// $Id$
// vim:tabstop=2

/***********************************************************************
Moses - factored phrase-based language decoder
Copyright (C) 2006 University of Edinburgh

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
***********************************************************************/

#ifndef moses_Hypothesis_h
#define moses_Hypothesis_h

#include <iostream>
#include <memory>
#include <vector>
#include "Phrase.h"
#include "TypeDef.h"
#include "WordsBitmap.h"
#include "Sentence.h"
#include "Phrase.h"
#include "GenerationDictionary.h"
#include "ScoreComponentCollection.h"
#include "InputType.h"
#include "ObjectPool.h"

namespace Moses
{

class SquareMatrix;
class StaticData;
class TranslationOption;
class WordsRange;
class Hypothesis;
class FFState;
class StatelessFeatureFunction;
class StatefulFeatureFunction;
class Manager;

typedef std::vector<Hypothesis*> ArcList;

/** Used to store a state in the beam search
    for the best translation. With its link back to the previous hypothesis
    m_prevHypo, we can trace back to the sentence start to read of the
    (partial) translation to this point.

		The expansion of hypotheses is handled in the class Manager, which
    stores active hypothesis in the search in hypothesis stacks.
***/
class Hypothesis
{
  friend std::ostream& operator<<(std::ostream&, const Hypothesis&);

protected:
  static ObjectPool<Hypothesis> s_objectPool;

  const Hypothesis* m_prevHypo; /*! backpointer to previous hypothesis (from which this one was created) */
//	const Phrase			&m_targetPhrase; /*! target phrase being created at the current decoding step */
  WordsBitmap				m_sourceCompleted; /*! keeps track of which words have been translated so far */
  //TODO: how to integrate this into confusion network framework; what if
  //it's a confusion network in the end???
  InputType const&  m_sourceInput;
  WordsRange				m_currSourceWordsRange; /*! source word positions of the last phrase that was used to create this hypothesis */
  WordsRange        m_currTargetWordsRange; /*! target word positions of the last phrase that was used to create this hypothesis */
  bool							m_wordDeleted;
  float							m_totalScore;  /*! score so far */
  float							m_futureScore; /*! estimated future cost to translate rest of sentence */
  ScoreComponentCollection m_scoreBreakdown; /*! scores for this hypothesis */
  std::vector<const FFState*> m_ffStates;
  const Hypothesis 	*m_winningHypo;
  ArcList 					*m_arcList; /*! all arcs that end at the same trellis point as this hypothesis */
  const TranslationOption &m_transOpt;
  Manager& m_manager;

  int m_id; /*! numeric ID of this hypothesis, used for logging */

  /*! used by initial seeding of the translation process */
  Hypothesis(Manager& manager, InputType const& source, const TranslationOption &initialTransOpt);
  /*! used when creating a new hypothesis using a translation option (phrase translation) */
  Hypothesis(const Hypothesis &prevHypo, const TranslationOption &transOpt);

public:
  static ObjectPool<Hypothesis> &GetObjectPool() {
    return s_objectPool;
  }

  ~Hypothesis();

  /** return the subclass of Hypothesis most appropriate to the given translation option */
  static Hypothesis* Create(const Hypothesis &prevHypo, const TranslationOption &transOpt);

  static Hypothesis* Create(Manager& manager, const WordsBitmap &initialCoverage);

  /** return the subclass of Hypothesis most appropriate to the given target phrase */
  static Hypothesis* Create(Manager& manager, InputType const& source, const TranslationOption &initialTransOpt);

  /** return the subclass of Hypothesis most appropriate to the given translation option */
  Hypothesis* CreateNext(const TranslationOption &transOpt) const;

  void PrintHypothesis() const;

  const InputType& GetInput() const {
    return m_sourceInput;
  }

  /** return target phrase used to create this hypothesis */
//	const Phrase &GetCurrTargetPhrase() const
  const TargetPhrase &GetCurrTargetPhrase() const;

  /** return input positions covered by the translation option (phrasal translation) used to create this hypothesis */
  inline const WordsRange &GetCurrSourceWordsRange() const {
    return m_currSourceWordsRange;
  }

  inline const WordsRange &GetCurrTargetWordsRange() const {
    return m_currTargetWordsRange;
  }

  Manager& GetManager() const {
    return m_manager;
  }

  /** output length of the translation option used to create this hypothesis */
  inline size_t GetCurrTargetLength() const {
    return m_currTargetWordsRange.GetNumWordsCovered();
  }

  void Evaluate(const SquareMatrix &futureScore);

  int GetId()const {
    return m_id;
  }

  const Hypothesis* GetPrevHypo() const;

  /** length of the partial translation (from the start of the sentence) */
  inline size_t GetSize() const {
    return m_currTargetWordsRange.GetEndPos() + 1;
  }

  std::string GetSourcePhraseStringRep(const std::vector<FactorType> factorsToPrint) const;
  std::string GetTargetPhraseStringRep(const std::vector<FactorType> factorsToPrint) const;
  std::string GetSourcePhraseStringRep() const;
  std::string GetTargetPhraseStringRep() const;

  /** curr - pos is relative from CURRENT hypothesis's starting index
   * (ie, start of sentence would be some negative number, which is
   * not allowed- USE WITH CAUTION) */
  inline const Word &GetCurrWord(size_t pos) const {
    return GetCurrTargetPhrase().GetWord(pos);
  }
  inline const Factor *GetCurrFactor(size_t pos, FactorType factorType) const {
    return GetCurrTargetPhrase().GetFactor(pos, factorType);
  }
  /** recursive - pos is relative from start of sentence */
  inline const Word &GetWord(size_t pos) const {
    const Hypothesis *hypo = this;
    while (pos < hypo->GetCurrTargetWordsRange().GetStartPos()) {
      hypo = hypo->GetPrevHypo();
      UTIL_THROW_IF2(hypo == NULL, "Previous hypothesis should not be NULL");
    }
    return hypo->GetCurrWord(pos - hypo->GetCurrTargetWordsRange().GetStartPos());
  }
  inline const Factor* GetFactor(size_t pos, FactorType factorType) const {
    return GetWord(pos)[factorType];
  }

  /***
   * \return The bitmap of source words we cover
   */
  inline const WordsBitmap &GetWordsBitmap() const {
    return m_sourceCompleted;
  }

  inline bool IsSourceCompleted() const {
    return m_sourceCompleted.IsComplete();
  }

  int RecombineCompare(const Hypothesis &compare) const;

  void GetOutputPhrase(Phrase &out) const;

  void ToStream(std::ostream& out) const {
    Phrase ret;
    GetOutputPhrase(ret);
    out << ret;
  }

  void ToStringStream(std::stringstream& out) const {
    if (m_prevHypo != NULL) {
      m_prevHypo->ToStream(out);
    }
    out << (Phrase) GetCurrTargetPhrase();
  }

  std::string GetOutputString() const {
    std::stringstream out;
    ToStringStream(out);
    return out.str();
  }

  TO_STRING();

  inline void SetWinningHypo(const Hypothesis *hypo) {
    m_winningHypo = hypo;
  }
  inline const Hypothesis *GetWinningHypo() const {
    return m_winningHypo;
  }

  void AddArc(Hypothesis *loserHypo);
  void CleanupArcList();

  //! returns a list alternative previous hypotheses (or NULL if n-best support is disabled)
  inline const ArcList* GetArcList() const {
    return m_arcList;
  }
  const ScoreComponentCollection& GetScoreBreakdown() const {
    return m_scoreBreakdown;
  }
  float GetTotalScore() const {
    return m_totalScore;
  }
  float GetScore() const {
    return m_totalScore-m_futureScore;
  }
  const FFState* GetFFState(int idx) const {
    return m_ffStates[idx];
  }
  void SetFFState(int idx, FFState* state) {
    m_ffStates[idx] = state;
  }

  // Added by oliver.wilson@ed.ac.uk for async lm stuff.
  void EvaluateWith(const StatefulFeatureFunction &sfff, int state_idx);
  void EvaluateWith(const StatelessFeatureFunction &slff);

  //! target span that trans opt would populate if applied to this hypo. Used for alignment check
  size_t GetNextStartPos(const TranslationOption &transOpt) const;

  std::vector<std::vector<unsigned int> > *GetLMStats() const {
    return NULL;
  }

  const TranslationOption &GetTranslationOption() const {
    return m_transOpt;
  }
};

std::ostream& operator<<(std::ostream& out, const Hypothesis& hypothesis);

// sorting helper
struct CompareHypothesisTotalScore {
  bool operator()(const Hypothesis* hypo1, const Hypothesis* hypo2) const {
    return hypo1->GetTotalScore() > hypo2->GetTotalScore();
  }
};

#ifdef USE_HYPO_POOL

#define FREEHYPO(hypo) \
{ \
	ObjectPool<Hypothesis> &pool = Hypothesis::GetObjectPool(); \
	pool.freeObject(hypo); \
} \
 
#else
#define FREEHYPO(hypo) delete hypo
#endif

/** defines less-than relation on hypotheses.
* The particular order is not important for us, we need just to figure out
* which hypothesis are equal based on:
*   the last n-1 target words are the same
*   and the covers (source words translated) are the same
* Directly using RecombineCompare is unreliable because the Compare methods
* of some states are based on archictecture-dependent pointer comparisons.
* That's why we use the hypothesis IDs instead.
*/
class HypothesisRecombinationOrderer
{
public:
  bool operator()(const Hypothesis* hypoA, const Hypothesis* hypoB) const {
    return (hypoA->RecombineCompare(*hypoB) < 0);
  }
};

}
#endif