/** * This brings up enough clocks to allow the processor to run quickly while initialising memory. * Other platform specific clock init can be done in init_platform() or init_architecture() */ WEAK void init_clocks( void ){ /** This brings up enough clocks to allow the processor to run quickly while initialising memory. * Other platform specific clock init can be done in init_platform() or init_architecture() */ //LPC54xx clock initialized in SystemInit(). #ifdef BOOTLOADER LPC_SYSCTL->SYSAHBCLKCTRL[0] |= 0x00000018; // Magicoe #if defined(__FPU_PRESENT) && __FPU_PRESENT == 1 fpuInit(); #endif #if defined(NO_BOARD_LIB) /* Chip specific SystemInit */ Chip_SystemInit(); #else /* Enable RAM 2 clock */ Chip_Clock_EnablePeriphClock(SYSCTL_CLOCK_SRAM2); /* Board specific SystemInit */ Board_SystemInit(); //init pin muxing and clock. #endif LPC_SYSCTL->SYSAHBCLKCTRL[0] |= 0x00000018; // Magicoe Chip_SYSCTL_PowerUp(PDRUNCFG_PD_IRC_OSC_EN|PDRUNCFG_PD_IRC_EN); /* Configure PIN0.21 as CLKOUT with pull-up, monitor the MAINCLK on scope */ Chip_IOCON_PinMuxSet(LPC_IOCON, 0, 21, IOCON_MODE_PULLUP | IOCON_FUNC1 | IOCON_DIGITAL_EN | IOCON_INPFILT_OFF); Chip_Clock_SetCLKOUTSource(SYSCTL_CLKOUTSRC_RTC, 1); Chip_Clock_EnableRTCOsc(); Chip_RTC_Init(LPC_RTC); Chip_RTC_Enable1KHZ(LPC_RTC); Chip_RTC_Enable(LPC_RTC); #endif }
void Board_RTC_Init(void) { Chip_RTC_Init(LPC_RTC); rtcCallback=NULL; Chip_RTC_CntIncrIntConfig(LPC_RTC,0, DISABLE); NVIC_EnableIRQ(RTC_IRQn); }
/* Wecan Modify platform_rtc_init 2015.06.10 */ OSStatus platform_rtc_init(void) { #ifdef MICO_ENABLE_MCU_RTC /* CLKOUT = 32K_Osc */ Chip_IOCON_PinMuxSet(LPC_IOCON, platform_gpio_pins[CLKOUT].port , platform_gpio_pins[CLKOUT].pin_number, (IOCON_MODE_PULLUP | IOCON_FUNC1 | IOCON_DIGITAL_EN | IOCON_INPFILT_OFF)); Chip_Clock_SetCLKOUTSource(SYSCON_CLKOUTSRC_RTC, 1); /* Turn on the RTC 32K Oscillator */ Chip_SYSCON_PowerUp(SYSCON_PDRUNCFG_PD_32K_OSC); /* Enable the RTC oscillator, oscillator rate can be determined by calling Chip_Clock_GetRTCOscRate() */ Chip_Clock_EnableRTCOsc(); /* Initialize RTC driver (enables RTC clocking) */ Chip_RTC_Init(LPC_RTC); /* Enable RTC as a peripheral wakeup event */ //Chip_SYSCON_EnsableWakeup(SYSCON_STARTER_RTC); /* RTC reset */ Chip_RTC_Reset(LPC_RTC); /* Start RTC at a count of 0 when RTC is disabled. If the RTC is enabled, you need to disable it before setting the initial RTC count. */ Chip_RTC_Disable(LPC_RTC); platform_rtc_set_time(&default_rtc_time); //Chip_RTC_SetCount(LPC_RTC, 0); /* Set a long alarm time so the interrupt won't trigger */ //Chip_RTC_SetAlarm(LPC_RTC, (Chip_RTC_GetCount(LPC_RTC) + 5)); /* Enable RTC and high resolution timer - this can be done in a single call with Chip_RTC_EnableOptions(LPC_RTC, (RTC_CTRL_RTC1KHZ_EN | RTC_CTRL_RTC_EN)); */ //Chip_RTC_Enable1KHZ(LPC_RTC); Chip_RTC_Enable(LPC_RTC); /* Clear latched RTC interrupt statuses */ Chip_RTC_ClearStatus(LPC_RTC, (RTC_CTRL_OFD | RTC_CTRL_ALARM1HZ | RTC_CTRL_WAKE1KHZ)); return kNoErr; #else return kUnsupportedErr; #endif }
// Set the current time given a time string in the format // 2015-02-21 05:57:00 void setTime(char *timeStr){ // Enable and configure Real-Time Clock Chip_Clock_EnableRTCOsc(); Chip_RTC_Init(LPC_RTC); // Set time in human readable form struct tm tm; time_t t = 0; tm = *localtime(&t); sscanf(timeStr, "%u-%u-%u %u:%u:%u", &(tm.tm_year), &(tm.tm_mon), &(tm.tm_mday), &(tm.tm_hour), &(tm.tm_min), &(tm.tm_sec)); tm.tm_year -= 1900; tm.tm_mon -= 1; tm.tm_isdst = 0; // No DST accounting t = mktime(&tm); Chip_RTC_Reset(LPC_RTC); // Set then clear SWRESET bit Chip_RTC_SetCount(LPC_RTC, t); // Set the time Chip_RTC_Enable(LPC_RTC); // Start counting log_string("Time Set"); }
/* * @Brief: Configure RTC peripheral. * @param RTC_t rtc: RTC structure * @return bool_t true (1) if config it is ok */ bool_t rtcConfig( RTC_t * rtc ){ bool_t ret_val = 1; static bool_t init; RTC_TIME_T rtcTime; if( init ){ /* Already initialized */ ret_val = 0; } else { /* RTC Block section ------------------------- */ Chip_RTC_Init(LPC_RTC); /* Set current time for RTC */ /* Current time is 22:00:00 , 2016-07-02 */ /* rtcTime.time[RTC_TIMETYPE_SECOND] = 0; rtcTime.time[RTC_TIMETYPE_MINUTE] = 0; rtcTime.time[RTC_TIMETYPE_HOUR] = 22; rtcTime.time[RTC_TIMETYPE_DAYOFMONTH] = 2; rtcTime.time[RTC_TIMETYPE_MONTH] = 7; rtcTime.time[RTC_TIMETYPE_YEAR] = 2016; Chip_RTC_SetFullAlarmTime(LPC_RTC, &rtcTime); */ rtcWrite( rtc ); /* Enable rtc (starts increase the tick counter and second counter register) */ Chip_RTC_Enable(LPC_RTC, ENABLE); init = 1; } return ret_val; }
/** * @brief Main program body * @return int */ int main(void) { CHIP_PMU_MCUPOWER_T crntPowerSetting; /* Setup SystemCoreClock and any needed board code */ SystemCoreClockUpdate(); Board_Init(); Board_LED_Set(0, true); /* Clear any previously set deep power down and sleep flags */ Chip_PMU_ClearSleepFlags(LPC_PMU, PMU_PCON_SLEEPFLAG | PMU_PCON_DPDFLAG); /* Enable the RTC oscillator, oscillator rate can be determined by calling Chip_Clock_GetRTCOscRate() */ Chip_Clock_EnableRTCOsc(); /* Initialize RTC driver (enables RTC clocking) */ Chip_RTC_Init(LPC_RTC); /* RTC reset */ Chip_RTC_Reset(LPC_RTC); /* Start RTC at a count of 0 when RTC is disabled. If the RTC is enabled, you need to disable it before setting the initial RTC count. */ Chip_RTC_Disable(LPC_RTC); Chip_RTC_SetCount(LPC_RTC, 0); /* Set a long alarm time so the interrupt won't trigger */ Chip_RTC_SetAlarm(LPC_RTC, 1000); /* Enable RTC */ Chip_RTC_Enable(LPC_RTC); /* Clear latched RTC interrupt statuses */ Chip_RTC_ClearStatus(LPC_RTC, (RTC_CTRL_OFD | RTC_CTRL_ALARM1HZ | RTC_CTRL_WAKE1KHZ)); /* Enable RTC interrupt */ NVIC_EnableIRQ(RTC_ALARM_IRQn); /* Enable RTC alarm interrupt */ Chip_RTC_EnableWakeup(LPC_RTC, RTC_CTRL_ALARMDPD_EN); /* Output example's activity banner */ DEBUGSTR("\r\n"); DEBUGSTR("-----------------------------------------------------------------\r\n"); #ifdef RESET_POWER_CYCLE_COUNT ProcessCycleCounter(); DEBUGOUT("Power Control Example\r\n"); #else DEBUGOUT("Power Control Example Cycle Count: %d\r\n", ProcessCycleCounter()); #endif DEBUGSTR(" System will cycle through SLEEP, DEEP SLEEP, POWER\r\n"); DEBUGSTR(" DOWN, and DEEP POWER DOWN power states\r\n"); DEBUGSTR("-----------------------------------------------------------------\r\n\r\n"); /* Setup alarm, process next power state then wait for alarm to wake-up system */ crntPowerSetting = PMU_MCU_SLEEP; while (1) { /* Set alarm to wakeup in POWER_CYCLE_SEC_DELAY seconds */ Chip_RTC_SetAlarm(LPC_RTC, Chip_RTC_GetCount(LPC_RTC) + POWER_CYCLE_SEC_DELAY); /* Enter first (or next) power state */ ProcessPowerState(crntPowerSetting); /* Inc current power setting and test for overflow */ if (crntPowerSetting == PMU_MCU_DEEP_PWRDOWN) { /* Reset to lowest power setting */ crntPowerSetting = PMU_MCU_SLEEP; } else { crntPowerSetting++; } } return 0; }
/** * @brief Main program body * @return int */ int main(void) { uint32_t rtcCount; /* Starting time for this example used to set the RTC */ struct tm startTime = { 56, /* tm_sec, seconds after the minute, 0 to 59 */ 59, /* tm_min, minutes after the hour, 0 to 59 */ 23, /* tm_hour, hours since midnight, 0 to 23 */ 25, /* tm_mday, day of the month, 1 to 31 */ 9, /* tm_mon, months since January, 0 to 11 */ (2014 - TM_YEAR_BASE), /* tm_year, years since base year (1900) */ /* The following 3 fields are not used by the ConvertTimeRtc() function, while the ConvertRtcTime() fucntion will generate data in them from an RTC tick (except tm_isdst) */ 0, /* tm_wday, days since Sunday, 0 to 6 */ 0, /* tm_yday, days since January 1, 0 to 365 */ 0 /* tm_isdst, Daylight Savings Time flag */ }; /* Setup SystemCoreClock and any needed board code */ SystemCoreClockUpdate(); Board_Init(); Board_LED_Set(0, false); /* Turn on the RTC 32K Oscillator */ Chip_SYSCON_PowerUp(SYSCON_PDRUNCFG_PD_32K_OSC); /* Enable the RTC oscillator, oscillator rate can be determined by calling Chip_Clock_GetRTCOscRate() */ Chip_Clock_EnableRTCOsc(); /* Initialize RTC driver (enables RTC clocking) */ Chip_RTC_Init(LPC_RTC); /* RTC reset */ Chip_RTC_Reset(LPC_RTC); /* Start RTC at a count of 0 when RTC is disabled. If the RTC is enabled, you need to disable it before setting the initial RTC count. */ Chip_RTC_Disable(LPC_RTC); /* COnvert tm structure to RTC tick count */ ConvertTimeRtc(&startTime, &rtcCount); Chip_RTC_SetCount(LPC_RTC, rtcCount); /* Set alarm to wakeup in 5s */ DEBUGOUT("Setting alarm to trigger in 5s\r\n"); rtcCount += 5; Chip_RTC_SetAlarm(LPC_RTC, rtcCount); /* Enable RTC */ Chip_RTC_Enable(LPC_RTC); /* Clear latched RTC interrupt statuses */ Chip_RTC_ClearStatus(LPC_RTC, (RTC_CTRL_OFD | RTC_CTRL_ALARM1HZ | RTC_CTRL_WAKE1KHZ)); /* Enable RTC interrupt */ NVIC_EnableIRQ(RTC_IRQn); /* Enable RTC alarm interrupt */ Chip_RTC_EnableWakeup(LPC_RTC, (RTC_CTRL_ALARMDPD_EN | RTC_CTRL_WAKEDPD_EN)); /* Sleep and do all the work in the RTC interrupt handler */ while (1) { /* 10 high resolution ticks that get slower each tick */ if (rtcAlarm) { /* Will not reset alarm */ DEBUGOUT("Alarm triggered, alarm reset to trigger in 5s\r\n"); rtcCount = Chip_RTC_GetCount(LPC_RTC) + 5; Chip_RTC_SetAlarm(LPC_RTC, rtcCount); rtcAlarm = false; } /* Show RTC time in UT format */ showTime(Chip_RTC_GetCount(LPC_RTC)); /* Sleep while waiting for alarm */ __WFI(); } return 0; }
/** * @brief Main program body * @return int */ int main(void) { int stateCounter = 0; /* Setup SystemCoreClock and any needed board code */ SystemCoreClockUpdate(); Board_Init(); Board_LED_Set(0, false); /* Turn on the RTC 32K Oscillator by clearing the power down bit */ if ( !Is_Chip_SYSCTL_PowerUp(PDRUNCFG_PD_32K_OSC) ) { Chip_SYSCTL_PowerUp(PDRUNCFG_PD_32K_OSC); } /* Enable the RTC oscillator, oscillator rate can be determined by calling Chip_Clock_GetRTCOscRate() */ Chip_Clock_EnableRTCOsc(); /* Initialize RTC driver (enables RTC clocking) */ Chip_RTC_Init(LPC_RTC); /* Enable RTC as a peripheral wakeup event */ Chip_SYSCTL_EnableWakeup(STARTERP0_RTC); /* RTC reset */ Chip_RTC_Reset(LPC_RTC); /* Start RTC at a count of 0 when RTC is disabled. If the RTC is enabled, you need to disable it before setting the initial RTC count. */ Chip_RTC_Disable(LPC_RTC); Chip_RTC_SetCount(LPC_RTC, 0); /* Set a long alarm time so the interrupt won't trigger */ Chip_RTC_SetAlarm(LPC_RTC, 1000); /* Enable RTC and high resolution timer - this can be done in a single call with Chip_RTC_EnableOptions(LPC_RTC, (RTC_CTRL_RTC1KHZ_EN | RTC_CTRL_RTC_EN)); */ Chip_RTC_Enable1KHZ(LPC_RTC); Chip_RTC_Enable(LPC_RTC); /* Clear latched RTC interrupt statuses */ Chip_RTC_ClearStatus(LPC_RTC, (RTC_CTRL_OFD | RTC_CTRL_ALARM1HZ | RTC_CTRL_WAKE1KHZ)); /* Enable RTC interrupt */ NVIC_EnableIRQ(RTC_IRQn); /* Enable RTC alarm interrupt */ Chip_RTC_EnableWakeup(LPC_RTC, (RTC_CTRL_ALARMDPD_EN | RTC_CTRL_WAKEDPD_EN)); /* Sleep and do all the work in the RTC interrupt handler */ while (1) { DEBUGOUT("Tick number: %d, 1KHZ int:%d, alarm int:%d\r\n", stateCounter, rtcWake, rtcAlarm); rtcWake = rtcAlarm = false; /* 10 high resolution ticks that get slower each tick */ if (stateCounter < 10) { /* Wakeup in 300, 400, 500, etc. milliSeconds */ Chip_RTC_SetWake(LPC_RTC, (300 + (stateCounter * 100))); stateCounter++; } else { DEBUGOUT("Setting alarm to wake up in 4s\r\n"); /* Set alarm to wakeup in 4 seconds */ Chip_RTC_SetAlarm(LPC_RTC, Chip_RTC_GetCount(LPC_RTC) + 4); stateCounter = 0; } // FIXME - Use ROM API's to put chip to power down modes /* LPC_PWRD_API->power_mode_configure(PMU_DEEP_POWERDOWN, PDRUNCFG_PD_32K_OSC, 1); */ __WFI(); } return 0; }
/** * @brief main routine for example_lwip_tcpecho_freertos_18xx43xx * @return Function should not exit */ int main(void) { prvSetupHardware(); Chip_RTC_Init(); /*Set current time for RTC 8:59:20PM, 2016-04-11 MONDAY 102*/ FullTime.time[RTC_TIMETYPE_SECOND] = 40; FullTime.time[RTC_TIMETYPE_MINUTE] = 59; FullTime.time[RTC_TIMETYPE_HOUR] = 8; FullTime.time[RTC_TIMETYPE_DAYOFMONTH] = 11; FullTime.time[RTC_TIMETYPE_DAYOFWEEK] = 1; FullTime.time[RTC_TIMETYPE_DAYOFYEAR] = 102; FullTime.time[RTC_TIMETYPE_MONTH] = 04; FullTime.time[RTC_TIMETYPE_YEAR] = 2016; Chip_RTC_SetFullTime(&FullTime); /* Set the RTC to generate an interrupt on each second */ Chip_RTC_CntIncrIntConfig(RTC_AMR_CIIR_IMSEC, ENABLE); /* Enable matching for alarm for second, minute, hour fields only */ Chip_RTC_AlarmIntConfig(RTC_AMR_CIIR_IMSEC | RTC_AMR_CIIR_IMMIN | RTC_AMR_CIIR_IMHOUR, ENABLE); /* Enable RTC interrupt in NVIC */ NVIC_EnableIRQ((IRQn_Type) RTC_IRQn); /* Enable RTC (starts increase the tick counter and second counter register) */ Chip_RTC_Enable(ENABLE); //DIFFERENZA TRA GIORNI IP_RTC_TIME_T data1 = FullTime, data2, diffDate; uint32_t nGiorniDifferenza; data2.time[RTC_TIMETYPE_SECOND] = 40; data2.time[RTC_TIMETYPE_MINUTE] = 59; data2.time[RTC_TIMETYPE_HOUR] = 7;//23;//8; data2.time[RTC_TIMETYPE_DAYOFMONTH] = 12; data2.time[RTC_TIMETYPE_DAYOFWEEK] = 2; data2.time[RTC_TIMETYPE_DAYOFYEAR] = 103; data2.time[RTC_TIMETYPE_MONTH] = 04; data2.time[RTC_TIMETYPE_YEAR] = 2016;//2017; diffDate = differenzaDate(data2, data1); nGiorniDifferenza = differenzaGiorni(data2, data1); uint8_t counter = 0; ptrMedic = inizializzaListaMed(); for(counter = 0; counter < maxR; counter++){ if (l_tabellaMedicine[counter][65]==0) { //se più volte al giorno == 0 if (l_tabellaMedicine[counter][59]==0) { ptrMedic = inserisciInTestaListaMed(ptrMedic, l_tabellaMedicine[counter]); } else { if (l_tabellaMedicine[counter][58] == 0) { //DA ASSUMERE ptrMedic = inserisciInTestaListaMed(ptrMedic, l_tabellaMedicine[counter]); l_tabellaMedicine[counter][58] ++; } else { l_tabellaMedicine[counter][58] ++; if (l_tabellaMedicine[counter][58] = l_tabellaMedicine[counter][59]) { l_tabellaMedicine[counter][58] = 0; } } } } else { //conta quante volte prendere la medicina if (l_tabellaMedicine[counter][65]==1) { //controlla la ripetizione Chip_RTC_GetFullTime(&FullTime); IP_RTC_TIME_T dataIn; dataIn.time[RTC_TIMETYPE_DAYOFMONTH] = l_tabellaMedicine[counter][43]; dataIn.time[RTC_TIMETYPE_MONTH] = l_tabellaMedicine[counter][44]; dataIn.time[RTC_TIMETYPE_YEAR] = (l_tabellaMedicine[counter][45]<<8) | l_tabellaMedicine[counter][46]; int oraInizio = l_tabellaMedicine[counter][51]; int intervalloOre = l_tabellaMedicine[counter][57]; if (FullTime.time[RTC_TIMETYPE_DAYOFMONTH]==dataIn.time[RTC_TIMETYPE_DAYOFMONTH] && FullTime.time[RTC_TIMETYPE_MONTH]==dataIn.time[RTC_TIMETYPE_MONTH] && FullTime.time[RTC_TIMETYPE_YEAR]==dataIn.time[RTC_TIMETYPE_YEAR]) { //E' il giorno di inizio e lascio l'ora iniziale invariata oraInizio = oraInizio; } else { int go = 1; while (go){ if ((oraInizio-intervalloOre)>=0) { oraInizio = oraInizio-intervalloOre; } else { go = 0; } } } int temp = oraInizio; int contatore = 1; while ((temp+intervalloOre) < 24) { temp = temp+intervalloOre; contatore++; } int c = 0; IP_RTC_TIME_T oraMed; oraMed.time[RTC_TIMETYPE_HOUR] = oraInizio; oraMed.time[RTC_TIMETYPE_MINUTE] = l_tabellaMedicine[counter][52]; oraMed.time[RTC_TIMETYPE_SECOND] = l_tabellaMedicine[counter][53]; for (c=0; c<contatore; c++) { ptrMedic = inserisciInTestaListaMedOra(ptrMedic, l_tabellaMedicine[counter], oraMed); oraMed.time[RTC_TIMETYPE_HOUR] += intervalloOre; } } else { //orari custom int n = l_tabellaMedicine[counter][65]; int c = 0; IP_RTC_TIME_T oraMed; oraMed.time[RTC_TIMETYPE_HOUR] = l_tabellaMedicine[counter][51]; oraMed.time[RTC_TIMETYPE_MINUTE] = l_tabellaMedicine[counter][52]; oraMed.time[RTC_TIMETYPE_SECOND] = l_tabellaMedicine[counter][53]; ptrMedic = inserisciInTestaListaMedOra(ptrMedic, l_tabellaMedicine[counter], oraMed); for (c=0; c<n-1; c++) { oraMed.time[RTC_TIMETYPE_HOUR] = l_tabellaMedicine[counter][66+3*c]; oraMed.time[RTC_TIMETYPE_MINUTE] = l_tabellaMedicine[counter][67+3*c]; oraMed.time[RTC_TIMETYPE_SECOND] = l_tabellaMedicine[counter][68+3*c]; ptrMedic = inserisciInTestaListaMedOra(ptrMedic, l_tabellaMedicine[counter], oraMed); } } } } ptrMedic = ordinamento_lista_med(ptrMedic); //Inizio dall'orario attuale e non considero tutti i medicinali precedenti in giornata IP_RTC_TIME_T oraAllarme; oraAllarme.time[RTC_TIMETYPE_HOUR] = ptrMedic->oraA; oraAllarme.time[RTC_TIMETYPE_MINUTE] = ptrMedic->minA; oraAllarme.time[RTC_TIMETYPE_SECOND] = ptrMedic->secA; while (orarioDopoOrario(FullTime, oraAllarme)) { ptrMedic = ptrMedic->next; oraAllarme.time[RTC_TIMETYPE_HOUR] = ptrMedic->oraA; oraAllarme.time[RTC_TIMETYPE_MINUTE] = ptrMedic->minA; oraAllarme.time[RTC_TIMETYPE_SECOND] = ptrMedic->secA; } FullTime.time[RTC_TIMETYPE_HOUR] = oraAllarme.time[RTC_TIMETYPE_HOUR];//ptrMedic->oraA; FullTime.time[RTC_TIMETYPE_MINUTE] = oraAllarme.time[RTC_TIMETYPE_MINUTE];//ptrMedic->minA; FullTime.time[RTC_TIMETYPE_SECOND] = oraAllarme.time[RTC_TIMETYPE_SECOND];//ptrMedic->secA; Chip_RTC_SetFullAlarmTime(&FullTime); // CICLO FOR PER LEGGERE TUTTI I BIT DI UN BYTE // unsigned bit=0, n_bits = 4u, *bits = (unsigned*)malloc(sizeof(unsigned) * n_bits); // for (bit = 0; bit < n_bits; ++bit, input >>1) // bits[bit] = input & 1; uint8_t i; for (i=0;i<35;i++){ //char t = (char)m1[4+i]; //nomeMed[i]=t; arrNomiMed[i]=l_tabellaMedicine[0][4+i]; } nomeMed=&arrNomiMed; vSemaphoreCreateBinary( xSemaDataAvail ); vSemaphoreCreateBinary( xSemaGUIend ); /* xTaskCreate(vTSCTask, (signed char *) "vTSCTask", configMINIMAL_STACK_SIZE, NULL, TASK_PRIO_TOUCHSCREEN, (xTaskHandle *) NULL); */ /* BASIC ONE xTaskCreate(vLcdTask, (signed char *) "vLCDTask", configMINIMAL_STACK_SIZE * 4, NULL, TASK_PRIO_LCD, (xTaskHandle *) NULL); */ xTaskCreate(vLcdTaskNew, (signed char *) "vLCDTaskNew", configMINIMAL_STACK_SIZE * 4, NULL, TASK_PRIO_LCD, (xTaskHandle *) NULL); /* Add another thread for initializing physical interface. This is delayed from the main LWIP initialization. */ /* xTaskCreate(vSetupIFTask, (signed char *) "SetupIFx", configMINIMAL_STACK_SIZE, NULL, (tskIDLE_PRIORITY + 1UL), (xTaskHandle *) NULL); */ xTaskCreate(vSetupPollTask, (signed char *) "SetupPoll", configMINIMAL_STACK_SIZE*4, NULL, (tskIDLE_PRIORITY + 1UL), (xTaskHandle *) NULL); /* xTaskCreate(vRTCTask, (signed char *) "RTCTask", configMINIMAL_STACK_SIZE*4, NULL, (tskIDLE_PRIORITY + 2UL), (xTaskHandle *) NULL); */ /* Start the scheduler */ vTaskStartScheduler(); /* Should never arrive here */ return 1; }
/** * Power State handler function */ static void PMC_PwrState_Handler(uint8_t buffer, uint8_t Wake_RTC) { CHIP_EVRT_SRC_T Evrt_Src; CHIP_PMC_PWR_STATE_T Pwr_state; uint8_t confirm = 0xFF; if (Wake_RTC) { /* Configure EVRT_SRC_RTC as wake up signal */ Evrt_Src = EVRT_SRC_RTC; /* Disable interrupt signal from Evrt_Src pin to EVRT */ Chip_EVRT_SetUpIntSrc(Evrt_Src, DISABLE); /* Initialize and configure RTC */ Chip_RTC_Init(LPC_RTC); Chip_RTC_ResetClockTickCounter(LPC_RTC); Chip_RTC_SetTime(LPC_RTC, RTC_TIMETYPE_SECOND, 0); /* Set alarm time = RTC_ALARM_TIME seconds. * So after each RTC_ALARM_TIME seconds, RTC will generate and wake-up system */ Chip_RTC_SetAlarmTime(LPC_RTC, RTC_TIMETYPE_SECOND, RTC_ALARM_TIME); Chip_RTC_CntIncrIntConfig(LPC_RTC, RTC_AMR_CIIR_IMSEC, DISABLE); /* Set the AMR for RTC_ALARM_TIME match alarm interrupt */ Chip_RTC_AlarmIntConfig(LPC_RTC, RTC_AMR_CIIR_IMSEC, ENABLE); Chip_RTC_ClearIntPending(LPC_RTC, RTC_INT_ALARM); } else { Evrt_Src = EVRT_SRC_WAKEUP0; } /* Configure wake up signal */ PMC_Evrt_Configure(Evrt_Src); /* Get confirmation from user to continue * Print wake up signal information to user */ DEBUGOUT(menu3); while ( (confirm != 'C') && (confirm != 'c')) { confirm = DEBUGIN(); } switch (buffer) { case '1': DEBUGOUT("Entering 'Sleep' state ...\r\n"); if (Wake_RTC) { DEBUGOUT("Wait for %d seconds, RTC alarm will wake up from 'Sleep' mode \r\n", RTC_ALARM_TIME); Chip_RTC_Enable(LPC_RTC, ENABLE); } else { DEBUGOUT("Press WAKEUP0 button/Connect WAKEUP0 pin to 3.3V to exit 'Sleep' mode \r\n"); } Chip_PMC_Sleep(); Chip_RTC_DeInit(LPC_RTC); DEBUGOUT("Woken up \r\n"); break; case '2': DEBUGOUT("Entering 'Deep Sleep' state ...\r\n"); if (Wake_RTC) { DEBUGOUT("Wait for %d seconds, RTC alarm will wake up from 'Deep Sleep' mode \r\n", RTC_ALARM_TIME); Chip_RTC_Enable(LPC_RTC, ENABLE); } else { DEBUGOUT("Press WAKEUP0 button/Connect WAKEUP0 pin to 3.3V to exit 'Deep Sleep' mode \r\n"); } Pwr_state = PMC_DeepSleep; /* Call Pre SleepPowerDown function */ PMC_Pre_SleepPowerDown(); /* Goto Deep Sleep mode */ Chip_PMC_Set_PwrState(Pwr_state); /* Call Post Wake up Initialisation function */ PMC_Post_Wakeup(buffer); DEBUGOUT("\r\nWoken up \r\n"); break; case '3': DEBUGOUT("Entering 'Power Down' state ...\r\n"); if (Wake_RTC) { DEBUGOUT("Wait for %d seconds, RTC alarm will wake up from 'Power Down' mode \r\n", RTC_ALARM_TIME); Chip_RTC_Enable(LPC_RTC, ENABLE); } else { DEBUGOUT("Press WAKEUP0 button/Connect WAKEUP0 pin to 3.3V to exit 'Power Down' mode \r\n"); } Pwr_state = PMC_PowerDown; /* Call Pre SleepPowerDown function */ PMC_Pre_SleepPowerDown(); /* Goto Deep Sleep mode */ Chip_PMC_Set_PwrState(Pwr_state); /* Call Post Wake up Initialisation function */ PMC_Post_Wakeup(buffer); DEBUGOUT("\r\nWoken up \r\n"); break; case '4': DEBUGOUT("Entering 'Deep Power Down' state ...\r\n"); if (Wake_RTC) { DEBUGOUT("Wait for %d seconds, RTC alarm will wake up from 'Deep Power Down' mode \r\n", RTC_ALARM_TIME); Chip_RTC_Enable(LPC_RTC, ENABLE); } else { DEBUGOUT("Press WAKEUP0 button/Connect WAKEUP0 pin to 3.3V to exit 'Deep Power Down' mode \r\n"); } Pwr_state = PMC_DeepPowerDown; /* Call Pre SleepPowerDown function */ PMC_Pre_SleepPowerDown(); /* Goto Deep Sleep mode */ Chip_PMC_Set_PwrState(Pwr_state); /* Wake up from Deep power down state is as good as RESET */ while (1) {} break; default: break; } }
/** * @brief Main entry point * @return Nothing */ int main(void) { RTC_TIME_T FullTime; SystemCoreClockUpdate(); Board_Init(); fIntervalReached = 0; fAlarmTimeMatched = 0; On0 = On1 = false; Board_LED_Set(2, false); DEBUGSTR("The RTC operates on a 1 Hz clock.\r\n" \ "Register writes can take up to 2 cycles.\r\n" \ "It will take a few seconds to fully\r\n" \ "initialize it and start it running.\r\n\r\n"); DEBUGSTR("We'll print a timestamp every 5 seconds.\r\n" \ "...and another when the alarm occurs.\r\n"); Chip_RTC_Init(LPC_RTC); /* Set current time for RTC 2:00:00PM, 2012-10-05 */ FullTime.time[RTC_TIMETYPE_SECOND] = 0; FullTime.time[RTC_TIMETYPE_MINUTE] = 0; FullTime.time[RTC_TIMETYPE_HOUR] = 14; FullTime.time[RTC_TIMETYPE_DAYOFMONTH] = 5; FullTime.time[RTC_TIMETYPE_DAYOFWEEK] = 5; FullTime.time[RTC_TIMETYPE_DAYOFYEAR] = 279; FullTime.time[RTC_TIMETYPE_MONTH] = 10; FullTime.time[RTC_TIMETYPE_YEAR] = 2012; Chip_RTC_SetFullTime(LPC_RTC, &FullTime); /* Set ALARM time for 17 seconds from time */ FullTime.time[RTC_TIMETYPE_SECOND] = 17; Chip_RTC_SetFullAlarmTime(LPC_RTC, &FullTime); /* Set the RTC to generate an interrupt on each second */ Chip_RTC_CntIncrIntConfig(LPC_RTC, RTC_AMR_CIIR_IMSEC, ENABLE); /* Enable matching for alarm for second, minute, hour fields only */ Chip_RTC_AlarmIntConfig(LPC_RTC, RTC_AMR_CIIR_IMSEC | RTC_AMR_CIIR_IMMIN | RTC_AMR_CIIR_IMHOUR, ENABLE); /* Clear interrupt pending */ Chip_RTC_ClearIntPending(LPC_RTC, RTC_INT_COUNTER_INCREASE | RTC_INT_ALARM); /* Enable RTC interrupt in NVIC */ NVIC_EnableIRQ((IRQn_Type) RTC_IRQn); /* Enable RTC (starts increase the tick counter and second counter register) */ Chip_RTC_Enable(LPC_RTC, ENABLE); /* Loop forever */ while (1) { if (fIntervalReached) { /* Every 5s */ fIntervalReached = 0; On1 = (bool) !On1; Board_LED_Set(1, On1); /* read and display time */ Chip_RTC_GetFullTime(LPC_RTC, &FullTime); showTime(&FullTime); } if (fAlarmTimeMatched) { fAlarmTimeMatched = false; /* announce event */ DEBUGSTR("ALARM triggered!\r\n"); Board_LED_Set(2, true); /* read and display time */ Chip_RTC_GetFullTime(LPC_RTC, &FullTime); showTime(&FullTime); } } }
/** * @brief Main program body * @return int */ int main(void) { int stateCounter = 0; uint32_t ticks = 0; /* Setup SystemCoreClock and any needed board code */ SystemCoreClockUpdate(); Board_Init(); /* Enable the RTC oscillator, oscillator rate can be determined by calling Chip_Clock_GetRTCOscRate() */ Chip_Clock_EnableRTCOsc(); /* Initialize RTC driver (enables RTC clocking) */ Chip_RTC_Init(LPC_RTC); /* Enable RTC as a peripheral wakeup event */ Chip_SYSCTL_EnableERP1PeriphWakeup(SYSCTL_ERP1_WAKEUP_RTCALARMINT | SYSCTL_ERP1_WAKEUP_RTCWAKEINT); /* RTC reset */ Chip_RTC_Reset(LPC_RTC); /* Start RTC at a count of 0 when RTC is disabled. If the RTC is enabled, you need to disable it before setting the initial RTC count. */ Chip_RTC_Disable(LPC_RTC); Chip_RTC_SetCount(LPC_RTC, 0); /* Set a long alarm time so the interrupt won't trigger */ Chip_RTC_SetAlarm(LPC_RTC, 1000); /* Enable RTC and high resolution timer - this can be done in a single call with Chip_RTC_EnableOptions(LPC_RTC, (RTC_CTRL_RTC1KHZ_EN | RTC_CTRL_RTC_EN)); */ Chip_RTC_Enable1KHZ(LPC_RTC); Chip_RTC_Enable(LPC_RTC); /* Clear latched RTC interrupt statuses */ Chip_RTC_ClearStatus(LPC_RTC, (RTC_CTRL_OFD | RTC_CTRL_ALARM1HZ | RTC_CTRL_WAKE1KHZ)); /* Enable RTC wake and alarm interrupts */ NVIC_EnableIRQ(RTC_ALARM_IRQn); NVIC_EnableIRQ(RTC_WAKE_IRQn); /* Enable RTC alarm interrupt */ Chip_RTC_EnableWakeup(LPC_RTC, (RTC_CTRL_ALARMDPD_EN | RTC_CTRL_WAKEDPD_EN)); /* Sleep and do all the work in the RTC interrupt handler */ while (1) { ticks = 0; DEBUGOUT("Tick number: %d, 1KHZ int:%d, alarm int:%d\r\n", stateCounter, rtcWake, rtcAlarm); rtcWake = rtcAlarm = false; /* 10 high resolution ticks that get slower each tick */ if (stateCounter < 10) { /* Wakeup in 300, 400, 500, etc. milliSeconds */ Chip_RTC_SetWake(LPC_RTC, (300 + (stateCounter * 100))); stateCounter++; } else { DEBUGOUT("Setting alarm to wake up in 4s\r\n"); /* Set alarm to wakeup in 4 seconds */ Chip_RTC_SetAlarm(LPC_RTC, Chip_RTC_GetCount(LPC_RTC) + 4); stateCounter = 0; } Chip_SYSCTL_SetWakeup(~(SYSCTL_SLPWAKE_IRCOUT_PD | SYSCTL_SLPWAKE_IRC_PD | SYSCTL_SLPWAKE_FLASH_PD | SYSCTL_SLPWAKE_SYSOSC_PD | SYSCTL_SLPWAKE_SYSPLL_PD)); Chip_SYSCTL_EnableERP1PeriphWakeup(SYSCTL_ERP1_WAKEUP_RTCALARMINT | SYSCTL_ERP1_WAKEUP_RTCWAKEINT); /* Delay to allow serial transmission to complete*/ while(ticks++ < 10000) {} /* Enter MCU Deep Sleep mode */ Chip_PMU_DeepSleepState(LPC_PMU); } return 0; }