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I understand the concept of what timeit does but I am not sure how to implement it in my code.

How can I compare two functions, say insertion_sort and tim_sort, with timeit?

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5 Answers 5

up vote 73 down vote accepted

The way timeit works is to run setup code once and then make repeated calls to a series of statements. So, if you want to test sorting, some care is required so that one pass at an in-place sort doesn't affect the next pass with already sorted data (that, of course, would make the Timsort really shine because it performs best when the data already partially ordered).

Here is an example of how to set up a test for sorting:

>>> import timeit

>>> setup = '''
import random

s = [random.random() for i in range(1000)]
timsort = list.sort

>>> print min(timeit.Timer('a=s[:]; timsort(a)', setup=setup).repeat(7, 1000))

Note that the series of statements makes a fresh copy of the unsorted data on every pass.

Also, note the timing technique of running the measurement suite seven times and keeping only the best time -- this can really help reduce measurement distortions due to other processes running on your system.

Those are my tips for using timeit correctly. Hope this helps :-)

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Yes, it includes the list copy (which is very fast compared to the sort itself). If you don't copy though, the first pass sorts the list and remaining passed don't have to do any work. If you want to know the time just for the sort, then run the above with and without the timsort(a) and take the difference :-) –  Raymond Hettinger Feb 7 '12 at 1:58
@max Use the min() rather than the average of the timings. That is a recommendation from me, from Tim Peters, and from Guido van Rossum. The fastest time represents the best an algorithm can perform when the caches are loaded and the system isn't busy with other tasks. All the timings are noisy -- the fastest time is the least noisy. It is easy to show that the fastest timings are the most reproducible and therefore the most useful when timing two different implementations. –  Raymond Hettinger Apr 3 '12 at 19:43
You calculate an average (well, total, but it's equivalent) for 1000 inputs; then repeat 7 times, and take the minimum. You need the averaging over 1000 inputs because you want the average (not best-case) algorithm complexity. You need the minimum for precisely the reason you gave. I thought I can improve your approach by choosing one input, running the algorithm 7 times, taking the minimum; then repeating it for 1000 different inputs, and taking the average. What I didn't realize is that your .repeat(7,1000) already does this (by using the same seed)! So your solution is perfect IMO. –  max Apr 3 '12 at 21:04
I can only add that how you allocate your budget of 7000 executions (e.g., .repeat(7, 1000) vs. .repeat(2, 3500) vs .repeat(35, 200) should depend on how the error due to system load compares to the error due to input variability. In the extreme case if your system is always under heavy load, and you see a long thin tail on the left of execution time distribution (when you catch it in a rare idle state), you might even find .repeat(7000,1) to be more useful than .repeat(7,1000) if you can't budget more than 7000 runs. –  max Apr 3 '12 at 21:19
Wouldn't "HeartOfGold" make for a better random seed? ;) –  Aaron Hall Feb 15 '14 at 22:35

If you want to use timeit in an interactive Python session, there are two convenient options:

  1. Use the IPython shell. It features the convenient %timeit special function:

    In [1]: def f(x):
       ...:     return x*x
    In [2]: %timeit for x in range(100): f(x)
    100000 loops, best of 3: 20.3 us per loop
  2. In a standard Python interpreter, you can access functions and other names you defined earlier during the interactive session by importing them from __main__ in the setup statement:

    >>> def f(x):
    ...     return x * x 
    >>> import timeit
    >>> timeit.repeat("for x in range(100): f(x)", "from __main__ import f",
    [2.0640320777893066, 2.0876040458679199, 2.0520210266113281]
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+1 for showing the from __main__ import f technique. I don't think this is as widely known as it should be. It is useful in cases like this where a function or method call is being timed. In other cases (timing a series of steps), it is less helpful because it introduces function call overhead. –  Raymond Hettinger Nov 22 '11 at 2:30
+1 for IPython %magic –  kmonsoor Jan 26 '14 at 11:36
from __main__ import f. It is awesome... –  BHAT IRSHAD Dec 22 '14 at 16:38
You can just do %timeit f(x) –  qed Dec 23 '14 at 15:55

I find the easiest way to use timeit is from the command line:

Given test.py:

def InsertionSort(): ...
def TimSort(): ...

run timeit like this:

% python -mtimeit -s'import test' 'test.InsertionSort()'
% python -mtimeit -s'import test' 'test.TimSort()'
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I'll let you in on a secret: the best way to use timeit is on the command line.

On the command line, timeit does proper statistical analysis: it tells you how long the shortest run took. This is good because all error in timing is positive. So the shortest time has the least error in it. There's no way to get negative error because a computer can't ever compute faster than it can compute!

So, the command-line interface:

%~> python -m timeit "1 + 2"
10000000 loops, best of 3: 0.0468 usec per loop

That's quite simple, eh?

You can set stuff up:

%~> python -m timeit -s "x = range(10000)" "sum(x)"
1000 loops, best of 3: 543 usec per loop

which is useful, too!

If you want multiple lines, you can either use the shell's automatic continuation or use separate arguments:

%~> python -m timeit -s "x = range(10000)" -s "y = range(100)" "sum(x)" "min(y)"
1000 loops, best of 3: 554 usec per loop

That gives a setup of

x = range(1000)
y = range(100)

and times


If you want to have longer scripts you might be tempted to move to timeit inside a Python script. I suggest avoiding that because the analysis and timing is simply better on the command line. Instead, I tend to make shell scripts:


 ... # lots of stuff


 echo Minmod arr1
 python -m timeit -s "$SETUP" "Minmod(arr1)"

 echo pure_minmod arr1
 python -m timeit -s "$SETUP" "pure_minmod(arr1)"

 echo better_minmod arr1
 python -m timeit -s "$SETUP" "better_minmod(arr1)"

 ... etc

This can take a bit longer due to the multiple initialisations, but normally that's not a big deal.

But what if you want to use timeit inside your module?

Well, the simple way is to do:

def function(...):


and that gives you cumulative (not minimum!) time to run that number of times.

To get a good analysis, use .repeat and take the minimum:

min(timeit.Timer(function).repeat(repeat=REPEATS, number=NUMBER))

You should normally combine this with functools.partial instead of lambda: ... to lower overhead. Thus you could have something like:

from functools import partial

def to_time(items):

test_items = [1, 2, 3] * 100
times = timeit.Timer(partial(to_time, test_items)).repeat(3, 1000)

# Divide by the number of repeats
time_taken = min(times) / 1000

You can also do:

timeit.timeit("...", setup="from __main__ import ...", number=NUMBER)

which would give you something closer to the interface from the command-line, but in a much less cool manner. The "from __main__ import ..." lets you use code from your main module inside the artificial environment created by timeit.

It's worth noting that this is a convenience wrapper for Timer(...).timeit(...) and so isn't particularly good at timing. I personally far prefer using Timer as I've shown above.


There are a few caveats with timeit that hold everywhere.

  • Overhead is not accounted for. Say you want to time x += 1, to find out how long addition takes:

    >>> python -m timeit -s "x = 0" "x += 1"
    10000000 loops, best of 3: 0.0476 usec per loop

    Well, it's not 0.0476 µs. You only know that it's less than that. All error is positive.

    So try and find pure overhead:

    >>> python -m timeit -s "x = 0" ""      
    100000000 loops, best of 3: 0.014 usec per loop

    That's a good 30% overhead just from timing! This can massively skew relative timings. But you only really cared about the adding timings; the look-up timings for x also need to be included in overhead:

    >>> python -m timeit -s "x = 0" "x"
    100000000 loops, best of 3: 0.0166 usec per loop

    The difference isn't much larger, but it's there.

  • Mutating methods are dangerous.

    python -m timeit -s "x = [0]*100000" "while x: x.pop()"
    10000000 loops, best of 3: 0.0436 usec per loop

    But that's completely wrong! x is the empty list after the first iteration. You'll need to reinitialize:

    >>> python -m timeit "x = [0]*100000" "while x: x.pop()"
    100 loops, best of 3: 9.79 msec per loop

    But then you have lots of overhead. Account for that separately.

    >>> python -m timeit "x = [0]*100000"                   
    1000 loops, best of 3: 261 usec per loop

    Note that subtracting the overhead is reasonable here only because the overhead is a small-ish fraction of the time.

    For your example, it's worth noting that both Insertion Sort and Tim Sort have completely unusual timing behaviours for already-sorted lists. This means you will require a random.shuffle between sorts if you want to avoid wrecking your timings.

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If you want to compare two blocks of code / functions quickly you could do:

import timeit

start_time = timeit.default_timer()
print(timeit.default_timer() - start_time)

start_time = timeit.default_timer()
print(timeit.default_timer() - start_time)
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