How to check if a binary number can be divided by 10 (decimal), without converting it to other system. For example, we have a number:
1010 1011 0100 0001 0000 0100
How we can check that this number is divisible by 10?
First split the number into odd and even bits (I'm calling "even" the bits corresponding to even powers of 2):
100100110010110000000101101110 0 1 0 1 0 0 1 0 0 0 1 1 0 1 0 even 1 0 0 1 0 1 1 0 0 0 0 0 1 1 1 odd
Now in each of these, add and subtract the digits alternately, as in the standard test for divisibility by 11 in decimal (starting with addition at the right):
100100110010110000000101101110 +0-1+0-1+0-0+1-0+0-0+1-1+0-1+0 = -2 +1-0+0-1+0-1+1-0+0-0+0-0+1-1+1 = 1
Now double the sum of the odd digits and add it to the sum of the even digits:
2*1 + -2 = 0
If the result is divisible by 5, as in this case, the number itself is divisible by 5.
Since this number is also divisible by 2 (the rightmost digit being 0), it is divisible by 10.
If you are talking about computational methods, you can do a divisiblity-by-5 test and a divisibility-by-2 test.
The numbers below assume unsigned 32-bit arithmetic, but can easily be extended to larger numbers.
I'll provide some code first, followed by a more textual explanation:
unsigned int div5exact(unsigned int n)
{
// returns n/5 as long as n actually divides 5
// (because 'n * (INV5 * 5)' == 'n * 1' mod 2^32
#define INV5 0xcccccccd
return n * INV5;
}
unsigned int divides5(unsigned int n)
{
unsigned int q = div5exact(n);
if (q <= 0x33333333) /* q*5 < 2^32? */
{
/* q*5 doesn't overflow, so n == q*5 */
return 1;
}
else
{
/* q*5 overflows, so n != q*5 */
return 0;
}
}
int divides2(unsigned int n)
{
/* easy divisibility by 2 test */
return (n & 1) == 0;
}
int divides10(unsigned int n)
{
return divides2(n) && divides5(n);
}
/* fast one-liner: */
#define DIVIDES10(n) ( ((n) & 1) == 0 && ((n) * 0xcccccccd) <= 0x33333333 )
Divisibility by 2 is easy: (n&1) == 0 means that n is even.
Divisibility by 5 involves multiplying by the inverse of 5, which is 0xcccccccd (because 0xcccccccd * 5 == 0x400000001, which is just 0x1 if you truncate to 32 bits).
When you multiply n*5 by the inverse of 5, you get n * 5*(inverse of 5), which in 32-bit math simplifies to n*1 .
Now let's say n and q are 32-bit numbers, and q = n*(inverse of 5) mod 2^{32}.
Because n is no greater than 0xffffffff, we know that n/5 is no greater than (2^{32}-1)/5 (which is 0x33333333). Therefore, we know if q is less than or equal to (2^{32}-1)/5, then we know n divides exactly by 5, because q * 5 doesn't get truncated in 32 bits, and is therefore equal to n, so n divides q and 5.
If q is greater than (2^{32}-1)/5, then we know it doesn't divide 5, because there is a one-one mapping between the 32-bit numbers divisible by 5 and the numbers between 0 and (2^{32}-1)/5, and so any number out of this range doesn't map to a number that's divisible by 5.
Here is the code in python to check the divisibilty by 10 using bitwise technique
#taking input in string which is a binary number eg: 1010,1110
s = input()
#taking initial value of x as o
x = 0
for i in s:
if i == '1':
x = (x*2 + 1) % 10
else:
x = x*2 % 10
#if x is turn to be 0 then it is divisible by 10
if x:
print("Not divisible by 10")
else:
print("Divisible by 10")
x
being divisable byy
means there exists some integerm
such thatym = x
that is it is divided without remainder -- so it was not at all ambiguous. I can understand how it can be confusing since we perform division on non-divisable numbers all the time, i.e. we get a result with a remiander/ a decimal -- which make no sense if you are careful with the definition of the word divisable.