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Is there any way to force GHC to thunk a particular computation for the lifetime of a particular value?

I could obviously place the value into a record, creating lazy record entries for the result of said computation, and create a maker function that builds the record and thunks the value into said entries.

I'd hate needing to pull the original value out from the record every time I wanted it though. And Haskell has no adhocly polymorphic is-a relationships like C++ or Java.

Are there any trick for memoizing values across multiple unrelated invocations of a function with identical parameters?

I could vaguely imagine various tricks with forms of dependent types that'd effectively tell the compiler multiple usages were coming. There aren't any dependent types in Haskell but maybe something around implicit parameters? I suppose not, but I thought I'd ask. A pragma perhaps?


Imagine I've a vector of Necklace data structures for which I need a resulting vector of rational numbers, stored as a common denominator and a vector of numerators.

{-# LANGUAGE ImplicitParams #-}
import qualified Data.Vector as V

data Necklace = Necklace { ... }
necklace_length n = ...

denominator :: (necklaces :: V.Vector Necklace) => Int
denominator = V.foldl' lcm 30 $ V.map necklace_length ?necklaces

numerators :: (necklaces :: V.Vector Necklace) => V.Vector Int
numerators = V.map f ?necklaces
  where f x = ... denominator ...

kittytoy :: (necklaces :: V.Vector Necklace) => Meow -> ...
kittytoy = \meow -> ... numerators ...

A priori, I'd expect that, if I invoke kittytoy several million times, each with a different parameter meow, then GHC produces code that invokes numerators a million times, each with an identical implicit parameters necklaces.

It's nevertheless obvious that numerators only needs to be invoked once though, the first time ?necklaces gets assigned, meaning GHC could potentially notice this optimization.

There should even be an explicit code refactoring approach using template haskell to explicitly pass the thunks by producing code like ?numerators = numerators and adding numerators :: V.Vector Int to type constraints of functions that call it.

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kittytoy necklaces = let n = numerators necklaces in \meow -> stuff should definitely memoize n. Not sure if it will also be this way as is as well. –  yairchu Apr 6 '12 at 21:24
    
Do you mean let k = kittytoy in ... replacing every call to kittytoy with k? Yes, I'd agree that should memoize the implicit parameter ?necklaces, but should I really need to do that? –  Jeff Burdges Apr 6 '12 at 21:27
    
Ahh, no I'm trying to memoize numerators outside the call to kittytoy, because kittytoy itself gets invoked several million times. Yes, that's a valid point that kittytoy should be a lambda expression regardless, I'll edit it for clarity. –  Jeff Burdges Apr 6 '12 at 21:29
    
It likely that numerators must be explicitly added to type constraints to achieve what I want, but maybe some template Haskell tricks exist for that. –  Jeff Burdges Apr 7 '12 at 9:37

2 Answers 2

There is another plausible approach arising from the fact that type now defined synonyms for type constrains, as noted in Philip JF's answer here.

You could probably create a synonym for a type constraint that created implicit parameters for all the various derived values :

type Necklaces = (necklaces :: V.Vector Necklace,
                  denominator :: Int,
                  numerators :: V.Vector Int)

kittytoy :: (Necklaces) => Meow -> ...

You'd initially assign all the values like ?numerators using a template Haskell construction of some form. I'll play with it to see if it works.

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You're probably looking for pure memoisation, as implemented by data-memocombinators. Basically, it works by creating a (lazy, possibly infinite) tree structure with all the possible values of the function at each leaf, and then creating a new function that simply accesses the value at the relevant location. For instance, you can write a memoiser for functions Bool -> a like this:

memoBool :: (Bool -> a) -> (Bool -> a)
memoBool f =
    let fTrue = f True
        fFalse = f False
    in \b -> if b then fTrue else fFalse

In this case, the "tree structure" is rather bonsai, having only two leaves.

data-memocombinators packages this up in the Memo a type, defined as forall r. (a -> r) -> (a -> r), with useful combinators like pair :: Memo a -> Memo b -> Memo (a, b) (read: if you can memoise functions of argument type a, and memoise functions of argument type b, you can memoise functions of argument type (a, b)).

This is pure, and pretty elegant, relying on the sharing implemented by basically all Haskell implementations (which is the same thing that makes your record idea work). Unfortunately, it's also not very fast, so for practical use you might want to use uglymemo instead, which uses a mutable Map behind the scenes (but exposes an externally-pure interface).

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I think not, although it's nice knowing that exists. I'd want the memoisation dumped when the implicit parameter ?necklaces changes. I found yairchu comment clarifying, basically implicit parameters might create additional opportunities, but only by explicitly making lambda expressions. It feels like more should be possible, but okay. –  Jeff Burdges Apr 6 '12 at 21:49
    
Well, you'd just write numerators :: V.Vector Necklace -> V.Vector Int. Then, calls with the same parameter would produce the same result without recalculation. Admittedly, depending on how big your Vector is, the cost of looking it up in a tree structure might outweigh the cost of performing the numerators computation from scratch. GHC has the required facilities to build a memoisation library based on pointer identity of the input values, but I don't know if there's anything on Hackage for it. –  ehird Apr 6 '12 at 21:53
    
By the way, implicit parameters are a very rare extension, and most people avoid them — I've only seen two pieces of code that actually use them, and they have nasty pitfalls, like adding a type signature to a definition changing its value. –  ehird Apr 6 '12 at 21:53
    
Really? How so? I've found them quite elegant. If I don't use implicit parameters, but do expose the optimal breaking of lambda expressions to GHC, then I must still assign a temporary value like k = kittytoy necklaces to invoke instead, and this value must get communicated amongst the various differeny functions calling kittytoy, that's what I'd like GHC to sort out. –  Jeff Burdges Apr 6 '12 at 22:07
    
Well, you can use the Reader monad to encapsulate carrying around a common environment. If you really want to avoid the plumbing, you could also try Edward Kmett's reflection package. But if implicit parameters work for you, that's great :) –  ehird Apr 6 '12 at 22:10

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