_BIT - QB64Official/qb64 GitHub Wiki
The _BIT datatype can return only values of 0 (bit off) and -1 (bit on).
_DEFINE Letter[-Range|,...] AS [_UNSIGNED] _BIT [* numberofbits]
- An _UNSIGNED _BIT can hold 0 or 1 instead of 0 and -1, if you set the numberofbits you can hold larger values depending on the number of bits you have set (_BIT * 8 can hold the same values as _BYTE for example) and the information below is compromised if setting any number of bits other than 1.
- If you set the variable to any other number then the least significant bit of that number will be set as the variables number, if the bit is 1 (on) then the variable will be -1 and if the bit is 0 (off) then the variable will be 0.
- The least significant bit is the last bit on a string of bits (11111) since that bit will only add 1 to the value if set. The most significant bit is the first bit on a string of bits and changes the value more dramatically (significantly) if set on or off.
- The _BIT datatype can be succesfully used as a Boolean (TRUE or FALSE) and it requires minimal amount of memory (the lowest amount possible actually, one byte can hold 8 bits, if you want to use bits in order to decrease memory usage, use them as arrays as a _BIT variable by itself allocates 4 bytes - DIM bitarray(800) AS _BIT uses 100 bytes).
- When a variable has not been assigned or has no type suffix, the value defaults to SINGLE.
- Keywords_currently_not_supported_by_QB64 Use a _BYTE and assign up to 8 bit values as shown below.
Use a _BYTE and assign up to 8 bit values as shown below.
*Suffix Symbols The _BIT type suffix used is below the grave accent (`), usually located under the tilde (~) key (not an apostrophe). Foreign keyboards may not have the ` key. Try Alt+96 in the IDE.
You can define a bit on-the-fly by adding a ` after the variable, like this:
variable\= -1`
If you want an unsigned bit you can define it on-the-fly by adding ~` instead, like this:
variable~\= 1`
You can set the number of bits on the fly by just adding that number - this defines it as being two bits:
variable\2 = -1`
-
The MSB is the most significant(largest) bit value and LSB is the least significant bit of a binary or register memory address value. The order in which the bits are read determines the binary or decimal byte value. There are two common ways to read a byte:
- "Big-endian": MSB is the first bit encountered, decreasing to the LSB as the last bit by position, memory address or time.
- "Little-endian": LSB is the first bit encountered, increasing to the MSB as the last bit by position, memory address or time.
**Offset or Position: 0 1 2 3 4 5 6 7 Example: 11110000**
---------------------------------- --------
**Big-Endian Bit On Value:** 128 64 32 16 8 4 2 1 240
**Little-Endian Bit On Value:** 1 2 4 8 16 32 64 128 15
The big-endian method compares exponents of 27 down to 20 while the little-endian method does the opposite.
- INTEGER values consist of 2 bytes called the HI and LO bytes. Anytime that the number of binary digits is a multiple of 16 (2bytes, 4 bytes, etc.) and the HI byte's MSB is on(1), the value returned will be negative. Even with SINGLE or DOUBLE values!
**16 BIT INTEGER OR REGISTER**
**AH (High Byte Bits) AL (Low Byte Bits)**
BIT: 15 14 13 12 11 10 9 8 | 7 6 5 4 3 2 1 0
---------------------------------------|--------------------------------------
HEX: 8000 4000 2000 1000 800 400 200 100 | 80 40 20 10 8 4 2 1
|
DEC: -32768 16384 8192 4096 2048 1024 512 256 | 128 64 32 16 8 4 2 1
The HI byte's MSB is often called the sign bit! When all 16 of the integer binary bits are on, the decimal return is -1.
Shifting bits in a value in QB64 versions prior to 1.3 (you can use _SHL and _SHR starting with version 1.3).
n = 24
Shift = 3
PRINT LShift(n, Shift)
PRINT RShift(n, Shift)
END
FUNCTION LShift&(n AS LONG, LS AS LONG)
IF LS < 0 THEN EXIT FUNCTION
LShift = INT(n * (2 ^ LS))
END FUNCTION
FUNCTION RShift&(n AS LONG, RS AS LONG)
IF RS < 0 THEN EXIT FUNCTION
RShift = INT(n / (2 ^ RS))
END FUNCTION
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