Hasql provides a robust and concise yet powerful API for communication with arbitrary relational databases using SQL.
Currently the only backend available is for PostgreSQL (which can yield great performance improvements over HDBC or postgresql-simple).
The code used here file is the demo found in the repository
For greater convenience the Hasql has a built-in connection pool. All interactions with the database backend are done within the context of such a pool.
So we have functions to create a pool and one to release all resources held by the pool:
H.acquirePool
:: Hasql.Backend.Cx c =>
Hasql.Backend.CxSettings c -> H.PoolSettings -> IO (H.Pool c)and
H.releasePool :: H.Pool c -> IO ()To create the pool we need to pass the connection settings (which are backend dependent) and the pool settings. The code sample below will open a connection to a PostgreSQL database.
{-# LANGUAGE QuasiQuotes, ScopedTypeVariables, OverloadedStrings #-}
-- Import the API from the "hasql" library
import qualified Hasql as H
-- Import the backend API from the "hasql-postgres" library
import qualified Hasql.Postgres as HP
let postgresSettings = HP.ParamSettings "localhost" 5432 "postgres" "" "postgres"
-- Prepare the pool settings with a smart constructor,
-- which checks the inputted values on correctness.
-- Set the connection pool size to 6 and the timeout to 30 seconds.
poolSettings <- maybe (fail "Improper session settings") return $
H.poolSettings 6 30
-- Acquire the database connections pool.
-- Gotta help the compiler with the type signature of the pool a bit.
pool :: H.Pool HP.Postgres
<- H.acquirePool postgresSettings poolSettingsTo execute statements we will use a Session, which is just a wrapper for the ReaderT monad.
This allow us to use the pool for all our session sub-computations.
So the session function, is a wrapper for the runReaderT, and besides a parameter with the pool,
we need to pass a function with the return type in H.Session monad. And as the return we get
either a SessionError or the result of our function.
The function we will use to actually execute the transactions is the tx
which conveniently enough receives a transaction mode, the transactions we want to execute (along with their session context)
and returns the type H.Session c m r.
It is important to notice that running IO in Tx is prohibited.
let's take a look at the signatures proceding:
H.session
:: H.Pool c -> H.Session c m a -> m (Either (H.SessionError c) a)
H.tx
:: (Control.Monad.Trans.Control.MonadBaseControl IO m,
Hasql.Backend.CxTx c) =>
H.TxMode -> (forall s. H.Tx c s r) -> H.Session c m rThe following code excerpt shows us how the demo code uses these functions to open a session and start a transaction to create a new table:
-- Provide a context for execution of transactions.
-- 'Session' is merely a convenience wrapper around 'ReaderT'.
H.session pool $ do
-- Execute a group of statements without any locking and ACID guarantees:
H.tx Nothing $ do
H.unitEx [H.stmt|DROP TABLE IF EXISTS a|]
H.unitEx [H.stmt|CREATE TABLE a (id SERIAL NOT NULL, balance INT8, PRIMARY KEY (id))|]You have probably noticed that the first parameter of tx belongs to the type TxMode.
This parameter deserves some consideration, for it will determine the behaviour of our transaction.
Let's take a look at its type definition:
type TxMode = Maybe (TxIsolationLevel, TxWriteMode)
data TxIsolationLevel =
RepeatableReads |
Serializable |
ReadCommitted |
ReadUncommitted
type TxWriteMode = Maybe BoolSo when the mode is Nothing, no transaction is explicitly estabilished on the server.
In PostgreSQL's case this means all commands be commited immediatly after execution
and their isolation level will be Read Committed.
If we pass the tuple, the first element will be the transaction isolation level, you can read more about transaction isolation levels on wikipedia.
The second element is the write mode, which will be interpreted as:
Nothingindicates a "read" mode.Just Trueindicates a "write" mode.Just Falseindicates a "write" mode without committing (can be useful for testing purposes).