module Data.GraphViz.Types.Generalised
( DotGraph(..)
, FromGeneralisedDot (..)
, DotStatements
, DotStatement(..)
, DotSubGraph(..)
, GraphID(..)
, GlobalAttributes(..)
, DotNode(..)
, DotEdge(..)
) where
import Data.GraphViz.Algorithms (canonicalise)
import Data.GraphViz.Internal.State (AttributeType (..))
import Data.GraphViz.Internal.Util (bool)
import Data.GraphViz.Parsing
import Data.GraphViz.Printing
import Data.GraphViz.Types
import qualified Data.GraphViz.Types.Canonical as C
import Data.GraphViz.Types.Internal.Common
import Data.GraphViz.Types.State
import Control.Arrow ((&&&))
import Control.Monad.Trans.State (evalState, execState, get, modify,
put)
import qualified Data.Foldable as F
import Data.Sequence (Seq, (><))
import qualified Data.Sequence as Seq
import qualified Data.Traversable as T
data DotGraph n = DotGraph {
strictGraph :: Bool
, directedGraph :: Bool
, graphID :: Maybe GraphID
, graphStatements :: DotStatements n
}
deriving (Eq, Ord, Show, Read)
instance (Ord n) => DotRepr DotGraph n where
fromCanonical = generaliseDotGraph
getID = graphID
setID i g = g { graphID = Just i }
graphIsDirected = directedGraph
setIsDirected d g = g { directedGraph = d }
graphIsStrict = strictGraph
setStrictness s g = g { strictGraph = s }
mapDotGraph = fmap
graphStructureInformation = getGraphInfo
. statementStructure . graphStatements
nodeInformation wGlobal = getNodeLookup wGlobal
. statementNodes . graphStatements
edgeInformation wGlobal = getDotEdges wGlobal
. statementEdges . graphStatements
unAnonymise = renumber
instance (Ord n, PrintDot n) => PrintDotRepr DotGraph n
instance (Ord n, ParseDot n) => ParseDotRepr DotGraph n
instance (Ord n, PrintDot n, ParseDot n) => PPDotRepr DotGraph n
instance (PrintDot n) => PrintDot (DotGraph n) where
unqtDot = printStmtBased printGraphID' (const GraphAttribute)
graphStatements printGStmts
where
printGraphID' = printGraphID strictGraph directedGraph graphID
instance (ParseDot n) => ParseDot (DotGraph n) where
parseUnqt = parseGraphID DotGraph
<*> parseBracesBased GraphAttribute parseGStmts
parse = parseUnqt
`adjustErr`
("Not a valid generalised DotGraph\n\t"++)
instance Functor DotGraph where
fmap f g = g { graphStatements = (fmap . fmap) f $ graphStatements g }
generaliseDotGraph :: C.DotGraph n -> DotGraph n
generaliseDotGraph dg = DotGraph { strictGraph = C.strictGraph dg
, directedGraph = C.directedGraph dg
, graphID = C.graphID dg
, graphStatements = generaliseStatements
$ C.graphStatements dg
}
class (DotRepr dg n) => FromGeneralisedDot dg n where
fromGeneralised :: DotGraph n -> dg n
instance (Ord n) => FromGeneralisedDot C.DotGraph n where
fromGeneralised = canonicalise
instance (Ord n) => FromGeneralisedDot DotGraph n where
fromGeneralised = id
type DotStatements n = Seq (DotStatement n)
printGStmts :: (PrintDot n) => DotStatements n -> DotCode
printGStmts = toDot . F.toList
parseGStmts :: (ParseDot n) => Parse (DotStatements n)
parseGStmts = (Seq.fromList <$> parse)
`adjustErr`
("Not a valid generalised DotStatements\n\t"++)
statementStructure :: DotStatements n -> GraphState ()
statementStructure = F.mapM_ stmtStructure
statementNodes :: (Ord n) => DotStatements n -> NodeState n ()
statementNodes = F.mapM_ stmtNodes
statementEdges :: DotStatements n -> EdgeState n ()
statementEdges = F.mapM_ stmtEdges
generaliseStatements :: C.DotStatements n -> DotStatements n
generaliseStatements stmts = atts >< sgs >< ns >< es
where
atts = Seq.fromList . map GA $ C.attrStmts stmts
sgs = Seq.fromList . map (SG . generaliseSubGraph) $ C.subGraphs stmts
ns = Seq.fromList . map DN $ C.nodeStmts stmts
es = Seq.fromList . map DE $ C.edgeStmts stmts
data DotStatement n = GA GlobalAttributes
| SG (DotSubGraph n)
| DN (DotNode n)
| DE (DotEdge n)
deriving (Eq, Ord, Show, Read)
instance (PrintDot n) => PrintDot (DotStatement n) where
unqtDot (GA ga) = unqtDot ga
unqtDot (SG sg) = unqtDot sg
unqtDot (DN dn) = unqtDot dn
unqtDot (DE de) = unqtDot de
unqtListToDot = vcat . mapM unqtDot
listToDot = unqtListToDot
instance (ParseDot n) => ParseDot (DotStatement n) where
parseUnqt = oneOf [ GA <$> parseUnqt
, SG <$> parseUnqt
, DN <$> parseUnqt
, DE <$> parseUnqt
]
parse = parseUnqt
`adjustErr`
("Not a valid statement\n\t"++)
parseUnqtList = fmap concat . wrapWhitespace
$ parseStatements p
where
p = fmap (map DE) parseEdgeLine
`onFail`
fmap (:[]) parse
parseList = parseUnqtList
instance Functor DotStatement where
fmap _ (GA ga) = GA ga
fmap f (SG sg) = SG $ fmap f sg
fmap f (DN dn) = DN $ fmap f dn
fmap f (DE de) = DE $ fmap f de
stmtStructure :: DotStatement n -> GraphState ()
stmtStructure (GA ga) = addGraphGlobals ga
stmtStructure (SG sg) = withSubGraphID addSubGraph statementStructure sg
stmtStructure _ = return ()
stmtNodes :: (Ord n) => DotStatement n -> NodeState n ()
stmtNodes (GA ga) = addNodeGlobals ga
stmtNodes (SG sg) = withSubGraphID recursiveCall statementNodes sg
stmtNodes (DN dn) = addNode dn
stmtNodes (DE de) = addEdgeNodes de
stmtEdges :: DotStatement n -> EdgeState n ()
stmtEdges (GA ga) = addEdgeGlobals ga
stmtEdges (SG sg) = withSubGraphID recursiveCall statementEdges sg
stmtEdges (DE de) = addEdge de
stmtEdges _ = return ()
data DotSubGraph n = DotSG { isCluster :: Bool
, subGraphID :: Maybe GraphID
, subGraphStmts :: DotStatements n
}
deriving (Eq, Ord, Show, Read)
instance (PrintDot n) => PrintDot (DotSubGraph n) where
unqtDot = printStmtBased printSubGraphID' subGraphAttrType
subGraphStmts printGStmts
unqtListToDot = printStmtBasedList printSubGraphID' subGraphAttrType
subGraphStmts printGStmts
listToDot = unqtListToDot
subGraphAttrType :: DotSubGraph n -> AttributeType
subGraphAttrType = bool SubGraphAttribute ClusterAttribute . isCluster
printSubGraphID' :: DotSubGraph n -> DotCode
printSubGraphID' = printSubGraphID (isCluster &&& subGraphID)
instance (ParseDot n) => ParseDot (DotSubGraph n) where
parseUnqt = parseSubGraph DotSG parseGStmts
`onFail`
fmap (DotSG False Nothing)
(parseBracesBased SubGraphAttribute parseGStmts)
parse = parseUnqt
`adjustErr`
("Not a valid Sub Graph\n\t"++)
parseUnqtList = sepBy (whitespace *> parseUnqt) newline'
parseList = parseUnqtList
instance Functor DotSubGraph where
fmap f sg = sg { subGraphStmts = (fmap . fmap) f $ subGraphStmts sg }
generaliseSubGraph :: C.DotSubGraph n -> DotSubGraph n
generaliseSubGraph (C.DotSG isC mID stmts) = DotSG { isCluster = isC
, subGraphID = mID
, subGraphStmts = stmts'
}
where
stmts' = generaliseStatements stmts
withSubGraphID :: (Maybe (Maybe GraphID) -> b -> a)
-> (DotStatements n -> b) -> DotSubGraph n -> a
withSubGraphID f g sg = f mid . g $ subGraphStmts sg
where
mid = bool Nothing (Just $ subGraphID sg) $ isCluster sg
renumber :: DotGraph n -> DotGraph n
renumber dg = dg { graphStatements = newStmts }
where
startN = succ $ maxSGInt dg
newStmts = evalState (stsRe $ graphStatements dg) startN
stsRe = T.mapM stRe
stRe (SG sg) = SG <$> sgRe sg
stRe stmt = pure stmt
sgRe sg = do sgid' <- case subGraphID sg of
Nothing -> do n <- get
put $ succ n
return . Just . Num $ Int n
sgid -> return sgid
stmts' <- stsRe $ subGraphStmts sg
return $ sg { subGraphID = sgid'
, subGraphStmts = stmts'
}
maxSGInt :: DotGraph n -> Int
maxSGInt dg = execState (stsInt $ graphStatements dg)
. (`check` 0)
$ graphID dg
where
check = maybe id max . (numericValue =<<)
stsInt = F.mapM_ stInt
stInt (SG sg) = sgInt sg
stInt _ = return ()
sgInt sg = do modify (check $ subGraphID sg)
stsInt $ subGraphStmts sg