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I've recently been working on Project Euler problems in Python. I am fairly new to Python, and still somewhat new as a programmer.

In any case, I've ran into a speed-related issue coding a solution for problem #5. The problem is,

"2520 is the smallest number that can be divided by each of the numbers from 1 to 10 without any remainder. What is the smallest positive number that is evenly divisible by all of the numbers from 1 to 20?"

I've checked around some, and I haven't been able to find anything on this problem pertaining to Python specifically. There were some completed scripts, but I want to avoid looking at other's code in full, if possible, instead wanting to improve my own.

The code I have written runs successfully for the example of 2520 and the range 1 to 10, and should be directly modifiable to work with the question. However, upon running it, I do not get an answer. Presumably, it is a very high number, and the code is not fast enough. Printing the current number being checked seems to support this, reaching several million without getting an answer.

The code, in it's current implementation is as follows:

rangemax = 20
def div_check(n):
    for i in xrange(11,rangemax+1):
        if n % i == 0:
            continue
        else:
            return False
    return True

if __name__ == '__main__':
   num = 2
   while not div_check(num):
       print num
       num += 2
   print num

I have already made a couple changes which I think should help the speed. For one, for a number to be divisible by all numbers 1 to 20, it must be even, as only even numbers are divisible by 2. Hence, I can increment by 2 instead of 1. Also, although I didn't think of it myself, I found someone point out that a number divisible by 11 to 20 is divisible by 1 to 10. (Haven't checked that one, but it seems reasonable)

The code still, however is not fast enough. What optimisations, either programmatic, or mathematics, can I make to make this code run faster?

Thanks in advance to any who can help.

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2  
Not code-related, but by the same logic you used to notice that the number has to be a multiple of 2, you can also conclude it has to be a multiple of 3,4,...,10, and therefore must be a multiple of the least common multiple of all of those, namely 2520. –  David Z Nov 6 '11 at 2:52
    
Thanks, didn't think of that. I'll try to implement code making use of the LCM. For future reference, is this question overly math-oriented, or is it acceptable as a code-related question? –  George Osterweil Nov 6 '11 at 2:59
1  
It's broad enough to be both, though I expect that the most beneficial optimizations you can make will be mathematical, not programmatic. Still, Stack Overflow's standards as to what constitutes a programming related question aren't particularly tight, so I suppose it's fine here. –  David Z Nov 6 '11 at 3:03
7  
For example for this question it is quite easy to use maths knowledge, make a prime factorization and find out that the least common multiple of all those numbers is 232792560 = 2*2*2*2*3*3*5*7*11*13*17*19. But it depends a lot on the question type to see if manual maths actually works good enough, or a simple program can solve it much faster (or more efficient). –  poke Nov 6 '11 at 3:11
1  
@poke: It is much simpler. [Giltheryn SPOILERS!!! You've been warned] See here. –  J.F. Sebastian Nov 6 '11 at 3:15

9 Answers 9

up vote 6 down vote accepted

Taking the advice of Michael Mior and poke, I wrote a solution. I tried to use a few tricks to make it fast.

Since we need a relatively short list of numbers tested, then we can pre-build the list of numbers rather than repeatedly calling xrange() or range().

Also, while it would work to just put the numbers [1, 2, 3, ..., 20] in the list, we can think a little bit, and pull numbers out:

Just take the 1 out. Every integer is evenly divisible by 1.

If we leave the 20 in, there is no need to leave the 2 in. Any integer evenly divisible by 20 is evenly divisible by 2 (but the reverse might not be true). So we leave the 20 and take out the 2, the 4, and the 5. Leave the 19, as it's prime. Leave the 18, but now we can take out the 3 and the 6. If you repeat this process, you wind up with a much shorter list of numbers to try.

We start at 20 and step numbers by 20, as Michael Mior suggested. We use a generator expression inside of all(), as poke suggested.

Instead of a while loop, I used a for loop with xrange(); I think this is slightly faster.

The result:

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

On my computer, this finds an answer in under nine seconds.

EDIT: And, if we take advice from David Zaslavsky, we realize we can start the loop at 2520, and step by 2520. If I do that, then on my computer I get the correct answer in about a tenth of a second.

I made find_solution() take an argument. Try calling find_solution(2520).

share|improve this answer
    
It occurs to me that we could write Python code to generate a list of numbers [2, 3, 4, 5, ..., N] and then loop over it and pull out all the non-needed numbers. Then we could multiply together all the numbers pulled out to get our starting value and step value. And that is just a few changes away from the most elegant solution, which is to just find the minimum set of prime factors and multiply them all together. –  steveha Nov 6 '11 at 8:07
    
Oh, you can't just multiply all the numbers pulled out; that list includes 2, 4, 6, 8, 10, etc. The final answer is too large, because it has more factors of 2 than it should; and so on. It's a common multiple but not the least common multiple. –  steveha Nov 6 '11 at 9:01
    
Quite, helpful, thanks. Implementing much of this logic results in finding the solution in a matter of seconds, rather than over 10 minutes previously. –  George Osterweil Nov 6 '11 at 14:40
    
Upon fully implementing this, the code completed in under a second. I didn't measure the exact runtime, but it was by far fast enough. –  George Osterweil Nov 6 '11 at 14:57
    
It seems to me that this code returns '20' as the answer rather than the actual solution, have I gone wrong somewhere or did other people get similar answers? –  KRS-fun Feb 13 at 13:33

My first answer sped up the original calculation from the question.

Here's another answer that solves it a different way: just find all the prime factors of each number, then multiply them together to go straight to the answer. In other words, this automates the process recommended by poke in a comment.

It finishes in a fraction of a second. I don't think there is a faster way to do this.

I did a Google search on "find prime factors Python" and found this:

http://www.stealthcopter.com/blog/2009/11/python-factors-of-a-number/

From that I found a link to factor.py (written by Mike Hansen) with some useful functions:

http://sage.math.washington.edu/home/mhansen/factor.py

His functions didn't do quite what I wanted, so I wrote a new one but used his pull_prime_factors() to do the hard work. The result was find_prime_factors() which returns a list of tuples: a prime number, and a count. For example, find_prime_factors(400) returns [(2,4), (5,2)] because the prime factors of 400 are: (2*2*2*2)*(5*5)

Then I use a simple defaultdict() to keep track of how many we have seen so far of each prime factor.

Finally, a loop multiplies everything together.

from collections import defaultdict
from factor import pull_off_factors

pf = defaultdict(int)

_primes = [2,3,5,7,11,13,17,19,23,29]
def find_prime_factors(n):
    lst = []
    for p in _primes:
        n = pull_off_factors(n, p, lst)
    return lst

def find_solution(low, high):
    for num in xrange(low, high+1):
        lst = find_prime_factors(num)
        for n, count in lst:
            pf[n] = max(pf[n], count)

    print "prime factors:", pf
    solution = 1
    for n, count in pf.items():
        solution *= n**count

    return solution

if __name__ == '__main__':
    solution = find_solution(1, 20)
    print "answer:", solution

EDIT: Oh wow, I just took a look at @J.F. Sebastian's answer to a related question. His answer does essentially the same thing as the above code, only far more simply and elegantly. And it is in fact faster than the above code.

Least common multiple for 3 or more numbers

I'll leave the above up, because I think the functions might have other uses in Project Euler. But here's the J.F. Sebastian solution:

def gcd(a, b):
    """Return greatest common divisor using Euclid's Algorithm."""
    while b:
        a, b = b, a % b
    return a

def lcm(a, b):
    """Return lowest common multiple."""
    return a * b // gcd(a, b)

def lcmm(*args):
    """Return lcm of args."""   
    return reduce(lcm, args)

def lcm_seq(seq):
    """Return lcm of sequence."""
    return reduce(lcm, seq)

solution = lcm_seq(xrange(1,21))
print "lcm_seq():", solution

I added lcm_seq() but you could also call:

lcmm(*range(1, 21))
share|improve this answer

Since your answer must be divisible by 20, you can start at 20 and increment by 20 instead of by two. In general, you can start at rangemax and increment by rangemax. This reduces the number of times div_check is called by an order of magnitude.

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List comprehensions are faster than for loops.

Do something like this to check a number:

def get_divs(n):
    divs = [x for x in range(1,20) if n % x == 0]
    return divs

You can then check the length of the divs array to see if all the numbers are present.

share|improve this answer
1  
Then you can also simply do return all( n % x == 0 for x in range(1,21) ) – note the upper range 21 to include the 20 in the checks. –  poke Nov 6 '11 at 3:17
    
I've not gotten in to list comprehensions yet, but it's easy enough to find out. I'll check that out, thanks. –  George Osterweil Nov 6 '11 at 3:21
    
Glitheryn, the solution by khill is a list comprehension solution, which generates a list. The solution by poke is a "generator expression" solution, which is similar to a listcomp but doesn't build the whole list; it yields numbers one at a time, which gives a speed advantage. A listcomp must build a list; if you didn't want the list, but just the numbers, then the list gets used once and then gets taken apart again. The overhead of building up and tearing down the list can be avoided by the genexp. –  steveha Nov 6 '11 at 7:32

Two different types of solutions have been posted here. One type uses gcd calculations; the other uses prime factorization. I'll propose a third type, which is based on the prime factorization approach, but is likely to be much faster than prime factorization itself. It relies on a few simple observations about prime powers -- prime numbers raised to some integral exponent. In short, it turns out that the least common multiple of all numbers below some number n is equal to the product of all maximal prime powers below n.

To prove this, we begin by thinking about the properties that x, the least common multiple of all numbers below n, must have, and expressing them in terms of prime powers.

  1. x must be a multiple of all prime powers below n. This is obvious; say n = 20. 2, 2 * 2, 2 * 2 * 2, and 2 * 2 * 2 * 2 are all below 20, so they all must divide x. Likewise, 3 and 3 * 3 are both below n and so both must divide x.

  2. If some number a is a multiple of the prime power p ** e, and p ** e is the maximal power of p below n, then a is also a multiple of all smaller prime powers of p. This is also quite obvious; if a == p * p * p, then a == (p * p) * p.

  3. By the unique factorization theorem, any number m can be expressed as a multiple of prime powers less than m. If m is less than n, then m can be expressed as a multiple of prime powers less than n.

Taken together, the second two observations show that any number x that is a multiple of all maximal prime powers below n must be a common multiple of all numbers below n. By (2), if x is a multiple of all maximal prime powers below n, it is also a multiple of all prime powers below n. So by (3), it is also a multiple of all other numbers below n, since they can all be expressed as multiples of prime powers below n.

Finally, given (1), we can prove that x is also the least common multiple of all numbers below n, because any number less than x could not be a multiple of all maximal prime powers below n, and so could not satisfy (1).

The upshot of all this is that we don't need to factorize anything. We can just generate primes less than n!

Given a nicely optimized sieve of eratosthenes, one can do that very quickly for n below one million. Then all you have to do is find the maximal prime power below n for each prime, and multiply them together.

prime_powers = [get_max_prime_power(p, n) for p in sieve(n)]
result = reduce(operator.mul, prime_powers)

I'll leave writing get_max_prime_power as an exercise. A fast version, combined with the above, can generate the lcm of all numbers below 200000 in 3 seconds on my machine.

The result is a 86871-digit number!

share|improve this answer
    
@steveha, I think you were on the right track with your prime factorization approach; see the above for another optimization that (on my machine) results in much faster code than any of the gcd-based code here, at least for large values. –  senderle Jul 15 '12 at 16:31

I got the solution in 0.066 milliseconds (only 74 spins through a loop) using the following procedure:

Start with smallest multiple for 1, which = 1. Then find the smallest multiple for the next_number_up. Do this by adding the previous smallest multiple to itself (smallest_multiple = smallest_multiple + prev_prod) until next_number_up % smallest_multiple == 0. At this point smallest_multiple is the correct smallest multiple for next_number_up. Then increment next_number_up and repeat until you reach the desired smallest_multiple (in this case 20 times). I believe this finds the solution in roughly n*log(n) time (though, given the way numbers seem to work, it seems to complete much faster than that usually).

For example:

1 is the smallest multiple for 1

Find smallest multiple for 2

Check if previous smallest multiple works 1/2 = .5, so no

previous smallest multiple + previous smallest multiple == 2.

Check if 2 is divisible by 2 - yes, so 2 is the smallest multiple for 2

Find smallest multiple for 3

Check if previous smallest multiple works 2/3 = .667, so no

previous smallest multiple + previous smallest multiple == 4

Check if 4 is divisible by 3 - no

4 + previous smallest multiple == 6

Check if 6 is divisible by 3 - yes, so 6 is the smallest multiple for 3

Find smallest multiple for 4

Check if previous smallest multiple works 6/4 = 1.5, so no

previous smallest multiple + previous smallest multiple == 12

Check if 12 is divisble by 4 - yes, so 12 is the smallest multiple for 4

repeat until 20..

Below is code in ruby implementing this approach:

def smallestMultiple(top)
    prod = 1
    counter = 0
    top.times do
        counter += 1
        prevprod = prod
        while prod % counter != 0
            prod = prod + prevprod
        end
    end
    return prod
end
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Here is program in C language. Cheers

#include <stdio.h>
#include <stdlib.h>
//2520 is the smallest number that can be divided by each of the numbers from 1 to 10 without any remainder.
//What is the smallest positive number that is evenly divisible by all of the numbers from 1 to 20?
bez_ost(int q)
{
    register br=0;
    for( register i=1;i<=20;i++)
    if(q%i==0)
    br++;

    if(br==20)
    return 1;
    return 0;
}

int main()
{
   register j=20;
   register ind=0;

   while(ind!=1)
   {
       j++;
       if(bez_ost(j))
       break;
   }
   fprintf(stdout,"\nSmallest positive number that is evenlu divisible by all of the numbers from 1 to 20 is: %d\n\a",j);
   system("Pause");

}
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I've had the same problem. The algorithm seems to be quite slow, but it does work nonetheless.

result = list()
xyz = [x for x in range(11, 21)]
number = [2520]
count = 0
while len(result) == 0:
    for n in number:
        print n
        for x in xyz:
            if n % x == 0:
                count += 1
            elif n % x != 0:
                count = 0
                break
    if count == 10:
        result.append(number[0])
    elif count != 10:
        number[0] += 1

print result 

This was the algorithm I made.

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Break down the number as a prime factorization.

All primes less than 20 are:

2,3,5,7,11,13,17,19

So the bare minimum number that can be divided by these numbers is:

2*3*5*7*11*13*17*19

Composites:

4,6,8,9,10,12,14,15,16,18,20 = 2^2, 2*3, 2^3, 3^2, 2*5, 2^2*3, 2*7, 3*5, 2*3^2, 2^2*5

Starting from the left to see which factors needed:

  • 2^3 to build 4, 8, and 16
  • 3 to build 9
  • Prime factorization: 2^4 * 3^2 * 5 * 7 * 11 * 13 * 17 * 19 = 232,792,560
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