<?xml version="1.0" encoding="utf-8" ?>
<!DOCTYPE erlref SYSTEM "erlref.dtd">
<erlref>
<header>
<copyright>
<year>2016</year>
<holder>Ericsson AB. All Rights Reserved.</holder>
</copyright>
<legalnotice>
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.
</legalnotice>
<title>gen_statem</title>
<prepared></prepared>
<docno></docno>
<date></date>
<rev></rev>
</header>
<module>gen_statem</module>
<modulesummary>Generic State Machine Behaviour</modulesummary>
<description>
<p>A behaviour module for implementing a state machine.
Two callback modes are supported. One for a finite state
machine like <seealso marker="gen_fsm">gen_fsm</seealso>
that require the state to be an atom and use that state as
the name of the callback function for a particular state,
and one without restriction on the state that use the same
callback function for all states.
</p>
<p>
A generic state machine process (gen_statem) 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:gen_server_concepts">
OTP Design Principles</seealso> for more information.
</p>
<p>A gen_statem 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_statem module Callback module
----------------- ---------------
gen_statem:start
gen_statem:start_link -----> Module:init/1
gen_statem:stop -----> Module:terminate/2
gen_statem:call
gen_statem:cast
erlang:send
erlang:'!' -----> Module:StateName/5
Module:handle_event/5
- -----> Module:terminate/3
- -----> Module:code_change/3</pre>
<p>Events are of different
<seealso marker="#type-event_type">types</seealso>
so the callback functions can know the origin of an event
and how to respond.
</p>
<p>If a callback function fails or returns a bad value,
the gen_statem will terminate. An exception of class
<seealso marker="erts:erlang#throw/1"><c>throw</c></seealso>,
however, is not regarded as an error but as a valid return.
</p>
<marker id="state_function" />
<p>The "<em>state function</em>" for a specific
<seealso marker="#type-state">state</seealso>
in a gen_statem is the callback function that is called
for all events in this state, and is selected depending on
<seealso marker="#type-callback_mode">callback_mode</seealso>
that the implementation selects during gen_statem init.
</p>
<p>When
<seealso marker="#type-callback_mode">callback_mode</seealso>
is <c>state_functions</c> the state has to be an atom and
is used as the state function name.
See
<seealso marker="#Module:StateName/5">
<c>Module:StateName/5</c>
</seealso>.
This naturally collects all code for a specific state
in one function and hence dispatches on state first.
</p>
<p>When
<seealso marker="#type-callback_mode">callback_mode</seealso>
is <c>handle_event_function</c> the state can be any term
and the state function name is
<seealso marker="#Module:handle_event/5">
<c>Module:handle_event/5</c>
</seealso>.
This makes it easy to dispatch on state or on event as
you like but you will have to implement it.
Also be careful about which events you handle in which
states so you do not accidentally postpone one event
forever creating an infinite busy loop.
</p>
<p>Any state name or any state value (depending on
<seealso marker="#type-callback_mode">callback_mode</seealso>)
is permitted with a small gotcha regarding the state
<c>undefined</c> that is used as the previous state when
the first gen_statem state function is called.
You might need to know about this faked state if you
inspect the previous state argument in your state functions.
</p>
<p>The gen_statem enqueues incoming events in order of arrival
and presents these to the
<seealso marker="#state_function">state function</seealso>
in that order. The state function can postpone an event
so it is not retried in the current state.
After a state change all enqueued events (including postponed)
are again presented to the state function.
</p>
<p>The gen_statem event queue model is sufficient to emulate
the normal process message queue and selective receive
with postponing an event corresponding to not matching
it in a receive statement and changing states corresponding
to entering a new receive statement.
</p>
<p>The
<seealso marker="#state_function">state function</seealso>
can insert events using the
<seealso marker="#type-state_operation">
<c>state_operation()</c> <c>next_event</c>
</seealso>
and such an event is inserted as the next to present
to the state function. That is: as if it is
the oldest incoming event. There is a dedicated
<seealso marker="#type-event_type">
<c>event_type()</c> <c>internal</c>
</seealso>
that can be used for such events making it impossible
to mistake for an external event.
</p>
<p>Inserting an event replaces the trick of calling your own
state handling functions that you often would have to
resort to in e.g <seealso marker="gen_fsm">gen_fsm</seealso>
to force processing a faked event before others.
If you for example in gen_statem postpone an event
in one state and then call some other state function of yours,
you have not changed states and hence the postponed event
will not be retried, which is logical but might be confusing.
</p>
<p>A gen_statem handles system messages as documented in
<seealso marker="sys">sys</seealso>.
The <seealso marker="sys">sys</seealso> module
can be used for debugging a gen_statem.
</p>
<p>Note that a gen_statem does not trap exit signals automatically,
this must be explicitly initiated by the callback module.
</p>
<p>Unless otherwise stated, all functions in this module fail if
the specified gen_statem does not exist or if bad arguments are given.
</p>
<p>The gen_statem process can go into hibernation (see
<seealso marker="erts:erlang#hibernate/3">
<c>erlang:hibernate/3</c>
</seealso>) if a
<seealso marker="#state_function">state function</seealso> or
<seealso marker="#Module:init/1"><c>Module:init/1</c></seealso>
specifies <c>'hibernate'</c> in the returned
<seealso marker="#type-state_op"><c>StateOps</c></seealso> list.
This might be useful if the server is expected to be idle
for a long time. However use this feature with care
since hibernation implies at least two garbage collections
(when hibernating and shortly after waking up) and that is not
something you'd want to do between each event on a busy server.
</p>
</description>
<datatypes>
<datatype>
<name name="server_name" />
<desc>
<p>Name specification to use when starting a gen_statem server.
See <seealso marker="#start_link/3">
<c>start_link/3</c>
</seealso> and
<seealso marker="#type-server_ref">
<c>server_ref()</c>
</seealso> below.
</p>
</desc>
</datatype>
<datatype>
<name name="server_ref" />
<desc>
<p>Server specification to use when addressing a gen_statem server.
See <seealso marker="#call/2">call/2</seealso> and
<seealso marker="#type-server_name">
<c>server_name()</c>
</seealso> above.
</p>
<p>It can be:</p>
<list type="bulleted">
<item>the <c>pid()</c>,</item>
<item><c><anno>Name</anno></c>,
if the gen_statem is locally registered,
</item>
<item><c>{<anno>Name</anno>,<anno>Node</anno>}</c>,
if the gen_statem is locally registered at another node, or
</item>
<item><c>{global,<anno>GlobalName</anno>}</c>,
if the gen_statem is globally registered.
</item>
<item><c>{via,<anno>RegMod</anno>,<anno>ViaName</anno>}</c>,
if the gen_statem is registered through
an alternative process registry.
The registry callback module <c>RegMod</c>
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 <seealso marker="kernel:global"><c>global</c></seealso>.
Thus, <c>{via,global,GlobalName}</c> is the same as
<c>{global,GlobalName}</c>.
</item>
</list>
</desc>
</datatype>
<datatype>
<name name="debug_opt" />
<desc>
<p>Debug option that can be used when starting
a gen_statem server through for example
<seealso marker="#enter_loop/4">enter_loop/4</seealso>.
</p>
<p>For every entry in <c><anno>Dbgs</anno></c>
the corresponding function in
<seealso marker="sys"><c>sys</c></seealso> will be called.
</p>
</desc>
</datatype>
<datatype>
<name name="start_opt" />
<desc>
<p>Options that can be used when starting
a gen_statem server through for example
<seealso marker="#start_link/3">start_link/3</seealso>.
</p>
</desc>
</datatype>
<datatype>
<name name="start_ret" />
<desc>
<p>Return value from the start functions for_example
<seealso marker="#start_link/3">start_link/3</seealso>.
</p>
</desc>
</datatype>
<datatype>
<name name="client" />
<desc>
<p>Client address to use when replying through for example the
<seealso marker="#type-state_op">state_op()</seealso>
<c>{reply,Client,Reply}</c> to a client
that has called the gen_statem server using
<seealso marker="#call/2">call/2</seealso>.
</p>
</desc>
</datatype>
<datatype>
<name name="state" />
<desc>
<p>After a state change (<c>NewState =/= State</c>)
all postponed events are retried.
</p>
</desc>
</datatype>
<datatype>
<name name="state_name" />
<desc>
<p>If
<seealso marker="#type-callback_mode">
callback_mode
</seealso> is <c>state_functions</c>, which is the default,
the state has to be of this type i.e an <c>atom()</c>.
</p>
</desc>
</datatype>
<datatype>
<name name="state_data" />
<desc>
<p>A <c>term()</c> in which the state machine implementation
should store any state data it needs. The difference between
this data and the
<seealso marker="#type-state">state()</seealso>
itself is that a change in this data does not cause
postponed events to be retried.
</p>
</desc>
</datatype>
<datatype>
<name name="event_type" />
<desc>
<p>External events are of 3 different type:
<c>{call,<anno>Client</anno>}</c>, <c>cast</c> or <c>info</c>.
Calls (synchronous) and casts (asynchronous)
originate from the corresponding API functions.
For calls the event contain whom to reply to.
Type <c>info</c> originates from normal messages sent
to the gen_statem process.
It is also possible for the state machine
implementation to insert events to itself,
in particular of types
<c>timeout</c> and <c>internal</c>.
</p>
</desc>
</datatype>
<datatype>
<name name="event_predicate" />
<desc>
<p>A <c>fun()</c> of arity 2 that takes an event
and returns a boolean.
When used in <c>{remove_event,RemoveEventPredicate}</c>
from <seealso marker="#type-state_op">state_op()</seealso>.
The event for which the predicate returns <c>true</c> will
be removed.
</p>
<p>
The predicate may <em>not</em> use a throw exception
to return its result.
</p>
</desc>
</datatype>
<datatype>
<name name="init_option" />
<desc>
<p>Option that only is valid when initializing the gen_statem
that is it can be returned from
<seealso marker="#Module:init/1">Module:init/1</seealso>
or given to
<seealso marker="#enter_loop/5">enter_loop/5,6</seealso>.
</p>
</desc>
</datatype>
<datatype>
<name name="callback_mode" />
<desc>
<taglist>
<tag><c>state_functions</c></tag>
<item>The state has to be of type
<seealso marker="#type-state_name"><c>state_name()</c></seealso>
and one callback function per state that is
<seealso marker="#Module:StateName/5">
<c>Module:StateName/5</c>
</seealso> is used. This is the default.
</item>
<tag><c>handle_event_function</c></tag>
<item>The state can be any term and the callback function
<seealso marker="#Module:handle_event/5">
<c>Module:handle_event/5</c>
</seealso> is used for all states.
</item>
</taglist>
</desc>
</datatype>
<datatype>
<name name="state_op" />
<desc>
<p>Either a
<seealso marker="#type-state_option">
<c>state_option()</c>
</seealso> of which the last occurence
in the containing list takes precedence, or a
<seealso marker="#type-state_operation">
<c>state_operation()</c>
</seealso> that are performed in order of
the containing list.
</p>
<p>These may be returned from the
<seealso marker="#state_function">state function</seealso>,
from <seealso marker="#Module:init/1">Module:init/1</seealso>
or given to
<seealso marker="#enter_loop/5">enter_loop/5,6</seealso>.
</p>
<p>The processing order for a state change is:</p>
<list type="ordered">
<item>If the option <c>postpone</c> is <c>true</c>
the current event is postponed.
</item>
<item>If the state changes the queue of incoming events
is reset to start with the oldest postponed.
</item>
<item>All operations are processed in order of appearance.
</item>
<item>The <c>timeout</c> option is processed if present,
so a state timer may be started or a timeout zero event
may be enqueued as the newest incoming.
</item>
<item>The (possibly new)
<seealso marker="#state_function">state function</seealso>
is called with the oldest enqueued event if there is any,
otherwise the gen_statem goes into <c>receive</c>
or hibernation (if the option <c>hibernate</c> is <c>true</c>)
to wait for the next message. In hibernation the next
non-system event awakens the gen_statem, or rather
the next incoming message awakens the gen_statem but if it
is a system event it goes back into hibernation.
</item>
</list>
</desc>
</datatype>
<datatype>
<name name="state_option" />
<desc>
<p>If multiple state options of the same type are present
in the containing list these are set in the list order
and the last value is kept.
</p>
<taglist>
<tag><c>postpone</c></tag>
<tag><c>{postpone,<anno>Postpone</anno>}</c></tag>
<item>If <c><anno>Postpone</anno> =:= true</c>
or plain <c>postpone</c> postpone the current event
to be retried after a state change.
This option is ignored when returned from
<seealso marker="#Module:init/1">Module:init/1</seealso>
or given to
<seealso marker="#enter_loop/5">enter_loop/5,6</seealso>
since there is no event to postpone in those cases.
</item>
<tag><c>hibernate</c></tag>
<tag><c>{hibernate,<anno>Hibernate</anno>}</c></tag>
<item>If <c><anno>Hibernate</anno> =:= true</c>
or plain <c>hibernate</c> hibernate the gen_statem by calling
<seealso marker="proc_lib#hibernate/3">
<c>proc_lib:hibernate/3</c>
</seealso> before <c>receive</c> to wait for a new event.
If there are enqueued events the <c>hibernate</c> operation
is ignored as if an event just arrived and awakened
the gen_statem.
</item>
<tag>
<c>{timeout,<anno>Time</anno>,<anno>Msg</anno>}</c>
</tag>
<item>Generate an event of
<seealso marker="#type-event_type">type <c>timeout</c></seealso>
after <c><anno>Time</anno></c> milliseconds unless some other
event is received before that time. Note that a retried
event counts just like a new in this respect.
If <c>Time =:= infinity</c> or <c>Time =:= 0</c>
no timer is started but for zero time the timeout
event is immediately enqueued as the newest received.
Also note that it is not possible nor needed
to cancel this timeout using the
<seealso marker="#type-state_operation">
<c>state_operation()</c>
</seealso> <c>cancel_timer</c>.
This timeout is cancelled automatically by any event.
</item>
</taglist>
</desc>
</datatype>
<datatype>
<name name="state_operation" />
<desc>
<p>The state operations are executed in the containing
list order. This matters for <c>next_event</c> where
the last one in the list will become the next event to present
to the state functions. Regarding the other operations
it is only for <c>{remove_event,<anno>EventPredicate</anno>}</c>
that the order may matter.
</p>
<taglist>
<tag>
<c>
{next_event,<anno>EventType</anno>,<anno>EventContent</anno>}
</c>
</tag>
<item>Insert the given event as the next to process.
An event of type
<seealso marker="#type-event_type">
<c>internal</c>
</seealso> should be used when you want to reliably distinguish
an event inserted this way from any external event.
</item>
<tag>
<c>
{remove_event,<anno>EventType</anno>,<anno>EventContent</anno>}
</c>
</tag>
<item>Remove the oldest queued event
that matches equal to the given event.
</item>
<tag>
<c>
{remove_event,<anno>EventPredicate</anno>}
</c>
</tag>
<item>Remove the oldest queued event for which
the <c><anno>EventPredicate</anno></c> returns <c>true</c>.
</item>
<tag><c>{cancel_timer,<anno>TimerRef</anno>}</c></tag>
<item>Uses <c><anno>TimerRef</anno></c> when calling
<seealso marker="erts:erlang#cancel_timer/2">
<c>erlang:cancel_timer/2</c>
</seealso> to cancel a timer, cleans the gen_statem's
message queue from any late timeout message from
the timer, and removes any late timeout message
from the queued events using
<c>{remove_event,<anno>EventPredicate</anno>}</c> above.
This is a convenience function that saves quite some
lines of code and testing time over doing it from
the primitives mentioned above.
</item>
<tag><c>{demonitor,<anno>MonitorRef</anno>}</c></tag>
<item>Like <c>{cancel_timer,_}</c> above but for
<seealso marker="erts:erlang#demonitor/2">
<c>demonitor/2</c>
</seealso>.
</item>
<tag><c>{unlink,<anno>Id</anno>}</c></tag>
<item>Like <c>{cancel_timer,_}</c> above but for
<seealso marker="erts:erlang#unlink/1">
<c>unlink/1</c>
</seealso>.
</item>
</taglist>
</desc>
</datatype>
<datatype>
<name name="reply_operation" />
<desc>
<taglist>
<tag>
<c>{reply,<anno>Client</anno>,<anno>Reply</anno>}</c>
</tag>
<item>Reply to a client that called
<seealso marker="#call/2"><c>call/2</c></seealso>.
<c><anno>Client</anno></c> must be the term from the
<seealso marker="#type-event_type">
<c>{call,<anno>Client</anno>}</c>
</seealso> argument to the
<seealso marker="#state_function">state function</seealso>.
</item>
</taglist>
</desc>
</datatype>
<datatype>
<name name="state_callback_result" />
<desc>
<taglist>
<tag>
<c>{stop,<anno>Reason</anno>}</c>
</tag>
<item>The same as
<c>{stop,<anno>Reason</anno>,[],StateData}</c>
but keeps the old <c>StateData</c>.
</item>
<tag>
<c>{stop,<anno>Reason</anno>,<anno>NewStateData</anno>}</c>
</tag>
<item>The same as
<c>{stop,<anno>Reason</anno>,[],<anno>NewStateData</anno>}</c>
</item>
<tag><c>{stop,
<anno>Reason</anno>,
<anno>Replies</anno>,
<anno>NewStateData</anno>}</c>
</tag>
<item>The gen_statem will first send all
<c><anno>Replies</anno></c> and then terminate by calling
<seealso marker="#Module:terminate/3">
<c>Module:terminate/3</c>
</seealso> with <c>Reason</c>.
</item>
<tag>
<c>
{next_state,<anno>StateOps</anno>}
</c>
</tag>
<item>The same as
<c>
{next_state,State,StateData,<anno>StateOps</anno>}
</c>but keeps the old <c>State</c> and <c>StateData</c>.
Believe it or not, but this one has actually
been proven useful to <c>throw/1</c> from deep down
in the state logic.
</item>
<tag>
<c>
{next_state,<anno>NewState</anno>,<anno>NewStateData</anno>}
</c>
</tag>
<item>The same as
<c>
{next_state,<anno>NewState</anno>,<anno>NewStateData</anno>,[]}
</c>
</item>
<tag>
<c>
{next_state,
<anno>NewState</anno>,
<anno>NewStateData</anno>,
<anno>StateOps</anno>}
</c>
</tag>
<item>The gen_statem will do a state transition to
<c><anno>NewState</anno></c>
(which may be the same as <c>State</c>)
and execute all <c>StateOps</c>
</item>
</taglist>
</desc>
</datatype>
</datatypes>
<funcs>
<func>
<name name="start_link" arity="3" />
<name name="start_link" arity="4" />
<fsummary>Create a linked gen_statem process</fsummary>
<desc>
<p>Creates a gen_statem process according to OTP design principles
(using
<seealso marker="proc_lib"><c>proc_lib</c></seealso>
primitives)
that is linked to the calling process.
This is essential when the gen_statem shall be part of
a supervision tree so it gets linked to its supervisor.
</p>
<p>The gen_statem process calls
<seealso marker="#Module:init/1"><c>Module:init/1</c></seealso>
to initialize the server. To ensure a synchronized start-up
procedure, <c>start_link/3,4</c> does not return until
<seealso marker="#Module:init/1"><c>Module:init/1</c></seealso>
has returned.
</p>
<p><c><anno>ServerName</anno></c> specifies the
<seealso marker="#type-server_name">
<c>server_name()</c>
</seealso> to register for the gen_statem.
If the gen_statem is started with <c>start_link/3</c>
no <c><anno>ServerName</anno></c> is provided and
the gen_statem is not registered.
</p>
<p><c><anno>Module</anno></c> is the name of the callback module.</p>
<p><c><anno>Args</anno></c> is an arbitrary term which is passed as
the argument to
<seealso marker="#Module:init/1"><c>Module:init/1</c>
</seealso>.
</p>
<p>If the option <c>{timeout,Time}</c> is present in
<c><anno>Options</anno></c>, the gen_statem is allowed to spend
<c>Time</c> milliseconds initializing or it will be
terminated and the start function will return
<seealso marker="#type-start_ret">
<c>{error,timeout}</c>
</seealso>.
</p>
<p>If the option
<seealso marker="#type-debug_opt"><c>{debug,Dbgs}</c></seealso>
is present in <c><anno>Options</anno></c>, debugging through
<seealso marker="sys"><c>sys</c></seealso> is activated.
</p>
<p>If the option <c>{spawn_opt,SOpts}</c> is present in
<c><anno>Options</anno></c>, <c>SOpts</c> will be passed
as option list to the <c>spawn_opt</c> BIF
which is used to
<seealso marker="erts:erlang#spawn_opt/2">spawn</seealso>
the gen_statem.
</p>
<note>
<p>Using the spawn option <c>monitor</c> is currently not
allowed, but will cause this function to fail with reason
<c>badarg</c>.</p>
</note>
<p>If the gen_statem is successfully created and initialized
this function returns
<seealso marker="#type-start_ret">
<c>{ok,Pid}</c>,
</seealso> where <c>Pid</c> is the <c>pid()</c> of the gen_statem.
If there already exists a process with the specified
<c><anno>ServerName</anno></c> this function returns
<seealso marker="#type-start_ret">
<c>{error,{already_started,Pid}}</c>
</seealso>, where <c>Pid</c> is the <c>pid()</c> of that process.
</p>
<p>If <c>Module:init/1</c> fails with <c>Reason</c>,
this function returns
<seealso marker="#type-start_ret">
<c>{error,Reason}</c>
</seealso>. If <c>Module:init/1</c> returns
<seealso marker="#type-start_ret">
<c>{stop,Reason}</c>
</seealso>
or
<seealso marker="#type-start_ret">
<c>ignore</c>
</seealso>, the process is terminated and this function
returns
<seealso marker="#type-start_ret">
<c>{error,Reason}</c>
</seealso> or
<seealso marker="#type-start_ret">
<c>ignore</c>
</seealso>, respectively.
</p>
</desc>
</func>
<func>
<name name="start" arity="3" />
<name name="start" arity="4" />
<fsummary>Create a stand-alone gen_statem process</fsummary>
<desc>
<p>Creates a stand-alone gen_statem process according to
OTP design principles (using
<seealso marker="proc_lib"><c>proc_lib</c></seealso>
primitives).
Since it does not get linked to the calling process
this start function can not be used by a supervisor
to start a child.
</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 name="stop" arity="1" />
<fsummary>Synchronously stop a generic server</fsummary>
<desc>
<p>The same as
<seealso marker="#stop/3">
<c>stop(<anno>ServerRef</anno>, normal, infinity)</c>
</seealso>.
</p>
</desc>
</func>
<func>
<name name="stop" arity="3" />
<fsummary>Synchronously stop a generic server</fsummary>
<desc>
<p>Orders the gen_statem
<seealso marker="#type-server_ref">
<c><anno>ServerRef</anno></c>
</seealso> to exit with the given <c><anno>Reason</anno></c>
and waits for it to terminate.
The gen_statem will call
<seealso marker="#Module:terminate/3">
Module:terminate/3
</seealso> before exiting.
</p>
<p>This function returns <c>ok</c> if the server terminates
with the expected reason. Any other reason than <c>normal</c>,
<c>shutdown</c>, or <c>{shutdown,Term}</c> will cause an
error report to be issued through
<seealso marker="kernel:error_logger#format/2">
error_logger:format/2
</seealso>.
The default <c><anno>Reason</anno></c> is <c>normal</c>.
</p>
<p><c><anno>Timeout</anno></c> is an integer greater than zero
which specifies how many milliseconds to wait for the server to
terminate, or the atom <c>infinity</c> to wait indefinitely.
The default value is <c>infinity</c>.
If the server has not terminated within the specified time,
a <c>timeout</c> exception is raised.
</p>
<p>If the process does not exist, a <c>noproc</c> exception
is raised.
</p>
</desc>
</func>
<func>
<name name="call" arity="2" />
<name name="call" arity="3" />
<fsummary>Make a synchronous call to a gen_statem</fsummary>
<desc>
<p>Makes a synchronous call to the gen_statem
<seealso marker="#type-server_ref">
<c><anno>ServerRef</anno></c>
</seealso> by sending a request
and waiting until its reply arrives.
The gen_statem will call the
<seealso marker="#state_function">state function</seealso> with
<seealso marker="#type-event_type"><c>event_type()</c></seealso>
<c>{call,Client}</c> and event content
<c><anno>Request</anno></c>.
</p>
<p>A <c><anno>Reply</anno></c> is generated when a
<seealso marker="#state_function">state function</seealso>
returns with
<c>{reply,Client,<anno>Reply</anno>}</c> as one
<seealso marker="#type-state_op"><c>state_op()</c></seealso>,
and that <c><anno>Reply</anno></c> becomes the return value
of this function.
</p>
<p><c><anno>Timeout</anno></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,
which is the default. If no reply is received within
the specified time, the function call fails.
<note>
<p>To avoid getting a late reply in the caller's
inbox this function spawns a proxy process that
does the call. A late reply gets delivered to the
dead proxy process hence gets discarded. This is
less efficient than using
<c><anno>Timeout</anno> =:= infinity</c>.
</p>
</note>
</p>
<p>The call may fail for example if the gen_statem dies
before or during this function call.
</p>
</desc>
</func>
<func>
<name name="cast" arity="2" />
<fsummary>Send an asynchronous event to a gen_statem</fsummary>
<desc>
<p>Sends an asynchronous event to the gen_statem
<seealso marker="#type-server_ref">
<c><anno>ServerRef</anno></c>
</seealso> and returns <c>ok</c> immediately,
ignoring if the destination node or gen_statem does not exist.
The gen_statem will call the
<seealso marker="#state_function">state function</seealso> with
<seealso marker="#type-event_type"><c>event_type()</c></seealso>
<c>cast</c> and event content
<c><anno>Msg</anno></c>.
</p>
</desc>
</func>
<func>
<name name="reply" arity="1" />
<name name="reply" arity="2" />
<fsummary>Send a reply to a client</fsummary>
<desc>
<p>This function can be used by a gen_statem to explicitly send
a reply to a client that called
<seealso marker="#call/2"><c>call/2</c></seealso>
when the reply cannot be defined in
the return value of the
<seealso marker="#state_function">state function</seealso>.
</p>
<p><c><anno>Client</anno></c> must be the term from the
<seealso marker="#type-event_type">
<c>{call,<anno>Client</anno>}</c>
</seealso> argument to the
<seealso marker="#state_function">state function</seealso>.
<c><anno>Client</anno></c> and <c><anno>Reply</anno></c>
an also be specified using <c><anno>ReplyOperation</anno></c>.
</p>
<note>
<p>A reply sent with this function will not be visible
in <seealso marker="sys">sys</seealso> debug output.
</p>
</note>
</desc>
</func>
<func>
<name name="enter_loop" arity="4" />
<fsummary>Enter the gen_statem receive loop</fsummary>
<desc>
<p>The same as
<seealso marker="#enter_loop/6"><c>enter_loop/6</c></seealso>
except that no
<seealso marker="#type-server_name">
<c>server_name()</c>
</seealso> must have been registered.
</p>
</desc>
</func>
<func>
<name name="enter_loop" arity="5" />
<fsummary>Enter the gen_statem receive loop</fsummary>
<desc>
<p>If <c><anno>Server_or_StateOps</anno></c> is a <c>list()</c>
the same as
<seealso marker="#enter_loop/6"><c>enter_loop/6</c></seealso>
except that no
<seealso marker="#type-server_name">
<c>server_name()</c>
</seealso> must have been registered and
<c>StateOps = <anno>Server_or_StateOps</anno></c>.
</p>
<p>Otherwise the same as
<seealso marker="#enter_loop/6"><c>enter_loop/6</c></seealso>
with
<c>Server = <anno>Server_or_StateOps</anno></c> and
<c>StateOps = []</c>.
</p>
</desc>
</func>
<func>
<name name="enter_loop" arity="6" />
<fsummary>Enter the gen_statem receive loop</fsummary>
<desc>
<p>Makes an the calling process become a gen_statem. Does not return,
instead the calling process will enter the gen_statem receive
loop and become a gen_statem server. The process
<em>must</em> have been started using one of the start
functions in
<seealso marker="proc_lib"><c>proc_lib</c></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_statem behaviour provides.
</p>
<p><c><anno>Module</anno></c>, <c><anno>Options</anno></c> and
<c><anno>Server</anno></c> have the same meanings
as when calling
<seealso marker="#start_link/3">
gen_statem:start[_link]/3,4
</seealso>.
However, the
<seealso marker="#type-server_name">
<c>server_name()</c>
</seealso> name must have been registered accordingly
<em>before</em> this function is called.</p>
<p><c><anno>State</anno></c>, <c><anno>StateData</anno></c>
and <c><anno>StateOps</anno></c>
have the same meanings as in the return value of
<seealso marker="#Module:init/1">Module:init/1</seealso>.
Also, the callback module <c><anno>Module</anno></c>
does not need to export an <c>init/1</c> function.
</p>
<p>Failure: If the calling process was not started by a
<seealso marker="proc_lib"><c>proc_lib</c></seealso>
start function, or if it is not registered
according to
<seealso marker="#type-server_name">
<c>server_name()</c>
</seealso>.
</p>
</desc>
</func>
</funcs>
<section>
<title>CALLBACK FUNCTIONS</title>
<p>The following functions should be exported from a
<c>gen_statem</c> callback module.
</p>
</section>
<funcs>
<func>
<name>Module:init(Args) -> Result</name>
<fsummary>Initialize process and internal state</fsummary>
<type>
<v>Args = term()</v>
<v>Result = {ok,State,StateData}</v>
<v> | {ok,State,StateData,StateOps}</v>
<v> | {stop,Reason} | ignore</v>
<v>State = <seealso marker="#type-state">state()</seealso></v>
<v>StateData =
<seealso marker="#type-state_data">state_data()</seealso>
</v>
<v>StateOps =
[<seealso marker="#type-state_op">state_op()</seealso>
| <seealso marker="#type-init_option">init_option()</seealso>]
</v>
<v>Reason = term()</v>
</type>
<desc>
<marker id="Module:init-1" />
<p>Whenever a gen_statem is started using
<seealso marker="#start_link/3">gen_statem:start_link/3,4</seealso>
or
<seealso marker="#start/3">gen_statem:start/3,4</seealso>,
this function is called by the new process to initialize
the implementation loop data.
</p>
<p><c>Args</c> is the <c>Args</c> argument provided to the start
function.</p>
<p>If the initialization is successful, the function should
return <c>{ok,State,StateData}</c> or
<c>{ok,State,StateData,StateOps}</c>.
<c>State</c> is the <seealso marker="#type-state">state</seealso>
of the gen_statem.
</p>
<p>The <seealso marker="#type-state_op"><c>StateOps</c></seealso>
are executed when entering the first
<seealso marker="#type-state">state</seealso> just as for a
<seealso marker="#state_function">state function</seealso>.
</p>
<p>This function allows an option to select the callback mode
of the gen_statem. See
<seealso marker="#type-init_option">init_option</seealso>.
This option is not allowed from the state function(s).
</p>
<p>If something goes wrong during the initialization
the function should return <c>{stop,Reason}</c>
or <c>ignore</c>. See
<seealso marker="#start_link/3">gen_statem:start_link/3,4</seealso>.
</p>
</desc>
</func>
<func>
<name>Module:StateName(EventType, EventContent,
PrevStateName, StateName, StateData) -> Result
</name>
<name>Module:handle_event(EventType, EventContent,
PrevState, State, StateData) -> Result
</name>
<fsummary>Handle an event</fsummary>
<type>
<v>EventType =
<seealso marker="#type-event_type">event_type()</seealso>
</v>
<v>EventContent = term()</v>
<v>PrevStateName =
<seealso marker="#type-state_name">state_name()</seealso>
</v>
<v>StateName =
<seealso marker="#type-state_name">state_name()</seealso>
</v>
<v>PrevState = State =
<seealso marker="#type-state">state()</seealso>
</v>
<v>StateData = NewStateData =
<seealso marker="#type-state_data">state_data()</seealso>
</v>
<v>Result =
<seealso marker="#type-state_callback_result">
state_callback_result()
</seealso>
</v>
</type>
<desc>
<p>Whenever a gen_statem receives an event from
<seealso marker="#call/2">gen_statem:call/2</seealso>,
<seealso marker="#cast/2">gen_statem:cast/2</seealso> or
as a normal process message this function is called.
If
<seealso marker="#type-callback_mode">callback_mode</seealso>
is <c>state_functions</c> then <c>Module:StateName/5</c> is called,
and if it is <c>handle_event_function</c>
then <c>Module:handle_event/5</c> is called.
</p>
<p>If <c>EventType</c> is
<seealso marker="#type-event_type"><c>{call,Client}</c></seealso>
the client is waiting for a reply. The reply can be sent
from this or from any other
<seealso marker="#state_function">state function</seealso>
by returning with <c>{reply,Client,Reply}</c> in
<seealso marker="#type-state_op">StateOps</seealso>, in
<seealso marker="#type-reply_operation">Replies</seealso>
or by calling
<seealso marker="#reply/2">
<c>gen_statem:reply(Client, Reply)</c>
</seealso>.
</p>
<p><c>StateName</c> is useful in some odd cases for example
if you call a common event handling function from your state
function then you might want to pass <c>StateName</c>.
</p>
<p><c>PrevStateName</c> and <c>PrevState</c> are useful
in some odd cases for example when you want to do something
only at the first event in a state.
Note that when gen_statem enters its first state
this is set to <c>undefined</c>.
</p>
<p>If this function returns with a new state that
does not match equal (<c>=/=</c>) to the current state
all postponed events will be retried in the new state.
</p>
<p>See <seealso marker="#type-state_op">state_op()</seealso>
for options that can be set and operations that can be done
by gen_statem after returning from this function.
</p>
</desc>
</func>
<func>
<name>Module:terminate(Reason, State, StateData) -> Ignored</name>
<fsummary>Clean up before termination</fsummary>
<type>
<v>Reason = normal | shutdown | {shutdown,term()} | term()</v>
<v>State = <seealso marker="#type-state">state()</seealso></v>
<v>StateData =
<seealso marker="#type-state_data">
state_data()
</seealso>
</v>
<v>Ignored = term()</v>
</type>
<desc>
<p>This function is called by a gen_statem when it is about to
terminate. It should be the opposite of
<seealso marker="#Module:init/1"><c>Module:init/1</c></seealso>
and do any necessary cleaning up. When it returns,
the gen_statem terminates with <c>Reason</c>. The return
value is ignored.</p>
<p><c>Reason</c> is a term denoting the stop reason and
<seealso marker="#type-state">State</seealso>
is the internal state of the gen_statem.
</p>
<p><c>Reason</c> depends on why the gen_statem is terminating.
If it is because another callback function has returned a
stop tuple <c>{stop,Reason}</c> in
<seealso marker="#type-state_op">StateOps</seealso>,
<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_statem 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_statem 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_statem 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_statem 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_statem 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, OldState, OldStateData, Extra) ->
Result
</name>
<fsummary>Update the internal state during upgrade/downgrade</fsummary>
<type>
<v>OldVsn = Vsn | {down,Vsn}</v>
<v> Vsn = term()</v>
<v>OldState = NewState = term()</v>
<v>Extra = term()</v>
<v>Result = {ok,{NewState,NewStateData}} | Reason</v>
<v>OldState = NewState =
<seealso marker="#type-state">state()</seealso>
</v>
<v>OldStateData = NewStateData =
<seealso marker="#type-state_data">state_data()</seealso>
</v>
<v>Reason = term()</v>
</type>
<desc>
<p>This function is called by a gen_statem when it should
update its internal state 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>
for more information.
</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>OldState</c> and <c>OldStateData</c> is the internal state
of the gen_statem.
</p>
<p><c>Extra</c> is passed as-is from the <c>{advanced,Extra}</c>
part of the update instruction.
</p>
<p>If successful, the function shall return the updated
internal state in an
<c>{ok,{NewState,NewStateData}}</c> tuple.
</p>
<p>If the function returns <c>Reason</c>, the ongoing
upgrade will fail and roll back to the old release.</p>
</desc>
</func>
<func>
<name>Module:format_status(Opt, [PDict,State,StateData]) ->
Status
</name>
<fsummary>Optional function for providing a term describing the
current gen_statem status</fsummary>
<type>
<v>Opt = normal | terminate</v>
<v>PDict = [{Key, Value}]</v>
<v>State =
<seealso marker="#type-state">state()</seealso>
</v>
<v>StateData =
<seealso marker="#type-state_data">state_data()</seealso>
</v>
<v>Key = term()</v>
<v>Value = term()</v>
<v>Status = term()</v>
</type>
<desc>
<note>
<p>This callback is optional, so callback modules need not
export it. The gen_statem module provides a default
implementation of this function that returns the callback
module state.
</p>
</note>
<p>This function is called by a gen_statem process when:</p>
<list type="bulleted">
<item>One of
<seealso marker="sys#get_status/1">
<c>sys:get_status/1,2</c>
</seealso>
is invoked to get the gen_statem status. <c>Opt</c> is set
to the atom <c>normal</c> for this case.
</item>
<item>The gen_statem 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_statem status for these cases. A
callback module wishing to customise the
<seealso marker="sys#get_status/1">
<c>sys:get_status/1,2</c>
</seealso> 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_statem.
</p>
<p><c>PDict</c> is the current value of the gen_statem's
process dictionary.
</p>
<p><seealso marker="#type-state"><c>State</c></seealso>
is the internal state of the gen_statem.
</p>
<p>The function should return <c>Status</c>, a term that
customises the details of the current state and status of
the gen_statem. There are no restrictions on the
form <c>Status</c> can take, but for the
<seealso marker="sys#get_status/1">
<c>sys:get_status/1,2</c>
</seealso> case (when <c>Opt</c>
is <c>normal</c>), the recommended form for
the <c>Status</c> value is <c>[{data, [{"State",
Term}]}]</c> where <c>Term</c> provides relevant details of
the gen_statem state. Following this recommendation isn't
required, but doing so will make the callback module status
consistent with the rest of the
<seealso marker="sys#get_status/1">
<c>sys:get_status/1,2</c>
</seealso> return value.
</p>
<p>One use for this function is to return compact alternative
state 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</seealso>,
<seealso marker="gen_fsm">gen_fsm</seealso>,
<seealso marker="gen_server">gen_server</seealso>,
<seealso marker="supervisor">supervisor</seealso>,
<seealso marker="proc_lib">proc_lib</seealso>,
<seealso marker="sys">sys</seealso></p>
</section>
</erlref>