Think in decimal for a second. If you have only 2 digits for a number, that means you can store from `00`

to `99`

in them. If you have 4 digits, that range becomes `0000`

to `9999`

.

A binary number is similar to decimal, except the digits can be only `0`

and `1`

, instead of `0`

, `1`

, `2`

, `3`

, ..., `9`

.

If you have a number like this:

```
01011101
```

This is:

```
0*128 + 1*64 + 0*32 + 1*16 + 1*8 + 1*4 + 0*2 + 1*1 = 93
```

So as you can see, you can store bigger values than `9`

in one byte. In an unsigned 8-bit number, you can actually store values from `00000000`

to `11111111`

, which is 255 in decimal.

In a 2-byte number, this range becomes from `00000000 00000000`

to `11111111 11111111`

which happens to be 65535.

Your statement "it takes 8 bits to store the binary representation of a number" is like saying "it takes 8 digits to store the decimal representation of a number", which is not correct. For example the number 12345678901234567890 has more than 8 digits. In the same way, you cannot fit *all* numbers in 8 bits, but only 256 of them. That's why you get 2-byte (`short`

), 4-byte (`int`

) and 8-byte (`long long`

) numbers. In truth, if you need even higher range of numbers, you would need to use a library.

As long as negative numbers are concerned, in a 2's-complement computer, they are just a convention to use the higher half of the range as negative values. This means the numbers that have a `1`

on the left side are considered negative.

Nevertheless, these numbers are congruent modulo 256 (modulo `2^n`

if `n`

bits) to their positive value as the number really suggests. For example the number `11111111`

is 255 if unsigned, and `-1`

if signed which are congruent modulo 256.