annotate toolboxes/FullBNT-1.0.7/graph/Old/dfs.m @ 0:e9a9cd732c1e tip

first hg version after svn
author wolffd
date Tue, 10 Feb 2015 15:05:51 +0000
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children
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wolffd@0 1 function [d, pre, post, height, cycle, pred] = dfs(adj_mat, start, directed)
wolffd@0 2 % DFS Perform a depth-first search of the graph starting from 'start'.
wolffd@0 3 % [d, pre, post, height, cycle, pred] = dfs(adj_mat, start, directed)
wolffd@0 4 %
wolffd@0 5 % d(i) is the time at which node i is first discovered.
wolffd@0 6 % pre is a listing of the nodes in the order in which they are first encountered (opened).
wolffd@0 7 % post is a listing of the nodes in the order in which they are last encountered (closed).
wolffd@0 8 % A node is last encountered once we have explored all of its neighbors.
wolffd@0 9 % If the graph is directed, i's neighbors are its children.
wolffd@0 10 % If the graph is a tree, preorder is parents before children, and
wolffd@0 11 % postorder is children before parents.
wolffd@0 12 % For a DAG, topological order = reverse(postorder).
wolffd@0 13 % height(i) is the height (distance) of node i from the start.
wolffd@0 14 % 'cycle' is true iff a (directed) cycle is found.
wolffd@0 15 % pred(i) is the parent of i in the dfs tree rooted at start.
wolffd@0 16 % See Cormen, Leiserson and Rivest, "An intro. to algorithms" 1994, p478.
wolffd@0 17
wolffd@0 18 % We can detect undirected cycles by checking if we are about to visit a node n which we have
wolffd@0 19 % already visited. To detect *directed* cycles, we need to know if n has been closed or is still open.
wolffd@0 20 % For example (where arcs are directed down)
wolffd@0 21 % 1 2
wolffd@0 22 % \ /
wolffd@0 23 % 3
wolffd@0 24 % Assume we visit 1, 3 and then 2 in order. The fact that a child of 2 (namely, 3) has
wolffd@0 25 % already been visited is okay, because 3 has been closed.
wolffd@0 26 % The algorithms in Aho, Hopcroft and Ullman, and Sedgewick, do not detect directed cycles.
wolffd@0 27
wolffd@0 28 n = length(adj_mat);
wolffd@0 29
wolffd@0 30 global white gray black
wolffd@0 31 white = 0; gray = 1; black = 2;
wolffd@0 32
wolffd@0 33 color = white*ones(1,n);
wolffd@0 34 d = zeros(1,n);
wolffd@0 35 height = zeros(1,n);
wolffd@0 36 pred = zeros(1,n);
wolffd@0 37 pre = [];
wolffd@0 38 post = [];
wolffd@0 39 cycle = 0;
wolffd@0 40 global count
wolffd@0 41 count = 0;
wolffd@0 42 h = 0;
wolffd@0 43 [d, pre, post, height, cycle, color, pred] = ...
wolffd@0 44 dfs2(adj_mat, start, directed, h, d, pre, post, height, cycle, color, pred);
wolffd@0 45
wolffd@0 46
wolffd@0 47
wolffd@0 48 %%%%%%%%%%
wolffd@0 49
wolffd@0 50 function [d, pre, post, height, cycle, color, pred] = ...
wolffd@0 51 dfs2(adj_mat, i, directed, h, d, pre, post, height, cycle, color, pred)
wolffd@0 52
wolffd@0 53 global count
wolffd@0 54 global white gray black
wolffd@0 55
wolffd@0 56 color(i) = gray;
wolffd@0 57 count = count + 1;
wolffd@0 58 d(i) = count;
wolffd@0 59 pre = [pre i];
wolffd@0 60 height(i) = h;
wolffd@0 61 if directed
wolffd@0 62 ns = children(adj_mat, i);
wolffd@0 63 else
wolffd@0 64 ns = neighbors(adj_mat, i);
wolffd@0 65 end
wolffd@0 66 for j=1:length(ns)
wolffd@0 67 n=ns(j);
wolffd@0 68 if ~directed & n==pred(i) % don't go back up the edge you just came down
wolffd@0 69 % continue
wolffd@0 70 else
wolffd@0 71 if color(n) == gray % going back to a non-closed vertex via a new edge
wolffd@0 72 %fprintf(1, 'cycle from %d to %d\n', i, n);
wolffd@0 73 cycle = 1;
wolffd@0 74 end
wolffd@0 75 if color(n) == white % not visited n before
wolffd@0 76 pred(n)=i;
wolffd@0 77 [d, pre, post, height, cycle, color, pred] = ...
wolffd@0 78 dfs2(adj_mat, n, directed, h+1, d, pre, post, height, cycle, color, pred);
wolffd@0 79 end
wolffd@0 80 end
wolffd@0 81 end
wolffd@0 82 color(i) = black;
wolffd@0 83 post = [post i];
wolffd@0 84