I stumbled across this question just now, 3 years after it is asked, so I am not sure how useful the answer will still be... Still, I am surprised not to see clearly stated that answering your question requires to know two and only two things:
- which processor you target
- which compiler you work with
To the first point, each processor has different instructions for tests. On one given processor, two similar comparisons may turn up to take a different number of cycles. For example, you may have a 1-cycle instruction to do a gt (>), eq (==), or a le (<=), but no 1-cycle instruction for other comparisons like a ge (>=). Following a test, you may decide to execute conditional instructions, or, more often, as in your code example, take a jump. There again, cycles spent in jumps take a variable number of cycles on most high-end processors, depending whether the conditional jump is taken or not taken, predicted or not predicted. When you write code in assembly and your code is time critical, you can actually take quite a bit of time to figure out how to best arrange your code to minimize overall the cycle count and may end up in a solution that may have to be optimized based on the number of time a given comparison returns a true or false.
Which leads me to the second point: compilers, like human coders, try to arrange the code to take into account the instructions available and their latencies. Their job is harder because some assumptions an assembly code would know like "counter is small" is hard (not impossible) to know. For trivial cases like a loop counter, most modern compilers can at least recognize the counter will always be positive and that a != will be the same as a > and thus generate the best code accordingly. But that, as many mentioned in the posts, you will only know if you either run measurements, or inspect your assembly code and convince yourself this is the best you could do in assembly. And when you upgrade to a new compiler, you may then get a different answer.