19972016 Ericsson AB. All Rights Reserved. Licensed under the Apache License, Version 2.0 (the "License"); you may not use this file except in compliance with the License. You may obtain a copy of the License at http://www.apache.org/licenses/LICENSE-2.0 Unless required by applicable law or agreed to in writing, software distributed under the License is distributed on an "AS IS" BASIS, WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. See the License for the specific language governing permissions and limitations under the License. gen_server Behaviour gen_server_concepts.xml

This section is to be read with the gen_server(3) manual page in stdblib, where all interface functions and callback functions are described in detail.

Client-Server Principles

The client-server model is characterized by a central server and an arbitrary number of clients. The client-server model is used for resource management operations, where several different clients want to share a common resource. The server is responsible for managing this resource.

Client-Server Model
Example

An example of a simple server written in plain Erlang is provided in Overview. The server can be reimplemented using gen_server, resulting in this callback module:

-module(ch3). -behaviour(gen_server). -export([start_link/0]). -export([alloc/0, free/1]). -export([init/1, handle_call/3, handle_cast/2]). start_link() -> gen_server:start_link({local, ch3}, ch3, [], []). alloc() -> gen_server:call(ch3, alloc). free(Ch) -> gen_server:cast(ch3, {free, Ch}). init(_Args) -> {ok, channels()}. handle_call(alloc, _From, Chs) -> {Ch, Chs2} = alloc(Chs), {reply, Ch, Chs2}. handle_cast({free, Ch}, Chs) -> Chs2 = free(Ch, Chs), {noreply, Chs2}.

The code is explained in the next sections.

Starting a Gen_Server

In the example in the previous section, gen_server is started by calling ch3:start_link():

start_link() -> gen_server:start_link({local, ch3}, ch3, [], []) => {ok, Pid}

start_link calls function gen_server:start_link/4. This function spawns and links to a new process, a gen_server.

The first argument, {local, ch3}, specifies the name. The gen_server is then locally registered as ch3.

If the name is omitted, the gen_server is not registered. Instead its pid must be used. The name can also be given as {global, Name}, in which case the gen_server is registered using global:register_name/2.

The second argument, ch3, is the name of the callback module, that is, the module where the callback functions are located.

The interface functions (start_link, alloc, and free) are then located in the same module as the callback functions (init, handle_call, and handle_cast). This is normally good programming practice, to have the code corresponding to one process contained in one module.

The third argument, [], is a term that is passed as is to the callback function init. Here, init does not need any indata and ignores the argument.

The fourth argument, [], is a list of options. See the gen_server(3) manual page for available options.

If name registration succeeds, the new gen_server process calls the callback function ch3:init([]). init is expected to return {ok, State}, where State is the internal state of the gen_server. In this case, the state is the available channels.

init(_Args) -> {ok, channels()}.

gen_server:start_link is synchronous. It does not return until the gen_server has been initialized and is ready to receive requests.

gen_server:start_link must be used if the gen_server is part of a supervision tree, that is, started by a supervisor. There is another function, gen_server:start, to start a standalone gen_server, that is, a gen_server that is not part of a supervision tree.

Synchronous Requests - Call

The synchronous request alloc() is implemented using gen_server:call/2:

alloc() -> gen_server:call(ch3, alloc).

ch3 is the name of the gen_server and must agree with the name used to start it. alloc is the actual request.

The request is made into a message and sent to the gen_server. When the request is received, the gen_server calls handle_call(Request, From, State), which is expected to return a tuple {reply,Reply,State1}. Reply is the reply that is to be sent back to the client, and State1 is a new value for the state of the gen_server.

handle_call(alloc, _From, Chs) -> {Ch, Chs2} = alloc(Chs), {reply, Ch, Chs2}.

In this case, the reply is the allocated channel Ch and the new state is the set of remaining available channels Chs2.

Thus, the call ch3:alloc() returns the allocated channel Ch and the gen_server then waits for new requests, now with an updated list of available channels.

Asynchronous Requests - Cast

The asynchronous request free(Ch) is implemented using gen_server:cast/2:

free(Ch) -> gen_server:cast(ch3, {free, Ch}).

ch3 is the name of the gen_server. {free, Ch} is the actual request.

The request is made into a message and sent to the gen_server. cast, and thus free, then returns ok.

When the request is received, the gen_server calls handle_cast(Request, State), which is expected to return a tuple {noreply,State1}. State1 is a new value for the state of the gen_server.

handle_cast({free, Ch}, Chs) -> Chs2 = free(Ch, Chs), {noreply, Chs2}.

In this case, the new state is the updated list of available channels Chs2. The gen_server is now ready for new requests.

Stopping
In a Supervision Tree

If the gen_server is part of a supervision tree, no stop function is needed. The gen_server is automatically terminated by its supervisor. Exactly how this is done is defined by a shutdown strategy set in the supervisor.

If it is necessary to clean up before termination, the shutdown strategy must be a time-out value and the gen_server must be set to trap exit signals in function init. When ordered to shutdown, the gen_server then calls the callback function terminate(shutdown, State):

init(Args) -> ..., process_flag(trap_exit, true), ..., {ok, State}. ... terminate(shutdown, State) -> ..code for cleaning up here.. ok.
Standalone Gen_Servers

If the gen_server is not part of a supervision tree, a stop function can be useful, for example:

... export([stop/0]). ... stop() -> gen_server:cast(ch3, stop). ... handle_cast(stop, State) -> {stop, normal, State}; handle_cast({free, Ch}, State) -> .... ... terminate(normal, State) -> ok.

The callback function handling the stop request returns a tuple {stop,normal,State1}, where normal specifies that it is a normal termination and State1 is a new value for the state of the gen_server. This causes the gen_server to call terminate(normal, State1) and then it terminates gracefully.

Handling Other Messages

If the gen_server is to be able to receive other messages than requests, the callback function handle_info(Info, State) must be implemented to handle them. Examples of other messages are exit messages, if the gen_server is linked to other processes (than the supervisor) and trapping exit signals.

handle_info({'EXIT', Pid, Reason}, State) -> ..code to handle exits here.. {noreply, State1}.

The code_change method must also be implemented.

code_change(OldVsn, State, Extra) -> ..code to convert state (and more) during code change {ok, NewState}.