Maybe you want to try out a semi-automatic proof method. Just to go for something different ;) For example, if you have a Java specification of Prim's and Kruskal's algorithms, optimally building upon the same graph model, you can use the KeY Prover to prove the equivalence of the algorithm.

The crucial part is to formalize your proof obligation in Dynamic Logic (this is an extension of first-order logic with types and means of symbolic execution of Java programs). The formula to prove could match the following (sketchy) pattern:

```
\forall Graph g. \exists Tree t.
(<{KRUSKAL_CODE_HERE}>resultVar1=t) <-> (<{PRIM_CODE_HERE}>resultVar2=t)
```

This expresses that for all graphs, both algorithms terminate and the result is the same tree.

If you're lucky and your formula (and algorithm implementations) are right, then KeY can prove it automatically for you. If not, you might need to instantiate some quantified variables which makes it necessary to inspect the previous proof tree.

After having proven the thing with KeY, you can either be happy about having learned something or try to reconstruct a manual proof from the KeY proof - this can be a tedious task since KeY knows a lot of rules specific to Java which are not easy to comprehend. However, maybe you can do something like extracting an Herbrand disjunction from the terms that KeY used to instantiate existential quantifiers at the right-hand side of sequents in the proof.

Well, I think that KeY is an interesting tool and more people should get used to prove critical Java code using tools like that ;)