# Fold and foldLeft method difference

I am not sure what is the difference between `fold` and `foldLeft` in Scala.

The question Difference between fold and foldLeft or foldRight? has an answer that talks about ordering. That is understandable. But I still don't understand why this works (from REPL):

``````scala> Array("1","2","3").foldLeft(0)(_ + _.toInt)
res6: Int = 6
``````

but this does not:

``````scala> Array("1","2","3").fold(0)(_ + _.toInt)
<console>:8: error: value toInt is not a member of Any
Array("1","2","3").fold(0)(_ + _.toInt)
^
``````

What does this error message mean?

This line from the documentation is also confusing to me.

z - a neutral element for the fold operation; may be added to the result an arbitrary number of times, and must not change the result (e.g., Nil for list concatenation, 0 for addition, or 1 for multiplication.)

Why will it be added an arbitrary number of times? I thought folding works differently.

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As defined by Scala, `foldLeft` is a linear operation while `fold` is allowed to be a tree operation. For example:

``````List(1,2,3,4,5).foldLeft(0)(_ + _)
// This is the only valid order of operations
0+1 = 1
1+2 = 3
3+3 = 6
6+4 = 10
10 + 5 = 15
15  // done

List(1,2,3,4,5).fold(0)(_ + _)
// This is valid
0+1 = 1             0+3 = 3           0+5 = 5
1+2 = 3             3+4 = 7           5
3         +         7=10        5
10    +   5 = 15
15  // done
``````

In order to allow arbitrary tree decompositions of a sequential list, you must have a zero that doesn't do anything (so you can add it wherever you need it in the tree) and you must create the same sort of thing that you take as your binary arguments so the types don't change on you depending on how you decompose the tree.

(Being able to evaluate as a tree is nice for parallelization. If you want to be able to transform your output time as you go, you need both a combination operator and a standard start-value-transforms-sequence-element-to-desired-type function just like `foldLeft` has. Scala has this and calls it `aggregate`, but in some ways this is more like `foldLeft` than `fold` is.)

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You give foldLeft in both examples; the second should presumably be fold instead of foldLeft. And you missed out the operator functions. Otherwise, this is a good illustration of parallel folds. –  Rick-777 Jul 4 '12 at 6:58
@Rick-777 - Fixed the typo. I'm not sure what you mean by "missed out the operator functions". –  Rex Kerr Jul 4 '12 at 14:11
The anonymous addition functions are needed, i.e. "( _ + _ )" –  Rick-777 Jul 8 '12 at 12:58
@Rick-777 Fair enough. I initially did that intentionally to focus attention on the `fold` vs. `foldLeft`, but on second look it just looked incomplete. Fixed now. –  Rex Kerr Jul 8 '12 at 18:43
Good work Rex. :) –  Rick-777 Jul 12 '12 at 20:48

I am not familiar with Scala, but Scala's collection library has a similar design to Haskell's. This answer is based on Haskell and is probably accurate for Scala as well.

Because `foldLeft` processes its inputs from left to right, it can have different input and output types. On the other hand, `fold` can process its inputs in various orders and so the inputs and output must all have the same type. This is easiest to see by expanding out the fold expressions. `foldLeft` operates in a specific order:

``````Array("1","2","3").foldLeft(0)(_ + _.toInt)
= ((0 + "1".toInt) + "2".toInt) + "3".toInt
``````

Note that array elements are never used as the first parameter to the combining function. They always appear on the right of the `+`.

`fold` does not guarantee a specific order. It could do various things, such as:

``````Array("1","2","3").fold(0)(_ + _.toInt)
=  ((0 + "1".toInt) + "2".toInt) + "3".toInt
or (0 + "1".toInt) + ("2" + "3".toInt).toInt
or "1" + ("2" + ("3" + 0.toInt).toInt).toInt
``````

Array elements can appear in either parameter of the combining function. But your combining function expects its first argument to be an int. If you don't respect that constraint, you end up adding strings to ints! This error is caught by the type system.

The neutral element may be introduced multiple times because, generally, a parallel fold is implemented by splitting up the input and executing multiple sequential folds. A sequential fold introduces the neutral element once. Imagine one particular execution of `Array(1,2,3,4).fold(0)(_ + _)` where the array is split into two separate arrays, and these are folded sequentially in two threads. (Of course, the real `fold` function does not spit the array into multiple arrays.) One thread executes `Array(1,2).fold(0)(_ + _)`, computing `0 + 1 + 2`. The other thread executes `Array(3,4).fold(0)(_ + _)`, computing `0 + 3 + 4`. Finally, the partial sums from the two threads are added together. Note that the neutral element, `0`, appears twice.

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NOTE: I could be completely wrong here. My scala is less than perfect.

I think that the difference is in the signature of the methods:

``````def fold[A1 >: A](z: A1)(op: (A1, A1) ⇒ A1): A1
``````

vs

``````def foldLeft[B](z: B)(op: (B, T) ⇒ B): B
``````

In short, fold is defined as operating on some type A1 which is a supertype of the array's type, which for your string array the compiler defines as "Any" (probably because it needs a type that can store your String or an int- notice that the combiner method passed to fold Fold takes two parameters of the same type?) That's also what the documentation means when it talks about z- the implementation of Fold could be such that it combines your inputs in parallel, for instance:

``````"1" + "2" --\
--> 3 + 3 -> 6
"3" + *z* --/
``````

On the other hand, foldLeft operates on type B (unconstrained) and only asks that you provide a combiner method that takes a parameter of type B and another of your array's type (String, in your case), and produces a B.

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That is almost perfect. `A1` is a supertype `A` -- that is, I can go from `Int` to `Any` (for example), but not from `Any` to `Int`. –  Daniel C. Sobral Jul 3 '12 at 21:34
OK. In that case, I am not sure why it was cast to `Any` and not `AnyVal`. But other than that, I think I understand. –  Karel Bílek Jul 3 '12 at 21:40
@KarelBílek presumably because it needs a base type common to String and int. String is (again, assuming, because it is in Java) a reference type. –  Chris Shain Jul 3 '12 at 23:30

## General difference

Here are the prototypes of the methods

``````fold[A1 >: A](z: A1)(op: (A1, A1) ⇒ A1): A1
foldLeft[B](z: B)(f: (B, A) ⇒ B): B
``````

So, for fold the result is of type `A1 >: A`instead of any `B`. Moreover, as specified in the doc, for `fold` the order is not

When typing `scala> Array("1","2","3").fold(0)(_ + _.toInt)` you assume that `0`, an `int` is a subtype of `String`. This is why the compiler throws an error.

## About the weird z in fold

Here we have to see the implementation of `fold` to understand what happens. Here is what we get:

``````def fold[A1 >: A](z: A1)(op: (A1, A1) => A1): A1 = foldLeft(z)(op)
``````

So basically, `fold` is an implementation of `foldleft` with a constraint on the output type. We can now see that `z` will in practice be used the same way as in `foldleft`. So we can just conclude that this comment was made because nothing assures that behavior in future implementations. We can already see it now, with parallels:

``````def fold[U >: T](z: U)(op: (U, U) => U): U = {
executeAndWaitResult(new Fold(z, op, splitter))
}
``````
-

As another answer points out, the `fold` method is primarily there to support a parallel fold. You can see this as follows. First we can define a kind of wrapper for integers that allows us to keep track of the operations that have been performed on its instances.

``````case class TrackInt(v: Int) {
val log = collection.mutable.Buffer.empty[Int]
def plus(that: TrackInt) = {
this.log += that.v
that.log += this.v
new TrackInt(this.v + that.v)
}
}
``````

Next we can create a parallel collection of these things and an identity element:

``````val xs = (1 to 10).map(TrackInt(_)).par
val zero = TrackInt(0)
``````

First we'll try `foldLeft`:

``````scala> xs.foldLeft(zero)(_ plus _)
res0: TrackInt = TrackInt(55)

scala> zero.log
res1: scala.collection.mutable.Buffer[Int] = ArrayBuffer(1)
``````

So our zero value is only used once, as we'd expect, since `foldLeft` performs a sequential fold. Next we can clear the log and try `fold`:

``````scala> zero.log.clear()

scala> xs.fold(zero)(_ plus _)
res2: TrackInt = TrackInt(55)

scala> zero.log
res3: scala.collection.mutable.Buffer[Int] = ArrayBuffer(1, 6, 2, 7, 8)
``````

So we can see that the fold has been parallelized in such a way that the zero value is used multiple times. If we ran this again we'd be likely to see different values in the log.

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The error. You are getting a compile-time error because the signature of `fold` only allows folding values of type which is the supertype of the type of the values in the collection, and the only supertype of `String` (your collection type) and `Int` (the type of your provided zero element) is `Any`. So, the type of the fold result is inferred to be `Any` - and `Any` does not have a method `toInt`.

Note that the two versions of `fold` have different signatures:

``````fold[A1 >: A](z: A1)(op: (A1, A1) => A1): A1

foldLeft[B](z: B)(f: (B, A) => B): B
``````

Why do they have different signatures? This is because `fold` could be implemented in parallel, as is the case with parallel collections. When multiple processors fold over the values in the collections, each one of the processors takes a subset of elements of type `A` and produces the folded value of type `A1`, by consecutively applying `op`. The results produced by those processors must be combined together into a final folding value - this is done using the `op` function, which does exactly that.

Now, note that this cannot be done using the `f` in `foldLeft`, because each of the processors produces a folded value of type `B`. Several values of type `B` cannot be combined using `f`, because `f` only combines value `B` with another value of type `A` - there is no correspondance between types `A` and `B`.

Example. In your example, assume the 1st processor takes elements `"1", "2"` and the 2nd takes element `"3"`. The first one will produce the folded value `3`, and the second will produce another folded value `3`. Now they have to combine their results to get the final folded value - this is impossible, because the closure `_ + _.toInt` only knows how to combine an `Int` and `String`, and not 2 `Int` values.

For situations where these types differ, use `aggregate`, in which you have to define how to combine two values of type `B`:

``````def aggregate[B](z: B)(seqop: (B, A) => B, combop: (B, B) => B): B
``````

The `combop` above defines how to do the final step when the fold result and the elements in the collection have different types.

The neutral element. As described above, multiple processors may fold over subsets of elements in the collection. Each one of them will start its folded value by adding the neutral element.

In the following example:

``````List(1, 2, 3).foldLeft(4)(_ + _)
``````

always returns `10 = 4 + 1 + 2 + 3`.

However, `4` should not be used with `fold`, as it is not a neutral element:

``````List(1, 2, 3).fold(4)(_ + _)
``````

The above may return `(4 + 1 + 2) + (4 + 3) = 14` or `(4 + 1) + (4 + 2) + (4 + 3) = 18`. If you don't use the neutral element for the `fold`, the results are nondeterministic. In the same way, you can use the `Nil` as a neutral element, but not a non-empty list.

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