# Precise sum of floating point numbers

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.
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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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
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
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
@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
@AShelly: `n + n/2 + n/4 + n/8 + ... = 2*n` –  hammar Nov 16 '12 at 14:26

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
Study the same thing twice ? –  High Performance Mark Nov 16 '12 at 14:00
@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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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
@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
@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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