I think the best way to understand this is to consider what these things are like as set-theoretic sets, as opposed to as Agda `Set`

. suppose you have `A = {a,b,c}`

. An example of a function `f : A → A`

is a set of pairs, let's say `f = { (a,a) , (b,b) , (c,c) }`

that satisfies some properties that don't matter for this discussion. That is to say, `f`

's elements are the same sort of thing that `A`

's elements are -- they're just values, or pairs of values, nothing too "big".

Now consider the a function `F : A → Set`

. It too is a set of pairs, but its pairs look different: `F = { (a,A) , (b,Nat) , (c,Bool) }`

lets say. The first element of each pair is just an element of `A`

, so it's pretty simple, but the *second* element of each pair is a `Set`

! That is, the second element is itself a "big" sort of thing. So `A → Set`

couldn't possibly be set, because if it were, then we should be able to have some `G : A → Set`

that looks like `G = { (a,G) , ... }`

. As soon as we can have this, we can get Russell's paradox. So we say `A → Set : Set1`

instead.

This also addresses the issue of whether or not `Set → A`

should also be in `Set1`

instead of `Set`

, because the functions in `Set → A`

are just like the functions in `A → Set`

, except that the `A`

s are on the right, and the `Set`

s are on the left, of the pairs.

programming languagethat has a perfectly legitimate and well defined answer. How is it an off topic post? – Edward Kmett Sep 25 '12 at 3:54