I think the thing to be careful about is that you aren't asking for knowledge where it's basically random whether the interviewee has it to hand or not. For your examples, I cannot immediately remember what the bit-twiddling hacks are for the most-significant bit questions (finding it, and rounding up to the next power of 2). I know that there are hacks that I could look up, and I know about
__builtin_clz on GCC which of course isn't portable.
So, have I failed the interview? And if so, are you sure that I'm not fit to program Qt in your company? You're implementing a filter, and you just have to think about the false positive rate (how many people will know the bit-twiddles but be poor employees) and the false negative rate (how many good employees have forgotten the bit-twiddles).
Of course all interviews have a false negative rate. The cost to your company hiring a bad employee is pretty high, so you have to be certain. For that reason, I think that if this employee turns out to be good, that's probably more by luck than judgement on the part of your company -- you shouldn't hire someone to be a Qt programmer without testing their ability with Qt or something similar. What's the cost of setting up a second interview with each of the three best candidates, taken by one of your Qt people, compared with the value of hiring the best one? What's the cost of your time to interview the candidates, given that this interview has no influence on the hiring decision?
Just remember that different kinds of programmers have different knowledge at their immediate command, and make sure that your questions are strongly correlated with the kind of programmer you want. On this particular subject, what it proves is that the interviewee has spent time bit-twiddling, possibly in the fairly recent past. On the plus side, that's time they spent programming. On the minus side, that's time they didn't spend writing and learning Qt.
I would be concerned if someone didn't know how to check the lsb, and didn't know that for positive values and for 2's complement negative values, the lsb is 1 for odd numbers and 0 for even numbers. That's because I expect programmers to know what a binary representation is. I would also be concerned if someone thought that
x & 1 was likely to be better in some way than
x % 2, because it means they use a terrible compiler ;-)
I wouldn't be too concerned if someone couldn't remember the bit-twiddle for popcount. Slightly more if they couldn't figure out the code for it after you'd given them a heavy hint of one of the simpler ways to do it: "How could I compute the popcount of a 2 bit integer using bit-twiddling? OK, now write a line to do that in parallel for each of the top and bottom 2 bits of a 4 bit integer. OK, now write a 32-bit popcount".