It can be proved that the following is correct:

```
c = floor((a+b/2)/b)
a = a - c*b
```

Note that floor means round down, towards negative infinity: not towards 0. (E.g. floor(-3.1)=-4. The `floor()`

library functions will do this; just be sure not to just cast to int, which will usually round towards 0 instead.)

Presumably `b`

is strictly positive, because otherwise neither loop will never terminate: adding `b`

will not make `a`

larger and subtracting `b`

will not make `a`

smaller. With that assumption, we can prove that the above code works. (And paranoidgeek's code is also almost correct, except that it uses a cast to int instead of `floor`

.)

**Clever way of proving it**:
The code adds or subtracts multiples of `b`

from `a`

until `a`

is in `[-b/2,b/2)`

, which you can view as adding or subtracting *integers* from `a/b`

until `a/b`

is in `[-1/2,1/2)`

, i.e. until `(a/b+1/2)`

(call it `x`

) is in `[0,1)`

. As you are only changing it by integers, the value of `x`

does not change `mod 1`

, i.e. it goes to its **remainder mod 1**, which is `x-floor(x)`

. So the effective number of subtractions you make (which is `c`

) is `floor(x)`

.

**Tedious way of proving it**:

_{
At the end of the first loop, the value of c is the negative of the number of times the loop runs, i.e.:}

- 0 if: a > -b/2 <=> a+b/2 > 0
- -1 if: -b/2 ≥ a > -3b/2 <=> 0 ≥ a+b/2 > -b <=> 0 ≥ x > -1
- -2 if: -3b/2 ≥ a > -5b/2 <=> -b ≥ a+b/2 > -2b <=> -1 ≥ x > -2 etc.,

where `x = (a+b/2)/b`

, so c is: 0 if x>0 and "ceiling(x)-1" otherwise. If the first loop ran at all, then it was ≤ -b/2 just before the *last time* the loop was executed, so it is ≤ -b/2+b now, i.e. ≤ b/2. According as whether it is exactly b/2 or not (i.e., whether `x`

when you started was exactly a non-positive integer or not), the second loop runs exactly 1 time or 0, and c is either ceiling(x) or ceiling(x)-1. So that solves it for the case when the first loop did run.

If the first loop didn't run, then the value of c at the end of the second loop is:

- 0 if: a < b/2 <=> a-b/2 < 0
- 1 if: b/2 ≤ a < 3b/2 <=> 0 ≤ a-b/2 < b <=> 0 ≤ y < 1
- 2 if: 3b/2 ≤ a < 5b/2 <=> b ≤ a-b/2 < 2b <=> 1 ≤ y < 2, etc.,

where `y = (a-b/2)/b`

, so c is: 0 if y<0 and 1+floor(y) otherwise. [And `a`

now is certainly < b/2 and ≥ -b/2.]

So you can write an expression for `c`

as:

```
x = (a+b/2)/b
y = (a-b/2)/b
c = (x≤0)*(ceiling(x) - 1 + (x is integer))
+(y≥0)*(1 + floor(y))
```

Of course, next you notice that `(ceiling(x)-1+(x is integer))`

is same as `floor(x+1)-1`

which is `floor(x)`

, and that `y`

is actually `x-1`

, so `(1+floor(y))=floor(x)`

, and as for the conditionals:

when x≤0, it cannot be that (y≥0), so `c`

is just the first term which is `floor(x)`

,

when 0 < x < 1, neither of the conditions holds, so `c`

is `0`

,

when 1 ≤ x, then only 0≤y, so c is just the second term which is `floor(x)`

again.
So c = `floor(x)`

in all cases.