Ejemplo n.º 1
0
asCScriptNode *asCParser::ParseStatement()
{
	sToken t1;

	GetToken(&t1);
	RewindTo(&t1);

	if( t1.type == ttIf )
		return ParseIf();
	else if( t1.type == ttFor )
		return ParseFor();
	else if( t1.type == ttWhile )
		return ParseWhile();
	else if( t1.type == ttReturn )
		return ParseReturn();
	else if( t1.type == ttStartStatementBlock )
		return ParseStatementBlock();
	else if( t1.type == ttBreak )
		return ParseBreak();
	else if( t1.type == ttContinue )
		return ParseContinue();
	else if( t1.type == ttDo )
		return ParseDoWhile();
	else if( t1.type == ttSwitch )
		return ParseSwitch();
	else
		return ParseExpressionStatement();
}
Ejemplo n.º 2
0
Statement *Statement::ParseIf() 
{
	Statement *snp; 

	dfs.puts("<ParseIf>");
	NextToken();
	if (lastst == kw_firstcall)
		return (ParseFirstcall());
	currentFn->UsesPredicate = TRUE;
	snp = NewStatement(st_if, FALSE);
	snp->predreg = iflevel;
	iflevel++;
	if ((iflevel > maxPn-1) && isThor)
		error(ERR_OUTOFPREDS);
	if( lastst != openpa ) 
		error(ERR_EXPREXPECT); 
	else {
		NextToken(); 
		if( expression(&(snp->exp)) == 0 ) 
			error(ERR_EXPREXPECT); 
		if (lastst == semicolon) {
			NextToken();
			snp->prediction = (GetIntegerExpression(NULL) & 1) | 2;
		}
		needpunc( closepa,19 ); 
		if (lastst==kw_then)
			NextToken();
		snp->s1 = Statement::Parse(); 
		if (snp->s1)
			snp->s1->outer = snp;
		if( lastst == kw_else ) { 
			NextToken(); 
			snp->s2 = Statement::Parse(); 
			if (snp->s2)
				snp->s2->outer = snp;
		} 
		else if (lastst == kw_elsif) {
			snp->s2 = ParseIf(); 
			if (snp->s2)
				snp->s2->outer = snp;
		}
		else 
			snp->s2 = 0; 
	} 
	iflevel--;
	dfs.puts("</ParseIf>");
	return snp; 
} 
Ejemplo n.º 3
0
NodeStatement* Parser::ParseElement()
{
	if (t.GetValue() == "begin")
		return ParseBlock();
	if (t.GetValue() == "if") 
		return ParseIf();
	if (t.GetValue() == "while")
		return ParseWhile();
	if (t.GetValue() == "repeat")
		return ParseRepeat();
	if (t.GetValue() == "for")
		return ParseFor();
	if (t.GetValue() == "write")
		return ParseWrite(true, false);
	if (t.GetValue() == "writeln")
		return ParseWrite(true, true);
	if (t.GetValue() == "exit")
	{
		t = sc.GetNextToken();
		return new StatementExit(true);
	}
	if (t.GetType() == identifier)
	{
		bool found = false;
		_Table::iterator it = TableStack.Find(t.GetValue(), found);
		if (found)
		{
			if (it->second->IsProc() || it->second->IsFunc())
			{
				t = sc.GetNextToken();
				return ParseSub((SymProc*)it->second);
			}
		}
		return ParseAssignment();
	}
	if (t.GetValue() == "(")
	{
		return ParseAssignment();
	}
	throw Error("Statement error", t);
}
Ejemplo n.º 4
0
static void ParseStatement (scontext_t owner)
{
	if (StatementIndex == MAX_STATEMENT_DEPTH)
	{
		PR_ParseError("statement overflow");
	}
	ContextHistory[StatementIndex++] = owner;

	if (TK_CHECK(TK_LBRACE))
	{
		ContextLevel += EnterContext[owner];
		do
		{
			ParseStatement(owner);
		} while (!TK_CHECK(TK_RBRACE));

		ContextLevel -= EnterContext[owner];
		StatementIndex--;
		return;
	}

	if (TK_CHECK(TK_SEMICOLON))
	{
		StatementIndex--;
		return;
	}
	if (LX_CheckFetch("return"))
	{
		ParseReturn();
		StatementIndex--;
		return;
	}
	if (LX_CheckFetch("loop"))
	{
		ParseLoop();
		StatementIndex--;
		return;
	}
	if (LX_CheckFetch("while"))
	{
		ParseWhile();
		StatementIndex--;
		return;
	}
	if (LX_CheckFetch("until"))
	{
		ParseUntil();
		StatementIndex--;
		return;
	}
	if (LX_CheckFetch("do"))
	{
		ParseDo();
		StatementIndex--;
		return;
	}
	if (LX_CheckFetch("switch"))
	{
		ParseSwitch();
		StatementIndex--;
		return;
	}
	if (LX_CheckFetch("case"))
	{
		if (owner != SCONTEXT_SWITCH)
		{
			PR_ParseError("misplaced case");
		}
		ParseCase();
		StatementIndex--;
		return;
	}
	if (LX_CheckFetch("break"))
	{
		if (BreakAncestor() == false)
		{
			PR_ParseError("misplaced break");
		}
		ParseBreak();
		StatementIndex--;
		return;
	}
	if (LX_CheckFetch("continue"))
	{
		if (ContinueAncestor() == false)
		{
			PR_ParseError("misplaced continue");
		}
		ParseContinue();
		StatementIndex--;
		return;
	}
	if (LX_CheckFetch("default"))
	{
		ParseDefault();
		StatementIndex--;
		return;
	}
	if (LX_CheckFetch("thinktime"))
	{
		ParseThinktime();
		StatementIndex--;
		return;
	}
	if (LX_CheckFetch("local"))
	{
		ParseLocalDefs();
		StatementIndex--;
		return;
	}
	if (LX_Check("float") || LX_Check("vector")
		|| LX_Check("entity") || LX_Check("string")
		|| LX_Check("void"))
	{
		ParseLocalDefs();
		StatementIndex--;
		return;
	}
	if (LX_CheckFetch("if"))
	{
		ParseIf();
		StatementIndex--;
		return;
	}

	EX_Expression(TOP_PRIORITY);
	LX_Require(";");
	StatementIndex--;
}
void Preprocessor::RecursivePreprocess( std::string filename, FileLoader& file_source, LexemList& lexems, DefineTable& define_table )
{
    unsigned int start_line = CurrentLine;
    LinesThisFile = 0;
    CurrentFile = filename;
    SetFileMacro( define_table, CurrentFile );
    SetLineMacro( define_table, LinesThisFile );

    // Path formatting must be done in main application
    std::string CurrentFileRoot = RootPath + CurrentFile;
    if( std::find( FilesPreprocessed.begin(), FilesPreprocessed.end(), CurrentFileRoot ) == FilesPreprocessed.end() )
        FilesPreprocessed.push_back( CurrentFileRoot );

    std::vector<char> data;
    bool              loaded = file_source.LoadFile( RootPath, filename, data );
    if( !loaded )
    {
        PrintErrorMessage( std::string( "Could not open file " ) + RootPath + filename );
        return;
    }

    if( data.size() == 0 )
        return;
    char* d_end = &data[data.size() - 1];
    ++d_end;
    Lex( &data[0], d_end, lexems );

    LexemList::iterator itr = lexems.begin();
    LexemList::iterator end = lexems.end();
    LLITR               old = end;
    while( itr != end )
    {
        if( itr->Type == Lexem::NEWLINE )
        {
            if( itr != old )
            {
                CurrentLine++;
                LinesThisFile++;
                SetLineMacro( define_table, LinesThisFile );
            }
            old = itr;
            ++itr;
        }
        else if( itr->Type == Lexem::PREPROCESSOR )
        {
            LLITR     start_of_line = itr;
            LLITR     end_of_line = ParsePreprocessor( lexems, itr, end );

            LexemList directive( start_of_line, end_of_line );

            if( SkipPragmas && directive.begin()->Value == "#pragma" )
            {
                itr = end_of_line;
                Lexem wspace;
                wspace.Type = Lexem::WHITESPACE;
                wspace.Value = " ";
                for( LLITR it = start_of_line; it != end_of_line;)
                {
                    ++it;
                    it = lexems.insert( it, wspace );
                    ++it;
                }
                continue;
            }

            itr = lexems.erase( start_of_line, end_of_line );

            std::string value = directive.begin()->Value;
            if( value == "#define" )
            {
                ParseDefine( define_table, directive );
            }
            else if( value == "#ifdef" )
            {
                std::string           def_name;
                ParseIf( directive, def_name );
                DefineTable::iterator dti = define_table.find( def_name );
                if( dti == define_table.end() )
                {
                    LLITR splice_to = ParseIfDef( itr, end );
                    itr = lexems.erase( itr, splice_to );
                }
            }
            else if( value == "#ifndef" )
            {
                std::string           def_name;
                ParseIf( directive, def_name );
                DefineTable::iterator dti = define_table.find( def_name );
                if( dti != define_table.end() )
                {
                    LLITR splice_to = ParseIfDef( itr, end );
                    itr = lexems.erase( itr, splice_to );
                }
            }
            else if( value == "#if" )
            {
                bool satisfied = EvaluateExpression( define_table, directive ) != 0;
                if( !satisfied )
                {
                    LLITR splice_to = ParseIfDef( itr, end );
                    itr = lexems.erase( itr, splice_to );
                }
            }
            else if( value == "#endif" )
            {
                // ignore
            }
            else if( value == "#include" )
            {
                if( LNT )
                    LNT->AddLineRange( PrependRootPath( filename ), start_line, CurrentLine - LinesThisFile );
                unsigned int save_lines_this_file = LinesThisFile;
                std::string  file_name;
                ParseIf( directive, file_name );

                std::string file_name_ = RemoveQuotes( file_name );
                if( IncludeTranslator )
                    IncludeTranslator->Call( file_name_ );
                if( std::find( FileDependencies.begin(), FileDependencies.end(), file_name_ ) == FileDependencies.end() )
                    FileDependencies.push_back( file_name_ );

                LexemList next_file;
                RecursivePreprocess( AddPaths( filename, file_name_ ), file_source, next_file, define_table );
                lexems.splice( itr, next_file );
                start_line = CurrentLine;
                LinesThisFile = save_lines_this_file;
                CurrentFile = filename;
                SetFileMacro( define_table, CurrentFile );
                SetLineMacro( define_table, LinesThisFile );
            }
            else if( value == "#pragma" )
            {
                ParsePragma( directive );
            }
            else if( value == "#message" )
            {
                std::string message;
                ParseTextLine( directive, message );
                PrintMessage( message );
            }
            else if( value == "#warning" )
            {
                std::string warning;
                ParseTextLine( directive, warning );
                PrintWarningMessage( warning );
            }
            else if( value == "#error" )
            {
                std::string error;
                ParseTextLine( directive, error );
                PrintErrorMessage( error );
            }
            else
            {
                PrintErrorMessage( "Unknown directive '" + value + "'." );
            }
        }
        else if( itr->Type == Lexem::IDENTIFIER )
        {
            itr = ExpandDefine( itr, end, lexems, define_table );
        }
        else
        {
            ++itr;
        }
    }

    if( LNT )
        LNT->AddLineRange( PrependRootPath( filename ), start_line, CurrentLine - LinesThisFile );
}
Ejemplo n.º 6
0
/* ParseStatement - parse a statement */
void ParseStatement(ParseContext *c, Token tkn)
{
    /* dispatch on the statement keyword */
    switch (tkn) {
    case T_REM:
        /* just a comment so ignore the rest of the line */
        break;
    case T_DEF:
        ParseDef(c);
        break;
    case T_END_DEF:
        ParseEndDef(c);
        break;
    case T_DIM:
        ParseDim(c);
        break;
    case T_LET:
        ParseLet(c);
        break;
    case T_IF:
        ParseIf(c);
        break;
    case T_ELSE:
        ParseElse(c);
        break;
    case T_ELSE_IF:
        ParseElseIf(c);
        break;
    case T_END_IF:
        ParseEndIf(c);
        break;
    case T_END:
        ParseEnd(c);
        break;
    case T_FOR:
        ParseFor(c);
        break;
    case T_NEXT:
        ParseNext(c);
        break;
    case T_DO:
        ParseDo(c);
        break;
    case T_DO_WHILE:
        ParseDoWhile(c);
        break;
    case T_DO_UNTIL:
        ParseDoUntil(c);
        break;
    case T_LOOP:
        ParseLoop(c);
        break;
    case T_LOOP_WHILE:
        ParseLoopWhile(c);
        break;
    case T_LOOP_UNTIL:
        ParseLoopUntil(c);
        break;
    case T_STOP:
        ParseStop(c);
        break;
    case T_GOTO:
        ParseGoto(c);
        break;
    case T_RETURN:
        ParseReturn(c);
        break;
    case T_PRINT:
        ParsePrint(c);
        break;
    case T_IDENTIFIER:
        if (SkipSpaces(c) == ':') {
            DefineLabel(c, c->token, codeaddr(c));
            break;
        }
        UngetC(c);
    default:
        SaveToken(c, tkn);
        ParseImpliedLetOrFunctionCall(c);
        break;
    }
}
Ejemplo n.º 7
0
ExprNode* Parser :: ParseStatement(){
    Token *token = scan.Get();
    ExprNode* Statement;
    if(token->Value == "if")
        return ParseIf();
    if(token->Value == "for"){
        if (isCanUseBreak){

            CycleStatement = ParseFor();
            Statement = CycleStatement;
        }
        else

        {
            isCanUseBreak = true;
            CycleStatement = ParseFor();
            Statement = CycleStatement;
            isCanUseBreak = false;
        }
        return Statement;

    }
    if(token->Value == "while"){
        if (isCanUseBreak){
            CycleStatement = ParseWhile();
            Statement = CycleStatement;
        }
        else

        {
            isCanUseBreak = true;

            CycleStatement = ParseWhile();
            Statement = CycleStatement;
            CycleStatement = nullptr;
            isCanUseBreak = false;

        }

        return Statement;

    }
    if(token->Value == "do"){
        if (CycleStatement){
            CycleStatement = ParseDoWhile();
            Statement = CycleStatement;
        }
        else

        {
            isCanUseBreak = true;

            CycleStatement = ParseDoWhile();
            Statement = CycleStatement;
            CycleStatement = nullptr;
            isCanUseBreak = false;

        }

        return Statement;
    }
    //    if(isEq(token, _SEPARATION, "("))
    //        return ParseBlock();
    if(token->Value == "return" || token->Value == "break" || token->Value == "continue")
        return ParseJumpStatement();
    else
        return ParseExpr();
    int *a  ;
     int s = a - a;
    s++;


}