llvm-6502/include/llvm/Analysis/DebugInfo.h

741 lines
28 KiB
C++

//===--- llvm/Analysis/DebugInfo.h - Debug Information Helpers --*- C++ -*-===//
//
// The LLVM Compiler Infrastructure
//
// This file is distributed under the University of Illinois Open Source
// License. See LICENSE.TXT for details.
//
//===----------------------------------------------------------------------===//
//
// This file defines a bunch of datatypes that are useful for creating and
// walking debug info in LLVM IR form. They essentially provide wrappers around
// the information in the global variables that's needed when constructing the
// DWARF information.
//
//===----------------------------------------------------------------------===//
#ifndef LLVM_ANALYSIS_DEBUGINFO_H
#define LLVM_ANALYSIS_DEBUGINFO_H
#include "llvm/Metadata.h"
#include "llvm/Target/TargetMachine.h"
#include "llvm/ADT/StringMap.h"
#include "llvm/ADT/DenseMap.h"
#include "llvm/ADT/SmallVector.h"
#include "llvm/ADT/SmallPtrSet.h"
#include "llvm/Support/Dwarf.h"
#include "llvm/Support/ValueHandle.h"
namespace llvm {
class BasicBlock;
class Constant;
class Function;
class GlobalVariable;
class Module;
class Type;
class Value;
struct DbgStopPointInst;
struct DbgDeclareInst;
struct DbgFuncStartInst;
struct DbgRegionStartInst;
struct DbgRegionEndInst;
class DebugLoc;
struct DebugLocTracker;
class Instruction;
class LLVMContext;
class DIDescriptor {
protected:
TrackingVH<MDNode> DbgNode;
/// DIDescriptor constructor. If the specified node is non-null, check
/// to make sure that the tag in the descriptor matches 'RequiredTag'. If
/// not, the debug info is corrupt and we ignore it.
DIDescriptor(MDNode *N, unsigned RequiredTag);
const char *getStringField(unsigned Elt) const;
unsigned getUnsignedField(unsigned Elt) const {
return (unsigned)getUInt64Field(Elt);
}
uint64_t getUInt64Field(unsigned Elt) const;
DIDescriptor getDescriptorField(unsigned Elt) const;
template <typename DescTy>
DescTy getFieldAs(unsigned Elt) const {
return DescTy(getDescriptorField(Elt).getNode());
}
GlobalVariable *getGlobalVariableField(unsigned Elt) const;
public:
explicit DIDescriptor() : DbgNode(0) {}
explicit DIDescriptor(MDNode *N) : DbgNode(N) {}
bool isNull() const { return DbgNode == 0; }
MDNode *getNode() const { return DbgNode; }
unsigned getVersion() const {
return getUnsignedField(0) & LLVMDebugVersionMask;
}
unsigned getTag() const {
return getUnsignedField(0) & ~LLVMDebugVersionMask;
}
/// ValidDebugInfo - Return true if N represents valid debug info value.
static bool ValidDebugInfo(MDNode *N, CodeGenOpt::Level OptLevel);
/// dump - print descriptor.
void dump() const;
bool isDerivedType() const;
bool isCompositeType() const;
bool isBasicType() const;
bool isVariable() const;
bool isSubprogram() const;
bool isGlobalVariable() const;
bool isScope() const;
bool isCompileUnit() const;
bool isLexicalBlock() const;
bool isSubrange() const;
bool isEnumerator() const;
bool isType() const;
bool isGlobal() const;
};
/// DISubrange - This is used to represent ranges, for array bounds.
class DISubrange : public DIDescriptor {
public:
explicit DISubrange(MDNode *N = 0)
: DIDescriptor(N, dwarf::DW_TAG_subrange_type) {}
int64_t getLo() const { return (int64_t)getUInt64Field(1); }
int64_t getHi() const { return (int64_t)getUInt64Field(2); }
};
/// DIArray - This descriptor holds an array of descriptors.
class DIArray : public DIDescriptor {
public:
explicit DIArray(MDNode *N = 0)
: DIDescriptor(N) {}
unsigned getNumElements() const;
DIDescriptor getElement(unsigned Idx) const {
return getDescriptorField(Idx);
}
};
/// DIScope - A base class for various scopes.
class DIScope : public DIDescriptor {
public:
explicit DIScope(MDNode *N = 0) : DIDescriptor (N) {
if (DbgNode && !isScope())
DbgNode = 0;
}
virtual ~DIScope() {}
const char *getFilename() const;
const char *getDirectory() const;
};
/// DICompileUnit - A wrapper for a compile unit.
class DICompileUnit : public DIScope {
public:
explicit DICompileUnit(MDNode *N = 0) : DIScope(N) {
if (DbgNode && !isCompileUnit())
DbgNode = 0;
}
unsigned getLanguage() const { return getUnsignedField(2); }
const char *getFilename() const { return getStringField(3); }
const char *getDirectory() const { return getStringField(4); }
const char *getProducer() const { return getStringField(5); }
/// isMain - Each input file is encoded as a separate compile unit in LLVM
/// debugging information output. However, many target specific tool chains
/// prefer to encode only one compile unit in an object file. In this
/// situation, the LLVM code generator will include debugging information
/// entities in the compile unit that is marked as main compile unit. The
/// code generator accepts maximum one main compile unit per module. If a
/// module does not contain any main compile unit then the code generator
/// will emit multiple compile units in the output object file.
bool isMain() const { return getUnsignedField(6); }
bool isOptimized() const { return getUnsignedField(7); }
const char *getFlags() const { return getStringField(8); }
unsigned getRunTimeVersion() const { return getUnsignedField(9); }
/// Verify - Verify that a compile unit is well formed.
bool Verify() const;
/// dump - print compile unit.
void dump() const;
};
/// DIEnumerator - A wrapper for an enumerator (e.g. X and Y in 'enum {X,Y}').
/// FIXME: it seems strange that this doesn't have either a reference to the
/// type/precision or a file/line pair for location info.
class DIEnumerator : public DIDescriptor {
public:
explicit DIEnumerator(MDNode *N = 0)
: DIDescriptor(N, dwarf::DW_TAG_enumerator) {}
const char *getName() const { return getStringField(1); }
uint64_t getEnumValue() const { return getUInt64Field(2); }
};
/// DIType - This is a wrapper for a type.
/// FIXME: Types should be factored much better so that CV qualifiers and
/// others do not require a huge and empty descriptor full of zeros.
class DIType : public DIDescriptor {
public:
enum {
FlagPrivate = 1 << 0,
FlagProtected = 1 << 1,
FlagFwdDecl = 1 << 2,
FlagAppleBlock = 1 << 3,
FlagBlockByrefStruct = 1 << 4
};
protected:
DIType(MDNode *N, unsigned Tag)
: DIDescriptor(N, Tag) {}
// This ctor is used when the Tag has already been validated by a derived
// ctor.
DIType(MDNode *N, bool, bool) : DIDescriptor(N) {}
public:
/// Verify - Verify that a type descriptor is well formed.
bool Verify() const;
public:
explicit DIType(MDNode *N);
explicit DIType() {}
virtual ~DIType() {}
DIDescriptor getContext() const { return getDescriptorField(1); }
const char *getName() const { return getStringField(2); }
DICompileUnit getCompileUnit() const{ return getFieldAs<DICompileUnit>(3); }
unsigned getLineNumber() const { return getUnsignedField(4); }
uint64_t getSizeInBits() const { return getUInt64Field(5); }
uint64_t getAlignInBits() const { return getUInt64Field(6); }
// FIXME: Offset is only used for DW_TAG_member nodes. Making every type
// carry this is just plain insane.
uint64_t getOffsetInBits() const { return getUInt64Field(7); }
unsigned getFlags() const { return getUnsignedField(8); }
bool isPrivate() const {
return (getFlags() & FlagPrivate) != 0;
}
bool isProtected() const {
return (getFlags() & FlagProtected) != 0;
}
bool isForwardDecl() const {
return (getFlags() & FlagFwdDecl) != 0;
}
// isAppleBlock - Return true if this is the Apple Blocks extension.
bool isAppleBlockExtension() const {
return (getFlags() & FlagAppleBlock) != 0;
}
bool isBlockByrefStruct() const {
return (getFlags() & FlagBlockByrefStruct) != 0;
}
/// dump - print type.
void dump() const;
};
/// DIBasicType - A basic type, like 'int' or 'float'.
class DIBasicType : public DIType {
public:
explicit DIBasicType(MDNode *N = 0)
: DIType(N, dwarf::DW_TAG_base_type) {}
unsigned getEncoding() const { return getUnsignedField(9); }
/// dump - print basic type.
void dump() const;
};
/// DIDerivedType - A simple derived type, like a const qualified type,
/// a typedef, a pointer or reference, etc.
class DIDerivedType : public DIType {
protected:
explicit DIDerivedType(MDNode *N, bool, bool)
: DIType(N, true, true) {}
public:
explicit DIDerivedType(MDNode *N = 0)
: DIType(N, true, true) {
if (DbgNode && !isDerivedType())
DbgNode = 0;
}
DIType getTypeDerivedFrom() const { return getFieldAs<DIType>(9); }
/// getOriginalTypeSize - If this type is derived from a base type then
/// return base type size.
uint64_t getOriginalTypeSize() const;
/// dump - print derived type.
void dump() const;
/// replaceAllUsesWith - Replace all uses of debug info referenced by
/// this descriptor. After this completes, the current debug info value
/// is erased.
void replaceAllUsesWith(DIDescriptor &D);
};
/// DICompositeType - This descriptor holds a type that can refer to multiple
/// other types, like a function or struct.
/// FIXME: Why is this a DIDerivedType??
class DICompositeType : public DIDerivedType {
public:
explicit DICompositeType(MDNode *N = 0)
: DIDerivedType(N, true, true) {
if (N && !isCompositeType())
DbgNode = 0;
}
DIArray getTypeArray() const { return getFieldAs<DIArray>(10); }
unsigned getRunTimeLang() const { return getUnsignedField(11); }
/// Verify - Verify that a composite type descriptor is well formed.
bool Verify() const;
/// dump - print composite type.
void dump() const;
};
/// DIGlobal - This is a common class for global variables and subprograms.
class DIGlobal : public DIDescriptor {
protected:
explicit DIGlobal(MDNode *N, unsigned RequiredTag)
: DIDescriptor(N, RequiredTag) {}
public:
virtual ~DIGlobal() {}
DIDescriptor getContext() const { return getDescriptorField(2); }
const char *getName() const { return getStringField(3); }
const char *getDisplayName() const { return getStringField(4); }
const char *getLinkageName() const { return getStringField(5); }
DICompileUnit getCompileUnit() const{ return getFieldAs<DICompileUnit>(6); }
unsigned getLineNumber() const { return getUnsignedField(7); }
DIType getType() const { return getFieldAs<DIType>(8); }
/// isLocalToUnit - Return true if this subprogram is local to the current
/// compile unit, like 'static' in C.
unsigned isLocalToUnit() const { return getUnsignedField(9); }
unsigned isDefinition() const { return getUnsignedField(10); }
/// dump - print global.
void dump() const;
};
/// DISubprogram - This is a wrapper for a subprogram (e.g. a function).
class DISubprogram : public DIScope {
public:
explicit DISubprogram(MDNode *N = 0) : DIScope(N) {
if (DbgNode && !isSubprogram())
DbgNode = 0;
}
DIDescriptor getContext() const { return getDescriptorField(2); }
const char *getName() const { return getStringField(3); }
const char *getDisplayName() const { return getStringField(4); }
const char *getLinkageName() const { return getStringField(5); }
DICompileUnit getCompileUnit() const{ return getFieldAs<DICompileUnit>(6); }
unsigned getLineNumber() const { return getUnsignedField(7); }
DICompositeType getType() const { return getFieldAs<DICompositeType>(8); }
/// getReturnTypeName - Subprogram return types are encoded either as
/// DIType or as DICompositeType.
const char *getReturnTypeName() const {
DICompositeType DCT(getFieldAs<DICompositeType>(8));
if (!DCT.isNull()) {
DIArray A = DCT.getTypeArray();
DIType T(A.getElement(0).getNode());
return T.getName();
}
DIType T(getFieldAs<DIType>(8));
return T.getName();
}
/// isLocalToUnit - Return true if this subprogram is local to the current
/// compile unit, like 'static' in C.
unsigned isLocalToUnit() const { return getUnsignedField(9); }
unsigned isDefinition() const { return getUnsignedField(10); }
const char *getFilename() const { return getCompileUnit().getFilename();}
const char *getDirectory() const { return getCompileUnit().getDirectory();}
/// Verify - Verify that a subprogram descriptor is well formed.
bool Verify() const;
/// dump - print subprogram.
void dump() const;
/// describes - Return true if this subprogram provides debugging
/// information for the function F.
bool describes(const Function *F);
};
/// DIGlobalVariable - This is a wrapper for a global variable.
class DIGlobalVariable : public DIGlobal {
public:
explicit DIGlobalVariable(MDNode *N = 0)
: DIGlobal(N, dwarf::DW_TAG_variable) {}
GlobalVariable *getGlobal() const { return getGlobalVariableField(11); }
/// Verify - Verify that a global variable descriptor is well formed.
bool Verify() const;
/// dump - print global variable.
void dump() const;
};
/// DIVariable - This is a wrapper for a variable (e.g. parameter, local,
/// global etc).
class DIVariable : public DIDescriptor {
public:
explicit DIVariable(MDNode *N = 0)
: DIDescriptor(N) {
if (DbgNode && !isVariable())
DbgNode = 0;
}
DIDescriptor getContext() const { return getDescriptorField(1); }
const char *getName() const { return getStringField(2); }
DICompileUnit getCompileUnit() const{ return getFieldAs<DICompileUnit>(3); }
unsigned getLineNumber() const { return getUnsignedField(4); }
DIType getType() const { return getFieldAs<DIType>(5); }
/// Verify - Verify that a variable descriptor is well formed.
bool Verify() const;
/// HasComplexAddr - Return true if the variable has a complex address.
bool hasComplexAddress() const {
return getNumAddrElements() > 0;
}
unsigned getNumAddrElements() const { return DbgNode->getNumElements()-6; }
uint64_t getAddrElement(unsigned Idx) const {
return getUInt64Field(Idx+6);
}
/// isBlockByrefVariable - Return true if the variable was declared as
/// a "__block" variable (Apple Blocks).
bool isBlockByrefVariable() const {
return getType().isBlockByrefStruct();
}
/// dump - print variable.
void dump() const;
};
/// DILexicalBlock - This is a wrapper for a lexical block.
class DILexicalBlock : public DIScope {
public:
explicit DILexicalBlock(MDNode *N = 0) : DIScope(N) {
if (DbgNode && !isLexicalBlock())
DbgNode = 0;
}
DIScope getContext() const { return getFieldAs<DIScope>(1); }
const char *getDirectory() const { return getContext().getDirectory(); }
const char *getFilename() const { return getContext().getFilename(); }
};
/// DILocation - This object holds location information. This object
/// is not associated with any DWARF tag.
class DILocation : public DIDescriptor {
public:
explicit DILocation(MDNode *N) : DIDescriptor(N) { ; }
unsigned getLineNumber() const { return getUnsignedField(0); }
unsigned getColumnNumber() const { return getUnsignedField(1); }
DIScope getScope() const { return getFieldAs<DIScope>(2); }
DILocation getOrigLocation() const { return getFieldAs<DILocation>(3); }
const char *getFilename() const { return getScope().getFilename(); }
const char *getDirectory() const { return getScope().getDirectory(); }
};
/// DIFactory - This object assists with the construction of the various
/// descriptors.
class DIFactory {
Module &M;
LLVMContext& VMContext;
// Cached values for uniquing and faster lookups.
const Type *EmptyStructPtr; // "{}*".
Function *StopPointFn; // llvm.dbg.stoppoint
Function *FuncStartFn; // llvm.dbg.func.start
Function *RegionStartFn; // llvm.dbg.region.start
Function *RegionEndFn; // llvm.dbg.region.end
Function *DeclareFn; // llvm.dbg.declare
StringMap<Constant*> StringCache;
DenseMap<Constant*, DIDescriptor> SimpleConstantCache;
DIFactory(const DIFactory &); // DO NOT IMPLEMENT
void operator=(const DIFactory&); // DO NOT IMPLEMENT
public:
enum ComplexAddrKind { OpPlus=1, OpDeref };
explicit DIFactory(Module &m);
/// GetOrCreateArray - Create an descriptor for an array of descriptors.
/// This implicitly uniques the arrays created.
DIArray GetOrCreateArray(DIDescriptor *Tys, unsigned NumTys);
/// GetOrCreateSubrange - Create a descriptor for a value range. This
/// implicitly uniques the values returned.
DISubrange GetOrCreateSubrange(int64_t Lo, int64_t Hi);
/// CreateCompileUnit - Create a new descriptor for the specified compile
/// unit.
DICompileUnit CreateCompileUnit(unsigned LangID,
StringRef Filenae,
StringRef Directory,
StringRef Producer,
bool isMain = false,
bool isOptimized = false,
const char *Flags = "",
unsigned RunTimeVer = 0);
/// CreateEnumerator - Create a single enumerator value.
DIEnumerator CreateEnumerator(StringRef Name, uint64_t Val);
/// CreateBasicType - Create a basic type like int, float, etc.
DIBasicType CreateBasicType(DIDescriptor Context, StringRef Name,
DICompileUnit CompileUnit, unsigned LineNumber,
uint64_t SizeInBits, uint64_t AlignInBits,
uint64_t OffsetInBits, unsigned Flags,
unsigned Encoding);
/// CreateDerivedType - Create a derived type like const qualified type,
/// pointer, typedef, etc.
DIDerivedType CreateDerivedType(unsigned Tag, DIDescriptor Context,
StringRef Name,
DICompileUnit CompileUnit,
unsigned LineNumber,
uint64_t SizeInBits, uint64_t AlignInBits,
uint64_t OffsetInBits, unsigned Flags,
DIType DerivedFrom);
/// CreateCompositeType - Create a composite type like array, struct, etc.
DICompositeType CreateCompositeType(unsigned Tag, DIDescriptor Context,
StringRef Name,
DICompileUnit CompileUnit,
unsigned LineNumber,
uint64_t SizeInBits,
uint64_t AlignInBits,
uint64_t OffsetInBits, unsigned Flags,
DIType DerivedFrom,
DIArray Elements,
unsigned RunTimeLang = 0);
/// CreateSubprogram - Create a new descriptor for the specified subprogram.
/// See comments in DISubprogram for descriptions of these fields.
DISubprogram CreateSubprogram(DIDescriptor Context, StringRef Name,
StringRef DisplayName,
StringRef LinkageName,
DICompileUnit CompileUnit, unsigned LineNo,
DIType Type, bool isLocalToUnit,
bool isDefinition);
/// CreateGlobalVariable - Create a new descriptor for the specified global.
DIGlobalVariable
CreateGlobalVariable(DIDescriptor Context, StringRef Name,
StringRef DisplayName,
StringRef LinkageName,
DICompileUnit CompileUnit,
unsigned LineNo, DIType Type, bool isLocalToUnit,
bool isDefinition, llvm::GlobalVariable *GV);
/// CreateVariable - Create a new descriptor for the specified variable.
DIVariable CreateVariable(unsigned Tag, DIDescriptor Context,
StringRef Name,
DICompileUnit CompileUnit, unsigned LineNo,
DIType Type);
/// CreateComplexVariable - Create a new descriptor for the specified
/// variable which has a complex address expression for its address.
DIVariable CreateComplexVariable(unsigned Tag, DIDescriptor Context,
const std::string &Name,
DICompileUnit CompileUnit, unsigned LineNo,
DIType Type,
SmallVector<Value *, 9> &addr);
/// CreateLexicalBlock - This creates a descriptor for a lexical block
/// with the specified parent context.
DILexicalBlock CreateLexicalBlock(DIDescriptor Context);
/// CreateLocation - Creates a debug info location.
DILocation CreateLocation(unsigned LineNo, unsigned ColumnNo,
DIScope S, DILocation OrigLoc);
/// InsertStopPoint - Create a new llvm.dbg.stoppoint intrinsic invocation,
/// inserting it at the end of the specified basic block.
void InsertStopPoint(DICompileUnit CU, unsigned LineNo, unsigned ColNo,
BasicBlock *BB);
/// InsertSubprogramStart - Create a new llvm.dbg.func.start intrinsic to
/// mark the start of the specified subprogram.
void InsertSubprogramStart(DISubprogram SP, BasicBlock *BB);
/// InsertRegionStart - Insert a new llvm.dbg.region.start intrinsic call to
/// mark the start of a region for the specified scoping descriptor.
void InsertRegionStart(DIDescriptor D, BasicBlock *BB);
/// InsertRegionEnd - Insert a new llvm.dbg.region.end intrinsic call to
/// mark the end of a region for the specified scoping descriptor.
void InsertRegionEnd(DIDescriptor D, BasicBlock *BB);
/// InsertDeclare - Insert a new llvm.dbg.declare intrinsic call.
void InsertDeclare(llvm::Value *Storage, DIVariable D,
BasicBlock *InsertAtEnd);
/// InsertDeclare - Insert a new llvm.dbg.declare intrinsic call.
void InsertDeclare(llvm::Value *Storage, DIVariable D,
Instruction *InsertBefore);
private:
Constant *GetTagConstant(unsigned TAG);
};
/// Finds the stoppoint coressponding to this instruction, that is the
/// stoppoint that dominates this instruction
const DbgStopPointInst *findStopPoint(const Instruction *Inst);
/// Finds the stoppoint corresponding to first real (non-debug intrinsic)
/// instruction in this Basic Block, and returns the stoppoint for it.
const DbgStopPointInst *findBBStopPoint(const BasicBlock *BB);
/// Finds the dbg.declare intrinsic corresponding to this value if any.
/// It looks through pointer casts too.
const DbgDeclareInst *findDbgDeclare(const Value *V, bool stripCasts = true);
/// Find the debug info descriptor corresponding to this global variable.
Value *findDbgGlobalDeclare(GlobalVariable *V);
bool getLocationInfo(const Value *V, std::string &DisplayName,
std::string &Type, unsigned &LineNo, std::string &File,
std::string &Dir);
/// isValidDebugInfoIntrinsic - Return true if SPI is a valid debug
/// info intrinsic.
bool isValidDebugInfoIntrinsic(DbgStopPointInst &SPI,
CodeGenOpt::Level OptLev);
/// isValidDebugInfoIntrinsic - Return true if FSI is a valid debug
/// info intrinsic.
bool isValidDebugInfoIntrinsic(DbgFuncStartInst &FSI,
CodeGenOpt::Level OptLev);
/// isValidDebugInfoIntrinsic - Return true if RSI is a valid debug
/// info intrinsic.
bool isValidDebugInfoIntrinsic(DbgRegionStartInst &RSI,
CodeGenOpt::Level OptLev);
/// isValidDebugInfoIntrinsic - Return true if REI is a valid debug
/// info intrinsic.
bool isValidDebugInfoIntrinsic(DbgRegionEndInst &REI,
CodeGenOpt::Level OptLev);
/// isValidDebugInfoIntrinsic - Return true if DI is a valid debug
/// info intrinsic.
bool isValidDebugInfoIntrinsic(DbgDeclareInst &DI,
CodeGenOpt::Level OptLev);
/// ExtractDebugLocation - Extract debug location information
/// from llvm.dbg.stoppoint intrinsic.
DebugLoc ExtractDebugLocation(DbgStopPointInst &SPI,
DebugLocTracker &DebugLocInfo);
/// ExtractDebugLocation - Extract debug location information
/// from DILocation.
DebugLoc ExtractDebugLocation(DILocation &Loc,
DebugLocTracker &DebugLocInfo);
/// ExtractDebugLocation - Extract debug location information
/// from llvm.dbg.func_start intrinsic.
DebugLoc ExtractDebugLocation(DbgFuncStartInst &FSI,
DebugLocTracker &DebugLocInfo);
/// isInlinedFnStart - Return true if FSI is starting an inlined function.
bool isInlinedFnStart(DbgFuncStartInst &FSI, const Function *CurrentFn);
/// isInlinedFnEnd - Return true if REI is ending an inlined function.
bool isInlinedFnEnd(DbgRegionEndInst &REI, const Function *CurrentFn);
/// DebugInfoFinder - This object collects DebugInfo from a module.
class DebugInfoFinder {
public:
/// processModule - Process entire module and collect debug info
/// anchors.
void processModule(Module &M);
private:
/// processType - Process DIType.
void processType(DIType DT);
/// processLexicalBlock - Process DILexicalBlock.
void processLexicalBlock(DILexicalBlock LB);
/// processSubprogram - Process DISubprogram.
void processSubprogram(DISubprogram SP);
/// processStopPoint - Process DbgStopPointInst.
void processStopPoint(DbgStopPointInst *SPI);
/// processFuncStart - Process DbgFuncStartInst.
void processFuncStart(DbgFuncStartInst *FSI);
/// processRegionStart - Process DbgRegionStart.
void processRegionStart(DbgRegionStartInst *DRS);
/// processRegionEnd - Process DbgRegionEnd.
void processRegionEnd(DbgRegionEndInst *DRE);
/// processDeclare - Process DbgDeclareInst.
void processDeclare(DbgDeclareInst *DDI);
/// addCompileUnit - Add compile unit into CUs.
bool addCompileUnit(DICompileUnit CU);
/// addGlobalVariable - Add global variable into GVs.
bool addGlobalVariable(DIGlobalVariable DIG);
// addSubprogram - Add subprgoram into SPs.
bool addSubprogram(DISubprogram SP);
/// addType - Add type into Tys.
bool addType(DIType DT);
public:
typedef SmallVector<MDNode *, 8>::iterator iterator;
iterator compile_unit_begin() { return CUs.begin(); }
iterator compile_unit_end() { return CUs.end(); }
iterator subprogram_begin() { return SPs.begin(); }
iterator subprogram_end() { return SPs.end(); }
iterator global_variable_begin() { return GVs.begin(); }
iterator global_variable_end() { return GVs.end(); }
iterator type_begin() { return TYs.begin(); }
iterator type_end() { return TYs.end(); }
unsigned compile_unit_count() { return CUs.size(); }
unsigned global_variable_count() { return GVs.size(); }
unsigned subprogram_count() { return SPs.size(); }
unsigned type_count() { return TYs.size(); }
private:
SmallVector<MDNode *, 8> CUs; // Compile Units
SmallVector<MDNode *, 8> SPs; // Subprograms
SmallVector<MDNode *, 8> GVs; // Global Variables;
SmallVector<MDNode *, 8> TYs; // Types
SmallPtrSet<MDNode *, 64> NodesSeen;
};
} // end namespace llvm
#endif