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 (|) flags = LOG_ERRORS | LOG_WARNINGS | LOG_INCOMING; // 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 == if ((flags & LOG_WARNINGS) == LOG_WARNINGS) ... // testing for multiple flags // as above, OR the bitmasks if ((flags & (LOG_INCOMING | LOG_OUTGOING)) == (LOG_INCOMING | LOG_OUTGOING)) ... // 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 == (LOG_INCOMING | LOG_OUTGOING)) ...
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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:
RRRR RGGG GGGB BBBB
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);
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.
rwx --- 110
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.
PERM_READ = 4 PERM_WRITE = 2 PERM_EXEC = 1 user_permissions = 6 if (user_permissions & PERM_READ == TRUE) then // this will be reached, as 6 & 4 is true fi
You need a working understanding of binary representation of numbers and logical operators to understand bit fields.