Open Source Computer Vision Library https://opencv.org/
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#if !defined(ANDROID_r2_2_0) && !defined(ANDROID_r2_3_3) && !defined(ANDROID_r3_0_1) && !defined(ANDROID_r4_0_0) && !defined(ANDROID_r4_0_3) && !defined(ANDROID_r4_1_1)
# error Building camera wrapper for your version of Android is not supported by OpenCV. You need to modify OpenCV sources in order to compile camera wrapper for your version of Android.
#endif
#include <camera/Camera.h>
#include <camera/CameraParameters.h>
#if defined(ANDROID_r4_0_0) || defined(ANDROID_r4_0_3)
# include <system/camera.h>
#endif //defined(ANDROID_r4_0_0) || defined(ANDROID_r4_0_3)
#include "camera_wrapper.h"
#include "../include/camera_properties.h"
#if defined(ANDROID_r3_0_1) || defined(ANDROID_r4_0_0) || defined(ANDROID_r4_0_3) || defined(ANDROID_r4_1_1)
//Include SurfaceTexture.h file with the SurfaceTexture class
# include <gui/SurfaceTexture.h>
# define MAGIC_OPENCV_TEXTURE_ID (0x10)
#else // defined(ANDROID_r3_0_1) || defined(ANDROID_r4_0_0) || defined(ANDROID_r4_0_3)
//TODO: This is either 2.2 or 2.3. Include the headers for ISurface.h access
#if defined(ANDROID_r4_1_1)
#include <gui/ISurface.h>
#include <gui/BufferQueue.h>
#else
# include <surfaceflinger/ISurface.h>
#endif // defined(ANDROID_r4_1_1)
#endif // defined(ANDROID_r3_0_1) || defined(ANDROID_r4_0_0) || defined(ANDROID_r4_0_3)
#include <string>
//undef logging macro from /system/core/libcutils/loghack.h
#ifdef LOGD
# undef LOGD
#endif
#ifdef LOGI
# undef LOGI
#endif
#ifdef LOGW
# undef LOGW
#endif
#ifdef LOGE
# undef LOGE
#endif
// LOGGING
#include <android/log.h>
#define CAMERA_LOG_TAG "OpenCV_NativeCamera"
#define LOGD(...) ((void)__android_log_print(ANDROID_LOG_DEBUG, CAMERA_LOG_TAG, __VA_ARGS__))
#define LOGI(...) ((void)__android_log_print(ANDROID_LOG_INFO, CAMERA_LOG_TAG, __VA_ARGS__))
#define LOGW(...) ((void)__android_log_print(ANDROID_LOG_WARN, CAMERA_LOG_TAG, __VA_ARGS__))
#define LOGE(...) ((void)__android_log_print(ANDROID_LOG_ERROR, CAMERA_LOG_TAG, __VA_ARGS__))
#include <dlfcn.h>
using namespace android;
void debugShowFPS();
#if defined(ANDROID_r4_1_1)
class ConsumerListenerStub: public BufferQueue::ConsumerListener
{
public:
virtual void onFrameAvailable()
{
}
virtual void onBuffersReleased()
{
}
};
#endif
void debugShowFPS()
{
static int mFrameCount = 0;
static int mLastFrameCount = 0;
static nsecs_t mLastFpsTime = systemTime();
static float mFps = 0;
mFrameCount++;
if (( mFrameCount % 30 ) != 0)
return;
nsecs_t now = systemTime();
nsecs_t diff = now - mLastFpsTime;
if (diff==0)
return;
mFps = ((mFrameCount - mLastFrameCount) * float(s2ns(1))) / diff;
mLastFpsTime = now;
mLastFrameCount = mFrameCount;
LOGI("### Camera FPS ### [%d] Frames, %.2f FPS", mFrameCount, mFps);
}
class CameraHandler: public CameraListener
{
protected:
int cameraId;
sp<Camera> camera;
CameraParameters params;
CameraCallback cameraCallback;
void* userData;
int emptyCameraCallbackReported;
static const char* flashModesNames[ANDROID_CAMERA_FLASH_MODES_NUM];
static const char* focusModesNames[ANDROID_CAMERA_FOCUS_MODES_NUM];
static const char* whiteBalanceModesNames[ANDROID_CAMERA_WHITE_BALANCE_MODES_NUM];
static const char* antibandingModesNames[ANDROID_CAMERA_ANTIBANDING_MODES_NUM];
void doCall(void* buffer, size_t bufferSize)
{
if (cameraCallback == 0)
{
if (!emptyCameraCallbackReported)
LOGE("CameraHandler::doCall(void*, size_t): Camera callback is empty!");
emptyCameraCallbackReported++;
}
else
{
bool res = (*cameraCallback)(buffer, bufferSize, userData);
if(!res)
{
LOGE("CameraHandler::doCall(void*, size_t): cameraCallback returns false (camera connection will be closed)");
closeCameraConnect();
}
}
}
void doCall(const sp<IMemory>& dataPtr)
{
if (dataPtr == NULL)
{
LOGE("CameraHandler::doCall(const sp<IMemory>&): dataPtr==NULL (no frame to handle)");
return;
}
size_t size = dataPtr->size();
if (size <= 0)
{
LOGE("CameraHandler::doCall(const sp<IMemory>&): IMemory object is of zero size");
return;
}
void* buffer = (void *)dataPtr->pointer();
if (!buffer)
{
LOGE("CameraHandler::doCall(const sp<IMemory>&): Buffer pointer is NULL");
return;
}
doCall(buffer, size);
}
virtual void postDataTimestamp(nsecs_t timestamp, int32_t msgType, const sp<IMemory>& dataPtr)
{
static uint32_t count = 0;
count++;
LOGE("Recording cb: %d %lld %%p Offset:%%d Stride:%%d\n", msgType, timestamp);
if (dataPtr == NULL)
{
LOGE("postDataTimestamp: dataPtr IS ZERO -- returning");
camera->releaseRecordingFrame(dataPtr);
LOGE("postDataTimestamp: camera->releaseRecordingFrame(dataPtr) is done");
return;
}
uint8_t *ptr = (uint8_t*) dataPtr->pointer();
if (ptr)
LOGE("VID_CB: 0x%x 0x%x 0x%x 0x%x 0x%x 0x%x 0x%x 0x%x 0x%x 0x%x", ptr[0], ptr[1], ptr[2], ptr[3], ptr[4], ptr[5], ptr[6], ptr[7], ptr[8], ptr[9]);
else
LOGE("postDataTimestamp: Ptr is zero");
camera->releaseRecordingFrame(dataPtr);
}
// Split list of floats, returns number of floats found
static int split_float(const char *str, float* out, char delim, int max_elem_num,
char **endptr = NULL)
{
// Find the first float.
char *end = const_cast<char*>(str);
int elem_num = 0;
for(; elem_num < max_elem_num; elem_num++ ){
char* curr_end;
out[elem_num] = (float)strtof(end, &curr_end);
// No other numbers found, finish the loop
if(end == curr_end){
break;
}
if (*curr_end != delim) {
// When end of string, finish the loop
if (*curr_end == 0){
elem_num++;
break;
}
else {
LOGE("Cannot find delimeter (%c) in str=%s", delim, str);
return -1;
}
}
// Skip the delimiter character
end = curr_end + 1;
}
if (endptr)
*endptr = end;
return elem_num;
}
int is_supported(const char* supp_modes_key, const char* mode)
{
const char* supported_modes = params.get(supp_modes_key);
return (supported_modes && mode && (strstr(supported_modes, mode) > 0));
}
float getFocusDistance(int focus_distance_type)
{
#if !defined(ANDROID_r2_2_0)
if (focus_distance_type >= 0 && focus_distance_type < 3)
{
float focus_distances[3];
const char* output = params.get(CameraParameters::KEY_FOCUS_DISTANCES);
int val_num = CameraHandler::split_float(output, focus_distances, ',', 3);
if(val_num == 3)
{
return focus_distances[focus_distance_type];
}
else
{
LOGE("Invalid focus distances.");
}
}
#endif
return -1;
}
static int getModeNum(const char** modes, const int modes_num, const char* mode_name)
{
for (int i = 0; i < modes_num; i++){
if(!strcmp(modes[i],mode_name))
return i;
}
return -1;
}
public:
CameraHandler(CameraCallback callback = 0, void* _userData = 0):
cameraId(0),
cameraCallback(callback),
userData(_userData),
emptyCameraCallbackReported(0)
{
LOGD("Instantiated new CameraHandler (%p, %p)", callback, _userData);
}
virtual ~CameraHandler()
{
LOGD("CameraHandler destructor is called");
}
virtual void notify(int32_t msgType, int32_t ext1, int32_t ext2)
{
LOGE("CameraHandler::Notify: msgType=%d ext1=%d ext2=%d\n", msgType, ext1, ext2);
#if 0
if ( msgType & CAMERA_MSG_FOCUS )
LOGE("CameraHandler::Notify AutoFocus %s in %llu us\n", (ext1) ? "OK" : "FAIL", timevalDelay(&autofocus_start));
if ( msgType & CAMERA_MSG_SHUTTER )
LOGE("CameraHandler::Notify Shutter done in %llu us\n", timeval_delay(&picture_start));
#endif
}
virtual void postData(int32_t msgType, const sp<IMemory>& dataPtr
#if defined(ANDROID_r4_0_0) || defined(ANDROID_r4_0_3) || defined(ANDROID_r4_1_1)
,camera_frame_metadata_t*
#endif
)
{
debugShowFPS();
if ( msgType & CAMERA_MSG_PREVIEW_FRAME )
{
doCall(dataPtr);
return;
}
//if (msgType != CAMERA_MSG_PREVIEW_FRAME)
//LOGE("CameraHandler::postData Recieved message %d is not equal to CAMERA_MSG_PREVIEW_FRAME (%d)", (int) msgType, CAMERA_MSG_PREVIEW_FRAME);
if ( msgType & CAMERA_MSG_RAW_IMAGE )
LOGE("CameraHandler::postData Unexpected data format: RAW\n");
if (msgType & CAMERA_MSG_POSTVIEW_FRAME)
LOGE("CameraHandler::postData Unexpected data format: Postview frame\n");
if (msgType & CAMERA_MSG_COMPRESSED_IMAGE )
LOGE("CameraHandler::postData Unexpected data format: JPEG");
}
static CameraHandler* initCameraConnect(const CameraCallback& callback, int cameraId, void* userData, CameraParameters* prevCameraParameters);
void closeCameraConnect();
double getProperty(int propIdx);
void setProperty(int propIdx, double value);
static void applyProperties(CameraHandler** ppcameraHandler);
std::string cameraPropertySupportedPreviewSizesString;
std::string cameraPropertyPreviewFormatString;
};
const char* CameraHandler::flashModesNames[ANDROID_CAMERA_FLASH_MODES_NUM] =
{
CameraParameters::FLASH_MODE_AUTO,
CameraParameters::FLASH_MODE_OFF,
CameraParameters::FLASH_MODE_ON,
CameraParameters::FLASH_MODE_RED_EYE,
CameraParameters::FLASH_MODE_TORCH
};
const char* CameraHandler::focusModesNames[ANDROID_CAMERA_FOCUS_MODES_NUM] =
{
CameraParameters::FOCUS_MODE_AUTO,
#if !defined(ANDROID_r2_2_0)
CameraParameters::FOCUS_MODE_CONTINUOUS_VIDEO,
#endif
CameraParameters::FOCUS_MODE_EDOF,
CameraParameters::FOCUS_MODE_FIXED,
CameraParameters::FOCUS_MODE_INFINITY
};
const char* CameraHandler::whiteBalanceModesNames[ANDROID_CAMERA_WHITE_BALANCE_MODES_NUM] =
{
CameraParameters::WHITE_BALANCE_AUTO,
CameraParameters::WHITE_BALANCE_CLOUDY_DAYLIGHT,
CameraParameters::WHITE_BALANCE_DAYLIGHT,
CameraParameters::WHITE_BALANCE_FLUORESCENT,
CameraParameters::WHITE_BALANCE_INCANDESCENT,
CameraParameters::WHITE_BALANCE_SHADE,
CameraParameters::WHITE_BALANCE_TWILIGHT
};
const char* CameraHandler::antibandingModesNames[ANDROID_CAMERA_ANTIBANDING_MODES_NUM] =
{
CameraParameters::ANTIBANDING_50HZ,
CameraParameters::ANTIBANDING_60HZ,
CameraParameters::ANTIBANDING_AUTO
};
CameraHandler* CameraHandler::initCameraConnect(const CameraCallback& callback, int cameraId, void* userData, CameraParameters* prevCameraParameters)
{
typedef sp<Camera> (*Android22ConnectFuncType)();
typedef sp<Camera> (*Android23ConnectFuncType)(int);
typedef sp<Camera> (*Android3DConnectFuncType)(int, int);
enum {
CAMERA_SUPPORT_MODE_2D = 0x01, /* Camera Sensor supports 2D mode. */
CAMERA_SUPPORT_MODE_3D = 0x02, /* Camera Sensor supports 3D mode. */
CAMERA_SUPPORT_MODE_NONZSL = 0x04, /* Camera Sensor in NON-ZSL mode. */
CAMERA_SUPPORT_MODE_ZSL = 0x08 /* Camera Sensor supports ZSL mode. */
};
const char Android22ConnectName[] = "_ZN7android6Camera7connectEv";
const char Android23ConnectName[] = "_ZN7android6Camera7connectEi";
const char Android3DConnectName[] = "_ZN7android6Camera7connectEii";
LOGD("CameraHandler::initCameraConnect(%p, %d, %p, %p)", callback, cameraId, userData, prevCameraParameters);
sp<Camera> camera = 0;
void* CameraHALHandle = dlopen("libcamera_client.so", RTLD_LAZY);
if (!CameraHALHandle)
{
LOGE("Cannot link to \"libcamera_client.so\"");
return NULL;
}
// reset errors
dlerror();
if (Android22ConnectFuncType Android22Connect = (Android22ConnectFuncType)dlsym(CameraHALHandle, Android22ConnectName))
{
LOGD("Connecting to CameraService v 2.2");
camera = Android22Connect();
LOGD("Connection to CameraService v 2.2 established");
}
else if (Android23ConnectFuncType Android23Connect = (Android23ConnectFuncType)dlsym(CameraHALHandle, Android23ConnectName))
{
LOGD("Connecting to CameraService v 2.3");
camera = Android23Connect(cameraId);
LOGD("Connection to CameraService v 2.3 established");
}
else if (Android3DConnectFuncType Android3DConnect = (Android3DConnectFuncType)dlsym(CameraHALHandle, Android3DConnectName))
{
LOGD("Connecting to CameraService v 3D");
camera = Android3DConnect(cameraId, CAMERA_SUPPORT_MODE_2D);
LOGD("Connection to CameraService v 3D established");
}
else
{
dlclose(CameraHALHandle);
LOGE("Cannot connect to CameraService. Connect method was not found!");
return NULL;
}
dlclose(CameraHALHandle);
if ( NULL == camera.get() )
{
LOGE("initCameraConnect: Unable to connect to CameraService\n");
return 0;
}
LOGD("Creating camera handler");
CameraHandler* handler = new CameraHandler(callback, userData);
LOGD("Setting camera listener");
camera->setListener(handler);
LOGD("Updating camera handler");
handler->camera = camera;
handler->cameraId = cameraId;
LOGD("Checking previous camera parameters");
if (NULL != prevCameraParameters)
{
LOGI("initCameraConnect: Setting paramers from previous camera handler");
camera->setParameters(prevCameraParameters->flatten());
handler->params.unflatten(prevCameraParameters->flatten());
}
else
{
android::String8 params_str = camera->getParameters();
LOGI("initCameraConnect: [%s]", params_str.string());
handler->params.unflatten(params_str);
LOGD("Supported Cameras: %s", handler->params.get("camera-indexes"));
LOGD("Supported Picture Sizes: %s", handler->params.get(CameraParameters::KEY_SUPPORTED_PICTURE_SIZES));
LOGD("Supported Picture Formats: %s", handler->params.get(CameraParameters::KEY_SUPPORTED_PICTURE_FORMATS));
LOGD("Supported Preview Sizes: %s", handler->params.get(CameraParameters::KEY_SUPPORTED_PREVIEW_SIZES));
LOGD("Supported Preview Formats: %s", handler->params.get(CameraParameters::KEY_SUPPORTED_PREVIEW_FORMATS));
LOGD("Supported Preview Frame Rates: %s", handler->params.get(CameraParameters::KEY_SUPPORTED_PREVIEW_FRAME_RATES));
LOGD("Supported Thumbnail Sizes: %s", handler->params.get(CameraParameters::KEY_SUPPORTED_JPEG_THUMBNAIL_SIZES));
LOGD("Supported Whitebalance Modes: %s", handler->params.get(CameraParameters::KEY_SUPPORTED_WHITE_BALANCE));
LOGD("Supported Effects: %s", handler->params.get(CameraParameters::KEY_SUPPORTED_EFFECTS));
LOGD("Supported Scene Modes: %s", handler->params.get(CameraParameters::KEY_SUPPORTED_SCENE_MODES));
LOGD("Supported Focus Modes: %s", handler->params.get(CameraParameters::KEY_SUPPORTED_FOCUS_MODES));
LOGD("Supported Antibanding Options: %s", handler->params.get(CameraParameters::KEY_SUPPORTED_ANTIBANDING));
LOGD("Supported Flash Modes: %s", handler->params.get(CameraParameters::KEY_SUPPORTED_FLASH_MODES));
#if !defined(ANDROID_r2_2_0)
// Set focus mode to continuous-video if supported
const char* available_focus_modes = handler->params.get(CameraParameters::KEY_SUPPORTED_FOCUS_MODES);
if (NULL != available_focus_modes)
{
if (strstr(available_focus_modes, "continuous-video") != NULL)
{
handler->params.set(CameraParameters::KEY_FOCUS_MODE, CameraParameters::FOCUS_MODE_CONTINUOUS_VIDEO);
status_t resParams = handler->camera->setParameters(handler->params.flatten());
if (0 != resParams)
{
LOGE("initCameraConnect: failed to set autofocus mode to \"continuous-video\"");
}
else
{
LOGD("initCameraConnect: autofocus is set to mode \"continuous-video\"");
}
}
}
#endif
//check if yuv420sp format available. Set this format as preview format.
const char* available_formats = handler->params.get(CameraParameters::KEY_SUPPORTED_PREVIEW_FORMATS);
if (available_formats != 0)
{
const char* format_to_set = 0;
const char* pos = available_formats;
const char* ptr = pos;
while(true)
{
while(*ptr != 0 && *ptr != ',') ++ptr;
if (ptr != pos)
{
if (0 == strncmp(pos, "yuv420sp", ptr - pos))
{
format_to_set = "yuv420sp";
break;
}
if (0 == strncmp(pos, "yvu420sp", ptr - pos))
format_to_set = "yvu420sp";
}
if (*ptr == 0)
break;
pos = ++ptr;
}
if (0 != format_to_set)
{
handler->params.setPreviewFormat(format_to_set);
status_t resParams = handler->camera->setParameters(handler->params.flatten());
if (resParams != 0)
LOGE("initCameraConnect: failed to set preview format to %s", format_to_set);
else
LOGD("initCameraConnect: preview format is set to %s", format_to_set);
}
}
}
status_t pdstatus;
#if defined(ANDROID_r2_2_0)
pdstatus = camera->setPreviewDisplay(sp<ISurface>(0 /*new DummySurface*/));
if (pdstatus != 0)
LOGE("initCameraConnect: failed setPreviewDisplay(0) call; camera migth not work correctly on some devices");
#elif defined(ANDROID_r2_3_3)
/* Do nothing in case of 2.3 for now */
#elif defined(ANDROID_r3_0_1) || defined(ANDROID_r4_0_0) || defined(ANDROID_r4_0_3)
sp<SurfaceTexture> surfaceTexture = new SurfaceTexture(MAGIC_OPENCV_TEXTURE_ID);
pdstatus = camera->setPreviewTexture(surfaceTexture);
if (pdstatus != 0)
LOGE("initCameraConnect: failed setPreviewTexture call; camera migth not work correctly");
#elif defined(ANDROID_r4_1_1)
sp<BufferQueue> bufferQueue = new BufferQueue();
sp<BufferQueue::ConsumerListener> queueListener = new ConsumerListenerStub();
bufferQueue->consumerConnect(queueListener);
pdstatus = camera->setPreviewTexture(bufferQueue);
if (pdstatus != 0)
LOGE("initCameraConnect: failed setPreviewTexture call; camera migth not work correctly");
#endif
#if (defined(ANDROID_r2_2_0) || defined(ANDROID_r2_3_3) || defined(ANDROID_r3_0_1))
# if 1
////ATTENTION: switching between two versions: with and without copying memory inside Android OS
//// see the method CameraService::Client::copyFrameAndPostCopiedFrame and where it is used
camera->setPreviewCallbackFlags( FRAME_CALLBACK_FLAG_ENABLE_MASK | FRAME_CALLBACK_FLAG_COPY_OUT_MASK);//with copy
# else
camera->setPreviewCallbackFlags( FRAME_CALLBACK_FLAG_ENABLE_MASK );//without copy
# endif
#else
camera->setPreviewCallbackFlags( CAMERA_FRAME_CALLBACK_FLAG_ENABLE_MASK | CAMERA_FRAME_CALLBACK_FLAG_COPY_OUT_MASK);//with copy
#endif //!(defined(ANDROID_r4_0_0) || defined(ANDROID_r4_0_3))
LOGD("Starting preview");
status_t resStart = camera->startPreview();
if (resStart != 0)
{
LOGE("initCameraConnect: startPreview() fails. Closing camera connection...");
handler->closeCameraConnect();
handler = 0;
}
else
{
LOGD("Preview started successfully");
}
return handler;
}
void CameraHandler::closeCameraConnect()
{
if (camera == NULL)
{
LOGI("... camera is already NULL");
return;
}
camera->stopPreview();
camera->disconnect();
camera.clear();
camera = NULL;
// ATTENTION!!!!!!!!!!!!!!!!!!!!!!!!!!
// When we set
// camera=NULL
// above, the pointed instance of android::Camera object is destructed,
// since this member `camera' has type android::sp<Camera> (android smart pointer template class),
// and this is the only pointer to it.
//
// BUT this instance of CameraHandler is set as a listener for that android::Camera object
// (see the function CameraHandler::initCameraConnect above),
// so this instance of CameraHandler is pointed from that android::Camera object as
// sp<CameraListener> mListener
// and there is no other android smart pointers to this.
//
// It means, when that instance of the android::Camera object is destructed,
// it calls destructor for this CameraHandler instance too.
//
// So, this line `camera=NULL' causes to the call `delete this'
// (see destructor of the template class android::sp)
//
// So, we must not call `delete this' after the line, since it just has been called indeed
}
double CameraHandler::getProperty(int propIdx)
{
LOGD("CameraHandler::getProperty(%d)", propIdx);
switch (propIdx)
{
case ANDROID_CAMERA_PROPERTY_FRAMEWIDTH:
{
int w,h;
params.getPreviewSize(&w, &h);
return w;
}
case ANDROID_CAMERA_PROPERTY_FRAMEHEIGHT:
{
int w,h;
params.getPreviewSize(&w, &h);
return h;
}
case ANDROID_CAMERA_PROPERTY_SUPPORTED_PREVIEW_SIZES_STRING:
{
cameraPropertySupportedPreviewSizesString = params.get(CameraParameters::KEY_SUPPORTED_PREVIEW_SIZES);
union {const char* str;double res;} u;
memset(&u.res, 0, sizeof(u.res));
u.str = cameraPropertySupportedPreviewSizesString.c_str();
return u.res;
}
case ANDROID_CAMERA_PROPERTY_PREVIEW_FORMAT_STRING:
{
const char* fmt = params.get(CameraParameters::KEY_PREVIEW_FORMAT);
if (fmt == CameraParameters::PIXEL_FORMAT_YUV422SP)
fmt = "yuv422sp";
else if (fmt == CameraParameters::PIXEL_FORMAT_YUV420SP)
fmt = "yuv420sp";
else if (fmt == CameraParameters::PIXEL_FORMAT_YUV422I)
fmt = "yuv422i";
else if (fmt == CameraParameters::PIXEL_FORMAT_RGB565)
fmt = "rgb565";
else if (fmt == CameraParameters::PIXEL_FORMAT_JPEG)
fmt = "jpeg";
cameraPropertyPreviewFormatString = fmt;
union {const char* str;double res;} u;
memset(&u.res, 0, sizeof(u.res));
u.str = cameraPropertyPreviewFormatString.c_str();
return u.res;
}
case ANDROID_CAMERA_PROPERTY_EXPOSURE:
{
int exposure = params.getInt(CameraParameters::KEY_EXPOSURE_COMPENSATION);
return exposure;
}
case ANDROID_CAMERA_PROPERTY_FPS:
{
return params.getPreviewFrameRate();
}
case ANDROID_CAMERA_PROPERTY_FLASH_MODE:
{
int flash_mode = getModeNum(CameraHandler::flashModesNames,
ANDROID_CAMERA_FLASH_MODES_NUM,
params.get(CameraParameters::KEY_FLASH_MODE));
return flash_mode;
}
case ANDROID_CAMERA_PROPERTY_FOCUS_MODE:
{
int focus_mode = getModeNum(CameraHandler::focusModesNames,
ANDROID_CAMERA_FOCUS_MODES_NUM,
params.get(CameraParameters::KEY_FOCUS_MODE));
return focus_mode;
}
case ANDROID_CAMERA_PROPERTY_WHITE_BALANCE:
{
int white_balance = getModeNum(CameraHandler::whiteBalanceModesNames,
ANDROID_CAMERA_WHITE_BALANCE_MODES_NUM,
params.get(CameraParameters::KEY_WHITE_BALANCE));
return white_balance;
}
case ANDROID_CAMERA_PROPERTY_ANTIBANDING:
{
int antibanding = getModeNum(CameraHandler::antibandingModesNames,
ANDROID_CAMERA_ANTIBANDING_MODES_NUM,
params.get(CameraParameters::KEY_ANTIBANDING));
return antibanding;
}
case ANDROID_CAMERA_PROPERTY_FOCAL_LENGTH:
{
float focal_length = params.getFloat(CameraParameters::KEY_FOCAL_LENGTH);
return focal_length;
}
case ANDROID_CAMERA_PROPERTY_FOCUS_DISTANCE_NEAR:
{
return getFocusDistance(ANDROID_CAMERA_FOCUS_DISTANCE_NEAR_INDEX);
}
case ANDROID_CAMERA_PROPERTY_FOCUS_DISTANCE_OPTIMAL:
{
return getFocusDistance(ANDROID_CAMERA_FOCUS_DISTANCE_OPTIMAL_INDEX);
}
case ANDROID_CAMERA_PROPERTY_FOCUS_DISTANCE_FAR:
{
return getFocusDistance(ANDROID_CAMERA_FOCUS_DISTANCE_FAR_INDEX);
}
default:
LOGW("CameraHandler::getProperty - Unsupported property.");
};
return -1;
}
void CameraHandler::setProperty(int propIdx, double value)
{
LOGD("CameraHandler::setProperty(%d, %f)", propIdx, value);
switch (propIdx)
{
case ANDROID_CAMERA_PROPERTY_FRAMEWIDTH:
{
int w,h;
params.getPreviewSize(&w, &h);
w = (int)value;
params.setPreviewSize(w, h);
}
break;
case ANDROID_CAMERA_PROPERTY_FRAMEHEIGHT:
{
int w,h;
params.getPreviewSize(&w, &h);
h = (int)value;
params.setPreviewSize(w, h);
}
break;
case ANDROID_CAMERA_PROPERTY_EXPOSURE:
{
int max_exposure = params.getInt("max-exposure-compensation");
int min_exposure = params.getInt("min-exposure-compensation");
if(max_exposure && min_exposure){
int exposure = (int)value;
if(exposure >= min_exposure && exposure <= max_exposure){
params.set("exposure-compensation", exposure);
} else {
LOGE("Exposure compensation not in valid range (%i,%i).", min_exposure, max_exposure);
}
} else {
LOGE("Exposure compensation adjust is not supported.");
}
}
break;
case ANDROID_CAMERA_PROPERTY_FLASH_MODE:
{
int new_val = (int)value;
if(new_val >= 0 && new_val < ANDROID_CAMERA_FLASH_MODES_NUM){
const char* mode_name = flashModesNames[new_val];
if(is_supported(CameraParameters::KEY_SUPPORTED_FLASH_MODES, mode_name))
params.set(CameraParameters::KEY_FLASH_MODE, mode_name);
else
LOGE("Flash mode %s is not supported.", mode_name);
} else {
LOGE("Flash mode value not in valid range.");
}
}
break;
case ANDROID_CAMERA_PROPERTY_FOCUS_MODE:
{
int new_val = (int)value;
if(new_val >= 0 && new_val < ANDROID_CAMERA_FOCUS_MODES_NUM){
const char* mode_name = focusModesNames[new_val];
if(is_supported(CameraParameters::KEY_SUPPORTED_FOCUS_MODES, mode_name))
params.set(CameraParameters::KEY_FOCUS_MODE, mode_name);
else
LOGE("Focus mode %s is not supported.", mode_name);
} else {
LOGE("Focus mode value not in valid range.");
}
}
break;
case ANDROID_CAMERA_PROPERTY_WHITE_BALANCE:
{
int new_val = (int)value;
if(new_val >= 0 && new_val < ANDROID_CAMERA_WHITE_BALANCE_MODES_NUM){
const char* mode_name = whiteBalanceModesNames[new_val];
if(is_supported(CameraParameters::KEY_SUPPORTED_WHITE_BALANCE, mode_name))
params.set(CameraParameters::KEY_WHITE_BALANCE, mode_name);
else
LOGE("White balance mode %s is not supported.", mode_name);
} else {
LOGE("White balance mode value not in valid range.");
}
}
break;
case ANDROID_CAMERA_PROPERTY_ANTIBANDING:
{
int new_val = (int)value;
if(new_val >= 0 && new_val < ANDROID_CAMERA_ANTIBANDING_MODES_NUM){
const char* mode_name = antibandingModesNames[new_val];
if(is_supported(CameraParameters::KEY_SUPPORTED_ANTIBANDING, mode_name))
params.set(CameraParameters::KEY_ANTIBANDING, mode_name);
else
LOGE("Antibanding mode %s is not supported.", mode_name);
} else {
LOGE("Antibanding mode value not in valid range.");
}
}
break;
default:
LOGW("CameraHandler::setProperty - Unsupported property.");
};
}
void CameraHandler::applyProperties(CameraHandler** ppcameraHandler)
{
LOGD("CameraHandler::applyProperties()");
if (NULL == ppcameraHandler)
{
LOGE("applyProperties: Passed NULL ppcameraHandler");
return;
}
if (NULL == *ppcameraHandler)
{
LOGE("applyProperties: Passed null *ppcameraHandler");
return;
}
LOGD("CameraHandler::applyProperties()");
#if !defined(ANDROID_r2_2_0)
LOGD("Reconnect camera");
(*ppcameraHandler)->camera->reconnect();
(*ppcameraHandler)->params = (*ppcameraHandler)->camera->getParameters();
#else
CameraHandler* previousCameraHandler = *ppcameraHandler;
CameraParameters curCameraParameters(previousCameraHandler->params.flatten());
CameraCallback cameraCallback = previousCameraHandler->cameraCallback;
void* userData = previousCameraHandler->userData;
int cameraId = previousCameraHandler->cameraId;
LOGD("CameraHandler::applyProperties(): before previousCameraHandler->closeCameraConnect");
previousCameraHandler->closeCameraConnect();
LOGD("CameraHandler::applyProperties(): after previousCameraHandler->closeCameraConnect");
LOGD("CameraHandler::applyProperties(): before initCameraConnect");
CameraHandler* handler = initCameraConnect(cameraCallback, cameraId, userData, &curCameraParameters);
LOGD("CameraHandler::applyProperties(): after initCameraConnect, handler=0x%x", (int)handler);
if (handler == NULL) {
LOGE("ERROR in applyProperties --- cannot reinit camera");
handler = initCameraConnect(cameraCallback, cameraId, userData, NULL);
LOGD("CameraHandler::applyProperties(): repeate initCameraConnect after ERROR, handler=0x%x", (int)handler);
if (handler == NULL) {
LOGE("ERROR in applyProperties --- cannot reinit camera AGAIN --- cannot do anything else");
}
}
(*ppcameraHandler) = handler;
#endif
}
extern "C" {
void* initCameraConnectC(void* callback, int cameraId, void* userData)
{
return CameraHandler::initCameraConnect((CameraCallback)callback, cameraId, userData, NULL);
}
void closeCameraConnectC(void** camera)
{
CameraHandler** cc = (CameraHandler**)camera;
(*cc)->closeCameraConnect();
*cc = 0;
}
double getCameraPropertyC(void* camera, int propIdx)
{
return ((CameraHandler*)camera)->getProperty(propIdx);
}
void setCameraPropertyC(void* camera, int propIdx, double value)
{
((CameraHandler*)camera)->setProperty(propIdx,value);
}
void applyCameraPropertiesC(void** camera)
{
CameraHandler::applyProperties((CameraHandler**)camera);
}
}