# Exact difference between div and quot

In this question here on SO the differences between the two operators `div` and `quot` are mentioned as well as the fact that the `quot` operator is more efficient than the `div` operator, whereas `div` is more natural for us humans to use.

My question is what the exact implementations of the two operators are and linked to that what the difference between implementations is. Also I want to know how the speed difference between those two comes to be, as using Hoogle and browsing the sources did not help me in my quest to understanding.

I want to clarify that I understand the general difference between the two operators and only am interested in the implementations or rather the differences.

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I added a tiny bit of benchmarking too, FYI. –  András Kovács Jun 10 at 21:00
@AndrásKovács Thank you for the great answer! :D –  ThreeFx Jun 10 at 21:39
As @augustss mentions in his answer to the question you linked, the fundamental reason for the speed difference is that `quot` is what is usually implemented directly as an instruction in modern CPUs. Thus, as mentioned below, that is what GHC chooses as its primitive operation. –  Ørjan Johansen Jun 12 at 22:24

`quot` rounds towards zero, `div` rounds towards negative infinity:

``````div  (-3) 2 == (-2)
quot (-3) 2 == (-1)
``````

As to the overhead of `div`, `quot` has a corresponding primitive GHC operation, while `div` does some extra work:

``````quotRemInt :: Int -> Int -> (Int, Int)
(I# x) `quotRemInt` (I# y) = case x `quotRemInt#` y of
(# q, r #) ->
(I# q, I# r)

divModInt# :: Int# -> Int# -> (# Int#, Int# #)
x# `divModInt#` y#
| (x# ># 0#) && (y# <# 0#) = case (x# -# 1#) `quotRemInt#` y# of
(# q, r #) -> (# q -# 1#, r +# y# +# 1# #)
| (x# <# 0#) && (y# ># 0#) = case (x# +# 1#) `quotRemInt#` y# of
(# q, r #) -> (# q -# 1#, r +# y# -# 1# #)
| otherwise                = x# `quotRemInt#` y#
``````

In their final forms, both functions have some error handling checks on them:

``````a `quot` b
| b == 0                     = divZeroError
| b == (-1) && a == minBound = overflowError -- Note [Order of tests]
-- in GHC.Int
| otherwise                  =  a `quotInt` b

a `div` b
| b == 0                     = divZeroError
| b == (-1) && a == minBound = overflowError -- Note [Order of tests]
-- in GHC.Int
| otherwise                  =  a `divInt` b
``````

I also did a very small bit of microbenchmarking, but it should be taken with a hefty amount of salt, because GHC and LLVM optimize tight numeric code away like there's no tomorrow. I tried to thwart them, and the results seem to be realistic: 14,67 ms for `div` and 13,37 ms for `quot`. Also, it's GHC 7.8.2 with -O2 and -fllvm. Here's the code:

``````{-# LANGUAGE BangPatterns #-}

import Criterion.Main
import System.Random

benchOp :: (Int -> Int) -> Int -> ()
benchOp f = go 0 0 where
go !i !acc !limit | i < limit = go (i + 1) (f i) limit
| otherwise = ()

main = do
limit1 <- randomRIO (1000000, 1000000 :: Int)
limit2 <- randomRIO (1000000, 1000000 :: Int)
n      <- randomRIO (100, 100 :: Int)
defaultMain [
bench "div"  \$ whnf (benchOp (`div`  n)) limit1,
bench "quot" \$ whnf (benchOp (`quot` n)) limit2]
``````
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I don't know enough about benchmarking to tell whether your benchmark tests negative numbers. Does it? –  dfeuer Jun 13 at 21:55
@dfeuer it's all positive. I ran some with negative numbers, and the results were similar, but anyway I think this is not a very good piece of benchmarking; a better one would be where we use NOINLINE-s and look at the GHC Core to make sure we're benchmarking the right thing. –  András Kovács Jun 14 at 7:51
The reason I mentioned the negatives is that if GHC/LLVM is smart enough to realize there are only positives, then it will gut the `divMod` logic after inlining. You're probably right that more careful benchmarking is needed, but I'm definitely not the right one to do that. –  dfeuer Jun 14 at 13:05