The surface is Z ordered so that it is behind the window holding its * SurfaceView; the SurfaceView punches a hole in its window to allow its * surface to be displayed. The view hierarchy will take care of correctly * compositing with the Surface any siblings of the SurfaceView that would * normally appear on top of it. This can be used to place overlays such as * buttons on top of the Surface, though note however that it can have an * impact on performance since a full alpha-blended composite will be performed * each time the Surface changes. * *
The transparent region that makes the surface visible is based on the * layout positions in the view hierarchy. If the post-layout transform * properties are used to draw a sibling view on top of the SurfaceView, the * view may not be properly composited with the surface. * *
Access to the underlying surface is provided via the SurfaceHolder interface, * which can be retrieved by calling {@link #getHolder}. * *
The Surface will be created for you while the SurfaceView's window is * visible; you should implement {@link SurfaceHolder.Callback#surfaceCreated} * and {@link SurfaceHolder.Callback#surfaceDestroyed} to discover when the * Surface is created and destroyed as the window is shown and hidden. * *
One of the purposes of this class is to provide a surface in which a * secondary thread can render into the screen. If you are going to use it * this way, you need to be aware of some threading semantics: * *
Note: Starting in platform version * {@link android.os.Build.VERSION_CODES#N}, SurfaceView's window position is * updated synchronously with other View rendering. This means that translating * and scaling a SurfaceView on screen will not cause rendering artifacts. Such * artifacts may occur on previous versions of the platform when its window is * positioned asynchronously.
* *Note: Starting in platform version
* {@link android.os.Build.VERSION_CODES#UPSIDE_DOWN_CAKE}, SurfaceView will support arbitrary
* alpha blending. Prior platform versions ignored alpha values on the SurfaceView if they were
* between 0 and 1. If the SurfaceView is configured with Z-above, then the alpha is applied
* directly to the Surface. If the SurfaceView is configured with Z-below, then the alpha is
* applied to the hole punch directly. Note that when using Z-below, overlapping SurfaceViews
* may not blend properly as a consequence of not applying alpha to the surface content directly.
*/
public class SurfaceView extends View implements ViewRootImpl.SurfaceChangedCallback {
/** @hide */
@Retention(RetentionPolicy.SOURCE)
@IntDef(prefix = {"SURFACE_LIFECYCLE_"},
value = {SURFACE_LIFECYCLE_DEFAULT,
SURFACE_LIFECYCLE_FOLLOWS_VISIBILITY,
SURFACE_LIFECYCLE_FOLLOWS_ATTACHMENT})
public @interface SurfaceLifecycleStrategy {}
/**
* Default lifecycle of the Surface owned by this SurfaceView.
*
* The default lifecycle matches {@link #SURFACE_LIFECYCLE_FOLLOWS_VISIBILITY}.
*/
public static final int SURFACE_LIFECYCLE_DEFAULT = 0;
/**
* The Surface lifecycle is tied to SurfaceView visibility.
*
* The Surface is created when the SurfaceView becomes visible, and is destroyed when the
* SurfaceView is no longer visible.
*/
public static final int SURFACE_LIFECYCLE_FOLLOWS_VISIBILITY = 1;
/**
* The Surface lifecycle is tied to SurfaceView attachment.
* The Surface is created when the SurfaceView first becomes attached, but is not destroyed
* until this SurfaceView has been detached from the current window.
*/
public static final int SURFACE_LIFECYCLE_FOLLOWS_ATTACHMENT = 2;
private static final String TAG = "SurfaceView";
private static final boolean DEBUG = false;
private static final boolean DEBUG_POSITION = false;
@UnsupportedAppUsage(
maxTargetSdk = Build.VERSION_CODES.TIRAMISU,
publicAlternatives = "Track {@link SurfaceHolder#addCallback} instead")
final ArrayList Note: Alpha value of the view is ignored and the underlying
* surface is rendered opaque by default. Note that this must be set before the surface view's containing
* window is attached to the window manager.
*
* Calling this overrides any previous call to {@link #setZOrderOnTop}.
*/
public void setZOrderMediaOverlay(boolean isMediaOverlay) {
mRequestedSubLayer = isMediaOverlay
? APPLICATION_MEDIA_OVERLAY_SUBLAYER : APPLICATION_MEDIA_SUBLAYER;
}
/**
* Control whether the surface view's surface is placed on top of its
* window. Normally it is placed behind the window, to allow it to
* (for the most part) appear to composite with the views in the
* hierarchy. By setting this, you cause it to be placed above the
* window. This means that none of the contents of the window this
* SurfaceView is in will be visible on top of its surface.
*
* Note that this must be set before the surface view's containing
* window is attached to the window manager. If you target {@link Build.VERSION_CODES#R}
* the Z ordering can be changed dynamically if the backing surface is
* created, otherwise it would be applied at surface construction time.
*
* Calling this overrides any previous call to {@link #setZOrderMediaOverlay}.
*
* @param onTop Whether to show the surface on top of this view's window.
*/
public void setZOrderOnTop(boolean onTop) {
// In R and above we allow dynamic layer changes.
final boolean allowDynamicChange = getContext().getApplicationInfo().targetSdkVersion
> Build.VERSION_CODES.Q;
setZOrderedOnTop(onTop, allowDynamicChange);
}
/**
* @return Whether the surface backing this view appears on top of its parent.
*
* @hide
*/
public boolean isZOrderedOnTop() {
return mRequestedSubLayer > 0;
}
/**
* Controls whether the surface view's surface is placed on top of its
* window. Normally it is placed behind the window, to allow it to
* (for the most part) appear to composite with the views in the
* hierarchy. By setting this, you cause it to be placed above the
* window. This means that none of the contents of the window this
* SurfaceView is in will be visible on top of its surface.
*
* Calling this overrides any previous call to {@link #setZOrderMediaOverlay}.
*
* @param onTop Whether to show the surface on top of this view's window.
* @param allowDynamicChange Whether this can happen after the surface is created.
* @return Whether the Z ordering changed.
*
* @hide
*/
public boolean setZOrderedOnTop(boolean onTop, boolean allowDynamicChange) {
final int subLayer;
if (onTop) {
subLayer = APPLICATION_PANEL_SUBLAYER;
} else {
subLayer = APPLICATION_MEDIA_SUBLAYER;
}
if (mRequestedSubLayer == subLayer) {
return false;
}
mRequestedSubLayer = subLayer;
if (!allowDynamicChange) {
return false;
}
if (mSurfaceControl == null) {
return true;
}
final ViewRootImpl viewRoot = getViewRootImpl();
if (viewRoot == null) {
return true;
}
updateSurface();
invalidate();
return true;
}
/**
* Control whether the surface view's content should be treated as secure,
* preventing it from appearing in screenshots or from being viewed on
* non-secure displays.
*
* Note that this must be set before the surface view's containing
* window is attached to the window manager.
*
* See {@link android.view.Display#FLAG_SECURE} for details.
*
* @param isSecure True if the surface view is secure.
*/
public void setSecure(boolean isSecure) {
if (isSecure) {
mSurfaceFlags |= SurfaceControl.SECURE;
} else {
mSurfaceFlags &= ~SurfaceControl.SECURE;
}
}
/**
* Controls the lifecycle of the Surface owned by this SurfaceView.
*
* By default, the lifecycycle strategy employed by the SurfaceView is
* {@link #SURFACE_LIFECYCLE_DEFAULT}.
*
* @param lifecycleStrategy The strategy for the lifecycle of the Surface owned by this
* SurfaceView.
*/
public void setSurfaceLifecycle(@SurfaceLifecycleStrategy int lifecycleStrategy) {
mRequestedSurfaceLifecycleStrategy = lifecycleStrategy;
updateSurface();
}
private void updateOpaqueFlag() {
if (!PixelFormat.formatHasAlpha(mRequestedFormat)) {
mSurfaceFlags |= SurfaceControl.OPAQUE;
} else {
mSurfaceFlags &= ~SurfaceControl.OPAQUE;
}
}
private void updateBackgroundVisibility(Transaction t) {
if (mBackgroundControl == null) {
return;
}
if ((mSubLayer < 0) && ((mSurfaceFlags & SurfaceControl.OPAQUE) != 0)
&& !mDisableBackgroundLayer) {
t.show(mBackgroundControl);
} else {
t.hide(mBackgroundControl);
}
}
private Transaction updateBackgroundColor(Transaction t) {
final float[] colorComponents = new float[] { Color.red(mBackgroundColor) / 255.f,
Color.green(mBackgroundColor) / 255.f, Color.blue(mBackgroundColor) / 255.f };
t.setColor(mBackgroundControl, colorComponents);
return t;
}
private void releaseSurfaces(boolean releaseSurfacePackage) {
mAlpha = 1f;
mSurface.destroy();
synchronized (mSurfaceControlLock) {
if (mBlastBufferQueue != null) {
mBlastBufferQueue.destroy();
mBlastBufferQueue = null;
}
final Transaction transaction = new Transaction();
if (mSurfaceControl != null) {
transaction.remove(mSurfaceControl);
mSurfaceControl = null;
}
if (mBackgroundControl != null) {
transaction.remove(mBackgroundControl);
mBackgroundControl = null;
}
if (mBlastSurfaceControl != null) {
transaction.remove(mBlastSurfaceControl);
mBlastSurfaceControl = null;
}
if (mSurfacePackage != null) {
try {
mSurfacePackage.getRemoteInterface().attachParentInterface(null);
mEmbeddedWindowParams.clear();
} catch (RemoteException e) {
Log.d(TAG, "Failed to remove parent interface from SCVH. Likely SCVH is "
+ "already dead");
}
if (releaseSurfacePackage) {
mSurfacePackage.release();
mSurfacePackage = null;
}
}
applyTransactionOnVriDraw(transaction);
}
}
// The position update listener is used to safely share the surface size between render thread
// workers and the UI thread. Both threads need to know the surface size to determine the scale.
// The parent layer scales the surface size to view size. The child (BBQ) layer scales
// the buffer to the surface size. Both scales along with the window crop must be applied
// synchronously otherwise we may see flickers.
// When the listener is updated, we will get at least a single position update call so we can
// guarantee any changes we post will be applied.
private void replacePositionUpdateListener(int surfaceWidth, int surfaceHeight) {
if (mPositionListener != null) {
mRenderNode.removePositionUpdateListener(mPositionListener);
}
mPositionListener = new SurfaceViewPositionUpdateListener(surfaceWidth, surfaceHeight);
mRenderNode.addPositionUpdateListener(mPositionListener);
}
private boolean performSurfaceTransaction(ViewRootImpl viewRoot, Translator translator,
boolean creating, boolean sizeChanged, boolean hintChanged, boolean relativeZChanged,
Transaction surfaceUpdateTransaction) {
boolean realSizeChanged = false;
mSurfaceLock.lock();
try {
mDrawingStopped = !surfaceShouldExist();
if (DEBUG) Log.i(TAG, System.identityHashCode(this) + " "
+ "Cur surface: " + mSurface);
// If we are creating the surface control or the parent surface has not
// changed, then set relative z. Otherwise allow the parent
// SurfaceChangedCallback to update the relative z. This is needed so that
// we do not change the relative z before the server is ready to swap the
// parent surface.
if (creating) {
updateRelativeZ(surfaceUpdateTransaction);
if (mSurfacePackage != null) {
reparentSurfacePackage(surfaceUpdateTransaction, mSurfacePackage);
}
}
mParentSurfaceSequenceId = viewRoot.getSurfaceSequenceId();
// Only control visibility if we're not hardware-accelerated. Otherwise we'll
// let renderthread drive since offscreen SurfaceControls should not be visible.
if (!isHardwareAccelerated()) {
if (mViewVisibility) {
surfaceUpdateTransaction.show(mSurfaceControl);
} else {
surfaceUpdateTransaction.hide(mSurfaceControl);
}
}
updateBackgroundVisibility(surfaceUpdateTransaction);
updateBackgroundColor(surfaceUpdateTransaction);
if (isAboveParent()) {
float alpha = getAlpha();
surfaceUpdateTransaction.setAlpha(mSurfaceControl, alpha);
}
if (relativeZChanged) {
if (!isAboveParent()) {
// If we're moving from z-above to z-below, then restore the surface alpha back to 1
// and let the holepunch drive visibility and blending.
surfaceUpdateTransaction.setAlpha(mSurfaceControl, 1.f);
}
updateRelativeZ(surfaceUpdateTransaction);
}
surfaceUpdateTransaction.setCornerRadius(mSurfaceControl, mCornerRadius);
if ((sizeChanged || hintChanged) && !creating) {
setBufferSize(surfaceUpdateTransaction);
}
if (sizeChanged || creating || !isHardwareAccelerated()) {
// Set a window crop when creating the surface or changing its size to
// crop the buffer to the surface size since the buffer producer may
// use SCALING_MODE_SCALE and submit a larger size than the surface
// size.
if (mClipSurfaceToBounds && mClipBounds != null) {
surfaceUpdateTransaction.setWindowCrop(mSurfaceControl, mClipBounds);
} else {
surfaceUpdateTransaction.setWindowCrop(mSurfaceControl, mSurfaceWidth,
mSurfaceHeight);
}
surfaceUpdateTransaction.setDesintationFrame(mBlastSurfaceControl, mSurfaceWidth,
mSurfaceHeight);
if (isHardwareAccelerated()) {
// This will consume the passed in transaction and the transaction will be
// applied on a render worker thread.
replacePositionUpdateListener(mSurfaceWidth, mSurfaceHeight);
} else {
onSetSurfacePositionAndScale(surfaceUpdateTransaction, mSurfaceControl,
mScreenRect.left /*positionLeft*/,
mScreenRect.top /*positionTop*/,
mScreenRect.width() / (float) mSurfaceWidth /*postScaleX*/,
mScreenRect.height() / (float) mSurfaceHeight /*postScaleY*/);
}
if (DEBUG_POSITION) {
Log.d(TAG, String.format(
"%d performSurfaceTransaction %s "
+ "position = [%d, %d, %d, %d] surfaceSize = %dx%d",
System.identityHashCode(this),
isHardwareAccelerated() ? "RenderWorker" : "UI Thread",
mScreenRect.left, mScreenRect.top, mScreenRect.right,
mScreenRect.bottom, mSurfaceWidth, mSurfaceHeight));
}
}
applyTransactionOnVriDraw(surfaceUpdateTransaction);
updateEmbeddedAccessibilityMatrix(false);
mSurfaceFrame.left = 0;
mSurfaceFrame.top = 0;
if (translator == null) {
mSurfaceFrame.right = mSurfaceWidth;
mSurfaceFrame.bottom = mSurfaceHeight;
} else {
float appInvertedScale = translator.applicationInvertedScale;
mSurfaceFrame.right = (int) (mSurfaceWidth * appInvertedScale + 0.5f);
mSurfaceFrame.bottom = (int) (mSurfaceHeight * appInvertedScale + 0.5f);
}
final int surfaceWidth = mSurfaceFrame.right;
final int surfaceHeight = mSurfaceFrame.bottom;
realSizeChanged = mLastSurfaceWidth != surfaceWidth
|| mLastSurfaceHeight != surfaceHeight;
mLastSurfaceWidth = surfaceWidth;
mLastSurfaceHeight = surfaceHeight;
} finally {
mSurfaceLock.unlock();
}
return realSizeChanged;
}
private boolean requiresSurfaceControlCreation(boolean formatChanged, boolean visibleChanged) {
if (mSurfaceLifecycleStrategy == SURFACE_LIFECYCLE_FOLLOWS_ATTACHMENT) {
return (mSurfaceControl == null || formatChanged) && mAttachedToWindow;
}
return (mSurfaceControl == null || formatChanged || visibleChanged) && mRequestedVisible;
}
private boolean surfaceShouldExist() {
final boolean respectVisibility =
mSurfaceLifecycleStrategy != SURFACE_LIFECYCLE_FOLLOWS_ATTACHMENT;
return mVisible || (!respectVisibility && mAttachedToWindow);
}
/** @hide */
protected void updateSurface() {
if (!mHaveFrame) {
if (DEBUG) {
Log.d(TAG, System.identityHashCode(this) + " updateSurface: has no frame");
}
return;
}
final ViewRootImpl viewRoot = getViewRootImpl();
if (viewRoot == null) {
return;
}
if (viewRoot.mSurface == null || !viewRoot.mSurface.isValid()) {
notifySurfaceDestroyed();
releaseSurfaces(false /* releaseSurfacePackage*/);
return;
}
final Translator translator = viewRoot.mTranslator;
if (translator != null) {
mSurface.setCompatibilityTranslator(translator);
}
int myWidth = mRequestedWidth;
if (myWidth <= 0) myWidth = getWidth();
int myHeight = mRequestedHeight;
if (myHeight <= 0) myHeight = getHeight();
final float alpha = getAlpha();
final boolean formatChanged = mFormat != mRequestedFormat;
final boolean visibleChanged = mVisible != mRequestedVisible;
final boolean alphaChanged = mAlpha != alpha;
final boolean creating = requiresSurfaceControlCreation(formatChanged, visibleChanged);
final boolean sizeChanged = mSurfaceWidth != myWidth || mSurfaceHeight != myHeight;
final boolean windowVisibleChanged = mWindowVisibility != mLastWindowVisibility;
getLocationInWindow(mLocation);
final boolean positionChanged = mWindowSpaceLeft != mLocation[0]
|| mWindowSpaceTop != mLocation[1];
final boolean layoutSizeChanged = getWidth() != mScreenRect.width()
|| getHeight() != mScreenRect.height();
final boolean hintChanged = (viewRoot.getBufferTransformHint() != mTransformHint)
&& mRequestedVisible;
final boolean relativeZChanged = mSubLayer != mRequestedSubLayer;
final boolean surfaceLifecycleStrategyChanged =
mSurfaceLifecycleStrategy != mRequestedSurfaceLifecycleStrategy;
if (creating || formatChanged || sizeChanged || visibleChanged
|| alphaChanged || windowVisibleChanged || positionChanged
|| layoutSizeChanged || hintChanged || relativeZChanged || !mAttachedToWindow
|| surfaceLifecycleStrategyChanged) {
if (DEBUG) Log.i(TAG, System.identityHashCode(this) + " "
+ "Changes: creating=" + creating
+ " format=" + formatChanged + " size=" + sizeChanged
+ " visible=" + visibleChanged + " alpha=" + alphaChanged
+ " hint=" + hintChanged
+ " visible=" + visibleChanged
+ " left=" + (mWindowSpaceLeft != mLocation[0])
+ " top=" + (mWindowSpaceTop != mLocation[1])
+ " z=" + relativeZChanged
+ " attached=" + mAttachedToWindow
+ " lifecycleStrategy=" + surfaceLifecycleStrategyChanged);
try {
mVisible = mRequestedVisible;
mWindowSpaceLeft = mLocation[0];
mWindowSpaceTop = mLocation[1];
mSurfaceWidth = myWidth;
mSurfaceHeight = myHeight;
mFormat = mRequestedFormat;
mAlpha = alpha;
mLastWindowVisibility = mWindowVisibility;
mTransformHint = viewRoot.getBufferTransformHint();
mSubLayer = mRequestedSubLayer;
final int previousSurfaceLifecycleStrategy = mSurfaceLifecycleStrategy;
mSurfaceLifecycleStrategy = mRequestedSurfaceLifecycleStrategy;
mScreenRect.left = mWindowSpaceLeft;
mScreenRect.top = mWindowSpaceTop;
mScreenRect.right = mWindowSpaceLeft + getWidth();
mScreenRect.bottom = mWindowSpaceTop + getHeight();
if (translator != null) {
translator.translateRectInAppWindowToScreen(mScreenRect);
}
final Rect surfaceInsets = viewRoot.mWindowAttributes.surfaceInsets;
mScreenRect.offset(surfaceInsets.left, surfaceInsets.top);
// Collect all geometry changes and apply these changes on the RenderThread worker
// via the RenderNode.PositionUpdateListener.
final Transaction surfaceUpdateTransaction = new Transaction();
if (creating) {
updateOpaqueFlag();
final String name = "SurfaceView[" + viewRoot.getTitle().toString() + "]";
createBlastSurfaceControls(viewRoot, name, surfaceUpdateTransaction);
} else if (mSurfaceControl == null) {
return;
}
final boolean redrawNeeded = sizeChanged || creating || hintChanged
|| (mVisible && !mDrawFinished) || alphaChanged || relativeZChanged;
boolean shouldSyncBuffer = redrawNeeded && viewRoot.wasRelayoutRequested()
&& viewRoot.isInWMSRequestedSync();
SyncBufferTransactionCallback syncBufferTransactionCallback = null;
if (shouldSyncBuffer) {
syncBufferTransactionCallback = new SyncBufferTransactionCallback();
mBlastBufferQueue.syncNextTransaction(
false /* acquireSingleBuffer */,
syncBufferTransactionCallback::onTransactionReady);
}
final boolean realSizeChanged = performSurfaceTransaction(viewRoot, translator,
creating, sizeChanged, hintChanged, relativeZChanged,
surfaceUpdateTransaction);
try {
SurfaceHolder.Callback[] callbacks = null;
final boolean surfaceChanged = creating;
final boolean respectVisibility =
mSurfaceLifecycleStrategy != SURFACE_LIFECYCLE_FOLLOWS_ATTACHMENT;
final boolean previouslyDidNotRespectVisibility =
previousSurfaceLifecycleStrategy
== SURFACE_LIFECYCLE_FOLLOWS_ATTACHMENT;
final boolean lifecycleNewlyRespectsVisibility = respectVisibility
&& previouslyDidNotRespectVisibility;
if (mSurfaceCreated) {
if (surfaceChanged || (!respectVisibility && !mAttachedToWindow)
|| (respectVisibility && !mVisible
&& (visibleChanged || lifecycleNewlyRespectsVisibility))) {
mSurfaceCreated = false;
notifySurfaceDestroyed();
}
}
copySurface(creating /* surfaceControlCreated */, sizeChanged);
if (surfaceShouldExist() && mSurface.isValid()) {
if (!mSurfaceCreated
&& (surfaceChanged || (respectVisibility && visibleChanged))) {
mSurfaceCreated = true;
mIsCreating = true;
if (DEBUG) Log.i(TAG, System.identityHashCode(this) + " "
+ "visibleChanged -- surfaceCreated");
callbacks = getSurfaceCallbacks();
for (SurfaceHolder.Callback c : callbacks) {
c.surfaceCreated(mSurfaceHolder);
}
}
if (creating || formatChanged || sizeChanged || hintChanged
|| (respectVisibility && visibleChanged) || realSizeChanged) {
if (DEBUG) Log.i(TAG, System.identityHashCode(this) + " "
+ "surfaceChanged -- format=" + mFormat
+ " w=" + myWidth + " h=" + myHeight);
if (callbacks == null) {
callbacks = getSurfaceCallbacks();
}
for (SurfaceHolder.Callback c : callbacks) {
c.surfaceChanged(mSurfaceHolder, mFormat, myWidth, myHeight);
}
}
if (redrawNeeded) {
if (DEBUG) {
Log.i(TAG, System.identityHashCode(this) + " surfaceRedrawNeeded");
}
if (callbacks == null) {
callbacks = getSurfaceCallbacks();
}
if (shouldSyncBuffer) {
handleSyncBufferCallback(callbacks, syncBufferTransactionCallback);
} else {
handleSyncNoBuffer(callbacks);
}
}
}
} finally {
mIsCreating = false;
if (mSurfaceControl != null && !mSurfaceCreated) {
releaseSurfaces(false /* releaseSurfacePackage*/);
}
}
} catch (Exception ex) {
Log.e(TAG, "Exception configuring surface", ex);
}
if (DEBUG) Log.v(
TAG, "Layout: x=" + mScreenRect.left + " y=" + mScreenRect.top
+ " w=" + mScreenRect.width() + " h=" + mScreenRect.height()
+ ", frame=" + mSurfaceFrame);
}
}
/**
* @hide
*/
public String getName() {
ViewRootImpl viewRoot = getViewRootImpl();
String viewRootName = viewRoot == null ? "detached" : viewRoot.getTitle().toString();
return "SurfaceView[" + viewRootName + "]";
}
/**
* If SV is trying to be part of the VRI sync, we need to add SV to the VRI sync before
* invoking the redrawNeeded call to the owner. This is to ensure we can set up the SV in
* the sync before the SV owner knows it needs to draw a new frame.
* Once the redrawNeeded callback is invoked, we can stop the continuous sync transaction
* call which will invoke the syncTransaction callback that contains the buffer. The
* code waits until we can retrieve the transaction that contains the buffer before
* notifying the syncer that the buffer is ready.
*/
private void handleSyncBufferCallback(SurfaceHolder.Callback[] callbacks,
SyncBufferTransactionCallback syncBufferTransactionCallback) {
final SurfaceSyncGroup surfaceSyncGroup = new SurfaceSyncGroup(getName());
getViewRootImpl().addToSync(surfaceSyncGroup);
redrawNeededAsync(callbacks, () -> {
Transaction t = null;
if (mBlastBufferQueue != null) {
mBlastBufferQueue.stopContinuousSyncTransaction();
t = syncBufferTransactionCallback.waitForTransaction();
}
surfaceSyncGroup.addTransaction(t);
surfaceSyncGroup.markSyncReady();
onDrawFinished();
});
}
private void handleSyncNoBuffer(SurfaceHolder.Callback[] callbacks) {
final SurfaceSyncGroup surfaceSyncGroup = new SurfaceSyncGroup(getName());
synchronized (mSyncGroups) {
mSyncGroups.add(surfaceSyncGroup);
}
redrawNeededAsync(callbacks, () -> {
synchronized (mSyncGroups) {
mSyncGroups.remove(surfaceSyncGroup);
}
surfaceSyncGroup.markSyncReady();
onDrawFinished();
});
}
private void redrawNeededAsync(SurfaceHolder.Callback[] callbacks,
Runnable callbacksCollected) {
SurfaceCallbackHelper sch = new SurfaceCallbackHelper(callbacksCollected);
sch.dispatchSurfaceRedrawNeededAsync(mSurfaceHolder, callbacks);
}
/**
* @hide
*/
@Override
public void vriDrawStarted(boolean isWmSync) {
ViewRootImpl viewRoot = getViewRootImpl();
synchronized (mSyncGroups) {
if (isWmSync && viewRoot != null) {
for (SurfaceSyncGroup syncGroup : mSyncGroups) {
viewRoot.addToSync(syncGroup);
}
}
mSyncGroups.clear();
}
}
private static class SyncBufferTransactionCallback {
private final CountDownLatch mCountDownLatch = new CountDownLatch(1);
private Transaction mTransaction;
Transaction waitForTransaction() {
try {
mCountDownLatch.await();
} catch (InterruptedException e) {
}
return mTransaction;
}
void onTransactionReady(Transaction t) {
mTransaction = t;
mCountDownLatch.countDown();
}
}
/**
* Copy the Surface from the SurfaceControl or the blast adapter.
*
* @param surfaceControlCreated true if we created the SurfaceControl and need to update our
* Surface if needed.
* @param bufferSizeChanged true if the BufferSize has changed and we need to recreate the
* Surface for compatibility reasons.
*/
private void copySurface(boolean surfaceControlCreated, boolean bufferSizeChanged) {
if (surfaceControlCreated) {
mSurface.copyFrom(mBlastBufferQueue);
}
if (bufferSizeChanged && getContext().getApplicationInfo().targetSdkVersion
< Build.VERSION_CODES.O) {
// Some legacy applications use the underlying native {@link Surface} object
// as a key to whether anything has changed. In these cases, updates to the
// existing {@link Surface} will be ignored when the size changes.
// Therefore, we must explicitly recreate the {@link Surface} in these
// cases.
if (mBlastBufferQueue != null) {
mSurface.transferFrom(mBlastBufferQueue.createSurfaceWithHandle());
}
}
}
private void setBufferSize(Transaction transaction) {
mBlastSurfaceControl.setTransformHint(mTransformHint);
if (mBlastBufferQueue != null) {
mBlastBufferQueue.update(mBlastSurfaceControl, mSurfaceWidth, mSurfaceHeight,
mFormat);
}
}
/**
* Creates the surface control hierarchy as follows
* ViewRootImpl surface
* bounds layer (crops all child surfaces to parent surface insets)
* * SurfaceView surface (drawn relative to ViewRootImpl surface)
* * Blast surface (if enabled)
* * Background color layer (drawn behind all SurfaceView surfaces)
*
* The bounds layer is used to crop the surface view so it does not draw into the parent
* surface inset region. Since there can be multiple surface views below or above the parent
* surface, one option is to create multiple bounds layer for each z order. The other option,
* the one implement is to create a single bounds layer and set z order for each child surface
* relative to the parent surface.
* When creating the surface view, we parent it to the bounds layer and then set the relative z
* order. When the parent surface changes, we have to make sure to update the relative z via
* ViewRootImpl.SurfaceChangedCallback.
*
* We don't recreate the surface controls but only recreate the adapter. Since the blast layer
* is still alive, the old buffers will continue to be presented until replaced by buffers from
* the new adapter. This means we do not need to track the old surface control and destroy it
* after the client has drawn to avoid any flickers.
*
*/
private void createBlastSurfaceControls(ViewRootImpl viewRoot, String name,
Transaction surfaceUpdateTransaction) {
if (mSurfaceControl == null) {
mSurfaceControl = new SurfaceControl.Builder(mSurfaceSession)
.setName(name)
.setLocalOwnerView(this)
.setParent(viewRoot.updateAndGetBoundsLayer(surfaceUpdateTransaction))
.setCallsite("SurfaceView.updateSurface")
.setContainerLayer()
.build();
}
if (mBlastSurfaceControl == null) {
mBlastSurfaceControl = new SurfaceControl.Builder(mSurfaceSession)
.setName(name + "(BLAST)")
.setLocalOwnerView(this)
.setParent(mSurfaceControl)
.setFlags(mSurfaceFlags)
.setHidden(false)
.setBLASTLayer()
.setCallsite("SurfaceView.updateSurface")
.build();
} else {
// update blast layer
surfaceUpdateTransaction
.setOpaque(mBlastSurfaceControl, (mSurfaceFlags & SurfaceControl.OPAQUE) != 0)
.setSecure(mBlastSurfaceControl, (mSurfaceFlags & SurfaceControl.SECURE) != 0)
.show(mBlastSurfaceControl);
}
if (mBackgroundControl == null) {
mBackgroundControl = new SurfaceControl.Builder(mSurfaceSession)
.setName("Background for " + name)
.setLocalOwnerView(this)
.setOpaque(true)
.setColorLayer()
.setParent(mSurfaceControl)
.setCallsite("SurfaceView.updateSurface")
.build();
}
// Always recreate the IGBP for compatibility. This can be optimized in the future but
// the behavior change will need to be gated by SDK version.
if (mBlastBufferQueue != null) {
mBlastBufferQueue.destroy();
}
mTransformHint = viewRoot.getBufferTransformHint();
mBlastSurfaceControl.setTransformHint(mTransformHint);
mBlastBufferQueue = new BLASTBufferQueue(name, false /* updateDestinationFrame */);
mBlastBufferQueue.update(mBlastSurfaceControl, mSurfaceWidth, mSurfaceHeight, mFormat);
mBlastBufferQueue.setTransactionHangCallback(ViewRootImpl.sTransactionHangCallback);
}
private void onDrawFinished() {
if (DEBUG) {
Log.i(TAG, System.identityHashCode(this) + " "
+ "finishedDrawing");
}
runOnUiThread(this::performDrawFinished);
}
/**
* Sets the surface position and scale. Can be called on
* the UI thread as well as on the renderer thread.
*
* @param transaction Transaction in which to execute.
* @param surface Surface whose location to set.
* @param positionLeft The left position to set.
* @param positionTop The top position to set.
* @param postScaleX The X axis post scale
* @param postScaleY The Y axis post scale
*
* @hide
*/
protected void onSetSurfacePositionAndScale(@NonNull Transaction transaction,
@NonNull SurfaceControl surface, int positionLeft, int positionTop,
float postScaleX, float postScaleY) {
transaction.setPosition(surface, positionLeft, positionTop);
transaction.setMatrix(surface, postScaleX /*dsdx*/, 0f /*dtdx*/,
0f /*dtdy*/, postScaleY /*dsdy*/);
}
/** @hide */
public void requestUpdateSurfacePositionAndScale() {
if (mSurfaceControl == null) {
return;
}
final Transaction transaction = new Transaction();
onSetSurfacePositionAndScale(transaction, mSurfaceControl,
mScreenRect.left, /*positionLeft*/
mScreenRect.top/*positionTop*/ ,
mScreenRect.width() / (float) mSurfaceWidth /*postScaleX*/,
mScreenRect.height() / (float) mSurfaceHeight /*postScaleY*/);
applyTransactionOnVriDraw(transaction);
invalidate();
}
/**
* @return The last render position of the backing surface or an empty rect.
*
* @hide
*/
public @NonNull Rect getSurfaceRenderPosition() {
return mRTLastReportedPosition;
}
private void applyOrMergeTransaction(Transaction t, long frameNumber) {
final ViewRootImpl viewRoot = getViewRootImpl();
if (viewRoot != null) {
// If we are using BLAST, merge the transaction with the viewroot buffer transaction.
viewRoot.mergeWithNextTransaction(t, frameNumber);
} else {
t.apply();
}
}
private final Rect mRTLastReportedPosition = new Rect();
private class SurfaceViewPositionUpdateListener implements RenderNode.PositionUpdateListener {
private final int mRtSurfaceWidth;
private final int mRtSurfaceHeight;
private final SurfaceControl.Transaction mPositionChangedTransaction =
new SurfaceControl.Transaction();
SurfaceViewPositionUpdateListener(int surfaceWidth, int surfaceHeight) {
mRtSurfaceWidth = surfaceWidth;
mRtSurfaceHeight = surfaceHeight;
}
@Override
public void positionChanged(long frameNumber, int left, int top, int right, int bottom) {
try {
if (DEBUG_POSITION) {
Log.d(TAG, String.format(
"%d updateSurfacePosition RenderWorker, frameNr = %d, "
+ "position = [%d, %d, %d, %d] surfaceSize = %dx%d",
System.identityHashCode(SurfaceView.this), frameNumber,
left, top, right, bottom, mRtSurfaceWidth, mRtSurfaceHeight));
}
synchronized (mSurfaceControlLock) {
if (mSurfaceControl == null) return;
mRTLastReportedPosition.set(left, top, right, bottom);
onSetSurfacePositionAndScale(mPositionChangedTransaction, mSurfaceControl,
mRTLastReportedPosition.left /*positionLeft*/,
mRTLastReportedPosition.top /*positionTop*/,
mRTLastReportedPosition.width()
/ (float) mRtSurfaceWidth /*postScaleX*/,
mRTLastReportedPosition.height()
/ (float) mRtSurfaceHeight /*postScaleY*/);
mPositionChangedTransaction.show(mSurfaceControl);
}
applyOrMergeTransaction(mPositionChangedTransaction, frameNumber);
} catch (Exception ex) {
Log.e(TAG, "Exception from repositionChild", ex);
}
}
@Override
public void applyStretch(long frameNumber, float width, float height,
float vecX, float vecY, float maxStretchX, float maxStretchY,
float childRelativeLeft, float childRelativeTop, float childRelativeRight,
float childRelativeBottom) {
mRtTransaction.setStretchEffect(mSurfaceControl, width, height, vecX, vecY,
maxStretchX, maxStretchY, childRelativeLeft, childRelativeTop,
childRelativeRight, childRelativeBottom);
applyOrMergeTransaction(mRtTransaction, frameNumber);
}
@Override
public void positionLost(long frameNumber) {
if (DEBUG_POSITION) {
Log.d(TAG, String.format("%d windowPositionLost, frameNr = %d",
System.identityHashCode(this), frameNumber));
}
mRTLastReportedPosition.setEmpty();
// positionLost can be called while UI thread is un-paused.
synchronized (mSurfaceControlLock) {
if (mSurfaceControl == null) return;
// b/131239825
mRtTransaction.hide(mSurfaceControl);
applyOrMergeTransaction(mRtTransaction, frameNumber);
}
}
}
private SurfaceViewPositionUpdateListener mPositionListener = null;
private SurfaceHolder.Callback[] getSurfaceCallbacks() {
SurfaceHolder.Callback[] callbacks;
synchronized (mCallbacks) {
callbacks = new SurfaceHolder.Callback[mCallbacks.size()];
mCallbacks.toArray(callbacks);
}
return callbacks;
}
private void runOnUiThread(Runnable runnable) {
Handler handler = getHandler();
if (handler != null && handler.getLooper() != Looper.myLooper()) {
handler.post(runnable);
} else {
runnable.run();
}
}
/**
* Check to see if the surface has fixed size dimensions or if the surface's
* dimensions are dimensions are dependent on its current layout.
*
* @return true if the surface has dimensions that are fixed in size
* @hide
*/
@UnsupportedAppUsage(
maxTargetSdk = Build.VERSION_CODES.TIRAMISU,
publicAlternatives = "Track {@link SurfaceHolder#setFixedSize} instead")
public boolean isFixedSize() {
return (mRequestedWidth != -1 || mRequestedHeight != -1);
}
private boolean isAboveParent() {
return mSubLayer >= 0;
}
/**
* Set an opaque background color to use with this {@link SurfaceView} when it's being resized
* and size of the content hasn't updated yet. This color will fill the expanded area when the
* view becomes larger.
* @param bgColor An opaque color to fill the background. Alpha component will be ignored.
* @hide
*/
public void setResizeBackgroundColor(int bgColor) {
final SurfaceControl.Transaction transaction = new SurfaceControl.Transaction();
setResizeBackgroundColor(transaction, bgColor);
applyTransactionOnVriDraw(transaction);
invalidate();
}
/**
* Version of {@link #setResizeBackgroundColor(int)} that allows you to provide
* {@link SurfaceControl.Transaction}.
* @hide
*/
public void setResizeBackgroundColor(@NonNull SurfaceControl.Transaction t, int bgColor) {
if (mBackgroundControl == null) {
return;
}
mBackgroundColor = bgColor;
updateBackgroundColor(t);
}
@UnsupportedAppUsage(
maxTargetSdk = Build.VERSION_CODES.TIRAMISU,
publicAlternatives = "Use {@link SurfaceView#getHolder} instead")
private final SurfaceHolder mSurfaceHolder = new SurfaceHolder() {
private static final String LOG_TAG = "SurfaceHolder";
@Override
public boolean isCreating() {
return mIsCreating;
}
@Override
public void addCallback(Callback callback) {
synchronized (mCallbacks) {
// This is a linear search, but in practice we'll
// have only a couple callbacks, so it doesn't matter.
if (!mCallbacks.contains(callback)) {
mCallbacks.add(callback);
}
}
}
@Override
public void removeCallback(Callback callback) {
synchronized (mCallbacks) {
mCallbacks.remove(callback);
}
}
@Override
public void setFixedSize(int width, int height) {
if (mRequestedWidth != width || mRequestedHeight != height) {
if (DEBUG_POSITION) {
Log.d(TAG, String.format("%d setFixedSize %dx%d -> %dx%d",
System.identityHashCode(this), mRequestedWidth, mRequestedHeight, width,
height));
}
mRequestedWidth = width;
mRequestedHeight = height;
requestLayout();
}
}
@Override
public void setSizeFromLayout() {
if (mRequestedWidth != -1 || mRequestedHeight != -1) {
if (DEBUG_POSITION) {
Log.d(TAG, String.format("%d setSizeFromLayout was %dx%d",
System.identityHashCode(this), mRequestedWidth, mRequestedHeight));
}
mRequestedWidth = mRequestedHeight = -1;
requestLayout();
}
}
@Override
public void setFormat(int format) {
// for backward compatibility reason, OPAQUE always
// means 565 for SurfaceView
if (format == PixelFormat.OPAQUE)
format = PixelFormat.RGB_565;
mRequestedFormat = format;
if (mSurfaceControl != null) {
updateSurface();
}
}
/**
* @deprecated setType is now ignored.
*/
@Override
@Deprecated
public void setType(int type) { }
@Override
public void setKeepScreenOn(boolean screenOn) {
runOnUiThread(() -> SurfaceView.this.setKeepScreenOn(screenOn));
}
/**
* Gets a {@link Canvas} for drawing into the SurfaceView's Surface
*
* After drawing into the provided {@link Canvas}, the caller must
* invoke {@link #unlockCanvasAndPost} to post the new contents to the surface.
*
* The caller must redraw the entire surface.
* @return A canvas for drawing into the surface.
*/
@Override
public Canvas lockCanvas() {
return internalLockCanvas(null, false);
}
/**
* Gets a {@link Canvas} for drawing into the SurfaceView's Surface
*
* After drawing into the provided {@link Canvas}, the caller must
* invoke {@link #unlockCanvasAndPost} to post the new contents to the surface.
*
* @param inOutDirty A rectangle that represents the dirty region that the caller wants
* to redraw. This function may choose to expand the dirty rectangle if for example
* the surface has been resized or if the previous contents of the surface were
* not available. The caller must redraw the entire dirty region as represented
* by the contents of the inOutDirty rectangle upon return from this function.
* The caller may also pass null instead, in the case where the
* entire surface should be redrawn.
* @return A canvas for drawing into the surface.
*/
@Override
public Canvas lockCanvas(Rect inOutDirty) {
return internalLockCanvas(inOutDirty, false);
}
@Override
public Canvas lockHardwareCanvas() {
return internalLockCanvas(null, true);
}
private Canvas internalLockCanvas(Rect dirty, boolean hardware) {
mSurfaceLock.lock();
if (DEBUG) Log.i(TAG, System.identityHashCode(this) + " " + "Locking canvas... stopped="
+ mDrawingStopped + ", surfaceControl=" + mSurfaceControl);
Canvas c = null;
if (!mDrawingStopped && mSurfaceControl != null) {
try {
if (hardware) {
c = mSurface.lockHardwareCanvas();
} else {
c = mSurface.lockCanvas(dirty);
}
} catch (Exception e) {
Log.e(LOG_TAG, "Exception locking surface", e);
}
}
if (DEBUG) Log.i(TAG, System.identityHashCode(this) + " " + "Returned canvas: " + c);
if (c != null) {
mLastLockTime = SystemClock.uptimeMillis();
return c;
}
// If the Surface is not ready to be drawn, then return null,
// but throttle calls to this function so it isn't called more
// than every 100ms.
long now = SystemClock.uptimeMillis();
long nextTime = mLastLockTime + 100;
if (nextTime > now) {
try {
Thread.sleep(nextTime-now);
} catch (InterruptedException e) {
}
now = SystemClock.uptimeMillis();
}
mLastLockTime = now;
mSurfaceLock.unlock();
return null;
}
/**
* Posts the new contents of the {@link Canvas} to the surface and
* releases the {@link Canvas}.
*
* @param canvas The canvas previously obtained from {@link #lockCanvas}.
*/
@Override
public void unlockCanvasAndPost(Canvas canvas) {
try {
mSurface.unlockCanvasAndPost(canvas);
} finally {
mSurfaceLock.unlock();
}
}
@Override
public Surface getSurface() {
return mSurface;
}
@Override
public Rect getSurfaceFrame() {
return mSurfaceFrame;
}
};
/**
* Return a SurfaceControl which can be used for parenting Surfaces to this SurfaceView.
*
* Note that this SurfaceControl is effectively read-only. Its only well-defined usage is in
* using the SurfaceControl as a parent for an application's hierarchy of SurfaceControls. All
* other properties of the SurfaceControl, such as its position, may be mutated by the
* SurfaceView at any time which will override what the application is requesting. Do not apply
* any {@link SurfaceControl.Transaction} to this SurfaceControl except for reparenting
* child SurfaceControls. See: {@link SurfaceControl.Transaction#reparent}.
*
* @return The SurfaceControl for this SurfaceView.
*/
public SurfaceControl getSurfaceControl() {
return mSurfaceControl;
}
/**
* A token used for constructing {@link SurfaceControlViewHost}. This token should
* be passed from the host process to the client process.
*
* @return The token
*/
public @Nullable IBinder getHostToken() {
final ViewRootImpl viewRoot = getViewRootImpl();
if (viewRoot == null) {
return null;
}
return viewRoot.getInputToken();
}
/**
* Set window stopped to false and update surface visibility when ViewRootImpl surface is
* created.
* @hide
*/
@Override
public void surfaceCreated(SurfaceControl.Transaction t) {
setWindowStopped(false);
}
/**
* Set window stopped to true and update surface visibility when ViewRootImpl surface is
* destroyed.
* @hide
*/
@Override
public void surfaceDestroyed() {
setWindowStopped(true);
mRemoteAccessibilityController.disassosciateHierarchy();
}
/**
* Called when a valid ViewRootImpl surface is replaced by another valid surface. In this
* case update relative z to the new parent surface.
* @hide
*/
@Override
public void surfaceReplaced(Transaction t) {
if (mSurfaceControl != null && mBackgroundControl != null) {
updateRelativeZ(t);
}
}
private void updateRelativeZ(Transaction t) {
final ViewRootImpl viewRoot = getViewRootImpl();
if (viewRoot == null) {
// We were just detached.
return;
}
final SurfaceControl viewRootControl = viewRoot.getSurfaceControl();
t.setRelativeLayer(mBackgroundControl, viewRootControl, Integer.MIN_VALUE);
t.setRelativeLayer(mSurfaceControl, viewRootControl, mSubLayer);
}
/**
* Display the view-hierarchy embedded within a {@link SurfaceControlViewHost.SurfacePackage}
* within this SurfaceView.
*
* This can be called independently of the SurfaceView lifetime callbacks. SurfaceView
* will internally manage reparenting the package to our Surface as it is created
* and destroyed.
*
* If this SurfaceView is above its host Surface (see
* {@link #setZOrderOnTop} then the embedded Surface hierarchy will be able to receive
* input.
*
* This will take ownership of the SurfaceControl contained inside the SurfacePackage
* and free the caller of the obligation to call
* {@link SurfaceControlViewHost.SurfacePackage#release}. However, note that
* {@link SurfaceControlViewHost.SurfacePackage#release} and
* {@link SurfaceControlViewHost#release} are not the same. While the ownership
* of this particular {@link SurfaceControlViewHost.SurfacePackage} will be taken by the
* SurfaceView the underlying {@link SurfaceControlViewHost} remains managed by it's original
* remote-owner.
*
* @param p The SurfacePackage to embed.
*/
public void setChildSurfacePackage(@NonNull SurfaceControlViewHost.SurfacePackage p) {
final SurfaceControl lastSc = mSurfacePackage != null ?
mSurfacePackage.getSurfaceControl() : null;
final SurfaceControl.Transaction transaction = new Transaction();
if (mSurfaceControl != null) {
if (lastSc != null) {
transaction.reparent(lastSc, null);
mSurfacePackage.release();
}
reparentSurfacePackage(transaction, p);
applyTransactionOnVriDraw(transaction);
}
mSurfacePackage = p;
try {
mSurfacePackage.getRemoteInterface().attachParentInterface(
mSurfaceControlViewHostParent);
} catch (RemoteException e) {
Log.d(TAG, "Failed to attach parent interface to SCVH. Likely SCVH is already dead.");
}
if (isFocused()) {
requestEmbeddedFocus(true);
}
invalidate();
}
private void reparentSurfacePackage(SurfaceControl.Transaction t,
SurfaceControlViewHost.SurfacePackage p) {
final SurfaceControl sc = p.getSurfaceControl();
if (sc == null || !sc.isValid()) {
return;
}
initEmbeddedHierarchyForAccessibility(p);
t.reparent(sc, mBlastSurfaceControl).show(sc);
}
/** @hide */
@Override
public void onInitializeAccessibilityNodeInfoInternal(AccessibilityNodeInfo info) {
super.onInitializeAccessibilityNodeInfoInternal(info);
if (!mRemoteAccessibilityController.connected()) {
return;
}
// Add a leashed child when this SurfaceView embeds another view hierarchy. Getting this
// leashed child would return the root node in the embedded hierarchy
info.addChild(mRemoteAccessibilityController.getLeashToken());
}
@Override
public int getImportantForAccessibility() {
final int mode = super.getImportantForAccessibility();
// If developers explicitly set the important mode for it, don't change the mode.
// Only change the mode to important when this SurfaceView isn't explicitly set and has
// an embedded hierarchy.
if ((mRemoteAccessibilityController!= null && !mRemoteAccessibilityController.connected())
|| mode != IMPORTANT_FOR_ACCESSIBILITY_AUTO) {
return mode;
}
return IMPORTANT_FOR_ACCESSIBILITY_YES;
}
private void initEmbeddedHierarchyForAccessibility(SurfaceControlViewHost.SurfacePackage p) {
final IAccessibilityEmbeddedConnection connection = p.getAccessibilityEmbeddedConnection();
if (mRemoteAccessibilityController.alreadyAssociated(connection)) {
return;
}
mRemoteAccessibilityController.assosciateHierarchy(connection,
getViewRootImpl().mLeashToken, getAccessibilityViewId());
updateEmbeddedAccessibilityMatrix(true);
}
private void notifySurfaceDestroyed() {
if (mSurface.isValid()) {
if (DEBUG) Log.i(TAG, System.identityHashCode(this) + " "
+ "surfaceDestroyed");
SurfaceHolder.Callback[] callbacks = getSurfaceCallbacks();
for (SurfaceHolder.Callback c : callbacks) {
c.surfaceDestroyed(mSurfaceHolder);
}
// Since Android N the same surface may be reused and given to us
// again by the system server at a later point. However
// as we didn't do this in previous releases, clients weren't
// necessarily required to clean up properly in
// surfaceDestroyed. This leads to problems for example when
// clients don't destroy their EGL context, and try
// and create a new one on the same surface following reuse.
// Since there is no valid use of the surface in-between
// surfaceDestroyed and surfaceCreated, we force a disconnect,
// so the next connect will always work if we end up reusing
// the surface.
if (mSurface.isValid()) {
mSurface.forceScopedDisconnect();
}
}
}
void updateEmbeddedAccessibilityMatrix(boolean force) {
if (!mRemoteAccessibilityController.connected()) {
return;
}
getBoundsOnScreen(mTmpRect);
// To compute the node bounds of the node on the embedded window,
// apply this matrix to get the bounds in host window-relative coordinates,
// then using the global transform to get the actual bounds on screen.
mTmpRect.offset(-mAttachInfo.mWindowLeft, -mAttachInfo.mWindowTop);
mTmpMatrix.reset();
mTmpMatrix.setTranslate(mTmpRect.left, mTmpRect.top);
mTmpMatrix.postScale(mScreenRect.width() / (float) mSurfaceWidth,
mScreenRect.height() / (float) mSurfaceHeight);
mRemoteAccessibilityController.setWindowMatrix(mTmpMatrix, force);
}
@Override
protected void onFocusChanged(boolean gainFocus, @FocusDirection int direction,
@Nullable Rect previouslyFocusedRect) {
super.onFocusChanged(gainFocus, direction, previouslyFocusedRect);
requestEmbeddedFocus(gainFocus);
}
private void requestEmbeddedFocus(boolean gainFocus) {
final ViewRootImpl viewRoot = getViewRootImpl();
if (mSurfacePackage == null || viewRoot == null) {
return;
}
try {
viewRoot.mWindowSession.grantEmbeddedWindowFocus(viewRoot.mWindow,
mSurfacePackage.getInputToken(), gainFocus);
} catch (Exception e) {
Log.e(TAG, System.identityHashCode(this)
+ "Exception requesting focus on embedded window", e);
}
}
private void applyTransactionOnVriDraw(Transaction t) {
final ViewRootImpl viewRoot = getViewRootImpl();
if (viewRoot != null) {
// If we are using BLAST, merge the transaction with the viewroot buffer transaction.
viewRoot.applyTransactionOnDraw(t);
} else {
t.apply();
}
}
/**
* @hide
*/
public void syncNextFrame(Consumer