/* * Copyright (C) 2017 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. */ #define LOG_TAG "CamDev@1.0-impl" #include #include #include #include #include #include // For VideoNativeHandleMetadata #include "CameraDevice_1_0.h" namespace android { namespace hardware { namespace camera { namespace device { namespace V1_0 { namespace implementation { using ::android::hardware::graphics::common::V1_0::BufferUsage; using ::android::hardware::graphics::common::V1_0::PixelFormat; HandleImporter CameraDevice::sHandleImporter; Status CameraDevice::getHidlStatus(const int& status) { switch (status) { case 0: return Status::OK; case -ENOSYS: return Status::OPERATION_NOT_SUPPORTED; case -EBUSY : return Status::CAMERA_IN_USE; case -EUSERS: return Status::MAX_CAMERAS_IN_USE; case -ENODEV: return Status::INTERNAL_ERROR; case -EINVAL: return Status::ILLEGAL_ARGUMENT; default: ALOGE("%s: unknown HAL status code %d", __FUNCTION__, status); return Status::INTERNAL_ERROR; } } status_t CameraDevice::getStatusT(const Status& s) { switch(s) { case Status::OK: return OK; case Status::ILLEGAL_ARGUMENT: return BAD_VALUE; case Status::CAMERA_IN_USE: return -EBUSY; case Status::MAX_CAMERAS_IN_USE: return -EUSERS; case Status::METHOD_NOT_SUPPORTED: return UNKNOWN_TRANSACTION; case Status::OPERATION_NOT_SUPPORTED: return INVALID_OPERATION; case Status::CAMERA_DISCONNECTED: return DEAD_OBJECT; case Status::INTERNAL_ERROR: return INVALID_OPERATION; } ALOGW("Unexpected HAL status code %d", s); return INVALID_OPERATION; } Status CameraDevice::initStatus() const { Mutex::Autolock _l(mLock); Status status = Status::OK; if (mInitFail) { status = Status::INTERNAL_ERROR; } else if (mDisconnected) { status = Status::CAMERA_DISCONNECTED; } return status; } CameraDevice::CameraDevice( sp module, const std::string& cameraId, const SortedVector>& cameraDeviceNames) : mModule(module), mCameraId(cameraId), mDisconnected(false), mCameraDeviceNames(cameraDeviceNames) { mCameraIdInt = atoi(mCameraId.c_str()); // Should not reach here as provider also validate ID if (mCameraIdInt < 0 || mCameraIdInt >= module->getNumberOfCameras()) { ALOGE("%s: Invalid camera id: %s", __FUNCTION__, mCameraId.c_str()); mInitFail = true; } mDeviceVersion = mModule->getDeviceVersion(mCameraIdInt); if (mDeviceVersion != CAMERA_DEVICE_API_VERSION_1_0 && !mModule->isOpenLegacyDefined()) { ALOGI("%s: Camera id %s does not support HAL1.0", __FUNCTION__, mCameraId.c_str()); mInitFail = true; } mAshmemAllocator = IAllocator::getService("ashmem"); if (mAshmemAllocator == nullptr) { ALOGI("%s: cannot get ashmemAllocator", __FUNCTION__); mInitFail = true; } } CameraDevice::~CameraDevice() { Mutex::Autolock _l(mLock); if (mDevice != nullptr) { ALOGW("%s: camera %s is deleted while open", __FUNCTION__, mCameraId.c_str()); closeLocked(); } mHalPreviewWindow.cleanUpCirculatingBuffers(); } void CameraDevice::setConnectionStatus(bool connected) { Mutex::Autolock _l(mLock); mDisconnected = !connected; if (mDevice == nullptr) { return; } if (!connected) { ALOGW("%s: camera %s is disconneted. Closing", __FUNCTION__, mCameraId.c_str()); closeLocked(); } return; } void CameraDevice::CameraPreviewWindow::cleanUpCirculatingBuffers() { Mutex::Autolock _l(mLock); for (auto pair : mCirculatingBuffers) { sHandleImporter.freeBuffer(pair.second); } mCirculatingBuffers.clear(); mBufferIdMap.clear(); } int CameraDevice::sDequeueBuffer(struct preview_stream_ops* w, buffer_handle_t** buffer, int *stride) { CameraPreviewWindow* object = static_cast(w); if (object->mPreviewCallback == nullptr) { ALOGE("%s: camera HAL calling preview ops while there is no preview window!", __FUNCTION__); return INVALID_OPERATION; } if (buffer == nullptr || stride == nullptr) { ALOGE("%s: buffer (%p) and stride (%p) must not be null!", __FUNCTION__, buffer, stride); return BAD_VALUE; } Status s; object->mPreviewCallback->dequeueBuffer( [&](auto status, uint64_t bufferId, const auto& buf, uint32_t strd) { s = status; if (s == Status::OK) { Mutex::Autolock _l(object->mLock); if (object->mCirculatingBuffers.count(bufferId) == 0) { buffer_handle_t importedBuf = buf.getNativeHandle(); sHandleImporter.importBuffer(importedBuf); if (importedBuf == nullptr) { ALOGE("%s: preview buffer import failed!", __FUNCTION__); s = Status::INTERNAL_ERROR; return; } else { object->mCirculatingBuffers[bufferId] = importedBuf; object->mBufferIdMap[&(object->mCirculatingBuffers[bufferId])] = bufferId; } } *buffer = &(object->mCirculatingBuffers[bufferId]); *stride = strd; } }); return getStatusT(s); } int CameraDevice::sLockBuffer(struct preview_stream_ops*, buffer_handle_t*) { return 0; } int CameraDevice::sEnqueueBuffer(struct preview_stream_ops* w, buffer_handle_t* buffer) { CameraPreviewWindow* object = static_cast(w); if (object->mPreviewCallback == nullptr) { ALOGE("%s: camera HAL calling preview ops while there is no preview window!", __FUNCTION__); return INVALID_OPERATION; } uint64_t bufferId = object->mBufferIdMap.at(buffer); return getStatusT(object->mPreviewCallback->enqueueBuffer(bufferId)); } int CameraDevice::sCancelBuffer(struct preview_stream_ops* w, buffer_handle_t* buffer) { CameraPreviewWindow* object = static_cast(w); if (object->mPreviewCallback == nullptr) { ALOGE("%s: camera HAL calling preview ops while there is no preview window!", __FUNCTION__); return INVALID_OPERATION; } uint64_t bufferId = object->mBufferIdMap.at(buffer); return getStatusT(object->mPreviewCallback->cancelBuffer(bufferId)); } int CameraDevice::sSetBufferCount(struct preview_stream_ops* w, int count) { CameraPreviewWindow* object = static_cast(w); if (object->mPreviewCallback == nullptr) { ALOGE("%s: camera HAL calling preview ops while there is no preview window!", __FUNCTION__); return INVALID_OPERATION; } object->cleanUpCirculatingBuffers(); return getStatusT(object->mPreviewCallback->setBufferCount(count)); } int CameraDevice::sSetBuffersGeometry(struct preview_stream_ops* w, int width, int height, int format) { CameraPreviewWindow* object = static_cast(w); if (object->mPreviewCallback == nullptr) { ALOGE("%s: camera HAL calling preview ops while there is no preview window!", __FUNCTION__); return INVALID_OPERATION; } object->cleanUpCirculatingBuffers(); return getStatusT( object->mPreviewCallback->setBuffersGeometry(width, height, (PixelFormat) format)); } int CameraDevice::sSetCrop(struct preview_stream_ops *w, int left, int top, int right, int bottom) { CameraPreviewWindow* object = static_cast(w); if (object->mPreviewCallback == nullptr) { ALOGE("%s: camera HAL calling preview ops while there is no preview window!", __FUNCTION__); return INVALID_OPERATION; } return getStatusT(object->mPreviewCallback->setCrop(left, top, right, bottom)); } int CameraDevice::sSetTimestamp(struct preview_stream_ops *w, int64_t timestamp) { CameraPreviewWindow* object = static_cast(w); if (object->mPreviewCallback == nullptr) { ALOGE("%s: camera HAL calling preview ops while there is no preview window!", __FUNCTION__); return INVALID_OPERATION; } return getStatusT(object->mPreviewCallback->setTimestamp(timestamp)); } int CameraDevice::sSetUsage(struct preview_stream_ops* w, int usage) { CameraPreviewWindow* object = static_cast(w); if (object->mPreviewCallback == nullptr) { ALOGE("%s: camera HAL calling preview ops while there is no preview window!", __FUNCTION__); return INVALID_OPERATION; } object->cleanUpCirculatingBuffers(); return getStatusT(object->mPreviewCallback->setUsage((BufferUsage)usage)); } int CameraDevice::sSetSwapInterval(struct preview_stream_ops *w, int interval) { CameraPreviewWindow* object = static_cast(w); if (object->mPreviewCallback == nullptr) { ALOGE("%s: camera HAL calling preview ops while there is no preview window!", __FUNCTION__); return INVALID_OPERATION; } return getStatusT(object->mPreviewCallback->setSwapInterval(interval)); } int CameraDevice::sGetMinUndequeuedBufferCount( const struct preview_stream_ops *w, int *count) { const CameraPreviewWindow* object = static_cast(w); if (object->mPreviewCallback == nullptr) { ALOGE("%s: camera HAL calling preview ops while there is no preview window!", __FUNCTION__); return INVALID_OPERATION; } if (count == nullptr) { ALOGE("%s: count is null!", __FUNCTION__); return BAD_VALUE; } Status s; object->mPreviewCallback->getMinUndequeuedBufferCount( [&](auto status, uint32_t cnt) { s = status; if (s == Status::OK) { *count = cnt; } }); return getStatusT(s); } CameraDevice::CameraHeapMemory::CameraHeapMemory( int fd, size_t buf_size, uint_t num_buffers) : mBufSize(buf_size), mNumBufs(num_buffers) { mHidlHandle = native_handle_create(1,0); mHidlHandle->data[0] = fcntl(fd, F_DUPFD_CLOEXEC, 0); const size_t pagesize = getpagesize(); size_t size = ((buf_size * num_buffers + pagesize-1) & ~(pagesize-1)); mHidlHeap = hidl_memory("ashmem", mHidlHandle, size); commonInitialization(); } CameraDevice::CameraHeapMemory::CameraHeapMemory( sp ashmemAllocator, size_t buf_size, uint_t num_buffers) : mBufSize(buf_size), mNumBufs(num_buffers) { const size_t pagesize = getpagesize(); size_t size = ((buf_size * num_buffers + pagesize-1) & ~(pagesize-1)); ashmemAllocator->allocate(size, [&](bool success, const hidl_memory& mem) { if (!success) { ALOGE("%s: allocating ashmem of %zu bytes failed!", __FUNCTION__, buf_size * num_buffers); return; } mHidlHandle = native_handle_clone(mem.handle()); mHidlHeap = hidl_memory("ashmem", mHidlHandle, size); }); commonInitialization(); } void CameraDevice::CameraHeapMemory::commonInitialization() { mHidlHeapMemory = mapMemory(mHidlHeap); if (mHidlHeapMemory == nullptr) { ALOGE("%s: memory map failed!", __FUNCTION__); native_handle_close(mHidlHandle); // close FD for the shared memory native_handle_delete(mHidlHandle); mHidlHeap = hidl_memory(); mHidlHandle = nullptr; return; } mHidlHeapMemData = mHidlHeapMemory->getPointer(); handle.data = mHidlHeapMemData; handle.size = mBufSize * mNumBufs; handle.handle = this; handle.release = sPutMemory; } CameraDevice::CameraHeapMemory::~CameraHeapMemory() { if (mHidlHeapMemory != nullptr) { mHidlHeapMemData = nullptr; mHidlHeapMemory.clear(); // The destructor will trigger munmap } if (mHidlHandle) { native_handle_close(mHidlHandle); // close FD for the shared memory native_handle_delete(mHidlHandle); } } // shared memory methods camera_memory_t* CameraDevice::sGetMemory(int fd, size_t buf_size, uint_t num_bufs, void *user) { ALOGV("%s", __FUNCTION__); CameraDevice* object = static_cast(user); if (object->mDeviceCallback == nullptr) { ALOGE("%s: camera HAL request memory while camera is not opened!", __FUNCTION__); return nullptr; } CameraHeapMemory* mem; if (fd < 0) { mem = new CameraHeapMemory(object->mAshmemAllocator, buf_size, num_bufs); } else { mem = new CameraHeapMemory(fd, buf_size, num_bufs); } mem->incStrong(mem); hidl_handle hidlHandle = mem->mHidlHandle; MemoryId id = object->mDeviceCallback->registerMemory(hidlHandle, buf_size, num_bufs); mem->handle.mId = id; { Mutex::Autolock _l(object->mMemoryMapLock); if (object->mMemoryMap.count(id) != 0) { ALOGE("%s: duplicate MemoryId %d returned by client!", __FUNCTION__, id); } object->mMemoryMap[id] = mem; } mem->handle.mDevice = object; return &mem->handle; } void CameraDevice::sPutMemory(camera_memory_t *data) { if (!data) return; CameraHeapMemory* mem = static_cast(data->handle); CameraDevice* device = mem->handle.mDevice; if (device == nullptr) { ALOGE("%s: camera HAL return memory for a null device!", __FUNCTION__); } if (device->mDeviceCallback == nullptr) { ALOGE("%s: camera HAL return memory while camera is not opened!", __FUNCTION__); } device->mDeviceCallback->unregisterMemory(mem->handle.mId); { Mutex::Autolock _l(device->mMemoryMapLock); device->mMemoryMap.erase(mem->handle.mId); } mem->decStrong(mem); } // Callback forwarding methods void CameraDevice::sNotifyCb(int32_t msg_type, int32_t ext1, int32_t ext2, void *user) { ALOGV("%s", __FUNCTION__); CameraDevice* object = static_cast(user); if (object->mDeviceCallback != nullptr) { object->mDeviceCallback->notifyCallback((NotifyCallbackMsg) msg_type, ext1, ext2); } } void CameraDevice::sDataCb(int32_t msg_type, const camera_memory_t *data, unsigned int index, camera_frame_metadata_t *metadata, void *user) { ALOGV("%s", __FUNCTION__); CameraDevice* object = static_cast(user); sp mem(static_cast(data->handle)); if (index >= mem->mNumBufs) { ALOGE("%s: invalid buffer index %d, max allowed is %d", __FUNCTION__, index, mem->mNumBufs); return; } if (object->mDeviceCallback != nullptr) { CameraFrameMetadata hidlMetadata; if (metadata) { hidlMetadata.faces.resize(metadata->number_of_faces); for (size_t i = 0; i < hidlMetadata.faces.size(); i++) { hidlMetadata.faces[i].score = metadata->faces[i].score; hidlMetadata.faces[i].id = metadata->faces[i].id; for (int k = 0; k < 4; k++) { hidlMetadata.faces[i].rect[k] = metadata->faces[i].rect[k]; } for (int k = 0; k < 2; k++) { hidlMetadata.faces[i].leftEye[k] = metadata->faces[i].left_eye[k]; } for (int k = 0; k < 2; k++) { hidlMetadata.faces[i].rightEye[k] = metadata->faces[i].right_eye[k]; } for (int k = 0; k < 2; k++) { hidlMetadata.faces[i].mouth[k] = metadata->faces[i].mouth[k]; } } } CameraHeapMemory* mem = static_cast(data->handle); object->mDeviceCallback->dataCallback( (DataCallbackMsg) msg_type, mem->handle.mId, index, hidlMetadata); } } void CameraDevice::handleCallbackTimestamp( nsecs_t timestamp, int32_t msg_type, MemoryId memId , unsigned index, native_handle_t* handle) { uint32_t batchSize = 0; { Mutex::Autolock _l(mBatchLock); batchSize = mBatchSize; } if (batchSize == 0) { // non-batch mode mDeviceCallback->handleCallbackTimestamp( (DataCallbackMsg) msg_type, handle, memId, index, timestamp); } else { // batch mode Mutex::Autolock _l(mBatchLock); size_t inflightSize = mInflightBatch.size(); if (inflightSize == 0) { mBatchMsgType = msg_type; } else if (mBatchMsgType != msg_type) { ALOGE("%s: msg_type change (from %d to %d) is not supported!", __FUNCTION__, mBatchMsgType, msg_type); return; } mInflightBatch.push_back({handle, memId, index, timestamp}); // Send batched frames to camera framework if (mInflightBatch.size() >= batchSize) { mDeviceCallback->handleCallbackTimestampBatch( (DataCallbackMsg) mBatchMsgType, mInflightBatch); mInflightBatch.clear(); } } } void CameraDevice::sDataCbTimestamp(nsecs_t timestamp, int32_t msg_type, const camera_memory_t *data, unsigned index, void *user) { ALOGV("%s", __FUNCTION__); CameraDevice* object = static_cast(user); // Start refcounting the heap object from here on. When the clients // drop all references, it will be destroyed (as well as the enclosed // MemoryHeapBase. sp mem(static_cast(data->handle)); if (index >= mem->mNumBufs) { ALOGE("%s: invalid buffer index %d, max allowed is %d", __FUNCTION__, index, mem->mNumBufs); return; } native_handle_t* handle = nullptr; if (object->mMetadataMode) { if (mem->mBufSize == sizeof(VideoNativeHandleMetadata)) { VideoNativeHandleMetadata* md = (VideoNativeHandleMetadata*) ((uint8_t*) mem->mHidlHeapMemData + index * mem->mBufSize); if (md->eType == kMetadataBufferTypeNativeHandleSource) { handle = md->pHandle; } } } if (object->mDeviceCallback != nullptr) { if (handle == nullptr) { object->mDeviceCallback->dataCallbackTimestamp( (DataCallbackMsg) msg_type, mem->handle.mId, index, timestamp); } else { object->handleCallbackTimestamp(timestamp, msg_type, mem->handle.mId, index, handle); } } } void CameraDevice::initHalPreviewWindow() { mHalPreviewWindow.cancel_buffer = sCancelBuffer; mHalPreviewWindow.lock_buffer = sLockBuffer; mHalPreviewWindow.dequeue_buffer = sDequeueBuffer; mHalPreviewWindow.enqueue_buffer = sEnqueueBuffer; mHalPreviewWindow.set_buffer_count = sSetBufferCount; mHalPreviewWindow.set_buffers_geometry = sSetBuffersGeometry; mHalPreviewWindow.set_crop = sSetCrop; mHalPreviewWindow.set_timestamp = sSetTimestamp; mHalPreviewWindow.set_usage = sSetUsage; mHalPreviewWindow.set_swap_interval = sSetSwapInterval; mHalPreviewWindow.get_min_undequeued_buffer_count = sGetMinUndequeuedBufferCount; } // Methods from ::android::hardware::camera::device::V1_0::ICameraDevice follow. Return CameraDevice::getResourceCost(getResourceCost_cb _hidl_cb) { Status status = initStatus(); CameraResourceCost resCost; if (status == Status::OK) { int cost = 100; std::vector conflicting_devices; struct camera_info info; // If using post-2.4 module version, query the cost + conflicting devices from the HAL if (mModule->getModuleApiVersion() >= CAMERA_MODULE_API_VERSION_2_4) { int ret = mModule->getCameraInfo(mCameraIdInt, &info); if (ret == OK) { cost = info.resource_cost; for (size_t i = 0; i < info.conflicting_devices_length; i++) { std::string cameraId(info.conflicting_devices[i]); for (const auto& pair : mCameraDeviceNames) { if (cameraId == pair.first) { conflicting_devices.push_back(pair.second); } } } } else { status = Status::INTERNAL_ERROR; } } if (status == Status::OK) { resCost.resourceCost = cost; resCost.conflictingDevices.resize(conflicting_devices.size()); for (size_t i = 0; i < conflicting_devices.size(); i++) { resCost.conflictingDevices[i] = conflicting_devices[i]; ALOGV("CamDevice %s is conflicting with camDevice %s", mCameraId.c_str(), resCost.conflictingDevices[i].c_str()); } } } _hidl_cb(status, resCost); return Void(); } Return CameraDevice::getCameraInfo(getCameraInfo_cb _hidl_cb) { Status status = initStatus(); CameraInfo cameraInfo; if (status == Status::OK) { struct camera_info info; int ret = mModule->getCameraInfo(mCameraIdInt, &info); if (ret == OK) { cameraInfo.facing = (CameraFacing) info.facing; // Device 1.0 does not support external camera facing. // The closest approximation would be front camera. if (cameraInfo.facing == CameraFacing::EXTERNAL) { cameraInfo.facing = CameraFacing::FRONT; } cameraInfo.orientation = info.orientation; } else { ALOGE("%s: get camera info failed!", __FUNCTION__); status = Status::INTERNAL_ERROR; } } _hidl_cb(status, cameraInfo); return Void(); } Return CameraDevice::setTorchMode(TorchMode mode) { if (!mModule->isSetTorchModeSupported()) { return Status::METHOD_NOT_SUPPORTED; } Status status = initStatus(); if (status == Status::OK) { bool enable = (mode == TorchMode::ON) ? true : false; status = getHidlStatus(mModule->setTorchMode(mCameraId.c_str(), enable)); } return status; } Return CameraDevice::dumpState(const hidl_handle& handle) { Mutex::Autolock _l(mLock); if (handle.getNativeHandle() == nullptr) { ALOGE("%s: handle must not be null", __FUNCTION__); return Status::ILLEGAL_ARGUMENT; } if (handle->numFds != 1 || handle->numInts != 0) { ALOGE("%s: handle must contain 1 FD and 0 integers! Got %d FDs and %d ints", __FUNCTION__, handle->numFds, handle->numInts); return Status::ILLEGAL_ARGUMENT; } int fd = handle->data[0]; if (mDevice != nullptr) { if (mDevice->ops->dump) { // It's fine if the HAL doesn't implement dump() return getHidlStatus(mDevice->ops->dump(mDevice, fd)); } } return Status::OK; } Return CameraDevice::open(const sp& callback) { ALOGI("Opening camera %s", mCameraId.c_str()); Mutex::Autolock _l(mLock); camera_info info; status_t res = mModule->getCameraInfo(mCameraIdInt, &info); if (res != OK) { ALOGE("Could not get camera info: %s: %d", mCameraId.c_str(), res); return getHidlStatus(res); } int rc = OK; if (mModule->getModuleApiVersion() >= CAMERA_MODULE_API_VERSION_2_3 && info.device_version > CAMERA_DEVICE_API_VERSION_1_0) { // Open higher version camera device as HAL1.0 device. rc = mModule->openLegacy(mCameraId.c_str(), CAMERA_DEVICE_API_VERSION_1_0, (hw_device_t **)&mDevice); } else { rc = mModule->open(mCameraId.c_str(), (hw_device_t **)&mDevice); } if (rc != OK) { mDevice = nullptr; ALOGE("Could not open camera %s: %d", mCameraId.c_str(), rc); return getHidlStatus(rc); } initHalPreviewWindow(); mDeviceCallback = callback; if (mDevice->ops->set_callbacks) { mDevice->ops->set_callbacks(mDevice, sNotifyCb, sDataCb, sDataCbTimestamp, sGetMemory, this); } return getHidlStatus(rc); } Return CameraDevice::setPreviewWindow(const sp& window) { ALOGV("%s(%s)", __FUNCTION__, mCameraId.c_str()); Mutex::Autolock _l(mLock); if (!mDevice) { ALOGE("%s called while camera is not opened", __FUNCTION__); return Status::OPERATION_NOT_SUPPORTED; } mHalPreviewWindow.mPreviewCallback = window; if (mDevice->ops->set_preview_window) { return getHidlStatus(mDevice->ops->set_preview_window(mDevice, (window == nullptr) ? nullptr : &mHalPreviewWindow)); } return Status::INTERNAL_ERROR; // HAL should provide set_preview_window } Return CameraDevice::enableMsgType(uint32_t msgType) { ALOGV("%s(%s)", __FUNCTION__, mCameraId.c_str()); Mutex::Autolock _l(mLock); if (!mDevice) { ALOGE("%s called while camera is not opened", __FUNCTION__); return Void(); } if (mDevice->ops->enable_msg_type) { mDevice->ops->enable_msg_type(mDevice, msgType); } return Void(); } Return CameraDevice::disableMsgType(uint32_t msgType) { ALOGV("%s(%s)", __FUNCTION__, mCameraId.c_str()); Mutex::Autolock _l(mLock); if (!mDevice) { ALOGE("%s called while camera is not opened", __FUNCTION__); return Void(); } if (mDevice->ops->disable_msg_type) { mDevice->ops->disable_msg_type(mDevice, msgType); } return Void(); } Return CameraDevice::msgTypeEnabled(uint32_t msgType) { ALOGV("%s(%s)", __FUNCTION__, mCameraId.c_str()); Mutex::Autolock _l(mLock); if (!mDevice) { ALOGE("%s called while camera is not opened", __FUNCTION__); return false; } if (mDevice->ops->msg_type_enabled) { return mDevice->ops->msg_type_enabled(mDevice, msgType); } return false; } Return CameraDevice::startPreview() { ALOGV("%s(%s)", __FUNCTION__, mCameraId.c_str()); Mutex::Autolock _l(mLock); if (!mDevice) { ALOGE("%s called while camera is not opened", __FUNCTION__); return Status::OPERATION_NOT_SUPPORTED; } if (mDevice->ops->start_preview) { return getHidlStatus(mDevice->ops->start_preview(mDevice)); } return Status::INTERNAL_ERROR; // HAL should provide start_preview } Return CameraDevice::stopPreview() { ALOGV("%s(%s)", __FUNCTION__, mCameraId.c_str()); Mutex::Autolock _l(mLock); if (!mDevice) { ALOGE("%s called while camera is not opened", __FUNCTION__); return Void(); } if (mDevice->ops->stop_preview) { mDevice->ops->stop_preview(mDevice); } return Void(); } Return CameraDevice::previewEnabled() { ALOGV("%s(%s)", __FUNCTION__, mCameraId.c_str()); Mutex::Autolock _l(mLock); if (!mDevice) { ALOGE("%s called while camera is not opened", __FUNCTION__); return false; } if (mDevice->ops->preview_enabled) { return mDevice->ops->preview_enabled(mDevice); } return false; } Return CameraDevice::storeMetaDataInBuffers(bool enable) { ALOGV("%s(%s)", __FUNCTION__, mCameraId.c_str()); Mutex::Autolock _l(mLock); if (!mDevice) { ALOGE("%s called while camera is not opened", __FUNCTION__); return Status::OPERATION_NOT_SUPPORTED; } if (mDevice->ops->store_meta_data_in_buffers) { status_t s = mDevice->ops->store_meta_data_in_buffers(mDevice, enable); if (s == OK && enable) { mMetadataMode = true; } return getHidlStatus(s); } return enable ? Status::ILLEGAL_ARGUMENT : Status::OK; } Return CameraDevice::startRecording() { ALOGV("%s(%s)", __FUNCTION__, mCameraId.c_str()); Mutex::Autolock _l(mLock); if (!mDevice) { ALOGE("%s called while camera is not opened", __FUNCTION__); return Status::OPERATION_NOT_SUPPORTED; } if (mDevice->ops->start_recording) { return getHidlStatus(mDevice->ops->start_recording(mDevice)); } return Status::ILLEGAL_ARGUMENT; } Return CameraDevice::stopRecording() { ALOGV("%s(%s)", __FUNCTION__, mCameraId.c_str()); Mutex::Autolock _l(mLock); if (!mDevice) { ALOGE("%s called while camera is not opened", __FUNCTION__); return Void(); } if (mDevice->ops->stop_recording) { mDevice->ops->stop_recording(mDevice); } return Void(); } Return CameraDevice::recordingEnabled() { ALOGV("%s(%s)", __FUNCTION__, mCameraId.c_str()); Mutex::Autolock _l(mLock); if (!mDevice) { ALOGE("%s called while camera is not opened", __FUNCTION__); return false; } if (mDevice->ops->recording_enabled) { return mDevice->ops->recording_enabled(mDevice); } return false; } void CameraDevice::releaseRecordingFrameLocked( uint32_t memId, uint32_t bufferIndex, const native_handle_t* handle) { if (!mDevice) { ALOGE("%s called while camera is not opened", __FUNCTION__); return; } if (mDevice->ops->release_recording_frame) { CameraHeapMemory* camMemory; { Mutex::Autolock _l(mMemoryMapLock); auto it = mMemoryMap.find(memId); if (it == mMemoryMap.end() || it->second == nullptr) { ALOGE("%s unknown memoryId %d", __FUNCTION__, memId); return; } camMemory = it->second; } if (bufferIndex >= camMemory->mNumBufs) { ALOGE("%s: bufferIndex %d exceeds number of buffers %d", __FUNCTION__, bufferIndex, camMemory->mNumBufs); return; } void *data = ((uint8_t *) camMemory->mHidlHeapMemData) + bufferIndex * camMemory->mBufSize; if (handle) { VideoNativeHandleMetadata* md = (VideoNativeHandleMetadata*) data; if (md->eType == kMetadataBufferTypeNativeHandleSource) { // Input handle will be closed by HIDL transport later, so clone it // HAL implementation is responsible to close/delete the clone native_handle_t* clone = native_handle_clone(handle); if (!clone) { ALOGE("%s: failed to clone buffer %p", __FUNCTION__, handle); return; } md->pHandle = clone; } else { ALOGE("%s:Malform VideoNativeHandleMetadata at memId %d, bufferId %d", __FUNCTION__, memId, bufferIndex); return; } } mDevice->ops->release_recording_frame(mDevice, data); } } Return CameraDevice::releaseRecordingFrame(uint32_t memId, uint32_t bufferIndex) { ALOGV("%s(%s)", __FUNCTION__, mCameraId.c_str()); Mutex::Autolock _l(mLock); releaseRecordingFrameLocked(memId, bufferIndex, nullptr); return Void(); } Return CameraDevice::releaseRecordingFrameHandle( uint32_t memId, uint32_t bufferIndex, const hidl_handle& frame) { ALOGV("%s(%s)", __FUNCTION__, mCameraId.c_str()); Mutex::Autolock _l(mLock); releaseRecordingFrameLocked( memId, bufferIndex, frame.getNativeHandle()); return Void(); } Return CameraDevice::releaseRecordingFrameHandleBatch( const hidl_vec& msgs) { ALOGV("%s(%s)", __FUNCTION__, mCameraId.c_str()); Mutex::Autolock _l(mLock); for (auto& msg : msgs) { releaseRecordingFrameLocked( msg.data, msg.bufferIndex, msg.frameData.getNativeHandle()); } return Void(); } Return CameraDevice::autoFocus() { ALOGV("%s(%s)", __FUNCTION__, mCameraId.c_str()); Mutex::Autolock _l(mLock); if (!mDevice) { ALOGE("%s called while camera is not opened", __FUNCTION__); return Status::OPERATION_NOT_SUPPORTED; } if (mDevice->ops->auto_focus) { return getHidlStatus(mDevice->ops->auto_focus(mDevice)); } return Status::ILLEGAL_ARGUMENT; } Return CameraDevice::cancelAutoFocus() { ALOGV("%s(%s)", __FUNCTION__, mCameraId.c_str()); Mutex::Autolock _l(mLock); if (!mDevice) { ALOGE("%s called while camera is not opened", __FUNCTION__); return Status::OPERATION_NOT_SUPPORTED; } if (mDevice->ops->cancel_auto_focus) { return getHidlStatus(mDevice->ops->cancel_auto_focus(mDevice)); } return Status::ILLEGAL_ARGUMENT; } Return CameraDevice::takePicture() { ALOGV("%s(%s)", __FUNCTION__, mCameraId.c_str()); Mutex::Autolock _l(mLock); if (!mDevice) { ALOGE("%s called while camera is not opened", __FUNCTION__); return Status::OPERATION_NOT_SUPPORTED; } if (mDevice->ops->take_picture) { return getHidlStatus(mDevice->ops->take_picture(mDevice)); } return Status::ILLEGAL_ARGUMENT; } Return CameraDevice::cancelPicture() { ALOGV("%s(%s)", __FUNCTION__, mCameraId.c_str()); Mutex::Autolock _l(mLock); if (!mDevice) { ALOGE("%s called while camera is not opened", __FUNCTION__); return Status::OPERATION_NOT_SUPPORTED; } if (mDevice->ops->cancel_picture) { return getHidlStatus(mDevice->ops->cancel_picture(mDevice)); } return Status::ILLEGAL_ARGUMENT; } Return CameraDevice::setParameters(const hidl_string& params) { ALOGV("%s(%s)", __FUNCTION__, mCameraId.c_str()); Mutex::Autolock _l(mLock); if (!mDevice) { ALOGE("%s called while camera is not opened", __FUNCTION__); return Status::OPERATION_NOT_SUPPORTED; } if (mDevice->ops->set_parameters) { return getHidlStatus(mDevice->ops->set_parameters(mDevice, params.c_str())); } return Status::ILLEGAL_ARGUMENT; } Return CameraDevice::getParameters(getParameters_cb _hidl_cb) { ALOGV("%s(%s)", __FUNCTION__, mCameraId.c_str()); Mutex::Autolock _l(mLock); hidl_string outStr; if (!mDevice) { ALOGE("%s called while camera is not opened", __FUNCTION__); _hidl_cb(outStr); return Void(); } if (mDevice->ops->get_parameters) { char *temp = mDevice->ops->get_parameters(mDevice); outStr = temp; if (mDevice->ops->put_parameters) { mDevice->ops->put_parameters(mDevice, temp); } else { free(temp); } } _hidl_cb(outStr); return Void(); } Return CameraDevice::sendCommand(CommandType cmd, int32_t arg1, int32_t arg2) { ALOGV("%s(%s)", __FUNCTION__, mCameraId.c_str()); Mutex::Autolock _l(mLock); if (!mDevice) { ALOGE("%s called while camera is not opened", __FUNCTION__); return Status::OPERATION_NOT_SUPPORTED; } if (mDevice->ops->send_command) { return getHidlStatus(mDevice->ops->send_command(mDevice, (int32_t) cmd, arg1, arg2)); } return Status::ILLEGAL_ARGUMENT; } Return CameraDevice::close() { Mutex::Autolock _l(mLock); closeLocked(); return Void(); } void CameraDevice::closeLocked() { ALOGI("Closing camera %s", mCameraId.c_str()); if(mDevice) { int rc = mDevice->common.close(&mDevice->common); if (rc != OK) { ALOGE("Could not close camera %s: %d", mCameraId.c_str(), rc); } mDevice = nullptr; } } } // namespace implementation } // namespace V1_0 } // namespace device } // namespace camera } // namespace hardware } // namespace android