Some processors have an instruction to count the leading binary zeros of an integer, and some compilers have instrinsics to allow you to use that instruction. For example, using GCC:

```
uint32_t significant_bits(uint32_t value, unsigned bits) {
unsigned leading_zeros = __builtin_clz(value);
unsigned highest_bit = 32 - leading_zeros;
unsigned lowest_bit = highest_bit - bits;
return value >> lowest_bit;
}
```

For simplicity, I left out checks that the requested number of bits are available. For Microsoft's compiler, the intrinsic is called `__lzcnt`

.

If your compiler doesn't provide that intrinsic, and you processor doesn't have a suitable instruction, then one way to count the zeros quickly is with a binary search:

```
unsigned leading_zeros(int32_t value) {
unsigned count = 0;
if ((value & 0xffff0000u) == 0) {
count += 16;
value <<= 16;
}
if ((value & 0xff000000u) == 0) {
count += 8;
value <<= 8;
}
if ((value & 0xf0000000u) == 0) {
count += 4;
value <<= 4;
}
if ((value & 0xc0000000u) == 0) {
count += 2;
value <<= 2;
}
if ((value & 0x80000000u) == 0) {
count += 1;
}
return count;
}
```

isthe most significant bits. You ignore leading 0s as if they don't exist. I.e. purely in decimal now, what is 12345000 to 2 significant digits? What about 000012345000? – BoBTFish Mar 15 '12 at 11:27