Personally, I think it becomes a bit more obvious when you remove redundant parentheses from the type (like a non-schemer would write it):

```
int -> (int -> bool -> int) -> bool -> int
```

So you are supposed to write a function that is given three arguments and returns an `int`

. That is, a solution must be expressible in the form:

```
lambda n. lambda f. lambda b. ____
```

But how do you fill in the hole? Well, looking at what types you get from the parameters, it is easy to see that you can just plug them together by applying `f`

to `n`

and `b`

, yielding an `int`

. So:

```
lambda n. lambda f. lambda b. f n b
```

That's one solution. But looking at the term carefully one notices that the innermost lambda can actually be eta-reduced, giving an even simpler term:

```
lambda n. lambda f. f n
```

But in fact, the question is a bit degenerate, because returning an int is always trivial. So the simplest solution probably is:

```
lambda n. lambda f. lambda b. 0
```

The general scheme to arrive at a solution often is by simple induction on the type structure: if you need a function, then write down a lambda and proceed recursively with the body. If you need a tuple, then write down a tuple and proceed recursively with its components. If you need a primitive type, well you can just pick a constant. If you need something you don't have (usually in the polymorphic case), look for some of the function parameters in scope that would give you such a thing. If that parameter is itself a function, try to recursively construct a suitable argument.