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I am looking for an appropriate way to calculate the rectangular bounding box of a triangle shape which has three corners given as points - (x1,y1), (x2,y2), (x3,y3).

Here is the data type that I am using (as suggested, I added more constructors):

data Shape =
     Circle Point Double |
     Rectangle Point Point |
     Triangle Point Point Point

The bounding box function should be of the form "bounding :: Shape -> Shape". I have also tried the bounding boxes of a rectangle and a circle:

bounding :: Shape -> Shape
bounding (Rectangle (Point x y) (Point z z1)) = (Rectangle (Point x y) (Point z z1))
bounding (Circle (Point p w) r) = (Rectangle (Point (p-r) (w-r)) (Point (p+r) (w+r)))

Are these right provided that the graphics coordinate system should be used (where (x,y) coordinates should be treated as (x,-y) instead)?

Could someone give me a helping hand please? P.S. No graphics library is required.

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1  
Surely your output type should be some kind of bounding box instead of another triangle? –  dave4420 Mar 22 '13 at 19:15
    
@dave4420 Yes, the output should only be an encompassing rectangle. –  Warditive Mar 22 '13 at 19:23
1  
But your type for Shape only lists triangles as possible shapes. Are you omitting something? –  Joachim Breitner Mar 22 '13 at 19:24

3 Answers 3

I'm only posting this answer to make the point that bounding boxes and rectangles are not the same things.

data Point = Point Double Double   -- Point x y

data BoundingBox = BoundingBox Double Double Double Double
                            -- top    left   bottom right

data Shape
    = Circle Point Double
    | Rectangle Point Point Double
        -- yes, you need two points and a scalar to specify arbitrary rectangles
    | Triangle Point Point Point

boundingBox :: Shape -> BoundingBox
boundingBox (Circle (Point x y) r) = BoundingBox (y-r) (x-r) (y+r) (x+r)
boundingBox (Rectangle (Point x0 y0) (Point x1 y1) d)
        = BoundingBox (minimum ys) (minimum xs) (maximum ys) (maximum xs) where
    xs = [x0, x1, x1+dx, x0+dx]
    ys = [y0, y1, y1+dy, y0+dy]
    d' = d / ((x0-x1)^^2 + ((y0-y1)^^2)
    dx = d' * (y0-y1)
    dy = d' * (x1-x0)
boundingBox (Triangle (Point x0 y0) (Point x1 y1) (Point x2 y2))
        = BoundingBox (minimum ys) (minimum xs) (maximum ys) (maximum xs) where
    xs = [x0, x1, x2]
    ys = [y0, y1, y2]

As an exercise, factor out the common code from the Rectangle and Triangle cases. (Bonus points for finding and fixing any bugs I've placed in the Rectangle case.)

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1  
I presume that your Rectangle is not required to be aliged with the axes. However, with three points, you can specify things that don't have a 90-degree corner. You only need two points and a scalar. The points specify the length and angle of one side, and the scalar specifies the length of the other perpendicular side. –  pat Mar 22 '13 at 20:56
    
Oh, good spot. Thank you. –  dave4420 Mar 22 '13 at 21:00

Based upon @dave4420's excellent observation, I am assuming that Rectangles are aligned with the x/y axes.

Based upon your rule for Circle, it appears the point with the smallest x,y comes first, and the point with the largest x,y comes second in the Rectangle.

You should probably stick to x and y with numeric suffixes instead of inventing new names like p, w, z and z1 which are very confusing.

The bounding box of a Rectangle is the Rectangle itself.

The bounding box of a Triangle is going to be a Rectangle with the smallest and largest x,y from any point.

bounding :: Shape -> Shape
bounding rect@(Rectangle _ _) = rect
bounding (Circle (Point x y) r) = Rectangle p1 p2 where
  p1 = (Point (x-r) (y-r))
  p2 = (Point (x+r) (y+r))
bounding (Triangle (Point x1 y1) (Point x2 y2) (Point x3 y3)) = Rectangle p1 p2 where
  p1 = Point (minimum [x1 x2 x3]) (minimum [y1 y2 y3])
  p2 = Point (maximum [x1 x2 x3]) (maximum [y1 y2 y3])
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What have you tried? Have you got any code?

You need:

 data Shape = Triangle Point Point Point | Rectangle Point Point

Assuming x increases to the right and y increases to the up. Upper left corner will be (min{x1, x2, x3}, max{y1, y2, y3}) and you need right lower corner.


Edit

x should increase to the right and y to the down. I added triangle one, deleted unnecessary parentheses and derived (Show) to be able to print Shape data type. Whole code for you:

data Point = Point Double Double deriving (Show)

data Shape =
        Circle Point Double |
        Rectangle Point Point |
        Triangle Point Point Point deriving (Show)

bounding :: Shape -> Shape
bounding (Rectangle (Point x y) (Point z z1)) = Rectangle (Point x y) (Point z z1)
bounding (Circle (Point p w) r) = Rectangle (Point (p-r) (w-r)) (Point (p+r) (w+r))
bounding (Triangle (Point x1 y1) (Point x2 y2) (Point x3 y3)) = Rectangle 
        (Point (minimum [x1, x2, x3]) (minimum [y1, y2, y3])) 
        (Point (maximum [x1, x2, x3]) (maximum [y1, y2, y3]))
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1  
Tyvm for your answer. Actually, y should increase to the down... (graphics coordinates requirement) –  Warditive Mar 22 '13 at 19:44
    
kyticka, please check the updated description above. –  Warditive Mar 22 '13 at 19:59
    
Best regards, kyticka! I am really grateful for your support! –  Warditive Mar 22 '13 at 21:02

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