{- | Module : Persistence.SimplicialComplex Copyright : (c) Eben Kadile, 2018 License : BSD 3 Clause Maintainer : eben.cowley42@gmail.com Stability : experimental This module provides functions for constructing neighborhood graphs, clique complexes, and Vietoris-Rips complexes, as well as the computation of Betti numbers. A simplicial complex is like a generalization of a graph, where you can have any number of n-dimensional simplices (line-segments, triangles, tetrahedrons), glued along their boundaries so that the intersection of any two simplices is a simplicial complex. These objects are fundamental to topological data analysis. An important thing to note about this module, and the library in general, is the difference between "fast" and "light" functions. Fast functions encode the metric in a 2D vector, so that distances don't need to be computed over and over again and can instead be accessed in constant time. Unfortunately, this takes O(n^2) memory so I would strongly recomend against using it for larger data sets unless you have a lot of RAM. "Light" functions do not use this speed optimization. The neighborhood graph of point cloud data is a graph where an edge exists between two data points if and only if the vertices fall within a given distance of each other. Graphs here are more of a helper data type for constructing filtrations, which is why they have a somewhat odd representation. Not to worry, though, I've supplied a way of encoding graphs of a more generic representation. The clique complex of a graph is a simplicial complex whose simplices are the complete subgraphs of the given graph. The Vietoris-Rips complex is the clique complex of the neighborhood graph. Betti numbers measure the number of n-dimensional holes in a given simplicial complex. The 0th Betti number is the number of connected components, or clusters; the 1st Betti number is the number of loops or tunnels; the 2nd Betti number measures voids or hollow volumes; and if you have high-dimensional data, you might have higher Betti numbers representing the number of high-dimensional holes. -} module Persistence.SimplicialComplex ( -- * Types Simplex , SimplicialComplex , Graph -- * Utilities , sc2String , getDim , encodeWeightedGraph , wGraph2sc , indexGraph -- * Construction , makeNbrhdGraph , makeNbrhdGraphPar , makeCliqueComplex , makeCliqueComplexPar , makeRipsComplexFast , makeRipsComplexFastPar , makeRipsComplexLight , makeRipsComplexLightPar -- * Homology , bettiNumbers , bettiNumbersPar --, simplicialHomology --, simplicialHomologyPar ) where import Persistence.Util import Persistence.Matrix import Data.List as L import Data.Vector as V import Data.IntSet as S import Control.Parallel.Strategies import Data.Algorithm.MaximalCliques -- * Types {- | This is type synonym exists to make other synonyms more concise. A simplex is represented as a pair: the vector of its vertices (their index in the original data set), and the vector of the indices of the faces in the next lowest dimension of the simplicial complex. 1-simplices are the exception: they do not store reference to their faces because it would be redundant with their vertices. -} type Simplex = (Vector Int, Vector Int) {- | The first component of the pair is the number of vertices. The second component is a vector whose entries are vectors of simplices of the same dimension. Index 0 of the vecor corresponds to dimension 1 because there is no need to store individual vertices. -} type SimplicialComplex = (Int, Vector (Vector Simplex)) {- | This represents the (symmetric) adjacency matrix of some weighted, undirected graph. The type a is whatever distance is in your data analysis procedure. The reason graphs are represented like this is because their main purpose is too speed up the construction of simplicial complexes and filtrations. If the clique complex of this graph were to be constructed, only the adjacencies would matter. But if a filtration is constructed all the distances will be required over and over again - this allows them to be accessed in constant time. -} type Graph a = Vector (Vector (a, Bool)) -- * Utilities -- | Show all the information in a simplicial complex. sc2String :: SimplicialComplex -> String sc2String (v, allSimplices) = if V.null allSimplices then (show v) L.++ " vertices" else let edges = V.head allSimplices simplices = V.tail allSimplices showSimplex s = '\n':(intercalate "\n" $ V.toList $ V.map show s) showAll sc = if V.null sc then '\n':(show v) L.++ " vertices" else showSimplex (V.head sc) L.++ ('\n':(showAll (V.tail sc))) in (intercalate "\n" $ V.toList $ V.map (show . fst) edges) L.++ ('\n':(showAll simplices)) -- | Get the dimension of the highest dimensional simplex (constant time). getDim :: SimplicialComplex -> Int getDim = L.length . snd -- | Safely index into the adjacency matrix of a graph. indexGraph :: Graph a -> (Int, Int) -> (a, Bool) indexGraph graph (i, j) = if i < j then graph ! j ! i else graph ! i ! j {- | Takes the number of vertices and each edge paired with its weight to output the graph encoded as a 2D vector. If only you have an unweighted graph, you can still encode your graph by simply letting the type a be (). If you have a weighted graph but there isn't a distance between every vertex, you can use the Extended type (essentially the same as Maybe) from the Filtration module which is already an instance of Ord. -} encodeWeightedGraph :: Int -> (Int -> Int -> (a, Bool)) -> Graph a encodeWeightedGraph numVerts edge = mapWithIndex (\i r -> mapWithIndex (\j _ -> edge i j) $ V.replicate (i + 1) ()) $ V.replicate numVerts () -- | Given a weighted graph, construct a 1-dimensional simplicial complex in the canonical way. Betti numbers of this simplicial complex can be used to count cycles and connected components. wGraph2sc :: Graph a -> SimplicialComplex wGraph2sc graph = let numVerts = V.length graph getEdges index result = if index == numVerts then result else let new = V.map (\(i, b) -> (V.fromList [index, i], V.empty)) $ V.filter snd $ mapWithIndex (\i (_, b) -> (i, b)) $ graph ! index in getEdges (index + 1) result in (numVerts, (getEdges 0 V.empty) `cons` V.empty) {- | The first argument is a scale, the second is a metric, and the third is the data. This function records the distance between every element of the data and whether or not it is smaller than the given scale. -} makeNbrhdGraph :: (Ord a, Eq b) => a -> (b -> b -> a) -> Either (Vector b) [b] -> Graph a makeNbrhdGraph scale metric dataSet = let vector = case dataSet of Left v -> v; Right l -> V.fromList l in mapWithIndex (\i x -> V.map (\y -> let d = metric x y in (d, d <= scale)) $ V.take (i + 1) vector) vector -- | Parallel version of the above. makeNbrhdGraphPar :: (Ord a, Eq b) => a -> (b -> b -> a) -> Either (Vector b) [b] -> Graph a makeNbrhdGraphPar scale metric dataSet = let vector = case dataSet of Left v -> v; Right l -> V.fromList l in parMapWithIndex (\i x -> V.map (\y -> let d = metric x y in (d, d <= scale)) $ V.take (i + 1) vector) vector -- * Construction {- | Makes a simplicial complex where the simplices are the complete subgraphs (cliques) of the given graph. Mainly a helper function for makeRipsComplexFast, but it might be useful if you happen to have a graph you want to analyze. I highly recomend using the parallel version, as this process is very expensive. -} makeCliqueComplex :: Graph a -> SimplicialComplex makeCliqueComplex graph = let numVerts = V.length graph --make a list with an entry for every dimension of simplices organizeCliques 1 _ = [] organizeCliques i cliques = --find the simplices with the given number of vertices let helper = V.partition (\simplex -> i == V.length simplex) cliques --append them to the next iteration of the function in (fst helper):(organizeCliques (i - 1) $ snd helper) --pair the organized maximal cliques with the dimension of the largest clique makePair simplices = case simplices of (x:_) -> let dim = V.length x in (dim, organizeCliques dim $ V.fromList simplices) --if there are no maximal cliques this acts as a flag --so that the algorithm doesn't try to generate all the other simplices [] -> (1, []) --find all maximal cliques and sort them from largest to smallest --excludes maximal cliques which are single points maxCliques :: (Int, Vector (Vector (Vector Int))) maxCliques = (\(x, y) -> (x, V.fromList y)) $ makePair $ sortVecs $ L.map V.fromList $ L.filter (\c -> L.length c > 1) $ getMaximalCliques (\i j -> snd $ graph `indexGraph` (i, j)) [0..numVerts - 1] --generates faces of simplices and records the boundary indices combos :: Int -> Int -> Vector (Vector (Vector Int)) -> Vector (Vector (Vector Int, Vector Int)) -> Vector (Vector (Vector Int, Vector Int)) combos i max sc result = if i == max then --don't record boundary indices for edges (V.map (\s -> (s, V.empty)) $ V.last sc) `cons` result else let i1 = i + 1 --sc is in reverse order, so sc !! i1 is the array of simplices one dimension lower current = sc ! i next = sc ! i1 len = V.length next allCombos = V.map getCombos current --get all the faces of every simplex uCombos = bigU allCombos --union of faces --the index of the faces of each simplex can be found by --adding the number of (n-1)-simplices to the index of each face in the union of faces indices = V.map (V.map (\face -> len + (elemIndexUnsafe face uCombos))) allCombos in combos i1 max (replaceElem i1 (next V.++ uCombos) sc) $ (V.zip current indices) `cons` result fstmc2 = fst maxCliques - 2 in --if there are no maximal cliques, the complex is just a bunch of points if fstmc2 == (-1) then (numVerts, V.empty) else let sc = combos 0 fstmc2 (snd maxCliques) V.empty in (numVerts, sc) -- | Parallel version of the above. makeCliqueComplexPar :: Graph a -> SimplicialComplex makeCliqueComplexPar graph = let numVerts = V.length graph --make a list with an entry for every dimension of simplices organizeCliques 1 _ = [] organizeCliques i cliques = --find the simplices with the given number of vertices let helper = V.partition (\simplex -> i == V.length simplex) cliques --append them to the next iteration of the function in (fst helper):(organizeCliques (i - 1) $ snd helper) --pair the organized maximal cliques with the dimension of the largest clique makePair simplices = case simplices of (x:_) -> let dim = V.length x in (dim, organizeCliques dim $ V.fromList simplices) --if there are no maximal cliques this acts as a flag --so that the algorithm doesn't try to generate all the other simplices [] -> (1, []) --find all maximal cliques and sort them from largest to smallest --excludes maximal cliques which are single points maxCliques :: (Int, Vector (Vector (Vector Int))) maxCliques = (\(x, y) -> (x, V.fromList y)) $ makePair $ sortVecs $ L.map V.fromList $ L.filter (\c -> L.length c > 1) $ getMaximalCliques (\i j -> snd $ graph `indexGraph` (i, j)) [0..numVerts - 1] --generates faces of simplices and records the boundary indices combos :: Int -> Int -> Vector (Vector (Vector Int)) -> Vector (Vector (Vector Int, Vector Int)) -> Vector (Vector (Vector Int, Vector Int)) combos i max sc result = if i == max then --don't record boundary indices for edges (V.map (\s -> (s, V.empty)) $ V.last sc) `cons` result else let i1 = i + 1 --sc is in reverse order, so sc !! i1 is the array of simplices one dimension lower current = sc ! i next = sc ! i1 len = V.length next allCombos = V.map getCombos current --get all the faces of every simplex uCombos = bigU allCombos --union of faces --the index of the faces of each simplex can be found by adding --the number of (n-1)-simplices to the index of each face in the union of faces indices = parMapVec (V.map (\face -> len + (elemIndexUnsafe face uCombos))) allCombos in combos i1 max (replaceElem i1 (next V.++ uCombos) sc) $ (V.zip current indices) `cons` result fstmc2 = fst maxCliques - 2 in --if there are no maximal cliques, the complex is just a bunch of points if fstmc2 == (-1) then (numVerts, V.empty) else let sc = combos 0 fstmc2 (snd maxCliques) V.empty in (numVerts, sc) {- | Constructs the Vietoris-Rips complex given a scale, metric, and data set. Also uses O(n^2) memory (where n is the number of data points) for a graph storing all the distances between data points. -} makeRipsComplexFast :: (Ord a, Eq b) => a -> (b -> b -> a) -> Either (Vector b) [b] -> (SimplicialComplex, Graph a) makeRipsComplexFast scale metric dataSet = let graph = makeNbrhdGraph scale metric dataSet sc = makeCliqueComplex graph in (sc, graph) -- | Parallel version of the above. makeRipsComplexFastPar :: (Ord a, Eq b) => a -> (b -> b -> a) -> Either (Vector b) [b] -> (SimplicialComplex, Graph a) makeRipsComplexFastPar scale metric dataSet = let graph = makeNbrhdGraphPar scale metric dataSet sc = makeCliqueComplexPar graph in (sc, graph) -- | Constructs the Vietoris-Rips complex given a scale, metric, and data set. makeRipsComplexLight :: (Ord a, Eq b) => a -> (b -> b -> a) -> Either (Vector b) [b] -> SimplicialComplex makeRipsComplexLight scale metric dataSet = let vector = case dataSet of Left v -> v; Right l -> V.fromList l numVerts = L.length vector --make a list with an entry for every dimension of simplices organizeCliques 1 _ = [] organizeCliques i cliques = --find the simplices with the given number of vertices let helper = V.partition (\simplex -> i == V.length simplex) cliques --append them to the next iteration of the function in (fst helper):(organizeCliques (i - 1) $ snd helper) --pair the organized maximal cliques with the dimension of the largest clique makePair simplices = case simplices of (x:_) -> let dim = V.length x in (dim, organizeCliques dim $ V.fromList simplices) --if there are no maximal cliques this acts as a flag --so that the algorithm doesn't try to generate all the other simplices [] -> (1, []) --find all maximal cliques and sort them from largest to smallest --excludes maximal cliques which are single points maxCliques :: (Int, Vector (Vector (Vector Int))) maxCliques = (\(x, y) -> (x, V.fromList y)) $ makePair $ sortVecs $ L.map V.fromList $ L.filter (\c -> L.length c > 1) $ getMaximalCliques (\i j -> metric (vector ! i) (vector ! j) <= scale) [0..numVerts-1] --generates faces of simplices and records the boundary indices combos :: Int -> Int -> Vector (Vector (Vector Int)) -> Vector (Vector (Vector Int, Vector Int)) -> Vector (Vector (Vector Int, Vector Int)) combos i max sc result = if i == max then --don't record boundary indices for edges (V.map (\s -> (s, V.empty)) $ V.last sc) `cons` result else let i1 = i + 1 --sc is in reverse order, so sc !! i1 is the array of simplices one dimension lower current = sc ! i next = sc ! i1 len = V.length next allCombos = V.map getCombos current --get all the faces of every simplex uCombos = bigU allCombos --union of faces --the index of the faces of each simplex can be found by --adding the number of (n-1)-simplices to the index of each face in the union of faces indices = V.map (V.map (\face -> len + (elemIndexUnsafe face uCombos))) allCombos in combos i1 max (replaceElem i1 (next V.++ uCombos) sc) $ (V.zip current indices) `cons` result fstmc2 = fst maxCliques - 2 in --if there are no maximal cliques, the complex is just a bunch of points if fstmc2 == (-1) then (numVerts, V.empty) else let sc = combos 0 fstmc2 (snd maxCliques) V.empty in (numVerts, sc) -- | Parallel version of the above. makeRipsComplexLightPar :: (Ord a, Eq b) => a -> (b -> b -> a) -> Either (Vector b) [b] -> SimplicialComplex makeRipsComplexLightPar scale metric dataSet = let numVerts = L.length dataSet vector = case dataSet of Left v -> v; Right l -> V.fromList l --make a list with an entry for every dimension of simplices organizeCliques 1 _ = [] organizeCliques i cliques = --find the simplices with the given number of vertices let helper = V.partition (\simplex -> i == V.length simplex) cliques --append them to the next iteration of the function in (fst helper):(organizeCliques (i - 1) $ snd helper) --pair the organized maximal cliques with the dimension of the largest clique makePair simplices = case simplices of (x:_) -> let dim = V.length x in (dim, organizeCliques dim $ V.fromList simplices) --if there are no maximal cliques this acts as a flag --so that the algorithm doesn't try to generate all the other simplices [] -> (1, []) --find all maximal cliques and sort them from largest to smallest --excludes maximal cliques which are single points maxCliques :: (Int, Vector (Vector (Vector Int))) maxCliques = (\(x, y) -> (x, V.fromList y)) $ makePair $ sortVecs $ L.map V.fromList $ L.filter (\c -> L.length c > 1) $ getMaximalCliques (\i j -> metric (vector ! i) (vector ! j) <= scale) [0..numVerts-1] --generates faces of simplices and records the boundary indices combos :: Int -> Int -> Vector (Vector (Vector Int)) -> Vector (Vector (Vector Int, Vector Int)) -> Vector (Vector (Vector Int, Vector Int)) combos i max sc result = if i == max then --don't record boundary indices for edges (V.map (\s -> (s, V.empty)) $ V.last sc) `cons` result else let i1 = i + 1 --sc is in reverse order, so sc !! i1 is the array of simplices one dimension lower current = sc ! i next = sc ! i1 len = V.length next allCombos = V.map getCombos current --get all the faces of every simplex uCombos = bigU allCombos --union of faces --the index of the faces of each simplex can be found by --adding the number of (n-1)-simplices to the index of each face in the union of faces indices = parMapVec (V.map (\face -> len + (elemIndexUnsafe face uCombos))) allCombos in combos i1 max (replaceElem i1 (next V.++ uCombos) sc) $ (V.zip current indices) `cons` result fstmc2 = fst maxCliques - 2 in --if there are no maximal cliques, the complex is just a bunch of points if fstmc2 == (-1) then (numVerts, V.empty) else let sc = combos 0 fstmc2 (snd maxCliques) V.empty in (numVerts, sc) -- * Homology --gets the first boundary operator (because edges don't need to point to their subsimplices) makeEdgeBoundariesBool :: SimplicialComplex -> BMatrix makeEdgeBoundariesBool sc = let mat = V.map (\edge -> V.map (\vert -> vert == V.head edge || vert == V.last edge) $ 0 `range` (fst sc - 1)) $ V.map fst $ V.head $ snd sc in case transposeMat mat of Just m -> m Nothing -> error "error in makeEdgeBoundariesBool" --gets the boundary coefficients for a simplex of dimension 2 or greater --first argument is dimension of the simplex --second argument is the simplicial complex --third argument is the simplex paired with the indices of its faces makeSimplexBoundaryBool :: Int -> SimplicialComplex -> (Vector Int, Vector Int) -> Vector Bool makeSimplexBoundaryBool dim simplices (simplex, indices) = mapWithIndex (\i s -> V.elem i indices) (V.map fst $ (snd simplices) ! (dim - 2)) --makes boundary operator for all simplices of dimension 2 or greater --first argument is the dimension of the boundary operator, second is the simplicial complex makeBoundaryOperatorBool :: Int -> SimplicialComplex -> BMatrix makeBoundaryOperatorBool dim sc = let mat = V.map (makeSimplexBoundaryBool dim sc) $ (snd sc) ! (dim - 1) in case transposeMat mat of Just m -> m Nothing -> error "error in makeBoundaryOperatorBool" --makes all the boundary operators makeBoundaryOperatorsBool :: SimplicialComplex -> Vector BMatrix makeBoundaryOperatorsBool sc = let dim = getDim sc calc i | i > dim = V.empty | i == 1 = (makeEdgeBoundariesBool sc) `cons` (calc 2) | otherwise = (makeBoundaryOperatorBool i sc) `cons` (calc (i + 1)) in calc 1 {- | The nth index of the output corresponds to the nth Betti number. The zeroth Betti number is the number of connected components, the 1st is the number of tunnels/ punctures, the 2nd is the number of hollow volumes, and so on for higher-dimensional holes. -} bettiNumbers :: SimplicialComplex -> [Int] bettiNumbers sc = let dim = (getDim sc) + 1 boundOps = makeBoundaryOperatorsBool sc --dimension of image paired with dimension of kernel ranks = (0, V.length $ V.head boundOps) `cons` (V.map (\op -> let rank = rankBool op in (rank, (V.length $ V.head op) - rank)) boundOps) calc 1 = [(snd $ ranks ! 0) - (fst $ ranks ! 1)] calc i = let i1 = i - 1 in if i == dim then (snd $ V.last ranks):(calc i1) else ((snd $ ranks ! i1) - (fst $ ranks ! i)):(calc i1) in if L.null $ snd sc then [fst sc] else L.reverse $ calc dim -- | Calculates all of the Betti numbers in parallel. bettiNumbersPar :: SimplicialComplex -> [Int] bettiNumbersPar sc = let dim = (getDim sc) + 1 boundOps = makeBoundaryOperatorsBool sc --dimension of image paired with dimension of kernel ranks = (0, V.length $ V.head boundOps) `cons` (parMapVec (\op -> let rank = rankBool op in (rank, (V.length $ V.head op) - rank)) boundOps) calc 1 = [(snd $ ranks ! 0) - (fst $ ranks ! 1)] calc i = let i1 = i - 1 in if i == dim then evalPar (snd $ V.last ranks) (calc i1) --see Util for evalPar else evalPar ((snd $ ranks ! i1) - (fst $ ranks ! i)) (calc i1) in if L.null $ snd sc then [fst sc] else L.reverse $ calc dim --gets the first boundary operator --because edges don't need to point to their faces makeEdgeBoundariesInt :: SimplicialComplex -> IMatrix makeEdgeBoundariesInt sc = let mat = V.map (\e -> let edge = fst e in replaceElem (V.head edge) (-1) $ replaceElem (V.last edge) 1 $ V.replicate (fst sc) 0) $ V.head $ snd sc in case transposeMat mat of Just m -> m Nothing -> error "error in makeEdgeBoundariesInt" --gets the boundary coefficients for a simplex of dimension 2 or greater --first argument is the simplices of one dimension lower --second argument is the simplex paired with the indices of its faces makeSimplexBoundaryInt :: Vector (Vector Int, Vector Int) -> (Vector Int, Vector Int) -> Vector Int makeSimplexBoundaryInt simplices (_, indices) = let calc1 ixs result = if V.null ixs then result else calc2 (V.tail ixs) $ replaceElem (V.head ixs) (-1) result calc2 ixs result = if V.null ixs then result else calc1 (V.tail ixs) $ replaceElem (V.head ixs) 1 result in calc1 indices $ V.replicate (V.length simplices) 0 --makes boundary operator for all simplices of dimension 2 or greater --first argument is the dimension of the boundary operator, second is the simplicial complex makeBoundaryOperatorInt :: Int -> SimplicialComplex -> IMatrix makeBoundaryOperatorInt dim sc = let mat = V.map (makeSimplexBoundaryInt ((snd sc) ! (dim - 2))) $ (snd sc) ! (dim - 1) in case transposeMat mat of Just m -> m Nothing -> error $ show mat --makes all the boundary operators makeBoundaryOperatorsInt :: SimplicialComplex -> Vector IMatrix makeBoundaryOperatorsInt sc = let dim = getDim sc calc 1 = (makeEdgeBoundariesInt sc) `cons` (calc 2) calc i = if i > dim then V.empty else (makeBoundaryOperatorInt i sc) `cons` (calc $ i + 1) in calc 1 {- | Calculates all homology groups of the complex. An int list represents a single homology group. Specifically, an int list represents a direct product of cyclic groups - a 0 entry corresponds to the infinite cylic group (also known as the integers), and an entry of n corresponds to a cyclic group of order n (also known as the integers modulo n). The nth index of the output represents the nth homology group. If you don't have a rigorous understanding of what homology is, I recomend using BettiNumbers on large data-sets instead, as the output of those functions is more easily interprettable. -} simplicialHomology :: SimplicialComplex -> [[Int]] simplicialHomology sc = let dim = getDim sc boundOps = makeBoundaryOperatorsInt sc calc 0 = [getUnsignedDiagonal $ normalFormInt (boundOps ! 0)] calc i = if i == dim then let op = V.last boundOps in (L.replicate ((V.length $ V.head op) - (rankInt op)) 0):(calc $ i - 1) else let i1 = i - 1 in (getUnsignedDiagonal $ normalFormInt $ imgInKerInt (boundOps ! i1) (boundOps ! i)):(calc i1) in if L.null $ snd sc then [L.replicate (fst sc) 0] else L.reverse $ L.map (L.filter (/=1)) $ calc dim -- | Same as simplicialHomology except it computes each of the groups in parallel and uses parallel matrix computations. simplicialHomologyPar :: SimplicialComplex -> [[Int]] simplicialHomologyPar sc = let dim = getDim sc boundOps = makeBoundaryOperatorsInt sc calc 0 = [getUnsignedDiagonal $ normalFormInt (boundOps ! 0)] calc i = if i == dim then let op = V.last boundOps in evalPar (L.replicate ((V.length $ V.head op) - (rankInt op)) 0) $ calc $ i - 1 else let i1 = i - 1 in evalPar (getUnsignedDiagonal $ normalFormIntPar $ --see Util for evalPar imgInKerIntPar (boundOps ! i1) (boundOps ! i)) $ calc i1 in if L.null $ snd sc then [L.replicate (fst sc) 0] else L.reverse $ L.map (L.filter (/=1)) $ calc dim