# Partial memoization in Haskell

I'm trying to find a good way to memoize a function for only part of its domain (non-negative integers) in Haskell, using Data.MemoCombinators.

import Data.MemoCombinators

--approach 1

partFib n | n < 0 = undefined
| otherwise = integral fib n where
fib 0 = 1
fib 1 = 1
fib k = partFib (k-1) + partFib (k-2)

--approach 2

partFib2 n | n < 0 = undefined
| otherwise = fib n
fib = integral fib'
where
fib' 0 = 1
fib' 1 = 1
fib' n = partFib2 (n-1) + partFib2 (n-2)

Approach 1 is how I would like to do it, however, it doesn't seem to work. I assume this is because the fib function is "recreated" every time partFib is called, throwing away the memoization. fib doesn't depend on the input of partFib, so you would assume that the compiler could hoist it, but apparently GHC doesn't work that way.

Approach 2 is how I end up doing it. Eerk, a lot of ugly wiring.

Does anybody know of a better way to do this?

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Not quite sure what's "ugly" to your eye, but you can have proper memoization while using only a single top-level identifier by lifting the memoization operation out of the function of n.

partFib3 = \n -> if n < 0 then undefined else fib' n
where fib 0 = 1
fib 1 = 1
fib k = partFib3 (k-1) + partFib3 (k-2)
fib' = integral fib
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Thanks, this is better than what I had. Nothing is really that "ugly" I just want the definition to look as similar to the naive Fibonacci implementation as possible. –  dainichi Sep 14 '11 at 7:52
Why does this make a difference? Isn't f n = e semantically exactly the same as f = \n -> e? –  Dan Burton Sep 14 '11 at 18:38
@Dan, semantically, yes. But memoization is getting into operational territory. The n in the former is scoped over the where clause whereas the n in the latter is not, thus changing how the thunks in the where clause are shared. –  luqui Sep 14 '11 at 19:47
@Dan, this recent article about sharing variable bindings has a bit more detail: neilmitchell.blogspot.com/2011/09/sharing-in-haskell.html –  JB. Sep 14 '11 at 21:47

There is a combinator in the library for this purpose:

switch :: (a -> Bool) -> Memo a -> Memo a -> Memo a

switch p a b uses the memo table a whenever p gives true and the memo table b whenever p gives false.

Recall that id is technically a memoizer (which does not memoize :-), so you can do:

partFib = Memo.switch (< 0) id Memo.integral fib'
where
...
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By "a memoizer (which does not memoize :-)" you mean that its type is Memo a, so the type system will allow you to use it as a memoizer? –  MatrixFrog Sep 14 '11 at 21:43
@MatrixFrog, yes, exactly. –  luqui Sep 14 '11 at 22:12

Hmm what about separating things a bit:

fib 0 = 0
fib 1 = 1
fib x = doFib (x-1) + doFib (x-2)

memFib = Memo.integral fib

doFib n | n < 0 = fib n
| otherwise memFib n

Now you need to use doFib.

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Thanks. I like this as well. It separates the function definition cleanly from the definition of what is memoized. –  dainichi Sep 14 '11 at 7:58