am 5f920c1a
: BufferQueueConsumer: signal onFrameReleased on dropped frames
* commit '5f920c1a2cf12c0638c05fbddee8ff6c1193731c': BufferQueueConsumer: signal onFrameReleased on dropped frames
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commit
59d6f2c322
@ -38,156 +38,169 @@ BufferQueueConsumer::~BufferQueueConsumer() {}
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status_t BufferQueueConsumer::acquireBuffer(BufferItem* outBuffer,
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nsecs_t expectedPresent, uint64_t maxFrameNumber) {
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ATRACE_CALL();
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Mutex::Autolock lock(mCore->mMutex);
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// Check that the consumer doesn't currently have the maximum number of
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// buffers acquired. We allow the max buffer count to be exceeded by one
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// buffer so that the consumer can successfully set up the newly acquired
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// buffer before releasing the old one.
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int numAcquiredBuffers = 0;
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for (int s = 0; s < BufferQueueDefs::NUM_BUFFER_SLOTS; ++s) {
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if (mSlots[s].mBufferState == BufferSlot::ACQUIRED) {
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++numAcquiredBuffers;
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int numDroppedBuffers = 0;
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sp<IProducerListener> listener;
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{
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Mutex::Autolock lock(mCore->mMutex);
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// Check that the consumer doesn't currently have the maximum number of
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// buffers acquired. We allow the max buffer count to be exceeded by one
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// buffer so that the consumer can successfully set up the newly acquired
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// buffer before releasing the old one.
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int numAcquiredBuffers = 0;
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for (int s = 0; s < BufferQueueDefs::NUM_BUFFER_SLOTS; ++s) {
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if (mSlots[s].mBufferState == BufferSlot::ACQUIRED) {
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++numAcquiredBuffers;
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}
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}
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if (numAcquiredBuffers >= mCore->mMaxAcquiredBufferCount + 1) {
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BQ_LOGE("acquireBuffer: max acquired buffer count reached: %d (max %d)",
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numAcquiredBuffers, mCore->mMaxAcquiredBufferCount);
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return INVALID_OPERATION;
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}
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}
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if (numAcquiredBuffers >= mCore->mMaxAcquiredBufferCount + 1) {
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BQ_LOGE("acquireBuffer: max acquired buffer count reached: %d (max %d)",
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numAcquiredBuffers, mCore->mMaxAcquiredBufferCount);
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return INVALID_OPERATION;
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}
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// Check if the queue is empty.
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// In asynchronous mode the list is guaranteed to be one buffer deep,
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// while in synchronous mode we use the oldest buffer.
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if (mCore->mQueue.empty()) {
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return NO_BUFFER_AVAILABLE;
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}
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// Check if the queue is empty.
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// In asynchronous mode the list is guaranteed to be one buffer deep,
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// while in synchronous mode we use the oldest buffer.
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if (mCore->mQueue.empty()) {
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return NO_BUFFER_AVAILABLE;
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}
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BufferQueueCore::Fifo::iterator front(mCore->mQueue.begin());
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BufferQueueCore::Fifo::iterator front(mCore->mQueue.begin());
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// If expectedPresent is specified, we may not want to return a buffer yet.
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// If it's specified and there's more than one buffer queued, we may want
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// to drop a buffer.
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if (expectedPresent != 0) {
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const int MAX_REASONABLE_NSEC = 1000000000ULL; // 1 second
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// If expectedPresent is specified, we may not want to return a buffer yet.
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// If it's specified and there's more than one buffer queued, we may want
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// to drop a buffer.
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if (expectedPresent != 0) {
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const int MAX_REASONABLE_NSEC = 1000000000ULL; // 1 second
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// The 'expectedPresent' argument indicates when the buffer is expected
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// to be presented on-screen. If the buffer's desired present time is
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// earlier (less) than expectedPresent -- meaning it will be displayed
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// on time or possibly late if we show it as soon as possible -- we
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// acquire and return it. If we don't want to display it until after the
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// expectedPresent time, we return PRESENT_LATER without acquiring it.
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//
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// To be safe, we don't defer acquisition if expectedPresent is more
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// than one second in the future beyond the desired present time
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// (i.e., we'd be holding the buffer for a long time).
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//
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// NOTE: Code assumes monotonic time values from the system clock
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// are positive.
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// The 'expectedPresent' argument indicates when the buffer is expected
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// to be presented on-screen. If the buffer's desired present time is
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// earlier (less) than expectedPresent -- meaning it will be displayed
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// on time or possibly late if we show it as soon as possible -- we
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// acquire and return it. If we don't want to display it until after the
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// expectedPresent time, we return PRESENT_LATER without acquiring it.
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//
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// To be safe, we don't defer acquisition if expectedPresent is more
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// than one second in the future beyond the desired present time
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// (i.e., we'd be holding the buffer for a long time).
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//
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// NOTE: Code assumes monotonic time values from the system clock
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// are positive.
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// Start by checking to see if we can drop frames. We skip this check if
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// the timestamps are being auto-generated by Surface. If the app isn't
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// generating timestamps explicitly, it probably doesn't want frames to
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// be discarded based on them.
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while (mCore->mQueue.size() > 1 && !mCore->mQueue[0].mIsAutoTimestamp) {
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const BufferItem& bufferItem(mCore->mQueue[1]);
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// Start by checking to see if we can drop frames. We skip this check if
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// the timestamps are being auto-generated by Surface. If the app isn't
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// generating timestamps explicitly, it probably doesn't want frames to
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// be discarded based on them.
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while (mCore->mQueue.size() > 1 && !mCore->mQueue[0].mIsAutoTimestamp) {
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const BufferItem& bufferItem(mCore->mQueue[1]);
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// If dropping entry[0] would leave us with a buffer that the
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// consumer is not yet ready for, don't drop it.
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if (maxFrameNumber && bufferItem.mFrameNumber > maxFrameNumber) {
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break;
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// If dropping entry[0] would leave us with a buffer that the
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// consumer is not yet ready for, don't drop it.
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if (maxFrameNumber && bufferItem.mFrameNumber > maxFrameNumber) {
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break;
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}
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// If entry[1] is timely, drop entry[0] (and repeat). We apply an
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// additional criterion here: we only drop the earlier buffer if our
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// desiredPresent falls within +/- 1 second of the expected present.
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// Otherwise, bogus desiredPresent times (e.g., 0 or a small
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// relative timestamp), which normally mean "ignore the timestamp
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// and acquire immediately", would cause us to drop frames.
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//
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// We may want to add an additional criterion: don't drop the
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// earlier buffer if entry[1]'s fence hasn't signaled yet.
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nsecs_t desiredPresent = bufferItem.mTimestamp;
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if (desiredPresent < expectedPresent - MAX_REASONABLE_NSEC ||
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desiredPresent > expectedPresent) {
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// This buffer is set to display in the near future, or
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// desiredPresent is garbage. Either way we don't want to drop
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// the previous buffer just to get this on the screen sooner.
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BQ_LOGV("acquireBuffer: nodrop desire=%" PRId64 " expect=%"
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PRId64 " (%" PRId64 ") now=%" PRId64,
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desiredPresent, expectedPresent,
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desiredPresent - expectedPresent,
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systemTime(CLOCK_MONOTONIC));
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break;
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}
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BQ_LOGV("acquireBuffer: drop desire=%" PRId64 " expect=%" PRId64
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" size=%zu",
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desiredPresent, expectedPresent, mCore->mQueue.size());
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if (mCore->stillTracking(front)) {
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// Front buffer is still in mSlots, so mark the slot as free
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mSlots[front->mSlot].mBufferState = BufferSlot::FREE;
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mCore->mFreeBuffers.push_back(front->mSlot);
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listener = mCore->mConnectedProducerListener;
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++numDroppedBuffers;
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}
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mCore->mQueue.erase(front);
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front = mCore->mQueue.begin();
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}
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// If entry[1] is timely, drop entry[0] (and repeat). We apply an
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// additional criterion here: we only drop the earlier buffer if our
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// desiredPresent falls within +/- 1 second of the expected present.
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// Otherwise, bogus desiredPresent times (e.g., 0 or a small
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// relative timestamp), which normally mean "ignore the timestamp
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// and acquire immediately", would cause us to drop frames.
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//
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// We may want to add an additional criterion: don't drop the
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// earlier buffer if entry[1]'s fence hasn't signaled yet.
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nsecs_t desiredPresent = bufferItem.mTimestamp;
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if (desiredPresent < expectedPresent - MAX_REASONABLE_NSEC ||
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desiredPresent > expectedPresent) {
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// This buffer is set to display in the near future, or
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// desiredPresent is garbage. Either way we don't want to drop
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// the previous buffer just to get this on the screen sooner.
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BQ_LOGV("acquireBuffer: nodrop desire=%" PRId64 " expect=%"
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PRId64 " (%" PRId64 ") now=%" PRId64,
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// See if the front buffer is ready to be acquired
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nsecs_t desiredPresent = front->mTimestamp;
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bool bufferIsDue = desiredPresent <= expectedPresent ||
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desiredPresent > expectedPresent + MAX_REASONABLE_NSEC;
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bool consumerIsReady = maxFrameNumber > 0 ?
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front->mFrameNumber <= maxFrameNumber : true;
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if (!bufferIsDue || !consumerIsReady) {
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BQ_LOGV("acquireBuffer: defer desire=%" PRId64 " expect=%" PRId64
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" (%" PRId64 ") now=%" PRId64 " frame=%" PRIu64
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" consumer=%" PRIu64,
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desiredPresent, expectedPresent,
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desiredPresent - expectedPresent,
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systemTime(CLOCK_MONOTONIC));
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break;
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systemTime(CLOCK_MONOTONIC),
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front->mFrameNumber, maxFrameNumber);
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return PRESENT_LATER;
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}
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BQ_LOGV("acquireBuffer: drop desire=%" PRId64 " expect=%" PRId64
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" size=%zu",
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desiredPresent, expectedPresent, mCore->mQueue.size());
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if (mCore->stillTracking(front)) {
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// Front buffer is still in mSlots, so mark the slot as free
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mSlots[front->mSlot].mBufferState = BufferSlot::FREE;
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mCore->mFreeBuffers.push_back(front->mSlot);
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}
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mCore->mQueue.erase(front);
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front = mCore->mQueue.begin();
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}
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// See if the front buffer is ready to be acquired
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nsecs_t desiredPresent = front->mTimestamp;
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bool bufferIsDue = desiredPresent <= expectedPresent ||
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desiredPresent > expectedPresent + MAX_REASONABLE_NSEC;
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bool consumerIsReady = maxFrameNumber > 0 ?
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front->mFrameNumber <= maxFrameNumber : true;
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if (!bufferIsDue || !consumerIsReady) {
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BQ_LOGV("acquireBuffer: defer desire=%" PRId64 " expect=%" PRId64
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" (%" PRId64 ") now=%" PRId64 " frame=%" PRIu64
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" consumer=%" PRIu64,
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desiredPresent, expectedPresent,
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BQ_LOGV("acquireBuffer: accept desire=%" PRId64 " expect=%" PRId64 " "
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"(%" PRId64 ") now=%" PRId64, desiredPresent, expectedPresent,
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desiredPresent - expectedPresent,
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systemTime(CLOCK_MONOTONIC),
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front->mFrameNumber, maxFrameNumber);
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return PRESENT_LATER;
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systemTime(CLOCK_MONOTONIC));
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}
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BQ_LOGV("acquireBuffer: accept desire=%" PRId64 " expect=%" PRId64 " "
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"(%" PRId64 ") now=%" PRId64, desiredPresent, expectedPresent,
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desiredPresent - expectedPresent,
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systemTime(CLOCK_MONOTONIC));
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int slot = front->mSlot;
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*outBuffer = *front;
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ATRACE_BUFFER_INDEX(slot);
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BQ_LOGV("acquireBuffer: acquiring { slot=%d/%" PRIu64 " buffer=%p }",
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slot, front->mFrameNumber, front->mGraphicBuffer->handle);
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// If the front buffer is still being tracked, update its slot state
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if (mCore->stillTracking(front)) {
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mSlots[slot].mAcquireCalled = true;
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mSlots[slot].mNeedsCleanupOnRelease = false;
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mSlots[slot].mBufferState = BufferSlot::ACQUIRED;
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mSlots[slot].mFence = Fence::NO_FENCE;
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}
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// If the buffer has previously been acquired by the consumer, set
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// mGraphicBuffer to NULL to avoid unnecessarily remapping this buffer
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// on the consumer side
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if (outBuffer->mAcquireCalled) {
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outBuffer->mGraphicBuffer = NULL;
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}
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mCore->mQueue.erase(front);
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// We might have freed a slot while dropping old buffers, or the producer
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// may be blocked waiting for the number of buffers in the queue to
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// decrease.
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mCore->mDequeueCondition.broadcast();
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ATRACE_INT(mCore->mConsumerName.string(), mCore->mQueue.size());
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mCore->validateConsistencyLocked();
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}
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int slot = front->mSlot;
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*outBuffer = *front;
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ATRACE_BUFFER_INDEX(slot);
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BQ_LOGV("acquireBuffer: acquiring { slot=%d/%" PRIu64 " buffer=%p }",
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slot, front->mFrameNumber, front->mGraphicBuffer->handle);
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// If the front buffer is still being tracked, update its slot state
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if (mCore->stillTracking(front)) {
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mSlots[slot].mAcquireCalled = true;
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mSlots[slot].mNeedsCleanupOnRelease = false;
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mSlots[slot].mBufferState = BufferSlot::ACQUIRED;
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mSlots[slot].mFence = Fence::NO_FENCE;
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if (listener != NULL) {
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for (int i = 0; i < numDroppedBuffers; ++i) {
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listener->onBufferReleased();
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}
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}
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// If the buffer has previously been acquired by the consumer, set
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// mGraphicBuffer to NULL to avoid unnecessarily remapping this buffer
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// on the consumer side
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if (outBuffer->mAcquireCalled) {
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outBuffer->mGraphicBuffer = NULL;
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}
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mCore->mQueue.erase(front);
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// We might have freed a slot while dropping old buffers, or the producer
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// may be blocked waiting for the number of buffers in the queue to
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// decrease.
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mCore->mDequeueCondition.broadcast();
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ATRACE_INT(mCore->mConsumerName.string(), mCore->mQueue.size());
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mCore->validateConsistencyLocked();
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return NO_ERROR;
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}
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