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 += d;
}
while (x > x_max) {
x -= d;
}
```

# 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.

(To see this more clearly, consider the number to be from "00000" to "32767": once every 328 throws, the first three digits of the number will be "327". When this happens, the last two digits can only go from "00" to "67", they cannot be "68" to "99" because 32768 is out of range. So, digits from 00 to 67 are slightly more likely.

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
}
}
#endif
return x_min + (
(
(x - x_min) % d
) + d
) % d;
```

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.explainwhat 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.2more comments