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//===-- SymbolFile.h --------------------------------------------*- C++ -*-===//
// Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions.
// See for license information.
// SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception
#ifndef liblldb_SymbolFile_h_
#define liblldb_SymbolFile_h_
#include "lldb/Core/PluginInterface.h"
#include "lldb/Symbol/CompilerDecl.h"
#include "lldb/Symbol/CompilerDeclContext.h"
#include "lldb/Symbol/CompilerType.h"
#include "lldb/Symbol/Function.h"
#include "lldb/Symbol/SourceModule.h"
#include "lldb/Symbol/Type.h"
#include "lldb/Symbol/TypeList.h"
#include "lldb/Symbol/TypeSystem.h"
#include "lldb/lldb-private.h"
#include "llvm/ADT/DenseSet.h"
#include "llvm/Support/Errc.h"
#include <mutex>
#define ASSERT_MODULE_LOCK(expr) (expr->AssertModuleLock())
#define ASSERT_MODULE_LOCK(expr) ((void)0)
namespace lldb_private {
class SymbolFile : public PluginInterface {
/// LLVM RTTI support.
static char ID;
/// LLVM RTTI support.
/// \{
virtual bool isA(const void *ClassID) const { return ClassID == &ID; }
static bool classof(const SymbolFile *obj) { return obj->isA(&ID); }
/// \}
// Symbol file ability bits.
// Each symbol file can claim to support one or more symbol file abilities.
// These get returned from SymbolFile::GetAbilities(). These help us to
// determine which plug-in will be best to load the debug information found
// in files.
enum Abilities {
CompileUnits = (1u << 0),
LineTables = (1u << 1),
Functions = (1u << 2),
Blocks = (1u << 3),
GlobalVariables = (1u << 4),
LocalVariables = (1u << 5),
VariableTypes = (1u << 6),
kAllAbilities = ((1u << 7) - 1u)
static SymbolFile *FindPlugin(lldb::ObjectFileSP objfile_sp);
// Constructors and Destructors
SymbolFile(lldb::ObjectFileSP objfile_sp)
: m_objfile_sp(std::move(objfile_sp)), m_abilities(0),
m_calculated_abilities(false) {}
~SymbolFile() override {}
/// Get a mask of what this symbol file supports for the object file
/// that it was constructed with.
/// Each symbol file gets to respond with a mask of abilities that
/// it supports for each object file. This happens when we are
/// trying to figure out which symbol file plug-in will get used
/// for a given object file. The plug-in that responds with the
/// best mix of "SymbolFile::Abilities" bits set, will get chosen to
/// be the symbol file parser. This allows each plug-in to check for
/// sections that contain data a symbol file plug-in would need. For
/// example the DWARF plug-in requires DWARF sections in a file that
/// contain debug information. If the DWARF plug-in doesn't find
/// these sections, it won't respond with many ability bits set, and
/// we will probably fall back to the symbol table SymbolFile plug-in
/// which uses any information in the symbol table. Also, plug-ins
/// might check for some specific symbols in a symbol table in the
/// case where the symbol table contains debug information (STABS
/// and COFF). Not a lot of work should happen in these functions
/// as the plug-in might not get selected due to another plug-in
/// having more abilities. Any initialization work should be saved
/// for "void SymbolFile::InitializeObject()" which will get called
/// on the SymbolFile object with the best set of abilities.
/// \return
/// A uint32_t mask containing bits from the SymbolFile::Abilities
/// enumeration. Any bits that are set represent an ability that
/// this symbol plug-in can parse from the object file.
uint32_t GetAbilities() {
if (!m_calculated_abilities) {
m_abilities = CalculateAbilities();
m_calculated_abilities = true;
return m_abilities;
virtual uint32_t CalculateAbilities() = 0;
/// Symbols file subclasses should override this to return the Module that
/// owns the TypeSystem that this symbol file modifies type information in.
virtual std::recursive_mutex &GetModuleMutex() const;
/// Initialize the SymbolFile object.
/// The SymbolFile object with the best set of abilities (detected
/// in "uint32_t SymbolFile::GetAbilities()) will have this function
/// called if it is chosen to parse an object file. More complete
/// initialization can happen in this function which will get called
/// prior to any other functions in the SymbolFile protocol.
virtual void InitializeObject() {}
// Compile Unit function calls
// Approach 1 - iterator
uint32_t GetNumCompileUnits();
lldb::CompUnitSP GetCompileUnitAtIndex(uint32_t idx);
Symtab *GetSymtab();
virtual lldb::LanguageType ParseLanguage(CompileUnit &comp_unit) = 0;
virtual size_t ParseFunctions(CompileUnit &comp_unit) = 0;
virtual bool ParseLineTable(CompileUnit &comp_unit) = 0;
virtual bool ParseDebugMacros(CompileUnit &comp_unit) = 0;
/// Apply a lambda to each external lldb::Module referenced by this
/// \p comp_unit. Recursively also descends into the referenced external
/// modules of any encountered compilation unit.
/// \param comp_unit
/// When this SymbolFile consists of multiple auxilliary
/// SymbolFiles, for example, a Darwin debug map that references
/// multiple .o files, comp_unit helps choose the auxilliary
/// file. In most other cases comp_unit's symbol file is
/// identiacal with *this.
/// \param[in] lambda
/// The lambda that should be applied to every function. The lambda can
/// return true if the iteration should be aborted earlier.
/// \param visited_symbol_files
/// A set of SymbolFiles that were already visited to avoid
/// visiting one file more than once.
/// \return
/// If the lambda early-exited, this function returns true to
/// propagate the early exit.
virtual bool ForEachExternalModule(
lldb_private::CompileUnit &comp_unit,
llvm::DenseSet<lldb_private::SymbolFile *> &visited_symbol_files,
llvm::function_ref<bool(Module &)> lambda) {
return false;
virtual bool ParseSupportFiles(CompileUnit &comp_unit,
FileSpecList &support_files) = 0;
virtual size_t ParseTypes(CompileUnit &comp_unit) = 0;
virtual bool ParseIsOptimized(CompileUnit &comp_unit) { return false; }
virtual bool
ParseImportedModules(const SymbolContext &sc,
std::vector<SourceModule> &imported_modules) = 0;
virtual size_t ParseBlocksRecursive(Function &func) = 0;
virtual size_t ParseVariablesForContext(const SymbolContext &sc) = 0;
virtual Type *ResolveTypeUID(lldb::user_id_t type_uid) = 0;
/// The characteristics of an array type.
struct ArrayInfo {
int64_t first_index = 0;
llvm::SmallVector<uint64_t, 1> element_orders;
uint32_t byte_stride = 0;
uint32_t bit_stride = 0;
/// If \c type_uid points to an array type, return its characteristics.
/// To support variable-length array types, this function takes an
/// optional \p ExtecutionContext. If \c exe_ctx is non-null, the
/// dynamic characteristics for that context are returned.
virtual llvm::Optional<ArrayInfo>
GetDynamicArrayInfoForUID(lldb::user_id_t type_uid,
const lldb_private::ExecutionContext *exe_ctx) = 0;
virtual bool CompleteType(CompilerType &compiler_type) = 0;
virtual void ParseDeclsForContext(CompilerDeclContext decl_ctx) {}
virtual CompilerDecl GetDeclForUID(lldb::user_id_t uid) {
return CompilerDecl();
virtual CompilerDeclContext GetDeclContextForUID(lldb::user_id_t uid) {
return CompilerDeclContext();
virtual CompilerDeclContext GetDeclContextContainingUID(lldb::user_id_t uid) {
return CompilerDeclContext();
virtual uint32_t ResolveSymbolContext(const Address &so_addr,
lldb::SymbolContextItem resolve_scope,
SymbolContext &sc) = 0;
virtual uint32_t ResolveSymbolContext(const FileSpec &file_spec,
uint32_t line, bool check_inlines,
lldb::SymbolContextItem resolve_scope,
SymbolContextList &sc_list);
virtual void DumpClangAST(Stream &s) {}
virtual void
FindGlobalVariables(ConstString name,
const CompilerDeclContext *parent_decl_ctx,
uint32_t max_matches, VariableList &variables);
virtual void FindGlobalVariables(const RegularExpression &regex,
uint32_t max_matches,
VariableList &variables);
virtual void FindFunctions(ConstString name,
const CompilerDeclContext *parent_decl_ctx,
lldb::FunctionNameType name_type_mask,
bool include_inlines, SymbolContextList &sc_list);
virtual void FindFunctions(const RegularExpression &regex,
bool include_inlines, SymbolContextList &sc_list);
virtual void
FindTypes(ConstString name, const CompilerDeclContext *parent_decl_ctx,
uint32_t max_matches,
llvm::DenseSet<lldb_private::SymbolFile *> &searched_symbol_files,
TypeMap &types);
/// Find types specified by a CompilerContextPattern.
/// \param languages
/// Only return results in these languages.
/// \param searched_symbol_files
/// Prevents one file from being visited multiple times.
virtual void
FindTypes(llvm::ArrayRef<CompilerContext> pattern, LanguageSet languages,
llvm::DenseSet<lldb_private::SymbolFile *> &searched_symbol_files,
TypeMap &types);
virtual void
GetMangledNamesForFunction(const std::string &scope_qualified_name,
std::vector<ConstString> &mangled_names);
virtual void GetTypes(lldb_private::SymbolContextScope *sc_scope,
lldb::TypeClass type_mask,
lldb_private::TypeList &type_list) = 0;
virtual void PreloadSymbols();
virtual llvm::Expected<lldb_private::TypeSystem &>
GetTypeSystemForLanguage(lldb::LanguageType language);
virtual CompilerDeclContext
FindNamespace(ConstString name,
const CompilerDeclContext *parent_decl_ctx) {
return CompilerDeclContext();
ObjectFile *GetObjectFile() { return m_objfile_sp.get(); }
const ObjectFile *GetObjectFile() const { return m_objfile_sp.get(); }
ObjectFile *GetMainObjectFile();
virtual std::vector<std::unique_ptr<CallEdge>>
ParseCallEdgesInFunction(UserID func_id) {
return {};
virtual void AddSymbols(Symtab &symtab) {}
/// Notify the SymbolFile that the file addresses in the Sections
/// for this module have been changed.
virtual void SectionFileAddressesChanged();
struct RegisterInfoResolver {
virtual ~RegisterInfoResolver(); // anchor
virtual const RegisterInfo *ResolveName(llvm::StringRef name) const = 0;
virtual const RegisterInfo *ResolveNumber(lldb::RegisterKind kind,
uint32_t number) const = 0;
virtual lldb::UnwindPlanSP
GetUnwindPlan(const Address &address, const RegisterInfoResolver &resolver) {
return nullptr;
/// Return the number of stack bytes taken up by the parameters to this
/// function.
virtual llvm::Expected<lldb::addr_t> GetParameterStackSize(Symbol &symbol) {
return llvm::createStringError(make_error_code(llvm::errc::not_supported),
"Operation not supported.");
virtual void Dump(Stream &s);
void AssertModuleLock();
virtual uint32_t CalculateNumCompileUnits() = 0;
virtual lldb::CompUnitSP ParseCompileUnitAtIndex(uint32_t idx) = 0;
virtual TypeList &GetTypeList() { return m_type_list; }
void SetCompileUnitAtIndex(uint32_t idx, const lldb::CompUnitSP &cu_sp);
lldb::ObjectFileSP m_objfile_sp; // Keep a reference to the object file in
// case it isn't the same as the module
// object file (debug symbols in a separate
// file)
llvm::Optional<std::vector<lldb::CompUnitSP>> m_compile_units;
TypeList m_type_list;
Symtab *m_symtab = nullptr;
uint32_t m_abilities;
bool m_calculated_abilities;
} // namespace lldb_private
#endif // liblldb_SymbolFile_h_