The problem is that Control.Monad.State.Lazy's (>>=) is so lazy that even the ($!) doesn't help you.
Try Control.Monad.State.Strict, that should reach the ($!).
The (>>=) of the lazy state monad doesn't look at all at the (value,state) pair, so the only way to get some evaluation done before the end is reached is having the
m >>= f deconstruct the pair. That doesn't happen here, so you get a huge thunk, that is too large for the stack when runState finally wants a result.
Okay, I've eaten, now I can elaborate. Let me use the old (mtl-1.x) definition of the lazy
State s monad, it's a bit easier to see there without the inner monad. The new (mtl-2.x) definition
type State s = StateT s Identity behaves the same, it's just more writing and reading. The definition of (>>=) was
m >>= k = State $ \s -> let
(a, s') = runState m s
in runState (k a) s'
let bindings are lazy, hence this is
m >>= k = State $ \s -> let
blob = runState m s
in runState (k $ fst blob) (snd blob)
only more readable. So the (>>=) lets the blob completely unevaluated. Evaluation is only required if
k needs to inspect
fst blob to determine how to continue, or
k a needs to inspect
replicateM r tick, the computations are chained with (>>), so the
k in (>>=)'s definition is
const tick. As a constant function, it most definitely doesn't need to inspect its argument. So
tick >> tick becomes
State $ \s ->
let blob1 = (\n -> let n' = n+1 in seq n' ((),n')) s
blob2 = (\m -> let m' = m+1 in seq m' ((),m')) (snd blob1)
seq isn't touched until
blobN has to be evaluated. But needing to evaluate it to the outermost constructor - the pair constructor
(,) - would be enough to trigger the seq and that would in turn lead to complete evaluation here. Now, in
million, nothing requires any evaluation until the final
snd after the
runState is reached. By that time, a thunk with a million layers has been built. Evaluating that thunk requires pushing many
let m' = m+1 in seq m' ((),m') on the stack until the initial state is reached, and if the stack is large enough to hold them, they'd then be popped and applied. So it'd be three traversals, 1. building the thunk, 2. peeling layers from the thunk and pushing them on the stack, 3. consuming the stack.
The (>>=) of Control.Monad.State.Strict is just strict enough to force the
seq s on each bind, thus there's only one traversal, no (nontrivial) thunk is built and the computation runs in constant space.
The definition is
m >>= k = State $ \s ->
case runState m s of
(a, s') -> runState (k a) s'
The important difference is that pattern matching in
case expressions is strict, here the
blob has to be evaluated to the outermost constructor to match it against the pattern in the
m = tick = State (\m -> let m' = m+1 in seq m' ((),m')) the essential part becomes
case let s' = s+1 in seq s' ((),s') of
(a, s'') -> runState (k a) s''
The pattern-match demands the evaluation of
((), s') [to the (,) constructor], by the
seq that is tied to the evaluation of
s' = s+1, everything is fully evaluated on each bind, no thunks, no stack.
However, you still need to be careful. In this case, due to the
($!)) and the shallow structure of the involved types,evaluation kept up with application of
(>>). In general, with deeper structured types and/or without
seqs, C.M.S.Strict also builds large thunks which can lead to stack overflow. The thunks are just a bit simpler and less entangled than those generated by C.M.S.Lazy in those circumstances.
On the other hand, the laziness of C.M.S.Lazy allows other computations that are impossible with C.M.S.Strict. For example, C.M.S.Lazy provides one of the very few monads where
take 100 <$> mapM_ something [1 .. ]
terminates. [But be aware that the state is then unusable; before it could be used, it would have to travel through the entire infinite list. So, if you do something like that, before you can resume state-dependent computations, you have to
put a fresh state.]