# Scala - can yield be used multiple times with a for loop?

An example:

``````val l = List(1,2,3)
val t = List(-1,-2,-3)
``````

Can I do something like this?

``````for (i <- 0 to 10) yield (l(i)) yield (t(i))
``````

Basically I want to yield multiple results for every iteration.

It's not clear what you're asking for - what you expect the semantics of multiple yield to be. One thing, though, is that you probably never want to use indexes to navigate a list - each call to t(i) is O(i) to execute.

So here's one possibility that you might be asking for

``````scala> val l = List(1,2,3); val t = List(-1,-2,-3)
l: List[Int] = List(1, 2, 3)
t: List[Int] = List(-1, -2, -3)

scala> val pairs = l zip t
pairs: List[(Int, Int)] = List((1,-1), (2,-2), (3,-3))
``````

And here's another possibility that you might be asking for

``````scala> val crossProduct = for (x <- l; y <- t) yield (x,y)
crossProduct: List[(Int, Int)] = List((1,-1), (1,-2), (1,-3), (2,-1), (2,-2), (2,-3), (3,-1), (3,-2), (3,-3))
``````

The later is just syntactic sugar for

``````scala> val crossProduct2 = l flatMap {x => t map {y => (x,y)}}
crossProduct2: List[(Int, Int)] = List((1,-1), (1,-2), (1,-3), (2,-1), (2,-2), (2,-3), (3,-1), (3,-2), (3,-3))
``````

A third possibility is you want to interleave them

``````scala> val interleaved = for ((x,y) <- l zip t; r <- List(x,y)) yield r
interleaved: List[Int] = List(1, -1, 2, -2, 3, -3, 4, -4, 5, -5, 6, -6, 7, -7, 8, -8, 9, -9, 10, -10)
``````

That's syntax sugar for

``````scala> val interleaved2 = l zip t flatMap {case (x,y) => List(x,y)}
interleaved2: List[Int] = List(1, -1, 2, -2, 3, -3, 4, -4, 5, -5, 6, -6, 7, -7, 8, -8, 9, -9, 10, -10)
``````
• I think he just wants to interpolate the lists. Jul 17, 2009 at 2:19
• right, I wanted to interleave them, so both these give the same result: [James] val interleaved = for ((x,y) <- l zip t; r <- List(x,y)) yield r [Daniel] for (i <- 0 to 10; r <- List(l(i), t(i))) yield r I think James' one is more elegant and it also outputs List. Thanks a lot guys. Jul 17, 2009 at 8:12

No, you can't use multiple yield clauses, but there are work-arounds. For example:

``````for (i <- 0 to 10;
r <- List(l(i), t(i)))
yield r
``````

You can nest for-comprehensions, of course, but that would result in a list of lists of elements, which I don't believe is what you want.

• Warning, this solution is O(n^2) Jul 17, 2009 at 2:29
• For l&t lists, which was, I'll concede, his example. If t&l were arrays or functions, that wouldn't be the case, right? Jul 17, 2009 at 3:30
• Right, for arrays indexed access is O(1) so the solution would be O(n). Jul 17, 2009 at 4:12

Yields can be nested, which would result ...

``````for (i <- 0 to 3) yield {
for (j <- 0 to 2) yield (i,j)
}
``````

in a Vector of Vector:

``````scala.collection.immutable.IndexedSeq[scala.collection.immutable.IndexedSeq[(Int, Int)]]
= Vector(Vector((0,0), (0,1), (0,2)), Vector((1,0), (1,1), (1,2)), Vector((2,0), (2,1), (2,2)), Vector((3,0), (3,1), (3,2)))

for (i <- 0 to 3;
j <- 0 to 2) yield (i,j)
``````

The flattened solution is semantically different.

Here is a type-agnostic solution for an unknown, varying number of elements in a unknown number of lists:

``````def xproduct (xx: List [List[_]]) : List [List[_]] =
xx match {
case aa :: bb :: Nil =>
aa.map (a => bb.map (b => List (a, b))).flatten
case aa :: bb :: cc =>
xproduct (bb :: cc).map (li => aa.map (a => a :: li)).flatten
case _ => xx
}
``````

For 2 Lists it is overengineered. You could although call it

``````   xproduct (List (l, t))
``````

Apparently not. I get a compile error when I try it.

It looks like for .. yield is an expression. You can't have two yields, since that's not really part of the expression.

If you want to yield multiple values, why not yield them as a tuple or a list?

For example:

``````for( t <- List(1,2,3); l <- List(-1,-2,-3))
yield (t, l)
``````

Maybe yield is not the best way to go? Perhaps simple array appending could be used here.

• There is no semantic difference between using yield and using a list. The practical difference involves memory usage, where yield is more efficient for large sets. Jul 16, 2009 at 21:09