test/910-methods/src/art/Test910.java - platform/art - Git at Google

 /*
  * Copyright (C) 2016 The Android Open Source Project
  *
  * Licensed under the Apache License, Version 2.0 (the "License");
  * you may not use this file except in compliance with the License.
  * You may obtain a copy of the License at
  *
  *      http://www.apache.org/licenses/LICENSE-2.0
  *
  * Unless required by applicable law or agreed to in writing, software
  * distributed under the License is distributed on an "AS IS" BASIS,
  * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
  * See the License for the specific language governing permissions and
  * limitations under the License.
  */

 package art;

 import java.lang.reflect.Method;
 import java.lang.reflect.Proxy;
 import java.util.Arrays;

 public class Test910 {
   public static void run() throws Exception {
     doTest();
   }

   public static void doTest() throws Exception {
     testMethod("java.lang.Object", "toString");
     testMethod("java.lang.String", "charAt", int.class);
     testMethod("java.lang.Math", "sqrt", double.class);
     testMethod("java.util.List", "add", Object.class);

     testMethod(getProxyClass(), "run");

     // Find a synthetic method in the dummy inner class. Do not print the name. Javac and Jack
     // disagree on the naming of synthetic accessors.
     testMethod(findSyntheticMethod(), NestedSynthetic.class, false);
   }

   private static void testMethod(String className, String methodName, Class<?>... types)
       throws Exception {
     Class<?> base = Class.forName(className);
     testMethod(base, methodName, types);
   }

   private static void testMethod(Class<?> base, String methodName, Class<?>... types)
       throws Exception {
     Method m = base.getDeclaredMethod(methodName, types);
     testMethod(m, base, true);
   }

   private static void testMethod(Method m, Class<?> base, boolean printName) {
     String[] result = getMethodName(m);
     if (!result[0].equals(m.getName())) {
       throw new RuntimeException("Name not equal: " + m.getName() + " vs " + result[0]);
     }
     if (printName) {
       System.out.println(Arrays.toString(result));
     }

     Class<?> declClass = getMethodDeclaringClass(m);
     if (base != declClass) {
       throw new RuntimeException("Declaring class not equal: " + base + " vs " + declClass);
     }
     System.out.println(declClass);

     int modifiers = getMethodModifiers(m);
     if (modifiers != m.getModifiers()) {
       throw new RuntimeException("Modifiers not equal: " + m.getModifiers() + " vs " + modifiers);
     }
     System.out.println(modifiers);

     System.out.print("Max locals: ");
     try {
       System.out.println(getMaxLocals(m));
     } catch (RuntimeException e) {
       System.out.println(e.getMessage());
     }

     System.out.print("Argument size: ");
     try {
       System.out.println(getArgumentsSize(m));
     } catch (RuntimeException e) {
       System.out.println(e.getMessage());
     }

     System.out.print("Location start: ");
     try {
       System.out.println(getMethodLocationStart(m));
     } catch (RuntimeException e) {
       System.out.println(e.getMessage());
     }

     System.out.print("Location end: ");
     try {
       System.out.println(getMethodLocationEnd(m));
     } catch (RuntimeException e) {
       System.out.println(e.getMessage());
     }

     System.out.println("Is native: " + isMethodNative(m));
     System.out.println("Is obsolete: " + isMethodObsolete(m));
     System.out.println("Is synthetic: " + isMethodSynthetic(m));
   }

   private static class NestedSynthetic {
     // Accessing this private field will create a synthetic accessor method;
     private static String dummy;
   }

   private static void dummyAccess() {
     System.out.println(NestedSynthetic.dummy);
   }

   private static Method findSyntheticMethod() throws Exception {
     Method methods[] = NestedSynthetic.class.getDeclaredMethods();
     for (Method m : methods) {
       if (m.isSynthetic()) {
         return m;
       }
     }
     throw new RuntimeException("Could not find synthetic method");
   }

   private static native String[] getMethodName(Method m);
   private static native Class<?> getMethodDeclaringClass(Method m);
   private static native int getMethodModifiers(Method m);
   private static native int getMaxLocals(Method m);
   private static native int getArgumentsSize(Method m);
   private static native long getMethodLocationStart(Method m);
   private static native long getMethodLocationEnd(Method m);
   private static native boolean isMethodNative(Method m);
   private static native boolean isMethodObsolete(Method m);
   private static native boolean isMethodSynthetic(Method m);

   // We need this machinery for a consistent proxy name. Names of proxy classes include a
   // unique number (derived by counting). This means that a simple call to getProxyClass
   // depends on the test environment.
   //
   // To work around this, we assume that at most twenty proxies have been created before
   // the test is run, and canonicalize on "$Proxy20". We add infrastructure to create
   // as many proxy classes but cycling through subsets of the test-provided interfaces
   // I0...I4.
   //
   //
   // (This is made under the judgment that we do not want to have proxy-specific behavior
   //  for testMethod.)

   private static Class<?> proxyClass = null;

   private static Class<?> getProxyClass() throws Exception {
     if (proxyClass != null) {
       return proxyClass;
     }

     for (int i = 1; i <= 21; i++) {
       proxyClass = createProxyClass(i);
       String name = proxyClass.getName();
       if (name.equals("$Proxy20")) {
         return proxyClass;
       }
     }
     return proxyClass;
   }

   private static Class<?> createProxyClass(int i) throws Exception {
     int count = Integer.bitCount(i);
     Class<?>[] input = new Class<?>[count + 1];
     input[0] = Runnable.class;
     int inputIndex = 1;
     int bitIndex = 0;
     while (i != 0) {
         if ((i & 1) != 0) {
             input[inputIndex++] = Class.forName("art.Test910$I" + bitIndex);
         }
         i >>>= 1;
         bitIndex++;
     }
     return Proxy.getProxyClass(Test910.class.getClassLoader(), input);
   }

   // Need this for the proxy naming.
   public static interface I0 {
   }
   public static interface I1 {
   }
   public static interface I2 {
   }
   public static interface I3 {
   }
   public static interface I4 {
   }
 }
	/*
	* Copyright (C) 2016 The Android Open Source Project
	*
	* Licensed under the Apache License, Version 2.0 (the "License");
	* you may not use this file except in compliance with the License.
	* You may obtain a copy of the License at
	*
	* http://www.apache.org/licenses/LICENSE-2.0
	*
	* Unless required by applicable law or agreed to in writing, software
	* distributed under the License is distributed on an "AS IS" BASIS,
	* WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
	* See the License for the specific language governing permissions and
	* limitations under the License.
	*/

	package art;

	import java.lang.reflect.Method;
	import java.lang.reflect.Proxy;
	import java.util.Arrays;

	public class Test910 {
	public static void run() throws Exception {
	doTest();
	}

	public static void doTest() throws Exception {
	testMethod("java.lang.Object", "toString");
	testMethod("java.lang.String", "charAt", int.class);
	testMethod("java.lang.Math", "sqrt", double.class);
	testMethod("java.util.List", "add", Object.class);

	testMethod(getProxyClass(), "run");

	// Find a synthetic method in the dummy inner class. Do not print the name. Javac and Jack
	// disagree on the naming of synthetic accessors.
	testMethod(findSyntheticMethod(), NestedSynthetic.class, false);
	}

	private static void testMethod(String className, String methodName, Class<?>... types)
	throws Exception {
	Class<?> base = Class.forName(className);
	testMethod(base, methodName, types);
	}

	private static void testMethod(Class<?> base, String methodName, Class<?>... types)
	throws Exception {
	Method m = base.getDeclaredMethod(methodName, types);
	testMethod(m, base, true);
	}

	private static void testMethod(Method m, Class<?> base, boolean printName) {
	String[] result = getMethodName(m);
	if (!result[0].equals(m.getName())) {
	throw new RuntimeException("Name not equal: " + m.getName() + " vs " + result[0]);
	}
	if (printName) {
	System.out.println(Arrays.toString(result));
	}

	Class<?> declClass = getMethodDeclaringClass(m);
	if (base != declClass) {
	throw new RuntimeException("Declaring class not equal: " + base + " vs " + declClass);
	}
	System.out.println(declClass);

	int modifiers = getMethodModifiers(m);
	if (modifiers != m.getModifiers()) {
	throw new RuntimeException("Modifiers not equal: " + m.getModifiers() + " vs " + modifiers);
	}
	System.out.println(modifiers);

	System.out.print("Max locals: ");
	try {
	System.out.println(getMaxLocals(m));
	} catch (RuntimeException e) {
	System.out.println(e.getMessage());
	}

	System.out.print("Argument size: ");
	try {
	System.out.println(getArgumentsSize(m));
	} catch (RuntimeException e) {
	System.out.println(e.getMessage());
	}

	System.out.print("Location start: ");
	try {
	System.out.println(getMethodLocationStart(m));
	} catch (RuntimeException e) {
	System.out.println(e.getMessage());
	}

	System.out.print("Location end: ");
	try {
	System.out.println(getMethodLocationEnd(m));
	} catch (RuntimeException e) {
	System.out.println(e.getMessage());
	}

	System.out.println("Is native: " + isMethodNative(m));
	System.out.println("Is obsolete: " + isMethodObsolete(m));
	System.out.println("Is synthetic: " + isMethodSynthetic(m));
	}

	private static class NestedSynthetic {
	// Accessing this private field will create a synthetic accessor method;
	private static String dummy;
	}

	private static void dummyAccess() {
	System.out.println(NestedSynthetic.dummy);
	}

	private static Method findSyntheticMethod() throws Exception {
	Method methods[] = NestedSynthetic.class.getDeclaredMethods();
	for (Method m : methods) {
	if (m.isSynthetic()) {
	return m;
	}
	}
	throw new RuntimeException("Could not find synthetic method");
	}

	private static native String[] getMethodName(Method m);
	private static native Class<?> getMethodDeclaringClass(Method m);
	private static native int getMethodModifiers(Method m);
	private static native int getMaxLocals(Method m);
	private static native int getArgumentsSize(Method m);
	private static native long getMethodLocationStart(Method m);
	private static native long getMethodLocationEnd(Method m);
	private static native boolean isMethodNative(Method m);
	private static native boolean isMethodObsolete(Method m);
	private static native boolean isMethodSynthetic(Method m);

	// We need this machinery for a consistent proxy name. Names of proxy classes include a
	// unique number (derived by counting). This means that a simple call to getProxyClass
	// depends on the test environment.
	//
	// To work around this, we assume that at most twenty proxies have been created before
	// the test is run, and canonicalize on "$Proxy20". We add infrastructure to create
	// as many proxy classes but cycling through subsets of the test-provided interfaces
	// I0...I4.
	//
	//
	// (This is made under the judgment that we do not want to have proxy-specific behavior
	// for testMethod.)

	private static Class<?> proxyClass = null;

	private static Class<?> getProxyClass() throws Exception {
	if (proxyClass != null) {
	return proxyClass;
	}

	for (int i = 1; i <= 21; i++) {
	proxyClass = createProxyClass(i);
	String name = proxyClass.getName();
	if (name.equals("$Proxy20")) {
	return proxyClass;
	}
	}
	return proxyClass;
	}

	private static Class<?> createProxyClass(int i) throws Exception {
	int count = Integer.bitCount(i);
	Class<?>[] input = new Class<?>[count + 1];
	input[0] = Runnable.class;
	int inputIndex = 1;
	int bitIndex = 0;
	while (i != 0) {
	if ((i & 1) != 0) {
	input[inputIndex++] = Class.forName("art.Test910$I" + bitIndex);
	}
	i >>>= 1;
	bitIndex++;
	}
	return Proxy.getProxyClass(Test910.class.getClassLoader(), input);
	}

	// Need this for the proxy naming.
	public static interface I0 {
	}
	public static interface I1 {
	}
	public static interface I2 {
	}
	public static interface I3 {
	}
	public static interface I4 {
	}
	}