{-
Bustle.Diagram: shapes for sequence diagrams
Copyright (C) 2008–2009 Collabora Ltd.
This library is free software; you can redistribute it and/or
modify it under the terms of the GNU Lesser General Public
License as published by the Free Software Foundation; either
version 2.1 of the License, or (at your option) any later version.
This library is distributed in the hope that it will be useful,
but WITHOUT ANY WARRANTY; without even the implied warranty of
MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
Lesser General Public License for more details.
You should have received a copy of the GNU Lesser General Public
License along with this library; if not, write to the Free Software
Foundation, Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA
-}
module Bustle.Diagram
( Diagram
-- Shapes, and smart constructors therefore
, Shape(..)
, memberLabel
, timestampLabel
, headers
, headerHeight
-- Attributes of shapes
, Arrowhead(..)
, Side(..)
, Colour(..)
, Rect
-- Annoying constants that users of this module need.
, columnWidth
, timestampAndMemberWidth
, firstColumnOffset
, eventHeight
-- Displaying diagrams
, diagramDimensions
, topLeftJustifyDiagram
, translateDiagram
, drawDiagram
, drawRegion
)
where
import Data.List (unzip4)
import Control.Arrow ((&&&))
import Control.Applicative ((<$>), (<*>))
import Control.Monad.Reader
import Graphics.Rendering.Cairo (Operator(..), Render, arc, curveTo, fill, getCurrentPoint, lineTo, moveTo, newPath, paint, rectangle, restore, save, setDash, setLineWidth, setOperator, setSourceRGB, stroke)
import Graphics.UI.Gtk.Cairo (cairoCreateContext, showLayout)
import Graphics.Rendering.Pango.Layout
import Graphics.Rendering.Pango.Font
import qualified Bustle.Marquee as Marquee
import Bustle.Marquee (Marquee)
import Bustle.Util
import Bustle.Types (ObjectPath, InterfaceName, MemberName)
-- Sorry Mum
import System.IO.Unsafe (unsafePerformIO)
type Point = (Double, Double)
type Rect = (Double, Double, Double, Double)
data Arrowhead = Above | Below
deriving (Eq, Show, Read, Ord)
above, below :: Arrowhead -> Bool
above Above = True
above Below = False
below = not . above
voffset :: Num a => Arrowhead -> (a -> a -> a)
voffset Above = (-)
voffset Below = (+)
data Side = L | R
deriving (Eq, Show, Read, Ord)
offset :: Num a => Side -> (a -> a -> a)
offset L = (-)
offset R = (+)
data Colour = Colour Double Double Double
deriving (Eq, Show, Read, Ord)
data Shape = Header { strs :: [String]
, shapex, shapey :: Double
}
| MemberLabel { labelPath :: ObjectPath
, labelInterface :: Maybe InterfaceName
, labelMember :: MemberName
, shapeIsReturn :: Bool
, shapex :: Double -- The coordinates of the *centre*
, shapey :: Double -- of the label
}
| TimestampLabel { str :: String
, shapex :: Double -- The coordinates of the
, shapey :: Double -- *centre* of the timestamp
}
| ClientLines { shapexs :: NonEmpty Double -- The x-coordinates of the lines to draw
, shapey1, shapey2 :: Double
}
| Rule { shapex1, shapex2, shapey :: Double }
| Arrow { shapecolour :: Maybe Colour
, arrowhead :: Arrowhead
, shapex1, shapex2, shapey :: Double
}
| SignalArrow { shapex1, epicentre, shapex2, shapey :: Double }
| DirectedSignalArrow { epicentre, shapex, shapey :: Double }
| Arc { topx, topy, bottomx, bottomy :: Double
, arcside :: Side
, caption :: String
}
| Highlight { highlightRegion :: Rect
}
deriving (Show, Eq)
-- Smart constructors for TimestampLabel and MemberLabel that fill in the
-- hardcoded (spit) x coordinates.
memberLabel :: ObjectPath
-> Maybe InterfaceName
-> MemberName
-> Bool -- ^ True if this is a return; False if it's a call
-> Double -- ^ y-coordinate
-> Shape
memberLabel p i m isReturn y = MemberLabel p i m isReturn memberx y
timestampLabel :: String -> Double -> Shape
timestampLabel s y = TimestampLabel s timestampx y
type Diagram = [Shape]
arcControlPoints :: Shape -> (Point, Point)
arcControlPoints (Arc { topx=x1, topy=y1, bottomx=x2, bottomy=y2, arcside=s }) =
let (+-) = offset s
cp1 = (x1 +- 60, y1 + 10)
cp2 = (x2 +- 60, y2 - 10)
in (cp1, cp2)
arcControlPoints _ = error "i see you've played arcy-shapey before"
mapX, mapY :: (Double -> Double) -> (Shape -> Shape)
mapX f s = case s of
Rule {} -> s { shapex1 = f (shapex1 s)
, shapex2 = f (shapex2 s)
}
Arrow {} -> s { shapex1 = f (shapex1 s)
, shapex2 = f (shapex2 s)
}
SignalArrow {} -> s { shapex1 = f (shapex1 s)
, epicentre = f (epicentre s)
, shapex2 = f (shapex2 s)
}
Arc {} -> s { topx = f (topx s)
, bottomx = f (bottomx s)
}
ClientLines {} -> s { shapexs = mapNonEmpty f (shapexs s) }
_ -> s { shapex = f (shapex s) }
mapY f s = case s of
Arc {} -> s { topy = f (topy s)
, bottomy = f (bottomy s)
}
ClientLines {} -> s { shapey1 = f (shapey1 s)
, shapey2 = f (shapey2 s)
}
_ -> s { shapey = f (shapey s) }
--
-- Constants
--
eventHeight :: Double
eventHeight = 30
timestampx, timestampWidth :: Double
timestampx = 0 + timestampWidth / 2
timestampWidth = 60
memberx, memberWidth :: Double
memberx = timestampWidth + memberWidth / 2
memberWidth = 340
timestampAndMemberWidth :: Double
timestampAndMemberWidth = timestampWidth + memberWidth
columnWidth :: Double
columnWidth = 90
-- Method return arcs can go outside the first column. Empirically, 20 is
-- enough to stop the arc (or the duration text) overlapping the object path
-- etc.
firstColumnOffset :: Double
firstColumnOffset = 20 + columnWidth / 2
--
-- Calculating bounds of shapes
--
minMax :: Ord a => (a, a) -> (a, a)
minMax = uncurry min &&& uncurry max
xMinMax :: Shape -> (Double, Double)
xMinMax = minMax . (shapex1 &&& shapex2)
fromCentre :: Double -> Double -> Double -> Rect
fromCentre x y width =
(x - width / 2, y - height / 2,
x + width / 2, y + height / 2)
where height = eventHeight
headerHeight :: [String] -> Double
headerHeight = fromIntegral . (10 *) . length
bounds :: Shape -> Rect
bounds s = case s of
ClientLines {} ->
let xs = nonEmptyToList (shapexs s)
in (minimum xs, shapey1 s, maximum xs, shapey2 s)
Rule {} -> (shapex1 s, shapey s, shapex2 s, shapey s)
Arrow {} ->
let (x1, x2) = xMinMax s
y1 = shapey s - (if above (arrowhead s) then 5 else 0)
y2 = shapey s + (if below (arrowhead s) then 5 else 0)
in (x1, y1, x2, y2)
SignalArrow {} ->
let (x1, x2) = xMinMax s
(y1, y2) = (subtract 5) &&& (+5) $ shapey s
in (x1, y1, x2, y2)
DirectedSignalArrow {} ->
let (x1, x2) = minMax (epicentre s, shapex s)
(y1, y2) = (subtract 5) &&& (+5) $ shapey s
in (x1, y1, x2, y2)
Arc { topx=x1, bottomx=x2, topy=y1, bottomy=y2 } ->
let ((cx, _), (dx, _)) = arcControlPoints s
-- FIXME: magic 5 makes the bounding box include the text
in (min x1 cx, y1, max x2 dx, y2 + 5)
TimestampLabel { shapex=x, shapey=y } -> fromCentre x y timestampWidth
MemberLabel { shapex=x, shapey=y } -> fromCentre x y memberWidth
Header { strs = ss, shapex = x, shapey = y} ->
let width = columnWidth
height = headerHeight ss
in (x - width / 2, y,
x + width / 2, y + height)
Highlight r -> r
intersects :: Rect -> Rect -> Bool
intersects (x,y,w,z) (x', y', w', z') =
not $ or [x > w', w < x', y > z', z < y']
-- Constructs a series of headers of various-sized lists of names,
-- bottom-justified.
headers :: [(Double, [String])] -- list of (x-coordinate, names)
-> Double -- y-coordinate of top of headers
-> (Double, [Shape]) -- the headers' combined height, and shapes
headers [] _ = (0, [])
headers xss y = (height, shapes)
where heights = map (headerHeight . snd) xss
height = maximum heights
adjs = map (height -) heights
shapes = zipWith (\(x, ss) adj -> Header ss x (y + adj)) xss adjs
--
-- Drawing
--
diagramBounds :: Diagram -> ((Double, Double), (Double, Double))
diagramBounds shapes = ((minimum (0:x1s) - padding, minimum (0:y1s) - padding)
,(maximum (0:x2s) + padding, maximum (0:y2s) + padding)
)
where
(x1s, y1s, x2s, y2s) = unzip4 $ map bounds shapes
padding = 6
diagramDimensions :: Diagram -> (Double, Double)
diagramDimensions shapes = (x2 - x1, y2 - y1)
where
((x1, y1), (x2, y2)) = diagramBounds shapes
topLeftJustifyDiagram
:: Diagram -- ^ the original diagram
-> ((Double, Double), Diagram) -- ^ the diagram transformed to be in
-- positive space, and the (x, y)-axis
-- shifts necessary to do so
topLeftJustifyDiagram shapes =
(translation, shapes')
where
((x1, y1), _) = diagramBounds shapes
translation = (negate x1, negate y1)
shapes' = translateDiagram translation shapes
translateDiagram :: (Double, Double) -> (Diagram -> Diagram)
translateDiagram (x, y) = map (mapX (+ x) . mapY (+ y))
drawDiagramInternal :: (Shape -> Bool) -- ^ A filter for the shapes
-> Bool -- ^ True to draw canvas items' bounding boxes
-- (for debugging)
-> Diagram -- ^ A diagram to render
-> Render ()
drawDiagramInternal f drawBounds shapes = do
clearCanvas
forM_ (filter f shapes) $ \x -> do
when drawBounds (drawBoundingBox x)
draw x
drawDiagram :: Bool -- ^ True to draw canvas items' bounding boxes (for
-- debugging)
-> Diagram -- ^ A diagram to render
-> Render ()
drawDiagram = drawDiagramInternal (const True)
drawRegion :: Rect -> Bool -> Diagram -> Render ()
drawRegion r = drawDiagramInternal isVisible
where isVisible = intersects r . bounds
saved :: Render () -> Render ()
saved act = save >> act >> restore
clearCanvas :: Render ()
clearCanvas = saved $ do
setSourceRGB 1 1 1
setOperator OperatorSource
paint
drawBoundingBox :: Shape -> Render ()
drawBoundingBox s = saved $ do
let (x,y,w,z) = bounds s
setSourceRGB 0 0 1
rectangle x y (w - x) (z - y)
stroke
draw :: Shape -> Render ()
draw s = draw' s
where draw' = case s of
Arc {} -> let ((cx, cy), (dx, dy)) = arcControlPoints s
in drawArc cx cy dx dy <$>
topx <*> topy <*> bottomx <*> bottomy <*> caption
SignalArrow {} -> drawSignalArrow <$> epicentre
<*> (Just . shapex1)
<*> (Just . shapex2)
<*> shapey
DirectedSignalArrow { } -> drawDirectedSignalArrow <$> epicentre
<*> shapex
<*> shapey
Arrow {} -> drawArrow <$> shapecolour <*> arrowhead <*> shapex1 <*>
shapex2 <*> shapey
Header {} -> drawHeader <$> strs <*> shapex <*> shapey
MemberLabel {} -> drawMember <$> labelPath
<*> labelInterface
<*> labelMember
<*> shapeIsReturn
<*> shapex
<*> shapey
TimestampLabel {} -> drawTimestamp <$> str
<*> shapex
<*> shapey
ClientLines {} -> drawClientLines <$> shapexs <*> shapey1 <*> shapey2
Rule {} -> drawRule <$> shapex1
<*> shapex2
<*> shapey
Highlight {} -> drawHighlight <$> highlightRegion
halfArrowHead :: Arrowhead -> Bool -> Render ()
halfArrowHead a left = do
(x,y) <- getCurrentPoint
let x' = if left then x - 10 else x + 10
let y' = voffset a y 5
if left -- work around weird artifacts
then moveTo x' y' >> lineTo x y
else lineTo x' y' >> moveTo x y
arrowHead :: Bool -> Render ()
arrowHead left = halfArrowHead Above left >> halfArrowHead Below left
drawArrow :: Maybe Colour -> Arrowhead -> Double -> Double -> Double
-> Render ()
drawArrow c a from to y = saved $ do
maybe (return ()) (\(Colour r g b) -> setSourceRGB r g b) c
moveTo from y
lineTo to y
halfArrowHead a (from < to)
stroke
drawDirectedSignalArrow :: Double -- ^ the signal emission source
-> Double -- ^ signal target coordinate
-> Double -- ^ vertical coordinate
-> Render ()
drawDirectedSignalArrow e x y
| x < e = drawSignalArrow e (Just x) Nothing y
| otherwise = drawSignalArrow e Nothing (Just x) y
drawSignalArrow :: Double -- ^ the signal emission source
-> Maybe Double -- ^ left-pointing arrow coordinate
-> Maybe Double -- ^ right-pointing arrow coordinate
-> Double -- ^ vertical coordinate
-> Render ()
drawSignalArrow e mleft mright y = do
newPath
arc e y 5 0 (2 * pi)
stroke
maybeM mleft $ \left -> do
moveTo left y
arrowHead False
lineTo (e - 5) y
stroke
maybeM mright $ \right -> do
moveTo (e + 5) y
lineTo right y
arrowHead True
stroke
drawArc :: Double -> Double -> Double -> Double
-> Double -> Double -> Double -> Double
-> String
-> Render ()
drawArc cx cy dx dy x1 y1 x2 y2 cap = saved $ do
setSourceRGB 0.4 0.7 0.4
setDash [3, 3] 0
moveTo x1 y1
curveTo cx cy dx dy x2 y2
stroke
setSourceRGB 0 0 0
l <- mkLayout (Marquee.escape cap) EllipsizeNone AlignLeft
(PangoRectangle _ _ textWidth _, _) <- liftIO $ layoutGetExtents l
let tx = min x2 dx + abs (x2 - dx) / 2
moveTo (if x1 > cx then tx - textWidth else tx) (y2 - 5)
showLayout l
font :: FontDescription
font = unsafePerformIO $ do
fd <- fontDescriptionNew
fontDescriptionSetSize fd 7
fontDescriptionSetFamily fd "Sans"
return fd
{-# NOINLINE font #-}
mkLayout :: (MonadIO m)
=> Marquee -> EllipsizeMode -> LayoutAlignment
-> m PangoLayout
mkLayout s e a = liftIO $ do
ctx <- cairoCreateContext Nothing
layout <- layoutEmpty ctx
-- layoutSetMarkup returns the un-marked-up text. We don't care about it,
-- but recent versions of Pango give it the type
-- GlibString string => ... -> IO string
-- which we need to disambiguate between Text and String. Old versions were
-- .. -> IO String
-- so go with that.
layoutSetMarkup layout (Marquee.toPangoMarkup s) :: IO String
layoutSetFontDescription layout (Just font)
layoutSetEllipsize layout e
layoutSetAlignment layout a
return layout
withWidth :: MonadIO m => m PangoLayout -> Double -> m PangoLayout
withWidth m w = do
l <- m
liftIO $ layoutSetWidth l (Just w)
return l
drawHeader :: [String] -> Double -> Double -> Render ()
drawHeader names x y = forM_ (zip [0..] names) $ \(i, name) -> do
l <- mkLayout (Marquee.escape name) EllipsizeEnd AlignCenter `withWidth` columnWidth
moveTo (x - (columnWidth / 2)) (y + i * h)
showLayout l
where h = 10
drawMember :: ObjectPath
-> Maybe InterfaceName
-> MemberName
-> Bool
-> Double
-> Double
-> Render ()
drawMember p i m isReturn x y = do
drawOne path (y - 10)
drawOne fullMethod y
where
drawOne markup y' = do
l <- mkLayout markup EllipsizeStart AlignLeft `withWidth` memberWidth
moveTo (x - memberWidth / 2) y'
showLayout l
path = (if isReturn then id else Marquee.b) $ Marquee.escape p
fullMethod =
(if isReturn then Marquee.i else id) $ Marquee.formatMember i m
drawTimestamp :: String -> Double -> Double -> Render ()
drawTimestamp ts x y = do
moveTo (x - timestampWidth / 2) (y - 10)
showLayout =<< mkLayout (Marquee.escape ts) EllipsizeNone AlignLeft `withWidth` timestampWidth
drawClientLines :: NonEmpty Double -> Double -> Double -> Render ()
drawClientLines xs y1 y2 = saved $ do
setSourceRGB 0.7 0.7 0.7
forM_ (nonEmptyToList xs) $ \x -> do
moveTo x y1
lineTo x y2
stroke
drawRule :: Double -> Double -> Double -> Render ()
drawRule x1 x2 y = saved $ do
setSourceRGB 0.9 0.9 0.9
setLineWidth 0.5
moveTo x1 y
lineTo x2 y
stroke
drawHighlight :: Rect -> Render ()
drawHighlight (x1, y1, x2, y2) = saved $ do
setSourceRGB 0.8 0.9 1.0
rectangle x1 y1 (x2 - x1) (y2 - y1)
fill
-- vim: sw=2 sts=2