An excellent recent study comparing several of the most modern techniques for counting the *number of 'set' (1-valued) bits* in a range of memory (*aka* Hamming Weight, *bitset cardinality*, *sideways sum*, *population count* or `popcnt`

, *etc.*) can be found in Wojciech, Kurz, and Lemire (2017), *Faster population counts using AVX2 instructions*^{ 1}

The following is a complete, tested, and fully-working **C#** adaptation of the "Harley-Seal" algorithm from that paper, which the authors found to be the fastest method that uses general-purpose bitwise operations (that is, that doesn't require special hardware).

**1. Managed array entry points**

(optional) Provides access to the block-optimized bit-counting for managed array `ulong[]`

.

```
/// <summary> Returns the total number of 1-valued bits in the array </summary>
[DebuggerStepThrough]
public static int OnesCount(ulong[] rg) => OnesCount(rg, 0, rg.Length);
/// <summary> Finds the total number of '1' bits in an array or its subset </summary>
/// <param name="rg"> Array of ulong values to scan </param>
/// <param name="index"> Starting index in the array </param>
/// <param name="count"> Number of ulong values to examine, starting at 'i' </param>
public static int OnesCount(ulong[] rg, int index, int count)
{
if ((index | count) < 0 || index > rg.Length - count)
throw new ArgumentException();
fixed (ulong* p = &rg[index])
return OnesCount(p, count);
}
```

**2. Scalar API**

Used by the block-optimized counter to aggregate results from the carry-save adder, and also to finish up any remainder for block sizes not divisible by the optimized chunk size of 16 x 8 bytes/ulong = 128 bytes. Suitable for general-purpose use also.

```
/// <summary> Finds the Hamming Weight or ones-count of a ulong value </summary>
/// <returns> The number of 1-bits that are set in 'x' </returns>
public static int OnesCount(ulong x)
{
x -= (x >> 1) & 0x5555555555555555;
x = ((x >> 2) & 0x3333333333333333) + (x & 0x3333333333333333);
return (int)((((x + (x >> 4)) & 0x0F0F0F0F0F0F0F0F) * 0x0101010101010101) >> 56);
}
```

**3. ***"Harley-Seal"* block-optimized 1s-bit counter

Processes blocks of 128 bytes at a time, i.e., 16 `ulong`

values per block. Uses the carry-save adder (shown below) to gang-add single bits across adjacent `ulong`

s, and aggregates totals upwards as powers of two.

```
/// <summary> Count the number of 'set' (1-valued) bits in a range of memory. </summary>
/// <param name="p"> Pointer to an array of 64-bit ulong values to scan </param>
/// <param name="c"> Size of the memory block as a count of 64-bit ulongs </param>
/// <returns> The total number of 1-bits </returns>
public static int OnesCount(ulong* p, int c)
{
ulong z, y, x, w;
int c = 0;
for (w = x = y = z = 0UL; cq >= 16; cq -= 16)
c += OnesCount(CSA(ref w,
CSA(ref x,
CSA(ref y,
CSA(ref z, *p++, *p++),
CSA(ref z, *p++, *p++)),
CSA(ref y,
CSA(ref z, *p++, *p++),
CSA(ref z, *p++, *p++))),
CSA(ref x,
CSA(ref y,
CSA(ref z, *p++, *p++),
CSA(ref z, *p++, *p++)),
CSA(ref y,
CSA(ref z, *p++, *p++),
CSA(ref z, *p++, *p++)))));
c <<= 4;
c += (OnesCount(w) << 3) + (OnesCount(x) << 2) + (OnesCount(y) << 1) + OnesCount(z);
while (--cq >= 0)
c += OnesCount(*p++);
return c;
}
```

**4. Carry-save adder (CSA)**

```
/// <summary> carry-save adder </summary>
[MethodImpl(MethodImplOptions.AggressiveInlining)]
static ulong CSA(ref ulong a, ulong b, ulong c)
{
ulong v = a & b | (a ^ b) & c;
a ^= b ^ c;
return v;
}
```

**Remarks**
Because the approach shown here counts the total number of 1-bits by proceeding 128-byte chunks at a time, it only becomes optimal with larger memory block sizes. For example, likely at least some (small) multiple of that sixteen-qword (16-`ulong`

) chunk size. For counting 1-bits in smaller memory ranges, this code will work correctly, but drastically underperform more naïve methods. See the paper for details.

From the paper, this diagram summarizes how the Carry-Save Adder works:

**References**
[1.] Muła, Wojciech, Nathan Kurz, and Daniel Lemire. "Faster population counts using AVX2 instructions." The Computer Journal 61, no. 1 (2017): 111-120.

`for (int i = ...; ...; ++i) count += bits_per_byte[((unsigned char*)ptr)[i]]`

. Where bits_per_byte is a precomputed array of 256 values holding the number of set bits for each possible byte value. You have a bit of messing around to do at the start and end of your loop where you don't have a whole byte to play with. – john Aug 27 '11 at 7:31`countSetBits()`

function in the question counts from MSB to LSB. – Michael Burr Aug 28 '11 at 15:32