# Fusion law for foldr1?

For `foldr` we have the fusion law: if `f` is strict, `f a = b`, and

`f (g x y) = h x (f y)` for all `x, y`, then `f . foldr g a = foldr h b`.

How can one discover/derive a similar law for `foldr1`? (It clearly can't even take the same form - consider the case when both sides act on `[x]`.)

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## 2 Answers

You can use free theorems to derive statements like the fusion law. The Automatic generation of free theorems does this work for you, it automatically derives the following statement if you enter `foldr1` or the type `(a -> a -> a) -> [a] -> a`.

If `f` strict and `f (p x y) = q (f x) (f y))` for all `x` and `y` you have `f (foldr1 p z) = foldr1 q (map f z))`. That is, in contrast to you statement about `foldr` you get an additional `map f` on the right hand side.

Also note that the free theorem for `foldr` is slightly more general than your fusion law and, therefore, looks quite similar to the law for `foldr1`. Namely you have for strict functions `g` and `f` if `g (p x y) = q (f x) (g y))` for all `x` and `y` then `g (foldr p z v) = foldr q (g z) (map f v))`.

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It's been some time since I've looked at the technical details of "theorems for free". Does it account for functions which may call `undefined` (as `foldr1` must)? –  Daniel Wagner Jul 26 '11 at 0:55
Free theorems consider the case that polymorphic functions use `undefined`. In the case of `foldr1` it is accounted by the requirement that `f` has to be strict. In fact, Philip Wadler already observed this requirement in his original paper about free theorems. In the automatic generation website you get these additional conditions for `undefined` by using the option "general recursion but no selective strictness". You can also consider the presence of the strict evaluation primitive `seq` by using the option "general recursion and selective strictness". –  Jan Christiansen Jul 26 '11 at 22:20
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I don't know if there's going to be anything satisfying for `foldr1`. [I think] It's just defined as

``````foldr1 f (x:xs) = foldr f x xs
``````

let's first expand what you have above to work on the entire list,

``````f (foldr g x xs) = foldr h (f x) xs
``````

for foldr1, you could say,

``````f (foldr1 g xs) = f (foldr g x xs)
= foldr h (f x) xs
``````

to recondense into foldr1, you can create some imaginary function that maps `f` to the left element, for a result of,

``````f . foldr1 g = foldr1 h (mapfst f) where
mapfst (x:xs) = f x : xs
``````
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Unfortunately your definition of `foldr1` is not quite correct if `f` isn't associative: consider `foldr1 (-) [3,4,5]` vs `foldr (-) 3 [4,5]`, for instance. –  Fixnum Jul 25 '11 at 14:07
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