import edu.neu.ccs.demeter.dj.*;
import edu.neu.ccs.demeter.aplib.*;
import java.util.*;
import edu.neu.ccs.demeter.*;
class Main {
  public Main() {
    super();
  }
  public static Main parse(java.io.Reader in) throws ParseException { return new Parser(in)._Main(); }
  public static Main parse(java.io.InputStream in) throws ParseException { return new Parser(in)._Main(); }
  public static Main parse(String s) {
    try { return parse(new java.io.StringReader(s)); }
    catch (ParseException e) {
      throw new RuntimeException(e.toString());
    }
  }

    // define some paths used here for convenience
    static String FClassGraph = " edu.neu.ccs.demeter.aplib.cd.ClassGraph ";
    static String FClassParts = " edu.neu.ccs.demeter.aplib.cd.ClassParts ";
    static String FClassName = " edu.neu.ccs.demeter.aplib.cd.ClassName ";
    static String FIdent = " edu.neu.ccs.demeter.Ident ";
  
  public static void main(String[] args) throws Exception {
    // parse the aspectfile input and extract the two components
    AspectFile af = AspectFile.parse(System.in);
    ClassDictionaryAspect cda = af.get_cdAspect();
    TraversalAspect ta = af.get_tAspect();

    // create a new SemanticChecker, provide it with the two components,
    // and do the checking
    SemanticChecker sc = new SemanticChecker();
	sc.generate(cda, ta);
    sc.check();
  }
  void universal_trv0_bef(UniversalVisitor _v_) {
    ((UniversalVisitor) _v_).before(this);
  }

  void universal_trv0_aft(UniversalVisitor _v_) {
    ((UniversalVisitor) _v_).after(this);
  }

  void universal_trv0(UniversalVisitor _v_) {
    universal_trv0_bef(_v_);
    universal_trv0_aft(_v_);
  }

}