# How to compare two numbers to see which is greater

Comparing two numbers x,y; if x>y I return 1, else return 0. I am trying to do this using only bitwise operators such as >> << ~ ! & | ^ +.

So far I got this:

``````int greaterThan(int x,int y) {
return ((~(x-y))>>31);
}
``````

So if x-y is negative, the most significant bit would be a 1. So I negate it to get a 0 and shift it so that it returns a 0. If x-y is positive, the most significant bit would be 0. Negate it to get 1 and shift it to return 1. It doesn't seem to work. Am I doing this wrong or missing something?

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It works fine for me with x and y ints. Specifically, if `x >= y`, the result is non-zero (true). I suggest you post your code. –  Matthew Flaschen Sep 27 '10 at 4:53
It works fine for "typical" ints, for certain definitions of "typical".. :-) –  R.. Sep 27 '10 at 4:58
well that is actually my code, I submit it and it tells me if it is wrong or not. Some of the test that failed are: (0,-3),(2147483644,-954450349). Is it because of overflow? –  Dan Sep 27 '10 at 4:59
@R, yes, I was assuming no overflow, but that apparently wasn't a safe assumption. :) @Dan, I meant all the code, including the declarations and how you check the result. It should work correctly for (0, -3). –  Matthew Flaschen Sep 27 '10 at 5:04
–  ruslik Sep 27 '10 at 5:48

Your method does not work for several reasons:

• Assuming `x` and `y` are signed values, the subtraction could overflow. Not only does this result in undefined behavior according to the C standard, but on typical implementations where overflow wraps, it will give the wrong results. For instance, if `x` is `INT_MIN` and `y` is `1`, `x-y` will yield `INT_MAX`, which does not have its high bit set.

• If `x` and `y` are unsigned values, then `x=UINT_MAX` and `y=0` is an example where you get the wrong answer. You'd have to impose a condition on the values of `x` and `y` (for instance, that neither has its high bit set) in order for this test to work.

What it comes down to is that in order to perform comparisons by testing the "high bit", you need one more bit than the number of bits in the values being compared. In assembly language on reasonably-CISC-ish architectures, the carry flag provides this extra bit, and special conditional jump instructions (as well as carry/borrow instructions) are able to read the value of the carry flag. C provides no way to access such a carry flag, however. One alternate approach might be to use a larger integer type (like `long long`) so that you can get an extra bit in your result. Good compilers will translate this to a read of the carry flag, rather than actually performing larger arithmetic operations.

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i forgot to mention I am working on 2's complement. I'm working with a lot of restriction on this. I can only use ints. If I can check there is a overflow, is there another way to check that the x>y? –  Dan Sep 27 '10 at 5:01
Integer overflow does not result in undefined behaviour. The behaviour of integer over-/underflows is well-defined for each host platform. –  DevSolar Sep 27 '10 at 5:03
@DevSolar, I think R is correct. See CERT and §6.5/5 of C99. Of course, unsigned overflow is guaranteed to wrap. –  Matthew Flaschen Sep 27 '10 at 5:20
"Of course, unsigned overflow is guaranteed to wrap." - since no CPU I know of distinguishes between signed or unsigned integers on the machine-code level, the only thing undefined in this case is the representation / interpretation of negative numbers, which is well-defined by the platform / CPU. I admit this is a corner case, but I feel the statement "this does result in undefined behaviour" is a tad strong here. –  DevSolar Sep 27 '10 at 8:27
It's not overly strong. Sure the machines with non-twos-complement arithmetic are legacy crap, but gcc purposefully exploits the fact that signed overflow is UB to better optimize. Hint: signed overflow being UB means gcc can always assume an additional constraint, which it would otherwise have a hard time proving, that the values used in arithmetic are within a range where overflow would not happen. –  R.. Sep 27 '10 at 12:51

C Standard (1999), chapter 6.5.7 Bitwise shift operators, paragraph 5:

The result of E1 >> E2 is E1 right-shifted E2 bit positions. If E1 has an unsigned type or if E1 has a signed type and a nonnegative value, the value of the result is the integral part of the quotient of E1 / 2E2 . If E1 has a signed type and a negative value, the resulting value is implementation-defined.

I.e., the result for a bit-shift-right on negative numbers is implementation-defined. One possibility is that the "sign bit" gets copied into the bits to the right, which is what GCC seems to do (as it results in all bits set, -1).

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That's correct, but shouldn't cause Dan's incorrect results, since 1 and -1 (in fact all non-zero numbers) have the same truth value in C. The only issue would be if he did something like `if(res == 1)`. –  Matthew Flaschen Sep 27 '10 at 5:22
@Matt, I can't use any if/else statements or ==. Here are some more failed test. Test (1,-2147483648) failed. Test (1,-3) failed. Test (1,-1299006977) failed. Test (1,-2147483647) failed. Test (1,-2) failed. Test (1,-707712875) failed. Test (1,-2147483646) failed. Test (1,-1) failed. –  Dan Sep 27 '10 at 5:47
@Dan, I tried the version with the `greaterThan` function, and it still works fine as long as there's no overflow. So (1,-3), (1,-2), (1,-1) are all -1, which is non-zero (true). What is `greaterThan` returning for you for those pairs? –  Matthew Flaschen Sep 27 '10 at 6:00
Its returning -1 as you said, but I am suppose to return only 0 or 1. So in the case of an overflow, how would I carry it out? –  Dan Sep 27 '10 at 6:22

@Dan, can you please clarify your question in first post, i.e. what exactly you can use and what you can't use (in your comments you mentioned that you can't use `if`/`else` etc.).

Anyway, if you want to get rid of unexpected `-1`, you should consider casting your value to `unsigned int` before shifting. This will not make your solution entirely correct though. Try to think about checking numbers' sign bit (e.g. if first bit of `x` is `0` and first bit of `y` is `1` then you can be sure that x>y).

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