{-# LANGUAGE CPP, FlexibleInstances, MultiParamTypeClasses #-} {- | Module : Data.GraphViz.Types.Monadic Description : A monadic interface for making Dot graphs. Copyright : (c) Ivan Lazar Miljenovic License : 3-Clause BSD-style Maintainer : Ivan.Miljenovic@gmail.com This module is based upon the /dotgen/ library by Andy Gill: <http://hackage.haskell.org/package/dotgen> It provides a monadic interface for constructing generalised Dot graphs. Note that this does /not/ have an instance for @DotRepr@ (e.g. what would be the point of the @fromCanonical@ function, as you can't do anything with the result): it is purely for construction purposes. Use the generalised Dot graph instance for printing, etc. Note that the generalised Dot graph types are /not/ re-exported, in case it causes a clash with other modules you may choose to import. The example graph in "Data.GraphViz.Types" can be written as: > digraph (Str "G") $ do > > cluster (Int 0) $ do > graphAttrs [style filled, color LightGray] > nodeAttrs [style filled, color White] > "a0" --> "a1" > "a1" --> "a2" > "a2" --> "a3" > graphAttrs [textLabel "process #1"] > > cluster (Int 1) $ do > nodeAttrs [style filled] > "b0" --> "b1" > "b1" --> "b2" > "b2" --> "b3" > graphAttrs [textLabel "process #2", color Blue] > > "start" --> "a0" > "start" --> "b0" > "a1" --> "b3" > "b2" --> "a3" > "a3" --> "end" > "b3" --> "end" > > node "start" [shape MDiamond] > node "end" [shape MSquare] -} module Data.GraphViz.Types.Monadic ( Dot , DotM , GraphID(..) -- * Creating a generalised DotGraph. , digraph , digraph' , graph , graph' -- * Adding global attributes. , graphAttrs , nodeAttrs , edgeAttrs -- * Adding items to the graph. -- ** Subgraphs and clusters , subgraph , anonSubgraph , cluster -- ** Nodes , node , node' -- ** Edges -- $edges , edge , (-->) , (<->) ) where import Data.GraphViz.Attributes (Attributes) import Data.GraphViz.Types.Generalised import Data.DList (DList) import qualified Data.DList as DL import qualified Data.Sequence as Seq #if !(MIN_VERSION_base (4,8,0)) import Control.Applicative (Applicative(..)) import Data.Monoid (Monoid(..)) #endif #if MIN_VERSION_base (4,9,0) && !MIN_VERSION_base (4,13,0) import Data.Semigroup (Semigroup(..)) #endif -- ----------------------------------------------------------------------------- -- The Dot monad. -- | The monadic representation of a Dot graph. type Dot n = DotM n () -- | The actual monad; as with 'Dot' but allows you to return a value -- within the do-block. The actual implementation is based upon the -- Writer monad. newtype DotM n a = DotM { runDot :: (a, DotStmts n) } execDot :: DotM n a -> DotStmts n execDot = snd . runDot instance Functor (DotM n) where fmap f (DotM (a,stmts)) = DotM (f a, stmts) instance Applicative (DotM n) where pure = DotM . flip (,) DL.empty (DotM (f,stmts1)) <*> (DotM (a,stmts2)) = DotM (f a, stmts1 `DL.append` stmts2) instance Monad (DotM n) where return = pure dt >>= f = DotM $ let ~(a,stmts) = runDot dt ~(b,stmts') = runDot $ f a in (b, stmts `DL.append` stmts') #if MIN_VERSION_base (4,9,0) instance Semigroup a => Semigroup (DotM n a) where DotM x1 <> DotM x2 = DotM (x1 <> x2) #endif instance Monoid a => Monoid (DotM n a) where mappend (DotM x1) (DotM x2) = DotM (mappend x1 x2) mempty = DotM mempty tell :: DotStmts n -> Dot n tell = DotM . (,) () tellStmt :: DotStmt n -> Dot n tellStmt = tell . DL.singleton -- ----------------------------------------------------------------------------- -- Creating the DotGraph -- | Create a directed dot graph with the specified graph ID. digraph :: GraphID -> DotM n a -> DotGraph n digraph = mkGraph True . Just -- | Create a directed dot graph with no graph ID. digraph' :: DotM n a -> DotGraph n digraph' = mkGraph True Nothing -- | Create a undirected dot graph with the specified graph ID. graph :: GraphID -> DotM n a -> DotGraph n graph = mkGraph False . Just -- | Create a undirected dot graph with no graph ID. graph' :: DotM n a -> DotGraph n graph' = mkGraph False Nothing mkGraph :: Bool -> Maybe GraphID -> DotM n a -> DotGraph n mkGraph isDir mid dot = DotGraph { strictGraph = False , directedGraph = isDir , graphID = mid , graphStatements = execStmts dot } -- ----------------------------------------------------------------------------- -- Statements type DotStmts n = DList (DotStmt n) execStmts :: DotM n a -> DotStatements n execStmts = convertStatements . execDot convertStatements :: DotStmts n -> DotStatements n convertStatements = Seq.fromList . map convertStatement . DL.toList data DotStmt n = MA GlobalAttributes | MS (Subgraph n) | MN (DotNode n) | ME (DotEdge n) convertStatement :: DotStmt n -> DotStatement n convertStatement (MA gas) = GA gas convertStatement (MS sg) = SG . DotSG (sgIsClust sg) (sgID sg) . execStmts $ sgStmts sg convertStatement (MN dn) = DN dn convertStatement (ME de) = DE de -- ----------------------------------------------------------------------------- -- Global Attributes -- | Add graph\/sub-graph\/cluster attributes. graphAttrs :: Attributes -> Dot n graphAttrs = tellStmt . MA . GraphAttrs -- | Add global node attributes. nodeAttrs :: Attributes -> Dot n nodeAttrs = tellStmt . MA . NodeAttrs -- | Add global edge attributes edgeAttrs :: Attributes -> Dot n edgeAttrs = tellStmt . MA . EdgeAttrs -- ----------------------------------------------------------------------------- -- Subgraphs (including Clusters) data Subgraph n = Sg { sgIsClust :: Bool , sgID :: Maybe GraphID , sgStmts :: Dot n } -- | Add a named subgraph to the graph. subgraph :: GraphID -> DotM n a -> Dot n subgraph = nonClust . Just -- | Add an anonymous subgraph to the graph. -- -- It is highly recommended you use 'subgraph' instead. anonSubgraph :: DotM n a -> Dot n anonSubgraph = nonClust Nothing nonClust :: Maybe GraphID -> DotM n a -> Dot n nonClust = createSubGraph False createSubGraph :: Bool -> Maybe GraphID -> DotM n a -> Dot n createSubGraph isCl mid = tellStmt . MS . Sg isCl mid . (>> return ()) -- | Add a named cluster to the graph. cluster :: GraphID -> DotM n a -> Dot n cluster = createSubGraph True . Just -- ----------------------------------------------------------------------------- -- Nodes -- | Add a node to the graph. node :: n -> Attributes -> Dot n node n = tellStmt . MN . DotNode n -- | Add a node with no attributes to the graph. node' :: n -> Dot n node' = (`node` []) -- ----------------------------------------------------------------------------- -- Edges {- $edges If you wish to use something analogous to Dot's ability to write multiple edges with in-line subgraphs such as: > {a b c} -> {d e f} Then you can use '-->' and '<->' in combination with monadic traversal functions such as @traverse_@, @for_@, @mapM_@, @forM_@ and @zipWithM_@; for example: > ("a" -->) `traverse_` ["d", "e", "f"] > ["a", "b", "c"] `for_` (--> "d") > zipWithM_ (-->) ["a", "b", "c"] ["d", "e", "f"] -} -- | Add an edge to the graph. edge :: n -> n -> Attributes -> Dot n edge f t = tellStmt . ME . DotEdge f t -- | Add an edge with no attributes. (-->) :: n -> n -> Dot n f --> t = edge f t [] infixr 9 --> -- | An alias for '-->' to make edges look more undirected. (<->) :: n -> n -> Dot n (<->) = (-->) infixr 9 <-> -- -----------------------------------------------------------------------------