I have an int m and an unsigned int j and want to determine whether they are both even or both odd.

In the past I've been using


to catch the case that only one is odd. But I'm concerned about the casting to int incorrectly changing the odd-even-ness of j.

Do either of these run into problems?


I know that


doesn't work because 'm%2' will produce -1 when m is negative, which will always evaluate to true no matter what the value of j%2 is.

  • 2
    why not use an abs(), if you dont have large inputs?
    – monster
    Jul 20, 2017 at 18:41
  • @IgnacioVazquez-Abrams Because && doesn't have the right behavior. I'm in effect trying to create a logical XOR which is exactly what the != does. Jul 21, 2017 at 3:21
  • 2
    FYI, the formal term for "odd-even-ness" is "parity" (not to be confused with parity bits).
    – jwodder
    Jul 21, 2017 at 12:53
  • 1
    @jwodder: That wikipedia article has two conflicting definitions for parity unfortunately. The LSB of a 1's complement negative number will be 0, not 1, if the number is odd.
    – Ben Voigt
    Jul 21, 2017 at 14:37
  • 1
    @jwodder That's specifically why I didn't say parity. Jul 21, 2017 at 19:13

6 Answers 6


Don't use %. This is a problem that calls for bitmasks:

bool same_parity = (i & 0x1) == (j & 0x1);

This works regardless of the sign of i, since the result of that expression will always be 0 or 1.

  • 22
    Is & defined in terms of unsigned integer "bits" or actual bits? In a 1s complement system -1's low order bit is actually 0. 1s compliment systems are pretty obscure, so I don't know off the top of my head how & is defined there. Jul 20, 2017 at 18:46
  • 26
    @Yakk Actual bits. I guess this would only work for 2s complement, but I've never worked on a 1s complement system before so I just pretend they don't exist.
    – Barry
    Jul 20, 2017 at 18:50
  • 9
    @JohnathanGross You explained the issue with % yourself in the question - it doesn't have the semantics you want. You want an f such that f(x) gives you 0 or 1, but (%2) doesn't give you 0 or 1... it gives you 0 or +/- 1.
    – Barry
    Jul 20, 2017 at 21:41
  • 4
    @Yakk I've thrown in a static_assert so the compiler catches in any system not using 2's complement. My computer uses 2's complement and I doubt this code will ever be used anywhere else. Jul 21, 2017 at 3:19
  • 3
    @JohnathanGross: Or you could use & 1u, or SolutionMill's variant, and then the code will also work for 1's complement.
    – Ben Voigt
    Jul 21, 2017 at 14:45
if (1 & (i ^ j))
// Getting here if i is even and j is odd
// or if i is odd and j is even

^ is the exclusive-or bitwise operator, which checks each bit in both numbers if they have the same value. For example, if the binary representation of i is 0101 and j is 1100, then i ^ j will evaluate to 1001, since their first and last bits are different, while the middle bits are the same.

& is the and bitwise operator, which checks each bit in both numbers if they are both 1.

Since just the last bit of each number determines if it's even or odd, i ^ j will evaluate to ...xxx0 if they are both even or odd, and ...xxx1 otherwise (the xs don't matter, we aren't looking at them anyway). Since 1 is actually ...0001, 1 & (i ^ j) evaluates to 0 if i and j are both even or odd, and 1 otherwise.

This works on any combination of unsigned numbers, 2s-complement, and sign-and-magnitude, but not the rare 1s-complement if exactly one is negative.

  • 1
    Ah, you beat me by seconds... This one generates shortest x86 assembly. Jul 20, 2017 at 20:31
  • 2
    That is the simplest, most effective way. Jul 20, 2017 at 21:09
  • 6
    The assertion that this doesn't work on 1s-complement systems is (probably) incorrect. The operation i ^ j is defined in the C++ standard to perform "[t]he usual arithmetic conversions" before the bitwise XOR is performed (in the N3337 draft, see p.117 S5.12). Unless the signed type is capable of representing all possible values of the unsigned type, this means the signed value will be converted to the unsigned type (p.84, S5 paragraph 9). The rules for converting a signed number to unsigned (p.80, S4.7 paragraph 2) require the result to be "congruent to the source integer (modulo 2^n ...
    – Jules
    Jul 21, 2017 at 9:28
  • 5
    ... where n is the number of bits used to represent the unsigned type)". This congruence relationship will preserve the parity of the values, and hence give the correct result. The same cannot be said, however, if both values are stored in a signed type, as demonstrated by @CoDEmanX above.
    – Jules
    Jul 21, 2017 at 9:32
  • 2
    @MaximEgorushkin You can convert it to unsigned though and overflow is not an issue.
    – Random832
    Jul 21, 2017 at 13:28

Adding two integers adds their parity, so the solution is simply:

if ( (j + m) % 2 )

Unsigned wraparound does not disturb this property, since it's done modulo UINT_MAX+1 which is an even number.

This solution does not depend on any implementatation-specific details such as negative number representation.

Footnote: I'm struggling to see why so many other answers are determined to complicate the issue with bit-shifts, bit-complements, XORs, etc. etc. Unfortunately, IMO, it is sometimes glorified in the C or C++ communities to write tricky code instead of simple code.

  • This code relies on the 'usual arithmetic conversions' to do the right thing, and so whether this is valid, and whether it will stay valid if the types change slightly, won't be as obvious to everyone as it is for some of the other answers.
    – JeremyR
    Jul 21, 2017 at 7:23
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    @JeremyR You can use Yakk's suggestion of explicltly casting if you would find that more readable. Every code relies on the rules of the language though!
    – M.M
    Jul 21, 2017 at 9:29
  • 2
    This produces asm for x86 (godbolt.org/g/BC6EFh) that's at least as good as other options, and better in some cases (especially any time both j and m are needed later), because it can use lea as a non-destructive add. It should be about equal on other ISAs like ARM or MIPS. Using + is only obvious once you point it out. Fun fact: compilers (other than ICC) can transform between 1 & (i ^ j) and (i & 0x1) != (j & 0x1), but not from either of those to this. Jul 22, 2017 at 7:15
  • (j + m + 1) % 2 gives you the opposite condition, and can still be computed with one x86 lea eax, [rsi+rdi+1] instruction. (plus and eax,1 or a test/jcc or whatever). The other answers end up with a not instruction when actually creating a bool in a register instead of branching on it. Jul 22, 2017 at 7:24
  • Gotta disagree with the self-aggrandizing footnote here. There is nothing complicated about masking the last bit to check for parity, with the benefit that it works for any inputs. (j+m)%2 is undefined if both are signed integer types whose sum overflows.
    – Barry
    Jul 22, 2017 at 16:54

Casting an unsigned int that is larger than INT_MAX to int is not guaranteed to return a sensible value. The result is undefined.

Casting an int to an unsigned int always results in defined behavior -- it does math mod 2^k for some k large enough that every positive int is less than 2^k.


should be




is the easiest way to see if both have the same parity. Moving to unsigned aka mod 2^k is going to keep parity, and in unsigned %2 returns parity correctly (and not negative parity).

  • 1
    As long as the result is correctly expressed, a good compiler should probably generate optimal code regardless of what you write, and readability is a matter of taste (I would not redundantly parenthesis arguments of ==, for instance, but I would write ...%2!=0 rather than rely on implicit conversion to bool). However I think a solution with just one % is preferable, like your first one. Also note that one can just write if ((j+m)%2!=0), as the signed m gets converted to the unsigned type of the other operand j automatically, but an explicit cast does make this more explicit. Jul 21, 2017 at 4:49
  • 1
    The result of the cast you describe in your first paragraph is implementation-defined, not undefined. (In both C and C++)
    – M.M
    Jul 21, 2017 at 5:39
  • You probably want to take a look at std::make_unsigned for maximum generality. Jul 21, 2017 at 8:41

Don't be too smart

Do either of these run into problems?


One problem I see is readability. It might not be obvious to someone else (or your future self) what it is supposed to do or what it actually does.

You could be more expressive by spending some extra lines:

#include <cmath>

const bool fooIsEven = foo % 2 == 0;
const bool barIsEven = std::abs(bar) % 2 == 0;
if (fooIsEven == barIsEven)
  // ...

Also consider implementing a properly named function that provides a comparison of the parity of two given integral types. This not only cleans your code up but also prevents you from repeating yourself.

Edit: Replaced cast by call to std::abs

  • 1
    What is std::abs(INT_MIN) ? The advantage of the cast is that it actually works.
    – Ben Voigt
    Jul 20, 2017 at 20:03
  • @Ben Voigt - Good point. Thanks for pointing it out. According to cppreference.com: "In 2's complement systems, the absolute value of the most-negative value is out of range, e.g. for 32-bit 2's complement type int, INT_MIN is -2147483648, but the would-be result 2147483648 is greater than INT_MAX, which is 2147483647."
    – plats1
    Jul 20, 2017 at 20:08
  • 1
    This is one those cases where % generates horrible code for signed integers because the sign is preserved in the result: godbolt.org/g/YSSARf Jul 20, 2017 at 20:29
  • 1
    @MaximEgorushkin I'm sorry, overflow of a signed integer does not guarantee the sign is preserved, unless you specify the compiler and provide the guarantees it gives; the result is in general undefined behavior. Jul 20, 2017 at 21:49
  • 1
    Why do you need std::abs(bar) in order to mod? If you're checking against 0, the original sign of bar shouldn't matter, should it?
    – Brian J
    Jul 21, 2017 at 15:19

This can be simplified:



if ((abs(m) % 2) != (j % 2))

be sure to include the math.h

#include <math.h>

Absolute value will take away the sign bit which is the left-most bit in storage.

Converting signed to unsigned is okay, and is defined in C99.

Found this resource.

Bitwise operators also should work with a C99 compiler, and the signed having a lesser max value is converted to greater (signed to unsigned).

  • 1
    The C++ way is to use the <cmath> (or <cstdlib> in this case) library instead of <math.h>.
    – plats1
    Jul 20, 2017 at 19:53
  • 1
    abs(int) returns an int. negative ints which do not have a positive representation are permitted. Overflow of an int is undefined behavior. Can you document that abs(int) on INT_MIN is defined behavior and produces the result we want? Jul 20, 2017 at 21:50
  • Since this is a C++ answer, do not include only <math.h>. You will get only the double abs(double) overload of abs. Anyway, since it turns out there are better answers that are portably safe, abs is a bad solution for this problem (for performance reasons if nothing else). Jul 22, 2017 at 6:25

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