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).
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.
All values on a computer are stored on the hardware in binary format.
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.