Using `ghci`

I have computed:

```
Prelude> let m = [1,2]
Prelude> let ys = [4, 5, 6]
Prelude> m >>= (\x -> ys >>= (\y -> return (x, y)))
[(1,4),(1,5),(1,6),(2,4),(2,5),(2,6)]
```

The monadic expression above doesn't seem to correspond to either side of the monad associativity law:

```
(m >>= f) >>= g ≡ m >>= (\x -> f x >>= g)
```

I would like to know how monad associativity can be applied to the expression:

```
m >>= (\x -> ys >>= (\y -> return (x, y)))
```

Because `return (x,y)`

closes on both the surrounding function and the one containing it, it seems that an intermediate monad, as exists on the left side of the associativity law `(m >>= f)`

, cannot exist in this example.

`ys`

isn't consuming the bound`x`

, i.e. your function is not in monadic normal form. – shelf Mar 2 at 7:17`\x -> x`

is a function, but`\x -> (x,y)`

isn't. For example,`[1,2] >>= (\x -> [x, x+1] >>= (\y -> [y+20,y-20]))`

gives`[21,-19,22,-18,22,-18,23,-17]`

and (respecting the associative law)`[1,2] >>= (\x -> [x, x+1]) >>= (\y -> [y+20,y-20])`

gives`[21,-19,22,-18,22,-18,23,-17]`

However, while`[1,2] >>= (\x -> [x, x+1] >>= (\y -> [x+y+20,y-20]))`

gives`[22,-19,23,-18,24,-18,25,-17]`

, this`[1,2] >>= (\x -> [x, x+1]) >>= (\y -> [x+y+20,y-20])`

raises an error – Leo D Mar 13 at 5:13