10

Note: I'm a Ruby developer trying to find my way in Python.

When I wanted to figure out why some scripts use mylist[:] instead of list(mylist) to duplicate lists, I made a quick benchmark of the various methods to duplicate range(10) (see code below).

EDIT: I updated the tests to make use of Python's timeit as suggested below. This makes it impossible to directly compare it to Ruby, because timeit doesn't account for the looping while Ruby's Benchmark does, so Ruby code is for reference only.

Python 2.7.2

Array duplicating. Tests run 50000000 times
list(a)     18.7599430084
copy(a)     59.1787488461
a[:]         9.58828091621
a[0:len(a)] 14.9832749367

For reference, I wrote the same script in Ruby too:

Ruby 1.9.2p0

Array duplicating. Tests 50000000 times
                      user     system      total        real
Array.new(a)     14.590000   0.030000  14.620000 ( 14.693033)
Array[*a]        18.840000   0.060000  18.900000 ( 19.156352)
a.take(a.size)    8.780000   0.020000   8.800000 (  8.805700)
a.clone          16.310000   0.040000  16.350000 ( 16.384711)
a[0,a.size]       8.950000   0.020000   8.970000 (  8.990514)

Question 1: what is mylist[:] doing differently that it is 25 % faster than even mylist[0:len(mylist)]. Does it copy in memory directly or what?

Question 2: edit: updated benchmarks don't show huge differences in Python and Ruby anymore. was: Did I implement the tests in some obviously inefficient way, so that Ruby code is so much faster than Python?

Now the code listings:

Python:

import timeit

COUNT = 50000000

print "Array duplicating. Tests run", COUNT, "times"

setup = 'a = range(10); import copy'

print "list(a)\t\t", timeit.timeit(stmt='list(a)', setup=setup, number=COUNT)
print "copy(a)\t\t", timeit.timeit(stmt='copy.copy(a)', setup=setup, number=COUNT)
print "a[:]\t\t", timeit.timeit(stmt='a[:]', setup=setup, number=COUNT)
print "a[0:len(a)]\t", timeit.timeit(stmt='a[0:len(a)]', setup=setup, number=COUNT)

Ruby:

require 'benchmark'

a = (0...10).to_a

COUNT = 50_000_000

puts "Array duplicating. Tests #{COUNT} times"

Benchmark.bm(16) do |x|
  x.report("Array.new(a)")   {COUNT.times{ Array.new(a) }}
  x.report("Array[*a]")   {COUNT.times{ Array[*a] }}
  x.report("a.take(a.size)")   {COUNT.times{ a.take(a.size) }}
  x.report("a.clone")    {COUNT.times{ a.clone }}
  x.report("a[0,a.size]"){COUNT.times{ a[0,a.size] }}
end
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  • 3
    Use the python timeit module to measure python execution times. I doubt it'll make things (much) faster but it'll avoid all the usual timing traps.
    – Martijn Pieters
    Oct 24, 2012 at 11:06
  • As for the time difference in alist[:] versus alist[0:len(alist)]; the latter creates python int objects, something the former method doesn't need to deal with.
    – Martijn Pieters
    Oct 24, 2012 at 11:08
  • 1
    @MartijnPieters -- The latter also needs to look up the global len (and call it) each time
    – mgilson
    Oct 24, 2012 at 11:13
  • 1
    Array(a) does not duplicate an array. When given an array it just calls to_ary on it, which returns self. You should also use Ruby's Benchmark library instead of doing your timing manually. Oct 24, 2012 at 11:59
  • 1
    Try obj.dup in Ruby and benchmark too.
    – SwiftMango
    Oct 24, 2012 at 13:51

2 Answers 2

9

Use the timeit module in python for testing timings.

from copy import *

a=range(1000)

def cop():
    b=copy(a)

def func1():
    b=list(a)

def slice():
    b=a[:]

def slice_len():
    b=a[0:len(a)]



if __name__=="__main__":
    import timeit
    print "copy(a)",timeit.timeit("cop()", setup="from __main__ import cop")
    print "list(a)",timeit.timeit("func1()", setup="from __main__ import func1")
    print "a[:]",timeit.timeit("slice()", setup="from __main__ import slice")
    print "a[0:len(a)]",timeit.timeit("slice_len()", setup="from __main__ import slice_len")

Results:

copy(a) 3.98940896988
list(a) 2.54542589188
a[:] 1.96630120277                   #winner
a[0:len(a)] 10.5431251526

It's surely the extra steps involved in a[0:len(a)] are the reason for it's slowness.

Here's the byte code comparison of the two:

In [19]: dis.dis(func1)
  2           0 LOAD_GLOBAL              0 (range)
              3 LOAD_CONST               1 (100000)
              6 CALL_FUNCTION            1
              9 STORE_FAST               0 (a)

  3          12 LOAD_FAST                0 (a)
             15 SLICE+0             
             16 STORE_FAST               1 (b)
             19 LOAD_CONST               0 (None)
             22 RETURN_VALUE        

In [20]: dis.dis(func2)
  2           0 LOAD_GLOBAL              0 (range)
              3 LOAD_CONST               1 (100000)
              6 CALL_FUNCTION            1
              9 STORE_FAST               0 (a)

  3          12 LOAD_FAST                0 (a)    #same up to here
             15 LOAD_CONST               2 (0)    #loads 0
             18 LOAD_GLOBAL              1 (len) # loads the builtin len(),
                                                 # so it might take some lookup time
             21 LOAD_FAST                0 (a)
             24 CALL_FUNCTION            1         
             27 SLICE+3             
             28 STORE_FAST               1 (b)
             31 LOAD_CONST               0 (None)
             34 RETURN_VALUE        
4
  • This surely answers my questions and shows that there are multiple ways a n00b can write inefficient code - even in the latter timeit variant my copy was way slower than your implementation. Thanks! ;-)
    – Laas
    Oct 24, 2012 at 12:10
  • @Laas glad that helped :), and which one of these came out to be the fastest one in your system? Oct 24, 2012 at 12:16
  • @Laas you're right copy() is not the fastest one, I gad a mistake in my code(forgot to call cop` function in timeit) Oct 24, 2012 at 12:24
  • Yes, I got a[:] as the winner too. I updated the question with my timings.
    – Laas
    Oct 24, 2012 at 12:43
6

I can't comment on the ruby timing vs. the python timing. But I can comment on list vs. slice. Here's a quick inspection of the bytecode:

>>> import dis
>>> a = range(10)
>>> def func(a):
...     return a[:]
... 
>>> def func2(a):
...     return list(a)
... 
>>> dis.dis(func)
  2           0 LOAD_FAST                0 (a)
              3 SLICE+0             
              4 RETURN_VALUE        
>>> dis.dis(func2)
  2           0 LOAD_GLOBAL              0 (list)
              3 LOAD_FAST                0 (a)
              6 CALL_FUNCTION            1
              9 RETURN_VALUE 

Notice that list requires a LOAD_GLOBAL to find the function list. Looking up globals (and calling functions) in python is relatively slow. This would explain why a[0:len(a)] is also slower. Also remember that list needs to be able to handle arbitrary iterators whereas slicing doesn't. This means that list needs to allocate a new list, pack elements into that list as it iterates over the list and resize when necessary. There are a few things in here which are expensive -- resizing if necessary and iterating (effectively in python, not C). With the slicing method, you can calculate the size of the memory you'll need so can probably avoid resizing, and the iteration can be done completely in C (probably with a memcpy or something.

disclaimer : I'm not a python dev, so I don't know how the internals of list() are implemented for sure. I'm just speculating based what I know of the specification.

EDIT -- So I've looked at the source (with a little guidance from Martijn). The relevant code is in listobject.c. list calls list_init which then calls listextend at line 799. That function has some checks to see if it can use a fast branch if the object is a list or a tuple (line 812). Finally, the heavy lifting is done starting at line 834:

 src = PySequence_Fast_ITEMS(b);
 dest = self->ob_item + m;
 for (i = 0; i < n; i++) {
     PyObject *o = src[i];
     Py_INCREF(o);
     dest[i] = o;
 }

Compare that to the slice version which I think is defined in list_subscript (line 2544). That calls list_slice (line 2570) where the heavy lifting is done by the following loop (line 486):

 src = a->ob_item + ilow;
 dest = np->ob_item;
 for (i = 0; i < len; i++) {
     PyObject *v = src[i];
     Py_INCREF(v);
     dest[i] = v;
 }

They're pretty much the same code, so it's not surprising that the performance is almost the same for large lists (where the overhead of the small stuff like unpacking slices, looking up global variables, etc becomes less important)


Here's how I would run the python tests (and the results for my Ubuntu system):

$ python -m timeit -s 'a=range(30)' 'list(a)'
1000000 loops, best of 3: 0.39 usec per loop
$ python -m timeit -s 'a=range(30)' 'a[:]'
10000000 loops, best of 3: 0.183 usec per loop
$ python -m timeit -s 'a=range(30)' 'a[0:len(a)]'
1000000 loops, best of 3: 0.254 usec per loop
15
  • Weird, but list(a) comes out to be the fastest one on my system. Oct 24, 2012 at 11:24
  • @AshwiniChaudhary -- what system? That is odd. It's slowest for me on my OS-X system and my Ubuntu linux system.
    – mgilson
    Oct 24, 2012 at 11:34
  • @AshwiniChaudhary: your lookup is local, vs. global in mgilson's case. If mgilson added len = __builtins__.len in his function it'd be faster too, I bet.
    – Martijn Pieters
    Oct 24, 2012 at 11:43
  • @MartijnPieters -- How is Ashwini's lookup local? Just because a is local that doesn't make len local ... (Though you're right that local variables are looked up faster than globals...). I suspect that the problem with his test is that range is included in the timing. This could make his results a lot more sensitive to various system fluctuations ...
    – mgilson
    Oct 24, 2012 at 11:54
  • @mgilson: it's in the iPython shell, so locals() is globals() is True. And range() is not included in his timings, only in the disassembly examples.
    – Martijn Pieters
    Oct 24, 2012 at 11:56

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