clang-r450784b/include/lldb/Symbol/CompilerType.h - platform/prebuilts/clang/host/windows-x86 - Git at Google

 //===-- CompilerType.h ------------------------------------------*- C++ -*-===//
 //
 // 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
 //
 //===----------------------------------------------------------------------===//

 #ifndef LLDB_SYMBOL_COMPILERTYPE_H
 #define LLDB_SYMBOL_COMPILERTYPE_H

 #include <functional>
 #include <string>
 #include <vector>

 #include "lldb/lldb-private.h"
 #include "llvm/ADT/APSInt.h"

 namespace lldb_private {

 class DataExtractor;

 /// Generic representation of a type in a programming language.
 ///
 /// This class serves as an abstraction for a type inside one of the TypeSystems
 /// implemented by the language plugins. It does not have any actual logic in it
 /// but only stores an opaque pointer and a pointer to the TypeSystem that
 /// gives meaning to this opaque pointer. All methods of this class should call
 /// their respective method in the TypeSystem interface and pass the opaque
 /// pointer along.
 ///
 /// \see lldb_private::TypeSystem
 class CompilerType {
 public:
   /// Creates a CompilerType with the given TypeSystem and opaque compiler type.
   ///
   /// This constructor should only be called from the respective TypeSystem
   /// implementation.
   ///
   /// \see lldb_private::TypeSystemClang::GetType(clang::QualType)
   CompilerType(TypeSystem *type_system, lldb::opaque_compiler_type_t type)
       : m_type(type), m_type_system(type_system) {
     assert(Verify() && "verification failed");
   }

   CompilerType(const CompilerType &rhs)
       : m_type(rhs.m_type), m_type_system(rhs.m_type_system) {}

   CompilerType() = default;

   /// Operators.
   /// \{
   const CompilerType &operator=(const CompilerType &rhs) {
     m_type = rhs.m_type;
     m_type_system = rhs.m_type_system;
     return *this;
   }

   bool operator<(const CompilerType &rhs) const {
     if (m_type_system == rhs.m_type_system)
       return m_type < rhs.m_type;
     return m_type_system < rhs.m_type_system;
   }
   /// \}

   /// Tests.
   /// \{
   explicit operator bool() const {
     return m_type != nullptr && m_type_system != nullptr;
   }

   bool IsValid() const { return m_type != nullptr && m_type_system != nullptr; }

   bool IsArrayType(CompilerType *element_type = nullptr,
                    uint64_t *size = nullptr,
                    bool *is_incomplete = nullptr) const;

   bool IsVectorType(CompilerType *element_type = nullptr,
                     uint64_t *size = nullptr) const;

   bool IsArrayOfScalarType() const;

   bool IsAggregateType() const;

   bool IsAnonymousType() const;

   bool IsScopedEnumerationType() const;

   bool IsBeingDefined() const;

   bool IsCharType() const;

   bool IsCompleteType() const;

   bool IsConst() const;

   bool IsCStringType(uint32_t &length) const;

   bool IsDefined() const;

   bool IsFloatingPointType(uint32_t &count, bool &is_complex) const;

   bool IsFunctionType() const;

   uint32_t IsHomogeneousAggregate(CompilerType *base_type_ptr) const;

   size_t GetNumberOfFunctionArguments() const;

   CompilerType GetFunctionArgumentAtIndex(const size_t index) const;

   bool IsVariadicFunctionType() const;

   bool IsFunctionPointerType() const;

   bool
   IsBlockPointerType(CompilerType *function_pointer_type_ptr = nullptr) const;

   bool IsIntegerType(bool &is_signed) const;

   bool IsEnumerationType(bool &is_signed) const;

   bool IsIntegerOrEnumerationType(bool &is_signed) const;

   bool IsPolymorphicClass() const;

   /// \param target_type    Can pass nullptr.
   bool IsPossibleDynamicType(CompilerType *target_type, bool check_cplusplus,
                              bool check_objc) const;

   bool IsPointerToScalarType() const;

   bool IsRuntimeGeneratedType() const;

   bool IsPointerType(CompilerType *pointee_type = nullptr) const;

   bool IsPointerOrReferenceType(CompilerType *pointee_type = nullptr) const;

   bool IsReferenceType(CompilerType *pointee_type = nullptr,
                        bool *is_rvalue = nullptr) const;

   bool ShouldTreatScalarValueAsAddress() const;

   bool IsScalarType() const;

   bool IsTypedefType() const;

   bool IsVoidType() const;
   /// \}

   /// Type Completion.
   /// \{
   bool GetCompleteType() const;
   /// \}

   /// AST related queries.
   /// \{
   size_t GetPointerByteSize() const;
   /// \}

   /// Accessors.
   /// \{
   TypeSystem *GetTypeSystem() const { return m_type_system; }

   ConstString GetTypeName() const;

   ConstString GetDisplayTypeName() const;

   uint32_t
   GetTypeInfo(CompilerType *pointee_or_element_compiler_type = nullptr) const;

   lldb::LanguageType GetMinimumLanguage();

   lldb::opaque_compiler_type_t GetOpaqueQualType() const { return m_type; }

   lldb::TypeClass GetTypeClass() const;

   void SetCompilerType(TypeSystem *type_system,
                        lldb::opaque_compiler_type_t type);

   unsigned GetTypeQualifiers() const;
   /// \}

   /// Creating related types.
   /// \{
   CompilerType GetArrayElementType(ExecutionContextScope *exe_scope) const;

   CompilerType GetArrayType(uint64_t size) const;

   CompilerType GetCanonicalType() const;

   CompilerType GetFullyUnqualifiedType() const;

   CompilerType GetEnumerationIntegerType() const;

   /// Returns -1 if this isn't a function of if the function doesn't
   /// have a prototype Returns a value >= 0 if there is a prototype.
   int GetFunctionArgumentCount() const;

   CompilerType GetFunctionArgumentTypeAtIndex(size_t idx) const;

   CompilerType GetFunctionReturnType() const;

   size_t GetNumMemberFunctions() const;

   TypeMemberFunctionImpl GetMemberFunctionAtIndex(size_t idx);

   /// If this type is a reference to a type (L value or R value reference),
   /// return a new type with the reference removed, else return the current type
   /// itself.
   CompilerType GetNonReferenceType() const;

   /// If this type is a pointer type, return the type that the pointer points
   /// to, else return an invalid type.
   CompilerType GetPointeeType() const;

   /// Return a new CompilerType that is a pointer to this type
   CompilerType GetPointerType() const;

   /// Return a new CompilerType that is a L value reference to this type if this
   /// type is valid and the type system supports L value references, else return
   /// an invalid type.
   CompilerType GetLValueReferenceType() const;

   /// Return a new CompilerType that is a R value reference to this type if this
   /// type is valid and the type system supports R value references, else return
   /// an invalid type.
   CompilerType GetRValueReferenceType() const;

   /// Return a new CompilerType adds a const modifier to this type if this type
   /// is valid and the type system supports const modifiers, else return an
   /// invalid type.
   CompilerType AddConstModifier() const;

   /// Return a new CompilerType adds a volatile modifier to this type if this
   /// type is valid and the type system supports volatile modifiers, else return
   /// an invalid type.
   CompilerType AddVolatileModifier() const;

   /// Return a new CompilerType that is the atomic type of this type. If this
   /// type is not valid or the type system doesn't support atomic types, this
   /// returns an invalid type.
   CompilerType GetAtomicType() const;

   /// Return a new CompilerType adds a restrict modifier to this type if this
   /// type is valid and the type system supports restrict modifiers, else return
   /// an invalid type.
   CompilerType AddRestrictModifier() const;

   /// Create a typedef to this type using "name" as the name of the typedef this
   /// type is valid and the type system supports typedefs, else return an
   /// invalid type.
   /// \param payload   The typesystem-specific \p lldb::Type payload.
   CompilerType CreateTypedef(const char *name,
                              const CompilerDeclContext &decl_ctx,
                              uint32_t payload) const;

   /// If the current object represents a typedef type, get the underlying type
   CompilerType GetTypedefedType() const;

   /// Create related types using the current type's AST
   CompilerType GetBasicTypeFromAST(lldb::BasicType basic_type) const;
   /// \}

   /// Exploring the type.
   /// \{
   struct IntegralTemplateArgument;

   /// Return the size of the type in bytes.
   llvm::Optional<uint64_t> GetByteSize(ExecutionContextScope *exe_scope) const;
   /// Return the size of the type in bits.
   llvm::Optional<uint64_t> GetBitSize(ExecutionContextScope *exe_scope) const;

   lldb::Encoding GetEncoding(uint64_t &count) const;

   lldb::Format GetFormat() const;

   llvm::Optional<size_t>
   GetTypeBitAlign(ExecutionContextScope *exe_scope) const;

   uint32_t GetNumChildren(bool omit_empty_base_classes,
                           const ExecutionContext *exe_ctx) const;

   lldb::BasicType GetBasicTypeEnumeration() const;

   static lldb::BasicType GetBasicTypeEnumeration(ConstString name);

   /// If this type is an enumeration, iterate through all of its enumerators
   /// using a callback. If the callback returns true, keep iterating, else abort
   /// the iteration.
   void ForEachEnumerator(
       std::function<bool(const CompilerType &integer_type, ConstString name,
                          const llvm::APSInt &value)> const &callback) const;

   uint32_t GetNumFields() const;

   CompilerType GetFieldAtIndex(size_t idx, std::string &name,
                                uint64_t *bit_offset_ptr,
                                uint32_t *bitfield_bit_size_ptr,
                                bool *is_bitfield_ptr) const;

   uint32_t GetNumDirectBaseClasses() const;

   uint32_t GetNumVirtualBaseClasses() const;

   CompilerType GetDirectBaseClassAtIndex(size_t idx,
                                          uint32_t *bit_offset_ptr) const;

   CompilerType GetVirtualBaseClassAtIndex(size_t idx,
                                           uint32_t *bit_offset_ptr) const;

   uint32_t GetIndexOfFieldWithName(const char *name,
                                    CompilerType *field_compiler_type = nullptr,
                                    uint64_t *bit_offset_ptr = nullptr,
                                    uint32_t *bitfield_bit_size_ptr = nullptr,
                                    bool *is_bitfield_ptr = nullptr) const;

   CompilerType GetChildCompilerTypeAtIndex(
       ExecutionContext *exe_ctx, size_t idx, bool transparent_pointers,
       bool omit_empty_base_classes, bool ignore_array_bounds,
       std::string &child_name, uint32_t &child_byte_size,
       int32_t &child_byte_offset, uint32_t &child_bitfield_bit_size,
       uint32_t &child_bitfield_bit_offset, bool &child_is_base_class,
       bool &child_is_deref_of_parent, ValueObject *valobj,
       uint64_t &language_flags) const;

   /// Lookup a child given a name. This function will match base class names and
   /// member member names in "clang_type" only, not descendants.
   uint32_t GetIndexOfChildWithName(const char *name,
                                    bool omit_empty_base_classes) const;

   /// Lookup a child member given a name. This function will match member names
   /// only and will descend into "clang_type" children in search for the first
   /// member in this class, or any base class that matches "name".
   /// TODO: Return all matches for a given name by returning a
   /// vector<vector<uint32_t>>
   /// so we catch all names that match a given child name, not just the first.
   size_t
   GetIndexOfChildMemberWithName(const char *name, bool omit_empty_base_classes,
                                 std::vector<uint32_t> &child_indexes) const;

   size_t GetNumTemplateArguments() const;

   lldb::TemplateArgumentKind GetTemplateArgumentKind(size_t idx) const;
   CompilerType GetTypeTemplateArgument(size_t idx) const;

   /// Returns the value of the template argument and its type.
   llvm::Optional<IntegralTemplateArgument>
   GetIntegralTemplateArgument(size_t idx) const;

   CompilerType GetTypeForFormatters() const;

   LazyBool ShouldPrintAsOneLiner(ValueObject *valobj) const;

   bool IsMeaninglessWithoutDynamicResolution() const;
   /// \}

   /// Dumping types.
   /// \{
 #ifndef NDEBUG
   /// Convenience LLVM-style dump method for use in the debugger only.
   /// Don't call this function from actual code.
   LLVM_DUMP_METHOD void dump() const;
 #endif

   void DumpValue(ExecutionContext *exe_ctx, Stream *s, lldb::Format format,
                  const DataExtractor &data, lldb::offset_t data_offset,
                  size_t data_byte_size, uint32_t bitfield_bit_size,
                  uint32_t bitfield_bit_offset, bool show_types,
                  bool show_summary, bool verbose, uint32_t depth);

   bool DumpTypeValue(Stream *s, lldb::Format format, const DataExtractor &data,
                      lldb::offset_t data_offset, size_t data_byte_size,
                      uint32_t bitfield_bit_size, uint32_t bitfield_bit_offset,
                      ExecutionContextScope *exe_scope);

   void DumpSummary(ExecutionContext *exe_ctx, Stream *s,
                    const DataExtractor &data, lldb::offset_t data_offset,
                    size_t data_byte_size);

   /// Dump to stdout.
   void DumpTypeDescription(lldb::DescriptionLevel level =
                            lldb::eDescriptionLevelFull) const;

   /// Print a description of the type to a stream. The exact implementation
   /// varies, but the expectation is that eDescriptionLevelFull returns a
   /// source-like representation of the type, whereas eDescriptionLevelVerbose
   /// does a dump of the underlying AST if applicable.
   void DumpTypeDescription(Stream *s, lldb::DescriptionLevel level =
                                           lldb::eDescriptionLevelFull) const;
   /// \}

   bool GetValueAsScalar(const DataExtractor &data, lldb::offset_t data_offset,
                         size_t data_byte_size, Scalar &value,
                         ExecutionContextScope *exe_scope) const;
   void Clear() {
     m_type = nullptr;
     m_type_system = nullptr;
   }

 private:
 #ifndef NDEBUG
   /// If the type is valid, ask the TypeSystem to verify the integrity
   /// of the type to catch CompilerTypes that mix and match invalid
   /// TypeSystem/Opaque type pairs.
   bool Verify() const;
 #endif

   lldb::opaque_compiler_type_t m_type = nullptr;
   TypeSystem *m_type_system = nullptr;
 };

 bool operator==(const CompilerType &lhs, const CompilerType &rhs);
 bool operator!=(const CompilerType &lhs, const CompilerType &rhs);

 struct CompilerType::IntegralTemplateArgument {
   llvm::APSInt value;
   CompilerType type;
 };

 } // namespace lldb_private

 #endif // LLDB_SYMBOL_COMPILERTYPE_H
	//===-- CompilerType.h ------------------------------------------- C++ --===//
	//
	// 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
	//
	//===----------------------------------------------------------------------===//

	#ifndef LLDB_SYMBOL_COMPILERTYPE_H
	#define LLDB_SYMBOL_COMPILERTYPE_H

	#include <functional>
	#include <string>
	#include <vector>

	#include "lldb/lldb-private.h"
	#include "llvm/ADT/APSInt.h"

	namespace lldb_private {

	class DataExtractor;

	/// Generic representation of a type in a programming language.
	///
	/// This class serves as an abstraction for a type inside one of the TypeSystems
	/// implemented by the language plugins. It does not have any actual logic in it
	/// but only stores an opaque pointer and a pointer to the TypeSystem that
	/// gives meaning to this opaque pointer. All methods of this class should call
	/// their respective method in the TypeSystem interface and pass the opaque
	/// pointer along.
	///
	/// \see lldb_private::TypeSystem
	class CompilerType {
	public:
	/// Creates a CompilerType with the given TypeSystem and opaque compiler type.
	///
	/// This constructor should only be called from the respective TypeSystem
	/// implementation.
	///
	/// \see lldb_private::TypeSystemClang::GetType(clang::QualType)
	CompilerType(TypeSystem *type_system, lldb::opaque_compiler_type_t type)
	: m_type(type), m_type_system(type_system) {
	assert(Verify() && "verification failed");
	}

	CompilerType(const CompilerType &rhs)
	: m_type(rhs.m_type), m_type_system(rhs.m_type_system) {}

	CompilerType() = default;

	/// Operators.
	/// \{
	const CompilerType &operator=(const CompilerType &rhs) {
	m_type = rhs.m_type;
	m_type_system = rhs.m_type_system;
	return *this;
	}

	bool operator<(const CompilerType &rhs) const {
	if (m_type_system == rhs.m_type_system)
	return m_type < rhs.m_type;
	return m_type_system < rhs.m_type_system;
	}
	/// \}

	/// Tests.
	/// \{
	explicit operator bool() const {
	return m_type != nullptr && m_type_system != nullptr;
	}

	bool IsValid() const { return m_type != nullptr && m_type_system != nullptr; }

	bool IsArrayType(CompilerType *element_type = nullptr,
	uint64_t *size = nullptr,
	bool *is_incomplete = nullptr) const;

	bool IsVectorType(CompilerType *element_type = nullptr,
	uint64_t *size = nullptr) const;

	bool IsArrayOfScalarType() const;

	bool IsAggregateType() const;

	bool IsAnonymousType() const;

	bool IsScopedEnumerationType() const;

	bool IsBeingDefined() const;

	bool IsCharType() const;

	bool IsCompleteType() const;

	bool IsConst() const;

	bool IsCStringType(uint32_t &length) const;

	bool IsDefined() const;

	bool IsFloatingPointType(uint32_t &count, bool &is_complex) const;

	bool IsFunctionType() const;

	uint32_t IsHomogeneousAggregate(CompilerType *base_type_ptr) const;

	size_t GetNumberOfFunctionArguments() const;

	CompilerType GetFunctionArgumentAtIndex(const size_t index) const;

	bool IsVariadicFunctionType() const;

	bool IsFunctionPointerType() const;

	bool
	IsBlockPointerType(CompilerType *function_pointer_type_ptr = nullptr) const;

	bool IsIntegerType(bool &is_signed) const;

	bool IsEnumerationType(bool &is_signed) const;

	bool IsIntegerOrEnumerationType(bool &is_signed) const;

	bool IsPolymorphicClass() const;

	/// \param target_type Can pass nullptr.
	bool IsPossibleDynamicType(CompilerType *target_type, bool check_cplusplus,
	bool check_objc) const;

	bool IsPointerToScalarType() const;

	bool IsRuntimeGeneratedType() const;

	bool IsPointerType(CompilerType *pointee_type = nullptr) const;

	bool IsPointerOrReferenceType(CompilerType *pointee_type = nullptr) const;

	bool IsReferenceType(CompilerType *pointee_type = nullptr,
	bool *is_rvalue = nullptr) const;

	bool ShouldTreatScalarValueAsAddress() const;

	bool IsScalarType() const;

	bool IsTypedefType() const;

	bool IsVoidType() const;
	/// \}

	/// Type Completion.
	/// \{
	bool GetCompleteType() const;
	/// \}

	/// AST related queries.
	/// \{
	size_t GetPointerByteSize() const;
	/// \}

	/// Accessors.
	/// \{
	TypeSystem *GetTypeSystem() const { return m_type_system; }

	ConstString GetTypeName() const;

	ConstString GetDisplayTypeName() const;

	uint32_t
	GetTypeInfo(CompilerType *pointee_or_element_compiler_type = nullptr) const;

	lldb::LanguageType GetMinimumLanguage();

	lldb::opaque_compiler_type_t GetOpaqueQualType() const { return m_type; }

	lldb::TypeClass GetTypeClass() const;

	void SetCompilerType(TypeSystem *type_system,
	lldb::opaque_compiler_type_t type);

	unsigned GetTypeQualifiers() const;
	/// \}

	/// Creating related types.
	/// \{
	CompilerType GetArrayElementType(ExecutionContextScope *exe_scope) const;

	CompilerType GetArrayType(uint64_t size) const;

	CompilerType GetCanonicalType() const;

	CompilerType GetFullyUnqualifiedType() const;

	CompilerType GetEnumerationIntegerType() const;

	/// Returns -1 if this isn't a function of if the function doesn't
	/// have a prototype Returns a value >= 0 if there is a prototype.
	int GetFunctionArgumentCount() const;

	CompilerType GetFunctionArgumentTypeAtIndex(size_t idx) const;

	CompilerType GetFunctionReturnType() const;

	size_t GetNumMemberFunctions() const;

	TypeMemberFunctionImpl GetMemberFunctionAtIndex(size_t idx);

	/// If this type is a reference to a type (L value or R value reference),
	/// return a new type with the reference removed, else return the current type
	/// itself.
	CompilerType GetNonReferenceType() const;

	/// If this type is a pointer type, return the type that the pointer points
	/// to, else return an invalid type.
	CompilerType GetPointeeType() const;

	/// Return a new CompilerType that is a pointer to this type
	CompilerType GetPointerType() const;

	/// Return a new CompilerType that is a L value reference to this type if this
	/// type is valid and the type system supports L value references, else return
	/// an invalid type.
	CompilerType GetLValueReferenceType() const;

	/// Return a new CompilerType that is a R value reference to this type if this
	/// type is valid and the type system supports R value references, else return
	/// an invalid type.
	CompilerType GetRValueReferenceType() const;

	/// Return a new CompilerType adds a const modifier to this type if this type
	/// is valid and the type system supports const modifiers, else return an
	/// invalid type.
	CompilerType AddConstModifier() const;

	/// Return a new CompilerType adds a volatile modifier to this type if this
	/// type is valid and the type system supports volatile modifiers, else return
	/// an invalid type.
	CompilerType AddVolatileModifier() const;

	/// Return a new CompilerType that is the atomic type of this type. If this
	/// type is not valid or the type system doesn't support atomic types, this
	/// returns an invalid type.
	CompilerType GetAtomicType() const;

	/// Return a new CompilerType adds a restrict modifier to this type if this
	/// type is valid and the type system supports restrict modifiers, else return
	/// an invalid type.
	CompilerType AddRestrictModifier() const;

	/// Create a typedef to this type using "name" as the name of the typedef this
	/// type is valid and the type system supports typedefs, else return an
	/// invalid type.
	/// \param payload The typesystem-specific \p lldb::Type payload.
	CompilerType CreateTypedef(const char *name,
	const CompilerDeclContext &decl_ctx,
	uint32_t payload) const;

	/// If the current object represents a typedef type, get the underlying type
	CompilerType GetTypedefedType() const;

	/// Create related types using the current type's AST
	CompilerType GetBasicTypeFromAST(lldb::BasicType basic_type) const;
	/// \}

	/// Exploring the type.
	/// \{
	struct IntegralTemplateArgument;

	/// Return the size of the type in bytes.
	llvm::Optional<uint64_t> GetByteSize(ExecutionContextScope *exe_scope) const;
	/// Return the size of the type in bits.
	llvm::Optional<uint64_t> GetBitSize(ExecutionContextScope *exe_scope) const;

	lldb::Encoding GetEncoding(uint64_t &count) const;

	lldb::Format GetFormat() const;

	llvm::Optional<size_t>
	GetTypeBitAlign(ExecutionContextScope *exe_scope) const;

	uint32_t GetNumChildren(bool omit_empty_base_classes,
	const ExecutionContext *exe_ctx) const;

	lldb::BasicType GetBasicTypeEnumeration() const;

	static lldb::BasicType GetBasicTypeEnumeration(ConstString name);

	/// If this type is an enumeration, iterate through all of its enumerators
	/// using a callback. If the callback returns true, keep iterating, else abort
	/// the iteration.
	void ForEachEnumerator(
	std::function<bool(const CompilerType &integer_type, ConstString name,
	const llvm::APSInt &value)> const &callback) const;

	uint32_t GetNumFields() const;

	CompilerType GetFieldAtIndex(size_t idx, std::string &name,
	uint64_t *bit_offset_ptr,
	uint32_t *bitfield_bit_size_ptr,
	bool *is_bitfield_ptr) const;

	uint32_t GetNumDirectBaseClasses() const;

	uint32_t GetNumVirtualBaseClasses() const;

	CompilerType GetDirectBaseClassAtIndex(size_t idx,
	uint32_t *bit_offset_ptr) const;

	CompilerType GetVirtualBaseClassAtIndex(size_t idx,
	uint32_t *bit_offset_ptr) const;

	uint32_t GetIndexOfFieldWithName(const char *name,
	CompilerType *field_compiler_type = nullptr,
	uint64_t *bit_offset_ptr = nullptr,
	uint32_t *bitfield_bit_size_ptr = nullptr,
	bool *is_bitfield_ptr = nullptr) const;

	CompilerType GetChildCompilerTypeAtIndex(
	ExecutionContext *exe_ctx, size_t idx, bool transparent_pointers,
	bool omit_empty_base_classes, bool ignore_array_bounds,
	std::string &child_name, uint32_t &child_byte_size,
	int32_t &child_byte_offset, uint32_t &child_bitfield_bit_size,
	uint32_t &child_bitfield_bit_offset, bool &child_is_base_class,
	bool &child_is_deref_of_parent, ValueObject *valobj,
	uint64_t &language_flags) const;

	/// Lookup a child given a name. This function will match base class names and
	/// member member names in "clang_type" only, not descendants.
	uint32_t GetIndexOfChildWithName(const char *name,
	bool omit_empty_base_classes) const;

	/// Lookup a child member given a name. This function will match member names
	/// only and will descend into "clang_type" children in search for the first
	/// member in this class, or any base class that matches "name".
	/// TODO: Return all matches for a given name by returning a
	/// vector<vector<uint32_t>>
	/// so we catch all names that match a given child name, not just the first.
	size_t
	GetIndexOfChildMemberWithName(const char *name, bool omit_empty_base_classes,
	std::vector<uint32_t> &child_indexes) const;

	size_t GetNumTemplateArguments() const;

	lldb::TemplateArgumentKind GetTemplateArgumentKind(size_t idx) const;
	CompilerType GetTypeTemplateArgument(size_t idx) const;

	/// Returns the value of the template argument and its type.
	llvm::Optional<IntegralTemplateArgument>
	GetIntegralTemplateArgument(size_t idx) const;

	CompilerType GetTypeForFormatters() const;

	LazyBool ShouldPrintAsOneLiner(ValueObject *valobj) const;

	bool IsMeaninglessWithoutDynamicResolution() const;
	/// \}

	/// Dumping types.
	/// \{
	#ifndef NDEBUG
	/// Convenience LLVM-style dump method for use in the debugger only.
	/// Don't call this function from actual code.
	LLVM_DUMP_METHOD void dump() const;
	#endif

	void DumpValue(ExecutionContext exe_ctx, Stream s, lldb::Format format,
	const DataExtractor &data, lldb::offset_t data_offset,
	size_t data_byte_size, uint32_t bitfield_bit_size,
	uint32_t bitfield_bit_offset, bool show_types,
	bool show_summary, bool verbose, uint32_t depth);

	bool DumpTypeValue(Stream *s, lldb::Format format, const DataExtractor &data,
	lldb::offset_t data_offset, size_t data_byte_size,
	uint32_t bitfield_bit_size, uint32_t bitfield_bit_offset,
	ExecutionContextScope *exe_scope);

	void DumpSummary(ExecutionContext exe_ctx, Stream s,
	const DataExtractor &data, lldb::offset_t data_offset,
	size_t data_byte_size);

	/// Dump to stdout.
	void DumpTypeDescription(lldb::DescriptionLevel level =
	lldb::eDescriptionLevelFull) const;

	/// Print a description of the type to a stream. The exact implementation
	/// varies, but the expectation is that eDescriptionLevelFull returns a
	/// source-like representation of the type, whereas eDescriptionLevelVerbose
	/// does a dump of the underlying AST if applicable.
	void DumpTypeDescription(Stream *s, lldb::DescriptionLevel level =
	lldb::eDescriptionLevelFull) const;
	/// \}

	bool GetValueAsScalar(const DataExtractor &data, lldb::offset_t data_offset,
	size_t data_byte_size, Scalar &value,
	ExecutionContextScope *exe_scope) const;
	void Clear() {
	m_type = nullptr;
	m_type_system = nullptr;
	}

	private:
	#ifndef NDEBUG
	/// If the type is valid, ask the TypeSystem to verify the integrity
	/// of the type to catch CompilerTypes that mix and match invalid
	/// TypeSystem/Opaque type pairs.
	bool Verify() const;
	#endif

	lldb::opaque_compiler_type_t m_type = nullptr;
	TypeSystem *m_type_system = nullptr;
	};

	bool operator==(const CompilerType &lhs, const CompilerType &rhs);
	bool operator!=(const CompilerType &lhs, const CompilerType &rhs);

	struct CompilerType::IntegralTemplateArgument {
	llvm::APSInt value;
	CompilerType type;
	};

	} // namespace lldb_private

	#endif // LLDB_SYMBOL_COMPILERTYPE_H