/* * Copyright (C) 2010 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. */ #ifndef _UI_INPUT_DISPATCHER_H #define _UI_INPUT_DISPATCHER_H #include #include #include #include #include #include #include #include #include #include #include #include #include namespace android { /* * Constants used to report the outcome of input event injection. */ enum { /* (INTERNAL USE ONLY) Specifies that injection is pending and its outcome is unknown. */ INPUT_EVENT_INJECTION_PENDING = -1, /* Injection succeeded. */ INPUT_EVENT_INJECTION_SUCCEEDED = 0, /* Injection failed because the injector did not have permission to inject * into the application with input focus. */ INPUT_EVENT_INJECTION_PERMISSION_DENIED = 1, /* Injection failed because there were no available input targets. */ INPUT_EVENT_INJECTION_FAILED = 2, /* Injection failed due to a timeout. */ INPUT_EVENT_INJECTION_TIMED_OUT = 3 }; /* * Constants used to determine the input event injection synchronization mode. */ enum { /* Injection is asynchronous and is assumed always to be successful. */ INPUT_EVENT_INJECTION_SYNC_NONE = 0, /* Waits for previous events to be dispatched so that the input dispatcher can determine * whether input event injection willbe permitted based on the current input focus. * Does not wait for the input event to finish processing. */ INPUT_EVENT_INJECTION_SYNC_WAIT_FOR_RESULT = 1, /* Waits for the input event to be completely processed. */ INPUT_EVENT_INJECTION_SYNC_WAIT_FOR_FINISHED = 2, }; /* * An input target specifies how an input event is to be dispatched to a particular window * including the window's input channel, control flags, a timeout, and an X / Y offset to * be added to input event coordinates to compensate for the absolute position of the * window area. */ struct InputTarget { enum { /* This flag indicates that the event is being delivered to a foreground application. */ FLAG_FOREGROUND = 0x01, /* This flag indicates that a MotionEvent with AMOTION_EVENT_ACTION_DOWN falls outside * of the area of this target and so should instead be delivered as an * AMOTION_EVENT_ACTION_OUTSIDE to this target. */ FLAG_OUTSIDE = 0x02, /* This flag indicates that a KeyEvent or MotionEvent is being canceled. * In the case of a key event, it should be delivered with flag * AKEY_EVENT_FLAG_CANCELED set. * In the case of a motion event, it should be delivered with action * AMOTION_EVENT_ACTION_CANCEL instead. */ FLAG_CANCEL = 0x04, /* This flag indicates that the target of a MotionEvent is partly or wholly * obscured by another visible window above it. The motion event should be * delivered with flag AMOTION_EVENT_FLAG_WINDOW_IS_OBSCURED. */ FLAG_WINDOW_IS_OBSCURED = 0x08, }; // The input channel to be targeted. sp inputChannel; // Flags for the input target. int32_t flags; // The x and y offset to add to a MotionEvent as it is delivered. // (ignored for KeyEvents) float xOffset, yOffset; }; /* * An input window describes the bounds of a window that can receive input. */ struct InputWindow { // Window flags from WindowManager.LayoutParams enum { FLAG_ALLOW_LOCK_WHILE_SCREEN_ON = 0x00000001, FLAG_DIM_BEHIND = 0x00000002, FLAG_BLUR_BEHIND = 0x00000004, FLAG_NOT_FOCUSABLE = 0x00000008, FLAG_NOT_TOUCHABLE = 0x00000010, FLAG_NOT_TOUCH_MODAL = 0x00000020, FLAG_TOUCHABLE_WHEN_WAKING = 0x00000040, FLAG_KEEP_SCREEN_ON = 0x00000080, FLAG_LAYOUT_IN_SCREEN = 0x00000100, FLAG_LAYOUT_NO_LIMITS = 0x00000200, FLAG_FULLSCREEN = 0x00000400, FLAG_FORCE_NOT_FULLSCREEN = 0x00000800, FLAG_DITHER = 0x00001000, FLAG_SECURE = 0x00002000, FLAG_SCALED = 0x00004000, FLAG_IGNORE_CHEEK_PRESSES = 0x00008000, FLAG_LAYOUT_INSET_DECOR = 0x00010000, FLAG_ALT_FOCUSABLE_IM = 0x00020000, FLAG_WATCH_OUTSIDE_TOUCH = 0x00040000, FLAG_SHOW_WHEN_LOCKED = 0x00080000, FLAG_SHOW_WALLPAPER = 0x00100000, FLAG_TURN_SCREEN_ON = 0x00200000, FLAG_DISMISS_KEYGUARD = 0x00400000, FLAG_IMMERSIVE = 0x00800000, FLAG_KEEP_SURFACE_WHILE_ANIMATING = 0x10000000, FLAG_COMPATIBLE_WINDOW = 0x20000000, FLAG_SYSTEM_ERROR = 0x40000000, }; // Window types from WindowManager.LayoutParams enum { FIRST_APPLICATION_WINDOW = 1, TYPE_BASE_APPLICATION = 1, TYPE_APPLICATION = 2, TYPE_APPLICATION_STARTING = 3, LAST_APPLICATION_WINDOW = 99, FIRST_SUB_WINDOW = 1000, TYPE_APPLICATION_PANEL = FIRST_SUB_WINDOW, TYPE_APPLICATION_MEDIA = FIRST_SUB_WINDOW+1, TYPE_APPLICATION_SUB_PANEL = FIRST_SUB_WINDOW+2, TYPE_APPLICATION_ATTACHED_DIALOG = FIRST_SUB_WINDOW+3, TYPE_APPLICATION_MEDIA_OVERLAY = FIRST_SUB_WINDOW+4, LAST_SUB_WINDOW = 1999, FIRST_SYSTEM_WINDOW = 2000, TYPE_STATUS_BAR = FIRST_SYSTEM_WINDOW, TYPE_SEARCH_BAR = FIRST_SYSTEM_WINDOW+1, TYPE_PHONE = FIRST_SYSTEM_WINDOW+2, TYPE_SYSTEM_ALERT = FIRST_SYSTEM_WINDOW+3, TYPE_KEYGUARD = FIRST_SYSTEM_WINDOW+4, TYPE_TOAST = FIRST_SYSTEM_WINDOW+5, TYPE_SYSTEM_OVERLAY = FIRST_SYSTEM_WINDOW+6, TYPE_PRIORITY_PHONE = FIRST_SYSTEM_WINDOW+7, TYPE_SYSTEM_DIALOG = FIRST_SYSTEM_WINDOW+8, TYPE_KEYGUARD_DIALOG = FIRST_SYSTEM_WINDOW+9, TYPE_SYSTEM_ERROR = FIRST_SYSTEM_WINDOW+10, TYPE_INPUT_METHOD = FIRST_SYSTEM_WINDOW+11, TYPE_INPUT_METHOD_DIALOG= FIRST_SYSTEM_WINDOW+12, TYPE_WALLPAPER = FIRST_SYSTEM_WINDOW+13, TYPE_STATUS_BAR_PANEL = FIRST_SYSTEM_WINDOW+14, LAST_SYSTEM_WINDOW = 2999, }; sp inputChannel; String8 name; int32_t layoutParamsFlags; int32_t layoutParamsType; nsecs_t dispatchingTimeout; int32_t frameLeft; int32_t frameTop; int32_t frameRight; int32_t frameBottom; int32_t visibleFrameLeft; int32_t visibleFrameTop; int32_t visibleFrameRight; int32_t visibleFrameBottom; int32_t touchableAreaLeft; int32_t touchableAreaTop; int32_t touchableAreaRight; int32_t touchableAreaBottom; bool visible; bool canReceiveKeys; bool hasFocus; bool hasWallpaper; bool paused; int32_t layer; int32_t ownerPid; int32_t ownerUid; bool visibleFrameIntersects(const InputWindow* other) const; bool touchableAreaContainsPoint(int32_t x, int32_t y) const; }; /* * A private handle type used by the input manager to track the window. */ class InputApplicationHandle : public RefBase { protected: InputApplicationHandle() { } virtual ~InputApplicationHandle() { } }; /* * An input application describes properties of an application that can receive input. */ struct InputApplication { String8 name; nsecs_t dispatchingTimeout; sp handle; }; /* * Input dispatcher policy interface. * * The input reader policy is used by the input reader to interact with the Window Manager * and other system components. * * The actual implementation is partially supported by callbacks into the DVM * via JNI. This interface is also mocked in the unit tests. */ class InputDispatcherPolicyInterface : public virtual RefBase { protected: InputDispatcherPolicyInterface() { } virtual ~InputDispatcherPolicyInterface() { } public: /* Notifies the system that a configuration change has occurred. */ virtual void notifyConfigurationChanged(nsecs_t when) = 0; /* Notifies the system that an application is not responding. * Returns a new timeout to continue waiting, or 0 to abort dispatch. */ virtual nsecs_t notifyANR(const sp& inputApplicationHandle, const sp& inputChannel) = 0; /* Notifies the system that an input channel is unrecoverably broken. */ virtual void notifyInputChannelBroken(const sp& inputChannel) = 0; /* Gets the key repeat initial timeout or -1 if automatic key repeating is disabled. */ virtual nsecs_t getKeyRepeatTimeout() = 0; /* Gets the key repeat inter-key delay. */ virtual nsecs_t getKeyRepeatDelay() = 0; /* Gets the maximum suggested event delivery rate per second. * This value is used to throttle motion event movement actions on a per-device * basis. It is not intended to be a hard limit. */ virtual int32_t getMaxEventsPerSecond() = 0; /* Allows the policy a chance to intercept a key before dispatching. */ virtual bool interceptKeyBeforeDispatching(const sp& inputChannel, const KeyEvent* keyEvent, uint32_t policyFlags) = 0; /* Poke user activity for an event dispatched to a window. */ virtual void pokeUserActivity(nsecs_t eventTime, int32_t windowType, int32_t eventType) = 0; /* Checks whether a given application pid/uid has permission to inject input events * into other applications. * * This method is special in that its implementation promises to be non-reentrant and * is safe to call while holding other locks. (Most other methods make no such guarantees!) */ virtual bool checkInjectEventsPermissionNonReentrant( int32_t injectorPid, int32_t injectorUid) = 0; }; /* Notifies the system about input events generated by the input reader. * The dispatcher is expected to be mostly asynchronous. */ class InputDispatcherInterface : public virtual RefBase { protected: InputDispatcherInterface() { } virtual ~InputDispatcherInterface() { } public: /* Dumps the state of the input dispatcher. * * This method may be called on any thread (usually by the input manager). */ virtual void dump(String8& dump) = 0; /* Runs a single iteration of the dispatch loop. * Nominally processes one queued event, a timeout, or a response from an input consumer. * * This method should only be called on the input dispatcher thread. */ virtual void dispatchOnce() = 0; /* Notifies the dispatcher about new events. * * These methods should only be called on the input reader thread. */ virtual void notifyConfigurationChanged(nsecs_t eventTime) = 0; virtual void notifyKey(nsecs_t eventTime, int32_t deviceId, int32_t source, uint32_t policyFlags, int32_t action, int32_t flags, int32_t keyCode, int32_t scanCode, int32_t metaState, nsecs_t downTime) = 0; virtual void notifyMotion(nsecs_t eventTime, int32_t deviceId, int32_t source, uint32_t policyFlags, int32_t action, int32_t flags, int32_t metaState, int32_t edgeFlags, uint32_t pointerCount, const int32_t* pointerIds, const PointerCoords* pointerCoords, float xPrecision, float yPrecision, nsecs_t downTime) = 0; /* Injects an input event and optionally waits for sync. * The synchronization mode determines whether the method blocks while waiting for * input injection to proceed. * Returns one of the INPUT_EVENT_INJECTION_XXX constants. * * This method may be called on any thread (usually by the input manager). */ virtual int32_t injectInputEvent(const InputEvent* event, int32_t injectorPid, int32_t injectorUid, int32_t syncMode, int32_t timeoutMillis) = 0; /* Sets the list of input windows. * * This method may be called on any thread (usually by the input manager). */ virtual void setInputWindows(const Vector& inputWindows) = 0; /* Sets the focused application. * * This method may be called on any thread (usually by the input manager). */ virtual void setFocusedApplication(const InputApplication* inputApplication) = 0; /* Sets the input dispatching mode. * * This method may be called on any thread (usually by the input manager). */ virtual void setInputDispatchMode(bool enabled, bool frozen) = 0; /* Registers or unregister input channels that may be used as targets for input events. * If monitor is true, the channel will receive a copy of all input events. * * These methods may be called on any thread (usually by the input manager). */ virtual status_t registerInputChannel(const sp& inputChannel, bool monitor) = 0; virtual status_t unregisterInputChannel(const sp& inputChannel) = 0; }; /* Dispatches events to input targets. Some functions of the input dispatcher, such as * identifying input targets, are controlled by a separate policy object. * * IMPORTANT INVARIANT: * Because the policy can potentially block or cause re-entrance into the input dispatcher, * the input dispatcher never calls into the policy while holding its internal locks. * The implementation is also carefully designed to recover from scenarios such as an * input channel becoming unregistered while identifying input targets or processing timeouts. * * Methods marked 'Locked' must be called with the lock acquired. * * Methods marked 'LockedInterruptible' must be called with the lock acquired but * may during the course of their execution release the lock, call into the policy, and * then reacquire the lock. The caller is responsible for recovering gracefully. * * A 'LockedInterruptible' method may called a 'Locked' method, but NOT vice-versa. */ class InputDispatcher : public InputDispatcherInterface { protected: virtual ~InputDispatcher(); public: explicit InputDispatcher(const sp& policy); virtual void dump(String8& dump); virtual void dispatchOnce(); virtual void notifyConfigurationChanged(nsecs_t eventTime); virtual void notifyKey(nsecs_t eventTime, int32_t deviceId, int32_t source, uint32_t policyFlags, int32_t action, int32_t flags, int32_t keyCode, int32_t scanCode, int32_t metaState, nsecs_t downTime); virtual void notifyMotion(nsecs_t eventTime, int32_t deviceId, int32_t source, uint32_t policyFlags, int32_t action, int32_t flags, int32_t metaState, int32_t edgeFlags, uint32_t pointerCount, const int32_t* pointerIds, const PointerCoords* pointerCoords, float xPrecision, float yPrecision, nsecs_t downTime); virtual int32_t injectInputEvent(const InputEvent* event, int32_t injectorPid, int32_t injectorUid, int32_t syncMode, int32_t timeoutMillis); virtual void setInputWindows(const Vector& inputWindows); virtual void setFocusedApplication(const InputApplication* inputApplication); virtual void setInputDispatchMode(bool enabled, bool frozen); virtual status_t registerInputChannel(const sp& inputChannel, bool monitor); virtual status_t unregisterInputChannel(const sp& inputChannel); private: template struct Link { T* next; T* prev; }; struct EventEntry : Link { enum { TYPE_SENTINEL, TYPE_CONFIGURATION_CHANGED, TYPE_KEY, TYPE_MOTION }; int32_t refCount; int32_t type; nsecs_t eventTime; int32_t injectionResult; // initially INPUT_EVENT_INJECTION_PENDING bool injectionIsAsync; // set to true if injection is not waiting for the result int32_t injectorPid; // -1 if not injected int32_t injectorUid; // -1 if not injected bool dispatchInProgress; // initially false, set to true while dispatching int32_t pendingForegroundDispatches; // the number of foreground dispatches in progress inline bool isInjected() { return injectorPid >= 0; } void recycle(); }; struct ConfigurationChangedEntry : EventEntry { }; struct KeyEntry : EventEntry { int32_t deviceId; int32_t source; uint32_t policyFlags; int32_t action; int32_t flags; int32_t keyCode; int32_t scanCode; int32_t metaState; int32_t repeatCount; nsecs_t downTime; bool syntheticRepeat; // set to true for synthetic key repeats enum InterceptKeyResult { INTERCEPT_KEY_RESULT_UNKNOWN, INTERCEPT_KEY_RESULT_SKIP, INTERCEPT_KEY_RESULT_CONTINUE, }; InterceptKeyResult interceptKeyResult; // set based on the interception result void recycle(); }; struct MotionSample { MotionSample* next; nsecs_t eventTime; PointerCoords pointerCoords[MAX_POINTERS]; }; struct MotionEntry : EventEntry { int32_t deviceId; int32_t source; uint32_t policyFlags; int32_t action; int32_t flags; int32_t metaState; int32_t edgeFlags; float xPrecision; float yPrecision; nsecs_t downTime; uint32_t pointerCount; int32_t pointerIds[MAX_POINTERS]; // Linked list of motion samples associated with this motion event. MotionSample firstSample; MotionSample* lastSample; uint32_t countSamples() const; }; // Tracks the progress of dispatching a particular event to a particular connection. struct DispatchEntry : Link { EventEntry* eventEntry; // the event to dispatch int32_t targetFlags; float xOffset; float yOffset; // True if dispatch has started. bool inProgress; // For motion events: // Pointer to the first motion sample to dispatch in this cycle. // Usually NULL to indicate that the list of motion samples begins at // MotionEntry::firstSample. Otherwise, some samples were dispatched in a previous // cycle and this pointer indicates the location of the first remainining sample // to dispatch during the current cycle. MotionSample* headMotionSample; // Pointer to a motion sample to dispatch in the next cycle if the dispatcher was // unable to send all motion samples during this cycle. On the next cycle, // headMotionSample will be initialized to tailMotionSample and tailMotionSample // will be set to NULL. MotionSample* tailMotionSample; inline bool hasForegroundTarget() const { return targetFlags & InputTarget::FLAG_FOREGROUND; } }; // A command entry captures state and behavior for an action to be performed in the // dispatch loop after the initial processing has taken place. It is essentially // a kind of continuation used to postpone sensitive policy interactions to a point // in the dispatch loop where it is safe to release the lock (generally after finishing // the critical parts of the dispatch cycle). // // The special thing about commands is that they can voluntarily release and reacquire // the dispatcher lock at will. Initially when the command starts running, the // dispatcher lock is held. However, if the command needs to call into the policy to // do some work, it can release the lock, do the work, then reacquire the lock again // before returning. // // This mechanism is a bit clunky but it helps to preserve the invariant that the dispatch // never calls into the policy while holding its lock. // // Commands are implicitly 'LockedInterruptible'. struct CommandEntry; typedef void (InputDispatcher::*Command)(CommandEntry* commandEntry); class Connection; struct CommandEntry : Link { CommandEntry(); ~CommandEntry(); Command command; // parameters for the command (usage varies by command) sp connection; nsecs_t eventTime; KeyEntry* keyEntry; sp inputChannel; sp inputApplicationHandle; int32_t windowType; int32_t userActivityEventType; }; // Generic queue implementation. template struct Queue { T headSentinel; T tailSentinel; inline Queue() { headSentinel.prev = NULL; headSentinel.next = & tailSentinel; tailSentinel.prev = & headSentinel; tailSentinel.next = NULL; } inline bool isEmpty() const { return headSentinel.next == & tailSentinel; } inline void enqueueAtTail(T* entry) { T* last = tailSentinel.prev; last->next = entry; entry->prev = last; entry->next = & tailSentinel; tailSentinel.prev = entry; } inline void enqueueAtHead(T* entry) { T* first = headSentinel.next; headSentinel.next = entry; entry->prev = & headSentinel; entry->next = first; first->prev = entry; } inline void dequeue(T* entry) { entry->prev->next = entry->next; entry->next->prev = entry->prev; } inline T* dequeueAtHead() { T* first = headSentinel.next; dequeue(first); return first; } uint32_t count() const; }; /* Allocates queue entries and performs reference counting as needed. */ class Allocator { public: Allocator(); ConfigurationChangedEntry* obtainConfigurationChangedEntry(nsecs_t eventTime); KeyEntry* obtainKeyEntry(nsecs_t eventTime, int32_t deviceId, int32_t source, uint32_t policyFlags, int32_t action, int32_t flags, int32_t keyCode, int32_t scanCode, int32_t metaState, int32_t repeatCount, nsecs_t downTime); MotionEntry* obtainMotionEntry(nsecs_t eventTime, int32_t deviceId, int32_t source, uint32_t policyFlags, int32_t action, int32_t flags, int32_t metaState, int32_t edgeFlags, float xPrecision, float yPrecision, nsecs_t downTime, uint32_t pointerCount, const int32_t* pointerIds, const PointerCoords* pointerCoords); DispatchEntry* obtainDispatchEntry(EventEntry* eventEntry, int32_t targetFlags, float xOffset, float yOffset); CommandEntry* obtainCommandEntry(Command command); void releaseEventEntry(EventEntry* entry); void releaseConfigurationChangedEntry(ConfigurationChangedEntry* entry); void releaseKeyEntry(KeyEntry* entry); void releaseMotionEntry(MotionEntry* entry); void releaseDispatchEntry(DispatchEntry* entry); void releaseCommandEntry(CommandEntry* entry); void appendMotionSample(MotionEntry* motionEntry, nsecs_t eventTime, const PointerCoords* pointerCoords); private: Pool mConfigurationChangeEntryPool; Pool mKeyEntryPool; Pool mMotionEntryPool; Pool mMotionSamplePool; Pool mDispatchEntryPool; Pool mCommandEntryPool; void initializeEventEntry(EventEntry* entry, int32_t type, nsecs_t eventTime); }; /* Tracks dispatched key and motion event state so that cancelation events can be * synthesized when events are dropped. */ class InputState { public: // Specifies whether a given event will violate input state consistency. enum Consistency { // The event is consistent with the current input state. CONSISTENT, // The event is inconsistent with the current input state but applications // will tolerate it. eg. Down followed by another down. TOLERABLE, // The event is inconsistent with the current input state and will probably // cause applications to crash. eg. Up without prior down, move with // unexpected number of pointers. BROKEN }; InputState(); ~InputState(); // Returns true if there is no state to be canceled. bool isNeutral() const; // Returns true if the input state believes it is out of sync. bool isOutOfSync() const; // Sets the input state to be out of sync if it is not neutral. void setOutOfSync(); // Resets the input state out of sync flag. void resetOutOfSync(); // Records tracking information for an event that has just been published. // Returns whether the event is consistent with the current input state. Consistency trackEvent(const EventEntry* entry); // Records tracking information for a key event that has just been published. // Returns whether the event is consistent with the current input state. Consistency trackKey(const KeyEntry* entry); // Records tracking information for a motion event that has just been published. // Returns whether the event is consistent with the current input state. Consistency trackMotion(const MotionEntry* entry); // Synthesizes cancelation events for the current state. void synthesizeCancelationEvents(Allocator* allocator, Vector& outEvents) const; // Clears the current state. void clear(); private: bool mIsOutOfSync; struct KeyMemento { int32_t deviceId; int32_t source; int32_t keyCode; int32_t scanCode; nsecs_t downTime; }; struct MotionMemento { int32_t deviceId; int32_t source; float xPrecision; float yPrecision; nsecs_t downTime; uint32_t pointerCount; int32_t pointerIds[MAX_POINTERS]; PointerCoords pointerCoords[MAX_POINTERS]; void setPointers(const MotionEntry* entry); }; Vector mKeyMementos; Vector mMotionMementos; }; /* Manages the dispatch state associated with a single input channel. */ class Connection : public RefBase { protected: virtual ~Connection(); public: enum Status { // Everything is peachy. STATUS_NORMAL, // An unrecoverable communication error has occurred. STATUS_BROKEN, // The input channel has been unregistered. STATUS_ZOMBIE }; Status status; sp inputChannel; InputPublisher inputPublisher; InputState inputState; Queue outboundQueue; nsecs_t lastEventTime; // the time when the event was originally captured nsecs_t lastDispatchTime; // the time when the last event was dispatched explicit Connection(const sp& inputChannel); inline const char* getInputChannelName() const { return inputChannel->getName().string(); } const char* getStatusLabel() const; // Finds a DispatchEntry in the outbound queue associated with the specified event. // Returns NULL if not found. DispatchEntry* findQueuedDispatchEntryForEvent(const EventEntry* eventEntry) const; // Gets the time since the current event was originally obtained from the input driver. inline double getEventLatencyMillis(nsecs_t currentTime) const { return (currentTime - lastEventTime) / 1000000.0; } // Gets the time since the current event entered the outbound dispatch queue. inline double getDispatchLatencyMillis(nsecs_t currentTime) const { return (currentTime - lastDispatchTime) / 1000000.0; } status_t initialize(); }; sp mPolicy; Mutex mLock; Allocator mAllocator; sp mLooper; EventEntry* mPendingEvent; Queue mInboundQueue; Queue mCommandQueue; Vector mTempCancelationEvents; void dispatchOnceInnerLocked(nsecs_t keyRepeatTimeout, nsecs_t keyRepeatDelay, nsecs_t* nextWakeupTime); // Enqueues an inbound event. Returns true if mLooper->wake() should be called. bool enqueueInboundEventLocked(EventEntry* entry); // App switch latency optimization. nsecs_t mAppSwitchDueTime; static bool isAppSwitchKey(int32_t keyCode); bool isAppSwitchPendingLocked(); bool detectPendingAppSwitchLocked(KeyEntry* inboundKeyEntry); void resetPendingAppSwitchLocked(bool handled); // All registered connections mapped by receive pipe file descriptor. KeyedVector > mConnectionsByReceiveFd; ssize_t getConnectionIndexLocked(const sp& inputChannel); // Active connections are connections that have a non-empty outbound queue. // We don't use a ref-counted pointer here because we explicitly abort connections // during unregistration which causes the connection's outbound queue to be cleared // and the connection itself to be deactivated. Vector mActiveConnections; // Input channels that will receive a copy of all input events. Vector > mMonitoringChannels; // Preallocated key event object used for policy inquiries. KeyEvent mReusableKeyEvent; // Event injection and synchronization. Condition mInjectionResultAvailableCondition; EventEntry* createEntryFromInjectedInputEventLocked(const InputEvent* event); void setInjectionResultLocked(EventEntry* entry, int32_t injectionResult); Condition mInjectionSyncFinishedCondition; void decrementPendingForegroundDispatchesLocked(EventEntry* entry); // Throttling state. struct ThrottleState { nsecs_t minTimeBetweenEvents; nsecs_t lastEventTime; int32_t lastDeviceId; uint32_t lastSource; uint32_t originalSampleCount; // only collected during debugging } mThrottleState; // Key repeat tracking. struct KeyRepeatState { KeyEntry* lastKeyEntry; // or null if no repeat nsecs_t nextRepeatTime; } mKeyRepeatState; void resetKeyRepeatLocked(); KeyEntry* synthesizeKeyRepeatLocked(nsecs_t currentTime, nsecs_t keyRepeatTimeout); // Deferred command processing. bool runCommandsLockedInterruptible(); CommandEntry* postCommandLocked(Command command); // Inbound event processing. void drainInboundQueueLocked(); void releasePendingEventLocked(bool wasDropped); void releaseInboundEventLocked(EventEntry* entry, bool wasDropped); bool isEventFromReliableSourceLocked(EventEntry* entry); // Dispatch state. bool mDispatchEnabled; bool mDispatchFrozen; Vector mWindows; Vector mWallpaperWindows; // Focus tracking for keys, trackball, etc. InputWindow* mFocusedWindow; // Focus tracking for touch. bool mTouchDown; InputWindow* mTouchedWindow; // primary target for current down bool mTouchedWindowIsObscured; // true if other windows may obscure the target Vector mTouchedWallpaperWindows; // wallpaper targets struct OutsideTarget { InputWindow* window; bool obscured; }; Vector mTempTouchedOutsideTargets; // temporary outside touch targets Vector > mTempTouchedWallpaperChannels; // temporary wallpaper targets // Focused application. InputApplication* mFocusedApplication; InputApplication mFocusedApplicationStorage; // preallocated storage for mFocusedApplication void releaseFocusedApplicationLocked(); // Dispatch inbound events. bool dispatchConfigurationChangedLocked( nsecs_t currentTime, ConfigurationChangedEntry* entry); bool dispatchKeyLocked( nsecs_t currentTime, KeyEntry* entry, nsecs_t keyRepeatTimeout, nsecs_t* nextWakeupTime); bool dispatchMotionLocked( nsecs_t currentTime, MotionEntry* entry, nsecs_t* nextWakeupTime); void dispatchEventToCurrentInputTargetsLocked( nsecs_t currentTime, EventEntry* entry, bool resumeWithAppendedMotionSample); void logOutboundKeyDetailsLocked(const char* prefix, const KeyEntry* entry); void logOutboundMotionDetailsLocked(const char* prefix, const MotionEntry* entry); // The input targets that were most recently identified for dispatch. bool mCurrentInputTargetsValid; // false while targets are being recomputed Vector mCurrentInputTargets; int32_t mCurrentInputWindowType; sp mCurrentInputChannel; enum InputTargetWaitCause { INPUT_TARGET_WAIT_CAUSE_NONE, INPUT_TARGET_WAIT_CAUSE_SYSTEM_NOT_READY, INPUT_TARGET_WAIT_CAUSE_APPLICATION_NOT_READY, }; InputTargetWaitCause mInputTargetWaitCause; nsecs_t mInputTargetWaitStartTime; nsecs_t mInputTargetWaitTimeoutTime; bool mInputTargetWaitTimeoutExpired; // Finding targets for input events. void startFindingTargetsLocked(); void finishFindingTargetsLocked(const InputWindow* window); int32_t handleTargetsNotReadyLocked(nsecs_t currentTime, const EventEntry* entry, const InputApplication* application, const InputWindow* window, nsecs_t* nextWakeupTime); void resumeAfterTargetsNotReadyTimeoutLocked(nsecs_t newTimeout, const sp& inputChannel); nsecs_t getTimeSpentWaitingForApplicationLocked(nsecs_t currentTime); void resetANRTimeoutsLocked(); int32_t findFocusedWindowLocked(nsecs_t currentTime, const EventEntry* entry, nsecs_t* nextWakeupTime, InputWindow** outWindow); int32_t findTouchedWindowLocked(nsecs_t currentTime, const MotionEntry* entry, nsecs_t* nextWakeupTime, InputWindow** outWindow); void addWindowTargetLocked(const InputWindow* window, int32_t targetFlags); void addMonitoringTargetsLocked(); void pokeUserActivityLocked(nsecs_t eventTime, int32_t windowType, int32_t eventType); bool checkInjectionPermission(const InputWindow* window, int32_t injectorPid, int32_t injectorUid); bool isWindowObscuredLocked(const InputWindow* window); bool isWindowFinishedWithPreviousInputLocked(const InputWindow* window); void releaseTouchedWindowLocked(); String8 getApplicationWindowLabelLocked(const InputApplication* application, const InputWindow* window); // Manage the dispatch cycle for a single connection. // These methods are deliberately not Interruptible because doing all of the work // with the mutex held makes it easier to ensure that connection invariants are maintained. // If needed, the methods post commands to run later once the critical bits are done. void prepareDispatchCycleLocked(nsecs_t currentTime, const sp& connection, EventEntry* eventEntry, const InputTarget* inputTarget, bool resumeWithAppendedMotionSample); void startDispatchCycleLocked(nsecs_t currentTime, const sp& connection); void finishDispatchCycleLocked(nsecs_t currentTime, const sp& connection); void startNextDispatchCycleLocked(nsecs_t currentTime, const sp& connection); void abortDispatchCycleLocked(nsecs_t currentTime, const sp& connection, bool broken); void drainOutboundQueueLocked(Connection* connection); static int handleReceiveCallback(int receiveFd, int events, void* data); // Dump state. void dumpDispatchStateLocked(String8& dump); void logDispatchStateLocked(); // Add or remove a connection to the mActiveConnections vector. void activateConnectionLocked(Connection* connection); void deactivateConnectionLocked(Connection* connection); // Interesting events that we might like to log or tell the framework about. void onDispatchCycleStartedLocked( nsecs_t currentTime, const sp& connection); void onDispatchCycleFinishedLocked( nsecs_t currentTime, const sp& connection); void onDispatchCycleBrokenLocked( nsecs_t currentTime, const sp& connection); void onANRLocked( nsecs_t currentTime, const InputApplication* application, const InputWindow* window, nsecs_t eventTime, nsecs_t waitStartTime); // Outbound policy interactions. void doNotifyConfigurationChangedInterruptible(CommandEntry* commandEntry); void doNotifyInputChannelBrokenLockedInterruptible(CommandEntry* commandEntry); void doNotifyANRLockedInterruptible(CommandEntry* commandEntry); void doInterceptKeyBeforeDispatchingLockedInterruptible(CommandEntry* commandEntry); void doPokeUserActivityLockedInterruptible(CommandEntry* commandEntry); // Statistics gathering. void updateDispatchStatisticsLocked(nsecs_t currentTime, const EventEntry* entry, int32_t injectionResult, nsecs_t timeSpentWaitingForApplication); }; /* Enqueues and dispatches input events, endlessly. */ class InputDispatcherThread : public Thread { public: explicit InputDispatcherThread(const sp& dispatcher); ~InputDispatcherThread(); private: virtual bool threadLoop(); sp mDispatcher; }; } // namespace android #endif // _UI_INPUT_DISPATCHER_H