As far as I can tell, one of the big uses of the monadic bind operation is to do variable substitution such as

```
do x <- maybeComputeSomething
y <- maybeComputeSomethingElse
maybeDoStuff x y
```

This is all well and good if maybeComputeSomething, maybeComputeSomethingElse, and maybeDoStuff all return Maybe values, but I feel like this form of iterated substitution would be useful in computations even if there wasn't the possibility of a returned Nothing. Since the identity is a monad, I would in some sense expect to be able to do something such as

```
do x <- computeSomething
y <- computeSomethingElse
doStuff x y
```

which would expand to something looking like

```
computeSomething >>= (\x ->
computeSomethingElse >>= (\y ->
doStuff x y))
```

and since bind in the identity monad is simply x >>= f = f x, this would act as

```
doStuff computeSomething computeSomethingElse
```

if >>= were treated as the identity monad's bind, but this (unsurprisingly) fails, because after all I never explicitly stated a monad (unlike the Maybe example when the types are clearly of the form Maybe a) and if Haskell assumed the identity monad everywhere the majority of cases would get cluttered up quite fast by the required disambiguations.

So this leads me to my question. I want some code that feels like

```
do x <- computeSomething
y <- computeSomethingElse
doStuff x y
```

and that does the same thing as

```
doStuff computeSomething computeSomthingElse
```

I understand that I could do this by explicitly defining an Id monad which looks like Maybe except without the Nothing possibility, but this takes types a -> Id a, and so doesn't really define the identity monad. Furthermore, my functions now have to have types a -> Id b, whereas I would really like them to still be of the form a -> b. Is there a way to create the repeated substitution feel without introducing complexity in the types involved?

`let x = computeSomething; y = computeSomethingElse in doStuff x y`

? – jho Mar 25 '11 at 10:54`let x = computeSomething; x = workWith x in workMoreWith x`

although I guess that would work? – Brian Hamrick Mar 25 '11 at 19:31`let a = 1; a = a+1 in a`

and it didn't compile, which doesn't make sense to me since it should seem to expand to`(\a -> (\a -> a) a+1) 1`

, which is fine, but the code`do a <- Just 1; a <- Just (a+1); Just (a+1)`

gives`Just 3`

, as expected, since that is actually`Just 1 >>= (\a -> Just (a+1) >>= (\a -> Just (a+1)))`

. This is a pretty big advantage which comes from the fact that the bind operator separates the lambda expressions enough to allow for reuse of the variable name. – Brian Hamrick Mar 25 '11 at 19:50`a`

is the one you are defining.`let a = a + 1`

will blow up for most numerical types. but consider`let ones = 1 : ones in ones`

which uses the same construction, and generates an infinite list by referencing itself. To implement your example, you'd need to alpha rename the second variable:`let a = 1; a' = a + 1 in a'`

or just`b where b = a + 1; a + 1`

. There is no "non-capturing variable binding" let (a la scheme/ml's let) in Haskell. With Haskell 2010 you can exploit pattern guards to get some semblance of this, but I'm out of room. – Edward Kmett Mar 25 '11 at 20:12`b where b = a + 1; a = 1`

– Edward Kmett Mar 26 '11 at 1:01