The pooler application allows you to manage pools of OTP behaviors
such as gen_servers, gen_fsms, or supervisors, and provide consumers
with exclusive access to pool members using pooler:take_member
.
The main pooler interface is pooler:take_member/1
and
pooler:return_member/3
. The pooler server will keep track of which
members are in use and which are free. There is no need to call
pooler:return_member
if the consumer is a short-lived process; in
this case, pooler will detect the consumer’s normal exit and reclaim
the member. To achieve this, pooler tracks the calling process of
take_member
as the consumer of the pool member. Thus pooler assumes
that there is no middle-man process calling take_member
and handing
out the member pid to another worker process.
You specify an initial and a maximum number of members in the pool. Pooler will create new members on demand until the maximum member count is reached. New pool members are added to replace members that crash. If a consumer crashes, the member it was using will be destroyed and replaced. You can configure Pooler to periodically check for and remove members that have not been used recently to reduce the member count back to its initial size.
You can use pooler to manage multiple independent pools and multiple
grouped pools. Independent pools allow you to pool clients for
different backend services (e.g. postgresql and redis). Grouped pools
can optionally be accessed using pooler:take_group_member/1
to
provide load balancing of the pools in the group. A typical use of
grouped pools is to have each pool contain clients connected to a
particular node in a cluster (think database read slaves). Pooler’s
take_group_member
function will randomly select a pool in the group
to fetch a member from. If the randomly selected pool has no free
members, pooler will attempt to obtain a member from each pool in the
group. If there is no pool with available members, pooler will return
error_no_members
.
The need for pooler arose while writing an Erlang-based application
that uses Riak for data storage. Riak’s protocol buffer client is a
gen_server
process that initiates a connection to a Riak node. A
pool is needed to avoid spinning up a new client for each request in
the application. Reusing clients also has the benefit of keeping the
vector clocks smaller since each client ID corresponds to an entry in
the vector clock.
When using the Erlang protocol buffer client for Riak, one should avoid accessing a given client concurrently. This is because each client is associated with a unique client ID that corresponds to an element in an object’s vector clock. Concurrent action from the same client ID defeats the vector clock. For some further explanation, see post 1 and post 2. Note that concurrent access to Riak’s pb client is actual ok as long as you avoid updating the same key at the same time. So the pool needs to have checkout/checkin semantics that give consumers exclusive access to a client.
On top of that, in order to evenly load a Riak cluster and be able to continue in the face of Riak node failures, consumers should spread their requests across clients connected to each node. The client pool provides an easy way to load balance.
Since writing pooler, I’ve seen it used to pool database connections for PostgreSQL, MySQL, and Redis. These uses led to a redesign to better support multiple independent pools.
Pool configuration is specified in the pooler application’s
environment. This can be provided in a config file using -config
or
set at startup using application:set_env(pooler, pools, Pools)
.
Here’s an example config file that creates two pools of
Riak pb clients each talking to a different node in a local cluster
and one pool talking to a Postgresql database:
% pooler.config
% Start Erlang as: erl -config pooler
% -*- mode: erlang -*-
% pooler app config
[
{pooler, [
{pools, [
#{name => rc8081,
group => riak,
max_count => 5,
init_count => 2,
start_mfa =>
{riakc_pb_socket, start_link, ["localhost", 8081]}},
#{name => rc8082,
group => riak,
max_count => 5,
init_count => 2,
start_mfa =>
{riakc_pb_socket, start_link, ["localhost", 8082]}},
#{name => pg_db1,
max_count => 10,
init_count => 2,
start_mfa =>
{my_pg_sql_driver, start_link, ["db_host"]}}
]}
%% if you want to enable metrics, set this to a module with
%% an API conformant to the folsom_metrics module.
%% If this config is missing, then no metrics are sent.
%% {metrics_module, folsom_metrics}
]}
].
Each pool has a unique name, specified as an atom, an initial and maximum number of members,
and an {M, F, A}
describing how to start members of the pool. When
pooler starts, it will create members in each pool according to
init_count
. Optionally, you can indicate that a pool is part of a
group. You can use pooler to load balance across pools labeled with
the same group tag.
The cull_interval
and max_age
pool configuration parameters allow
you to control how (or if) the pool should be returned to its initial
size after a traffic burst. Both parameters specify a time value which
is specified as a tuple with the intended units. The following
examples are valid:
%% two minutes, your way
{2, min}
{120, sec}
{120000, ms}
The cull_interval
determines the schedule when a check will be made
for stale members. Checks are scheduled using erlang:send_after/3
which provides a light-weight timing mechanism. The next check is
scheduled after the prior check completes.
During a check, pool members that have not been used in more than
max_age
minutes will be removed until the pool size reaches
init_count
.
The default value for cull_interval
is {1, min}
. You can disable
culling by specifying a value os {0, min}
. The max_age
parameter
defaults to {30, sec}
.
You can create pools using pooler:new_pool/1
when accepts a
map of pool configuration. Here’s an example:
PoolConfig = #{
name => rc8081,
group => riak,
max_count => 5,
init_count => 2,
start_mfa => {riakc_pb_socket, start_link, ["localhost", 8081]}
},
pooler:new_pool(PoolConfig).
Here’s an example session:
pooler:start().
P = pooler:take_member(mysql),
% use P
pooler:return_member(mysql, P, ok).
Once started, the main interaction you will have with pooler is
through two functions, take_member/1
and return_member/3
(or
return_member/2
).
Call pooler:take_member(Pool)
to obtain the pid belonging to a
member of the pool Pool
. When you are done with it, return it to
the pool using pooler:return_member(Pool, Pid, ok)
. If you
encountered an error using the member, you can pass fail
as the
second argument. In this case, pooler will permanently remove that
member from the pool and start a new member to replace it. If your
process is short lived, you can omit the call to return_member
. In
this case, pooler will detect the normal exit of the consumer and
reclaim the member.
If you would like to obtain a member from a randomly selected pool in
a group, call pooler:take_group_member(Group)
. This will return a
Pid
which must be returned using pooler:return_group_member/2
or
pooler:return_group_member/3
.
In order for pooler to start properly, all applications required to start a pool member must be start before pooler starts. Since pooler does not depend on members and since OTP may parallelize application starts for applications with no detectable dependencies, this can cause problems. One way to work around this is to specify pooler as an included application in your app. This means you will call pooler’s top-level supervisor in your app’s top-level supervisor and can regain control over the application start order. To do this, you would remove pooler from the list of applications in your_app.app and add it to the included_application key:
{application, your_app,
[
{description, "Your App"},
{vsn, "0.1"},
{registered, []},
{applications, [kernel,
stdlib,
crypto,
mod_xyz]},
{included_applications, [pooler]},
{mod, {your_app, []}}
]}.
Then start pooler’s top-level supervisor with something like the following in your app’s top-level supervisor:
PoolerSup = {pooler_sup, {pooler_sup, start_link, []},
permanent, infinity, supervisor, [pooler_sup]},
{ok, {{one_for_one, 5, 10}, [PoolerSup]}}.
You can enable metrics collection by adding a metrics_module
entry
to pooler’s app config. Metrics are disabled by default. The module
specified must have an API matching that of the folsom_metrics module
in folsom (to use folsom, specify {metrics_module, folsom_metrics}}
and ensure that folsom is in your code path and has been started.
When enabled, the following metrics will be tracked:
Metric Label | Description |
pooler.POOL_NAME.take_rate | meter recording rate at which take_member is called |
pooler.error_no_members_count | counter indicating how many times take_member has returned error_no_members |
pooler.killed_free_count | counter how many members have been killed when in the free state |
pooler.killed_in_use_count | counter how many members have been killed when in the in_use state |
pooler.event | history various error conditions |
- Clone the repo:
git clone https://github.com/epgsql/pooler.git
- Build and run tests:
cd pooler; make && make test
- Start a demo
make run Erlang R16B03 (erts-5.10.4) [source] [64-bit] [smp:8:8] [async-threads:10] [kernel-poll:false] Eshell V5.10.4 (abort with ^G) 1> pooler:start(). ok 2> M = pooler:take_member(pool1). <0.44.0> 3> pooled_gs:get_id(M). {"p1",#Ref<0.0.0.38>} 4> M2 = pooler:take_member(pool1). <0.45.0> 5> pooled_gs:get_id(M2). {"p1",#Ref<0.0.0.40>} 6> pooler:return_member(pool1, M, ok). ok 7> pooler:return_member(pool1, M2, ok). ok
The top-level supervisor is pooler_sup. It supervises one supervisor for each pool configured in pooler’s app config.
At startup, a pooler_NAME_pool_sup is started for each pool described in pooler’s app config with NAME matching the name attribute of the config.
The pooler_NAME_pool_sup starts the gen_server that will register with pooler_NAME_pool as well as a pooler_NAME_member_sup that will be used to start and supervise the members of this pool. The pooler_starter_sup is used to start temporary workers used for managing async member start.
pooler_sup: one_for_one pooler_NAME_pool_sup: all_for_one pooler_NAME_member_sup: simple_one_for_one pooler_starter_sup: simple_one_for_one
Groups of pools are managed using the pg
(OTP-23+) or pg2
(OTP below 23) application. This imposes a
requirement to set a configuration parameter on the kernel application
in an OTP release. Like this in sys.config:
% OTP_RELEASE >= 23
{kernel, [{start_pg, true}]}
% OTP_RELEASE < 23
{kernel, [{start_pg2, true}]}
All contributions are welcome!
Pooler uses rebar3 fmt
code formatter. Please make sure to apply make format
before committing any code.
In pooler
we are trying to maintain high test coverage. Run make test
to ensure code coverage does not
fall below a threshold (it is automatically validated).
Pooler is quite critical to performance regressions. We do not run benchmarks in CI, so, to make sure your change does not make pooler slower, please run the benchmarks before and after your changes and make sure there are no major regressions on the most recent OTP release. The workflow is:
$ git checkout master
$ rebar3 bench --save-baseline master # run benchmarks, save results to `master` file
$ git checkout -b <my feature branch>
# <do your code changes>
$ rebar3 bench --baseline master # run benchmarks on updated code, compare results with `master` results
$ git commit ... && git push ...
Please attach the output of rebar3 bench --baseline master
after your changes to the PR description
in order to prove that there were no performance regressions. Please attach the OTP version you run the
benchmarks on.
Pooler is licensed under the Apache License Version 2.0. See the LICENSE file for details.