# How To Represent 0.1 In Floating Point Arithmetic And Decimal

I am trying to understand floating point arithmetic better and have seen a few links to 'What Every Computer Scientist Should Know About Floating Point Arithmetic'.

I still don't understand how a number like `0.1` or `0.5` is stored in floats and as decimals.

Can someone please explain how it is laid out is memory?

I know about the float being two parts (i.e., a number to the power of something).

I've always pointed people towards Harald Schmidt's online converter, along with the Wikipedia IEEE754-1985 article with its nice pictures.

For those two specific values, you get (for 0.1):

``````s eeeeeeee mmmmmmmmmmmmmmmmmmmmmmm    1/n
0 01111011 10011001100110011001101
|  ||  ||  ||  ||  || +- 8388608
|  ||  ||  ||  ||  |+--- 2097152
|  ||  ||  ||  ||  +---- 1048576
|  ||  ||  ||  |+-------  131072
|  ||  ||  ||  +--------   65536
|  ||  ||  |+-----------    8192
|  ||  ||  +------------    4096
|  ||  |+---------------     512
|  ||  +----------------     256
|  |+-------------------      32
|  +--------------------      16
+-----------------------       2
``````

The sign is positive, that's pretty easy.

The exponent is `64+32+16+8+2+1 = 123 - 127 bias = -4`, so the multiplier is `2-4` or `1/16`.

The mantissa is chunky. It consists of `1` (the implicit base) plus (for all those bits with each being worth `1/(2n)` as `n` starts at `1` and increases to the right), `{1/2, 1/16, 1/32, 1/256, 1/512, 1/4096, 1/8192, 1/65536, 1/131072, 1/1048576, 1/2097152, 1/8388608}`.

When you add all these up, you get `1.60000002384185791015625`.

When you multiply that by the multiplier, you get `0.100000001490116119384765625`, which is why they say you cannot represent `0.1` exactly as an IEEE754 float, and provides so much opportunity on SO for people answering `"why doesn't 0.1 + 0.1 + 0.1 == 0.3?"`-type questions :-)

The 0.5 example is substantially easier. It's represented as:

``````s eeeeeeee mmmmmmmmmmmmmmmmmmmmmmm
0 01111110 00000000000000000000000
``````

which means it's the implicit base, `1`, plus no other additives (all the mantissa bits are zero).

The sign is again positive. The exponent is `64+32+16+8+4+2 = 126 - 127 bias = -1`. Hence the multiplier is `2-1` which is `1/2` or `0.5`.

So the final value is `1` multiplied by `0.5`, or `0.5`. Voila!

I've sometimes found it easier to think of it in terms of decimal.

The number 1.345 is equivalent to

``````1 + 3/10   + 4/100 + 5/1000
``````

or:

``````        -1       -2      -3
1 + 3*10   + 4*10  + 5*10
``````

Similarly, the IEEE754 representation for decimal `0.8125` is:

``````s eeeeeeee mmmmmmmmmmmmmmmmmmmmmmm
0 01111110 10100000000000000000000
``````

With the implicit base of 1, that's equivalent to the binary:

``````         01111110-01111111
1.101 * 2
``````

or:

``````                     -1
(1   + 1/2 + 1/8) * 2     (no 1/4 since that bit is 0)
``````

which becomes:

``````(8/8 + 4/8 + 1/8) * 1/2
``````

and then becomes:

``````13/8 * 1/2 = 0.8125
``````

See the Wikipedia entry and the IEEE group, first.

Basically, there's a sign, a number, and an exponent. A number in one base cannot be represented finitely in another base if the source base has factors not present in the destination base. For instance, 1/3 cannot be represented as a finite decimal number, but is trivial to represent as a ternary (base-3) number: (0.1)3.

So 0.5 has a finite binary representation, (0.1)2, that is, 2-1, but 0.1 has a repeating representation because 2 and 10 have a factor (5) not in common.