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I've profiled my application, and it spends 90% of its time in plus_minus_variations.

The function finds ways to make various numbers given a list of numbers using addition and subtraction.

For example:
Input

1, 2

Output

1+2=3
1-2=-1
-1+2=1
-1-2=-3

This is my current code. I think it could be improved a lot in terms of speed.

def plus_minus_variations(nums):
    result = dict()
    for i, ops in zip(xrange(2 ** len(nums)), \
            itertools.product([-1, 1], repeat=len(nums))):
        total = sum(map(operator.mul, ops, nums))
        result[total] = ops
    return result

I'm mainly looking for a different algorithm to approach this with. My current one seems pretty inefficient. However, if you have optimization suggestions about the code itself, I'd be happy to hear those too.

Additional:

  • It's okay if the result is missing some of the answers (or has some extraneous answers) if it finishes a lot faster.
  • If there are multiple ways to get a number, any of them are fine.
  • For the list sizes I'm using, 99.9% of the ways produce duplicate numbers.
  • It's okay if the result doesn't have the way that the numbers were produced, if, again, it finishes a lot faster.
share|improve this question

6 Answers 6

up vote 4 down vote accepted

This seems to be significantly faster for large random lists, I guess you could further micro-optimize it, but I prefer readability.

I chunk the list into smaller pieces and create variations for it. Since you get a lot less than 2 ** len(chunk) variatons it's going to be faster. Chunk length is 6, you can play with it to see what's the optimal chunk length.

def pmv(nums):
    chunklen=6
    res = dict()
    res[0] = ()
    for i in xrange(0, len(nums), chunklen):
        part = plus_minus_variations(nums[i:i+chunklen])
        resnew = dict()
        for (i,j) in itertools.product(res, part):
            resnew[i + j] = tuple(list(res[i]) + list(part[j]))
        res = resnew
    return res
share|improve this answer
    
You made me to look through your suggestion once again :-) Well, +1. –  tyz Aug 7 '11 at 15:37
    
Awesome, by using your chunking aproach, I reduced runtime of my function by a factor of 10^4. –  Nick ODell Aug 7 '11 at 17:52

If it is ok not to get trace of number producing there is no reasons to recalculate sum of number combination every time. You can store intermediate results:

def combine(l,r):
    res = set()
    for x in l:
        for y in r:
            res.add( x+y )
            res.add( x-y )
            res.add( -x+y )
            res.add( -x-y )
    return list(res)

def pmv(nums):
    if len(nums) > 1:
        l = pmv( nums[:len(nums)/2] )
        r = pmv( nums[len(nums)/2:] )
        return combine( l, r )
    return nums

EDIT: if the way of number generation is important you can use this variant:

def combine(l,r):
    res = dict()
    for x,q in l.iteritems():
        for y,w in r.iteritems():
            if not res.has_key(x+y):
                res[x+y] = w+q
                res[-x-y] = [-i for i in res[x+y]]
            if not res.has_key(x-y):
                res[x-y] = w+[-i for i in q]
                res[-x+y] = [-i for i in res[x-y]]
    return res

def pmv(nums):
    if len(nums) > 1:
        l = pmv( nums[:len(nums)/2] )
        r = pmv( nums[len(nums)/2:] )
        return combine( l, r )
    return {nums[0]:[1]}

My tests shows that it is still faster than the other solutions.

share|improve this answer
    
This is very interesting and very fast! (+1) –  Jiri Aug 7 '11 at 12:14
    
what kind of test did you do? I've tested it and my solution seems to be 1.5-2.5 times faster. I'm using random integers between 0 and 200 in the input. –  Karoly Horvath Aug 7 '11 at 14:18
    
also, with agf's implementation and changing the magic constant in my code to 5 it's almost 4x faster. –  Karoly Horvath Aug 7 '11 at 14:35
    
@yi_H, I've tested it on a range(1,100). Time of my solution - 4.25308320829, yours - 6.89982147061. Now I've checked the range 0 to 200. Results are 80.2901003113 and 76.8834856788. So you win on this data, but your algorithm does not provide significant handicap on my computer. –  tyz Aug 7 '11 at 14:51
    
test it with more than 18 elements. –  Karoly Horvath Aug 7 '11 at 14:54

EDITED:

Aha!
Code is in Python 3, inspired by tyz:

from functools import reduce # only in Python 3

def process(old, num):
    new = set(map(num.__add__, old)) # use itertools.imap for Python 2
    new.update(map((-num).__add__, old))
    return new

def pmv(nums):
    n = iter(nums)
    x = next(n)
    result = {x, -x} # set([x, -x]) for Python 2
    return reduce(process, n, result)

Instead of split half and recursive, I use reduce to compute it one by one. that extremely reduced the times of function calls.

Take less than 1 sec to compute 256 numbers.


Why product then mult?

def pmv(nums):
    return {sum(i):i for i in itertools.product(*((num, -num) for num in nums))}

Can be faster without how the numbers were produced:

def pmv(nums):
    return set(map(sum, itertools.product(*((num, -num) for num in nums))))
share|improve this answer
    
and even faster with itertools.imap; nice! –  tomasz Aug 7 '11 at 10:28
    
Also do from itertools import product and I think the second one is as fast as possible, the first one would be faster wth a normal loop instead of a dict comprehension, at least for me on Windows with Python 2.7. –  agf Aug 7 '11 at 11:04
    
now, that's fast :) –  Karoly Horvath Aug 7 '11 at 18:18

You can get something like a 50% speedup (at least for short lists) just by doing:

from itertools import product, imap
from operator import mul

def plus_minus_variations(nums):
    result = {}
    for ops in product((-1, 1), repeat=len(nums)):
        result[sum(imap(mul, ops, nums))] = ops
    return result

imap won't create intermediate lists you don't need. Importing into the local namespace saves the time attribute lookup takes. Tuples are faster than lists. Don't store unneeded intermediate items.

I tried this with a dict comprehension but it was a bit slower. I tried it with a set comprehension (not saving the ops) and it was the same speed.

I don't know why you were using zip and xrange at all... you weren't using the result in your calculation.

Edit: I get significant speedups with this version all the way up to the point where your version gives a memory error, not just for short lists.

share|improve this answer
    
Re: "I tried this with a dict comprehension..." -- meaning this? def plus_minus_variations(nums):\n return dict(\n (sum(imap(mul, ops, nums)), ops)\n for ops in product((-1, 1), repeat=len(nums))\n )\n –  hughdbrown Aug 9 '11 at 15:22
    
A dict comprehension is Python 2.7 / 3.2 syntactic sugar for that, {sum(imap(mul, ops, nums)): ops for ops in product((-1, 1), repeat = len(nums))} –  agf Aug 9 '11 at 15:28

From a mathematical point of view you finally arive at all multiples of the greatest common divisor of your startvalues.

For example:

  • startvalues 2,4. then the gcd(2,4) is 2, so the generated numbers are .. -4, -2, 0, 2, 4, ...
  • startvalues 3,5. then the gcd(3,5) is 1, you get all integers.
  • startvalues 12, 18, 15. the gcd(12,15,18) is 3, you get .. -6, -3, 0, 3, 6, ....
share|improve this answer
    
nice point, but you can't use a number more than once, so you get finite numbers of results. –  tomasz Aug 7 '11 at 10:41

This simple iterative method computes all possible sums. It could be about 5 times faster than the recursive method by @tyz.

def pmv(nums):
    sums = set()
    sums.add(0)
    for i in range(0, len(nums)):
        partialsums = set()
        for s in sums:
            partialsums.add(s + nums[i])
            partialsums.add(s - nums[i])
        sums = partialsums
    return sums
share|improve this answer

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