/*
* Copyright (C) 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_NDEBUG 0
#define LOG_TAG "ACameraDeviceVendor"
#include <vector>
#include <inttypes.h>
#include <android/frameworks/cameraservice/service/2.0/ICameraService.h>
#include <android/frameworks/cameraservice/device/2.0/types.h>
#include <CameraMetadata.h>
#include "ndk_vendor/impl/ACameraDevice.h"
#include "ACameraCaptureSession.h"
#include "ACameraMetadata.h"
#include "ACaptureRequest.h"
#include "utils.h"
#include "ACameraCaptureSession.inc"
#define CHECK_TRANSACTION_AND_RET(remoteRet, status, callName) \
if (!remoteRet.isOk()) { \
ALOGE("%s: Transaction error during %s call %s", __FUNCTION__, callName, \
remoteRet.description().c_str()); \
return ACAMERA_ERROR_UNKNOWN; \
} \
if (status != Status::NO_ERROR) { \
ALOGE("%s: %s call failed", __FUNCTION__, callName); \
return utils::convertFromHidl(status); \
}
using namespace android;
ACameraDevice::~ACameraDevice() {
mDevice->stopLooper();
}
namespace android {
namespace acam {
using HCameraMetadata = frameworks::cameraservice::device::V2_0::CameraMetadata;
using OutputConfiguration = frameworks::cameraservice::device::V2_0::OutputConfiguration;
using SessionConfiguration = frameworks::cameraservice::device::V2_0::SessionConfiguration;
using hardware::Void;
// Static member definitions
const char* CameraDevice::kContextKey = "Context";
const char* CameraDevice::kDeviceKey = "Device";
const char* CameraDevice::kErrorCodeKey = "ErrorCode";
const char* CameraDevice::kCallbackFpKey = "Callback";
const char* CameraDevice::kSessionSpKey = "SessionSp";
const char* CameraDevice::kCaptureRequestKey = "CaptureRequest";
const char* CameraDevice::kTimeStampKey = "TimeStamp";
const char* CameraDevice::kCaptureResultKey = "CaptureResult";
const char* CameraDevice::kPhysicalCaptureResultKey = "PhysicalCaptureResult";
const char* CameraDevice::kCaptureFailureKey = "CaptureFailure";
const char* CameraDevice::kSequenceIdKey = "SequenceId";
const char* CameraDevice::kFrameNumberKey = "FrameNumber";
const char* CameraDevice::kAnwKey = "Anw";
const char* CameraDevice::kFailingPhysicalCameraId= "FailingPhysicalCameraId";
/**
* CameraDevice Implementation
*/
CameraDevice::CameraDevice(
const char* id,
ACameraDevice_StateCallbacks* cb,
sp<ACameraMetadata> chars,
ACameraDevice* wrapper) :
mCameraId(id),
mAppCallbacks(*cb),
mChars(std::move(chars)),
mServiceCallback(new ServiceCallback(this)),
mWrapper(wrapper),
mInError(false),
mError(ACAMERA_OK),
mIdle(true),
mCurrentSession(nullptr) {
mClosing = false;
// Setup looper thread to perfrom device callbacks to app
mCbLooper = new ALooper;
mCbLooper->setName("C2N-dev-looper");
status_t err = mCbLooper->start(
/*runOnCallingThread*/false,
/*canCallJava*/ true,
PRIORITY_DEFAULT);
if (err != OK) {
ALOGE("%s: Unable to start camera device callback looper: %s (%d)",
__FUNCTION__, strerror(-err), err);
setCameraDeviceErrorLocked(ACAMERA_ERROR_CAMERA_DEVICE);
}
mHandler = new CallbackHandler(id);
mCbLooper->registerHandler(mHandler);
const CameraMetadata& metadata = mChars->getInternalData();
camera_metadata_ro_entry entry = metadata.find(ANDROID_REQUEST_PARTIAL_RESULT_COUNT);
if (entry.count != 1) {
ALOGW("%s: bad count %zu for partial result count", __FUNCTION__, entry.count);
mPartialResultCount = 1;
} else {
mPartialResultCount = entry.data.i32[0];
}
entry = metadata.find(ANDROID_LENS_INFO_SHADING_MAP_SIZE);
if (entry.count != 2) {
ALOGW("%s: bad count %zu for shading map size", __FUNCTION__, entry.count);
mShadingMapSize[0] = 0;
mShadingMapSize[1] = 0;
} else {
mShadingMapSize[0] = entry.data.i32[0];
mShadingMapSize[1] = entry.data.i32[1];
}
}
// Device close implementaiton
CameraDevice::~CameraDevice() {
sp<ACameraCaptureSession> session = mCurrentSession.promote();
{
Mutex::Autolock _l(mDeviceLock);
if (!isClosed()) {
disconnectLocked(session);
}
mCurrentSession = nullptr;
LOG_ALWAYS_FATAL_IF(mCbLooper != nullptr,
"CameraDevice looper should've been stopped before ~CameraDevice");
}
}
void
CameraDevice::postSessionMsgAndCleanup(sp<AMessage>& msg) {
msg->post();
msg.clear();
sp<AMessage> cleanupMsg = new AMessage(kWhatCleanUpSessions, mHandler);
cleanupMsg->post();
}
// TODO: cached created request?
camera_status_t
CameraDevice::createCaptureRequest(
ACameraDevice_request_template templateId,
const ACameraIdList* physicalCameraIdList,
ACaptureRequest** request) const {
Mutex::Autolock _l(mDeviceLock);
camera_status_t ret = checkCameraClosedOrErrorLocked();
if (ret != ACAMERA_OK) {
return ret;
}
if (mRemote == nullptr) {
return ACAMERA_ERROR_CAMERA_DISCONNECTED;
}
CameraMetadata rawRequest;
Status status = Status::UNKNOWN_ERROR;
auto remoteRet = mRemote->createDefaultRequest(
utils::convertToHidl(templateId),
[&status, &rawRequest](auto s, const hidl_vec<uint8_t> &metadata) {
status = s;
if (status == Status::NO_ERROR && utils::convertFromHidlCloned(metadata, &rawRequest)) {
} else {
ALOGE("%s: Couldn't create default request", __FUNCTION__);
}
});
CHECK_TRANSACTION_AND_RET(remoteRet, status, "createDefaultRequest()")
ACaptureRequest* outReq = new ACaptureRequest();
outReq->settings = new ACameraMetadata(rawRequest.release(), ACameraMetadata::ACM_REQUEST);
if (physicalCameraIdList != nullptr) {
for (auto i = 0; i < physicalCameraIdList->numCameras; i++) {
outReq->physicalSettings.emplace(physicalCameraIdList->cameraIds[i],
new ACameraMetadata(*(outReq->settings)));
}
}
outReq->targets = new ACameraOutputTargets();
*request = outReq;
return ACAMERA_OK;
}
camera_status_t
CameraDevice::createCaptureSession(
const ACaptureSessionOutputContainer* outputs,
const ACaptureRequest* sessionParameters,
const ACameraCaptureSession_stateCallbacks* callbacks,
/*out*/ACameraCaptureSession** session) {
sp<ACameraCaptureSession> currentSession = mCurrentSession.promote();
Mutex::Autolock _l(mDeviceLock);
camera_status_t ret = checkCameraClosedOrErrorLocked();
if (ret != ACAMERA_OK) {
return ret;
}
if (currentSession != nullptr) {
currentSession->closeByDevice();
stopRepeatingLocked();
}
// Create new session
ret = configureStreamsLocked(outputs, sessionParameters);
if (ret != ACAMERA_OK) {
ALOGE("Fail to create new session. cannot configure streams");
return ret;
}
ACameraCaptureSession* newSession = new ACameraCaptureSession(
mNextSessionId++, outputs, callbacks, this);
// set new session as current session
newSession->incStrong((void *) ACameraDevice_createCaptureSession);
mCurrentSession = newSession;
mFlushing = false;
*session = newSession;
return ACAMERA_OK;
}
camera_status_t CameraDevice::isSessionConfigurationSupported(
const ACaptureSessionOutputContainer* sessionOutputContainer) const {
Mutex::Autolock _l(mDeviceLock);
camera_status_t ret = checkCameraClosedOrErrorLocked();
if (ret != ACAMERA_OK) {
return ret;
}
SessionConfiguration sessionConfig;
sessionConfig.inputWidth = 0;
sessionConfig.inputHeight = 0;
sessionConfig.inputFormat = -1;
sessionConfig.operationMode = StreamConfigurationMode::NORMAL_MODE;
sessionConfig.outputStreams.resize(sessionOutputContainer->mOutputs.size());
size_t index = 0;
for (const auto& output : sessionOutputContainer->mOutputs) {
sessionConfig.outputStreams[index].rotation = utils::convertToHidl(output.mRotation);
sessionConfig.outputStreams[index].windowGroupId = -1;
sessionConfig.outputStreams[index].windowHandles.resize(output.mSharedWindows.size() + 1);
sessionConfig.outputStreams[index].windowHandles[0] = output.mWindow;
sessionConfig.outputStreams[index].physicalCameraId = output.mPhysicalCameraId;
index++;
}
bool configSupported = false;
Status status = Status::UNKNOWN_ERROR;
auto remoteRet = mRemote->isSessionConfigurationSupported(sessionConfig,
[&status, &configSupported](auto s, auto supported) {
status = s;
configSupported = supported;
});
CHECK_TRANSACTION_AND_RET(remoteRet, status, "isSessionConfigurationSupported()");
return configSupported ? ACAMERA_OK : ACAMERA_ERROR_STREAM_CONFIGURE_FAIL;
}
static void addMetadataToPhysicalCameraSettings(const CameraMetadata *metadata,
const std::string &cameraId, PhysicalCameraSettings *physicalCameraSettings) {
CameraMetadata metadataCopy = *metadata;
camera_metadata_t *camera_metadata = metadataCopy.release();
HCameraMetadata hCameraMetadata;
utils::convertToHidl(camera_metadata, &hCameraMetadata, /*shouldOwn*/ true);
physicalCameraSettings->settings.metadata(std::move(hCameraMetadata));
physicalCameraSettings->id = cameraId;
}
void CameraDevice::addRequestSettingsMetadata(ACaptureRequest *aCaptureRequest,
sp<CaptureRequest> &req) {
req->mPhysicalCameraSettings.resize(1 + aCaptureRequest->physicalSettings.size());
addMetadataToPhysicalCameraSettings(&(aCaptureRequest->settings->getInternalData()), getId(),
&(req->mPhysicalCameraSettings[0]));
size_t i = 1;
for (auto &physicalSetting : aCaptureRequest->physicalSettings) {
addMetadataToPhysicalCameraSettings(&(physicalSetting.second->getInternalData()),
physicalSetting.first, &(req->mPhysicalCameraSettings[i]));
i++;
}
}
camera_status_t CameraDevice::updateOutputConfigurationLocked(ACaptureSessionOutput *output) {
camera_status_t ret = checkCameraClosedOrErrorLocked();
if (ret != ACAMERA_OK) {
return ret;
}
if (output == nullptr) {
return ACAMERA_ERROR_INVALID_PARAMETER;
}
if (!output->mIsShared) {
ALOGE("Error output configuration is not shared");
return ACAMERA_ERROR_INVALID_OPERATION;
}
int32_t streamId = -1;
for (auto& kvPair : mConfiguredOutputs) {
if (utils::isWindowNativeHandleEqual(kvPair.second.first, output->mWindow)) {
streamId = kvPair.first;
break;
}
}
if (streamId < 0) {
ALOGE("Error: Invalid output configuration");
return ACAMERA_ERROR_INVALID_PARAMETER;
}
OutputConfigurationWrapper outConfigW;
OutputConfiguration &outConfig = outConfigW.mOutputConfiguration;
outConfig.rotation = utils::convertToHidl(output->mRotation);
outConfig.windowHandles.resize(output->mSharedWindows.size() + 1);
outConfig.windowHandles[0] = output->mWindow;
outConfig.physicalCameraId = output->mPhysicalCameraId;
int i = 1;
for (auto& anw : output->mSharedWindows) {
outConfig.windowHandles[i++] = anw;
}
auto remoteRet = mRemote->updateOutputConfiguration(streamId, outConfig);
if (!remoteRet.isOk()) {
ALOGE("%s: Transaction error in updating OutputConfiguration: %s", __FUNCTION__,
remoteRet.description().c_str());
return ACAMERA_ERROR_UNKNOWN;
}
switch (remoteRet) {
case Status::NO_ERROR:
break;
case Status::INVALID_OPERATION:
ALOGE("Camera device %s invalid operation", getId());
return ACAMERA_ERROR_INVALID_OPERATION;
case Status::ALREADY_EXISTS:
ALOGE("Camera device %s output surface already exists", getId());
return ACAMERA_ERROR_INVALID_PARAMETER;
case Status::ILLEGAL_ARGUMENT:
ALOGE("Camera device %s invalid input argument", getId());
return ACAMERA_ERROR_INVALID_PARAMETER;
default:
ALOGE("Camera device %s failed to add shared output", getId());
return ACAMERA_ERROR_UNKNOWN;
}
mConfiguredOutputs[streamId] = std::make_pair(output->mWindow, outConfigW);
return ACAMERA_OK;
}
camera_status_t
CameraDevice::allocateCaptureRequestLocked(
const ACaptureRequest* request, /*out*/sp<CaptureRequest> &outReq) {
sp<CaptureRequest> req(new CaptureRequest());
req->mCaptureRequest.physicalCameraSettings.resize(1 + request->physicalSettings.size());
size_t index = 0;
allocateOneCaptureRequestMetadata(
req->mCaptureRequest.physicalCameraSettings[index++], mCameraId, request->settings);
for (auto& physicalEntry : request->physicalSettings) {
allocateOneCaptureRequestMetadata(
req->mCaptureRequest.physicalCameraSettings[index++],
physicalEntry.first, physicalEntry.second);
}
std::vector<int32_t> requestStreamIdxList;
std::vector<int32_t> requestSurfaceIdxList;
for (auto outputTarget : request->targets->mOutputs) {
native_handle_t* anw = outputTarget.mWindow;
bool found = false;
req->mSurfaceList.push_back(anw);
// lookup stream/surface ID
for (const auto& kvPair : mConfiguredOutputs) {
int streamId = kvPair.first;
const OutputConfigurationWrapper& outConfig = kvPair.second.second;
const auto& windowHandles = outConfig.mOutputConfiguration.windowHandles;
for (int surfaceId = 0; surfaceId < (int) windowHandles.size(); surfaceId++) {
// If two native handles are equivalent, so are their surfaces.
if (utils::isWindowNativeHandleEqual(windowHandles[surfaceId].getNativeHandle(),
anw)) {
found = true;
requestStreamIdxList.push_back(streamId);
requestSurfaceIdxList.push_back(surfaceId);
break;
}
}
if (found) {
break;
}
}
if (!found) {
ALOGE("Unconfigured output target %p in capture request!", anw);
return ACAMERA_ERROR_INVALID_PARAMETER;
}
}
req->mCaptureRequest.streamAndWindowIds.resize(requestStreamIdxList.size());
for (int i = 0; i < requestStreamIdxList.size(); i++) {
req->mCaptureRequest.streamAndWindowIds[i].streamId = requestStreamIdxList[i];
req->mCaptureRequest.streamAndWindowIds[i].windowId = requestSurfaceIdxList[i];
}
outReq = req;
return ACAMERA_OK;
}
void CameraDevice::allocateOneCaptureRequestMetadata(
PhysicalCameraSettings& cameraSettings,
const std::string& id, const sp<ACameraMetadata>& metadata) {
cameraSettings.id = id;
// TODO: Do we really need to copy the metadata here ?
CameraMetadata metadataCopy = metadata->getInternalData();
camera_metadata_t *cameraMetadata = metadataCopy.release();
HCameraMetadata hCameraMetadata;
utils::convertToHidl(cameraMetadata, &hCameraMetadata, true);
if (metadata != nullptr) {
if (hCameraMetadata.data() != nullptr &&
mCaptureRequestMetadataQueue != nullptr &&
mCaptureRequestMetadataQueue->write(
reinterpret_cast<const uint8_t *>(hCameraMetadata.data()),
hCameraMetadata.size())) {
// The metadata field of the union would've been destructued, so no need
// to re-size it.
cameraSettings.settings.fmqMetadataSize(hCameraMetadata.size());
} else {
ALOGE("Fmq write capture result failed, falling back to hwbinder");
cameraSettings.settings.metadata(std::move(hCameraMetadata));
}
}
}
ACaptureRequest*
CameraDevice::allocateACaptureRequest(sp<CaptureRequest>& req, const char* deviceId) {
ACaptureRequest* pRequest = new ACaptureRequest();
for (size_t i = 0; i < req->mPhysicalCameraSettings.size(); i++) {
const std::string& id = req->mPhysicalCameraSettings[i].id;
CameraMetadata clone;
utils::convertFromHidlCloned(req->mPhysicalCameraSettings[i].settings.metadata(), &clone);
camera_metadata_t *clonep = clone.release();
if (id == deviceId) {
pRequest->settings = new ACameraMetadata(clonep, ACameraMetadata::ACM_REQUEST);
} else {
pRequest->physicalSettings[req->mPhysicalCameraSettings[i].id] =
new ACameraMetadata(clonep, ACameraMetadata::ACM_REQUEST);
}
}
pRequest->targets = new ACameraOutputTargets();
for (size_t i = 0; i < req->mSurfaceList.size(); i++) {
native_handle_t* anw = req->mSurfaceList[i];
ACameraOutputTarget outputTarget(anw);
pRequest->targets->mOutputs.insert(outputTarget);
}
return pRequest;
}
void
CameraDevice::freeACaptureRequest(ACaptureRequest* req) {
if (req == nullptr) {
return;
}
req->settings.clear();
delete req->targets;
delete req;
}
void
CameraDevice::notifySessionEndOfLifeLocked(ACameraCaptureSession* session) {
if (isClosed()) {
// Device is closing already. do nothing
return;
}
if (mCurrentSession != session) {
// Session has been replaced by other seesion or device is closed
return;
}
mCurrentSession = nullptr;
// Should not happen
if (!session->mIsClosed) {
ALOGE("Error: unclosed session %p reaches end of life!", session);
setCameraDeviceErrorLocked(ACAMERA_ERROR_CAMERA_DEVICE);
return;
}
// No new session, unconfigure now
camera_status_t ret = configureStreamsLocked(nullptr, nullptr);
if (ret != ACAMERA_OK) {
ALOGE("Unconfigure stream failed. Device might still be configured! ret %d", ret);
}
}
void
CameraDevice::disconnectLocked(sp<ACameraCaptureSession>& session) {
if (mClosing.exchange(true)) {
// Already closing, just return
ALOGW("Camera device %s is already closing.", getId());
return;
}
if (mRemote != nullptr) {
auto ret = mRemote->disconnect();
if (!ret.isOk()) {
ALOGE("%s: Transaction error while disconnecting device %s", __FUNCTION__,
ret.description().c_str());
}
}
mRemote = nullptr;
if (session != nullptr) {
session->closeByDevice();
}
}
camera_status_t
CameraDevice::stopRepeatingLocked() {
camera_status_t ret = checkCameraClosedOrErrorLocked();
if (ret != ACAMERA_OK) {
ALOGE("Camera %s stop repeating failed! ret %d", getId(), ret);
return ret;
}
if (mRepeatingSequenceId != REQUEST_ID_NONE) {
int repeatingSequenceId = mRepeatingSequenceId;
mRepeatingSequenceId = REQUEST_ID_NONE;
int64_t lastFrameNumber;
Status status = Status::UNKNOWN_ERROR;
auto remoteRet = mRemote->cancelRepeatingRequest(
[&status, &lastFrameNumber](Status s, auto frameNumber) {
status = s;
lastFrameNumber = frameNumber;
});
CHECK_TRANSACTION_AND_RET(remoteRet, status, "cancelRepeatingRequest()");
checkRepeatingSequenceCompleteLocked(repeatingSequenceId, lastFrameNumber);
}
return ACAMERA_OK;
}
camera_status_t
CameraDevice::flushLocked(ACameraCaptureSession* session) {
camera_status_t ret = checkCameraClosedOrErrorLocked();
if (ret != ACAMERA_OK) {
ALOGE("Camera %s abort captures failed! ret %d", getId(), ret);
return ret;
}
// This should never happen because creating a new session will close
// previous one and thus reject any API call from previous session.
// But still good to check here in case something unexpected happen.
if (mCurrentSession != session) {
ALOGE("Camera %s session %p is not current active session!", getId(), session);
return ACAMERA_ERROR_INVALID_OPERATION;
}
if (mFlushing) {
ALOGW("Camera %s is already aborting captures", getId());
return ACAMERA_OK;
}
mFlushing = true;
// Send onActive callback to guarantee there is always active->ready transition
sp<AMessage> msg = new AMessage(kWhatSessionStateCb, mHandler);
msg->setPointer(kContextKey, session->mUserSessionCallback.context);
msg->setObject(kSessionSpKey, session);
msg->setPointer(kCallbackFpKey, (void*) session->mUserSessionCallback.onActive);
postSessionMsgAndCleanup(msg);
// If device is already idling, send callback and exit early
if (mIdle) {
sp<AMessage> msg = new AMessage(kWhatSessionStateCb, mHandler);
msg->setPointer(kContextKey, session->mUserSessionCallback.context);
msg->setObject(kSessionSpKey, session);
msg->setPointer(kCallbackFpKey, (void*) session->mUserSessionCallback.onReady);
postSessionMsgAndCleanup(msg);
mFlushing = false;
return ACAMERA_OK;
}
int64_t lastFrameNumber;
Status status = Status::UNKNOWN_ERROR;
auto remoteRet = mRemote->flush([&status, &lastFrameNumber](auto s, auto frameNumber) {
status = s;
lastFrameNumber = frameNumber;
});
CHECK_TRANSACTION_AND_RET(remoteRet, status, "flush()")
if (mRepeatingSequenceId != REQUEST_ID_NONE) {
checkRepeatingSequenceCompleteLocked(mRepeatingSequenceId, lastFrameNumber);
}
return ACAMERA_OK;
}
camera_status_t
CameraDevice::waitUntilIdleLocked() {
camera_status_t ret = checkCameraClosedOrErrorLocked();
if (ret != ACAMERA_OK) {
ALOGE("Wait until camera %s idle failed! ret %d", getId(), ret);
return ret;
}
if (mRepeatingSequenceId != REQUEST_ID_NONE) {
ALOGE("Camera device %s won't go to idle when there is repeating request!", getId());
return ACAMERA_ERROR_INVALID_OPERATION;
}
auto remoteRet = mRemote->waitUntilIdle();
CHECK_TRANSACTION_AND_RET(remoteRet, remoteRet, "waitUntilIdle()")
return ACAMERA_OK;
}
camera_status_t
CameraDevice::configureStreamsLocked(const ACaptureSessionOutputContainer* outputs,
const ACaptureRequest* sessionParameters) {
ACaptureSessionOutputContainer emptyOutput;
if (outputs == nullptr) {
outputs = &emptyOutput;
}
camera_status_t ret = checkCameraClosedOrErrorLocked();
if (ret != ACAMERA_OK) {
return ret;
}
std::set<std::pair<native_handle_ptr_wrapper, OutputConfigurationWrapper>> outputSet;
for (auto outConfig : outputs->mOutputs) {
native_handle_t* anw = outConfig.mWindow;
OutputConfigurationWrapper outConfigInsertW;
OutputConfiguration &outConfigInsert = outConfigInsertW.mOutputConfiguration;
outConfigInsert.rotation = utils::convertToHidl(outConfig.mRotation);
outConfigInsert.windowGroupId = -1;
outConfigInsert.windowHandles.resize(outConfig.mSharedWindows.size() + 1);
outConfigInsert.windowHandles[0] = anw;
outConfigInsert.physicalCameraId = outConfig.mPhysicalCameraId;
native_handle_ptr_wrapper wrap(anw);
outputSet.insert(std::make_pair(anw, outConfigInsertW));
}
std::set<std::pair<native_handle_ptr_wrapper, OutputConfigurationWrapper>> addSet = outputSet;
std::vector<int32_t> deleteList;
// Determine which streams need to be created, which to be deleted
for (auto& kvPair : mConfiguredOutputs) {
int32_t streamId = kvPair.first;
auto& outputPair = kvPair.second;
if (outputSet.count(outputPair)) {
deleteList.push_back(streamId); // Need to delete a no longer needed stream
} else {
addSet.erase(outputPair); // No need to add already existing stream
}
}
ret = stopRepeatingLocked();
if (ret != ACAMERA_OK) {
ALOGE("Camera device %s stop repeating failed, ret %d", getId(), ret);
return ret;
}
ret = waitUntilIdleLocked();
if (ret != ACAMERA_OK) {
ALOGE("Camera device %s wait until idle failed, ret %d", getId(), ret);
return ret;
}
// Send onReady to previous session
// CurrentSession will be updated after configureStreamLocked, so here
// mCurrentSession is the session to be replaced by a new session
if (!mIdle && mCurrentSession != nullptr) {
if (mBusySession != mCurrentSession) {
ALOGE("Current session != busy session");
setCameraDeviceErrorLocked(ACAMERA_ERROR_CAMERA_DEVICE);
return ACAMERA_ERROR_CAMERA_DEVICE;
}
sp<AMessage> msg = new AMessage(kWhatSessionStateCb, mHandler);
msg->setPointer(kContextKey, mBusySession->mUserSessionCallback.context);
msg->setObject(kSessionSpKey, mBusySession);
msg->setPointer(kCallbackFpKey, (void*) mBusySession->mUserSessionCallback.onReady);
mBusySession.clear();
postSessionMsgAndCleanup(msg);
}
mIdle = true;
auto remoteRet = mRemote->beginConfigure();
CHECK_TRANSACTION_AND_RET(remoteRet, remoteRet, "beginConfigure()")
// delete to-be-deleted streams
for (auto streamId : deleteList) {
remoteRet = mRemote->deleteStream(streamId);
CHECK_TRANSACTION_AND_RET(remoteRet, remoteRet, "deleteStream()")
mConfiguredOutputs.erase(streamId);
}
// add new streams
for (auto outputPair : addSet) {
int streamId;
Status status = Status::UNKNOWN_ERROR;
auto ret = mRemote->createStream(outputPair.second,
[&status, &streamId](Status s, auto stream_id) {
status = s;
streamId = stream_id;
});
CHECK_TRANSACTION_AND_RET(ret, status, "createStream()")
mConfiguredOutputs.insert(std::make_pair(streamId, outputPair));
}
CameraMetadata params;
HCameraMetadata hidlParams;
if ((sessionParameters != nullptr) && (sessionParameters->settings != nullptr)) {
params.append(sessionParameters->settings->getInternalData());
const camera_metadata_t *params_metadata = params.getAndLock();
utils::convertToHidl(params_metadata, &hidlParams);
params.unlock(params_metadata);
}
remoteRet = mRemote->endConfigure(StreamConfigurationMode::NORMAL_MODE, hidlParams);
CHECK_TRANSACTION_AND_RET(remoteRet, remoteRet, "endConfigure()")
return ACAMERA_OK;
}
void
CameraDevice::setRemoteDevice(sp<ICameraDeviceUser> remote) {
Mutex::Autolock _l(mDeviceLock);
mRemote = remote;
}
bool
CameraDevice::setDeviceMetadataQueues() {
if (mRemote == nullptr) {
ALOGE("mRemote must not be null while trying to fetch metadata queues");
return false;
}
std::shared_ptr<RequestMetadataQueue> &reqQueue = mCaptureRequestMetadataQueue;
auto ret =
mRemote->getCaptureRequestMetadataQueue(
[&reqQueue](const auto &mqDescriptor) {
reqQueue = std::make_shared<RequestMetadataQueue>(mqDescriptor);
if (!reqQueue->isValid() || reqQueue->availableToWrite() <=0) {
ALOGE("Empty fmq from cameraserver");
reqQueue = nullptr;
}
});
if (!ret.isOk()) {
ALOGE("Transaction error trying to get capture request metadata queue");
return false;
}
std::shared_ptr<ResultMetadataQueue> &resQueue = mCaptureResultMetadataQueue;
ret =
mRemote->getCaptureResultMetadataQueue(
[&resQueue](const auto &mqDescriptor) {
resQueue = std::make_shared<ResultMetadataQueue>(mqDescriptor);
if (!resQueue->isValid() || resQueue->availableToWrite() <=0) {
ALOGE("Empty fmq from cameraserver");
}
});
if (!ret.isOk()) {
ALOGE("Transaction error trying to get capture result metadata queue");
return false;
}
return true;
}
camera_status_t
CameraDevice::checkCameraClosedOrErrorLocked() const {
if (mRemote == nullptr) {
ALOGE("%s: camera device already closed", __FUNCTION__);
return ACAMERA_ERROR_CAMERA_DISCONNECTED;
}
if (mInError) {// triggered by onDeviceError
ALOGE("%s: camera device has encountered a serious error", __FUNCTION__);
return mError;
}
return ACAMERA_OK;
}
void
CameraDevice::setCameraDeviceErrorLocked(camera_status_t error) {
mInError = true;
mError = error;
return;
}
void
CameraDevice::FrameNumberTracker::updateTracker(int64_t frameNumber, bool isError) {
ALOGV("updateTracker frame %" PRId64 " isError %d", frameNumber, isError);
if (isError) {
mFutureErrorSet.insert(frameNumber);
} else if (frameNumber <= mCompletedFrameNumber) {
ALOGE("Frame number %" PRId64 " decreased! current fn %" PRId64,
frameNumber, mCompletedFrameNumber);
return;
} else {
if (frameNumber != mCompletedFrameNumber + 1) {
ALOGE("Frame number out of order. Expect %" PRId64 " but get %" PRId64,
mCompletedFrameNumber + 1, frameNumber);
// Do not assert as in java implementation
}
mCompletedFrameNumber = frameNumber;
}
update();
}
void
CameraDevice::FrameNumberTracker::update() {
for (auto it = mFutureErrorSet.begin(); it != mFutureErrorSet.end();) {
int64_t errorFrameNumber = *it;
if (errorFrameNumber == mCompletedFrameNumber + 1) {
mCompletedFrameNumber++;
it = mFutureErrorSet.erase(it);
} else if (errorFrameNumber <= mCompletedFrameNumber) {
// This should not happen, but deal with it anyway
ALOGE("Completd frame number passed through current frame number!");
// erase the old error since it's no longer useful
it = mFutureErrorSet.erase(it);
} else {
// Normal requests hasn't catched up error frames, just break
break;
}
}
ALOGV("Update complete frame %" PRId64, mCompletedFrameNumber);
}
void
CameraDevice::onCaptureErrorLocked(
ErrorCode errorCode,
const CaptureResultExtras& resultExtras) {
int sequenceId = resultExtras.requestId;
int64_t frameNumber = resultExtras.frameNumber;
int32_t burstId = resultExtras.burstId;
auto it = mSequenceCallbackMap.find(sequenceId);
if (it == mSequenceCallbackMap.end()) {
ALOGE("%s: Error: capture sequence index %d not found!",
__FUNCTION__, sequenceId);
setCameraDeviceErrorLocked(ACAMERA_ERROR_CAMERA_SERVICE);
return;
}
CallbackHolder cbh = (*it).second;
sp<ACameraCaptureSession> session = cbh.mSession;
if ((size_t) burstId >= cbh.mRequests.size()) {
ALOGE("%s: Error: request index %d out of bound (size %zu)",
__FUNCTION__, burstId, cbh.mRequests.size());
setCameraDeviceErrorLocked(ACAMERA_ERROR_CAMERA_SERVICE);
return;
}
sp<CaptureRequest> request = cbh.mRequests[burstId];
// Handle buffer error
if (errorCode == ErrorCode::CAMERA_BUFFER) {
int32_t streamId = resultExtras.errorStreamId;
ACameraCaptureSession_captureCallback_bufferLost onBufferLost =
cbh.mOnCaptureBufferLost;
auto outputPairIt = mConfiguredOutputs.find(streamId);
if (outputPairIt == mConfiguredOutputs.end()) {
ALOGE("%s: Error: stream id %d does not exist", __FUNCTION__, streamId);
setCameraDeviceErrorLocked(ACAMERA_ERROR_CAMERA_SERVICE);
return;
}
const auto& windowHandles = outputPairIt->second.second.mOutputConfiguration.windowHandles;
for (const auto& outHandle : windowHandles) {
for (auto streamAndWindowId : request->mCaptureRequest.streamAndWindowIds) {
int32_t windowId = streamAndWindowId.windowId;
if (utils::isWindowNativeHandleEqual(windowHandles[windowId],outHandle)) {
native_handle_t* anw =
const_cast<native_handle_t *>(windowHandles[windowId].getNativeHandle());
ALOGV("Camera %s Lost output buffer for ANW %p frame %" PRId64,
getId(), anw, frameNumber);
sp<AMessage> msg = new AMessage(kWhatCaptureBufferLost, mHandler);
msg->setPointer(kContextKey, cbh.mContext);
msg->setObject(kSessionSpKey, session);
msg->setPointer(kCallbackFpKey, (void*) onBufferLost);
msg->setObject(kCaptureRequestKey, request);
msg->setPointer(kAnwKey, (void*) anw);
msg->setInt64(kFrameNumberKey, frameNumber);
postSessionMsgAndCleanup(msg);
}
}
}
} else { // Handle other capture failures
// Fire capture failure callback if there is one registered
ACameraCaptureSession_captureCallback_failed onError = cbh.mOnCaptureFailed;
sp<CameraCaptureFailure> failure(new CameraCaptureFailure());
failure->frameNumber = frameNumber;
// TODO: refine this when implementing flush
failure->reason = CAPTURE_FAILURE_REASON_ERROR;
failure->sequenceId = sequenceId;
failure->wasImageCaptured = (errorCode == ErrorCode::CAMERA_RESULT);
sp<AMessage> msg = new AMessage(cbh.mIsLogicalCameraCallback ? kWhatLogicalCaptureFail :
kWhatCaptureFail, mHandler);
msg->setPointer(kContextKey, cbh.mContext);
msg->setObject(kSessionSpKey, session);
if (cbh.mIsLogicalCameraCallback) {
if (resultExtras.errorPhysicalCameraId.size() > 0) {
msg->setString(kFailingPhysicalCameraId, resultExtras.errorPhysicalCameraId.c_str(),
resultExtras.errorPhysicalCameraId.size());
}
msg->setPointer(kCallbackFpKey, (void*) cbh.mOnLogicalCameraCaptureFailed);
} else {
msg->setPointer(kCallbackFpKey, (void*) onError);
}
msg->setObject(kCaptureRequestKey, request);
msg->setObject(kCaptureFailureKey, failure);
postSessionMsgAndCleanup(msg);
// Update tracker
mFrameNumberTracker.updateTracker(frameNumber, /*isError*/true);
checkAndFireSequenceCompleteLocked();
}
return;
}
CameraDevice::CallbackHandler::CallbackHandler(const char *id) : mId(id) { }
void CameraDevice::CallbackHandler::onMessageReceived(
const sp<AMessage> &msg) {
switch (msg->what()) {
case kWhatOnDisconnected:
case kWhatOnError:
case kWhatSessionStateCb:
case kWhatCaptureStart:
case kWhatCaptureResult:
case kWhatLogicalCaptureResult:
case kWhatCaptureFail:
case kWhatLogicalCaptureFail:
case kWhatCaptureSeqEnd:
case kWhatCaptureSeqAbort:
case kWhatCaptureBufferLost:
ALOGV("%s: Received msg %d", __FUNCTION__, msg->what());
break;
case kWhatCleanUpSessions:
mCachedSessions.clear();
return;
default:
ALOGE("%s:Error: unknown device callback %d", __FUNCTION__, msg->what());
return;
}
// Check the common part of all message
void* context;
bool found = msg->findPointer(kContextKey, &context);
if (!found) {
ALOGE("%s: Cannot find callback context!", __FUNCTION__);
return;
}
switch (msg->what()) {
case kWhatOnDisconnected:
{
ACameraDevice* dev;
found = msg->findPointer(kDeviceKey, (void**) &dev);
if (!found || dev == nullptr) {
ALOGE("%s: Cannot find device pointer!", __FUNCTION__);
return;
}
ACameraDevice_StateCallback onDisconnected;
found = msg->findPointer(kCallbackFpKey, (void**) &onDisconnected);
if (!found) {
ALOGE("%s: Cannot find onDisconnected!", __FUNCTION__);
return;
}
if (onDisconnected == nullptr) {
return;
}
(*onDisconnected)(context, dev);
break;
}
case kWhatOnError:
{
ACameraDevice* dev;
found = msg->findPointer(kDeviceKey, (void**) &dev);
if (!found || dev == nullptr) {
ALOGE("%s: Cannot find device pointer!", __FUNCTION__);
return;
}
ACameraDevice_ErrorStateCallback onError;
found = msg->findPointer(kCallbackFpKey, (void**) &onError);
if (!found) {
ALOGE("%s: Cannot find onError!", __FUNCTION__);
return;
}
int errorCode;
found = msg->findInt32(kErrorCodeKey, &errorCode);
if (!found) {
ALOGE("%s: Cannot find error code!", __FUNCTION__);
return;
}
if (onError == nullptr) {
return;
}
(*onError)(context, dev, errorCode);
break;
}
case kWhatSessionStateCb:
case kWhatCaptureStart:
case kWhatCaptureResult:
case kWhatLogicalCaptureResult:
case kWhatCaptureFail:
case kWhatLogicalCaptureFail:
case kWhatCaptureSeqEnd:
case kWhatCaptureSeqAbort:
case kWhatCaptureBufferLost:
{
sp<RefBase> obj;
found = msg->findObject(kSessionSpKey, &obj);
if (!found || obj == nullptr) {
ALOGE("%s: Cannot find session pointer!", __FUNCTION__);
return;
}
sp<ACameraCaptureSession> session(static_cast<ACameraCaptureSession*>(obj.get()));
mCachedSessions.push(session);
sp<CaptureRequest> requestSp = nullptr;
const char *id_cstr = mId.c_str();
switch (msg->what()) {
case kWhatCaptureStart:
case kWhatCaptureResult:
case kWhatLogicalCaptureResult:
case kWhatCaptureFail:
case kWhatLogicalCaptureFail:
case kWhatCaptureBufferLost:
found = msg->findObject(kCaptureRequestKey, &obj);
if (!found) {
ALOGE("%s: Cannot find capture request!", __FUNCTION__);
return;
}
requestSp = static_cast<CaptureRequest*>(obj.get());
break;
}
switch (msg->what()) {
case kWhatSessionStateCb:
{
ACameraCaptureSession_stateCallback onState;
found = msg->findPointer(kCallbackFpKey, (void**) &onState);
if (!found) {
ALOGE("%s: Cannot find state callback!", __FUNCTION__);
return;
}
if (onState == nullptr) {
return;
}
(*onState)(context, session.get());
break;
}
case kWhatCaptureStart:
{
ACameraCaptureSession_captureCallback_start onStart;
found = msg->findPointer(kCallbackFpKey, (void**) &onStart);
if (!found) {
ALOGE("%s: Cannot find capture start callback!", __FUNCTION__);
return;
}
if (onStart == nullptr) {
return;
}
int64_t timestamp;
found = msg->findInt64(kTimeStampKey, ×tamp);
if (!found) {
ALOGE("%s: Cannot find timestamp!", __FUNCTION__);
return;
}
ACaptureRequest* request = allocateACaptureRequest(requestSp, id_cstr);
(*onStart)(context, session.get(), request, timestamp);
freeACaptureRequest(request);
break;
}
case kWhatCaptureResult:
{
ACameraCaptureSession_captureCallback_result onResult;
found = msg->findPointer(kCallbackFpKey, (void**) &onResult);
if (!found) {
ALOGE("%s: Cannot find capture result callback!", __FUNCTION__);
return;
}
if (onResult == nullptr) {
return;
}
found = msg->findObject(kCaptureResultKey, &obj);
if (!found) {
ALOGE("%s: Cannot find capture result!", __FUNCTION__);
return;
}
sp<ACameraMetadata> result(static_cast<ACameraMetadata*>(obj.get()));
ACaptureRequest* request = allocateACaptureRequest(requestSp, id_cstr);
(*onResult)(context, session.get(), request, result.get());
freeACaptureRequest(request);
break;
}
case kWhatLogicalCaptureResult:
{
ACameraCaptureSession_logicalCamera_captureCallback_result onResult;
found = msg->findPointer(kCallbackFpKey, (void**) &onResult);
if (!found) {
ALOGE("%s: Cannot find capture result callback!", __FUNCTION__);
return;
}
if (onResult == nullptr) {
return;
}
found = msg->findObject(kCaptureResultKey, &obj);
if (!found) {
ALOGE("%s: Cannot find capture result!", __FUNCTION__);
return;
}
sp<ACameraMetadata> result(static_cast<ACameraMetadata*>(obj.get()));
found = msg->findObject(kPhysicalCaptureResultKey, &obj);
if (!found) {
ALOGE("%s: Cannot find physical capture result!", __FUNCTION__);
return;
}
sp<ACameraPhysicalCaptureResultInfo> physicalResult(
static_cast<ACameraPhysicalCaptureResultInfo*>(obj.get()));
std::vector<PhysicalCaptureResultInfoLocal>& physicalResultInfo =
physicalResult->mPhysicalResultInfo;
std::vector<std::string> physicalCameraIds;
std::vector<sp<ACameraMetadata>> physicalMetadataCopy;
for (size_t i = 0; i < physicalResultInfo.size(); i++) {
physicalCameraIds.push_back(physicalResultInfo[i].physicalCameraId);
CameraMetadata clone = physicalResultInfo[i].physicalMetadata;
clone.update(ANDROID_SYNC_FRAME_NUMBER,
&physicalResult->mFrameNumber, /*data_count*/1);
sp<ACameraMetadata> metadata =
new ACameraMetadata(clone.release(), ACameraMetadata::ACM_RESULT);
physicalMetadataCopy.push_back(metadata);
}
std::vector<const char*> physicalCameraIdPtrs;
std::vector<const ACameraMetadata*> physicalMetadataCopyPtrs;
for (size_t i = 0; i < physicalResultInfo.size(); i++) {
physicalCameraIdPtrs.push_back(physicalCameraIds[i].c_str());
physicalMetadataCopyPtrs.push_back(physicalMetadataCopy[i].get());
}
ACaptureRequest* request = allocateACaptureRequest(requestSp, id_cstr);
(*onResult)(context, session.get(), request, result.get(),
physicalResultInfo.size(), physicalCameraIdPtrs.data(),
physicalMetadataCopyPtrs.data());
freeACaptureRequest(request);
break;
}
case kWhatCaptureFail:
{
ACameraCaptureSession_captureCallback_failed onFail;
found = msg->findPointer(kCallbackFpKey, (void**) &onFail);
if (!found) {
ALOGE("%s: Cannot find capture fail callback!", __FUNCTION__);
return;
}
if (onFail == nullptr) {
return;
}
found = msg->findObject(kCaptureFailureKey, &obj);
if (!found) {
ALOGE("%s: Cannot find capture failure!", __FUNCTION__);
return;
}
sp<CameraCaptureFailure> failureSp(
static_cast<CameraCaptureFailure*>(obj.get()));
ACameraCaptureFailure* failure =
static_cast<ACameraCaptureFailure*>(failureSp.get());
ACaptureRequest* request = allocateACaptureRequest(requestSp, id_cstr);
(*onFail)(context, session.get(), request, failure);
freeACaptureRequest(request);
break;
}
case kWhatLogicalCaptureFail:
{
ACameraCaptureSession_logicalCamera_captureCallback_failed onFail;
found = msg->findPointer(kCallbackFpKey, (void**) &onFail);
if (!found) {
ALOGE("%s: Cannot find capture fail callback!", __FUNCTION__);
return;
}
if (onFail == nullptr) {
return;
}
found = msg->findObject(kCaptureFailureKey, &obj);
if (!found) {
ALOGE("%s: Cannot find capture failure!", __FUNCTION__);
return;
}
sp<CameraCaptureFailure> failureSp(
static_cast<CameraCaptureFailure*>(obj.get()));
ALogicalCameraCaptureFailure failure;
AString physicalCameraId;
found = msg->findString(kFailingPhysicalCameraId, &physicalCameraId);
if (found && !physicalCameraId.empty()) {
failure.physicalCameraId = physicalCameraId.c_str();
} else {
failure.physicalCameraId = nullptr;
}
failure.captureFailure = *failureSp;
ACaptureRequest* request = allocateACaptureRequest(requestSp, id_cstr);
(*onFail)(context, session.get(), request, &failure);
freeACaptureRequest(request);
break;
}
case kWhatCaptureSeqEnd:
{
ACameraCaptureSession_captureCallback_sequenceEnd onSeqEnd;
found = msg->findPointer(kCallbackFpKey, (void**) &onSeqEnd);
if (!found) {
ALOGE("%s: Cannot find sequence end callback!", __FUNCTION__);
return;
}
if (onSeqEnd == nullptr) {
return;
}
int seqId;
found = msg->findInt32(kSequenceIdKey, &seqId);
if (!found) {
ALOGE("%s: Cannot find frame number!", __FUNCTION__);
return;
}
int64_t frameNumber;
found = msg->findInt64(kFrameNumberKey, &frameNumber);
if (!found) {
ALOGE("%s: Cannot find frame number!", __FUNCTION__);
return;
}
(*onSeqEnd)(context, session.get(), seqId, frameNumber);
break;
}
case kWhatCaptureSeqAbort:
{
ACameraCaptureSession_captureCallback_sequenceAbort onSeqAbort;
found = msg->findPointer(kCallbackFpKey, (void**) &onSeqAbort);
if (!found) {
ALOGE("%s: Cannot find sequence end callback!", __FUNCTION__);
return;
}
if (onSeqAbort == nullptr) {
return;
}
int seqId;
found = msg->findInt32(kSequenceIdKey, &seqId);
if (!found) {
ALOGE("%s: Cannot find frame number!", __FUNCTION__);
return;
}
(*onSeqAbort)(context, session.get(), seqId);
break;
}
case kWhatCaptureBufferLost:
{
ACameraCaptureSession_captureCallback_bufferLost onBufferLost;
found = msg->findPointer(kCallbackFpKey, (void**) &onBufferLost);
if (!found) {
ALOGE("%s: Cannot find buffer lost callback!", __FUNCTION__);
return;
}
if (onBufferLost == nullptr) {
return;
}
native_handle_t* anw;
found = msg->findPointer(kAnwKey, (void**) &anw);
if (!found) {
ALOGE("%s: Cannot find native_handle_t!", __FUNCTION__);
return;
}
int64_t frameNumber;
found = msg->findInt64(kFrameNumberKey, &frameNumber);
if (!found) {
ALOGE("%s: Cannot find frame number!", __FUNCTION__);
return;
}
ACaptureRequest* request = allocateACaptureRequest(requestSp, id_cstr);
(*onBufferLost)(context, session.get(), request, anw, frameNumber);
freeACaptureRequest(request);
break;
}
}
break;
}
}
}
CameraDevice::CallbackHolder::CallbackHolder(
sp<ACameraCaptureSession> session,
const Vector<sp<CaptureRequest> >& requests,
bool isRepeating,
ACameraCaptureSession_captureCallbacks* cbs) :
mSession(session), mRequests(requests),
mIsRepeating(isRepeating),
mIsLogicalCameraCallback(false) {
initCaptureCallbacks(cbs);
if (cbs != nullptr) {
mOnCaptureCompleted = cbs->onCaptureCompleted;
mOnCaptureFailed = cbs->onCaptureFailed;
}
}
CameraDevice::CallbackHolder::CallbackHolder(
sp<ACameraCaptureSession> session,
const Vector<sp<CaptureRequest> >& requests,
bool isRepeating,
ACameraCaptureSession_logicalCamera_captureCallbacks* lcbs) :
mSession(session), mRequests(requests),
mIsRepeating(isRepeating),
mIsLogicalCameraCallback(true) {
initCaptureCallbacks(lcbs);
if (lcbs != nullptr) {
mOnLogicalCameraCaptureCompleted = lcbs->onLogicalCameraCaptureCompleted;
mOnLogicalCameraCaptureFailed = lcbs->onLogicalCameraCaptureFailed;
}
}
void
CameraDevice::checkRepeatingSequenceCompleteLocked(
const int sequenceId, const int64_t lastFrameNumber) {
ALOGV("Repeating seqId %d lastFrameNumer %" PRId64, sequenceId, lastFrameNumber);
if (lastFrameNumber == NO_FRAMES_CAPTURED) {
if (mSequenceCallbackMap.count(sequenceId) == 0) {
ALOGW("No callback found for sequenceId %d", sequenceId);
return;
}
// remove callback holder from callback map
auto cbIt = mSequenceCallbackMap.find(sequenceId);
CallbackHolder cbh = cbIt->second;
mSequenceCallbackMap.erase(cbIt);
// send seq aborted callback
sp<AMessage> msg = new AMessage(kWhatCaptureSeqAbort, mHandler);
msg->setPointer(kContextKey, cbh.mContext);
msg->setObject(kSessionSpKey, cbh.mSession);
msg->setPointer(kCallbackFpKey, (void*) cbh.mOnCaptureSequenceAborted);
msg->setInt32(kSequenceIdKey, sequenceId);
postSessionMsgAndCleanup(msg);
} else {
// Use mSequenceLastFrameNumberMap to track
mSequenceLastFrameNumberMap.insert(std::make_pair(sequenceId, lastFrameNumber));
// Last frame might have arrived. Check now
checkAndFireSequenceCompleteLocked();
}
}
void
CameraDevice::checkAndFireSequenceCompleteLocked() {
int64_t completedFrameNumber = mFrameNumberTracker.getCompletedFrameNumber();
auto it = mSequenceLastFrameNumberMap.begin();
while (it != mSequenceLastFrameNumberMap.end()) {
int sequenceId = it->first;
int64_t lastFrameNumber = it->second;
bool seqCompleted = false;
bool hasCallback = true;
if (mRemote == nullptr) {
ALOGW("Camera %s closed while checking sequence complete", getId());
return;
}
// Check if there is callback for this sequence
// This should not happen because we always register callback (with nullptr inside)
if (mSequenceCallbackMap.count(sequenceId) == 0) {
ALOGW("No callback found for sequenceId %d", sequenceId);
hasCallback = false;
}
if (lastFrameNumber <= completedFrameNumber) {
ALOGV("seq %d reached last frame %" PRId64 ", completed %" PRId64,
sequenceId, lastFrameNumber, completedFrameNumber);
seqCompleted = true;
}
if (seqCompleted && hasCallback) {
// remove callback holder from callback map
auto cbIt = mSequenceCallbackMap.find(sequenceId);
CallbackHolder cbh = cbIt->second;
mSequenceCallbackMap.erase(cbIt);
// send seq complete callback
sp<AMessage> msg = new AMessage(kWhatCaptureSeqEnd, mHandler);
msg->setPointer(kContextKey, cbh.mContext);
msg->setObject(kSessionSpKey, cbh.mSession);
msg->setPointer(kCallbackFpKey, (void*) cbh.mOnCaptureSequenceCompleted);
msg->setInt32(kSequenceIdKey, sequenceId);
msg->setInt64(kFrameNumberKey, lastFrameNumber);
// Clear the session sp before we send out the message
// This will guarantee the rare case where the message is processed
// before cbh goes out of scope and causing we call the session
// destructor while holding device lock
cbh.mSession.clear();
postSessionMsgAndCleanup(msg);
}
// No need to track sequence complete if there is no callback registered
if (seqCompleted || !hasCallback) {
it = mSequenceLastFrameNumberMap.erase(it);
} else {
++it;
}
}
}
void CameraDevice::stopLooper() {
Mutex::Autolock _l(mDeviceLock);
if (mCbLooper != nullptr) {
mCbLooper->unregisterHandler(mHandler->id());
mCbLooper->stop();
}
mCbLooper.clear();
mHandler.clear();
}
/**
* Camera service callback implementation
*/
android::hardware::Return<void>
CameraDevice::ServiceCallback::onDeviceError(
ErrorCode errorCode,
const CaptureResultExtras& resultExtras) {
ALOGD("Device error received, code %d, frame number %" PRId64 ", request ID %d, subseq ID %d"
" physical camera ID %s", errorCode, resultExtras.frameNumber, resultExtras.requestId,
resultExtras.burstId, resultExtras.errorPhysicalCameraId.c_str());
auto ret = Void();
sp<CameraDevice> dev = mDevice.promote();
if (dev == nullptr) {
return ret; // device has been closed
}
sp<ACameraCaptureSession> session = dev->mCurrentSession.promote();
Mutex::Autolock _l(dev->mDeviceLock);
if (dev->mRemote == nullptr) {
return ret; // device has been closed
}
switch (errorCode) {
case ErrorCode::CAMERA_DISCONNECTED:
{
// Camera is disconnected, close the session and expect no more callbacks
if (session != nullptr) {
session->closeByDevice();
}
dev->mCurrentSession = nullptr;
sp<AMessage> msg = new AMessage(kWhatOnDisconnected, dev->mHandler);
msg->setPointer(kContextKey, dev->mAppCallbacks.context);
msg->setPointer(kDeviceKey, (void*) dev->getWrapper());
msg->setPointer(kCallbackFpKey, (void*) dev->mAppCallbacks.onDisconnected);
msg->post();
break;
}
default:
ALOGE("Unknown error from camera device: %d", errorCode);
[[fallthrough]];
case ErrorCode::CAMERA_DEVICE:
case ErrorCode::CAMERA_SERVICE:
{
int32_t errorVal = ::ERROR_CAMERA_DEVICE;
// We keep this switch since this block might be encountered with
// more than just 2 states. The default fallthrough could have us
// handling more unmatched error cases.
switch (errorCode) {
case ErrorCode::CAMERA_DEVICE:
dev->setCameraDeviceErrorLocked(ACAMERA_ERROR_CAMERA_DEVICE);
break;
case ErrorCode::CAMERA_SERVICE:
dev->setCameraDeviceErrorLocked(ACAMERA_ERROR_CAMERA_SERVICE);
errorVal = ::ERROR_CAMERA_SERVICE;
break;
default:
dev->setCameraDeviceErrorLocked(ACAMERA_ERROR_UNKNOWN);
break;
}
sp<AMessage> msg = new AMessage(kWhatOnError, dev->mHandler);
msg->setPointer(kContextKey, dev->mAppCallbacks.context);
msg->setPointer(kDeviceKey, (void*) dev->getWrapper());
msg->setPointer(kCallbackFpKey, (void*) dev->mAppCallbacks.onError);
msg->setInt32(kErrorCodeKey, errorVal);
msg->post();
break;
}
case ErrorCode::CAMERA_REQUEST:
case ErrorCode::CAMERA_RESULT:
case ErrorCode::CAMERA_BUFFER:
dev->onCaptureErrorLocked(errorCode, resultExtras);
break;
}
return ret;
}
android::hardware::Return<void>
CameraDevice::ServiceCallback::onDeviceIdle() {
ALOGV("Camera is now idle");
auto ret = Void();
sp<CameraDevice> dev = mDevice.promote();
if (dev == nullptr) {
return ret; // device has been closed
}
Mutex::Autolock _l(dev->mDeviceLock);
if (dev->isClosed() || dev->mRemote == nullptr) {
return ret;
}
if (dev->mIdle) {
// Already in idle state. Possibly other thread did waitUntilIdle
return ret;
}
if (dev->mCurrentSession != nullptr) {
ALOGE("onDeviceIdle sending state cb");
if (dev->mBusySession != dev->mCurrentSession) {
ALOGE("Current session != busy session");
dev->setCameraDeviceErrorLocked(ACAMERA_ERROR_CAMERA_DEVICE);
return ret;
}
sp<AMessage> msg = new AMessage(kWhatSessionStateCb, dev->mHandler);
msg->setPointer(kContextKey, dev->mBusySession->mUserSessionCallback.context);
msg->setObject(kSessionSpKey, dev->mBusySession);
msg->setPointer(kCallbackFpKey, (void*) dev->mBusySession->mUserSessionCallback.onReady);
// Make sure we clear the sp first so the session destructor can
// only happen on handler thread (where we don't hold device/session lock)
dev->mBusySession.clear();
dev->postSessionMsgAndCleanup(msg);
}
dev->mIdle = true;
dev->mFlushing = false;
return ret;
}
android::hardware::Return<void>
CameraDevice::ServiceCallback::onCaptureStarted(
const CaptureResultExtras& resultExtras,
uint64_t timestamp) {
auto ret = Void();
sp<CameraDevice> dev = mDevice.promote();
if (dev == nullptr) {
return ret; // device has been closed
}
Mutex::Autolock _l(dev->mDeviceLock);
if (dev->isClosed() || dev->mRemote == nullptr) {
return ret;
}
int32_t sequenceId = resultExtras.requestId;
int32_t burstId = resultExtras.burstId;
auto it = dev->mSequenceCallbackMap.find(sequenceId);
if (it != dev->mSequenceCallbackMap.end()) {
CallbackHolder cbh = (*it).second;
ACameraCaptureSession_captureCallback_start onStart = cbh.mOnCaptureStarted;
sp<ACameraCaptureSession> session = cbh.mSession;
if ((size_t) burstId >= cbh.mRequests.size()) {
ALOGE("%s: Error: request index %d out of bound (size %zu)",
__FUNCTION__, burstId, cbh.mRequests.size());
dev->setCameraDeviceErrorLocked(ACAMERA_ERROR_CAMERA_SERVICE);
}
sp<CaptureRequest> request = cbh.mRequests[burstId];
sp<AMessage> msg = new AMessage(kWhatCaptureStart, dev->mHandler);
msg->setPointer(kContextKey, cbh.mContext);
msg->setObject(kSessionSpKey, session);
msg->setPointer(kCallbackFpKey, (void*) onStart);
msg->setObject(kCaptureRequestKey, request);
msg->setInt64(kTimeStampKey, timestamp);
dev->postSessionMsgAndCleanup(msg);
}
return ret;
}
android::hardware::Return<void>
CameraDevice::ServiceCallback::onResultReceived(
const FmqSizeOrMetadata& resultMetadata,
const CaptureResultExtras& resultExtras,
const hidl_vec<PhysicalCaptureResultInfo>& physicalResultInfos) {
auto ret = Void();
sp<CameraDevice> dev = mDevice.promote();
if (dev == nullptr) {
return ret; // device has been closed
}
int32_t sequenceId = resultExtras.requestId;
int64_t frameNumber = resultExtras.frameNumber;
int32_t burstId = resultExtras.burstId;
bool isPartialResult = (resultExtras.partialResultCount < dev->mPartialResultCount);
if (!isPartialResult) {
ALOGV("SeqId %d frame %" PRId64 " result arrive.", sequenceId, frameNumber);
}
Mutex::Autolock _l(dev->mDeviceLock);
if (dev->mRemote == nullptr) {
return ret; // device has been disconnected
}
if (dev->isClosed()) {
if (!isPartialResult) {
dev->mFrameNumberTracker.updateTracker(frameNumber, /*isError*/false);
}
// early return to avoid callback sent to closed devices
return ret;
}
CameraMetadata metadataCopy;
camera_status_t status = readOneResultMetadata(resultMetadata,
dev->mCaptureResultMetadataQueue.get(), &metadataCopy);
if (status != ACAMERA_OK) {
ALOGE("%s: result metadata couldn't be converted", __FUNCTION__);
return ret;
}
metadataCopy.update(ANDROID_LENS_INFO_SHADING_MAP_SIZE, dev->mShadingMapSize, /*data_count*/2);
metadataCopy.update(ANDROID_SYNC_FRAME_NUMBER, &frameNumber, /*data_count*/1);
auto it = dev->mSequenceCallbackMap.find(sequenceId);
if (it != dev->mSequenceCallbackMap.end()) {
CallbackHolder cbh = (*it).second;
sp<ACameraCaptureSession> session = cbh.mSession;
if ((size_t) burstId >= cbh.mRequests.size()) {
ALOGE("%s: Error: request index %d out of bound (size %zu)",
__FUNCTION__, burstId, cbh.mRequests.size());
dev->setCameraDeviceErrorLocked(ACAMERA_ERROR_CAMERA_SERVICE);
}
sp<CaptureRequest> request = cbh.mRequests[burstId];
sp<ACameraMetadata> result(new ACameraMetadata(
metadataCopy.release(), ACameraMetadata::ACM_RESULT));
std::vector<PhysicalCaptureResultInfoLocal> localPhysicalResult;
localPhysicalResult.resize(physicalResultInfos.size());
for (size_t i = 0; i < physicalResultInfos.size(); i++) {
localPhysicalResult[i].physicalCameraId = physicalResultInfos[i].physicalCameraId;
status = readOneResultMetadata(physicalResultInfos[i].physicalCameraMetadata,
dev->mCaptureResultMetadataQueue.get(),
&localPhysicalResult[i].physicalMetadata);
if (status != ACAMERA_OK) {
ALOGE("%s: physical camera result metadata couldn't be converted", __FUNCTION__);
return ret;
}
}
sp<ACameraPhysicalCaptureResultInfo> physicalResult(
new ACameraPhysicalCaptureResultInfo(localPhysicalResult, frameNumber));
sp<AMessage> msg = new AMessage(
cbh.mIsLogicalCameraCallback ? kWhatLogicalCaptureResult : kWhatCaptureResult,
dev->mHandler);
msg->setPointer(kContextKey, cbh.mContext);
msg->setObject(kSessionSpKey, session);
msg->setObject(kCaptureRequestKey, request);
msg->setObject(kCaptureResultKey, result);
if (isPartialResult) {
msg->setPointer(kCallbackFpKey,
(void *)cbh.mOnCaptureProgressed);
} else if (cbh.mIsLogicalCameraCallback) {
msg->setPointer(kCallbackFpKey,
(void *)cbh.mOnLogicalCameraCaptureCompleted);
msg->setObject(kPhysicalCaptureResultKey, physicalResult);
} else {
msg->setPointer(kCallbackFpKey,
(void *)cbh.mOnCaptureCompleted);
}
dev->postSessionMsgAndCleanup(msg);
}
if (!isPartialResult) {
dev->mFrameNumberTracker.updateTracker(frameNumber, /*isError*/false);
dev->checkAndFireSequenceCompleteLocked();
}
return ret;
}
android::hardware::Return<void>
CameraDevice::ServiceCallback::onRepeatingRequestError(
uint64_t lastFrameNumber, int32_t stoppedSequenceId) {
auto ret = Void();
sp<CameraDevice> dev = mDevice.promote();
if (dev == nullptr) {
return ret; // device has been closed
}
Mutex::Autolock _l(dev->mDeviceLock);
int repeatingSequenceId = dev->mRepeatingSequenceId;
if (stoppedSequenceId == repeatingSequenceId) {
dev->mRepeatingSequenceId = REQUEST_ID_NONE;
}
dev->checkRepeatingSequenceCompleteLocked(repeatingSequenceId, lastFrameNumber);
return ret;
}
camera_status_t CameraDevice::ServiceCallback::readOneResultMetadata(
const FmqSizeOrMetadata& fmqSizeOrMetadata, ResultMetadataQueue* metadataQueue,
CameraMetadata* metadata) {
if (metadataQueue == nullptr || metadata == nullptr) {
return ACAMERA_ERROR_INVALID_PARAMETER;
}
bool converted;
HCameraMetadata hCameraMetadata;
if (fmqSizeOrMetadata.getDiscriminator() ==
FmqSizeOrMetadata::hidl_discriminator::fmqMetadataSize) {
hCameraMetadata.resize(fmqSizeOrMetadata.fmqMetadataSize());
bool read = metadataQueue->read(
hCameraMetadata.data(), fmqSizeOrMetadata.fmqMetadataSize());
if (!read) {
ALOGE("%s capture request settings could't be read from fmq", __FUNCTION__);
return ACAMERA_ERROR_UNKNOWN;
}
// TODO: Do we actually need to clone here ?
converted = utils::convertFromHidlCloned(hCameraMetadata, metadata);
} else {
converted = utils::convertFromHidlCloned(fmqSizeOrMetadata.metadata(), metadata);
}
return converted ? ACAMERA_OK : ACAMERA_ERROR_UNKNOWN;
}
} // namespace acam
} // namespace android