今天来聊聊了解LeakCanary1.6.3来龙去脉–源码分析

疑问?️

  1. 内存泄露的定义
    内存泄露:指程序中已动态分配的堆内存由于某种原因程序未释放或无法释放,造成系统内存的浪费,导致程序运行速度减慢甚至系统崩溃等严重后果
    内存泄漏可以分为4类:常发性内存泄漏;偶发性内存泄漏;一次性内存泄漏;隐式内存泄漏
  2. 内存泄露依据方法
    可达性分析法
  3. 怎么实现内存泄露的分析
    leakCanary

依赖核心理论-可达性分析法

可达性分析法 根据是否被GC Root引用确认是否是垃圾对象要被GC回收。
常见可以作为GC Root的对象有:

  1. 在线程栈中的局部变量(即正在被调用的方法里面的参数和局部变量)
  2. 存活的线程对象
  3. JNI的引用
  4. Class对象(在Android中Class被加载后是不会被卸载的)
  5. 引用类型的静态变量

LeakCannary的原理分析

  • 通过监听Activity或者Fragment的声明周期,在activity或者fragment结束的时候,监听生命周期转发给 RefWatcher 处理
  1. 顺着代码入口install(application)
    LeakCanary.java
  public static @NonNull RefWatcher install(@NonNull Application application) {
    return refWatcher(application).listenerServiceClass(DisplayLeakService.class)
        .excludedRefs(AndroidExcludedRefs.createAppDefaults().build())
        .buildAndInstall();
  }


  public static @NonNull AndroidRefWatcherBuilder refWatcher(@NonNull Context context) {
    return new AndroidRefWatcherBuilder(context);
  }

AndroidRefWatcherBuilder.java

public @NonNull AndroidRefWatcherBuilder listenerServiceClass(
      @NonNull Class<? extends AbstractAnalysisResultService> listenerServiceClass) {
    enableDisplayLeakActivity = DisplayLeakService.class.isAssignableFrom(listenerServiceClass);
    return heapDumpListener(new ServiceHeapDumpListener(context, listenerServiceClass));
  }

DisplayLeakService类是发生内存泄漏时的通知服务
excludedRefs()是排除Android源码出现的内存泄漏问题

  1. buildAndInstall()方法的实现
    AndroidRefWatcherBuilder.java中的buildAndInstall()方法,开始进行添加activity和fragment的声明周期的监听
  public @NonNull RefWatcher buildAndInstall() {
    if (LeakCanaryInternals.installedRefWatcher != null) {
      throw new UnsupportedOperationException("buildAndInstall() should only be called once.");
    }
    RefWatcher refWatcher = build();
    //判断是否可以进行监听
    if (refWatcher != DISABLED) {
      if (enableDisplayLeakActivity) {
        // 根据app包名生成LeakCanary关联应用,(桌面上会生成第二个应用图标)
        LeakCanaryInternals.setEnabledAsync(context, DisplayLeakActivity.class, true);
      }
      //activity监听
      if (watchActivities) {
        ActivityRefWatcher.install(context, refWatcher);
      }
      //fragment的监听
      if (watchFragments) {
        FragmentRefWatcher.Helper.install(context, refWatcher);
      }
    }
    LeakCanaryInternals.installedRefWatcher = refWatcher;
    return refWatcher;
  }

设置关联LeakCanary关联应用
LeakCanaryInternals.java中的实现:

  public static void setEnabledAsync(Context context, final Class<?> componentClass,
      final boolean enabled) {
    final Context appContext = context.getApplicationContext();
    AsyncTask.THREAD_POOL_EXECUTOR.execute(new Runnable() {
      @Override public void run() {
        setEnabledBlocking(appContext, componentClass, enabled);
      }
    });
  }

  public static void setEnabledBlocking(Context appContext, Class<?> componentClass,
      boolean enabled) {
    ComponentName component = new ComponentName(appContext, componentClass);
    PackageManager packageManager = appContext.getPackageManager();
    int newState = enabled ? COMPONENT_ENABLED_STATE_ENABLED : COMPONENT_ENABLED_STATE_DISABLED;
    // Blocks on IPC.
    packageManager.setComponentEnabledSetting(component, newState, DONT_KILL_APP);
  }

ActivityRefWatcher.java类(Activity监听):

  public static void install(@NonNull Context context, @NonNull RefWatcher refWatcher) {
    Application application = (Application) context.getApplicationContext();
    ActivityRefWatcher activityRefWatcher = new ActivityRefWatcher(application, refWatcher);

    application.registerActivityLifecycleCallbacks(activityRefWatcher.lifecycleCallbacks);
  }

  private final Application.ActivityLifecycleCallbacks lifecycleCallbacks =
      new ActivityLifecycleCallbacksAdapter() {
        @Override public void onActivityDestroyed(Activity activity) {
          //在activity被销毁的时候,将activity对象通知给RefWatcher(这个作为触发点,leakCanary去进行检测该activity中是否内存泄露)
          refWatcher.watch(activity);
        }
      };

FragmentRefWatcher.java接口(fragment监听):
fragment的监听有个区分:在大于8.0的时候,使用的是新的fragment的监听

 public static void install(Context context, RefWatcher refWatcher) {
      List<FragmentRefWatcher> fragmentRefWatchers = new ArrayList<>();

      if (SDK_INT >= O) {
        //android api大于8.0的使用AndroidOFragmentRefWatcher的监听
        fragmentRefWatchers.add(new AndroidOFragmentRefWatcher(refWatcher));
      }

      try {
        Class<?> fragmentRefWatcherClass = Class.forName(SUPPORT_FRAGMENT_REF_WATCHER_CLASS_NAME);
        Constructor<?> constructor =
            fragmentRefWatcherClass.getDeclaredConstructor(RefWatcher.class);
        FragmentRefWatcher supportFragmentRefWatcher =
            (FragmentRefWatcher) constructor.newInstance(refWatcher);
        fragmentRefWatchers.add(supportFragmentRefWatcher);
      } catch (Exception ignored) {
      }

      if (fragmentRefWatchers.size() == 0) {
        return;
      }

      Helper helper = new Helper(fragmentRefWatchers);

      Application application = (Application) context.getApplicationContext();
      application.registerActivityLifecycleCallbacks(helper.activityLifecycleCallbacks);
    }

    private final Application.ActivityLifecycleCallbacks activityLifecycleCallbacks =
        new ActivityLifecycleCallbacksAdapter() {
          @Override public void onActivityCreated(Activity activity, Bundle savedInstanceState) {
            for (FragmentRefWatcher watcher : fragmentRefWatchers) {
              watcher.watchFragments(activity);
            }
          }
        };

AndroidOFragmentRefWatcher.java(android8.0以上的监听):

  private final FragmentManager.FragmentLifecycleCallbacks fragmentLifecycleCallbacks =
      new FragmentManager.FragmentLifecycleCallbacks() {

        @Override public void onFragmentViewDestroyed(FragmentManager fm, Fragment fragment) {
          View view = fragment.getView();
          if (view != null) {
            refWatcher.watch(view);
          }
        }

        @Override
        public void onFragmentDestroyed(FragmentManager fm, Fragment fragment) {
          //在fragment被销毁的时候,将fragment对象通知给RefWatcher(这个作为触发点,leakCanary去进行检测该fragment中是否内存泄露)
          refWatcher.watch(fragment);
        }
      };

  @Override public void watchFragments(Activity activity) {
    FragmentManager fragmentManager = activity.getFragmentManager();
    fragmentManager.registerFragmentLifecycleCallbacks(fragmentLifecycleCallbacks, true);
  }

  1. 结合上面的接听,在activity或fragment声明周期destroy的阶段,将该对象传给RefWatcher进行watch
    补充点:WeakReference 弱引用的 ReferenceQueue 确认队列中是否有数据,如果有数据,就说明 WeakReference 被GC回收了,如果没有,说明WeakReference的数据无法被GC回收

RefWatcher.java:

  private final Set<String> retainedKeys;
  private final ReferenceQueue<Object> queue;


  .............省略部分呢代码..............

  //activity或者fragment传入
  public void watch(Object watchedReference) {
    watch(watchedReference, "");
  }

  public void watch(Object watchedReference, String referenceName) {
    if (this == DISABLED) {
      return;
    }
    checkNotNull(watchedReference, "watchedReference");
    checkNotNull(referenceName, "referenceName");
    final long watchStartNanoTime = System.nanoTime();
    //给每个watchedReference创建一个key,作为跟踪该对象是否被gc
    String key = UUID.randomUUID().toString();
    retainedKeys.add(key);
    // 创建一个KeyedWeakReference类继承WeakReference,gc后,通过确认ReferenceQueue中是否有KeyedWeakReference的数据
    final KeyedWeakReference reference =
        new KeyedWeakReference(watchedReference, key, referenceName, queue);

    ensureGoneAsync(watchStartNanoTime, reference);
  }

  private void ensureGoneAsync(final long watchStartNanoTime, final KeyedWeakReference reference) {
    watchExecutor.execute(new Retryable() {
      @Override public Retryable.Result run() {
        return ensureGone(reference, watchStartNanoTime);
      }
    });
  }

  Retryable.Result ensureGone(final KeyedWeakReference reference, final long watchStartNanoTime) {
    long gcStartNanoTime = System.nanoTime();
    long watchDurationMs = NANOSECONDS.toMillis(gcStartNanoTime - watchStartNanoTime);

    //将GC掉的对象从内存泄漏的怀疑列表中移除
    removeWeaklyReachableReferences();

    if (debuggerControl.isDebuggerAttached()) {
      // The debugger can create false leaks.
      return RETRY;
    }

    // 如果列表没有内存泄漏的引用对象,说明当前GC已经回收对象,没有内存泄漏,不需要处理
    if (gone(reference)) {
      return DONE;
    }

    // 如果还有内存泄露的怀疑对象 执行一次GC
    gcTrigger.runGc();

    //再一次将GC掉的对象从内存泄漏的怀疑列表中移除
    removeWeaklyReachableReferences();

    //判断是否还有内存泄露的对象,没有直接返回DONE,有的话,进行dump
    if (!gone(reference)) {
      long startDumpHeap = System.nanoTime();
      long gcDurationMs = NANOSECONDS.toMillis(startDumpHeap - gcStartNanoTime);
      //dump分析,发通知,弹出等待的toast
      File heapDumpFile = heapDumper.dumpHeap();
      if (heapDumpFile == RETRY_LATER) {
        // Could not dump the heap.
        return RETRY;
      }
      long heapDumpDurationMs = NANOSECONDS.toMillis(System.nanoTime() - startDumpHeap);

      HeapDump heapDump = heapDumpBuilder.heapDumpFile(heapDumpFile).referenceKey(reference.key)
          .referenceName(reference.name)
          .watchDurationMs(watchDurationMs)
          .gcDurationMs(gcDurationMs)
          .heapDumpDurationMs(heapDumpDurationMs)
          .build();

      heapdumpListener.analyze(heapDump);
    }
    return DONE;
  }

  //通过key判断是否还有对象无法被回收
  private boolean gone(KeyedWeakReference reference) {
    return !retainedKeys.contains(reference.key);
  }

  ////将GC掉的对象从内存泄漏的怀疑名单中移除
  private void removeWeaklyReachableReferences() {

    KeyedWeakReference ref;
    while ((ref = (KeyedWeakReference) queue.poll()) != null) {
      retainedKeys.remove(ref.key);
    }
  }

到了这一步,就是可以确认是否有内存泄露了。

  1. dump文件, 发通知
    AndroidHeapDumper.java:
public File dumpHeap() {
    File heapDumpFile = leakDirectoryProvider.newHeapDumpFile();

    if (heapDumpFile == RETRY_LATER) {
      return RETRY_LATER;
    }

    //等待toast提示
    FutureResult<Toast> waitingForToast = new FutureResult<>();
    showToast(waitingForToast);

    if (!waitingForToast.wait(5, SECONDS)) {
      CanaryLog.d("Did not dump heap, too much time waiting for Toast.");
      return RETRY_LATER;
    }

    //发通知
    Notification.Builder builder = new Notification.Builder(context)
        .setContentTitle(context.getString(R.string.leak_canary_notification_dumping));
    Notification notification = LeakCanaryInternals.buildNotification(context, builder);
    NotificationManager notificationManager =
        (NotificationManager) context.getSystemService(Context.NOTIFICATION_SERVICE);
    int notificationId = (int) SystemClock.uptimeMillis();
    notificationManager.notify(notificationId, notification);

    Toast toast = waitingForToast.get();
    try {
      // 最终使用的是Android提供的工具dump数据到hprof文件
      Debug.dumpHprofData(heapDumpFile.getAbsolutePath());
      cancelToast(toast);
      notificationManager.cancel(notificationId);
      return heapDumpFile;
    } catch (Exception e) {
      CanaryLog.d(e, "Could not dump heap");
      // Abort heap dump
      return RETRY_LATER;
    }
  }

  1. 继上面的调用heapdumpListener.analyze(heapDump)进行dump数据分析,启动服务HeapAnalyzerService
    ServiceHeapDumpListener.java
public final class ServiceHeapDumpListener implements HeapDump.Listener {

  private final Context context;
  private final Class<? extends AbstractAnalysisResultService> listenerServiceClass;

  public ServiceHeapDumpListener(@NonNull final Context context,
      @NonNull final Class<? extends AbstractAnalysisResultService> listenerServiceClass) {
    this.listenerServiceClass = checkNotNull(listenerServiceClass, "listenerServiceClass");
    this.context = checkNotNull(context, "context").getApplicationContext();
  }

  //其实就是启动了一个前台服务在其他进程分析内存泄漏的引用路径
  @Override public void analyze(@NonNull HeapDump heapDump) {
    checkNotNull(heapDump, "heapDump");
    HeapAnalyzerService.runAnalysis(context, heapDump, listenerServiceClass);
  }
}

HeapAnalyzerService.java

public final class HeapAnalyzerService extends ForegroundService
    implements AnalyzerProgressListener {

  private static final String LISTENER_CLASS_EXTRA = "listener_class_extra";
  private static final String HEAPDUMP_EXTRA = "heapdump_extra";

  public static void runAnalysis(Context context, HeapDump heapDump,
      Class<? extends AbstractAnalysisResultService> listenerServiceClass) {
    setEnabledBlocking(context, HeapAnalyzerService.class, true);
    setEnabledBlocking(context, listenerServiceClass, true);
    Intent intent = new Intent(context, HeapAnalyzerService.class);
    intent.putExtra(LISTENER_CLASS_EXTRA, listenerServiceClass.getName());
    intent.putExtra(HEAPDUMP_EXTRA, heapDump);
    ContextCompat.startForegroundService(context, intent);
  }

  public HeapAnalyzerService() {
    super(HeapAnalyzerService.class.getSimpleName(), R.string.leak_canary_notification_analysing);
  }

  @Override protected void onHandleIntentInForeground(@Nullable Intent intent) {
    if (intent == null) {
      CanaryLog.d("HeapAnalyzerService received a null intent, ignoring.");
      return;
    }
    String listenerClassName = intent.getStringExtra(LISTENER_CLASS_EXTRA);
    HeapDump heapDump = (HeapDump) intent.getSerializableExtra(HEAPDUMP_EXTRA);

    HeapAnalyzer heapAnalyzer =
        new HeapAnalyzer(heapDump.excludedRefs, this, heapDump.reachabilityInspectorClasses);
    // 开始分析
    AnalysisResult result = heapAnalyzer.checkForLeak(heapDump.heapDumpFile, heapDump.referenceKey,
        heapDump.computeRetainedHeapSize);
    // 返回分析结果
    AbstractAnalysisResultService.sendResultToListener(this, listenerClassName, heapDump, result);
  }

  @Override public void onProgressUpdate(Step step) {
    int percent = (int) ((100f * step.ordinal()) / Step.values().length);
    CanaryLog.d("Analysis in progress, working on: %s", step.name());
    String lowercase = step.name().replace("_", " ").toLowerCase();
    String message = lowercase.substring(0, 1).toUpperCase() + lowercase.substring(1);
    showForegroundNotification(100, percent, false, message);
  }
}

HeapAnalyzer.java:

public @NonNull AnalysisResult checkForLeak(@NonNull File heapDumpFile,
      @NonNull String referenceKey,
      boolean computeRetainedSize) {
    long analysisStartNanoTime = System.nanoTime();

    if (!heapDumpFile.exists()) {
      Exception exception = new IllegalArgumentException("File does not exist: " + heapDumpFile);
      return failure(exception, since(analysisStartNanoTime));
    }

    try {
      listener.onProgressUpdate(READING_HEAP_DUMP_FILE);
      HprofBuffer buffer = new MemoryMappedFileBuffer(heapDumpFile);
      HprofParser parser = new HprofParser(buffer);
      listener.onProgressUpdate(PARSING_HEAP_DUMP);
      Snapshot snapshot = parser.parse();
      listener.onProgressUpdate(DEDUPLICATING_GC_ROOTS);
      deduplicateGcRoots(snapshot);
      listener.onProgressUpdate(FINDING_LEAKING_REF);
      Instance leakingRef = findLeakingReference(referenceKey, snapshot);

      // False alarm, weak reference was cleared in between key check and heap dump.
      if (leakingRef == null) {
        String className = leakingRef.getClassObj().getClassName();
        return noLeak(className, since(analysisStartNanoTime));
      }
      return findLeakTrace(analysisStartNanoTime, snapshot, leakingRef, computeRetainedSize);
    } catch (Throwable e) {
      return failure(e, since(analysisStartNanoTime));
    }
  }

总结

在应用启动时,通过 LeakCanary.install() 监听内存泄漏,LeakCanary的处理过程如下:

构建 RetWatcher 提供内存泄漏分析前的相关参数(如 DisplayService 通知服务,excludeRefs() 排除系统源码泄漏),通过 Application.registerXxxLifecycleCallback() 监听Activity或Fragment生命周期转发给 RefWatcher

在Activity或Fragment回调 onDestroy() 时,监听引用对象是否还在 ReferenceQueue 中,有则表示内存泄漏,创建dump文件并通过Android工具 Debug.dumpHprofData() 写入内存泄漏数据,hprof文件将会在另一个前台服务分析

正文完