I'm following the book Software Foundation and I'm on the chapter named "Imp".
The authors expose a small language that is the following :
Inductive aexp : Type := | ANum : nat -> aexp | APlus : aexp -> aexp -> aexp | AMinus : aexp -> aexp -> aexp | AMult : aexp -> aexp -> aexp.
Here is the function to evaluate these expressions :
Fixpoint aeval (a : aexp) : nat := match a with | ANum n ⇒ n | APlus a1 a2 ⇒ (aeval a1) + (aeval a2) | AMinus a1 a2 ⇒ (aeval a1) - (aeval a2) | AMult a1 a2 ⇒ (aeval a1) × (aeval a2) end.
The exercise is to create a function that optimize the evaluation. For example :
APlus a (ANum 0) --> a
Here there is my optimize function :
Fixpoint optimizer_a (a:aexp) :aexp := match a with | ANum n => ANum n | APlus (ANum 0) e2 => optimizer_a e2 | APlus e1 (ANum 0) => optimizer_a e1 | APlus e1 e2 => APlus (optimizer_a e1) (optimizer_a e2) | AMinus e1 (ANum 0) => optimizer_a e1 | AMinus e1 e2 => AMinus (optimizer_a e1) (optimizer_a e2) | AMult (ANum 1) e2 => optimizer_a e2 | AMult e1 (ANum 1) => optimizer_a e1 | AMult e1 e2 => AMult (optimizer_a e1) (optimizer_a e2) end.
And now, I would prove that the optimization function is sound :
Theorem optimizer_a_sound : forall a, aeval (optimizer_a a) = aeval a.
This proof is quite difficult. So I tried to decompose the proof using some lemmas.
Here is one lemma :
Lemma optimizer_a_plus_sound : forall a b, aeval (optimizer_a (APlus a b)) = aeval (APlus (optimizer_a a) (optimizer_a b)).
I have the proof, but it is boring. I do an induction on a and then, for every case, I destruct b and destruct the exp to handle the case when b is 0.
I need to do that because
n+0 = n
doesn't reduce automatically, we need a theorem which is plus_0_r.
Now, I wonder, how can I build a better proof with Coq in order to avoid some boring repetitions during the proof.
Here is my proof for this lemma :
I think I should use "Hint Rewrite plus_0_r" but I don't know how.
By the way, I'm also interested to know some tips in order to show the initial theorem (the soudness of my optimization function).