It comes down to how one converts an
Integer value to a
Double that is not exactly representable. Note that this can happen not just because
Integer is too big (or too small), but
Double values by design "skip around" integral values as their magnitude gets larger. So, not every integral value in the range is exactly representable either. In this case, an implementation has to pick a value based on the rounding-mode. Unfortunately, there are multiple candidates; and what you are observing is that the candidate picked by Haskell gives you a worse numeric result.
Most languages, including Python, use what's known as "round-to-nearest-ties-to-even" rounding mechanism; which is the default IEEE754 rounding mode and is typically what you would get unless you explicitly set a rounding mode when issuing a floating-point related instruction in a compliant processor. Using Python as the "reference" here, we get:
I haven't tried in other languages that support so called big-integers, but I'd expect most of them would give you this result.
How Haskell converts
Haskell, however, uses what's known as truncation, or round-towards-zero. So you get:
*Main> (fromIntegral $ 4141414141414141*4141414141414141) :: Double
Turns out this is a "worse" approximation in this case (cf. to the Python produced value above), and you get the unexpected result in your original example.
The call to
sqrt is really red-herring at this point.
Show me the code
It all originates from this code: (https://hackage.haskell.org/package/integer-gmp-22.214.171.124/docs/src/GHC.Integer.Type.html#doubleFromInteger)
doubleFromInteger :: Integer -> Double#
doubleFromInteger (S# m#) = int2Double# m#
doubleFromInteger (Jp# bn@(BN# bn#))
= c_mpn_get_d bn# (sizeofBigNat# bn) 0#
doubleFromInteger (Jn# bn@(BN# bn#))
= c_mpn_get_d bn# (negateInt# (sizeofBigNat# bn)) 0#
which in turn calls: (https://github.com/ghc/ghc/blob/master/libraries/integer-gmp/cbits/wrappers.c#L183-L190):
/* Convert bignum to a `double`, truncating if necessary
* (i.e. rounding towards zero).
* sign of mp_size_t argument controls sign of converted double
integer_gmp_mpn_get_d (const mp_limb_t sp, const mp_size_t sn,
const HsInt exponent)
which purposefully says the conversion is done rounding-toward zero.
So, that explains the behavior you get.
Why does Haskell do this?
None of this explains why Haskell uses round-towards-zero for integer-to-double conversion. I'd strongly argue that it should use the default rounding mode, i.e., round-nearest-ties-to-even. I can't find any mention whether this was a conscious choice, and it at least disagrees with what Python does. (Not that I'd consider Python the gold standard, but it does tend to get these things right.)
My best guess is it was just coded that way, without a conscious choice; but perhaps other people familiar with the history of numeric programming in Haskell can remember better.
What to do
Interestingly, I found the following discussion dating all the way back to 2008 as a Python bug: https://bugs.python.org/issue3166. Apparently, Python used to do the wrong thing here as well, but they fixed the behavior. It's hard to track the exact history, but it appears Haskell and Python both made the same mistake; Python recovered, but it went unnoticed in Haskell. If this was a conscious choice, I'd like to know why.
So, that's where it stands. I'd recommend opening a GHC ticket so it can be at least documented properly that this is the "chosen" behavior; or better, fix it so that it uses the default rounding mode instead.
GHC ticket opened: https://gitlab.haskell.org/ghc/ghc/issues/17231