3. Connecting to a Database
Alright, let’s get going.
In this chapter we start from the beginning. First we write a program that connects to a database and returns a value, and then we run that program in the REPL. We also touch on composing small programs to construct larger ones.
Our First Program
Before we can use doobie we need to import some symbols. We will use the doobie.imports
module here as a convenience; it exposes the most commonly-used symbols when working with the high-level API. We will also import the scalaz core, as well as Task
from scalaz-concurrent.
import doobie.imports._
import scalaz._, Scalaz._
import scalaz.concurrent.Task
In the doobie high level API the most common types we will deal with have the form ConnectionIO[A]
, specifying computations that take place in a context where a java.sql.Connection
is available, ultimately producing a value of type A
.
So let’s start with a ConnectionIO
program that simply returns a constant.
scala> val program1 = 42.point[ConnectionIO]
program1: doobie.imports.ConnectionIO[Int] = Return(42)
This is a perfectly respectable doobie program, but we can’t run it as-is; we need a Connection
first. There are several ways to do this, but here let’s use a Transactor
.
val xa = DriverManagerTransactor[Task](
"org.postgresql.Driver", "jdbc:postgresql:world", "postgres", ""
)
A Transactor
is simply a structure that knows how to connect to a database, hand out connections, and clean them up; and with this knowledge it can transform ConnectionIO ~> Task
, which gives us something we can run. Specifically it gives us a Task
that, when run, will connect to the database and run our program in a single transaction.
The DriverManagerTransactor
simply delegates to the java.sql.DriverManager
to allocate connections, which is fine for development but inefficient for production use. In a later chapter we discuss other approaches for connection management.
Right, so let’s do this.
scala> val task = program1.transact(xa)
task: scalaz.concurrent.Task[Int] = scalaz.concurrent.Task@19f63b41
scala> task.unsafePerformSync
res0: Int = 42
Hooray! We have computed a constant. It’s not very interesting because we never ask the database to perform any work, but it’s a first step.
Keep in mind that all the code in this book is pure except the calls to
Task.unsafePerformSync
, which is the “end of the world” operation that typically appears only at your application’s entry points. In the REPL we use it to force a computation to “happen”.
Right. Now let’s try something more interesting.
Our Second Program
Let’s use the sql
string interpolator to construct a query that asks the database to compute a constant. We will cover this construction in great detail later on, but the meaning of program2
is “run the query, interpret the resultset as a stream of Int
values, and yield its one and only element.”
scala> val program2 = sql"select 42".query[Int].unique
program2: doobie.imports.ConnectionIO[Int] = Gosub(Gosub(Suspend(PrepareStatement4(select 42)),<function1>),<function1>)
scala> val task2 = program2.transact(xa)
task2: scalaz.concurrent.Task[Int] = scalaz.concurrent.Task@6be96fc1
scala> task2.unsafePerformSync
res1: Int = 42
Ok! We have now connected to a database to compute a constant. Considerably more impressive.
Our Third Program
What if we want to do more than one thing in a transaction? Easy! ConnectionIO
is a monad, so we can use a for
comprehension to compose two smaller programs into one larger program.
val program3 =
for {
a <- sql"select 42".query[Int].unique
b <- sql"select random()".query[Double].unique
} yield (a, b)
And behold!
scala> program3.transact(xa).unsafePerformSync
res2: (Int, Double) = (42,0.8670884524472058)
The astute among you will note that we don’t actually need a monad to do this; an applicative functor is all we need here. So we could also write program3
as:
val program3a = {
val a = sql"select 42".query[Int].unique
val b = sql"select random()".query[Double].unique
(a |@| b).tupled
}
And lo, it was good:
scala> program3a.transact(xa).unsafePerformSync
res3: (Int, Double) = (42,0.007854437455534935)
And of course this composition can continue indefinitely.
scala> program3a.replicateM(5).transact(xa).unsafePerformSync.foreach(println)
(42,0.6472118003293872)
(42,0.37534416001290083)
(42,0.6658719899132848)
(42,0.2659648545086384)
(42,0.9221543571911752)
Diving Deeper
You do not need to know this, but if you’re a scalaz user you might find it helpful.
All of the doobie monads are implemented via Free
and have no operational semantics; we can only “run” a doobie program by transforming FooIO
(for some carrier type java.sql.Foo
) to a monad that actually has some meaning.
Out of the box all of the doobie free monads provide a transformation to Kleisli[M, Foo, ?]
given Monad[M]
, Catchable[M]
, and Capture[M]
(we will discuss Capture
shortly, standby). The transK
method gives quick access to this transformation.
scala> val kleisli = program1.transK[Task]
kleisli: scalaz.Kleisli[scalaz.concurrent.Task,java.sql.Connection,Int] = Kleisli(<function1>)
scala> val task = Task.delay(null: java.sql.Connection) >>= kleisli
task: scalaz.concurrent.Task[Int] = scalaz.concurrent.Task@52288573
scala> task.unsafePerformSync // sneaky; program1 never looks at the connection
res5: Int = 42
So the Transactor
above simply knows how to construct a Task[Connection]
, which it can bind through the Kleisli
, yielding our Task[Int]
. There is a bit more going on (we add commit/rollback handling and ensure that the connection is closed in all cases) but fundamentally it’s just a natural transformation and a bind.
In addition to the transK
syntax above, doobie provides natural transformations on each algebra’s module. For example doobie.free.connection
(aliased as FC
in doobie.imports
) provides:
trans[M: Monad: Capture: Catchable](c: Connection): ConnectionIO ~> M
transK[M: Monad: Capture: Catchable]: ConnectionIO ~> Kleisli[M, Connection, ?]
And analogously for other modules in doobie.free
.
The Capture Typeclass
Currently scalaz has no typeclass for monads with effect-capturing unit, so that’s all Capture
does; it’s simply (=> A) => M[A]
that is referentially transparent for all expressions, even those with side-effects. This allows us to sequence the same effect multiple times in the same program. This is exactly the behavior you expect from IO
for example.
doobie provides instances for Task
and IO
, and the implementations are simply delay
and apply
, respectively.
Note that
scala.concurrent.Future
does not have an effect-capturing constructor and thus cannot be used as a target type for doobie programs. AlthoughFuture
is very commonly used for side-effecting operations, doing so is not referentially transparent.Future
has nothing at all to say about side-effects. It is well-behaved in a functional sense only for pure computations.