You can wrap it using two modulo operations, **which is still equivalent to a division**. I don't think there is a more efficient way of doing this without assuming something about `x`

.

```
x = (((x - x_min) % (x_max - x_min)) + (x_max - x_min)) % (x_max - x_min) + x_min;
```

The additional sum and modulo in the formula are to handle those cases where `x`

is actually less than `x_min`

and the modulo might come up negative. Or you could do this with an `if`

, and a single modular division:

```
if (x < x_min)
x = x_max - (x_min - x) % (x_max - x_min);
else
x = x_min + (x - x_min) % (x_max - x_min);
```

Unless `x`

is not far from `x_min`

and `x_max`

, and is reachable with very few sums or subtractions (think also *error propagation*), I think the modulo is your only available method.

# Without division

Keeping in mind that error propagation might become relevant, we can do this with a cycle:

```
d = x_max - x_min;
if (abs(d) < MINIMUM_PRECISION) {
return x_min; // Actually a divide by zero error :-)
}
while (x < x_min) {
x += (x_max - x_min);
}
while (x > x_max) {
x -= (x_max - x_min);
}
```

# Note on probabilities

The use of modular arithmetic has some statistical implications (floating point arithmetic also would have different ones).

For example say we wrap a random value between 0 and 5 included (e.g. a six-sided dice result) into a [0,1] range (i.e. a coin flip). Then

```
0 -> 0 1 -> 1
2 -> 0 3 -> 1
4 -> 0 5 -> 1
```

if the input has flat spectrum, i.e., every number (0-5) has 1/6 probability, the output will also be flat, and each item will have 3/6 = 50% probability.

But if we had a five-sided dice (0-4), or if we had a random number between 0 and 32767 and wanted to reduce it in the (0, 99) range to get a percentage, the output would not be flat, and some number would be slightly (or not so slightly) more likely than others. In the five-sided dice to coin-flip case, heads vs. tails would be 60%-40%. In the 32767-to-percent case, percentages below 67 would be CEIL(32767/100)/FLOOR(32767/100) = 0.3% more likely to come up than the others.

So, if one wanted a flat output, one would have to ensure that (max-min) was a divisor of the input range. In the case of 32767 and 100, the input range would have to be truncated at the nearest hundred (minus one), 32699, so that (0-32699) contained 32700 outcomes. Whenever the input was >= 32700, the input function would have to be called again to obtain a new value:

```
function reduced() {
#ifdef RECURSIVE
int x = get_random();
if (x > MAX_ALLOWED) {
return reduced(); // Retry
}
#else
for (;;) {
int x = get_random();
int d = x_max - x_min;
if (x > MAX_ALLOWED) {
continue; // Retry
}
return x_min + (
(
(x - x_min) % d
) + d
) % d;
}
#endif
```

When (INPUTRANGE%OUTPUTRANGE)/(INPUTRANGE) is significant, the overhead might be considerable (e.g. reducing 0-197 to 0-99 requires making roughly twice as many calls).

If the input range is less than the output range (e.g. we have a coin flipper and we want to make a dice tosser), multiply (do not add) using Horner's algorithm as many times as required to get an input range which is larger. Coin flip has a range of 2, CEIL(LN(OUTPUTRANGE)/LN(INPUTRANGE)) is 3, so we need three multiplications:

```
for (;;) {
x = ( flip() * 2 + flip() ) * 2 + flip();
if (x < 6) {
break;
}
}
```

or to get a number between 122 and 221 (range=100) out of a dice tosser:

```
for (;;) {
// ROUNDS = 1 + FLOOR(LN(OUTPUTRANGE)/LN(INPUTRANGE)) and can be hardwired
// INPUTRANGE is 6
// x = 0; for (i = 0; i < ROUNDS; i++) { x = 6*x + dice(); }
x = dice() + 6 * (
dice() + 6 * (
dice() /* + 6*... */
)
);
if (x < 200) {
break;
}
}
// x is now 0..199, x/2 is 0..99
y = 122 + x/2;
```

`Math.Min(Math.Max(x_min, x), x_max)`

I doubt that involves floating point division. – JLRishe Jan 19 '13 at 15:23explainwhat your formula is actually doing beyond that it's "wrapping", because I think everyone here, including myself, has yet to really understand what it is you're trying to achieve. – JLRishe Jan 19 '13 at 16:16