mirror of
https://github.com/moses-smt/mosesdecoder.git
synced 2024-12-26 13:23:25 +03:00
315 lines
9.3 KiB
C++
315 lines
9.3 KiB
C++
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////////////////////////////////////////////////////////////
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//
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// generate set of target candidates for confusion net
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//
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////////////////////////////////////////////////////////////
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#include <numeric>
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#include "moses/Word.h"
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#include "moses/Phrase.h"
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#include "moses/ConfusionNet.h"
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#include "moses/WordsRange.h"
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#include "moses/TranslationModel/PhraseDictionaryTree.h"
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using namespace Moses;
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#if 0
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// Generates all tuples from n indexes with ranges 0 to card[j]-1, respectively..
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// Input: number of indexes and ranges: ranges[0] ... ranges[num_idx-1]
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// Output: number of tuples and monodimensional array of tuples.
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// Reference: mixed-radix generation algorithm (D. E. Knuth, TAOCP v. 4.2)
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size_t GenerateTuples(unsigned num_idx,unsigned* ranges,unsigned *&tuples)
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{
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unsigned* single_tuple= new unsigned[num_idx+1];
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unsigned num_tuples=1;
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for (unsigned k=0; k<num_idx; ++k) {
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num_tuples *= ranges[k];
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single_tuple[k]=0;
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}
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tuples=new unsigned[num_idx * num_tuples];
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// we need this additional element for the last iteration
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single_tuple[num_idx]=0;
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unsigned j=0;
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for (unsigned n=0; n<num_tuples; ++n) {
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memcpy((void *)((tuples + n * num_idx)),(void *)single_tuple,num_idx * sizeof(unsigned));
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j=0;
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while (single_tuple[j]==ranges[j]-1) {
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single_tuple[j]=0;
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++j;
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}
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++single_tuple[j];
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}
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delete [] single_tuple;
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return num_tuples;
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}
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typedef PhraseDictionaryTree::PrefixPtr PPtr;
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typedef std::vector<PPtr> vPPtr;
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typedef std::vector<std::vector<Factor const*> > mPhrase;
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std::ostream& operator<<(std::ostream& out,const mPhrase& p)
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{
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for(size_t i=0; i<p.size(); ++i) {
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out<<i<<" - ";
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for(size_t j=0; j<p[i].size(); ++j)
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out<<p[i][j]->ToString()<<" ";
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out<<"|";
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}
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return out;
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}
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struct State {
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vPPtr ptrs;
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WordsRange range;
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float score;
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State() : range(0,0),score(0.0) {}
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State(size_t b,size_t e,const vPPtr& v,float sc=0.0) : ptrs(v),range(b,e),score(sc) {}
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size_t begin() const {
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return range.GetStartPos();
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}
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size_t end() const {
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return range.GetEndPos();
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}
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float GetScore() const {
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return score;
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}
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};
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std::ostream& operator<<(std::ostream& out,const State& s)
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{
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out<<"["<<s.ptrs.size()<<" ("<<s.begin()<<","<<s.end()<<") "<<s.GetScore()<<"]";
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return out;
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}
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typedef std::map<mPhrase,float> E2Costs;
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struct GCData {
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const std::vector<PhraseDictionaryTree const*>& pdicts;
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const std::vector<std::vector<float> >& weights;
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std::vector<FactorType> inF,outF;
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size_t distinctOutputFactors;
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vPPtr root;
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size_t totalTuples,distinctTuples;
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GCData(const std::vector<PhraseDictionaryTree const*>& a,
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const std::vector<std::vector<float> >& b)
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: pdicts(a),weights(b),totalTuples(0),distinctTuples(0) {
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CHECK(pdicts.size()==weights.size());
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std::set<FactorType> distinctOutFset;
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inF.resize(pdicts.size());
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outF.resize(pdicts.size());
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root.resize(pdicts.size());
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for(size_t i=0; i<pdicts.size(); ++i) {
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root[i]=pdicts[i]->GetRoot();
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inF[i]=pdicts[i]->GetInputFactorType();
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outF[i]=pdicts[i]->GetOutputFactorType();
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distinctOutFset.insert(pdicts[i]->GetOutputFactorType());
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}
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distinctOutputFactors=distinctOutFset.size();
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}
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FactorType OutFT(size_t i) const {
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return outF[i];
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}
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FactorType InFT(size_t i) const {
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return inF[i];
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}
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size_t DistinctOutFactors() const {
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return distinctOutputFactors;
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}
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const vPPtr& GetRoot() const {
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return root;
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}
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};
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typedef std::vector<Factor const*> vFactor;
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typedef std::vector<std::pair<float,vFactor> > TgtCandList;
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typedef std::vector<TgtCandList> OutputFactor2TgtCandList;
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typedef std::vector<OutputFactor2TgtCandList*> Len2Cands;
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void GeneratePerFactorTgtList(size_t factorType,PPtr pptr,GCData& data,Len2Cands& len2cands)
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{
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std::vector<FactorTgtCand> cands;
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data.pdicts[factorType]->GetTargetCandidates(pptr,cands);
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for(std::vector<FactorTgtCand>::const_iterator cand=cands.begin(); cand!=cands.end(); ++cand) {
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CHECK(data.weights[factorType].size()==cand->second.size());
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float costs=std::inner_product(data.weights[factorType].begin(),
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data.weights[factorType].end(),
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cand->second.begin(),
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0.0);
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size_t len=cand->first.size();
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if(len>=len2cands.size()) len2cands.resize(len+1,0);
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if(!len2cands[len]) len2cands[len]=new OutputFactor2TgtCandList(data.DistinctOutFactors());
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OutputFactor2TgtCandList &outf2tcandlist=*len2cands[len];
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outf2tcandlist[data.OutFT(factorType)].push_back(std::make_pair(costs,cand->first));
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}
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}
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void GenerateTupleTgtCands(OutputFactor2TgtCandList& tCand,E2Costs& e2costs,GCData& data)
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{
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// check if candidates are non-empty
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bool gotCands=1;
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for(size_t j=0; gotCands && j<tCand.size(); ++j)
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gotCands &= !tCand[j].empty();
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if(gotCands) {
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// enumerate tuples
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CHECK(data.DistinctOutFactors()==tCand.size());
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std::vector<unsigned> radix(data.DistinctOutFactors());
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for(size_t i=0; i<tCand.size(); ++i) radix[i]=tCand[i].size();
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unsigned *tuples=0;
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size_t numTuples=GenerateTuples(radix.size(),&radix[0],tuples);
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data.totalTuples+=numTuples;
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for(size_t i=0; i<numTuples; ++i) {
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mPhrase e(radix.size());
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float costs=0.0;
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for(size_t j=0; j<radix.size(); ++j) {
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CHECK(tuples[radix.size()*i+j]<tCand[j].size());
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std::pair<float,vFactor> const& mycand=tCand[j][tuples[radix.size()*i+j]];
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e[j]=mycand.second;
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costs+=mycand.first;
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}
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#ifdef DEBUG
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bool mismatch=0;
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for(size_t j=1; !mismatch && j<e.size(); ++j)
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if(e[j].size()!=e[j-1].size()) mismatch=1;
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CHECK(mismatch==0);
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#endif
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std::pair<E2Costs::iterator,bool> p=e2costs.insert(std::make_pair(e,costs));
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if(p.second) ++data.distinctTuples;
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else {
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// entry known, take min of costs, alternative: sum probs
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if(costs<p.first->second) p.first->second=costs;
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}
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}
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delete [] tuples;
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}
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}
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void GenerateCandidates_(E2Costs& e2costs,const vPPtr& nextP,GCData& data)
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{
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Len2Cands len2cands;
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// generate candidates for each element of nextP:
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for(size_t factorType=0; factorType<nextP.size(); ++factorType)
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if(nextP[factorType])
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GeneratePerFactorTgtList(factorType,nextP[factorType],data,len2cands);
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// for each length: enumerate tuples, compute score, and insert in e2costs
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for(size_t len=0; len<len2cands.size(); ++len) if(len2cands[len])
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GenerateTupleTgtCands(*len2cands[len],e2costs,data);
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}
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void GenerateCandidates(const ConfusionNet& src,
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const std::vector<PhraseDictionaryTree const*>& pdicts,
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const std::vector<std::vector<float> >& weights,
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int verbose)
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{
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GCData data(pdicts,weights);
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std::vector<State> stack;
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for(size_t i=0; i<src.GetSize(); ++i) stack.push_back(State(i,i,data.GetRoot()));
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std::map<WordsRange,E2Costs> cov2E;
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// std::cerr<<"start while loop. initial stack size: "<<stack.size()<<"\n";
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while(!stack.empty()) {
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State curr(stack.back());
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stack.pop_back();
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//std::cerr<<"processing state "<<curr<<" stack size: "<<stack.size()<<"\n";
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CHECK(curr.end()<src.GetSize());
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const ConfusionNet::Column &currCol=src[curr.end()];
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for(size_t colidx=0; colidx<currCol.size(); ++colidx) {
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const Word& w=currCol[colidx].first;
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vPPtr nextP(curr.ptrs);
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for(size_t j=0; j<nextP.size(); ++j)
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nextP[j]=pdicts[j]->Extend(nextP[j],
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w.GetFactor(data.InFT(j))->GetString());
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bool valid=1;
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for(size_t j=0; j<nextP.size(); ++j) if(!nextP[j]) {
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valid=0;
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break;
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}
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if(valid) {
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if(curr.end()+1<src.GetSize())
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stack.push_back(State(curr.begin(),curr.end()+1,nextP,
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curr.GetScore()+currCol[colidx].second));
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E2Costs &e2costs=cov2E[WordsRange(curr.begin(),curr.end()+1)];
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GenerateCandidates_(e2costs,nextP,data);
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}
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}
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// check if there are translations of one-word phrases ...
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//if(curr.begin()==curr.end() && tCand.empty()) {}
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} // end while(!stack.empty())
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if(verbose) {
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// print statistics for debugging purposes
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std::cerr<<"tuple stats: total: "<<data.totalTuples
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<<" distinct: "<<data.distinctTuples<<" ("
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<<(data.distinctTuples/(0.01*data.totalTuples))
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<<"%)\n";
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std::cerr<<"per coverage set:\n";
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for(std::map<WordsRange,E2Costs>::const_iterator i=cov2E.begin();
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i!=cov2E.end(); ++i) {
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std::cerr<<i->first<<" -- distinct cands: "
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<<i->second.size()<<"\n";
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}
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std::cerr<<"\n\n";
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}
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if(verbose>10) {
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std::cerr<<"full list:\n";
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for(std::map<WordsRange,E2Costs>::const_iterator i=cov2E.begin();
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i!=cov2E.end(); ++i) {
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std::cerr<<i->first<<" -- distinct cands: "
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<<i->second.size()<<"\n";
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for(E2Costs::const_iterator j=i->second.begin(); j!=i->second.end(); ++j)
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std::cerr<<j->first<<" -- "<<j->second<<"\n";
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}
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}
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}
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#else
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void GenerateCandidates(const ConfusionNet&,
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const std::vector<PhraseDictionaryTree const*>&,
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const std::vector<std::vector<float> >&,
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int)
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{
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std::cerr<<"ERROR: GenerateCandidates is currently broken\n";
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}
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#endif
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