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I have two functions defined in a piece of haskell code:

lengthwtilde [] = 0
lengthwtilde ~(_:xs) = 1 + lengthwtilde xs

lengthwotilde [] = 0
lengthwotilde (_:xs) = 1 + lengthwotilde xs

When I test them both out in ghci (using :set +s), I find that lengthwtilde (the one with a tilde in front of the pattern match) performs significantly slower than lengthwotilde by about three seconds.

*Main> lengthwtilde [1..10000000]
(19.40 secs, 1731107132 bytes)
*Main> lengthwotilde [1..10000000]
(16.45 secs, 1531241716 bytes)

Why is this?

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1 Answer 1

up vote 24 down vote accepted

Adding a ~ in front of a pattern match makes that match irrefutable. You can think of this as adding extra laziness to a pattern, so that it never fails to match unless that match is absolutely required for evaluation. Here's a simple example:

Prelude> (\ (_:_) -> "non-empty") []
"*** Exception: <interactive>:2:2-23: Non-exhaustive patterns in lambda

Prelude> (\ ~(_:_) -> "oops") []

With the irrefutable pattern match, even though the pattern match fails on an empty list, since no bound variables are evaluated, there's no error. Essentially, the irrefutable pattern match transforms the function to:

\ xs -> let (_:_) = xs in "oops"

It's this extra wrapping of laziness that slows down your length function. If you apply the same let-binding transform to lengthwtilde you get

lengthwtilde [] = 0
lengthwtilde xs' = let (_:xs) = xs' in 1 + lengthwtilde xs

Think about how this is evaluated. At the top level, you get 1+lengthwtilde xs. But xs isn't even evaluated, since it's a let-bound variable. So at the next step first xs is evaluated to determine it matches the second case of lengthwtilde, and the process repeats.

Contrast this to lengthwotilde. In this function, the act of matching on the second case of the function forces the argument to be evaluated as well. The end result is the same, but it's more efficient to be able to unwrap it sooner rather than leaving another thunk to be forced.

Technically lengthwtilde is slightly more complex: the argument is already evaluated in the second branch since that's how we determine which branch we're in, however it gets re-wrapped when passed into the recursive call.

It's useful to be able to see the produced core. Here's the output of lengthwotilde (produced from ghc -O0:

Foo.lengthwotilde =
  \ (@ t_afD)
    (@ a_afE)
    ($dNum_afF :: GHC.Num.Num a_afE)
    (eta_B1 :: [t_afD]) ->
    letrec {
      lengthwotilde1_af2 [Occ=LoopBreaker] :: [t_afD] -> a_afE
      [LclId, Arity=1]
      lengthwotilde1_af2 =
        \ (ds_dgd :: [t_afD]) ->
          case ds_dgd of _ {
            [] -> GHC.Num.fromInteger @ a_afE $dNum_afF (__integer 0);
            : ds1_dge xs_af1 ->
                @ a_afE
                (GHC.Num.fromInteger @ a_afE $dNum_afF (__integer 1))
                (lengthwotilde1_af2 xs_af1)
          }; } in
    lengthwotilde1_af2 eta_B1

Note the function lengthwotilde1_af2 immediately does a case on the argument ds_dgd (this is the input list), and then recurses inside the case, forming a thunk (with some expansions):

1 + len [2..]
1 + (1 + len [3..])
1 + (1 + (1 + len [4..])

which ultimately requires the evaluation of 1 + (1 + (1 + (1 + ..)))

Here's lengthwtilde

Foo.lengthwtilde =
  \ (@ t_afW)
    (@ a_afX)
    ($dNum_afY :: GHC.Num.Num a_afX)
    (eta_B1 :: [t_afW]) ->
    letrec {
      lengthwtilde1_afM [Occ=LoopBreaker] :: [t_afW] -> a_afX
      [LclId, Arity=1]
      lengthwtilde1_afM =
        \ (ds_dgh :: [t_afW]) ->
          case ds_dgh of wild_X9 {
            [] -> GHC.Num.fromInteger @ a_afX $dNum_afY (__integer 0);
            : ipv_sgv ipv1_sgw ->
                @ a_afX
                (GHC.Num.fromInteger @ a_afX $dNum_afY (__integer 1))
                   (case wild_X9 of _ {
                      [] ->
                           @ () "foo.hs:(3,1)-(4,42)|(_ : xs)")
                        `cast` (UnsafeCo () [t_afW] :: () ~# [t_afW]);
                      : ds1_dgk xs_aeH -> xs_aeH
          }; } in
    lengthwtilde1_afM eta_B1

Evaluation of this forms a different thunk:

len [1..]
1 + (len (if null [1..] then error else [2..]))
1 + (len [2..])
1 + (1 + len (if null [2..] then error else [3..]))

which eventually results in the same chain of additions you got the first time, but with some extra logic to handle the irrefutable pattern failures.

Now, if you were running compiled code with any optimizations, ghc would almost certainly spot that the arguments couldn't possibly be null, since they're already evaluated and known to use the (:) constructor at this point. And when I compile the code with ghc -O2 and run it, both functions execute in the same amount of time. They're both pretty bad, because either way results in a chain of thunks. The standard definition of length is much better, as would be a good foldl' definition.

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