Java程序
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4984行
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198.97 KB
/*
* Copyright (C) 2006 The Android Open Source Project
*
* Licensed under the Apache License, Version 2.0 (the "License");
* you may not use this file except in compliance with the License.
* You may obtain a copy of the License at
*
* http://www.apache.org/licenses/LICENSE-2.0
*
* Unless required by applicable law or agreed to in writing, software
* distributed under the License is distributed on an "AS IS" BASIS,
* WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
* See the License for the specific language governing permissions and
* limitations under the License.
*/
package android.view;
import android.Manifest;
import android.animation.LayoutTransition;
import android.app.ActivityManagerNative;
import android.content.ClipDescription;
import android.content.ComponentCallbacks;
import android.content.ComponentCallbacks2;
import android.content.Context;
import android.content.pm.PackageManager;
import android.content.res.CompatibilityInfo;
import android.content.res.Configuration;
import android.content.res.Resources;
import android.graphics.Canvas;
import android.graphics.Paint;
import android.graphics.PixelFormat;
import android.graphics.Point;
import android.graphics.PointF;
import android.graphics.PorterDuff;
import android.graphics.Rect;
import android.graphics.Region;
import android.media.AudioManager;
import android.os.Binder;
import android.os.Bundle;
import android.os.Debug;
import android.os.Handler;
import android.os.LatencyTimer;
import android.os.Looper;
import android.os.Message;
import android.os.ParcelFileDescriptor;
import android.os.Process;
import android.os.RemoteException;
import android.os.SystemClock;
import android.os.SystemProperties;
import android.util.AndroidRuntimeException;
import android.util.DisplayMetrics;
import android.util.EventLog;
import android.util.Log;
import android.util.Pool;
import android.util.Poolable;
import android.util.PoolableManager;
import android.util.Pools;
import android.util.Slog;
import android.util.SparseArray;
import android.util.TypedValue;
import android.view.View.MeasureSpec;
import android.view.accessibility.AccessibilityEvent;
import android.view.accessibility.AccessibilityInteractionClient;
import android.view.accessibility.AccessibilityManager;
import android.view.accessibility.AccessibilityManager.AccessibilityStateChangeListener;
import android.view.accessibility.AccessibilityNodeInfo;
import android.view.accessibility.IAccessibilityInteractionConnection;
import android.view.accessibility.IAccessibilityInteractionConnectionCallback;
import android.view.animation.AccelerateDecelerateInterpolator;
import android.view.animation.Interpolator;
import android.view.inputmethod.InputConnection;
import android.view.inputmethod.InputMethodManager;
import android.widget.Scroller;
import com.android.internal.policy.PolicyManager;
import com.android.internal.view.BaseSurfaceHolder;
import com.android.internal.view.IInputMethodCallback;
import com.android.internal.view.IInputMethodSession;
import com.android.internal.view.RootViewSurfaceTaker;
import java.io.IOException;
import java.io.OutputStream;
import java.io.PrintWriter;
import java.lang.ref.WeakReference;
import java.util.ArrayList;
import java.util.List;
/**
* The top of a view hierarchy, implementing the needed protocol between View
* and the WindowManager. This is for the most part an internal implementation
* detail of {@link WindowManagerImpl}.
*
* {@hide}
*/
@SuppressWarnings({"EmptyCatchBlock", "PointlessBooleanExpression"})
public final class ViewRootImpl extends Handler implements ViewParent,
View.AttachInfo.Callbacks, HardwareRenderer.HardwareDrawCallbacks {
private static final String TAG = "ViewRootImpl";
private static final boolean DBG = false;
private static final boolean LOCAL_LOGV = false;
/** @noinspection PointlessBooleanExpression*/
private static final boolean DEBUG_DRAW = false || LOCAL_LOGV;
private static final boolean DEBUG_LAYOUT = false || LOCAL_LOGV;
private static final boolean DEBUG_DIALOG = false || LOCAL_LOGV;
private static final boolean DEBUG_INPUT_RESIZE = false || LOCAL_LOGV;
private static final boolean DEBUG_ORIENTATION = false || LOCAL_LOGV;
private static final boolean DEBUG_TRACKBALL = false || LOCAL_LOGV;
private static final boolean DEBUG_IMF = false || LOCAL_LOGV;
private static final boolean DEBUG_CONFIGURATION = false || LOCAL_LOGV;
private static final boolean DEBUG_FPS = false;
private static final boolean WATCH_POINTER = false;
/**
* Set this system property to true to force the view hierarchy to render
* at 60 Hz. This can be used to measure the potential framerate.
*/
private static final String PROPERTY_PROFILE_RENDERING = "viewancestor.profile_rendering";
private static final boolean MEASURE_LATENCY = false;
private static LatencyTimer lt;
/**
* Maximum time we allow the user to roll the trackball enough to generate
* a key event, before resetting the counters.
*/
static final int MAX_TRACKBALL_DELAY = 250;
static IWindowSession sWindowSession;
static final Object mStaticInit = new Object();
static boolean mInitialized = false;
static final ThreadLocal<RunQueue> sRunQueues = new ThreadLocal<RunQueue>();
static final ArrayList<Runnable> sFirstDrawHandlers = new ArrayList<Runnable>();
static boolean sFirstDrawComplete = false;
static final ArrayList<ComponentCallbacks> sConfigCallbacks
= new ArrayList<ComponentCallbacks>();
long mLastTrackballTime = 0;
final TrackballAxis mTrackballAxisX = new TrackballAxis();
final TrackballAxis mTrackballAxisY = new TrackballAxis();
int mLastJoystickXDirection;
int mLastJoystickYDirection;
int mLastJoystickXKeyCode;
int mLastJoystickYKeyCode;
final int[] mTmpLocation = new int[2];
final TypedValue mTmpValue = new TypedValue();
final InputMethodCallback mInputMethodCallback;
final SparseArray<Object> mPendingEvents = new SparseArray<Object>();
int mPendingEventSeq = 0;
final Thread mThread;
final WindowLeaked mLocation;
final WindowManager.LayoutParams mWindowAttributes = new WindowManager.LayoutParams();
final W mWindow;
final int mTargetSdkVersion;
int mSeq;
View mView;
View mFocusedView;
View mRealFocusedView; // this is not set to null in touch mode
int mViewVisibility;
boolean mAppVisible = true;
int mOrigWindowType = -1;
// Set to true if the owner of this window is in the stopped state,
// so the window should no longer be active.
boolean mStopped = false;
boolean mLastInCompatMode = false;
SurfaceHolder.Callback2 mSurfaceHolderCallback;
BaseSurfaceHolder mSurfaceHolder;
boolean mIsCreating;
boolean mDrawingAllowed;
final Region mTransparentRegion;
final Region mPreviousTransparentRegion;
int mWidth;
int mHeight;
Rect mDirty;
final Rect mCurrentDirty = new Rect();
final Rect mPreviousDirty = new Rect();
boolean mIsAnimating;
CompatibilityInfo.Translator mTranslator;
final View.AttachInfo mAttachInfo;
InputChannel mInputChannel;
InputQueue.Callback mInputQueueCallback;
InputQueue mInputQueue;
FallbackEventHandler mFallbackEventHandler;
final Rect mTempRect; // used in the transaction to not thrash the heap.
final Rect mVisRect; // used to retrieve visible rect of focused view.
boolean mTraversalScheduled;
long mLastTraversalFinishedTimeNanos;
long mLastDrawDurationNanos;
boolean mWillDrawSoon;
boolean mLayoutRequested;
boolean mFirst;
boolean mReportNextDraw;
boolean mFullRedrawNeeded;
boolean mNewSurfaceNeeded;
boolean mHasHadWindowFocus;
boolean mLastWasImTarget;
InputEventMessage mPendingInputEvents = null;
boolean mWindowAttributesChanged = false;
int mWindowAttributesChangesFlag = 0;
// These can be accessed by any thread, must be protected with a lock.
// Surface can never be reassigned or cleared (use Surface.clear()).
private final Surface mSurface = new Surface();
boolean mAdded;
boolean mAddedTouchMode;
CompatibilityInfoHolder mCompatibilityInfo;
/*package*/ int mAddNesting;
// These are accessed by multiple threads.
final Rect mWinFrame; // frame given by window manager.
final Rect mPendingVisibleInsets = new Rect();
final Rect mPendingContentInsets = new Rect();
final ViewTreeObserver.InternalInsetsInfo mLastGivenInsets
= new ViewTreeObserver.InternalInsetsInfo();
final Configuration mLastConfiguration = new Configuration();
final Configuration mPendingConfiguration = new Configuration();
class ResizedInfo {
Rect coveredInsets;
Rect visibleInsets;
Configuration newConfig;
}
boolean mScrollMayChange;
int mSoftInputMode;
View mLastScrolledFocus;
int mScrollY;
int mCurScrollY;
Scroller mScroller;
HardwareLayer mResizeBuffer;
long mResizeBufferStartTime;
int mResizeBufferDuration;
static final Interpolator mResizeInterpolator = new AccelerateDecelerateInterpolator();
private ArrayList<LayoutTransition> mPendingTransitions;
final ViewConfiguration mViewConfiguration;
/* Drag/drop */
ClipDescription mDragDescription;
View mCurrentDragView;
volatile Object mLocalDragState;
final PointF mDragPoint = new PointF();
final PointF mLastTouchPoint = new PointF();
private boolean mProfileRendering;
private Thread mRenderProfiler;
private volatile boolean mRenderProfilingEnabled;
// Variables to track frames per second, enabled via DEBUG_FPS flag
private long mFpsStartTime = -1;
private long mFpsPrevTime = -1;
private int mFpsNumFrames;
/**
* see {@link #playSoundEffect(int)}
*/
AudioManager mAudioManager;
final AccessibilityManager mAccessibilityManager;
AccessibilityInteractionController mAccessibilityInteractionController;
AccessibilityInteractionConnectionManager mAccessibilityInteractionConnectionManager;
SendWindowContentChangedAccessibilityEvent mSendWindowContentChangedAccessibilityEvent;
private final int mDensity;
/**
* Consistency verifier for debugging purposes.
*/
protected final InputEventConsistencyVerifier mInputEventConsistencyVerifier =
InputEventConsistencyVerifier.isInstrumentationEnabled() ?
new InputEventConsistencyVerifier(this, 0) : null;
public static IWindowSession getWindowSession(Looper mainLooper) {
synchronized (mStaticInit) {
if (!mInitialized) {
try {
InputMethodManager imm = InputMethodManager.getInstance(mainLooper);
sWindowSession = Display.getWindowManager().openSession(
imm.getClient(), imm.getInputContext());
mInitialized = true;
} catch (RemoteException e) {
}
}
return sWindowSession;
}
}
static final class SystemUiVisibilityInfo {
int seq;
int globalVisibility;
int localValue;
int localChanges;
}
public ViewRootImpl(Context context) {
super();
if (MEASURE_LATENCY) {
if (lt == null) {
lt = new LatencyTimer(100, 1000);
}
}
// Initialize the statics when this class is first instantiated. This is
// done here instead of in the static block because Zygote does not
// allow the spawning of threads.
getWindowSession(context.getMainLooper());
mThread = Thread.currentThread();
mLocation = new WindowLeaked(null);
mLocation.fillInStackTrace();
mWidth = -1;
mHeight = -1;
mDirty = new Rect();
mTempRect = new Rect();
mVisRect = new Rect();
mWinFrame = new Rect();
mWindow = new W(this);
mTargetSdkVersion = context.getApplicationInfo().targetSdkVersion;
mInputMethodCallback = new InputMethodCallback(this);
mViewVisibility = View.GONE;
mTransparentRegion = new Region();
mPreviousTransparentRegion = new Region();
mFirst = true; // true for the first time the view is added
mAdded = false;
mAccessibilityManager = AccessibilityManager.getInstance(context);
mAccessibilityInteractionConnectionManager =
new AccessibilityInteractionConnectionManager();
mAccessibilityManager.addAccessibilityStateChangeListener(
mAccessibilityInteractionConnectionManager);
mAttachInfo = new View.AttachInfo(sWindowSession, mWindow, this, this);
mViewConfiguration = ViewConfiguration.get(context);
mDensity = context.getResources().getDisplayMetrics().densityDpi;
mFallbackEventHandler = PolicyManager.makeNewFallbackEventHandler(context);
mProfileRendering = Boolean.parseBoolean(
SystemProperties.get(PROPERTY_PROFILE_RENDERING, "false"));
}
public static void addFirstDrawHandler(Runnable callback) {
synchronized (sFirstDrawHandlers) {
if (!sFirstDrawComplete) {
sFirstDrawHandlers.add(callback);
}
}
}
public static void addConfigCallback(ComponentCallbacks callback) {
synchronized (sConfigCallbacks) {
sConfigCallbacks.add(callback);
}
}
// FIXME for perf testing only
private boolean mProfile = false;
/**
* Call this to profile the next traversal call.
* FIXME for perf testing only. Remove eventually
*/
public void profile() {
mProfile = true;
}
/**
* Indicates whether we are in touch mode. Calling this method triggers an IPC
* call and should be avoided whenever possible.
*
* @return True, if the device is in touch mode, false otherwise.
*
* @hide
*/
static boolean isInTouchMode() {
if (mInitialized) {
try {
return sWindowSession.getInTouchMode();
} catch (RemoteException e) {
}
}
return false;
}
/**
* We have one child
*/
public void setView(View view, WindowManager.LayoutParams attrs, View panelParentView) {
synchronized (this) {
if (mView == null) {
mView = view;
mFallbackEventHandler.setView(view);
mWindowAttributes.copyFrom(attrs);
attrs = mWindowAttributes;
if (view instanceof RootViewSurfaceTaker) {
mSurfaceHolderCallback =
((RootViewSurfaceTaker)view).willYouTakeTheSurface();
if (mSurfaceHolderCallback != null) {
mSurfaceHolder = new TakenSurfaceHolder();
mSurfaceHolder.setFormat(PixelFormat.UNKNOWN);
}
}
CompatibilityInfo compatibilityInfo = mCompatibilityInfo.get();
mTranslator = compatibilityInfo.getTranslator();
// If the application owns the surface, don't enable hardware acceleration
if (mSurfaceHolder == null) {
enableHardwareAcceleration(attrs);
}
boolean restore = false;
if (mTranslator != null) {
mSurface.setCompatibilityTranslator(mTranslator);
restore = true;
attrs.backup();
mTranslator.translateWindowLayout(attrs);
}
if (DEBUG_LAYOUT) Log.d(TAG, "WindowLayout in setView:" + attrs);
if (!compatibilityInfo.supportsScreen()) {
attrs.flags |= WindowManager.LayoutParams.FLAG_COMPATIBLE_WINDOW;
mLastInCompatMode = true;
}
mSoftInputMode = attrs.softInputMode;
mWindowAttributesChanged = true;
mWindowAttributesChangesFlag = WindowManager.LayoutParams.EVERYTHING_CHANGED;
mAttachInfo.mRootView = view;
mAttachInfo.mScalingRequired = mTranslator != null;
mAttachInfo.mApplicationScale =
mTranslator == null ? 1.0f : mTranslator.applicationScale;
if (panelParentView != null) {
mAttachInfo.mPanelParentWindowToken
= panelParentView.getApplicationWindowToken();
}
mAdded = true;
int res; /* = WindowManagerImpl.ADD_OKAY; */
// Schedule the first layout -before- adding to the window
// manager, to make sure we do the relayout before receiving
// any other events from the system.
requestLayout();
if ((mWindowAttributes.inputFeatures
& WindowManager.LayoutParams.INPUT_FEATURE_NO_INPUT_CHANNEL) == 0) {
mInputChannel = new InputChannel();
}
try {
mOrigWindowType = mWindowAttributes.type;
res = sWindowSession.add(mWindow, mSeq, mWindowAttributes,
getHostVisibility(), mAttachInfo.mContentInsets,
mInputChannel);
} catch (RemoteException e) {
mAdded = false;
mView = null;
mAttachInfo.mRootView = null;
mInputChannel = null;
mFallbackEventHandler.setView(null);
unscheduleTraversals();
throw new RuntimeException("Adding window failed", e);
} finally {
if (restore) {
attrs.restore();
}
}
if (mTranslator != null) {
mTranslator.translateRectInScreenToAppWindow(mAttachInfo.mContentInsets);
}
mPendingContentInsets.set(mAttachInfo.mContentInsets);
mPendingVisibleInsets.set(0, 0, 0, 0);
if (DEBUG_LAYOUT) Log.v(TAG, "Added window " + mWindow);
if (res < WindowManagerImpl.ADD_OKAY) {
mView = null;
mAttachInfo.mRootView = null;
mAdded = false;
mFallbackEventHandler.setView(null);
unscheduleTraversals();
switch (res) {
case WindowManagerImpl.ADD_BAD_APP_TOKEN:
case WindowManagerImpl.ADD_BAD_SUBWINDOW_TOKEN:
throw new WindowManagerImpl.BadTokenException(
"Unable to add window -- token " + attrs.token
+ " is not valid; is your activity running?");
case WindowManagerImpl.ADD_NOT_APP_TOKEN:
throw new WindowManagerImpl.BadTokenException(
"Unable to add window -- token " + attrs.token
+ " is not for an application");
case WindowManagerImpl.ADD_APP_EXITING:
throw new WindowManagerImpl.BadTokenException(
"Unable to add window -- app for token " + attrs.token
+ " is exiting");
case WindowManagerImpl.ADD_DUPLICATE_ADD:
throw new WindowManagerImpl.BadTokenException(
"Unable to add window -- window " + mWindow
+ " has already been added");
case WindowManagerImpl.ADD_STARTING_NOT_NEEDED:
// Silently ignore -- we would have just removed it
// right away, anyway.
return;
case WindowManagerImpl.ADD_MULTIPLE_SINGLETON:
throw new WindowManagerImpl.BadTokenException(
"Unable to add window " + mWindow +
" -- another window of this type already exists");
case WindowManagerImpl.ADD_PERMISSION_DENIED:
throw new WindowManagerImpl.BadTokenException(
"Unable to add window " + mWindow +
" -- permission denied for this window type");
}
throw new RuntimeException(
"Unable to add window -- unknown error code " + res);
}
if (view instanceof RootViewSurfaceTaker) {
mInputQueueCallback =
((RootViewSurfaceTaker)view).willYouTakeTheInputQueue();
}
if (mInputChannel != null) {
if (mInputQueueCallback != null) {
mInputQueue = new InputQueue(mInputChannel);
mInputQueueCallback.onInputQueueCreated(mInputQueue);
} else {
InputQueue.registerInputChannel(mInputChannel, mInputHandler,
Looper.myQueue());
}
}
view.assignParent(this);
mAddedTouchMode = (res&WindowManagerImpl.ADD_FLAG_IN_TOUCH_MODE) != 0;
mAppVisible = (res&WindowManagerImpl.ADD_FLAG_APP_VISIBLE) != 0;
if (mAccessibilityManager.isEnabled()) {
mAccessibilityInteractionConnectionManager.ensureConnection();
}
}
}
}
void destroyHardwareResources() {
if (mAttachInfo.mHardwareRenderer != null) {
if (mAttachInfo.mHardwareRenderer.isEnabled()) {
mAttachInfo.mHardwareRenderer.destroyLayers(mView);
}
mAttachInfo.mHardwareRenderer.destroy(false);
}
}
void terminateHardwareResources() {
if (mAttachInfo.mHardwareRenderer != null) {
mAttachInfo.mHardwareRenderer.destroyHardwareResources(mView);
mAttachInfo.mHardwareRenderer.destroy(false);
}
}
void destroyHardwareLayers() {
if (mThread != Thread.currentThread()) {
if (mAttachInfo.mHardwareRenderer != null &&
mAttachInfo.mHardwareRenderer.isEnabled()) {
HardwareRenderer.trimMemory(ComponentCallbacks2.TRIM_MEMORY_MODERATE);
}
} else {
if (mAttachInfo.mHardwareRenderer != null &&
mAttachInfo.mHardwareRenderer.isEnabled()) {
mAttachInfo.mHardwareRenderer.destroyLayers(mView);
}
}
}
private void enableHardwareAcceleration(WindowManager.LayoutParams attrs) {
mAttachInfo.mHardwareAccelerated = false;
mAttachInfo.mHardwareAccelerationRequested = false;
// Don't enable hardware acceleration when the application is in compatibility mode
if (mTranslator != null) return;
// Try to enable hardware acceleration if requested
final boolean hardwareAccelerated =
(attrs.flags & WindowManager.LayoutParams.FLAG_HARDWARE_ACCELERATED) != 0;
if (hardwareAccelerated) {
if (!HardwareRenderer.isAvailable()) {
return;
}
// Persistent processes (including the system) should not do
// accelerated rendering on low-end devices. In that case,
// sRendererDisabled will be set. In addition, the system process
// itself should never do accelerated rendering. In that case, both
// sRendererDisabled and sSystemRendererDisabled are set. When
// sSystemRendererDisabled is set, PRIVATE_FLAG_FORCE_HARDWARE_ACCELERATED
// can be used by code on the system process to escape that and enable
// HW accelerated drawing. (This is basically for the lock screen.)
final boolean fakeHwAccelerated = (attrs.privateFlags &
WindowManager.LayoutParams.PRIVATE_FLAG_FAKE_HARDWARE_ACCELERATED) != 0;
final boolean forceHwAccelerated = (attrs.privateFlags &
WindowManager.LayoutParams.PRIVATE_FLAG_FORCE_HARDWARE_ACCELERATED) != 0;
if (!HardwareRenderer.sRendererDisabled || (HardwareRenderer.sSystemRendererDisabled
&& forceHwAccelerated)) {
// Don't enable hardware acceleration when we're not on the main thread
if (!HardwareRenderer.sSystemRendererDisabled
&& Looper.getMainLooper() != Looper.myLooper()) {
Log.w(HardwareRenderer.LOG_TAG, "Attempting to initialize hardware "
+ "acceleration outside of the main thread, aborting");
return;
}
final boolean translucent = attrs.format != PixelFormat.OPAQUE;
if (mAttachInfo.mHardwareRenderer != null) {
mAttachInfo.mHardwareRenderer.destroy(true);
}
mAttachInfo.mHardwareRenderer = HardwareRenderer.createGlRenderer(2, translucent);
mAttachInfo.mHardwareAccelerated = mAttachInfo.mHardwareAccelerationRequested
= mAttachInfo.mHardwareRenderer != null;
} else if (fakeHwAccelerated) {
// The window had wanted to use hardware acceleration, but this
// is not allowed in its process. By setting this flag, it can
// still render as if it was accelerated. This is basically for
// the preview windows the window manager shows for launching
// applications, so they will look more like the app being launched.
mAttachInfo.mHardwareAccelerationRequested = true;
}
}
}
public View getView() {
return mView;
}
final WindowLeaked getLocation() {
return mLocation;
}
void setLayoutParams(WindowManager.LayoutParams attrs, boolean newView) {
synchronized (this) {
int oldSoftInputMode = mWindowAttributes.softInputMode;
// preserve compatible window flag if exists.
int compatibleWindowFlag =
mWindowAttributes.flags & WindowManager.LayoutParams.FLAG_COMPATIBLE_WINDOW;
mWindowAttributesChangesFlag = mWindowAttributes.copyFrom(attrs);
mWindowAttributes.flags |= compatibleWindowFlag;
if (newView) {
mSoftInputMode = attrs.softInputMode;
requestLayout();
}
// Don't lose the mode we last auto-computed.
if ((attrs.softInputMode&WindowManager.LayoutParams.SOFT_INPUT_MASK_ADJUST)
== WindowManager.LayoutParams.SOFT_INPUT_ADJUST_UNSPECIFIED) {
mWindowAttributes.softInputMode = (mWindowAttributes.softInputMode
& ~WindowManager.LayoutParams.SOFT_INPUT_MASK_ADJUST)
| (oldSoftInputMode
& WindowManager.LayoutParams.SOFT_INPUT_MASK_ADJUST);
}
mWindowAttributesChanged = true;
scheduleTraversals();
}
}
void handleAppVisibility(boolean visible) {
if (mAppVisible != visible) {
mAppVisible = visible;
scheduleTraversals();
}
}
void handleGetNewSurface() {
mNewSurfaceNeeded = true;
mFullRedrawNeeded = true;
scheduleTraversals();
}
/**
* {@inheritDoc}
*/
public void requestLayout() {
checkThread();
mLayoutRequested = true;
scheduleTraversals();
}
/**
* {@inheritDoc}
*/
public boolean isLayoutRequested() {
return mLayoutRequested;
}
public void invalidateChild(View child, Rect dirty) {
checkThread();
if (DEBUG_DRAW) Log.v(TAG, "Invalidate child: " + dirty);
if (dirty == null) {
// Fast invalidation for GL-enabled applications; GL must redraw everything
invalidate();
return;
}
if (mCurScrollY != 0 || mTranslator != null) {
mTempRect.set(dirty);
dirty = mTempRect;
if (mCurScrollY != 0) {
dirty.offset(0, -mCurScrollY);
}
if (mTranslator != null) {
mTranslator.translateRectInAppWindowToScreen(dirty);
}
if (mAttachInfo.mScalingRequired) {
dirty.inset(-1, -1);
}
}
if (!mDirty.isEmpty() && !mDirty.contains(dirty)) {
mAttachInfo.mSetIgnoreDirtyState = true;
mAttachInfo.mIgnoreDirtyState = true;
}
mDirty.union(dirty);
if (!mWillDrawSoon) {
scheduleTraversals();
}
}
void invalidate() {
mDirty.set(0, 0, mWidth, mHeight);
scheduleTraversals();
}
void setStopped(boolean stopped) {
if (mStopped != stopped) {
mStopped = stopped;
if (!stopped) {
scheduleTraversals();
}
}
}
public ViewParent getParent() {
return null;
}
public ViewParent invalidateChildInParent(final int[] location, final Rect dirty) {
invalidateChild(null, dirty);
return null;
}
public boolean getChildVisibleRect(View child, Rect r, android.graphics.Point offset) {
if (child != mView) {
throw new RuntimeException("child is not mine, honest!");
}
// Note: don't apply scroll offset, because we want to know its
// visibility in the virtual canvas being given to the view hierarchy.
return r.intersect(0, 0, mWidth, mHeight);
}
public void bringChildToFront(View child) {
}
public void scheduleTraversals() {
if (!mTraversalScheduled) {
mTraversalScheduled = true;
//noinspection ConstantConditions
if (ViewDebug.DEBUG_LATENCY && mLastTraversalFinishedTimeNanos != 0) {
final long now = System.nanoTime();
Log.d(TAG, "Latency: Scheduled traversal, it has been "
+ ((now - mLastTraversalFinishedTimeNanos) * 0.000001f)
+ "ms since the last traversal finished.");
}
sendEmptyMessage(DO_TRAVERSAL);
}
}
public void unscheduleTraversals() {
if (mTraversalScheduled) {
mTraversalScheduled = false;
removeMessages(DO_TRAVERSAL);
}
}
int getHostVisibility() {
return mAppVisible ? mView.getVisibility() : View.GONE;
}
void disposeResizeBuffer() {
if (mResizeBuffer != null) {
mResizeBuffer.destroy();
mResizeBuffer = null;
}
}
/**
* Add LayoutTransition to the list of transitions to be started in the next traversal.
* This list will be cleared after the transitions on the list are start()'ed. These
* transitionsa re added by LayoutTransition itself when it sets up animations. The setup
* happens during the layout phase of traversal, which we want to complete before any of the
* animations are started (because those animations may side-effect properties that layout
* depends upon, like the bounding rectangles of the affected views). So we add the transition
* to the list and it is started just prior to starting the drawing phase of traversal.
*
* @param transition The LayoutTransition to be started on the next traversal.
*
* @hide
*/
public void requestTransitionStart(LayoutTransition transition) {
if (mPendingTransitions == null || !mPendingTransitions.contains(transition)) {
if (mPendingTransitions == null) {
mPendingTransitions = new ArrayList<LayoutTransition>();
}
mPendingTransitions.add(transition);
}
}
private void processInputEvents(boolean outOfOrder) {
while (mPendingInputEvents != null) {
handleMessage(mPendingInputEvents.mMessage);
InputEventMessage tmpMessage = mPendingInputEvents;
mPendingInputEvents = mPendingInputEvents.mNext;
tmpMessage.recycle();
if (outOfOrder) {
removeMessages(PROCESS_INPUT_EVENTS);
}
}
}
private void performTraversals() {
// cache mView since it is used so much below...
final View host = mView;
processInputEvents(true);
if (DBG) {
System.out.println("======================================");
System.out.println("performTraversals");
host.debug();
}
if (host == null || !mAdded)
return;
mTraversalScheduled = false;
mWillDrawSoon = true;
boolean windowSizeMayChange = false;
boolean fullRedrawNeeded = mFullRedrawNeeded;
boolean newSurface = false;
boolean surfaceChanged = false;
WindowManager.LayoutParams lp = mWindowAttributes;
int desiredWindowWidth;
int desiredWindowHeight;
int childWidthMeasureSpec;
int childHeightMeasureSpec;
final View.AttachInfo attachInfo = mAttachInfo;
final int viewVisibility = getHostVisibility();
boolean viewVisibilityChanged = mViewVisibility != viewVisibility
|| mNewSurfaceNeeded;
WindowManager.LayoutParams params = null;
if (mWindowAttributesChanged) {
mWindowAttributesChanged = false;
surfaceChanged = true;
params = lp;
}
CompatibilityInfo compatibilityInfo = mCompatibilityInfo.get();
if (compatibilityInfo.supportsScreen() == mLastInCompatMode) {
params = lp;
fullRedrawNeeded = true;
mLayoutRequested = true;
if (mLastInCompatMode) {
params.flags &= ~WindowManager.LayoutParams.FLAG_COMPATIBLE_WINDOW;
mLastInCompatMode = false;
} else {
params.flags |= WindowManager.LayoutParams.FLAG_COMPATIBLE_WINDOW;
mLastInCompatMode = true;
}
}
mWindowAttributesChangesFlag = 0;
Rect frame = mWinFrame;
if (mFirst) {
fullRedrawNeeded = true;
mLayoutRequested = true;
if (lp.type == WindowManager.LayoutParams.TYPE_STATUS_BAR_PANEL) {
// NOTE -- system code, won't try to do compat mode.
Display disp = WindowManagerImpl.getDefault().getDefaultDisplay();
Point size = new Point();
disp.getRealSize(size);
desiredWindowWidth = size.x;
desiredWindowHeight = size.y;
} else {
DisplayMetrics packageMetrics =
mView.getContext().getResources().getDisplayMetrics();
desiredWindowWidth = packageMetrics.widthPixels;
desiredWindowHeight = packageMetrics.heightPixels;
}
// For the very first time, tell the view hierarchy that it
// is attached to the window. Note that at this point the surface
// object is not initialized to its backing store, but soon it
// will be (assuming the window is visible).
attachInfo.mSurface = mSurface;
// We used to use the following condition to choose 32 bits drawing caches:
// PixelFormat.hasAlpha(lp.format) || lp.format == PixelFormat.RGBX_8888
// However, windows are now always 32 bits by default, so choose 32 bits
attachInfo.mUse32BitDrawingCache = true;
attachInfo.mHasWindowFocus = false;
attachInfo.mWindowVisibility = viewVisibility;
attachInfo.mRecomputeGlobalAttributes = false;
attachInfo.mKeepScreenOn = false;
attachInfo.mSystemUiVisibility = 0;
viewVisibilityChanged = false;
mLastConfiguration.setTo(host.getResources().getConfiguration());
host.dispatchAttachedToWindow(attachInfo, 0);
//Log.i(TAG, "Screen on initialized: " + attachInfo.mKeepScreenOn);
host.fitSystemWindows(mAttachInfo.mContentInsets);
} else {
desiredWindowWidth = frame.width();
desiredWindowHeight = frame.height();
if (desiredWindowWidth != mWidth || desiredWindowHeight != mHeight) {
if (DEBUG_ORIENTATION) Log.v(TAG,
"View " + host + " resized to: " + frame);
fullRedrawNeeded = true;
mLayoutRequested = true;
windowSizeMayChange = true;
}
}
if (viewVisibilityChanged) {
attachInfo.mWindowVisibility = viewVisibility;
host.dispatchWindowVisibilityChanged(viewVisibility);
if (viewVisibility != View.VISIBLE || mNewSurfaceNeeded) {
destroyHardwareResources();
}
if (viewVisibility == View.GONE) {
// After making a window gone, we will count it as being
// shown for the first time the next time it gets focus.
mHasHadWindowFocus = false;
}
}
boolean insetsChanged = false;
if (mLayoutRequested && !mStopped) {
// Execute enqueued actions on every layout in case a view that was detached
// enqueued an action after being detached
getRunQueue().executeActions(attachInfo.mHandler);
final Resources res = mView.getContext().getResources();
if (mFirst) {
// make sure touch mode code executes by setting cached value
// to opposite of the added touch mode.
mAttachInfo.mInTouchMode = !mAddedTouchMode;
ensureTouchModeLocally(mAddedTouchMode);
} else {
if (!mPendingContentInsets.equals(mAttachInfo.mContentInsets)) {
insetsChanged = true;
}
if (!mPendingVisibleInsets.equals(mAttachInfo.mVisibleInsets)) {
mAttachInfo.mVisibleInsets.set(mPendingVisibleInsets);
if (DEBUG_LAYOUT) Log.v(TAG, "Visible insets changing to: "
+ mAttachInfo.mVisibleInsets);
}
if (lp.width == ViewGroup.LayoutParams.WRAP_CONTENT
|| lp.height == ViewGroup.LayoutParams.WRAP_CONTENT) {
windowSizeMayChange = true;
if (lp.type == WindowManager.LayoutParams.TYPE_STATUS_BAR_PANEL) {
// NOTE -- system code, won't try to do compat mode.
Display disp = WindowManagerImpl.getDefault().getDefaultDisplay();
Point size = new Point();
disp.getRealSize(size);
desiredWindowWidth = size.x;
desiredWindowHeight = size.y;
} else {
DisplayMetrics packageMetrics = res.getDisplayMetrics();
desiredWindowWidth = packageMetrics.widthPixels;
desiredWindowHeight = packageMetrics.heightPixels;
}
}
}
// Ask host how big it wants to be
if (DEBUG_ORIENTATION || DEBUG_LAYOUT) Log.v(TAG,
"Measuring " + host + " in display " + desiredWindowWidth
+ "x" + desiredWindowHeight + "...");
boolean goodMeasure = false;
if (lp.width == ViewGroup.LayoutParams.WRAP_CONTENT) {
// On large screens, we don't want to allow dialogs to just
// stretch to fill the entire width of the screen to display
// one line of text. First try doing the layout at a smaller
// size to see if it will fit.
final DisplayMetrics packageMetrics = res.getDisplayMetrics();
res.getValue(com.android.internal.R.dimen.config_prefDialogWidth, mTmpValue, true);
int baseSize = 0;
if (mTmpValue.type == TypedValue.TYPE_DIMENSION) {
baseSize = (int)mTmpValue.getDimension(packageMetrics);
}
if (DEBUG_DIALOG) Log.v(TAG, "Window " + mView + ": baseSize=" + baseSize);
if (baseSize != 0 && desiredWindowWidth > baseSize) {
childWidthMeasureSpec = getRootMeasureSpec(baseSize, lp.width);
childHeightMeasureSpec = getRootMeasureSpec(desiredWindowHeight, lp.height);
host.measure(childWidthMeasureSpec, childHeightMeasureSpec);
if (DEBUG_DIALOG) Log.v(TAG, "Window " + mView + ": measured ("
+ host.getMeasuredWidth() + "," + host.getMeasuredHeight() + ")");
if ((host.getMeasuredWidthAndState()&View.MEASURED_STATE_TOO_SMALL) == 0) {
goodMeasure = true;
} else {
// Didn't fit in that size... try expanding a bit.
baseSize = (baseSize+desiredWindowWidth)/2;
if (DEBUG_DIALOG) Log.v(TAG, "Window " + mView + ": next baseSize="
+ baseSize);
childWidthMeasureSpec = getRootMeasureSpec(baseSize, lp.width);
host.measure(childWidthMeasureSpec, childHeightMeasureSpec);
if (DEBUG_DIALOG) Log.v(TAG, "Window " + mView + ": measured ("
+ host.getMeasuredWidth() + "," + host.getMeasuredHeight() + ")");
if ((host.getMeasuredWidthAndState()&View.MEASURED_STATE_TOO_SMALL) == 0) {
if (DEBUG_DIALOG) Log.v(TAG, "Good!");
goodMeasure = true;
}
}
}
}
if (!goodMeasure) {
childWidthMeasureSpec = getRootMeasureSpec(desiredWindowWidth, lp.width);
childHeightMeasureSpec = getRootMeasureSpec(desiredWindowHeight, lp.height);
host.measure(childWidthMeasureSpec, childHeightMeasureSpec);
if (mWidth != host.getMeasuredWidth() || mHeight != host.getMeasuredHeight()) {
windowSizeMayChange = true;
}
}
if (DBG) {
System.out.println("======================================");
System.out.println("performTraversals -- after measure");
host.debug();
}
}
if (attachInfo.mRecomputeGlobalAttributes && host.mAttachInfo != null) {
//Log.i(TAG, "Computing view hierarchy attributes!");
attachInfo.mRecomputeGlobalAttributes = false;
boolean oldScreenOn = attachInfo.mKeepScreenOn;
int oldVis = attachInfo.mSystemUiVisibility;
boolean oldHasSystemUiListeners = attachInfo.mHasSystemUiListeners;
attachInfo.mKeepScreenOn = false;
attachInfo.mSystemUiVisibility = 0;
attachInfo.mHasSystemUiListeners = false;
host.dispatchCollectViewAttributes(0);
if (attachInfo.mKeepScreenOn != oldScreenOn
|| attachInfo.mSystemUiVisibility != oldVis
|| attachInfo.mHasSystemUiListeners != oldHasSystemUiListeners) {
params = lp;
}
}
if (attachInfo.mForceReportNewAttributes) {
attachInfo.mForceReportNewAttributes = false;
params = lp;
}
if (mFirst || attachInfo.mViewVisibilityChanged) {
attachInfo.mViewVisibilityChanged = false;
int resizeMode = mSoftInputMode &
WindowManager.LayoutParams.SOFT_INPUT_MASK_ADJUST;
// If we are in auto resize mode, then we need to determine
// what mode to use now.
if (resizeMode == WindowManager.LayoutParams.SOFT_INPUT_ADJUST_UNSPECIFIED) {
final int N = attachInfo.mScrollContainers.size();
for (int i=0; i<N; i++) {
if (attachInfo.mScrollContainers.get(i).isShown()) {
resizeMode = WindowManager.LayoutParams.SOFT_INPUT_ADJUST_RESIZE;
}
}
if (resizeMode == 0) {
resizeMode = WindowManager.LayoutParams.SOFT_INPUT_ADJUST_PAN;
}
if ((lp.softInputMode &
WindowManager.LayoutParams.SOFT_INPUT_MASK_ADJUST) != resizeMode) {
lp.softInputMode = (lp.softInputMode &
~WindowManager.LayoutParams.SOFT_INPUT_MASK_ADJUST) |
resizeMode;
params = lp;
}
}
}
if (params != null && (host.mPrivateFlags & View.REQUEST_TRANSPARENT_REGIONS) != 0) {
if (!PixelFormat.formatHasAlpha(params.format)) {
params.format = PixelFormat.TRANSLUCENT;
}
}
boolean windowShouldResize = mLayoutRequested && windowSizeMayChange
&& ((mWidth != host.getMeasuredWidth() || mHeight != host.getMeasuredHeight())
|| (lp.width == ViewGroup.LayoutParams.WRAP_CONTENT &&
frame.width() < desiredWindowWidth && frame.width() != mWidth)
|| (lp.height == ViewGroup.LayoutParams.WRAP_CONTENT &&
frame.height() < desiredWindowHeight && frame.height() != mHeight));
final boolean computesInternalInsets =
attachInfo.mTreeObserver.hasComputeInternalInsetsListeners();
boolean insetsPending = false;
int relayoutResult = 0;
if (mFirst || windowShouldResize || insetsChanged ||
viewVisibilityChanged || params != null) {
if (viewVisibility == View.VISIBLE) {
// If this window is giving internal insets to the window
// manager, and it is being added or changing its visibility,
// then we want to first give the window manager "fake"
// insets to cause it to effectively ignore the content of
// the window during layout. This avoids it briefly causing
// other windows to resize/move based on the raw frame of the
// window, waiting until we can finish laying out this window
// and get back to the window manager with the ultimately
// computed insets.
insetsPending = computesInternalInsets && (mFirst || viewVisibilityChanged);
}
if (mSurfaceHolder != null) {
mSurfaceHolder.mSurfaceLock.lock();
mDrawingAllowed = true;
}
boolean hwInitialized = false;
boolean contentInsetsChanged = false;
boolean visibleInsetsChanged;
boolean hadSurface = mSurface.isValid();
try {
int fl = 0;
if (params != null) {
fl = params.flags;
if (attachInfo.mKeepScreenOn) {
params.flags |= WindowManager.LayoutParams.FLAG_KEEP_SCREEN_ON;
}
params.subtreeSystemUiVisibility = attachInfo.mSystemUiVisibility;
params.hasSystemUiListeners = attachInfo.mHasSystemUiListeners;
}
if (DEBUG_LAYOUT) {
Log.i(TAG, "host=w:" + host.getMeasuredWidth() + ", h:" +
host.getMeasuredHeight() + ", params=" + params);
}
final int surfaceGenerationId = mSurface.getGenerationId();
relayoutResult = relayoutWindow(params, viewVisibility, insetsPending);
if (params != null) {
params.flags = fl;
}
if (DEBUG_LAYOUT) Log.v(TAG, "relayout: frame=" + frame.toShortString()
+ " content=" + mPendingContentInsets.toShortString()
+ " visible=" + mPendingVisibleInsets.toShortString()
+ " surface=" + mSurface);
if (mPendingConfiguration.seq != 0) {
if (DEBUG_CONFIGURATION) Log.v(TAG, "Visible with new config: "
+ mPendingConfiguration);
updateConfiguration(mPendingConfiguration, !mFirst);
mPendingConfiguration.seq = 0;
}
contentInsetsChanged = !mPendingContentInsets.equals(
mAttachInfo.mContentInsets);
visibleInsetsChanged = !mPendingVisibleInsets.equals(
mAttachInfo.mVisibleInsets);
if (contentInsetsChanged) {
if (mWidth > 0 && mHeight > 0 &&
mSurface != null && mSurface.isValid() &&
!mAttachInfo.mTurnOffWindowResizeAnim &&
mAttachInfo.mHardwareRenderer != null &&
mAttachInfo.mHardwareRenderer.isEnabled() &&
mAttachInfo.mHardwareRenderer.validate() &&
lp != null && !PixelFormat.formatHasAlpha(lp.format)) {
disposeResizeBuffer();
boolean completed = false;
HardwareCanvas hwRendererCanvas = mAttachInfo.mHardwareRenderer.getCanvas();
HardwareCanvas layerCanvas = null;
try {
if (mResizeBuffer == null) {
mResizeBuffer = mAttachInfo.mHardwareRenderer.createHardwareLayer(
mWidth, mHeight, false);
} else if (mResizeBuffer.getWidth() != mWidth ||
mResizeBuffer.getHeight() != mHeight) {
mResizeBuffer.resize(mWidth, mHeight);
}
layerCanvas = mResizeBuffer.start(hwRendererCanvas);
layerCanvas.setViewport(mWidth, mHeight);
layerCanvas.onPreDraw(null);
final int restoreCount = layerCanvas.save();
layerCanvas.drawColor(0xff000000, PorterDuff.Mode.SRC);
int yoff;
final boolean scrolling = mScroller != null
&& mScroller.computeScrollOffset();
if (scrolling) {
yoff = mScroller.getCurrY();
mScroller.abortAnimation();
} else {
yoff = mScrollY;
}
layerCanvas.translate(0, -yoff);
if (mTranslator != null) {
mTranslator.translateCanvas(layerCanvas);
}
mView.draw(layerCanvas);
mResizeBufferStartTime = SystemClock.uptimeMillis();
mResizeBufferDuration = mView.getResources().getInteger(
com.android.internal.R.integer.config_mediumAnimTime);
completed = true;
layerCanvas.restoreToCount(restoreCount);
} catch (OutOfMemoryError e) {
Log.w(TAG, "Not enough memory for content change anim buffer", e);
} finally {
if (layerCanvas != null) {
layerCanvas.onPostDraw();
}
if (mResizeBuffer != null) {
mResizeBuffer.end(hwRendererCanvas);
if (!completed) {
mResizeBuffer.destroy();
mResizeBuffer = null;
}
}
}
}
mAttachInfo.mContentInsets.set(mPendingContentInsets);
host.fitSystemWindows(mAttachInfo.mContentInsets);
if (DEBUG_LAYOUT) Log.v(TAG, "Content insets changing to: "
+ mAttachInfo.mContentInsets);
}
if (visibleInsetsChanged) {
mAttachInfo.mVisibleInsets.set(mPendingVisibleInsets);
if (DEBUG_LAYOUT) Log.v(TAG, "Visible insets changing to: "
+ mAttachInfo.mVisibleInsets);
}
if (!hadSurface) {
if (mSurface.isValid()) {
// If we are creating a new surface, then we need to
// completely redraw it. Also, when we get to the
// point of drawing it we will hold off and schedule
// a new traversal instead. This is so we can tell the
// window manager about all of the windows being displayed
// before actually drawing them, so it can display then
// all at once.
newSurface = true;
fullRedrawNeeded = true;
mPreviousTransparentRegion.setEmpty();
if (mAttachInfo.mHardwareRenderer != null) {
try {
hwInitialized = mAttachInfo.mHardwareRenderer.initialize(mHolder);
} catch (Surface.OutOfResourcesException e) {
Log.e(TAG, "OutOfResourcesException initializing HW surface", e);
try {
if (!sWindowSession.outOfMemory(mWindow)) {
Slog.w(TAG, "No processes killed for memory; killing self");
Process.killProcess(Process.myPid());
}
} catch (RemoteException ex) {
}
mLayoutRequested = true; // ask wm for a new surface next time.
return;
}
}
}
} else if (!mSurface.isValid()) {
// If the surface has been removed, then reset the scroll
// positions.
mLastScrolledFocus = null;
mScrollY = mCurScrollY = 0;
if (mScroller != null) {
mScroller.abortAnimation();
}
disposeResizeBuffer();
// Our surface is gone
if (mAttachInfo.mHardwareRenderer != null &&
mAttachInfo.mHardwareRenderer.isEnabled()) {
mAttachInfo.mHardwareRenderer.destroy(true);
}
} else if (surfaceGenerationId != mSurface.getGenerationId() &&
mSurfaceHolder == null && mAttachInfo.mHardwareRenderer != null) {
fullRedrawNeeded = true;
try {
mAttachInfo.mHardwareRenderer.updateSurface(mHolder);
} catch (Surface.OutOfResourcesException e) {
Log.e(TAG, "OutOfResourcesException updating HW surface", e);
try {
if (!sWindowSession.outOfMemory(mWindow)) {
Slog.w(TAG, "No processes killed for memory; killing self");
Process.killProcess(Process.myPid());
}
} catch (RemoteException ex) {
}
mLayoutRequested = true; // ask wm for a new surface next time.
return;
}
}
} catch (RemoteException e) {
}
if (DEBUG_ORIENTATION) Log.v(
TAG, "Relayout returned: frame=" + frame + ", surface=" + mSurface);
attachInfo.mWindowLeft = frame.left;
attachInfo.mWindowTop = frame.top;
// !!FIXME!! This next section handles the case where we did not get the
// window size we asked for. We should avoid this by getting a maximum size from
// the window session beforehand.
mWidth = frame.width();
mHeight = frame.height();
if (mSurfaceHolder != null) {
// The app owns the surface; tell it about what is going on.
if (mSurface.isValid()) {
// XXX .copyFrom() doesn't work!
//mSurfaceHolder.mSurface.copyFrom(mSurface);
mSurfaceHolder.mSurface = mSurface;
}
mSurfaceHolder.setSurfaceFrameSize(mWidth, mHeight);
mSurfaceHolder.mSurfaceLock.unlock();
if (mSurface.isValid()) {
if (!hadSurface) {
mSurfaceHolder.ungetCallbacks();
mIsCreating = true;
mSurfaceHolderCallback.surfaceCreated(mSurfaceHolder);
SurfaceHolder.Callback callbacks[] = mSurfaceHolder.getCallbacks();
if (callbacks != null) {
for (SurfaceHolder.Callback c : callbacks) {
c.surfaceCreated(mSurfaceHolder);
}
}
surfaceChanged = true;
}
if (surfaceChanged) {
mSurfaceHolderCallback.surfaceChanged(mSurfaceHolder,
lp.format, mWidth, mHeight);
SurfaceHolder.Callback callbacks[] = mSurfaceHolder.getCallbacks();
if (callbacks != null) {
for (SurfaceHolder.Callback c : callbacks) {
c.surfaceChanged(mSurfaceHolder, lp.format,
mWidth, mHeight);
}
}
}
mIsCreating = false;
} else if (hadSurface) {
mSurfaceHolder.ungetCallbacks();
SurfaceHolder.Callback callbacks[] = mSurfaceHolder.getCallbacks();
mSurfaceHolderCallback.surfaceDestroyed(mSurfaceHolder);
if (callbacks != null) {
for (SurfaceHolder.Callback c : callbacks) {
c.surfaceDestroyed(mSurfaceHolder);
}
}
mSurfaceHolder.mSurfaceLock.lock();
try {
mSurfaceHolder.mSurface = new Surface();
} finally {
mSurfaceHolder.mSurfaceLock.unlock();
}
}
}
if (mAttachInfo.mHardwareRenderer != null &&
mAttachInfo.mHardwareRenderer.isEnabled()) {
if (hwInitialized || windowShouldResize ||
mWidth != mAttachInfo.mHardwareRenderer.getWidth() ||
mHeight != mAttachInfo.mHardwareRenderer.getHeight()) {
mAttachInfo.mHardwareRenderer.setup(mWidth, mHeight);
if (!hwInitialized) {
mAttachInfo.mHardwareRenderer.invalidate(mHolder);
}
}
}
if (!mStopped) {
boolean focusChangedDueToTouchMode = ensureTouchModeLocally(
(relayoutResult&WindowManagerImpl.RELAYOUT_RES_IN_TOUCH_MODE) != 0);
if (focusChangedDueToTouchMode || mWidth != host.getMeasuredWidth()
|| mHeight != host.getMeasuredHeight() || contentInsetsChanged) {
childWidthMeasureSpec = getRootMeasureSpec(mWidth, lp.width);
childHeightMeasureSpec = getRootMeasureSpec(mHeight, lp.height);
if (DEBUG_LAYOUT) Log.v(TAG, "Ooops, something changed! mWidth="
+ mWidth + " measuredWidth=" + host.getMeasuredWidth()
+ " mHeight=" + mHeight
+ " measuredHeight=" + host.getMeasuredHeight()
+ " coveredInsetsChanged=" + contentInsetsChanged);
// Ask host how big it wants to be
host.measure(childWidthMeasureSpec, childHeightMeasureSpec);
// Implementation of weights from WindowManager.LayoutParams
// We just grow the dimensions as needed and re-measure if
// needs be
int width = host.getMeasuredWidth();
int height = host.getMeasuredHeight();
boolean measureAgain = false;
if (lp.horizontalWeight > 0.0f) {
width += (int) ((mWidth - width) * lp.horizontalWeight);
childWidthMeasureSpec = MeasureSpec.makeMeasureSpec(width,
MeasureSpec.EXACTLY);
measureAgain = true;
}
if (lp.verticalWeight > 0.0f) {
height += (int) ((mHeight - height) * lp.verticalWeight);
childHeightMeasureSpec = MeasureSpec.makeMeasureSpec(height,
MeasureSpec.EXACTLY);
measureAgain = true;
}
if (measureAgain) {
if (DEBUG_LAYOUT) Log.v(TAG,
"And hey let's measure once more: width=" + width
+ " height=" + height);
host.measure(childWidthMeasureSpec, childHeightMeasureSpec);
}
mLayoutRequested = true;
}
}
}
final boolean didLayout = mLayoutRequested && !mStopped;
boolean triggerGlobalLayoutListener = didLayout
|| attachInfo.mRecomputeGlobalAttributes;
if (didLayout) {
mLayoutRequested = false;
mScrollMayChange = true;
if (DEBUG_ORIENTATION || DEBUG_LAYOUT) Log.v(
TAG, "Laying out " + host + " to (" +
host.getMeasuredWidth() + ", " + host.getMeasuredHeight() + ")");
long startTime = 0L;
if (ViewDebug.DEBUG_PROFILE_LAYOUT) {
startTime = SystemClock.elapsedRealtime();
}
host.layout(0, 0, host.getMeasuredWidth(), host.getMeasuredHeight());
if (false && ViewDebug.consistencyCheckEnabled) {
if (!host.dispatchConsistencyCheck(ViewDebug.CONSISTENCY_LAYOUT)) {
throw new IllegalStateException("The view hierarchy is an inconsistent state,"
+ "please refer to the logs with the tag "
+ ViewDebug.CONSISTENCY_LOG_TAG + " for more infomation.");
}
}
if (ViewDebug.DEBUG_PROFILE_LAYOUT) {
EventLog.writeEvent(60001, SystemClock.elapsedRealtime() - startTime);
}
// By this point all views have been sized and positionned
// We can compute the transparent area
if ((host.mPrivateFlags & View.REQUEST_TRANSPARENT_REGIONS) != 0) {
// start out transparent
// TODO: AVOID THAT CALL BY CACHING THE RESULT?
host.getLocationInWindow(mTmpLocation);
mTransparentRegion.set(mTmpLocation[0], mTmpLocation[1],
mTmpLocation[0] + host.mRight - host.mLeft,
mTmpLocation[1] + host.mBottom - host.mTop);
host.gatherTransparentRegion(mTransparentRegion);
if (mTranslator != null) {
mTranslator.translateRegionInWindowToScreen(mTransparentRegion);
}
if (!mTransparentRegion.equals(mPreviousTransparentRegion)) {
mPreviousTransparentRegion.set(mTransparentRegion);
// reconfigure window manager
try {
sWindowSession.setTransparentRegion(mWindow, mTransparentRegion);
} catch (RemoteException e) {
}
}
}
if (DBG) {
System.out.println("======================================");
System.out.println("performTraversals -- after setFrame");
host.debug();
}
}
if (triggerGlobalLayoutListener) {
attachInfo.mRecomputeGlobalAttributes = false;
attachInfo.mTreeObserver.dispatchOnGlobalLayout();
if (AccessibilityManager.getInstance(host.mContext).isEnabled()) {
postSendWindowContentChangedCallback();
}
}
if (computesInternalInsets) {
// Clear the original insets.
final ViewTreeObserver.InternalInsetsInfo insets = attachInfo.mGivenInternalInsets;
insets.reset();
// Compute new insets in place.
attachInfo.mTreeObserver.dispatchOnComputeInternalInsets(insets);
// Tell the window manager.
if (insetsPending || !mLastGivenInsets.equals(insets)) {
mLastGivenInsets.set(insets);
// Translate insets to screen coordinates if needed.
final Rect contentInsets;
final Rect visibleInsets;
final Region touchableRegion;
if (mTranslator != null) {
contentInsets = mTranslator.getTranslatedContentInsets(insets.contentInsets);
visibleInsets = mTranslator.getTranslatedVisibleInsets(insets.visibleInsets);
touchableRegion = mTranslator.getTranslatedTouchableArea(insets.touchableRegion);
} else {
contentInsets = insets.contentInsets;
visibleInsets = insets.visibleInsets;
touchableRegion = insets.touchableRegion;
}
try {
sWindowSession.setInsets(mWindow, insets.mTouchableInsets,
contentInsets, visibleInsets, touchableRegion);
} catch (RemoteException e) {
}
}
}
if (mFirst) {
// handle first focus request
if (DEBUG_INPUT_RESIZE) Log.v(TAG, "First: mView.hasFocus()="
+ mView.hasFocus());
if (mView != null) {
if (!mView.hasFocus()) {
mView.requestFocus(View.FOCUS_FORWARD);
mFocusedView = mRealFocusedView = mView.findFocus();
if (DEBUG_INPUT_RESIZE) Log.v(TAG, "First: requested focused view="
+ mFocusedView);
} else {
mRealFocusedView = mView.findFocus();
if (DEBUG_INPUT_RESIZE) Log.v(TAG, "First: existing focused view="
+ mRealFocusedView);
}
}
}
mFirst = false;
mWillDrawSoon = false;
mNewSurfaceNeeded = false;
mViewVisibility = viewVisibility;
if (mAttachInfo.mHasWindowFocus) {
final boolean imTarget = WindowManager.LayoutParams
.mayUseInputMethod(mWindowAttributes.flags);
if (imTarget != mLastWasImTarget) {
mLastWasImTarget = imTarget;
InputMethodManager imm = InputMethodManager.peekInstance();
if (imm != null && imTarget) {
imm.startGettingWindowFocus(mView);
imm.onWindowFocus(mView, mView.findFocus(),
mWindowAttributes.softInputMode,
!mHasHadWindowFocus, mWindowAttributes.flags);
}
}
}
boolean cancelDraw = attachInfo.mTreeObserver.dispatchOnPreDraw() ||
viewVisibility != View.VISIBLE;
if (!cancelDraw && !newSurface) {
if (mPendingTransitions != null && mPendingTransitions.size() > 0) {
for (int i = 0; i < mPendingTransitions.size(); ++i) {
mPendingTransitions.get(i).startChangingAnimations();
}
mPendingTransitions.clear();
}
mFullRedrawNeeded = false;
final long drawStartTime;
if (ViewDebug.DEBUG_LATENCY) {
drawStartTime = System.nanoTime();
}
draw(fullRedrawNeeded);
if (ViewDebug.DEBUG_LATENCY) {
mLastDrawDurationNanos = System.nanoTime() - drawStartTime;
}
if ((relayoutResult&WindowManagerImpl.RELAYOUT_RES_FIRST_TIME) != 0
|| mReportNextDraw) {
if (LOCAL_LOGV) {
Log.v(TAG, "FINISHED DRAWING: " + mWindowAttributes.getTitle());
}
mReportNextDraw = false;
if (mSurfaceHolder != null && mSurface.isValid()) {
mSurfaceHolderCallback.surfaceRedrawNeeded(mSurfaceHolder);
SurfaceHolder.Callback callbacks[] = mSurfaceHolder.getCallbacks();
if (callbacks != null) {
for (SurfaceHolder.Callback c : callbacks) {
if (c instanceof SurfaceHolder.Callback2) {
((SurfaceHolder.Callback2)c).surfaceRedrawNeeded(
mSurfaceHolder);
}
}
}
}
try {
sWindowSession.finishDrawing(mWindow);
} catch (RemoteException e) {
}
}
} else {
// End any pending transitions on this non-visible window
if (mPendingTransitions != null && mPendingTransitions.size() > 0) {
for (int i = 0; i < mPendingTransitions.size(); ++i) {
mPendingTransitions.get(i).endChangingAnimations();
}
mPendingTransitions.clear();
}
// We were supposed to report when we are done drawing. Since we canceled the
// draw, remember it here.
if ((relayoutResult&WindowManagerImpl.RELAYOUT_RES_FIRST_TIME) != 0) {
mReportNextDraw = true;
}
if (fullRedrawNeeded) {
mFullRedrawNeeded = true;
}
if (viewVisibility == View.VISIBLE) {
// Try again
scheduleTraversals();
}
}
}
public void requestTransparentRegion(View child) {
// the test below should not fail unless someone is messing with us
checkThread();
if (mView == child) {
mView.mPrivateFlags |= View.REQUEST_TRANSPARENT_REGIONS;
// Need to make sure we re-evaluate the window attributes next
// time around, to ensure the window has the correct format.
mWindowAttributesChanged = true;
mWindowAttributesChangesFlag = 0;
requestLayout();
}
}
/**
* Figures out the measure spec for the root view in a window based on it's
* layout params.
*
* @param windowSize
* The available width or height of the window
*
* @param rootDimension
* The layout params for one dimension (width or height) of the
* window.
*
* @return The measure spec to use to measure the root view.
*/
private int getRootMeasureSpec(int windowSize, int rootDimension) {
int measureSpec;
switch (rootDimension) {
case ViewGroup.LayoutParams.MATCH_PARENT:
// Window can't resize. Force root view to be windowSize.
measureSpec = MeasureSpec.makeMeasureSpec(windowSize, MeasureSpec.EXACTLY);
break;
case ViewGroup.LayoutParams.WRAP_CONTENT:
// Window can resize. Set max size for root view.
measureSpec = MeasureSpec.makeMeasureSpec(windowSize, MeasureSpec.AT_MOST);
break;
default:
// Window wants to be an exact size. Force root view to be that size.
measureSpec = MeasureSpec.makeMeasureSpec(rootDimension, MeasureSpec.EXACTLY);
break;
}
return measureSpec;
}
int mHardwareYOffset;
int mResizeAlpha;
final Paint mResizePaint = new Paint();
public void onHardwarePreDraw(HardwareCanvas canvas) {
canvas.translate(0, -mHardwareYOffset);
}
public void onHardwarePostDraw(HardwareCanvas canvas) {
if (mResizeBuffer != null) {
mResizePaint.setAlpha(mResizeAlpha);
canvas.drawHardwareLayer(mResizeBuffer, 0.0f, mHardwareYOffset, mResizePaint);
}
}
/**
* @hide
*/
void outputDisplayList(View view) {
if (mAttachInfo != null && mAttachInfo.mHardwareCanvas != null) {
DisplayList displayList = view.getDisplayList();
if (displayList != null) {
mAttachInfo.mHardwareCanvas.outputDisplayList(displayList);
}
}
}
/**
* @see #PROPERTY_PROFILE_RENDERING
*/
private void profileRendering(boolean enabled) {
if (mProfileRendering) {
mRenderProfilingEnabled = enabled;
if (mRenderProfiler == null) {
mRenderProfiler = new Thread(new Runnable() {
@Override
public void run() {
Log.d(TAG, "Starting profiling thread");
while (mRenderProfilingEnabled) {
mAttachInfo.mHandler.post(new Runnable() {
@Override
public void run() {
mDirty.set(0, 0, mWidth, mHeight);
scheduleTraversals();
}
});
try {
// TODO: This should use vsync when we get an API
Thread.sleep(15);
} catch (InterruptedException e) {
Log.d(TAG, "Exiting profiling thread");
}
}
}
}, "Rendering Profiler");
mRenderProfiler.start();
} else {
mRenderProfiler.interrupt();
mRenderProfiler = null;
}
}
}
/**
* Called from draw() when DEBUG_FPS is enabled
*/
private void trackFPS() {
// Tracks frames per second drawn. First value in a series of draws may be bogus
// because it down not account for the intervening idle time
long nowTime = System.currentTimeMillis();
if (mFpsStartTime < 0) {
mFpsStartTime = mFpsPrevTime = nowTime;
mFpsNumFrames = 0;
} else {
++mFpsNumFrames;
String thisHash = Integer.toHexString(System.identityHashCode(this));
long frameTime = nowTime - mFpsPrevTime;
long totalTime = nowTime - mFpsStartTime;
Log.v(TAG, "0x" + thisHash + "\tFrame time:\t" + frameTime);
mFpsPrevTime = nowTime;
if (totalTime > 1000) {
float fps = (float) mFpsNumFrames * 1000 / totalTime;
Log.v(TAG, "0x" + thisHash + "\tFPS:\t" + fps);
mFpsStartTime = nowTime;
mFpsNumFrames = 0;
}
}
}
private void draw(boolean fullRedrawNeeded) {
Surface surface = mSurface;
if (surface == null || !surface.isValid()) {
return;
}
if (DEBUG_FPS) {
trackFPS();
}
if (!sFirstDrawComplete) {
synchronized (sFirstDrawHandlers) {
sFirstDrawComplete = true;
final int count = sFirstDrawHandlers.size();
for (int i = 0; i< count; i++) {
post(sFirstDrawHandlers.get(i));
}
}
}
scrollToRectOrFocus(null, false);
if (mAttachInfo.mViewScrollChanged) {
mAttachInfo.mViewScrollChanged = false;
mAttachInfo.mTreeObserver.dispatchOnScrollChanged();
}
int yoff;
boolean animating = mScroller != null && mScroller.computeScrollOffset();
if (animating) {
yoff = mScroller.getCurrY();
} else {
yoff = mScrollY;
}
if (mCurScrollY != yoff) {
mCurScrollY = yoff;
fullRedrawNeeded = true;
}
float appScale = mAttachInfo.mApplicationScale;
boolean scalingRequired = mAttachInfo.mScalingRequired;
int resizeAlpha = 0;
if (mResizeBuffer != null) {
long deltaTime = SystemClock.uptimeMillis() - mResizeBufferStartTime;
if (deltaTime < mResizeBufferDuration) {
float amt = deltaTime/(float) mResizeBufferDuration;
amt = mResizeInterpolator.getInterpolation(amt);
animating = true;
resizeAlpha = 255 - (int)(amt*255);
} else {
disposeResizeBuffer();
}
}
Rect dirty = mDirty;
if (mSurfaceHolder != null) {
// The app owns the surface, we won't draw.
dirty.setEmpty();
if (animating) {
if (mScroller != null) {
mScroller.abortAnimation();
}
disposeResizeBuffer();
}
return;
}
if (fullRedrawNeeded) {
mAttachInfo.mIgnoreDirtyState = true;
dirty.set(0, 0, (int) (mWidth * appScale + 0.5f), (int) (mHeight * appScale + 0.5f));
}
if (mAttachInfo.mHardwareRenderer != null && mAttachInfo.mHardwareRenderer.isEnabled()) {
if (!dirty.isEmpty() || mIsAnimating) {
mIsAnimating = false;
mHardwareYOffset = yoff;
mResizeAlpha = resizeAlpha;
mCurrentDirty.set(dirty);
mCurrentDirty.union(mPreviousDirty);
mPreviousDirty.set(dirty);
dirty.setEmpty();
Rect currentDirty = mCurrentDirty;
if (animating) {
currentDirty = null;
}
if (mAttachInfo.mHardwareRenderer.draw(mView, mAttachInfo, this, currentDirty)) {
mPreviousDirty.set(0, 0, mWidth, mHeight);
}
}
if (animating) {
mFullRedrawNeeded = true;
scheduleTraversals();
}
return;
}
if (DEBUG_ORIENTATION || DEBUG_DRAW) {
Log.v(TAG, "Draw " + mView + "/"
+ mWindowAttributes.getTitle()
+ ": dirty={" + dirty.left + "," + dirty.top
+ "," + dirty.right + "," + dirty.bottom + "} surface="
+ surface + " surface.isValid()=" + surface.isValid() + ", appScale:" +
appScale + ", width=" + mWidth + ", height=" + mHeight);
}
if (!dirty.isEmpty() || mIsAnimating) {
Canvas canvas;
try {
int left = dirty.left;
int top = dirty.top;
int right = dirty.right;
int bottom = dirty.bottom;
final long lockCanvasStartTime;
if (ViewDebug.DEBUG_LATENCY) {
lockCanvasStartTime = System.nanoTime();
}
canvas = surface.lockCanvas(dirty);
if (ViewDebug.DEBUG_LATENCY) {
long now = System.nanoTime();
Log.d(TAG, "Latency: Spent "
+ ((now - lockCanvasStartTime) * 0.000001f)
+ "ms waiting for surface.lockCanvas()");
}
if (left != dirty.left || top != dirty.top || right != dirty.right ||
bottom != dirty.bottom) {
mAttachInfo.mIgnoreDirtyState = true;
}
// TODO: Do this in native
canvas.setDensity(mDensity);
} catch (Surface.OutOfResourcesException e) {
Log.e(TAG, "OutOfResourcesException locking surface", e);
try {
if (!sWindowSession.outOfMemory(mWindow)) {
Slog.w(TAG, "No processes killed for memory; killing self");
Process.killProcess(Process.myPid());
}
} catch (RemoteException ex) {
}
mLayoutRequested = true; // ask wm for a new surface next time.
return;
} catch (IllegalArgumentException e) {
Log.e(TAG, "IllegalArgumentException locking surface", e);
// Don't assume this is due to out of memory, it could be
// something else, and if it is something else then we could
// kill stuff (or ourself) for no reason.
mLayoutRequested = true; // ask wm for a new surface next time.
return;
}
try {
if (!dirty.isEmpty() || mIsAnimating) {
long startTime = 0L;
if (DEBUG_ORIENTATION || DEBUG_DRAW) {
Log.v(TAG, "Surface " + surface + " drawing to bitmap w="
+ canvas.getWidth() + ", h=" + canvas.getHeight());
//canvas.drawARGB(255, 255, 0, 0);
}
if (ViewDebug.DEBUG_PROFILE_DRAWING) {
startTime = SystemClock.elapsedRealtime();
}
// If this bitmap's format includes an alpha channel, we
// need to clear it before drawing so that the child will
// properly re-composite its drawing on a transparent
// background. This automatically respects the clip/dirty region
// or
// If we are applying an offset, we need to clear the area
// where the offset doesn't appear to avoid having garbage
// left in the blank areas.
if (!canvas.isOpaque() || yoff != 0) {
canvas.drawColor(0, PorterDuff.Mode.CLEAR);
}
dirty.setEmpty();
mIsAnimating = false;
mAttachInfo.mDrawingTime = SystemClock.uptimeMillis();
mView.mPrivateFlags |= View.DRAWN;
if (DEBUG_DRAW) {
Context cxt = mView.getContext();
Log.i(TAG, "Drawing: package:" + cxt.getPackageName() +
", metrics=" + cxt.getResources().getDisplayMetrics() +
", compatibilityInfo=" + cxt.getResources().getCompatibilityInfo());
}
try {
canvas.translate(0, -yoff);
if (mTranslator != null) {
mTranslator.translateCanvas(canvas);
}
canvas.setScreenDensity(scalingRequired
? DisplayMetrics.DENSITY_DEVICE : 0);
mAttachInfo.mSetIgnoreDirtyState = false;
mView.draw(canvas);
} finally {
if (!mAttachInfo.mSetIgnoreDirtyState) {
// Only clear the flag if it was not set during the mView.draw() call
mAttachInfo.mIgnoreDirtyState = false;
}
}
if (false && ViewDebug.consistencyCheckEnabled) {
mView.dispatchConsistencyCheck(ViewDebug.CONSISTENCY_DRAWING);
}
if (ViewDebug.DEBUG_PROFILE_DRAWING) {
EventLog.writeEvent(60000, SystemClock.elapsedRealtime() - startTime);
}
}
} finally {
surface.unlockCanvasAndPost(canvas);
}
}
if (LOCAL_LOGV) {
Log.v(TAG, "Surface " + surface + " unlockCanvasAndPost");
}
if (animating) {
mFullRedrawNeeded = true;
scheduleTraversals();
}
}
boolean scrollToRectOrFocus(Rect rectangle, boolean immediate) {
final View.AttachInfo attachInfo = mAttachInfo;
final Rect ci = attachInfo.mContentInsets;
final Rect vi = attachInfo.mVisibleInsets;
int scrollY = 0;
boolean handled = false;
if (vi.left > ci.left || vi.top > ci.top
|| vi.right > ci.right || vi.bottom > ci.bottom) {
// We'll assume that we aren't going to change the scroll
// offset, since we want to avoid that unless it is actually
// going to make the focus visible... otherwise we scroll
// all over the place.
scrollY = mScrollY;
// We can be called for two different situations: during a draw,
// to update the scroll position if the focus has changed (in which
// case 'rectangle' is null), or in response to a
// requestChildRectangleOnScreen() call (in which case 'rectangle'
// is non-null and we just want to scroll to whatever that
// rectangle is).
View focus = mRealFocusedView;
// When in touch mode, focus points to the previously focused view,
// which may have been removed from the view hierarchy. The following
// line checks whether the view is still in our hierarchy.
if (focus == null || focus.mAttachInfo != mAttachInfo) {
mRealFocusedView = null;
return false;
}
if (focus != mLastScrolledFocus) {
// If the focus has changed, then ignore any requests to scroll
// to a rectangle; first we want to make sure the entire focus
// view is visible.
rectangle = null;
}
if (DEBUG_INPUT_RESIZE) Log.v(TAG, "Eval scroll: focus=" + focus
+ " rectangle=" + rectangle + " ci=" + ci
+ " vi=" + vi);
if (focus == mLastScrolledFocus && !mScrollMayChange
&& rectangle == null) {
// Optimization: if the focus hasn't changed since last
// time, and no layout has happened, then just leave things
// as they are.
if (DEBUG_INPUT_RESIZE) Log.v(TAG, "Keeping scroll y="
+ mScrollY + " vi=" + vi.toShortString());
} else if (focus != null) {
// We need to determine if the currently focused view is
// within the visible part of the window and, if not, apply
// a pan so it can be seen.
mLastScrolledFocus = focus;
mScrollMayChange = false;
if (DEBUG_INPUT_RESIZE) Log.v(TAG, "Need to scroll?");
// Try to find the rectangle from the focus view.
if (focus.getGlobalVisibleRect(mVisRect, null)) {
if (DEBUG_INPUT_RESIZE) Log.v(TAG, "Root w="
+ mView.getWidth() + " h=" + mView.getHeight()
+ " ci=" + ci.toShortString()
+ " vi=" + vi.toShortString());
if (rectangle == null) {
focus.getFocusedRect(mTempRect);
if (DEBUG_INPUT_RESIZE) Log.v(TAG, "Focus " + focus
+ ": focusRect=" + mTempRect.toShortString());
if (mView instanceof ViewGroup) {
((ViewGroup) mView).offsetDescendantRectToMyCoords(
focus, mTempRect);
}
if (DEBUG_INPUT_RESIZE) Log.v(TAG,
"Focus in window: focusRect="
+ mTempRect.toShortString()
+ " visRect=" + mVisRect.toShortString());
} else {
mTempRect.set(rectangle);
if (DEBUG_INPUT_RESIZE) Log.v(TAG,
"Request scroll to rect: "
+ mTempRect.toShortString()
+ " visRect=" + mVisRect.toShortString());
}
if (mTempRect.intersect(mVisRect)) {
if (DEBUG_INPUT_RESIZE) Log.v(TAG,
"Focus window visible rect: "
+ mTempRect.toShortString());
if (mTempRect.height() >
(mView.getHeight()-vi.top-vi.bottom)) {
// If the focus simply is not going to fit, then
// best is probably just to leave things as-is.
if (DEBUG_INPUT_RESIZE) Log.v(TAG,
"Too tall; leaving scrollY=" + scrollY);
} else if ((mTempRect.top-scrollY) < vi.top) {
scrollY -= vi.top - (mTempRect.top-scrollY);
if (DEBUG_INPUT_RESIZE) Log.v(TAG,
"Top covered; scrollY=" + scrollY);
} else if ((mTempRect.bottom-scrollY)
> (mView.getHeight()-vi.bottom)) {
scrollY += (mTempRect.bottom-scrollY)
- (mView.getHeight()-vi.bottom);
if (DEBUG_INPUT_RESIZE) Log.v(TAG,
"Bottom covered; scrollY=" + scrollY);
}
handled = true;
}
}
}
}
if (scrollY != mScrollY) {
if (DEBUG_INPUT_RESIZE) Log.v(TAG, "Pan scroll changed: old="
+ mScrollY + " , new=" + scrollY);
if (!immediate && mResizeBuffer == null) {
if (mScroller == null) {
mScroller = new Scroller(mView.getContext());
}
mScroller.startScroll(0, mScrollY, 0, scrollY-mScrollY);
} else if (mScroller != null) {
mScroller.abortAnimation();
}
mScrollY = scrollY;
}
return handled;
}
public void requestChildFocus(View child, View focused) {
checkThread();
if (mFocusedView != focused) {
mAttachInfo.mTreeObserver.dispatchOnGlobalFocusChange(mFocusedView, focused);
scheduleTraversals();
}
mFocusedView = mRealFocusedView = focused;
if (DEBUG_INPUT_RESIZE) Log.v(TAG, "Request child focus: focus now "
+ mFocusedView);
}
public void clearChildFocus(View child) {
checkThread();
View oldFocus = mFocusedView;
if (DEBUG_INPUT_RESIZE) Log.v(TAG, "Clearing child focus");
mFocusedView = mRealFocusedView = null;
if (mView != null && !mView.hasFocus()) {
// If a view gets the focus, the listener will be invoked from requestChildFocus()
if (!mView.requestFocus(View.FOCUS_FORWARD)) {
mAttachInfo.mTreeObserver.dispatchOnGlobalFocusChange(oldFocus, null);
}
} else if (oldFocus != null) {
mAttachInfo.mTreeObserver.dispatchOnGlobalFocusChange(oldFocus, null);
}
}
public void focusableViewAvailable(View v) {
checkThread();
if (mView != null) {
if (!mView.hasFocus()) {
v.requestFocus();
} else {
// the one case where will transfer focus away from the current one
// is if the current view is a view group that prefers to give focus
// to its children first AND the view is a descendant of it.
mFocusedView = mView.findFocus();
boolean descendantsHaveDibsOnFocus =
(mFocusedView instanceof ViewGroup) &&
(((ViewGroup) mFocusedView).getDescendantFocusability() ==
ViewGroup.FOCUS_AFTER_DESCENDANTS);
if (descendantsHaveDibsOnFocus && isViewDescendantOf(v, mFocusedView)) {
// If a view gets the focus, the listener will be invoked from requestChildFocus()
v.requestFocus();
}
}
}
}
public void recomputeViewAttributes(View child) {
checkThread();
if (mView == child) {
mAttachInfo.mRecomputeGlobalAttributes = true;
if (!mWillDrawSoon) {
scheduleTraversals();
}
}
}
void dispatchDetachedFromWindow() {
if (mView != null && mView.mAttachInfo != null) {
if (mAttachInfo.mHardwareRenderer != null &&
mAttachInfo.mHardwareRenderer.isEnabled()) {
mAttachInfo.mHardwareRenderer.validate();
}
mView.dispatchDetachedFromWindow();
}
mAccessibilityInteractionConnectionManager.ensureNoConnection();
mAccessibilityManager.removeAccessibilityStateChangeListener(
mAccessibilityInteractionConnectionManager);
removeSendWindowContentChangedCallback();
mView = null;
mAttachInfo.mRootView = null;
mAttachInfo.mSurface = null;
destroyHardwareRenderer();
mSurface.release();
if (mInputQueueCallback != null && mInputQueue != null) {
mInputQueueCallback.onInputQueueDestroyed(mInputQueue);
mInputQueueCallback = null;
mInputQueue = null;
} else if (mInputChannel != null) {
InputQueue.unregisterInputChannel(mInputChannel);
}
try {
sWindowSession.remove(mWindow);
} catch (RemoteException e) {
}
// Dispose the input channel after removing the window so the Window Manager
// doesn't interpret the input channel being closed as an abnormal termination.
if (mInputChannel != null) {
mInputChannel.dispose();
mInputChannel = null;
}
}
void updateConfiguration(Configuration config, boolean force) {
if (DEBUG_CONFIGURATION) Log.v(TAG,
"Applying new config to window "
+ mWindowAttributes.getTitle()
+ ": " + config);
CompatibilityInfo ci = mCompatibilityInfo.getIfNeeded();
if (ci != null) {
config = new Configuration(config);
ci.applyToConfiguration(config);
}
synchronized (sConfigCallbacks) {
for (int i=sConfigCallbacks.size()-1; i>=0; i--) {
sConfigCallbacks.get(i).onConfigurationChanged(config);
}
}
if (mView != null) {
// At this point the resources have been updated to
// have the most recent config, whatever that is. Use
// the on in them which may be newer.
config = mView.getResources().getConfiguration();
if (force || mLastConfiguration.diff(config) != 0) {
mLastConfiguration.setTo(config);
mView.dispatchConfigurationChanged(config);
}
}
}
/**
* Return true if child is an ancestor of parent, (or equal to the parent).
*/
private static boolean isViewDescendantOf(View child, View parent) {
if (child == parent) {
return true;
}
final ViewParent theParent = child.getParent();
return (theParent instanceof ViewGroup) && isViewDescendantOf((View) theParent, parent);
}
private static void forceLayout(View view) {
view.forceLayout();
if (view instanceof ViewGroup) {
ViewGroup group = (ViewGroup) view;
final int count = group.getChildCount();
for (int i = 0; i < count; i++) {
forceLayout(group.getChildAt(i));
}
}
}
public final static int DO_TRAVERSAL = 1000;
public final static int DIE = 1001;
public final static int RESIZED = 1002;
public final static int RESIZED_REPORT = 1003;
public final static int WINDOW_FOCUS_CHANGED = 1004;
public final static int DISPATCH_KEY = 1005;
public final static int DISPATCH_POINTER = 1006;
public final static int DISPATCH_TRACKBALL = 1007;
public final static int DISPATCH_APP_VISIBILITY = 1008;
public final static int DISPATCH_GET_NEW_SURFACE = 1009;
public final static int FINISHED_EVENT = 1010;
public final static int DISPATCH_KEY_FROM_IME = 1011;
public final static int FINISH_INPUT_CONNECTION = 1012;
public final static int CHECK_FOCUS = 1013;
public final static int CLOSE_SYSTEM_DIALOGS = 1014;
public final static int DISPATCH_DRAG_EVENT = 1015;
public final static int DISPATCH_DRAG_LOCATION_EVENT = 1016;
public final static int DISPATCH_SYSTEM_UI_VISIBILITY = 1017;
public final static int DISPATCH_GENERIC_MOTION = 1018;
public final static int UPDATE_CONFIGURATION = 1019;
public final static int DO_PERFORM_ACCESSIBILITY_ACTION = 1020;
public final static int DO_FIND_ACCESSIBLITY_NODE_INFO_BY_ACCESSIBILITY_ID = 1021;
public final static int DO_FIND_ACCESSIBLITY_NODE_INFO_BY_VIEW_ID = 1022;
public final static int DO_FIND_ACCESSIBLITY_NODE_INFO_BY_VIEW_TEXT = 1023;
public final static int PROCESS_INPUT_EVENTS = 1024;
@Override
public String getMessageName(Message message) {
switch (message.what) {
case DO_TRAVERSAL:
return "DO_TRAVERSAL";
case DIE:
return "DIE";
case RESIZED:
return "RESIZED";
case RESIZED_REPORT:
return "RESIZED_REPORT";
case WINDOW_FOCUS_CHANGED:
return "WINDOW_FOCUS_CHANGED";
case DISPATCH_KEY:
return "DISPATCH_KEY";
case DISPATCH_POINTER:
return "DISPATCH_POINTER";
case DISPATCH_TRACKBALL:
return "DISPATCH_TRACKBALL";
case DISPATCH_APP_VISIBILITY:
return "DISPATCH_APP_VISIBILITY";
case DISPATCH_GET_NEW_SURFACE:
return "DISPATCH_GET_NEW_SURFACE";
case FINISHED_EVENT:
return "FINISHED_EVENT";
case DISPATCH_KEY_FROM_IME:
return "DISPATCH_KEY_FROM_IME";
case FINISH_INPUT_CONNECTION:
return "FINISH_INPUT_CONNECTION";
case CHECK_FOCUS:
return "CHECK_FOCUS";
case CLOSE_SYSTEM_DIALOGS:
return "CLOSE_SYSTEM_DIALOGS";
case DISPATCH_DRAG_EVENT:
return "DISPATCH_DRAG_EVENT";
case DISPATCH_DRAG_LOCATION_EVENT:
return "DISPATCH_DRAG_LOCATION_EVENT";
case DISPATCH_SYSTEM_UI_VISIBILITY:
return "DISPATCH_SYSTEM_UI_VISIBILITY";
case DISPATCH_GENERIC_MOTION:
return "DISPATCH_GENERIC_MOTION";
case UPDATE_CONFIGURATION:
return "UPDATE_CONFIGURATION";
case DO_PERFORM_ACCESSIBILITY_ACTION:
return "DO_PERFORM_ACCESSIBILITY_ACTION";
case DO_FIND_ACCESSIBLITY_NODE_INFO_BY_ACCESSIBILITY_ID:
return "DO_FIND_ACCESSIBLITY_NODE_INFO_BY_ACCESSIBILITY_ID";
case DO_FIND_ACCESSIBLITY_NODE_INFO_BY_VIEW_ID:
return "DO_FIND_ACCESSIBLITY_NODE_INFO_BY_VIEW_ID";
case DO_FIND_ACCESSIBLITY_NODE_INFO_BY_VIEW_TEXT:
return "DO_FIND_ACCESSIBLITY_NODE_INFO_BY_VIEW_TEXT";
case PROCESS_INPUT_EVENTS:
return "PROCESS_INPUT_EVENTS";
}
return super.getMessageName(message);
}
@Override
public void handleMessage(Message msg) {
switch (msg.what) {
case View.AttachInfo.INVALIDATE_MSG:
((View) msg.obj).invalidate();
break;
case View.AttachInfo.INVALIDATE_RECT_MSG:
final View.AttachInfo.InvalidateInfo info = (View.AttachInfo.InvalidateInfo) msg.obj;
info.target.invalidate(info.left, info.top, info.right, info.bottom);
info.release();
break;
case DO_TRAVERSAL:
if (mProfile) {
Debug.startMethodTracing("ViewAncestor");
}
final long traversalStartTime;
if (ViewDebug.DEBUG_LATENCY) {
traversalStartTime = System.nanoTime();
mLastDrawDurationNanos = 0;
}
performTraversals();
if (ViewDebug.DEBUG_LATENCY) {
long now = System.nanoTime();
Log.d(TAG, "Latency: Spent "
+ ((now - traversalStartTime) * 0.000001f)
+ "ms in performTraversals(), with "
+ (mLastDrawDurationNanos * 0.000001f)
+ "ms of that time in draw()");
mLastTraversalFinishedTimeNanos = now;
}
if (mProfile) {
Debug.stopMethodTracing();
mProfile = false;
}
break;
case FINISHED_EVENT:
handleFinishedEvent(msg.arg1, msg.arg2 != 0);
break;
case DISPATCH_KEY:
deliverKeyEvent((KeyEvent)msg.obj, msg.arg1 != 0);
break;
case DISPATCH_POINTER:
deliverPointerEvent((MotionEvent) msg.obj, msg.arg1 != 0);
break;
case DISPATCH_TRACKBALL:
deliverTrackballEvent((MotionEvent) msg.obj, msg.arg1 != 0);
break;
case DISPATCH_GENERIC_MOTION:
deliverGenericMotionEvent((MotionEvent) msg.obj, msg.arg1 != 0);
break;
case PROCESS_INPUT_EVENTS:
processInputEvents(false);
break;
case DISPATCH_APP_VISIBILITY:
handleAppVisibility(msg.arg1 != 0);
break;
case DISPATCH_GET_NEW_SURFACE:
handleGetNewSurface();
break;
case RESIZED:
ResizedInfo ri = (ResizedInfo)msg.obj;
if (mWinFrame.width() == msg.arg1 && mWinFrame.height() == msg.arg2
&& mPendingContentInsets.equals(ri.coveredInsets)
&& mPendingVisibleInsets.equals(ri.visibleInsets)
&& ((ResizedInfo)msg.obj).newConfig == null) {
break;
}
// fall through...
case RESIZED_REPORT:
if (mAdded) {
Configuration config = ((ResizedInfo)msg.obj).newConfig;
if (config != null) {
updateConfiguration(config, false);
}
mWinFrame.left = 0;
mWinFrame.right = msg.arg1;
mWinFrame.top = 0;
mWinFrame.bottom = msg.arg2;
mPendingContentInsets.set(((ResizedInfo)msg.obj).coveredInsets);
mPendingVisibleInsets.set(((ResizedInfo)msg.obj).visibleInsets);
if (msg.what == RESIZED_REPORT) {
mReportNextDraw = true;
}
if (mView != null) {
forceLayout(mView);
}
requestLayout();
}
break;
case WINDOW_FOCUS_CHANGED: {
if (mAdded) {
boolean hasWindowFocus = msg.arg1 != 0;
mAttachInfo.mHasWindowFocus = hasWindowFocus;
profileRendering(hasWindowFocus);
if (hasWindowFocus) {
boolean inTouchMode = msg.arg2 != 0;
ensureTouchModeLocally(inTouchMode);
if (mAttachInfo.mHardwareRenderer != null &&
mSurface != null && mSurface.isValid()) {
mFullRedrawNeeded = true;
try {
mAttachInfo.mHardwareRenderer.initializeIfNeeded(mWidth, mHeight,
mAttachInfo, mHolder);
} catch (Surface.OutOfResourcesException e) {
Log.e(TAG, "OutOfResourcesException locking surface", e);
try {
if (!sWindowSession.outOfMemory(mWindow)) {
Slog.w(TAG, "No processes killed for memory; killing self");
Process.killProcess(Process.myPid());
}
} catch (RemoteException ex) {
}
// Retry in a bit.
sendMessageDelayed(obtainMessage(msg.what, msg.arg1, msg.arg2), 500);
return;
}
}
}
mLastWasImTarget = WindowManager.LayoutParams
.mayUseInputMethod(mWindowAttributes.flags);
InputMethodManager imm = InputMethodManager.peekInstance();
if (mView != null) {
if (hasWindowFocus && imm != null && mLastWasImTarget) {
imm.startGettingWindowFocus(mView);
}
mAttachInfo.mKeyDispatchState.reset();
mView.dispatchWindowFocusChanged(hasWindowFocus);
}
// Note: must be done after the focus change callbacks,
// so all of the view state is set up correctly.
if (hasWindowFocus) {
if (imm != null && mLastWasImTarget) {
imm.onWindowFocus(mView, mView.findFocus(),
mWindowAttributes.softInputMode,
!mHasHadWindowFocus, mWindowAttributes.flags);
}
// Clear the forward bit. We can just do this directly, since
// the window manager doesn't care about it.
mWindowAttributes.softInputMode &=
~WindowManager.LayoutParams.SOFT_INPUT_IS_FORWARD_NAVIGATION;
((WindowManager.LayoutParams)mView.getLayoutParams())
.softInputMode &=
~WindowManager.LayoutParams.SOFT_INPUT_IS_FORWARD_NAVIGATION;
mHasHadWindowFocus = true;
}
if (hasWindowFocus && mView != null) {
sendAccessibilityEvents();
}
}
} break;
case DIE:
doDie();
break;
case DISPATCH_KEY_FROM_IME: {
if (LOCAL_LOGV) Log.v(
TAG, "Dispatching key "
+ msg.obj + " from IME to " + mView);
KeyEvent event = (KeyEvent)msg.obj;
if ((event.getFlags()&KeyEvent.FLAG_FROM_SYSTEM) != 0) {
// The IME is trying to say this event is from the
// system! Bad bad bad!
//noinspection UnusedAssignment
event = KeyEvent.changeFlags(event, event.getFlags() & ~KeyEvent.FLAG_FROM_SYSTEM);
}
deliverKeyEventPostIme((KeyEvent)msg.obj, false);
} break;
case FINISH_INPUT_CONNECTION: {
InputMethodManager imm = InputMethodManager.peekInstance();
if (imm != null) {
imm.reportFinishInputConnection((InputConnection)msg.obj);
}
} break;
case CHECK_FOCUS: {
InputMethodManager imm = InputMethodManager.peekInstance();
if (imm != null) {
imm.checkFocus();
}
} break;
case CLOSE_SYSTEM_DIALOGS: {
if (mView != null) {
mView.onCloseSystemDialogs((String)msg.obj);
}
} break;
case DISPATCH_DRAG_EVENT:
case DISPATCH_DRAG_LOCATION_EVENT: {
DragEvent event = (DragEvent)msg.obj;
event.mLocalState = mLocalDragState; // only present when this app called startDrag()
handleDragEvent(event);
} break;
case DISPATCH_SYSTEM_UI_VISIBILITY: {
handleDispatchSystemUiVisibilityChanged((SystemUiVisibilityInfo)msg.obj);
} break;
case UPDATE_CONFIGURATION: {
Configuration config = (Configuration)msg.obj;
if (config.isOtherSeqNewer(mLastConfiguration)) {
config = mLastConfiguration;
}
updateConfiguration(config, false);
} break;
case DO_FIND_ACCESSIBLITY_NODE_INFO_BY_ACCESSIBILITY_ID: {
if (mView != null) {
getAccessibilityInteractionController()
.findAccessibilityNodeInfoByAccessibilityIdUiThread(msg);
}
} break;
case DO_PERFORM_ACCESSIBILITY_ACTION: {
if (mView != null) {
getAccessibilityInteractionController()
.perfromAccessibilityActionUiThread(msg);
}
} break;
case DO_FIND_ACCESSIBLITY_NODE_INFO_BY_VIEW_ID: {
if (mView != null) {
getAccessibilityInteractionController()
.findAccessibilityNodeInfoByViewIdUiThread(msg);
}
} break;
case DO_FIND_ACCESSIBLITY_NODE_INFO_BY_VIEW_TEXT: {
if (mView != null) {
getAccessibilityInteractionController()
.findAccessibilityNodeInfosByViewTextUiThread(msg);
}
} break;
}
}
private void startInputEvent(InputQueue.FinishedCallback finishedCallback) {
if (mFinishedCallback != null) {
Slog.w(TAG, "Received a new input event from the input queue but there is "
+ "already an unfinished input event in progress.");
}
if (ViewDebug.DEBUG_LATENCY) {
mInputEventReceiveTimeNanos = System.nanoTime();
mInputEventDeliverTimeNanos = 0;
mInputEventDeliverPostImeTimeNanos = 0;
}
mFinishedCallback = finishedCallback;
}
private void finishInputEvent(InputEvent event, boolean handled) {
if (LOCAL_LOGV) Log.v(TAG, "Telling window manager input event is finished");
if (mFinishedCallback == null) {
Slog.w(TAG, "Attempted to tell the input queue that the current input event "
+ "is finished but there is no input event actually in progress.");
return;
}
if (ViewDebug.DEBUG_LATENCY) {
final long now = System.nanoTime();
final long eventTime = event.getEventTimeNano();
final StringBuilder msg = new StringBuilder();
msg.append("Latency: Spent ");
msg.append((now - mInputEventReceiveTimeNanos) * 0.000001f);
msg.append("ms processing ");
if (event instanceof KeyEvent) {
final KeyEvent keyEvent = (KeyEvent)event;
msg.append("key event, action=");
msg.append(KeyEvent.actionToString(keyEvent.getAction()));
} else {
final MotionEvent motionEvent = (MotionEvent)event;
msg.append("motion event, action=");
msg.append(MotionEvent.actionToString(motionEvent.getAction()));
msg.append(", historySize=");
msg.append(motionEvent.getHistorySize());
}
msg.append(", handled=");
msg.append(handled);
msg.append(", received at +");
msg.append((mInputEventReceiveTimeNanos - eventTime) * 0.000001f);
if (mInputEventDeliverTimeNanos != 0) {
msg.append("ms, delivered at +");
msg.append((mInputEventDeliverTimeNanos - eventTime) * 0.000001f);
}
if (mInputEventDeliverPostImeTimeNanos != 0) {
msg.append("ms, delivered post IME at +");
msg.append((mInputEventDeliverPostImeTimeNanos - eventTime) * 0.000001f);
}
msg.append("ms, finished at +");
msg.append((now - eventTime) * 0.000001f);
msg.append("ms.");
Log.d(TAG, msg.toString());
}
mFinishedCallback.finished(handled);
mFinishedCallback = null;
}
/**
* Something in the current window tells us we need to change the touch mode. For
* example, we are not in touch mode, and the user touches the screen.
*
* If the touch mode has changed, tell the window manager, and handle it locally.
*
* @param inTouchMode Whether we want to be in touch mode.
* @return True if the touch mode changed and focus changed was changed as a result
*/
boolean ensureTouchMode(boolean inTouchMode) {
if (DBG) Log.d("touchmode", "ensureTouchMode(" + inTouchMode + "), current "
+ "touch mode is " + mAttachInfo.mInTouchMode);
if (mAttachInfo.mInTouchMode == inTouchMode) return false;
// tell the window manager
try {
sWindowSession.setInTouchMode(inTouchMode);
} catch (RemoteException e) {
throw new RuntimeException(e);
}
// handle the change
return ensureTouchModeLocally(inTouchMode);
}
/**
* Ensure that the touch mode for this window is set, and if it is changing,
* take the appropriate action.
* @param inTouchMode Whether we want to be in touch mode.
* @return True if the touch mode changed and focus changed was changed as a result
*/
private boolean ensureTouchModeLocally(boolean inTouchMode) {
if (DBG) Log.d("touchmode", "ensureTouchModeLocally(" + inTouchMode + "), current "
+ "touch mode is " + mAttachInfo.mInTouchMode);
if (mAttachInfo.mInTouchMode == inTouchMode) return false;
mAttachInfo.mInTouchMode = inTouchMode;
mAttachInfo.mTreeObserver.dispatchOnTouchModeChanged(inTouchMode);
return (inTouchMode) ? enterTouchMode() : leaveTouchMode();
}
private boolean enterTouchMode() {
if (mView != null) {
if (mView.hasFocus()) {
// note: not relying on mFocusedView here because this could
// be when the window is first being added, and mFocused isn't
// set yet.
final View focused = mView.findFocus();
if (focused != null && !focused.isFocusableInTouchMode()) {
final ViewGroup ancestorToTakeFocus =
findAncestorToTakeFocusInTouchMode(focused);
if (ancestorToTakeFocus != null) {
// there is an ancestor that wants focus after its descendants that
// is focusable in touch mode.. give it focus
return ancestorToTakeFocus.requestFocus();
} else {
// nothing appropriate to have focus in touch mode, clear it out
mView.unFocus();
mAttachInfo.mTreeObserver.dispatchOnGlobalFocusChange(focused, null);
mFocusedView = null;
return true;
}
}
}
}
return false;
}
/**
* Find an ancestor of focused that wants focus after its descendants and is
* focusable in touch mode.
* @param focused The currently focused view.
* @return An appropriate view, or null if no such view exists.
*/
private ViewGroup findAncestorToTakeFocusInTouchMode(View focused) {
ViewParent parent = focused.getParent();
while (parent instanceof ViewGroup) {
final ViewGroup vgParent = (ViewGroup) parent;
if (vgParent.getDescendantFocusability() == ViewGroup.FOCUS_AFTER_DESCENDANTS
&& vgParent.isFocusableInTouchMode()) {
return vgParent;
}
if (vgParent.isRootNamespace()) {
return null;
} else {
parent = vgParent.getParent();
}
}
return null;
}
private boolean leaveTouchMode() {
if (mView != null) {
if (mView.hasFocus()) {
// i learned the hard way to not trust mFocusedView :)
mFocusedView = mView.findFocus();
if (!(mFocusedView instanceof ViewGroup)) {
// some view has focus, let it keep it
return false;
} else if (((ViewGroup)mFocusedView).getDescendantFocusability() !=
ViewGroup.FOCUS_AFTER_DESCENDANTS) {
// some view group has focus, and doesn't prefer its children
// over itself for focus, so let them keep it.
return false;
}
}
// find the best view to give focus to in this brave new non-touch-mode
// world
final View focused = focusSearch(null, View.FOCUS_DOWN);
if (focused != null) {
return focused.requestFocus(View.FOCUS_DOWN);
}
}
return false;
}
private void deliverPointerEvent(MotionEvent event, boolean sendDone) {
if (ViewDebug.DEBUG_LATENCY) {
mInputEventDeliverTimeNanos = System.nanoTime();
}
final boolean isTouchEvent = event.isTouchEvent();
if (mInputEventConsistencyVerifier != null) {
if (isTouchEvent) {
mInputEventConsistencyVerifier.onTouchEvent(event, 0);
} else {
mInputEventConsistencyVerifier.onGenericMotionEvent(event, 0);
}
}
// If there is no view, then the event will not be handled.
if (mView == null || !mAdded) {
finishMotionEvent(event, sendDone, false);
return;
}
// Translate the pointer event for compatibility, if needed.
if (mTranslator != null) {
mTranslator.translateEventInScreenToAppWindow(event);
}
// Enter touch mode on down or scroll.
final int action = event.getAction();
if (action == MotionEvent.ACTION_DOWN || action == MotionEvent.ACTION_SCROLL) {
ensureTouchMode(true);
}
// Offset the scroll position.
if (mCurScrollY != 0) {
event.offsetLocation(0, mCurScrollY);
}
if (MEASURE_LATENCY) {
lt.sample("A Dispatching PointerEvents", System.nanoTime() - event.getEventTimeNano());
}
// Remember the touch position for possible drag-initiation.
if (isTouchEvent) {
mLastTouchPoint.x = event.getRawX();
mLastTouchPoint.y = event.getRawY();
}
// Dispatch touch to view hierarchy.
boolean handled = mView.dispatchPointerEvent(event);
if (MEASURE_LATENCY) {
lt.sample("B Dispatched PointerEvents ", System.nanoTime() - event.getEventTimeNano());
}
if (handled) {
finishMotionEvent(event, sendDone, true);
return;
}
// Pointer event was unhandled.
finishMotionEvent(event, sendDone, false);
}
private void finishMotionEvent(MotionEvent event, boolean sendDone, boolean handled) {
event.recycle();
if (sendDone) {
finishInputEvent(event, handled);
}
//noinspection ConstantConditions
if (LOCAL_LOGV || WATCH_POINTER) {
if ((event.getSource() & InputDevice.SOURCE_CLASS_POINTER) != 0) {
Log.i(TAG, "Done dispatching!");
}
}
}
private void deliverTrackballEvent(MotionEvent event, boolean sendDone) {
if (ViewDebug.DEBUG_LATENCY) {
mInputEventDeliverTimeNanos = System.nanoTime();
}
if (DEBUG_TRACKBALL) Log.v(TAG, "Motion event:" + event);
if (mInputEventConsistencyVerifier != null) {
mInputEventConsistencyVerifier.onTrackballEvent(event, 0);
}
// If there is no view, then the event will not be handled.
if (mView == null || !mAdded) {
finishMotionEvent(event, sendDone, false);
return;
}
// Deliver the trackball event to the view.
if (mView.dispatchTrackballEvent(event)) {
// If we reach this, we delivered a trackball event to mView and
// mView consumed it. Because we will not translate the trackball
// event into a key event, touch mode will not exit, so we exit
// touch mode here.
ensureTouchMode(false);
finishMotionEvent(event, sendDone, true);
mLastTrackballTime = Integer.MIN_VALUE;
return;
}
// Translate the trackball event into DPAD keys and try to deliver those.
final TrackballAxis x = mTrackballAxisX;
final TrackballAxis y = mTrackballAxisY;
long curTime = SystemClock.uptimeMillis();
if ((mLastTrackballTime + MAX_TRACKBALL_DELAY) < curTime) {
// It has been too long since the last movement,
// so restart at the beginning.
x.reset(0);
y.reset(0);
mLastTrackballTime = curTime;
}
final int action = event.getAction();
final int metaState = event.getMetaState();
switch (action) {
case MotionEvent.ACTION_DOWN:
x.reset(2);
y.reset(2);
deliverKeyEvent(new KeyEvent(curTime, curTime,
KeyEvent.ACTION_DOWN, KeyEvent.KEYCODE_DPAD_CENTER, 0, metaState,
KeyCharacterMap.VIRTUAL_KEYBOARD, 0, KeyEvent.FLAG_FALLBACK,
InputDevice.SOURCE_KEYBOARD), false);
break;
case MotionEvent.ACTION_UP:
x.reset(2);
y.reset(2);
deliverKeyEvent(new KeyEvent(curTime, curTime,
KeyEvent.ACTION_UP, KeyEvent.KEYCODE_DPAD_CENTER, 0, metaState,
KeyCharacterMap.VIRTUAL_KEYBOARD, 0, KeyEvent.FLAG_FALLBACK,
InputDevice.SOURCE_KEYBOARD), false);
break;
}
if (DEBUG_TRACKBALL) Log.v(TAG, "TB X=" + x.position + " step="
+ x.step + " dir=" + x.dir + " acc=" + x.acceleration
+ " move=" + event.getX()
+ " / Y=" + y.position + " step="
+ y.step + " dir=" + y.dir + " acc=" + y.acceleration
+ " move=" + event.getY());
final float xOff = x.collect(event.getX(), event.getEventTime(), "X");
final float yOff = y.collect(event.getY(), event.getEventTime(), "Y");
// Generate DPAD events based on the trackball movement.
// We pick the axis that has moved the most as the direction of
// the DPAD. When we generate DPAD events for one axis, then the
// other axis is reset -- we don't want to perform DPAD jumps due
// to slight movements in the trackball when making major movements
// along the other axis.
int keycode = 0;
int movement = 0;
float accel = 1;
if (xOff > yOff) {
movement = x.generate((2/event.getXPrecision()));
if (movement != 0) {
keycode = movement > 0 ? KeyEvent.KEYCODE_DPAD_RIGHT
: KeyEvent.KEYCODE_DPAD_LEFT;
accel = x.acceleration;
y.reset(2);
}
} else if (yOff > 0) {
movement = y.generate((2/event.getYPrecision()));
if (movement != 0) {
keycode = movement > 0 ? KeyEvent.KEYCODE_DPAD_DOWN
: KeyEvent.KEYCODE_DPAD_UP;
accel = y.acceleration;
x.reset(2);
}
}
if (keycode != 0) {
if (movement < 0) movement = -movement;
int accelMovement = (int)(movement * accel);
if (DEBUG_TRACKBALL) Log.v(TAG, "Move: movement=" + movement
+ " accelMovement=" + accelMovement
+ " accel=" + accel);
if (accelMovement > movement) {
if (DEBUG_TRACKBALL) Log.v("foo", "Delivering fake DPAD: "
+ keycode);
movement--;
int repeatCount = accelMovement - movement;
deliverKeyEvent(new KeyEvent(curTime, curTime,
KeyEvent.ACTION_MULTIPLE, keycode, repeatCount, metaState,
KeyCharacterMap.VIRTUAL_KEYBOARD, 0, KeyEvent.FLAG_FALLBACK,
InputDevice.SOURCE_KEYBOARD), false);
}
while (movement > 0) {
if (DEBUG_TRACKBALL) Log.v("foo", "Delivering fake DPAD: "
+ keycode);
movement--;
curTime = SystemClock.uptimeMillis();
deliverKeyEvent(new KeyEvent(curTime, curTime,
KeyEvent.ACTION_DOWN, keycode, 0, metaState,
KeyCharacterMap.VIRTUAL_KEYBOARD, 0, KeyEvent.FLAG_FALLBACK,
InputDevice.SOURCE_KEYBOARD), false);
deliverKeyEvent(new KeyEvent(curTime, curTime,
KeyEvent.ACTION_UP, keycode, 0, metaState,
KeyCharacterMap.VIRTUAL_KEYBOARD, 0, KeyEvent.FLAG_FALLBACK,
InputDevice.SOURCE_KEYBOARD), false);
}
mLastTrackballTime = curTime;
}
// Unfortunately we can't tell whether the application consumed the keys, so
// we always consider the trackball event handled.
finishMotionEvent(event, sendDone, true);
}
private void deliverGenericMotionEvent(MotionEvent event, boolean sendDone) {
if (ViewDebug.DEBUG_LATENCY) {
mInputEventDeliverTimeNanos = System.nanoTime();
}
if (mInputEventConsistencyVerifier != null) {
mInputEventConsistencyVerifier.onGenericMotionEvent(event, 0);
}
final int source = event.getSource();
final boolean isJoystick = (source & InputDevice.SOURCE_CLASS_JOYSTICK) != 0;
// If there is no view, then the event will not be handled.
if (mView == null || !mAdded) {
if (isJoystick) {
updateJoystickDirection(event, false);
}
finishMotionEvent(event, sendDone, false);
return;
}
// Deliver the event to the view.
if (mView.dispatchGenericMotionEvent(event)) {
if (isJoystick) {
updateJoystickDirection(event, false);
}
finishMotionEvent(event, sendDone, true);
return;
}
if (isJoystick) {
// Translate the joystick event into DPAD keys and try to deliver those.
updateJoystickDirection(event, true);
finishMotionEvent(event, sendDone, true);
} else {
finishMotionEvent(event, sendDone, false);
}
}
private void updateJoystickDirection(MotionEvent event, boolean synthesizeNewKeys) {
final long time = event.getEventTime();
final int metaState = event.getMetaState();
final int deviceId = event.getDeviceId();
final int source = event.getSource();
int xDirection = joystickAxisValueToDirection(event.getAxisValue(MotionEvent.AXIS_HAT_X));
if (xDirection == 0) {
xDirection = joystickAxisValueToDirection(event.getX());
}
int yDirection = joystickAxisValueToDirection(event.getAxisValue(MotionEvent.AXIS_HAT_Y));
if (yDirection == 0) {
yDirection = joystickAxisValueToDirection(event.getY());
}
if (xDirection != mLastJoystickXDirection) {
if (mLastJoystickXKeyCode != 0) {
deliverKeyEvent(new KeyEvent(time, time,
KeyEvent.ACTION_UP, mLastJoystickXKeyCode, 0, metaState,
deviceId, 0, KeyEvent.FLAG_FALLBACK, source), false);
mLastJoystickXKeyCode = 0;
}
mLastJoystickXDirection = xDirection;
if (xDirection != 0 && synthesizeNewKeys) {
mLastJoystickXKeyCode = xDirection > 0
? KeyEvent.KEYCODE_DPAD_RIGHT : KeyEvent.KEYCODE_DPAD_LEFT;
deliverKeyEvent(new KeyEvent(time, time,
KeyEvent.ACTION_DOWN, mLastJoystickXKeyCode, 0, metaState,
deviceId, 0, KeyEvent.FLAG_FALLBACK, source), false);
}
}
if (yDirection != mLastJoystickYDirection) {
if (mLastJoystickYKeyCode != 0) {
deliverKeyEvent(new KeyEvent(time, time,
KeyEvent.ACTION_UP, mLastJoystickYKeyCode, 0, metaState,
deviceId, 0, KeyEvent.FLAG_FALLBACK, source), false);
mLastJoystickYKeyCode = 0;
}
mLastJoystickYDirection = yDirection;
if (yDirection != 0 && synthesizeNewKeys) {
mLastJoystickYKeyCode = yDirection > 0
? KeyEvent.KEYCODE_DPAD_DOWN : KeyEvent.KEYCODE_DPAD_UP;
deliverKeyEvent(new KeyEvent(time, time,
KeyEvent.ACTION_DOWN, mLastJoystickYKeyCode, 0, metaState,
deviceId, 0, KeyEvent.FLAG_FALLBACK, source), false);
}
}
}
private static int joystickAxisValueToDirection(float value) {
if (value >= 0.5f) {
return 1;
} else if (value <= -0.5f) {
return -1;
} else {
return 0;
}
}
/**
* Returns true if the key is used for keyboard navigation.
* @param keyEvent The key event.
* @return True if the key is used for keyboard navigation.
*/
private static boolean isNavigationKey(KeyEvent keyEvent) {
switch (keyEvent.getKeyCode()) {
case KeyEvent.KEYCODE_DPAD_LEFT:
case KeyEvent.KEYCODE_DPAD_RIGHT:
case KeyEvent.KEYCODE_DPAD_UP:
case KeyEvent.KEYCODE_DPAD_DOWN:
case KeyEvent.KEYCODE_DPAD_CENTER:
case KeyEvent.KEYCODE_PAGE_UP:
case KeyEvent.KEYCODE_PAGE_DOWN:
case KeyEvent.KEYCODE_MOVE_HOME:
case KeyEvent.KEYCODE_MOVE_END:
case KeyEvent.KEYCODE_TAB:
case KeyEvent.KEYCODE_SPACE:
case KeyEvent.KEYCODE_ENTER:
return true;
}
return false;
}
/**
* Returns true if the key is used for typing.
* @param keyEvent The key event.
* @return True if the key is used for typing.
*/
private static boolean isTypingKey(KeyEvent keyEvent) {
return keyEvent.getUnicodeChar() > 0;
}
/**
* See if the key event means we should leave touch mode (and leave touch mode if so).
* @param event The key event.
* @return Whether this key event should be consumed (meaning the act of
* leaving touch mode alone is considered the event).
*/
private boolean checkForLeavingTouchModeAndConsume(KeyEvent event) {
// Only relevant in touch mode.
if (!mAttachInfo.mInTouchMode) {
return false;
}
// Only consider leaving touch mode on DOWN or MULTIPLE actions, never on UP.
final int action = event.getAction();
if (action != KeyEvent.ACTION_DOWN && action != KeyEvent.ACTION_MULTIPLE) {
return false;
}
// Don't leave touch mode if the IME told us not to.
if ((event.getFlags() & KeyEvent.FLAG_KEEP_TOUCH_MODE) != 0) {
return false;
}
// If the key can be used for keyboard navigation then leave touch mode
// and select a focused view if needed (in ensureTouchMode).
// When a new focused view is selected, we consume the navigation key because
// navigation doesn't make much sense unless a view already has focus so
// the key's purpose is to set focus.
if (isNavigationKey(event)) {
return ensureTouchMode(false);
}
// If the key can be used for typing then leave touch mode
// and select a focused view if needed (in ensureTouchMode).
// Always allow the view to process the typing key.
if (isTypingKey(event)) {
ensureTouchMode(false);
return false;
}
return false;
}
int enqueuePendingEvent(Object event, boolean sendDone) {
int seq = mPendingEventSeq+1;
if (seq < 0) seq = 0;
mPendingEventSeq = seq;
mPendingEvents.put(seq, event);
return sendDone ? seq : -seq;
}
Object retrievePendingEvent(int seq) {
if (seq < 0) seq = -seq;
Object event = mPendingEvents.get(seq);
if (event != null) {
mPendingEvents.remove(seq);
}
return event;
}
private void deliverKeyEvent(KeyEvent event, boolean sendDone) {
if (ViewDebug.DEBUG_LATENCY) {
mInputEventDeliverTimeNanos = System.nanoTime();
}
if (mInputEventConsistencyVerifier != null) {
mInputEventConsistencyVerifier.onKeyEvent(event, 0);
}
// If there is no view, then the event will not be handled.
if (mView == null || !mAdded) {
finishKeyEvent(event, sendDone, false);
return;
}
if (LOCAL_LOGV) Log.v(TAG, "Dispatching key " + event + " to " + mView);
// Perform predispatching before the IME.
if (mView.dispatchKeyEventPreIme(event)) {
finishKeyEvent(event, sendDone, true);
return;
}
// Dispatch to the IME before propagating down the view hierarchy.
// The IME will eventually call back into handleFinishedEvent.
if (mLastWasImTarget) {
InputMethodManager imm = InputMethodManager.peekInstance();
if (imm != null) {
int seq = enqueuePendingEvent(event, sendDone);
if (DEBUG_IMF) Log.v(TAG, "Sending key event to IME: seq="
+ seq + " event=" + event);
imm.dispatchKeyEvent(mView.getContext(), seq, event, mInputMethodCallback);
return;
}
}
// Not dispatching to IME, continue with post IME actions.
deliverKeyEventPostIme(event, sendDone);
}
private void handleFinishedEvent(int seq, boolean handled) {
final KeyEvent event = (KeyEvent)retrievePendingEvent(seq);
if (DEBUG_IMF) Log.v(TAG, "IME finished event: seq=" + seq
+ " handled=" + handled + " event=" + event);
if (event != null) {
final boolean sendDone = seq >= 0;
if (handled) {
finishKeyEvent(event, sendDone, true);
} else {
deliverKeyEventPostIme(event, sendDone);
}
}
}
private void deliverKeyEventPostIme(KeyEvent event, boolean sendDone) {
if (ViewDebug.DEBUG_LATENCY) {
mInputEventDeliverPostImeTimeNanos = System.nanoTime();
}
// If the view went away, then the event will not be handled.
if (mView == null || !mAdded) {
finishKeyEvent(event, sendDone, false);
return;
}
// If the key's purpose is to exit touch mode then we consume it and consider it handled.
if (checkForLeavingTouchModeAndConsume(event)) {
finishKeyEvent(event, sendDone, true);
return;
}
// Make sure the fallback event policy sees all keys that will be delivered to the
// view hierarchy.
mFallbackEventHandler.preDispatchKeyEvent(event);
// Deliver the key to the view hierarchy.
if (mView.dispatchKeyEvent(event)) {
finishKeyEvent(event, sendDone, true);
return;
}
// If the Control modifier is held, try to interpret the key as a shortcut.
if (event.getAction() == KeyEvent.ACTION_DOWN
&& event.isCtrlPressed()
&& event.getRepeatCount() == 0
&& !KeyEvent.isModifierKey(event.getKeyCode())) {
if (mView.dispatchKeyShortcutEvent(event)) {
finishKeyEvent(event, sendDone, true);
return;
}
}
// Apply the fallback event policy.
if (mFallbackEventHandler.dispatchKeyEvent(event)) {
finishKeyEvent(event, sendDone, true);
return;
}
// Handle automatic focus changes.
if (event.getAction() == KeyEvent.ACTION_DOWN) {
int direction = 0;
switch (event.getKeyCode()) {
case KeyEvent.KEYCODE_DPAD_LEFT:
if (event.hasNoModifiers()) {
direction = View.FOCUS_LEFT;
}
break;
case KeyEvent.KEYCODE_DPAD_RIGHT:
if (event.hasNoModifiers()) {
direction = View.FOCUS_RIGHT;
}
break;
case KeyEvent.KEYCODE_DPAD_UP:
if (event.hasNoModifiers()) {
direction = View.FOCUS_UP;
}
break;
case KeyEvent.KEYCODE_DPAD_DOWN:
if (event.hasNoModifiers()) {
direction = View.FOCUS_DOWN;
}
break;
case KeyEvent.KEYCODE_TAB:
if (event.hasNoModifiers()) {
direction = View.FOCUS_FORWARD;
} else if (event.hasModifiers(KeyEvent.META_SHIFT_ON)) {
direction = View.FOCUS_BACKWARD;
}
break;
}
if (direction != 0) {
View focused = mView != null ? mView.findFocus() : null;
if (focused != null) {
View v = focused.focusSearch(direction);
if (v != null && v != focused) {
// do the math the get the interesting rect
// of previous focused into the coord system of
// newly focused view
focused.getFocusedRect(mTempRect);
if (mView instanceof ViewGroup) {
((ViewGroup) mView).offsetDescendantRectToMyCoords(
focused, mTempRect);
((ViewGroup) mView).offsetRectIntoDescendantCoords(
v, mTempRect);
}
if (v.requestFocus(direction, mTempRect)) {
playSoundEffect(
SoundEffectConstants.getContantForFocusDirection(direction));
finishKeyEvent(event, sendDone, true);
return;
}
}
// Give the focused view a last chance to handle the dpad key.
if (mView.dispatchUnhandledMove(focused, direction)) {
finishKeyEvent(event, sendDone, true);
return;
}
}
}
}
// Key was unhandled.
finishKeyEvent(event, sendDone, false);
}
private void finishKeyEvent(KeyEvent event, boolean sendDone, boolean handled) {
if (sendDone) {
finishInputEvent(event, handled);
}
}
/* drag/drop */
void setLocalDragState(Object obj) {
mLocalDragState = obj;
}
private void handleDragEvent(DragEvent event) {
// From the root, only drag start/end/location are dispatched. entered/exited
// are determined and dispatched by the viewgroup hierarchy, who then report
// that back here for ultimate reporting back to the framework.
if (mView != null && mAdded) {
final int what = event.mAction;
if (what == DragEvent.ACTION_DRAG_EXITED) {
// A direct EXITED event means that the window manager knows we've just crossed
// a window boundary, so the current drag target within this one must have
// just been exited. Send it the usual notifications and then we're done
// for now.
mView.dispatchDragEvent(event);
} else {
// Cache the drag description when the operation starts, then fill it in
// on subsequent calls as a convenience
if (what == DragEvent.ACTION_DRAG_STARTED) {
mCurrentDragView = null; // Start the current-recipient tracking
mDragDescription = event.mClipDescription;
} else {
event.mClipDescription = mDragDescription;
}
// For events with a [screen] location, translate into window coordinates
if ((what == DragEvent.ACTION_DRAG_LOCATION) || (what == DragEvent.ACTION_DROP)) {
mDragPoint.set(event.mX, event.mY);
if (mTranslator != null) {
mTranslator.translatePointInScreenToAppWindow(mDragPoint);
}
if (mCurScrollY != 0) {
mDragPoint.offset(0, mCurScrollY);
}
event.mX = mDragPoint.x;
event.mY = mDragPoint.y;
}
// Remember who the current drag target is pre-dispatch
final View prevDragView = mCurrentDragView;
// Now dispatch the drag/drop event
boolean result = mView.dispatchDragEvent(event);
// If we changed apparent drag target, tell the OS about it
if (prevDragView != mCurrentDragView) {
try {
if (prevDragView != null) {
sWindowSession.dragRecipientExited(mWindow);
}
if (mCurrentDragView != null) {
sWindowSession.dragRecipientEntered(mWindow);
}
} catch (RemoteException e) {
Slog.e(TAG, "Unable to note drag target change");
}
}
// Report the drop result when we're done
if (what == DragEvent.ACTION_DROP) {
mDragDescription = null;
try {
Log.i(TAG, "Reporting drop result: " + result);
sWindowSession.reportDropResult(mWindow, result);
} catch (RemoteException e) {
Log.e(TAG, "Unable to report drop result");
}
}
// When the drag operation ends, release any local state object
// that may have been in use
if (what == DragEvent.ACTION_DRAG_ENDED) {
setLocalDragState(null);
}
}
}
event.recycle();
}
public void handleDispatchSystemUiVisibilityChanged(SystemUiVisibilityInfo args) {
if (mSeq != args.seq) {
// The sequence has changed, so we need to update our value and make
// sure to do a traversal afterward so the window manager is given our
// most recent data.
mSeq = args.seq;
mAttachInfo.mForceReportNewAttributes = true;
scheduleTraversals();
}
if (mView == null) return;
if (args.localChanges != 0) {
if (mAttachInfo != null) {
mAttachInfo.mSystemUiVisibility =
(mAttachInfo.mSystemUiVisibility&~args.localChanges)
| (args.localValue&args.localChanges);
}
mView.updateLocalSystemUiVisibility(args.localValue, args.localChanges);
mAttachInfo.mRecomputeGlobalAttributes = true;
scheduleTraversals();
}
mView.dispatchSystemUiVisibilityChanged(args.globalVisibility);
}
public void getLastTouchPoint(Point outLocation) {
outLocation.x = (int) mLastTouchPoint.x;
outLocation.y = (int) mLastTouchPoint.y;
}
public void setDragFocus(View newDragTarget) {
if (mCurrentDragView != newDragTarget) {
mCurrentDragView = newDragTarget;
}
}
private AudioManager getAudioManager() {
if (mView == null) {
throw new IllegalStateException("getAudioManager called when there is no mView");
}
if (mAudioManager == null) {
mAudioManager = (AudioManager) mView.getContext().getSystemService(Context.AUDIO_SERVICE);
}
return mAudioManager;
}
public AccessibilityInteractionController getAccessibilityInteractionController() {
if (mView == null) {
throw new IllegalStateException("getAccessibilityInteractionController"
+ " called when there is no mView");
}
if (mAccessibilityInteractionController == null) {
mAccessibilityInteractionController = new AccessibilityInteractionController();
}
return mAccessibilityInteractionController;
}
private int relayoutWindow(WindowManager.LayoutParams params, int viewVisibility,
boolean insetsPending) throws RemoteException {
float appScale = mAttachInfo.mApplicationScale;
boolean restore = false;
if (params != null && mTranslator != null) {
restore = true;
params.backup();
mTranslator.translateWindowLayout(params);
}
if (params != null) {
if (DBG) Log.d(TAG, "WindowLayout in layoutWindow:" + params);
}
mPendingConfiguration.seq = 0;
//Log.d(TAG, ">>>>>> CALLING relayout");
if (params != null && mOrigWindowType != params.type) {
// For compatibility with old apps, don't crash here.
if (mTargetSdkVersion < android.os.Build.VERSION_CODES.ICE_CREAM_SANDWICH) {
Slog.w(TAG, "Window type can not be changed after "
+ "the window is added; ignoring change of " + mView);
params.type = mOrigWindowType;
}
}
int relayoutResult = sWindowSession.relayout(
mWindow, mSeq, params,
(int) (mView.getMeasuredWidth() * appScale + 0.5f),
(int) (mView.getMeasuredHeight() * appScale + 0.5f),
viewVisibility, insetsPending ? WindowManagerImpl.RELAYOUT_INSETS_PENDING : 0,
mWinFrame, mPendingContentInsets, mPendingVisibleInsets,
mPendingConfiguration, mSurface);
//Log.d(TAG, "<<<<<< BACK FROM relayout");
if (restore) {
params.restore();
}
if (mTranslator != null) {
mTranslator.translateRectInScreenToAppWinFrame(mWinFrame);
mTranslator.translateRectInScreenToAppWindow(mPendingContentInsets);
mTranslator.translateRectInScreenToAppWindow(mPendingVisibleInsets);
}
return relayoutResult;
}
/**
* {@inheritDoc}
*/
public void playSoundEffect(int effectId) {
checkThread();
try {
final AudioManager audioManager = getAudioManager();
switch (effectId) {
case SoundEffectConstants.CLICK:
audioManager.playSoundEffect(AudioManager.FX_KEY_CLICK);
return;
case SoundEffectConstants.NAVIGATION_DOWN:
audioManager.playSoundEffect(AudioManager.FX_FOCUS_NAVIGATION_DOWN);
return;
case SoundEffectConstants.NAVIGATION_LEFT:
audioManager.playSoundEffect(AudioManager.FX_FOCUS_NAVIGATION_LEFT);
return;
case SoundEffectConstants.NAVIGATION_RIGHT:
audioManager.playSoundEffect(AudioManager.FX_FOCUS_NAVIGATION_RIGHT);
return;
case SoundEffectConstants.NAVIGATION_UP:
audioManager.playSoundEffect(AudioManager.FX_FOCUS_NAVIGATION_UP);
return;
default:
throw new IllegalArgumentException("unknown effect id " + effectId +
" not defined in " + SoundEffectConstants.class.getCanonicalName());
}
} catch (IllegalStateException e) {
// Exception thrown by getAudioManager() when mView is null
Log.e(TAG, "FATAL EXCEPTION when attempting to play sound effect: " + e);
e.printStackTrace();
}
}
/**
* {@inheritDoc}
*/
public boolean performHapticFeedback(int effectId, boolean always) {
try {
return sWindowSession.performHapticFeedback(mWindow, effectId, always);
} catch (RemoteException e) {
return false;
}
}
/**
* {@inheritDoc}
*/
public View focusSearch(View focused, int direction) {
checkThread();
if (!(mView instanceof ViewGroup)) {
return null;
}
return FocusFinder.getInstance().findNextFocus((ViewGroup) mView, focused, direction);
}
public void debug() {
mView.debug();
}
public void dumpGfxInfo(PrintWriter pw, int[] info) {
if (mView != null) {
getGfxInfo(mView, info);
} else {
info[0] = info[1] = 0;
}
}
private void getGfxInfo(View view, int[] info) {
DisplayList displayList = view.mDisplayList;
info[0]++;
if (displayList != null) {
info[1] += displayList.getSize();
}
if (view instanceof ViewGroup) {
ViewGroup group = (ViewGroup) view;
int count = group.getChildCount();
for (int i = 0; i < count; i++) {
getGfxInfo(group.getChildAt(i), info);
}
}
}
public void die(boolean immediate) {
if (immediate) {
doDie();
} else {
sendEmptyMessage(DIE);
}
}
void doDie() {
checkThread();
if (LOCAL_LOGV) Log.v(TAG, "DIE in " + this + " of " + mSurface);
synchronized (this) {
if (mAdded) {
mAdded = false;
dispatchDetachedFromWindow();
}
if (mAdded && !mFirst) {
destroyHardwareRenderer();
int viewVisibility = mView.getVisibility();
boolean viewVisibilityChanged = mViewVisibility != viewVisibility;
if (mWindowAttributesChanged || viewVisibilityChanged) {
// If layout params have been changed, first give them
// to the window manager to make sure it has the correct
// animation info.
try {
if ((relayoutWindow(mWindowAttributes, viewVisibility, false)
& WindowManagerImpl.RELAYOUT_RES_FIRST_TIME) != 0) {
sWindowSession.finishDrawing(mWindow);
}
} catch (RemoteException e) {
}
}
mSurface.release();
}
}
}
public void requestUpdateConfiguration(Configuration config) {
Message msg = obtainMessage(UPDATE_CONFIGURATION, config);
sendMessage(msg);
}
private void destroyHardwareRenderer() {
if (mAttachInfo.mHardwareRenderer != null) {
mAttachInfo.mHardwareRenderer.destroy(true);
mAttachInfo.mHardwareRenderer = null;
mAttachInfo.mHardwareAccelerated = false;
}
}
public void dispatchFinishedEvent(int seq, boolean handled) {
Message msg = obtainMessage(FINISHED_EVENT);
msg.arg1 = seq;
msg.arg2 = handled ? 1 : 0;
sendMessage(msg);
}
public void dispatchResized(int w, int h, Rect coveredInsets,
Rect visibleInsets, boolean reportDraw, Configuration newConfig) {
if (DEBUG_LAYOUT) Log.v(TAG, "Resizing " + this + ": w=" + w
+ " h=" + h + " coveredInsets=" + coveredInsets.toShortString()
+ " visibleInsets=" + visibleInsets.toShortString()
+ " reportDraw=" + reportDraw);
Message msg = obtainMessage(reportDraw ? RESIZED_REPORT :RESIZED);
if (mTranslator != null) {
mTranslator.translateRectInScreenToAppWindow(coveredInsets);
mTranslator.translateRectInScreenToAppWindow(visibleInsets);
w *= mTranslator.applicationInvertedScale;
h *= mTranslator.applicationInvertedScale;
}
msg.arg1 = w;
msg.arg2 = h;
ResizedInfo ri = new ResizedInfo();
ri.coveredInsets = new Rect(coveredInsets);
ri.visibleInsets = new Rect(visibleInsets);
ri.newConfig = newConfig;
msg.obj = ri;
sendMessage(msg);
}
private long mInputEventReceiveTimeNanos;
private long mInputEventDeliverTimeNanos;
private long mInputEventDeliverPostImeTimeNanos;
private InputQueue.FinishedCallback mFinishedCallback;
private final InputHandler mInputHandler = new InputHandler() {
public void handleKey(KeyEvent event, InputQueue.FinishedCallback finishedCallback) {
startInputEvent(finishedCallback);
dispatchKey(event, true);
}
public void handleMotion(MotionEvent event, InputQueue.FinishedCallback finishedCallback) {
startInputEvent(finishedCallback);
dispatchMotion(event, true);
}
};
/**
* Utility class used to queue up input events which are then handled during
* performTraversals(). Doing it this way allows us to ensure that we are up to date with
* all input events just prior to drawing, instead of placing those events on the regular
* handler queue, potentially behind a drawing event.
*/
static class InputEventMessage {
Message mMessage;
InputEventMessage mNext;
private static final Object sPoolSync = new Object();
private static InputEventMessage sPool;
private static int sPoolSize = 0;
private static final int MAX_POOL_SIZE = 10;
private InputEventMessage(Message m) {
mMessage = m;
mNext = null;
}
/**
* Return a new Message instance from the global pool. Allows us to
* avoid allocating new objects in many cases.
*/
public static InputEventMessage obtain(Message msg) {
synchronized (sPoolSync) {
if (sPool != null) {
InputEventMessage m = sPool;
sPool = m.mNext;
m.mNext = null;
sPoolSize--;
m.mMessage = msg;
return m;
}
}
return new InputEventMessage(msg);
}
/**
* Return the message to the pool.
*/
public void recycle() {
mMessage.recycle();
synchronized (sPoolSync) {
if (sPoolSize < MAX_POOL_SIZE) {
mNext = sPool;
sPool = this;
sPoolSize++;
}
}
}
}
/**
* Place the input event message at the end of the current pending list
*/
private void enqueueInputEvent(Message msg, long when) {
InputEventMessage inputMessage = InputEventMessage.obtain(msg);
if (mPendingInputEvents == null) {
mPendingInputEvents = inputMessage;
} else {
InputEventMessage currMessage = mPendingInputEvents;
while (currMessage.mNext != null) {
currMessage = currMessage.mNext;
}
currMessage.mNext = inputMessage;
}
sendEmptyMessageAtTime(PROCESS_INPUT_EVENTS, when);
}
public void dispatchKey(KeyEvent event) {
dispatchKey(event, false);
}
private void dispatchKey(KeyEvent event, boolean sendDone) {
//noinspection ConstantConditions
if (false && event.getAction() == KeyEvent.ACTION_DOWN) {
if (event.getKeyCode() == KeyEvent.KEYCODE_CAMERA) {
if (DBG) Log.d("keydisp", "===================================================");
if (DBG) Log.d("keydisp", "Focused view Hierarchy is:");
debug();
if (DBG) Log.d("keydisp", "===================================================");
}
}
Message msg = obtainMessage(DISPATCH_KEY);
msg.obj = event;
msg.arg1 = sendDone ? 1 : 0;
if (LOCAL_LOGV) Log.v(
TAG, "sending key " + event + " to " + mView);
enqueueInputEvent(msg, event.getEventTime());
}
private void dispatchMotion(MotionEvent event, boolean sendDone) {
int source = event.getSource();
if ((source & InputDevice.SOURCE_CLASS_POINTER) != 0) {
dispatchPointer(event, sendDone);
} else if ((source & InputDevice.SOURCE_CLASS_TRACKBALL) != 0) {
dispatchTrackball(event, sendDone);
} else {
dispatchGenericMotion(event, sendDone);
}
}
private void dispatchPointer(MotionEvent event, boolean sendDone) {
Message msg = obtainMessage(DISPATCH_POINTER);
msg.obj = event;
msg.arg1 = sendDone ? 1 : 0;
enqueueInputEvent(msg, event.getEventTime());
}
private void dispatchTrackball(MotionEvent event, boolean sendDone) {
Message msg = obtainMessage(DISPATCH_TRACKBALL);
msg.obj = event;
msg.arg1 = sendDone ? 1 : 0;
enqueueInputEvent(msg, event.getEventTime());
}
private void dispatchGenericMotion(MotionEvent event, boolean sendDone) {
Message msg = obtainMessage(DISPATCH_GENERIC_MOTION);
msg.obj = event;
msg.arg1 = sendDone ? 1 : 0;
enqueueInputEvent(msg, event.getEventTime());
}
public void dispatchAppVisibility(boolean visible) {
Message msg = obtainMessage(DISPATCH_APP_VISIBILITY);
msg.arg1 = visible ? 1 : 0;
sendMessage(msg);
}
public void dispatchGetNewSurface() {
Message msg = obtainMessage(DISPATCH_GET_NEW_SURFACE);
sendMessage(msg);
}
public void windowFocusChanged(boolean hasFocus, boolean inTouchMode) {
Message msg = Message.obtain();
msg.what = WINDOW_FOCUS_CHANGED;
msg.arg1 = hasFocus ? 1 : 0;
msg.arg2 = inTouchMode ? 1 : 0;
sendMessage(msg);
}
public void dispatchCloseSystemDialogs(String reason) {
Message msg = Message.obtain();
msg.what = CLOSE_SYSTEM_DIALOGS;
msg.obj = reason;
sendMessage(msg);
}
public void dispatchDragEvent(DragEvent event) {
final int what;
if (event.getAction() == DragEvent.ACTION_DRAG_LOCATION) {
what = DISPATCH_DRAG_LOCATION_EVENT;
removeMessages(what);
} else {
what = DISPATCH_DRAG_EVENT;
}
Message msg = obtainMessage(what, event);
sendMessage(msg);
}
public void dispatchSystemUiVisibilityChanged(int seq, int globalVisibility,
int localValue, int localChanges) {
SystemUiVisibilityInfo args = new SystemUiVisibilityInfo();
args.seq = seq;
args.globalVisibility = globalVisibility;
args.localValue = localValue;
args.localChanges = localChanges;
sendMessage(obtainMessage(DISPATCH_SYSTEM_UI_VISIBILITY, args));
}
/**
* The window is getting focus so if there is anything focused/selected
* send an {@link AccessibilityEvent} to announce that.
*/
private void sendAccessibilityEvents() {
if (!mAccessibilityManager.isEnabled()) {
return;
}
mView.sendAccessibilityEvent(AccessibilityEvent.TYPE_WINDOW_STATE_CHANGED);
View focusedView = mView.findFocus();
if (focusedView != null && focusedView != mView) {
focusedView.sendAccessibilityEvent(AccessibilityEvent.TYPE_VIEW_FOCUSED);
}
}
/**
* Post a callback to send a
* {@link AccessibilityEvent#TYPE_WINDOW_CONTENT_CHANGED} event.
* This event is send at most once every
* {@link ViewConfiguration#getSendRecurringAccessibilityEventsInterval()}.
*/
private void postSendWindowContentChangedCallback() {
if (mSendWindowContentChangedAccessibilityEvent == null) {
mSendWindowContentChangedAccessibilityEvent =
new SendWindowContentChangedAccessibilityEvent();
}
if (!mSendWindowContentChangedAccessibilityEvent.mIsPending) {
mSendWindowContentChangedAccessibilityEvent.mIsPending = true;
postDelayed(mSendWindowContentChangedAccessibilityEvent,
ViewConfiguration.getSendRecurringAccessibilityEventsInterval());
}
}
/**
* Remove a posted callback to send a
* {@link AccessibilityEvent#TYPE_WINDOW_CONTENT_CHANGED} event.
*/
private void removeSendWindowContentChangedCallback() {
if (mSendWindowContentChangedAccessibilityEvent != null) {
removeCallbacks(mSendWindowContentChangedAccessibilityEvent);
}
}
public boolean showContextMenuForChild(View originalView) {
return false;
}
public ActionMode startActionModeForChild(View originalView, ActionMode.Callback callback) {
return null;
}
public void createContextMenu(ContextMenu menu) {
}
public void childDrawableStateChanged(View child) {
}
public boolean requestSendAccessibilityEvent(View child, AccessibilityEvent event) {
if (mView == null) {
return false;
}
mAccessibilityManager.sendAccessibilityEvent(event);
return true;
}
void checkThread() {
if (mThread != Thread.currentThread()) {
throw new CalledFromWrongThreadException(
"Only the original thread that created a view hierarchy can touch its views.");
}
}
public void requestDisallowInterceptTouchEvent(boolean disallowIntercept) {
// ViewAncestor never intercepts touch event, so this can be a no-op
}
public boolean requestChildRectangleOnScreen(View child, Rect rectangle,
boolean immediate) {
return scrollToRectOrFocus(rectangle, immediate);
}
class TakenSurfaceHolder extends BaseSurfaceHolder {
@Override
public boolean onAllowLockCanvas() {
return mDrawingAllowed;
}
@Override
public void onRelayoutContainer() {
// Not currently interesting -- from changing between fixed and layout size.
}
public void setFormat(int format) {
((RootViewSurfaceTaker)mView).setSurfaceFormat(format);
}
public void setType(int type) {
((RootViewSurfaceTaker)mView).setSurfaceType(type);
}
@Override
public void onUpdateSurface() {
// We take care of format and type changes on our own.
throw new IllegalStateException("Shouldn't be here");
}
public boolean isCreating() {
return mIsCreating;
}
@Override
public void setFixedSize(int width, int height) {
throw new UnsupportedOperationException(
"Currently only support sizing from layout");
}
public void setKeepScreenOn(boolean screenOn) {
((RootViewSurfaceTaker)mView).setSurfaceKeepScreenOn(screenOn);
}
}
static class InputMethodCallback extends IInputMethodCallback.Stub {
private WeakReference<ViewRootImpl> mViewAncestor;
public InputMethodCallback(ViewRootImpl viewAncestor) {
mViewAncestor = new WeakReference<ViewRootImpl>(viewAncestor);
}
public void finishedEvent(int seq, boolean handled) {
final ViewRootImpl viewAncestor = mViewAncestor.get();
if (viewAncestor != null) {
viewAncestor.dispatchFinishedEvent(seq, handled);
}
}
public void sessionCreated(IInputMethodSession session) {
// Stub -- not for use in the client.
}
}
static class W extends IWindow.Stub {
private final WeakReference<ViewRootImpl> mViewAncestor;
W(ViewRootImpl viewAncestor) {
mViewAncestor = new WeakReference<ViewRootImpl>(viewAncestor);
}
public void resized(int w, int h, Rect coveredInsets, Rect visibleInsets,
boolean reportDraw, Configuration newConfig) {
final ViewRootImpl viewAncestor = mViewAncestor.get();
if (viewAncestor != null) {
viewAncestor.dispatchResized(w, h, coveredInsets, visibleInsets, reportDraw,
newConfig);
}
}
public void dispatchAppVisibility(boolean visible) {
final ViewRootImpl viewAncestor = mViewAncestor.get();
if (viewAncestor != null) {
viewAncestor.dispatchAppVisibility(visible);
}
}
public void dispatchGetNewSurface() {
final ViewRootImpl viewAncestor = mViewAncestor.get();
if (viewAncestor != null) {
viewAncestor.dispatchGetNewSurface();
}
}
public void windowFocusChanged(boolean hasFocus, boolean inTouchMode) {
final ViewRootImpl viewAncestor = mViewAncestor.get();
if (viewAncestor != null) {
viewAncestor.windowFocusChanged(hasFocus, inTouchMode);
}
}
private static int checkCallingPermission(String permission) {
try {
return ActivityManagerNative.getDefault().checkPermission(
permission, Binder.getCallingPid(), Binder.getCallingUid());
} catch (RemoteException e) {
return PackageManager.PERMISSION_DENIED;
}
}
public void executeCommand(String command, String parameters, ParcelFileDescriptor out) {
final ViewRootImpl viewAncestor = mViewAncestor.get();
if (viewAncestor != null) {
final View view = viewAncestor.mView;
if (view != null) {
if (checkCallingPermission(Manifest.permission.DUMP) !=
PackageManager.PERMISSION_GRANTED) {
throw new SecurityException("Insufficient permissions to invoke"
+ " executeCommand() from pid=" + Binder.getCallingPid()
+ ", uid=" + Binder.getCallingUid());
}
OutputStream clientStream = null;
try {
clientStream = new ParcelFileDescriptor.AutoCloseOutputStream(out);
ViewDebug.dispatchCommand(view, command, parameters, clientStream);
} catch (IOException e) {
e.printStackTrace();
} finally {
if (clientStream != null) {
try {
clientStream.close();
} catch (IOException e) {
e.printStackTrace();
}
}
}
}
}
}
public void closeSystemDialogs(String reason) {
final ViewRootImpl viewAncestor = mViewAncestor.get();
if (viewAncestor != null) {
viewAncestor.dispatchCloseSystemDialogs(reason);
}
}
public void dispatchWallpaperOffsets(float x, float y, float xStep, float yStep,
boolean sync) {
if (sync) {
try {
sWindowSession.wallpaperOffsetsComplete(asBinder());
} catch (RemoteException e) {
}
}
}
public void dispatchWallpaperCommand(String action, int x, int y,
int z, Bundle extras, boolean sync) {
if (sync) {
try {
sWindowSession.wallpaperCommandComplete(asBinder(), null);
} catch (RemoteException e) {
}
}
}
/* Drag/drop */
public void dispatchDragEvent(DragEvent event) {
final ViewRootImpl viewAncestor = mViewAncestor.get();
if (viewAncestor != null) {
viewAncestor.dispatchDragEvent(event);
}
}
public void dispatchSystemUiVisibilityChanged(int seq, int globalVisibility,
int localValue, int localChanges) {
final ViewRootImpl viewAncestor = mViewAncestor.get();
if (viewAncestor != null) {
viewAncestor.dispatchSystemUiVisibilityChanged(seq, globalVisibility,
localValue, localChanges);
}
}
}
/**
* Maintains state information for a single trackball axis, generating
* discrete (DPAD) movements based on raw trackball motion.
*/
static final class TrackballAxis {
/**
* The maximum amount of acceleration we will apply.
*/
static final float MAX_ACCELERATION = 20;
/**
* The maximum amount of time (in milliseconds) between events in order
* for us to consider the user to be doing fast trackball movements,
* and thus apply an acceleration.
*/
static final long FAST_MOVE_TIME = 150;
/**
* Scaling factor to the time (in milliseconds) between events to how
* much to multiple/divide the current acceleration. When movement
* is < FAST_MOVE_TIME this multiplies the acceleration; when >
* FAST_MOVE_TIME it divides it.
*/
static final float ACCEL_MOVE_SCALING_FACTOR = (1.0f/40);
float position;
float absPosition;
float acceleration = 1;
long lastMoveTime = 0;
int step;
int dir;
int nonAccelMovement;
void reset(int _step) {
position = 0;
acceleration = 1;
lastMoveTime = 0;
step = _step;
dir = 0;
}
/**
* Add trackball movement into the state. If the direction of movement
* has been reversed, the state is reset before adding the
* movement (so that you don't have to compensate for any previously
* collected movement before see the result of the movement in the
* new direction).
*
* @return Returns the absolute value of the amount of movement
* collected so far.
*/
float collect(float off, long time, String axis) {
long normTime;
if (off > 0) {
normTime = (long)(off * FAST_MOVE_TIME);
if (dir < 0) {
if (DEBUG_TRACKBALL) Log.v(TAG, axis + " reversed to positive!");
position = 0;
step = 0;
acceleration = 1;
lastMoveTime = 0;
}
dir = 1;
} else if (off < 0) {
normTime = (long)((-off) * FAST_MOVE_TIME);
if (dir > 0) {
if (DEBUG_TRACKBALL) Log.v(TAG, axis + " reversed to negative!");
position = 0;
step = 0;
acceleration = 1;
lastMoveTime = 0;
}
dir = -1;
} else {
normTime = 0;
}
// The number of milliseconds between each movement that is
// considered "normal" and will not result in any acceleration
// or deceleration, scaled by the offset we have here.
if (normTime > 0) {
long delta = time - lastMoveTime;
lastMoveTime = time;
float acc = acceleration;
if (delta < normTime) {
// The user is scrolling rapidly, so increase acceleration.
float scale = (normTime-delta) * ACCEL_MOVE_SCALING_FACTOR;
if (scale > 1) acc *= scale;
if (DEBUG_TRACKBALL) Log.v(TAG, axis + " accelerate: off="
+ off + " normTime=" + normTime + " delta=" + delta
+ " scale=" + scale + " acc=" + acc);
acceleration = acc < MAX_ACCELERATION ? acc : MAX_ACCELERATION;
} else {
// The user is scrolling slowly, so decrease acceleration.
float scale = (delta-normTime) * ACCEL_MOVE_SCALING_FACTOR;
if (scale > 1) acc /= scale;
if (DEBUG_TRACKBALL) Log.v(TAG, axis + " deccelerate: off="
+ off + " normTime=" + normTime + " delta=" + delta
+ " scale=" + scale + " acc=" + acc);
acceleration = acc > 1 ? acc : 1;
}
}
position += off;
return (absPosition = Math.abs(position));
}
/**
* Generate the number of discrete movement events appropriate for
* the currently collected trackball movement.
*
* @param precision The minimum movement required to generate the
* first discrete movement.
*
* @return Returns the number of discrete movements, either positive
* or negative, or 0 if there is not enough trackball movement yet
* for a discrete movement.
*/
int generate(float precision) {
int movement = 0;
nonAccelMovement = 0;
do {
final int dir = position >= 0 ? 1 : -1;
switch (step) {
// If we are going to execute the first step, then we want
// to do this as soon as possible instead of waiting for
// a full movement, in order to make things look responsive.
case 0:
if (absPosition < precision) {
return movement;
}
movement += dir;
nonAccelMovement += dir;
step = 1;
break;
// If we have generated the first movement, then we need
// to wait for the second complete trackball motion before
// generating the second discrete movement.
case 1:
if (absPosition < 2) {
return movement;
}
movement += dir;
nonAccelMovement += dir;
position += dir > 0 ? -2 : 2;
absPosition = Math.abs(position);
step = 2;
break;
// After the first two, we generate discrete movements
// consistently with the trackball, applying an acceleration
// if the trackball is moving quickly. This is a simple
// acceleration on top of what we already compute based
// on how quickly the wheel is being turned, to apply
// a longer increasing acceleration to continuous movement
// in one direction.
default:
if (absPosition < 1) {
return movement;
}
movement += dir;
position += dir >= 0 ? -1 : 1;
absPosition = Math.abs(position);
float acc = acceleration;
acc *= 1.1f;
acceleration = acc < MAX_ACCELERATION ? acc : acceleration;
break;
}
} while (true);
}
}
public static final class CalledFromWrongThreadException extends AndroidRuntimeException {
public CalledFromWrongThreadException(String msg) {
super(msg);
}
}
private SurfaceHolder mHolder = new SurfaceHolder() {
// we only need a SurfaceHolder for opengl. it would be nice
// to implement everything else though, especially the callback
// support (opengl doesn't make use of it right now, but eventually
// will).
public Surface getSurface() {
return mSurface;
}
public boolean isCreating() {
return false;
}
public void addCallback(Callback callback) {
}
public void removeCallback(Callback callback) {
}
public void setFixedSize(int width, int height) {
}
public void setSizeFromLayout() {
}
public void setFormat(int format) {
}
public void setType(int type) {
}
public void setKeepScreenOn(boolean screenOn) {
}
public Canvas lockCanvas() {
return null;
}
public Canvas lockCanvas(Rect dirty) {
return null;
}
public void unlockCanvasAndPost(Canvas canvas) {
}
public Rect getSurfaceFrame() {
return null;
}
};
static RunQueue getRunQueue() {
RunQueue rq = sRunQueues.get();
if (rq != null) {
return rq;
}
rq = new RunQueue();
sRunQueues.set(rq);
return rq;
}
/**
* @hide
*/
static final class RunQueue {
private final ArrayList<HandlerAction> mActions = new ArrayList<HandlerAction>();
void post(Runnable action) {
postDelayed(action, 0);
}
void postDelayed(Runnable action, long delayMillis) {
HandlerAction handlerAction = new HandlerAction();
handlerAction.action = action;
handlerAction.delay = delayMillis;
synchronized (mActions) {
mActions.add(handlerAction);
}
}
void removeCallbacks(Runnable action) {
final HandlerAction handlerAction = new HandlerAction();
handlerAction.action = action;
synchronized (mActions) {
final ArrayList<HandlerAction> actions = mActions;
while (actions.remove(handlerAction)) {
// Keep going
}
}
}
void executeActions(Handler handler) {
synchronized (mActions) {
final ArrayList<HandlerAction> actions = mActions;
final int count = actions.size();
for (int i = 0; i < count; i++) {
final HandlerAction handlerAction = actions.get(i);
handler.postDelayed(handlerAction.action, handlerAction.delay);
}
actions.clear();
}
}
private static class HandlerAction {
Runnable action;
long delay;
@Override
public boolean equals(Object o) {
if (this == o) return true;
if (o == null || getClass() != o.getClass()) return false;
HandlerAction that = (HandlerAction) o;
return !(action != null ? !action.equals(that.action) : that.action != null);
}
@Override
public int hashCode() {
int result = action != null ? action.hashCode() : 0;
result = 31 * result + (int) (delay ^ (delay >>> 32));
return result;
}
}
}
/**
* Class for managing the accessibility interaction connection
* based on the global accessibility state.
*/
final class AccessibilityInteractionConnectionManager
implements AccessibilityStateChangeListener {
public void onAccessibilityStateChanged(boolean enabled) {
if (enabled) {
ensureConnection();
} else {
ensureNoConnection();
}
}
public void ensureConnection() {
final boolean registered = mAttachInfo.mAccessibilityWindowId != View.NO_ID;
if (!registered) {
mAttachInfo.mAccessibilityWindowId =
mAccessibilityManager.addAccessibilityInteractionConnection(mWindow,
new AccessibilityInteractionConnection(ViewRootImpl.this));
}
}
public void ensureNoConnection() {
final boolean registered = mAttachInfo.mAccessibilityWindowId != View.NO_ID;
if (registered) {
mAttachInfo.mAccessibilityWindowId = View.NO_ID;
mAccessibilityManager.removeAccessibilityInteractionConnection(mWindow);
}
}
}
/**
* This class is an interface this ViewAncestor provides to the
* AccessibilityManagerService to the latter can interact with
* the view hierarchy in this ViewAncestor.
*/
static final class AccessibilityInteractionConnection
extends IAccessibilityInteractionConnection.Stub {
private final WeakReference<ViewRootImpl> mRootImpl;
AccessibilityInteractionConnection(ViewRootImpl viewAncestor) {
mRootImpl = new WeakReference<ViewRootImpl>(viewAncestor);
}
public void findAccessibilityNodeInfoByAccessibilityId(int accessibilityId,
int interactionId, IAccessibilityInteractionConnectionCallback callback,
int interrogatingPid, long interrogatingTid) {
ViewRootImpl viewRootImpl = mRootImpl.get();
if (viewRootImpl != null) {
viewRootImpl.getAccessibilityInteractionController()
.findAccessibilityNodeInfoByAccessibilityIdClientThread(accessibilityId,
interactionId, callback, interrogatingPid, interrogatingTid);
}
}
public void performAccessibilityAction(int accessibilityId, int action,
int interactionId, IAccessibilityInteractionConnectionCallback callback,
int interogatingPid, long interrogatingTid) {
ViewRootImpl viewRootImpl = mRootImpl.get();
if (viewRootImpl != null) {
viewRootImpl.getAccessibilityInteractionController()
.performAccessibilityActionClientThread(accessibilityId, action, interactionId,
callback, interogatingPid, interrogatingTid);
}
}
public void findAccessibilityNodeInfoByViewId(int viewId,
int interactionId, IAccessibilityInteractionConnectionCallback callback,
int interrogatingPid, long interrogatingTid) {
ViewRootImpl viewRootImpl = mRootImpl.get();
if (viewRootImpl != null) {
viewRootImpl.getAccessibilityInteractionController()
.findAccessibilityNodeInfoByViewIdClientThread(viewId, interactionId, callback,
interrogatingPid, interrogatingTid);
}
}
public void findAccessibilityNodeInfosByViewText(String text, int accessibilityId,
int interactionId, IAccessibilityInteractionConnectionCallback callback,
int interrogatingPid, long interrogatingTid) {
ViewRootImpl viewRootImpl = mRootImpl.get();
if (viewRootImpl != null) {
viewRootImpl.getAccessibilityInteractionController()
.findAccessibilityNodeInfosByViewTextClientThread(text, accessibilityId,
interactionId, callback, interrogatingPid, interrogatingTid);
}
}
}
/**
* Class for managing accessibility interactions initiated from the system
* and targeting the view hierarchy. A *ClientThread method is to be
* called from the interaction connection this ViewAncestor gives the
* system to talk to it and a corresponding *UiThread method that is executed
* on the UI thread.
*/
final class AccessibilityInteractionController {
private static final int POOL_SIZE = 5;
private ArrayList<AccessibilityNodeInfo> mTempAccessibilityNodeInfoList =
new ArrayList<AccessibilityNodeInfo>();
// Reusable poolable arguments for interacting with the view hierarchy
// to fit more arguments than Message and to avoid sharing objects between
// two messages since several threads can send messages concurrently.
private final Pool<SomeArgs> mPool = Pools.synchronizedPool(Pools.finitePool(
new PoolableManager<SomeArgs>() {
public SomeArgs newInstance() {
return new SomeArgs();
}
public void onAcquired(SomeArgs info) {
/* do nothing */
}
public void onReleased(SomeArgs info) {
info.clear();
}
}, POOL_SIZE)
);
public class SomeArgs implements Poolable<SomeArgs> {
private SomeArgs mNext;
private boolean mIsPooled;
public Object arg1;
public Object arg2;
public int argi1;
public int argi2;
public int argi3;
public SomeArgs getNextPoolable() {
return mNext;
}
public boolean isPooled() {
return mIsPooled;
}
public void setNextPoolable(SomeArgs args) {
mNext = args;
}
public void setPooled(boolean isPooled) {
mIsPooled = isPooled;
}
private void clear() {
arg1 = null;
arg2 = null;
argi1 = 0;
argi2 = 0;
argi3 = 0;
}
}
public void findAccessibilityNodeInfoByAccessibilityIdClientThread(int accessibilityId,
int interactionId, IAccessibilityInteractionConnectionCallback callback,
int interrogatingPid, long interrogatingTid) {
Message message = Message.obtain();
message.what = DO_FIND_ACCESSIBLITY_NODE_INFO_BY_ACCESSIBILITY_ID;
message.arg1 = accessibilityId;
message.arg2 = interactionId;
message.obj = callback;
// If the interrogation is performed by the same thread as the main UI
// thread in this process, set the message as a static reference so
// after this call completes the same thread but in the interrogating
// client can handle the message to generate the result.
if (interrogatingPid == Process.myPid()
&& interrogatingTid == Looper.getMainLooper().getThread().getId()) {
message.setTarget(ViewRootImpl.this);
AccessibilityInteractionClient.getInstance().setSameThreadMessage(message);
} else {
sendMessage(message);
}
}
public void findAccessibilityNodeInfoByAccessibilityIdUiThread(Message message) {
final int accessibilityId = message.arg1;
final int interactionId = message.arg2;
final IAccessibilityInteractionConnectionCallback callback =
(IAccessibilityInteractionConnectionCallback) message.obj;
AccessibilityNodeInfo info = null;
try {
View target = findViewByAccessibilityId(accessibilityId);
if (target != null) {
info = target.createAccessibilityNodeInfo();
}
} finally {
try {
callback.setFindAccessibilityNodeInfoResult(info, interactionId);
} catch (RemoteException re) {
/* ignore - the other side will time out */
}
}
}
public void findAccessibilityNodeInfoByViewIdClientThread(int viewId, int interactionId,
IAccessibilityInteractionConnectionCallback callback, int interrogatingPid,
long interrogatingTid) {
Message message = Message.obtain();
message.what = DO_FIND_ACCESSIBLITY_NODE_INFO_BY_VIEW_ID;
message.arg1 = viewId;
message.arg2 = interactionId;
message.obj = callback;
// If the interrogation is performed by the same thread as the main UI
// thread in this process, set the message as a static reference so
// after this call completes the same thread but in the interrogating
// client can handle the message to generate the result.
if (interrogatingPid == Process.myPid()
&& interrogatingTid == Looper.getMainLooper().getThread().getId()) {
message.setTarget(ViewRootImpl.this);
AccessibilityInteractionClient.getInstance().setSameThreadMessage(message);
} else {
sendMessage(message);
}
}
public void findAccessibilityNodeInfoByViewIdUiThread(Message message) {
final int viewId = message.arg1;
final int interactionId = message.arg2;
final IAccessibilityInteractionConnectionCallback callback =
(IAccessibilityInteractionConnectionCallback) message.obj;
AccessibilityNodeInfo info = null;
try {
View root = ViewRootImpl.this.mView;
View target = root.findViewById(viewId);
if (target != null && target.getVisibility() == View.VISIBLE) {
info = target.createAccessibilityNodeInfo();
}
} finally {
try {
callback.setFindAccessibilityNodeInfoResult(info, interactionId);
} catch (RemoteException re) {
/* ignore - the other side will time out */
}
}
}
public void findAccessibilityNodeInfosByViewTextClientThread(String text,
int accessibilityViewId, int interactionId,
IAccessibilityInteractionConnectionCallback callback, int interrogatingPid,
long interrogatingTid) {
Message message = Message.obtain();
message.what = DO_FIND_ACCESSIBLITY_NODE_INFO_BY_VIEW_TEXT;
SomeArgs args = mPool.acquire();
args.arg1 = text;
args.argi1 = accessibilityViewId;
args.argi2 = interactionId;
args.arg2 = callback;
message.obj = args;
// If the interrogation is performed by the same thread as the main UI
// thread in this process, set the message as a static reference so
// after this call completes the same thread but in the interrogating
// client can handle the message to generate the result.
if (interrogatingPid == Process.myPid()
&& interrogatingTid == Looper.getMainLooper().getThread().getId()) {
message.setTarget(ViewRootImpl.this);
AccessibilityInteractionClient.getInstance().setSameThreadMessage(message);
} else {
sendMessage(message);
}
}
public void findAccessibilityNodeInfosByViewTextUiThread(Message message) {
SomeArgs args = (SomeArgs) message.obj;
final String text = (String) args.arg1;
final int accessibilityViewId = args.argi1;
final int interactionId = args.argi2;
final IAccessibilityInteractionConnectionCallback callback =
(IAccessibilityInteractionConnectionCallback) args.arg2;
mPool.release(args);
List<AccessibilityNodeInfo> infos = null;
try {
ArrayList<View> foundViews = mAttachInfo.mFocusablesTempList;
foundViews.clear();
View root = null;
if (accessibilityViewId != View.NO_ID) {
root = findViewByAccessibilityId(accessibilityViewId);
} else {
root = ViewRootImpl.this.mView;
}
if (root == null || root.getVisibility() != View.VISIBLE) {
return;
}
root.findViewsWithText(foundViews, text, View.FIND_VIEWS_WITH_TEXT
| View.FIND_VIEWS_WITH_CONTENT_DESCRIPTION);
if (foundViews.isEmpty()) {
return;
}
infos = mTempAccessibilityNodeInfoList;
infos.clear();
final int viewCount = foundViews.size();
for (int i = 0; i < viewCount; i++) {
View foundView = foundViews.get(i);
if (foundView.getVisibility() == View.VISIBLE) {
infos.add(foundView.createAccessibilityNodeInfo());
}
}
} finally {
try {
callback.setFindAccessibilityNodeInfosResult(infos, interactionId);
} catch (RemoteException re) {
/* ignore - the other side will time out */
}
}
}
public void performAccessibilityActionClientThread(int accessibilityId, int action,
int interactionId, IAccessibilityInteractionConnectionCallback callback,
int interogatingPid, long interrogatingTid) {
Message message = Message.obtain();
message.what = DO_PERFORM_ACCESSIBILITY_ACTION;
SomeArgs args = mPool.acquire();
args.argi1 = accessibilityId;
args.argi2 = action;
args.argi3 = interactionId;
args.arg1 = callback;
message.obj = args;
// If the interrogation is performed by the same thread as the main UI
// thread in this process, set the message as a static reference so
// after this call completes the same thread but in the interrogating
// client can handle the message to generate the result.
if (interogatingPid == Process.myPid()
&& interrogatingTid == Looper.getMainLooper().getThread().getId()) {
message.setTarget(ViewRootImpl.this);
AccessibilityInteractionClient.getInstance().setSameThreadMessage(message);
} else {
sendMessage(message);
}
}
public void perfromAccessibilityActionUiThread(Message message) {
SomeArgs args = (SomeArgs) message.obj;
final int accessibilityId = args.argi1;
final int action = args.argi2;
final int interactionId = args.argi3;
final IAccessibilityInteractionConnectionCallback callback =
(IAccessibilityInteractionConnectionCallback) args.arg1;
mPool.release(args);
boolean succeeded = false;
try {
switch (action) {
case AccessibilityNodeInfo.ACTION_FOCUS: {
succeeded = performActionFocus(accessibilityId);
} break;
case AccessibilityNodeInfo.ACTION_CLEAR_FOCUS: {
succeeded = performActionClearFocus(accessibilityId);
} break;
case AccessibilityNodeInfo.ACTION_SELECT: {
succeeded = performActionSelect(accessibilityId);
} break;
case AccessibilityNodeInfo.ACTION_CLEAR_SELECTION: {
succeeded = performActionClearSelection(accessibilityId);
} break;
}
} finally {
try {
callback.setPerformAccessibilityActionResult(succeeded, interactionId);
} catch (RemoteException re) {
/* ignore - the other side will time out */
}
}
}
private boolean performActionFocus(int accessibilityId) {
View target = findViewByAccessibilityId(accessibilityId);
if (target == null || target.getVisibility() != View.VISIBLE) {
return false;
}
// Get out of touch mode since accessibility wants to move focus around.
ensureTouchMode(false);
return target.requestFocus();
}
private boolean performActionClearFocus(int accessibilityId) {
View target = findViewByAccessibilityId(accessibilityId);
if (target == null || target.getVisibility() != View.VISIBLE) {
return false;
}
if (!target.isFocused()) {
return false;
}
target.clearFocus();
return !target.isFocused();
}
private boolean performActionSelect(int accessibilityId) {
View target = findViewByAccessibilityId(accessibilityId);
if (target == null || target.getVisibility() != View.VISIBLE) {
return false;
}
if (target.isSelected()) {
return false;
}
target.setSelected(true);
return target.isSelected();
}
private boolean performActionClearSelection(int accessibilityId) {
View target = findViewByAccessibilityId(accessibilityId);
if (target == null || target.getVisibility() != View.VISIBLE) {
return false;
}
if (!target.isSelected()) {
return false;
}
target.setSelected(false);
return !target.isSelected();
}
private View findViewByAccessibilityId(int accessibilityId) {
View root = ViewRootImpl.this.mView;
if (root == null) {
return null;
}
View foundView = root.findViewByAccessibilityId(accessibilityId);
if (foundView != null && foundView.getVisibility() != View.VISIBLE) {
return null;
}
return foundView;
}
}
private class SendWindowContentChangedAccessibilityEvent implements Runnable {
public volatile boolean mIsPending;
public void run() {
if (mView != null) {
mView.sendAccessibilityEvent(AccessibilityEvent.TYPE_WINDOW_CONTENT_CHANGED);
mIsPending = false;
}
}
}
}