# Optimise the solution to Project Euler 12 (Python)

I have the following code for Project Euler Problem 12. However, it takes a very long time to execute. Does anyone have any suggestions for speeding it up?

``````n = input("Enter number: ")
def genfact(n):
t = []
for i in xrange(1, n+1):
if n%i == 0:
t.append(i)
return t

print "Numbers of divisors: ", len(genfact(n))
print

m = input("Enter the number of triangle numbers to check: ")
print
for i in xrange (2, m+2):
a = sum(xrange(i))
b = len(genfact(a))
if b > 500:
print a
``````

For n, I enter an arbitrary number such as 6 just to check whether it indeed returns the length of the list of the number of factors. For m, I enter entered 80 000 000

It works relatively quickly for small numbers. If I enter `b > 50` ; it returns 28 for a, which is correct.

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My answer here isn't pretty or elegant, it is still brute force. But, it simplifies the problem space a little and terminates successfully in less than 10 seconds.

Getting factors of n: Like @usethedeathstar mentioned, it is possible to test for factors only up to `n/2`. However, we can do better by testing only up to the square root of n:

``````let n = 36
=> factors(n) : (1x36, 2x18, 3x12, 4x9, 6x6, 9x4, 12x3, 18x2, 36x1)
``````

As you can see, it loops around after 6 (the square root of 36). We also don't need to explicitly return the factors, just find out how many there are... so just count them off with a generator inside of sum():

``````import math

def get_factors(n):
return sum(2 for i in range(1, round(math.sqrt(n)+1)) if not n % i)
``````

Testing the triangular numbers

I have used a generator function to yield the triangular numbers:

``````def generate_triangles(limit):
l = 1
while l <= limit:
yield sum(range(l + 1))
l += 1
``````

And finally, start testing:

``````def test_triangles():
triangles = generate_triangles(100000)
for i in triangles:
if get_factors(i) > 499:
return i
``````

Running this with the profiler, it completes in less than 10 seconds:

``````\$ python3 -m cProfile euler12.py

361986 function calls in 8.006 seconds
``````

The BIGGEST time saving here is `get_factors(n)` testing only up to the square root of n - this makes it heeeaps quicker and you save heaps of memory overhead by not generating a list of factors.

As I said, it still isn't pretty - I am sure there are more elegant solutions. But, it fits the bill of being faster :)

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wow - when you complete this you get to read Project Euler's overview on the problem. They have some very cool approaches :) –  Nick Burns Jul 19 '13 at 11:55
Hi, thanks for the reply. def get_factors(n): return sum(2 for i in range(1, round(math.sqrt(n)+1)) if not n % i) You said you use a generator within the sum. Could you explain this please –  TopGun Jul 19 '13 at 12:18
My solution already counted to sqrt(n) instead of n/2?, and the fact of not writing them to memory but just counting doesnt improve much? –  usethedeathstar Jul 19 '13 at 13:52
Yeah this definitely helps. I just wanted to understand how the 'generator' works 'within the sum'. –  TopGun Jul 19 '13 at 14:01
@TopGun, hey, the `sum(...)` expression works like this: it tests every value `i` from `1 -> sqrt(n) + 1` and if `i` divides `n` evenly (`not n% i`), then it adds `2` to the sum. Putting it inside the sum(), means that it works in a similar way to `xrange` in Python2x, it evaluates one value at a time without needing to evaluate the entire sequence at once –  Nick Burns Jul 19 '13 at 20:16

one of the hints i can give is

``````def genfact(n):
t = []
for i in xrange(1, n+1):
if n%i == 0:
t.append(i)
return t
``````

change that to

``````def genfact(n):
t=[]
for i in xrange(1,numpy.sqrt(n)+1):
if(n%i==0):
t.append(i)
t.apend(n/i)
``````

since if a is a divisor than so is b=n/a, since a*b=a*n/b=n, That should help a part already (not sure if in your case a square is possible, but if so, add another case to exclude adding the same number twice)

You could devise a recursive thing too, (like if it is something like for 28, you get 1,28,2,14 and at the moment you are at knowing 14, you put in something to actually remember the divisors of 14 (memoize), than check if they are alraedy in the list, and if not, add them to the list, together with 28/d for each of the divisors of 14, and at the end just take out the duplicates

If you think my first answer is still not fast enough, ask for more, and i will check how it would be done to solve it faster with some more tricks (could probably make use of erastothenes sieve or so too, and some other tricks could be thought up as well if you would wish to really blow up the problem to huge proportions, like to check the first one with over 10k divisors or so)

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Thanks for the reply. I understand the logic behind your modification. However, as you suspected, it's still too slow. :) –  TopGun Jul 19 '13 at 12:27