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i have a byte array. Now i need to know the count of appearances of a bit pattern which length is N.

For example, my byte array is "00100100 10010010" and the pattern is "001". here N=3, and the count is 5.

Dealing with bits is always my weak side.

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Why do you need to do this? – anon May 31 '10 at 12:53
Do you count overlapping matches? – WhirlWind May 31 '10 at 12:58
just to understand what you mean: "00010010 01001001" is count here again 5? – OlimilOops May 31 '10 at 13:01
@Neil Butterworth: Why do you need to ask that? – Viktor Sehr May 31 '10 at 13:01
how many bytes do you have in your byte array? – OlimilOops May 31 '10 at 13:02
up vote 7 down vote accepted

You could always XOR the first N bits and if you get 0 as a result you have a match. Then shift the searched bit "stream" one bit to the left and repeat. That is assuming you want to get matches if those sub-patterns overlap. Otherwise you should shift by pattern length on match.

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You still need to take care at the byte boundaries but yes, basically this is the right approach. – Konrad Rudolph May 31 '10 at 13:00
Inefficient for longer inputs, but it works. (Consider the case where the pattern is 100 bits - you don't need to XOR all of them after you've found the first 1 bit) – MSalters May 31 '10 at 14:38
Of course you don't have to do that. I was trying just to give a basic algorithm. I think its much better than giving a full blown optimized code, because it then leads to plain copy-paste which obviously isn't what we want :) – PeterK May 31 '10 at 15:14

Assuming your array fits into an unsigned int:

int main () {
    unsigned int curnum;
    unsigned int num = 0x2492;
    unsigned int pattern = 0x1;
    unsigned int i;
    unsigned int mask = 0;
    unsigned int n = 3;
    unsigned int count = 0;

    for (i = 0; i < n; i++) {
        mask |= 1 << i;

    for (i = 8 * sizeof(num) - n; i >= 0; i--) {
        curnum = (num >> i) & mask;
        if (! (curnum ^ pattern)) {
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Convert your byte array and pattern each to a std::vector<bool>, then call std::search(source.begin(), source.end(), pattern.begin(), pattern.end());. Despite vector<bool>s idiosyncracies, this will work.

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This will certainly be much less efficient than @PeterK’s proposed solution. std::search isn’t specialized for vector<bool>::iterator. – Konrad Rudolph May 31 '10 at 14:46
The second sentence is a strong statement, but generally true. However, I disagree entirely with the first. His is certainly O(N*M). I expect a std::search() implementation to be far more efficient, and move on on the first non-match. That means you check on average 2 bits per possible position, for an overall average complexity O(N). – MSalters May 31 '10 at 15:00
how do you expect std::search to beat O(NM)? That’s very unrealistic/infeasible in general. Peter’s implementation uses O(N) (strictly speaking for for M <= 8 bit) because he XORs the bits all at once instead of comparing them one by one, so you get *exactly one (plus one for every byte border overflow) comparison for each position in the array while std::search will perform multiple comparisons. – Konrad Rudolph May 31 '10 at 15:20
(cont’d) Of course, a theoretical performance of O(N+M) is possible but only using advanced string searching algorithms which generalize very badly (in particular they depend heavily on the alphabet size) and it’s a safe bet that std::search does not implement them. – Konrad Rudolph May 31 '10 at 15:21
I expect std::search to have an worst-case complexity of O(N*M) just like PeterK's solution. The average case, though, is O(N). The reason is that in the worst case, it's the last (Mth) bit of the pattern that doesn't match, but on average it's the second. – MSalters Jun 1 '10 at 7:52

If N may be arbitrary large You can store the bit pattern in a vector

vector<unsigned char> pattern;

The size of the vector should be

(N + 7) / 8

Store the pattern shifted to the right. By this, I mean, that for example, if N == 19, Your vector should look like:

|<-    v[0]   ->|<-    v[1]   ->|<-    v[2]   ->|
 0 0 0 0 0 0 1 1 0 0 0 1 0 0 1 0 0 1 0 0 1 0 0 1
|         |<-             pattern             ->|

If You have Your pattern originally shifted to the left, You can use the function I'll present below, to shift the bits to the right.

Define a vector of bytes, of the same length as the pattern, to store a part of Your bit stream for comparing it with the pattern. I'll call it window

vector<unsigned char> window;

If N is not an integer multiple of 8, You will need to mask some leftmost bits in Your window, when comparing it with the pattern. You can define the mask this way:

unsigned char mask = (1 << (N % 8)) - 1;

Now, assuming the window contains the bits, it should, You could theoretically compare the pattern with the window using vector's operator == like this

window[0] &= mask;
bool isMatch = (window == pattern);

But there are good reasons to be a little bit more sophisticated. If N is large and Your byte array, You look for the pattern in, is significantly larger, it's worth it, to process the pattern and build a vector of size N+1:

vector<int> shifts;

This vector will store the information, how many bits to shift the bit stream by, for the next comparison, based on the position, at which there is a mismatch in the current window.

Consider the pattern 0001001100. You should compare the bits with the window from right to left. If there is a missmatch at the first bit, You know it's 1 and the first occurrence of 1 in Your pattern is at the position 2 counting form 0 form the right to the left. So in that case, You know, that it doesn't make sense to make a comparison if the number of new bits shifted form the bit stream into the window is less than 2. Similarly if the mismatch occurs at the third bit (position 2 counting form 0), the window should be moved by 7, because 3 consecutive zeros in your pattern are at the end. If the mismatch is at the position 4, You can move the window by 8 and so on. The sifts vector, at an index i will hold number of bits, by which to move the window, if the mismatch occurs at the position i. If there is a match, the window should be moved by the number of bits stored in shifts[N]. In the example above, a match means a shift by 8.

In practice of course, You compare whole bytes form the pattern with the bytes from the window (going form right to left) and if there is a mismatch You examine the bits in the byte to find the mismatch position.

if(window[i] != pattern[i])
    int j = 0;
    unsigned char mismatches = window[i] ^ pattern[i];
    while((mismatches & 1) == 0)
        mismatches >>= 1;
    mismatch_position = 8 * (window.size() - i - 1) + j;

Here is a function that might come handy, when You need to shift some bits from Your bit stream into the window. I wrote it in C#, but conversion to C++ should be trivial. C# makes some casts necessary, that are probably not necessary in C++. Use unsigned char instead of byte, vector<unsigned char> & instead of byte [], size() instead of Length and maybe some more minor tweaks. The function is probably a little more general than needed in Your scenario, as it doesn't use the fact, that consecutive calls retrieve consecutive chunks of Your byte array, which maybe could make it a bit simpler, but I don't think it hurts. In the current form, it can retrieve arbitrary bit substring form the byte array.

public static void shiftBitsIntoWindow_MSbFirst(byte[] window, byte[] source,
                                                int startBitPosition, int numberOfBits)
    int nob = numberOfBits / 8;
    // number of full bytes from the source

    int ntsh = numberOfBits % 8;
    // number of bits, by which to shift the left part of the window,
    // in the case, when numberOfBits is not an integer multiple of 8

    int nfstbb = (8 - startBitPosition % 8);
    // number Of bits from the start to the first byte boundary
    // The value is from the range [1, 8], which comes handy,
    // when checking if the substring of ntsh first bits
    // crosses the byte boundary in the source, by evaluating
    // the expression ntsh <= nfstbb.

    int nfbbte = (startBitPosition + numberOfBits) % 8;
    // number of bits from the last byte boundary to the end

    int sbtci;
    // index of the first byte in the source, from which to start
    // copying nob bytes from the source
    // The way in which the (sbtci) index is calculated depends on,
    // whether nob < window.Length

    if(nob < window.Length)// part of the window will be replaced
    // with bits from the source, but some part will remain in the
    // window, only moved to the beginning and possibly shifted
        sbtci = (startBitPosition + ntsh) / 8;

        //Loop below moves bits form the end of the window to the front
        //making room for new bits that will come form the source

        // In the corner case, when the number by which to shift (ntsh)
        // is zero the expression (window[i + nob + 1] >> (8 - ntsh)) is
        // zero and the loop just moves whole bytes
        for(int i = 0; i < window.Length - nob - 1; ++i)
            window[i] = (byte)((window[i + nob] << ntsh)
                | (window[i + nob + 1] >> (8 - ntsh)));

        // At this point, the left part of the window contains all the
        // bytes that could be constructed solely from the bytes
        // contained in the right part of the window. Next byte in the
        // window may contain bits from up to 3 different bytes. One byte
        // form the right edge of the window and one or two bytes form
        // the source. If the substring of ntsh first bits crosses the
        // byte boundary in the source it's two.

        int si = startBitPosition / 8; // index of the byte in the source
        // where the bit stream starts

        byte byteSecondPart; // Temporary variable to store the bits,
        // that come from the source, to combine them later with the bits
        // form the right edge of the window

        int mask = (1 << ntsh) - 1;
        // the mask of the form 0 0 1 1 1 1 1 1
        //                         |<-  ntsh ->|

        if(ntsh <= nfstbb)// the substring of ntsh first bits
        // doesn't cross the byte boundary in the source
            byteSecondPart = (byte)((source[si] >> (nfstbb - ntsh)) & mask);
        else// the substring of ntsh first bits crosses the byte boundary
        // in the source
            byteSecondPart = (byte)(((source[si] << (ntsh - nfstbb))
                                   | (source[si + 1] >> (8 - ntsh + nfstbb))) & mask);

        // The bits that go into one byte, but come form two sources
        // -the right edge of the window and the source, are combined below
        window[window.Length - nob - 1] = (byte)((window[window.Length - 1] << ntsh)
                                                | byteSecondPart);

        // At this point nob whole bytes in the window need to be filled
        // with remaining bits form the source. It's done by a common loop
        // for both cases (nob < window.Length) and (nob >= window.Length)

    else// !(nob < window.Length) - all bits of the window will be replaced
    // with the bits from the source. In this case, only the appropriate
    // variables are set and the copying is done by the loop common for both
    // cases
        sbtci = (startBitPosition + numberOfBits) / 8 - window.Length;
        nob = window.Length;

    if(nfbbte > 0)// The bit substring coppied into one byte in the
    // window crosses byte boundary in the source, so it has to be
    // combined form the bits, commming form two consecutive bytes
    // in the source
        for(int i = 0; i < nob; ++i)
            window[window.Length - nob + i] = (byte)((source[sbtci + i] << nfbbte)
                | (source[sbtci + 1 + i] >> (8 - nfbbte)));
    else// The bit substring coppied into one byte in the window
    // doesn't cross byte boundary in the source, so whole bytes
    // are simply coppied
        for(int i = 0; i < nob; ++i)
            window[window.Length - nob + i] = source[sbtci + i];
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