# How to explicitly bind variables in an induction proof?

I have a datatype and an inductive predicate over it (which is actually a small-step semantics of some transition system):

``````datatype dtype = E | A | B dtype

inductive dsem :: "dtype ⇒ dtype ⇒ bool" where
"dsem A E"
| "dsem (B E) E"
| "dsem d d' ⟹ dsem (B d) (B d')"
``````

and also a function which is computed by case distinction:

``````fun f :: "dtype ⇒ nat" where
"f E = 0"
| "f A = 1"
| "f (B _) = 2"
``````

I'm trying to prove some property about the inductive predicate, and assumptions also involve computing the value of `f` which doesn't participate in induction.

``````lemma
assumes d: "dsem s s'"
and h: "h s v"
and v: "v = f s"
shows "P v"
using d h
proof (induct rule: dsem.induct)
``````

For the 3rd semantics rule Isabelle computes the subgoal

``````⋀d d'. dsem d d' ⟹ (h d v ⟹ P v) ⟹ h (B d) v ⟹ P v
``````

where the value of `s` is lost so it is impossible to compute the value `v`. I can neither include `v` into the induction assumptions because then Isabelle generates the subgoal

``````⋀d d'. dsem d d' ⟹ (h d v ⟹ v = f d ⟹ P v) ⟹ h (B d) v ⟹ v = f (B d) ⟹ P v
``````

where the induction hypothesis says `v = f d` which is incorrect since `v = f (B d)` in this case. Nor can I put `v` into `arbitrary: ...` because the value of `v` must be fixed throughout the proof.

It would be nice to have an explicit binding `s = B d` in the generated subgoal; unfortunately, the rule `dsem.induct` doesn't provide it.

Does anybody know a workaround for computing the value `v` in this case?

-
Does it help to rephrase your lemma as `lemma "dsem s s' ⟹ (⋀v. ⟦ h s v ; v = f s ⟧ ⟹ P v)"`? – John Wickerson Jan 30 '14 at 10:47
Since the fact `v` (i.e., `v = f s`) contains the variable `s` and you are doing induction on `dsem s s'` (which also contains `s`) there is no way around also including `v` into the induction assumptions. If the statement is not provable after doing so, you will have to reformulate it appropriately (whatever that means). – chris Jan 30 '14 at 11:11
@JohnWickerson No, it is the same problem. – Nadezhda Baklanova Jan 30 '14 at 13:27
You might try the proof with assumption `v` unfolded, i.e. `lemma "dsem s s' ⟹ h s (f s) ⟹ P (f s)"`. This version is logically equivalent to the one stated in the question (and to the one suggested by John Wickerson above). – Brian Huffman Jan 30 '14 at 18:09

It seems strange to me that `v` should be at the same time fixed and computed from `s` and that is what chris is saying in the comments.

If the solution Brian gives in the comments is what you want, it could duplicate the expression `f s` which could be big (and use `s` several times) and perhaps the point of the assumption `v = f s` was to avoid this.

A first workaround (that was possibly what Brian implicitly proposed) is to make Isabelle do the `unfolding`:

``````lemma
assumes d: "dsem s s'"
and h: "h s v"
and v: "v = big_f s s"
shows "P v"
using d h
unfolding v -- {* <<<< *}
proof (induct rule: dsem.induct)
``````

A second workaround could be to abbreviate `big_f` instead of `big_f s s`:

``````lemma
assumes d: "dsem s s'"
and h: "h s (f s)"
and v: "f = (λs. big_f s s)" -- {* <<<< *}
shows "P (f s)"
using d h
proof (induct rule: dsem.induct)
``````
-
Thanks for your suggestions. Unfortunately, all these propositions lead to the described issue. The lemma in the form I wanted it seems to be unprovable, so I had to reformulate it. – Nadezhda Baklanova Feb 5 '14 at 12:21