/* * constituent_reorder_model.cc * * Created on: Jul 10, 2013 * Author: junhuili */ #include #include "alignment.h" #include "tree.h" #include "synutils.h" #include "tsuruoka_maxent.h" #include using namespace std; typedef std::unordered_map Map; typedef std::unordered_map::iterator Iterator; namespace po = boost::program_options; inline void fnPreparingTrainingdata(const char* pszFName, int iCutoff, const char* pszNewFName) { SFReader* pFReader = new STxtFileReader(pszFName); char* pszLine = new char[100001]; int iLen; Map hashPredicate; while (pFReader->fnReadNextLine(pszLine, &iLen)) { if (iLen == 0) continue; vector vecTerms; SplitOnWhitespace(string(pszLine), &vecTerms); for (size_t i = 0; i < vecTerms.size() - 1; i++) { Iterator iter = hashPredicate.find(vecTerms[i]); if (iter == hashPredicate.end()) { hashPredicate[vecTerms[i]] = 1; } else { iter->second++; } } } delete pFReader; pFReader = new STxtFileReader(pszFName); FILE* fpOut = fopen(pszNewFName, "w"); while (pFReader->fnReadNextLine(pszLine, &iLen)) { if (iLen == 0) continue; vector vecTerms; SplitOnWhitespace(string(pszLine), &vecTerms); ostringstream ostr; for (size_t i = 0; i < vecTerms.size() - 1; i++) { Iterator iter = hashPredicate.find(vecTerms[i]); assert(iter != hashPredicate.end()); if (iter->second >= iCutoff) { ostr << vecTerms[i] << " "; } } if (ostr.str().length() > 0) { ostr << vecTerms[vecTerms.size() - 1]; fprintf(fpOut, "%s\n", ostr.str().c_str()); } } fclose(fpOut); delete pFReader; delete[] pszLine; } struct SConstReorderTrainer { SConstReorderTrainer( const char* pszSynFname, // source-side flattened parse tree file name const char* pszAlignFname, // alignment filename const char* pszSourceFname, // source file name const char* pszTargetFname, // target file name const char* pszInstanceFname, // training instance file name const char* pszModelPrefix, // classifier model file name prefix int iClassifierType, // classifier type int iCutoff, // feature count threshold const char* pszOption // other classifier parameters (for svmlight) ) { fnGenerateInstanceFile(pszSynFname, pszAlignFname, pszSourceFname, pszTargetFname, pszInstanceFname); string strInstanceLeftFname = string(pszInstanceFname) + string(".left"); string strInstanceRightFname = string(pszInstanceFname) + string(".right"); string strModelLeftFname = string(pszModelPrefix) + string(".left"); string strModelRightFname = string(pszModelPrefix) + string(".right"); fprintf(stdout, "...Training the left ordering model\n"); fnTraining(strInstanceLeftFname.c_str(), strModelLeftFname.c_str(), iCutoff); fprintf(stdout, "...Training the right ordering model\n"); fnTraining(strInstanceRightFname.c_str(), strModelRightFname.c_str(), iCutoff); } ~SConstReorderTrainer() {} private: void fnTraining(const char* pszInstanceFname, const char* pszModelFname, int iCutoff) { char* pszNewInstanceFName = new char[strlen(pszInstanceFname) + 50]; if (iCutoff > 0) { sprintf(pszNewInstanceFName, "%s.tmp", pszInstanceFname); fnPreparingTrainingdata(pszInstanceFname, iCutoff, pszNewInstanceFName); } else { strcpy(pszNewInstanceFName, pszInstanceFname); } /*Zhangle_Maxent *pZhangleMaxent = new Zhangle_Maxent(NULL); pZhangleMaxent->fnTrain(pszInstanceFname, "lbfgs", pszModelFname, 100, 2.0); delete pZhangleMaxent;*/ Tsuruoka_Maxent* pMaxent = new Tsuruoka_Maxent(NULL); pMaxent->fnTrain(pszNewInstanceFName, "l1", pszModelFname, 300); delete pMaxent; if (strcmp(pszNewInstanceFName, pszInstanceFname) != 0) { sprintf(pszNewInstanceFName, "rm %s.tmp", pszInstanceFname); system(pszNewInstanceFName); } delete[] pszNewInstanceFName; } inline bool fnIsVerbPOS(const char* pszTerm) { if (strcmp(pszTerm, "VV") == 0 || strcmp(pszTerm, "VA") == 0 || strcmp(pszTerm, "VC") == 0 || strcmp(pszTerm, "VE") == 0) return true; return false; } inline void fnGetOutcome(int iL1, int iR1, int iL2, int iR2, const SAlignment* pAlign, string& strOutcome) { if (iL1 == -1 && iL2 == -1) strOutcome = "BU"; // 1. both are untranslated else if (iL1 == -1) strOutcome = "1U"; // 2. XP1 is untranslated else if (iL2 == -1) strOutcome = "2U"; // 3. XP2 is untranslated else if (iL1 == iL2 && iR2 == iR2) strOutcome = "SS"; // 4. Have same scope else if (iL1 <= iL2 && iR1 >= iR2) strOutcome = "1C2"; // 5. XP1's translation covers XP2's else if (iL1 >= iL2 && iR1 <= iR2) strOutcome = "2C1"; // 6. XP2's translation covers XP1's else if (iR1 < iL2) { int i = iR1 + 1; /*while (i < iL2) { if (pAlign->fnIsAligned(i, false)) break; i++; }*/ if (i == iL2) strOutcome = "M"; // 7. Monotone else strOutcome = "DM"; // 8. Discontinuous monotone } else if (iL1 < iL2 && iL2 <= iR1 && iR1 < iR2) strOutcome = "OM"; // 9. Overlap monotone else if (iR2 < iL1) { int i = iR2 + 1; /*while (i < iL1) { if (pAlign->fnIsAligned(i, false)) break; i++; }*/ if (i == iL1) strOutcome = "S"; // 10. Swap else strOutcome = "DS"; // 11. Discontinuous swap } else if (iL2 < iL1 && iL1 <= iR2 && iR2 < iR1) strOutcome = "OS"; // 12. Overlap swap else assert(false); } inline void fnGetOutcome(int i1, int i2, string& strOutcome) { assert(i1 != i2); if (i1 < i2) { if (i2 > i1 + 1) strOutcome = string("DM"); else strOutcome = string("M"); } else { if (i1 > i2 + 1) strOutcome = string("DS"); else strOutcome = string("S"); } } inline void fnGetRelativePosition(const vector& vecLeft, vector& vecPosition) { vecPosition.clear(); vector vec; for (size_t i = 0; i < vecLeft.size(); i++) { if (vecLeft[i] == -1) { if (i == 0) vec.push_back(-1); else vec.push_back(vecLeft[i - 1] + 0.1); } else vec.push_back(vecLeft[i]); } for (size_t i = 0; i < vecLeft.size(); i++) { int count = 0; for (size_t j = 0; j < vecLeft.size(); j++) { if (j == i) continue; if (vec[j] < vec[i]) { count++; } else if (vec[j] == vec[i] && j < i) { count++; } } vecPosition.push_back(count); } } /* * features: * f1: (left_label, right_label, parent_label) * f2: (left_label, right_label, parent_label, other_right_sibling_label) * f3: (left_label, right_label, parent_label, other_left_sibling_label) * f4: (left_label, right_label, left_head_pos) * f5: (left_label, right_label, left_head_word) * f6: (left_label, right_label, right_head_pos) * f7: (left_label, right_label, right_head_word) * f8: (left_label, right_label, left_chunk_status) * f9: (left_label, right_label, right_chunk_status) * f10: (left_label, parent_label) * f11: (right_label, parent_label) */ void fnGenerateInstance(const SParsedTree* pTree, const STreeItem* pParent, int iPos, const vector& vecChunkStatus, const vector& vecPosition, const vector& vecSTerms, const vector& vecTTerms, string& strOutcome, ostringstream& ostr) { STreeItem* pCon1, *pCon2; pCon1 = pParent->m_vecChildren[iPos - 1]; pCon2 = pParent->m_vecChildren[iPos]; fnGetOutcome(vecPosition[iPos - 1], vecPosition[iPos], strOutcome); string left_label = string(pCon1->m_pszTerm); string right_label = string(pCon2->m_pszTerm); string parent_label = string(pParent->m_pszTerm); vector vec_other_right_sibling; for (int i = iPos + 1; i < pParent->m_vecChildren.size(); i++) vec_other_right_sibling.push_back( string(pParent->m_vecChildren[i]->m_pszTerm)); if (vec_other_right_sibling.size() == 0) vec_other_right_sibling.push_back(string("NULL")); vector vec_other_left_sibling; for (int i = 0; i < iPos - 1; i++) vec_other_left_sibling.push_back( string(pParent->m_vecChildren[i]->m_pszTerm)); if (vec_other_left_sibling.size() == 0) vec_other_left_sibling.push_back(string("NULL")); // generate features // f1 ostr << "f1=" << left_label << "_" << right_label << "_" << parent_label; // f2 for (int i = 0; i < vec_other_right_sibling.size(); i++) ostr << " f2=" << left_label << "_" << right_label << "_" << parent_label << "_" << vec_other_right_sibling[i]; // f3 for (int i = 0; i < vec_other_left_sibling.size(); i++) ostr << " f3=" << left_label << "_" << right_label << "_" << parent_label << "_" << vec_other_left_sibling[i]; // f4 ostr << " f4=" << left_label << "_" << right_label << "_" << pTree->m_vecTerminals[pCon1->m_iHeadWord]->m_ptParent->m_pszTerm; // f5 ostr << " f5=" << left_label << "_" << right_label << "_" << vecSTerms[pCon1->m_iHeadWord]; // f6 ostr << " f6=" << left_label << "_" << right_label << "_" << pTree->m_vecTerminals[pCon2->m_iHeadWord]->m_ptParent->m_pszTerm; // f7 ostr << " f7=" << left_label << "_" << right_label << "_" << vecSTerms[pCon2->m_iHeadWord]; // f8 ostr << " f8=" << left_label << "_" << right_label << "_" << vecChunkStatus[iPos - 1]; // f9 ostr << " f9=" << left_label << "_" << right_label << "_" << vecChunkStatus[iPos]; // f10 ostr << " f10=" << left_label << "_" << parent_label; // f11 ostr << " f11=" << right_label << "_" << parent_label; } /* * Source side (11 features): * f1: the categories of XP1 and XP2 (f1_1, f1_2) * f2: the head words of XP1 and XP2 (f2_1, f2_2) * f3: the first and last word of XP1 (f3_f, f3_l) * f4: the first and last word of XP2 (f4_f, f4_l) * f5: is XP1 or XP2 the head node (f5_1, f5_2) * f6: the category of the common parent * Target side (6 features): * f7: the first and the last word of XP1's translation (f7_f, f7_l) * f8: the first and the last word of XP2's translation (f8_f, f8_l) * f9: the translation of XP1's and XP2's head word (f9_1, f9_2) */ void fnGenerateInstance(const SParsedTree* pTree, const STreeItem* pParent, const STreeItem* pCon1, const STreeItem* pCon2, const SAlignment* pAlign, const vector& vecSTerms, const vector& vecTTerms, string& strOutcome, ostringstream& ostr) { int iLeft1, iRight1, iLeft2, iRight2; pAlign->fnGetLeftRightMost(pCon1->m_iBegin, pCon1->m_iEnd, true, iLeft1, iRight1); pAlign->fnGetLeftRightMost(pCon2->m_iBegin, pCon2->m_iEnd, true, iLeft2, iRight2); fnGetOutcome(iLeft1, iRight1, iLeft2, iRight2, pAlign, strOutcome); // generate features // f1 ostr << "f1_1=" << pCon1->m_pszTerm << " f1_2=" << pCon2->m_pszTerm; // f2 ostr << " f2_1=" << vecSTerms[pCon1->m_iHeadWord] << " f2_2" << vecSTerms[pCon2->m_iHeadWord]; // f3 ostr << " f3_f=" << vecSTerms[pCon1->m_iBegin] << " f3_l=" << vecSTerms[pCon1->m_iEnd]; // f4 ostr << " f4_f=" << vecSTerms[pCon2->m_iBegin] << " f4_l=" << vecSTerms[pCon2->m_iEnd]; // f5 if (pParent->m_iHeadChild == pCon1->m_iBrotherIndex) ostr << " f5_1=1"; else ostr << " f5_1=0"; if (pParent->m_iHeadChild == pCon2->m_iBrotherIndex) ostr << " f5_2=1"; else ostr << " f5_2=0"; // f6 ostr << " f6=" << pParent->m_pszTerm; /*//f7 if (iLeft1 != -1) { ostr << " f7_f=" << vecTTerms[iLeft1] << " f7_l=" << vecTTerms[iRight1]; } if (iLeft2 != -1) { ostr << " f8_f=" << vecTTerms[iLeft2] << " f8_l=" << vecTTerms[iRight2]; } const vector* pvecTarget = pAlign->fnGetSingleWordAlign(pCon1->m_iHeadWord, true); string str = ""; for (size_t i = 0; pvecTarget != NULL && i < pvecTarget->size(); i++) { str += vecTTerms[(*pvecTarget)[i]] + "_"; } if (str.length() > 0) { ostr << " f9_1=" << str.substr(0, str.size()-1); } pvecTarget = pAlign->fnGetSingleWordAlign(pCon2->m_iHeadWord, true); str = ""; for (size_t i = 0; pvecTarget != NULL && i < pvecTarget->size(); i++) { str += vecTTerms[(*pvecTarget)[i]] + "_"; } if (str.length() > 0) { ostr << " f9_2=" << str.substr(0, str.size()-1); } */ } void fnGetFocusedParentNodes(const SParsedTree* pTree, vector& vecFocused) { for (size_t i = 0; i < pTree->m_vecTerminals.size(); i++) { STreeItem* pParent = pTree->m_vecTerminals[i]->m_ptParent; while (pParent != NULL) { // if (pParent->m_vecChildren.size() > 1 && pParent->m_iEnd - // pParent->m_iBegin > 5) { if (pParent->m_vecChildren.size() > 1) { // do constituent reordering for all children of pParent vecFocused.push_back(pParent); } if (pParent->m_iBrotherIndex != 0) break; pParent = pParent->m_ptParent; } } } void fnGenerateInstanceFile( const char* pszSynFname, // source-side flattened parse tree file name const char* pszAlignFname, // alignment filename const char* pszSourceFname, // source file name const char* pszTargetFname, // target file name const char* pszInstanceFname // training instance file name ) { SAlignmentReader* pAlignReader = new SAlignmentReader(pszAlignFname); SParseReader* pParseReader = new SParseReader(pszSynFname, false); STxtFileReader* pTxtSReader = new STxtFileReader(pszSourceFname); STxtFileReader* pTxtTReader = new STxtFileReader(pszTargetFname); string strInstanceLeftFname = string(pszInstanceFname) + string(".left"); string strInstanceRightFname = string(pszInstanceFname) + string(".right"); FILE* fpLeftOut = fopen(strInstanceLeftFname.c_str(), "w"); assert(fpLeftOut != NULL); FILE* fpRightOut = fopen(strInstanceRightFname.c_str(), "w"); assert(fpRightOut != NULL); // read sentence by sentence SAlignment* pAlign; SParsedTree* pTree; char* pszLine = new char[50001]; int iSentNum = 0; while ((pAlign = pAlignReader->fnReadNextAlignment()) != NULL) { pTree = pParseReader->fnReadNextParseTree(); assert(pTxtSReader->fnReadNextLine(pszLine, NULL)); vector vecSTerms; SplitOnWhitespace(string(pszLine), &vecSTerms); assert(pTxtTReader->fnReadNextLine(pszLine, NULL)); vector vecTTerms; SplitOnWhitespace(string(pszLine), &vecTTerms); if (pTree != NULL) { vector vecFocused; fnGetFocusedParentNodes(pTree, vecFocused); for (size_t i = 0; i < vecFocused.size(); i++) { STreeItem* pParent = vecFocused[i]; vector vecLeft, vecRight; for (size_t j = 0; j < pParent->m_vecChildren.size(); j++) { STreeItem* pCon1 = pParent->m_vecChildren[j]; int iLeft1, iRight1; pAlign->fnGetLeftRightMost(pCon1->m_iBegin, pCon1->m_iEnd, true, iLeft1, iRight1); vecLeft.push_back(iLeft1); vecRight.push_back(iRight1); } vector vecLeftPosition; fnGetRelativePosition(vecLeft, vecLeftPosition); vector vecRightPosition; fnGetRelativePosition(vecRight, vecRightPosition); vector vecChunkStatus; for (size_t j = 0; j < pParent->m_vecChildren.size(); j++) { string strOutcome = pAlign->fnIsContinuous(pParent->m_vecChildren[j]->m_iBegin, pParent->m_vecChildren[j]->m_iEnd); vecChunkStatus.push_back(strOutcome); } for (size_t j = 1; j < pParent->m_vecChildren.size(); j++) { // children[j-1] vs. children[j] reordering string strLeftOutcome; ostringstream ostr; fnGenerateInstance(pTree, pParent, j, vecChunkStatus, vecLeftPosition, vecSTerms, vecTTerms, strLeftOutcome, ostr); // fprintf(stderr, "%s %s\n", ostr.str().c_str(), // strLeftOutcome.c_str()); fprintf(fpLeftOut, "%s %s\n", ostr.str().c_str(), strLeftOutcome.c_str()); string strRightOutcome; fnGetOutcome(vecRightPosition[j - 1], vecRightPosition[j], strRightOutcome); fprintf(fpRightOut, "%s LeftOrder=%s %s\n", ostr.str().c_str(), strLeftOutcome.c_str(), strRightOutcome.c_str()); } } delete pTree; } delete pAlign; iSentNum++; if (iSentNum % 100000 == 0) fprintf(stderr, "#%d\n", iSentNum); } fclose(fpLeftOut); fclose(fpRightOut); delete pAlignReader; delete pParseReader; delete pTxtSReader; delete pTxtTReader; delete[] pszLine; } void fnGenerateInstanceFile2( const char* pszSynFname, // source-side flattened parse tree file name const char* pszAlignFname, // alignment filename const char* pszSourceFname, // source file name const char* pszTargetFname, // target file name const char* pszInstanceFname // training instance file name ) { SAlignmentReader* pAlignReader = new SAlignmentReader(pszAlignFname); SParseReader* pParseReader = new SParseReader(pszSynFname, false); STxtFileReader* pTxtSReader = new STxtFileReader(pszSourceFname); STxtFileReader* pTxtTReader = new STxtFileReader(pszTargetFname); FILE* fpOut = fopen(pszInstanceFname, "w"); assert(fpOut != NULL); // read sentence by sentence SAlignment* pAlign; SParsedTree* pTree; char* pszLine = new char[50001]; int iSentNum = 0; while ((pAlign = pAlignReader->fnReadNextAlignment()) != NULL) { pTree = pParseReader->fnReadNextParseTree(); assert(pTxtSReader->fnReadNextLine(pszLine, NULL)); vector vecSTerms; SplitOnWhitespace(string(pszLine), &vecSTerms); assert(pTxtTReader->fnReadNextLine(pszLine, NULL)); vector vecTTerms; SplitOnWhitespace(string(pszLine), &vecTTerms); if (pTree != NULL) { vector vecFocused; fnGetFocusedParentNodes(pTree, vecFocused); for (size_t i = 0; i < vecFocused.size() && pTree->m_vecTerminals.size() > 10; i++) { STreeItem* pParent = vecFocused[i]; for (size_t j = 1; j < pParent->m_vecChildren.size(); j++) { // children[j-1] vs. children[j] reordering string strOutcome; ostringstream ostr; fnGenerateInstance(pTree, pParent, pParent->m_vecChildren[j - 1], pParent->m_vecChildren[j], pAlign, vecSTerms, vecTTerms, strOutcome, ostr); // fprintf(stderr, "%s %s\n", ostr.str().c_str(), // strOutcome.c_str()); fprintf(fpOut, "%s %s\n", ostr.str().c_str(), strOutcome.c_str()); } } delete pTree; } delete pAlign; iSentNum++; if (iSentNum % 100000 == 0) fprintf(stderr, "#%d\n", iSentNum); } fclose(fpOut); delete pAlignReader; delete pParseReader; delete pTxtSReader; delete pTxtTReader; delete[] pszLine; } }; struct SConstContTrainer { SConstContTrainer( const char* pszFlattenedSynFname, // source-side flattened parse tree // file name const char* pszAlignFname, // alignment filename const char* pszSourceFname, // source file name const char* pszTargetFname, // target file name const char* pszInstanceFname, // training instance file name const char* pszModelPrefix, // classifier model file name prefix int iClassifierType, // classifier type int iCutoff, // feature count threshold const char* pszOption // other classifier parameters (for svmlight) ) { fnGenerateInstanceFile(pszFlattenedSynFname, pszAlignFname, pszSourceFname, pszTargetFname, pszInstanceFname); // fnTraining(pszInstanceFname, pszModelPrefix, iClassifierType, iCutoff, // pszOption); fnTraining(pszInstanceFname, pszModelPrefix, iCutoff); } ~SConstContTrainer() {} private: void fnTraining(const char* pszInstanceFname, const char* pszModelFname, int iCutoff) { char* pszNewInstanceFName = new char[strlen(pszInstanceFname) + 50]; if (iCutoff > 0) { sprintf(pszNewInstanceFName, "%s.tmp", pszInstanceFname); fnPreparingTrainingdata(pszInstanceFname, iCutoff, pszNewInstanceFName); } else { strcpy(pszNewInstanceFName, pszInstanceFname); } /*Zhangle_Maxent *pZhangleMaxent = new Zhangle_Maxent(NULL); pZhangleMaxent->fnTrain(pszInstanceFname, "lbfgs", pszModelFname, 100, 2.0); delete pZhangleMaxent;*/ Tsuruoka_Maxent* pMaxent = new Tsuruoka_Maxent(NULL); pMaxent->fnTrain(pszInstanceFname, "l1", pszModelFname, 300); delete pMaxent; if (strcmp(pszNewInstanceFName, pszInstanceFname) != 0) { sprintf(pszNewInstanceFName, "rm %s.tmp", pszInstanceFname); system(pszNewInstanceFName); } delete[] pszNewInstanceFName; } void fnGetFocusedParentNodes(const SParsedTree* pTree, vector& vecFocused) { for (size_t i = 0; i < pTree->m_vecTerminals.size(); i++) { STreeItem* pParent = pTree->m_vecTerminals[i]->m_ptParent; while (pParent != NULL) { // if (pParent->m_vecChildren.size() > 1 && pParent->m_iEnd - // pParent->m_iBegin > 5) { if (pParent->m_vecChildren.size() > 1) { // do constituent reordering for all children of pParent vecFocused.push_back(pParent); } if (pParent->m_iBrotherIndex != 0) break; pParent = pParent->m_ptParent; } } } inline void fnGetOutcome(int iL1, int iR1, const SAlignment* pAlign, string& strOutcome) { strOutcome = pAlign->fnIsContinuous(iL1, iR1); } inline string fnGetLengthType(int iLen) { if (iLen == 1) return string("1"); if (iLen == 2) return string("2"); if (iLen == 3) return string("3"); if (iLen < 6) return string("4"); if (iLen < 11) return string("6"); return string("11"); } /* * Source side (11 features): * f1: the syntactic category * f2: the syntactic category of its parent * f3: the head word's pos * f4: =1 if it's the head of its parent node * or * the head of its parent node * f5: length type */ void fnGenerateInstance(const SParsedTree* pTree, const STreeItem* pCon1, const SAlignment* pAlign, const vector& vecSTerms, const vector& vecTTerms, string& strOutcome, ostringstream& ostr) { fnGetOutcome(pCon1->m_iBegin, pCon1->m_iEnd, pAlign, strOutcome); // generate features // f1 ostr << "f1=" << pCon1->m_pszTerm; // f2 ostr << " f2=" << pCon1->m_ptParent->m_pszTerm; // f3 ostr << " f3=" << pTree->m_vecTerminals[pCon1->m_iHeadWord] ->m_ptParent->m_pszTerm; // f4 if (pCon1->m_iBrotherIndex == pCon1->m_ptParent->m_iHeadChild) { ostr << " f4=1"; } else { ostr << " f4=" << pCon1->m_ptParent->m_vecChildren[pCon1->m_ptParent->m_iHeadChild] ->m_pszTerm; } // f5 ostr << " f5=" << fnGetLengthType(pCon1->m_iEnd - pCon1->m_iBegin + 1); } void fnGenerateInstanceFile( const char* pszFlattenedSynFname, // source-side flattened parse tree // file name const char* pszAlignFname, // alignment filename const char* pszSourceFname, // source file name const char* pszTargetFname, // target file name const char* pszInstanceFname // training instance file name ) { SAlignmentReader* pAlignReader = new SAlignmentReader(pszAlignFname); SParseReader* pParseReader = new SParseReader(pszFlattenedSynFname, true); STxtFileReader* pTxtSReader = new STxtFileReader(pszSourceFname); STxtFileReader* pTxtTReader = new STxtFileReader(pszTargetFname); FILE* fpOut = fopen(pszInstanceFname, "w"); assert(fpOut != NULL); // read sentence by sentence SAlignment* pAlign; SParsedTree* pTree; char* pszLine = new char[50001]; int iSentNum = 0; while ((pAlign = pAlignReader->fnReadNextAlignment()) != NULL) { pTree = pParseReader->fnReadNextParseTree(); assert(pTree != NULL); assert(pTxtSReader->fnReadNextLine(pszLine, NULL)); vector vecSTerms; SplitOnWhitespace(string(pszLine), &vecSTerms); assert(pTxtTReader->fnReadNextLine(pszLine, NULL)); vector vecTTerms; SplitOnWhitespace(string(pszLine), &vecTTerms); vector vecFocused; fnGetFocusedParentNodes(pTree, vecFocused); for (size_t i = 0; i < vecFocused.size() && pTree->m_vecTerminals.size() > 10; i++) { STreeItem* pParent = vecFocused[i]; for (size_t j = 0; j < pParent->m_vecChildren.size(); j++) { // children[j-1] vs. children[j] reordering string strOutcome; ostringstream ostr; fnGenerateInstance(pTree, pParent->m_vecChildren[j], pAlign, vecSTerms, vecTTerms, strOutcome, ostr); // fprintf(stderr, "%s %s\n", ostr.str().c_str(), strOutcome.c_str()); fprintf(fpOut, "%s %s\n", ostr.str().c_str(), strOutcome.c_str()); } } delete pAlign; delete pTree; iSentNum++; if (iSentNum % 100000 == 0) fprintf(stderr, "#%d\n", iSentNum); } fclose(fpOut); delete pAlignReader; delete pParseReader; delete pTxtSReader; delete pTxtTReader; delete[] pszLine; } }; inline void print_options(std::ostream& out, po::options_description const& opts) { typedef std::vector > Ds; Ds const& ds = opts.options(); out << '"'; for (unsigned i = 0; i < ds.size(); ++i) { if (i) out << ' '; out << "--" << ds[i]->long_name(); } out << '\n'; } inline string str(char const* name, po::variables_map const& conf) { return conf[name].as(); } //--parse_file /scratch0/mt_exp/gq-ctb/data/train.srl.cn --align_file ///scratch0/mt_exp/gq-ctb/data/aligned.grow-diag-final-and --source_file ///scratch0/mt_exp/gq-ctb/data/train.cn --target_file ///scratch0/mt_exp/gq-ctb/data/train.en --instance_file ///scratch0/mt_exp/gq-ctb/data/srl-instance --model_prefix ///scratch0/mt_exp/gq-ctb/data/srl-instance --feature_cutoff 10 //--classifier_type 1 int main(int argc, char** argv) { po::options_description opts("Configuration options"); opts.add_options()("parse_file", po::value(), "parse file path (input)")( "align_file", po::value(), "Alignment file path (input)")( "source_file", po::value(), "Source text file path (input)")( "target_file", po::value(), "Target text file path (input)")( "instance_file", po::value(), "Instance file path (output)")( "model_prefix", po::value(), "Model file path prefix (output): three files will be generated")( "classifier_type", po::value()->default_value(1), "Classifier type: 1 for openNLP maxent; 2 for Zhangle maxent; and 3 for " "SVMLight")("feature_cutoff", po::value()->default_value(100), "Feature cutoff threshold")( "svm_option", po::value(), "Parameters for SVMLight classifier")( "help", "produce help message"); po::variables_map vm; if (argc) { po::store(po::parse_command_line(argc, argv, opts), vm); po::notify(vm); } if (vm.count("help")) { print_options(cout, opts); return 1; } if (!vm.count("parse_file") || !vm.count("align_file") || !vm.count("source_file") || !vm.count("target_file") || !vm.count("instance_file") || !vm.count("model_prefix")) { print_options(cout, opts); if (!vm.count("parse_file")) cout << "--parse_file NOT FOUND\n"; if (!vm.count("align_file")) cout << "--align_file NOT FOUND\n"; if (!vm.count("source_file")) cout << "--source_file NOT FOUND\n"; if (!vm.count("target_file")) cout << "--target_file NOT FOUND\n"; if (!vm.count("instance_file")) cout << "--instance_file NOT FOUND\n"; if (!vm.count("model_prefix")) cout << "--model_prefix NOT FOUND\n"; exit(0); } const char* pOption; if (vm.count("svm_option")) pOption = str("svm_option", vm).c_str(); else pOption = NULL; SConstReorderTrainer* pTrainer = new SConstReorderTrainer( str("parse_file", vm).c_str(), str("align_file", vm).c_str(), str("source_file", vm).c_str(), str("target_file", vm).c_str(), str("instance_file", vm).c_str(), str("model_prefix", vm).c_str(), vm["classifier_type"].as(), vm["feature_cutoff"].as(), pOption); delete pTrainer; return 1; }