**TL;DR:** `NaN`

have an arbitrary representation between `2 ^ 1024`

and `2 ^ 1025`

(bounds not included), and `- 1.5 * 2 ^ 1024`

(which is *one possible*) `NaN`

happens to be the one you hit.

# Why any reasoning is off

What is happening here?

You're entering the region of undefined behaviour. Or at least that is what you would call it in some other languages. The report defines `round`

as follows:

The `ceiling`

, `floor`

, `truncate`

, and `round`

functions each take a real fractional argument and return an integral result. … `round x`

returns the nearest integer to `x`

, the even integer if `x`

is equidistant between two integers.

In our case `x`

does not represent a number to begin with. According to 6.4.6, `y = round x`

should fulfil that any other `z`

from `round`

's codomain has an equal or greater distance:

```
y = round x ⇒ ∀z : dist(z,x) >= dist(y,x)
```

However, the distance (aka the subtraction) of numbers is defined only for, well, numbers. If we used

```
dist n d = fromIntegral n - d
```

we get in trouble soon: any operation that includes `NaN`

will return `NaN`

again, and comparisons on `NaN`

fail, so our property above **does not hold for any** `z`

if `x`

was a `NaN`

to begin with. If we check for `NaN`

, we can return any value, but then our property **holds for all pairs**:

```
dist n d = if isNaN d then constant else fromIntegral n - d
```

So we're completely arbitrary in what `round x`

shall return if `x`

was not a number.

# Why do we get that large number regardless?

"OK", I hear you say, "that's all fine and dandy, but why do I get that number?" That's a good question.

Is this behavior intended?

Somewhat. It isn't really intended, but to be expected. First of all, we have to know how `Double`

works.

## IEE 754 double precision floating point numbers

A `Double`

in Haskell is usually a IEEE 754 compliant double precision floating point number, that is a number that has 64 bits and is represented with

```
x = s * m * (b ^ e)
```

where `s`

is a single bit, `m`

is the mantissa (52 bits) and `e`

is the exponent (11 bits, `floatRange`

). `b`

is the base, and its usually `2`

(you can check with `floadRadix`

). Since the value of `m`

is normalized, every well-formed `Double`

has a unique representation.

## IEEE 754 NaN

Except `NaN`

. `NaN`

is represented as the e_{max}+1, *as well as a non-zero mantissa*. So if the bitfield

```
SEEEEEEEEEEEMMMMMMMMMMMMMMMMMMMMMMMMMMMMMMMMMMMMMMMMMMMMMMMMMMMM
```

represents a `Double`

, what's a valid way to represent `NaN`

?

```
?111111111111000000000000000000000000000000000000000000000000000
^
```

That is, a single `M`

is set to `1`

, the other are not necessary to set this notion. The sign is arbitrary. Why only a single bit? Because its sufficient.

## Interpret NaN as `Double`

Now, when we ignore the fact that this is a malformed `Double`

—a `NaN`

– and really, *really*, *really* want to interpret it as number, what number would we get?

```
m = 1.5
e = 1024
x = 1.5 * 2 ^ 1024
= 3 * 2 ^ 1024 / 2
= 3 * 2 ^ 1023
```

And lo and behold, that's exactly the number you get for `round (0/0)`

:

```
ghci> round $ 0 / 0
-269653970229347386159395778618353710042696546841345985910145121736599013708251444699062715983611304031680170819807090036488184653221624933739271145959211186566651840137298227914453329401869141179179624428127508653257226023513694322210869665811240855745025766026879447359920868907719574457253034494436336205824
ghci> negate $ 3 * 2 ^ 1023
-269653970229347386159395778618353710042696546841345985910145121736599013708251444699062715983611304031680170819807090036488184653221624933739271145959211186566651840137298227914453329401869141179179624428127508653257226023513694322210869665811240855745025766026879447359920868907719574457253034494436336205824
```

Which brings our small adventure to a halt. We have a `NaN`

, which yields a `2 ^ 1024`

, and we have some non-zero mantissa, which yields a result with absolute value between `2 ^ 1024 < x < 2 ^ 1025`

.

Note that this isn't the only way `NaN`

can get represented:

In IEEE 754, NaNs are often represented as floating-point numbers with the exponent e_{max} + 1 and nonzero significands. Implementations are free to put system-dependent information into the significand. Thus there is not a unique NaN, but rather a whole family of NaNs.

For more information, see the classic paper on floating point numbers by Goldberg.

`properFraction`

which is used to implement`round`

, test it with:`fst $ properFraction $ (0/0 :: Double) :: Integer`

. If you test with`fst $ properFraction $ (0/0 :: Float) :: Integer`

, you get`-510423550381407695195061911147652317184`

instead.`properFraction`

is implemented here: github.com/ghc/ghc/blob/master/libraries/base/GHC/… – Centril Jun 6 '17 at 1:03`round NaN`

. – Daniel Wagner Jun 6 '17 at 1:18`roundFP :: Double -> Double`

which 1) can perform rounding without an intermediate integral type, and 2) can map NaN to NaN. – chi Jun 6 '17 at 7:58`not (round NaN > -Infinity)`

;). – Zeta Jun 6 '17 at 10:17