lldb/source/Symbol/CompileUnit.cpp - llvm-project - Git at Google

 //===-- CompileUnit.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 "lldb/Symbol/CompileUnit.h"
 #include "lldb/Core/Module.h"
 #include "lldb/Symbol/LineTable.h"
 #include "lldb/Symbol/SymbolFile.h"
 #include "lldb/Symbol/VariableList.h"
 #include "lldb/Target/Language.h"
 #include "lldb/Utility/Timer.h"
 #include <optional>

 using namespace lldb;
 using namespace lldb_private;

 CompileUnit::CompileUnit(const lldb::ModuleSP &module_sp, void *user_data,
                          const char *pathname, const lldb::user_id_t cu_sym_id,
                          lldb::LanguageType language,
                          lldb_private::LazyBool is_optimized)
     : CompileUnit(module_sp, user_data,
                   std::make_shared<SupportFile>(FileSpec(pathname)), cu_sym_id,
                   language, is_optimized) {}

 CompileUnit::CompileUnit(const lldb::ModuleSP &module_sp, void *user_data,
                          lldb::SupportFileSP support_file_sp,
                          const lldb::user_id_t cu_sym_id,
                          lldb::LanguageType language,
                          lldb_private::LazyBool is_optimized,
                          SupportFileList &&support_files)
     : ModuleChild(module_sp), UserID(cu_sym_id), m_user_data(user_data),
       m_language(language), m_flags(0),
       m_primary_support_file_sp(support_file_sp),
       m_support_files(std::move(support_files)), m_is_optimized(is_optimized) {
   if (language != eLanguageTypeUnknown)
     m_flags.Set(flagsParsedLanguage);
   assert(module_sp);
 }

 void CompileUnit::CalculateSymbolContext(SymbolContext *sc) {
   sc->comp_unit = this;
   GetModule()->CalculateSymbolContext(sc);
 }

 ModuleSP CompileUnit::CalculateSymbolContextModule() { return GetModule(); }

 CompileUnit *CompileUnit::CalculateSymbolContextCompileUnit() { return this; }

 void CompileUnit::DumpSymbolContext(Stream *s) {
   GetModule()->DumpSymbolContext(s);
   s->Printf(", CompileUnit{0x%8.8" PRIx64 "}", GetID());
 }

 void CompileUnit::GetDescription(Stream *s,
                                  lldb::DescriptionLevel level) const {
   const char *language = GetCachedLanguage();
   *s << "id = " << (const UserID &)*this << ", file = \""
      << this->GetPrimaryFile() << "\", language = \"" << language << '"';
 }

 void CompileUnit::ForeachFunction(
     llvm::function_ref<bool(const FunctionSP &)> lambda) const {
   std::vector<lldb::FunctionSP> sorted_functions;
   sorted_functions.reserve(m_functions_by_uid.size());
   for (auto &p : m_functions_by_uid)
     sorted_functions.push_back(p.second);
   llvm::sort(sorted_functions,
              [](const lldb::FunctionSP &a, const lldb::FunctionSP &b) {
                return a->GetID() < b->GetID();
              });

   for (auto &f : sorted_functions)
     if (lambda(f))
       return;
 }

 lldb::FunctionSP CompileUnit::FindFunction(
     llvm::function_ref<bool(const FunctionSP &)> matching_lambda) {
   LLDB_SCOPED_TIMER();

   lldb::ModuleSP module = CalculateSymbolContextModule();

   if (!module)
     return {};

   SymbolFile *symbol_file = module->GetSymbolFile();

   if (!symbol_file)
     return {};

   // m_functions_by_uid is filled in lazily but we need all the entries.
   symbol_file->ParseFunctions(*this);

   for (auto &p : m_functions_by_uid) {
     if (matching_lambda(p.second))
       return p.second;
   }
   return {};
 }

 const char *CompileUnit::GetCachedLanguage() const {
   if (m_flags.IsClear(flagsParsedLanguage))
     return "<not loaded>";
   return Language::GetNameForLanguageType(m_language);
 }

 // Dump the current contents of this object. No functions that cause on demand
 // parsing of functions, globals, statics are called, so this is a good
 // function to call to get an idea of the current contents of the CompileUnit
 // object.
 void CompileUnit::Dump(Stream *s, bool show_context) const {
   const char *language = GetCachedLanguage();

   s->Printf("%p: ", static_cast<const void *>(this));
   s->Indent();
   *s << "CompileUnit" << static_cast<const UserID &>(*this) << ", language = \""
      << language << "\", file = '" << GetPrimaryFile() << "'\n";

   //  m_types.Dump(s);

   if (m_variables.get()) {
     s->IndentMore();
     m_variables->Dump(s, show_context);
     s->IndentLess();
   }

   if (!m_functions_by_uid.empty()) {
     s->IndentMore();
     ForeachFunction([&s, show_context](const FunctionSP &f) {
       f->Dump(s, show_context);
       return false;
     });

     s->IndentLess();
     s->EOL();
   }
 }

 // Add a function to this compile unit
 void CompileUnit::AddFunction(FunctionSP &funcSP) {
   m_functions_by_uid[funcSP->GetID()] = funcSP;
 }

 FunctionSP CompileUnit::FindFunctionByUID(lldb::user_id_t func_uid) {
   auto it = m_functions_by_uid.find(func_uid);
   if (it == m_functions_by_uid.end())
     return FunctionSP();
   return it->second;
 }

 lldb::LanguageType CompileUnit::GetLanguage() {
   if (m_language == eLanguageTypeUnknown) {
     if (m_flags.IsClear(flagsParsedLanguage)) {
       m_flags.Set(flagsParsedLanguage);
       if (SymbolFile *symfile = GetModule()->GetSymbolFile())
         m_language = symfile->ParseLanguage(*this);
     }
   }
   return m_language;
 }

 LineTable *CompileUnit::GetLineTable() {
   if (m_line_table_up == nullptr) {
     if (m_flags.IsClear(flagsParsedLineTable)) {
       m_flags.Set(flagsParsedLineTable);
       if (SymbolFile *symfile = GetModule()->GetSymbolFile())
         symfile->ParseLineTable(*this);
     }
   }
   return m_line_table_up.get();
 }

 void CompileUnit::SetLineTable(LineTable *line_table) {
   if (line_table == nullptr)
     m_flags.Clear(flagsParsedLineTable);
   else
     m_flags.Set(flagsParsedLineTable);
   m_line_table_up.reset(line_table);
 }

 DebugMacros *CompileUnit::GetDebugMacros() {
   if (m_debug_macros_sp.get() == nullptr) {
     if (m_flags.IsClear(flagsParsedDebugMacros)) {
       m_flags.Set(flagsParsedDebugMacros);
       if (SymbolFile *symfile = GetModule()->GetSymbolFile())
         symfile->ParseDebugMacros(*this);
     }
   }

   return m_debug_macros_sp.get();
 }

 void CompileUnit::SetDebugMacros(const DebugMacrosSP &debug_macros_sp) {
   if (debug_macros_sp.get() == nullptr)
     m_flags.Clear(flagsParsedDebugMacros);
   else
     m_flags.Set(flagsParsedDebugMacros);
   m_debug_macros_sp = debug_macros_sp;
 }

 VariableListSP CompileUnit::GetVariableList(bool can_create) {
   if (m_variables.get() == nullptr && can_create) {
     SymbolContext sc;
     CalculateSymbolContext(&sc);
     assert(sc.module_sp);
     sc.module_sp->GetSymbolFile()->ParseVariablesForContext(sc);
   }

   return m_variables;
 }

 std::vector<uint32_t>
 FindFileIndexes(const SupportFileList &files, const FileSpec &file,
                 RealpathPrefixes *realpath_prefixes = nullptr) {
   std::vector<uint32_t> result;
   uint32_t idx = -1;
   while ((idx = files.FindCompatibleIndex(idx + 1, file, realpath_prefixes)) !=
          UINT32_MAX)
     result.push_back(idx);
   return result;
 }

 uint32_t CompileUnit::FindLineEntry(uint32_t start_idx, uint32_t line,
                                     const FileSpec *file_spec_ptr, bool exact,
                                     LineEntry *line_entry_ptr) {
   if (!file_spec_ptr)
     file_spec_ptr = &GetPrimaryFile();
   std::vector<uint32_t> file_indexes = FindFileIndexes(GetSupportFiles(),
                                                        *file_spec_ptr);
   if (file_indexes.empty())
     return UINT32_MAX;

   // TODO: Handle SourceLocationSpec column information
   SourceLocationSpec location_spec(*file_spec_ptr, line,
                                    /*column=*/std::nullopt,
                                    /*check_inlines=*/false, exact);

   LineTable *line_table = GetLineTable();
   if (line_table)
     return line_table->FindLineEntryIndexByFileIndex(
         start_idx, file_indexes, location_spec, line_entry_ptr);
   return UINT32_MAX;
 }

 void CompileUnit::ResolveSymbolContext(
     const SourceLocationSpec &src_location_spec,
     SymbolContextItem resolve_scope, SymbolContextList &sc_list,
     RealpathPrefixes *realpath_prefixes) {
   const FileSpec file_spec = src_location_spec.GetFileSpec();
   const uint32_t line =
       src_location_spec.GetLine().value_or(LLDB_INVALID_LINE_NUMBER);
   const uint32_t column_num =
       src_location_spec.GetColumn().value_or(LLDB_INVALID_COLUMN_NUMBER);
   const bool check_inlines = src_location_spec.GetCheckInlines();

   // First find all of the file indexes that match our "file_spec". If
   // "file_spec" has an empty directory, then only compare the basenames when
   // finding file indexes
   bool file_spec_matches_cu_file_spec =
       FileSpec::Match(file_spec, this->GetPrimaryFile());

   // If we are not looking for inlined functions and our file spec doesn't
   // match then we are done...
   if (!file_spec_matches_cu_file_spec && !check_inlines)
     return;

   SymbolContext sc(GetModule());
   sc.comp_unit = this;

   if (line == LLDB_INVALID_LINE_NUMBER) {
     if (file_spec_matches_cu_file_spec && !check_inlines) {
       // only append the context if we aren't looking for inline call sites by
       // file and line and if the file spec matches that of the compile unit
       sc_list.Append(sc);
     }
     return;
   }

   std::vector<uint32_t> file_indexes =
       FindFileIndexes(GetSupportFiles(), file_spec, realpath_prefixes);
   const size_t num_file_indexes = file_indexes.size();
   if (num_file_indexes == 0)
     return;

   // Found a matching source file in this compile unit load its debug info.
   GetModule()->GetSymbolFile()->SetLoadDebugInfoEnabled();

   LineTable *line_table = sc.comp_unit->GetLineTable();

   if (line_table == nullptr) {
     if (file_spec_matches_cu_file_spec && !check_inlines) {
       sc_list.Append(sc);
     }
     return;
   }

   uint32_t line_idx;
   LineEntry line_entry;

   if (num_file_indexes == 1) {
     // We only have a single support file that matches, so use the line
     // table function that searches for a line entries that match a single
     // support file index
     line_idx = line_table->FindLineEntryIndexByFileIndex(
         0, file_indexes.front(), src_location_spec, &line_entry);
   } else {
     // We found multiple support files that match "file_spec" so use the
     // line table function that searches for a line entries that match a
     // multiple support file indexes.
     line_idx = line_table->FindLineEntryIndexByFileIndex(
         0, file_indexes, src_location_spec, &line_entry);
   }

   // If we didn't manage to find a breakpoint that matched the line number
   // requested, that might be because it is only an inline call site, and
   // doesn't have a line entry in the line table.  Scan for that here.
   //
   // We are making the assumption that if there was an inlined function it will
   // contribute at least 1 non-call-site entry to the line table.  That's handy
   // because we don't move line breakpoints over function boundaries, so if we
   // found a hit, and there were also a call site entry, it would have to be in
   // the function containing the PC of the line table match.  That way we can
   // limit the call site search to that function.
   // We will miss functions that ONLY exist as a call site entry.

   if (line_entry.IsValid() &&
       (line_entry.line != line ||
        (column_num != 0 && line_entry.column != column_num)) &&
       (resolve_scope & eSymbolContextLineEntry) && check_inlines) {
     // We don't move lines over function boundaries, so the address in the
     // line entry will be the in function that contained the line that might
     // be a CallSite, and we can just iterate over that function to find any
     // inline records, and dig up their call sites.
     Address start_addr = line_entry.range.GetBaseAddress();
     Function *function = start_addr.CalculateSymbolContextFunction();
     // Record the size of the list to see if we added to it:
     size_t old_sc_list_size = sc_list.GetSize();

     Declaration sought_decl(file_spec, line, column_num);
     // We use this recursive function to descend the block structure looking
     // for a block that has this Declaration as in it's CallSite info.
     // This function recursively scans the sibling blocks of the incoming
     // block parameter.
     std::function<void(Block &)> examine_block =
         [&sought_decl, &sc_list, &src_location_spec, resolve_scope,
          &examine_block](Block &block) -> void {
       // Iterate over the sibling child blocks of the incoming block.
       Block *sibling_block = block.GetFirstChild();
       while (sibling_block) {
         // We only have to descend through the regular blocks, looking for
         // immediate inlines, since those are the only ones that will have this
         // callsite.
         const InlineFunctionInfo *inline_info =
             sibling_block->GetInlinedFunctionInfo();
         if (inline_info) {
           // If this is the call-site we are looking for, record that:
           // We need to be careful because the call site from the debug info
           // will generally have a column, but the user might not have specified
           // it.
           Declaration found_decl = inline_info->GetCallSite();
           uint32_t sought_column = sought_decl.GetColumn();
           if (found_decl.FileAndLineEqual(sought_decl, false) &&
               (sought_column == LLDB_INVALID_COLUMN_NUMBER ||
                sought_column == found_decl.GetColumn())) {
             // If we found a call site, it belongs not in this inlined block,
             // but in the parent block that inlined it.
             Address parent_start_addr;
             if (sibling_block->GetParent()->GetStartAddress(
                     parent_start_addr)) {
               SymbolContext sc;
               parent_start_addr.CalculateSymbolContext(&sc, resolve_scope);
               // Now swap out the line entry for the one we found.
               LineEntry call_site_line = sc.line_entry;
               call_site_line.line = found_decl.GetLine();
               call_site_line.column = found_decl.GetColumn();
               bool matches_spec = true;
               // If the user asked for an exact match, we need to make sure the
               // call site we found actually matches the location.
               if (src_location_spec.GetExactMatch()) {
                 matches_spec = false;
                 if ((src_location_spec.GetFileSpec() ==
                      sc.line_entry.GetFile()) &&
                     (src_location_spec.GetLine() &&
                      *src_location_spec.GetLine() == call_site_line.line) &&
                     (src_location_spec.GetColumn() &&
                      *src_location_spec.GetColumn() == call_site_line.column))
                   matches_spec = true;
               }
               if (matches_spec &&
                   sibling_block->GetRangeAtIndex(0, call_site_line.range)) {
                 SymbolContext call_site_sc(sc.target_sp, sc.module_sp,
                                            sc.comp_unit, sc.function, sc.block,
                                            &call_site_line, sc.symbol);
                 sc_list.Append(call_site_sc);
               }
             }
           }
         }

         // Descend into the child blocks:
         examine_block(*sibling_block);
         // Now go to the next sibling:
         sibling_block = sibling_block->GetSibling();
       }
     };

     if (function) {
       // We don't need to examine the function block, it can't be inlined.
       Block &func_block = function->GetBlock(true);
       examine_block(func_block);
     }
     // If we found entries here, we are done.  We only get here because we
     // didn't find an exact line entry for this line & column, but if we found
     // an exact match from the call site info that's strictly better than
     // continuing to look for matches further on in the file.
     // FIXME: Should I also do this for "call site line exists between the
     // given line number and the later line we found in the line table"?  That's
     // a closer approximation to our general sliding algorithm.
     if (sc_list.GetSize() > old_sc_list_size)
       return;
   }

   // If "exact == true", then "found_line" will be the same as "line". If
   // "exact == false", the "found_line" will be the closest line entry
   // with a line number greater than "line" and we will use this for our
   // subsequent line exact matches below.
   const bool inlines = false;
   const bool exact = true;
   const std::optional<uint16_t> column =
       src_location_spec.GetColumn() ? std::optional<uint16_t>(line_entry.column)
                                     : std::nullopt;

   SourceLocationSpec found_entry(line_entry.GetFile(), line_entry.line, column,
                                  inlines, exact);

   while (line_idx != UINT32_MAX) {
     // If they only asked for the line entry, then we're done, we can
     // just copy that over. But if they wanted more than just the line
     // number, fill it in.
     SymbolContext resolved_sc;
     sc.line_entry = line_entry;
     if (resolve_scope == eSymbolContextLineEntry) {
       sc_list.Append(sc);
     } else {
       line_entry.range.GetBaseAddress().CalculateSymbolContext(&resolved_sc,
                                                                resolve_scope);
       // Sometimes debug info is bad and isn't able to resolve the line entry's
       // address back to the same compile unit and/or line entry. If the compile
       // unit changed, then revert back to just the compile unit and line entry.
       // Prior to this fix, the above code might end up not being able to lookup
       // the address, and then it would clear compile unit and the line entry in
       // the symbol context and the breakpoint would fail to get set even though
       // we have a valid line table entry in this compile unit. The address
       // lookup can also end up finding another function in another compiler
       // unit if the DWARF has overlappging address ranges. So if we end up with
       // no compile unit or a different one after the above function call,
       // revert back to the same results as if resolve_scope was set exactly to
       // eSymbolContextLineEntry.
       if (resolved_sc.comp_unit == this) {
         sc_list.Append(resolved_sc);
       } else {
         if (resolved_sc.comp_unit == nullptr && resolved_sc.module_sp) {
           // Only report an error if we don't map back to any compile unit. With
           // link time optimizations, the debug info might have many compile
           // units that have the same address range due to function outlining
           // or other link time optimizations. If the compile unit is NULL, then
           // address resolving is completely failing and more deserving of an
           // error message the user can see.
           resolved_sc.module_sp->ReportError(
               "unable to resolve a line table file address {0:x16} back "
               "to a compile unit, please file a bug and attach the address "
               "and file.",
               line_entry.range.GetBaseAddress().GetFileAddress());
         }
         sc_list.Append(sc);
       }
     }

     if (num_file_indexes == 1)
       line_idx = line_table->FindLineEntryIndexByFileIndex(
           line_idx + 1, file_indexes.front(), found_entry, &line_entry);
     else
       line_idx = line_table->FindLineEntryIndexByFileIndex(
           line_idx + 1, file_indexes, found_entry, &line_entry);
   }
 }

 bool CompileUnit::GetIsOptimized() {
   if (m_is_optimized == eLazyBoolCalculate) {
     m_is_optimized = eLazyBoolNo;
     if (SymbolFile *symfile = GetModule()->GetSymbolFile()) {
       if (symfile->ParseIsOptimized(*this))
         m_is_optimized = eLazyBoolYes;
     }
   }
   return m_is_optimized;
 }

 void CompileUnit::SetVariableList(VariableListSP &variables) {
   m_variables = variables;
 }

 const std::vector<SourceModule> &CompileUnit::GetImportedModules() {
   if (m_imported_modules.empty() &&
       m_flags.IsClear(flagsParsedImportedModules)) {
     m_flags.Set(flagsParsedImportedModules);
     if (SymbolFile *symfile = GetModule()->GetSymbolFile()) {
       SymbolContext sc;
       CalculateSymbolContext(&sc);
       symfile->ParseImportedModules(sc, m_imported_modules);
     }
   }
   return m_imported_modules;
 }

 bool CompileUnit::ForEachExternalModule(
     llvm::DenseSet<SymbolFile *> &visited_symbol_files,
     llvm::function_ref<bool(Module &)> lambda) {
   if (SymbolFile *symfile = GetModule()->GetSymbolFile())
     return symfile->ForEachExternalModule(*this, visited_symbol_files, lambda);
   return false;
 }

 const SupportFileList &CompileUnit::GetSupportFiles() {
   if (m_support_files.GetSize() == 0) {
     if (m_flags.IsClear(flagsParsedSupportFiles)) {
       m_flags.Set(flagsParsedSupportFiles);
       if (SymbolFile *symfile = GetModule()->GetSymbolFile())
         symfile->ParseSupportFiles(*this, m_support_files);
     }
   }
   return m_support_files;
 }

 void *CompileUnit::GetUserData() const { return m_user_data; }
	//===-- CompileUnit.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 "lldb/Symbol/CompileUnit.h"
	#include "lldb/Core/Module.h"
	#include "lldb/Symbol/LineTable.h"
	#include "lldb/Symbol/SymbolFile.h"
	#include "lldb/Symbol/VariableList.h"
	#include "lldb/Target/Language.h"
	#include "lldb/Utility/Timer.h"
	#include <optional>

	using namespace lldb;
	using namespace lldb_private;

	CompileUnit::CompileUnit(const lldb::ModuleSP &module_sp, void *user_data,
	const char *pathname, const lldb::user_id_t cu_sym_id,
	lldb::LanguageType language,
	lldb_private::LazyBool is_optimized)
	: CompileUnit(module_sp, user_data,
	std::make_shared<SupportFile>(FileSpec(pathname)), cu_sym_id,
	language, is_optimized) {}

	CompileUnit::CompileUnit(const lldb::ModuleSP &module_sp, void *user_data,
	lldb::SupportFileSP support_file_sp,
	const lldb::user_id_t cu_sym_id,
	lldb::LanguageType language,
	lldb_private::LazyBool is_optimized,
	SupportFileList &&support_files)
	: ModuleChild(module_sp), UserID(cu_sym_id), m_user_data(user_data),
	m_language(language), m_flags(0),
	m_primary_support_file_sp(support_file_sp),
	m_support_files(std::move(support_files)), m_is_optimized(is_optimized) {
	if (language != eLanguageTypeUnknown)
	m_flags.Set(flagsParsedLanguage);
	assert(module_sp);
	}

	void CompileUnit::CalculateSymbolContext(SymbolContext *sc) {
	sc->comp_unit = this;
	GetModule()->CalculateSymbolContext(sc);
	}

	ModuleSP CompileUnit::CalculateSymbolContextModule() { return GetModule(); }

	CompileUnit *CompileUnit::CalculateSymbolContextCompileUnit() { return this; }

	void CompileUnit::DumpSymbolContext(Stream *s) {
	GetModule()->DumpSymbolContext(s);
	s->Printf(", CompileUnit{0x%8.8" PRIx64 "}", GetID());
	}

	void CompileUnit::GetDescription(Stream *s,
	lldb::DescriptionLevel level) const {
	const char *language = GetCachedLanguage();
	s << "id = " << (const UserID &)this << ", file = \""
	<< this->GetPrimaryFile() << "\", language = \"" << language << '"';
	}

	void CompileUnit::ForeachFunction(
	llvm::function_ref<bool(const FunctionSP &)> lambda) const {
	std::vector<lldb::FunctionSP> sorted_functions;
	sorted_functions.reserve(m_functions_by_uid.size());
	for (auto &p : m_functions_by_uid)
	sorted_functions.push_back(p.second);
	llvm::sort(sorted_functions,
	[](const lldb::FunctionSP &a, const lldb::FunctionSP &b) {
	return a->GetID() < b->GetID();
	});

	for (auto &f : sorted_functions)
	if (lambda(f))
	return;
	}

	lldb::FunctionSP CompileUnit::FindFunction(
	llvm::function_ref<bool(const FunctionSP &)> matching_lambda) {
	LLDB_SCOPED_TIMER();

	lldb::ModuleSP module = CalculateSymbolContextModule();

	if (!module)
	return {};

	SymbolFile *symbol_file = module->GetSymbolFile();

	if (!symbol_file)
	return {};

	// m_functions_by_uid is filled in lazily but we need all the entries.
	symbol_file->ParseFunctions(*this);

	for (auto &p : m_functions_by_uid) {
	if (matching_lambda(p.second))
	return p.second;
	}
	return {};
	}

	const char *CompileUnit::GetCachedLanguage() const {
	if (m_flags.IsClear(flagsParsedLanguage))
	return "<not loaded>";
	return Language::GetNameForLanguageType(m_language);
	}

	// Dump the current contents of this object. No functions that cause on demand
	// parsing of functions, globals, statics are called, so this is a good
	// function to call to get an idea of the current contents of the CompileUnit
	// object.
	void CompileUnit::Dump(Stream *s, bool show_context) const {
	const char *language = GetCachedLanguage();

	s->Printf("%p: ", static_cast<const void *>(this));
	s->Indent();
	s << "CompileUnit" << static_cast<const UserID &>(this) << ", language = \""
	<< language << "\", file = '" << GetPrimaryFile() << "'\n";

	// m_types.Dump(s);

	if (m_variables.get()) {
	s->IndentMore();
	m_variables->Dump(s, show_context);
	s->IndentLess();
	}

	if (!m_functions_by_uid.empty()) {
	s->IndentMore();
	ForeachFunction([&s, show_context](const FunctionSP &f) {
	f->Dump(s, show_context);
	return false;
	});

	s->IndentLess();
	s->EOL();
	}
	}

	// Add a function to this compile unit
	void CompileUnit::AddFunction(FunctionSP &funcSP) {
	m_functions_by_uid[funcSP->GetID()] = funcSP;
	}

	FunctionSP CompileUnit::FindFunctionByUID(lldb::user_id_t func_uid) {
	auto it = m_functions_by_uid.find(func_uid);
	if (it == m_functions_by_uid.end())
	return FunctionSP();
	return it->second;
	}

	lldb::LanguageType CompileUnit::GetLanguage() {
	if (m_language == eLanguageTypeUnknown) {
	if (m_flags.IsClear(flagsParsedLanguage)) {
	m_flags.Set(flagsParsedLanguage);
	if (SymbolFile *symfile = GetModule()->GetSymbolFile())
	m_language = symfile->ParseLanguage(*this);
	}
	}
	return m_language;
	}

	LineTable *CompileUnit::GetLineTable() {
	if (m_line_table_up == nullptr) {
	if (m_flags.IsClear(flagsParsedLineTable)) {
	m_flags.Set(flagsParsedLineTable);
	if (SymbolFile *symfile = GetModule()->GetSymbolFile())
	symfile->ParseLineTable(*this);
	}
	}
	return m_line_table_up.get();
	}

	void CompileUnit::SetLineTable(LineTable *line_table) {
	if (line_table == nullptr)
	m_flags.Clear(flagsParsedLineTable);
	else
	m_flags.Set(flagsParsedLineTable);
	m_line_table_up.reset(line_table);
	}

	DebugMacros *CompileUnit::GetDebugMacros() {
	if (m_debug_macros_sp.get() == nullptr) {
	if (m_flags.IsClear(flagsParsedDebugMacros)) {
	m_flags.Set(flagsParsedDebugMacros);
	if (SymbolFile *symfile = GetModule()->GetSymbolFile())
	symfile->ParseDebugMacros(*this);
	}
	}

	return m_debug_macros_sp.get();
	}

	void CompileUnit::SetDebugMacros(const DebugMacrosSP &debug_macros_sp) {
	if (debug_macros_sp.get() == nullptr)
	m_flags.Clear(flagsParsedDebugMacros);
	else
	m_flags.Set(flagsParsedDebugMacros);
	m_debug_macros_sp = debug_macros_sp;
	}

	VariableListSP CompileUnit::GetVariableList(bool can_create) {
	if (m_variables.get() == nullptr && can_create) {
	SymbolContext sc;
	CalculateSymbolContext(&sc);
	assert(sc.module_sp);
	sc.module_sp->GetSymbolFile()->ParseVariablesForContext(sc);
	}

	return m_variables;
	}

	std::vector<uint32_t>
	FindFileIndexes(const SupportFileList &files, const FileSpec &file,
	RealpathPrefixes *realpath_prefixes = nullptr) {
	std::vector<uint32_t> result;
	uint32_t idx = -1;
	while ((idx = files.FindCompatibleIndex(idx + 1, file, realpath_prefixes)) !=
	UINT32_MAX)
	result.push_back(idx);
	return result;
	}

	uint32_t CompileUnit::FindLineEntry(uint32_t start_idx, uint32_t line,
	const FileSpec *file_spec_ptr, bool exact,
	LineEntry *line_entry_ptr) {
	if (!file_spec_ptr)
	file_spec_ptr = &GetPrimaryFile();
	std::vector<uint32_t> file_indexes = FindFileIndexes(GetSupportFiles(),
	*file_spec_ptr);
	if (file_indexes.empty())
	return UINT32_MAX;

	// TODO: Handle SourceLocationSpec column information
	SourceLocationSpec location_spec(*file_spec_ptr, line,
	/column=/std::nullopt,
	/check_inlines=/false, exact);

	LineTable *line_table = GetLineTable();
	if (line_table)
	return line_table->FindLineEntryIndexByFileIndex(
	start_idx, file_indexes, location_spec, line_entry_ptr);
	return UINT32_MAX;
	}

	void CompileUnit::ResolveSymbolContext(
	const SourceLocationSpec &src_location_spec,
	SymbolContextItem resolve_scope, SymbolContextList &sc_list,
	RealpathPrefixes *realpath_prefixes) {
	const FileSpec file_spec = src_location_spec.GetFileSpec();
	const uint32_t line =
	src_location_spec.GetLine().value_or(LLDB_INVALID_LINE_NUMBER);
	const uint32_t column_num =
	src_location_spec.GetColumn().value_or(LLDB_INVALID_COLUMN_NUMBER);
	const bool check_inlines = src_location_spec.GetCheckInlines();

	// First find all of the file indexes that match our "file_spec". If
	// "file_spec" has an empty directory, then only compare the basenames when
	// finding file indexes
	bool file_spec_matches_cu_file_spec =
	FileSpec::Match(file_spec, this->GetPrimaryFile());

	// If we are not looking for inlined functions and our file spec doesn't
	// match then we are done...
	if (!file_spec_matches_cu_file_spec && !check_inlines)
	return;

	SymbolContext sc(GetModule());
	sc.comp_unit = this;

	if (line == LLDB_INVALID_LINE_NUMBER) {
	if (file_spec_matches_cu_file_spec && !check_inlines) {
	// only append the context if we aren't looking for inline call sites by
	// file and line and if the file spec matches that of the compile unit
	sc_list.Append(sc);
	}
	return;
	}

	std::vector<uint32_t> file_indexes =
	FindFileIndexes(GetSupportFiles(), file_spec, realpath_prefixes);
	const size_t num_file_indexes = file_indexes.size();
	if (num_file_indexes == 0)
	return;

	// Found a matching source file in this compile unit load its debug info.
	GetModule()->GetSymbolFile()->SetLoadDebugInfoEnabled();

	LineTable *line_table = sc.comp_unit->GetLineTable();

	if (line_table == nullptr) {
	if (file_spec_matches_cu_file_spec && !check_inlines) {
	sc_list.Append(sc);
	}
	return;
	}

	uint32_t line_idx;
	LineEntry line_entry;

	if (num_file_indexes == 1) {
	// We only have a single support file that matches, so use the line
	// table function that searches for a line entries that match a single
	// support file index
	line_idx = line_table->FindLineEntryIndexByFileIndex(
	0, file_indexes.front(), src_location_spec, &line_entry);
	} else {
	// We found multiple support files that match "file_spec" so use the
	// line table function that searches for a line entries that match a
	// multiple support file indexes.
	line_idx = line_table->FindLineEntryIndexByFileIndex(
	0, file_indexes, src_location_spec, &line_entry);
	}

	// If we didn't manage to find a breakpoint that matched the line number
	// requested, that might be because it is only an inline call site, and
	// doesn't have a line entry in the line table. Scan for that here.
	//
	// We are making the assumption that if there was an inlined function it will
	// contribute at least 1 non-call-site entry to the line table. That's handy
	// because we don't move line breakpoints over function boundaries, so if we
	// found a hit, and there were also a call site entry, it would have to be in
	// the function containing the PC of the line table match. That way we can
	// limit the call site search to that function.
	// We will miss functions that ONLY exist as a call site entry.

	if (line_entry.IsValid() &&
	(line_entry.line != line \|\|
	(column_num != 0 && line_entry.column != column_num)) &&
	(resolve_scope & eSymbolContextLineEntry) && check_inlines) {
	// We don't move lines over function boundaries, so the address in the
	// line entry will be the in function that contained the line that might
	// be a CallSite, and we can just iterate over that function to find any
	// inline records, and dig up their call sites.
	Address start_addr = line_entry.range.GetBaseAddress();
	Function *function = start_addr.CalculateSymbolContextFunction();
	// Record the size of the list to see if we added to it:
	size_t old_sc_list_size = sc_list.GetSize();

	Declaration sought_decl(file_spec, line, column_num);
	// We use this recursive function to descend the block structure looking
	// for a block that has this Declaration as in it's CallSite info.
	// This function recursively scans the sibling blocks of the incoming
	// block parameter.
	std::function<void(Block &)> examine_block =
	[&sought_decl, &sc_list, &src_location_spec, resolve_scope,
	&examine_block](Block &block) -> void {
	// Iterate over the sibling child blocks of the incoming block.
	Block *sibling_block = block.GetFirstChild();
	while (sibling_block) {
	// We only have to descend through the regular blocks, looking for
	// immediate inlines, since those are the only ones that will have this
	// callsite.
	const InlineFunctionInfo *inline_info =
	sibling_block->GetInlinedFunctionInfo();
	if (inline_info) {
	// If this is the call-site we are looking for, record that:
	// We need to be careful because the call site from the debug info
	// will generally have a column, but the user might not have specified
	// it.
	Declaration found_decl = inline_info->GetCallSite();
	uint32_t sought_column = sought_decl.GetColumn();
	if (found_decl.FileAndLineEqual(sought_decl, false) &&
	(sought_column == LLDB_INVALID_COLUMN_NUMBER \|\|
	sought_column == found_decl.GetColumn())) {
	// If we found a call site, it belongs not in this inlined block,
	// but in the parent block that inlined it.
	Address parent_start_addr;
	if (sibling_block->GetParent()->GetStartAddress(
	parent_start_addr)) {
	SymbolContext sc;
	parent_start_addr.CalculateSymbolContext(&sc, resolve_scope);
	// Now swap out the line entry for the one we found.
	LineEntry call_site_line = sc.line_entry;
	call_site_line.line = found_decl.GetLine();
	call_site_line.column = found_decl.GetColumn();
	bool matches_spec = true;
	// If the user asked for an exact match, we need to make sure the
	// call site we found actually matches the location.
	if (src_location_spec.GetExactMatch()) {
	matches_spec = false;
	if ((src_location_spec.GetFileSpec() ==
	sc.line_entry.GetFile()) &&
	(src_location_spec.GetLine() &&
	*src_location_spec.GetLine() == call_site_line.line) &&
	(src_location_spec.GetColumn() &&
	*src_location_spec.GetColumn() == call_site_line.column))
	matches_spec = true;
	}
	if (matches_spec &&
	sibling_block->GetRangeAtIndex(0, call_site_line.range)) {
	SymbolContext call_site_sc(sc.target_sp, sc.module_sp,
	sc.comp_unit, sc.function, sc.block,
	&call_site_line, sc.symbol);
	sc_list.Append(call_site_sc);
	}
	}
	}
	}

	// Descend into the child blocks:
	examine_block(*sibling_block);
	// Now go to the next sibling:
	sibling_block = sibling_block->GetSibling();
	}
	};

	if (function) {
	// We don't need to examine the function block, it can't be inlined.
	Block &func_block = function->GetBlock(true);
	examine_block(func_block);
	}
	// If we found entries here, we are done. We only get here because we
	// didn't find an exact line entry for this line & column, but if we found
	// an exact match from the call site info that's strictly better than
	// continuing to look for matches further on in the file.
	// FIXME: Should I also do this for "call site line exists between the
	// given line number and the later line we found in the line table"? That's
	// a closer approximation to our general sliding algorithm.
	if (sc_list.GetSize() > old_sc_list_size)
	return;
	}

	// If "exact == true", then "found_line" will be the same as "line". If
	// "exact == false", the "found_line" will be the closest line entry
	// with a line number greater than "line" and we will use this for our
	// subsequent line exact matches below.
	const bool inlines = false;
	const bool exact = true;
	const std::optional<uint16_t> column =
	src_location_spec.GetColumn() ? std::optional<uint16_t>(line_entry.column)
	: std::nullopt;

	SourceLocationSpec found_entry(line_entry.GetFile(), line_entry.line, column,
	inlines, exact);

	while (line_idx != UINT32_MAX) {
	// If they only asked for the line entry, then we're done, we can
	// just copy that over. But if they wanted more than just the line
	// number, fill it in.
	SymbolContext resolved_sc;
	sc.line_entry = line_entry;
	if (resolve_scope == eSymbolContextLineEntry) {
	sc_list.Append(sc);
	} else {
	line_entry.range.GetBaseAddress().CalculateSymbolContext(&resolved_sc,
	resolve_scope);
	// Sometimes debug info is bad and isn't able to resolve the line entry's
	// address back to the same compile unit and/or line entry. If the compile
	// unit changed, then revert back to just the compile unit and line entry.
	// Prior to this fix, the above code might end up not being able to lookup
	// the address, and then it would clear compile unit and the line entry in
	// the symbol context and the breakpoint would fail to get set even though
	// we have a valid line table entry in this compile unit. The address
	// lookup can also end up finding another function in another compiler
	// unit if the DWARF has overlappging address ranges. So if we end up with
	// no compile unit or a different one after the above function call,
	// revert back to the same results as if resolve_scope was set exactly to
	// eSymbolContextLineEntry.
	if (resolved_sc.comp_unit == this) {
	sc_list.Append(resolved_sc);
	} else {
	if (resolved_sc.comp_unit == nullptr && resolved_sc.module_sp) {
	// Only report an error if we don't map back to any compile unit. With
	// link time optimizations, the debug info might have many compile
	// units that have the same address range due to function outlining
	// or other link time optimizations. If the compile unit is NULL, then
	// address resolving is completely failing and more deserving of an
	// error message the user can see.
	resolved_sc.module_sp->ReportError(
	"unable to resolve a line table file address {0:x16} back "
	"to a compile unit, please file a bug and attach the address "
	"and file.",
	line_entry.range.GetBaseAddress().GetFileAddress());
	}
	sc_list.Append(sc);
	}
	}

	if (num_file_indexes == 1)
	line_idx = line_table->FindLineEntryIndexByFileIndex(
	line_idx + 1, file_indexes.front(), found_entry, &line_entry);
	else
	line_idx = line_table->FindLineEntryIndexByFileIndex(
	line_idx + 1, file_indexes, found_entry, &line_entry);
	}
	}

	bool CompileUnit::GetIsOptimized() {
	if (m_is_optimized == eLazyBoolCalculate) {
	m_is_optimized = eLazyBoolNo;
	if (SymbolFile *symfile = GetModule()->GetSymbolFile()) {
	if (symfile->ParseIsOptimized(*this))
	m_is_optimized = eLazyBoolYes;
	}
	}
	return m_is_optimized;
	}

	void CompileUnit::SetVariableList(VariableListSP &variables) {
	m_variables = variables;
	}

	const std::vector<SourceModule> &CompileUnit::GetImportedModules() {
	if (m_imported_modules.empty() &&
	m_flags.IsClear(flagsParsedImportedModules)) {
	m_flags.Set(flagsParsedImportedModules);
	if (SymbolFile *symfile = GetModule()->GetSymbolFile()) {
	SymbolContext sc;
	CalculateSymbolContext(&sc);
	symfile->ParseImportedModules(sc, m_imported_modules);
	}
	}
	return m_imported_modules;
	}

	bool CompileUnit::ForEachExternalModule(
	llvm::DenseSet<SymbolFile *> &visited_symbol_files,
	llvm::function_ref<bool(Module &)> lambda) {
	if (SymbolFile *symfile = GetModule()->GetSymbolFile())
	return symfile->ForEachExternalModule(*this, visited_symbol_files, lambda);
	return false;
	}

	const SupportFileList &CompileUnit::GetSupportFiles() {
	if (m_support_files.GetSize() == 0) {
	if (m_flags.IsClear(flagsParsedSupportFiles)) {
	m_flags.Set(flagsParsedSupportFiles);
	if (SymbolFile *symfile = GetModule()->GetSymbolFile())
	symfile->ParseSupportFiles(*this, m_support_files);
	}
	}
	return m_support_files;
	}

	void *CompileUnit::GetUserData() const { return m_user_data; }