Basically floating point numbers are represented as:

```
digits * 2 ** movement
```

digits (*the mantissa*) has 52 bits (and 1 "hidden bit"), movement has 11 bits, and both together form a 64bit number (with 1 sign bit). Through that, you can represent all kinds of different numbers as you can store very large numbers (large positive movement), very small numbers (large negative movement), and integers (digits).

What is Number.MAX_SAFE_INTEGER ?

Integers can just be represented with movement being set in a way that the mantissa is actually the number itself, then digits contains the 52 + 1 bit number, and that can hold up to `2 ** 53 - 1`

numbers (which is `Number.MAX_SAFE_INTEGER`

).

Now for larger numbers, you have to use movement, which basically means that you move the digits left or right, and therefore you lose accuracy.

(Imagine `digits`

would just take 8 bits)

```
number > digits | movement > result
// savely represented
11111111 > 11111111 | 0 > 11111111
// lost the last 1
111111111 > 11111111 | 1 > 111111110
// lost the two last 1s
1111111111 > 11111111 | 10 > 1111111100
```

What is Number.MAX_VALUE ?

If you set all bits of `digits`

and all bits of `movement`

, you get a number (`2 ** 53 - 1`

) that is moved by `2 ** 10 - 1`

to the left, and that is the largest number that can be stored in the 64 bit, everything that is larger is `Infinity`

(which is represented as the movement being 2 ** 10 and the mantissa being 0).

`MAX_VALUE`

is not integral. And to answer your questions check en.wikipedia.org/wiki/IEEE_floating_point