/* * This file is part of the MicroPython project, http://micropython.org/ * * The MIT License (MIT) * * Copyright (c) 2013-2018 Damien P. George * * Permission is hereby granted, free of charge, to any person obtaining a copy * of this software and associated documentation files (the "Software"), to deal * in the Software without restriction, including without limitation the rights * to use, copy, modify, merge, publish, distribute, sublicense, and/or sell * copies of the Software, and to permit persons to whom the Software is * furnished to do so, subject to the following conditions: * * The above copyright notice and this permission notice shall be included in * all copies or substantial portions of the Software. * * THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR * IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, * FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE * AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER * LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, * OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN * THE SOFTWARE. */ #include "py/mperrno.h" #include "py/mphal.h" #include "powerctrl.h" #include "rtc.h" #include "genhdr/pllfreqtable.h" #if defined(STM32H7) #define RCC_SR RSR #if defined(STM32H743xx) #define RCC_SR_SFTRSTF RCC_RSR_SFTRSTF #elif defined(STM32H747xx) #define RCC_SR_SFTRSTF RCC_RSR_SFT2RSTF #endif #define RCC_SR_RMVF RCC_RSR_RMVF // This macro returns the actual voltage scaling level factoring in the power overdrive bit. // If the current voltage scale is VOLTAGE_SCALE1 and PWER_ODEN bit is set return VOLTAGE_SCALE0 // otherwise the current voltage scaling (level VOS1 to VOS3) set in PWER_CSR is returned instead. #define POWERCTRL_GET_VOLTAGE_SCALING() \ (((PWR->CSR1 & PWR_CSR1_ACTVOS) && (SYSCFG->PWRCR & SYSCFG_PWRCR_ODEN)) ? \ PWR_REGULATOR_VOLTAGE_SCALE0 : (PWR->CSR1 & PWR_CSR1_ACTVOS)) #else #define RCC_SR CSR #define RCC_SR_SFTRSTF RCC_CSR_SFTRSTF #define RCC_SR_RMVF RCC_CSR_RMVF #endif // Location in RAM of bootloader state (just after the top of the stack) extern uint32_t _estack[]; #define BL_STATE ((uint32_t *)&_estack) static inline void powerctrl_disable_hsi_if_unused(void) { #if !MICROPY_HW_CLK_USE_HSI && (defined(STM32F4) || defined(STM32F7) || defined(STM32H7)) // Disable HSI if it's not used to save a little bit of power __HAL_RCC_HSI_DISABLE(); #endif } NORETURN void powerctrl_mcu_reset(void) { BL_STATE[1] = 1; // invalidate bootloader address #if __DCACHE_PRESENT == 1 SCB_CleanDCache(); #endif NVIC_SystemReset(); } NORETURN void powerctrl_enter_bootloader(uint32_t r0, uint32_t bl_addr) { BL_STATE[0] = r0; BL_STATE[1] = bl_addr; #if __DCACHE_PRESENT == 1 SCB_CleanDCache(); #endif NVIC_SystemReset(); } static __attribute__((naked)) void branch_to_bootloader(uint32_t r0, uint32_t bl_addr) { __asm volatile ( "ldr r2, [r1, #0]\n" // get address of stack pointer "msr msp, r2\n" // get stack pointer "ldr r2, [r1, #4]\n" // get address of destination "bx r2\n" // branch to bootloader ); } void powerctrl_check_enter_bootloader(void) { uint32_t bl_addr = BL_STATE[1]; BL_STATE[1] = 1; // invalidate bootloader address if ((bl_addr & 0xfff) == 0 && (RCC->RCC_SR & RCC_SR_SFTRSTF)) { // Reset by NVIC_SystemReset with bootloader data set -> branch to bootloader RCC->RCC_SR = RCC_SR_RMVF; #if defined(STM32F0) || defined(STM32F4) || defined(STM32L0) || defined(STM32L4) || defined(STM32WB) __HAL_SYSCFG_REMAPMEMORY_SYSTEMFLASH(); #endif uint32_t r0 = BL_STATE[0]; branch_to_bootloader(r0, bl_addr); } } #if !defined(STM32F0) && !defined(STM32L0) && !defined(STM32WB) typedef struct _sysclk_scaling_table_entry_t { uint16_t mhz; uint16_t value; } sysclk_scaling_table_entry_t; #if defined(STM32F7) STATIC const sysclk_scaling_table_entry_t volt_scale_table[] = { { 151, PWR_REGULATOR_VOLTAGE_SCALE3 }, { 180, PWR_REGULATOR_VOLTAGE_SCALE2 }, // Above 180MHz uses default PWR_REGULATOR_VOLTAGE_SCALE1 }; #elif defined(STM32H7) STATIC const sysclk_scaling_table_entry_t volt_scale_table[] = { // See table 55 "Kernel clock distribution overview" of RM0433. {200, PWR_REGULATOR_VOLTAGE_SCALE3}, {300, PWR_REGULATOR_VOLTAGE_SCALE2}, // Above 300MHz uses default PWR_REGULATOR_VOLTAGE_SCALE1 // (above 400MHz needs special handling for overdrive, currently unsupported) }; #endif STATIC int powerctrl_config_vos(uint32_t sysclk_mhz) { #if defined(STM32F7) || defined(STM32H7) uint32_t volt_scale = PWR_REGULATOR_VOLTAGE_SCALE1; for (int i = 0; i < MP_ARRAY_SIZE(volt_scale_table); ++i) { if (sysclk_mhz <= volt_scale_table[i].mhz) { volt_scale = volt_scale_table[i].value; break; } } if (HAL_PWREx_ControlVoltageScaling(volt_scale) != HAL_OK) { return -MP_EIO; } #endif return 0; } // Assumes that PLL is used as the SYSCLK source int powerctrl_rcc_clock_config_pll(RCC_ClkInitTypeDef *rcc_init, uint32_t sysclk_mhz, bool need_pllsai) { uint32_t flash_latency; #if defined(STM32F7) if (need_pllsai) { // Configure PLLSAI at 48MHz for those peripherals that need this freq // (calculation assumes it can get an integral value of PLLSAIN) const uint32_t pllm = (RCC->PLLCFGR >> RCC_PLLCFGR_PLLM_Pos) & 0x3f; const uint32_t pllsaip = 4; const uint32_t pllsaiq = 2; const uint32_t pllsain = 48 * pllsaip * pllm / (HSE_VALUE / 1000000); RCC->PLLSAICFGR = pllsaiq << RCC_PLLSAICFGR_PLLSAIQ_Pos | (pllsaip / 2 - 1) << RCC_PLLSAICFGR_PLLSAIP_Pos | pllsain << RCC_PLLSAICFGR_PLLSAIN_Pos; RCC->CR |= RCC_CR_PLLSAION; uint32_t ticks = mp_hal_ticks_ms(); while (!(RCC->CR & RCC_CR_PLLSAIRDY)) { if (mp_hal_ticks_ms() - ticks > 200) { return -MP_ETIMEDOUT; } } RCC->DCKCFGR2 |= RCC_DCKCFGR2_CK48MSEL; } #endif // If possible, scale down the internal voltage regulator to save power int ret = powerctrl_config_vos(sysclk_mhz); if (ret) { return ret; } #if defined(STM32F7) // These flash_latency values assume a supply voltage between 2.7V and 3.6V if (sysclk_mhz <= 30) { flash_latency = FLASH_LATENCY_0; } else if (sysclk_mhz <= 60) { flash_latency = FLASH_LATENCY_1; } else if (sysclk_mhz <= 90) { flash_latency = FLASH_LATENCY_2; } else if (sysclk_mhz <= 120) { flash_latency = FLASH_LATENCY_3; } else if (sysclk_mhz <= 150) { flash_latency = FLASH_LATENCY_4; } else if (sysclk_mhz <= 180) { flash_latency = FLASH_LATENCY_5; } else if (sysclk_mhz <= 210) { flash_latency = FLASH_LATENCY_6; } else { flash_latency = FLASH_LATENCY_7; } #elif defined(MICROPY_HW_FLASH_LATENCY) flash_latency = MICROPY_HW_FLASH_LATENCY; #else flash_latency = FLASH_LATENCY_5; #endif rcc_init->SYSCLKSource = RCC_SYSCLKSOURCE_PLLCLK; if (HAL_RCC_ClockConfig(rcc_init, flash_latency) != HAL_OK) { return -MP_EIO; } powerctrl_disable_hsi_if_unused(); return 0; } #endif #if !defined(STM32F0) && !defined(STM32L0) && !defined(STM32L4) STATIC uint32_t calc_ahb_div(uint32_t wanted_div) { #if defined(STM32H7) if (wanted_div <= 1) { return RCC_HCLK_DIV1; } else if (wanted_div <= 2) { return RCC_HCLK_DIV2; } else if (wanted_div <= 4) { return RCC_HCLK_DIV4; } else if (wanted_div <= 8) { return RCC_HCLK_DIV8; } else if (wanted_div <= 16) { return RCC_HCLK_DIV16; } else if (wanted_div <= 64) { return RCC_HCLK_DIV64; } else if (wanted_div <= 128) { return RCC_HCLK_DIV128; } else if (wanted_div <= 256) { return RCC_HCLK_DIV256; } else { return RCC_HCLK_DIV512; } #else if (wanted_div <= 1) { return RCC_SYSCLK_DIV1; } else if (wanted_div <= 2) { return RCC_SYSCLK_DIV2; } else if (wanted_div <= 4) { return RCC_SYSCLK_DIV4; } else if (wanted_div <= 8) { return RCC_SYSCLK_DIV8; } else if (wanted_div <= 16) { return RCC_SYSCLK_DIV16; } else if (wanted_div <= 64) { return RCC_SYSCLK_DIV64; } else if (wanted_div <= 128) { return RCC_SYSCLK_DIV128; } else if (wanted_div <= 256) { return RCC_SYSCLK_DIV256; } else { return RCC_SYSCLK_DIV512; } #endif } STATIC uint32_t calc_apb1_div(uint32_t wanted_div) { #if defined(STM32H7) if (wanted_div <= 1) { return RCC_APB1_DIV1; } else if (wanted_div <= 2) { return RCC_APB1_DIV2; } else if (wanted_div <= 4) { return RCC_APB1_DIV4; } else if (wanted_div <= 8) { return RCC_APB1_DIV8; } else { return RCC_APB1_DIV16; } #else if (wanted_div <= 1) { return RCC_HCLK_DIV1; } else if (wanted_div <= 2) { return RCC_HCLK_DIV2; } else if (wanted_div <= 4) { return RCC_HCLK_DIV4; } else if (wanted_div <= 8) { return RCC_HCLK_DIV8; } else { return RCC_HCLK_DIV16; } #endif } STATIC uint32_t calc_apb2_div(uint32_t wanted_div) { #if defined(STM32H7) if (wanted_div <= 1) { return RCC_APB2_DIV1; } else if (wanted_div <= 2) { return RCC_APB2_DIV2; } else if (wanted_div <= 4) { return RCC_APB2_DIV4; } else if (wanted_div <= 8) { return RCC_APB2_DIV8; } else { return RCC_APB2_DIV16; } #else return calc_apb1_div(wanted_div); #endif } #if defined(STM32F4) || defined(STM32F7) || defined(STM32H7) int powerctrl_set_sysclk(uint32_t sysclk, uint32_t ahb, uint32_t apb1, uint32_t apb2) { // Return straightaway if the clocks are already at the desired frequency if (sysclk == HAL_RCC_GetSysClockFreq() && ahb == HAL_RCC_GetHCLKFreq() && apb1 == HAL_RCC_GetPCLK1Freq() && apb2 == HAL_RCC_GetPCLK2Freq()) { return 0; } // Default PLL parameters that give 48MHz on PLL48CK uint32_t m = MICROPY_HW_CLK_VALUE / 1000000, n = 336, p = 2, q = 7; uint32_t sysclk_source; bool need_pllsai = false; // Search for a valid PLL configuration that keeps USB at 48MHz uint32_t sysclk_mhz = sysclk / 1000000; for (const pll_freq_table_t *pll = &pll_freq_table[MP_ARRAY_SIZE(pll_freq_table) - 1]; pll >= &pll_freq_table[0]; --pll) { uint32_t sys = PLL_FREQ_TABLE_SYS(*pll); if (sys <= sysclk_mhz) { m = PLL_FREQ_TABLE_M(*pll); p = PLL_FREQ_TABLE_P(*pll); if (m == 0) { // special entry for using HSI directly sysclk_source = RCC_SYSCLKSOURCE_HSI; } else if (m == 1) { // special entry for using HSE directly sysclk_source = RCC_SYSCLKSOURCE_HSE; } else { // use PLL sysclk_source = RCC_SYSCLKSOURCE_PLLCLK; uint32_t vco_out = sys * p; n = vco_out * m / (MICROPY_HW_CLK_VALUE / 1000000); q = vco_out / 48; #if defined(STM32F7) need_pllsai = vco_out % 48 != 0; #endif } goto set_clk; } } return -MP_EINVAL; set_clk: // Let the USB CDC have a chance to process before we change the clock mp_hal_delay_ms(5); // Desired system clock source is in sysclk_source RCC_ClkInitTypeDef RCC_ClkInitStruct; RCC_ClkInitStruct.ClockType = (RCC_CLOCKTYPE_SYSCLK | RCC_CLOCKTYPE_HCLK | RCC_CLOCKTYPE_PCLK1 | RCC_CLOCKTYPE_PCLK2); if (sysclk_source == RCC_SYSCLKSOURCE_PLLCLK) { // Set HSE as system clock source to allow modification of the PLL configuration // We then change to PLL after re-configuring PLL #if MICROPY_HW_CLK_USE_HSI RCC_ClkInitStruct.SYSCLKSource = RCC_SYSCLKSOURCE_HSI; #else RCC_ClkInitStruct.SYSCLKSource = RCC_SYSCLKSOURCE_HSE; #endif } else { // Directly set the system clock source as desired RCC_ClkInitStruct.SYSCLKSource = sysclk_source; } // Determine the bus clock dividers // Note: AHB freq required to be >= 14.2MHz for USB operation RCC_ClkInitStruct.AHBCLKDivider = calc_ahb_div(sysclk / ahb); #if !defined(STM32H7) ahb = sysclk >> AHBPrescTable[RCC_ClkInitStruct.AHBCLKDivider >> RCC_CFGR_HPRE_Pos]; #endif RCC_ClkInitStruct.APB1CLKDivider = calc_apb1_div(ahb / apb1); RCC_ClkInitStruct.APB2CLKDivider = calc_apb2_div(ahb / apb2); #if defined(STM32H7) RCC_ClkInitStruct.SYSCLKDivider = RCC_SYSCLK_DIV1; RCC_ClkInitStruct.APB3CLKDivider = RCC_APB3_DIV2; RCC_ClkInitStruct.APB4CLKDivider = RCC_APB4_DIV2; #endif #if MICROPY_HW_CLK_LAST_FREQ // Save the bus dividers for use later uint32_t h = RCC_ClkInitStruct.AHBCLKDivider >> 4; uint32_t b1 = RCC_ClkInitStruct.APB1CLKDivider >> 10; uint32_t b2 = RCC_ClkInitStruct.APB2CLKDivider >> 10; #endif // Configure clock if (HAL_RCC_ClockConfig(&RCC_ClkInitStruct, FLASH_LATENCY_1) != HAL_OK) { return -MP_EIO; } #if defined(STM32F7) // Deselect PLLSAI as 48MHz source if we were using it RCC->DCKCFGR2 &= ~RCC_DCKCFGR2_CK48MSEL; // Turn PLLSAI off because we are changing PLLM (which drives PLLSAI) RCC->CR &= ~RCC_CR_PLLSAION; #endif // Re-configure PLL // Even if we don't use the PLL for the system clock, we still need it for USB, RNG and SDIO RCC_OscInitTypeDef RCC_OscInitStruct; RCC_OscInitStruct.OscillatorType = MICROPY_HW_RCC_OSCILLATOR_TYPE; RCC_OscInitStruct.HSEState = MICROPY_HW_RCC_HSE_STATE; RCC_OscInitStruct.HSIState = MICROPY_HW_RCC_HSI_STATE; RCC_OscInitStruct.HSICalibrationValue = RCC_HSICALIBRATION_DEFAULT; RCC_OscInitStruct.PLL.PLLState = RCC_PLL_ON; RCC_OscInitStruct.PLL.PLLSource = MICROPY_HW_RCC_PLL_SRC; RCC_OscInitStruct.PLL.PLLM = m; RCC_OscInitStruct.PLL.PLLN = n; RCC_OscInitStruct.PLL.PLLP = p; RCC_OscInitStruct.PLL.PLLQ = q; #if defined(STM32H7) RCC_OscInitStruct.PLL.PLLR = 0; if (MICROPY_HW_CLK_VALUE / 1000000 <= 2 * m) { RCC_OscInitStruct.PLL.PLLRGE = RCC_PLL1VCIRANGE_0; // 1-2MHz } else if (MICROPY_HW_CLK_VALUE / 1000000 <= 4 * m) { RCC_OscInitStruct.PLL.PLLRGE = RCC_PLL1VCIRANGE_1; // 2-4MHz } else if (MICROPY_HW_CLK_VALUE / 1000000 <= 8 * m) { RCC_OscInitStruct.PLL.PLLRGE = RCC_PLL1VCIRANGE_2; // 4-8MHz } else { RCC_OscInitStruct.PLL.PLLRGE = RCC_PLL1VCIRANGE_3; // 8-16MHz } if (MICROPY_HW_CLK_VALUE / 1000000 * n <= 420 * m) { RCC_OscInitStruct.PLL.PLLVCOSEL = RCC_PLL1VCOMEDIUM; // 150-420MHz } else { RCC_OscInitStruct.PLL.PLLVCOSEL = RCC_PLL1VCOWIDE; // 192-960MHz } RCC_OscInitStruct.PLL.PLLFRACN = 0; #endif if (HAL_RCC_OscConfig(&RCC_OscInitStruct) != HAL_OK) { return -MP_EIO; } // Set PLL as system clock source if wanted if (sysclk_source == RCC_SYSCLKSOURCE_PLLCLK) { RCC_ClkInitStruct.ClockType = RCC_CLOCKTYPE_SYSCLK; int ret = powerctrl_rcc_clock_config_pll(&RCC_ClkInitStruct, sysclk_mhz, need_pllsai); if (ret != 0) { return ret; } } #if MICROPY_HW_CLK_LAST_FREQ // Save settings in RTC backup register to reconfigure clocks on hard-reset #if defined(STM32F7) #define FREQ_BKP BKP31R #else #define FREQ_BKP BKP19R #endif // qqqqqqqq pppppppp nnnnnnnn nnmmmmmm // qqqqQQQQ ppppppPP nNNNNNNN NNMMMMMM // 222111HH HHQQQQPP nNNNNNNN NNMMMMMM p = (p / 2) - 1; RTC->FREQ_BKP = m | (n << 6) | (p << 16) | (q << 18) | (h << 22) | (b1 << 26) | (b2 << 29); #endif return 0; } #elif defined(STM32WB) int powerctrl_set_sysclk(uint32_t sysclk, uint32_t ahb, uint32_t apb1, uint32_t apb2) { // For now it's not supported to change SYSCLK (only bus dividers). if (sysclk != HAL_RCC_GetSysClockFreq()) { return -MP_EINVAL; } // Return straightaway if the clocks are already at the desired frequency. if (ahb == HAL_RCC_GetHCLKFreq() && apb1 == HAL_RCC_GetPCLK1Freq() && apb2 == HAL_RCC_GetPCLK2Freq()) { return 0; } // Calculate and configure the bus clock dividers. uint32_t cfgr = RCC->CFGR; cfgr &= ~(7 << RCC_CFGR_PPRE2_Pos | 7 << RCC_CFGR_PPRE1_Pos | 0xf << RCC_CFGR_HPRE_Pos); cfgr |= calc_ahb_div(sysclk / ahb); cfgr |= calc_apb1_div(ahb / apb1); cfgr |= calc_apb2_div(ahb / apb2) << (RCC_CFGR_PPRE2_Pos - RCC_CFGR_PPRE1_Pos); RCC->CFGR = cfgr; return 0; } #endif #endif // !defined(STM32F0) && !defined(STM32L0) && !defined(STM32L4) void powerctrl_enter_stop_mode(void) { // Disable IRQs so that the IRQ that wakes the device from stop mode is not // executed until after the clocks are reconfigured uint32_t irq_state = disable_irq(); #if defined(STM32H7) // Disable SysTick Interrupt // Note: This seems to be required at least on the H7 REV Y, // otherwise the MCU will leave stop mode immediately on entry. SysTick->CTRL &= ~SysTick_CTRL_TICKINT_Msk; #endif #if defined(MICROPY_BOARD_ENTER_STOP) MICROPY_BOARD_ENTER_STOP #endif #if defined(STM32L4) // Configure the MSI as the clock source after waking up __HAL_RCC_WAKEUPSTOP_CLK_CONFIG(RCC_STOP_WAKEUPCLOCK_MSI); #endif #if !defined(STM32F0) && !defined(STM32L0) && !defined(STM32L4) && !defined(STM32WB) // takes longer to wake but reduces stop current HAL_PWREx_EnableFlashPowerDown(); #endif #if defined(STM32H7) // Save RCC CR to re-enable OSCs and PLLs after wake up from low power mode. uint32_t rcc_cr = RCC->CR; // Save the current voltage scaling level to restore after exiting low power mode. uint32_t vscaling = POWERCTRL_GET_VOLTAGE_SCALING(); // If the current voltage scaling level is 0, switch to level 1 before entering low power mode. if (vscaling == PWR_REGULATOR_VOLTAGE_SCALE0) { __HAL_PWR_VOLTAGESCALING_CONFIG(PWR_REGULATOR_VOLTAGE_SCALE1); // Wait for PWR_FLAG_VOSRDY while (!__HAL_PWR_GET_FLAG(PWR_FLAG_VOSRDY)) { } } #endif #if defined(STM32F7) HAL_PWR_EnterSTOPMode((PWR_CR1_LPDS | PWR_CR1_LPUDS | PWR_CR1_FPDS | PWR_CR1_UDEN), PWR_STOPENTRY_WFI); #else HAL_PWR_EnterSTOPMode(PWR_LOWPOWERREGULATOR_ON, PWR_STOPENTRY_WFI); #endif // reconfigure the system clock after waking up #if defined(STM32F0) // Enable HSI48 __HAL_RCC_HSI48_ENABLE(); while (!__HAL_RCC_GET_FLAG(RCC_FLAG_HSI48RDY)) { } // Select HSI48 as system clock source MODIFY_REG(RCC->CFGR, RCC_CFGR_SW, RCC_SYSCLKSOURCE_HSI48); while (__HAL_RCC_GET_SYSCLK_SOURCE() != RCC_CFGR_SWS_HSI48) { } #else #if defined(STM32H7) // When exiting from Stop or Standby modes, the Run mode voltage scaling is reset to // the default VOS3 value. Restore the voltage scaling to the previous voltage scale. if (vscaling != POWERCTRL_GET_VOLTAGE_SCALING()) { __HAL_PWR_VOLTAGESCALING_CONFIG(vscaling); // Wait for PWR_FLAG_VOSRDY while (!__HAL_PWR_GET_FLAG(PWR_FLAG_VOSRDY)) { } } #endif #if !defined(STM32L4) // enable clock __HAL_RCC_HSE_CONFIG(MICROPY_HW_RCC_HSE_STATE); #if MICROPY_HW_CLK_USE_HSI __HAL_RCC_HSI_ENABLE(); #endif while (!__HAL_RCC_GET_FLAG(MICROPY_HW_RCC_FLAG_HSxRDY)) { } #endif #if defined(STM32F7) // Enable overdrive to reach 216MHz (if needed) HAL_PWREx_EnableOverDrive(); #endif // enable PLL __HAL_RCC_PLL_ENABLE(); while (!__HAL_RCC_GET_FLAG(RCC_FLAG_PLLRDY)) { } // select PLL as system clock source MODIFY_REG(RCC->CFGR, RCC_CFGR_SW, RCC_SYSCLKSOURCE_PLLCLK); #if defined(STM32H7) while (__HAL_RCC_GET_SYSCLK_SOURCE() != RCC_CFGR_SWS_PLL1) { } #elif defined(STM32WB) while (__HAL_RCC_GET_SYSCLK_SOURCE() != RCC_SYSCLKSOURCE_STATUS_PLLCLK) { } #else while (__HAL_RCC_GET_SYSCLK_SOURCE() != RCC_CFGR_SWS_PLL) { } #endif powerctrl_disable_hsi_if_unused(); #if defined(STM32F7) if (RCC->DCKCFGR2 & RCC_DCKCFGR2_CK48MSEL) { // Enable PLLSAI if it is selected as 48MHz source RCC->CR |= RCC_CR_PLLSAION; while (!(RCC->CR & RCC_CR_PLLSAIRDY)) { } } #endif #if defined(STM32H7) // Enable HSI if (rcc_cr & RCC_CR_HSION) { RCC->CR |= RCC_CR_HSION; while (!(RCC->CR & RCC_CR_HSIRDY)) { } } // Enable CSI if (rcc_cr & RCC_CR_CSION) { RCC->CR |= RCC_CR_CSION; while (!(RCC->CR & RCC_CR_CSIRDY)) { } } // Enable HSI48 if (rcc_cr & RCC_CR_HSI48ON) { RCC->CR |= RCC_CR_HSI48ON; while (!(RCC->CR & RCC_CR_HSI48RDY)) { } } // Enable PLL2 if (rcc_cr & RCC_CR_PLL2ON) { RCC->CR |= RCC_CR_PLL2ON; while (!(RCC->CR & RCC_CR_PLL2RDY)) { } } // Enable PLL3 if (rcc_cr & RCC_CR_PLL3ON) { RCC->CR |= RCC_CR_PLL3ON; while (!(RCC->CR & RCC_CR_PLL3RDY)) { } } #endif #if defined(STM32L4) // Enable PLLSAI1 for peripherals that use it RCC->CR |= RCC_CR_PLLSAI1ON; while (!(RCC->CR & RCC_CR_PLLSAI1RDY)) { } #endif #endif #if defined(MICROPY_BOARD_LEAVE_STOP) MICROPY_BOARD_LEAVE_STOP #endif #if defined(STM32H7) // Enable SysTick Interrupt SysTick->CTRL |= SysTick_CTRL_TICKINT_Msk; #endif // Enable IRQs now that all clocks are reconfigured enable_irq(irq_state); } void powerctrl_enter_standby_mode(void) { rtc_init_finalise(); #if defined(MICROPY_BOARD_ENTER_STANDBY) MICROPY_BOARD_ENTER_STANDBY #endif // We need to clear the PWR wake-up-flag before entering standby, since // the flag may have been set by a previous wake-up event. Furthermore, // we need to disable the wake-up sources while clearing this flag, so // that if a source is active it does actually wake the device. // See section 5.3.7 of RM0090. // Note: we only support RTC ALRA, ALRB, WUT and TS. // TODO support TAMP and WKUP (PA0 external pin). #if defined(STM32F0) || defined(STM32L0) #define CR_BITS (RTC_CR_ALRAIE | RTC_CR_WUTIE | RTC_CR_TSIE) #define ISR_BITS (RTC_ISR_ALRAF | RTC_ISR_WUTF | RTC_ISR_TSF) #else #define CR_BITS (RTC_CR_ALRAIE | RTC_CR_ALRBIE | RTC_CR_WUTIE | RTC_CR_TSIE) #define ISR_BITS (RTC_ISR_ALRAF | RTC_ISR_ALRBF | RTC_ISR_WUTF | RTC_ISR_TSF) #endif // save RTC interrupts uint32_t save_irq_bits = RTC->CR & CR_BITS; // disable register write protection RTC->WPR = 0xca; RTC->WPR = 0x53; // disable RTC interrupts RTC->CR &= ~CR_BITS; // clear RTC wake-up flags RTC->ISR &= ~ISR_BITS; #if defined(STM32F7) // Save EWUP state uint32_t csr2_ewup = PWR->CSR2 & (PWR_CSR2_EWUP6 | PWR_CSR2_EWUP5 | PWR_CSR2_EWUP4 | PWR_CSR2_EWUP3 | PWR_CSR2_EWUP2 | PWR_CSR2_EWUP1); // disable wake-up flags PWR->CSR2 &= ~(PWR_CSR2_EWUP6 | PWR_CSR2_EWUP5 | PWR_CSR2_EWUP4 | PWR_CSR2_EWUP3 | PWR_CSR2_EWUP2 | PWR_CSR2_EWUP1); // clear global wake-up flag PWR->CR2 |= PWR_CR2_CWUPF6 | PWR_CR2_CWUPF5 | PWR_CR2_CWUPF4 | PWR_CR2_CWUPF3 | PWR_CR2_CWUPF2 | PWR_CR2_CWUPF1; // Restore EWUP state PWR->CSR2 |= csr2_ewup; #elif defined(STM32H7) EXTI_D1->PR1 = 0x3fffff; PWR->WKUPCR |= PWR_WAKEUP_FLAG1 | PWR_WAKEUP_FLAG2 | PWR_WAKEUP_FLAG3 | PWR_WAKEUP_FLAG4 | PWR_WAKEUP_FLAG5 | PWR_WAKEUP_FLAG6; #elif defined(STM32L4) || defined(STM32WB) // clear all wake-up flags PWR->SCR |= PWR_SCR_CWUF5 | PWR_SCR_CWUF4 | PWR_SCR_CWUF3 | PWR_SCR_CWUF2 | PWR_SCR_CWUF1; // TODO #else // clear global wake-up flag PWR->CR |= PWR_CR_CWUF; #endif // enable previously-enabled RTC interrupts RTC->CR |= save_irq_bits; // enable register write protection RTC->WPR = 0xff; #if defined(STM32F7) // Enable the internal (eg RTC) wakeup sources // See Errata 2.2.2 "Wakeup from Standby mode when the back-up SRAM regulator is enabled" PWR->CSR1 |= PWR_CSR1_EIWUP; #endif // enter standby mode HAL_PWR_EnterSTANDBYMode(); // we never return; MCU is reset on exit from standby }