Jetpack 之 Lifecycles 源码分析
2020/6/24 23:27:05
本文主要是介绍Jetpack 之 Lifecycles 源码分析,对大家解决编程问题具有一定的参考价值,需要的程序猿们随着小编来一起学习吧!
LifecycleOwner
LifecycleOwner是单一方法接口,实现此接口表明此类具有生命周期Lifecycle。
public interface LifecycleOwner {
/**
* Returns the Lifecycle of the provider.
*
* @return The lifecycle of the provider.
*/
@NonNull
Lifecycle getLifecycle();
}
复制代码LifecycleObserver
LifecycleObserver,实现此接口的类,可以观察LifecycleOwner的生命周期Lifecycle状态。
public interface LifecycleObserver {
}
复制代码这里了解一下它的几个常用实现类。
FullLifecycleObserver
实现了
LifecycleObserver,定义了一些常用的生命周期事件回调。
interface FullLifecycleObserver extends LifecycleObserver {
void onCreate(LifecycleOwner owner);
void onStart(LifecycleOwner owner);
void onResume(LifecycleOwner owner);
void onPause(LifecycleOwner owner);
void onStop(LifecycleOwner owner);
void onDestroy(LifecycleOwner owner);
}
复制代码LifecycleEventObserver
实现了
LifecycleObserver,暴露生命周期变更时的回调。
public interface LifecycleEventObserver extends LifecycleObserver {
/**
* Called when a state transition event happens.
*
* @param source The source of the event
* @param event The event
*/
void onStateChanged(@NonNull LifecycleOwner source, @NonNull Lifecycle.Event event);
}
复制代码ReflectiveGenericLifecycleObserver
实现了
LifecycleObserver。在构造器中,会通过反射将使用了OnLifecycleEvent注解的方法保存到Map中,当生命周期变动的时候,通过反射调用对应的方法。
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);
}
}
复制代码构造器里面接受一个 LifecycleObserver,然后所有的解析逻辑实际上都是 ClassesInfoCache完成的。
ClassesInfoCache
通过反射解析和存放使用了
OnLifecycleEvent的方法,方便生命周期变动的时候回调对应的方法。
CallbackInfo getInfo(Class klass) {
CallbackInfo existing = mCallbackMap.get(klass);
// 已经存在,直接返回缓存的
if (existing != null) {
return existing;
}
// 解析
existing = createInfo(klass, null);
return existing;
}
复制代码解析的过程主要是发生在 createInfo() 里面,我们来看看这个方法。
private CallbackInfo createInfo(Class klass, @Nullable Method[] declaredMethods) {
// 解析父类
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);
}
}
// 解析父接口
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);
}
}
// 开始解析自身
// 1. 获取所有声明的方法
Method[] methods = declaredMethods != null ? declaredMethods : getDeclaredMethods(klass);
boolean hasLifecycleMethods = false;
for (Method method : methods) {
// 2. 找到所有使用了 OnLifecycleEvent 注解的方法
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();
// 这里是确定参数,除了ON_ANY事件可以接收两个参数,其他事件只能接收一个LifecycleOwner参数
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");
}
// 3. 保存对应关系
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;
}
复制代码Lifecycle
Lifecycle用于存储有关组件(如 Activity 或 Fragment)的生命周期状态的信息,并允许其他对象观察此状态。
Lifecyce.State
Lifecycle.State标记组件生命周期状态。
public enum State {
// 标记 LifecycleOwner 是 DESTROYED 状态,这个状态之后,不会再分发任何事件。比如 Activity.onDestroy() 已经调用了。
DESTROYED,
// 标记 LifecycleOwner 是 INITIALIZED 状态。比如 Activity 已经创建,但是还没有走到 onCreate()。
INITIALIZED,
// 标记 LifecycleOwner 是 CREATED 状态。比如 Activity.onCreate() 或 Activity.onStop()。
CREATED,
// 标记 LifecycleOwner 是 STARTED 状态。比如 Activity.onStart() 或者 Activity.onPause()。
STARTED,
// 标记 LifecycleOwner 是 RESUMED 状态。比如 Activity.onResume()。
RESUMED;
public boolean isAtLeast(@NonNull State state) {
return compareTo(state) >= 0;
}
}
复制代码Lifecycle.Event
Lifecycle.Event是分发的生命周期事件,对应组件一系列生命周期回调。
public enum Event {
ON_CREATE,
ON_START,
ON_RESUME,
ON_PAUSE,
ON_STOP,
ON_DESTROY,
ON_ANY
}
复制代码ON_CREATE, ON_START, ON_RESUME 这三个事件是
LifecycleOwner对应的生命周期方法返回之后被分发的;ON_PAUSE, ON_STOP, ON_DESTROY 这三个事件是在LifecycleOwner对应的生命周期事件调用之前被分发的。
下图显示了 Event 与 State 之间的关系。
LifecycleRegistry
LifecycleRegistry是Lifecycle的实现类。
前面说了,Lifecycle 用来存放组件生命周期状态,且允许其他对象观察此状态。那么里面必然会存放 LifecycleOwner 和 Lifecycle.State ,并提供 添加/移除 LifecycleObserver 的方法。
private State mState;
private final WeakReference<LifecycleOwner> mLifecycleOwner;
public LifecycleRegistry(@NonNull LifecycleOwner provider) {
mLifecycleOwner = new WeakReference<>(provider);
mState = INITIALIZED;
}
// 用来存放 LifecycleObserver
private FastSafeIterableMap<LifecycleObserver, ObserverWithState> mObserverMap =
new FastSafeIterableMap<>();
@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);
// 已经被在 mObserverMap 里面了
if (previous != null) {
return;
}
LifecycleOwner lifecycleOwner = mLifecycleOwner.get();
if (lifecycleOwner == null) {
return;
}
boolean isReentrance = mAddingObserverCounter != 0 || mHandlingEvent;
State targetState = calculateTargetState(observer);
mAddingObserverCounter++;
// 保证给新增加的 LifecycleObserver 分发对应的 Lifecycle.Event 让其到达最新的状态
while ((statefulObserver.mState.compareTo(targetState) < 0
&& mObserverMap.contains(observer))) {
pushParentState(statefulObserver.mState);
statefulObserver.dispatchEvent(lifecycleOwner, upEvent(statefulObserver.mState));
popParentState();
// mState / subling may have been changed recalculate
targetState = calculateTargetState(observer);
}
if (!isReentrance) {
sync();
}
mAddingObserverCounter--;
}
@Override
public void removeObserver(@NonNull LifecycleObserver observer) {
mObserverMap.remove(observer);
}
复制代码这里需要注意一下 ObserverWithState,这个类是 LifecycleRegistry 的内部类,他在构造器中对 LifecycleObserver 进行了一次转换。
ObserverWithState(LifecycleObserver observer, State initialState) {
// 这里通过 Lifecycling.lifecycleEventObserver()进行一次转换
mLifecycleObserver = Lifecycling.lifecycleEventObserver(observer);
mState = initialState;
}
复制代码我们来看一下 Lifecycling.lifecycleEventObserver()。
static LifecycleEventObserver lifecycleEventObserver(Object object) {
boolean isLifecycleEventObserver = object instanceof LifecycleEventObserver;
boolean isFullLifecycleObserver = object instanceof FullLifecycleObserver;
// 1. 如果是 LifecycleEventObserver,FullLifecycleObserver 则返回 FullLifecycleObserverAdapter
if (isLifecycleEventObserver && isFullLifecycleObserver) {
return new FullLifecycleObserverAdapter((FullLifecycleObserver) object,
(LifecycleEventObserver) object);
}
// 2. 如果是 FullLifecycleObserver 则返回 FullLifecycleObserverAdapter
if (isFullLifecycleObserver) {
return new FullLifecycleObserverAdapter((FullLifecycleObserver) object, null);
}
// 3. 如果是 LifecycleEventObserver 直接返回
if (isLifecycleEventObserver) {
return (LifecycleEventObserver) object;
}
// 4. 不是上面的情况,需要通过 getObserverConstructorType() 决定
final Class<?> klass = object.getClass();
int type = getObserverConstructorType(klass);
if (type == GENERATED_CALLBACK) {
List<Constructor<? extends GeneratedAdapter>> constructors =
sClassToAdapters.get(klass);
if (constructors.size() == 1) {
GeneratedAdapter generatedAdapter = createGeneratedAdapter(
constructors.get(0), object);
return new SingleGeneratedAdapterObserver(generatedAdapter);
}
GeneratedAdapter[] adapters = new GeneratedAdapter[constructors.size()];
for (int i = 0; i < constructors.size(); i++) {
adapters[i] = createGeneratedAdapter(constructors.get(i), object);
}
return new CompositeGeneratedAdaptersObserver(adapters);
}
return new ReflectiveGenericLifecycleObserver(object);
}
复制代码这个方法对 LifecycleObserver 进行了如下转换。
- 如果是
LifecycleEventObserver和FullLifecycleObserver,则转换成FullLifecycleObserverAdapter; - 如果是
FullLifecycleObserver,则转换成FullLifecycleObserverAdapter; - 如果是
LifecycleEventObserver,直接返回; - 如果
getObserverConstructorType()是 GENERATED_CALLBACK,则转换成对应的 GeneratedAdapterObserver; - 其他情况则转换成
ReflectiveGenericLifecycleObserver。
这里主要分析一下 getObserverConstructorType() 这个方法,其他的几种情况都比较简单,可以自行查看源码,这里就不赘述了。
private static int getObserverConstructorType(Class<?> klass) {
// 缓存有,直接返回缓存里面的
Integer callbackCache = sCallbackCache.get(klass);
if (callbackCache != null) {
return callbackCache;
}
// 这里调用了 resolveObserverCallbackType()
int type = resolveObserverCallbackType(klass);
sCallbackCache.put(klass, type);
return type;
}
复制代码这个方法调用了 resolveObserverCallbackType() 来解析 callBack 类型。
private static int resolveObserverCallbackType(Class<?> klass) {
// anonymous class bug:35073837
if (klass.getCanonicalName() == null) {
return REFLECTIVE_CALLBACK;
}
// 1. generatedConstructor() 获取构造器
Constructor<? extends GeneratedAdapter> constructor = generatedConstructor(klass);
if (constructor != null) {
sClassToAdapters.put(klass, Collections
.<Constructor<? extends GeneratedAdapter>>singletonList(constructor));
return GENERATED_CALLBACK;
}
// 2. 使用了 OnLifecycleEvent 注解的
boolean hasLifecycleMethods = ClassesInfoCache.sInstance.hasLifecycleMethods(klass);
if (hasLifecycleMethods) {
return REFLECTIVE_CALLBACK;
}
// 3. 递归看父类
Class<?> superclass = klass.getSuperclass();
List<Constructor<? extends GeneratedAdapter>> adapterConstructors = null;
if (isLifecycleParent(superclass)) {
if (getObserverConstructorType(superclass) == REFLECTIVE_CALLBACK) {
return REFLECTIVE_CALLBACK;
}
adapterConstructors = new ArrayList<>(sClassToAdapters.get(superclass));
}
// 递归看父接口
for (Class<?> intrface : klass.getInterfaces()) {
if (!isLifecycleParent(intrface)) {
continue;
}
if (getObserverConstructorType(intrface) == REFLECTIVE_CALLBACK) {
return REFLECTIVE_CALLBACK;
}
if (adapterConstructors == null) {
adapterConstructors = new ArrayList<>();
}
adapterConstructors.addAll(sClassToAdapters.get(intrface));
}
if (adapterConstructors != null) {
sClassToAdapters.put(klass, adapterConstructors);
return GENERATED_CALLBACK;
}
return REFLECTIVE_CALLBACK;
}
复制代码这里我们主要看下返回 GENERATED_CALLBACK 的情况,它通过 generatedConstructor() 获取构造器。
private static Constructor<? extends GeneratedAdapter> generatedConstructor(Class<?> klass) {
try {
Package aPackage = klass.getPackage();
String name = klass.getCanonicalName();
final String fullPackage = aPackage != null ? aPackage.getName() : "";
final String adapterName = getAdapterName(fullPackage.isEmpty() ? name :
name.substring(fullPackage.length() + 1));
@SuppressWarnings("unchecked") final Class<? extends GeneratedAdapter> aClass =
(Class<? extends GeneratedAdapter>) Class.forName(
fullPackage.isEmpty() ? adapterName : fullPackage + "." + adapterName);
Constructor<? extends GeneratedAdapter> constructor =
aClass.getDeclaredConstructor(klass);
if (!constructor.isAccessible()) {
constructor.setAccessible(true);
}
return constructor;
} catch (ClassNotFoundException e) {
return null;
} catch (NoSuchMethodException e) {
// this should not happen
throw new RuntimeException(e);
}
}
复制代码这个代码看着就很奇怪,我们没有去定义一个 xxx_LifecycleAdapter 的类,这是哪来的?这个比较有意思,它是 apt 在编译的时候自动生成的,我们可以在 build/generated/source/kapt 下面找到。
这里我们看一下定义的 LifecycleObserver 和它的生成类。
// 我们定义的 LifecycleObserver
class LifecycleObserverA
: LifecycleObserver {
@OnLifecycleEvent(Lifecycle.Event.ON_CREATE)
fun onCreate(owner: LifecycleOwner) {
}
}
// apt 的生成类
public class LifecycleObserverA_LifecycleAdapter implements GeneratedAdapter {
final LifecycleObserverA mReceiver;
LifecycleObserverA_LifecycleAdapter(LifecycleObserverA receiver) {
this.mReceiver = receiver;
}
@Override
public void callMethods(LifecycleOwner owner, Lifecycle.Event event, boolean onAny,
MethodCallsLogger logger) {
boolean hasLogger = logger != null;
if (onAny) {
return;
}
if (event == Lifecycle.Event.ON_CREATE) {
if (!hasLogger || logger.approveCall("onCreate", 2)) {
mReceiver.onCreate(owner);
}
return;
}
}
}
复制代码分析完这个过程,我们回到 LifecycleRegistry,
状态同步
当
LifecycleOwner的生命周期状态发生变化的时候,LifecycleRegistry主要是通过sync()方法来给LifecycleObserver进行状态同步的。
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;
// LifecycleOwner 状态 比 LifecycleObserver 对应的状态小,则同步 LifecycleObserver downEvent()
if (mState.compareTo(mObserverMap.eldest().getValue().mState) < 0) {
backwardPass(lifecycleOwner);
}
Entry<LifecycleObserver, ObserverWithState> newest = mObserverMap.newest();
// LifecycleOwner 状态比 LifecycleObserver 对应的状态大,则同步 LifecycleObserver upEvent()
if (!mNewEventOccurred && newest != null
&& mState.compareTo(newest.getValue().mState) > 0) {
forwardPass(lifecycleOwner);
}
}
mNewEventOccurred = false;
}
// 当 LifecycleOwner 里面存在状态与 mState 不一致,或者 LifecycleOwner 之间存在状态不一致的时候,需要进行状态同步
private boolean isSynced() {
if (mObserverMap.size() == 0) {
return true;
}
State eldestObserverState = mObserverMap.eldest().getValue().mState;
State newestObserverState = mObserverMap.newest().getValue().mState;
return eldestObserverState == newestObserverState && mState == newestObserverState;
}
复制代码
isSynced()方法决定了是否需要进行状态同步。然后在 while 循环里面,通过LifecycleOwner和LifecycleObserver状态的比较,决定是应该走backwardPass(),还是forwardPass()。backwardPass()和forwardPass()方法也比较简单,就是遍历所有的LifecycleObserver,然后进行一层层的事件分发,直到LifecycleObserver的状态和LifecycleOwner的状态平齐。
private void forwardPass(LifecycleOwner lifecycleOwner) {
Iterator<Entry<LifecycleObserver, ObserverWithState>> ascendingIterator =
mObserverMap.iteratorWithAdditions();
while (ascendingIterator.hasNext() && !mNewEventOccurred) {
Entry<LifecycleObserver, ObserverWithState> entry = ascendingIterator.next();
ObserverWithState observer = entry.getValue();
while ((observer.mState.compareTo(mState) < 0 && !mNewEventOccurred
&& mObserverMap.contains(entry.getKey()))) {
pushParentState(observer.mState);
// 分发 upEvent()
observer.dispatchEvent(lifecycleOwner, upEvent(observer.mState));
popParentState();
}
}
}
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));
// 分发 downEvent()
observer.dispatchEvent(lifecycleOwner, event);
popParentState();
}
}
}
private static Event downEvent(State state) {
switch (state) {
case INITIALIZED:
throw new IllegalArgumentException();
case CREATED:
return ON_DESTROY;
case STARTED:
return ON_STOP;
case RESUMED:
return ON_PAUSE;
case DESTROYED:
throw new IllegalArgumentException();
}
throw new IllegalArgumentException("Unexpected state value " + state);
}
private static Event upEvent(State state) {
switch (state) {
case INITIALIZED:
case DESTROYED:
return ON_CREATE;
case CREATED:
return ON_START;
case STARTED:
return ON_RESUME;
case RESUMED:
throw new IllegalArgumentException();
}
throw new IllegalArgumentException("Unexpected state value " + state);
}
复制代码
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