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fuchsia / third_party / android / platform / frameworks / av / refs/heads/upstream/android10-qpr2-s1-release / . / services / camera / libcameraservice / api1 / CameraClient.cpp
blob: d65ac7b339d59ce2e6a8d15f50b5c69c1c7b3283 [file] [log] [blame]
/*
* Copyright (C) 2012 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 "CameraClient"
//#define LOG_NDEBUG 0
#include <cutils/atomic.h>
#include <cutils/properties.h>
#include <gui/Surface.h>
#include <media/hardware/HardwareAPI.h>
#include "api1/CameraClient.h"
#include "device1/CameraHardwareInterface.h"
#include "CameraService.h"
#include "utils/CameraThreadState.h"
namespace android {
#define LOG1(...) ALOGD_IF(gLogLevel >= 1, __VA_ARGS__);
#define LOG2(...) ALOGD_IF(gLogLevel >= 2, __VA_ARGS__);
CameraClient::CameraClient(const sp<CameraService>& cameraService,
const sp<hardware::ICameraClient>& cameraClient,
const String16& clientPackageName,
int cameraId, int cameraFacing,
int clientPid, int clientUid,
int servicePid):
Client(cameraService, cameraClient, clientPackageName,
String8::format("%d", cameraId), cameraId, cameraFacing, clientPid,
clientUid, servicePid)
{
int callingPid = CameraThreadState::getCallingPid();
LOG1("CameraClient::CameraClient E (pid %d, id %d)", callingPid, cameraId);
mHardware = NULL;
mMsgEnabled = 0;
mSurface = 0;
mPreviewWindow = 0;
mDestructionStarted = false;
// Callback is disabled by default
mPreviewCallbackFlag = CAMERA_FRAME_CALLBACK_FLAG_NOOP;
mOrientation = getOrientation(0, mCameraFacing == CAMERA_FACING_FRONT);
mPlayShutterSound = true;
LOG1("CameraClient::CameraClient X (pid %d, id %d)", callingPid, cameraId);
}
status_t CameraClient::initialize(sp<CameraProviderManager> manager,
const String8& /*monitorTags*/) {
int callingPid = CameraThreadState::getCallingPid();
status_t res;
LOG1("CameraClient::initialize E (pid %d, id %d)", callingPid, mCameraId);
// Verify ops permissions
res = startCameraOps();
if (res != OK) {
return res;
}
char camera_device_name[10];
snprintf(camera_device_name, sizeof(camera_device_name), "%d", mCameraId);
mHardware = new CameraHardwareInterface(camera_device_name);
res = mHardware->initialize(manager);
if (res != OK) {
ALOGE("%s: Camera %d: unable to initialize device: %s (%d)",
__FUNCTION__, mCameraId, strerror(-res), res);
mHardware.clear();
return res;
}
mHardware->setCallbacks(notifyCallback,
dataCallback,
dataCallbackTimestamp,
handleCallbackTimestampBatch,
(void *)(uintptr_t)mCameraId);
// Enable zoom, error, focus, and metadata messages by default
enableMsgType(CAMERA_MSG_ERROR | CAMERA_MSG_ZOOM | CAMERA_MSG_FOCUS |
CAMERA_MSG_PREVIEW_METADATA | CAMERA_MSG_FOCUS_MOVE);
LOG1("CameraClient::initialize X (pid %d, id %d)", callingPid, mCameraId);
return OK;
}
// tear down the client
CameraClient::~CameraClient() {
mDestructionStarted = true;
int callingPid = CameraThreadState::getCallingPid();
LOG1("CameraClient::~CameraClient E (pid %d, this %p)", callingPid, this);
disconnect();
LOG1("CameraClient::~CameraClient X (pid %d, this %p)", callingPid, this);
}
status_t CameraClient::dump(int fd, const Vector<String16>& args) {
return BasicClient::dump(fd, args);
}
status_t CameraClient::dumpClient(int fd, const Vector<String16>& args) {
const size_t SIZE = 256;
char buffer[SIZE];
size_t len = snprintf(buffer, SIZE, "Client[%d] (%p) with UID %d\n",
mCameraId,
(getRemoteCallback() != NULL ?
IInterface::asBinder(getRemoteCallback()).get() : NULL),
mClientUid);
len = (len > SIZE - 1) ? SIZE - 1 : len;
write(fd, buffer, len);
len = snprintf(buffer, SIZE, "Latest set parameters:\n");
len = (len > SIZE - 1) ? SIZE - 1 : len;
write(fd, buffer, len);
mLatestSetParameters.dump(fd, args);
const char *enddump = "\n\n";
write(fd, enddump, strlen(enddump));
sp<CameraHardwareInterface> hardware = mHardware;
if (hardware != nullptr) {
return hardware->dump(fd, args);
}
ALOGI("%s: camera device closed already, skip dumping", __FUNCTION__);
return OK;
}
// ----------------------------------------------------------------------------
status_t CameraClient::checkPid() const {
int callingPid = CameraThreadState::getCallingPid();
if (callingPid == mClientPid) return NO_ERROR;
ALOGW("attempt to use a locked camera from a different process"
" (old pid %d, new pid %d)", mClientPid, callingPid);
return EBUSY;
}
status_t CameraClient::checkPidAndHardware() const {
if (mHardware == 0) {
ALOGE("attempt to use a camera after disconnect() (pid %d)",
CameraThreadState::getCallingPid());
return INVALID_OPERATION;
}
status_t result = checkPid();
if (result != NO_ERROR) return result;
return NO_ERROR;
}
status_t CameraClient::lock() {
int callingPid = CameraThreadState::getCallingPid();
LOG1("lock (pid %d)", callingPid);
Mutex::Autolock lock(mLock);
// lock camera to this client if the the camera is unlocked
if (mClientPid == 0) {
mClientPid = callingPid;
return NO_ERROR;
}
// returns NO_ERROR if the client already owns the camera, EBUSY otherwise
return checkPid();
}
status_t CameraClient::unlock() {
int callingPid = CameraThreadState::getCallingPid();
LOG1("unlock (pid %d)", callingPid);
Mutex::Autolock lock(mLock);
// allow anyone to use camera (after they lock the camera)
status_t result = checkPid();
if (result == NO_ERROR) {
if (mHardware->recordingEnabled()) {
ALOGE("Not allowed to unlock camera during recording.");
return INVALID_OPERATION;
}
mClientPid = 0;
LOG1("clear mRemoteCallback (pid %d)", callingPid);
// we need to remove the reference to ICameraClient so that when the app
// goes away, the reference count goes to 0.
mRemoteCallback.clear();
}
return result;
}
// connect a new client to the camera
status_t CameraClient::connect(const sp<hardware::ICameraClient>& client) {
int callingPid = CameraThreadState::getCallingPid();
LOG1("connect E (pid %d)", callingPid);
Mutex::Autolock lock(mLock);
if (mClientPid != 0 && checkPid() != NO_ERROR) {
ALOGW("Tried to connect to a locked camera (old pid %d, new pid %d)",
mClientPid, callingPid);
return EBUSY;
}
if (mRemoteCallback != 0 &&
(IInterface::asBinder(client) == IInterface::asBinder(mRemoteCallback))) {
LOG1("Connect to the same client");
return NO_ERROR;
}
mPreviewCallbackFlag = CAMERA_FRAME_CALLBACK_FLAG_NOOP;
mClientPid = callingPid;
mRemoteCallback = client;
LOG1("connect X (pid %d)", callingPid);
return NO_ERROR;
}
static void disconnectWindow(const sp<ANativeWindow>& window) {
if (window != 0) {
status_t result = native_window_api_disconnect(window.get(),
NATIVE_WINDOW_API_CAMERA);
if (result != NO_ERROR) {
ALOGW("native_window_api_disconnect failed: %s (%d)", strerror(-result),
result);
}
}
}
binder::Status CameraClient::disconnect() {
int callingPid = CameraThreadState::getCallingPid();
LOG1("disconnect E (pid %d)", callingPid);
Mutex::Autolock lock(mLock);
binder::Status res = binder::Status::ok();
// Allow both client and the cameraserver to disconnect at all times
if (callingPid != mClientPid && callingPid != mServicePid) {
ALOGW("different client - don't disconnect");
return res;
}
// Make sure disconnect() is done once and once only, whether it is called
// from the user directly, or called by the destructor.
if (mHardware == 0) return res;
LOG1("hardware teardown");
// Before destroying mHardware, we must make sure it's in the
// idle state.
// Turn off all messages.
disableMsgType(CAMERA_MSG_ALL_MSGS);
mHardware->stopPreview();
sCameraService->updateProxyDeviceState(
hardware::ICameraServiceProxy::CAMERA_STATE_IDLE,
mCameraIdStr, mCameraFacing, mClientPackageName,
hardware::ICameraServiceProxy::CAMERA_API_LEVEL_1);
mHardware->cancelPicture();
// Release the hardware resources.
mHardware->release();
// Release the held ANativeWindow resources.
if (mPreviewWindow != 0) {
disconnectWindow(mPreviewWindow);
mPreviewWindow = 0;
mHardware->setPreviewWindow(mPreviewWindow);
}
mHardware.clear();
CameraService::Client::disconnect();
LOG1("disconnect X (pid %d)", callingPid);
return res;
}
// ----------------------------------------------------------------------------
status_t CameraClient::setPreviewWindow(const sp<IBinder>& binder,
const sp<ANativeWindow>& window) {
Mutex::Autolock lock(mLock);
status_t result = checkPidAndHardware();
if (result != NO_ERROR) return result;
// return if no change in surface.
if (binder == mSurface) {
return NO_ERROR;
}
if (window != 0) {
result = native_window_api_connect(window.get(), NATIVE_WINDOW_API_CAMERA);
if (result != NO_ERROR) {
ALOGE("native_window_api_connect failed: %s (%d)", strerror(-result),
result);
return result;
}
}
// If preview has been already started, register preview buffers now.
if (mHardware->previewEnabled()) {
if (window != 0) {
mHardware->setPreviewScalingMode(NATIVE_WINDOW_SCALING_MODE_SCALE_TO_WINDOW);
mHardware->setPreviewTransform(mOrientation);
result = mHardware->setPreviewWindow(window);
}
}
if (result == NO_ERROR) {
// Everything has succeeded. Disconnect the old window and remember the
// new window.
disconnectWindow(mPreviewWindow);
mSurface = binder;
mPreviewWindow = window;
} else {
// Something went wrong after we connected to the new window, so
// disconnect here.
disconnectWindow(window);
}
return result;
}
// set the buffer consumer that the preview will use
status_t CameraClient::setPreviewTarget(
const sp<IGraphicBufferProducer>& bufferProducer) {
LOG1("setPreviewTarget(%p) (pid %d)", bufferProducer.get(),
CameraThreadState::getCallingPid());
sp<IBinder> binder;
sp<ANativeWindow> window;
if (bufferProducer != 0) {
binder = IInterface::asBinder(bufferProducer);
// Using controlledByApp flag to ensure that the buffer queue remains in
// async mode for the old camera API, where many applications depend
// on that behavior.
window = new Surface(bufferProducer, /*controlledByApp*/ true);
}
return setPreviewWindow(binder, window);
}
// set the preview callback flag to affect how the received frames from
// preview are handled.
void CameraClient::setPreviewCallbackFlag(int callback_flag) {
LOG1("setPreviewCallbackFlag(%d) (pid %d)", callback_flag, CameraThreadState::getCallingPid());
Mutex::Autolock lock(mLock);
if (checkPidAndHardware() != NO_ERROR) return;
mPreviewCallbackFlag = callback_flag;
if (mPreviewCallbackFlag & CAMERA_FRAME_CALLBACK_FLAG_ENABLE_MASK) {
enableMsgType(CAMERA_MSG_PREVIEW_FRAME);
} else {
disableMsgType(CAMERA_MSG_PREVIEW_FRAME);
}
}
status_t CameraClient::setPreviewCallbackTarget(
const sp<IGraphicBufferProducer>& callbackProducer) {
(void)callbackProducer;
ALOGE("%s: Unimplemented!", __FUNCTION__);
return INVALID_OPERATION;
}
// start preview mode
status_t CameraClient::startPreview() {
LOG1("startPreview (pid %d)", CameraThreadState::getCallingPid());
return startCameraMode(CAMERA_PREVIEW_MODE);
}
// start recording mode
status_t CameraClient::startRecording() {
LOG1("startRecording (pid %d)", CameraThreadState::getCallingPid());
return startCameraMode(CAMERA_RECORDING_MODE);
}
// start preview or recording
status_t CameraClient::startCameraMode(camera_mode mode) {
LOG1("startCameraMode(%d)", mode);
Mutex::Autolock lock(mLock);
status_t result = checkPidAndHardware();
if (result != NO_ERROR) return result;
switch(mode) {
case CAMERA_PREVIEW_MODE:
if (mSurface == 0 && mPreviewWindow == 0) {
LOG1("mSurface is not set yet.");
// still able to start preview in this case.
}
return startPreviewMode();
case CAMERA_RECORDING_MODE:
if (mSurface == 0 && mPreviewWindow == 0) {
ALOGE("mSurface or mPreviewWindow must be set before startRecordingMode.");
return INVALID_OPERATION;
}
return startRecordingMode();
default:
return UNKNOWN_ERROR;
}
}
status_t CameraClient::startPreviewMode() {
LOG1("startPreviewMode");
status_t result = NO_ERROR;
// if preview has been enabled, nothing needs to be done
if (mHardware->previewEnabled()) {
return NO_ERROR;
}
if (mPreviewWindow != 0) {
mHardware->setPreviewScalingMode(
NATIVE_WINDOW_SCALING_MODE_SCALE_TO_WINDOW);
mHardware->setPreviewTransform(mOrientation);
}
mHardware->setPreviewWindow(mPreviewWindow);
result = mHardware->startPreview();
if (result == NO_ERROR) {
sCameraService->updateProxyDeviceState(
hardware::ICameraServiceProxy::CAMERA_STATE_ACTIVE,
mCameraIdStr, mCameraFacing, mClientPackageName,
hardware::ICameraServiceProxy::CAMERA_API_LEVEL_1);
}
return result;
}
status_t CameraClient::startRecordingMode() {
LOG1("startRecordingMode");
status_t result = NO_ERROR;
// if recording has been enabled, nothing needs to be done
if (mHardware->recordingEnabled()) {
return NO_ERROR;
}
// if preview has not been started, start preview first
if (!mHardware->previewEnabled()) {
result = startPreviewMode();
if (result != NO_ERROR) {
return result;
}
}
// start recording mode
enableMsgType(CAMERA_MSG_VIDEO_FRAME);
sCameraService->playSound(CameraService::SOUND_RECORDING_START);
result = mHardware->startRecording();
if (result != NO_ERROR) {
ALOGE("mHardware->startRecording() failed with status %d", result);
}
return result;
}
// stop preview mode
void CameraClient::stopPreview() {
LOG1("stopPreview (pid %d)", CameraThreadState::getCallingPid());
Mutex::Autolock lock(mLock);
if (checkPidAndHardware() != NO_ERROR) return;
disableMsgType(CAMERA_MSG_PREVIEW_FRAME);
mHardware->stopPreview();
sCameraService->updateProxyDeviceState(
hardware::ICameraServiceProxy::CAMERA_STATE_IDLE,
mCameraIdStr, mCameraFacing, mClientPackageName,
hardware::ICameraServiceProxy::CAMERA_API_LEVEL_1);
mPreviewBuffer.clear();
}
// stop recording mode
void CameraClient::stopRecording() {
LOG1("stopRecording (pid %d)", CameraThreadState::getCallingPid());
{
Mutex::Autolock lock(mLock);
if (checkPidAndHardware() != NO_ERROR) return;
disableMsgType(CAMERA_MSG_VIDEO_FRAME);
mHardware->stopRecording();
sCameraService->playSound(CameraService::SOUND_RECORDING_STOP);
mPreviewBuffer.clear();
}
{
Mutex::Autolock l(mAvailableCallbackBuffersLock);
if (!mAvailableCallbackBuffers.empty()) {
mAvailableCallbackBuffers.clear();
}
}
}
// release a recording frame
void CameraClient::releaseRecordingFrame(const sp<IMemory>& mem) {
Mutex::Autolock lock(mLock);
if (checkPidAndHardware() != NO_ERROR) return;
if (mem == nullptr) {
android_errorWriteWithInfoLog(CameraService::SN_EVENT_LOG_ID, "26164272",
CameraThreadState::getCallingUid(), nullptr, 0);
return;
}
mHardware->releaseRecordingFrame(mem);
}
void CameraClient::releaseRecordingFrameHandle(native_handle_t *handle) {
if (handle == nullptr) return;
Mutex::Autolock lock(mLock);
sp<IMemory> dataPtr;
{
Mutex::Autolock l(mAvailableCallbackBuffersLock);
if (!mAvailableCallbackBuffers.empty()) {
dataPtr = mAvailableCallbackBuffers.back();
mAvailableCallbackBuffers.pop_back();
}
}
if (dataPtr == nullptr) {
ALOGE("%s: %d: No callback buffer available. Dropping a native handle.", __FUNCTION__,
__LINE__);
native_handle_close(handle);
native_handle_delete(handle);
return;
} else if (dataPtr->size() != sizeof(VideoNativeHandleMetadata)) {
ALOGE("%s: %d: Callback buffer size doesn't match VideoNativeHandleMetadata", __FUNCTION__,
__LINE__);
native_handle_close(handle);
native_handle_delete(handle);
return;
}
if (mHardware != nullptr) {
VideoNativeHandleMetadata *metadata = (VideoNativeHandleMetadata*)(dataPtr->pointer());
metadata->eType = kMetadataBufferTypeNativeHandleSource;
metadata->pHandle = handle;
mHardware->releaseRecordingFrame(dataPtr);
}
}
void CameraClient::releaseRecordingFrameHandleBatch(const std::vector<native_handle_t*>& handles) {
Mutex::Autolock lock(mLock);
bool disconnected = (mHardware == nullptr);
size_t n = handles.size();
std::vector<sp<IMemory>> frames;
if (!disconnected) {
frames.reserve(n);
}
bool error = false;
for (auto& handle : handles) {
sp<IMemory> dataPtr;
{
Mutex::Autolock l(mAvailableCallbackBuffersLock);
if (!mAvailableCallbackBuffers.empty()) {
dataPtr = mAvailableCallbackBuffers.back();
mAvailableCallbackBuffers.pop_back();
}
}
if (dataPtr == nullptr) {
ALOGE("%s: %d: No callback buffer available. Dropping frames.", __FUNCTION__,
__LINE__);
error = true;
break;
} else if (dataPtr->size() != sizeof(VideoNativeHandleMetadata)) {
ALOGE("%s: %d: Callback buffer must be VideoNativeHandleMetadata", __FUNCTION__,
__LINE__);
error = true;
break;
}
if (!disconnected) {
VideoNativeHandleMetadata *metadata = (VideoNativeHandleMetadata*)(dataPtr->pointer());
metadata->eType = kMetadataBufferTypeNativeHandleSource;
metadata->pHandle = handle;
frames.push_back(dataPtr);
}
}
if (error) {
for (auto& handle : handles) {
native_handle_close(handle);
native_handle_delete(handle);
}
} else if (!disconnected) {
mHardware->releaseRecordingFrameBatch(frames);
}
return;
}
status_t CameraClient::setVideoBufferMode(int32_t videoBufferMode) {
LOG1("setVideoBufferMode: %d", videoBufferMode);
bool enableMetadataInBuffers = false;
if (videoBufferMode == VIDEO_BUFFER_MODE_DATA_CALLBACK_METADATA) {
enableMetadataInBuffers = true;
} else if (videoBufferMode != VIDEO_BUFFER_MODE_DATA_CALLBACK_YUV) {
ALOGE("%s: %d: videoBufferMode %d is not supported.", __FUNCTION__, __LINE__,
videoBufferMode);
return BAD_VALUE;
}
Mutex::Autolock lock(mLock);
if (checkPidAndHardware() != NO_ERROR) {
return UNKNOWN_ERROR;
}
return mHardware->storeMetaDataInBuffers(enableMetadataInBuffers);
}
bool CameraClient::previewEnabled() {
LOG1("previewEnabled (pid %d)", CameraThreadState::getCallingPid());
Mutex::Autolock lock(mLock);
if (checkPidAndHardware() != NO_ERROR) return false;
return mHardware->previewEnabled();
}
bool CameraClient::recordingEnabled() {
LOG1("recordingEnabled (pid %d)", CameraThreadState::getCallingPid());
Mutex::Autolock lock(mLock);
if (checkPidAndHardware() != NO_ERROR) return false;
return mHardware->recordingEnabled();
}
status_t CameraClient::autoFocus() {
LOG1("autoFocus (pid %d)", CameraThreadState::getCallingPid());
Mutex::Autolock lock(mLock);
status_t result = checkPidAndHardware();
if (result != NO_ERROR) return result;
return mHardware->autoFocus();
}
status_t CameraClient::cancelAutoFocus() {
LOG1("cancelAutoFocus (pid %d)", CameraThreadState::getCallingPid());
Mutex::Autolock lock(mLock);
status_t result = checkPidAndHardware();
if (result != NO_ERROR) return result;
return mHardware->cancelAutoFocus();
}
// take a picture - image is returned in callback
status_t CameraClient::takePicture(int msgType) {
LOG1("takePicture (pid %d): 0x%x", CameraThreadState::getCallingPid(), msgType);
Mutex::Autolock lock(mLock);
status_t result = checkPidAndHardware();
if (result != NO_ERROR) return result;
if ((msgType & CAMERA_MSG_RAW_IMAGE) &&
(msgType & CAMERA_MSG_RAW_IMAGE_NOTIFY)) {
ALOGE("CAMERA_MSG_RAW_IMAGE and CAMERA_MSG_RAW_IMAGE_NOTIFY"
" cannot be both enabled");
return BAD_VALUE;
}
// We only accept picture related message types
// and ignore other types of messages for takePicture().
int picMsgType = msgType
& (CAMERA_MSG_SHUTTER |
CAMERA_MSG_POSTVIEW_FRAME |
CAMERA_MSG_RAW_IMAGE |
CAMERA_MSG_RAW_IMAGE_NOTIFY |
CAMERA_MSG_COMPRESSED_IMAGE);
enableMsgType(picMsgType);
return mHardware->takePicture();
}
// set preview/capture parameters - key/value pairs
status_t CameraClient::setParameters(const String8& params) {
LOG1("setParameters (pid %d) (%s)", CameraThreadState::getCallingPid(), params.string());
Mutex::Autolock lock(mLock);
status_t result = checkPidAndHardware();
if (result != NO_ERROR) return result;
mLatestSetParameters = CameraParameters(params);
CameraParameters p(params);
return mHardware->setParameters(p);
}
// get preview/capture parameters - key/value pairs
String8 CameraClient::getParameters() const {
Mutex::Autolock lock(mLock);
// The camera service can unconditionally get the parameters at all times
if (CameraThreadState::getCallingPid() != mServicePid && checkPidAndHardware() != NO_ERROR) {
return String8();
}
String8 params(mHardware->getParameters().flatten());
LOG1("getParameters (pid %d) (%s)", CameraThreadState::getCallingPid(), params.string());
return params;
}
// enable shutter sound
status_t CameraClient::enableShutterSound(bool enable) {
LOG1("enableShutterSound (pid %d)", CameraThreadState::getCallingPid());
status_t result = checkPidAndHardware();
if (result != NO_ERROR) return result;
if (enable) {
mPlayShutterSound = true;
return OK;
}
mPlayShutterSound = false;
return OK;
}
status_t CameraClient::sendCommand(int32_t cmd, int32_t arg1, int32_t arg2) {
LOG1("sendCommand (pid %d)", CameraThreadState::getCallingPid());
int orientation;
Mutex::Autolock lock(mLock);
status_t result = checkPidAndHardware();
if (result != NO_ERROR) return result;
if (cmd == CAMERA_CMD_SET_DISPLAY_ORIENTATION) {
// Mirror the preview if the camera is front-facing.
orientation = getOrientation(arg1, mCameraFacing == CAMERA_FACING_FRONT);
if (orientation == -1) return BAD_VALUE;
if (mOrientation != orientation) {
mOrientation = orientation;
if (mPreviewWindow != 0) {
mHardware->setPreviewTransform(mOrientation);
}
}
return OK;
} else if (cmd == CAMERA_CMD_ENABLE_SHUTTER_SOUND) {
switch (arg1) {
case 0:
return enableShutterSound(false);
case 1:
return enableShutterSound(true);
default:
return BAD_VALUE;
}
return OK;
} else if (cmd == CAMERA_CMD_PLAY_RECORDING_SOUND) {
sCameraService->playSound(CameraService::SOUND_RECORDING_START);
} else if (cmd == CAMERA_CMD_SET_VIDEO_BUFFER_COUNT) {
// Silently ignore this command
return INVALID_OPERATION;
} else if (cmd == CAMERA_CMD_PING) {
// If mHardware is 0, checkPidAndHardware will return error.
return OK;
}
return mHardware->sendCommand(cmd, arg1, arg2);
}
// ----------------------------------------------------------------------------
void CameraClient::enableMsgType(int32_t msgType) {
android_atomic_or(msgType, &mMsgEnabled);
mHardware->enableMsgType(msgType);
}
void CameraClient::disableMsgType(int32_t msgType) {
android_atomic_and(~msgType, &mMsgEnabled);
mHardware->disableMsgType(msgType);
}
#define CHECK_MESSAGE_INTERVAL 10 // 10ms
bool CameraClient::lockIfMessageWanted(int32_t msgType) {
int sleepCount = 0;
while (mMsgEnabled & msgType) {
if (mLock.tryLock() == NO_ERROR) {
if (sleepCount > 0) {
LOG1("lockIfMessageWanted(%d): waited for %d ms",
msgType, sleepCount * CHECK_MESSAGE_INTERVAL);
}
// If messages are no longer enabled after acquiring lock, release and drop message
if ((mMsgEnabled & msgType) == 0) {
mLock.unlock();
break;
}
return true;
}
if (sleepCount++ == 0) {
LOG1("lockIfMessageWanted(%d): enter sleep", msgType);
}
usleep(CHECK_MESSAGE_INTERVAL * 1000);
}
ALOGW("lockIfMessageWanted(%d): dropped unwanted message", msgType);
return false;
}
sp<CameraClient> CameraClient::getClientFromCookie(void* user) {
String8 cameraId = String8::format("%d", (int)(intptr_t) user);
auto clientDescriptor = sCameraService->mActiveClientManager.get(cameraId);
if (clientDescriptor != nullptr) {
return sp<CameraClient>{
static_cast<CameraClient*>(clientDescriptor->getValue().get())};
}
return sp<CameraClient>{nullptr};
}
// Callback messages can be dispatched to internal handlers or pass to our
// client's callback functions, depending on the message type.
//
// notifyCallback:
// CAMERA_MSG_SHUTTER handleShutter
// (others) c->notifyCallback
// dataCallback:
// CAMERA_MSG_PREVIEW_FRAME handlePreviewData
// CAMERA_MSG_POSTVIEW_FRAME handlePostview
// CAMERA_MSG_RAW_IMAGE handleRawPicture
// CAMERA_MSG_COMPRESSED_IMAGE handleCompressedPicture
// (others) c->dataCallback
// dataCallbackTimestamp
// (others) c->dataCallbackTimestamp
void CameraClient::notifyCallback(int32_t msgType, int32_t ext1,
int32_t ext2, void* user) {
LOG2("notifyCallback(%d)", msgType);
sp<CameraClient> client = getClientFromCookie(user);
if (client.get() == nullptr) return;
if (!client->lockIfMessageWanted(msgType)) return;
switch (msgType) {
case CAMERA_MSG_SHUTTER:
// ext1 is the dimension of the yuv picture.
client->handleShutter();
break;
default:
client->handleGenericNotify(msgType, ext1, ext2);
break;
}
}
void CameraClient::dataCallback(int32_t msgType,
const sp<IMemory>& dataPtr, camera_frame_metadata_t *metadata, void* user) {
LOG2("dataCallback(%d)", msgType);
sp<CameraClient> client = getClientFromCookie(user);
if (client.get() == nullptr) return;
if (!client->lockIfMessageWanted(msgType)) return;
if (dataPtr == 0 && metadata == NULL) {
ALOGE("Null data returned in data callback");
client->handleGenericNotify(CAMERA_MSG_ERROR, UNKNOWN_ERROR, 0);
return;
}
switch (msgType & ~CAMERA_MSG_PREVIEW_METADATA) {
case CAMERA_MSG_PREVIEW_FRAME:
client->handlePreviewData(msgType, dataPtr, metadata);
break;
case CAMERA_MSG_POSTVIEW_FRAME:
client->handlePostview(dataPtr);
break;
case CAMERA_MSG_RAW_IMAGE:
client->handleRawPicture(dataPtr);
break;
case CAMERA_MSG_COMPRESSED_IMAGE:
client->handleCompressedPicture(dataPtr);
break;
default:
client->handleGenericData(msgType, dataPtr, metadata);
break;
}
}
void CameraClient::dataCallbackTimestamp(nsecs_t timestamp,
int32_t msgType, const sp<IMemory>& dataPtr, void* user) {
LOG2("dataCallbackTimestamp(%d)", msgType);
sp<CameraClient> client = getClientFromCookie(user);
if (client.get() == nullptr) return;
if (!client->lockIfMessageWanted(msgType)) return;
if (dataPtr == 0) {
ALOGE("Null data returned in data with timestamp callback");
client->handleGenericNotify(CAMERA_MSG_ERROR, UNKNOWN_ERROR, 0);
return;
}
client->handleGenericDataTimestamp(timestamp, msgType, dataPtr);
}
void CameraClient::handleCallbackTimestampBatch(
int32_t msgType, const std::vector<HandleTimestampMessage>& msgs, void* user) {
LOG2("dataCallbackTimestampBatch");
sp<CameraClient> client = getClientFromCookie(user);
if (client.get() == nullptr) return;
if (!client->lockIfMessageWanted(msgType)) return;
sp<hardware::ICameraClient> c = client->mRemoteCallback;
client->mLock.unlock();
if (c != 0 && msgs.size() > 0) {
size_t n = msgs.size();
std::vector<nsecs_t> timestamps;
std::vector<native_handle_t*> handles;
timestamps.reserve(n);
handles.reserve(n);
for (auto& msg : msgs) {
native_handle_t* handle = nullptr;
if (msg.dataPtr->size() != sizeof(VideoNativeHandleMetadata)) {
ALOGE("%s: dataPtr does not contain VideoNativeHandleMetadata!", __FUNCTION__);
return;
}
VideoNativeHandleMetadata *metadata =
(VideoNativeHandleMetadata*)(msg.dataPtr->pointer());
if (metadata->eType == kMetadataBufferTypeNativeHandleSource) {
handle = metadata->pHandle;
}
if (handle == nullptr) {
ALOGE("%s: VideoNativeHandleMetadata type mismatch or null handle passed!",
__FUNCTION__);
return;
}
{
Mutex::Autolock l(client->mAvailableCallbackBuffersLock);
client->mAvailableCallbackBuffers.push_back(msg.dataPtr);
}
timestamps.push_back(msg.timestamp);
handles.push_back(handle);
}
c->recordingFrameHandleCallbackTimestampBatch(timestamps, handles);
}
}
// snapshot taken callback
void CameraClient::handleShutter(void) {
if (mPlayShutterSound) {
sCameraService->playSound(CameraService::SOUND_SHUTTER);
}
sp<hardware::ICameraClient> c = mRemoteCallback;
if (c != 0) {
mLock.unlock();
c->notifyCallback(CAMERA_MSG_SHUTTER, 0, 0);
if (!lockIfMessageWanted(CAMERA_MSG_SHUTTER)) return;
}
disableMsgType(CAMERA_MSG_SHUTTER);
// Shutters only happen in response to takePicture, so mark device as
// idle now, until preview is restarted
sCameraService->updateProxyDeviceState(
hardware::ICameraServiceProxy::CAMERA_STATE_IDLE,
mCameraIdStr, mCameraFacing, mClientPackageName,
hardware::ICameraServiceProxy::CAMERA_API_LEVEL_1);
mLock.unlock();
}
// preview callback - frame buffer update
void CameraClient::handlePreviewData(int32_t msgType,
const sp<IMemory>& mem,
camera_frame_metadata_t *metadata) {
ssize_t offset;
size_t size;
sp<IMemoryHeap> heap = mem->getMemory(&offset, &size);
// local copy of the callback flags
int flags = mPreviewCallbackFlag;
// is callback enabled?
if (!(flags & CAMERA_FRAME_CALLBACK_FLAG_ENABLE_MASK)) {
// If the enable bit is off, the copy-out and one-shot bits are ignored
LOG2("frame callback is disabled");
mLock.unlock();
return;
}
// hold a strong pointer to the client
sp<hardware::ICameraClient> c = mRemoteCallback;
// clear callback flags if no client or one-shot mode
if (c == 0 || (mPreviewCallbackFlag & CAMERA_FRAME_CALLBACK_FLAG_ONE_SHOT_MASK)) {
LOG2("Disable preview callback");
mPreviewCallbackFlag &= ~(CAMERA_FRAME_CALLBACK_FLAG_ONE_SHOT_MASK |
CAMERA_FRAME_CALLBACK_FLAG_COPY_OUT_MASK |
CAMERA_FRAME_CALLBACK_FLAG_ENABLE_MASK);
disableMsgType(CAMERA_MSG_PREVIEW_FRAME);
}
if (c != 0) {
// Is the received frame copied out or not?
if (flags & CAMERA_FRAME_CALLBACK_FLAG_COPY_OUT_MASK) {
LOG2("frame is copied");
copyFrameAndPostCopiedFrame(msgType, c, heap, offset, size, metadata);
} else {
LOG2("frame is forwarded");
mLock.unlock();
c->dataCallback(msgType, mem, metadata);
}
} else {
mLock.unlock();
}
}
// picture callback - postview image ready
void CameraClient::handlePostview(const sp<IMemory>& mem) {
disableMsgType(CAMERA_MSG_POSTVIEW_FRAME);
sp<hardware::ICameraClient> c = mRemoteCallback;
mLock.unlock();
if (c != 0) {
c->dataCallback(CAMERA_MSG_POSTVIEW_FRAME, mem, NULL);
}
}
// picture callback - raw image ready
void CameraClient::handleRawPicture(const sp<IMemory>& mem) {
disableMsgType(CAMERA_MSG_RAW_IMAGE);
ssize_t offset;
size_t size;
sp<IMemoryHeap> heap = mem->getMemory(&offset, &size);
sp<hardware::ICameraClient> c = mRemoteCallback;
mLock.unlock();
if (c != 0) {
c->dataCallback(CAMERA_MSG_RAW_IMAGE, mem, NULL);
}
}
// picture callback - compressed picture ready
void CameraClient::handleCompressedPicture(const sp<IMemory>& mem) {
disableMsgType(CAMERA_MSG_COMPRESSED_IMAGE);
sp<hardware::ICameraClient> c = mRemoteCallback;
mLock.unlock();
if (c != 0) {
c->dataCallback(CAMERA_MSG_COMPRESSED_IMAGE, mem, NULL);
}
}
void CameraClient::handleGenericNotify(int32_t msgType,
int32_t ext1, int32_t ext2) {
sp<hardware::ICameraClient> c = mRemoteCallback;
mLock.unlock();
if (c != 0) {
c->notifyCallback(msgType, ext1, ext2);
}
}
void CameraClient::handleGenericData(int32_t msgType,
const sp<IMemory>& dataPtr, camera_frame_metadata_t *metadata) {
sp<hardware::ICameraClient> c = mRemoteCallback;
mLock.unlock();
if (c != 0) {
c->dataCallback(msgType, dataPtr, metadata);
}
}
void CameraClient::handleGenericDataTimestamp(nsecs_t timestamp,
int32_t msgType, const sp<IMemory>& dataPtr) {
sp<hardware::ICameraClient> c = mRemoteCallback;
mLock.unlock();
if (c != 0 && dataPtr != nullptr) {
native_handle_t* handle = nullptr;
// Check if dataPtr contains a VideoNativeHandleMetadata.
if (dataPtr->size() == sizeof(VideoNativeHandleMetadata)) {
VideoNativeHandleMetadata *metadata =
(VideoNativeHandleMetadata*)(dataPtr->pointer());
if (metadata->eType == kMetadataBufferTypeNativeHandleSource) {
handle = metadata->pHandle;
}
}
// If dataPtr contains a native handle, send it via recordingFrameHandleCallbackTimestamp.
if (handle != nullptr) {
{
Mutex::Autolock l(mAvailableCallbackBuffersLock);
mAvailableCallbackBuffers.push_back(dataPtr);
}
c->recordingFrameHandleCallbackTimestamp(timestamp, handle);
} else {
c->dataCallbackTimestamp(timestamp, msgType, dataPtr);
}
}
}
void CameraClient::copyFrameAndPostCopiedFrame(
int32_t msgType, const sp<hardware::ICameraClient>& client,
const sp<IMemoryHeap>& heap, size_t offset, size_t size,
camera_frame_metadata_t *metadata) {
LOG2("copyFrameAndPostCopiedFrame");
// It is necessary to copy out of pmem before sending this to
// the callback. For efficiency, reuse the same MemoryHeapBase
// provided it's big enough. Don't allocate the memory or
// perform the copy if there's no callback.
// hold the preview lock while we grab a reference to the preview buffer
sp<MemoryHeapBase> previewBuffer;
if (mPreviewBuffer == 0) {
mPreviewBuffer = new MemoryHeapBase(size, 0, NULL);
} else if (size > mPreviewBuffer->virtualSize()) {
mPreviewBuffer.clear();
mPreviewBuffer = new MemoryHeapBase(size, 0, NULL);
}
if (mPreviewBuffer == 0) {
ALOGE("failed to allocate space for preview buffer");
mLock.unlock();
return;
}
previewBuffer = mPreviewBuffer;
void* previewBufferBase = previewBuffer->base();
void* heapBase = heap->base();
if (heapBase == MAP_FAILED) {
ALOGE("%s: Failed to mmap heap for preview frame.", __FUNCTION__);
mLock.unlock();
return;
} else if (previewBufferBase == MAP_FAILED) {
ALOGE("%s: Failed to mmap preview buffer for preview frame.", __FUNCTION__);
mLock.unlock();
return;
}
memcpy(previewBufferBase, (uint8_t *) heapBase + offset, size);
sp<MemoryBase> frame = new MemoryBase(previewBuffer, 0, size);
if (frame == 0) {
ALOGE("failed to allocate space for frame callback");
mLock.unlock();
return;
}
mLock.unlock();
client->dataCallback(msgType, frame, metadata);
}
int CameraClient::getOrientation(int degrees, bool mirror) {
if (!mirror) {
if (degrees == 0) return 0;
else if (degrees == 90) return HAL_TRANSFORM_ROT_90;
else if (degrees == 180) return HAL_TRANSFORM_ROT_180;
else if (degrees == 270) return HAL_TRANSFORM_ROT_270;
} else { // Do mirror (horizontal flip)
if (degrees == 0) { // FLIP_H and ROT_0
return HAL_TRANSFORM_FLIP_H;
} else if (degrees == 90) { // FLIP_H and ROT_90
return HAL_TRANSFORM_FLIP_H | HAL_TRANSFORM_ROT_90;
} else if (degrees == 180) { // FLIP_H and ROT_180
return HAL_TRANSFORM_FLIP_V;
} else if (degrees == 270) { // FLIP_H and ROT_270
return HAL_TRANSFORM_FLIP_V | HAL_TRANSFORM_ROT_90;
}
}
ALOGE("Invalid setDisplayOrientation degrees=%d", degrees);
return -1;
}
status_t CameraClient::setVideoTarget(const sp<IGraphicBufferProducer>& bufferProducer) {
(void)bufferProducer;
ALOGE("%s: %d: CameraClient doesn't support setting a video target.", __FUNCTION__, __LINE__);
return INVALID_OPERATION;
}
}; // namespace android