Haskell is a non-strict language by definition, all implementations I'm aware of use lazy evaluation to provide the non-strict semantics.

The analogous code (with arguments for the start and end, so a compile-time evaluation isn't possible)

```
val :: Int -> Int -> Int
val low high = sum $ filter even [low .. high]
```

computes the sum with only one traversal, and in constant small memory. `[low .. high]`

is syntactic sugar for `enumFromTo low high`

, and the definition of `enumFromTo`

for `Int`

is basically

```
enumFromTo x y
| y < x = []
| otherwise = go x
where
go k = k : if k == y then [] else go (k+1)
```

(actually, GHC's implementation uses unboxed `Int#`

s for reasons of efficiency in the worker `go`

, but that has no influence on the semantics; for other `Integral`

types, the definition is analogous).

The definition of `filter`

is

```
filter :: (a -> Bool) -> [a] -> [a]
filter _pred [] = []
filter pred (x:xs)
| pred x = x : filter pred xs
| otherwise = filter pred xs
```

and `sum`

:

```
sum l = sum' l 0
where
sum' [] a = a
sum' (x:xs) a = sum' xs (a+x)
```

Assembling that, even without any optimisations, the evaluation would proceed

```
sum' (filter even (enumFromTo 1 6)) 0
-- Now it must be determined whether the first argument of sum' is [] or not
-- For that, the application of filter must be evaluated
-- For that, enumFromTo must be evaluated
~> sum' (filter even (1 : go 2)) 0
-- Now filter knows which equation to use, unfortunately, `even 1` is False
~> sum' (filter even (go 2)) 0
~> sum' (filter even (2 : go 3)) 0
-- 2 is even, so
~> sum' (2 : filter even (go 3)) 0
~> sum' (filter even (go 3)) (0+2)
-- Once again, sum asks whether filter is done or not, so filter demands another value or []
-- from go
~> sum' (filter even (3 : go 4)) 2
~> sum' (filter even (go 4)) 2
~> sum' (filter even (4 : go 5)) 2
~> sum' (4 : filter even (go 5)) 2
~> sum' (filter even (go 5)) (2+4)
~> sum' (filter even (5 : go 6)) 6
~> sum' (filter even (go 6)) 6
~> sum' (filter even (6 : [])) 6
~> sum' (6 : filter even []) 6
~> sum' (filter even []) (6+6)
~> sum' [] 12
~> 12
```

That would of course be less efficient than the loop, since for each element of the enumeration, a list cell has to be produced, then for each element passing the filter a list cell has to be produced, only to be immediately consumed by the sum.

Let's check that the memory usage is indeed small:

```
module Main (main) where
import System.Environment (getArgs)
main :: IO ()
main = do
args <- getArgs
let (low, high) = case args of
(a:b:_) -> (read a, read b)
_ -> error "Want two args"
print $ sum $ filter even [low :: Int .. high]
```

and run it,

```
$ ./sumEvens +RTS -s -RTS 1 1000000
250000500000
40,071,856 bytes allocated in the heap
12,504 bytes copied during GC
44,416 bytes maximum residency (2 sample(s))
21,120 bytes maximum slop
1 MB total memory in use (0 MB lost due to fragmentation)
Tot time (elapsed) Avg pause Max pause
Gen 0 75 colls, 0 par 0.00s 0.00s 0.0000s 0.0000s
Gen 1 2 colls, 0 par 0.00s 0.00s 0.0002s 0.0003s
INIT time 0.00s ( 0.00s elapsed)
MUT time 0.01s ( 0.01s elapsed)
GC time 0.00s ( 0.00s elapsed)
EXIT time 0.00s ( 0.00s elapsed)
Total time 0.01s ( 0.01s elapsed)
%GC time 6.1% (7.6% elapsed)
Alloc rate 4,367,976,530 bytes per MUT second
Productivity 91.8% of total user, 115.8% of total elapsed
```

It allocated about 40MB for 0.5 million list cells^{(1)} and a bit of change, but the maximum residency was about 44KB. Running it with an upper limit of 10 million, the overall allocation (and running time) grows by a factor of 10 (minus constant stuff), but the maximum residency remains the same.

^{(1)} GHC fuses the enumeration and the filter, and produces only the even numbers in the range at type `Int`

. Unfortunately, it cannot fuse away `sum`

, since that is a left fold, and GHC's fusion framework only fuses right folds.

Now, to fuse also the `sum`

, one must do a lot of work teaching GHC to do that with rewrite rules. Fortunately, that has been done for many algorithms in the `vector`

package, and if we use that,

```
module Main where
import qualified Data.Vector.Unboxed as U
import System.Environment (getArgs)
val :: Int -> Int -> Int
val low high = U.sum . U.filter even $ U.enumFromN low (high - low + 1)
main :: IO ()
main = do
args <- getArgs
let (low, high) = case args of
(a:b:_) -> (read a, read b)
_ -> error "Want two args"
print $ val low high
```

we get a faster programme that doesn't even allocate any list cells anymore, the pipeline *is* really rewritten to the loop:

```
$ ./sumFilter +RTS -s -RTS 1 10000000
25000005000000
72,640 bytes allocated in the heap
3,512 bytes copied during GC
44,416 bytes maximum residency (1 sample(s))
17,024 bytes maximum slop
1 MB total memory in use (0 MB lost due to fragmentation)
Tot time (elapsed) Avg pause Max pause
Gen 0 0 colls, 0 par 0.00s 0.00s 0.0000s 0.0000s
Gen 1 1 colls, 0 par 0.00s 0.00s 0.0001s 0.0001s
INIT time 0.00s ( 0.00s elapsed)
MUT time 0.01s ( 0.01s elapsed)
GC time 0.00s ( 0.00s elapsed)
EXIT time 0.00s ( 0.00s elapsed)
Total time 0.01s ( 0.01s elapsed)
%GC time 1.0% (1.2% elapsed)
Alloc rate 7,361,805 bytes per MUT second
Productivity 97.7% of total user, 111.5% of total elapsed
```

Here's the core that GHC produces for (the worker of) `val`

, if somebody is interested:

```
Rec {
Main.main_$s$wfoldlM'_loop [Occ=LoopBreaker]
:: GHC.Prim.Int# -> GHC.Prim.Int# -> GHC.Prim.Int# -> GHC.Prim.Int#
[GblId, Arity=3, Caf=NoCafRefs, Str=DmdType LLL]
Main.main_$s$wfoldlM'_loop =
\ (sc_s303 :: GHC.Prim.Int#)
(sc1_s304 :: GHC.Prim.Int#)
(sc2_s305 :: GHC.Prim.Int#) ->
case GHC.Prim.># sc1_s304 0 of _ {
GHC.Types.False -> sc_s303;
GHC.Types.True ->
case GHC.Prim.remInt# sc2_s305 2 of _ {
__DEFAULT ->
Main.main_$s$wfoldlM'_loop
sc_s303 (GHC.Prim.-# sc1_s304 1) (GHC.Prim.+# sc2_s305 1);
0 ->
Main.main_$s$wfoldlM'_loop
(GHC.Prim.+# sc_s303 sc2_s305)
(GHC.Prim.-# sc1_s304 1)
(GHC.Prim.+# sc2_s305 1)
}
}
end Rec }
```

couldeven optimize this to compile-time evaluation:`val sum = 250000500000`

. Maybe some compilers do? – leemes Jan 7 '13 at 22:21not knownat compile time. – Tomás Senart Jan 7 '13 at 22:24