/* -*- Mode: C++; tab-width: 4; indent-tabs-mode: nil; c-basic-offset: 4 -*- */ /* * This file is part of the LibreOffice project. * * This Source Code Form is subject to the terms of the Mozilla Public * License, v. 2.0. If a copy of the MPL was not distributed with this * file, You can obtain one at http://mozilla.org/MPL/2.0/. * * This file incorporates work covered by the following license notice: * * Licensed to the Apache Software Foundation (ASF) under one or more * contributor license agreements. See the NOTICE file distributed * with this work for additional information regarding copyright * ownership. The ASF licenses this file to you under the Apache * License, Version 2.0 (the "License"); you may not use this file * except in compliance with the License. You may obtain a copy of * the License at http://www.apache.org/licenses/LICENSE-2.0 . */ // Makes parser a static resource, // we're synchronized externally. // But watch out, the parser might have // state not visible to this code! #define BOOST_SPIRIT_SINGLE_GRAMMAR_INSTANCE #if OSL_DEBUG_LEVEL >= 2 && defined(DBG_UTIL) #include #define BOOST_SPIRIT_DEBUG #endif #include #include "RowFunctionParser.hxx" #include #include #if (OSL_DEBUG_LEVEL > 0) #include #endif #include #include #include namespace connectivity { using namespace com::sun::star; namespace { // EXPRESSION NODES class ConstantValueExpression : public ExpressionNode { ORowSetValueDecoratorRef maValue; public: explicit ConstantValueExpression( ORowSetValueDecoratorRef const & rValue ) : maValue( rValue ) { } virtual ORowSetValueDecoratorRef evaluate(const ODatabaseMetaDataResultSet::ORow& /*_aRow*/ ) const override { return maValue; } virtual void fill(const ODatabaseMetaDataResultSet::ORow& /*_aRow*/ ) const override { } }; /** ExpressionNode implementation for unary function over two ExpressionNodes */ class BinaryFunctionExpression : public ExpressionNode { const ExpressionFunct meFunct; std::shared_ptr mpFirstArg; std::shared_ptr mpSecondArg; public: BinaryFunctionExpression( const ExpressionFunct eFunct, const std::shared_ptr& rFirstArg, const std::shared_ptr& rSecondArg ) : meFunct( eFunct ), mpFirstArg( rFirstArg ), mpSecondArg( rSecondArg ) { } virtual ORowSetValueDecoratorRef evaluate(const ODatabaseMetaDataResultSet::ORow& _aRow ) const override { ORowSetValueDecoratorRef aRet; switch(meFunct) { case ENUM_FUNC_EQUATION: aRet = new ORowSetValueDecorator( mpFirstArg->evaluate(_aRow )->getValue() == mpSecondArg->evaluate(_aRow )->getValue() ); break; case ENUM_FUNC_AND: aRet = new ORowSetValueDecorator( mpFirstArg->evaluate(_aRow )->getValue().getBool() && mpSecondArg->evaluate(_aRow )->getValue().getBool() ); break; case ENUM_FUNC_OR: aRet = new ORowSetValueDecorator( mpFirstArg->evaluate(_aRow )->getValue().getBool() || mpSecondArg->evaluate(_aRow )->getValue().getBool() ); break; default: break; } return aRet; } virtual void fill(const ODatabaseMetaDataResultSet::ORow& _aRow ) const override { switch(meFunct) { case ENUM_FUNC_EQUATION: (*mpFirstArg->evaluate(_aRow )) = mpSecondArg->evaluate(_aRow )->getValue(); break; default: break; } } }; // FUNCTION PARSER typedef const sal_Char* StringIteratorT; struct ParserContext { typedef ::std::stack< std::shared_ptr > OperandStack; // stores a stack of not-yet-evaluated operands. This is used // by the operators (i.e. '+', '*', 'sin' etc.) to pop their // arguments from. If all arguments to an operator are constant, // the operator pushes a precalculated result on the stack, and // a composite ExpressionNode otherwise. OperandStack maOperandStack; }; typedef std::shared_ptr< ParserContext > ParserContextSharedPtr; /** Generate apriori constant value */ class ConstantFunctor { ParserContextSharedPtr mpContext; public: explicit ConstantFunctor( const ParserContextSharedPtr& rContext ) : mpContext( rContext ) { } void operator()( StringIteratorT rFirst,StringIteratorT rSecond) const { OUString sVal( rFirst, rSecond - rFirst, RTL_TEXTENCODING_UTF8 ); mpContext->maOperandStack.push( std::shared_ptr( new ConstantValueExpression( new ORowSetValueDecorator( sVal ) ) ) ); } }; /** Generate parse-dependent-but-then-constant value */ class IntConstantFunctor { ParserContextSharedPtr mpContext; public: explicit IntConstantFunctor( const ParserContextSharedPtr& rContext ) : mpContext( rContext ) { } void operator()( sal_Int32 n ) const { mpContext->maOperandStack.push( std::shared_ptr( new ConstantValueExpression( new ORowSetValueDecorator( n ) ) ) ); } }; /** Implements a binary function over two ExpressionNodes @tpl Generator Generator functor, to generate an ExpressionNode of appropriate type */ class BinaryFunctionFunctor { const ExpressionFunct meFunct; ParserContextSharedPtr mpContext; public: BinaryFunctionFunctor( const ExpressionFunct eFunct, const ParserContextSharedPtr& rContext ) : meFunct( eFunct ), mpContext( rContext ) { } void operator()( StringIteratorT, StringIteratorT ) const { ParserContext::OperandStack& rNodeStack( mpContext->maOperandStack ); if( rNodeStack.size() < 2 ) throw ParseError( "Not enough arguments for binary operator" ); // retrieve arguments std::shared_ptr pSecondArg( rNodeStack.top() ); rNodeStack.pop(); std::shared_ptr pFirstArg( rNodeStack.top() ); rNodeStack.pop(); // create combined ExpressionNode std::shared_ptr pNode = std::shared_ptr( new BinaryFunctionExpression( meFunct, pFirstArg, pSecondArg ) ); // check for constness rNodeStack.push( pNode ); } }; /** ExpressionNode implementation for unary function over one ExpressionNode */ class UnaryFunctionExpression : public ExpressionNode { std::shared_ptr mpArg; public: explicit UnaryFunctionExpression( const std::shared_ptr& rArg ) : mpArg( rArg ) { } virtual ORowSetValueDecoratorRef evaluate(const ODatabaseMetaDataResultSet::ORow& _aRow ) const override { return _aRow[mpArg->evaluate(_aRow )->getValue().getInt32()]; } virtual void fill(const ODatabaseMetaDataResultSet::ORow& /*_aRow*/ ) const override { } }; class UnaryFunctionFunctor { ParserContextSharedPtr mpContext; public: explicit UnaryFunctionFunctor(const ParserContextSharedPtr& rContext) : mpContext(rContext) { } void operator()( StringIteratorT, StringIteratorT ) const { ParserContext::OperandStack& rNodeStack( mpContext->maOperandStack ); if( rNodeStack.size() < 1 ) throw ParseError( "Not enough arguments for unary operator" ); // retrieve arguments std::shared_ptr pArg( rNodeStack.top() ); rNodeStack.pop(); rNodeStack.push( std::shared_ptr( new UnaryFunctionExpression( pArg ) ) ); } }; /* This class implements the following grammar (more or less literally written down below, only slightly obfuscated by the parser actions): basic_expression = number | '(' additive_expression ')' unary_expression = basic_expression multiplicative_expression = unary_expression ( ( '*' unary_expression )* | ( '/' unary_expression )* ) additive_expression = multiplicative_expression ( ( '+' multiplicative_expression )* | ( '-' multiplicative_expression )* ) */ class ExpressionGrammar : public ::boost::spirit::grammar< ExpressionGrammar > { public: /** Create an arithmetic expression grammar @param rParserContext Contains context info for the parser */ explicit ExpressionGrammar( const ParserContextSharedPtr& rParserContext ) : mpParserContext( rParserContext ) { } template< typename ScannerT > class definition { public: // grammar definition explicit definition( const ExpressionGrammar& self ) { using ::boost::spirit::space_p; using ::boost::spirit::range_p; using ::boost::spirit::lexeme_d; using ::boost::spirit::ch_p; using ::boost::spirit::int_p; using ::boost::spirit::as_lower_d; using ::boost::spirit::strlit; using ::boost::spirit::inhibit_case; typedef inhibit_case > token_t; token_t COLUMN = as_lower_d[ "column" ]; token_t OR_ = as_lower_d[ "or" ]; token_t AND_ = as_lower_d[ "and" ]; integer = int_p [IntConstantFunctor(self.getContext())]; argument = integer | lexeme_d[ +( range_p('a','z') | range_p('A','Z') | range_p('0','9') ) ] [ ConstantFunctor(self.getContext()) ] ; unaryFunction = (COLUMN >> '(' >> integer >> ')' ) [ UnaryFunctionFunctor( self.getContext()) ] ; assignment = unaryFunction >> ch_p('=') >> argument [ BinaryFunctionFunctor( ENUM_FUNC_EQUATION, self.getContext()) ] ; andExpression = assignment | ( '(' >> orExpression >> ')' ) | ( assignment >> AND_ >> assignment ) [ BinaryFunctionFunctor( ENUM_FUNC_AND, self.getContext()) ] ; orExpression = andExpression | ( orExpression >> OR_ >> andExpression ) [ BinaryFunctionFunctor( ENUM_FUNC_OR, self.getContext()) ] ; basicExpression = orExpression ; BOOST_SPIRIT_DEBUG_RULE(basicExpression); BOOST_SPIRIT_DEBUG_RULE(unaryFunction); BOOST_SPIRIT_DEBUG_RULE(assignment); BOOST_SPIRIT_DEBUG_RULE(argument); BOOST_SPIRIT_DEBUG_RULE(integer); BOOST_SPIRIT_DEBUG_RULE(orExpression); BOOST_SPIRIT_DEBUG_RULE(andExpression); } const ::boost::spirit::rule< ScannerT >& start() const { return basicExpression; } private: // the constituents of the Spirit arithmetic expression grammar. // For the sake of readability, without 'ma' prefix. ::boost::spirit::rule< ScannerT > basicExpression; ::boost::spirit::rule< ScannerT > unaryFunction; ::boost::spirit::rule< ScannerT > assignment; ::boost::spirit::rule< ScannerT > integer,argument; ::boost::spirit::rule< ScannerT > orExpression,andExpression; }; const ParserContextSharedPtr& getContext() const { return mpParserContext; } private: ParserContextSharedPtr mpParserContext; // might get modified during parsing }; #ifdef BOOST_SPIRIT_SINGLE_GRAMMAR_INSTANCE const ParserContextSharedPtr& getParserContext() { static ParserContextSharedPtr lcl_parserContext( new ParserContext() ); // clear node stack (since we reuse the static object, that's // the whole point here) while( !lcl_parserContext->maOperandStack.empty() ) lcl_parserContext->maOperandStack.pop(); return lcl_parserContext; } #endif } std::shared_ptr FunctionParser::parseFunction( const OUString& _sFunction) { // TODO(Q1): Check if a combination of the RTL_UNICODETOTEXT_FLAGS_* // gives better conversion robustness here (we might want to map space // etc. to ASCII space here) const OString& rAsciiFunction( OUStringToOString( _sFunction, RTL_TEXTENCODING_ASCII_US ) ); StringIteratorT aStart( rAsciiFunction.getStr() ); StringIteratorT aEnd( rAsciiFunction.getStr()+rAsciiFunction.getLength() ); ParserContextSharedPtr pContext; #ifdef BOOST_SPIRIT_SINGLE_GRAMMAR_INSTANCE // static parser context, because the actual // Spirit parser is also a static object pContext = getParserContext(); #else pContext.reset( new ParserContext() ); #endif ExpressionGrammar aExpressionGrammer( pContext ); const ::boost::spirit::parse_info aParseInfo( ::boost::spirit::parse( aStart, aEnd, aExpressionGrammer, ::boost::spirit::space_p ) ); #if (OSL_DEBUG_LEVEL > 0) ::std::cout.flush(); // needed to keep stdout and cout in sync #endif // input fully congested by the parser? if( !aParseInfo.full ) throw ParseError( "RowFunctionParser::parseFunction(): string not fully parseable" ); // parser's state stack now must contain exactly _one_ ExpressionNode, // which represents our formula. if( pContext->maOperandStack.size() != 1 ) throw ParseError( "RowFunctionParser::parseFunction(): incomplete or empty expression" ); return pContext->maOperandStack.top(); } } /* vim:set shiftwidth=4 softtabstop=4 expandtab: */