Source Code of jp.ac.kobe_u.cs.prolog.builtin.PRED_java_declared_method0_3

package jp.ac.kobe_u.cs.prolog.builtin;

import java.lang.reflect.InvocationTargetException;
import java.lang.reflect.Method;

import jp.ac.kobe_u.cs.prolog.lang.ExistenceException;
import jp.ac.kobe_u.cs.prolog.lang.IllegalTypeException;
import jp.ac.kobe_u.cs.prolog.lang.JavaException;
import jp.ac.kobe_u.cs.prolog.lang.JavaObjectTerm;
import jp.ac.kobe_u.cs.prolog.lang.JavaPredicate;
import jp.ac.kobe_u.cs.prolog.lang.PInstantiationException;
import jp.ac.kobe_u.cs.prolog.lang.Predicate;
import jp.ac.kobe_u.cs.prolog.lang.Prolog;
import jp.ac.kobe_u.cs.prolog.lang.StructureTerm;
import jp.ac.kobe_u.cs.prolog.lang.SymbolTerm;
import jp.ac.kobe_u.cs.prolog.lang.Term;

/**
 * <code>java_declared_method0/3</code>
 *
 * @author Mutsunori Banbara (banbara@kobe-u.ac.jp)
 * @author Naoyuki Tamura (tamura@kobe-u.ac.jp)
 * @version 1.1
 */
public class PRED_java_declared_method0_3 extends JavaPredicate {
  /**
   *
   */
  private static final long serialVersionUID = -8169648771246605125L;
  private Term arg1, arg2, arg3;

  public PRED_java_declared_method0_3() {
  }

  public PRED_java_declared_method0_3(Term a1, Term a2, Term a3,
      Predicate cont) {
    arg1 = a1;
    arg2 = a2;
    arg3 = a3;
    this.cont = cont;
  }

  @Override
  public void setArgument(Term[] args, Predicate cont) {
    arg1 = args[0];
    arg2 = args[1];
    arg3 = args[2];
    this.cont = cont;
  }

  @Override
  public int arity() {
    return 3;
  }

  @Override
  public String toString() {
    return "java_declared_method0(" + arg1 + "," + arg2 + "," + arg3 + ")";
  }

  @Override
  public Predicate exec(Prolog engine) {
    engine.setB0();
    Term a1, a2, a3;
    a1 = arg1;
    a2 = arg2;
    a3 = arg3;

    Class clazz = null;
    Object instance = null;
    Method[] methods = null;
    Method m = null;
    Object value = null;
    int arity;
    Term[] pArgs = null;
    Object[] jArgs = null;
    String methodName = null;

    // 3rd. argument (unbound variable)
    a3 = a3.dereference();
    if (!a3.isVariable()) {
      throw new IllegalTypeException(this, 3, "variable", a3);
    }
    try {
      // 1st. argument (atom or java term)
      a1 = a1.dereference();
      if (a1.isVariable()) {
        throw new PInstantiationException(this, 1);
      } else if (a1.isSymbol()) { // class
        clazz = Class.forName(((SymbolTerm) a1).name());
      } else if (a1.isJavaObject()) { // instance
        instance = ((JavaObjectTerm) a1).object();
        clazz = ((JavaObjectTerm) a1).getClazz();
      } else {
        throw new IllegalTypeException(this, 1, "atom_or_java", a1);
      }
      // 2nd. argument (atom or callable term)
      a2 = a2.dereference();
      if (a2.isVariable()) {
        throw new PInstantiationException(this, 2);
      } else if (a2.isSymbol()) { // No argument method
        m = clazz.getDeclaredMethod(((SymbolTerm) a2).name());
        m.setAccessible(true);
        value = m.invoke(instance);
      } else if (a2.isStructure()) { // Parameterized method
        methodName = ((StructureTerm) a2).name();
        arity = ((StructureTerm) a2).arity();
        methods = clazz.getDeclaredMethods();
        if (methods.length == 0) {
          throw new ExistenceException(this, 2, "method", a2, "");
        }
        pArgs = ((StructureTerm) a2).args();
        jArgs = new Object[arity];
        for (int i = 0; i < arity; i++) {
          pArgs[i] = pArgs[i].dereference();
          if (!pArgs[i].isJavaObject()) {
            pArgs[i] = new JavaObjectTerm(pArgs[i]);
          }
          jArgs[i] = pArgs[i].toJava();
        }
        for (Method method : methods) {
          if (method.getName().equals(methodName)
              && checkParameterTypes(method.getParameterTypes(),
                  pArgs)) {
            try {
              m = method;
              m.setAccessible(true);
              value = m.invoke(instance, jArgs);
              break; // Succeeds to invoke the method
            } catch (Exception e) {
              m = null; // Back to loop
            }
          }
        }
        if (m == null) {
          throw new ExistenceException(this, 2, "method", a2, "");
        }
      } else {
        throw new IllegalTypeException(this, 2, "callable", a2);
      }
      if (value == null) {
        return cont;
      }
      if (!a3.unify(toPrologTerm(value), engine.trail)) {
        return engine.fail();
      }
      return cont;
    } catch (ClassNotFoundException e) { // Class.forName
      throw new JavaException(this, 1, e);
    } catch (NoSuchMethodException e) { // Class.getDeclaredMethod
      throw new JavaException(this, 2, e);
    } catch (SecurityException e) { // Class.getDeclaredMethods
      throw new JavaException(this, 2, e);
    } catch (IllegalAccessException e) { // Method.invoke
      throw new JavaException(this, 2, e);
    } catch (IllegalArgumentException e) { // Method.invoke
      throw new JavaException(this, 2, e);
    } catch (InvocationTargetException e) { // Method.invoke
      throw new JavaException(this, 2, e);
    } catch (NullPointerException e) { // Method.invoke
      throw new JavaException(this, 2, e);
    }
  }

  private Term toPrologTerm(Object obj) {
    if (Term.instanceOfTerm(obj)) {
      return (Term) obj;
    } else {
      return new JavaObjectTerm(obj);
    }
  }
}