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<!DOCTYPE erlref SYSTEM "erlref.dtd">
<erlref>
<header>
<copyright>
<year>1996</year><year>2011</year>
<holder>Ericsson AB. All Rights Reserved.</holder>
</copyright>
<legalnotice>
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 online 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.
</legalnotice>
<title>gen_fsm</title>
<prepared></prepared>
<docno></docno>
<date></date>
<rev></rev>
</header>
<module>gen_fsm</module>
<modulesummary>Generic Finite State Machine Behaviour</modulesummary>
<description>
<p>A behaviour module for implementing a finite state machine.
A generic finite state machine process (gen_fsm) implemented
using this module will have a standard set of interface functions
and include functionality for tracing and error reporting. It will
also fit into an OTP supervision tree. Refer to
<seealso marker="doc/design_principles:fsm">OTP Design Principles</seealso> for more information.</p>
<p>A gen_fsm assumes all specific parts to be located in a callback
module exporting a pre-defined set of functions. The relationship
between the behaviour functions and the callback functions can be
illustrated as follows:</p>
<pre>
gen_fsm module Callback module
-------------- ---------------
gen_fsm:start_link -----> Module:init/1
gen_fsm:send_event -----> Module:StateName/2
gen_fsm:send_all_state_event -----> Module:handle_event/3
gen_fsm:sync_send_event -----> Module:StateName/3
gen_fsm:sync_send_all_state_event -----> Module:handle_sync_event/4
- -----> Module:handle_info/3
- -----> Module:terminate/3
- -----> Module:code_change/4</pre>
<p>If a callback function fails or returns a bad value, the gen_fsm
will terminate.</p>
<p>A gen_fsm handles system messages as documented in
<seealso marker="sys">sys(3)</seealso>. The <c>sys</c> module
can be used for debugging a gen_fsm.</p>
<p>Note that a gen_fsm does not trap exit signals automatically,
this must be explicitly initiated in the callback module.</p>
<p>Unless otherwise stated, all functions in this module fail if
the specified gen_fsm does not exist or if bad arguments are
given.</p>
<p>The gen_fsm process can go into hibernation
(see <seealso marker="erts:erlang#erlang:hibernate/3">erlang(3)</seealso>) if a callback
function specifies <c>'hibernate'</c> instead of a timeout value. This
might be useful if the server is expected to be idle for a long
time. However this feature should be used with care as hibernation
implies at least two garbage collections (when hibernating and
shortly after waking up) and is not something you'd want to do
between each call to a busy state machine.</p>
</description>
<funcs>
<func>
<name>start_link(Module, Args, Options) -> Result</name>
<name>start_link(FsmName, Module, Args, Options) -> Result</name>
<fsummary>Create a gen_fsm process in a supervision tree.</fsummary>
<type>
<v>FsmName = {local,Name} | {global,GlobalName}
| {via,Module,ViaName}</v>
<v> Name = atom()</v>
<v> GlobalName = ViaName = term()</v>
<v>Module = atom()</v>
<v>Args = term()</v>
<v>Options = [Option]</v>
<v> Option = {debug,Dbgs} | {timeout,Time} | {spawn_opt,SOpts}</v>
<v> Dbgs = [Dbg]</v>
<v> Dbg = trace | log | statistics</v>
<v> | {log_to_file,FileName} | {install,{Func,FuncState}}</v>
<v> SOpts = [SOpt]</v>
<v> SOpt - see erlang:spawn_opt/2,3,4,5</v>
<v>Result = {ok,Pid} | ignore | {error,Error}</v>
<v> Pid = pid()</v>
<v> Error = {already_started,Pid} | term()</v>
</type>
<desc>
<p>Creates a gen_fsm process as part of a supervision tree.
The function should be called, directly or indirectly, by
the supervisor. It will, among other things, ensure that
the gen_fsm is linked to the supervisor.</p>
<p>The gen_fsm process calls <c>Module:init/1</c> to
initialize. To ensure a synchronized start-up procedure,
<c>start_link/3,4</c> does not return until
<c>Module:init/1</c> has returned.</p>
<p>If <c>FsmName={local,Name}</c>, the gen_fsm is registered
locally as <c>Name</c> using <c>register/2</c>.
If <c>FsmName={global,GlobalName}</c>, the gen_fsm is
registered globally as <c>GlobalName</c> using
<c>global:register_name/2</c>.
If <c>EventMgrName={via,Module,ViaName}</c>, the event manager will
register with the registry represented by <c>Module</c>.
The <c>Module</c> callback should export the functions
<c>register_name/2</c>, <c>unregister_name/1</c>,
<c>whereis_name/1</c> and <c>send/2</c>, which should behave like the
corresponding functions in <c>global</c>. Thus,
<c>{via,global,GlobalName}</c> is a valid reference.</p>
<p>If no name is provided,
the gen_fsm is not registered.</p>
<p><c>Module</c> is the name of the callback module.</p>
<p><c>Args</c> is an arbitrary term which is passed as
the argument to <c>Module:init/1</c>.</p>
<p>If the option <c>{timeout,Time}</c> is present, the gen_fsm
is allowed to spend <c>Time</c> milliseconds initializing
or it will be terminated and the start function will return
<c>{error,timeout}</c>.</p>
<p>If the option <c>{debug,Dbgs}</c> is present,
the corresponding <c>sys</c> function will be called for each
item in <c>Dbgs</c>. See
<seealso marker="sys">sys(3)</seealso>.</p>
<p>If the option <c>{spawn_opt,SOpts}</c> is present,
<c>SOpts</c> will be passed as option list to
the <c>spawn_opt</c> BIF which is used to spawn the gen_fsm
process. See
<seealso marker="erts:erlang#spawn_opt/2">erlang(3)</seealso>.</p>
<note>
<p>Using the spawn option <c>monitor</c> is currently not
allowed, but will cause the function to fail with reason
<c>badarg</c>.</p>
</note>
<p>If the gen_fsm is successfully created and initialized
the function returns <c>{ok,Pid}</c>, where <c>Pid</c> is
the pid of the gen_fsm. If there already exists a process with
the specified <c>FsmName</c>, the function returns
<c>{error,{already_started,Pid}}</c> where <c>Pid</c> is
the pid of that process.</p>
<p>If <c>Module:init/1</c> fails with <c>Reason</c>,
the function returns <c>{error,Reason}</c>. If
<c>Module:init/1</c> returns <c>{stop,Reason}</c> or
<c>ignore</c>, the process is terminated and the function
returns <c>{error,Reason}</c> or <c>ignore</c>, respectively.</p>
</desc>
</func>
<func>
<name>start(Module, Args, Options) -> Result</name>
<name>start(FsmName, Module, Args, Options) -> Result</name>
<fsummary>Create a stand-alone gen_fsm process.</fsummary>
<type>
<v>FsmName = {local,Name} | {global,GlobalName}
| {via,Module,ViaName}</v>
<v> Name = atom()</v>
<v> GlobalName = ViaName = term()</v>
<v>Module = atom()</v>
<v>Args = term()</v>
<v>Options = [Option]</v>
<v> Option = {debug,Dbgs} | {timeout,Time} | {spawn_opt,SOpts}</v>
<v> Dbgs = [Dbg]</v>
<v> Dbg = trace | log | statistics</v>
<v> | {log_to_file,FileName} | {install,{Func,FuncState}}</v>
<v> SOpts = [term()]</v>
<v>Result = {ok,Pid} | ignore | {error,Error}</v>
<v> Pid = pid()</v>
<v> Error = {already_started,Pid} | term()</v>
</type>
<desc>
<p>Creates a stand-alone gen_fsm process, i.e. a gen_fsm which
is not part of a supervision tree and thus has no supervisor.</p>
<p>See <seealso marker="#start_link/3">start_link/3,4</seealso>
for a description of arguments and return values.</p>
</desc>
</func>
<func>
<name>send_event(FsmRef, Event) -> ok</name>
<fsummary>Send an event asynchronously to a generic FSM.</fsummary>
<type>
<v>FsmRef = Name | {Name,Node} | {global,GlobalName}
| {via,Module,ViaName} | pid()</v>
<v> Name = Node = atom()</v>
<v> GlobalName = ViaName = term()</v>
<v>Event = term()</v>
</type>
<desc>
<p>Sends an event asynchronously to the gen_fsm <c>FsmRef</c>
and returns <c>ok</c> immediately. The gen_fsm will call
<c>Module:StateName/2</c> to handle the event, where
<c>StateName</c> is the name of the current state of
the gen_fsm.</p>
<p><c>FsmRef</c> can be:</p>
<list type="bulleted">
<item>the pid,</item>
<item><c>Name</c>, if the gen_fsm is locally registered,</item>
<item><c>{Name,Node}</c>, if the gen_fsm is locally
registered at another node, or</item>
<item><c>{global,GlobalName}</c>, if the gen_fsm is globally
registered.</item>
<item><c>{via,Module,ViaName}</c>, if the event manager is registered
through an alternative process registry.</item>
</list>
<p><c>Event</c> is an arbitrary term which is passed as one of
the arguments to <c>Module:StateName/2</c>.</p>
</desc>
</func>
<func>
<name>send_all_state_event(FsmRef, Event) -> ok</name>
<fsummary>Send an event asynchronously to a generic FSM.</fsummary>
<type>
<v>FsmRef = Name | {Name,Node} | {global,GlobalName}
| {via,Module,ViaName} | pid()</v>
<v> Name = Node = atom()</v>
<v> GlobalName = ViaName = term()</v>
<v>Event = term()</v>
</type>
<desc>
<p>Sends an event asynchronously to the gen_fsm <c>FsmRef</c>
and returns <c>ok</c> immediately. The gen_fsm will call
<c>Module:handle_event/3</c> to handle the event.</p>
<p>See <seealso marker="#send_event/2">send_event/2</seealso>
for a description of the arguments.</p>
<p>The difference between <c>send_event</c> and
<c>send_all_state_event</c> is which callback function is
used to handle the event. This function is useful when
sending events that are handled the same way in every state,
as only one <c>handle_event</c> clause is needed to handle
the event instead of one clause in each state name function.</p>
</desc>
</func>
<func>
<name>sync_send_event(FsmRef, Event) -> Reply</name>
<name>sync_send_event(FsmRef, Event, Timeout) -> Reply</name>
<fsummary>Send an event synchronously to a generic FSM.</fsummary>
<type>
<v>FsmRef = Name | {Name,Node} | {global,GlobalName}
| {via,Module,ViaName} | pid()</v>
<v> Name = Node = atom()</v>
<v> GlobalName = ViaName = term()</v>
<v>Event = term()</v>
<v>Timeout = int()>0 | infinity</v>
<v>Reply = term()</v>
</type>
<desc>
<p>Sends an event to the gen_fsm <c>FsmRef</c> and waits until a
reply arrives or a timeout occurs. The gen_fsm will call
<c>Module:StateName/3</c> to handle the event, where
<c>StateName</c> is the name of the current state of
the gen_fsm.</p>
<p>See <seealso marker="#send_event/2">send_event/2</seealso>
for a description of <c>FsmRef</c> and <c>Event</c>.</p>
<p><c>Timeout</c> is an integer greater than zero which
specifies how many milliseconds to wait for a reply, or
the atom <c>infinity</c> to wait indefinitely. Default value
is 5000. If no reply is received within the specified time,
the function call fails.</p>
<p>The return value <c>Reply</c> is defined in the return value
of <c>Module:StateName/3</c>.</p>
<p>The ancient behaviour of sometimes consuming the server
exit message if the server died during the call while
linked to the client has been removed in OTP R12B/Erlang 5.6.</p>
</desc>
</func>
<func>
<name>sync_send_all_state_event(FsmRef, Event) -> Reply</name>
<name>sync_send_all_state_event(FsmRef, Event, Timeout) -> Reply</name>
<fsummary>Send an event synchronously to a generic FSM.</fsummary>
<type>
<v>FsmRef = Name | {Name,Node} | {global,GlobalName}
| {via,Module,ViaName} | pid()</v>
<v> Name = Node = atom()</v>
<v> GlobalName = ViaName = term()</v>
<v>Event = term()</v>
<v>Timeout = int()>0 | infinity</v>
<v>Reply = term()</v>
</type>
<desc>
<p>Sends an event to the gen_fsm <c>FsmRef</c> and waits until a
reply arrives or a timeout occurs. The gen_fsm will call
<c>Module:handle_sync_event/4</c> to handle the event.</p>
<p>See <seealso marker="#send_event/2">send_event/2</seealso>
for a description of <c>FsmRef</c> and <c>Event</c>. See
<seealso marker="#sync_send_event/3">sync_send_event/3</seealso>
for a description of <c>Timeout</c> and <c>Reply</c>.</p>
<p>See
<seealso marker="#send_all_state_event/2">send_all_state_event/2</seealso>
for a discussion about the difference between
<c>sync_send_event</c> and <c>sync_send_all_state_event</c>.</p>
</desc>
</func>
<func>
<name>reply(Caller, Reply) -> true</name>
<fsummary>Send a reply to a caller.</fsummary>
<type>
<v>Caller - see below</v>
<v>Reply = term()</v>
</type>
<desc>
<p>This function can be used by a gen_fsm to explicitly send a
reply to a client process that called
<seealso marker="#sync_send_event/2">sync_send_event/2,3</seealso>
or
<seealso marker="#sync_send_all_state_event/2">sync_send_all_state_event/2,3</seealso>,
when the reply cannot be defined in the return value of
<c>Module:State/3</c> or <c>Module:handle_sync_event/4</c>.</p>
<p><c>Caller</c> must be the <c>From</c> argument provided to
the callback function. <c>Reply</c> is an arbitrary term,
which will be given back to the client as the return value of
<c>sync_send_event/2,3</c> or
<c>sync_send_all_state_event/2,3</c>.</p>
</desc>
</func>
<func>
<name>send_event_after(Time, Event) -> Ref</name>
<fsummary>Send a delayed event internally in a generic FSM.</fsummary>
<type>
<v>Time = integer()</v>
<v>Event = term()</v>
<v>Ref = reference()</v>
</type>
<desc>
<p>Sends a delayed event internally in the gen_fsm that calls
this function after <c>Time</c> ms. Returns immediately a
reference that can be used to cancel the delayed send using
<seealso marker="#cancel_timer/1">cancel_timer/1</seealso>.</p>
<p>The gen_fsm will call <c>Module:StateName/2</c> to handle
the event, where <c>StateName</c> is the name of the current
state of the gen_fsm at the time the delayed event is
delivered.</p>
<p><c>Event</c> is an arbitrary term which is passed as one of
the arguments to <c>Module:StateName/2</c>.</p>
</desc>
</func>
<func>
<name>start_timer(Time, Msg) -> Ref</name>
<fsummary>Send a timeout event internally in a generic FSM.</fsummary>
<type>
<v>Time = integer()</v>
<v>Msg = term()</v>
<v>Ref = reference()</v>
</type>
<desc>
<p>Sends a timeout event internally in the gen_fsm that calls
this function after <c>Time</c> ms. Returns immediately a
reference that can be used to cancel the timer using
<seealso marker="#cancel_timer/1">cancel_timer/1</seealso>.</p>
<p>The gen_fsm will call <c>Module:StateName/2</c> to handle
the event, where <c>StateName</c> is the name of the current
state of the gen_fsm at the time the timeout message is
delivered.</p>
<p><c>Msg</c> is an arbitrary term which is passed in the
timeout message, <c>{timeout, Ref, Msg}</c>, as one of
the arguments to <c>Module:StateName/2</c>.</p>
</desc>
</func>
<func>
<name>cancel_timer(Ref) -> RemainingTime | false</name>
<fsummary>Cancel an internal timer in a generic FSM.</fsummary>
<type>
<v>Ref = reference()</v>
<v>RemainingTime = integer()</v>
</type>
<desc>
<p>Cancels an internal timer referred by <c>Ref</c> in the
gen_fsm that calls this function.</p>
<p><c>Ref</c> is a reference returned from
<seealso marker="#send_event_after/2">send_event_after/2</seealso>
or
<seealso marker="#start_timer/2">start_timer/2</seealso>.</p>
<p>If the timer has already timed out, but the event not yet
been delivered, it is cancelled as if it had <em>not</em>
timed out, so there will be no false timer event after
returning from this function.</p>
<p>Returns the remaining time in ms until the timer would
have expired if <c>Ref</c> referred to an active timer,
<c>false</c> otherwise.</p>
</desc>
</func>
<func>
<name>enter_loop(Module, Options, StateName, StateData)</name>
<name>enter_loop(Module, Options, StateName, StateData, FsmName)</name>
<name>enter_loop(Module, Options, StateName, StateData, Timeout)</name>
<name>enter_loop(Module, Options, StateName, StateData, FsmName, Timeout)</name>
<fsummary>Enter the gen_fsm receive loop</fsummary>
<type>
<v>Module = atom()</v>
<v>Options = [Option]</v>
<v> Option = {debug,Dbgs}</v>
<v> Dbgs = [Dbg]</v>
<v> Dbg = trace | log | statistics</v>
<v> | {log_to_file,FileName} | {install,{Func,FuncState}}</v>
<v>StateName = atom()</v>
<v>StateData = term()</v>
<v>FsmName = {local,Name} | {global,GlobalName}
| {via,Module,ViaName}</v>
<v> Name = atom()</v>
<v> GlobalName = ViaName = term()</v>
<v>Timeout = int() | infinity</v>
</type>
<desc>
<p>Makes an existing process into a gen_fsm. Does not return,
instead the calling process will enter the gen_fsm receive
loop and become a gen_fsm process. The process <em>must</em>
have been started using one of the start functions in
<c>proc_lib</c>, see
<seealso marker="proc_lib">proc_lib(3)</seealso>. The user is
responsible for any initialization of the process, including
registering a name for it.</p>
<p>This function is useful when a more complex initialization
procedure is needed than the gen_fsm behaviour provides.</p>
<p><c>Module</c>, <c>Options</c> and <c>FsmName</c> have
the same meanings as when calling
<seealso marker="#start_link/3">start[_link]/3,4</seealso>.
However, if <c>FsmName</c> is specified, the process must have
been registered accordingly <em>before</em> this function is
called.</p>
<p><c>StateName</c>, <c>StateData</c> and <c>Timeout</c> have
the same meanings as in the return value of
<seealso marker="#Moduleinit">Module:init/1</seealso>.
Also, the callback module <c>Module</c> does not need to
export an <c>init/1</c> function.</p>
<p>Failure: If the calling process was not started by a
<c>proc_lib</c> start function, or if it is not registered
according to <c>FsmName</c>.</p>
</desc>
</func>
</funcs>
<section>
<title>CALLBACK FUNCTIONS</title>
<p>The following functions should be exported from a <c>gen_fsm</c>
callback module.</p>
<p>In the description, the expression <em>state name</em> is used to
denote a state of the state machine. <em>state data</em> is used
to denote the internal state of the Erlang process which
implements the state machine.</p>
</section>
<funcs>
<func>
<name>Module:init(Args) -> Result</name>
<fsummary>Initialize process and internal state name and state data.</fsummary>
<type>
<v>Args = term()</v>
<v>Result = {ok,StateName,StateData} | {ok,StateName,StateData,Timeout}</v>
<v> | {ok,StateName,StateData,hibernate}</v>
<v> | {stop,Reason} | ignore</v>
<v> StateName = atom()</v>
<v> StateData = term()</v>
<v> Timeout = int()>0 | infinity</v>
<v> Reason = term()</v>
</type>
<desc>
<marker id="Moduleinit"></marker>
<p>Whenever a gen_fsm is started using
<seealso marker="#start/3">gen_fsm:start/3,4</seealso> or
<seealso marker="#start_link/3">gen_fsm:start_link/3,4</seealso>,
this function is called by the new process to initialize.</p>
<p><c>Args</c> is the <c>Args</c> argument provided to the start
function.</p>
<p>If initialization is successful, the function should return
<c>{ok,StateName,StateData}</c>,
<c>{ok,StateName,StateData,Timeout}</c> or <c>{ok,StateName,StateData,hibernate}</c>,
where <c>StateName</c>
is the initial state name and <c>StateData</c> the initial
state data of the gen_fsm.</p>
<p>If an integer timeout value is provided, a timeout will occur
unless an event or a message is received within <c>Timeout</c>
milliseconds. A timeout is represented by the atom
<c>timeout</c> and should be handled by
the <c>Module:StateName/2</c> callback functions. The atom
<c>infinity</c> can be used to wait indefinitely, this is
the default value.</p>
<p>If <c>hibernate</c> is specified instead of a timeout value, the process will go
into hibernation when waiting for the next message to arrive (by calling
<seealso marker="proc_lib#hibernate/3">proc_lib:hibernate/3</seealso>).</p>
<p>If something goes wrong during the initialization
the function should return <c>{stop,Reason}</c>, where
<c>Reason</c> is any term, or <c>ignore</c>.</p>
</desc>
</func>
<func>
<name>Module:StateName(Event, StateData) -> Result</name>
<fsummary>Handle an asynchronous event.</fsummary>
<type>
<v>Event = timeout | term()</v>
<v>StateData = term()</v>
<v>Result = {next_state,NextStateName,NewStateData} </v>
<v> | {next_state,NextStateName,NewStateData,Timeout}</v>
<v> | {next_state,NextStateName,NewStateData,hibernate}</v>
<v> | {stop,Reason,NewStateData}</v>
<v> NextStateName = atom()</v>
<v> NewStateData = term()</v>
<v> Timeout = int()>0 | infinity</v>
<v> Reason = term()</v>
</type>
<desc>
<p>There should be one instance of this function for each
possible state name. Whenever a gen_fsm receives an event
sent using
<seealso marker="#send_event/2">gen_fsm:send_event/2</seealso>,
the instance of this function with the same name as
the current state name <c>StateName</c> is called to handle
the event. It is also called if a timeout occurs.</p>
<p><c>Event</c> is either the atom <c>timeout</c>, if a timeout
has occurred, or the <c>Event</c> argument provided to
<c>send_event/2</c>.</p>
<p><c>StateData</c> is the state data of the gen_fsm.</p>
<p>If the function returns
<c>{next_state,NextStateName,NewStateData}</c>,
<c>{next_state,NextStateName,NewStateData,Timeout}</c> or
<c>{next_state,NextStateName,NewStateData,hibernate}</c>,
the gen_fsm will continue executing with the current state
name set to <c>NextStateName</c> and with the possibly
updated state data <c>NewStateData</c>. See
<c>Module:init/1</c> for a description of <c>Timeout</c> and <c>hibernate</c>.</p>
<p>If the function returns <c>{stop,Reason,NewStateData}</c>,
the gen_fsm will call
<c>Module:terminate(Reason,NewStateData)</c> and terminate.</p>
</desc>
</func>
<func>
<name>Module:handle_event(Event, StateName, StateData) -> Result</name>
<fsummary>Handle an asynchronous event.</fsummary>
<type>
<v>Event = term()</v>
<v>StateName = atom()</v>
<v>StateData = term()</v>
<v>Result = {next_state,NextStateName,NewStateData} </v>
<v> | {next_state,NextStateName,NewStateData,Timeout}</v>
<v> | {next_state,NextStateName,NewStateData,hibernate}</v>
<v> | {stop,Reason,NewStateData}</v>
<v> NextStateName = atom()</v>
<v> NewStateData = term()</v>
<v> Timeout = int()>0 | infinity</v>
<v> Reason = term()</v>
</type>
<desc>
<p>Whenever a gen_fsm receives an event sent using
<seealso marker="#send_all_state_event/2">gen_fsm:send_all_state_event/2</seealso>,
this function is called to handle the event.</p>
<p><c>StateName</c> is the current state name of the gen_fsm.</p>
<p>See <c>Module:StateName/2</c> for a description of the other
arguments and possible return values.</p>
</desc>
</func>
<func>
<name>Module:StateName(Event, From, StateData) -> Result</name>
<fsummary>Handle a synchronous event.</fsummary>
<type>
<v>Event = term()</v>
<v>From = {pid(),Tag}</v>
<v>StateData = term()</v>
<v>Result = {reply,Reply,NextStateName,NewStateData}</v>
<v> | {reply,Reply,NextStateName,NewStateData,Timeout}</v>
<v> | {reply,Reply,NextStateName,NewStateData,hibernate}</v>
<v> | {next_state,NextStateName,NewStateData}</v>
<v> | {next_state,NextStateName,NewStateData,Timeout}</v>
<v> | {next_state,NextStateName,NewStateData,hibernate}</v>
<v> | {stop,Reason,Reply,NewStateData} | {stop,Reason,NewStateData}</v>
<v> Reply = term()</v>
<v> NextStateName = atom()</v>
<v> NewStateData = term()</v>
<v> Timeout = int()>0 | infinity</v>
<v> Reason = normal | term()</v>
</type>
<desc>
<p>There should be one instance of this function for each
possible state name. Whenever a gen_fsm receives an event
sent using
<seealso marker="#sync_send_event/2">gen_fsm:sync_send_event/2,3</seealso>,
the instance of this function with the same name as
the current state name <c>StateName</c> is called to handle
the event.</p>
<p><c>Event</c> is the <c>Event</c> argument provided to
<c>sync_send_event</c>.</p>
<p><c>From</c> is a tuple <c>{Pid,Tag}</c> where <c>Pid</c> is
the pid of the process which called <c>sync_send_event/2,3</c>
and <c>Tag</c> is a unique tag.</p>
<p><c>StateData</c> is the state data of the gen_fsm.</p>
<p>If the function returns
<c>{reply,Reply,NextStateName,NewStateData}</c>,
<c>{reply,Reply,NextStateName,NewStateData,Timeout}</c> or
<c>{reply,Reply,NextStateName,NewStateData,hibernate}</c>,
<c>Reply</c> will be given back to <c>From</c> as the return
value of <c>sync_send_event/2,3</c>. The gen_fsm then
continues executing with the current state name set to
<c>NextStateName</c> and with the possibly updated state data
<c>NewStateData</c>. See <c>Module:init/1</c> for a
description of <c>Timeout</c> and <c>hibernate</c>.</p>
<p>If the function returns
<c>{next_state,NextStateName,NewStateData}</c>,
<c>{next_state,NextStateName,NewStateData,Timeout}</c> or
<c>{next_state,NextStateName,NewStateData,hibernate}</c>,
the gen_fsm will continue executing in <c>NextStateName</c>
with <c>NewStateData</c>. Any reply to <c>From</c> must be
given explicitly using
<seealso marker="#reply/2">gen_fsm:reply/2</seealso>.</p>
<p>If the function returns
<c>{stop,Reason,Reply,NewStateData}</c>, <c>Reply</c> will be
given back to <c>From</c>. If the function returns
<c>{stop,Reason,NewStateData}</c>, any reply to <c>From</c>
must be given explicitly using <c>gen_fsm:reply/2</c>.
The gen_fsm will then call
<c>Module:terminate(Reason,NewStateData)</c> and terminate.</p>
</desc>
</func>
<func>
<name>Module:handle_sync_event(Event, From, StateName, StateData) -> Result</name>
<fsummary>Handle a synchronous event.</fsummary>
<type>
<v>Event = term()</v>
<v>From = {pid(),Tag}</v>
<v>StateName = atom()</v>
<v>StateData = term()</v>
<v>Result = {reply,Reply,NextStateName,NewStateData}</v>
<v> | {reply,Reply,NextStateName,NewStateData,Timeout}</v>
<v> | {reply,Reply,NextStateName,NewStateData,hibernate}</v>
<v> | {next_state,NextStateName,NewStateData}</v>
<v> | {next_state,NextStateName,NewStateData,Timeout}</v>
<v> | {next_state,NextStateName,NewStateData,hibernate}</v>
<v> | {stop,Reason,Reply,NewStateData} | {stop,Reason,NewStateData}</v>
<v> Reply = term()</v>
<v> NextStateName = atom()</v>
<v> NewStateData = term()</v>
<v> Timeout = int()>0 | infinity</v>
<v> Reason = term()</v>
</type>
<desc>
<p>Whenever a gen_fsm receives an event sent using
<seealso marker="#sync_send_all_state_event/2">gen_fsm:sync_send_all_state_event/2,3</seealso>,
this function is called to handle the event.</p>
<p><c>StateName</c> is the current state name of the gen_fsm.</p>
<p>See <c>Module:StateName/3</c> for a description of the other
arguments and possible return values.</p>
</desc>
</func>
<func>
<name>Module:handle_info(Info, StateName, StateData) -> Result</name>
<fsummary>Handle an incoming message.</fsummary>
<type>
<v>Info = term()</v>
<v>StateName = atom()</v>
<v>StateData = term()</v>
<v>Result = {next_state,NextStateName,NewStateData}</v>
<v> | {next_state,NextStateName,NewStateData,Timeout}</v>
<v> | {next_state,NextStateName,NewStateData,hibernate}</v>
<v> | {stop,Reason,NewStateData}</v>
<v> NextStateName = atom()</v>
<v> NewStateData = term()</v>
<v> Timeout = int()>0 | infinity</v>
<v> Reason = normal | term()</v>
</type>
<desc>
<p>This function is called by a gen_fsm when it receives any
other message than a synchronous or asynchronous event (or a
system message).</p>
<p><c>Info</c> is the received message.</p>
<p>See <c>Module:StateName/2</c> for a description of the other
arguments and possible return values.</p>
</desc>
</func>
<func>
<name>Module:terminate(Reason, StateName, StateData)</name>
<fsummary>Clean up before termination.</fsummary>
<type>
<v>Reason = normal | shutdown | {shutdown,term()} | term()</v>
<v>StateName = atom()</v>
<v>StateData = term()</v>
</type>
<desc>
<p>This function is called by a gen_fsm when it is about to
terminate. It should be the opposite of <c>Module:init/1</c>
and do any necessary cleaning up. When it returns, the gen_fsm
terminates with <c>Reason</c>. The return value is ignored.</p>
<p><c>Reason</c> is a term denoting the stop reason,
<c>StateName</c> is the current state name, and
<c>StateData</c> is the state data of the gen_fsm.</p>
<p><c>Reason</c> depends on why the gen_fsm is terminating. If
it is because another callback function has returned a stop
tuple <c>{stop,..}</c>, <c>Reason</c> will have the value
specified in that tuple. If it is due to a failure,
<c>Reason</c> is the error reason.</p>
<p>If the gen_fsm is part of a supervision tree and is ordered
by its supervisor to terminate, this function will be called
with <c>Reason=shutdown</c> if the following conditions apply:</p>
<list type="bulleted">
<item>the gen_fsm has been set to trap exit signals, and</item>
<item>the shutdown strategy as defined in the supervisor's
child specification is an integer timeout value, not
<c>brutal_kill</c>.</item>
</list>
<p>Even if the gen_fsm is <em>not</em> part of a supervision tree,
this function will be called if it receives an <c>'EXIT'</c>
message from its parent. <c>Reason</c> will be the same as in
the <c>'EXIT'</c> message.</p>
<p>Otherwise, the gen_fsm will be immediately terminated.</p>
<p>Note that for any other reason than <c>normal</c>,
<c>shutdown</c>, or <c>{shutdown,Term}</c> the gen_fsm is
assumed to terminate due to an error and
an error report is issued using
<seealso marker="kernel:error_logger#format/2">error_logger:format/2</seealso>.</p>
</desc>
</func>
<func>
<name>Module:code_change(OldVsn, StateName, StateData, Extra) -> {ok, NextStateName, NewStateData}</name>
<fsummary>Update the internal state data during upgrade/downgrade.</fsummary>
<type>
<v>OldVsn = Vsn | {down, Vsn}</v>
<v> Vsn = term()</v>
<v>StateName = NextStateName = atom()</v>
<v>StateData = NewStateData = term()</v>
<v>Extra = term()</v>
</type>
<desc>
<p>This function is called by a gen_fsm when it should update
its internal state data during a release upgrade/downgrade,
i.e. when the instruction <c>{update,Module,Change,...}</c>
where <c>Change={advanced,Extra}</c> is given in
the <c>appup</c> file. See
<seealso marker="doc/design_principles:release_handling#instr">OTP Design Principles</seealso>.</p>
<p>In the case of an upgrade, <c>OldVsn</c> is <c>Vsn</c>, and
in the case of a downgrade, <c>OldVsn</c> is
<c>{down,Vsn}</c>. <c>Vsn</c> is defined by the <c>vsn</c>
attribute(s) of the old version of the callback module
<c>Module</c>. If no such attribute is defined, the version is
the checksum of the BEAM file.</p>
<p><c>StateName</c> is the current state name and
<c>StateData</c> the internal state data of the gen_fsm.</p>
<p><c>Extra</c> is passed as-is from the <c>{advanced,Extra}</c>
part of the update instruction.</p>
<p>The function should return the new current state name and
updated internal data.</p>
</desc>
</func>
<func>
<name>Module:format_status(Opt, [PDict, StateData]) -> Status</name>
<fsummary>Optional function for providing a term describing the
current gen_fsm status.</fsummary>
<type>
<v>Opt = normal | terminate</v>
<v>PDict = [{Key, Value}]</v>
<v>StateData = term()</v>
<v>Status = term()</v>
</type>
<desc>
<note>
<p>This callback is optional, so callback modules need not
export it. The gen_fsm module provides a default
implementation of this function that returns the callback
module state data.</p>
</note>
<p>This function is called by a gen_fsm process when:</p>
<list typed="bulleted">
<item>One
of <seealso marker="sys#get_status/1">sys:get_status/1,2</seealso>
is invoked to get the gen_fsm status. <c>Opt</c> is set to
the atom <c>normal</c> for this case.</item>
<item>The gen_fsm terminates abnormally and logs an
error. <c>Opt</c> is set to the atom <c>terminate</c> for
this case.</item>
</list>
<p>This function is useful for customising the form and
appearance of the gen_fsm status for these cases. A callback
module wishing to customise the <c>sys:get_status/1,2</c>
return value as well as how its status appears in
termination error logs exports an instance
of <c>format_status/2</c> that returns a term describing the
current status of the gen_fsm.</p>
<p><c>PDict</c> is the current value of the gen_fsm's
process dictionary.</p>
<p><c>StateData</c> is the internal state data of the
gen_fsm.</p>
<p>The function should return <c>Status</c>, a term that
customises the details of the current state and status of
the gen_fsm. There are no restrictions on the
form <c>Status</c> can take, but for
the <c>sys:get_status/1,2</c> case (when <c>Opt</c>
is <c>normal</c>), the recommended form for
the <c>Status</c> value is <c>[{data, [{"StateData",
Term}]}]</c> where <c>Term</c> provides relevant details of
the gen_fsm state data. Following this recommendation isn't
required, but doing so will make the callback module status
consistent with the rest of the <c>sys:get_status/1,2</c>
return value.</p>
<p>One use for this function is to return compact alternative
state data representations to avoid having large state terms
printed in logfiles.</p>
</desc>
</func>
</funcs>
<section>
<title>SEE ALSO</title>
<p><seealso marker="gen_event">gen_event(3)</seealso>,
<seealso marker="gen_server">gen_server(3)</seealso>,
<seealso marker="supervisor">supervisor(3)</seealso>,
<seealso marker="proc_lib">proc_lib(3)</seealso>,
<seealso marker="sys">sys(3)</seealso></p>
</section>
</erlref>
