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What are some real world use cases of the following bitwise operators?

  • AND
  • XOR
  • NOT
  • OR
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9  
Define "real-world". –  Anon. Jan 19 '10 at 20:48
37  
question.flags |= COMMUNITY_WIKI_FLAG –  Laurence Gonsalves Jan 19 '10 at 21:28
1  
bitwise provide great questions on a comp sci test –  Yada Jan 19 '10 at 22:31
1  
@Anon.: In my mind, real world was supposed to mean anything but low level programming which is the most obvious use of bitwise operators. –  Olivier Lalonde Jan 20 '10 at 1:03

41 Answers 41

I was always under the assumption that bitwise operations are fairly simple operations to be performed, so when running time is crucial a solution which is implemented via bitsets can improve running time by a constant amount, algorithm depending.

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Another real world application in the database world is MySQL which has a datatype called SET.

Bitwise operators are by the DBMS to store the SET datatype. Set can save space.

Element    SET Value    Decimal Value
Travel      00000001    1
Sports      00000010    2
Dancing    00000100    4
Fine Dining   00001000  8
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I use them to implement fast BCD calculations (accountants and auditors get upset with fp rounding).

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We use Bitwise Flags to make the session smaller for login permissions on our internal website.

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A very specific example, but I used them to make my sudoku solver run faster (I was having a competition with a friend)

Each column, row and 3x3 was represented as an unsigned integer and as I set numbers I'd flag the appriate bit for the number set in the relevent column,row and 3x3 square.

This then made it very easy to see what possible numbers I could place in a given square since I would OR together the right column,row and 3x3 square and then NOT this to leave me with a mask that represented the possible legal values for a given position.

Hope that makes sense.

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RAID 5/6 !! You are probably using it right now when you interact with this website! Isn't that about as real as it gets!?

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Nobody's mentioned collections yet. Sometimes you have a smallish collection of possible values, say only 10 or 20 possible values, and you want to keep some of them in a set. Sure you can use a regular Set implementation which will most likely use a backing hashtable. But since the set of possible values is so small this is really just a waste of time and space. Instead, you can store the set in a single int or long value which is exactly what the java EnumSet does if I remember correctly.

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When you only want to change some bits of a microcontroller's Outputs, but the register to write to is a byte, you do something like this (pseudocode):

char newOut = OutRegister & 0b00011111 //clear 3 msb's
newOut = newOut | 0b10100000 //write '101' to the 3 msb's
OutRegister = newOut //Update Outputs

Of course, many microcontrollers allow you to change each bit individually...

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If you ever want to calculate your number mod(%) a certain power of 2, you can use yourNumber & 2^N-1, which in this case is the same as yourNumber % 2^N.

number % 16 = number & 15;
number % 128 = number & 127;

This is probably only useful being an alternative to modulus operation with a very big dividend that is 2^N... But even then its speed boost over the modulus operation is negligible in my test on .NET 2.0. I suspect modern compilers already perform optimizations like this. Anyone know more about this?

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A common use is for alignment e.g I need my data aligned on 4-byte or 16-byte boundaries.This is very common with RISC processors where an unaligned load/store is either expensive ( because it triggers an exception handler that then needs to fix up the non-aligned load ) or not allowed at all.

For any alignment that is a power of 2, the next aligned pos can be calculated as follows :

aligned_offset = alignment + ((current_offset - 1) & ~(alignment - 1))

So in the case of 4 byte alignment and a current offset of 9 then :

aligned_offset = 4 + ((9-1) & ~(4-1)) = 4 + (8 & 0xFFFFFFFC) = 4+ 8  = 12  

so the next 4 byte aligned offset would be 12

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Tower Of Hanoi linear solution uses bit wise operations to solve the problem.

public static void linear(char start,char temp,char end,int discs)
{
    int from,to;
    for (int i = 1; i < (1 << discs); i++) {
        from = (i&i-1)%3;
        to = ((i|i-1)+1)%3;
        System.out.println(from+" => "+to);
    }
}

The Explanation for this solution can be found here

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protected by Baba May 8 '13 at 16:58

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