Writing a `Comparator`

manually for such an use case is a terrible solution IMO. Such ad hoc approaches have many drawbacks:

- No code reuse. Violates DRY.
- Boilerplate.
- Increased possibility of errors.

**So what's the solution?**

First some theory.

Let us denote the proposition "type `A`

supports comparison" by `Ord A`

. (From program perspective, you can think of `Ord A`

as an object containing logic for comparing two `A`

s. Yes, just like `Comparator`

.)

Now, if `Ord A`

and `Ord B`

, then their composite `(A, B)`

should also support comparison. i.e. `Ord (A, B)`

. If `Ord A`

, `Ord B`

, and `Ord C`

, then `Ord (A, B, C)`

.

We can extend this argument to arbitrary arity, and say:

`Ord A, Ord B, Ord C, ..., Ord Z`

⇒ `Ord (A, B, C, .., Z)`

Let's call this statement 1.

The comparison of the composites will work just as you described in your question: the first comparison will be tried first, then the next one, then the next, and so on.

That's the first part of our solution. Now the second part.

If you know that `Ord A`

, and know how to transform `B`

to `A`

(call that transformation function `f`

), then you can also have `Ord B`

. How? Well, when the two `B`

instances are to be compared, you first transform them to `A`

using `f`

and then apply `Ord A`

.

Here, we are mapping the transformation `B → A`

to `Ord A → Ord B`

. This is known as contravariant mapping (or `comap`

for short).

`Ord A, (B → A)`

⇒_{comap} `Ord B`

Let's call this statement 2.

Now let's apply this to your example.

You have a data type named `Person`

that comprises three fields of type `String`

.

We know that `Ord String`

. By statement 1, `Ord (String, String, String)`

.

We can easily write a function from `Person`

to `(String, String, String)`

. (Just return the three fields.) Since we know `Ord (String, String, String)`

and `Person → (String, String, String)`

, by statement 2, we can use `comap`

to get `Ord Person`

.

QED.

**How do I implement all these concepts?**

The good news is you don't have to. There already exists a library which implements all the ideas described in this post. (If you are curious how these are implemented, you can look under the hood.)

This is how the code will look with it:

```
Ord<Person> personOrd =
p3Ord(stringOrd, stringOrd, stringOrd).comap(
new F<Person, P3<String, String, String>>() {
public P3<String, String, String> f(Person x) {
return p(x.getFirstName(), x.getLastname(), x.getAge());
}
}
);
```

**Explanation:**

`stringOrd`

is an object of type `Ord<String>`

. This corresponds to our original "supports comparison" proposition.
`p3Ord`

is a method that takes `Ord<A>`

, `Ord<B>`

, `Ord<C>`

, and returns `Ord<P3<A, B, C>>`

. This corresponds to statement 1. (`P3`

stands for product with three elements. Product is an algebraic term for composites.)
`comap`

corresponds to well, `comap`

.
`F<A, B>`

represents a transformation function `A → B`

.
`p`

is a factory method for creating products.
- The whole expression corresponds to statement 2.

Hope that helps.