Please explain in the simplest, most jargon-free English possible, the “universal property of fold”?

I am working through "Real World Haskell", which led to to a free PDF called "A tutorial on the universality and expressiveness of fold". It makes the point that a "fold" is "universal". I am wrestling with his definition of "universal", and would like to hear the from those who have already invested time digesting it: Please explain in the simplest, most jargon-free English possible, the "universal property of fold"? What is this "universal property", and why is it important?

Thanks.

• 4 years since I asked, and just tonight I came across an article talking about this. I don't know if it will fully answer my question, but it is definitely related. Search this url for "universal property": jeremykun.com/2013/04/16/categories-whats-the-point – Charlie Flowers Apr 17 '13 at 4:25
• Funnily, four years ago I didn't know what a universal property was either. Now I'm writing that series of blog posts. What a coincidence that I ran across this while writing a more detailed post on universal properties. Should be done in the next week. – JeremyKun May 22 '13 at 23:43
• @Bean, glad to hear it! I will be looking forward to reading it. Because though I am starting to have an inkling, I'm still a long way from being able to claim I deeply understand what a universal property is. – Charlie Flowers May 23 '13 at 3:21

(Jargon mode off :-)

The universal property is just a way of proving that two expressions are equal. (That's what is meant by the jargon "proof principle".) The universal property says that if you are able to prove these two equations

g []     = v
g (x:xs) = f x (g xs)

then you may conclude the additional equation

g = fold f v

The converse is also true, but that's trivial to show just by expanding the definition of fold. The universal property is a much deeper property (which is a jargony way of saying it's less obvious why it is true.)

The reason it's interesting to do this at all is that it lets you avoid proof by induction, which is almost always worth avoiding.

• There was also a notion in the paper, something along the lines of, "There is only one way to fold from the right and apply a function. That one way is foldr. If you have some other method you think is different, look closer and you will see that it is not different, because only one way exists." At least, that's what I think I read :). I need a few more re-readings. Is what I said correct or in the ballpark? And if so, how does this relate to the universal property? Thanks. – Charlie Flowers May 9 '09 at 3:28
• Charlie, I don't think I grokked that part of the paper. – Norman Ramsey May 9 '09 at 3:37
• Charlie, I think that is right, yes. The universal property is nice in that it lets you rewrite the appropriate kinds of recursive definition in terms of fold. – Ganesh Sittampalam May 9 '09 at 9:34
• When you say "folding from the right" that means that you have a function g which behaves like this: g [] = v g (x:xs) = f x (g xs) which is exactly the universal property, so this g is actually the same as fold f v. You can think of the property as a statement about sets. The set P of the things which satisfy the two equations on the left and F - the things which look like fold f v. Then the left-to-right implication says: every x in P is also in F. And right-to-left it is: every x in F is in P. Taken together this means that satisfying the two equations is eqivalent to being a fold. – Daniel Velkov Feb 2 '10 at 18:41

the paper defines two properties:

g   []     = v
g (x : xs) = f x (g xs)

and then states that fold is not only a function that satisfies those properties, but is the only function that satisfies those properties. that it is unique in that regard is what makes it 'universal' in the sense the paper is using.

The property that fold has is that it is a list-recursing function, which is equivalent to all other list-recursing functions, provided you give it the right parameters.

It has this property, because it accepts as a parameter, the functions which will be applied to the items in the list.

For example, if we wrote a simple sum function:

sum []          = 0

then we could actually write it as a fold function instead, by passing in the (+) operator which we want to use to combine the items:

sum list = foldl (+) 0 list

So any function which acts simply and recursively over a list can be rewritten as a fold function. That equivalence is the property it holds. I believe he calls the property universal, because it works over all these linear-list-recursive algorithms, without exception.

And as he explains, the reason this property is so useful, is that because we can show all these other algorithms are actually equivalent to fold, by proving something about fold, we also prove it for all those other algorithms.

I personally found the fold function hard to understand, so sometimes I used my own which looks like this:

-- forall - A kind of for next loop
-- list is list of things to loop through
-- f is function to perform on each thing
-- c is the function which combines the results of f
-- e is the thing to combine to when the end of the list is reached
forall :: [a] -> (a->b) -> (b->b->b) -> b -> b
forall [] f c e = e
forall (x:xs) f c e = c (f x) (forall xs f c e)

(This is actually slightly more powerful than foldl because it has the extra feature of applying the function f to each item in the list.)

Well nobody proved anything about my function. But that doesn't matter, because I can show that my function is in fact a fold function:

forall l f c e = foldl c e (map fn l)

And hence all the things that have been proved about fold, are also proven true for my forall function, and all its uses throughout my program. (Note we need not even consider what kind of function c is supplied in each of the different calls to forall and foldl, it doesn't matter!)

• forall l f c e = foldr (c . f) e l – Tirpen Nov 20 '09 at 11:14

I just found a new (to me) entry in Wikipedia, "Universal Property". It sheds a TON of light on this question. Here's the link: From it, I (tenatively) conclude the following:

1. Though you may think of 100 different ways to walk through a list, computing along the way, and producing one final value from the list, all 100 of those ways are isomorphic (meaning that ultimately, they're the same). There really is only one way to reduce a list to one value, and that is FOLD.
2. Fold is also the "most efficient solution" to how to reduce a list to a single value. Or you might say, the most "factored" or most "simplified" solution.

Together, it seems, those 2 points capture the meaning of the term "universal property".

Though it may be a bit difficult to follow without reading the previous posts in the series explaining universal properties from a categorical standpoint, this post gives a detailed categorical explanation of the universal property of fold, as well as map and filter.

http://jeremykun.com/2013/09/30/the-universal-properties-of-map-fold-and-filter/

Though I have yet to write it, the followup will generalize this (and make it much simpler to understand, albeit more abstract) to "fold-like" operations on general data structures.

See this post for more on what a universal property is: http://jeremykun.com/2013/05/24/universal-properties/

And here for links to all posts in the series: http://jeremykun.com/main-content/

In truth, the currently accepted answer is the easiest way to understand what the universal property is saying about fold. The articles linked to above simply give a more detailed technical description via category theory that is absent from the paper in question. I disagree the statement in the accepted answer, though, that the universal property is a much deeper property than the jargon-free statement. The universal property of fold is precisely the same statement, just boxed up into the language of initial and final objects as per the nature of analyzing things with category theory. This analysis is valuable precisely because of its natural generalizations.