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Using only bitwise operators (|, &, ~, ^, >>, <<) and other basic operators like +, -, and !, is it possible to replace the "==" below?

int equal(int x, int y) {
    return x == y;
}
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1  
This is mostly to understand what is actually going on with "==" to see how the computer looks at the "==" on a bitwise level and to find if similar operators can be replicated in the same fashion. –  not_l33t Nov 12 '10 at 4:41
    
@Jens: "The homework tag...is now discouraged," but, @not_l33t, please (as always) follow general guidelines: state any special restrictions, show what you've tried so far, and ask about what specifically is confusing you. –  Roger Pate Nov 12 '10 at 14:06
    
What are the requirements as you approach an int's limits? I.e. INT_MAX, INT_MIN? Or does it only have to work for a much smaller range? –  Roger Pate Nov 12 '10 at 14:09
    
I am fairly new to programming, and the question is more to understand how it works. With that in mind, it would be ideal to have an infinite limit, though I am beginning to see that that might not really be possible for me to figure out (bitwise manipulation works because of the 32 bit string). –  not_l33t Nov 12 '10 at 15:55
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5 Answers

up vote 13 down vote accepted

Two numbers are equal if there is no difference between them:

int equal(int x, int y){
   return !(x-y);
}
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I like this approach. +1 –  Prasoon Saurav Nov 12 '10 at 4:42
1  
Though not really using a bitwise operator. –  Yada Nov 12 '10 at 4:44
    
@Yada: But it uses a "BASIC" operator :) –  Hippo Nov 12 '10 at 4:47
    
I have used this approach in combination with another approach (negating a variable). that way i could use a + instead, making it closer to what the computer reads. thus making it faster? –  not_l33t Nov 12 '10 at 5:30
    
int equal(int x, int y){ return !((!x+1)+y); } –  not_l33t Nov 12 '10 at 5:31
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return !(x ^ y);
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You're combining bit-wise with logical operators here, which may be confusing. –  David Titarenco Nov 12 '10 at 4:46
    
No this is wicked :P –  Matt Joiner Nov 12 '10 at 5:02
1  
It's better than the accepted solution, because by definition XOR is faster than ADD (add have to transport carry, so it's not very scalable). –  ruslik Nov 12 '10 at 9:44
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The C ! operator is really just shorthand for != 0, so using it seems very close to cheating :)

Here's my take just using bitwise operations, assuming a 32-bit two's complement machine with arithmetic right shifts (technically, in C arithmetic right shifts are undefined, but every C compiler I've ever seen on a two's complement machine supports this correctly):

int t = (x - y) | (y - x); // <0 iff x != y, 0 otherwise
t >>= 31; // -1 iff x != y, 0 otherwise
return 1 + t; // 0 iff x != y, 1 otherwise

That said, actual compilers don't have this problem. Real hardware actually has direct support for comparisons. The details depend on the architecture, but there's two basic models:

  1. Condition codes returned for arithmetic operations (e.g. x86 and ARM do this). In this case, there's usually a "compare" instruction which subtracts two values, doesn't write back to an integer register but sets the condition code/flags based on the result.
  2. More RISC-like platforms typically have direct "branch if equal" and "branch if less than" operands that do a comparison and branch based on the result. It's basically equivalent to the C code

    if (a == b) goto label;
    

    or

    if (a < b) goto label;
    

    all in one machine instruction.

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This example is the same as subtraction, but is more explicit as to how some architectures do register comparison (like the ARM, I believe).

return !(1 + ~x + y);

The 1 signifies the carry-bit input into the ALU. One number x is bitwise complemented. Taking the complement and adding 1 produces the two's complement of the number (x becomes -x), and then it's added to the other number to get the difference to determine equality.

So if both numbers are equal, you get -x + x => 0.

(On a register level the ! operator isn't done, and you just test the "zero bit" of the condition codes or flags register, which gets set if the register operation produces a result of zero, and is clear otherwise.)

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My Take on this

int equal(int x, int y){
   if((x & ~y) == 0)
       return 1;
   else
       return 0; 
}

Explanation: If x == y, then x & ~y evaluates to 0 return 1, else return 0 as x!=y.

Edit1: The above is equivalent to 

int equal(int x, int y){
    return !(x & ~y) ; // returns 1 if equal , 0 otherwise. 
}

The above code fails in certain cases where the Most significant bit turns to 1. The solution is to add a 1. i.e correct answer is

return !(x & (~y +1) );
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Two problems. 1) This checks if y has all the same bits as x set, not that x == y. 2) You're using == even though it is neither wanted nor needed. –  Ignacio Vazquez-Abrams Nov 12 '10 at 7:09
2  
3) just return it instead of using an if. –  Mark Nov 12 '10 at 7:38
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