No, but you can use better functions. I'm not talking about `V.map (+64)`

, which would make things certainly a lot faster, but about `nTimes`

. We have three candidates that already do what `nTimes`

does:

```
{-# INLINE nTimesFoldr #-}
nTimesFoldr :: Int -> (a -> a) -> a -> a
nTimesFoldr n f x = foldr (.) id (replicate n f) $ x
{-# INLINE nTimesIterate #-}
nTimesIterate :: Int -> (a -> a) -> a -> a
nTimesIterate n f x = iterate f x !! n
{-# INLINE nTimesTail #-}
nTimesTail :: Int -> (a -> a) -> a -> a
nTimesTail n f = go n
where
{-# INLINE go #-}
go n x | n <= 0 = x
go n x = go (n - 1) (f x)
```

All versions take around 8 seconds, compared to the 40 seconds your versions take. Joachim's version also takes 8 seconds, by the way. Note that the `iterate`

version takes more memory on my system. While there is an unroll plugin for GHC, it hasn't been updated in the last five years (it uses custom ANNotations).

# No unroll at all?

However, before we despair, how well does GHC actually try to inline everything? Let's use `nTimesTail`

and `nTimes 1`

:

```
module Main where
import qualified Data.Vector.Unboxed as V
{-# INLINE incAll #-}
incAll :: V.Vector Int -> V.Vector Int
incAll = V.map (+ 1)
{-# INLINE nTimes #-}
nTimes :: Int -> (a -> a) -> a -> a
nTimes n f = go n
where
{-# INLINE go #-}
go n x | n <= 0 = x
go n x = go (n - 1) (f x)
main :: IO ()
main = do
let size = 100000000 :: Int
let array = V.replicate size 0 :: V.Vector Int
print $ V.sum (nTimes 1 incAll array)
```

```
$ stack ghc --package vector -- -O2 -ddump-simpl -dsuppress-all SO.hs
```

```
main2 =
case (runSTRep main3) `cast` ...
of _ { Vector ww1_s9vw ww2_s9vx ww3_s9vy ->
case $wgo 1 ww1_s9vw ww2_s9vx ww3_s9vy
of _ { (# ww5_s9w3, ww6_s9w4, ww7_s9w5 #) ->
```

We can stop right there. `$wgo`

is the `go`

defined above. Even with `1`

GHC does not unroll the loop. It's disturbing since `1`

is a constant.

# Templates to the rescue

But alas, it's not all for naught. If C++ programmers are able to do the following for compile time constants, so should we, right?

```
template <int N>
struct Call{
template <class F, class T>
static T call(F f, T && t){
return f(Call<N-1>::call(f,std::forward<T>(t)));
}
};
template <>
struct Call<0>{
template <class F, class T>
static T call(F f, T && t){
return t;
}
};
```

And sure enough, we can, with TemplateHaskell^{*}:

```
-- Times.sh
{-# LANGUAGE TemplateHaskell #-}
module Times where
import Control.Monad (when)
import Language.Haskell.TH
nTimesTH :: Int -> Q Exp
nTimesTH n = do
f <- newName "f"
x <- newName "x"
when (n <= 0) (reportWarning "nTimesTH: argument non-positive")
let go k | k <= 0 = VarE x
go k = AppE (VarE f) (go (k - 1))
return $ LamE [VarP f,VarP x] (go n)
```

What does `nTimesTH`

do? It creates a new function where the first name `f`

is going to be applied to the second name `x`

for a total of `n`

times. `n`

now needs to be a compile-time constant, which suits us, since loop-unrolling is only possible with compile-time constants:

```
$(nTimesTH 0) = \f x -> x
$(nTimesTH 1) = \f x -> f x
$(nTimesTH 2) = \f x -> f (f x)
$(nTimesTH 3) = \f x -> f (f (f x))
...
```

Does it work? And is it fast? How fast compared to `nTimes`

? Let's try another `main`

for that:

```
-- SO.hs
{-# LANGUAGE TemplateHaskell #-}
module Main where
import Times
import qualified Data.Vector.Unboxed as V
{-# INLINE incAll #-}
incAll :: V.Vector Int -> V.Vector Int
incAll = V.map (+ 1)
{-# INLINE nTimes #-}
nTimes :: Int -> (a -> a) -> a -> a
nTimes n f = go n
where
{-# INLINE go #-}
go n x | n <= 0 = x
go n x = go (n - 1) (f x)
main :: IO ()
main = do
let size = 100000000 :: Int
let array = V.replicate size 0 :: V.Vector Int
let vTH = V.sum ($(nTimesTH 64) incAll array)
let vNorm = V.sum (nTimes 64 incAll array)
print $ vTH == vNorm
```

```
stack ghc --package vector -- -O2 SO.hs && SO.exe +RTS -t
```

```
True
<<ghc: 52000056768 bytes, 66 GCs, 400034700/800026736 avg/max bytes residency (2 samples), 1527M in use, 0.000 INIT (0.000 elapsed), 8.875 MUT (9.119 elapsed), 0.000 GC (0.094 elapsed) :ghc>>
```

It yields the correct result. How fast is it? Let's use another `main`

again:

```
main :: IO ()
main = do
let size = 100000000 :: Int
let array = V.replicate size 0 :: V.Vector Int
print $ V.sum ($(nTimesTH 64) incAll array)
```

```
800,048,112 bytes allocated in the heap
4,352 bytes copied during GC
42,664 bytes maximum residency (1 sample(s))
18,776 bytes maximum slop
764 MB total memory in use (0 MB lost due to fragmentation)
Tot time (elapsed) Avg pause Max pause
Gen 0 1 colls, 0 par 0.000s 0.000s 0.0000s 0.0000s
Gen 1 1 colls, 0 par 0.000s 0.049s 0.0488s 0.0488s
INIT time 0.000s ( 0.000s elapsed)
MUT time 0.172s ( 0.221s elapsed)
GC time 0.000s ( 0.049s elapsed)
EXIT time 0.000s ( 0.049s elapsed)
Total time 0.188s ( 0.319s elapsed)
%GC time 0.0% (15.3% elapsed)
Alloc rate 4,654,825,378 bytes per MUT second
Productivity 100.0% of total user, 58.7% of total elapsed
```

Well, compare that to the 8s. So for a **TL;DR**: if you have compile-time constants, and you want to create and/or modify your code based on that constants, consider Template Haskell.

_{* Please note that this is my first Template Haskell code I've ever written. Use with care. Don't use too large n, or you might end up with a messed up function.}