# CodeSprint 2's Complement challenge running too slowly

On the original InterviewStreet Codesprint, there's a question about counting the number of ones in the two's complement representations of the numbers between a and b inclusive. I was able to pass all of the test cases for accuracy using iteration, but I was only able to pass two in the correct amount of time. There was hint that mentioned finding a recurrence relation, so I switched to recursion, but it ended up taking the same amount of time. So can anyone find a faster way to do this than the code I've provided? The first number of the input file is the test cases in the file. I've provided a sample input file after the code.

import java.util.Scanner;

public class Solution {

public static void main(String[] args) {

Scanner scanner = new Scanner(System.in);
int numCases = scanner.nextInt();
for (int i = 0; i < numCases; i++) {
int a = scanner.nextInt();
int b = scanner.nextInt();
System.out.println(count(a, b));
}
}

/**
* Returns the number of ones between a and b inclusive
*/
public static int count(int a, int b) {
int count = 0;
for (int i = a; i <= b; i++) {
if (i < 0)
count += (32 - countOnes((-i) - 1, 0));
else
count += countOnes(i, 0);
}

return count;
}

/**
* Returns the number of ones in a
*/
public static int countOnes(int a, int count) {
if (a == 0)
return count;
if (a % 2 == 0)
return countOnes(a / 2, count);
else
return countOnes((a - 1) / 2, count + 1);
}
}


Input:

3
-2 0
-3 4
-1 4

Output:
63
99
37

• Did you try this trick? Commented Mar 12, 2012 at 0:46

A first step is to replace

public static int countOnes(int a, int count) {
if (a == 0)
return count;
if (a % 2 == 0)
return countOnes(a / 2, count);
else
return countOnes((a - 1) / 2, count + 1);
}


which recurs to a depth of log2 a, with a faster implementation, for example the famous bit-twiddling

public static int popCount(int n) {
// count the set bits in each bit-pair
// 11 -> 10, 10 -> 01, 0* -> 0*
n -= (n >>> 1) & 0x55555555;
// count bits in each nibble
n = ((n >>> 2) & 0x33333333) + (n & 0x33333333);
// count bits in each byte
n = ((n >> 4) & 0x0F0F0F0F) + (n & 0x0F0F0F0F);
// accumulate the counts in the highest byte and shift
return (0x01010101 * n) >> 24;
// Java guarantees wrap-around, so we can use int here,
// in C, one would need to use unsigned or a 64-bit type
// to avoid undefined behaviour
}


which uses four shifts, five bitwise ands, one subtraction, two additions and one multiplication for a total of thirteen very cheap instructions.

But unless the ranges are very small, one can do much better than counting the bits of each individual number.

Let us consider non-negative numbers first. The numbers from 0 to 2k-1 all have up to k bits set. Every bit is set in exactly half of these, so the total number of bits is k*2^(k-1). Now let 2^k <= a < 2^(k+1). The total number of bits in the numbers 0 <= n <= a is the sum of the bits in the numbers 0 <= n < 2^k and the bits in the numbers 2^k <= n <= a. The first count is, as we saw above, k*2^(k-1). In the second part, we have a - 2^k + 1 numbers, each of them has the 2k-bit set, and ignoring the leading bit, the bits of these are the same as in the numbers 0 <= n <= (a - 2^k), so

totalBits(a) = k*2^(k-1) + (a - 2^k + 1) + totalBits(a - 2^k)


Now for the negative numbers. In twos complement, -(n+1) = ~n, so the numbers -a <= n <= -1 are the complements of the numbers 0 <= m <= (a-1) and the total number of set bits in the numbers -a <= n <= -1 is a*32 - totalBits(a-1).

For the total number of bits in a range a <= n <= b, we have to add or subtract, depending on whether both ends of the range have opposite or the same sign.

// if n >= 0, return the total of set bits for
// the numbers 0 <= k <= n
// if n < 0, return the total of set bits for
// the numbers n <= k <= -1
public static long totalBits(int n){
if (n < 0) {
long a = -(long)n;
return (a*32 - totalBits((int)(a-1)));
}
if (n < 3) return n;
int lg = 0, mask = n;
// find the highest set bit in n and its position
++lg;
}
// total bit count for 0 <= k < 2^lg
long total = 1L << lg-1;
total *= lg;
// add number of 2^lg bits
// add number of other bits for 2^lg <= k <= n
}

// return total set bits for the numbers a <= n <= b
public static long totalBits(int a, int b) {
if (b < a) throw new IllegalArgumentException("Invalid range");
if (a == b) return popCount(a);