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I have a list of numbers (example: [-1, 1, -4, 5]) and I have to remove numbers from the list without changing the total sum of the list. I want to remove the numbers with biggest absolute value possible, without changing the total, in the example removing [-1, -4, 5] will leave [1] so the sum doesn't change.

I wrote the naive approach, which is finding all possible combinations that don't change the total and see which one removes the biggest absolute value. But that is be really slow since the actual list will be a lot bigger than that.

Here's my combinations code:

from itertools import chain, combinations

def remove(items):
    all_comb = chain.from_iterable(combinations(items, n+1) 
                                   for n in xrange(len(items)))
    biggest = None
    biggest_sum = 0
    for comb in all_comb:
        if sum(comb) != 0:
            continue # this comb would change total, skip
        abs_sum = sum(abs(item) for item in comb)
        if abs_sum > biggest_sum:
            biggest = comb
            biggest_sum = abs_sum
    return biggest

print remove([-1, 1, -4, 5])

It corectly prints (-1, -4, 5). However I am looking for some clever, more efficient solution than looping over all possible item combinations.

Any ideas?

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3  
In this case, it's a win if we observe that the sum is an item in this list. If we have sum(items) and abs_sum(items) it is then likely more efficient trying to add up to the sum using 1, 2, 3, etc elements from the list, that is starting from the empty list case rather than the full list(?) –  u0b34a0f6ae Dec 19 '09 at 11:33
    
You should probably save smallest_abs_sum instead of biggest_sum. Consider: [1,-1,100,-100]. –  J.F. Sebastian Dec 19 '09 at 20:02
    
@J.F. Sebastian: If the input is [1,-1,100,-100] it should remove everything (abs_sum of 202) keeping the sum 0. –  nosklo Dec 19 '09 at 23:00
    
@nosklo: I've got it: your remove() function returns items to be removed, not the final result list. –  J.F. Sebastian Dec 22 '09 at 0:39
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5 Answers

if you redefine the problem as finding a subset whose sum equals the value of the complete set, you will realize that this is a NP-Hard problem, (subset sum)

so there is no polynomial complexity solution for this problem .

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Thank you for your answer, and the good link. Wikipedia seems to imply that there is a Pseudo-polynomial time dynamic programming solution, which means I'd store part of the solution to help with future calculation, but by reading it I couldn't make sense (it is in english form and english is not my natural language). Can you help me understand it so I can write an algorithm using this metod and test it against mine? Seems like it will be faster. –  nosklo Dec 19 '09 at 18:03
    
I think I got it!! Look at my answer. –  nosklo Dec 19 '09 at 18:43
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#!/usr/bin/env python
# -*- coding: utf-8 -*-
# Copyright © 2009 Clóvis Fabrício Costa
# Licensed under GPL version 3.0 or higher

def posneg_calcsums(subset):
    sums = {}
    for group in chain.from_iterable(combinations(subset, n+1) 
                                     for n in xrange(len(subset))):
        sums[sum(group)] = group
    return sums

def posneg(items):
    positive = posneg_calcsums([item for item in items if item > 0])
    negative = posneg_calcsums([item for item in items if item < 0])
    for n in sorted(positive, reverse=True):
        if -n in negative:
            return positive[n] + negative[-n]
    else:
        return None

print posneg([-1, 1, -4, 5])
print posneg([6, 44, 1, -7, -6, 19])

It works fine, and is a lot faster than my first approach. Thanks to Alon for the wikipedia link and ivazquez|laptop on #python irc channel for a good hint that led me into the solution.

I think it can be further optimized - I want a way to stop calculating the expensive part once the solution was found. I will keep trying.

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very nice implementation! gland it you've got it worked out ;-) –  Alon Dec 19 '09 at 19:05
    
@Alon: I think I can get further optimizations - any ideas? –  nosklo Dec 19 '09 at 19:17
    
Is it correct that your solution assumes that sum(items) == 0? –  J.F. Sebastian Dec 19 '09 at 20:08
    
@J.F. Sebastian : no. If sum(items) == 0 that would mean that I can remove everything... So it assumes that sum(items) != 0 –  nosklo Dec 19 '09 at 22:47
    
@nosklo: I thought so. Why then sum(positive[n]+negative[-n]) == 0 (where sum(positive[n]) == n and sum(negative[-n]) == -n by definition). –  J.F. Sebastian Dec 22 '09 at 0:35
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Your requirements don't say if the function is allowed to change the list order or not. Here's a possibility:

def remove(items):
    items.sort()
    running = original = sum(items)
    try:
        items.index(original) # we just want the exception
        return [original]
    except ValueError:
        pass
    if abs(items[0]) > items[-1]:
        running -= items.pop(0)
    else:
        running -= items.pop()
    while running != original:
        try:
            running -= items.pop(items.index(original - running))
        except ValueError:
            if running > original:
                running -= items.pop()
            elif running < original:
                running -= items.pop(0)
    return items

This sorts the list (big items will be at the end, smaller ones will be at the beginning) and calculates the sum, and removes an item from the list. It then continues removing items until the new total equals the original total. An alternative version that preserves order can be written as a wrapper:

from copy import copy

def remove_preserve_order(items):
    a = remove(copy(items))
    return [x for x in items if x in a]

Though you should probably rewrite this with collections.deque if you really want to preserve order. If you can guarantee uniqueness in your list, you can get a big win by using a set instead.

We could probably write a better version that traverses the list to find the two numbers closest to the running total each time and remove the closer of the two, but then we'd probably end up with O(N^2) performance. I believe this code's performance will be O(N*log(N)) as it just has to sort the list (I hope Python's list sorting isn't O(N^2)) and then get the sum.

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Interesting code. Order doesn't matter to me. But I have duplicate items that count to the sum, so I don't think I can use sets. Your code works with my original numbers ([1] is returned) and is very fast. but when I tried it with [6, 44, 1, -7, -6, 19] (I would expect it to remove (6, 1, -7) returning [-6, 19, 44], keeping the same sum 57) it fails with IndexError: pop from empty list on the last running -= items.pop(0). Do you know any way to solve this? Thanks for your help. –  nosklo Dec 19 '09 at 15:47
    
It does that because my version tries one order and one order only. You could make a recursive version, but you'd have to split the function into two functions (the part that does setup work, and the part that loops and recurses). I can whip up something really quickly if you like, but you may lose some efficiency. But let's code and not guess at efficiency before we've started, shall we? –  Chris Lutz Dec 20 '09 at 10:41
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I do not program in Python so my apologies for not offering code. But I think I can help with the algorithm:

  1. Find the sum
  2. Add numbers with the lowest value until you get to the same sum
  3. Everything else can be deleted

I hope this helps

share|improve this answer
    
Thanks. Can you give me an example on how to do that? I mean, if I run it with [6, 44, 1, -7, -6, 19], I would expect it to remove (6, 1, -7) leaving [-6, 19, 44], would that happen? –  nosklo Dec 19 '09 at 18:06
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This can be solved using integer programming. You can define a binary variable s_i for each of your list elements x_i and minimize \sum_i s_i, limited by the constraint that \sum_i (x_i*s_i) is equal to the original sum of your list.

Here's an implementation using the lpSolve package in R:

library(lpSolve)
get.subset <- function(lst) {
  res <- lp("min", rep(1, length(lst)), matrix(lst, nrow=1), "=", sum(lst),
            binary.vec=seq_along(lst))
  lst[res$solution > 0.999]
}

Now, we can test it with a few examples:

get.subset(c(1, -1, -4, 5))
# [1] 1
get.subset(c(6, 44, 1, -7, -6, 19))
# [1] 44 -6 19
get.subset(c(1, 2, 3, 4))
# [1] 1 2 3 4
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