(&&) is strict in its second argument only if its first argument is
True. It is always strict in its first argument. This strictness / laziness is what guarantees the order of evaluation.
So it behaves exactly like C. The difference is that in Haskell,
(&&) is an ordinary function. In C, this would be impossible.
But Haskell is lazy, and, generally, there are no guarantee what operation will execute first, until we don't use seq, $!, or something else to make our code strict.
This is not correct. The truth is deeper.
Crash course in strictness:
(&&) is strict in its first parameter because:
⊥ && x = ⊥
Here, ⊥ is something like
undefined or an infinite loop (⊥ is pronounced "bottom"). We also know that
(False &&) is non-strict in its second argument:
False && ⊥ = False
It can't possibly evaluate its second argument, because its second argument is ⊥ which can't be evaluated. However, the function
(True &&) is strict in its second argument, because:
True && ⊥ = ⊥
So, we say that
(&&) is always strict in its first argument, and strict in its second argument only when the first argument is
Order of evaluation:
(&&), its strictness properties are enough to guarantee order of execution. That is not always the case. For example,
(+) :: Int -> Int -> Int is always strict in both arguments, so either argument can be evaluated first. However, you can only tell the difference by catching exceptions in the
IO monad, or if you use an