# Shorten a line by a number of pixels

I'm drawing a custom diagram of business objects using .NET GDI+. Among other things, the diagram consists of several lines that are connecting the objects.

In a particular scenario, I need to shorten a line by a specific number of pixels, let's say 10 pixels, i.e. find the point on the line that lies 10 pixels before the end point of the line.

Imagine a circle with radius r = 10 pixels, and a line with start point (x1, y1) and end point (x2, y2). The circle is centered at the end point of the line, as in the following illustration.

How do I calculate the point marked with a red circle, i.e. the intersection between circle and line? This would give me the new end point of the line, shortening it by 10 pixels.

## Solution

Thank you for your answers from which I was able to put together the following procedure. I named it LengthenLine, since I find it more natural to pass a negative number of pixels if I want the line shortened.

Specifically, I was trying to put together a function that could draw a line with rounded corners, which can be found here.

``````public void LengthenLine(PointF startPoint, ref PointF endPoint, float pixelCount)
{
if (startPoint.Equals(endPoint))
return; // not a line

double dx = endPoint.X - startPoint.X;
double dy = endPoint.Y - startPoint.Y;
if (dx == 0)
{
// vertical line:
if (endPoint.Y < startPoint.Y)
endPoint.Y -= pixelCount;
else
endPoint.Y += pixelCount;
}
else if (dy == 0)
{
// horizontal line:
if (endPoint.X < startPoint.X)
endPoint.X -= pixelCount;
else
endPoint.X += pixelCount;
}
else
{
// non-horizontal, non-vertical line:
double length = Math.Sqrt(dx * dx + dy * dy);
double scale = (length + pixelCount) / length;
dx *= scale;
dy *= scale;
endPoint.X = startPoint.X + Convert.ToSingle(dx);
endPoint.Y = startPoint.Y + Convert.ToSingle(dy);
}
}
``````
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I'm glad you're trying to shorten a finite line. Cause I don't know how the heck I'd go about shortening an infinite one :-) –  paxdiablo Dec 8 '09 at 13:33
Haha, d'oh. A result of rephrasing the title several times. I'll change it once more :) –  mbjdev Dec 8 '09 at 13:39
I think the term you were looking for is 'line segment' =) –  Erik Forbes Dec 8 '09 at 13:50

Find the direction vector, i.e. let the position vectors be (using floats) B = (x2, y2) and A = (x1, y1), then AB = B - A. Normalize that vector by dividing by its length ( Math.Sqrt(x*x + y*y) ). Then multiply the direction vector AB by the original length minus the circle's radius, and add back to the lines starting position:

``````double dx = x2 - x1;
double dy = y2 - y1;
double length = Math.Sqrt(dx * dx + dy * dy);
if (length > 0)
{
dx /= length;
dy /= length;
}
int x3 = (int)(x1 + dx);
int y3 = (int)(y1 + dy);
``````

Edit: Fixed the code, aaand fixed the initial explanation (thought you wanted the line to go out from the circle's center to its perimeter :P)

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Thanks, I appreciate the example code. –  mbjdev Dec 8 '09 at 13:55
You even be able to "optimize" (not as in micro-optimization) it a little, by precalculating the multiplication factor `double scale = (length - radius) / length`, but I tend to think in stepwise vector operations. –  Cecil Has a Name Dec 8 '09 at 14:06

You can use similar triangles. For the main triangle, `d` is the hypotenuses and the extension of `r` is the vertical line that meets the right angle. Inside the circle you will have a smaller triangle with a hypotenuses of length `r`.

```r/d = (x2-a0)/(x2-x1) = (y2-b0)/(y2-y1)

a0 = x2 + (x2-x1)r/d

b0 = y2 + (y2-y1)r/d
```
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@unholysampler: I've contributed my handdrawn pic. If you don't like it, just rollback :-) –  dtb Dec 8 '09 at 13:46
Nice drawing ;) Thanks. –  mbjdev Dec 8 '09 at 13:56
Keep in mind you'll have to watch out for cases where the slope is infinite or zero (i.e., vertical and horizontal lines) or close enough to that to cause overflow - in those cases, your divisions will fail. –  paxdiablo Dec 8 '09 at 15:34

I'm not sure why you even had to introduce the circle. For a line stretching from `(x2,y2)` to `(x1,y1)`, you can calculate any point on that line as:

``````(x2+p*(x1-x2),y2+p*(y1-y2))
``````

where `p` is the percentage along the line you wish to go.

To calculate the percentage, you just need:

``````p = r/L
``````

So in your case, `(x3,y3)` can be calculated as:

``````(x2+(10/L)*(x1-x2),y2+(10/L)*(y1-y2))
``````

For example, if you have the two points `(x2=1,y2=5)` and `(x1=-6,y1=22)`, they have a length of sqrt(72 + 172 or 18.38477631 and 10 divided by that is 0.543928293. Putting all those figures into the equation above:

``````  (x2 + (10/l)      * (x1-x2) , y2 + (10/l)      * (y1-y2))
= (1  + 0.543928293 * (-6- 1) , 5  + 0.543928293 * (22- 5))
= (1  + 0.543928293 * -7      , 5  + 0.543928293 * 17     )
= (x3=-2.807498053,y3=14.24678098)
``````

The distance between `(x3,y3)` and `(x1,y1)` is sqrt(3.1925019472 + 7.7532190152) or 8.384776311, a difference of 10 to within one part in a thousand million, and that's only because of rounding errors on my calculator.

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I don't know why I introduced that damned circle. I'm obviously too tired to be pondering over these types of (simple) challenges. But thanks anyway for the simplification :) It makes complete sense. –  mbjdev Dec 8 '09 at 13:53