scala> def a(i:Int)(j:Int) = i * j
a: (i: Int)(j: Int)Int
scala> def b(i:Int, j:Int) = i * j
b: (i: Int, j: Int)Int
The two definitions are very similar, and they (appear to me) do the same thing.
Apart from defining a function which receives implicit parameters or a code block as parameter, is there any reason to use the first definition style?
This is the list I have compiled over the time:
1) Type resolution across multiple argument lists
class ResourceManager {
type Resource
def open: Resource = ???
}
class ResourceManagerTest {
// Does not compile: def test1(rm: ResourceManager, r: rm.Resource) = ???
// Compiles: This way the type can be resolved
def test2(rm: ResourceManager)(r: rm.Resource) = ???
}
2) Type inference where earlier arguments can "lock down" type parameters for later arguments (thanks to Myserious Dan)
def foo1[A](x: A, f: A => Int) = ???
def foo2[A](x: A)(f: A => Int) = ???
def foo1foo2Demo() {
// This will always demand a type annotation on any anonymous function
// you pass in:
foo1(1, (i: Int) => i * i)
// Does not compile: foo1(1, i => i * i)
// Type not required
foo2(2)(i => i * i)
}
3) Syntax-like language extensions
object MultipleArgumentListsDemo {
// This style of function definition allows syntax-like language extensions
@tailrec
def myWhile(conditional: => Boolean)(f: => Unit) {
if (conditional) {
f
myWhile(conditional)(f)
}
}
def myWhileDemo() {
var count = 0
myWhile(count < 5) {
count += 1
println(count)
}
}
4) Having both implicit and non implicit arguments, as implicit is a modifier for a whole argument list:
def f[A](x: A)(implicit mf: Manifest[A]) {
}
5) A parameter's value from one parameter list can be used to compute a default value in another parameter list, but not in the same one.
def g(x: Int)(y: Int = x * 2) = {
x + y
}
6) Multiple repeated argument lists ("varargs")
def h(as: Int*)(bs: Int*)(cs: Int*) = as.sum * bs.sum * cs.sum
7) Partial application
def i() {
val foop = h(1, 2, 3)(4, 5, 6, 7, 9) _
println(foop(Seq(10, 11)))
}
As I have not tracked my sources while I was compiling that list over the time: It's possible that some or all examples are copied from elsewhere (other questions on SO), so please drop a note, and I will add the reference as to where it came from.
def foo[A](x: A, f: A => Int), do def foo[A](x: A)(f: A => Int), because the former will always demand a type annotation on any anonymous function you pass in.
Aug 8, 2013 at 11:30
def g(x: Int)(y: Int = x * 2)) examples look the same to me.
Aug 8, 2013 at 12:56
The main reason for "currying" functions in this manner is to enable partial application:
scala> val c = a(5) _
c: Int => Int = <function1>
Here c is a function that takes a single int and returns the result of multiplying that int with 5. It may be that you would set up c in one method, and pass it into another method that expects a function taking one Int parameter. A bit trivial in this case, but very flexible for a range of uses.
def c(i:Int) = b(5, i)
Aug 8, 2013 at 12:20
Additional to support currying, it also helps with type inference: Sometimes the compiler can't infer the correct type if everything is in one argument list, but if you split off the part that depends on the binding of the other arguments, it works. A typical example is foldLeft: Try to implement it with one argument list, and then in some cases the compiler needs type annotations.
