mosesdecoder/moses/ChartManager.cpp

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// $Id$
// vim:tabstop=2
/***********************************************************************
Moses - factored phrase-based language decoder
Copyright (C) 2010 Hieu Hoang
This library is free software; you can redistribute it and/or
modify it under the terms of the GNU Lesser General Public
License as published by the Free Software Foundation; either
version 2.1 of the License, or (at your option) any later version.
This library is distributed in the hope that it will be useful,
but WITHOUT ANY WARRANTY; without even the implied warranty of
MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
Lesser General Public License for more details.
You should have received a copy of the GNU Lesser General Public
License along with this library; if not, write to the Free Software
Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA
***********************************************************************/
#include <stdio.h>
#include "ChartManager.h"
#include "ChartCell.h"
#include "ChartHypothesis.h"
#include "ChartTranslationOptions.h"
#include "ChartTrellisDetourQueue.h"
#include "ChartTrellisNode.h"
#include "ChartTrellisPath.h"
#include "ChartTrellisPathList.h"
#include "StaticData.h"
#include "DecodeStep.h"
#include "TreeInput.h"
#include "moses/FF/WordPenaltyProducer.h"
using namespace std;
using namespace Moses;
namespace Moses
{
extern bool g_mosesDebug;
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/* constructor. Initialize everything prior to decoding a particular sentence.
* \param source the sentence to be decoded
* \param system which particular set of models to use.
*/
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ChartManager::ChartManager(InputType const& source)
:m_source(source)
,m_hypoStackColl(source, *this)
,m_start(clock())
,m_hypothesisId(0)
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,m_parser(source, m_hypoStackColl)
,m_translationOptionList(StaticData::Instance().GetRuleLimit(), source)
{
}
ChartManager::~ChartManager()
{
clock_t end = clock();
float et = (end - m_start);
et /= (float)CLOCKS_PER_SEC;
VERBOSE(1, "Translation took " << et << " seconds" << endl);
}
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//! decode the sentence. This contains the main laps. Basically, the CKY++ algorithm
void ChartManager::ProcessSentence()
{
VERBOSE(1,"Translating: " << m_source << endl);
ResetSentenceStats(m_source);
VERBOSE(2,"Decoding: " << endl);
//ChartHypothesis::ResetHypoCount();
AddXmlChartOptions();
// MAIN LOOP
size_t size = m_source.GetSize();
for (size_t width = 1; width <= size; ++width) {
for (size_t startPos = 0; startPos <= size-width; ++startPos) {
size_t endPos = startPos + width - 1;
WordsRange range(startPos, endPos);
// create trans opt
m_translationOptionList.Clear();
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m_parser.Create(range, m_translationOptionList);
m_translationOptionList.ApplyThreshold();
const InputPath &inputPath = m_parser.GetInputPath(range);
m_translationOptionList.Evaluate(m_source, inputPath);
// decode
ChartCell &cell = m_hypoStackColl.Get(range);
cell.ProcessSentence(m_translationOptionList, m_hypoStackColl);
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m_translationOptionList.Clear();
cell.PruneToSize();
cell.CleanupArcList();
cell.SortHypotheses();
}
}
IFVERBOSE(1) {
for (size_t startPos = 0; startPos < size; ++startPos) {
cerr.width(3);
cerr << startPos << " ";
}
cerr << endl;
for (size_t width = 1; width <= size; width++) {
for( size_t space = 0; space < width-1; space++ ) {
cerr << " ";
}
for (size_t startPos = 0; startPos <= size-width; ++startPos) {
WordsRange range(startPos, startPos+width-1);
cerr.width(3);
cerr << m_hypoStackColl.Get(range).GetSize() << " ";
}
cerr << endl;
}
}
}
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/** add specific translation options and hypotheses according to the XML override translation scheme.
* Doesn't seem to do anything about walls and zones.
* @todo check walls & zones. Check that the implementation doesn't leak, xml options sometimes does if you're not careful
*/
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void ChartManager::AddXmlChartOptions()
{
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const StaticData &staticData = StaticData::Instance();
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const std::vector <ChartTranslationOptions*> xmlChartOptionsList = m_source.GetXmlChartTranslationOptions();
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IFVERBOSE(2) {
cerr << "AddXmlChartOptions " << xmlChartOptionsList.size() << endl;
}
if (xmlChartOptionsList.size() == 0) return;
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for(std::vector<ChartTranslationOptions*>::const_iterator i = xmlChartOptionsList.begin();
i != xmlChartOptionsList.end(); ++i) {
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ChartTranslationOptions* opt = *i;
const WordsRange &range = opt->GetSourceWordsRange();
RuleCubeItem* item = new RuleCubeItem( *opt, m_hypoStackColl );
ChartHypothesis* hypo = new ChartHypothesis(*opt, *item, *this);
hypo->Evaluate();
ChartCell &cell = m_hypoStackColl.Get(range);
cell.AddHypothesis(hypo);
}
}
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//! get best complete translation from the top chart cell.
const ChartHypothesis *ChartManager::GetBestHypothesis() const
{
size_t size = m_source.GetSize();
if (size == 0) // empty source
return NULL;
else {
WordsRange range(0, size-1);
const ChartCell &lastCell = m_hypoStackColl.Get(range);
return lastCell.GetBestHypothesis();
}
}
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/** Calculate the n-best paths through the output hypergraph.
* Return the list of paths with the variable ret
* \param count how may paths to return
* \param ret return argument
* \param onlyDistinct whether to check for distinct output sentence or not (default - don't check, just return top n-paths)
*/
void ChartManager::CalcNBest(size_t count, ChartTrellisPathList &ret,bool onlyDistinct) const
{
size_t size = m_source.GetSize();
if (count == 0 || size == 0)
return;
// Build a ChartTrellisPath for the 1-best path, if any.
WordsRange range(0, size-1);
const ChartCell &lastCell = m_hypoStackColl.Get(range);
const ChartHypothesis *hypo = lastCell.GetBestHypothesis();
if (hypo == NULL) {
// no hypothesis
return;
}
boost::shared_ptr<ChartTrellisPath> basePath(new ChartTrellisPath(*hypo));
// Add it to the n-best list.
if (count == 1) {
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ret.Add(basePath);
return;
}
// Set a limit on the number of detours to pop. If the n-best list is
// restricted to distinct translations then this limit should be bigger
// than n. The n-best factor determines how much bigger the limit should be.
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const StaticData &staticData = StaticData::Instance();
const size_t nBestFactor = staticData.GetNBestFactor();
size_t popLimit;
if (!onlyDistinct) {
popLimit = count-1;
} else if (nBestFactor == 0) {
// 0 = 'unlimited.' This actually sets a large-ish limit in case too many
// translations are identical.
popLimit = count * 1000;
} else {
popLimit = count * nBestFactor;
}
// Create an empty priority queue of detour objects. It is bounded to
// contain no more than popLimit items.
ChartTrellisDetourQueue contenders(popLimit);
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// Get all complete translations
const HypoList *topHypos = lastCell.GetAllSortedHypotheses();
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// Create a ChartTrellisDetour for each complete translation and add it to the queue
HypoList::const_iterator iter;
for (iter = topHypos->begin(); iter != topHypos->end(); ++iter) {
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const ChartHypothesis &hypo = **iter;
boost::shared_ptr<ChartTrellisPath> basePath(new ChartTrellisPath(hypo));
ChartTrellisDetour *detour = new ChartTrellisDetour(basePath, basePath->GetFinalNode(), hypo);
contenders.Push(detour);
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}
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delete topHypos;
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// Record the output phrase if distinct translations are required.
set<Phrase> distinctHyps;
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// MAIN loop
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for (size_t i = 0; ret.GetSize() < count && !contenders.Empty() && i < popLimit; ++i) {
// Get the best detour from the queue.
std::auto_ptr<const ChartTrellisDetour> detour(contenders.Pop());
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UTIL_THROW_IF2(detour.get() == NULL, "Empty detour");
// Create a full base path from the chosen detour.
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//basePath.reset(new ChartTrellisPath(*detour));
boost::shared_ptr<ChartTrellisPath> path(new ChartTrellisPath(*detour));
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// Generate new detours from this base path and add them to the queue of
// contenders. The new detours deviate from the base path by a single
// replacement along the previous detour sub-path.
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UTIL_THROW_IF2(path->GetDeviationPoint() == NULL, "Empty deviant path");
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CreateDeviantPaths(path, *(path->GetDeviationPoint()), contenders);
// If the n-best list is allowed to contain duplicate translations (at the
// surface level) then add the new path unconditionally, otherwise check
// whether the translation has seen before.
if (!onlyDistinct) {
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ret.Add(path);
} else {
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Phrase tgtPhrase = path->GetOutputPhrase();
if (distinctHyps.insert(tgtPhrase).second) {
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ret.Add(path);
}
}
}
}
void ChartManager::GetSearchGraph(long translationId, std::ostream &outputSearchGraphStream) const
{
size_t size = m_source.GetSize();
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// which hypotheses are reachable?
std::map<unsigned,bool> reachable;
WordsRange fullRange(0, size-1);
const ChartCell &lastCell = m_hypoStackColl.Get(fullRange);
const ChartHypothesis *hypo = lastCell.GetBestHypothesis();
if (hypo == NULL) {
// no hypothesis
return;
}
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FindReachableHypotheses( hypo, reachable);
for (size_t width = 1; width <= size; ++width) {
for (size_t startPos = 0; startPos <= size-width; ++startPos) {
size_t endPos = startPos + width - 1;
WordsRange range(startPos, endPos);
TRACE_ERR(" " << range << "=");
const ChartCell &cell = m_hypoStackColl.Get(range);
cell.GetSearchGraph(translationId, outputSearchGraphStream, reachable);
}
}
}
void ChartManager::FindReachableHypotheses( const ChartHypothesis *hypo, std::map<unsigned,bool> &reachable ) const
{
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// do not recurse, if already visited
if (reachable.find(hypo->GetId()) != reachable.end()) {
return;
}
// recurse
reachable[ hypo->GetId() ] = true;
const std::vector<const ChartHypothesis*> &previous = hypo->GetPrevHypos();
for(std::vector<const ChartHypothesis*>::const_iterator i = previous.begin(); i != previous.end(); ++i) {
FindReachableHypotheses( *i, reachable );
}
// also loop over recombined hypotheses (arcs)
const ChartArcList *arcList = hypo->GetArcList();
if (arcList) {
ChartArcList::const_iterator iterArc;
for (iterArc = arcList->begin(); iterArc != arcList->end(); ++iterArc) {
const ChartHypothesis &arc = **iterArc;
FindReachableHypotheses( &arc, reachable );
}
}
}
void ChartManager::CreateDeviantPaths(
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boost::shared_ptr<const ChartTrellisPath> basePath,
ChartTrellisDetourQueue &q)
{
CreateDeviantPaths(basePath, basePath->GetFinalNode(), q);
}
void ChartManager::CreateDeviantPaths(
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boost::shared_ptr<const ChartTrellisPath> basePath,
const ChartTrellisNode &substitutedNode,
ChartTrellisDetourQueue &queue)
{
const ChartArcList *arcList = substitutedNode.GetHypothesis().GetArcList();
if (arcList) {
for (ChartArcList::const_iterator iter = arcList->begin();
iter != arcList->end(); ++iter) {
const ChartHypothesis &replacement = **iter;
queue.Push(new ChartTrellisDetour(basePath, substitutedNode,
replacement));
}
}
// recusively create deviant paths for child nodes
const ChartTrellisNode::NodeChildren &children = substitutedNode.GetChildren();
ChartTrellisNode::NodeChildren::const_iterator iter;
for (iter = children.begin(); iter != children.end(); ++iter) {
const ChartTrellisNode &child = **iter;
CreateDeviantPaths(basePath, child, queue);
}
}
} // namespace Moses