Android事件分发机制
一. Android分发机制概述:
Android如此受欢迎,就在于其优秀的交互性,这其中,Android优秀的事件分发机制功不可没。那么,作为一个优秀的程序员,要想做一个具有良好交互性的应用,必须透彻理解Android的事件分发机制。
要想充分理解android的分发机制,需要先对以下几个知识点有所了解:
① View和ViewGroup什么?
② 事件
③ View 事件的分发机制
④ ViewGroup事件的分发机制
下面,就让我们沿着大致方针,开始事件分发的探究之旅吧……
二、View和ViewGroup:
Android的UI界面都是由View和ViewGroup及其派生类组合而成的。其中,View是所有UI组件的基类,而ViewGroup是容纳这些组件的容器,其本身也是从View派生出来的,也就是说ViewGroup的父类就是View。
通常来说,Button、ImageView、TextView等控件都是继承父类View来实现的。RelativeLayout、LinearLayout、FrameLayout等布局都是继承父类ViewGroup来实现的。
事件:
当手指触摸到View或ViewGroup派生的控件后,将会触发一系列的触发响应事件,如:
onTouchEvent、onClick、onLongClick等。每个View都有自己处理事件的回调方法,开发人员只需要重写这些回调方法,就可以实现需要的响应事件。
而事件通常重要的有如下三种:
MotionEvent.ACTION_DOWN 按下View,是所有事件的开始
MotionEvent.ACTION_MOVE 滑动事件
MotionEvent.ACTION_UP 与down对应,表示抬起
事件的响应原理:
在android开发设计模式中,最广泛应用的就是监听、回调,进而形成了事件响应的过程。
以Button的OnClick为例,因为Button也是一个View,所以它也拥有View父类的方法,在View中源码如下:
/**定义接口成员变量*/protected OnClickListener mOnClickListener; /** * Interface definition for a callback to be invoked when a view is clicked. */ public interface OnClickListener { /** * Called when a view has been clicked. * * @param v The view that was clicked. */ void onClick(View v); }/** * Register a callback to be invoked when this view is clicked. If this view is not * clickable, it becomes clickable. * * @param l The callback that will run * * @see #setClickable(boolean) */ public void setOnClickListener(OnClickListener l) { if (!isClickable()) { setClickable(true); } mOnClickListener = l;} /** * Call this view's OnClickListener, if it is defined. * * @return True there was an assigned OnClickListener that was called, false * otherwise is returned. */ public boolean performClick() { sendAccessibilityEvent(AccessibilityEvent.TYPE_VIEW_CLICKED); if (mOnClickListener != null) { playSoundEffect(SoundEffectConstants.CLICK); mOnClickListener.onClick(this); return true; } return false;}/**触摸了屏幕后,实现并调用的方法*/public boolean onTouchEvent(MotionEvent event) { ….. if (mPerformClick == null) { mPerformClick = new PerformClick(); } if (!post(mPerformClick)) { performClick(); } …..}以上是View源码中关键代码行,以Button为例,假设需要在一个布局上添加一个按钮,并实现它的OnClick事件,需要如下步骤:
1、 OnClickListener类是一个当控件被点击后进行回调的一个接口,它完成被点击后的回调通知。2、 创建一个按钮Button,并设置监听事件,对这个Button进行setOnClickListener操作3、 当手指触摸到Button按钮,通过一系列方法(之后将会详细讲解,这里暂时忽略),触发并执行到onTouchEvent方法并执行mPerformClick方法,在mPerformClick方法中,首先会判断注册的mOnClickListener是否为空,若不为空,它就会回调之前注册的onClick方法,进而执行用户自定义代码。事件响应机制,简单来说上面的例子就已经基本上诠释了注册一个监听对象
实现监听对象的监听事件
当某一触发事件到来,在触发事件中通过注册过的监听对象,回调注册对象的响应事件,来完成用户自定义实现。
但凡明白了这一个简单的事件响应的过程,就离事件驱动开发整个过程就不远了,大道至简,请完全理解了这个例子,再继续之后的学习,事半功倍。
三、View事件的分发机制:
通过上面的例子,我们初步的接触了View的事件分发机制,再进一步了解。首先,我们要熟悉dispatchTouchEvent和onTouchEvent两个函数,这两个函数都是View的函数,要理解View事件的分发机制,只要清楚这两个函数就基本上清楚了。
在这里先提醒一句,这里的“分发”是指一个触摸或点击的事件发生,分发给当前触摸控件所监听的事件(如OnClick、onTouch等),进而来决定是控件的哪个函数来响应此次事件。
dispatchTouchEvent:
此函数负责事件的分发,你只需要记住当触摸一个View控件,首先会调用这个函数就行,在这个函数体里决定将事件分发给谁来处理。
onTouchEvent:
此函数负责执行事件的处理,负责处理事件,主要处理MotionEvent.ACTION_DOWN、
MotionEvent.ACTION_MOVE 、
MotionEvent.ACTION_UP这三个事件。
public boolean onTouchEvent (MotionEvent event)
参数event为手机屏幕触摸事件封装类的对象,其中封装了该事件的所有信息,例如触摸的位置、触摸的类型以及触摸的时间等。该对象会在用户触摸手机屏幕时被创建。
那么它是如何执行这个流程的呢?我们还以布局上的按钮为例,看看它是如何实现的。(看图①)
image.png
我们知道,View做为所有控件的父类,它本身定义了很多接口来监听触摸在View上的事件,如OnClickListener(点击)、OnLongClickListener(长按)、OnTouchListener(触摸监听)等,那么当手指触摸到View时候,该响应“点击”还是”触摸”呢,就是根据dispatchTouchEvent和onTouchEvent这两个函数组合实现的,我们之下的讨论,仅对常用的“点击OnClick”和“触摸onTouch”来讨论,顺藤摸瓜,找出主线,进而搞清楚View的事件分发机制。
对于上面的按钮,点击它一下,我们期望2种结果,第一种:它响应一个点击事件。第二种:不响应点击事件。
第一种源码:
public class MainActivity extends Activity implements OnClickListener ,OnTouchListener{ private Button btnButton; @Override protected void onCreate(Bundle savedInstanceState) { super.onCreate(savedInstanceState); setContentView(R.layout.activity_main); btnButton=(Button) findViewById(R.id.btn); btnButton.setOnClickListener(this); btnButton.setOnTouchListener(this); } @Override public void onClick(View v) { // TODO Auto-generated method stub switch (v.getId()) { case R.id.btn: Log.e("View", "onClick===========>"); break; default: break; } } @Override public boolean onTouch(View v, MotionEvent event) { // TODO Auto-generated method stub Log.e("View", "onTouch.................................."); return false; } }第二种源码:
public class MainActivity extends Activity implements OnClickListener ,OnTouchListener{ private Button btnButton; @Override protected void onCreate(Bundle savedInstanceState) { super.onCreate(savedInstanceState); setContentView(R.layout.activity_main); btnButton=(Button) findViewById(R.id.btn); btnButton.setOnClickListener(this); btnButton.setOnTouchListener(this); } @Override public void onClick(View v) { // TODO Auto-generated method stub switch (v.getId()) { case R.id.btn: Log.e("View", "onClick===========>"); break; default: break; } } @Override public boolean onTouch(View v, MotionEvent event) { // TODO Auto-generated method stub Log.e("View", "onTouch.................................."); return true; } }结果分析:
上面两处代码,第一种执行了OnClick函数和OnTouch函数,第二种执行了OnTouch函数,并没有执行OnClick函数,而且对两处代码进行比较,发现只有在onTouch处返回值true和false不同。当onTouch返回false,onClick被执行了,返回true,onClick未被执行。
为什么会这样呢?我们只有深入源码才能分析出来。
前面提到,触摸一个View就会执行dispatchTouchEvent方法去“分发”事件, 既然触摸的是按钮Button,那么我们就查看Button的源码,寻找dispatchTouchEvent方法,Button源码中没有dispatchTouchEvent方法,但知道Button继承自TextView,寻找TextView,发现它也没有dispatchTouchEvent方法,继续查找TextView的父类View,发现View有dispatchTouchEvent方法,那我们就分析dispatchTouchEvent方法。
主要代码如下:
public boolean dispatchTouchEvent(MotionEvent event) { if (onFilterTouchEventForSecurity(event)) { //noinspection SimplifiableIfStatement if (mOnTouchListener != null && (mViewFlags & ENABLED_MASK) == ENABLED && mOnTouchListener.onTouch(this, event)) { return true; } if (onTouchEvent(event)) { return true; } } return false; }分析:
先来看dispatchTouchEvent函数返回值,如果返回true,表明事件被处理了,反之,表明事件未被处理。
if (onFilterTouchEventForSecurity(event))这个是事件安全过滤,与主题无关,继续看。
if (mOnTouchListener != null && (mViewFlags & ENABLED_MASK) == ENABLED && mOnTouchListener.onTouch(this, event)) { return true; }这个判定很重要,mOnTouchListener != null,判断该控件是否注册了OnTouchListener对象的监听,(mViewFlags & ENABLED_MASK) == ENABLED,判断当前的控件是否能被点击(比如Button默认可以点击,ImageView默认不许点击,看到这里就了然了),mOnTouchListener.onTouch(this, event)这个是关键,这个调用,就是回调你注册在这个View上的mOnTouchListener对象的onTouch方法,如果你在onTouch方法里返回false,那么这个判断语句就跳出,去执行下面的程序,否则,当前2个都返回了true,自定义onTouch方法也返回true,条件成立,就直接返回了,不再执行下面的程序。接下来,if (onTouchEvent(event)) 这个判断很重要,能否回调OnClickListener接口的onClick函数,关键在于此,可以肯定的是,如果上面
if (mOnTouchListener != null && (mViewFlags & ENABLED_MASK) == ENABLED &&
mOnTouchListener.onTouch(this, event))返回true,那么就不会执行并回调OnClickListener接口的onClick函数。
接下来,我们看onTouchEvent这个函数,看它是如何响应点击事件的。
主要代码如下:
public boolean onTouchEvent(MotionEvent event) { final int viewFlags = mViewFlags; if ((viewFlags & ENABLED_MASK) == DISABLED) { if (event.getAction() == MotionEvent.ACTION_UP && (mPrivateFlags & PRESSED) != 0) { mPrivateFlags &= ~PRESSED; refreshDrawableState(); } // 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)); } if (mTouchDelegate != null) { if (mTouchDelegate.onTouchEvent(event)) { return true; } } if (((viewFlags & CLICKABLE) == CLICKABLE || (viewFlags & LONG_CLICKABLE) == LONG_CLICKABLE)) { switch (event.getAction()) { case MotionEvent.ACTION_UP: boolean prepressed = (mPrivateFlags & PREPRESSED) != 0; if ((mPrivateFlags & 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. mPrivateFlags |= PRESSED; refreshDrawableState(); } if (!mHasPerformedLongPress) { // 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(); } 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 |= PREPRESSED; if (mPendingCheckForTap == null) { mPendingCheckForTap = new CheckForTap(); } postDelayed(mPendingCheckForTap, ViewConfiguration.getTapTimeout()); } else { // Not inside a scrolling container, so show the feedback right away mPrivateFlags |= PRESSED; refreshDrawableState(); checkForLongClick(0); } break; case MotionEvent.ACTION_CANCEL: mPrivateFlags &= ~PRESSED; refreshDrawableState(); removeTapCallback(); break; case MotionEvent.ACTION_MOVE: final int x = (int) event.getX(); final int y = (int) event.getY(); // Be lenient about moving outside of buttons if (!pointInView(x, y, mTouchSlop)) { // Outside button removeTapCallback(); if ((mPrivateFlags & PRESSED) != 0) { // Remove any future long press/tap checks removeLongPressCallback(); // Need to switch from pressed to not pressed mPrivateFlags &= ~PRESSED; refreshDrawableState(); } } break; } return true; } return false; } public boolean performClick() { sendAccessibilityEvent(AccessibilityEvent.TYPE_VIEW_CLICKED); if (mOnClickListener != null) { playSoundEffect(SoundEffectConstants.CLICK); mOnClickListener.onClick(this); return true; } return false; }代码量太大了,不过不要紧,我们通过主要代码分析一下。
public boolean onTouchEvent(MotionEvent event) { //控件不能被点击 if ((viewFlags & ENABLED_MASK) == DISABLED) { … } //委托代理别的View去实现 if (mTouchDelegate != null) { if (mTouchDelegate.onTouchEvent(event)) { return true; } } //控件能够点击或者长按 if (((viewFlags & CLICKABLE) == CLICKABLE || (viewFlags & LONG_CLICKABLE) == LONG_CLICKABLE)) { switch (event.getAction()) { //抬起事件 case MotionEvent.ACTION_UP: …... 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)) { //这里就是去执行回调注册的onClick函数,实现点击 performClick(); } } …… break; //按下事件 case MotionEvent.ACTION_DOWN: …… break; …… //移动事件 case MotionEvent.ACTION_MOVE: …… break; } return true; } return false; }从上面主要代码可以看出onTouchEvent传参MotionEvent类型,它封装了触摸的活动事件,其中就有MotionEvent.ACTION_DOWN、MotionEvent.ACTION_MOVE、MotionEvent.ACTION_UP三个事件。我们在来看看onTouchEvent的返回值,因为onTouchEvent是在dispatchTouchEvent事件分发处理中调用的,
public boolean dispatchTouchEvent(MotionEvent event) { …… if (onTouchEvent(event)) { return true; } return fasle; }如果onTouchEvent返回true,dispatchTouchEvent就返回true,表明事件被处理了,反之,事件未被处理。 程序的关键在 if (((viewFlags & CLICKABLE) == CLICKABLE || (viewFlags & LONG_CLICKABLE) == LONG_CLICKABLE))的判断里,我们发现无论switch的分支在什么地方跳出,返回都是true。这就表明,无论是三个事件中的哪一个,都会返回true。参照下图,结合上述,不难理解View的分发机制了。(图④)
image.png
四、ViewGroup事件分发机制:
ViewGroup事件分发机制较View的稍微复杂一些,不过对View的机制只要精确的理解后,仔细看过这一节,睡几觉起来,估计也就悟出来了,学习就是这么奇怪,当下理解不了或模糊的地方,只要脑子有印象,忽然一夜好像就懂了。
先来看下面的一个简单布局,我们将通过例子,了解ViewGroup+View的android事件处理机制。
image.png
上图由:黑色为线性布局LinearLayout,紫色为相对布局RelativeLayout,按钮Button三部分组成。RelativeLayout为LinearLayout的子布局,Button为RelativeLayout的子布局。以下RelativeLayout简称(R),LinearLayout简称(L),Button简称(B)。经过前面讲解,我们首先知道这样两件事情。1、(R)和(L)的父类是ViewGroup,(B)的父类是View。2、dispatchTouchEvent这个函数很重要,不论是ViewGroup还是View,都由它来处理事件的消费和传递。下面,我们通过横向和纵向两个维度,通过源码和图解的方式,充分理解事件的传递机制。先来看整体的事件传递过程:当手指点击按钮B时,事件传递的顺序是从底向上传递的,也就是按照L->R->B的顺序由下往上逐层传递,响应正好相反,是自上而下。
L首先接收到点击事件,L的父类是ViewGroup类,并将事件传递给dispatchTouchEvent方法,dispatchTouchEvent函数中判断该控件L是否重载了onInterceptTouchEvent方法进行事件拦截,onInterceptTouchEvent默认返回false不拦截,那么dispatchTouchEvent方法将事件传递给R去处理(进入第2流程处理),如果返回true表示当前L控件拦截了事件向其它控件的传递,交给它自己父类View的dispatchTouchEvent去处理,在父方法的dispatchTouchEvent中,将会按照前面讲的View的事件处理机制去判断,比如判断L是否重载了onTouch方法,是否可点击,是否做了监听等事件。
R也是ViewGroup的子类,因此与第1流程基本相似,如果onInterceptTouchEvent返回了false,表示事件将不拦截继续传递给B。
B是View的子类,它没有onInterceptTouchEvent方法,直接交给自己父类View的dispatchTouchEvent去处理,流程同不再敷述。
总结:
onInterceptTouchEvent只有ViewGroup才有,当一个控件是继承自ViewGroup而来的,那么它就可能会有子控件,因此,才有可能传递给子控件,而继承自View的控件,不会有子控件,也就没有onInterceptTouchEvent函数了。
通过dispatchTouchEvent分发的控件返回值True和false,表示当前控件是否消费了传递过来的事件,如果消费了,返回True,反之false。消费了,就不再继续传递了,没有消费,如果有子控件将继续传递。
啰嗦点,如果想再深层次了解一下,再次从源码ViewGroup来分析一个L控件的事件传递过程,请看下图:
image.png
结合上面的图例,下面列出ViewGroup源码来分析一下,我们只需要分析ViewGroup的dispatchTouchEvent、onInterceptTouchEvent、dispatchTransformedTouchEvent三个方法即可。 public boolean dispatchTouchEvent(MotionEvent ev) { if (mInputEventConsistencyVerifier != null) { mInputEventConsistencyVerifier.onTouchEvent(ev, 1); } boolean handled = false; if (onFilterTouchEventForSecurity(ev)) { final int action = ev.getAction(); final int actionMasked = action & MotionEvent.ACTION_MASK; // Handle an initial down. 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(); } // 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; } // Check for cancelation. final boolean canceled = resetCancelNextUpFlag(this) || actionMasked == MotionEvent.ACTION_CANCEL; // Update list of touch targets for pointer down, if needed. final boolean split = (mGroupFlags & FLAG_SPLIT_MOTION_EVENTS) != 0; TouchTarget newTouchTarget = null; boolean alreadyDispatchedToNewTouchTarget = false; if (!canceled && !intercepted) { if (actionMasked == MotionEvent.ACTION_DOWN || (split && actionMasked == MotionEvent.ACTION_POINTER_DOWN) || actionMasked == MotionEvent.ACTION_HOVER_MOVE) { final int actionIndex = ev.getActionIndex(); // always 0 for down final int idBitsToAssign = split ? 1 << ev.getPointerId(actionIndex) : TouchTarget.ALL_POINTER_IDS; // Clean up earlier touch targets for this pointer id in case they // have become out of sync. removePointersFromTouchTargets(idBitsToAssign); final int childrenCount = mChildrenCount; if (childrenCount != 0) { // Find a child that can receive the event. // Scan children from front to back. final View[] children = mChildren; final float x = ev.getX(actionIndex); final float y = ev.getY(actionIndex); for (int i = childrenCount - 1; i >= 0; i--) { final View child = children[i]; if (!canViewReceivePointerEvents(child) || !isTransformedTouchPointInView(x, y, child, null)) { 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(); mLastTouchDownIndex = i; mLastTouchDownX = ev.getX(); mLastTouchDownY = ev.getY(); newTouchTarget = addTouchTarget(child, idBitsToAssign); alreadyDispatchedToNewTouchTarget = true; break; } } } if (newTouchTarget == null && mFirstTouchTarget != null) { // Did not find a child to receive the event. // Assign the pointer to the least recently added target. newTouchTarget = mFirstTouchTarget; while (newTouchTarget.next != null) { newTouchTarget = newTouchTarget.next; } newTouchTarget.pointerIdBits |= idBitsToAssign; } } } // Dispatch to touch targets. if (mFirstTouchTarget == null) { // No touch targets so treat this as an ordinary view. handled = dispatchTransformedTouchEvent(ev, canceled, null, TouchTarget.ALL_POINTER_IDS); } else { // 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; } } // Update list of touch targets for pointer up or cancel, if needed. if (canceled || actionMasked == MotionEvent.ACTION_UP || actionMasked == MotionEvent.ACTION_HOVER_MOVE) { resetTouchState(); } else if (split && actionMasked == MotionEvent.ACTION_POINTER_UP) { final int actionIndex = ev.getActionIndex(); final int idBitsToRemove = 1 << ev.getPointerId(actionIndex); removePointersFromTouchTargets(idBitsToRemove); } } if (!handled && mInputEventConsistencyVerifier != null) { mInputEventConsistencyVerifier.onUnhandledEvent(ev, 1); } return handled; } public boolean onInterceptTouchEvent(MotionEvent ev) { return false; } 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; }代码量比较大,我们先概述一下各个函数的主要作用。
dispatchTouchEvent主要用来分发事件,函数主要作用是来决定当前的事件是交由自己消费处理,还是交由子控件处理。
onInterceptTouchEvent主要来决定当前控件是否需要拦截传递给子控件,如果返回True表示该控件拦截,并交由自己父类的dispatchTouchEvent处理消费,如果返回false表示不拦截,允许传递给子控件处理。
dispatchTransformedTouchEvent主要根据传来的子控件,决定是自身处理消费,还是交由子控件处理消费。
我们主要来分析一下dispatchTouchEvent函数:
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; }这段代码,如果当前传递的事件是Down(按下)或者当前触摸链表不为空,那么它调用onInterceptTouchEvent函数,判断是否进行事件拦截处理,通过返回值来决定intercepted变量的值。
接下来if (!canceled && !intercepted){} 这个括号内的代码需要注意了,只有当intercepted返回值为false的时候,才满足这个条件进入代码段。因此,我们结合onInterceptTouchEvent源码,发现它默认值返回的是false,也就说如果你不重载onInterceptTouchEvent方法并令其返回True,它一定是返回false,并能够执行花括号内的代码。
我们分析一下花括号中的代码,
if (actionMasked == MotionEvent.ACTION_DOWN || (split && actionMasked == MotionEvent.ACTION_POINTER_DOWN) || actionMasked == MotionEvent.ACTION_HOVER_MOVE) {} 判断当前的事件是否是ACTION_DOWN、ACTION_POINTER_DOWN(多点触摸)、ACTION_HOVER_MOVE(悬停),如果是,执行花括号内代码, final int childrenCount = mChildrenCount;if (childrenCount != 0) {}判断当前控件是否有子控件,如果大于0,执行花括号内代码,
for (int i = childrenCount - 1; i >= 0; i--)遍历子控件,
if (!canViewReceivePointerEvents(child)
判断当前的down、POINTER_DOWN、HOVER_MOVE三个事件的坐标点是否落在了子控件上,如果落在子控件上,
if (dispatchTransformedTouchEvent(ev, false, child, idBitsToAssign))
通过dispatchTransformedTouchEvent传递事件,交由子控件判断是否传递或自己消费处理。如果dispatchTransformedTouchEvent返回true,表示子控件已消费处理,并添加此子控件View到触摸链表,并放置链表头,并结束遍历子控件。newTouchTarget = addTouchTarget(child, idBitsToAssign);false表示未处理。
接着分析
if (mFirstTouchTarget == null) { handled = dispatchTransformedTouchEvent(ev, canceled, null, TouchTarget.ALL_POINTER_IDS); } else { ……}mFirstTouchTarget什么时候为空呢?从前面的代码可以看到,如果onInterceptTouchEvent返回为false(也就是不拦截),mFirstTouchTarget就为空,直接交给自己父View执行dispatchTouchEvent去了。如果mFirstTouchTarget不为空,它就取出触摸链表,逐个遍历判断处理,如果前面比如Down事件处理过了,就不再处理了。
一个完整的事件 一个up 一个down 和多个move尽可能有一个控件来完成这个事件。假如一个事件被两个控件分别完成 就是事件冲突。ScrollView和Viewpager 就是事件冲突 down 和up不是一个控件来执行。 左右和上下滑动冲突。解决就是自定义这两个。
打断和分发尽量 不要重写
继承View么有打断事件。
打断事件分发,不能打断本身的事件,只能打断事件向下分发,一旦事件被打断,就由谁来处理,谁打断谁处理
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