# Homework - C bit puzzle - Perform % using C bit operations (no looping, conditionals, function calls, etc)

I'm completely stuck on how to do this homework problem and looking for a hint or two to keep me going. I'm limited to 20 operations (= doesn't count in this 20).

I'm supposed to fill in a function that looks like this:

/* Supposed to do x%(2^n).
For example: for x = 15 and n = 2, the result would be 3.

Additionally, if positive overflow occurs, the result should be the
maximum positive number, and if negative overflow occurs, the result
should be the most negative number.
*/
int remainder_power_of_2(int x, int n){

int twoToN = 1 << n;

/* Magic...? How can I do this without looping? We are assuming it is a
32 bit machine, and we can't use constants bigger than 8 bits
(0xFF is valid for example).
However, I can make a 32 bit number by ORing together a bunch of stuff.
Valid operations are: << >> + ~ ! | & ^
*/

}

I was thinking maybe I could shift the twoToN over left... until I somehow check (without if/else) that it is bigger than x, and then shift back to the right once... then xor it with x... and repeat? But I only have 20 operations!

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You have a mistake somewhere. If the result is supposed to be x%(2^n) (where “^” is exponentiation, not XOR), then 15%(2^4) is 15, not 3. So either the result is supposed to be x%n (15%4 is 3) or the example should say the result is 15, not 3. –  Eric Postpischil Aug 27 '12 at 19:27
Whoops! Thanks! Should be a 2 –  user114518 Aug 27 '12 at 19:29

Since binary is base 2, remainders mod 2^N are exactly represented by the rightmost bits of a value. For example, consider the following 32 bit integer:

00000000001101001101000110010101

This has the two's compliment value of 3461525. The remainder mod 2 is exactly the last bit (1). The remainder mod 4 (2^2) is exactly the last 2 bits (01). The remainder mod 8 (2^3) is exactly the last 3 bits (101). Generally, the remainder mod 2^N is exactly the last N bits.

In short, you need to be able to take your input number, and mask it somehow to get only the last few bits.

A tip: say you're using mod 64. The value of 64 in binary is:

00000000000000000000000001000000

The modulus you're interested in is the last 6 bits. I'll provide you a sequence of operations that can transform that number into a mask (but I'm not going to tell you what they are, you can figure them out yourself :D)

00000000000000000000000001000000 // starting value
11111111111111111111111110111111 // ???
11111111111111111111111111000000 // ???
00000000000000000000000000111111 // the mask you need

Each of those steps equates to exactly one operation that can be performed on an int type. Can you figure them out? Can you see how to simplify my steps? :D

Another hint:

00000000000000000000000001000000 //  64
11111111111111111111111111000000 // -64
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Yes, right! I negate, then ?, then negate. The problem is the step between the two ?s for me... so... hmmm.. maybe... + 1? ... right? aha! I think... right? Dunno going to try it out thanks! –  user114518 Aug 27 '12 at 19:40
@Silver: What much simpler, glaringly obvious thing could you do to get from step 1 to step 4 in one shot (that embarrasingly enough I didn't notice until after I submitted my post :D)? –  Wug Aug 27 '12 at 19:42
Ah! minus one! sneaky! –  user114518 Aug 27 '12 at 19:43
@Silver: you should post your code when you're done. I want to see what you come up with, and we can critique it. –  Wug Aug 27 '12 at 19:48
For sure, I will, but it might be a little while because this isn't due for another two weeks (and I don't want to get in trouble so much). So you're algorithm is working great, except it always returns a positive result. Now... I know how to negate ~result + 1... but how to do it conditionally without conditionals –  user114518 Aug 27 '12 at 19:58

Hint: In decadic system to do a modulo by power of 10, you just leave the last few digits and null the other. E.g. 12345 % 100 = 00045 = 45. Well, in computer numbers are binary. So you have to null the binary digits (bits). So look at various bit manipulation operators (&, |, ^) to do so.

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Ah! I'm chewin on this –  user114518 Aug 27 '12 at 19:38

Since your divisor is always power of two, it's easy.

uint32_t remainder(uint32_t number, uint32_t power)
{
power = 1 << power;
return (number & (power - 1));
}

Suppose you input number as 5 and divisor as 2

`00000000000000000000000000000101` number
AND
`00000000000000000000000000000001` divisor - 1
=
`00000000000000000000000000000001` remainder (what we expected)

Suppose you input number as 7 and divisor as 4

`00000000000000000000000000000111` number
AND
`00000000000000000000000000000011` divisor - 1
=
`00000000000000000000000000000011` remainder (what we expected)

This only works as long as divisor is a power of two (Except for divisor = 1), so use it carefully.

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1 is in fact a power of two. –  aschepler Sep 19 '12 at 22:38
care to read the last line ? –  user1075375 Sep 21 '12 at 4:50
I meant there's no need for that exception. remainder(n,0) == 0 is correct. –  aschepler Oct 1 '12 at 12:59