TL;DR: Type variable order is determined by first left-to-right encounter. When in doubt, use `:type +v`

.

### Don't use `:type`

Using `:type`

is misleading here. `:type`

infers the type of a whole expression. So when you write `:t (,)`

, the type checker looks at

```
(,) :: forall a b. a -> b -> (a, b)
```

and instantiates all the forall’s with fresh type variables

```
(,) :: a1 -> b1 -> (a1, b1)
```

which is necessary if you would apply `(,)`

. Alas, you don’t, so type inference is almost done, and it generalizes over all free variables, and you get, for example,

```
(,) :: forall {b} {a}. a -> b -> (a, b)
```

This step makes no guarantees over the order of the free variable, and the compiler is free to change.

Also note that it writes `forall {a}`

instead of `forall a`

, which means that you can’t use visible type application here.

### Use `:type +v`

But of course you can use `(,) @Bool`

– but here the type-checker treats the first expression differently and does not do this instantiation/generalization step.

And you can get this behaviour in GHCi as well – pass `+v`

to `:type`

:

```
:type +v (,)
(,) :: forall a b. a -> b -> (a, b)
:type +v (,) @Bool
(,) @Bool :: forall b. Bool -> b -> (Bool, b)
```

Look, no `{…}`

around type variables!

### Where does this order come from?

The the GHC user's guide section on visible type application states:

If an identifier’s type signature does not include an explicit forall, the type variable arguments appear in the left-to-right order in which the variables appear in the type. So, foo :: Monad m => a b -> m (a c) will have its type variables ordered as m, a, b, c.

That this only applies to things that have an explicit type signature. There is no guaranteed order to variables in inferred types, but you also can't use expressions with inferred types with `VisibleTypeApplication`

.