If Haskell's type system is a inconsistent proof system, then we can't trust it?
As @chi alluded to, type safety is a much weaker condition than logical consistency. Quoting Types and Programming Languages (a good read if you're interested in this sort of thing!),
Safety = Progress + Preservation
What we want to know, then, is that well-typed terms do not get stuck. We show this in two steps, commonly known as the progress and preservation theorems.
- Progress: a well-typed term is not stuck (either it is a value or it can take a step according to the evaluation rules).
- Preservation: If a well-typed term takes a step of evaluation, then the resulting term is also well-typed.
These properties together tell us that a well-typed term can never reach a stuck state during evaluation.
Note that this definition of type safety doesn't exclude the possibility that a well-typed term will loop for ever, or throw an exception. But those two rules do make the guarantee that if you've successfully obtained an
Int then it really is an
Int and not a
Bool or a
Ennui. (In Haskell this is somewhat complicated by laziness, but the basic idea remains true.) This is a very useful property, and programmers learn to rely upon it crucially in their daily workflow!
I guess my point is, the PL community has a tendency to place a great deal of emphasis on proving properties of systems (such as type safety), but that's often not how software engineers get their work done! The engineers I know care about whether a tool helps them write fewer bugs, not about whether it's been proven safe or consistent. I just think each group could learn a lot from the other! When the clever people in the ultra-typed community get together with the clever people in the untyped community to build tools for engineering, interesting things can happen.
Would be possible to represent endless loop with no
Sure. Lots of ways.
loop = loop
fib = 1 : 1 : zipWith (+) fib (tail fib)
repeat x = unfoldr (const (Just x))
main = forever $ print "cheese"
From a formal perspective all of these terms are
⊥, but in practice it matters very much which
⊥ you're running.
If your question was really does the ability to write looping terms imply inconsistency? then the short answer is yes, viz
let x = x in x :: forall a. a. That's why proof assistants like Agda typically feature a termination checker which examines the syntax of your program and rejects suspicious-looking usages of general recursion. The longer answer is no, not exactly - you can embed the general-recursive parts of your program in a monad and then implement the semantics of that partiality monad with some external evaluator. (This is precisely the approach that Haskell takes to purity: put the impure parts in the
IO monad and delegate execution to the runtime system.)
In conclusion, yes, Haskell is inconsistent as a logic - every type is inhabited by an infinite family of
⊥s with a variety of runtime behaviours, so you can easily "prove" any proposition. That (along with the overall clunkiness of dependent types) is why people don't use Haskell as a theorem prover. For engineering, though, the lesser guarantees of type safety are generally quite enough, and some of those
⊥s are interesting!