Mercurial > hg > camir-aes2014
comparison toolboxes/FullBNT-1.0.7/graph/mk_nbrs_of_digraph_broken.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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| -1:000000000000 | 0:e9a9cd732c1e |
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| 1 function [Gs, op, nodes] = mk_nbrs_of_digraph(G0) | |
| 2 % MK_NBRS_OF_DIGRAPH Make all digraphs that differ from G0 by a single edge deletion, addition or reversal | |
| 3 % [Gs, op, nodes] = mk_nbrs_of_digraph(G0) | |
| 4 % | |
| 5 % Gs(:,:,i) is the i'th neighbor | |
| 6 % op{i} = 'add', 'del', or 'rev' is the operation used to create the i'th neighbor. | |
| 7 % nodes(i,1:2) are the head and tail of the operated-on arc. | |
| 8 | |
| 9 debug = 0; % the vectorized version is about 3 to 10 times faster | |
| 10 | |
| 11 n = length(G0); | |
| 12 [I,J] = find(G0); % I(k), J(k) is the k'th edge | |
| 13 E = length(I); % num edges present in G0 | |
| 14 | |
| 15 % SINGLE EDGE DELETIONS | |
| 16 | |
| 17 Grep = repmat(G0(:), 1, E); % each column is a copy of G0 | |
| 18 % edge_ndx(k) is the scalar location of the k'th edge | |
| 19 edge_ndx = find(G0); | |
| 20 % edge_ndx = subv2ind([n n], [I J]); % equivalent | |
| 21 % We set (ndx(k), k) to 0 for k=1:E in Grep | |
| 22 ndx = subv2ind(size(Grep), [edge_ndx(:) (1:E)']); | |
| 23 G1 = Grep; | |
| 24 G1(ndx) = 0; | |
| 25 Gdel = reshape(G1, [n n E]); | |
| 26 | |
| 27 | |
| 28 % if debug | |
| 29 % % Non-vectorized version | |
| 30 % ctr = 1; | |
| 31 % for e=1:E | |
| 32 % i = I(e); j = J(e); | |
| 33 % Gdel2(:,:,ctr) = G0; | |
| 34 % Gdel2(i,j,ctr) = 0; | |
| 35 % ctr = ctr + 1; | |
| 36 % end | |
| 37 % assert(isequal(Gdel, Gdel2)); | |
| 38 % end | |
| 39 | |
| 40 | |
| 41 % SINGLE EDGE REVERSALS | |
| 42 | |
| 43 % rev_edge_ndx(k) is the scalar location of the k'th reversed edge | |
| 44 %rev_edge_ndx = find(G0'); % different order to edge_ndx, which is bad | |
| 45 rev_edge_ndx = subv2ind([n n], [J I]); | |
| 46 % We set (rev_edge_ndx(k), k) to 1 for k=1:E in G1 | |
| 47 % We have already deleted i->j in the previous step | |
| 48 ndx = subv2ind(size(Grep), [rev_edge_ndx(:) (1:E)']); | |
| 49 G1(ndx) = 1; | |
| 50 Grev = reshape(G1, [n n E]); | |
| 51 | |
| 52 % if debug | |
| 53 % % Non-vectorized version | |
| 54 % ctr = 1; | |
| 55 % for e=1:E | |
| 56 % i = I(e); j = J(e); | |
| 57 % Grev2(:,:,ctr) = G0; | |
| 58 % Grev2(i,j,ctr) = 0; | |
| 59 % Grev2(j,i,ctr) = 1; | |
| 60 % ctr = ctr + 1; | |
| 61 % end | |
| 62 % assert(isequal(Grev, Grev2)); | |
| 63 % end | |
| 64 | |
| 65 | |
| 66 % SINGLE EDGE ADDITIONS | |
| 67 | |
| 68 Gbar = ~G0; % Gbar(i,j)=1 iff there is no i->j edge in G0 | |
| 69 Gbar = setdiag(Gbar, 0); % turn off self loops | |
| 70 [Ibar,Jbar] = find(Gbar); | |
| 71 | |
| 72 bar_edge_ndx = find(Gbar); | |
| 73 Ebar = length(Ibar); % num edges present in Gbar | |
| 74 Grep = repmat(G0(:), 1, Ebar); % each column is a copy of G0 | |
| 75 ndx = subv2ind(size(Grep), [bar_edge_ndx(:) (1:Ebar)']); | |
| 76 Grep(ndx) = 1; | |
| 77 Gadd = reshape(Grep, [n n Ebar]); | |
| 78 | |
| 79 % if debug | |
| 80 % % Non-vectorized version | |
| 81 % ctr = 1; | |
| 82 % for e=1:length(Ibar) | |
| 83 % i = Ibar(e); j = Jbar(e); | |
| 84 % Gadd2(:,:,ctr) = G0; | |
| 85 % Gadd2(i,j,ctr) = 1; | |
| 86 % ctr = ctr + 1; | |
| 87 % end | |
| 88 % assert(isequal(Gadd, Gadd2)); | |
| 89 % end | |
| 90 | |
| 91 | |
| 92 Gs = cat(3, Gdel, Grev, Gadd); | |
| 93 | |
| 94 nodes = [I J; | |
| 95 I J; | |
| 96 Ibar Jbar]; | |
| 97 | |
| 98 op = cell(1, E+E+Ebar); | |
| 99 op(1:E) = {'del'}; | |
| 100 op(E+1:2*E) = {'rev'}; | |
| 101 op(2*E+1:end) = {'add'}; | |
| 102 | |
| 103 | |
| 104 % numeric output: | |
| 105 % op(i) = 1, 2, or 3, if the i'th neighbor was created by adding, deleting or reversing an arc. | |
| 106 | |
| 107 ADD = 1; | |
| 108 DEL = 2; | |
| 109 REV = 3; | |
| 110 | |
| 111 %op = [repmat(DEL, 1, E) repmat(REV, 1, E) repmat(ADD, 1, Ebar)]; |