Your definition is unnecessarily complicated. Why do you not just write
def pred ≡ "λn::nat. n - 1"
Then you can have
have [simp]: "⋀n. n > 0 ⟹ Suc (pred n) = n" by (simp add: pred_def)
In the case of
pred function then simply returns
Suc (pred 0) = 0 obviously doesn't hold. You could also define
pred ≡ "λn. THE n'. Suc n' = n". That would return the unique natural number whose successor is
n if such a number exists (i.e. if
n > 0) and
undefined (i.e. some natural number you know nothing about) otherwise. However, I would argue that in this case, it is much easier and sensible to just do
pred ≡ λn::nat. n - 1.
I would suspect that in most cases, you can simply forgo the
pred function and write
n - 1; however, I do know that it is sometimes good to have the
- 1 “protected” by a definition. In these cases, I usually
def a variable
n - 1 and prove
Suc n' = n – basically the same thing. In my opinion, seeing as proving this takes only one line, it does not really merit a definition of its own, such as this
pred function, but one could make a reasonable case for it, I guess.
Another thing: I've noticed you use
lemma "1 = 1" as some kind of dummy environment to do Isar proofs in. I would like to point out the existence of
notepad, which exists precisely for that use case and that can be used as follows:
have "some fact" by something