# Overflow problems in dealing with IO and MonadRandom and chained computations

So basically I have a computation `step` that takes in a previous result and outputs a `Rand g Path`, where `Path` is a custom data type (think of it like a traveling salesman kind of problem). I'm letting `MonadRandom` handle all of the generator passing and stuff.

I want to find the, say, nth composition of this computation upon itself. Right now I'm using

``````thecomputation :: (RandomGen g) => Rand g Path
thecomputation = (iterate (>>= step) (return startingPath)) !! n
``````

And then to print it out I would run

``````main = do
res <- evalRandIO thecomputation
print res
``````

However, I have a problem

If I pick a high enough `n` (i need on the order of 10^6), I get a stack overflow.

I've managed to track the problem to the fact that thecomputation is actually a heavily composed (nested?) IO object. It's a series of IO computations and so ghc has to keep track of all of those layers of nested IO's, and after enough layers, it gives up.

How am I supposed to deal with this? In an imperative language there really isn't much to this. But what should I do here? Should I force some of the IO's to evaluate or ...?

There is a similar question on this site but I wasn't able to get anything helpful out of the accepted answer so I'm still pretty lost

## Concrete Example

``````import System.Random

data Path = DoublePath Double deriving Show

step :: (RandomGen g) => Path -> Rand g Path
step (DoublePath x) = do
dx <- getRandom
return (DoublePath ((x + dx)/x))

thecomputation :: (RandomGen g) => Rand g Path
thecomputation = (iterate (>>= step) (return (DoublePath 10.0))) !! 1000000

main = do
result <- evalRandIO thecomputation
print result
``````

does overflow on my computer

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Please present a complete example for us to be able to reproduce the problem. –  Nikita Volkov May 14 at 9:17
@NikitaVolkov is this example ok? –  Justin L. May 14 at 9:35

You are bitten by lazyness: Everytime you call `step` on some value `x`, GHC is creating a thunk `step x` that is not evaluated until the final value is required.

A simple fix is to make `step` strict in its argument, e.g. by pattern-matching on `DoublePath !x` (and using `-XBangPatterns`) or inserting `x `seq`` before the body of the function. Then your code finished without stack overflow (heh).

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It is enough to make the type strict. This ought to be second nature especially for numerical and other 'unboxable' parameters and doesn't require a language extension.

``````data Path = DoublePath !Double deriving Show

-- \$ ghc -O2 doublepath.hs
-- ...
-- \$ time ./doublepath
-- DoublePath 1.526581416150007

-- real    0m2.516s
-- user    0m2.307s
-- sys 0m0.092s
``````
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