#include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include "camera_test.h" using namespace android; extern bool stopScript; extern bool hardwareActive; extern sp camera; extern CameraParameters params; extern bool recordingMode; extern int camera_index; extern int rotation; extern const preview_size previewSize []; extern const Vcapture_size VcaptureSize []; extern const capture_Size captureSize[]; extern const outformat outputFormat[]; extern const video_Codecs videoCodecs[]; extern const audio_Codecs audioCodecs[]; extern const V_bitRate VbitRate[]; extern const fps_ranges fpsRanges[]; extern const fpsConst_Ranges fpsConstRanges[]; extern const fpsConst_RangesSec fpsConstRangesSec[]; extern const Zoom zoom []; extern int previewSizeIDX; extern bool reSizePreview; extern bool previewRunning; extern int captureSizeIDX; extern float compensation; extern int videoCodecIDX; extern int outputFormatIDX; extern int audioCodecIDX; extern int VcaptureSizeIDX; extern int VbitRateIDX; extern int thumbSizeIDX; extern int thumbQuality; extern int jpegQuality; extern int dump_preview; extern int ippIDX_old; extern const char *capture[]; extern int capture_mode; extern int ippIDX; extern const char *ipp_mode[]; extern int tempBracketRange; extern int iso_mode; extern int sharpness; extern int contrast; extern int zoomIDX; extern int brightness; extern int saturation; extern int fpsRangeIdx; extern timeval autofocus_start, picture_start; extern const char *cameras[]; extern double latitude; extern double degree_by_step; extern double longitude; extern double altitude; extern char dir_path[80]; extern int AutoConvergenceModeIDX; extern const char *autoconvergencemode[]; extern const char *manualconvergencevalues[]; extern const int ManualConvergenceDefaultValueIDX; extern size_t length_cam; extern char script_name[]; extern int restartCount; extern bool bLogSysLinkTrace; extern int bufferStarvationTest; extern size_t length_previewSize; extern size_t lenght_Vcapture_size; extern size_t length_outformat; extern size_t length_capture_Size; extern size_t length_video_Codecs; extern size_t length_audio_Codecs; extern size_t length_V_bitRate; extern size_t length_Zoom; extern size_t length_fps_ranges; extern size_t length_fpsConst_Ranges; extern size_t length_fpsConst_RangesSec; int execute_functional_script(char *script) { char *cmd, *ctx, *cycle_cmd, *temp_cmd; char id; unsigned int i; int dly; int cycleCounter = 1; int tLen = 0; unsigned int iteration = 0; status_t ret = NO_ERROR; int frameR = 20; int frameRateIndex = 0; LOG_FUNCTION_NAME; dump_mem_status(); cmd = strtok_r((char *) script, DELIMITER, &ctx); while ( NULL != cmd && (stopScript == false)) { id = cmd[0]; printf("Full Command: %s \n", cmd); printf("Command: %c \n", cmd[0]); switch (id) { // Case for Suspend-Resume Feature case '!': { // STEP 1: Mount Debugfs system("mkdir /debug"); system("mount -t debugfs debugfs /debug"); // STEP 2: Set up wake up Timer - wake up happens after 5 seconds system("echo 10 > /debug/pm_debug/wakeup_timer_seconds"); // STEP 3: Make system ready for Suspend system("echo camerahal_test > /sys/power/wake_unlock"); // Release wake lock held by test app printf(" Wake lock released "); system("cat /sys/power/wake_lock"); system("sendevent /dev/input/event0 1 60 1"); system("sendevent /dev/input/event0 1 60 0"); // Simulate F2 key press to make display OFF printf(" F2 event simulation complete "); //STEP 4: Wait for system Resume and then simuate F1 key sleep(50);//50s // This delay is not related to suspend resume timer printf(" After 30 seconds of sleep"); system("sendevent /dev/input/event0 1 59 0"); system("sendevent /dev/input/event0 1 59 1"); // Simulate F1 key press to make display ON system("echo camerahal_test > /sys/power/wake_lock"); // Acquire wake lock for test app break; } case '[': if ( hardwareActive ) { camera->setParameters(params.flatten()); printf("starting camera preview.."); status_t ret = camera->startPreview(); if(ret !=NO_ERROR) { printf("startPreview failed %d..", ret); } } break; case '+': { cycleCounter = atoi(cmd + 1); cycle_cmd = get_cycle_cmd(ctx); tLen = strlen(cycle_cmd); temp_cmd = new char[tLen+1]; for (int ind = 0; ind < cycleCounter; ind++) { strcpy(temp_cmd, cycle_cmd); if ( execute_functional_script(temp_cmd) != 0 ) return -1; temp_cmd[0] = '\0'; //patch for image capture //[ if (ind < cycleCounter - 1) { if (hardwareActive == false) { if ( openCamera() < 0 ) { printf("Camera initialization failed\n"); return -1; } initDefaults(); } } //] } ctx += tLen + 1; if (temp_cmd) { delete temp_cmd; temp_cmd = NULL; } if (cycle_cmd) { delete cycle_cmd; cycle_cmd = NULL; } break; } case '0': { initDefaults(); break; } case '1': if ( startPreview() < 0 ) { printf("Error while starting preview\n"); return -1; } break; case '2': stopPreview(); if ( recordingMode ) { camera->disconnect(); camera.clear(); stopRecording(); closeRecorder(); camera = Camera::connect(camera_index); if ( NULL == camera.get() ) { sleep(1); camera = Camera::connect(camera_index); if ( NULL == camera.get() ) { return -1; } } camera->setListener(new CameraHandler()); camera->setParameters(params.flatten()); recordingMode = false; } break; case '3': rotation = atoi(cmd + 1); params.set(CameraParameters::KEY_ROTATION, rotation); if ( hardwareActive ) camera->setParameters(params.flatten()); break; case '4': { printf("Setting resolution..."); int width, height; for(i = 0; i < length_previewSize ; i++) { if( strcmp((cmd + 1), previewSize[i].desc) == 0) { width = previewSize[i].width; height = previewSize[i].height; previewSizeIDX = i; break; } } if (i == length_previewSize ) //if the resolution is not in the supported ones { char *res = NULL; res = strtok(cmd + 1, "x"); width = atoi(res); res = strtok(NULL, "x"); height = atoi(res); } if ( NULL != params.get(KEY_STEREO_CAMERA) ) { if ( strcmp(params.get(KEY_STEREO_CAMERA), "true") == 0 ) { height *=2; } } printf("Resolution: %d x %d\n", width, height); params.setPreviewSize(width, height); reSizePreview = true; if ( hardwareActive && previewRunning ) { camera->stopPreview(); camera->setParameters(params.flatten()); camera->startPreview(); } else if ( hardwareActive ) { camera->setParameters(params.flatten()); } break; } case '5': for (i = 0; i < length_capture_Size; i++) { if ( strcmp((cmd + 1), captureSize[i].name) == 0) break; } if ( i < length_capture_Size ) { params.setPictureSize(captureSize[i].width, captureSize[i].height); captureSizeIDX = i; } if ( hardwareActive ) camera->setParameters(params.flatten()); break; case '6': if ( !recordingMode ) { recordingMode = true; if ( startPreview() < 0 ) { printf("Error while starting preview\n"); return -1; } if ( openRecorder() < 0 ) { printf("Error while openning video recorder\n"); return -1; } if ( configureRecorder() < 0 ) { printf("Error while configuring video recorder\n"); return -1; } if ( startRecording() < 0 ) { printf("Error while starting video recording\n"); return -1; } } break; case '7': compensation = atof(cmd + 1); params.set(KEY_COMPENSATION, (int) (compensation * 10)); if ( hardwareActive ) camera->setParameters(params.flatten()); break; case '8': params.set(params.KEY_WHITE_BALANCE, (cmd + 1)); if ( hardwareActive ) camera->setParameters(params.flatten()); break; case '9': for(i = 0; i < length_video_Codecs; i++) { if( strcmp((cmd + 1), videoCodecs[i].desc) == 0) { videoCodecIDX = i; printf("Video Codec Selected: %s\n", videoCodecs[i].desc); break; } } break; case 'v': for(i = 0; i < length_outformat; i++) { if( strcmp((cmd + 1), outputFormat[i].desc) == 0) { outputFormatIDX = i; printf("Video Codec Selected: %s\n", videoCodecs[i].desc); break; } } break; case '~': params.setPreviewFormat(cmd + 1); if ( hardwareActive ) camera->setParameters(params.flatten()); break; case '$': params.setPictureFormat(cmd + 1); if ( hardwareActive ) camera->setParameters(params.flatten()); break; case '-': for(i = 0; i < length_audio_Codecs; i++) { if( strcmp((cmd + 1), audioCodecs[i].desc) == 0) { audioCodecIDX = i; printf("Selected Audio: %s\n", audioCodecs[i].desc); break; } } break; case 'A': camera_index=atoi(cmd+1); // camera_index %= ARRAY_SIZE(cameras); camera_index %= length_cam; if ( camera_index == 2) params.set(KEY_STEREO_CAMERA, "true"); else params.set(KEY_STEREO_CAMERA, "false"); printf("%s selected.\n", cameras[camera_index]); if ( hardwareActive ) { stopPreview(); closeCamera(); openCamera(); } else { closeCamera(); openCamera(); } if (camera_index == 0) params.setPreviewFrameRate(30); else params.setPreviewFrameRate(27); break; case 'a': char * temp_str; temp_str = strtok(cmd+1,"!"); printf("Latitude %s \n",temp_str); params.set(params.KEY_GPS_LATITUDE, temp_str); temp_str=strtok(NULL,"!"); printf("Longitude %s \n",temp_str); params.set(params.KEY_GPS_LONGITUDE, temp_str); temp_str=strtok(NULL,"!"); printf("Altitude %s \n",temp_str); params.set(params.KEY_GPS_ALTITUDE, temp_str); if ( hardwareActive ) camera->setParameters(params.flatten()); break; case 'l': case 'L': for(i = 0; i < lenght_Vcapture_size; i++) { if( strcmp((cmd + 1), VcaptureSize[i].desc) == 0) { VcaptureSizeIDX = i; printf("Video Capture Size: %s\n", VcaptureSize[i].desc); break; } } break; case ']': for(i = 0; i < length_V_bitRate; i++) { if( strcmp((cmd + 1), VbitRate[i].desc) == 0) { VbitRateIDX = i; printf("Video Bit Rate: %s\n", VbitRate[i].desc); break; } } break; case ':': int width, height; for(i = 0; i < length_previewSize ; i++) { if( strcmp((cmd + 1), previewSize[i].desc) == 0) { width = previewSize[i].width; height = previewSize[i].height; thumbSizeIDX = i; break; } } if (i == length_previewSize ) //if the resolution is not in the supported ones { char *res = NULL; res = strtok(cmd + 1, "x"); width = atoi(res); res = strtok(NULL, "x"); height = atoi(res); } params.set(CameraParameters::KEY_JPEG_THUMBNAIL_WIDTH, width); params.set(CameraParameters::KEY_JPEG_THUMBNAIL_HEIGHT, height); if ( hardwareActive ) camera->setParameters(params.flatten()); break; case '\'': thumbQuality = atoi(cmd + 1); params.set(CameraParameters::KEY_JPEG_THUMBNAIL_QUALITY, thumbQuality); if ( hardwareActive ) camera->setParameters(params.flatten()); break; case '*': if ( hardwareActive ) camera->startRecording(); break; case 't': params.setPreviewFormat((cmd + 1)); if ( hardwareActive ) camera->setParameters(params.flatten()); break; case 'o': jpegQuality = atoi(cmd + 1); params.set(CameraParameters::KEY_JPEG_QUALITY, jpegQuality); if ( hardwareActive ) camera->setParameters(params.flatten()); break; case '&': printf("Enabling Preview Callback"); dump_preview = 1; camera->setPreviewCallbackFlags(CAMERA_FRAME_CALLBACK_FLAG_ENABLE_MASK); break; case 'k': ippIDX_old = atoi(cmd + 1); params.set(KEY_IPP, atoi(cmd + 1)); if ( hardwareActive ) camera->setParameters(params.flatten()); break; case 'K': params.set(KEY_GBCE, (cmd+1)); if ( hardwareActive ) camera->setParameters(params.flatten()); break; case 'F': if ( hardwareActive ) camera->sendCommand(CAMERA_CMD_START_FACE_DETECTION, 0, 0); break; case 'T': if ( hardwareActive ) camera->sendCommand(CAMERA_CMD_STOP_FACE_DETECTION, 0, 0); case 'O': params.set(KEY_GLBCE, (cmd+1)); if ( hardwareActive ) camera->setParameters(params.flatten()); break; case 'u': // HQ should always be in ldc-nsf // if not HQ, then return the ipp to its previous state if( !strcmp(capture[capture_mode], "high-quality") ) { ippIDX_old = ippIDX; ippIDX = 3; params.set(KEY_IPP, ipp_mode[ippIDX]); } else { ippIDX = ippIDX_old; } params.set(KEY_MODE, (cmd + 1)); if ( hardwareActive ) camera->setParameters(params.flatten()); break; case 'U': params.set(KEY_TEMP_BRACKETING, (cmd + 1)); if ( hardwareActive ) camera->setParameters(params.flatten()); break; case 'W': tempBracketRange = atoi(cmd + 1); tempBracketRange %= TEMP_BRACKETING_MAX_RANGE; if ( 0 == tempBracketRange ) { tempBracketRange = 1; } params.set(KEY_TEMP_BRACKETING_NEG, tempBracketRange); params.set(KEY_TEMP_BRACKETING_POS, tempBracketRange); if ( hardwareActive ) camera->setParameters(params.flatten()); break; case '#': params.set(KEY_BURST, atoi(cmd + 1)); if ( hardwareActive ) camera->setParameters(params.flatten()); break; case 'J': params.set(CameraParameters::KEY_FLASH_MODE, (cmd+1)); if ( hardwareActive ) camera->setParameters(params.flatten()); break; case 'w': params.set(params.KEY_SCENE_MODE, (cmd + 1)); if ( hardwareActive ) camera->setParameters(params.flatten()); break; case 'B' : params.set(KEY_VNF, (cmd + 1)); if ( hardwareActive ) camera->setParameters(params.flatten()); case 'C' : params.set(KEY_VSTAB, (cmd + 1)); if ( hardwareActive ) camera->setParameters(params.flatten()); break; case 'D': if ( hardwareActive ) camera->stopRecording(); break; case 'E': if(hardwareActive) params.unflatten(camera->getParameters()); printSupportedParams(); break; case 'i': iso_mode = atoi(cmd + 1); params.set(KEY_ISO, iso_mode); if ( hardwareActive ) camera->setParameters(params.flatten()); break; case 'h': sharpness = atoi(cmd + 1); params.set(KEY_SHARPNESS, sharpness); if ( hardwareActive ) camera->setParameters(params.flatten()); break; case '@': if ( hardwareActive ) { closeCamera(); if ( 0 >= openCamera() ) { printf( "Reconnected to CameraService \n"); } } break; case 'c': contrast = atoi(cmd + 1); params.set(KEY_CONTRAST, contrast); if ( hardwareActive ) { camera->setParameters(params.flatten()); } break; case 'z': case 'Z': #if defined(OMAP_ENHANCEMENT) && defined(TARGET_OMAP3) params.set(CameraParameters::KEY_ZOOM, atoi(cmd + 1)); #else for(i = 0; i < length_Zoom; i++) { if( strcmp((cmd + 1), zoom[i].zoom_description) == 0) { zoomIDX = i; break; } } params.set(CameraParameters::KEY_ZOOM, zoom[zoomIDX].idx); #endif if ( hardwareActive ) camera->setParameters(params.flatten()); break; case 'j': params.set(KEY_EXPOSURE, (cmd + 1)); if ( hardwareActive ) camera->setParameters(params.flatten()); break; case 'b': brightness = atoi(cmd + 1); params.set(KEY_BRIGHTNESS, brightness); if ( hardwareActive ) camera->setParameters(params.flatten()); break; case 's': saturation = atoi(cmd + 1); params.set(KEY_SATURATION, saturation); if ( hardwareActive ) camera->setParameters(params.flatten()); break; case 'e': params.set(params.KEY_EFFECT, (cmd + 1)); if ( hardwareActive ) camera->setParameters(params.flatten()); break; case 'r': frameR = atoi(cmd + 1); if (camera_index == 0) { for (i = 0; i < length_fpsConst_Ranges; i++) { if (frameR == fpsConstRanges[i].constFramerate) frameRateIndex = i; } } else { for (i = 0; i < length_fpsConst_RangesSec; i++) { if (frameR == fpsConstRangesSec[i].constFramerate) frameRateIndex = i; } } if (camera_index == 0) params.set(CameraParameters::KEY_PREVIEW_FPS_RANGE, fpsConstRanges[frameRateIndex].range); else params.set(CameraParameters::KEY_PREVIEW_FPS_RANGE, fpsConstRangesSec[frameRateIndex].range); if ( hardwareActive && previewRunning ) { camera->stopPreview(); camera->setParameters(params.flatten()); camera->startPreview(); } else if ( hardwareActive ) { camera->setParameters(params.flatten()); } break; case 'R': for(i = 0; i < length_fps_ranges; i++) { if( strcmp((cmd + 1), fpsRanges[i].rangeDescription) == 0) { fpsRangeIdx = i; printf("Selected Framerate range: %s\n", fpsRanges[i].rangeDescription); if ( hardwareActive ) { params.set(CameraParameters::KEY_PREVIEW_FPS_RANGE, fpsRanges[i].range); params.remove(CameraParameters::KEY_PREVIEW_FRAME_RATE); camera->setParameters(params.flatten()); } break; } } break; case 'x': params.set(params.KEY_ANTIBANDING, (cmd + 1)); if ( hardwareActive ) camera->setParameters(params.flatten()); break; case 'g': params.set(params.KEY_FOCUS_MODE, (cmd + 1)); if ( hardwareActive ) camera->setParameters(params.flatten()); break; case 'G': params.set(CameraParameters::KEY_FOCUS_AREAS, (cmd + 1)); if ( hardwareActive ) camera->setParameters(params.flatten()); params.remove(CameraParameters::KEY_FOCUS_AREAS); case 'f': gettimeofday(&autofocus_start, 0); if ( hardwareActive ) camera->autoFocus(); break; case 'p': gettimeofday(&picture_start, 0); if ( hardwareActive ) ret = camera->takePicture(CAMERA_MSG_COMPRESSED_IMAGE|CAMERA_MSG_RAW_IMAGE); if ( ret != NO_ERROR ) printf("Error returned while taking a picture"); break; case 'd': dly = atoi(cmd + 1); sleep(dly); break; case 'q': dump_mem_status(); stopPreview(); if ( recordingMode ) { stopRecording(); closeRecorder(); recordingMode = false; } goto exit; case '\n': printf("Iteration: %d \n", iteration); iteration++; break; case '{': if ( atoi(cmd + 1) > 0 ) params.set(KEY_S3D2D_PREVIEW_MODE, "on"); else params.set(KEY_S3D2D_PREVIEW_MODE, "off"); if ( hardwareActive ) camera->setParameters(params.flatten()); break; case 'M': params.set(KEY_MEASUREMENT, (cmd + 1)); if ( hardwareActive ) camera->setParameters(params.flatten()); break; case 'm': { params.set(KEY_METERING_MODE, (cmd + 1)); if ( hardwareActive ) { camera->setParameters(params.flatten()); } break; } case '<': { char coord_str[8]; latitude += degree_by_step; if (latitude > 90.0) { latitude -= 180.0; } snprintf(coord_str, 7, "%.7lf", latitude); params.set(params.KEY_GPS_LATITUDE, coord_str); if ( hardwareActive ) { camera->setParameters(params.flatten()); } break; } case '=': { char coord_str[8]; longitude += degree_by_step; if (longitude > 180.0) { longitude -= 360.0; } snprintf(coord_str, 7, "%.7lf", longitude); params.set(params.KEY_GPS_LONGITUDE, coord_str); if ( hardwareActive ) { camera->setParameters(params.flatten()); } break; } case '>': { char coord_str[8]; altitude += 12345.67890123456789; if (altitude > 100000.0) { altitude -= 200000.0; } snprintf(coord_str, 7, "%.7lf", altitude); params.set(params.KEY_GPS_ALTITUDE, coord_str); if ( hardwareActive ) { camera->setParameters(params.flatten()); } break; } case 'X': { char rem_str[50]; printf("Deleting images from %s \n", dir_path); if(!sprintf(rem_str,"rm %s/*.jpg",dir_path)) printf("Sprintf Error"); if(system(rem_str)) printf("Images were not deleted\n"); break; } case '_': { AutoConvergenceModeIDX = atoi(cmd + 1); if ( AutoConvergenceModeIDX < 0 || AutoConvergenceModeIDX > 4 ) AutoConvergenceModeIDX = 0; params.set(KEY_AUTOCONVERGENCE, autoconvergencemode[AutoConvergenceModeIDX]); if ( AutoConvergenceModeIDX != 4 ) params.set(KEY_MANUALCONVERGENCE_VALUES, manualconvergencevalues[ManualConvergenceDefaultValueIDX]); if ( hardwareActive ) camera->setParameters(params.flatten()); break; } case '^': { char strtmpval[7]; if ( strcmp (autoconvergencemode[AutoConvergenceModeIDX], AUTOCONVERGENCE_MODE_MANUAL) == 0) { sprintf(strtmpval,"%d", atoi(cmd + 1)); params.set(KEY_MANUALCONVERGENCE_VALUES, strtmpval); if ( hardwareActive ) camera->setParameters(params.flatten()); } break; } default: printf("Unrecognized command!\n"); break; } cmd = strtok_r(NULL, DELIMITER, &ctx); } exit: if (stopScript == true) { return -1; } else { return 0; } } char * get_cycle_cmd(const char *aSrc) { unsigned ind = 0; char *cycle_cmd = new char[256]; while ((*aSrc != '+') && (*aSrc != '\0')) { cycle_cmd[ind++] = *aSrc++; } cycle_cmd[ind] = '\0'; return cycle_cmd; } status_t dump_mem_status() { system(MEDIASERVER_DUMP); return system(MEMORY_DUMP); } char *load_script(char *config) { FILE *infile; size_t fileSize; char *script; size_t nRead = 0; char dir_name[40]; size_t count; char rCount [5]; count = 0; infile = fopen(config, "r"); strcpy(script_name,config); // remove just the '.txt' part of the config while((config[count] != '.') && (count < sizeof(dir_name)/sizeof(dir_name[0]))) count++; printf("\n SCRIPT : <%s> is currently being executed \n",script_name); if(strncpy(dir_name,config,count) == NULL) printf("Strcpy error"); dir_name[count]=NULL; if(strcat(dir_path,dir_name) == NULL) printf("Strcat error"); if(restartCount) { sprintf(rCount,"_%d",restartCount); if(strcat(dir_path, rCount) == NULL) printf("Strcat error RestartCount"); } printf("\n COMPLETE FOLDER PATH : %s \n",dir_path); if(mkdir(dir_path,0777) == -1) { printf("\n Directory %s was not created \n",dir_path); } else { printf("\n Directory %s was created \n",dir_path); } printf("\n DIRECTORY CREATED FOR TEST RESULT IMAGES IN MMC CARD : %s \n",dir_name); if( (NULL == infile)){ printf("Error while opening script file %s!\n", config); return NULL; } fseek(infile, 0, SEEK_END); fileSize = ftell(infile); fseek(infile, 0, SEEK_SET); script = (char *) malloc(fileSize); if ( NULL == script ) { printf("Unable to allocate buffer for the script\n"); return NULL; } if ((nRead = fread(script, 1, fileSize, infile)) != fileSize) { printf("Error while reading script file!\n"); free(script); fclose(infile); return NULL; } fclose(infile); return script; } int start_logging(char *config, int &pid) { char dir_name[40]; size_t count = 0; int status = 0; // remove just the '.txt' part of the config while((config[count] != '.') && (count < sizeof(dir_name)/sizeof(dir_name[0]))) count++; if(strncpy(dir_name,config,count) == NULL) printf("Strcpy error"); dir_name[count]=NULL; pid = fork(); if (pid == 0) { char *command_list[] = {"sh", "-c", NULL, NULL}; char log_cmd[120]; // child process to run logging // set group id of this process to itself // we will use this group id to kill the // application logging setpgid(getpid(), getpid()); /* Start logcat */ if(!sprintf(log_cmd,"logcat > /sdcard/%s/log.txt &",dir_name)) printf(" Sprintf Error"); /* Start Syslink Trace */ if(bLogSysLinkTrace) { if(!sprintf(log_cmd,"%s /system/bin/syslink_trace_daemon.out -l /sdcard/%s/syslink_trace.txt -f &",log_cmd, dir_name)) printf(" Sprintf Error"); } command_list[2] = (char *)log_cmd; execvp("/system/bin/sh", command_list); } if(pid < 0) { printf("failed to fork logcat\n"); return -1; } //wait for logging to start if(waitpid(pid, &status, 0) != pid) { printf("waitpid failed in log fork\n"); return -1; }else printf("logging started... status=%d\n", status); return 0; } int stop_logging(int &pid) { if(pid > 0) { if(killpg(pid, SIGKILL)) { printf("Exit command failed"); return -1; } else { printf("\nlogging for script %s is complete\n logcat saved @ location: %s\n",script_name,dir_path); if (bLogSysLinkTrace) printf(" syslink_trace is saved @ location: %s\n\n",dir_path); } } return 0; } int execute_error_script(char *script) { char *cmd, *ctx; char id; status_t stat = NO_ERROR; LOG_FUNCTION_NAME; cmd = strtok_r((char *) script, DELIMITER, &ctx); while ( NULL != cmd ) { id = cmd[0]; switch (id) { case '0': { bufferStarvationTest = 1; params.set(KEY_BUFF_STARV, bufferStarvationTest); //enable buffer starvation if ( !recordingMode ) { recordingMode = true; if ( startPreview() < 0 ) { printf("Error while starting preview\n"); return -1; } if ( openRecorder() < 0 ) { printf("Error while openning video recorder\n"); return -1; } if ( configureRecorder() < 0 ) { printf("Error while configuring video recorder\n"); return -1; } if ( startRecording() < 0 ) { printf("Error while starting video recording\n"); return -1; } } usleep(1000000);//1s stopPreview(); if ( recordingMode ) { stopRecording(); closeRecorder(); recordingMode = false; } break; } case '1': { int* tMemoryEater = new int[999999999]; if (!tMemoryEater) { printf("Not enough memory\n"); return -1; } else { delete tMemoryEater; } break; } case '2': { //camera = Camera::connect(); if ( NULL == camera.get() ) { printf("Unable to connect to CameraService\n"); return -1; } break; } case '3': { int err = 0; err = open("/dev/video5", O_RDWR); if (err < 0) { printf("Could not open the camera device5: %d\n", err ); return err; } if ( startPreview() < 0 ) { printf("Error while starting preview\n"); return -1; } usleep(1000000);//1s stopPreview(); close(err); break; } case '4': { if ( hardwareActive ) { params.setPictureFormat("invalid-format"); params.setPreviewFormat("invalid-format"); stat = camera->setParameters(params.flatten()); if ( NO_ERROR != stat ) { printf("Test passed!\n"); } else { printf("Test failed!\n"); } initDefaults(); } break; } case '5': { if ( hardwareActive ) { params.setPictureSize(-1, -1); params.setPreviewSize(-1, -1); stat = camera->setParameters(params.flatten()); if ( NO_ERROR != stat ) { printf("Test passed!\n"); } else { printf("Test failed!\n"); } initDefaults(); } break; } case '6': { if ( hardwareActive ) { params.setPreviewFrameRate(-1); stat = camera->setParameters(params.flatten()); if ( NO_ERROR != stat ) { printf("Test passed!\n"); } else { printf("Test failed!\n"); } initDefaults(); } break; } case 'q': { goto exit; break; } default: { printf("Unrecognized command!\n"); break; } } cmd = strtok_r(NULL, DELIMITER, &ctx); } exit: return 0; }