# Javascript, all possible sums of an array members (up to 4)

I am unable to figure out how to write a function that will calculate all possible sums of of the elements of an array, with a max of 4 elements per addition.

Given

``````x = [1, 32, 921, 9213, 97, 23, 97, 81, 965, 82, 965, 823]
``````

I need to go from `(1+32) ~ (965+823)` to `(1+32+921+9213) ~ (965+82+965+823)`, calculating all the possible sums.

The output should be an array like this:

{33: [1, 32], 922: [1, 921], .... 2835: [965, 82, 965, 823]}

filled by all the possible sums.

It's not for homework, and what I was looking for is explained down there by Travis J: it was about permutations. Thanks everybody, I hope this could be useful also to someone else.

• Look up permutations. Dec 19, 2014 at 0:06
• What have you attempted so far? Dec 19, 2014 at 0:06
• @TravisJ—I think you mean combinations. Addition doesn't care about order. ;-)
– RobG
Dec 19, 2014 at 0:09
• Spend some time thinking about how you would do this problem with pencil and paper, working systematically. Dec 19, 2014 at 0:12
• @KyleMuir I did some test with Python (on which I'm most familiar), trying to build a recursive function that increase the list indexes, but I haven't gone so far. Dec 19, 2014 at 0:12

`jsFiddle Demo`

You can use a permutation subset recursive algorithm to find the set of all of the sums and also their combinations.

``````var x = [1, 32, 921, 9213, 97, 23, 97, 81, 965, 82, 965, 823];
var sums = [];
var sets = [];
if( read.length == 4 || (read.length <= 4 && queued.length == 0) ){
if(sums.indexOf(total)==-1){
sums.push(total);
}
}
}else{
}
}
SubSets([],x);
console.log(sums.sort(function(a,b){return a-b;}));
//log sums without sort to have them line up to sets or modify previous structure
console.log(sets);``````

• That doesn't seem to get the right number of combinations (or maybe I'm calculating them incorrectly). The general formula for combinations of k members of a population of n is given by: `n! / (( n - k)! * k!)`. Summing for n = 12 and k = 2 to 4 gives 781, the above gives 426 results. There are 495 combinations where k = 4. Have I missed something (very probably I have)?
– RobG
Dec 19, 2014 at 1:40
• @RobG - I believe your number may be correct for a unique set. However, this set included duplicate numbers. Moreover, since there were additions, it included duplicate totals. I had both of those removed and that is what led to the smaller number. So I think your math is probably accurate for the domain described. Dec 19, 2014 at 5:22
• @TravisJ—if all combinations are summed, then duplicate values removed, there are 418 remaining. If duplicates are removed first (97, 965), then duplicate results also removed, there are 334 remaining. Dups removed using: `arr.sort(function(a, b){return a-b}).filter(function(v, i){return !i || v != arr[i-1]});`.
– RobG
Dec 19, 2014 at 7:48
• The initial idea was to compare results of the additions with the members of a second array, and return the matching sets, if equal. Accomplished, thanks to this code, in a blazing fast way. This means I doesn't care about duplicates. Also, it's usable on a small set of data (up to 10 or so), and I had to apply some filters to reduce the array size, cause the initial array length is 60 ~ 90 members, and turned out it needs too much computing power. Everything worked like a charm and I really have to say thank you. Dec 19, 2014 at 10:41
• @TravisJ—Ah, the difference is that you are summing 1 to 4 terms, I was summing 2 to 4 (since summing single terms didn't make any sense to me).
– RobG
Dec 20, 2014 at 0:24

There is a function to generate combinations of k members of a population of n here: https://gist.github.com/axelpale/3118596.

I won't reproduce the function here. You can combine it with another function to sum the combinations generated from an input array, e.g.

``````// Add combinations of k members of set
function getComboSums(set, k) {
return k_combinations(arr, n).map(function(a){
var sum=0;
a.forEach(function(v){sum += v})
return sum;
});
}
``````

This can be combined with another function to get all combinations from 2 to 4 and concatenate them all together. Note that the total number of combinations in a set of 12 members is 781.

``````// Add all combinations from kStart to kEnd of set
function getComboSumRange(set, kStart, kEnd) {
var result = [];
for (var i=kStart; i <= kEnd; i++) {
result = result.concat(getComboSums(set, i));
}
return result;
}
``````

Then given:

``````var arr = [1, 32, 921, 9213, 97, 23, 97, 81, 965, 82, 965, 823];

console.log(getComboSumRange(arr, 2, 4)) // length is 781
``````

The length of 781 agrees with the calculated number of terms based on the formula for finding combinations of k in n:

``````n! / (k!(n - k)!)
``````

and summing for k = 2 -> 4.

The result looks like:

``````[33, 922, 9214, 98, 24, 98 ...  2834, 1951, 2835];
``````

``````arr[0] + arr[1], arr[0] + arr[2]], ...
``````... arr[7] + arr[9] + arr[10] + arr[11], arr[8] + arr[9] + arr[10] + arr[11]