Lifecycle
Lifecycles中文意思就是生命周期感知型组件,用来感知activity和fragment的生命周期的组件,主要运用观察者模式,Jetpack里很多组件都是基于Lifecycles来实现的,可以毫不夸张的说,Lifecycles是Jetpack的基础、是Jetpack组件库的重中之重。
基本使用
被观察者:主要是activity和fragment,实现LifecycleOwner接口(Support Library 26.1.0 及更高版本中的 Fragment 和 Activity 已实现 LifecycleOwner接口),并且在初始化方法里添加观察者就行了
public class ComponentActivity extends androidx.core.app.ComponentActivity implements
LifecycleOwner,
ViewModelStoreOwner,
SavedStateRegistryOwner,
OnBackPressedDispatcherOwner {
class MainActivity : BaseActivity() {
companion object {
const val TAG = "MainActivity"
fun open(context: Context) {
val intent = Intent(context, MainActivity::class.java)
intent.flags = Intent.FLAG_ACTIVITY_CLEAR_TOP
context.startActivity(intent)
}
}
override fun layoutId(): Int {
return R.layout.activity_main
}
override fun onCreate(savedInstanceState: Bundle?) {
super.onCreate(savedInstanceState)
ivIconBaidu.setOnClickListener {
WebViewActivity.open(baseContext)
}
var basePresenter: BasePresenter<TextView> = BasePresenter();
lifecycle.addObserver(basePresenter)
}
}
观察者:实现LifecycleObserver接口,就能观测到被观察者的生命周期了,并且想观测哪些生命周期就运用哪个注解
public class BasePresenter<T> implements LifecycleObserver {
private static final String TAG = "BasePresenter";
/**
* 绑定view
*/
public void attachView(T view) {
Log.e(TAG, "绑定了view");
}
/**
* 解绑
*/
public void detachView() {
Log.e(TAG, "解绑了view");
}
@OnLifecycleEvent(Lifecycle.Event.ON_CREATE)
void onCreateX(LifecycleOwner owner) {
attachView(null);
}
@OnLifecycleEvent(Lifecycle.Event.ON_START)
void onStartX(LifecycleOwner owner) {
}
@OnLifecycleEvent(Lifecycle.Event.ON_STOP)
void onStop(LifecycleOwner owner) {
}
@OnLifecycleEvent(Lifecycle.Event.ON_RESUME)
void onResume(LifecycleOwner owner) {
}
@OnLifecycleEvent(Lifecycle.Event.ON_PAUSE)
void onPause(LifecycleOwner owner) {
}
@OnLifecycleEvent(Lifecycle.Event.ON_DESTROY)
void onDestory(LifecycleOwner owner) {
detachView();
}
@OnLifecycleEvent(Lifecycle.Event.ON_ANY)
void onAny(LifecycleOwner owner) {
}
}
打印结果
绑定了view
解绑了view
打印结果和我们预期的也是一样的,到这里,我们Lifecycles的基本用法讲完了,那么Lifecycles是怎么实现监听生命周期变化的呢?其实内部和glide的生命周期监听也是类似的,其实就是在当前Activity或者fragment中绑定一个空的fragment来实现监听的。
源码分析
上面说过Support Library 26.1.0 及更高版本中的 Activity 已经实现 LifecycleOwner接口,所以先找实现LifecycleOwner接口的Activity的父类
public class ComponentActivity extends androidx.core.app.ComponentActivity implements
LifecycleOwner,
ViewModelStoreOwner,
SavedStateRegistryOwner,
OnBackPressedDispatcherOwner {
先进入接口LifecycleOwner看看
/**
* A class that has an Android lifecycle. These events can be used by custom components to
* handle lifecycle changes without implementing any code inside the Activity or the Fragment.
*
* @see Lifecycle
*/
@SuppressWarnings({"WeakerAccess", "unused"})
public interface LifecycleOwner {
/**
* Returns the Lifecycle of the provider.
*
* @return The lifecycle of the provider.
*/
@NonNull
Lifecycle getLifecycle();
}
我们发现里面就一个Lifecycle变量声明的方法getLifecycle,所有我们直接进入Lifecycle类,Lifecycle是个抽象类,我们查看里面的方法和变量
我们看到有Event,它里面包含了生命周期的一些事件的枚举,然后是State,它里面是一些状态的枚举。
构成 Android Activity 生命周期的状态和事件
您可以将状态State看作图中的节点,将事件Event看作这些节点之间的边,比如你执行ON_CREATE事件的时候,你的状态就会从INITIALIZED变为CREATED。 还有addObserver添加和removeObserver删除观察者的方法,还有一个getCurrentState获取当前状态的方法,我们现进入addObserver方法看下
@Override
public void addObserver(@NonNull LifecycleObserver observer) {
State initialState = mState == DESTROYED ? DESTROYED : INITIALIZED;
ObserverWithState statefulObserver = new ObserverWithState(observer, initialState);
ObserverWithState previous = mObserverMap.putIfAbsent(observer, statefulObserver);
首先会获得初始状态值,如果是第一次进入肯定不等于DESTROYED,所以初始状态会是INITIALIZED,再把这个状态initialState和observer观察者放入ObserverWithState类型的变量statefulObserver里,最后再把statefulObserver和observer放进一个Map数组里mObserverMap,addObserver我们先看到这一步,因为再看下去我怕你们会懵逼,所以我们先直接到ComponentActivity的onCreate方法看
/**
* {@inheritDoc}
*
* If your ComponentActivity is annotated with {@link ContentView}, this will
* call {@link #setContentView(int)} for you.
*/
@Override
protected void onCreate(@Nullable Bundle savedInstanceState) {
super.onCreate(savedInstanceState);
mSavedStateRegistryController.performRestore(savedInstanceState);
ReportFragment.injectIfNeededIn(this);
if (mContentLayoutId != 0) {
setContentView(mContentLayoutId);
}
}
我看进入ReportFragment.injectIfNeededIn(this)的方法里看下
public static void injectIfNeededIn(Activity activity) {
// ProcessLifecycleOwner should always correctly work and some activities may not extend
// FragmentActivity from support lib, so we use framework fragments for activities
android.app.FragmentManager manager = activity.getFragmentManager();
if (manager.findFragmentByTag(REPORT_FRAGMENT_TAG) == null) {
manager.beginTransaction().add(new ReportFragment(), REPORT_FRAGMENT_TAG).commit();
// Hopefully, we are the first to make a transaction.
manager.executePendingTransactions();
}
}
我们看到injectIfNeededIn的作用就是把ReportFragment通过beginTransaction().add添加到Fragment管理器manager里面,我们再进入ReportFragment里看看
@RestrictTo(RestrictTo.Scope.LIBRARY_GROUP_PREFIX)
public class ReportFragment extends Fragment {
private static final String REPORT_FRAGMENT_TAG = "androidx.lifecycle"
+ ".LifecycleDispatcher.report_fragment_tag";
public static void injectIfNeededIn(Activity activity) {
// ProcessLifecycleOwner should always correctly work and some activities may not extend
// FragmentActivity from support lib, so we use framework fragments for activities
android.app.FragmentManager manager = activity.getFragmentManager();
if (manager.findFragmentByTag(REPORT_FRAGMENT_TAG) == null) {
manager.beginTransaction().add(new ReportFragment(), REPORT_FRAGMENT_TAG).commit();
// Hopefully, we are the first to make a transaction.
manager.executePendingTransactions();
}
}
static ReportFragment get(Activity activity) {
return (ReportFragment) activity.getFragmentManager().findFragmentByTag(
REPORT_FRAGMENT_TAG);
}
private ActivityInitializationListener mProcessListener;
private void dispatchCreate(ActivityInitializationListener listener) {
if (listener != null) {
listener.onCreate();
}
}
private void dispatchStart(ActivityInitializationListener listener) {
if (listener != null) {
listener.onStart();
}
}
private void dispatchResume(ActivityInitializationListener listener) {
if (listener != null) {
listener.onResume();
}
}
@Override
public void onActivityCreated(Bundle savedInstanceState) {
super.onActivityCreated(savedInstanceState);
dispatchCreate(mProcessListener);
dispatch(Lifecycle.Event.ON_CREATE);
}
@Override
public void onStart() {
super.onStart();
dispatchStart(mProcessListener);
dispatch(Lifecycle.Event.ON_START);
}
@Override
public void onResume() {
super.onResume();
dispatchResume(mProcessListener);
dispatch(Lifecycle.Event.ON_RESUME);
}
@Override
public void onPause() {
super.onPause();
dispatch(Lifecycle.Event.ON_PAUSE);
}
@Override
public void onStop() {
super.onStop();
dispatch(Lifecycle.Event.ON_STOP);
}
@Override
public void onDestroy() {
super.onDestroy();
dispatch(Lifecycle.Event.ON_DESTROY);
// just want to be sure that we won't leak reference to an activity
mProcessListener = null;
}
private void dispatch(Lifecycle.Event event) {
Activity activity = getActivity();
if (activity instanceof LifecycleRegistryOwner) {
((LifecycleRegistryOwner) activity).getLifecycle().handleLifecycleEvent(event);
return;
}
if (activity instanceof LifecycleOwner) {
Lifecycle lifecycle = ((LifecycleOwner) activity).getLifecycle();
if (lifecycle instanceof LifecycleRegistry) {
((LifecycleRegistry) lifecycle).handleLifecycleEvent(event);
}
}
}
void setProcessListener(ActivityInitializationListener processListener) {
mProcessListener = processListener;
}
interface ActivityInitializationListener {
void onCreate();
void onStart();
void onResume();
}
}
我们看到ReportFragment的生命周期里对应分发了Lifecycle里的那些枚举事件,所以activity生命周期发生变化的时候就会走ReportFragment的生命周期里的一些方法,所以我们再进入dispatch()方法
private void dispatch(Lifecycle.Event event) {
Activity activity = getActivity();
if (activity instanceof LifecycleRegistryOwner) {
((LifecycleRegistryOwner) activity).getLifecycle().handleLifecycleEvent(event);
return;
}
if (activity instanceof LifecycleOwner) {
Lifecycle lifecycle = ((LifecycleOwner) activity).getLifecycle();
if (lifecycle instanceof LifecycleRegistry) {
((LifecycleRegistry) lifecycle).handleLifecycleEvent(event);
}
}
}
dispatch方法里前面就是判断了activity是否有实现LifecycleRegistryOwner接口或者是LifecycleOwner接口(LifecycleRegistryOwner其实也是派生于LifecycleOwner的),如果是的话就进入执行handleLifecycleEvent方法,
public void handleLifecycleEvent(@NonNull Lifecycle.Event event) {
State next = getStateAfter(event);
moveToState(next);
}
一开始先通过getStateAfter获取当前状态的下一个状态
static State getStateAfter(Event event) {
switch (event) {
case ON_CREATE:
case ON_STOP:
return CREATED;
case ON_START:
case ON_PAUSE:
return STARTED;
case ON_RESUME:
return RESUMED;
case ON_DESTROY:
return DESTROYED;
case ON_ANY:
break;
}
throw new IllegalArgumentException("Unexpected event value " + event);
}
看过前面那张状态和事件的枚举图现在来看这个getStateAfter方法就很好理解了把,例如如果你当前正在ON_CREATE或者ON_STOP,下一个状态就会走到CREATED状态。我们再把获得的下一个状态传到moveToState方法里,去真正移动到下一个状态
private void moveToState(State next) {
if (mState == next) {
return;
}
mState = next;
if (mHandlingEvent || mAddingObserverCounter != 0) {
mNewEventOccurred = true;
// we will figure out what to do on upper level.
return;
}
mHandlingEvent = true;
sync();
mHandlingEvent = false;
}
如果下一个状态和当前状态相同就直接返回,否则执行sync()同步操作,我们再进入sync
private void sync() {
LifecycleOwner lifecycleOwner = mLifecycleOwner.get();
if (lifecycleOwner == null) {
throw new IllegalStateException("LifecycleOwner of this LifecycleRegistry is already"
+ "garbage collected. It is too late to change lifecycle state.");
}
while (!isSynced()) {
mNewEventOccurred = false;
// no need to check eldest for nullability, because isSynced does it for us.
if (mState.compareTo(mObserverMap.eldest().getValue().mState) < 0) {
backwardPass(lifecycleOwner);
}
Entry<LifecycleObserver, ObserverWithState> newest = mObserverMap.newest();
if (!mNewEventOccurred && newest != null
&& mState.compareTo(newest.getValue().mState) > 0) {
forwardPass(lifecycleOwner);
}
}
mNewEventOccurred = false;
}
在看这个同步方法之前,我们再来理解下那张状态图,
构成 Android Activity 生命周期的状态和事件
我们知道我们的activity随着用户的操作,状态会不断的改变,状态改变就会遵循上面这张图,比如onCreate跑完,状态就会变成created,如果执行完onStart,状态就会从created变成started,执行完onResune状态就会从started变成resumed以此类推。我们在前面代码知道,我们的观察者刚刚进来的初始换状态是INITIALIZED状态,所以观察者的状态可能和我们的activity的状态不一样,所以sync方法就是来让观察者和activity的状态同步的,我们再看到代码,里面主要是两个方法backwardPass和forwardPass,一个是向前移动,一个是向后移动, 如果activity的状态是started,观察者的状态是created,那就要把观察者往后推;如果activity的状态是started,观察者的状态是resumed,那就要把观察者往前推。我们进入其中一个方法看看,我们进入backwardPass
private void backwardPass(LifecycleOwner lifecycleOwner) {
Iterator<Entry<LifecycleObserver, ObserverWithState>> descendingIterator =
mObserverMap.descendingIterator();
while (descendingIterator.hasNext() && !mNewEventOccurred) {
Entry<LifecycleObserver, ObserverWithState> entry = descendingIterator.next();
ObserverWithState observer = entry.getValue();
while ((observer.mState.compareTo(mState) > 0 && !mNewEventOccurred
&& mObserverMap.contains(entry.getKey()))) {
Event event = downEvent(observer.mState);
pushParentState(getStateAfter(event));
observer.dispatchEvent(lifecycleOwner, event);
popParentState();
}
}
}
一开始就是拿到mObserverMap(所有观察者的map)的迭代器,然后循环每一个观察者,然后把被观察者lifecycleOwner和观察者的执行event 传入到dispatchEvent执行,我们进入dispatchEvent方法
static class ObserverWithState {
State mState;
LifecycleEventObserver mLifecycleObserver;
ObserverWithState(LifecycleObserver observer, State initialState) {
mLifecycleObserver = Lifecycling.lifecycleEventObserver(observer);
mState = initialState;
}
void dispatchEvent(LifecycleOwner owner, Event event) {
State newState = getStateAfter(event);
mState = min(mState, newState);
mLifecycleObserver.onStateChanged(owner, event);
mState = newState;
}
}
我们发现dispatchEvent是静态内部类ObserverWithState其中的一个方法,ObserverWithState类还记得么?就是前面我们把所有观察者和状态存起来的类, 所以我们先看ObserverWithState的构造方法里的lifecycleEventObserver,我们发现lifecycleEventObserver最后都 return new ReflectiveGenericLifecycleObserver(object)到这里,所以我们直接进入
/**
* An internal implementation of {@link LifecycleObserver} that relies on reflection.
*/
class ReflectiveGenericLifecycleObserver implements LifecycleEventObserver {
private final Object mWrapped;
private final CallbackInfo mInfo;
ReflectiveGenericLifecycleObserver(Object wrapped) {
mWrapped = wrapped;
mInfo = ClassesInfoCache.sInstance.getInfo(mWrapped.getClass());
}
@Override
public void onStateChanged(LifecycleOwner source, Event event) {
mInfo.invokeCallbacks(source, event, mWrapped);
}
}
CallbackInfo getInfo(Class klass) {
CallbackInfo existing = mCallbackMap.get(klass);
if (existing != null) {
return existing;
}
existing = createInfo(klass, null);
return existing;
}
private CallbackInfo createInfo(Class klass, @Nullable Method[] declaredMethods) {
Class superclass = klass.getSuperclass();
Map<MethodReference, Lifecycle.Event> handlerToEvent = new HashMap<>();
if (superclass != null) {
CallbackInfo superInfo = getInfo(superclass);
if (superInfo != null) {
handlerToEvent.putAll(superInfo.mHandlerToEvent);
}
}
Class[] interfaces = klass.getInterfaces();
for (Class intrfc : interfaces) {
for (Map.Entry<MethodReference, Lifecycle.Event> entry : getInfo(
intrfc).mHandlerToEvent.entrySet()) {
verifyAndPutHandler(handlerToEvent, entry.getKey(), entry.getValue(), klass);
}
}
Method[] methods = declaredMethods != null ? declaredMethods : getDeclaredMethods(klass);
boolean hasLifecycleMethods = false;
for (Method method : methods) {
OnLifecycleEvent annotation = method.getAnnotation(OnLifecycleEvent.class);
if (annotation == null) {
continue;
}
hasLifecycleMethods = true;
Class<?>[] params = method.getParameterTypes();
int callType = CALL_TYPE_NO_ARG;
if (params.length > 0) {
callType = CALL_TYPE_PROVIDER;
if (!params[0].isAssignableFrom(LifecycleOwner.class)) {
throw new IllegalArgumentException(
"invalid parameter type. Must be one and instanceof LifecycleOwner");
}
}
Lifecycle.Event event = annotation.value();
if (params.length > 1) {
callType = CALL_TYPE_PROVIDER_WITH_EVENT;
if (!params[1].isAssignableFrom(Lifecycle.Event.class)) {
throw new IllegalArgumentException(
"invalid parameter type. second arg must be an event");
}
if (event != Lifecycle.Event.ON_ANY) {
throw new IllegalArgumentException(
"Second arg is supported only for ON_ANY value");
}
}
if (params.length > 2) {
throw new IllegalArgumentException("cannot have more than 2 params");
}
MethodReference methodReference = new MethodReference(callType, method);
verifyAndPutHandler(handlerToEvent, methodReference, event, klass);
}
CallbackInfo info = new CallbackInfo(handlerToEvent);
mCallbackMap.put(klass, info);
mHasLifecycleMethods.put(klass, hasLifecycleMethods);
return info;
}
其实一步步追踪进去ClassesInfoCache.sInstance.getInfo(mWrapped.getClass());就是通过反射拿到带有那些注解的方法, mInfo.invokeCallbacks(source, event, mWrapped);就是最后真正执行那些注解方法的地方。
至此,我们已经分析完Lifecycles全部源码的,了解了Lifecycles的实际具体执行过程。
总结:
通过在被观察者的activity里套一个空的fragment来监听被观察者的生命周期,观察者实现LifecycleObserver然后通过注解获取一些和被观察者生命周期的一些监听方法,来实现观察者和被观察者的生命周期的统一。
一开始通过addObserver把观察者和它的初始状态放进一个数组里(因为观察者可能有好多个),然后在fragment的生命周期里会去调一个dispatch方法,把Event事件传进去,然后获取activity的下一个状态,(这个很好理解吧,因为随着用户的操作,actvity的状态是会不断改变的,比如你当前处于Created状态,如果用户操作了onCreate事件,actvity就从Created到达resumed状态了),然后会去同步观察者和activity的状态,然后去通过反射执行你注解了的方法,就可以在观察者里获取actvity的状态了
如果activity或者fragment生命周期变化Lifecycle通过反射获取观察者对象,调用标注了注解的方法。