# Why do nested MaybeT's cause exponential allocation

I have a program.

``````import Control.Monad

import System.Environment

tryR :: Monad m => ([a] -> MaybeT m [a]) -> ([a] -> m [a])
tryR f x = do
m <- runMaybeT (f x)
case m of
Just t -> return t
Nothing -> return x

check :: MonadPlus m => Int -> m Int
check x = if x `mod` 2 == 0 then return (x `div` 2) else mzero

foo :: MonadPlus m => [Int] -> m [Int]
foo [] = return []
foo (x:xs) = liftM2 (:) (check x) (tryR foo xs)

runFoo :: [Int] -> [Int]
runFoo x = runIdentity \$ tryR foo x

main :: IO ()
main = do
[n_str] <- getArgs
let n = read n_str :: Int
print \$ runFoo [2,4..n]
``````

The main interesting thing about this program is that it can have many nested layers of MaybeT's. Here, doing so serves absolutely no purpose, but it did in the original program where I encountered this problem.

Care to take a guess of the time complexity of this program?

Okay, you cheated by reading the title of this question. Yes, it's exponential:

``````[jkoppel@dhcp-18-189-103-38:~/tmp]\$ time ./ExpAlloc 50                                                                                                                                        (03-31 17:15)
[1,2,3,4,5,6,7,8,9,10,11,12,13,14,15,16,17,18,19,20,21,22,23,24,25]
./ExpAlloc 50  8.10s user 0.06s system 99% cpu 8.169 total
[jkoppel@dhcp-18-189-103-38:~/tmp]\$ time ./ExpAlloc 52                                                                                                                                        (03-31 17:15)
[1,2,3,4,5,6,7,8,9,10,11,12,13,14,15,16,17,18,19,20,21,22,23,24,25,26]
./ExpAlloc 52  16.10s user 0.12s system 99% cpu 16.227 total
[jkoppel@dhcp-18-189-103-38:~/tmp]\$ time ./ExpAlloc 54                                                                                                                                        (03-31 17:16)
[1,2,3,4,5,6,7,8,9,10,11,12,13,14,15,16,17,18,19,20,21,22,23,24,25,26,27]
./ExpAlloc 54  32.32s user 0.23s system 99% cpu 32.561 total
``````

Some further inspection shows the reason is because it allocates an exponential amount of memory, which naturally takes an exponential amount of time:

``````[jkoppel@dhcp-18-189-103-38:~/tmp]\$ time ./ExpAlloc 40 +RTS -s                                                                                                                                (03-31 17:17)
[1,2,3,4,5,6,7,8,9,10,11,12,13,14,15,16,17,18,19,20]
939,634,520 bytes allocated in the heap
5,382,816 bytes copied during GC
75,808 bytes maximum residency (2 sample(s))
66,592 bytes maximum slop
2 MB total memory in use (0 MB lost due to fragmentation)

Tot time (elapsed)  Avg pause  Max pause
Gen  0      1796 colls,     0 par    0.008s   0.009s     0.0000s    0.0000s
Gen  1         2 colls,     0 par    0.000s   0.000s     0.0001s    0.0001s

INIT    time    0.000s  (  0.000s elapsed)
MUT     time    0.243s  (  0.246s elapsed)
GC      time    0.008s  (  0.009s elapsed)
EXIT    time    0.000s  (  0.000s elapsed)
Total   time    0.252s  (  0.256s elapsed)

%GC     time       3.2%  (3.6% elapsed)

Alloc rate    3,869,930,149 bytes per MUT second

Productivity  96.8% of total user, 95.3% of total elapsed

./ExpAlloc 40 +RTS -s  0.25s user 0.00s system 98% cpu 0.260 total
[jkoppel@dhcp-18-189-103-38:~/tmp]\$ time ./ExpAlloc 42 +RTS -s                                                                                                                                (03-31 17:17)
[1,2,3,4,5,6,7,8,9,10,11,12,13,14,15,16,17,18,19,20,21]
1,879,159,424 bytes allocated in the heap
10,767,048 bytes copied during GC
95,504 bytes maximum residency (3 sample(s))
71,152 bytes maximum slop
2 MB total memory in use (0 MB lost due to fragmentation)

Tot time (elapsed)  Avg pause  Max pause
Gen  0      3593 colls,     0 par    0.016s   0.018s     0.0000s    0.0000s
Gen  1         3 colls,     0 par    0.000s   0.000s     0.0001s    0.0001s

INIT    time    0.000s  (  0.000s elapsed)
MUT     time    0.493s  (  0.498s elapsed)
GC      time    0.016s  (  0.018s elapsed)
EXIT    time    0.000s  (  0.000s elapsed)
Total   time    0.510s  (  0.517s elapsed)

%GC     time       3.1%  (3.5% elapsed)

Alloc rate    3,810,430,292 bytes per MUT second

Productivity  96.8% of total user, 95.7% of total elapsed

./ExpAlloc 42 +RTS -s  0.51s user 0.01s system 99% cpu 0.521 total
[jkoppel@dhcp-18-189-103-38:~/tmp]\$ time ./ExpAlloc 44 +RTS -s                                                                                                                                (03-31 17:17)
[1,2,3,4,5,6,7,8,9,10,11,12,13,14,15,16,17,18,19,20,21,22]
3,758,208,408 bytes allocated in the heap
21,499,312 bytes copied during GC
102,056 bytes maximum residency (5 sample(s))
73,784 bytes maximum slop
2 MB total memory in use (0 MB lost due to fragmentation)

Tot time (elapsed)  Avg pause  Max pause
Gen  0      7186 colls,     0 par    0.032s   0.037s     0.0000s    0.0009s
Gen  1         5 colls,     0 par    0.000s   0.001s     0.0001s    0.0001s

INIT    time    0.000s  (  0.000s elapsed)
MUT     time    0.979s  (  0.987s elapsed)
GC      time    0.033s  (  0.038s elapsed)
EXIT    time    0.000s  (  0.000s elapsed)
Total   time    1.013s  (  1.024s elapsed)

%GC     time       3.2%  (3.7% elapsed)

Alloc rate    3,840,757,815 bytes per MUT second

Productivity  96.7% of total user, 95.6% of total elapsed

./ExpAlloc 44 +RTS -s  1.01s user 0.01s system 99% cpu 1.029 total
``````

I cannot for the life of me figure out why it does this. I'd appreciate any light people could shed on the situation.

• Maybe I'm just not experienced enough, but I am having a hard time understanding the recursion between `foo`/`tryR`/`check`. If you expand on how you think the function behaves, you will (a) make it easier for someone else to step in with an answer, and (b) perhaps discover the answer yourself by explaining the code more thoroughly. FWIW to me it looks like it ought to be quadratic, but as noted I don't think I have a clear idea of what is really going on. Commented Mar 31, 2017 at 22:01
• Well, it definitely is exponential. Also, optimisation (`-O2`) changes the performance by a constant factor but does nothing to the scaling. Commented Apr 1, 2017 at 0:09
• Interestingly the exponential behavior disappeared when I wrote `MaybeT` by hand. I traced it back to the implementation of `lift` which uses `liftM` instead of `fmap`... I almost have an explanation there. Commented Apr 1, 2017 at 0:19
• Tangential note: as far as my understanding of the runtime statistics goes, the "bytes allocated" value is best taken as a symptom, rather than a cause -- adding an extra element really doubles the amount of work (cf. Li-yao Xia's answer), which in this case also results in a doubling of the allocations throughout the run. Commented Apr 1, 2017 at 3:26

The transformers package (currently at version 0.5.4.0) implements `MonadTrans` using `liftM`:

``````lift :: Monad m => m a -> MaybeT m a
lift = MaybeT . liftM Just
``````

where `liftM` is a combinator defined as

``````liftM :: Monad m => (a -> b) -> m a -> m b
liftM f m = m >>= \a -> return (f a)
``````

Furthermore, `return` is defined for `MaybeT` as

``````return :: Monad m => a -> MaybeT m a
return a = lift . return
``````

Reduce the definition:

``````return :: Monad m => a -> MaybeT m a
return a = MaybeT (return a >>= \a -> return (Just a))
``````

where the two inner `return` are instantiated at type `m`.

One call to `return @(MaybeT m)` calls `return @m` twice, hence the exponential behavior you observe for a tower of `MaybeT`.

This is fixable by using `fmap` instead of `liftM`, but this is backwards incompatible, when `Functor` was not a superclass of `Monad`.

EDIT: Other transformers do not have this issue, as `return` is not defined using `lift`, which provides an even better fix.

``````return = MaybeT . return . Just
``````

Here is a more minimal test case:

``````{-# LANGUAGE RankNTypes, ScopedTypeVariables #-}
import System.Environment

f :: forall m proxy. Monad m => proxy m -> Int -> ()
f _ 0 = (return () :: m ()) `seq` ()
f _ n = f (undefined :: proxy (MaybeT m)) (n - 1)

main = do
n : _ <- getArgs
f (undefined :: proxy []) (read n) `seq` return ()
``````

Output

``````> for i in {18..21} ; time ./b \$i
./b \$i  0.35s user 0.04s system 99% cpu 0.390 total
./b \$i  0.71s user 0.07s system 99% cpu 0.782 total
./b \$i  1.38s user 0.18s system 99% cpu 1.565 total
./b \$i  2.82s user 0.32s system 100% cpu 3.139 total
``````
• An even simpler/cruder demo: turn on `+s` and feed this to GHCi; then, add an extra `MaybeT` and try again: `return "foo" :: MaybeT ( MaybeT (MaybeT (MaybeT (MaybeT (MaybeT (MaybeT (MaybeT (MaybeT (MaybeT (MaybeT (MaybeT (MaybeT (MaybeT (MaybeT (MaybeT (MaybeT (MaybeT (MaybeT (MaybeT (MaybeT (MaybeT (MaybeT (MaybeT (Identity))))))))))))))))))))))) ) String` Commented Apr 1, 2017 at 1:37
• Also, as you say, making `lift` use `fmap` rather than `liftM` will fix it: `return` for a tower of `MaybeT` will then boil down to to `MaybeT . MaybeT . . . fmap (fmap Just) . fmap Just . return`, which is linear in the height of the tower. Commented Apr 1, 2017 at 1:50
• Have you considered submitting a bugfix to `transformers`? Commented Apr 1, 2017 at 10:10
• BTW `Functor` was always a superclass of `Monad`. It was `Applicative` that was missing from the hierarchy. I don't think there was any rational reason `lift` was defined like that, it was just a regular bug Commented Apr 1, 2017 at 10:13
• `Functor` was made a superclass of `Monad` at the same time as `Applicative` (base 4.7 only has `class Monad m`), and this is why many instances in `transformers` have `(Functor m, Monad m)` constraints. I have reported this bug though I haven't gotten around to fixing it myself. Commented Apr 1, 2017 at 14:56