# Find the numbers that can be made with addition and subtraction, using all numbers given

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.

• 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.

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 = ()
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
``````
• You made me to look through your suggestion once again :-) Well, +1. – eugene_che 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:
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:}
``````

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

• This is very interesting and very fast! (+1) – Jiri Kriz 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. – eugene_che 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
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))))
``````
• 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

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.

• 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, ....
• 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()