# Does the sum of numbers depend on the sequence in which they are added?

It was my intuition so far that sum for a set of numbers is independent of the order in which they are added. In the following, the set of random numbers is determined by the seed=0, but the sequence is determined by the order of execution in threads.

I would like to use the sum of a large number doubles from a multi-threaded computation as a checksum. Is there a way to find a rounding scheme for the sum that is maximally sensitive to the constituent numbers in the sum, but insensitive to the particular random sequence of additions?

``````import java.io.IOException;
import java.util.ArrayList;
import java.util.Random;
import java.util.concurrent.Callable;
import java.util.concurrent.ExecutionException;
import java.util.concurrent.ExecutorService;
import java.util.concurrent.Executors;
import java.util.concurrent.Future;

public class Test implements Callable<Double> {

public static class Sum {

double sum = 0;

public synchronized void add(double val) {
sum += val;
}

public double getSum() {
return sum;
}
};
Sum sum;

public Test(Sum sum) {
this.sum = sum;
}

@Override
public Double call() {
Random rand = new Random(0);
for (long i = 0; i < 1000000L; i++) {
}
return 0D;
}

static double mean() {
Sum sum = new Sum();
int cores = Runtime.getRuntime().availableProcessors();
ArrayList<Future<Double>> results = new ArrayList<>();
double x = 0;
for (int i = 0; i < cores; i++) {
Test test = new Test(sum);
}

for (Future<Double> entry : results) {
try {
x += entry.get();
} catch (InterruptedException ex) {
} catch (ExecutionException ex) {
throw new RuntimeException("Excecution exception:");
}
}

pool.shutdown();

return sum.getSum();
}

public static void main(String[] args) throws IOException {
for (int i = 0; i < 10; i++) {
System.out.format("Avg:%22.20f\n", mean());
}
}
}
``````
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I would not recommend adding `double`s since it can result in loss of precision. Instead, use `long` or `BigDecimal`. And no, remember a basic rule when adding numbers: the order of the factors does not affect the product. –  Luiggi Mendoza May 21 at 1:34
Try the example ... order does seem to effect the sum. –  fodon May 21 at 1:35
The synchronized method should take care of threading issues. So this should even happen with just one "core". I can imagine that adding doubles works differently depending on order because of differing effects of rounding errors. –  Thilo May 21 at 1:37
try it out ... doesn't happen with one core. –  fodon May 21 at 1:38
So, is there an operation that will work as a has for a large number of doubles? –  fodon May 21 at 1:45
show 1 more comment

Assuming your data structures are properly synchronised, the order should not affect the final sum, provided that the operations are commutative.

In other words, provided that `a + b` is identical to `b + a`.

That's not always the case with floating point numbers since they are, after all, an approximation of the number you want.

Adding two numbers (`a` and `b` above) is probably commutative but it becomes more complex when the quantity of numbers becomes bigger.

For example, if you add the smallest possible number to a (relatively) large number, the fact that you only have a certain precision means that you'll end up with the larger number, for example:

``````      -20
1 + 10     => 1
``````

So, if you add `10-20` to `1` a lot of times (1020 to be exact), you'll still end up with `1`:

``````      -20    -20    -20        -20    -20    -20
1 + 10   + 10   + 10   ... + 10   + 10   + 10      => 1
\__________________________________________/
20
10   of these
``````

However, if you first add together all those `10-20` values, you'll end up with `1` (a), then adding `1` to that will give you `2`:

``````  -20    -20    -20        -20    -20    -20
10   + 10   + 10   ... + 10   + 10   + 10    + 1   => 2
\__________________________________________/
20
10   of these
``````

(a) This isn't necessarily quite true since the accumulated amount will stop increasing as soon as it becomes large enough relative to `10-20` for that value to have zero effect on it.

However, it won't be at the point where the accumulated amount is zero so you should see a difference in the final sums.

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If you're adding doubles of wildly differing magnitudes, you should sort them first by absolute value and start with the smallest.

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The synchronized method should take care of threading issues. So this should even happen with just one "core".

I can imagine that adding doubles works differently depending on order because of differing effects of rounding errors.

For example, BIG + 1 is probably the same as BIG + 2, which violates basic arithmetic sanity. That's floating points for you.

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