llvm-6502/include/llvm/IR/DebugInfo.h
Adrian Prantl e240cc0b4b Remove support for DIVariable's FlagIndirectVariable and expect
frontends to use a DIExpression with a DW_OP_deref instead.

This is not only a much more natural place for this informationl; there
is also a technical reason: The FlagIndirectVariable is used to mark a
variable that is turned into a reference by virtue of the calling
convention; this happens for example to aggregate return values.
The inliner, for example, may actually need to undo this indirection to
correctly represent the value in its new context. This is impossible to
implement because the DIVariable can't be safely modified. We can however
safely construct a new DIExpression on the fly.

git-svn-id: https://llvm.org/svn/llvm-project/llvm/trunk@226476 91177308-0d34-0410-b5e6-96231b3b80d8
2015-01-19 17:57:29 +00:00

1105 lines
37 KiB
C++

//===- 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_IR_DEBUGINFO_H
#define LLVM_IR_DEBUGINFO_H
#include "llvm/ADT/DenseMap.h"
#include "llvm/ADT/SmallPtrSet.h"
#include "llvm/ADT/SmallVector.h"
#include "llvm/ADT/StringRef.h"
#include "llvm/ADT/iterator_range.h"
#include "llvm/IR/Metadata.h"
#include "llvm/Support/Casting.h"
#include "llvm/Support/Dwarf.h"
#include "llvm/Support/ErrorHandling.h"
#include <iterator>
namespace llvm {
class BasicBlock;
class Constant;
class Function;
class GlobalVariable;
class Module;
class Type;
class Value;
class DbgDeclareInst;
class DbgValueInst;
class Instruction;
class Metadata;
class MDNode;
class MDString;
class NamedMDNode;
class LLVMContext;
class raw_ostream;
class DIFile;
class DISubprogram;
class DILexicalBlock;
class DILexicalBlockFile;
class DIVariable;
class DIType;
class DIScope;
class DIObjCProperty;
/// \brief Maps from type identifier to the actual MDNode.
typedef DenseMap<const MDString *, MDNode *> DITypeIdentifierMap;
class DIHeaderFieldIterator
: public std::iterator<std::input_iterator_tag, StringRef, std::ptrdiff_t,
const StringRef *, StringRef> {
StringRef Header;
StringRef Current;
public:
DIHeaderFieldIterator() {}
DIHeaderFieldIterator(StringRef Header)
: Header(Header), Current(Header.slice(0, Header.find('\0'))) {}
StringRef operator*() const { return Current; }
const StringRef * operator->() const { return &Current; }
DIHeaderFieldIterator &operator++() {
increment();
return *this;
}
DIHeaderFieldIterator operator++(int) {
DIHeaderFieldIterator X(*this);
increment();
return X;
}
bool operator==(const DIHeaderFieldIterator &X) const {
return Current.data() == X.Current.data();
}
bool operator!=(const DIHeaderFieldIterator &X) const {
return !(*this == X);
}
StringRef getHeader() const { return Header; }
StringRef getCurrent() const { return Current; }
StringRef getPrefix() const {
if (Current.begin() == Header.begin())
return StringRef();
return Header.slice(0, Current.begin() - Header.begin() - 1);
}
StringRef getSuffix() const {
if (Current.end() == Header.end())
return StringRef();
return Header.slice(Current.end() - Header.begin() + 1, StringRef::npos);
}
private:
void increment() {
assert(Current.data() != nullptr && "Cannot increment past the end");
StringRef Suffix = getSuffix();
Current = Suffix.slice(0, Suffix.find('\0'));
}
};
/// \brief A thin wraper around MDNode to access encoded debug info.
///
/// This should not be stored in a container, because the underlying MDNode may
/// change in certain situations.
class DIDescriptor {
// Befriends DIRef so DIRef can befriend the protected member
// function: getFieldAs<DIRef>.
template <typename T> friend class DIRef;
public:
/// \brief Accessibility flags.
///
/// The three accessibility flags are mutually exclusive and rolled together
/// in the first two bits.
enum {
FlagAccessibility = 1 << 0 | 1 << 1,
FlagPrivate = 1,
FlagProtected = 2,
FlagPublic = 3,
FlagFwdDecl = 1 << 2,
FlagAppleBlock = 1 << 3,
FlagBlockByrefStruct = 1 << 4,
FlagVirtual = 1 << 5,
FlagArtificial = 1 << 6,
FlagExplicit = 1 << 7,
FlagPrototyped = 1 << 8,
FlagObjcClassComplete = 1 << 9,
FlagObjectPointer = 1 << 10,
FlagVector = 1 << 11,
FlagStaticMember = 1 << 12,
FlagLValueReference = 1 << 13,
FlagRValueReference = 1 << 14
};
protected:
const MDNode *DbgNode;
StringRef getStringField(unsigned Elt) const;
unsigned getUnsignedField(unsigned Elt) const {
return (unsigned)getUInt64Field(Elt);
}
uint64_t getUInt64Field(unsigned Elt) const;
int64_t getInt64Field(unsigned Elt) const;
DIDescriptor getDescriptorField(unsigned Elt) const;
template <typename DescTy> DescTy getFieldAs(unsigned Elt) const {
return DescTy(getDescriptorField(Elt));
}
GlobalVariable *getGlobalVariableField(unsigned Elt) const;
Constant *getConstantField(unsigned Elt) const;
Function *getFunctionField(unsigned Elt) const;
void replaceFunctionField(unsigned Elt, Function *F);
public:
explicit DIDescriptor(const MDNode *N = nullptr) : DbgNode(N) {}
bool Verify() const;
MDNode *get() const { return const_cast<MDNode *>(DbgNode); }
operator MDNode *() const { return get(); }
MDNode *operator->() const { return get(); }
// An explicit operator bool so that we can do testing of DI values
// easily.
// FIXME: This operator bool isn't actually protecting anything at the
// moment due to the conversion operator above making DIDescriptor nodes
// implicitly convertable to bool.
LLVM_EXPLICIT operator bool() const { return DbgNode != nullptr; }
bool operator==(DIDescriptor Other) const { return DbgNode == Other.DbgNode; }
bool operator!=(DIDescriptor Other) const { return !operator==(Other); }
StringRef getHeader() const {
return getStringField(0);
}
size_t getNumHeaderFields() const {
return std::distance(DIHeaderFieldIterator(getHeader()),
DIHeaderFieldIterator());
}
StringRef getHeaderField(unsigned Index) const {
// Since callers expect an empty string for out-of-range accesses, we can't
// use std::advance() here.
for (DIHeaderFieldIterator I(getHeader()), E; I != E; ++I, --Index)
if (!Index)
return *I;
return StringRef();
}
template <class T> T getHeaderFieldAs(unsigned Index) const {
T Int;
if (getHeaderField(Index).getAsInteger(0, Int))
return 0;
return Int;
}
uint16_t getTag() const { return getHeaderFieldAs<uint16_t>(0); }
bool isDerivedType() const;
bool isCompositeType() const;
bool isSubroutineType() const;
bool isBasicType() const;
bool isVariable() const;
bool isSubprogram() const;
bool isGlobalVariable() const;
bool isScope() const;
bool isFile() const;
bool isCompileUnit() const;
bool isNameSpace() const;
bool isLexicalBlockFile() const;
bool isLexicalBlock() const;
bool isSubrange() const;
bool isEnumerator() const;
bool isType() const;
bool isTemplateTypeParameter() const;
bool isTemplateValueParameter() const;
bool isObjCProperty() const;
bool isImportedEntity() const;
bool isExpression() const;
void print(raw_ostream &OS) const;
void dump() const;
/// \brief Replace all uses of debug info referenced by this descriptor.
void replaceAllUsesWith(LLVMContext &VMContext, DIDescriptor D);
void replaceAllUsesWith(MDNode *D);
};
/// \brief This is used to represent ranges, for array bounds.
class DISubrange : public DIDescriptor {
friend class DIDescriptor;
void printInternal(raw_ostream &OS) const;
public:
explicit DISubrange(const MDNode *N = nullptr) : DIDescriptor(N) {}
int64_t getLo() const { return getHeaderFieldAs<int64_t>(1); }
int64_t getCount() const { return getHeaderFieldAs<int64_t>(2); }
bool Verify() const;
};
/// \brief This descriptor holds an array of nodes with type T.
template <typename T> class DITypedArray : public DIDescriptor {
public:
explicit DITypedArray(const MDNode *N = nullptr) : DIDescriptor(N) {}
unsigned getNumElements() const {
return DbgNode ? DbgNode->getNumOperands() : 0;
}
T getElement(unsigned Idx) const {
return getFieldAs<T>(Idx);
}
};
typedef DITypedArray<DIDescriptor> DIArray;
/// \brief 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 {
friend class DIDescriptor;
void printInternal(raw_ostream &OS) const;
public:
explicit DIEnumerator(const MDNode *N = nullptr) : DIDescriptor(N) {}
StringRef getName() const { return getHeaderField(1); }
int64_t getEnumValue() const { return getHeaderFieldAs<int64_t>(2); }
bool Verify() const;
};
template <typename T> class DIRef;
typedef DIRef<DIScope> DIScopeRef;
typedef DIRef<DIType> DITypeRef;
typedef DITypedArray<DITypeRef> DITypeArray;
/// \brief A base class for various scopes.
///
/// Although, implementation-wise, DIScope is the parent class of most
/// other DIxxx classes, including DIType and its descendants, most of
/// DIScope's descendants are not a substitutable subtype of
/// DIScope. The DIDescriptor::isScope() method only is true for
/// DIScopes that are scopes in the strict lexical scope sense
/// (DICompileUnit, DISubprogram, etc.), but not for, e.g., a DIType.
class DIScope : public DIDescriptor {
protected:
friend class DIDescriptor;
void printInternal(raw_ostream &OS) const;
public:
explicit DIScope(const MDNode *N = nullptr) : DIDescriptor(N) {}
/// \brief Get the parent scope.
///
/// Gets the parent scope for this scope node or returns a default
/// constructed scope.
DIScopeRef getContext() const;
/// \brief Get the scope name.
///
/// If the scope node has a name, return that, else return an empty string.
StringRef getName() const;
StringRef getFilename() const;
StringRef getDirectory() const;
/// \brief Generate a reference to this DIScope.
///
/// Uses the type identifier instead of the actual MDNode if possible, to
/// help type uniquing.
DIScopeRef getRef() const;
};
/// \brief Represents reference to a DIDescriptor.
///
/// Abstracts over direct and identifier-based metadata references.
template <typename T> class DIRef {
template <typename DescTy>
friend DescTy DIDescriptor::getFieldAs(unsigned Elt) const;
friend DIScopeRef DIScope::getContext() const;
friend DIScopeRef DIScope::getRef() const;
friend class DIType;
/// \brief Val can be either a MDNode or a MDString.
///
/// In the latter, MDString specifies the type identifier.
const Metadata *Val;
explicit DIRef(const Metadata *V);
public:
T resolve(const DITypeIdentifierMap &Map) const;
StringRef getName() const;
operator Metadata *() const { return const_cast<Metadata *>(Val); }
};
template <typename T>
T DIRef<T>::resolve(const DITypeIdentifierMap &Map) const {
if (!Val)
return T();
if (const MDNode *MD = dyn_cast<MDNode>(Val))
return T(MD);
const MDString *MS = cast<MDString>(Val);
// Find the corresponding MDNode.
DITypeIdentifierMap::const_iterator Iter = Map.find(MS);
assert(Iter != Map.end() && "Identifier not in the type map?");
assert(DIDescriptor(Iter->second).isType() &&
"MDNode in DITypeIdentifierMap should be a DIType.");
return T(Iter->second);
}
template <typename T> StringRef DIRef<T>::getName() const {
if (!Val)
return StringRef();
if (const MDNode *MD = dyn_cast<MDNode>(Val))
return T(MD).getName();
const MDString *MS = cast<MDString>(Val);
return MS->getString();
}
/// \brief Handle fields that are references to DIScopes.
template <> DIScopeRef DIDescriptor::getFieldAs<DIScopeRef>(unsigned Elt) const;
/// \brief Specialize DIRef constructor for DIScopeRef.
template <> DIRef<DIScope>::DIRef(const Metadata *V);
/// \brief Handle fields that are references to DITypes.
template <> DITypeRef DIDescriptor::getFieldAs<DITypeRef>(unsigned Elt) const;
/// \brief Specialize DIRef constructor for DITypeRef.
template <> DIRef<DIType>::DIRef(const Metadata *V);
/// \briefThis 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 DIScope {
protected:
friend class DIDescriptor;
void printInternal(raw_ostream &OS) const;
public:
explicit DIType(const MDNode *N = nullptr) : DIScope(N) {}
operator DITypeRef () const {
assert(isType() &&
"constructing DITypeRef from an MDNode that is not a type");
return DITypeRef(&*getRef());
}
bool Verify() const;
DIScopeRef getContext() const { return getFieldAs<DIScopeRef>(2); }
StringRef getName() const { return getHeaderField(1); }
unsigned getLineNumber() const {
return getHeaderFieldAs<unsigned>(2);
}
uint64_t getSizeInBits() const {
return getHeaderFieldAs<unsigned>(3);
}
uint64_t getAlignInBits() const {
return getHeaderFieldAs<unsigned>(4);
}
// FIXME: Offset is only used for DW_TAG_member nodes. Making every type
// carry this is just plain insane.
uint64_t getOffsetInBits() const {
return getHeaderFieldAs<unsigned>(5);
}
unsigned getFlags() const { return getHeaderFieldAs<unsigned>(6); }
bool isPrivate() const {
return (getFlags() & FlagAccessibility) == FlagPrivate;
}
bool isProtected() const {
return (getFlags() & FlagAccessibility) == FlagProtected;
}
bool isPublic() const {
return (getFlags() & FlagAccessibility) == FlagPublic;
}
bool isForwardDecl() const { return (getFlags() & FlagFwdDecl) != 0; }
bool isAppleBlockExtension() const {
return (getFlags() & FlagAppleBlock) != 0;
}
bool isBlockByrefStruct() const {
return (getFlags() & FlagBlockByrefStruct) != 0;
}
bool isVirtual() const { return (getFlags() & FlagVirtual) != 0; }
bool isArtificial() const { return (getFlags() & FlagArtificial) != 0; }
bool isObjectPointer() const { return (getFlags() & FlagObjectPointer) != 0; }
bool isObjcClassComplete() const {
return (getFlags() & FlagObjcClassComplete) != 0;
}
bool isVector() const { return (getFlags() & FlagVector) != 0; }
bool isStaticMember() const { return (getFlags() & FlagStaticMember) != 0; }
bool isLValueReference() const {
return (getFlags() & FlagLValueReference) != 0;
}
bool isRValueReference() const {
return (getFlags() & FlagRValueReference) != 0;
}
bool isValid() const { return DbgNode && isType(); }
};
/// \brief A basic type, like 'int' or 'float'.
class DIBasicType : public DIType {
public:
explicit DIBasicType(const MDNode *N = nullptr) : DIType(N) {}
unsigned getEncoding() const { return getHeaderFieldAs<unsigned>(7); }
bool Verify() const;
};
/// \brief A simple derived type
///
/// Like a const qualified type, a typedef, a pointer or reference, et cetera.
/// Or, a data member of a class/struct/union.
class DIDerivedType : public DIType {
friend class DIDescriptor;
void printInternal(raw_ostream &OS) const;
public:
explicit DIDerivedType(const MDNode *N = nullptr) : DIType(N) {}
DITypeRef getTypeDerivedFrom() const { return getFieldAs<DITypeRef>(3); }
/// \brief Return property node, if this ivar is associated with one.
MDNode *getObjCProperty() const;
DITypeRef getClassType() const {
assert(getTag() == dwarf::DW_TAG_ptr_to_member_type);
return getFieldAs<DITypeRef>(4);
}
Constant *getConstant() const {
assert((getTag() == dwarf::DW_TAG_member) && isStaticMember());
return getConstantField(4);
}
bool Verify() const;
};
/// \brief Types that refer to multiple other types.
///
/// This descriptor holds a type that can refer to multiple other types, like a
/// function or struct.
///
/// DICompositeType is derived from DIDerivedType because some
/// composite types (such as enums) can be derived from basic types
// FIXME: Make this derive from DIType directly & just store the
// base type in a single DIType field.
class DICompositeType : public DIDerivedType {
friend class DIBuilder;
friend class DIDescriptor;
void printInternal(raw_ostream &OS) const;
/// \brief Set the array of member DITypes.
void setArraysHelper(MDNode *Elements, MDNode *TParams);
public:
explicit DICompositeType(const MDNode *N = nullptr) : DIDerivedType(N) {}
DIArray getElements() const {
assert(!isSubroutineType() && "no elements for DISubroutineType");
return getFieldAs<DIArray>(4);
}
private:
template <typename T>
void setArrays(DITypedArray<T> Elements, DIArray TParams = DIArray()) {
assert((!TParams || DbgNode->getNumOperands() == 8) &&
"If you're setting the template parameters this should include a slot "
"for that!");
setArraysHelper(Elements, TParams);
}
public:
unsigned getRunTimeLang() const {
return getHeaderFieldAs<unsigned>(7);
}
DITypeRef getContainingType() const { return getFieldAs<DITypeRef>(5); }
private:
/// \brief Set the containing type.
void setContainingType(DICompositeType ContainingType);
public:
DIArray getTemplateParams() const { return getFieldAs<DIArray>(6); }
MDString *getIdentifier() const;
bool Verify() const;
};
class DISubroutineType : public DICompositeType {
public:
explicit DISubroutineType(const MDNode *N = nullptr) : DICompositeType(N) {}
DITypedArray<DITypeRef> getTypeArray() const {
return getFieldAs<DITypedArray<DITypeRef>>(4);
}
};
/// \brief This is a wrapper for a file.
class DIFile : public DIScope {
friend class DIDescriptor;
public:
explicit DIFile(const MDNode *N = nullptr) : DIScope(N) {}
/// \brief Retrieve the MDNode for the directory/file pair.
MDNode *getFileNode() const;
bool Verify() const;
};
/// \brief A wrapper for a compile unit.
class DICompileUnit : public DIScope {
friend class DIDescriptor;
void printInternal(raw_ostream &OS) const;
public:
explicit DICompileUnit(const MDNode *N = nullptr) : DIScope(N) {}
dwarf::SourceLanguage getLanguage() const {
return static_cast<dwarf::SourceLanguage>(getHeaderFieldAs<unsigned>(1));
}
StringRef getProducer() const { return getHeaderField(2); }
bool isOptimized() const { return getHeaderFieldAs<bool>(3) != 0; }
StringRef getFlags() const { return getHeaderField(4); }
unsigned getRunTimeVersion() const { return getHeaderFieldAs<unsigned>(5); }
DIArray getEnumTypes() const;
DIArray getRetainedTypes() const;
DIArray getSubprograms() const;
DIArray getGlobalVariables() const;
DIArray getImportedEntities() const;
void replaceSubprograms(DIArray Subprograms);
void replaceGlobalVariables(DIArray GlobalVariables);
StringRef getSplitDebugFilename() const { return getHeaderField(6); }
unsigned getEmissionKind() const { return getHeaderFieldAs<unsigned>(7); }
bool Verify() const;
};
/// \brief This is a wrapper for a subprogram (e.g. a function).
class DISubprogram : public DIScope {
friend class DIDescriptor;
void printInternal(raw_ostream &OS) const;
public:
explicit DISubprogram(const MDNode *N = nullptr) : DIScope(N) {}
StringRef getName() const { return getHeaderField(1); }
StringRef getDisplayName() const { return getHeaderField(2); }
StringRef getLinkageName() const { return getHeaderField(3); }
unsigned getLineNumber() const { return getHeaderFieldAs<unsigned>(4); }
/// \brief Check if this is local (like 'static' in C).
unsigned isLocalToUnit() const { return getHeaderFieldAs<unsigned>(5); }
unsigned isDefinition() const { return getHeaderFieldAs<unsigned>(6); }
unsigned getVirtuality() const { return getHeaderFieldAs<unsigned>(7); }
unsigned getVirtualIndex() const { return getHeaderFieldAs<unsigned>(8); }
unsigned getFlags() const { return getHeaderFieldAs<unsigned>(9); }
unsigned isOptimized() const { return getHeaderFieldAs<bool>(10); }
/// \brief Get the beginning of the scope of the function (not the name).
unsigned getScopeLineNumber() const { return getHeaderFieldAs<unsigned>(11); }
DIScopeRef getContext() const { return getFieldAs<DIScopeRef>(2); }
DISubroutineType getType() const { return getFieldAs<DISubroutineType>(3); }
DITypeRef getContainingType() const { return getFieldAs<DITypeRef>(4); }
bool Verify() const;
/// \brief Check if this provides debugging information for the function F.
bool describes(const Function *F);
Function *getFunction() const { return getFunctionField(5); }
void replaceFunction(Function *F) { replaceFunctionField(5, F); }
DIArray getTemplateParams() const { return getFieldAs<DIArray>(6); }
DISubprogram getFunctionDeclaration() const {
return getFieldAs<DISubprogram>(7);
}
MDNode *getVariablesNodes() const;
DIArray getVariables() const;
unsigned isArtificial() const { return (getFlags() & FlagArtificial) != 0; }
/// \brief Check for the "private" access specifier.
bool isPrivate() const {
return (getFlags() & FlagAccessibility) == FlagPrivate;
}
/// \brief Check for the "protected" access specifier.
bool isProtected() const {
return (getFlags() & FlagAccessibility) == FlagProtected;
}
/// \brief Check for the "public" access specifier.
bool isPublic() const {
return (getFlags() & FlagAccessibility) == FlagPublic;
}
/// \brief Check for "explicit".
bool isExplicit() const { return (getFlags() & FlagExplicit) != 0; }
/// \brief Check if this is prototyped.
bool isPrototyped() const { return (getFlags() & FlagPrototyped) != 0; }
/// \brief Check if this is reference-qualified.
///
/// Return true if this subprogram is a C++11 reference-qualified non-static
/// member function (void foo() &).
unsigned isLValueReference() const {
return (getFlags() & FlagLValueReference) != 0;
}
/// \brief Check if this is rvalue-reference-qualified.
///
/// Return true if this subprogram is a C++11 rvalue-reference-qualified
/// non-static member function (void foo() &&).
unsigned isRValueReference() const {
return (getFlags() & FlagRValueReference) != 0;
}
};
/// \brief This is a wrapper for a lexical block.
class DILexicalBlock : public DIScope {
public:
explicit DILexicalBlock(const MDNode *N = nullptr) : DIScope(N) {}
DIScope getContext() const { return getFieldAs<DIScope>(2); }
unsigned getLineNumber() const {
return getHeaderFieldAs<unsigned>(1);
}
unsigned getColumnNumber() const {
return getHeaderFieldAs<unsigned>(2);
}
bool Verify() const;
};
/// \brief This is a wrapper for a lexical block with a filename change.
class DILexicalBlockFile : public DIScope {
public:
explicit DILexicalBlockFile(const MDNode *N = nullptr) : DIScope(N) {}
DIScope getContext() const {
if (getScope().isSubprogram())
return getScope();
return getScope().getContext();
}
unsigned getLineNumber() const { return getScope().getLineNumber(); }
unsigned getColumnNumber() const { return getScope().getColumnNumber(); }
DILexicalBlock getScope() const { return getFieldAs<DILexicalBlock>(2); }
unsigned getDiscriminator() const { return getHeaderFieldAs<unsigned>(1); }
bool Verify() const;
};
/// \brief A wrapper for a C++ style name space.
class DINameSpace : public DIScope {
friend class DIDescriptor;
void printInternal(raw_ostream &OS) const;
public:
explicit DINameSpace(const MDNode *N = nullptr) : DIScope(N) {}
StringRef getName() const { return getHeaderField(1); }
unsigned getLineNumber() const { return getHeaderFieldAs<unsigned>(2); }
DIScope getContext() const { return getFieldAs<DIScope>(2); }
bool Verify() const;
};
/// \brief This is a wrapper for template type parameter.
class DITemplateTypeParameter : public DIDescriptor {
public:
explicit DITemplateTypeParameter(const MDNode *N = nullptr)
: DIDescriptor(N) {}
StringRef getName() const { return getHeaderField(1); }
unsigned getLineNumber() const { return getHeaderFieldAs<unsigned>(2); }
unsigned getColumnNumber() const { return getHeaderFieldAs<unsigned>(3); }
DIScopeRef getContext() const { return getFieldAs<DIScopeRef>(1); }
DITypeRef getType() const { return getFieldAs<DITypeRef>(2); }
StringRef getFilename() const { return getFieldAs<DIFile>(3).getFilename(); }
StringRef getDirectory() const {
return getFieldAs<DIFile>(3).getDirectory();
}
bool Verify() const;
};
/// \brief This is a wrapper for template value parameter.
class DITemplateValueParameter : public DIDescriptor {
public:
explicit DITemplateValueParameter(const MDNode *N = nullptr)
: DIDescriptor(N) {}
StringRef getName() const { return getHeaderField(1); }
unsigned getLineNumber() const { return getHeaderFieldAs<unsigned>(2); }
unsigned getColumnNumber() const { return getHeaderFieldAs<unsigned>(3); }
DIScopeRef getContext() const { return getFieldAs<DIScopeRef>(1); }
DITypeRef getType() const { return getFieldAs<DITypeRef>(2); }
Metadata *getValue() const;
StringRef getFilename() const { return getFieldAs<DIFile>(4).getFilename(); }
StringRef getDirectory() const {
return getFieldAs<DIFile>(4).getDirectory();
}
bool Verify() const;
};
/// \brief This is a wrapper for a global variable.
class DIGlobalVariable : public DIDescriptor {
friend class DIDescriptor;
void printInternal(raw_ostream &OS) const;
public:
explicit DIGlobalVariable(const MDNode *N = nullptr) : DIDescriptor(N) {}
StringRef getName() const { return getHeaderField(1); }
StringRef getDisplayName() const { return getHeaderField(2); }
StringRef getLinkageName() const { return getHeaderField(3); }
unsigned getLineNumber() const { return getHeaderFieldAs<unsigned>(4); }
unsigned isLocalToUnit() const { return getHeaderFieldAs<bool>(5); }
unsigned isDefinition() const { return getHeaderFieldAs<bool>(6); }
DIScope getContext() const { return getFieldAs<DIScope>(1); }
StringRef getFilename() const { return getFieldAs<DIFile>(2).getFilename(); }
StringRef getDirectory() const {
return getFieldAs<DIFile>(2).getDirectory();
}
DITypeRef getType() const { return getFieldAs<DITypeRef>(3); }
GlobalVariable *getGlobal() const { return getGlobalVariableField(4); }
Constant *getConstant() const { return getConstantField(4); }
DIDerivedType getStaticDataMemberDeclaration() const {
return getFieldAs<DIDerivedType>(5);
}
bool Verify() const;
};
/// \brief This is a wrapper for a variable (e.g. parameter, local, global etc).
class DIVariable : public DIDescriptor {
friend class DIDescriptor;
void printInternal(raw_ostream &OS) const;
public:
explicit DIVariable(const MDNode *N = nullptr) : DIDescriptor(N) {}
StringRef getName() const { return getHeaderField(1); }
unsigned getLineNumber() const {
// FIXME: Line number and arg number shouldn't be merged together like this.
return (getHeaderFieldAs<unsigned>(2) << 8) >> 8;
}
unsigned getArgNumber() const { return getHeaderFieldAs<unsigned>(2) >> 24; }
DIScope getContext() const { return getFieldAs<DIScope>(1); }
DIFile getFile() const { return getFieldAs<DIFile>(2); }
DITypeRef getType() const { return getFieldAs<DITypeRef>(3); }
/// \brief Return true if this variable is marked as "artificial".
bool isArtificial() const {
return (getHeaderFieldAs<unsigned>(3) & FlagArtificial) != 0;
}
bool isObjectPointer() const {
return (getHeaderFieldAs<unsigned>(3) & FlagObjectPointer) != 0;
}
/// \brief If this variable is inlined then return inline location.
MDNode *getInlinedAt() const;
bool Verify() const;
/// \brief Check if this is a "__block" variable (Apple Blocks).
bool isBlockByrefVariable(const DITypeIdentifierMap &Map) const {
return (getType().resolve(Map)).isBlockByrefStruct();
}
/// \brief Check if this is an inlined function argument.
bool isInlinedFnArgument(const Function *CurFn);
/// \brief Return the size reported by the variable's type.
unsigned getSizeInBits(const DITypeIdentifierMap &Map);
void printExtendedName(raw_ostream &OS) const;
};
/// \brief A complex location expression.
class DIExpression : public DIDescriptor {
friend class DIDescriptor;
void printInternal(raw_ostream &OS) const;
public:
explicit DIExpression(const MDNode *N = nullptr) : DIDescriptor(N) {}
bool Verify() const;
/// \brief Return the number of elements in the complex expression.
unsigned getNumElements() const {
if (!DbgNode)
return 0;
unsigned N = getNumHeaderFields();
assert(N > 0 && "missing tag");
return N - 1;
}
/// \brief return the Idx'th complex address element.
uint64_t getElement(unsigned Idx) const;
/// \brief Return whether this is a piece of an aggregate variable.
bool isVariablePiece() const;
/// \brief Return the offset of this piece in bytes.
uint64_t getPieceOffset() const;
/// \brief Return the size of this piece in bytes.
uint64_t getPieceSize() const;
};
/// \brief This object holds location information.
///
/// This object is not associated with any DWARF tag.
class DILocation : public DIDescriptor {
public:
explicit DILocation(const MDNode *N) : DIDescriptor(N) {}
unsigned getLineNumber() const {
if (auto *L = dyn_cast_or_null<MDLocation>(DbgNode))
return L->getLine();
return 0;
}
unsigned getColumnNumber() const {
if (auto *L = dyn_cast_or_null<MDLocation>(DbgNode))
return L->getColumn();
return 0;
}
DIScope getScope() const {
if (auto *L = dyn_cast_or_null<MDLocation>(DbgNode))
return DIScope(dyn_cast_or_null<MDNode>(L->getScope()));
return DIScope(nullptr);
}
DILocation getOrigLocation() const {
if (auto *L = dyn_cast_or_null<MDLocation>(DbgNode))
return DILocation(dyn_cast_or_null<MDNode>(L->getInlinedAt()));
return DILocation(nullptr);
}
StringRef getFilename() const { return getScope().getFilename(); }
StringRef getDirectory() const { return getScope().getDirectory(); }
bool Verify() const;
bool atSameLineAs(const DILocation &Other) const {
return (getLineNumber() == Other.getLineNumber() &&
getFilename() == Other.getFilename());
}
/// \brief Get the DWAF discriminator.
///
/// DWARF discriminators are used to distinguish identical file locations for
/// instructions that are on different basic blocks. If two instructions are
/// inside the same lexical block and are in different basic blocks, we
/// create a new lexical block with identical location as the original but
/// with a different discriminator value
/// (lib/Transforms/Util/AddDiscriminators.cpp for details).
unsigned getDiscriminator() const {
// Since discriminators are associated with lexical blocks, make
// sure this location is a lexical block before retrieving its
// value.
return getScope().isLexicalBlockFile()
? DILexicalBlockFile(
cast<MDNode>(cast<MDLocation>(DbgNode)->getScope()))
.getDiscriminator()
: 0;
}
/// \brief Generate a new discriminator value for this location.
unsigned computeNewDiscriminator(LLVMContext &Ctx);
/// \brief Return a copy of this location with a different scope.
DILocation copyWithNewScope(LLVMContext &Ctx, DILexicalBlockFile NewScope);
};
class DIObjCProperty : public DIDescriptor {
friend class DIDescriptor;
void printInternal(raw_ostream &OS) const;
public:
explicit DIObjCProperty(const MDNode *N) : DIDescriptor(N) {}
StringRef getObjCPropertyName() const { return getHeaderField(1); }
DIFile getFile() const { return getFieldAs<DIFile>(1); }
unsigned getLineNumber() const { return getHeaderFieldAs<unsigned>(2); }
StringRef getObjCPropertyGetterName() const { return getHeaderField(3); }
StringRef getObjCPropertySetterName() const { return getHeaderField(4); }
unsigned getAttributes() const { return getHeaderFieldAs<unsigned>(5); }
bool isReadOnlyObjCProperty() const {
return (getAttributes() & dwarf::DW_APPLE_PROPERTY_readonly) != 0;
}
bool isReadWriteObjCProperty() const {
return (getAttributes() & dwarf::DW_APPLE_PROPERTY_readwrite) != 0;
}
bool isAssignObjCProperty() const {
return (getAttributes() & dwarf::DW_APPLE_PROPERTY_assign) != 0;
}
bool isRetainObjCProperty() const {
return (getAttributes() & dwarf::DW_APPLE_PROPERTY_retain) != 0;
}
bool isCopyObjCProperty() const {
return (getAttributes() & dwarf::DW_APPLE_PROPERTY_copy) != 0;
}
bool isNonAtomicObjCProperty() const {
return (getAttributes() & dwarf::DW_APPLE_PROPERTY_nonatomic) != 0;
}
/// \brief Get the type.
///
/// \note Objective-C doesn't have an ODR, so there is no benefit in storing
/// the type as a DITypeRef here.
DIType getType() const { return getFieldAs<DIType>(2); }
bool Verify() const;
};
/// \brief An imported module (C++ using directive or similar).
class DIImportedEntity : public DIDescriptor {
friend class DIDescriptor;
void printInternal(raw_ostream &OS) const;
public:
explicit DIImportedEntity(const MDNode *N) : DIDescriptor(N) {}
DIScope getContext() const { return getFieldAs<DIScope>(1); }
DIScopeRef getEntity() const { return getFieldAs<DIScopeRef>(2); }
unsigned getLineNumber() const { return getHeaderFieldAs<unsigned>(1); }
StringRef getName() const { return getHeaderField(2); }
bool Verify() const;
};
/// \brief Find subprogram that is enclosing this scope.
DISubprogram getDISubprogram(const MDNode *Scope);
/// \brief Find debug info for a given function.
/// \returns a valid DISubprogram, if found. Otherwise, it returns an empty
/// DISubprogram.
DISubprogram getDISubprogram(const Function *F);
/// \brief Find underlying composite type.
DICompositeType getDICompositeType(DIType T);
/// \brief Create a new inlined variable based on current variable.
///
/// @param DV Current Variable.
/// @param InlinedScope Location at current variable is inlined.
DIVariable createInlinedVariable(MDNode *DV, MDNode *InlinedScope,
LLVMContext &VMContext);
/// \brief Remove inlined scope from the variable.
DIVariable cleanseInlinedVariable(MDNode *DV, LLVMContext &VMContext);
/// \brief Generate map by visiting all retained types.
DITypeIdentifierMap generateDITypeIdentifierMap(const NamedMDNode *CU_Nodes);
/// \brief Strip debug info in the module if it exists.
///
/// To do this, we remove all calls to the debugger intrinsics and any named
/// metadata for debugging. We also remove debug locations for instructions.
/// Return true if module is modified.
bool StripDebugInfo(Module &M);
/// \brief Return Debug Info Metadata Version by checking module flags.
unsigned getDebugMetadataVersionFromModule(const Module &M);
/// \brief Utility to find all debug info in a module.
///
/// DebugInfoFinder tries to list all debug info MDNodes used in a module. To
/// list debug info MDNodes used by an instruction, DebugInfoFinder uses
/// processDeclare, processValue and processLocation to handle DbgDeclareInst,
/// DbgValueInst and DbgLoc attached to instructions. processModule will go
/// through all DICompileUnits in llvm.dbg.cu and list debug info MDNodes
/// used by the CUs.
class DebugInfoFinder {
public:
DebugInfoFinder() : TypeMapInitialized(false) {}
/// \brief Process entire module and collect debug info anchors.
void processModule(const Module &M);
/// \brief Process DbgDeclareInst.
void processDeclare(const Module &M, const DbgDeclareInst *DDI);
/// \brief Process DbgValueInst.
void processValue(const Module &M, const DbgValueInst *DVI);
/// \brief Process DILocation.
void processLocation(const Module &M, DILocation Loc);
/// \brief Clear all lists.
void reset();
private:
void InitializeTypeMap(const Module &M);
void processType(DIType DT);
void processSubprogram(DISubprogram SP);
void processScope(DIScope Scope);
bool addCompileUnit(DICompileUnit CU);
bool addGlobalVariable(DIGlobalVariable DIG);
bool addSubprogram(DISubprogram SP);
bool addType(DIType DT);
bool addScope(DIScope Scope);
public:
typedef SmallVectorImpl<DICompileUnit>::const_iterator compile_unit_iterator;
typedef SmallVectorImpl<DISubprogram>::const_iterator subprogram_iterator;
typedef SmallVectorImpl<DIGlobalVariable>::const_iterator global_variable_iterator;
typedef SmallVectorImpl<DIType>::const_iterator type_iterator;
typedef SmallVectorImpl<DIScope>::const_iterator scope_iterator;
iterator_range<compile_unit_iterator> compile_units() const {
return iterator_range<compile_unit_iterator>(CUs.begin(), CUs.end());
}
iterator_range<subprogram_iterator> subprograms() const {
return iterator_range<subprogram_iterator>(SPs.begin(), SPs.end());
}
iterator_range<global_variable_iterator> global_variables() const {
return iterator_range<global_variable_iterator>(GVs.begin(), GVs.end());
}
iterator_range<type_iterator> types() const {
return iterator_range<type_iterator>(TYs.begin(), TYs.end());
}
iterator_range<scope_iterator> scopes() const {
return iterator_range<scope_iterator>(Scopes.begin(), Scopes.end());
}
unsigned compile_unit_count() const { return CUs.size(); }
unsigned global_variable_count() const { return GVs.size(); }
unsigned subprogram_count() const { return SPs.size(); }
unsigned type_count() const { return TYs.size(); }
unsigned scope_count() const { return Scopes.size(); }
private:
SmallVector<DICompileUnit, 8> CUs;
SmallVector<DISubprogram, 8> SPs;
SmallVector<DIGlobalVariable, 8> GVs;
SmallVector<DIType, 8> TYs;
SmallVector<DIScope, 8> Scopes;
SmallPtrSet<MDNode *, 64> NodesSeen;
DITypeIdentifierMap TypeIdentifierMap;
/// \brief Specify if TypeIdentifierMap is initialized.
bool TypeMapInitialized;
};
DenseMap<const Function *, DISubprogram> makeSubprogramMap(const Module &M);
} // end namespace llvm
#endif