xref: /freebsd/contrib/llvm-project/llvm/utils/TableGen/CodeGenMapTable.cpp (revision c8e7f78a3d28ff6e6223ed136ada8e1e2f34965e)
1 //===- CodeGenMapTable.cpp - Instruction Mapping Table Generator ----------===//
2 //
3 // Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions.
4 // See https://llvm.org/LICENSE.txt for license information.
5 // SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception
6 //
7 //===----------------------------------------------------------------------===//
8 // CodeGenMapTable provides functionality for the TableGen to create
9 // relation mapping between instructions. Relation models are defined using
10 // InstrMapping as a base class. This file implements the functionality which
11 // parses these definitions and generates relation maps using the information
12 // specified there. These maps are emitted as tables in the XXXGenInstrInfo.inc
13 // file along with the functions to query them.
14 //
15 // A relationship model to relate non-predicate instructions with their
16 // predicated true/false forms can be defined as follows:
17 //
18 // def getPredOpcode : InstrMapping {
19 //  let FilterClass = "PredRel";
20 //  let RowFields = ["BaseOpcode"];
21 //  let ColFields = ["PredSense"];
22 //  let KeyCol = ["none"];
23 //  let ValueCols = [["true"], ["false"]]; }
24 //
25 // CodeGenMapTable parses this map and generates a table in XXXGenInstrInfo.inc
26 // file that contains the instructions modeling this relationship. This table
27 // is defined in the function
28 // "int getPredOpcode(uint16_t Opcode, enum PredSense inPredSense)"
29 // that can be used to retrieve the predicated form of the instruction by
30 // passing its opcode value and the predicate sense (true/false) of the desired
31 // instruction as arguments.
32 //
33 // Short description of the algorithm:
34 //
35 // 1) Iterate through all the records that derive from "InstrMapping" class.
36 // 2) For each record, filter out instructions based on the FilterClass value.
37 // 3) Iterate through this set of instructions and insert them into
38 // RowInstrMap map based on their RowFields values. RowInstrMap is keyed by the
39 // vector of RowFields values and contains vectors of Records (instructions) as
40 // values. RowFields is a list of fields that are required to have the same
41 // values for all the instructions appearing in the same row of the relation
42 // table. All the instructions in a given row of the relation table have some
43 // sort of relationship with the key instruction defined by the corresponding
44 // relationship model.
45 //
46 // Ex: RowInstrMap(RowVal1, RowVal2, ...) -> [Instr1, Instr2, Instr3, ... ]
47 // Here Instr1, Instr2, Instr3 have same values (RowVal1, RowVal2) for
48 // RowFields. These groups of instructions are later matched against ValueCols
49 // to determine the column they belong to, if any.
50 //
51 // While building the RowInstrMap map, collect all the key instructions in
52 // KeyInstrVec. These are the instructions having the same values as KeyCol
53 // for all the fields listed in ColFields.
54 //
55 // For Example:
56 //
57 // Relate non-predicate instructions with their predicated true/false forms.
58 //
59 // def getPredOpcode : InstrMapping {
60 //  let FilterClass = "PredRel";
61 //  let RowFields = ["BaseOpcode"];
62 //  let ColFields = ["PredSense"];
63 //  let KeyCol = ["none"];
64 //  let ValueCols = [["true"], ["false"]]; }
65 //
66 // Here, only instructions that have "none" as PredSense will be selected as key
67 // instructions.
68 //
69 // 4) For each key instruction, get the group of instructions that share the
70 // same key-value as the key instruction from RowInstrMap. Iterate over the list
71 // of columns in ValueCols (it is defined as a list<list<string> >. Therefore,
72 // it can specify multi-column relationships). For each column, find the
73 // instruction from the group that matches all the values for the column.
74 // Multiple matches are not allowed.
75 //
76 //===----------------------------------------------------------------------===//
77 
78 #include "CodeGenInstruction.h"
79 #include "CodeGenTarget.h"
80 #include "llvm/TableGen/Error.h"
81 #include "llvm/TableGen/Record.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 = std::string(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->empty())
132       PrintFatalError(MapRec->getLoc(), "InstrMapping record `" +
133         MapRec->getName() + "' has empty " + "`ValueCols' field!");
134 
135     for (Init *I : ColValList->getValues()) {
136       auto *ColI = cast<ListInit>(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->size() != ColFields->size())
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   const std::string &getName() const { return Name; }
149 
150   const std::string &getFilterClass() const { return FilterClass; }
151 
152   ListInit *getRowFields() const { return RowFields; }
153 
154   ListInit *getColFields() const { return ColFields; }
155 
156   ListInit *getKeyCol() const { return KeyCol; }
157 
158   const std::vector<ListInit*> &getValueCols() const {
159     return ValueCols;
160   }
161 };
162 } // end anonymous namespace
163 
164 
165 //===----------------------------------------------------------------------===//
166 // class MapTableEmitter : It builds the instruction relation maps using
167 // the information provided in InstrMapping records. It outputs these
168 // relationship maps as tables into XXXGenInstrInfo.inc file along with the
169 // functions to query them.
170 
171 namespace {
172 class MapTableEmitter {
173 private:
174 //  std::string TargetName;
175   const CodeGenTarget &Target;
176   // InstrMapDesc - InstrMapping record to be processed.
177   InstrMap InstrMapDesc;
178 
179   // InstrDefs - list of instructions filtered using FilterClass defined
180   // in InstrMapDesc.
181   std::vector<Record*> InstrDefs;
182 
183   // RowInstrMap - maps RowFields values to the instructions. It's keyed by the
184   // values of the row fields and contains vector of records as values.
185   RowInstrMapTy RowInstrMap;
186 
187   // KeyInstrVec - list of key instructions.
188   std::vector<Record*> KeyInstrVec;
189   DenseMap<Record*, std::vector<Record*> > MapTable;
190 
191 public:
192   MapTableEmitter(CodeGenTarget &Target, RecordKeeper &Records, Record *IMRec):
193                   Target(Target), InstrMapDesc(IMRec) {
194     const std::string &FilterClass = InstrMapDesc.getFilterClass();
195     InstrDefs = Records.getAllDerivedDefinitions(FilterClass);
196   }
197 
198   void buildRowInstrMap();
199 
200   // Returns true if an instruction is a key instruction, i.e., its ColFields
201   // have same values as KeyCol.
202   bool isKeyColInstr(Record* CurInstr);
203 
204   // Find column instruction corresponding to a key instruction based on the
205   // constraints for that column.
206   Record *getInstrForColumn(Record *KeyInstr, ListInit *CurValueCol);
207 
208   // Find column instructions for each key instruction based
209   // on ValueCols and store them into MapTable.
210   void buildMapTable();
211 
212   void emitBinSearch(raw_ostream &OS, unsigned TableSize);
213   void emitTablesWithFunc(raw_ostream &OS);
214   unsigned emitBinSearchTable(raw_ostream &OS);
215 
216   // Lookup functions to query binary search tables.
217   void emitMapFuncBody(raw_ostream &OS, unsigned TableSize);
218 
219 };
220 } // end anonymous namespace
221 
222 
223 //===----------------------------------------------------------------------===//
224 // Process all the instructions that model this relation (alreday present in
225 // InstrDefs) and insert them into RowInstrMap which is keyed by the values of
226 // the fields listed as RowFields. It stores vectors of records as values.
227 // All the related instructions have the same values for the RowFields thus are
228 // part of the same key-value pair.
229 //===----------------------------------------------------------------------===//
230 
231 void MapTableEmitter::buildRowInstrMap() {
232   for (Record *CurInstr : InstrDefs) {
233     std::vector<Init*> KeyValue;
234     ListInit *RowFields = InstrMapDesc.getRowFields();
235     for (Init *RowField : RowFields->getValues()) {
236       RecordVal *RecVal = CurInstr->getValue(RowField);
237       if (RecVal == nullptr)
238         PrintFatalError(CurInstr->getLoc(), "No value " +
239                         RowField->getAsString() + " found in \"" +
240                         CurInstr->getName() + "\" instruction description.");
241       Init *CurInstrVal = RecVal->getValue();
242       KeyValue.push_back(CurInstrVal);
243     }
244 
245     // Collect key instructions into KeyInstrVec. Later, these instructions are
246     // processed to assign column position to the instructions sharing
247     // their KeyValue in RowInstrMap.
248     if (isKeyColInstr(CurInstr))
249       KeyInstrVec.push_back(CurInstr);
250 
251     RowInstrMap[KeyValue].push_back(CurInstr);
252   }
253 }
254 
255 //===----------------------------------------------------------------------===//
256 // Return true if an instruction is a KeyCol instruction.
257 //===----------------------------------------------------------------------===//
258 
259 bool MapTableEmitter::isKeyColInstr(Record* CurInstr) {
260   ListInit *ColFields = InstrMapDesc.getColFields();
261   ListInit *KeyCol = InstrMapDesc.getKeyCol();
262 
263   // Check if the instruction is a KeyCol instruction.
264   bool MatchFound = true;
265   for (unsigned j = 0, endCF = ColFields->size();
266       (j < endCF) && MatchFound; j++) {
267     RecordVal *ColFieldName = CurInstr->getValue(ColFields->getElement(j));
268     std::string CurInstrVal = ColFieldName->getValue()->getAsUnquotedString();
269     std::string KeyColValue = KeyCol->getElement(j)->getAsUnquotedString();
270     MatchFound = (CurInstrVal == KeyColValue);
271   }
272   return MatchFound;
273 }
274 
275 //===----------------------------------------------------------------------===//
276 // Build a map to link key instructions with the column instructions arranged
277 // according to their column positions.
278 //===----------------------------------------------------------------------===//
279 
280 void MapTableEmitter::buildMapTable() {
281   // Find column instructions for a given key based on the ColField
282   // constraints.
283   const std::vector<ListInit*> &ValueCols = InstrMapDesc.getValueCols();
284   unsigned NumOfCols = ValueCols.size();
285   for (Record *CurKeyInstr : KeyInstrVec) {
286     std::vector<Record*> ColInstrVec(NumOfCols);
287 
288     // Find the column instruction based on the constraints for the column.
289     for (unsigned ColIdx = 0; ColIdx < NumOfCols; ColIdx++) {
290       ListInit *CurValueCol = ValueCols[ColIdx];
291       Record *ColInstr = getInstrForColumn(CurKeyInstr, CurValueCol);
292       ColInstrVec[ColIdx] = ColInstr;
293     }
294     MapTable[CurKeyInstr] = ColInstrVec;
295   }
296 }
297 
298 //===----------------------------------------------------------------------===//
299 // Find column instruction based on the constraints for that column.
300 //===----------------------------------------------------------------------===//
301 
302 Record *MapTableEmitter::getInstrForColumn(Record *KeyInstr,
303                                            ListInit *CurValueCol) {
304   ListInit *RowFields = InstrMapDesc.getRowFields();
305   std::vector<Init*> KeyValue;
306 
307   // Construct KeyValue using KeyInstr's values for RowFields.
308   for (Init *RowField : RowFields->getValues()) {
309     Init *KeyInstrVal = KeyInstr->getValue(RowField)->getValue();
310     KeyValue.push_back(KeyInstrVal);
311   }
312 
313   // Get all the instructions that share the same KeyValue as the KeyInstr
314   // in RowInstrMap. We search through these instructions to find a match
315   // for the current column, i.e., the instruction which has the same values
316   // as CurValueCol for all the fields in ColFields.
317   const std::vector<Record*> &RelatedInstrVec = RowInstrMap[KeyValue];
318 
319   ListInit *ColFields = InstrMapDesc.getColFields();
320   Record *MatchInstr = nullptr;
321 
322   for (llvm::Record *CurInstr : RelatedInstrVec) {
323     bool MatchFound = true;
324     for (unsigned j = 0, endCF = ColFields->size();
325          (j < endCF) && MatchFound; j++) {
326       Init *ColFieldJ = ColFields->getElement(j);
327       Init *CurInstrInit = CurInstr->getValue(ColFieldJ)->getValue();
328       std::string CurInstrVal = CurInstrInit->getAsUnquotedString();
329       Init *ColFieldJVallue = CurValueCol->getElement(j);
330       MatchFound = (CurInstrVal == ColFieldJVallue->getAsUnquotedString());
331     }
332 
333     if (MatchFound) {
334       if (MatchInstr) {
335         // Already had a match
336         // Error if multiple matches are found for a column.
337         std::string KeyValueStr;
338         for (Init *Value : KeyValue) {
339           if (!KeyValueStr.empty())
340             KeyValueStr += ", ";
341           KeyValueStr += Value->getAsString();
342         }
343 
344         PrintFatalError("Multiple matches found for `" + KeyInstr->getName() +
345                         "', for the relation `" + InstrMapDesc.getName() +
346                         "', row fields [" + KeyValueStr + "], column `" +
347                         CurValueCol->getAsString() + "'");
348       }
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   ArrayRef<const CodeGenInstruction*> NumberedInstructions =
364                                             Target.getInstructionsByEnumValue();
365   StringRef Namespace = Target.getInstNamespace();
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.empty()) {
381       for (unsigned j = 0; j < NumCol; j++) {
382         if (ColInstrs[j] != nullptr) {
383           RelExists = 1;
384           OutStr += ", ";
385           OutStr += Namespace;
386           OutStr += "::";
387           OutStr += ColInstrs[j]->getName();
388         } else { OutStr += ", (uint16_t)-1U";}
389       }
390 
391       if (RelExists) {
392         OS << "  { " << Namespace << "::" << CurInstr->getName();
393         OS << OutStr <<" },\n";
394         TableSize++;
395       }
396     }
397   }
398   if (!TableSize) {
399     OS << "  { " << Namespace << "::" << "INSTRUCTION_LIST_END, ";
400     OS << Namespace << "::" << "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       OS << "  if (";
448       for (unsigned j = 0, ColSize = ColumnI->size(); j < ColSize; ++j) {
449         std::string ColName = ColFields->getElement(j)->getAsUnquotedString();
450         OS << "in" << ColName;
451         OS << " == ";
452         OS << ColName << "_" << ColumnI->getElement(j)->getAsUnquotedString();
453         if (j < ColumnI->size() - 1)
454           OS << " && ";
455       }
456       OS << ")\n";
457       OS << "    return " << InstrMapDesc.getName();
458       OS << "Table[mid]["<<i+1<<"];\n";
459     }
460     OS << "  return -1;";
461   }
462   else
463     OS << "  return " << InstrMapDesc.getName() << "Table[mid][1];\n";
464 
465   OS <<"}\n\n";
466 }
467 
468 //===----------------------------------------------------------------------===//
469 // Emit relation tables and the functions to query them.
470 //===----------------------------------------------------------------------===//
471 
472 void MapTableEmitter::emitTablesWithFunc(raw_ostream &OS) {
473 
474   // Emit function name and the input parameters : mostly opcode value of the
475   // current instruction. However, if a table has multiple columns (more than 2
476   // since first column is used for the key instructions), then we also need
477   // to pass another input to indicate the column to be selected.
478 
479   ListInit *ColFields = InstrMapDesc.getColFields();
480   const std::vector<ListInit*> &ValueCols = InstrMapDesc.getValueCols();
481   OS << "// "<< InstrMapDesc.getName() << "\nLLVM_READONLY\n";
482   OS << "int "<< InstrMapDesc.getName() << "(uint16_t Opcode";
483   if (ValueCols.size() > 1) {
484     for (Init *CF : ColFields->getValues()) {
485       std::string ColName = CF->getAsUnquotedString();
486       OS << ", enum " << ColName << " in" << ColName;
487     }
488   }
489   OS << ") {\n";
490 
491   // Emit map table.
492   unsigned TableSize = emitBinSearchTable(OS);
493 
494   // Emit rest of the function body.
495   emitMapFuncBody(OS, TableSize);
496 }
497 
498 //===----------------------------------------------------------------------===//
499 // Emit enums for the column fields across all the instruction maps.
500 //===----------------------------------------------------------------------===//
501 
502 static void emitEnums(raw_ostream &OS, RecordKeeper &Records) {
503 
504   std::vector<Record*> InstrMapVec;
505   InstrMapVec = Records.getAllDerivedDefinitions("InstrMapping");
506   std::map<std::string, std::vector<Init*> > ColFieldValueMap;
507 
508   // Iterate over all InstrMapping records and create a map between column
509   // fields and their possible values across all records.
510   for (Record *CurMap : InstrMapVec) {
511     ListInit *ColFields;
512     ColFields = CurMap->getValueAsListInit("ColFields");
513     ListInit *List = CurMap->getValueAsListInit("ValueCols");
514     std::vector<ListInit*> ValueCols;
515     unsigned ListSize = List->size();
516 
517     for (unsigned j = 0; j < ListSize; j++) {
518       auto *ListJ = cast<ListInit>(List->getElement(j));
519 
520       if (ListJ->size() != ColFields->size())
521         PrintFatalError("Record `" + CurMap->getName() + "', field "
522           "`ValueCols' entries don't match with the entries in 'ColFields' !");
523       ValueCols.push_back(ListJ);
524     }
525 
526     for (unsigned j = 0, endCF = ColFields->size(); j < endCF; j++) {
527       for (unsigned k = 0; k < ListSize; k++){
528         std::string ColName = ColFields->getElement(j)->getAsUnquotedString();
529         ColFieldValueMap[ColName].push_back((ValueCols[k])->getElement(j));
530       }
531     }
532   }
533 
534   for (auto &Entry : ColFieldValueMap) {
535     std::vector<Init*> FieldValues = Entry.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           --j;
544         }
545       }
546     }
547 
548     // Emit enumerated values for the column fields.
549     OS << "enum " << Entry.first << " {\n";
550     for (unsigned i = 0, endFV = FieldValues.size(); i < endFV; i++) {
551       OS << "\t" << Entry.first << "_" << FieldValues[i]->getAsUnquotedString();
552       if (i != endFV - 1)
553         OS << ",\n";
554       else
555         OS << "\n};\n\n";
556     }
557   }
558 }
559 
560 namespace llvm {
561 //===----------------------------------------------------------------------===//
562 // Parse 'InstrMapping' records and use the information to form relationship
563 // between instructions. These relations are emitted as a tables along with the
564 // functions to query them.
565 //===----------------------------------------------------------------------===//
566 void EmitMapTable(RecordKeeper &Records, raw_ostream &OS) {
567   CodeGenTarget Target(Records);
568   StringRef NameSpace = Target.getInstNamespace();
569   std::vector<Record*> InstrMapVec;
570   InstrMapVec = Records.getAllDerivedDefinitions("InstrMapping");
571 
572   if (InstrMapVec.empty())
573     return;
574 
575   OS << "#ifdef GET_INSTRMAP_INFO\n";
576   OS << "#undef GET_INSTRMAP_INFO\n";
577   OS << "namespace llvm {\n\n";
578   OS << "namespace " << NameSpace << " {\n\n";
579 
580   // Emit coulumn field names and their values as enums.
581   emitEnums(OS, Records);
582 
583   // Iterate over all instruction mapping records and construct relationship
584   // maps based on the information specified there.
585   //
586   for (Record *CurMap : InstrMapVec) {
587     MapTableEmitter IMap(Target, Records, CurMap);
588 
589     // Build RowInstrMap to group instructions based on their values for
590     // RowFields. In the process, also collect key instructions into
591     // KeyInstrVec.
592     IMap.buildRowInstrMap();
593 
594     // Build MapTable to map key instructions with the corresponding column
595     // instructions.
596     IMap.buildMapTable();
597 
598     // Emit map tables and the functions to query them.
599     IMap.emitTablesWithFunc(OS);
600   }
601   OS << "} // end namespace " << NameSpace << "\n";
602   OS << "} // end namespace llvm\n";
603   OS << "#endif // GET_INSTRMAP_INFO\n\n";
604 }
605 
606 } // End llvm namespace
607