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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


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

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

share|improve this question
Obligatory link: – 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
up vote 4 down vote accepted

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;
share|improve this answer
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.

share|improve this answer
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 v = nbitsmask;
        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.

share|improve this answer

This should do the trick

int a = 1200;
int mask = ~((2<<(32-n))-1);
int b = a&mask;

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.

share|improve this answer
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

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