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Scala uses a type-system based on System F ω, which is normally said to be strongly normalizing. Strongly normalizing implies non-Turing completeness.

Nevertheless, Scala's type-system is Turing-complete.

Which changes/additions/modifications make Scala's type-system Turing-complete compared to the formal algorithms and systems?

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closed as off topic by oluies, Dan Burton, Matthew Farwell, Debilski, pad Dec 14 '11 at 19:55

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Have links/references? (For spectators, like me :-) – user166390 Dec 13 '11 at 23:42
The fact that System F is strongly normalizing implies that System F is not Turing complete. It does not imply that its type system isn't. And in fact it has been shown that typechecking an unrestricted System F is undecidable – sepp2k Dec 14 '11 at 0:20
@sepp2k -- yikes, the worst thing about Turing-completeness and it's got that. – Malvolio Dec 14 '11 at 1:52
@sepp2k, the result you cite holds only for undecorated lambda terms. If explicit types are given for lambda-abstracted type variables, and if type abstraction is explicit in the source code, then type checking System F is a snap---my students do it as a homework assignment. – Norman Ramsey Dec 14 '11 at 2:43
up vote 4 down vote accepted

It's not a comprehensive answer but the reason is that you can define recursive types.

I've asked similar questions before (about what a non-Turing complete language might look like). The answers were of the form: a Turing complete language must support either arbitrary looping or recursion. Scala's type system supports the latter

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Recursive types exist in most languages, including Java and Pascal. Any type that refers to itself (like a linked list) is recursive. You need a way to perform computation at the type level, such as type application. In Scala, you have type members and partial type application in type aliases. – Iulian Dragos Dec 14 '11 at 13:41
I meant recursive types in the sense of the peano encoding:… using type, not class or trait. I thought that was reasonably obvious given the context. Like I said, I am echoing here, what I have been told about turing completeness. – oxbow_lakes Dec 14 '11 at 15:26
Recursive types can be used to encode numbers like you say, but they're not enough for Turing completeness. What you want is a way to compute, in this case using type application (which in turn uses substitution). Scala's type members make it somewhat easy, though Java performs similar substitutions for generics. – Iulian Dragos Dec 15 '11 at 12:26

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