# In C# integer arithmetic, does a/b/c always equal a/(b*c)?

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?

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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

Let `\` denote integer division (the C# `/` operator between two `int`s) 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)
``````

where

``````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.

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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)
``````

where

`````` 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`.

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+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.

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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.

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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.

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counter example: INT_MIN / -1 / 2

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"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