{-# LANGUAGE CPP #-} #if __GLASGOW_HASKELL__ {-# LANGUAGE Rank2Types #-} {-# LANGUAGE DeriveDataTypeable #-} {-# LANGUAGE StandaloneDeriving #-} #endif #if __GLASGOW_HASKELL__ >= 703 {-# LANGUAGE Trustworthy #-} #endif #if __GLASGOW_HASKELL__ >= 702 {-# LANGUAGE DeriveGeneric #-} {-# LANGUAGE StandaloneDeriving #-} #endif #include "containers.h" ----------------------------------------------------------------------------- -- | -- Module : Data.Graph -- Copyright : (c) The University of Glasgow 2002 -- License : BSD-style (see the file libraries/base/LICENSE) -- -- Maintainer : libraries@haskell.org -- Stability : experimental -- Portability : portable -- -- A version of the graph algorithms described in: -- -- /Structuring Depth-First Search Algorithms in Haskell/, -- by David King and John Launchbury. -- ----------------------------------------------------------------------------- module Data.Graph( -- * External interface -- At present the only one with a "nice" external interface stronglyConnComp, stronglyConnCompR, SCC(..), flattenSCC, flattenSCCs, -- * Graphs Graph, Table, Bounds, Edge, Vertex, -- ** Building graphs graphFromEdges, graphFromEdges', buildG, transposeG, -- reverseE, -- ** Graph properties vertices, edges, outdegree, indegree, -- * Algorithms dfs, dff, topSort, components, scc, bcc, -- tree, back, cross, forward, reachable, path, module Data.Tree ) where #if __GLASGOW_HASKELL__ # define USE_ST_MONAD 1 #endif -- Extensions #if USE_ST_MONAD import Control.Monad.ST import Data.Array.ST (STArray, newArray, readArray, writeArray) #else import Data.IntSet (IntSet) import qualified Data.IntSet as Set #endif import Data.Tree (Tree(Node), Forest) -- std interfaces #if !MIN_VERSION_base(4,8,0) import Control.Applicative import qualified Data.Foldable as F import Data.Traversable #else import Data.Foldable as F #endif import Control.DeepSeq (NFData(rnf)) import Data.Maybe import Data.Array import Data.List #if MIN_VERSION_base(4,9,0) import Data.Functor.Classes import Data.Semigroup (Semigroup (..)) #endif #if __GLASGOW_HASKELL__ >= 706 import GHC.Generics (Generic, Generic1) #elif __GLASGOW_HASKELL__ >= 702 import GHC.Generics (Generic) #endif #ifdef __GLASGOW_HASKELL__ import Data.Data (Data) #endif import Data.Typeable ------------------------------------------------------------------------- -- - -- External interface -- - ------------------------------------------------------------------------- -- | Strongly connected component. data SCC vertex = AcyclicSCC vertex -- ^ A single vertex that is not -- in any cycle. | CyclicSCC [vertex] -- ^ A maximal set of mutually -- reachable vertices. deriving (Eq, Show, Read) INSTANCE_TYPEABLE1(SCC) #ifdef __GLASGOW_HASKELL__ deriving instance Data vertex => Data (SCC vertex) #endif #if __GLASGOW_HASKELL__ >= 706 deriving instance Generic1 SCC #endif #if __GLASGOW_HASKELL__ >= 702 deriving instance Generic (SCC vertex) #endif #if MIN_VERSION_base(4,9,0) instance Eq1 SCC where liftEq eq (AcyclicSCC v1) (AcyclicSCC v2) = eq v1 v2 liftEq eq (CyclicSCC vs1) (CyclicSCC vs2) = liftEq eq vs1 vs2 liftEq _ _ _ = False instance Show1 SCC where liftShowsPrec sp _sl d (AcyclicSCC v) = showsUnaryWith sp "AcyclicSCC" d v liftShowsPrec _sp sl d (CyclicSCC vs) = showsUnaryWith (const sl) "CyclicSCC" d vs instance Read1 SCC where liftReadsPrec rp rl = readsData $ readsUnaryWith rp "AcyclicSCC" AcyclicSCC <> readsUnaryWith (const rl) "CyclicSCC" CyclicSCC #endif instance F.Foldable SCC where foldr c n (AcyclicSCC v) = c v n foldr c n (CyclicSCC vs) = foldr c n vs instance Traversable SCC where -- We treat the non-empty cyclic case specially to cut one -- fmap application. traverse f (AcyclicSCC vertex) = AcyclicSCC <$> f vertex traverse _f (CyclicSCC []) = pure (CyclicSCC []) traverse f (CyclicSCC (x : xs)) = (\x' xs' -> CyclicSCC (x' : xs')) <$> f x <*> traverse f xs instance NFData a => NFData (SCC a) where rnf (AcyclicSCC v) = rnf v rnf (CyclicSCC vs) = rnf vs instance Functor SCC where fmap f (AcyclicSCC v) = AcyclicSCC (f v) fmap f (CyclicSCC vs) = CyclicSCC (fmap f vs) -- | The vertices of a list of strongly connected components. flattenSCCs :: [SCC a] -> [a] flattenSCCs = concatMap flattenSCC -- | The vertices of a strongly connected component. flattenSCC :: SCC vertex -> [vertex] flattenSCC (AcyclicSCC v) = [v] flattenSCC (CyclicSCC vs) = vs -- | The strongly connected components of a directed graph, topologically -- sorted. stronglyConnComp :: Ord key => [(node, key, [key])] -- ^ The graph: a list of nodes uniquely identified by keys, -- with a list of keys of nodes this node has edges to. -- The out-list may contain keys that don't correspond to -- nodes of the graph; such edges are ignored. -> [SCC node] stronglyConnComp edges0 = map get_node (stronglyConnCompR edges0) where get_node (AcyclicSCC (n, _, _)) = AcyclicSCC n get_node (CyclicSCC triples) = CyclicSCC [n | (n,_,_) <- triples] -- | The strongly connected components of a directed graph, topologically -- sorted. The function is the same as 'stronglyConnComp', except that -- all the information about each node retained. -- This interface is used when you expect to apply 'SCC' to -- (some of) the result of 'SCC', so you don't want to lose the -- dependency information. stronglyConnCompR :: Ord key => [(node, key, [key])] -- ^ The graph: a list of nodes uniquely identified by keys, -- with a list of keys of nodes this node has edges to. -- The out-list may contain keys that don't correspond to -- nodes of the graph; such edges are ignored. -> [SCC (node, key, [key])] -- ^ Topologically sorted stronglyConnCompR [] = [] -- added to avoid creating empty array in graphFromEdges -- SOF stronglyConnCompR edges0 = map decode forest where (graph, vertex_fn,_) = graphFromEdges edges0 forest = scc graph decode (Node v []) | mentions_itself v = CyclicSCC [vertex_fn v] | otherwise = AcyclicSCC (vertex_fn v) decode other = CyclicSCC (dec other []) where dec (Node v ts) vs = vertex_fn v : foldr dec vs ts mentions_itself v = v `elem` (graph ! v) ------------------------------------------------------------------------- -- - -- Graphs -- - ------------------------------------------------------------------------- -- | Abstract representation of vertices. type Vertex = Int -- | Table indexed by a contiguous set of vertices. type Table a = Array Vertex a -- | Adjacency list representation of a graph, mapping each vertex to its -- list of successors. type Graph = Table [Vertex] -- | The bounds of a 'Table'. type Bounds = (Vertex, Vertex) -- | An edge from the first vertex to the second. type Edge = (Vertex, Vertex) -- | All vertices of a graph. vertices :: Graph -> [Vertex] vertices = indices -- | All edges of a graph. edges :: Graph -> [Edge] edges g = [ (v, w) | v <- vertices g, w <- g!v ] mapT :: (Vertex -> a -> b) -> Table a -> Table b mapT f t = array (bounds t) [ (,) v (f v (t!v)) | v <- indices t ] -- | Build a graph from a list of edges. buildG :: Bounds -> [Edge] -> Graph buildG bounds0 edges0 = accumArray (flip (:)) [] bounds0 edges0 -- | The graph obtained by reversing all edges. transposeG :: Graph -> Graph transposeG g = buildG (bounds g) (reverseE g) reverseE :: Graph -> [Edge] reverseE g = [ (w, v) | (v, w) <- edges g ] -- | A table of the count of edges from each node. outdegree :: Graph -> Table Int outdegree = mapT numEdges where numEdges _ ws = length ws -- | A table of the count of edges into each node. indegree :: Graph -> Table Int indegree = outdegree . transposeG -- | Identical to 'graphFromEdges', except that the return value -- does not include the function which maps keys to vertices. This -- version of 'graphFromEdges' is for backwards compatibility. graphFromEdges' :: Ord key => [(node, key, [key])] -> (Graph, Vertex -> (node, key, [key])) graphFromEdges' x = (a,b) where (a,b,_) = graphFromEdges x -- | Build a graph from a list of nodes uniquely identified by keys, -- with a list of keys of nodes this node should have edges to. -- The out-list may contain keys that don't correspond to -- nodes of the graph; they are ignored. graphFromEdges :: Ord key => [(node, key, [key])] -> (Graph, Vertex -> (node, key, [key]), key -> Maybe Vertex) graphFromEdges edges0 = (graph, \v -> vertex_map ! v, key_vertex) where max_v = length edges0 - 1 bounds0 = (0,max_v) :: (Vertex, Vertex) sorted_edges = sortBy lt edges0 edges1 = zipWith (,) [0..] sorted_edges graph = array bounds0 [(,) v (mapMaybe key_vertex ks) | (,) v (_, _, ks) <- edges1] key_map = array bounds0 [(,) v k | (,) v (_, k, _ ) <- edges1] vertex_map = array bounds0 edges1 (_,k1,_) `lt` (_,k2,_) = k1 `compare` k2 -- key_vertex :: key -> Maybe Vertex -- returns Nothing for non-interesting vertices key_vertex k = findVertex 0 max_v where findVertex a b | a > b = Nothing findVertex a b = case compare k (key_map ! mid) of LT -> findVertex a (mid-1) EQ -> Just mid GT -> findVertex (mid+1) b where mid = a + (b - a) `div` 2 ------------------------------------------------------------------------- -- - -- Depth first search -- - ------------------------------------------------------------------------- -- | A spanning forest of the graph, obtained from a depth-first search of -- the graph starting from each vertex in an unspecified order. dff :: Graph -> Forest Vertex dff g = dfs g (vertices g) -- | A spanning forest of the part of the graph reachable from the listed -- vertices, obtained from a depth-first search of the graph starting at -- each of the listed vertices in order. dfs :: Graph -> [Vertex] -> Forest Vertex dfs g vs = prune (bounds g) (map (generate g) vs) generate :: Graph -> Vertex -> Tree Vertex generate g v = Node v (map (generate g) (g!v)) prune :: Bounds -> Forest Vertex -> Forest Vertex prune bnds ts = run bnds (chop ts) chop :: Forest Vertex -> SetM s (Forest Vertex) chop [] = return [] chop (Node v ts : us) = do visited <- contains v if visited then chop us else do include v as <- chop ts bs <- chop us return (Node v as : bs) -- A monad holding a set of vertices visited so far. #if USE_ST_MONAD -- Use the ST monad if available, for constant-time primitives. newtype SetM s a = SetM { runSetM :: STArray s Vertex Bool -> ST s a } instance Monad (SetM s) where return = pure {-# INLINE return #-} SetM v >>= f = SetM $ \s -> do { x <- v s; runSetM (f x) s } {-# INLINE (>>=) #-} instance Functor (SetM s) where f `fmap` SetM v = SetM $ \s -> f `fmap` v s {-# INLINE fmap #-} instance Applicative (SetM s) where pure x = SetM $ const (return x) {-# INLINE pure #-} SetM f <*> SetM v = SetM $ \s -> f s >>= (`fmap` v s) -- We could also use the following definition -- SetM f <*> SetM v = SetM $ \s -> f s <*> v s -- but Applicative (ST s) instance is present only in GHC 7.2+ {-# INLINE (<*>) #-} run :: Bounds -> (forall s. SetM s a) -> a run bnds act = runST (newArray bnds False >>= runSetM act) contains :: Vertex -> SetM s Bool contains v = SetM $ \ m -> readArray m v include :: Vertex -> SetM s () include v = SetM $ \ m -> writeArray m v True #else /* !USE_ST_MONAD */ -- Portable implementation using IntSet. newtype SetM s a = SetM { runSetM :: IntSet -> (a, IntSet) } instance Monad (SetM s) where return x = SetM $ \s -> (x, s) SetM v >>= f = SetM $ \s -> case v s of (x, s') -> runSetM (f x) s' instance Functor (SetM s) where f `fmap` SetM v = SetM $ \s -> case v s of (x, s') -> (f x, s') {-# INLINE fmap #-} instance Applicative (SetM s) where pure x = SetM $ \s -> (x, s) {-# INLINE pure #-} SetM f <*> SetM v = SetM $ \s -> case f s of (k, s') -> case v s' of (x, s'') -> (k x, s'') {-# INLINE (<*>) #-} run :: Bounds -> SetM s a -> a run _ act = fst (runSetM act Set.empty) contains :: Vertex -> SetM s Bool contains v = SetM $ \ m -> (Set.member v m, m) include :: Vertex -> SetM s () include v = SetM $ \ m -> ((), Set.insert v m) #endif /* !USE_ST_MONAD */ ------------------------------------------------------------------------- -- - -- Algorithms -- - ------------------------------------------------------------------------- ------------------------------------------------------------ -- Algorithm 1: depth first search numbering ------------------------------------------------------------ preorder' :: Tree a -> [a] -> [a] preorder' (Node a ts) = (a :) . preorderF' ts preorderF' :: Forest a -> [a] -> [a] preorderF' ts = foldr (.) id $ map preorder' ts preorderF :: Forest a -> [a] preorderF ts = preorderF' ts [] tabulate :: Bounds -> [Vertex] -> Table Int tabulate bnds vs = array bnds (zipWith (,) vs [1..]) preArr :: Bounds -> Forest Vertex -> Table Int preArr bnds = tabulate bnds . preorderF ------------------------------------------------------------ -- Algorithm 2: topological sorting ------------------------------------------------------------ postorder :: Tree a -> [a] -> [a] postorder (Node a ts) = postorderF ts . (a :) postorderF :: Forest a -> [a] -> [a] postorderF ts = foldr (.) id $ map postorder ts postOrd :: Graph -> [Vertex] postOrd g = postorderF (dff g) [] -- | A topological sort of the graph. -- The order is partially specified by the condition that a vertex /i/ -- precedes /j/ whenever /j/ is reachable from /i/ but not vice versa. topSort :: Graph -> [Vertex] topSort = reverse . postOrd ------------------------------------------------------------ -- Algorithm 3: connected components ------------------------------------------------------------ -- | The connected components of a graph. -- Two vertices are connected if there is a path between them, traversing -- edges in either direction. components :: Graph -> Forest Vertex components = dff . undirected undirected :: Graph -> Graph undirected g = buildG (bounds g) (edges g ++ reverseE g) -- Algorithm 4: strongly connected components -- | The strongly connected components of a graph. scc :: Graph -> Forest Vertex scc g = dfs g (reverse (postOrd (transposeG g))) ------------------------------------------------------------ -- Algorithm 5: Classifying edges ------------------------------------------------------------ {- XXX unused code tree :: Bounds -> Forest Vertex -> Graph tree bnds ts = buildG bnds (concat (map flat ts)) where flat (Node v ts') = [ (v, w) | Node w _us <- ts' ] ++ concat (map flat ts') back :: Graph -> Table Int -> Graph back g post = mapT select g where select v ws = [ w | w <- ws, post!v < post!w ] cross :: Graph -> Table Int -> Table Int -> Graph cross g pre post = mapT select g where select v ws = [ w | w <- ws, post!v > post!w, pre!v > pre!w ] forward :: Graph -> Graph -> Table Int -> Graph forward g tree' pre = mapT select g where select v ws = [ w | w <- ws, pre!v < pre!w ] \\ tree' ! v -} ------------------------------------------------------------ -- Algorithm 6: Finding reachable vertices ------------------------------------------------------------ -- | A list of vertices reachable from a given vertex. reachable :: Graph -> Vertex -> [Vertex] reachable g v = preorderF (dfs g [v]) -- | Is the second vertex reachable from the first? path :: Graph -> Vertex -> Vertex -> Bool path g v w = w `elem` (reachable g v) ------------------------------------------------------------ -- Algorithm 7: Biconnected components ------------------------------------------------------------ -- | The biconnected components of a graph. -- An undirected graph is biconnected if the deletion of any vertex -- leaves it connected. bcc :: Graph -> Forest [Vertex] bcc g = (concat . map bicomps . map (do_label g dnum)) forest where forest = dff g dnum = preArr (bounds g) forest do_label :: Graph -> Table Int -> Tree Vertex -> Tree (Vertex,Int,Int) do_label g dnum (Node v ts) = Node (v,dnum!v,lv) us where us = map (do_label g dnum) ts lv = minimum ([dnum!v] ++ [dnum!w | w <- g!v] ++ [lu | Node (_,_,lu) _ <- us]) bicomps :: Tree (Vertex,Int,Int) -> Forest [Vertex] bicomps (Node (v,_,_) ts) = [ Node (v:vs) us | (_,Node vs us) <- map collect ts] collect :: Tree (Vertex,Int,Int) -> (Int, Tree [Vertex]) collect (Node (v,dv,lv) ts) = (lv, Node (v:vs) cs) where collected = map collect ts vs = concat [ ws | (lw, Node ws _) <- collected, lw