# Mod of power 2 on bitwise operators?

1. How does mod of power of 2 work on only lower order bits of a binary number (`1011000111011010`)?
2. What is this number mod 2 to power 0, 2 to power 4?
3. What does power of 2 have to do with the modulo operator? Does it hold a special property?
4. Can someone give me an example?

The instructor says "When you take something mod to power of 2 you just take its lower order bits". I was too afraid to ask what he meant =)

• Why don't you try a few example calculations by hand, then you'll see what happens. Jul 13, 2011 at 10:20

He meant that taking `number mod 2^n` is equivalent to stripping off all but the `n` lowest-order (right-most) bits of `number`.

For example, if n == 2,

``````number      number mod 4
00000001      00000001
00000010      00000010
00000011      00000011
00000100      00000000
00000101      00000001
00000110      00000010
00000111      00000011
00001000      00000000
00001001      00000001
etc.
``````

So in other words, `number mod 4` is the same as `number & 00000011` (where `&` means bitwise-and)

Note that this works exactly the same in base-10: `number mod 10` gives you the last digit of the number in base-10, `number mod 100` gives you the last two digits, etc.

• This is only the case when all operands are positive! Depending on the language the behavior will differ. For instance in C, `-5 % 4 == -1` despite the fact that in algebra we usually expect that `-5 mod 4` is 3 (and in C: `-5 & (4 - 1) == 3`. This means for instance that a compiler will not optimize a literal `% 4` with a `&` if the left operand is not unsigned. Nov 18, 2016 at 15:46
• @calandoa: We are discussing binary as a number system here, not bit-encoding of numbers. `-5`, for instance, is written `-101`. Nov 18, 2016 at 16:08
• @BlueRaja: Of course we are talking about bit encoding : `&` is not defined for mathematical `-`. I guess your remark is more "we are not talking about negative numbers". Maybe we are not, but this is not clear in the question nor in your answer, so I made it clearer. Nov 22, 2016 at 11:18
• Do you thing at something like `number MOD 256` <=> `(number & (0xFF00)) >> 8` (for 2^8 = 256) Nov 26, 2019 at 15:29

What he means is that :

``````x modulo y = (x & (y − 1))
``````

When y is a power of 2.

Example:

``````0110010110 (406) modulo
0001000000 (64)  =
0000010110 (22)
^^^^<- ignore these bits
``````

``````1011000111011010 (45530) modulo
0000000000000001 (2 power 0) =
0000000000000000 (0)
^^^^^^^^^^^^^^^^<- ignore these bits

1011000111011010 (45530) modulo
0000000000010000 (2 power 4) =
0000000000001010 (10)
^^^^^^^^^^^^<- ignore these bits
``````

Consider when you take a number modulo 10. If you do that, you just get the last digit of the number.

``````  334 % 10 = 4
12345 % 10 = 5
``````

Likewise if you take a number modulo 100, you just get the last two digits.

``````  334 % 100 = 34
12345 % 100 = 45
``````

So you can get the modulo of a power of two by looking at its last digits in binary. That's the same as doing a bitwise and.

• Would that hold for powers of 2 as well ? 54 % 32 which is 2^5 gives 22. Jul 12, 2011 at 21:07
• Popo: Yes. The number of bits at the end is determined by which power of two you're using. As described by Cicada, you would calculate it as 54 & (32-1). Jul 12, 2011 at 21:39

Modulo in general returns the remainder of a value after division. So `x mod 4`, for example, returns 0, 1, 2 or 3 depending on x. These possible values can be represented using two bits in binary (00, 01, 10, 11) - another way to do `x mod 4` is to simply set all the bits to zero in x except the last two ones.

Example:

``````      x = 10101010110101110
x mod 4 = 00000000000000010
``````