# a) `p -> (q -> q)`

We need something to take a `p`

,

```
\p -> …
```

and produce a `q -> q`

, so we repeat, taking a q, and the only thing we can do is then return that q

```
\p -> \q -> q
```

we can add parens for emphasis:

```
\p -> (\q -> q)
```

# b) (p -> q) -> ((q -> r) -> (p -> r))

We repeat. Our term starts by taking a function from `p`

to `q`

:

```
\p2q -> …
```

It must return a function of type `((q -> r) -> (p -> r))`

, so we start by returning something taking a function from `q`

to `r`

```
\p2q -> \q2r -> …
```

And we now need it to produce an `r`

given a `p`

. There are only so many ways to piece together the available pieces:

```
\p2q -> \q2r -> \p -> q2r (p2q p)
```

Again, with parenthesis for emphasis:

```
\p2q -> (\q2r -> (\p -> q2r (p2q p)))
```

# c) `(p -> (q -> (q -> r))) -> (p -> (q -> r))`

Hmm, my naming convention falls a little short on this one ;)

First, our term takes a `(p -> (q -> (q -> r)))`

:

```
\p2q2q2r -> …
```

Next, we must produce a term of type `(p -> (q -> r))`

, so we let it take a `p`

, and next take a `q`

:

```
\p2q2q2r -> \p -> \q -> …
```

Producing an `r`

now just involves piecing together what we have

```
\p2q2q2r -> \p -> \q -> ((p2q2q2r p) q) q
```

Hoped that helped with your homework ;)