Connection pool is a family of specialised resource pools. Currently package provides two
- pool for TCP client connections,
- and pool for UNIX Sockets client connections.
In addition it can be used to build your own connection pool using provided primitives.
This package is built on top of resource-pool and streaming-commons. The later allows us to use conduit-extra package for implementation of TCP or UNIX Sockets clients.
Stable releases with API documentation are available on Hackage
Simple code examples, including example from the following section, are available in example/ directory.
Here is a simple example that demonstrates how TCP client can be created and how connection pool behaves.
{-# LANGUAGE OverloadedStrings #-}
module Main (main)
where
import Control.Concurrent
( forkIO
, newEmptyMVar
, putMVar
, readMVar
, threadDelay
)
import Control.Monad (void, mapM_)
import System.Environment (getArgs)
import Control.Lens ((.~), (&))
import Data.ConnectionPool
( createTcpClientPool
, numberOfResourcesPerStripe
, numberOfStripes
, withTcpClientConnection
)
import Data.Default.Class (Default(def))
import Data.Streaming.Network (appWrite, clientSettingsTCP)
main :: IO ()
main = do
[port, numStripes, numPerStripe] <- getArgs
pool <- createTcpClientPool
(poolParams numStripes numPerStripe)
(clientSettingsTCP (read port) "127.0.0.1")
thread1 <- newEmptyMVar
thread2 <- newEmptyMVar
void . forkIO . withTcpClientConnection pool $ \appData -> do
threadDelay 1000
appWrite appData "1: I'm alive!\n"
putMVar thread1 ()
void . forkIO . withTcpClientConnection pool $ \appData -> do
appWrite appData "2: I'm alive!\n"
putMVar thread2 ()
mapM_ readMVar [thread1, thread2]
where
poolParams m n =
def & numberOfStripes .~ read m
& numberOfResourcesPerStripe .~ read n
To test it we can use socat
or some netcat
like application. Our test will
require two terminals, in one we will execute socat
as a server listenting on
UNIX socket and in the other one we execute above example.
Simple TCP server listening on port 8001
that prints what it receives to
stdout:
$ socat TCP4-LISTEN:8001,bind=127.0.0.1,fork -
The fork
parameter in the above example is important, otherwise socat
would
terminate when client closes its connection.
If we run above example as:
$ runghc tcp-example.hs 8001 1 1
We can see that socat
received following text:
1: I'm alive!
2: I'm alive!
But if we increment number of stripes or number of connections (resources) per stripe, then we will get:
2: I'm alive!
1: I'm alive!
The reason for this is that we use threadDelay 1000
in the first executed
thread. So when we have only one stripe and one connection per stripe, then we
have only one connection in the pool. Therefore when the first thread executes
and acquires a connection, then all the other threads (the other one in above
example) will block. If we have more then one connection available in our pool,
then the first thread acquires connection, blocks on threadDelay
call, but
the other thread also acquires connection and prints its output while the first
thread is still blocked on threadDelay
. This example demonstrates how
connection pool behaves if it reached its capacity and when it has enough free
resources.
The BSD 3-Clause License, see LICENSE file for details.
Contributions, pull requests and bug reports are welcome! Please don't be
afraid to contact author using GitHub or by e-mail (see .cabal
file for
that).