Getting Started¶
The easiest way to get started is with a working application in Typesafe Activator. The following templates are created by the Slick team, with updated versions being made for new Slick releases:
- To learn the basics of Slick, start with the Hello Slick template. It contains an extended version of the tutorial and code from this page.
- The Slick Plain SQL Queries template shows you how to do SQL queries with Slick.
- The Slick Multi-DB Patterns template shows you how to write Slick applications that can use different database systems and how to use custom database functions in Slick queries.
- The Slick TestKit Example template shows you how to use Slick TestKit to test your own Slick profiles.
There are more Slick templates created by the community, as well as versions of our own templates for other Slick releases. You can find all Slick templates on the Typesafe web site.
Adding Slick to Your Project¶
To include Slick in an existing project use the library published on Maven Central. For sbt projects add the
following to your build definition - build.sbt
or project/Build.scala
:
libraryDependencies ++= Seq( "com.typesafe.slick" %% "slick" % "3.2.0-M1", "org.slf4j" % "slf4j-nop" % "1.6.4", "com.typesafe.slick" %% "slick-hikaricp" % "3.2.0-M1" )
For Maven projects add the following to your <dependencies>
(make sure to use the correct Scala
version prefix, _2.10
or _2.11
, to match your project’s Scala version):
<dependency> <groupId>com.typesafe.slick</groupId> <artifactId>slick_2.10</artifactId> <version>3.2.0-M1</version> </dependency> <dependency> <groupId>org.slf4j</groupId> <artifactId>slf4j-nop</artifactId> <version>1.6.4</version> </dependency>
Slick uses SLF4J for its own debug logging so you also need to add an SLF4J
implementation. Here we are using slf4j-nop
to disable logging. You have
to replace this with a real logging framework like Logback if you want to see
log output.
The Reactive Streams API is pulled in automatically as a transitive dependency.
If you want to use Slick’s connection pool support for HikariCP, you need to add
the slick-hikaricp
module as a dependency as shown above. It will automatically
provide a compatible version of HikariCP as a transitive dependency. Otherwise, you
might need to disable connection pooling or specify a third-party connection pool.
Quick Introduction¶
Note
The rest of this chapter is based on the Hello Slick template. The preferred way of reading this introduction is in Activator, where you can edit and run the code directly while reading the tutorial.
To use Slick you first need to import the API for the database you will be using, like:
// Use H2Profile to connect to an H2 database
import slick.jdbc.H2Profile.api._
import scala.concurrent.ExecutionContext.Implicits.global
Since we are using H2 as our database system, we need to import features
from Slick’s H2Profile
. A profile’s api
object contains all commonly
needed imports from the profile and other parts of Slick such as
database handling.
Slick’s API is fully asynchronous and runs database calls in a separate thread pool. For running
user code in composition of DBIOAction
and Future
values, we import the global
ExecutionContext
. When using Slick as part of a larger application (e.g. with Play or
Akka) the framework may provide a better alternative to this default ExecutionContext
.
Database Configuration¶
In the body of the application we create a Database
object which specifies how to connect to a
database. In most cases you will want to configure database connections with Typesafe Config in
your application.conf
, which is also used by Play and Akka for their configuration:
h2mem1 = {
url = "jdbc:h2:mem:test1"
driver = org.h2.Driver
connectionPool = disabled
keepAliveConnection = true
}
For the purpose of this example we disable the connection pool (there is no point in using one for an embedded in-memory database) and request a keep-alive connection (which ensures that the database does not get dropped while we are using it). The database can be easily instantiated from the configuration like this:
val db = Database.forConfig("h2mem1")
try {
// ...
} finally db.close
Note
A Database
object usually manages a thread pool and a connection pool. You should always
shut it down properly when it is no longer needed (unless the JVM process terminates anyway).
Schema¶
Before we can write Slick queries, we need to describe a database schema with Table
row classes
and TableQuery
values for our tables. You can either use the code generator
to automatically create them for your database schema or you can write them by hand:
// Definition of the SUPPLIERS table
class Suppliers(tag: Tag) extends Table[(Int, String, String, String, String, String)](tag, "SUPPLIERS") {
def id = column[Int]("SUP_ID", O.PrimaryKey) // This is the primary key column
def name = column[String]("SUP_NAME")
def street = column[String]("STREET")
def city = column[String]("CITY")
def state = column[String]("STATE")
def zip = column[String]("ZIP")
// Every table needs a * projection with the same type as the table's type parameter
def * = (id, name, street, city, state, zip)
}
val suppliers = TableQuery[Suppliers]
// Definition of the COFFEES table
class Coffees(tag: Tag) extends Table[(String, Int, Double, Int, Int)](tag, "COFFEES") {
def name = column[String]("COF_NAME", O.PrimaryKey)
def supID = column[Int]("SUP_ID")
def price = column[Double]("PRICE")
def sales = column[Int]("SALES")
def total = column[Int]("TOTAL")
def * = (name, supID, price, sales, total)
// A reified foreign key relation that can be navigated to create a join
def supplier = foreignKey("SUP_FK", supID, suppliers)(_.id)
}
val coffees = TableQuery[Coffees]
All columns get a name (usually in camel case for Scala and upper case with
underscores for SQL) and a Scala type (from which the SQL type can be derived
automatically).
The table object also needs a Scala name, SQL name and type. The type argument
of the table must match the type of the special *
projection. In simple
cases this is a tuple of all columns but more complex mappings are possible.
The foreignKey
definition in the coffees
table ensures that the
supID
field can only contain values for which a corresponding id
exists in the suppliers
table, thus creating an n to one relationship:
A Coffees
row points to exactly one Suppliers
row but any number
of coffees can point to the same supplier. This constraint is enforced at the
database level.
Populating the Database¶
The connection to the embedded H2 database engine provides us with an empty
database. Before we can execute queries, we need to create the database schema
(consisting of the coffees
and suppliers
tables) and insert some test
data:
val setup = DBIO.seq(
// Create the tables, including primary and foreign keys
(suppliers.schema ++ coffees.schema).create,
// Insert some suppliers
suppliers += (101, "Acme, Inc.", "99 Market Street", "Groundsville", "CA", "95199"),
suppliers += ( 49, "Superior Coffee", "1 Party Place", "Mendocino", "CA", "95460"),
suppliers += (150, "The High Ground", "100 Coffee Lane", "Meadows", "CA", "93966"),
// Equivalent SQL code:
// insert into SUPPLIERS(SUP_ID, SUP_NAME, STREET, CITY, STATE, ZIP) values (?,?,?,?,?,?)
// Insert some coffees (using JDBC's batch insert feature, if supported by the DB)
coffees ++= Seq(
("Colombian", 101, 7.99, 0, 0),
("French_Roast", 49, 8.99, 0, 0),
("Espresso", 150, 9.99, 0, 0),
("Colombian_Decaf", 101, 8.99, 0, 0),
("French_Roast_Decaf", 49, 9.99, 0, 0)
)
// Equivalent SQL code:
// insert into COFFEES(COF_NAME, SUP_ID, PRICE, SALES, TOTAL) values (?,?,?,?,?)
)
val setupFuture = db.run(setup)
The TableQuery
‘s schema
method creates DDL
(data definition language) objects
with the database-specific code for creating and dropping tables and other
database entities. Multiple DDL
values can be combined with ++
to
allow all entities to be created and dropped in the correct order, even when
they have circular dependencies on each other.
Inserting the tuples of data is done with the +=
and ++=
methods,
similar to how you add data to mutable Scala collections.
The create
, +=
and ++=
methods return a DBIOAction
which can be executed on a database
at a later time to produce a result. There are several different combinators for combining multiple
DBIOAction``s into sequences, yielding another action. Here we use the simplest one, ``DBIO.seq
, which
can concatenate any number of actions, discarding the return values (i.e. the resulting DBIOAction
produces a result of type Unit
). We then execute the setup action asynchronously with
db.run
, yielding a Future[Unit]
.
Note
Database connections and transactions are managed automatically by Slick. By default
connections are acquired and released on demand and used in auto-commit mode. In this mode we
have to populate the suppliers
table first because the coffees
data can only refer to valid
supplier IDs. We could also use an explicit transaction bracket encompassing all these statements
(db.run(setup.transactionally)
). Then the order would not matter because the constraints are
only enforced at the end when the transaction is committed.
Querying¶
The simplest kind of query iterates over all the data in a table:
// Read all coffees and print them to the console
println("Coffees:")
db.run(coffees.result).map(_.foreach {
case (name, supID, price, sales, total) =>
println(" " + name + "\t" + supID + "\t" + price + "\t" + sales + "\t" + total)
})
// Equivalent SQL code:
// select COF_NAME, SUP_ID, PRICE, SALES, TOTAL from COFFEES
This corresponds to a SELECT * FROM COFFEES
in SQL (except that the *
is the table’s *
projection we defined earlier and not whatever the
database sees as *
). The type of the values we get in the loop is,
unsurprisingly, the type parameter of Coffees
.
Let’s add a projection to this basic query. This is written in Scala with
the map
method or a for comprehension:
// Why not let the database do the string conversion and concatenation?
val q1 = for(c <- coffees)
yield LiteralColumn(" ") ++ c.name ++ "\t" ++ c.supID.asColumnOf[String] ++
"\t" ++ c.price.asColumnOf[String] ++ "\t" ++ c.sales.asColumnOf[String] ++
"\t" ++ c.total.asColumnOf[String]
// The first string constant needs to be lifted manually to a LiteralColumn
// so that the proper ++ operator is found
// Equivalent SQL code:
// select ' ' || COF_NAME || '\t' || SUP_ID || '\t' || PRICE || '\t' SALES || '\t' TOTAL from COFFEES
db.stream(q1.result).foreach(println)
The output will be the same: for each row of the table, all columns get
converted to strings and concatenated into one tab-separated string. The
difference is that all of this now happens inside the database engine, and
only the resulting concatenated string is shipped to the client. Note that we
avoid Scala’s +
operator (which is already heavily overloaded) in favor of
++
(commonly used for sequence concatenation). Also, there is no automatic
conversion of other argument types to strings. This has to be done explicitly
with the type conversion method asColumnOf
.
This time we also use Reactive Streams to get a streaming result from the database and print the elements as they come in instead of materializing the whole result set upfront.
Joining and filtering tables is done the same way as when working with Scala collections:
// Perform a join to retrieve coffee names and supplier names for
// all coffees costing less than $9.00
val q2 = for {
c <- coffees if c.price < 9.0
s <- suppliers if s.id === c.supID
} yield (c.name, s.name)
// Equivalent SQL code:
// select c.COF_NAME, s.SUP_NAME from COFFEES c, SUPPLIERS s where c.PRICE < 9.0 and s.SUP_ID = c.SUP_ID
Warning
Note the use of ===
instead of ==
for comparing two values for equality and =!=
instead of !=
for inequality. This is necessary because these operators are already defined
(with unsuitable types and semantics) on the base type Any
, so they cannot be replaced by
extension methods. The other comparison operators are the same as in standard Scala code:
<
, <=
, >=
, >
.
The generator expression suppliers if s.id === c.supID
follows the
relationship established by the foreign key Coffees.supplier
. Instead of
repeating the join condition here we can use the foreign key directly:
val q3 = for {
c <- coffees if c.price < 9.0
s <- c.supplier
} yield (c.name, s.name)
// Equivalent SQL code:
// select c.COF_NAME, s.SUP_NAME from COFFEES c, SUPPLIERS s where c.PRICE < 9.0 and s.SUP_ID = c.SUP_ID