# C++: compute a number's complement and its number of possible mismatches

I got a bit stuck with my algorithm and I need some help to solve my problem. I think an example would explain better my problem.

Assuming:

• d = 4 (maximum number of allowed bits in a number, 2^4-1=15).
• m_max = 1 (maximum number of allowed bits mismatches).
• kappa = (maximum number of elements to find for a given d and m, where m in m_max)

The main idea is for a given number, x, to compute its complement number (in binary base) and all the possible combinations for up to m_max mismatches from x complement's number.

Now the program start to scan from i = 0 till 15.

• for i = 0 and m = 0, kappa = \binom{d}{0} = 1 (this called a perfect match) possible combinations in bits, is only 1111 (for 0: 0000).

• for i = 0 and m = 1, kappa = \binom{d}{1} = 4 (one mismatch) possible combinations in bits are: 1000, 0100, 0010 and 0001

My problem was to generalize it to general d and m. I wrote the following code:

#include <stdlib.h>
#include <iomanip>
#include <boost/math/special_functions/binomial.hpp>
#include <iostream>
#include <stdint.h>
#include <vector>

namespace vec {
typedef std::vector<unsigned int>  uint_1d_vec_t;
}

int main( int argc, char* argv[] ) {

int counter, d, m;
uint_1d_vec_t kappa;

d = 4;
m = 2;

for ( unsigned i = 0 ; i < num_elemets ; i++ ) {
counter = 0;
for ( unsigned m = 0 ; m < max_num_mismatch ; m++ ) {
// maximum number of allowed combinations
num_combination = boost::math::binomial_coefficient<double>( static_cast<unsigned>( d ), static_cast<unsigned>(m) );
kappa.push_back( num_combination );
for ( unsigned j = 0 ; j < kappa.at(m) ; j++ ) {
if ( m == 0 )
else {
bit_mask = 1 << ( num_bits - j );
}
}
}
}

return 0;

}


I got stuck in the line v[i][counter++] = v[i][0] ^ bits_mask since I was unable to generalize my algorithm to m_max>1, since I needed for m_max mismatches m_max loops and in my original problem, m is unknown until runtime.

-
So what you want is, given two bit sequences, to compare them and count the number of bits that are different between them? It's generally a lot easier to read a question if you beign with a short informal description of what you're trying to do. then your precise algorithm, variable names and exact code can come later, when we have a context for it, and know what it's supposed to mean. –  jalf Dec 13 '09 at 13:27
@jalf - is that the case? If so, this is a lot easier to do than the solution. –  D.Shawley Dec 13 '09 at 13:32
@Eagle - you seem to be using the caret (^) as an exponentiation operator. Caret in C and C++ represents a bitwise XOR operation. –  D.Shawley Dec 13 '09 at 13:33
i used XOR operation to compute the complement number of i (this is what i search at first). First 0 mismatches, then 1 mismatch and etc. –  Eagle Dec 13 '09 at 13:52
@D.Shawley, in general the operation ('~') is what i need, but if you compute the complement of a 32bits number to group of numbers which are only up to 4 bits, you wont get the complement number of a 4 bits number... using XOR between two number with the same bits length, give returns me exactly what i want. –  Eagle Dec 13 '09 at 14:05

i wrote a code that do what i want, but since i am newbie, it is a bit ugly. i fixed m and d although this code would work fine for genral m and d.

the main idea is simple, assuming we would like to compute the complement of 0 up to two failure (d= 4,m=2), we will see that max number of possibilities is given by \sum_{i = 0)^2\binom{4}{i} = 11.
The complement to 0 (at 4 bits) is 15
With 1 bit possible mismatch (from 15): 7 11 13 14
with 2 bits possible mismatches (from 15): 3 5 6 9 10 12

i wanted that the output of this program will be a vector with the numbers 15 7 11 13 14 3 5 6 9 10 12 inside it.

i hope that this time i am more clear with presenting my question (although i also supplied the solution). I would appreachiate if someone could point out, in my code, ways to improve it and make it faster.

regards

#include <boost/math/special_functions/binomial.hpp>
#include <iostream>
#include <vector>

#define USE_VECTOR

namespace vec {
#if defined(USE_VECTOR) || !defined(USE_DEQUE)
typedef std::vector<unsigned int>  uint_1d_vec_t;
typedef std::vector<uint_1d_vec_t> uint_2d_vec_t;
#else
typedef std::deque<unsigned int>   uint_1d_vec_t;
typedef std::deque<uint_1d_vec_t>  uint_2d_vec_t;
#endif
}

using namespace std;

void     get_pointers_vec( vec::uint_2d_vec_t &v , unsigned num_elemets , unsigned      max_num_unmatch , unsigned num_bits );
double   get_kappa( int m , int d );

int main( ) {

unsigned int num_elements , m , num_bits;

num_elements = 16;
num_bits     = 4;   // 2^4 = 16
m            = 2;

double kappa = 0;
for ( unsigned int i = 0 ; i <= m ; i++ )
kappa += get_kappa( num_bits , i );

vec::uint_2d_vec_t    Pointer(           num_elements   , vec::uint_1d_vec_t (kappa ,0 ) );

get_pointers_vec( Pointer , num_elements , m , num_bits );

for ( unsigned int i = 0 ; i < num_elements ; i++ ) {
std::cout << setw(2) << i << ":";
for ( unsigned int j = 0 ; j < kappa ; j++ )
std::cout << setw(3) << Pointer[i][j];
std::cout << std::endl;
}

return EXIT_SUCCESS;
}

double get_kappa( int n , int k ) {

double kappa = boost::math::binomial_coefficient<double>( static_cast<unsigned>( n ), static_cast<unsigned>(k) );

return kappa;
}

void get_pointers_vec( vec::uint_2d_vec_t &v , unsigned num_elemets , unsigned   max_num_unmatch , unsigned num_bits ) {

int counter;
vec::uint_1d_vec_t kappa;

bits_mask = pow( 2 , num_bits ) - 1;
for ( unsigned i = 0 ; i < num_elemets ; i++ ) {
counter = 0;
kappa.clear();
ref_index = 0;

for ( unsigned m = 0 ; m <= max_num_unmatch ; m++ ) {
num_combination = get_kappa( num_bits , m ); // maximum number of allowed combinations
kappa.push_back( num_combination );
if (  m == 0 ) {
}
else if ( num_bits == kappa.at(m) ) {

for ( unsigned k = m ; k <= num_bits ; k++ ) {
bit_mask = 1 << ( num_bits - k );
}
}
else {
// Find first element's index
ref_index += kappa.at( m - 2 );

for( unsigned j = 0 ; j < ( kappa.at(m - 1) - 1 ) ; j++ ) {
for ( unsigned k = m + j ; k <= num_bits ; k++ ) {
bit_mask = 1 << ( num_bits - k );