XXIIVV — binary

Binary numbers are a base 2 numeral system.

A binary number is a number expressed in the base-2 numeral system, which uses only two symbols: 0 and 1. Each digit is referred to as a bit. Because of its straightforward implementation in digital electronic circuitry using logic gates, the binary system is used by almost all modern computers and computer-based devices.

Bit: The smallest unit in computers. It is either a 1 or a 0.
Nibble: Half a byte, or 4 bits.
Byte: 8 bits together form one byte, a number from 0 to 255. Bits in a byte are numbered starting from the right at 0.
Short: Two bytes put together are 16 bits, forming a number from 0 to 65535. The low byte is the rightmost eight bits.
Big Endian: Stores data big-end first. When looking at multiple bytes, the first byte (lowest address) is the biggest.
Little Endian: Stores data little-end first. When looking at multiple bytes, the first byte is smallest.

Two of Leibniz's binary calculation examples

Conversion

Break down the binary value in chunks of 4, multiply each 1 by its equivalent value, either 8, 4, 2 or 1. Add the resulting numbers together to get the result. For example, the value 1100, or (8*1 + 4*1), is equal to C(decimal 12).

`1101 0101(D5)`
1	1	0	1	0	1	0	1	Binary
128	64	32	16	8	4	2	1	Values
128	64		16		4		1	Result: 213

Binary Arithmetic

In the first column, divide the first number by 2 by removing the last bit, until 1 is reached. In the second column, multiply by 2 by adding an extra bit of 0. The answer is found by adding the numbers in the second column with odd numbers in the first column. A binary number ending with 1 is odd.

35	19
`100011`	`10011`
`10001`	`100110`
`1000`	`1001100`
`100`	`10011000`
`10`	`100110000`
`1`	`1001100000`
	`1010011001`

This example multiplies 35 by 19, to arrive at a result of 665. The result 1010011001 can be deconstucted as:

10 1001 1001 = 1 + 8 + 16 + 128 + 512 = 665

Binary numbers can be multiplied and divided by multiples of 2, by rotating one bit left to multiply by 2, or one bit right to divide by 2.

22		0	1	0	1	1	0
44	`ROL`	1	0	1	1	0	0
11	`ROR`	0	0	1	0	1	1

AND, or "both", sets individual bits to 0. AND is useful for masking bits, for example, to mask the high order bits of a value AND with $0F: $36 AND $0F = $06. ORA(OR), or "either one or both", sets individual bits to 1. OR is useful for setting a particular bit, for example, $80 OR $08 = $88. EOR(XOR), or "one or the other but not both", inverts individual bits.

input	output	AND	ORA	EOR
0	1	0	1	1
0	0	0	0	0
1	1	1	1	0
1	0	0	1	1

To activate the 1st, 2nd and 4th bits:

unsigned char num = 0;
num |= (1 << 0);
num |= (1 << 1);
num |= (1 << 3);

To deactivate the 1st, 4th and 6th bits:

unsigned char num = 255;
num &= ~(1 << 0);
num &= ~(1 << 3);
num &= ~(1 << 5);

To read value of bit:

(num >> bit) & 1;

If Bit 7 is not set (as in the first example) the representation of signed and unsigned numbers is the same. However, when Bit 7 is set, the number is always negative. For this reason Bit 7 is sometimes called the sign bit.

Binary	Unsigned	Signed
0010 0011	35	35
1010 0011	163	-93
1111 1111	255	-1
1000 0000	128	-128

A fixed-point number is a number that has a fixed number of digits after the decimal point. If, for example, we use 8 bits to store a number with decimal points, we could decide to store it this way. The high and low nibbles have the same resolution.

			Decimal Points
0	0	0	0	0	0	0	0.0
0	1	1	1	0	1	0	3.a
1	0	0	0	1	0	1	4.5

To turn a regular integer into fixed point, shift left by the number of fractional bits(width << bits), and to turn a fixed point into integer, shift right by the number of fractional bits(width >> bits).

To multiply, you do the multiply, and then you shift right by the number of fractional bits.

(3.8 * 2.0) >> 8

To divide, you first shift the numerator left by the number of fractional bits, then you do the division.

(3.8 << 8) / 2.0

Incoming: noton nibble dice ternary assembly vga fractran uxn devlog