1 //===- CodeGenMapTable.cpp - Instruction Mapping Table Generator ----------===// 2 // 3 // The LLVM Compiler Infrastructure 4 // 5 // This file is distributed under the University of Illinois Open Source 6 // License. See LICENSE.TXT for details. 7 // 8 //===----------------------------------------------------------------------===// 9 // CodeGenMapTable provides functionality for the TabelGen to create 10 // relation mapping between instructions. Relation models are defined using 11 // InstrMapping as a base class. This file implements the functionality which 12 // parses these definitions and generates relation maps using the information 13 // specified there. These maps are emitted as tables in the XXXGenInstrInfo.inc 14 // file along with the functions to query them. 15 // 16 // A relationship model to relate non-predicate instructions with their 17 // predicated true/false forms can be defined as follows: 18 // 19 // def getPredOpcode : InstrMapping { 20 // let FilterClass = "PredRel"; 21 // let RowFields = ["BaseOpcode"]; 22 // let ColFields = ["PredSense"]; 23 // let KeyCol = ["none"]; 24 // let ValueCols = [["true"], ["false"]]; } 25 // 26 // CodeGenMapTable parses this map and generates a table in XXXGenInstrInfo.inc 27 // file that contains the instructions modeling this relationship. This table 28 // is defined in the function 29 // "int getPredOpcode(uint16_t Opcode, enum PredSense inPredSense)" 30 // that can be used to retrieve the predicated form of the instruction by 31 // passing its opcode value and the predicate sense (true/false) of the desired 32 // instruction as arguments. 33 // 34 // Short description of the algorithm: 35 // 36 // 1) Iterate through all the records that derive from "InstrMapping" class. 37 // 2) For each record, filter out instructions based on the FilterClass value. 38 // 3) Iterate through this set of instructions and insert them into 39 // RowInstrMap map based on their RowFields values. RowInstrMap is keyed by the 40 // vector of RowFields values and contains vectors of Records (instructions) as 41 // values. RowFields is a list of fields that are required to have the same 42 // values for all the instructions appearing in the same row of the relation 43 // table. All the instructions in a given row of the relation table have some 44 // sort of relationship with the key instruction defined by the corresponding 45 // relationship model. 46 // 47 // Ex: RowInstrMap(RowVal1, RowVal2, ...) -> [Instr1, Instr2, Instr3, ... ] 48 // Here Instr1, Instr2, Instr3 have same values (RowVal1, RowVal2) for 49 // RowFields. These groups of instructions are later matched against ValueCols 50 // to determine the column they belong to, if any. 51 // 52 // While building the RowInstrMap map, collect all the key instructions in 53 // KeyInstrVec. These are the instructions having the same values as KeyCol 54 // for all the fields listed in ColFields. 55 // 56 // For Example: 57 // 58 // Relate non-predicate instructions with their predicated true/false forms. 59 // 60 // def getPredOpcode : InstrMapping { 61 // let FilterClass = "PredRel"; 62 // let RowFields = ["BaseOpcode"]; 63 // let ColFields = ["PredSense"]; 64 // let KeyCol = ["none"]; 65 // let ValueCols = [["true"], ["false"]]; } 66 // 67 // Here, only instructions that have "none" as PredSense will be selected as key 68 // instructions. 69 // 70 // 4) For each key instruction, get the group of instructions that share the 71 // same key-value as the key instruction from RowInstrMap. Iterate over the list 72 // of columns in ValueCols (it is defined as a list<list<string> >. Therefore, 73 // it can specify multi-column relationships). For each column, find the 74 // instruction from the group that matches all the values for the column. 75 // Multiple matches are not allowed. 76 // 77 //===----------------------------------------------------------------------===// 78 79 #include "CodeGenTarget.h" 80 #include "llvm/Support/Format.h" 81 #include "llvm/TableGen/Error.h" 82 using namespace llvm; 83 typedef std::map<std::string, std::vector<Record*> > InstrRelMapTy; 84 85 typedef std::map<std::vector<Init*>, std::vector<Record*> > RowInstrMapTy; 86 87 namespace { 88 89 //===----------------------------------------------------------------------===// 90 // This class is used to represent InstrMapping class defined in Target.td file. 91 class InstrMap { 92 private: 93 std::string Name; 94 std::string FilterClass; 95 ListInit *RowFields; 96 ListInit *ColFields; 97 ListInit *KeyCol; 98 std::vector<ListInit*> ValueCols; 99 100 public: 101 InstrMap(Record* MapRec) { 102 Name = MapRec->getName(); 103 104 // FilterClass - It's used to reduce the search space only to the 105 // instructions that define the kind of relationship modeled by 106 // this InstrMapping object/record. 107 const RecordVal *Filter = MapRec->getValue("FilterClass"); 108 FilterClass = Filter->getValue()->getAsUnquotedString(); 109 110 // List of fields/attributes that need to be same across all the 111 // instructions in a row of the relation table. 112 RowFields = MapRec->getValueAsListInit("RowFields"); 113 114 // List of fields/attributes that are constant across all the instruction 115 // in a column of the relation table. Ex: ColFields = 'predSense' 116 ColFields = MapRec->getValueAsListInit("ColFields"); 117 118 // Values for the fields/attributes listed in 'ColFields'. 119 // Ex: KeyCol = 'noPred' -- key instruction is non predicated 120 KeyCol = MapRec->getValueAsListInit("KeyCol"); 121 122 // List of values for the fields/attributes listed in 'ColFields', one for 123 // each column in the relation table. 124 // 125 // Ex: ValueCols = [['true'],['false']] -- it results two columns in the 126 // table. First column requires all the instructions to have predSense 127 // set to 'true' and second column requires it to be 'false'. 128 ListInit *ColValList = MapRec->getValueAsListInit("ValueCols"); 129 130 // Each instruction map must specify at least one column for it to be valid. 131 if (ColValList->getSize() == 0) 132 PrintFatalError(MapRec->getLoc(), "InstrMapping record `" + 133 MapRec->getName() + "' has empty " + "`ValueCols' field!"); 134 135 for (unsigned i = 0, e = ColValList->getSize(); i < e; i++) { 136 ListInit *ColI = dyn_cast<ListInit>(ColValList->getElement(i)); 137 138 // Make sure that all the sub-lists in 'ValueCols' have same number of 139 // elements as the fields in 'ColFields'. 140 if (ColI->getSize() != ColFields->getSize()) 141 PrintFatalError(MapRec->getLoc(), "Record `" + MapRec->getName() + 142 "', field `ValueCols' entries don't match with " + 143 " the entries in 'ColFields'!"); 144 ValueCols.push_back(ColI); 145 } 146 } 147 148 std::string getName() const { 149 return Name; 150 } 151 152 std::string getFilterClass() { 153 return FilterClass; 154 } 155 156 ListInit *getRowFields() const { 157 return RowFields; 158 } 159 160 ListInit *getColFields() const { 161 return ColFields; 162 } 163 164 ListInit *getKeyCol() const { 165 return KeyCol; 166 } 167 168 const std::vector<ListInit*> &getValueCols() const { 169 return ValueCols; 170 } 171 }; 172 } // End anonymous namespace. 173 174 175 //===----------------------------------------------------------------------===// 176 // class MapTableEmitter : It builds the instruction relation maps using 177 // the information provided in InstrMapping records. It outputs these 178 // relationship maps as tables into XXXGenInstrInfo.inc file along with the 179 // functions to query them. 180 181 namespace { 182 class MapTableEmitter { 183 private: 184 // std::string TargetName; 185 const CodeGenTarget &Target; 186 // InstrMapDesc - InstrMapping record to be processed. 187 InstrMap InstrMapDesc; 188 189 // InstrDefs - list of instructions filtered using FilterClass defined 190 // in InstrMapDesc. 191 std::vector<Record*> InstrDefs; 192 193 // RowInstrMap - maps RowFields values to the instructions. It's keyed by the 194 // values of the row fields and contains vector of records as values. 195 RowInstrMapTy RowInstrMap; 196 197 // KeyInstrVec - list of key instructions. 198 std::vector<Record*> KeyInstrVec; 199 DenseMap<Record*, std::vector<Record*> > MapTable; 200 201 public: 202 MapTableEmitter(CodeGenTarget &Target, RecordKeeper &Records, Record *IMRec): 203 Target(Target), InstrMapDesc(IMRec) { 204 const std::string FilterClass = InstrMapDesc.getFilterClass(); 205 InstrDefs = Records.getAllDerivedDefinitions(FilterClass); 206 } 207 208 void buildRowInstrMap(); 209 210 // Returns true if an instruction is a key instruction, i.e., its ColFields 211 // have same values as KeyCol. 212 bool isKeyColInstr(Record* CurInstr); 213 214 // Find column instruction corresponding to a key instruction based on the 215 // constraints for that column. 216 Record *getInstrForColumn(Record *KeyInstr, ListInit *CurValueCol); 217 218 // Find column instructions for each key instruction based 219 // on ValueCols and store them into MapTable. 220 void buildMapTable(); 221 222 void emitBinSearch(raw_ostream &OS, unsigned TableSize); 223 void emitTablesWithFunc(raw_ostream &OS); 224 unsigned emitBinSearchTable(raw_ostream &OS); 225 226 // Lookup functions to query binary search tables. 227 void emitMapFuncBody(raw_ostream &OS, unsigned TableSize); 228 229 }; 230 } // End anonymous namespace. 231 232 233 //===----------------------------------------------------------------------===// 234 // Process all the instructions that model this relation (alreday present in 235 // InstrDefs) and insert them into RowInstrMap which is keyed by the values of 236 // the fields listed as RowFields. It stores vectors of records as values. 237 // All the related instructions have the same values for the RowFields thus are 238 // part of the same key-value pair. 239 //===----------------------------------------------------------------------===// 240 241 void MapTableEmitter::buildRowInstrMap() { 242 for (unsigned i = 0, e = InstrDefs.size(); i < e; i++) { 243 std::vector<Record*> InstrList; 244 Record *CurInstr = InstrDefs[i]; 245 std::vector<Init*> KeyValue; 246 ListInit *RowFields = InstrMapDesc.getRowFields(); 247 for (unsigned j = 0, endRF = RowFields->getSize(); j < endRF; j++) { 248 Init *RowFieldsJ = RowFields->getElement(j); 249 Init *CurInstrVal = CurInstr->getValue(RowFieldsJ)->getValue(); 250 KeyValue.push_back(CurInstrVal); 251 } 252 253 // Collect key instructions into KeyInstrVec. Later, these instructions are 254 // processed to assign column position to the instructions sharing 255 // their KeyValue in RowInstrMap. 256 if (isKeyColInstr(CurInstr)) 257 KeyInstrVec.push_back(CurInstr); 258 259 RowInstrMap[KeyValue].push_back(CurInstr); 260 } 261 } 262 263 //===----------------------------------------------------------------------===// 264 // Return true if an instruction is a KeyCol instruction. 265 //===----------------------------------------------------------------------===// 266 267 bool MapTableEmitter::isKeyColInstr(Record* CurInstr) { 268 ListInit *ColFields = InstrMapDesc.getColFields(); 269 ListInit *KeyCol = InstrMapDesc.getKeyCol(); 270 271 // Check if the instruction is a KeyCol instruction. 272 bool MatchFound = true; 273 for (unsigned j = 0, endCF = ColFields->getSize(); 274 (j < endCF) && MatchFound; j++) { 275 RecordVal *ColFieldName = CurInstr->getValue(ColFields->getElement(j)); 276 std::string CurInstrVal = ColFieldName->getValue()->getAsUnquotedString(); 277 std::string KeyColValue = KeyCol->getElement(j)->getAsUnquotedString(); 278 MatchFound = (CurInstrVal == KeyColValue); 279 } 280 return MatchFound; 281 } 282 283 //===----------------------------------------------------------------------===// 284 // Build a map to link key instructions with the column instructions arranged 285 // according to their column positions. 286 //===----------------------------------------------------------------------===// 287 288 void MapTableEmitter::buildMapTable() { 289 // Find column instructions for a given key based on the ColField 290 // constraints. 291 const std::vector<ListInit*> &ValueCols = InstrMapDesc.getValueCols(); 292 unsigned NumOfCols = ValueCols.size(); 293 for (unsigned j = 0, endKI = KeyInstrVec.size(); j < endKI; j++) { 294 Record *CurKeyInstr = KeyInstrVec[j]; 295 std::vector<Record*> ColInstrVec(NumOfCols); 296 297 // Find the column instruction based on the constraints for the column. 298 for (unsigned ColIdx = 0; ColIdx < NumOfCols; ColIdx++) { 299 ListInit *CurValueCol = ValueCols[ColIdx]; 300 Record *ColInstr = getInstrForColumn(CurKeyInstr, CurValueCol); 301 ColInstrVec[ColIdx] = ColInstr; 302 } 303 MapTable[CurKeyInstr] = ColInstrVec; 304 } 305 } 306 307 //===----------------------------------------------------------------------===// 308 // Find column instruction based on the constraints for that column. 309 //===----------------------------------------------------------------------===// 310 311 Record *MapTableEmitter::getInstrForColumn(Record *KeyInstr, 312 ListInit *CurValueCol) { 313 ListInit *RowFields = InstrMapDesc.getRowFields(); 314 std::vector<Init*> KeyValue; 315 316 // Construct KeyValue using KeyInstr's values for RowFields. 317 for (unsigned j = 0, endRF = RowFields->getSize(); j < endRF; j++) { 318 Init *RowFieldsJ = RowFields->getElement(j); 319 Init *KeyInstrVal = KeyInstr->getValue(RowFieldsJ)->getValue(); 320 KeyValue.push_back(KeyInstrVal); 321 } 322 323 // Get all the instructions that share the same KeyValue as the KeyInstr 324 // in RowInstrMap. We search through these instructions to find a match 325 // for the current column, i.e., the instruction which has the same values 326 // as CurValueCol for all the fields in ColFields. 327 const std::vector<Record*> &RelatedInstrVec = RowInstrMap[KeyValue]; 328 329 ListInit *ColFields = InstrMapDesc.getColFields(); 330 Record *MatchInstr = NULL; 331 332 for (unsigned i = 0, e = RelatedInstrVec.size(); i < e; i++) { 333 bool MatchFound = true; 334 Record *CurInstr = RelatedInstrVec[i]; 335 for (unsigned j = 0, endCF = ColFields->getSize(); 336 (j < endCF) && MatchFound; j++) { 337 Init *ColFieldJ = ColFields->getElement(j); 338 Init *CurInstrInit = CurInstr->getValue(ColFieldJ)->getValue(); 339 std::string CurInstrVal = CurInstrInit->getAsUnquotedString(); 340 Init *ColFieldJVallue = CurValueCol->getElement(j); 341 MatchFound = (CurInstrVal == ColFieldJVallue->getAsUnquotedString()); 342 } 343 344 if (MatchFound) { 345 if (MatchInstr) // Already had a match 346 // Error if multiple matches are found for a column. 347 PrintFatalError("Multiple matches found for `" + KeyInstr->getName() + 348 "', for the relation `" + InstrMapDesc.getName()); 349 MatchInstr = CurInstr; 350 } 351 } 352 return MatchInstr; 353 } 354 355 //===----------------------------------------------------------------------===// 356 // Emit one table per relation. Only instructions with a valid relation of a 357 // given type are included in the table sorted by their enum values (opcodes). 358 // Binary search is used for locating instructions in the table. 359 //===----------------------------------------------------------------------===// 360 361 unsigned MapTableEmitter::emitBinSearchTable(raw_ostream &OS) { 362 363 const std::vector<const CodeGenInstruction*> &NumberedInstructions = 364 Target.getInstructionsByEnumValue(); 365 std::string TargetName = Target.getName(); 366 const std::vector<ListInit*> &ValueCols = InstrMapDesc.getValueCols(); 367 unsigned NumCol = ValueCols.size(); 368 unsigned TotalNumInstr = NumberedInstructions.size(); 369 unsigned TableSize = 0; 370 371 OS << "static const uint16_t "<<InstrMapDesc.getName(); 372 // Number of columns in the table are NumCol+1 because key instructions are 373 // emitted as first column. 374 OS << "Table[]["<< NumCol+1 << "] = {\n"; 375 for (unsigned i = 0; i < TotalNumInstr; i++) { 376 Record *CurInstr = NumberedInstructions[i]->TheDef; 377 std::vector<Record*> ColInstrs = MapTable[CurInstr]; 378 std::string OutStr(""); 379 unsigned RelExists = 0; 380 if (ColInstrs.size()) { 381 for (unsigned j = 0; j < NumCol; j++) { 382 if (ColInstrs[j] != NULL) { 383 RelExists = 1; 384 OutStr += ", "; 385 OutStr += TargetName; 386 OutStr += "::"; 387 OutStr += ColInstrs[j]->getName(); 388 } else { OutStr += ", -1";} 389 } 390 391 if (RelExists) { 392 OS << " { " << TargetName << "::" << CurInstr->getName(); 393 OS << OutStr <<" },\n"; 394 TableSize++; 395 } 396 } 397 } 398 if (!TableSize) { 399 OS << " { " << TargetName << "::" << "INSTRUCTION_LIST_END, "; 400 OS << TargetName << "::" << "INSTRUCTION_LIST_END }"; 401 } 402 OS << "}; // End of " << InstrMapDesc.getName() << "Table\n\n"; 403 return TableSize; 404 } 405 406 //===----------------------------------------------------------------------===// 407 // Emit binary search algorithm as part of the functions used to query 408 // relation tables. 409 //===----------------------------------------------------------------------===// 410 411 void MapTableEmitter::emitBinSearch(raw_ostream &OS, unsigned TableSize) { 412 OS << " unsigned mid;\n"; 413 OS << " unsigned start = 0;\n"; 414 OS << " unsigned end = " << TableSize << ";\n"; 415 OS << " while (start < end) {\n"; 416 OS << " mid = start + (end - start)/2;\n"; 417 OS << " if (Opcode == " << InstrMapDesc.getName() << "Table[mid][0]) {\n"; 418 OS << " break;\n"; 419 OS << " }\n"; 420 OS << " if (Opcode < " << InstrMapDesc.getName() << "Table[mid][0])\n"; 421 OS << " end = mid;\n"; 422 OS << " else\n"; 423 OS << " start = mid + 1;\n"; 424 OS << " }\n"; 425 OS << " if (start == end)\n"; 426 OS << " return -1; // Instruction doesn't exist in this table.\n\n"; 427 } 428 429 //===----------------------------------------------------------------------===// 430 // Emit functions to query relation tables. 431 //===----------------------------------------------------------------------===// 432 433 void MapTableEmitter::emitMapFuncBody(raw_ostream &OS, 434 unsigned TableSize) { 435 436 ListInit *ColFields = InstrMapDesc.getColFields(); 437 const std::vector<ListInit*> &ValueCols = InstrMapDesc.getValueCols(); 438 439 // Emit binary search algorithm to locate instructions in the 440 // relation table. If found, return opcode value from the appropriate column 441 // of the table. 442 emitBinSearch(OS, TableSize); 443 444 if (ValueCols.size() > 1) { 445 for (unsigned i = 0, e = ValueCols.size(); i < e; i++) { 446 ListInit *ColumnI = ValueCols[i]; 447 for (unsigned j = 0, ColSize = ColumnI->getSize(); j < ColSize; j++) { 448 std::string ColName = ColFields->getElement(j)->getAsUnquotedString(); 449 OS << " if (in" << ColName; 450 OS << " == "; 451 OS << ColName << "_" << ColumnI->getElement(j)->getAsUnquotedString(); 452 if (j < ColumnI->getSize() - 1) OS << " && "; 453 else OS << ")\n"; 454 } 455 OS << " return " << InstrMapDesc.getName(); 456 OS << "Table[mid]["<<i+1<<"];\n"; 457 } 458 OS << " return -1;"; 459 } 460 else 461 OS << " return " << InstrMapDesc.getName() << "Table[mid][1];\n"; 462 463 OS <<"}\n\n"; 464 } 465 466 //===----------------------------------------------------------------------===// 467 // Emit relation tables and the functions to query them. 468 //===----------------------------------------------------------------------===// 469 470 void MapTableEmitter::emitTablesWithFunc(raw_ostream &OS) { 471 472 // Emit function name and the input parameters : mostly opcode value of the 473 // current instruction. However, if a table has multiple columns (more than 2 474 // since first column is used for the key instructions), then we also need 475 // to pass another input to indicate the column to be selected. 476 477 ListInit *ColFields = InstrMapDesc.getColFields(); 478 const std::vector<ListInit*> &ValueCols = InstrMapDesc.getValueCols(); 479 OS << "// "<< InstrMapDesc.getName() << "\n"; 480 OS << "int "<< InstrMapDesc.getName() << "(uint16_t Opcode"; 481 if (ValueCols.size() > 1) { 482 for (unsigned i = 0, e = ColFields->getSize(); i < e; i++) { 483 std::string ColName = ColFields->getElement(i)->getAsUnquotedString(); 484 OS << ", enum " << ColName << " in" << ColName << ") {\n"; 485 } 486 } else { OS << ") {\n"; } 487 488 // Emit map table. 489 unsigned TableSize = emitBinSearchTable(OS); 490 491 // Emit rest of the function body. 492 emitMapFuncBody(OS, TableSize); 493 } 494 495 //===----------------------------------------------------------------------===// 496 // Emit enums for the column fields across all the instruction maps. 497 //===----------------------------------------------------------------------===// 498 499 static void emitEnums(raw_ostream &OS, RecordKeeper &Records) { 500 501 std::vector<Record*> InstrMapVec; 502 InstrMapVec = Records.getAllDerivedDefinitions("InstrMapping"); 503 std::map<std::string, std::vector<Init*> > ColFieldValueMap; 504 505 // Iterate over all InstrMapping records and create a map between column 506 // fields and their possible values across all records. 507 for (unsigned i = 0, e = InstrMapVec.size(); i < e; i++) { 508 Record *CurMap = InstrMapVec[i]; 509 ListInit *ColFields; 510 ColFields = CurMap->getValueAsListInit("ColFields"); 511 ListInit *List = CurMap->getValueAsListInit("ValueCols"); 512 std::vector<ListInit*> ValueCols; 513 unsigned ListSize = List->getSize(); 514 515 for (unsigned j = 0; j < ListSize; j++) { 516 ListInit *ListJ = dyn_cast<ListInit>(List->getElement(j)); 517 518 if (ListJ->getSize() != ColFields->getSize()) 519 PrintFatalError("Record `" + CurMap->getName() + "', field " 520 "`ValueCols' entries don't match with the entries in 'ColFields' !"); 521 ValueCols.push_back(ListJ); 522 } 523 524 for (unsigned j = 0, endCF = ColFields->getSize(); j < endCF; j++) { 525 for (unsigned k = 0; k < ListSize; k++){ 526 std::string ColName = ColFields->getElement(j)->getAsUnquotedString(); 527 ColFieldValueMap[ColName].push_back((ValueCols[k])->getElement(j)); 528 } 529 } 530 } 531 532 for (std::map<std::string, std::vector<Init*> >::iterator 533 II = ColFieldValueMap.begin(), IE = ColFieldValueMap.end(); 534 II != IE; II++) { 535 std::vector<Init*> FieldValues = (*II).second; 536 537 // Delete duplicate entries from ColFieldValueMap 538 for (unsigned i = 0; i < FieldValues.size() - 1; i++) { 539 Init *CurVal = FieldValues[i]; 540 for (unsigned j = i+1; j < FieldValues.size(); j++) { 541 if (CurVal == FieldValues[j]) { 542 FieldValues.erase(FieldValues.begin()+j); 543 } 544 } 545 } 546 547 // Emit enumerated values for the column fields. 548 OS << "enum " << (*II).first << " {\n"; 549 for (unsigned i = 0, endFV = FieldValues.size(); i < endFV; i++) { 550 OS << "\t" << (*II).first << "_" << FieldValues[i]->getAsUnquotedString(); 551 if (i != endFV - 1) 552 OS << ",\n"; 553 else 554 OS << "\n};\n\n"; 555 } 556 } 557 } 558 559 namespace llvm { 560 //===----------------------------------------------------------------------===// 561 // Parse 'InstrMapping' records and use the information to form relationship 562 // between instructions. These relations are emitted as a tables along with the 563 // functions to query them. 564 //===----------------------------------------------------------------------===// 565 void EmitMapTable(RecordKeeper &Records, raw_ostream &OS) { 566 CodeGenTarget Target(Records); 567 std::string TargetName = Target.getName(); 568 std::vector<Record*> InstrMapVec; 569 InstrMapVec = Records.getAllDerivedDefinitions("InstrMapping"); 570 571 if (!InstrMapVec.size()) 572 return; 573 574 OS << "#ifdef GET_INSTRMAP_INFO\n"; 575 OS << "#undef GET_INSTRMAP_INFO\n"; 576 OS << "namespace llvm {\n\n"; 577 OS << "namespace " << TargetName << " {\n\n"; 578 579 // Emit coulumn field names and their values as enums. 580 emitEnums(OS, Records); 581 582 // Iterate over all instruction mapping records and construct relationship 583 // maps based on the information specified there. 584 // 585 for (unsigned i = 0, e = InstrMapVec.size(); i < e; i++) { 586 MapTableEmitter IMap(Target, Records, InstrMapVec[i]); 587 588 // Build RowInstrMap to group instructions based on their values for 589 // RowFields. In the process, also collect key instructions into 590 // KeyInstrVec. 591 IMap.buildRowInstrMap(); 592 593 // Build MapTable to map key instructions with the corresponding column 594 // instructions. 595 IMap.buildMapTable(); 596 597 // Emit map tables and the functions to query them. 598 IMap.emitTablesWithFunc(OS); 599 } 600 OS << "} // End " << TargetName << " namespace\n"; 601 OS << "} // End llvm namespace\n"; 602 OS << "#endif // GET_INSTRMAP_INFO\n\n"; 603 } 604 605 } // End llvm namespace 606