syndicate-nim/src/syndicate/relays.nim

# SPDX-FileCopyrightText: ☭ Emery Hemingway
# SPDX-License-Identifier: Unlicense

import std/[asyncdispatch, options, tables]
from std/os import getEnv, `/`
import preserves
import ../syndicate, /capabilities, ./durings, ./membranes, ./protocols/[gatekeeper, protocol, sturdy, transportAddress]

when defined(traceSyndicate):
  when defined(posix):
    template trace(args: varargs[untyped]): untyped = stderr.writeLine(args)
  else:
    template trace(args: varargs[untyped]): untyped = echo(args)
else:
  template trace(args: varargs[untyped]): untyped = discard

export `$`

type
  Oid = sturdy.Oid

export Stdio, Tcp, WebSocket, Unix

type
  Assertion = Value
  WireRef = sturdy.WireRef
  Turn = syndicate.Turn
  Handle = actors.Handle

type
  PacketHandler = proc (buf: seq[byte]) {.gcsafe.}
  RelaySetup = proc (turn: var Turn; relay: Relay) {.gcsafe.}

  Relay* = ref object of RootObj
    facet: Facet
    inboundAssertions: Table[Handle,
      tuple[localHandle: Handle, imported: seq[WireSymbol]]]
    outboundAssertions: Table[Handle, seq[WireSymbol]]
    exported: Membrane
    imported: Membrane
    nextLocalOid: Oid
    pendingTurn: protocol.Turn
    packetSender: PacketHandler
    wireBuf: BufferedDecoder
    untrusted: bool

  SyncPeerEntity = ref object of Entity
    relay: Relay
    peer: Cap
    handleMap: Table[Handle, Handle]
    e: WireSymbol

  RelayEntity = ref object of Entity
    ## https://synit.org/book/protocol.html#relay-entities
    label: string
    relay: Relay

proc releaseCapOut(r: Relay; e: WireSymbol) =
  r.exported.drop e

method publish(spe: SyncPeerEntity; t: var Turn; a: AssertionRef; h: Handle) =
  spe.handleMap[h] = publish(t, spe.peer, a.value)

method retract(se: SyncPeerEntity; t: var Turn; h: Handle) =
  var other: Handle
  if se.handleMap.pop(h, other):
    retract(t, other)

method message(se: SyncPeerEntity; t: var Turn; a: AssertionRef) =
  if not se.e.isNil:
    se.relay.releaseCapOut(se.e)
  message(t, se.peer, a.value)

method sync(se: SyncPeerEntity; t: var Turn; peer: Cap) =
  sync(t, se.peer, peer)

proc newSyncPeerEntity(r: Relay; p: Cap): SyncPeerEntity =
  SyncPeerEntity(relay: r, peer: p)

proc rewriteCapOut(relay: Relay; cap: Cap; exported: var seq[WireSymbol]): WireRef =
  if cap.target of RelayEntity and cap.target.RelayEntity.relay == relay and cap.attenuation.len == 0:
    result = WireRef(orKind: WireRefKind.yours, yours: WireRefYours(oid: cap.target.oid))
  else:
    var ws = grab(relay.exported, cap)
    if ws.isNil:
      ws = newWireSymbol(relay.exported, relay.nextLocalOid, cap)
      inc relay.nextLocalOid
    exported.add ws
    result = WireRef(
        orKind: WireRefKind.mine,
        mine: WireRefMine(oid: ws.oid))

proc rewriteOut(relay: Relay; v: Assertion):
    tuple[rewritten: Value, exported: seq[WireSymbol]] {.gcsafe.} =
  var exported: seq[WireSymbol]
  result.rewritten = mapEmbeds(v) do (pr: Value) -> Value:
    let o = pr.unembed(Cap); if o.isSome:
      rewriteCapOut(relay, o.get, exported).toPreserves
    else: pr
  result.exported = exported

proc register(relay: Relay; v: Assertion; h: Handle): tuple[rewritten: Value, exported: seq[WireSymbol]] =
  result = rewriteOut(relay, v)
  relay.outboundAssertions[h] = result.exported

proc deregister(relay: Relay; h: Handle) =
  var outbound: seq[WireSymbol]
  if relay.outboundAssertions.pop(h, outbound):
    for e in outbound: releaseCapOut(relay, e)

proc send(r: Relay; turn: var Turn; rOid: protocol.Oid; m: Event) =
  if r.pendingTurn.len == 0:
    # If the pending queue is empty then schedule a packet
    # to be sent after pending I/O is processed.
    callSoon do ():
      r.facet.run do (turn: var Turn):
        var pkt = Packet(
          orKind: PacketKind.Turn,
          turn: move r.pendingTurn)
        trace "C: ", pkt
        assert(not r.packetSender.isNil, "missing packetSender proc")
        r.packetSender(encode pkt)
  r.pendingTurn.add TurnEvent(oid: rOid, event: m)

proc send(re: RelayEntity; turn: var Turn; ev: Event) =
  send(re.relay, turn, protocol.Oid re.oid, ev)

method publish(re: RelayEntity; t: var Turn; a: AssertionRef; h: Handle) {.gcsafe.} =
  re.send(t, Event(
      orKind: EventKind.Assert,
      `assert`: protocol.Assert(
        assertion: re.relay.register(a.value, h).rewritten,
        handle: h)))

method retract(re: RelayEntity; t: var Turn; h: Handle) {.gcsafe.} =
  re.relay.deregister h
  re.send(t, Event(
    orKind: EventKind.Retract,
    retract: Retract(handle: h)))

method message(re: RelayEntity; turn: var Turn; msg: AssertionRef) {.gcsafe.} =
  var (value, exported) = rewriteOut(re.relay, msg.value)
  assert(len(exported) == 0, "cannot send a reference in a message")
  if len(exported) == 0:
    re.send(turn, Event(orKind: EventKind.Message, message: Message(body: value)))

method sync(re: RelayEntity; turn: var Turn; peer: Cap) {.gcsafe.} =
  var
    peerEntity = newSyncPeerEntity(re.relay, peer)
    exported: seq[WireSymbol]
    wr = rewriteCapOut(re.relay, turn.newCap(peerEntity), exported)
  peerEntity.e = exported[0]
  var ev = Event(orKind: EventKind.Sync)
  ev.sync.peer = wr.toPreserves.embed
  re.send(turn, ev)

proc newRelayEntity(label: string; r: Relay; o: Oid): RelayEntity =
  RelayEntity(label: label, relay: r, oid: o)

using
  relay: Relay
  facet: Facet

proc lookupLocal(relay; oid: Oid): Cap =
  let sym = relay.exported.grab oid
  if sym.isNil: newInertCap()
  else: sym.cap

proc isInert(r: Cap): bool =
  r.target.isNil

proc rewriteCapIn(relay; facet; n: WireRef, imported: var seq[WireSymbol]): Cap =
  case n.orKind
  of WireRefKind.mine:
    var e = relay.imported.grab(n.mine.oid)
    if e.isNil:
      e = newWireSymbol(
          relay.imported,
          n.mine.oid,
          newCap(facet, newRelayEntity("rewriteCapIn", relay, n.mine.oid)),
        )
    imported.add e
    result = e.cap
  of WireRefKind.yours:
    let r = relay.lookupLocal(n.yours.oid)
    if n.yours.attenuation.len == 0 or r.isInert: result = r
    else: raiseAssert "attenuation not implemented"

proc rewriteIn(relay; facet; v: Value):
    tuple[rewritten: Assertion; imported: seq[WireSymbol]] {.gcsafe.} =
  var imported: seq[WireSymbol]
  result.rewritten = mapEmbeds(v) do (pr: Value) -> Value:
    let wr = pr.preservesTo WireRef; if wr.isSome:
      result = rewriteCapIn(relay, facet, wr.get, imported).embed
    else:
      result = pr
  result.imported = imported

proc close(r: Relay) = discard

proc dispatch(relay: Relay; turn: var Turn; cap: Cap; event: Event) {.gcsafe.} =
  case event.orKind
  of EventKind.Assert:
    let (a, imported) = rewriteIn(relay, turn.facet, event.assert.assertion)
    relay.inboundAssertions[event.assert.handle] = (publish(turn, cap, a), imported,)

  of EventKind.Retract:
    let remoteHandle = event.retract.handle
    var outbound: tuple[localHandle: Handle, imported: seq[WireSymbol]]
    if relay.inboundAssertions.pop(remoteHandle, outbound):
      for e in outbound.imported: relay.imported.drop e
      turn.retract(outbound.localHandle)

  of EventKind.Message:
    let (a, imported) = rewriteIn(relay, turn.facet, event.message.body)
    assert imported.len == 0, "Cannot receive transient reference"
    turn.message(cap, a)

  of EventKind.Sync:
    discard # TODO
    #[
    var imported: seq[WireSymbol]
    let k = relay.rewriteCapIn(turn, evenr.sync.peer, imported)
    turn.sync(cap) do (turn: var Turn):
      turn.message(k, true)
      for e in imported: relay.imported.del e
      ]#

proc dispatch(relay: Relay; v: Value) {.gcsafe.} =
  trace "S: ", v
  run(relay.facet) do (t: var Turn):
    var pkt: Packet
    if pkt.fromPreserves(v):
      case pkt.orKind
      of PacketKind.Turn:
        # https://synit.org/book/protocol.html#turn-packets
        for te in pkt.turn:
          let r = lookupLocal(relay, te.oid.Oid)
          if not r.isInert:
            dispatch(relay, t, r, te.event)
          else:
            stderr.writeLine("discarding event for unknown Cap; ", te.event)
      of PacketKind.Error:
        # https://synit.org/book/protocol.html#error-packets
        when defined(posix):
          stderr.writeLine("Error from server: ", pkt.error.message, " (detail: ", pkt.error.detail, ")")
        close relay
      of PacketKind.Extension:
        # https://synit.org/book/protocol.html#extension-packets
        discard
    else:
      when defined(posix):
        stderr.writeLine("discarding undecoded packet ", v)

proc dispatch(relay: Relay; buf: seq[byte]) =
  feed(relay.wireBuf, buf)
  var pr = decode(relay.wireBuf)
  if pr.isSome: dispatch(relay, get pr)

type
  RelayOptions* = object of RootObj
    untrusted*: bool
  RelayActorOptions* = object of RelayOptions
    initialOid*: Option[Oid]
    initialCap*: Cap
    nextLocalOid*: Option[Oid]

proc newRelay(turn: var Turn; opts: RelayOptions; setup: RelaySetup): Relay =
  result = Relay(
    facet: turn.facet,
    wireBuf: newBufferedDecoder(0),
    untrusted: opts.untrusted)
  discard result.facet.preventInertCheck()
  setup(turn, result)

proc transportConnectionResolve(addrAss: Assertion; ds: Cap): gatekeeper.TransportConnection =
  result.`addr` = addrAss
  result.resolved = Resolved(orKind: ResolvedKind.accepted)
  result.resolved.accepted.responderSession = ds

proc spawnRelay*(name: string; turn: var Turn; ds: Cap; addrAss: Assertion; opts: RelayActorOptions; setup: RelaySetup) =
  discard spawn(name, turn) do (turn: var Turn):
    let relay = newRelay(turn, opts, setup)
    if not opts.initialCap.isNil:
      var exported: seq[WireSymbol]
      discard rewriteCapOut(relay, opts.initialCap, exported)
    opts.nextLocalOid.map do (oid: Oid):
      relay.nextLocalOid =
        if oid == 0.Oid: 1.Oid
        else: oid
    if opts.initialOid.isSome:
      var
        imported: seq[WireSymbol]
        wr = WireRef(
          orKind: WireRefKind.mine,
          mine: WireRefMine(oid: opts.initialOid.get))
        res = rewriteCapIn(relay, turn.facet, wr, imported)
      discard publish(turn, ds, transportConnectionResolve(addrAss, res))
    else:
      discard publish(turn, ds, transportConnectionResolve(addrAss, ds))

when defined(posix):
  import std/asyncnet
  from std/nativesockets import AF_INET, AF_UNIX, IPPROTO_TCP, SOCK_STREAM, Protocol

type ShutdownEntity* = ref object of Entity

method retract(e: ShutdownEntity; turn: var Turn; h: Handle) =
  stopActor(turn)

type ConnectProc* = proc (turn: var Turn; ds: Cap) {.gcsafe.}

export Tcp

when defined(posix):
  import std/asyncfile
  export Unix

  proc newStdioTunnel(facet: Facet; receiver: PacketHandler): PacketHandler =
    let asyncStdin = openAsync("/dev/stdin") # this is universal now?
    close(stdin)
    const readSize = 0x2000
    proc readCb(fut: Future[string]) {.gcsafe.} =
      if fut.failed: terminate(facet, fut.error)
      else:
        receiver(cast[seq[byte]](fut.read))
        asyncStdin.read(readSize).addCallback(readCb)
    asyncStdin.read(readSize).addCallback(readCb)
    proc sender(buf: seq[byte]) =
      try:
        if writeBytes(stdout, buf, 0, buf.len) != buf.len:
          raise newException(IOError, "failed to write Preserves to stdout")
        flushFile(stdout)
      except CatchableError as err:
        terminate(facet, err)
    sender

  proc connectStdio*(turn: var Turn; ds: Cap) =
    ## Connect to an external dataspace over stdin and stdout.
    var opts = RelayActorOptions(
      initialCap: ds,
      initialOid: 0.Oid.some)
    spawnRelay("stdio", turn, ds, Stdio().toPreserves, opts) do (turn: var Turn; relay: Relay):
      proc receiver(buf: seq[byte]) = dispatch(relay, buf)
      relay.packetSender = newStdioTunnel(turn.facet, receiver)

  proc newTunnel(facet: Facet; receiver: PacketHandler; socket: AsyncSocket): PacketHandler =
    const recvSize = 0x2000
    proc recvCb(fut: Future[string]) {.gcsafe.} =
      if fut.failed: terminate(facet, fut.error)
      else:
        receiver(cast[seq[byte]](fut.read))
        if not socket.isClosed:
          socket.recv(recvSize).addCallback(recvCb)
    socket.recv(recvSize).addCallback(recvCb)
    proc sender(buf: seq[byte]) =
      asyncCheck(facet, socket.send(cast[string](buf)))
    sender

  proc connect*(turn: var Turn; ds: Cap; route: Route; addrAss: Assertion; socket: AsyncSocket; steps: seq[Value]) =
    ## Relay a dataspace over an open `AsyncSocket`.
    var shutdownCap: Cap
    let
      reenable = turn.facet.preventInertCheck()
      connectionClosedCap = newCap(turn, ShutdownEntity())
    discard bootActor("socket") do (turn: var Turn):
      var ops = RelayActorOptions(
        initialOid: 0.Oid.some)
      spawnRelay("socket", turn, ds, addrAss, ops) do (turn: var Turn; relay: Relay):
        let facet = turn.facet
        proc receiver(buf: seq[byte]) = dispatch(relay, buf)
        relay.packetSender = newTunnel(turn.facet, receiver, socket)
        turn.facet.actor.atExit do (turn: var Turn): close(socket)
        discard publish(turn, connectionClosedCap, true)
        shutdownCap = newCap(turn, ShutdownEntity())
      onPublish(turn, ds, TransportConnection ?: {0: ?addrAss, 2: ?:Rejected}) do (detail: Value):
        raise newException(IOError, $detail)
      onPublish(turn, ds, TransportConnection ?: {0: ?addrAss, 2: ?:ResolvedAccepted}) do (gatekeeper: Cap):
        run(gatekeeper.relay) do (turn: var Turn):
          reenable()
          discard publish(turn, shutdownCap, true)
          proc duringCallback(turn: var Turn; ass: Assertion; h: Handle): TurnAction =
            let facet = inFacet(turn) do (turn: var Turn):
              let o = ass.preservesTo Resolved; if o.isSome:
                discard publish(turn, ds, ResolvePath(
                  route: route, `addr`: addrAss, resolved: o.get))
            proc action(turn: var Turn) =
              stop(turn, facet)
            result = action
          var resolve = Resolve(
              step: steps[0],
              observer: newCap(turn, during(duringCallback)),
            )
          discard publish(turn, gatekeeper, resolve)

  proc connect*(turn: var Turn; ds: Cap; route: Route; transport: Tcp; steps: seq[Value]) =
    ## Relay a dataspace over TCP.
    let socket = newAsyncSocket(
      domain = AF_INET,
      sockType = SOCK_STREAM,
      protocol = IPPROTO_TCP,
      buffered = false)
    let fut = connect(socket, transport.host, Port transport.port)
    addCallback(fut, turn) do (turn: var Turn):
      connect(turn, ds, route, transport.toPreserves, socket, steps)

  proc connect*(turn: var Turn; ds: Cap; route: Route; transport: Unix; steps: seq[Value]) =
    ## Relay a dataspace over a UNIX socket.
    let socket = newAsyncSocket(
      domain = AF_UNIX,
      sockType = SOCK_STREAM,
      protocol = cast[Protocol](0),
      buffered = false)
    let fut = connectUnix(socket, transport.path)
    addCallback(fut, turn) do (turn: var Turn):
      connect(turn, ds, route, transport.toPreserves, socket, steps)

type BootProc* = proc (turn: var Turn; ds: Cap) {.gcsafe.}

proc envRoute*: Route =
  var text = getEnv("SYNDICATE_ROUTE")
  if text == "":
    var tx = (getEnv("XDG_RUNTIME_DIR", "/run/user/1000") / "dataspace").toPreserves
    result.transports = @[initRecord("unix", tx)]
    result.pathSteps = @[capabilities.mint().toPreserves]
  else:
    var pr = parsePreserves(text)
    if not result.fromPreserves(pr):
      raise newException(ValueError, "failed to parse $SYNDICATE_ROUTE " & $pr)

proc resolve*(turn: var Turn; ds: Cap; route: Route; bootProc: BootProc) =
  var
    unix: Unix
    tcp: Tcp
    stdio: Stdio
  doAssert(route.transports.len == 1, "only a single transport supported for routes")
  if unix.fromPreserves route.transports[0]:
    connect(turn, ds, route, unix, route.pathSteps)
  elif tcp.fromPreserves route.transports[0]:
    connect(turn, ds, route, tcp, route.pathSteps)
  elif stdio.fromPreserves route.transports[0]:
    doAssert(route.pathSteps.len == 0, "route steps not available over stdio")
    connectStdio(turn, ds)
    bootProc(turn, ds)
  else:
    raise newException(ValueError, "unsupported route")

  during(turn, ds, ResolvePath ?: { 0: ?route, 3: ?:ResolvedAccepted}) do (dest: Cap):
    bootProc(turn, dest)