src/test/java/com/google/devtools/build/lib/concurrent/ThreadSafetyTest.java - bazel - Git at Google

 // Copyright 2014 The Bazel Authors. All rights reserved.
 //
 // 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 com.google.devtools.build.lib.concurrent;

 import com.google.devtools.build.lib.concurrent.ThreadSafety.ConditionallyThreadCompatible;
 import com.google.devtools.build.lib.concurrent.ThreadSafety.ConditionallyThreadSafe;
 import com.google.devtools.build.lib.concurrent.ThreadSafety.Immutable;
 import com.google.devtools.build.lib.concurrent.ThreadSafety.ThreadCompatible;
 import com.google.devtools.build.lib.concurrent.ThreadSafety.ThreadHostile;
 import com.google.devtools.build.lib.concurrent.ThreadSafety.ThreadSafe;

 import org.junit.Test;
 import org.junit.runner.RunWith;
 import org.junit.runners.JUnit4;

 import java.util.Random;
 import java.util.concurrent.atomic.AtomicInteger;

 /**
  * This file just contains some examples of the use of
  * annotations for different categories of thread safety:
  *   ThreadSafe
  *   ThreadCompatible
  *   ThreadHostile
  *   Immutable ThreadSafe
  *   Immutable ThreadHostile
  *
  * It doesn't really test much -- just that this code
  * using those annotations compiles and runs.
  *
  * The main class here is annotated as being both ConditionallyThreadSafe
  * and ConditionallyThreadCompatible, and accordingly we document here the
  * conditions under which it is thread-safe and thread-compatible:
  *    - it is thread-safe if you only use the testThreadSafety() method,
  *      the ThreadSafeCounter class, and/or ImmutableThreadSafeCounter class;
  *    - it is thread-compatible if you use only those and/or the
  *      ThreadCompatibleCounter and/or ImmutableThreadCompatibleCounter class;
  *    - it is thread-hostile otherwise.
  */
 @ConditionallyThreadSafe @ConditionallyThreadCompatible
 @RunWith(JUnit4.class)
 public class ThreadSafetyTest {

   @ThreadSafe
   public static final class ThreadSafeCounter {

     // A ThreadSafe class can have public mutable fields,
     // provided they are atomic or volatile.

     public volatile boolean myBool;
     public AtomicInteger myInt;

     // A ThreadSafe class can have private mutable fields,
     // provided that access to them is synchronized.
     private int value;
     public ThreadSafeCounter(int value) {
       synchronized (this) { // is this needed?
         this.value = value;
       }
     }
     public synchronized int getValue() {
       return value;
     }
     public synchronized void increment() {
       value++;
     }

     // A ThreadSafe class can have private mutable members
     // provided that the methods of the class synchronize access
     // to them.
     // These members could be static...
     private static int numFoos = 0;
     public static synchronized void foo() {
       numFoos++;
     }
     public static synchronized int getNumFoos() {
       return numFoos;
     }
     // ... or non-static.
     private int numBars = 0;
     public synchronized void bar() {
       numBars++;
     }
     public synchronized int getNumBars() {
       return numBars;
     }
   }

   @ThreadCompatible
   public static final class ThreadCompatibleCounter {

     // A ThreadCompatible class can have public mutable fields.
     public int value;
     public ThreadCompatibleCounter(int value) {
       this.value = value;
     }
     public int getValue() {
       return value;
     }
     public void increment() {
       value++;
     }

     // A ThreadCompatible class can have mutable static members
     // provided that the methods of the class synchronize access
     // to them.
     private static int numFoos = 0;
     public static synchronized void foo() {
       numFoos++;
     }
     public static synchronized int getNumFoos() {
       return numFoos;
     }
   }

   @ThreadHostile
   public static final class ThreadHostileCounter {

     // A ThreadHostile class can have public mutable fields.
     public int value;
     public ThreadHostileCounter(int value) {
       this.value = value;
     }
     public int getValue() {
       return value;
     }
     public void increment() {
       value++;
     }

     // A ThreadHostile class can perform unsynchronized access
     // to mutable static data.
     private static int numFoos = 0;
     public static void foo() {
       numFoos++;
     }
     public static int getNumFoos() {
       return numFoos;
     }
   }

   @Immutable @ThreadSafe
   public static final class ImmutableThreadSafeCounter {

     // An Immutable ThreadSafe class can have public fields,
     // provided they are final and immutable.
     public final int value;
     public ImmutableThreadSafeCounter(int value) {
       this.value = value;
     }
     public int getValue() {
       return value;
     }
     public ImmutableThreadSafeCounter increment() {
       return new ImmutableThreadSafeCounter(value + 1);
     }

     // An Immutable ThreadSafe class can have immutable static members.
     public static final int NUM_STATIC_CACHE_ENTRIES = 3;
     private static final ImmutableThreadSafeCounter[] staticCache =
         new ImmutableThreadSafeCounter[] {
           new ImmutableThreadSafeCounter(0),
           new ImmutableThreadSafeCounter(1),
           new ImmutableThreadSafeCounter(2)
         };
     public static ImmutableThreadSafeCounter makeUsingStaticCache(int value) {
       if (value < NUM_STATIC_CACHE_ENTRIES) {
         return staticCache[value];
       } else {
         return new ImmutableThreadSafeCounter(value);
       }
     }

     // An Immutable ThreadSafe class can have private mutable members
     // provided that the methods of the class synchronize access
     // to them.
     // These members could be static...
     private static int cachedValue = 0;
     private static ImmutableThreadSafeCounter cachedCounter =
         new ImmutableThreadSafeCounter(0);
     public static synchronized ImmutableThreadSafeCounter
         makeUsingDynamicCache(int value) {
       if (value != cachedValue) {
         cachedValue = value;
         cachedCounter = new ImmutableThreadSafeCounter(value);
       }
       return cachedCounter;
     }
     // ... or non-static.
     private ImmutableThreadSafeCounter incrementCache = null;
     public synchronized ImmutableThreadSafeCounter incrementUsingCache() {
       if (incrementCache == null) {
         incrementCache = new ImmutableThreadSafeCounter(value + 1);
       }
       return incrementCache;
     }
     // Methods of an Immutable class need not be deterministic.
     private static Random random = new Random();
     public int choose() {
       return random.nextInt(value);
     }
   }

   @Immutable @ThreadHostile
   public static final class ImmutableThreadHostileCounter {

     // An Immutable ThreadHostile class can have public fields,
     // provided they are final and immutable.
     public final int value;
     public ImmutableThreadHostileCounter(int value) {
       this.value = value;
     }
     public int getValue() {
       return value;
     }
     public ImmutableThreadHostileCounter increment() {
       return new ImmutableThreadHostileCounter(value + 1);
     }

     // An Immutable ThreadHostile class can have private mutable members,
     // and doesn't need to synchronize access to them.
     // These members could be static...
     private static int cachedValue = 0;
     private static ImmutableThreadHostileCounter cachedCounter =
         new ImmutableThreadHostileCounter(0);
     public static ImmutableThreadHostileCounter
         makeUsingDynamicCache(int value) {
       if (value != cachedValue) {
         cachedValue = value;
         cachedCounter = new ImmutableThreadHostileCounter(value);
       }
       return cachedCounter;
     }
     // ... or non-static.
     private ImmutableThreadHostileCounter incrementCache = null;
     public ImmutableThreadHostileCounter incrementUsingCache() {
       if (incrementCache == null) {
         incrementCache = new ImmutableThreadHostileCounter(value + 1);
       }
       return incrementCache;
     }
   }

   @Test
   public void threadSafety() throws InterruptedException {
     final ThreadSafeCounter threadSafeCounterArray[] =
         new ThreadSafeCounter[] {
           new ThreadSafeCounter(1),
           new ThreadSafeCounter(2),
           new ThreadSafeCounter(3)
         };
     final ThreadCompatibleCounter threadCompatibleCounterArray[] =
         new ThreadCompatibleCounter[] {
           new ThreadCompatibleCounter(1),
           new ThreadCompatibleCounter(2),
           new ThreadCompatibleCounter(3)
         };
     final ThreadHostileCounter threadHostileCounter =
         new ThreadHostileCounter(1);

     class MyThread implements Runnable {

       ThreadCompatibleCounter threadCompatibleCounter =
           new ThreadCompatibleCounter(1);

       @Override
       public void run() {

         // ThreadSafe objects can be accessed with without synchronization
         for (ThreadSafeCounter counter : threadSafeCounterArray) {
           counter.increment();
         }

         // ThreadCompatible objects can be accessed with without
         // synchronization if they are thread-local
         threadCompatibleCounter.increment();

         // Access to ThreadCompatible objects must be synchronized
         // if they could be concurrently accessed by other threads
         for (ThreadCompatibleCounter counter : threadCompatibleCounterArray) {
           synchronized (counter) {
             counter.increment();
           }
         }

         // Access to ThreadHostile objects must be synchronized.
         synchronized (this.getClass()) {
           threadHostileCounter.increment();
         }

       }
     }

     Thread thread1 = new Thread(new MyThread());
     Thread thread2 = new Thread(new MyThread());
     thread1.start();
     thread2.start();
     thread1.join();
     thread2.join();
   }

 }
	// Copyright 2014 The Bazel Authors. All rights reserved.
	//
	// 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 com.google.devtools.build.lib.concurrent;

	import com.google.devtools.build.lib.concurrent.ThreadSafety.ConditionallyThreadCompatible;
	import com.google.devtools.build.lib.concurrent.ThreadSafety.ConditionallyThreadSafe;
	import com.google.devtools.build.lib.concurrent.ThreadSafety.Immutable;
	import com.google.devtools.build.lib.concurrent.ThreadSafety.ThreadCompatible;
	import com.google.devtools.build.lib.concurrent.ThreadSafety.ThreadHostile;
	import com.google.devtools.build.lib.concurrent.ThreadSafety.ThreadSafe;

	import org.junit.Test;
	import org.junit.runner.RunWith;
	import org.junit.runners.JUnit4;

	import java.util.Random;
	import java.util.concurrent.atomic.AtomicInteger;

	/**
	* This file just contains some examples of the use of
	* annotations for different categories of thread safety:
	* ThreadSafe
	* ThreadCompatible
	* ThreadHostile
	* Immutable ThreadSafe
	* Immutable ThreadHostile
	*
	* It doesn't really test much -- just that this code
	* using those annotations compiles and runs.
	*
	* The main class here is annotated as being both ConditionallyThreadSafe
	* and ConditionallyThreadCompatible, and accordingly we document here the
	* conditions under which it is thread-safe and thread-compatible:
	* - it is thread-safe if you only use the testThreadSafety() method,
	* the ThreadSafeCounter class, and/or ImmutableThreadSafeCounter class;
	* - it is thread-compatible if you use only those and/or the
	* ThreadCompatibleCounter and/or ImmutableThreadCompatibleCounter class;
	* - it is thread-hostile otherwise.
	*/
	@ConditionallyThreadSafe @ConditionallyThreadCompatible
	@RunWith(JUnit4.class)
	public class ThreadSafetyTest {

	@ThreadSafe
	public static final class ThreadSafeCounter {

	// A ThreadSafe class can have public mutable fields,
	// provided they are atomic or volatile.

	public volatile boolean myBool;
	public AtomicInteger myInt;

	// A ThreadSafe class can have private mutable fields,
	// provided that access to them is synchronized.
	private int value;
	public ThreadSafeCounter(int value) {
	synchronized (this) { // is this needed?
	this.value = value;
	}
	}
	public synchronized int getValue() {
	return value;
	}
	public synchronized void increment() {
	value++;
	}

	// A ThreadSafe class can have private mutable members
	// provided that the methods of the class synchronize access
	// to them.
	// These members could be static...
	private static int numFoos = 0;
	public static synchronized void foo() {
	numFoos++;
	}
	public static synchronized int getNumFoos() {
	return numFoos;
	}
	// ... or non-static.
	private int numBars = 0;
	public synchronized void bar() {
	numBars++;
	}
	public synchronized int getNumBars() {
	return numBars;
	}
	}

	@ThreadCompatible
	public static final class ThreadCompatibleCounter {

	// A ThreadCompatible class can have public mutable fields.
	public int value;
	public ThreadCompatibleCounter(int value) {
	this.value = value;
	}
	public int getValue() {
	return value;
	}
	public void increment() {
	value++;
	}

	// A ThreadCompatible class can have mutable static members
	// provided that the methods of the class synchronize access
	// to them.
	private static int numFoos = 0;
	public static synchronized void foo() {
	numFoos++;
	}
	public static synchronized int getNumFoos() {
	return numFoos;
	}
	}

	@ThreadHostile
	public static final class ThreadHostileCounter {

	// A ThreadHostile class can have public mutable fields.
	public int value;
	public ThreadHostileCounter(int value) {
	this.value = value;
	}
	public int getValue() {
	return value;
	}
	public void increment() {
	value++;
	}

	// A ThreadHostile class can perform unsynchronized access
	// to mutable static data.
	private static int numFoos = 0;
	public static void foo() {
	numFoos++;
	}
	public static int getNumFoos() {
	return numFoos;
	}
	}

	@Immutable @ThreadSafe
	public static final class ImmutableThreadSafeCounter {

	// An Immutable ThreadSafe class can have public fields,
	// provided they are final and immutable.
	public final int value;
	public ImmutableThreadSafeCounter(int value) {
	this.value = value;
	}
	public int getValue() {
	return value;
	}
	public ImmutableThreadSafeCounter increment() {
	return new ImmutableThreadSafeCounter(value + 1);
	}

	// An Immutable ThreadSafe class can have immutable static members.
	public static final int NUM_STATIC_CACHE_ENTRIES = 3;
	private static final ImmutableThreadSafeCounter[] staticCache =
	new ImmutableThreadSafeCounter[] {
	new ImmutableThreadSafeCounter(0),
	new ImmutableThreadSafeCounter(1),
	new ImmutableThreadSafeCounter(2)
	};
	public static ImmutableThreadSafeCounter makeUsingStaticCache(int value) {
	if (value < NUM_STATIC_CACHE_ENTRIES) {
	return staticCache[value];
	} else {
	return new ImmutableThreadSafeCounter(value);
	}
	}

	// An Immutable ThreadSafe class can have private mutable members
	// provided that the methods of the class synchronize access
	// to them.
	// These members could be static...
	private static int cachedValue = 0;
	private static ImmutableThreadSafeCounter cachedCounter =
	new ImmutableThreadSafeCounter(0);
	public static synchronized ImmutableThreadSafeCounter
	makeUsingDynamicCache(int value) {
	if (value != cachedValue) {
	cachedValue = value;
	cachedCounter = new ImmutableThreadSafeCounter(value);
	}
	return cachedCounter;
	}
	// ... or non-static.
	private ImmutableThreadSafeCounter incrementCache = null;
	public synchronized ImmutableThreadSafeCounter incrementUsingCache() {
	if (incrementCache == null) {
	incrementCache = new ImmutableThreadSafeCounter(value + 1);
	}
	return incrementCache;
	}
	// Methods of an Immutable class need not be deterministic.
	private static Random random = new Random();
	public int choose() {
	return random.nextInt(value);
	}
	}

	@Immutable @ThreadHostile
	public static final class ImmutableThreadHostileCounter {

	// An Immutable ThreadHostile class can have public fields,
	// provided they are final and immutable.
	public final int value;
	public ImmutableThreadHostileCounter(int value) {
	this.value = value;
	}
	public int getValue() {
	return value;
	}
	public ImmutableThreadHostileCounter increment() {
	return new ImmutableThreadHostileCounter(value + 1);
	}

	// An Immutable ThreadHostile class can have private mutable members,
	// and doesn't need to synchronize access to them.
	// These members could be static...
	private static int cachedValue = 0;
	private static ImmutableThreadHostileCounter cachedCounter =
	new ImmutableThreadHostileCounter(0);
	public static ImmutableThreadHostileCounter
	makeUsingDynamicCache(int value) {
	if (value != cachedValue) {
	cachedValue = value;
	cachedCounter = new ImmutableThreadHostileCounter(value);
	}
	return cachedCounter;
	}
	// ... or non-static.
	private ImmutableThreadHostileCounter incrementCache = null;
	public ImmutableThreadHostileCounter incrementUsingCache() {
	if (incrementCache == null) {
	incrementCache = new ImmutableThreadHostileCounter(value + 1);
	}
	return incrementCache;
	}
	}

	@Test
	public void threadSafety() throws InterruptedException {
	final ThreadSafeCounter threadSafeCounterArray[] =
	new ThreadSafeCounter[] {
	new ThreadSafeCounter(1),
	new ThreadSafeCounter(2),
	new ThreadSafeCounter(3)
	};
	final ThreadCompatibleCounter threadCompatibleCounterArray[] =
	new ThreadCompatibleCounter[] {
	new ThreadCompatibleCounter(1),
	new ThreadCompatibleCounter(2),
	new ThreadCompatibleCounter(3)
	};
	final ThreadHostileCounter threadHostileCounter =
	new ThreadHostileCounter(1);

	class MyThread implements Runnable {

	ThreadCompatibleCounter threadCompatibleCounter =
	new ThreadCompatibleCounter(1);

	@Override
	public void run() {

	// ThreadSafe objects can be accessed with without synchronization
	for (ThreadSafeCounter counter : threadSafeCounterArray) {
	counter.increment();
	}

	// ThreadCompatible objects can be accessed with without
	// synchronization if they are thread-local
	threadCompatibleCounter.increment();

	// Access to ThreadCompatible objects must be synchronized
	// if they could be concurrently accessed by other threads
	for (ThreadCompatibleCounter counter : threadCompatibleCounterArray) {
	synchronized (counter) {
	counter.increment();
	}
	}

	// Access to ThreadHostile objects must be synchronized.
	synchronized (this.getClass()) {
	threadHostileCounter.increment();
	}

	}
	}

	Thread thread1 = new Thread(new MyThread());
	Thread thread2 = new Thread(new MyThread());
	thread1.start();
	thread2.start();
	thread1.join();
	thread2.join();
	}

	}