# How to compute the integer absolute value

How to compute the integer absolute value without using if condition. I guess we need to use some bitwise operation. Can anybody help?

• Is the ternary operator allowed ? – cnicutar Aug 20 '12 at 16:42
• No, I guess you cannot use that too. – Pragyan Aug 20 '12 at 16:43
• What's the motivation? Performance? Are you trying to solve a branch-predication failure by eliminating the branch? Intellectual curiosity? Homework? Something else? – Adrian McCarthy Aug 20 '12 at 17:04
• What is the proper answer for ABS(INT_MIN)? (use 8-bits for simplicity): ABS(-128) ideally should be 128. But the maximum signed 8-bit int is only 127! – abelenky Sep 4 '14 at 15:18

1) Set the mask as right shift of integer by 31 (assuming integers are stored as two's-complement 32-bit values and that the right-shift operator does sign extension).

`````` mask = n>>31
``````

2) XOR the mask with number

``````mask ^ n
``````

3) Subtract mask from result of step 2 and return the result.

``````(mask^n) - mask
``````
• graphics.stanford.edu/~seander/bithacks.html is this patented? – Quonux Oct 20 '13 at 16:32
• Keep in mind that not all languages intepret integer the same way. There are some that support positive and negative zero where `abs(~int)-abs(int)` results in `0` while your solution requires: `abs(abs(~int)-abs(int))` beeing 1. – dhein Sep 22 '15 at 13:19

Same as existing answers, but with more explanations:

Let's assume a twos-complement number (as it's the usual case and you don't say otherwise) and let's assume 32-bit:

First, we perform an arithmetic right-shift by 31 bits. This shifts in all `1`s for a negative number or all `0`s for a positive one (but note that the actual `>>`-operator's behaviour in C or C++ is implementation defined for negative numbers, but will usually also perform an arithmetic shift, but let's just assume pseudocode or actual hardware instructions, since it sounds like homework anyway):

``````mask = x >> 31;
``````

So what we get is `111...111` (-1) for negative numbers and `000...000` (0) for positives

Now we XOR this with `x`, getting the behaviour of a NOT for `mask=111...111` (negative) and a no-op for `mask=000...000` (positive):

``````x = x XOR mask;
``````

And finally subtract our mask, which means +1 for negatives and +0/no-op for positives:

``````x = x - mask;
``````

So for positives we perform an XOR with 0 and a subtraction of 0 and thus get the same number. And for negatives, we got `(NOT x) + 1`, which is exactly `-x` when using twos-complement representation.

• Upvote for the clear explanation, much better than the accepted answer! – Chuntao Lu Aug 30 '14 at 14:18
• In C or C++, can't this result in undefined behavior? If x is INT_MIN, then the XOR operation will make x == INT_MAX, and adding 1 to INT_MAX is an overflow error (aka undefined behavior for signed integers) – Joshua Wise May 31 '17 at 20:20
• @JoshuaWise Well, I didn't assume a specific programming language, though. In that case, the signed right-shift would already be implementation-defined behaviour. – Christian Rau Jul 26 '17 at 15:37

Assume `int` is of 32-bit.

``````int my_abs(int x)
{
int y = (x >> 31);
return (x ^ y) - y;
}
``````

One can also perform the above operation as:

``````return n*(((n>0)<<1)-1);
``````

where `n` is the number whose absolute need to be calculated.

I wrote my own, before discovering this question.

My answer is probably slower, but still valid:

``````int abs_of_x = ((x*(x >> 31)) | ((~x + 1) * ((~x + 1) >> 31)));
``````

In C, you can use unions to perform bit manipulations on doubles. The following will work in C and can be used for both integers, floats, and doubles.

``````/**
* Calculates the absolute value of a double.
* @param x An 8-byte floating-point double
* @return A positive double
* @note Uses bit manipulation and does not care about NaNs
*/
double abs(double x)
{
union{
uint64_t bits;
double dub;
} b;

b.dub = x;

//Sets the sign bit to 0
b.bits &= 0x7FFFFFFFFFFFFFFF;

return b.dub;
}
``````

Note that this assumes that doubles are 8 bytes.

What is the programming language you're using? In C# you can use the Math.Abs methos:

``````int value1 = -1000;
int value2 = 20;
int abs1 = Math.Abs(value1);
int abs2 = Math.Abs(value2);
``````
• Well, I'm pretty sure that's also outruled by the question. Of course using a prebuilt functions is always easiest ;) – Christian Rau Aug 20 '12 at 16:51
• I can see that now. Worth trying to help though. Good thing he got his answer. – Florin Bombeanu Aug 20 '12 at 17:42
• Always worth mentioning the obvious. Sometimes I find that the bitmask or branchless hacks that are supposed to be faster are really slower. All depends on the processor and the compiler. – Paul Chernoch Oct 21 '13 at 15:00

For assembly the most efficient would be to initialize a value to 0, substract the integer, and then take the max:

``````pxor mm1, mm1 ; set mm1 to all zeros
psubw mm1, mm0 ; make each mm1 word contain the negative of each mm0 word
pmaxswmm1, mm0 ; mm1 will contain only the positive (larger) values - the absolute value
``````
• SSSE3 (Core2 and newer) directly has `pabsw` – harold Jan 25 '18 at 17:00
• yes indeed but question was tagged 'algorithm' so I assumed the author didn't want a library function or instruction that does the job automatically ;) – Antonin GAVREL Jan 25 '18 at 17:22

In C#, you can implement abs() without using any local variables:

``````public static long abs(long d) => (d + (d >>= 63)) ^ d;

public static int abs(int d) => (d + (d >>= 63)) ^ d;
``````

Note: regarding `0x80000000 (int.MinValue)` and `0x8000000000000000 (long.MinValue)`:

As with all of the other bitwise/non-branching methods shown on this page, this gives the single non-mathematical result `abs(int.MinValue) == int.MinValue` (likewise for `long.MinValue`). These represent the only cases where result value is negative, that is, where the MSB of the two's-complement result is `1`--and are also the only cases where the input value is returned unchanged. I don't believe this important point was mentioned elsewhere on this page.

The code shown above depends on the value of `d` used on the right side of the xor being the value of `d` updated during the computation of left side. To C# programmers this will seem obvious. They are used to seeing code like this because .NET formally incorporates a strong memory model which strictly guarantees the correct fetching sequence here. The reason I mention this is because in `C` or `C++` one may need to be more cautious. The memory models of the latter are considerably more permissive, which may allow certain compiler optimizations to issue out-of-order fetches. Obviously, in such a regime, fetch-order sensitivity would represent a correctness hazard.

If you are not allowed to use the minus sign you could do something like this:

``````int absVal(int x) {
return ((x >> 31) + x) ^ (x >> 31);
}
``````