# Python Efficiency / Optimization Project Euler #5 example

I wrote this solution to Project Euler #5.

``````import time
start_time = time.time()

def ProjectEulerFive (m = 20):

a = m
start = 2
while (m % start) == 0:
start += 1

b = start
while b < m:
if ( a % b) != 0:
a += m
b = start
continue
else:
b += 1
return a

import sys

if (len(sys.argv)) > 2:
print "error: this function takes a max of 1 argument"
elif (len(sys.argv)) == 2:
print ProjectEulerFive(int(sys.argv[1]))
else:
print ProjectEulerFive();

print "took " + str(time.time() - start_time ) + " seconds"
``````

Takes my system about 8.5 seconds.

Then I decided to compare with other peoples solutions. I found this Project Euler 5 in Python - How can I optimize my solution?.

I hadn't thought of unique prime factorization.

But anyways, one supposedly optimized non-prime factorization based solution posted there:

``````import time
start_time = time.time()

check_list = [11, 13, 14, 16, 17, 18, 19, 20]

def find_solution(step):
for num in xrange(step, 999999999, step):
if all(num % n == 0 for n in check_list):
return num
return None

if __name__ == '__main__':
solution = find_solution(20)
if solution is None:
print "No answer found"
else:
print "found an answer:", solution

print "took " + str(time.time() - start_time ) + " seconds"
``````

Takes my system about 37 seconds

My code is about 4 times faster even though I unnecessarily check for divisibility of 3,4,5,6,7,8,9,10, and 12.

I'm new to python, and having trouble seeing where the inefficiency is coming from.

EDIT:

I did another test.

``````import time
start_time = time.time()

def ProjectEulerFive (m = 20):
ls = [11, 13, 14, 15, 16, 17, 18, 19]
a = m
i = 0
while i < len(ls):
if ( a % ls[i]) != 0:
a += m
i = 0
continue
else:
i += 1
return a

print ProjectEulerFive();
print "took " + str(time.time() - start_time ) + " seconds"
``````

Takes my system 6 seconds, but this:

``````import time
start_time = time.time()

def ProjectEulerFive (m = 20):

a = m
start = 11

b = start
while b < m:
if ( a % b) != 0:
a += m
b = start
continue
else:
b += 1
return a

print ProjectEulerFive()
print "took " + str(time.time() - start_time ) + " seconds"
``````

Takes about 3.7 seconds

-
Maybe an interesting question on an academic level, but if you were writing a real application, you would either be happy now that the problem is solved, or, in that order 1. try a faster algorithm, 2. use a library that does the performance critical stuff already, 3. run the code with pypy, 4. rewrite it in C (possibly as Python extension via swig or cython). But micro-optimizing interpreted code... nope ;-) –  maxy Jul 15 '12 at 17:24
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## 3 Answers

I see that although a faster solution has been posted, no one has actually answered the question. It's a rather difficult one to answer, in fact! The fundamental explanation is that function calls are relatively expensive. In order to make this conclusion persuasive, though, I'll have to dig fairly deeply into Python internals. Prepare yourself!

First of all, I'm going to disassemble (your third version of) `ProjectEulerFive` and `find_solution` from the "optimized" solution, using `dis.dis`. There's a lot here, but a quick scan is all that's required to confirm that your code calls no functions at all:

``````>>> dis.dis(ProjectEulerFive)
2           0 LOAD_FAST                0 (m)
3 STORE_FAST               1 (a)

3           6 LOAD_CONST               1 (11)
9 STORE_FAST               2 (start)

4          12 LOAD_FAST                2 (start)
15 STORE_FAST               3 (b)

5          18 SETUP_LOOP              64 (to 85)
>>   21 LOAD_FAST                3 (b)
24 LOAD_FAST                0 (m)
27 COMPARE_OP               0 (<)
30 POP_JUMP_IF_FALSE       84

6          33 LOAD_FAST                1 (a)
36 LOAD_FAST                3 (b)
39 BINARY_MODULO
40 LOAD_CONST               2 (0)
43 COMPARE_OP               3 (!=)
46 POP_JUMP_IF_FALSE       71

7          49 LOAD_FAST                1 (a)
52 LOAD_FAST                0 (m)
55 INPLACE_ADD
56 STORE_FAST               1 (a)

8          59 LOAD_FAST                2 (start)
62 STORE_FAST               3 (b)

9          65 JUMP_ABSOLUTE           21
68 JUMP_ABSOLUTE           21

11     >>   71 LOAD_FAST                3 (b)
74 LOAD_CONST               3 (1)
77 INPLACE_ADD
78 STORE_FAST               3 (b)
81 JUMP_ABSOLUTE           21
>>   84 POP_BLOCK

12     >>   85 LOAD_FAST                1 (a)
88 RETURN_VALUE
``````

Now let's look at `find_solution`:

``````>>> dis.dis(find_solution)
2           0 SETUP_LOOP              58 (to 61)
3 LOAD_GLOBAL              0 (xrange)
6 LOAD_FAST                0 (step)
9 LOAD_CONST               1 (999999999)
12 LOAD_FAST                0 (step)
15 CALL_FUNCTION            3
18 GET_ITER
>>   19 FOR_ITER                38 (to 60)
22 STORE_DEREF              0 (num)

3          25 LOAD_GLOBAL              1 (all)
28 LOAD_CLOSURE             0 (num)
31 BUILD_TUPLE              1
34 LOAD_CONST               2 (<code object <genexpr> at
0x10027eeb0, file "<stdin>",
line 3>)
37 MAKE_CLOSURE             0
40 LOAD_GLOBAL              2 (check_list)
43 GET_ITER
44 CALL_FUNCTION            1
47 CALL_FUNCTION            1
50 POP_JUMP_IF_FALSE       19

4          53 LOAD_DEREF               0 (num)
56 RETURN_VALUE
57 JUMP_ABSOLUTE           19
>>   60 POP_BLOCK

5     >>   61 LOAD_CONST               0 (None)
64 RETURN_VALUE
``````

Immediately it becomes clear that (a) this code is much less complex, but (b) it also calls three different functions. The first one is simply a single call to `xrange`, but the other two calls appear inside the outermost for loop. The first call is the call to `all`; the second, I suspect, is the generator expression's `next` method being called. But it doesn't really matter what the functions are; what matters is that they are called inside the loop.

Now, you might think "What's the big deal?" here. It's just a function call; a few nanoseconds here or there -- right? But in fact, those nanoseconds add up. Since the outermost loop proceeds through a total of `232792560 / 20 == 11639628` loops, any overhead gets multiplied by more than eleven million. A quick timing using the `%timeit` command in `ipython` shows that a function call -- all by itself -- costs about 120 nanoseconds on my machine:

``````>>> def no_call():
...     pass
...
>>> def calling():
...     no_call()
...
>>> %timeit no_call()
10000000 loops, best of 3: 107 ns per loop
>>> %timeit calling()
1000000 loops, best of 3: 235 ns per loop
``````

So for every function call that appears inside the while loop, that's `120 nanoseconds * 11000000 = 1.32 seconds` more time spent. And if I'm right that the second function call is a call to the generator expression's `next` method, then that function is called even more times, once for every iteration through the genex -- probably 3-4 times per loop on average.

Now to test this hypothesis. If function calls are the problem, then eliminating function calls is the solution. Let's see...

``````def find_solution(step):
for num in xrange(step, 999999999, step):
for n in check_list:
if num % n != 0:
break
else:
return num
return None
``````

Here's a version of `find_solution` that does almost exactly what the original does using `for/else` syntax. The only function call is the outer one, to `xrange`, which shouldn't cause any problems. Now, when I timed the original version, it took 11 seconds:

``````found an answer: 232792560
took 11.2349967957 seconds
``````

Let's see what this new, improved version manages:

``````found an answer: 232792560
took 2.12648200989 seconds
``````

That's a hair faster than the performance of your fastest version of `ProjectEulerFive` on my machine:

``````232792560
took 2.40848493576 seconds
``````

And everything makes sense again.

-
Very nice answer. –  MVTC Jul 15 '12 at 16:02
@MVTCplusplus, see also here for what I believe is the fastest approach to this problem. –  senderle Jul 15 '12 at 16:25
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Not an answer to your question (hence the community wiki), but here is a useful decorator for timing functions:

``````from functools import wraps
import time

def print_time(f):
@wraps(f)
def wrapper(*args, **kwargs):
t0 = time.time()
result = f(*args, **kwargs)
print "{0} took {1}s".format(f.__name__, time.time() - t0)
return result
return wrapper
``````

Usage is as follows:

``````@print_time
def foo(x, y):
time.sleep(1)
return x + y
``````

And in practice:

``````>>> foo(1, 2)
foo took 1.0s
3
``````
-
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This ought to take about no time:

``````def gcd(a, b):
if (b == 0): return a
else: return gcd(b, a%b)

def lcm(a, b):
return abs(a*b) / gcd(a, b)

def euler5(n):
if (n == 1): return 1
else: return lcm(n, euler5(n-1))

print euler5(20)
``````
-
Perfect solution. Takes 0.000147819519043 seconds on my system. –  MVTC Jul 14 '12 at 22:04
A way to optimize further is to turn all of your recursive functions into iterative ones. This is because Python doesn't do tail call optimization and you can eliminate the function call overhead by using iteration. –  Joel Cornett Jul 14 '12 at 22:07
No need to write your own `gcd`; there's one in the `fractions` module. [Admittedly it's never easy to know where to draw the line in terms of what you should allow yourself access to for Euler problems..] –  DSM Jul 14 '12 at 22:18
@MVTCplusplus: I'm disappointed. I was trying for less. –  user448810 Jul 14 '12 at 22:40
@JoelCornett: These functions are simple enough that it doesn't matter. But look sometime at avl trees in recursive Scheme and iterative C to see a situation where it does matter. I prefer the readable but slower recursive version; fortunately, I normally use a language that doesn't make me choose. –  user448810 Jul 14 '12 at 23:10
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