This is because `Control.Monad.State`

re-exports `Control.Monad.State.Lazy`

. If you imported, `Control.Monad.State.Strict`

, both would overflow that way.

The reason it overflows with strict `State`

or `IO`

is that `replicateM`

needs to run the action `iterations`

times recursively, before it can build the list. To put it loosely, `replicateM`

must "combine" the "effects" of all the actions it replicates into one giant "effect". The terms "combine" and "effect" are very vague, and can mean an infinite number of different things, but they're about the best we've got for talking about such abstract things. `replicateM`

with a large value will end up overflowing the stack in nearly every choice of monad. It's the fact that it doesn't with lazy `State`

that's bizarre.

To see why it doesn't overflow with lazy `State`

, you need to look into the details of `(>>=)`

for lazy `State`

, and `replicateM`

. The following definitions are greatly simplified, but they reflect the details necessary to illustrate how this works.

```
newtype State s a = State { runState :: s -> (a, s) }
instance Monad (State s) where
return x = State $ \s -> (x, s)
x >>= f = State $ \s -> let (a, s') = runState x s in runState (f a) s'
replicateM :: Monad m => Int -> m a -> m [a]
replicateM 0 _ = return []
replicateM n mx | n < 0 = error "don't do this"
| otherwise =
mx >>= \x -> replicateM (n - 1) mx >>= \xs -> return (x:xs)
```

So first, look at `replicateM`

. Take note that when `n`

is greater than 0, it is a call to `(>>=)`

. So the behavior of `replicateM`

depends closely on what `(>>=)`

does.

When you look at `(>>=)`

, you see it produces a state transition function that binds the results of the state transition function `x`

in a let binding, then returns the result of the transition function that's the result of `f`

applied to arguments from that binding.

Ok, that statement was clear as mud, but it's really important. Let's just look inside the lambda for the moment. Looking at the result of the function `(>>=)`

creates, you see `let {something to do with x} in {something to do with f and the results of the let binding}`

. This is important with lazy evaluation. It means that *just maybe* it can ignore `x`

, or maybe part of it, when it evaluates `(>>=)`

, if the particular function `f`

allows it to. In the case of lazy `State`

, it means that it might be able to delay calculating future state values, if `f`

can produce a constructor before looking at the state.

This turns out to be what allows it to work. The particular way `replicateM`

assembles calls to `(>>=)`

, it results in a function that produces `(:)`

constructors before examining the state passed to them. This allows incremental processing of the list, if the final state is never examined. If you ever look at the final state, that destroys the ability to function incrementally, because the final state requires doing all the work to calculate it. But your use of `evalState`

resulted in the final state being thrown away unexamined, so evaluation was free to proceed incrementally.

`getStdRandom`

that often is never good. The state version is okay but there is also the`Rand`

monad that would make the`roll`

become this`roll = getRandomR (0,1) gen`

and you just change the`evalState`

to`evalRand`

. – DiegoNolan Dec 19 '13 at 19:12`rnd g = v : rnd ng where (v,ng) = randomR (0,1) g`

and then`take`

whatever is needed from the infinite list. Or convert it to a recursive function with accumulator to do sum. Or great many other things. It was the strange results of similar (at least in my head) code that puzzled me. – nope Dec 21 '13 at 7:05