/* * This file is part of libeval, a simple math expression evaluator * * Copyright (C) 2017 Michael Geselbracht, mgeselbracht3@gmail.com * Copyright (C) 2019-2021 KiCad Developers, see AUTHORS.txt for contributors. * * This program is free software: you can redistribute it and/or modify * it under the terms of the GNU General Public License as published by * the Free Software Foundation, either version 3 of the License, or * (at your option) any later version. * * This program is distributed in the hope that it will be useful, * but WITHOUT ANY WARRANTY; without even the implied warranty of * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the * GNU General Public License for more details. * * You should have received a copy of the GNU General Public License * along with this program. If not, see . */ #include #include #include #include #include #include #ifdef DEBUG #include #endif #include /* The (generated) lemon parser is written in C. * In order to keep its symbol from the global namespace include the parser code with * a C++ namespace. */ namespace LIBEVAL { #ifdef __GNUC__ #pragma GCC diagnostic push #pragma GCC diagnostic ignored "-Wunused-variable" #pragma GCC diagnostic ignored "-Wsign-compare" #endif #include #include #ifdef __GNUC__ #pragma GCC diagnostic pop #endif #define libeval_dbg(level, fmt, ...) \ wxLogTrace( "libeval_compiler", fmt, __VA_ARGS__ ); TREE_NODE* newNode( LIBEVAL::COMPILER* compiler, int op, const T_TOKEN_VALUE& value ) { auto t2 = new TREE_NODE(); t2->valid = true; t2->value.str = value.str ? new wxString( *value.str ) : nullptr; t2->value.num = value.num; t2->value.idx = value.idx; t2->op = op; t2->leaf[0] = nullptr; t2->leaf[1] = nullptr; t2->isTerminal = false; t2->srcPos = compiler->GetSourcePos(); t2->uop = nullptr; libeval_dbg(10, " ostr %p nstr %p nnode %p op %d", value.str, t2->value.str, t2, t2->op ); if(t2->value.str) compiler->GcItem( t2->value.str ); compiler->GcItem( t2 ); return t2; } static const wxString formatOpName( int op ) { static const struct { int op; wxString mnemonic; } simpleOps[] = { { TR_OP_MUL, "MUL" }, { TR_OP_DIV, "DIV" }, { TR_OP_ADD, "ADD" }, { TR_OP_SUB, "SUB" }, { TR_OP_LESS, "LESS" }, { TR_OP_GREATER, "GREATER" }, { TR_OP_LESS_EQUAL, "LESS_EQUAL" }, { TR_OP_GREATER_EQUAL, "GREATER_EQUAL" }, { TR_OP_EQUAL, "EQUAL" }, { TR_OP_NOT_EQUAL, "NEQUAL" }, { TR_OP_BOOL_AND, "AND" }, { TR_OP_BOOL_OR, "OR" }, { TR_OP_BOOL_NOT, "NOT" }, { -1, "" } }; for( int i = 0; simpleOps[i].op >= 0; i++ ) { if( simpleOps[i].op == op ) return simpleOps[i].mnemonic; } return "???"; } bool VALUE::EqualTo( const VALUE* b ) const { if( m_type == VT_UNDEFINED || b->m_type == VT_UNDEFINED ) return false; if( m_type == VT_NUMERIC && b->m_type == VT_NUMERIC ) { return m_valueDbl == b->m_valueDbl; } else if( m_type == VT_STRING && b->m_type == VT_STRING ) { if( b->m_stringIsWildcard ) return WildCompareString( b->m_valueStr, m_valueStr, false ); else return !m_valueStr.CmpNoCase( b->m_valueStr ); } return false; } bool VALUE::NotEqualTo( const VALUE* b ) const { if( m_type == VT_UNDEFINED || b->m_type == VT_UNDEFINED ) return false; return !EqualTo( b ); } wxString UOP::Format() const { wxString str; switch( m_op ) { case TR_UOP_PUSH_VAR: str = wxString::Format( "PUSH VAR [%p]", m_ref.get() ); break; case TR_UOP_PUSH_VALUE: { if( !m_value ) str = wxString::Format( "PUSH nullptr" ); else if( m_value->GetType() == VT_NUMERIC ) str = wxString::Format( "PUSH NUM [%.10f]", m_value->AsDouble() ); else str = wxString::Format( "PUSH STR [%ls]", m_value->AsString() ); } break; case TR_OP_METHOD_CALL: str = wxString::Format( "MCALL" ); break; case TR_OP_FUNC_CALL: str = wxString::Format( "FCALL" ); break; default: str = wxString::Format( "%s %d", formatOpName( m_op ).c_str(), m_op ); break; } return str; } UCODE::~UCODE() { for ( auto op : m_ucode ) { delete op; } } wxString UCODE::Dump() const { wxString rv; for( auto op : m_ucode ) { rv += op->Format(); rv += "\n"; } return rv; }; wxString TOKENIZER::GetChars( const std::function& cond ) const { wxString rv; size_t p = m_pos; while( p < m_str.length() && cond( m_str[p] ) ) { rv.append( 1, m_str[p] ); p++; } return rv; } bool TOKENIZER::MatchAhead( const wxString& match, const std::function& stopCond ) const { int remaining = (int) m_str.Length() - m_pos; if( remaining < (int) match.length() ) return false; if( m_str.substr( m_pos, match.length() ) == match ) return ( remaining == (int) match.length() || stopCond( m_str[m_pos + match.length()] ) ); return false; } COMPILER::COMPILER() : m_lexerState( COMPILER::LS_DEFAULT ) { m_localeDecimalSeparator = '.'; m_sourcePos = 0; m_parseFinished = false; m_unitResolver = std::make_unique(); m_parser = LIBEVAL::ParseAlloc( malloc ); m_tree = nullptr; m_errorStatus.pendingError = false; } COMPILER::~COMPILER() { LIBEVAL::ParseFree( m_parser, free ); if( m_tree ) { freeTree( m_tree ); } // Allow explicit call to destructor m_parser = nullptr; Clear(); } void COMPILER::Clear() { //free( current.token ); m_tokenizer.Clear(); if( m_tree ) { freeTree( m_tree ); m_tree = nullptr; } m_tree = nullptr; for( auto tok : m_gcItems ) delete tok; for( auto tok: m_gcStrings ) delete tok; m_gcItems.clear(); m_gcStrings.clear(); } void COMPILER::parseError( const char* s ) { reportError( CST_PARSE, s ); } void COMPILER::parseOk() { m_parseFinished = true; } bool COMPILER::Compile( const wxString& aString, UCODE* aCode, CONTEXT* aPreflightContext ) { // Feed parser token after token until end of input. newString( aString ); if( m_tree ) { freeTree( m_tree ); m_tree = nullptr; } m_tree = nullptr; m_parseFinished = false; T_TOKEN tok( defaultToken ); libeval_dbg(0, "str: '%s' empty: %d\n", aString.c_str(), !!aString.empty() ); if( aString.empty() ) { m_parseFinished = true; return generateUCode( aCode, aPreflightContext ); } do { m_sourcePos = m_tokenizer.GetPos(); tok = getToken(); if( tok.value.str ) GcItem( tok.value.str ); libeval_dbg(10, "parse: tok %d valstr %p\n", tok.token, tok.value.str ); Parse( m_parser, tok.token, tok, this ); if ( m_errorStatus.pendingError ) return false; if( m_parseFinished || tok.token == G_ENDS ) { // Reset parser by passing zero as token ID, value is ignored. Parse( m_parser, 0, tok, this ); break; } } while( tok.token ); return generateUCode( aCode, aPreflightContext ); } void COMPILER::newString( const wxString& aString ) { Clear(); m_lexerState = LS_DEFAULT; m_tokenizer.Restart( aString ); m_parseFinished = false; } T_TOKEN COMPILER::getToken() { T_TOKEN rv; rv.value.str = nullptr; bool done = false; do { switch( m_lexerState ) { case LS_DEFAULT: done = lexDefault( rv ); break; case LS_STRING: done = lexString( rv ); break; } } while( !done ); return rv; } bool COMPILER::lexString( T_TOKEN& aToken ) { wxString str = m_tokenizer.GetChars( []( int c ) -> bool { return c != '\''; } ); aToken.token = G_STRING; aToken.value.str = new wxString( str ); m_tokenizer.NextChar( str.length() + 1 ); m_lexerState = LS_DEFAULT; return true; } int COMPILER::resolveUnits() { int unitId = 0; for( const wxString& unitName : m_unitResolver->GetSupportedUnits() ) { if( m_tokenizer.MatchAhead( unitName, []( int c ) -> bool { return !isalnum( c ); } ) ) { libeval_dbg(10, "Match unit '%s'\n", unitName.c_str() ); m_tokenizer.NextChar( unitName.length() ); return unitId; } unitId++; } return -1; } bool COMPILER::lexDefault( T_TOKEN& aToken ) { T_TOKEN retval; wxString current; int convertFrom; wxString msg; retval.value.str = nullptr; retval.value.num = 0.0; retval.value.idx = -1; retval.token = G_ENDS; if( m_tokenizer.Done() ) { aToken = retval; return true; } auto isDecimalSeparator = [&]( wxUniChar ch ) -> bool { return ( ch == m_localeDecimalSeparator || ch == '.' || ch == ',' ); }; // Lambda: get value as string, store into clToken.token and update current index. auto extractNumber = [&]() { bool haveSeparator = false; wxUniChar ch = m_tokenizer.GetChar(); do { if( isDecimalSeparator( ch ) && haveSeparator ) break; current.append( 1, ch ); if( isDecimalSeparator( ch ) ) haveSeparator = true; m_tokenizer.NextChar(); ch = m_tokenizer.GetChar(); } while( isdigit( ch ) || isDecimalSeparator( ch ) ); // Ensure that the systems decimal separator is used for( int i = current.length(); i; i-- ) { if( isDecimalSeparator( current[i - 1] ) ) current[i - 1] = m_localeDecimalSeparator; } }; int ch; // Start processing of first/next token: Remove whitespace for( ;; ) { ch = m_tokenizer.GetChar(); if( ch == ' ' ) m_tokenizer.NextChar(); else break; } libeval_dbg(10, "LEX ch '%c' pos %lu\n", ch, (unsigned long)m_tokenizer.GetPos() ); if( ch == 0 ) { /* End of input */ } else if( isdigit( ch ) ) { // VALUE extractNumber(); retval.token = G_VALUE; retval.value.str = new wxString( current ); } else if( ( convertFrom = resolveUnits() ) >= 0 ) { // UNIT // Units are appended to a VALUE. // Determine factor to default unit if unit for value is given. // Example: Default is mm, unit is inch: factor is 25.4 // The factor is assigned to the terminal UNIT. The actual // conversion is done within a parser action. retval.token = G_UNIT; retval.value.idx = convertFrom; } else if( ch == '\'' ) // string literal { m_lexerState = LS_STRING; m_tokenizer.NextChar(); return false; } else if( isalpha( ch ) || ch == '_' ) { current = m_tokenizer.GetChars( []( int c ) -> bool { return isalnum( c ) || c == '_'; } ); retval.token = G_IDENTIFIER; retval.value.str = new wxString( current ); m_tokenizer.NextChar( current.length() ); } else if( m_tokenizer.MatchAhead( "==", []( int c ) -> bool { return c != '='; } ) ) { retval.token = G_EQUAL; m_tokenizer.NextChar( 2 ); } else if( m_tokenizer.MatchAhead( "!=", []( int c ) -> bool { return c != '='; } ) ) { retval.token = G_NOT_EQUAL; m_tokenizer.NextChar( 2 ); } else if( m_tokenizer.MatchAhead( "<=", []( int c ) -> bool { return c != '='; } ) ) { retval.token = G_LESS_EQUAL_THAN; m_tokenizer.NextChar( 2 ); } else if( m_tokenizer.MatchAhead( ">=", []( int c ) -> bool { return c != '='; } ) ) { retval.token = G_GREATER_EQUAL_THAN; m_tokenizer.NextChar( 2 ); } else if( m_tokenizer.MatchAhead( "&&", []( int c ) -> bool { return c != '&'; } ) ) { retval.token = G_BOOL_AND; m_tokenizer.NextChar( 2 ); } else if( m_tokenizer.MatchAhead( "||", []( int c ) -> bool { return c != '|'; } ) ) { retval.token = G_BOOL_OR; m_tokenizer.NextChar( 2 ); } else { // Single char tokens switch( ch ) { case '+': retval.token = G_PLUS; break; case '!': retval.token = G_BOOL_NOT; break; case '-': retval.token = G_MINUS; break; case '*': retval.token = G_MULT; break; case '/': retval.token = G_DIVIDE; break; case '<': retval.token = G_LESS_THAN; break; case '>': retval.token = G_GREATER_THAN; break; case '(': retval.token = G_PARENL; break; case ')': retval.token = G_PARENR; break; case ';': retval.token = G_SEMCOL; break; case '.': retval.token = G_STRUCT_REF; break; case ',': retval.token = G_COMMA; break; default: reportError( CST_PARSE, wxString::Format( _( "Unrecognized character '%c'" ), (char) ch ) ); break; } m_tokenizer.NextChar(); } aToken = retval; return true; } const wxString formatNode( TREE_NODE* node ) { return node->value.str ? *(node->value.str) : ""; } void dumpNode( wxString& buf, TREE_NODE* tok, int depth = 0 ) { wxString str; if( !tok ) return; str.Printf( "\n[%p L0:%-20p L1:%-20p] ", tok, tok->leaf[0], tok->leaf[1] ); buf += str; for( int i = 0; i < 2 * depth; i++ ) buf += " "; if( tok->op & TR_OP_BINARY_MASK ) { buf += formatOpName( tok->op ); dumpNode( buf, tok->leaf[0], depth + 1 ); dumpNode( buf, tok->leaf[1], depth + 1 ); } switch( tok->op ) { case TR_NUMBER: buf += "NUMERIC: "; buf += formatNode( tok ); if( tok->leaf[0] ) dumpNode( buf, tok->leaf[0], depth + 1 ); break; case TR_ARG_LIST: buf += "ARG_LIST: "; buf += formatNode( tok ); if( tok->leaf[0] ) dumpNode( buf, tok->leaf[0], depth + 1 ); if( tok->leaf[1] ) dumpNode( buf, tok->leaf[1], depth + 1 ); break; case TR_STRING: buf += "STRING: "; buf += formatNode( tok ); break; case TR_IDENTIFIER: buf += "ID: "; buf += formatNode( tok ); break; case TR_STRUCT_REF: buf += "SREF: "; dumpNode( buf, tok->leaf[0], depth + 1 ); dumpNode( buf, tok->leaf[1], depth + 1 ); break; case TR_OP_FUNC_CALL: buf += "CALL '"; buf += *tok->leaf[0]->value.str; buf += "': "; dumpNode( buf, tok->leaf[1], depth + 1 ); break; case TR_UNIT: str.Printf( "UNIT: %d ", tok->value.idx ); buf += str; break; } } void CONTEXT::ReportError( const wxString& aErrorMsg ) { if( m_errorCallback ) m_errorCallback( aErrorMsg, -1 ); } void COMPILER::reportError( COMPILATION_STAGE stage, const wxString& aErrorMsg, int aPos ) { if( aPos == -1 ) aPos = m_sourcePos; m_errorStatus.pendingError = true; m_errorStatus.stage = stage; m_errorStatus.message = aErrorMsg; m_errorStatus.srcPos = aPos; if( m_errorCallback ) m_errorCallback( aErrorMsg, aPos ); } void COMPILER::setRoot( TREE_NODE *root ) { m_tree = root; } void COMPILER::freeTree( LIBEVAL::TREE_NODE *tree ) { if ( tree->leaf[0] ) freeTree( tree->leaf[0] ); if ( tree->leaf[1] ) freeTree( tree->leaf[1] ); delete tree->uop; } void TREE_NODE::SetUop( int aOp, double aValue ) { delete uop; std::unique_ptr val = std::make_unique( aValue ); uop = new UOP( aOp, std::move( val ) ); } void TREE_NODE::SetUop( int aOp, const wxString& aValue, bool aStringIsWildcard ) { delete uop; std::unique_ptr val = std::make_unique( aValue, aStringIsWildcard ); uop = new UOP( aOp, std::move( val ) ); } void TREE_NODE::SetUop( int aOp, std::unique_ptr aRef ) { delete uop; uop = new UOP( aOp, std::move( aRef ) ); } void TREE_NODE::SetUop( int aOp, FUNC_CALL_REF aFunc, std::unique_ptr aRef ) { delete uop; uop = new UOP( aOp, std::move( aFunc ), std::move( aRef ) ); } static void prepareTree( LIBEVAL::TREE_NODE *node ) { node->isVisited = false; // fixme: for reasons I don't understand the lemon parser isn't initializing the // leaf node pointers of function name nodes. -JY if( node->op == TR_OP_FUNC_CALL && node->leaf[0] ) { node->leaf[0]->leaf[0] = nullptr; node->leaf[0]->leaf[1] = nullptr; } if ( node->leaf[0] ) prepareTree( node->leaf[0] ); if ( node->leaf[1] ) prepareTree( node->leaf[1] ); } static std::vector squashParamList( TREE_NODE* root ) { std::vector args; if( !root ) { return args; } if( root->op != TR_ARG_LIST && root->op != TR_NULL ) { args.push_back( root ); } else { TREE_NODE *n = root; do { if( n->leaf[1] ) args.push_back(n->leaf[1]); n = n->leaf[0]; } while ( n && n->op == TR_ARG_LIST ); if( n ) { args.push_back( n ); } } std::reverse( args.begin(), args.end() ); for( size_t i = 0; i < args.size(); i++ ) libeval_dbg( 10, "squash arg%d: %s\n", int( i ), *args[i]->value.str ); return args; } bool COMPILER::generateUCode( UCODE* aCode, CONTEXT* aPreflightContext ) { std::vector stack; wxString msg; if( !m_tree ) { std::unique_ptr val = std::make_unique( 1.0 ); // Empty expression returns true aCode->AddOp( new UOP( TR_UOP_PUSH_VALUE, std::move(val) ) ); return true; } prepareTree( m_tree ); stack.push_back( m_tree ); wxString dump; dumpNode( dump, m_tree, 0 ); libeval_dbg( 3, "Tree dump:\n%s\n\n", (const char*) dump.c_str() ); while( !stack.empty() ) { TREE_NODE* node = stack.back(); libeval_dbg( 4, "process node %p [op %d] [stack %lu]\n", node, node->op, (unsigned long)stack.size() ); // process terminal nodes first switch( node->op ) { case TR_OP_FUNC_CALL: // Function call's uop was generated inside TR_STRUCT_REF if( !node->uop ) { reportError( CST_CODEGEN, _( "Unknown parent of function parameters" ), node->srcPos ); } node->isTerminal = true; break; case TR_STRUCT_REF: { // leaf[0]: object // leaf[1]: field (TR_IDENTIFIER) or TR_OP_FUNC_CALL if( node->leaf[0]->op != TR_IDENTIFIER ) { int pos = node->leaf[0]->srcPos; if( node->leaf[0]->value.str ) pos -= static_cast( node->leaf[0]->value.str->length() ); reportError( CST_CODEGEN, _( "Unknown parent of property" ), pos ); node->leaf[0]->isVisited = true; node->leaf[1]->isVisited = true; node->SetUop( TR_UOP_PUSH_VALUE, 0.0 ); node->isTerminal = true; break; } switch( node->leaf[1]->op ) { case TR_IDENTIFIER: { // leaf[0]: object // leaf[1]: field wxString itemName = *node->leaf[0]->value.str; wxString propName = *node->leaf[1]->value.str; std::unique_ptr vref = aCode->CreateVarRef( itemName, propName ); if( !vref ) { msg.Printf( _( "Unrecognized item '%s'" ), itemName ); reportError( CST_CODEGEN, msg, node->leaf[0]->srcPos - (int) itemName.length() ); } else if( vref->GetType() == VT_PARSE_ERROR ) { msg.Printf( _( "Unrecognized property '%s'" ), propName ); reportError( CST_CODEGEN, msg, node->leaf[1]->srcPos - (int) propName.length() ); } node->leaf[0]->isVisited = true; node->leaf[1]->isVisited = true; node->SetUop( TR_UOP_PUSH_VAR, std::move( vref ) ); node->isTerminal = true; break; } case TR_OP_FUNC_CALL: { // leaf[0]: object // leaf[1]: TR_OP_FUNC_CALL // leaf[0]: function name // leaf[1]: parameter wxString itemName = *node->leaf[0]->value.str; std::unique_ptr vref = aCode->CreateVarRef( itemName, "" ); if( !vref ) { msg.Printf( _( "Unrecognized item '%s'" ), itemName ); reportError( CST_CODEGEN, msg, node->leaf[0]->srcPos - (int) itemName.length() ); } wxString functionName = *node->leaf[1]->leaf[0]->value.str; auto func = aCode->CreateFuncCall( functionName ); std::vector params = squashParamList( node->leaf[1]->leaf[1] ); libeval_dbg( 10, "emit func call: %s\n", functionName ); if( !func ) { msg.Printf( _( "Unrecognized function '%s'" ), functionName ); reportError( CST_CODEGEN, msg, node->leaf[0]->srcPos + 1 ); } if( func ) { // Preflight the function call for( TREE_NODE* pnode : params ) { VALUE* param = aPreflightContext->AllocValue(); param->Set( *pnode->value.str ); aPreflightContext->Push( param ); } aPreflightContext->SetErrorCallback( [&]( const wxString& aMessage, int aOffset ) { size_t loc = node->leaf[1]->leaf[1]->srcPos; reportError( CST_CODEGEN, aMessage, (int) loc - 1 ); } ); try { func( aPreflightContext, vref.get() ); aPreflightContext->Pop(); // return value } catch( ... ) { } } node->leaf[0]->isVisited = true; node->leaf[1]->isVisited = true; node->leaf[1]->leaf[0]->isVisited = true; node->leaf[1]->leaf[1]->isVisited = true; // Our non-terminal-node stacking algorithm can't handle doubly-nested // structures so we need to pop a level by replacing the TR_STRUCT_REF with // a TR_OP_FUNC_CALL and its function parameter stack.pop_back(); stack.push_back( node->leaf[1] ); for( TREE_NODE* pnode : params ) stack.push_back( pnode ); node->leaf[1]->SetUop( TR_OP_METHOD_CALL, func, std::move( vref ) ); node->isTerminal = false; break; } default: // leaf[0]: object // leaf[1]: malformed syntax wxString itemName = *node->leaf[0]->value.str; wxString propName = *node->leaf[1]->value.str; std::unique_ptr vref = aCode->CreateVarRef( itemName, propName ); if( !vref ) { msg.Printf( _( "Unrecognized item '%s'" ), itemName ); reportError( CST_CODEGEN, msg, node->leaf[0]->srcPos - (int) itemName.length() ); } msg.Printf( _( "Unrecognized property '%s'" ), propName ); reportError( CST_CODEGEN, msg, node->leaf[0]->srcPos + 1 ); node->leaf[0]->isVisited = true; node->leaf[1]->isVisited = true; node->SetUop( TR_UOP_PUSH_VALUE, 0.0 ); node->isTerminal = true; break; } break; } case TR_NUMBER: { TREE_NODE* son = node->leaf[0]; double value; if( !node->value.str ) { value = 0.0; } else if( son && son->op == TR_UNIT ) { int units = son->value.idx; value = m_unitResolver->Convert( *node->value.str, units ); son->isVisited = true; } else { msg.Printf( _( "Missing units for '%s'| (%s)" ), *node->value.str, m_unitResolver->GetSupportedUnitsMessage() ); reportError( CST_CODEGEN, msg, node->srcPos ); value = DoubleValueFromString( EDA_UNITS::UNSCALED, *node->value.str ); } node->SetUop( TR_UOP_PUSH_VALUE, value ); node->isTerminal = true; break; } case TR_STRING: { wxString str = *node->value.str; bool isWildcard = str.Contains("?") || str.Contains("*"); node->SetUop( TR_UOP_PUSH_VALUE, str, isWildcard ); node->isTerminal = true; break; } case TR_IDENTIFIER: { std::unique_ptr vref = aCode->CreateVarRef( *node->value.str, "" ); if( !vref ) { msg.Printf( _( "Unrecognized item '%s'" ), *node->value.str ); reportError( CST_CODEGEN, msg, node->srcPos - (int) node->value.str->length() ); } node->SetUop( TR_UOP_PUSH_VALUE, std::move( vref ) ); node->isTerminal = true; break; } default: node->SetUop( node->op ); node->isTerminal = ( !node->leaf[0] || node->leaf[0]->isVisited ) && ( !node->leaf[1] || node->leaf[1]->isVisited ); break; } if( !node->isTerminal ) { if( node->leaf[0] && !node->leaf[0]->isVisited ) { stack.push_back( node->leaf[0] ); node->leaf[0]->isVisited = true; continue; } else if( node->leaf[1] && !node->leaf[1]->isVisited ) { stack.push_back( node->leaf[1] ); node->leaf[1]->isVisited = true; } continue; } node->isVisited = true; if( node->uop ) { aCode->AddOp( node->uop ); node->uop = nullptr; } stack.pop_back(); } libeval_dbg(2,"dump: \n%s\n", aCode->Dump().c_str() ); return true; } void UOP::Exec( CONTEXT* ctx ) { switch( m_op ) { case TR_UOP_PUSH_VAR: { VALUE* value = ctx->AllocValue(); if( m_ref ) value->Set( m_ref->GetValue( ctx ) ); ctx->Push( value ); } break; case TR_UOP_PUSH_VALUE: ctx->Push( m_value.get() ); return; case TR_OP_METHOD_CALL: m_func( ctx, m_ref.get() ); return; default: break; } if( m_op & TR_OP_BINARY_MASK ) { LIBEVAL::VALUE* arg2 = ctx->Pop(); LIBEVAL::VALUE* arg1 = ctx->Pop(); double arg2Value = arg2 ? arg2->AsDouble() : 0.0; double arg1Value = arg1 ? arg1->AsDouble() : 0.0; double result; if( ctx->HasErrorCallback() ) { if( arg1 && arg1->GetType() == VT_STRING && arg2 && arg2->GetType() == VT_NUMERIC ) { ctx->ReportError( wxString::Format( _( "Type mismatch between '%s' and %lf" ), arg1->AsString(), arg2->AsDouble() ) ); } else if( arg1 && arg1->GetType() == VT_NUMERIC && arg2 && arg2->GetType() == VT_STRING ) { ctx->ReportError( wxString::Format( _( "Type mismatch between %lf and '%s'" ), arg1->AsDouble(), arg2->AsString() ) ); } } switch( m_op ) { case TR_OP_ADD: result = arg1Value + arg2Value; break; case TR_OP_SUB: result = arg1Value - arg2Value; break; case TR_OP_MUL: result = arg1Value * arg2Value; break; case TR_OP_DIV: result = arg1Value / arg2Value; break; case TR_OP_LESS_EQUAL: result = arg1Value <= arg2Value ? 1 : 0; break; case TR_OP_GREATER_EQUAL: result = arg1Value >= arg2Value ? 1 : 0; break; case TR_OP_LESS: result = arg1Value < arg2Value ? 1 : 0; break; case TR_OP_GREATER: result = arg1Value > arg2Value ? 1 : 0; break; case TR_OP_EQUAL: result = arg1 && arg2 && arg1->EqualTo( arg2 ) ? 1 : 0; break; case TR_OP_NOT_EQUAL: result = arg1 && arg2 && arg1->NotEqualTo( arg2 ) ? 1 : 0; break; case TR_OP_BOOL_AND: result = arg1Value != 0.0 && arg2Value != 0.0 ? 1 : 0; break; case TR_OP_BOOL_OR: result = arg1Value != 0.0 || arg2Value != 0.0 ? 1 : 0; break; default: result = 0.0; break; } auto rp = ctx->AllocValue(); rp->Set( result ); ctx->Push( rp ); return; } else if( m_op & TR_OP_UNARY_MASK ) { LIBEVAL::VALUE* arg1 = ctx->Pop(); double arg1Value = arg1 ? arg1->AsDouble() : 0.0; double result; switch( m_op ) { case TR_OP_BOOL_NOT: result = arg1Value != 0.0 ? 0 : 1; break; default: result = 0.0; break; } auto rp = ctx->AllocValue(); rp->Set( result ); ctx->Push( rp ); return; } } VALUE* UCODE::Run( CONTEXT* ctx ) { static VALUE g_false( 0 ); try { for( UOP* op : m_ucode ) op->Exec( ctx ); } catch(...) { // rules which fail outright should not be fired return &g_false; } if( ctx->SP() == 1 ) { return ctx->Pop(); } else { // If stack is corrupted after execution it suggests a problem with the compiler, not // the rule.... // do not use "assert"; it crashes outright on OSX wxASSERT( ctx->SP() == 1 ); // non-well-formed rules should not be fired on a release build return &g_false; } } } // namespace LIBEVAL