How do i use it in C++ ? when is it useful to use ?
Please give me an example of a problem where bitmask is used , how it actually works . Thanks!


Briefly bitmask helps to manipulate position of multiple values. There is a good example here ;

Bitflags are a method of storing multiple values, which are not mutually exclusive, in one variable. You've probably seen them before. Each flag is a bit position which can be set on or off. You then have a bunch of bitmasks #defined for each bit position so you can easily manipulate it:

    #define LOG_ERRORS            1  // 2^0, bit 0
    #define LOG_WARNINGS          2  // 2^1, bit 1
    #define LOG_NOTICES           4  // 2^2, bit 2
    #define LOG_INCOMING          8  // 2^3, bit 3
    #define LOG_OUTGOING         16  // 2^4, bit 4
    #define LOG_LOOPBACK         32  // and so on...

// Only 6 flags/bits used, so a char is fine
unsigned char flags;

// initialising the flags
// note that assigning a value will clobber any other flags, so you
// should generally only use the = operator when initialising vars.
flags = LOG_ERRORS;
// sets to 1 i.e. bit 0

//initialising to multiple values with OR (|)
// sets to 1 + 2 + 8 i.e. bits 0, 1 and 3

// setting one flag on, leaving the rest untouched
// OR bitmask with the current value
flags |= LOG_INCOMING;

// testing for a flag
// AND with the bitmask before testing with ==

// testing for multiple flags
// as above, OR the bitmasks

// removing a flag, leaving the rest untouched
// AND with the inverse (NOT) of the bitmask
flags &= ~LOG_OUTGOING;

// toggling a flag, leaving the rest untouched
flags ^= LOG_LOOPBACK;


WARNING: DO NOT use the equality operator (i.e. bitflags == bitmask) for testing if a flag is set - that expression will only be true if that flag is set and all others are unset. To test for a single flag you need to use & and == :


if (flags == LOG_WARNINGS) //DON'T DO THIS
if ((flags & LOG_WARNINGS) == LOG_WARNINGS) // The right way
if ((flags & (LOG_INCOMING | LOG_OUTGOING)) // Test for multiple flags set

You can also search C++ Triks

  • in your example about bitflags, how does it know which bit belongs to which variable? it's position in the byte, or the actual value of the byte turns on and off certain features?
    – MarcusJ
    Jun 1 '15 at 19:38

Bit masking is "useful" to use when you want to store (and subsequently extract) different data within a single data value.

An example application I've used before is imagine you were storing colour RGB values in a 16 bit value. So something that looks like this:


You could then use bit masking to retrieve the colour components as follows:

  const unsigned short redMask   = 0xF800;
  const unsigned short greenMask = 0x07E0;
  const unsigned short blueMask  = 0x001F;

  unsigned short lightGray = 0x7BEF;

  unsigned short redComponent   = (lightGray & redMask) >> 11;
  unsigned short greenComponent = (lightGray & greenMask) >> 5;
  unsigned short blueComponent =  (lightGray & blueMask);
  • 1
    I don't understand this, you're saying 0xF800 is basically a group of bits that it's selecting from (aka it's extracting those bits from a set group of bytes by address)? I thought a bitmask was basically a int of the same size as the data (so in this case it would be 48 bits) and the mask was applied overtop, when the values of the mask is 1 the value of the underlying bit shows through, and when it's zero, it doesn't, allowing you to ignore the off bits? and what is the shifting for?
    – MarcusJ
    Jun 1 '15 at 19:36
  • @MarcusJ: please refer to the example by goGud below, which provides more detail on bitmasks (i.e. stackoverflow.com/questions/18591924/how-to-use-bitmask/…)
    – a505999
    Feb 16 '16 at 18:41
  • I'm an idiot. I knew what bitmasking was, but I didn't realize that the RGB triple wasn't 8 bits each, causing my confusion. thanks for the help though! :)
    – MarcusJ
    Feb 17 '16 at 8:36
  • @MarcusJ: RGB triple can be 8 bit for each channel and normally is. However there are some RGB formats where the channels can be less than 8 bits such as 5, 6, 5 so that RGB can be fitted into 16 bits. Aug 21 '17 at 5:46

Let's say I have 32-bit ARGB value with 8-bits per channel. I want to replace the alpha component with another alpha value, such as 0x45

unsigned long alpha = 0x45
unsigned long pixel = 0x12345678;
pixel = ((pixel & 0x00FFFFFF) | (alpha << 24));

The mask turns the top 8 bits to 0, where the old alpha value was. The alpha value is shifted up to the final bit positions it will take, then it is OR-ed into the masked pixel value. The final result is 0x45345678 which is stored into pixel.


Bitmasks are used when you want to encode multiple layers of information in a single number.

So (assuming unix file permissions) if you want to store 3 levels of access restriction (read, write, execute) you could check for each level by checking the corresponding bit.


110 in base 2 translates to 6 in base 10.

So you can easily check if someone is allowed to e.g. read the file by and'ing the permission field with the wanted permission.



user_permissions = 6

if (user_permissions & PERM_READ == TRUE) then
  // this will be reached, as 6 & 4 is true

You need a working understanding of binary representation of numbers and logical operators to understand bit fields.

  • 1
    Why is 6 & 4 true though? what mathematical operation is actually happening here?
    – MarcusJ
    Jun 1 '15 at 19:56
  • 1
    A binary number is either 0 or 1. 4 is 100, 6 is 110. To and the numbers, and each binary digit. Jun 17 '17 at 6:39
  • @LaurieStearn bitwise AND of 100 & 110 is = 100 why is 100 TRUE? Jan 30 at 20:01
  • 1
    @A-Sharabiani: Depends on how it is evaluated. 000 is commonly evaluated as FALSE. If any of the 0 values switch on to 1 then it commonly evaluates as TRUE. Jan 31 at 2:22

Your Answer

By clicking “Post Your Answer”, you agree to our terms of service, privacy policy and cookie policy

Not the answer you're looking for? Browse other questions tagged or ask your own question.