I notice some interesting behavior when it comes to building lists in different ways.
.append takes longer than list-comprehensions, which take longer than
map, as shown in the experiments below:
def square(x): return x**2 def appendtime(times=10**6): answer =  start = time.clock() for i in range(times): answer.append(square(i)) end = time.clock() return end-start def comptime(times=10**6): start = time.clock() answer = [square(i) for i in range(times)] end = time.clock() return end-start def maptime(times=10**6): start = time.clock() answer = map(square, range(times)) end = time.clock() return end-start for func in [appendtime, comptime, maptime]: print("%s: %s" %(func.__name__, func()))
appendtime: 0.42632 comptime: 0.312877 maptime: 0.232474
appendtime: 0.614167 comptime: 0.5506650000000001 maptime: 0.57115
Now, I am very aware that
range in python 2.7 builds a list, so I get why there is a disparity between the times of the corresponding functions in python 2.7 and 3.3. What I am more concerned about is the relative time differences between
append, list-comprehension and
At first, I considered that this might be because
map and list comprehensions may afford the interpreter knowledge of the eventual size of the resultant list, which would allow the interpreter to malloc a sufficiently large C array under the hood to store the list. By that logic, list-comprehensions and
map should take pretty much the same amount of time.
However, the timing data shows that in python 2.7, listcomps are ~1.36x as fast as
map is ~1.34x as fast as listcomps.
More curious is that in python 3.3, listcomps are ~1.12x as fast as
map is actually slower than listcomps.
map and listcomps don't "play by the same rules"; clearly, map takes advantage of something that listcomps don't.
Could anybody shed some light on the reason behind the difference in these timing values?