//===- LLVMToSPIRVDbgTran.cpp - Converts debug info to SPIR-V ---*- C++ -*-===// // // The LLVM/SPIR-V Translator // // This file is distributed under the University of Illinois Open Source // License. See LICENSE.TXT for details. // // Copyright (c) 2018 Intel Corporation. All rights reserved. // // Permission is hereby granted, free of charge, to any person obtaining a // copy of this software and associated documentation files (the "Software"), // to deal with the Software without restriction, including without limitation // the rights to use, copy, modify, merge, publish, distribute, sublicense, // and/or sell copies of the Software, and to permit persons to whom the // Software is furnished to do so, subject to the following conditions: // // Redistributions of source code must retain the above copyright notice, // this list of conditions and the following disclaimers. // Redistributions in binary form must reproduce the above copyright notice, // this list of conditions and the following disclaimers in the documentation // and/or other materials provided with the distribution. // Neither the names of Intel Corporation, nor the names of its // contributors may be used to endorse or promote products derived from this // Software without specific prior written permission. // THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR // IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, // FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE // CONTRIBUTORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER // LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, // OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS WITH // THE SOFTWARE. // //===----------------------------------------------------------------------===// // // This file implements translation of debug info from LLVM metadata to SPIR-V // //===----------------------------------------------------------------------===// #include "LLVMToSPIRVDbgTran.h" #include "SPIRV.debug.h" #include "SPIRVWriter.h" #include "llvm/IR/DebugInfo.h" #include "llvm/IR/DebugInfoMetadata.h" using namespace SPIRV; // Public interface /// This function is looking for debug information in the LLVM module /// and translates it to SPIRV void LLVMToSPIRVDbgTran::transDebugMetadata() { DIF.processModule(*M); if (DIF.compile_unit_count() == 0) return; if (isNonSemanticDebugInfo()) { if (!BM->isAllowedToUseVersion(VersionNumber::SPIRV_1_6)) BM->addExtension(SPIRV::ExtensionID::SPV_KHR_non_semantic_info); else BM->setMinSPIRVVersion(VersionNumber::SPIRV_1_6); } for (DICompileUnit *CU : DIF.compile_units()) { transDbgEntry(CU); for (DIImportedEntity *IE : CU->getImportedEntities()) transDbgEntry(IE); } for (const DIType *T : DIF.types()) transDbgEntry(T); // When translating a debug lexical block, we expect the translation of its // parent scope (say it's a subprogram) already been created in MDMap. // Otherwise, we have to dive into the details of subprogram translation // first. During this process, we will try to resolve all retainedNodes // (aka, variables) owned by this subprogram. // And local variable's scope could be the original lexical block that we // haven't finish translating yet. In other words, the block hasn't been // inserted into MDMap cache yet. // So we try to invoke transDbgEntryImpl on the same lexical block again, // then we get a duplicated lexical block messing up the debug info. // // Scheduling the translation of subprograms ahead of scopes (lexical blocks) // solves this dependency cycle issue. for (const DISubprogram *F : DIF.subprograms()) transDbgEntry(F); for (const DIScope *S : DIF.scopes()) transDbgEntry(S); for (const DIGlobalVariableExpression *G : DIF.global_variables()) { transDbgEntry(G->getVariable()); } for (const DbgVariableIntrinsic *DDI : DbgDeclareIntrinsics) finalizeDebugDeclare(DDI); for (const DbgVariableIntrinsic *DVI : DbgValueIntrinsics) finalizeDebugValue(DVI); transLocationInfo(); } // llvm.dbg.declare intrinsic. SPIRVValue *LLVMToSPIRVDbgTran::createDebugDeclarePlaceholder( const DbgVariableIntrinsic *DbgDecl, SPIRVBasicBlock *BB) { DbgDeclareIntrinsics.push_back(DbgDecl); using namespace SPIRVDebug::Operand::DebugDeclare; SPIRVWordVec Ops(OperandCount, getDebugInfoNoneId()); SPIRVId ExtSetId = BM->getExtInstSetId(BM->getDebugInfoEIS()); return BM->addExtInst(getVoidTy(), ExtSetId, SPIRVDebug::Declare, Ops, BB); } void LLVMToSPIRVDbgTran::finalizeDebugDeclare( const DbgVariableIntrinsic *DbgDecl) { SPIRVValue *V = SPIRVWriter->getTranslatedValue(DbgDecl); assert(V && "llvm.dbg.declare intrinsic isn't mapped to a SPIRV instruction"); assert(V->isExtInst(BM->getDebugInfoEIS(), SPIRVDebug::Declare) && "llvm.dbg.declare intrinsic has been translated wrong!"); if (!V || !V->isExtInst(BM->getDebugInfoEIS(), SPIRVDebug::Declare)) return; SPIRVExtInst *DD = static_cast(V); SPIRVBasicBlock *BB = DD->getBasicBlock(); llvm::Value *Alloca = DbgDecl->getVariableLocationOp(0); using namespace SPIRVDebug::Operand::DebugDeclare; SPIRVWordVec Ops(OperandCount); Ops[DebugLocalVarIdx] = transDbgEntry(DbgDecl->getVariable())->getId(); Ops[VariableIdx] = Alloca ? SPIRVWriter->transValue(Alloca, BB)->getId() : getDebugInfoNoneId(); Ops[ExpressionIdx] = transDbgEntry(DbgDecl->getExpression())->getId(); DD->setArguments(Ops); } // llvm.dbg.value intrinsic. SPIRVValue *LLVMToSPIRVDbgTran::createDebugValuePlaceholder( const DbgVariableIntrinsic *DbgValue, SPIRVBasicBlock *BB) { if (!DbgValue->getVariableLocationOp(0)) return nullptr; // It is pointless without new value DbgValueIntrinsics.push_back(DbgValue); using namespace SPIRVDebug::Operand::DebugValue; SPIRVWordVec Ops(MinOperandCount, getDebugInfoNone()->getId()); SPIRVId ExtSetId = BM->getExtInstSetId(BM->getDebugInfoEIS()); return BM->addExtInst(getVoidTy(), ExtSetId, SPIRVDebug::Value, Ops, BB); } void LLVMToSPIRVDbgTran::finalizeDebugValue( const DbgVariableIntrinsic *DbgValue) { SPIRVValue *V = SPIRVWriter->getTranslatedValue(DbgValue); assert(V && "llvm.dbg.value intrinsic isn't mapped to a SPIRV instruction"); assert(V->isExtInst(BM->getDebugInfoEIS(), SPIRVDebug::Value) && "llvm.dbg.value intrinsic has been translated wrong!"); if (!V || !V->isExtInst(BM->getDebugInfoEIS(), SPIRVDebug::Value)) return; SPIRVExtInst *DV = static_cast(V); SPIRVBasicBlock *BB = DV->getBasicBlock(); Value *Val = DbgValue->getVariableLocationOp(0); DIExpression *Expr = DbgValue->getExpression(); if (DbgValue->getNumVariableLocationOps() > 1) { Val = UndefValue::get(Val->getType()); Expr = DIExpression::get(M->getContext(), {}); } using namespace SPIRVDebug::Operand::DebugValue; SPIRVWordVec Ops(MinOperandCount); Ops[DebugLocalVarIdx] = transDbgEntry(DbgValue->getVariable())->getId(); Ops[ValueIdx] = SPIRVWriter->transValue(Val, BB)->getId(); Ops[ExpressionIdx] = transDbgEntry(Expr)->getId(); DV->setArguments(Ops); } // Emitting DebugScope and OpLine instructions void LLVMToSPIRVDbgTran::transLocationInfo() { for (const Function &F : *M) { for (const BasicBlock &BB : F) { SPIRVValue *V = SPIRVWriter->getTranslatedValue(&BB); assert(V && V->isBasicBlock() && "Basic block is expected to be translated"); SPIRVBasicBlock *SBB = static_cast(V); MDNode *DbgScope = nullptr; MDNode *InlinedAt = nullptr; SPIRVString *File = nullptr; unsigned LineNo = 0; unsigned Col = 0; for (const Instruction &I : BB) { if (auto *II = dyn_cast(&I)) { if (II->getIntrinsicID() == Intrinsic::dbg_label) { // SPIR-V doesn't support llvm.dbg.label intrinsic translation continue; } if (II->getIntrinsicID() == Intrinsic::annotation || II->getIntrinsicID() == Intrinsic::var_annotation || II->getIntrinsicID() == Intrinsic::ptr_annotation) { // llvm call instruction for llvm .*annotation intrinsics // is translated into SPIR-V instruction only if it represents // call of __builtin_intel_fpga_reg() builtin. In other cases this // instruction is dropped. In these cases debug info for this call // should be skipped too. // TODO: Remove skipping of debug info when *.annotation call will // be handled in a better way during SPIR-V translation. V = SPIRVWriter->getTranslatedValue(&I); if (!V || V->getOpCode() != OpFPGARegINTEL) continue; } } V = SPIRVWriter->getTranslatedValue(&I); if (!V || isConstantOpCode(V->getOpCode())) continue; const DebugLoc &DL = I.getDebugLoc(); if (!DL.get()) { if (DbgScope || InlinedAt) { // Emit DebugNoScope DbgScope = nullptr; InlinedAt = nullptr; transDebugLoc(DL, SBB, static_cast(V)); } continue; } // Once scope or inlining has changed emit another DebugScope if (DL.getScope() != DbgScope || DL.getInlinedAt() != InlinedAt) { DbgScope = DL.getScope(); InlinedAt = DL.getInlinedAt(); transDebugLoc(DL, SBB, static_cast(V)); } // If any component of OpLine has changed emit another OpLine SPIRVString *DirAndFile = BM->getString(getFullPath(DL.get())); if (File != DirAndFile || LineNo != DL.getLine() || Col != DL.getCol()) { File = DirAndFile; LineNo = DL.getLine(); Col = DL.getCol(); // According to the spec, OpLine for an OpBranch/OpBranchConditional // must precede the merge instruction and not the branch instruction if (V->getOpCode() == OpBranch || V->getOpCode() == OpBranchConditional) { auto *VPrev = static_cast(V)->getPrevious(); if (VPrev && (VPrev->getOpCode() == OpLoopMerge || VPrev->getOpCode() == OpLoopControlINTEL)) { V = VPrev; } } if (BM->getDebugInfoEIS() == SPIRVEIS_NonSemantic_Shader_DebugInfo_100 || BM->getDebugInfoEIS() == SPIRVEIS_NonSemantic_Shader_DebugInfo_200) BM->addDebugLine(V, getVoidTy(), File ? File->getId() : getDebugInfoNoneId(), LineNo, LineNo, Col, Col + 1); else BM->addLine(V, File ? File->getId() : getDebugInfoNoneId(), LineNo, Col); } } // Instructions } // Basic Blocks } // Functions } // Translation of single debug entry SPIRVEntry *LLVMToSPIRVDbgTran::transDbgEntry(const MDNode *DIEntry) { // Caching auto It = MDMap.find(DIEntry); if (It != MDMap.end()) { assert(It->second && "Invalid SPIRVEntry is cached!"); return It->second; } SPIRVEntry *Res = transDbgEntryImpl(DIEntry); assert(Res && "Translation failure"); // We might end up having a recursive debug info generation like the // following: // translation of DIDerivedType (member) calls DICompositeType translation // as its parent scope; // translation of DICompositeType calls translation of its members // (DIDerivedType with member tag). // Here we make only the latest of these instructions be cached and hence // reused // FIXME: find a way to not create dead instruction if (MDMap[DIEntry]) return MDMap[DIEntry]; MDMap[DIEntry] = Res; return Res; } // Dispatcher implementation SPIRVEntry *LLVMToSPIRVDbgTran::transDbgEntryImpl(const MDNode *MDN) { if (!MDN) return BM->addDebugInfo(SPIRVDebug::DebugInfoNone, getVoidTy(), SPIRVWordVec()); if (const DINode *DIEntry = dyn_cast(MDN)) { switch (DIEntry->getTag()) { // Types case dwarf::DW_TAG_base_type: case dwarf::DW_TAG_unspecified_type: return transDbgBaseType(cast(DIEntry)); case dwarf::DW_TAG_reference_type: case dwarf::DW_TAG_rvalue_reference_type: case dwarf::DW_TAG_pointer_type: return transDbgPointerType(cast(DIEntry)); case dwarf::DW_TAG_array_type: return transDbgArrayType(cast(DIEntry)); case dwarf::DW_TAG_subrange_type: if (BM->getDebugInfoEIS() == SPIRVEIS_NonSemantic_Shader_DebugInfo_200) return transDbgSubrangeType(cast(DIEntry)); else return getDebugInfoNone(); case dwarf::DW_TAG_string_type: { if (BM->getDebugInfoEIS() == SPIRVEIS_NonSemantic_Shader_DebugInfo_200) return transDbgStringType(cast(DIEntry)); return getDebugInfoNone(); } case dwarf::DW_TAG_const_type: case dwarf::DW_TAG_restrict_type: case dwarf::DW_TAG_volatile_type: case dwarf::DW_TAG_atomic_type: return transDbgQualifiedType(cast(DIEntry)); case dwarf::DW_TAG_subroutine_type: return transDbgSubroutineType(cast(DIEntry)); case dwarf::DW_TAG_class_type: case dwarf::DW_TAG_structure_type: case dwarf::DW_TAG_union_type: return transDbgCompositeType(cast(DIEntry)); case dwarf::DW_TAG_member: return transDbgMemberType(cast(DIEntry)); case dwarf::DW_TAG_inheritance: return transDbgInheritance(cast(DIEntry)); case dwarf::DW_TAG_enumeration_type: return transDbgEnumType(cast(DIEntry)); case dwarf::DW_TAG_file_type: return transDbgFileType(cast(DIEntry)); case dwarf::DW_TAG_typedef: return transDbgTypeDef(cast(DIEntry)); case dwarf::DW_TAG_ptr_to_member_type: return transDbgPtrToMember(cast(DIEntry)); // Scope case dwarf::DW_TAG_namespace: case dwarf::DW_TAG_lexical_block: return transDbgScope(cast(DIEntry)); // Function case dwarf::DW_TAG_subprogram: return transDbgFunction(cast(DIEntry)); // Variables case dwarf::DW_TAG_variable: if (const DILocalVariable *LV = dyn_cast(DIEntry)) return transDbgLocalVariable(LV); if (const DIGlobalVariable *GV = dyn_cast(DIEntry)) return transDbgGlobalVariable(GV); llvm_unreachable("Unxpected debug info type for variable"); case dwarf::DW_TAG_formal_parameter: return transDbgLocalVariable(cast(DIEntry)); // Compilation unit case dwarf::DW_TAG_compile_unit: return transDbgCompileUnit(cast(DIEntry)); // Templates case dwarf::DW_TAG_template_type_parameter: case dwarf::DW_TAG_template_value_parameter: return transDbgTemplateParameter(cast(DIEntry)); case dwarf::DW_TAG_GNU_template_template_param: return transDbgTemplateTemplateParameter( cast(DIEntry)); case dwarf::DW_TAG_GNU_template_parameter_pack: return transDbgTemplateParameterPack( cast(DIEntry)); case dwarf::DW_TAG_imported_module: case dwarf::DW_TAG_imported_declaration: return transDbgImportedEntry(cast(DIEntry)); case dwarf::DW_TAG_module: { if (BM->isAllowedToUseExtension(ExtensionID::SPV_INTEL_debug_module) || BM->getDebugInfoEIS() == SPIRVEIS_NonSemantic_Shader_DebugInfo_200) return transDbgModule(cast(DIEntry)); return getDebugInfoNone(); } default: return getDebugInfoNone(); } } if (const DIExpression *Expr = dyn_cast(MDN)) return transDbgExpression(Expr); if (const DILocation *Loc = dyn_cast(MDN)) { return transDbgInlinedAt(Loc); } llvm_unreachable("Not implemented debug info entry!"); } // Helper methods SPIRVType *LLVMToSPIRVDbgTran::getVoidTy() { if (!VoidT) { assert(M && "Pointer to LLVM Module is expected to be initialized!"); // Cache void type in a member. VoidT = SPIRVWriter->transType(Type::getVoidTy(M->getContext())); } return VoidT; } SPIRVType *LLVMToSPIRVDbgTran::getInt32Ty() { if (!Int32T) { assert(M && "Pointer to LLVM Module is expected to be initialized!"); // Cache int32 type in a member. Int32T = SPIRVWriter->transType(Type::getInt32Ty(M->getContext())); } return Int32T; } SPIRVEntry *LLVMToSPIRVDbgTran::getScope(DIScope *S) { if (S) return transDbgEntry(S); assert(!SPIRVCUMap.empty() && "Compile units are expected to be already translated"); return SPIRVCUMap.begin()->second; } SPIRVEntry *LLVMToSPIRVDbgTran::getGlobalVariable(const DIGlobalVariable *GV) { for (GlobalVariable &V : M->globals()) { SmallVector GVs; V.getDebugInfo(GVs); for (DIGlobalVariableExpression *GVE : GVs) { if (GVE->getVariable() == GV) return SPIRVWriter->transValue(&V, nullptr); } } return getDebugInfoNone(); } inline bool LLVMToSPIRVDbgTran::isNonSemanticDebugInfo() { return (BM->getDebugInfoEIS() == SPIRVEIS_NonSemantic_Shader_DebugInfo_100 || BM->getDebugInfoEIS() == SPIRVEIS_NonSemantic_Shader_DebugInfo_200); } void LLVMToSPIRVDbgTran::transformToConstant(std::vector &Ops, std::vector Idxs) { for (const auto Idx : Idxs) { SPIRVValue *Const = BM->addIntegerConstant( static_cast(getInt32Ty()), Ops[Idx]); Ops[Idx] = Const->getId(); } } SPIRVWord LLVMToSPIRVDbgTran::mapDebugFlags(DINode::DIFlags DFlags) { SPIRVWord Flags = 0; if ((DFlags & DINode::FlagAccessibility) == DINode::FlagPublic) Flags |= SPIRVDebug::FlagIsPublic; if ((DFlags & DINode::FlagAccessibility) == DINode::FlagProtected) Flags |= SPIRVDebug::FlagIsProtected; if ((DFlags & DINode::FlagAccessibility) == DINode::FlagPrivate) Flags |= SPIRVDebug::FlagIsPrivate; if (DFlags & DINode::FlagFwdDecl) Flags |= SPIRVDebug::FlagIsFwdDecl; if (DFlags & DINode::FlagArtificial) Flags |= SPIRVDebug::FlagIsArtificial; if (DFlags & DINode::FlagExplicit) Flags |= SPIRVDebug::FlagIsExplicit; if (DFlags & DINode::FlagPrototyped) Flags |= SPIRVDebug::FlagIsPrototyped; if (DFlags & DINode::FlagObjectPointer) Flags |= SPIRVDebug::FlagIsObjectPointer; if (DFlags & DINode::FlagStaticMember) Flags |= SPIRVDebug::FlagIsStaticMember; // inderect variable flag ? if (DFlags & DINode::FlagLValueReference) Flags |= SPIRVDebug::FlagIsLValueReference; if (DFlags & DINode::FlagRValueReference) Flags |= SPIRVDebug::FlagIsRValueReference; if (DFlags & DINode::FlagTypePassByValue) Flags |= SPIRVDebug::FlagTypePassByValue; if (DFlags & DINode::FlagTypePassByReference) Flags |= SPIRVDebug::FlagTypePassByReference; if (BM->getDebugInfoEIS() == SPIRVEIS_NonSemantic_Shader_DebugInfo_200) if (DFlags & DINode::FlagBitField) Flags |= SPIRVDebug::FlagBitField; return Flags; } SPIRVWord LLVMToSPIRVDbgTran::transDebugFlags(const DINode *DN) { SPIRVWord Flags = 0; if (const DIGlobalVariable *GV = dyn_cast(DN)) { if (GV->isLocalToUnit()) Flags |= SPIRVDebug::FlagIsLocal; if (GV->isDefinition()) Flags |= SPIRVDebug::FlagIsDefinition; } if (const DISubprogram *DS = dyn_cast(DN)) { if (DS->isLocalToUnit()) Flags |= SPIRVDebug::FlagIsLocal; if (DS->isOptimized()) Flags |= SPIRVDebug::FlagIsOptimized; if (DS->isDefinition()) Flags |= SPIRVDebug::FlagIsDefinition; Flags |= mapDebugFlags(DS->getFlags()); } if (DN->getTag() == dwarf::DW_TAG_reference_type) Flags |= SPIRVDebug::FlagIsLValueReference; if (DN->getTag() == dwarf::DW_TAG_rvalue_reference_type) Flags |= SPIRVDebug::FlagIsRValueReference; if (const DIType *DT = dyn_cast(DN)) Flags |= mapDebugFlags(DT->getFlags()); if (const DILocalVariable *DLocVar = dyn_cast(DN)) Flags |= mapDebugFlags(DLocVar->getFlags()); return Flags; } /// Clang doesn't emit access flags for members with default access specifier /// See clang/lib/CodeGen/CGDebugInfo.cpp: getAccessFlag() /// In SPIR-V we set the flags even for members with default access specifier SPIRVWord adjustAccessFlags(DIScope *Scope, SPIRVWord Flags) { if (Scope && (Flags & SPIRVDebug::FlagAccess) == 0) { unsigned Tag = Scope->getTag(); if (Tag == dwarf::DW_TAG_class_type) Flags |= SPIRVDebug::FlagIsPrivate; else if (Tag == dwarf::DW_TAG_structure_type || Tag == dwarf::DW_TAG_union_type) Flags |= SPIRVDebug::FlagIsPublic; } return Flags; } // Fortran dynamic arrays can have following 'dataLocation', 'associated' // 'allocated' and 'rank' debug metadata. Such arrays are being mapped on // DebugTypeArrayDynamic from NonSemantic.Shader.200 debug spec inline bool isFortranArrayDynamic(const DICompositeType *AT) { return (AT->getRawDataLocation() || AT->getRawAssociated() || AT->getRawAllocated() || AT->getRawRank()); } /// The following methods (till the end of the file) implement translation of /// debug instrtuctions described in the spec. // Absent Debug Info SPIRVEntry *LLVMToSPIRVDbgTran::getDebugInfoNone() { if (!DebugInfoNone) { DebugInfoNone = transDbgEntry(nullptr); } return DebugInfoNone; } SPIRVId LLVMToSPIRVDbgTran::getDebugInfoNoneId() { return getDebugInfoNone()->getId(); } // Compilation unit SPIRVEntry *LLVMToSPIRVDbgTran::transDbgCompileUnit(const DICompileUnit *CU) { using namespace SPIRVDebug::Operand::CompilationUnit; SPIRVWordVec Ops(MinOperandCount); Ops[SPIRVDebugInfoVersionIdx] = SPIRVDebug::DebugInfoVersion; Ops[DWARFVersionIdx] = M->getDwarfVersion(); Ops[SourceIdx] = getSource(CU)->getId(); if (isNonSemanticDebugInfo()) generateBuildIdentifierAndStoragePath(CU); auto DwarfLang = static_cast(CU->getSourceLanguage()); Ops[LanguageIdx] = BM->getDebugInfoEIS() == SPIRVEIS_NonSemantic_Shader_DebugInfo_200 ? convertDWARFSourceLangToSPIRVNonSemanticDbgInfo(DwarfLang) : convertDWARFSourceLangToSPIRV(DwarfLang); if (isNonSemanticDebugInfo()) transformToConstant( Ops, {SPIRVDebugInfoVersionIdx, DWARFVersionIdx, LanguageIdx}); if (isNonSemanticDebugInfo()) { if (BM->getDebugInfoEIS() == SPIRVEIS_NonSemantic_Shader_DebugInfo_200) { Ops.push_back(BM->getString(CU->getProducer().str())->getId()); } } else { // TODO: Remove this workaround once we switch to NonSemantic.Shader.* debug // info by default BM->addModuleProcessed(SPIRVDebug::ProducerPrefix + CU->getProducer().str()); } // Cache CU in a member. SPIRVCUMap[CU] = static_cast( BM->addDebugInfo(SPIRVDebug::CompilationUnit, getVoidTy(), Ops)); return SPIRVCUMap[CU]; } // Types SPIRVEntry *LLVMToSPIRVDbgTran::transDbgBaseType(const DIBasicType *BT) { using namespace SPIRVDebug::Operand::TypeBasic; SPIRVWordVec Ops(OperandCountOCL); Ops[NameIdx] = BM->getString(BT->getName().str())->getId(); ConstantInt *Size = getUInt(M, BT->getSizeInBits()); Ops[SizeIdx] = SPIRVWriter->transValue(Size, nullptr)->getId(); auto Encoding = static_cast(BT->getEncoding()); SPIRVDebug::EncodingTag EncTag = SPIRVDebug::Unspecified; SPIRV::DbgEncodingMap::find(Encoding, &EncTag); // Unset encoding if it's complex and NonSemantic.Shader.DebugInfo.200 is not // enabled if (EncTag == SPIRVDebug::Complex && BM->getDebugInfoEIS() != SPIRVEIS_NonSemantic_Shader_DebugInfo_200) EncTag = SPIRVDebug::Unspecified; Ops[EncodingIdx] = EncTag; if (isNonSemanticDebugInfo()) { transformToConstant(Ops, {EncodingIdx}); // Flags value could not be generated by clang or by LLVM environment. Ops.push_back(getDebugInfoNoneId()); } return BM->addDebugInfo(SPIRVDebug::TypeBasic, getVoidTy(), Ops); } SPIRVEntry *LLVMToSPIRVDbgTran::transDbgPointerType(const DIDerivedType *PT) { using namespace SPIRVDebug::Operand::TypePointer; SPIRVWordVec Ops(OperandCount); SPIRVEntry *Base = transDbgEntry(PT->getBaseType()); Ops[BaseTypeIdx] = Base->getId(); Ops[StorageClassIdx] = ~0U; // all ones denote no address space Optional AS = PT->getDWARFAddressSpace(); if (AS.hasValue()) { SPIRAddressSpace SPIRAS = static_cast(AS.getValue()); Ops[StorageClassIdx] = SPIRSPIRVAddrSpaceMap::map(SPIRAS); } Ops[FlagsIdx] = transDebugFlags(PT); if (isNonSemanticDebugInfo()) transformToConstant(Ops, {StorageClassIdx, FlagsIdx}); SPIRVEntry *Res = BM->addDebugInfo(SPIRVDebug::TypePointer, getVoidTy(), Ops); return Res; } SPIRVEntry *LLVMToSPIRVDbgTran::transDbgQualifiedType(const DIDerivedType *QT) { using namespace SPIRVDebug::Operand::TypeQualifier; SPIRVWordVec Ops(OperandCount); SPIRVEntry *Base = transDbgEntry(QT->getBaseType()); Ops[BaseTypeIdx] = Base->getId(); Ops[QualifierIdx] = SPIRV::DbgTypeQulifierMap::map( static_cast(QT->getTag())); if (isNonSemanticDebugInfo()) transformToConstant(Ops, {QualifierIdx}); return BM->addDebugInfo(SPIRVDebug::TypeQualifier, getVoidTy(), Ops); } SPIRVEntry *LLVMToSPIRVDbgTran::transDbgArrayType(const DICompositeType *AT) { if (BM->getDebugInfoEIS() == SPIRVEIS_NonSemantic_Shader_DebugInfo_200) { if (isFortranArrayDynamic(AT)) return transDbgArrayTypeDynamic(AT); return transDbgArrayTypeNonSemantic(AT); } return transDbgArrayTypeOpenCL(AT); } SPIRVEntry * LLVMToSPIRVDbgTran::transDbgArrayTypeOpenCL(const DICompositeType *AT) { using namespace SPIRVDebug::Operand::TypeArray; SPIRVWordVec Ops(MinOperandCount); Ops[BaseTypeIdx] = transDbgEntry(AT->getBaseType())->getId(); DINodeArray AR(AT->getElements()); // For N-dimensianal arrays AR.getNumElements() == N const unsigned N = AR.size(); Ops.resize(ComponentCountIdx + N); SPIRVWordVec LowerBounds(N); for (unsigned I = 0; I < N; ++I) { DISubrange *SR = cast(AR[I]); ConstantInt *Count = SR->getCount().get(); if (AT->isVector()) { assert(N == 1 && "Multidimensional vector is not expected!"); Ops[ComponentCountIdx] = static_cast(Count->getZExtValue()); if (isNonSemanticDebugInfo()) transformToConstant(Ops, {ComponentCountIdx}); return BM->addDebugInfo(SPIRVDebug::TypeVector, getVoidTy(), Ops); } if (Count) { Ops[ComponentCountIdx + I] = SPIRVWriter->transValue(Count, nullptr)->getId(); } else { if (auto *UpperBound = dyn_cast(SR->getRawUpperBound())) Ops[ComponentCountIdx + I] = transDbgEntry(UpperBound)->getId(); else Ops[ComponentCountIdx + I] = getDebugInfoNoneId(); } if (auto *RawLB = SR->getRawLowerBound()) { if (auto *DIExprLB = dyn_cast(RawLB)) LowerBounds[I] = transDbgEntry(DIExprLB)->getId(); else { ConstantInt *ConstIntLB = SR->getLowerBound().get(); LowerBounds[I] = SPIRVWriter->transValue(ConstIntLB, nullptr)->getId(); } } else { LowerBounds[I] = getDebugInfoNoneId(); } } Ops.insert(Ops.end(), LowerBounds.begin(), LowerBounds.end()); return BM->addDebugInfo(SPIRVDebug::TypeArray, getVoidTy(), Ops); } SPIRVEntry * LLVMToSPIRVDbgTran::transDbgArrayTypeNonSemantic(const DICompositeType *AT) { using namespace SPIRVDebug::Operand::TypeArray; SPIRVWordVec Ops(MinOperandCount); Ops[BaseTypeIdx] = transDbgEntry(AT->getBaseType())->getId(); DINodeArray AR(AT->getElements()); // For N-dimensianal arrays AR.getNumElements() == N const unsigned N = AR.size(); Ops.resize(SubrangesIdx + N); for (unsigned I = 0; I < N; ++I) { DISubrange *SR = cast(AR[I]); ConstantInt *Count = SR->getCount().get(); if (AT->isVector()) { assert(N == 1 && "Multidimensional vector is not expected!"); Ops[ComponentCountIdx] = static_cast(Count->getZExtValue()); if (isNonSemanticDebugInfo()) transformToConstant(Ops, {ComponentCountIdx}); return BM->addDebugInfo(SPIRVDebug::TypeVector, getVoidTy(), Ops); } Ops[SubrangesIdx + I] = transDbgEntry(SR)->getId(); } return BM->addDebugInfo(SPIRVDebug::TypeArray, getVoidTy(), Ops); } // The function is used to translate Fortran's dynamic arrays SPIRVEntry * LLVMToSPIRVDbgTran::transDbgArrayTypeDynamic(const DICompositeType *AT) { using namespace SPIRVDebug::Operand::TypeArrayDynamic; SPIRVWordVec Ops(MinOperandCount); Ops[BaseTypeIdx] = transDbgEntry(AT->getBaseType())->getId(); // DataLocation, Associated, Allocated and Rank can be either DIExpression // metadata or DIVariable auto TransOperand = [&](llvm::Metadata *DIMD) -> SPIRVWord { if (auto *DIExpr = dyn_cast_or_null(DIMD)) return transDbgExpression(DIExpr)->getId(); if (auto *DIVar = dyn_cast_or_null(DIMD)) { if (const DILocalVariable *LV = dyn_cast(DIVar)) return transDbgLocalVariable(LV)->getId(); if (const DIGlobalVariable *GV = dyn_cast(DIVar)) return transDbgGlobalVariable(GV)->getId(); } return getDebugInfoNoneId(); }; Ops[DataLocationIdx] = TransOperand(AT->getRawDataLocation()); Ops[AssociatedIdx] = TransOperand(AT->getRawAssociated()); Ops[AllocatedIdx] = TransOperand(AT->getRawAllocated()); Ops[RankIdx] = TransOperand(AT->getRawRank()); DINodeArray AR(AT->getElements()); // For N-dimensianal arrays AR.getNumElements() == N const unsigned N = AR.size(); Ops.resize(SubrangesIdx + N); for (unsigned I = 0; I < N; ++I) { DISubrange *SR = cast(AR[I]); Ops[SubrangesIdx + I] = transDbgEntry(SR)->getId(); } return BM->addDebugInfo(SPIRVDebug::TypeArrayDynamic, getVoidTy(), Ops); } SPIRVEntry *LLVMToSPIRVDbgTran::transDbgSubrangeType(const DISubrange *ST) { using namespace SPIRVDebug::Operand::TypeSubrange; SPIRVWordVec Ops(OperandCount); auto TransOperand = [&Ops, this, ST](int Idx) -> void { Metadata *RawNode = nullptr; switch (Idx) { case LowerBoundIdx: RawNode = ST->getRawLowerBound(); break; case UpperBoundIdx: RawNode = ST->getRawUpperBound(); break; case CountIdx: RawNode = ST->getRawCountNode(); break; case StrideIdx: RawNode = ST->getRawStride(); break; } if (!RawNode) { Ops[Idx] = getDebugInfoNoneId(); return; } if (auto *Node = dyn_cast(RawNode)) { Ops[Idx] = transDbgEntry(Node)->getId(); } else { ConstantInt *IntNode = nullptr; switch (Idx) { case LowerBoundIdx: IntNode = ST->getLowerBound().get(); break; case UpperBoundIdx: IntNode = ST->getUpperBound().get(); break; case CountIdx: IntNode = ST->getCount().get(); break; case StrideIdx: IntNode = ST->getStride().get(); break; } Ops[Idx] = IntNode ? SPIRVWriter->transValue(IntNode, nullptr)->getId() : getDebugInfoNoneId(); } }; for (int Idx = CountIdx; Idx < OperandCount; ++Idx) TransOperand(Idx); return BM->addDebugInfo(SPIRVDebug::TypeSubrange, getVoidTy(), Ops); } SPIRVEntry *LLVMToSPIRVDbgTran::transDbgStringType(const DIStringType *ST) { using namespace SPIRVDebug::Operand::TypeString; SPIRVWordVec Ops(MinOperandCount); Ops[NameIdx] = BM->getString(ST->getName().str())->getId(); Ops[BaseTypeIdx] = ST->getEncoding() ? getDebugInfoNoneId() /*TODO: replace with basetype*/ : getDebugInfoNoneId(); auto TransOperand = [&](llvm::Metadata *DIMD) -> SPIRVWord { if (auto *DIExpr = dyn_cast_or_null(DIMD)) return transDbgExpression(DIExpr)->getId(); if (auto *DIVar = dyn_cast_or_null(DIMD)) { if (const DILocalVariable *LV = dyn_cast(DIVar)) return transDbgLocalVariable(LV)->getId(); if (const DIGlobalVariable *GV = dyn_cast(DIVar)) return transDbgGlobalVariable(GV)->getId(); } return getDebugInfoNoneId(); }; Ops[DataLocationIdx] = TransOperand(ST->getRawStringLocationExp()); ConstantInt *Size = getUInt(M, ST->getSizeInBits()); Ops[SizeIdx] = SPIRVWriter->transValue(Size, nullptr)->getId(); if (auto *StrLengthExp = ST->getRawStringLengthExp()) { Ops[LengthAddrIdx] = TransOperand(StrLengthExp); } else if (auto *StrLengthVar = ST->getRawStringLength()) { Ops[LengthAddrIdx] = TransOperand(StrLengthVar); } else { Ops[LengthAddrIdx] = getDebugInfoNoneId(); } return BM->addDebugInfo(SPIRVDebug::TypeString, getVoidTy(), Ops); } SPIRVEntry *LLVMToSPIRVDbgTran::transDbgTypeDef(const DIDerivedType *DT) { using namespace SPIRVDebug::Operand::Typedef; SPIRVWordVec Ops(OperandCount); Ops[NameIdx] = BM->getString(DT->getName().str())->getId(); SPIRVEntry *BaseTy = transDbgEntry(DT->getBaseType()); assert(BaseTy && "Couldn't translate base type!"); Ops[BaseTypeIdx] = BaseTy->getId(); Ops[SourceIdx] = getSource(DT)->getId(); Ops[LineIdx] = 0; // This version of DIDerivedType has no line number Ops[ColumnIdx] = 0; // This version of DIDerivedType has no column number SPIRVEntry *Scope = getScope(DT->getScope()); assert(Scope && "Couldn't translate scope!"); Ops[ParentIdx] = Scope->getId(); if (isNonSemanticDebugInfo()) transformToConstant(Ops, {LineIdx, ColumnIdx}); return BM->addDebugInfo(SPIRVDebug::Typedef, getVoidTy(), Ops); } SPIRVEntry * LLVMToSPIRVDbgTran::transDbgSubroutineType(const DISubroutineType *FT) { using namespace SPIRVDebug::Operand::TypeFunction; SPIRVWordVec Ops(MinOperandCount); Ops[FlagsIdx] = transDebugFlags(FT); DITypeRefArray Types = FT->getTypeArray(); const size_t NumElements = Types.size(); if (NumElements) { Ops.resize(1 + NumElements); // First element of the TypeArray is the type of the return value, // followed by types of the function arguments' types. // The same order is preserved in SPIRV. for (unsigned I = 0; I < NumElements; ++I) Ops[ReturnTypeIdx + I] = transDbgEntry(Types[I])->getId(); } else { // void foo(); Ops[ReturnTypeIdx] = getVoidTy()->getId(); } if (isNonSemanticDebugInfo()) transformToConstant(Ops, {FlagsIdx}); return BM->addDebugInfo(SPIRVDebug::TypeFunction, getVoidTy(), Ops); } SPIRVEntry *LLVMToSPIRVDbgTran::transDbgEnumType(const DICompositeType *ET) { using namespace SPIRVDebug::Operand::TypeEnum; SPIRVWordVec Ops(MinOperandCount); SPIRVEntry *UnderlyingType = getVoidTy(); if (DIType *DerivedFrom = ET->getBaseType()) UnderlyingType = transDbgEntry(DerivedFrom); ConstantInt *Size = getUInt(M, ET->getSizeInBits()); Ops[NameIdx] = BM->getString(ET->getName().str())->getId(); Ops[UnderlyingTypeIdx] = UnderlyingType->getId(); Ops[SourceIdx] = getSource(ET)->getId(); Ops[LineIdx] = ET->getLine(); Ops[ColumnIdx] = 0; // This version of DICompositeType has no column number Ops[ParentIdx] = getScope(ET->getScope())->getId(); Ops[SizeIdx] = SPIRVWriter->transValue(Size, nullptr)->getId(); Ops[FlagsIdx] = transDebugFlags(ET); DINodeArray Elements = ET->getElements(); size_t ElemCount = Elements.size(); for (unsigned I = 0; I < ElemCount; ++I) { DIEnumerator *E = cast(Elements[I]); ConstantInt *EnumValue = getInt(M, E->getValue().getSExtValue()); SPIRVValue *Val = SPIRVWriter->transValue(EnumValue, nullptr); assert(Val->getOpCode() == OpConstant && "LLVM constant must be translated to SPIRV constant"); Ops.push_back(Val->getId()); SPIRVString *Name = BM->getString(E->getName().str()); Ops.push_back(Name->getId()); } if (isNonSemanticDebugInfo()) transformToConstant(Ops, {LineIdx, ColumnIdx, FlagsIdx}); return BM->addDebugInfo(SPIRVDebug::TypeEnum, getVoidTy(), Ops); } SPIRVEntry * LLVMToSPIRVDbgTran::transDbgCompositeType(const DICompositeType *CT) { using namespace SPIRVDebug::Operand::TypeComposite; SPIRVWordVec Ops(MinOperandCount); SPIRVForward *Tmp = BM->addForward(nullptr); MDMap.insert(std::make_pair(CT, Tmp)); auto Tag = static_cast(CT->getTag()); SPIRVId UniqId = getDebugInfoNoneId(); StringRef Identifier = CT->getIdentifier(); if (!Identifier.empty()) UniqId = BM->getString(Identifier.str())->getId(); ConstantInt *Size = getUInt(M, CT->getSizeInBits()); Ops[NameIdx] = BM->getString(CT->getName().str())->getId(); Ops[TagIdx] = SPIRV::DbgCompositeTypeMap::map(Tag); Ops[SourceIdx] = getSource(CT)->getId(); Ops[LineIdx] = CT->getLine(); Ops[ColumnIdx] = 0; // This version of DICompositeType has no column number Ops[ParentIdx] = getScope(CT->getScope())->getId(); Ops[LinkageNameIdx] = UniqId; Ops[SizeIdx] = SPIRVWriter->transValue(Size, nullptr)->getId(); Ops[FlagsIdx] = transDebugFlags(CT); for (DINode *N : CT->getElements()) { Ops.push_back(transDbgEntry(N)->getId()); } if (isNonSemanticDebugInfo()) transformToConstant(Ops, {TagIdx, LineIdx, ColumnIdx, FlagsIdx}); SPIRVEntry *Res = BM->addDebugInfo(SPIRVDebug::TypeComposite, getVoidTy(), Ops); // Translate template parameters. if (DITemplateParameterArray TP = CT->getTemplateParams()) { const unsigned int NumTParams = TP.size(); SPIRVWordVec Args(1 + NumTParams); Args[0] = Res->getId(); for (unsigned int I = 0; I < NumTParams; ++I) { Args[I + 1] = transDbgEntry(TP[I])->getId(); } Res = BM->addDebugInfo(SPIRVDebug::TypeTemplate, getVoidTy(), Args); } BM->replaceForward(Tmp, Res); MDMap[CT] = Res; return Res; } SPIRVEntry *LLVMToSPIRVDbgTran::transDbgMemberType(const DIDerivedType *MT) { if (isNonSemanticDebugInfo()) return transDbgMemberTypeNonSemantic(MT); return transDbgMemberTypeOpenCL(MT); } SPIRVEntry * LLVMToSPIRVDbgTran::transDbgMemberTypeOpenCL(const DIDerivedType *MT) { using namespace SPIRVDebug::Operand::TypeMember::OpenCL; SPIRVWordVec Ops(MinOperandCount); Ops[NameIdx] = BM->getString(MT->getName().str())->getId(); Ops[TypeIdx] = transDbgEntry(MT->getBaseType())->getId(); Ops[SourceIdx] = getSource(MT)->getId(); Ops[LineIdx] = MT->getLine(); Ops[ColumnIdx] = 0; // This version of DIDerivedType has no column number Ops[ParentIdx] = transDbgEntry(MT->getScope())->getId(); ConstantInt *Offset = getUInt(M, MT->getOffsetInBits()); Ops[OffsetIdx] = SPIRVWriter->transValue(Offset, nullptr)->getId(); ConstantInt *Size = getUInt(M, MT->getSizeInBits()); Ops[SizeIdx] = SPIRVWriter->transValue(Size, nullptr)->getId(); Ops[FlagsIdx] = adjustAccessFlags(MT->getScope(), transDebugFlags(MT)); if (MT->isStaticMember()) { if (llvm::Constant *C = MT->getConstant()) { SPIRVValue *Val = SPIRVWriter->transValue(C, nullptr); assert(isConstantOpCode(Val->getOpCode()) && "LLVM constant must be translated to SPIRV constant"); Ops.push_back(Val->getId()); } } if (isNonSemanticDebugInfo()) transformToConstant(Ops, {LineIdx, ColumnIdx, FlagsIdx}); return BM->addDebugInfo(SPIRVDebug::TypeMember, getVoidTy(), Ops); } SPIRVEntry * LLVMToSPIRVDbgTran::transDbgMemberTypeNonSemantic(const DIDerivedType *MT) { using namespace SPIRVDebug::Operand::TypeMember::NonSemantic; SPIRVWordVec Ops(MinOperandCount); Ops[NameIdx] = BM->getString(MT->getName().str())->getId(); Ops[TypeIdx] = transDbgEntry(MT->getBaseType())->getId(); Ops[SourceIdx] = getSource(MT)->getId(); Ops[LineIdx] = MT->getLine(); Ops[ColumnIdx] = 0; // This version of DIDerivedType has no column number ConstantInt *Offset = getUInt(M, MT->getOffsetInBits()); Ops[OffsetIdx] = SPIRVWriter->transValue(Offset, nullptr)->getId(); ConstantInt *Size = getUInt(M, MT->getSizeInBits()); Ops[SizeIdx] = SPIRVWriter->transValue(Size, nullptr)->getId(); Ops[FlagsIdx] = adjustAccessFlags(MT->getScope(), transDebugFlags(MT)); transDbgEntry(MT->getScope())->getId(); if (MT->isStaticMember()) { if (llvm::Constant *C = MT->getConstant()) { SPIRVValue *Val = SPIRVWriter->transValue(C, nullptr); assert(isConstantOpCode(Val->getOpCode()) && "LLVM constant must be translated to SPIRV constant"); Ops.push_back(Val->getId()); } } transformToConstant(Ops, {LineIdx, ColumnIdx, FlagsIdx}); return BM->addDebugInfo(SPIRVDebug::TypeMember, getVoidTy(), Ops); } SPIRVEntry *LLVMToSPIRVDbgTran::transDbgInheritance(const DIDerivedType *DT) { using namespace SPIRVDebug::Operand::TypeInheritance; unsigned ParentIdx, OffsetIdx, SizeIdx, FlagsIdx, OperandCount; if (isNonSemanticDebugInfo()) { ParentIdx = NonSemantic::ParentIdx; OffsetIdx = NonSemantic::OffsetIdx; SizeIdx = NonSemantic::SizeIdx; FlagsIdx = NonSemantic::FlagsIdx; OperandCount = NonSemantic::OperandCount; } else { ParentIdx = OpenCL::ParentIdx; OffsetIdx = OpenCL::OffsetIdx; SizeIdx = OpenCL::SizeIdx; FlagsIdx = OpenCL::FlagsIdx; OperandCount = OpenCL::OperandCount; } SPIRVWordVec Ops(OperandCount); Ops[ParentIdx] = transDbgEntry(DT->getBaseType())->getId(); ConstantInt *OffsetInBits = getUInt(M, DT->getOffsetInBits()); Ops[OffsetIdx] = SPIRVWriter->transValue(OffsetInBits, nullptr)->getId(); ConstantInt *Size = getUInt(M, DT->getSizeInBits()); Ops[SizeIdx] = SPIRVWriter->transValue(Size, nullptr)->getId(); Ops[FlagsIdx] = transDebugFlags(DT); if (isNonSemanticDebugInfo()) { transformToConstant(Ops, {FlagsIdx}); } else { Ops[OpenCL::ChildIdx] = transDbgEntry(DT->getScope())->getId(); } return BM->addDebugInfo(SPIRVDebug::TypeInheritance, getVoidTy(), Ops); } SPIRVEntry *LLVMToSPIRVDbgTran::transDbgPtrToMember(const DIDerivedType *DT) { using namespace SPIRVDebug::Operand::TypePtrToMember; SPIRVWordVec Ops(OperandCount); Ops[MemberTypeIdx] = transDbgEntry(DT->getBaseType())->getId(); Ops[ParentIdx] = transDbgEntry(DT->getClassType())->getId(); return BM->addDebugInfo(SPIRVDebug::TypePtrToMember, getVoidTy(), Ops); } // Templates SPIRVEntry * LLVMToSPIRVDbgTran::transDbgTemplateParams(DITemplateParameterArray TPA, const SPIRVEntry *Target) { using namespace SPIRVDebug::Operand::TypeTemplate; SPIRVWordVec Ops(MinOperandCount); Ops[TargetIdx] = Target->getId(); for (DITemplateParameter *TP : TPA) { Ops.push_back(transDbgEntry(TP)->getId()); } return BM->addDebugInfo(SPIRVDebug::TypeTemplate, getVoidTy(), Ops); } SPIRVEntry * LLVMToSPIRVDbgTran::transDbgTemplateParameter(const DITemplateParameter *TP) { using namespace SPIRVDebug::Operand::TypeTemplateParameter; SPIRVWordVec Ops(OperandCount); Ops[NameIdx] = BM->getString(TP->getName().str())->getId(); Ops[TypeIdx] = transDbgEntry(TP->getType())->getId(); Ops[ValueIdx] = getDebugInfoNoneId(); if (TP->getTag() == dwarf::DW_TAG_template_value_parameter) { const DITemplateValueParameter *TVP = cast(TP); if (auto *TVVal = TVP->getValue()) { Constant *C = cast(TVVal)->getValue(); Ops[ValueIdx] = SPIRVWriter->transValue(C, nullptr)->getId(); } else { SPIRVType *TyPtr = SPIRVWriter->transType( PointerType::get(Type::getInt8Ty(M->getContext()), 0)); Ops[ValueIdx] = BM->addNullConstant(TyPtr)->getId(); } } Ops[SourceIdx] = getDebugInfoNoneId(); Ops[LineIdx] = 0; // This version of DITemplateParameter has no line number Ops[ColumnIdx] = 0; // This version of DITemplateParameter has no column info if (isNonSemanticDebugInfo()) transformToConstant(Ops, {LineIdx, ColumnIdx}); return BM->addDebugInfo(SPIRVDebug::TypeTemplateParameter, getVoidTy(), Ops); } SPIRVEntry *LLVMToSPIRVDbgTran::transDbgTemplateTemplateParameter( const DITemplateValueParameter *TVP) { using namespace SPIRVDebug::Operand::TypeTemplateTemplateParameter; SPIRVWordVec Ops(OperandCount); assert(isa(TVP->getValue())); MDString *Val = cast(TVP->getValue()); Ops[NameIdx] = BM->getString(TVP->getName().str())->getId(); Ops[TemplateNameIdx] = BM->getString(Val->getString().str())->getId(); Ops[SourceIdx] = getDebugInfoNoneId(); Ops[LineIdx] = 0; // This version of DITemplateValueParameter has no line info Ops[ColumnIdx] = 0; // This version of DITemplateValueParameter has no column if (isNonSemanticDebugInfo()) transformToConstant(Ops, {LineIdx, ColumnIdx}); return BM->addDebugInfo(SPIRVDebug::TypeTemplateTemplateParameter, getVoidTy(), Ops); } SPIRVEntry *LLVMToSPIRVDbgTran::transDbgTemplateParameterPack( const DITemplateValueParameter *TVP) { using namespace SPIRVDebug::Operand::TypeTemplateParameterPack; SPIRVWordVec Ops(MinOperandCount); assert(isa(TVP->getValue())); MDNode *Params = cast(TVP->getValue()); Ops[NameIdx] = BM->getString(TVP->getName().str())->getId(); Ops[SourceIdx] = getDebugInfoNoneId(); Ops[LineIdx] = 0; // This version of DITemplateValueParameter has no line info Ops[ColumnIdx] = 0; // This version of DITemplateValueParameter has no column for (const MDOperand &Op : Params->operands()) { SPIRVEntry *P = transDbgEntry(cast(Op.get())); Ops.push_back(P->getId()); } if (isNonSemanticDebugInfo()) transformToConstant(Ops, {LineIdx, ColumnIdx}); return BM->addDebugInfo(SPIRVDebug::TypeTemplateParameterPack, getVoidTy(), Ops); } // Global objects SPIRVEntry * LLVMToSPIRVDbgTran::transDbgGlobalVariable(const DIGlobalVariable *GV) { using namespace SPIRVDebug::Operand::GlobalVariable; SPIRVWordVec Ops(MinOperandCount); Ops[NameIdx] = BM->getString(GV->getName().str())->getId(); Ops[TypeIdx] = transDbgEntry(GV->getType())->getId(); Ops[SourceIdx] = getSource(GV)->getId(); Ops[LineIdx] = GV->getLine(); Ops[ColumnIdx] = 0; // This version of DIGlobalVariable has no column number // Parent scope DIScope *Context = GV->getScope(); SPIRVEntry *Parent = SPIRVCUMap.begin()->second; // Global variable may be declared in scope of a namespace or imported module, // it may also be a static variable declared in scope of a function. if (Context && (isa(Context) || isa(Context) || isa(Context))) Parent = transDbgEntry(Context); Ops[ParentIdx] = Parent->getId(); Ops[LinkageNameIdx] = BM->getString(GV->getLinkageName().str())->getId(); Ops[VariableIdx] = getGlobalVariable(GV)->getId(); Ops[FlagsIdx] = transDebugFlags(GV); // Check if GV is the definition of previously declared static member if (DIDerivedType *StaticMember = GV->getStaticDataMemberDeclaration()) Ops.push_back(transDbgEntry(StaticMember)->getId()); if (isNonSemanticDebugInfo()) transformToConstant(Ops, {LineIdx, ColumnIdx, FlagsIdx}); return BM->addDebugInfo(SPIRVDebug::GlobalVariable, getVoidTy(), Ops); } SPIRVEntry *LLVMToSPIRVDbgTran::transDbgFunction(const DISubprogram *Func) { auto It = MDMap.find(Func); if (It != MDMap.end()) return static_cast(It->second); // As long as indexes of FunctionDeclaration operands match with Function using namespace SPIRVDebug::Operand::FunctionDeclaration; SPIRVWordVec Ops(OperandCount); Ops[NameIdx] = BM->getString(Func->getName().str())->getId(); Ops[TypeIdx] = transDbgEntry(Func->getType())->getId(); Ops[SourceIdx] = getSource(Func)->getId(); Ops[LineIdx] = Func->getLine(); Ops[ColumnIdx] = 0; // This version of DISubprogram has no column number auto Scope = Func->getScope(); if (Scope && !isa(Scope)) { Ops[ParentIdx] = getScope(Scope)->getId(); } else { if (auto *Unit = Func->getUnit()) Ops[ParentIdx] = SPIRVCUMap[Unit]->getId(); else // it might so happen, that DISubprogram is missing Unit parameter Ops[ParentIdx] = SPIRVCUMap.begin()->second->getId(); } Ops[LinkageNameIdx] = BM->getString(Func->getLinkageName().str())->getId(); Ops[FlagsIdx] = adjustAccessFlags(Scope, transDebugFlags(Func)); if (isNonSemanticDebugInfo()) transformToConstant(Ops, {LineIdx, ColumnIdx, FlagsIdx}); SPIRVEntry *DebugFunc = nullptr; SPIRVValue *FuncDef = nullptr; bool IsEntryPointKernel = false; if (!Func->isDefinition()) { DebugFunc = BM->addDebugInfo(SPIRVDebug::FunctionDeclaration, getVoidTy(), Ops); } else { // Here we add operands specific function definition using namespace SPIRVDebug::Operand::Function; Ops.resize(MinOperandCount); Ops[ScopeLineIdx] = Func->getScopeLine(); if (isNonSemanticDebugInfo()) transformToConstant(Ops, {ScopeLineIdx}); Ops[FunctionIdIdx] = getDebugInfoNoneId(); for (const llvm::Function &F : M->functions()) { if (Func->describes(&F)) { // Function definition of spir_kernel can have no "spir_kernel" calling // convention because SPIRVRegularizeLLVMBase::addKernelEntryPoint pass // could have turned it to spir_func. The "true" entry point is a // wrapper kernel function, which can be found further in the module. if (FuncDef) { if (F.getCallingConv() == CallingConv::SPIR_KERNEL) { IsEntryPointKernel = true; break; } continue; } SPIRVValue *SPIRVFunc = SPIRVWriter->getTranslatedValue(&F); assert(SPIRVFunc && "All function must be already translated"); Ops[FunctionIdIdx] = SPIRVFunc->getId(); FuncDef = SPIRVFunc; if (!isNonSemanticDebugInfo()) break; // Most likely unreachable because of Regularise LLVM pass if (F.getCallingConv() == CallingConv::SPIR_KERNEL) { IsEntryPointKernel = true; break; } } } // For NonSemantic.Shader.DebugInfo we store Function Id index as a // separate DebugFunctionDefinition instruction. if (isNonSemanticDebugInfo()) Ops.pop_back(); if (DISubprogram *FuncDecl = Func->getDeclaration()) Ops.push_back(transDbgEntry(FuncDecl)->getId()); else { Ops.push_back(getDebugInfoNoneId()); if (BM->getDebugInfoEIS() == SPIRVEIS_NonSemantic_Shader_DebugInfo_200) { // Translate targetFuncName mostly for Fortran trampoline function if it // is the case StringRef TargetFunc = Func->getTargetFuncName(); if (!TargetFunc.empty()) Ops.push_back(BM->getString(TargetFunc.str())->getId()); } } DebugFunc = BM->addDebugInfo(SPIRVDebug::Function, getVoidTy(), Ops); MDMap.insert(std::make_pair(Func, DebugFunc)); // Functions local variable might be not refered to anywhere else, except // here. // Just translate them. for (const DINode *Var : Func->getRetainedNodes()) transDbgEntry(Var); } // If the function has template parameters the function *is* a template. if (DITemplateParameterArray TPA = Func->getTemplateParams()) { DebugFunc = transDbgTemplateParams(TPA, DebugFunc); } if (isNonSemanticDebugInfo() && (Func->isMainSubprogram() || IsEntryPointKernel)) [[maybe_unused]] SPIRVEntry *Inst = transDbgEntryPoint(Func, DebugFunc); if (isNonSemanticDebugInfo() && FuncDef) [[maybe_unused]] SPIRVEntry *Inst = transDbgFuncDefinition(FuncDef, DebugFunc); return DebugFunc; } SPIRVEntry *LLVMToSPIRVDbgTran::transDbgFuncDefinition(SPIRVValue *FuncDef, SPIRVEntry *DbgFunc) { using namespace SPIRVDebug::Operand::FunctionDefinition; SPIRVWordVec Ops(OperandCount); Ops[FunctionIdx] = DbgFunc->getId(); Ops[DefinitionIdx] = FuncDef->getId(); SPIRVFunction *F = static_cast(FuncDef); SPIRVBasicBlock *BB = F->getNumBasicBlock() ? F->getBasicBlock(0) : nullptr; SPIRVId ExtSetId = BM->getExtInstSetId(BM->getDebugInfoEIS()); return BM->addExtInst(getVoidTy(), ExtSetId, SPIRVDebug::FunctionDefinition, Ops, BB, BB->getInst(0)); } SPIRVEntry *LLVMToSPIRVDbgTran::transDbgEntryPoint(const DISubprogram *Func, SPIRVEntry *DbgFunc) { using namespace SPIRVDebug::Operand::EntryPoint; SPIRVWordVec Ops(OperandCount); Ops[EntryPointIdx] = DbgFunc->getId(); DICompileUnit *CU = Func->getUnit(); if (!CU) { Ops[CompilationUnitIdx] = SPIRVCUMap.begin()->second->getId(); SPIRVWord EmptyStrIdx = BM->getString("")->getId(); Ops[CompilerSignatureIdx] = EmptyStrIdx; Ops[CommandLineArgsIdx] = EmptyStrIdx; return BM->addDebugInfo(SPIRVDebug::EntryPoint, getVoidTy(), Ops); } StringRef Producer = CU->getProducer(); StringRef Flags = CU->getFlags(); SPIRVEntry *CUVal = SPIRVCUMap[CU] ? SPIRVCUMap[CU] : getDebugInfoNone(); Ops[CompilationUnitIdx] = CUVal->getId(); Ops[CompilerSignatureIdx] = BM->getString(Producer.str())->getId(); Ops[CommandLineArgsIdx] = BM->getString(Flags.str())->getId(); return BM->addDebugInfo(SPIRVDebug::EntryPoint, getVoidTy(), Ops); } // Location information SPIRVEntry *LLVMToSPIRVDbgTran::transDbgScope(const DIScope *S) { if (const DILexicalBlockFile *LBF = dyn_cast(S)) { using namespace SPIRVDebug::Operand::LexicalBlockDiscriminator; SPIRVWordVec Ops(OperandCount); Ops[SourceIdx] = getSource(S)->getId(); Ops[DiscriminatorIdx] = LBF->getDiscriminator(); Ops[ParentIdx] = getScope(S->getScope())->getId(); if (isNonSemanticDebugInfo()) transformToConstant(Ops, {DiscriminatorIdx}); return BM->addDebugInfo(SPIRVDebug::LexicalBlockDiscriminator, getVoidTy(), Ops); } using namespace SPIRVDebug::Operand::LexicalBlock; SPIRVWordVec Ops(MinOperandCount); Ops[SourceIdx] = getSource(S)->getId(); Ops[ParentIdx] = getScope(S->getScope())->getId(); if (const DILexicalBlock *LB = dyn_cast(S)) { Ops[LineIdx] = LB->getLine(); Ops[ColumnIdx] = LB->getColumn(); } else if (const DINamespace *NS = dyn_cast(S)) { Ops[LineIdx] = 0; // This version of DINamespace has no line number Ops[ColumnIdx] = 0; // This version of DINamespace has no column number Ops.push_back(BM->getString(NS->getName().str())->getId()); if (BM->getDebugInfoEIS() == SPIRVEIS_NonSemantic_Shader_DebugInfo_200) { SPIRVValue *ExpConst = BM->addConstant( SPIRVWriter->transType(Type::getInt1Ty(M->getContext())), NS->getExportSymbols() /*Is inlined namespace*/); Ops.push_back(ExpConst->getId()); } } if (isNonSemanticDebugInfo()) transformToConstant(Ops, {LineIdx, ColumnIdx}); return BM->addDebugInfo(SPIRVDebug::LexicalBlock, getVoidTy(), Ops); } // Generating DebugScope and DebugNoScope instructions. They can interleave with // core instructions. SPIRVEntry *LLVMToSPIRVDbgTran::transDebugLoc(const DebugLoc &Loc, SPIRVBasicBlock *BB, SPIRVInstruction *InsertBefore) { SPIRVId ExtSetId = BM->getExtInstSetId(BM->getDebugInfoEIS()); if (!Loc.get()) return BM->addExtInst(getVoidTy(), ExtSetId, SPIRVDebug::NoScope, std::vector(), BB, InsertBefore); using namespace SPIRVDebug::Operand::Scope; SPIRVWordVec Ops(MinOperandCount); Ops[ScopeIdx] = getScope(static_cast(Loc.getScope()))->getId(); if (DILocation *IA = Loc.getInlinedAt()) Ops.push_back(transDbgEntry(IA)->getId()); return BM->addExtInst(getVoidTy(), ExtSetId, SPIRVDebug::Scope, Ops, BB, InsertBefore); } SPIRVEntry *LLVMToSPIRVDbgTran::transDbgInlinedAt(const DILocation *Loc) { // There is a Column operand in NonSemantic.Shader.200 spec if (BM->getDebugInfoEIS() == SPIRVEIS_NonSemantic_Shader_DebugInfo_200) return transDbgInlinedAtNonSemanticShader200(Loc); using namespace SPIRVDebug::Operand::InlinedAt::OpenCL; SPIRVWordVec Ops(MinOperandCount); Ops[LineIdx] = Loc->getLine(); Ops[ScopeIdx] = getScope(Loc->getScope())->getId(); if (DILocation *IA = Loc->getInlinedAt()) Ops.push_back(transDbgEntry(IA)->getId()); if (isNonSemanticDebugInfo()) transformToConstant(Ops, {LineIdx}); return BM->addDebugInfo(SPIRVDebug::InlinedAt, getVoidTy(), Ops); } SPIRVEntry *LLVMToSPIRVDbgTran::transDbgInlinedAtNonSemanticShader200( const DILocation *Loc) { using namespace SPIRVDebug::Operand::InlinedAt::NonSemantic; SPIRVWordVec Ops(MinOperandCount); Ops[LineIdx] = Loc->getLine(); Ops[ColumnIdx] = Loc->getColumn(); transformToConstant(Ops, {LineIdx, ColumnIdx}); Ops[ScopeIdx] = getScope(Loc->getScope())->getId(); if (DILocation *IA = Loc->getInlinedAt()) Ops.push_back(transDbgEntry(IA)->getId()); return BM->addDebugInfo(SPIRVDebug::InlinedAt, getVoidTy(), Ops); } template SPIRVExtInst *LLVMToSPIRVDbgTran::getSource(const T *DIEntry) { const std::string FileName = getFullPath(DIEntry); auto It = FileMap.find(FileName); if (It != FileMap.end()) return It->second; using namespace SPIRVDebug::Operand::Source; SPIRVWordVec Ops(MinOperandCount); Ops[FileIdx] = BM->getString(FileName)->getId(); DIFile *F = DIEntry ? DIEntry->getFile() : nullptr; if (F && F->getRawChecksum()) { auto CheckSum = F->getChecksum().getValue(); if (!isNonSemanticDebugInfo()) Ops.push_back(BM->getString("//__" + CheckSum.getKindAsString().str() + ":" + CheckSum.Value.str()) ->getId()); else if (BM->getDebugInfoEIS() == SPIRVEIS_NonSemantic_Shader_DebugInfo_200) { const SPIRVDebug::FileChecksumKind ChecksumKind = SPIRV::DbgChecksumKindMap::map(CheckSum.Kind); Ops.push_back( BM->addIntegerConstant(static_cast(getInt32Ty()), ChecksumKind) ->getId()); Ops.push_back(BM->getString(CheckSum.Value.str())->getId()); } } if (F && F->getRawSource() && isNonSemanticDebugInfo()) { std::string Str = F->getSource().getValue().str(); constexpr size_t MaxNumWords = MaxWordCount - 2 /*Fixed WC for SPIRVString*/; constexpr size_t MaxStrSize = MaxNumWords * 4 - 1; const size_t NumWords = getSizeInWords(Str); if (BM->getDebugInfoEIS() == SPIRVEIS_NonSemantic_Shader_DebugInfo_200 && Ops.size() == MinOperandCount) { Ops.push_back(getDebugInfoNoneId()); Ops.push_back(getDebugInfoNoneId()); } Ops.push_back(BM->getString(Str.substr(0, MaxStrSize))->getId()); SPIRVExtInst *Source = static_cast( BM->addDebugInfo(SPIRVDebug::Source, getVoidTy(), Ops)); FileMap[FileName] = Source; Str.erase(0, MaxStrSize); // No need to generate source continued instructions if (NumWords < MaxNumWords) return Source; const uint64_t NumOfContinuedInstructions = NumWords / MaxNumWords - 1 + (NumWords % MaxNumWords ? 1 : 0); for (uint64_t J = 0; J < NumOfContinuedInstructions; J++) { const SPIRVWord Op = BM->getString(Str.substr(0, MaxStrSize))->getId(); BM->addDebugInfo(SPIRVDebug::SourceContinued, getVoidTy(), {Op}); Str.erase(0, MaxStrSize); } return Source; } SPIRVExtInst *Source = static_cast( BM->addDebugInfo(SPIRVDebug::Source, getVoidTy(), Ops)); FileMap[FileName] = Source; return Source; } void LLVMToSPIRVDbgTran::generateBuildIdentifierAndStoragePath( const DICompileUnit *DIEntry) { // get information from LLVM IR auto BuildIdentifier = DIEntry->getDWOId(); const std::string BuildIdentifierString = std::to_string(BuildIdentifier); const std::string StoragePath = DIEntry->getSplitDebugFilename().str(); using namespace SPIRVDebug::Operand; if (BuildIdentifierInsn || StoragePathInsn) { #ifndef NDEBUG assert(BuildIdentifierInsn && StoragePathInsn && "BuildIdentifier and StoragePath instructions must both be created"); auto PreviousBuildIdentifierString = BM->get( BuildIdentifierInsn ->getArguments()[BuildIdentifier::IdentifierIdx]) ->getStr(); assert(PreviousBuildIdentifierString == BuildIdentifierString && "New BuildIdentifier should match previous BuildIdentifier"); auto PreviousStoragePath = BM->get( StoragePathInsn->getArguments()[StoragePath::PathIdx]) ->getStr(); assert(PreviousStoragePath == StoragePath && "New StoragePath should match previous StoragePath"); #endif return; } // generate BuildIdentifier inst SPIRVWordVec BuildIdentifierOps(BuildIdentifier::OperandCount); BuildIdentifierOps[BuildIdentifier::IdentifierIdx] = BM->getString(BuildIdentifierString)->getId(); BuildIdentifierOps[BuildIdentifier::FlagsIdx] = BM->getLiteralAsConstant(1)->getId(); // Placeholder value for now BuildIdentifierInsn = static_cast(BM->addDebugInfo( SPIRVDebug::BuildIdentifier, getVoidTy(), BuildIdentifierOps)); // generate StoragePath inst SPIRVWordVec StoragePathOps(StoragePath::OperandCount); StoragePathOps[StoragePath::PathIdx] = BM->getString(StoragePath)->getId(); StoragePathInsn = static_cast( BM->addDebugInfo(SPIRVDebug::StoragePath, getVoidTy(), StoragePathOps)); } SPIRVEntry *LLVMToSPIRVDbgTran::transDbgFileType(const DIFile *F) { return BM->getString(getFullPath(F)); } // Local variables SPIRVEntry * LLVMToSPIRVDbgTran::transDbgLocalVariable(const DILocalVariable *Var) { using namespace SPIRVDebug::Operand::LocalVariable; SPIRVWordVec Ops(MinOperandCount); Ops[NameIdx] = BM->getString(Var->getName().str())->getId(); Ops[TypeIdx] = transDbgEntry(Var->getType())->getId(); Ops[SourceIdx] = getSource(Var->getFile())->getId(); Ops[LineIdx] = Var->getLine(); Ops[ColumnIdx] = 0; // This version of DILocalVariable has no column number Ops[ParentIdx] = getScope(Var->getScope())->getId(); Ops[FlagsIdx] = transDebugFlags(Var); if (SPIRVWord ArgNumber = Var->getArg()) Ops.push_back(ArgNumber); if (isNonSemanticDebugInfo()) transformToConstant(Ops, {LineIdx, ColumnIdx, FlagsIdx}); return BM->addDebugInfo(SPIRVDebug::LocalVariable, getVoidTy(), Ops); } // DWARF Operations and expressions SPIRVEntry *LLVMToSPIRVDbgTran::transDbgExpression(const DIExpression *Expr) { SPIRVWordVec Operations; for (unsigned I = 0, N = Expr->getNumElements(); I < N; ++I) { using namespace SPIRVDebug::Operand::Operation; auto DWARFOpCode = static_cast(Expr->getElement(I)); SPIRVDebug::ExpressionOpCode OC = SPIRV::DbgExpressionOpCodeMap::map(DWARFOpCode); if (OpCountMap.find(OC) == OpCountMap.end()) report_fatal_error(llvm::Twine("unknown opcode found in DIExpression")); if (OC > SPIRVDebug::Fragment && !(BM->allowExtraDIExpressions() || BM->getDebugInfoEIS() == SPIRVEIS_NonSemantic_Shader_DebugInfo_200)) report_fatal_error( llvm::Twine("unsupported opcode found in DIExpression")); unsigned OpCount = OpCountMap[OC]; SPIRVWordVec Op(OpCount); Op[OpCodeIdx] = OC; if (isNonSemanticDebugInfo()) transformToConstant(Op, {OpCodeIdx}); for (unsigned J = 1; J < OpCount; ++J) { Op[J] = Expr->getElement(++I); if (isNonSemanticDebugInfo()) transformToConstant(Op, {J}); } auto *Operation = BM->addDebugInfo(SPIRVDebug::Operation, getVoidTy(), Op); Operations.push_back(Operation->getId()); } return BM->addDebugInfo(SPIRVDebug::Expression, getVoidTy(), Operations); } // Imported entries (C++ using directive) SPIRVEntry * LLVMToSPIRVDbgTran::transDbgImportedEntry(const DIImportedEntity *IE) { using namespace SPIRVDebug::Operand::ImportedEntity; auto Tag = static_cast(IE->getTag()); // FIXME: 'OpenCL/bugged' version is kept because it's hard to remove it // It's W/A for missing 2nd index in OpenCL's implementation const SPIRVWord OffsetIdx = isNonSemanticDebugInfo() ? OperandCount - NonSemantic::OperandCount : 0; SPIRVWordVec Ops(OperandCount - OffsetIdx); Ops[NameIdx] = BM->getString(IE->getName().str())->getId(); Ops[TagIdx] = SPIRV::DbgImportedEntityMap::map(Tag); Ops[SourceIdx - OffsetIdx] = getSource(IE->getFile())->getId(); Ops[EntityIdx - OffsetIdx] = transDbgEntry(IE->getEntity())->getId(); Ops[LineIdx - OffsetIdx] = IE->getLine(); // This version of DIImportedEntity has no column number Ops[ColumnIdx - OffsetIdx] = 0; Ops[ParentIdx - OffsetIdx] = getScope(IE->getScope())->getId(); if (isNonSemanticDebugInfo()) transformToConstant(Ops, {TagIdx, LineIdx - OffsetIdx, ColumnIdx - OffsetIdx}); return BM->addDebugInfo(SPIRVDebug::ImportedEntity, getVoidTy(), Ops); } SPIRVEntry *LLVMToSPIRVDbgTran::transDbgModule(const DIModule *Module) { using namespace SPIRVDebug::Operand::ModuleINTEL; SPIRVWordVec Ops(OperandCount); Ops[NameIdx] = BM->getString(Module->getName().str())->getId(); Ops[SourceIdx] = getSource(Module->getFile())->getId(); Ops[LineIdx] = Module->getLineNo(); Ops[ParentIdx] = getScope(Module->getScope())->getId(); Ops[ConfigMacrosIdx] = BM->getString(Module->getConfigurationMacros().str())->getId(); Ops[IncludePathIdx] = BM->getString(Module->getIncludePath().str())->getId(); Ops[ApiNotesIdx] = BM->getString(Module->getAPINotesFile().str())->getId(); Ops[IsDeclIdx] = Module->getIsDecl(); if (BM->getDebugInfoEIS() == SPIRVEIS_NonSemantic_Shader_DebugInfo_200) { // The difference in translation of NonSemantic Debug Info and // SPV_INTEL_debug_module extension is that extension allows Line and IsDecl // operands to be Literals, when the non-OpenCL Debug Info allows only IDs // to the constant values. transformToConstant(Ops, {LineIdx, IsDeclIdx}); return BM->addDebugInfo(SPIRVDebug::Module, getVoidTy(), Ops); } BM->addExtension(ExtensionID::SPV_INTEL_debug_module); BM->addCapability(spv::CapabilityDebugInfoModuleINTEL); return BM->addDebugInfo(SPIRVDebug::ModuleINTEL, getVoidTy(), Ops); }