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I am aware of a similar question, but I want to ask for people opinion on my algorithm to sum floating point numbers as accurately as possible with practical costs.

Here is my first solution:

put all numbers into a min-absolute-heap. // EDIT as told by comments below
pop the 2 smallest ones.
add them.
put the result back into the heap.
continue until there is only 1 number in the heap.

This one would take O(n*logn) instead of normal O(n). Is that really worth it?

The second solution comes from the characteristic of the data I'm working on. It is a huge list of positive numbers with similar order of magnitude.

a[size]; // contains numbers, start at index 0
for(step = 1; step < size; step<<=1)
    for(i = step-1; i+step<size; i+=2*step)
        a[i+step] += a[i];
    if(i < size-1)
        a[size-1] += a[i];

The basic idea is to do sum in a 'binary tree' fashion.

Note: it's a pseudo C code. step<<=1 means multiply step by 2. This one would take O(n). I feel like there might be a better approach. Can you recommend/criticize?

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3  
It seems that you are implicitly assuming the numbers to sum are positive. If they could be of different signs, a strategy would be something like “adding the number of smallest magnitude and of sign opposite to the current count, if possible”. –  Pascal Cuoq Nov 16 '12 at 13:37
1  
The elements will be put into the heap in increasing order, so you can use two queues instead. This produces O(n) if the numbers are pre-sorted –  Jan Dvorak Nov 16 '12 at 13:48
3  
When choosing algorithms consider the following set of numbers: {DBL_MAX, 1, -DBL_MAX}. If all your algorithm does is decide what order to sum the numbers in, then it gets the incorrect answer 0 unless it adds the two large numbers first, in which case it gets the correct answer 1. So, your min-heap fails for that particular input, as for that matter do most heuristics for this job. Kahan gets it right, I think. –  Steve Jessop Nov 16 '12 at 14:03
1  
@AShelly My second algorithm is not O(N lg N) but O(N) because in the first 'step loop' it adds N/2 times, the second time it adds N/4 times, the third time it adds N/8 times, and so on –  Billiska Nov 16 '12 at 14:22
1  
@AShelly: n + n/2 + n/4 + n/8 + ... = 2*n –  hammar Nov 16 '12 at 14:26

4 Answers 4

up vote 18 down vote accepted

Kahan's summation algorithm is significantly more precise than straightforward summation, and it runs in O(n) (somewhere between 1-4 times slower than straightforward summation depending how fast floating-point is compared to data access. Definitely less than 4 times slower on desktop hardware, and without any shuffling around of data).


Alternately, if you are using the usual x86 hardware, and if your compiler allows access to the 80-bit long double type, simply use the straightforward summation algorithm with the accumulator of type long double. Only convert the result to double at the very end.


If you really need a lot of precision, you can combine the above two solutions by using long double for variables c, y, t, sum in Kahan's summation algorithm.

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Thank you for recommending Kahan's algorithm. Let me read it a bit and I'll come back to accept the answer. –  Billiska Nov 16 '12 at 13:56

If you are concerned about reducing the numerical error in your summation then you may be interested in Kahan's algorithm.

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Thank you for recommending Kahan's algorithm. I'm new to stackoverflow, what do you do if there's 2 same answer? –  Billiska Nov 16 '12 at 13:58
5  
Study the same thing twice ? –  High Performance Mark Nov 16 '12 at 14:00
1  
@Billiska generally the most complete/helpful is accepted but you can still upvote other helpful anwers –  ratchet freak Nov 16 '12 at 14:54

The elements will be put into the heap in increasing order, so you can use two queues instead. This produces O(n) if the numbers are pre-sorted.

This pseudocode produces the same results as your algorithm and runs in O(n) if the input is pre-sorted and the sorting algorithm detects that:

Queue<float> leaves = sort(arguments[0]).toQueue();
Queue<float> nodes = new Queue();

popAny = #(){
       if(leaves.length == 0) return nodes.pop();
  else if(nodes.length == 0) return leaves.pop();
  else if(leaves.top() > nodes.top()) return nodes.pop();
  else return leaves.pop();
}

while(leaves.length>0 || nodes.length>1) nodes.push(popAny()+popAny());

return nodes.pop();
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2  
I implemented both the Kahan summation algorithm and sort-then-sum using float (32-bit IEEE 754) and compared them to the result obtained using double (64-bit) to sum 1024 numbers selected randomly and uniformly from [0, 1). I ran a few dozen trials. In some, Kahan and sort returned the same value. In most, Kahan had less error. In none did sorting produce less error. –  Eric Postpischil Nov 16 '12 at 15:00
2  
@EricPostpischil I was replying to the asker's comment I'm still interested in how using 2 queues can make it O(n) in that case. Still can't imagine it. –  Jan Dvorak Nov 16 '12 at 15:41
    
@JanDvorak Closer inspection. The maximum number of elements in node queue can reach N/2 with this input = {k,k+1,k+2,...,2*k} where k is positive. Hence, your algorithm is O(N/2 lg N/2) which is the same as O(N lg N). –  Billiska Nov 16 '12 at 16:33
1  
@Billiska Inserting an element into a queue is a constant time operation. Removing an element from a queue is a constant time operation. The while loop will run exactly N-1 times. The while loop by itself is linear in the number of elements. The only non-linear step is the sorting step. –  Jan Dvorak Nov 16 '12 at 17:08
    
Elaborating about the queue: If you don't care about the space, a queue is {data=[], start=0, end=0, push=#(x){data[end++]=x}, pop=#(){if(start==end) die(); return data[start++]}} –  Jan Dvorak Nov 16 '12 at 17:15

My guess is that your binary decomposition will work almost as well as Kahan summation.

Here is an example to illustrate it:

#include <stdio.h>
#include <stdlib.h>
#include <algorithm>

void sumpair( float *a, float *b)
{
    volatile float sum = *a + *b;
    volatile float small = sum - std::max(*a,*b);
    volatile float residue = std::min(*a,*b) - small;
    *a = sum;
    *b = residue;
}

void sumpairs( float *a,size_t size, size_t stride)
{
    if (size <= stride*2 ) {
        if( stride<size )
            sumpair(a+i,a+i+stride);
    } else {
        size_t half = 1;
        while(half*2 < size) half*=2;;
        sumpairs( a , half , stride );
        sumpairs( a+half , size-half , stride );
    }
}

void sumpairwise( float *a,size_t size )
{
    for(size_t stride=1;stride<size;stride*=2)
        sumpairs(a,size,stride);
}

int main()
{
    float data[10000000];
    size_t size= sizeof data/sizeof data[0];
    for(size_t i=0;i<size;i++) data[i]=((1<<30)*-1.0+random())/(1.0+random());

    float naive=0;
    for(size_t i=0;i<size;i++) naive+=data[i];
    printf("naive      sum=%.8g\n",naive);

    double dprec=0;
    for(size_t i=0;i<size;i++) dprec+=data[i];
    printf("dble prec  sum=%.8g\n",(float)dprec);

    sumpairwise( data , size );
    printf("1st approx sum=%.8g\n",data[0]);
    sumpairwise( data+1 , size-1);
    sumpairwise( data , 2 );
    printf("2nd approx sum=%.8g\n",data[0]);
    sumpairwise( data+2 , size-2);
    sumpairwise( data+1 , 2 );
    sumpairwise( data , 2 );
    printf("3rd approx sum=%.8g\n",data[0]);
    return 0;
}

I declared my operands volatile and compiled with -ffloat-store to avoid extra precision on x86 architecture

g++  -ffloat-store  -Wl,-stack_size,0x20000000 test_sum.c

and get: (0.03125 is 1ULP)

naive      sum=-373226.25
dble prec  sum=-373223.03
1st approx sum=-373223
2nd approx sum=-373223.06
3rd approx sum=-373223.06

This deserve a little explanation.

  • I first display naive summation
  • Then double precision summation (Kahan is roughly equivalent to that)
  • The 1st approximation is the same as your binary decomposition. Except that I store the sum in data[0] and that I care of storing residues. This way, the exact sum of data before and after summation is unchanged
  • This enables me to approximate the error by summing the residues at 2nd iteration in order to correct the 1st iteration (equivalent to applying Kahan on binary summation)
  • By iterating further I can further refine the result and we see a convergence
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