# Irrefutable pattern does not leak memory in recursion, but why?

The `mapAndSum` function in the code block all the way below combines `map` and `sum` (never mind that another `sum` is applied in the main function, it just serves to make the output compact). The `map` is computed lazily, while the `sum` is computed using an accumulating parameter. The idea is that the result of `map` can be consumed without ever having the complete list in memory, and (only) afterwards the `sum` is available "for free". The main function indicates that we had a problem with irrefutable patterns when calling `mapAndSum`. Let me explain this problem.

According to the Haskell standard, the irrefutable pattern example `let (xs, s) = mapAndSum ... in print xs >> print s` is translated into

``````(\ v ->    print (case v of { (xs, s) -> xs })
>> print (case v of { (xs, s) -> s }))
\$ mapAndSum ...
``````

And hence, both `print` calls carry a reference to the whole pair, which leads to the whole list being kept in memory.

We (my colleague Toni Dietze and I) solved this using an explicit `case` statement (compare "bad" vs "good2"). BTW, finding this out took us a considerable amount of time..!

Now, what we do not understand is two-fold:

• Why does `mapAndSum` work in the first place? It also uses an irrefutable pattern, so it should also keep the whole list in memory, but it obviously doesn't. And converting the `let` into a `case` would make the function behave completely unlazy (to the point that the stack overflows; no pun intended).

We had a look at the "core" code generated by GHC, but as far as we could interpret it, it actually contained the same translation of `let` as the one above. So no clue here, and more confusion instead.

• Why does "bad?" work when optimization is turned off, but not when it is turned on?

One remark concerning our actual application: we want to achieve stream processing (format conversion) of a large text file while also accumulating some value that is then written to a separate file. As indicated, we were successful, but the two questions remain, and answers may improve our understanding of GHC for upcoming tasks and problems.

Thank you!

``````{-# LANGUAGE BangPatterns #-}

-- Tested with The Glorious Glasgow Haskell Compilation System, version 7.4.2.

module Main where

import Control.Arrow (first)
import Data.List (foldl')
import System.Environment (getArgs)

mapAndSum :: Num a => (a -> b) -> [a] -> ([b], a)
mapAndSum f = go 0
where go !s (x : xs) = let (xs', s') = go (s + x) xs in (f x : xs', s')
-- ^ I have no idea why it works here. (TD)
go !s []       = ([], s)

main :: IO ()
main = do
let foo  = mapAndSum (^ (2 :: Integer)) [1 .. 1000000 :: Integer]
let sum' = foldl' (+) 0
args <- getArgs
case args of
["bad" ]  -> let (xs, s) = foo in print (sum xs) >> print s
["bad?"]  -> print \$ first sum' \$ foo
-- ^ Without ghc's optimizer, this version is as memory
-- efficient as the “good” versions
-- With optimization “bad?” is as bad as “bad”. Why? (TD)
["good1"] -> print \$ first' sum' \$ foo
where first' g (x, y) = (g x, y)
["good2"] -> case foo of
(xs, s) -> print (sum' xs) >> print s
["good3"] -> (\ (xs, s) -> print (sum' xs) >> print s) \$ foo
_ -> error "Sorry, I do not understand."
``````
-
Your `mapAnsSum` function might be improved by using `mapAccumL` from Data.Traversable. –  Laar Jul 24 '12 at 7:47
I assume you mean “ghc’s optimizer” in the comment, correct? –  Joachim Breitner Jul 24 '12 at 7:55
Yes, sorry, we mean ghc's optimizer. –  buechse Jul 24 '12 at 8:05
Perhaps I am missing something, but you do not seem to be using any irrefutable patterns. –  dave4420 Jul 24 '12 at 8:06
This document details how let expressions are converted into case with an irrefutable pattern: haskell.org/onlinereport/haskell2010/… Summary: "Pattern bindings are matched lazily; an implicit ~ makes these patterns irrefutable" –  buechse Jul 24 '12 at 8:10

Let me first answer why `mapAndSome` can work good at all: What you see is (very likely) the effect of an optimization described by Philip Wadler in “Fixing some space leaks with a garbage collector”. Short summary: If the garbage collector sees a thunk of the form `fst x` and `x` is already evaluated to the tuple constructor, e.g. `(y,z)`, it will replace `fst x` by `y`, possibly freeing up `z` if it is not referenced anywhere else.

In your code, the `s'` will, once the result of `go` is evaluated to a tuple and after one round of GCing, not keep a reference to the tuple but will be replaced by the accumulated parameter.

Now let’s look a the other patterns by investigating core. The `foo` binding is compiled to:

``````foo_r2eT :: ([Type.Integer], Type.Integer)

foo_r2eT =
case \$wgo_r2eP mapAndSum1 lvl2_r2eS
of _ { (# ww1_s2d7, ww2_s2d8 #) ->
(ww1_s2d7, ww2_s2d8)
}
``````

Here is the code in the `"bad"` case (`lvl18_r2fd` is "bad"):

``````case eqString ds_dyA lvl18_r2fd of _ {
False -> \$wa_s2da new_s_a14o;
True ->
case ds1_dyB of _ {
[] ->
case Handle.Text.hPutStr2
Handle.FD.stdout lvl17_r2fc True new_s_a14o
of _ { (# new_s1_X15h, _ #) ->
Handle.Text.hPutStr2
Handle.FD.stdout lvl16_r2fb True new_s1_X15h
};
: ipv_sIs ipv1_sIt -> \$wa_s2da new_s_a14o
}
``````

We can see that two values at the module level are printed, `lvl17_r2fc` and `lvl16_r2fb`, here is their code:

``````lvl17_r2fc :: String
[GblId]
lvl17_r2fc =
case foo_r2eT of _ { (xs_Xqp, s_Xq9) ->
\$w\$cshowsPrec
0
(Data.List.sum_sum' xs_Xqp Data.List.genericDrop2)
([] @ Char)
}

lvl16_r2fb :: String
[GblId]
lvl16_r2fb =
case foo_r2eT of _ { (xs_apS, s_Xqp) ->
\$w\$cshowsPrec 0 s_Xqp ([] @ Char)
}
``````

Why are they bound at the module level, and not inside the expression? This is an effect of lazy lifting, another optimization that increases sharing and hence sometime has an adverse effect on space performance. See GHC ticket 719 for another occurrence of this effect.

So what happens is that the evaluation of `lvl17_r2fc` causes `foo` to be evaluated, and the left entry lazily printed. Unfortunately, `lvl16_r2fb` is still live and retains the full tuple. And because the garbage collector (seems) to fail to see that this is an selector thunk, Wadler’s optimization does not kick in.

In contrast, here is the code for `"good1"` a.k.a. `lvl8_r2f1`:

``````            case eqString ds_dyA lvl8_r2f1 of _ {
False -> \$wa2_s2dI w3_s2cF;
True ->
case ds1_dyB of _ {
[] ->
Handle.Text.hPutStr2
Handle.FD.stdout lvl7_r2f0 True w3_s2cF;
: ipv_sHg ipv1_sHh -> \$wa2_s2dI w3_s2cF
}
} } in
``````

where the printed value is this string:

``````lvl7_r2f0 :: String
[GblId]
lvl7_r2f0 =
case foo_r2eT of _ { (x_af6, y_af7) ->
show_tuple
(:
@ ShowS
(let {
w2_a2bY [Dmd=Just L] :: Type.Integer

w2_a2bY = lgo_r2eU mapAndSum1 x_af6 } in
\ (w3_a2bZ :: String) ->
\$w\$cshowsPrec 0 w2_a2bY w3_a2bZ)
(:
@ ShowS
(\ (w2_a2bZ :: String) ->
\$w\$cshowsPrec 0 y_af7 w2_a2bZ)
([] @ ShowS)))
([] @ Char)
}
``````

As you can see the tuple is taken apart only once, and both values are used. So nothing refers to the tuple as a whole and it can be garbage collected. Similar for `"good2"` and `"good3"`.

Now to `"bad?"`: In the unoptimized case, we get this code:

`````` case eqString ds_dyA (unpackCString# "bad?")
of _ {
False -> fail2_dyN realWorld#;
True ->
case ds1_dyB of _ {
[] ->
\$
@ (Type.Integer, Type.Integer)
@ (IO ())
(System.IO.print
@ (Type.Integer, Type.Integer) \$dShow_rzk)
(\$
@ ([Type.Integer], Type.Integer)
@ (Type.Integer, Type.Integer)
(Control.Arrow.first
@ (->)
Control.Arrow.\$fArrow(->)
@ [Type.Integer]
@ Type.Integer
@ Type.Integer
sum'_rzm)
foo_rzl);
: ipv_szd ipv1_sze -> fail2_dyN realWorld#
}
} } in
``````

The implementation of `first` via `***` uses refutable patterns, so the kind of selector thunks that the garbage collector handles well are generated.

In the optimized case, things are a bit scattered, but anyways here is the relevant code (the last value is the one that is being printed):

``````w_r2f2 :: Type.Integer

w_r2f2 =
case foo_r2eT of _ { (x_aI1, y_aI2) ->
lgo_r2eU mapAndSum1 x_aI1
}

lvl9_r2f3 :: String -> String
[GblId, Arity=1]
lvl9_r2f3 =
\ (w2_a2bZ :: String) ->
\$w\$cshowsPrec 0 w_r2f2 w2_a2bZ

w1_r2f4 :: Type.Integer

w1_r2f4 = case foo_r2eT of _ { (x_aI6, y_aI7) -> y_aI7 }

lvl10_r2f5 :: String -> String
[GblId, Arity=1]
lvl10_r2f5 =
\ (w2_a2bZ :: String) ->
\$w\$cshowsPrec 0 w1_r2f4 w2_a2bZ

lvl11_r2f6 :: [ShowS]
[GblId]
lvl11_r2f6 =
:
@ ShowS lvl10_r2f5 ([] @ ShowS)

lvl12_r2f7 :: [ShowS]
[GblId]
lvl12_r2f7 = : @ ShowS lvl9_r2f3 lvl11_r2f6

lvl13_r2f8 :: ShowS
[GblId]
lvl13_r2f8 = show_tuple lvl12_r2f7

lvl14_r2f9 :: String
[GblId]
lvl14_r2f9 = lvl13_r2f8 ([] @ Char)
``````

The use of `first` has been inlined. We see two calls to `case foo_r2eT`, so this is prone for a space leak, despite `w1_rf24` looking like a selector (so I’d expect the runtime to apply Wadler’s optimization). Maybe it does not work well for static thunks? Indeed the commentary, if up to date, only talks about dynamic allocated selector thunks. So if your `foo` were not a module-level-value (or rather lazy-liftable into one) but rather dependent on some input, `w1_rf24` might be dynamically allocated and hence eligible for the special treatment. But then the code might look very different anyways.

-
If I am getting you right, we are looking at an implementation issue rather than a language issue? In other words I could not find anything about my problem in the Haskell report or the core output, and with another Haskell implementation all the variants we have in the main function may behave like "bad"? In still other words, our performance critical program sits on very thin ice? –  buechse Jul 24 '12 at 8:18
Well, the Haskell report makes no statement about space behavior, so you are lost there anyways. And yes, other implementations of Haskell might perform bad in each of the cases. –  Joachim Breitner Jul 24 '12 at 8:21
I believe that this is what things like the `pipe` library are about, but I’m not an expert on this. –  Joachim Breitner Jul 24 '12 at 8:35
The situation is even worse as the compiler is sometimes unable to apply the optimization that Wadler suggested, for example see this thread haskell.org/pipermail/glasgow-haskell-users/2010-October/…. There are cases where other optimizations are applied first and the compiler is unable to recognize that the program projects to one component of a constructor. –  Jan Christiansen Jul 24 '12 at 8:37
All good, except it was not invented by Phil Wadler. It was documented by Phil, but invented independently by at least two people before Phil wrote that paper. –  augustss Jul 24 '12 at 9:01