Mercurial > hg > camir-aes2014

comparison toolboxes/FullBNT-1.0.7/bnt/CPDs/@boolean_CPD/boolean_CPD.m @ 0:e9a9cd732c1e tip

Find changesets by keywords (author, files, the commit message), revision number or hash, or revset expression.
first hg version after svn
author wolffd
date Tue, 10 Feb 2015 15:05:51 +0000
parents
children
comparison
equal deleted inserted replaced
-1:000000000000 0:e9a9cd732c1e
1 function CPD = boolean_CPD(bnet, self, ftype, fname, pfail)
2 % BOOLEAN_CPD Make a tabular CPD representing a (noisy) boolean function
3 %
4 % CPD = boolean_cpd(bnet, self, 'inline', f) uses the inline function f
5 % to specify the CPT.
6 % e.g., suppose X4 = X2 AND (NOT X3). Then we can write
7 % bnet.CPD{4} = boolean_CPD(bnet, 4, 'inline', inline('(x(1) & ~x(2)'));
8 % Note that x(1) refers pvals(1) = X2, and x(2) refers to pvals(2)=X3.
9 %
10 % CPD = boolean_cpd(bnet, self, 'named', f) assumes f is a function name.
11 % f can be built-in to matlab, or a file.
12 % e.g., If X4 = X2 AND X3, we can write
13 % bnet.CPD{4} = boolean_CPD(bnet, 4, 'named', 'and');
14 % e.g., If X4 = X2 OR X3, we can write
15 % bnet.CPD{4} = boolean_CPD(bnet, 4, 'named', 'any');
16 %
17 % CPD = boolean_cpd(bnet, self, 'rnd') makes a random non-redundant bool fn.
18 %
19 % CPD = boolean_CPD(bnet, self, 'inline'/'named', f, pfail)
20 % will put probability mass 1-pfail on f(parents), and put pfail on the other value.
21 % This is useful for simulating noisy boolean functions.
22 % If pfail is omitted, it is set to 0.
23 % (Note that adding noise to a random (non-redundant) boolean function just creates a different
24 % (potentially redundant) random boolean function.)
25 %
26 % Note: This cannot be used to simulate a noisy-OR gate.
27 % Example: suppose C has parents A and B, and the
28 % link of A->C fails with prob pA and the link B->C fails with pB.
29 % Then the noisy-OR gate defines the following distribution
30 %
31 % A B P(C=0)
32 % 0 0 1.0
33 % 1 0 pA
34 % 0 1 pB
35 % 1 1 pA * PB
36 %
37 % By contrast, boolean_CPD(bnet, C, 'any', p) would define
38 %
39 % A B P(C=0)
40 % 0 0 1-p
41 % 1 0 p
42 % 0 1 p
43 % 1 1 p
44
45
46 if nargin==0
47 % This occurs if we are trying to load an object from a file.
48 CPD = tabular_CPD(bnet, self);
49 return;
50 elseif isa(bnet, 'boolean_CPD')
51 % This might occur if we are copying an object.
52 CPD = bnet;
53 return;
54 end
55
56 if nargin < 5, pfail = 0; end
57
58 ps = parents(bnet.dag, self);
59 ns = bnet.node_sizes;
60 psizes = ns(ps);
61 self_size = ns(self);
62
63 psucc = 1-pfail;
64
65 k = length(ps);
66 switch ftype
67 case 'inline', f = eval_bool_fn(fname, k);
68 case 'named', f = eval_bool_fn(fname, k);
69 case 'rnd', f = mk_rnd_bool_fn(k);
70 otherwise, error(['unknown function type ' ftype]);
71 end
72
73 CPT = zeros(prod(psizes), self_size);
74 ndx = find(f==0);
75 CPT(ndx, 1) = psucc;
76 CPT(ndx, 2) = pfail;
77 ndx = find(f==1);
78 CPT(ndx, 2) = psucc;
79 CPT(ndx, 1) = pfail;
80 if k > 0
81 CPT = reshape(CPT, [psizes self_size]);
82 end
83
84 clamp = 1;
85 CPD = tabular_CPD(bnet, self, CPT, [], clamp);
86
87
88
89 %%%%%%%%%%%%
90
91 function f = eval_bool_fn(fname, n)
92 % EVAL_BOOL_FN Evaluate a boolean function on all bit vectors of length n
93 % f = eval_bool_fn(fname, n)
94 %
95 % e.g. f = eval_bool_fn(inline('x(1) & x(3)'), 3)
96 % returns 0 0 0 0 0 1 0 1
97
98 ns = 2*ones(1, n);
99 f = zeros(1, 2^n);
100 bits = ind2subv(ns, 1:2^n);
101 for i=1:2^n
102 f(i) = feval(fname, bits(i,:)-1);
103 end
104
105 %%%%%%%%%%%%%%%
106
107 function f = mk_rnd_bool_fn(n)
108 % MK_RND_BOOL_FN Make a random bit vector of length n that encodes a non-redundant boolean function
109 % f = mk_rnd_bool_fn(n)
110
111 red = 1;
112 while red
113 f = sample_discrete([0.5 0.5], 2^n, 1)-1;
114 red = redundant_bool_fn(f);
115 end
116
117 %%%%%%%%
118
119
120 function red = redundant_bool_fn(f)
121 % REDUNDANT_BOOL_FN Does a boolean function depend on all its input values?
122 % r = redundant_bool_fn(f)
123 %
124 % f is a vector of length 2^n, representing the output for each bit vector.
125 % An input is redundant if there is no assignment to the other bits
126 % which changes the output e.g., input 1 is redundant if u(2:n) s.t.,
127 % f([0 u(2:n)]) <> f([1 u(2:n)]).
128 % A function is redundant it it has any redundant inputs.
129
130 n = log2(length(f));
131 ns = 2*ones(1,n);
132 red = 0;
133 for i=1:n
134 ens = ns;
135 ens(i) = 1;
136 U = ind2subv(ens, 1:2^(n-1));
137 U(:,i) = 1;
138 f1 = f(subv2ind(ns, U));
139 U(:,i) = 2;
140 f2 = f(subv2ind(ns, U));
141 if isequal(f1, f2)
142 red = 1;
143 return;
144 end
145 end
146
147
148 %%%%%%%%%%
149
150 function [b, iter] = rnd_truth_table(N)
151 % RND_TRUTH_TABLE Construct the output of a random truth table s.t. each input is non-redundant
152 % b = rnd_truth_table(N)
153 %
154 % N is the number of inputs.
155 % b is a random bit string of length N, representing the output of the truth table.
156 % Non-redundant means that, for each input position k,
157 % there are at least two bit patterns, u and v, that differ only in the k'th position,
158 % s.t., f(u) ~= f(v), where f is the function represented by b.
159 % We use rejection sampling to ensure non-redundancy.
160 %
161 % Example: b = [0 0 0 1 0 0 0 1] is indep of 3rd input (AND of inputs 1 and 2)
162
163 bits = ind2subv(2*ones(1,N), 1:2^N)-1;
164 redundant = 1;
165 iter = 0;
166 while redundant & (iter < 4)
167 iter = iter + 1;
168 b = sample_discrete([0.5 0.5], 1, 2^N)-1;
169 redundant = 0;
170 for i=1:N
171 on = find(bits(:,i)==1);
172 off = find(bits(:,i)==0);
173 if isequal(b(on), b(off))
174 redundant = 1;
175 break;
176 end
177 end
178 end
179