# Wrap value into range [min,max] without division

Is there any way in C# to wrap a given value x between x_min and x_max. The value should not be clamped as in `Math.Min/Max` but wrapped like a `float` modulus.

A way to implement this would be:

``````x = x - (x_max - x_min) * floor( x / (x_max - x_min));
``````

However, I am wondering if there is an algorithm or C# method that implements the same functionality without divisions and without the likely float-limited-precision issues that may arise when the value lies far away from the desired range.

-
What do you mean between two number, you could just use an if statement –  msarchet Jan 19 '13 at 15:22
What is the purpose of doint that? –  AgentFire Jan 19 '13 at 15:23
What's the purpose of this formula? If you want to keep x between two values, wouldn't this do the job? `Math.Min(Math.Max(x_min, x), x_max)` I doubt that involves floating point division. –  JLRishe Jan 19 '13 at 15:23
The above formula implements wrapping and not clamping. Math.Min/Max would simply cut off values which I do not want. Think of wrapping angles between 0 and 2pi but the above is more general. –  pad_ares Jan 19 '13 at 15:33
I haven't voted it down, but tt doesn't fit well with StackOverflow in its current state because you have yet to really explain your problem or what you are trying to do. I added a "non-clamping" division-less answer below, but now I realize you seem to be concerned with precision and not performance. Could you please explain what 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

``````x = x<x_min?  x_min:
x>x_max?  x_max:x;
``````

Its a little convoluted, and you can definitely break it into a pair of if statements.. But I don't see the need for division to begin with.

Edit:

I seem to have missunderstood, le

``````x = x<x_min?  x_max - (x_min - x):
x>x_max?  x_min + (x - x_max):x;
``````

This would work if your value of x does not vary too much.. which might work depending on the use case. Else for a more robust version I expect you need divide or repeated (recursive?) subtraction atleast.

This should be a more robust version which keeps performing the above calculation until x is stable.

``````int x = ?, oldx = x+1; // random init value.

while(x != oldx){
oldx = x;
x = x<x_min?  x_max - (x_min - x):
x>x_max?  x_min + (x - x_max):x;
}
``````
-
That seems more like a clamp, rather than 'wrapping'. –  JasonD Jan 19 '13 at 15:23
@JasonD ah yes, didnt see his last statement –  Karthik T Jan 19 '13 at 15:25
Thanks but I do not want to clamp but wrap (also, I improved my question). –  pad_ares Jan 19 '13 at 15:50
@pad_ares See my edit for an answer. –  Karthik T Jan 19 '13 at 15:56

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;
``````
-

Modulo works fine on floating point, so how about:

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

It's still effectively a divide though, and you need to tweak it for values less < min...

You are worrying about accuracy when the number is far away from the range. However this is not related to the modulo operation, however it is performed, but is a property of floating point. If you take a number between 0 and 1, and you add a large constant to it, say to bring it into the range 100 to 101, it will lose some precision.

-

Are min and max fixed values? If so, you could figure out their range and the inverse of that in advance:

``````const decimal x_min = 5.6m;
const decimal x_max = 8.9m;
const decimal x_range = x_max - x_min;
const decimal x_range_inv = 1 / x_range;

public static decimal WrapValue(decimal x)
{
return x - x_range * floor(x * x_range_inv);
}
``````

The multiplication should perform somewhat better than division.

-
Thank, thats a great idea! –  pad_ares Jan 19 '13 at 16:16
I'd test that extensively, both performance-wise and precision-wise; you have two multiplications and a conversion in there. If the range is small, and x is very near the beginning of the range, I think you might experience problems. Actually, it would be good to have a couple of test cases. –  lserni Jan 20 '13 at 21:41

How about using an extension method on `IComparable`.

``````public static class LimitExtension
{
public static T Limit<T>(this T value, T min, T max)
where T : IComparable
{
if (value.CompareTo(min) < 0) return min;
if (value.CompareTo(max) > 0) return max;

return value;
}
}
``````

And a unit test:

``````public class LimitTest
{
[Fact]
public void Test()
{
int number = 3;

Assert.Equal(3, number.Limit(0, 4));
Assert.Equal(4, number.Limit(4, 6));
Assert.Equal(1, number.Limit(0, 1));

}
}
``````
-
Thanks for your answer but I do not want to clamp but wrap (see improved question). –  pad_ares Jan 19 '13 at 15:50

LinqPad SAMPLE CODE (Restricted to 3 decimal places)

``````void Main()
{
Test(int.MinValue, 0, 1,0.1f, "value = int.MinValue");
Test(int.MinValue, -2,- 1,0.1f, "value = int.MinValue");
Test(int.MaxValue, 0, 1,0.1f, "value = int.MaxValue");
Test(int.MaxValue, -2,- 1,0.1f, "value = int.MaxValue");
Test(-2,-2,-1,0.1f, string.Empty);
Test(0,0,1,0.1f, string.Empty);
Test(1,1,2,0.1f, string.Empty);

Test(int.MinValue, 0, 1, -0.1f, "value = int.MinValue");
Test(int.MinValue, -2,- 1, -0.1f, "value = int.MinValue");
Test(int.MaxValue, 0, 1, -0.1f, "value = int.MaxValue");
Test(int.MaxValue, -2,- 1, -0.1f, "value = int.MaxValue");
Test(-2,-2,-1, -0.1f, string.Empty);
Test(0,0,1, -0.1f, string.Empty);
Test(1,1,2, -0.1f, string.Empty);
}

private void Test(float value, float min ,float max, float direction, string comment)
{
"".Dump("    " + min + " to " + max + " direction = " + direction + "   " + comment);
for (int i = 0; i < 11; i++)
{
value = (float)Math.Round(min + ((value - min) % (max - min)), 3);
string.Format("    {1} -> value: {0}", value,  i).Dump();
value = value + direction < min && direction < 0 ? max + direction : value + direction;
}
}
``````

RESULTS

``````0 to 1 direction = 0.1   value = int.MinValue

0 -> value: 0
1 -> value: 0.1
2 -> value: 0.2
3 -> value: 0.3
4 -> value: 0.4
5 -> value: 0.5
6 -> value: 0.6
7 -> value: 0.7
8 -> value: 0.8
9 -> value: 0.9
10 -> value: 0

-2 to -1 direction = 0.1   value = int.MinValue

0 -> value: -2
1 -> value: -1.9
2 -> value: -1.8
3 -> value: -1.7
4 -> value: -1.6
5 -> value: -1.5
6 -> value: -1.4
7 -> value: -1.3
8 -> value: -1.2
9 -> value: -1.1
10 -> value: -2

0 to 1 direction = 0.1   value = int.MaxValue

0 -> value: 0
1 -> value: 0.1
2 -> value: 0.2
3 -> value: 0.3
4 -> value: 0.4
5 -> value: 0.5
6 -> value: 0.6
7 -> value: 0.7
8 -> value: 0.8
9 -> value: 0.9
10 -> value: 0

-2 to -1 direction = 0.1   value = int.MaxValue

0 -> value: -2
1 -> value: -1.9
2 -> value: -1.8
3 -> value: -1.7
4 -> value: -1.6
5 -> value: -1.5
6 -> value: -1.4
7 -> value: -1.3
8 -> value: -1.2
9 -> value: -1.1
10 -> value: -2

-2 to -1 direction = 0.1

0 -> value: -2
1 -> value: -1.9
2 -> value: -1.8
3 -> value: -1.7
4 -> value: -1.6
5 -> value: -1.5
6 -> value: -1.4
7 -> value: -1.3
8 -> value: -1.2
9 -> value: -1.1
10 -> value: -2

0 to 1 direction = 0.1

0 -> value: 0
1 -> value: 0.1
2 -> value: 0.2
3 -> value: 0.3
4 -> value: 0.4
5 -> value: 0.5
6 -> value: 0.6
7 -> value: 0.7
8 -> value: 0.8
9 -> value: 0.9
10 -> value: 0

1 to 2 direction = 0.1

0 -> value: 1
1 -> value: 1.1
2 -> value: 1.2
3 -> value: 1.3
4 -> value: 1.4
5 -> value: 1.5
6 -> value: 1.6
7 -> value: 1.7
8 -> value: 1.8
9 -> value: 1.9
10 -> value: 1

0 to 1 direction = -0.1   value = int.MinValue

0 -> value: 0
1 -> value: 0.9
2 -> value: 0.8
3 -> value: 0.7
4 -> value: 0.6
5 -> value: 0.5
6 -> value: 0.4
7 -> value: 0.3
8 -> value: 0.2
9 -> value: 0.1
10 -> value: 0

-2 to -1 direction = -0.1   value = int.MinValue

0 -> value: -2
1 -> value: -1.1
2 -> value: -1.2
3 -> value: -1.3
4 -> value: -1.4
5 -> value: -1.5
6 -> value: -1.6
7 -> value: -1.7
8 -> value: -1.8
9 -> value: -1.9
10 -> value: -2

0 to 1 direction = -0.1   value = int.MaxValue

0 -> value: 0
1 -> value: 0.9
2 -> value: 0.8
3 -> value: 0.7
4 -> value: 0.6
5 -> value: 0.5
6 -> value: 0.4
7 -> value: 0.3
8 -> value: 0.2
9 -> value: 0.1
10 -> value: 0

-2 to -1 direction = -0.1   value = int.MaxValue

0 -> value: -2
1 -> value: -1.1
2 -> value: -1.2
3 -> value: -1.3
4 -> value: -1.4
5 -> value: -1.5
6 -> value: -1.6
7 -> value: -1.7
8 -> value: -1.8
9 -> value: -1.9
10 -> value: -2

-2 to -1 direction = -0.1

0 -> value: -2
1 -> value: -1.1
2 -> value: -1.2
3 -> value: -1.3
4 -> value: -1.4
5 -> value: -1.5
6 -> value: -1.6
7 -> value: -1.7
8 -> value: -1.8
9 -> value: -1.9
10 -> value: -2

0 to 1 direction = -0.1

0 -> value: 0
1 -> value: 0.9
2 -> value: 0.8
3 -> value: 0.7
4 -> value: 0.6
5 -> value: 0.5
6 -> value: 0.4
7 -> value: 0.3
8 -> value: 0.2
9 -> value: 0.1
10 -> value: 0

1 to 2 direction = -0.1

0 -> value: 1
1 -> value: 1.9
2 -> value: 1.8
3 -> value: 1.7
4 -> value: 1.6
5 -> value: 1.5
6 -> value: 1.4
7 -> value: 1.3
8 -> value: 1.2
9 -> value: 1.1
10 -> value: 1
``````
-

use Wouter de Kort's answer but change

``````if (value.CompareTo(max) > 0) return max;
``````

to

``````if (value.CompareTo(max) > 0) return min;
``````
-
That will not work. If the range is 0-5 for instance, then 7 should give 1, 8 should give 2 etc. This code would produce 0 for any number greater than 5 in that scenario. –  odyss-jii Jan 19 '13 at 16:03
This is a clamp; not a wrap. OP wants a wrap between +/-180 or 0...360, etc. –  geowar Mar 28 at 15:42