/* * Copyright (C) 2016-2018 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 "camera_hidl_hal_test" #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include using namespace ::android::hardware::camera::device; using ::android::BufferItemConsumer; using ::android::BufferQueue; using ::android::GraphicBuffer; using ::android::IGraphicBufferConsumer; using ::android::IGraphicBufferProducer; using ::android::sp; using ::android::Surface; using ::android::wp; using ::android::hardware::hidl_bitfield; using ::android::hardware::hidl_handle; using ::android::hardware::hidl_string; using ::android::hardware::hidl_vec; using ::android::hardware::kSynchronizedReadWrite; using ::android::hardware::MessageQueue; using ::android::hardware::Return; using ::android::hardware::Void; using ::android::hardware::camera::common::V1_0::CameraDeviceStatus; using ::android::hardware::camera::common::V1_0::Status; using ::android::hardware::camera::common::V1_0::TorchMode; using ::android::hardware::camera::common::V1_0::TorchModeStatus; using ::android::hardware::camera::common::V1_0::helper::CameraParameters; using ::android::hardware::camera::common::V1_0::helper::HandleImporter; using ::android::hardware::camera::common::V1_0::helper::Size; using ::android::hardware::camera::device::V1_0::CameraFacing; using ::android::hardware::camera::device::V1_0::CameraFrameMetadata; using ::android::hardware::camera::device::V1_0::CommandType; using ::android::hardware::camera::device::V1_0::DataCallbackMsg; using ::android::hardware::camera::device::V1_0::FrameCallbackFlag; using ::android::hardware::camera::device::V1_0::HandleTimestampMessage; using ::android::hardware::camera::device::V1_0::ICameraDevicePreviewCallback; using ::android::hardware::camera::device::V1_0::NotifyCallbackMsg; using ::android::hardware::camera::device::V3_2::BufferCache; using ::android::hardware::camera::device::V3_2::BufferStatus; using ::android::hardware::camera::device::V3_2::CameraMetadata; using ::android::hardware::camera::device::V3_2::CaptureRequest; using ::android::hardware::camera::device::V3_2::CaptureResult; using ::android::hardware::camera::device::V3_2::ErrorCode; using ::android::hardware::camera::device::V3_2::ErrorMsg; using ::android::hardware::camera::device::V3_2::HalStreamConfiguration; using ::android::hardware::camera::device::V3_2::ICameraDevice; using ::android::hardware::camera::device::V3_2::ICameraDeviceSession; using ::android::hardware::camera::device::V3_2::MsgType; using ::android::hardware::camera::device::V3_2::NotifyMsg; using ::android::hardware::camera::device::V3_2::RequestTemplate; using ::android::hardware::camera::device::V3_2::StreamBuffer; using ::android::hardware::camera::device::V3_2::StreamConfiguration; using ::android::hardware::camera::device::V3_2::StreamConfigurationMode; using ::android::hardware::camera::device::V3_2::StreamRotation; using ::android::hardware::camera::device::V3_2::StreamType; using ::android::hardware::camera::device::V3_4::PhysicalCameraMetadata; using ::android::hardware::camera::metadata::V3_4:: CameraMetadataEnumAndroidSensorInfoColorFilterArrangement; using ::android::hardware::camera::metadata::V3_4::CameraMetadataTag; using ::android::hardware::camera::metadata::V3_6::CameraMetadataEnumAndroidSensorPixelMode; using ::android::hardware::camera::provider::V2_4::ICameraProvider; using ::android::hardware::camera::provider::V2_4::ICameraProviderCallback; using ::android::hardware::camera::provider::V2_6::CameraIdAndStreamCombination; using ::android::hardware::graphics::common::V1_0::BufferUsage; using ::android::hardware::graphics::common::V1_0::Dataspace; using ::android::hardware::graphics::common::V1_0::PixelFormat; using ::android::hidl::allocator::V1_0::IAllocator; using ::android::hidl::memory::V1_0::IMemory; using ResultMetadataQueue = MessageQueue; using ::android::hidl::manager::V1_0::IServiceManager; using namespace ::android::hardware::camera; const uint32_t kMaxPreviewWidth = 1920; const uint32_t kMaxPreviewHeight = 1080; const uint32_t kMaxStillWidth = 2048; const uint32_t kMaxStillHeight = 1536; const uint32_t kMaxVideoWidth = 4096; const uint32_t kMaxVideoHeight = 2160; const int64_t kStreamBufferTimeoutSec = 3; const int64_t kAutoFocusTimeoutSec = 5; const int64_t kTorchTimeoutSec = 1; const int64_t kEmptyFlushTimeoutMSec = 200; const char kDumpOutput[] = "/dev/null"; const uint32_t kBurstFrameCount = 10; const int64_t kBufferReturnTimeoutSec = 1; struct AvailableStream { int32_t width; int32_t height; int32_t format; }; struct RecordingRateSizePair { int32_t recordingRate; int32_t width; int32_t height; bool operator==(const RecordingRateSizePair &p) const{ return p.recordingRate == recordingRate && p.width == width && p.height == height; } }; struct RecordingRateSizePairHasher { size_t operator()(const RecordingRateSizePair& p) const { std::size_t p1 = std::hash()(p.recordingRate); std::size_t p2 = std::hash()(p.width); std::size_t p3 = std::hash()(p.height); return p1 ^ p2 ^ p3; } }; struct AvailableZSLInputOutput { int32_t inputFormat; int32_t outputFormat; }; enum ReprocessType { PRIV_REPROCESS, YUV_REPROCESS, }; enum SystemCameraKind { /** * These camera devices are visible to all apps and system components alike */ PUBLIC = 0, /** * These camera devices are visible only to processes having the * android.permission.SYSTEM_CAMERA permission. They are not exposed to 3P * apps. */ SYSTEM_ONLY_CAMERA, /** * These camera devices are visible only to HAL clients (that try to connect * on a hwbinder thread). */ HIDDEN_SECURE_CAMERA }; const static std::vector kMandatoryUseCases = { ANDROID_SCALER_AVAILABLE_STREAM_USE_CASES_DEFAULT, ANDROID_SCALER_AVAILABLE_STREAM_USE_CASES_PREVIEW, ANDROID_SCALER_AVAILABLE_STREAM_USE_CASES_STILL_CAPTURE, ANDROID_SCALER_AVAILABLE_STREAM_USE_CASES_VIDEO_RECORD, ANDROID_SCALER_AVAILABLE_STREAM_USE_CASES_PREVIEW_VIDEO_STILL, ANDROID_SCALER_AVAILABLE_STREAM_USE_CASES_VIDEO_CALL }; namespace { // "device@/legacy/" const char* kDeviceNameRE = "device@([0-9]+\\.[0-9]+)/%s/(.+)"; const int CAMERA_DEVICE_API_VERSION_3_7 = 0x307; const int CAMERA_DEVICE_API_VERSION_3_6 = 0x306; const int CAMERA_DEVICE_API_VERSION_3_5 = 0x305; const int CAMERA_DEVICE_API_VERSION_3_4 = 0x304; const int CAMERA_DEVICE_API_VERSION_3_3 = 0x303; const int CAMERA_DEVICE_API_VERSION_3_2 = 0x302; const int CAMERA_DEVICE_API_VERSION_1_0 = 0x100; const char* kHAL3_7 = "3.7"; const char* kHAL3_6 = "3.6"; const char* kHAL3_5 = "3.5"; const char* kHAL3_4 = "3.4"; const char* kHAL3_3 = "3.3"; const char* kHAL3_2 = "3.2"; const char* kHAL1_0 = "1.0"; bool matchDeviceName(const hidl_string& deviceName, const hidl_string& providerType, std::string* deviceVersion, std::string* cameraId) { ::android::String8 pattern; pattern.appendFormat(kDeviceNameRE, providerType.c_str()); std::regex e(pattern.c_str()); std::string deviceNameStd(deviceName.c_str()); std::smatch sm; if (std::regex_match(deviceNameStd, sm, e)) { if (deviceVersion != nullptr) { *deviceVersion = sm[1]; } if (cameraId != nullptr) { *cameraId = sm[2]; } return true; } return false; } int getCameraDeviceVersionAndId(const hidl_string& deviceName, const hidl_string &providerType, std::string* id) { std::string version; bool match = matchDeviceName(deviceName, providerType, &version, id); if (!match) { return -1; } if (version.compare(kHAL3_7) == 0) { return CAMERA_DEVICE_API_VERSION_3_7; } else if (version.compare(kHAL3_6) == 0) { return CAMERA_DEVICE_API_VERSION_3_6; } else if (version.compare(kHAL3_5) == 0) { return CAMERA_DEVICE_API_VERSION_3_5; } else if (version.compare(kHAL3_4) == 0) { return CAMERA_DEVICE_API_VERSION_3_4; } else if (version.compare(kHAL3_3) == 0) { return CAMERA_DEVICE_API_VERSION_3_3; } else if (version.compare(kHAL3_2) == 0) { return CAMERA_DEVICE_API_VERSION_3_2; } else if (version.compare(kHAL1_0) == 0) { return CAMERA_DEVICE_API_VERSION_1_0; } return 0; } int getCameraDeviceVersion(const hidl_string& deviceName, const hidl_string &providerType) { return getCameraDeviceVersionAndId(deviceName, providerType, nullptr); } bool parseProviderName(const std::string& name, std::string *type /*out*/, uint32_t *id /*out*/) { if (!type || !id) { ADD_FAILURE(); return false; } std::string::size_type slashIdx = name.find('/'); if (slashIdx == std::string::npos || slashIdx == name.size() - 1) { ADD_FAILURE() << "Provider name does not have / separator between type" "and id"; return false; } std::string typeVal = name.substr(0, slashIdx); char *endPtr; errno = 0; long idVal = strtol(name.c_str() + slashIdx + 1, &endPtr, 10); if (errno != 0) { ADD_FAILURE() << "cannot parse provider id as an integer:" << name.c_str() << strerror(errno) << errno; return false; } if (endPtr != name.c_str() + name.size()) { ADD_FAILURE() << "provider id has unexpected length " << name.c_str(); return false; } if (idVal < 0) { ADD_FAILURE() << "id is negative: " << name.c_str() << idVal; return false; } *type = typeVal; *id = static_cast(idVal); return true; } Status mapToStatus(::android::status_t s) { switch(s) { case ::android::OK: return Status::OK ; case ::android::BAD_VALUE: return Status::ILLEGAL_ARGUMENT ; case -EBUSY: return Status::CAMERA_IN_USE; case -EUSERS: return Status::MAX_CAMERAS_IN_USE; case ::android::UNKNOWN_TRANSACTION: return Status::METHOD_NOT_SUPPORTED; case ::android::INVALID_OPERATION: return Status::OPERATION_NOT_SUPPORTED; case ::android::DEAD_OBJECT: return Status::CAMERA_DISCONNECTED; } ALOGW("Unexpected HAL status code %d", s); return Status::OPERATION_NOT_SUPPORTED; } void getFirstApiLevel(/*out*/int32_t* outApiLevel) { int32_t firstApiLevel = property_get_int32("ro.product.first_api_level", /*default*/-1); if (firstApiLevel < 0) { firstApiLevel = property_get_int32("ro.build.version.sdk", /*default*/-1); } ASSERT_GT(firstApiLevel, 0); // first_api_level must exist *outApiLevel = firstApiLevel; return; } } struct BufferItemHander: public BufferItemConsumer::FrameAvailableListener { BufferItemHander(wp consumer) : mConsumer(consumer) {} void onFrameAvailable(const android::BufferItem&) override { sp consumer = mConsumer.promote(); ASSERT_NE(nullptr, consumer.get()); android::BufferItem buffer; ASSERT_EQ(android::OK, consumer->acquireBuffer(&buffer, 0)); ASSERT_EQ(android::OK, consumer->releaseBuffer(buffer)); } private: wp mConsumer; }; struct PreviewWindowCb : public ICameraDevicePreviewCallback { PreviewWindowCb(sp anw) : mPreviewWidth(0), mPreviewHeight(0), mFormat(0), mPreviewUsage(0), mPreviewSwapInterval(-1), mCrop{-1, -1, -1, -1}, mAnw(anw) {} using dequeueBuffer_cb = std::function; Return dequeueBuffer(dequeueBuffer_cb _hidl_cb) override; Return enqueueBuffer(uint64_t bufferId) override; Return cancelBuffer(uint64_t bufferId) override; Return setBufferCount(uint32_t count) override; Return setBuffersGeometry(uint32_t w, uint32_t h, PixelFormat format) override; Return setCrop(int32_t left, int32_t top, int32_t right, int32_t bottom) override; Return setUsage(BufferUsage usage) override; Return setSwapInterval(int32_t interval) override; using getMinUndequeuedBufferCount_cb = std::function; Return getMinUndequeuedBufferCount( getMinUndequeuedBufferCount_cb _hidl_cb) override; Return setTimestamp(int64_t timestamp) override; private: struct BufferHasher { size_t operator()(const buffer_handle_t& buf) const { if (buf == nullptr) return 0; size_t result = 1; result = 31 * result + buf->numFds; for (int i = 0; i < buf->numFds; i++) { result = 31 * result + buf->data[i]; } return result; } }; struct BufferComparator { bool operator()(const buffer_handle_t& buf1, const buffer_handle_t& buf2) const { if (buf1->numFds == buf2->numFds) { for (int i = 0; i < buf1->numFds; i++) { if (buf1->data[i] != buf2->data[i]) { return false; } } return true; } return false; } }; std::pair getBufferId(ANativeWindowBuffer* anb); void cleanupCirculatingBuffers(); std::mutex mBufferIdMapLock; // protecting mBufferIdMap and mNextBufferId typedef std::unordered_map BufferIdMap; BufferIdMap mBufferIdMap; // stream ID -> per stream buffer ID map std::unordered_map mReversedBufMap; uint64_t mNextBufferId = 1; uint32_t mPreviewWidth, mPreviewHeight; int mFormat, mPreviewUsage; int32_t mPreviewSwapInterval; android_native_rect_t mCrop; sp mAnw; //Native window reference }; std::pair PreviewWindowCb::getBufferId( ANativeWindowBuffer* anb) { std::lock_guard lock(mBufferIdMapLock); buffer_handle_t& buf = anb->handle; auto it = mBufferIdMap.find(buf); if (it == mBufferIdMap.end()) { uint64_t bufId = mNextBufferId++; mBufferIdMap[buf] = bufId; mReversedBufMap[bufId] = anb; return std::make_pair(true, bufId); } else { return std::make_pair(false, it->second); } } void PreviewWindowCb::cleanupCirculatingBuffers() { std::lock_guard lock(mBufferIdMapLock); mBufferIdMap.clear(); mReversedBufMap.clear(); } Return PreviewWindowCb::dequeueBuffer(dequeueBuffer_cb _hidl_cb) { ANativeWindowBuffer* anb; auto rc = native_window_dequeue_buffer_and_wait(mAnw.get(), &anb); uint64_t bufferId = 0; uint32_t stride = 0; hidl_handle buf = nullptr; if (rc == ::android::OK) { auto pair = getBufferId(anb); buf = (pair.first) ? anb->handle : nullptr; bufferId = pair.second; stride = anb->stride; } _hidl_cb(mapToStatus(rc), bufferId, buf, stride); return Void(); } Return PreviewWindowCb::enqueueBuffer(uint64_t bufferId) { if (mReversedBufMap.count(bufferId) == 0) { ALOGE("%s: bufferId %" PRIu64 " not found", __FUNCTION__, bufferId); return Status::ILLEGAL_ARGUMENT; } return mapToStatus(mAnw->queueBuffer(mAnw.get(), mReversedBufMap.at(bufferId), -1)); } Return PreviewWindowCb::cancelBuffer(uint64_t bufferId) { if (mReversedBufMap.count(bufferId) == 0) { ALOGE("%s: bufferId %" PRIu64 " not found", __FUNCTION__, bufferId); return Status::ILLEGAL_ARGUMENT; } return mapToStatus(mAnw->cancelBuffer(mAnw.get(), mReversedBufMap.at(bufferId), -1)); } Return PreviewWindowCb::setBufferCount(uint32_t count) { if (mAnw.get() != nullptr) { // WAR for b/27039775 native_window_api_disconnect(mAnw.get(), NATIVE_WINDOW_API_CAMERA); native_window_api_connect(mAnw.get(), NATIVE_WINDOW_API_CAMERA); if (mPreviewWidth != 0) { native_window_set_buffers_dimensions(mAnw.get(), mPreviewWidth, mPreviewHeight); native_window_set_buffers_format(mAnw.get(), mFormat); } if (mPreviewUsage != 0) { native_window_set_usage(mAnw.get(), mPreviewUsage); } if (mPreviewSwapInterval >= 0) { mAnw->setSwapInterval(mAnw.get(), mPreviewSwapInterval); } if (mCrop.left >= 0) { native_window_set_crop(mAnw.get(), &(mCrop)); } } auto rc = native_window_set_buffer_count(mAnw.get(), count); if (rc == ::android::OK) { cleanupCirculatingBuffers(); } return mapToStatus(rc); } Return PreviewWindowCb::setBuffersGeometry(uint32_t w, uint32_t h, PixelFormat format) { auto rc = native_window_set_buffers_dimensions(mAnw.get(), w, h); if (rc == ::android::OK) { mPreviewWidth = w; mPreviewHeight = h; rc = native_window_set_buffers_format(mAnw.get(), static_cast(format)); if (rc == ::android::OK) { mFormat = static_cast(format); } } return mapToStatus(rc); } Return PreviewWindowCb::setCrop(int32_t left, int32_t top, int32_t right, int32_t bottom) { android_native_rect_t crop = { left, top, right, bottom }; auto rc = native_window_set_crop(mAnw.get(), &crop); if (rc == ::android::OK) { mCrop = crop; } return mapToStatus(rc); } Return PreviewWindowCb::setUsage(BufferUsage usage) { auto rc = native_window_set_usage(mAnw.get(), static_cast(usage)); if (rc == ::android::OK) { mPreviewUsage = static_cast(usage); } return mapToStatus(rc); } Return PreviewWindowCb::setSwapInterval(int32_t interval) { auto rc = mAnw->setSwapInterval(mAnw.get(), interval); if (rc == ::android::OK) { mPreviewSwapInterval = interval; } return mapToStatus(rc); } Return PreviewWindowCb::getMinUndequeuedBufferCount( getMinUndequeuedBufferCount_cb _hidl_cb) { int count = 0; auto rc = mAnw->query(mAnw.get(), NATIVE_WINDOW_MIN_UNDEQUEUED_BUFFERS, &count); _hidl_cb(mapToStatus(rc), count); return Void(); } Return PreviewWindowCb::setTimestamp(int64_t timestamp) { return mapToStatus(native_window_set_buffers_timestamp(mAnw.get(), timestamp)); } // The main test class for camera HIDL HAL. class CameraHidlTest : public ::testing::TestWithParam { public: virtual void SetUp() override { std::string service_name = GetParam(); ALOGI("get service with name: %s", service_name.c_str()); mProvider = ICameraProvider::getService(service_name); ASSERT_NE(mProvider, nullptr); uint32_t id; ASSERT_TRUE(parseProviderName(service_name, &mProviderType, &id)); castProvider(mProvider, &mProvider2_5, &mProvider2_6, &mProvider2_7); notifyDeviceState(provider::V2_5::DeviceState::NORMAL); } virtual void TearDown() override {} hidl_vec getCameraDeviceNames(sp provider, bool addSecureOnly = false); bool isSecureOnly(sp provider, const hidl_string& name); std::map getCameraDeviceIdToNameMap(sp provider); hidl_vec> getConcurrentDeviceCombinations( sp<::android::hardware::camera::provider::V2_6::ICameraProvider>&); struct EmptyDeviceCb : public V3_5::ICameraDeviceCallback { virtual Return processCaptureResult( const hidl_vec& /*results*/) override { ALOGI("processCaptureResult callback"); ADD_FAILURE(); // Empty callback should not reach here return Void(); } virtual Return processCaptureResult_3_4( const hidl_vec& /*results*/) override { ALOGI("processCaptureResult_3_4 callback"); ADD_FAILURE(); // Empty callback should not reach here return Void(); } virtual Return notify(const hidl_vec& /*msgs*/) override { ALOGI("notify callback"); ADD_FAILURE(); // Empty callback should not reach here return Void(); } virtual Return requestStreamBuffers( const hidl_vec&, requestStreamBuffers_cb _hidl_cb) override { ALOGI("requestStreamBuffers callback"); // HAL might want to request buffer after configureStreams, but tests with EmptyDeviceCb // doesn't actually need to send capture requests, so just return an error. hidl_vec emptyBufRets; _hidl_cb(V3_5::BufferRequestStatus::FAILED_UNKNOWN, emptyBufRets); return Void(); } virtual Return returnStreamBuffers(const hidl_vec&) override { ALOGI("returnStreamBuffers"); ADD_FAILURE(); // Empty callback should not reach here return Void(); } }; struct DeviceCb : public V3_5::ICameraDeviceCallback { DeviceCb(CameraHidlTest* parent, int deviceVersion, const camera_metadata_t* staticMeta) : mParent(parent), mDeviceVersion(deviceVersion) { mStaticMetadata = staticMeta; } Return processCaptureResult_3_4(const hidl_vec& results) override; Return processCaptureResult(const hidl_vec& results) override; Return notify(const hidl_vec& msgs) override; Return requestStreamBuffers(const hidl_vec& bufReqs, requestStreamBuffers_cb _hidl_cb) override; Return returnStreamBuffers(const hidl_vec& buffers) override; void setCurrentStreamConfig(const hidl_vec& streams, const hidl_vec& halStreams); void waitForBuffersReturned(); private: bool processCaptureResultLocked(const CaptureResult& results, hidl_vec physicalCameraMetadata); Return notifyHelper(const hidl_vec& msgs, const std::vector>& readoutTimestamps); CameraHidlTest* mParent; // Parent object int mDeviceVersion; android::hardware::camera::common::V1_0::helper::CameraMetadata mStaticMetadata; bool hasOutstandingBuffersLocked(); /* members for requestStreamBuffers() and returnStreamBuffers()*/ std::mutex mLock; // protecting members below bool mUseHalBufManager = false; hidl_vec mStreams; hidl_vec mHalStreams; uint64_t mNextBufferId = 1; using OutstandingBuffers = std::unordered_map; // size == mStreams.size(). Tracking each streams outstanding buffers std::vector mOutstandingBufferIds; std::condition_variable mFlushedCondition; }; struct TorchProviderCb : public ICameraProviderCallback { TorchProviderCb(CameraHidlTest *parent) : mParent(parent) {} virtual Return cameraDeviceStatusChange( const hidl_string&, CameraDeviceStatus) override { return Void(); } virtual Return torchModeStatusChange( const hidl_string&, TorchModeStatus newStatus) override { std::lock_guard l(mParent->mTorchLock); mParent->mTorchStatus = newStatus; mParent->mTorchCond.notify_one(); return Void(); } private: CameraHidlTest *mParent; // Parent object }; struct Camera1DeviceCb : public ::android::hardware::camera::device::V1_0::ICameraDeviceCallback { Camera1DeviceCb(CameraHidlTest *parent) : mParent(parent) {} Return notifyCallback(NotifyCallbackMsg msgType, int32_t ext1, int32_t ext2) override; Return registerMemory(const hidl_handle& descriptor, uint32_t bufferSize, uint32_t bufferCount) override; Return unregisterMemory(uint32_t memId) override; Return dataCallback(DataCallbackMsg msgType, uint32_t data, uint32_t bufferIndex, const CameraFrameMetadata& metadata) override; Return dataCallbackTimestamp(DataCallbackMsg msgType, uint32_t data, uint32_t bufferIndex, int64_t timestamp) override; Return handleCallbackTimestamp(DataCallbackMsg msgType, const hidl_handle& frameData,uint32_t data, uint32_t bufferIndex, int64_t timestamp) override; Return handleCallbackTimestampBatch(DataCallbackMsg msgType, const ::android::hardware::hidl_vec& batch) override; private: CameraHidlTest *mParent; // Parent object }; void notifyDeviceState(::android::hardware::camera::provider::V2_5::DeviceState newState); void openCameraDevice(const std::string &name, sp provider, sp<::android::hardware::camera::device::V1_0::ICameraDevice> *device /*out*/); void setupPreviewWindow( const sp<::android::hardware::camera::device::V1_0::ICameraDevice> &device, sp *bufferItemConsumer /*out*/, sp *bufferHandler /*out*/); void stopPreviewAndClose( const sp<::android::hardware::camera::device::V1_0::ICameraDevice> &device); void startPreview( const sp<::android::hardware::camera::device::V1_0::ICameraDevice> &device); void enableMsgType(unsigned int msgType, const sp<::android::hardware::camera::device::V1_0::ICameraDevice> &device); void disableMsgType(unsigned int msgType, const sp<::android::hardware::camera::device::V1_0::ICameraDevice> &device); void getParameters( const sp<::android::hardware::camera::device::V1_0::ICameraDevice> &device, CameraParameters *cameraParams /*out*/); void setParameters( const sp<::android::hardware::camera::device::V1_0::ICameraDevice> &device, const CameraParameters &cameraParams); void allocateGraphicBuffer(uint32_t width, uint32_t height, uint64_t usage, PixelFormat format, hidl_handle *buffer_handle /*out*/); void waitForFrameLocked(DataCallbackMsg msgFrame, std::unique_lock &l); void openEmptyDeviceSession(const std::string &name, sp provider, sp *session /*out*/, camera_metadata_t **staticMeta /*out*/, ::android::sp *device = nullptr/*out*/); void castProvider(const sp& provider, sp* provider2_5 /*out*/, sp* provider2_6 /*out*/, sp* provider2_7 /*out*/); void castSession(const sp& session, int32_t deviceVersion, sp* session3_3 /*out*/, sp* session3_4 /*out*/, sp* session3_5 /*out*/, sp* session3_6 /*out*/, sp* session3_7 /*out*/); void castInjectionSession( const sp& session, sp* injectionSession3_7 /*out*/); void castDevice(const sp& device, int32_t deviceVersion, sp* device3_5 /*out*/, sp* device3_7 /*out*/); void createStreamConfiguration( const ::android::hardware::hidl_vec& streams3_2, StreamConfigurationMode configMode, ::android::hardware::camera::device::V3_2::StreamConfiguration* config3_2, ::android::hardware::camera::device::V3_4::StreamConfiguration* config3_4, ::android::hardware::camera::device::V3_5::StreamConfiguration* config3_5, ::android::hardware::camera::device::V3_7::StreamConfiguration* config3_7, uint32_t jpegBufferSize = 0); void configureOfflineStillStream(const std::string &name, int32_t deviceVersion, sp provider, const AvailableStream *threshold, sp *session/*out*/, V3_2::Stream *stream /*out*/, device::V3_6::HalStreamConfiguration *halStreamConfig /*out*/, bool *supportsPartialResults /*out*/, uint32_t *partialResultCount /*out*/, sp *outCb /*out*/, uint32_t *jpegBufferSize /*out*/, bool *useHalBufManager /*out*/); void configureStreams3_7(const std::string& name, int32_t deviceVersion, sp provider, PixelFormat format, sp* session3_7 /*out*/, V3_2::Stream* previewStream /*out*/, device::V3_6::HalStreamConfiguration* halStreamConfig /*out*/, bool* supportsPartialResults /*out*/, uint32_t* partialResultCount /*out*/, bool* useHalBufManager /*out*/, sp* outCb /*out*/, uint32_t streamConfigCounter, bool maxResolution); void configurePreviewStreams3_4(const std::string &name, int32_t deviceVersion, sp provider, const AvailableStream *previewThreshold, const std::unordered_set& physicalIds, sp *session3_4 /*out*/, sp *session3_5 /*out*/, V3_2::Stream* previewStream /*out*/, device::V3_4::HalStreamConfiguration *halStreamConfig /*out*/, bool *supportsPartialResults /*out*/, uint32_t *partialResultCount /*out*/, bool *useHalBufManager /*out*/, sp *cb /*out*/, uint32_t streamConfigCounter = 0, bool allowUnsupport = false); void configurePreviewStream(const std::string &name, int32_t deviceVersion, sp provider, const AvailableStream *previewThreshold, sp *session /*out*/, V3_2::Stream *previewStream /*out*/, HalStreamConfiguration *halStreamConfig /*out*/, bool *supportsPartialResults /*out*/, uint32_t *partialResultCount /*out*/, bool *useHalBufManager /*out*/, sp *cb /*out*/, uint32_t streamConfigCounter = 0); void configureSingleStream(const std::string& name, int32_t deviceVersion, sp provider, const AvailableStream* previewThreshold, uint64_t bufferUsage, RequestTemplate reqTemplate, sp* session /*out*/, V3_2::Stream* previewStream /*out*/, HalStreamConfiguration* halStreamConfig /*out*/, bool* supportsPartialResults /*out*/, uint32_t* partialResultCount /*out*/, bool* useHalBufManager /*out*/, sp* cb /*out*/, uint32_t streamConfigCounter = 0); void verifyLogicalOrUltraHighResCameraMetadata( const std::string& cameraName, const ::android::sp<::android::hardware::camera::device::V3_2::ICameraDevice>& device, const CameraMetadata& chars, int deviceVersion, const hidl_vec& deviceNames); void verifyCameraCharacteristics(Status status, const CameraMetadata& chars); void verifyExtendedSceneModeCharacteristics(const camera_metadata_t* metadata); void verifyZoomCharacteristics(const camera_metadata_t* metadata); void verifyStreamUseCaseCharacteristics(const camera_metadata_t* metadata); void verifyRecommendedConfigs(const CameraMetadata& metadata); void verifyMonochromeCharacteristics(const CameraMetadata& chars, int deviceVersion); void verifyMonochromeCameraResult( const ::android::hardware::camera::common::V1_0::helper::CameraMetadata& metadata); void verifyStreamCombination( sp cameraDevice3_7, const ::android::hardware::camera::device::V3_7::StreamConfiguration& config3_7, sp cameraDevice3_5, const ::android::hardware::camera::device::V3_4::StreamConfiguration& config3_4, bool expectedStatus, bool expectStreamCombQuery); void verifyLogicalCameraResult(const camera_metadata_t* staticMetadata, const ::android::hardware::camera::common::V1_0::helper::CameraMetadata& resultMetadata); void verifyBuffersReturned(sp session, int deviceVerison, int32_t streamId, sp cb, uint32_t streamConfigCounter = 0); void verifyBuffersReturned(sp session, hidl_vec streamIds, sp cb, uint32_t streamConfigCounter = 0); void verifyBuffersReturned(sp session, hidl_vec streamIds, sp cb, uint32_t streamConfigCounter = 0); void verifySessionReconfigurationQuery(sp session3_5, camera_metadata* oldSessionParams, camera_metadata* newSessionParams); void verifyRequestTemplate(const camera_metadata_t* metadata, RequestTemplate requestTemplate); static void overrideRotateAndCrop(::android::hardware::hidl_vec *settings /*in/out*/); static bool isDepthOnly(const camera_metadata_t* staticMeta); static bool isUltraHighResolution(const camera_metadata_t* staticMeta); static Status getAvailableOutputStreams(const camera_metadata_t* staticMeta, std::vector& outputStreams, const AvailableStream* threshold = nullptr, bool maxResolution = false); static Status getMaxOutputSizeForFormat(const camera_metadata_t* staticMeta, PixelFormat format, Size* size, bool maxResolution = false); static Status getMandatoryConcurrentStreams(const camera_metadata_t* staticMeta, std::vector* outputStreams); static Status getJpegBufferSize(camera_metadata_t *staticMeta, uint32_t* outBufSize); static Status isConstrainedModeAvailable(camera_metadata_t *staticMeta); static Status isLogicalMultiCamera(const camera_metadata_t *staticMeta); static bool isTorchStrengthControlSupported(const camera_metadata_t *staticMeta); static Status isOfflineSessionSupported(const camera_metadata_t *staticMeta); static Status getPhysicalCameraIds(const camera_metadata_t *staticMeta, std::unordered_set *physicalIds/*out*/); static Status getSupportedKeys(camera_metadata_t *staticMeta, uint32_t tagId, std::unordered_set *requestIDs/*out*/); static void fillOutputStreams(camera_metadata_ro_entry_t* entry, std::vector& outputStreams, const AvailableStream *threshold = nullptr, const int32_t availableConfigOutputTag = 0u); static void constructFilteredSettings(const sp& session, const std::unordered_set& availableKeys, RequestTemplate reqTemplate, android::hardware::camera::common::V1_0::helper::CameraMetadata* defaultSettings/*out*/, android::hardware::camera::common::V1_0::helper::CameraMetadata* filteredSettings /*out*/); static Status pickConstrainedModeSize(camera_metadata_t *staticMeta, AvailableStream &hfrStream); static Status isZSLModeAvailable(const camera_metadata_t *staticMeta); static Status isZSLModeAvailable(const camera_metadata_t *staticMeta, ReprocessType reprocType); static Status getZSLInputOutputMap(camera_metadata_t *staticMeta, std::vector &inputOutputMap); static Status findLargestSize( const std::vector &streamSizes, int32_t format, AvailableStream &result); static Status isAutoFocusModeAvailable( CameraParameters &cameraParams, const char *mode) ; static Status isMonochromeCamera(const camera_metadata_t *staticMeta); static Status getSystemCameraKind(const camera_metadata_t* staticMeta, SystemCameraKind* systemCameraKind); static void getMultiResolutionStreamConfigurations( camera_metadata_ro_entry* multiResStreamConfigs, camera_metadata_ro_entry* streamConfigs, camera_metadata_ro_entry* maxResolutionStreamConfigs, const camera_metadata_t* staticMetadata); void getPrivacyTestPatternModes( const camera_metadata_t* staticMetadata, std::unordered_set* privacyTestPatternModes/*out*/); static V3_2::DataspaceFlags getDataspace(PixelFormat format); void processCaptureRequestInternal(uint64_t bufferusage, RequestTemplate reqTemplate, bool useSecureOnlyCameras); // Used by switchToOffline where a new result queue is created for offline reqs void updateInflightResultQueue(std::shared_ptr resultQueue); protected: // In-flight queue for tracking completion of capture requests. struct InFlightRequest { // Set by notify() SHUTTER call. nsecs_t shutterTimestamp; bool shutterReadoutTimestampValid; nsecs_t shutterReadoutTimestamp; bool errorCodeValid; ErrorCode errorCode; //Is partial result supported bool usePartialResult; //Partial result count expected uint32_t numPartialResults; // Message queue std::shared_ptr resultQueue; // Set by process_capture_result call with valid metadata bool haveResultMetadata; // Decremented by calls to process_capture_result with valid output // and input buffers ssize_t numBuffersLeft; // A 64bit integer to index the frame number associated with this result. int64_t frameNumber; // The partial result count (index) for this capture result. int32_t partialResultCount; // For buffer drop errors, the stream ID for the stream that lost a buffer. // For physical sub-camera result errors, the Id of the physical stream // for the physical sub-camera. // Otherwise -1. int32_t errorStreamId; // If this request has any input buffer bool hasInputBuffer; // Result metadata ::android::hardware::camera::common::V1_0::helper::CameraMetadata collectedResult; // Buffers are added by process_capture_result when output buffers // return from HAL but framework. ::android::Vector resultOutputBuffers; std::unordered_set expectedPhysicalResults; InFlightRequest() : shutterTimestamp(0), shutterReadoutTimestampValid(false), shutterReadoutTimestamp(0), errorCodeValid(false), errorCode(ErrorCode::ERROR_BUFFER), usePartialResult(false), numPartialResults(0), resultQueue(nullptr), haveResultMetadata(false), numBuffersLeft(0), frameNumber(0), partialResultCount(0), errorStreamId(-1), hasInputBuffer(false), collectedResult(1, 10) {} InFlightRequest(ssize_t numBuffers, bool hasInput, bool partialResults, uint32_t partialCount, std::shared_ptr queue = nullptr) : shutterTimestamp(0), shutterReadoutTimestampValid(false), shutterReadoutTimestamp(0), errorCodeValid(false), errorCode(ErrorCode::ERROR_BUFFER), usePartialResult(partialResults), numPartialResults(partialCount), resultQueue(queue), haveResultMetadata(false), numBuffersLeft(numBuffers), frameNumber(0), partialResultCount(0), errorStreamId(-1), hasInputBuffer(hasInput), collectedResult(1, 10) {} InFlightRequest(ssize_t numBuffers, bool hasInput, bool partialResults, uint32_t partialCount, const std::unordered_set& extraPhysicalResult, std::shared_ptr queue = nullptr) : shutterTimestamp(0), shutterReadoutTimestampValid(false), shutterReadoutTimestamp(0), errorCodeValid(false), errorCode(ErrorCode::ERROR_BUFFER), usePartialResult(partialResults), numPartialResults(partialCount), resultQueue(queue), haveResultMetadata(false), numBuffersLeft(numBuffers), frameNumber(0), partialResultCount(0), errorStreamId(-1), hasInputBuffer(hasInput), collectedResult(1, 10), expectedPhysicalResults(extraPhysicalResult) {} }; // Map from frame number to the in-flight request state typedef ::android::KeyedVector InFlightMap; std::mutex mLock; // Synchronize access to member variables std::condition_variable mResultCondition; // Condition variable for incoming results InFlightMap mInflightMap; // Map of all inflight requests DataCallbackMsg mDataMessageTypeReceived; // Most recent message type received through data callbacks uint32_t mVideoBufferIndex; // Buffer index of the most recent video buffer uint32_t mVideoData; // Buffer data of the most recent video buffer hidl_handle mVideoNativeHandle; // Most recent video buffer native handle NotifyCallbackMsg mNotifyMessage; // Current notification message std::mutex mTorchLock; // Synchronize access to torch status std::condition_variable mTorchCond; // Condition variable for torch status TorchModeStatus mTorchStatus; // Current torch status // Holds camera registered buffers std::unordered_map > mMemoryPool; // Camera provider service sp mProvider; sp<::android::hardware::camera::provider::V2_5::ICameraProvider> mProvider2_5; sp<::android::hardware::camera::provider::V2_6::ICameraProvider> mProvider2_6; sp<::android::hardware::camera::provider::V2_7::ICameraProvider> mProvider2_7; // Camera provider type. std::string mProviderType; HandleImporter mHandleImporter; }; Return CameraHidlTest::Camera1DeviceCb::notifyCallback( NotifyCallbackMsg msgType, int32_t ext1 __unused, int32_t ext2 __unused) { std::unique_lock l(mParent->mLock); mParent->mNotifyMessage = msgType; mParent->mResultCondition.notify_one(); return Void(); } Return CameraHidlTest::Camera1DeviceCb::registerMemory( const hidl_handle& descriptor, uint32_t bufferSize, uint32_t bufferCount) { if (descriptor->numFds != 1) { ADD_FAILURE() << "camera memory descriptor has" " numFds " << descriptor->numFds << " (expect 1)" ; return 0; } if (descriptor->data[0] < 0) { ADD_FAILURE() << "camera memory descriptor has" " FD " << descriptor->data[0] << " (expect >= 0)"; return 0; } sp<::android::MemoryHeapBase> pool = new ::android::MemoryHeapBase( descriptor->data[0], bufferSize*bufferCount, 0, 0); mParent->mMemoryPool.emplace(pool->getHeapID(), pool); return pool->getHeapID(); } Return CameraHidlTest::Camera1DeviceCb::unregisterMemory(uint32_t memId) { if (mParent->mMemoryPool.count(memId) == 0) { ALOGE("%s: memory pool ID %d not found", __FUNCTION__, memId); ADD_FAILURE(); return Void(); } mParent->mMemoryPool.erase(memId); return Void(); } Return CameraHidlTest::Camera1DeviceCb::dataCallback( DataCallbackMsg msgType __unused, uint32_t data __unused, uint32_t bufferIndex __unused, const CameraFrameMetadata& metadata __unused) { std::unique_lock l(mParent->mLock); mParent->mDataMessageTypeReceived = msgType; mParent->mResultCondition.notify_one(); return Void(); } Return CameraHidlTest::Camera1DeviceCb::dataCallbackTimestamp( DataCallbackMsg msgType, uint32_t data, uint32_t bufferIndex, int64_t timestamp __unused) { std::unique_lock l(mParent->mLock); mParent->mDataMessageTypeReceived = msgType; mParent->mVideoBufferIndex = bufferIndex; if (mParent->mMemoryPool.count(data) == 0) { ADD_FAILURE() << "memory pool ID " << data << "not found"; } mParent->mVideoData = data; mParent->mResultCondition.notify_one(); return Void(); } Return CameraHidlTest::Camera1DeviceCb::handleCallbackTimestamp( DataCallbackMsg msgType, const hidl_handle& frameData, uint32_t data __unused, uint32_t bufferIndex, int64_t timestamp __unused) { std::unique_lock l(mParent->mLock); mParent->mDataMessageTypeReceived = msgType; mParent->mVideoBufferIndex = bufferIndex; if (mParent->mMemoryPool.count(data) == 0) { ADD_FAILURE() << "memory pool ID " << data << " not found"; } mParent->mVideoData = data; mParent->mVideoNativeHandle = frameData; mParent->mResultCondition.notify_one(); return Void(); } Return CameraHidlTest::Camera1DeviceCb::handleCallbackTimestampBatch( DataCallbackMsg msgType, const hidl_vec& batch) { std::unique_lock l(mParent->mLock); for (auto& msg : batch) { mParent->mDataMessageTypeReceived = msgType; mParent->mVideoBufferIndex = msg.bufferIndex; if (mParent->mMemoryPool.count(msg.data) == 0) { ADD_FAILURE() << "memory pool ID " << msg.data << " not found"; } mParent->mVideoData = msg.data; mParent->mVideoNativeHandle = msg.frameData; mParent->mResultCondition.notify_one(); } return Void(); } Return CameraHidlTest::DeviceCb::processCaptureResult_3_4( const hidl_vec& results) { if (nullptr == mParent) { return Void(); } bool notify = false; std::unique_lock l(mParent->mLock); for (size_t i = 0 ; i < results.size(); i++) { notify = processCaptureResultLocked(results[i].v3_2, results[i].physicalCameraMetadata); } l.unlock(); if (notify) { mParent->mResultCondition.notify_one(); } return Void(); } Return CameraHidlTest::DeviceCb::processCaptureResult( const hidl_vec& results) { if (nullptr == mParent) { return Void(); } bool notify = false; std::unique_lock l(mParent->mLock); ::android::hardware::hidl_vec noPhysMetadata; for (size_t i = 0 ; i < results.size(); i++) { notify = processCaptureResultLocked(results[i], noPhysMetadata); } l.unlock(); if (notify) { mParent->mResultCondition.notify_one(); } return Void(); } bool CameraHidlTest::DeviceCb::processCaptureResultLocked(const CaptureResult& results, hidl_vec physicalCameraMetadata) { bool notify = false; uint32_t frameNumber = results.frameNumber; if ((results.result.size() == 0) && (results.outputBuffers.size() == 0) && (results.inputBuffer.buffer == nullptr) && (results.fmqResultSize == 0)) { ALOGE("%s: No result data provided by HAL for frame %d result count: %d", __func__, frameNumber, (int) results.fmqResultSize); ADD_FAILURE(); return notify; } ssize_t idx = mParent->mInflightMap.indexOfKey(frameNumber); if (::android::NAME_NOT_FOUND == idx) { ALOGE("%s: Unexpected frame number! received: %u", __func__, frameNumber); ADD_FAILURE(); return notify; } bool isPartialResult = false; bool hasInputBufferInRequest = false; InFlightRequest *request = mParent->mInflightMap.editValueAt(idx); ::android::hardware::camera::device::V3_2::CameraMetadata resultMetadata; size_t resultSize = 0; if (results.fmqResultSize > 0) { resultMetadata.resize(results.fmqResultSize); if (request->resultQueue == nullptr) { ADD_FAILURE(); return notify; } if (!request->resultQueue->read(resultMetadata.data(), results.fmqResultSize)) { ALOGE("%s: Frame %d: Cannot read camera metadata from fmq," "size = %" PRIu64, __func__, frameNumber, results.fmqResultSize); ADD_FAILURE(); return notify; } // Physical device results are only expected in the last/final // partial result notification. bool expectPhysicalResults = !(request->usePartialResult && (results.partialResult < request->numPartialResults)); if (expectPhysicalResults && (physicalCameraMetadata.size() != request->expectedPhysicalResults.size())) { ALOGE("%s: Frame %d: Returned physical metadata count %zu " "must be equal to expected count %zu", __func__, frameNumber, physicalCameraMetadata.size(), request->expectedPhysicalResults.size()); ADD_FAILURE(); return notify; } std::vector<::android::hardware::camera::device::V3_2::CameraMetadata> physResultMetadata; physResultMetadata.resize(physicalCameraMetadata.size()); for (size_t i = 0; i < physicalCameraMetadata.size(); i++) { physResultMetadata[i].resize(physicalCameraMetadata[i].fmqMetadataSize); if (!request->resultQueue->read(physResultMetadata[i].data(), physicalCameraMetadata[i].fmqMetadataSize)) { ALOGE("%s: Frame %d: Cannot read physical camera metadata from fmq," "size = %" PRIu64, __func__, frameNumber, physicalCameraMetadata[i].fmqMetadataSize); ADD_FAILURE(); return notify; } } resultSize = resultMetadata.size(); } else if (results.result.size() > 0) { resultMetadata.setToExternal(const_cast( results.result.data()), results.result.size()); resultSize = resultMetadata.size(); } if (!request->usePartialResult && (resultSize > 0) && (results.partialResult != 1)) { ALOGE("%s: Result is malformed for frame %d: partial_result %u " "must be 1 if partial result is not supported", __func__, frameNumber, results.partialResult); ADD_FAILURE(); return notify; } if (results.partialResult != 0) { request->partialResultCount = results.partialResult; } // Check if this result carries only partial metadata if (request->usePartialResult && (resultSize > 0)) { if ((results.partialResult > request->numPartialResults) || (results.partialResult < 1)) { ALOGE("%s: Result is malformed for frame %d: partial_result %u" " must be in the range of [1, %d] when metadata is " "included in the result", __func__, frameNumber, results.partialResult, request->numPartialResults); ADD_FAILURE(); return notify; } // Verify no duplicate tags between partial results const camera_metadata_t* partialMetadata = reinterpret_cast(resultMetadata.data()); const camera_metadata_t* collectedMetadata = request->collectedResult.getAndLock(); camera_metadata_ro_entry_t searchEntry, foundEntry; for (size_t i = 0; i < get_camera_metadata_entry_count(partialMetadata); i++) { if (0 != get_camera_metadata_ro_entry(partialMetadata, i, &searchEntry)) { ADD_FAILURE(); request->collectedResult.unlock(collectedMetadata); return notify; } if (-ENOENT != find_camera_metadata_ro_entry(collectedMetadata, searchEntry.tag, &foundEntry)) { ADD_FAILURE(); request->collectedResult.unlock(collectedMetadata); return notify; } } request->collectedResult.unlock(collectedMetadata); request->collectedResult.append(partialMetadata); isPartialResult = (results.partialResult < request->numPartialResults); } else if (resultSize > 0) { request->collectedResult.append(reinterpret_cast( resultMetadata.data())); isPartialResult = false; } hasInputBufferInRequest = request->hasInputBuffer; // Did we get the (final) result metadata for this capture? if ((resultSize > 0) && !isPartialResult) { if (request->haveResultMetadata) { ALOGE("%s: Called multiple times with metadata for frame %d", __func__, frameNumber); ADD_FAILURE(); return notify; } request->haveResultMetadata = true; request->collectedResult.sort(); // Verify final result metadata bool isAtLeast_3_5 = mDeviceVersion >= CAMERA_DEVICE_API_VERSION_3_5; if (isAtLeast_3_5) { auto staticMetadataBuffer = mStaticMetadata.getAndLock(); bool isMonochrome = Status::OK == CameraHidlTest::isMonochromeCamera(staticMetadataBuffer); if (isMonochrome) { mParent->verifyMonochromeCameraResult(request->collectedResult); } // Verify logical camera result metadata bool isLogicalCamera = Status::OK == CameraHidlTest::isLogicalMultiCamera(staticMetadataBuffer); if (isLogicalCamera) { mParent->verifyLogicalCameraResult(staticMetadataBuffer, request->collectedResult); } mStaticMetadata.unlock(staticMetadataBuffer); } } uint32_t numBuffersReturned = results.outputBuffers.size(); if (results.inputBuffer.buffer != nullptr) { if (hasInputBufferInRequest) { numBuffersReturned += 1; } else { ALOGW("%s: Input buffer should be NULL if there is no input" " buffer sent in the request", __func__); } } request->numBuffersLeft -= numBuffersReturned; if (request->numBuffersLeft < 0) { ALOGE("%s: Too many buffers returned for frame %d", __func__, frameNumber); ADD_FAILURE(); return notify; } request->resultOutputBuffers.appendArray(results.outputBuffers.data(), results.outputBuffers.size()); // If shutter event is received notify the pending threads. if (request->shutterTimestamp != 0) { notify = true; } if (mUseHalBufManager) { // Don't return buffers of bufId 0 (empty buffer) std::vector buffers; for (const auto& sb : results.outputBuffers) { if (sb.bufferId != 0) { buffers.push_back(sb); } } returnStreamBuffers(buffers); } return notify; } void CameraHidlTest::DeviceCb::setCurrentStreamConfig( const hidl_vec& streams, const hidl_vec& halStreams) { ASSERT_EQ(streams.size(), halStreams.size()); ASSERT_NE(streams.size(), 0); for (size_t i = 0; i < streams.size(); i++) { ASSERT_EQ(streams[i].v3_2.id, halStreams[i].id); } std::lock_guard l(mLock); mUseHalBufManager = true; mStreams = streams; mHalStreams = halStreams; mOutstandingBufferIds.clear(); for (size_t i = 0; i < streams.size(); i++) { mOutstandingBufferIds.emplace_back(); } } bool CameraHidlTest::DeviceCb::hasOutstandingBuffersLocked() { if (!mUseHalBufManager) { return false; } for (const auto& outstandingBuffers : mOutstandingBufferIds) { if (!outstandingBuffers.empty()) { return true; } } return false; } void CameraHidlTest::DeviceCb::waitForBuffersReturned() { std::unique_lock lk(mLock); if (hasOutstandingBuffersLocked()) { auto timeout = std::chrono::seconds(kBufferReturnTimeoutSec); auto st = mFlushedCondition.wait_for(lk, timeout); ASSERT_NE(std::cv_status::timeout, st); } } Return CameraHidlTest::DeviceCb::notify( const hidl_vec& messages) { std::vector> readoutTimestamps; readoutTimestamps.resize(messages.size()); for (size_t i = 0; i < messages.size(); i++) { readoutTimestamps[i] = {false, 0}; } return notifyHelper(messages, readoutTimestamps); } Return CameraHidlTest::DeviceCb::notifyHelper( const hidl_vec& messages, const std::vector>& readoutTimestamps) { std::lock_guard l(mParent->mLock); for (size_t i = 0; i < messages.size(); i++) { switch(messages[i].type) { case MsgType::ERROR: if (ErrorCode::ERROR_DEVICE == messages[i].msg.error.errorCode) { ALOGE("%s: Camera reported serious device error", __func__); ADD_FAILURE(); } else { ssize_t idx = mParent->mInflightMap.indexOfKey( messages[i].msg.error.frameNumber); if (::android::NAME_NOT_FOUND == idx) { ALOGE("%s: Unexpected error frame number! received: %u", __func__, messages[i].msg.error.frameNumber); ADD_FAILURE(); break; } InFlightRequest *r = mParent->mInflightMap.editValueAt(idx); if (ErrorCode::ERROR_RESULT == messages[i].msg.error.errorCode && messages[i].msg.error.errorStreamId != -1) { if (r->haveResultMetadata) { ALOGE("%s: Camera must report physical camera result error before " "the final capture result!", __func__); ADD_FAILURE(); } else { for (size_t j = 0; j < mStreams.size(); j++) { if (mStreams[j].v3_2.id == messages[i].msg.error.errorStreamId) { hidl_string physicalCameraId = mStreams[j].physicalCameraId; bool idExpected = r->expectedPhysicalResults.find( physicalCameraId) != r->expectedPhysicalResults.end(); if (!idExpected) { ALOGE("%s: ERROR_RESULT's error stream's physicalCameraId " "%s must be expected", __func__, physicalCameraId.c_str()); ADD_FAILURE(); } else { r->expectedPhysicalResults.erase(physicalCameraId); } break; } } } } else { r->errorCodeValid = true; r->errorCode = messages[i].msg.error.errorCode; r->errorStreamId = messages[i].msg.error.errorStreamId; } } break; case MsgType::SHUTTER: { ssize_t idx = mParent->mInflightMap.indexOfKey(messages[i].msg.shutter.frameNumber); if (::android::NAME_NOT_FOUND == idx) { ALOGE("%s: Unexpected shutter frame number! received: %u", __func__, messages[i].msg.shutter.frameNumber); ADD_FAILURE(); break; } InFlightRequest *r = mParent->mInflightMap.editValueAt(idx); r->shutterTimestamp = messages[i].msg.shutter.timestamp; r->shutterReadoutTimestampValid = readoutTimestamps[i].first; r->shutterReadoutTimestamp = readoutTimestamps[i].second; } break; default: ALOGE("%s: Unsupported notify message %d", __func__, messages[i].type); ADD_FAILURE(); break; } } mParent->mResultCondition.notify_one(); return Void(); } Return CameraHidlTest::DeviceCb::requestStreamBuffers( const hidl_vec& bufReqs, requestStreamBuffers_cb _hidl_cb) { using V3_5::BufferRequestStatus; using V3_5::StreamBufferRet; using V3_5::StreamBufferRequestError; hidl_vec bufRets; std::unique_lock l(mLock); if (!mUseHalBufManager) { ALOGE("%s: Camera does not support HAL buffer management", __FUNCTION__); ADD_FAILURE(); _hidl_cb(BufferRequestStatus::FAILED_ILLEGAL_ARGUMENTS, bufRets); return Void(); } if (bufReqs.size() > mStreams.size()) { ALOGE("%s: illegal buffer request: too many requests!", __FUNCTION__); ADD_FAILURE(); _hidl_cb(BufferRequestStatus::FAILED_ILLEGAL_ARGUMENTS, bufRets); return Void(); } std::vector indexes(bufReqs.size()); for (size_t i = 0; i < bufReqs.size(); i++) { bool found = false; for (size_t idx = 0; idx < mStreams.size(); idx++) { if (bufReqs[i].streamId == mStreams[idx].v3_2.id) { found = true; indexes[i] = idx; break; } } if (!found) { ALOGE("%s: illegal buffer request: unknown streamId %d!", __FUNCTION__, bufReqs[i].streamId); ADD_FAILURE(); _hidl_cb(BufferRequestStatus::FAILED_ILLEGAL_ARGUMENTS, bufRets); return Void(); } } bool allStreamOk = true; bool atLeastOneStreamOk = false; bufRets.resize(bufReqs.size()); for (size_t i = 0; i < bufReqs.size(); i++) { int32_t idx = indexes[i]; const auto& stream = mStreams[idx]; const auto& halStream = mHalStreams[idx]; const V3_5::BufferRequest& bufReq = bufReqs[i]; if (mOutstandingBufferIds[idx].size() + bufReq.numBuffersRequested > halStream.maxBuffers) { bufRets[i].streamId = stream.v3_2.id; bufRets[i].val.error(StreamBufferRequestError::MAX_BUFFER_EXCEEDED); allStreamOk = false; continue; } hidl_vec tmpRetBuffers(bufReq.numBuffersRequested); for (size_t j = 0; j < bufReq.numBuffersRequested; j++) { hidl_handle buffer_handle; uint32_t w = stream.v3_2.width; uint32_t h = stream.v3_2.height; if (stream.v3_2.format == PixelFormat::BLOB) { w = stream.bufferSize; h = 1; } mParent->allocateGraphicBuffer(w, h, android_convertGralloc1To0Usage( halStream.producerUsage, halStream.consumerUsage), halStream.overrideFormat, &buffer_handle); tmpRetBuffers[j] = {stream.v3_2.id, mNextBufferId, buffer_handle, BufferStatus::OK, nullptr, nullptr}; mOutstandingBufferIds[idx].insert(std::make_pair(mNextBufferId++, buffer_handle)); } atLeastOneStreamOk = true; bufRets[i].streamId = stream.v3_2.id; bufRets[i].val.buffers(std::move(tmpRetBuffers)); } if (allStreamOk) { _hidl_cb(BufferRequestStatus::OK, bufRets); } else if (atLeastOneStreamOk) { _hidl_cb(BufferRequestStatus::FAILED_PARTIAL, bufRets); } else { _hidl_cb(BufferRequestStatus::FAILED_UNKNOWN, bufRets); } if (!hasOutstandingBuffersLocked()) { l.unlock(); mFlushedCondition.notify_one(); } return Void(); } Return CameraHidlTest::DeviceCb::returnStreamBuffers( const hidl_vec& buffers) { if (!mUseHalBufManager) { ALOGE("%s: Camera does not support HAL buffer management", __FUNCTION__); ADD_FAILURE(); } std::unique_lock l(mLock); for (const auto& buf : buffers) { bool found = false; for (size_t idx = 0; idx < mOutstandingBufferIds.size(); idx++) { if (mStreams[idx].v3_2.id == buf.streamId && mOutstandingBufferIds[idx].count(buf.bufferId) == 1) { mOutstandingBufferIds[idx].erase(buf.bufferId); // TODO: check do we need to close/delete native handle or assume we have enough // memory to run till the test finish? since we do not capture much requests (and // most of time one buffer is sufficient) found = true; break; } } if (found) { continue; } ALOGE("%s: unknown buffer ID %" PRIu64, __FUNCTION__, buf.bufferId); ADD_FAILURE(); } if (!hasOutstandingBuffersLocked()) { l.unlock(); mFlushedCondition.notify_one(); } return Void(); } std::map CameraHidlTest::getCameraDeviceIdToNameMap( sp provider) { hidl_vec cameraDeviceNames = getCameraDeviceNames(provider); std::map idToNameMap; for (auto& name : cameraDeviceNames) { std::string version, cameraId; if (!matchDeviceName(name, mProviderType, &version, &cameraId)) { ADD_FAILURE(); } idToNameMap.insert(std::make_pair(hidl_string(cameraId), name)); } return idToNameMap; } hidl_vec CameraHidlTest::getCameraDeviceNames(sp provider, bool addSecureOnly) { std::vector cameraDeviceNames; Return ret; ret = provider->getCameraIdList( [&](auto status, const auto& idList) { ALOGI("getCameraIdList returns status:%d", (int)status); for (size_t i = 0; i < idList.size(); i++) { ALOGI("Camera Id[%zu] is %s", i, idList[i].c_str()); } ASSERT_EQ(Status::OK, status); for (const auto& id : idList) { cameraDeviceNames.push_back(id); } }); if (!ret.isOk()) { ADD_FAILURE(); } // External camera devices are reported through cameraDeviceStatusChange struct ProviderCb : public ICameraProviderCallback { virtual Return cameraDeviceStatusChange( const hidl_string& devName, CameraDeviceStatus newStatus) override { ALOGI("camera device status callback name %s, status %d", devName.c_str(), (int) newStatus); if (newStatus == CameraDeviceStatus::PRESENT) { externalCameraDeviceNames.push_back(devName); } return Void(); } virtual Return torchModeStatusChange( const hidl_string&, TorchModeStatus) override { return Void(); } std::vector externalCameraDeviceNames; }; sp cb = new ProviderCb; auto status = mProvider->setCallback(cb); for (const auto& devName : cb->externalCameraDeviceNames) { if (cameraDeviceNames.end() == std::find( cameraDeviceNames.begin(), cameraDeviceNames.end(), devName)) { cameraDeviceNames.push_back(devName); } } std::vector retList; for (size_t i = 0; i < cameraDeviceNames.size(); i++) { bool isSecureOnlyCamera = isSecureOnly(mProvider, cameraDeviceNames[i]); if (addSecureOnly) { if (isSecureOnlyCamera) { retList.emplace_back(cameraDeviceNames[i]); } } else if (!isSecureOnlyCamera) { retList.emplace_back(cameraDeviceNames[i]); } } hidl_vec finalRetList = std::move(retList); return finalRetList; } bool CameraHidlTest::isSecureOnly(sp provider, const hidl_string& name) { Return ret; ::android::sp device3_x; bool retVal = false; if (getCameraDeviceVersion(name, mProviderType) == CAMERA_DEVICE_API_VERSION_1_0) { return false; } ret = provider->getCameraDeviceInterface_V3_x(name, [&](auto status, const auto& device) { ALOGI("getCameraDeviceInterface_V3_x returns status:%d", (int)status); ASSERT_EQ(Status::OK, status); ASSERT_NE(device, nullptr); device3_x = device; }); if (!ret.isOk()) { ADD_FAILURE() << "Failed to get camera device interface for " << name; } ret = device3_x->getCameraCharacteristics([&](Status s, CameraMetadata metadata) { ASSERT_EQ(Status::OK, s); camera_metadata_t* chars = (camera_metadata_t*)metadata.data(); SystemCameraKind systemCameraKind = SystemCameraKind::PUBLIC; Status status = getSystemCameraKind(chars, &systemCameraKind); ASSERT_EQ(status, Status::OK); if (systemCameraKind == SystemCameraKind::HIDDEN_SECURE_CAMERA) { retVal = true; } }); if (!ret.isOk()) { ADD_FAILURE() << "Failed to get camera characteristics for device " << name; } return retVal; } hidl_vec> CameraHidlTest::getConcurrentDeviceCombinations( sp<::android::hardware::camera::provider::V2_6::ICameraProvider>& provider2_6) { hidl_vec> combinations; Return ret = provider2_6->getConcurrentStreamingCameraIds( [&combinations](Status concurrentIdStatus, const hidl_vec>& cameraDeviceIdCombinations) { ASSERT_EQ(concurrentIdStatus, Status::OK); combinations = cameraDeviceIdCombinations; }); if (!ret.isOk()) { ADD_FAILURE(); } return combinations; } // Test devices with first_api_level >= P does not advertise device@1.0 TEST_P(CameraHidlTest, noHal1AfterP) { constexpr int32_t HAL1_PHASE_OUT_API_LEVEL = 28; int32_t firstApiLevel = 0; getFirstApiLevel(&firstApiLevel); // all devices with first API level == 28 and <= 1GB of RAM must set low_ram // and thus be allowed to continue using HAL1 if ((firstApiLevel == HAL1_PHASE_OUT_API_LEVEL) && (property_get_bool("ro.config.low_ram", /*default*/ false))) { ALOGI("Hal1 allowed for low ram device"); return; } if (firstApiLevel >= HAL1_PHASE_OUT_API_LEVEL) { hidl_vec cameraDeviceNames = getCameraDeviceNames(mProvider); for (const auto& name : cameraDeviceNames) { int deviceVersion = getCameraDeviceVersion(name, mProviderType); ASSERT_NE(deviceVersion, 0); // Must be a valid device version ASSERT_NE(deviceVersion, CAMERA_DEVICE_API_VERSION_1_0); // Must not be device@1.0 } } } // Test if ICameraProvider::isTorchModeSupported returns Status::OK // Also if first_api_level >= Q torch API must be supported. TEST_P(CameraHidlTest, isTorchModeSupported) { constexpr int32_t API_LEVEL_Q = 29; int32_t firstApiLevel = 0; getFirstApiLevel(&firstApiLevel); Return ret; ret = mProvider->isSetTorchModeSupported([&](auto status, bool support) { ALOGI("isSetTorchModeSupported returns status:%d supported:%d", (int)status, support); ASSERT_EQ(Status::OK, status); if (firstApiLevel >= API_LEVEL_Q) { ASSERT_EQ(true, support); } }); ASSERT_TRUE(ret.isOk()); } // TODO: consider removing this test if getCameraDeviceNames() has the same coverage TEST_P(CameraHidlTest, getCameraIdList) { Return ret; ret = mProvider->getCameraIdList([&](auto status, const auto& idList) { ALOGI("getCameraIdList returns status:%d", (int)status); for (size_t i = 0; i < idList.size(); i++) { ALOGI("Camera Id[%zu] is %s", i, idList[i].c_str()); } ASSERT_EQ(Status::OK, status); }); ASSERT_TRUE(ret.isOk()); } // Test if ICameraProvider::getVendorTags returns Status::OK TEST_P(CameraHidlTest, getVendorTags) { Return ret; ret = mProvider->getVendorTags([&](auto status, const auto& vendorTagSecs) { ALOGI("getVendorTags returns status:%d numSections %zu", (int)status, vendorTagSecs.size()); for (size_t i = 0; i < vendorTagSecs.size(); i++) { ALOGI("Vendor tag section %zu name %s", i, vendorTagSecs[i].sectionName.c_str()); for (size_t j = 0; j < vendorTagSecs[i].tags.size(); j++) { const auto& tag = vendorTagSecs[i].tags[j]; ALOGI("Vendor tag id %u name %s type %d", tag.tagId, tag.tagName.c_str(), (int)tag.tagType); } } ASSERT_EQ(Status::OK, status); }); ASSERT_TRUE(ret.isOk()); } // Test if ICameraProvider::setCallback returns Status::OK TEST_P(CameraHidlTest, setCallback) { struct ProviderCb : public ICameraProviderCallback { virtual Return cameraDeviceStatusChange( const hidl_string& cameraDeviceName, CameraDeviceStatus newStatus) override { ALOGI("camera device status callback name %s, status %d", cameraDeviceName.c_str(), (int) newStatus); return Void(); } virtual Return torchModeStatusChange( const hidl_string& cameraDeviceName, TorchModeStatus newStatus) override { ALOGI("Torch mode status callback name %s, status %d", cameraDeviceName.c_str(), (int) newStatus); return Void(); } }; struct ProviderCb2_6 : public ::android::hardware::camera::provider::V2_6::ICameraProviderCallback { virtual Return cameraDeviceStatusChange(const hidl_string& cameraDeviceName, CameraDeviceStatus newStatus) override { ALOGI("camera device status callback name %s, status %d", cameraDeviceName.c_str(), (int)newStatus); return Void(); } virtual Return torchModeStatusChange(const hidl_string& cameraDeviceName, TorchModeStatus newStatus) override { ALOGI("Torch mode status callback name %s, status %d", cameraDeviceName.c_str(), (int)newStatus); return Void(); } virtual Return physicalCameraDeviceStatusChange( const hidl_string& cameraDeviceName, const hidl_string& physicalCameraDeviceName, CameraDeviceStatus newStatus) override { ALOGI("physical camera device status callback name %s, physical camera name %s," " status %d", cameraDeviceName.c_str(), physicalCameraDeviceName.c_str(), (int)newStatus); return Void(); } }; sp cb = new ProviderCb; auto status = mProvider->setCallback(cb); ASSERT_TRUE(status.isOk()); ASSERT_EQ(Status::OK, status); status = mProvider->setCallback(nullptr); ASSERT_TRUE(status.isOk()); ASSERT_EQ(Status::OK, status); if (mProvider2_6.get() != nullptr) { sp cb = new ProviderCb2_6; auto status = mProvider2_6->setCallback(cb); ASSERT_TRUE(status.isOk()); ASSERT_EQ(Status::OK, status); status = mProvider2_6->setCallback(nullptr); ASSERT_TRUE(status.isOk()); ASSERT_EQ(Status::OK, status); } } // Test if ICameraProvider::getCameraDeviceInterface returns Status::OK and non-null device TEST_P(CameraHidlTest, getCameraDeviceInterface) { hidl_vec cameraDeviceNames = getCameraDeviceNames(mProvider); for (const auto& name : cameraDeviceNames) { int deviceVersion = getCameraDeviceVersion(name, mProviderType); switch (deviceVersion) { case CAMERA_DEVICE_API_VERSION_3_7: case CAMERA_DEVICE_API_VERSION_3_6: case CAMERA_DEVICE_API_VERSION_3_5: case CAMERA_DEVICE_API_VERSION_3_4: case CAMERA_DEVICE_API_VERSION_3_3: case CAMERA_DEVICE_API_VERSION_3_2: { Return ret; ret = mProvider->getCameraDeviceInterface_V3_x( name, [&](auto status, const auto& device3_x) { ALOGI("getCameraDeviceInterface_V3_x returns status:%d", (int)status); ASSERT_EQ(Status::OK, status); ASSERT_NE(device3_x, nullptr); }); ASSERT_TRUE(ret.isOk()); } break; case CAMERA_DEVICE_API_VERSION_1_0: { Return ret; ret = mProvider->getCameraDeviceInterface_V1_x( name, [&](auto status, const auto& device1) { ALOGI("getCameraDeviceInterface_V1_x returns status:%d", (int)status); ASSERT_EQ(Status::OK, status); ASSERT_NE(device1, nullptr); }); ASSERT_TRUE(ret.isOk()); } break; default: { ALOGE("%s: Unsupported device version %d", __func__, deviceVersion); ADD_FAILURE(); } break; } } } // Verify that the device resource cost can be retrieved and the values are // correct. TEST_P(CameraHidlTest, getResourceCost) { hidl_vec cameraDeviceNames = getCameraDeviceNames(mProvider); for (const auto& name : cameraDeviceNames) { int deviceVersion = getCameraDeviceVersion(name, mProviderType); switch (deviceVersion) { case CAMERA_DEVICE_API_VERSION_3_7: case CAMERA_DEVICE_API_VERSION_3_6: case CAMERA_DEVICE_API_VERSION_3_5: case CAMERA_DEVICE_API_VERSION_3_4: case CAMERA_DEVICE_API_VERSION_3_3: case CAMERA_DEVICE_API_VERSION_3_2: { ::android::sp<::android::hardware::camera::device::V3_2::ICameraDevice> device3_x; ALOGI("getResourceCost: Testing camera device %s", name.c_str()); Return ret; ret = mProvider->getCameraDeviceInterface_V3_x( name, [&](auto status, const auto& device) { ALOGI("getCameraDeviceInterface_V3_x returns status:%d", (int)status); ASSERT_EQ(Status::OK, status); ASSERT_NE(device, nullptr); device3_x = device; }); ASSERT_TRUE(ret.isOk()); ret = device3_x->getResourceCost([&](auto status, const auto& resourceCost) { ALOGI("getResourceCost returns status:%d", (int)status); ASSERT_EQ(Status::OK, status); ALOGI(" Resource cost is %d", resourceCost.resourceCost); ASSERT_LE(resourceCost.resourceCost, 100u); for (const auto& name : resourceCost.conflictingDevices) { ALOGI(" Conflicting device: %s", name.c_str()); } }); ASSERT_TRUE(ret.isOk()); } break; case CAMERA_DEVICE_API_VERSION_1_0: { ::android::sp<::android::hardware::camera::device::V1_0::ICameraDevice> device1; ALOGI("getResourceCost: Testing camera device %s", name.c_str()); Return ret; ret = mProvider->getCameraDeviceInterface_V1_x( name, [&](auto status, const auto& device) { ALOGI("getCameraDeviceInterface_V1_x returns status:%d", (int)status); ASSERT_EQ(Status::OK, status); ASSERT_NE(device, nullptr); device1 = device; }); ASSERT_TRUE(ret.isOk()); ret = device1->getResourceCost([&](auto status, const auto& resourceCost) { ALOGI("getResourceCost returns status:%d", (int)status); ASSERT_EQ(Status::OK, status); ALOGI(" Resource cost is %d", resourceCost.resourceCost); ASSERT_LE(resourceCost.resourceCost, 100u); for (const auto& name : resourceCost.conflictingDevices) { ALOGI(" Conflicting device: %s", name.c_str()); } }); ASSERT_TRUE(ret.isOk()); } break; default: { ALOGE("%s: Unsupported device version %d", __func__, deviceVersion); ADD_FAILURE(); } break; } } } // Verify that the static camera info can be retrieved // successfully. TEST_P(CameraHidlTest, getCameraInfo) { hidl_vec cameraDeviceNames = getCameraDeviceNames(mProvider); for (const auto& name : cameraDeviceNames) { if (getCameraDeviceVersion(name, mProviderType) == CAMERA_DEVICE_API_VERSION_1_0) { ::android::sp<::android::hardware::camera::device::V1_0::ICameraDevice> device1; ALOGI("getCameraCharacteristics: Testing camera device %s", name.c_str()); Return ret; ret = mProvider->getCameraDeviceInterface_V1_x( name, [&](auto status, const auto& device) { ALOGI("getCameraDeviceInterface_V1_x returns status:%d", (int)status); ASSERT_EQ(Status::OK, status); ASSERT_NE(device, nullptr); device1 = device; }); ASSERT_TRUE(ret.isOk()); ret = device1->getCameraInfo([&](auto status, const auto& info) { ALOGI("getCameraInfo returns status:%d", (int)status); ASSERT_EQ(Status::OK, status); switch (info.orientation) { case 0: case 90: case 180: case 270: // Expected cases ALOGI("camera orientation: %d", info.orientation); break; default: FAIL() << "Unexpected camera orientation:" << info.orientation; } switch (info.facing) { case CameraFacing::BACK: case CameraFacing::FRONT: case CameraFacing::EXTERNAL: // Expected cases ALOGI("camera facing: %d", info.facing); break; default: FAIL() << "Unexpected camera facing:" << static_cast(info.facing); } }); ASSERT_TRUE(ret.isOk()); } } } // Check whether preview window can be configured TEST_P(CameraHidlTest, setPreviewWindow) { hidl_vec cameraDeviceNames = getCameraDeviceNames(mProvider); for (const auto& name : cameraDeviceNames) { if (getCameraDeviceVersion(name, mProviderType) == CAMERA_DEVICE_API_VERSION_1_0) { sp<::android::hardware::camera::device::V1_0::ICameraDevice> device1; openCameraDevice(name, mProvider, &device1 /*out*/); ASSERT_NE(nullptr, device1.get()); sp bufferItemConsumer; sp bufferHandler; setupPreviewWindow(device1, &bufferItemConsumer /*out*/, &bufferHandler /*out*/); Return ret; ret = device1->close(); ASSERT_TRUE(ret.isOk()); } } } // Verify that setting preview window fails in case device is not open TEST_P(CameraHidlTest, setPreviewWindowInvalid) { hidl_vec cameraDeviceNames = getCameraDeviceNames(mProvider); for (const auto& name : cameraDeviceNames) { if (getCameraDeviceVersion(name, mProviderType) == CAMERA_DEVICE_API_VERSION_1_0) { ::android::sp<::android::hardware::camera::device::V1_0::ICameraDevice> device1; ALOGI("getCameraCharacteristics: Testing camera device %s", name.c_str()); Return ret; ret = mProvider->getCameraDeviceInterface_V1_x( name, [&](auto status, const auto& device) { ALOGI("getCameraDeviceInterface_V1_x returns status:%d", (int)status); ASSERT_EQ(Status::OK, status); ASSERT_NE(device, nullptr); device1 = device; }); ASSERT_TRUE(ret.isOk()); Return returnStatus = device1->setPreviewWindow(nullptr); ASSERT_TRUE(returnStatus.isOk()); ASSERT_EQ(Status::OPERATION_NOT_SUPPORTED, returnStatus); } } } // Start and stop preview checking whether it gets enabled in between. TEST_P(CameraHidlTest, startStopPreview) { hidl_vec cameraDeviceNames = getCameraDeviceNames(mProvider); for (const auto& name : cameraDeviceNames) { if (getCameraDeviceVersion(name, mProviderType) == CAMERA_DEVICE_API_VERSION_1_0) { sp<::android::hardware::camera::device::V1_0::ICameraDevice> device1; openCameraDevice(name, mProvider, &device1 /*out*/); ASSERT_NE(nullptr, device1.get()); sp bufferItemConsumer; sp bufferHandler; setupPreviewWindow(device1, &bufferItemConsumer /*out*/, &bufferHandler /*out*/); startPreview(device1); Return returnBoolStatus = device1->previewEnabled(); ASSERT_TRUE(returnBoolStatus.isOk()); ASSERT_TRUE(returnBoolStatus); stopPreviewAndClose(device1); } } } // Start preview without active preview window. Preview should start as soon // as a valid active window gets configured. TEST_P(CameraHidlTest, startStopPreviewDelayed) { hidl_vec cameraDeviceNames = getCameraDeviceNames(mProvider); for (const auto& name : cameraDeviceNames) { if (getCameraDeviceVersion(name, mProviderType) == CAMERA_DEVICE_API_VERSION_1_0) { sp<::android::hardware::camera::device::V1_0::ICameraDevice> device1; openCameraDevice(name, mProvider, &device1 /*out*/); ASSERT_NE(nullptr, device1.get()); Return returnStatus = device1->setPreviewWindow(nullptr); ASSERT_TRUE(returnStatus.isOk()); ASSERT_EQ(Status::OK, returnStatus); startPreview(device1); sp bufferItemConsumer; sp bufferHandler; setupPreviewWindow(device1, &bufferItemConsumer /*out*/, &bufferHandler /*out*/); // Preview should get enabled now Return returnBoolStatus = device1->previewEnabled(); ASSERT_TRUE(returnBoolStatus.isOk()); ASSERT_TRUE(returnBoolStatus); stopPreviewAndClose(device1); } } } // Verify that image capture behaves as expected along with preview callbacks. TEST_P(CameraHidlTest, takePicture) { hidl_vec cameraDeviceNames = getCameraDeviceNames(mProvider); for (const auto& name : cameraDeviceNames) { if (getCameraDeviceVersion(name, mProviderType) == CAMERA_DEVICE_API_VERSION_1_0) { sp<::android::hardware::camera::device::V1_0::ICameraDevice> device1; openCameraDevice(name, mProvider, &device1 /*out*/); ASSERT_NE(nullptr, device1.get()); sp bufferItemConsumer; sp bufferHandler; setupPreviewWindow(device1, &bufferItemConsumer /*out*/, &bufferHandler /*out*/); { std::unique_lock l(mLock); mDataMessageTypeReceived = DataCallbackMsg::RAW_IMAGE_NOTIFY; } enableMsgType((unsigned int)DataCallbackMsg::PREVIEW_FRAME, device1); startPreview(device1); { std::unique_lock l(mLock); waitForFrameLocked(DataCallbackMsg::PREVIEW_FRAME, l); } disableMsgType((unsigned int)DataCallbackMsg::PREVIEW_FRAME, device1); enableMsgType((unsigned int)DataCallbackMsg::COMPRESSED_IMAGE, device1); { std::unique_lock l(mLock); mDataMessageTypeReceived = DataCallbackMsg::RAW_IMAGE_NOTIFY; } Return returnStatus = device1->takePicture(); ASSERT_TRUE(returnStatus.isOk()); ASSERT_EQ(Status::OK, returnStatus); { std::unique_lock l(mLock); waitForFrameLocked(DataCallbackMsg::COMPRESSED_IMAGE, l); } disableMsgType((unsigned int)DataCallbackMsg::COMPRESSED_IMAGE, device1); stopPreviewAndClose(device1); } } } // Image capture should fail in case preview didn't get enabled first. TEST_P(CameraHidlTest, takePictureFail) { hidl_vec cameraDeviceNames = getCameraDeviceNames(mProvider); for (const auto& name : cameraDeviceNames) { if (getCameraDeviceVersion(name, mProviderType) == CAMERA_DEVICE_API_VERSION_1_0) { sp<::android::hardware::camera::device::V1_0::ICameraDevice> device1; openCameraDevice(name, mProvider, &device1 /*out*/); ASSERT_NE(nullptr, device1.get()); Return returnStatus = device1->takePicture(); ASSERT_TRUE(returnStatus.isOk()); ASSERT_NE(Status::OK, returnStatus); Return ret = device1->close(); ASSERT_TRUE(ret.isOk()); } } } // Verify that image capture can be cancelled. TEST_P(CameraHidlTest, cancelPicture) { hidl_vec cameraDeviceNames = getCameraDeviceNames(mProvider); for (const auto& name : cameraDeviceNames) { if (getCameraDeviceVersion(name, mProviderType) == CAMERA_DEVICE_API_VERSION_1_0) { sp<::android::hardware::camera::device::V1_0::ICameraDevice> device1; openCameraDevice(name, mProvider, &device1 /*out*/); ASSERT_NE(nullptr, device1.get()); sp bufferItemConsumer; sp bufferHandler; setupPreviewWindow(device1, &bufferItemConsumer /*out*/, &bufferHandler /*out*/); startPreview(device1); Return returnStatus = device1->takePicture(); ASSERT_TRUE(returnStatus.isOk()); ASSERT_EQ(Status::OK, returnStatus); returnStatus = device1->cancelPicture(); ASSERT_TRUE(returnStatus.isOk()); ASSERT_EQ(Status::OK, returnStatus); stopPreviewAndClose(device1); } } } // Image capture cancel is a no-op when image capture is not running. TEST_P(CameraHidlTest, cancelPictureNOP) { hidl_vec cameraDeviceNames = getCameraDeviceNames(mProvider); for (const auto& name : cameraDeviceNames) { if (getCameraDeviceVersion(name, mProviderType) == CAMERA_DEVICE_API_VERSION_1_0) { sp<::android::hardware::camera::device::V1_0::ICameraDevice> device1; openCameraDevice(name, mProvider, &device1 /*out*/); ASSERT_NE(nullptr, device1.get()); sp bufferItemConsumer; sp bufferHandler; setupPreviewWindow(device1, &bufferItemConsumer /*out*/, &bufferHandler /*out*/); startPreview(device1); Return returnStatus = device1->cancelPicture(); ASSERT_TRUE(returnStatus.isOk()); ASSERT_EQ(Status::OK, returnStatus); stopPreviewAndClose(device1); } } } // Test basic video recording. TEST_P(CameraHidlTest, startStopRecording) { hidl_vec cameraDeviceNames = getCameraDeviceNames(mProvider); for (const auto& name : cameraDeviceNames) { if (getCameraDeviceVersion(name, mProviderType) == CAMERA_DEVICE_API_VERSION_1_0) { sp<::android::hardware::camera::device::V1_0::ICameraDevice> device1; openCameraDevice(name, mProvider, &device1 /*out*/); ASSERT_NE(nullptr, device1.get()); sp bufferItemConsumer; sp bufferHandler; setupPreviewWindow(device1, &bufferItemConsumer /*out*/, &bufferHandler /*out*/); { std::unique_lock l(mLock); mDataMessageTypeReceived = DataCallbackMsg::RAW_IMAGE_NOTIFY; } enableMsgType((unsigned int)DataCallbackMsg::PREVIEW_FRAME, device1); startPreview(device1); { std::unique_lock l(mLock); waitForFrameLocked(DataCallbackMsg::PREVIEW_FRAME, l); mDataMessageTypeReceived = DataCallbackMsg::RAW_IMAGE_NOTIFY; mVideoBufferIndex = UINT32_MAX; } disableMsgType((unsigned int)DataCallbackMsg::PREVIEW_FRAME, device1); bool videoMetaEnabled = false; Return returnStatus = device1->storeMetaDataInBuffers(true); ASSERT_TRUE(returnStatus.isOk()); // It is allowed for devices to not support this feature ASSERT_TRUE((Status::OK == returnStatus) || (Status::OPERATION_NOT_SUPPORTED == returnStatus)); if (Status::OK == returnStatus) { videoMetaEnabled = true; } enableMsgType((unsigned int)DataCallbackMsg::VIDEO_FRAME, device1); Return returnBoolStatus = device1->recordingEnabled(); ASSERT_TRUE(returnBoolStatus.isOk()); ASSERT_FALSE(returnBoolStatus); returnStatus = device1->startRecording(); ASSERT_TRUE(returnStatus.isOk()); ASSERT_EQ(Status::OK, returnStatus); { std::unique_lock l(mLock); waitForFrameLocked(DataCallbackMsg::VIDEO_FRAME, l); ASSERT_NE(UINT32_MAX, mVideoBufferIndex); disableMsgType((unsigned int)DataCallbackMsg::VIDEO_FRAME, device1); } returnBoolStatus = device1->recordingEnabled(); ASSERT_TRUE(returnBoolStatus.isOk()); ASSERT_TRUE(returnBoolStatus); Return ret; if (videoMetaEnabled) { ret = device1->releaseRecordingFrameHandle(mVideoData, mVideoBufferIndex, mVideoNativeHandle); ASSERT_TRUE(ret.isOk()); } else { ret = device1->releaseRecordingFrame(mVideoData, mVideoBufferIndex); ASSERT_TRUE(ret.isOk()); } ret = device1->stopRecording(); ASSERT_TRUE(ret.isOk()); stopPreviewAndClose(device1); } } } // It shouldn't be possible to start recording without enabling preview first. TEST_P(CameraHidlTest, startRecordingFail) { hidl_vec cameraDeviceNames = getCameraDeviceNames(mProvider); for (const auto& name : cameraDeviceNames) { if (getCameraDeviceVersion(name, mProviderType) == CAMERA_DEVICE_API_VERSION_1_0) { sp<::android::hardware::camera::device::V1_0::ICameraDevice> device1; openCameraDevice(name, mProvider, &device1 /*out*/); ASSERT_NE(nullptr, device1.get()); Return returnBoolStatus = device1->recordingEnabled(); ASSERT_TRUE(returnBoolStatus.isOk()); ASSERT_FALSE(returnBoolStatus); Return returnStatus = device1->startRecording(); ASSERT_TRUE(returnStatus.isOk()); ASSERT_NE(Status::OK, returnStatus); Return ret = device1->close(); ASSERT_TRUE(ret.isOk()); } } } // Check autofocus support if available. TEST_P(CameraHidlTest, autoFocus) { hidl_vec cameraDeviceNames = getCameraDeviceNames(mProvider); std::vector focusModes = {CameraParameters::FOCUS_MODE_AUTO, CameraParameters::FOCUS_MODE_CONTINUOUS_PICTURE, CameraParameters::FOCUS_MODE_CONTINUOUS_VIDEO}; for (const auto& name : cameraDeviceNames) { if (getCameraDeviceVersion(name, mProviderType) == CAMERA_DEVICE_API_VERSION_1_0) { sp<::android::hardware::camera::device::V1_0::ICameraDevice> device1; openCameraDevice(name, mProvider, &device1 /*out*/); ASSERT_NE(nullptr, device1.get()); CameraParameters cameraParams; getParameters(device1, &cameraParams /*out*/); if (Status::OK != isAutoFocusModeAvailable(cameraParams, CameraParameters::FOCUS_MODE_AUTO)) { Return ret = device1->close(); ASSERT_TRUE(ret.isOk()); continue; } sp bufferItemConsumer; sp bufferHandler; setupPreviewWindow(device1, &bufferItemConsumer /*out*/, &bufferHandler /*out*/); startPreview(device1); enableMsgType((unsigned int)NotifyCallbackMsg::FOCUS, device1); for (auto& iter : focusModes) { if (Status::OK != isAutoFocusModeAvailable(cameraParams, iter)) { continue; } cameraParams.set(CameraParameters::KEY_FOCUS_MODE, iter); setParameters(device1, cameraParams); { std::unique_lock l(mLock); mNotifyMessage = NotifyCallbackMsg::ERROR; } Return returnStatus = device1->autoFocus(); ASSERT_TRUE(returnStatus.isOk()); ASSERT_EQ(Status::OK, returnStatus); { std::unique_lock l(mLock); while (NotifyCallbackMsg::FOCUS != mNotifyMessage) { auto timeout = std::chrono::system_clock::now() + std::chrono::seconds(kAutoFocusTimeoutSec); ASSERT_NE(std::cv_status::timeout, mResultCondition.wait_until(l, timeout)); } } } disableMsgType((unsigned int)NotifyCallbackMsg::FOCUS, device1); stopPreviewAndClose(device1); } } } // In case autofocus is supported verify that it can be cancelled. TEST_P(CameraHidlTest, cancelAutoFocus) { hidl_vec cameraDeviceNames = getCameraDeviceNames(mProvider); for (const auto& name : cameraDeviceNames) { if (getCameraDeviceVersion(name, mProviderType) == CAMERA_DEVICE_API_VERSION_1_0) { sp<::android::hardware::camera::device::V1_0::ICameraDevice> device1; openCameraDevice(name, mProvider, &device1 /*out*/); ASSERT_NE(nullptr, device1.get()); CameraParameters cameraParams; getParameters(device1, &cameraParams /*out*/); if (Status::OK != isAutoFocusModeAvailable(cameraParams, CameraParameters::FOCUS_MODE_AUTO)) { Return ret = device1->close(); ASSERT_TRUE(ret.isOk()); continue; } // It should be fine to call before preview starts. ASSERT_EQ(Status::OK, device1->cancelAutoFocus()); sp bufferItemConsumer; sp bufferHandler; setupPreviewWindow(device1, &bufferItemConsumer /*out*/, &bufferHandler /*out*/); startPreview(device1); // It should be fine to call after preview starts too. Return returnStatus = device1->cancelAutoFocus(); ASSERT_TRUE(returnStatus.isOk()); ASSERT_EQ(Status::OK, returnStatus); returnStatus = device1->autoFocus(); ASSERT_TRUE(returnStatus.isOk()); ASSERT_EQ(Status::OK, returnStatus); returnStatus = device1->cancelAutoFocus(); ASSERT_TRUE(returnStatus.isOk()); ASSERT_EQ(Status::OK, returnStatus); stopPreviewAndClose(device1); } } } // Check whether face detection is available and try to enable&disable. TEST_P(CameraHidlTest, sendCommandFaceDetection) { hidl_vec cameraDeviceNames = getCameraDeviceNames(mProvider); for (const auto& name : cameraDeviceNames) { if (getCameraDeviceVersion(name, mProviderType) == CAMERA_DEVICE_API_VERSION_1_0) { sp<::android::hardware::camera::device::V1_0::ICameraDevice> device1; openCameraDevice(name, mProvider, &device1 /*out*/); ASSERT_NE(nullptr, device1.get()); CameraParameters cameraParams; getParameters(device1, &cameraParams /*out*/); int32_t hwFaces = cameraParams.getInt(CameraParameters::KEY_MAX_NUM_DETECTED_FACES_HW); int32_t swFaces = cameraParams.getInt(CameraParameters::KEY_MAX_NUM_DETECTED_FACES_SW); if ((0 >= hwFaces) && (0 >= swFaces)) { Return ret = device1->close(); ASSERT_TRUE(ret.isOk()); continue; } sp bufferItemConsumer; sp bufferHandler; setupPreviewWindow(device1, &bufferItemConsumer /*out*/, &bufferHandler /*out*/); startPreview(device1); if (0 < hwFaces) { Return returnStatus = device1->sendCommand( CommandType::START_FACE_DETECTION, CAMERA_FACE_DETECTION_HW, 0); ASSERT_TRUE(returnStatus.isOk()); ASSERT_EQ(Status::OK, returnStatus); // TODO(epeev) : Enable and check for face notifications returnStatus = device1->sendCommand(CommandType::STOP_FACE_DETECTION, CAMERA_FACE_DETECTION_HW, 0); ASSERT_TRUE(returnStatus.isOk()); ASSERT_EQ(Status::OK, returnStatus); } if (0 < swFaces) { Return returnStatus = device1->sendCommand( CommandType::START_FACE_DETECTION, CAMERA_FACE_DETECTION_SW, 0); ASSERT_TRUE(returnStatus.isOk()); ASSERT_EQ(Status::OK, returnStatus); // TODO(epeev) : Enable and check for face notifications returnStatus = device1->sendCommand(CommandType::STOP_FACE_DETECTION, CAMERA_FACE_DETECTION_SW, 0); ASSERT_TRUE(returnStatus.isOk()); ASSERT_EQ(Status::OK, returnStatus); } stopPreviewAndClose(device1); } } } // Check whether smooth zoom is available and try to enable&disable. TEST_P(CameraHidlTest, sendCommandSmoothZoom) { hidl_vec cameraDeviceNames = getCameraDeviceNames(mProvider); for (const auto& name : cameraDeviceNames) { if (getCameraDeviceVersion(name, mProviderType) == CAMERA_DEVICE_API_VERSION_1_0) { sp<::android::hardware::camera::device::V1_0::ICameraDevice> device1; openCameraDevice(name, mProvider, &device1 /*out*/); ASSERT_NE(nullptr, device1.get()); CameraParameters cameraParams; getParameters(device1, &cameraParams /*out*/); const char* smoothZoomStr = cameraParams.get(CameraParameters::KEY_SMOOTH_ZOOM_SUPPORTED); bool smoothZoomSupported = ((nullptr != smoothZoomStr) && (strcmp(smoothZoomStr, CameraParameters::TRUE) == 0)) ? true : false; if (!smoothZoomSupported) { Return ret = device1->close(); ASSERT_TRUE(ret.isOk()); continue; } int32_t maxZoom = cameraParams.getInt(CameraParameters::KEY_MAX_ZOOM); ASSERT_TRUE(0 < maxZoom); sp bufferItemConsumer; sp bufferHandler; setupPreviewWindow(device1, &bufferItemConsumer /*out*/, &bufferHandler /*out*/); startPreview(device1); setParameters(device1, cameraParams); Return returnStatus = device1->sendCommand(CommandType::START_SMOOTH_ZOOM, maxZoom, 0); ASSERT_TRUE(returnStatus.isOk()); ASSERT_EQ(Status::OK, returnStatus); // TODO(epeev) : Enable and check for face notifications returnStatus = device1->sendCommand(CommandType::STOP_SMOOTH_ZOOM, 0, 0); ASSERT_TRUE(returnStatus.isOk()); ASSERT_EQ(Status::OK, returnStatus); stopPreviewAndClose(device1); } } } // Basic correctness tests related to camera parameters. TEST_P(CameraHidlTest, getSetParameters) { hidl_vec cameraDeviceNames = getCameraDeviceNames(mProvider); for (const auto& name : cameraDeviceNames) { if (getCameraDeviceVersion(name, mProviderType) == CAMERA_DEVICE_API_VERSION_1_0) { sp<::android::hardware::camera::device::V1_0::ICameraDevice> device1; openCameraDevice(name, mProvider, &device1 /*out*/); ASSERT_NE(nullptr, device1.get()); CameraParameters cameraParams; getParameters(device1, &cameraParams /*out*/); int32_t width, height; cameraParams.getPictureSize(&width, &height); ASSERT_TRUE((0 < width) && (0 < height)); cameraParams.getPreviewSize(&width, &height); ASSERT_TRUE((0 < width) && (0 < height)); int32_t minFps, maxFps; cameraParams.getPreviewFpsRange(&minFps, &maxFps); ASSERT_TRUE((0 < minFps) && (0 < maxFps)); ASSERT_NE(nullptr, cameraParams.getPreviewFormat()); ASSERT_NE(nullptr, cameraParams.getPictureFormat()); ASSERT_TRUE( strcmp(CameraParameters::PIXEL_FORMAT_JPEG, cameraParams.getPictureFormat()) == 0); const char* flashMode = cameraParams.get(CameraParameters::KEY_FLASH_MODE); ASSERT_TRUE((nullptr == flashMode) || (strcmp(CameraParameters::FLASH_MODE_OFF, flashMode) == 0)); const char* wbMode = cameraParams.get(CameraParameters::KEY_WHITE_BALANCE); ASSERT_TRUE((nullptr == wbMode) || (strcmp(CameraParameters::WHITE_BALANCE_AUTO, wbMode) == 0)); const char* effect = cameraParams.get(CameraParameters::KEY_EFFECT); ASSERT_TRUE((nullptr == effect) || (strcmp(CameraParameters::EFFECT_NONE, effect) == 0)); ::android::Vector previewSizes; cameraParams.getSupportedPreviewSizes(previewSizes); ASSERT_FALSE(previewSizes.empty()); ::android::Vector pictureSizes; cameraParams.getSupportedPictureSizes(pictureSizes); ASSERT_FALSE(pictureSizes.empty()); const char* previewFormats = cameraParams.get(CameraParameters::KEY_SUPPORTED_PREVIEW_FORMATS); ASSERT_NE(nullptr, previewFormats); ::android::String8 previewFormatsString(previewFormats); ASSERT_TRUE(previewFormatsString.contains(CameraParameters::PIXEL_FORMAT_YUV420SP)); ASSERT_NE(nullptr, cameraParams.get(CameraParameters::KEY_SUPPORTED_PICTURE_FORMATS)); ASSERT_NE(nullptr, cameraParams.get(CameraParameters::KEY_SUPPORTED_PREVIEW_FRAME_RATES)); const char* focusModes = cameraParams.get(CameraParameters::KEY_SUPPORTED_FOCUS_MODES); ASSERT_NE(nullptr, focusModes); ::android::String8 focusModesString(focusModes); const char* focusMode = cameraParams.get(CameraParameters::KEY_FOCUS_MODE); ASSERT_NE(nullptr, focusMode); // Auto focus mode should be default if (focusModesString.contains(CameraParameters::FOCUS_MODE_AUTO)) { ASSERT_TRUE(strcmp(CameraParameters::FOCUS_MODE_AUTO, focusMode) == 0); } ASSERT_TRUE(0 < cameraParams.getInt(CameraParameters::KEY_FOCAL_LENGTH)); int32_t horizontalViewAngle = cameraParams.getInt(CameraParameters::KEY_HORIZONTAL_VIEW_ANGLE); ASSERT_TRUE((0 < horizontalViewAngle) && (360 >= horizontalViewAngle)); int32_t verticalViewAngle = cameraParams.getInt(CameraParameters::KEY_VERTICAL_VIEW_ANGLE); ASSERT_TRUE((0 < verticalViewAngle) && (360 >= verticalViewAngle)); int32_t jpegQuality = cameraParams.getInt(CameraParameters::KEY_JPEG_QUALITY); ASSERT_TRUE((1 <= jpegQuality) && (100 >= jpegQuality)); int32_t jpegThumbQuality = cameraParams.getInt(CameraParameters::KEY_JPEG_THUMBNAIL_QUALITY); ASSERT_TRUE((1 <= jpegThumbQuality) && (100 >= jpegThumbQuality)); cameraParams.setPictureSize(pictureSizes[0].width, pictureSizes[0].height); cameraParams.setPreviewSize(previewSizes[0].width, previewSizes[0].height); setParameters(device1, cameraParams); getParameters(device1, &cameraParams /*out*/); cameraParams.getPictureSize(&width, &height); ASSERT_TRUE((pictureSizes[0].width == width) && (pictureSizes[0].height == height)); cameraParams.getPreviewSize(&width, &height); ASSERT_TRUE((previewSizes[0].width == width) && (previewSizes[0].height == height)); Return ret = device1->close(); ASSERT_TRUE(ret.isOk()); } } } TEST_P(CameraHidlTest, systemCameraTest) { hidl_vec cameraDeviceNames = getCameraDeviceNames(mProvider); std::map> hiddenPhysicalIdToLogicalMap; for (const auto& name : cameraDeviceNames) { int deviceVersion = getCameraDeviceVersion(name, mProviderType); switch (deviceVersion) { case CAMERA_DEVICE_API_VERSION_3_7: case CAMERA_DEVICE_API_VERSION_3_6: case CAMERA_DEVICE_API_VERSION_3_5: case CAMERA_DEVICE_API_VERSION_3_4: case CAMERA_DEVICE_API_VERSION_3_3: case CAMERA_DEVICE_API_VERSION_3_2: { ::android::sp<::android::hardware::camera::device::V3_2::ICameraDevice> device3_x; ALOGI("getCameraCharacteristics: Testing camera device %s", name.c_str()); Return ret; ret = mProvider->getCameraDeviceInterface_V3_x( name, [&](auto status, const auto& device) { ALOGI("getCameraDeviceInterface_V3_x returns status:%d", (int)status); ASSERT_EQ(Status::OK, status); ASSERT_NE(device, nullptr); device3_x = device; }); ASSERT_TRUE(ret.isOk()); ret = device3_x->getCameraCharacteristics([&](auto status, const auto& chars) { ASSERT_EQ(status, Status::OK); const camera_metadata_t* staticMeta = reinterpret_cast(chars.data()); ASSERT_NE(staticMeta, nullptr); Status rc = isLogicalMultiCamera(staticMeta); ASSERT_TRUE(Status::OK == rc || Status::METHOD_NOT_SUPPORTED == rc); if (Status::METHOD_NOT_SUPPORTED == rc) { return; } std::unordered_set physicalIds; ASSERT_EQ(Status::OK, getPhysicalCameraIds(staticMeta, &physicalIds)); SystemCameraKind systemCameraKind = SystemCameraKind::PUBLIC; rc = getSystemCameraKind(staticMeta, &systemCameraKind); ASSERT_EQ(rc, Status::OK); for (auto physicalId : physicalIds) { bool isPublicId = false; for (auto& deviceName : cameraDeviceNames) { std::string publicVersion, publicId; ASSERT_TRUE(::matchDeviceName(deviceName, mProviderType, &publicVersion, &publicId)); if (physicalId == publicId) { isPublicId = true; break; } } // For hidden physical cameras, collect their associated logical cameras // and store the system camera kind. if (!isPublicId) { auto it = hiddenPhysicalIdToLogicalMap.find(physicalId); if (it == hiddenPhysicalIdToLogicalMap.end()) { hiddenPhysicalIdToLogicalMap.insert(std::make_pair( physicalId, std::list(systemCameraKind))); } else { it->second.push_back(systemCameraKind); } } } }); ASSERT_TRUE(ret.isOk()); } break; case CAMERA_DEVICE_API_VERSION_1_0: { // Not applicable } break; default: { ALOGE("%s: Unsupported device version %d", __func__, deviceVersion); ADD_FAILURE(); } break; } } // Check that the system camera kind of the logical cameras associated with // each hidden physical camera is the same. for (const auto& it : hiddenPhysicalIdToLogicalMap) { SystemCameraKind neededSystemCameraKind = it.second.front(); for (auto foundSystemCamera : it.second) { ASSERT_EQ(neededSystemCameraKind, foundSystemCamera); } } } // Verify that the static camera characteristics can be retrieved // successfully. TEST_P(CameraHidlTest, getCameraCharacteristics) { hidl_vec cameraDeviceNames = getCameraDeviceNames(mProvider); for (const auto& name : cameraDeviceNames) { int deviceVersion = getCameraDeviceVersion(name, mProviderType); switch (deviceVersion) { case CAMERA_DEVICE_API_VERSION_3_7: case CAMERA_DEVICE_API_VERSION_3_6: case CAMERA_DEVICE_API_VERSION_3_5: case CAMERA_DEVICE_API_VERSION_3_4: case CAMERA_DEVICE_API_VERSION_3_3: case CAMERA_DEVICE_API_VERSION_3_2: { ::android::sp<::android::hardware::camera::device::V3_2::ICameraDevice> device3_x; ALOGI("getCameraCharacteristics: Testing camera device %s", name.c_str()); Return ret; ret = mProvider->getCameraDeviceInterface_V3_x( name, [&](auto status, const auto& device) { ALOGI("getCameraDeviceInterface_V3_x returns status:%d", (int)status); ASSERT_EQ(Status::OK, status); ASSERT_NE(device, nullptr); device3_x = device; }); ASSERT_TRUE(ret.isOk()); ret = device3_x->getCameraCharacteristics([&](auto status, const auto& chars) { verifyCameraCharacteristics(status, chars); verifyMonochromeCharacteristics(chars, deviceVersion); verifyRecommendedConfigs(chars); verifyLogicalOrUltraHighResCameraMetadata(name, device3_x, chars, deviceVersion, cameraDeviceNames); }); ASSERT_TRUE(ret.isOk()); //getPhysicalCameraCharacteristics will fail for publicly //advertised camera IDs. if (deviceVersion >= CAMERA_DEVICE_API_VERSION_3_5) { auto castResult = device::V3_5::ICameraDevice::castFrom(device3_x); ASSERT_TRUE(castResult.isOk()); ::android::sp<::android::hardware::camera::device::V3_5::ICameraDevice> device3_5 = castResult; ASSERT_NE(device3_5, nullptr); std::string version, cameraId; ASSERT_TRUE(::matchDeviceName(name, mProviderType, &version, &cameraId)); Return ret = device3_5->getPhysicalCameraCharacteristics(cameraId, [&](auto status, const auto& chars) { ASSERT_TRUE(Status::ILLEGAL_ARGUMENT == status); ASSERT_EQ(0, chars.size()); }); ASSERT_TRUE(ret.isOk()); } } break; case CAMERA_DEVICE_API_VERSION_1_0: { //Not applicable } break; default: { ALOGE("%s: Unsupported device version %d", __func__, deviceVersion); ADD_FAILURE(); } break; } } } //In case it is supported verify that torch can be enabled. //Check for corresponding toch callbacks as well. TEST_P(CameraHidlTest, setTorchMode) { hidl_vec cameraDeviceNames = getCameraDeviceNames(mProvider); bool torchControlSupported = false; Return ret; ret = mProvider->isSetTorchModeSupported([&](auto status, bool support) { ALOGI("isSetTorchModeSupported returns status:%d supported:%d", (int)status, support); ASSERT_EQ(Status::OK, status); torchControlSupported = support; }); sp cb = new TorchProviderCb(this); Return returnStatus = mProvider->setCallback(cb); ASSERT_TRUE(returnStatus.isOk()); ASSERT_EQ(Status::OK, returnStatus); for (const auto& name : cameraDeviceNames) { int deviceVersion = getCameraDeviceVersion(name, mProviderType); switch (deviceVersion) { case CAMERA_DEVICE_API_VERSION_3_7: case CAMERA_DEVICE_API_VERSION_3_6: case CAMERA_DEVICE_API_VERSION_3_5: case CAMERA_DEVICE_API_VERSION_3_4: case CAMERA_DEVICE_API_VERSION_3_3: case CAMERA_DEVICE_API_VERSION_3_2: { ::android::sp<::android::hardware::camera::device::V3_2::ICameraDevice> device3_x; ALOGI("setTorchMode: Testing camera device %s", name.c_str()); ret = mProvider->getCameraDeviceInterface_V3_x( name, [&](auto status, const auto& device) { ALOGI("getCameraDeviceInterface_V3_x returns status:%d", (int)status); ASSERT_EQ(Status::OK, status); ASSERT_NE(device, nullptr); device3_x = device; }); ASSERT_TRUE(ret.isOk()); mTorchStatus = TorchModeStatus::NOT_AVAILABLE; returnStatus = device3_x->setTorchMode(TorchMode::ON); ASSERT_TRUE(returnStatus.isOk()); if (!torchControlSupported) { ASSERT_EQ(Status::METHOD_NOT_SUPPORTED, returnStatus); } else { ASSERT_TRUE(returnStatus == Status::OK || returnStatus == Status::OPERATION_NOT_SUPPORTED); if (returnStatus == Status::OK) { { std::unique_lock l(mTorchLock); while (TorchModeStatus::NOT_AVAILABLE == mTorchStatus) { auto timeout = std::chrono::system_clock::now() + std::chrono::seconds(kTorchTimeoutSec); ASSERT_NE(std::cv_status::timeout, mTorchCond.wait_until(l, timeout)); } ASSERT_EQ(TorchModeStatus::AVAILABLE_ON, mTorchStatus); mTorchStatus = TorchModeStatus::NOT_AVAILABLE; } returnStatus = device3_x->setTorchMode(TorchMode::OFF); ASSERT_TRUE(returnStatus.isOk()); ASSERT_EQ(Status::OK, returnStatus); { std::unique_lock l(mTorchLock); while (TorchModeStatus::NOT_AVAILABLE == mTorchStatus) { auto timeout = std::chrono::system_clock::now() + std::chrono::seconds(kTorchTimeoutSec); ASSERT_NE(std::cv_status::timeout, mTorchCond.wait_until(l, timeout)); } ASSERT_EQ(TorchModeStatus::AVAILABLE_OFF, mTorchStatus); } } } } break; case CAMERA_DEVICE_API_VERSION_1_0: { ::android::sp<::android::hardware::camera::device::V1_0::ICameraDevice> device1; ALOGI("dumpState: Testing camera device %s", name.c_str()); ret = mProvider->getCameraDeviceInterface_V1_x( name, [&](auto status, const auto& device) { ALOGI("getCameraDeviceInterface_V1_x returns status:%d", (int)status); ASSERT_EQ(Status::OK, status); ASSERT_NE(device, nullptr); device1 = device; }); ASSERT_TRUE(ret.isOk()); mTorchStatus = TorchModeStatus::NOT_AVAILABLE; returnStatus = device1->setTorchMode(TorchMode::ON); ASSERT_TRUE(returnStatus.isOk()); if (!torchControlSupported) { ASSERT_EQ(Status::METHOD_NOT_SUPPORTED, returnStatus); } else { ASSERT_TRUE(returnStatus == Status::OK || returnStatus == Status::OPERATION_NOT_SUPPORTED); if (returnStatus == Status::OK) { { std::unique_lock l(mTorchLock); while (TorchModeStatus::NOT_AVAILABLE == mTorchStatus) { auto timeout = std::chrono::system_clock::now() + std::chrono::seconds(kTorchTimeoutSec); ASSERT_NE(std::cv_status::timeout, mTorchCond.wait_until(l, timeout)); } ASSERT_EQ(TorchModeStatus::AVAILABLE_ON, mTorchStatus); mTorchStatus = TorchModeStatus::NOT_AVAILABLE; } returnStatus = device1->setTorchMode(TorchMode::OFF); ASSERT_TRUE(returnStatus.isOk()); ASSERT_EQ(Status::OK, returnStatus); { std::unique_lock l(mTorchLock); while (TorchModeStatus::NOT_AVAILABLE == mTorchStatus) { auto timeout = std::chrono::system_clock::now() + std::chrono::seconds(kTorchTimeoutSec); ASSERT_NE(std::cv_status::timeout, mTorchCond.wait_until(l, timeout)); } ASSERT_EQ(TorchModeStatus::AVAILABLE_OFF, mTorchStatus); } } } ret = device1->close(); ASSERT_TRUE(ret.isOk()); } break; default: { ALOGE("%s: Unsupported device version %d", __func__, deviceVersion); ADD_FAILURE(); } break; } } returnStatus = mProvider->setCallback(nullptr); ASSERT_TRUE(returnStatus.isOk()); ASSERT_EQ(Status::OK, returnStatus); } // Check dump functionality. TEST_P(CameraHidlTest, dumpState) { hidl_vec