zhaw-fup/Exercises/exercise-6/Shapes.hs

module Shape where

import Data.List
import Matrix (Matrix (Matrix), Vector, Point, invert, apply)

{- Definition of 'Shape'
    Shapes are things that discriminate between outside and inside
-}
newtype Shape = Shape { inside :: Point -> Bool }

{- Basic Shapes
    These are the basic shapes used to construct more complicated shapes
-}

{-
    A simple empty shape
-}
empty :: Shape
empty = Shape $ const False

{-
    A disc with radius 1 located at (0,0)
-}
unitDisc :: Shape
unitDisc = Shape $ \(x, y) ->
    x^2 + y^2 <= 1

{-
    A square with length/width 1 located at (0,0)
-}
unitSq :: Shape
unitSq = Shape $ \(x, y) ->
    abs x <= 1 && abs y <= 1

{- Manipulations
   Functions to change and combine existing shapes into new shapes
-}

{- Translation
    Moving a shape along a vector
-}
translate :: Vector -> Shape -> Shape
translate (dx, dy) s = Shape $ \(x, y) ->
    error "Fixme"

{- Inverting
    Inverting a shape i.e. switching outside vs inside
-}
negate :: Shape -> Shape
negate s = error "Fixme"

{- General combinator
    Combining two shapes with a parametric boolean function
-}
combineBool
    :: (Bool -> Bool -> Bool)
    -> Shape
    -> Shape
    -> Shape
combineBool f s1 s2 = Shape $ \p -> f (f1 p) (f2 p)
    where
        f1 = inside s1
        f2 = inside s2

{-
    All points that are in both shapes
-}
intersect :: Shape -> Shape -> Shape
intersect = error "Fixme"

{-
    All points that in at least one of the shapes
-}
merge :: Shape -> Shape -> Shape
merge = error "Fixme"

{-
    All points in the first shape that are not in the secnond shape
-}
minus :: Shape -> Shape -> Shape
minus = error "Fixme"


{- Matrix transformations
    Applying a matrix/linear transformation to a shape
-}
transformM :: Matrix -> Shape -> Shape
transformM m s = Shape $ \p ->
    inside s $ apply m' p
    where
        m' = invert m

{-
    Stretch a shape along the X axis
-}
stretchX :: Float -> Shape -> Shape
stretchX r = transformM $ Matrix (r, 0) (0, 1)

{-
    Stretch a shape along the Y axis
-}
stretchY :: Float -> Shape -> Shape
stretchY r = transformM $ Matrix (1, 0) (0, r)

{-
    Stretch a shape
-}
stretch :: Float -> Shape -> Shape
stretch r = transformM $ Matrix (r, 0) (0, r)

{-
    Mirror a shape at the X-axis
-}
flipX :: Shape -> Shape
flipX = transformM (Matrix (1, 0) (0, -1))

{-
    Mirror a shape at the Y-axis
-}
flipY :: Shape -> Shape
flipY = transformM (Matrix (-1, 0) (0, 1))


flip45 :: Shape -> Shape
flip45 = transformM (Matrix (0, 1) (1, 0))

{-
    Mirror a shape at the origin
-}
flip0 :: Shape -> Shape
flip0 = transformM (Matrix (-1, 0) (0, -1))


{-
    Rotate a shape around the origin
-}
rotate :: Float -> Shape -> Shape
rotate a = transformM $ Matrix
        (cos a, -(sin a))
        (sin a, cos a)

{- Semantics
    Here we render/interpret shapes in terms of "ASCII-Art" text files
-}

render :: Float -> Float -> Shape -> IO ()
render length height shape = writeFile "shape.txt" lines
    where
        draw p
            | inside shape p = ('#', p)
            | otherwise = (' ', p)

        breakLn (d, (x,y))
            | x == length = [d,'\n']
            | otherwise = [d]

        pixels = [draw (x,y) | y <- [(-height)..height],  x <- [(-length)..length]]

        lines = concatMap breakLn pixels

{- Examples
--}

shape1 = translate (100, 100) $ stretch 10 unitDisc
shape2 = rotate 1 unitSq

shape3 = translate (100, 100) $ merge shape1 shape2

iShape = flipX $ merge
    (stretchY 2 unitSq)
    (translate (0, 5) unitDisc)

disc50 = stretch 50 unitDisc
Add files for Exercise 6 2024-06-16 20:32:20 +00:00			`module Shape where`

			`import Data.List`
			`import Matrix (Matrix (Matrix), Vector, Point, invert, apply)`

			`{- Definition of 'Shape'`
			`Shapes are things that discriminate between outside and inside`
			`-}`
			`newtype Shape = Shape { inside :: Point -> Bool }`

			`{- Basic Shapes`
			`These are the basic shapes used to construct more complicated shapes`
			`-}`

			`{-`
			`A simple empty shape`
			`-}`
			`empty :: Shape`
			`empty = Shape $ const False`

			`{-`
			`A disc with radius 1 located at (0,0)`
			`-}`
			`unitDisc :: Shape`
			`unitDisc = Shape $ \(x, y) ->`
			`x^2 + y^2 <= 1`

			`{-`
			`A square with length/width 1 located at (0,0)`
			`-}`
			`unitSq :: Shape`
			`unitSq = Shape $ \(x, y) ->`
			`abs x <= 1 && abs y <= 1`

			`{- Manipulations`
			`Functions to change and combine existing shapes into new shapes`
			`-}`

			`{- Translation`
			`Moving a shape along a vector`
			`-}`
			`translate :: Vector -> Shape -> Shape`
			`translate (dx, dy) s = Shape $ \(x, y) ->`
			`error "Fixme"`

			`{- Inverting`
			`Inverting a shape i.e. switching outside vs inside`
			`-}`
			`negate :: Shape -> Shape`
			`negate s = error "Fixme"`

			`{- General combinator`
			`Combining two shapes with a parametric boolean function`
			`-}`
			`combineBool`
			`:: (Bool -> Bool -> Bool)`
			`-> Shape`
			`-> Shape`
			`-> Shape`
			`combineBool f s1 s2 = Shape $ \p -> f (f1 p) (f2 p)`
			`where`
			`f1 = inside s1`
			`f2 = inside s2`

			`{-`
			`All points that are in both shapes`
			`-}`
			`intersect :: Shape -> Shape -> Shape`
			`intersect = error "Fixme"`

			`{-`
			`All points that in at least one of the shapes`
			`-}`
			`merge :: Shape -> Shape -> Shape`
			`merge = error "Fixme"`

			`{-`
			`All points in the first shape that are not in the secnond shape`
			`-}`
			`minus :: Shape -> Shape -> Shape`
			`minus = error "Fixme"`


			`{- Matrix transformations`
			`Applying a matrix/linear transformation to a shape`
			`-}`
			`transformM :: Matrix -> Shape -> Shape`
			`transformM m s = Shape $ \p ->`
			`inside s $ apply m' p`
			`where`
			`m' = invert m`

			`{-`
			`Stretch a shape along the X axis`
			`-}`
			`stretchX :: Float -> Shape -> Shape`
			`stretchX r = transformM $ Matrix (r, 0) (0, 1)`

			`{-`
			`Stretch a shape along the Y axis`
			`-}`
			`stretchY :: Float -> Shape -> Shape`
			`stretchY r = transformM $ Matrix (1, 0) (0, r)`

			`{-`
			`Stretch a shape`
			`-}`
			`stretch :: Float -> Shape -> Shape`
			`stretch r = transformM $ Matrix (r, 0) (0, r)`

			`{-`
			`Mirror a shape at the X-axis`
			`-}`
			`flipX :: Shape -> Shape`
			`flipX = transformM (Matrix (1, 0) (0, -1))`

			`{-`
			`Mirror a shape at the Y-axis`
			`-}`
			`flipY :: Shape -> Shape`
			`flipY = transformM (Matrix (-1, 0) (0, 1))`


			`flip45 :: Shape -> Shape`
			`flip45 = transformM (Matrix (0, 1) (1, 0))`

			`{-`
			`Mirror a shape at the origin`
			`-}`
			`flip0 :: Shape -> Shape`
			`flip0 = transformM (Matrix (-1, 0) (0, -1))`


			`{-`
			`Rotate a shape around the origin`
			`-}`
			`rotate :: Float -> Shape -> Shape`
			`rotate a = transformM $ Matrix`
			`(cos a, -(sin a))`
			`(sin a, cos a)`

			`{- Semantics`
			`Here we render/interpret shapes in terms of "ASCII-Art" text files`
			`-}`

			`render :: Float -> Float -> Shape -> IO ()`
			`render length height shape = writeFile "shape.txt" lines`
			`where`
			`draw p`
			`\| inside shape p = ('#', p)`
			`\| otherwise = (' ', p)`

			`breakLn (d, (x,y))`
			`\| x == length = [d,'\n']`
			`\| otherwise = [d]`

			`pixels = [draw (x,y) \| y <- [(-height)..height], x <- [(-length)..length]]`

			`lines = concatMap breakLn pixels`

			`{- Examples`
			`--}`

			`shape1 = translate (100, 100) $ stretch 10 unitDisc`
			`shape2 = rotate 1 unitSq`

			`shape3 = translate (100, 100) $ merge shape1 shape2`

			`iShape = flipX $ merge`
			`(stretchY 2 unitSq)`
			`(translate (0, 5) unitDisc)`

			`disc50 = stretch 50 unitDisc`