# Rewrite a monad computation in prefix notation

I'm trying to figure out how to rewrite a monadic computation with prefix notation (not for real practical goals, just for research), but the problem that one lambda doesn't see another one's parameter

so given a working example

``````*Main> [1, 3, 4] >>= \x -> [x + 1, x - 1] >>= \y -> return (y*x)
[2,0,12,6,20,12]
``````

the rewritten one shows the error on not seeing the parameter of other lambda

``````*Main> (>>=) ( (>>=)  [1, 3, 4] (\x -> [x + 1, x - 1]) ) (\y -> return (y*x))
<interactive>:133:68: Not in scope: `x'
``````

but if I make the last one not using it (by replacing x with y), the computation starts working

``````*Main> (>>=) ( (>>=)  [1, 3, 4] (\x -> [x + 1, x - 1]) ) (\y -> return (y*y))
[4,0,16,4,25,9]
``````

So does full rewriting in prefix notation technically possible? Or this property of accessing other lambdas parameters is exclusive to the infix notation?

-

The problem is that you got the precedences slightly wrong, see also Haskell Precedence: Lambda and operator

The body of a lambda-expression extends as far to the right as possible. Then your example is parenthesized as follows:

``````[1, 3, 4] >>= (\x -> [x + 1, x - 1] >>= (\y -> return (y*x)))
``````

Bringing it into prefix form results in

``````(>>=) [1, 3, 4] (\x -> (>>=) [x + 1, x - 1] (\y -> return (y*x)))
``````

Now `x` is visible inside the body of `\y -> ...`.

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Seems like infix notation containing lambdas (if inference allows them in the operators context) should inject expressions inside the bodies of lambdas, right? Looks natural in your explanation, but I never met this in tutorials. – Maksee Mar 17 '13 at 7:52
@Maksee Your question isn't very clear to me. What do you think is being injected where? – Daniel Wagner Mar 17 '13 at 15:24