# Proving A ==> B ==> C ==> B in Isabelle

``````A ==> B ==> C ==> B
``````

in Isabelle. Obviously you could

``````apply simp
``````

but how could I prove this with using rules?

Alternatively, is there a way to dump the rules `simp` used? Thanks.

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If you really want to understand how proofs work, you should forget both about funny tactics and automated reasoning tools as a start.

The statement `A ==> B ==> C ==> B` (using this special `==>` connective) of Isabelle/Pure is immediately true, so its proof in Isabelle/Isar is:

``````lemma "A ==> B ==> C ==> B" .
``````

That's it, just `.` (which abbreviates `by this`, but the `this` is actually empty here).

As slightly less vacuous proof uses actual Isabelle/HOL connectives, which you can then handle by standard introduction or elimination steps. E.g. like this:

``````lemma "A --> B --> C --> B"
proof
show "B --> C --> B"
proof
assume b: B
show "C --> B"
proof
show B by (rule b)
qed
qed
qed
``````

But that is not so interesting either: you build up a boring implication that that is then decomposed until you are finished.

To find more interesting Isabelle/Isar proofs just do some web search, or look through the sources that come with the system. A totally arbitrary example is here: Drinker.

There are also tons of manuals, actually too many of them.

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Thank you for your solution and recommendations! :-) –  TFuto Mar 28 '14 at 17:17

You can enable simplifier tracing; in Proof General, you can do this with Isabelle → Settings → Tracing → Trace Simplifier, I don't know about jEdit.

EDIT: In this case the simp trace will not be very helpful, since `simp` does not use rewrite rules to solve this, instead it "sees" A, B, and C in the premises and concludes that it can, in the context of this statement, rewrite `A = True`, `B = True`, and `C = True`, then it rewrites the goal `B` to `True` and you're done.

However, the "normal" way of proving statements such as this is to use the `assumption` method, which matches the goal against a premise, in this case `B`. There is probably a way to prove this using `rule` as well, but that would be unnecessarily complicated. `assumption` uses `assume_tac`, which in turn is just a wrapper around the very basic function `Thm.assumption`, so this can really be considered one of the most elementary proof methods in Isabelle. So just write `by assumption`.

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Thank you Manuel! :-) –  TFuto Dec 5 '13 at 14:43
The information by Manuel is inaccurate. You hardly ever see `by assumption` in proper Isar proofs -- that is already implicit in the closing of the proof. –  Makarius Mar 14 '14 at 20:22