# Does this Haskell code reuse previous computation?

I have a piece of Haskell code that computes regular numbers, i.e. positive integers whose only prime factors can be 2, 3 or 5. The algorithm is straightforward and follows what's suggested in the same Wikipedia article.

``````regularSeq :: [Integer]
regularSeq = 1 : union timesTwo (union timesThree timesFive)
where
timesTwo   = map (* 2) regularSeq
timesThree = map (* 3) regularSeq
timesFive  = map (* 5) regularSeq

union :: (Ord a) => [a] -> [a] -> [a]
union [] ys = ys
union xs [] = xs
union (x : xs) (y : ys)
| x < y     = x : union      xs (y : ys)
| x > y     = y : union (x : xs)     ys
| otherwise = x : union      xs      ys
``````

Example:

``````ghci> takeWhile (<= 60) regularSeq
[1,2,3,4,5,6,8,9,10,12,15,16,18,20,24,25,27,30,32,36,40,45,48,50,54,60]
``````

I have a couple questions regarding the performance of this code, specifically the lazy evaluation, "memoization" and memory usage.

1. Since the computation of a new number in the sequence relies on previous values further back, are older values of `regularSeq` "cached"/"memoized" and reused in the computation of `timesTwo`/`timesThree`/`timesFive`? Or does the recursive code spawn an inefficient degree-3 tree of computations similar to the naive Fibonacci implementation?

``````fib 0 = 1
fib 1 = 1
fib n = fib (n-1) + fib (n-2)
``````
2. During the evlauation of `regularSeq`, is there only a single list of integers present in memory, with `timesTwo`/`timesThree`/`timesFive` acting as pointers to different elements inside this same list? Or do they point to independent lists, thus not sharing computation?

In my mind, `timesTwo`/`timesThree`/`timesFive` simply "lag behind" and reuse the values already discovered by the evaluation of `regularSeq`, however I'm not entirely sure this is correct.

3. If I were to implement the sequence in an imperative language (say C or Rust) as an endless stream, I would keep in memory only the values from the head of `timesFive` to the current value, as the older ones are no longer needed to compute further elements. Is the Haskell garbage collector able to see that older values are not reachable anymore and does it deallocate them? Or does it deallocate the entire sequence only when it is discarded in its entirety?

4. I find it quite hard to reason about the memory behavior of Haskell programs, and it is often not apparent to me whether the result of computation is shared or something need to be unnecessarily re-evaluated. What are some general principles and a good framework to reason about this problem?

• Not quite sure where this notion comes from that Haskell or GHC does automatic memoization, it does not. If you don't do it there is no magic adding it. May 22 at 15:52
• @cafce25 Ok, I agree the term "memoization" is improper. What I wanted to express is that the naive Fibonacci I wrote needlessly recomputes `fib 1` in both `fib (n-1)` and `fib (n-2)`, whereas I expect `regularSeq` to somehow "reuse" the already computed elements in the evaluation of the `times*` subexpressions. I don't know how to name this fact. I don't even know whether it's true. That's basically the question. May 22 at 15:57

## 1 Answer

Since the computation of a new number in the sequence relies on previous values further back, are older values of regularSeq "cached"/"memoized" and reused in the computation of timesTwo/timesThree/timesFive? Or does the recursive code spawn an inefficient degree-3 tree of computations similar to the naive Fibonacci implementation?

They are simply stored in the list as soon as they are produced, resulting in an efficient computation. This is unlike your `fib` example.

Memoization is a related, but different concept which makes computing `f x` fast when `f x` was previously computed before for the same argument `x`. In your case, `regularSeq` is not a function, but only a list. No memoization is needed.

Operationally, you can think of its state as being `regularSeq = x0 : x1 : ... : xN : <<to be computed>>` where the last tail is a to-be-evaluated expression.

During the evlauation of regularSeq, is there only a single list of integers present in memory, with timesTwo/timesThree/timesFive acting as pointers to different elements inside this same list? Or do they point to independent lists, thus not sharing computation?

`timesTwo/...` are distinct lists, but they indeed reuse the values stored inside `regularSeq`.

In my mind, timesTwo/timesThree/timesFive simply "lag behind" and reuse the values already discovered by the evaluation of regularSeq, however I'm not entirely sure this is correct.

I think this is a good intuition. The idea is that whenever we read the next element from `regularSeq`, its code demands the next element from `timesTwo/...` according to how `union` works. That will in turn access the already-evaluated data in `regularSeq` (the "lag behind" you mentioned) and produce the result.

If I were to implement the sequence in an imperative language (say C or Rust) as an endless stream, I would keep in memory only the values from the head of timesFive to the current value, as the older ones are no longer needed to compute further elements. Is the Haskell garbage collector able to see that older values are not reachable anymore and does it deallocate them? Or does it deallocate the entire sequence only when it is discarded in its entirety?

Garbage collection should indeed make your code work in O(1) memory overhead beyond the data actually stored in `regularSeq`. This is because in order to generate one more element in `regularSeq` we only need to evaluate the "next" elements from `timesTwo/...`. So, at any time, we only have the three "next" elements in memory, plus old ones that will be GC'd soon.

The optimizer might even be able to avoid generating the lists `timesTwo/...` since they will be GC'd anyway. To see if this is the case, one must usually check the GHC Core resulting from the optimizer.

I find it quite hard to reason about the memory behavior of Haskell programs, and it is often not apparent to me whether the result of computation is shared or something need to be unnecessarily re-evaluated. What are some general principles and a good framework to reason about this problem?

It is indeed hard. In my opinion, understanding Haskell performance is the hardest task in Haskell programming. Since so much optimization is going on underneath the hood, it is hard to guess what is really going on. At best, with experience, one can get some intuition, but it is still a bit of a dark art.

To improve the intuition, one can try reading the Simon Peyton-Jones book on the implementation of functional languages, even if it's old nowadays. You can also try experimenting with `:sprint` to observe thunks as they are computed. Or `ghc-vis` if that still works, and you feel really adventurous.