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yap-6.3/packages/CLPBN/horus/Factor.h
2012-12-27 22:25:45 +00:00

295 lines
7.2 KiB
C++

#ifndef HORUS_FACTOR_H
#define HORUS_FACTOR_H
#include <vector>
#include "Indexer.h"
#include "Util.h"
using namespace std;
template <typename T>
class TFactor
{
public:
const vector<T>& arguments (void) const { return args_; }
vector<T>& arguments (void) { return args_; }
const Ranges& ranges (void) const { return ranges_; }
const Params& params (void) const { return params_; }
Params& params (void) { return params_; }
size_t nrArguments (void) const { return args_.size(); }
size_t size (void) const { return params_.size(); }
unsigned distId (void) const { return distId_; }
void setDistId (unsigned id) { distId_ = id; }
void normalize (void) { LogAware::normalize (params_); }
void randomize (void)
{
for (size_t i = 0; i < params_.size(); ++i) {
params_[i] = (double) std::rand() / RAND_MAX;
}
}
void setParams (const Params& newParams)
{
params_ = newParams;
assert (params_.size() == Util::sizeExpected (ranges_));
}
size_t indexOf (const T& t) const
{
return Util::indexOf (args_, t);
}
const T& argument (size_t idx) const
{
assert (idx < args_.size());
return args_[idx];
}
T& argument (size_t idx)
{
assert (idx < args_.size());
return args_[idx];
}
unsigned range (size_t idx) const
{
assert (idx < ranges_.size());
return ranges_[idx];
}
void multiply (TFactor<T>& g)
{
if (args_ == g.arguments()) {
// optimization
Globals::logDomain
? params_ += g.params()
: params_ *= g.params();
return;
}
unsigned range_prod = 1;
bool share_arguments = false;
const vector<T>& g_args = g.arguments();
const Ranges& g_ranges = g.ranges();
const Params& g_params = g.params();
for (size_t i = 0; i < g_args.size(); i++) {
size_t idx = indexOf (g_args[i]);
if (idx == args_.size()) {
range_prod *= g_ranges[i];
args_.push_back (g_args[i]);
ranges_.push_back (g_ranges[i]);
} else {
share_arguments = true;
}
}
if (share_arguments == false) {
// optimization
cartesianProduct (g_params.begin(), g_params.end());
} else {
extend (range_prod);
Params::iterator it = params_.begin();
MapIndexer indexer (args_, ranges_, g_args, g_ranges);
if (Globals::logDomain) {
for (; indexer.valid(); ++it, ++indexer) {
*it += g_params[indexer];
}
} else {
for (; indexer.valid(); ++it, ++indexer) {
*it *= g_params[indexer];
}
}
}
}
void sumOutIndex (size_t idx)
{
assert (idx < args_.size());
assert (args_.size() > 1);
size_t new_size = params_.size() / ranges_[idx];
Params newps (new_size, LogAware::addIdenty());
Params::const_iterator first = params_.begin();
Params::const_iterator last = params_.end();
MapIndexer indexer (ranges_, idx);
if (Globals::logDomain) {
for (; first != last; ++indexer) {
newps[indexer] = Util::logSum (newps[indexer], *first++);
}
} else {
for (; first != last; ++indexer) {
newps[indexer] += *first++;
}
}
params_ = newps;
args_.erase (args_.begin() + idx);
ranges_.erase (ranges_.begin() + idx);
}
void absorveEvidence (const T& arg, unsigned obsIdx)
{
size_t idx = indexOf (arg);
assert (idx != args_.size());
assert (obsIdx < ranges_[idx]);
Params newps;
newps.reserve (params_.size() / ranges_[idx]);
Indexer indexer (ranges_);
for (unsigned i = 0; i < obsIdx; ++i) {
indexer.incrementDimension (idx);
}
while (indexer.valid()) {
newps.push_back (params_[indexer]);
indexer.incrementExceptDimension (idx);
}
params_ = newps;
args_.erase (args_.begin() + idx);
ranges_.erase (ranges_.begin() + idx);
}
void reorderArguments (const vector<T> new_args)
{
assert (new_args.size() == args_.size());
if (new_args == args_) {
return; // already on the desired order
}
Ranges new_ranges;
for (size_t i = 0; i < new_args.size(); i++) {
size_t idx = indexOf (new_args[i]);
assert (idx != args_.size());
new_ranges.push_back (ranges_[idx]);
}
Params newps;
newps.reserve (params_.size());
MapIndexer indexer (new_args, new_ranges, args_, ranges_);
for (; indexer.valid(); ++indexer) {
newps.push_back (params_[indexer]);
}
params_ = newps;
args_ = new_args;
ranges_ = new_ranges;
}
bool contains (const T& arg) const
{
return Util::contains (args_, arg);
}
bool contains (const vector<T>& args) const
{
for (size_t i = 0; i < args.size(); i++) {
if (contains (args[i]) == false) {
return false;
}
}
return true;
}
double& operator[] (size_t idx)
{
assert (idx < params_.size());
return params_[idx];
}
protected:
vector<T> args_;
Ranges ranges_;
Params params_;
unsigned distId_;
private:
void extend (unsigned range_prod)
{
Params backup = params_;
params_.clear();
params_.reserve (backup.size() * range_prod);
Params::const_iterator first = backup.begin();
Params::const_iterator last = backup.end();
for (; first != last; ++first) {
for (unsigned reps = 0; reps < range_prod; ++reps) {
params_.push_back (*first);
}
}
}
void cartesianProduct (
Params::const_iterator first2,
Params::const_iterator last2)
{
Params backup = params_;
params_.clear();
params_.reserve (params_.size() * (last2 - first2));
Params::const_iterator first1 = backup.begin();
Params::const_iterator last1 = backup.end();
Params::const_iterator tmp;
if (Globals::logDomain) {
for (; first1 != last1; ++first1) {
for (tmp = first2; tmp != last2; ++tmp) {
params_.push_back ((*first1) + (*tmp));
}
}
} else {
for (; first1 != last1; ++first1) {
for (tmp = first2; tmp != last2; ++tmp) {
params_.push_back ((*first1) * (*tmp));
}
}
}
}
};
class Factor : public TFactor<VarId>
{
public:
Factor (void) { }
Factor (const Factor&);
Factor (const VarIds&, const Ranges&, const Params&,
unsigned = Util::maxUnsigned());
Factor (const Vars&, const Params&,
unsigned = Util::maxUnsigned());
void sumOut (VarId);
void sumOutAllExcept (VarId);
void sumOutAllExcept (const VarIds&);
void sumOutAllExceptIndex (size_t idx);
void multiply (Factor&);
string getLabel (void) const;
void print (void) const;
private:
void sumOutFirstVariable (void);
void sumOutLastVariable (void);
void sumOutArgs (const vector<bool>& mask);
void clone (const Factor& f);
DISALLOW_ASSIGN (Factor);
};
#endif // HORUS_FACTOR_H