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From the haskell report:

The quot, rem, div, and mod class methods satisfy these laws if y is non-zero:

(x `quot` y)*y + (x `rem` y) == x
(x `div`  y)*y + (x `mod` y) == x

quot is integer division truncated toward zero, while the result of div is truncated toward negative infinity.

For example:

Prelude> (-12) `quot` 5
-2
Prelude> (-12) `div` 5
-3

What are some examples of where the difference between how the result is truncated matters?

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3 Answers 3

up vote 24 down vote accepted

Many languages have a "mod" or "%" operator that gives the remainder after division with truncation towards 0; for example C, C++, and Java, and probably C#, would say:

(-11)/5 = -2
(-11)%5 = -1
5*((-11)/5) + (-11)%5 = 5*(-2) + (-1) = -11.

Haskell's quot and rem are intended to imitate this behaviour. I can imagine compatibility with the output of some C program might be desirable in some contrived situation.

Haskell's div and mod, and subsequently Python's / and %, follow the convention of mathematicians (at least number-theorists) in always truncating down division (not towards 0 -- towards negative infinity) so that the remainder is always nonnegative. Thus in Python,

(-11)/5 = -3
(-11)%5 = 4
5*((-11)/5) + (-11)%5 = 5*(-3) + 4 = -11.

Haskell's div and mod follow this behaviour.

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4  
"so that the remainder is always nonnegative" Technically, the sign of of mod follows the sign of the second operand. –  newacct May 7 '09 at 4:41
    
Huh, you're right. I don't understand this design decision... –  ShreevatsaR May 7 '09 at 15:31
    
it's to maintain the property that (q,r) = divMod x y if and only if x = q*y + r. Run an example, it's clever how it works out. –  luqui Dec 17 '10 at 0:28
2  
@luqui: No, that does not explain it. You can always have x=q*y+r with r nonnegative; e.g. if divMod 11 (-5) = (-2, 1) (instead of (-3,-4)), you'd still have "11 = (-2)*(-5) + 1". So your condition does not force the sign of mod to follow the second operand. BTW, the property that x=q*y+r is always true of quotRem as well, and there are always infinitely many pairs (q,r) such that x=q*y+r (and exactly two of these pairs have |r|<q, except when r=0 gives a solution there's only one pair). –  ShreevatsaR Dec 17 '10 at 4:09
    
hmm, yeah. Maybe mod is compensating for some related design decision in div? Not sure... –  luqui Dec 17 '10 at 6:06

A simple example where it would matter is testing if an integer is even or odd.

let buggyOdd x = x `rem` 2 == 1
buggyOdd 1 // True
buggyOdd (-1) // False (wrong!)

let odd x = x `mod` 2 == 1
odd 1 // True
odd (-1) // True

Note, of course, you could avoid thinking about these issues by just defining odd in this way:

let odd x = x `rem` 2 /= 0
odd 1 // True
odd (-1) // True

In general, just remember that, for y > 0, x mod y always return something >= 0 while x rem y returns 0 or something of the same sign as x.

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This is not exactly an answer to your question, but in GHC on x86, quotRem on Int will compile down to a single machine instruction, whereas divMod does quite a bit more work. So if you are in a speed-critical section and working on positive numbers only, quotRem is the way to go.

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2  
For solving the SPOJ primes, using rem rather than mod makes my test file run in 4.758s rather than 5.533s. This is means the quicker version is 16% quicker under 32-bit Ubuntu, Haskell Platform 2011. –  Tim Perry May 5 '11 at 0:33
    
@TimPerry, I don't think that follows. What if you did one mod in your whole program and saw that same improvement? –  luqui Jan 11 '13 at 17:55
    
I stated that when I changed calls in my primes code from mod to rem and I saw a 20% speedup. It is not a theoretical comment. It was a description of an event. I only changed one thing (albeit multiple places) and I saw a 20% speedup. It seems a 20% speedup DID follow. –  Tim Perry Jan 11 '13 at 22:30
    
@TimPerry ah I thought "the quicker version" referred to rem, not your modified program. (Not sure why I thought you wouldn't just say rem if that's what you meant though...) –  luqui Jan 11 '13 at 22:32
1  
On many architectures including x86, when dividing by non-constants, using truncate-toward-zero division is slightly faster than than floor-toward-negative-infinity, but when dividing by many constant values, especially powers of two, truncate-toward-zero is much faster (e.g. one instruction versus 3). I would posit that code which is speed-sensitive is apt to have more "fast" divisions in it than slow ones. –  supercat Nov 13 '13 at 20:53

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