1 /* 2 * Copyright (C) 2005 The Guava Authors 3 * 4 * Licensed under the Apache License, Version 2.0 (the "License"); 5 * you may not use this file except in compliance with the License. 6 * You may obtain a copy of the License at 7 * 8 * http://www.apache.org/licenses/LICENSE-2.0 9 * 10 * Unless required by applicable law or agreed to in writing, software 11 * distributed under the License is distributed on an "AS IS" BASIS, 12 * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. 13 * See the License for the specific language governing permissions and 14 * limitations under the License. 15 */ 16 17 package com.google.common.base; 18 19 import com.google.common.testing.GcFinalization; 20 21 import junit.framework.TestCase; 22 23 import java.io.Closeable; 24 import java.lang.ref.WeakReference; 25 import java.lang.reflect.Constructor; 26 import java.lang.reflect.Field; 27 import java.net.URL; 28 import java.net.URLClassLoader; 29 import java.security.Permission; 30 import java.security.Policy; 31 import java.security.ProtectionDomain; 32 import java.util.concurrent.Callable; 33 import java.util.concurrent.Semaphore; 34 import java.util.concurrent.TimeUnit; 35 import java.util.concurrent.atomic.AtomicReference; 36 37 /** 38 * Tests that the {@code ClassLoader} of {@link FinalizableReferenceQueue} can be unloaded. These 39 * tests are separate from {@link FinalizableReferenceQueueTest} so that they can be excluded from 40 * coverage runs, as the coverage system interferes with them. 41 * 42 * @author Eamonn McManus 43 */ 44 public class FinalizableReferenceQueueClassLoaderUnloadingTest extends TestCase { 45 46 /* 47 * The following tests check that the use of FinalizableReferenceQueue does not prevent the 48 * ClassLoader that loaded that class from later being garbage-collected. If anything continues 49 * to reference the FinalizableReferenceQueue class then its ClassLoader cannot be 50 * garbage-collected, even if there are no more instances of FinalizableReferenceQueue itself. 51 * The code in FinalizableReferenceQueue goes to considerable trouble to ensure that there are 52 * no such references and the tests here check that that trouble has not been in vain. 53 * 54 * When we reference FinalizableReferenceQueue in this test, we are referencing a class that is 55 * loaded by this test and that will obviously remain loaded for as long as the test is running. 56 * So in order to check ClassLoader garbage collection we need to create a new ClassLoader and 57 * make it load its own version of FinalizableReferenceQueue. Then we need to interact with that 58 * parallel version through reflection in order to exercise the parallel 59 * FinalizableReferenceQueue, and then check that the parallel ClassLoader can be 60 * garbage-collected after that. 61 */ 62 63 public static class MyFinalizableWeakReference extends FinalizableWeakReference<Object> { 64 public MyFinalizableWeakReference(Object x, FinalizableReferenceQueue queue) { 65 super(x, queue); 66 } 67 68 @Override 69 public void finalizeReferent() { 70 } 71 } 72 73 private static class PermissivePolicy extends Policy { 74 @Override 75 public boolean implies(ProtectionDomain pd, Permission perm) { 76 return true; 77 } 78 } 79 80 private WeakReference<ClassLoader> useFrqInSeparateLoader() throws Exception { 81 final URLClassLoader myLoader = (URLClassLoader) getClass().getClassLoader(); 82 final URL[] urls = myLoader.getURLs(); 83 URLClassLoader sepLoader = new URLClassLoader(urls, myLoader.getParent()); 84 // sepLoader is the loader that we will use to load the parallel FinalizableReferenceQueue (FRQ) 85 // and friends, and that we will eventually expect to see garbage-collected. The assumption 86 // is that the ClassLoader of this test is a URLClassLoader, and that it loads FRQ itself 87 // rather than delegating to a parent ClassLoader. If this assumption is violated the test will 88 // fail and will need to be rewritten. 89 90 Class<?> frqC = FinalizableReferenceQueue.class; 91 Class<?> sepFrqC = sepLoader.loadClass(frqC.getName()); 92 assertNotSame(frqC, sepFrqC); 93 // Check the assumptions above. 94 95 // FRQ tries to load the Finalizer class (for the reference-collecting thread) in a few ways. 96 // If the class is accessible to the system ClassLoader (ClassLoader.getSystemClassLoader()) 97 // then FRQ does not bother to load Finalizer.class through a separate ClassLoader. That happens 98 // in our test environment, which foils the purpose of this test, so we disable the logic for 99 // our test by setting a static field. We are changing the field in the parallel version of FRQ 100 // and each test creates its own one of those, so there is no test interference here. 101 Class<?> sepFrqSystemLoaderC = 102 sepLoader.loadClass(FinalizableReferenceQueue.SystemLoader.class.getName()); 103 Field disabled = sepFrqSystemLoaderC.getDeclaredField("disabled"); 104 disabled.setAccessible(true); 105 disabled.set(null, true); 106 107 // Now make a parallel FRQ and an associated FinalizableWeakReference to an object, in order to 108 // exercise some classes from the parallel ClassLoader. 109 AtomicReference<Object> sepFrqA = new AtomicReference<Object>(sepFrqC.newInstance()); 110 Class<?> sepFwrC = sepLoader.loadClass(MyFinalizableWeakReference.class.getName()); 111 Constructor<?> sepFwrCons = sepFwrC.getConstructor(Object.class, sepFrqC); 112 // The object that we will wrap in FinalizableWeakReference is a Stopwatch. 113 Class<?> sepStopwatchC = sepLoader.loadClass(Stopwatch.class.getName()); 114 assertSame(sepLoader, sepStopwatchC.getClassLoader()); 115 AtomicReference<Object> sepStopwatchA = 116 new AtomicReference<Object>(sepStopwatchC.getMethod("createUnstarted").invoke(null)); 117 AtomicReference<WeakReference<?>> sepStopwatchRef = new AtomicReference<WeakReference<?>>( 118 (WeakReference<?>) sepFwrCons.newInstance(sepStopwatchA.get(), sepFrqA.get())); 119 assertNotNull(sepStopwatchA.get()); 120 // Clear all references to the Stopwatch and wait for it to be gc'd. 121 sepStopwatchA.set(null); 122 GcFinalization.awaitClear(sepStopwatchRef.get()); 123 // Return a weak reference to the parallel ClassLoader. This is the reference that should 124 // eventually become clear if there are no other references to the ClassLoader. 125 return new WeakReference<ClassLoader>(sepLoader); 126 } 127 128 private void doTestUnloadable() throws Exception { 129 WeakReference<ClassLoader> loaderRef = useFrqInSeparateLoader(); 130 GcFinalization.awaitClear(loaderRef); 131 } 132 133 public void testUnloadableWithoutSecurityManager() throws Exception { 134 // Test that the use of a FinalizableReferenceQueue does not subsequently prevent the 135 // loader of that class from being garbage-collected. 136 SecurityManager oldSecurityManager = System.getSecurityManager(); 137 try { 138 System.setSecurityManager(null); 139 doTestUnloadable(); 140 } finally { 141 System.setSecurityManager(oldSecurityManager); 142 } 143 } 144 145 public void testUnloadableWithSecurityManager() throws Exception { 146 // Test that the use of a FinalizableReferenceQueue does not subsequently prevent the 147 // loader of that class from being garbage-collected even if there is a SecurityManager. 148 // The SecurityManager environment makes such leaks more likely because when you create 149 // a URLClassLoader with a SecurityManager, the creating code's AccessControlContext is 150 // captured, and that references the creating code's ClassLoader. 151 Policy oldPolicy = Policy.getPolicy(); 152 SecurityManager oldSecurityManager = System.getSecurityManager(); 153 try { 154 Policy.setPolicy(new PermissivePolicy()); 155 System.setSecurityManager(new SecurityManager()); 156 doTestUnloadable(); 157 } finally { 158 System.setSecurityManager(oldSecurityManager); 159 Policy.setPolicy(oldPolicy); 160 } 161 } 162 163 public static class FrqUser implements Callable<WeakReference<Object>> { 164 public static FinalizableReferenceQueue frq = new FinalizableReferenceQueue(); 165 public static final Semaphore finalized = new Semaphore(0); 166 167 @Override 168 public WeakReference<Object> call() { 169 WeakReference<Object> wr = new FinalizableWeakReference<Object>(new Integer(23), frq) { 170 @Override 171 public void finalizeReferent() { 172 finalized.release(); 173 } 174 }; 175 return wr; 176 } 177 } 178 179 public void testUnloadableInStaticFieldIfClosed() throws Exception { 180 Policy oldPolicy = Policy.getPolicy(); 181 SecurityManager oldSecurityManager = System.getSecurityManager(); 182 try { 183 Policy.setPolicy(new PermissivePolicy()); 184 System.setSecurityManager(new SecurityManager()); 185 WeakReference<ClassLoader> loaderRef = doTestUnloadableInStaticFieldIfClosed(); 186 GcFinalization.awaitClear(loaderRef); 187 } finally { 188 System.setSecurityManager(oldSecurityManager); 189 Policy.setPolicy(oldPolicy); 190 } 191 } 192 193 // If you have a FinalizableReferenceQueue that is a static field of one of the classes of your 194 // app (like the FrqUser class above), then the app's ClassLoader will never be gc'd. The reason 195 // is that we attempt to run a thread in a separate ClassLoader that will detect when the FRQ 196 // is no longer referenced, meaning that the app's ClassLoader has been gc'd, and when that 197 // happens. But the thread's supposedly separate ClassLoader actually has a reference to the app's 198 // ClasLoader via its AccessControlContext. It does not seem to be possible to make a 199 // URLClassLoader without capturing this reference, and it probably would not be desirable for 200 // security reasons anyway. Therefore, the FRQ.close() method provides a way to stop the thread 201 // explicitly. This test checks that calling that method does allow an app's ClassLoader to be 202 // gc'd even if there is a still a FinalizableReferenceQueue in a static field. (Setting the field 203 // to null would also work, but only if there are no references to the FRQ anywhere else.) 204 private WeakReference<ClassLoader> doTestUnloadableInStaticFieldIfClosed() throws Exception { 205 final URLClassLoader myLoader = (URLClassLoader) getClass().getClassLoader(); 206 final URL[] urls = myLoader.getURLs(); 207 URLClassLoader sepLoader = new URLClassLoader(urls, myLoader.getParent()); 208 209 Class<?> frqC = FinalizableReferenceQueue.class; 210 Class<?> sepFrqC = sepLoader.loadClass(frqC.getName()); 211 assertNotSame(frqC, sepFrqC); 212 213 Class<?> sepFrqSystemLoaderC = 214 sepLoader.loadClass(FinalizableReferenceQueue.SystemLoader.class.getName()); 215 Field disabled = sepFrqSystemLoaderC.getDeclaredField("disabled"); 216 disabled.setAccessible(true); 217 disabled.set(null, true); 218 219 Class<?> frqUserC = FrqUser.class; 220 Class<?> sepFrqUserC = sepLoader.loadClass(frqUserC.getName()); 221 assertNotSame(frqUserC, sepFrqUserC); 222 assertSame(sepLoader, sepFrqUserC.getClassLoader()); 223 224 Callable<?> sepFrqUser = (Callable<?>) sepFrqUserC.newInstance(); 225 WeakReference<?> finalizableWeakReference = (WeakReference<?>) sepFrqUser.call(); 226 227 GcFinalization.awaitClear(finalizableWeakReference); 228 229 Field sepFrqUserFinalizedF = sepFrqUserC.getField("finalized"); 230 Semaphore finalizeCount = (Semaphore) sepFrqUserFinalizedF.get(null); 231 boolean finalized = finalizeCount.tryAcquire(5, TimeUnit.SECONDS); 232 assertTrue(finalized); 233 234 Field sepFrqUserFrqF = sepFrqUserC.getField("frq"); 235 Closeable frq = (Closeable) sepFrqUserFrqF.get(null); 236 frq.close(); 237 238 return new WeakReference<ClassLoader>(sepLoader); 239 } 240 } 241