I would like to know if I can find so-called n-cliques in an igraph object. Those are defined as "a maximal subgraph in which the largest geodesic distance between any two nodes is no greater than n" according to Wasserman & Faust. I'm aware that cliques of n=1 can be found via cliques() and that the sizes of cliques can be defined beforehand, but is there any way to find cliques of n larger than 1?

  • In the future, please supplement your R questions with a minimal reproducible example (hover over R tag). Here's how. – lukeA Oct 17 '16 at 17:02
  • Thank you very much for the advice! I wasn't sure about the usefulness of an example in this case. Since I'm not reporting on a potential bug or any unexpected behavior but only asking for a specific feature, I don't know how a meaningful example would look like. – supersambo Oct 18 '16 at 7:52
  • You're welcome. It could be as simple as library(igraph);set.seed(1); g <- random.graph.game(100, p.or.m = 300, type = "gnm"). Based on that graph, you could illustrate what you expect magicCliqueFun to return. That way, all are talking about the same basis. In addition, it increases the chances of getting responses, because R Stackoverflow folks like to spot code instead of digging through heaps of texts. (In fact, posts without reproducible code are not very welcome afaik.) – lukeA Oct 18 '16 at 8:05
  • 1
    Ok got it. This also explains the low response rate of some of my other questions :) – supersambo Oct 18 '16 at 8:18

In theory, you could try RBGL::kCliques:

g <- random.graph.game(100, p.or.m = 300, type = "gnm")
coords <- layout.auto(g)
cl <- kCliques(igraph.to.graphNEL(g))

k <- 2
clSel <- cl[[paste0(k, '-cliques')]][[1]] # select first of all k-cliques (e.g.)

  layout = coords,
  vertex.shape = "none",
  vertex.label.color = ifelse(V(g) %in% clSel, "red", "darkgrey"), 
  edge.color = ifelse(tail_of(g, E(g)) %in% clSel & head_of(g, E(g)) %in% clSel, "orange", "#F0F0F099"),
  vertex.size = .5, 
  edge.curved = 1

However, in practice...

all(print(distances(induced_subgraph(g, clSel))) <=k ) # should be TRUE
# [1] FALSE

there seems to be something wrong if we use the definition:

In Social Network Analysis, a k-clique in a graph is a subgraph where the distance between any two nodes is no greater than k.

Or maybe I misunderstood something...


Thanks to lukeA for pointing out RBGL::kCliques as a solution within R for this problem.

n-cliques are allowed to have links through other nodes that aren't cliques. So A -- B -- C -- D, with B -- E and C -- E as well can be a 2-clique if A and D are linked through another node, F, even though F is not in the 2-clique (since it is 3 away from E). See http://faculty.ucr.edu/~hanneman/nettext/C11_Cliques.html#nclique

n-clans are not allowed to have this behavior, however; all paths must pass through members of the subgraph to count. lukeA's test therefore demonstrates that the n-cliques are not all n-clans.

You could construct a function that outputs n-clans by throwing out all subgraphs in which the paths aren't fully within the subgraph, e.g.,

nclan <- function(g,n){
  g <- as.undirected(g)
  E(g)$weight <- 1 #just in case g has weights - does not modify original graph
  ncliques <- kCliques(ugraph(igraph.to.graphNEL(g))) #get cliques
  n.cand <- ncliques[[n]] #n-clique candidates to be an n-clan
  n.clan <- list() #initializes a list to store the n-clans
  n.clan.i <- 1 #initializes a list pointer
  for (n.cand.i in 1:length(n.cand)){ #loop over all of the candidates
    g.n.cand <- induced_subgraph(g,n.cand[[n.cand.i]]) #get the subgraph
    if (diameter(g.n.cand)<=n){ #check diameter of the subgraph
      n.clan[[n.clan.i]] <- n.cand[[n.cand.i]] #add n-clan to the list
      n.clan.i <- n.clan.i+1 #increment list pointer
  return(n.clan) #return the entire list

The removal of edge weights is due to an odd bug in RBGL's kCliques implementation. Similarly, you can write a k-plex function:

kplex <- function(g,k,m){
  g.sym <- as.undirected(g) #to make sure that degree functions properly
  g.sym.degmk <- induced_subgraph(g.sym,igraph::degree(g.sym)>=(m-k)) #makes algorithm faster
  k.cand <- combn(V(g.sym.degmk)$name,m) #all candidate combinations with m members
  k.plex <- list() #initializes a list to store the k-plexes
  k.plex.i <- 1 #initializes a list pointer
  for (k.cand.i in 1:dim(k.cand)[2]){ #loop over all of the columns
    g.k.cand <- induced_subgraph(g.sym.degmk,k.cand[,k.cand.i]) #get the subgraph
    if (min(igraph::degree(g.k.cand))>=(m-k)){ #if minimum degree of sugraph is > m=k, k-plex!
      k.plex[[k.plex.i]] <- k.cand[,k.cand.i] #add k-plex to list
      k.plex.i <- k.plex.i+1 #increment list pointer
  return(k.plex) #return the entire list

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