As a side note, for such purely logic properties, you can use `lemma`

s instead of `assert`

, as in `//@ lemma pow2_1: positive_power_of_2(1);`

. Since a `lemma`

is a global annotation, it spares you from writing a function just for the sake of holding an `assert`

.

Now back to the issue itself. Mixing bitwise operations with arithmetic ones (the less-than comparison) tends to confuse automated theorem provers. You did not specify which one(s) you use, but if you only used one, you might want to try installing others (nowadays, a mix of alt-ergo, z3 and cvc4 tends to provide good results). That said, a small interactive help to WP's internal simplifier QED is also sufficient: by using the GUI (see section 2.4 of WP manual), you can conclude by just unfolding the definition of `positive_power_of_2`

in each of the goals (as far as I know, there's no command-line option to do the equivalent).

Basically, once you are in the `WP Proofs`

panel of the GUI, you have to double click in the `Script`

column of the row corresponding to the proof obligation you want to work on, which will let you enter the interactive proof mode, as in the screenshot below:

Now, the point is that the list of available tactics (on the right) is contextual: only the ones that are relevant for the term you have selected in the proof obligation (on the left) are shown. Some tactics are always relevant, such as `Cut`

, which let you prove an auxiliary statement that can be used as an hypothesis in the rest of the proof, but unfolding a definition only makes sense if there's a definition to unfold in your selection. Hence you have to click on `P_positive_power_of_2`

to let the tactic appear. Afterwards, just click on the corresponding triangle to let WP unfold the definition and attempt to complete the proof afterwards.