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android / platform / frameworks / base / 41c4da37ed9fc69eb53787f2d458d6d0a51225a9 / . / services / core / java / com / android / server / display / DisplayManagerService.java
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/*
* Copyright (C) 2012 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 com.android.server.display;
import static android.Manifest.permission.CAPTURE_SECURE_VIDEO_OUTPUT;
import static android.Manifest.permission.CAPTURE_VIDEO_OUTPUT;
import static android.Manifest.permission.INTERNAL_SYSTEM_WINDOW;
import static android.hardware.display.DisplayManager.VIRTUAL_DISPLAY_FLAG_AUTO_MIRROR;
import static android.hardware.display.DisplayManager.VIRTUAL_DISPLAY_FLAG_CAN_SHOW_WITH_INSECURE_KEYGUARD;
import static android.hardware.display.DisplayManager.VIRTUAL_DISPLAY_FLAG_OWN_CONTENT_ONLY;
import static android.hardware.display.DisplayManager.VIRTUAL_DISPLAY_FLAG_PUBLIC;
import static android.hardware.display.DisplayManager.VIRTUAL_DISPLAY_FLAG_SECURE;
import static android.hardware.display.DisplayManager.VIRTUAL_DISPLAY_FLAG_SHOULD_SHOW_SYSTEM_DECORATIONS;
import static android.hardware.display.DisplayViewport.VIEWPORT_EXTERNAL;
import static android.hardware.display.DisplayViewport.VIEWPORT_INTERNAL;
import static android.hardware.display.DisplayViewport.VIEWPORT_VIRTUAL;
import android.Manifest;
import android.annotation.NonNull;
import android.annotation.Nullable;
import android.annotation.UserIdInt;
import android.app.AppOpsManager;
import android.content.Context;
import android.content.pm.PackageManager;
import android.content.pm.ParceledListSlice;
import android.content.res.Resources;
import android.content.res.TypedArray;
import android.graphics.ColorSpace;
import android.graphics.Point;
import android.graphics.Rect;
import android.hardware.SensorManager;
import android.hardware.display.AmbientBrightnessDayStats;
import android.hardware.display.BrightnessChangeEvent;
import android.hardware.display.BrightnessConfiguration;
import android.hardware.display.Curve;
import android.hardware.display.DisplayManagerGlobal;
import android.hardware.display.DisplayManagerInternal;
import android.hardware.display.DisplayManagerInternal.DisplayTransactionListener;
import android.hardware.display.DisplayViewport;
import android.hardware.display.DisplayedContentSample;
import android.hardware.display.DisplayedContentSamplingAttributes;
import android.hardware.display.IDisplayManager;
import android.hardware.display.IDisplayManagerCallback;
import android.hardware.display.IVirtualDisplayCallback;
import android.hardware.display.WifiDisplayStatus;
import android.hardware.input.InputManagerInternal;
import android.media.projection.IMediaProjection;
import android.media.projection.IMediaProjectionManager;
import android.os.Binder;
import android.os.Handler;
import android.os.IBinder;
import android.os.IBinder.DeathRecipient;
import android.os.Looper;
import android.os.Message;
import android.os.PowerManager;
import android.os.Process;
import android.os.RemoteException;
import android.os.ResultReceiver;
import android.os.ServiceManager;
import android.os.ShellCallback;
import android.os.SystemClock;
import android.os.SystemProperties;
import android.os.Trace;
import android.os.UserHandle;
import android.os.UserManager;
import android.provider.Settings;
import android.text.TextUtils;
import android.util.IntArray;
import android.util.Pair;
import android.util.Slog;
import android.util.SparseArray;
import android.util.Spline;
import android.view.Display;
import android.view.DisplayInfo;
import android.view.Surface;
import android.view.SurfaceControl;
import com.android.internal.annotations.GuardedBy;
import com.android.internal.annotations.VisibleForTesting;
import com.android.internal.util.DumpUtils;
import com.android.internal.util.IndentingPrintWriter;
import com.android.server.AnimationThread;
import com.android.server.DisplayThread;
import com.android.server.LocalServices;
import com.android.server.SystemService;
import com.android.server.UiThread;
import com.android.server.wm.SurfaceAnimationThread;
import com.android.server.wm.WindowManagerInternal;
import java.io.FileDescriptor;
import java.io.PrintWriter;
import java.util.ArrayList;
import java.util.Arrays;
import java.util.List;
import java.util.concurrent.CopyOnWriteArrayList;
/**
* Manages attached displays.
* <p>
* The {@link DisplayManagerService} manages the global lifecycle of displays,
* decides how to configure logical displays based on the physical display devices currently
* attached, sends notifications to the system and to applications when the state
* changes, and so on.
* </p><p>
* The display manager service relies on a collection of {@link DisplayAdapter} components,
* for discovering and configuring physical display devices attached to the system.
* There are separate display adapters for each manner that devices are attached:
* one display adapter for built-in local displays, one for simulated non-functional
* displays when the system is headless, one for simulated overlay displays used for
* development, one for wifi displays, etc.
* </p><p>
* Display adapters are only weakly coupled to the display manager service.
* Display adapters communicate changes in display device state to the display manager
* service asynchronously via a {@link DisplayAdapter.Listener} registered
* by the display manager service. This separation of concerns is important for
* two main reasons. First, it neatly encapsulates the responsibilities of these
* two classes: display adapters handle individual display devices whereas
* the display manager service handles the global state. Second, it eliminates
* the potential for deadlocks resulting from asynchronous display device discovery.
* </p>
*
* <h3>Synchronization</h3>
* <p>
* Because the display manager may be accessed by multiple threads, the synchronization
* story gets a little complicated. In particular, the window manager may call into
* the display manager while holding a surface transaction with the expectation that
* it can apply changes immediately. Unfortunately, that means we can't just do
* everything asynchronously (*grump*).
* </p><p>
* To make this work, all of the objects that belong to the display manager must
* use the same lock. We call this lock the synchronization root and it has a unique
* type {@link DisplayManagerService.SyncRoot}. Methods that require this lock are
* named with the "Locked" suffix.
* </p><p>
* Where things get tricky is that the display manager is not allowed to make
* any potentially reentrant calls, especially into the window manager. We generally
* avoid this by making all potentially reentrant out-calls asynchronous.
* </p>
*/
public final class DisplayManagerService extends SystemService {
private static final String TAG = "DisplayManagerService";
private static final boolean DEBUG = false;
// When this system property is set to 0, WFD is forcibly disabled on boot.
// When this system property is set to 1, WFD is forcibly enabled on boot.
// Otherwise WFD is enabled according to the value of config_enableWifiDisplay.
private static final String FORCE_WIFI_DISPLAY_ENABLE = "persist.debug.wfd.enable";
private static final String PROP_DEFAULT_DISPLAY_TOP_INSET = "persist.sys.displayinset.top";
private static final long WAIT_FOR_DEFAULT_DISPLAY_TIMEOUT = 10000;
private static final int MSG_REGISTER_DEFAULT_DISPLAY_ADAPTERS = 1;
private static final int MSG_REGISTER_ADDITIONAL_DISPLAY_ADAPTERS = 2;
private static final int MSG_DELIVER_DISPLAY_EVENT = 3;
private static final int MSG_REQUEST_TRAVERSAL = 4;
private static final int MSG_UPDATE_VIEWPORT = 5;
private static final int MSG_LOAD_BRIGHTNESS_CONFIGURATION = 6;
private final Context mContext;
private final DisplayManagerHandler mHandler;
private final Handler mUiHandler;
private final DisplayAdapterListener mDisplayAdapterListener;
private final DisplayModeDirector mDisplayModeDirector;
private WindowManagerInternal mWindowManagerInternal;
private InputManagerInternal mInputManagerInternal;
private IMediaProjectionManager mProjectionService;
// The synchronization root for the display manager.
// This lock guards most of the display manager's state.
// NOTE: This is synchronized on while holding WindowManagerService.mWindowMap so never call
// into WindowManagerService methods that require mWindowMap while holding this unless you are
// very very sure that no deadlock can occur.
private final SyncRoot mSyncRoot = new SyncRoot();
// True if in safe mode.
// This option may disable certain display adapters.
public boolean mSafeMode;
// True if we are in a special boot mode where only core applications and
// services should be started. This option may disable certain display adapters.
public boolean mOnlyCore;
// True if the display manager service should pretend there is only one display
// and only tell applications about the existence of the default logical display.
// The display manager can still mirror content to secondary displays but applications
// cannot present unique content on those displays.
// Used for demonstration purposes only.
private final boolean mSingleDisplayDemoMode;
// All callback records indexed by calling process id.
public final SparseArray<CallbackRecord> mCallbacks =
new SparseArray<CallbackRecord>();
// List of all currently registered display adapters.
private final ArrayList<DisplayAdapter> mDisplayAdapters = new ArrayList<DisplayAdapter>();
// List of all currently connected display devices.
private final ArrayList<DisplayDevice> mDisplayDevices = new ArrayList<DisplayDevice>();
// List of all logical displays indexed by logical display id.
private final SparseArray<LogicalDisplay> mLogicalDisplays =
new SparseArray<LogicalDisplay>();
private int mNextNonDefaultDisplayId = Display.DEFAULT_DISPLAY + 1;
// List of all display transaction listeners.
private final CopyOnWriteArrayList<DisplayTransactionListener> mDisplayTransactionListeners =
new CopyOnWriteArrayList<DisplayTransactionListener>();
// Display power controller.
private DisplayPowerController mDisplayPowerController;
// The overall display state, independent of changes that might influence one
// display or another in particular.
private int mGlobalDisplayState = Display.STATE_ON;
// The overall display brightness.
// For now, this only applies to the built-in display but we may split it up eventually.
private int mGlobalDisplayBrightness = PowerManager.BRIGHTNESS_DEFAULT;
// Set to true when there are pending display changes that have yet to be applied
// to the surface flinger state.
private boolean mPendingTraversal;
// The Wifi display adapter, or null if not registered.
private WifiDisplayAdapter mWifiDisplayAdapter;
// The number of active wifi display scan requests.
private int mWifiDisplayScanRequestCount;
// The virtual display adapter, or null if not registered.
private VirtualDisplayAdapter mVirtualDisplayAdapter;
// The User ID of the current user
private @UserIdInt int mCurrentUserId;
// The stable device screen height and width. These are not tied to a specific display, even
// the default display, because they need to be stable over the course of the device's entire
// life, even if the default display changes (e.g. a new monitor is plugged into a PC-like
// device).
private Point mStableDisplaySize = new Point();
// Whether the system has finished booting or not.
private boolean mSystemReady;
// The top inset of the default display.
// This gets persisted so that the boot animation knows how to transition from the display's
// full size to the size configured by the user. Right now we only persist and animate the top
// inset, but theoretically we could do it for all of them.
private int mDefaultDisplayTopInset;
// Viewports of the default display and the display that should receive touch
// input from an external source. Used by the input system.
@GuardedBy("mSyncRoot")
private final ArrayList<DisplayViewport> mViewports = new ArrayList<>();
// Persistent data store for all internal settings maintained by the display manager service.
private final PersistentDataStore mPersistentDataStore = new PersistentDataStore();
// Temporary callback list, used when sending display events to applications.
// May be used outside of the lock but only on the handler thread.
private final ArrayList<CallbackRecord> mTempCallbacks = new ArrayList<CallbackRecord>();
// Temporary display info, used for comparing display configurations.
private final DisplayInfo mTempDisplayInfo = new DisplayInfo();
// Temporary viewports, used when sending new viewport information to the
// input system. May be used outside of the lock but only on the handler thread.
private final ArrayList<DisplayViewport> mTempViewports = new ArrayList<>();
// The default color mode for default displays. Overrides the usual
// Display.Display.COLOR_MODE_DEFAULT for displays with the
// DisplayDeviceInfo.FLAG_DEFAULT_DISPLAY flag set.
private final int mDefaultDisplayDefaultColorMode;
// Temporary list of deferred work to perform when setting the display state.
// Only used by requestDisplayState. The field is self-synchronized and only
// intended for use inside of the requestGlobalDisplayStateInternal function.
private final ArrayList<Runnable> mTempDisplayStateWorkQueue = new ArrayList<Runnable>();
// Lists of UIDs that are present on the displays. Maps displayId -> array of UIDs.
private final SparseArray<IntArray> mDisplayAccessUIDs = new SparseArray<>();
private final Injector mInjector;
// The minimum brightness curve, which guarantess that any brightness curve that dips below it
// is rejected by the system.
private final Curve mMinimumBrightnessCurve;
private final Spline mMinimumBrightnessSpline;
private final ColorSpace mWideColorSpace;
private SensorManager mSensorManager;
public DisplayManagerService(Context context) {
this(context, new Injector());
}
@VisibleForTesting
DisplayManagerService(Context context, Injector injector) {
super(context);
mInjector = injector;
mContext = context;
mHandler = new DisplayManagerHandler(DisplayThread.get().getLooper());
mUiHandler = UiThread.getHandler();
mDisplayAdapterListener = new DisplayAdapterListener();
mDisplayModeDirector = new DisplayModeDirector(context, mHandler);
mSingleDisplayDemoMode = SystemProperties.getBoolean("persist.demo.singledisplay", false);
Resources resources = mContext.getResources();
mDefaultDisplayDefaultColorMode = mContext.getResources().getInteger(
com.android.internal.R.integer.config_defaultDisplayDefaultColorMode);
mDefaultDisplayTopInset = SystemProperties.getInt(PROP_DEFAULT_DISPLAY_TOP_INSET, -1);
float[] lux = getFloatArray(resources.obtainTypedArray(
com.android.internal.R.array.config_minimumBrightnessCurveLux));
float[] nits = getFloatArray(resources.obtainTypedArray(
com.android.internal.R.array.config_minimumBrightnessCurveNits));
mMinimumBrightnessCurve = new Curve(lux, nits);
mMinimumBrightnessSpline = Spline.createSpline(lux, nits);
PowerManager pm = mContext.getSystemService(PowerManager.class);
mGlobalDisplayBrightness = pm.getDefaultScreenBrightnessSetting();
mCurrentUserId = UserHandle.USER_SYSTEM;
ColorSpace[] colorSpaces = SurfaceControl.getCompositionColorSpaces();
mWideColorSpace = colorSpaces[1];
mSystemReady = false;
}
public void setupSchedulerPolicies() {
// android.display and android.anim is critical to user experience and we should make sure
// it is not in the default foregroup groups, add it to top-app to make sure it uses all
// the cores and scheduling settings for top-app when it runs.
Process.setThreadGroupAndCpuset(DisplayThread.get().getThreadId(),
Process.THREAD_GROUP_TOP_APP);
Process.setThreadGroupAndCpuset(AnimationThread.get().getThreadId(),
Process.THREAD_GROUP_TOP_APP);
Process.setThreadGroupAndCpuset(SurfaceAnimationThread.get().getThreadId(),
Process.THREAD_GROUP_TOP_APP);
}
@Override
public void onStart() {
// We need to pre-load the persistent data store so it's ready before the default display
// adapter is up so that we have it's configuration. We could load it lazily, but since
// we're going to have to read it in eventually we may as well do it here rather than after
// we've waited for the display to register itself with us.
synchronized (mSyncRoot) {
mPersistentDataStore.loadIfNeeded();
loadStableDisplayValuesLocked();
}
mHandler.sendEmptyMessage(MSG_REGISTER_DEFAULT_DISPLAY_ADAPTERS);
publishBinderService(Context.DISPLAY_SERVICE, new BinderService(),
true /*allowIsolated*/);
publishLocalService(DisplayManagerInternal.class, new LocalService());
}
@Override
public void onBootPhase(int phase) {
if (phase == PHASE_WAIT_FOR_DEFAULT_DISPLAY) {
synchronized (mSyncRoot) {
long timeout = SystemClock.uptimeMillis()
+ mInjector.getDefaultDisplayDelayTimeout();
while (mLogicalDisplays.get(Display.DEFAULT_DISPLAY) == null ||
mVirtualDisplayAdapter == null) {
long delay = timeout - SystemClock.uptimeMillis();
if (delay <= 0) {
throw new RuntimeException("Timeout waiting for default display "
+ "to be initialized. DefaultDisplay="
+ mLogicalDisplays.get(Display.DEFAULT_DISPLAY)
+ ", mVirtualDisplayAdapter=" + mVirtualDisplayAdapter);
}
if (DEBUG) {
Slog.d(TAG, "waitForDefaultDisplay: waiting, timeout=" + delay);
}
try {
mSyncRoot.wait(delay);
} catch (InterruptedException ex) {
}
}
}
}
}
@Override
public void onSwitchUser(@UserIdInt int newUserId) {
final int userSerial = getUserManager().getUserSerialNumber(newUserId);
synchronized (mSyncRoot) {
if (mCurrentUserId != newUserId) {
mCurrentUserId = newUserId;
BrightnessConfiguration config =
mPersistentDataStore.getBrightnessConfiguration(userSerial);
mDisplayPowerController.setBrightnessConfiguration(config);
}
mDisplayPowerController.onSwitchUser(newUserId);
}
}
// TODO: Use dependencies or a boot phase
public void windowManagerAndInputReady() {
synchronized (mSyncRoot) {
mWindowManagerInternal = LocalServices.getService(WindowManagerInternal.class);
mInputManagerInternal = LocalServices.getService(InputManagerInternal.class);
scheduleTraversalLocked(false);
}
}
/**
* Called when the system is ready to go.
*/
public void systemReady(boolean safeMode, boolean onlyCore) {
synchronized (mSyncRoot) {
mSafeMode = safeMode;
mOnlyCore = onlyCore;
mSystemReady = true;
// Just in case the top inset changed before the system was ready. At this point, any
// relevant configuration should be in place.
recordTopInsetLocked(mLogicalDisplays.get(Display.DEFAULT_DISPLAY));
}
mDisplayModeDirector.setListener(new AllowedDisplayModeObserver());
mDisplayModeDirector.start(mSensorManager);
mHandler.sendEmptyMessage(MSG_REGISTER_ADDITIONAL_DISPLAY_ADAPTERS);
}
@VisibleForTesting
Handler getDisplayHandler() {
return mHandler;
}
private void loadStableDisplayValuesLocked() {
final Point size = mPersistentDataStore.getStableDisplaySize();
if (size.x > 0 && size.y > 0) {
// Just set these values directly so we don't write the display persistent data again
// unnecessarily
mStableDisplaySize.set(size.x, size.y);
} else {
final Resources res = mContext.getResources();
final int width = res.getInteger(
com.android.internal.R.integer.config_stableDeviceDisplayWidth);
final int height = res.getInteger(
com.android.internal.R.integer.config_stableDeviceDisplayHeight);
if (width > 0 && height > 0) {
setStableDisplaySizeLocked(width, height);
}
}
}
private Point getStableDisplaySizeInternal() {
Point r = new Point();
synchronized (mSyncRoot) {
if (mStableDisplaySize.x > 0 && mStableDisplaySize.y > 0) {
r.set(mStableDisplaySize.x, mStableDisplaySize.y);
}
}
return r;
}
private void registerDisplayTransactionListenerInternal(
DisplayTransactionListener listener) {
// List is self-synchronized copy-on-write.
mDisplayTransactionListeners.add(listener);
}
private void unregisterDisplayTransactionListenerInternal(
DisplayTransactionListener listener) {
// List is self-synchronized copy-on-write.
mDisplayTransactionListeners.remove(listener);
}
private void setDisplayInfoOverrideFromWindowManagerInternal(
int displayId, DisplayInfo info) {
synchronized (mSyncRoot) {
LogicalDisplay display = mLogicalDisplays.get(displayId);
if (display != null) {
if (display.setDisplayInfoOverrideFromWindowManagerLocked(info)) {
handleLogicalDisplayChanged(displayId, display);
scheduleTraversalLocked(false);
}
}
}
}
/**
* @see DisplayManagerInternal#getNonOverrideDisplayInfo(int, DisplayInfo)
*/
private void getNonOverrideDisplayInfoInternal(int displayId, DisplayInfo outInfo) {
synchronized (mSyncRoot) {
final LogicalDisplay display = mLogicalDisplays.get(displayId);
if (display != null) {
display.getNonOverrideDisplayInfoLocked(outInfo);
}
}
}
@VisibleForTesting
void performTraversalInternal(SurfaceControl.Transaction t) {
synchronized (mSyncRoot) {
if (!mPendingTraversal) {
return;
}
mPendingTraversal = false;
performTraversalLocked(t);
}
// List is self-synchronized copy-on-write.
for (DisplayTransactionListener listener : mDisplayTransactionListeners) {
listener.onDisplayTransaction(t);
}
}
private void requestGlobalDisplayStateInternal(int state, int brightness) {
if (state == Display.STATE_UNKNOWN) {
state = Display.STATE_ON;
}
if (state == Display.STATE_OFF) {
brightness = PowerManager.BRIGHTNESS_OFF;
} else if (brightness < 0) {
brightness = PowerManager.BRIGHTNESS_DEFAULT;
} else if (brightness > PowerManager.BRIGHTNESS_ON) {
brightness = PowerManager.BRIGHTNESS_ON;
}
synchronized (mTempDisplayStateWorkQueue) {
try {
// Update the display state within the lock.
// Note that we do not need to schedule traversals here although it
// may happen as a side-effect of displays changing state.
synchronized (mSyncRoot) {
if (mGlobalDisplayState == state
&& mGlobalDisplayBrightness == brightness) {
return; // no change
}
Trace.traceBegin(Trace.TRACE_TAG_POWER, "requestGlobalDisplayState("
+ Display.stateToString(state)
+ ", brightness=" + brightness + ")");
mGlobalDisplayState = state;
mGlobalDisplayBrightness = brightness;
applyGlobalDisplayStateLocked(mTempDisplayStateWorkQueue);
}
// Setting the display power state can take hundreds of milliseconds
// to complete so we defer the most expensive part of the work until
// after we have exited the critical section to avoid blocking other
// threads for a long time.
for (int i = 0; i < mTempDisplayStateWorkQueue.size(); i++) {
mTempDisplayStateWorkQueue.get(i).run();
}
Trace.traceEnd(Trace.TRACE_TAG_POWER);
} finally {
mTempDisplayStateWorkQueue.clear();
}
}
}
private DisplayInfo getDisplayInfoInternal(int displayId, int callingUid) {
synchronized (mSyncRoot) {
LogicalDisplay display = mLogicalDisplays.get(displayId);
if (display != null) {
DisplayInfo info = display.getDisplayInfoLocked();
if (info.hasAccess(callingUid)
|| isUidPresentOnDisplayInternal(callingUid, displayId)) {
return info;
}
}
return null;
}
}
private int[] getDisplayIdsInternal(int callingUid) {
synchronized (mSyncRoot) {
final int count = mLogicalDisplays.size();
int[] displayIds = new int[count];
int n = 0;
for (int i = 0; i < count; i++) {
LogicalDisplay display = mLogicalDisplays.valueAt(i);
DisplayInfo info = display.getDisplayInfoLocked();
if (info.hasAccess(callingUid)) {
displayIds[n++] = mLogicalDisplays.keyAt(i);
}
}
if (n != count) {
displayIds = Arrays.copyOfRange(displayIds, 0, n);
}
return displayIds;
}
}
private void registerCallbackInternal(IDisplayManagerCallback callback, int callingPid) {
synchronized (mSyncRoot) {
if (mCallbacks.get(callingPid) != null) {
throw new SecurityException("The calling process has already "
+ "registered an IDisplayManagerCallback.");
}
CallbackRecord record = new CallbackRecord(callingPid, callback);
try {
IBinder binder = callback.asBinder();
binder.linkToDeath(record, 0);
} catch (RemoteException ex) {
// give up
throw new RuntimeException(ex);
}
mCallbacks.put(callingPid, record);
}
}
private void onCallbackDied(CallbackRecord record) {
synchronized (mSyncRoot) {
mCallbacks.remove(record.mPid);
stopWifiDisplayScanLocked(record);
}
}
private void startWifiDisplayScanInternal(int callingPid) {
synchronized (mSyncRoot) {
CallbackRecord record = mCallbacks.get(callingPid);
if (record == null) {
throw new IllegalStateException("The calling process has not "
+ "registered an IDisplayManagerCallback.");
}
startWifiDisplayScanLocked(record);
}
}
private void startWifiDisplayScanLocked(CallbackRecord record) {
if (!record.mWifiDisplayScanRequested) {
record.mWifiDisplayScanRequested = true;
if (mWifiDisplayScanRequestCount++ == 0) {
if (mWifiDisplayAdapter != null) {
mWifiDisplayAdapter.requestStartScanLocked();
}
}
}
}
private void stopWifiDisplayScanInternal(int callingPid) {
synchronized (mSyncRoot) {
CallbackRecord record = mCallbacks.get(callingPid);
if (record == null) {
throw new IllegalStateException("The calling process has not "
+ "registered an IDisplayManagerCallback.");
}
stopWifiDisplayScanLocked(record);
}
}
private void stopWifiDisplayScanLocked(CallbackRecord record) {
if (record.mWifiDisplayScanRequested) {
record.mWifiDisplayScanRequested = false;
if (--mWifiDisplayScanRequestCount == 0) {
if (mWifiDisplayAdapter != null) {
mWifiDisplayAdapter.requestStopScanLocked();
}
} else if (mWifiDisplayScanRequestCount < 0) {
Slog.wtf(TAG, "mWifiDisplayScanRequestCount became negative: "
+ mWifiDisplayScanRequestCount);
mWifiDisplayScanRequestCount = 0;
}
}
}
private void connectWifiDisplayInternal(String address) {
synchronized (mSyncRoot) {
if (mWifiDisplayAdapter != null) {
mWifiDisplayAdapter.requestConnectLocked(address);
}
}
}
private void pauseWifiDisplayInternal() {
synchronized (mSyncRoot) {
if (mWifiDisplayAdapter != null) {
mWifiDisplayAdapter.requestPauseLocked();
}
}
}
private void resumeWifiDisplayInternal() {
synchronized (mSyncRoot) {
if (mWifiDisplayAdapter != null) {
mWifiDisplayAdapter.requestResumeLocked();
}
}
}
private void disconnectWifiDisplayInternal() {
synchronized (mSyncRoot) {
if (mWifiDisplayAdapter != null) {
mWifiDisplayAdapter.requestDisconnectLocked();
}
}
}
private void renameWifiDisplayInternal(String address, String alias) {
synchronized (mSyncRoot) {
if (mWifiDisplayAdapter != null) {
mWifiDisplayAdapter.requestRenameLocked(address, alias);
}
}
}
private void forgetWifiDisplayInternal(String address) {
synchronized (mSyncRoot) {
if (mWifiDisplayAdapter != null) {
mWifiDisplayAdapter.requestForgetLocked(address);
}
}
}
private WifiDisplayStatus getWifiDisplayStatusInternal() {
synchronized (mSyncRoot) {
if (mWifiDisplayAdapter != null) {
return mWifiDisplayAdapter.getWifiDisplayStatusLocked();
}
return new WifiDisplayStatus();
}
}
private void requestColorModeInternal(int displayId, int colorMode) {
synchronized (mSyncRoot) {
LogicalDisplay display = mLogicalDisplays.get(displayId);
if (display != null &&
display.getRequestedColorModeLocked() != colorMode) {
display.setRequestedColorModeLocked(colorMode);
scheduleTraversalLocked(false);
}
}
}
private int createVirtualDisplayInternal(IVirtualDisplayCallback callback,
IMediaProjection projection, int callingUid, String packageName, String name, int width,
int height, int densityDpi, Surface surface, int flags, String uniqueId) {
synchronized (mSyncRoot) {
if (mVirtualDisplayAdapter == null) {
Slog.w(TAG, "Rejecting request to create private virtual display "
+ "because the virtual display adapter is not available.");
return -1;
}
DisplayDevice device = mVirtualDisplayAdapter.createVirtualDisplayLocked(
callback, projection, callingUid, packageName, name, width, height, densityDpi,
surface, flags, uniqueId);
if (device == null) {
return -1;
}
handleDisplayDeviceAddedLocked(device);
LogicalDisplay display = findLogicalDisplayForDeviceLocked(device);
if (display != null) {
return display.getDisplayIdLocked();
}
// Something weird happened and the logical display was not created.
Slog.w(TAG, "Rejecting request to create virtual display "
+ "because the logical display was not created.");
mVirtualDisplayAdapter.releaseVirtualDisplayLocked(callback.asBinder());
handleDisplayDeviceRemovedLocked(device);
}
return -1;
}
private void resizeVirtualDisplayInternal(IBinder appToken,
int width, int height, int densityDpi) {
synchronized (mSyncRoot) {
if (mVirtualDisplayAdapter == null) {
return;
}
mVirtualDisplayAdapter.resizeVirtualDisplayLocked(appToken, width, height, densityDpi);
}
}
private void setVirtualDisplaySurfaceInternal(IBinder appToken, Surface surface) {
synchronized (mSyncRoot) {
if (mVirtualDisplayAdapter == null) {
return;
}
mVirtualDisplayAdapter.setVirtualDisplaySurfaceLocked(appToken, surface);
}
}
private void releaseVirtualDisplayInternal(IBinder appToken) {
synchronized (mSyncRoot) {
if (mVirtualDisplayAdapter == null) {
return;
}
DisplayDevice device =
mVirtualDisplayAdapter.releaseVirtualDisplayLocked(appToken);
if (device != null) {
handleDisplayDeviceRemovedLocked(device);
}
}
}
private void setVirtualDisplayStateInternal(IBinder appToken, boolean isOn) {
synchronized (mSyncRoot) {
if (mVirtualDisplayAdapter == null) {
return;
}
mVirtualDisplayAdapter.setVirtualDisplayStateLocked(appToken, isOn);
}
}
private void registerDefaultDisplayAdapters() {
// Register default display adapters.
synchronized (mSyncRoot) {
// main display adapter
registerDisplayAdapterLocked(new LocalDisplayAdapter(
mSyncRoot, mContext, mHandler, mDisplayAdapterListener));
// Standalone VR devices rely on a virtual display as their primary display for
// 2D UI. We register virtual display adapter along side the main display adapter
// here so that it is ready by the time the system sends the home Intent for
// early apps like SetupWizard/Launcher. In particular, SUW is displayed using
// the virtual display inside VR before any VR-specific apps even run.
mVirtualDisplayAdapter = mInjector.getVirtualDisplayAdapter(mSyncRoot, mContext,
mHandler, mDisplayAdapterListener);
if (mVirtualDisplayAdapter != null) {
registerDisplayAdapterLocked(mVirtualDisplayAdapter);
}
}
}
private void registerAdditionalDisplayAdapters() {
synchronized (mSyncRoot) {
if (shouldRegisterNonEssentialDisplayAdaptersLocked()) {
registerOverlayDisplayAdapterLocked();
registerWifiDisplayAdapterLocked();
}
}
}
private void registerOverlayDisplayAdapterLocked() {
registerDisplayAdapterLocked(new OverlayDisplayAdapter(
mSyncRoot, mContext, mHandler, mDisplayAdapterListener, mUiHandler));
}
private void registerWifiDisplayAdapterLocked() {
if (mContext.getResources().getBoolean(
com.android.internal.R.bool.config_enableWifiDisplay)
|| SystemProperties.getInt(FORCE_WIFI_DISPLAY_ENABLE, -1) == 1) {
mWifiDisplayAdapter = new WifiDisplayAdapter(
mSyncRoot, mContext, mHandler, mDisplayAdapterListener,
mPersistentDataStore);
registerDisplayAdapterLocked(mWifiDisplayAdapter);
}
}
private boolean shouldRegisterNonEssentialDisplayAdaptersLocked() {
// In safe mode, we disable non-essential display adapters to give the user
// an opportunity to fix broken settings or other problems that might affect
// system stability.
// In only-core mode, we disable non-essential display adapters to minimize
// the number of dependencies that are started while in this mode and to
// prevent problems that might occur due to the device being encrypted.
return !mSafeMode && !mOnlyCore;
}
private void registerDisplayAdapterLocked(DisplayAdapter adapter) {
mDisplayAdapters.add(adapter);
adapter.registerLocked();
}
private void handleDisplayDeviceAdded(DisplayDevice device) {
synchronized (mSyncRoot) {
handleDisplayDeviceAddedLocked(device);
}
}
private void handleDisplayDeviceAddedLocked(DisplayDevice device) {
DisplayDeviceInfo info = device.getDisplayDeviceInfoLocked();
if (mDisplayDevices.contains(device)) {
Slog.w(TAG, "Attempted to add already added display device: " + info);
return;
}
Slog.i(TAG, "Display device added: " + info);
device.mDebugLastLoggedDeviceInfo = info;
mDisplayDevices.add(device);
LogicalDisplay display = addLogicalDisplayLocked(device);
Runnable work = updateDisplayStateLocked(device);
if (work != null) {
work.run();
}
scheduleTraversalLocked(false);
}
private void handleDisplayDeviceChanged(DisplayDevice device) {
synchronized (mSyncRoot) {
DisplayDeviceInfo info = device.getDisplayDeviceInfoLocked();
if (!mDisplayDevices.contains(device)) {
Slog.w(TAG, "Attempted to change non-existent display device: " + info);
return;
}
int diff = device.mDebugLastLoggedDeviceInfo.diff(info);
if (diff == DisplayDeviceInfo.DIFF_STATE) {
Slog.i(TAG, "Display device changed state: \"" + info.name
+ "\", " + Display.stateToString(info.state));
} else if (diff != 0) {
Slog.i(TAG, "Display device changed: " + info);
}
if ((diff & DisplayDeviceInfo.DIFF_COLOR_MODE) != 0) {
try {
mPersistentDataStore.setColorMode(device, info.colorMode);
} finally {
mPersistentDataStore.saveIfNeeded();
}
}
device.mDebugLastLoggedDeviceInfo = info;
device.applyPendingDisplayDeviceInfoChangesLocked();
if (updateLogicalDisplaysLocked()) {
scheduleTraversalLocked(false);
}
}
}
private void handleDisplayDeviceRemoved(DisplayDevice device) {
synchronized (mSyncRoot) {
handleDisplayDeviceRemovedLocked(device);
}
}
private void handleDisplayDeviceRemovedLocked(DisplayDevice device) {
DisplayDeviceInfo info = device.getDisplayDeviceInfoLocked();
if (!mDisplayDevices.remove(device)) {
Slog.w(TAG, "Attempted to remove non-existent display device: " + info);
return;
}
Slog.i(TAG, "Display device removed: " + info);
device.mDebugLastLoggedDeviceInfo = info;
updateLogicalDisplaysLocked();
scheduleTraversalLocked(false);
}
private void handleLogicalDisplayChanged(int displayId, @NonNull LogicalDisplay display) {
if (displayId == Display.DEFAULT_DISPLAY) {
recordTopInsetLocked(display);
}
sendDisplayEventLocked(displayId, DisplayManagerGlobal.EVENT_DISPLAY_CHANGED);
}
private void applyGlobalDisplayStateLocked(List<Runnable> workQueue) {
final int count = mDisplayDevices.size();
for (int i = 0; i < count; i++) {
DisplayDevice device = mDisplayDevices.get(i);
Runnable runnable = updateDisplayStateLocked(device);
if (runnable != null) {
workQueue.add(runnable);
}
}
}
private Runnable updateDisplayStateLocked(DisplayDevice device) {
// Blank or unblank the display immediately to match the state requested
// by the display power controller (if known).
DisplayDeviceInfo info = device.getDisplayDeviceInfoLocked();
if ((info.flags & DisplayDeviceInfo.FLAG_NEVER_BLANK) == 0) {
return device.requestDisplayStateLocked(mGlobalDisplayState, mGlobalDisplayBrightness);
}
return null;
}
// Adds a new logical display based on the given display device.
// Sends notifications if needed.
private LogicalDisplay addLogicalDisplayLocked(DisplayDevice device) {
DisplayDeviceInfo deviceInfo = device.getDisplayDeviceInfoLocked();
boolean isDefault = (deviceInfo.flags
& DisplayDeviceInfo.FLAG_DEFAULT_DISPLAY) != 0;
if (isDefault && mLogicalDisplays.get(Display.DEFAULT_DISPLAY) != null) {
Slog.w(TAG, "Ignoring attempt to add a second default display: " + deviceInfo);
isDefault = false;
}
if (!isDefault && mSingleDisplayDemoMode) {
Slog.i(TAG, "Not creating a logical display for a secondary display "
+ " because single display demo mode is enabled: " + deviceInfo);
return null;
}
final int displayId = assignDisplayIdLocked(isDefault);
final int layerStack = assignLayerStackLocked(displayId);
LogicalDisplay display = new LogicalDisplay(displayId, layerStack, device);
display.updateLocked(mDisplayDevices);
if (!display.isValidLocked()) {
// This should never happen currently.
Slog.w(TAG, "Ignoring display device because the logical display "
+ "created from it was not considered valid: " + deviceInfo);
return null;
}
configureColorModeLocked(display, device);
if (isDefault) {
recordStableDisplayStatsIfNeededLocked(display);
recordTopInsetLocked(display);
}
mLogicalDisplays.put(displayId, display);
// Wake up waitForDefaultDisplay.
if (isDefault) {
mSyncRoot.notifyAll();
}
sendDisplayEventLocked(displayId, DisplayManagerGlobal.EVENT_DISPLAY_ADDED);
return display;
}
private int assignDisplayIdLocked(boolean isDefault) {
return isDefault ? Display.DEFAULT_DISPLAY : mNextNonDefaultDisplayId++;
}
private int assignLayerStackLocked(int displayId) {
// Currently layer stacks and display ids are the same.
// This need not be the case.
return displayId;
}
private void configureColorModeLocked(LogicalDisplay display, DisplayDevice device) {
if (display.getPrimaryDisplayDeviceLocked() == device) {
int colorMode = mPersistentDataStore.getColorMode(device);
if (colorMode == Display.COLOR_MODE_INVALID) {
if ((device.getDisplayDeviceInfoLocked().flags
& DisplayDeviceInfo.FLAG_DEFAULT_DISPLAY) != 0) {
colorMode = mDefaultDisplayDefaultColorMode;
} else {
colorMode = Display.COLOR_MODE_DEFAULT;
}
}
display.setRequestedColorModeLocked(colorMode);
}
}
// If we've never recorded stable device stats for this device before and they aren't
// explicitly configured, go ahead and record the stable device stats now based on the status
// of the default display at first boot.
private void recordStableDisplayStatsIfNeededLocked(LogicalDisplay d) {
if (mStableDisplaySize.x <= 0 && mStableDisplaySize.y <= 0) {
DisplayInfo info = d.getDisplayInfoLocked();
setStableDisplaySizeLocked(info.getNaturalWidth(), info.getNaturalHeight());
}
}
private void recordTopInsetLocked(@Nullable LogicalDisplay d) {
// We must only persist the inset after boot has completed, otherwise we will end up
// overwriting the persisted value before the masking flag has been loaded from the
// resource overlay.
if (!mSystemReady || d == null) {
return;
}
int topInset = d.getInsets().top;
if (topInset == mDefaultDisplayTopInset) {
return;
}
mDefaultDisplayTopInset = topInset;
SystemProperties.set(PROP_DEFAULT_DISPLAY_TOP_INSET, Integer.toString(topInset));
}
private void setStableDisplaySizeLocked(int width, int height) {
mStableDisplaySize = new Point(width, height);
try {
mPersistentDataStore.setStableDisplaySize(mStableDisplaySize);
} finally {
mPersistentDataStore.saveIfNeeded();
}
}
@VisibleForTesting
Curve getMinimumBrightnessCurveInternal() {
return mMinimumBrightnessCurve;
}
int getPreferredWideGamutColorSpaceIdInternal() {
return mWideColorSpace.getId();
}
private void setBrightnessConfigurationForUserInternal(
@Nullable BrightnessConfiguration c, @UserIdInt int userId,
@Nullable String packageName) {
validateBrightnessConfiguration(c);
final int userSerial = getUserManager().getUserSerialNumber(userId);
synchronized (mSyncRoot) {
try {
mPersistentDataStore.setBrightnessConfigurationForUser(c, userSerial,
packageName);
} finally {
mPersistentDataStore.saveIfNeeded();
}
if (userId == mCurrentUserId) {
mDisplayPowerController.setBrightnessConfiguration(c);
}
}
}
@VisibleForTesting
void validateBrightnessConfiguration(BrightnessConfiguration config) {
if (config == null) {
return;
}
if (isBrightnessConfigurationTooDark(config)) {
throw new IllegalArgumentException("brightness curve is too dark");
}
}
private boolean isBrightnessConfigurationTooDark(BrightnessConfiguration config) {
Pair<float[], float[]> curve = config.getCurve();
float[] lux = curve.first;
float[] nits = curve.second;
for (int i = 0; i < lux.length; i++) {
if (nits[i] < mMinimumBrightnessSpline.interpolate(lux[i])) {
return true;
}
}
return false;
}
private void loadBrightnessConfiguration() {
synchronized (mSyncRoot) {
final int userSerial = getUserManager().getUserSerialNumber(mCurrentUserId);
BrightnessConfiguration config =
mPersistentDataStore.getBrightnessConfiguration(userSerial);
mDisplayPowerController.setBrightnessConfiguration(config);
}
}
// Updates all existing logical displays given the current set of display devices.
// Removes invalid logical displays.
// Sends notifications if needed.
private boolean updateLogicalDisplaysLocked() {
boolean changed = false;
for (int i = mLogicalDisplays.size(); i-- > 0; ) {
final int displayId = mLogicalDisplays.keyAt(i);
LogicalDisplay display = mLogicalDisplays.valueAt(i);
mTempDisplayInfo.copyFrom(display.getDisplayInfoLocked());
display.updateLocked(mDisplayDevices);
if (!display.isValidLocked()) {
mLogicalDisplays.removeAt(i);
sendDisplayEventLocked(displayId, DisplayManagerGlobal.EVENT_DISPLAY_REMOVED);
changed = true;
} else if (!mTempDisplayInfo.equals(display.getDisplayInfoLocked())) {
handleLogicalDisplayChanged(displayId, display);
changed = true;
}
}
return changed;
}
private void performTraversalLocked(SurfaceControl.Transaction t) {
// Clear all viewports before configuring displays so that we can keep
// track of which ones we have configured.
clearViewportsLocked();
// Configure each display device.
final int count = mDisplayDevices.size();
for (int i = 0; i < count; i++) {
DisplayDevice device = mDisplayDevices.get(i);
configureDisplayLocked(t, device);
device.performTraversalLocked(t);
}
// Tell the input system about these new viewports.
if (mInputManagerInternal != null) {
mHandler.sendEmptyMessage(MSG_UPDATE_VIEWPORT);
}
}
private void setDisplayPropertiesInternal(int displayId, boolean hasContent,
float requestedRefreshRate, int requestedModeId, boolean inTraversal) {
synchronized (mSyncRoot) {
LogicalDisplay display = mLogicalDisplays.get(displayId);
if (display == null) {
return;
}
if (display.hasContentLocked() != hasContent) {
if (DEBUG) {
Slog.d(TAG, "Display " + displayId + " hasContent flag changed: "
+ "hasContent=" + hasContent + ", inTraversal=" + inTraversal);
}
display.setHasContentLocked(hasContent);
scheduleTraversalLocked(inTraversal);
}
if (requestedModeId == 0 && requestedRefreshRate != 0) {
// Scan supported modes returned by display.getInfo() to find a mode with the same
// size as the default display mode but with the specified refresh rate instead.
requestedModeId = display.getDisplayInfoLocked().findDefaultModeByRefreshRate(
requestedRefreshRate);
}
mDisplayModeDirector.getAppRequestObserver().setAppRequestedMode(
displayId, requestedModeId);
}
}
private void setDisplayOffsetsInternal(int displayId, int x, int y) {
synchronized (mSyncRoot) {
LogicalDisplay display = mLogicalDisplays.get(displayId);
if (display == null) {
return;
}
if (display.getDisplayOffsetXLocked() != x
|| display.getDisplayOffsetYLocked() != y) {
if (DEBUG) {
Slog.d(TAG, "Display " + displayId + " burn-in offset set to ("
+ x + ", " + y + ")");
}
display.setDisplayOffsetsLocked(x, y);
scheduleTraversalLocked(false);
}
}
}
private void setDisplayScalingDisabledInternal(int displayId, boolean disable) {
synchronized (mSyncRoot) {
final LogicalDisplay display = mLogicalDisplays.get(displayId);
if (display == null) {
return;
}
if (display.isDisplayScalingDisabled() != disable) {
if (DEBUG) {
Slog.d(TAG, "Display " + displayId + " content scaling disabled = " + disable);
}
display.setDisplayScalingDisabledLocked(disable);
scheduleTraversalLocked(false);
}
}
}
// Updates the lists of UIDs that are present on displays.
private void setDisplayAccessUIDsInternal(SparseArray<IntArray> newDisplayAccessUIDs) {
synchronized (mSyncRoot) {
mDisplayAccessUIDs.clear();
for (int i = newDisplayAccessUIDs.size() - 1; i >= 0; i--) {
mDisplayAccessUIDs.append(newDisplayAccessUIDs.keyAt(i),
newDisplayAccessUIDs.valueAt(i));
}
}
}
// Checks if provided UID's content is present on the display and UID has access to it.
private boolean isUidPresentOnDisplayInternal(int uid, int displayId) {
synchronized (mSyncRoot) {
final IntArray displayUIDs = mDisplayAccessUIDs.get(displayId);
return displayUIDs != null && displayUIDs.indexOf(uid) != -1;
}
}
@Nullable
private IBinder getDisplayToken(int displayId) {
synchronized (mSyncRoot) {
final LogicalDisplay display = mLogicalDisplays.get(displayId);
if (display != null) {
final DisplayDevice device = display.getPrimaryDisplayDeviceLocked();
if (device != null) {
return device.getDisplayTokenLocked();
}
}
}
return null;
}
private SurfaceControl.ScreenshotGraphicBuffer screenshotInternal(int displayId) {
final IBinder token = getDisplayToken(displayId);
if (token == null) {
return null;
}
return SurfaceControl.screenshotToBufferWithSecureLayersUnsafe(
token, new Rect(), 0 /* width */, 0 /* height */,
false /* useIdentityTransform */, 0 /* rotation */);
}
@VisibleForTesting
DisplayedContentSamplingAttributes getDisplayedContentSamplingAttributesInternal(
int displayId) {
final IBinder token = getDisplayToken(displayId);
if (token == null) {
return null;
}
return SurfaceControl.getDisplayedContentSamplingAttributes(token);
}
@VisibleForTesting
boolean setDisplayedContentSamplingEnabledInternal(
int displayId, boolean enable, int componentMask, int maxFrames) {
final IBinder token = getDisplayToken(displayId);
if (token == null) {
return false;
}
return SurfaceControl.setDisplayedContentSamplingEnabled(
token, enable, componentMask, maxFrames);
}
@VisibleForTesting
DisplayedContentSample getDisplayedContentSampleInternal(int displayId,
long maxFrames, long timestamp) {
final IBinder token = getDisplayToken(displayId);
if (token == null) {
return null;
}
return SurfaceControl.getDisplayedContentSample(token, maxFrames, timestamp);
}
private void onAllowedDisplayModesChangedInternal() {
boolean changed = false;
synchronized (mSyncRoot) {
final int count = mLogicalDisplays.size();
for (int i = 0; i < count; i++) {
LogicalDisplay display = mLogicalDisplays.valueAt(i);
int displayId = mLogicalDisplays.keyAt(i);
int[] allowedModes = mDisplayModeDirector.getAllowedModes(displayId);
// Note that order is important here since not all display devices are capable of
// automatically switching, so we do actually want to check for equality and not
// just equivalent contents (regardless of order).
if (!Arrays.equals(allowedModes, display.getAllowedDisplayModesLocked())) {
display.setAllowedDisplayModesLocked(allowedModes);
changed = true;
}
}
if (changed) {
scheduleTraversalLocked(false);
}
}
}
private void clearViewportsLocked() {
mViewports.clear();
}
private void configureDisplayLocked(SurfaceControl.Transaction t, DisplayDevice device) {
final DisplayDeviceInfo info = device.getDisplayDeviceInfoLocked();
final boolean ownContent = (info.flags & DisplayDeviceInfo.FLAG_OWN_CONTENT_ONLY) != 0;
// Find the logical display that the display device is showing.
// Certain displays only ever show their own content.
LogicalDisplay display = findLogicalDisplayForDeviceLocked(device);
if (!ownContent) {
if (display != null && !display.hasContentLocked()) {
// If the display does not have any content of its own, then
// automatically mirror the default logical display contents.
display = null;
}
if (display == null) {
display = mLogicalDisplays.get(Display.DEFAULT_DISPLAY);
}
}
// Apply the logical display configuration to the display device.
if (display == null) {
// TODO: no logical display for the device, blank it
Slog.w(TAG, "Missing logical display to use for physical display device: "
+ device.getDisplayDeviceInfoLocked());
return;
}
display.configureDisplayLocked(t, device, info.state == Display.STATE_OFF);
final int viewportType;
// Update the corresponding viewport.
if ((info.flags & DisplayDeviceInfo.FLAG_DEFAULT_DISPLAY) != 0) {
viewportType = VIEWPORT_INTERNAL;
} else if (info.touch == DisplayDeviceInfo.TOUCH_EXTERNAL) {
viewportType = VIEWPORT_EXTERNAL;
} else if (info.touch == DisplayDeviceInfo.TOUCH_VIRTUAL
&& !TextUtils.isEmpty(info.uniqueId)) {
viewportType = VIEWPORT_VIRTUAL;
} else {
Slog.i(TAG, "Display " + info + " does not support input device matching.");
return;
}
populateViewportLocked(viewportType, display.getDisplayIdLocked(), device, info.uniqueId);
}
/**
* Get internal or external viewport. Create it if does not currently exist.
* @param viewportType - either INTERNAL or EXTERNAL
* @return the viewport with the requested type
*/
private DisplayViewport getViewportLocked(int viewportType, String uniqueId) {
if (viewportType != VIEWPORT_INTERNAL && viewportType != VIEWPORT_EXTERNAL
&& viewportType != VIEWPORT_VIRTUAL) {
Slog.wtf(TAG, "Cannot call getViewportByTypeLocked for type "
+ DisplayViewport.typeToString(viewportType));
return null;
}
// Only allow a single INTERNAL or EXTERNAL viewport by forcing their uniqueIds
// to be identical (in particular, empty).
// TODO (b/116824030) allow multiple EXTERNAL viewports and remove this function.
if (viewportType != VIEWPORT_VIRTUAL) {
uniqueId = "";
}
DisplayViewport viewport;
final int count = mViewports.size();
for (int i = 0; i < count; i++) {
viewport = mViewports.get(i);
if (viewport.type == viewportType && uniqueId.equals(viewport.uniqueId)) {
return viewport;
}
}
// Creates the viewport if none exists.
viewport = new DisplayViewport();
viewport.type = viewportType;
viewport.uniqueId = uniqueId;
mViewports.add(viewport);
return viewport;
}
private void populateViewportLocked(int viewportType,
int displayId, DisplayDevice device, String uniqueId) {
final DisplayViewport viewport = getViewportLocked(viewportType, uniqueId);
device.populateViewportLocked(viewport);
viewport.valid = true;
viewport.displayId = displayId;
}
private LogicalDisplay findLogicalDisplayForDeviceLocked(DisplayDevice device) {
final int count = mLogicalDisplays.size();
for (int i = 0; i < count; i++) {
LogicalDisplay display = mLogicalDisplays.valueAt(i);
if (display.getPrimaryDisplayDeviceLocked() == device) {
return display;
}
}
return null;
}
private void sendDisplayEventLocked(int displayId, int event) {
Message msg = mHandler.obtainMessage(MSG_DELIVER_DISPLAY_EVENT, displayId, event);
mHandler.sendMessage(msg);
}
// Requests that performTraversals be called at a
// later time to apply changes to surfaces and displays.
private void scheduleTraversalLocked(boolean inTraversal) {
if (!mPendingTraversal && mWindowManagerInternal != null) {
mPendingTraversal = true;
if (!inTraversal) {
mHandler.sendEmptyMessage(MSG_REQUEST_TRAVERSAL);
}
}
}
// Runs on Handler thread.
// Delivers display event notifications to callbacks.
private void deliverDisplayEvent(int displayId, int event) {
if (DEBUG) {
Slog.d(TAG, "Delivering display event: displayId="
+ displayId + ", event=" + event);
}
// Grab the lock and copy the callbacks.
final int count;
synchronized (mSyncRoot) {
count = mCallbacks.size();
mTempCallbacks.clear();
for (int i = 0; i < count; i++) {
mTempCallbacks.add(mCallbacks.valueAt(i));
}
}
// After releasing the lock, send the notifications out.
for (int i = 0; i < count; i++) {
mTempCallbacks.get(i).notifyDisplayEventAsync(displayId, event);
}
mTempCallbacks.clear();
}
private IMediaProjectionManager getProjectionService() {
if (mProjectionService == null) {
IBinder b = ServiceManager.getService(Context.MEDIA_PROJECTION_SERVICE);
mProjectionService = IMediaProjectionManager.Stub.asInterface(b);
}
return mProjectionService;
}
private UserManager getUserManager() {
return mContext.getSystemService(UserManager.class);
}
private void dumpInternal(PrintWriter pw) {
pw.println("DISPLAY MANAGER (dumpsys display)");
synchronized (mSyncRoot) {
pw.println(" mOnlyCode=" + mOnlyCore);
pw.println(" mSafeMode=" + mSafeMode);
pw.println(" mPendingTraversal=" + mPendingTraversal);
pw.println(" mGlobalDisplayState=" + Display.stateToString(mGlobalDisplayState));
pw.println(" mNextNonDefaultDisplayId=" + mNextNonDefaultDisplayId);
pw.println(" mViewports=" + mViewports);
pw.println(" mDefaultDisplayDefaultColorMode=" + mDefaultDisplayDefaultColorMode);
pw.println(" mSingleDisplayDemoMode=" + mSingleDisplayDemoMode);
pw.println(" mWifiDisplayScanRequestCount=" + mWifiDisplayScanRequestCount);
pw.println(" mStableDisplaySize=" + mStableDisplaySize);
pw.println(" mMinimumBrightnessCurve=" + mMinimumBrightnessCurve);
IndentingPrintWriter ipw = new IndentingPrintWriter(pw, " ");
ipw.increaseIndent();
pw.println();
pw.println("Display Adapters: size=" + mDisplayAdapters.size());
for (DisplayAdapter adapter : mDisplayAdapters) {
pw.println(" " + adapter.getName());
adapter.dumpLocked(ipw);
}
pw.println();
pw.println("Display Devices: size=" + mDisplayDevices.size());
for (DisplayDevice device : mDisplayDevices) {
pw.println(" " + device.getDisplayDeviceInfoLocked());
device.dumpLocked(ipw);
}
final int logicalDisplayCount = mLogicalDisplays.size();
pw.println();
pw.println("Logical Displays: size=" + logicalDisplayCount);
for (int i = 0; i < logicalDisplayCount; i++) {
int displayId = mLogicalDisplays.keyAt(i);
LogicalDisplay display = mLogicalDisplays.valueAt(i);
pw.println(" Display " + displayId + ":");
display.dumpLocked(ipw);
}
pw.println();
mDisplayModeDirector.dump(pw);
final int callbackCount = mCallbacks.size();
pw.println();
pw.println("Callbacks: size=" + callbackCount);
for (int i = 0; i < callbackCount; i++) {
CallbackRecord callback = mCallbacks.valueAt(i);
pw.println(" " + i + ": mPid=" + callback.mPid
+ ", mWifiDisplayScanRequested=" + callback.mWifiDisplayScanRequested);
}
if (mDisplayPowerController != null) {
mDisplayPowerController.dump(pw);
}
pw.println();
mPersistentDataStore.dump(pw);
}
}
private static float[] getFloatArray(TypedArray array) {
int length = array.length();
float[] floatArray = new float[length];
for (int i = 0; i < length; i++) {
floatArray[i] = array.getFloat(i, Float.NaN);
}
array.recycle();
return floatArray;
}
/**
* This is the object that everything in the display manager locks on.
* We make it an inner class within the {@link DisplayManagerService} to so that it is
* clear that the object belongs to the display manager service and that it is
* a unique object with a special purpose.
*/
public static final class SyncRoot {
}
@VisibleForTesting
static class Injector {
VirtualDisplayAdapter getVirtualDisplayAdapter(SyncRoot syncRoot, Context context,
Handler handler, DisplayAdapter.Listener displayAdapterListener) {
return new VirtualDisplayAdapter(syncRoot, context, handler, displayAdapterListener);
}
long getDefaultDisplayDelayTimeout() {
return WAIT_FOR_DEFAULT_DISPLAY_TIMEOUT;
}
}
@VisibleForTesting
DisplayDeviceInfo getDisplayDeviceInfoInternal(int displayId) {
synchronized (mSyncRoot) {
LogicalDisplay display = mLogicalDisplays.get(displayId);
if (display != null) {
DisplayDevice displayDevice = display.getPrimaryDisplayDeviceLocked();
return displayDevice.getDisplayDeviceInfoLocked();
}
return null;
}
}
private final class DisplayManagerHandler extends Handler {
public DisplayManagerHandler(Looper looper) {
super(looper, null, true /*async*/);
}
@Override
public void handleMessage(Message msg) {
switch (msg.what) {
case MSG_REGISTER_DEFAULT_DISPLAY_ADAPTERS:
registerDefaultDisplayAdapters();
break;
case MSG_REGISTER_ADDITIONAL_DISPLAY_ADAPTERS:
registerAdditionalDisplayAdapters();
break;
case MSG_DELIVER_DISPLAY_EVENT:
deliverDisplayEvent(msg.arg1, msg.arg2);
break;
case MSG_REQUEST_TRAVERSAL:
mWindowManagerInternal.requestTraversalFromDisplayManager();
break;
case MSG_UPDATE_VIEWPORT: {
final boolean changed;
synchronized (mSyncRoot) {
changed = !mTempViewports.equals(mViewports);
if (changed) {
mTempViewports.clear();
for (DisplayViewport d : mViewports) {
mTempViewports.add(d.makeCopy());
}
}
}
if (changed) {
mInputManagerInternal.setDisplayViewports(mTempViewports);
}
break;
}
case MSG_LOAD_BRIGHTNESS_CONFIGURATION:
loadBrightnessConfiguration();
break;
}
}
}
private final class DisplayAdapterListener implements DisplayAdapter.Listener {
@Override
public void onDisplayDeviceEvent(DisplayDevice device, int event) {
switch (event) {
case DisplayAdapter.DISPLAY_DEVICE_EVENT_ADDED:
handleDisplayDeviceAdded(device);
break;
case DisplayAdapter.DISPLAY_DEVICE_EVENT_CHANGED:
handleDisplayDeviceChanged(device);
break;
case DisplayAdapter.DISPLAY_DEVICE_EVENT_REMOVED:
handleDisplayDeviceRemoved(device);
break;
}
}
@Override
public void onTraversalRequested() {
synchronized (mSyncRoot) {
scheduleTraversalLocked(false);
}
}
}
private final class CallbackRecord implements DeathRecipient {
public final int mPid;
private final IDisplayManagerCallback mCallback;
public boolean mWifiDisplayScanRequested;
public CallbackRecord(int pid, IDisplayManagerCallback callback) {
mPid = pid;
mCallback = callback;
}
@Override
public void binderDied() {
if (DEBUG) {
Slog.d(TAG, "Display listener for pid " + mPid + " died.");
}
onCallbackDied(this);
}
public void notifyDisplayEventAsync(int displayId, int event) {
try {
mCallback.onDisplayEvent(displayId, event);
} catch (RemoteException ex) {
Slog.w(TAG, "Failed to notify process "
+ mPid + " that displays changed, assuming it died.", ex);
binderDied();
}
}
}
@VisibleForTesting
final class BinderService extends IDisplayManager.Stub {
/**
* Returns information about the specified logical display.
*
* @param displayId The logical display id.
* @return The logical display info, return {@code null} if the display does not exist or
* the calling UID isn't present on the display. The returned object must be treated as
* immutable.
*/
@Override // Binder call
public DisplayInfo getDisplayInfo(int displayId) {
final int callingUid = Binder.getCallingUid();
final long token = Binder.clearCallingIdentity();
try {
return getDisplayInfoInternal(displayId, callingUid);
} finally {
Binder.restoreCallingIdentity(token);
}
}
/**
* Returns the list of all display ids.
*/
@Override // Binder call
public int[] getDisplayIds() {
final int callingUid = Binder.getCallingUid();
final long token = Binder.clearCallingIdentity();
try {
return getDisplayIdsInternal(callingUid);
} finally {
Binder.restoreCallingIdentity(token);
}
}
@Override // Binder call
public boolean isUidPresentOnDisplay(int uid, int displayId) {
final long token = Binder.clearCallingIdentity();
try {
return isUidPresentOnDisplayInternal(uid, displayId);
} finally {
Binder.restoreCallingIdentity(token);
}
}
/**
* Returns the stable device display size, in pixels.
*/
@Override // Binder call
public Point getStableDisplaySize() {
final long token = Binder.clearCallingIdentity();
try {
return getStableDisplaySizeInternal();
} finally {
Binder.restoreCallingIdentity(token);
}
}
@Override // Binder call
public void registerCallback(IDisplayManagerCallback callback) {
if (callback == null) {
throw new IllegalArgumentException("listener must not be null");
}
final int callingPid = Binder.getCallingPid();
final long token = Binder.clearCallingIdentity();
try {
registerCallbackInternal(callback, callingPid);
} finally {
Binder.restoreCallingIdentity(token);
}
}
@Override // Binder call
public void startWifiDisplayScan() {
mContext.enforceCallingOrSelfPermission(Manifest.permission.CONFIGURE_WIFI_DISPLAY,
"Permission required to start wifi display scans");
final int callingPid = Binder.getCallingPid();
final long token = Binder.clearCallingIdentity();
try {
startWifiDisplayScanInternal(callingPid);
} finally {
Binder.restoreCallingIdentity(token);
}
}
@Override // Binder call
public void stopWifiDisplayScan() {
mContext.enforceCallingOrSelfPermission(Manifest.permission.CONFIGURE_WIFI_DISPLAY,
"Permission required to stop wifi display scans");
final int callingPid = Binder.getCallingPid();
final long token = Binder.clearCallingIdentity();
try {
stopWifiDisplayScanInternal(callingPid);
} finally {
Binder.restoreCallingIdentity(token);
}
}
@Override // Binder call
public void connectWifiDisplay(String address) {
if (address == null) {
throw new IllegalArgumentException("address must not be null");
}
mContext.enforceCallingOrSelfPermission(Manifest.permission.CONFIGURE_WIFI_DISPLAY,
"Permission required to connect to a wifi display");
final long token = Binder.clearCallingIdentity();
try {
connectWifiDisplayInternal(address);
} finally {
Binder.restoreCallingIdentity(token);
}
}
@Override // Binder call
public void disconnectWifiDisplay() {
// This request does not require special permissions.
// Any app can request disconnection from the currently active wifi display.
// This exception should no longer be needed once wifi display control moves
// to the media router service.
final long token = Binder.clearCallingIdentity();
try {
disconnectWifiDisplayInternal();
} finally {
Binder.restoreCallingIdentity(token);
}
}
@Override // Binder call
public void renameWifiDisplay(String address, String alias) {
if (address == null) {
throw new IllegalArgumentException("address must not be null");
}
mContext.enforceCallingOrSelfPermission(Manifest.permission.CONFIGURE_WIFI_DISPLAY,
"Permission required to rename to a wifi display");
final long token = Binder.clearCallingIdentity();
try {
renameWifiDisplayInternal(address, alias);
} finally {
Binder.restoreCallingIdentity(token);
}
}
@Override // Binder call
public void forgetWifiDisplay(String address) {
if (address == null) {
throw new IllegalArgumentException("address must not be null");
}
mContext.enforceCallingOrSelfPermission(Manifest.permission.CONFIGURE_WIFI_DISPLAY,
"Permission required to forget to a wifi display");
final long token = Binder.clearCallingIdentity();
try {
forgetWifiDisplayInternal(address);
} finally {
Binder.restoreCallingIdentity(token);
}
}
@Override // Binder call
public void pauseWifiDisplay() {
mContext.enforceCallingOrSelfPermission(Manifest.permission.CONFIGURE_WIFI_DISPLAY,
"Permission required to pause a wifi display session");
final long token = Binder.clearCallingIdentity();
try {
pauseWifiDisplayInternal();
} finally {
Binder.restoreCallingIdentity(token);
}
}
@Override // Binder call
public void resumeWifiDisplay() {
mContext.enforceCallingOrSelfPermission(Manifest.permission.CONFIGURE_WIFI_DISPLAY,
"Permission required to resume a wifi display session");
final long token = Binder.clearCallingIdentity();
try {
resumeWifiDisplayInternal();
} finally {
Binder.restoreCallingIdentity(token);
}
}
@Override // Binder call
public WifiDisplayStatus getWifiDisplayStatus() {
// This request does not require special permissions.
// Any app can get information about available wifi displays.
final long token = Binder.clearCallingIdentity();
try {
return getWifiDisplayStatusInternal();
} finally {
Binder.restoreCallingIdentity(token);
}
}
@Override // Binder call
public void requestColorMode(int displayId, int colorMode) {
mContext.enforceCallingOrSelfPermission(
Manifest.permission.CONFIGURE_DISPLAY_COLOR_MODE,
"Permission required to change the display color mode");
final long token = Binder.clearCallingIdentity();
try {
requestColorModeInternal(displayId, colorMode);
} finally {
Binder.restoreCallingIdentity(token);
}
}
@Override // Binder call
public int createVirtualDisplay(IVirtualDisplayCallback callback,
IMediaProjection projection, String packageName, String name,
int width, int height, int densityDpi, Surface surface, int flags,
String uniqueId) {
final int callingUid = Binder.getCallingUid();
if (!validatePackageName(callingUid, packageName)) {
throw new SecurityException("packageName must match the calling uid");
}
if (callback == null) {
throw new IllegalArgumentException("appToken must not be null");
}
if (TextUtils.isEmpty(name)) {
throw new IllegalArgumentException("name must be non-null and non-empty");
}
if (width <= 0 || height <= 0 || densityDpi <= 0) {
throw new IllegalArgumentException("width, height, and densityDpi must be "
+ "greater than 0");
}
if (surface != null && surface.isSingleBuffered()) {
throw new IllegalArgumentException("Surface can't be single-buffered");
}
if ((flags & VIRTUAL_DISPLAY_FLAG_PUBLIC) != 0) {
flags |= VIRTUAL_DISPLAY_FLAG_AUTO_MIRROR;
// Public displays can't be allowed to show content when locked.
if ((flags & VIRTUAL_DISPLAY_FLAG_CAN_SHOW_WITH_INSECURE_KEYGUARD) != 0) {
throw new IllegalArgumentException(
"Public display must not be marked as SHOW_WHEN_LOCKED_INSECURE");
}
}
if ((flags & VIRTUAL_DISPLAY_FLAG_OWN_CONTENT_ONLY) != 0) {
flags &= ~VIRTUAL_DISPLAY_FLAG_AUTO_MIRROR;
}
if (projection != null) {
try {
if (!getProjectionService().isValidMediaProjection(projection)) {
throw new SecurityException("Invalid media projection");
}
flags = projection.applyVirtualDisplayFlags(flags);
} catch (RemoteException e) {
throw new SecurityException("unable to validate media projection or flags");
}
}
if (callingUid != Process.SYSTEM_UID &&
(flags & VIRTUAL_DISPLAY_FLAG_AUTO_MIRROR) != 0) {
if (!canProjectVideo(projection)) {
throw new SecurityException("Requires CAPTURE_VIDEO_OUTPUT or "
+ "CAPTURE_SECURE_VIDEO_OUTPUT permission, or an appropriate "
+ "MediaProjection token in order to create a screen sharing virtual "
+ "display.");
}
}
if (callingUid != Process.SYSTEM_UID && (flags & VIRTUAL_DISPLAY_FLAG_SECURE) != 0) {
if (!canProjectSecureVideo(projection)) {
throw new SecurityException("Requires CAPTURE_SECURE_VIDEO_OUTPUT "
+ "or an appropriate MediaProjection token to create a "
+ "secure virtual display.");
}
}
// Sometimes users can have sensitive information in system decoration windows. An app
// could create a virtual display with system decorations support and read the user info
// from the surface.
// We should only allow adding flag VIRTUAL_DISPLAY_FLAG_SHOULD_SHOW_SYSTEM_DECORATIONS
// to virtual displays that are owned by the system.
if (callingUid != Process.SYSTEM_UID
&& (flags & VIRTUAL_DISPLAY_FLAG_SHOULD_SHOW_SYSTEM_DECORATIONS) != 0) {
if (!checkCallingPermission(INTERNAL_SYSTEM_WINDOW, "createVirtualDisplay()")) {
throw new SecurityException("Requires INTERNAL_SYSTEM_WINDOW permission");
}
}
final long token = Binder.clearCallingIdentity();
try {
return createVirtualDisplayInternal(callback, projection, callingUid, packageName,
name, width, height, densityDpi, surface, flags, uniqueId);
} finally {
Binder.restoreCallingIdentity(token);
}
}
@Override // Binder call
public void resizeVirtualDisplay(IVirtualDisplayCallback callback,
int width, int height, int densityDpi) {
final long token = Binder.clearCallingIdentity();
try {
resizeVirtualDisplayInternal(callback.asBinder(), width, height, densityDpi);
} finally {
Binder.restoreCallingIdentity(token);
}
}
@Override // Binder call
public void setVirtualDisplaySurface(IVirtualDisplayCallback callback, Surface surface) {
if (surface != null && surface.isSingleBuffered()) {
throw new IllegalArgumentException("Surface can't be single-buffered");
}
final long token = Binder.clearCallingIdentity();
try {
setVirtualDisplaySurfaceInternal(callback.asBinder(), surface);
} finally {
Binder.restoreCallingIdentity(token);
}
}
@Override // Binder call
public void releaseVirtualDisplay(IVirtualDisplayCallback callback) {
final long token = Binder.clearCallingIdentity();
try {
releaseVirtualDisplayInternal(callback.asBinder());
} finally {
Binder.restoreCallingIdentity(token);
}
}
@Override // Binder call
public void setVirtualDisplayState(IVirtualDisplayCallback callback, boolean isOn) {
final long token = Binder.clearCallingIdentity();
try {
setVirtualDisplayStateInternal(callback.asBinder(), isOn);
} finally {
Binder.restoreCallingIdentity(token);
}
}
@Override // Binder call
public void dump(FileDescriptor fd, final PrintWriter pw, String[] args) {
if (!DumpUtils.checkDumpPermission(mContext, TAG, pw)) return;
final long token = Binder.clearCallingIdentity();
try {
dumpInternal(pw);
} finally {
Binder.restoreCallingIdentity(token);
}
}
@Override // Binder call
public ParceledListSlice<BrightnessChangeEvent> getBrightnessEvents(String callingPackage) {
mContext.enforceCallingOrSelfPermission(
Manifest.permission.BRIGHTNESS_SLIDER_USAGE,
"Permission to read brightness events.");
final int callingUid = Binder.getCallingUid();
AppOpsManager appOpsManager = mContext.getSystemService(AppOpsManager.class);
final int mode = appOpsManager.noteOp(AppOpsManager.OP_GET_USAGE_STATS,
callingUid, callingPackage);
final boolean hasUsageStats;
if (mode == AppOpsManager.MODE_DEFAULT) {
// The default behavior here is to check if PackageManager has given the app
// permission.
hasUsageStats = mContext.checkCallingPermission(
Manifest.permission.PACKAGE_USAGE_STATS)
== PackageManager.PERMISSION_GRANTED;
} else {
hasUsageStats = mode == AppOpsManager.MODE_ALLOWED;
}
final int userId = UserHandle.getUserId(callingUid);
final long token = Binder.clearCallingIdentity();
try {
synchronized (mSyncRoot) {
return mDisplayPowerController.getBrightnessEvents(userId, hasUsageStats);
}
} finally {
Binder.restoreCallingIdentity(token);
}
}
@Override // Binder call
public ParceledListSlice<AmbientBrightnessDayStats> getAmbientBrightnessStats() {
mContext.enforceCallingOrSelfPermission(
Manifest.permission.ACCESS_AMBIENT_LIGHT_STATS,
"Permission required to to access ambient light stats.");
final int callingUid = Binder.getCallingUid();
final int userId = UserHandle.getUserId(callingUid);
final long token = Binder.clearCallingIdentity();
try {
synchronized (mSyncRoot) {
return mDisplayPowerController.getAmbientBrightnessStats(userId);
}
} finally {
Binder.restoreCallingIdentity(token);
}
}
@Override // Binder call
public void setBrightnessConfigurationForUser(
BrightnessConfiguration c, @UserIdInt int userId, String packageName) {
mContext.enforceCallingOrSelfPermission(
Manifest.permission.CONFIGURE_DISPLAY_BRIGHTNESS,
"Permission required to change the display's brightness configuration");
if (userId != UserHandle.getCallingUserId()) {
mContext.enforceCallingOrSelfPermission(
Manifest.permission.INTERACT_ACROSS_USERS,
"Permission required to change the display brightness"
+ " configuration of another user");
}
if (packageName != null && !validatePackageName(getCallingUid(), packageName)) {
packageName = null;
}
final long token = Binder.clearCallingIdentity();
try {
setBrightnessConfigurationForUserInternal(c, userId, packageName);
} finally {
Binder.restoreCallingIdentity(token);
}
}
@Override // Binder call
public BrightnessConfiguration getBrightnessConfigurationForUser(int userId) {
mContext.enforceCallingOrSelfPermission(
Manifest.permission.CONFIGURE_DISPLAY_BRIGHTNESS,
"Permission required to read the display's brightness configuration");
if (userId != UserHandle.getCallingUserId()) {
mContext.enforceCallingOrSelfPermission(
Manifest.permission.INTERACT_ACROSS_USERS,
"Permission required to read the display brightness"
+ " configuration of another user");
}
final long token = Binder.clearCallingIdentity();
try {
final int userSerial = getUserManager().getUserSerialNumber(userId);
synchronized (mSyncRoot) {
BrightnessConfiguration config =
mPersistentDataStore.getBrightnessConfiguration(userSerial);
if (config == null) {
config = mDisplayPowerController.getDefaultBrightnessConfiguration();
}
return config;
}
} finally {
Binder.restoreCallingIdentity(token);
}
}
@Override // Binder call
public BrightnessConfiguration getDefaultBrightnessConfiguration() {
mContext.enforceCallingOrSelfPermission(
Manifest.permission.CONFIGURE_DISPLAY_BRIGHTNESS,
"Permission required to read the display's default brightness configuration");
final long token = Binder.clearCallingIdentity();
try {
synchronized (mSyncRoot) {
return mDisplayPowerController.getDefaultBrightnessConfiguration();
}
} finally {
Binder.restoreCallingIdentity(token);
}
}
@Override // Binder call
public void setTemporaryBrightness(int brightness) {
mContext.enforceCallingOrSelfPermission(
Manifest.permission.CONTROL_DISPLAY_BRIGHTNESS,
"Permission required to set the display's brightness");
final long token = Binder.clearCallingIdentity();
try {
synchronized (mSyncRoot) {
mDisplayPowerController.setTemporaryBrightness(brightness);
}
} finally {
Binder.restoreCallingIdentity(token);
}
}
@Override // Binder call
public void setTemporaryAutoBrightnessAdjustment(float adjustment) {
mContext.enforceCallingOrSelfPermission(
Manifest.permission.CONTROL_DISPLAY_BRIGHTNESS,
"Permission required to set the display's auto brightness adjustment");
final long token = Binder.clearCallingIdentity();
try {
synchronized (mSyncRoot) {
mDisplayPowerController.setTemporaryAutoBrightnessAdjustment(adjustment);
}
} finally {
Binder.restoreCallingIdentity(token);
}
}
@Override // Binder call
public void onShellCommand(FileDescriptor in, FileDescriptor out,
FileDescriptor err, String[] args, ShellCallback callback,
ResultReceiver resultReceiver) {
final long token = Binder.clearCallingIdentity();
try {
DisplayManagerShellCommand command = new DisplayManagerShellCommand(this);
command.exec(this, in, out, err, args, callback, resultReceiver);
} finally {
Binder.restoreCallingIdentity(token);
}
}
@Override // Binder call
public Curve getMinimumBrightnessCurve() {
final long token = Binder.clearCallingIdentity();
try {
return getMinimumBrightnessCurveInternal();
} finally {
Binder.restoreCallingIdentity(token);
}
}
@Override // Binder call
public int getPreferredWideGamutColorSpaceId() {
final long token = Binder.clearCallingIdentity();
try {
return getPreferredWideGamutColorSpaceIdInternal();
} finally {
Binder.restoreCallingIdentity(token);
}
}
void setBrightness(int brightness) {
Settings.System.putIntForUser(mContext.getContentResolver(),
Settings.System.SCREEN_BRIGHTNESS, brightness, UserHandle.USER_CURRENT);
}
void resetBrightnessConfiguration() {
setBrightnessConfigurationForUserInternal(null, mContext.getUserId(),
mContext.getPackageName());
}
void setAutoBrightnessLoggingEnabled(boolean enabled) {
if (mDisplayPowerController != null) {
synchronized (mSyncRoot) {
mDisplayPowerController.setAutoBrightnessLoggingEnabled(enabled);
}
}
}
void setDisplayWhiteBalanceLoggingEnabled(boolean enabled) {
if (mDisplayPowerController != null) {
synchronized (mSyncRoot) {
mDisplayPowerController.setDisplayWhiteBalanceLoggingEnabled(enabled);
}
}
}
void setAmbientColorTemperatureOverride(float cct) {
if (mDisplayPowerController != null) {
synchronized (mSyncRoot) {
mDisplayPowerController.setAmbientColorTemperatureOverride(cct);
}
}
}
private boolean validatePackageName(int uid, String packageName) {
if (packageName != null) {
String[] packageNames = mContext.getPackageManager().getPackagesForUid(uid);
if (packageNames != null) {
for (String n : packageNames) {
if (n.equals(packageName)) {
return true;
}
}
}
}
return false;
}
private boolean canProjectVideo(IMediaProjection projection) {
if (projection != null) {
try {
if (projection.canProjectVideo()) {
return true;
}
} catch (RemoteException e) {
Slog.e(TAG, "Unable to query projection service for permissions", e);
}
}
if (checkCallingPermission(CAPTURE_VIDEO_OUTPUT, "canProjectVideo()")) {
return true;
}
return canProjectSecureVideo(projection);
}
private boolean canProjectSecureVideo(IMediaProjection projection) {
if (projection != null) {
try {
if (projection.canProjectSecureVideo()){
return true;
}
} catch (RemoteException e) {
Slog.e(TAG, "Unable to query projection service for permissions", e);
}
}
return checkCallingPermission(CAPTURE_SECURE_VIDEO_OUTPUT, "canProjectSecureVideo()");
}
private boolean checkCallingPermission(String permission, String func) {
if (mContext.checkCallingPermission(permission) == PackageManager.PERMISSION_GRANTED) {
return true;
}
final String msg = "Permission Denial: " + func + " from pid=" + Binder.getCallingPid()
+ ", uid=" + Binder.getCallingUid() + " requires " + permission;
Slog.w(TAG, msg);
return false;
}
}
private final class LocalService extends DisplayManagerInternal {
@Override
public void initPowerManagement(final DisplayPowerCallbacks callbacks, Handler handler,
SensorManager sensorManager) {
synchronized (mSyncRoot) {
DisplayBlanker blanker = new DisplayBlanker() {
@Override
public void requestDisplayState(int state, int brightness) {
// The order of operations is important for legacy reasons.
if (state == Display.STATE_OFF) {
requestGlobalDisplayStateInternal(state, brightness);
}
callbacks.onDisplayStateChange(state);
if (state != Display.STATE_OFF) {
requestGlobalDisplayStateInternal(state, brightness);
}
}
};
mDisplayPowerController = new DisplayPowerController(
mContext, callbacks, handler, sensorManager, blanker);
mSensorManager = sensorManager;
}
mHandler.sendEmptyMessage(MSG_LOAD_BRIGHTNESS_CONFIGURATION);
}
@Override
public boolean requestPowerState(DisplayPowerRequest request,
boolean waitForNegativeProximity) {
synchronized (mSyncRoot) {
return mDisplayPowerController.requestPowerState(request,
waitForNegativeProximity);
}
}
@Override
public boolean isProximitySensorAvailable() {
synchronized (mSyncRoot) {
return mDisplayPowerController.isProximitySensorAvailable();
}
}
@Override
public SurfaceControl.ScreenshotGraphicBuffer screenshot(int displayId) {
return screenshotInternal(displayId);
}
@Override
public DisplayInfo getDisplayInfo(int displayId) {
return getDisplayInfoInternal(displayId, Process.myUid());
}
@Override
public void registerDisplayTransactionListener(DisplayTransactionListener listener) {
if (listener == null) {
throw new IllegalArgumentException("listener must not be null");
}
registerDisplayTransactionListenerInternal(listener);
}
@Override
public void unregisterDisplayTransactionListener(DisplayTransactionListener listener) {
if (listener == null) {
throw new IllegalArgumentException("listener must not be null");
}
unregisterDisplayTransactionListenerInternal(listener);
}
@Override
public void setDisplayInfoOverrideFromWindowManager(int displayId, DisplayInfo info) {
setDisplayInfoOverrideFromWindowManagerInternal(displayId, info);
}
@Override
public void getNonOverrideDisplayInfo(int displayId, DisplayInfo outInfo) {
getNonOverrideDisplayInfoInternal(displayId, outInfo);
}
@Override
public void performTraversal(SurfaceControl.Transaction t) {
performTraversalInternal(t);
}
@Override
public void setDisplayProperties(int displayId, boolean hasContent,
float requestedRefreshRate, int requestedMode, boolean inTraversal) {
setDisplayPropertiesInternal(displayId, hasContent, requestedRefreshRate,
requestedMode, inTraversal);
}
@Override
public void setDisplayOffsets(int displayId, int x, int y) {
setDisplayOffsetsInternal(displayId, x, y);
}
@Override
public void setDisplayScalingDisabled(int displayId, boolean disableScaling) {
setDisplayScalingDisabledInternal(displayId, disableScaling);
}
@Override
public void setDisplayAccessUIDs(SparseArray<IntArray> newDisplayAccessUIDs) {
setDisplayAccessUIDsInternal(newDisplayAccessUIDs);
}
@Override
public void persistBrightnessTrackerState() {
synchronized (mSyncRoot) {
mDisplayPowerController.persistBrightnessTrackerState();
}
}
@Override
public void onOverlayChanged() {
synchronized (mSyncRoot) {
for (int i = 0; i < mDisplayDevices.size(); i++) {
mDisplayDevices.get(i).onOverlayChangedLocked();
}
}
}
@Override
public DisplayedContentSamplingAttributes getDisplayedContentSamplingAttributes(
int displayId) {
return getDisplayedContentSamplingAttributesInternal(displayId);
}
@Override
public boolean setDisplayedContentSamplingEnabled(
int displayId, boolean enable, int componentMask, int maxFrames) {
return setDisplayedContentSamplingEnabledInternal(
displayId, enable, componentMask, maxFrames);
}
@Override
public DisplayedContentSample getDisplayedContentSample(int displayId,
long maxFrames, long timestamp) {
return getDisplayedContentSampleInternal(displayId, maxFrames, timestamp);
}
}
class AllowedDisplayModeObserver implements DisplayModeDirector.Listener {
public void onAllowedDisplayModesChanged() {
onAllowedDisplayModesChangedInternal();
}
}
}