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I have to find the greater of two numbers using bit manipulation. These are the rules for the same:

 /* 
  * isGreater - if x > y  then return 1, else return 0 
  * Example: isGreater(4,5) = 0, isGreater(5,4) = 1
  *   Legal ops: ! ~ & ^ | + << >>
  *   Max ops: 24
 */

This is the code I've written for this:

int isGreater(int x, int y) {
/* to find greater, subtract y from x using 2's complement method.
 * then find 2's complement of the answer and shift right by 31 to give MSB
 * which is 1 if x>y and 0 if x<y */
 int ydash=(~y)+0x01;
 int diff=x+ydash;
 int a=(~diff)+0x01;
 int b=a>>31;
 int c=b&0x01;  
 return c;
}

For which I get this error:

ERROR: Test isGreater(-2147483648[0x80000000],2147483647[0x7fffffff]) failed... ...Gives 1[0x1]. Should be 0[0x0]

I'm allowed to use unsigned int, but no other data types. I'm not sure how that'd help though. How do I get around this?

  • negatives are allowed? – saadtaame Jan 25 '15 at 21:55
  • So, the input values are signed or unsigned integers? Are you allowed to use plain int too? (It seems like the answer's "yes", but may as well check.) Given the error message, the inputs seem to be signed. Also, we're dealing with 32-bit values, not 64-bit values? This is the sort of sadistic homework question that drives people not in college bonkers; the answer is trivial when you're allowed to use the comparison operators, and ridiculously hard when you aren't — as you aren't. To your credit, you've clearly stated the constraints up front — thank you for that. – Jonathan Leffler Jan 25 '15 at 21:55
  • 2
    Since you are using signed int in your code, every overflow is undefined behaviour. Whether that's actually impacting your answer is less clear, but in theory, you should avoid overflows when the types are signed. – Jonathan Leffler Jan 25 '15 at 22:00
  • Is't rightshifting negative values UB in C? – CodesInChaos Jan 25 '15 at 22:01
  • Apparently negatives are allowed. Theres a test harness that checks for all possible values of input for each of the functions. This function popped up this error. It IS homework, this here is the code I arrived at before running it through the test harness. Thing is, I've tried everything I can think of and theoretically it works with math when I tried, but this error fits into what I've programmed, because as unsigned, the negative number is greater than the other. Yes, 32-bit values; and it drives people who are IN college bonkers as well :) – stalagmite7 Jan 25 '15 at 22:06
2

Here you may not be allowed use if-else or any of the control statements. But you can "construct" some if-else-like statement.

int isGreater(int x, int y) {        
    int sgnext_x = x >> 31;  //sgnext_x = x >= 0 ? 00000000 : 11111111
    int sgnext_y = y >> 31;
    int sgn_y = sgnext_y & 1;  //sgn_y = y >= 0 ? 0 : 1
    int minus = x + (~y + 1);  // a - b = a + (~b+1)
    int sgn_minus =(minus >> 31) & 1;

    //A control-like statement. ((statement & a) | (!(statement | (b))))
    //Returns a if statment = 11111111
    //Returns (b&1) if statment = 00000000

    int which = sgnext_x ^sgnext_y;
    int result = (!!(x^y)) & ((which & sgn_y) | (!(which | (sgn_minus))));
  return result;
}
| improve this answer | |
2

With x = -2147483648 and y = 2147483647 then x - y = -4,294,967,295 which is outside the range of int, hence the result cannot be represented in the variable and you got undefined behavior.

To get over this you need to use a type wider than int. As you are only allowed to use unsigned int, you'll have to implement big int operations yourself if you want to use a bigger type. You can also use another way like checking the overflow condition separately

if ((x ^ y) & 0x80000000) // x and y have different sign
{
    return (y >> 31) & 1; // return 1 if y is negative
}
else     // x and y have the same sign, overflow never occurs
{
    unsigned int xu = x, yu = y;
    unsigned int xmu = ~xu + 1U;
    unsigned int diffu = yu + xmu;
    return diffu >> 31;
}

If you aren't allowed to use conditionals you can use a muxer to mux the values

unsigned int r1 = (y >> 31) & 1U; // 1st case

unsigned int xu = x, yu = y;
unsigned int xmu = ~xu + 1U;
unsigned int diffu = yu + xmu;
unsigned int r2 = diffu >> 31;    // 2nd case

unsigned int s = ((x ^ y) >> 31) & 1U; // s = 1 if x and y have different sign, 0 otherwise
unsigned int mask = 0xFFFFFFFFU + s;
return (r1 & ~mask) | (r2 & mask);
| improve this answer | |
  • 1
    I am not alowed to use loops or conditionals, so no if statements :( Only bitwise operators mentioned in my code block above, can't use anything else. – stalagmite7 Jan 26 '15 at 6:54
  • @stalagmite7 you could just mux them of course, that doesn't prevent the overflow anymore but that wasn't the problem anyway – harold Jan 26 '15 at 7:19
1

The algorithm you came up with fundamentally doesn't work, since if you subtract, almost all possible answers can be both the result of a subtraction where a < b and of a subtraction where a >= b. So essentially, the result doesn't tell you anything, except when it's zero then you know that a == b.

Hacker's Delight has this answer in chapter 2.11, Comparison Predicates:

x < y: (x & ~y) | ((x ^ ~y) & (x - y))

(verification)

You know how to implement subtraction in terms of addition, and swapping x and y shouldn't be a problem either. The result appears in the sign bit.

| improve this answer | |
  • I like your bot. But why does it return false for many expressions in bit hacks? For example with y ^ ((x ^ y) & -(x < y)) == min(x, y) it returns [false] in 0x7fffffff00000000 cases, for example: [y = -1 (0xffffffff), x = -3 (0xfffffffd)]. Also [true] in 0x8000000100000000 cases, for example: [y = -1 (0xffffffff), x = -1 (0xffffffff)] – phuclv Jan 26 '15 at 12:27
  • @LưuVĩnhPhúc booleans are 0 or -1 there, so you have to remove that minus. Btw you can make abs like let m = x >> 31 in x + m ^ m – harold Jan 26 '15 at 15:16
  • How can you run a test 2^64 times like that? – phuclv Jan 26 '15 at 16:10
  • @LưuVĩnhPhúc I don't, I'm not patient enough for that. I convert the expression to a BDD, that is why it works so well for some things (and, or, xor, addition, comparison) and badly or not at all for other things (shifting by a variable, multiplying two variables) – harold Jan 26 '15 at 16:26

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