Those two solutions do very different things. The first loops in a nested way, then computes indexes with
list.index, effectively making this a doubly-nested for loop and requiring what you could think of as 125,000,000 operations. The second iterates in lockstep, making 500 pairs without doing 250000 operations. No wonder they're so different!
Are you familiar with Big O notation for describing the complexity of algorithms? If so, the first solution is cubic and the second solution is linear. The cost of choosing the first one over the second one is going to grow at an alarming rate as
b get longer, so no one would use an algorithm like that.
Personally, I would almost certainly use code like
', '.join('%s=%s' % pair for pair in itertools.izip(a, b))
or if I wasn't too worried about the size of
b and just writing quick, I would use
zip instead of
itertools.izip. This code has several advantages
It's linear. Although premature optimization is a huge problem, it's best not to cavalierly use an algorithm with an unnecessarily bad asymptotic performance.
It's simple and idiomatic. I see other people write code like this frequently.
It's memory efficient. By using a generator expression instead of a list comprehension (and
itertools.izip rather than
zip), I don't build unnecessary lists in memory and turn what could be an O(n) (linear)-memory operation into an O(1) (constant)-memory operation.
As for timing to find the fastest solution, this would almost certainly be an example of premature optimization. To write performant programs, we use theory and experience to write high-quality, maintainable, good code. Experience shows it's at best futile and at worst counterproductive to stop at random operations and ask the question, "What is the best way to do this particular operation," and trying to determine it from guessing or even testing.
In reality, the programs with the best performance are the ones that are written with code of the highest quality and very selective optimizations. High-quality code that values readability and simplicity over microbenchmarks ends up being easier to test, less buggy, and nicer to refactor--these factors are key for effectively optimizing your program. The time you spend fixing unnecessary bugs, understanding complicated code, and fighting with re factoring can be spent optimizing instead.
When it comes time to optimize a program -- after it's tested and probably documented -- this is not done on random snippets, but on ones determined by actual usecases and/or performance tests, with measurements collected by profiling. If a particular piece of code is only taking 0.1% of the time in the program, no amount of speeding up that piece is going to do any real good.