#include "ns_ter.h" #include #include #include #include #ifndef HAVE_OLD_CPP # include #else # include namespace std { using std::tr1::unordered_map; } #endif #include #include #include "tdict.h" static const bool ter_use_average_ref_len = true; static const int ter_short_circuit_long_sentences = -1; static const unsigned kINSERTIONS = 0; static const unsigned kDELETIONS = 1; static const unsigned kSUBSTITUTIONS = 2; static const unsigned kSHIFTS = 3; static const unsigned kREF_WORDCOUNT = 4; static const unsigned kDUMMY_LAST_ENTRY = 5; using namespace std; bool TERMetric::IsErrorMetric() const { return true; } namespace NewScorer { struct COSTS { static const float substitution; static const float deletion; static const float insertion; static const float shift; }; const float COSTS::substitution = 1.0f; const float COSTS::deletion = 1.0f; const float COSTS::insertion = 1.0f; const float COSTS::shift = 1.0f; static const int MAX_SHIFT_SIZE = 10; static const int MAX_SHIFT_DIST = 50; struct Shift { unsigned int d_; Shift() : d_() {} Shift(int b, int e, int m) : d_() { begin(b); end(e); moveto(m); } inline int begin() const { return d_ & 0x3ff; } inline int end() const { return (d_ >> 10) & 0x3ff; } inline int moveto() const { int m = (d_ >> 20) & 0x7ff; if (m > 1024) { m -= 1024; m *= -1; } return m; } inline void begin(int b) { d_ &= 0xfffffc00u; d_ |= (b & 0x3ff); } inline void end(int e) { d_ &= 0xfff003ffu; d_ |= (e & 0x3ff) << 10; } inline void moveto(int m) { bool neg = (m < 0); if (neg) { m *= -1; m += 1024; } d_ &= 0xfffff; d_ |= (m & 0x7ff) << 20; } }; class TERScorerImpl { public: enum TransType { MATCH, SUBSTITUTION, INSERTION, DELETION }; explicit TERScorerImpl(const vector& ref) : ref_(ref) { for (unsigned i = 0; i < ref.size(); ++i) rwexists_.insert(ref[i]); } float Calculate(const vector& hyp, int* subs, int* ins, int* dels, int* shifts) const { return CalculateAllShifts(hyp, subs, ins, dels, shifts); } inline int GetRefLength() const { return ref_.size(); } private: const vector& ref_; set rwexists_; typedef unordered_map, set, boost::hash > > NgramToIntsMap; mutable NgramToIntsMap nmap_; static float MinimumEditDistance( const vector& hyp, const vector& ref, vector* path) { vector > bmat(hyp.size() + 1, vector(ref.size() + 1, MATCH)); vector > cmat(hyp.size() + 1, vector(ref.size() + 1, 0)); for (int i = 0; i <= hyp.size(); ++i) cmat[i][0] = i; for (int j = 0; j <= ref.size(); ++j) cmat[0][j] = j; for (int i = 1; i <= hyp.size(); ++i) { const WordID& hw = hyp[i-1]; for (int j = 1; j <= ref.size(); ++j) { const WordID& rw = ref[j-1]; float& cur_c = cmat[i][j]; TransType& cur_b = bmat[i][j]; if (rw == hw) { cur_c = cmat[i-1][j-1]; cur_b = MATCH; } else { cur_c = cmat[i-1][j-1] + COSTS::substitution; cur_b = SUBSTITUTION; } float cwoi = cmat[i-1][j]; if (cur_c > cwoi + COSTS::insertion) { cur_c = cwoi + COSTS::insertion; cur_b = INSERTION; } float cwod = cmat[i][j-1]; if (cur_c > cwod + COSTS::deletion) { cur_c = cwod + COSTS::deletion; cur_b = DELETION; } } } // trace back along the best path and record the transition types path->clear(); int i = hyp.size(); int j = ref.size(); while (i > 0 || j > 0) { if (j == 0) { --i; path->push_back(INSERTION); } else if (i == 0) { --j; path->push_back(DELETION); } else { TransType t = bmat[i][j]; path->push_back(t); switch (t) { case SUBSTITUTION: case MATCH: --i; --j; break; case INSERTION: --i; break; case DELETION: --j; break; } } } reverse(path->begin(), path->end()); return cmat[hyp.size()][ref.size()]; } void BuildWordMatches(const vector& hyp, NgramToIntsMap* nmap) const { nmap->clear(); set exists_both; for (int i = 0; i < hyp.size(); ++i) if (rwexists_.find(hyp[i]) != rwexists_.end()) exists_both.insert(hyp[i]); for (int start=0; start cp; int mlen = min(MAX_SHIFT_SIZE, static_cast(ref_.size() - start)); for (int len=0; len& in, int start, int end, int moveto, vector* out) { // cerr << "ps: " << start << " " << end << " " << moveto << endl; out->clear(); if (moveto == -1) { for (int i = start; i <= end; ++i) out->push_back(in[i]); for (int i = 0; i < start; ++i) out->push_back(in[i]); for (int i = end+1; i < in.size(); ++i) out->push_back(in[i]); } else if (moveto < start) { for (int i = 0; i <= moveto; ++i) out->push_back(in[i]); for (int i = start; i <= end; ++i) out->push_back(in[i]); for (int i = moveto+1; i < start; ++i) out->push_back(in[i]); for (int i = end+1; i < in.size(); ++i) out->push_back(in[i]); } else if (moveto > end) { for (int i = 0; i < start; ++i) out->push_back(in[i]); for (int i = end+1; i <= moveto; ++i) out->push_back(in[i]); for (int i = start; i <= end; ++i) out->push_back(in[i]); for (int i = moveto+1; i < in.size(); ++i) out->push_back(in[i]); } else { for (int i = 0; i < start; ++i) out->push_back(in[i]); for (int i = end+1; (i < in.size()) && (i <= end + (moveto - start)); ++i) out->push_back(in[i]); for (int i = start; i <= end; ++i) out->push_back(in[i]); for (int i = (end + (moveto - start))+1; i < in.size(); ++i) out->push_back(in[i]); } if (out->size() != in.size()) { cerr << "ps: " << start << " " << end << " " << moveto << endl; cerr << "in=" << TD::GetString(in) << endl; cerr << "out=" << TD::GetString(*out) << endl; } assert(out->size() == in.size()); // cerr << "ps: " << TD::GetString(*out) << endl; } void GetAllPossibleShifts(const vector& hyp, const vector& ralign, const vector& herr, const vector& rerr, const int min_size, vector >* shifts) const { for (int start = 0; start < hyp.size(); ++start) { vector cp(1, hyp[start]); NgramToIntsMap::iterator niter = nmap_.find(cp); if (niter == nmap_.end()) continue; bool ok = false; int moveto; for (set::iterator i = niter->second.begin(); i != niter->second.end(); ++i) { moveto = *i; int rm = ralign[moveto]; ok = (start != rm && (rm - start) < MAX_SHIFT_DIST && (start - rm - 1) < MAX_SHIFT_DIST); if (ok) break; } if (!ok) continue; cp.clear(); for (int end = start + min_size - 1; ok && end < hyp.size() && end < (start + MAX_SHIFT_SIZE); ++end) { cp.push_back(hyp[end]); vector& sshifts = (*shifts)[end - start]; ok = false; NgramToIntsMap::iterator niter = nmap_.find(cp); if (niter == nmap_.end()) break; bool any_herr = false; for (int i = start; i <= end && !any_herr; ++i) any_herr = herr[i]; if (!any_herr) { ok = true; continue; } for (set::iterator mi = niter->second.begin(); mi != niter->second.end(); ++mi) { int moveto = *mi; int rm = ralign[moveto]; if (! ((rm != start) && ((rm < start) || (rm > end)) && (rm - start <= MAX_SHIFT_DIST) && ((start - rm - 1) <= MAX_SHIFT_DIST))) continue; ok = true; bool any_rerr = false; for (int i = 0; (i <= end - start) && (!any_rerr); ++i) any_rerr = rerr[moveto+i]; if (!any_rerr) continue; for (int roff = 0; roff <= (end - start); ++roff) { int rmr = ralign[moveto+roff]; if ((start != rmr) && ((roff == 0) || (rmr != ralign[moveto]))) sshifts.push_back(Shift(start, end, moveto + roff)); } } } } } bool CalculateBestShift(const vector& cur, const vector& /*hyp*/, float curerr, const vector& path, vector* new_hyp, float* newerr, vector* new_path) const { vector herr, rerr; vector ralign; int hpos = -1; for (int i = 0; i < path.size(); ++i) { switch (path[i]) { case MATCH: ++hpos; herr.push_back(false); rerr.push_back(false); ralign.push_back(hpos); break; case SUBSTITUTION: ++hpos; herr.push_back(true); rerr.push_back(true); ralign.push_back(hpos); break; case INSERTION: ++hpos; herr.push_back(true); break; case DELETION: rerr.push_back(true); ralign.push_back(hpos); break; } } #if 0 cerr << "RALIGN: "; for (int i = 0; i < rerr.size(); ++i) cerr << ralign[i] << " "; cerr << endl; cerr << "RERR: "; for (int i = 0; i < rerr.size(); ++i) cerr << (bool)rerr[i] << " "; cerr << endl; cerr << "HERR: "; for (int i = 0; i < herr.size(); ++i) cerr << (bool)herr[i] << " "; cerr << endl; #endif vector > shifts(MAX_SHIFT_SIZE + 1); GetAllPossibleShifts(cur, ralign, herr, rerr, 1, &shifts); float cur_best_shift_cost = 0; *newerr = curerr; vector cur_best_path; vector cur_best_hyp; bool res = false; for (int i = shifts.size() - 1; i >=0; --i) { float curfix = curerr - (cur_best_shift_cost + *newerr); float maxfix = 2.0f * (1 + i) - COSTS::shift; if ((curfix > maxfix) || ((cur_best_shift_cost == 0) && (curfix == maxfix))) break; for (int j = 0; j < shifts[i].size(); ++j) { const Shift& s = shifts[i][j]; curfix = curerr - (cur_best_shift_cost + *newerr); maxfix = 2.0f * (1 + i) - COSTS::shift; // TODO remove? if ((curfix > maxfix) || ((cur_best_shift_cost == 0) && (curfix == maxfix))) continue; vector shifted(cur.size()); PerformShift(cur, s.begin(), s.end(), ralign[s.moveto()], &shifted); vector try_path; float try_cost = MinimumEditDistance(shifted, ref_, &try_path); float gain = (*newerr + cur_best_shift_cost) - (try_cost + COSTS::shift); if (gain > 0.0f || ((cur_best_shift_cost == 0.0f) && (gain == 0.0f))) { *newerr = try_cost; cur_best_shift_cost = COSTS::shift; new_path->swap(try_path); new_hyp->swap(shifted); res = true; // cerr << "Found better shift " << s.begin() << "..." << s.end() << " moveto " << s.moveto() << endl; } } } return res; } static void GetPathStats(const vector& path, int* subs, int* ins, int* dels) { *subs = *ins = *dels = 0; for (int i = 0; i < path.size(); ++i) { switch (path[i]) { case SUBSTITUTION: ++(*subs); case MATCH: break; case INSERTION: ++(*ins); break; case DELETION: ++(*dels); break; } } } float CalculateAllShifts(const vector& hyp, int* subs, int* ins, int* dels, int* shifts) const { BuildWordMatches(hyp, &nmap_); vector path; float med_cost = MinimumEditDistance(hyp, ref_, &path); float edits = 0; vector cur = hyp; *shifts = 0; if (ter_short_circuit_long_sentences < 0 || ref_.size() < ter_short_circuit_long_sentences) { while (true) { vector new_hyp; vector new_path; float new_med_cost; if (!CalculateBestShift(cur, hyp, med_cost, path, &new_hyp, &new_med_cost, &new_path)) break; edits += COSTS::shift; ++(*shifts); med_cost = new_med_cost; path.swap(new_path); cur.swap(new_hyp); } } GetPathStats(path, subs, ins, dels); return med_cost + edits; } }; #if 0 void TERScore::ScoreDetails(std::string* details) const { char buf[200]; sprintf(buf, "TER = %.2f, %3d|%3d|%3d|%3d (len=%d)", ComputeScore() * 100.0f, stats[kINSERTIONS], stats[kDELETIONS], stats[kSUBSTITUTIONS], stats[kSHIFTS], stats[kREF_WORDCOUNT]); *details = buf; } #endif } // namespace NewScorer void TERMetric::ComputeSufficientStatistics(const vector& hyp, const vector >& refs, SufficientStats* out) const { out->fields.resize(kDUMMY_LAST_ENTRY); float best_score = numeric_limits::max(); unsigned avg_len = 0; for (int i = 0; i < refs.size(); ++i) avg_len += refs[i].size(); avg_len /= refs.size(); for (int i = 0; i < refs.size(); ++i) { int subs, ins, dels, shifts; NewScorer::TERScorerImpl ter(refs[i]); float score = ter.Calculate(hyp, &subs, &ins, &dels, &shifts); // cerr << "Component TER cost: " << score << endl; if (score < best_score) { out->fields[kINSERTIONS] = ins; out->fields[kDELETIONS] = dels; out->fields[kSUBSTITUTIONS] = subs; out->fields[kSHIFTS] = shifts; if (ter_use_average_ref_len) { out->fields[kREF_WORDCOUNT] = avg_len; } else { out->fields[kREF_WORDCOUNT] = refs[i].size(); } best_score = score; } } } unsigned TERMetric::SufficientStatisticsVectorSize() const { return kDUMMY_LAST_ENTRY; } float TERMetric::ComputeScore(const SufficientStats& stats) const { float edits = static_cast(stats[kINSERTIONS] + stats[kDELETIONS] + stats[kSUBSTITUTIONS] + stats[kSHIFTS]); return edits / static_cast(stats[kREF_WORDCOUNT]); } string TERMetric::DetailedScore(const SufficientStats& stats) const { char buf[200]; sprintf(buf, "TER = %.2f, %3.f|%3.f|%3.f|%3.f (len=%3.f)", ComputeScore(stats) * 100.0f, stats[kINSERTIONS], stats[kDELETIONS], stats[kSUBSTITUTIONS], stats[kSHIFTS], stats[kREF_WORDCOUNT]); return buf; }