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|
%% This file is a copy of gen_server.erl from the R13B-1 Erlang/OTP
%% distribution, with the following modifications:
%%
%% 1) the module name is gen_server2
%%
%% 2) more efficient handling of selective receives in callbacks
%% gen_server2 processes drain their message queue into an internal
%% buffer before invoking any callback module functions. Messages are
%% dequeued from the buffer for processing. Thus the effective message
%% queue of a gen_server2 process is the concatenation of the internal
%% buffer and the real message queue.
%% As a result of the draining, any selective receive invoked inside a
%% callback is less likely to have to scan a large message queue.
%%
%% 3) gen_server2:cast is guaranteed to be order-preserving
%% The original code could reorder messages when communicating with a
%% process on a remote node that was not currently connected.
%%
%% 4) The callback module can optionally implement prioritise_call/4,
%% prioritise_cast/3 and prioritise_info/3. These functions take
%% Message, From, Length and State or just Message, Length and State
%% (where Length is the current number of messages waiting to be
%% processed) and return a single integer representing the priority
%% attached to the message, or 'drop' to ignore it (for
%% prioritise_cast/3 and prioritise_info/3 only). Messages with
%% higher priorities are processed before requests with lower
%% priorities. The default priority is 0.
%%
%% 5) The callback module can optionally implement
%% handle_pre_hibernate/1 and handle_post_hibernate/1. These will be
%% called immediately prior to and post hibernation, respectively. If
%% handle_pre_hibernate returns {hibernate, NewState} then the process
%% will hibernate. If the module does not implement
%% handle_pre_hibernate/1 then the default action is to hibernate.
%%
%% 6) init can return a 4th arg, {backoff, InitialTimeout,
%% MinimumTimeout, DesiredHibernatePeriod} (all in milliseconds,
%% 'infinity' does not make sense here). Then, on all callbacks which
%% can return a timeout (including init), timeout can be
%% 'hibernate'. When this is the case, the current timeout value will
%% be used (initially, the InitialTimeout supplied from init). After
%% this timeout has occurred, hibernation will occur as normal. Upon
%% awaking, a new current timeout value will be calculated.
%%
%% The purpose is that the gen_server2 takes care of adjusting the
%% current timeout value such that the process will increase the
%% timeout value repeatedly if it is unable to sleep for the
%% DesiredHibernatePeriod. If it is able to sleep for the
%% DesiredHibernatePeriod it will decrease the current timeout down to
%% the MinimumTimeout, so that the process is put to sleep sooner (and
%% hopefully stays asleep for longer). In short, should a process
%% using this receive a burst of messages, it should not hibernate
%% between those messages, but as the messages become less frequent,
%% the process will not only hibernate, it will do so sooner after
%% each message.
%%
%% When using this backoff mechanism, normal timeout values (i.e. not
%% 'hibernate') can still be used, and if they are used then the
%% handle_info(timeout, State) will be called as normal. In this case,
%% returning 'hibernate' from handle_info(timeout, State) will not
%% hibernate the process immediately, as it would if backoff wasn't
%% being used. Instead it'll wait for the current timeout as described
%% above.
%%
%% 7) The callback module can return from any of the handle_*
%% functions, a {become, Module, State} triple, or a {become, Module,
%% State, Timeout} quadruple. This allows the gen_server to
%% dynamically change the callback module. The State is the new state
%% which will be passed into any of the callback functions in the new
%% module. Note there is no form also encompassing a reply, thus if
%% you wish to reply in handle_call/3 and change the callback module,
%% you need to use gen_server2:reply/2 to issue the reply manually.
%%
%% 8) The callback module can optionally implement
%% format_message_queue/2 which is the equivalent of format_status/2
%% but where the second argument is specifically the priority_queue
%% which contains the prioritised message_queue.
%%
%% 9) The function with_state/2 can be used to debug a process with
%% heavyweight state (without needing to copy the entire state out of
%% process as sys:get_status/1 would). Pass through a function which
%% can be invoked on the state, get back the result. The state is not
%% modified.
%%
%% 10) an mcall/1 function has been added for performing multiple
%% call/3 in parallel. Unlike multi_call, which sends the same request
%% to same-named processes residing on a supplied list of nodes, it
%% operates on name/request pairs, where name is anything accepted by
%% call/3, i.e. a pid, global name, local name, or local name on a
%% particular node.
%%
%% All modifications are (C) 2009-2013 GoPivotal, Inc.
%% ``The contents of this file are subject to the Erlang Public License,
%% Version 1.1, (the "License"); you may not use this file except in
%% compliance with the License. You should have received a copy of the
%% Erlang Public License along with this software. If not, it can be
%% retrieved via the world wide web at http://www.erlang.org/.
%%
%% Software distributed under the License is distributed on an "AS IS"
%% basis, WITHOUT WARRANTY OF ANY KIND, either express or implied. See
%% the License for the specific language governing rights and limitations
%% under the License.
%%
%% The Initial Developer of the Original Code is Ericsson Utvecklings AB.
%% Portions created by Ericsson are Copyright 1999, Ericsson Utvecklings
%% AB. All Rights Reserved.''
%%
%% $Id$
%%
-module(gen_server2).
%%% ---------------------------------------------------
%%%
%%% The idea behind THIS server is that the user module
%%% provides (different) functions to handle different
%%% kind of inputs.
%%% If the Parent process terminates the Module:terminate/2
%%% function is called.
%%%
%%% The user module should export:
%%%
%%% init(Args)
%%% ==> {ok, State}
%%% {ok, State, Timeout}
%%% {ok, State, Timeout, Backoff}
%%% ignore
%%% {stop, Reason}
%%%
%%% handle_call(Msg, {From, Tag}, State)
%%%
%%% ==> {reply, Reply, State}
%%% {reply, Reply, State, Timeout}
%%% {noreply, State}
%%% {noreply, State, Timeout}
%%% {stop, Reason, Reply, State}
%%% Reason = normal | shutdown | Term terminate(State) is called
%%%
%%% handle_cast(Msg, State)
%%%
%%% ==> {noreply, State}
%%% {noreply, State, Timeout}
%%% {stop, Reason, State}
%%% Reason = normal | shutdown | Term terminate(State) is called
%%%
%%% handle_info(Info, State) Info is e.g. {'EXIT', P, R}, {nodedown, N}, ...
%%%
%%% ==> {noreply, State}
%%% {noreply, State, Timeout}
%%% {stop, Reason, State}
%%% Reason = normal | shutdown | Term, terminate(State) is called
%%%
%%% terminate(Reason, State) Let the user module clean up
%%% Reason = normal | shutdown | {shutdown, Term} | Term
%%% always called when server terminates
%%%
%%% ==> ok | Term
%%%
%%% handle_pre_hibernate(State)
%%%
%%% ==> {hibernate, State}
%%% {stop, Reason, State}
%%% Reason = normal | shutdown | Term, terminate(State) is called
%%%
%%% handle_post_hibernate(State)
%%%
%%% ==> {noreply, State}
%%% {stop, Reason, State}
%%% Reason = normal | shutdown | Term, terminate(State) is called
%%%
%%% The work flow (of the server) can be described as follows:
%%%
%%% User module Generic
%%% ----------- -------
%%% start -----> start
%%% init <----- .
%%%
%%% loop
%%% handle_call <----- .
%%% -----> reply
%%%
%%% handle_cast <----- .
%%%
%%% handle_info <----- .
%%%
%%% terminate <----- .
%%%
%%% -----> reply
%%%
%%%
%%% ---------------------------------------------------
%% API
-export([start/3, start/4,
start_link/3, start_link/4,
call/2, call/3,
cast/2, reply/2,
abcast/2, abcast/3,
multi_call/2, multi_call/3, multi_call/4,
mcall/1,
with_state/2,
enter_loop/3, enter_loop/4, enter_loop/5, enter_loop/6, wake_hib/1]).
%% System exports
-export([system_continue/3,
system_terminate/4,
system_code_change/4,
format_status/2]).
%% Internal exports
-export([init_it/6]).
-import(error_logger, [format/2]).
%% State record
-record(gs2_state, {parent, name, state, mod, time,
timeout_state, queue, debug, prioritisers}).
-ifdef(use_specs).
%%%=========================================================================
%%% Specs. These exist only to shut up dialyzer's warnings
%%%=========================================================================
-type(gs2_state() :: #gs2_state{}).
-spec(handle_common_termination/3 ::
(any(), atom(), gs2_state()) -> no_return()).
-spec(hibernate/1 :: (gs2_state()) -> no_return()).
-spec(pre_hibernate/1 :: (gs2_state()) -> no_return()).
-spec(system_terminate/4 :: (_, _, _, gs2_state()) -> no_return()).
-type(millis() :: non_neg_integer()).
%%%=========================================================================
%%% API
%%%=========================================================================
-callback init(Args :: term()) ->
{ok, State :: term()} |
{ok, State :: term(), timeout() | hibernate} |
{ok, State :: term(), timeout() | hibernate,
{backoff, millis(), millis(), millis()}} |
ignore |
{stop, Reason :: term()}.
-callback handle_call(Request :: term(), From :: {pid(), Tag :: term()},
State :: term()) ->
{reply, Reply :: term(), NewState :: term()} |
{reply, Reply :: term(), NewState :: term(), timeout() | hibernate} |
{noreply, NewState :: term()} |
{noreply, NewState :: term(), timeout() | hibernate} |
{stop, Reason :: term(),
Reply :: term(), NewState :: term()}.
-callback handle_cast(Request :: term(), State :: term()) ->
{noreply, NewState :: term()} |
{noreply, NewState :: term(), timeout() | hibernate} |
{stop, Reason :: term(), NewState :: term()}.
-callback handle_info(Info :: term(), State :: term()) ->
{noreply, NewState :: term()} |
{noreply, NewState :: term(), timeout() | hibernate} |
{stop, Reason :: term(), NewState :: term()}.
-callback terminate(Reason :: (normal | shutdown | {shutdown, term()} | term()),
State :: term()) ->
ok | term().
-callback code_change(OldVsn :: (term() | {down, term()}), State :: term(),
Extra :: term()) ->
{ok, NewState :: term()} | {error, Reason :: term()}.
%% It's not possible to define "optional" -callbacks, so putting specs
%% for handle_pre_hibernate/1 and handle_post_hibernate/1 will result
%% in warnings (the same applied for the behaviour_info before).
-else.
-export([behaviour_info/1]).
behaviour_info(callbacks) ->
[{init,1},{handle_call,3},{handle_cast,2},{handle_info,2},
{terminate,2},{code_change,3}];
behaviour_info(_Other) ->
undefined.
-endif.
%%% -----------------------------------------------------------------
%%% Starts a generic server.
%%% start(Mod, Args, Options)
%%% start(Name, Mod, Args, Options)
%%% start_link(Mod, Args, Options)
%%% start_link(Name, Mod, Args, Options) where:
%%% Name ::= {local, atom()} | {global, atom()}
%%% Mod ::= atom(), callback module implementing the 'real' server
%%% Args ::= term(), init arguments (to Mod:init/1)
%%% Options ::= [{timeout, Timeout} | {debug, [Flag]}]
%%% Flag ::= trace | log | {logfile, File} | statistics | debug
%%% (debug == log && statistics)
%%% Returns: {ok, Pid} |
%%% {error, {already_started, Pid}} |
%%% {error, Reason}
%%% -----------------------------------------------------------------
start(Mod, Args, Options) ->
gen:start(?MODULE, nolink, Mod, Args, Options).
start(Name, Mod, Args, Options) ->
gen:start(?MODULE, nolink, Name, Mod, Args, Options).
start_link(Mod, Args, Options) ->
gen:start(?MODULE, link, Mod, Args, Options).
start_link(Name, Mod, Args, Options) ->
gen:start(?MODULE, link, Name, Mod, Args, Options).
%% -----------------------------------------------------------------
%% Make a call to a generic server.
%% If the server is located at another node, that node will
%% be monitored.
%% If the client is trapping exits and is linked server termination
%% is handled here (? Shall we do that here (or rely on timeouts) ?).
%% -----------------------------------------------------------------
call(Name, Request) ->
case catch gen:call(Name, '$gen_call', Request) of
{ok,Res} ->
Res;
{'EXIT',Reason} ->
exit({Reason, {?MODULE, call, [Name, Request]}})
end.
call(Name, Request, Timeout) ->
case catch gen:call(Name, '$gen_call', Request, Timeout) of
{ok,Res} ->
Res;
{'EXIT',Reason} ->
exit({Reason, {?MODULE, call, [Name, Request, Timeout]}})
end.
%% -----------------------------------------------------------------
%% Make a cast to a generic server.
%% -----------------------------------------------------------------
cast({global,Name}, Request) ->
catch global:send(Name, cast_msg(Request)),
ok;
cast({Name,Node}=Dest, Request) when is_atom(Name), is_atom(Node) ->
do_cast(Dest, Request);
cast(Dest, Request) when is_atom(Dest) ->
do_cast(Dest, Request);
cast(Dest, Request) when is_pid(Dest) ->
do_cast(Dest, Request).
do_cast(Dest, Request) ->
do_send(Dest, cast_msg(Request)),
ok.
cast_msg(Request) -> {'$gen_cast',Request}.
%% -----------------------------------------------------------------
%% Send a reply to the client.
%% -----------------------------------------------------------------
reply({To, Tag}, Reply) ->
catch To ! {Tag, Reply}.
%% -----------------------------------------------------------------
%% Asyncronous broadcast, returns nothing, it's just send'n pray
%% -----------------------------------------------------------------
abcast(Name, Request) when is_atom(Name) ->
do_abcast([node() | nodes()], Name, cast_msg(Request)).
abcast(Nodes, Name, Request) when is_list(Nodes), is_atom(Name) ->
do_abcast(Nodes, Name, cast_msg(Request)).
do_abcast([Node|Nodes], Name, Msg) when is_atom(Node) ->
do_send({Name,Node},Msg),
do_abcast(Nodes, Name, Msg);
do_abcast([], _,_) -> abcast.
%%% -----------------------------------------------------------------
%%% Make a call to servers at several nodes.
%%% Returns: {[Replies],[BadNodes]}
%%% A Timeout can be given
%%%
%%% A middleman process is used in case late answers arrives after
%%% the timeout. If they would be allowed to glog the callers message
%%% queue, it would probably become confused. Late answers will
%%% now arrive to the terminated middleman and so be discarded.
%%% -----------------------------------------------------------------
multi_call(Name, Req)
when is_atom(Name) ->
do_multi_call([node() | nodes()], Name, Req, infinity).
multi_call(Nodes, Name, Req)
when is_list(Nodes), is_atom(Name) ->
do_multi_call(Nodes, Name, Req, infinity).
multi_call(Nodes, Name, Req, infinity) ->
do_multi_call(Nodes, Name, Req, infinity);
multi_call(Nodes, Name, Req, Timeout)
when is_list(Nodes), is_atom(Name), is_integer(Timeout), Timeout >= 0 ->
do_multi_call(Nodes, Name, Req, Timeout).
%%% -----------------------------------------------------------------
%%% Make multiple calls to multiple servers, given pairs of servers
%%% and messages.
%%% Returns: {[{Dest, Reply}], [{Dest, Error}]}
%%%
%%% Dest can be pid() | RegName :: atom() |
%%% {Name :: atom(), Node :: atom()} | {global, Name :: atom()}
%%%
%%% A middleman process is used to avoid clogging up the callers
%%% message queue.
%%% -----------------------------------------------------------------
mcall(CallSpecs) ->
Tag = make_ref(),
{_, MRef} = spawn_monitor(
fun() ->
Refs = lists:foldl(
fun ({Dest, _Request}=S, Dict) ->
dict:store(do_mcall(S), Dest, Dict)
end, dict:new(), CallSpecs),
collect_replies(Tag, Refs, [], [])
end),
receive
{'DOWN', MRef, _, _, {Tag, Result}} -> Result;
{'DOWN', MRef, _, _, Reason} -> exit(Reason)
end.
do_mcall({{global,Name}=Dest, Request}) ->
%% whereis_name is simply an ets lookup, and is precisely what
%% global:send/2 does, yet we need a Ref to put in the call to the
%% server, so invoking whereis_name makes a lot more sense here.
case global:whereis_name(Name) of
Pid when is_pid(Pid) ->
MRef = erlang:monitor(process, Pid),
catch msend(Pid, MRef, Request),
MRef;
undefined ->
Ref = make_ref(),
self() ! {'DOWN', Ref, process, Dest, noproc},
Ref
end;
do_mcall({{Name,Node}=Dest, Request}) when is_atom(Name), is_atom(Node) ->
{_Node, MRef} = start_monitor(Node, Name), %% NB: we don't handle R6
catch msend(Dest, MRef, Request),
MRef;
do_mcall({Dest, Request}) when is_atom(Dest); is_pid(Dest) ->
MRef = erlang:monitor(process, Dest),
catch msend(Dest, MRef, Request),
MRef.
msend(Dest, MRef, Request) ->
erlang:send(Dest, {'$gen_call', {self(), MRef}, Request}, [noconnect]).
collect_replies(Tag, Refs, Replies, Errors) ->
case dict:size(Refs) of
0 -> exit({Tag, {Replies, Errors}});
_ -> receive
{MRef, Reply} ->
{Refs1, Replies1} = handle_call_result(MRef, Reply,
Refs, Replies),
collect_replies(Tag, Refs1, Replies1, Errors);
{'DOWN', MRef, _, _, Reason} ->
Reason1 = case Reason of
noconnection -> nodedown;
_ -> Reason
end,
{Refs1, Errors1} = handle_call_result(MRef, Reason1,
Refs, Errors),
collect_replies(Tag, Refs1, Replies, Errors1)
end
end.
handle_call_result(MRef, Result, Refs, AccList) ->
%% we avoid the mailbox scanning cost of a call to erlang:demonitor/{1,2}
%% here, so we must cope with MRefs that we've already seen and erased
case dict:find(MRef, Refs) of
{ok, Pid} -> {dict:erase(MRef, Refs), [{Pid, Result}|AccList]};
_ -> {Refs, AccList}
end.
%% -----------------------------------------------------------------
%% Apply a function to a generic server's state.
%% -----------------------------------------------------------------
with_state(Name, Fun) ->
case catch gen:call(Name, '$with_state', Fun, infinity) of
{ok,Res} ->
Res;
{'EXIT',Reason} ->
exit({Reason, {?MODULE, with_state, [Name, Fun]}})
end.
%%-----------------------------------------------------------------
%% enter_loop(Mod, Options, State, <ServerName>, <TimeOut>, <Backoff>) ->_
%%
%% Description: Makes an existing process into a gen_server.
%% The calling process will enter the gen_server receive
%% loop and become a gen_server process.
%% The process *must* have been started using one of the
%% start functions in proc_lib, see proc_lib(3).
%% The user is responsible for any initialization of the
%% process, including registering a name for it.
%%-----------------------------------------------------------------
enter_loop(Mod, Options, State) ->
enter_loop(Mod, Options, State, self(), infinity, undefined).
enter_loop(Mod, Options, State, Backoff = {backoff, _, _ , _}) ->
enter_loop(Mod, Options, State, self(), infinity, Backoff);
enter_loop(Mod, Options, State, ServerName = {_, _}) ->
enter_loop(Mod, Options, State, ServerName, infinity, undefined);
enter_loop(Mod, Options, State, Timeout) ->
enter_loop(Mod, Options, State, self(), Timeout, undefined).
enter_loop(Mod, Options, State, ServerName, Backoff = {backoff, _, _, _}) ->
enter_loop(Mod, Options, State, ServerName, infinity, Backoff);
enter_loop(Mod, Options, State, ServerName, Timeout) ->
enter_loop(Mod, Options, State, ServerName, Timeout, undefined).
enter_loop(Mod, Options, State, ServerName, Timeout, Backoff) ->
Name = get_proc_name(ServerName),
Parent = get_parent(),
Debug = debug_options(Name, Options),
Queue = priority_queue:new(),
Backoff1 = extend_backoff(Backoff),
loop(find_prioritisers(
#gs2_state { parent = Parent, name = Name, state = State,
mod = Mod, time = Timeout, timeout_state = Backoff1,
queue = Queue, debug = Debug })).
%%%========================================================================
%%% Gen-callback functions
%%%========================================================================
%%% ---------------------------------------------------
%%% Initiate the new process.
%%% Register the name using the Rfunc function
%%% Calls the Mod:init/Args function.
%%% Finally an acknowledge is sent to Parent and the main
%%% loop is entered.
%%% ---------------------------------------------------
init_it(Starter, self, Name, Mod, Args, Options) ->
init_it(Starter, self(), Name, Mod, Args, Options);
init_it(Starter, Parent, Name0, Mod, Args, Options) ->
Name = name(Name0),
Debug = debug_options(Name, Options),
Queue = priority_queue:new(),
GS2State = find_prioritisers(
#gs2_state { parent = Parent,
name = Name,
mod = Mod,
queue = Queue,
debug = Debug }),
case catch Mod:init(Args) of
{ok, State} ->
proc_lib:init_ack(Starter, {ok, self()}),
loop(GS2State #gs2_state { state = State,
time = infinity,
timeout_state = undefined });
{ok, State, Timeout} ->
proc_lib:init_ack(Starter, {ok, self()}),
loop(GS2State #gs2_state { state = State,
time = Timeout,
timeout_state = undefined });
{ok, State, Timeout, Backoff = {backoff, _, _, _}} ->
Backoff1 = extend_backoff(Backoff),
proc_lib:init_ack(Starter, {ok, self()}),
loop(GS2State #gs2_state { state = State,
time = Timeout,
timeout_state = Backoff1 });
{stop, Reason} ->
%% For consistency, we must make sure that the
%% registered name (if any) is unregistered before
%% the parent process is notified about the failure.
%% (Otherwise, the parent process could get
%% an 'already_started' error if it immediately
%% tried starting the process again.)
unregister_name(Name0),
proc_lib:init_ack(Starter, {error, Reason}),
exit(Reason);
ignore ->
unregister_name(Name0),
proc_lib:init_ack(Starter, ignore),
exit(normal);
{'EXIT', Reason} ->
unregister_name(Name0),
proc_lib:init_ack(Starter, {error, Reason}),
exit(Reason);
Else ->
Error = {bad_return_value, Else},
proc_lib:init_ack(Starter, {error, Error}),
exit(Error)
end.
name({local,Name}) -> Name;
name({global,Name}) -> Name;
%% name(Pid) when is_pid(Pid) -> Pid;
%% when R12 goes away, drop the line beneath and uncomment the line above
name(Name) -> Name.
unregister_name({local,Name}) ->
_ = (catch unregister(Name));
unregister_name({global,Name}) ->
_ = global:unregister_name(Name);
unregister_name(Pid) when is_pid(Pid) ->
Pid;
%% Under R12 let's just ignore it, as we have a single term as Name.
%% On R13 it will never get here, as we get tuple with 'local/global' atom.
unregister_name(_Name) -> ok.
extend_backoff(undefined) ->
undefined;
extend_backoff({backoff, InitialTimeout, MinimumTimeout, DesiredHibPeriod}) ->
{backoff, InitialTimeout, MinimumTimeout, DesiredHibPeriod, now()}.
%%%========================================================================
%%% Internal functions
%%%========================================================================
%%% ---------------------------------------------------
%%% The MAIN loop.
%%% ---------------------------------------------------
loop(GS2State = #gs2_state { time = hibernate,
timeout_state = undefined }) ->
pre_hibernate(GS2State);
loop(GS2State) ->
process_next_msg(drain(GS2State)).
drain(GS2State) ->
receive
Input -> drain(in(Input, GS2State))
after 0 -> GS2State
end.
process_next_msg(GS2State = #gs2_state { time = Time,
timeout_state = TimeoutState,
queue = Queue }) ->
case priority_queue:out(Queue) of
{{value, Msg}, Queue1} ->
process_msg(Msg, GS2State #gs2_state { queue = Queue1 });
{empty, Queue1} ->
{Time1, HibOnTimeout}
= case {Time, TimeoutState} of
{hibernate, {backoff, Current, _Min, _Desired, _RSt}} ->
{Current, true};
{hibernate, _} ->
%% wake_hib/7 will set Time to hibernate. If
%% we were woken and didn't receive a msg
%% then we will get here and need a sensible
%% value for Time1, otherwise we crash.
%% R13B1 always waits infinitely when waking
%% from hibernation, so that's what we do
%% here too.
{infinity, false};
_ -> {Time, false}
end,
receive
Input ->
%% Time could be 'hibernate' here, so *don't* call loop
process_next_msg(
drain(in(Input, GS2State #gs2_state { queue = Queue1 })))
after Time1 ->
case HibOnTimeout of
true ->
pre_hibernate(
GS2State #gs2_state { queue = Queue1 });
false ->
process_msg(timeout,
GS2State #gs2_state { queue = Queue1 })
end
end
end.
wake_hib(GS2State = #gs2_state { timeout_state = TS }) ->
TimeoutState1 = case TS of
undefined ->
undefined;
{SleptAt, TimeoutState} ->
adjust_timeout_state(SleptAt, now(), TimeoutState)
end,
post_hibernate(
drain(GS2State #gs2_state { timeout_state = TimeoutState1 })).
hibernate(GS2State = #gs2_state { timeout_state = TimeoutState }) ->
TS = case TimeoutState of
undefined -> undefined;
{backoff, _, _, _, _} -> {now(), TimeoutState}
end,
proc_lib:hibernate(?MODULE, wake_hib,
[GS2State #gs2_state { timeout_state = TS }]).
pre_hibernate(GS2State = #gs2_state { state = State,
mod = Mod }) ->
case erlang:function_exported(Mod, handle_pre_hibernate, 1) of
true ->
case catch Mod:handle_pre_hibernate(State) of
{hibernate, NState} ->
hibernate(GS2State #gs2_state { state = NState } );
Reply ->
handle_common_termination(Reply, pre_hibernate, GS2State)
end;
false ->
hibernate(GS2State)
end.
post_hibernate(GS2State = #gs2_state { state = State,
mod = Mod }) ->
case erlang:function_exported(Mod, handle_post_hibernate, 1) of
true ->
case catch Mod:handle_post_hibernate(State) of
{noreply, NState} ->
process_next_msg(GS2State #gs2_state { state = NState,
time = infinity });
{noreply, NState, Time} ->
process_next_msg(GS2State #gs2_state { state = NState,
time = Time });
Reply ->
handle_common_termination(Reply, post_hibernate, GS2State)
end;
false ->
%% use hibernate here, not infinity. This matches
%% R13B. The key is that we should be able to get through
%% to process_msg calling sys:handle_system_msg with Time
%% still set to hibernate, iff that msg is the very msg
%% that woke us up (or the first msg we receive after
%% waking up).
process_next_msg(GS2State #gs2_state { time = hibernate })
end.
adjust_timeout_state(SleptAt, AwokeAt, {backoff, CurrentTO, MinimumTO,
DesiredHibPeriod, RandomState}) ->
NapLengthMicros = timer:now_diff(AwokeAt, SleptAt),
CurrentMicros = CurrentTO * 1000,
MinimumMicros = MinimumTO * 1000,
DesiredHibMicros = DesiredHibPeriod * 1000,
GapBetweenMessagesMicros = NapLengthMicros + CurrentMicros,
Base =
%% If enough time has passed between the last two messages then we
%% should consider sleeping sooner. Otherwise stay awake longer.
case GapBetweenMessagesMicros > (MinimumMicros + DesiredHibMicros) of
true -> lists:max([MinimumTO, CurrentTO div 2]);
false -> CurrentTO
end,
{Extra, RandomState1} = random:uniform_s(Base, RandomState),
CurrentTO1 = Base + Extra,
{backoff, CurrentTO1, MinimumTO, DesiredHibPeriod, RandomState1}.
in({'$gen_cast', Msg} = Input,
GS2State = #gs2_state { prioritisers = {_, F, _} }) ->
in(Input, F(Msg, GS2State), GS2State);
in({'$gen_call', From, Msg} = Input,
GS2State = #gs2_state { prioritisers = {F, _, _} }) ->
in(Input, F(Msg, From, GS2State), GS2State);
in({'$with_state', _From, _Fun} = Input, GS2State) ->
in(Input, 0, GS2State);
in({'EXIT', Parent, _R} = Input, GS2State = #gs2_state { parent = Parent }) ->
in(Input, infinity, GS2State);
in({system, _From, _Req} = Input, GS2State) ->
in(Input, infinity, GS2State);
in(Input, GS2State = #gs2_state { prioritisers = {_, _, F} }) ->
in(Input, F(Input, GS2State), GS2State).
in(_Input, drop, GS2State) ->
GS2State;
in(Input, Priority, GS2State = #gs2_state { queue = Queue }) ->
GS2State # gs2_state { queue = priority_queue:in(Input, Priority, Queue) }.
process_msg({system, From, Req},
GS2State = #gs2_state { parent = Parent, debug = Debug }) ->
%% gen_server puts Hib on the end as the 7th arg, but that version
%% of the fun seems not to be documented so leaving out for now.
sys:handle_system_msg(Req, From, Parent, ?MODULE, Debug, GS2State);
process_msg({'$with_state', From, Fun},
GS2State = #gs2_state{state = State}) ->
reply(From, catch Fun(State)),
loop(GS2State);
process_msg({'EXIT', Parent, Reason} = Msg,
GS2State = #gs2_state { parent = Parent }) ->
terminate(Reason, Msg, GS2State);
process_msg(Msg, GS2State = #gs2_state { debug = [] }) ->
handle_msg(Msg, GS2State);
process_msg(Msg, GS2State = #gs2_state { name = Name, debug = Debug }) ->
Debug1 = sys:handle_debug(Debug, fun print_event/3, Name, {in, Msg}),
handle_msg(Msg, GS2State #gs2_state { debug = Debug1 }).
%%% ---------------------------------------------------
%%% Send/recive functions
%%% ---------------------------------------------------
do_send(Dest, Msg) ->
catch erlang:send(Dest, Msg).
do_multi_call(Nodes, Name, Req, infinity) ->
Tag = make_ref(),
Monitors = send_nodes(Nodes, Name, Tag, Req),
rec_nodes(Tag, Monitors, Name, undefined);
do_multi_call(Nodes, Name, Req, Timeout) ->
Tag = make_ref(),
Caller = self(),
Receiver =
spawn(
fun () ->
%% Middleman process. Should be unsensitive to regular
%% exit signals. The sychronization is needed in case
%% the receiver would exit before the caller started
%% the monitor.
process_flag(trap_exit, true),
Mref = erlang:monitor(process, Caller),
receive
{Caller,Tag} ->
Monitors = send_nodes(Nodes, Name, Tag, Req),
TimerId = erlang:start_timer(Timeout, self(), ok),
Result = rec_nodes(Tag, Monitors, Name, TimerId),
exit({self(),Tag,Result});
{'DOWN',Mref,_,_,_} ->
%% Caller died before sending us the go-ahead.
%% Give up silently.
exit(normal)
end
end),
Mref = erlang:monitor(process, Receiver),
Receiver ! {self(),Tag},
receive
{'DOWN',Mref,_,_,{Receiver,Tag,Result}} ->
Result;
{'DOWN',Mref,_,_,Reason} ->
%% The middleman code failed. Or someone did
%% exit(_, kill) on the middleman process => Reason==killed
exit(Reason)
end.
send_nodes(Nodes, Name, Tag, Req) ->
send_nodes(Nodes, Name, Tag, Req, []).
send_nodes([Node|Tail], Name, Tag, Req, Monitors)
when is_atom(Node) ->
Monitor = start_monitor(Node, Name),
%% Handle non-existing names in rec_nodes.
catch {Name, Node} ! {'$gen_call', {self(), {Tag, Node}}, Req},
send_nodes(Tail, Name, Tag, Req, [Monitor | Monitors]);
send_nodes([_Node|Tail], Name, Tag, Req, Monitors) ->
%% Skip non-atom Node
send_nodes(Tail, Name, Tag, Req, Monitors);
send_nodes([], _Name, _Tag, _Req, Monitors) ->
Monitors.
%% Against old nodes:
%% If no reply has been delivered within 2 secs. (per node) check that
%% the server really exists and wait for ever for the answer.
%%
%% Against contemporary nodes:
%% Wait for reply, server 'DOWN', or timeout from TimerId.
rec_nodes(Tag, Nodes, Name, TimerId) ->
rec_nodes(Tag, Nodes, Name, [], [], 2000, TimerId).
rec_nodes(Tag, [{N,R}|Tail], Name, Badnodes, Replies, Time, TimerId ) ->
receive
{'DOWN', R, _, _, _} ->
rec_nodes(Tag, Tail, Name, [N|Badnodes], Replies, Time, TimerId);
{{Tag, N}, Reply} -> %% Tag is bound !!!
unmonitor(R),
rec_nodes(Tag, Tail, Name, Badnodes,
[{N,Reply}|Replies], Time, TimerId);
{timeout, TimerId, _} ->
unmonitor(R),
%% Collect all replies that already have arrived
rec_nodes_rest(Tag, Tail, Name, [N|Badnodes], Replies)
end;
rec_nodes(Tag, [N|Tail], Name, Badnodes, Replies, Time, TimerId) ->
%% R6 node
receive
{nodedown, N} ->
monitor_node(N, false),
rec_nodes(Tag, Tail, Name, [N|Badnodes], Replies, 2000, TimerId);
{{Tag, N}, Reply} -> %% Tag is bound !!!
receive {nodedown, N} -> ok after 0 -> ok end,
monitor_node(N, false),
rec_nodes(Tag, Tail, Name, Badnodes,
[{N,Reply}|Replies], 2000, TimerId);
{timeout, TimerId, _} ->
receive {nodedown, N} -> ok after 0 -> ok end,
monitor_node(N, false),
%% Collect all replies that already have arrived
rec_nodes_rest(Tag, Tail, Name, [N | Badnodes], Replies)
after Time ->
case rpc:call(N, erlang, whereis, [Name]) of
Pid when is_pid(Pid) -> % It exists try again.
rec_nodes(Tag, [N|Tail], Name, Badnodes,
Replies, infinity, TimerId);
_ -> % badnode
receive {nodedown, N} -> ok after 0 -> ok end,
monitor_node(N, false),
rec_nodes(Tag, Tail, Name, [N|Badnodes],
Replies, 2000, TimerId)
end
end;
rec_nodes(_, [], _, Badnodes, Replies, _, TimerId) ->
case catch erlang:cancel_timer(TimerId) of
false -> % It has already sent it's message
receive
{timeout, TimerId, _} -> ok
after 0 ->
ok
end;
_ -> % Timer was cancelled, or TimerId was 'undefined'
ok
end,
{Replies, Badnodes}.
%% Collect all replies that already have arrived
rec_nodes_rest(Tag, [{N,R}|Tail], Name, Badnodes, Replies) ->
receive
{'DOWN', R, _, _, _} ->
rec_nodes_rest(Tag, Tail, Name, [N|Badnodes], Replies);
{{Tag, N}, Reply} -> %% Tag is bound !!!
unmonitor(R),
rec_nodes_rest(Tag, Tail, Name, Badnodes, [{N,Reply}|Replies])
after 0 ->
unmonitor(R),
rec_nodes_rest(Tag, Tail, Name, [N|Badnodes], Replies)
end;
rec_nodes_rest(Tag, [N|Tail], Name, Badnodes, Replies) ->
%% R6 node
receive
{nodedown, N} ->
monitor_node(N, false),
rec_nodes_rest(Tag, Tail, Name, [N|Badnodes], Replies);
{{Tag, N}, Reply} -> %% Tag is bound !!!
receive {nodedown, N} -> ok after 0 -> ok end,
monitor_node(N, false),
rec_nodes_rest(Tag, Tail, Name, Badnodes, [{N,Reply}|Replies])
after 0 ->
receive {nodedown, N} -> ok after 0 -> ok end,
monitor_node(N, false),
rec_nodes_rest(Tag, Tail, Name, [N|Badnodes], Replies)
end;
rec_nodes_rest(_Tag, [], _Name, Badnodes, Replies) ->
{Replies, Badnodes}.
%%% ---------------------------------------------------
%%% Monitor functions
%%% ---------------------------------------------------
start_monitor(Node, Name) when is_atom(Node), is_atom(Name) ->
if node() =:= nonode@nohost, Node =/= nonode@nohost ->
Ref = make_ref(),
self() ! {'DOWN', Ref, process, {Name, Node}, noconnection},
{Node, Ref};
true ->
case catch erlang:monitor(process, {Name, Node}) of
{'EXIT', _} ->
%% Remote node is R6
monitor_node(Node, true),
Node;
Ref when is_reference(Ref) ->
{Node, Ref}
end
end.
%% Cancels a monitor started with Ref=erlang:monitor(_, _).
unmonitor(Ref) when is_reference(Ref) ->
erlang:demonitor(Ref),
receive
{'DOWN', Ref, _, _, _} ->
true
after 0 ->
true
end.
%%% ---------------------------------------------------
%%% Message handling functions
%%% ---------------------------------------------------
dispatch({'$gen_cast', Msg}, Mod, State) ->
Mod:handle_cast(Msg, State);
dispatch(Info, Mod, State) ->
Mod:handle_info(Info, State).
common_reply(_Name, From, Reply, _NState, [] = _Debug) ->
reply(From, Reply),
[];
common_reply(Name, {To, _Tag} = From, Reply, NState, Debug) ->
reply(From, Reply),
sys:handle_debug(Debug, fun print_event/3, Name, {out, Reply, To, NState}).
common_noreply(_Name, _NState, [] = _Debug) ->
[];
common_noreply(Name, NState, Debug) ->
sys:handle_debug(Debug, fun print_event/3, Name, {noreply, NState}).
common_become(_Name, _Mod, _NState, [] = _Debug) ->
[];
common_become(Name, Mod, NState, Debug) ->
sys:handle_debug(Debug, fun print_event/3, Name, {become, Mod, NState}).
handle_msg({'$gen_call', From, Msg}, GS2State = #gs2_state { mod = Mod,
state = State,
name = Name,
debug = Debug }) ->
case catch Mod:handle_call(Msg, From, State) of
{reply, Reply, NState} ->
Debug1 = common_reply(Name, From, Reply, NState, Debug),
loop(GS2State #gs2_state { state = NState,
time = infinity,
debug = Debug1 });
{reply, Reply, NState, Time1} ->
Debug1 = common_reply(Name, From, Reply, NState, Debug),
loop(GS2State #gs2_state { state = NState,
time = Time1,
debug = Debug1});
{stop, Reason, Reply, NState} ->
{'EXIT', R} =
(catch terminate(Reason, Msg,
GS2State #gs2_state { state = NState })),
common_reply(Name, From, Reply, NState, Debug),
exit(R);
Other ->
handle_common_reply(Other, Msg, GS2State)
end;
handle_msg(Msg, GS2State = #gs2_state { mod = Mod, state = State }) ->
Reply = (catch dispatch(Msg, Mod, State)),
handle_common_reply(Reply, Msg, GS2State).
handle_common_reply(Reply, Msg, GS2State = #gs2_state { name = Name,
debug = Debug}) ->
case Reply of
{noreply, NState} ->
Debug1 = common_noreply(Name, NState, Debug),
loop(GS2State #gs2_state {state = NState,
time = infinity,
debug = Debug1});
{noreply, NState, Time1} ->
Debug1 = common_noreply(Name, NState, Debug),
loop(GS2State #gs2_state {state = NState,
time = Time1,
debug = Debug1});
{become, Mod, NState} ->
Debug1 = common_become(Name, Mod, NState, Debug),
loop(find_prioritisers(
GS2State #gs2_state { mod = Mod,
state = NState,
time = infinity,
debug = Debug1 }));
{become, Mod, NState, Time1} ->
Debug1 = common_become(Name, Mod, NState, Debug),
loop(find_prioritisers(
GS2State #gs2_state { mod = Mod,
state = NState,
time = Time1,
debug = Debug1 }));
_ ->
handle_common_termination(Reply, Msg, GS2State)
end.
handle_common_termination(Reply, Msg, GS2State) ->
case Reply of
{stop, Reason, NState} ->
terminate(Reason, Msg, GS2State #gs2_state { state = NState });
{'EXIT', What} ->
terminate(What, Msg, GS2State);
_ ->
terminate({bad_return_value, Reply}, Msg, GS2State)
end.
%%-----------------------------------------------------------------
%% Callback functions for system messages handling.
%%-----------------------------------------------------------------
system_continue(Parent, Debug, GS2State) ->
loop(GS2State #gs2_state { parent = Parent, debug = Debug }).
system_terminate(Reason, _Parent, Debug, GS2State) ->
terminate(Reason, [], GS2State #gs2_state { debug = Debug }).
system_code_change(GS2State = #gs2_state { mod = Mod,
state = State },
_Module, OldVsn, Extra) ->
case catch Mod:code_change(OldVsn, State, Extra) of
{ok, NewState} ->
NewGS2State = find_prioritisers(
GS2State #gs2_state { state = NewState }),
{ok, [NewGS2State]};
Else ->
Else
end.
%%-----------------------------------------------------------------
%% Format debug messages. Print them as the call-back module sees
%% them, not as the real erlang messages. Use trace for that.
%%-----------------------------------------------------------------
print_event(Dev, {in, Msg}, Name) ->
case Msg of
{'$gen_call', {From, _Tag}, Call} ->
io:format(Dev, "*DBG* ~p got call ~p from ~w~n",
[Name, Call, From]);
{'$gen_cast', Cast} ->
io:format(Dev, "*DBG* ~p got cast ~p~n",
[Name, Cast]);
_ ->
io:format(Dev, "*DBG* ~p got ~p~n", [Name, Msg])
end;
print_event(Dev, {out, Msg, To, State}, Name) ->
io:format(Dev, "*DBG* ~p sent ~p to ~w, new state ~w~n",
[Name, Msg, To, State]);
print_event(Dev, {noreply, State}, Name) ->
io:format(Dev, "*DBG* ~p new state ~w~n", [Name, State]);
print_event(Dev, Event, Name) ->
io:format(Dev, "*DBG* ~p dbg ~p~n", [Name, Event]).
%%% ---------------------------------------------------
%%% Terminate the server.
%%% ---------------------------------------------------
terminate(Reason, Msg, #gs2_state { name = Name,
mod = Mod,
state = State,
debug = Debug }) ->
case catch Mod:terminate(Reason, State) of
{'EXIT', R} ->
error_info(R, Reason, Name, Msg, State, Debug),
exit(R);
_ ->
case Reason of
normal ->
exit(normal);
shutdown ->
exit(shutdown);
{shutdown,_}=Shutdown ->
exit(Shutdown);
_ ->
error_info(Reason, undefined, Name, Msg, State, Debug),
exit(Reason)
end
end.
error_info(_Reason, _RootCause, application_controller, _Msg, _State, _Debug) ->
%% OTP-5811 Don't send an error report if it's the system process
%% application_controller which is terminating - let init take care
%% of it instead
ok;
error_info(Reason, RootCause, Name, Msg, State, Debug) ->
Reason1 = error_reason(Reason),
Fmt =
"** Generic server ~p terminating~n"
"** Last message in was ~p~n"
"** When Server state == ~p~n"
"** Reason for termination == ~n** ~p~n",
case RootCause of
undefined -> format(Fmt, [Name, Msg, State, Reason1]);
_ -> format(Fmt ++ "** In 'terminate' callback "
"with reason ==~n** ~p~n",
[Name, Msg, State, Reason1,
error_reason(RootCause)])
end,
sys:print_log(Debug),
ok.
error_reason({undef,[{M,F,A}|MFAs]} = Reason) ->
case code:is_loaded(M) of
false -> {'module could not be loaded',[{M,F,A}|MFAs]};
_ -> case erlang:function_exported(M, F, length(A)) of
true -> Reason;
false -> {'function not exported',[{M,F,A}|MFAs]}
end
end;
error_reason(Reason) ->
Reason.
%%% ---------------------------------------------------
%%% Misc. functions.
%%% ---------------------------------------------------
opt(Op, [{Op, Value}|_]) ->
{ok, Value};
opt(Op, [_|Options]) ->
opt(Op, Options);
opt(_, []) ->
false.
debug_options(Name, Opts) ->
case opt(debug, Opts) of
{ok, Options} -> dbg_options(Name, Options);
_ -> dbg_options(Name, [])
end.
dbg_options(Name, []) ->
Opts =
case init:get_argument(generic_debug) of
error ->
[];
_ ->
[log, statistics]
end,
dbg_opts(Name, Opts);
dbg_options(Name, Opts) ->
dbg_opts(Name, Opts).
dbg_opts(Name, Opts) ->
case catch sys:debug_options(Opts) of
{'EXIT',_} ->
format("~p: ignoring erroneous debug options - ~p~n",
[Name, Opts]),
[];
Dbg ->
Dbg
end.
get_proc_name(Pid) when is_pid(Pid) ->
Pid;
get_proc_name({local, Name}) ->
case process_info(self(), registered_name) of
{registered_name, Name} ->
Name;
{registered_name, _Name} ->
exit(process_not_registered);
[] ->
exit(process_not_registered)
end;
get_proc_name({global, Name}) ->
case whereis_name(Name) of
undefined ->
exit(process_not_registered_globally);
Pid when Pid =:= self() ->
Name;
_Pid ->
exit(process_not_registered_globally)
end.
get_parent() ->
case get('$ancestors') of
[Parent | _] when is_pid(Parent)->
Parent;
[Parent | _] when is_atom(Parent)->
name_to_pid(Parent);
_ ->
exit(process_was_not_started_by_proc_lib)
end.
name_to_pid(Name) ->
case whereis(Name) of
undefined ->
case whereis_name(Name) of
undefined ->
exit(could_not_find_registerd_name);
Pid ->
Pid
end;
Pid ->
Pid
end.
whereis_name(Name) ->
case ets:lookup(global_names, Name) of
[{_Name, Pid, _Method, _RPid, _Ref}] ->
if node(Pid) == node() ->
case is_process_alive(Pid) of
true -> Pid;
false -> undefined
end;
true ->
Pid
end;
[] -> undefined
end.
find_prioritisers(GS2State = #gs2_state { mod = Mod }) ->
PCall = function_exported_or_default(Mod, 'prioritise_call', 4,
fun (_Msg, _From, _State) -> 0 end),
PCast = function_exported_or_default(Mod, 'prioritise_cast', 3,
fun (_Msg, _State) -> 0 end),
PInfo = function_exported_or_default(Mod, 'prioritise_info', 3,
fun (_Msg, _State) -> 0 end),
GS2State #gs2_state { prioritisers = {PCall, PCast, PInfo} }.
function_exported_or_default(Mod, Fun, Arity, Default) ->
case erlang:function_exported(Mod, Fun, Arity) of
true -> case Arity of
3 -> fun (Msg, GS2State = #gs2_state { queue = Queue,
state = State }) ->
Length = priority_queue:len(Queue),
case catch Mod:Fun(Msg, Length, State) of
drop ->
drop;
Res when is_integer(Res) ->
Res;
Err ->
handle_common_termination(Err, Msg, GS2State)
end
end;
4 -> fun (Msg, From, GS2State = #gs2_state { queue = Queue,
state = State }) ->
Length = priority_queue:len(Queue),
case catch Mod:Fun(Msg, From, Length, State) of
Res when is_integer(Res) ->
Res;
Err ->
handle_common_termination(Err, Msg, GS2State)
end
end
end;
false -> Default
end.
%%-----------------------------------------------------------------
%% Status information
%%-----------------------------------------------------------------
format_status(Opt, StatusData) ->
[PDict, SysState, Parent, Debug,
#gs2_state{name = Name, state = State, mod = Mod, queue = Queue}] =
StatusData,
NameTag = if is_pid(Name) ->
pid_to_list(Name);
is_atom(Name) ->
Name
end,
Header = lists:concat(["Status for generic server ", NameTag]),
Log = sys:get_debug(log, Debug, []),
Specfic = callback(Mod, format_status, [Opt, [PDict, State]],
fun () -> [{data, [{"State", State}]}] end),
Messages = callback(Mod, format_message_queue, [Opt, Queue],
fun () -> priority_queue:to_list(Queue) end),
[{header, Header},
{data, [{"Status", SysState},
{"Parent", Parent},
{"Logged events", Log},
{"Queued messages", Messages}]} |
Specfic].
callback(Mod, FunName, Args, DefaultThunk) ->
case erlang:function_exported(Mod, FunName, length(Args)) of
true -> case catch apply(Mod, FunName, Args) of
{'EXIT', _} -> DefaultThunk();
Success -> Success
end;
false -> DefaultThunk()
end.
|