//===-- CPlusPlusLanguage.cpp -----------------------------------*- C++ -*-===// // // The LLVM Compiler Infrastructure // // This file is distributed under the University of Illinois Open Source // License. See LICENSE.TXT for details. // //===----------------------------------------------------------------------===// #include "CPlusPlusLanguage.h" // C Includes #include #include // C++ Includes #include #include #include #include // Other libraries and framework includes #include "llvm/ADT/StringRef.h" // Project includes #include "lldb/Core/ConstString.h" #include "lldb/Core/FastDemangle.h" #include "lldb/Core/Log.h" #include "lldb/Core/PluginManager.h" #include "lldb/Core/RegularExpression.h" #include "lldb/Core/UniqueCStringMap.h" #include "lldb/DataFormatters/CXXFunctionPointer.h" #include "lldb/DataFormatters/DataVisualization.h" #include "lldb/DataFormatters/FormattersHelpers.h" #include "lldb/DataFormatters/VectorType.h" #include "BlockPointer.h" #include "CxxStringTypes.h" #include "LibCxx.h" #include "LibCxxAtomic.h" #include "LibStdcpp.h" using namespace lldb; using namespace lldb_private; using namespace lldb_private::formatters; void CPlusPlusLanguage::Initialize() { PluginManager::RegisterPlugin(GetPluginNameStatic(), "C++ Language", CreateInstance); } void CPlusPlusLanguage::Terminate() { PluginManager::UnregisterPlugin(CreateInstance); } lldb_private::ConstString CPlusPlusLanguage::GetPluginNameStatic() { static ConstString g_name("cplusplus"); return g_name; } //------------------------------------------------------------------ // PluginInterface protocol //------------------------------------------------------------------ lldb_private::ConstString CPlusPlusLanguage::GetPluginName() { return GetPluginNameStatic(); } uint32_t CPlusPlusLanguage::GetPluginVersion() { return 1; } //------------------------------------------------------------------ // Static Functions //------------------------------------------------------------------ Language *CPlusPlusLanguage::CreateInstance(lldb::LanguageType language) { if (Language::LanguageIsCPlusPlus(language)) return new CPlusPlusLanguage(); return nullptr; } void CPlusPlusLanguage::MethodName::Clear() { m_full.Clear(); m_basename = llvm::StringRef(); m_context = llvm::StringRef(); m_arguments = llvm::StringRef(); m_qualifiers = llvm::StringRef(); m_type = eTypeInvalid; m_parsed = false; m_parse_error = false; } bool ReverseFindMatchingChars(const llvm::StringRef &s, const llvm::StringRef &left_right_chars, size_t &left_pos, size_t &right_pos, size_t pos = llvm::StringRef::npos) { assert(left_right_chars.size() == 2); left_pos = llvm::StringRef::npos; const char left_char = left_right_chars[0]; const char right_char = left_right_chars[1]; pos = s.find_last_of(left_right_chars, pos); if (pos == llvm::StringRef::npos || s[pos] == left_char) return false; right_pos = pos; uint32_t depth = 1; while (pos > 0 && depth > 0) { pos = s.find_last_of(left_right_chars, pos); if (pos == llvm::StringRef::npos) return false; if (s[pos] == left_char) { if (--depth == 0) { left_pos = pos; return left_pos < right_pos; } } else if (s[pos] == right_char) { ++depth; } } return false; } static bool IsValidBasename(const llvm::StringRef &basename) { // Check that the basename matches with the following regular expression or is // an operator name: // "^~?([A-Za-z_][A-Za-z_0-9]*)(<.*>)?$" // We are using a hand written implementation because it is significantly more // efficient then // using the general purpose regular expression library. size_t idx = 0; if (basename.size() > 0 && basename[0] == '~') idx = 1; if (basename.size() <= idx) return false; // Empty string or "~" if (!std::isalpha(basename[idx]) && basename[idx] != '_') return false; // First charater (after removing the possible '~'') isn't in // [A-Za-z_] // Read all characters matching [A-Za-z_0-9] ++idx; while (idx < basename.size()) { if (!std::isalnum(basename[idx]) && basename[idx] != '_') break; ++idx; } // We processed all characters. It is a vaild basename. if (idx == basename.size()) return true; // Check for basename with template arguments // TODO: Improve the quality of the validation with validating the template // arguments if (basename[idx] == '<' && basename.back() == '>') return true; // Check if the basename is a vaild C++ operator name if (!basename.startswith("operator")) return false; static RegularExpression g_operator_regex( llvm::StringRef("^(operator)( " "?)([A-Za-z_][A-Za-z_0-9]*|\$\$|" "\\[\\]|[\\^<>=!\\/" "*+-]+)(<.*>)?(\\[\\])?$")); std::string basename_str(basename.str()); return g_operator_regex.Execute(basename_str, nullptr); } void CPlusPlusLanguage::MethodName::Parse() { if (!m_parsed && m_full) { // ConstString mangled; // m_full.GetMangledCounterpart(mangled); // printf ("\n parsing = '%s'\n", m_full.GetCString()); // if (mangled) // printf (" mangled = '%s'\n", mangled.GetCString()); m_parse_error = false; m_parsed = true; llvm::StringRef full(m_full.GetCString()); size_t arg_start, arg_end; llvm::StringRef parens("()", 2); if (ReverseFindMatchingChars(full, parens, arg_start, arg_end)) { m_arguments = full.substr(arg_start, arg_end - arg_start + 1); if (arg_end + 1 < full.size()) m_qualifiers = full.substr(arg_end + 1); if (arg_start > 0) { size_t basename_end = arg_start; size_t context_start = 0; size_t context_end = llvm::StringRef::npos; if (basename_end > 0 && full[basename_end - 1] == '>') { // TODO: handle template junk... // Templated function size_t template_start, template_end; llvm::StringRef lt_gt("<>", 2); if (ReverseFindMatchingChars(full, lt_gt, template_start, template_end, basename_end)) { // Check for templated functions that include return type like: // 'void foo()' context_start = full.rfind(' ', template_start); if (context_start == llvm::StringRef::npos) context_start = 0; else ++context_start; context_end = full.rfind(':', template_start); if (context_end == llvm::StringRef::npos || context_end < context_start) context_end = context_start; } else { context_end = full.rfind(':', basename_end); } } else if (context_end == llvm::StringRef::npos) { context_end = full.rfind(':', basename_end); } if (context_end == llvm::StringRef::npos) m_basename = full.substr(0, basename_end); else { if (context_start < context_end) m_context = full.substr(context_start, context_end - 1 - context_start); const size_t basename_begin = context_end + 1; m_basename = full.substr(basename_begin, basename_end - basename_begin); } m_type = eTypeUnknownMethod; } else { m_parse_error = true; return; } if (!IsValidBasename(m_basename)) { // The C++ basename doesn't match our regular expressions so this can't // be a valid C++ method, clear everything out and indicate an error m_context = llvm::StringRef(); m_basename = llvm::StringRef(); m_arguments = llvm::StringRef(); m_qualifiers = llvm::StringRef(); m_parse_error = true; } } else { m_parse_error = true; } } } llvm::StringRef CPlusPlusLanguage::MethodName::GetBasename() { if (!m_parsed) Parse(); return m_basename; } llvm::StringRef CPlusPlusLanguage::MethodName::GetContext() { if (!m_parsed) Parse(); return m_context; } llvm::StringRef CPlusPlusLanguage::MethodName::GetArguments() { if (!m_parsed) Parse(); return m_arguments; } llvm::StringRef CPlusPlusLanguage::MethodName::GetQualifiers() { if (!m_parsed) Parse(); return m_qualifiers; } std::string CPlusPlusLanguage::MethodName::GetScopeQualifiedName() { if (!m_parsed) Parse(); if (m_basename.empty() || m_context.empty()) return std::string(); std::string res; res += m_context; res += "::"; res += m_basename; return res; } bool CPlusPlusLanguage::IsCPPMangledName(const char *name) { // FIXME, we should really run through all the known C++ Language plugins and // ask each one if // this is a C++ mangled name, but we can put that off till there is actually // more than one // we care about. return (name != nullptr && name[0] == '_' && name[1] == 'Z'); } bool CPlusPlusLanguage::ExtractContextAndIdentifier( const char *name, llvm::StringRef &context, llvm::StringRef &identifier) { static RegularExpression g_basename_regex(llvm::StringRef( "^(([A-Za-z_][A-Za-z_0-9]*::)*)(~?[A-Za-z_~][A-Za-z_0-9]*)$")); RegularExpression::Match match(4); if (g_basename_regex.Execute(llvm::StringRef::withNullAsEmpty(name), &match)) { match.GetMatchAtIndex(name, 1, context); match.GetMatchAtIndex(name, 3, identifier); return true; } return false; } class CPPRuntimeEquivalents { public: CPPRuntimeEquivalents() { m_impl.Append(ConstString("std::basic_string, " "std::allocator >") .GetStringRef(), ConstString("basic_string")); // these two (with a prefixed std::) occur when c++stdlib string class // occurs as a template argument in some STL container m_impl.Append(ConstString("std::basic_string, " "std::allocator >") .GetStringRef(), ConstString("std::basic_string")); m_impl.Sort(); } void Add(ConstString &type_name, ConstString &type_equivalent) { m_impl.Insert(type_name.GetStringRef(), type_equivalent); } uint32_t FindExactMatches(ConstString &type_name, std::vector &equivalents) { uint32_t count = 0; for (ImplData match = m_impl.FindFirstValueForName(type_name.GetStringRef()); match != nullptr; match = m_impl.FindNextValueForName(match)) { equivalents.push_back(match->value); count++; } return count; } // partial matches can occur when a name with equivalents is a template // argument. // e.g. we may have "class Foo" be a match for "struct Bar". if we have a // typename // such as "class Templatized" we want this to be // replaced with // "class Templatized". Since partial matching is time // consuming // once we get a partial match, we add it to the exact matches list for faster // retrieval uint32_t FindPartialMatches(ConstString &type_name, std::vector &equivalents) { uint32_t count = 0; llvm::StringRef type_name_cstr = type_name.GetStringRef(); size_t items_count = m_impl.GetSize(); for (size_t item = 0; item < items_count; item++) { llvm::StringRef key_cstr = m_impl.GetCStringAtIndex(item); if (type_name_cstr.contains(key_cstr)) { count += AppendReplacements(type_name_cstr, key_cstr, equivalents); } } return count; } private: std::string &replace(std::string &target, std::string &pattern, std::string &with) { size_t pos; size_t pattern_len = pattern.size(); while ((pos = target.find(pattern)) != std::string::npos) target.replace(pos, pattern_len, with); return target; } uint32_t AppendReplacements(llvm::StringRef original, llvm::StringRef matching_key, std::vector &equivalents) { std::string matching_key_str(matching_key); ConstString original_const(original); uint32_t count = 0; for (ImplData match = m_impl.FindFirstValueForName(matching_key); match != nullptr; match = m_impl.FindNextValueForName(match)) { std::string target(original); std::string equiv_class(match->value.AsCString()); replace(target, matching_key_str, equiv_class); ConstString target_const(target.c_str()); // you will most probably want to leave this off since it might make this map // grow indefinitely #ifdef ENABLE_CPP_EQUIVALENTS_MAP_TO_GROW Add(original_const, target_const); #endif equivalents.push_back(target_const); count++; } return count; } typedef UniqueCStringMap Impl; typedef const Impl::Entry *ImplData; Impl m_impl; }; static CPPRuntimeEquivalents &GetEquivalentsMap() { static CPPRuntimeEquivalents g_equivalents_map; return g_equivalents_map; } uint32_t CPlusPlusLanguage::FindEquivalentNames(ConstString type_name, std::vector &equivalents) { uint32_t count = GetEquivalentsMap().FindExactMatches(type_name, equivalents); bool might_have_partials = (count == 0) // if we have a full name match just use it && (strchr(type_name.AsCString(), '<') != nullptr // we should only have partial matches when templates are // involved, check that we have && strchr(type_name.AsCString(), '>') != nullptr); // angle brackets // in the type_name // before trying to // scan for partial // matches if (might_have_partials) count = GetEquivalentsMap().FindPartialMatches(type_name, equivalents); return count; } /// Given a mangled function `mangled`, replace all the primitive function type /// arguments of `search` with type `replace`. static ConstString SubsPrimitiveParmItanium(llvm::StringRef mangled, llvm::StringRef search, llvm::StringRef replace) { Log *log = GetLogIfAllCategoriesSet(LIBLLDB_LOG_LANGUAGE); const size_t max_len = mangled.size() + mangled.count(search) * replace.size() + 1; // Make a temporary buffer to fix up the mangled parameter types and copy the // original there std::string output_buf; output_buf.reserve(max_len); output_buf.insert(0, mangled.str()); ptrdiff_t replaced_offset = 0; auto swap_parms_hook = [&](const char *parsee) { if (!parsee || !*parsee) return; // Check whether we've found a substitutee llvm::StringRef s(parsee); if (s.startswith(search)) { // account for the case where a replacement is of a different length to // the original replaced_offset += replace.size() - search.size(); ptrdiff_t replace_idx = (mangled.size() - s.size()) + replaced_offset; output_buf.erase(replace_idx, search.size()); output_buf.insert(replace_idx, replace.str()); } }; // FastDemangle will call our hook for each instance of a primitive type, // allowing us to perform substitution const char *const demangled = FastDemangle(mangled.str().c_str(), mangled.size(), swap_parms_hook); if (log) log->Printf("substituted mangling for %s:{%s} %s:{%s}\n", mangled.str().c_str(), demangled, output_buf.c_str(), FastDemangle(output_buf.c_str())); return output_buf == mangled ? ConstString() : ConstString(output_buf); } uint32_t CPlusPlusLanguage::FindAlternateFunctionManglings( const ConstString mangled_name, std::set &alternates) { const auto start_size = alternates.size(); /// Get a basic set of alternative manglings for the given symbol `name`, by /// making a few basic possible substitutions on basic types, storage duration /// and `const`ness for the given symbol. The output parameter `alternates` /// is filled with a best-guess, non-exhaustive set of different manglings /// for the given name. // Maybe we're looking for a const symbol but the debug info told us it was // non-const... if (!strncmp(mangled_name.GetCString(), "_ZN", 3) && strncmp(mangled_name.GetCString(), "_ZNK", 4)) { std::string fixed_scratch("_ZNK"); fixed_scratch.append(mangled_name.GetCString() + 3); alternates.insert(ConstString(fixed_scratch)); } // Maybe we're looking for a static symbol but we thought it was global... if (!strncmp(mangled_name.GetCString(), "_Z", 2) && strncmp(mangled_name.GetCString(), "_ZL", 3)) { std::string fixed_scratch("_ZL"); fixed_scratch.append(mangled_name.GetCString() + 2); alternates.insert(ConstString(fixed_scratch)); } // `char` is implementation defined as either `signed` or `unsigned`. As a // result a char parameter has 3 possible manglings: 'c'-char, 'a'-signed // char, 'h'-unsigned char. If we're looking for symbols with a signed char // parameter, try finding matches which have the general case 'c'. if (ConstString char_fixup = SubsPrimitiveParmItanium(mangled_name.GetStringRef(), "a", "c")) alternates.insert(char_fixup); // long long parameter mangling 'x', may actually just be a long 'l' argument if (ConstString long_fixup = SubsPrimitiveParmItanium(mangled_name.GetStringRef(), "x", "l")) alternates.insert(long_fixup); // unsigned long long parameter mangling 'y', may actually just be unsigned // long 'm' argument if (ConstString ulong_fixup = SubsPrimitiveParmItanium(mangled_name.GetStringRef(), "y", "m")) alternates.insert(ulong_fixup); return alternates.size() - start_size; } static void LoadLibCxxFormatters(lldb::TypeCategoryImplSP cpp_category_sp) { if (!cpp_category_sp) return; TypeSummaryImpl::Flags stl_summary_flags; stl_summary_flags.SetCascades(true) .SetSkipPointers(false) .SetSkipReferences(false) .SetDontShowChildren(true) .SetDontShowValue(true) .SetShowMembersOneLiner(false) .SetHideItemNames(false); #ifndef LLDB_DISABLE_PYTHON lldb::TypeSummaryImplSP std_string_summary_sp(new CXXFunctionSummaryFormat( stl_summary_flags, lldb_private::formatters::LibcxxStringSummaryProvider, "std::string summary provider")); lldb::TypeSummaryImplSP std_wstring_summary_sp(new CXXFunctionSummaryFormat( stl_summary_flags, lldb_private::formatters::LibcxxWStringSummaryProvider, "std::wstring summary provider")); cpp_category_sp->GetTypeSummariesContainer()->Add( ConstString("std::__1::string"), std_string_summary_sp); cpp_category_sp->GetTypeSummariesContainer()->Add( ConstString("std::__ndk1::string"), std_string_summary_sp); cpp_category_sp->GetTypeSummariesContainer()->Add( ConstString("std::__1::basic_string, " "std::__1::allocator >"), std_string_summary_sp); cpp_category_sp->GetTypeSummariesContainer()->Add( ConstString("std::__ndk1::basic_string, " "std::__ndk1::allocator >"), std_string_summary_sp); cpp_category_sp->GetTypeSummariesContainer()->Add( ConstString("std::__1::wstring"), std_wstring_summary_sp); cpp_category_sp->GetTypeSummariesContainer()->Add( ConstString("std::__ndk1::wstring"), std_wstring_summary_sp); cpp_category_sp->GetTypeSummariesContainer()->Add( ConstString("std::__1::basic_string, " "std::__1::allocator >"), std_wstring_summary_sp); cpp_category_sp->GetTypeSummariesContainer()->Add( ConstString("std::__ndk1::basic_string, " "std::__ndk1::allocator >"), std_wstring_summary_sp); SyntheticChildren::Flags stl_synth_flags; stl_synth_flags.SetCascades(true).SetSkipPointers(false).SetSkipReferences( false); AddCXXSynthetic( cpp_category_sp, lldb_private::formatters::LibcxxVectorBoolSyntheticFrontEndCreator, "libc++ std::vector synthetic children", ConstString( "^std::__(ndk)?1::vector >$"), stl_synth_flags, true); AddCXXSynthetic( cpp_category_sp, lldb_private::formatters::LibcxxStdVectorSyntheticFrontEndCreator, "libc++ std::vector synthetic children", ConstString("^std::__(ndk)?1::vector<.+>(( )?&)?$"), stl_synth_flags, true); AddCXXSynthetic( cpp_category_sp, lldb_private::formatters::LibcxxStdListSyntheticFrontEndCreator, "libc++ std::list synthetic children", ConstString("^std::__(ndk)?1::list<.+>(( )?&)?$"), stl_synth_flags, true); AddCXXSynthetic( cpp_category_sp, lldb_private::formatters::LibcxxStdMapSyntheticFrontEndCreator, "libc++ std::map synthetic children", ConstString("^std::__(ndk)?1::map<.+> >(( )?&)?$"), stl_synth_flags, true); AddCXXSynthetic( cpp_category_sp, lldb_private::formatters::LibcxxVectorBoolSyntheticFrontEndCreator, "libc++ std::vector synthetic children", ConstString("std::__(ndk)?1::vector >"), stl_synth_flags); AddCXXSynthetic( cpp_category_sp, lldb_private::formatters::LibcxxVectorBoolSyntheticFrontEndCreator, "libc++ std::vector synthetic children", ConstString( "std::__(ndk)?1::vector >"), stl_synth_flags); AddCXXSynthetic( cpp_category_sp, lldb_private::formatters::LibcxxStdMapSyntheticFrontEndCreator, "libc++ std::set synthetic children", ConstString("^std::__(ndk)?1::set<.+> >(( )?&)?$"), stl_synth_flags, true); AddCXXSynthetic( cpp_category_sp, lldb_private::formatters::LibcxxStdMapSyntheticFrontEndCreator, "libc++ std::multiset synthetic children", ConstString("^std::__(ndk)?1::multiset<.+> >(( )?&)?$"), stl_synth_flags, true); AddCXXSynthetic( cpp_category_sp, lldb_private::formatters::LibcxxStdMapSyntheticFrontEndCreator, "libc++ std::multimap synthetic children", ConstString("^std::__(ndk)?1::multimap<.+> >(( )?&)?$"), stl_synth_flags, true); AddCXXSynthetic( cpp_category_sp, lldb_private::formatters::LibcxxStdUnorderedMapSyntheticFrontEndCreator, "libc++ std::unordered containers synthetic children", ConstString("^(std::__(ndk)?1::)unordered_(multi)?(map|set)<.+> >$"), stl_synth_flags, true); AddCXXSynthetic( cpp_category_sp, lldb_private::formatters::LibcxxInitializerListSyntheticFrontEndCreator, "libc++ std::initializer_list synthetic children", ConstString("^std::initializer_list<.+>(( )?&)?$"), stl_synth_flags, true); AddCXXSynthetic( cpp_category_sp, lldb_private::formatters::LibcxxAtomicSyntheticFrontEndCreator, "libc++ std::atomic synthetic children", ConstString("^std::__(ndk)?1::atomic<.+>$"), stl_synth_flags, true); cpp_category_sp->GetRegexTypeSyntheticsContainer()->Add( RegularExpressionSP(new RegularExpression( llvm::StringRef("^(std::__(ndk)?1::)deque<.+>(( )?&)?$"))), SyntheticChildrenSP(new ScriptedSyntheticChildren( stl_synth_flags, "lldb.formatters.cpp.libcxx.stddeque_SynthProvider"))); AddCXXSynthetic( cpp_category_sp, lldb_private::formatters::LibcxxSharedPtrSyntheticFrontEndCreator, "shared_ptr synthetic children", ConstString("^(std::__(ndk)?1::)shared_ptr<.+>(( )?&)?$"), stl_synth_flags, true); AddCXXSynthetic( cpp_category_sp, lldb_private::formatters::LibcxxSharedPtrSyntheticFrontEndCreator, "weak_ptr synthetic children", ConstString("^(std::__(ndk)?1::)weak_ptr<.+>(( )?&)?$"), stl_synth_flags, true); stl_summary_flags.SetDontShowChildren(false); stl_summary_flags.SetSkipPointers(false); AddCXXSummary( cpp_category_sp, lldb_private::formatters::LibcxxContainerSummaryProvider, "libc++ std::vector summary provider", ConstString( "std::__(ndk)?1::vector >"), stl_summary_flags, true); AddCXXSummary(cpp_category_sp, lldb_private::formatters::LibcxxContainerSummaryProvider, "libc++ std::vector summary provider", ConstString("^std::__(ndk)?1::vector<.+>(( )?&)?$"), stl_summary_flags, true); AddCXXSummary(cpp_category_sp, lldb_private::formatters::LibcxxContainerSummaryProvider, "libc++ std::list summary provider", ConstString("^std::__(ndk)?1::list<.+>(( )?&)?$"), stl_summary_flags, true); AddCXXSummary(cpp_category_sp, lldb_private::formatters::LibcxxContainerSummaryProvider, "libc++ std::map summary provider", ConstString("^std::__(ndk)?1::map<.+>(( )?&)?$"), stl_summary_flags, true); AddCXXSummary(cpp_category_sp, lldb_private::formatters::LibcxxContainerSummaryProvider, "libc++ std::deque summary provider", ConstString("^std::__(ndk)?1::deque<.+>(( )?&)?$"), stl_summary_flags, true); AddCXXSummary(cpp_category_sp, lldb_private::formatters::LibcxxContainerSummaryProvider, "libc++ std::set summary provider", ConstString("^std::__(ndk)?1::set<.+>(( )?&)?$"), stl_summary_flags, true); AddCXXSummary(cpp_category_sp, lldb_private::formatters::LibcxxContainerSummaryProvider, "libc++ std::multiset summary provider", ConstString("^std::__(ndk)?1::multiset<.+>(( )?&)?$"), stl_summary_flags, true); AddCXXSummary(cpp_category_sp, lldb_private::formatters::LibcxxContainerSummaryProvider, "libc++ std::multimap summary provider", ConstString("^std::__(ndk)?1::multimap<.+>(( )?&)?$"), stl_summary_flags, true); AddCXXSummary( cpp_category_sp, lldb_private::formatters::LibcxxContainerSummaryProvider, "libc++ std::unordered containers summary provider", ConstString("^(std::__(ndk)?1::)unordered_(multi)?(map|set)<.+> >$"), stl_summary_flags, true); AddCXXSummary( cpp_category_sp, lldb_private::formatters::LibCxxAtomicSummaryProvider, "libc++ std::atomic summary provider", ConstString("^std::__(ndk)?1::atomic<.+>$"), stl_summary_flags, true); stl_summary_flags.SetSkipPointers(true); AddCXXSummary(cpp_category_sp, lldb_private::formatters::LibcxxSmartPointerSummaryProvider, "libc++ std::shared_ptr summary provider", ConstString("^std::__(ndk)?1::shared_ptr<.+>(( )?&)?$"), stl_summary_flags, true); AddCXXSummary(cpp_category_sp, lldb_private::formatters::LibcxxSmartPointerSummaryProvider, "libc++ std::weak_ptr summary provider", ConstString("^std::__(ndk)?1::weak_ptr<.+>(( )?&)?$"), stl_summary_flags, true); AddCXXSynthetic( cpp_category_sp, lldb_private::formatters::LibCxxVectorIteratorSyntheticFrontEndCreator, "std::vector iterator synthetic children", ConstString("^std::__(ndk)?1::__wrap_iter<.+>$"), stl_synth_flags, true); AddCXXSummary( cpp_category_sp, lldb_private::formatters::LibcxxContainerSummaryProvider, "libc++ std::vector summary provider", ConstString( "std::__(ndk)?1::vector >"), stl_summary_flags); AddCXXSynthetic( cpp_category_sp, lldb_private::formatters::LibCxxMapIteratorSyntheticFrontEndCreator, "std::map iterator synthetic children", ConstString("^std::__(ndk)?1::__map_iterator<.+>$"), stl_synth_flags, true); AddCXXSynthetic( cpp_category_sp, lldb_private::formatters::LibcxxFunctionFrontEndCreator, "std::function synthetic value provider", ConstString("^std::__1::function<.+>$"), stl_synth_flags, true); #endif } static void LoadLibStdcppFormatters(lldb::TypeCategoryImplSP cpp_category_sp) { if (!cpp_category_sp) return; TypeSummaryImpl::Flags stl_summary_flags; stl_summary_flags.SetCascades(true) .SetSkipPointers(false) .SetSkipReferences(false) .SetDontShowChildren(true) .SetDontShowValue(true) .SetShowMembersOneLiner(false) .SetHideItemNames(false); lldb::TypeSummaryImplSP std_string_summary_sp( new StringSummaryFormat(stl_summary_flags, "${var._M_dataplus._M_p}")); lldb::TypeSummaryImplSP cxx11_string_summary_sp(new CXXFunctionSummaryFormat( stl_summary_flags, LibStdcppStringSummaryProvider, "libstdc++ c++11 std::string summary provider")); lldb::TypeSummaryImplSP cxx11_wstring_summary_sp(new CXXFunctionSummaryFormat( stl_summary_flags, LibStdcppWStringSummaryProvider, "libstdc++ c++11 std::wstring summary provider")); cpp_category_sp->GetTypeSummariesContainer()->Add(ConstString("std::string"), std_string_summary_sp); cpp_category_sp->GetTypeSummariesContainer()->Add( ConstString("std::basic_string"), std_string_summary_sp); cpp_category_sp->GetTypeSummariesContainer()->Add( ConstString("std::basic_string,std::" "allocator >"), std_string_summary_sp); cpp_category_sp->GetTypeSummariesContainer()->Add( ConstString("std::basic_string, " "std::allocator >"), std_string_summary_sp); cpp_category_sp->GetTypeSummariesContainer()->Add( ConstString("std::__cxx11::string"), cxx11_string_summary_sp); cpp_category_sp->GetTypeSummariesContainer()->Add( ConstString("std::__cxx11::basic_string, " "std::allocator >"), cxx11_string_summary_sp); // making sure we force-pick the summary for printing wstring (_M_p is a // wchar_t*) lldb::TypeSummaryImplSP std_wstring_summary_sp( new StringSummaryFormat(stl_summary_flags, "${var._M_dataplus._M_p%S}")); cpp_category_sp->GetTypeSummariesContainer()->Add(ConstString("std::wstring"), std_wstring_summary_sp); cpp_category_sp->GetTypeSummariesContainer()->Add( ConstString("std::basic_string"), std_wstring_summary_sp); cpp_category_sp->GetTypeSummariesContainer()->Add( ConstString("std::basic_string,std::" "allocator >"), std_wstring_summary_sp); cpp_category_sp->GetTypeSummariesContainer()->Add( ConstString("std::basic_string, " "std::allocator >"), std_wstring_summary_sp); cpp_category_sp->GetTypeSummariesContainer()->Add( ConstString("std::__cxx11::wstring"), cxx11_wstring_summary_sp); cpp_category_sp->GetTypeSummariesContainer()->Add( ConstString("std::__cxx11::basic_string, std::allocator >"), cxx11_wstring_summary_sp); #ifndef LLDB_DISABLE_PYTHON SyntheticChildren::Flags stl_synth_flags; stl_synth_flags.SetCascades(true).SetSkipPointers(false).SetSkipReferences( false); cpp_category_sp->GetRegexTypeSyntheticsContainer()->Add( RegularExpressionSP( new RegularExpression(llvm::StringRef("^std::vector<.+>(( )?&)?$"))), SyntheticChildrenSP(new ScriptedSyntheticChildren( stl_synth_flags, "lldb.formatters.cpp.gnu_libstdcpp.StdVectorSynthProvider"))); cpp_category_sp->GetRegexTypeSyntheticsContainer()->Add( RegularExpressionSP( new RegularExpression(llvm::StringRef("^std::map<.+> >(( )?&)?$"))), SyntheticChildrenSP(new ScriptedSyntheticChildren( stl_synth_flags, "lldb.formatters.cpp.gnu_libstdcpp.StdMapSynthProvider"))); cpp_category_sp->GetRegexTypeSyntheticsContainer()->Add( RegularExpressionSP(new RegularExpression( llvm::StringRef("^std::(__cxx11::)?list<.+>(( )?&)?$"))), SyntheticChildrenSP(new ScriptedSyntheticChildren( stl_synth_flags, "lldb.formatters.cpp.gnu_libstdcpp.StdListSynthProvider"))); stl_summary_flags.SetDontShowChildren(false); stl_summary_flags.SetSkipPointers(true); cpp_category_sp->GetRegexTypeSummariesContainer()->Add( RegularExpressionSP( new RegularExpression(llvm::StringRef("^std::vector<.+>(( )?&)?$"))), TypeSummaryImplSP( new StringSummaryFormat(stl_summary_flags, "size=${svar%#}"))); cpp_category_sp->GetRegexTypeSummariesContainer()->Add( RegularExpressionSP( new RegularExpression(llvm::StringRef("^std::map<.+> >(( )?&)?$"))), TypeSummaryImplSP( new StringSummaryFormat(stl_summary_flags, "size=${svar%#}"))); cpp_category_sp->GetRegexTypeSummariesContainer()->Add( RegularExpressionSP(new RegularExpression( llvm::StringRef("^std::(__cxx11::)?list<.+>(( )?&)?$"))), TypeSummaryImplSP( new StringSummaryFormat(stl_summary_flags, "size=${svar%#}"))); AddCXXSynthetic( cpp_category_sp, lldb_private::formatters::LibStdcppVectorIteratorSyntheticFrontEndCreator, "std::vector iterator synthetic children", ConstString("^__gnu_cxx::__normal_iterator<.+>$"), stl_synth_flags, true); AddCXXSynthetic( cpp_category_sp, lldb_private::formatters::LibstdcppMapIteratorSyntheticFrontEndCreator, "std::map iterator synthetic children", ConstString("^std::_Rb_tree_iterator<.+>$"), stl_synth_flags, true); AddCXXSynthetic( cpp_category_sp, lldb_private::formatters::LibStdcppUniquePtrSyntheticFrontEndCreator, "std::unique_ptr synthetic children", ConstString("^std::unique_ptr<.+>(( )?&)?$"), stl_synth_flags, true); AddCXXSynthetic( cpp_category_sp, lldb_private::formatters::LibStdcppSharedPtrSyntheticFrontEndCreator, "std::shared_ptr synthetic children", ConstString("^std::shared_ptr<.+>(( )?&)?$"), stl_synth_flags, true); AddCXXSynthetic( cpp_category_sp, lldb_private::formatters::LibStdcppSharedPtrSyntheticFrontEndCreator, "std::weak_ptr synthetic children", ConstString("^std::weak_ptr<.+>(( )?&)?$"), stl_synth_flags, true); AddCXXSynthetic( cpp_category_sp, lldb_private::formatters::LibStdcppTupleSyntheticFrontEndCreator, "std::tuple synthetic children", ConstString("^std::tuple<.+>(( )?&)?$"), stl_synth_flags, true); AddCXXSummary(cpp_category_sp, lldb_private::formatters::LibStdcppUniquePointerSummaryProvider, "libstdc++ std::unique_ptr summary provider", ConstString("^std::unique_ptr<.+>(( )?&)?$"), stl_summary_flags, true); AddCXXSummary(cpp_category_sp, lldb_private::formatters::LibStdcppSmartPointerSummaryProvider, "libstdc++ std::shared_ptr summary provider", ConstString("^std::shared_ptr<.+>(( )?&)?$"), stl_summary_flags, true); AddCXXSummary(cpp_category_sp, lldb_private::formatters::LibStdcppSmartPointerSummaryProvider, "libstdc++ std::weak_ptr summary provider", ConstString("^std::weak_ptr<.+>(( )?&)?$"), stl_summary_flags, true); #endif } static void LoadSystemFormatters(lldb::TypeCategoryImplSP cpp_category_sp) { if (!cpp_category_sp) return; TypeSummaryImpl::Flags string_flags; string_flags.SetCascades(true) .SetSkipPointers(true) .SetSkipReferences(false) .SetDontShowChildren(true) .SetDontShowValue(false) .SetShowMembersOneLiner(false) .SetHideItemNames(false); TypeSummaryImpl::Flags string_array_flags; string_array_flags.SetCascades(true) .SetSkipPointers(true) .SetSkipReferences(false) .SetDontShowChildren(true) .SetDontShowValue(true) .SetShowMembersOneLiner(false) .SetHideItemNames(false); #ifndef LLDB_DISABLE_PYTHON // FIXME because of a bug in the FormattersContainer we need to add a summary // for both X* and const X* () AddCXXSummary( cpp_category_sp, lldb_private::formatters::Char16StringSummaryProvider, "char16_t * summary provider", ConstString("char16_t *"), string_flags); AddCXXSummary(cpp_category_sp, lldb_private::formatters::Char16StringSummaryProvider, "char16_t [] summary provider", ConstString("char16_t \\[[0-9]+\\]"), string_array_flags, true); AddCXXSummary( cpp_category_sp, lldb_private::formatters::Char32StringSummaryProvider, "char32_t * summary provider", ConstString("char32_t *"), string_flags); AddCXXSummary(cpp_category_sp, lldb_private::formatters::Char32StringSummaryProvider, "char32_t [] summary provider", ConstString("char32_t \\[[0-9]+\\]"), string_array_flags, true); AddCXXSummary( cpp_category_sp, lldb_private::formatters::WCharStringSummaryProvider, "wchar_t * summary provider", ConstString("wchar_t *"), string_flags); AddCXXSummary(cpp_category_sp, lldb_private::formatters::WCharStringSummaryProvider, "wchar_t * summary provider", ConstString("wchar_t \\[[0-9]+\\]"), string_array_flags, true); AddCXXSummary( cpp_category_sp, lldb_private::formatters::Char16StringSummaryProvider, "unichar * summary provider", ConstString("unichar *"), string_flags); TypeSummaryImpl::Flags widechar_flags; widechar_flags.SetDontShowValue(true) .SetSkipPointers(true) .SetSkipReferences(false) .SetCascades(true) .SetDontShowChildren(true) .SetHideItemNames(true) .SetShowMembersOneLiner(false); AddCXXSummary( cpp_category_sp, lldb_private::formatters::Char16SummaryProvider, "char16_t summary provider", ConstString("char16_t"), widechar_flags); AddCXXSummary( cpp_category_sp, lldb_private::formatters::Char32SummaryProvider, "char32_t summary provider", ConstString("char32_t"), widechar_flags); AddCXXSummary(cpp_category_sp, lldb_private::formatters::WCharSummaryProvider, "wchar_t summary provider", ConstString("wchar_t"), widechar_flags); AddCXXSummary( cpp_category_sp, lldb_private::formatters::Char16SummaryProvider, "unichar summary provider", ConstString("unichar"), widechar_flags); #endif } std::unique_ptr CPlusPlusLanguage::GetTypeScavenger() { class CPlusPlusTypeScavenger : public Language::ImageListTypeScavenger { public: virtual CompilerType AdjustForInclusion(CompilerType &candidate) override { LanguageType lang_type(candidate.GetMinimumLanguage()); if (!Language::LanguageIsC(lang_type) && !Language::LanguageIsCPlusPlus(lang_type)) return CompilerType(); if (candidate.IsTypedefType()) return candidate.GetTypedefedType(); return candidate; } }; return std::unique_ptr(new CPlusPlusTypeScavenger()); } lldb::TypeCategoryImplSP CPlusPlusLanguage::GetFormatters() { static std::once_flag g_initialize; static TypeCategoryImplSP g_category; std::call_once(g_initialize, [this]() -> void { DataVisualization::Categories::GetCategory(GetPluginName(), g_category); if (g_category) { LoadLibCxxFormatters(g_category); LoadLibStdcppFormatters(g_category); LoadSystemFormatters(g_category); } }); return g_category; } HardcodedFormatters::HardcodedSummaryFinder CPlusPlusLanguage::GetHardcodedSummaries() { static std::once_flag g_initialize; static ConstString g_vectortypes("VectorTypes"); static HardcodedFormatters::HardcodedSummaryFinder g_formatters; std::call_once(g_initialize, []() -> void { g_formatters.push_back( [](lldb_private::ValueObject &valobj, lldb::DynamicValueType, FormatManager &) -> TypeSummaryImpl::SharedPointer { static CXXFunctionSummaryFormat::SharedPointer formatter_sp( new CXXFunctionSummaryFormat( TypeSummaryImpl::Flags(), lldb_private::formatters::CXXFunctionPointerSummaryProvider, "Function pointer summary provider")); if (valobj.GetCompilerType().IsFunctionPointerType()) { return formatter_sp; } return nullptr; }); g_formatters.push_back( [](lldb_private::ValueObject &valobj, lldb::DynamicValueType, FormatManager &fmt_mgr) -> TypeSummaryImpl::SharedPointer { static CXXFunctionSummaryFormat::SharedPointer formatter_sp( new CXXFunctionSummaryFormat( TypeSummaryImpl::Flags() .SetCascades(true) .SetDontShowChildren(true) .SetHideItemNames(true) .SetShowMembersOneLiner(true) .SetSkipPointers(true) .SetSkipReferences(false), lldb_private::formatters::VectorTypeSummaryProvider, "vector_type pointer summary provider")); if (valobj.GetCompilerType().IsVectorType(nullptr, nullptr)) { if (fmt_mgr.GetCategory(g_vectortypes)->IsEnabled()) return formatter_sp; } return nullptr; }); g_formatters.push_back( [](lldb_private::ValueObject &valobj, lldb::DynamicValueType, FormatManager &fmt_mgr) -> TypeSummaryImpl::SharedPointer { static CXXFunctionSummaryFormat::SharedPointer formatter_sp( new CXXFunctionSummaryFormat( TypeSummaryImpl::Flags() .SetCascades(true) .SetDontShowChildren(true) .SetHideItemNames(true) .SetShowMembersOneLiner(true) .SetSkipPointers(true) .SetSkipReferences(false), lldb_private::formatters::BlockPointerSummaryProvider, "block pointer summary provider")); if (valobj.GetCompilerType().IsBlockPointerType(nullptr)) { return formatter_sp; } return nullptr; }); }); return g_formatters; } HardcodedFormatters::HardcodedSyntheticFinder CPlusPlusLanguage::GetHardcodedSynthetics() { static std::once_flag g_initialize; static ConstString g_vectortypes("VectorTypes"); static HardcodedFormatters::HardcodedSyntheticFinder g_formatters; std::call_once(g_initialize, []() -> void { g_formatters.push_back([](lldb_private::ValueObject &valobj, lldb::DynamicValueType, FormatManager & fmt_mgr) -> SyntheticChildren::SharedPointer { static CXXSyntheticChildren::SharedPointer formatter_sp( new CXXSyntheticChildren( SyntheticChildren::Flags() .SetCascades(true) .SetSkipPointers(true) .SetSkipReferences(true) .SetNonCacheable(true), "vector_type synthetic children", lldb_private::formatters::VectorTypeSyntheticFrontEndCreator)); if (valobj.GetCompilerType().IsVectorType(nullptr, nullptr)) { if (fmt_mgr.GetCategory(g_vectortypes)->IsEnabled()) return formatter_sp; } return nullptr; }); g_formatters.push_back([](lldb_private::ValueObject &valobj, lldb::DynamicValueType, FormatManager & fmt_mgr) -> SyntheticChildren::SharedPointer { static CXXSyntheticChildren::SharedPointer formatter_sp( new CXXSyntheticChildren( SyntheticChildren::Flags() .SetCascades(true) .SetSkipPointers(true) .SetSkipReferences(true) .SetNonCacheable(true), "block pointer synthetic children", lldb_private::formatters::BlockPointerSyntheticFrontEndCreator)); if (valobj.GetCompilerType().IsBlockPointerType(nullptr)) { return formatter_sp; } return nullptr; }); }); return g_formatters; }