# Clamping a value to a range (sort of)

I have a slider that returns values from 0.0f to 1.0f.

I want to use this value and clamp it to MIN and MAX, but not exactly clamp.

Say min is 0.2f and max is 0.3f. When the slider would be at 0, I want 0.2f. When the slider is at 0.5f, I want 0.25f, and so on.

It's just so that the effect of the slider is not as strong.

given MIN MAX and sliderVal, how could I clamp the sliderVal?

Thanks

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This is called a "linear interpolation". –  DeadMG Jun 30 '12 at 5:48

slider_range = slider_max - slider_min;
range = range_max - range_min;

value = (double)(slider_pos - slider_min) / slider_range * range + range_min;
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This assumes that slider_min is zero... –  Oli Charlesworth Jun 30 '12 at 10:52
@OliCharlesworth: Oops -- I think I've fixed that. Thanks. –  Jerry Coffin Jun 30 '12 at 15:45

Assuming you want the slider to linearly change between 0.2f and 0.3f, then the transformation from the interval [0.0 1.0] to [0.2 0.3] is trivial:

newVal = 0.2f + (sliderVal)*0.1f;

Looking at this from a mathematical perspective, you want the output to be linear with respect to the input, according to your desciption. Thus, the transfer function between the input and output values must be of the form:

y = mx + b

Consider the x value to be the input (the slider value), and the y value to be the output (the new, desired value). Thus, you have two points: (0.0, 0.2) and (1.0, 0.3) Substitute these points into the above equation:

0.2 = (0.0)m + b
0.3 = (1.0)m + b

You now have a system of linear equations which are trivial to solve for:

0.2 = (0.0)m + b --> b = 0.2
0.3 = (1.0)m + b --> 0.3 = m + 0.2 --> m = 0.1

Thus, the transfer function is:

y = 0.1 * x + 0.2

Q.E.D.

We can generalize the above process. Instead of using points (0.0, 0.2) and (1.0, 0.3), use points (minSlider, maxSlider) and (minValue, maxValue).

minValue = (minSlider)m + b
maxValue = (maxSlider)m + b

Elimate the variable b:

minValue = (minSlider)m + b
-maxValue = -(maxSlider)m - b

--> minValue-maxValue = (minSlider-maxSlider)m
m = (minValue-maxValue)/(minSlider-maxSlider)

Eliminate the variable m:

minValue*maxSlider = (minSlider*maxSlider)m + b*maxSlider
-maxValue*minSlider = -(minSlider*maxSlider)m - b*minSlider

--> minValue*maxSlider - maxValue*minSlider = b(maxSlider-minSlider)
b = (minValue*maxSlider - maxValue*minSlider)/(maxSlider-minSlider)

You can verify that these equations give you the exact same values for m and b. If we assume that the minimum slider value will always be 0.0:

m = (minValue-maxValue)/(minSlider-maxSlider)
b = (minValue*maxSlider - maxValue*minSlider)/(maxSlider-minSlider)

--> m = (maxValue-minValue)/(maxSlider)
b = minValue

In C++:

const double maxSlider = 1.0;
const double minValue = 0.2;
const double maxValue = 0.3;
double value = (maxValue-minValue)/(maxSlider)*getSliderPosition() + minValue;
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lots of numbers is good, but you dont show the generic form like the other answers –  Mooing Duck Jun 30 '12 at 4:47
@Mooing Duck: The idea is to let the O.P. know how to arrive at the answer, and not just give the formula and let the OP use it without thinking. :-) –  In silico Jun 30 '12 at 4:49