xref: /freebsd/contrib/llvm-project/clang/lib/Support/RISCVVIntrinsicUtils.cpp (revision 1db9f3b21e39176dd5b67cf8ac378633b172463e)
1 //===- RISCVVIntrinsicUtils.cpp - RISC-V Vector Intrinsic Utils -*- C++ -*-===//
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 
9 #include "clang/Support/RISCVVIntrinsicUtils.h"
10 #include "llvm/ADT/ArrayRef.h"
11 #include "llvm/ADT/SmallSet.h"
12 #include "llvm/ADT/StringExtras.h"
13 #include "llvm/ADT/StringSet.h"
14 #include "llvm/ADT/Twine.h"
15 #include "llvm/Support/ErrorHandling.h"
16 #include "llvm/Support/raw_ostream.h"
17 #include <numeric>
18 #include <optional>
19 
20 using namespace llvm;
21 
22 namespace clang {
23 namespace RISCV {
24 
25 const PrototypeDescriptor PrototypeDescriptor::Mask = PrototypeDescriptor(
26     BaseTypeModifier::Vector, VectorTypeModifier::MaskVector);
27 const PrototypeDescriptor PrototypeDescriptor::VL =
28     PrototypeDescriptor(BaseTypeModifier::SizeT);
29 const PrototypeDescriptor PrototypeDescriptor::Vector =
30     PrototypeDescriptor(BaseTypeModifier::Vector);
31 
32 //===----------------------------------------------------------------------===//
33 // Type implementation
34 //===----------------------------------------------------------------------===//
35 
36 LMULType::LMULType(int NewLog2LMUL) {
37   // Check Log2LMUL is -3, -2, -1, 0, 1, 2, 3
38   assert(NewLog2LMUL <= 3 && NewLog2LMUL >= -3 && "Bad LMUL number!");
39   Log2LMUL = NewLog2LMUL;
40 }
41 
42 std::string LMULType::str() const {
43   if (Log2LMUL < 0)
44     return "mf" + utostr(1ULL << (-Log2LMUL));
45   return "m" + utostr(1ULL << Log2LMUL);
46 }
47 
48 VScaleVal LMULType::getScale(unsigned ElementBitwidth) const {
49   int Log2ScaleResult = 0;
50   switch (ElementBitwidth) {
51   default:
52     break;
53   case 8:
54     Log2ScaleResult = Log2LMUL + 3;
55     break;
56   case 16:
57     Log2ScaleResult = Log2LMUL + 2;
58     break;
59   case 32:
60     Log2ScaleResult = Log2LMUL + 1;
61     break;
62   case 64:
63     Log2ScaleResult = Log2LMUL;
64     break;
65   }
66   // Illegal vscale result would be less than 1
67   if (Log2ScaleResult < 0)
68     return std::nullopt;
69   return 1 << Log2ScaleResult;
70 }
71 
72 void LMULType::MulLog2LMUL(int log2LMUL) { Log2LMUL += log2LMUL; }
73 
74 RVVType::RVVType(BasicType BT, int Log2LMUL,
75                  const PrototypeDescriptor &prototype)
76     : BT(BT), LMUL(LMULType(Log2LMUL)) {
77   applyBasicType();
78   applyModifier(prototype);
79   Valid = verifyType();
80   if (Valid) {
81     initBuiltinStr();
82     initTypeStr();
83     if (isVector()) {
84       initClangBuiltinStr();
85     }
86   }
87 }
88 
89 // clang-format off
90 // boolean type are encoded the ratio of n (SEW/LMUL)
91 // SEW/LMUL | 1         | 2         | 4         | 8        | 16        | 32        | 64
92 // c type   | vbool64_t | vbool32_t | vbool16_t | vbool8_t | vbool4_t  | vbool2_t  | vbool1_t
93 // IR type  | nxv1i1    | nxv2i1    | nxv4i1    | nxv8i1   | nxv16i1   | nxv32i1   | nxv64i1
94 
95 // type\lmul | 1/8    | 1/4      | 1/2     | 1       | 2        | 4        | 8
96 // --------  |------  | -------- | ------- | ------- | -------- | -------- | --------
97 // i64       | N/A    | N/A      | N/A     | nxv1i64 | nxv2i64  | nxv4i64  | nxv8i64
98 // i32       | N/A    | N/A      | nxv1i32 | nxv2i32 | nxv4i32  | nxv8i32  | nxv16i32
99 // i16       | N/A    | nxv1i16  | nxv2i16 | nxv4i16 | nxv8i16  | nxv16i16 | nxv32i16
100 // i8        | nxv1i8 | nxv2i8   | nxv4i8  | nxv8i8  | nxv16i8  | nxv32i8  | nxv64i8
101 // double    | N/A    | N/A      | N/A     | nxv1f64 | nxv2f64  | nxv4f64  | nxv8f64
102 // float     | N/A    | N/A      | nxv1f32 | nxv2f32 | nxv4f32  | nxv8f32  | nxv16f32
103 // half      | N/A    | nxv1f16  | nxv2f16 | nxv4f16 | nxv8f16  | nxv16f16 | nxv32f16
104 // bfloat16  | N/A    | nxv1bf16 | nxv2bf16| nxv4bf16| nxv8bf16 | nxv16bf16| nxv32bf16
105 // clang-format on
106 
107 bool RVVType::verifyType() const {
108   if (ScalarType == Invalid)
109     return false;
110   if (isScalar())
111     return true;
112   if (!Scale)
113     return false;
114   if (isFloat() && ElementBitwidth == 8)
115     return false;
116   if (isBFloat() && ElementBitwidth != 16)
117     return false;
118   if (IsTuple && (NF == 1 || NF > 8))
119     return false;
120   if (IsTuple && (1 << std::max(0, LMUL.Log2LMUL)) * NF > 8)
121     return false;
122   unsigned V = *Scale;
123   switch (ElementBitwidth) {
124   case 1:
125   case 8:
126     // Check Scale is 1,2,4,8,16,32,64
127     return (V <= 64 && isPowerOf2_32(V));
128   case 16:
129     // Check Scale is 1,2,4,8,16,32
130     return (V <= 32 && isPowerOf2_32(V));
131   case 32:
132     // Check Scale is 1,2,4,8,16
133     return (V <= 16 && isPowerOf2_32(V));
134   case 64:
135     // Check Scale is 1,2,4,8
136     return (V <= 8 && isPowerOf2_32(V));
137   }
138   return false;
139 }
140 
141 void RVVType::initBuiltinStr() {
142   assert(isValid() && "RVVType is invalid");
143   switch (ScalarType) {
144   case ScalarTypeKind::Void:
145     BuiltinStr = "v";
146     return;
147   case ScalarTypeKind::Size_t:
148     BuiltinStr = "z";
149     if (IsImmediate)
150       BuiltinStr = "I" + BuiltinStr;
151     if (IsPointer)
152       BuiltinStr += "*";
153     return;
154   case ScalarTypeKind::Ptrdiff_t:
155     BuiltinStr = "Y";
156     return;
157   case ScalarTypeKind::UnsignedLong:
158     BuiltinStr = "ULi";
159     return;
160   case ScalarTypeKind::SignedLong:
161     BuiltinStr = "Li";
162     return;
163   case ScalarTypeKind::Boolean:
164     assert(ElementBitwidth == 1);
165     BuiltinStr += "b";
166     break;
167   case ScalarTypeKind::SignedInteger:
168   case ScalarTypeKind::UnsignedInteger:
169     switch (ElementBitwidth) {
170     case 8:
171       BuiltinStr += "c";
172       break;
173     case 16:
174       BuiltinStr += "s";
175       break;
176     case 32:
177       BuiltinStr += "i";
178       break;
179     case 64:
180       BuiltinStr += "Wi";
181       break;
182     default:
183       llvm_unreachable("Unhandled ElementBitwidth!");
184     }
185     if (isSignedInteger())
186       BuiltinStr = "S" + BuiltinStr;
187     else
188       BuiltinStr = "U" + BuiltinStr;
189     break;
190   case ScalarTypeKind::Float:
191     switch (ElementBitwidth) {
192     case 16:
193       BuiltinStr += "x";
194       break;
195     case 32:
196       BuiltinStr += "f";
197       break;
198     case 64:
199       BuiltinStr += "d";
200       break;
201     default:
202       llvm_unreachable("Unhandled ElementBitwidth!");
203     }
204     break;
205   case ScalarTypeKind::BFloat:
206     BuiltinStr += "y";
207     break;
208   default:
209     llvm_unreachable("ScalarType is invalid!");
210   }
211   if (IsImmediate)
212     BuiltinStr = "I" + BuiltinStr;
213   if (isScalar()) {
214     if (IsConstant)
215       BuiltinStr += "C";
216     if (IsPointer)
217       BuiltinStr += "*";
218     return;
219   }
220   BuiltinStr = "q" + utostr(*Scale) + BuiltinStr;
221   // Pointer to vector types. Defined for segment load intrinsics.
222   // segment load intrinsics have pointer type arguments to store the loaded
223   // vector values.
224   if (IsPointer)
225     BuiltinStr += "*";
226 
227   if (IsTuple)
228     BuiltinStr = "T" + utostr(NF) + BuiltinStr;
229 }
230 
231 void RVVType::initClangBuiltinStr() {
232   assert(isValid() && "RVVType is invalid");
233   assert(isVector() && "Handle Vector type only");
234 
235   ClangBuiltinStr = "__rvv_";
236   switch (ScalarType) {
237   case ScalarTypeKind::Boolean:
238     ClangBuiltinStr += "bool" + utostr(64 / *Scale) + "_t";
239     return;
240   case ScalarTypeKind::Float:
241     ClangBuiltinStr += "float";
242     break;
243   case ScalarTypeKind::BFloat:
244     ClangBuiltinStr += "bfloat";
245     break;
246   case ScalarTypeKind::SignedInteger:
247     ClangBuiltinStr += "int";
248     break;
249   case ScalarTypeKind::UnsignedInteger:
250     ClangBuiltinStr += "uint";
251     break;
252   default:
253     llvm_unreachable("ScalarTypeKind is invalid");
254   }
255   ClangBuiltinStr += utostr(ElementBitwidth) + LMUL.str() +
256                      (IsTuple ? "x" + utostr(NF) : "") + "_t";
257 }
258 
259 void RVVType::initTypeStr() {
260   assert(isValid() && "RVVType is invalid");
261 
262   if (IsConstant)
263     Str += "const ";
264 
265   auto getTypeString = [&](StringRef TypeStr) {
266     if (isScalar())
267       return Twine(TypeStr + Twine(ElementBitwidth) + "_t").str();
268     return Twine("v" + TypeStr + Twine(ElementBitwidth) + LMUL.str() +
269                  (IsTuple ? "x" + utostr(NF) : "") + "_t")
270         .str();
271   };
272 
273   switch (ScalarType) {
274   case ScalarTypeKind::Void:
275     Str = "void";
276     return;
277   case ScalarTypeKind::Size_t:
278     Str = "size_t";
279     if (IsPointer)
280       Str += " *";
281     return;
282   case ScalarTypeKind::Ptrdiff_t:
283     Str = "ptrdiff_t";
284     return;
285   case ScalarTypeKind::UnsignedLong:
286     Str = "unsigned long";
287     return;
288   case ScalarTypeKind::SignedLong:
289     Str = "long";
290     return;
291   case ScalarTypeKind::Boolean:
292     if (isScalar())
293       Str += "bool";
294     else
295       // Vector bool is special case, the formulate is
296       // `vbool<N>_t = MVT::nxv<64/N>i1` ex. vbool16_t = MVT::4i1
297       Str += "vbool" + utostr(64 / *Scale) + "_t";
298     break;
299   case ScalarTypeKind::Float:
300     if (isScalar()) {
301       if (ElementBitwidth == 64)
302         Str += "double";
303       else if (ElementBitwidth == 32)
304         Str += "float";
305       else if (ElementBitwidth == 16)
306         Str += "_Float16";
307       else
308         llvm_unreachable("Unhandled floating type.");
309     } else
310       Str += getTypeString("float");
311     break;
312   case ScalarTypeKind::BFloat:
313     if (isScalar()) {
314       if (ElementBitwidth == 16)
315         Str += "__bf16";
316       else
317         llvm_unreachable("Unhandled floating type.");
318     } else
319       Str += getTypeString("bfloat");
320     break;
321   case ScalarTypeKind::SignedInteger:
322     Str += getTypeString("int");
323     break;
324   case ScalarTypeKind::UnsignedInteger:
325     Str += getTypeString("uint");
326     break;
327   default:
328     llvm_unreachable("ScalarType is invalid!");
329   }
330   if (IsPointer)
331     Str += " *";
332 }
333 
334 void RVVType::initShortStr() {
335   switch (ScalarType) {
336   case ScalarTypeKind::Boolean:
337     assert(isVector());
338     ShortStr = "b" + utostr(64 / *Scale);
339     return;
340   case ScalarTypeKind::Float:
341     ShortStr = "f" + utostr(ElementBitwidth);
342     break;
343   case ScalarTypeKind::BFloat:
344     ShortStr = "bf" + utostr(ElementBitwidth);
345     break;
346   case ScalarTypeKind::SignedInteger:
347     ShortStr = "i" + utostr(ElementBitwidth);
348     break;
349   case ScalarTypeKind::UnsignedInteger:
350     ShortStr = "u" + utostr(ElementBitwidth);
351     break;
352   default:
353     llvm_unreachable("Unhandled case!");
354   }
355   if (isVector())
356     ShortStr += LMUL.str();
357   if (isTuple())
358     ShortStr += "x" + utostr(NF);
359 }
360 
361 static VectorTypeModifier getTupleVTM(unsigned NF) {
362   assert(2 <= NF && NF <= 8 && "2 <= NF <= 8");
363   return static_cast<VectorTypeModifier>(
364       static_cast<uint8_t>(VectorTypeModifier::Tuple2) + (NF - 2));
365 }
366 
367 void RVVType::applyBasicType() {
368   switch (BT) {
369   case BasicType::Int8:
370     ElementBitwidth = 8;
371     ScalarType = ScalarTypeKind::SignedInteger;
372     break;
373   case BasicType::Int16:
374     ElementBitwidth = 16;
375     ScalarType = ScalarTypeKind::SignedInteger;
376     break;
377   case BasicType::Int32:
378     ElementBitwidth = 32;
379     ScalarType = ScalarTypeKind::SignedInteger;
380     break;
381   case BasicType::Int64:
382     ElementBitwidth = 64;
383     ScalarType = ScalarTypeKind::SignedInteger;
384     break;
385   case BasicType::Float16:
386     ElementBitwidth = 16;
387     ScalarType = ScalarTypeKind::Float;
388     break;
389   case BasicType::Float32:
390     ElementBitwidth = 32;
391     ScalarType = ScalarTypeKind::Float;
392     break;
393   case BasicType::Float64:
394     ElementBitwidth = 64;
395     ScalarType = ScalarTypeKind::Float;
396     break;
397   case BasicType::BFloat16:
398     ElementBitwidth = 16;
399     ScalarType = ScalarTypeKind::BFloat;
400     break;
401   default:
402     llvm_unreachable("Unhandled type code!");
403   }
404   assert(ElementBitwidth != 0 && "Bad element bitwidth!");
405 }
406 
407 std::optional<PrototypeDescriptor>
408 PrototypeDescriptor::parsePrototypeDescriptor(
409     llvm::StringRef PrototypeDescriptorStr) {
410   PrototypeDescriptor PD;
411   BaseTypeModifier PT = BaseTypeModifier::Invalid;
412   VectorTypeModifier VTM = VectorTypeModifier::NoModifier;
413 
414   if (PrototypeDescriptorStr.empty())
415     return PD;
416 
417   // Handle base type modifier
418   auto PType = PrototypeDescriptorStr.back();
419   switch (PType) {
420   case 'e':
421     PT = BaseTypeModifier::Scalar;
422     break;
423   case 'v':
424     PT = BaseTypeModifier::Vector;
425     break;
426   case 'w':
427     PT = BaseTypeModifier::Vector;
428     VTM = VectorTypeModifier::Widening2XVector;
429     break;
430   case 'q':
431     PT = BaseTypeModifier::Vector;
432     VTM = VectorTypeModifier::Widening4XVector;
433     break;
434   case 'o':
435     PT = BaseTypeModifier::Vector;
436     VTM = VectorTypeModifier::Widening8XVector;
437     break;
438   case 'm':
439     PT = BaseTypeModifier::Vector;
440     VTM = VectorTypeModifier::MaskVector;
441     break;
442   case '0':
443     PT = BaseTypeModifier::Void;
444     break;
445   case 'z':
446     PT = BaseTypeModifier::SizeT;
447     break;
448   case 't':
449     PT = BaseTypeModifier::Ptrdiff;
450     break;
451   case 'u':
452     PT = BaseTypeModifier::UnsignedLong;
453     break;
454   case 'l':
455     PT = BaseTypeModifier::SignedLong;
456     break;
457   case 'f':
458     PT = BaseTypeModifier::Float32;
459     break;
460   default:
461     llvm_unreachable("Illegal primitive type transformers!");
462   }
463   PD.PT = static_cast<uint8_t>(PT);
464   PrototypeDescriptorStr = PrototypeDescriptorStr.drop_back();
465 
466   // Compute the vector type transformers, it can only appear one time.
467   if (PrototypeDescriptorStr.starts_with("(")) {
468     assert(VTM == VectorTypeModifier::NoModifier &&
469            "VectorTypeModifier should only have one modifier");
470     size_t Idx = PrototypeDescriptorStr.find(')');
471     assert(Idx != StringRef::npos);
472     StringRef ComplexType = PrototypeDescriptorStr.slice(1, Idx);
473     PrototypeDescriptorStr = PrototypeDescriptorStr.drop_front(Idx + 1);
474     assert(!PrototypeDescriptorStr.contains('(') &&
475            "Only allow one vector type modifier");
476 
477     auto ComplexTT = ComplexType.split(":");
478     if (ComplexTT.first == "Log2EEW") {
479       uint32_t Log2EEW;
480       if (ComplexTT.second.getAsInteger(10, Log2EEW)) {
481         llvm_unreachable("Invalid Log2EEW value!");
482         return std::nullopt;
483       }
484       switch (Log2EEW) {
485       case 3:
486         VTM = VectorTypeModifier::Log2EEW3;
487         break;
488       case 4:
489         VTM = VectorTypeModifier::Log2EEW4;
490         break;
491       case 5:
492         VTM = VectorTypeModifier::Log2EEW5;
493         break;
494       case 6:
495         VTM = VectorTypeModifier::Log2EEW6;
496         break;
497       default:
498         llvm_unreachable("Invalid Log2EEW value, should be [3-6]");
499         return std::nullopt;
500       }
501     } else if (ComplexTT.first == "FixedSEW") {
502       uint32_t NewSEW;
503       if (ComplexTT.second.getAsInteger(10, NewSEW)) {
504         llvm_unreachable("Invalid FixedSEW value!");
505         return std::nullopt;
506       }
507       switch (NewSEW) {
508       case 8:
509         VTM = VectorTypeModifier::FixedSEW8;
510         break;
511       case 16:
512         VTM = VectorTypeModifier::FixedSEW16;
513         break;
514       case 32:
515         VTM = VectorTypeModifier::FixedSEW32;
516         break;
517       case 64:
518         VTM = VectorTypeModifier::FixedSEW64;
519         break;
520       default:
521         llvm_unreachable("Invalid FixedSEW value, should be 8, 16, 32 or 64");
522         return std::nullopt;
523       }
524     } else if (ComplexTT.first == "LFixedLog2LMUL") {
525       int32_t Log2LMUL;
526       if (ComplexTT.second.getAsInteger(10, Log2LMUL)) {
527         llvm_unreachable("Invalid LFixedLog2LMUL value!");
528         return std::nullopt;
529       }
530       switch (Log2LMUL) {
531       case -3:
532         VTM = VectorTypeModifier::LFixedLog2LMULN3;
533         break;
534       case -2:
535         VTM = VectorTypeModifier::LFixedLog2LMULN2;
536         break;
537       case -1:
538         VTM = VectorTypeModifier::LFixedLog2LMULN1;
539         break;
540       case 0:
541         VTM = VectorTypeModifier::LFixedLog2LMUL0;
542         break;
543       case 1:
544         VTM = VectorTypeModifier::LFixedLog2LMUL1;
545         break;
546       case 2:
547         VTM = VectorTypeModifier::LFixedLog2LMUL2;
548         break;
549       case 3:
550         VTM = VectorTypeModifier::LFixedLog2LMUL3;
551         break;
552       default:
553         llvm_unreachable("Invalid LFixedLog2LMUL value, should be [-3, 3]");
554         return std::nullopt;
555       }
556     } else if (ComplexTT.first == "SFixedLog2LMUL") {
557       int32_t Log2LMUL;
558       if (ComplexTT.second.getAsInteger(10, Log2LMUL)) {
559         llvm_unreachable("Invalid SFixedLog2LMUL value!");
560         return std::nullopt;
561       }
562       switch (Log2LMUL) {
563       case -3:
564         VTM = VectorTypeModifier::SFixedLog2LMULN3;
565         break;
566       case -2:
567         VTM = VectorTypeModifier::SFixedLog2LMULN2;
568         break;
569       case -1:
570         VTM = VectorTypeModifier::SFixedLog2LMULN1;
571         break;
572       case 0:
573         VTM = VectorTypeModifier::SFixedLog2LMUL0;
574         break;
575       case 1:
576         VTM = VectorTypeModifier::SFixedLog2LMUL1;
577         break;
578       case 2:
579         VTM = VectorTypeModifier::SFixedLog2LMUL2;
580         break;
581       case 3:
582         VTM = VectorTypeModifier::SFixedLog2LMUL3;
583         break;
584       default:
585         llvm_unreachable("Invalid LFixedLog2LMUL value, should be [-3, 3]");
586         return std::nullopt;
587       }
588 
589     } else if (ComplexTT.first == "SEFixedLog2LMUL") {
590       int32_t Log2LMUL;
591       if (ComplexTT.second.getAsInteger(10, Log2LMUL)) {
592         llvm_unreachable("Invalid SEFixedLog2LMUL value!");
593         return std::nullopt;
594       }
595       switch (Log2LMUL) {
596       case -3:
597         VTM = VectorTypeModifier::SEFixedLog2LMULN3;
598         break;
599       case -2:
600         VTM = VectorTypeModifier::SEFixedLog2LMULN2;
601         break;
602       case -1:
603         VTM = VectorTypeModifier::SEFixedLog2LMULN1;
604         break;
605       case 0:
606         VTM = VectorTypeModifier::SEFixedLog2LMUL0;
607         break;
608       case 1:
609         VTM = VectorTypeModifier::SEFixedLog2LMUL1;
610         break;
611       case 2:
612         VTM = VectorTypeModifier::SEFixedLog2LMUL2;
613         break;
614       case 3:
615         VTM = VectorTypeModifier::SEFixedLog2LMUL3;
616         break;
617       default:
618         llvm_unreachable("Invalid LFixedLog2LMUL value, should be [-3, 3]");
619         return std::nullopt;
620       }
621     } else if (ComplexTT.first == "Tuple") {
622       unsigned NF = 0;
623       if (ComplexTT.second.getAsInteger(10, NF)) {
624         llvm_unreachable("Invalid NF value!");
625         return std::nullopt;
626       }
627       VTM = getTupleVTM(NF);
628     } else {
629       llvm_unreachable("Illegal complex type transformers!");
630     }
631   }
632   PD.VTM = static_cast<uint8_t>(VTM);
633 
634   // Compute the remain type transformers
635   TypeModifier TM = TypeModifier::NoModifier;
636   for (char I : PrototypeDescriptorStr) {
637     switch (I) {
638     case 'P':
639       if ((TM & TypeModifier::Const) == TypeModifier::Const)
640         llvm_unreachable("'P' transformer cannot be used after 'C'");
641       if ((TM & TypeModifier::Pointer) == TypeModifier::Pointer)
642         llvm_unreachable("'P' transformer cannot be used twice");
643       TM |= TypeModifier::Pointer;
644       break;
645     case 'C':
646       TM |= TypeModifier::Const;
647       break;
648     case 'K':
649       TM |= TypeModifier::Immediate;
650       break;
651     case 'U':
652       TM |= TypeModifier::UnsignedInteger;
653       break;
654     case 'I':
655       TM |= TypeModifier::SignedInteger;
656       break;
657     case 'F':
658       TM |= TypeModifier::Float;
659       break;
660     case 'S':
661       TM |= TypeModifier::LMUL1;
662       break;
663     default:
664       llvm_unreachable("Illegal non-primitive type transformer!");
665     }
666   }
667   PD.TM = static_cast<uint8_t>(TM);
668 
669   return PD;
670 }
671 
672 void RVVType::applyModifier(const PrototypeDescriptor &Transformer) {
673   // Handle primitive type transformer
674   switch (static_cast<BaseTypeModifier>(Transformer.PT)) {
675   case BaseTypeModifier::Scalar:
676     Scale = 0;
677     break;
678   case BaseTypeModifier::Vector:
679     Scale = LMUL.getScale(ElementBitwidth);
680     break;
681   case BaseTypeModifier::Void:
682     ScalarType = ScalarTypeKind::Void;
683     break;
684   case BaseTypeModifier::SizeT:
685     ScalarType = ScalarTypeKind::Size_t;
686     break;
687   case BaseTypeModifier::Ptrdiff:
688     ScalarType = ScalarTypeKind::Ptrdiff_t;
689     break;
690   case BaseTypeModifier::UnsignedLong:
691     ScalarType = ScalarTypeKind::UnsignedLong;
692     break;
693   case BaseTypeModifier::SignedLong:
694     ScalarType = ScalarTypeKind::SignedLong;
695     break;
696   case BaseTypeModifier::Float32:
697     ElementBitwidth = 32;
698     ScalarType = ScalarTypeKind::Float;
699     break;
700   case BaseTypeModifier::Invalid:
701     ScalarType = ScalarTypeKind::Invalid;
702     return;
703   }
704 
705   switch (static_cast<VectorTypeModifier>(Transformer.VTM)) {
706   case VectorTypeModifier::Widening2XVector:
707     ElementBitwidth *= 2;
708     LMUL.MulLog2LMUL(1);
709     Scale = LMUL.getScale(ElementBitwidth);
710     break;
711   case VectorTypeModifier::Widening4XVector:
712     ElementBitwidth *= 4;
713     LMUL.MulLog2LMUL(2);
714     Scale = LMUL.getScale(ElementBitwidth);
715     break;
716   case VectorTypeModifier::Widening8XVector:
717     ElementBitwidth *= 8;
718     LMUL.MulLog2LMUL(3);
719     Scale = LMUL.getScale(ElementBitwidth);
720     break;
721   case VectorTypeModifier::MaskVector:
722     ScalarType = ScalarTypeKind::Boolean;
723     Scale = LMUL.getScale(ElementBitwidth);
724     ElementBitwidth = 1;
725     break;
726   case VectorTypeModifier::Log2EEW3:
727     applyLog2EEW(3);
728     break;
729   case VectorTypeModifier::Log2EEW4:
730     applyLog2EEW(4);
731     break;
732   case VectorTypeModifier::Log2EEW5:
733     applyLog2EEW(5);
734     break;
735   case VectorTypeModifier::Log2EEW6:
736     applyLog2EEW(6);
737     break;
738   case VectorTypeModifier::FixedSEW8:
739     applyFixedSEW(8);
740     break;
741   case VectorTypeModifier::FixedSEW16:
742     applyFixedSEW(16);
743     break;
744   case VectorTypeModifier::FixedSEW32:
745     applyFixedSEW(32);
746     break;
747   case VectorTypeModifier::FixedSEW64:
748     applyFixedSEW(64);
749     break;
750   case VectorTypeModifier::LFixedLog2LMULN3:
751     applyFixedLog2LMUL(-3, FixedLMULType::LargerThan);
752     break;
753   case VectorTypeModifier::LFixedLog2LMULN2:
754     applyFixedLog2LMUL(-2, FixedLMULType::LargerThan);
755     break;
756   case VectorTypeModifier::LFixedLog2LMULN1:
757     applyFixedLog2LMUL(-1, FixedLMULType::LargerThan);
758     break;
759   case VectorTypeModifier::LFixedLog2LMUL0:
760     applyFixedLog2LMUL(0, FixedLMULType::LargerThan);
761     break;
762   case VectorTypeModifier::LFixedLog2LMUL1:
763     applyFixedLog2LMUL(1, FixedLMULType::LargerThan);
764     break;
765   case VectorTypeModifier::LFixedLog2LMUL2:
766     applyFixedLog2LMUL(2, FixedLMULType::LargerThan);
767     break;
768   case VectorTypeModifier::LFixedLog2LMUL3:
769     applyFixedLog2LMUL(3, FixedLMULType::LargerThan);
770     break;
771   case VectorTypeModifier::SFixedLog2LMULN3:
772     applyFixedLog2LMUL(-3, FixedLMULType::SmallerThan);
773     break;
774   case VectorTypeModifier::SFixedLog2LMULN2:
775     applyFixedLog2LMUL(-2, FixedLMULType::SmallerThan);
776     break;
777   case VectorTypeModifier::SFixedLog2LMULN1:
778     applyFixedLog2LMUL(-1, FixedLMULType::SmallerThan);
779     break;
780   case VectorTypeModifier::SFixedLog2LMUL0:
781     applyFixedLog2LMUL(0, FixedLMULType::SmallerThan);
782     break;
783   case VectorTypeModifier::SFixedLog2LMUL1:
784     applyFixedLog2LMUL(1, FixedLMULType::SmallerThan);
785     break;
786   case VectorTypeModifier::SFixedLog2LMUL2:
787     applyFixedLog2LMUL(2, FixedLMULType::SmallerThan);
788     break;
789   case VectorTypeModifier::SFixedLog2LMUL3:
790     applyFixedLog2LMUL(3, FixedLMULType::SmallerThan);
791     break;
792   case VectorTypeModifier::SEFixedLog2LMULN3:
793     applyFixedLog2LMUL(-3, FixedLMULType::SmallerOrEqual);
794     break;
795   case VectorTypeModifier::SEFixedLog2LMULN2:
796     applyFixedLog2LMUL(-2, FixedLMULType::SmallerOrEqual);
797     break;
798   case VectorTypeModifier::SEFixedLog2LMULN1:
799     applyFixedLog2LMUL(-1, FixedLMULType::SmallerOrEqual);
800     break;
801   case VectorTypeModifier::SEFixedLog2LMUL0:
802     applyFixedLog2LMUL(0, FixedLMULType::SmallerOrEqual);
803     break;
804   case VectorTypeModifier::SEFixedLog2LMUL1:
805     applyFixedLog2LMUL(1, FixedLMULType::SmallerOrEqual);
806     break;
807   case VectorTypeModifier::SEFixedLog2LMUL2:
808     applyFixedLog2LMUL(2, FixedLMULType::SmallerOrEqual);
809     break;
810   case VectorTypeModifier::SEFixedLog2LMUL3:
811     applyFixedLog2LMUL(3, FixedLMULType::SmallerOrEqual);
812     break;
813   case VectorTypeModifier::Tuple2:
814   case VectorTypeModifier::Tuple3:
815   case VectorTypeModifier::Tuple4:
816   case VectorTypeModifier::Tuple5:
817   case VectorTypeModifier::Tuple6:
818   case VectorTypeModifier::Tuple7:
819   case VectorTypeModifier::Tuple8: {
820     IsTuple = true;
821     NF = 2 + static_cast<uint8_t>(Transformer.VTM) -
822          static_cast<uint8_t>(VectorTypeModifier::Tuple2);
823     break;
824   }
825   case VectorTypeModifier::NoModifier:
826     break;
827   }
828 
829   // Early return if the current type modifier is already invalid.
830   if (ScalarType == Invalid)
831     return;
832 
833   for (unsigned TypeModifierMaskShift = 0;
834        TypeModifierMaskShift <= static_cast<unsigned>(TypeModifier::MaxOffset);
835        ++TypeModifierMaskShift) {
836     unsigned TypeModifierMask = 1 << TypeModifierMaskShift;
837     if ((static_cast<unsigned>(Transformer.TM) & TypeModifierMask) !=
838         TypeModifierMask)
839       continue;
840     switch (static_cast<TypeModifier>(TypeModifierMask)) {
841     case TypeModifier::Pointer:
842       IsPointer = true;
843       break;
844     case TypeModifier::Const:
845       IsConstant = true;
846       break;
847     case TypeModifier::Immediate:
848       IsImmediate = true;
849       IsConstant = true;
850       break;
851     case TypeModifier::UnsignedInteger:
852       ScalarType = ScalarTypeKind::UnsignedInteger;
853       break;
854     case TypeModifier::SignedInteger:
855       ScalarType = ScalarTypeKind::SignedInteger;
856       break;
857     case TypeModifier::Float:
858       ScalarType = ScalarTypeKind::Float;
859       break;
860     case TypeModifier::BFloat:
861       ScalarType = ScalarTypeKind::BFloat;
862       break;
863     case TypeModifier::LMUL1:
864       LMUL = LMULType(0);
865       // Update ElementBitwidth need to update Scale too.
866       Scale = LMUL.getScale(ElementBitwidth);
867       break;
868     default:
869       llvm_unreachable("Unknown type modifier mask!");
870     }
871   }
872 }
873 
874 void RVVType::applyLog2EEW(unsigned Log2EEW) {
875   // update new elmul = (eew/sew) * lmul
876   LMUL.MulLog2LMUL(Log2EEW - Log2_32(ElementBitwidth));
877   // update new eew
878   ElementBitwidth = 1 << Log2EEW;
879   ScalarType = ScalarTypeKind::SignedInteger;
880   Scale = LMUL.getScale(ElementBitwidth);
881 }
882 
883 void RVVType::applyFixedSEW(unsigned NewSEW) {
884   // Set invalid type if src and dst SEW are same.
885   if (ElementBitwidth == NewSEW) {
886     ScalarType = ScalarTypeKind::Invalid;
887     return;
888   }
889   // Update new SEW
890   ElementBitwidth = NewSEW;
891   Scale = LMUL.getScale(ElementBitwidth);
892 }
893 
894 void RVVType::applyFixedLog2LMUL(int Log2LMUL, enum FixedLMULType Type) {
895   switch (Type) {
896   case FixedLMULType::LargerThan:
897     if (Log2LMUL <= LMUL.Log2LMUL) {
898       ScalarType = ScalarTypeKind::Invalid;
899       return;
900     }
901     break;
902   case FixedLMULType::SmallerThan:
903     if (Log2LMUL >= LMUL.Log2LMUL) {
904       ScalarType = ScalarTypeKind::Invalid;
905       return;
906     }
907     break;
908   case FixedLMULType::SmallerOrEqual:
909     if (Log2LMUL > LMUL.Log2LMUL) {
910       ScalarType = ScalarTypeKind::Invalid;
911       return;
912     }
913     break;
914   }
915 
916   // Update new LMUL
917   LMUL = LMULType(Log2LMUL);
918   Scale = LMUL.getScale(ElementBitwidth);
919 }
920 
921 std::optional<RVVTypes>
922 RVVTypeCache::computeTypes(BasicType BT, int Log2LMUL, unsigned NF,
923                            ArrayRef<PrototypeDescriptor> Prototype) {
924   RVVTypes Types;
925   for (const PrototypeDescriptor &Proto : Prototype) {
926     auto T = computeType(BT, Log2LMUL, Proto);
927     if (!T)
928       return std::nullopt;
929     // Record legal type index
930     Types.push_back(*T);
931   }
932   return Types;
933 }
934 
935 // Compute the hash value of RVVType, used for cache the result of computeType.
936 static uint64_t computeRVVTypeHashValue(BasicType BT, int Log2LMUL,
937                                         PrototypeDescriptor Proto) {
938   // Layout of hash value:
939   // 0               8    16          24        32          40
940   // | Log2LMUL + 3  | BT  | Proto.PT | Proto.TM | Proto.VTM |
941   assert(Log2LMUL >= -3 && Log2LMUL <= 3);
942   return (Log2LMUL + 3) | (static_cast<uint64_t>(BT) & 0xff) << 8 |
943          ((uint64_t)(Proto.PT & 0xff) << 16) |
944          ((uint64_t)(Proto.TM & 0xff) << 24) |
945          ((uint64_t)(Proto.VTM & 0xff) << 32);
946 }
947 
948 std::optional<RVVTypePtr> RVVTypeCache::computeType(BasicType BT, int Log2LMUL,
949                                                     PrototypeDescriptor Proto) {
950   uint64_t Idx = computeRVVTypeHashValue(BT, Log2LMUL, Proto);
951   // Search first
952   auto It = LegalTypes.find(Idx);
953   if (It != LegalTypes.end())
954     return &(It->second);
955 
956   if (IllegalTypes.count(Idx))
957     return std::nullopt;
958 
959   // Compute type and record the result.
960   RVVType T(BT, Log2LMUL, Proto);
961   if (T.isValid()) {
962     // Record legal type index and value.
963     std::pair<std::unordered_map<uint64_t, RVVType>::iterator, bool>
964         InsertResult = LegalTypes.insert({Idx, T});
965     return &(InsertResult.first->second);
966   }
967   // Record illegal type index.
968   IllegalTypes.insert(Idx);
969   return std::nullopt;
970 }
971 
972 //===----------------------------------------------------------------------===//
973 // RVVIntrinsic implementation
974 //===----------------------------------------------------------------------===//
975 RVVIntrinsic::RVVIntrinsic(
976     StringRef NewName, StringRef Suffix, StringRef NewOverloadedName,
977     StringRef OverloadedSuffix, StringRef IRName, bool IsMasked,
978     bool HasMaskedOffOperand, bool HasVL, PolicyScheme Scheme,
979     bool SupportOverloading, bool HasBuiltinAlias, StringRef ManualCodegen,
980     const RVVTypes &OutInTypes, const std::vector<int64_t> &NewIntrinsicTypes,
981     const std::vector<StringRef> &RequiredFeatures, unsigned NF,
982     Policy NewPolicyAttrs, bool HasFRMRoundModeOp)
983     : IRName(IRName), IsMasked(IsMasked),
984       HasMaskedOffOperand(HasMaskedOffOperand), HasVL(HasVL), Scheme(Scheme),
985       SupportOverloading(SupportOverloading), HasBuiltinAlias(HasBuiltinAlias),
986       ManualCodegen(ManualCodegen.str()), NF(NF), PolicyAttrs(NewPolicyAttrs) {
987 
988   // Init BuiltinName, Name and OverloadedName
989   BuiltinName = NewName.str();
990   Name = BuiltinName;
991   if (NewOverloadedName.empty())
992     OverloadedName = NewName.split("_").first.str();
993   else
994     OverloadedName = NewOverloadedName.str();
995   if (!Suffix.empty())
996     Name += "_" + Suffix.str();
997   if (!OverloadedSuffix.empty())
998     OverloadedName += "_" + OverloadedSuffix.str();
999 
1000   updateNamesAndPolicy(IsMasked, hasPolicy(), Name, BuiltinName, OverloadedName,
1001                        PolicyAttrs, HasFRMRoundModeOp);
1002 
1003   // Init OutputType and InputTypes
1004   OutputType = OutInTypes[0];
1005   InputTypes.assign(OutInTypes.begin() + 1, OutInTypes.end());
1006 
1007   // IntrinsicTypes is unmasked TA version index. Need to update it
1008   // if there is merge operand (It is always in first operand).
1009   IntrinsicTypes = NewIntrinsicTypes;
1010   if ((IsMasked && hasMaskedOffOperand()) ||
1011       (!IsMasked && hasPassthruOperand())) {
1012     for (auto &I : IntrinsicTypes) {
1013       if (I >= 0)
1014         I += NF;
1015     }
1016   }
1017 }
1018 
1019 std::string RVVIntrinsic::getBuiltinTypeStr() const {
1020   std::string S;
1021   S += OutputType->getBuiltinStr();
1022   for (const auto &T : InputTypes) {
1023     S += T->getBuiltinStr();
1024   }
1025   return S;
1026 }
1027 
1028 std::string RVVIntrinsic::getSuffixStr(
1029     RVVTypeCache &TypeCache, BasicType Type, int Log2LMUL,
1030     llvm::ArrayRef<PrototypeDescriptor> PrototypeDescriptors) {
1031   SmallVector<std::string> SuffixStrs;
1032   for (auto PD : PrototypeDescriptors) {
1033     auto T = TypeCache.computeType(Type, Log2LMUL, PD);
1034     SuffixStrs.push_back((*T)->getShortStr());
1035   }
1036   return join(SuffixStrs, "_");
1037 }
1038 
1039 llvm::SmallVector<PrototypeDescriptor> RVVIntrinsic::computeBuiltinTypes(
1040     llvm::ArrayRef<PrototypeDescriptor> Prototype, bool IsMasked,
1041     bool HasMaskedOffOperand, bool HasVL, unsigned NF,
1042     PolicyScheme DefaultScheme, Policy PolicyAttrs, bool IsTuple) {
1043   SmallVector<PrototypeDescriptor> NewPrototype(Prototype.begin(),
1044                                                 Prototype.end());
1045   bool HasPassthruOp = DefaultScheme == PolicyScheme::HasPassthruOperand;
1046   if (IsMasked) {
1047     // If HasMaskedOffOperand, insert result type as first input operand if
1048     // need.
1049     if (HasMaskedOffOperand && !PolicyAttrs.isTAMAPolicy()) {
1050       if (NF == 1) {
1051         NewPrototype.insert(NewPrototype.begin() + 1, NewPrototype[0]);
1052       } else if (NF > 1) {
1053         if (IsTuple) {
1054           PrototypeDescriptor BasePtrOperand = Prototype[1];
1055           PrototypeDescriptor MaskoffType = PrototypeDescriptor(
1056               static_cast<uint8_t>(BaseTypeModifier::Vector),
1057               static_cast<uint8_t>(getTupleVTM(NF)),
1058               BasePtrOperand.TM & ~static_cast<uint8_t>(TypeModifier::Pointer));
1059           NewPrototype.insert(NewPrototype.begin() + 1, MaskoffType);
1060         } else {
1061           // Convert
1062           // (void, op0 address, op1 address, ...)
1063           // to
1064           // (void, op0 address, op1 address, ..., maskedoff0, maskedoff1, ...)
1065           PrototypeDescriptor MaskoffType = NewPrototype[1];
1066           MaskoffType.TM &= ~static_cast<uint8_t>(TypeModifier::Pointer);
1067           NewPrototype.insert(NewPrototype.begin() + NF + 1, NF, MaskoffType);
1068         }
1069       }
1070     }
1071     if (HasMaskedOffOperand && NF > 1) {
1072       // Convert
1073       // (void, op0 address, op1 address, ..., maskedoff0, maskedoff1, ...)
1074       // to
1075       // (void, op0 address, op1 address, ..., mask, maskedoff0, maskedoff1,
1076       // ...)
1077       if (IsTuple)
1078         NewPrototype.insert(NewPrototype.begin() + 1,
1079                             PrototypeDescriptor::Mask);
1080       else
1081         NewPrototype.insert(NewPrototype.begin() + NF + 1,
1082                             PrototypeDescriptor::Mask);
1083     } else {
1084       // If IsMasked, insert PrototypeDescriptor:Mask as first input operand.
1085       NewPrototype.insert(NewPrototype.begin() + 1, PrototypeDescriptor::Mask);
1086     }
1087   } else {
1088     if (NF == 1) {
1089       if (PolicyAttrs.isTUPolicy() && HasPassthruOp)
1090         NewPrototype.insert(NewPrototype.begin(), NewPrototype[0]);
1091     } else if (PolicyAttrs.isTUPolicy() && HasPassthruOp) {
1092       if (IsTuple) {
1093         PrototypeDescriptor BasePtrOperand = Prototype[0];
1094         PrototypeDescriptor MaskoffType = PrototypeDescriptor(
1095             static_cast<uint8_t>(BaseTypeModifier::Vector),
1096             static_cast<uint8_t>(getTupleVTM(NF)),
1097             BasePtrOperand.TM & ~static_cast<uint8_t>(TypeModifier::Pointer));
1098         NewPrototype.insert(NewPrototype.begin(), MaskoffType);
1099       } else {
1100         // NF > 1 cases for segment load operations.
1101         // Convert
1102         // (void, op0 address, op1 address, ...)
1103         // to
1104         // (void, op0 address, op1 address, maskedoff0, maskedoff1, ...)
1105         PrototypeDescriptor MaskoffType = Prototype[1];
1106         MaskoffType.TM &= ~static_cast<uint8_t>(TypeModifier::Pointer);
1107         NewPrototype.insert(NewPrototype.begin() + NF + 1, NF, MaskoffType);
1108       }
1109     }
1110  }
1111 
1112   // If HasVL, append PrototypeDescriptor:VL to last operand
1113   if (HasVL)
1114     NewPrototype.push_back(PrototypeDescriptor::VL);
1115 
1116   return NewPrototype;
1117 }
1118 
1119 llvm::SmallVector<Policy> RVVIntrinsic::getSupportedUnMaskedPolicies() {
1120   return {Policy(Policy::PolicyType::Undisturbed)}; // TU
1121 }
1122 
1123 llvm::SmallVector<Policy>
1124 RVVIntrinsic::getSupportedMaskedPolicies(bool HasTailPolicy,
1125                                          bool HasMaskPolicy) {
1126   if (HasTailPolicy && HasMaskPolicy)
1127     return {Policy(Policy::PolicyType::Undisturbed,
1128                    Policy::PolicyType::Agnostic), // TUM
1129             Policy(Policy::PolicyType::Undisturbed,
1130                    Policy::PolicyType::Undisturbed), // TUMU
1131             Policy(Policy::PolicyType::Agnostic,
1132                    Policy::PolicyType::Undisturbed)}; // MU
1133   if (HasTailPolicy && !HasMaskPolicy)
1134     return {Policy(Policy::PolicyType::Undisturbed,
1135                    Policy::PolicyType::Agnostic)}; // TU
1136   if (!HasTailPolicy && HasMaskPolicy)
1137     return {Policy(Policy::PolicyType::Agnostic,
1138                    Policy::PolicyType::Undisturbed)}; // MU
1139   llvm_unreachable("An RVV instruction should not be without both tail policy "
1140                    "and mask policy");
1141 }
1142 
1143 void RVVIntrinsic::updateNamesAndPolicy(
1144     bool IsMasked, bool HasPolicy, std::string &Name, std::string &BuiltinName,
1145     std::string &OverloadedName, Policy &PolicyAttrs, bool HasFRMRoundModeOp) {
1146 
1147   auto appendPolicySuffix = [&](const std::string &suffix) {
1148     Name += suffix;
1149     BuiltinName += suffix;
1150     OverloadedName += suffix;
1151   };
1152 
1153   // This follows the naming guideline under riscv-c-api-doc to add the
1154   // `__riscv_` suffix for all RVV intrinsics.
1155   Name = "__riscv_" + Name;
1156   OverloadedName = "__riscv_" + OverloadedName;
1157 
1158   if (HasFRMRoundModeOp) {
1159     Name += "_rm";
1160     BuiltinName += "_rm";
1161   }
1162 
1163   if (IsMasked) {
1164     if (PolicyAttrs.isTUMUPolicy())
1165       appendPolicySuffix("_tumu");
1166     else if (PolicyAttrs.isTUMAPolicy())
1167       appendPolicySuffix("_tum");
1168     else if (PolicyAttrs.isTAMUPolicy())
1169       appendPolicySuffix("_mu");
1170     else if (PolicyAttrs.isTAMAPolicy()) {
1171       Name += "_m";
1172       BuiltinName += "_m";
1173     } else
1174       llvm_unreachable("Unhandled policy condition");
1175   } else {
1176     if (PolicyAttrs.isTUPolicy())
1177       appendPolicySuffix("_tu");
1178     else if (PolicyAttrs.isTAPolicy()) // no suffix needed
1179       return;
1180     else
1181       llvm_unreachable("Unhandled policy condition");
1182   }
1183 }
1184 
1185 SmallVector<PrototypeDescriptor> parsePrototypes(StringRef Prototypes) {
1186   SmallVector<PrototypeDescriptor> PrototypeDescriptors;
1187   const StringRef Primaries("evwqom0ztulf");
1188   while (!Prototypes.empty()) {
1189     size_t Idx = 0;
1190     // Skip over complex prototype because it could contain primitive type
1191     // character.
1192     if (Prototypes[0] == '(')
1193       Idx = Prototypes.find_first_of(')');
1194     Idx = Prototypes.find_first_of(Primaries, Idx);
1195     assert(Idx != StringRef::npos);
1196     auto PD = PrototypeDescriptor::parsePrototypeDescriptor(
1197         Prototypes.slice(0, Idx + 1));
1198     if (!PD)
1199       llvm_unreachable("Error during parsing prototype.");
1200     PrototypeDescriptors.push_back(*PD);
1201     Prototypes = Prototypes.drop_front(Idx + 1);
1202   }
1203   return PrototypeDescriptors;
1204 }
1205 
1206 raw_ostream &operator<<(raw_ostream &OS, const RVVIntrinsicRecord &Record) {
1207   OS << "{";
1208   OS << "\"" << Record.Name << "\",";
1209   if (Record.OverloadedName == nullptr ||
1210       StringRef(Record.OverloadedName).empty())
1211     OS << "nullptr,";
1212   else
1213     OS << "\"" << Record.OverloadedName << "\",";
1214   OS << Record.PrototypeIndex << ",";
1215   OS << Record.SuffixIndex << ",";
1216   OS << Record.OverloadedSuffixIndex << ",";
1217   OS << (int)Record.PrototypeLength << ",";
1218   OS << (int)Record.SuffixLength << ",";
1219   OS << (int)Record.OverloadedSuffixSize << ",";
1220   OS << Record.RequiredExtensions << ",";
1221   OS << (int)Record.TypeRangeMask << ",";
1222   OS << (int)Record.Log2LMULMask << ",";
1223   OS << (int)Record.NF << ",";
1224   OS << (int)Record.HasMasked << ",";
1225   OS << (int)Record.HasVL << ",";
1226   OS << (int)Record.HasMaskedOffOperand << ",";
1227   OS << (int)Record.HasTailPolicy << ",";
1228   OS << (int)Record.HasMaskPolicy << ",";
1229   OS << (int)Record.HasFRMRoundModeOp << ",";
1230   OS << (int)Record.IsTuple << ",";
1231   OS << (int)Record.UnMaskedPolicyScheme << ",";
1232   OS << (int)Record.MaskedPolicyScheme << ",";
1233   OS << "},\n";
1234   return OS;
1235 }
1236 
1237 } // end namespace RISCV
1238 } // end namespace clang
1239