//===-- CPlusPlusNameParser.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 "CPlusPlusNameParser.h" #include "clang/Basic/IdentifierTable.h" #include "clang/Basic/TokenKinds.h" #include "llvm/ADT/StringMap.h" #include "llvm/Support/Threading.h" #include using namespace lldb; using namespace lldb_private; using ParsedFunction = lldb_private::CPlusPlusNameParser::ParsedFunction; using ParsedName = lldb_private::CPlusPlusNameParser::ParsedName; namespace tok = clang::tok; std::optional CPlusPlusNameParser::ParseAsFunctionDefinition() { m_next_token_index = 0; std::optional result(std::nullopt); // Try to parse the name as function without a return type specified e.g. // main(int, char*[]) { Bookmark start_position = SetBookmark(); result = ParseFunctionImpl(false); if (result && !HasMoreTokens()) return result; } // Try to parse the name as function with function pointer return type e.g. // void (*get_func(const char*))() result = ParseFuncPtr(true); if (result) return result; // Finally try to parse the name as a function with non-function return type // e.g. int main(int, char*[]) result = ParseFunctionImpl(true); if (HasMoreTokens()) return std::nullopt; return result; } std::optional CPlusPlusNameParser::ParseAsFullName() { m_next_token_index = 0; std::optional name_ranges = ParseFullNameImpl(); if (!name_ranges) return std::nullopt; if (HasMoreTokens()) return std::nullopt; ParsedName result; result.basename = GetTextForRange(name_ranges->basename_range); result.context = GetTextForRange(name_ranges->context_range); return result; } bool CPlusPlusNameParser::HasMoreTokens() { return m_next_token_index < m_tokens.size(); } void CPlusPlusNameParser::Advance() { ++m_next_token_index; } void CPlusPlusNameParser::TakeBack() { --m_next_token_index; } bool CPlusPlusNameParser::ConsumeToken(tok::TokenKind kind) { if (!HasMoreTokens()) return false; if (!Peek().is(kind)) return false; Advance(); return true; } template bool CPlusPlusNameParser::ConsumeToken(Ts... kinds) { if (!HasMoreTokens()) return false; if (!Peek().isOneOf(kinds...)) return false; Advance(); return true; } CPlusPlusNameParser::Bookmark CPlusPlusNameParser::SetBookmark() { return Bookmark(m_next_token_index); } size_t CPlusPlusNameParser::GetCurrentPosition() { return m_next_token_index; } clang::Token &CPlusPlusNameParser::Peek() { assert(HasMoreTokens()); return m_tokens[m_next_token_index]; } std::optional CPlusPlusNameParser::ParseFunctionImpl(bool expect_return_type) { Bookmark start_position = SetBookmark(); ParsedFunction result; if (expect_return_type) { size_t return_start = GetCurrentPosition(); // Consume return type if it's expected. if (!ConsumeToken(tok::kw_auto) && !ConsumeTypename()) return std::nullopt; size_t return_end = GetCurrentPosition(); result.return_type = GetTextForRange(Range(return_start, return_end)); } auto maybe_name = ParseFullNameImpl(); if (!maybe_name) { return std::nullopt; } size_t argument_start = GetCurrentPosition(); if (!ConsumeArguments()) { return std::nullopt; } size_t qualifiers_start = GetCurrentPosition(); SkipFunctionQualifiers(); size_t end_position = GetCurrentPosition(); result.name.basename = GetTextForRange(maybe_name->basename_range); result.name.context = GetTextForRange(maybe_name->context_range); result.arguments = GetTextForRange(Range(argument_start, qualifiers_start)); result.qualifiers = GetTextForRange(Range(qualifiers_start, end_position)); start_position.Remove(); return result; } std::optional CPlusPlusNameParser::ParseFuncPtr(bool expect_return_type) { // This function parses a function definition // that returns a pointer type. // E.g., double (*(*func(long))(int))(float) // Step 1: // Remove the return type of the innermost // function pointer type. // // Leaves us with: // (*(*func(long))(int))(float) Bookmark start_position = SetBookmark(); if (expect_return_type) { // Consume return type. if (!ConsumeTypename()) return std::nullopt; } // Step 2: // // Skip a pointer and parenthesis pair. // // Leaves us with: // (*func(long))(int))(float) if (!ConsumeToken(tok::l_paren)) return std::nullopt; if (!ConsumePtrsAndRefs()) return std::nullopt; // Step 3: // // Consume inner function name. This will fail unless // we stripped all the pointers on the left hand side // of the function name. { Bookmark before_inner_function_pos = SetBookmark(); auto maybe_inner_function_name = ParseFunctionImpl(false); if (maybe_inner_function_name) if (ConsumeToken(tok::r_paren)) if (ConsumeArguments()) { SkipFunctionQualifiers(); start_position.Remove(); before_inner_function_pos.Remove(); return maybe_inner_function_name; } } // Step 4: // // Parse the remaining string as a function pointer again. // This time don't consume the inner-most typename since // we're left with pointers only. This will strip another // layer of pointers until we're left with the innermost // function name/argument. I.e., func(long))(int))(float) // // Once we successfully stripped all pointers and gotten // the innermost function name from ParseFunctionImpl above, // we consume a single ')' and the arguments '(...)' that follows. // // Leaves us with: // )(float) // // This is the remnant of the outer function pointers' arguments. // Unwinding the recursive calls will remove the remaining // arguments. auto maybe_inner_function_ptr_name = ParseFuncPtr(false); if (maybe_inner_function_ptr_name) if (ConsumeToken(tok::r_paren)) if (ConsumeArguments()) { SkipFunctionQualifiers(); start_position.Remove(); return maybe_inner_function_ptr_name; } return std::nullopt; } bool CPlusPlusNameParser::ConsumeArguments() { return ConsumeBrackets(tok::l_paren, tok::r_paren); } bool CPlusPlusNameParser::ConsumeTemplateArgs() { Bookmark start_position = SetBookmark(); if (!HasMoreTokens() || Peek().getKind() != tok::less) return false; Advance(); // Consuming template arguments is a bit trickier than consuming function // arguments, because '<' '>' brackets are not always trivially balanced. In // some rare cases tokens '<' and '>' can appear inside template arguments as // arithmetic or shift operators not as template brackets. Examples: // std::enable_if<(10u)<(64), bool> // f> // Good thing that compiler makes sure that really ambiguous cases of '>' // usage should be enclosed within '()' brackets. int template_counter = 1; bool can_open_template = false; while (HasMoreTokens() && template_counter > 0) { tok::TokenKind kind = Peek().getKind(); switch (kind) { case tok::greatergreater: template_counter -= 2; can_open_template = false; Advance(); break; case tok::greater: --template_counter; can_open_template = false; Advance(); break; case tok::less: // '<' is an attempt to open a subteamplte // check if parser is at the point where it's actually possible, // otherwise it's just a part of an expression like 'sizeof(T)<(10)'. No // need to do the same for '>' because compiler actually makes sure that // '>' always surrounded by brackets to avoid ambiguity. if (can_open_template) ++template_counter; can_open_template = false; Advance(); break; case tok::kw_operator: // C++ operator overloading. if (!ConsumeOperator()) return false; can_open_template = true; break; case tok::raw_identifier: can_open_template = true; Advance(); break; case tok::l_square: // Handle templates tagged with an ABI tag. // An example demangled/prettified version is: // func[abi:tag1][abi:tag2](int) if (ConsumeAbiTag()) can_open_template = true; else if (ConsumeBrackets(tok::l_square, tok::r_square)) can_open_template = false; else return false; break; case tok::l_paren: if (!ConsumeArguments()) return false; can_open_template = false; break; default: can_open_template = false; Advance(); break; } } if (template_counter != 0) { return false; } start_position.Remove(); return true; } bool CPlusPlusNameParser::ConsumeAbiTag() { Bookmark start_position = SetBookmark(); if (!ConsumeToken(tok::l_square)) return false; if (HasMoreTokens() && Peek().is(tok::raw_identifier) && Peek().getRawIdentifier() == "abi") Advance(); else return false; if (!ConsumeToken(tok::colon)) return false; // Consume the actual tag string (and allow some special characters) while (ConsumeToken(tok::raw_identifier, tok::comma, tok::period, tok::numeric_constant)) ; if (!ConsumeToken(tok::r_square)) return false; start_position.Remove(); return true; } bool CPlusPlusNameParser::ConsumeAnonymousNamespace() { Bookmark start_position = SetBookmark(); if (!ConsumeToken(tok::l_paren)) { return false; } constexpr llvm::StringLiteral g_anonymous("anonymous"); if (HasMoreTokens() && Peek().is(tok::raw_identifier) && Peek().getRawIdentifier() == g_anonymous) { Advance(); } else { return false; } if (!ConsumeToken(tok::kw_namespace)) { return false; } if (!ConsumeToken(tok::r_paren)) { return false; } start_position.Remove(); return true; } bool CPlusPlusNameParser::ConsumeLambda() { Bookmark start_position = SetBookmark(); if (!ConsumeToken(tok::l_brace)) { return false; } constexpr llvm::StringLiteral g_lambda("lambda"); if (HasMoreTokens() && Peek().is(tok::raw_identifier) && Peek().getRawIdentifier() == g_lambda) { // Put the matched brace back so we can use ConsumeBrackets TakeBack(); } else { return false; } if (!ConsumeBrackets(tok::l_brace, tok::r_brace)) { return false; } start_position.Remove(); return true; } bool CPlusPlusNameParser::ConsumeBrackets(tok::TokenKind left, tok::TokenKind right) { Bookmark start_position = SetBookmark(); if (!HasMoreTokens() || Peek().getKind() != left) return false; Advance(); int counter = 1; while (HasMoreTokens() && counter > 0) { tok::TokenKind kind = Peek().getKind(); if (kind == right) --counter; else if (kind == left) ++counter; Advance(); } assert(counter >= 0); if (counter > 0) { return false; } start_position.Remove(); return true; } bool CPlusPlusNameParser::ConsumeOperator() { Bookmark start_position = SetBookmark(); if (!ConsumeToken(tok::kw_operator)) return false; if (!HasMoreTokens()) { return false; } const auto &token = Peek(); // When clang generates debug info it adds template parameters to names. // Since clang doesn't add a space between the name and the template parameter // in some cases we are not generating valid C++ names e.g.: // // operator< // // In some of these cases we will not parse them correctly. This fixes the // issue by detecting this case and inserting tok::less in place of // tok::lessless and returning successfully that we consumed the operator. if (token.getKind() == tok::lessless) { // Make sure we have more tokens before attempting to look ahead one more. if (m_next_token_index + 1 < m_tokens.size()) { // Look ahead two tokens. clang::Token n_token = m_tokens[m_next_token_index + 1]; // If we find ( or < then this is indeed operator<< no need for fix. if (n_token.getKind() != tok::l_paren && n_token.getKind() != tok::less) { clang::Token tmp_tok; tmp_tok.startToken(); tmp_tok.setLength(1); tmp_tok.setLocation(token.getLocation().getLocWithOffset(1)); tmp_tok.setKind(tok::less); m_tokens[m_next_token_index] = tmp_tok; start_position.Remove(); return true; } } } switch (token.getKind()) { case tok::kw_new: case tok::kw_delete: // This is 'new' or 'delete' operators. Advance(); // Check for array new/delete. if (HasMoreTokens() && Peek().is(tok::l_square)) { // Consume the '[' and ']'. if (!ConsumeBrackets(tok::l_square, tok::r_square)) return false; } break; #define OVERLOADED_OPERATOR(Name, Spelling, Token, Unary, Binary, MemberOnly) \ case tok::Token: \ Advance(); \ break; #define OVERLOADED_OPERATOR_MULTI(Name, Spelling, Unary, Binary, MemberOnly) #include "clang/Basic/OperatorKinds.def" #undef OVERLOADED_OPERATOR #undef OVERLOADED_OPERATOR_MULTI case tok::l_paren: // Call operator consume '(' ... ')'. if (ConsumeBrackets(tok::l_paren, tok::r_paren)) break; return false; case tok::l_square: // This is a [] operator. // Consume the '[' and ']'. if (ConsumeBrackets(tok::l_square, tok::r_square)) break; return false; default: // This might be a cast operator. if (ConsumeTypename()) break; return false; } start_position.Remove(); return true; } void CPlusPlusNameParser::SkipTypeQualifiers() { while (ConsumeToken(tok::kw_const, tok::kw_volatile)) ; } void CPlusPlusNameParser::SkipFunctionQualifiers() { while (ConsumeToken(tok::kw_const, tok::kw_volatile, tok::amp, tok::ampamp)) ; } bool CPlusPlusNameParser::ConsumeBuiltinType() { bool result = false; bool continue_parsing = true; // Built-in types can be made of a few keywords like 'unsigned long long // int'. This function consumes all built-in type keywords without checking // if they make sense like 'unsigned char void'. while (continue_parsing && HasMoreTokens()) { switch (Peek().getKind()) { case tok::kw_short: case tok::kw_long: case tok::kw___int64: case tok::kw___int128: case tok::kw_signed: case tok::kw_unsigned: case tok::kw_void: case tok::kw_char: case tok::kw_int: case tok::kw_half: case tok::kw_float: case tok::kw_double: case tok::kw___float128: case tok::kw_wchar_t: case tok::kw_bool: case tok::kw_char16_t: case tok::kw_char32_t: result = true; Advance(); break; default: continue_parsing = false; break; } } return result; } void CPlusPlusNameParser::SkipPtrsAndRefs() { // Ignoring result. ConsumePtrsAndRefs(); } bool CPlusPlusNameParser::ConsumePtrsAndRefs() { bool found = false; SkipTypeQualifiers(); while (ConsumeToken(tok::star, tok::amp, tok::ampamp, tok::kw_const, tok::kw_volatile)) { found = true; SkipTypeQualifiers(); } return found; } bool CPlusPlusNameParser::ConsumeDecltype() { Bookmark start_position = SetBookmark(); if (!ConsumeToken(tok::kw_decltype)) return false; if (!ConsumeArguments()) return false; start_position.Remove(); return true; } bool CPlusPlusNameParser::ConsumeTypename() { Bookmark start_position = SetBookmark(); SkipTypeQualifiers(); if (!ConsumeBuiltinType() && !ConsumeDecltype()) { if (!ParseFullNameImpl()) return false; } SkipPtrsAndRefs(); start_position.Remove(); return true; } std::optional CPlusPlusNameParser::ParseFullNameImpl() { // Name parsing state machine. enum class State { Beginning, // start of the name AfterTwoColons, // right after :: AfterIdentifier, // right after alphanumerical identifier ([a-z0-9_]+) AfterTemplate, // right after template brackets () AfterOperator, // right after name of C++ operator }; Bookmark start_position = SetBookmark(); State state = State::Beginning; bool continue_parsing = true; std::optional last_coloncolon_position; while (continue_parsing && HasMoreTokens()) { const auto &token = Peek(); switch (token.getKind()) { case tok::raw_identifier: // Just a name. if (state != State::Beginning && state != State::AfterTwoColons) { continue_parsing = false; break; } Advance(); state = State::AfterIdentifier; break; case tok::l_square: { // Handles types or functions that were tagged // with, e.g., // [[gnu::abi_tag("tag1","tag2")]] func() // and demangled/prettified into: // func[abi:tag1][abi:tag2]() // ABI tags only appear after a method or type name const bool valid_state = state == State::AfterIdentifier || state == State::AfterOperator; if (!valid_state || !ConsumeAbiTag()) { continue_parsing = false; } break; } case tok::l_paren: { if (state == State::Beginning || state == State::AfterTwoColons) { // (anonymous namespace) if (ConsumeAnonymousNamespace()) { state = State::AfterIdentifier; break; } } // Type declared inside a function 'func()::Type' if (state != State::AfterIdentifier && state != State::AfterTemplate && state != State::AfterOperator) { continue_parsing = false; break; } Bookmark l_paren_position = SetBookmark(); // Consume the '(' ... ') [const]'. if (!ConsumeArguments()) { continue_parsing = false; break; } SkipFunctionQualifiers(); // Consume '::' size_t coloncolon_position = GetCurrentPosition(); if (!ConsumeToken(tok::coloncolon)) { continue_parsing = false; break; } l_paren_position.Remove(); last_coloncolon_position = coloncolon_position; state = State::AfterTwoColons; break; } case tok::l_brace: if (state == State::Beginning || state == State::AfterTwoColons) { if (ConsumeLambda()) { state = State::AfterIdentifier; break; } } continue_parsing = false; break; case tok::coloncolon: // Type nesting delimiter. if (state != State::Beginning && state != State::AfterIdentifier && state != State::AfterTemplate) { continue_parsing = false; break; } last_coloncolon_position = GetCurrentPosition(); Advance(); state = State::AfterTwoColons; break; case tok::less: // Template brackets. if (state != State::AfterIdentifier && state != State::AfterOperator) { continue_parsing = false; break; } if (!ConsumeTemplateArgs()) { continue_parsing = false; break; } state = State::AfterTemplate; break; case tok::kw_operator: // C++ operator overloading. if (state != State::Beginning && state != State::AfterTwoColons) { continue_parsing = false; break; } if (!ConsumeOperator()) { continue_parsing = false; break; } state = State::AfterOperator; break; case tok::tilde: // Destructor. if (state != State::Beginning && state != State::AfterTwoColons) { continue_parsing = false; break; } Advance(); if (ConsumeToken(tok::raw_identifier)) { state = State::AfterIdentifier; } else { TakeBack(); continue_parsing = false; } break; default: continue_parsing = false; break; } } if (state == State::AfterIdentifier || state == State::AfterOperator || state == State::AfterTemplate) { ParsedNameRanges result; if (last_coloncolon_position) { result.context_range = Range(start_position.GetSavedPosition(), *last_coloncolon_position); result.basename_range = Range(*last_coloncolon_position + 1, GetCurrentPosition()); } else { result.basename_range = Range(start_position.GetSavedPosition(), GetCurrentPosition()); } start_position.Remove(); return result; } else { return std::nullopt; } } llvm::StringRef CPlusPlusNameParser::GetTextForRange(const Range &range) { if (range.empty()) return llvm::StringRef(); assert(range.begin_index < range.end_index); assert(range.begin_index < m_tokens.size()); assert(range.end_index <= m_tokens.size()); clang::Token &first_token = m_tokens[range.begin_index]; clang::Token &last_token = m_tokens[range.end_index - 1]; clang::SourceLocation start_loc = first_token.getLocation(); clang::SourceLocation end_loc = last_token.getLocation(); unsigned start_pos = start_loc.getRawEncoding(); unsigned end_pos = end_loc.getRawEncoding() + last_token.getLength(); return m_text.take_front(end_pos).drop_front(start_pos); } static const clang::LangOptions &GetLangOptions() { static clang::LangOptions g_options; static llvm::once_flag g_once_flag; llvm::call_once(g_once_flag, []() { g_options.LineComment = true; g_options.C99 = true; g_options.C11 = true; g_options.CPlusPlus = true; g_options.CPlusPlus11 = true; g_options.CPlusPlus14 = true; g_options.CPlusPlus17 = true; g_options.CPlusPlus20 = true; }); return g_options; } static const llvm::StringMap &GetKeywordsMap() { static llvm::StringMap g_map{ #define KEYWORD(Name, Flags) {llvm::StringRef(#Name), tok::kw_##Name}, #include "clang/Basic/TokenKinds.def" #undef KEYWORD }; return g_map; } void CPlusPlusNameParser::ExtractTokens() { if (m_text.empty()) return; clang::Lexer lexer(clang::SourceLocation(), GetLangOptions(), m_text.data(), m_text.data(), m_text.data() + m_text.size()); const auto &kw_map = GetKeywordsMap(); clang::Token token; for (lexer.LexFromRawLexer(token); !token.is(clang::tok::eof); lexer.LexFromRawLexer(token)) { if (token.is(clang::tok::raw_identifier)) { auto it = kw_map.find(token.getRawIdentifier()); if (it != kw_map.end()) { token.setKind(it->getValue()); } } m_tokens.push_back(token); } }