# Why is power set considered non-deterministic example in haskell?

Given a set [1,2,3] the power set is unique. Why do we say it's non deterministic? Consider another example

``````[1,2] >>= \n -> ['a','b'] >>= \ch -> return (n,ch)
``````

Why is this function non-deterministic?

If I consider `\ch -> return (n,ch)` as the second function where is the first?

And if the first function is

``````\n -> ['a','b'] >>= \ch -> return (n,ch)
``````

Why is it evaluation from right to left.

Shouldn't it be `\n -> (function)`?

And what function is this `(['a','b'] >>= \ch -> return (n,ch))`?

If it's left to right It can't evaluate the second `\ch` function without using the first part `['a','b']` which doesn't have to do anything with `'n'` parameter.

• List are not sets, I suspect that's the cause of confusion here. Powerset as such is perfectly deterministic, and list operations are deterministic too, but since there's no 1:1 correspondence between lists and sets represented by them, a "powerset" implementation by lists isn't quite well-specified. Jan 21, 2015 at 12:02
• Who says it's non-deterministic? I ask because either they are wrong or you have misunderstood their intention. We commonly say the list monad allows us to model non-determinism – that doesn't mean the result of our computations are non-deterministic all the time – quite the opposite. Lists allow us to model non-determinism deterministically. By representing a single value with a list of possible values, and treating it as sort of a single value, we can pretend we are working with single values when in fact we are working with all possible combinations of values.
– kqr
Jan 21, 2015 at 12:19