It's worth noting that if each bit would have some amount of leading zeros prepended then adding all the input values would yield the bitcount of each, we would just have to mask it out or something of the sort to retrieve it. Then the bit counting itself becomes trivial, but it raises other questions such as:

- How do I transform my input into the format on which I would like to operate?
- How do I retrieve my bit counts once the operation is performed?
- Should I be storing my input in the transformed format in the first place?
- What is the maximum bit count?

In the below code I decided to support a maximum bit count of 15, but it could easily be extended to 255. I decided to only consider well-formed input to the function (no empty or too-large input arrays). And that even though the assembly generated to access the bit fields by the caller will likely involve some shifts or masks, that that is okay.

This implementation uses a look-up table for the expansion, and though I didn't profile it, I think it should be quite a bit faster than the looping bit-by-bit solution.

```
struct BitCount
{
unsigned char bit0 : 4;
unsigned char bit1 : 4;
unsigned char bit2 : 4;
unsigned char bit3 : 4;
unsigned char bit4 : 4;
unsigned char bit5 : 4;
unsigned char bit6 : 4;
unsigned char bit7 : 4;
unsigned char bit8 : 4;
unsigned char bit9 : 4;
unsigned char bitA : 4;
unsigned char bitB : 4;
unsigned char bitC : 4;
unsigned char bitD : 4;
unsigned char bitE : 4;
unsigned char bitF : 4;
};
void CountBits(const short *invals, unsigned incount, BitCount &bitcount)
{
assert(incount && incount <= 0xF && sizeof bitcount == 8);
static const unsigned expand[256] = {
// _0 _1 _2 _3 _4 _5 _6 _7 _8 _9 _A _B _C _D _E _F
0x00000000, 0x00000001, 0x00000010, 0x00000011, 0x00000100, 0x00000101, 0x00000110, 0x00000111, 0x00001000, 0x00001001, 0x00001010, 0x00001011, 0x00001100, 0x00001101, 0x00001110, 0x00001111, // 0_
0x00010000, 0x00010001, 0x00010010, 0x00010011, 0x00010100, 0x00010101, 0x00010110, 0x00010111, 0x00011000, 0x00011001, 0x00011010, 0x00011011, 0x00011100, 0x00011101, 0x00011110, 0x00011111, // 1_
0x00100000, 0x00100001, 0x00100010, 0x00100011, 0x00100100, 0x00100101, 0x00100110, 0x00100111, 0x00101000, 0x00101001, 0x00101010, 0x00101011, 0x00101100, 0x00101101, 0x00101110, 0x00101111, // 2_
0x00110000, 0x00110001, 0x00110010, 0x00110011, 0x00110100, 0x00110101, 0x00110110, 0x00110111, 0x00111000, 0x00111001, 0x00111010, 0x00111011, 0x00111100, 0x00111101, 0x00111110, 0x00111111, // 3_
0x01000000, 0x01000001, 0x01000010, 0x01000011, 0x01000100, 0x01000101, 0x01000110, 0x01000111, 0x01001000, 0x01001001, 0x01001010, 0x01001011, 0x01001100, 0x01001101, 0x01001110, 0x01001111, // 4_
0x01010000, 0x01010001, 0x01010010, 0x01010011, 0x01010100, 0x01010101, 0x01010110, 0x01010111, 0x01011000, 0x01011001, 0x01011010, 0x01011011, 0x01011100, 0x01011101, 0x01011110, 0x01011111, // 5_
0x01100000, 0x01100001, 0x01100010, 0x01100011, 0x01100100, 0x01100101, 0x01100110, 0x01100111, 0x01101000, 0x01101001, 0x01101010, 0x01101011, 0x01101100, 0x01101101, 0x01101110, 0x01101111, // 6_
0x01110000, 0x01110001, 0x01110010, 0x01110011, 0x01110100, 0x01110101, 0x01110110, 0x01110111, 0x01111000, 0x01111001, 0x01111010, 0x01111011, 0x01111100, 0x01111101, 0x01111110, 0x01111111, // 7_
0x10000000, 0x10000001, 0x10000010, 0x10000011, 0x10000100, 0x10000101, 0x10000110, 0x10000111, 0x10001000, 0x10001001, 0x10001010, 0x10001011, 0x10001100, 0x10001101, 0x10001110, 0x10001111, // 8_
0x10010000, 0x10010001, 0x10010010, 0x10010011, 0x10010100, 0x10010101, 0x10010110, 0x10010111, 0x10011000, 0x10011001, 0x10011010, 0x10011011, 0x10011100, 0x10011101, 0x10011110, 0x10011111, // 9_
0x10100000, 0x10100001, 0x10100010, 0x10100011, 0x10100100, 0x10100101, 0x10100110, 0x10100111, 0x10101000, 0x10101001, 0x10101010, 0x10101011, 0x10101100, 0x10101101, 0x10101110, 0x10101111, // A_
0x10110000, 0x10110001, 0x10110010, 0x10110011, 0x10110100, 0x10110101, 0x10110110, 0x10110111, 0x10111000, 0x10111001, 0x10111010, 0x10111011, 0x10111100, 0x10111101, 0x10111110, 0x10111111, // B_
0x11000000, 0x11000001, 0x11000010, 0x11000011, 0x11000100, 0x11000101, 0x11000110, 0x11000111, 0x11001000, 0x11001001, 0x11001010, 0x11001011, 0x11001100, 0x11001101, 0x11001110, 0x11001111, // C_
0x11010000, 0x11010001, 0x11010010, 0x11010011, 0x11010100, 0x11010101, 0x11010110, 0x11010111, 0x11011000, 0x11011001, 0x11011010, 0x11011011, 0x11011100, 0x11011101, 0x11011110, 0x11011111, // D_
0x11100000, 0x11100001, 0x11100010, 0x11100011, 0x11100100, 0x11100101, 0x11100110, 0x11100111, 0x11101000, 0x11101001, 0x11101010, 0x11101011, 0x11101100, 0x11101101, 0x11101110, 0x11101111, // E_
0x11110000, 0x11110001, 0x11110010, 0x11110011, 0x11110100, 0x11110101, 0x11110110, 0x11110111, 0x11111000, 0x11111001, 0x11111010, 0x11111011, 0x11111100, 0x11111101, 0x11111110, 0x11111111 }; // F_
unsigned *const countLo = (unsigned*)&bitcount;
unsigned *const countHi = (unsigned*)&bitcount + 1;
*countLo = expand[*invals & 0xFF];
*countHi = expand[*invals++ >> 8];
switch (incount)
{
case 0xF:
*countLo += expand[*invals & 0xFF];
*countHi += expand[*invals++ >> 8];
case 0xE:
*countLo += expand[*invals & 0xFF];
*countHi += expand[*invals++ >> 8];
case 0xD:
*countLo += expand[*invals & 0xFF];
*countHi += expand[*invals++ >> 8];
case 0xC:
*countLo += expand[*invals & 0xFF];
*countHi += expand[*invals++ >> 8];
case 0xB:
*countLo += expand[*invals & 0xFF];
*countHi += expand[*invals++ >> 8];
case 0xA:
*countLo += expand[*invals & 0xFF];
*countHi += expand[*invals++ >> 8];
case 0x9:
*countLo += expand[*invals & 0xFF];
*countHi += expand[*invals++ >> 8];
case 0x8:
*countLo += expand[*invals & 0xFF];
*countHi += expand[*invals++ >> 8];
case 0x7:
*countLo += expand[*invals & 0xFF];
*countHi += expand[*invals++ >> 8];
case 0x6:
*countLo += expand[*invals & 0xFF];
*countHi += expand[*invals++ >> 8];
case 0x5:
*countLo += expand[*invals & 0xFF];
*countHi += expand[*invals++ >> 8];
case 0x4:
*countLo += expand[*invals & 0xFF];
*countHi += expand[*invals++ >> 8];
case 0x3:
*countLo += expand[*invals & 0xFF];
*countHi += expand[*invals++ >> 8];
case 0x2:
*countLo += expand[*invals & 0xFF];
*countHi += expand[*invals >> 8];
};
}
```

**EDIT** You can skip the above table look-up on a 64-bit system if you widen the bit count values from 4 bits to 8 bits by taking advantage of the properties of multiplication.

This is the property we are interested in (a, b, c, and d are 0 or 1, and n is a binary number):

n * (a * 2^3 + b * 2^2 + c *2^1 + d * 2^0) <=> ((a * n) << 3) + ((b * n) << 2) + ((c * n) << 1) + ((d * n) << 0)

So if we cast a byte to a 64-bit int and carefully pick a multiplier we can end up with a 0 or a 1 in the first bit of every byte of the product. Here is such a multiplier:

00000000 00000010 00000100 00001000 00010000 00100000 01000000 10000001

or 0x002040810204081

So, we can expand a byte to 64 bits like this:

```
unsigned char b = ...
// this operation can be used in substitution of the below look-up table
// (if the code is written for 8-bit wide count, instead of 4-bit wide counts)
unsigned __int64 valx = ((unsigned __int64)b * 0x002040810204081) & 0x0101010101010101;
```

We can then extract bit counts like this on little endian systems

```
union ResultType {
unsigned __int64 result;
unsigned char bitcount[8]; // bitcount[x] is the number of times the x-th most significant bit appeared
};
ResultType r;
r.result = val1 + val2 + val3 + ...; // up to 255 values can be summed before we risk overflow
r.bitcount[2] // how many times the 00000100 bit was set
```