# How does map() on 'zipped' Lists work?

I am looking to calculate the scalar product of two lists. Let's say we have two Lists, `l1 = List(1,2,3)` and `l2 = List(4,5,6)`, the result should be `List(4,10,18)`

The code below works:

``````def scalarProduct(l1 : List[Int], l2 : List[Int]):List[Int] = {
val l3 = l1 zip(l2); l3 map(xy => xy._1*xy._2)
}
``````

However, the following fails to compile, and says `Cannot resolve reference map with such signature` :

``````def scalarProduct(l1 : List[Int], l2 : List[Int]):List[Int] = {
val l3 = l1 zip(l2); l3 map((x:Int,y:Int) => x*y)
}
``````

This zip() would return a list of Int pairs, and the above map is also taking a function which takes an Int pair. Could someone point out why does the second variant fail in this case?

Your second example fails because you provide a function with 2 parameters to the `map`, while `map` takes a function with 1 parameter.

Have a look, here's a (simplified) signature of the `map` function:

``````def map[B, That](f: A => B): That
``````

The function `f` is the one that you have to pass to do the conversion. As you can see, it has type `A => B`, i.e. accept a single parameter.

Now take a look at the (simplified) zip function signature:

``````def zip [B](that : List[B]) : List[(A, B)]
``````

It actually produces a list whose members are tuples. Tuple of 2 elements looks like this: `(A, B)`. When you call `map` on the list of tuples, you have to provide the function `f` that takes a tuple of 2 elements as a parameter, exactly like you do in your first example.

Since it's inconvenient to work with tuples directly, you could extract values of tuple's members to a separate variables using pattern matching.

Here's an REPL session to illustrate this.

``````scala> List(1, 2, 3)
res0: List[Int] = List(1, 2, 3)

scala> List(2, 3, 4)
res1: List[Int] = List(2, 3, 4)

scala> res0 zip res1
res2: List[(Int, Int)] = List((1,2), (2,3), (3,4))
``````

Here's how you do a standard tuple values extraction with pattern matching:

``````scala> res2.map(t => t match {
|   case (x, y) => x * y
| })
res3: List[Int] = List(2, 6, 12)
``````

It's important to note here that pattern matching expects a partial function as an argument. I.e. the following expression is actually a partial function:

``````{
case (x, y) => x * y
}
``````

The partial function has its own type in Scala: `trait PartialFunction[-A, +B] extends (A) => B`, and you could read more about it, for example, here.

Partial function is a normal function, since it extends `(A) => B`, and that's why you can pass a partial function to the `map` call:

``````scala> res2.map { case (x, y) => x * y }
res4: List[Int] = List(2, 6, 12)
``````

You actually use special Scala syntax here, that allows for functions invocations (`map` in our case) without parentheses around its parameters. You can alternatively write this with parentheses as follows:

``````scala> res2.map ({ case (x, y) => x * y })
res5: List[Int] = List(2, 6, 12)
``````

There's no difference between the 2 last calls at all.

The fact that you don't have to declare a parameter of anonymous function you pass to the `map` before you do pattern matching on it, is actually Scala's syntactic sugar. When you call `res2.map { case (x, y) => x * y }`, what's really going on is pattern matching with partial function.

Hope this helps.

• This is great! This answer has alone helped me tighten quite a few loose knots. Thanks..! – Ankit Khettry Mar 2 '16 at 10:53
• if you use curly braces on the map, you don't need the `t => t.match {` part. Just do `res2.map { case (x, y) => x*y }` – Zoltán Mar 2 '16 at 10:59

you need something like:

``````def scalarProduct(l1 : List[Int], l2 : List[Int]):List[Int] = {
val l3 = l1 zip(l2); l3 map{ case (x:Int,y:Int) => x*y}
}
``````

• when you use a `map` with a list, you have a reference to each object of the list. So you would need pattern matching to transform that reference into an object you may use. For those cases, instead of using `map(x => x._1 * x._2)` you should use `map{x => x match { case (x:Int,y:Int) => x*y}` As that is quite ugly, we can use some syntactic sugar: `map{ case (x:Int,y:Int) => x*y}` – Carlos Vilchez Mar 2 '16 at 10:26
• It's pretty strange, since one of these definitions has `map(f)` and another has `map{f}`. I hate to admit but I am totally confused now – Ankit Khettry Mar 2 '16 at 10:32