{-# LANGUAGE CPP #-} {-# LANGUAGE FlexibleInstances #-} {-# LANGUAGE MultiParamTypeClasses #-} -------------------------------------------------------------------------------- -- See end of this file for licence information. -------------------------------------------------------------------------------- -- | -- Module : GraphMatch -- Copyright : (c) 2003, Graham Klyne, 2009 Vasili I Galchin, 2011, 2012 Douglas Burke -- License : GPL V2 -- -- Maintainer : Douglas Burke -- Stability : experimental -- Portability : CPP, FlexibleInstances, MultiParamTypeClasses -- -- This module contains graph-matching logic. -- -- The algorithm used is derived from a paper on RDF graph matching -- by Jeremy Carroll . -- -------------------------------------------------------------------------------- module Swish.GraphMatch ( graphMatch, -- * Exported for testing LabelMap, GenLabelMap(..), LabelEntry, GenLabelEntry(..), ScopedLabel(..), makeScopedLabel, makeScopedArc, LabelIndex, EquivalenceClass, nullLabelVal, emptyMap, labelIsVar, labelHash, mapLabelIndex, setLabelHash, newLabelMap, graphLabels, assignLabelMap, newGenerationMap, graphMatch1, graphMatch2, equivalenceClasses, reclassify ) where import Swish.GraphClass (Arc(..), ArcSet, Label(..)) import Swish.GraphClass (getComponents, arcLabels, hasLabel, arcToTriple) import Control.Exception.Base (assert) import Control.Arrow (second) import Data.Function (on) import Data.Hashable (hashWithSalt) import Data.List (foldl', sortBy, groupBy, partition) import Data.Ord (comparing) import Data.Word import qualified Data.List as L import qualified Data.Map as M import qualified Data.Set as S -------------------------- -- Label index value type -------------------------- -- -- | LabelIndex is a unique value assigned to each label, such that -- labels with different values are definitely different values -- in the graph; e.g. do not map to each other in the graph -- bijection. The first member is a generation counter that -- ensures new values are distinct from earlier passes. type LabelIndex = (Word32, Word32) -- | The null, or empty, index value. nullLabelVal :: LabelIndex nullLabelVal = (0, 0) ----------------------- -- Label mapping types ----------------------- -- | A Mapping between a label and a value (e.g. an index -- value). data (Label lb) => GenLabelEntry lb lv = LabelEntry lb lv -- | A label associated with a 'LabelIndex' type LabelEntry lb = GenLabelEntry lb LabelIndex instance (Label lb, Show lv) => Show (GenLabelEntry lb lv) where show (LabelEntry k v) = show k ++ ":" ++ show v instance (Label lb, Eq lv) => Eq (GenLabelEntry lb lv) where (LabelEntry k1 v1) == (LabelEntry k2 v2) = (k1,v1) == (k2,v2) instance (Label lb, Show lv, Ord lv) => Ord (GenLabelEntry lb lv) where (LabelEntry lb1 lv1) `compare` (LabelEntry lb2 lv2) = (lb1, lv1) `compare` (lb2, lv2) -- | Type for label->index lookup table data (Label lb, Eq lv, Show lv) => GenLabelMap lb lv = LabelMap Word32 (M.Map lb lv) -- | A label lookup table specialized to 'LabelIndex' indices. type LabelMap lb = GenLabelMap lb LabelIndex instance (Label lb) => Show (LabelMap lb) where show = showLabelMap instance (Label lb) => Eq (LabelMap lb) where LabelMap gen1 lmap1 == LabelMap gen2 lmap2 = (gen1, lmap1) == (gen2, lmap2) -- | The empty label map table. emptyMap :: (Label lb) => LabelMap lb emptyMap = LabelMap 1 M.empty -------------------------- -- Equivalence class type -------------------------- -- -- | Type for equivalence class description -- (An equivalence class is a collection of labels with -- the same 'LabelIndex' value.) type EquivalenceClass lb = (LabelIndex, [lb]) {- ecIndex :: EquivalenceClass lb -> LabelIndex ecIndex = fst -} ecLabels :: EquivalenceClass lb -> [lb] ecLabels = snd {- ecSize :: EquivalenceClass lb -> Int ecSize = length . ecLabels -} ecRemoveLabel :: (Label lb) => EquivalenceClass lb -> lb -> EquivalenceClass lb ecRemoveLabel xs l = second (L.delete l) xs ------------------------------------------------------------ -- Filter, ungroup, sort and group pairs by first member ------------------------------------------------------------ {- pairSelect :: ((a,b) -> Bool) -> ((a,b) -> c) -> [(a,b)] -> [c] pairSelect p f as = map f (filter p as) -} -- | Ungroup the pairs. pairUngroup :: (a,[b]) -- ^ Given (a,bs) -> [(a,b)] -- ^ Returns (a,b) for all b in bs pairUngroup (a,bs) = [ (a,b) | b <- bs ] -- | Order the pairs based on the first argument. pairSort :: (Ord a) => [(a,b)] -> [(a,b)] pairSort = sortBy (comparing fst) -- TODO: use set on input -- | Group the pairs based on the first argument. pairGroup :: (Ord a) => [(a,b)] -> [(a,[b])] pairGroup = map (factor . unzip) . groupBy eqFirst . pairSort where -- as is not [] by construction, but would be nice to have -- this enforced by the types factor (as, bs) = (head as, bs) eqFirst = (==) `on` fst ------------------------------------------------------------ -- Augmented graph label value - for graph matching ------------------------------------------------------------ -- -- | This instance of class label adds a graph identifier to -- each variable label, so that variable labels from -- different graphs are always seen as distinct values. -- -- The essential logic added by this class instance is embodied -- in the eq and hash functions. Note that variable label hashes -- depend only on the graph in which they appear, and non-variable -- label hashes depend only on the variable. Label hash values are -- used when initializing a label equivalence-class map (and, for -- non-variable labels, also for resolving hash collisions). data (Label lb) => ScopedLabel lb = ScopedLabel Int lb -- | Create a scoped label given an identifier and label. makeScopedLabel :: (Label lb) => Int -> lb -> ScopedLabel lb makeScopedLabel = ScopedLabel -- | Create an arc containining a scoped label with the given identifier. makeScopedArc :: (Label lb) => Int -> Arc lb -> Arc (ScopedLabel lb) makeScopedArc scope = fmap (ScopedLabel scope) instance (Label lb) => Label (ScopedLabel lb) where getLocal lab = error $ "getLocal for ScopedLabel: "++show lab makeLabel locnam = error $ "makeLabel for ScopedLabel: "++locnam labelIsVar (ScopedLabel _ lab) = labelIsVar lab labelHash seed (ScopedLabel scope lab) | labelIsVar lab = seed `hashWithSalt` scope | otherwise = labelHash seed lab instance (Label lb) => Eq (ScopedLabel lb) where (ScopedLabel s1 l1) == (ScopedLabel s2 l2) = l1 == l2 && s1 == s2 instance (Label lb) => Show (ScopedLabel lb) where show (ScopedLabel s1 l1) = show s1 ++ ":" ++ show l1 instance (Label lb) => Ord (ScopedLabel lb) where compare (ScopedLabel s1 l1) (ScopedLabel s2 l2) = case compare s1 s2 of LT -> LT EQ -> compare l1 l2 GT -> GT -- QUS: why doesn't this return Maybe (LabelMap (ScopedLabel lb)) ? -- TODO: Should this use Set (Arc lb) instead of [Arc lb]? -- | Graph matching function accepting two lists of arcs and -- returning a node map if successful -- graphMatch :: (Label lb) => (lb -> lb -> Bool) -- ^ a function that tests for additional constraints -- that may prevent the matching of a supplied pair -- of nodes. Returns `True` if the supplied nodes may be -- matched. (Used in RDF graph matching for checking -- that formula assignments are compatible.) -> ArcSet lb -- ^ the first graph to be compared -> ArcSet lb -- ^ the second graph to be compared -> (Bool, LabelMap (ScopedLabel lb)) -- ^ If the first element is `True` then the second element maps each label -- to an equivalence class identifier, otherwise it is just -- `emptyMap`. -- graphMatch matchable gs1 gs2 = let sgs1 = {- trace "sgs1 " $ -} S.map (makeScopedArc 1) gs1 sgs2 = {- trace "sgs2 " $ -} S.map (makeScopedArc 2) gs2 ls1 = {- traceShow "ls1 " $ -} graphLabels sgs1 ls2 = {- traceShow "ls2 " $ -} graphLabels sgs2 lmap = {- traceShow "lmap " $ -} newGenerationMap $ assignLabelMap ls1 $ assignLabelMap ls2 emptyMap ec1 = {- traceShow "ec1 " $ -} equivalenceClasses lmap ls1 ec2 = {- traceShow "ec2 " $ -} equivalenceClasses lmap ls2 ecpairs = zip (pairSort ec1) (pairSort ec2) matchableScoped (ScopedLabel _ l1) (ScopedLabel _ l2) = matchable l1 l2 match = graphMatch1 False matchableScoped sgs1 sgs2 lmap ecpairs in if length ec1 /= length ec2 then (False,emptyMap) else match -- TODO: -- -- * replace Equivalence class pair by @(index,[lb],[lb])@ ? -- -- * possible optimization: the @graphMapEq@ test should be -- needed only if `graphMatch2` has been used to guess a -- mapping; either: -- a) supply flag saying guess has been used, or -- b) move test to `graphMatch2` and use different -- test to prevent rechecking for each guess used. -- -- | Recursive graph matching function -- -- This function assumes that no variable label appears in both graphs. -- (Function `graphMatch`, which calls this, ensures that all variable -- labels are distinct.) -- graphMatch1 :: (Label lb) => Bool -- ^ `True` if a guess has been used before trying this comparison, -- `False` if nodes are being matched without any guesswork -> (lb -> lb -> Bool) -- ^ Test for additional constraints that may prevent the matching -- of a supplied pair of nodes. Returns `True` if the supplied -- nodes may be matched. -> ArcSet lb -- ^ (@gs1@ argument) -- first of two lists of arcs (triples) to be compared -> ArcSet lb -- ^ (@gs2@ argument) -- secind of two lists of arcs (triples) to be compared -> LabelMap lb -- ^ the map so far used to map label values to equivalence class -- values -> [(EquivalenceClass lb,EquivalenceClass lb)] -- ^ (the @ecpairs@ argument) list of pairs of corresponding -- equivalence classes of nodes from @gs1@ and @gs2@ that have not -- been confirmed in 1:1 correspondence with each other. Each -- pair of equivalence classes contains nodes that must be placed -- in 1:1 correspondence with each other. -- -> (Bool,LabelMap lb) -- ^ the pair @(match, map)@ where @match@ is @True@ if the supplied -- sets of arcs can be matched, in which case @map@ is a -- corresponding map from labels to equivalence class identifiers. -- When @match@ is @False@, @map@ is the most detailed equivalence -- class map obtained before a mismatch was detected or a guess -- was required -- this is intended to help identify where the -- graph mismatch may be. graphMatch1 guessed matchable gs1 gs2 lmap ecpairs = let (secs,mecs) = partition uniqueEc ecpairs uniqueEc ( (_,[_]) , (_,[_]) ) = True uniqueEc ( _ , _ ) = False doMatch ( (_,[l1]) , (_,[l2]) ) = labelMatch matchable lmap l1 l2 doMatch x = error $ "doMatch failue: " ++ show x -- keep -Wall happy ecEqSize ( (_,ls1) , (_,ls2) ) = length ls1 == length ls2 eSize ( (_,ls1) , _ ) = length ls1 ecCompareSize = comparing eSize (lmap',mecs',newEc,matchEc) = reclassify gs1 gs2 lmap mecs match2 = graphMatch2 matchable gs1 gs2 lmap $ sortBy ecCompareSize mecs in -- trace ("graphMatch1\nsingle ECs:\n"++show secs++ -- "\nmultiple ECs:\n"++show mecs++ -- "\n\n") $ -- if mismatch in singleton equivalence classes, fail if not $ all doMatch secs then (False,lmap) else -- if no multi-member equivalence classes, -- check and return label map supplied -- trace ("graphMatch1\ngraphMapEq: "++show (graphMapEq lmap gs1 gs2)) $ if null mecs then (graphMapEq lmap gs1 gs2,lmap) else -- if size mismatch in equivalence classes, fail -- trace ("graphMatch1\nall ecEqSize mecs: "++show (all ecEqSize mecs)) $ -- invoke reclassification, and deal with result if not (all ecEqSize mecs) || not matchEc then (False, lmap) else if newEc then graphMatch1 guessed matchable gs1 gs2 lmap' mecs' -- if guess does not result in a match, return supplied label map else if fst match2 then match2 else (False, lmap) {- if not $ all ecEqSize mecs then (False,lmap) else if not matchEc then (False,lmap) else if newEc then graphMatch1 guessed matchable gs1 gs2 lmap' mecs' else if fst match2 then match2 else (False,lmap) -} -- | Auxiliary graph matching function -- -- This function is called when deterministic decomposition of node -- mapping equivalence classes has run its course. -- -- It picks a pair of equivalence classes in ecpairs, and arbitrarily matches -- pairs of nodes in those equivalence classes, recursively calling the -- graph matching function until a suitable node mapping is discovered -- (success), or until all such pairs have been tried (failure). -- -- This function represents a point to which arbitrary choices are backtracked. -- The list comprehension 'glp' represents the alternative choices at the -- point of backtracking -- -- The selected pair of nodes are placed in a new equivalence class based on their -- original equivalence class value, but with a new NodeVal generation number. graphMatch2 :: (Label lb) => (lb -> lb -> Bool) -> ArcSet lb -> ArcSet lb -> LabelMap lb -> [(EquivalenceClass lb,EquivalenceClass lb)] -> (Bool,LabelMap lb) graphMatch2 _ _ _ _ [] = error "graphMatch2 sent an empty list" -- To keep -Wall happy graphMatch2 matchable gs1 gs2 lmap ((ec1@(ev1,ls1),ec2@(ev2,ls2)):ecpairs) = let v1 = snd ev1 -- Return any equivalence-mapping obtained by matching a pair -- of labels in the supplied list, or Nothing. try [] = (False,lmap) try ((l1,l2):lps) = if isEquiv try1 l1 l2 then try1 else try lps where try1 = graphMatch1 True matchable gs1 gs2 lmap' ecpairs' lmap' = newLabelMap lmap [(l1,v1),(l2,v1)] ecpairs' = ((ev',[l1]),(ev',[l2])):ec':ecpairs ev' = mapLabelIndex lmap' l1 ec' = (ecRemoveLabel ec1 l1, ecRemoveLabel ec2 l2) -- [[[TODO: replace this: if isJust try ?]]] isEquiv (False,_) _ _ = False isEquiv (True,lm) x1 x2 = mapLabelIndex m1 x1 == mapLabelIndex m2 x2 where m1 = remapLabels gs1 lm [x1] m2 = remapLabels gs2 lm [x2] -- glp is a list of label-pair candidates for matching, -- selected from the first label-equivalence class. -- NOTE: final test is call of external matchable function glp = [ (l1,l2) | l1 <- ls1 , l2 <- ls2 , matchable l1 l2 ] in assert (ev1==ev2) -- "GraphMatch2: Equivalence class value mismatch" $ $ try glp -- this was in Swish.Utils.MiscHelpers along with a simple hash-based function -- based on Sedgewick, Algorithms in C, p233. As we have now moved to using -- Data.Hashable it is not clear whether this is still necessary or sensible. -- hashModulus :: Int hashModulus = 16000001 -- | Returns a string representation of a LabelMap value -- showLabelMap :: (Label lb) => LabelMap lb -> String showLabelMap (LabelMap gn lmap) = "LabelMap gen="++ Prelude.show gn ++", map="++ foldl' (++) "" (map (("\n "++) . Prelude.show) es) where es = M.toList lmap -- | Map a label to its corresponding label index value in the -- supplied LabelMap. -- mapLabelIndex :: (Label lb) => LabelMap lb -> lb -> LabelIndex mapLabelIndex (LabelMap _ lxms) lb = M.findWithDefault nullLabelVal lb lxms -- | Confirm that a given pair of labels are matchable, and are -- mapped to the same value by the supplied label map -- labelMatch :: (Label lb) => (lb -> lb -> Bool) -> LabelMap lb -> lb -> lb -> Bool labelMatch matchable lmap l1 l2 = matchable l1 l2 && (mapLabelIndex lmap l1 == mapLabelIndex lmap l2) -- | Replace selected values in a label map with new values from the supplied -- list of labels and new label index values. The generation number is -- supplied from the current label map. The generation number in the -- resulting label map is incremented. -- newLabelMap :: (Label lb) => LabelMap lb -> [(lb, Word32)] -> LabelMap lb newLabelMap lmap [] = newGenerationMap lmap newLabelMap lmap (lv:lvs) = setLabelHash (newLabelMap lmap lvs) lv -- | Replace a label and its associated value in a label map -- with a new value using the supplied hash value and the current -- `LabelMap` generation number. If the key is not found, then no change -- is made to the label map. setLabelHash :: (Label lb) => LabelMap lb -> (lb, Word32) -> LabelMap lb setLabelHash (LabelMap g lmap) (lb,lh) = LabelMap g $ M.insert lb (g,lh) lmap -- | Increment the generation of the label map. -- -- Returns a new label map identical to the supplied value -- but with an incremented generation number. -- newGenerationMap :: (Label lb) => LabelMap lb -> LabelMap lb newGenerationMap (LabelMap g lvs) = LabelMap (g+1) lvs -- | Scan label list, assigning initial label map values, -- adding new values to the label map supplied. -- -- Label map values are assigned on the basis of the -- label alone, without regard for it's connectivity in -- the graph. (cf. `reclassify`). -- -- All variable node labels are assigned the same initial -- value, as they may be matched with each other. -- assignLabelMap :: (Label lb) => S.Set lb -> LabelMap lb -> LabelMap lb assignLabelMap ns lmap = S.foldl' (flip assignLabelMap1) lmap ns assignLabelMap1 :: (Label lb) => lb -> LabelMap lb -> LabelMap lb assignLabelMap1 lab (LabelMap g lvs) = LabelMap g $ M.insertWith (flip const) lab (g, initVal lab) lvs -- Calculate initial value for a node initVal :: (Label lb) => lb -> Word32 initVal = fromIntegral . hashVal 0 hashVal :: (Label lb) => Word32 -> lb -> Int hashVal seed lab = if labelIsVar lab then 23 `hashWithSalt` seed else labelHash (fromIntegral seed) lab -- | Return the equivalence classes of the supplied nodes -- using the label map. equivalenceClasses :: (Label lb) => LabelMap lb -- ^ label map -> S.Set lb -- ^ nodes to be reclassified -> [EquivalenceClass lb] equivalenceClasses lmap ls = pairGroup $ S.toList $ S.map labelPair ls where labelPair l = (mapLabelIndex lmap l,l) -- | Reclassify labels -- -- Examines the supplied label equivalence classes (based on the supplied -- label map), and evaluates new equivalence subclasses based on node -- values and adjacency (for variable nodes) and rehashing -- (for non-variable nodes). -- -- Note, assumes that all all equivalence classes supplied are -- non-singletons; i.e. contain more than one label. -- reclassify :: (Label lb) => ArcSet lb -- ^ (the @gs1@ argument) the first of two sets of arcs to perform a -- basis for reclassifying the labels in the first equivalence -- class in each pair of @ecpairs@. -> ArcSet lb -- ^ (the @gs2@ argument) the second of two sets of arcs to perform a -- basis for reclassifying the labels in the second equivalence -- class in each pair of the @ecpairs@ argument -> LabelMap lb -- ^ the label map used for classification of the labels in -- the supplied equivalence classes -> [(EquivalenceClass lb,EquivalenceClass lb)] -- ^ (the @ecpairs@ argument) a list of pairs of corresponding equivalence classes of -- nodes from @gs1@ and @gs2@ that have not been confirmed -- in 1:1 correspondence with each other. -> (LabelMap lb,[(EquivalenceClass lb,EquivalenceClass lb)],Bool,Bool) -- ^ The output tuple consists of: -- -- 1) a revised label map reflecting the reclassification -- -- 2) a new list of equivalence class pairs based on the -- new node map -- -- 3) if the reclassification partitions any of the -- supplied equivalence classes then `True`, else `False` -- -- 4) if reclassification results in each equivalence class -- being split same-sized equivalence classes in the two graphs, -- then `True`, otherwise `False`. reclassify gs1 gs2 lmap@(LabelMap _ lm) ecpairs = assert (gen1==gen2) -- "Label map generation mismatch" (LabelMap gen1 lm',ecpairs',newPart,matchPart) where LabelMap gen1 lm1 = remapLabels gs1 lmap $ foldl1 (++) $ map (ecLabels . fst) ecpairs LabelMap gen2 lm2 = remapLabels gs2 lmap $ foldl1 (++) $ map (ecLabels . snd) ecpairs lm' = classifyCombine lm $ M.union lm1 lm2 tmap f (a,b) = (f a, f b) -- ecGroups :: [([EquivalenceClass lb],[EquivalenceClass lb])] ecGroups = map (tmap remapEc) ecpairs ecpairs' = concatMap (uncurry zip) ecGroups newPart = any pairG1 lenGroups matchPart = all pairEq lenGroups lenGroups = map (tmap length) ecGroups pairEq = uncurry (==) pairG1 (p1,p2) = p1 > 1 || p2 > 1 remapEc = pairGroup . map (newIndex lm') . pairUngroup newIndex x (_,lab) = (M.findWithDefault nullLabelVal lab x,lab) -- Replace the values in lm1 with those from lm2, but do not copy over new -- keys from lm2 classifyCombine :: (Ord a) => M.Map a b -> M.Map a b -> M.Map a b #if MIN_VERSION_containers(0,5,0) classifyCombine = M.mergeWithKey (\_ _ v -> Just v) id (const M.empty) #else -- rely on the left-biased nature of union classifyCombine lm1 lm2 = M.intersection lm2 lm1 `M.union` lm1 #endif -- | Calculate a new index value for a supplied set of labels based on the -- supplied label map and adjacency calculations in the supplied graph -- remapLabels :: (Label lb) => ArcSet lb -- ^ arcs used for adjacency calculations when remapping -> LabelMap lb -- ^ the current label index values -> [lb] -- ^ the graph labels for which new mappings are to be created -> LabelMap lb -- ^ the updated label map containing recalculated label index values -- for the given graph labels. The label map generation number is -- incremented by 1. remapLabels gs lmap@(LabelMap gen _) ls = LabelMap gen' $ M.fromList newEntries where gen' = gen+1 newEntries = [ (l, (gen', fromIntegral (newIndex l))) | l <- ls ] -- TODO: should review this given the changes to the hash code -- since it was re-written newIndex l | labelIsVar l = mapAdjacent l -- adjacency classifies variable labels | otherwise = fromIntegral $ hashVal gen l -- otherwise rehash (to disentangle collisions) -- mapAdjacent used to use `rem` hashModulus mapAdjacent l = hashModulus `hashWithSalt` sum (sigsOver l) gls = S.toList gs sigsOver l = select (hasLabel l) gls (arcSignatures lmap gls) -- |Select is like filter, except that it tests one list to select -- elements from a second list. select :: ( a -> Bool ) -> [a] -> [b] -> [b] select _ [] [] = [] select f (e1:l1) (e2:l2) | f e1 = e2 : select f l1 l2 | otherwise = select f l1 l2 select _ _ _ = error "select supplied with different length lists" -- | Return the set of distinct labels used in the graph. graphLabels :: (Label lb) => ArcSet lb -> S.Set lb graphLabels = getComponents arcLabels -- TODO: worry about overflow? -- TODO: should probably return a Set of (Int, Arc lb) or something, -- as may be useful for the calling code -- | Calculate a signature value for each arc that can be used in -- constructing an adjacency based value for a node. The adjacancy -- value for a label is obtained by summing the signatures of all -- statements containing that label. -- arcSignatures :: (Label lb) => LabelMap lb -- ^ the current label index values -> [Arc lb] -- ^ calculate signatures for these arcs -> [Int] -- ^ the signatures of the arcs arcSignatures lmap = map (sigCalc . arcToTriple) where sigCalc (s,p,o) = hashModulus `hashWithSalt` ( labelVal2 s + labelVal2 p * 3 + labelVal2 o * 5 ) labelVal = mapLabelIndex lmap labelVal2 = uncurry (*) . labelVal -- | Return a new graph that is supplied graph with every node/arc -- mapped to a new value according to the supplied function. -- -- Used for testing for graph equivalence under a supplied -- label mapping; e.g. -- -- > if ( graphMap nodeMap gs1 ) == ( graphMap nodeMap gs2 ) then (same) -- graphMap :: (Label lb) => LabelMap lb -> ArcSet lb -> ArcSet LabelIndex graphMap = S.map . fmap . mapLabelIndex -- | Compare a pair of graphs for equivalence under a given mapping -- function. -- -- This is used to perform the ultimate test that two graphs are -- indeed equivalent: guesswork in `graphMatch2` means that it is -- occasionally possible to construct a node mapping that generates -- the required singleton equivalence classes, but does not fully -- reflect the topology of the graphs. graphMapEq :: (Label lb) => LabelMap lb -> ArcSet lb -> ArcSet lb -> Bool graphMapEq lmap = (==) `on` graphMap lmap -------------------------------------------------------------------------------- -- -- Copyright (c) 2003, Graham Klyne, 2009 Vasili I Galchin, -- 2011, 2012 Douglas Burke -- All rights reserved. -- -- This file is part of Swish. -- -- Swish is free software; you can redistribute it and/or modify -- it under the terms of the GNU General Public License as published by -- the Free Software Foundation; either version 2 of the License, or -- (at your option) any later version. -- -- Swish is distributed in the hope that it will be useful, -- but WITHOUT ANY WARRANTY; without even the implied warranty of -- MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the -- GNU General Public License for more details. -- -- You should have received a copy of the GNU General Public License -- along with Swish; if not, write to: -- The Free Software Foundation, Inc., -- 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA -- --------------------------------------------------------------------------------