N = 616310 = (6×103) + (1×102) + (6×101) + (3×100)
In base 2 (binary) instead of 10's power we represent in 2's power. To convert keep dividing number by two and append remainder to a string. In the end reverse the string.
AND = A.B
OR = A + B
NOT = 1 - A = !A
XOR = A!B + !AB
Moore's Law:
!(A + B) = A!.B!
!(A.B) = A! + B!
XNOR = !XOR = (A + B!).(A! + B)
NOR = !OR = A!.B!
NAND = !AND = A! + B!
If XOR of two numbers/string/any data is 0 then both are same.
If between two number there's a bit difference of exactly one by XOR then it is called Gray Code. It is used in signal detection to check if there's any wrong signal.
| Type | Size (bit) | Range |
|---|---|---|
| Bit | 1 | 0 or 1 |
| Nibble | 4 | 0 to 24-1 |
| Byte | 8 | 0 to 28-1 |
| Word | 16 | 0 to 216-1 |
| Double | 32 | 0 to 232-1 |
| Qword | 64 | 0 to 264-1 |
Gb (Gigabits), GB (Gigabytes), Gib (103 bits), GiB (103 bytes)
Hexadecimals: 0xAABBCCDD
Different colors represent a byte (AA 1 byte). Nibble has 4 bits i.e. 24 so a hexadecimal value which is from 0-15 (10 - A, B, C, D, E, F)
Least Significant Bit (LSB) & Most Significant Bit (MSB): 99 in binary (MSB part)01100011(LSB part) so in MSB 01100011 in LSB 11000110
Endiness (Storing data in memory) : Little Endian (LSB), Big Endian (MSB)
We use LSB
Finding ith bit:
X(1<<4) >> 4
output:
010x00
00010x
000x00
x1's Complement: Toggling every bit ~
2's Complement:
-X = !X + 1
X = !(-X-1)
| Decimal | Binary | Hexadecimal | Decimal | Binary | Hexadecimal |
|---|---|---|---|---|---|
| 0 | 0000 | 0x0 | 0 | 0000 | 0x9 |
| 1 | 0001 | 0x1 | -1 | 1111 | 0xA |
| 2 | 0010 | 0x2 | -2 | 1110 | 0xB |
| 3 | 0011 | 0x3 | -3 | 1101 | 0xC |
| 4 | 0100 | 0x4 | -4 | 1011 | 0xD |
| 5 | 0101 | 0x5 | -5 | 1011 | 0xE |
| 6 | 0110 | 0x6 | -6 | 1010 | 0xF |
| 7 | 0111 | 0x7 | -7 | 1001 | 0x7 |
| 8 | 1000 | 0x8 | -8 | 1000 | 0x8 |
1 in 8th first value means it's a negative number which is not true so range is -8 to 7 only
0000111110110011
// << 3 yields:
0111110110011000
// >> 3 yields:
0000000111110110
// Multiplication
i * 8; // normal
i << 3; // bitwise [8 = 2^3, so use 3]
// Division
i / 16; // normal
i >> 4; // bitwise [16 = 2^4, so use 4]
// Modulus
i % 4; // normal
i & 3; // bitwise [4 = 1 << 2, apply ((1 << 2) - 1), so use 3]
i % 2^i = n & (2^i - 1)
Bitwise shifts << >> shouldn't be used on negative numbers./*
Booth's Multiplication Algo: (01011 x 01011)
01011 x 1 = 01011
010110 x 1 = 010110
0101100 x 0 = 0000000
01011000 x 1 = 01011000
1111001
*/
int mul(int a, int b)
{
int ans = 0;
for (int i = 0 ; i < 32; i++)
{
if (b & 1) ans += a;
b = b>>1;
a = a<<1;
}
return ans;
}