{-| Module : Gargantext.Core.Viz.Graph.Bridgeness Description : Bridgeness filter Copyright : (c) CNRS, 2017-Present License : AGPL + CECILL v3 Maintainer : team@gargantext.org Stability : experimental Portability : POSIX Let be a graph Bridgeness filters inter-communities links in two ways. If the partitions are known, filtering is uniform to expose the communities clearly for the beginners. But uniformly filters inter-communities links. TODO use Map LouvainNodeId (Map LouvainNodeId) -} {-# LANGUAGE BangPatterns #-} module Gargantext.Core.Viz.Graph.Bridgeness -- (bridgeness) where import Gargantext.Core.Methods.Similarities (Similarity(..)) -- import Data.IntMap (IntMap) import Data.Map.Strict (Map, fromListWith, lookup, toList, mapWithKey, elems) import Data.Maybe (catMaybes) import Data.Ord (Down(..)) import Debug.Trace (trace) import Gargantext.Prelude import Graph.Types (ClusterNode(..)) -- import qualified Data.IntMap as IntMap import qualified Data.List as List import qualified Data.Map.Strict as Map -- import qualified Data.Set as Set ---------------------------------------------------------------------- type Partitions = Map (Int, Int) Double -> IO [ClusterNode] ---------------------------------------------------------------------- nodeId2comId :: ClusterNode -> (NodeId, CommunityId) nodeId2comId (ClusterNode i1 i2) = (i1, i2) type NodeId = Int type CommunityId = Int ---------------------------------------------------------------------- ---------------------------------------------------------------------- data Bridgeness = Bridgeness_Basic { bridgeness_partitions :: [ClusterNode] , bridgeness_filter :: Double } | Bridgeness_Advanced { bridgeness_similarity :: Similarity , bridgness_confluence :: Confluence } type Confluence = Map (NodeId, NodeId) Double bridgeness :: Bridgeness -> Map (NodeId, NodeId) Double -> Map (NodeId, NodeId) Double bridgeness (Bridgeness_Advanced sim c) m = Map.fromList $ List.filter (\x -> if sim == Conditional then snd x > 0.2 else snd x > 0.02) $ map (\(ks, (v1,_v2)) -> (ks,v1)) -- $ List.take (if sim == Conditional then 2*n else 3*n) -- $ List.sortOn (Down . (snd . snd)) $ Map.toList $ trace ("bridgeness3 m c" <> show (m,c)) $ Map.intersectionWithKey (\k v1 v2 -> trace ("intersectionWithKey " <> (show (k, v1, v2))) (v1, v2)) m c {- where !m' = Map.toList m n :: Int !n = trace ("bridgeness m size: " <> (show $ List.length m')) $ round $ (fromIntegral $ List.length m') / (log $ fromIntegral nodesNumber :: Double) nodesNumber :: Int nodesNumber = Set.size $ Set.fromList $ as <> bs where (as, bs) = List.unzip $ Map.keys m -} bridgeness (Bridgeness_Basic ns b) m = Map.fromList $ List.concat $ Map.elems $ filterComs b $ groupEdges (Map.fromList $ map nodeId2comId ns) m groupEdges :: (Ord a, Ord b1) => Map b1 a -> Map (b1, b1) b2 -> Map (a, a) [((b1, b1), b2)] groupEdges m = fromListWith (<>) . catMaybes . map (\((n1,n2), d) -> let n1n2_m = (,) <$> lookup n1 m <*> lookup n2 m n1n2_d = Just [((n1,n2),d)] in (,) <$> n1n2_m <*> n1n2_d ) . toList -- | TODO : sortOn Confluence filterComs :: (Ord n1, Eq n2) => p -> Map (n2, n2) [(a3, n1)] -> Map (n2, n2) [(a3, n1)] filterComs _b m = Map.filter (\n -> length n > 0) $ mapWithKey filter' m where filter' (c1,c2) a | c1 == c2 = a -- TODO use n here | otherwise = take n $ List.sortOn (Down . snd) a where n :: Int n = round $ 100 * a' / t a'= fromIntegral $ length a t :: Double t = fromIntegral $ length $ List.concat $ elems m -------------------------------------------------------------- -- Utils {-- map2intMap :: Map (Int, Int) a -> IntMap (IntMap a) map2intMap m = IntMap.fromListWith (<>) $ map (\((k1,k2), v) -> if k1 < k2 then (k1, IntMap.singleton k2 v) else (k2, IntMap.singleton k1 v) ) $ Map.toList m look :: (Int,Int) -> IntMap (IntMap a) -> Maybe a look (k1,k2) m = if k1 < k2 then case (IntMap.lookup k1 m) of Just m' -> IntMap.lookup k2 m' _ -> Nothing else look (k2,k1) m {- Compute the median of a list From: https://hackage.haskell.org/package/dsp-0.2.5.1/docs/src/Numeric.Statistics.Median.html Compute the center of the list in a more lazy manner and thus halves memory requirement. -} median :: (Ord a, Fractional a) => [a] -> a median [] = panic "medianFast: empty list has no median" median zs = let recurse (x0:_) (_:[]) = x0 recurse (x0:x1:_) (_:_:[]) = (x0+x1)/2 recurse (_:xs) (_:_:ys) = recurse xs ys recurse _ _ = panic "median: this error cannot occur in the way 'recurse' is called" in recurse zs zs -}