{-# LANGUAGE FlexibleContexts #-} {-# LANGUAGE ScopedTypeVariables #-} {-# LANGUAGE TypeFamilies #-} ------------------------------------------------------------------------ -- | -- Module : Diagrams.Layout.Wrap -- Copyright : (c) 2012 Michael Sloan -- License : BSD-style (see the LICENSE file) -- Maintainer : Michael Sloan -- -- An algorithm for filling space in a fashion akin to word-wrapping. -- ------------------------------------------------------------------------ module Diagrams.Layout.Wrap where import Control.Arrow (first, (&&&)) import Data.Foldable (foldMap) import Data.List (find, inits, tails) import Diagrams.Prelude hiding (start) -- TODO: Take into account the negative bounds, and iteratively refine -- the list selection. -- TODO: Search for a region before / after the target pick. -- | @wrapDiagram@ post-processes the results of @wrapOutside@ / -- @wrapInside@ into a Diagram of the result. This only works when -- applying them to a list of diagrams. wrapDiagram :: (HasLinearMap v, InnerSpace v, OrderedField (Scalar v)) => ([(v, Diagram b v)], [Diagram b v]) -> Diagram b v wrapDiagram = foldMap (uncurry translate) . fst -- | @wrapOutside@ is the same as @wrapInside@, but with an inverted -- predicate. wrapOutside :: ( Enveloped a, v ~ V a , InnerSpace v, OrderedField (Scalar v) -- See [6.12.3] note below ) => (Point v -> Bool) -> [v] -> Point v -> [a] -> ([(v, a)], [a]) wrapOutside f = wrapInside (not . f) -- | fillInside greedily wraps content to fill a space defined by a -- predicate. It is passed a list of vectors which express the -- order of dimensions to be filled. In other words, wrapping RTL -- text is done by passing in [unitX, unitY], to first exhaust -- space horizontally, and then vertically. -- -- Note that this function does not guarantee that there are not -- points inside each positioned item for which the predicate is -- False. Instead, only the corners of the bounds, along each axii, -- are used. wrapInside :: forall a v. ( Enveloped a, v ~ V a , InnerSpace v, OrderedField (Scalar v) -- See [6.12.3] note below ) => (Point v -> Bool) -> [v] -> Point v -> [a] -> ([(v, a)], [a]) wrapInside f axis start = rec zeros where zeros = map snd . zip axis $ repeat (0, 0) norms = map normalized axis getVector = sumV . zipWith (^*) norms -- [[min bound, max bound]] of each axis. boundsScalars :: a -> [[v]] boundsScalars d = flip map norms $ \v -> map (.-. origin) [envelopeP (negateV v) d, envelopeP v d] -- Recurses on the list of items to lay out, maintaing a current set of -- coefficients for the different axii, each paired with the maximum -- boundary seen in that direction. rec :: [(Scalar v, Scalar v)] -> [a] -> ([(v, a)], [a]) rec _ [] = (mempty, []) rec scs (d:ds) -- Recurse a satisfactory position can be found, otherwise yields the -- list of the remaining diagrams to be laid out. = maybe (mempty, d:ds) (\(v, scs') -> first ((v, d):) $ rec scs' ds) $ find (check . fst) potential where curB = boundsScalars d -- Yields whether a given vector offset avoids collision. check v = all (f . (start .+^) . sumV . (v:)) $ sequence curB -- Updates the max bounds of an axis. maxB [_, b] (x, m) = (x, max m $ x + magnitude b) maxB _ _ = error "Diagrams.Layout.Wrap.wrapInside:maxB: pattern-match failure. Please report this as a bug." -- List of potential offsets to try, each paired with an updated list -- of current / maxbound scalar coefficients for the axis. potential = map (getVector . map fst &&& zipWith maxB curB) -- Try setting an axis to its max-seen bound, zeroing all preceding. . zipWith (++) (inits $ repeat (0, 0)) . map dupFirstY . init $ tails scs dupFirstY ((_,x):xs) = (x,x):xs dupFirstY _ = error "Diagrams.Layout.Wrap.wrapInside:dupFirstY: pattern-match failure. Please report this as a bug." -- [6.12.3]: It should be possible to infer the InnerSpace v and -- OrderedField (Scalar v) constraints from Enveloped a, v ~ V a, -- but GHC 6.12.3 cannot, so we redundantly list them here to -- preserve support for 6.12.3. -- Attempt at diagrams-haddock example, but I don't understand how Wrap works -- -- > import Diagrams.Layout.Wrap -- > import Control.Arrow (first) -- > wrapInsideEx = position ((map . first $ (origin .+^)) ds) -- > where (ds,_) = wrapInside -- > (getAny . (runQuery . query $ (circle 15 :: D R2))) -- > [unitX, unitY] -- > (origin) -- > (repeat (circle 1 # fc black)) -- --