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Each of the integers can be as large as the size of an integer itself (Java int-32 bits), so storing the sum of the integer numbers in an integer variable isn't an option. I'm afraid using Java BigInts might affect the performance badly.

Right now I'm trying divide and conquer while using long to store the sum.

Are there any better solutions?

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1  
How about storing the sum in a floating point number? The average will be a floating point number anyway. –  Sven Marnach Jan 25 '11 at 16:54
    
Do you know the number of integers in advance? –  biziclop Jan 25 '11 at 16:59
1  
@Justin: your answer is also saying to use a bigger data type for the sum - you use "double" when you multiply currentAverage * currentCount, and ignoring floating point inaccuracy the result of that multiplication is exactly the same value that everyone else is storing in a long or BigInteger running total. You just do a lot of unnecessary division along the way. –  Steve Jessop Jan 25 '11 at 17:11
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@Justin: Avoiding overflow doesn't require changing the algorithm, just the datatype. Assuming that double is the correct datatype to use for the sum, your answer does extra work (perhaps introducing extra inaccuracy), that's completely unrelated to avoiding overflow. Using a running average doesn't help avoid overflow in any way. –  Steve Jessop Jan 25 '11 at 17:15
1  
Floating point won't be slower. For a large number of integers, this will be limited by memory bandwidth anyway. –  Sven Marnach Jan 25 '11 at 17:22

8 Answers 8

up vote 6 down vote accepted

You can use long (64-bit) to hold the sum. If you overrun that, BigInteger is the way to go.

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Yes, I was editing my question and meanwhile your answer came up. :) Actually I was wondering that can the algorithm be somehow optimized instead of just finding a way to store bigger sum. –  Atul Goyal Jan 25 '11 at 17:00
2  
Why are you assuming that sum followed by divide isn't the most optimal solution? Storing the intermediary result is going to be nothing even if you are dealing with gazillion integers. The sum just doesn't grow that fast. Adding and division are pretty basic operations and perform very fast. –  Konstantin Komissarchik Jan 25 '11 at 17:13
    
Using long is the way to go, unless long is not long enough. With more than 2**32 numbers it could overflow. In such a case I'd recommend BigInteger. Using double could be faster in theory, but with so many numbers you most probably need to fetch it from the disk, which is way slower than any such computation. Don't care about the speed, it's surely useless optimization. –  maaartinus Jan 25 '11 at 17:15
    
@maaartinus 232 integers is over 16GB of space. Can't belive that Asker need to calculate average of so many numbers. Also summing 232 BigInts will take forever :). –  UmmaGumma Jan 25 '11 at 17:23
    
I know... but 16 GB is a tiny fraction of my HD and your "forever" takes less than 4 minutes. Still, it's much more than adding 2**32 longs. –  maaartinus Jan 25 '11 at 17:51

BigInt is pretty fast. As I always say, do it right first, profile and optimize later.

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+1: ameeeeeeeen –  Rekin Jan 25 '11 at 16:56
    
"Do it right first" - that includes using the proper algorithm for the job. See my answer. stackoverflow.com/questions/4796433/… –  jjnguy Jan 25 '11 at 17:03
    
Pretty fast means order of magnitude slower than int. However, the memory latency probably dominates the computation time, anyway. –  maaartinus Jan 25 '11 at 17:04
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@Justin: for me "do it right" means give the correct answer –  Andrew White Jan 25 '11 at 17:06
    
@Andrew, I'll give you that. But, there is a specific algorithm suited perfectly for this purpose. I'd say using that is the right way. –  jjnguy Jan 25 '11 at 17:08

How about long datatype? It should be pretty fast even on 32-bit machines.

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3  
long will be big enough for around 4 billion worst-case ints. It's also very fast. –  pmdj Jan 25 '11 at 16:57

You can use floats and then convert the result back into a integer. That might not be optimal but should be fast enough (and straight forward)

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That may also be incorrect in some cases, no (say, as an example, when suming up Integer.Max_VALUE-2 with Integer.Max_VALUE-3) ? –  Riduidel Jan 25 '11 at 16:59
    
yes indeed, but I'm not sure you need a such precision for an average. Anyway the result is not a integer either but MAX_VALUE-2.5 . –  mb14 Jan 25 '11 at 17:02
    
Using float is pure nonsense given the existence of long and double. This way you get a wrong result even for averaging a single number, as e.g. (int) (float) x != x for x=Integer.MAX_VALUE-1. –  maaartinus Jan 25 '11 at 17:11
    
ok. I m not a java expert so when I say floats I mean any floating type, and so double if needed ;-) –  mb14 Jan 25 '11 at 17:22

If you know the number of ints you'll have to average in advance, you can do the division one-by-one

int [] a;
int average;
int remainder;
int alen = a.length;

for( int i = 0; i < alen; i++ ) {
  int q = a[i] / alen;  //calculate the quotient and the remainder for the current element
  int r = a[i] % alen;
  average += q; // add up the averages and the remainders
  remainder += r;
  if( remainder >= alen ) { //roll the average over if needed 
    remainder -= alen;
    average++;
  }
}

Of course in practice it doesn't matter because you can't have more than 231 elements in an array, which means you could store the sum in a long.

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Unless you're calculating the average of billions of numbers, using BigInteger shouldn't have much of an effect on performance. You should try coding it with BigInteger and then decide if it's fast enough.

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Use floating point with Kahan's summation.

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not for the mean. The error term of the sum is in sqrt n, so the error term of the mean is in 1/sqrt n. –  oao May 22 '13 at 22:12
    
@oao: the error term of the Kahan sum is bounded, independent of n. –  ybungalobill May 23 '13 at 15:21
    
The issue isn't that Kahan's summation doesn't work, but that it is more costly and not really more accurate in this case. This is because we average the sum. The order of magnitude of the information can be saved with Kahan's sum is epsilon*sqrt(n), with epsilon the last digit of the biggest term of the sum. Because we mean, this become epsilon/sqrt(n). Epsilon and 1/sqrt(n) are small, so their product is very small. Unless you need really accurate results (but in this case you will not use floating point) the difference will generally be too small for being stored in the resulting float. –  oao May 23 '13 at 16:50

You can store above 2billions of ints in a long. What's the problem? Well, if you need even more ints. Do a simple class holding multiple longs (and long[] will do), and add on top of the 1st. Each 2billions of adds, get a fresh new long.

In the end (avg) sum the longs in a BigInteger and divide. The code has close to no overhead, one extra counter and one extra check (that's branch predicted).

[hopefully I didn't make some stupid off by 1 ;) ]

package t1;

import java.math.BigInteger;
import java.util.Arrays;

public class Avg {
    long sum;
    long[] totals = new long[0];

    int counter;

    public void add(int v){
        if (counter++==Integer.MAX_VALUE){
            counter = 0;
            int len =totals.length;
            totals = Arrays.copyOf(totals, len+1);
            totals[len]=sum;
            sum = 0;
        }
        sum+=v;         
    }

    public int avg(){
        long count = this.counter;
        count+=totals.length*(long)Integer.MAX_VALUE;

        BigInteger sum = BigInteger.valueOf(this.sum);
        for (long subSum : totals)
            sum=sum.add(BigInteger.valueOf(subSum));

        return sum.divide(BigInteger.valueOf(count)).intValue();//tweak if you need be
    }
}
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