// Copyright 2013 Dolphin Emulator Project // Licensed under GPLv2+ // Refer to the license.txt file included. #include #include #include #include #include #include #include #include "Common/StringUtil.h" #include "InputCommon/ControlReference/ExpressionParser.h" namespace ciface::ExpressionParser { using namespace ciface::Core; enum TokenType { TOK_DISCARD, TOK_INVALID, TOK_EOF, TOK_LPAREN, TOK_RPAREN, TOK_AND, TOK_OR, TOK_NOT, TOK_ADD, TOK_MUL, TOK_DIV, TOK_CONTROL, TOK_LITERAL, }; inline std::string OpName(TokenType op) { switch (op) { case TOK_AND: return "And"; case TOK_OR: return "Or"; case TOK_NOT: return "Not"; case TOK_ADD: return "Add"; case TOK_MUL: return "Mul"; case TOK_DIV: return "Div"; default: assert(false); return ""; } } class Token { public: TokenType type; std::string data; Token(TokenType type_) : type(type_) {} Token(TokenType type_, std::string data_) : type(type_), data(std::move(data_)) {} operator std::string() const { switch (type) { case TOK_DISCARD: return "Discard"; case TOK_EOF: return "EOF"; case TOK_LPAREN: return "("; case TOK_RPAREN: return ")"; case TOK_AND: return "&"; case TOK_OR: return "|"; case TOK_NOT: return "!"; case TOK_ADD: return "+"; case TOK_MUL: return "*"; case TOK_DIV: return "/"; case TOK_CONTROL: return "Device(" + data + ")"; case TOK_LITERAL: return '\'' + data + '\''; case TOK_INVALID: break; } return "Invalid"; } }; class Lexer { public: std::string expr; std::string::iterator it; Lexer(const std::string& expr_) : expr(expr_) { it = expr.begin(); } bool FetchDelimString(std::string& value, char delim) { value = ""; while (it != expr.end()) { char c = *it; ++it; if (c == delim) return true; value += c; } return false; } Token GetLiteral() { std::string value; FetchDelimString(value, '\''); return Token(TOK_LITERAL, value); } Token GetFullyQualifiedControl() { std::string value; FetchDelimString(value, '`'); return Token(TOK_CONTROL, value); } Token GetBarewordsControl(char c) { std::string name; name += c; while (it != expr.end()) { c = *it; if (!isalpha(c)) break; name += c; ++it; } ControlQualifier qualifier; qualifier.control_name = name; return Token(TOK_CONTROL, qualifier); } Token NextToken() { if (it == expr.end()) return Token(TOK_EOF); char c = *it++; switch (c) { case ' ': case '\t': case '\n': case '\r': return Token(TOK_DISCARD); case '(': return Token(TOK_LPAREN); case ')': return Token(TOK_RPAREN); case '&': return Token(TOK_AND); case '|': return Token(TOK_OR); case '!': return Token(TOK_NOT); case '+': return Token(TOK_ADD); case '*': return Token(TOK_MUL); case '/': return Token(TOK_DIV); case '\'': return GetLiteral(); case '`': return GetFullyQualifiedControl(); default: if (isalpha(c)) return GetBarewordsControl(c); else return Token(TOK_INVALID); } } ParseStatus Tokenize(std::vector& tokens) { while (true) { Token tok = NextToken(); if (tok.type == TOK_DISCARD) continue; if (tok.type == TOK_INVALID) { tokens.clear(); return ParseStatus::SyntaxError; } tokens.push_back(tok); if (tok.type == TOK_EOF) break; } return ParseStatus::Successful; } }; class ControlExpression : public Expression { public: ControlQualifier qualifier; Device::Control* control = nullptr; // Keep a shared_ptr to the device so the control pointer doesn't become invalid std::shared_ptr m_device; explicit ControlExpression(ControlQualifier qualifier_) : qualifier(qualifier_) {} ControlState GetValue() const override { if (!control) return 0.0; // Note: Inputs may return negative values in situations where opposing directions are // activated. We clamp off the negative values here. // FYI: Clamping values greater than 1.0 is purposely not done to support unbounded values in // the future. (e.g. raw accelerometer/gyro data) return std::max(0.0, control->ToInput()->GetState()); } void SetValue(ControlState value) override { if (control) control->ToOutput()->SetState(value); } int CountNumControls() const override { return control ? 1 : 0; } void UpdateReferences(ControlFinder& finder) override { m_device = finder.FindDevice(qualifier); control = finder.FindControl(qualifier); } operator std::string() const override { return "`" + static_cast(qualifier) + "`"; } }; class BinaryExpression : public Expression { public: TokenType op; std::unique_ptr lhs; std::unique_ptr rhs; BinaryExpression(TokenType op_, std::unique_ptr&& lhs_, std::unique_ptr&& rhs_) : op(op_), lhs(std::move(lhs_)), rhs(std::move(rhs_)) { } ControlState GetValue() const override { ControlState lhsValue = lhs->GetValue(); ControlState rhsValue = rhs->GetValue(); switch (op) { case TOK_AND: return std::min(lhsValue, rhsValue); case TOK_OR: return std::max(lhsValue, rhsValue); case TOK_ADD: return lhsValue + rhsValue; case TOK_MUL: return lhsValue * rhsValue; case TOK_DIV: { const ControlState result = lhsValue / rhsValue; return std::isinf(result) ? 0.0 : result; } default: assert(false); return 0; } } void SetValue(ControlState value) override { // Don't do anything special with the op we have. // Treat "A & B" the same as "A | B". lhs->SetValue(value); rhs->SetValue(value); } int CountNumControls() const override { return lhs->CountNumControls() + rhs->CountNumControls(); } void UpdateReferences(ControlFinder& finder) override { lhs->UpdateReferences(finder); rhs->UpdateReferences(finder); } operator std::string() const override { return OpName(op) + "(" + (std::string)(*lhs) + ", " + (std::string)(*rhs) + ")"; } }; class UnaryExpression : public Expression { public: TokenType op; std::unique_ptr inner; UnaryExpression(TokenType op_, std::unique_ptr&& inner_) : op(op_), inner(std::move(inner_)) { } ControlState GetValue() const override { ControlState value = inner->GetValue(); switch (op) { case TOK_NOT: return 1.0 - value; default: assert(false); return 0; } } void SetValue(ControlState value) override { switch (op) { case TOK_NOT: inner->SetValue(1.0 - value); break; default: assert(false); } } int CountNumControls() const override { return inner->CountNumControls(); } void UpdateReferences(ControlFinder& finder) override { inner->UpdateReferences(finder); } operator std::string() const override { return OpName(op) + "(" + (std::string)(*inner) + ")"; } }; class LiteralExpression : public Expression { public: explicit LiteralExpression(const std::string& str) { // If it fails to parse it will just be the default: 0.0 TryParse(str, &m_value); } ControlState GetValue() const override { return m_value; } void SetValue(ControlState value) override { // Do nothing. } int CountNumControls() const override { return 1; } void UpdateReferences(ControlFinder&) override { // Nothing needed. } operator std::string() const override { return '\'' + ValueToString(m_value) + '\''; } private: ControlState m_value{}; }; // This class proxies all methods to its either left-hand child if it has bound controls, or its // right-hand child. Its intended use is for supporting old-style barewords expressions. class CoalesceExpression : public Expression { public: CoalesceExpression(std::unique_ptr&& lhs, std::unique_ptr&& rhs) : m_lhs(std::move(lhs)), m_rhs(std::move(rhs)) { } ControlState GetValue() const override { return GetActiveChild()->GetValue(); } void SetValue(ControlState value) override { GetActiveChild()->SetValue(value); } int CountNumControls() const override { return GetActiveChild()->CountNumControls(); } operator std::string() const override { return "Coalesce(" + static_cast(*m_lhs) + ", " + static_cast(*m_rhs) + ')'; } void UpdateReferences(ControlFinder& finder) override { m_lhs->UpdateReferences(finder); m_rhs->UpdateReferences(finder); } private: const std::unique_ptr& GetActiveChild() const { return m_lhs->CountNumControls() > 0 ? m_lhs : m_rhs; } std::unique_ptr m_lhs; std::unique_ptr m_rhs; }; std::shared_ptr ControlFinder::FindDevice(ControlQualifier qualifier) const { if (qualifier.has_device) return container.FindDevice(qualifier.device_qualifier); else return container.FindDevice(default_device); } Device::Control* ControlFinder::FindControl(ControlQualifier qualifier) const { const std::shared_ptr device = FindDevice(qualifier); if (!device) return nullptr; if (is_input) return device->FindInput(qualifier.control_name); else return device->FindOutput(qualifier.control_name); } struct ParseResult { ParseResult(ParseStatus status_, std::unique_ptr&& expr_ = {}) : status(status_), expr(std::move(expr_)) { } ParseStatus status; std::unique_ptr expr; }; class Parser { public: explicit Parser(std::vector tokens_) : tokens(tokens_) { m_it = tokens.begin(); } ParseResult Parse() { return Toplevel(); } private: std::vector tokens; std::vector::iterator m_it; Token Chew() { return *m_it++; } Token Peek() { return *m_it; } bool Expects(TokenType type) { Token tok = Chew(); return tok.type == type; } ParseResult Atom() { Token tok = Chew(); switch (tok.type) { case TOK_CONTROL: { ControlQualifier cq; cq.FromString(tok.data); return {ParseStatus::Successful, std::make_unique(cq)}; } case TOK_LITERAL: { return {ParseStatus::Successful, std::make_unique(tok.data)}; } case TOK_LPAREN: return Paren(); default: return {ParseStatus::SyntaxError}; } } bool IsUnaryExpression(TokenType type) { switch (type) { case TOK_NOT: return true; default: return false; } } ParseResult Unary() { if (IsUnaryExpression(Peek().type)) { Token tok = Chew(); ParseResult result = Atom(); if (result.status == ParseStatus::SyntaxError) return result; return {ParseStatus::Successful, std::make_unique(tok.type, std::move(result.expr))}; } return Atom(); } bool IsBinaryToken(TokenType type) { switch (type) { case TOK_AND: case TOK_OR: case TOK_ADD: case TOK_MUL: case TOK_DIV: return true; default: return false; } } ParseResult Binary() { ParseResult result = Unary(); if (result.status == ParseStatus::SyntaxError) return result; std::unique_ptr expr = std::move(result.expr); while (IsBinaryToken(Peek().type)) { Token tok = Chew(); ParseResult unary_result = Unary(); if (unary_result.status == ParseStatus::SyntaxError) { return unary_result; } expr = std::make_unique(tok.type, std::move(expr), std::move(unary_result.expr)); } return {ParseStatus::Successful, std::move(expr)}; } ParseResult Paren() { // lparen already chewed ParseResult result = Toplevel(); if (result.status != ParseStatus::Successful) return result; if (!Expects(TOK_RPAREN)) { return {ParseStatus::SyntaxError}; } return result; } ParseResult Toplevel() { return Binary(); } }; static ParseResult ParseComplexExpression(const std::string& str) { Lexer l(str); std::vector tokens; ParseStatus tokenize_status = l.Tokenize(tokens); if (tokenize_status != ParseStatus::Successful) return {tokenize_status}; return Parser(std::move(tokens)).Parse(); } static std::unique_ptr ParseBarewordExpression(const std::string& str) { ControlQualifier qualifier; qualifier.control_name = str; qualifier.has_device = false; return std::make_unique(qualifier); } std::pair> ParseExpression(const std::string& str) { if (StripSpaces(str).empty()) return std::make_pair(ParseStatus::EmptyExpression, nullptr); auto bareword_expr = ParseBarewordExpression(str); ParseResult complex_result = ParseComplexExpression(str); if (complex_result.status != ParseStatus::Successful) { return std::make_pair(complex_result.status, std::move(bareword_expr)); } auto combined_expr = std::make_unique(std::move(bareword_expr), std::move(complex_result.expr)); return std::make_pair(complex_result.status, std::move(combined_expr)); } } // namespace ciface::ExpressionParser