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I use the LINQ Aggregate operator quite often. Essentially, it lets you "accumulate" a function over a sequence by repeatedly applying the function on the last computed value of the function and the next element of the sequence.

For example:

int[] numbers = ...
int result = numbers.Aggregate(0, (result, next) => result + next * next);

will compute the sum of the squares of the elements of an array.

After some googling, I discovered that the general term for this in functional programming is "fold".

Now I think that a function that can be computed with this operator only needs to satisfy (please correct me if I am wrong):

f(x1, x2, ..., xn) = f(f(x1, x2, ..., xn-1), xn)

This property seems common enough to deserve a special name. Is there one?

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A mathematical function usually has a fixed number of arguments. It is not clear what is meant by +(1,2,3,4,5), unless you define it as 1+2+3+4+5. –  n.m. Nov 11 '11 at 19:13
@n.m.: Yes, that's something I've thought about. Is there really no concept of a "variadic function" in mathematics? How about in the context of "Finite sequences and series"‌​? –  Ani Nov 11 '11 at 19:17
You can define a "variadic" function, but you usually do it in terms of more simple functions. In any case, when reason about a fold, you think in terms in two-argument functions, not variadic ones. You can fold a (+), the properties of this fold are determined by properties of the two-argument (+) alone. Moreover, if you define a variadic (+) function, you basically must define it as the fold of the two-argument (+). So it is not productive to think about variadic functions in this context. –  n.m. Nov 11 '11 at 19:22
@n.m.: Great point! –  Ani Nov 11 '11 at 19:24
Are you familiar with associative and commutative functions? With both properties, you can think of f(x1,...,xn) as a function from the unordered set {x1,...,xn} to the aggregated value. –  han Nov 12 '11 at 8:28

3 Answers 3

up vote 2 down vote accepted

To clarify the question: 'sum of squares' is a special function because it has the property that it can be expressed in terms of the fold functional plus a lambda, ie

sumSq = fold ((result, next) => result + next * next) 0

Which functions f have this property, where dom f = { A tuples }, ran f :: B?

Clearly, due to the mechanics of fold, the statement that f is foldable is the assertion that there exists an h :: A * B -> B such that for any n > 0, x1, ..., xn in A, f ((x1,...xn)) = h (xn, f ((x1,...,xn-1))).

The assertion that the h exists says almost the same thing as your condition that

f((x1, x2, ..., xn)) = f((f((x1, x2, ..., xn-1)), xn))     (*)

so you were very nearly correct; the difference is that you are requiring A=B which is a bit more restrictive than being a general fold-expressible function. More problematically though, fold in general also takes a starting value a, which is set to a = f nil. The main reason your formulation (*) is wrong is that it assumes that h is whatever f does on pair lists, but that is only true when h(x, a) = a. That is, in your example of sum of squares, the starting value you gave to Accumulate was 0, which is a does-nothing when you add it, but there are fold-expressible functions where the starting value does something, in which case we have a fold-expressible function which does not satisfy (*).

For example, take this fold-expressible function lengthPlusOne:

lengthPlusOne = fold  ((result, next) => result + 1) 1

f (1) = 2, but f(f(), 1) = f(1, 1) = 3.

Finally, let's give an example of a functions on lists not expressible in terms of fold. Suppose we had a black box function and tested it on these inputs:

f (1) = 1
f (1, 1) = 1    (1)
f (2, 1) = 1
f (1, 2, 1) = 2 (2)

Such a function on tuples (=finite lists) obviously exists (we can just define it to have those outputs above and be zero on any other lists). Yet, it is not foldable because (1) implies h(1,1)=1, while (2) implies h(1,1)=2.

I don't know if there is other terminology than just saying 'a function expressible as a fold'. Perhaps a (left/right) context-free list function would be a good way of describing it?

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An Iterated binary operation may be what you are looking for.

You would also need to add some stopping conditions like

f(x) = something
f(x1,x2) = something2

They define a binary operation f and another function F in the link I provided to handle what happens when you get down to f(x1,x2).

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Very interesting, thanks. –  Ani Nov 11 '11 at 19:33
+1 Good answer. There are lots of ways of thinking about fold; in these terms we're saying that the fold-expressible functions are 'iterable'. I wrote a note in my answer about those stopping conditions. –  Nicholas Wilson Nov 12 '11 at 12:21

In functional programming, fold is used to aggregate results on collections like list, array, sequence... Your formulation of fold is incorrect, which leads to confusion. A correct formulation could be:

fold f e [x1, x2, x3,..., xn] = f((...f(f(f(e, x1),x2),x3)...), xn)

The requirement for f is actually very loose. Lets say the type of elements is T and type of e is U. So function f indeed takes two arguments, the first one of type U and the second one of type T, and returns a value of type U (because this value will be supplied as the first argument of function f again). In short, we have an "accumulate" function with a signature f: U * T -> U. Due to this reason, I don't think there is a formal term for these kinds of function.

In your example, e = 0, T = int, U = int and your lambda function (result, next) => result + next * next has a signaturef: int * int -> int, which satisfies the condition of "foldable" functions.

In case you want to know, another variant of fold is foldBack, which accumulates results with the reverse order from xn to x1:

   foldBack f [x1, x2,..., xn] e = f(x1,f(x2,...,f(n,e)...))

There are interesting cases with commutative functions, which satisfy f(x, y) = f(x, y), when fold and foldBack return the same result. About fold itself, it is a specific instance of catamorphism in category theory. You can read more about catamorphism here.

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Why / how is my formulation incorrect? –  Ani Nov 12 '11 at 6:17
As I said, f only has two arguments. The nature of fold helps to apply f on the whole collection. You were confused between the inner function f and the outer function fold, which leads to a variadic function f. Maybe the following one is close to your idea: fold f e [x1, x2, ..., xn] = f(fold f e [x1, x2, ..., xn-1], xn) –  pad Nov 12 '11 at 7:05
Right, but if we allow variadic functions, my formulation is correct? Also could you explain the "Due to this reason, I don't think there is a formal term for these kinds of function" bit? I don't quite get it. –  Ani Nov 12 '11 at 7:09
Apparently in LINQ the function must be of type T * T -> T. –  han Nov 12 '11 at 8:29
I think @pad and @Ani are talking about different things, slightly. The original question is 'which functions are foldable', meaning, which functions can be written in terms of fold. pad's answer was that a foldable function is any with type U * T -> U is about which lambdas we can apply fold to. The original question was about the property of 'sum of squares' though that mean that it can be written as a fold plus a lambda. –  Nicholas Wilson Nov 12 '11 at 11:21

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