Question

In the spirit of:

• Hidden Features of C#
• Hidden Features of Java
• Hidden Features of ASP.NET
• Hidden Features of Python
• Hidden Features of HTML
• and other Hidden Features questions

What are the hidden features of Scala that every Scala developer should be aware of?

One hidden feature per answer, please.

Answer 1

Manifests which are a sort of way at getting the type information at runtime, as if Scala had reified types.

Answer 2

Extractors which allow you to replace messy if-elseif-else style code with patterns. I know that these are not exactly hidden but I've been using Scala for a few months without really understanding the power of them. For (a long) example I can replace:

val code: String = ...
val ps: ProductService = ...
var p: Product = null
if (code.endsWith("=") {
  p = ps.findCash(code.substring(0, 3)) //e.g. USD=, GBP= etc
}
else if (code.endsWith(".FWD")) {
  //e.g. GBP20090625.FWD
  p = ps.findForward(code.substring(0,3), code.substring(3, 9))
}
else {
  p = ps.lookupProductByRic(code)
}

With this, which is much clearer in my opinion

implicit val ps: ProductService = ...
val p = code match {
  case SyntheticCodes.Cash(c) => c
  case SyntheticCodes.Forward(f) => f
  case _ => ps.lookupProductByRic(code)
}

I have to do a bit of legwork in the background...

object SyntheticCodes {
  // Synthetic Code for a CashProduct
  object Cash extends (CashProduct => String) {
    def apply(p: CashProduct) = p.currency.name + "="

    //EXTRACTOR
    def unapply(s: String)(implicit ps: ProductService): Option[CashProduct] = {
      if (s.endsWith("=") 
        Some(ps.findCash(s.substring(0,3))) 
      else None
    }
  }
  //Synthetic Code for a ForwardProduct
  object Forward extends (ForwardProduct => String) {
    def apply(p: ForwardProduct) = p.currency.name + p.date.toString + ".FWD"

    //EXTRACTOR
    def unapply(s: String)(implicit ps: ProductService): Option[ForwardProduct] = {
      if (s.endsWith(".FWD") 
        Some(ps.findForward(s.substring(0,3), s.substring(3, 9)) 
      else None
    }
  }

But the legwork is worth it for the fact that it separates a piece of business logic into a sensible place. I can implement my Product.getCode methods as follows..

class CashProduct {
  def getCode = SyntheticCodes.Cash(this)
}

class ForwardProduct {
  def getCode = SyntheticCodes.Forward(this)     
}

Answer 3

Maybe not too hidden, but I think this is useful:

@scala.reflect.BeanProperty
var firstName:String = _

This will automatically generate a getter and setter for the field that matches bean convention.

Further description at developerworks

Answer 4

You can designate a lazy parameter to a function and it will not be evaluated until used by the function. See this faq for details

class Bar(i:Int) {
    println("constructing bar " + i)
    override def toString():String = {
    	"bar with value: " + i
    }
}

// NOTE the => in the method declaration.  It indicates a lazy paramter
def foo(x: => Bar) = {
    println("foo called")
    println("bar: " + x)
}


foo(new Bar(22))

/*
prints the following:
foo called
constructing bar 22
bar with value: 22
*/

Answer 5

Implicit anonymous function.

It is now possible to define anonymous functions using underscores in parameter position. For instance, the expressions in the left column are each function values which expand to the anonymous functions on their right.

_ + 1                  x => x + 1
_ * _                  (x1, x2) => x1 * x2
(_: int) * 2           (x: int) => (x: int) * 2
if (_) x else y        z => if (z) x else y
_.map(f)               x => x.map(f)
_.map(_ + 1)           x => x.map(y => y + 1)

Using this you could do something like:

def filesEnding(query: String) =
  filesMatching(_.endsWith(query))

Answer 6

Structural type definitions - i.e. a type described by what methods it supports. For example:

object Closer {
    def using(closeable: { def close(): Unit }, f: => Unit) {
      try { 
        f
      } finally { closeable.close }
    }
}

Notice that the type of the parameter closeable is not defined other than it has a close method

Answer 7

Implicit definitions, particularly conversions.

For example, assume a function which will format an input string to fit to a size, by replacing the middle of it with "...":

def sizeBoundedString(s: String, n: Int): String = {
  if (n < 5 && n < s.length) throw new IllegalArgumentException
  if (s.length > n) {
    val trailLength = ((n - 3) / 2) min 3
    val headLength = n - 3 - trailLength
    s.substring(0, headLength)+"..."+s.substring(s.length - trailLength, s.length)
  } else s
}

You can use that with any String, and, of course, use the toString method to convert anything. But you could also write it like this:

def sizeBoundedString[T](s: T, n: Int)(implicit toStr: T => String): String = {
  if (n < 5 && n < s.length) throw new IllegalArgumentException
  if (s.length > n) {
    val trailLength = ((n - 3) / 2) min 3
    val headLength = n - 3 - trailLength
    s.substring(0, headLength)+"..."+s.substring(s.length - trailLength, s.length)
  } else s
}

And then, you could pass classes of other types by doing this:

implicit def double2String(d: Double) = d.toString

Now you can call that function passing a double:

sizeBoundedString(12345.12345D, 8)

The last argument is implicit, and is being passed automatically because of the implicit de declaration. Furthermore, "s" is being treated like a String inside sizeBoundedString because there is an implicit conversion from it to String.

Implicits of this type are better defined for uncommon types to avoid unexpected conversions. You can also explictly pass a conversion, and it will still be implicitly used inside sizeBoundedString:

sizeBoundedString(1234567890L, 8)((l : Long) => l.toString)

You can also have multiple implicit arguments, but then you must either pass all of them, or not pass any of them. There is also a shortcut syntax for implicit conversions:

def sizeBoundedString[T <% String](s: T, n: Int): String = {
  if (n < 5 && n < s.length) throw new IllegalArgumentException
  if (s.length > n) {
    val trailLength = ((n - 3) / 2) min 3
    val headLength = n - 3 - trailLength
    s.substring(0, headLength)+"..."+s.substring(s.length - trailLength, s.length)
  } else s
}

This is used exactly the same way.

Implicits can have any value. They can be used, for instance, to hide library information. Take the following example, for instance:

case class Daemon(name: String) {
  def log(msg: String) = println(name+": "+msg)
}

object DefaultDaemon extends Daemon("Default")

trait Logger {
  private var logd: Option[Daemon] = None
  implicit def daemon: Daemon = logd getOrElse DefaultDaemon

  def logTo(daemon: Daemon) = 
    if (logd == None) logd = Some(daemon) 
    else throw new IllegalArgumentException

  def log(msg: String)(implicit daemon: Daemon) = daemon.log(msg)
}

class X extends Logger {
  logTo(Daemon("X Daemon"))

  def f = {
    log("f called")
    println("Stuff")
  }

  def g = {
    log("g called")(DefaultDaemon)
  }
}

class Y extends Logger {
  def f = {
    log("f called")
    println("Stuff")
  }
}

In this example, calling "f" in an Y object will send the log to the default daemon, and on an instance of X to the Daemon X daemon. But calling g on an instance of X will send the log to the explicitly given DefaultDaemon.

While this simple example can be re-written with overload and private state, implicits do not require private state, and can be brought into context with imports.

Answer 8

Type-Constructor Polymorphism (a.k.a. higher-kinded types)

Without this feature you can, for example, express the idea of mapping a function over a list to return another list, or mapping a function over a tree to return another tree. But you can't express this idea generally without higher kinds.

With higher kinds, you can capture the idea of any type that's parameterised with another type. A type constructor that takes one parameter is said to be of kind (*->*). For example, List. A type constructor that returns another type constructor is said to be of kind (*->*->*). For example, Function1. But in Scala, we have higher kinds, so we can have type constructors that are parameterised with other type constructors. So they're of kinds like ((*->*)->*).

For example:

trait Functor[F[_]] {
  def fmap[A, B](f: A => B, fa: F[A]): F[B]
}

Now, if you have a Functor[List], you can map over lists. If you have a Functor[Tree], you can map over trees. But more importantly, if you have Functor[A] for any A of kind (*->*), you can map a function over A.

Answer 9

You can define your own control structures. It's really just functions and objects and some syntactic sugar, but they look and behave like the real thing.

For example, the following code defines dont {...} uness (cond) and dont {...} until (cond):

def dont(code: => Unit) = new DontCommand(code)

class DontCommand(code: => Unit) {
  def unless(condition: => Boolean) =
    if (condition) code

  def until(condition: => Boolean) = {
    while (!condition) {}
    code
  }
}

Now you can do the following:

/* This will only get executed if the condition is true */
dont {
  println("Yep, 2 really is greater than 1.")
} unless (2 > 1) 

/* Just a helper function */
var number = 0;
def nextNumber() = {
  number += 1
  println(number)
  number
}

/* This will not be printed until the condition is met. */
dont {
  println("Done counting to 5!")
} until (nextNumber() == 5)