path: root/lib/stdlib/src/peer.erl

%%
%% Copyright WhatsApp Inc. and its affiliates. All rights reserved.
%%
%% Licensed under the Apache License, Version 2.0 (the "License");
%% you may not use this file except in compliance with the License.
%% You may obtain a copy of the License at
%%
%%     http://www.apache.org/licenses/LICENSE-2.0
%%
%% Unless required by applicable law or agreed to in writing, software
%% distributed under the License is distributed on an "AS IS" BASIS,
%% WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
%% See the License for the specific language governing permissions and
%% limitations under the License.
%%

%% @doc
%% Controller for additional Erlang node running on the same host,
%%  or in a different container/host (e.g. Docker).
%%
%% == Terms ==
%% Origin node - Erlang VM instance that spawns additional nodes.
%% Peer node - a node spawned by the origin.
%% Control process - a process running on origin node, if it terminates,
%%  peer node terminates too.
%% Control connection - a connection between origin and peer, can be
%%  ether Erlang Distribution connection, or alternative one.
%%
%% I/O is forwarded from peer node to origin via control connection.
%%
%% When standard_io is used as alternative connection, peer node
%%  uses standard out to multiplex console output and control sequences.
%% Characters in range of 192-255 are reserved for control sequences,
%%  see encode_port_data for details. If peer node attempts to print
%%  characters in this range, an controlling process on the origin
%%  node may terminate with an error (because CRC check will fail).
%%
%% Alternative connection via TCP does not have that limitation, but
%%  it also does not redirect console I/O from the peer node.
%% @end
-module(peer).
-author("maximfca@gmail.com").

%% API
-export([
         start_link/0,
         start_link/1,
         start/1,
         stop/1,

         random_name/0,
         random_name/1,

         get_state/1,

         call/4,
         call/5,
         cast/4,
         send/3
        ]).

-export_type([server_ref/0]).

-type server_ref() :: % What stop, get_state, call, cast, send accepts
        pid().


%% Could be gen_statem too, with peer_state, but most interactions
%%  are anyway available in all states.
-behaviour(gen_server).

%% gen_server callbacks
-export([
         init/1,
         handle_call/3,
         handle_cast/2,
         handle_info/2,
         terminate/2
        ]).

%% Internal exports for stdin/stdout, non-distribution RPC, and tests
-export([
         start/0, %% this function must be named "start", requirement for user.erl

         %% Peer supervision...
         supervision_child_spec/0,
         start_supervision/0,
         init_supervision/2,
         system_continue/3,
         system_terminate/4,
         system_code_change/4,
         system_get_state/1,
         system_replace_state/2
        ]).

%% Origin node will listen to the specified port (port 0 is auto-select),
%%  or specified IP/Port, and expect peer node to connect to this port.
-type connection() ::
        Port :: 0..65535 |
                {inet:ip_address(), 0..65535} |
                standard_io.

%% Specification for boot waiting
-type wait_boot() ::
        timeout() |                 %% wait for node to boot (default, 15 sec),
        {pid(), Tag :: term()} |    %% do not wait, send {Tag, {started, node(), pid()}} to Pid when node boots
        false.                      %% don't wait, don't notify

-type exec() ::
        file:name() |               %% path to "erl" (default is init:get_argument(progname))
        {file:name(), [string()]}.  %% SSH support: {"/usr/bin/ssh", ["account@host_b", "/usr/bin/erl"]}

%% Peer node start options
-type start_options() ::
        #{
          name => atom() | string(),          %% node name (part before @), if not defined, peer
          %%  starts in non-distributed mode (requires alternative connection)
          longnames => boolean(),             %% long/short names (default is net_kernel:longnames(), and shortnames)
          host => string(),                   %% force hostname (when not specified, actual peer node hostname is used)
          peer_down => stop | continue | crash,   %% stop (default): when peer terminates, peer control process
          %%  stops normally regardless of the reason.
          %% continue: when peer terminates, peer control process stays up
          %%  saving exit reason in the state
          %% crash: when peer terminates, origin process
          %%  terminates with underlying reason
          connection => connection(),         %% alternative connection specification
          exec => exec(),                     %% path to executable, or SSH/Docker support
          detached => boolean(),              %% if the node should be start in detached mode
          args => [string()],                 %% additional command line parameters to append
          post_process_args =>
              fun(([string()]) -> [string()]),%% fix the arguments
          env => [{string(), string()}],      %% additional environment variables
          wait_boot => wait_boot(),           %% default is synchronous start with 15 sec timeout
          shutdown => close |                 %% close supervision channel
          halt | %% The default...            %% stop node using erlang:halt() wait default timeout for nodedown
          {halt, disconnect_timeout()} |      %% stop node using erlang:halt() wait timeout() for nodedown
          disconnect_timeout()                %% send init:stop() request and wait up to specified timeout for nodedown
         }.

%% Peer node states
-type peer_state() :: booting | running | {down, Reason :: term()}.

-export_type([
              start_options/0,
              peer_state/0,
              exec/0,
              disconnect_timeout/0
             ]).

%% Maximum integer timeout value in a receive...
-define (MAX_INT_TIMEOUT, 4294967295).

%% Default time we wait for distributed connection to be removed,
%% when shutdown type is halt, before we disconnect from the node...
-define (DEFAULT_HALT_DISCONNECT_TIMEOUT, 5000).

%% Minimum time we wait for distributed connection to be removed,
%% before we disconnect from the node (except in the shutdown
%% close case)...
-define (MIN_DISCONNECT_TIMEOUT, 1000).

%% Socket connect timeout, for TCP connection.
-define (CONNECT_TIMEOUT, 10000).

%% Socket accept timeout, for TCP connection.
-define (ACCEPT_TIMEOUT, 60000).

%% How long to wait for graceful shutdown.
-define (SHUTDOWN_TIMEOUT, 10000).

%% Synchronous RPC timeout for alternative connection.
-define (SYNC_RPC_TIMEOUT, 5000).

%% Default timeout for peer node to boot.
-define (WAIT_BOOT_TIMEOUT, 15000).

-type disconnect_timeout() :: ?MIN_DISCONNECT_TIMEOUT..?MAX_INT_TIMEOUT | infinity.

%% Peer supervisor channel connect timeout.
-define(PEER_SUP_CHANNEL_CONNECT_TIMEOUT, 30000).

%% @doc Creates random node name, using "peer" as prefix.
-spec random_name() -> string().
random_name() ->
    random_name(?MODULE_STRING).

%% @doc Creates sufficiently random node name,
%%      using OS process ID for origin VM, resulting name
%%      looks like prefix-3-7161
-spec random_name(Prefix :: string() | atom()) -> string().
random_name(Prefix) ->
    OsPid = os:getpid(),
    Uniq = erlang:unique_integer([positive]),
    lists:concat([Prefix, "-", Uniq, "-", OsPid]).

%% @doc Starts a distributed node with random name, on this host,
%%      and waits for that node to boot. Returns full node name,
%%      registers local process with the same name as peer node.
-spec start_link() -> {ok, pid(), node()} | {error, Reason :: term()}.
start_link() ->
    start_link(#{name => random_name()}).

%% @doc Starts peer node, linked to the calling process.
%%      Accepts additional command line arguments and
%%      other important options.
-spec start_link(start_options()) -> {ok, pid()} | {ok, pid(), node()} | {error, Reason}
              when Reason :: term().
start_link(Options) ->
    start_it(Options, start_link).

%% @doc Starts peer node, not linked to the calling process.
-spec start(start_options()) -> {ok, pid()} | {ok, pid(), node()} | {error, Reason}
              when Reason :: term().
start(Options) ->
    start_it(Options, start).

%% @doc Stops controlling process, shutting down peer node synchronously
-spec stop(Dest :: server_ref()) -> ok.
stop(Dest) ->
    gen_server:stop(Dest).

%% @doc returns peer node state.
-spec get_state(Dest :: server_ref()) -> peer_state().
get_state(Dest) ->
    gen_server:call(Dest, get_state).

%% @doc Calls M:F(A) remotely, via alternative connection, with default 5 seconds timeout
-spec call(Dest :: server_ref(), Module :: module(), Function :: atom(),
           Args :: [term()]) -> Result :: term().
call(Dest, M, F, A) ->
    call(Dest, M, F, A, ?SYNC_RPC_TIMEOUT).

%% @doc Call M:F(A) remotely, timeout is explicitly specified
-spec call(Dest :: server_ref(), Module :: module(), Function :: atom(),
           Args :: [term()], Timeout :: timeout()) -> Result :: term().
call(Dest, M, F, A, Timeout) ->
    case gen_server:call(Dest, {call, M, F, A}, Timeout) of
        {ok, Reply} ->
            Reply;
        {Class, {Reason, Stack}} ->
            erlang:raise(Class, Reason, Stack);
        {error, Reason} ->
            erlang:error(Reason)
    end.

%% @doc Cast M:F(A) remotely, don't care about the result
-spec cast(Dest :: server_ref(), Module :: module(), Function :: atom(), Args :: [term()]) -> ok.
cast(Dest, M, F, A) ->
    gen_server:cast(Dest, {cast, M, F, A}).

%% @doc Sends a message to pid or named process on the peer node
%%  using alternative connection. No delivery guarantee.
-spec send(Dest :: server_ref(), To :: pid() | atom(), Message :: term()) -> ok.
send(Dest, To, Message) ->
    gen_server:cast(Dest, {send, To, Message}).

%%--------------------------------------------------------------------
%%% gen_server callbacks

-record(peer_state, {
                     options :: start_options(),
                     %% full node name, can be 'undefined'
                     node :: atom(),
                     %% debugging information: executable and arguments used to
                     %%  start the peer
                     exec :: file:name(),
                     args :: [string()],
                     %% alternative connection socket/port
                     connection :: undefined | port() | gen_tcp:socket(),
                     %% listening socket, while waiting for network alternative connection
                     listen_socket :: undefined | gen_tcp:socket(),
                     %% accumulator for RPC over standard_io
                     stdio = <<>> :: binary(),
                     %% peer state
                     peer_state = booting :: peer_state(),
                     %% pid/ref saved for gen:reply() when node is booted, or false
                     notify = false :: false | {pid(), reference()},
                     %% counter (reference) for calls.
                     %% it is not possible to use erlang reference, or pid,
                     %%  because it changes when node becomes distributed dynamically.
                     seq = 0 :: non_neg_integer(),
                     %% outstanding calls
                     outstanding = #{} :: #{non_neg_integer() => {reference(), pid()}}
                    }).

-type state() :: #peer_state{}.

-spec init([Name :: atom(), ... ]) -> {ok, state()}.
init([Notify, Options]) ->
    process_flag(trap_exit, true), %% need this to ensure terminate/2 is called

    {ListenSocket, Listen} = maybe_listen(Options),
    {Exec, Args} = command_line(Listen, Options),

    Env = maps:get(env, Options, []),

    PostProcessArgs = maps:get(post_process_args, Options, fun(As) -> As end),
    FinalArgs = PostProcessArgs(Args),

    %% close port if running detached
    Conn =
        case maps:find(connection, Options)  of
            {ok, standard_io} ->
                %% Cannot detach a peer that uses stdio. Request exit_status.
                open_port({spawn_executable, Exec},
                          [{args, FinalArgs}, {env, Env}, hide,
                           binary, exit_status, stderr_to_stdout]);
            _ ->
                Port = open_port({spawn_executable, Exec},
                                 [{args, FinalArgs}, {env, Env}, hide, binary]),
                %% peer can close the port before we get here which will cause
                %%  port_close to throw. Catch this and ignore.
                catch erlang:port_close(Port),
                receive {'EXIT', Port, _} -> undefined end
        end,

    %% Remove the default 'halt' shutdown option if present; the default is
    %% defined in terminate()...
    SaveOptions = case maps:find(shutdown, Options) of
                      {ok, halt} ->
                          maps:remove(shutdown, Options);
                      _ ->
                          Options
                  end,

    State = #peer_state{options = SaveOptions, notify = Notify, args = Args, exec = Exec},

    %% accept TCP connection if requested
    if ListenSocket =:= undefined ->
            {ok, State#peer_state{connection = Conn}};
       true ->
            _ = prim_inet:async_accept(ListenSocket, ?ACCEPT_TIMEOUT),
            {ok, State#peer_state{listen_socket = ListenSocket}}
    end.

%% not connected: no alternative connection available
handle_call({call, _M, _F, _A}, _From, #peer_state{connection = undefined} = State) ->
    {reply, {error, noconnection}, State};

handle_call({call, M, F, A}, From,
            #peer_state{connection = Port, options = #{connection := standard_io},
                        outstanding = Out, seq = Seq} = State) ->
    origin_to_peer(port, Port, {call, Seq, M, F, A}),
    {noreply, State#peer_state{outstanding = Out#{Seq => From}, seq = Seq + 1}};

handle_call({call, M, F, A}, From,
            #peer_state{connection = Socket, outstanding = Out, seq = Seq} = State) ->
    origin_to_peer(tcp, Socket, {call, Seq, M, F, A}),
    {noreply, State#peer_state{outstanding = Out#{Seq => From}, seq = Seq + 1}};

handle_call({starting, Node}, _From, #peer_state{ options = Options } = State) ->
    case maps:find(shutdown, Options) of
        {ok, {Timeout, MainCoverNode}} when is_integer(Timeout),
                                            is_atom(MainCoverNode) ->
            %% The node was started using test_server:start_peer/2 with cover enabled
            %% so we should start cover on the starting node.
            Modules = erpc:call(MainCoverNode,cover,modules,[]),
            Sticky = [ begin erpc:call(Node, code, unstick_mod, [M]), M end
                       || M <- Modules, erpc:call(Node, code, is_sticky,[M])],
            _ = erpc:call(MainCoverNode, cover, start, [Node]),
            _ = [erpc:call(Node, code,stick_mod,[M]) || M <- Sticky],
            ok;
        _ ->
            ok
    end,
    {reply, ok, State};
handle_call(get_node, _From, #peer_state{node = Node} = State) ->
    {reply, Node, State};

handle_call(get_state, _From, #peer_state{peer_state = PeerState} = State) ->
    {reply, PeerState, State};

handle_call(group_leader, _From, State) ->
    {reply, group_leader(), State}.

handle_cast({cast, _M, _F, _A}, #peer_state{connection = undefined} = State) ->
    {noreply, State};

handle_cast({cast, M, F, A},
            #peer_state{connection = Port, options = #{connection := standard_io}} = State) ->
    origin_to_peer(port, Port, {cast, M, F, A}),
    {noreply, State};

handle_cast({cast, M, F, A}, #peer_state{connection = Socket} = State) ->
    origin_to_peer(tcp, Socket, {cast, M, F, A}),
    {noreply, State};

handle_cast({send, _Dest, _Message}, #peer_state{connection = undefined} = State) ->
    {noreply, State};

handle_cast({send, Dest, Message},
            #peer_state{connection = Port, options = #{connection := standard_io}} = State) ->
    origin_to_peer(port, Port, {message, Dest, Message}),
    {noreply, State};

handle_cast({send, Dest, Message}, #peer_state{connection = Socket} = State) ->
    origin_to_peer(tcp, Socket, {message, Dest, Message}),
    {noreply, State}.

%%--------------------------------------------------------------------
%% alternative connections handling

%% alternative communications - request or response from peer
handle_info({tcp, Socket, SocketData},  #peer_state{connection = Socket} = State) ->
    ok = inet:setopts(Socket, [{active, once}]),
    {noreply, handle_alternative_data(tcp, binary_to_term(SocketData), State)};

%% standard_io
handle_info({Port, {data, PortData}}, #peer_state{connection = Port, stdio = PrevBin} = State) ->
    {Str, NewBin} = decode_port_data(PortData, <<>>, PrevBin),
    Str =/= <<>> andalso io:put_chars(Str),
    {noreply, handle_port_binary(NewBin, State)};

%% booting: accepted TCP connection from the peer, but it is not yet
%%  complete handshake
handle_info({inet_async, LSock, _Ref, {ok, CliSocket}},
            #peer_state{listen_socket = LSock} = State) ->
    true = inet_db:register_socket(CliSocket, inet_tcp),
    ok = inet:setopts(CliSocket, [{active, once}]),
    catch gen_tcp:close(LSock),
    {noreply, State#peer_state{connection = CliSocket, listen_socket = undefined}};

handle_info({inet_async, LSock, _Ref, {error, Reason}},
            #peer_state{listen_socket = LSock} = State) ->
    %% failed to accept a TCP connection
    catch gen_tcp:close(LSock),
    %% stop unconditionally, it is essentially a part of gen_server:init callback
    {stop, {inet_async, Reason}, State#peer_state{connection = undefined, listen_socket = undefined}};

%% booting: peer notifies via Erlang distribution
handle_info({started, Node}, State)->
    true = erlang:monitor_node(Node, true),
    {noreply, boot_complete(Node, started, State)};

%% nodedown: no-alternative dist-connected peer node is down
handle_info({nodedown, Node}, #peer_state{connection = undefined} = State) ->
    maybe_stop({nodedown, Node}, State);

%% external program exited, returned Status code
handle_info({Port, {exit_status, Status}}, #peer_state{connection = Port} = State) ->
    catch erlang:port_close(Port),
    maybe_stop({exit_status, Status}, State);

%% port terminated: cannot proceed, stop the server
handle_info({'EXIT', Port, Reason}, #peer_state{connection = Port} = State) ->
    catch erlang:port_close(Port),
    maybe_stop(Reason, State);

handle_info({tcp_closed, Sock}, #peer_state{connection = Sock} = State) ->
    %% TCP connection closed, no i/o port - assume node is stopped
    catch gen_tcp:close(Sock),
    maybe_stop(tcp_closed, State#peer_state{connection = undefined}).

%%--------------------------------------------------------------------
%% cleanup/termination

-spec terminate(Reason :: term(), state()) -> ok.
terminate(_Reason, #peer_state{connection = Port, options = Options, node = Node}) ->
    case {maps:get(shutdown, Options, {halt, ?DEFAULT_HALT_DISCONNECT_TIMEOUT}),
          maps:find(connection, Options)} of
        {close, {ok, standard_io}} ->
            Port /= undefined andalso (catch erlang:port_close(Port));
        {close, {ok, _TCP}} ->
            Port /= undefined andalso (catch gen_tcp:close(Port));
        {close, error} ->
            _ = erlang:disconnect_node(Node);
        {{halt, Timeout}, {ok, standard_io}} ->
            Port /= undefined andalso (catch erlang:port_close(Port)),
            wait_disconnected(Node, {timeout, Timeout});
        {{halt, Timeout}, {ok, _TCP}} ->
            Port /= undefined andalso (catch gen_tcp:close(Port)),
            wait_disconnected(Node, {timeout, Timeout});
        {{halt, Timeout}, error} ->
            try
                _ = erpc:call(Node, erlang, halt, [], Timeout),
                ok
            catch
                error:{erpc,noconnection} -> ok;
                _:_ -> force_disconnect_node(Node)
            end;
        {Shutdown, error} ->
            Timeout = shutdown(dist, undefined, Node, Shutdown),
            wait_disconnected(Node, {timeout, Timeout});
        {Shutdown, {ok, standard_io}} ->
            Timeout = shutdown(port, Port, Node, Shutdown),
            Deadline = deadline(Timeout),
            receive {'EXIT', Port, _Reason2} -> ok after Timeout -> ok end,
            catch erlang:port_close(Port),
            wait_disconnected(Node, Deadline);
        {Shutdown, {ok, _TCP}} ->
            Timeout = shutdown(tcp, Port, Node, Shutdown),
            Deadline = deadline(Timeout),
            receive {tcp_closed, Port} -> ok after Timeout -> ok end,
            catch catch gen_tcp:close(Port),
            wait_disconnected(Node, Deadline)
    end,
    ok.

%%--------------------------------------------------------------------
%% Internal implementation

deadline(infinity) ->
    {timeout, infinity};
deadline(Timeout) when is_integer(Timeout) ->
    {deadline, erlang:monotonic_time(millisecond) + Timeout}.

wait_disconnected(Node, WaitUntil) ->
    %% Should only be called just before we are exiting the caller, so
    %% we do not bother disabling nodes monitoring if we enable it and
    %% do not flush any nodeup/nodedown messages that we got due to the
    %% nodes monitoring...
    case lists:member(Node, nodes(connected)) of
        false ->
            ok;
        true ->
            _ = net_kernel:monitor_nodes(true, [{node_type, all}]),
            %% Need to check connected nodes list again, since it
            %% might have disconnected before we enabled nodes
            %% monitoring...
            case lists:member(Node, nodes(connected)) of
                false ->
                    ok;
                true ->
                    Tmo = case WaitUntil of
                              {timeout, T} ->
                                  T;
                              {deadline, T} ->
                                  TL = T - erlang:monotonic_time(millisecond),
                                  if TL < 0 -> 0;
                                     true -> TL
                                  end
                          end,
                    receive {nodedown, Node, _} -> ok
                    after Tmo -> force_disconnect_node(Node)
                    end
            end
    end.

force_disconnect_node(Node) ->
    _ = erlang:disconnect_node(Node),
    logger:warning("peer:stop() timed out waiting for disconnect from "
                   "node ~p. The connection was forcefully taken down.",
                   [Node]).

%% This hack is a temporary workaround for test coverage reports
shutdown(_Type, _Port, Node, Timeout) when is_integer(Timeout); Timeout =:= infinity ->
    erpc:cast(Node, init, stop, []),
    Timeout;
shutdown(dist, undefined, Node, {Timeout, CoverNode}) when is_integer(Timeout); Timeout =:= infinity ->
    rpc:call(CoverNode, cover, flush, [Node]),
    erpc:cast(Node, init, stop, []),
    Timeout;
shutdown(Type, Port, Node, {Timeout, CoverNode}) when is_integer(Timeout); Timeout =:= infinity ->
    rpc:call(CoverNode, cover, flush, [Node]),
    Port /= undefined andalso origin_to_peer(Type, Port, {cast, init, stop, []}),
    Timeout.

%% Verify options correctness (Dialyzer also does the job, but slightly less convenient)
verify_args(Options) ->
    %% verify that "Args" is valid - common problem is when Args aren't strings
    Args = maps:get(args, Options, []),
    is_list(Args) orelse error({invalid_arg, Args}),
    [error({invalid_arg, Arg}) || Arg <- Args, not io_lib:char_list(Arg)],
    %% alternative connection must be requested for non-distributed node,
    %%  or a distributed node when origin is not alive
    is_map_key(connection, Options)
        orelse
          (is_map_key(name, Options) andalso erlang:is_alive()) orelse error(not_alive),
    %% exec must be a string, or a tuple of string(), [string()]
    case maps:find(exec, Options) of
        {ok, {Exec, Strs}} ->
            io_lib:char_list(Exec) orelse error({exec, Exec}),
            [error({exec, Str}) || Str <- Strs, not io_lib:char_list(Str)],
            ok;
        {ok, Exec} when is_list(Exec) ->
            io_lib:char_list(Exec) orelse error({exec, Exec}),
            ok;
        error ->
            ok;
        {ok, Err} ->
            error({exec, Err})
    end,
    case maps:find(shutdown, Options) of
        {ok, close} ->
            ok;
        {ok, halt} ->
            ok;
        {ok, {halt, Tmo}} when (is_integer(Tmo)
                                andalso ?MIN_DISCONNECT_TIMEOUT =< Tmo
                                andalso Tmo =< ?MAX_INT_TIMEOUT)
                               orelse Tmo == infinity ->
            ok;
        {ok, Tmo} when (is_integer(Tmo)
                        andalso ?MIN_DISCONNECT_TIMEOUT =< Tmo
                        andalso Tmo =< ?MAX_INT_TIMEOUT)
                       orelse Tmo == infinity ->
            ok;
        {ok, {Tmo, Node}} when ((is_integer(Tmo)
                                 andalso ?MIN_DISCONNECT_TIMEOUT =< Tmo
                                 andalso Tmo =< ?MAX_INT_TIMEOUT)
                                orelse Tmo == infinity)
                               andalso is_atom(Node) ->
            ok;
        error ->
            ok;
        {ok, Err2} ->
            error({shutdown, Err2})
    end,
    case maps:find(detached, Options) of
        {ok, false} when map_get(connection, Options) =:= standard_io ->
            error({detached, cannot_detach_with_standard_io});
        _ ->
            ok
    end.

make_notify_ref(infinity) ->
    {self(), make_ref()};
make_notify_ref(WaitBoot) when is_integer(WaitBoot) ->
    {self(), make_ref()};
make_notify_ref({ReplyTo, Tag}) when is_pid(ReplyTo) ->
    {ReplyTo, Tag};
make_notify_ref(false) ->
    false.

start_it(Options, StartFun) ->
    verify_args(Options),
    WaitBoot = maps:get(wait_boot, Options, ?WAIT_BOOT_TIMEOUT),
    Notify = make_notify_ref(WaitBoot),
    case gen_server:StartFun(?MODULE, [Notify, Options], []) of
        {ok, Pid} when WaitBoot =:= infinity; is_integer(WaitBoot) ->
            {_, Ref} = Notify,
            Mref = erlang:monitor(process, Pid),
            receive
                {Ref, {started, NodeName, Pid}} ->
                    erlang:demonitor(Mref, [flush]),
                    {ok, Pid, NodeName};
                {Ref, {boot_failed, Reason, Pid}} ->
                    erlang:demonitor(Mref, [flush]),
                    erlang:exit({boot_failed, Reason});
                {'DOWN', Mref, _, _, Reason} ->
                    erlang:exit(Reason)
            after
                WaitBoot ->
                    _ = gen_server:stop(Pid),
                    erlang:demonitor(Mref, [flush]),
                    erlang:exit(timeout)
            end;
        {ok, Pid} when is_map_key(host, Options) ->
            {ok, Pid, node_name(Options)};
        {ok, Pid} ->
            {ok, Pid};
        Error ->
            Error
    end.

node_name(#{name := Name, host := Host}) ->
    list_to_atom(lists:concat([Name, "@", Host]));
node_name(_Options) ->
    undefined.

%% Lost control connection to the peer while the node was
%%  booting, this generally means a crash
maybe_stop(Reason, #peer_state{peer_state = booting} = State) ->
    _ = boot_complete(Reason, boot_failed, State),
    maybe_stop(Reason, State#peer_state{peer_state = {down, Reason}});
%%
maybe_stop(Reason, #peer_state{options = #{peer_down := crash}} = State) ->
    {stop, Reason, State#peer_state{peer_state = {down, Reason}, connection = undefined}};
%% if state was already down, keep the original reason
maybe_stop(_Reason, #peer_state{options = #{peer_down := continue}, peer_state = {down, _}} = State) ->
    {noreply, State};
%% continue working setting peer state to down
maybe_stop(Reason, #peer_state{options = #{peer_down := continue}} = State) ->
    {noreply, State#peer_state{peer_state = {down, Reason}}};
%% default: ignore Reason and shut down normally
maybe_stop(Reason, State) ->
    {stop, normal, State#peer_state{peer_state = {down, Reason}}}.

%% i/o protocol from origin:
%%  * {io_reply, ...}
%%  * {message, To, Content}
%%  * {call, From, M, F, A}
%%
%% i/o port protocol, from peer:
%%  * {io_request, From, ReplyAs, Request}
%%  * {message, To, Content}
%%  * {reply, From, ok | throw | error | exit | crash, Result | {Reason, Stack}}

%% Handles bytes coming from alternative connection, forwarding as needed.
handle_alternative_data(Kind, {io_request, From, FromRef, IoReq}, #peer_state{connection = Conn} = State) ->
    %% TODO: make i/o completely async
    Reply = {io_reply, From, FromRef, forward_request(IoReq)},
    origin_to_peer(Kind, Conn, Reply),
    State;
handle_alternative_data(_Kind, {message, To, Content}, State) ->
    To ! Content,
    State;
handle_alternative_data(_Kind, {reply, Seq, Class, Result}, #peer_state{outstanding = Out} = State) ->
    {From, NewOut} = maps:take(Seq, Out),
    gen:reply(From, {Class, Result}),
    State#peer_state{outstanding = NewOut};
handle_alternative_data(_Kind, {started, NodeName}, State)->
    boot_complete(NodeName, started, State).

forward_request(Req) ->
    GL = group_leader(),
    MRef = erlang:monitor(process, GL),
    GL ! {io_request,self(), MRef, Req},
    receive
        {io_reply, MRef, Reply} ->
            erlang:demonitor(MRef, [flush]),
            Reply;
        {'DOWN', MRef, _, _, _} ->
            {error, terminated}
    end.

%% generic primitive to send data from origin to peer via alternative connection
origin_to_peer(tcp, Sock, Term) ->
    ok = gen_tcp:send(Sock, term_to_binary(Term));
origin_to_peer(port, Port, Term) ->
    true = erlang:port_command(Port, encode_port_data(term_to_binary(Term))).

%% generic primitive to send data from peer to origin
peer_to_origin(tcp, Sock, Term) ->
    ok = gen_tcp:send(Sock, term_to_binary(Term));
peer_to_origin(port, Port, Term) ->
    %% converts Erlang term to terminal codes
    %% Every binary byte is converted into two 4-bit sequences.
    Bytes = term_to_binary(Term),
    true = erlang:port_command(Port, encode_port_data(Bytes)).

%% convert/escape Erlang term into terminal codes.
%% Protocol consists of Erlang terms serialised into
%% External Term Format (ETF) via term_to_binary. Then
%% every byte of the resulting binary is split into two
%% nibbles (4-bit sequences), which are encoded into two
%% characters.
%% Control characters must have first two and last two bits
%% set, so the byte looks this way: 11xxxx11.
%% Example encoding, hexadecimal 16#0F will be encoded as
%%  11000011 11111111 (decimal 195 255).
encode_port_data(Bytes) ->
    Size = byte_size(Bytes),
    Crc = erlang:crc32(Bytes),
    Total = <<Size:32, Bytes/binary, Crc:32>>,
    <<<<3:2, Upper:4, 3:2, 3:2, Lower:4, 3:2>> || <<Upper:4, Lower:4>> <= Total>>.

%% convert terminal codes to Erlang term, printing everything that
%%  was detected as text
decode_port_data(<<>>, Str, Bin) ->
    {Str, Bin};
decode_port_data(<<3:2, Quad:4, 3:2, Rest/binary>>, Str, Bin) ->
    decode_port_data(Rest, Str, <<Bin/bitstring, Quad:4>>);
decode_port_data(<<Char:8, Rest/binary>>, Str, Bin) ->
    decode_port_data(Rest, <<Str/binary, Char>>, Bin).

%% recursively process buffers, potentially changing the state
handle_port_binary(<<Size:32, Payload:Size/binary, Crc:32, Rest/binary>>, State) ->
    Crc = erlang:crc32(Payload),
    Term = binary_to_term(Payload),
    NewState = handle_alternative_data(port, Term, State),
    handle_port_binary(Rest, NewState);
handle_port_binary(NewBin, State) ->
    State#peer_state{stdio = NewBin}.

boot_complete(Node, _Result, #peer_state{notify = false} = State) ->
    State#peer_state{peer_state = running, node = Node};
boot_complete(Node, Result, #peer_state{notify = {ReplyTo, Tag}} = State) ->
    ReplyTo ! {Tag, {Result, Node, self()}},
    State#peer_state{peer_state = running, node = Node}.

%% check if TCP connection is enabled, and starts listener
maybe_listen(#{connection := Port}) when is_integer(Port) ->
    {ok, LSock} = gen_tcp:listen(Port, [binary, {reuseaddr, true}, {packet, 4}]),
    {ok, WaitPort} = inet:port(LSock),
    %% try guessing a local IP address
    {ok, Ifs} = inet:getifaddrs(),
    %% next incantation gets all IP addresses of all local interfaces that are up
    LocalUp = lists:append(
                [proplists:get_all_values(addr, Opts)
                 || {_, Opts} <- Ifs, lists:member(up, proplists:get_value(flags, Opts, []))]),
    %% filter invalid addresses
    Local = prefer_localhost([Valid || Valid <- LocalUp, is_list(inet:ntoa(Valid))], [], []),
    {LSock, {Local, WaitPort}};
maybe_listen(#{connection := {Ip, Port}}) when is_integer(Port) ->
    {ok, LSock} = gen_tcp:listen(Port, [binary, {reuseaddr, true}, {packet, 4}, {ip, Ip}]),
    WaitPort = if Port =:= 0 -> {ok, Dyn} = inet:port(LSock), Dyn; true -> Port end,
    {LSock, {[Ip], WaitPort}};
maybe_listen(_Options) ->
    {undefined, undefined}.

%% prefer localhost, IPv6 localhost, then everything else
prefer_localhost([], Preferred, Other) ->
    Preferred ++ Other;
prefer_localhost([{127, _, _, _} = Local | Tail], Preferred, Other) ->
    prefer_localhost(Tail, [Local | Preferred], Other);
prefer_localhost([{0, 0, 0, 0, 0, 0, 0, 1} = Local | Tail], Preferred, Other) ->
    prefer_localhost(Tail, [Local | Preferred], Other);
prefer_localhost([Local | Tail], Preferred, Other) ->
    prefer_localhost(Tail, Preferred, [Local | Other]).

name_arg(error, error, _) ->
    []; %% no name, no host - starting node that is not distributed
name_arg(error, {ok, Host}, LongOrShort) ->
    %% interesting fallback: host is set, name is not. Do what predecessor did,
    %%  take the current node name and use it...
    [Name, _] = string:lexemes(atom_to_list(node()), "@"),
    name_arg(Name ++ "@" ++ Host, error, LongOrShort);
name_arg({ok, Name}, Host, LongOrShort) ->
    name_arg(Name, Host, LongOrShort); %% unpack node name
name_arg(Name, Host, LongOrShort) when is_atom(Name) ->
    name_arg(atom_to_list(Name), Host, LongOrShort); %% convert atom to list for command line
name_arg(Name, Host, {ok, ignored}) ->
    name_arg(Name, Host, {ok, false}); %% fallback to shortnames when origin is not distributed
name_arg(Name, Host, error) ->
    name_arg(Name, Host, {ok, net_kernel:longnames()}); %% no longnames present it start options
name_arg(Name, {ok, Host}, LongOrShort) ->
    name_arg(Name ++ "@" ++ Host, error, LongOrShort); %% merge host part
%% only these are actual name creation clauses
name_arg(Name, error, {ok, true}) ->
    ["-name", Name];
name_arg(Name, error, {ok, false}) ->
    ["-sname", Name].

command_line(Listen, Options) ->
    %% Node name/sname
    NameArg = name_arg(maps:find(name, Options), maps:find(host, Options), maps:find(longnames, Options)),
    %% additional command line args
    CmdOpts = maps:get(args, Options, []),

    %% If we should detach from the node. We use -detached to tell erl to detach
    %% and -peer_detached to tell peer:start that we are detached.
    DetachArgs = case maps:get(detached, Options, true) of
                     true -> ["-detached","-peer_detached"];
                     false -> []
                 end,

    %% start command
    StartCmd =
        case Listen of
            undefined when map_get(connection, Options) =:= standard_io ->
                ["-user", atom_to_list(?MODULE)];
            undefined ->
                Self = base64:encode_to_string(term_to_binary(self())),
                DetachArgs ++ ["-user", atom_to_list(?MODULE), "-origin", Self];
            {Ips, Port} ->
                IpStr = lists:concat(lists:join(",", [inet:ntoa(Ip) || Ip <- Ips])),
                DetachArgs ++ ["-user", atom_to_list(?MODULE), "-origin", IpStr, integer_to_list(Port)]
        end,
    %% build command line
    {Exec, PreArgs} = exec(Options),
    {Exec, PreArgs ++ NameArg ++ CmdOpts ++ StartCmd}.

exec(#{exec := Prog}) when is_list(Prog) ->
    {Prog, []};
exec(#{exec := {Prog, Args}}) when is_list(Prog), is_list(Args) ->
    {Prog, Args};
exec(Options) when not is_map_key(exec, Options) ->
    case init:get_argument(progname) of
        {ok, [[Prog]]} ->
            case os:find_executable(Prog) of
                Exec when is_list(Exec) ->
                    {Exec, []};
                false ->
                    maybe_otp_test_suite(Prog)
            end;
        _ ->
            default_erts()
    end.

maybe_otp_test_suite(Prog) ->
    case string:split(Prog, "cerl ") of
        [CerlPath, Args] ->
            %% This is a hack to handle the 'cerl' script used
            %% by the Erlang/OTP test suites. When 'cerl'
            %% starts the runtime system, it typically sets
            %% 'progname' to the path of the 'cerl' script,
            %% followed by an argument. For example:
            %%
            %%     /<full_path_to>/cerl -debug
            %%     /<full_path_to>/cerl -asan
            %%     /<full_path_to>/cerl -gcov
            %%
            %% We should find a better way to handle this, for
            %% example by passing the emulator type and flavor
            %% using the '-emu_type' and '-emu_flavor'
            %% options. However, this is not without
            %% complications as those options do not really
            %% work for an installed system. Also, it is
            %% probably a good idea to stop using 'slave'
            %% before attempting to do this.
            {filename:join(CerlPath, "cerl"), parse_args(Args)};
        _ ->
            default_erts()
    end.


%% Split command line string into a list of arguments.
-spec parse_args(string()) -> [string()].
parse_args([]) ->
    [];
parse_args([Deep | _] = AlreadyParsed) when is_list(Deep) ->
    AlreadyParsed;
parse_args(CmdLine) ->
    %% following regex splits command line, preserving quoted arguments, into argv[] list
    Re = <<"((?:\"[^\"\\\\]*(?:\\\\[\\S\\s][^\"\\\\]*)*\"|'[^'\\\\]*(?:\\\\[\\S\\s][^'\\\\]*)*'|\\/[^\\/\\\\]*(?:\\\\[\\S\\s][^\\/\\\\]*)*\\/[gimy]*(?=\\s|$)|(?:\\\\\\s|\\S))+)(?=\\s|$)">>,
    {match, Args} = re:run(CmdLine, Re, [{capture, all_but_first, list}, global]),
    %% unquote arguments. It is possible to change regex capture groups to avoid extra processing.
    [unquote(Arg) || [Arg] <- Args].

unquote([Q | Arg]) when Q =:= $\"; Q =:= $\' ->
    case lists:last(Arg) of
        Q -> lists:droplast(Arg);
        _ -> [Q | Arg]
    end;
                        unquote(Arg) ->
    Arg.

%% if progname is not known, use `erlexec` from the same ERTS version we're currently running
%% BINDIR environment variable is already set
%% EMU variable it also set
default_erts() ->
    Root = code:root_dir(),
    Erts = filename:join(Root, lists:concat(["erts-", erlang:system_info(version)])),
    BinDir = filename:join(Erts, "bin"),
    {filename:join(BinDir, "erlexec"), []}.

%%--------------------------------------------------------------------
%% peer node implementation

notify_when_started(Kind, Port) ->
    init:notify_when_started(self()) =:= started andalso
        notify_started(Kind, Port),
    ok.

notify_started(dist, Process) ->
    Process ! {started, node()},
    ok;
notify_started(Kind, Port) ->
    peer_to_origin(Kind, Port, {started, node()}).

%%
%% Supervision of peer user process (which supervise the control channel) making
%% sure that the peer node is halted if the peer user process crashes...
%%

supervision_child_spec() ->
    case init:get_argument(user) of
        {ok, [["peer"]]} ->
            {ok, #{id => peer_supervision,
                   start => {?MODULE, start_supervision, []},
                   restart => permanent,
                   shutdown => 1000,
                   type => worker,
                   modules => [?MODULE]}};
        _ ->
            none
    end.

start_supervision() ->
    proc_lib:start_link(?MODULE, init_supervision, [self(), true]).

start_orphan_supervision() ->
    proc_lib:start(?MODULE, init_supervision, [self(), false]).

-record(peer_sup_state, {parent, channel, in_sup_tree}).

-spec init_supervision(term(), term()) -> no_return().
init_supervision(Parent, InSupTree) ->
    try
        process_flag(priority, high),
        process_flag(trap_exit, true),
        register(peer_supervision, self()),
        proc_lib:init_ack(Parent, {ok, self()}),
        Channel = receive
                      {channel_connect, Ref, From, ConnectChannel} ->
                          true = is_pid(ConnectChannel),
                          From ! Ref,
                          try
                              link(ConnectChannel)
                          catch error:noproc ->
                                  exit({peer_channel_terminated, noproc})
                          end,
                          ConnectChannel
                  after
                      ?PEER_SUP_CHANNEL_CONNECT_TIMEOUT ->
                          exit(peer_channel_connect_timeout)
                  end,
        loop_supervision(#peer_sup_state{parent = Parent,
                                         channel = Channel,
                                         in_sup_tree = InSupTree})
    catch
        _:_ when not InSupTree ->
            erlang:halt(1)
    end.

peer_sup_connect_channel(PeerSupervision, PeerChannelHandler) ->
    Ref = make_ref(),
    PeerSupervision ! {channel_connect, Ref, self(), PeerChannelHandler},
    receive
        Ref -> ok
    after
        ?PEER_SUP_CHANNEL_CONNECT_TIMEOUT ->
            exit(peer_supervision_connect_timeout)
    end.

loop_supervision(#peer_sup_state{parent = Parent,
                                 channel = Channel} = State) ->
    receive
        {'EXIT', Channel, Reason} ->
            exit({peer_channel_terminated, Reason});
        {system, From, Request} ->
            sys:handle_system_msg(Request, From, Parent, ?MODULE, [], State);
        _ ->
            loop_supervision(State)
    end.


system_continue(_Parent, _, #peer_sup_state{} = State) ->
    loop_supervision(State).

system_terminate(Reason, _Parent, _Debug, _State) ->
    exit(Reason).

system_code_change(State, _Module, _OldVsn, _Extra) ->
    {ok, State}.

system_get_state(State) ->
    {ok, State}.

system_replace_state(StateFun, State) ->
    NState = StateFun(State),
    {ok, NState, NState}.

%% End of peer user supervision

%% I/O redirection: peer side
-spec start() -> pid().
start() ->
    try
        PeerChannelHandler = start_peer_channel_handler(),
        PeerSup = case whereis(peer_supervision) of
                      PeerSup0 when is_pid(PeerSup0) ->
                          PeerSup0;
                      undefined ->
                          {ok, PeerSup0} = start_orphan_supervision(),
                          PeerSup0
                  end,
        peer_sup_connect_channel(PeerSup, PeerChannelHandler),
        PeerChannelHandler
    catch _:_ ->
            erlang:halt(1)
    end.

start_peer_channel_handler() ->
    case init:get_argument(origin) of
        {ok, [[IpStr, PortString]]} ->
            %% enter this clause when -origin IpList Port is specified in the command line.
            Port = list_to_integer(PortString),
            Ips = [begin {ok, Addr} = inet:parse_address(Ip), Addr end ||
                      Ip <- string:lexemes(IpStr, ",")],
            TCPConnection = spawn(fun () -> tcp_init(Ips, Port) end),
            _ = case init:get_argument(peer_detached) of
                    {ok, _} ->
                        _ = register(user, TCPConnection);
                    error ->
                        _= user_sup:init(
                             [Flag || Flag <- init:get_arguments(), Flag =/= {user,["peer"]}])
                end,
            TCPConnection;
        {ok, [[Base64EncProc]]} ->
            %% No alternative connection, but have "-origin Base64EncProc"
            OriginProcess = binary_to_term(base64:decode(Base64EncProc)),
            OriginLink = spawn(
                           fun () ->
                                   MRef = monitor(process, OriginProcess),
                                   notify_when_started(dist, OriginProcess),
                                   origin_link(MRef, OriginProcess)
                           end),
            ok = gen_server:call(OriginProcess, {starting, node()}),
            _ = case init:get_argument(peer_detached) of
                    {ok, _} ->
                        %% We are detached, so setup 'user' process, I/O redirection:
                        %%   ask controlling process who is the group leader.
                        GroupLeader = gen_server:call(OriginProcess, group_leader),
                        RelayPid = spawn(fun () ->
                                                 link(OriginLink),
                                                 relay(GroupLeader)
                                         end),
                        _ = register(user, RelayPid);
                    error ->
                        %% We are not detached, so after we spawn the link process we
                        %% start the terminal as normal but without the -user peer flag.
                        _ = user_sup:init(
                              [Flag || Flag <- init:get_arguments(), Flag =/= {user,["peer"]}])
                end,
            OriginLink;
        error ->
            %% no -origin specified, meaning that standard I/O is used for alternative
            spawn(fun io_server/0)
    end.

relay(GroupLeader) ->
    receive
        IO ->
            GroupLeader ! IO,
            relay(GroupLeader)
    end.

origin_link(MRef, Origin) ->
    receive
        {'DOWN', MRef, process, Origin, _Reason} ->
            erlang:halt();
        {init, started} ->
            notify_started(dist, Origin),
            origin_link(MRef, Origin)
    end.

-spec io_server() -> no_return().
io_server() ->
   try
       process_flag(trap_exit, true),
       Port = erlang:open_port({fd, 0, 1}, [eof, binary]),
       register(user, self()),
       group_leader(self(), self()),
       notify_when_started(port, Port),
       io_server_loop(port, Port, #{}, #{}, <<>>)
    catch
        _:_ ->
            erlang:halt(1)
    end.

-spec tcp_init([term()], term()) -> no_return().
tcp_init(IpList, Port) ->
    try
        Sock = loop_connect(IpList, Port),
        erlang:group_leader(self(), self()),
        notify_when_started(tcp, Sock),
        io_server_loop(tcp, Sock, #{}, #{}, undefined)
    catch
        _:_ ->
            erlang:halt(1)
    end.

loop_connect([], _Port) ->
    error(noconnection);
loop_connect([Ip | More], Port) ->
    case gen_tcp:connect(Ip, Port, [binary, {packet, 4}], ?CONNECT_TIMEOUT) of
        {ok, Sock} ->
            Sock;
        _Error ->
            loop_connect(More, Port)
    end.

%% Message protocol between peers
io_server_loop(Kind, Port, Refs, Out, PortBuf) ->
    receive
        {io_request, From, ReplyAs, Request} when is_pid(From) ->
            %% i/o request from this node, forward it to origin
            peer_to_origin(Kind, Port, {io_request, From, ReplyAs, Request}),
            io_server_loop(Kind, Port, Refs, Out, PortBuf);
        {Port, {data, Bytes}} when Kind =:= port ->
            {_Str, NewBin} = decode_port_data(Bytes, <<>>, PortBuf),
            {NewRefs, NewOut, NewBuf} = handle_port_alternative(NewBin, Refs, Out),
            io_server_loop(Kind, Port, NewRefs, NewOut, NewBuf);
        {Port, eof} when Kind =:= port ->
            %% stdin closed, if there is no active alternative, stop the node
            erlang:halt(1);
        {'EXIT', Port, badsig} when Kind =:= port ->
            %% ignore badsig (what is it?)
            io_server_loop(Kind, Port, Refs, Out, PortBuf);
        {'EXIT', Port, _Reason} when Kind =:= port ->
            %% stdin closed, if there is no active alternative, stop the node
            erlang:halt(1);
        {tcp, Port, Data} when Kind =:= tcp ->
            ok = inet:setopts(Port, [{active, once}]), %% flow control
            {NewRefs, NewOut} = handle_peer_alternative(binary_to_term(Data), Refs, Out),
            io_server_loop(Kind, Port, NewRefs, NewOut, PortBuf);
        {tcp_closed, Port} when Kind =:= tcp ->
            %% TCP connection closed, time to shut down
            erlang:halt(1);
        {reply, Seq, Class, Reply} when is_integer(Seq), is_map_key(Seq, Out) ->
            %% stdin/stdout RPC
            {CallerRef, Out2} = maps:take(Seq, Out),
            Refs2 = maps:remove(CallerRef, Refs),
            erlang:demonitor(CallerRef, [flush]),
            peer_to_origin(Kind, Port, {reply, Seq, Class, Reply}),
            io_server_loop(Kind, Port, Refs2, Out2, PortBuf);
        %% stdin/stdout message forwarding
        {message, To, Content} ->
            peer_to_origin(Kind, Port, {message, To, Content}),
            io_server_loop(Kind, Port, Refs, Out, PortBuf);
        {'DOWN', CallerRef, _, _, Reason} ->
            %% this is really not expected to happen, because "do_call"
            %%  catches all exceptions
            {Seq, Refs3} = maps:take(CallerRef, Refs),
            {CallerRef, Out3} = maps:take(Seq, Out),
            peer_to_origin(Kind, Port, {reply, Seq, crash, Reason}),
            io_server_loop(Kind, Port, Refs3, Out3, PortBuf);
        {init, started} ->
            notify_started(Kind, Port),
            io_server_loop(Kind, Port, Refs, Out, PortBuf);
        _Other ->
            %% below, what is it?
            io_server_loop(Kind, Port, Refs, Out, PortBuf)
    end.

handle_peer_alternative({io_reply, From, FromRef, Reply}, Refs, Out) ->
    From ! {io_reply, FromRef, Reply},
    {Refs, Out};
handle_peer_alternative({call, Seq, M, F, A}, Refs, Out) ->
    CallerRef = do_call(Seq, M, F, A),
    {Refs#{CallerRef => Seq}, Out#{Seq => CallerRef}};
handle_peer_alternative({cast, M, F, A}, Refs, Out) ->
    %% spawn a separate process to avoid blocking further RPC
    spawn(fun () -> erlang:apply(M, F, A) end),
    {Refs, Out};
handle_peer_alternative({message, Dest, Message}, Refs, Out) ->
    Dest ! Message,
    {Refs, Out}.

%% single port input message may contain multiple messages
handle_port_alternative(<<Size:32, Payload:Size/binary, Crc:32, Rest/binary>>, Refs, Out) ->
    Crc = erlang:crc32(Payload), %% assert
    {NewRefs, NewOut} = handle_peer_alternative(binary_to_term(Payload), Refs, Out),
    handle_port_alternative(Rest, NewRefs, NewOut);
handle_port_alternative(Rest, Refs, Out) ->
    {Refs, Out, Rest}.

do_call(Seq, M, F, A) ->
    Proxy = self(),
    {_, CallerRef} =
        spawn_monitor(
          fun () ->
                  %% catch all errors, otherwise emulator will log
                  %%  ERROR REPORT when it is not expected
                  try
                      Proxy ! {reply, Seq, ok, erlang:apply(M, F, A)}
                  catch
                      Class:Reason:Stack ->
                          Proxy ! {reply, Seq, Class, {Reason, Stack}}
                  end
          end),
    CallerRef.