# Minimize floating point error when adding multiple floating point variables

In my c++ app i have a vector of doubles in the range (0,1) and i have to calculate its total as accurately as possible. It feels like this issue should have been addressed before, but i cant find anything.

Obviously iterating through each item on the vector and doing sum+=vect[i] accumulates a significant error if the vector size is large and there are items which are significantly smaller then the others.

My current solution is this function:

``````double sumDoubles(vector<double> arg)// pass by copy
{
sort(arg.rbegin(),arg.rend());  // sort in reverse order
for(int i=1;i<=arg.size();i*=2)
for(int j=0;j<arg.size()-i;j+=(2*i))
arg[j]+=arg[j+i];
return arg;
}
``````

Basically it sorts the input in ascending order and calculates pairwise sums:

a+b+c+d+e+f+g+h=((a+b)+(c+d))+((e+f)+(g+h))

Like constructing a binary tree, but doing it in place. Sorting should ensure that at each step the two summands are of comparable magnitude.

The code above does perform better than a single loop with accumulative sum. However i am curious if it is possible to increase precision further while not degrading performance too much.

• u tried `long double`?
– Kal
Oct 2, 2013 at 4:35
• that's only a way to postpone the problem. I will still run into issues if the vector size is large or there are outliers among the elements. Oct 2, 2013 at 4:40
• @Alex_Waterloo Relying on a more precise `long double`, if available, is a fine solution that can be used alone or in conjunction with algorithmic solutions such as Kahan summation. No constant-space solution completely avoids issues in presence of outliers. Oct 2, 2013 at 7:11
• @PascalCuoq: Outliers aren't a problem with sorting (if done properly). Either they sort toward the front or they sort toward the back. In either case, their summation is with similar values, if present, or else a tiny value is correctly ignored and a huge value correctly dominates the result. Oct 2, 2013 at 8:02

One of the standard ways of approaching this issue is the Kahan summation algorithm. This algorithm reduces your worst-case error to being dependent upon your floating point precision rather than growing proportional to the length of your vector (and does it in O(n) time, albeit with more calculations per iteration).

Kahan summation will likely outperform your current `sumDoubles` due to your sorting every call, and will additionally improve pairwise summation's error growth of O(log n) to O(1). This said, if the `sort` is unnecessary, pairwise summation will likely outperform Kahan summation (due to the additional per-iteration math involved) with what may be (for your circumstances) minimal error growth.

• I was not aware of Kahan's algorithm, thanks for the reference!