# Java Counting one bits in number range

I have a problem counting one bits in a large number ranges.

So I have to count one bits in a eq number range from 1 to 1000 which is 4938.

``````public static long countRangeOneBits(long n){
long t = 0;
for (long i = 1; i <= n; i++) {
long x = i;
while (x > 0) {
t += x%2;
x /= 2;
}
}
return t;
}
``````

Ok this works fine, but I need to calculate range 1..10^16. First of all java won't count that big numbers, at least with long data type. Do I have any other options or do you guys have any tips on how I should approach this problem.

``````| From 1 To        | Total             |
|                1 |                1  |
|               10 |               14  |
|              100 |              319  |
|             1000 |             4938  |
|            10000 |            64613  |
|           100000 |           815030  |
|          1000000 |          9884999  |
|         10000000 |        114434632  |
|        100000000 |       1314447116  |
|       1000000000 |      14846928141  |
|  100000000000000 | 2306412649693200  |
| 1000000000000000 |24784747400675300  |
``````
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Is this Project Euler? –  Simeon Visser Dec 31 '13 at 16:44
I am fairly confident that there's a pattern there that would allow you to "count" bits without enumerating every possibility. –  Hot Licks Dec 31 '13 at 16:45
No, but school extra programming assignment. I just need some help in ways to approach this problem. –  Jompper Dec 31 '13 at 16:45
Maybe you should post this to the Math board... But if you do want to do this the bruteforce way: Use `BigInteger`, you can represent any whole number with that (As long as you have enough memory...). –  Sibbo Dec 31 '13 at 16:45
–  lwi Dec 31 '13 at 16:47

I guess you need to play with 2^n. As total number of 1 bits from 0 to (2^n - 1) = n * 2^(n-1).

And in programs this is what you want

``````private static long getBits(long l){
if(l == 0){
return 0;
}else if(l == 1){
return 1;
}
boolean isPowerOf2Minus1 = (l & (l+1)) == 0;
long maxBitNum = Long.highestOneBit(isPowerOf2Minus1 ? l+1 : l);
int maxBit = Long.numberOfTrailingZeros(maxBitNum);
if((l & (l+1)) == 0){
return maxBit * (maxBitNum >> 1);
}
long diff = l - maxBitNum;
return diff + 1 + getBits(maxBitNum - 1) + getBits(diff);
}
``````

With below results

``````                   1 :                    1
10 :                   17
100 :                  319
1000 :                 4938
10000 :                64613
100000 :               815030
1000000 :              9884999
10000000 :            114434632
100000000 :           1314447116
1000000000 :          14846928141
10000000000 :         164293127179
100000000000 :        1809725656079
1000000000000 :       19809942118413
10000000000000 :      214309466746894
100000000000000 :     2306412649693201
1000000000000000 :    24784747400675348
10000000000000000 :   264286863212871700
100000000000000000 :  2804216299269586964
``````
-

Since you need to do it with so many numbers probably a lookup table would be the easiest way to go:

``````final int TABLE_SIZE = 65536;
int[] table = new int[TABLE_SIZE];

for (int i = 0; i < TABLE_SIZE; ++i)
table = hammingWeight(i);
``````

Then you could just split your number in 16 bits chunks and sum all their weights together to compute the result, since the hamming weight can be computed as the sum of the weights of two parts of the starting number, eg:

``````long number = 12445235;
int weight = table[number & 0xFFFF] + table[(number >>> 16) & 0xFFFF];
``````

Of course you'll have to find a way to specify numbers that are longer than a `long` data type but it shouldn't be too difficult, just care about sign and shifts.

-

You can use

``````// this turns into a single machine instruction
int numOfBitSet = Long.bitCount(n);
``````

This will count the number of bits set for values up to 9 * 10^18.

-
+1 Generally useful answer. But I suspect that the instructor wouldn't accept it. :-) –  Willie Wheeler Dec 31 '13 at 17:48

For powers of 2

countRangeOneBits(n) = 2 * countRangeOneBits(n / 2) + (n / 2)

Explanation: if you have a table of numbers as bits, the second half just has one bit to the right (n/2 extra bits).

So 10^16 should be doable with a long.

More details I cannot with good conscience deliver.

-
For the range 0..2n-1, for some n, each number can be expressed with n bits, and over that entire range, for exactly half of the numbers a given bit will be 0, and it will be 1 for the other half. For example, `0..7` gives you 000, 001, 010, 011, 100, 101, 110, 111 and each bit is 0 for four of those numbers and 1 for four of those numbers. Ergo, the sum of the hamming weights for all eight numbers is 2n*n/2, which here is 8*3/2 or 12.