Optimize the performance of a GDI+ function

When profiling my GDI+ project I discovered that the following `IsLineVisible` function is one of the "hottest" while the drawing and moving objects on my custom panel.

Is there a possibility to optimize it?

``````  Private Function IsLineVisible(ByVal detectorRectangle As Rectangle,
ByVal pen As Pen,
ByVal ParamArray points() As Point) As Boolean
Using path As New GraphicsPath()
Return IsPathVisible(detectorRectangle, path, pen)
End Using
End Function

' Helper functions '''''''''''''''''''''''''''''''''''''
Private Function IsPathVisible(ByVal detectorRectangle As Rectangle,
ByVal path As GraphicsPath,
ByVal pen As Pen) As Boolean
If Not path.IsPoint Then
path.Widen(pen)
End If
Return IsPathVisible(detectorRectangle, path)
End Function

Private Function IsPathVisible(ByVal detectorRectangle As Rectangle,
ByVal path As GraphicsPath) As Boolean
Using r As New Region(path)
If r.IsVisible(detectorRectangle) Then
Return True
Else
Return False
End If
End Using
End Function
``````

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UPDATE 2:

``````    public bool AreLinesVisible(Point[] p, int width, Rectangle rect)
{
for (var i = 1; i < p.Length; i++)
if (IsLineVisible(p[i - 1], p[i], width, rect))
return true;
return false;
}
``````

UPDATED to include thickness/width.

This is completely untested code, but it should give you the basic idea for a hyper-fast solution with no expensive framwork calls:

``````public bool IsLineVisible(Point p1, Point p2, int width, Rectangle rect)
{
var a = Math.Atan2(p1.Y - p2.Y, p1.X - p2.X) + Math.PI/2;
var whalf = (width + 1)*0.5;
var dx = (int) Math.Round(whalf*Math.Sin(a));
var dy = (int) Math.Round(whalf*Math.Cos(a));
return IsLineVisible( new Point(p1.X - dx, p1.Y - dy), new Point(p2.X - dx, p2.Y - dy), rect)
|| IsLineVisible( new Point(p1.X + dx, p1.Y + dy), new Point(p2.X + dx, p2.Y + dy), rect);
}

public bool IsLineVisible(Point p1, Point p2, Rectangle rect)
{
if (p1.X > p2.X)  // make sure p1 is the leftmost point
return IsLineVisible(p2, p1, rect);

if (rect.Contains(p1) || rect.Contains(p2))
return true; // one or both end-points within the rect -> line is visible

//if both points are simultaneously left or right or above or below -> line is NOT visible
if (p1.X < rect.X && p2.X < rect.X)
return false;
if (p1.X >= rect.Right && p2.X >= rect.Right)
return false;
if (p1.Y < rect.Y && p2.Y < rect.Y)
return false;
if (p1.Y >= rect.Bottom && p2.Y >= rect.Bottom)
return false;

// now recursivley break down the line in two part and see what happens
// (this is an approximation...)
var pMiddle = new Point((p1.X + p2.X)/2, (p1.Y + p2.Y)/2);
return IsLineVisible(p1, new Point(pMiddle.X - 1, pMiddle.Y), rect)
|| IsLineVisible(new Point(pMiddle.X + 1, pMiddle.Y), p2, rect);
}
``````
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thanks. But you "forgot" the Pen's Width (thickness). –  serhio Oct 11 '11 at 17:18
Yes, but i said the basic idea - you just have to calculate the two contour lines that makes up your thick line and pass them both. If one of them is visible - then your thick line is visible! –  Dan Byström Oct 11 '11 at 17:26
the line could also have a style: dotted, dashed... –  serhio Oct 11 '11 at 18:55
Is a dashed line any more or less visible within a rectangle??? Are you after the exact pixel overlap when the dashed line just touch the corner of the rectangle? –  Dan Byström Oct 11 '11 at 19:45
C# and VB.Net differs here. An integer divided by an integer doesn't result in a double in C#. In VB.Net I guess you could use "\" for integer division. You could in plain old VB, at least. –  Dan Byström Oct 19 '11 at 8:36

The only thing I can see is perhaps using a wider/thicker `Pen`.

This will let the method recurse less and cut down the calls to `Widen` without losing too much of the effect (I hope on the last one).

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I cand use other pen that I pass as argument... this is all the point. I hae some wide lines, other thick lines, so I should detect different types of line... –  serhio Oct 11 '11 at 16:26

Instead of creating a path, which is a very expensive GDI construct, how about looping through your points, connecting that point with the previous point, and checking to see if that line intersects with your rectangle?

It should be less computationally expensive, with the bonus of being able to stop the loop on the first segment to intersect the rectangle.

This other post should help with the intersection test. How to find the intersection point between a line and a rectangle?

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the idea is the PEN, can be different. is not just a one line pixel story. –  serhio Oct 11 '11 at 16:09