/* * Copyright 2000-2010 Sun Microsystems, Inc. All Rights Reserved. * DO NOT ALTER OR REMOVE COPYRIGHT NOTICES OR THIS FILE HEADER. * * This code is free software; you can redistribute it and/or modify it * under the terms of the GNU General Public License version 2 only, as * published by the Free Software Foundation. Sun designates this * particular file as subject to the "Classpath" exception as provided * by Sun in the LICENSE file that accompanied this code. * * This code 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 * version 2 for more details (a copy is included in the LICENSE file that * accompanied this code). * * You should have received a copy of the GNU General Public License version * 2 along with this work; if not, write to the Free Software Foundation, * Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA. * * Please contact Sun Microsystems, Inc., 4150 Network Circle, Santa Clara, * CA 95054 USA or visit www.sun.com if you need additional information or * have any questions. */ package java.beans; import java.lang.reflect.AccessibleObject; import java.lang.reflect.Array; import java.lang.reflect.Constructor; import java.lang.reflect.InvocationTargetException; import java.lang.reflect.Method; import com.sun.beans.finder.ClassFinder; import com.sun.beans.finder.ConstructorFinder; import com.sun.beans.finder.MethodFinder; import sun.reflect.misc.MethodUtil; /** * A Statement object represents a primitive statement * in which a single method is applied to a target and * a set of arguments - as in "a.setFoo(b)". * Note that where this example uses names * to denote the target and its argument, a statement * object does not require a name space and is constructed with * the values themselves. * The statement object associates the named method * with its environment as a simple set of values: * the target and an array of argument values. * * @since 1.4 * * @author Philip Milne */ public class Statement { private static Object[] emptyArray = new Object[]{}; static ExceptionListener defaultExceptionListener = new ExceptionListener() { public void exceptionThrown(Exception e) { System.err.println(e); // e.printStackTrace(); System.err.println("Continuing ..."); } }; Object target; String methodName; Object[] arguments; ClassLoader loader; /** * Creates a new {@link Statement} object * for the specified target object to invoke the method * specified by the name and by the array of arguments. *

* The {@code target} and the {@code methodName} values should not be {@code null}. * Otherwise an attempt to execute this {@code Expression} * will result in a {@code NullPointerException}. * If the {@code arguments} value is {@code null}, * an empty array is used as the value of the {@code arguments} property. * * @param target the target object of this statement * @param methodName the name of the method to invoke on the specified target * @param arguments the array of arguments to invoke the specified method */ @ConstructorProperties({"target", "methodName", "arguments"}) public Statement(Object target, String methodName, Object[] arguments) { this.target = target; this.methodName = methodName; this.arguments = (arguments == null) ? emptyArray : arguments; } /** * Returns the target object of this statement. * If this method returns {@code null}, * the {@link #execute} method * throws a {@code NullPointerException}. * * @return the target object of this statement */ public Object getTarget() { return target; } /** * Returns the name of the method to invoke. * If this method returns {@code null}, * the {@link #execute} method * throws a {@code NullPointerException}. * * @return the name of the method */ public String getMethodName() { return methodName; } /** * Returns the arguments for the method to invoke. * The number of arguments and their types * must match the method being called. * {@code null} can be used as a synonym of an empty array. * * @return the array of arguments */ public Object[] getArguments() { return arguments; } /** * The {@code execute} method finds a method whose name is the same * as the {@code methodName} property, and invokes the method on * the target. * * When the target's class defines many methods with the given name * the implementation should choose the most specific method using * the algorithm specified in the Java Language Specification * (15.11). The dynamic class of the target and arguments are used * in place of the compile-time type information and, like the * {@link java.lang.reflect.Method} class itself, conversion between * primitive values and their associated wrapper classes is handled * internally. *

* The following method types are handled as special cases: *

* * @throws NullPointerException if the value of the {@code target} or * {@code methodName} property is {@code null} * @throws NoSuchMethodException if a matching method is not found * @throws SecurityException if a security manager exists and * it denies the method invocation * @throws Exception that is thrown by the invoked method * * @see java.lang.reflect.Method */ public void execute() throws Exception { invoke(); } Object invoke() throws Exception { Object target = getTarget(); String methodName = getMethodName(); if (target == null || methodName == null) { throw new NullPointerException((target == null ? "target" : "methodName") + " should not be null"); } Object[] arguments = getArguments(); if (arguments == null) { arguments = emptyArray; } // Class.forName() won't load classes outside // of core from a class inside core. Special // case this method. if (target == Class.class && methodName.equals("forName")) { return ClassFinder.resolveClass((String)arguments[0], this.loader); } Class[] argClasses = new Class[arguments.length]; for(int i = 0; i < arguments.length; i++) { argClasses[i] = (arguments[i] == null) ? null : arguments[i].getClass(); } AccessibleObject m = null; if (target instanceof Class) { /* For class methods, simluate the effect of a meta class by taking the union of the static methods of the actual class, with the instance methods of "Class.class" and the overloaded "newInstance" methods defined by the constructors. This way "System.class", for example, will perform both the static method getProperties() and the instance method getSuperclass() defined in "Class.class". */ if (methodName.equals("new")) { methodName = "newInstance"; } // Provide a short form for array instantiation by faking an nary-constructor. if (methodName.equals("newInstance") && ((Class)target).isArray()) { Object result = Array.newInstance(((Class)target).getComponentType(), arguments.length); for(int i = 0; i < arguments.length; i++) { Array.set(result, i, arguments[i]); } return result; } if (methodName.equals("newInstance") && arguments.length != 0) { // The Character class, as of 1.4, does not have a constructor // which takes a String. All of the other "wrapper" classes // for Java's primitive types have a String constructor so we // fake such a constructor here so that this special case can be // ignored elsewhere. if (target == Character.class && arguments.length == 1 && argClasses[0] == String.class) { return new Character(((String)arguments[0]).charAt(0)); } try { m = ConstructorFinder.findConstructor((Class)target, argClasses); } catch (NoSuchMethodException exception) { m = null; } } if (m == null && target != Class.class) { m = getMethod((Class)target, methodName, argClasses); } if (m == null) { m = getMethod(Class.class, methodName, argClasses); } } else { /* This special casing of arrays is not necessary, but makes files involving arrays much shorter and simplifies the archiving infrastrcure. The Array.set() method introduces an unusual idea - that of a static method changing the state of an instance. Normally statements with side effects on objects are instance methods of the objects themselves and we reinstate this rule (perhaps temporarily) by special-casing arrays. */ if (target.getClass().isArray() && (methodName.equals("set") || methodName.equals("get"))) { int index = ((Integer)arguments[0]).intValue(); if (methodName.equals("get")) { return Array.get(target, index); } else { Array.set(target, index, arguments[1]); return null; } } m = getMethod(target.getClass(), methodName, argClasses); } if (m != null) { try { if (m instanceof Method) { return MethodUtil.invoke((Method)m, target, arguments); } else { return ((Constructor)m).newInstance(arguments); } } catch (IllegalAccessException iae) { throw new Exception("Statement cannot invoke: " + methodName + " on " + target.getClass(), iae); } catch (InvocationTargetException ite) { Throwable te = ite.getTargetException(); if (te instanceof Exception) { throw (Exception)te; } else { throw ite; } } } throw new NoSuchMethodException(toString()); } String instanceName(Object instance) { if (instance == null) { return "null"; } else if (instance.getClass() == String.class) { return "\""+(String)instance + "\""; } else { // Note: there is a minor problem with using the non-caching // NameGenerator method. The return value will not have // specific information about the inner class name. For example, // In 1.4.2 an inner class would be represented as JList$1 now // would be named Class. return NameGenerator.unqualifiedClassName(instance.getClass()); } } /** * Prints the value of this statement using a Java-style syntax. */ public String toString() { // Respect a subclass's implementation here. Object target = getTarget(); String methodName = getMethodName(); Object[] arguments = getArguments(); if (arguments == null) { arguments = emptyArray; } StringBuffer result = new StringBuffer(instanceName(target) + "." + methodName + "("); int n = arguments.length; for(int i = 0; i < n; i++) { result.append(instanceName(arguments[i])); if (i != n -1) { result.append(", "); } } result.append(");"); return result.toString(); } static Method getMethod(Class type, String name, Class... args) { try { return MethodFinder.findMethod(type, name, args); } catch (NoSuchMethodException exception) { return null; } } }