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.

Let a, b and c be non-large positive integers. Does a/b/c always equal a/(b * c) with C# integer arithmetic? For me, in C# it looks like:

int a = 5126, b = 76, c = 14;
int x1 = a / b / c;
int x2 = a / (b * c);

So my question is: does x1 == x2 for all a, b and c?

share|improve this question
This is a maths question, not a programming one. Can you explain what the programming specific part of this question is? –  Oded May 30 '13 at 13:43
@Oded in the scope of any rational number, sure, but this is specifically referring to integer arithmetic (in C#). IMO that makes it programming-related. Maybe the rule that a/b/c == a/(b*c) holds in integer arithmetic, maybe it only holds in rational number arithmetic. –  Tim S. May 30 '13 at 13:46
This is a perfectly reasonable question about C#, and easy to answer. –  Eric Lippert May 30 '13 at 13:46
@Oded This is a question about computer arithmetic and whether it behaves the same as pure math. It should not be closed. –  Jeffrey Sax May 30 '13 at 13:49
I'd be quite interested in a mathematical proof of why (or indeed whether), ignoring overflows, the two are in fact equivalent, but I've not managed to put one together yet. –  Rawling May 30 '13 at 14:06

6 Answers 6

up vote 71 down vote accepted

Let \ denote integer division (the C# / operator between two ints) and let / denote usual math division. Then, if x,y,z are positive integers and we are ignoring overflow,

(x \ y) \ z
    = floor(floor(x / y) / z)      [1]
    = floor((x / y) / z)           [2]
    = floor(x / (y * z))
    = x \ (y * z)


a \ b = floor(a / b)

The jump from line [1] to line [2] above is explained as follows. Suppose you have two integers a and b and a fractional number f in the range [0, 1). It is straightforward to see that

floor(a / b) = floor((a + f) / b)  [3]

If in line [1] you identify a = floor(x / y), f = (x / y) - floor(x / y), and b = z, then [3] implies that [1] and [2] are equal.

You can generalize this proof to negative integers (still ignoring overflow), but I'll leave that to the reader to keep the point simple.

On the issue of overflow - see Eric Lippert's answer for a good explanation! He also takes a much more rigorous approach in his blog post and answer, something you should look into if you feel I'm being too hand-wavy.

share|improve this answer
Hah, that's what I was after :) –  Rawling May 30 '13 at 14:25
I like your use of \ and / for this. Makes things much more clear. –  Justin Morgan May 30 '13 at 15:29
@JustinMorgan The notation is actually used in some other programming languages (although I don't remember which ones at the moment). –  Timothy Shields May 30 '13 at 15:31
@TimothyShields VB.net does. –  Alex Shaw May 30 '13 at 16:08
I think the claim is true, but your proof seems to be missing a key step. It's possible I misunderstood your justification for line 2 => line 3. The way I interpreted it was floor(x / y) - (x / y) is small and z >= 1 so taking the floor of that is 0 and we can ignore it. That doesn't actually follow since it's actually an addend within a floor() (i.e. consider floor(1/2) vs floor(1/2 + 1/2)). –  rliu May 31 '13 at 7:36

I liked this question so much I made it the subject of my blog on June 4th, 2013. Thanks for the great question!

Large cases are easy to come by. For example:

a = 1073741823; 
b = 134217727;
c = 134217727;

because b * c overflows to a negative number.

I would add to that the fact that in checked arithmetic, the difference between a / (b * c) and (a / b) / c can be the difference between a program that works and a program that crashes. If the product of b and c overflows the bounds of an integer then the former will crash in a checked context.

For small positive integers, say, small enough to fit into a short, the identity should be maintained.

Timothy Shields just posted a proof; I present here an alternative proof. Assume all the numbers here are non-negative integers and none of the operations overflow.

Integer division of x / y finds the value q such that q * y + r == x, where 0 <= r < y.

So the division a / (b * c) finds the value q1 such that

q1 * b * c + r1 == a

where 0 <= r1 < b * c

the division ( a / b ) / c first finds the value qt such that

qt * b + r3 == a

and then finds the value q2 such that

q2 * c + r2 == qt

So substitute that in for qt and we get:

q2 * b * c + b * r2 + r3 == a

where 0 <= r2 < c and 0 <= r3 < b.

Two things equal to the same are equal to each other, so we have

q1 * b * c + r1 == q2 * b * c + b * r2 + r3

Suppose q1 == q2 + x for some integer x. Substitute that in and solve for x:

q2 * b * c + x * b * c + r1 = q2 * b * c + b * r2 + r3
x  = (b * r2 + r3 - r1) / (b * c)


 0 <= r1 < b * c
 0 <= r2 < c
 0 <= r3 < b

Can x be greater than zero? No. We have the inequalities:

 b * r2 + r3 - r1 <= b * r2 + r3 <= b * (c - 1) + r3 < b * (c - 1) + b == b * c

So the numerator of that fraction is always smaller than b * c, so x cannot be greater than zero.

Can x be less than zero? No, by similar argument, left to the reader.

Therefore integer x is zero, and therefore q1 == q2.

share|improve this answer
+1 Also will crash if either b or c are zero. –  Jose Rui Santos May 30 '13 at 13:51
@JoseRuiSantos yes, but both the x1 and the x2 operation will crash identically in that case –  Marc Gravell May 30 '13 at 13:52
@JoseRuiSantos is that not true of both cases? –  Jodrell May 30 '13 at 13:53
vc 74's answer has been deleted, so most people can no longer see the example you're referencing. –  Gabe May 30 '13 at 13:54
That's correct, both x1 and x2 will crash if b or c are zero. For other values, the x1 expression is better, since will avoid the possible integer overflow of ( b * c) that x2 has. –  Jose Rui Santos May 30 '13 at 13:55

If the absolute values of b and c are below about sqrt(2^31) (approx. 46 300), so that b * c will never overflow, the values will always match. If b * c overflows, then an error can be thrown in a checked context, or you can get an incorrect value in an unchecked context.

share|improve this answer

Avoiding the overflow errors noticed by others, they always match.

Let's suppose that a/b=q1, which means that a=b*q1+r1, where 0<=r1<b.
Now suppose that a/b/c=q2, which means that q1=c*q2+r2, where 0<=r2<c.
This means that a=b(c*q2+r2)+r1=b*c*q2+br2+r1.
In order for a/(b*c)=a/b/c=q2, we need to have 0<=b*r2+r1<b*c.
But b*r2+r1<b*r2+b=b*(r2+1)<=b*c, as required, and the two operations match.

This doesn't work if b or c are negative, but I don't know how integer division works in that case either.

share|improve this answer

I'll offer my own proof for fun. This also ignores overflow and only handles positives unfortunately, but I think the proof is clean and clear.

The goal is to show that

floor(floor(x/y)/z) = floor(x/y/z)

where / is normal division (throughout this proof).

We represent the quotient and remainder of a/b uniquely as a = kb + r (by that we mean that k,r are unique and also note |r| < |b|). Then we have:

(1) floor(x/y) = k => x = ky + r
(2) floor(floor(x/y)/r) = k1 => floor(x/y) = k1*z + r1
(3) floor(x/y/z) = k2 => x/y = k2*z + r2

So our goal is just to show that k1 == k2. Well we have:

k1*z + r1 = floor(x/y) = k = (x-r)/y (from lines 1 and 2)
=> x/y - r/y = k1*z + r1 => x/y = k1*z + r1 + r/y

and thus:

(4) x/y = k1*z + r1 + r/y (from above)
x/y = k2*z + r2 (from line 3)

Now observe from (2) that r1 is an integer (for k1*z is an integer by definition) and r1 < z (also by definition). Furthermore from (1) we know that r < y => r/y < 1. Now consider the sum r1 + r/y from (4). The claim is that r1 + r/y < z and this is clear from the previous claims (because 0 <= r1 < z and r1 is an integer so we have 0 <= r1 <= z-1. Therefore 0 <= r1 + r/y < z). Thus r1 + r/y = r2 by definition of r2 (otherwise there would be two remainders from x/y which contradicts the definition of remainder). Hence we have:

x/y = k1*z + r2
x/y = k2*z + r2

and we have our desired conclusion that k1 = k2.

The above proof should work with negatives except for a couple steps that you'd need to check an extra case(s)... but I didn't check.

share|improve this answer

counter example: INT_MIN / -1 / 2

share|improve this answer
"Let a, b and c be non-large positive integers." –  Pang Jun 5 '13 at 1:28
That's an interesting case (i.e. -INT_MIN is an overflow). Thanks! –  Jason Crease Jun 5 '13 at 10:05

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.