module Data.Graph.Inductive.Query.ArtPoint( ap ) where import Data.Graph.Inductive.Graph ------------------------------------------------------------------------------ -- Tree for storing the DFS numbers and back edges for each node in the graph. -- Each node in this tree is of the form (v,n,b) where v is the vertex number, -- n is its DFS number and b is the list of nodes (and their DFS numbers) that -- lead to back back edges for that vertex v. ------------------------------------------------------------------------------ data DFSTree a = B (a,a,[(a,a)]) [DFSTree a] deriving (Eq, Show, Read) ------------------------------------------------------------------------------ -- Tree for storing the DFS and low numbers for each node in the graph. -- Each node in this tree is of the form (v,n,l) where v is the vertex number, -- n is its DFS number and l is its low number. ------------------------------------------------------------------------------ data LOWTree a = Brc (a,a,a) [LOWTree a] deriving (Eq, Show, Read) ------------------------------------------------------------------------------ -- Finds the back edges for a given node. ------------------------------------------------------------------------------ getBackEdges :: Node -> [[(Node,Int)]] -> [(Node,Int)] getBackEdges _ [] = [] getBackEdges v ls = map head (filter (elem (v,0)) (tail ls)) ------------------------------------------------------------------------------ -- Builds a DFS tree for a given graph. Each element (v,n,b) in the tree -- contains: the node number v, the DFS number n, and a list of backedges b. ------------------------------------------------------------------------------ dfsTree :: (Graph gr) => Int -> Node -> [Node] -> [[(Node,Int)]] -> gr a b -> ([DFSTree Int],gr a b,Int) dfsTree n _ [] _ g = ([],g,n) dfsTree n _ _ _ g | isEmpty g = ([],g,n) dfsTree n u (v:vs) ls g = case match v g of (Nothing, g1) -> dfsTree n u vs ls g1 (Just c , g1) -> (B (v,n+1,bck) ts:ts', g3, k) where bck = getBackEdges v ls (ts, g2,m) = dfsTree (n+1) v sc ls' g1 (ts',g3,k) = dfsTree m v vs ls g2 ls' = ((v,n+1):sc'):ls sc' = map (\x->(x,0)) sc sc = suc' c ------------------------------------------------------------------------------ -- Finds the minimum between a dfs number and a list of back edges' dfs -- numbers. ------------------------------------------------------------------------------ minbckEdge :: Int -> [(Node,Int)] -> Int minbckEdge n [] = n minbckEdge n bs = min n (minimum (map snd bs)) ------------------------------------------------------------------------------ -- Returns the low number for a node in a subtree. ------------------------------------------------------------------------------ getLow :: LOWTree Int -> Int getLow (Brc (_,_,l) _) = l ------------------------------------------------------------------------------ -- Builds a low tree from a DFS tree. Each element (v,n,low) in the tree -- contains: the node number v, the DFS number n, and the low number low. ------------------------------------------------------------------------------ lowTree :: DFSTree Int -> LOWTree Int lowTree (B (v,n,[] ) [] ) = Brc (v,n,n) [] lowTree (B (v,n,bcks) [] ) = Brc (v,n,minbckEdge n bcks) [] lowTree (B (v,n,bcks) trs) = Brc (v,n,lowv) ts where lowv = min (minbckEdge n bcks) lowChild lowChild = minimum (map getLow ts) ts = map lowTree trs ------------------------------------------------------------------------------ -- Builds a low tree for a given graph. Each element (v,n,low) in the tree -- contains: the node number v, the DFS number n, and the low number low. ------------------------------------------------------------------------------ getLowTree :: (Graph gr) => gr a b -> Node -> LOWTree Int getLowTree g v = lowTree (head dfsf) where (dfsf, _, _) = dfsTree 0 0 [v] [] g ------------------------------------------------------------------------------ -- Tests if a node in a subtree is an articulation point. An non-root node v -- is an articulation point iff there exists at least one child w of v such -- that lowNumber(w) >= dfsNumber(v). The root node is an articulation point -- iff it has two or more children. ------------------------------------------------------------------------------ isap :: LOWTree Int -> Bool isap (Brc (_,_,_) []) = False isap (Brc (_,1,_) ts) = length ts > 1 isap (Brc (_,n,_) ts) = not (null ch) where ch = filter ( >=n) (map getLow ts) ------------------------------------------------------------------------------ -- Finds the articulation points by traversing the low tree. ------------------------------------------------------------------------------ arp :: LOWTree Int -> [Node] arp (Brc (v,1,_) ts) | length ts > 1 = v:concatMap arp ts | otherwise = concatMap arp ts arp (Brc (v,n,l) ts) | isap (Brc (v,n,l) ts) = v:concatMap arp ts | otherwise = concatMap arp ts ------------------------------------------------------------------------------ -- Finds the articulation points of a graph starting at a given node. ------------------------------------------------------------------------------ artpoints :: (Graph gr) => gr a b -> Node -> [Node] artpoints g v = arp (getLowTree g v) {-| Finds the articulation points for a connected undirected graph, by using the low numbers criteria: a) The root node is an articulation point iff it has two or more children. b) An non-root node v is an articulation point iff there exists at least one child w of v such that lowNumber(w) >= dfsNumber(v). -} ap :: (Graph gr) => gr a b -> [Node] ap g = artpoints g v where ((_,v,_,_),_) = matchAny g