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`

.