The question is also tagged `AVX`

, but there are no instructions for integer processing in `AVX`

, which means one needs to fall back to SSE on platforms that support `AVX`

but not `AVX2`

. I am showing an exhaustively tested, but a bit pedestrian version below. The basic idea here is as in the other answers, in that the count of leading zeros is determined by the floating-point normalization that occurs during integer to floating-point conversion. The exponent of the result has a one-to-one correspondence with the count of leading zeros, except that the result is wrong in the case of an argument of zero. Conceptually:

```
clz (a) = (158 - (float_as_uint32 (uint32_to_float_rz (a)) >> 23)) + (a == 0)
```

where `float_as_uint32()`

is a re-interpreting cast and `uint32_to_float_rz()`

is a conversion from unsigned integer to floating-point *with truncation*. A normal, rounding, conversion could bump up the conversion result to the next power of two, resulting in an incorrect count of leading zero bits.

`SSE`

does not provide truncating integer to floating-point conversion as a single instruction, nor conversions from unsigned integers. This functionality needs to be emulated. The emulation does not need to be exact, as long as it does not change the magnitude of the conversion result. The truncation part is handled by the *invert - right shift - andn* technique from aqrit's answer. To use signed conversion, we cut the number in half before the conversion, then double and increment after the conversion:

```
float approximate_uint32_to_float_rz (uint32_t a)
{
float r = (float)(int)((a >> 1) & ~(a >> 2));
return r + r + 1.0f;
}
```

This approach is translated into `SSE`

intrinsics in `sse_clz()`

below.

```
#include <stdio.h>
#include <stdlib.h>
#include <stdint.h>
#include <string.h>
#include "immintrin.h"
/* compute count of leading zero bits using floating-point normalization.
clz(a) = (158 - (float_as_uint32 (uint32_to_float_rz (a)) >> 23)) + (a == 0)
The problematic part here is uint32_to_float_rz(). SSE does not offer
conversion of unsigned integers, and no rounding modes in integer to
floating-point conversion. Since all we need is an approximate version
that preserves order of magnitude:
float approximate_uint32_to_float_rz (uint32_t a)
{
float r = (float)(int)((a >> 1) & ~(a >> 2));
return r + r + 1.0f;
}
*/
__m128i sse_clz (__m128i a)
{
__m128 fp1 = _mm_set_ps1 (1.0f);
__m128i zero = _mm_set1_epi32 (0);
__m128i i158 = _mm_set1_epi32 (158);
__m128i iszero = _mm_cmpeq_epi32 (a, zero);
__m128i lsr1 = _mm_srli_epi32 (a, 1);
__m128i lsr2 = _mm_srli_epi32 (a, 2);
__m128i atrunc = _mm_andnot_si128 (lsr2, lsr1);
__m128 atruncf = _mm_cvtepi32_ps (atrunc);
__m128 atruncf2 = _mm_add_ps (atruncf, atruncf);
__m128 conv = _mm_add_ps (atruncf2, fp1);
__m128i convi = _mm_castps_si128 (conv);
__m128i lsr23 = _mm_srli_epi32 (convi, 23);
__m128i res = _mm_sub_epi32 (i158, lsr23);
return _mm_sub_epi32 (res, iszero);
}
/* Portable reference implementation of 32-bit count of leading zeros */
int clz32 (uint32_t a)
{
uint32_t r = 32;
if (a >= 0x00010000) { a >>= 16; r -= 16; }
if (a >= 0x00000100) { a >>= 8; r -= 8; }
if (a >= 0x00000010) { a >>= 4; r -= 4; }
if (a >= 0x00000004) { a >>= 2; r -= 2; }
r -= a - (a & (a >> 1));
return r;
}
/* Test floating-point based count leading zeros exhaustively */
int main (void)
{
__m128i res;
uint32_t resi[4], refi[4];
uint32_t count = 0;
do {
refi[0] = clz32 (count);
refi[1] = clz32 (count + 1);
refi[2] = clz32 (count + 2);
refi[3] = clz32 (count + 3);
res = sse_clz (_mm_set_epi32 (count + 3, count + 2, count + 1, count));
memcpy (resi, &res, sizeof resi);
if ((resi[0] != refi[0]) || (resi[1] != refi[1]) ||
(resi[2] != refi[2]) || (resi[3] != refi[3])) {
printf ("error @ %08x %08x %08x %08x\n",
count, count+1, count+2, count+3);
return EXIT_FAILURE;
}
count += 4;
} while (count);
return EXIT_SUCCESS;
}
```