Take the 2-minute tour ×
Stack Overflow is a question and answer site for professional and enthusiast programmers. It's 100% free.

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?

share|improve this question
2  
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
2  
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?

share|improve this answer

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).

share|improve this answer
    
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.

share|improve this answer
    
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
1  
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

Your Answer

 
discard

By posting your answer, you agree to the privacy policy and terms of service.

Not the answer you're looking for? Browse other questions tagged or ask your own question.