There is a blog post somewhere with a type-level implementation of the SKI combinator calculus, which is known to be Turing-complete.

Turing-complete type systems have basically the same benefits and drawbacks that Turing-complete languages have: you can do anything, but you can prove very little. In particular, you cannot prove that you will actually eventually do something.

One example of type-level computation are the new type-preserving collection transformers in Scala 2.8. In Scala 2.8, methods like `map`

, `filter`

and so on are guaranteed to return a collection of the same type that they were called on. So, if you `filter`

a `Set[Int]`

, you get back a `Set[Int]`

and if you `map`

a `List[String]`

you get back a `List[Whatever the return type of the anonymous function is]`

.

Now, as you can see, `map`

can actually transform the element type. So, what happens if the new element type cannot be represented with the original collection type? Example: a `BitSet`

can only contain fixed-width integers. So, what happens if you have a `BitSet[Short]`

and you map each number to its string representation?

```
someBitSet map { _.toString() }
```

The result *would* be a `BitSet[String]`

, but that's impossible. So, Scala chooses the most derived supertype of `BitSet`

, which can hold a `String`

, which in this case is a `Set[String]`

.

All of this computation is going on during *compile time*, or more precisely during *type checking time*, using type-level functions. Thus, it is statically guaranteed to be type-safe, even though the types are actually computed and thus not known at design time.