{-# OPTIONS_HADDOCK ignore-exports #-} module Graphics.Diagram.Types where import Algebra.Vector import Algebra.VectorTypes import Diagrams.Backend.Cairo import Diagrams.Prelude import MyPrelude type MeshString = String -- |Represents a Cairo Diagram. This allows us to create multiple -- diagrams with different algorithms but based on the same -- coordinates and common properties. data Diag = Diag { mkDiag :: DiagProp -> Object -> Diagram Cairo R2 } | GifDiag { mkGifDiag :: DiagProp -> Colour Double -> ([PT] -> [[PT]]) -> [PT] -> [Diagram Cairo R2] } | EmptyDiag (Diagram Cairo R2) data Object = Object [PT] | Objects [[PT]] -- |Holds the properties for a Diagram, like thickness of 2d points etc. -- This can also be seen as a context when merging multiple diagrams. data DiagProp = MkProp { -- |The thickness of the dots. dotSize :: Double, -- |The dimensions of the x-axis. xDimension :: Coord, -- |The dimensions of the y-axis. yDimension :: Coord, -- |Algorithm to use. algo :: Int, -- |If we want to show the grid. haveGrid :: Bool, -- |If we want to show the coordinates as text. showCoordText :: Bool, -- |Square size used to show the grid and x/y-axis. squareSize :: Double, -- |The path to a quad in the quad tree. quadPath :: String } instance Def DiagProp where def = diagDefaultProp instance Monoid Diag where mempty = EmptyDiag mempty mappend d1@(Diag {}) d2@(Diag {}) = Diag g where g p obj = mkDiag d1 p obj <> mkDiag d2 p obj mappend d1@(GifDiag {}) d2@(Diag {}) = GifDiag g where g p col f vt = mkGifDiag d1 p col f vt ++ [mkDiag d2 p (Object vt)] mappend d1@(Diag {}) d2@(GifDiag {}) = GifDiag g where g p col f vt = mkDiag d2 p (Object vt) : mkGifDiag d1 p col f vt mappend d1@(GifDiag {}) d2@(GifDiag {}) = GifDiag g where g p col f vt = mkGifDiag d1 p col f vt ++ mkGifDiag d2 p col f vt mappend (EmptyDiag _) g = g mappend g (EmptyDiag _) = g mconcat = foldr mappend mempty -- |The default properties of the Diagram. diagDefaultProp :: DiagProp diagDefaultProp = MkProp 2 (0,500) (0,500) 0 False False 50 "" -- |Extract the lower bound of the x-axis dimension. diagXmin :: DiagProp -> Double diagXmin = fst . xDimension -- |Extract the upper bound of the x-axis dimension. diagXmax :: DiagProp -> Double diagXmax = snd . xDimension -- |Extract the lower bound of the y-axis dimension. diagYmin :: DiagProp -> Double diagYmin = fst . yDimension -- |Extract the upper bound of the y-axis dimension. diagYmax :: DiagProp -> Double diagYmax = snd . yDimension -- |The full width of the x dimension. diagWidth :: DiagProp -> Double diagWidth p = diagXmax p - diagXmin p -- |The full height of the y dimension. diagHeight :: DiagProp -> Double diagHeight p = diagYmax p - diagYmin p -- |The offset on the x-axis to move the grid and the white rectangle -- to the right place. diagWidthOffset :: DiagProp -> Double diagWidthOffset p = diagXmin p + (diagWidth p / 2) -- |The offset on the y-axis to move the grid and the white rectangle -- to the right place. diagHeightOffset :: DiagProp -> Double diagHeightOffset p = diagYmin p + (diagWidth p / 2) -- |Returns the specified diagram if True is passed, -- otherwise returns the empty diagram. This is just for convenience -- to avoid if else constructs. maybeDiag :: Bool -> Diag -> Diag maybeDiag b d | b = d | otherwise = mempty filterValidPT :: DiagProp -> [PT] -> [PT] filterValidPT p = filter (inRange (xDimension p, yDimension p))