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begio
[专家分:0] 发布于 2009-08-05 11:16:00
这是一个关于深度优先搜索算法(greensim团队里的),它采用了函数的递归调用。我不理解算法中v的值是怎样传递给u的,请大家赐教啊。现在附上程序。
function [d, pre, post, cycle, f, pred] = dfs1(adj_mat, start, directed)
% 此程序从国外网站收集得到,是标准的深度优先搜索算法,可实现节点遍历和检测回路等功能,详细情况请看原英文注释
% 我在此程序中添加了随机性,即遇到分叉时,随机选下一个节点,成为随机深度优先搜索算法
% 欢迎访问GreenSim团队的主页[url=http://blog.sina.com.cn/greensim]http://blog.sina.com.cn/greensim[/url]
% DFS Perform a depth-first search of the graph starting from 'start'.
% [d, pre, post, cycle, f, pred] = dfs(adj_mat, start, directed)
%
% Input:
% adj_mat(i,j)=1 iff i is connected to j.
% start is the root vertex of the dfs tree; if [], all nodes are searched
% directed = 1 if the graph is directed
%
% Output:
% d(i) is the time at which node i is first discovered.
% pre is a list of the nodes in the order in which they are first encountered (opened).
% post is a list of the nodes in the order in which they are last encountered (closed).
% 'cycle' is true iff a (directed) cycle is found.
% f(i) is the time at which node i is finished.
% pred(i) is the predecessor of i in the dfs tree.
%
% If the graph is a tree, preorder is parents before children,
% and postorder is children before parents.
% For a DAG, topological order = reverse(postorder).
%
% See Cormen, Leiserson and Rivest, "An intro. to algorithms" 1994, p478.
adj_mat=triu(adj_mat);%考虑兼容性,只取上三角部分
n = length(adj_mat);
global white gray black color
white = 0; gray = 1; black = 2;
color = white*ones(1,n);
global time_stamp
time_stamp = 0;
global d f
d = zeros(1,n);
f = zeros(1,n);
global pred
pred = zeros(1,n);
global cycle
cycle = 0;
global pre post
pre = [];
post = [];
if ~isempty(start)
dfs_visit(start, adj_mat, directed);
end
for u=1:n
if color(u)==white
dfs_visit(u, adj_mat, directed);
end
end
%%%%%%%%%%
function dfs_visit(u, adj_mat, directed)
global white gray black color time_stamp d f pred cycle pre post
pre = [pre u];
color(u) = gray;
time_stamp = time_stamp + 1;
d(u) = time_stamp;
if directed
ns = children(adj_mat, u);
else
ns = neighbors(adj_mat, u);
ns = setdiff(ns, pred(u)); % don't go back to visit the guy who called you!
end
%以下三句是为随机选路而设置
%lns=length(ns);
%pos=randperm(lns);
%ns=ns(pos);
for v=ns(:)'
fprintf('u=%d, v=%d, color(v)=%d\n', u, v, color(v))
switch color(v)
case white, % not visited v before (tree edge)
pred(v)=u;
dfs_visit(v, adj_mat, directed);
case gray, % back edge - v has been visited, but is still open
cycle = 1;
fprintf('cycle: back edge from v=%d to u=%d\n', v, u);
case black, % v has been visited, but is closed
% no-op
end
end
color(u) = black;
post = [post u];
time_stamp = time_stamp + 1;
f(u) = time_stamp;
function cs = children(adj_mat, i, t)
% CHILDREN Return the indices of a node's children in sorted order
% c = children(adj_mat, i, t)
%
% t is an optional argument: if present, dag is assumed to be a 2-slice DBN
if nargin < 3
cs = find(adj_mat(i,:));
else
if t==1
cs = find(adj_mat(i,:));
else
ss = length(adj_mat)/2;
j = i+ss;
cs = find(adj_mat(j,:)) + (t-2)*ss;
end
end
function ns = neighbors(adj_mat, i)
% NEIGHBORS Find the parents and children of a node in a graph.
% ns = neighbors(adj_mat, i)
%ns = myunion(children(adj_mat, i), parents(adj_mat, i));
ns = [find(adj_mat(i,:)) find(adj_mat(:,i))'];
我用的关联矩阵是:
adj_mat=[0 1 1 0 0 ;
1 0 0 1 0;
1 0 0 1 0;
0 1 1 0 1;
0 0 0 01 0];
sart=1, directed=0.
function [d, pre, post, cycle, f, pred] = dfs1(adj_mat, start, directed)
% 此程序从国外网站收集得到,是标准的深度优先搜索算法,可实现节点遍历和检测回路等功能,详细情况请看原英文注释
% 我在此程序中添加了随机性,即遇到分叉时,随机选下一个节点,成为随机深度优先搜索算法
% 欢迎访问GreenSim团队的主页[url=http://blog.sina.com.cn/greensim]http://blog.sina.com.cn/greensim[/url]
% DFS Perform a depth-first search of the graph starting from 'start'.
% [d, pre, post, cycle, f, pred] = dfs(adj_mat, start, directed)
%
% Input:
% adj_mat(i,j)=1 iff i is connected to j.
% start is the root vertex of the dfs tree; if [], all nodes are searched
% directed = 1 if the graph is directed
%
% Output:
% d(i) is the time at which node i is first discovered.
% pre is a list of the nodes in the order in which they are first encountered (opened).
% post is a list of the nodes in the order in which they are last encountered (closed).
% 'cycle' is true iff a (directed) cycle is found.
% f(i) is the time at which node i is finished.
% pred(i) is the predecessor of i in the dfs tree.
%
% If the graph is a tree, preorder is parents before children,
% and postorder is children before parents.
% For a DAG, topological order = reverse(postorder).
%
% See Cormen, Leiserson and Rivest, "An intro. to algorithms" 1994, p478.
adj_mat=triu(adj_mat);%考虑兼容性,只取上三角部分
n = length(adj_mat);
global white gray black color
white = 0; gray = 1; black = 2;
color = white*ones(1,n);
global time_stamp
time_stamp = 0;
global d f
d = zeros(1,n);
f = zeros(1,n);
global pred
pred = zeros(1,n);
global cycle
cycle = 0;
global pre post
pre = [];
post = [];
if ~isempty(start)
dfs_visit(start, adj_mat, directed);
end
for u=1:n
if color(u)==white
dfs_visit(u, adj_mat, directed);
end
end
%%%%%%%%%%
function dfs_visit(u, adj_mat, directed)
global white gray black color time_stamp d f pred cycle pre post
pre = [pre u];
color(u) = gray;
time_stamp = time_stamp + 1;
d(u) = time_stamp;
if directed
ns = children(adj_mat, u);
else
ns = neighbors(adj_mat, u);
ns = setdiff(ns, pred(u)); % don't go back to visit the guy who called you!
end
%以下三句是为随机选路而设置
%lns=length(ns);
%pos=randperm(lns);
%ns=ns(pos);
for v=ns(:)'
fprintf('u=%d, v=%d, color(v)=%d\n', u, v, color(v))
switch color(v)
case white, % not visited v before (tree edge)
pred(v)=u;
dfs_visit(v, adj_mat, directed);
case gray, % back edge - v has been visited, but is still open
cycle = 1;
fprintf('cycle: back edge from v=%d to u=%d\n', v, u);
case black, % v has been visited, but is closed
% no-op
end
end
color(u) = black;
post = [post u];
time_stamp = time_stamp + 1;
f(u) = time_stamp;
function cs = children(adj_mat, i, t)
% CHILDREN Return the indices of a node's children in sorted order
% c = children(adj_mat, i, t)
%
% t is an optional argument: if present, dag is assumed to be a 2-slice DBN
if nargin < 3
cs = find(adj_mat(i,:));
else
if t==1
cs = find(adj_mat(i,:));
else
ss = length(adj_mat)/2;
j = i+ss;
cs = find(adj_mat(j,:)) + (t-2)*ss;
end
end
function ns = neighbors(adj_mat, i)
% NEIGHBORS Find the parents and children of a node in a graph.
% ns = neighbors(adj_mat, i)
%ns = myunion(children(adj_mat, i), parents(adj_mat, i));
ns = [find(adj_mat(i,:)) find(adj_mat(:,i))'];
我用的关联矩阵是:
adj_mat=[0 1 1 0 0 ;
1 0 0 1 0;
1 0 0 1 0;
0 1 1 0 1;
0 0 0 01 0];
sart=1, directed=0.