/usr/include/opengm/inference/dmc.hxx is in libopengm-dev 2.3.6+20160905-1build2.
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#ifndef OPENGM_DMC_HXX
#define OPENGM_DMC_HXX
#include <vector>
#include <string>
#include <iostream>
#include "opengm/opengm.hxx"
//#include "opengm/inference/visitors/visitor.hxx"
#include "opengm/inference/inference.hxx"
#include "opengm/inference/movemaker.hxx"
#include "opengm/datastructures/buffer_vector.hxx"
#include <opengm/graphicalmodel/space/simplediscretespace.hxx>
#include <opengm/functions/potts.hxx>
#include "opengm/inference/visitors/visitors.hxx"
namespace opengm {
template<class GM, class INF>
class DMC : public Inference<GM, typename INF::AccumulationType>
{
public:
typedef typename INF::AccumulationType ACC;
typedef ACC AccumulationType;
typedef GM GraphicalModelType;
OPENGM_GM_TYPE_TYPEDEFS;
typedef typename INF::Parameter InfParam;
typedef opengm::visitors::VerboseVisitor<DMC<GM,INF> > VerboseVisitorType;
typedef opengm::visitors::EmptyVisitor<DMC<GM,INF> > EmptyVisitorType;
typedef opengm::visitors::TimingVisitor<DMC<GM,INF> > TimingVisitorType;
class Parameter {
public:
Parameter(
const ValueType threshold = ValueType(-0.000000001),
const InfParam infParam = InfParam()
)
: threshold_(threshold),
infParam_(infParam){
}
ValueType threshold_;
InfParam infParam_;
};
DMC(const GraphicalModelType&, const Parameter&);
std::string name() const;
const GraphicalModelType& graphicalModel() const;
InferenceTermination infer();
void reset();
template<class VisitorType>
InferenceTermination infer(VisitorType&);
void setStartingPoint(typename std::vector<LabelType>::const_iterator);
virtual InferenceTermination arg(std::vector<LabelType>&, const size_t = 1) const ;
virtual ValueType value()const{
assert(false); // FIXME: the return of this function was missing, just added something arbitrary
return ValueType();
}
private:
const GraphicalModelType& gm_;
Parameter param_;
ValueType value_;
std::vector<LabelType> arg_;
};
template<class GM, class INF>
inline
DMC<GM, INF>::DMC
(
const GraphicalModelType& gm,
const Parameter& parameter
)
: gm_(gm),
param_(parameter),
value_(),
arg_(gm.numberOfVariables(), 0) {
}
template<class GM, class INF>
inline void
DMC<GM, INF>::reset()
{
}
template<class GM, class INF>
inline void
DMC<GM,INF>::setStartingPoint
(
typename std::vector<typename DMC<GM,INF>::LabelType>::const_iterator begin
) {
}
template<class GM, class INF>
inline std::string
DMC<GM, INF>::name() const
{
return "DMC";
}
template<class GM, class INF>
inline const typename DMC<GM, INF>::GraphicalModelType&
DMC<GM, INF>::graphicalModel() const
{
return gm_;
}
template<class GM, class INF>
inline InferenceTermination
DMC<GM,INF>::infer()
{
EmptyVisitorType v;
return infer(v);
}
template<class GM, class INF>
template<class VisitorType>
InferenceTermination DMC<GM,INF>::infer
(
VisitorType& visitor
)
{
visitor.begin(*this);
LabelType lAA[2]={0, 0};
LabelType lAB[2]={0, 1};
// decomposition
Partition<LabelType> ufd(gm_.numberOfVariables());
for(size_t fi=0; fi< gm_.numberOfFactors(); ++fi){
if(gm_[fi].numberOfVariables()==2){
const ValueType val00 = gm_[fi](lAA);
const ValueType val01 = gm_[fi](lAB);
const ValueType weight = val01 - val00;
if(weight>param_.threshold_){
const size_t vi0 = gm_[fi].variableIndex(0);
const size_t vi1 = gm_[fi].variableIndex(1);
ufd.merge(vi0, vi1);
}
}
else{
throw RuntimeError("wrong factor order for multicut");
}
}
if(ufd.numberOfSets() == 1){
//std::cout<<" all in one cc\n";
// FALL BACK HERE!!!
typedef typename INF:: template rebind<GM,ACC>::type OrgInf;
typename OrgInf::Parameter orgInfParam(param_.infParam_);
OrgInf orgInf(gm_, orgInfParam);
orgInf.infer();
orgInf.arg(arg_);
value_ = gm_.evaluate(arg_);
}
else {
//std::cout<<" NOT all in one cc\n";
std::map<LabelType, LabelType> repr;
ufd.representativeLabeling(repr);
//std::cout<<"gm_.numVar "<<gm_.numberOfVariables()<<"\n";
//std::cout<<"reprs size"<<repr.size()<<"\n";
//std::cout<<"ufd.numberOfSets() "<<ufd.numberOfSets()<<"\n";
std::vector< std::vector< LabelType> > subVar(ufd.numberOfSets());
// set up the sub var
for(size_t vi=0; vi<gm_.numberOfVariables(); ++vi){
subVar[repr[ufd.find(vi)]].push_back(vi);
}
const size_t nSubProb = subVar.size();
std::vector<unsigned char> usedFactors_(gm_.numberOfFactors(),0);
// mark all factors where weight is smaller
// as param_.threshold_ as used
for(size_t fi=0; fi< gm_.numberOfFactors(); ++fi){
if(
ufd.find(gm_[fi].variableIndex(0))
!=
ufd.find(gm_[fi].variableIndex(1))
)
{
usedFactors_[fi] = 1;
}
}
std::vector<IndexType> globalToLocal(gm_.numberOfVariables(), gm_.numberOfVariables()+1);
IndexType offset = 0;
for(size_t subProb = 0; subProb<nSubProb; ++subProb){
//std::cout<<"subProb "<<subProb<<"\n";
const IndexType nSubVar = subVar[subProb].size();
//std::cout<<"nSubVar "<<nSubVar<<"\n";
typedef PottsFunction<ValueType,IndexType,IndexType> Pf;
typedef SimpleDiscreteSpace<IndexType, IndexType> Space;
typedef GraphicalModel<ValueType, OperatorType, Pf , Space> Model;
Space space(nSubVar, nSubVar);
Model subGm(space);
for(IndexType lvi=0; lvi<nSubVar; ++lvi){
const IndexType gvi = subVar[subProb][lvi];
globalToLocal[gvi] = lvi;
}
if(nSubVar==1){
const IndexType gvi = subVar[subProb][0];
arg_[gvi] = offset;
}
else if(nSubVar==2){
const IndexType gvi0 = subVar[subProb][0];
const IndexType gvi1 = subVar[subProb][1];
arg_[gvi0] = offset;
arg_[gvi1] = offset;
}
else{
for(IndexType lvi=0; lvi<nSubVar; ++lvi){
const IndexType gvi = subVar[subProb][lvi];
OPENGM_CHECK_OP(lvi, == , globalToLocal[gvi], ' ');
// number of factors
const size_t nf = gm_.numberOfFactors(gvi);
for(size_t f=0; f<nf; ++f){
const IndexType nfi = gm_.factorOfVariable(gvi, f);
if(usedFactors_[nfi] != 1){
usedFactors_[nfi] = 1;
// add factor to graphical model
const ValueType val00 = gm_[nfi](lAA);
const ValueType val01 = gm_[nfi](lAB);
const ValueType weight = val01 - val00;
const IndexType vi0 = gm_[nfi].variableIndex(0);
const IndexType vi1 = gm_[nfi].variableIndex(1);
if( ufd.find(vi0) != ufd.find(vi1)){
OPENGM_CHECK_OP(ufd.find(vi0),!=,ufd.find(vi1), "internal error");
}
const IndexType lvis[] = {
std::min(globalToLocal[vi0],globalToLocal[vi1]),
std::max(globalToLocal[vi0],globalToLocal[vi1])
};
const Pf pf(nSubVar, nSubVar, 0.0, weight);
subGm.addFactor(subGm.addFunction(pf), lvis, lvis+2);
}
}
}
// infer the submodel
typedef typename INF:: template rebind<Model,ACC>::type SubInf;
typename SubInf::Parameter subInfParam(param_.infParam_);
SubInf subInf(subGm, subInfParam);
subInf.infer();
std::vector<LabelType> subArg(subGm.numberOfVariables());
subInf.arg(subArg);
for(IndexType lvi=0; lvi<nSubVar; ++lvi){
const IndexType gvi = subVar[subProb][lvi];
arg_[gvi] = subArg[lvi] + offset;
}
}
offset += nSubVar;
}
value_ = gm_.evaluate(arg_);
visitor.end(*this);
}
return NORMAL;
}
template<class GM, class INF>
inline InferenceTermination
DMC<GM,INF>::arg
(
std::vector<LabelType>& x,
const size_t N
) const
{
if(N==1) {
x.resize(gm_.numberOfVariables());
for(size_t j=0; j<x.size(); ++j) {
x[j] =arg_[j];
}
return NORMAL;
}
else {
return UNKNOWN;
}
}
} // namespace opengm
#endif // #ifndef OPENGM_DMC_HXX
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