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#include "HypPackEnumerator.h"
#include <cassert>
#include <algorithm>
#include <boost/unordered_set.hpp>
using namespace std;
namespace MosesTuning
{
StreamingHypPackEnumerator::StreamingHypPackEnumerator
(
vector<std::string> const& featureFiles,
vector<std::string> const& scoreFiles
)
: m_featureFiles(featureFiles),
m_scoreFiles(scoreFiles)
{
if (scoreFiles.size() == 0 || featureFiles.size() == 0) {
cerr << "No data to process" << endl;
exit(0);
}
if (featureFiles.size() != scoreFiles.size()) {
cerr << "Error: Number of feature files (" << featureFiles.size() <<
") does not match number of score files (" << scoreFiles.size() << ")" << endl;
exit(1);
}
m_num_lists = scoreFiles.size();
m_primed = false;
m_iNumDense = -1;
}
size_t StreamingHypPackEnumerator::num_dense() const
{
if(m_iNumDense<0) {
cerr << "Error: Requested num_dense() for an unprimed StreamingHypPackEnumerator" << endl;
exit(1);
}
return (size_t) m_iNumDense;
}
void StreamingHypPackEnumerator::prime()
{
m_current_indexes.clear();
m_current_featureVectors.clear();
boost::unordered_set<FeatureDataItem> seen;
m_primed = true;
for (size_t i = 0; i < m_num_lists; ++i) {
if (m_featureDataIters[i] == FeatureDataIterator::end()) {
cerr << "Error: Feature file " << i << " ended prematurely" << endl;
exit(1);
}
if (m_scoreDataIters[i] == ScoreDataIterator::end()) {
cerr << "Error: Score file " << i << " ended prematurely" << endl;
exit(1);
}
if (m_featureDataIters[i]->size() != m_scoreDataIters[i]->size()) {
cerr << "Error: For sentence " << m_sentenceId << " features and scores have different size" << endl;
exit(1);
}
for (size_t j = 0; j < m_featureDataIters[i]->size(); ++j) {
const FeatureDataItem& item = m_featureDataIters[i]->operator[](j);
// Dedup
if(seen.find(item)==seen.end()) {
seen.insert(item);
// Confirm dense features are always the same
int iDense = item.dense.size();
if(m_iNumDense != iDense) {
if(m_iNumDense==-1) m_iNumDense = iDense;
else {
cerr << "Error: expecting constant number of dense features: "
<< m_iNumDense << " != " << iDense << endl;
exit(1);
}
}
// Store item for retrieval
m_current_indexes.push_back(pair<size_t,size_t>(i,j));
m_current_featureVectors.push_back(MiraFeatureVector(item));
}
}
}
}
void StreamingHypPackEnumerator::reset()
{
m_featureDataIters.clear();
m_scoreDataIters.clear();
for (size_t i = 0; i < m_num_lists; ++i) {
m_featureDataIters.push_back(FeatureDataIterator(m_featureFiles[i]));
m_scoreDataIters.push_back(ScoreDataIterator(m_scoreFiles[i]));
}
m_sentenceId=0;
prime();
}
bool StreamingHypPackEnumerator::finished()
{
return m_featureDataIters[0]==FeatureDataIterator::end();
}
void StreamingHypPackEnumerator::next()
{
if(!m_primed) {
cerr << "Enumerating an unprimed HypPackEnumerator" << endl;
exit(1);
}
for (size_t i = 0; i < m_num_lists; ++i) {
++m_featureDataIters[i];
++m_scoreDataIters[i];
}
m_sentenceId++;
if(m_sentenceId % 100 == 0) cerr << ".";
if(!finished()) prime();
}
size_t StreamingHypPackEnumerator::cur_size()
{
if(!m_primed) {
cerr << "Querying size from an unprimed HypPackEnumerator" << endl;
exit(1);
}
return m_current_indexes.size();
}
const MiraFeatureVector& StreamingHypPackEnumerator::featuresAt(size_t index)
{
if(!m_primed) {
cerr << "Querying features from an unprimed HypPackEnumerator" << endl;
exit(1);
}
return m_current_featureVectors[index];
}
const ScoreDataItem& StreamingHypPackEnumerator::scoresAt(size_t index)
{
if(!m_primed) {
cerr << "Querying scores from an unprimed HypPackEnumerator" << endl;
exit(1);
}
const pair<size_t,size_t>& pij = m_current_indexes[index];
return m_scoreDataIters[pij.first]->operator[](pij.second);
}
size_t StreamingHypPackEnumerator::cur_id()
{
return m_sentenceId;
}
/* --------- RandomAccessHypPackEnumerator ------------- */
RandomAccessHypPackEnumerator::RandomAccessHypPackEnumerator(vector<string> const& featureFiles,
vector<string> const& scoreFiles,
bool no_shuffle)
{
StreamingHypPackEnumerator train(featureFiles,scoreFiles);
size_t index=0;
for(train.reset(); !train.finished(); train.next()) {
m_features.push_back(vector<MiraFeatureVector>());
m_scores.push_back(vector<ScoreDataItem>());
for(size_t j=0; j<train.cur_size(); j++) {
m_features.back().push_back(train.featuresAt(j));
m_scores.back().push_back(train.scoresAt(j));
}
m_indexes.push_back(index++);
}
m_cur_index = 0;
m_no_shuffle = no_shuffle;
m_num_dense = train.num_dense();
}
size_t RandomAccessHypPackEnumerator::num_dense() const
{
return m_num_dense;
}
void RandomAccessHypPackEnumerator::reset()
{
m_cur_index = 0;
if(!m_no_shuffle) random_shuffle(m_indexes.begin(),m_indexes.end());
}
bool RandomAccessHypPackEnumerator::finished()
{
return m_cur_index >= m_indexes.size();
}
void RandomAccessHypPackEnumerator::next()
{
m_cur_index++;
}
size_t RandomAccessHypPackEnumerator::cur_size()
{
assert(m_features[m_indexes[m_cur_index]].size()==m_scores[m_indexes[m_cur_index]].size());
return m_features[m_indexes[m_cur_index]].size();
}
const MiraFeatureVector& RandomAccessHypPackEnumerator::featuresAt(size_t i)
{
return m_features[m_indexes[m_cur_index]][i];
}
const ScoreDataItem& RandomAccessHypPackEnumerator::scoresAt(size_t i)
{
return m_scores[m_indexes[m_cur_index]][i];
}
size_t RandomAccessHypPackEnumerator::cur_id()
{
return m_indexes[m_cur_index];
}
// --Emacs trickery--
// Local Variables:
// mode:c++
// c-basic-offset:2
// End:
}
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