8 | 1 ; //9
8 in binary = 1000
if you take each binary digit and treat them as if statements (1 being true and 0 being false), you get this:
and the result is 1001, which is 9 in decimal
If it had been 8 & 1, it would go like this:
and the result would be 0
Here's a quick example of how you might use these:
You would use the OR operator if you wanted to combine masks -
Using an example of file permissions, you may have the following flags:
If you wanted to create a mask for read and execute, you'd do something like
Now you have a mask that you can check a file's permissions to see if it has both of these permissions, using the
Example file 1 (has read, write, and execute)
Its permission value is 7 (111 in bin): 111 & 101 = 101, so it does have those perms
Example file 2 (has read and write)
Its permission value is 6 (110 in bin): 110 & 101 = 100, so it only has the 100 (4 in dec) perms (read) of the two provided from the mask
8 (base 10) is 1000 (base 2; binary). 1 is 0001
So, 8 | 1 (base 10) is equal to 1000 | 0001 binary, which is 1001 binary, which is 9 (base 10).
All values on a computer are stored on the hardware in binary format.
Well, in your example, take the binary representations:
Then apply a logical OR to each bit (hence "bitwise"): For each bit, if either one, the other or both is/are 1 then the result is 1, else the result is 0.
Which is 9.
It takes the binary representation of two numbers, and finds the union ("or") between them.
Consider the two you gave:
So, if a bit is 1 in the first number (8) or the second number (1) or if it is 1 in both then it is carried down to the result.