The type of *twice* states that *twice* is a function from a function with domain *a* and codomain *a* to a function with domain *a* and codomain *a*. The type of *thrice* states that *thrice* is a function from a function with domain *a* and codomain *a* to a function with domain *a* and codomain *a*.

To see why, consider a derivation of the type of *twice* and *thrice*. Given a function *f* : *a* → *a* and variable *x*, the rule for determining the type of *f* (*f x*) states that we must first determine the types of of *f* and *(f x)*, then apply the rule for function application. The rule for determining the type of *(f x)* states that we must first determine the type of *f* and *x*, then apply the rule for function application.

First, since *f* has type *a* → *a* and *x* has type *a*, the rule for function application states that (*f x*) has type *a*. Since *f* has type *a* → *a* and (*f x*) has type *a*, the rule for function application states that *f* (*f x*) has type *a*. An additional application of the rule for function application gives *f* (*f* (*f x*)) has type *a*. As you see, repeated application of the rule for application gives *f*^{n} *x* will have type *a* for all *n* ∈ ℕ.

Second, the rule for function abstraction states that if *x* : *τ*, *M* : *τ'* and *x* does not occur free in *M*, then the abstraction λ *x* : *τ* . *M* has type *τ* → *τ'*. We have terms *f* (*f x*) and *f* (*f* (*f x*)) both with type *a* and a variable *x* with type *a*. Hence, the abstractions λ *x* : *a* . *f* (*f x*) and λ *x* : *a* . *f* (*f* (*f x*)) both have type *a* → *a*. Finally, since *f* : *a* → *a*, applying the rule for function abstraction once more gives λ *f* : *a* → *a* . λ *x* : *a* . *f* (*f x*) and λ *f* : *a* → *a* . λ *x* : *a* . *f* (*f* (*f x*)) have type (*a* → *a*) → (*a* → *a*).

As you can see, Haskell's type system is too inexpressive to state that *twice* applies a function *f* to an argument *x* two times whereas *thrice* applies a function *f* to an argument *x* three times. What it *can* express is that both *twice* and *thrice* accept a function as input and return a function from a term *x* to a term *y* both of type *a*. This function is λ *x* : *a* . *f* (*f x*) for *twice* and λ *x* : *a* . *f* (*f* (*f x*)) for *thrice*.

I would suggest reading a short introduction to the polymorphic λ-calculus, which Haskell's type system is based on. This will present the typing relation and, presumably, guide the reader in proving that certain terms have certain types.