I begin by defining a large integer `n`

:

```
Prelude> let n = 5705979550618670446308578858542675373983
Prelude> n :: Integer
5705979550618670446308578858542675373983
```

Next I looked at the behavior of `s1`

and `s2`

:

```
Prelude> let s1 = (sqrt (fromIntegral n))^2
Prelude> let s2 = (floor(sqrt(fromIntegral n)))^2
Prelude> s1 == fromIntegral n
True
Prelude> s1 == fromIntegral s2
True
Prelude> (fromIntegral n) == (fromIntegral s2)
False
```

Since any fractional part might be discarded, equality on the last 2 expressions was not expected. However, I didn't expect equality to be intransitive (e.g. `n == s1, s1 == s2`

, but `n != s2`

.)

Furthermore, `floor`

appears to lose precision on the integer part, despite retaining 40 significant digits.

```
Prelude> s1
5.70597955061867e39
Prelude> s2
5705979550618669899723442048678773129216
```

This lost precision becomes obvious when testing subtraction:

```
Prelude> (fromIntegral n) - s1
0.0
Prelude> (fromIntegral n) - (fromIntegral s2)
546585136809863902244767
```

Why does `floor`

lose precision, and how is this violating transitivity of equality (if at all)?

What is the best approach to computing `floor . sqrt`

without loss of precision?