# Understanding A bit of Haskell

I have a quick question about Haskell. I've been following Learn You a Haskell, and am just a bit confused as to the execution order / logic of the following snippet, used to calculate the side lengths of a triangle, when all sides are equal to or less than 10 and the total perimeter of the triangle is 24:

`[(a,b,c) | c <- [1..10], b <- [1..c], a <- [1..b], a^2 + b^2 == c^2, a+b+c==24]`

The part that is confusing to me is the upper expansion bound on the `b` and `a` binding. From what I gather, the `..c` and `..b` are used to remove additional permutations (combinations?) of the same set of triangle sides.

When I run it with the `..c/b`, I get the answer:

`[(6,8,10)]`

When I don't have the `..c/b`:

`[(a,b,c) | c <- [1..10], b <- [1..10], a <- [1..10], a^2 + b^2 == c^2, a+b+c==24]`

as I didn't when I initially typed it in, I got:

`[(8,6,10),(6,8,10)]`

Which is obviously representative of the same triangle, save for the `a` and `b` values have been swapped.

So, can someone walk me through the logic / execution / evaluation of what's going on here?

-

The original version considers all triplets (a,b,c) where c is a number between 1 and 10, b is a number between 1 and c and a is a number between 1 and b. (6,8,10) fits that criteria, (8,6,10) doesn't (because here a is 8 and b is 6, so a isn't between 0 and 6).

In your version you consider all triplets (a,b,c) where a, b and c are between 1 and 10. You make no restrictions on how a, b and c relate to each other, so (8, 6, 10) is not excluded since all numbers in it are indeed between 1 and 10.

If you think of it in terms of imperative for-loops, your version does this:

``````for c from 1 to 10:
for b from 1 to 10:
for a from 1 to 10:
if a^2 + b^2 == c^2 and a+b+c==24:
``````

while the original version does this:

``````for c from 1 to 10:
for b from 1 to c:
for c from 1 to b:
if a^2 + b^2 == c^2 and a+b+c==24:
``````
-
Gotcha, thanks! –  Josh Jun 8 '12 at 14:34

It's not about execution order. In the first example you don't see the degenerate solution

``````[(8,6,10)]
``````

since `a <= b <= c`. In the second case `a > b` is included in the list comprehension.

-

List comprehensions can be written in terms of other functions like `concatMap`, which clarifies the scope of the bindings. As a one-liner, your example becomes something like this:

``````concatMap (\c -> concatMap (\b -> concatMap (\a -> if a^2 + b^2 == c^2 then (if a+b+c == 24 then [(a,b,c)] else []) else []) (enumFromTo 1 b)) (enumFromTo 1 c)) (enumFromTo 1 10)
``````

Yeah, that looks ugly, but it's similar to what Haskell desugars your comprehensions into. The scope of each of the variables `a`, `b` and `c`, should be obvious from this.

Or alternatively, this can be written with the `List` monad:

``````import Control.Monad

example = do c <- [1..10]
b <- [1..c]
a <- [1..b]
guard (a^2 + b^2 == c^2)
guard (a+b+c == 24)
return (a,b,c)
``````

This is actually very similar as the one-liner above, given the definition of the `List` Monad and `guard`:

``````instance Monad [] where
return x = [x]
xs >>= f = concatMap f xs

Did you at least follow the one-liner? `concatMap f xs` is like `map f xs` except that `f` produces a list of items and `concatMap` appends them: `map (\n -> [1..n]) [1..3]` is `[[1],[1,2],[1,2,3]]`, `concatMap (\n -> [1..n]) [1..3]` is `[1,1,2,1,2,3]`. Basically, the one-liner is using nested `concatMap` over [1..10], [1..c] and [1..b] to generate the triples, returning `[]` to reject a triple and `[(a,b,c)]` to accept a triple. The final result concatenates all the singleton `[(a,b,c)]` lists for good triples and empty lists for bad ones. –  Luis Casillas Jun 8 '12 at 18:15