android事件分发机制的实现原理

android中的事件处理,以及解决滑动冲突问题都离不开事件分发机制,android中的事件流,即MotionEvent都会经历一个从分发,拦截到处理的一个过程。即dispatchTouchEvent(),onInterceptEvent()到onTouchEvent()的一个过程,在dispatchTouchEvent()负责了事件的分发过程,在dispatchTouchEvent()中会调用onInterceptEvent()与onTouchEvent(),如果onInterceptEvent()返回true,那么会调用到当前view的onTouchEvent()方法,如果不拦截,事件就会下发到子view的dispatchTouchEvent()中进行同样的操作。本文将带领大家从源码角度来分析android是如何进行事件分发的。

android中的事件分发流程最先从activity的dispatchTouchEvent()开始:

public boolean dispatchTouchEvent(MotionEvent ev) {

if (ev.getAction() == MotionEvent.ACTION_DOWN) {

onUserInteraction();

}

if (getWidow().superDispatchTouchEvent(ev)) {

return true;

}

return onTouchEvent(ev);

}

这里调用了getWindow().superDispatchTouchEvent(ev),这里可以看出activity将MotionEvent传寄给了Window。而Window是一个抽象类,superDispatchTouchEvent()也是一个抽象方法,这里用到的是window的子类phoneWindow。

@Override

public boolean superDispatchTouchEvent(MotionEvent event) {

return mDecor.superDispatchTouchEvent(event);

}

从这里可以看出,event事件被传到了DecorView,也就是我们的顶层view.我们继续跟踪:

public boolean superDispatchTouchEvent(MotionEvent event) {

return super.dispatchTouchEvent(event);

}

这里调用到了父类的dispatchTouchEvent()方法,而DecorView是继承自FrameLayout,FrameLayout继承了ViewGroup,所以这里会调用到ViewGroup的dispatchTouchEvent()方法。

所以整个事件流从activity开始,传递到window,最后再到我们的view(viewGroup也是继承自view)中,而view才是我们整个事件处理的核心阶段。

我们来看一下viewGroup的dispatchTouchEvent()中的实现:

if (actionMasked == MotionEvent.ACTION_DOWN) {

// Throw away all previous state when starting a new touch gesture.

// The framework may have dropped the up or cancel event for the previous gesture

// due to an app switch, ANR, or some other state change.

cancelAndClearTouchTargets(ev);

resetTouchState();

}

这是dispatchTouchEvent()开始时截取的一段代码,我们来看一下,首先,当我们手指按下view时,会调用到resetTouchState()方法,在resetTouchState()中:

private void resetTouchState() {

clearTouchTargets();

resetCancelNextUpFlag(this);

mGroupFlags &= ~FLAG_DISALLOW_INTERCEPT;

mNestedScrollAxes = SCROLL_AXIS_NONE;

}

我们继续跟踪clearTouchTargets()方法:

private void clearTouchTargets() {

TouchTarget target = mFirstTouchTarget;

if (target != null) {

do {

TouchTarget next = target.next;

target.recycle();

target = next;

} while (target != null);

mFirstTouchTarget = null;

}

}

在clearTouchTargets()方法中,我们最终将mFirstTouchTarget赋值为null,我们继续回到dispatchTouchEvent()中,接着执行了下段代码:

// Check for interception.

final boolean intercepted;

if (actionMasked == MotionEvent.ACTION_DOWN

|| mFirstTouchTarget != null) {

final boolean disallowIntercept = (mGroupFlags & FLAG_DISALLOW_INTERCEPT) != 0;

if (!disallowIntercept) {

intercepted = onInterceptTouchEvent(ev);

ev.setAction(action); // restore action in case it was changed

} else {

intercepted = false;

}

} else {

// There are no touch targets and this action is not an initial down

// so this view group continues to intercept touches.

intercepted = true;

}

当view被按下或mFirstTouchTarget != null 的时候,从前面可以知道,当每次view被按下时,也就是重新开始一次事件流的处理时,mFirstTouchTarget都会被设置成null,一会我们看mFirstTouchTarget是什么时候被赋值的。

从disallowIntercept属性我们大概能猜到是用来判断是否需要坐拦截处理,而我们知道可以通过调用父view的requestDisallowInterceptTouchEvent(true)可以让我们的父view不能对事件进行拦截,我们先来看看requestDisallowInterceptTouchEvent()方法中的实现:

@Override

public void requestDisallowInterceptTouchEvent(boolean disallowIntercept) {

if (disallowIntercept == ((mGroupFlags & FLAG_DISALLOW_INTERCEPT) != 0)) {

// We're already in this state, assume our ancestors are too

return;

}

if (disallowIntercept) {

mGroupFlags |= FLAG_DISALLOW_INTERCEPT;

} else {

mGroupFlags &= ~FLAG_DISALLOW_INTERCEPT;

}

// Pass it up to our parent

if (mParent != null) {

mParent.requestDisallowInterceptTouchEvent(disallowIntercept);

}

}

这里也是通过设置标志位做判断处理,所以这里是通过改变mGroupFlags标志,然后在dispatchTouchEvent()刚发中变更disallowIntercept的值判断是否拦截,当为true时,即需要拦截,这个时候便会跳过onInterceptTouchEvent()拦截判断,并标记为不拦截,即intercepted = false,我们继续看viewGroup的onInterceptTouchEvent()处理:

public boolean onInterceptTouchEvent(MotionEvent ev) {

if (ev.isFromSource(InputDevice.SOURCE_MOUSE)

&& ev.getAction() == MotionEvent.ACTION_DOWN

&& ev.isButtonPressed(MotionEvent.BUTTON_PRIMARY)

&& isOnScrollbarThumb(ev.getX(), ev.getY())) {

return true;

}

return false;

}

即默认情况下,只有在ACTION_DOWN时,viewGroup才会表现为拦截。

我们继续往下看:

final int childrenCount = mChildrenCount;

if (newTouchTarget == null && childrenCount != 0) {

final float x = ev.getX(actionIndex);

final float y = ev.getY(actionIndex);

// Find a child that can receive the event.

// Scan children from front to back.

final ArrayList<View> preorderedList = buildTouchDispatchChildList();

final boolean customOrder = preorderedList == null

&& isChildrenDrawingOrderEnabled();

final View[] children = mChildren;

for (int i = childrenCount - 1; i >= 0; i--) {

final int childIndex = getAndVerifyPreorderedIndex(

childrenCount, i, customOrder);

final View child = getAndVerifyPreorderedView(

preorderedList, children, childIndex);

// If there is a view that has accessibility focus we want it

// to get the event first and if not handled we will perform a

// normal dispatch. We may do a double iteration but this is

// safer given the timeframe.

if (childWithAccessibilityFocus != null) {

if (childWithAccessibilityFocus != child) {

continue;

}

childWithAccessibilityFocus = null;

i = childrenCount - 1;

}

if (!canViewReceivePointerEvents(child)

|| !isTransformedTouchPointInView(x, y, child, null)) {

ev.setTargetAccessibilityFocus(false);

continue;

}

newTouchTarget = getTouchTarget(child);

if (newTouchTarget != null) {

// Child is already receiving touch within its bounds.

// Give it the new pointer in addition to the ones it is handling.

newTouchTarget.pointerIdBits |= idBitsToAssign;

break;

}

resetCancelNextUpFlag(child);

if (dispatchTransformedTouchEvent(ev, false, child, idBitsToAssign)) {

// Child wants to receive touch within its bounds.

mLastTouchDownTime = ev.getDownTime();

if (preorderedList != null) {

// childIndex points into presorted list, find original index

for (int j = 0; j < childrenCount; j++) {

if (children[childIndex] == mChildren[j]) {

mLastTouchDownIndex = j;

break;

}

}

} else {

mLastTouchDownIndex = childIndex;

}

mLastTouchDownX = ev.getX();

mLastTouchDownY = ev.getY();

newTouchTarget = addTouchTarget(child, idBitsToAssign);

alreadyDispatchedToNewTouchTarget = true;

break;

}

// The accessibility focus didn't handle the event, so clear

// the flag and do a normal dispatch to all children.

ev.setTargetAccessibilityFocus(false);

}

if (preorderedList != null) preorderedList.clear();

}

这段代码首先会通过一个循环去遍历所有的子view,最终会调用到dispatchTransformedTouchEvent()方法,我们继续看dispatchTransformedTouchEvent()的实现:

private boolean dispatchTransformedTouchEvent(MotionEvent event, boolean cancel,

View child, int desiredPointerIdBits) {

final boolean handled;

// Canceling motions is a special case. We don't need to perform any transformations

// or filtering. The important part is the action, not the contents.

final int oldAction = event.getAction();

if (cancel || oldAction == MotionEvent.ACTION_CANCEL) {

event.setAction(MotionEvent.ACTION_CANCEL);

if (child == null) {

handled = super.dispatchTouchEvent(event);

} else {

handled = child.dispatchTouchEvent(event);

}

event.setAction(oldAction);

return handled;

}

// Calculate the number of pointers to deliver.

final int oldPointerIdBits = event.getPointerIdBits();

final int newPointerIdBits = oldPointerIdBits & desiredPointerIdBits;

// If for some reason we ended up in an inconsistent state where it looks like we

// might produce a motion event with no pointers in it, then drop the event.

if (newPointerIdBits == 0) {

return false;

}

// If the number of pointers is the same and we don't need to perform any fancy

// irreversible transformations, then we can reuse the motion event for this

// dispatch as long as we are careful to revert any changes we make.

// Otherwise we need to make a copy.

final MotionEvent transformedEvent;

if (newPointerIdBits == oldPointerIdBits) {

if (child == null || child.hasIdentityMatrix()) {

if (child == null) {

handled = super.dispatchTouchEvent(event);

} else {

final float offsetX = mScrollX - child.mLeft;

final float offsetY = mScrollY - child.mTop;

event.offsetLocation(offsetX, offsetY);

handled = child.dispatchTouchEvent(event);

event.offsetLocation(-offsetX, -offsetY);

}

return handled;

}

transformedEvent = MotionEvent.obtain(event);

} else {

transformedEvent = event.split(newPointerIdBits);

}

// Perform any necessary transformations and dispatch.

if (child == null) {

handled = super.dispatchTouchEvent(transformedEvent);

} else {

final float offsetX = mScrollX - child.mLeft;

final float offsetY = mScrollY - child.mTop;

transformedEvent.offsetLocation(offsetX, offsetY);

if (! child.hasIdentityMatrix()) {

transformedEvent.transform(child.getInverseMatrix());

}

handled = child.dispatchTouchEvent(transformedEvent);

}

// Done.

transformedEvent.recycle();

return handled;

}

这段代码就比较明显了,如果child不为null,始终会调用到child.dispatchTouchEvent();否则调用super.dispatchTouchEvent();

如果child不为null时,事件就会向下传递,如果子view处理了事件,即dispatchTransformedTouchEvent()即返回true。继续向下执行到addTouchTarget()方法,我们继续看addTouchTarget()方法的执行结果:

private TouchTarget addTouchTarget(@NonNull View child, int pointerIdBits) {

final TouchTarget target = TouchTarget.obtain(child, pointerIdBits);

target.next = mFirstTouchTarget;

mFirstTouchTarget = target;

return target;

}

这个时候我们发现mFirstTouchTarget又出现了,这时候会给mFirstTouchTarget重新赋值,即mFirstTouchTarget不为null。也就是说,如果事件被当前view或子view消费了,那么在接下来的ACTION_MOVE或ACTION_UP事件中,mFirstTouchTarget就不为null。但如果我们继承了该viewGroup,并在onInterceptTouchEvent()的ACTION_MOVE中拦截了事件,那么后续事件将不会下发,将由该viewGroup直接处理,从下面代码我们可以得到:

// Dispatch to touch targets, excluding the new touch target if we already

// dispatched to it. Cancel touch targets if necessary.

TouchTarget predecessor = null;

TouchTarget target = mFirstTouchTarget;

while (target != null) {

final TouchTarget next = target.next;

if (alreadyDispatchedToNewTouchTarget && target == newTouchTarget) {

handled = true;

} else {

final boolean cancelChild = resetCancelNextUpFlag(target.child)

|| intercepted;

if (dispatchTransformedTouchEvent(ev, cancelChild,

target.child, target.pointerIdBits)) {

handled = true;

}

if (cancelChild) {

if (predecessor == null) {

mFirstTouchTarget = next;

} else {

predecessor.next = next;

}

target.recycle();

target = next;

continue;

}

}

predecessor = target;

target = next;

}

当存在子view并且事件被子view消费时,即在ACTION_DOWN阶段mFirstTouchTarget会被赋值,即在接下来的ACTION_MOVE事件中,由于intercepted为true,所以将ACTION_CANCEL 事件传递过去,从dispatchTransformedTouchEvent()中可以看到:

if (cancel || oldAction == MotionEvent.ACTION_CANCEL) {

event.setAction(MotionEvent.ACTION_CANCEL);

if (child == null) {

handled = super.dispatchTouchEvent(event);

} else {

handled = child.dispatchTouchEvent(event);

}

event.setAction(oldAction);

return handled;

}

并将mFirstTouchTarget 最终赋值为 next,而此时mFirstTouchTarget位于TouchTarget链表尾部,所以mFirstTouchTarget会赋值为null,那么接下来的事件将不会进入到onInterceptTouchEvent()中。也就会直接交由该view处理。

如果我们没有进行事件的拦截,而是交由子view去处理,由于ViewGroup的onInterceptTouchEvent()默认并不会拦截除了ACTION_DOWN以外的事件,所以后续事件将继续交由子view去处理,如果存在子view且事件位于子view内部区域的话。

所以无论是否进行拦截,事件流都会交由view的dispatchTouchEvent()中进行处理,我们接下来跟踪一下view中的dispatchTouchEvent()处理过程:

if (actionMasked == MotionEvent.ACTION_DOWN) {

// Defensive cleanup for new gesture

stopNestedScroll();

}

if (onFilterTouchEventForSecurity(event)) {

if ((mViewFlags & ENABLED_MASK) == ENABLED && handleScrollBarDragging(event)) {

result = true;

}

//noinspection SimplifiableIfStatement

ListenerInfo li = mListenerInfo;

if (li != null && li.mOnTouchListener != null

&& (mViewFlags & ENABLED_MASK) == ENABLED

&& li.mOnTouchListener.onTouch(this, event)) {

result = true;

}

if (!result && onTouchEvent(event)) {

result = true;

}

}

当被按下时,即ACTION_DOWN时,view会停止内部的滚动,如果view没有被覆盖或遮挡时,首先会进行mListenerInfo是否为空的判断,我们看下mListenerInfo是在哪里初始化的:

ListenerInfo getListenerInfo() {

if (mListenerInfo != null) {

return mListenerInfo;

}

mListenerInfo = new ListenerInfo();

return mListenerInfo;

}

这里可以看出,mListenerInfo一般不会是null,知道在我们使用它时调用过这段代码,而当view被加入window中的时候,会调用下面这段代码,从注释中也可以看出来:

/**

* Add a listener for attach state changes.

*

* This listener will be called whenever this view is attached or detached

* from a window. Remove the listener using

* {@link #removeOnAttachStateChangeListener(OnAttachStateChangeListener)}.

*

* @param listener Listener to attach

* @see #removeOnAttachStateChangeListener(OnAttachStateChangeListener)

*/

public void addOnAttachStateChangeListener(OnAttachStateChangeListener listener) {

ListenerInfo li = getListenerInfo();

if (li.mOnAttachStateChangeListeners == null) {

li.mOnAttachStateChangeListeners

= new CopyOnWriteArrayList<OnAttachStateChangeListener>();

}

li.mOnAttachStateChangeListeners.add(listener);

}

到这里我们就知道,mListenerInfo一开始就是被初始化好了的,所以li不可能为null,li.mOnTouchListener != null即当设置了TouchListener时不为null,并且view是enabled状态,一般情况view都是enable的。这个时候会调用到onTouch()事件,当onTouch()返回true时,这个时候result会赋值true。而当result为true时,onTouchEvent()将不会被调用。

从这里可以看出,onTouch()会优先onTouchEvent()调用;

当view设置touch监听并返回true时,那么它的onTouchEvent()将被屏蔽。否则会调用onTouchEvent()处理。

那么让我们继续来看看onTouchEvent()中的事件处理:

if ((viewFlags & ENABLED_MASK) == DISABLED) {

if (action == MotionEvent.ACTION_UP && (mPrivateFlags & PFLAG_PRESSED) != 0) {

setPressed(false);

}

// A disabled view that is clickable still consumes the touch

// events, it just doesn't respond to them.

return (((viewFlags & CLICKABLE) == CLICKABLE

|| (viewFlags & LONG_CLICKABLE) == LONG_CLICKABLE)

|| (viewFlags & CONTEXT_CLICKABLE) == CONTEXT_CLICKABLE);

}

首先,当view状态是DISABLED时,只要view是CLICKABLE或LONG_CLICKABLE或CONTEXT_CLICKABLE,都会返回true,而button默认是CLICKABLE的,textview默认不是CLICKABLE的,而view一般默认都不是LONG_CLICKABLE的。

我们继续向下看:

if (mTouchDelegate != null) {

if (mTouchDelegate.onTouchEvent(event)) {

return true;

}

}

如果有代理事件,仍然会返回true.

if (((viewFlags & CLICKABLE) == CLICKABLE ||

(viewFlags & LONG_CLICKABLE) == LONG_CLICKABLE) ||

(viewFlags & CONTEXT_CLICKABLE) == CONTEXT_CLICKABLE) {

switch (action) {

case MotionEvent.ACTION_UP:

boolean prepressed = (mPrivateFlags & PFLAG_PREPRESSED) != 0;

if ((mPrivateFlags & PFLAG_PRESSED) != 0 || prepressed) {

// take focus if we don't have it already and we should in

// touch mode.

boolean focusTaken = false;

if (isFocusable() && isFocusableInTouchMode() && !isFocused()) {

focusTaken = requestFocus();

}

if (prepressed) {

// The button is being released before we actually

// showed it as pressed. Make it show the pressed

// state now (before scheduling the click) to ensure

// the user sees it.

setPressed(true, x, y);

}

if (!mHasPerformedLongPress && !mIgnoreNextUpEvent) {

// This is a tap, so remove the longpress check

removeLongPressCallback();

// Only perform take click actions if we were in the pressed state

if (!focusTaken) {

// Use a Runnable and post this rather than calling

// performClick directly. This lets other visual state

// of the view update before click actions start.

if (mPerformClick == null) {

mPerformClick = new PerformClick();

}

if (!post(mPerformClick)) {

performClick();

}

}

}

if (mUnsetPressedState == null) {

mUnsetPressedState = new UnsetPressedState();

}

if (prepressed) {

postDelayed(mUnsetPressedState,

ViewConfiguration.getPressedStateDuration());

} else if (!post(mUnsetPressedState)) {

// If the post failed, unpress right now

mUnsetPressedState.run();

}

removeTapCallback();

}

mIgnoreNextUpEvent = false;

break;

case MotionEvent.ACTION_DOWN:

mHasPerformedLongPress = false;

if (performButtonActionOnTouchDown(event)) {

break;

}

// Walk up the hierarchy to determine if we're inside a scrolling container.

boolean isInScrollingContainer = isInScrollingContainer();

// For views inside a scrolling container, delay the pressed feedback for

// a short period in case this is a scroll.

if (isInScrollingContainer) {

mPrivateFlags |= PFLAG_PREPRESSED;

if (mPendingCheckForTap == null) {

mPendingCheckForTap = new CheckForTap();

}

mPendingCheckForTap.x = event.getX();

mPendingCheckForTap.y = event.getY();

postDelayed(mPendingCheckForTap, ViewConfiguration.getTapTimeout());

} else {

// Not inside a scrolling container, so show the feedback right away

setPressed(true, x, y);

checkForLongClick(0, x, y);

}

break;

case MotionEvent.ACTION_CANCEL:

setPressed(false);

removeTapCallback();

removeLongPressCallback();

mInContextButtonPress = false;

mHasPerformedLongPress = false;

mIgnoreNextUpEvent = false;

break;

case MotionEvent.ACTION_MOVE:

drawableHotspotChanged(x, y);

// Be lenient about moving outside of buttons

if (!pointInView(x, y, mTouchSlop)) {

// Outside button

removeTapCallback();

if ((mPrivateFlags & PFLAG_PRESSED) != 0) {

// Remove any future long press/tap checks

removeLongPressCallback();

setPressed(false);

}

}

break;

}

return true;

}

当view是CLICKABLE或LONG_CLICKABLE或CONTEXT_CLICKABLE状态时,当手指抬起时,如果设置了click监听,最终会调用到performClick(),触发click()事件。这点从performClick()方法中可以看出:

public boolean performClick() {

final boolean result;

final ListenerInfo li = mListenerInfo;

if (li != null && li.mOnClickListener != null) {

playSoundEffect(SoundEffectConstants.CLICK);

li.mOnClickListener.onClick(this);

result = true;

} else {

result = false;

}

sendAccessibilityEvent(AccessibilityEvent.TYPE_VIEW_CLICKED);

return result;

}

从这里我们也可以得出,click事件会在onTouchEvent()中被调用,如果view设置了onTouch()监听并返回true,那么click事件也会被屏蔽掉,不过我们可以在onTouch()中通过调用view的performClick()继续执行click()事件,这个就看我们的业务中的需求了。

从这里我们可以看出,如果事件没有被当前view或子view处理,即返回false,那么事件就会交由外层view继续处理,直到被消费。

如果事件一直没有被处理,会最终传递到Activity的onTouchEvent()中。

到这里我们总结一下:

事件是从Activity->Window->View(ViewGroup)的一个传递流程;

如果事件没有被中途拦截,那么它会一直传到最内层的view控件;

如果事件被某一层拦截,那么事件将不会向下传递,交由该view处理。如果该view消费了事件,那么接下来的事件也会交由该view处理;如果该view没有消费该事件,那么事件会交由外层view处理,...并最终调用到activity的onTouchEvent()中,除非某一层消费了该事件;

一个事件只能交由一个view处理;

DispatchTouchEvent()总是会被调用,而且最先被调用,onInterceptTouchEvent()和onTouchEvent()在DispatchTouchEvent()内部调用;

子view不能干扰ViewGroup对ACTION_DOWN事件的处理;

子view可以通过requestDisallowInterceptTouchEvent(true)控制父view不对事件进行拦截,跳过onInterceptTouchEvent()方法的执行。

以上是 android事件分发机制的实现原理 的全部内容, 来源链接: utcz.com/z/319511.html

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