The first thing to realize is that when you enter `0.1::Double`

and ghci prints `0.1`

back, it's only an "illusion:"

```
Prelude Data.Ratio> 0.1::Double
0.1
```

Why is that an illusion? Because the number `0.1`

is actually not precisely representable as a floating point number! This is true for both `Float`

and `Double`

. Observe:

```
Prelude Data.Ratio> toRational (0.1::Float)
13421773 % 134217728
Prelude Data.Ratio> toRational (0.1::Double)
3602879701896397 % 36028797018963968
```

So, in reality, these numbers are indeed "close" to the actual real number `0.1`

, but neither is precisely `0.1`

. How close are they? Let's find out:

```
Prelude Data.Ratio> toRational (0.1::Float) - (1%10)
1 % 671088640
Prelude Data.Ratio> toRational (0.1::Double) - (1%10)
1 % 180143985094819840
```

As you see, `Double`

is indeed a lot more precise than `Float`

; the difference between the representation of `0.1`

as a `Double`

and the actual real-number `0.1`

is a lot smaller. But neither is precise.

So, indeed the `Double`

addition is a lot more precise, and should be preferred over the `Float`

version. The confusing equality you see is nothing but the weird effect of rounding. The results of `==`

should *not* be trusted in the floating-point land. In fact, there are many floating point numbers `x`

such that `x == x + 1`

holds. Here's one example:

```
Prelude> let x = -2.1474836e9::Float
Prelude> x == x + 1
True
```

A good read on floating-point representation is the classic What Every Computer Scientist Should Know about Floating-Point Arithmetic, which explains many of these quirky aspects of floating-point arithmetic.

Also note that this behavior is not unique to Haskell. Any language that uses IEEE754 Floating-point arithmetic will behave this way, which is the standard implemented by modern microprocessors.