```
h1 f g x y = f (g x y) x
```

So, from left-to-right:

`f`

is a function applied to two arguments: the first is the result of `(g x y)`

and the second is `x`

- we don't know what type the first argument is yet, so let's call it
`a`

- we don't know the second type either, so let's call that
`b`

- we also don't know the result type (so we'll call that
`c`

), but we *do* know this must be the type returned by `h1`

- now
`f`

is a function mapping `a -> b -> c`

`g`

is a function applied to two arguments: the first is `x`

and the second `y`

- we know the first argument to
`g`

is the same as the second argument to `f`

, so it must be the same type: we already labelled that `b`

- the second argument to
`g`

is `y`

, which we haven't assigned a placeholder type yet, so that gets the next in sequence, `d`

`g`

's result is the first argument to `f`

, and we already labelled that `a`

- so now
`g`

is a function mapping `b -> d -> a`

- third argument is
`x`

, and as that's the second argument to `f`

, we've already labelled its type `b`

- fourth argument is
`y`

, which is the second argument to `g`

, so we've already labelled *its* type `d`

- the result of
`h1`

is the result of applying `f`

to `(g x y) x`

, as we said before, so it has the same type, already labelled `c`

When I said *from left-to-right* above, I meant *taking the argument list* in that order. So, I started with `f`

and worked my way through to `y`

. However, the actual process of labelling, inferring and unifying types is done by looking at the body of `h1`

.

So, my first bullet could be elaborated as:

`f`

is the first argument to consider, so let's look at the body of `h1`

(everything after the `=`

) to see how it's used
`f (g x y) x`

means that `f`

is applied to `(g x y) x`

, so `f`

must be a function
`(g x y)`

is in parenthesis, which means whatever is inside those parentheses is being evaluated, and the *result* of that evaluation is an argument to `f`

`x`

is just a simple argument to `f`

, passed straight from `h1`

's own argument list
- so,
`f`

is a function taking two arguments

If it helps read `f (g x y) x`

, you can consider the equivalent expression in C-like notation would be `f(g(x,y), x)`

. Here, you can see right away that `f`

and `g`

are functions taking two arguments, that `f`

's first argument is whatever `g`

returns, etc.

Note that the left-hand side of the expression, `h1 f g x y`

, only gives one piece of type information by itself: `h1`

is a function on four arguments. The argument names themselves are just placeholders used in the right-hand side of the expression (the body of `h1`

). The relative ordering of the arguments here just tells us how to call `h1`

, but *nothing* about how `h1`

uses the arguments internally.

Again, here's a procedural-style equivalent (I'll use Python so I don't have to fill in any types):

```
def h1(f, g, x, y):
return f(g(x,y),x)
```

this means *exactly* the same as

```
h1 f g x y = f (g x y) x
```

(with one caveat - partial application - that I suspect will only confuse matters further here).

In both cases, the declaration (left of the `=`

in Haskell, and before the `:`

in Python) only tells us the function name and how many arguments it takes.

In both cases, we can *infer* from the definition (right hand side in Haskell, the indented block after `:`

in Python) that `f`

and `g`

are both functions on two arguments, that `g`

's first argument is the same as `f`

's second, etc. In Haskell, the compiler does this for us; Python will just complain at runtime if we call `g`

with the wrong number of arguments, or it returns something `f`

can't use as a first argument.