replicant-frameworks_native/libs/ui/InputDispatcher.cpp
Jeff Brown 3c3cc62e24 Add unit tests for native input and fix bugs identified.
Fixed a bug where we would lose the first touch point when swiping out of
the virtual key area.

Fixed a bug where we would not send an ACTION_MOVE event in cases where
individual pointers went down/up and the remaining pointers actually moved.
This is important since many applications do not handle pointer movements
during ACTION_POINTER_DOWN or ACTION_POINTER_UP.  In the case of
ACTION_POINTER_UP the movement was completely lost since all pointers were
dispatched using their old location rather than the new location.

Improved motion event validation to check for duplicate pointer ids.

Added an input source constant that was missing from the NDK api but
defined in the framework api.

Added a timestamp when reporting added/removed devices in EventHub.

Bug: 3070082
Change-Id: I3206a030f43b7616e2f48006e5a9d522c4d92e56
2010-10-23 03:52:57 -07:00

3483 lines
130 KiB
C++

//
// Copyright 2010 The Android Open Source Project
//
// The input dispatcher.
//
#define LOG_TAG "InputDispatcher"
//#define LOG_NDEBUG 0
// Log detailed debug messages about each inbound event notification to the dispatcher.
#define DEBUG_INBOUND_EVENT_DETAILS 0
// Log detailed debug messages about each outbound event processed by the dispatcher.
#define DEBUG_OUTBOUND_EVENT_DETAILS 0
// Log debug messages about batching.
#define DEBUG_BATCHING 0
// Log debug messages about the dispatch cycle.
#define DEBUG_DISPATCH_CYCLE 0
// Log debug messages about registrations.
#define DEBUG_REGISTRATION 0
// Log debug messages about performance statistics.
#define DEBUG_PERFORMANCE_STATISTICS 0
// Log debug messages about input event injection.
#define DEBUG_INJECTION 0
// Log debug messages about input event throttling.
#define DEBUG_THROTTLING 0
// Log debug messages about input focus tracking.
#define DEBUG_FOCUS 0
// Log debug messages about the app switch latency optimization.
#define DEBUG_APP_SWITCH 0
#include <cutils/log.h>
#include <ui/InputDispatcher.h>
#include <ui/PowerManager.h>
#include <stddef.h>
#include <unistd.h>
#include <errno.h>
#include <limits.h>
#define INDENT " "
#define INDENT2 " "
namespace android {
// Delay between reporting long touch events to the power manager.
const nsecs_t EVENT_IGNORE_DURATION = 300 * 1000000LL; // 300 ms
// Default input dispatching timeout if there is no focused application or paused window
// from which to determine an appropriate dispatching timeout.
const nsecs_t DEFAULT_INPUT_DISPATCHING_TIMEOUT = 5000 * 1000000LL; // 5 sec
// Amount of time to allow for all pending events to be processed when an app switch
// key is on the way. This is used to preempt input dispatch and drop input events
// when an application takes too long to respond and the user has pressed an app switch key.
const nsecs_t APP_SWITCH_TIMEOUT = 500 * 1000000LL; // 0.5sec
static inline nsecs_t now() {
return systemTime(SYSTEM_TIME_MONOTONIC);
}
static inline const char* toString(bool value) {
return value ? "true" : "false";
}
static inline int32_t getMotionEventActionPointerIndex(int32_t action) {
return (action & AMOTION_EVENT_ACTION_POINTER_INDEX_MASK)
>> AMOTION_EVENT_ACTION_POINTER_INDEX_SHIFT;
}
static bool isValidKeyAction(int32_t action) {
switch (action) {
case AKEY_EVENT_ACTION_DOWN:
case AKEY_EVENT_ACTION_UP:
return true;
default:
return false;
}
}
static bool validateKeyEvent(int32_t action) {
if (! isValidKeyAction(action)) {
LOGE("Key event has invalid action code 0x%x", action);
return false;
}
return true;
}
static bool isValidMotionAction(int32_t action, size_t pointerCount) {
switch (action & AMOTION_EVENT_ACTION_MASK) {
case AMOTION_EVENT_ACTION_DOWN:
case AMOTION_EVENT_ACTION_UP:
case AMOTION_EVENT_ACTION_CANCEL:
case AMOTION_EVENT_ACTION_MOVE:
case AMOTION_EVENT_ACTION_OUTSIDE:
return true;
case AMOTION_EVENT_ACTION_POINTER_DOWN:
case AMOTION_EVENT_ACTION_POINTER_UP: {
int32_t index = getMotionEventActionPointerIndex(action);
return index >= 0 && size_t(index) < pointerCount;
}
default:
return false;
}
}
static bool validateMotionEvent(int32_t action, size_t pointerCount,
const int32_t* pointerIds) {
if (! isValidMotionAction(action, pointerCount)) {
LOGE("Motion event has invalid action code 0x%x", action);
return false;
}
if (pointerCount < 1 || pointerCount > MAX_POINTERS) {
LOGE("Motion event has invalid pointer count %d; value must be between 1 and %d.",
pointerCount, MAX_POINTERS);
return false;
}
BitSet32 pointerIdBits;
for (size_t i = 0; i < pointerCount; i++) {
int32_t id = pointerIds[i];
if (id < 0 || id > MAX_POINTER_ID) {
LOGE("Motion event has invalid pointer id %d; value must be between 0 and %d",
id, MAX_POINTER_ID);
return false;
}
if (pointerIdBits.hasBit(id)) {
LOGE("Motion event has duplicate pointer id %d", id);
return false;
}
pointerIdBits.markBit(id);
}
return true;
}
// --- InputWindow ---
bool InputWindow::touchableAreaContainsPoint(int32_t x, int32_t y) const {
return x >= touchableAreaLeft && x <= touchableAreaRight
&& y >= touchableAreaTop && y <= touchableAreaBottom;
}
bool InputWindow::frameContainsPoint(int32_t x, int32_t y) const {
return x >= frameLeft && x <= frameRight
&& y >= frameTop && y <= frameBottom;
}
bool InputWindow::isTrustedOverlay() const {
return layoutParamsType == TYPE_INPUT_METHOD
|| layoutParamsType == TYPE_INPUT_METHOD_DIALOG
|| layoutParamsType == TYPE_SECURE_SYSTEM_OVERLAY;
}
// --- InputDispatcher ---
InputDispatcher::InputDispatcher(const sp<InputDispatcherPolicyInterface>& policy) :
mPolicy(policy),
mPendingEvent(NULL), mAppSwitchDueTime(LONG_LONG_MAX),
mDispatchEnabled(true), mDispatchFrozen(false),
mFocusedWindow(NULL),
mFocusedApplication(NULL),
mCurrentInputTargetsValid(false),
mInputTargetWaitCause(INPUT_TARGET_WAIT_CAUSE_NONE) {
mLooper = new Looper(false);
mInboundQueue.headSentinel.refCount = -1;
mInboundQueue.headSentinel.type = EventEntry::TYPE_SENTINEL;
mInboundQueue.headSentinel.eventTime = LONG_LONG_MIN;
mInboundQueue.tailSentinel.refCount = -1;
mInboundQueue.tailSentinel.type = EventEntry::TYPE_SENTINEL;
mInboundQueue.tailSentinel.eventTime = LONG_LONG_MAX;
mKeyRepeatState.lastKeyEntry = NULL;
int32_t maxEventsPerSecond = policy->getMaxEventsPerSecond();
mThrottleState.minTimeBetweenEvents = 1000000000LL / maxEventsPerSecond;
mThrottleState.lastDeviceId = -1;
#if DEBUG_THROTTLING
mThrottleState.originalSampleCount = 0;
LOGD("Throttling - Max events per second = %d", maxEventsPerSecond);
#endif
}
InputDispatcher::~InputDispatcher() {
{ // acquire lock
AutoMutex _l(mLock);
resetKeyRepeatLocked();
releasePendingEventLocked();
drainInboundQueueLocked();
}
while (mConnectionsByReceiveFd.size() != 0) {
unregisterInputChannel(mConnectionsByReceiveFd.valueAt(0)->inputChannel);
}
}
void InputDispatcher::dispatchOnce() {
nsecs_t keyRepeatTimeout = mPolicy->getKeyRepeatTimeout();
nsecs_t keyRepeatDelay = mPolicy->getKeyRepeatDelay();
nsecs_t nextWakeupTime = LONG_LONG_MAX;
{ // acquire lock
AutoMutex _l(mLock);
dispatchOnceInnerLocked(keyRepeatTimeout, keyRepeatDelay, & nextWakeupTime);
if (runCommandsLockedInterruptible()) {
nextWakeupTime = LONG_LONG_MIN; // force next poll to wake up immediately
}
} // release lock
// Wait for callback or timeout or wake. (make sure we round up, not down)
nsecs_t currentTime = now();
int32_t timeoutMillis;
if (nextWakeupTime > currentTime) {
uint64_t timeout = uint64_t(nextWakeupTime - currentTime);
timeout = (timeout + 999999LL) / 1000000LL;
timeoutMillis = timeout > INT_MAX ? -1 : int32_t(timeout);
} else {
timeoutMillis = 0;
}
mLooper->pollOnce(timeoutMillis);
}
void InputDispatcher::dispatchOnceInnerLocked(nsecs_t keyRepeatTimeout,
nsecs_t keyRepeatDelay, nsecs_t* nextWakeupTime) {
nsecs_t currentTime = now();
// Reset the key repeat timer whenever we disallow key events, even if the next event
// is not a key. This is to ensure that we abort a key repeat if the device is just coming
// out of sleep.
if (keyRepeatTimeout < 0) {
resetKeyRepeatLocked();
}
// If dispatching is frozen, do not process timeouts or try to deliver any new events.
if (mDispatchFrozen) {
#if DEBUG_FOCUS
LOGD("Dispatch frozen. Waiting some more.");
#endif
return;
}
// Optimize latency of app switches.
// Essentially we start a short timeout when an app switch key (HOME / ENDCALL) has
// been pressed. When it expires, we preempt dispatch and drop all other pending events.
bool isAppSwitchDue = mAppSwitchDueTime <= currentTime;
if (mAppSwitchDueTime < *nextWakeupTime) {
*nextWakeupTime = mAppSwitchDueTime;
}
// Ready to start a new event.
// If we don't already have a pending event, go grab one.
if (! mPendingEvent) {
if (mInboundQueue.isEmpty()) {
if (isAppSwitchDue) {
// The inbound queue is empty so the app switch key we were waiting
// for will never arrive. Stop waiting for it.
resetPendingAppSwitchLocked(false);
isAppSwitchDue = false;
}
// Synthesize a key repeat if appropriate.
if (mKeyRepeatState.lastKeyEntry) {
if (currentTime >= mKeyRepeatState.nextRepeatTime) {
mPendingEvent = synthesizeKeyRepeatLocked(currentTime, keyRepeatDelay);
} else {
if (mKeyRepeatState.nextRepeatTime < *nextWakeupTime) {
*nextWakeupTime = mKeyRepeatState.nextRepeatTime;
}
}
}
if (! mPendingEvent) {
return;
}
} else {
// Inbound queue has at least one entry.
EventEntry* entry = mInboundQueue.headSentinel.next;
// Throttle the entry if it is a move event and there are no
// other events behind it in the queue. Due to movement batching, additional
// samples may be appended to this event by the time the throttling timeout
// expires.
// TODO Make this smarter and consider throttling per device independently.
if (entry->type == EventEntry::TYPE_MOTION
&& !isAppSwitchDue
&& mDispatchEnabled
&& (entry->policyFlags & POLICY_FLAG_PASS_TO_USER)
&& !entry->isInjected()) {
MotionEntry* motionEntry = static_cast<MotionEntry*>(entry);
int32_t deviceId = motionEntry->deviceId;
uint32_t source = motionEntry->source;
if (! isAppSwitchDue
&& motionEntry->next == & mInboundQueue.tailSentinel // exactly one event
&& motionEntry->action == AMOTION_EVENT_ACTION_MOVE
&& deviceId == mThrottleState.lastDeviceId
&& source == mThrottleState.lastSource) {
nsecs_t nextTime = mThrottleState.lastEventTime
+ mThrottleState.minTimeBetweenEvents;
if (currentTime < nextTime) {
// Throttle it!
#if DEBUG_THROTTLING
LOGD("Throttling - Delaying motion event for "
"device 0x%x, source 0x%08x by up to %0.3fms.",
deviceId, source, (nextTime - currentTime) * 0.000001);
#endif
if (nextTime < *nextWakeupTime) {
*nextWakeupTime = nextTime;
}
if (mThrottleState.originalSampleCount == 0) {
mThrottleState.originalSampleCount =
motionEntry->countSamples();
}
return;
}
}
#if DEBUG_THROTTLING
if (mThrottleState.originalSampleCount != 0) {
uint32_t count = motionEntry->countSamples();
LOGD("Throttling - Motion event sample count grew by %d from %d to %d.",
count - mThrottleState.originalSampleCount,
mThrottleState.originalSampleCount, count);
mThrottleState.originalSampleCount = 0;
}
#endif
mThrottleState.lastEventTime = entry->eventTime < currentTime
? entry->eventTime : currentTime;
mThrottleState.lastDeviceId = deviceId;
mThrottleState.lastSource = source;
}
mInboundQueue.dequeue(entry);
mPendingEvent = entry;
}
// Poke user activity for this event.
if (mPendingEvent->policyFlags & POLICY_FLAG_PASS_TO_USER) {
pokeUserActivityLocked(mPendingEvent);
}
}
// Now we have an event to dispatch.
assert(mPendingEvent != NULL);
bool done = false;
DropReason dropReason = DROP_REASON_NOT_DROPPED;
if (!(mPendingEvent->policyFlags & POLICY_FLAG_PASS_TO_USER)) {
dropReason = DROP_REASON_POLICY;
} else if (!mDispatchEnabled) {
dropReason = DROP_REASON_DISABLED;
}
switch (mPendingEvent->type) {
case EventEntry::TYPE_CONFIGURATION_CHANGED: {
ConfigurationChangedEntry* typedEntry =
static_cast<ConfigurationChangedEntry*>(mPendingEvent);
done = dispatchConfigurationChangedLocked(currentTime, typedEntry);
dropReason = DROP_REASON_NOT_DROPPED; // configuration changes are never dropped
break;
}
case EventEntry::TYPE_KEY: {
KeyEntry* typedEntry = static_cast<KeyEntry*>(mPendingEvent);
if (isAppSwitchDue) {
if (isAppSwitchKeyEventLocked(typedEntry)) {
resetPendingAppSwitchLocked(true);
isAppSwitchDue = false;
} else if (dropReason == DROP_REASON_NOT_DROPPED) {
dropReason = DROP_REASON_APP_SWITCH;
}
}
done = dispatchKeyLocked(currentTime, typedEntry, keyRepeatTimeout,
&dropReason, nextWakeupTime);
break;
}
case EventEntry::TYPE_MOTION: {
MotionEntry* typedEntry = static_cast<MotionEntry*>(mPendingEvent);
if (dropReason == DROP_REASON_NOT_DROPPED && isAppSwitchDue) {
dropReason = DROP_REASON_APP_SWITCH;
}
done = dispatchMotionLocked(currentTime, typedEntry,
&dropReason, nextWakeupTime);
break;
}
default:
assert(false);
break;
}
if (done) {
if (dropReason != DROP_REASON_NOT_DROPPED) {
dropInboundEventLocked(mPendingEvent, dropReason);
}
releasePendingEventLocked();
*nextWakeupTime = LONG_LONG_MIN; // force next poll to wake up immediately
}
}
bool InputDispatcher::enqueueInboundEventLocked(EventEntry* entry) {
bool needWake = mInboundQueue.isEmpty();
mInboundQueue.enqueueAtTail(entry);
switch (entry->type) {
case EventEntry::TYPE_KEY: {
KeyEntry* keyEntry = static_cast<KeyEntry*>(entry);
if (isAppSwitchKeyEventLocked(keyEntry)) {
if (keyEntry->action == AKEY_EVENT_ACTION_DOWN) {
mAppSwitchSawKeyDown = true;
} else if (keyEntry->action == AKEY_EVENT_ACTION_UP) {
if (mAppSwitchSawKeyDown) {
#if DEBUG_APP_SWITCH
LOGD("App switch is pending!");
#endif
mAppSwitchDueTime = keyEntry->eventTime + APP_SWITCH_TIMEOUT;
mAppSwitchSawKeyDown = false;
needWake = true;
}
}
}
break;
}
}
return needWake;
}
void InputDispatcher::dropInboundEventLocked(EventEntry* entry, DropReason dropReason) {
const char* reason;
switch (dropReason) {
case DROP_REASON_POLICY:
#if DEBUG_INBOUND_EVENT_DETAILS
LOGD("Dropped event because policy consumed it.");
#endif
reason = "inbound event was dropped because the policy consumed it";
break;
case DROP_REASON_DISABLED:
LOGI("Dropped event because input dispatch is disabled.");
reason = "inbound event was dropped because input dispatch is disabled";
break;
case DROP_REASON_APP_SWITCH:
LOGI("Dropped event because of pending overdue app switch.");
reason = "inbound event was dropped because of pending overdue app switch";
break;
default:
assert(false);
return;
}
switch (entry->type) {
case EventEntry::TYPE_KEY:
synthesizeCancelationEventsForAllConnectionsLocked(
InputState::CANCEL_NON_POINTER_EVENTS, reason);
break;
case EventEntry::TYPE_MOTION: {
MotionEntry* motionEntry = static_cast<MotionEntry*>(entry);
if (motionEntry->source & AINPUT_SOURCE_CLASS_POINTER) {
synthesizeCancelationEventsForAllConnectionsLocked(
InputState::CANCEL_POINTER_EVENTS, reason);
} else {
synthesizeCancelationEventsForAllConnectionsLocked(
InputState::CANCEL_NON_POINTER_EVENTS, reason);
}
break;
}
}
}
bool InputDispatcher::isAppSwitchKeyCode(int32_t keyCode) {
return keyCode == AKEYCODE_HOME || keyCode == AKEYCODE_ENDCALL;
}
bool InputDispatcher::isAppSwitchKeyEventLocked(KeyEntry* keyEntry) {
return ! (keyEntry->flags & AKEY_EVENT_FLAG_CANCELED)
&& isAppSwitchKeyCode(keyEntry->keyCode)
&& (keyEntry->policyFlags & POLICY_FLAG_TRUSTED)
&& (keyEntry->policyFlags & POLICY_FLAG_PASS_TO_USER);
}
bool InputDispatcher::isAppSwitchPendingLocked() {
return mAppSwitchDueTime != LONG_LONG_MAX;
}
void InputDispatcher::resetPendingAppSwitchLocked(bool handled) {
mAppSwitchDueTime = LONG_LONG_MAX;
#if DEBUG_APP_SWITCH
if (handled) {
LOGD("App switch has arrived.");
} else {
LOGD("App switch was abandoned.");
}
#endif
}
bool InputDispatcher::runCommandsLockedInterruptible() {
if (mCommandQueue.isEmpty()) {
return false;
}
do {
CommandEntry* commandEntry = mCommandQueue.dequeueAtHead();
Command command = commandEntry->command;
(this->*command)(commandEntry); // commands are implicitly 'LockedInterruptible'
commandEntry->connection.clear();
mAllocator.releaseCommandEntry(commandEntry);
} while (! mCommandQueue.isEmpty());
return true;
}
InputDispatcher::CommandEntry* InputDispatcher::postCommandLocked(Command command) {
CommandEntry* commandEntry = mAllocator.obtainCommandEntry(command);
mCommandQueue.enqueueAtTail(commandEntry);
return commandEntry;
}
void InputDispatcher::drainInboundQueueLocked() {
while (! mInboundQueue.isEmpty()) {
EventEntry* entry = mInboundQueue.dequeueAtHead();
releaseInboundEventLocked(entry);
}
}
void InputDispatcher::releasePendingEventLocked() {
if (mPendingEvent) {
releaseInboundEventLocked(mPendingEvent);
mPendingEvent = NULL;
}
}
void InputDispatcher::releaseInboundEventLocked(EventEntry* entry) {
InjectionState* injectionState = entry->injectionState;
if (injectionState && injectionState->injectionResult == INPUT_EVENT_INJECTION_PENDING) {
#if DEBUG_DISPATCH_CYCLE
LOGD("Injected inbound event was dropped.");
#endif
setInjectionResultLocked(entry, INPUT_EVENT_INJECTION_FAILED);
}
mAllocator.releaseEventEntry(entry);
}
void InputDispatcher::resetKeyRepeatLocked() {
if (mKeyRepeatState.lastKeyEntry) {
mAllocator.releaseKeyEntry(mKeyRepeatState.lastKeyEntry);
mKeyRepeatState.lastKeyEntry = NULL;
}
}
InputDispatcher::KeyEntry* InputDispatcher::synthesizeKeyRepeatLocked(
nsecs_t currentTime, nsecs_t keyRepeatDelay) {
KeyEntry* entry = mKeyRepeatState.lastKeyEntry;
// Reuse the repeated key entry if it is otherwise unreferenced.
uint32_t policyFlags = (entry->policyFlags & POLICY_FLAG_RAW_MASK)
| POLICY_FLAG_PASS_TO_USER | POLICY_FLAG_TRUSTED;
if (entry->refCount == 1) {
mAllocator.recycleKeyEntry(entry);
entry->eventTime = currentTime;
entry->policyFlags = policyFlags;
entry->repeatCount += 1;
} else {
KeyEntry* newEntry = mAllocator.obtainKeyEntry(currentTime,
entry->deviceId, entry->source, policyFlags,
entry->action, entry->flags, entry->keyCode, entry->scanCode,
entry->metaState, entry->repeatCount + 1, entry->downTime);
mKeyRepeatState.lastKeyEntry = newEntry;
mAllocator.releaseKeyEntry(entry);
entry = newEntry;
}
entry->syntheticRepeat = true;
// Increment reference count since we keep a reference to the event in
// mKeyRepeatState.lastKeyEntry in addition to the one we return.
entry->refCount += 1;
if (entry->repeatCount == 1) {
entry->flags |= AKEY_EVENT_FLAG_LONG_PRESS;
}
mKeyRepeatState.nextRepeatTime = currentTime + keyRepeatDelay;
return entry;
}
bool InputDispatcher::dispatchConfigurationChangedLocked(
nsecs_t currentTime, ConfigurationChangedEntry* entry) {
#if DEBUG_OUTBOUND_EVENT_DETAILS
LOGD("dispatchConfigurationChanged - eventTime=%lld", entry->eventTime);
#endif
// Reset key repeating in case a keyboard device was added or removed or something.
resetKeyRepeatLocked();
// Enqueue a command to run outside the lock to tell the policy that the configuration changed.
CommandEntry* commandEntry = postCommandLocked(
& InputDispatcher::doNotifyConfigurationChangedInterruptible);
commandEntry->eventTime = entry->eventTime;
return true;
}
bool InputDispatcher::dispatchKeyLocked(
nsecs_t currentTime, KeyEntry* entry, nsecs_t keyRepeatTimeout,
DropReason* dropReason, nsecs_t* nextWakeupTime) {
// Give the policy a chance to intercept the key.
if (entry->interceptKeyResult == KeyEntry::INTERCEPT_KEY_RESULT_UNKNOWN) {
if (entry->policyFlags & POLICY_FLAG_PASS_TO_USER) {
CommandEntry* commandEntry = postCommandLocked(
& InputDispatcher::doInterceptKeyBeforeDispatchingLockedInterruptible);
if (mFocusedWindow) {
commandEntry->inputChannel = mFocusedWindow->inputChannel;
}
commandEntry->keyEntry = entry;
entry->refCount += 1;
return false; // wait for the command to run
} else {
entry->interceptKeyResult = KeyEntry::INTERCEPT_KEY_RESULT_CONTINUE;
}
} else if (entry->interceptKeyResult == KeyEntry::INTERCEPT_KEY_RESULT_SKIP) {
if (*dropReason == DROP_REASON_NOT_DROPPED) {
*dropReason = DROP_REASON_POLICY;
}
}
// Clean up if dropping the event.
if (*dropReason != DROP_REASON_NOT_DROPPED) {
resetTargetsLocked();
setInjectionResultLocked(entry, *dropReason == DROP_REASON_POLICY
? INPUT_EVENT_INJECTION_SUCCEEDED : INPUT_EVENT_INJECTION_FAILED);
return true;
}
// Preprocessing.
if (! entry->dispatchInProgress) {
logOutboundKeyDetailsLocked("dispatchKey - ", entry);
if (entry->repeatCount == 0
&& entry->action == AKEY_EVENT_ACTION_DOWN
&& (entry->policyFlags & POLICY_FLAG_TRUSTED)
&& !entry->isInjected()) {
if (mKeyRepeatState.lastKeyEntry
&& mKeyRepeatState.lastKeyEntry->keyCode == entry->keyCode) {
// We have seen two identical key downs in a row which indicates that the device
// driver is automatically generating key repeats itself. We take note of the
// repeat here, but we disable our own next key repeat timer since it is clear that
// we will not need to synthesize key repeats ourselves.
entry->repeatCount = mKeyRepeatState.lastKeyEntry->repeatCount + 1;
resetKeyRepeatLocked();
mKeyRepeatState.nextRepeatTime = LONG_LONG_MAX; // don't generate repeats ourselves
} else {
// Not a repeat. Save key down state in case we do see a repeat later.
resetKeyRepeatLocked();
mKeyRepeatState.nextRepeatTime = entry->eventTime + keyRepeatTimeout;
}
mKeyRepeatState.lastKeyEntry = entry;
entry->refCount += 1;
} else if (! entry->syntheticRepeat) {
resetKeyRepeatLocked();
}
entry->dispatchInProgress = true;
resetTargetsLocked();
}
// Identify targets.
if (! mCurrentInputTargetsValid) {
int32_t injectionResult = findFocusedWindowTargetsLocked(currentTime,
entry, nextWakeupTime);
if (injectionResult == INPUT_EVENT_INJECTION_PENDING) {
return false;
}
setInjectionResultLocked(entry, injectionResult);
if (injectionResult != INPUT_EVENT_INJECTION_SUCCEEDED) {
return true;
}
addMonitoringTargetsLocked();
commitTargetsLocked();
}
// Dispatch the key.
dispatchEventToCurrentInputTargetsLocked(currentTime, entry, false);
return true;
}
void InputDispatcher::logOutboundKeyDetailsLocked(const char* prefix, const KeyEntry* entry) {
#if DEBUG_OUTBOUND_EVENT_DETAILS
LOGD("%seventTime=%lld, deviceId=0x%x, source=0x%x, policyFlags=0x%x, "
"action=0x%x, flags=0x%x, keyCode=0x%x, scanCode=0x%x, metaState=0x%x, "
"downTime=%lld",
prefix,
entry->eventTime, entry->deviceId, entry->source, entry->policyFlags,
entry->action, entry->flags, entry->keyCode, entry->scanCode, entry->metaState,
entry->downTime);
#endif
}
bool InputDispatcher::dispatchMotionLocked(
nsecs_t currentTime, MotionEntry* entry, DropReason* dropReason, nsecs_t* nextWakeupTime) {
// Clean up if dropping the event.
if (*dropReason != DROP_REASON_NOT_DROPPED) {
resetTargetsLocked();
setInjectionResultLocked(entry, *dropReason == DROP_REASON_POLICY
? INPUT_EVENT_INJECTION_SUCCEEDED : INPUT_EVENT_INJECTION_FAILED);
return true;
}
// Preprocessing.
if (! entry->dispatchInProgress) {
logOutboundMotionDetailsLocked("dispatchMotion - ", entry);
entry->dispatchInProgress = true;
resetTargetsLocked();
}
bool isPointerEvent = entry->source & AINPUT_SOURCE_CLASS_POINTER;
// Identify targets.
if (! mCurrentInputTargetsValid) {
int32_t injectionResult;
if (isPointerEvent) {
// Pointer event. (eg. touchscreen)
injectionResult = findTouchedWindowTargetsLocked(currentTime,
entry, nextWakeupTime);
} else {
// Non touch event. (eg. trackball)
injectionResult = findFocusedWindowTargetsLocked(currentTime,
entry, nextWakeupTime);
}
if (injectionResult == INPUT_EVENT_INJECTION_PENDING) {
return false;
}
setInjectionResultLocked(entry, injectionResult);
if (injectionResult != INPUT_EVENT_INJECTION_SUCCEEDED) {
return true;
}
addMonitoringTargetsLocked();
commitTargetsLocked();
}
// Dispatch the motion.
dispatchEventToCurrentInputTargetsLocked(currentTime, entry, false);
return true;
}
void InputDispatcher::logOutboundMotionDetailsLocked(const char* prefix, const MotionEntry* entry) {
#if DEBUG_OUTBOUND_EVENT_DETAILS
LOGD("%seventTime=%lld, deviceId=0x%x, source=0x%x, policyFlags=0x%x, "
"action=0x%x, flags=0x%x, "
"metaState=0x%x, edgeFlags=0x%x, xPrecision=%f, yPrecision=%f, downTime=%lld",
prefix,
entry->eventTime, entry->deviceId, entry->source, entry->policyFlags,
entry->action, entry->flags,
entry->metaState, entry->edgeFlags, entry->xPrecision, entry->yPrecision,
entry->downTime);
// Print the most recent sample that we have available, this may change due to batching.
size_t sampleCount = 1;
const MotionSample* sample = & entry->firstSample;
for (; sample->next != NULL; sample = sample->next) {
sampleCount += 1;
}
for (uint32_t i = 0; i < entry->pointerCount; i++) {
LOGD(" Pointer %d: id=%d, x=%f, y=%f, pressure=%f, size=%f, "
"touchMajor=%f, touchMinor=%f, toolMajor=%f, toolMinor=%f, "
"orientation=%f",
i, entry->pointerIds[i],
sample->pointerCoords[i].x, sample->pointerCoords[i].y,
sample->pointerCoords[i].pressure, sample->pointerCoords[i].size,
sample->pointerCoords[i].touchMajor, sample->pointerCoords[i].touchMinor,
sample->pointerCoords[i].toolMajor, sample->pointerCoords[i].toolMinor,
sample->pointerCoords[i].orientation);
}
// Keep in mind that due to batching, it is possible for the number of samples actually
// dispatched to change before the application finally consumed them.
if (entry->action == AMOTION_EVENT_ACTION_MOVE) {
LOGD(" ... Total movement samples currently batched %d ...", sampleCount);
}
#endif
}
void InputDispatcher::dispatchEventToCurrentInputTargetsLocked(nsecs_t currentTime,
EventEntry* eventEntry, bool resumeWithAppendedMotionSample) {
#if DEBUG_DISPATCH_CYCLE
LOGD("dispatchEventToCurrentInputTargets - "
"resumeWithAppendedMotionSample=%s",
toString(resumeWithAppendedMotionSample));
#endif
assert(eventEntry->dispatchInProgress); // should already have been set to true
pokeUserActivityLocked(eventEntry);
for (size_t i = 0; i < mCurrentInputTargets.size(); i++) {
const InputTarget& inputTarget = mCurrentInputTargets.itemAt(i);
ssize_t connectionIndex = getConnectionIndexLocked(inputTarget.inputChannel);
if (connectionIndex >= 0) {
sp<Connection> connection = mConnectionsByReceiveFd.valueAt(connectionIndex);
prepareDispatchCycleLocked(currentTime, connection, eventEntry, & inputTarget,
resumeWithAppendedMotionSample);
} else {
#if DEBUG_FOCUS
LOGD("Dropping event delivery to target with channel '%s' because it "
"is no longer registered with the input dispatcher.",
inputTarget.inputChannel->getName().string());
#endif
}
}
}
void InputDispatcher::resetTargetsLocked() {
mCurrentInputTargetsValid = false;
mCurrentInputTargets.clear();
mInputTargetWaitCause = INPUT_TARGET_WAIT_CAUSE_NONE;
}
void InputDispatcher::commitTargetsLocked() {
mCurrentInputTargetsValid = true;
}
int32_t InputDispatcher::handleTargetsNotReadyLocked(nsecs_t currentTime,
const EventEntry* entry, const InputApplication* application, const InputWindow* window,
nsecs_t* nextWakeupTime) {
if (application == NULL && window == NULL) {
if (mInputTargetWaitCause != INPUT_TARGET_WAIT_CAUSE_SYSTEM_NOT_READY) {
#if DEBUG_FOCUS
LOGD("Waiting for system to become ready for input.");
#endif
mInputTargetWaitCause = INPUT_TARGET_WAIT_CAUSE_SYSTEM_NOT_READY;
mInputTargetWaitStartTime = currentTime;
mInputTargetWaitTimeoutTime = LONG_LONG_MAX;
mInputTargetWaitTimeoutExpired = false;
}
} else {
if (mInputTargetWaitCause != INPUT_TARGET_WAIT_CAUSE_APPLICATION_NOT_READY) {
#if DEBUG_FOCUS
LOGD("Waiting for application to become ready for input: %s",
getApplicationWindowLabelLocked(application, window).string());
#endif
nsecs_t timeout = window ? window->dispatchingTimeout :
application ? application->dispatchingTimeout : DEFAULT_INPUT_DISPATCHING_TIMEOUT;
mInputTargetWaitCause = INPUT_TARGET_WAIT_CAUSE_APPLICATION_NOT_READY;
mInputTargetWaitStartTime = currentTime;
mInputTargetWaitTimeoutTime = currentTime + timeout;
mInputTargetWaitTimeoutExpired = false;
}
}
if (mInputTargetWaitTimeoutExpired) {
return INPUT_EVENT_INJECTION_TIMED_OUT;
}
if (currentTime >= mInputTargetWaitTimeoutTime) {
onANRLocked(currentTime, application, window, entry->eventTime, mInputTargetWaitStartTime);
// Force poll loop to wake up immediately on next iteration once we get the
// ANR response back from the policy.
*nextWakeupTime = LONG_LONG_MIN;
return INPUT_EVENT_INJECTION_PENDING;
} else {
// Force poll loop to wake up when timeout is due.
if (mInputTargetWaitTimeoutTime < *nextWakeupTime) {
*nextWakeupTime = mInputTargetWaitTimeoutTime;
}
return INPUT_EVENT_INJECTION_PENDING;
}
}
void InputDispatcher::resumeAfterTargetsNotReadyTimeoutLocked(nsecs_t newTimeout,
const sp<InputChannel>& inputChannel) {
if (newTimeout > 0) {
// Extend the timeout.
mInputTargetWaitTimeoutTime = now() + newTimeout;
} else {
// Give up.
mInputTargetWaitTimeoutExpired = true;
// Release the touch targets.
mTouchState.reset();
// Input state will not be realistic. Mark it out of sync.
if (inputChannel.get()) {
ssize_t connectionIndex = getConnectionIndexLocked(inputChannel);
if (connectionIndex >= 0) {
sp<Connection> connection = mConnectionsByReceiveFd.valueAt(connectionIndex);
synthesizeCancelationEventsForConnectionLocked(
connection, InputState::CANCEL_ALL_EVENTS,
"application not responding");
}
}
}
}
nsecs_t InputDispatcher::getTimeSpentWaitingForApplicationLocked(
nsecs_t currentTime) {
if (mInputTargetWaitCause == INPUT_TARGET_WAIT_CAUSE_APPLICATION_NOT_READY) {
return currentTime - mInputTargetWaitStartTime;
}
return 0;
}
void InputDispatcher::resetANRTimeoutsLocked() {
#if DEBUG_FOCUS
LOGD("Resetting ANR timeouts.");
#endif
// Reset input target wait timeout.
mInputTargetWaitCause = INPUT_TARGET_WAIT_CAUSE_NONE;
}
int32_t InputDispatcher::findFocusedWindowTargetsLocked(nsecs_t currentTime,
const EventEntry* entry, nsecs_t* nextWakeupTime) {
mCurrentInputTargets.clear();
int32_t injectionResult;
// If there is no currently focused window and no focused application
// then drop the event.
if (! mFocusedWindow) {
if (mFocusedApplication) {
#if DEBUG_FOCUS
LOGD("Waiting because there is no focused window but there is a "
"focused application that may eventually add a window: %s.",
getApplicationWindowLabelLocked(mFocusedApplication, NULL).string());
#endif
injectionResult = handleTargetsNotReadyLocked(currentTime, entry,
mFocusedApplication, NULL, nextWakeupTime);
goto Unresponsive;
}
LOGI("Dropping event because there is no focused window or focused application.");
injectionResult = INPUT_EVENT_INJECTION_FAILED;
goto Failed;
}
// Check permissions.
if (! checkInjectionPermission(mFocusedWindow, entry->injectionState)) {
injectionResult = INPUT_EVENT_INJECTION_PERMISSION_DENIED;
goto Failed;
}
// If the currently focused window is paused then keep waiting.
if (mFocusedWindow->paused) {
#if DEBUG_FOCUS
LOGD("Waiting because focused window is paused.");
#endif
injectionResult = handleTargetsNotReadyLocked(currentTime, entry,
mFocusedApplication, mFocusedWindow, nextWakeupTime);
goto Unresponsive;
}
// If the currently focused window is still working on previous events then keep waiting.
if (! isWindowFinishedWithPreviousInputLocked(mFocusedWindow)) {
#if DEBUG_FOCUS
LOGD("Waiting because focused window still processing previous input.");
#endif
injectionResult = handleTargetsNotReadyLocked(currentTime, entry,
mFocusedApplication, mFocusedWindow, nextWakeupTime);
goto Unresponsive;
}
// Success! Output targets.
injectionResult = INPUT_EVENT_INJECTION_SUCCEEDED;
addWindowTargetLocked(mFocusedWindow, InputTarget::FLAG_FOREGROUND, BitSet32(0));
// Done.
Failed:
Unresponsive:
nsecs_t timeSpentWaitingForApplication = getTimeSpentWaitingForApplicationLocked(currentTime);
updateDispatchStatisticsLocked(currentTime, entry,
injectionResult, timeSpentWaitingForApplication);
#if DEBUG_FOCUS
LOGD("findFocusedWindow finished: injectionResult=%d, "
"timeSpendWaitingForApplication=%0.1fms",
injectionResult, timeSpentWaitingForApplication / 1000000.0);
#endif
return injectionResult;
}
int32_t InputDispatcher::findTouchedWindowTargetsLocked(nsecs_t currentTime,
const MotionEntry* entry, nsecs_t* nextWakeupTime) {
enum InjectionPermission {
INJECTION_PERMISSION_UNKNOWN,
INJECTION_PERMISSION_GRANTED,
INJECTION_PERMISSION_DENIED
};
mCurrentInputTargets.clear();
nsecs_t startTime = now();
// For security reasons, we defer updating the touch state until we are sure that
// event injection will be allowed.
//
// FIXME In the original code, screenWasOff could never be set to true.
// The reason is that the POLICY_FLAG_WOKE_HERE
// and POLICY_FLAG_BRIGHT_HERE flags were set only when preprocessing raw
// EV_KEY, EV_REL and EV_ABS events. As it happens, the touch event was
// actually enqueued using the policyFlags that appeared in the final EV_SYN
// events upon which no preprocessing took place. So policyFlags was always 0.
// In the new native input dispatcher we're a bit more careful about event
// preprocessing so the touches we receive can actually have non-zero policyFlags.
// Unfortunately we obtain undesirable behavior.
//
// Here's what happens:
//
// When the device dims in anticipation of going to sleep, touches
// in windows which have FLAG_TOUCHABLE_WHEN_WAKING cause
// the device to brighten and reset the user activity timer.
// Touches on other windows (such as the launcher window)
// are dropped. Then after a moment, the device goes to sleep. Oops.
//
// Also notice how screenWasOff was being initialized using POLICY_FLAG_BRIGHT_HERE
// instead of POLICY_FLAG_WOKE_HERE...
//
bool screenWasOff = false; // original policy: policyFlags & POLICY_FLAG_BRIGHT_HERE;
int32_t action = entry->action;
int32_t maskedAction = action & AMOTION_EVENT_ACTION_MASK;
// Update the touch state as needed based on the properties of the touch event.
int32_t injectionResult = INPUT_EVENT_INJECTION_PENDING;
InjectionPermission injectionPermission = INJECTION_PERMISSION_UNKNOWN;
if (maskedAction == AMOTION_EVENT_ACTION_DOWN) {
mTempTouchState.reset();
mTempTouchState.down = true;
} else {
mTempTouchState.copyFrom(mTouchState);
}
bool isSplit = mTempTouchState.split && mTempTouchState.down;
if (maskedAction == AMOTION_EVENT_ACTION_DOWN
|| (isSplit && maskedAction == AMOTION_EVENT_ACTION_POINTER_DOWN)) {
/* Case 1: New splittable pointer going down. */
int32_t pointerIndex = getMotionEventActionPointerIndex(action);
int32_t x = int32_t(entry->firstSample.pointerCoords[pointerIndex].x);
int32_t y = int32_t(entry->firstSample.pointerCoords[pointerIndex].y);
const InputWindow* newTouchedWindow = NULL;
const InputWindow* topErrorWindow = NULL;
// Traverse windows from front to back to find touched window and outside targets.
size_t numWindows = mWindows.size();
for (size_t i = 0; i < numWindows; i++) {
const InputWindow* window = & mWindows.editItemAt(i);
int32_t flags = window->layoutParamsFlags;
if (flags & InputWindow::FLAG_SYSTEM_ERROR) {
if (! topErrorWindow) {
topErrorWindow = window;
}
}
if (window->visible) {
if (! (flags & InputWindow::FLAG_NOT_TOUCHABLE)) {
bool isTouchModal = (flags & (InputWindow::FLAG_NOT_FOCUSABLE
| InputWindow::FLAG_NOT_TOUCH_MODAL)) == 0;
if (isTouchModal || window->touchableAreaContainsPoint(x, y)) {
if (! screenWasOff || flags & InputWindow::FLAG_TOUCHABLE_WHEN_WAKING) {
newTouchedWindow = window;
}
break; // found touched window, exit window loop
}
}
if (maskedAction == AMOTION_EVENT_ACTION_DOWN
&& (flags & InputWindow::FLAG_WATCH_OUTSIDE_TOUCH)) {
int32_t outsideTargetFlags = InputTarget::FLAG_OUTSIDE;
if (isWindowObscuredAtPointLocked(window, x, y)) {
outsideTargetFlags |= InputTarget::FLAG_WINDOW_IS_OBSCURED;
}
mTempTouchState.addOrUpdateWindow(window, outsideTargetFlags, BitSet32(0));
}
}
}
// If there is an error window but it is not taking focus (typically because
// it is invisible) then wait for it. Any other focused window may in
// fact be in ANR state.
if (topErrorWindow && newTouchedWindow != topErrorWindow) {
#if DEBUG_FOCUS
LOGD("Waiting because system error window is pending.");
#endif
injectionResult = handleTargetsNotReadyLocked(currentTime, entry,
NULL, NULL, nextWakeupTime);
injectionPermission = INJECTION_PERMISSION_UNKNOWN;
goto Unresponsive;
}
// Figure out whether splitting will be allowed for this window.
if (newTouchedWindow
&& (newTouchedWindow->layoutParamsFlags & InputWindow::FLAG_SPLIT_TOUCH)) {
// New window supports splitting.
isSplit = true;
} else if (isSplit) {
// New window does not support splitting but we have already split events.
// Assign the pointer to the first foreground window we find.
// (May be NULL which is why we put this code block before the next check.)
newTouchedWindow = mTempTouchState.getFirstForegroundWindow();
}
// If we did not find a touched window then fail.
if (! newTouchedWindow) {
if (mFocusedApplication) {
#if DEBUG_FOCUS
LOGD("Waiting because there is no touched window but there is a "
"focused application that may eventually add a new window: %s.",
getApplicationWindowLabelLocked(mFocusedApplication, NULL).string());
#endif
injectionResult = handleTargetsNotReadyLocked(currentTime, entry,
mFocusedApplication, NULL, nextWakeupTime);
goto Unresponsive;
}
LOGI("Dropping event because there is no touched window or focused application.");
injectionResult = INPUT_EVENT_INJECTION_FAILED;
goto Failed;
}
// Set target flags.
int32_t targetFlags = InputTarget::FLAG_FOREGROUND;
if (isSplit) {
targetFlags |= InputTarget::FLAG_SPLIT;
}
if (isWindowObscuredAtPointLocked(newTouchedWindow, x, y)) {
targetFlags |= InputTarget::FLAG_WINDOW_IS_OBSCURED;
}
// Update the temporary touch state.
BitSet32 pointerIds;
if (isSplit) {
uint32_t pointerId = entry->pointerIds[pointerIndex];
pointerIds.markBit(pointerId);
}
mTempTouchState.addOrUpdateWindow(newTouchedWindow, targetFlags, pointerIds);
} else {
/* Case 2: Pointer move, up, cancel or non-splittable pointer down. */
// If the pointer is not currently down, then ignore the event.
if (! mTempTouchState.down) {
LOGI("Dropping event because the pointer is not down.");
injectionResult = INPUT_EVENT_INJECTION_FAILED;
goto Failed;
}
}
// Check permission to inject into all touched foreground windows and ensure there
// is at least one touched foreground window.
{
bool haveForegroundWindow = false;
for (size_t i = 0; i < mTempTouchState.windows.size(); i++) {
const TouchedWindow& touchedWindow = mTempTouchState.windows[i];
if (touchedWindow.targetFlags & InputTarget::FLAG_FOREGROUND) {
haveForegroundWindow = true;
if (! checkInjectionPermission(touchedWindow.window, entry->injectionState)) {
injectionResult = INPUT_EVENT_INJECTION_PERMISSION_DENIED;
injectionPermission = INJECTION_PERMISSION_DENIED;
goto Failed;
}
}
}
if (! haveForegroundWindow) {
#if DEBUG_INPUT_DISPATCHER_POLICY
LOGD("Dropping event because there is no touched foreground window to receive it.");
#endif
injectionResult = INPUT_EVENT_INJECTION_FAILED;
goto Failed;
}
// Permission granted to injection into all touched foreground windows.
injectionPermission = INJECTION_PERMISSION_GRANTED;
}
// Ensure all touched foreground windows are ready for new input.
for (size_t i = 0; i < mTempTouchState.windows.size(); i++) {
const TouchedWindow& touchedWindow = mTempTouchState.windows[i];
if (touchedWindow.targetFlags & InputTarget::FLAG_FOREGROUND) {
// If the touched window is paused then keep waiting.
if (touchedWindow.window->paused) {
#if DEBUG_INPUT_DISPATCHER_POLICY
LOGD("Waiting because touched window is paused.");
#endif
injectionResult = handleTargetsNotReadyLocked(currentTime, entry,
NULL, touchedWindow.window, nextWakeupTime);
goto Unresponsive;
}
// If the touched window is still working on previous events then keep waiting.
if (! isWindowFinishedWithPreviousInputLocked(touchedWindow.window)) {
#if DEBUG_FOCUS
LOGD("Waiting because touched window still processing previous input.");
#endif
injectionResult = handleTargetsNotReadyLocked(currentTime, entry,
NULL, touchedWindow.window, nextWakeupTime);
goto Unresponsive;
}
}
}
// If this is the first pointer going down and the touched window has a wallpaper
// then also add the touched wallpaper windows so they are locked in for the duration
// of the touch gesture.
if (maskedAction == AMOTION_EVENT_ACTION_DOWN) {
const InputWindow* foregroundWindow = mTempTouchState.getFirstForegroundWindow();
if (foregroundWindow->hasWallpaper) {
for (size_t i = 0; i < mWindows.size(); i++) {
const InputWindow* window = & mWindows[i];
if (window->layoutParamsType == InputWindow::TYPE_WALLPAPER) {
mTempTouchState.addOrUpdateWindow(window,
InputTarget::FLAG_WINDOW_IS_OBSCURED, BitSet32(0));
}
}
}
}
// Success! Output targets.
injectionResult = INPUT_EVENT_INJECTION_SUCCEEDED;
for (size_t i = 0; i < mTempTouchState.windows.size(); i++) {
const TouchedWindow& touchedWindow = mTempTouchState.windows.itemAt(i);
addWindowTargetLocked(touchedWindow.window, touchedWindow.targetFlags,
touchedWindow.pointerIds);
}
// Drop the outside touch window since we will not care about them in the next iteration.
mTempTouchState.removeOutsideTouchWindows();
Failed:
// Check injection permission once and for all.
if (injectionPermission == INJECTION_PERMISSION_UNKNOWN) {
if (checkInjectionPermission(NULL, entry->injectionState)) {
injectionPermission = INJECTION_PERMISSION_GRANTED;
} else {
injectionPermission = INJECTION_PERMISSION_DENIED;
}
}
// Update final pieces of touch state if the injector had permission.
if (injectionPermission == INJECTION_PERMISSION_GRANTED) {
if (maskedAction == AMOTION_EVENT_ACTION_UP
|| maskedAction == AMOTION_EVENT_ACTION_CANCEL) {
// All pointers up or canceled.
mTempTouchState.reset();
} else if (maskedAction == AMOTION_EVENT_ACTION_DOWN) {
// First pointer went down.
if (mTouchState.down) {
#if DEBUG_FOCUS
LOGD("Pointer down received while already down.");
#endif
}
} else if (maskedAction == AMOTION_EVENT_ACTION_POINTER_UP) {
// One pointer went up.
if (isSplit) {
int32_t pointerIndex = getMotionEventActionPointerIndex(action);
uint32_t pointerId = entry->pointerIds[pointerIndex];
for (size_t i = 0; i < mTempTouchState.windows.size(); ) {
TouchedWindow& touchedWindow = mTempTouchState.windows.editItemAt(i);
if (touchedWindow.targetFlags & InputTarget::FLAG_SPLIT) {
touchedWindow.pointerIds.clearBit(pointerId);
if (touchedWindow.pointerIds.isEmpty()) {
mTempTouchState.windows.removeAt(i);
continue;
}
}
i += 1;
}
}
}
// Save changes to touch state.
mTouchState.copyFrom(mTempTouchState);
} else {
#if DEBUG_FOCUS
LOGD("Not updating touch focus because injection was denied.");
#endif
}
Unresponsive:
nsecs_t timeSpentWaitingForApplication = getTimeSpentWaitingForApplicationLocked(currentTime);
updateDispatchStatisticsLocked(currentTime, entry,
injectionResult, timeSpentWaitingForApplication);
#if DEBUG_FOCUS
LOGD("findTouchedWindow finished: injectionResult=%d, injectionPermission=%d, "
"timeSpentWaitingForApplication=%0.1fms",
injectionResult, injectionPermission, timeSpentWaitingForApplication / 1000000.0);
#endif
return injectionResult;
}
void InputDispatcher::addWindowTargetLocked(const InputWindow* window, int32_t targetFlags,
BitSet32 pointerIds) {
mCurrentInputTargets.push();
InputTarget& target = mCurrentInputTargets.editTop();
target.inputChannel = window->inputChannel;
target.flags = targetFlags;
target.xOffset = - window->frameLeft;
target.yOffset = - window->frameTop;
target.pointerIds = pointerIds;
}
void InputDispatcher::addMonitoringTargetsLocked() {
for (size_t i = 0; i < mMonitoringChannels.size(); i++) {
mCurrentInputTargets.push();
InputTarget& target = mCurrentInputTargets.editTop();
target.inputChannel = mMonitoringChannels[i];
target.flags = 0;
target.xOffset = 0;
target.yOffset = 0;
}
}
bool InputDispatcher::checkInjectionPermission(const InputWindow* window,
const InjectionState* injectionState) {
if (injectionState
&& (window == NULL || window->ownerUid != injectionState->injectorUid)
&& !hasInjectionPermission(injectionState->injectorPid, injectionState->injectorUid)) {
if (window) {
LOGW("Permission denied: injecting event from pid %d uid %d to window "
"with input channel %s owned by uid %d",
injectionState->injectorPid, injectionState->injectorUid,
window->inputChannel->getName().string(),
window->ownerUid);
} else {
LOGW("Permission denied: injecting event from pid %d uid %d",
injectionState->injectorPid, injectionState->injectorUid);
}
return false;
}
return true;
}
bool InputDispatcher::isWindowObscuredAtPointLocked(
const InputWindow* window, int32_t x, int32_t y) const {
size_t numWindows = mWindows.size();
for (size_t i = 0; i < numWindows; i++) {
const InputWindow* other = & mWindows.itemAt(i);
if (other == window) {
break;
}
if (other->visible && ! other->isTrustedOverlay() && other->frameContainsPoint(x, y)) {
return true;
}
}
return false;
}
bool InputDispatcher::isWindowFinishedWithPreviousInputLocked(const InputWindow* window) {
ssize_t connectionIndex = getConnectionIndexLocked(window->inputChannel);
if (connectionIndex >= 0) {
sp<Connection> connection = mConnectionsByReceiveFd.valueAt(connectionIndex);
return connection->outboundQueue.isEmpty();
} else {
return true;
}
}
String8 InputDispatcher::getApplicationWindowLabelLocked(const InputApplication* application,
const InputWindow* window) {
if (application) {
if (window) {
String8 label(application->name);
label.append(" - ");
label.append(window->name);
return label;
} else {
return application->name;
}
} else if (window) {
return window->name;
} else {
return String8("<unknown application or window>");
}
}
void InputDispatcher::pokeUserActivityLocked(const EventEntry* eventEntry) {
int32_t eventType = POWER_MANAGER_BUTTON_EVENT;
if (eventEntry->type == EventEntry::TYPE_MOTION) {
const MotionEntry* motionEntry = static_cast<const MotionEntry*>(eventEntry);
if (motionEntry->source & AINPUT_SOURCE_CLASS_POINTER) {
switch (motionEntry->action) {
case AMOTION_EVENT_ACTION_DOWN:
eventType = POWER_MANAGER_TOUCH_EVENT;
break;
case AMOTION_EVENT_ACTION_UP:
eventType = POWER_MANAGER_TOUCH_UP_EVENT;
break;
default:
if (motionEntry->eventTime - motionEntry->downTime >= EVENT_IGNORE_DURATION) {
eventType = POWER_MANAGER_TOUCH_EVENT;
} else {
eventType = POWER_MANAGER_LONG_TOUCH_EVENT;
}
break;
}
}
}
CommandEntry* commandEntry = postCommandLocked(
& InputDispatcher::doPokeUserActivityLockedInterruptible);
commandEntry->eventTime = eventEntry->eventTime;
commandEntry->userActivityEventType = eventType;
}
void InputDispatcher::prepareDispatchCycleLocked(nsecs_t currentTime,
const sp<Connection>& connection, EventEntry* eventEntry, const InputTarget* inputTarget,
bool resumeWithAppendedMotionSample) {
#if DEBUG_DISPATCH_CYCLE
LOGD("channel '%s' ~ prepareDispatchCycle - flags=%d, "
"xOffset=%f, yOffset=%f, "
"windowType=%d, pointerIds=0x%x, "
"resumeWithAppendedMotionSample=%s",
connection->getInputChannelName(), inputTarget->flags,
inputTarget->xOffset, inputTarget->yOffset,
inputTarget->windowType, inputTarget->pointerIds.value,
toString(resumeWithAppendedMotionSample));
#endif
// Make sure we are never called for streaming when splitting across multiple windows.
bool isSplit = inputTarget->flags & InputTarget::FLAG_SPLIT;
assert(! (resumeWithAppendedMotionSample && isSplit));
// Skip this event if the connection status is not normal.
// We don't want to enqueue additional outbound events if the connection is broken.
if (connection->status != Connection::STATUS_NORMAL) {
#if DEBUG_DISPATCH_CYCLE
LOGD("channel '%s' ~ Dropping event because the channel status is %s",
connection->getInputChannelName(), connection->getStatusLabel());
#endif
return;
}
// Split a motion event if needed.
if (isSplit) {
assert(eventEntry->type == EventEntry::TYPE_MOTION);
MotionEntry* originalMotionEntry = static_cast<MotionEntry*>(eventEntry);
if (inputTarget->pointerIds.count() != originalMotionEntry->pointerCount) {
MotionEntry* splitMotionEntry = splitMotionEvent(
originalMotionEntry, inputTarget->pointerIds);
#if DEBUG_FOCUS
LOGD("channel '%s' ~ Split motion event.",
connection->getInputChannelName());
logOutboundMotionDetailsLocked(" ", splitMotionEntry);
#endif
eventEntry = splitMotionEntry;
}
}
// Resume the dispatch cycle with a freshly appended motion sample.
// First we check that the last dispatch entry in the outbound queue is for the same
// motion event to which we appended the motion sample. If we find such a dispatch
// entry, and if it is currently in progress then we try to stream the new sample.
bool wasEmpty = connection->outboundQueue.isEmpty();
if (! wasEmpty && resumeWithAppendedMotionSample) {
DispatchEntry* motionEventDispatchEntry =
connection->findQueuedDispatchEntryForEvent(eventEntry);
if (motionEventDispatchEntry) {
// If the dispatch entry is not in progress, then we must be busy dispatching an
// earlier event. Not a problem, the motion event is on the outbound queue and will
// be dispatched later.
if (! motionEventDispatchEntry->inProgress) {
#if DEBUG_BATCHING
LOGD("channel '%s' ~ Not streaming because the motion event has "
"not yet been dispatched. "
"(Waiting for earlier events to be consumed.)",
connection->getInputChannelName());
#endif
return;
}
// If the dispatch entry is in progress but it already has a tail of pending
// motion samples, then it must mean that the shared memory buffer filled up.
// Not a problem, when this dispatch cycle is finished, we will eventually start
// a new dispatch cycle to process the tail and that tail includes the newly
// appended motion sample.
if (motionEventDispatchEntry->tailMotionSample) {
#if DEBUG_BATCHING
LOGD("channel '%s' ~ Not streaming because no new samples can "
"be appended to the motion event in this dispatch cycle. "
"(Waiting for next dispatch cycle to start.)",
connection->getInputChannelName());
#endif
return;
}
// The dispatch entry is in progress and is still potentially open for streaming.
// Try to stream the new motion sample. This might fail if the consumer has already
// consumed the motion event (or if the channel is broken).
MotionEntry* motionEntry = static_cast<MotionEntry*>(eventEntry);
MotionSample* appendedMotionSample = motionEntry->lastSample;
status_t status = connection->inputPublisher.appendMotionSample(
appendedMotionSample->eventTime, appendedMotionSample->pointerCoords);
if (status == OK) {
#if DEBUG_BATCHING
LOGD("channel '%s' ~ Successfully streamed new motion sample.",
connection->getInputChannelName());
#endif
return;
}
#if DEBUG_BATCHING
if (status == NO_MEMORY) {
LOGD("channel '%s' ~ Could not append motion sample to currently "
"dispatched move event because the shared memory buffer is full. "
"(Waiting for next dispatch cycle to start.)",
connection->getInputChannelName());
} else if (status == status_t(FAILED_TRANSACTION)) {
LOGD("channel '%s' ~ Could not append motion sample to currently "
"dispatched move event because the event has already been consumed. "
"(Waiting for next dispatch cycle to start.)",
connection->getInputChannelName());
} else {
LOGD("channel '%s' ~ Could not append motion sample to currently "
"dispatched move event due to an error, status=%d. "
"(Waiting for next dispatch cycle to start.)",
connection->getInputChannelName(), status);
}
#endif
// Failed to stream. Start a new tail of pending motion samples to dispatch
// in the next cycle.
motionEventDispatchEntry->tailMotionSample = appendedMotionSample;
return;
}
}
// This is a new event.
// Enqueue a new dispatch entry onto the outbound queue for this connection.
DispatchEntry* dispatchEntry = mAllocator.obtainDispatchEntry(eventEntry, // increments ref
inputTarget->flags, inputTarget->xOffset, inputTarget->yOffset);
if (dispatchEntry->hasForegroundTarget()) {
incrementPendingForegroundDispatchesLocked(eventEntry);
}
// Handle the case where we could not stream a new motion sample because the consumer has
// already consumed the motion event (otherwise the corresponding dispatch entry would
// still be in the outbound queue for this connection). We set the head motion sample
// to the list starting with the newly appended motion sample.
if (resumeWithAppendedMotionSample) {
#if DEBUG_BATCHING
LOGD("channel '%s' ~ Preparing a new dispatch cycle for additional motion samples "
"that cannot be streamed because the motion event has already been consumed.",
connection->getInputChannelName());
#endif
MotionSample* appendedMotionSample = static_cast<MotionEntry*>(eventEntry)->lastSample;
dispatchEntry->headMotionSample = appendedMotionSample;
}
// Enqueue the dispatch entry.
connection->outboundQueue.enqueueAtTail(dispatchEntry);
// If the outbound queue was previously empty, start the dispatch cycle going.
if (wasEmpty) {
activateConnectionLocked(connection.get());
startDispatchCycleLocked(currentTime, connection);
}
}
void InputDispatcher::startDispatchCycleLocked(nsecs_t currentTime,
const sp<Connection>& connection) {
#if DEBUG_DISPATCH_CYCLE
LOGD("channel '%s' ~ startDispatchCycle",
connection->getInputChannelName());
#endif
assert(connection->status == Connection::STATUS_NORMAL);
assert(! connection->outboundQueue.isEmpty());
DispatchEntry* dispatchEntry = connection->outboundQueue.headSentinel.next;
assert(! dispatchEntry->inProgress);
// Mark the dispatch entry as in progress.
dispatchEntry->inProgress = true;
// Update the connection's input state.
EventEntry* eventEntry = dispatchEntry->eventEntry;
InputState::Consistency consistency = connection->inputState.trackEvent(eventEntry);
#if FILTER_INPUT_EVENTS
// Filter out inconsistent sequences of input events.
// The input system may drop or inject events in a way that could violate implicit
// invariants on input state and potentially cause an application to crash
// or think that a key or pointer is stuck down. Technically we make no guarantees
// of consistency but it would be nice to improve on this where possible.
// XXX: This code is a proof of concept only. Not ready for prime time.
if (consistency == InputState::TOLERABLE) {
#if DEBUG_DISPATCH_CYCLE
LOGD("channel '%s' ~ Sending an event that is inconsistent with the connection's "
"current input state but that is likely to be tolerated by the application.",
connection->getInputChannelName());
#endif
} else if (consistency == InputState::BROKEN) {
LOGI("channel '%s' ~ Dropping an event that is inconsistent with the connection's "
"current input state and that is likely to cause the application to crash.",
connection->getInputChannelName());
startNextDispatchCycleLocked(currentTime, connection);
return;
}
#endif
// Publish the event.
status_t status;
switch (eventEntry->type) {
case EventEntry::TYPE_KEY: {
KeyEntry* keyEntry = static_cast<KeyEntry*>(eventEntry);
// Apply target flags.
int32_t action = keyEntry->action;
int32_t flags = keyEntry->flags;
// Publish the key event.
status = connection->inputPublisher.publishKeyEvent(keyEntry->deviceId, keyEntry->source,
action, flags, keyEntry->keyCode, keyEntry->scanCode,
keyEntry->metaState, keyEntry->repeatCount, keyEntry->downTime,
keyEntry->eventTime);
if (status) {
LOGE("channel '%s' ~ Could not publish key event, "
"status=%d", connection->getInputChannelName(), status);
abortBrokenDispatchCycleLocked(currentTime, connection);
return;
}
break;
}
case EventEntry::TYPE_MOTION: {
MotionEntry* motionEntry = static_cast<MotionEntry*>(eventEntry);
// Apply target flags.
int32_t action = motionEntry->action;
int32_t flags = motionEntry->flags;
if (dispatchEntry->targetFlags & InputTarget::FLAG_OUTSIDE) {
action = AMOTION_EVENT_ACTION_OUTSIDE;
}
if (dispatchEntry->targetFlags & InputTarget::FLAG_WINDOW_IS_OBSCURED) {
flags |= AMOTION_EVENT_FLAG_WINDOW_IS_OBSCURED;
}
// If headMotionSample is non-NULL, then it points to the first new sample that we
// were unable to dispatch during the previous cycle so we resume dispatching from
// that point in the list of motion samples.
// Otherwise, we just start from the first sample of the motion event.
MotionSample* firstMotionSample = dispatchEntry->headMotionSample;
if (! firstMotionSample) {
firstMotionSample = & motionEntry->firstSample;
}
// Set the X and Y offset depending on the input source.
float xOffset, yOffset;
if (motionEntry->source & AINPUT_SOURCE_CLASS_POINTER) {
xOffset = dispatchEntry->xOffset;
yOffset = dispatchEntry->yOffset;
} else {
xOffset = 0.0f;
yOffset = 0.0f;
}
// Publish the motion event and the first motion sample.
status = connection->inputPublisher.publishMotionEvent(motionEntry->deviceId,
motionEntry->source, action, flags, motionEntry->edgeFlags, motionEntry->metaState,
xOffset, yOffset,
motionEntry->xPrecision, motionEntry->yPrecision,
motionEntry->downTime, firstMotionSample->eventTime,
motionEntry->pointerCount, motionEntry->pointerIds,
firstMotionSample->pointerCoords);
if (status) {
LOGE("channel '%s' ~ Could not publish motion event, "
"status=%d", connection->getInputChannelName(), status);
abortBrokenDispatchCycleLocked(currentTime, connection);
return;
}
// Append additional motion samples.
MotionSample* nextMotionSample = firstMotionSample->next;
for (; nextMotionSample != NULL; nextMotionSample = nextMotionSample->next) {
status = connection->inputPublisher.appendMotionSample(
nextMotionSample->eventTime, nextMotionSample->pointerCoords);
if (status == NO_MEMORY) {
#if DEBUG_DISPATCH_CYCLE
LOGD("channel '%s' ~ Shared memory buffer full. Some motion samples will "
"be sent in the next dispatch cycle.",
connection->getInputChannelName());
#endif
break;
}
if (status != OK) {
LOGE("channel '%s' ~ Could not append motion sample "
"for a reason other than out of memory, status=%d",
connection->getInputChannelName(), status);
abortBrokenDispatchCycleLocked(currentTime, connection);
return;
}
}
// Remember the next motion sample that we could not dispatch, in case we ran out
// of space in the shared memory buffer.
dispatchEntry->tailMotionSample = nextMotionSample;
break;
}
default: {
assert(false);
}
}
// Send the dispatch signal.
status = connection->inputPublisher.sendDispatchSignal();
if (status) {
LOGE("channel '%s' ~ Could not send dispatch signal, status=%d",
connection->getInputChannelName(), status);
abortBrokenDispatchCycleLocked(currentTime, connection);
return;
}
// Record information about the newly started dispatch cycle.
connection->lastEventTime = eventEntry->eventTime;
connection->lastDispatchTime = currentTime;
// Notify other system components.
onDispatchCycleStartedLocked(currentTime, connection);
}
void InputDispatcher::finishDispatchCycleLocked(nsecs_t currentTime,
const sp<Connection>& connection) {
#if DEBUG_DISPATCH_CYCLE
LOGD("channel '%s' ~ finishDispatchCycle - %01.1fms since event, "
"%01.1fms since dispatch",
connection->getInputChannelName(),
connection->getEventLatencyMillis(currentTime),
connection->getDispatchLatencyMillis(currentTime));
#endif
if (connection->status == Connection::STATUS_BROKEN
|| connection->status == Connection::STATUS_ZOMBIE) {
return;
}
// Notify other system components.
onDispatchCycleFinishedLocked(currentTime, connection);
// Reset the publisher since the event has been consumed.
// We do this now so that the publisher can release some of its internal resources
// while waiting for the next dispatch cycle to begin.
status_t status = connection->inputPublisher.reset();
if (status) {
LOGE("channel '%s' ~ Could not reset publisher, status=%d",
connection->getInputChannelName(), status);
abortBrokenDispatchCycleLocked(currentTime, connection);
return;
}
startNextDispatchCycleLocked(currentTime, connection);
}
void InputDispatcher::startNextDispatchCycleLocked(nsecs_t currentTime,
const sp<Connection>& connection) {
// Start the next dispatch cycle for this connection.
while (! connection->outboundQueue.isEmpty()) {
DispatchEntry* dispatchEntry = connection->outboundQueue.headSentinel.next;
if (dispatchEntry->inProgress) {
// Finish or resume current event in progress.
if (dispatchEntry->tailMotionSample) {
// We have a tail of undispatched motion samples.
// Reuse the same DispatchEntry and start a new cycle.
dispatchEntry->inProgress = false;
dispatchEntry->headMotionSample = dispatchEntry->tailMotionSample;
dispatchEntry->tailMotionSample = NULL;
startDispatchCycleLocked(currentTime, connection);
return;
}
// Finished.
connection->outboundQueue.dequeueAtHead();
if (dispatchEntry->hasForegroundTarget()) {
decrementPendingForegroundDispatchesLocked(dispatchEntry->eventEntry);
}
mAllocator.releaseDispatchEntry(dispatchEntry);
} else {
// If the head is not in progress, then we must have already dequeued the in
// progress event, which means we actually aborted it.
// So just start the next event for this connection.
startDispatchCycleLocked(currentTime, connection);
return;
}
}
// Outbound queue is empty, deactivate the connection.
deactivateConnectionLocked(connection.get());
}
void InputDispatcher::abortBrokenDispatchCycleLocked(nsecs_t currentTime,
const sp<Connection>& connection) {
#if DEBUG_DISPATCH_CYCLE
LOGD("channel '%s' ~ abortBrokenDispatchCycle - broken=%s",
connection->getInputChannelName(), toString(broken));
#endif
// Clear the outbound queue.
drainOutboundQueueLocked(connection.get());
// The connection appears to be unrecoverably broken.
// Ignore already broken or zombie connections.
if (connection->status == Connection::STATUS_NORMAL) {
connection->status = Connection::STATUS_BROKEN;
// Notify other system components.
onDispatchCycleBrokenLocked(currentTime, connection);
}
}
void InputDispatcher::drainOutboundQueueLocked(Connection* connection) {
while (! connection->outboundQueue.isEmpty()) {
DispatchEntry* dispatchEntry = connection->outboundQueue.dequeueAtHead();
if (dispatchEntry->hasForegroundTarget()) {
decrementPendingForegroundDispatchesLocked(dispatchEntry->eventEntry);
}
mAllocator.releaseDispatchEntry(dispatchEntry);
}
deactivateConnectionLocked(connection);
}
int InputDispatcher::handleReceiveCallback(int receiveFd, int events, void* data) {
InputDispatcher* d = static_cast<InputDispatcher*>(data);
{ // acquire lock
AutoMutex _l(d->mLock);
ssize_t connectionIndex = d->mConnectionsByReceiveFd.indexOfKey(receiveFd);
if (connectionIndex < 0) {
LOGE("Received spurious receive callback for unknown input channel. "
"fd=%d, events=0x%x", receiveFd, events);
return 0; // remove the callback
}
nsecs_t currentTime = now();
sp<Connection> connection = d->mConnectionsByReceiveFd.valueAt(connectionIndex);
if (events & (ALOOPER_EVENT_ERROR | ALOOPER_EVENT_HANGUP)) {
LOGE("channel '%s' ~ Consumer closed input channel or an error occurred. "
"events=0x%x", connection->getInputChannelName(), events);
d->abortBrokenDispatchCycleLocked(currentTime, connection);
d->runCommandsLockedInterruptible();
return 0; // remove the callback
}
if (! (events & ALOOPER_EVENT_INPUT)) {
LOGW("channel '%s' ~ Received spurious callback for unhandled poll event. "
"events=0x%x", connection->getInputChannelName(), events);
return 1;
}
status_t status = connection->inputPublisher.receiveFinishedSignal();
if (status) {
LOGE("channel '%s' ~ Failed to receive finished signal. status=%d",
connection->getInputChannelName(), status);
d->abortBrokenDispatchCycleLocked(currentTime, connection);
d->runCommandsLockedInterruptible();
return 0; // remove the callback
}
d->finishDispatchCycleLocked(currentTime, connection);
d->runCommandsLockedInterruptible();
return 1;
} // release lock
}
void InputDispatcher::synthesizeCancelationEventsForAllConnectionsLocked(
InputState::CancelationOptions options, const char* reason) {
for (size_t i = 0; i < mConnectionsByReceiveFd.size(); i++) {
synthesizeCancelationEventsForConnectionLocked(
mConnectionsByReceiveFd.valueAt(i), options, reason);
}
}
void InputDispatcher::synthesizeCancelationEventsForInputChannelLocked(
const sp<InputChannel>& channel, InputState::CancelationOptions options,
const char* reason) {
ssize_t index = getConnectionIndexLocked(channel);
if (index >= 0) {
synthesizeCancelationEventsForConnectionLocked(
mConnectionsByReceiveFd.valueAt(index), options, reason);
}
}
void InputDispatcher::synthesizeCancelationEventsForConnectionLocked(
const sp<Connection>& connection, InputState::CancelationOptions options,
const char* reason) {
nsecs_t currentTime = now();
mTempCancelationEvents.clear();
connection->inputState.synthesizeCancelationEvents(currentTime, & mAllocator,
mTempCancelationEvents, options);
if (! mTempCancelationEvents.isEmpty()
&& connection->status != Connection::STATUS_BROKEN) {
#if DEBUG_OUTBOUND_EVENT_DETAILS
LOGD("channel '%s' ~ Synthesized %d cancelation events to bring channel back in sync "
"with reality: %s, options=%d.",
connection->getInputChannelName(), mTempCancelationEvents.size(), reason, options);
#endif
for (size_t i = 0; i < mTempCancelationEvents.size(); i++) {
EventEntry* cancelationEventEntry = mTempCancelationEvents.itemAt(i);
switch (cancelationEventEntry->type) {
case EventEntry::TYPE_KEY:
logOutboundKeyDetailsLocked("cancel - ",
static_cast<KeyEntry*>(cancelationEventEntry));
break;
case EventEntry::TYPE_MOTION:
logOutboundMotionDetailsLocked("cancel - ",
static_cast<MotionEntry*>(cancelationEventEntry));
break;
}
int32_t xOffset, yOffset;
const InputWindow* window = getWindowLocked(connection->inputChannel);
if (window) {
xOffset = -window->frameLeft;
yOffset = -window->frameTop;
} else {
xOffset = 0;
yOffset = 0;
}
DispatchEntry* cancelationDispatchEntry =
mAllocator.obtainDispatchEntry(cancelationEventEntry, // increments ref
0, xOffset, yOffset);
connection->outboundQueue.enqueueAtTail(cancelationDispatchEntry);
mAllocator.releaseEventEntry(cancelationEventEntry);
}
if (!connection->outboundQueue.headSentinel.next->inProgress) {
startDispatchCycleLocked(currentTime, connection);
}
}
}
InputDispatcher::MotionEntry*
InputDispatcher::splitMotionEvent(const MotionEntry* originalMotionEntry, BitSet32 pointerIds) {
assert(pointerIds.value != 0);
uint32_t splitPointerIndexMap[MAX_POINTERS];
int32_t splitPointerIds[MAX_POINTERS];
PointerCoords splitPointerCoords[MAX_POINTERS];
uint32_t originalPointerCount = originalMotionEntry->pointerCount;
uint32_t splitPointerCount = 0;
for (uint32_t originalPointerIndex = 0; originalPointerIndex < originalPointerCount;
originalPointerIndex++) {
int32_t pointerId = uint32_t(originalMotionEntry->pointerIds[originalPointerIndex]);
if (pointerIds.hasBit(pointerId)) {
splitPointerIndexMap[splitPointerCount] = originalPointerIndex;
splitPointerIds[splitPointerCount] = pointerId;
splitPointerCoords[splitPointerCount] =
originalMotionEntry->firstSample.pointerCoords[originalPointerIndex];
splitPointerCount += 1;
}
}
assert(splitPointerCount == pointerIds.count());
int32_t action = originalMotionEntry->action;
int32_t maskedAction = action & AMOTION_EVENT_ACTION_MASK;
if (maskedAction == AMOTION_EVENT_ACTION_POINTER_DOWN
|| maskedAction == AMOTION_EVENT_ACTION_POINTER_UP) {
int32_t originalPointerIndex = getMotionEventActionPointerIndex(action);
int32_t pointerId = originalMotionEntry->pointerIds[originalPointerIndex];
if (pointerIds.hasBit(pointerId)) {
if (pointerIds.count() == 1) {
// The first/last pointer went down/up.
action = maskedAction == AMOTION_EVENT_ACTION_POINTER_DOWN
? AMOTION_EVENT_ACTION_DOWN : AMOTION_EVENT_ACTION_UP;
} else {
// A secondary pointer went down/up.
uint32_t splitPointerIndex = 0;
while (pointerId != splitPointerIds[splitPointerIndex]) {
splitPointerIndex += 1;
}
action = maskedAction | (splitPointerIndex
<< AMOTION_EVENT_ACTION_POINTER_INDEX_SHIFT);
}
} else {
// An unrelated pointer changed.
action = AMOTION_EVENT_ACTION_MOVE;
}
}
MotionEntry* splitMotionEntry = mAllocator.obtainMotionEntry(
originalMotionEntry->eventTime,
originalMotionEntry->deviceId,
originalMotionEntry->source,
originalMotionEntry->policyFlags,
action,
originalMotionEntry->flags,
originalMotionEntry->metaState,
originalMotionEntry->edgeFlags,
originalMotionEntry->xPrecision,
originalMotionEntry->yPrecision,
originalMotionEntry->downTime,
splitPointerCount, splitPointerIds, splitPointerCoords);
for (MotionSample* originalMotionSample = originalMotionEntry->firstSample.next;
originalMotionSample != NULL; originalMotionSample = originalMotionSample->next) {
for (uint32_t splitPointerIndex = 0; splitPointerIndex < splitPointerCount;
splitPointerIndex++) {
uint32_t originalPointerIndex = splitPointerIndexMap[splitPointerIndex];
splitPointerCoords[splitPointerIndex] =
originalMotionSample->pointerCoords[originalPointerIndex];
}
mAllocator.appendMotionSample(splitMotionEntry, originalMotionSample->eventTime,
splitPointerCoords);
}
return splitMotionEntry;
}
void InputDispatcher::notifyConfigurationChanged(nsecs_t eventTime) {
#if DEBUG_INBOUND_EVENT_DETAILS
LOGD("notifyConfigurationChanged - eventTime=%lld", eventTime);
#endif
bool needWake;
{ // acquire lock
AutoMutex _l(mLock);
ConfigurationChangedEntry* newEntry = mAllocator.obtainConfigurationChangedEntry(eventTime);
needWake = enqueueInboundEventLocked(newEntry);
} // release lock
if (needWake) {
mLooper->wake();
}
}
void InputDispatcher::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) {
#if DEBUG_INBOUND_EVENT_DETAILS
LOGD("notifyKey - eventTime=%lld, deviceId=0x%x, source=0x%x, policyFlags=0x%x, action=0x%x, "
"flags=0x%x, keyCode=0x%x, scanCode=0x%x, metaState=0x%x, downTime=%lld",
eventTime, deviceId, source, policyFlags, action, flags,
keyCode, scanCode, metaState, downTime);
#endif
if (! validateKeyEvent(action)) {
return;
}
policyFlags |= POLICY_FLAG_TRUSTED;
mPolicy->interceptKeyBeforeQueueing(eventTime, deviceId, action, /*byref*/ flags,
keyCode, scanCode, /*byref*/ policyFlags);
bool needWake;
{ // acquire lock
AutoMutex _l(mLock);
int32_t repeatCount = 0;
KeyEntry* newEntry = mAllocator.obtainKeyEntry(eventTime,
deviceId, source, policyFlags, action, flags, keyCode, scanCode,
metaState, repeatCount, downTime);
needWake = enqueueInboundEventLocked(newEntry);
} // release lock
if (needWake) {
mLooper->wake();
}
}
void InputDispatcher::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) {
#if DEBUG_INBOUND_EVENT_DETAILS
LOGD("notifyMotion - eventTime=%lld, deviceId=0x%x, source=0x%x, policyFlags=0x%x, "
"action=0x%x, flags=0x%x, metaState=0x%x, edgeFlags=0x%x, "
"xPrecision=%f, yPrecision=%f, downTime=%lld",
eventTime, deviceId, source, policyFlags, action, flags, metaState, edgeFlags,
xPrecision, yPrecision, downTime);
for (uint32_t i = 0; i < pointerCount; i++) {
LOGD(" Pointer %d: id=%d, x=%f, y=%f, pressure=%f, size=%f, "
"touchMajor=%f, touchMinor=%f, toolMajor=%f, toolMinor=%f, "
"orientation=%f",
i, pointerIds[i], pointerCoords[i].x, pointerCoords[i].y,
pointerCoords[i].pressure, pointerCoords[i].size,
pointerCoords[i].touchMajor, pointerCoords[i].touchMinor,
pointerCoords[i].toolMajor, pointerCoords[i].toolMinor,
pointerCoords[i].orientation);
}
#endif
if (! validateMotionEvent(action, pointerCount, pointerIds)) {
return;
}
policyFlags |= POLICY_FLAG_TRUSTED;
mPolicy->interceptGenericBeforeQueueing(eventTime, /*byref*/ policyFlags);
bool needWake;
{ // acquire lock
AutoMutex _l(mLock);
// Attempt batching and streaming of move events.
if (action == AMOTION_EVENT_ACTION_MOVE) {
// BATCHING CASE
//
// Try to append a move sample to the tail of the inbound queue for this device.
// Give up if we encounter a non-move motion event for this device since that
// means we cannot append any new samples until a new motion event has started.
for (EventEntry* entry = mInboundQueue.tailSentinel.prev;
entry != & mInboundQueue.headSentinel; entry = entry->prev) {
if (entry->type != EventEntry::TYPE_MOTION) {
// Keep looking for motion events.
continue;
}
MotionEntry* motionEntry = static_cast<MotionEntry*>(entry);
if (motionEntry->deviceId != deviceId) {
// Keep looking for this device.
continue;
}
if (motionEntry->action != AMOTION_EVENT_ACTION_MOVE
|| motionEntry->pointerCount != pointerCount
|| motionEntry->isInjected()) {
// Last motion event in the queue for this device is not compatible for
// appending new samples. Stop here.
goto NoBatchingOrStreaming;
}
// The last motion event is a move and is compatible for appending.
// Do the batching magic.
mAllocator.appendMotionSample(motionEntry, eventTime, pointerCoords);
#if DEBUG_BATCHING
LOGD("Appended motion sample onto batch for most recent "
"motion event for this device in the inbound queue.");
#endif
return; // done!
}
// STREAMING CASE
//
// There is no pending motion event (of any kind) for this device in the inbound queue.
// Search the outbound queue for the current foreground targets to find a dispatched
// motion event that is still in progress. If found, then, appen the new sample to
// that event and push it out to all current targets. The logic in
// prepareDispatchCycleLocked takes care of the case where some targets may
// already have consumed the motion event by starting a new dispatch cycle if needed.
if (mCurrentInputTargetsValid) {
for (size_t i = 0; i < mCurrentInputTargets.size(); i++) {
const InputTarget& inputTarget = mCurrentInputTargets[i];
if ((inputTarget.flags & InputTarget::FLAG_FOREGROUND) == 0) {
// Skip non-foreground targets. We only want to stream if there is at
// least one foreground target whose dispatch is still in progress.
continue;
}
ssize_t connectionIndex = getConnectionIndexLocked(inputTarget.inputChannel);
if (connectionIndex < 0) {
// Connection must no longer be valid.
continue;
}
sp<Connection> connection = mConnectionsByReceiveFd.valueAt(connectionIndex);
if (connection->outboundQueue.isEmpty()) {
// This foreground target has an empty outbound queue.
continue;
}
DispatchEntry* dispatchEntry = connection->outboundQueue.headSentinel.next;
if (! dispatchEntry->inProgress
|| dispatchEntry->eventEntry->type != EventEntry::TYPE_MOTION
|| dispatchEntry->isSplit()) {
// No motion event is being dispatched, or it is being split across
// windows in which case we cannot stream.
continue;
}
MotionEntry* motionEntry = static_cast<MotionEntry*>(
dispatchEntry->eventEntry);
if (motionEntry->action != AMOTION_EVENT_ACTION_MOVE
|| motionEntry->deviceId != deviceId
|| motionEntry->pointerCount != pointerCount
|| motionEntry->isInjected()) {
// The motion event is not compatible with this move.
continue;
}
// Hurray! This foreground target is currently dispatching a move event
// that we can stream onto. Append the motion sample and resume dispatch.
mAllocator.appendMotionSample(motionEntry, eventTime, pointerCoords);
#if DEBUG_BATCHING
LOGD("Appended motion sample onto batch for most recently dispatched "
"motion event for this device in the outbound queues. "
"Attempting to stream the motion sample.");
#endif
nsecs_t currentTime = now();
dispatchEventToCurrentInputTargetsLocked(currentTime, motionEntry,
true /*resumeWithAppendedMotionSample*/);
runCommandsLockedInterruptible();
return; // done!
}
}
NoBatchingOrStreaming:;
}
// Just enqueue a new motion event.
MotionEntry* newEntry = mAllocator.obtainMotionEntry(eventTime,
deviceId, source, policyFlags, action, flags, metaState, edgeFlags,
xPrecision, yPrecision, downTime,
pointerCount, pointerIds, pointerCoords);
needWake = enqueueInboundEventLocked(newEntry);
} // release lock
if (needWake) {
mLooper->wake();
}
}
void InputDispatcher::notifySwitch(nsecs_t when, int32_t switchCode, int32_t switchValue,
uint32_t policyFlags) {
#if DEBUG_INBOUND_EVENT_DETAILS
LOGD("notifySwitch - switchCode=%d, switchValue=%d, policyFlags=0x%x",
switchCode, switchValue, policyFlags);
#endif
policyFlags |= POLICY_FLAG_TRUSTED;
mPolicy->notifySwitch(when, switchCode, switchValue, policyFlags);
}
int32_t InputDispatcher::injectInputEvent(const InputEvent* event,
int32_t injectorPid, int32_t injectorUid, int32_t syncMode, int32_t timeoutMillis) {
#if DEBUG_INBOUND_EVENT_DETAILS
LOGD("injectInputEvent - eventType=%d, injectorPid=%d, injectorUid=%d, "
"syncMode=%d, timeoutMillis=%d",
event->getType(), injectorPid, injectorUid, syncMode, timeoutMillis);
#endif
nsecs_t endTime = now() + milliseconds_to_nanoseconds(timeoutMillis);
uint32_t policyFlags = POLICY_FLAG_INJECTED;
if (hasInjectionPermission(injectorPid, injectorUid)) {
policyFlags |= POLICY_FLAG_TRUSTED;
}
EventEntry* injectedEntry;
switch (event->getType()) {
case AINPUT_EVENT_TYPE_KEY: {
const KeyEvent* keyEvent = static_cast<const KeyEvent*>(event);
int32_t action = keyEvent->getAction();
if (! validateKeyEvent(action)) {
return INPUT_EVENT_INJECTION_FAILED;
}
nsecs_t eventTime = keyEvent->getEventTime();
int32_t deviceId = keyEvent->getDeviceId();
int32_t flags = keyEvent->getFlags();
int32_t keyCode = keyEvent->getKeyCode();
int32_t scanCode = keyEvent->getScanCode();
mPolicy->interceptKeyBeforeQueueing(eventTime, deviceId, action, /*byref*/ flags,
keyCode, scanCode, /*byref*/ policyFlags);
mLock.lock();
injectedEntry = mAllocator.obtainKeyEntry(eventTime, deviceId, keyEvent->getSource(),
policyFlags, action, flags, keyCode, scanCode, keyEvent->getMetaState(),
keyEvent->getRepeatCount(), keyEvent->getDownTime());
break;
}
case AINPUT_EVENT_TYPE_MOTION: {
const MotionEvent* motionEvent = static_cast<const MotionEvent*>(event);
int32_t action = motionEvent->getAction();
size_t pointerCount = motionEvent->getPointerCount();
const int32_t* pointerIds = motionEvent->getPointerIds();
if (! validateMotionEvent(action, pointerCount, pointerIds)) {
return INPUT_EVENT_INJECTION_FAILED;
}
nsecs_t eventTime = motionEvent->getEventTime();
mPolicy->interceptGenericBeforeQueueing(eventTime, /*byref*/ policyFlags);
mLock.lock();
const nsecs_t* sampleEventTimes = motionEvent->getSampleEventTimes();
const PointerCoords* samplePointerCoords = motionEvent->getSamplePointerCoords();
MotionEntry* motionEntry = mAllocator.obtainMotionEntry(*sampleEventTimes,
motionEvent->getDeviceId(), motionEvent->getSource(), policyFlags,
action, motionEvent->getFlags(),
motionEvent->getMetaState(), motionEvent->getEdgeFlags(),
motionEvent->getXPrecision(), motionEvent->getYPrecision(),
motionEvent->getDownTime(), uint32_t(pointerCount),
pointerIds, samplePointerCoords);
for (size_t i = motionEvent->getHistorySize(); i > 0; i--) {
sampleEventTimes += 1;
samplePointerCoords += pointerCount;
mAllocator.appendMotionSample(motionEntry, *sampleEventTimes, samplePointerCoords);
}
injectedEntry = motionEntry;
break;
}
default:
LOGW("Cannot inject event of type %d", event->getType());
return INPUT_EVENT_INJECTION_FAILED;
}
InjectionState* injectionState = mAllocator.obtainInjectionState(injectorPid, injectorUid);
if (syncMode == INPUT_EVENT_INJECTION_SYNC_NONE) {
injectionState->injectionIsAsync = true;
}
injectionState->refCount += 1;
injectedEntry->injectionState = injectionState;
bool needWake = enqueueInboundEventLocked(injectedEntry);
mLock.unlock();
if (needWake) {
mLooper->wake();
}
int32_t injectionResult;
{ // acquire lock
AutoMutex _l(mLock);
if (syncMode == INPUT_EVENT_INJECTION_SYNC_NONE) {
injectionResult = INPUT_EVENT_INJECTION_SUCCEEDED;
} else {
for (;;) {
injectionResult = injectionState->injectionResult;
if (injectionResult != INPUT_EVENT_INJECTION_PENDING) {
break;
}
nsecs_t remainingTimeout = endTime - now();
if (remainingTimeout <= 0) {
#if DEBUG_INJECTION
LOGD("injectInputEvent - Timed out waiting for injection result "
"to become available.");
#endif
injectionResult = INPUT_EVENT_INJECTION_TIMED_OUT;
break;
}
mInjectionResultAvailableCondition.waitRelative(mLock, remainingTimeout);
}
if (injectionResult == INPUT_EVENT_INJECTION_SUCCEEDED
&& syncMode == INPUT_EVENT_INJECTION_SYNC_WAIT_FOR_FINISHED) {
while (injectionState->pendingForegroundDispatches != 0) {
#if DEBUG_INJECTION
LOGD("injectInputEvent - Waiting for %d pending foreground dispatches.",
injectionState->pendingForegroundDispatches);
#endif
nsecs_t remainingTimeout = endTime - now();
if (remainingTimeout <= 0) {
#if DEBUG_INJECTION
LOGD("injectInputEvent - Timed out waiting for pending foreground "
"dispatches to finish.");
#endif
injectionResult = INPUT_EVENT_INJECTION_TIMED_OUT;
break;
}
mInjectionSyncFinishedCondition.waitRelative(mLock, remainingTimeout);
}
}
}
mAllocator.releaseInjectionState(injectionState);
} // release lock
#if DEBUG_INJECTION
LOGD("injectInputEvent - Finished with result %d. "
"injectorPid=%d, injectorUid=%d",
injectionResult, injectorPid, injectorUid);
#endif
return injectionResult;
}
bool InputDispatcher::hasInjectionPermission(int32_t injectorPid, int32_t injectorUid) {
return injectorUid == 0
|| mPolicy->checkInjectEventsPermissionNonReentrant(injectorPid, injectorUid);
}
void InputDispatcher::setInjectionResultLocked(EventEntry* entry, int32_t injectionResult) {
InjectionState* injectionState = entry->injectionState;
if (injectionState) {
#if DEBUG_INJECTION
LOGD("Setting input event injection result to %d. "
"injectorPid=%d, injectorUid=%d",
injectionResult, injectionState->injectorPid, injectionState->injectorUid);
#endif
if (injectionState->injectionIsAsync) {
// Log the outcome since the injector did not wait for the injection result.
switch (injectionResult) {
case INPUT_EVENT_INJECTION_SUCCEEDED:
LOGV("Asynchronous input event injection succeeded.");
break;
case INPUT_EVENT_INJECTION_FAILED:
LOGW("Asynchronous input event injection failed.");
break;
case INPUT_EVENT_INJECTION_PERMISSION_DENIED:
LOGW("Asynchronous input event injection permission denied.");
break;
case INPUT_EVENT_INJECTION_TIMED_OUT:
LOGW("Asynchronous input event injection timed out.");
break;
}
}
injectionState->injectionResult = injectionResult;
mInjectionResultAvailableCondition.broadcast();
}
}
void InputDispatcher::incrementPendingForegroundDispatchesLocked(EventEntry* entry) {
InjectionState* injectionState = entry->injectionState;
if (injectionState) {
injectionState->pendingForegroundDispatches += 1;
}
}
void InputDispatcher::decrementPendingForegroundDispatchesLocked(EventEntry* entry) {
InjectionState* injectionState = entry->injectionState;
if (injectionState) {
injectionState->pendingForegroundDispatches -= 1;
if (injectionState->pendingForegroundDispatches == 0) {
mInjectionSyncFinishedCondition.broadcast();
}
}
}
const InputWindow* InputDispatcher::getWindowLocked(const sp<InputChannel>& inputChannel) {
for (size_t i = 0; i < mWindows.size(); i++) {
const InputWindow* window = & mWindows[i];
if (window->inputChannel == inputChannel) {
return window;
}
}
return NULL;
}
void InputDispatcher::setInputWindows(const Vector<InputWindow>& inputWindows) {
#if DEBUG_FOCUS
LOGD("setInputWindows");
#endif
{ // acquire lock
AutoMutex _l(mLock);
// Clear old window pointers.
sp<InputChannel> oldFocusedWindowChannel;
if (mFocusedWindow) {
oldFocusedWindowChannel = mFocusedWindow->inputChannel;
mFocusedWindow = NULL;
}
mWindows.clear();
// Loop over new windows and rebuild the necessary window pointers for
// tracking focus and touch.
mWindows.appendVector(inputWindows);
size_t numWindows = mWindows.size();
for (size_t i = 0; i < numWindows; i++) {
const InputWindow* window = & mWindows.itemAt(i);
if (window->hasFocus) {
mFocusedWindow = window;
break;
}
}
if (oldFocusedWindowChannel != NULL) {
if (!mFocusedWindow || oldFocusedWindowChannel != mFocusedWindow->inputChannel) {
#if DEBUG_FOCUS
LOGD("Focus left window: %s",
oldFocusedWindowChannel->getName().string());
#endif
synthesizeCancelationEventsForInputChannelLocked(oldFocusedWindowChannel,
InputState::CANCEL_NON_POINTER_EVENTS, "focus left window");
oldFocusedWindowChannel.clear();
}
}
if (mFocusedWindow && oldFocusedWindowChannel == NULL) {
#if DEBUG_FOCUS
LOGD("Focus entered window: %s",
mFocusedWindow->inputChannel->getName().string());
#endif
}
for (size_t i = 0; i < mTouchState.windows.size(); ) {
TouchedWindow& touchedWindow = mTouchState.windows.editItemAt(i);
const InputWindow* window = getWindowLocked(touchedWindow.channel);
if (window) {
touchedWindow.window = window;
i += 1;
} else {
#if DEBUG_FOCUS
LOGD("Touched window was removed: %s", touchedWindow.channel->getName().string());
#endif
synthesizeCancelationEventsForInputChannelLocked(touchedWindow.channel,
InputState::CANCEL_POINTER_EVENTS, "touched window was removed");
mTouchState.windows.removeAt(i);
}
}
#if DEBUG_FOCUS
//logDispatchStateLocked();
#endif
} // release lock
// Wake up poll loop since it may need to make new input dispatching choices.
mLooper->wake();
}
void InputDispatcher::setFocusedApplication(const InputApplication* inputApplication) {
#if DEBUG_FOCUS
LOGD("setFocusedApplication");
#endif
{ // acquire lock
AutoMutex _l(mLock);
releaseFocusedApplicationLocked();
if (inputApplication) {
mFocusedApplicationStorage = *inputApplication;
mFocusedApplication = & mFocusedApplicationStorage;
}
#if DEBUG_FOCUS
//logDispatchStateLocked();
#endif
} // release lock
// Wake up poll loop since it may need to make new input dispatching choices.
mLooper->wake();
}
void InputDispatcher::releaseFocusedApplicationLocked() {
if (mFocusedApplication) {
mFocusedApplication = NULL;
mFocusedApplicationStorage.handle.clear();
}
}
void InputDispatcher::setInputDispatchMode(bool enabled, bool frozen) {
#if DEBUG_FOCUS
LOGD("setInputDispatchMode: enabled=%d, frozen=%d", enabled, frozen);
#endif
bool changed;
{ // acquire lock
AutoMutex _l(mLock);
if (mDispatchEnabled != enabled || mDispatchFrozen != frozen) {
if (mDispatchFrozen && ! frozen) {
resetANRTimeoutsLocked();
}
mDispatchEnabled = enabled;
mDispatchFrozen = frozen;
changed = true;
} else {
changed = false;
}
#if DEBUG_FOCUS
//logDispatchStateLocked();
#endif
} // release lock
if (changed) {
// Wake up poll loop since it may need to make new input dispatching choices.
mLooper->wake();
}
}
void InputDispatcher::logDispatchStateLocked() {
String8 dump;
dumpDispatchStateLocked(dump);
char* text = dump.lockBuffer(dump.size());
char* start = text;
while (*start != '\0') {
char* end = strchr(start, '\n');
if (*end == '\n') {
*(end++) = '\0';
}
LOGD("%s", start);
start = end;
}
}
void InputDispatcher::dumpDispatchStateLocked(String8& dump) {
dump.appendFormat(INDENT "DispatchEnabled: %d\n", mDispatchEnabled);
dump.appendFormat(INDENT "DispatchFrozen: %d\n", mDispatchFrozen);
if (mFocusedApplication) {
dump.appendFormat(INDENT "FocusedApplication: name='%s', dispatchingTimeout=%0.3fms\n",
mFocusedApplication->name.string(),
mFocusedApplication->dispatchingTimeout / 1000000.0);
} else {
dump.append(INDENT "FocusedApplication: <null>\n");
}
dump.appendFormat(INDENT "FocusedWindow: name='%s'\n",
mFocusedWindow != NULL ? mFocusedWindow->name.string() : "<null>");
dump.appendFormat(INDENT "TouchDown: %s\n", toString(mTouchState.down));
dump.appendFormat(INDENT "TouchSplit: %s\n", toString(mTouchState.split));
if (!mTouchState.windows.isEmpty()) {
dump.append(INDENT "TouchedWindows:\n");
for (size_t i = 0; i < mTouchState.windows.size(); i++) {
const TouchedWindow& touchedWindow = mTouchState.windows[i];
dump.appendFormat(INDENT2 "%d: name='%s', pointerIds=0x%0x, targetFlags=0x%x\n",
i, touchedWindow.window->name.string(), touchedWindow.pointerIds.value,
touchedWindow.targetFlags);
}
} else {
dump.append(INDENT "TouchedWindows: <none>\n");
}
if (!mWindows.isEmpty()) {
dump.append(INDENT "Windows:\n");
for (size_t i = 0; i < mWindows.size(); i++) {
const InputWindow& window = mWindows[i];
dump.appendFormat(INDENT2 "%d: name='%s', paused=%s, hasFocus=%s, hasWallpaper=%s, "
"visible=%s, canReceiveKeys=%s, flags=0x%08x, type=0x%08x, layer=%d, "
"frame=[%d,%d][%d,%d], "
"visibleFrame=[%d,%d][%d,%d], "
"touchableArea=[%d,%d][%d,%d], "
"ownerPid=%d, ownerUid=%d, dispatchingTimeout=%0.3fms\n",
i, window.name.string(),
toString(window.paused),
toString(window.hasFocus),
toString(window.hasWallpaper),
toString(window.visible),
toString(window.canReceiveKeys),
window.layoutParamsFlags, window.layoutParamsType,
window.layer,
window.frameLeft, window.frameTop,
window.frameRight, window.frameBottom,
window.visibleFrameLeft, window.visibleFrameTop,
window.visibleFrameRight, window.visibleFrameBottom,
window.touchableAreaLeft, window.touchableAreaTop,
window.touchableAreaRight, window.touchableAreaBottom,
window.ownerPid, window.ownerUid,
window.dispatchingTimeout / 1000000.0);
}
} else {
dump.append(INDENT "Windows: <none>\n");
}
if (!mMonitoringChannels.isEmpty()) {
dump.append(INDENT "MonitoringChannels:\n");
for (size_t i = 0; i < mMonitoringChannels.size(); i++) {
const sp<InputChannel>& channel = mMonitoringChannels[i];
dump.appendFormat(INDENT2 "%d: '%s'\n", i, channel->getName().string());
}
} else {
dump.append(INDENT "MonitoringChannels: <none>\n");
}
dump.appendFormat(INDENT "InboundQueue: length=%u\n", mInboundQueue.count());
if (!mActiveConnections.isEmpty()) {
dump.append(INDENT "ActiveConnections:\n");
for (size_t i = 0; i < mActiveConnections.size(); i++) {
const Connection* connection = mActiveConnections[i];
dump.appendFormat(INDENT2 "%d: '%s', status=%s, outboundQueueLength=%u"
"inputState.isNeutral=%s\n",
i, connection->getInputChannelName(), connection->getStatusLabel(),
connection->outboundQueue.count(),
toString(connection->inputState.isNeutral()));
}
} else {
dump.append(INDENT "ActiveConnections: <none>\n");
}
if (isAppSwitchPendingLocked()) {
dump.appendFormat(INDENT "AppSwitch: pending, due in %01.1fms\n",
(mAppSwitchDueTime - now()) / 1000000.0);
} else {
dump.append(INDENT "AppSwitch: not pending\n");
}
}
status_t InputDispatcher::registerInputChannel(const sp<InputChannel>& inputChannel, bool monitor) {
#if DEBUG_REGISTRATION
LOGD("channel '%s' ~ registerInputChannel - monitor=%s", inputChannel->getName().string(),
toString(monitor));
#endif
{ // acquire lock
AutoMutex _l(mLock);
if (getConnectionIndexLocked(inputChannel) >= 0) {
LOGW("Attempted to register already registered input channel '%s'",
inputChannel->getName().string());
return BAD_VALUE;
}
sp<Connection> connection = new Connection(inputChannel);
status_t status = connection->initialize();
if (status) {
LOGE("Failed to initialize input publisher for input channel '%s', status=%d",
inputChannel->getName().string(), status);
return status;
}
int32_t receiveFd = inputChannel->getReceivePipeFd();
mConnectionsByReceiveFd.add(receiveFd, connection);
if (monitor) {
mMonitoringChannels.push(inputChannel);
}
mLooper->addFd(receiveFd, 0, ALOOPER_EVENT_INPUT, handleReceiveCallback, this);
runCommandsLockedInterruptible();
} // release lock
return OK;
}
status_t InputDispatcher::unregisterInputChannel(const sp<InputChannel>& inputChannel) {
#if DEBUG_REGISTRATION
LOGD("channel '%s' ~ unregisterInputChannel", inputChannel->getName().string());
#endif
{ // acquire lock
AutoMutex _l(mLock);
ssize_t connectionIndex = getConnectionIndexLocked(inputChannel);
if (connectionIndex < 0) {
LOGW("Attempted to unregister already unregistered input channel '%s'",
inputChannel->getName().string());
return BAD_VALUE;
}
sp<Connection> connection = mConnectionsByReceiveFd.valueAt(connectionIndex);
mConnectionsByReceiveFd.removeItemsAt(connectionIndex);
connection->status = Connection::STATUS_ZOMBIE;
for (size_t i = 0; i < mMonitoringChannels.size(); i++) {
if (mMonitoringChannels[i] == inputChannel) {
mMonitoringChannels.removeAt(i);
break;
}
}
mLooper->removeFd(inputChannel->getReceivePipeFd());
nsecs_t currentTime = now();
abortBrokenDispatchCycleLocked(currentTime, connection);
runCommandsLockedInterruptible();
} // release lock
// Wake the poll loop because removing the connection may have changed the current
// synchronization state.
mLooper->wake();
return OK;
}
ssize_t InputDispatcher::getConnectionIndexLocked(const sp<InputChannel>& inputChannel) {
ssize_t connectionIndex = mConnectionsByReceiveFd.indexOfKey(inputChannel->getReceivePipeFd());
if (connectionIndex >= 0) {
sp<Connection> connection = mConnectionsByReceiveFd.valueAt(connectionIndex);
if (connection->inputChannel.get() == inputChannel.get()) {
return connectionIndex;
}
}
return -1;
}
void InputDispatcher::activateConnectionLocked(Connection* connection) {
for (size_t i = 0; i < mActiveConnections.size(); i++) {
if (mActiveConnections.itemAt(i) == connection) {
return;
}
}
mActiveConnections.add(connection);
}
void InputDispatcher::deactivateConnectionLocked(Connection* connection) {
for (size_t i = 0; i < mActiveConnections.size(); i++) {
if (mActiveConnections.itemAt(i) == connection) {
mActiveConnections.removeAt(i);
return;
}
}
}
void InputDispatcher::onDispatchCycleStartedLocked(
nsecs_t currentTime, const sp<Connection>& connection) {
}
void InputDispatcher::onDispatchCycleFinishedLocked(
nsecs_t currentTime, const sp<Connection>& connection) {
}
void InputDispatcher::onDispatchCycleBrokenLocked(
nsecs_t currentTime, const sp<Connection>& connection) {
LOGE("channel '%s' ~ Channel is unrecoverably broken and will be disposed!",
connection->getInputChannelName());
CommandEntry* commandEntry = postCommandLocked(
& InputDispatcher::doNotifyInputChannelBrokenLockedInterruptible);
commandEntry->connection = connection;
}
void InputDispatcher::onANRLocked(
nsecs_t currentTime, const InputApplication* application, const InputWindow* window,
nsecs_t eventTime, nsecs_t waitStartTime) {
LOGI("Application is not responding: %s. "
"%01.1fms since event, %01.1fms since wait started",
getApplicationWindowLabelLocked(application, window).string(),
(currentTime - eventTime) / 1000000.0,
(currentTime - waitStartTime) / 1000000.0);
CommandEntry* commandEntry = postCommandLocked(
& InputDispatcher::doNotifyANRLockedInterruptible);
if (application) {
commandEntry->inputApplicationHandle = application->handle;
}
if (window) {
commandEntry->inputChannel = window->inputChannel;
}
}
void InputDispatcher::doNotifyConfigurationChangedInterruptible(
CommandEntry* commandEntry) {
mLock.unlock();
mPolicy->notifyConfigurationChanged(commandEntry->eventTime);
mLock.lock();
}
void InputDispatcher::doNotifyInputChannelBrokenLockedInterruptible(
CommandEntry* commandEntry) {
sp<Connection> connection = commandEntry->connection;
if (connection->status != Connection::STATUS_ZOMBIE) {
mLock.unlock();
mPolicy->notifyInputChannelBroken(connection->inputChannel);
mLock.lock();
}
}
void InputDispatcher::doNotifyANRLockedInterruptible(
CommandEntry* commandEntry) {
mLock.unlock();
nsecs_t newTimeout = mPolicy->notifyANR(
commandEntry->inputApplicationHandle, commandEntry->inputChannel);
mLock.lock();
resumeAfterTargetsNotReadyTimeoutLocked(newTimeout, commandEntry->inputChannel);
}
void InputDispatcher::doInterceptKeyBeforeDispatchingLockedInterruptible(
CommandEntry* commandEntry) {
KeyEntry* entry = commandEntry->keyEntry;
mReusableKeyEvent.initialize(entry->deviceId, entry->source, entry->action, entry->flags,
entry->keyCode, entry->scanCode, entry->metaState, entry->repeatCount,
entry->downTime, entry->eventTime);
mLock.unlock();
bool consumed = mPolicy->interceptKeyBeforeDispatching(commandEntry->inputChannel,
& mReusableKeyEvent, entry->policyFlags);
mLock.lock();
entry->interceptKeyResult = consumed
? KeyEntry::INTERCEPT_KEY_RESULT_SKIP
: KeyEntry::INTERCEPT_KEY_RESULT_CONTINUE;
mAllocator.releaseKeyEntry(entry);
}
void InputDispatcher::doPokeUserActivityLockedInterruptible(CommandEntry* commandEntry) {
mLock.unlock();
mPolicy->pokeUserActivity(commandEntry->eventTime, commandEntry->userActivityEventType);
mLock.lock();
}
void InputDispatcher::updateDispatchStatisticsLocked(nsecs_t currentTime, const EventEntry* entry,
int32_t injectionResult, nsecs_t timeSpentWaitingForApplication) {
// TODO Write some statistics about how long we spend waiting.
}
void InputDispatcher::dump(String8& dump) {
dump.append("Input Dispatcher State:\n");
dumpDispatchStateLocked(dump);
}
// --- InputDispatcher::Queue ---
template <typename T>
uint32_t InputDispatcher::Queue<T>::count() const {
uint32_t result = 0;
for (const T* entry = headSentinel.next; entry != & tailSentinel; entry = entry->next) {
result += 1;
}
return result;
}
// --- InputDispatcher::Allocator ---
InputDispatcher::Allocator::Allocator() {
}
InputDispatcher::InjectionState*
InputDispatcher::Allocator::obtainInjectionState(int32_t injectorPid, int32_t injectorUid) {
InjectionState* injectionState = mInjectionStatePool.alloc();
injectionState->refCount = 1;
injectionState->injectorPid = injectorPid;
injectionState->injectorUid = injectorUid;
injectionState->injectionIsAsync = false;
injectionState->injectionResult = INPUT_EVENT_INJECTION_PENDING;
injectionState->pendingForegroundDispatches = 0;
return injectionState;
}
void InputDispatcher::Allocator::initializeEventEntry(EventEntry* entry, int32_t type,
nsecs_t eventTime, uint32_t policyFlags) {
entry->type = type;
entry->refCount = 1;
entry->dispatchInProgress = false;
entry->eventTime = eventTime;
entry->policyFlags = policyFlags;
entry->injectionState = NULL;
}
void InputDispatcher::Allocator::releaseEventEntryInjectionState(EventEntry* entry) {
if (entry->injectionState) {
releaseInjectionState(entry->injectionState);
entry->injectionState = NULL;
}
}
InputDispatcher::ConfigurationChangedEntry*
InputDispatcher::Allocator::obtainConfigurationChangedEntry(nsecs_t eventTime) {
ConfigurationChangedEntry* entry = mConfigurationChangeEntryPool.alloc();
initializeEventEntry(entry, EventEntry::TYPE_CONFIGURATION_CHANGED, eventTime, 0);
return entry;
}
InputDispatcher::KeyEntry* InputDispatcher::Allocator::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) {
KeyEntry* entry = mKeyEntryPool.alloc();
initializeEventEntry(entry, EventEntry::TYPE_KEY, eventTime, policyFlags);
entry->deviceId = deviceId;
entry->source = source;
entry->action = action;
entry->flags = flags;
entry->keyCode = keyCode;
entry->scanCode = scanCode;
entry->metaState = metaState;
entry->repeatCount = repeatCount;
entry->downTime = downTime;
entry->syntheticRepeat = false;
entry->interceptKeyResult = KeyEntry::INTERCEPT_KEY_RESULT_UNKNOWN;
return entry;
}
InputDispatcher::MotionEntry* InputDispatcher::Allocator::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) {
MotionEntry* entry = mMotionEntryPool.alloc();
initializeEventEntry(entry, EventEntry::TYPE_MOTION, eventTime, policyFlags);
entry->eventTime = eventTime;
entry->deviceId = deviceId;
entry->source = source;
entry->action = action;
entry->flags = flags;
entry->metaState = metaState;
entry->edgeFlags = edgeFlags;
entry->xPrecision = xPrecision;
entry->yPrecision = yPrecision;
entry->downTime = downTime;
entry->pointerCount = pointerCount;
entry->firstSample.eventTime = eventTime;
entry->firstSample.next = NULL;
entry->lastSample = & entry->firstSample;
for (uint32_t i = 0; i < pointerCount; i++) {
entry->pointerIds[i] = pointerIds[i];
entry->firstSample.pointerCoords[i] = pointerCoords[i];
}
return entry;
}
InputDispatcher::DispatchEntry* InputDispatcher::Allocator::obtainDispatchEntry(
EventEntry* eventEntry,
int32_t targetFlags, float xOffset, float yOffset) {
DispatchEntry* entry = mDispatchEntryPool.alloc();
entry->eventEntry = eventEntry;
eventEntry->refCount += 1;
entry->targetFlags = targetFlags;
entry->xOffset = xOffset;
entry->yOffset = yOffset;
entry->inProgress = false;
entry->headMotionSample = NULL;
entry->tailMotionSample = NULL;
return entry;
}
InputDispatcher::CommandEntry* InputDispatcher::Allocator::obtainCommandEntry(Command command) {
CommandEntry* entry = mCommandEntryPool.alloc();
entry->command = command;
return entry;
}
void InputDispatcher::Allocator::releaseInjectionState(InjectionState* injectionState) {
injectionState->refCount -= 1;
if (injectionState->refCount == 0) {
mInjectionStatePool.free(injectionState);
} else {
assert(injectionState->refCount > 0);
}
}
void InputDispatcher::Allocator::releaseEventEntry(EventEntry* entry) {
switch (entry->type) {
case EventEntry::TYPE_CONFIGURATION_CHANGED:
releaseConfigurationChangedEntry(static_cast<ConfigurationChangedEntry*>(entry));
break;
case EventEntry::TYPE_KEY:
releaseKeyEntry(static_cast<KeyEntry*>(entry));
break;
case EventEntry::TYPE_MOTION:
releaseMotionEntry(static_cast<MotionEntry*>(entry));
break;
default:
assert(false);
break;
}
}
void InputDispatcher::Allocator::releaseConfigurationChangedEntry(
ConfigurationChangedEntry* entry) {
entry->refCount -= 1;
if (entry->refCount == 0) {
releaseEventEntryInjectionState(entry);
mConfigurationChangeEntryPool.free(entry);
} else {
assert(entry->refCount > 0);
}
}
void InputDispatcher::Allocator::releaseKeyEntry(KeyEntry* entry) {
entry->refCount -= 1;
if (entry->refCount == 0) {
releaseEventEntryInjectionState(entry);
mKeyEntryPool.free(entry);
} else {
assert(entry->refCount > 0);
}
}
void InputDispatcher::Allocator::releaseMotionEntry(MotionEntry* entry) {
entry->refCount -= 1;
if (entry->refCount == 0) {
releaseEventEntryInjectionState(entry);
for (MotionSample* sample = entry->firstSample.next; sample != NULL; ) {
MotionSample* next = sample->next;
mMotionSamplePool.free(sample);
sample = next;
}
mMotionEntryPool.free(entry);
} else {
assert(entry->refCount > 0);
}
}
void InputDispatcher::Allocator::releaseDispatchEntry(DispatchEntry* entry) {
releaseEventEntry(entry->eventEntry);
mDispatchEntryPool.free(entry);
}
void InputDispatcher::Allocator::releaseCommandEntry(CommandEntry* entry) {
mCommandEntryPool.free(entry);
}
void InputDispatcher::Allocator::appendMotionSample(MotionEntry* motionEntry,
nsecs_t eventTime, const PointerCoords* pointerCoords) {
MotionSample* sample = mMotionSamplePool.alloc();
sample->eventTime = eventTime;
uint32_t pointerCount = motionEntry->pointerCount;
for (uint32_t i = 0; i < pointerCount; i++) {
sample->pointerCoords[i] = pointerCoords[i];
}
sample->next = NULL;
motionEntry->lastSample->next = sample;
motionEntry->lastSample = sample;
}
void InputDispatcher::Allocator::recycleKeyEntry(KeyEntry* keyEntry) {
releaseEventEntryInjectionState(keyEntry);
keyEntry->dispatchInProgress = false;
keyEntry->syntheticRepeat = false;
keyEntry->interceptKeyResult = KeyEntry::INTERCEPT_KEY_RESULT_UNKNOWN;
}
// --- InputDispatcher::MotionEntry ---
uint32_t InputDispatcher::MotionEntry::countSamples() const {
uint32_t count = 1;
for (MotionSample* sample = firstSample.next; sample != NULL; sample = sample->next) {
count += 1;
}
return count;
}
// --- InputDispatcher::InputState ---
InputDispatcher::InputState::InputState() {
}
InputDispatcher::InputState::~InputState() {
}
bool InputDispatcher::InputState::isNeutral() const {
return mKeyMementos.isEmpty() && mMotionMementos.isEmpty();
}
InputDispatcher::InputState::Consistency InputDispatcher::InputState::trackEvent(
const EventEntry* entry) {
switch (entry->type) {
case EventEntry::TYPE_KEY:
return trackKey(static_cast<const KeyEntry*>(entry));
case EventEntry::TYPE_MOTION:
return trackMotion(static_cast<const MotionEntry*>(entry));
default:
return CONSISTENT;
}
}
InputDispatcher::InputState::Consistency InputDispatcher::InputState::trackKey(
const KeyEntry* entry) {
int32_t action = entry->action;
for (size_t i = 0; i < mKeyMementos.size(); i++) {
KeyMemento& memento = mKeyMementos.editItemAt(i);
if (memento.deviceId == entry->deviceId
&& memento.source == entry->source
&& memento.keyCode == entry->keyCode
&& memento.scanCode == entry->scanCode) {
switch (action) {
case AKEY_EVENT_ACTION_UP:
mKeyMementos.removeAt(i);
return CONSISTENT;
case AKEY_EVENT_ACTION_DOWN:
return TOLERABLE;
default:
return BROKEN;
}
}
}
switch (action) {
case AKEY_EVENT_ACTION_DOWN: {
mKeyMementos.push();
KeyMemento& memento = mKeyMementos.editTop();
memento.deviceId = entry->deviceId;
memento.source = entry->source;
memento.keyCode = entry->keyCode;
memento.scanCode = entry->scanCode;
memento.downTime = entry->downTime;
return CONSISTENT;
}
default:
return BROKEN;
}
}
InputDispatcher::InputState::Consistency InputDispatcher::InputState::trackMotion(
const MotionEntry* entry) {
int32_t action = entry->action & AMOTION_EVENT_ACTION_MASK;
for (size_t i = 0; i < mMotionMementos.size(); i++) {
MotionMemento& memento = mMotionMementos.editItemAt(i);
if (memento.deviceId == entry->deviceId
&& memento.source == entry->source) {
switch (action) {
case AMOTION_EVENT_ACTION_UP:
case AMOTION_EVENT_ACTION_CANCEL:
mMotionMementos.removeAt(i);
return CONSISTENT;
case AMOTION_EVENT_ACTION_DOWN:
return TOLERABLE;
case AMOTION_EVENT_ACTION_POINTER_DOWN:
if (entry->pointerCount == memento.pointerCount + 1) {
memento.setPointers(entry);
return CONSISTENT;
}
return BROKEN;
case AMOTION_EVENT_ACTION_POINTER_UP:
if (entry->pointerCount == memento.pointerCount - 1) {
memento.setPointers(entry);
return CONSISTENT;
}
return BROKEN;
case AMOTION_EVENT_ACTION_MOVE:
if (entry->pointerCount == memento.pointerCount) {
return CONSISTENT;
}
return BROKEN;
default:
return BROKEN;
}
}
}
switch (action) {
case AMOTION_EVENT_ACTION_DOWN: {
mMotionMementos.push();
MotionMemento& memento = mMotionMementos.editTop();
memento.deviceId = entry->deviceId;
memento.source = entry->source;
memento.xPrecision = entry->xPrecision;
memento.yPrecision = entry->yPrecision;
memento.downTime = entry->downTime;
memento.setPointers(entry);
return CONSISTENT;
}
default:
return BROKEN;
}
}
void InputDispatcher::InputState::MotionMemento::setPointers(const MotionEntry* entry) {
pointerCount = entry->pointerCount;
for (uint32_t i = 0; i < entry->pointerCount; i++) {
pointerIds[i] = entry->pointerIds[i];
pointerCoords[i] = entry->lastSample->pointerCoords[i];
}
}
void InputDispatcher::InputState::synthesizeCancelationEvents(nsecs_t currentTime,
Allocator* allocator, Vector<EventEntry*>& outEvents,
CancelationOptions options) {
for (size_t i = 0; i < mKeyMementos.size(); ) {
const KeyMemento& memento = mKeyMementos.itemAt(i);
if (shouldCancelEvent(memento.source, options)) {
outEvents.push(allocator->obtainKeyEntry(currentTime,
memento.deviceId, memento.source, 0,
AKEY_EVENT_ACTION_UP, AKEY_EVENT_FLAG_CANCELED,
memento.keyCode, memento.scanCode, 0, 0, memento.downTime));
mKeyMementos.removeAt(i);
} else {
i += 1;
}
}
for (size_t i = 0; i < mMotionMementos.size(); ) {
const MotionMemento& memento = mMotionMementos.itemAt(i);
if (shouldCancelEvent(memento.source, options)) {
outEvents.push(allocator->obtainMotionEntry(currentTime,
memento.deviceId, memento.source, 0,
AMOTION_EVENT_ACTION_CANCEL, 0, 0, 0,
memento.xPrecision, memento.yPrecision, memento.downTime,
memento.pointerCount, memento.pointerIds, memento.pointerCoords));
mMotionMementos.removeAt(i);
} else {
i += 1;
}
}
}
void InputDispatcher::InputState::clear() {
mKeyMementos.clear();
mMotionMementos.clear();
}
bool InputDispatcher::InputState::shouldCancelEvent(int32_t eventSource,
CancelationOptions options) {
switch (options) {
case CANCEL_POINTER_EVENTS:
return eventSource & AINPUT_SOURCE_CLASS_POINTER;
case CANCEL_NON_POINTER_EVENTS:
return !(eventSource & AINPUT_SOURCE_CLASS_POINTER);
default:
return true;
}
}
// --- InputDispatcher::Connection ---
InputDispatcher::Connection::Connection(const sp<InputChannel>& inputChannel) :
status(STATUS_NORMAL), inputChannel(inputChannel), inputPublisher(inputChannel),
lastEventTime(LONG_LONG_MAX), lastDispatchTime(LONG_LONG_MAX) {
}
InputDispatcher::Connection::~Connection() {
}
status_t InputDispatcher::Connection::initialize() {
return inputPublisher.initialize();
}
const char* InputDispatcher::Connection::getStatusLabel() const {
switch (status) {
case STATUS_NORMAL:
return "NORMAL";
case STATUS_BROKEN:
return "BROKEN";
case STATUS_ZOMBIE:
return "ZOMBIE";
default:
return "UNKNOWN";
}
}
InputDispatcher::DispatchEntry* InputDispatcher::Connection::findQueuedDispatchEntryForEvent(
const EventEntry* eventEntry) const {
for (DispatchEntry* dispatchEntry = outboundQueue.tailSentinel.prev;
dispatchEntry != & outboundQueue.headSentinel; dispatchEntry = dispatchEntry->prev) {
if (dispatchEntry->eventEntry == eventEntry) {
return dispatchEntry;
}
}
return NULL;
}
// --- InputDispatcher::CommandEntry ---
InputDispatcher::CommandEntry::CommandEntry() :
keyEntry(NULL) {
}
InputDispatcher::CommandEntry::~CommandEntry() {
}
// --- InputDispatcher::TouchState ---
InputDispatcher::TouchState::TouchState() :
down(false), split(false) {
}
InputDispatcher::TouchState::~TouchState() {
}
void InputDispatcher::TouchState::reset() {
down = false;
split = false;
windows.clear();
}
void InputDispatcher::TouchState::copyFrom(const TouchState& other) {
down = other.down;
split = other.split;
windows.clear();
windows.appendVector(other.windows);
}
void InputDispatcher::TouchState::addOrUpdateWindow(const InputWindow* window,
int32_t targetFlags, BitSet32 pointerIds) {
if (targetFlags & InputTarget::FLAG_SPLIT) {
split = true;
}
for (size_t i = 0; i < windows.size(); i++) {
TouchedWindow& touchedWindow = windows.editItemAt(i);
if (touchedWindow.window == window) {
touchedWindow.targetFlags |= targetFlags;
touchedWindow.pointerIds.value |= pointerIds.value;
return;
}
}
windows.push();
TouchedWindow& touchedWindow = windows.editTop();
touchedWindow.window = window;
touchedWindow.targetFlags = targetFlags;
touchedWindow.pointerIds = pointerIds;
touchedWindow.channel = window->inputChannel;
}
void InputDispatcher::TouchState::removeOutsideTouchWindows() {
for (size_t i = 0 ; i < windows.size(); ) {
if (windows[i].targetFlags & InputTarget::FLAG_OUTSIDE) {
windows.removeAt(i);
} else {
i += 1;
}
}
}
const InputWindow* InputDispatcher::TouchState::getFirstForegroundWindow() {
for (size_t i = 0; i < windows.size(); i++) {
if (windows[i].targetFlags & InputTarget::FLAG_FOREGROUND) {
return windows[i].window;
}
}
return NULL;
}
// --- InputDispatcherThread ---
InputDispatcherThread::InputDispatcherThread(const sp<InputDispatcherInterface>& dispatcher) :
Thread(/*canCallJava*/ true), mDispatcher(dispatcher) {
}
InputDispatcherThread::~InputDispatcherThread() {
}
bool InputDispatcherThread::threadLoop() {
mDispatcher->dispatchOnce();
return true;
}
} // namespace android