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361 lines
12 KiB
C++
361 lines
12 KiB
C++
// vim:tabstop=2
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/***********************************************************************
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Moses - factored phrase-based language decoder
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Copyright (C) 2010 Hieu Hoang
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This library is free software; you can redistribute it and/or
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modify it under the terms of the GNU Lesser General Public
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License as published by the Free Software Foundation; either
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version 2.1 of the License, or (at your option) any later version.
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This library is distributed in the hope that it will be useful,
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but WITHOUT ANY WARRANTY; without even the implied warranty of
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MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
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Lesser General Public License for more details.
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You should have received a copy of the GNU Lesser General Public
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License along with this library; if not, write to the Free Software
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Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA
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***********************************************************************/
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#include <algorithm>
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#include <vector>
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#include "ChartHypothesis.h"
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#include "RuleCubeItem.h"
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#include "ChartCell.h"
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#include "ChartManager.h"
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#include "TargetPhrase.h"
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#include "Phrase.h"
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#include "StaticData.h"
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#include "ChartTranslationOptions.h"
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#include "moses/FF/FFState.h"
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#include "moses/FF/StatefulFeatureFunction.h"
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#include "moses/FF/StatelessFeatureFunction.h"
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using namespace std;
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namespace Moses
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{
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#ifdef USE_HYPO_POOL
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ObjectPool<ChartHypothesis> ChartHypothesis::s_objectPool("ChartHypothesis", 300000);
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#endif
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/** Create a hypothesis from a rule
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* \param transOpt wrapper around the rule
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* \param item @todo dunno
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* \param manager reference back to manager
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*/
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ChartHypothesis::ChartHypothesis(const ChartTranslationOptions &transOpt,
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const RuleCubeItem &item,
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ChartManager &manager)
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:m_transOpt(item.GetTranslationDimension().GetTranslationOption())
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,m_currSourceWordsRange(transOpt.GetSourceWordsRange())
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,m_ffStates(StatefulFeatureFunction::GetStatefulFeatureFunctions().size())
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,m_arcList(NULL)
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,m_winningHypo(NULL)
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,m_manager(manager)
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,m_id(manager.GetNextHypoId())
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{
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// underlying hypotheses for sub-spans
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const std::vector<HypothesisDimension> &childEntries = item.GetHypothesisDimensions();
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m_prevHypos.reserve(childEntries.size());
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std::vector<HypothesisDimension>::const_iterator iter;
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for (iter = childEntries.begin(); iter != childEntries.end(); ++iter) {
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m_prevHypos.push_back(iter->GetHypothesis());
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}
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}
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// Intended to be used by ChartKBestExtractor only. This creates a mock
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// ChartHypothesis for use by the extractor's top-level target vertex.
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ChartHypothesis::ChartHypothesis(const ChartHypothesis &pred,
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const ChartKBestExtractor & /*unused*/)
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:m_currSourceWordsRange(pred.m_currSourceWordsRange)
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,m_totalScore(pred.m_totalScore)
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,m_arcList(NULL)
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,m_winningHypo(NULL)
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,m_manager(pred.m_manager)
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,m_id(pred.m_manager.GetNextHypoId())
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{
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// One predecessor, which is an existing top-level ChartHypothesis.
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m_prevHypos.push_back(&pred);
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}
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ChartHypothesis::~ChartHypothesis()
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{
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// delete feature function states
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for (unsigned i = 0; i < m_ffStates.size(); ++i) {
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delete m_ffStates[i];
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}
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// delete hypotheses that are not in the chart (recombined away)
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if (m_arcList) {
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ChartArcList::iterator iter;
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for (iter = m_arcList->begin() ; iter != m_arcList->end() ; ++iter) {
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ChartHypothesis *hypo = *iter;
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Delete(hypo);
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}
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m_arcList->clear();
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delete m_arcList;
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}
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}
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/** Create full output phrase that is contained in the hypothesis (and its children)
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* \param outPhrase full output phrase as return argument
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*/
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void ChartHypothesis::GetOutputPhrase(Phrase &outPhrase) const
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{
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FactorType placeholderFactor = StaticData::Instance().GetPlaceholderFactor();
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for (size_t pos = 0; pos < GetCurrTargetPhrase().GetSize(); ++pos) {
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const Word &word = GetCurrTargetPhrase().GetWord(pos);
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if (word.IsNonTerminal()) {
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// non-term. fill out with prev hypo
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size_t nonTermInd = GetCurrTargetPhrase().GetAlignNonTerm().GetNonTermIndexMap()[pos];
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const ChartHypothesis *prevHypo = m_prevHypos[nonTermInd];
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prevHypo->GetOutputPhrase(outPhrase);
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} else {
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outPhrase.AddWord(word);
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if (placeholderFactor != NOT_FOUND) {
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std::set<size_t> sourcePosSet = GetCurrTargetPhrase().GetAlignTerm().GetAlignmentsForTarget(pos);
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if (sourcePosSet.size() == 1) {
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const std::vector<const Word*> *ruleSourceFromInputPath = GetTranslationOption().GetSourceRuleFromInputPath();
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UTIL_THROW_IF2(ruleSourceFromInputPath == NULL,
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"No source rule");
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size_t sourcePos = *sourcePosSet.begin();
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const Word *sourceWord = ruleSourceFromInputPath->at(sourcePos);
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UTIL_THROW_IF2(sourceWord == NULL,
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"No source word");
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const Factor *factor = sourceWord->GetFactor(placeholderFactor);
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if (factor) {
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outPhrase.Back()[0] = factor;
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}
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}
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}
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}
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}
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}
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/** Return full output phrase */
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Phrase ChartHypothesis::GetOutputPhrase() const
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{
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Phrase outPhrase(ARRAY_SIZE_INCR);
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GetOutputPhrase(outPhrase);
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return outPhrase;
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}
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/** TODO: this method isn't used anywhere. Remove? */
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void ChartHypothesis::GetOutputPhrase(size_t leftRightMost, size_t numWords, Phrase &outPhrase) const
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{
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const TargetPhrase &tp = GetCurrTargetPhrase();
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size_t targetSize = tp.GetSize();
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for (size_t i = 0; i < targetSize; ++i) {
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size_t pos;
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if (leftRightMost == 1) {
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pos = i;
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} else if (leftRightMost == 2) {
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pos = targetSize - i - 1;
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} else {
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abort();
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}
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const Word &word = tp.GetWord(pos);
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if (word.IsNonTerminal()) {
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// non-term. fill out with prev hypo
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size_t nonTermInd = tp.GetAlignNonTerm().GetNonTermIndexMap()[pos];
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const ChartHypothesis *prevHypo = m_prevHypos[nonTermInd];
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prevHypo->GetOutputPhrase(outPhrase);
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} else {
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outPhrase.AddWord(word);
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}
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if (outPhrase.GetSize() >= numWords) {
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return;
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}
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}
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}
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/** check, if two hypothesis can be recombined.
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this is actually a sorting function that allows us to
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keep an ordered list of hypotheses. This makes recombination
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much quicker. Returns one of 3 possible values:
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-1 = this < compare
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+1 = this > compare
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0 = this ==compare
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\param compare the other hypo to compare to
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*/
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int ChartHypothesis::RecombineCompare(const ChartHypothesis &compare) const
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{
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int comp = 0;
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for (unsigned i = 0; i < m_ffStates.size(); ++i) {
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if (m_ffStates[i] == NULL || compare.m_ffStates[i] == NULL)
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comp = m_ffStates[i] - compare.m_ffStates[i];
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else
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comp = m_ffStates[i]->Compare(*compare.m_ffStates[i]);
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if (comp != 0)
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return comp;
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}
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return 0;
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}
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/** calculate total score */
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void ChartHypothesis::EvaluateWhenApplied()
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{
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const StaticData &staticData = StaticData::Instance();
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// compute values of stateless feature functions that were not
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// cached in the translation option-- there is no principled distinction
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const std::vector<const StatelessFeatureFunction*>& sfs =
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StatelessFeatureFunction::GetStatelessFeatureFunctions();
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for (unsigned i = 0; i < sfs.size(); ++i) {
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if (! staticData.IsFeatureFunctionIgnored( *sfs[i] )) {
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sfs[i]->EvaluateWhenApplied(*this,&m_currScoreBreakdown);
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}
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}
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const std::vector<const StatefulFeatureFunction*>& ffs =
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StatefulFeatureFunction::GetStatefulFeatureFunctions();
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for (unsigned i = 0; i < ffs.size(); ++i) {
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if (! staticData.IsFeatureFunctionIgnored( *ffs[i] )) {
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m_ffStates[i] = ffs[i]->EvaluateWhenApplied(*this,i,&m_currScoreBreakdown);
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}
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}
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// total score from current translation rule
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m_totalScore = GetTranslationOption().GetScores().GetWeightedScore();
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m_totalScore += m_currScoreBreakdown.GetWeightedScore();
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// total scores from prev hypos
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for (std::vector<const ChartHypothesis*>::const_iterator iter = m_prevHypos.begin(); iter != m_prevHypos.end(); ++iter) {
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const ChartHypothesis &prevHypo = **iter;
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m_totalScore += prevHypo.GetTotalScore();
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}
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}
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void ChartHypothesis::AddArc(ChartHypothesis *loserHypo)
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{
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if (!m_arcList) {
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if (loserHypo->m_arcList) {
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// we don't have an arcList, but loser does
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this->m_arcList = loserHypo->m_arcList; // take ownership, we'll delete
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loserHypo->m_arcList = 0; // prevent a double deletion
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} else {
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this->m_arcList = new ChartArcList();
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}
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} else {
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if (loserHypo->m_arcList) {
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// both have an arc list: merge. delete loser
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size_t my_size = m_arcList->size();
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size_t add_size = loserHypo->m_arcList->size();
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this->m_arcList->resize(my_size + add_size, 0);
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std::memcpy(&(*m_arcList)[0] + my_size, &(*loserHypo->m_arcList)[0], add_size * sizeof(ChartHypothesis *));
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delete loserHypo->m_arcList;
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loserHypo->m_arcList = 0;
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} else {
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// loserHypo doesn't have any arcs
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// DO NOTHING
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}
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}
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m_arcList->push_back(loserHypo);
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}
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// sorting helper
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struct CompareChartHypothesisTotalScore {
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bool operator()(const ChartHypothesis* hypo1, const ChartHypothesis* hypo2) const {
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return hypo1->GetTotalScore() > hypo2->GetTotalScore();
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}
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};
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void ChartHypothesis::CleanupArcList()
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{
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// point this hypo's main hypo to itself
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m_winningHypo = this;
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if (!m_arcList) return;
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/* keep only number of arcs we need to create all n-best paths.
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* However, may not be enough if only unique candidates are needed,
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* so we'll keep all of arc list if nedd distinct n-best list
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*/
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const StaticData &staticData = StaticData::Instance();
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size_t nBestSize = staticData.GetNBestSize();
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bool distinctNBest = staticData.GetDistinctNBest() || staticData.UseMBR() || staticData.GetOutputSearchGraph() || staticData.GetOutputSearchGraphHypergraph();
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if (!distinctNBest && m_arcList->size() > nBestSize) {
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// prune arc list only if there too many arcs
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NTH_ELEMENT4(m_arcList->begin()
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, m_arcList->begin() + nBestSize - 1
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, m_arcList->end()
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, CompareChartHypothesisTotalScore());
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// delete bad ones
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ChartArcList::iterator iter;
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for (iter = m_arcList->begin() + nBestSize ; iter != m_arcList->end() ; ++iter) {
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ChartHypothesis *arc = *iter;
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ChartHypothesis::Delete(arc);
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}
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m_arcList->erase(m_arcList->begin() + nBestSize
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, m_arcList->end());
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}
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// set all arc's main hypo variable to this hypo
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ChartArcList::iterator iter = m_arcList->begin();
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for (; iter != m_arcList->end() ; ++iter) {
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ChartHypothesis *arc = *iter;
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arc->SetWinningHypo(this);
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}
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//cerr << m_arcList->size() << " ";
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}
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void ChartHypothesis::SetWinningHypo(const ChartHypothesis *hypo)
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{
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m_winningHypo = hypo;
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}
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TO_STRING_BODY(ChartHypothesis)
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// friend
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std::ostream& operator<<(std::ostream& out, const ChartHypothesis& hypo)
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{
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out << hypo.GetId();
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// recombination
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if (hypo.GetWinningHypothesis() != NULL &&
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hypo.GetWinningHypothesis() != &hypo) {
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out << "->" << hypo.GetWinningHypothesis()->GetId();
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}
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if (StaticData::Instance().GetIncludeLHSInSearchGraph()) {
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out << " " << hypo.GetTargetLHS() << "=>";
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}
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out << " " << hypo.GetCurrTargetPhrase()
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//<< " " << outPhrase
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<< " " << hypo.GetCurrSourceRange();
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HypoList::const_iterator iter;
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for (iter = hypo.GetPrevHypos().begin(); iter != hypo.GetPrevHypos().end(); ++iter) {
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const ChartHypothesis &prevHypo = **iter;
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out << " " << prevHypo.GetId();
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}
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out << " [total=" << hypo.GetTotalScore() << "]";
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out << " " << hypo.GetScoreBreakdown();
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//out << endl;
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return out;
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}
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}
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