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I'm trying to draw a gradient in a rectangle object, with a given angle (Theta), where the ends of the gradient are touching the perimeter of the rectangle.

Graph

I thought that using tangent would work, but I'm having trouble getting the kinks out. Is there an easy algorithm that I am just missing?

End Result

So, this is going to be a function of (angle, RectX1, RectX2, RectY1, RectY2). I want it returned in the form of [x1, x2, y1, y2], so that the gradient will draw across the square. In my problem, if the origin is 0, then x2 = -x1 and y2 = -y1. But it's not always going to be on the origin.

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3  
what does the picture have to do with the problem? Only one end of the line (I'm assuming the line is the hypotenuse in this case) touches the boundary. will the line always pass through (or, as pictured, start at) the origin? –  aaronasterling Oct 31 '10 at 2:42
    
@aaronasterling, It's my understanding of what I am trying to achieve. I need both X and Y. The triangle will change based on the angle. –  bradlis7 Oct 31 '10 at 3:04

4 Answers 4

up vote 15 down vote accepted

Let's call a and b your rectangle sides, and (x0,y0) the coordinates of your rectangle center.

You have four regions to consider:

alt text

    Region    from               to                 Where
    ====================================================================
       1      -arctan(b/a)       +arctan(b/a)       Right green triangle
       2      +arctan(b/a)        π-arctan(b/a)     Upper yellow triangle
       3       π-arctan(b/a)      π+arctan(b/a)     Left green triangle
       4       π+arctan(b/a)     -arctan(b/a)       Lower yellow triangle

With a little of trigonometry-fu, we can get the coordinates for your desired intersection in each region.

alt text

So Z0 is the expression for the intersection point for regions 1 and 3
And Z1 is the expression for the intersection point for regions 2 and 4

The desired lines pass from (X0,Y0) to Z0 or Z1 depending the region. So remembering that Tan(φ)=Sin(φ)/Cos(φ)


    Lines in regions      Start                   End
    ======================================================================
       1 and 3           (X0,Y0)      (X0 + a/2 , (a/2 * Tan(φ))+ Y0
       2 and 4           (X0,Y0)      (X0 + b/(2* Tan(φ)) , b/2 + Y0)

Just be aware of the signs of Tan(φ) in each quadrant, and that the angle is always measured from THE POSITIVE x axis ANTICLOCKWISE.

HTH!

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Nice job! I'll see what I can do with this info. –  bradlis7 Nov 1 '10 at 23:39
    
Excellent answer! Thank you! –  BillyBBone Feb 26 '12 at 8:06
    
I don't understand what the two angles φ and θ represent in your answer or the other answer -- doesn't the question only specify one angle? And shouldn't there be a different x coordinate for the intersecting / end point in region 1 compared to 3 (and a different y coordinate for the intersecting point in region 2 compared to 4)? –  Victor Van Hee Mar 2 '12 at 1:20
    
@VictorVanHee: the angles are the angle from the center point. He used 2 letters to indicate that they are different possible code-paths but, in the formulas, it's just "theta" (or whatever variable you use.) –  Olie Oct 31 '14 at 20:39
1  
@Olie: The end position in region 2 has an X value lower than X0 (it's left of it, after all), making x(end)=X0 - a/2 (note the minus sign instead of the plus) the proper way to calculate X in region 2. Similarly, in region 4, the Y value is calculated by Y(end)=Y0 - b/2. –  Felix Alcala Jun 11 at 22:02

Following your picture, I'm going to assume that the rectangle is centered at (0,0), and that the upper right corner is (w,h). Then the line connecting (0,0) to (w,h) forms an angle φ with the X axis, where tan(φ) = h/w.

Assuming that θ > φ, we are looking for the point (x,y) where the line that you have drawn intersects the top edge of the rectangle. Then y/x = tan(θ). We know that y=h so, solving for x, we get x = h/tan(θ).

If θ < φ, the line intersects with the right edge of the rectangle at (x,y). This time, we know that x=w, so y = tan(θ)*w.

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Ok, whew!, I finally got this one.

NOTE: I based this off of belisarius's awesome answer. If you like this, please like his, too. All I did was turn what he said into code.

Here's what it looks like in Objective-C. It should be simple enough to convert to whatever your favorite language is.

+ (CGPoint) edgeOfView: (UIView*) view atAngle: (float) theta
{
    // Move theta to range -M_PI .. M_PI
    const double twoPI = M_PI * 2.;
    while (theta < -M_PI)
    {
        theta += twoPI;
    }

    while (theta > M_PI)
    {
        theta -= twoPI;
    }

    // find edge ofview
    // Ref: http://stackoverflow.com/questions/4061576/finding-points-on-a-rectangle-at-a-given-angle
    float aa = view.bounds.size.width;                                          // "a" in the diagram
    float bb = view.bounds.size.height;                                         // "b"

    // Find our region (diagram)
    float rectAtan = atan2f(bb, aa);
    float tanTheta = tan(theta);

    int region;
    if ((theta > -rectAtan)
    &&  (theta <= rectAtan) )
    {
        region = 1;
    }
    else if ((theta >  rectAtan)
    &&       (theta <= (M_PI - rectAtan)) )
    {
        region = 2;
    }
    else if ((theta >   (M_PI - rectAtan))
    ||       (theta <= -(M_PI - rectAtan)) )
    {
        region = 3;
    }
    else
    {
        region = 4;
    }

    CGPoint edgePoint = view.center;
    float xFactor = 1;
    float yFactor = 1;

    switch (region)
    {
        case 1: yFactor = -1;       break;
        case 2: yFactor = -1;       break;
        case 3: xFactor = -1;       break;
        case 4: xFactor = -1;       break;
    }

    if ((region == 1)
    ||  (region == 3) )
    {
        edgePoint.x += xFactor * (aa / 2.);                                     // "Z0"
        edgePoint.y += yFactor * (aa / 2.) * tanTheta;
    }
    else                                                                        // region 2 or 4
    {
        edgePoint.x += xFactor * (bb / (2. * tanTheta));                        // "Z1"
        edgePoint.y += yFactor * (bb /  2.);
    }

    return edgePoint;
}

In addition, here's a little test-view I created to verify that it works. Create this view and put it somewhere, it will make another little view scoot around the edge.

@interface DebugEdgeView()
{
    int degrees;
    UIView *dotView;
    NSTimer *timer;
}

@end

@implementation DebugEdgeView

- (void) dealloc
{
    [timer invalidate];
}


- (id) initWithFrame: (CGRect) frame
{
    self = [super initWithFrame: frame];
    if (self)
    {
        self.backgroundColor = [[UIColor magentaColor] colorWithAlphaComponent: 0.25];
        degrees = 0;
        self.clipsToBounds = NO;

        // create subview dot
        CGRect dotRect = CGRectMake(frame.size.width / 2., frame.size.height / 2., 20, 20);
        dotView = [[DotView alloc] initWithFrame: dotRect];
        dotView.backgroundColor = [UIColor magentaColor];
        [self addSubview: dotView];

        // move it around our edges
        timer = [NSTimer scheduledTimerWithTimeInterval: (5. / 360.)
                                                 target: self
                                               selector: @selector(timerFired:)
                                               userInfo: nil
                                                repeats: YES];
    }

    return self;
}


- (void) timerFired: (NSTimer*) timer
{
    float radians = ++degrees * M_PI / 180.;
    if (degrees > 360)
    {
        degrees -= 360;
    }

    dispatch_async(dispatch_get_main_queue(), ^{
        CGPoint edgePoint = [MFUtils edgeOfView: self atAngle: radians];
        edgePoint.x += (self.bounds.size.width  / 2.) - self.center.x;
        edgePoint.y += (self.bounds.size.height / 2.) - self.center.y;
        dotView.center = edgePoint;
    });
}

@end
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There's a good (more programmatic iOS / Objective-C) answer to this question at Find the CGPoint on a UIView rectangle intersected by a straight line at a given angle from the center point involving the following steps:

  1. Assume that the angle is greater than or equal to 0 and less than 2*π, going counterclockwise from 0 (East).
  2. Get the y coordinate of the intersection with the right edge of the rectangle [tan(angle)*width/2].
  3. Check whether this y coordinate is in the rectangle frame (absolute value less than or equal to half the height).
  4. If the y intersection is in the rectangle, then if the angle is less than π/2 or greater than 3π/2 choose the right edge (width/2, -y coord). Otherwise choose the left edge (-width/2, y coord).
  5. If the y coordinate of the right edge intersection was out-of-bounds, calculate the x coordinate of the intersection with the bottom edge [half the height/tan(angle)].
  6. Next determine whether you want the top edge or the bottom edge. If the angle is less than π, we want the bottom edge (x, -half the height). Otherwise, we want the top edge (-x coord, half the height).
  7. Then (if the center of the frame is not 0,0), offset the point by the actual center of the frame.
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