static void s_osal_cfg_on_fatal_error(void* task, osal_fatalerror_t errorcode, const char * errormsg) { uint8_t tskid = 0; char str[64]; osal_task_id_get((osal_task_t*)task, &tskid); snprintf(str, sizeof(str), "osalerror %d taskid %d: %s", errorcode, tskid, errormsg); if(eobool_true == eo_errman_IsErrorHandlerConfigured(eo_errman_GetHandle())) { // ok ... use the error manager, either in its simple form or in its networked form eOerrmanDescriptor_t errdes = {0}; errdes.code = eoerror_code_get(eoerror_category_System, eoerror_value_SYS_osalerror); errdes.par16 = errorcode; errdes.par64 = 0; errdes.sourcedevice = eo_errman_sourcedevice_localboard; errdes.sourceaddress = 0; eo_errman_Error(eo_errman_GetHandle(), eo_errortype_fatal, str, "OSAL", &errdes); } else { if(NULL != errormsg) { hal_trace_puts(errormsg); } // in case of fatal error we blink all leds but led1 hal_led_init(hal_led0, NULL); hal_led_init(hal_led1, NULL); hal_led_init(hal_led2, NULL); hal_led_init(hal_led3, NULL); hal_led_init(hal_led4, NULL); hal_led_init(hal_led5, NULL); hal_led_off(hal_led0); hal_led_off(hal_led1); hal_led_off(hal_led2); hal_led_off(hal_led3); hal_led_off(hal_led4); hal_led_off(hal_led5); for(;;) { hal_sys_delay(100); hal_led_toggle(hal_led0); //hal_led_toggle(hal_led1); hal_led_toggle(hal_led2); hal_led_toggle(hal_led3); hal_led_toggle(hal_led4); hal_led_toggle(hal_led5); } } }
static void s_hal_core_cfg_on_fatalerror(hal_fatalerror_t errorcode, const char * errormsg) { errorcode = errorcode; if(NULL != errormsg) { hal_trace_puts(errormsg); } hal_led_init(hal_led2, NULL); for(;;) { hal_sys_delay(250*1000); hal_led_toggle(hal_led2); } }
static void s_hal_core_cfg_on_fatalerror(hal_fatalerror_t errorcode, const char * errormsg) { if(eobool_true == eo_errman_IsErrorHandlerConfigured(eo_errman_GetHandle())) { // ok ... use the error manager, either in its simple form or in its networked form eOerrmanDescriptor_t errdes = {0}; errdes.code = eoerror_code_get(eoerror_category_System, eoerror_value_SYS_halerror); errdes.par16 = errorcode; errdes.par64 = 0; errdes.sourcedevice = eo_errman_sourcedevice_localboard; errdes.sourceaddress = 0; eo_errman_Error(eo_errman_GetHandle(), (hal_fatalerror_warning == errorcode) ? eo_errortype_warning : eo_errortype_fatal, errormsg, "HAL", &errdes); } else { if(NULL != errormsg) { hal_trace_puts(errormsg); } if(hal_fatalerror_warning == errorcode) { return; } // in case of fatal error we blink all leds but led0 hal_led_init(hal_led0, NULL); hal_led_init(hal_led1, NULL); hal_led_init(hal_led2, NULL); hal_led_init(hal_led3, NULL); hal_led_init(hal_led4, NULL); hal_led_init(hal_led5, NULL); hal_led_off(hal_led0); hal_led_off(hal_led1); hal_led_off(hal_led2); hal_led_off(hal_led3); hal_led_off(hal_led4); hal_led_off(hal_led5); for(;;) { hal_sys_delay(100); //hal_led_toggle(hal_led0); hal_led_toggle(hal_led1); hal_led_toggle(hal_led2); hal_led_toggle(hal_led3); hal_led_toggle(hal_led4); hal_led_toggle(hal_led5); } } }
void main(void) { halMcuInit(); hal_led_init(); hal_uart_init(); //Uart0Init(0, 0); printf("s rssi: d\r\n"); //Uart0Init(unsigned char StopBits,unsigned char Parity) if (FAILED == halRfInit()) { HAL_ASSERT(FALSE); } // Config basicRF basicRfConfig.panId = PAN_ID; basicRfConfig.channel = RF_CHANNEL; basicRfConfig.ackRequest = TRUE; #ifdef SECURITY_CCM basicRfConfig.securityKey = key; #endif // Initialize BasicRF #if NODE_TYPE basicRfConfig.myAddr = SEND_ADDR; #else basicRfConfig.myAddr = RECV_ADDR; #endif if(basicRfInit(&basicRfConfig)==FAILED) { HAL_ASSERT(FALSE); } #if NODE_TYPE //uWaveInit(); dht11_io_init(); rfSendData(); #else rfRecvData(); #endif }
static void s_hal_core_cfg_on_fatalerror(hal_fatalerror_t errorcode, const char * errormsg) { errorcode = errorcode; if(NULL != errormsg) { hal_trace_puts(errormsg); } if(hal_fatalerror_warning == errorcode) { return; } hal_led_init(hal_led3, NULL); for(;;) { hal_sys_delay(200*1000); hal_led_toggle(hal_led3); } }
void main(void) { halMcuInit(); hal_led_init(); hal_uart_init(); printf("你知道串口是正常的.....\r\n"); if (FAILED == halRfInit()) { HAL_ASSERT(FALSE); } // Config basicRF basicRfConfig.panId = PAN_ID; basicRfConfig.channel = RF_CHANNEL; basicRfConfig.ackRequest = TRUE; #ifdef SECURITY_CCM basicRfConfig.securityKey = key; #endif // Initialize BasicRF #if NODE_TYPE basicRfConfig.myAddr = SEND_ADDR; #else basicRfConfig.myAddr = RECV_ADDR; #endif if(basicRfInit(&basicRfConfig)==FAILED) { HAL_ASSERT(FALSE); } #if NODE_TYPE dht11_io_init(); InitialT1test(); rfSendData(); #else printf("接收数据\r\n"); rfRecvData(); #endif }
static void overridden_appl_led_error_init(void) { // marco.accame: we init all the leds and we switch them off hal_led_init(hal_led0, NULL); hal_led_init(hal_led1, NULL); hal_led_init(hal_led2, NULL); hal_led_init(hal_led3, NULL); hal_led_init(hal_led4, NULL); hal_led_init(hal_led5, NULL); hal_led_off(hal_led0); hal_led_off(hal_led1); hal_led_off(hal_led2); hal_led_off(hal_led3); hal_led_off(hal_led4); hal_led_off(hal_led5); }
static void s_hal_cfg_on_fatalerror(hal_fatalerror_t errorcode, const char * errormsg) { errorcode = errorcode; if(NULL != errormsg) { hal_trace_puts(errormsg); } if(hal_fatalerror_warning == errorcode) { return; } hal_led_init(hal_led2, NULL); for(;;) { uint32_t volatile i = 0x100000; for(;i--; i>1); hal_led_toggle(hal_led2); } }