DwarfDebug.cpp

  for (Value::use_iterator UI = RootC->use_begin(), UE = Root->use_end();
       UI != UE; ++UI)
    for (Value::use_iterator UUI = UI->use_begin(), UUE = UI->use_end();
         UUI != UUE; ++UUI) {
      GlobalVariable *GV = cast<GlobalVariable>(*UUI);
      ConstructCompileUnit(GV);
    }
}

bool DwarfDebug::ConstructGlobalVariableDIE(GlobalVariable *GV) {
  DIGlobalVariable DI_GV(GV);
  CompileUnit *DW_Unit = MainCU;
  if (!DW_Unit)
    DW_Unit = &FindCompileUnit(DI_GV.getCompileUnit());

  // Check for pre-existence.
  DIE *&Slot = DW_Unit->getDieMapSlotFor(DI_GV.getGV());
  if (Slot)
    return false;

  DIE *VariableDie = CreateGlobalVariableDIE(DW_Unit, DI_GV);

  // Add address.
  DIEBlock *Block = new DIEBlock();
  AddUInt(Block, 0, dwarf::DW_FORM_data1, dwarf::DW_OP_addr);
  std::string GLN;
  AddObjectLabel(Block, 0, dwarf::DW_FORM_udata,
                 Asm->getGlobalLinkName(DI_GV.getGlobal(), GLN));
  AddBlock(VariableDie, dwarf::DW_AT_location, 0, Block);

  // Add to map.
  Slot = VariableDie;

  // Add to context owner.
  DW_Unit->getDie()->AddChild(VariableDie);

  // Expose as global. FIXME - need to check external flag.
  std::string Name;
  DW_Unit->AddGlobal(DI_GV.getName(Name), VariableDie);
  return true;
}

/// ConstructGlobalVariableDIEs - Create DIEs for each of the externally visible
/// global variables. Return true if at least one global DIE is created.
bool DwarfDebug::ConstructGlobalVariableDIEs() {
  GlobalVariable *Root = M->getGlobalVariable("llvm.dbg.global_variables");
  if (!Root)
    return false;

  assert(Root->hasLinkOnceLinkage() && Root->hasOneUse() &&
         "Malformed global variable descriptor anchor type");
  Constant *RootC = cast<Constant>(*Root->use_begin());
  assert(RootC->hasNUsesOrMore(1) &&
         "Malformed global variable descriptor anchor type");

  bool Result = false;
  for (Value::use_iterator UI = RootC->use_begin(), UE = Root->use_end();
       UI != UE; ++UI)
    for (Value::use_iterator UUI = UI->use_begin(), UUE = UI->use_end();
         UUI != UUE; ++UUI)
      Result |= ConstructGlobalVariableDIE(cast<GlobalVariable>(*UUI));

  return Result;
}

bool DwarfDebug::ConstructSubprogram(GlobalVariable *GV) {
  DISubprogram SP(GV);
  CompileUnit *Unit = MainCU;
  if (!Unit)
    Unit = &FindCompileUnit(SP.getCompileUnit());

  // Check for pre-existence.
  DIE *&Slot = Unit->getDieMapSlotFor(GV);
  if (Slot)
    return false;

  if (!SP.isDefinition())
    // This is a method declaration which will be handled while constructing
    // class type.
    return false;

  DIE *SubprogramDie = CreateSubprogramDIE(Unit, SP);

  // Add to map.
  Slot = SubprogramDie;

  // Add to context owner.
  Unit->getDie()->AddChild(SubprogramDie);

  // Expose as global.
  std::string Name;
  Unit->AddGlobal(SP.getName(Name), SubprogramDie);
  return true;
}

/// ConstructSubprograms - Create DIEs for each of the externally visible
/// subprograms. Return true if at least one subprogram DIE is created.
bool DwarfDebug::ConstructSubprograms() {
  GlobalVariable *Root = M->getGlobalVariable("llvm.dbg.subprograms");
  if (!Root)
    return false;

  assert(Root->hasLinkOnceLinkage() && Root->hasOneUse() &&
         "Malformed subprogram descriptor anchor type");
  Constant *RootC = cast<Constant>(*Root->use_begin());
  assert(RootC->hasNUsesOrMore(1) &&
         "Malformed subprogram descriptor anchor type");

  bool Result = false;
  for (Value::use_iterator UI = RootC->use_begin(), UE = Root->use_end();
       UI != UE; ++UI)
    for (Value::use_iterator UUI = UI->use_begin(), UUE = UI->use_end();
         UUI != UUE; ++UUI)
      Result |= ConstructSubprogram(cast<GlobalVariable>(*UUI));

  return Result;
}

/// SetDebugInfo - Create global DIEs and emit initial debug info sections.
/// This is inovked by the target AsmPrinter.
void DwarfDebug::SetDebugInfo(MachineModuleInfo *mmi) {
  if (TimePassesIsEnabled)
    DebugTimer->startTimer();

  // Create all the compile unit DIEs.
  ConstructCompileUnits();

  if (CompileUnits.empty()) {
    if (TimePassesIsEnabled)
      DebugTimer->stopTimer();

    return;
  }

  // Create DIEs for each of the externally visible global variables.
  bool globalDIEs = ConstructGlobalVariableDIEs();

  // Create DIEs for each of the externally visible subprograms.
  bool subprogramDIEs = ConstructSubprograms();

  // If there is not any debug info available for any global variables and any
  // subprograms then there is not any debug info to emit.
  if (!globalDIEs && !subprogramDIEs) {
    if (TimePassesIsEnabled)
      DebugTimer->stopTimer();

    return;
  }

  MMI = mmi;
  shouldEmit = true;
  MMI->setDebugInfoAvailability(true);

  // Prime section data.
  SectionMap.insert(TAI->getTextSection());

  // Print out .file directives to specify files for .loc directives. These are
  // printed out early so that they precede any .loc directives.
  if (TAI->hasDotLocAndDotFile()) {
    for (unsigned i = 1, e = getNumSourceIds()+1; i != e; ++i) {
      // Remember source id starts at 1.
      std::pair<unsigned, unsigned> Id = getSourceDirectoryAndFileIds(i);
      sys::Path FullPath(getSourceDirectoryName(Id.first));
      bool AppendOk =
        FullPath.appendComponent(getSourceFileName(Id.second));
      assert(AppendOk && "Could not append filename to directory!");
      AppendOk = false;
      Asm->EmitFile(i, FullPath.toString());
      Asm->EOL();
    }
  }

  // Emit initial sections
  EmitInitial();

  if (TimePassesIsEnabled)
    DebugTimer->stopTimer();
}

/// EndModule - Emit all Dwarf sections that should come after the content.
///
void DwarfDebug::EndModule() {
  if (!ShouldEmitDwarfDebug())
    return;

  if (TimePassesIsEnabled)
    DebugTimer->startTimer();

  // Standard sections final addresses.
  Asm->SwitchToSection(TAI->getTextSection());
  EmitLabel("text_end", 0);
  Asm->SwitchToSection(TAI->getDataSection());
  EmitLabel("data_end", 0);

  // End text sections.
  for (unsigned i = 1, N = SectionMap.size(); i <= N; ++i) {
    Asm->SwitchToSection(SectionMap[i]);
    EmitLabel("section_end", i);
  }

  // Emit common frame information.
  EmitCommonDebugFrame();

  // Emit function debug frame information
  for (std::vector<FunctionDebugFrameInfo>::iterator I = DebugFrames.begin(),
         E = DebugFrames.end(); I != E; ++I)
    EmitFunctionDebugFrame(*I);

  // Compute DIE offsets and sizes.
  SizeAndOffsets();

  // Emit all the DIEs into a debug info section
  EmitDebugInfo();

  // Corresponding abbreviations into a abbrev section.
  EmitAbbreviations();

  // Emit source line correspondence into a debug line section.
  EmitDebugLines();

  // Emit info into a debug pubnames section.
  EmitDebugPubNames();

  // Emit info into a debug str section.
  EmitDebugStr();

  // Emit info into a debug loc section.
  EmitDebugLoc();

  // Emit info into a debug aranges section.
  EmitDebugARanges();

  // Emit info into a debug ranges section.
  EmitDebugRanges();

  // Emit info into a debug macinfo section.
  EmitDebugMacInfo();

  // Emit inline info.
  EmitDebugInlineInfo();

  if (TimePassesIsEnabled)
    DebugTimer->stopTimer();
}

/// BeginFunction - Gather pre-function debug information.  Assumes being
/// emitted immediately after the function entry point.
void DwarfDebug::BeginFunction(MachineFunction *MF) {
  this->MF = MF;

  if (!ShouldEmitDwarfDebug()) return;

  if (TimePassesIsEnabled)
    DebugTimer->startTimer();

  // Begin accumulating function debug information.
  MMI->BeginFunction(MF);

  // Assumes in correct section after the entry point.
  EmitLabel("func_begin", ++SubprogramCount);

  // Emit label for the implicitly defined dbg.stoppoint at the start of the
  // function.
  DebugLoc FDL = MF->getDefaultDebugLoc();
  if (!FDL.isUnknown()) {
    DebugLocTuple DLT = MF->getDebugLocTuple(FDL);
    unsigned LabelID = RecordSourceLine(DLT.Line, DLT.Col,
                                        DICompileUnit(DLT.CompileUnit));
    Asm->printLabel(LabelID);
  }

  if (TimePassesIsEnabled)
    DebugTimer->stopTimer();
}

/// EndFunction - Gather and emit post-function debug information.
///
void DwarfDebug::EndFunction(MachineFunction *MF) {
  if (!ShouldEmitDwarfDebug()) return;

  if (TimePassesIsEnabled)
    DebugTimer->startTimer();

  // Define end label for subprogram.
  EmitLabel("func_end", SubprogramCount);

  // Get function line info.
  if (!Lines.empty()) {
    // Get section line info.
    unsigned ID = SectionMap.insert(Asm->CurrentSection_);
    if (SectionSourceLines.size() < ID) SectionSourceLines.resize(ID);
    std::vector<SrcLineInfo> &SectionLineInfos = SectionSourceLines[ID-1];
    // Append the function info to section info.
    SectionLineInfos.insert(SectionLineInfos.end(),
                            Lines.begin(), Lines.end());
  }

  // Construct the DbgScope for abstract instances.
  for (SmallVector<DbgScope *, 32>::iterator
         I = AbstractInstanceRootList.begin(),
         E = AbstractInstanceRootList.end(); I != E; ++I)
    ConstructAbstractDbgScope(*I);

  // Construct scopes for subprogram.
  if (FunctionDbgScope)
    ConstructFunctionDbgScope(FunctionDbgScope);
  else
    // FIXME: This is wrong. We are essentially getting past a problem with
    // debug information not being able to handle unreachable blocks that have
    // debug information in them. In particular, those unreachable blocks that
    // have "region end" info in them. That situation results in the "root
    // scope" not being created. If that's the case, then emit a "default"
    // scope, i.e., one that encompasses the whole function. This isn't
    // desirable. And a better way of handling this (and all of the debugging
    // information) needs to be explored.
    ConstructDefaultDbgScope(MF);

  DebugFrames.push_back(FunctionDebugFrameInfo(SubprogramCount,
                                               MMI->getFrameMoves()));

  // Clear debug info
  if (FunctionDbgScope) {
    delete FunctionDbgScope;
    DbgScopeMap.clear();
    DbgAbstractScopeMap.clear();
    DbgConcreteScopeMap.clear();
    InlinedVariableScopes.clear();
    FunctionDbgScope = NULL;
    LexicalScopeStack.clear();
    AbstractInstanceRootList.clear();
  }

  Lines.clear();

  if (TimePassesIsEnabled)
    DebugTimer->stopTimer();
}

/// RecordSourceLine - Records location information and associates it with a
/// label. Returns a unique label ID used to generate a label and provide
/// correspondence to the source line list.
unsigned DwarfDebug::RecordSourceLine(Value *V, unsigned Line, unsigned Col) {
  if (TimePassesIsEnabled)
    DebugTimer->startTimer();

  CompileUnit *Unit = CompileUnitMap[V];
  assert(Unit && "Unable to find CompileUnit");
  unsigned ID = MMI->NextLabelID();
  Lines.push_back(SrcLineInfo(Line, Col, Unit->getID(), ID));

  if (TimePassesIsEnabled)
    DebugTimer->stopTimer();

  return ID;
}

/// RecordSourceLine - Records location information and associates it with a
/// label. Returns a unique label ID used to generate a label and provide
/// correspondence to the source line list.
unsigned DwarfDebug::RecordSourceLine(unsigned Line, unsigned Col,
                                      DICompileUnit CU) {
  if (TimePassesIsEnabled)
    DebugTimer->startTimer();

  std::string Dir, Fn;
  unsigned Src = GetOrCreateSourceID(CU.getDirectory(Dir),
                                     CU.getFilename(Fn));
  unsigned ID = MMI->NextLabelID();
  Lines.push_back(SrcLineInfo(Line, Col, Src, ID));

  if (TimePassesIsEnabled)
    DebugTimer->stopTimer();

  return ID;
}

/// getOrCreateSourceID - Public version of GetOrCreateSourceID. This can be
/// timed. Look up the source id with the given directory and source file
/// names. If none currently exists, create a new id and insert it in the
/// SourceIds map. This can update DirectoryNames and SourceFileNames maps as
/// well.
unsigned DwarfDebug::getOrCreateSourceID(const std::string &DirName,
                                         const std::string &FileName) {
  if (TimePassesIsEnabled)
    DebugTimer->startTimer();

  unsigned SrcId = GetOrCreateSourceID(DirName, FileName);

  if (TimePassesIsEnabled)
    DebugTimer->stopTimer();

  return SrcId;
}

/// RecordRegionStart - Indicate the start of a region.
unsigned DwarfDebug::RecordRegionStart(GlobalVariable *V) {
  if (TimePassesIsEnabled)
    DebugTimer->startTimer();

  DbgScope *Scope = getOrCreateScope(V);
  unsigned ID = MMI->NextLabelID();
  if (!Scope->getStartLabelID()) Scope->setStartLabelID(ID);
  LexicalScopeStack.push_back(Scope);

  if (TimePassesIsEnabled)
    DebugTimer->stopTimer();

  return ID;
}

/// RecordRegionEnd - Indicate the end of a region.
unsigned DwarfDebug::RecordRegionEnd(GlobalVariable *V) {
  if (TimePassesIsEnabled)
    DebugTimer->startTimer();

  DbgScope *Scope = getOrCreateScope(V);
  unsigned ID = MMI->NextLabelID();
  Scope->setEndLabelID(ID);
  if (LexicalScopeStack.size() != 0)
    LexicalScopeStack.pop_back();

  if (TimePassesIsEnabled)
    DebugTimer->stopTimer();

  return ID;
}

/// RecordVariable - Indicate the declaration of a local variable.
void DwarfDebug::RecordVariable(GlobalVariable *GV, unsigned FrameIndex,
                                const MachineInstr *MI) {
  if (TimePassesIsEnabled)
    DebugTimer->startTimer();

  DIDescriptor Desc(GV);
  DbgScope *Scope = NULL;

  if (Desc.getTag() == dwarf::DW_TAG_variable) {
    // GV is a global variable.
    DIGlobalVariable DG(GV);
    Scope = getOrCreateScope(DG.getContext().getGV());
  } else {
    DenseMap<const MachineInstr *, DbgScope *>::iterator
      SI = InlinedVariableScopes.find(MI);

    if (SI != InlinedVariableScopes.end()) {
      // or GV is an inlined local variable.
      Scope = SI->second;
    } else {
      DIVariable DV(GV);
      GlobalVariable *V = DV.getContext().getGV();

      // FIXME: The code that checks for the inlined local variable is a hack!
      DenseMap<const GlobalVariable *, DbgScope *>::iterator
        AI = AbstractInstanceRootMap.find(V);

      if (AI != AbstractInstanceRootMap.end()) {
        // This method is called each time a DECLARE node is encountered. For an
        // inlined function, this could be many, many times. We don't want to
        // re-add variables to that DIE for each time. We just want to add them
        // once. Check to make sure that we haven't added them already.
        DenseMap<const GlobalVariable *,
          SmallSet<const GlobalVariable *, 32> >::iterator
          IP = InlinedParamMap.find(V);

        if (IP != InlinedParamMap.end() && IP->second.count(GV) > 0) {
          if (TimePassesIsEnabled)
            DebugTimer->stopTimer();
          return;
        }

        // or GV is an inlined local variable.
        Scope = AI->second;
        InlinedParamMap[V].insert(GV);
      } else {
        // or GV is a local variable.
        Scope = getOrCreateScope(V);
      }
    }
  }

  assert(Scope && "Unable to find the variable's scope");
  DbgVariable *DV = new DbgVariable(DIVariable(GV), FrameIndex);
  Scope->AddVariable(DV);

  if (TimePassesIsEnabled)
    DebugTimer->stopTimer();
}

//// RecordInlinedFnStart - Indicate the start of inlined subroutine.
unsigned DwarfDebug::RecordInlinedFnStart(DISubprogram &SP, DICompileUnit CU,
                                          unsigned Line, unsigned Col) {
  unsigned LabelID = MMI->NextLabelID();

  if (!TAI->doesDwarfUsesInlineInfoSection())
    return LabelID;

  if (TimePassesIsEnabled)
    DebugTimer->startTimer();

  GlobalVariable *GV = SP.getGV();
  DenseMap<const GlobalVariable *, DbgScope *>::iterator
    II = AbstractInstanceRootMap.find(GV);

  if (II == AbstractInstanceRootMap.end()) {
    // Create an abstract instance entry for this inlined function if it doesn't
    // already exist.
    DbgScope *Scope = new DbgScope(NULL, DIDescriptor(GV));

    // Get the compile unit context.
    CompileUnit *Unit = &FindCompileUnit(SP.getCompileUnit());
    DIE *SPDie = Unit->getDieMapSlotFor(GV);
    if (!SPDie)
      SPDie = CreateSubprogramDIE(Unit, SP, false, true);

    // Mark as being inlined. This makes this subprogram entry an abstract
    // instance root.
    // FIXME: Our debugger doesn't care about the value of DW_AT_inline, only
    // that it's defined. That probably won't change in the future. However,
    // this could be more elegant.
    AddUInt(SPDie, dwarf::DW_AT_inline, 0, dwarf::DW_INL_declared_not_inlined);

    // Keep track of the abstract scope for this function.
    DbgAbstractScopeMap[GV] = Scope;

    AbstractInstanceRootMap[GV] = Scope;
    AbstractInstanceRootList.push_back(Scope);
  }

  // Create a concrete inlined instance for this inlined function.
  DbgConcreteScope *ConcreteScope = new DbgConcreteScope(DIDescriptor(GV));
  DIE *ScopeDie = new DIE(dwarf::DW_TAG_inlined_subroutine);
  CompileUnit *Unit = &FindCompileUnit(SP.getCompileUnit());
  ScopeDie->setAbstractCompileUnit(Unit);

  DIE *Origin = Unit->getDieMapSlotFor(GV);
  AddDIEEntry(ScopeDie, dwarf::DW_AT_abstract_origin,
              dwarf::DW_FORM_ref4, Origin);
  AddUInt(ScopeDie, dwarf::DW_AT_call_file, 0, Unit->getID());
  AddUInt(ScopeDie, dwarf::DW_AT_call_line, 0, Line);
  AddUInt(ScopeDie, dwarf::DW_AT_call_column, 0, Col);

  ConcreteScope->setDie(ScopeDie);
  ConcreteScope->setStartLabelID(LabelID);
  MMI->RecordUsedDbgLabel(LabelID);

  LexicalScopeStack.back()->AddConcreteInst(ConcreteScope);

  // Keep track of the concrete scope that's inlined into this function.
  DenseMap<GlobalVariable *, SmallVector<DbgScope *, 8> >::iterator
    SI = DbgConcreteScopeMap.find(GV);

  if (SI == DbgConcreteScopeMap.end())
    DbgConcreteScopeMap[GV].push_back(ConcreteScope);
  else
    SI->second.push_back(ConcreteScope);

  // Track the start label for this inlined function.
  DenseMap<GlobalVariable *, SmallVector<unsigned, 4> >::iterator
    I = InlineInfo.find(GV);

  if (I == InlineInfo.end())
    InlineInfo[GV].push_back(LabelID);
  else
    I->second.push_back(LabelID);

  if (TimePassesIsEnabled)
    DebugTimer->stopTimer();

  return LabelID;
}

/// RecordInlinedFnEnd - Indicate the end of inlined subroutine.
unsigned DwarfDebug::RecordInlinedFnEnd(DISubprogram &SP) {
  if (!TAI->doesDwarfUsesInlineInfoSection())
    return 0;

  if (TimePassesIsEnabled)
    DebugTimer->startTimer();

  GlobalVariable *GV = SP.getGV();
  DenseMap<GlobalVariable *, SmallVector<DbgScope *, 8> >::iterator
    I = DbgConcreteScopeMap.find(GV);

  if (I == DbgConcreteScopeMap.end()) {
    // FIXME: Can this situation actually happen? And if so, should it?
    if (TimePassesIsEnabled)
      DebugTimer->stopTimer();

    return 0;
  }

  SmallVector<DbgScope *, 8> &Scopes = I->second;
  assert(!Scopes.empty() && "We should have at least one debug scope!");
  DbgScope *Scope = Scopes.back(); Scopes.pop_back();
  unsigned ID = MMI->NextLabelID();
  MMI->RecordUsedDbgLabel(ID);
  Scope->setEndLabelID(ID);

  if (TimePassesIsEnabled)
    DebugTimer->stopTimer();

  return ID;
}

/// RecordVariableScope - Record scope for the variable declared by
/// DeclareMI. DeclareMI must describe TargetInstrInfo::DECLARE. Record scopes
/// for only inlined subroutine variables. Other variables's scopes are
/// determined during RecordVariable().
void DwarfDebug::RecordVariableScope(DIVariable &DV,
                                     const MachineInstr *DeclareMI) {
  if (TimePassesIsEnabled)
    DebugTimer->startTimer();

  DISubprogram SP(DV.getContext().getGV());

  if (SP.isNull()) {
    if (TimePassesIsEnabled)
      DebugTimer->stopTimer();

    return;
  }

  DenseMap<GlobalVariable *, DbgScope *>::iterator
    I = DbgAbstractScopeMap.find(SP.getGV());
  if (I != DbgAbstractScopeMap.end())
    InlinedVariableScopes[DeclareMI] = I->second;

  if (TimePassesIsEnabled)
    DebugTimer->stopTimer();
}