Take the 2-minute tour ×
Stack Overflow is a question and answer site for professional and enthusiast programmers. It's 100% free, no registration required.

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
Prelude> (-12) `div` 5

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

share|improve this question

3 Answers 3

up vote 25 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.

share|improve this answer
"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
@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

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.

share|improve this answer
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
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

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.

share|improve this answer

Your Answer


By posting your answer, you agree to the privacy policy and terms of service.

Not the answer you're looking for? Browse other questions tagged or ask your own question.