aboutsummaryrefslogtreecommitdiffstats
path: root/XMonad
diff options
context:
space:
mode:
authoranton.pirogov <anton.pirogov@gmail.com>2015-03-12 15:52:20 +0100
committeranton.pirogov <anton.pirogov@gmail.com>2015-03-12 15:52:20 +0100
commit5289cd22b024060faf3f7e150fb4ca7300344d71 (patch)
tree001d55bed4635e70738c99d4b7c4ca250f1ba4f2 /XMonad
parente3c75d3c5716150cacf1850de67970e12fcdd78e (diff)
downloadXMonadContrib-5289cd22b024060faf3f7e150fb4ca7300344d71.tar.gz
XMonadContrib-5289cd22b024060faf3f7e150fb4ca7300344d71.tar.xz
XMonadContrib-5289cd22b024060faf3f7e150fb4ca7300344d71.zip
Improved BinarySpacePartition, added Equalize,Balance and FocusParent and mouse resize support
Ignore-this: 31b5d7bf38e5b391df266906deb5e382 darcs-hash:20150312145220-8e960-c72823501fda2fa7a60ec99e5eecb01c5e2f200c.gz
Diffstat (limited to '')
-rw-r--r--XMonad/Layout/BinarySpacePartition.hs543
1 files changed, 425 insertions, 118 deletions
diff --git a/XMonad/Layout/BinarySpacePartition.hs b/XMonad/Layout/BinarySpacePartition.hs
index 2fbf13d..e5e7dbb 100644
--- a/XMonad/Layout/BinarySpacePartition.hs
+++ b/XMonad/Layout/BinarySpacePartition.hs
@@ -2,7 +2,8 @@
-----------------------------------------------------------------------------
-- |
-- Module : XMonad.Layout.BinarySpacePartition
--- Copyright : (c) 2013 Ben Weitzman <benweitzman@gmail.com>
+-- Copyright : (c) 2013 Ben Weitzman <benweitzman@gmail.com>
+-- 2015 Anton Pirogov <anton.pirogov@gmail.com>
-- License : BSD3-style (see LICENSE)
--
-- Maintainer : Ben Weitzman <benweitzman@gmail.com>
@@ -14,22 +15,35 @@
-----------------------------------------------------------------------------
module XMonad.Layout.BinarySpacePartition (
- -- * Usage
- -- $usage
- emptyBSP
- , Rotate(..)
- , Swap(..)
- , ResizeDirectional(..)
- , Direction2D(..)
- ) where
+ -- * Usage
+ -- $usage
+ emptyBSP
+ , Rotate(..)
+ , Swap(..)
+ , ResizeDirectional(..)
+ , TreeRotate(..)
+ , TreeBalance(..)
+ , FocusParent(..)
+ , Direction2D(..)
+ ) where
import XMonad
import qualified XMonad.StackSet as W
import XMonad.Util.Stack hiding (Zipper)
import XMonad.Util.Types
+
+-- for mouse resizing
+import XMonad.Layout.WindowArranger (WindowArrangerMsg(SetGeometry))
+-- for "focus parent" node border
+import XMonad.Util.XUtils
+
import qualified Data.Map as M
-import Data.List ((\\))
+import qualified Data.Set as S
+import Data.List ((\\), elemIndex, foldl')
+import Data.Maybe (fromMaybe, isNothing, isJust, mapMaybe, catMaybes)
+import Control.Applicative
import Control.Monad
+import Data.Ratio ((%))
-- $usage
-- You can use this module with the following in your @~\/.xmonad\/xmonad.hs@:
@@ -40,7 +54,13 @@ import Control.Monad
--
-- > myLayout = emptyBSP ||| etc ..
--
--- It will be helpful to add the following key bindings
+-- It may be a good idea to use "XMonad.Actions.Navigation2D" to move between the windows.
+--
+-- This layout responds to SetGeometry and is compatible with e.g. "XMonad.Actions.MouseResize"
+-- or "XMonad.Layout.BorderResize". You should probably try both to decide which is better for you,
+-- if you want to be able to resize the splits with the mouse.
+--
+-- If you don't want to use the mouse, add the following key bindings to resize the splits with the keyboard:
--
-- > , ((modm .|. altMask, xK_l ), sendMessage $ ExpandTowards R)
-- > , ((modm .|. altMask, xK_h ), sendMessage $ ExpandTowards L)
@@ -52,6 +72,7 @@ import Control.Monad
-- > , ((modm .|. altMask .|. ctrlMask , xK_k ), sendMessage $ ShrinkFrom U)
-- > , ((modm, xK_r ), sendMessage Rotate)
-- > , ((modm, xK_s ), sendMessage Swap)
+-- > , ((modm, xK_n ), sendMessage FocusParent)
--
-- Here's an alternative key mapping, this time using additionalKeysP,
-- arrow keys, and slightly different behavior when resizing windows
@@ -67,22 +88,39 @@ import Control.Monad
-- > , ("M-s", sendMessage $ BSP.Swap)
-- > , ("M-M1-s", sendMessage $ Rotate) ]
--
+-- If you have many windows open and the layout begins to look too hard to manage, you can 'Balance'
+-- the layout, so that the current splittings are discarded and windows are tiled freshly in a way that
+-- the split depth is minimized. You can combine this with 'Equalize', which does not change your tree,
+-- but tunes the split ratios in a way that each window gets the same amount of space:
+--
+-- > , ((myModMask, xK_a), sendMessage Balance)
+-- > , ((myModMask .|. shiftMask, xK_a), sendMessage Equalize)
+--
--- |Message for rotating a split in the BSP. Keep in mind that this does not change the order
--- of the windows, it will just turn a horizontal split into a verticial one and vice versa
-data Rotate = Rotate deriving Typeable
-instance Message Rotate
+-- |Message for rotating the binary tree around the parent node of the window to the left or right
+data TreeRotate = RotateL | RotateR deriving Typeable
+instance Message TreeRotate
+
+-- |Message to balance the tree in some way (Balance retiles the windows, Equalize changes ratios)
+data TreeBalance = Balance | Equalize deriving Typeable
+instance Message TreeBalance
-- |Message for resizing one of the cells in the BSP
data ResizeDirectional = ExpandTowards Direction2D | ShrinkFrom Direction2D | MoveSplit Direction2D deriving Typeable
instance Message ResizeDirectional
--- |Message for swapping the left child of a split with the right child of split.
--- Keep in mind that it does not change the order of windows and will seem to have bizarre effects
--- if you are not expecting them.
+-- |Message for rotating a split (horizontal/vertical) in the BSP
+data Rotate = Rotate deriving Typeable
+instance Message Rotate
+
+-- |Message for swapping the left child of a split with the right child of split
data Swap = Swap deriving Typeable
instance Message Swap
+-- |Message to select the parent node instead of the leaf
+data FocusParent = FocusParent deriving Typeable
+instance Message FocusParent
+
data Axis = Horizontal | Vertical deriving (Show, Read, Eq)
oppositeDirection :: Direction2D -> Direction2D
@@ -124,15 +162,24 @@ increaseRatio (Split d r) delta = Split d (min 0.9 (max 0.1 (r + delta)))
resizeDiff :: Rational
resizeDiff = 0.05
-data Tree a = Leaf | Node { value :: a
+
+data Tree a = Leaf Int | Node { value :: a
, left :: Tree a
, right :: Tree a
} deriving (Show, Read, Eq)
numLeaves :: Tree a -> Int
-numLeaves Leaf = 1
+numLeaves (Leaf _) = 1
numLeaves (Node _ l r) = numLeaves l + numLeaves r
+-- right or left rotation of a (sub)tree, no effect if rotation not possible
+rotTree dir (Leaf n) = (Leaf n)
+rotTree R n@(Node _ (Leaf _) _) = n
+rotTree L n@(Node _ _ (Leaf _)) = n
+rotTree R (Node sp (Node sp2 l2 r2) r) = Node sp2 l2 (Node sp r2 r)
+rotTree L (Node sp l (Node sp2 l2 r2)) = Node sp2 (Node sp l l2) r2
+
+
data Crumb a = LeftCrumb a (Tree a) | RightCrumb a (Tree a) deriving (Show, Read, Eq)
swapCrumb :: Crumb a -> Crumb a
@@ -153,11 +200,11 @@ toZipper :: Tree a -> Zipper a
toZipper t = (t, [])
goLeft :: Zipper a -> Maybe (Zipper a)
-goLeft (Leaf, _) = Nothing
+goLeft (Leaf _, _) = Nothing
goLeft (Node x l r, bs) = Just (l, LeftCrumb x r:bs)
goRight :: Zipper a -> Maybe (Zipper a)
-goRight (Leaf, _) = Nothing
+goRight (Leaf _, _) = Nothing
goRight (Node x l r, bs) = Just (r, RightCrumb x l:bs)
goUp :: Zipper a -> Maybe (Zipper a)
@@ -170,8 +217,16 @@ goSibling (_, []) = Nothing
goSibling z@(_, LeftCrumb _ _:_) = Just z >>= goUp >>= goRight
goSibling z@(_, RightCrumb _ _:_) = Just z >>= goUp >>= goLeft
+top :: Zipper a -> Zipper a
+top z = case goUp z of
+ Nothing -> z
+ Just z' -> top z'
+
+toTree :: Zipper a -> Tree a
+toTree = fst . top
+
goToNthLeaf :: Int -> Zipper a -> Maybe (Zipper a)
-goToNthLeaf _ z@(Leaf, _) = Just z
+goToNthLeaf _ z@(Leaf _, _) = Just z
goToNthLeaf n z@(t, _) =
if numLeaves (left t) > n
then do z' <- goLeft z
@@ -179,26 +234,31 @@ goToNthLeaf n z@(t, _) =
else do z' <- goRight z
goToNthLeaf (n - (numLeaves . left $ t)) z'
+goToFocusedLocation :: (Int,Int,[Window]) -> Zipper a -> Maybe (Zipper a)
+goToFocusedLocation (l,n,_) z = goToNthLeaf l z >>= goUpN n
+ where goUpN 0 b = return b
+ goUpN n b = goUp b >>= goUpN (n-1)
+
splitCurrentLeaf :: Zipper Split -> Maybe (Zipper Split)
-splitCurrentLeaf (Leaf, []) = Just (Node (Split Vertical 0.5) Leaf Leaf, [])
-splitCurrentLeaf (Leaf, crumb:cs) = Just (Node (Split (oppositeAxis . axis . parentVal $ crumb) 0.5) Leaf Leaf, crumb:cs)
+splitCurrentLeaf (Leaf _, []) = Just (Node (Split Vertical 0.5) (Leaf 0) (Leaf 0), [])
+splitCurrentLeaf (Leaf _, crumb:cs) = Just (Node (Split (oppositeAxis . axis . parentVal $ crumb) 0.5) (Leaf 0) (Leaf 0), crumb:cs)
splitCurrentLeaf _ = Nothing
removeCurrentLeaf :: Zipper a -> Maybe (Zipper a)
-removeCurrentLeaf (Leaf, []) = Nothing
-removeCurrentLeaf (Leaf, LeftCrumb _ r:cs) = Just (r, cs)
-removeCurrentLeaf (Leaf, RightCrumb _ l:cs) = Just (l, cs)
+removeCurrentLeaf (Leaf _, []) = Nothing
+removeCurrentLeaf (Leaf _, LeftCrumb _ r:cs) = Just (r, cs)
+removeCurrentLeaf (Leaf _, RightCrumb _ l:cs) = Just (l, cs)
removeCurrentLeaf _ = Nothing
-rotateCurrentLeaf :: Zipper Split -> Maybe (Zipper Split)
-rotateCurrentLeaf (Leaf, []) = Just (Leaf, [])
-rotateCurrentLeaf (Leaf, c:cs) = Just (Leaf, modifyParentVal oppositeSplit c:cs)
-rotateCurrentLeaf _ = Nothing
+rotateCurrent :: Zipper Split -> Maybe (Zipper Split)
+rotateCurrent l@(Leaf _, []) = Just l
+rotateCurrent (n, c:cs) = Just (n, modifyParentVal oppositeSplit c:cs)
+rotateCurrent _ = Nothing
-swapCurrentLeaf :: Zipper a -> Maybe (Zipper a)
-swapCurrentLeaf (Leaf, []) = Just (Leaf, [])
-swapCurrentLeaf (Leaf, c:cs) = Just (Leaf, swapCrumb c:cs)
-swapCurrentLeaf _ = Nothing
+swapCurrent :: Zipper a -> Maybe (Zipper a)
+swapCurrent l@(Leaf _, []) = Just l
+swapCurrent (n, c:cs) = Just (n, swapCrumb c:cs)
+swapCurrent _ = Nothing
isAllTheWay :: Direction2D -> Zipper Split -> Bool
isAllTheWay _ (_, []) = True
@@ -210,11 +270,11 @@ isAllTheWay D (_, LeftCrumb s _:_)
| axis s == Horizontal = False
isAllTheWay U (_, RightCrumb s _:_)
| axis s == Horizontal = False
-isAllTheWay dir z = maybe False id $ goUp z >>= Just . isAllTheWay dir
+isAllTheWay dir z = fromMaybe False $ goUp z >>= Just . isAllTheWay dir
expandTreeTowards :: Direction2D -> Zipper Split -> Maybe (Zipper Split)
expandTreeTowards _ z@(_, []) = Just z
-expandTreeTowards dir z
+expandTreeTowards dir z
| isAllTheWay dir z = shrinkTreeFrom (oppositeDirection dir) z
expandTreeTowards R (t, LeftCrumb s r:cs)
| axis s == Vertical = Just (t, LeftCrumb (increaseRatio s resizeDiff) r:cs)
@@ -239,7 +299,7 @@ shrinkTreeFrom U z@(_, RightCrumb s _:_)
shrinkTreeFrom dir z = goUp z >>= shrinkTreeFrom dir
-- Direction2D refers to which direction the divider should move.
-autoSizeTree :: Direction2D -> Zipper Split -> Maybe (Zipper Split)
+autoSizeTree :: Direction2D -> Zipper Split -> Maybe (Zipper Split)
autoSizeTree _ z@(_, []) = Just z
autoSizeTree d z =
Just z >>= getSplit (toAxis d) >>= resizeTree d
@@ -247,28 +307,28 @@ autoSizeTree d z =
-- resizing once found the correct split. YOU MUST FIND THE RIGHT SPLIT FIRST.
resizeTree :: Direction2D -> Zipper Split -> Maybe (Zipper Split)
resizeTree _ z@(_, []) = Just z
-resizeTree R z@(_, LeftCrumb _ _:_) =
+resizeTree R z@(_, LeftCrumb _ _:_) =
Just z >>= expandTreeTowards R
-resizeTree L z@(_, LeftCrumb _ _:_) =
+resizeTree L z@(_, LeftCrumb _ _:_) =
Just z >>= shrinkTreeFrom R
-resizeTree U z@(_, LeftCrumb _ _:_) =
+resizeTree U z@(_, LeftCrumb _ _:_) =
Just z >>= shrinkTreeFrom D
-resizeTree D z@(_, LeftCrumb _ _:_) =
+resizeTree D z@(_, LeftCrumb _ _:_) =
Just z >>= expandTreeTowards D
-resizeTree R z@(_, RightCrumb _ _:_) =
+resizeTree R z@(_, RightCrumb _ _:_) =
Just z >>= shrinkTreeFrom L
-resizeTree L z@(_, RightCrumb _ _:_) =
+resizeTree L z@(_, RightCrumb _ _:_) =
Just z >>= expandTreeTowards L
-resizeTree U z@(_, RightCrumb _ _:_) =
+resizeTree U z@(_, RightCrumb _ _:_) =
Just z >>= expandTreeTowards U
-resizeTree D z@(_, RightCrumb _ _:_) =
+resizeTree D z@(_, RightCrumb _ _:_) =
Just z >>= shrinkTreeFrom U
getSplit :: Axis -> Zipper Split -> Maybe (Zipper Split)
getSplit _ (_, []) = Nothing
getSplit d z =
do let fs = findSplit d z
- if fs == Nothing
+ if isNothing fs
then findClosest d z
else fs
@@ -278,124 +338,371 @@ findClosest d z@(_, LeftCrumb s _:_)
| axis s == d = Just z
findClosest d z@(_, RightCrumb s _:_)
| axis s == d = Just z
-findClosest d z = goUp z >>= findClosest d
+findClosest d z = goUp z >>= findClosest d
findSplit :: Axis -> Zipper Split -> Maybe (Zipper Split)
findSplit _ (_, []) = Nothing
findSplit d z@(_, LeftCrumb s _:_)
| axis s == d = Just z
-findSplit d z = goUp z >>= findSplit d
-
-top :: Zipper a -> Zipper a
-top z = case goUp z of
- Nothing -> z
- Just z' -> top z'
-
-toTree :: Zipper a -> Tree a
-toTree = fst . top
-
-index :: W.Stack a -> Int
-index s = case toIndex (Just s) of
- (_, Nothing) -> 0
- (_, Just int) -> int
-
-data BinarySpacePartition a = BinarySpacePartition { getTree :: Maybe (Tree Split) } deriving (Show, Read)
+findSplit d z = goUp z >>= findSplit d
+
+resizeSplit :: Direction2D -> (Rational,Rational) -> Zipper Split -> Maybe (Zipper Split)
+resizeSplit _ _ z@(_, []) = Just z
+resizeSplit dir (xsc,ysc) z = case goToBorder dir z of
+ Nothing -> Just z
+ Just (t, crumb) -> Just $ case dir of
+ R -> (t{value=sp{ratio=scaleRatio (ratio sp) xsc}}, crumb)
+ D -> (t{value=sp{ratio=scaleRatio (ratio sp) ysc}}, crumb)
+ L -> (t{value=sp{ratio=1-scaleRatio (1-ratio sp) xsc}}, crumb)
+ U -> (t{value=sp{ratio=1-scaleRatio (1-ratio sp) ysc}}, crumb)
+ where sp = value t
+ scaleRatio r fac = min 0.9 $ max 0.1 $ r*fac
+
+-- starting from a leaf, go to node representing a border of the according window
+goToBorder :: Direction2D -> Zipper Split -> Maybe (Zipper Split)
+goToBorder L z@(_, RightCrumb (Split Vertical _) l:cs) = goUp z
+goToBorder L z = goUp z >>= goToBorder L
+goToBorder R z@(_, LeftCrumb (Split Vertical _) r:cs) = goUp z
+goToBorder R z = goUp z >>= goToBorder R
+goToBorder U z@(_, RightCrumb (Split Horizontal _) l:cs) = goUp z
+goToBorder U z = goUp z >>= goToBorder U
+goToBorder D z@(_, LeftCrumb (Split Horizontal _) r:cs) = goUp z
+goToBorder D z = goUp z >>= goToBorder D
+
+
+data BinarySpacePartition a = BinarySpacePartition { getOldRects :: [(Window,Rectangle)]
+ , getFocusedNode :: (Int,Int,[Window]) -- leaf, steps up,deco
+ , getTree :: Maybe (Tree Split) } deriving (Show, Read)
-- | an empty BinarySpacePartition to use as a default for adding windows to.
emptyBSP :: BinarySpacePartition a
-emptyBSP = BinarySpacePartition Nothing
+emptyBSP = BinarySpacePartition [] ((-1),0,[]) Nothing
makeBSP :: Tree Split -> BinarySpacePartition a
-makeBSP = BinarySpacePartition . Just
+makeBSP = BinarySpacePartition [] ((-1),0,[]) . Just
makeZipper :: BinarySpacePartition a -> Maybe (Zipper Split)
-makeZipper (BinarySpacePartition Nothing) = Nothing
-makeZipper (BinarySpacePartition (Just t)) = Just . toZipper $ t
+makeZipper (BinarySpacePartition _ _ Nothing) = Nothing
+makeZipper (BinarySpacePartition _ _ (Just t)) = Just . toZipper $ t
size :: BinarySpacePartition a -> Int
size = maybe 0 numLeaves . getTree
zipperToBinarySpacePartition :: Maybe (Zipper Split) -> BinarySpacePartition b
-zipperToBinarySpacePartition Nothing = BinarySpacePartition Nothing
-zipperToBinarySpacePartition (Just z) = BinarySpacePartition . Just . toTree . top $ z
+zipperToBinarySpacePartition Nothing = emptyBSP
+zipperToBinarySpacePartition (Just z) = BinarySpacePartition [] ((-1),0,[]) . Just . toTree . top $ z
rectangles :: BinarySpacePartition a -> Rectangle -> [Rectangle]
-rectangles (BinarySpacePartition Nothing) _ = []
-rectangles (BinarySpacePartition (Just Leaf)) rootRect = [rootRect]
-rectangles (BinarySpacePartition (Just node)) rootRect =
+rectangles (BinarySpacePartition _ _ Nothing) _ = []
+rectangles (BinarySpacePartition _ _ (Just (Leaf _))) rootRect = [rootRect]
+rectangles (BinarySpacePartition _ _ (Just node)) rootRect =
rectangles (makeBSP . left $ node) leftBox ++
rectangles (makeBSP . right $ node) rightBox
where (leftBox, rightBox) = split (axis info) (ratio info) rootRect
info = value node
+getNodeRect :: BinarySpacePartition a -> Rectangle -> (Int,Int) -> Rectangle
+getNodeRect b r (l,n) = fromMaybe (Rectangle 0 0 1 1)
+ $ (makeZipper b >>= goToFocusedLocation (l,n,[]) >>= getRect [])
+ where getRect ls z@(n, []) = Just $ foldl (\r' (s,f) -> f $ split' s r') r ls
+ getRect ls z@(n, LeftCrumb s t:cs) = goUp z >>= getRect ((s,fst):ls)
+ getRect ls z@(n, RightCrumb s t:cs) = goUp z >>= getRect ((s,snd):ls)
+ split' s = split (axis s) (ratio s)
+
doToNth :: (Zipper Split -> Maybe (Zipper Split)) -> BinarySpacePartition a -> Int -> BinarySpacePartition a
-doToNth f b n = zipperToBinarySpacePartition $ makeZipper b >>= goToNthLeaf n >>= f
+doToNth f b n = zipperToBinarySpacePartition $ makeZipper b >>= goToFocusedLocation (getFocusedNode b) >>= f
splitNth :: BinarySpacePartition a -> Int -> BinarySpacePartition a
-splitNth (BinarySpacePartition Nothing) _ = makeBSP Leaf
+splitNth (BinarySpacePartition _ _ Nothing) _ = makeBSP (Leaf 0)
splitNth b n = doToNth splitCurrentLeaf b n
removeNth :: BinarySpacePartition a -> Int -> BinarySpacePartition a
-removeNth (BinarySpacePartition Nothing) _ = emptyBSP
-removeNth (BinarySpacePartition (Just Leaf)) _ = emptyBSP
+removeNth (BinarySpacePartition _ _ Nothing) _ = emptyBSP
+removeNth (BinarySpacePartition _ _ (Just (Leaf _))) _ = emptyBSP
removeNth b n = doToNth removeCurrentLeaf b n
rotateNth :: BinarySpacePartition a -> Int -> BinarySpacePartition a
-rotateNth (BinarySpacePartition Nothing) _ = emptyBSP
-rotateNth b@(BinarySpacePartition (Just Leaf)) _ = b
-rotateNth b n = doToNth rotateCurrentLeaf b n
+rotateNth (BinarySpacePartition _ _ Nothing) _ = emptyBSP
+rotateNth b@(BinarySpacePartition _ _ (Just (Leaf _))) _ = b
+rotateNth b n = doToNth rotateCurrent b n
swapNth :: BinarySpacePartition a -> Int -> BinarySpacePartition a
-swapNth (BinarySpacePartition Nothing) _ = emptyBSP
-swapNth b@(BinarySpacePartition (Just Leaf)) _ = b
-swapNth b n = doToNth swapCurrentLeaf b n
+swapNth (BinarySpacePartition _ _ Nothing) _ = emptyBSP
+swapNth b@(BinarySpacePartition _ _ (Just (Leaf _))) _ = b
+swapNth b n = doToNth swapCurrent b n
growNthTowards :: Direction2D -> BinarySpacePartition a -> Int -> BinarySpacePartition a
-growNthTowards _ (BinarySpacePartition Nothing) _ = emptyBSP
-growNthTowards _ b@(BinarySpacePartition (Just Leaf)) _ = b
+growNthTowards _ (BinarySpacePartition _ _ Nothing) _ = emptyBSP
+growNthTowards _ b@(BinarySpacePartition _ _ (Just (Leaf _))) _ = b
growNthTowards dir b n = doToNth (expandTreeTowards dir) b n
shrinkNthFrom :: Direction2D -> BinarySpacePartition a -> Int -> BinarySpacePartition a
-shrinkNthFrom _ (BinarySpacePartition Nothing) _ = emptyBSP
-shrinkNthFrom _ b@(BinarySpacePartition (Just Leaf)) _ = b
+shrinkNthFrom _ (BinarySpacePartition _ _ Nothing) _ = emptyBSP
+shrinkNthFrom _ b@(BinarySpacePartition _ _ (Just (Leaf _))) _ = b
shrinkNthFrom dir b n = doToNth (shrinkTreeFrom dir) b n
-autoSizeNth :: Direction2D -> BinarySpacePartition a -> Int -> BinarySpacePartition a
-autoSizeNth _ (BinarySpacePartition Nothing) _ = emptyBSP
-autoSizeNth _ b@(BinarySpacePartition (Just Leaf)) _ = b
-autoSizeNth dir b n = doToNth (autoSizeTree dir) b n
-
-instance LayoutClass BinarySpacePartition a where
- doLayout b r s = return (zip ws rs, layout b) where
- ws = W.integrate s
- layout bsp
- | l == count = Just bsp
- | l > count = layout $ splitNth bsp n
- | otherwise = layout $ removeNth bsp n
- where count = size bsp
-
- l = length ws
- n = index s
- rs = case layout b of
- Nothing -> rectangles b r
- Just bsp' -> rectangles bsp' r
- handleMessage b m =
- do ms <- (W.stack . W.workspace . W.current) `fmap` gets windowset
- fs <- (M.keys . W.floating) `fmap` gets windowset
- return $ ms >>= unfloat fs >>= handleMesg
- where handleMesg s = msum [fmap (`rotate` s) (fromMessage m)
- ,fmap (`resize` s) (fromMessage m)
- ,fmap (`swap` s) (fromMessage m)
+autoSizeNth :: Direction2D -> BinarySpacePartition a -> Int -> BinarySpacePartition a
+autoSizeNth _ (BinarySpacePartition _ _ Nothing) _ = emptyBSP
+autoSizeNth _ b@(BinarySpacePartition _ _ (Just (Leaf _))) _ = b
+autoSizeNth dir b n = doToNth (autoSizeTree dir) b n
+
+resizeSplitNth :: Direction2D -> (Rational,Rational) -> BinarySpacePartition a -> Int -> BinarySpacePartition a
+resizeSplitNth _ _ (BinarySpacePartition _ _ Nothing) _ = emptyBSP
+resizeSplitNth _ _ b@(BinarySpacePartition _ _ (Just (Leaf _))) _ = b
+resizeSplitNth dir sc b n = doToNth (resizeSplit dir sc) b n
+
+-- rotate tree left or right around parent of nth leaf
+rotateTreeNth :: Direction2D -> BinarySpacePartition a -> Int -> BinarySpacePartition a
+rotateTreeNth _ (BinarySpacePartition _ _ Nothing) _ = emptyBSP
+rotateTreeNth U b _ = b
+rotateTreeNth D b _ = b
+rotateTreeNth dir b@(BinarySpacePartition _ _ (Just t)) n =
+ doToNth (\t -> case goUp t of
+ Nothing -> Just t
+ Just (t, c) -> Just (rotTree dir t, c)) b n
+
+-- set the split ratios so that all windows have the same size, without changing tree itself
+equalizeTree :: BinarySpacePartition a -> BinarySpacePartition a
+equalizeTree (BinarySpacePartition _ _ Nothing) = emptyBSP
+equalizeTree (BinarySpacePartition olr foc (Just t)) = BinarySpacePartition olr foc $ Just $ eql t
+ where eql (Leaf n) = Leaf n
+ eql n@(Node s l r) = Node s{ratio=fromIntegral (numLeaves l) % fromIntegral (numLeaves n)}
+ (eql l) (eql r)
+
+-- generate a symmetrical balanced tree for n leaves
+balancedTree :: Int -> BinarySpacePartition a
+balancedTree n = numerateLeaves $ BinarySpacePartition [] ((-1),0,[]) $ Just $ balanced n
+ where balanced 1 = Leaf 0
+ balanced 2 = Node (Split Horizontal 0.5) (Leaf 0) (Leaf 0)
+ balanced n = Node (Split Horizontal 0.5) (balanced (n`div`2)) (balanced (n-n`div`2))
+
+-- attempt to rotate splits optimally in order choose more quad-like rects
+optimizeOrientation :: Rectangle -> BinarySpacePartition a -> BinarySpacePartition a
+optimizeOrientation r (BinarySpacePartition _ _ Nothing) = emptyBSP
+optimizeOrientation r (BinarySpacePartition olr foc (Just t)) = BinarySpacePartition olr foc $ Just $ opt t r
+ where opt (Leaf v) rect = (Leaf v)
+ opt (Node sp l r) rect = Node sp' (opt l lrect) (opt r rrect)
+ where (Rectangle _ _ w1 h1,Rectangle _ _ w2 h2) = split (axis sp) (ratio sp) rect
+ (Rectangle _ _ w3 h3,Rectangle _ _ w4 h4) = split (axis $ oppositeSplit sp) (ratio sp) rect
+ f w h = if w > h then w'/h' else h'/w' where (w',h') = (fromIntegral w, fromIntegral h)
+ wratio = min (f w1 h1) (f w2 h2)
+ wratio' = min (f w3 h3) (f w4 h4)
+ sp' = if wratio<wratio' then sp else oppositeSplit sp
+ (lrect, rrect) = split (axis sp') (ratio sp') rect
+
+-- traverse and collect all leave numbers, left to right
+flattenLeaves :: BinarySpacePartition a -> [Int]
+flattenLeaves (BinarySpacePartition _ _ Nothing) = []
+flattenLeaves (BinarySpacePartition _ _ (Just t)) = flatten t
+ where flatten (Leaf n) = [n]
+ flatten (Node _ l r) = flatten l++flatten r
+
+-- we do this before an action to look afterwards which leaves moved where
+numerateLeaves :: BinarySpacePartition a -> BinarySpacePartition a
+numerateLeaves b@(BinarySpacePartition _ _ Nothing) = b
+numerateLeaves b@(BinarySpacePartition olr foc (Just t)) = BinarySpacePartition olr foc . Just . snd $ numerate 0 t
+ where numerate n (Leaf _) = (n+1, Leaf n)
+ numerate n (Node s l r) = (n'', Node s nl nr)
+ where (n', nl) = numerate n l
+ (n'', nr) = numerate n' r
+
+-- returns index of focused window or 0 for empty stack
+index :: W.Stack a -> Int
+index s = case toIndex (Just s) of
+ (_, Nothing) -> 0
+ (_, Just int) -> int
+
+--move windows to new positions according to tree transformations, keeping focus on originally focused window
+--CAREFUL here! introduce a bug here and have fun debugging as your windows start to disappear or explode
+adjustStack :: Maybe (W.Stack Window) --original stack
+ -> Maybe (W.Stack Window) --stack without floating windows
+ -> [Window] --just floating windows of this WS
+ -> Maybe (BinarySpacePartition Window) -- Tree with numbered leaves telling what to move where
+ -> Maybe (W.Stack Window) --resulting stack
+adjustStack orig Nothing _ _ = orig --no new stack -> no changes
+adjustStack orig _ _ Nothing = orig --empty tree -> no changes
+adjustStack orig s fw (Just b) =
+ if length ls<length ws then orig --less leaves than non-floating windows -> tree incomplete, no changes
+ else fromIndex ws' fid'
+ where ws' = (mapMaybe ((flip M.lookup) wsmap) ls)++fw
+ fid' = fromMaybe 0 $ elemIndex focused ws'
+ wsmap = M.fromList $ zip [0..] ws -- map: old index in list -> window
+ ls = flattenLeaves b -- get new index ordering from tree
+ (ws,fid) = toIndex s
+ focused = ws !! (fromMaybe 0 $ fid)
+
+--replace the window stack of the managed workspace with our modified stack
+replaceStack :: Maybe (W.Stack Window) -> X ()
+replaceStack s = do
+ st <- get
+ let wset = windowset st
+ cur = W.current wset
+ wsp = W.workspace cur
+ put st{windowset=wset{W.current=cur{W.workspace=wsp{W.stack=s}}}}
+
+replaceFloating :: M.Map Window W.RationalRect -> X ()
+replaceFloating wsm = do
+ st <- get
+ let wset = windowset st
+ put st{windowset=wset{W.floating=wsm}}
+
+-- some helpers to filter windows
+getFloating = (M.keys . W.floating) <$> gets windowset -- all floating windows
+getStackSet = (W.stack . W.workspace . W.current) <$> gets windowset -- windows on this WS (with floating)
+withoutFloating fs = maybe Nothing (unfloat fs)
+isFloating w = getFloating >>= (\fs -> return $ w `elem` fs)
+getScreenRect = (screenRect . W.screenDetail . W.current) <$> gets windowset
+
+-- ignore messages if current focus is on floating window, otherwise return stack without floating
+unfloat :: [Window] -> W.Stack Window -> Maybe (W.Stack Window)
+unfloat fs s = if W.focus s `elem` fs
+ then Nothing
+ else Just $ s{W.up = W.up s \\ fs, W.down = W.down s \\ fs}
+
+instance LayoutClass BinarySpacePartition Window where
+ doLayout b r s = do
+ let b' = layout b
+ b'' <- if size b /= size b' then clearBorder b' else updateBorder r b'
+ -- when (getFocusedNode b/= getFocusedNode b'') $ debug $ show $ getFocusedNode b''
+
+ let rs = rectangles b'' r
+ wrs = zip ws rs
+ return (wrs, Just b''{getOldRects=wrs,getFocusedNode=getFocusedNode b''})
+ where
+ ws = W.integrate s
+ l = length ws
+ n = index s
+ layout bsp
+ | l == count = bsp
+ | l > count = layout $ splitNth bsp n
+ | otherwise = layout $ removeNth bsp n
+ where count = size bsp
+
+ handleMessage b_orig m
+ | Just FocusParent <- fromMessage m = focusParent b
+ | Just msg@(SetGeometry _) <- fromMessage m = handleResize b msg >>= return . updateNodeFocus
+ | otherwise = do
+ ws <- getStackSet
+ fs <- getFloating
+ r <- getScreenRect
+ let lws = withoutFloating fs ws -- tiled windows on WS
+ lfs = (maybe [] W.integrate ws) \\ (maybe [] W.integrate lws) -- untiled windows on WS
+ b' = lws >>= handleMesg r -- transform tree (concerns only tiled windows)
+ ws' = adjustStack ws lws lfs b' -- apply transformation to window stack, reintegrate floating wins
+ replaceStack ws'
+ return $ updateNodeFocus b'
+ where handleMesg r s = msum [fmap (`rotate` s) (fromMessage m)
+ ,fmap (`resize` s) (fromMessage m)
+ ,fmap (`swap` s) (fromMessage m)
+ ,fmap (`rotateTr` s) (fromMessage m)
+ ,fmap (balanceTr r) (fromMessage m)
]
- unfloat fs s = if W.focus s `elem` fs
- then Nothing
- else Just (s { W.up = W.up s \\ fs
- , W.down = W.down s \\ fs })
+
+ updateNodeFocus = maybe Nothing (\bsp -> Just $ bsp{getFocusedNode=clr $ getFocusedNode b_orig})
+ where clr (_,_,ws) = ((-1),0,ws)
+
+ b = numerateLeaves b_orig
+
rotate Rotate s = rotateNth b $ index s
swap Swap s = swapNth b $ index s
resize (ExpandTowards dir) s = growNthTowards dir b $ index s
resize (ShrinkFrom dir) s = shrinkNthFrom dir b $ index s
resize (MoveSplit dir) s = autoSizeNth dir b $ index s
+ rotateTr RotateL s = rotateTreeNth L b $ index s
+ rotateTr RotateR s = rotateTreeNth R b $ index s
+ balanceTr r Equalize = equalizeTree b
+ balanceTr r Balance = optimizeOrientation r $ balancedTree (size b)
description _ = "BSP"
+-- React to SetGeometry message to work with BorderResize/MouseResize
+handleResize :: BinarySpacePartition Window -> WindowArrangerMsg -> X (Maybe (BinarySpacePartition Window))
+handleResize b (SetGeometry newrect@(Rectangle x y w h)) = do
+ ws <- getStackSet
+ fs <- getFloating
+ case W.focus <$> ws of
+ Nothing -> return Nothing
+ Just win -> do
+ isfloat <- isFloating win
+ (_,_,_,_,_,mx,my,_) <- withDisplay (\d -> (io $ queryPointer d win))
+ let oldrect@(Rectangle ox oy ow oh) = fromMaybe (Rectangle 0 0 0 0) $ lookup win $ getOldRects b
+ let (xsc,ysc) = (fi w % fi ow, fi h % fi oh)
+ (xsc',ysc') = (rough xsc, rough ysc)
+ dirs = changedDirs oldrect newrect (fi mx,fi my)
+ n = elemIndex win $ maybe [] W.integrate $ withoutFloating fs ws
+ -- unless (isNothing dir) $ debug $
+ -- show (fi x-fi ox,fi y-fi oy) ++ show (fi w-fi ow,fi h-fi oh)
+ -- ++ show dir ++ " " ++ show win ++ " " ++ show (mx,my)
+ return $ case n of
+ Just n' -> Just $ foldl' (\b' d -> resizeSplitNth d (xsc',ysc') b' n') b dirs
+ Nothing -> Nothing --focused window is floating -> ignore
+
+ where rough v = min 1.5 $ max 0.75 v -- extreme scale factors are forbidden
+
+-- find out which borders have been pulled. We need the old and new rects and the mouse coordinates
+changedDirs :: Rectangle -> Rectangle -> (Int,Int) -> [Direction2D]
+changedDirs (Rectangle ox oy ow oh) (Rectangle x y w h) (mx,my) = catMaybes [lr, ud]
+ where lr = if ow==w then Nothing
+ else Just (if fi mx > (fi ow)/2 then R else L)
+ ud = if oh==h then Nothing
+ else Just (if fi my > (fi oh)/2 then D else U)
+
+-- move focus to next higher parent node of current focused leaf if possible, cyclic
+focusParent :: BinarySpacePartition a -> X (Maybe (BinarySpacePartition a))
+focusParent b = do
+ foc <- maybe 0 index <$> (withoutFloating <$> getFloating <*> getStackSet)
+ let (l,n,d) = getFocusedNode b
+ return . Just $ if foc/= l then b{getFocusedNode=(foc,1,d)}
+ else b{getFocusedNode=upFocus (l,n,d)}
+ -- debug $ "Focus Parent: "++(maybe "" (show.getFocusedNode) ret)
+ where upFocus (l,n,d)
+ | canFocus (l,n+1,d) = (l,n+1,d)
+ | otherwise = (l,0,d)
+ canFocus (l,n,d) = isJust $ makeZipper b >>= goToFocusedLocation (l,n+1,d)
+
+-- "focus parent" border helpers
+
+updateBorder :: Rectangle -> BinarySpacePartition a -> X (BinarySpacePartition a)
+updateBorder r b = do
+ foc <- maybe 0 index <$> (withoutFloating <$> getFloating <*> getStackSet)
+ let (l,n,ws) = getFocusedNode b
+ removeBorder ws
+ if n==0 || foc/=l then return $ b{getFocusedNode=(foc,0,[])}
+ else createBorder (getNodeRect b r (l,n)) Nothing >>= (\ws -> return $ b{getFocusedNode=(l,n,ws)})
+
+clearBorder :: BinarySpacePartition a -> X (BinarySpacePartition a)
+clearBorder b = do
+ let (_,_,ws) = getFocusedNode b
+ removeBorder ws
+ return b{getFocusedNode=((-1),0,[])}
+
+-- create a window for each border line, show, add into stack and set floating
+createBorder r@(Rectangle wx wy ww wh) c = do
+ bw <- asks (borderWidth.config)
+ bc <- case c of
+ Nothing -> asks (focusedBorderColor.config)
+ Just s -> return s
+ let rects = [ Rectangle wx wy ww (fi bw)
+ , Rectangle wx wy (fi bw) wh
+ , Rectangle wx (wy+fi wh-fi bw) ww (fi bw)
+ , Rectangle (wx+fi ww-fi bw) wy (fi bw) wh
+ ]
+ ws <- mapM (\r -> createNewWindow r Nothing bc False) rects
+ showWindows ws
+ maybe Nothing (\s -> Just s{W.down=W.down s ++ ws}) <$> getStackSet >>= replaceStack
+ M.union (M.fromList $ zip ws $ map toRR rects) . W.floating . windowset <$> get >>= replaceFloating
+ modify (\s -> s{mapped=mapped s `S.union` S.fromList ws})
+
+ -- show <$> mapM isClient ws >>= debug
+ return ws
+ where toRR (Rectangle x y w h) = W.RationalRect (fi x) (fi y) (fi w) (fi h)
+
+-- remove border line windows from stack + floating, kill
+removeBorder ws = do
+ modify (\s -> s{mapped = mapped s `S.difference` S.fromList ws})
+ flip (foldl (flip M.delete)) ws . W.floating . windowset <$> get >>= replaceFloating
+ maybe Nothing (\s -> Just s{W.down=W.down s \\ ws}) <$> getStackSet >>= replaceStack
+ deleteWindows ws
+
+debug str = spawn $ "echo \""++str++"\" >> /tmp/xdebug"
+