The Euclidean division theorem, with which most math students and Haskellers are familiar, states that

Given two integers a and b, with b ≠ 0, there exist unique integers q and r such that a = bq + r and 0 ≤ r < |b|.

This gives the conventional definitions of quotient and remainder. This 1992 paper argues that they are the best ones to implement in a programming language. Why, then, does `divMod`

always round the dividend toward negative infinity?

Exact difference between div and quot shows that `divMod`

already does a fair bit of extra work over `quotRem`

; it seems unlikely to be much harder to get it right.

### Code

I wrote the following implementation of a Euclidean-style `divMod`

based on the implementation in `GHC.Base`

. I'm pretty sure it's right.

```
divModInt2 :: Int -> Int -> (Int, Int)
divModInt2 (I# x) (I# y) = case (x `divModInt2#` y) of
divModInt2# :: Int# -> Int# -> (# Int#, Int# #)
x# `divModInt2#` y#
| (x# <# 0#) = case (x# +# 1#) `quotRemInt#` y# of
(# q, r #) -> if y# <# 0#
then (# q +# 1#, r -# y# -# 1# #)
else (# q -# 1#, r +# y# -# 1# #)
| otherwise = x# `quotRemInt#` y#
```

Not only does this produce pleasantly Euclidean results, but it's actually *simpler* than the GHC code. It clearly performs at most two comparisons (as opposed to four for the GHC code).

In fact, this could probably be made entirely branchless without too much work by someone who knows more about primitives than I.

The gist of a branchless version (presumably someone who knows more could make it more efficient).

```
x `divMod` y = (q + yNeg, r - yNeg * y - xNeg)
where
(q,r) = (x + xNeg) `quotRem` y
xNeg = fromEnum (x < 0)
yNeg = xNeg*(2 * fromEnum (y < 0) - 1)
```

faster(see the code I just added). – dfeuer Jun 13 at 18:42`/`

, should make it easy for programmers to either specify what they want or say they don't care [e.g. because the dividend is expected to always exact multiple of the divisor, or dividend and divisor are expected to always be positive]. I'd say there's probably a roughly 1000:50:1 ratio between cases where I didn't care which style was used, those where I wanted either floored or Euclidian, ... – supercat Jun 13 at 20:06