# What USEFUL bitwise operator code tricks should a developer know about?

I must say I have never had cause to use bitwise operators, but I am sure there are some operations that I have performed that would have been more efficiently done with them. How have "shifting" and "OR-ing" helped you solve a problem more efficiently?

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See the famous Bit Twiddling Hacks
Most of the multiply/divide ones are unnecessary - the compiler will do that automatically and you will just confuse people.

But there are a bunch of, 'check/set/toggle bit N' type hacks that are very useful if you work with hardware or communications protocols.

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• Bitwise operations on integers(int)

Get the maximum integer

``````int maxInt = ~(1 << 31);
int maxInt = (1 << 31) - 1;
int maxInt = (1 << -1) - 1;
``````

Get the minimum integer

``````int minInt = 1 << 31;
int minInt = 1 << -1;
``````

Get the maximum long

``````long maxLong = ((long)1 << 127) - 1;
``````

Multiplied by 2

``````n << 1; // n*2
``````

Divided by 2

``````n >> 1; // n/2
``````

Multiplied by the m-th power of 2

``````n << m;
``````

Divided by the m-th power of 2

``````n >> m;
``````

Check odd number

``````(n & 1) == 1;
``````

Exchange two values

``````a ^= b;
b ^= a;
a ^= b;
``````

Get absolute value

``````(n ^ (n >> 31)) - (n >> 31);
``````

Get the max of two values

``````b & ((a-b) >> 31) | a & (~(a-b) >> 31);
``````

Get the min of two values

``````a & ((a-b) >> 31) | b & (~(a-b) >> 31);
``````

Check whether both have the same sign

``````(x ^ y) >= 0;
``````

Calculate 2^n

``````2 << (n-1);
``````

Whether is factorial of 2

``````n > 0 ? (n & (n - 1)) == 0 : false;
``````

Modulo 2^n against m

``````m & (n - 1);
``````

Get the average

``````(x + y) >> 1;
((x ^ y) >> 1) + (x & y);
``````

Get the m-th bit of n (from low to high)

``````(n >> (m-1)) & 1;
``````

Set the m-th bit of n to 0 (from low to high)

``````n & ~(1 << (m-1));
``````

n + 1

``````-~n
``````

n - 1

``````~-n
``````

Get the contrast number

``````~n + 1;
(n ^ -1) + 1;
``````

if (x==a) x=b; if (x==b) x=a;

``````x = a ^ b ^ x;
``````
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Check out this links. It's for actionscript but bitwise operators are pretty much the same as in other languages: bitwise gems fast integer math

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## Using bitwise operations on strings (characters)

Convert letter to lowercase:

• `OR` by space => `(x | ' ')`
• Result is always lowercase even if letter is already lowercase
• eg. `('a' | ' ') => 'a'` ; `('A' | ' ') => 'a'`

Convert letter to uppercase:

• `AND` by underline => `(x & '_')`
• Result is always uppercase even if letter is already uppercase
• eg. `('a' & '_') => 'A'` ; `('A' & '_') => 'A'`

Invert letter's case:

• `XOR` by space => `(x ^ ' ')`
• eg. `('a' ^ ' ') => 'A'` ; `('A' ^ ' ') => 'a'`

Letter's position in alphabet:

• `AND` by `chr(31)`/`binary('11111')`/(`hex('1F')` => `(x & "\x1F")`
• Result is in 1..26 range, letter case is not important
• eg. `('a' & "\x1F") => 1` ; `('B' & "\x1F") => 2`

Get letter's position in alphabet (for Uppercase letters only):

• `AND` by `?` => `(x & '?')` or `XOR` by `@` => `(x ^ '@')`
• eg. `('C' & '?') => 3` ; `('Z' ^ '@') => 26`

Get letter's position in alphabet (for lowercase letters only):

• `XOR` by backtick/`chr(96)`/`binary('1100000')`/`hex('60')` => `(x ^ '`')`
• eg. `('d' ^ '`') => 4` ; `('x' ^ '`') => 25`

Note: using anything other than the english letters will produce garbage results

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How did you know i would be interested .... :) –  Baba Apr 23 '13 at 18:41
@Ka: Does this works in javascript too? I tried these in `firebug's console` but I always got `0`. –  Razort4x May 6 '13 at 7:01
@Razort4x it works in JS via fromCharCode and charCodeAt. eg. `String.fromCharCode("a".charCodeAt(0) & 95);` –  CSᵠ May 7 '13 at 10:13

Matters Computational: Ideas, Algorithms, Source Code, by Jorg Arndt (PDF). This book contains tons of stuff, I found it via a link at http://www.hackersdelight.org/

Average without overflow

A routine for the computation of the average (x + y)/2 of two arguments x and y is

``````static inline ulong average(ulong x, ulong y)
// Return floor( (x+y)/2 )
// Use: x+y == ((x&y)<<1) + (x^y)
// that is: sum == carries + sum_without_carries
{
return (x & y) + ((x ^ y) >> 1);
}
``````
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There's only three that I've ever used with any frequency:

1. Set a bit: a |= 1 << bit;

2. Clear a bit: a &= ~(1 << bit);

3. Test that a bit is set: a & (1 << bit);

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I wanted a function to round numbers to the next highest power of two, so I visited the Bit Twiddling website that's been brought up several times and came up with this:

``````i--;
i |= i >> 1;
i |= i >> 2;
i |= i >> 4;
i |= i >> 8;
i |= i >> 16;
i++;
``````

I use it on a `size_t` type. It probably won't play well on signed types. If you're worried about portability to platforms with different sized types, sprinkle your code with `#if SIZE_MAX >= (number)` directives in appropriate places.

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Counting set bits, finding lowest/highest set bit, finding nth-from-top/bottom set bit and others can be useful, and it's worth looking at the bit-twiddling hacks site.

That said, this kind of thing isn't day-to-day important. Useful to have a library, but even then the most common uses are indirect (e.g. using a bitset container). Also, ideally, these would be standard library functions - a lot of them are better handled using specialise CPU instructions on some platforms.

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I used bitwise operators to efficiently implement distance calculations for bitstrings. In my application bitstrings were used to represent positions in a discretised space (an octree, if you're interested, encoded with Morton ordering). The distance calculations were needed to know whether points on the grid fell within a particular radius.

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You can compress data, e.g. a collection of integers:

• See which integer values appear more frequently in the collection
• Use short bit-sequences to represent the values which appear more frequently (and longer bit-sequences to represent the values which appear less frequently)
• Concatenate the bits-sequences: so for example, the first 3 bits in the resulting bit stream might represent one integer, then the next 9 bits another integer, etc.
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While multiplying/dividing by shifting seems nifty, the only thing I needed once in a while was compressing booleans into bits. For that you need bitwise AND/OR, and probably bit shifting/inversion.

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I have not read the book (yet), but I have been told that the Book Hacker's Delight shows a number of tricks in working with bits.

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1) Divide/Multiply by a power of 2

`foo >>= x;` (divide by power of 2)

`foo <<= x;` (multiply by power of 2)

2) Swap

``````x ^= y;
y = x ^ y;
x ^= y;
``````
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It'd be interesting to see benchmarks demonstrating whether those are actually faster than the normal way on modern compilers. –  sepp2k Oct 7 '09 at 18:04
I'd be pretty confident the shift is faster. The swap is more about not needing additional memory than being faster. –  Taylor Leese Oct 7 '09 at 18:16
@Taylor: Most modern compilers will use a shift when it's the fastest way, without you having to manually code it. –  Ken White Oct 7 '09 at 18:33