//=== DWARFLinker.cpp -----------------------------------------------------===// // // Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions. // See https://llvm.org/LICENSE.txt for license information. // SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception // //===----------------------------------------------------------------------===// #include "llvm/DWARFLinker/Classic/DWARFLinker.h" #include "llvm/ADT/ArrayRef.h" #include "llvm/ADT/BitVector.h" #include "llvm/ADT/STLExtras.h" #include "llvm/ADT/StringExtras.h" #include "llvm/CodeGen/NonRelocatableStringpool.h" #include "llvm/DWARFLinker/Classic/DWARFLinkerDeclContext.h" #include "llvm/DWARFLinker/Classic/DWARFStreamer.h" #include "llvm/DWARFLinker/Utils.h" #include "llvm/DebugInfo/DWARF/DWARFAbbreviationDeclaration.h" #include "llvm/DebugInfo/DWARF/DWARFAcceleratorTable.h" #include "llvm/DebugInfo/DWARF/DWARFContext.h" #include "llvm/DebugInfo/DWARF/DWARFDataExtractor.h" #include "llvm/DebugInfo/DWARF/DWARFDebugLine.h" #include "llvm/DebugInfo/DWARF/DWARFDebugMacro.h" #include "llvm/DebugInfo/DWARF/DWARFDebugRangeList.h" #include "llvm/DebugInfo/DWARF/DWARFDie.h" #include "llvm/DebugInfo/DWARF/DWARFExpression.h" #include "llvm/DebugInfo/DWARF/DWARFFormValue.h" #include "llvm/DebugInfo/DWARF/DWARFSection.h" #include "llvm/DebugInfo/DWARF/DWARFUnit.h" #include "llvm/MC/MCDwarf.h" #include "llvm/Support/DataExtractor.h" #include "llvm/Support/Error.h" #include "llvm/Support/ErrorHandling.h" #include "llvm/Support/ErrorOr.h" #include "llvm/Support/FormatVariadic.h" #include "llvm/Support/LEB128.h" #include "llvm/Support/Path.h" #include "llvm/Support/ThreadPool.h" #include namespace llvm { using namespace dwarf_linker; using namespace dwarf_linker::classic; /// Hold the input and output of the debug info size in bytes. struct DebugInfoSize { uint64_t Input; uint64_t Output; }; /// Compute the total size of the debug info. static uint64_t getDebugInfoSize(DWARFContext &Dwarf) { uint64_t Size = 0; for (auto &Unit : Dwarf.compile_units()) { Size += Unit->getLength(); } return Size; } /// Similar to DWARFUnitSection::getUnitForOffset(), but returning our /// CompileUnit object instead. static CompileUnit *getUnitForOffset(const UnitListTy &Units, uint64_t Offset) { auto CU = llvm::upper_bound( Units, Offset, [](uint64_t LHS, const std::unique_ptr &RHS) { return LHS < RHS->getOrigUnit().getNextUnitOffset(); }); return CU != Units.end() ? CU->get() : nullptr; } /// Resolve the DIE attribute reference that has been extracted in \p RefValue. /// The resulting DIE might be in another CompileUnit which is stored into \p /// ReferencedCU. \returns null if resolving fails for any reason. DWARFDie DWARFLinker::resolveDIEReference(const DWARFFile &File, const UnitListTy &Units, const DWARFFormValue &RefValue, const DWARFDie &DIE, CompileUnit *&RefCU) { assert(RefValue.isFormClass(DWARFFormValue::FC_Reference)); uint64_t RefOffset; if (std::optional Off = RefValue.getAsRelativeReference()) { RefOffset = RefValue.getUnit()->getOffset() + *Off; } else if (Off = RefValue.getAsDebugInfoReference(); Off) { RefOffset = *Off; } else { reportWarning("Unsupported reference type", File, &DIE); return DWARFDie(); } if ((RefCU = getUnitForOffset(Units, RefOffset))) if (const auto RefDie = RefCU->getOrigUnit().getDIEForOffset(RefOffset)) { // In a file with broken references, an attribute might point to a NULL // DIE. if (!RefDie.isNULL()) return RefDie; } reportWarning("could not find referenced DIE", File, &DIE); return DWARFDie(); } /// \returns whether the passed \a Attr type might contain a DIE reference /// suitable for ODR uniquing. static bool isODRAttribute(uint16_t Attr) { switch (Attr) { default: return false; case dwarf::DW_AT_type: case dwarf::DW_AT_containing_type: case dwarf::DW_AT_specification: case dwarf::DW_AT_abstract_origin: case dwarf::DW_AT_import: return true; } llvm_unreachable("Improper attribute."); } static bool isTypeTag(uint16_t Tag) { switch (Tag) { case dwarf::DW_TAG_array_type: case dwarf::DW_TAG_class_type: case dwarf::DW_TAG_enumeration_type: case dwarf::DW_TAG_pointer_type: case dwarf::DW_TAG_reference_type: case dwarf::DW_TAG_string_type: case dwarf::DW_TAG_structure_type: case dwarf::DW_TAG_subroutine_type: case dwarf::DW_TAG_template_alias: case dwarf::DW_TAG_typedef: case dwarf::DW_TAG_union_type: case dwarf::DW_TAG_ptr_to_member_type: case dwarf::DW_TAG_set_type: case dwarf::DW_TAG_subrange_type: case dwarf::DW_TAG_base_type: case dwarf::DW_TAG_const_type: case dwarf::DW_TAG_constant: case dwarf::DW_TAG_file_type: case dwarf::DW_TAG_namelist: case dwarf::DW_TAG_packed_type: case dwarf::DW_TAG_volatile_type: case dwarf::DW_TAG_restrict_type: case dwarf::DW_TAG_atomic_type: case dwarf::DW_TAG_interface_type: case dwarf::DW_TAG_unspecified_type: case dwarf::DW_TAG_shared_type: case dwarf::DW_TAG_immutable_type: return true; default: break; } return false; } bool DWARFLinker::DIECloner::getDIENames(const DWARFDie &Die, AttributesInfo &Info, OffsetsStringPool &StringPool, bool StripTemplate) { // This function will be called on DIEs having low_pcs and // ranges. As getting the name might be more expansive, filter out // blocks directly. if (Die.getTag() == dwarf::DW_TAG_lexical_block) return false; if (!Info.MangledName) if (const char *MangledName = Die.getLinkageName()) Info.MangledName = StringPool.getEntry(MangledName); if (!Info.Name) if (const char *Name = Die.getShortName()) Info.Name = StringPool.getEntry(Name); if (!Info.MangledName) Info.MangledName = Info.Name; if (StripTemplate && Info.Name && Info.MangledName != Info.Name) { StringRef Name = Info.Name.getString(); if (std::optional StrippedName = StripTemplateParameters(Name)) Info.NameWithoutTemplate = StringPool.getEntry(*StrippedName); } return Info.Name || Info.MangledName; } /// Resolve the relative path to a build artifact referenced by DWARF by /// applying DW_AT_comp_dir. static void resolveRelativeObjectPath(SmallVectorImpl &Buf, DWARFDie CU) { sys::path::append(Buf, dwarf::toString(CU.find(dwarf::DW_AT_comp_dir), "")); } /// Collect references to parseable Swift interfaces in imported /// DW_TAG_module blocks. static void analyzeImportedModule( const DWARFDie &DIE, CompileUnit &CU, DWARFLinkerBase::SwiftInterfacesMapTy *ParseableSwiftInterfaces, std::function ReportWarning) { if (CU.getLanguage() != dwarf::DW_LANG_Swift) return; if (!ParseableSwiftInterfaces) return; StringRef Path = dwarf::toStringRef(DIE.find(dwarf::DW_AT_LLVM_include_path)); if (!Path.ends_with(".swiftinterface")) return; // Don't track interfaces that are part of the SDK. StringRef SysRoot = dwarf::toStringRef(DIE.find(dwarf::DW_AT_LLVM_sysroot)); if (SysRoot.empty()) SysRoot = CU.getSysRoot(); if (!SysRoot.empty() && Path.starts_with(SysRoot)) return; // Don't track interfaces that are part of the toolchain. // For example: Swift, _Concurrency, ... StringRef DeveloperDir = guessDeveloperDir(SysRoot); if (!DeveloperDir.empty() && Path.starts_with(DeveloperDir)) return; if (isInToolchainDir(Path)) return; std::optional Name = dwarf::toString(DIE.find(dwarf::DW_AT_name)); if (!Name) return; auto &Entry = (*ParseableSwiftInterfaces)[*Name]; // The prepend path is applied later when copying. DWARFDie CUDie = CU.getOrigUnit().getUnitDIE(); SmallString<128> ResolvedPath; if (sys::path::is_relative(Path)) resolveRelativeObjectPath(ResolvedPath, CUDie); sys::path::append(ResolvedPath, Path); if (!Entry.empty() && Entry != ResolvedPath) ReportWarning(Twine("Conflicting parseable interfaces for Swift Module ") + *Name + ": " + Entry + " and " + Path, DIE); Entry = std::string(ResolvedPath); } /// The distinct types of work performed by the work loop in /// analyzeContextInfo. enum class ContextWorklistItemType : uint8_t { AnalyzeContextInfo, UpdateChildPruning, UpdatePruning, }; /// This class represents an item in the work list. The type defines what kind /// of work needs to be performed when processing the current item. Everything /// but the Type and Die fields are optional based on the type. struct ContextWorklistItem { DWARFDie Die; unsigned ParentIdx; union { CompileUnit::DIEInfo *OtherInfo; DeclContext *Context; }; ContextWorklistItemType Type; bool InImportedModule; ContextWorklistItem(DWARFDie Die, ContextWorklistItemType T, CompileUnit::DIEInfo *OtherInfo = nullptr) : Die(Die), ParentIdx(0), OtherInfo(OtherInfo), Type(T), InImportedModule(false) {} ContextWorklistItem(DWARFDie Die, DeclContext *Context, unsigned ParentIdx, bool InImportedModule) : Die(Die), ParentIdx(ParentIdx), Context(Context), Type(ContextWorklistItemType::AnalyzeContextInfo), InImportedModule(InImportedModule) {} }; static bool updatePruning(const DWARFDie &Die, CompileUnit &CU, uint64_t ModulesEndOffset) { CompileUnit::DIEInfo &Info = CU.getInfo(Die); // Prune this DIE if it is either a forward declaration inside a // DW_TAG_module or a DW_TAG_module that contains nothing but // forward declarations. Info.Prune &= (Die.getTag() == dwarf::DW_TAG_module) || (isTypeTag(Die.getTag()) && dwarf::toUnsigned(Die.find(dwarf::DW_AT_declaration), 0)); // Only prune forward declarations inside a DW_TAG_module for which a // definition exists elsewhere. if (ModulesEndOffset == 0) Info.Prune &= Info.Ctxt && Info.Ctxt->getCanonicalDIEOffset(); else Info.Prune &= Info.Ctxt && Info.Ctxt->getCanonicalDIEOffset() > 0 && Info.Ctxt->getCanonicalDIEOffset() <= ModulesEndOffset; return Info.Prune; } static void updateChildPruning(const DWARFDie &Die, CompileUnit &CU, CompileUnit::DIEInfo &ChildInfo) { CompileUnit::DIEInfo &Info = CU.getInfo(Die); Info.Prune &= ChildInfo.Prune; } /// Recursive helper to build the global DeclContext information and /// gather the child->parent relationships in the original compile unit. /// /// This function uses the same work list approach as lookForDIEsToKeep. /// /// \return true when this DIE and all of its children are only /// forward declarations to types defined in external clang modules /// (i.e., forward declarations that are children of a DW_TAG_module). static void analyzeContextInfo( const DWARFDie &DIE, unsigned ParentIdx, CompileUnit &CU, DeclContext *CurrentDeclContext, DeclContextTree &Contexts, uint64_t ModulesEndOffset, DWARFLinkerBase::SwiftInterfacesMapTy *ParseableSwiftInterfaces, std::function ReportWarning) { // LIFO work list. std::vector Worklist; Worklist.emplace_back(DIE, CurrentDeclContext, ParentIdx, false); while (!Worklist.empty()) { ContextWorklistItem Current = Worklist.back(); Worklist.pop_back(); switch (Current.Type) { case ContextWorklistItemType::UpdatePruning: updatePruning(Current.Die, CU, ModulesEndOffset); continue; case ContextWorklistItemType::UpdateChildPruning: updateChildPruning(Current.Die, CU, *Current.OtherInfo); continue; case ContextWorklistItemType::AnalyzeContextInfo: break; } unsigned Idx = CU.getOrigUnit().getDIEIndex(Current.Die); CompileUnit::DIEInfo &Info = CU.getInfo(Idx); // Clang imposes an ODR on modules(!) regardless of the language: // "The module-id should consist of only a single identifier, // which provides the name of the module being defined. Each // module shall have a single definition." // // This does not extend to the types inside the modules: // "[I]n C, this implies that if two structs are defined in // different submodules with the same name, those two types are // distinct types (but may be compatible types if their // definitions match)." // // We treat non-C++ modules like namespaces for this reason. if (Current.Die.getTag() == dwarf::DW_TAG_module && Current.ParentIdx == 0 && dwarf::toString(Current.Die.find(dwarf::DW_AT_name), "") != CU.getClangModuleName()) { Current.InImportedModule = true; analyzeImportedModule(Current.Die, CU, ParseableSwiftInterfaces, ReportWarning); } Info.ParentIdx = Current.ParentIdx; Info.InModuleScope = CU.isClangModule() || Current.InImportedModule; if (CU.hasODR() || Info.InModuleScope) { if (Current.Context) { auto PtrInvalidPair = Contexts.getChildDeclContext( *Current.Context, Current.Die, CU, Info.InModuleScope); Current.Context = PtrInvalidPair.getPointer(); Info.Ctxt = PtrInvalidPair.getInt() ? nullptr : PtrInvalidPair.getPointer(); if (Info.Ctxt) Info.Ctxt->setDefinedInClangModule(Info.InModuleScope); } else Info.Ctxt = Current.Context = nullptr; } Info.Prune = Current.InImportedModule; // Add children in reverse order to the worklist to effectively process // them in order. Worklist.emplace_back(Current.Die, ContextWorklistItemType::UpdatePruning); for (auto Child : reverse(Current.Die.children())) { CompileUnit::DIEInfo &ChildInfo = CU.getInfo(Child); Worklist.emplace_back( Current.Die, ContextWorklistItemType::UpdateChildPruning, &ChildInfo); Worklist.emplace_back(Child, Current.Context, Idx, Current.InImportedModule); } } } static bool dieNeedsChildrenToBeMeaningful(uint32_t Tag) { switch (Tag) { default: return false; case dwarf::DW_TAG_class_type: case dwarf::DW_TAG_common_block: case dwarf::DW_TAG_lexical_block: case dwarf::DW_TAG_structure_type: case dwarf::DW_TAG_subprogram: case dwarf::DW_TAG_subroutine_type: case dwarf::DW_TAG_union_type: return true; } llvm_unreachable("Invalid Tag"); } void DWARFLinker::cleanupAuxiliarryData(LinkContext &Context) { Context.clear(); for (DIEBlock *I : DIEBlocks) I->~DIEBlock(); for (DIELoc *I : DIELocs) I->~DIELoc(); DIEBlocks.clear(); DIELocs.clear(); DIEAlloc.Reset(); } static bool isTlsAddressCode(uint8_t DW_OP_Code) { return DW_OP_Code == dwarf::DW_OP_form_tls_address || DW_OP_Code == dwarf::DW_OP_GNU_push_tls_address; } std::pair> DWARFLinker::getVariableRelocAdjustment(AddressesMap &RelocMgr, const DWARFDie &DIE) { assert((DIE.getTag() == dwarf::DW_TAG_variable || DIE.getTag() == dwarf::DW_TAG_constant) && "Wrong type of input die"); const auto *Abbrev = DIE.getAbbreviationDeclarationPtr(); // Check if DIE has DW_AT_location attribute. DWARFUnit *U = DIE.getDwarfUnit(); std::optional LocationIdx = Abbrev->findAttributeIndex(dwarf::DW_AT_location); if (!LocationIdx) return std::make_pair(false, std::nullopt); // Get offset to the DW_AT_location attribute. uint64_t AttrOffset = Abbrev->getAttributeOffsetFromIndex(*LocationIdx, DIE.getOffset(), *U); // Get value of the DW_AT_location attribute. std::optional LocationValue = Abbrev->getAttributeValueFromOffset(*LocationIdx, AttrOffset, *U); if (!LocationValue) return std::make_pair(false, std::nullopt); // Check that DW_AT_location attribute is of 'exprloc' class. // Handling value of location expressions for attributes of 'loclist' // class is not implemented yet. std::optional> Expr = LocationValue->getAsBlock(); if (!Expr) return std::make_pair(false, std::nullopt); // Parse 'exprloc' expression. DataExtractor Data(toStringRef(*Expr), U->getContext().isLittleEndian(), U->getAddressByteSize()); DWARFExpression Expression(Data, U->getAddressByteSize(), U->getFormParams().Format); bool HasLocationAddress = false; uint64_t CurExprOffset = 0; for (DWARFExpression::iterator It = Expression.begin(); It != Expression.end(); ++It) { DWARFExpression::iterator NextIt = It; ++NextIt; const DWARFExpression::Operation &Op = *It; switch (Op.getCode()) { case dwarf::DW_OP_const2u: case dwarf::DW_OP_const4u: case dwarf::DW_OP_const8u: case dwarf::DW_OP_const2s: case dwarf::DW_OP_const4s: case dwarf::DW_OP_const8s: if (NextIt == Expression.end() || !isTlsAddressCode(NextIt->getCode())) break; [[fallthrough]]; case dwarf::DW_OP_addr: { HasLocationAddress = true; // Check relocation for the address. if (std::optional RelocAdjustment = RelocMgr.getExprOpAddressRelocAdjustment( *U, Op, AttrOffset + CurExprOffset, AttrOffset + Op.getEndOffset(), Options.Verbose)) return std::make_pair(HasLocationAddress, *RelocAdjustment); } break; case dwarf::DW_OP_constx: case dwarf::DW_OP_addrx: { HasLocationAddress = true; if (std::optional AddressOffset = DIE.getDwarfUnit()->getIndexedAddressOffset( Op.getRawOperand(0))) { // Check relocation for the address. if (std::optional RelocAdjustment = RelocMgr.getExprOpAddressRelocAdjustment( *U, Op, *AddressOffset, *AddressOffset + DIE.getDwarfUnit()->getAddressByteSize(), Options.Verbose)) return std::make_pair(HasLocationAddress, *RelocAdjustment); } } break; default: { // Nothing to do. } break; } CurExprOffset = Op.getEndOffset(); } return std::make_pair(HasLocationAddress, std::nullopt); } /// Check if a variable describing DIE should be kept. /// \returns updated TraversalFlags. unsigned DWARFLinker::shouldKeepVariableDIE(AddressesMap &RelocMgr, const DWARFDie &DIE, CompileUnit::DIEInfo &MyInfo, unsigned Flags) { const auto *Abbrev = DIE.getAbbreviationDeclarationPtr(); // Global variables with constant value can always be kept. if (!(Flags & TF_InFunctionScope) && Abbrev->findAttributeIndex(dwarf::DW_AT_const_value)) { MyInfo.InDebugMap = true; return Flags | TF_Keep; } // See if there is a relocation to a valid debug map entry inside this // variable's location. The order is important here. We want to always check // if the variable has a valid relocation, so that the DIEInfo is filled. // However, we don't want a static variable in a function to force us to keep // the enclosing function, unless requested explicitly. std::pair> LocExprAddrAndRelocAdjustment = getVariableRelocAdjustment(RelocMgr, DIE); if (LocExprAddrAndRelocAdjustment.first) MyInfo.HasLocationExpressionAddr = true; if (!LocExprAddrAndRelocAdjustment.second) return Flags; MyInfo.AddrAdjust = *LocExprAddrAndRelocAdjustment.second; MyInfo.InDebugMap = true; if (((Flags & TF_InFunctionScope) && !LLVM_UNLIKELY(Options.KeepFunctionForStatic))) return Flags; if (Options.Verbose) { outs() << "Keeping variable DIE:"; DIDumpOptions DumpOpts; DumpOpts.ChildRecurseDepth = 0; DumpOpts.Verbose = Options.Verbose; DIE.dump(outs(), 8 /* Indent */, DumpOpts); } return Flags | TF_Keep; } /// Check if a function describing DIE should be kept. /// \returns updated TraversalFlags. unsigned DWARFLinker::shouldKeepSubprogramDIE( AddressesMap &RelocMgr, const DWARFDie &DIE, const DWARFFile &File, CompileUnit &Unit, CompileUnit::DIEInfo &MyInfo, unsigned Flags) { Flags |= TF_InFunctionScope; auto LowPc = dwarf::toAddress(DIE.find(dwarf::DW_AT_low_pc)); if (!LowPc) return Flags; assert(LowPc && "low_pc attribute is not an address."); std::optional RelocAdjustment = RelocMgr.getSubprogramRelocAdjustment(DIE, Options.Verbose); if (!RelocAdjustment) return Flags; MyInfo.AddrAdjust = *RelocAdjustment; MyInfo.InDebugMap = true; if (Options.Verbose) { outs() << "Keeping subprogram DIE:"; DIDumpOptions DumpOpts; DumpOpts.ChildRecurseDepth = 0; DumpOpts.Verbose = Options.Verbose; DIE.dump(outs(), 8 /* Indent */, DumpOpts); } if (DIE.getTag() == dwarf::DW_TAG_label) { if (Unit.hasLabelAt(*LowPc)) return Flags; DWARFUnit &OrigUnit = Unit.getOrigUnit(); // FIXME: dsymutil-classic compat. dsymutil-classic doesn't consider labels // that don't fall into the CU's aranges. This is wrong IMO. Debug info // generation bugs aside, this is really wrong in the case of labels, where // a label marking the end of a function will have a PC == CU's high_pc. if (dwarf::toAddress(OrigUnit.getUnitDIE().find(dwarf::DW_AT_high_pc)) .value_or(UINT64_MAX) <= LowPc) return Flags; Unit.addLabelLowPc(*LowPc, MyInfo.AddrAdjust); return Flags | TF_Keep; } Flags |= TF_Keep; std::optional HighPc = DIE.getHighPC(*LowPc); if (!HighPc) { reportWarning("Function without high_pc. Range will be discarded.\n", File, &DIE); return Flags; } if (*LowPc > *HighPc) { reportWarning("low_pc greater than high_pc. Range will be discarded.\n", File, &DIE); return Flags; } // Replace the debug map range with a more accurate one. Unit.addFunctionRange(*LowPc, *HighPc, MyInfo.AddrAdjust); return Flags; } /// Check if a DIE should be kept. /// \returns updated TraversalFlags. unsigned DWARFLinker::shouldKeepDIE(AddressesMap &RelocMgr, const DWARFDie &DIE, const DWARFFile &File, CompileUnit &Unit, CompileUnit::DIEInfo &MyInfo, unsigned Flags) { switch (DIE.getTag()) { case dwarf::DW_TAG_constant: case dwarf::DW_TAG_variable: return shouldKeepVariableDIE(RelocMgr, DIE, MyInfo, Flags); case dwarf::DW_TAG_subprogram: case dwarf::DW_TAG_label: return shouldKeepSubprogramDIE(RelocMgr, DIE, File, Unit, MyInfo, Flags); case dwarf::DW_TAG_base_type: // DWARF Expressions may reference basic types, but scanning them // is expensive. Basic types are tiny, so just keep all of them. case dwarf::DW_TAG_imported_module: case dwarf::DW_TAG_imported_declaration: case dwarf::DW_TAG_imported_unit: // We always want to keep these. return Flags | TF_Keep; default: break; } return Flags; } /// Helper that updates the completeness of the current DIE based on the /// completeness of one of its children. It depends on the incompleteness of /// the children already being computed. static void updateChildIncompleteness(const DWARFDie &Die, CompileUnit &CU, CompileUnit::DIEInfo &ChildInfo) { switch (Die.getTag()) { case dwarf::DW_TAG_structure_type: case dwarf::DW_TAG_class_type: case dwarf::DW_TAG_union_type: break; default: return; } CompileUnit::DIEInfo &MyInfo = CU.getInfo(Die); if (ChildInfo.Incomplete || ChildInfo.Prune) MyInfo.Incomplete = true; } /// Helper that updates the completeness of the current DIE based on the /// completeness of the DIEs it references. It depends on the incompleteness of /// the referenced DIE already being computed. static void updateRefIncompleteness(const DWARFDie &Die, CompileUnit &CU, CompileUnit::DIEInfo &RefInfo) { switch (Die.getTag()) { case dwarf::DW_TAG_typedef: case dwarf::DW_TAG_member: case dwarf::DW_TAG_reference_type: case dwarf::DW_TAG_ptr_to_member_type: case dwarf::DW_TAG_pointer_type: break; default: return; } CompileUnit::DIEInfo &MyInfo = CU.getInfo(Die); if (MyInfo.Incomplete) return; if (RefInfo.Incomplete) MyInfo.Incomplete = true; } /// Look at the children of the given DIE and decide whether they should be /// kept. void DWARFLinker::lookForChildDIEsToKeep( const DWARFDie &Die, CompileUnit &CU, unsigned Flags, SmallVectorImpl &Worklist) { // The TF_ParentWalk flag tells us that we are currently walking up the // parent chain of a required DIE, and we don't want to mark all the children // of the parents as kept (consider for example a DW_TAG_namespace node in // the parent chain). There are however a set of DIE types for which we want // to ignore that directive and still walk their children. if (dieNeedsChildrenToBeMeaningful(Die.getTag())) Flags &= ~DWARFLinker::TF_ParentWalk; // We're finished if this DIE has no children or we're walking the parent // chain. if (!Die.hasChildren() || (Flags & DWARFLinker::TF_ParentWalk)) return; // Add children in reverse order to the worklist to effectively process them // in order. for (auto Child : reverse(Die.children())) { // Add a worklist item before every child to calculate incompleteness right // after the current child is processed. CompileUnit::DIEInfo &ChildInfo = CU.getInfo(Child); Worklist.emplace_back(Die, CU, WorklistItemType::UpdateChildIncompleteness, &ChildInfo); Worklist.emplace_back(Child, CU, Flags); } } static bool isODRCanonicalCandidate(const DWARFDie &Die, CompileUnit &CU) { CompileUnit::DIEInfo &Info = CU.getInfo(Die); if (!Info.Ctxt || (Die.getTag() == dwarf::DW_TAG_namespace)) return false; if (!CU.hasODR() && !Info.InModuleScope) return false; return !Info.Incomplete && Info.Ctxt != CU.getInfo(Info.ParentIdx).Ctxt; } void DWARFLinker::markODRCanonicalDie(const DWARFDie &Die, CompileUnit &CU) { CompileUnit::DIEInfo &Info = CU.getInfo(Die); Info.ODRMarkingDone = true; if (Info.Keep && isODRCanonicalCandidate(Die, CU) && !Info.Ctxt->hasCanonicalDIE()) Info.Ctxt->setHasCanonicalDIE(); } /// Look at DIEs referenced by the given DIE and decide whether they should be /// kept. All DIEs referenced though attributes should be kept. void DWARFLinker::lookForRefDIEsToKeep( const DWARFDie &Die, CompileUnit &CU, unsigned Flags, const UnitListTy &Units, const DWARFFile &File, SmallVectorImpl &Worklist) { bool UseOdr = (Flags & DWARFLinker::TF_DependencyWalk) ? (Flags & DWARFLinker::TF_ODR) : CU.hasODR(); DWARFUnit &Unit = CU.getOrigUnit(); DWARFDataExtractor Data = Unit.getDebugInfoExtractor(); const auto *Abbrev = Die.getAbbreviationDeclarationPtr(); uint64_t Offset = Die.getOffset() + getULEB128Size(Abbrev->getCode()); SmallVector, 4> ReferencedDIEs; for (const auto &AttrSpec : Abbrev->attributes()) { DWARFFormValue Val(AttrSpec.Form); if (!Val.isFormClass(DWARFFormValue::FC_Reference) || AttrSpec.Attr == dwarf::DW_AT_sibling) { DWARFFormValue::skipValue(AttrSpec.Form, Data, &Offset, Unit.getFormParams()); continue; } Val.extractValue(Data, &Offset, Unit.getFormParams(), &Unit); CompileUnit *ReferencedCU; if (auto RefDie = resolveDIEReference(File, Units, Val, Die, ReferencedCU)) { CompileUnit::DIEInfo &Info = ReferencedCU->getInfo(RefDie); // If the referenced DIE has a DeclContext that has already been // emitted, then do not keep the one in this CU. We'll link to // the canonical DIE in cloneDieReferenceAttribute. // // FIXME: compatibility with dsymutil-classic. UseODR shouldn't // be necessary and could be advantageously replaced by // ReferencedCU->hasODR() && CU.hasODR(). // // FIXME: compatibility with dsymutil-classic. There is no // reason not to unique ref_addr references. if (AttrSpec.Form != dwarf::DW_FORM_ref_addr && isODRAttribute(AttrSpec.Attr) && Info.Ctxt && Info.Ctxt->hasCanonicalDIE()) continue; // Keep a module forward declaration if there is no definition. if (!(isODRAttribute(AttrSpec.Attr) && Info.Ctxt && Info.Ctxt->hasCanonicalDIE())) Info.Prune = false; ReferencedDIEs.emplace_back(RefDie, *ReferencedCU); } } unsigned ODRFlag = UseOdr ? DWARFLinker::TF_ODR : 0; // Add referenced DIEs in reverse order to the worklist to effectively // process them in order. for (auto &P : reverse(ReferencedDIEs)) { // Add a worklist item before every child to calculate incompleteness right // after the current child is processed. CompileUnit::DIEInfo &Info = P.second.getInfo(P.first); Worklist.emplace_back(Die, CU, WorklistItemType::UpdateRefIncompleteness, &Info); Worklist.emplace_back(P.first, P.second, DWARFLinker::TF_Keep | DWARFLinker::TF_DependencyWalk | ODRFlag); } } /// Look at the parent of the given DIE and decide whether they should be kept. void DWARFLinker::lookForParentDIEsToKeep( unsigned AncestorIdx, CompileUnit &CU, unsigned Flags, SmallVectorImpl &Worklist) { // Stop if we encounter an ancestor that's already marked as kept. if (CU.getInfo(AncestorIdx).Keep) return; DWARFUnit &Unit = CU.getOrigUnit(); DWARFDie ParentDIE = Unit.getDIEAtIndex(AncestorIdx); Worklist.emplace_back(CU.getInfo(AncestorIdx).ParentIdx, CU, Flags); Worklist.emplace_back(ParentDIE, CU, Flags); } /// Recursively walk the \p DIE tree and look for DIEs to keep. Store that /// information in \p CU's DIEInfo. /// /// This function is the entry point of the DIE selection algorithm. It is /// expected to walk the DIE tree in file order and (though the mediation of /// its helper) call hasValidRelocation() on each DIE that might be a 'root /// DIE' (See DwarfLinker class comment). /// /// While walking the dependencies of root DIEs, this function is also called, /// but during these dependency walks the file order is not respected. The /// TF_DependencyWalk flag tells us which kind of traversal we are currently /// doing. /// /// The recursive algorithm is implemented iteratively as a work list because /// very deep recursion could exhaust the stack for large projects. The work /// list acts as a scheduler for different types of work that need to be /// performed. /// /// The recursive nature of the algorithm is simulated by running the "main" /// algorithm (LookForDIEsToKeep) followed by either looking at more DIEs /// (LookForChildDIEsToKeep, LookForRefDIEsToKeep, LookForParentDIEsToKeep) or /// fixing up a computed property (UpdateChildIncompleteness, /// UpdateRefIncompleteness). /// /// The return value indicates whether the DIE is incomplete. void DWARFLinker::lookForDIEsToKeep(AddressesMap &AddressesMap, const UnitListTy &Units, const DWARFDie &Die, const DWARFFile &File, CompileUnit &Cu, unsigned Flags) { // LIFO work list. SmallVector Worklist; Worklist.emplace_back(Die, Cu, Flags); while (!Worklist.empty()) { WorklistItem Current = Worklist.pop_back_val(); // Look at the worklist type to decide what kind of work to perform. switch (Current.Type) { case WorklistItemType::UpdateChildIncompleteness: updateChildIncompleteness(Current.Die, Current.CU, *Current.OtherInfo); continue; case WorklistItemType::UpdateRefIncompleteness: updateRefIncompleteness(Current.Die, Current.CU, *Current.OtherInfo); continue; case WorklistItemType::LookForChildDIEsToKeep: lookForChildDIEsToKeep(Current.Die, Current.CU, Current.Flags, Worklist); continue; case WorklistItemType::LookForRefDIEsToKeep: lookForRefDIEsToKeep(Current.Die, Current.CU, Current.Flags, Units, File, Worklist); continue; case WorklistItemType::LookForParentDIEsToKeep: lookForParentDIEsToKeep(Current.AncestorIdx, Current.CU, Current.Flags, Worklist); continue; case WorklistItemType::MarkODRCanonicalDie: markODRCanonicalDie(Current.Die, Current.CU); continue; case WorklistItemType::LookForDIEsToKeep: break; } unsigned Idx = Current.CU.getOrigUnit().getDIEIndex(Current.Die); CompileUnit::DIEInfo &MyInfo = Current.CU.getInfo(Idx); if (MyInfo.Prune) { // We're walking the dependencies of a module forward declaration that was // kept because there is no definition. if (Current.Flags & TF_DependencyWalk) MyInfo.Prune = false; else continue; } // If the Keep flag is set, we are marking a required DIE's dependencies. // If our target is already marked as kept, we're all set. bool AlreadyKept = MyInfo.Keep; if ((Current.Flags & TF_DependencyWalk) && AlreadyKept) continue; if (!(Current.Flags & TF_DependencyWalk)) Current.Flags = shouldKeepDIE(AddressesMap, Current.Die, File, Current.CU, MyInfo, Current.Flags); // We need to mark context for the canonical die in the end of normal // traversing(not TF_DependencyWalk) or after normal traversing if die // was not marked as kept. if (!(Current.Flags & TF_DependencyWalk) || (MyInfo.ODRMarkingDone && !MyInfo.Keep)) { if (Current.CU.hasODR() || MyInfo.InModuleScope) Worklist.emplace_back(Current.Die, Current.CU, WorklistItemType::MarkODRCanonicalDie); } // Finish by looking for child DIEs. Because of the LIFO worklist we need // to schedule that work before any subsequent items are added to the // worklist. Worklist.emplace_back(Current.Die, Current.CU, Current.Flags, WorklistItemType::LookForChildDIEsToKeep); if (AlreadyKept || !(Current.Flags & TF_Keep)) continue; // If it is a newly kept DIE mark it as well as all its dependencies as // kept. MyInfo.Keep = true; // We're looking for incomplete types. MyInfo.Incomplete = Current.Die.getTag() != dwarf::DW_TAG_subprogram && Current.Die.getTag() != dwarf::DW_TAG_member && dwarf::toUnsigned(Current.Die.find(dwarf::DW_AT_declaration), 0); // After looking at the parent chain, look for referenced DIEs. Because of // the LIFO worklist we need to schedule that work before any subsequent // items are added to the worklist. Worklist.emplace_back(Current.Die, Current.CU, Current.Flags, WorklistItemType::LookForRefDIEsToKeep); bool UseOdr = (Current.Flags & TF_DependencyWalk) ? (Current.Flags & TF_ODR) : Current.CU.hasODR(); unsigned ODRFlag = UseOdr ? TF_ODR : 0; unsigned ParFlags = TF_ParentWalk | TF_Keep | TF_DependencyWalk | ODRFlag; // Now schedule the parent walk. Worklist.emplace_back(MyInfo.ParentIdx, Current.CU, ParFlags); } } #ifndef NDEBUG /// A broken link in the keep chain. By recording both the parent and the child /// we can show only broken links for DIEs with multiple children. struct BrokenLink { BrokenLink(DWARFDie Parent, DWARFDie Child) : Parent(Parent), Child(Child) {} DWARFDie Parent; DWARFDie Child; }; /// Verify the keep chain by looking for DIEs that are kept but who's parent /// isn't. static void verifyKeepChain(CompileUnit &CU) { std::vector Worklist; Worklist.push_back(CU.getOrigUnit().getUnitDIE()); // List of broken links. std::vector BrokenLinks; while (!Worklist.empty()) { const DWARFDie Current = Worklist.back(); Worklist.pop_back(); const bool CurrentDieIsKept = CU.getInfo(Current).Keep; for (DWARFDie Child : reverse(Current.children())) { Worklist.push_back(Child); const bool ChildDieIsKept = CU.getInfo(Child).Keep; if (!CurrentDieIsKept && ChildDieIsKept) BrokenLinks.emplace_back(Current, Child); } } if (!BrokenLinks.empty()) { for (BrokenLink Link : BrokenLinks) { WithColor::error() << formatv( "Found invalid link in keep chain between {0:x} and {1:x}\n", Link.Parent.getOffset(), Link.Child.getOffset()); errs() << "Parent:"; Link.Parent.dump(errs(), 0, {}); CU.getInfo(Link.Parent).dump(); errs() << "Child:"; Link.Child.dump(errs(), 2, {}); CU.getInfo(Link.Child).dump(); } report_fatal_error("invalid keep chain"); } } #endif /// Assign an abbreviation number to \p Abbrev. /// /// Our DIEs get freed after every DebugMapObject has been processed, /// thus the FoldingSet we use to unique DIEAbbrevs cannot refer to /// the instances hold by the DIEs. When we encounter an abbreviation /// that we don't know, we create a permanent copy of it. void DWARFLinker::assignAbbrev(DIEAbbrev &Abbrev) { // Check the set for priors. FoldingSetNodeID ID; Abbrev.Profile(ID); void *InsertToken; DIEAbbrev *InSet = AbbreviationsSet.FindNodeOrInsertPos(ID, InsertToken); // If it's newly added. if (InSet) { // Assign existing abbreviation number. Abbrev.setNumber(InSet->getNumber()); } else { // Add to abbreviation list. Abbreviations.push_back( std::make_unique(Abbrev.getTag(), Abbrev.hasChildren())); for (const auto &Attr : Abbrev.getData()) Abbreviations.back()->AddAttribute(Attr); AbbreviationsSet.InsertNode(Abbreviations.back().get(), InsertToken); // Assign the unique abbreviation number. Abbrev.setNumber(Abbreviations.size()); Abbreviations.back()->setNumber(Abbreviations.size()); } } unsigned DWARFLinker::DIECloner::cloneStringAttribute(DIE &Die, AttributeSpec AttrSpec, const DWARFFormValue &Val, const DWARFUnit &U, AttributesInfo &Info) { std::optional String = dwarf::toString(Val); if (!String) return 0; DwarfStringPoolEntryRef StringEntry; if (AttrSpec.Form == dwarf::DW_FORM_line_strp) { StringEntry = DebugLineStrPool.getEntry(*String); } else { StringEntry = DebugStrPool.getEntry(*String); if (AttrSpec.Attr == dwarf::DW_AT_APPLE_origin) { Info.HasAppleOrigin = true; if (std::optional FileName = ObjFile.Addresses->getLibraryInstallName()) { StringEntry = DebugStrPool.getEntry(*FileName); } } // Update attributes info. if (AttrSpec.Attr == dwarf::DW_AT_name) Info.Name = StringEntry; else if (AttrSpec.Attr == dwarf::DW_AT_MIPS_linkage_name || AttrSpec.Attr == dwarf::DW_AT_linkage_name) Info.MangledName = StringEntry; if (U.getVersion() >= 5) { // Switch everything to DW_FORM_strx strings. auto StringOffsetIndex = StringOffsetPool.getValueIndex(StringEntry.getOffset()); return Die .addValue(DIEAlloc, dwarf::Attribute(AttrSpec.Attr), dwarf::DW_FORM_strx, DIEInteger(StringOffsetIndex)) ->sizeOf(U.getFormParams()); } // Switch everything to out of line strings. AttrSpec.Form = dwarf::DW_FORM_strp; } Die.addValue(DIEAlloc, dwarf::Attribute(AttrSpec.Attr), AttrSpec.Form, DIEInteger(StringEntry.getOffset())); return 4; } unsigned DWARFLinker::DIECloner::cloneDieReferenceAttribute( DIE &Die, const DWARFDie &InputDIE, AttributeSpec AttrSpec, unsigned AttrSize, const DWARFFormValue &Val, const DWARFFile &File, CompileUnit &Unit) { const DWARFUnit &U = Unit.getOrigUnit(); uint64_t Ref; if (std::optional Off = Val.getAsRelativeReference()) Ref = Val.getUnit()->getOffset() + *Off; else if (Off = Val.getAsDebugInfoReference(); Off) Ref = *Off; else return 0; DIE *NewRefDie = nullptr; CompileUnit *RefUnit = nullptr; DWARFDie RefDie = Linker.resolveDIEReference(File, CompileUnits, Val, InputDIE, RefUnit); // If the referenced DIE is not found, drop the attribute. if (!RefDie || AttrSpec.Attr == dwarf::DW_AT_sibling) return 0; CompileUnit::DIEInfo &RefInfo = RefUnit->getInfo(RefDie); // If we already have emitted an equivalent DeclContext, just point // at it. if (isODRAttribute(AttrSpec.Attr) && RefInfo.Ctxt && RefInfo.Ctxt->getCanonicalDIEOffset()) { assert(RefInfo.Ctxt->hasCanonicalDIE() && "Offset to canonical die is set, but context is not marked"); DIEInteger Attr(RefInfo.Ctxt->getCanonicalDIEOffset()); Die.addValue(DIEAlloc, dwarf::Attribute(AttrSpec.Attr), dwarf::DW_FORM_ref_addr, Attr); return U.getRefAddrByteSize(); } if (!RefInfo.Clone) { // We haven't cloned this DIE yet. Just create an empty one and // store it. It'll get really cloned when we process it. RefInfo.UnclonedReference = true; RefInfo.Clone = DIE::get(DIEAlloc, dwarf::Tag(RefDie.getTag())); } NewRefDie = RefInfo.Clone; if (AttrSpec.Form == dwarf::DW_FORM_ref_addr || (Unit.hasODR() && isODRAttribute(AttrSpec.Attr))) { // We cannot currently rely on a DIEEntry to emit ref_addr // references, because the implementation calls back to DwarfDebug // to find the unit offset. (We don't have a DwarfDebug) // FIXME: we should be able to design DIEEntry reliance on // DwarfDebug away. uint64_t Attr; if (Ref < InputDIE.getOffset() && !RefInfo.UnclonedReference) { // We have already cloned that DIE. uint32_t NewRefOffset = RefUnit->getStartOffset() + NewRefDie->getOffset(); Attr = NewRefOffset; Die.addValue(DIEAlloc, dwarf::Attribute(AttrSpec.Attr), dwarf::DW_FORM_ref_addr, DIEInteger(Attr)); } else { // A forward reference. Note and fixup later. Attr = 0xBADDEF; Unit.noteForwardReference( NewRefDie, RefUnit, RefInfo.Ctxt, Die.addValue(DIEAlloc, dwarf::Attribute(AttrSpec.Attr), dwarf::DW_FORM_ref_addr, DIEInteger(Attr))); } return U.getRefAddrByteSize(); } Die.addValue(DIEAlloc, dwarf::Attribute(AttrSpec.Attr), dwarf::Form(AttrSpec.Form), DIEEntry(*NewRefDie)); return AttrSize; } void DWARFLinker::DIECloner::cloneExpression( DataExtractor &Data, DWARFExpression Expression, const DWARFFile &File, CompileUnit &Unit, SmallVectorImpl &OutputBuffer, int64_t AddrRelocAdjustment, bool IsLittleEndian) { using Encoding = DWARFExpression::Operation::Encoding; uint8_t OrigAddressByteSize = Unit.getOrigUnit().getAddressByteSize(); uint64_t OpOffset = 0; for (auto &Op : Expression) { auto Desc = Op.getDescription(); // DW_OP_const_type is variable-length and has 3 // operands. Thus far we only support 2. if ((Desc.Op.size() == 2 && Desc.Op[0] == Encoding::BaseTypeRef) || (Desc.Op.size() == 2 && Desc.Op[1] == Encoding::BaseTypeRef && Desc.Op[0] != Encoding::Size1)) Linker.reportWarning("Unsupported DW_OP encoding.", File); if ((Desc.Op.size() == 1 && Desc.Op[0] == Encoding::BaseTypeRef) || (Desc.Op.size() == 2 && Desc.Op[1] == Encoding::BaseTypeRef && Desc.Op[0] == Encoding::Size1)) { // This code assumes that the other non-typeref operand fits into 1 byte. assert(OpOffset < Op.getEndOffset()); uint32_t ULEBsize = Op.getEndOffset() - OpOffset - 1; assert(ULEBsize <= 16); // Copy over the operation. assert(!Op.getSubCode() && "SubOps not yet supported"); OutputBuffer.push_back(Op.getCode()); uint64_t RefOffset; if (Desc.Op.size() == 1) { RefOffset = Op.getRawOperand(0); } else { OutputBuffer.push_back(Op.getRawOperand(0)); RefOffset = Op.getRawOperand(1); } uint32_t Offset = 0; // Look up the base type. For DW_OP_convert, the operand may be 0 to // instead indicate the generic type. The same holds for // DW_OP_reinterpret, which is currently not supported. if (RefOffset > 0 || Op.getCode() != dwarf::DW_OP_convert) { RefOffset += Unit.getOrigUnit().getOffset(); auto RefDie = Unit.getOrigUnit().getDIEForOffset(RefOffset); CompileUnit::DIEInfo &Info = Unit.getInfo(RefDie); if (DIE *Clone = Info.Clone) Offset = Clone->getOffset(); else Linker.reportWarning( "base type ref doesn't point to DW_TAG_base_type.", File); } uint8_t ULEB[16]; unsigned RealSize = encodeULEB128(Offset, ULEB, ULEBsize); if (RealSize > ULEBsize) { // Emit the generic type as a fallback. RealSize = encodeULEB128(0, ULEB, ULEBsize); Linker.reportWarning("base type ref doesn't fit.", File); } assert(RealSize == ULEBsize && "padding failed"); ArrayRef ULEBbytes(ULEB, ULEBsize); OutputBuffer.append(ULEBbytes.begin(), ULEBbytes.end()); } else if (!Linker.Options.Update && Op.getCode() == dwarf::DW_OP_addrx) { if (std::optional SA = Unit.getOrigUnit().getAddrOffsetSectionItem( Op.getRawOperand(0))) { // DWARFLinker does not use addrx forms since it generates relocated // addresses. Replace DW_OP_addrx with DW_OP_addr here. // Argument of DW_OP_addrx should be relocated here as it is not // processed by applyValidRelocs. OutputBuffer.push_back(dwarf::DW_OP_addr); uint64_t LinkedAddress = SA->Address + AddrRelocAdjustment; if (IsLittleEndian != sys::IsLittleEndianHost) sys::swapByteOrder(LinkedAddress); ArrayRef AddressBytes( reinterpret_cast(&LinkedAddress), OrigAddressByteSize); OutputBuffer.append(AddressBytes.begin(), AddressBytes.end()); } else Linker.reportWarning("cannot read DW_OP_addrx operand.", File); } else if (!Linker.Options.Update && Op.getCode() == dwarf::DW_OP_constx) { if (std::optional SA = Unit.getOrigUnit().getAddrOffsetSectionItem( Op.getRawOperand(0))) { // DWARFLinker does not use constx forms since it generates relocated // addresses. Replace DW_OP_constx with DW_OP_const[*]u here. // Argument of DW_OP_constx should be relocated here as it is not // processed by applyValidRelocs. std::optional OutOperandKind; switch (OrigAddressByteSize) { case 4: OutOperandKind = dwarf::DW_OP_const4u; break; case 8: OutOperandKind = dwarf::DW_OP_const8u; break; default: Linker.reportWarning( formatv(("unsupported address size: {0}."), OrigAddressByteSize), File); break; } if (OutOperandKind) { OutputBuffer.push_back(*OutOperandKind); uint64_t LinkedAddress = SA->Address + AddrRelocAdjustment; if (IsLittleEndian != sys::IsLittleEndianHost) sys::swapByteOrder(LinkedAddress); ArrayRef AddressBytes( reinterpret_cast(&LinkedAddress), OrigAddressByteSize); OutputBuffer.append(AddressBytes.begin(), AddressBytes.end()); } } else Linker.reportWarning("cannot read DW_OP_constx operand.", File); } else { // Copy over everything else unmodified. StringRef Bytes = Data.getData().slice(OpOffset, Op.getEndOffset()); OutputBuffer.append(Bytes.begin(), Bytes.end()); } OpOffset = Op.getEndOffset(); } } unsigned DWARFLinker::DIECloner::cloneBlockAttribute( DIE &Die, const DWARFDie &InputDIE, const DWARFFile &File, CompileUnit &Unit, AttributeSpec AttrSpec, const DWARFFormValue &Val, bool IsLittleEndian) { DIEValueList *Attr; DIEValue Value; DIELoc *Loc = nullptr; DIEBlock *Block = nullptr; if (AttrSpec.Form == dwarf::DW_FORM_exprloc) { Loc = new (DIEAlloc) DIELoc; Linker.DIELocs.push_back(Loc); } else { Block = new (DIEAlloc) DIEBlock; Linker.DIEBlocks.push_back(Block); } Attr = Loc ? static_cast(Loc) : static_cast(Block); DWARFUnit &OrigUnit = Unit.getOrigUnit(); // If the block is a DWARF Expression, clone it into the temporary // buffer using cloneExpression(), otherwise copy the data directly. SmallVector Buffer; ArrayRef Bytes = *Val.getAsBlock(); if (DWARFAttribute::mayHaveLocationExpr(AttrSpec.Attr) && (Val.isFormClass(DWARFFormValue::FC_Block) || Val.isFormClass(DWARFFormValue::FC_Exprloc))) { DataExtractor Data(StringRef((const char *)Bytes.data(), Bytes.size()), IsLittleEndian, OrigUnit.getAddressByteSize()); DWARFExpression Expr(Data, OrigUnit.getAddressByteSize(), OrigUnit.getFormParams().Format); cloneExpression(Data, Expr, File, Unit, Buffer, Unit.getInfo(InputDIE).AddrAdjust, IsLittleEndian); Bytes = Buffer; } for (auto Byte : Bytes) Attr->addValue(DIEAlloc, static_cast(0), dwarf::DW_FORM_data1, DIEInteger(Byte)); // FIXME: If DIEBlock and DIELoc just reuses the Size field of // the DIE class, this "if" could be replaced by // Attr->setSize(Bytes.size()). if (Loc) Loc->setSize(Bytes.size()); else Block->setSize(Bytes.size()); if (Loc) Value = DIEValue(dwarf::Attribute(AttrSpec.Attr), dwarf::Form(AttrSpec.Form), Loc); else { // The expression location data might be updated and exceed the original // size. Check whether the new data fits into the original form. if ((AttrSpec.Form == dwarf::DW_FORM_block1 && (Bytes.size() > UINT8_MAX)) || (AttrSpec.Form == dwarf::DW_FORM_block2 && (Bytes.size() > UINT16_MAX)) || (AttrSpec.Form == dwarf::DW_FORM_block4 && (Bytes.size() > UINT32_MAX))) AttrSpec.Form = dwarf::DW_FORM_block; Value = DIEValue(dwarf::Attribute(AttrSpec.Attr), dwarf::Form(AttrSpec.Form), Block); } return Die.addValue(DIEAlloc, Value)->sizeOf(OrigUnit.getFormParams()); } unsigned DWARFLinker::DIECloner::cloneAddressAttribute( DIE &Die, const DWARFDie &InputDIE, AttributeSpec AttrSpec, unsigned AttrSize, const DWARFFormValue &Val, const CompileUnit &Unit, AttributesInfo &Info) { if (AttrSpec.Attr == dwarf::DW_AT_low_pc) Info.HasLowPc = true; if (LLVM_UNLIKELY(Linker.Options.Update)) { Die.addValue(DIEAlloc, dwarf::Attribute(AttrSpec.Attr), dwarf::Form(AttrSpec.Form), DIEInteger(Val.getRawUValue())); return AttrSize; } // Cloned Die may have address attributes relocated to a // totally unrelated value. This can happen: // - If high_pc is an address (Dwarf version == 2), then it might have been // relocated to a totally unrelated value (because the end address in the // object file might be start address of another function which got moved // independently by the linker). // - If address relocated in an inline_subprogram that happens at the // beginning of its inlining function. // To avoid above cases and to not apply relocation twice (in // applyValidRelocs and here), read address attribute from InputDIE and apply // Info.PCOffset here. std::optional AddrAttribute = InputDIE.find(AttrSpec.Attr); if (!AddrAttribute) llvm_unreachable("Cann't find attribute."); std::optional Addr = AddrAttribute->getAsAddress(); if (!Addr) { Linker.reportWarning("Cann't read address attribute value.", ObjFile); return 0; } if (InputDIE.getTag() == dwarf::DW_TAG_compile_unit && AttrSpec.Attr == dwarf::DW_AT_low_pc) { if (std::optional LowPC = Unit.getLowPc()) Addr = *LowPC; else return 0; } else if (InputDIE.getTag() == dwarf::DW_TAG_compile_unit && AttrSpec.Attr == dwarf::DW_AT_high_pc) { if (uint64_t HighPc = Unit.getHighPc()) Addr = HighPc; else return 0; } else { *Addr += Info.PCOffset; } if (AttrSpec.Form == dwarf::DW_FORM_addr) { Die.addValue(DIEAlloc, static_cast(AttrSpec.Attr), AttrSpec.Form, DIEInteger(*Addr)); return Unit.getOrigUnit().getAddressByteSize(); } auto AddrIndex = AddrPool.getValueIndex(*Addr); return Die .addValue(DIEAlloc, static_cast(AttrSpec.Attr), dwarf::Form::DW_FORM_addrx, DIEInteger(AddrIndex)) ->sizeOf(Unit.getOrigUnit().getFormParams()); } unsigned DWARFLinker::DIECloner::cloneScalarAttribute( DIE &Die, const DWARFDie &InputDIE, const DWARFFile &File, CompileUnit &Unit, AttributeSpec AttrSpec, const DWARFFormValue &Val, unsigned AttrSize, AttributesInfo &Info) { uint64_t Value; // Check for the offset to the macro table. If offset is incorrect then we // need to remove the attribute. if (AttrSpec.Attr == dwarf::DW_AT_macro_info) { if (std::optional Offset = Val.getAsSectionOffset()) { const llvm::DWARFDebugMacro *Macro = File.Dwarf->getDebugMacinfo(); if (Macro == nullptr || !Macro->hasEntryForOffset(*Offset)) return 0; } } if (AttrSpec.Attr == dwarf::DW_AT_macros) { if (std::optional Offset = Val.getAsSectionOffset()) { const llvm::DWARFDebugMacro *Macro = File.Dwarf->getDebugMacro(); if (Macro == nullptr || !Macro->hasEntryForOffset(*Offset)) return 0; } } if (AttrSpec.Attr == dwarf::DW_AT_str_offsets_base) { // DWARFLinker generates common .debug_str_offsets table used for all // compile units. The offset to the common .debug_str_offsets table is 8 on // DWARF32. Info.AttrStrOffsetBaseSeen = true; return Die .addValue(DIEAlloc, dwarf::DW_AT_str_offsets_base, dwarf::DW_FORM_sec_offset, DIEInteger(8)) ->sizeOf(Unit.getOrigUnit().getFormParams()); } if (LLVM_UNLIKELY(Linker.Options.Update)) { if (auto OptionalValue = Val.getAsUnsignedConstant()) Value = *OptionalValue; else if (auto OptionalValue = Val.getAsSignedConstant()) Value = *OptionalValue; else if (auto OptionalValue = Val.getAsSectionOffset()) Value = *OptionalValue; else { Linker.reportWarning( "Unsupported scalar attribute form. Dropping attribute.", File, &InputDIE); return 0; } if (AttrSpec.Attr == dwarf::DW_AT_declaration && Value) Info.IsDeclaration = true; if (AttrSpec.Form == dwarf::DW_FORM_loclistx) Die.addValue(DIEAlloc, dwarf::Attribute(AttrSpec.Attr), dwarf::Form(AttrSpec.Form), DIELocList(Value)); else Die.addValue(DIEAlloc, dwarf::Attribute(AttrSpec.Attr), dwarf::Form(AttrSpec.Form), DIEInteger(Value)); return AttrSize; } [[maybe_unused]] dwarf::Form OriginalForm = AttrSpec.Form; if (AttrSpec.Form == dwarf::DW_FORM_rnglistx) { // DWARFLinker does not generate .debug_addr table. Thus we need to change // all "addrx" related forms to "addr" version. Change DW_FORM_rnglistx // to DW_FORM_sec_offset here. std::optional Index = Val.getAsSectionOffset(); if (!Index) { Linker.reportWarning("Cannot read the attribute. Dropping.", File, &InputDIE); return 0; } std::optional Offset = Unit.getOrigUnit().getRnglistOffset(*Index); if (!Offset) { Linker.reportWarning("Cannot read the attribute. Dropping.", File, &InputDIE); return 0; } Value = *Offset; AttrSpec.Form = dwarf::DW_FORM_sec_offset; AttrSize = Unit.getOrigUnit().getFormParams().getDwarfOffsetByteSize(); } else if (AttrSpec.Form == dwarf::DW_FORM_loclistx) { // DWARFLinker does not generate .debug_addr table. Thus we need to change // all "addrx" related forms to "addr" version. Change DW_FORM_loclistx // to DW_FORM_sec_offset here. std::optional Index = Val.getAsSectionOffset(); if (!Index) { Linker.reportWarning("Cannot read the attribute. Dropping.", File, &InputDIE); return 0; } std::optional Offset = Unit.getOrigUnit().getLoclistOffset(*Index); if (!Offset) { Linker.reportWarning("Cannot read the attribute. Dropping.", File, &InputDIE); return 0; } Value = *Offset; AttrSpec.Form = dwarf::DW_FORM_sec_offset; AttrSize = Unit.getOrigUnit().getFormParams().getDwarfOffsetByteSize(); } else if (AttrSpec.Attr == dwarf::DW_AT_high_pc && Die.getTag() == dwarf::DW_TAG_compile_unit) { std::optional LowPC = Unit.getLowPc(); if (!LowPC) return 0; // Dwarf >= 4 high_pc is an size, not an address. Value = Unit.getHighPc() - *LowPC; } else if (AttrSpec.Form == dwarf::DW_FORM_sec_offset) Value = *Val.getAsSectionOffset(); else if (AttrSpec.Form == dwarf::DW_FORM_sdata) Value = *Val.getAsSignedConstant(); else if (auto OptionalValue = Val.getAsUnsignedConstant()) Value = *OptionalValue; else { Linker.reportWarning( "Unsupported scalar attribute form. Dropping attribute.", File, &InputDIE); return 0; } DIE::value_iterator Patch = Die.addValue(DIEAlloc, dwarf::Attribute(AttrSpec.Attr), dwarf::Form(AttrSpec.Form), DIEInteger(Value)); if (AttrSpec.Attr == dwarf::DW_AT_ranges || AttrSpec.Attr == dwarf::DW_AT_start_scope) { Unit.noteRangeAttribute(Die, Patch); Info.HasRanges = true; } else if (DWARFAttribute::mayHaveLocationList(AttrSpec.Attr) && dwarf::doesFormBelongToClass(AttrSpec.Form, DWARFFormValue::FC_SectionOffset, Unit.getOrigUnit().getVersion())) { CompileUnit::DIEInfo &LocationDieInfo = Unit.getInfo(InputDIE); Unit.noteLocationAttribute({Patch, LocationDieInfo.InDebugMap ? LocationDieInfo.AddrAdjust : Info.PCOffset}); } else if (AttrSpec.Attr == dwarf::DW_AT_declaration && Value) Info.IsDeclaration = true; // check that all dwarf::DW_FORM_rnglistx are handled previously. assert((Info.HasRanges || (OriginalForm != dwarf::DW_FORM_rnglistx)) && "Unhandled DW_FORM_rnglistx attribute"); return AttrSize; } /// Clone \p InputDIE's attribute described by \p AttrSpec with /// value \p Val, and add it to \p Die. /// \returns the size of the cloned attribute. unsigned DWARFLinker::DIECloner::cloneAttribute( DIE &Die, const DWARFDie &InputDIE, const DWARFFile &File, CompileUnit &Unit, const DWARFFormValue &Val, const AttributeSpec AttrSpec, unsigned AttrSize, AttributesInfo &Info, bool IsLittleEndian) { const DWARFUnit &U = Unit.getOrigUnit(); switch (AttrSpec.Form) { case dwarf::DW_FORM_strp: case dwarf::DW_FORM_line_strp: case dwarf::DW_FORM_string: case dwarf::DW_FORM_strx: case dwarf::DW_FORM_strx1: case dwarf::DW_FORM_strx2: case dwarf::DW_FORM_strx3: case dwarf::DW_FORM_strx4: return cloneStringAttribute(Die, AttrSpec, Val, U, Info); case dwarf::DW_FORM_ref_addr: case dwarf::DW_FORM_ref1: case dwarf::DW_FORM_ref2: case dwarf::DW_FORM_ref4: case dwarf::DW_FORM_ref8: return cloneDieReferenceAttribute(Die, InputDIE, AttrSpec, AttrSize, Val, File, Unit); case dwarf::DW_FORM_block: case dwarf::DW_FORM_block1: case dwarf::DW_FORM_block2: case dwarf::DW_FORM_block4: case dwarf::DW_FORM_exprloc: return cloneBlockAttribute(Die, InputDIE, File, Unit, AttrSpec, Val, IsLittleEndian); case dwarf::DW_FORM_addr: case dwarf::DW_FORM_addrx: case dwarf::DW_FORM_addrx1: case dwarf::DW_FORM_addrx2: case dwarf::DW_FORM_addrx3: case dwarf::DW_FORM_addrx4: return cloneAddressAttribute(Die, InputDIE, AttrSpec, AttrSize, Val, Unit, Info); case dwarf::DW_FORM_data1: case dwarf::DW_FORM_data2: case dwarf::DW_FORM_data4: case dwarf::DW_FORM_data8: case dwarf::DW_FORM_udata: case dwarf::DW_FORM_sdata: case dwarf::DW_FORM_sec_offset: case dwarf::DW_FORM_flag: case dwarf::DW_FORM_flag_present: case dwarf::DW_FORM_rnglistx: case dwarf::DW_FORM_loclistx: case dwarf::DW_FORM_implicit_const: return cloneScalarAttribute(Die, InputDIE, File, Unit, AttrSpec, Val, AttrSize, Info); default: Linker.reportWarning("Unsupported attribute form " + dwarf::FormEncodingString(AttrSpec.Form) + " in cloneAttribute. Dropping.", File, &InputDIE); } return 0; } void DWARFLinker::DIECloner::addObjCAccelerator(CompileUnit &Unit, const DIE *Die, DwarfStringPoolEntryRef Name, OffsetsStringPool &StringPool, bool SkipPubSection) { std::optional Names = getObjCNamesIfSelector(Name.getString()); if (!Names) return; Unit.addNameAccelerator(Die, StringPool.getEntry(Names->Selector), SkipPubSection); Unit.addObjCAccelerator(Die, StringPool.getEntry(Names->ClassName), SkipPubSection); if (Names->ClassNameNoCategory) Unit.addObjCAccelerator( Die, StringPool.getEntry(*Names->ClassNameNoCategory), SkipPubSection); if (Names->MethodNameNoCategory) Unit.addNameAccelerator( Die, StringPool.getEntry(*Names->MethodNameNoCategory), SkipPubSection); } static bool shouldSkipAttribute(bool Update, DWARFAbbreviationDeclaration::AttributeSpec AttrSpec, bool SkipPC) { switch (AttrSpec.Attr) { default: return false; case dwarf::DW_AT_low_pc: case dwarf::DW_AT_high_pc: case dwarf::DW_AT_ranges: return !Update && SkipPC; case dwarf::DW_AT_rnglists_base: // In case !Update the .debug_addr table is not generated/preserved. // Thus instead of DW_FORM_rnglistx the DW_FORM_sec_offset is used. // Since DW_AT_rnglists_base is used for only DW_FORM_rnglistx the // DW_AT_rnglists_base is removed. return !Update; case dwarf::DW_AT_loclists_base: // In case !Update the .debug_addr table is not generated/preserved. // Thus instead of DW_FORM_loclistx the DW_FORM_sec_offset is used. // Since DW_AT_loclists_base is used for only DW_FORM_loclistx the // DW_AT_loclists_base is removed. return !Update; case dwarf::DW_AT_location: case dwarf::DW_AT_frame_base: return !Update && SkipPC; } } struct AttributeLinkedOffsetFixup { int64_t LinkedOffsetFixupVal; uint64_t InputAttrStartOffset; uint64_t InputAttrEndOffset; }; DIE *DWARFLinker::DIECloner::cloneDIE(const DWARFDie &InputDIE, const DWARFFile &File, CompileUnit &Unit, int64_t PCOffset, uint32_t OutOffset, unsigned Flags, bool IsLittleEndian, DIE *Die) { DWARFUnit &U = Unit.getOrigUnit(); unsigned Idx = U.getDIEIndex(InputDIE); CompileUnit::DIEInfo &Info = Unit.getInfo(Idx); // Should the DIE appear in the output? if (!Unit.getInfo(Idx).Keep) return nullptr; uint64_t Offset = InputDIE.getOffset(); assert(!(Die && Info.Clone) && "Can't supply a DIE and a cloned DIE"); if (!Die) { // The DIE might have been already created by a forward reference // (see cloneDieReferenceAttribute()). if (!Info.Clone) Info.Clone = DIE::get(DIEAlloc, dwarf::Tag(InputDIE.getTag())); Die = Info.Clone; } assert(Die->getTag() == InputDIE.getTag()); Die->setOffset(OutOffset); if (isODRCanonicalCandidate(InputDIE, Unit) && Info.Ctxt && (Info.Ctxt->getCanonicalDIEOffset() == 0)) { if (!Info.Ctxt->hasCanonicalDIE()) Info.Ctxt->setHasCanonicalDIE(); // We are about to emit a DIE that is the root of its own valid // DeclContext tree. Make the current offset the canonical offset // for this context. Info.Ctxt->setCanonicalDIEOffset(OutOffset + Unit.getStartOffset()); } // Extract and clone every attribute. DWARFDataExtractor Data = U.getDebugInfoExtractor(); // Point to the next DIE (generally there is always at least a NULL // entry after the current one). If this is a lone // DW_TAG_compile_unit without any children, point to the next unit. uint64_t NextOffset = (Idx + 1 < U.getNumDIEs()) ? U.getDIEAtIndex(Idx + 1).getOffset() : U.getNextUnitOffset(); AttributesInfo AttrInfo; // We could copy the data only if we need to apply a relocation to it. After // testing, it seems there is no performance downside to doing the copy // unconditionally, and it makes the code simpler. SmallString<40> DIECopy(Data.getData().substr(Offset, NextOffset - Offset)); Data = DWARFDataExtractor(DIECopy, Data.isLittleEndian(), Data.getAddressSize()); // Modify the copy with relocated addresses. ObjFile.Addresses->applyValidRelocs(DIECopy, Offset, Data.isLittleEndian()); // Reset the Offset to 0 as we will be working on the local copy of // the data. Offset = 0; const auto *Abbrev = InputDIE.getAbbreviationDeclarationPtr(); Offset += getULEB128Size(Abbrev->getCode()); // We are entering a subprogram. Get and propagate the PCOffset. if (Die->getTag() == dwarf::DW_TAG_subprogram) PCOffset = Info.AddrAdjust; AttrInfo.PCOffset = PCOffset; if (Abbrev->getTag() == dwarf::DW_TAG_subprogram) { Flags |= TF_InFunctionScope; if (!Info.InDebugMap && LLVM_LIKELY(!Update)) Flags |= TF_SkipPC; } else if (Abbrev->getTag() == dwarf::DW_TAG_variable) { // Function-local globals could be in the debug map even when the function // is not, e.g., inlined functions. if ((Flags & TF_InFunctionScope) && Info.InDebugMap) Flags &= ~TF_SkipPC; // Location expressions referencing an address which is not in debug map // should be deleted. else if (!Info.InDebugMap && Info.HasLocationExpressionAddr && LLVM_LIKELY(!Update)) Flags |= TF_SkipPC; } std::optional LibraryInstallName = ObjFile.Addresses->getLibraryInstallName(); SmallVector AttributesFixups; for (const auto &AttrSpec : Abbrev->attributes()) { if (shouldSkipAttribute(Update, AttrSpec, Flags & TF_SkipPC)) { DWARFFormValue::skipValue(AttrSpec.Form, Data, &Offset, U.getFormParams()); continue; } AttributeLinkedOffsetFixup CurAttrFixup; CurAttrFixup.InputAttrStartOffset = InputDIE.getOffset() + Offset; CurAttrFixup.LinkedOffsetFixupVal = Unit.getStartOffset() + OutOffset - CurAttrFixup.InputAttrStartOffset; DWARFFormValue Val = AttrSpec.getFormValue(); uint64_t AttrSize = Offset; Val.extractValue(Data, &Offset, U.getFormParams(), &U); CurAttrFixup.InputAttrEndOffset = InputDIE.getOffset() + Offset; AttrSize = Offset - AttrSize; uint64_t FinalAttrSize = cloneAttribute(*Die, InputDIE, File, Unit, Val, AttrSpec, AttrSize, AttrInfo, IsLittleEndian); if (FinalAttrSize != 0 && ObjFile.Addresses->needToSaveValidRelocs()) AttributesFixups.push_back(CurAttrFixup); OutOffset += FinalAttrSize; } uint16_t Tag = InputDIE.getTag(); // Add the DW_AT_APPLE_origin attribute to Compile Unit die if we have // an install name and the DWARF doesn't have the attribute yet. const bool NeedsAppleOrigin = (Tag == dwarf::DW_TAG_compile_unit) && LibraryInstallName.has_value() && !AttrInfo.HasAppleOrigin; if (NeedsAppleOrigin) { auto StringEntry = DebugStrPool.getEntry(LibraryInstallName.value()); Die->addValue(DIEAlloc, dwarf::Attribute(dwarf::DW_AT_APPLE_origin), dwarf::DW_FORM_strp, DIEInteger(StringEntry.getOffset())); AttrInfo.Name = StringEntry; OutOffset += 4; } // Look for accelerator entries. // FIXME: This is slightly wrong. An inline_subroutine without a // low_pc, but with AT_ranges might be interesting to get into the // accelerator tables too. For now stick with dsymutil's behavior. if ((Info.InDebugMap || AttrInfo.HasLowPc || AttrInfo.HasRanges) && Tag != dwarf::DW_TAG_compile_unit && getDIENames(InputDIE, AttrInfo, DebugStrPool, Tag != dwarf::DW_TAG_inlined_subroutine)) { if (AttrInfo.MangledName && AttrInfo.MangledName != AttrInfo.Name) Unit.addNameAccelerator(Die, AttrInfo.MangledName, Tag == dwarf::DW_TAG_inlined_subroutine); if (AttrInfo.Name) { if (AttrInfo.NameWithoutTemplate) Unit.addNameAccelerator(Die, AttrInfo.NameWithoutTemplate, /* SkipPubSection */ true); Unit.addNameAccelerator(Die, AttrInfo.Name, Tag == dwarf::DW_TAG_inlined_subroutine); } if (AttrInfo.Name) addObjCAccelerator(Unit, Die, AttrInfo.Name, DebugStrPool, /* SkipPubSection =*/true); } else if (Tag == dwarf::DW_TAG_namespace) { if (!AttrInfo.Name) AttrInfo.Name = DebugStrPool.getEntry("(anonymous namespace)"); Unit.addNamespaceAccelerator(Die, AttrInfo.Name); } else if (Tag == dwarf::DW_TAG_imported_declaration && AttrInfo.Name) { Unit.addNamespaceAccelerator(Die, AttrInfo.Name); } else if (isTypeTag(Tag) && !AttrInfo.IsDeclaration && getDIENames(InputDIE, AttrInfo, DebugStrPool) && AttrInfo.Name && AttrInfo.Name.getString()[0]) { uint32_t Hash = hashFullyQualifiedName(InputDIE, Unit, File); uint64_t RuntimeLang = dwarf::toUnsigned(InputDIE.find(dwarf::DW_AT_APPLE_runtime_class)) .value_or(0); bool ObjCClassIsImplementation = (RuntimeLang == dwarf::DW_LANG_ObjC || RuntimeLang == dwarf::DW_LANG_ObjC_plus_plus) && dwarf::toUnsigned(InputDIE.find(dwarf::DW_AT_APPLE_objc_complete_type)) .value_or(0); Unit.addTypeAccelerator(Die, AttrInfo.Name, ObjCClassIsImplementation, Hash); } // Determine whether there are any children that we want to keep. bool HasChildren = false; for (auto Child : InputDIE.children()) { unsigned Idx = U.getDIEIndex(Child); if (Unit.getInfo(Idx).Keep) { HasChildren = true; break; } } if (Unit.getOrigUnit().getVersion() >= 5 && !AttrInfo.AttrStrOffsetBaseSeen && Die->getTag() == dwarf::DW_TAG_compile_unit) { // No DW_AT_str_offsets_base seen, add it to the DIE. Die->addValue(DIEAlloc, dwarf::DW_AT_str_offsets_base, dwarf::DW_FORM_sec_offset, DIEInteger(8)); OutOffset += 4; } DIEAbbrev NewAbbrev = Die->generateAbbrev(); if (HasChildren) NewAbbrev.setChildrenFlag(dwarf::DW_CHILDREN_yes); // Assign a permanent abbrev number Linker.assignAbbrev(NewAbbrev); Die->setAbbrevNumber(NewAbbrev.getNumber()); uint64_t AbbrevNumberSize = getULEB128Size(Die->getAbbrevNumber()); // Add the size of the abbreviation number to the output offset. OutOffset += AbbrevNumberSize; // Update fixups with the size of the abbreviation number for (AttributeLinkedOffsetFixup &F : AttributesFixups) F.LinkedOffsetFixupVal += AbbrevNumberSize; for (AttributeLinkedOffsetFixup &F : AttributesFixups) ObjFile.Addresses->updateAndSaveValidRelocs( Unit.getOrigUnit().getVersion() >= 5, Unit.getOrigUnit().getOffset(), F.LinkedOffsetFixupVal, F.InputAttrStartOffset, F.InputAttrEndOffset); if (!HasChildren) { // Update our size. Die->setSize(OutOffset - Die->getOffset()); return Die; } // Recursively clone children. for (auto Child : InputDIE.children()) { if (DIE *Clone = cloneDIE(Child, File, Unit, PCOffset, OutOffset, Flags, IsLittleEndian)) { Die->addChild(Clone); OutOffset = Clone->getOffset() + Clone->getSize(); } } // Account for the end of children marker. OutOffset += sizeof(int8_t); // Update our size. Die->setSize(OutOffset - Die->getOffset()); return Die; } /// Patch the input object file relevant debug_ranges or debug_rnglists /// entries and emit them in the output file. Update the relevant attributes /// to point at the new entries. void DWARFLinker::generateUnitRanges(CompileUnit &Unit, const DWARFFile &File, DebugDieValuePool &AddrPool) const { if (LLVM_UNLIKELY(Options.Update)) return; const auto &FunctionRanges = Unit.getFunctionRanges(); // Build set of linked address ranges for unit function ranges. AddressRanges LinkedFunctionRanges; for (const AddressRangeValuePair &Range : FunctionRanges) LinkedFunctionRanges.insert( {Range.Range.start() + Range.Value, Range.Range.end() + Range.Value}); // Emit LinkedFunctionRanges into .debug_aranges if (!LinkedFunctionRanges.empty()) TheDwarfEmitter->emitDwarfDebugArangesTable(Unit, LinkedFunctionRanges); RngListAttributesTy AllRngListAttributes = Unit.getRangesAttributes(); std::optional UnitRngListAttribute = Unit.getUnitRangesAttribute(); if (!AllRngListAttributes.empty() || UnitRngListAttribute) { std::optional CachedRange; MCSymbol *EndLabel = TheDwarfEmitter->emitDwarfDebugRangeListHeader(Unit); // Read original address ranges, apply relocation value, emit linked address // ranges. for (PatchLocation &AttributePatch : AllRngListAttributes) { // Get ranges from the source DWARF corresponding to the current // attribute. AddressRanges LinkedRanges; if (Expected OriginalRanges = Unit.getOrigUnit().findRnglistFromOffset(AttributePatch.get())) { // Apply relocation adjustment. for (const auto &Range : *OriginalRanges) { if (!CachedRange || !CachedRange->Range.contains(Range.LowPC)) CachedRange = FunctionRanges.getRangeThatContains(Range.LowPC); // All range entries should lie in the function range. if (!CachedRange) { reportWarning("inconsistent range data.", File); continue; } // Store range for emiting. LinkedRanges.insert({Range.LowPC + CachedRange->Value, Range.HighPC + CachedRange->Value}); } } else { llvm::consumeError(OriginalRanges.takeError()); reportWarning("invalid range list ignored.", File); } // Emit linked ranges. TheDwarfEmitter->emitDwarfDebugRangeListFragment( Unit, LinkedRanges, AttributePatch, AddrPool); } // Emit ranges for Unit AT_ranges attribute. if (UnitRngListAttribute.has_value()) TheDwarfEmitter->emitDwarfDebugRangeListFragment( Unit, LinkedFunctionRanges, *UnitRngListAttribute, AddrPool); // Emit ranges footer. TheDwarfEmitter->emitDwarfDebugRangeListFooter(Unit, EndLabel); } } void DWARFLinker::DIECloner::generateUnitLocations( CompileUnit &Unit, const DWARFFile &File, ExpressionHandlerRef ExprHandler) { if (LLVM_UNLIKELY(Linker.Options.Update)) return; const LocListAttributesTy &AllLocListAttributes = Unit.getLocationAttributes(); if (AllLocListAttributes.empty()) return; // Emit locations list table header. MCSymbol *EndLabel = Emitter->emitDwarfDebugLocListHeader(Unit); for (auto &CurLocAttr : AllLocListAttributes) { // Get location expressions vector corresponding to the current attribute // from the source DWARF. Expected OriginalLocations = Unit.getOrigUnit().findLoclistFromOffset(CurLocAttr.get()); if (!OriginalLocations) { llvm::consumeError(OriginalLocations.takeError()); Linker.reportWarning("Invalid location attribute ignored.", File); continue; } DWARFLocationExpressionsVector LinkedLocationExpressions; for (DWARFLocationExpression &CurExpression : *OriginalLocations) { DWARFLocationExpression LinkedExpression; if (CurExpression.Range) { // Relocate address range. LinkedExpression.Range = { CurExpression.Range->LowPC + CurLocAttr.RelocAdjustment, CurExpression.Range->HighPC + CurLocAttr.RelocAdjustment}; } // Clone expression. LinkedExpression.Expr.reserve(CurExpression.Expr.size()); ExprHandler(CurExpression.Expr, LinkedExpression.Expr, CurLocAttr.RelocAdjustment); LinkedLocationExpressions.push_back(LinkedExpression); } // Emit locations list table fragment corresponding to the CurLocAttr. Emitter->emitDwarfDebugLocListFragment(Unit, LinkedLocationExpressions, CurLocAttr, AddrPool); } // Emit locations list table footer. Emitter->emitDwarfDebugLocListFooter(Unit, EndLabel); } static void patchAddrBase(DIE &Die, DIEInteger Offset) { for (auto &V : Die.values()) if (V.getAttribute() == dwarf::DW_AT_addr_base) { V = DIEValue(V.getAttribute(), V.getForm(), Offset); return; } llvm_unreachable("Didn't find a DW_AT_addr_base in cloned DIE!"); } void DWARFLinker::DIECloner::emitDebugAddrSection( CompileUnit &Unit, const uint16_t DwarfVersion) const { if (LLVM_UNLIKELY(Linker.Options.Update)) return; if (DwarfVersion < 5) return; if (AddrPool.getValues().empty()) return; MCSymbol *EndLabel = Emitter->emitDwarfDebugAddrsHeader(Unit); patchAddrBase(*Unit.getOutputUnitDIE(), DIEInteger(Emitter->getDebugAddrSectionSize())); Emitter->emitDwarfDebugAddrs(AddrPool.getValues(), Unit.getOrigUnit().getAddressByteSize()); Emitter->emitDwarfDebugAddrsFooter(Unit, EndLabel); } /// Insert the new line info sequence \p Seq into the current /// set of already linked line info \p Rows. static void insertLineSequence(std::vector &Seq, std::vector &Rows) { if (Seq.empty()) return; if (!Rows.empty() && Rows.back().Address < Seq.front().Address) { llvm::append_range(Rows, Seq); Seq.clear(); return; } object::SectionedAddress Front = Seq.front().Address; auto InsertPoint = partition_point( Rows, [=](const DWARFDebugLine::Row &O) { return O.Address < Front; }); // FIXME: this only removes the unneeded end_sequence if the // sequences have been inserted in order. Using a global sort like // described in generateLineTableForUnit() and delaying the end_sequene // elimination to emitLineTableForUnit() we can get rid of all of them. if (InsertPoint != Rows.end() && InsertPoint->Address == Front && InsertPoint->EndSequence) { *InsertPoint = Seq.front(); Rows.insert(InsertPoint + 1, Seq.begin() + 1, Seq.end()); } else { Rows.insert(InsertPoint, Seq.begin(), Seq.end()); } Seq.clear(); } static void patchStmtList(DIE &Die, DIEInteger Offset) { for (auto &V : Die.values()) if (V.getAttribute() == dwarf::DW_AT_stmt_list) { V = DIEValue(V.getAttribute(), V.getForm(), Offset); return; } llvm_unreachable("Didn't find DW_AT_stmt_list in cloned DIE!"); } void DWARFLinker::DIECloner::rememberUnitForMacroOffset(CompileUnit &Unit) { DWARFUnit &OrigUnit = Unit.getOrigUnit(); DWARFDie OrigUnitDie = OrigUnit.getUnitDIE(); if (std::optional MacroAttr = dwarf::toSectionOffset(OrigUnitDie.find(dwarf::DW_AT_macros))) { UnitMacroMap.insert(std::make_pair(*MacroAttr, &Unit)); return; } if (std::optional MacroAttr = dwarf::toSectionOffset(OrigUnitDie.find(dwarf::DW_AT_macro_info))) { UnitMacroMap.insert(std::make_pair(*MacroAttr, &Unit)); return; } } void DWARFLinker::DIECloner::generateLineTableForUnit(CompileUnit &Unit) { if (LLVM_UNLIKELY(Emitter == nullptr)) return; // Check whether DW_AT_stmt_list attribute is presented. DWARFDie CUDie = Unit.getOrigUnit().getUnitDIE(); auto StmtList = dwarf::toSectionOffset(CUDie.find(dwarf::DW_AT_stmt_list)); if (!StmtList) return; // Update the cloned DW_AT_stmt_list with the correct debug_line offset. if (auto *OutputDIE = Unit.getOutputUnitDIE()) patchStmtList(*OutputDIE, DIEInteger(Emitter->getLineSectionSize())); if (const DWARFDebugLine::LineTable *LT = ObjFile.Dwarf->getLineTableForUnit(&Unit.getOrigUnit())) { DWARFDebugLine::LineTable LineTable; // Set Line Table header. LineTable.Prologue = LT->Prologue; // Set Line Table Rows. if (Linker.Options.Update) { LineTable.Rows = LT->Rows; // If all the line table contains is a DW_LNE_end_sequence, clear the line // table rows, it will be inserted again in the DWARFStreamer. if (LineTable.Rows.size() == 1 && LineTable.Rows[0].EndSequence) LineTable.Rows.clear(); LineTable.Sequences = LT->Sequences; } else { // This vector is the output line table. std::vector NewRows; NewRows.reserve(LT->Rows.size()); // Current sequence of rows being extracted, before being inserted // in NewRows. std::vector Seq; const auto &FunctionRanges = Unit.getFunctionRanges(); std::optional CurrRange; // FIXME: This logic is meant to generate exactly the same output as // Darwin's classic dsymutil. There is a nicer way to implement this // by simply putting all the relocated line info in NewRows and simply // sorting NewRows before passing it to emitLineTableForUnit. This // should be correct as sequences for a function should stay // together in the sorted output. There are a few corner cases that // look suspicious though, and that required to implement the logic // this way. Revisit that once initial validation is finished. // Iterate over the object file line info and extract the sequences // that correspond to linked functions. for (DWARFDebugLine::Row Row : LT->Rows) { // Check whether we stepped out of the range. The range is // half-open, but consider accept the end address of the range if // it is marked as end_sequence in the input (because in that // case, the relocation offset is accurate and that entry won't // serve as the start of another function). if (!CurrRange || !CurrRange->Range.contains(Row.Address.Address)) { // We just stepped out of a known range. Insert a end_sequence // corresponding to the end of the range. uint64_t StopAddress = CurrRange ? CurrRange->Range.end() + CurrRange->Value : -1ULL; CurrRange = FunctionRanges.getRangeThatContains(Row.Address.Address); if (StopAddress != -1ULL && !Seq.empty()) { // Insert end sequence row with the computed end address, but // the same line as the previous one. auto NextLine = Seq.back(); NextLine.Address.Address = StopAddress; NextLine.EndSequence = 1; NextLine.PrologueEnd = 0; NextLine.BasicBlock = 0; NextLine.EpilogueBegin = 0; Seq.push_back(NextLine); insertLineSequence(Seq, NewRows); } if (!CurrRange) continue; } // Ignore empty sequences. if (Row.EndSequence && Seq.empty()) continue; // Relocate row address and add it to the current sequence. Row.Address.Address += CurrRange->Value; Seq.emplace_back(Row); if (Row.EndSequence) insertLineSequence(Seq, NewRows); } LineTable.Rows = std::move(NewRows); } Emitter->emitLineTableForUnit(LineTable, Unit, DebugStrPool, DebugLineStrPool); } else Linker.reportWarning("Cann't load line table.", ObjFile); } void DWARFLinker::emitAcceleratorEntriesForUnit(CompileUnit &Unit) { for (AccelTableKind AccelTableKind : Options.AccelTables) { switch (AccelTableKind) { case AccelTableKind::Apple: { // Add namespaces. for (const auto &Namespace : Unit.getNamespaces()) AppleNamespaces.addName(Namespace.Name, Namespace.Die->getOffset() + Unit.getStartOffset()); // Add names. for (const auto &Pubname : Unit.getPubnames()) AppleNames.addName(Pubname.Name, Pubname.Die->getOffset() + Unit.getStartOffset()); // Add types. for (const auto &Pubtype : Unit.getPubtypes()) AppleTypes.addName( Pubtype.Name, Pubtype.Die->getOffset() + Unit.getStartOffset(), Pubtype.Die->getTag(), Pubtype.ObjcClassImplementation ? dwarf::DW_FLAG_type_implementation : 0, Pubtype.QualifiedNameHash); // Add ObjC names. for (const auto &ObjC : Unit.getObjC()) AppleObjc.addName(ObjC.Name, ObjC.Die->getOffset() + Unit.getStartOffset()); } break; case AccelTableKind::Pub: { TheDwarfEmitter->emitPubNamesForUnit(Unit); TheDwarfEmitter->emitPubTypesForUnit(Unit); } break; case AccelTableKind::DebugNames: { for (const auto &Namespace : Unit.getNamespaces()) DebugNames.addName( Namespace.Name, Namespace.Die->getOffset(), DWARF5AccelTableData::getDefiningParentDieOffset(*Namespace.Die), Namespace.Die->getTag(), Unit.getUniqueID(), Unit.getTag() == dwarf::DW_TAG_type_unit); for (const auto &Pubname : Unit.getPubnames()) DebugNames.addName( Pubname.Name, Pubname.Die->getOffset(), DWARF5AccelTableData::getDefiningParentDieOffset(*Pubname.Die), Pubname.Die->getTag(), Unit.getUniqueID(), Unit.getTag() == dwarf::DW_TAG_type_unit); for (const auto &Pubtype : Unit.getPubtypes()) DebugNames.addName( Pubtype.Name, Pubtype.Die->getOffset(), DWARF5AccelTableData::getDefiningParentDieOffset(*Pubtype.Die), Pubtype.Die->getTag(), Unit.getUniqueID(), Unit.getTag() == dwarf::DW_TAG_type_unit); } break; } } } /// Read the frame info stored in the object, and emit the /// patched frame descriptions for the resulting file. /// /// This is actually pretty easy as the data of the CIEs and FDEs can /// be considered as black boxes and moved as is. The only thing to do /// is to patch the addresses in the headers. void DWARFLinker::patchFrameInfoForObject(LinkContext &Context) { DWARFContext &OrigDwarf = *Context.File.Dwarf; unsigned SrcAddrSize = OrigDwarf.getDWARFObj().getAddressSize(); StringRef FrameData = OrigDwarf.getDWARFObj().getFrameSection().Data; if (FrameData.empty()) return; RangesTy AllUnitsRanges; for (std::unique_ptr &Unit : Context.CompileUnits) { for (auto CurRange : Unit->getFunctionRanges()) AllUnitsRanges.insert(CurRange.Range, CurRange.Value); } DataExtractor Data(FrameData, OrigDwarf.isLittleEndian(), 0); uint64_t InputOffset = 0; // Store the data of the CIEs defined in this object, keyed by their // offsets. DenseMap LocalCIES; while (Data.isValidOffset(InputOffset)) { uint64_t EntryOffset = InputOffset; uint32_t InitialLength = Data.getU32(&InputOffset); if (InitialLength == 0xFFFFFFFF) return reportWarning("Dwarf64 bits no supported", Context.File); uint32_t CIEId = Data.getU32(&InputOffset); if (CIEId == 0xFFFFFFFF) { // This is a CIE, store it. StringRef CIEData = FrameData.substr(EntryOffset, InitialLength + 4); LocalCIES[EntryOffset] = CIEData; // The -4 is to account for the CIEId we just read. InputOffset += InitialLength - 4; continue; } uint64_t Loc = Data.getUnsigned(&InputOffset, SrcAddrSize); // Some compilers seem to emit frame info that doesn't start at // the function entry point, thus we can't just lookup the address // in the debug map. Use the AddressInfo's range map to see if the FDE // describes something that we can relocate. std::optional Range = AllUnitsRanges.getRangeThatContains(Loc); if (!Range) { // The +4 is to account for the size of the InitialLength field itself. InputOffset = EntryOffset + InitialLength + 4; continue; } // This is an FDE, and we have a mapping. // Have we already emitted a corresponding CIE? StringRef CIEData = LocalCIES[CIEId]; if (CIEData.empty()) return reportWarning("Inconsistent debug_frame content. Dropping.", Context.File); // Look if we already emitted a CIE that corresponds to the // referenced one (the CIE data is the key of that lookup). auto IteratorInserted = EmittedCIEs.insert( std::make_pair(CIEData, TheDwarfEmitter->getFrameSectionSize())); // If there is no CIE yet for this ID, emit it. if (IteratorInserted.second) { LastCIEOffset = TheDwarfEmitter->getFrameSectionSize(); IteratorInserted.first->getValue() = LastCIEOffset; TheDwarfEmitter->emitCIE(CIEData); } // Emit the FDE with updated address and CIE pointer. // (4 + AddrSize) is the size of the CIEId + initial_location // fields that will get reconstructed by emitFDE(). unsigned FDERemainingBytes = InitialLength - (4 + SrcAddrSize); TheDwarfEmitter->emitFDE(IteratorInserted.first->getValue(), SrcAddrSize, Loc + Range->Value, FrameData.substr(InputOffset, FDERemainingBytes)); InputOffset += FDERemainingBytes; } } uint32_t DWARFLinker::DIECloner::hashFullyQualifiedName(DWARFDie DIE, CompileUnit &U, const DWARFFile &File, int ChildRecurseDepth) { const char *Name = nullptr; DWARFUnit *OrigUnit = &U.getOrigUnit(); CompileUnit *CU = &U; std::optional Ref; while (true) { if (const char *CurrentName = DIE.getName(DINameKind::ShortName)) Name = CurrentName; if (!(Ref = DIE.find(dwarf::DW_AT_specification)) && !(Ref = DIE.find(dwarf::DW_AT_abstract_origin))) break; if (!Ref->isFormClass(DWARFFormValue::FC_Reference)) break; CompileUnit *RefCU; if (auto RefDIE = Linker.resolveDIEReference(File, CompileUnits, *Ref, DIE, RefCU)) { CU = RefCU; OrigUnit = &RefCU->getOrigUnit(); DIE = RefDIE; } } unsigned Idx = OrigUnit->getDIEIndex(DIE); if (!Name && DIE.getTag() == dwarf::DW_TAG_namespace) Name = "(anonymous namespace)"; if (CU->getInfo(Idx).ParentIdx == 0 || // FIXME: dsymutil-classic compatibility. Ignore modules. CU->getOrigUnit().getDIEAtIndex(CU->getInfo(Idx).ParentIdx).getTag() == dwarf::DW_TAG_module) return djbHash(Name ? Name : "", djbHash(ChildRecurseDepth ? "" : "::")); DWARFDie Die = OrigUnit->getDIEAtIndex(CU->getInfo(Idx).ParentIdx); return djbHash( (Name ? Name : ""), djbHash((Name ? "::" : ""), hashFullyQualifiedName(Die, *CU, File, ++ChildRecurseDepth))); } static uint64_t getDwoId(const DWARFDie &CUDie) { auto DwoId = dwarf::toUnsigned( CUDie.find({dwarf::DW_AT_dwo_id, dwarf::DW_AT_GNU_dwo_id})); if (DwoId) return *DwoId; return 0; } static std::string remapPath(StringRef Path, const DWARFLinkerBase::ObjectPrefixMapTy &ObjectPrefixMap) { if (ObjectPrefixMap.empty()) return Path.str(); SmallString<256> p = Path; for (const auto &Entry : ObjectPrefixMap) if (llvm::sys::path::replace_path_prefix(p, Entry.first, Entry.second)) break; return p.str().str(); } static std::string getPCMFile(const DWARFDie &CUDie, const DWARFLinkerBase::ObjectPrefixMapTy *ObjectPrefixMap) { std::string PCMFile = dwarf::toString( CUDie.find({dwarf::DW_AT_dwo_name, dwarf::DW_AT_GNU_dwo_name}), ""); if (PCMFile.empty()) return PCMFile; if (ObjectPrefixMap) PCMFile = remapPath(PCMFile, *ObjectPrefixMap); return PCMFile; } std::pair DWARFLinker::isClangModuleRef(const DWARFDie &CUDie, std::string &PCMFile, LinkContext &Context, unsigned Indent, bool Quiet) { if (PCMFile.empty()) return std::make_pair(false, false); // Clang module DWARF skeleton CUs abuse this for the path to the module. uint64_t DwoId = getDwoId(CUDie); std::string Name = dwarf::toString(CUDie.find(dwarf::DW_AT_name), ""); if (Name.empty()) { if (!Quiet) reportWarning("Anonymous module skeleton CU for " + PCMFile, Context.File); return std::make_pair(true, true); } if (!Quiet && Options.Verbose) { outs().indent(Indent); outs() << "Found clang module reference " << PCMFile; } auto Cached = ClangModules.find(PCMFile); if (Cached != ClangModules.end()) { // FIXME: Until PR27449 (https://llvm.org/bugs/show_bug.cgi?id=27449) is // fixed in clang, only warn about DWO_id mismatches in verbose mode. // ASTFileSignatures will change randomly when a module is rebuilt. if (!Quiet && Options.Verbose && (Cached->second != DwoId)) reportWarning(Twine("hash mismatch: this object file was built against a " "different version of the module ") + PCMFile, Context.File); if (!Quiet && Options.Verbose) outs() << " [cached].\n"; return std::make_pair(true, true); } return std::make_pair(true, false); } bool DWARFLinker::registerModuleReference(const DWARFDie &CUDie, LinkContext &Context, ObjFileLoaderTy Loader, CompileUnitHandlerTy OnCUDieLoaded, unsigned Indent) { std::string PCMFile = getPCMFile(CUDie, Options.ObjectPrefixMap); std::pair IsClangModuleRef = isClangModuleRef(CUDie, PCMFile, Context, Indent, false); if (!IsClangModuleRef.first) return false; if (IsClangModuleRef.second) return true; if (Options.Verbose) outs() << " ...\n"; // Cyclic dependencies are disallowed by Clang, but we still // shouldn't run into an infinite loop, so mark it as processed now. ClangModules.insert({PCMFile, getDwoId(CUDie)}); if (Error E = loadClangModule(Loader, CUDie, PCMFile, Context, OnCUDieLoaded, Indent + 2)) { consumeError(std::move(E)); return false; } return true; } Error DWARFLinker::loadClangModule( ObjFileLoaderTy Loader, const DWARFDie &CUDie, const std::string &PCMFile, LinkContext &Context, CompileUnitHandlerTy OnCUDieLoaded, unsigned Indent) { uint64_t DwoId = getDwoId(CUDie); std::string ModuleName = dwarf::toString(CUDie.find(dwarf::DW_AT_name), ""); /// Using a SmallString<0> because loadClangModule() is recursive. SmallString<0> Path(Options.PrependPath); if (sys::path::is_relative(PCMFile)) resolveRelativeObjectPath(Path, CUDie); sys::path::append(Path, PCMFile); // Don't use the cached binary holder because we have no thread-safety // guarantee and the lifetime is limited. if (Loader == nullptr) { reportError("Could not load clang module: loader is not specified.\n", Context.File); return Error::success(); } auto ErrOrObj = Loader(Context.File.FileName, Path); if (!ErrOrObj) return Error::success(); std::unique_ptr Unit; for (const auto &CU : ErrOrObj->Dwarf->compile_units()) { OnCUDieLoaded(*CU); // Recursively get all modules imported by this one. auto ChildCUDie = CU->getUnitDIE(); if (!ChildCUDie) continue; if (!registerModuleReference(ChildCUDie, Context, Loader, OnCUDieLoaded, Indent)) { if (Unit) { std::string Err = (PCMFile + ": Clang modules are expected to have exactly 1 compile unit.\n"); reportError(Err, Context.File); return make_error(Err, inconvertibleErrorCode()); } // FIXME: Until PR27449 (https://llvm.org/bugs/show_bug.cgi?id=27449) is // fixed in clang, only warn about DWO_id mismatches in verbose mode. // ASTFileSignatures will change randomly when a module is rebuilt. uint64_t PCMDwoId = getDwoId(ChildCUDie); if (PCMDwoId != DwoId) { if (Options.Verbose) reportWarning( Twine("hash mismatch: this object file was built against a " "different version of the module ") + PCMFile, Context.File); // Update the cache entry with the DwoId of the module loaded from disk. ClangModules[PCMFile] = PCMDwoId; } // Add this module. Unit = std::make_unique(*CU, UniqueUnitID++, !Options.NoODR, ModuleName); } } if (Unit) Context.ModuleUnits.emplace_back(RefModuleUnit{*ErrOrObj, std::move(Unit)}); return Error::success(); } uint64_t DWARFLinker::DIECloner::cloneAllCompileUnits( DWARFContext &DwarfContext, const DWARFFile &File, bool IsLittleEndian) { uint64_t OutputDebugInfoSize = (Emitter == nullptr) ? 0 : Emitter->getDebugInfoSectionSize(); const uint64_t StartOutputDebugInfoSize = OutputDebugInfoSize; for (auto &CurrentUnit : CompileUnits) { const uint16_t DwarfVersion = CurrentUnit->getOrigUnit().getVersion(); const uint32_t UnitHeaderSize = DwarfVersion >= 5 ? 12 : 11; auto InputDIE = CurrentUnit->getOrigUnit().getUnitDIE(); CurrentUnit->setStartOffset(OutputDebugInfoSize); if (!InputDIE) { OutputDebugInfoSize = CurrentUnit->computeNextUnitOffset(DwarfVersion); continue; } if (CurrentUnit->getInfo(0).Keep) { // Clone the InputDIE into your Unit DIE in our compile unit since it // already has a DIE inside of it. CurrentUnit->createOutputDIE(); rememberUnitForMacroOffset(*CurrentUnit); cloneDIE(InputDIE, File, *CurrentUnit, 0 /* PC offset */, UnitHeaderSize, 0, IsLittleEndian, CurrentUnit->getOutputUnitDIE()); } OutputDebugInfoSize = CurrentUnit->computeNextUnitOffset(DwarfVersion); if (Emitter != nullptr) { generateLineTableForUnit(*CurrentUnit); Linker.emitAcceleratorEntriesForUnit(*CurrentUnit); if (LLVM_UNLIKELY(Linker.Options.Update)) continue; Linker.generateUnitRanges(*CurrentUnit, File, AddrPool); auto ProcessExpr = [&](SmallVectorImpl &SrcBytes, SmallVectorImpl &OutBytes, int64_t RelocAdjustment) { DWARFUnit &OrigUnit = CurrentUnit->getOrigUnit(); DataExtractor Data(SrcBytes, IsLittleEndian, OrigUnit.getAddressByteSize()); cloneExpression(Data, DWARFExpression(Data, OrigUnit.getAddressByteSize(), OrigUnit.getFormParams().Format), File, *CurrentUnit, OutBytes, RelocAdjustment, IsLittleEndian); }; generateUnitLocations(*CurrentUnit, File, ProcessExpr); emitDebugAddrSection(*CurrentUnit, DwarfVersion); } AddrPool.clear(); } if (Emitter != nullptr) { assert(Emitter); // Emit macro tables. Emitter->emitMacroTables(File.Dwarf.get(), UnitMacroMap, DebugStrPool); // Emit all the compile unit's debug information. for (auto &CurrentUnit : CompileUnits) { CurrentUnit->fixupForwardReferences(); if (!CurrentUnit->getOutputUnitDIE()) continue; unsigned DwarfVersion = CurrentUnit->getOrigUnit().getVersion(); assert(Emitter->getDebugInfoSectionSize() == CurrentUnit->getStartOffset()); Emitter->emitCompileUnitHeader(*CurrentUnit, DwarfVersion); Emitter->emitDIE(*CurrentUnit->getOutputUnitDIE()); assert(Emitter->getDebugInfoSectionSize() == CurrentUnit->computeNextUnitOffset(DwarfVersion)); } } return OutputDebugInfoSize - StartOutputDebugInfoSize; } void DWARFLinker::copyInvariantDebugSection(DWARFContext &Dwarf) { TheDwarfEmitter->emitSectionContents(Dwarf.getDWARFObj().getLocSection().Data, DebugSectionKind::DebugLoc); TheDwarfEmitter->emitSectionContents( Dwarf.getDWARFObj().getRangesSection().Data, DebugSectionKind::DebugRange); TheDwarfEmitter->emitSectionContents( Dwarf.getDWARFObj().getFrameSection().Data, DebugSectionKind::DebugFrame); TheDwarfEmitter->emitSectionContents(Dwarf.getDWARFObj().getArangesSection(), DebugSectionKind::DebugARanges); TheDwarfEmitter->emitSectionContents( Dwarf.getDWARFObj().getAddrSection().Data, DebugSectionKind::DebugAddr); TheDwarfEmitter->emitSectionContents( Dwarf.getDWARFObj().getRnglistsSection().Data, DebugSectionKind::DebugRngLists); TheDwarfEmitter->emitSectionContents( Dwarf.getDWARFObj().getLoclistsSection().Data, DebugSectionKind::DebugLocLists); } void DWARFLinker::addObjectFile(DWARFFile &File, ObjFileLoaderTy Loader, CompileUnitHandlerTy OnCUDieLoaded) { ObjectContexts.emplace_back(LinkContext(File)); if (ObjectContexts.back().File.Dwarf) { for (const std::unique_ptr &CU : ObjectContexts.back().File.Dwarf->compile_units()) { DWARFDie CUDie = CU->getUnitDIE(); if (!CUDie) continue; OnCUDieLoaded(*CU); if (!LLVM_UNLIKELY(Options.Update)) registerModuleReference(CUDie, ObjectContexts.back(), Loader, OnCUDieLoaded); } } } Error DWARFLinker::link() { assert((Options.TargetDWARFVersion != 0) && "TargetDWARFVersion should be set"); // First populate the data structure we need for each iteration of the // parallel loop. unsigned NumObjects = ObjectContexts.size(); // This Dwarf string pool which is used for emission. It must be used // serially as the order of calling getStringOffset matters for // reproducibility. OffsetsStringPool DebugStrPool(true); OffsetsStringPool DebugLineStrPool(false); DebugDieValuePool StringOffsetPool; // ODR Contexts for the optimize. DeclContextTree ODRContexts; for (LinkContext &OptContext : ObjectContexts) { if (Options.Verbose) outs() << "DEBUG MAP OBJECT: " << OptContext.File.FileName << "\n"; if (!OptContext.File.Dwarf) continue; if (Options.VerifyInputDWARF) verifyInput(OptContext.File); // Look for relocations that correspond to address map entries. // there was findvalidrelocations previously ... probably we need to gather // info here if (LLVM_LIKELY(!Options.Update) && !OptContext.File.Addresses->hasValidRelocs()) { if (Options.Verbose) outs() << "No valid relocations found. Skipping.\n"; // Set "Skip" flag as a signal to other loops that we should not // process this iteration. OptContext.Skip = true; continue; } // Setup access to the debug info. if (!OptContext.File.Dwarf) continue; // Check whether type units are presented. if (!OptContext.File.Dwarf->types_section_units().empty()) { reportWarning("type units are not currently supported: file will " "be skipped", OptContext.File); OptContext.Skip = true; continue; } // Clone all the clang modules with requires extracting the DIE units. We // don't need the full debug info until the Analyze phase. OptContext.CompileUnits.reserve( OptContext.File.Dwarf->getNumCompileUnits()); for (const auto &CU : OptContext.File.Dwarf->compile_units()) { auto CUDie = CU->getUnitDIE(/*ExtractUnitDIEOnly=*/true); if (Options.Verbose) { outs() << "Input compilation unit:"; DIDumpOptions DumpOpts; DumpOpts.ChildRecurseDepth = 0; DumpOpts.Verbose = Options.Verbose; CUDie.dump(outs(), 0, DumpOpts); } } for (auto &CU : OptContext.ModuleUnits) { if (Error Err = cloneModuleUnit(OptContext, CU, ODRContexts, DebugStrPool, DebugLineStrPool, StringOffsetPool)) reportWarning(toString(std::move(Err)), CU.File); } } // At this point we know how much data we have emitted. We use this value to // compare canonical DIE offsets in analyzeContextInfo to see if a definition // is already emitted, without being affected by canonical die offsets set // later. This prevents undeterminism when analyze and clone execute // concurrently, as clone set the canonical DIE offset and analyze reads it. const uint64_t ModulesEndOffset = (TheDwarfEmitter == nullptr) ? 0 : TheDwarfEmitter->getDebugInfoSectionSize(); // These variables manage the list of processed object files. // The mutex and condition variable are to ensure that this is thread safe. std::mutex ProcessedFilesMutex; std::condition_variable ProcessedFilesConditionVariable; BitVector ProcessedFiles(NumObjects, false); // Analyzing the context info is particularly expensive so it is executed in // parallel with emitting the previous compile unit. auto AnalyzeLambda = [&](size_t I) { auto &Context = ObjectContexts[I]; if (Context.Skip || !Context.File.Dwarf) return; for (const auto &CU : Context.File.Dwarf->compile_units()) { // Previously we only extracted the unit DIEs. We need the full debug info // now. auto CUDie = CU->getUnitDIE(/*ExtractUnitDIEOnly=*/false); std::string PCMFile = getPCMFile(CUDie, Options.ObjectPrefixMap); if (!CUDie || LLVM_UNLIKELY(Options.Update) || !isClangModuleRef(CUDie, PCMFile, Context, 0, true).first) { Context.CompileUnits.push_back(std::make_unique( *CU, UniqueUnitID++, !Options.NoODR && !Options.Update, "")); } } // Now build the DIE parent links that we will use during the next phase. for (auto &CurrentUnit : Context.CompileUnits) { auto CUDie = CurrentUnit->getOrigUnit().getUnitDIE(); if (!CUDie) continue; analyzeContextInfo(CurrentUnit->getOrigUnit().getUnitDIE(), 0, *CurrentUnit, &ODRContexts.getRoot(), ODRContexts, ModulesEndOffset, Options.ParseableSwiftInterfaces, [&](const Twine &Warning, const DWARFDie &DIE) { reportWarning(Warning, Context.File, &DIE); }); } }; // For each object file map how many bytes were emitted. StringMap SizeByObject; // And then the remaining work in serial again. // Note, although this loop runs in serial, it can run in parallel with // the analyzeContextInfo loop so long as we process files with indices >= // than those processed by analyzeContextInfo. auto CloneLambda = [&](size_t I) { auto &OptContext = ObjectContexts[I]; if (OptContext.Skip || !OptContext.File.Dwarf) return; // Then mark all the DIEs that need to be present in the generated output // and collect some information about them. // Note that this loop can not be merged with the previous one because // cross-cu references require the ParentIdx to be setup for every CU in // the object file before calling this. if (LLVM_UNLIKELY(Options.Update)) { for (auto &CurrentUnit : OptContext.CompileUnits) CurrentUnit->markEverythingAsKept(); copyInvariantDebugSection(*OptContext.File.Dwarf); } else { for (auto &CurrentUnit : OptContext.CompileUnits) { lookForDIEsToKeep(*OptContext.File.Addresses, OptContext.CompileUnits, CurrentUnit->getOrigUnit().getUnitDIE(), OptContext.File, *CurrentUnit, 0); #ifndef NDEBUG verifyKeepChain(*CurrentUnit); #endif } } // The calls to applyValidRelocs inside cloneDIE will walk the reloc // array again (in the same way findValidRelocsInDebugInfo() did). We // need to reset the NextValidReloc index to the beginning. if (OptContext.File.Addresses->hasValidRelocs() || LLVM_UNLIKELY(Options.Update)) { SizeByObject[OptContext.File.FileName].Input = getDebugInfoSize(*OptContext.File.Dwarf); SizeByObject[OptContext.File.FileName].Output = DIECloner(*this, TheDwarfEmitter, OptContext.File, DIEAlloc, OptContext.CompileUnits, Options.Update, DebugStrPool, DebugLineStrPool, StringOffsetPool) .cloneAllCompileUnits(*OptContext.File.Dwarf, OptContext.File, OptContext.File.Dwarf->isLittleEndian()); } if ((TheDwarfEmitter != nullptr) && !OptContext.CompileUnits.empty() && LLVM_LIKELY(!Options.Update)) patchFrameInfoForObject(OptContext); // Clean-up before starting working on the next object. cleanupAuxiliarryData(OptContext); }; auto EmitLambda = [&]() { // Emit everything that's global. if (TheDwarfEmitter != nullptr) { TheDwarfEmitter->emitAbbrevs(Abbreviations, Options.TargetDWARFVersion); TheDwarfEmitter->emitStrings(DebugStrPool); TheDwarfEmitter->emitStringOffsets(StringOffsetPool.getValues(), Options.TargetDWARFVersion); TheDwarfEmitter->emitLineStrings(DebugLineStrPool); for (AccelTableKind TableKind : Options.AccelTables) { switch (TableKind) { case AccelTableKind::Apple: TheDwarfEmitter->emitAppleNamespaces(AppleNamespaces); TheDwarfEmitter->emitAppleNames(AppleNames); TheDwarfEmitter->emitAppleTypes(AppleTypes); TheDwarfEmitter->emitAppleObjc(AppleObjc); break; case AccelTableKind::Pub: // Already emitted by emitAcceleratorEntriesForUnit. // Already emitted by emitAcceleratorEntriesForUnit. break; case AccelTableKind::DebugNames: TheDwarfEmitter->emitDebugNames(DebugNames); break; } } } }; auto AnalyzeAll = [&]() { for (unsigned I = 0, E = NumObjects; I != E; ++I) { AnalyzeLambda(I); std::unique_lock LockGuard(ProcessedFilesMutex); ProcessedFiles.set(I); ProcessedFilesConditionVariable.notify_one(); } }; auto CloneAll = [&]() { for (unsigned I = 0, E = NumObjects; I != E; ++I) { { std::unique_lock LockGuard(ProcessedFilesMutex); if (!ProcessedFiles[I]) { ProcessedFilesConditionVariable.wait( LockGuard, [&]() { return ProcessedFiles[I]; }); } } CloneLambda(I); } EmitLambda(); }; // To limit memory usage in the single threaded case, analyze and clone are // run sequentially so the OptContext is freed after processing each object // in endDebugObject. if (Options.Threads == 1) { for (unsigned I = 0, E = NumObjects; I != E; ++I) { AnalyzeLambda(I); CloneLambda(I); } EmitLambda(); } else { DefaultThreadPool Pool(hardware_concurrency(2)); Pool.async(AnalyzeAll); Pool.async(CloneAll); Pool.wait(); } if (Options.Statistics) { // Create a vector sorted in descending order by output size. std::vector> Sorted; for (auto &E : SizeByObject) Sorted.emplace_back(E.first(), E.second); llvm::sort(Sorted, [](auto &LHS, auto &RHS) { return LHS.second.Output > RHS.second.Output; }); auto ComputePercentange = [](int64_t Input, int64_t Output) -> float { const float Difference = Output - Input; const float Sum = Input + Output; if (Sum == 0) return 0; return (Difference / (Sum / 2)); }; int64_t InputTotal = 0; int64_t OutputTotal = 0; const char *FormatStr = "{0,-45} {1,10}b {2,10}b {3,8:P}\n"; // Print header. outs() << ".debug_info section size (in bytes)\n"; outs() << "----------------------------------------------------------------" "---------------\n"; outs() << "Filename Object " " dSYM Change\n"; outs() << "----------------------------------------------------------------" "---------------\n"; // Print body. for (auto &E : Sorted) { InputTotal += E.second.Input; OutputTotal += E.second.Output; llvm::outs() << formatv( FormatStr, sys::path::filename(E.first).take_back(45), E.second.Input, E.second.Output, ComputePercentange(E.second.Input, E.second.Output)); } // Print total and footer. outs() << "----------------------------------------------------------------" "---------------\n"; llvm::outs() << formatv(FormatStr, "Total", InputTotal, OutputTotal, ComputePercentange(InputTotal, OutputTotal)); outs() << "----------------------------------------------------------------" "---------------\n\n"; } return Error::success(); } Error DWARFLinker::cloneModuleUnit(LinkContext &Context, RefModuleUnit &Unit, DeclContextTree &ODRContexts, OffsetsStringPool &DebugStrPool, OffsetsStringPool &DebugLineStrPool, DebugDieValuePool &StringOffsetPool, unsigned Indent) { assert(Unit.Unit.get() != nullptr); if (!Unit.Unit->getOrigUnit().getUnitDIE().hasChildren()) return Error::success(); if (Options.Verbose) { outs().indent(Indent); outs() << "cloning .debug_info from " << Unit.File.FileName << "\n"; } // Analyze context for the module. analyzeContextInfo(Unit.Unit->getOrigUnit().getUnitDIE(), 0, *(Unit.Unit), &ODRContexts.getRoot(), ODRContexts, 0, Options.ParseableSwiftInterfaces, [&](const Twine &Warning, const DWARFDie &DIE) { reportWarning(Warning, Context.File, &DIE); }); // Keep everything. Unit.Unit->markEverythingAsKept(); // Clone unit. UnitListTy CompileUnits; CompileUnits.emplace_back(std::move(Unit.Unit)); assert(TheDwarfEmitter); DIECloner(*this, TheDwarfEmitter, Unit.File, DIEAlloc, CompileUnits, Options.Update, DebugStrPool, DebugLineStrPool, StringOffsetPool) .cloneAllCompileUnits(*Unit.File.Dwarf, Unit.File, Unit.File.Dwarf->isLittleEndian()); return Error::success(); } void DWARFLinker::verifyInput(const DWARFFile &File) { assert(File.Dwarf); std::string Buffer; raw_string_ostream OS(Buffer); DIDumpOptions DumpOpts; if (!File.Dwarf->verify(OS, DumpOpts.noImplicitRecursion())) { if (Options.InputVerificationHandler) Options.InputVerificationHandler(File, OS.str()); } } } // namespace llvm