First of all, you need a very precise definition of "strict" in order for this to make sense. A function `f`

is strict iff evaluating `f x`

to whnf causes `x`

to be evaluated to whnf. The interaction this has with currying is a bit awkward, and I'm going to ignore some of the potential weirdness that introduces.

Assuming the type here is `f :: Bool -> Int -> Bool -> Bool`

your analysis of the behavior wrt `y`

is correct - evaluating `f x y z`

to whnf will always require evaluating `y`

to determine which equation to choose. As that is the only factor determining which equation to use, we have to split the analysis for `x`

and `z`

. In the first equation, evaluating the result to whnf results in both `x`

and `z`

being evaluated. In the second equation, evaluating the result to whnf results in evaluating `x`

to whnf.

Since `x`

is evaluated in both branches, this function is strict in `x`

. This is a little bit amusing - it's strict in the way `id`

is strict. But that's still valid! `z`

, however, is a different story. Only one of the branches causes `z`

to be evaluated, so it's not evaluated strictly - it's only evaluated on demand. Usually we talk about this happening where evaluation is guarded behind a constructor or when a function is applied and the result isn't evaluated, but being conditionally evaluated is sufficient. `f True 1 undefined`

evaluates to `True`

. If `f`

was strict in `z`

, that would have to evaluate to `undefined`

.