### TL;DR

Both decimals precisely represent 0.1. It's just that the `decimal`

format, exactly like IEEE floating point, allows multiple bitwise-different values that represent the exact same number.

### Explanation

It isn't about `single`

not being able to represent 0.1 precisely. As per the documentation of `GetBits`

:

The binary representation of a `Decimal`

number consists of a 1-bit
sign, a 96-bit integer number, and a scaling factor used to divide the
integer number and specify what portion of it is a decimal fraction.
The scaling factor is implicitly the number 10, raised to an exponent
ranging from 0 to 28.

The return value is a four-element array of 32-bit signed integers.

The first, second, and third elements of the returned array contain
the low, middle, and high 32 bits of the 96-bit integer number.

The fourth element of the returned array contains the scale factor and
sign. It consists of the following parts:

Bits 0 to 15, the lower word, are unused and must be zero.

Bits 16 to 23 must contain an exponent between 0 and 28, which
indicates the power of 10 to divide the integer number.

Bits 24 to 30 are unused and must be zero.

Bit 31 contains the sign: 0 mean positive, and 1 means negative.

Note that the bit representation differentiates between negative and
positive zero. These values are treated as being equal in all
operations.

The fourth integer of each `decimal`

in your example is `0x00030000`

for `bitsSingle`

and `0x00020000`

for `bitsDecimal`

. In binary this maps to:

```
bitsSingle 00000000 00000011 00000000 00000000
|\-----/ \------/ \---------------/
| | | |
sign <-+ unused exponent unused
| | | |
|/-----\ /------\ /---------------\
bitsDecimal 00000000 00000010 00000000 00000000
NOTE: exponent represents multiplication by negative power of 10
```

Therefore, in the first case the 96-bit integer is divided by an additional factor of 10 compared to the second -- bits 16 to 23 give the value 3 instead of 2. But that is offset by the 96-bit integer itself, which in the first case is also 10 times greater than in the second (obvious from the values of the first elements).

The difference in observed values can therefore be attributed simply to the fact that the conversion from `single`

uses subtly different logic to derive the internal representation compared to the "straight" constructor.

`Decimal.GetBits()`

, but aside from that I think this is interesting. – m.edmondson Mar 9 '14 at 9:20