/* * Copyright (C) 2009 The Android Open Source Project * * Licensed under the Apache License, Version 2.0 (the "License"); * you may not use this file except in compliance with the License. * You may obtain a copy of the License at * * http://www.apache.org/licenses/LICENSE-2.0 * * Unless required by applicable law or agreed to in writing, software * distributed under the License is distributed on an "AS IS" BASIS, * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. * See the License for the specific language governing permissions and * limitations under the License. */ #include //#define LOG_NDEBUG 0 #define LOG_TAG "CameraSource" #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #if LOG_NDEBUG #define UNUSED_UNLESS_VERBOSE(x) (void)(x) #else #define UNUSED_UNLESS_VERBOSE(x) #endif namespace android { static const int64_t CAMERA_SOURCE_TIMEOUT_NS = 3000000000LL; static int32_t getColorFormat(const char* colorFormat) { if (!colorFormat) { ALOGE("Invalid color format"); return -1; } if (!strcmp(colorFormat, CameraParameters::PIXEL_FORMAT_YUV420P)) { return OMX_COLOR_FormatYUV420Planar; } if (!strcmp(colorFormat, CameraParameters::PIXEL_FORMAT_YUV422SP)) { return OMX_COLOR_FormatYUV422SemiPlanar; } if (!strcmp(colorFormat, CameraParameters::PIXEL_FORMAT_YUV420SP)) { return OMX_COLOR_FormatYUV420SemiPlanar; } if (!strcmp(colorFormat, CameraParameters::PIXEL_FORMAT_YUV422I)) { return OMX_COLOR_FormatYCbYCr; } if (!strcmp(colorFormat, CameraParameters::PIXEL_FORMAT_RGB565)) { return OMX_COLOR_Format16bitRGB565; } if (!strcmp(colorFormat, "OMX_TI_COLOR_FormatYUV420PackedSemiPlanar")) { return OMX_TI_COLOR_FormatYUV420PackedSemiPlanar; } if (!strcmp(colorFormat, CameraParameters::PIXEL_FORMAT_ANDROID_OPAQUE)) { return OMX_COLOR_FormatAndroidOpaque; } ALOGE("Uknown color format (%s), please add it to " "CameraSource::getColorFormat", colorFormat); CHECK(!"Unknown color format"); return -1; } // static CameraSource *CameraSource::CreateFromCamera( const sp& camera, const sp& proxy, int32_t cameraId, const String16& clientName, uid_t clientUid, pid_t clientPid, Size videoSize, int32_t frameRate, const sp& surface) { CameraSource *source = new CameraSource(camera, proxy, cameraId, clientName, clientUid, clientPid, videoSize, frameRate, surface); return source; } CameraSource::CameraSource( const sp& camera, const sp& proxy, int32_t cameraId, const String16& clientName, uid_t clientUid, pid_t clientPid, Size videoSize, int32_t frameRate, const sp& surface) : mCameraFlags(0), mNumInputBuffers(0), mVideoFrameRate(-1), mCamera(0), mSurface(surface), mNumFramesReceived(0), mLastFrameTimestampUs(0), mStarted(false), mEos(false), mNumFramesEncoded(0), mTimeBetweenFrameCaptureUs(0), mFirstFrameTimeUs(0), mStopSystemTimeUs(-1), mNumFramesDropped(0), mNumGlitches(0), mGlitchDurationThresholdUs(200000), mCollectStats(false) { mVideoSize.width = -1; mVideoSize.height = -1; mInitCheck = init(camera, proxy, cameraId, clientName, clientUid, clientPid, videoSize, frameRate); if (mInitCheck != OK) releaseCamera(); } status_t CameraSource::initCheck() const { return mInitCheck; } status_t CameraSource::isCameraAvailable( const sp& camera, const sp& proxy, int32_t cameraId, const std::string& clientName, uid_t clientUid, pid_t clientPid) { if (camera == 0) { mCamera = Camera::connect(cameraId, clientName, clientUid, clientPid, /*targetSdkVersion*/__ANDROID_API_FUTURE__, /*rotationOverride*/hardware::ICameraService::ROTATION_OVERRIDE_NONE, /*forceSlowJpegMode*/false); if (mCamera == 0) return -EBUSY; mCameraFlags &= ~FLAGS_HOT_CAMERA; } else { // We get the proxy from Camera, not ICamera. We need to get the proxy // to the remote Camera owned by the application. Here mCamera is a // local Camera object created by us. We cannot use the proxy from // mCamera here. mCamera = Camera::create(camera); if (mCamera == 0) return -EBUSY; mCameraRecordingProxy = proxy; mCameraFlags |= FLAGS_HOT_CAMERA; mDeathNotifier = new DeathNotifier(); // isBinderAlive needs linkToDeath to work. IInterface::asBinder(mCameraRecordingProxy)->linkToDeath(mDeathNotifier); } mCamera->lock(); return OK; } /* * Check to see whether the requested video width and height is one * of the supported sizes. * @param width the video frame width in pixels * @param height the video frame height in pixels * @param suppportedSizes the vector of sizes that we check against * @return true if the dimension (width and height) is supported. */ static bool isVideoSizeSupported( int32_t width, int32_t height, const Vector& supportedSizes) { ALOGV("isVideoSizeSupported"); for (size_t i = 0; i < supportedSizes.size(); ++i) { if (width == supportedSizes[i].width && height == supportedSizes[i].height) { return true; } } return false; } /* * If the preview and video output is separate, we only set the * the video size, and applications should set the preview size * to some proper value, and the recording framework will not * change the preview size; otherwise, if the video and preview * output is the same, we need to set the preview to be the same * as the requested video size. * */ /* * Query the camera to retrieve the supported video frame sizes * and also to see whether CameraParameters::setVideoSize() * is supported or not. * @param params CameraParameters to retrieve the information * @@param isSetVideoSizeSupported retunrs whether method * CameraParameters::setVideoSize() is supported or not. * @param sizes returns the vector of Size objects for the * supported video frame sizes advertised by the camera. */ static void getSupportedVideoSizes( const CameraParameters& params, bool *isSetVideoSizeSupported, Vector& sizes) { *isSetVideoSizeSupported = true; params.getSupportedVideoSizes(sizes); if (sizes.size() == 0) { ALOGD("Camera does not support setVideoSize()"); params.getSupportedPreviewSizes(sizes); *isSetVideoSizeSupported = false; } } /* * Check whether the camera has the supported color format * @param params CameraParameters to retrieve the information * @return OK if no error. */ status_t CameraSource::isCameraColorFormatSupported( const CameraParameters& params) { mColorFormat = getColorFormat(params.get( CameraParameters::KEY_VIDEO_FRAME_FORMAT)); if (mColorFormat == -1) { return BAD_VALUE; } return OK; } /* * Configure the camera to use the requested video size * (width and height) and/or frame rate. If both width and * height are -1, configuration on the video size is skipped. * if frameRate is -1, configuration on the frame rate * is skipped. Skipping the configuration allows one to * use the current camera setting without the need to * actually know the specific values (see Create() method). * * @param params the CameraParameters to be configured * @param width the target video frame width in pixels * @param height the target video frame height in pixels * @param frameRate the target frame rate in frames per second. * @return OK if no error. */ status_t CameraSource::configureCamera( CameraParameters* params, int32_t width, int32_t height, int32_t frameRate) { ALOGV("configureCamera"); Vector sizes; bool isSetVideoSizeSupportedByCamera = true; getSupportedVideoSizes(*params, &isSetVideoSizeSupportedByCamera, sizes); bool isCameraParamChanged = false; if (width != -1 && height != -1) { if (!isVideoSizeSupported(width, height, sizes)) { ALOGE("Video dimension (%dx%d) is unsupported", width, height); return BAD_VALUE; } if (isSetVideoSizeSupportedByCamera) { params->setVideoSize(width, height); } else { params->setPreviewSize(width, height); } isCameraParamChanged = true; } else if ((width == -1 && height != -1) || (width != -1 && height == -1)) { // If one and only one of the width and height is -1 // we reject such a request. ALOGE("Requested video size (%dx%d) is not supported", width, height); return BAD_VALUE; } else { // width == -1 && height == -1 // Do not configure the camera. // Use the current width and height value setting from the camera. } if (frameRate != -1) { CHECK(frameRate > 0 && frameRate <= 120); const char* supportedFrameRates = params->get(CameraParameters::KEY_SUPPORTED_PREVIEW_FRAME_RATES); CHECK(supportedFrameRates != NULL); ALOGV("Supported frame rates: %s", supportedFrameRates); char buf[4]; snprintf(buf, 4, "%d", frameRate); if (strstr(supportedFrameRates, buf) == NULL) { ALOGE("Requested frame rate (%d) is not supported: %s", frameRate, supportedFrameRates); return BAD_VALUE; } // The frame rate is supported, set the camera to the requested value. params->setPreviewFrameRate(frameRate); isCameraParamChanged = true; } else { // frameRate == -1 // Do not configure the camera. // Use the current frame rate value setting from the camera } if (isCameraParamChanged) { // Either frame rate or frame size needs to be changed. String8 s = params->flatten(); if (OK != mCamera->setParameters(s)) { ALOGE("Could not change settings." " Someone else is using camera %p?", mCamera.get()); return -EBUSY; } } return OK; } /* * Check whether the requested video frame size * has been successfully configured or not. If both width and height * are -1, check on the current width and height value setting * is performed. * * @param params CameraParameters to retrieve the information * @param the target video frame width in pixels to check against * @param the target video frame height in pixels to check against * @return OK if no error */ status_t CameraSource::checkVideoSize( const CameraParameters& params, int32_t width, int32_t height) { ALOGV("checkVideoSize"); // The actual video size is the same as the preview size // if the camera hal does not support separate video and // preview output. In this case, we retrieve the video // size from preview. int32_t frameWidthActual = -1; int32_t frameHeightActual = -1; Vector sizes; params.getSupportedVideoSizes(sizes); if (sizes.size() == 0) { // video size is the same as preview size params.getPreviewSize(&frameWidthActual, &frameHeightActual); } else { // video size may not be the same as preview params.getVideoSize(&frameWidthActual, &frameHeightActual); } if (frameWidthActual < 0 || frameHeightActual < 0) { ALOGE("Failed to retrieve video frame size (%dx%d)", frameWidthActual, frameHeightActual); return UNKNOWN_ERROR; } // Check the actual video frame size against the target/requested // video frame size. if (width != -1 && height != -1) { if (frameWidthActual != width || frameHeightActual != height) { ALOGE("Failed to set video frame size to %dx%d. " "The actual video size is %dx%d ", width, height, frameWidthActual, frameHeightActual); return UNKNOWN_ERROR; } } // Good now. mVideoSize.width = frameWidthActual; mVideoSize.height = frameHeightActual; return OK; } /* * Check the requested frame rate has been successfully configured or not. * If the target frameRate is -1, check on the current frame rate value * setting is performed. * * @param params CameraParameters to retrieve the information * @param the target video frame rate to check against * @return OK if no error. */ status_t CameraSource::checkFrameRate( const CameraParameters& params, int32_t frameRate) { ALOGV("checkFrameRate"); int32_t frameRateActual = params.getPreviewFrameRate(); if (frameRateActual < 0) { ALOGE("Failed to retrieve preview frame rate (%d)", frameRateActual); return UNKNOWN_ERROR; } // Check the actual video frame rate against the target/requested // video frame rate. if (frameRate != -1 && (frameRateActual - frameRate) != 0) { ALOGE("Failed to set preview frame rate to %d fps. The actual " "frame rate is %d", frameRate, frameRateActual); return UNKNOWN_ERROR; } // Good now. mVideoFrameRate = frameRateActual; return OK; } /* * Initialize the CameraSource to so that it becomes * ready for providing the video input streams as requested. * @param camera the camera object used for the video source * @param cameraId if camera == 0, use camera with this id * as the video source * @param videoSize the target video frame size. If both * width and height in videoSize is -1, use the current * width and heigth settings by the camera * @param frameRate the target frame rate in frames per second. * if it is -1, use the current camera frame rate setting. * @param storeMetaDataInVideoBuffers request to store meta * data or real YUV data in video buffers. Request to * store meta data in video buffers may not be honored * if the source does not support this feature. * * @return OK if no error. */ status_t CameraSource::init( const sp& camera, const sp& proxy, int32_t cameraId, const String16& clientName, uid_t clientUid, pid_t clientPid, Size videoSize, int32_t frameRate) { ALOGV("init"); status_t err = OK; int64_t token = IPCThreadState::self()->clearCallingIdentity(); err = initWithCameraAccess(camera, proxy, cameraId, clientName, clientUid, clientPid, videoSize, frameRate); IPCThreadState::self()->restoreCallingIdentity(token); return err; } void CameraSource::createVideoBufferMemoryHeap(size_t size, uint32_t bufferCount) { mMemoryHeapBase = new MemoryHeapBase(size * bufferCount, 0, "StageFright-CameraSource-BufferHeap"); for (uint32_t i = 0; i < bufferCount; i++) { mMemoryBases.push_back(new MemoryBase(mMemoryHeapBase, i * size, size)); } } status_t CameraSource::initBufferQueue(uint32_t width, uint32_t height, uint32_t format, android_dataspace dataSpace, uint32_t bufferCount) { ALOGV("initBufferQueue"); if (mVideoBufferConsumer != nullptr || mVideoBufferProducer != nullptr) { ALOGE("%s: Buffer queue already exists", __FUNCTION__); return ALREADY_EXISTS; } // Create a buffer queue. sp producer; sp consumer; BufferQueue::createBufferQueue(&producer, &consumer); uint32_t usage = GRALLOC_USAGE_SW_READ_OFTEN; if (format == HAL_PIXEL_FORMAT_IMPLEMENTATION_DEFINED) { usage = GRALLOC_USAGE_HW_VIDEO_ENCODER; } bufferCount += kConsumerBufferCount; mVideoBufferConsumer = new BufferItemConsumer(consumer, usage, bufferCount); mVideoBufferConsumer->setName(String8::format("StageFright-CameraSource")); mVideoBufferProducer = producer; status_t res = mVideoBufferConsumer->setDefaultBufferSize(width, height); if (res != OK) { ALOGE("%s: Could not set buffer dimensions %dx%d: %s (%d)", __FUNCTION__, width, height, strerror(-res), res); return res; } res = mVideoBufferConsumer->setDefaultBufferFormat(format); if (res != OK) { ALOGE("%s: Could not set buffer format %d: %s (%d)", __FUNCTION__, format, strerror(-res), res); return res; } res = mVideoBufferConsumer->setDefaultBufferDataSpace(dataSpace); if (res != OK) { ALOGE("%s: Could not set data space %d: %s (%d)", __FUNCTION__, dataSpace, strerror(-res), res); return res; } res = mCamera->setVideoTarget(mVideoBufferProducer); if (res != OK) { ALOGE("%s: Failed to set video target: %s (%d)", __FUNCTION__, strerror(-res), res); return res; } // Create memory heap to store buffers as VideoNativeMetadata. createVideoBufferMemoryHeap(sizeof(VideoNativeMetadata), bufferCount); mBufferQueueListener = new BufferQueueListener(mVideoBufferConsumer, this); res = mBufferQueueListener->run("CameraSource-BufferQueueListener"); if (res != OK) { ALOGE("%s: Could not run buffer queue listener thread: %s (%d)", __FUNCTION__, strerror(-res), res); return res; } return OK; } status_t CameraSource::initWithCameraAccess( const sp& camera, const sp& proxy, int32_t cameraId, const String16& clientName, uid_t clientUid, pid_t clientPid, Size videoSize, int32_t frameRate) { ALOGV("initWithCameraAccess"); status_t err = OK; if ((err = isCameraAvailable(camera, proxy, cameraId, toStdString(clientName), clientUid, clientPid)) != OK) { ALOGE("Camera connection could not be established."); return err; } CameraParameters params(mCamera->getParameters()); if ((err = isCameraColorFormatSupported(params)) != OK) { return err; } // Set the camera to use the requested video frame size // and/or frame rate. if ((err = configureCamera(¶ms, videoSize.width, videoSize.height, frameRate))) { return err; } // Check on video frame size and frame rate. CameraParameters newCameraParams(mCamera->getParameters()); if ((err = checkVideoSize(newCameraParams, videoSize.width, videoSize.height)) != OK) { return err; } if ((err = checkFrameRate(newCameraParams, frameRate)) != OK) { return err; } // Set the preview display. Skip this if mSurface is null because // applications may already set a surface to the camera. if (mSurface != NULL) { // Surface may be set incorrectly or could already be used even if we just // passed the lock/unlock check earlier by calling mCamera->setParameters(). if ((err = mCamera->setPreviewTarget(mSurface)) != OK) { return err; } } // Use buffer queue to receive video buffers from camera err = mCamera->setVideoBufferMode(hardware::ICamera::VIDEO_BUFFER_MODE_BUFFER_QUEUE); if (err != OK) { ALOGE("%s: Setting video buffer mode to VIDEO_BUFFER_MODE_BUFFER_QUEUE failed: " "%s (err=%d)", __FUNCTION__, strerror(-err), err); return err; } int64_t glitchDurationUs = (1000000LL / mVideoFrameRate); if (glitchDurationUs > mGlitchDurationThresholdUs) { mGlitchDurationThresholdUs = glitchDurationUs; } // XXX: query camera for the stride and slice height // when the capability becomes available. mMeta = new MetaData; mMeta->setCString(kKeyMIMEType, MEDIA_MIMETYPE_VIDEO_RAW); mMeta->setInt32(kKeyColorFormat, mColorFormat); mMeta->setInt32(kKeyWidth, mVideoSize.width); mMeta->setInt32(kKeyHeight, mVideoSize.height); mMeta->setInt32(kKeyStride, mVideoSize.width); mMeta->setInt32(kKeySliceHeight, mVideoSize.height); mMeta->setInt32(kKeyFrameRate, mVideoFrameRate); return OK; } CameraSource::~CameraSource() { if (mStarted) { reset(); } else if (mInitCheck == OK) { // Camera is initialized but because start() is never called, // the lock on Camera is never released(). This makes sure // Camera's lock is released in this case. releaseCamera(); } } status_t CameraSource::startCameraRecording() { ALOGV("startCameraRecording"); // Reset the identity to the current thread because media server owns the // camera and recording is started by the applications. The applications // will connect to the camera in ICameraRecordingProxy::startRecording. int64_t token = IPCThreadState::self()->clearCallingIdentity(); status_t err; // Initialize buffer queue. err = initBufferQueue(mVideoSize.width, mVideoSize.height, mEncoderFormat, (android_dataspace_t)mEncoderDataSpace, mNumInputBuffers > 0 ? mNumInputBuffers : 1); if (err != OK) { ALOGE("%s: Failed to initialize buffer queue: %s (err=%d)", __FUNCTION__, strerror(-err), err); return err; } // Start data flow err = OK; if (mCameraFlags & FLAGS_HOT_CAMERA) { mCamera->unlock(); mCamera.clear(); if ((err = mCameraRecordingProxy->startRecording()) != OK) { ALOGE("Failed to start recording, received error: %s (%d)", strerror(-err), err); } } else { mCamera->startRecording(); if (!mCamera->recordingEnabled()) { err = -EINVAL; ALOGE("Failed to start recording"); } } IPCThreadState::self()->restoreCallingIdentity(token); return err; } status_t CameraSource::start(MetaData *meta) { ALOGV("start"); CHECK(!mStarted); if (mInitCheck != OK) { ALOGE("CameraSource is not initialized yet"); return mInitCheck; } if (property_get_bool("media.stagefright.record-stats", false)) { mCollectStats = true; } mStartTimeUs = 0; mNumInputBuffers = 0; mEncoderFormat = HAL_PIXEL_FORMAT_IMPLEMENTATION_DEFINED; mEncoderDataSpace = mBufferDataSpace = HAL_DATASPACE_V0_BT709; if (meta) { int64_t startTimeUs; if (meta->findInt64(kKeyTime, &startTimeUs)) { mStartTimeUs = startTimeUs; } int32_t nBuffers; if (meta->findInt32(kKeyNumBuffers, &nBuffers)) { CHECK_GT(nBuffers, 0); mNumInputBuffers = nBuffers; } // apply encoder color format if specified if (meta->findInt32(kKeyPixelFormat, &mEncoderFormat)) { ALOGI("Using encoder format: %#x", mEncoderFormat); } if (meta->findInt32(kKeyColorSpace, &mEncoderDataSpace)) { ALOGI("Using encoder data space: %#x", mEncoderDataSpace); mBufferDataSpace = mEncoderDataSpace; } } status_t err; if ((err = startCameraRecording()) == OK) { mStarted = true; } return err; } void CameraSource::stopCameraRecording() { ALOGV("stopCameraRecording"); if (mCameraFlags & FLAGS_HOT_CAMERA) { if (mCameraRecordingProxy != 0) { mCameraRecordingProxy->stopRecording(); } } else { if (mCamera != 0) { mCamera->stopRecording(); } } } void CameraSource::releaseCamera() { ALOGV("releaseCamera"); sp camera; bool coldCamera = false; { Mutex::Autolock autoLock(mLock); // get a local ref and clear ref to mCamera now camera = mCamera; mCamera.clear(); coldCamera = (mCameraFlags & FLAGS_HOT_CAMERA) == 0; } if (camera != 0) { int64_t token = IPCThreadState::self()->clearCallingIdentity(); if (coldCamera) { ALOGV("Camera was cold when we started, stopping preview"); camera->stopPreview(); camera->disconnect(); } camera->unlock(); IPCThreadState::self()->restoreCallingIdentity(token); } { Mutex::Autolock autoLock(mLock); if (mCameraRecordingProxy != 0) { IInterface::asBinder(mCameraRecordingProxy)->unlinkToDeath(mDeathNotifier); mCameraRecordingProxy.clear(); } mCameraFlags = 0; } } status_t CameraSource::reset() { ALOGD("reset: E"); { Mutex::Autolock autoLock(mLock); mStarted = false; mEos = false; mStopSystemTimeUs = -1; mFrameAvailableCondition.signal(); int64_t token; bool isTokenValid = false; if (mCamera != 0) { token = IPCThreadState::self()->clearCallingIdentity(); isTokenValid = true; } releaseQueuedFrames(); while (!mFramesBeingEncoded.empty()) { if (NO_ERROR != mFrameCompleteCondition.waitRelative(mLock, mTimeBetweenFrameCaptureUs * 1000LL + CAMERA_SOURCE_TIMEOUT_NS)) { ALOGW("Timed out waiting for outstanding frames being encoded: %zu", mFramesBeingEncoded.size()); } } stopCameraRecording(); if (isTokenValid) { IPCThreadState::self()->restoreCallingIdentity(token); } if (mCollectStats) { ALOGI("Frames received/encoded/dropped: %d/%d/%d in %" PRId64 " us", mNumFramesReceived, mNumFramesEncoded, mNumFramesDropped, mLastFrameTimestampUs - mFirstFrameTimeUs); } if (mNumGlitches > 0) { ALOGW("%d long delays between neighboring video frames", mNumGlitches); } CHECK_EQ(mNumFramesReceived, mNumFramesEncoded + mNumFramesDropped); } if (mBufferQueueListener != nullptr) { mBufferQueueListener->requestExit(); mBufferQueueListener->join(); mBufferQueueListener.clear(); } mVideoBufferConsumer.clear(); mVideoBufferProducer.clear(); releaseCamera(); ALOGD("reset: X"); return OK; } void CameraSource::releaseRecordingFrame(const sp& frame) { ALOGV("releaseRecordingFrame"); // Return the buffer to buffer queue in VIDEO_BUFFER_MODE_BUFFER_QUEUE mode. ssize_t offset; size_t size; sp heap = frame->getMemory(&offset, &size); if (heap->getHeapID() != mMemoryHeapBase->getHeapID()) { ALOGE("%s: Mismatched heap ID, ignoring release (got %x, expected %x)", __FUNCTION__, heap->getHeapID(), mMemoryHeapBase->getHeapID()); return; } VideoNativeMetadata *payload = reinterpret_cast( (uint8_t*)heap->getBase() + offset); // Find the corresponding buffer item for the native window buffer. ssize_t index = mReceivedBufferItemMap.indexOfKey(payload->pBuffer); if (index == NAME_NOT_FOUND) { ALOGE("%s: Couldn't find buffer item for %p", __FUNCTION__, payload->pBuffer); return; } BufferItem buffer = mReceivedBufferItemMap.valueAt(index); mReceivedBufferItemMap.removeItemsAt(index); mVideoBufferConsumer->releaseBuffer(buffer); mMemoryBases.push_back(frame); mMemoryBaseAvailableCond.signal(); } void CameraSource::releaseQueuedFrames() { List >::iterator it; while (!mFramesReceived.empty()) { it = mFramesReceived.begin(); releaseRecordingFrame(*it); mFramesReceived.erase(it); ++mNumFramesDropped; } } sp CameraSource::getFormat() { return mMeta; } void CameraSource::releaseOneRecordingFrame(const sp& frame) { releaseRecordingFrame(frame); } void CameraSource::signalBufferReturned(MediaBufferBase *buffer) { ALOGV("signalBufferReturned: %p", buffer->data()); Mutex::Autolock autoLock(mLock); for (List >::iterator it = mFramesBeingEncoded.begin(); it != mFramesBeingEncoded.end(); ++it) { if ((*it)->unsecurePointer() == buffer->data()) { releaseOneRecordingFrame((*it)); mFramesBeingEncoded.erase(it); ++mNumFramesEncoded; buffer->setObserver(0); buffer->release(); mFrameCompleteCondition.signal(); return; } } CHECK(!"signalBufferReturned: bogus buffer"); } status_t CameraSource::read( MediaBufferBase **buffer, const ReadOptions *options) { ALOGV("read"); *buffer = NULL; int64_t seekTimeUs; ReadOptions::SeekMode mode; if (options && options->getSeekTo(&seekTimeUs, &mode)) { return ERROR_UNSUPPORTED; } sp frame; int64_t frameTime; { Mutex::Autolock autoLock(mLock); while (mStarted && !mEos && mFramesReceived.empty()) { if (NO_ERROR != mFrameAvailableCondition.waitRelative(mLock, mTimeBetweenFrameCaptureUs * 1000LL + CAMERA_SOURCE_TIMEOUT_NS)) { if (mCameraRecordingProxy != 0 && !IInterface::asBinder(mCameraRecordingProxy)->isBinderAlive()) { ALOGW("camera recording proxy is gone"); return ERROR_END_OF_STREAM; } ALOGW("Timed out waiting for incoming camera video frames: %" PRId64 " us", mLastFrameTimestampUs); } } if (!mStarted) { return OK; } if (mFramesReceived.empty()) { return ERROR_END_OF_STREAM; } frame = *mFramesReceived.begin(); mFramesReceived.erase(mFramesReceived.begin()); frameTime = *mFrameTimes.begin(); mFrameTimes.erase(mFrameTimes.begin()); mFramesBeingEncoded.push_back(frame); // TODO: Using unsecurePointer() has some associated security pitfalls // (see declaration for details). // Either document why it is safe in this case or address the // issue (e.g. by copying). *buffer = new MediaBuffer(frame->unsecurePointer(), frame->size()); (*buffer)->setObserver(this); (*buffer)->add_ref(); (*buffer)->meta_data().setInt64(kKeyTime, frameTime); if (mBufferDataSpace != mEncoderDataSpace) { ALOGD("Data space updated to %x", mBufferDataSpace); (*buffer)->meta_data().setInt32(kKeyColorSpace, mBufferDataSpace); mEncoderDataSpace = mBufferDataSpace; } } return OK; } status_t CameraSource::setStopTimeUs(int64_t stopTimeUs) { Mutex::Autolock autoLock(mLock); ALOGV("Set stoptime: %lld us", (long long)stopTimeUs); if (stopTimeUs < -1) { ALOGE("Invalid stop time %lld us", (long long)stopTimeUs); return BAD_VALUE; } else if (stopTimeUs == -1) { ALOGI("reset stopTime to be -1"); } mStopSystemTimeUs = stopTimeUs; return OK; } bool CameraSource::shouldSkipFrameLocked(int64_t timestampUs) { if (!mStarted || (mNumFramesReceived == 0 && timestampUs < mStartTimeUs)) { ALOGV("Drop frame at %lld/%lld us", (long long)timestampUs, (long long)mStartTimeUs); return true; } if (mStopSystemTimeUs != -1 && timestampUs >= mStopSystemTimeUs) { ALOGV("Drop Camera frame at %lld stop time: %lld us", (long long)timestampUs, (long long)mStopSystemTimeUs); mEos = true; mFrameAvailableCondition.signal(); return true; } // May need to skip frame or modify timestamp. Currently implemented // by the subclass CameraSourceTimeLapse. if (skipCurrentFrame(timestampUs)) { return true; } if (mNumFramesReceived > 0) { if (timestampUs <= mLastFrameTimestampUs) { ALOGW("Dropping frame with backward timestamp %lld (last %lld)", (long long)timestampUs, (long long)mLastFrameTimestampUs); return true; } if (timestampUs - mLastFrameTimestampUs > mGlitchDurationThresholdUs) { ++mNumGlitches; } } mLastFrameTimestampUs = timestampUs; if (mNumFramesReceived == 0) { mFirstFrameTimeUs = timestampUs; // Initial delay if (mStartTimeUs > 0) { if (timestampUs < mStartTimeUs) { // Frame was captured before recording was started // Drop it without updating the statistical data. return true; } mStartTimeUs = timestampUs - mStartTimeUs; } } return false; } CameraSource::BufferQueueListener::BufferQueueListener(const sp& consumer, const sp& cameraSource) { mConsumer = consumer; mConsumer->setFrameAvailableListener(this); mCameraSource = cameraSource; } void CameraSource::BufferQueueListener::onFrameAvailable(const BufferItem& /*item*/) { ALOGV("%s: onFrameAvailable", __FUNCTION__); Mutex::Autolock l(mLock); if (!mFrameAvailable) { mFrameAvailable = true; mFrameAvailableSignal.signal(); } } bool CameraSource::BufferQueueListener::threadLoop() { if (mConsumer == nullptr || mCameraSource == nullptr) { return false; } { Mutex::Autolock l(mLock); while (!mFrameAvailable) { if (mFrameAvailableSignal.waitRelative(mLock, kFrameAvailableTimeout) == TIMED_OUT) { return true; } } mFrameAvailable = false; } BufferItem buffer; while (mConsumer->acquireBuffer(&buffer, 0) == OK) { mCameraSource->processBufferQueueFrame(buffer); } return true; } void CameraSource::processBufferQueueFrame(BufferItem& buffer) { Mutex::Autolock autoLock(mLock); int64_t timestampUs = buffer.mTimestamp / 1000; if (shouldSkipFrameLocked(timestampUs)) { mVideoBufferConsumer->releaseBuffer(buffer); return; } while (mMemoryBases.empty()) { if (mMemoryBaseAvailableCond.waitRelative(mLock, kMemoryBaseAvailableTimeoutNs) == TIMED_OUT) { ALOGW("Waiting on an available memory base timed out. Dropping a recording frame."); mVideoBufferConsumer->releaseBuffer(buffer); return; } } ++mNumFramesReceived; // Find a available memory slot to store the buffer as VideoNativeMetadata. sp data = *mMemoryBases.begin(); mMemoryBases.erase(mMemoryBases.begin()); mBufferDataSpace = buffer.mDataSpace; ssize_t offset; size_t size; sp heap = data->getMemory(&offset, &size); VideoNativeMetadata *payload = reinterpret_cast( (uint8_t*)heap->getBase() + offset); memset(payload, 0, sizeof(VideoNativeMetadata)); payload->eType = kMetadataBufferTypeANWBuffer; payload->pBuffer = buffer.mGraphicBuffer->getNativeBuffer(); payload->nFenceFd = -1; // Add the mapping so we can find the corresponding buffer item to release to the buffer queue // when the encoder returns the native window buffer. mReceivedBufferItemMap.add(payload->pBuffer, buffer); mFramesReceived.push_back(data); int64_t timeUs = mStartTimeUs + (timestampUs - mFirstFrameTimeUs); mFrameTimes.push_back(timeUs); ALOGV("initial delay: %" PRId64 ", current time stamp: %" PRId64, mStartTimeUs, timeUs); mFrameAvailableCondition.signal(); } MetadataBufferType CameraSource::metaDataStoredInVideoBuffers() const { ALOGV("metaDataStoredInVideoBuffers"); return kMetadataBufferTypeANWBuffer; } void CameraSource::DeathNotifier::binderDied(const wp& who __unused) { ALOGI("Camera recording proxy died"); } } // namespace android