proto.mcodec)) case proto.kind of Fixed, Length, Path: if len(value) == 0: err("multiaddress: Value must not be empty array") else: if proto.kind == Fixed: res.data.writeArray(value) else: res.data.writeSeq(value) res.data.finish() ok(res) of Marker: if len(value) != 0: err("multiaddress: Value must be empty for markers") else: res.data.finish() ok(res) of None: raiseAssert "None checked above" proc init*(mtype: typedesc[MultiAddress], protocol: MultiCodec, value: PeerId): MaResult[MultiAddress] {.inline.} = ## Initialize MultiAddress object from protocol id ``protocol`` and peer id ## ``value``. init(mtype, protocol, value.data) proc init*(mtype: typedesc[MultiAddress], protocol: MultiCodec, value: int): MaResult[MultiAddress] = ## Initialize MultiAddress object from protocol id ``protocol`` and integer ## ``value``. This procedure can be used to instantiate ``tcp``, ``udp``, ## ``dccp`` and ``sctp`` MultiAddresses. var allowed = [multiCodec("tcp"), multiCodec("udp"), multiCodec("dccp"), multiCodec("sctp")] if protocol notin allowed: err("multiaddress: Incorrect protocol for integer value") else: let proto = CodeAddresses.getOrDefault(protocol) var res: MultiAddress res.data = initVBuffer() res.data.writeVarint(cast[uint64](proto.mcodec)) if value < 0 or value > 65535: err("multiaddress: Incorrect integer value") else: res.data.writeArray(toBytesBE(cast[uint16](value))) res.data.finish() ok(res) proc getProtocol(name: string): MAProtocol {.inline.} = let mc = MultiCodec.codec(name) if mc != InvalidMultiCodec: result = CodeAddresses.getOrDefault(mc) proc init*(mtype: typedesc[MultiAddress], value: string): MaResult[MultiAddress] = ## Initialize MultiAddress object from string representation ``value``. if len(value) == 0 or value == "/": return err("multiaddress: Address must not be empty!") var parts = value.trimRight('/').split('/') if len(parts[0]) != 0: err("multiaddress: Invalid MultiAddress, must start with `/`") else: var offset = 1 var res: MultiAddress res.data = initVBuffer() while offset < len(parts): let part = parts[offset] let proto = getProtocol(part) if proto.kind == None: return err("multiaddress: Unsupported protocol '" & part & "'") else: if proto.kind in {Fixed, Length, Path}: if isNil(proto.coder.stringToBuffer): return err("multiaddress: Missing protocol '" & part & "' transcoder") if offset + 1 >= len(parts): return err("multiaddress: Missing protocol '" & part & "' argument") if proto.kind in {Fixed, Length}: res.data.write(proto.mcodec) let res = proto.coder.stringToBuffer(parts[offset + 1], res.data) if not res: return err("multiaddress: Error encoding `" & part & "/" & parts[offset + 1] & "`") offset += 2 elif proto.kind == Path: var path = "/" & (parts[(offset + 1)..^1].join("/")) res.data.write(proto.mcodec) if not proto.coder.stringToBuffer(path, res.data): return err("multiaddress: Error encoding `" & part & "/" & path & "`") break elif proto.kind == Marker: res.data.write(proto.mcodec) offset += 1 res.data.finish() ok(res) proc init*(mtype: typedesc[MultiAddress], data: openArray[byte]): MaResult[MultiAddress] = ## Initialize MultiAddress with array of bytes ``data``. if len(data) == 0: err("multiaddress: Address must not be empty!") else: var res: MultiAddress res.data = initVBuffer() res.data.buffer.setLen(len(data)) copyMem(addr res.data.buffer[0], unsafeAddr data[0], len(data)) if not res.validate(): err("multiaddress: Incorrect MultiAddress!") else: ok(res) proc init*(mtype: typedesc[MultiAddress]): MultiAddress = ## Initialize empty MultiAddress. result.data = initVBuffer() proc init*(mtype: typedesc[MultiAddress], address: ValidIpAddress, protocol: IpTransportProtocol, port: Port): MultiAddress = var res: MultiAddress res.data = initVBuffer() let networkProto = case address.family of IpAddressFamily.IPv4: getProtocol("ip4") of IpAddressFamily.IPv6: getProtocol("ip6") transportProto = case protocol of tcpProtocol: getProtocol("tcp") of udpProtocol: getProtocol("udp") res.data.write(networkProto.mcodec) case address.family of IpAddressFamily.IPv4: res.data.writeArray(address.address_v4) of IpAddressFamily.IPv6: res.data.writeArray(address.address_v6) res.data.write(transportProto.mcodec) res.data.writeArray(toBytesBE(uint16(port))) res.data.finish() res proc init*(mtype: typedesc[MultiAddress], address: TransportAddress, protocol = IPPROTO_TCP): MaResult[MultiAddress] = ## Initialize MultiAddress using chronos.TransportAddress (IPv4/IPv6/Unix) ## and protocol information (UDP/TCP). var res: MultiAddress res.data = initVBuffer() let protoProto = case protocol of IPPROTO_TCP: getProtocol("tcp") of IPPROTO_UDP: getProtocol("udp") else: default(MAProtocol) if protoProto.size == 0: return err("multiaddress: protocol should be either TCP or UDP") if address.family == AddressFamily.IPv4: res.data.write(getProtocol("ip4").mcodec) res.data.writeArray(address.address_v4) res.data.write(protoProto.mcodec) discard protoProto.coder.stringToBuffer($address.port, res.data) elif address.family == AddressFamily.IPv6: res.data.write(getProtocol("ip6").mcodec) res.data.writeArray(address.address_v6) res.data.write(protoProto.mcodec) discard protoProto.coder.stringToBuffer($address.port, res.data) elif address.family == AddressFamily.Unix: res.data.write(getProtocol("unix").mcodec) res.data.writeSeq(address.address_un) res.data.finish() ok(res) proc isEmpty*(ma: MultiAddress): bool = ## Returns ``true``, if MultiAddress ``ma`` is empty or non initialized. result = len(ma.data) == 0 proc concat*(m1, m2: MultiAddress): MaResult[MultiAddress] = var res: MultiAddress res.data = initVBuffer() res.data.buffer = m1.data.buffer & m2.data.buffer if not res.validate(): err("multiaddress: Incorrect MultiAddress!") else: ok(res) proc append*(m1: var MultiAddress, m2: MultiAddress): MaResult[void] = m1.data.buffer &= m2.data.buffer if not m1.validate(): err("multiaddress: Incorrect MultiAddress!") else: ok() proc `&`*(m1, m2: MultiAddress): MultiAddress {. raises: [Defect, LPError].} = ## Concatenates two addresses ``m1`` and ``m2``, and returns result. ## ## This procedure performs validation of concatenated result and can raise ## exception on error. ## concat(m1, m2).tryGet() proc `&=`*(m1: var MultiAddress, m2: MultiAddress) {. raises: [Defect, LPError].} = ## Concatenates two addresses ``m1`` and ``m2``. ## ## This procedure performs validation of concatenated result and can raise ## exception on error. ## m1.append(m2).tryGet() proc `==`*(m1: var MultiAddress, m2: MultiAddress): bool = ## Check of two MultiAddress are equal m1.data == m2.data proc matchPart(pat: MaPattern, protos: seq[MultiCodec]): MaPatResult = var empty: seq[MultiCodec] var pcs = protos if pat.operator == Or: result = MaPatResult(flag: false, rem: empty) for a in pat.args: let res = a.matchPart(pcs) if res.flag: #Greedy Or if result.flag == false or result.rem.len > res.rem.len: result = res elif pat.operator == And: if len(pcs) < len(pat.args): return MaPatResult(flag: false, rem: empty) for i in 0..