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[0];
}
```

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.

`long double`

?`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.