No, not all, but there exists a range within which you can represent all integers accurately.

## Structure of 32bit floating point numbers

The 32bit floating point type uses

- 1 bit for the sign
- 8 bits for the exponent
- 23 bits for the fraction (leading 1 implied)

**Representing numbers**

Basically, you have a number in the form

```
(-)1.xxxx_xxxx_xxxx_xxxx_xxxx_xxx (binary)
```

which you then shift left/right with the (unbiased) exponent.

To have it represent an integer requiring `n`

bits, you need to shift it by `n-1`

bits to the left. (All `x`

es beyond the floating point are simply zero)

**Representing integers with 24 bits**

It is easy to see, that we can represent all integers requiring 24 bits (and less)

```
1xxx_xxxx_xxxx_xxxx_xxxx_xxxx.0 (unbiased exponent = 23)
```

since we can set the `x`

es at will to either `1`

or `0`

.

The highest number we can represent in this fashion is:

```
1111_1111_1111_1111_1111_1111.0
```

or `2^24 - 1 = 16777215`

The next higher integer is `1_0000_0000_0000_0000_0000_0000`

. Thus, we need 25 bits.

**Representing integers with 25 bits**

If you try to represent a 25 bit integer (unbiased exponent = 24), the numbers have the following form:

```
1_xxxx_xxxx_xxxx_xxxx_xxxx_xxx0.0
```

The twenty-three digits that are available to you have all been shifted past the floating point. The leading digit is always a 1. In total, we have 24 digits. But since we need 25, a zero is appended.

**A maximum is found**

We can represent ``1_0000_0000_0000_0000_0000_0000`

with the form `1_xxxx_xxxx_xxxx_xxxx_xxxx_xxx0.0`

, by simply assigning `1`

to all `x`

es. The next higher integer from that is: `1_0000_0000_0000_0000_0000_0001`

. It's easy to see that this number cannot be represented accurately, because the form does not allow us to set the last digit to `1`

: It is always `0`

.

It follows, that the `1`

followed by 24 zeroes is an upper bound for the integers we can accurately represent.
The lower bound simply has its sign bit flipped.

**Range within which all integers can be represented (including boundaries)**

- 2
^{24} as an upper bound
- -2
^{24} as a lower bound

## Structure of 64bit floating point numbers

- 1 bit for the sign
- 11 exponent bits
- 52 fraction bits

**Range within which all integers can be represented (including boundaries)**

- 2
^{54} as an upper bound
- -2
^{54} as a lower bound

This easily follows by applying the same argumentation to the structure of 64bit floating point numbers.

**Note**: That is not to say these are *all* integers we can represent, but it gives you a range within which you can represent *all* integers. Beyond that range, we can only represent a power of two multiplied with an integer from said range.

## Combinatorial argument

Simply convincing ourselves that it is impossible for 32bit floating point numbers to represent all integers a 32bit integer can represent, we need not even look at the structure of floating point numbers.

- With 32 bits, there are 2
^{32} different things we can represent. No more, no less.
- A 32bit integer uses all of these "things" to represent numbers (pairwise different).
- A 32bit floating point number can represent at least one number with a fractional part.

Thus, it is impossible for the 32bit floating point number to be able to represent this fractional number in addition to all 2^{32} integers.

`integer`

? – Macmade Sep 15 '12 at 21:29