I want to extract bits of a decimal number.
For example, 7 is binary 0111, and I want to get 0 1 1 1 all bits stored in bool. How can I do so?
OK, a loop is not a good option, can I do something else for this?
If you want the k-th bit of n, then do
(n & ( 1 << k )) >> k
Here we create a mask, apply the mask to n, and then right shift the masked value to get just the bit we want. We could write it out more fully as:
int mask = 1 << k;
int masked_n = n & mask;
int thebit = masked_n >> k;
You can read more about bit-masking here.
Here is a program:
#include <stdio.h>
#include <stdlib.h>
int *get_bits(int n, int bitswanted){
int *bits = malloc(sizeof(int) * bitswanted);
int k;
for(k=0; k<bitswanted; k++){
int mask = 1 << k;
int masked_n = n & mask;
int thebit = masked_n >> k;
bits[k] = thebit;
}
return bits;
}
int main(){
int n=7;
int bitswanted = 5;
int *bits = get_bits(n, bitswanted);
printf("%d = ", n);
int i;
for(i=bitswanted-1; i>=0;i--){
printf("%d ", bits[i]);
}
printf("\n");
}
(n >> k) & 1
is equally valid and does not require computing the mask as the mask is constant due to shifting before masking instead of the other way around.
struct
can be useful too, as you get all the required data with a single operation.
As requested, I decided to extend my comment on forefinger's answer to a full-fledged answer. Although his answer is correct, it is needlessly complex. Furthermore all current answers use signed int
s to represent the values. This is dangerous, as right-shifting of negative values is implementation-defined (i.e. not portable) and left-shifting can lead to undefined behavior (see this question).
By right-shifting the desired bit into the least significant bit position, masking can be done with 1
. No need to compute a new mask value for each bit.
(n >> k) & 1
As a complete program, computing (and subsequently printing) an array of single bit values:
#include <stdio.h>
#include <stdlib.h>
int main(int argc, char** argv)
{
unsigned
input = 0b0111u,
n_bits = 4u,
*bits = (unsigned*)malloc(sizeof(unsigned) * n_bits),
bit = 0;
for(bit = 0; bit < n_bits; ++bit)
bits[bit] = (input >> bit) & 1;
for(bit = n_bits; bit--;)
printf("%u", bits[bit]);
printf("\n");
free(bits);
}
Assuming that you want to calculate all bits as in this case, and not a specific one, the loop can be further changed to
for(bit = 0; bit < n_bits; ++bit, input >>= 1)
bits[bit] = input & 1;
This modifies input
in place and thereby allows the use of a constant width, single-bit shift, which may be more efficient on some architectures.
Here's one way to do it—there are many others:
bool b[4];
int v = 7; // number to dissect
for (int j = 0; j < 4; ++j)
b [j] = 0 != (v & (1 << j));
It is hard to understand why use of a loop is not desired, but it is easy enough to unroll the loop:
bool b[4];
int v = 7; // number to dissect
b [0] = 0 != (v & (1 << 0));
b [1] = 0 != (v & (1 << 1));
b [2] = 0 != (v & (1 << 2));
b [3] = 0 != (v & (1 << 3));
Or evaluating constant expressions in the last four statements:
b [0] = 0 != (v & 1);
b [1] = 0 != (v & 2);
b [2] = 0 != (v & 4);
b [3] = 0 != (v & 8);
Here's a very simple way to do it;
int main()
{
int s=7,l=1;
vector <bool> v;
v.clear();
while (l <= 4)
{
v.push_back(s%2);
s /= 2;
l++;
}
for (l=(v.size()-1); l >= 0; l--)
{
cout<<v[l]<<" ";
}
return 0;
}
Using std::bitset
int value = 123;
std::bitset<sizeof(int)> bits(value);
std::cout <<bits.to_string();
@prateek thank you for your help. I rewrote the function with comments for use in a program. Increase 8 for more bits (up to 32 for an integer).
std::vector <bool> bits_from_int (int integer) // discern which bits of PLC codes are true
{
std::vector <bool> bool_bits;
// continously divide the integer by 2, if there is no remainder, the bit is 1, else it's 0
for (int i = 0; i < 8; i++)
{
bool_bits.push_back (integer%2); // remainder of dividing by 2
integer /= 2; // integer equals itself divided by 2
}
return bool_bits;
}
#include <stdio.h>
int main(void)
{
int number = 7; /* signed */
int vbool[8 * sizeof(int)];
int i;
for (i = 0; i < 8 * sizeof(int); i++)
{
vbool[i] = number<<i < 0;
printf("%d", vbool[i]);
}
return 0;
}
If you don't want any loops, you'll have to write it out:
#include <stdio.h>
#include <stdbool.h>
int main(void)
{
int num = 7;
#if 0
bool arr[4] = { (num&1) ?true: false, (num&2) ?true: false, (num&4) ?true: false, (num&8) ?true: false };
#else
#define BTB(v,i) ((v) & (1u << (i))) ? true : false
bool arr[4] = { BTB(num,0), BTB(num,1), BTB(num,2), BTB(num,3)};
#undef BTB
#endif
printf("%d %d %d %d\n", arr[3], arr[2], arr[1], arr[0]);
return 0;
}
As demonstrated here, this also works in an initializer.
If I could rephrase the question, a more general request to extract a set of bits from an integer could be stated as:
I want to extract "size" number of bits from a decimal number "n" from "pos" bit onwards so that I get the bits starting from bit positions "pos + size" to "pos"
The more general statement above can then be stated as:
I want to extract 1 bit from a decimal number "n' from bit position "pos"
You can then change the above statement to:
I want to extract the bits of a from a decimal number "n" one bit at a time and store it into a boolean array so that the bit position "pos" corresponds to the array index "pos".
Assuming that the first "position" of the bit in the decimal number is the LSB i.e bit 0, we can extract n bits from a decimal number like this:
create mask for number of bits :
(1 << size) - 1
shift the number by number of bits so that the bit at index is now the LSB :n >> pos
Logical AND the shifted value with the mask :(n >> pos) & ((1 << size) - 1)
Here is an example:
#define GET_N_BITS(n, size, pos, ret) ({ \
ret = (n >> pos) & ((1 << size) - 1); \
)}
main()
{
int n = 7;
int extracted_bits = 0;
// extract 2 bits from bit 1 onwards from decimal number 7
GET_N_BITS(n, 2, 1, extracted_bits);
// extracted bits = b0011 = 3
}
We can then change the above to extract and return one bit from a given bit position and store it in an array.
#define GET_NTH_BIT(n, pos) ({ \
bool ret; \
ret = (n >> pos) & 1 \
ret; \
})
main()
{
int n = 7, i = 0;
bool n_bit_by_bit[32];
for (i = 0 ; i < 32 ; i++)
n_bit_by_bit[i] = GET_NTH_BIT(n, i);
}