# 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. ## The switch is the core of libp2p, which brings together the ## transports, the connection manager, the upgrader and other ## parts to allow programs to use libp2p {.push raises: [].} import std/[tables, options, sequtils, sets, oids] import chronos, chronicles, metrics import stream/connection, transports/transport, upgrademngrs/upgrade, multistream, multiaddress, protocols/protocol, protocols/secure/secure, peerinfo, utils/semaphore, connmanager, nameresolving/nameresolver, peerid, peerstore, errors, utility, dialer export connmanager, upgrade, dialer, peerstore logScope: topics = "libp2p switch" #TODO: General note - use a finite state machine to manage the different # steps of connections establishing and upgrading. This makes everything # more robust and less prone to ordering attacks - i.e. muxing can come if # and only if the channel has been secured (i.e. if a secure manager has been # previously provided) const ConcurrentUpgrades* = 4 type Switch* {.public.} = ref object of Dial peerInfo*: PeerInfo connManager*: ConnManager transports*: seq[Transport] ms*: MultistreamSelect acceptFuts: seq[Future[void]] dialer*: Dial peerStore*: PeerStore nameResolver*: NameResolver started: bool services*: seq[Service] Service* = ref object of RootObj inUse: bool method setup*(self: Service, switch: Switch): Future[bool] {.base, async, gcsafe.} = if self.inUse: warn "service setup has already been called" return false self.inUse = true return true method run*(self: Service, switch: Switch) {.base, async, gcsafe.} = doAssert(false, "Not implemented!") method stop*(self: Service, switch: Switch): Future[bool] {.base, async, gcsafe.} = if not self.inUse: warn "service is already stopped" return false self.inUse = false return true proc addConnEventHandler*(s: Switch, handler: ConnEventHandler, kind: ConnEventKind) {.public.} = ## Adds a ConnEventHandler, which will be triggered when ## a connection to a peer is created or dropped. ## There may be multiple connections per peer. ## ## The handler should not raise. s.connManager.addConnEventHandler(handler, kind) proc removeConnEventHandler*(s: Switch, handler: ConnEventHandler, kind: ConnEventKind) {.public.} = s.connManager.removeConnEventHandler(handler, kind) proc addPeerEventHandler*(s: Switch, handler: PeerEventHandler, kind: PeerEventKind) {.public.} = ## Adds a PeerEventHandler, which will be triggered when ## a peer connects or disconnects from us. ## ## The handler should not raise. s.connManager.addPeerEventHandler(handler, kind) proc removePeerEventHandler*(s: Switch, handler: PeerEventHandler, kind: PeerEventKind) {.public.} = s.connManager.removePeerEventHandler(handler, kind) method addTransport*(s: Switch, t: Transport) = s.transports &= t s.dialer.addTransport(t) proc connectedPeers*(s: Switch, dir: Direction): seq[PeerId] = s.connManager.connectedPeers(dir) proc isConnected*(s: Switch, peerId: PeerId): bool {.public.} = ## returns true if the peer has one or more ## associated connections ## peerId in s.connManager proc disconnect*(s: Switch, peerId: PeerId): Future[void] {.gcsafe, public.} = ## Disconnect from a peer, waiting for the connection(s) to be dropped s.connManager.dropPeer(peerId) method connect*( s: Switch, peerId: PeerId, addrs: seq[MultiAddress], forceDial = false, reuseConnection = true, dir = Direction.Out): Future[void] {.public.} = ## Connects to a peer without opening a stream to it s.dialer.connect(peerId, addrs, forceDial, reuseConnection, dir) method connect*( s: Switch, address: MultiAddress, allowUnknownPeerId = false): Future[PeerId] = ## Connects to a peer and retrieve its PeerId ## ## If the P2P part is missing from the MA and `allowUnknownPeerId` is set ## to true, this will discover the PeerId while connecting. This exposes ## you to MiTM attacks, so it shouldn't be used without care! s.dialer.connect(address, allowUnknownPeerId) method dial*( s: Switch, peerId: PeerId, protos: seq[string]): Future[Connection] {.public.} = ## Open a stream to a connected peer with the specified `protos` s.dialer.dial(peerId, protos) proc dial*(s: Switch, peerId: PeerId, proto: string): Future[Connection] {.public.} = ## Open a stream to a connected peer with the specified `proto` dial(s, peerId, @[proto]) method dial*( s: Switch, peerId: PeerId, addrs: seq[MultiAddress], protos: seq[string], forceDial = false): Future[Connection] {.public.} = ## Connected to a peer and open a stream ## with the specified `protos` s.dialer.dial(peerId, addrs, protos, forceDial) proc dial*( s: Switch, peerId: PeerId, addrs: seq[MultiAddress], proto: string): Future[Connection] {.public.} = ## Connected to a peer and open a stream ## with the specified `proto` dial(s, peerId, addrs, @[proto]) proc mount*[T: LPProtocol](s: Switch, proto: T, matcher: Matcher = nil) {.gcsafe, raises: [LPError], public.} = ## mount a protocol to the switch if isNil(proto.handler): raise newException(LPError, "Protocol has to define a handle method or proc") if proto.codec.len == 0: raise newException(LPError, "Protocol has to define a codec string") if s.started and not proto.started: raise newException(LPError, "Protocol not started") s.ms.addHandler(proto.codecs, proto, matcher) s.peerInfo.protocols.add(proto.codec) proc upgrader(switch: Switch, trans: Transport, conn: Connection) {.async.} = let muxed = await trans.upgrade(conn, Opt.none(PeerId)) switch.connManager.storeMuxer(muxed) await switch.peerStore.identify(muxed) trace "Connection upgrade succeeded" proc upgradeMonitor( switch: Switch, trans: Transport, conn: Connection, upgrades: AsyncSemaphore) {.async.} = try: await switch.upgrader(trans, conn).wait(30.seconds) except CatchableError as exc: if exc isnot CancelledError: libp2p_failed_upgrades_incoming.inc() if not isNil(conn): await conn.close() trace "Exception awaiting connection upgrade", exc = exc.msg, conn finally: upgrades.release() proc accept(s: Switch, transport: Transport) {.async.} = # noraises ## switch accept loop, ran for every transport ## let upgrades = newAsyncSemaphore(ConcurrentUpgrades) while transport.running: var conn: Connection try: debug "About to accept incoming connection" # remember to always release the slot when # the upgrade succeeds or fails, this is # currently done by the `upgradeMonitor` await upgrades.acquire() # first wait for an upgrade slot to become available let slot = await s.connManager.getIncomingSlot() conn = try: await transport.accept() except CatchableError as exc: slot.release() raise exc slot.trackConnection(conn) if isNil(conn): # A nil connection means that we might have hit a # file-handle limit (or another non-fatal error), # we can get one on the next try debug "Unable to get a connection" upgrades.release() continue # set the direction of this bottom level transport # in order to be able to consume this information in gossipsub if required # gossipsub gives priority to connections we make conn.transportDir = Direction.In debug "Accepted an incoming connection", conn asyncSpawn s.upgradeMonitor(transport, conn, upgrades) except CancelledError as exc: trace "releasing semaphore on cancellation" upgrades.release() # always release the slot except CatchableError as exc: error "Exception in accept loop, exiting", exc = exc.msg upgrades.release() # always release the slot if not isNil(conn): await conn.close() return proc stop*(s: Switch) {.async, public.} = ## Stop listening on every transport, and ## close every active connections trace "Stopping switch" s.started = false for service in s.services: discard await service.stop(s) # close and cleanup all connections await s.connManager.close() for transp in s.transports: try: await transp.stop() except CancelledError as exc: raise exc except CatchableError as exc: warn "error cleaning up transports", msg = exc.msg try: await allFutures(s.acceptFuts) .wait(1.seconds) except CatchableError as exc: trace "Exception while stopping accept loops", exc = exc.msg # check that all futures were properly # stopped and otherwise cancel them for a in s.acceptFuts: if not a.finished: a.cancel() for service in s.services: discard await service.stop(s) await s.ms.stop() trace "Switch stopped" proc start*(s: Switch) {.async, gcsafe, public.} = ## Start listening on every transport if s.started: warn "Switch has already been started" return debug "starting switch for peer", peerInfo = s.peerInfo var startFuts: seq[Future[void]] for t in s.transports: let addrs = s.peerInfo.listenAddrs.filterIt( t.handles(it) ) s.peerInfo.listenAddrs.keepItIf( it notin addrs ) if addrs.len > 0 or t.running: startFuts.add(t.start(addrs)) await allFutures(startFuts) for fut in startFuts: if fut.failed: await s.stop() raise fut.error for t in s.transports: # for each transport if t.addrs.len > 0 or t.running: s.acceptFuts.add(s.accept(t)) s.peerInfo.listenAddrs &= t.addrs await s.peerInfo.update() await s.ms.start() for service in s.services: discard await service.setup(s) s.started = true debug "Started libp2p node", peer = s.peerInfo proc newSwitch*(peerInfo: PeerInfo, transports: seq[Transport], secureManagers: openArray[Secure] = [], connManager: ConnManager, ms: MultistreamSelect, peerStore: PeerStore, nameResolver: NameResolver = nil, services = newSeq[Service]()): Switch {.raises: [LPError].} = if secureManagers.len == 0: raise newException(LPError, "Provide at least one secure manager") let switch = Switch( peerInfo: peerInfo, ms: ms, transports: transports, connManager: connManager, peerStore: peerStore, dialer: Dialer.new(peerInfo.peerId, connManager, peerStore, transports, nameResolver), nameResolver: nameResolver, services: services) switch.connManager.peerStore = peerStore return switch