## T - Tagging

OK, I'd like to rename your types to help understand them. `T`

assigns numbers to values, and since I'm not sure what the structure of the container is (and would like to remain flexible), I'll pop the value and the number in a pair `(x,n)`

. Let's call that tagging, so reaname `T`

`Tagger`

, so assuming I know your collection type is `Coll`

a collection of `X`

s would have type `Coll X`

, so I'll need

```
type CollTaggerXInt = Coll X -> Coll (X,Int)
```

which makes a type synonym for the functions you want.

But what if `Int`

's too small and you want to use `Integer`

, or `Double`

or some other numeric type?

```
data Num n => CollTaggerX n = CollTaggerX (Coll X -> Coll (X,n))
```

This means that you can tag `X`

values with any fixed type of numeric data. (`Num n =>`

is a datatype constraint that asserts that n has to be a numeric type.) The CollTaggerX on the right hand side ensures type safety by wrapping your tagging function in a lightweight constructor. We need to use `data`

instead of `type`

because I've parameterised by `n`

.

I'd be inclined to replace the fixed type `X`

and the collection type `Coll`

with type parameters (like generics in some languages eg Java) to improve code reuse:

```
data (Functor coll,Num n) => Tagger coll x n = Tgr (coll x -> coll (x,n))
```

So now we've insisted that the `coll`

ection type is a Functor, so we can use `fmap`

to apply functions pointwise to collections (crucial in your case, and any collection type will be an instance of Functor).

I'm happiest with that definition of `Tagger`

for your `T`

, but you can use `CollTaggerXInt`

if you have just one possibility for `coll`

, `x`

and `n`

.

## U - Making Taggers

Your `U`

type is for turning elementwise taggers into collection taggers. I feel like calling that `Lift`

ing, rather than `U`

. If you're using `CollTaggerXInt`

, you can use a type synonym again:

```
type LiftXIntToTagger = (X -> Int) -> Coll X -> Coll (X,Int)
```

or if you're using the more flexible `Tagger`

definition, you could write

```
data (Functor coll,Num n) => Lifter coll x n = Lifter ((x -> n) -> coll x -> coll (x,n))
```

but this all feels crazy to make a type for this, because if you've got a pointwise function, you can allready lift it using `fmap`

which works on your `coll`

type anyway:

```
fmap :: Functor f => (a -> b) -> f a -> f b
```

So we can use this with `coll`

as `f`

, `x`

as `a`

and `(x,n)`

as b, and define

```
liftT :: (Functor coll,Num n) => (x -> n) -> coll x -> coll (x,n)
liftT f = fmap tag where
tag x = (x,f x)
```

If you want to define your type, OK, but I think `liftT`

might be the only sensible function in your type `U`

.

## Rank - U+Context

Now I think your rank example is useful, so let's investigate that. A rankfunction needs to examine *all* elements of the collection, so let's give it the whole collection as it's first parameter, so `rankfunction :: coll x -> x -> n`

(within the context `(Functor coll,Num n)`

).

```
liftInContext :: (Functor coll,Num n) => (coll x -> x -> n) -> coll x -> coll (x,n)
liftInContext rankfunction mycoll = liftT (rankfunction mycoll) mycoll
```

Here the function `(rankfunction mycoll)`

passes the rankfunction its first parameter - the whole collection - before using liftT to apply it to each element. This is called partial evaluation, and is very handy for this sort of thing.

`U`

is just a specialized`Functor`

. – phg Sep 18 '12 at 11:15