I want to prove that a compiler that I wrote for a toy language is correct. I defined a predicate P which relates the runtime configuration of the source toy language and the target toy assembly.

The proof is set up as proving that if the source language's small-step relation steps from state S1 to state S2, and that P(S1,T1), where T1 is the target language's runtime configuration, then we can find a T2 such that P(S2,T2), and T1 steps to T2 in target language.

When translating constructs like array creations and functions calls, the number of instructions of the translated code depends on the size of the array/number of function arguments. For example, the translated instructions of `x = array<v1,v2,...,vn>`

is something like `mov r1 (translated value of v1); store r2 0 r1;...;mov r1 (translated value for vn); store r2 (n-1) r1;...`

.

When I prove other properties I would manually step through each instruction (because Coq can't do unification and I have to manually use apply with ... for arguments that Coq can't infer). For variable length instruction sequences I can't do the same thing, so I'm wondering what I can do.

It would be great if someone can provide some github code examples that does something similar to what I'm trying to do. The reason I mentioned lightweight is because if possible, I don't want to use heavy libraries with many predefined tactics.