Extract n most significant non-zero bits from int in C++ without loops

I want to extract the n most significant bits from an integer in C++ and convert those n bits to an integer.

For example

``````int a=1200;
// its binary representation within 32 bit word-size is
// 00000000000000000000010010110000
``````

Now I want to extract the 4 most significant digits from that representation, i.e. 1111

``````00000000000000000000010010110000
^^^^
``````

and convert them again to an integer (1001 in decimal = 9).

How is possible with a simple c++ function without loops?

-
Obligatory link: graphics.stanford.edu/~seander/bithacks.html. – Oliver Charlesworth Mar 15 '12 at 11:10
You're looking for the first n bits which start with a 1 bit. This is not the same as the n most significant bits. The 4 most significant bits in your example are all 0s. – Ferruccio Mar 15 '12 at 11:21
As I understand it, that is the 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
@BoBTFish: My understanding is that a bit (in fact, any digit) is more significant the further "left" it's written, no matter what value (zero or one, in this case) it has. I think it's more significant the further 'left' it is because changing the digit more significantely changes the total value than changing a digit further right. – Frerich Raabe Mar 15 '12 at 11:31
@Ferruccio: "significant bits" could have either meaning, and the question clearly describes what is meant here. – Mike Seymour Mar 15 '12 at 12:43

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 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;
}
``````
-
Thanks, that's definitely the function I was looking for! It's exactly what I meant. I modified the uint32_t type to simply int because I know here size is 8 byte for integers. (p.s. compiled on g++4.5 x86_64 Linux) – linello Mar 15 '12 at 13:24

It's not fast, but `(int)(log(x)/log(2) + .5) + 1` will tell you the position of the most significant non-zero bit. Finishing the algorithm from there is fairly straight-forward.

-
It involves floating point arithmetic...i don't want to use floating point values... – linello Mar 15 '12 at 13:27

This seems to work (done in C# with UInt32 then ported so apologies to Bjarne):

``````        unsigned int input = 1200;
unsigned int most_significant_bits_to_get = 4;
// shift + or the msb over all the lower bits
unsigned int m1 = input | input >> 8 | input >> 16 | input >> 24;
unsigned int m2 = m1 | m1 >> 2 | m1 >> 4 | m1 >> 6;
unsigned int m3 = m2 | m2 >> 1;
unsigned int nbitsmask = m3 ^ m3 >> most_significant_bits_to_get;

unsigned int c = 32; // c will be the number of zero bits on the right
v &= -((int)v);
if (v>0) c--;
if ((v & 0x0000FFFF) >0) c -= 16;
if ((v & 0x00FF00FF) >0) c -= 8;
if ((v & 0x0F0F0F0F) >0 ) c -= 4;
if ((v & 0x33333333) >0) c -= 2;
if ((v & 0x55555555) >0) c -= 1;

unsigned int result = (input & nbitsmask) >> c;
``````

I assumed you meant using only integer math.

I used some code from @OliCharlesworth's link, you could remove the conditionals too by using the LUT for trailing zeroes code there.

-

This should do the trick

``````int a = 1200;
``````

If you want te convert them to an integer, a simple shift-operation is sufficient:

``````int b = a>>(32-n);
``````

If 32 is the bitlength. however I don't have a C++ compiler installed at the moment.

The trick is to first built a mask that extracts the least significant bits. By using a bitwise NOT operator, one can convert it to a most significant bit mask.

-
Thats why a decrement is performed. – Willem Van Onsem Mar 15 '12 at 11:20
I think your answer is missing the part which answers `[..] convert them again to an integer (1111 in decimal = 15).` (just a matter of right-shifting). – Frerich Raabe Mar 15 '12 at 11:24
In that case it would only be a>>(32-n) ?? – Willem Van Onsem Mar 15 '12 at 11:26
@CommuSoft: Exactly, I think that would answer the question given in the title. Unfortunately, as Ferruccio pointed out in a comment, the question in the title does not match the question given in the actual text. – Frerich Raabe Mar 15 '12 at 11:28
I think you are right. My reference here is Introduction to algorithms. In this case the n most significant bits for 32 bits words are all 0s. If I'd use 11 bits for word-size, in this case the 4 most significant bits were 1001 which in decimal is 9. Probably I explained myself bad...sorry – linello Mar 15 '12 at 11:36