As danportin mentioned, Coq is telling you that it does not know how to instantiate
y. Indeed, when you do
rewrite -> neg_move, you ask it to replace some
negb x by a
y. Now, what
y is Coq supposed to use here? It cannot figure it out.
One option is to instantiate
y explicitly upon rewriting:
rewrite -> neg_move with (y:=some_term)
This will perform the rewrite and ask you to prove the premises, here it will add a subgoal of the form
x = negb some_term.
Another option is to specialize
neg_move upon rewriting:
rewrite -> (neg_move _ _ H)
H must be a term of type
some_x = negb some_y. I put two wildcards for the
x and the
y parameters of
neg_move since Coq is able to infer them from
H as being
some_y respectively. Coq will then try to rewrite an occurence of
negb some_x in your goal with
But you first need to get this
H term in your hypotheses, which might be some additional burden...
(Note that the first option I gave you should be equivalent to
rewrite -> (neg_move _ some_term))
Another option is
erewrite -> negb_move, which will add uninstantiated variables that will look like
?y, and try to do the rewrite. You will then have to prove the premise, which will look like
(evenb (S (S n'))) = negb ?y, and hopefully in the process of solving this subgoal, Coq will find out what
?y should have been from the start (there are some restrictions though, and some problems may arise is Coq solves the goal without figuring out what
?y must be).
However, for your particular problem, it is quite easier:
evenb (S n') = negb (evenb (S (S n')))
negb (evenb (S (S n'))) = evenb (S n')
evenb (S (S n')) = negb (evenb (S n'))
And that's what you wanted (backwards, do another
symmetry. if you care).