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llvm / llvm-project / 7e6df41f655e51c984b92bbd9c19a6fb851f35d4 / . / lldb / source / Plugins / SymbolFile / PDB / SymbolFilePDB.cpp
blob: db0ae241be7ec31078827a983f183b5121454683 [file] [log] [blame]
//===-- SymbolFilePDB.cpp -------------------------------------------------===//
//
// 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
//
//===----------------------------------------------------------------------===//
#include "SymbolFilePDB.h"
#include "PDBASTParser.h"
#include "PDBLocationToDWARFExpression.h"
#include "clang/Lex/Lexer.h"
#include "Plugins/TypeSystem/Clang/TypeSystemClang.h"
#include "lldb/Core/Module.h"
#include "lldb/Core/PluginManager.h"
#include "lldb/Symbol/CompileUnit.h"
#include "lldb/Symbol/LineTable.h"
#include "lldb/Symbol/ObjectFile.h"
#include "lldb/Symbol/SymbolContext.h"
#include "lldb/Symbol/SymbolVendor.h"
#include "lldb/Symbol/TypeList.h"
#include "lldb/Symbol/TypeMap.h"
#include "lldb/Symbol/Variable.h"
#include "lldb/Utility/Log.h"
#include "lldb/Utility/RegularExpression.h"
#include "llvm/DebugInfo/PDB/GenericError.h"
#include "llvm/DebugInfo/PDB/IPDBDataStream.h"
#include "llvm/DebugInfo/PDB/IPDBEnumChildren.h"
#include "llvm/DebugInfo/PDB/IPDBLineNumber.h"
#include "llvm/DebugInfo/PDB/IPDBSectionContrib.h"
#include "llvm/DebugInfo/PDB/IPDBSourceFile.h"
#include "llvm/DebugInfo/PDB/IPDBTable.h"
#include "llvm/DebugInfo/PDB/PDBSymbol.h"
#include "llvm/DebugInfo/PDB/PDBSymbolBlock.h"
#include "llvm/DebugInfo/PDB/PDBSymbolCompiland.h"
#include "llvm/DebugInfo/PDB/PDBSymbolCompilandDetails.h"
#include "llvm/DebugInfo/PDB/PDBSymbolData.h"
#include "llvm/DebugInfo/PDB/PDBSymbolExe.h"
#include "llvm/DebugInfo/PDB/PDBSymbolFunc.h"
#include "llvm/DebugInfo/PDB/PDBSymbolFuncDebugEnd.h"
#include "llvm/DebugInfo/PDB/PDBSymbolFuncDebugStart.h"
#include "llvm/DebugInfo/PDB/PDBSymbolPublicSymbol.h"
#include "llvm/DebugInfo/PDB/PDBSymbolTypeEnum.h"
#include "llvm/DebugInfo/PDB/PDBSymbolTypeTypedef.h"
#include "llvm/DebugInfo/PDB/PDBSymbolTypeUDT.h"
#include "Plugins/Language/CPlusPlus/CPlusPlusLanguage.h"
#include "Plugins/Language/CPlusPlus/MSVCUndecoratedNameParser.h"
#include "Plugins/SymbolFile/NativePDB/SymbolFileNativePDB.h"
#if defined(_WIN32)
#include "llvm/Config/config.h"
#endif
using namespace lldb;
using namespace lldb_private;
using namespace llvm::pdb;
LLDB_PLUGIN_DEFINE(SymbolFilePDB)
char SymbolFilePDB::ID;
namespace {
lldb::LanguageType TranslateLanguage(PDB_Lang lang) {
switch (lang) {
case PDB_Lang::Cpp:
return lldb::LanguageType::eLanguageTypeC_plus_plus;
case PDB_Lang::C:
return lldb::LanguageType::eLanguageTypeC;
case PDB_Lang::Swift:
return lldb::LanguageType::eLanguageTypeSwift;
default:
return lldb::LanguageType::eLanguageTypeUnknown;
}
}
bool ShouldAddLine(uint32_t requested_line, uint32_t actual_line,
uint32_t addr_length) {
return ((requested_line == 0 || actual_line == requested_line) &&
addr_length > 0);
}
} // namespace
static bool ShouldUseNativeReader() {
#if defined(_WIN32)
#if LLVM_ENABLE_DIA_SDK
llvm::StringRef use_native = ::getenv("LLDB_USE_NATIVE_PDB_READER");
if (!use_native.equals_insensitive("on") &&
!use_native.equals_insensitive("yes") &&
!use_native.equals_insensitive("1") &&
!use_native.equals_insensitive("true"))
return false;
#endif
#endif
return true;
}
void SymbolFilePDB::Initialize() {
if (ShouldUseNativeReader()) {
npdb::SymbolFileNativePDB::Initialize();
} else {
PluginManager::RegisterPlugin(GetPluginNameStatic(),
GetPluginDescriptionStatic(), CreateInstance,
DebuggerInitialize);
}
}
void SymbolFilePDB::Terminate() {
if (ShouldUseNativeReader()) {
npdb::SymbolFileNativePDB::Terminate();
} else {
PluginManager::UnregisterPlugin(CreateInstance);
}
}
void SymbolFilePDB::DebuggerInitialize(lldb_private::Debugger &debugger) {}
llvm::StringRef SymbolFilePDB::GetPluginDescriptionStatic() {
return "Microsoft PDB debug symbol file reader.";
}
lldb_private::SymbolFile *
SymbolFilePDB::CreateInstance(ObjectFileSP objfile_sp) {
return new SymbolFilePDB(std::move(objfile_sp));
}
SymbolFilePDB::SymbolFilePDB(lldb::ObjectFileSP objfile_sp)
: SymbolFile(std::move(objfile_sp)), m_session_up(), m_global_scope_up() {}
SymbolFilePDB::~SymbolFilePDB() = default;
uint32_t SymbolFilePDB::CalculateAbilities() {
uint32_t abilities = 0;
if (!m_objfile_sp)
return 0;
if (!m_session_up) {
// Lazily load and match the PDB file, but only do this once.
std::string exePath = m_objfile_sp->GetFileSpec().GetPath();
auto error = loadDataForEXE(PDB_ReaderType::DIA, llvm::StringRef(exePath),
m_session_up);
if (error) {
llvm::consumeError(std::move(error));
auto module_sp = m_objfile_sp->GetModule();
if (!module_sp)
return 0;
// See if any symbol file is specified through `--symfile` option.
FileSpec symfile = module_sp->GetSymbolFileFileSpec();
if (!symfile)
return 0;
error = loadDataForPDB(PDB_ReaderType::DIA,
llvm::StringRef(symfile.GetPath()), m_session_up);
if (error) {
llvm::consumeError(std::move(error));
return 0;
}
}
}
if (!m_session_up)
return 0;
auto enum_tables_up = m_session_up->getEnumTables();
if (!enum_tables_up)
return 0;
while (auto table_up = enum_tables_up->getNext()) {
if (table_up->getItemCount() == 0)
continue;
auto type = table_up->getTableType();
switch (type) {
case PDB_TableType::Symbols:
// This table represents a store of symbols with types listed in
// PDBSym_Type
abilities |= (CompileUnits | Functions | Blocks | GlobalVariables |
LocalVariables | VariableTypes);
break;
case PDB_TableType::LineNumbers:
abilities |= LineTables;
break;
default:
break;
}
}
return abilities;
}
void SymbolFilePDB::InitializeObject() {
lldb::addr_t obj_load_address =
m_objfile_sp->GetBaseAddress().GetFileAddress();
lldbassert(obj_load_address && obj_load_address != LLDB_INVALID_ADDRESS);
m_session_up->setLoadAddress(obj_load_address);
if (!m_global_scope_up)
m_global_scope_up = m_session_up->getGlobalScope();
lldbassert(m_global_scope_up.get());
}
uint32_t SymbolFilePDB::CalculateNumCompileUnits() {
auto compilands = m_global_scope_up->findAllChildren<PDBSymbolCompiland>();
if (!compilands)
return 0;
// The linker could link *.dll (compiland language = LINK), or import
// *.dll. For example, a compiland with name `Import:KERNEL32.dll` could be
// found as a child of the global scope (PDB executable). Usually, such
// compilands contain `thunk` symbols in which we are not interested for
// now. However we still count them in the compiland list. If we perform
// any compiland related activity, like finding symbols through
// llvm::pdb::IPDBSession methods, such compilands will all be searched
// automatically no matter whether we include them or not.
uint32_t compile_unit_count = compilands->getChildCount();
// The linker can inject an additional "dummy" compilation unit into the
// PDB. Ignore this special compile unit for our purposes, if it is there.
// It is always the last one.
auto last_compiland_up = compilands->getChildAtIndex(compile_unit_count - 1);
lldbassert(last_compiland_up.get());
std::string name = last_compiland_up->getName();
if (name == "* Linker *")
--compile_unit_count;
return compile_unit_count;
}
void SymbolFilePDB::GetCompileUnitIndex(
const llvm::pdb::PDBSymbolCompiland &pdb_compiland, uint32_t &index) {
auto results_up = m_global_scope_up->findAllChildren<PDBSymbolCompiland>();
if (!results_up)
return;
auto uid = pdb_compiland.getSymIndexId();
for (uint32_t cu_idx = 0; cu_idx < GetNumCompileUnits(); ++cu_idx) {
auto compiland_up = results_up->getChildAtIndex(cu_idx);
if (!compiland_up)
continue;
if (compiland_up->getSymIndexId() == uid) {
index = cu_idx;
return;
}
}
index = UINT32_MAX;
return;
}
std::unique_ptr<llvm::pdb::PDBSymbolCompiland>
SymbolFilePDB::GetPDBCompilandByUID(uint32_t uid) {
return m_session_up->getConcreteSymbolById<PDBSymbolCompiland>(uid);
}
lldb::CompUnitSP SymbolFilePDB::ParseCompileUnitAtIndex(uint32_t index) {
if (index >= GetNumCompileUnits())
return CompUnitSP();
// Assuming we always retrieve same compilands listed in same order through
// `PDBSymbolExe::findAllChildren` method, otherwise using `index` to get a
// compile unit makes no sense.
auto results = m_global_scope_up->findAllChildren<PDBSymbolCompiland>();
if (!results)
return CompUnitSP();
auto compiland_up = results->getChildAtIndex(index);
if (!compiland_up)
return CompUnitSP();
return ParseCompileUnitForUID(compiland_up->getSymIndexId(), index);
}
lldb::LanguageType SymbolFilePDB::ParseLanguage(CompileUnit &comp_unit) {
std::lock_guard<std::recursive_mutex> guard(GetModuleMutex());
auto compiland_up = GetPDBCompilandByUID(comp_unit.GetID());
if (!compiland_up)
return lldb::eLanguageTypeUnknown;
auto details = compiland_up->findOneChild<PDBSymbolCompilandDetails>();
if (!details)
return lldb::eLanguageTypeUnknown;
return TranslateLanguage(details->getLanguage());
}
lldb_private::Function *
SymbolFilePDB::ParseCompileUnitFunctionForPDBFunc(const PDBSymbolFunc &pdb_func,
CompileUnit &comp_unit) {
if (FunctionSP result = comp_unit.FindFunctionByUID(pdb_func.getSymIndexId()))
return result.get();
auto file_vm_addr = pdb_func.getVirtualAddress();
if (file_vm_addr == LLDB_INVALID_ADDRESS || file_vm_addr == 0)
return nullptr;
auto func_length = pdb_func.getLength();
AddressRange func_range =
AddressRange(file_vm_addr, func_length,
GetObjectFile()->GetModule()->GetSectionList());
if (!func_range.GetBaseAddress().IsValid())
return nullptr;
lldb_private::Type *func_type = ResolveTypeUID(pdb_func.getSymIndexId());
if (!func_type)
return nullptr;
user_id_t func_type_uid = pdb_func.getSignatureId();
Mangled mangled = GetMangledForPDBFunc(pdb_func);
FunctionSP func_sp =
std::make_shared<Function>(&comp_unit, pdb_func.getSymIndexId(),
func_type_uid, mangled, func_type, func_range);
comp_unit.AddFunction(func_sp);
LanguageType lang = ParseLanguage(comp_unit);
auto type_system_or_err = GetTypeSystemForLanguage(lang);
if (auto err = type_system_or_err.takeError()) {
LLDB_LOG_ERROR(lldb_private::GetLogIfAnyCategoriesSet(LIBLLDB_LOG_SYMBOLS),
std::move(err), "Unable to parse PDBFunc");
return nullptr;
}
TypeSystemClang *clang_type_system =
llvm::dyn_cast_or_null<TypeSystemClang>(&type_system_or_err.get());
if (!clang_type_system)
return nullptr;
clang_type_system->GetPDBParser()->GetDeclForSymbol(pdb_func);
return func_sp.get();
}
size_t SymbolFilePDB::ParseFunctions(CompileUnit &comp_unit) {
std::lock_guard<std::recursive_mutex> guard(GetModuleMutex());
size_t func_added = 0;
auto compiland_up = GetPDBCompilandByUID(comp_unit.GetID());
if (!compiland_up)
return 0;
auto results_up = compiland_up->findAllChildren<PDBSymbolFunc>();
if (!results_up)
return 0;
while (auto pdb_func_up = results_up->getNext()) {
auto func_sp = comp_unit.FindFunctionByUID(pdb_func_up->getSymIndexId());
if (!func_sp) {
if (ParseCompileUnitFunctionForPDBFunc(*pdb_func_up, comp_unit))
++func_added;
}
}
return func_added;
}
bool SymbolFilePDB::ParseLineTable(CompileUnit &comp_unit) {
std::lock_guard<std::recursive_mutex> guard(GetModuleMutex());
if (comp_unit.GetLineTable())
return true;
return ParseCompileUnitLineTable(comp_unit, 0);
}
bool SymbolFilePDB::ParseDebugMacros(CompileUnit &comp_unit) {
// PDB doesn't contain information about macros
return false;
}
bool SymbolFilePDB::ParseSupportFiles(
CompileUnit &comp_unit, lldb_private::FileSpecList &support_files) {
// In theory this is unnecessary work for us, because all of this information
// is easily (and quickly) accessible from DebugInfoPDB, so caching it a
// second time seems like a waste. Unfortunately, there's no good way around
// this short of a moderate refactor since SymbolVendor depends on being able
// to cache this list.
std::lock_guard<std::recursive_mutex> guard(GetModuleMutex());
auto compiland_up = GetPDBCompilandByUID(comp_unit.GetID());
if (!compiland_up)
return false;
auto files = m_session_up->getSourceFilesForCompiland(*compiland_up);
if (!files || files->getChildCount() == 0)
return false;
while (auto file = files->getNext()) {
FileSpec spec(file->getFileName(), FileSpec::Style::windows);
support_files.AppendIfUnique(spec);
}
return true;
}
bool SymbolFilePDB::ParseImportedModules(
const lldb_private::SymbolContext &sc,
std::vector<SourceModule> &imported_modules) {
// PDB does not yet support module debug info
return false;
}
static size_t ParseFunctionBlocksForPDBSymbol(
uint64_t func_file_vm_addr, const llvm::pdb::PDBSymbol *pdb_symbol,
lldb_private::Block *parent_block, bool is_top_parent) {
assert(pdb_symbol && parent_block);
size_t num_added = 0;
switch (pdb_symbol->getSymTag()) {
case PDB_SymType::Block:
case PDB_SymType::Function: {
Block *block = nullptr;
auto &raw_sym = pdb_symbol->getRawSymbol();
if (auto *pdb_func = llvm::dyn_cast<PDBSymbolFunc>(pdb_symbol)) {
if (pdb_func->hasNoInlineAttribute())
break;
if (is_top_parent)
block = parent_block;
else
break;
} else if (llvm::dyn_cast<PDBSymbolBlock>(pdb_symbol)) {
auto uid = pdb_symbol->getSymIndexId();
if (parent_block->FindBlockByID(uid))
break;
if (raw_sym.getVirtualAddress() < func_file_vm_addr)
break;
auto block_sp = std::make_shared<Block>(pdb_symbol->getSymIndexId());
parent_block->AddChild(block_sp);
block = block_sp.get();
} else
llvm_unreachable("Unexpected PDB symbol!");
block->AddRange(Block::Range(
raw_sym.getVirtualAddress() - func_file_vm_addr, raw_sym.getLength()));
block->FinalizeRanges();
++num_added;
auto results_up = pdb_symbol->findAllChildren();
if (!results_up)
break;
while (auto symbol_up = results_up->getNext()) {
num_added += ParseFunctionBlocksForPDBSymbol(
func_file_vm_addr, symbol_up.get(), block, false);
}
} break;
default:
break;
}
return num_added;
}
size_t SymbolFilePDB::ParseBlocksRecursive(Function &func) {
std::lock_guard<std::recursive_mutex> guard(GetModuleMutex());
size_t num_added = 0;
auto uid = func.GetID();
auto pdb_func_up = m_session_up->getConcreteSymbolById<PDBSymbolFunc>(uid);
if (!pdb_func_up)
return 0;
Block &parent_block = func.GetBlock(false);
num_added = ParseFunctionBlocksForPDBSymbol(
pdb_func_up->getVirtualAddress(), pdb_func_up.get(), &parent_block, true);
return num_added;
}
size_t SymbolFilePDB::ParseTypes(CompileUnit &comp_unit) {
std::lock_guard<std::recursive_mutex> guard(GetModuleMutex());
size_t num_added = 0;
auto compiland = GetPDBCompilandByUID(comp_unit.GetID());
if (!compiland)
return 0;
auto ParseTypesByTagFn = [&num_added, this](const PDBSymbol &raw_sym) {
std::unique_ptr<IPDBEnumSymbols> results;
PDB_SymType tags_to_search[] = {PDB_SymType::Enum, PDB_SymType::Typedef,
PDB_SymType::UDT};
for (auto tag : tags_to_search) {
results = raw_sym.findAllChildren(tag);
if (!results || results->getChildCount() == 0)
continue;
while (auto symbol = results->getNext()) {
switch (symbol->getSymTag()) {
case PDB_SymType::Enum:
case PDB_SymType::UDT:
case PDB_SymType::Typedef:
break;
default:
continue;
}
// This should cause the type to get cached and stored in the `m_types`
// lookup.
if (auto type = ResolveTypeUID(symbol->getSymIndexId())) {
// Resolve the type completely to avoid a completion
// (and so a list change, which causes an iterators invalidation)
// during a TypeList dumping
type->GetFullCompilerType();
++num_added;
}
}
}
};
ParseTypesByTagFn(*compiland);
// Also parse global types particularly coming from this compiland.
// Unfortunately, PDB has no compiland information for each global type. We
// have to parse them all. But ensure we only do this once.
static bool parse_all_global_types = false;
if (!parse_all_global_types) {
ParseTypesByTagFn(*m_global_scope_up);
parse_all_global_types = true;
}
return num_added;
}
size_t
SymbolFilePDB::ParseVariablesForContext(const lldb_private::SymbolContext &sc) {
std::lock_guard<std::recursive_mutex> guard(GetModuleMutex());
if (!sc.comp_unit)
return 0;
size_t num_added = 0;
if (sc.function) {
auto pdb_func = m_session_up->getConcreteSymbolById<PDBSymbolFunc>(
sc.function->GetID());
if (!pdb_func)
return 0;
num_added += ParseVariables(sc, *pdb_func);
sc.function->GetBlock(false).SetDidParseVariables(true, true);
} else if (sc.comp_unit) {
auto compiland = GetPDBCompilandByUID(sc.comp_unit->GetID());
if (!compiland)
return 0;
if (sc.comp_unit->GetVariableList(false))
return 0;
auto results = m_global_scope_up->findAllChildren<PDBSymbolData>();
if (results && results->getChildCount()) {
while (auto result = results->getNext()) {
auto cu_id = GetCompilandId(*result);
// FIXME: We are not able to determine variable's compile unit.
if (cu_id == 0)
continue;
if (cu_id == sc.comp_unit->GetID())
num_added += ParseVariables(sc, *result);
}
}
// FIXME: A `file static` or `global constant` variable appears both in
// compiland's children and global scope's children with unexpectedly
// different symbol's Id making it ambiguous.
// FIXME: 'local constant', for example, const char var[] = "abc", declared
// in a function scope, can't be found in PDB.
// Parse variables in this compiland.
num_added += ParseVariables(sc, *compiland);
}
return num_added;
}
lldb_private::Type *SymbolFilePDB::ResolveTypeUID(lldb::user_id_t type_uid) {
std::lock_guard<std::recursive_mutex> guard(GetModuleMutex());
auto find_result = m_types.find(type_uid);
if (find_result != m_types.end())
return find_result->second.get();
auto type_system_or_err =
GetTypeSystemForLanguage(lldb::eLanguageTypeC_plus_plus);
if (auto err = type_system_or_err.takeError()) {
LLDB_LOG_ERROR(lldb_private::GetLogIfAnyCategoriesSet(LIBLLDB_LOG_SYMBOLS),
std::move(err), "Unable to ResolveTypeUID");
return nullptr;
}
TypeSystemClang *clang_type_system =
llvm::dyn_cast_or_null<TypeSystemClang>(&type_system_or_err.get());
if (!clang_type_system)
return nullptr;
PDBASTParser *pdb = clang_type_system->GetPDBParser();
if (!pdb)
return nullptr;
auto pdb_type = m_session_up->getSymbolById(type_uid);
if (pdb_type == nullptr)
return nullptr;
lldb::TypeSP result = pdb->CreateLLDBTypeFromPDBType(*pdb_type);
if (result) {
m_types.insert(std::make_pair(type_uid, result));
GetTypeList().Insert(result);
}
return result.get();
}
llvm::Optional<SymbolFile::ArrayInfo> SymbolFilePDB::GetDynamicArrayInfoForUID(
lldb::user_id_t type_uid, const lldb_private::ExecutionContext *exe_ctx) {
return llvm::None;
}
bool SymbolFilePDB::CompleteType(lldb_private::CompilerType &compiler_type) {
std::lock_guard<std::recursive_mutex> guard(
GetObjectFile()->GetModule()->GetMutex());
auto type_system_or_err =
GetTypeSystemForLanguage(lldb::eLanguageTypeC_plus_plus);
if (auto err = type_system_or_err.takeError()) {
LLDB_LOG_ERROR(lldb_private::GetLogIfAnyCategoriesSet(LIBLLDB_LOG_SYMBOLS),
std::move(err), "Unable to get dynamic array info for UID");
return false;
}
TypeSystemClang *clang_ast_ctx =
llvm::dyn_cast_or_null<TypeSystemClang>(&type_system_or_err.get());
if (!clang_ast_ctx)
return false;
PDBASTParser *pdb = clang_ast_ctx->GetPDBParser();
if (!pdb)
return false;
return pdb->CompleteTypeFromPDB(compiler_type);
}
lldb_private::CompilerDecl SymbolFilePDB::GetDeclForUID(lldb::user_id_t uid) {
auto type_system_or_err =
GetTypeSystemForLanguage(lldb::eLanguageTypeC_plus_plus);
if (auto err = type_system_or_err.takeError()) {
LLDB_LOG_ERROR(lldb_private::GetLogIfAnyCategoriesSet(LIBLLDB_LOG_SYMBOLS),
std::move(err), "Unable to get decl for UID");
return CompilerDecl();
}
TypeSystemClang *clang_ast_ctx =
llvm::dyn_cast_or_null<TypeSystemClang>(&type_system_or_err.get());
if (!clang_ast_ctx)
return CompilerDecl();
PDBASTParser *pdb = clang_ast_ctx->GetPDBParser();
if (!pdb)
return CompilerDecl();
auto symbol = m_session_up->getSymbolById(uid);
if (!symbol)
return CompilerDecl();
auto decl = pdb->GetDeclForSymbol(*symbol);
if (!decl)
return CompilerDecl();
return clang_ast_ctx->GetCompilerDecl(decl);
}
lldb_private::CompilerDeclContext
SymbolFilePDB::GetDeclContextForUID(lldb::user_id_t uid) {
auto type_system_or_err =
GetTypeSystemForLanguage(lldb::eLanguageTypeC_plus_plus);
if (auto err = type_system_or_err.takeError()) {
LLDB_LOG_ERROR(lldb_private::GetLogIfAnyCategoriesSet(LIBLLDB_LOG_SYMBOLS),
std::move(err), "Unable to get DeclContext for UID");
return CompilerDeclContext();
}
TypeSystemClang *clang_ast_ctx =
llvm::dyn_cast_or_null<TypeSystemClang>(&type_system_or_err.get());
if (!clang_ast_ctx)
return CompilerDeclContext();
PDBASTParser *pdb = clang_ast_ctx->GetPDBParser();
if (!pdb)
return CompilerDeclContext();
auto symbol = m_session_up->getSymbolById(uid);
if (!symbol)
return CompilerDeclContext();
auto decl_context = pdb->GetDeclContextForSymbol(*symbol);
if (!decl_context)
return GetDeclContextContainingUID(uid);
return clang_ast_ctx->CreateDeclContext(decl_context);
}
lldb_private::CompilerDeclContext
SymbolFilePDB::GetDeclContextContainingUID(lldb::user_id_t uid) {
auto type_system_or_err =
GetTypeSystemForLanguage(lldb::eLanguageTypeC_plus_plus);
if (auto err = type_system_or_err.takeError()) {
LLDB_LOG_ERROR(lldb_private::GetLogIfAnyCategoriesSet(LIBLLDB_LOG_SYMBOLS),
std::move(err), "Unable to get DeclContext containing UID");
return CompilerDeclContext();
}
TypeSystemClang *clang_ast_ctx =
llvm::dyn_cast_or_null<TypeSystemClang>(&type_system_or_err.get());
if (!clang_ast_ctx)
return CompilerDeclContext();
PDBASTParser *pdb = clang_ast_ctx->GetPDBParser();
if (!pdb)
return CompilerDeclContext();
auto symbol = m_session_up->getSymbolById(uid);
if (!symbol)
return CompilerDeclContext();
auto decl_context = pdb->GetDeclContextContainingSymbol(*symbol);
assert(decl_context);
return clang_ast_ctx->CreateDeclContext(decl_context);
}
void SymbolFilePDB::ParseDeclsForContext(
lldb_private::CompilerDeclContext decl_ctx) {
auto type_system_or_err =
GetTypeSystemForLanguage(lldb::eLanguageTypeC_plus_plus);
if (auto err = type_system_or_err.takeError()) {
LLDB_LOG_ERROR(lldb_private::GetLogIfAnyCategoriesSet(LIBLLDB_LOG_SYMBOLS),
std::move(err), "Unable to parse decls for context");
return;
}
TypeSystemClang *clang_ast_ctx =
llvm::dyn_cast_or_null<TypeSystemClang>(&type_system_or_err.get());
if (!clang_ast_ctx)
return;
PDBASTParser *pdb = clang_ast_ctx->GetPDBParser();
if (!pdb)
return;
pdb->ParseDeclsForDeclContext(
static_cast<clang::DeclContext *>(decl_ctx.GetOpaqueDeclContext()));
}
uint32_t
SymbolFilePDB::ResolveSymbolContext(const lldb_private::Address &so_addr,
SymbolContextItem resolve_scope,
lldb_private::SymbolContext &sc) {
std::lock_guard<std::recursive_mutex> guard(GetModuleMutex());
uint32_t resolved_flags = 0;
if (resolve_scope & eSymbolContextCompUnit ||
resolve_scope & eSymbolContextVariable ||
resolve_scope & eSymbolContextFunction ||
resolve_scope & eSymbolContextBlock ||
resolve_scope & eSymbolContextLineEntry) {
auto cu_sp = GetCompileUnitContainsAddress(so_addr);
if (!cu_sp) {
if (resolved_flags & eSymbolContextVariable) {
// TODO: Resolve variables
}
return 0;
}
sc.comp_unit = cu_sp.get();
resolved_flags |= eSymbolContextCompUnit;
lldbassert(sc.module_sp == cu_sp->GetModule());
}
if (resolve_scope & eSymbolContextFunction ||
resolve_scope & eSymbolContextBlock) {
addr_t file_vm_addr = so_addr.GetFileAddress();
auto symbol_up =
m_session_up->findSymbolByAddress(file_vm_addr, PDB_SymType::Function);
if (symbol_up) {
auto *pdb_func = llvm::dyn_cast<PDBSymbolFunc>(symbol_up.get());
assert(pdb_func);
auto func_uid = pdb_func->getSymIndexId();
sc.function = sc.comp_unit->FindFunctionByUID(func_uid).get();
if (sc.function == nullptr)
sc.function =
ParseCompileUnitFunctionForPDBFunc(*pdb_func, *sc.comp_unit);
if (sc.function) {
resolved_flags |= eSymbolContextFunction;
if (resolve_scope & eSymbolContextBlock) {
auto block_symbol = m_session_up->findSymbolByAddress(
file_vm_addr, PDB_SymType::Block);
auto block_id = block_symbol ? block_symbol->getSymIndexId()
: sc.function->GetID();
sc.block = sc.function->GetBlock(true).FindBlockByID(block_id);
if (sc.block)
resolved_flags |= eSymbolContextBlock;
}
}
}
}
if (resolve_scope & eSymbolContextLineEntry) {
if (auto *line_table = sc.comp_unit->GetLineTable()) {
Address addr(so_addr);
if (line_table->FindLineEntryByAddress(addr, sc.line_entry))
resolved_flags |= eSymbolContextLineEntry;
}
}
return resolved_flags;
}
uint32_t SymbolFilePDB::ResolveSymbolContext(
const lldb_private::SourceLocationSpec &src_location_spec,
SymbolContextItem resolve_scope, lldb_private::SymbolContextList &sc_list) {
std::lock_guard<std::recursive_mutex> guard(GetModuleMutex());
const size_t old_size = sc_list.GetSize();
const FileSpec &file_spec = src_location_spec.GetFileSpec();
const uint32_t line = src_location_spec.GetLine().getValueOr(0);
if (resolve_scope & lldb::eSymbolContextCompUnit) {
// Locate all compilation units with line numbers referencing the specified
// file. For example, if `file_spec` is <vector>, then this should return
// all source files and header files that reference <vector>, either
// directly or indirectly.
auto compilands = m_session_up->findCompilandsForSourceFile(
file_spec.GetPath(), PDB_NameSearchFlags::NS_CaseInsensitive);
if (!compilands)
return 0;
// For each one, either find its previously parsed data or parse it afresh
// and add it to the symbol context list.
while (auto compiland = compilands->getNext()) {
// If we're not checking inlines, then don't add line information for
// this file unless the FileSpec matches. For inline functions, we don't
// have to match the FileSpec since they could be defined in headers
// other than file specified in FileSpec.
if (!src_location_spec.GetCheckInlines()) {
std::string source_file = compiland->getSourceFileFullPath();
if (source_file.empty())
continue;
FileSpec this_spec(source_file, FileSpec::Style::windows);
bool need_full_match = !file_spec.GetDirectory().IsEmpty();
if (FileSpec::Compare(file_spec, this_spec, need_full_match) != 0)
continue;
}
SymbolContext sc;
auto cu = ParseCompileUnitForUID(compiland->getSymIndexId());
if (!cu)
continue;
sc.comp_unit = cu.get();
sc.module_sp = cu->GetModule();
// If we were asked to resolve line entries, add all entries to the line
// table that match the requested line (or all lines if `line` == 0).
if (resolve_scope & (eSymbolContextFunction | eSymbolContextBlock |
eSymbolContextLineEntry)) {
bool has_line_table = ParseCompileUnitLineTable(*sc.comp_unit, line);
if ((resolve_scope & eSymbolContextLineEntry) && !has_line_table) {
// The query asks for line entries, but we can't get them for the
// compile unit. This is not normal for `line` = 0. So just assert
// it.
assert(line && "Couldn't get all line entries!\n");
// Current compiland does not have the requested line. Search next.
continue;
}
if (resolve_scope & (eSymbolContextFunction | eSymbolContextBlock)) {
if (!has_line_table)
continue;
auto *line_table = sc.comp_unit->GetLineTable();
lldbassert(line_table);
uint32_t num_line_entries = line_table->GetSize();
// Skip the terminal line entry.
--num_line_entries;
// If `line `!= 0, see if we can resolve function for each line entry
// in the line table.
for (uint32_t line_idx = 0; line && line_idx < num_line_entries;
++line_idx) {
if (!line_table->GetLineEntryAtIndex(line_idx, sc.line_entry))
continue;
auto file_vm_addr =
sc.line_entry.range.GetBaseAddress().GetFileAddress();
if (file_vm_addr == LLDB_INVALID_ADDRESS || file_vm_addr == 0)
continue;
auto symbol_up = m_session_up->findSymbolByAddress(
file_vm_addr, PDB_SymType::Function);
if (symbol_up) {
auto func_uid = symbol_up->getSymIndexId();
sc.function = sc.comp_unit->FindFunctionByUID(func_uid).get();
if (sc.function == nullptr) {
auto pdb_func = llvm::dyn_cast<PDBSymbolFunc>(symbol_up.get());
assert(pdb_func);
sc.function = ParseCompileUnitFunctionForPDBFunc(*pdb_func,
*sc.comp_unit);
}
if (sc.function && (resolve_scope & eSymbolContextBlock)) {
Block &block = sc.function->GetBlock(true);
sc.block = block.FindBlockByID(sc.function->GetID());
}
}
sc_list.Append(sc);
}
} else if (has_line_table) {
// We can parse line table for the compile unit. But no query to
// resolve function or block. We append `sc` to the list anyway.
sc_list.Append(sc);
}
} else {
// No query for line entry, function or block. But we have a valid
// compile unit, append `sc` to the list.
sc_list.Append(sc);
}
}
}
return sc_list.GetSize() - old_size;
}
std::string SymbolFilePDB::GetMangledForPDBData(const PDBSymbolData &pdb_data) {
// Cache public names at first
if (m_public_names.empty())
if (auto result_up =
m_global_scope_up->findAllChildren(PDB_SymType::PublicSymbol))
while (auto symbol_up = result_up->getNext())
if (auto addr = symbol_up->getRawSymbol().getVirtualAddress())
m_public_names[addr] = symbol_up->getRawSymbol().getName();
// Look up the name in the cache
return m_public_names.lookup(pdb_data.getVirtualAddress());
}
VariableSP SymbolFilePDB::ParseVariableForPDBData(
const lldb_private::SymbolContext &sc,
const llvm::pdb::PDBSymbolData &pdb_data) {
VariableSP var_sp;
uint32_t var_uid = pdb_data.getSymIndexId();
auto result = m_variables.find(var_uid);
if (result != m_variables.end())
return result->second;
ValueType scope = eValueTypeInvalid;
bool is_static_member = false;
bool is_external = false;
bool is_artificial = false;
switch (pdb_data.getDataKind()) {
case PDB_DataKind::Global:
scope = eValueTypeVariableGlobal;
is_external = true;
break;
case PDB_DataKind::Local:
scope = eValueTypeVariableLocal;
break;
case PDB_DataKind::FileStatic:
scope = eValueTypeVariableStatic;
break;
case PDB_DataKind::StaticMember:
is_static_member = true;
scope = eValueTypeVariableStatic;
break;
case PDB_DataKind::Member:
scope = eValueTypeVariableStatic;
break;
case PDB_DataKind::Param:
scope = eValueTypeVariableArgument;
break;
case PDB_DataKind::Constant:
scope = eValueTypeConstResult;
break;
default:
break;
}
switch (pdb_data.getLocationType()) {
case PDB_LocType::TLS:
scope = eValueTypeVariableThreadLocal;
break;
case PDB_LocType::RegRel: {
// It is a `this` pointer.
if (pdb_data.getDataKind() == PDB_DataKind::ObjectPtr) {
scope = eValueTypeVariableArgument;
is_artificial = true;
}
} break;
default:
break;
}
Declaration decl;
if (!is_artificial && !pdb_data.isCompilerGenerated()) {
if (auto lines = pdb_data.getLineNumbers()) {
if (auto first_line = lines->getNext()) {
uint32_t src_file_id = first_line->getSourceFileId();
auto src_file = m_session_up->getSourceFileById(src_file_id);
if (src_file) {
FileSpec spec(src_file->getFileName());
decl.SetFile(spec);
decl.SetColumn(first_line->getColumnNumber());
decl.SetLine(first_line->getLineNumber());
}
}
}
}
Variable::RangeList ranges;
SymbolContextScope *context_scope = sc.comp_unit;
if (scope == eValueTypeVariableLocal || scope == eValueTypeVariableArgument) {
if (sc.function) {
Block &function_block = sc.function->GetBlock(true);
Block *block =
function_block.FindBlockByID(pdb_data.getLexicalParentId());
if (!block)
block = &function_block;
context_scope = block;
for (size_t i = 0, num_ranges = block->GetNumRanges(); i < num_ranges;
++i) {
AddressRange range;
if (!block->GetRangeAtIndex(i, range))
continue;
ranges.Append(range.GetBaseAddress().GetFileAddress(),
range.GetByteSize());
}
}
}
SymbolFileTypeSP type_sp =
std::make_shared<SymbolFileType>(*this, pdb_data.getTypeId());
auto var_name = pdb_data.getName();
auto mangled = GetMangledForPDBData(pdb_data);
auto mangled_cstr = mangled.empty() ? nullptr : mangled.c_str();
bool is_constant;
DWARFExpression location = ConvertPDBLocationToDWARFExpression(
GetObjectFile()->GetModule(), pdb_data, ranges, is_constant);
var_sp = std::make_shared<Variable>(
var_uid, var_name.c_str(), mangled_cstr, type_sp, scope, context_scope,
ranges, &decl, location, is_external, is_artificial, is_constant,
is_static_member);
m_variables.insert(std::make_pair(var_uid, var_sp));
return var_sp;
}
size_t
SymbolFilePDB::ParseVariables(const lldb_private::SymbolContext &sc,
const llvm::pdb::PDBSymbol &pdb_symbol,
lldb_private::VariableList *variable_list) {
size_t num_added = 0;
if (auto pdb_data = llvm::dyn_cast<PDBSymbolData>(&pdb_symbol)) {
VariableListSP local_variable_list_sp;
auto result = m_variables.find(pdb_data->getSymIndexId());
if (result != m_variables.end()) {
if (variable_list)
variable_list->AddVariableIfUnique(result->second);
} else {
// Prepare right VariableList for this variable.
if (auto lexical_parent = pdb_data->getLexicalParent()) {
switch (lexical_parent->getSymTag()) {
case PDB_SymType::Exe:
assert(sc.comp_unit);
LLVM_FALLTHROUGH;
case PDB_SymType::Compiland: {
if (sc.comp_unit) {
local_variable_list_sp = sc.comp_unit->GetVariableList(false);
if (!local_variable_list_sp) {
local_variable_list_sp = std::make_shared<VariableList>();
sc.comp_unit->SetVariableList(local_variable_list_sp);
}
}
} break;
case PDB_SymType::Block:
case PDB_SymType::Function: {
if (sc.function) {
Block *block = sc.function->GetBlock(true).FindBlockByID(
lexical_parent->getSymIndexId());
if (block) {
local_variable_list_sp = block->GetBlockVariableList(false);
if (!local_variable_list_sp) {
local_variable_list_sp = std::make_shared<VariableList>();
block->SetVariableList(local_variable_list_sp);
}
}
}
} break;
default:
break;
}
}
if (local_variable_list_sp) {
if (auto var_sp = ParseVariableForPDBData(sc, *pdb_data)) {
local_variable_list_sp->AddVariableIfUnique(var_sp);
if (variable_list)
variable_list->AddVariableIfUnique(var_sp);
++num_added;
PDBASTParser *ast = GetPDBAstParser();
if (ast)
ast->GetDeclForSymbol(*pdb_data);
}
}
}
}
if (auto results = pdb_symbol.findAllChildren()) {
while (auto result = results->getNext())
num_added += ParseVariables(sc, *result, variable_list);
}
return num_added;
}
void SymbolFilePDB::FindGlobalVariables(
lldb_private::ConstString name, const CompilerDeclContext &parent_decl_ctx,
uint32_t max_matches, lldb_private::VariableList &variables) {
std::lock_guard<std::recursive_mutex> guard(GetModuleMutex());
if (!DeclContextMatchesThisSymbolFile(parent_decl_ctx))
return;
if (name.IsEmpty())
return;
auto results = m_global_scope_up->findAllChildren<PDBSymbolData>();
if (!results)
return;
uint32_t matches = 0;
size_t old_size = variables.GetSize();
while (auto result = results->getNext()) {
auto pdb_data = llvm::dyn_cast<PDBSymbolData>(result.get());
if (max_matches > 0 && matches >= max_matches)
break;
SymbolContext sc;
sc.module_sp = m_objfile_sp->GetModule();
lldbassert(sc.module_sp.get());
if (!name.GetStringRef().equals(
MSVCUndecoratedNameParser::DropScope(pdb_data->getName())))
continue;
sc.comp_unit = ParseCompileUnitForUID(GetCompilandId(*pdb_data)).get();
// FIXME: We are not able to determine the compile unit.
if (sc.comp_unit == nullptr)
continue;
if (parent_decl_ctx.IsValid() &&
GetDeclContextContainingUID(result->getSymIndexId()) != parent_decl_ctx)
continue;
ParseVariables(sc, *pdb_data, &variables);
matches = variables.GetSize() - old_size;
}
}
void SymbolFilePDB::FindGlobalVariables(
const lldb_private::RegularExpression &regex, uint32_t max_matches,
lldb_private::VariableList &variables) {
std::lock_guard<std::recursive_mutex> guard(GetModuleMutex());
if (!regex.IsValid())
return;
auto results = m_global_scope_up->findAllChildren<PDBSymbolData>();
if (!results)
return;
uint32_t matches = 0;
size_t old_size = variables.GetSize();
while (auto pdb_data = results->getNext()) {
if (max_matches > 0 && matches >= max_matches)
break;
auto var_name = pdb_data->getName();
if (var_name.empty())
continue;
if (!regex.Execute(var_name))
continue;
SymbolContext sc;
sc.module_sp = m_objfile_sp->GetModule();
lldbassert(sc.module_sp.get());
sc.comp_unit = ParseCompileUnitForUID(GetCompilandId(*pdb_data)).get();
// FIXME: We are not able to determine the compile unit.
if (sc.comp_unit == nullptr)
continue;
ParseVariables(sc, *pdb_data, &variables);
matches = variables.GetSize() - old_size;
}
}
bool SymbolFilePDB::ResolveFunction(const llvm::pdb::PDBSymbolFunc &pdb_func,
bool include_inlines,
lldb_private::SymbolContextList &sc_list) {
lldb_private::SymbolContext sc;
sc.comp_unit = ParseCompileUnitForUID(pdb_func.getCompilandId()).get();
if (!sc.comp_unit)
return false;
sc.module_sp = sc.comp_unit->GetModule();
sc.function = ParseCompileUnitFunctionForPDBFunc(pdb_func, *sc.comp_unit);
if (!sc.function)
return false;
sc_list.Append(sc);
return true;
}
bool SymbolFilePDB::ResolveFunction(uint32_t uid, bool include_inlines,
lldb_private::SymbolContextList &sc_list) {
auto pdb_func_up = m_session_up->getConcreteSymbolById<PDBSymbolFunc>(uid);
if (!pdb_func_up && !(include_inlines && pdb_func_up->hasInlineAttribute()))
return false;
return ResolveFunction(*pdb_func_up, include_inlines, sc_list);
}
void SymbolFilePDB::CacheFunctionNames() {
if (!m_func_full_names.IsEmpty())
return;
std::map<uint64_t, uint32_t> addr_ids;
if (auto results_up = m_global_scope_up->findAllChildren<PDBSymbolFunc>()) {
while (auto pdb_func_up = results_up->getNext()) {
if (pdb_func_up->isCompilerGenerated())
continue;
auto name = pdb_func_up->getName();
auto demangled_name = pdb_func_up->getUndecoratedName();
if (name.empty() && demangled_name.empty())
continue;
auto uid = pdb_func_up->getSymIndexId();
if (!demangled_name.empty() && pdb_func_up->getVirtualAddress())
addr_ids.insert(std::make_pair(pdb_func_up->getVirtualAddress(), uid));
if (auto parent = pdb_func_up->getClassParent()) {
// PDB have symbols for class/struct methods or static methods in Enum
// Class. We won't bother to check if the parent is UDT or Enum here.
m_func_method_names.Append(ConstString(name), uid);
// To search a method name, like NS::Class:MemberFunc, LLDB searches
// its base name, i.e. MemberFunc by default. Since PDBSymbolFunc does
// not have information of this, we extract base names and cache them
// by our own effort.
llvm::StringRef basename = MSVCUndecoratedNameParser::DropScope(name);
if (!basename.empty())
m_func_base_names.Append(ConstString(basename), uid);
else {
m_func_base_names.Append(ConstString(name), uid);
}
if (!demangled_name.empty())
m_func_full_names.Append(ConstString(demangled_name), uid);
} else {
// Handle not-method symbols.
// The function name might contain namespace, or its lexical scope.
llvm::StringRef basename = MSVCUndecoratedNameParser::DropScope(name);
if (!basename.empty())
m_func_base_names.Append(ConstString(basename), uid);
else
m_func_base_names.Append(ConstString(name), uid);
if (name == "main") {
m_func_full_names.Append(ConstString(name), uid);
if (!demangled_name.empty() && name != demangled_name) {
m_func_full_names.Append(ConstString(demangled_name), uid);
m_func_base_names.Append(ConstString(demangled_name), uid);
}
} else if (!demangled_name.empty()) {
m_func_full_names.Append(ConstString(demangled_name), uid);
} else {
m_func_full_names.Append(ConstString(name), uid);
}
}
}
}
if (auto results_up =
m_global_scope_up->findAllChildren<PDBSymbolPublicSymbol>()) {
while (auto pub_sym_up = results_up->getNext()) {
if (!pub_sym_up->isFunction())
continue;
auto name = pub_sym_up->getName();
if (name.empty())
continue;
if (CPlusPlusLanguage::IsCPPMangledName(name.c_str())) {
auto vm_addr = pub_sym_up->getVirtualAddress();
// PDB public symbol has mangled name for its associated function.
if (vm_addr && addr_ids.find(vm_addr) != addr_ids.end()) {
// Cache mangled name.
m_func_full_names.Append(ConstString(name), addr_ids[vm_addr]);
}
}
}
}
// Sort them before value searching is working properly
m_func_full_names.Sort();
m_func_full_names.SizeToFit();
m_func_method_names.Sort();
m_func_method_names.SizeToFit();
m_func_base_names.Sort();
m_func_base_names.SizeToFit();
}
void SymbolFilePDB::FindFunctions(
lldb_private::ConstString name,
const lldb_private::CompilerDeclContext &parent_decl_ctx,
FunctionNameType name_type_mask, bool include_inlines,
lldb_private::SymbolContextList &sc_list) {
std::lock_guard<std::recursive_mutex> guard(GetModuleMutex());
lldbassert((name_type_mask & eFunctionNameTypeAuto) == 0);
if (name_type_mask == eFunctionNameTypeNone)
return;
if (!DeclContextMatchesThisSymbolFile(parent_decl_ctx))
return;
if (name.IsEmpty())
return;
if (name_type_mask & eFunctionNameTypeFull ||
name_type_mask & eFunctionNameTypeBase ||
name_type_mask & eFunctionNameTypeMethod) {
CacheFunctionNames();
std::set<uint32_t> resolved_ids;
auto ResolveFn = [this, &name, parent_decl_ctx, include_inlines, &sc_list,
&resolved_ids](UniqueCStringMap<uint32_t> &Names) {
std::vector<uint32_t> ids;
if (!Names.GetValues(name, ids))
return;
for (uint32_t id : ids) {
if (resolved_ids.find(id) != resolved_ids.end())
continue;
if (parent_decl_ctx.IsValid() &&
GetDeclContextContainingUID(id) != parent_decl_ctx)
continue;
if (ResolveFunction(id, include_inlines, sc_list))
resolved_ids.insert(id);
}
};
if (name_type_mask & eFunctionNameTypeFull) {
ResolveFn(m_func_full_names);
ResolveFn(m_func_base_names);
ResolveFn(m_func_method_names);
}
if (name_type_mask & eFunctionNameTypeBase)
ResolveFn(m_func_base_names);
if (name_type_mask & eFunctionNameTypeMethod)
ResolveFn(m_func_method_names);
}
}
void SymbolFilePDB::FindFunctions(const lldb_private::RegularExpression &regex,
bool include_inlines,
lldb_private::SymbolContextList &sc_list) {
std::lock_guard<std::recursive_mutex> guard(GetModuleMutex());
if (!regex.IsValid())
return;
CacheFunctionNames();
std::set<uint32_t> resolved_ids;
auto ResolveFn = [&regex, include_inlines, &sc_list, &resolved_ids,
this](UniqueCStringMap<uint32_t> &Names) {
std::vector<uint32_t> ids;
if (Names.GetValues(regex, ids)) {
for (auto id : ids) {
if (resolved_ids.find(id) == resolved_ids.end())
if (ResolveFunction(id, include_inlines, sc_list))
resolved_ids.insert(id);
}
}
};
ResolveFn(m_func_full_names);
ResolveFn(m_func_base_names);
}
void SymbolFilePDB::GetMangledNamesForFunction(
const std::string &scope_qualified_name,
std::vector<lldb_private::ConstString> &mangled_names) {}
void SymbolFilePDB::AddSymbols(lldb_private::Symtab &symtab) {
std::set<lldb::addr_t> sym_addresses;
for (size_t i = 0; i < symtab.GetNumSymbols(); i++)
sym_addresses.insert(symtab.SymbolAtIndex(i)->GetFileAddress());
auto results = m_global_scope_up->findAllChildren<PDBSymbolPublicSymbol>();
if (!results)
return;
auto section_list = m_objfile_sp->GetSectionList();
if (!section_list)
return;
while (auto pub_symbol = results->getNext()) {
auto section_id = pub_symbol->getAddressSection();
auto section = section_list->FindSectionByID(section_id);
if (!section)
continue;
auto offset = pub_symbol->getAddressOffset();
auto file_addr = section->GetFileAddress() + offset;
if (sym_addresses.find(file_addr) != sym_addresses.end())
continue;
sym_addresses.insert(file_addr);
auto size = pub_symbol->getLength();
symtab.AddSymbol(
Symbol(pub_symbol->getSymIndexId(), // symID
pub_symbol->getName().c_str(), // name
pub_symbol->isCode() ? eSymbolTypeCode : eSymbolTypeData, // type
true, // external
false, // is_debug
false, // is_trampoline
false, // is_artificial
section, // section_sp
offset, // value
size, // size
size != 0, // size_is_valid
false, // contains_linker_annotations
0 // flags
));
}
symtab.Finalize();
}
void SymbolFilePDB::FindTypes(
lldb_private::ConstString name, const CompilerDeclContext &parent_decl_ctx,
uint32_t max_matches,
llvm::DenseSet<lldb_private::SymbolFile *> &searched_symbol_files,
lldb_private::TypeMap &types) {
std::lock_guard<std::recursive_mutex> guard(GetModuleMutex());
if (!name)
return;
if (!DeclContextMatchesThisSymbolFile(parent_decl_ctx))
return;
searched_symbol_files.clear();
searched_symbol_files.insert(this);
// There is an assumption 'name' is not a regex
FindTypesByName(name.GetStringRef(), parent_decl_ctx, max_matches, types);
}
void SymbolFilePDB::DumpClangAST(Stream &s) {
auto type_system_or_err =
GetTypeSystemForLanguage(lldb::eLanguageTypeC_plus_plus);
if (auto err = type_system_or_err.takeError()) {
LLDB_LOG_ERROR(lldb_private::GetLogIfAnyCategoriesSet(LIBLLDB_LOG_SYMBOLS),
std::move(err), "Unable to dump ClangAST");
return;
}
auto *clang_type_system =
llvm::dyn_cast_or_null<TypeSystemClang>(&type_system_or_err.get());
if (!clang_type_system)
return;
clang_type_system->Dump(s.AsRawOstream());
}
void SymbolFilePDB::FindTypesByRegex(
const lldb_private::RegularExpression &regex, uint32_t max_matches,
lldb_private::TypeMap &types) {
// When searching by regex, we need to go out of our way to limit the search
// space as much as possible since this searches EVERYTHING in the PDB,
// manually doing regex comparisons. PDB library isn't optimized for regex
// searches or searches across multiple symbol types at the same time, so the
// best we can do is to search enums, then typedefs, then classes one by one,
// and do a regex comparison against each of them.
PDB_SymType tags_to_search[] = {PDB_SymType::Enum, PDB_SymType::Typedef,
PDB_SymType::UDT};
std::unique_ptr<IPDBEnumSymbols> results;
uint32_t matches = 0;
for (auto tag : tags_to_search) {
results = m_global_scope_up->findAllChildren(tag);
if (!results)
continue;
while (auto result = results->getNext()) {
if (max_matches > 0 && matches >= max_matches)
break;
std::string type_name;
if (auto enum_type = llvm::dyn_cast<PDBSymbolTypeEnum>(result.get()))
type_name = enum_type->getName();
else if (auto typedef_type =
llvm::dyn_cast<PDBSymbolTypeTypedef>(result.get()))
type_name = typedef_type->getName();
else if (auto class_type = llvm::dyn_cast<PDBSymbolTypeUDT>(result.get()))
type_name = class_type->getName();
else {
// We're looking only for types that have names. Skip symbols, as well
// as unnamed types such as arrays, pointers, etc.
continue;
}
if (!regex.Execute(type_name))
continue;
// This should cause the type to get cached and stored in the `m_types`
// lookup.
if (!ResolveTypeUID(result->getSymIndexId()))
continue;
auto iter = m_types.find(result->getSymIndexId());
if (iter == m_types.end())
continue;
types.Insert(iter->second);
++matches;
}
}
}
void SymbolFilePDB::FindTypesByName(
llvm::StringRef name,
const lldb_private::CompilerDeclContext &parent_decl_ctx,
uint32_t max_matches, lldb_private::TypeMap &types) {
std::unique_ptr<IPDBEnumSymbols> results;
if (name.empty())
return;
results = m_global_scope_up->findAllChildren(PDB_SymType::None);
if (!results)
return;
uint32_t matches = 0;
while (auto result = results->getNext()) {
if (max_matches > 0 && matches >= max_matches)
break;
if (MSVCUndecoratedNameParser::DropScope(
result->getRawSymbol().getName()) != name)
continue;
switch (result->getSymTag()) {
case PDB_SymType::Enum:
case PDB_SymType::UDT:
case PDB_SymType::Typedef:
break;
default:
// We're looking only for types that have names. Skip symbols, as well
// as unnamed types such as arrays, pointers, etc.
continue;
}
// This should cause the type to get cached and stored in the `m_types`
// lookup.
if (!ResolveTypeUID(result->getSymIndexId()))
continue;
if (parent_decl_ctx.IsValid() &&
GetDeclContextContainingUID(result->getSymIndexId()) != parent_decl_ctx)
continue;
auto iter = m_types.find(result->getSymIndexId());
if (iter == m_types.end())
continue;
types.Insert(iter->second);
++matches;
}
}
void SymbolFilePDB::FindTypes(
llvm::ArrayRef<CompilerContext> pattern, LanguageSet languages,
llvm::DenseSet<SymbolFile *> &searched_symbol_files,
lldb_private::TypeMap &types) {}
void SymbolFilePDB::GetTypesForPDBSymbol(const llvm::pdb::PDBSymbol &pdb_symbol,
uint32_t type_mask,
TypeCollection &type_collection) {
bool can_parse = false;
switch (pdb_symbol.getSymTag()) {
case PDB_SymType::ArrayType:
can_parse = ((type_mask & eTypeClassArray) != 0);
break;
case PDB_SymType::BuiltinType:
can_parse = ((type_mask & eTypeClassBuiltin) != 0);
break;
case PDB_SymType::Enum:
can_parse = ((type_mask & eTypeClassEnumeration) != 0);
break;
case PDB_SymType::Function:
case PDB_SymType::FunctionSig:
can_parse = ((type_mask & eTypeClassFunction) != 0);
break;
case PDB_SymType::PointerType:
can_parse = ((type_mask & (eTypeClassPointer | eTypeClassBlockPointer |
eTypeClassMemberPointer)) != 0);
break;
case PDB_SymType::Typedef:
can_parse = ((type_mask & eTypeClassTypedef) != 0);
break;
case PDB_SymType::UDT: {
auto *udt = llvm::dyn_cast<PDBSymbolTypeUDT>(&pdb_symbol);
assert(udt);
can_parse = (udt->getUdtKind() != PDB_UdtType::Interface &&
((type_mask & (eTypeClassClass | eTypeClassStruct |
eTypeClassUnion)) != 0));
} break;
default:
break;
}
if (can_parse) {
if (auto *type = ResolveTypeUID(pdb_symbol.getSymIndexId())) {
auto result =
std::find(type_collection.begin(), type_collection.end(), type);
if (result == type_collection.end())
type_collection.push_back(type);
}
}
auto results_up = pdb_symbol.findAllChildren();
while (auto symbol_up = results_up->getNext())
GetTypesForPDBSymbol(*symbol_up, type_mask, type_collection);
}
void SymbolFilePDB::GetTypes(lldb_private::SymbolContextScope *sc_scope,
TypeClass type_mask,
lldb_private::TypeList &type_list) {
std::lock_guard<std::recursive_mutex> guard(GetModuleMutex());
TypeCollection type_collection;
CompileUnit *cu =
sc_scope ? sc_scope->CalculateSymbolContextCompileUnit() : nullptr;
if (cu) {
auto compiland_up = GetPDBCompilandByUID(cu->GetID());
if (!compiland_up)
return;
GetTypesForPDBSymbol(*compiland_up, type_mask, type_collection);
} else {
for (uint32_t cu_idx = 0; cu_idx < GetNumCompileUnits(); ++cu_idx) {
auto cu_sp = ParseCompileUnitAtIndex(cu_idx);
if (cu_sp) {
if (auto compiland_up = GetPDBCompilandByUID(cu_sp->GetID()))
GetTypesForPDBSymbol(*compiland_up, type_mask, type_collection);
}
}
}
for (auto type : type_collection) {
type->GetForwardCompilerType();
type_list.Insert(type->shared_from_this());
}
}
llvm::Expected<lldb_private::TypeSystem &>
SymbolFilePDB::GetTypeSystemForLanguage(lldb::LanguageType language) {
auto type_system_or_err =
m_objfile_sp->GetModule()->GetTypeSystemForLanguage(language);
if (type_system_or_err) {
type_system_or_err->SetSymbolFile(this);
}
return type_system_or_err;
}
PDBASTParser *SymbolFilePDB::GetPDBAstParser() {
auto type_system_or_err =
GetTypeSystemForLanguage(lldb::eLanguageTypeC_plus_plus);
if (auto err = type_system_or_err.takeError()) {
LLDB_LOG_ERROR(lldb_private::GetLogIfAnyCategoriesSet(LIBLLDB_LOG_SYMBOLS),
std::move(err), "Unable to get PDB AST parser");
return nullptr;
}
auto *clang_type_system =
llvm::dyn_cast_or_null<TypeSystemClang>(&type_system_or_err.get());
if (!clang_type_system)
return nullptr;
return clang_type_system->GetPDBParser();
}
lldb_private::CompilerDeclContext
SymbolFilePDB::FindNamespace(lldb_private::ConstString name,
const CompilerDeclContext &parent_decl_ctx) {
std::lock_guard<std::recursive_mutex> guard(GetModuleMutex());
auto type_system_or_err =
GetTypeSystemForLanguage(lldb::eLanguageTypeC_plus_plus);
if (auto err = type_system_or_err.takeError()) {
LLDB_LOG_ERROR(lldb_private::GetLogIfAnyCategoriesSet(LIBLLDB_LOG_SYMBOLS),
std::move(err), "Unable to find namespace {}",
name.AsCString());
return CompilerDeclContext();
}
auto *clang_type_system =
llvm::dyn_cast_or_null<TypeSystemClang>(&type_system_or_err.get());
if (!clang_type_system)
return CompilerDeclContext();
PDBASTParser *pdb = clang_type_system->GetPDBParser();
if (!pdb)
return CompilerDeclContext();
clang::DeclContext *decl_context = nullptr;
if (parent_decl_ctx)
decl_context = static_cast<clang::DeclContext *>(
parent_decl_ctx.GetOpaqueDeclContext());
auto namespace_decl =
pdb->FindNamespaceDecl(decl_context, name.GetStringRef());
if (!namespace_decl)
return CompilerDeclContext();
return clang_type_system->CreateDeclContext(namespace_decl);
}
IPDBSession &SymbolFilePDB::GetPDBSession() { return *m_session_up; }
const IPDBSession &SymbolFilePDB::GetPDBSession() const {
return *m_session_up;
}
lldb::CompUnitSP SymbolFilePDB::ParseCompileUnitForUID(uint32_t id,
uint32_t index) {
auto found_cu = m_comp_units.find(id);
if (found_cu != m_comp_units.end())
return found_cu->second;
auto compiland_up = GetPDBCompilandByUID(id);
if (!compiland_up)
return CompUnitSP();
lldb::LanguageType lang;
auto details = compiland_up->findOneChild<PDBSymbolCompilandDetails>();
if (!details)
lang = lldb::eLanguageTypeC_plus_plus;
else
lang = TranslateLanguage(details->getLanguage());
if (lang == lldb::LanguageType::eLanguageTypeUnknown)
return CompUnitSP();
std::string path = compiland_up->getSourceFileFullPath();
if (path.empty())
return CompUnitSP();
// Don't support optimized code for now, DebugInfoPDB does not return this
// information.
LazyBool optimized = eLazyBoolNo;
auto cu_sp = std::make_shared<CompileUnit>(m_objfile_sp->GetModule(), nullptr,
path.c_str(), id, lang, optimized);
if (!cu_sp)
return CompUnitSP();
m_comp_units.insert(std::make_pair(id, cu_sp));
if (index == UINT32_MAX)
GetCompileUnitIndex(*compiland_up, index);
lldbassert(index != UINT32_MAX);
SetCompileUnitAtIndex(index, cu_sp);
return cu_sp;
}
bool SymbolFilePDB::ParseCompileUnitLineTable(CompileUnit &comp_unit,
uint32_t match_line) {
auto compiland_up = GetPDBCompilandByUID(comp_unit.GetID());
if (!compiland_up)
return false;
// LineEntry needs the *index* of the file into the list of support files
// returned by ParseCompileUnitSupportFiles. But the underlying SDK gives us
// a globally unique idenfitifier in the namespace of the PDB. So, we have
// to do a mapping so that we can hand out indices.
llvm::DenseMap<uint32_t, uint32_t> index_map;
BuildSupportFileIdToSupportFileIndexMap(*compiland_up, index_map);
auto line_table = std::make_unique<LineTable>(&comp_unit);
// Find contributions to `compiland` from all source and header files.
auto files = m_session_up->getSourceFilesForCompiland(*compiland_up);
if (!files)
return false;
// For each source and header file, create a LineSequence for contributions
// to the compiland from that file, and add the sequence.
while (auto file = files->getNext()) {
std::unique_ptr<LineSequence> sequence(
line_table->CreateLineSequenceContainer());
auto lines = m_session_up->findLineNumbers(*compiland_up, *file);
if (!lines)
continue;
int entry_count = lines->getChildCount();
uint64_t prev_addr;
uint32_t prev_length;
uint32_t prev_line;
uint32_t prev_source_idx;
for (int i = 0; i < entry_count; ++i) {
auto line = lines->getChildAtIndex(i);
uint64_t lno = line->getLineNumber();
uint64_t addr = line->getVirtualAddress();
uint32_t length = line->getLength();
uint32_t source_id = line->getSourceFileId();
uint32_t col = line->getColumnNumber();
uint32_t source_idx = index_map[source_id];
// There was a gap between the current entry and the previous entry if
// the addresses don't perfectly line up.
bool is_gap = (i > 0) && (prev_addr + prev_length < addr);
// Before inserting the current entry, insert a terminal entry at the end
// of the previous entry's address range if the current entry resulted in
// a gap from the previous entry.
if (is_gap && ShouldAddLine(match_line, prev_line, prev_length)) {
line_table->AppendLineEntryToSequence(
sequence.get(), prev_addr + prev_length, prev_line, 0,
prev_source_idx, false, false, false, false, true);
line_table->InsertSequence(sequence.get());
sequence = line_table->CreateLineSequenceContainer();
}
if (ShouldAddLine(match_line, lno, length)) {
bool is_statement = line->isStatement();
bool is_prologue = false;
bool is_epilogue = false;
auto func =
m_session_up->findSymbolByAddress(addr, PDB_SymType::Function);
if (func) {
auto prologue = func->findOneChild<PDBSymbolFuncDebugStart>();
if (prologue)
is_prologue = (addr == prologue->getVirtualAddress());
auto epilogue = func->findOneChild<PDBSymbolFuncDebugEnd>();
if (epilogue)
is_epilogue = (addr == epilogue->getVirtualAddress());
}
line_table->AppendLineEntryToSequence(sequence.get(), addr, lno, col,
source_idx, is_statement, false,
is_prologue, is_epilogue, false);
}
prev_addr = addr;
prev_length = length;
prev_line = lno;
prev_source_idx = source_idx;
}
if (entry_count > 0 && ShouldAddLine(match_line, prev_line, prev_length)) {
// The end is always a terminal entry, so insert it regardless.
line_table->AppendLineEntryToSequence(
sequence.get(), prev_addr + prev_length, prev_line, 0,
prev_source_idx, false, false, false, false, true);
}
line_table->InsertSequence(sequence.get());
}
if (line_table->GetSize()) {
comp_unit.SetLineTable(line_table.release());
return true;
}
return false;
}
void SymbolFilePDB::BuildSupportFileIdToSupportFileIndexMap(
const PDBSymbolCompiland &compiland,
llvm::DenseMap<uint32_t, uint32_t> &index_map) const {
// This is a hack, but we need to convert the source id into an index into
// the support files array. We don't want to do path comparisons to avoid
// basename / full path issues that may or may not even be a problem, so we
// use the globally unique source file identifiers. Ideally we could use the
// global identifiers everywhere, but LineEntry currently assumes indices.
auto source_files = m_session_up->getSourceFilesForCompiland(compiland);
if (!source_files)
return;
int index = 0;
while (auto file = source_files->getNext()) {
uint32_t source_id = file->getUniqueId();
index_map[source_id] = index++;
}
}
lldb::CompUnitSP SymbolFilePDB::GetCompileUnitContainsAddress(
const lldb_private::Address &so_addr) {
lldb::addr_t file_vm_addr = so_addr.GetFileAddress();
if (file_vm_addr == LLDB_INVALID_ADDRESS || file_vm_addr == 0)
return nullptr;
// If it is a PDB function's vm addr, this is the first sure bet.
if (auto lines =
m_session_up->findLineNumbersByAddress(file_vm_addr, /*Length=*/1)) {
if (auto first_line = lines->getNext())
return ParseCompileUnitForUID(first_line->getCompilandId());
}
// Otherwise we resort to section contributions.
if (auto sec_contribs = m_session_up->getSectionContribs()) {
while (auto section = sec_contribs->getNext()) {
auto va = section->getVirtualAddress();
if (file_vm_addr >= va && file_vm_addr < va + section->getLength())
return ParseCompileUnitForUID(section->getCompilandId());
}
}
return nullptr;
}
Mangled
SymbolFilePDB::GetMangledForPDBFunc(const llvm::pdb::PDBSymbolFunc &pdb_func) {
Mangled mangled;
auto func_name = pdb_func.getName();
auto func_undecorated_name = pdb_func.getUndecoratedName();
std::string func_decorated_name;
// Seek from public symbols for non-static function's decorated name if any.
// For static functions, they don't have undecorated names and aren't exposed
// in Public Symbols either.
if (!func_undecorated_name.empty()) {
auto result_up = m_global_scope_up->findChildren(
PDB_SymType::PublicSymbol, func_undecorated_name,
PDB_NameSearchFlags::NS_UndecoratedName);
if (result_up) {
while (auto symbol_up = result_up->getNext()) {
// For a public symbol, it is unique.
lldbassert(result_up->getChildCount() == 1);
if (auto *pdb_public_sym =
llvm::dyn_cast_or_null<PDBSymbolPublicSymbol>(
symbol_up.get())) {
if (pdb_public_sym->isFunction()) {
func_decorated_name = pdb_public_sym->getName();
break;
}
}
}
}
}
if (!func_decorated_name.empty()) {
mangled.SetMangledName(ConstString(func_decorated_name));
// For MSVC, format of C funciton's decorated name depends on calling
// convention. Unfortunately none of the format is recognized by current
// LLDB. For example, `_purecall` is a __cdecl C function. From PDB,
// `__purecall` is retrieved as both its decorated and undecorated name
// (using PDBSymbolFunc::getUndecoratedName method). However `__purecall`
// string is not treated as mangled in LLDB (neither `?` nor `_Z` prefix).
// Mangled::GetDemangledName method will fail internally and caches an
// empty string as its undecorated name. So we will face a contradiction
// here for the same symbol:
// non-empty undecorated name from PDB
// empty undecorated name from LLDB
if (!func_undecorated_name.empty() && mangled.GetDemangledName().IsEmpty())
mangled.SetDemangledName(ConstString(func_undecorated_name));
// LLDB uses several flags to control how a C++ decorated name is
// undecorated for MSVC. See `safeUndecorateName` in Class Mangled. So the
// yielded name could be different from what we retrieve from
// PDB source unless we also apply same flags in getting undecorated
// name through PDBSymbolFunc::getUndecoratedNameEx method.
if (!func_undecorated_name.empty() &&
mangled.GetDemangledName() != ConstString(func_undecorated_name))
mangled.SetDemangledName(ConstString(func_undecorated_name));
} else if (!func_undecorated_name.empty()) {
mangled.SetDemangledName(ConstString(func_undecorated_name));
} else if (!func_name.empty())
mangled.SetValue(ConstString(func_name), false);
return mangled;
}
bool SymbolFilePDB::DeclContextMatchesThisSymbolFile(
const lldb_private::CompilerDeclContext &decl_ctx) {
if (!decl_ctx.IsValid())
return true;
TypeSystem *decl_ctx_type_system = decl_ctx.GetTypeSystem();
if (!decl_ctx_type_system)
return false;
auto type_system_or_err = GetTypeSystemForLanguage(
decl_ctx_type_system->GetMinimumLanguage(nullptr));
if (auto err = type_system_or_err.takeError()) {
LLDB_LOG_ERROR(
lldb_private::GetLogIfAnyCategoriesSet(LIBLLDB_LOG_SYMBOLS),
std::move(err),
"Unable to determine if DeclContext matches this symbol file");
return false;
}
if (decl_ctx_type_system == &type_system_or_err.get())
return true; // The type systems match, return true
return false;
}
uint32_t SymbolFilePDB::GetCompilandId(const llvm::pdb::PDBSymbolData &data) {
static const auto pred_upper = [](uint32_t lhs, SecContribInfo rhs) {
return lhs < rhs.Offset;
};
// Cache section contributions
if (m_sec_contribs.empty()) {
if (auto SecContribs = m_session_up->getSectionContribs()) {
while (auto SectionContrib = SecContribs->getNext()) {
auto comp_id = SectionContrib->getCompilandId();
if (!comp_id)
continue;
auto sec = SectionContrib->getAddressSection();
auto &sec_cs = m_sec_contribs[sec];
auto offset = SectionContrib->getAddressOffset();
auto it =
std::upper_bound(sec_cs.begin(), sec_cs.end(), offset, pred_upper);
auto size = SectionContrib->getLength();
sec_cs.insert(it, {offset, size, comp_id});
}
}
}
// Check by line number
if (auto Lines = data.getLineNumbers()) {
if (auto FirstLine = Lines->getNext())
return FirstLine->getCompilandId();
}
// Retrieve section + offset
uint32_t DataSection = data.getAddressSection();
uint32_t DataOffset = data.getAddressOffset();
if (DataSection == 0) {
if (auto RVA = data.getRelativeVirtualAddress())
m_session_up->addressForRVA(RVA, DataSection, DataOffset);
}
if (DataSection) {
// Search by section contributions
auto &sec_cs = m_sec_contribs[DataSection];
auto it =
std::upper_bound(sec_cs.begin(), sec_cs.end(), DataOffset, pred_upper);
if (it != sec_cs.begin()) {
--it;
if (DataOffset < it->Offset + it->Size)
return it->CompilandId;
}
} else {
// Search in lexical tree
auto LexParentId = data.getLexicalParentId();
while (auto LexParent = m_session_up->getSymbolById(LexParentId)) {
if (LexParent->getSymTag() == PDB_SymType::Exe)
break;
if (LexParent->getSymTag() == PDB_SymType::Compiland)
return LexParentId;
LexParentId = LexParent->getRawSymbol().getLexicalParentId();
}
}
return 0;
}