#include #include #include #include #include namespace hex::pl { #define TOKEN(type, value) Token::Type::type, Token::type::value, lineNumber #define VALUE_TOKEN(type, value) Token::Type::type, value, lineNumber std::string matchTillInvalid(const char *characters, std::function predicate) { std::string ret; while (*characters != 0x00) { ret += *characters; characters++; if (!predicate(*characters)) break; } return ret; } size_t getIntegerLiteralLength(const std::string &string) { return string.find_first_not_of("0123456789ABCDEFabcdef.xUL"); } std::optional parseIntegerLiteral(const std::string &string) { Token::ValueType type = Token::ValueType::Any; Token::Literal result; u8 base; auto endPos = getIntegerLiteralLength(string); auto numberData = std::string_view(string).substr(0, endPos); if (numberData.ends_with('U')) { type = Token::ValueType::Unsigned128Bit; numberData.remove_suffix(1); } else if (!numberData.starts_with("0x") && !numberData.starts_with("0b")) { if (numberData.ends_with('F')) { type = Token::ValueType::Float; numberData.remove_suffix(1); } else if (numberData.ends_with('D')) { type = Token::ValueType::Double; numberData.remove_suffix(1); } } if (numberData.starts_with("0x")) { numberData = numberData.substr(2); base = 16; if (Token::isFloatingPoint(type)) return std::nullopt; if (numberData.find_first_not_of("0123456789ABCDEFabcdef") != std::string_view::npos) return std::nullopt; } else if (numberData.starts_with("0b")) { numberData = numberData.substr(2); base = 2; if (Token::isFloatingPoint(type)) return std::nullopt; if (numberData.find_first_not_of("01") != std::string_view::npos) return std::nullopt; } else if (numberData.find('.') != std::string_view::npos || Token::isFloatingPoint(type)) { base = 10; if (type == Token::ValueType::Any) type = Token::ValueType::Double; if (std::count(numberData.begin(), numberData.end(), '.') > 1 || numberData.find_first_not_of("0123456789.") != std::string_view::npos) return std::nullopt; if (numberData.ends_with('.')) return std::nullopt; } else if (isdigit(numberData[0])) { base = 10; if (numberData.find_first_not_of("0123456789") != std::string_view::npos) return std::nullopt; } else return std::nullopt; if (type == Token::ValueType::Any) type = Token::ValueType::Signed128Bit; if (numberData.length() == 0) return std::nullopt; if (Token::isUnsigned(type) || Token::isSigned(type)) { u128 integer = 0; for (const char &c : numberData) { integer *= base; if (isdigit(c)) integer += (c - '0'); else if (c >= 'A' && c <= 'F') integer += 10 + (c - 'A'); else if (c >= 'a' && c <= 'f') integer += 10 + (c - 'a'); else return std::nullopt; } switch (type) { case Token::ValueType::Unsigned128Bit: return { u128(integer) }; case Token::ValueType::Signed128Bit: return { i128(integer) }; default: return std::nullopt; } } else if (Token::isFloatingPoint(type)) { double floatingPoint = strtod(numberData.data(), nullptr); switch (type) { case Token::ValueType::Float: return { float(floatingPoint) }; case Token::ValueType::Double: return { double(floatingPoint) }; default: return std::nullopt; } } return std::nullopt; } std::optional> getCharacter(const std::string &string) { if (string.length() < 1) return std::nullopt; // Escape sequences if (string[0] == '\\') { if (string.length() < 2) return std::nullopt; // Handle simple escape sequences switch (string[1]) { case 'a': return { {'\a', 2} }; case 'b': return { {'\b', 2} }; case 'f': return { {'\f', 2} }; case 'n': return { {'\n', 2} }; case 'r': return { {'\r', 2} }; case 't': return { {'\t', 2} }; case 'v': return { {'\v', 2} }; case '\\': return { {'\\', 2} }; case '\'': return { {'\'', 2} }; case '\"': return { {'\"', 2} }; } // Hexadecimal number if (string[1] == 'x') { if (string.length() != 4) return std::nullopt; if (!isxdigit(string[2]) || !isxdigit(string[3])) return std::nullopt; return { {std::strtoul(&string[2], nullptr, 16), 4} }; } // Octal number if (string[1] == 'o') { if (string.length() != 5) return {}; if (string[2] < '0' || string[2] > '7' || string[3] < '0' || string[3] > '7' || string[4] < '0' || string[4] > '7') return {}; return { {std::strtoul(&string[2], nullptr, 8), 5} }; } return std::nullopt; } else return { {string[0], 1} }; } std::optional> getStringLiteral(const std::string &string) { if (!string.starts_with('\"')) return {}; size_t size = 1; std::string result; while (string[size] != '\"') { auto character = getCharacter(string.substr(size)); if (!character.has_value()) return {}; auto &[c, charSize] = character.value(); result += c; size += charSize; if (size >= string.length()) return {}; } return { {result, size + 1} }; } std::optional> getCharacterLiteral(const std::string &string) { if (string.empty()) return {}; if (string[0] != '\'') return {}; auto character = getCharacter(string.substr(1)); if (!character.has_value()) return {}; auto &[c, charSize] = character.value(); if (string.length() >= charSize + 2 && string[charSize + 1] != '\'') return {}; return { {c, charSize + 2} }; } std::optional> Lexer::lex(const std::string &code) { std::vector tokens; u32 offset = 0; u32 lineNumber = 1; try { while (offset < code.length()) { const char &c = code[offset]; if (c == 0x00) break; if (std::isblank(c) || std::isspace(c)) { if (code[offset] == '\n') lineNumber++; offset += 1; } else if (c == ';') { tokens.emplace_back(TOKEN(Separator, EndOfExpression)); offset += 1; } else if (c == '(') { tokens.emplace_back(TOKEN(Separator, RoundBracketOpen)); offset += 1; } else if (c == ')') { tokens.emplace_back(TOKEN(Separator, RoundBracketClose)); offset += 1; } else if (c == '{') { tokens.emplace_back(TOKEN(Separator, CurlyBracketOpen)); offset += 1; } else if (c == '}') { tokens.emplace_back(TOKEN(Separator, CurlyBracketClose)); offset += 1; } else if (c == '[') { tokens.emplace_back(TOKEN(Separator, SquareBracketOpen)); offset += 1; } else if (c == ']') { tokens.emplace_back(TOKEN(Separator, SquareBracketClose)); offset += 1; } else if (c == ',') { tokens.emplace_back(TOKEN(Separator, Comma)); offset += 1; } else if (c == '.') { tokens.emplace_back(TOKEN(Separator, Dot)); offset += 1; } else if (code.substr(offset, 2) == "::") { tokens.emplace_back(TOKEN(Operator, ScopeResolution)); offset += 2; } else if (c == '@') { tokens.emplace_back(TOKEN(Operator, AtDeclaration)); offset += 1; } else if (code.substr(offset, 2) == "==") { tokens.emplace_back(TOKEN(Operator, BoolEquals)); offset += 2; } else if (code.substr(offset, 2) == "!=") { tokens.emplace_back(TOKEN(Operator, BoolNotEquals)); offset += 2; } else if (code.substr(offset, 2) == ">=") { tokens.emplace_back(TOKEN(Operator, BoolGreaterThanOrEquals)); offset += 2; } else if (code.substr(offset, 2) == "<=") { tokens.emplace_back(TOKEN(Operator, BoolLessThanOrEquals)); offset += 2; } else if (code.substr(offset, 2) == "&&") { tokens.emplace_back(TOKEN(Operator, BoolAnd)); offset += 2; } else if (code.substr(offset, 2) == "||") { tokens.emplace_back(TOKEN(Operator, BoolOr)); offset += 2; } else if (code.substr(offset, 2) == "^^") { tokens.emplace_back(TOKEN(Operator, BoolXor)); offset += 2; } else if (c == '=') { tokens.emplace_back(TOKEN(Operator, Assignment)); offset += 1; } else if (c == ':') { tokens.emplace_back(TOKEN(Operator, Inherit)); offset += 1; } else if (c == '+') { tokens.emplace_back(TOKEN(Operator, Plus)); offset += 1; } else if (c == '-') { tokens.emplace_back(TOKEN(Operator, Minus)); offset += 1; } else if (c == '*') { tokens.emplace_back(TOKEN(Operator, Star)); offset += 1; } else if (c == '/') { tokens.emplace_back(TOKEN(Operator, Slash)); offset += 1; } else if (c == '%') { tokens.emplace_back(TOKEN(Operator, Percent)); offset += 1; } else if (code.substr(offset, 2) == "<<") { tokens.emplace_back(TOKEN(Operator, ShiftLeft)); offset += 2; } else if (code.substr(offset, 2) == ">>") { tokens.emplace_back(TOKEN(Operator, ShiftRight)); offset += 2; } else if (c == '>') { tokens.emplace_back(TOKEN(Operator, BoolGreaterThan)); offset += 1; } else if (c == '<') { tokens.emplace_back(TOKEN(Operator, BoolLessThan)); offset += 1; } else if (c == '!') { tokens.emplace_back(TOKEN(Operator, BoolNot)); offset += 1; } else if (c == '|') { tokens.emplace_back(TOKEN(Operator, BitOr)); offset += 1; } else if (c == '&') { tokens.emplace_back(TOKEN(Operator, BitAnd)); offset += 1; } else if (c == '^') { tokens.emplace_back(TOKEN(Operator, BitXor)); offset += 1; } else if (c == '~') { tokens.emplace_back(TOKEN(Operator, BitNot)); offset += 1; } else if (c == '?') { tokens.emplace_back(TOKEN(Operator, TernaryConditional)); offset += 1; } else if (c == '$') { tokens.emplace_back(TOKEN(Operator, Dollar)); offset += 1; } else if (code.substr(offset, 9) == "addressof") { tokens.emplace_back(TOKEN(Operator, AddressOf)); offset += 9; } else if (code.substr(offset, 6) == "sizeof") { tokens.emplace_back(TOKEN(Operator, SizeOf)); offset += 6; } else if (c == '\'') { auto character = getCharacterLiteral(code.substr(offset)); if (!character.has_value()) throwLexerError("invalid character literal", lineNumber); auto [c, charSize] = character.value(); tokens.emplace_back(VALUE_TOKEN(Integer, Token::Literal(c))); offset += charSize; } else if (c == '\"') { auto string = getStringLiteral(code.substr(offset)); if (!string.has_value()) throwLexerError("invalid string literal", lineNumber); auto [s, stringSize] = string.value(); tokens.emplace_back(VALUE_TOKEN(String, Token::Literal(s))); offset += stringSize; } else if (std::isalpha(c) || c == '_') { std::string identifier = matchTillInvalid(&code[offset], [](char c) -> bool { return std::isalnum(c) || c == '_'; }); // Check for reserved keywords if (identifier == "struct") tokens.emplace_back(TOKEN(Keyword, Struct)); else if (identifier == "union") tokens.emplace_back(TOKEN(Keyword, Union)); else if (identifier == "using") tokens.emplace_back(TOKEN(Keyword, Using)); else if (identifier == "enum") tokens.emplace_back(TOKEN(Keyword, Enum)); else if (identifier == "bitfield") tokens.emplace_back(TOKEN(Keyword, Bitfield)); else if (identifier == "be") tokens.emplace_back(TOKEN(Keyword, BigEndian)); else if (identifier == "le") tokens.emplace_back(TOKEN(Keyword, LittleEndian)); else if (identifier == "if") tokens.emplace_back(TOKEN(Keyword, If)); else if (identifier == "else") tokens.emplace_back(TOKEN(Keyword, Else)); else if (identifier == "false") tokens.emplace_back(VALUE_TOKEN(Integer, Token::Literal(false))); else if (identifier == "true") tokens.emplace_back(VALUE_TOKEN(Integer, Token::Literal(true))); else if (identifier == "parent") tokens.emplace_back(TOKEN(Keyword, Parent)); else if (identifier == "this") tokens.emplace_back(TOKEN(Keyword, This)); else if (identifier == "while") tokens.emplace_back(TOKEN(Keyword, While)); else if (identifier == "for") tokens.emplace_back(TOKEN(Keyword, For)); else if (identifier == "fn") tokens.emplace_back(TOKEN(Keyword, Function)); else if (identifier == "return") tokens.emplace_back(TOKEN(Keyword, Return)); else if (identifier == "namespace") tokens.emplace_back(TOKEN(Keyword, Namespace)); else if (identifier == "in") tokens.emplace_back(TOKEN(Keyword, In)); else if (identifier == "out") tokens.emplace_back(TOKEN(Keyword, Out)); else if (identifier == "break") tokens.emplace_back(TOKEN(Keyword, Break)); else if (identifier == "continue") tokens.emplace_back(TOKEN(Keyword, Continue)); // Check for built-in types else if (identifier == "u8") tokens.emplace_back(TOKEN(ValueType, Unsigned8Bit)); else if (identifier == "s8") tokens.emplace_back(TOKEN(ValueType, Signed8Bit)); else if (identifier == "u16") tokens.emplace_back(TOKEN(ValueType, Unsigned16Bit)); else if (identifier == "s16") tokens.emplace_back(TOKEN(ValueType, Signed16Bit)); else if (identifier == "u32") tokens.emplace_back(TOKEN(ValueType, Unsigned32Bit)); else if (identifier == "s32") tokens.emplace_back(TOKEN(ValueType, Signed32Bit)); else if (identifier == "u64") tokens.emplace_back(TOKEN(ValueType, Unsigned64Bit)); else if (identifier == "s64") tokens.emplace_back(TOKEN(ValueType, Signed64Bit)); else if (identifier == "u128") tokens.emplace_back(TOKEN(ValueType, Unsigned128Bit)); else if (identifier == "s128") tokens.emplace_back(TOKEN(ValueType, Signed128Bit)); else if (identifier == "float") tokens.emplace_back(TOKEN(ValueType, Float)); else if (identifier == "double") tokens.emplace_back(TOKEN(ValueType, Double)); else if (identifier == "char") tokens.emplace_back(TOKEN(ValueType, Character)); else if (identifier == "char16") tokens.emplace_back(TOKEN(ValueType, Character16)); else if (identifier == "bool") tokens.emplace_back(TOKEN(ValueType, Boolean)); else if (identifier == "str") tokens.emplace_back(TOKEN(ValueType, String)); else if (identifier == "padding") tokens.emplace_back(TOKEN(ValueType, Padding)); else if (identifier == "auto") tokens.emplace_back(TOKEN(ValueType, Auto)); // If it's not a keyword and a builtin type, it has to be an identifier else tokens.emplace_back(VALUE_TOKEN(Identifier, Token::Identifier(identifier))); offset += identifier.length(); } else if (std::isdigit(c)) { auto integer = parseIntegerLiteral(&code[offset]); if (!integer.has_value()) throwLexerError("invalid integer literal", lineNumber); tokens.emplace_back(VALUE_TOKEN(Integer, Token::Literal(integer.value()))); offset += getIntegerLiteralLength(&code[offset]); } else throwLexerError("unknown token", lineNumber); } tokens.emplace_back(TOKEN(Separator, EndOfProgram)); } catch (LexerError &e) { this->m_error = e; return {}; } return tokens; } }