/* * Copyright (C) 2013 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 "Camera2-ZslProcessor3" #define ATRACE_TAG ATRACE_TAG_CAMERA //#define LOG_NDEBUG 0 //#define LOG_NNDEBUG 0 #ifdef LOG_NNDEBUG #define ALOGVV(...) ALOGV(__VA_ARGS__) #else #define ALOGVV(...) ((void)0) #endif #include <inttypes.h> #include <utils/Log.h> #include <utils/Trace.h> #include <gui/Surface.h> #include "common/CameraDeviceBase.h" #include "api1/Camera2Client.h" #include "api1/client2/CaptureSequencer.h" #include "api1/client2/ZslProcessor3.h" #include "device3/Camera3Device.h" namespace android { namespace camera2 { ZslProcessor3::ZslProcessor3( sp<Camera2Client> client, wp<CaptureSequencer> sequencer): Thread(false), mLatestClearedBufferTimestamp(0), mState(RUNNING), mClient(client), mSequencer(sequencer), mId(client->getCameraId()), mZslStreamId(NO_STREAM), mFrameListHead(0), mZslQueueHead(0), mZslQueueTail(0), mHasFocuser(false) { // Initialize buffer queue and frame list based on pipeline max depth. size_t pipelineMaxDepth = kDefaultMaxPipelineDepth; if (client != 0) { sp<Camera3Device> device = static_cast<Camera3Device*>(client->getCameraDevice().get()); if (device != 0) { camera_metadata_ro_entry_t entry = device->info().find(ANDROID_REQUEST_PIPELINE_MAX_DEPTH); if (entry.count == 1) { pipelineMaxDepth = entry.data.u8[0]; } else { ALOGW("%s: Unable to find the android.request.pipelineMaxDepth," " use default pipeline max depth %zu", __FUNCTION__, kDefaultMaxPipelineDepth); } entry = device->info().find(ANDROID_LENS_INFO_MINIMUM_FOCUS_DISTANCE); if (entry.count > 0 && entry.data.f[0] != 0.) { mHasFocuser = true; } } } ALOGV("%s: Initialize buffer queue and frame list depth based on max pipeline depth (%d)", __FUNCTION__, pipelineMaxDepth); // Need to keep buffer queue longer than metadata queue because sometimes buffer arrives // earlier than metadata which causes the buffer corresponding to oldest metadata being // removed. mFrameListDepth = pipelineMaxDepth; mBufferQueueDepth = mFrameListDepth + 1; mZslQueue.insertAt(0, mBufferQueueDepth); mFrameList.insertAt(0, mFrameListDepth); sp<CaptureSequencer> captureSequencer = mSequencer.promote(); if (captureSequencer != 0) captureSequencer->setZslProcessor(this); } ZslProcessor3::~ZslProcessor3() { ALOGV("%s: Exit", __FUNCTION__); deleteStream(); } void ZslProcessor3::onResultAvailable(const CaptureResult &result) { ATRACE_CALL(); ALOGV("%s:", __FUNCTION__); Mutex::Autolock l(mInputMutex); camera_metadata_ro_entry_t entry; entry = result.mMetadata.find(ANDROID_SENSOR_TIMESTAMP); nsecs_t timestamp = entry.data.i64[0]; if (entry.count == 0) { ALOGE("%s: metadata doesn't have timestamp, skip this result", __FUNCTION__); return; } entry = result.mMetadata.find(ANDROID_REQUEST_FRAME_COUNT); if (entry.count == 0) { ALOGE("%s: metadata doesn't have frame number, skip this result", __FUNCTION__); return; } int32_t frameNumber = entry.data.i32[0]; ALOGVV("Got preview metadata for frame %d with timestamp %" PRId64, frameNumber, timestamp); if (mState != RUNNING) return; // Corresponding buffer has been cleared. No need to push into mFrameList if (timestamp <= mLatestClearedBufferTimestamp) return; mFrameList.editItemAt(mFrameListHead) = result.mMetadata; mFrameListHead = (mFrameListHead + 1) % mFrameListDepth; } status_t ZslProcessor3::updateStream(const Parameters ¶ms) { ATRACE_CALL(); ALOGV("%s: Configuring ZSL streams", __FUNCTION__); status_t res; Mutex::Autolock l(mInputMutex); sp<Camera2Client> client = mClient.promote(); if (client == 0) { ALOGE("%s: Camera %d: Client does not exist", __FUNCTION__, mId); return INVALID_OPERATION; } sp<Camera3Device> device = static_cast<Camera3Device*>(client->getCameraDevice().get()); if (device == 0) { ALOGE("%s: Camera %d: Device does not exist", __FUNCTION__, mId); return INVALID_OPERATION; } if (mZslStreamId != NO_STREAM) { // Check if stream parameters have to change uint32_t currentWidth, currentHeight; res = device->getStreamInfo(mZslStreamId, ¤tWidth, ¤tHeight, 0, 0); if (res != OK) { ALOGE("%s: Camera %d: Error querying capture output stream info: " "%s (%d)", __FUNCTION__, client->getCameraId(), strerror(-res), res); return res; } if (currentWidth != (uint32_t)params.fastInfo.arrayWidth || currentHeight != (uint32_t)params.fastInfo.arrayHeight) { ALOGV("%s: Camera %d: Deleting stream %d since the buffer " "dimensions changed", __FUNCTION__, client->getCameraId(), mZslStreamId); res = device->deleteStream(mZslStreamId); if (res == -EBUSY) { ALOGV("%s: Camera %d: Device is busy, call updateStream again " " after it becomes idle", __FUNCTION__, mId); return res; } else if(res != OK) { ALOGE("%s: Camera %d: Unable to delete old output stream " "for ZSL: %s (%d)", __FUNCTION__, client->getCameraId(), strerror(-res), res); return res; } mZslStreamId = NO_STREAM; } } if (mZslStreamId == NO_STREAM) { // Create stream for HAL production // TODO: Sort out better way to select resolution for ZSL // Note that format specified internally in Camera3ZslStream res = device->createZslStream( params.fastInfo.arrayWidth, params.fastInfo.arrayHeight, mBufferQueueDepth, &mZslStreamId, &mZslStream); if (res != OK) { ALOGE("%s: Camera %d: Can't create ZSL stream: " "%s (%d)", __FUNCTION__, client->getCameraId(), strerror(-res), res); return res; } // Only add the camera3 buffer listener when the stream is created. mZslStream->addBufferListener(this); } client->registerFrameListener(Camera2Client::kPreviewRequestIdStart, Camera2Client::kPreviewRequestIdEnd, this, /*sendPartials*/false); return OK; } status_t ZslProcessor3::deleteStream() { ATRACE_CALL(); status_t res; Mutex::Autolock l(mInputMutex); if (mZslStreamId != NO_STREAM) { sp<Camera2Client> client = mClient.promote(); if (client == 0) { ALOGE("%s: Camera %d: Client does not exist", __FUNCTION__, mId); return INVALID_OPERATION; } sp<Camera3Device> device = reinterpret_cast<Camera3Device*>(client->getCameraDevice().get()); if (device == 0) { ALOGE("%s: Camera %d: Device does not exist", __FUNCTION__, mId); return INVALID_OPERATION; } res = device->deleteStream(mZslStreamId); if (res != OK) { ALOGE("%s: Camera %d: Cannot delete ZSL output stream %d: " "%s (%d)", __FUNCTION__, client->getCameraId(), mZslStreamId, strerror(-res), res); return res; } mZslStreamId = NO_STREAM; } return OK; } int ZslProcessor3::getStreamId() const { Mutex::Autolock l(mInputMutex); return mZslStreamId; } status_t ZslProcessor3::updateRequestWithDefaultStillRequest(CameraMetadata &request) const { sp<Camera2Client> client = mClient.promote(); if (client == 0) { ALOGE("%s: Camera %d: Client does not exist", __FUNCTION__, mId); return INVALID_OPERATION; } sp<Camera3Device> device = static_cast<Camera3Device*>(client->getCameraDevice().get()); if (device == 0) { ALOGE("%s: Camera %d: Device does not exist", __FUNCTION__, mId); return INVALID_OPERATION; } CameraMetadata stillTemplate; device->createDefaultRequest(CAMERA3_TEMPLATE_STILL_CAPTURE, &stillTemplate); // Find some of the post-processing tags, and assign the value from template to the request. // Only check the aberration mode and noise reduction mode for now, as they are very important // for image quality. uint32_t postProcessingTags[] = { ANDROID_NOISE_REDUCTION_MODE, ANDROID_COLOR_CORRECTION_ABERRATION_MODE, ANDROID_COLOR_CORRECTION_MODE, ANDROID_TONEMAP_MODE, ANDROID_SHADING_MODE, ANDROID_HOT_PIXEL_MODE, ANDROID_EDGE_MODE }; camera_metadata_entry_t entry; for (size_t i = 0; i < sizeof(postProcessingTags) / sizeof(uint32_t); i++) { entry = stillTemplate.find(postProcessingTags[i]); if (entry.count > 0) { request.update(postProcessingTags[i], entry.data.u8, 1); } } return OK; } status_t ZslProcessor3::pushToReprocess(int32_t requestId) { ALOGV("%s: Send in reprocess request with id %d", __FUNCTION__, requestId); Mutex::Autolock l(mInputMutex); status_t res; sp<Camera2Client> client = mClient.promote(); if (client == 0) { ALOGE("%s: Camera %d: Client does not exist", __FUNCTION__, mId); return INVALID_OPERATION; } IF_ALOGV() { dumpZslQueue(-1); } size_t metadataIdx; nsecs_t candidateTimestamp = getCandidateTimestampLocked(&metadataIdx); if (candidateTimestamp == -1) { ALOGE("%s: Could not find good candidate for ZSL reprocessing", __FUNCTION__); return NOT_ENOUGH_DATA; } res = mZslStream->enqueueInputBufferByTimestamp(candidateTimestamp, /*actualTimestamp*/NULL); if (res == mZslStream->NO_BUFFER_AVAILABLE) { ALOGV("%s: No ZSL buffers yet", __FUNCTION__); return NOT_ENOUGH_DATA; } else if (res != OK) { ALOGE("%s: Unable to push buffer for reprocessing: %s (%d)", __FUNCTION__, strerror(-res), res); return res; } { CameraMetadata request = mFrameList[metadataIdx]; // Verify that the frame is reasonable for reprocessing camera_metadata_entry_t entry; entry = request.find(ANDROID_CONTROL_AE_STATE); if (entry.count == 0) { ALOGE("%s: ZSL queue frame has no AE state field!", __FUNCTION__); return BAD_VALUE; } if (entry.data.u8[0] != ANDROID_CONTROL_AE_STATE_CONVERGED && entry.data.u8[0] != ANDROID_CONTROL_AE_STATE_LOCKED) { ALOGV("%s: ZSL queue frame AE state is %d, need full capture", __FUNCTION__, entry.data.u8[0]); return NOT_ENOUGH_DATA; } uint8_t requestType = ANDROID_REQUEST_TYPE_REPROCESS; res = request.update(ANDROID_REQUEST_TYPE, &requestType, 1); if (res != OK) { ALOGE("%s: Unable to update request type", __FUNCTION__); return INVALID_OPERATION; } int32_t inputStreams[1] = { mZslStreamId }; res = request.update(ANDROID_REQUEST_INPUT_STREAMS, inputStreams, 1); if (res != OK) { ALOGE("%s: Unable to update request input streams", __FUNCTION__); return INVALID_OPERATION; } uint8_t captureIntent = static_cast<uint8_t>(ANDROID_CONTROL_CAPTURE_INTENT_STILL_CAPTURE); res = request.update(ANDROID_CONTROL_CAPTURE_INTENT, &captureIntent, 1); if (res != OK ) { ALOGE("%s: Unable to update request capture intent", __FUNCTION__); return INVALID_OPERATION; } // TODO: Shouldn't we also update the latest preview frame? int32_t outputStreams[1] = { client->getCaptureStreamId() }; res = request.update(ANDROID_REQUEST_OUTPUT_STREAMS, outputStreams, 1); if (res != OK) { ALOGE("%s: Unable to update request output streams", __FUNCTION__); return INVALID_OPERATION; } res = request.update(ANDROID_REQUEST_ID, &requestId, 1); if (res != OK ) { ALOGE("%s: Unable to update frame to a reprocess request", __FUNCTION__); return INVALID_OPERATION; } res = client->stopStream(); if (res != OK) { ALOGE("%s: Camera %d: Unable to stop preview for ZSL capture: " "%s (%d)", __FUNCTION__, client->getCameraId(), strerror(-res), res); return INVALID_OPERATION; } // Update JPEG settings { SharedParameters::Lock l(client->getParameters()); res = l.mParameters.updateRequestJpeg(&request); if (res != OK) { ALOGE("%s: Camera %d: Unable to update JPEG entries of ZSL " "capture request: %s (%d)", __FUNCTION__, client->getCameraId(), strerror(-res), res); return res; } } // Update post-processing settings res = updateRequestWithDefaultStillRequest(request); if (res != OK) { ALOGW("%s: Unable to update post-processing tags, the reprocessed image quality " "may be compromised", __FUNCTION__); } mLatestCapturedRequest = request; res = client->getCameraDevice()->capture(request); if (res != OK ) { ALOGE("%s: Unable to send ZSL reprocess request to capture: %s" " (%d)", __FUNCTION__, strerror(-res), res); return res; } mState = LOCKED; } return OK; } status_t ZslProcessor3::clearZslQueue() { Mutex::Autolock l(mInputMutex); // If in middle of capture, can't clear out queue if (mState == LOCKED) return OK; return clearZslQueueLocked(); } status_t ZslProcessor3::clearZslQueueLocked() { if (mZslStream != 0) { // clear result metadata list first. clearZslResultQueueLocked(); return mZslStream->clearInputRingBuffer(&mLatestClearedBufferTimestamp); } return OK; } void ZslProcessor3::clearZslResultQueueLocked() { mFrameList.clear(); mFrameListHead = 0; mFrameList.insertAt(0, mFrameListDepth); } void ZslProcessor3::dump(int fd, const Vector<String16>& /*args*/) const { Mutex::Autolock l(mInputMutex); if (!mLatestCapturedRequest.isEmpty()) { String8 result(" Latest ZSL capture request:\n"); write(fd, result.string(), result.size()); mLatestCapturedRequest.dump(fd, 2, 6); } else { String8 result(" Latest ZSL capture request: none yet\n"); write(fd, result.string(), result.size()); } dumpZslQueue(fd); } bool ZslProcessor3::threadLoop() { // TODO: remove dependency on thread. For now, shut thread down right // away. return false; } void ZslProcessor3::dumpZslQueue(int fd) const { String8 header("ZSL queue contents:"); String8 indent(" "); ALOGV("%s", header.string()); if (fd != -1) { header = indent + header + "\n"; write(fd, header.string(), header.size()); } for (size_t i = 0; i < mZslQueue.size(); i++) { const ZslPair &queueEntry = mZslQueue[i]; nsecs_t bufferTimestamp = queueEntry.buffer.mTimestamp; camera_metadata_ro_entry_t entry; nsecs_t frameTimestamp = 0; int frameAeState = -1; if (!queueEntry.frame.isEmpty()) { entry = queueEntry.frame.find(ANDROID_SENSOR_TIMESTAMP); if (entry.count > 0) frameTimestamp = entry.data.i64[0]; entry = queueEntry.frame.find(ANDROID_CONTROL_AE_STATE); if (entry.count > 0) frameAeState = entry.data.u8[0]; } String8 result = String8::format(" %zu: b: %" PRId64 "\tf: %" PRId64 ", AE state: %d", i, bufferTimestamp, frameTimestamp, frameAeState); ALOGV("%s", result.string()); if (fd != -1) { result = indent + result + "\n"; write(fd, result.string(), result.size()); } } } bool ZslProcessor3::isFixedFocusMode(uint8_t afMode) const { switch (afMode) { case ANDROID_CONTROL_AF_MODE_AUTO: case ANDROID_CONTROL_AF_MODE_CONTINUOUS_VIDEO: case ANDROID_CONTROL_AF_MODE_CONTINUOUS_PICTURE: case ANDROID_CONTROL_AF_MODE_MACRO: return false; break; case ANDROID_CONTROL_AF_MODE_OFF: case ANDROID_CONTROL_AF_MODE_EDOF: return true; default: ALOGE("%s: unknown focus mode %d", __FUNCTION__, afMode); return false; } } nsecs_t ZslProcessor3::getCandidateTimestampLocked(size_t* metadataIdx) const { /** * Find the smallest timestamp we know about so far * - ensure that aeState is either converged or locked */ size_t idx = 0; nsecs_t minTimestamp = -1; size_t emptyCount = mFrameList.size(); for (size_t j = 0; j < mFrameList.size(); j++) { const CameraMetadata &frame = mFrameList[j]; if (!frame.isEmpty()) { emptyCount--; camera_metadata_ro_entry_t entry; entry = frame.find(ANDROID_SENSOR_TIMESTAMP); if (entry.count == 0) { ALOGE("%s: Can't find timestamp in frame!", __FUNCTION__); continue; } nsecs_t frameTimestamp = entry.data.i64[0]; if (minTimestamp > frameTimestamp || minTimestamp == -1) { entry = frame.find(ANDROID_CONTROL_AE_STATE); if (entry.count == 0) { /** * This is most likely a HAL bug. The aeState field is * mandatory, so it should always be in a metadata packet. */ ALOGW("%s: ZSL queue frame has no AE state field!", __FUNCTION__); continue; } if (entry.data.u8[0] != ANDROID_CONTROL_AE_STATE_CONVERGED && entry.data.u8[0] != ANDROID_CONTROL_AE_STATE_LOCKED) { ALOGVV("%s: ZSL queue frame AE state is %d, need " "full capture", __FUNCTION__, entry.data.u8[0]); continue; } entry = frame.find(ANDROID_CONTROL_AF_MODE); if (entry.count == 0) { ALOGW("%s: ZSL queue frame has no AF mode field!", __FUNCTION__); continue; } uint8_t afMode = entry.data.u8[0]; if (afMode == ANDROID_CONTROL_AF_MODE_OFF) { // Skip all the ZSL buffer for manual AF mode, as we don't really // know the af state. continue; } // Check AF state if device has focuser and focus mode isn't fixed if (mHasFocuser && !isFixedFocusMode(afMode)) { // Make sure the candidate frame has good focus. entry = frame.find(ANDROID_CONTROL_AF_STATE); if (entry.count == 0) { ALOGW("%s: ZSL queue frame has no AF state field!", __FUNCTION__); continue; } uint8_t afState = entry.data.u8[0]; if (afState != ANDROID_CONTROL_AF_STATE_PASSIVE_FOCUSED && afState != ANDROID_CONTROL_AF_STATE_FOCUSED_LOCKED && afState != ANDROID_CONTROL_AF_STATE_NOT_FOCUSED_LOCKED) { ALOGVV("%s: ZSL queue frame AF state is %d is not good for capture, skip it", __FUNCTION__, afState); continue; } } minTimestamp = frameTimestamp; idx = j; } ALOGVV("%s: Saw timestamp %" PRId64, __FUNCTION__, frameTimestamp); } } if (emptyCount == mFrameList.size()) { /** * This could be mildly bad and means our ZSL was triggered before * there were any frames yet received by the camera framework. * * This is a fairly corner case which can happen under: * + a user presses the shutter button real fast when the camera starts * (startPreview followed immediately by takePicture). * + burst capture case (hitting shutter button as fast possible) * * If this happens in steady case (preview running for a while, call * a single takePicture) then this might be a fwk bug. */ ALOGW("%s: ZSL queue has no metadata frames", __FUNCTION__); } ALOGV("%s: Candidate timestamp %" PRId64 " (idx %zu), empty frames: %zu", __FUNCTION__, minTimestamp, idx, emptyCount); if (metadataIdx) { *metadataIdx = idx; } return minTimestamp; } void ZslProcessor3::onBufferAcquired(const BufferInfo& /*bufferInfo*/) { // Intentionally left empty // Although theoretically we could use this to get better dump info } void ZslProcessor3::onBufferReleased(const BufferInfo& bufferInfo) { // ignore output buffers if (bufferInfo.mOutput) { return; } // Lock mutex only once we know this is an input buffer returned to avoid // potential deadlock Mutex::Autolock l(mInputMutex); // TODO: Verify that the buffer is in our queue by looking at timestamp // theoretically unnecessary unless we change the following assumptions: // -- only 1 buffer reprocessed at a time (which is the case now) // Erase entire ZSL queue since we've now completed the capture and preview // is stopped. // // We need to guarantee that if we do two back-to-back captures, // the second won't use a buffer that's older/the same as the first, which // is theoretically possible if we don't clear out the queue and the // selection criteria is something like 'newest'. Clearing out the result // metadata queue on a completed capture ensures we'll only use new timestamp. // Calling clearZslQueueLocked is a guaranteed deadlock because this callback // holds the Camera3Stream internal lock (mLock), and clearZslQueueLocked requires // to hold the same lock. // TODO: need figure out a way to clear the Zsl buffer queue properly. Right now // it is safe not to do so, as back to back ZSL capture requires stop and start // preview, which will flush ZSL queue automatically. ALOGV("%s: Memory optimization, clearing ZSL queue", __FUNCTION__); clearZslResultQueueLocked(); // Required so we accept more ZSL requests mState = RUNNING; } }; // namespace camera2 }; // namespace android