/* * * Copyright (c) 2019 Linaro Limited. * Copyright (c) 2020 Jeremy LOCHE * Copyright (c) 2021 Electrolance Solutions * * SPDX-License-Identifier: Apache-2.0 */ #include #include #include #include #include #include #include #include #include #include "clock_stm32_ll_mco.h" #include "stm32_hsem.h" /* Macros to fill up prescaler values */ #define z_hsi_divider(v) LL_RCC_HSI_DIV ## v #define hsi_divider(v) z_hsi_divider(v) #define z_sysclk_prescaler(v) LL_RCC_SYSCLK_DIV_ ## v #define sysclk_prescaler(v) z_sysclk_prescaler(v) #define z_ahb_prescaler(v) LL_RCC_AHB_DIV_ ## v #define ahb_prescaler(v) z_ahb_prescaler(v) #define z_apb1_prescaler(v) LL_RCC_APB1_DIV_ ## v #define apb1_prescaler(v) z_apb1_prescaler(v) #define z_apb2_prescaler(v) LL_RCC_APB2_DIV_ ## v #define apb2_prescaler(v) z_apb2_prescaler(v) #define z_apb3_prescaler(v) LL_RCC_APB3_DIV_ ## v #define apb3_prescaler(v) z_apb3_prescaler(v) #define z_apb4_prescaler(v) LL_RCC_APB4_DIV_ ## v #define apb4_prescaler(v) z_apb4_prescaler(v) /* Macro to check for clock feasibility */ /* It is Cortex M7's responsibility to setup clock tree */ /* This check should only be performed for the M7 core code */ #ifdef CONFIG_CPU_CORTEX_M7 /* Choose PLL SRC */ #if defined(STM32_PLL_SRC_HSI) #define PLLSRC_FREQ ((STM32_HSI_FREQ)/(STM32_HSI_DIVISOR)) #elif defined(STM32_PLL_SRC_CSI) #define PLLSRC_FREQ STM32_CSI_FREQ #elif defined(STM32_PLL_SRC_HSE) #define PLLSRC_FREQ STM32_HSE_FREQ #else #define PLLSRC_FREQ 0 #endif /* Given source clock and dividers, computed the output frequency of PLLP */ #define PLLP_FREQ(pllsrc_freq, divm, divn, divp) (((pllsrc_freq)*\ (divn))/((divm)*(divp))) /* PLL P output frequency value */ #define PLLP_VALUE PLLP_FREQ(\ PLLSRC_FREQ,\ STM32_PLL_M_DIVISOR,\ STM32_PLL_N_MULTIPLIER,\ STM32_PLL_P_DIVISOR) /* SYSCLKSRC before the D1CPRE prescaler */ #if defined(STM32_SYSCLK_SRC_PLL) #define SYSCLKSRC_FREQ PLLP_VALUE #elif defined(STM32_SYSCLK_SRC_HSI) #define SYSCLKSRC_FREQ ((STM32_HSI_FREQ)/(STM32_HSI_DIVISOR)) #elif defined(STM32_SYSCLK_SRC_CSI) #define SYSCLKSRC_FREQ STM32_CSI_FREQ #elif defined(STM32_SYSCLK_SRC_HSE) #define SYSCLKSRC_FREQ STM32_HSE_FREQ #endif /* ARM Sys CPU Clock before HPRE prescaler */ #define SYSCLK_FREQ ((SYSCLKSRC_FREQ)/(STM32_D1CPRE)) #define AHB_FREQ ((SYSCLK_FREQ)/(STM32_HPRE)) #define APB1_FREQ ((AHB_FREQ)/(STM32_D2PPRE1)) #define APB2_FREQ ((AHB_FREQ)/(STM32_D2PPRE2)) #define APB3_FREQ ((AHB_FREQ)/(STM32_D1PPRE)) #define APB4_FREQ ((AHB_FREQ)/(STM32_D3PPRE)) /* Datasheet maximum frequency definitions */ #if defined(CONFIG_SOC_STM32H743XX) ||\ defined(CONFIG_SOC_STM32H745XX_M7) || defined(CONFIG_SOC_STM32H745XX_M4) ||\ defined(CONFIG_SOC_STM32H747XX_M7) || defined(CONFIG_SOC_STM32H747XX_M4) ||\ defined(CONFIG_SOC_STM32H750XX) ||\ defined(CONFIG_SOC_STM32H753XX) /* All h7 SoC with maximum 480MHz SYSCLK */ #define SYSCLK_FREQ_MAX 480000000UL #define AHB_FREQ_MAX 240000000UL #define APBx_FREQ_MAX 120000000UL #elif defined(CONFIG_SOC_STM32H723XX) ||\ defined(CONFIG_SOC_STM32H725XX) ||\ defined(CONFIG_SOC_STM32H730XX) || defined(CONFIG_SOC_STM32H730XXQ) ||\ defined(CONFIG_SOC_STM32H735XX) /* All h7 SoC with maximum 550MHz SYSCLK */ #define SYSCLK_FREQ_MAX 550000000UL #define AHB_FREQ_MAX 275000000UL #define APBx_FREQ_MAX 137500000UL #elif defined(CONFIG_SOC_STM32H7A3XX) || defined(CONFIG_SOC_STM32H7A3XXQ) ||\ defined(CONFIG_SOC_STM32H7B0XX) || defined(CONFIG_SOC_STM32H7B0XXQ) ||\ defined(CONFIG_SOC_STM32H7B3XX) || defined(CONFIG_SOC_STM32H7B3XXQ) #define SYSCLK_FREQ_MAX 280000000UL #define AHB_FREQ_MAX 280000000UL #define APBx_FREQ_MAX 140000000UL #else /* Default: All h7 SoC with maximum 280MHz SYSCLK */ #define SYSCLK_FREQ_MAX 280000000UL #define AHB_FREQ_MAX 140000000UL #define APBx_FREQ_MAX 70000000UL #endif #if SYSCLK_FREQ > SYSCLK_FREQ_MAX #error "SYSCLK frequency is too high!" #endif #if AHB_FREQ > AHB_FREQ_MAX #error "AHB frequency is too high!" #endif #if APB1_FREQ > APBx_FREQ_MAX #error "APB1 frequency is too high!" #endif #if APB2_FREQ > APBx_FREQ_MAX #error "APB2 frequency is too high!" #endif #if APB3_FREQ > APBx_FREQ_MAX #error "APB3 frequency is too high!" #endif #if APB4_FREQ > APBx_FREQ_MAX #error "APB4 frequency is too high!" #endif #if SYSCLK_FREQ != CONFIG_SYS_CLOCK_HW_CYCLES_PER_SEC #error "SYS clock frequency for M7 core doesn't match CONFIG_SYS_CLOCK_HW_CYCLES_PER_SEC" #endif /* end of clock feasibility check */ #endif /* CONFIG_CPU_CORTEX_M7 */ #if defined(CONFIG_CPU_CORTEX_M7) #if STM32_D1CPRE > 1 /* * D1CPRE prescaler allows to set a HCLK frequency lower than SYSCLK frequency. * Though, zephyr doesn't make a difference today between these two clocks. * So, changing this prescaler is not allowed until it is made possible to * use them independently in zephyr clock subsystem. */ #error "D1CPRE presacler can't be higher than 1" #endif #endif /* CONFIG_CPU_CORTEX_M7 */ #if defined(CONFIG_CPU_CORTEX_M7) /* Offset to access bus clock registers from M7 (or only) core */ #define STM32H7_BUS_CLK_REG DT_REG_ADDR(DT_NODELABEL(rcc)) #elif defined(CONFIG_CPU_CORTEX_M4) /* Offset to access bus clock registers from M4 core */ #define STM32H7_BUS_CLK_REG DT_REG_ADDR(DT_NODELABEL(rcc)) + 0x60 #endif static uint32_t get_bus_clock(uint32_t clock, uint32_t prescaler) { return clock / prescaler; } __unused static uint32_t get_pllout_frequency(uint32_t pllsrc_freq, int pllm_div, int plln_mul, int pllout_div) { __ASSERT_NO_MSG(pllm_div && pllout_div); return (pllsrc_freq / pllm_div) * plln_mul / pllout_div; } __unused static uint32_t get_pllsrc_frequency(void) { switch (LL_RCC_PLL_GetSource()) { case LL_RCC_PLLSOURCE_HSI: return STM32_HSI_FREQ; case LL_RCC_PLLSOURCE_CSI: return STM32_CSI_FREQ; case LL_RCC_PLLSOURCE_HSE: return STM32_HSE_FREQ; case LL_RCC_PLLSOURCE_NONE: default: return 0; } } __unused static uint32_t get_hclk_frequency(void) { uint32_t sysclk = 0; /* Get the current system clock source */ switch (LL_RCC_GetSysClkSource()) { case LL_RCC_SYS_CLKSOURCE_STATUS_HSI: sysclk = STM32_HSI_FREQ/STM32_HSI_DIVISOR; break; case LL_RCC_SYS_CLKSOURCE_STATUS_CSI: sysclk = STM32_CSI_FREQ; break; case LL_RCC_SYS_CLKSOURCE_STATUS_HSE: sysclk = STM32_HSE_FREQ; break; #if defined(STM32_PLL_ENABLED) case LL_RCC_SYS_CLKSOURCE_STATUS_PLL1: sysclk = get_pllout_frequency(get_pllsrc_frequency(), STM32_PLL_M_DIVISOR, STM32_PLL_N_MULTIPLIER, STM32_PLL_P_DIVISOR); break; #endif /* STM32_PLL_ENABLED */ } return get_bus_clock(sysclk, STM32_HPRE); } #if !defined(CONFIG_CPU_CORTEX_M4) static int32_t prepare_regulator_voltage_scale(void) { /* Apply system power supply configuration */ #if defined(SMPS) && defined(CONFIG_POWER_SUPPLY_DIRECT_SMPS) LL_PWR_ConfigSupply(LL_PWR_DIRECT_SMPS_SUPPLY); #elif defined(SMPS) && defined(CONFIG_POWER_SUPPLY_SMPS_1V8_SUPPLIES_LDO) LL_PWR_ConfigSupply(LL_PWR_SMPS_1V8_SUPPLIES_LDO); #elif defined(SMPS) && defined(CONFIG_POWER_SUPPLY_SMPS_2V5_SUPPLIES_LDO) LL_PWR_ConfigSupply(LL_PWR_SMPS_2V5_SUPPLIES_LDO); #elif defined(SMPS) && defined(CONFIG_POWER_SUPPLY_SMPS_1V8_SUPPLIES_EXT_AND_LDO) LL_PWR_ConfigSupply(LL_PWR_SMPS_1V8_SUPPLIES_EXT_AND_LDO); #elif defined(SMPS) && defined(CONFIG_POWER_SUPPLY_SMPS_2V5_SUPPLIES_EXT_AND_LDO) LL_PWR_ConfigSupply(LL_PWR_SMPS_2V5_SUPPLIES_EXT_AND_LDO); #elif defined(SMPS) && defined(CONFIG_POWER_SUPPLY_SMPS_1V8_SUPPLIES_EXT) LL_PWR_ConfigSupply(LL_PWR_SMPS_1V8_SUPPLIES_EXT); #elif defined(SMPS) && defined(CONFIG_POWER_SUPPLY_SMPS_2V5_SUPPLIES_EXT) LL_PWR_ConfigSupply(LL_PWR_SMPS_2V5_SUPPLIES_EXT); #elif defined(CONFIG_POWER_SUPPLY_EXTERNAL_SOURCE) LL_PWR_ConfigSupply(LL_PWR_EXTERNAL_SOURCE_SUPPLY); #else LL_PWR_ConfigSupply(LL_PWR_LDO_SUPPLY); #endif /* Make sure to put the CPU in highest Voltage scale during clock configuration */ /* Highest voltage is SCALE0 */ LL_PWR_SetRegulVoltageScaling(LL_PWR_REGU_VOLTAGE_SCALE0); while (LL_PWR_IsActiveFlag_VOS() == 0) { } return 0; } static int32_t optimize_regulator_voltage_scale(uint32_t sysclk_freq) { /* After sysclock is configured, tweak the voltage scale down */ /* to reduce power consumption */ /* Needs some smart work to configure properly */ /* LL_PWR_REGULATOR_SCALE3 is lowest power consumption */ /* Must be done in accordance to the Maximum allowed frequency vs VOS*/ /* See RM0433 page 352 for more details */ #if defined(SMPS) && defined(CONFIG_POWER_SUPPLY_DIRECT_SMPS) LL_PWR_ConfigSupply(LL_PWR_DIRECT_SMPS_SUPPLY); #elif defined(SMPS) && defined(CONFIG_POWER_SUPPLY_SMPS_1V8_SUPPLIES_LDO) LL_PWR_ConfigSupply(LL_PWR_SMPS_1V8_SUPPLIES_LDO); #elif defined(SMPS) && defined(CONFIG_POWER_SUPPLY_SMPS_2V5_SUPPLIES_LDO) LL_PWR_ConfigSupply(LL_PWR_SMPS_2V5_SUPPLIES_LDO); #elif defined(SMPS) && defined(CONFIG_POWER_SUPPLY_SMPS_1V8_SUPPLIES_EXT_AND_LDO) LL_PWR_ConfigSupply(LL_PWR_SMPS_1V8_SUPPLIES_EXT_AND_LDO); #elif defined(SMPS) && defined(CONFIG_POWER_SUPPLY_SMPS_2V5_SUPPLIES_EXT_AND_LDO) LL_PWR_ConfigSupply(LL_PWR_SMPS_2V5_SUPPLIES_EXT_AND_LDO); #elif defined(SMPS) && defined(CONFIG_POWER_SUPPLY_SMPS_1V8_SUPPLIES_EXT) LL_PWR_ConfigSupply(LL_PWR_SMPS_1V8_SUPPLIES_EXT); #elif defined(SMPS) && defined(CONFIG_POWER_SUPPLY_SMPS_2V5_SUPPLIES_EXT) LL_PWR_ConfigSupply(LL_PWR_SMPS_2V5_SUPPLIES_EXT); #elif defined(CONFIG_POWER_SUPPLY_EXTERNAL_SOURCE) LL_PWR_ConfigSupply(LL_PWR_EXTERNAL_SOURCE_SUPPLY); #else LL_PWR_ConfigSupply(LL_PWR_LDO_SUPPLY); #endif LL_PWR_SetRegulVoltageScaling(LL_PWR_REGU_VOLTAGE_SCALE0); while (LL_PWR_IsActiveFlag_VOS() == 0) { } return 0; } __unused static int get_vco_input_range(uint32_t m_div, uint32_t *range) { uint32_t vco_freq; vco_freq = PLLSRC_FREQ / m_div; if (MHZ(1) <= vco_freq && vco_freq <= MHZ(2)) { *range = LL_RCC_PLLINPUTRANGE_1_2; } else if (MHZ(2) < vco_freq && vco_freq <= MHZ(4)) { *range = LL_RCC_PLLINPUTRANGE_2_4; } else if (MHZ(4) < vco_freq && vco_freq <= MHZ(8)) { *range = LL_RCC_PLLINPUTRANGE_4_8; } else if (MHZ(8) < vco_freq && vco_freq <= MHZ(16)) { *range = LL_RCC_PLLINPUTRANGE_8_16; } else { return -ERANGE; } return 0; } __unused static uint32_t get_vco_output_range(uint32_t vco_input_range) { if (vco_input_range == LL_RCC_PLLINPUTRANGE_1_2) { return LL_RCC_PLLVCORANGE_MEDIUM; } return LL_RCC_PLLVCORANGE_WIDE; } #endif /* ! CONFIG_CPU_CORTEX_M4 */ /** @brief Verifies clock is part of active clock configuration */ static int enabled_clock(uint32_t src_clk) { if ((src_clk == STM32_SRC_SYSCLK) || ((src_clk == STM32_SRC_CKPER) && IS_ENABLED(STM32_CKPER_ENABLED)) || ((src_clk == STM32_SRC_HSE) && IS_ENABLED(STM32_HSE_ENABLED)) || ((src_clk == STM32_SRC_HSI_KER) && IS_ENABLED(STM32_HSI_ENABLED)) || ((src_clk == STM32_SRC_CSI_KER) && IS_ENABLED(STM32_CSI_ENABLED)) || ((src_clk == STM32_SRC_HSI48) && IS_ENABLED(STM32_HSI48_ENABLED)) || ((src_clk == STM32_SRC_LSE) && IS_ENABLED(STM32_LSE_ENABLED)) || ((src_clk == STM32_SRC_LSI) && IS_ENABLED(STM32_LSI_ENABLED)) || ((src_clk == STM32_SRC_PLL1_P) && IS_ENABLED(STM32_PLL_P_ENABLED)) || ((src_clk == STM32_SRC_PLL1_Q) && IS_ENABLED(STM32_PLL_Q_ENABLED)) || ((src_clk == STM32_SRC_PLL1_R) && IS_ENABLED(STM32_PLL_R_ENABLED)) || ((src_clk == STM32_SRC_PLL2_P) && IS_ENABLED(STM32_PLL2_P_ENABLED)) || ((src_clk == STM32_SRC_PLL2_Q) && IS_ENABLED(STM32_PLL2_Q_ENABLED)) || ((src_clk == STM32_SRC_PLL2_R) && IS_ENABLED(STM32_PLL2_R_ENABLED)) || ((src_clk == STM32_SRC_PLL3_P) && IS_ENABLED(STM32_PLL3_P_ENABLED)) || ((src_clk == STM32_SRC_PLL3_Q) && IS_ENABLED(STM32_PLL3_Q_ENABLED)) || ((src_clk == STM32_SRC_PLL3_R) && IS_ENABLED(STM32_PLL3_R_ENABLED))) { return 0; } return -ENOTSUP; } static inline int stm32_clock_control_on(const struct device *dev, clock_control_subsys_t sub_system) { struct stm32_pclken *pclken = (struct stm32_pclken *)(sub_system); volatile int temp; ARG_UNUSED(dev); if (IN_RANGE(pclken->bus, STM32_PERIPH_BUS_MIN, STM32_PERIPH_BUS_MAX) == 0) { /* Attempt to toggle a wrong periph clock bit */ return -ENOTSUP; } z_stm32_hsem_lock(CFG_HW_RCC_SEMID, HSEM_LOCK_DEFAULT_RETRY); sys_set_bits(STM32H7_BUS_CLK_REG + pclken->bus, pclken->enr); /* Delay after enabling the clock, to allow it to become active. * See RM0433 8.5.10 "Clock enabling delays" */ temp = sys_read32(STM32H7_BUS_CLK_REG + pclken->bus); UNUSED(temp); z_stm32_hsem_unlock(CFG_HW_RCC_SEMID); return 0; } static inline int stm32_clock_control_off(const struct device *dev, clock_control_subsys_t sub_system) { struct stm32_pclken *pclken = (struct stm32_pclken *)(sub_system); ARG_UNUSED(dev); if (IN_RANGE(pclken->bus, STM32_PERIPH_BUS_MIN, STM32_PERIPH_BUS_MAX) == 0) { /* Attempt to toggle a wrong periph clock bit */ return -ENOTSUP; } z_stm32_hsem_lock(CFG_HW_RCC_SEMID, HSEM_LOCK_DEFAULT_RETRY); sys_clear_bits(STM32H7_BUS_CLK_REG + pclken->bus, pclken->enr); z_stm32_hsem_unlock(CFG_HW_RCC_SEMID); return 0; } static inline int stm32_clock_control_configure(const struct device *dev, clock_control_subsys_t sub_system, void *data) { struct stm32_pclken *pclken = (struct stm32_pclken *)(sub_system); int err; ARG_UNUSED(dev); ARG_UNUSED(data); err = enabled_clock(pclken->bus); if (err < 0) { /* Attempt to configure a src clock not available or not valid */ return err; } z_stm32_hsem_lock(CFG_HW_RCC_SEMID, HSEM_LOCK_DEFAULT_RETRY); sys_clear_bits(DT_REG_ADDR(DT_NODELABEL(rcc)) + STM32_CLOCK_REG_GET(pclken->enr), STM32_CLOCK_MASK_GET(pclken->enr) << STM32_CLOCK_SHIFT_GET(pclken->enr)); sys_set_bits(DT_REG_ADDR(DT_NODELABEL(rcc)) + STM32_CLOCK_REG_GET(pclken->enr), STM32_CLOCK_VAL_GET(pclken->enr) << STM32_CLOCK_SHIFT_GET(pclken->enr)); z_stm32_hsem_unlock(CFG_HW_RCC_SEMID); return 0; } static int stm32_clock_control_get_subsys_rate(const struct device *clock, clock_control_subsys_t sub_system, uint32_t *rate) { struct stm32_pclken *pclken = (struct stm32_pclken *)(sub_system); /* * Get AHB Clock (= SystemCoreClock = SYSCLK/prescaler) * SystemCoreClock is preferred to CONFIG_SYS_CLOCK_HW_CYCLES_PER_SEC * since it will be updated after clock configuration and hence * more likely to contain actual clock speed */ #if defined(CONFIG_CPU_CORTEX_M4) uint32_t ahb_clock = SystemCoreClock; #else uint32_t ahb_clock = get_bus_clock(SystemCoreClock, STM32_HPRE); #endif uint32_t apb1_clock = get_bus_clock(ahb_clock, STM32_D2PPRE1); uint32_t apb2_clock = get_bus_clock(ahb_clock, STM32_D2PPRE2); uint32_t apb3_clock = get_bus_clock(ahb_clock, STM32_D1PPRE); uint32_t apb4_clock = get_bus_clock(ahb_clock, STM32_D3PPRE); ARG_UNUSED(clock); switch (pclken->bus) { case STM32_CLOCK_BUS_AHB1: case STM32_CLOCK_BUS_AHB2: case STM32_CLOCK_BUS_AHB3: case STM32_CLOCK_BUS_AHB4: *rate = ahb_clock; break; case STM32_CLOCK_BUS_APB1: case STM32_CLOCK_BUS_APB1_2: *rate = apb1_clock; break; case STM32_CLOCK_BUS_APB2: *rate = apb2_clock; break; case STM32_CLOCK_BUS_APB3: *rate = apb3_clock; break; case STM32_CLOCK_BUS_APB4: *rate = apb4_clock; break; case STM32_SRC_SYSCLK: *rate = get_hclk_frequency(); break; #if defined(STM32_CKPER_ENABLED) case STM32_SRC_CKPER: *rate = LL_RCC_GetCLKPClockFreq(LL_RCC_CLKP_CLKSOURCE); break; #endif /* STM32_CKPER_ENABLED */ #if defined(STM32_HSE_ENABLED) case STM32_SRC_HSE: *rate = STM32_HSE_FREQ; break; #endif /* STM32_HSE_ENABLED */ #if defined(STM32_LSE_ENABLED) case STM32_SRC_LSE: *rate = STM32_LSE_FREQ; break; #endif /* STM32_LSE_ENABLED */ #if defined(STM32_LSI_ENABLED) case STM32_SRC_LSI: *rate = STM32_LSI_FREQ; break; #endif /* STM32_LSI_ENABLED */ #if defined(STM32_HSI48_ENABLED) case STM32_SRC_HSI48: *rate = STM32_HSI48_FREQ; break; #endif /* STM32_HSI48_ENABLED */ #if defined(STM32_PLL_ENABLED) case STM32_SRC_PLL1_P: *rate = get_pllout_frequency(get_pllsrc_frequency(), STM32_PLL_M_DIVISOR, STM32_PLL_N_MULTIPLIER, STM32_PLL_P_DIVISOR); break; case STM32_SRC_PLL1_Q: *rate = get_pllout_frequency(get_pllsrc_frequency(), STM32_PLL_M_DIVISOR, STM32_PLL_N_MULTIPLIER, STM32_PLL_Q_DIVISOR); break; case STM32_SRC_PLL1_R: *rate = get_pllout_frequency(get_pllsrc_frequency(), STM32_PLL_M_DIVISOR, STM32_PLL_N_MULTIPLIER, STM32_PLL_R_DIVISOR); break; #endif /* STM32_PLL_ENABLED */ #if defined(STM32_PLL2_ENABLED) case STM32_SRC_PLL2_P: *rate = get_pllout_frequency(get_pllsrc_frequency(), STM32_PLL2_M_DIVISOR, STM32_PLL2_N_MULTIPLIER, STM32_PLL2_P_DIVISOR); break; case STM32_SRC_PLL2_Q: *rate = get_pllout_frequency(get_pllsrc_frequency(), STM32_PLL2_M_DIVISOR, STM32_PLL2_N_MULTIPLIER, STM32_PLL2_Q_DIVISOR); break; case STM32_SRC_PLL2_R: *rate = get_pllout_frequency(get_pllsrc_frequency(), STM32_PLL2_M_DIVISOR, STM32_PLL2_N_MULTIPLIER, STM32_PLL2_R_DIVISOR); break; #endif /* STM32_PLL2_ENABLED */ #if defined(STM32_PLL3_ENABLED) case STM32_SRC_PLL3_P: *rate = get_pllout_frequency(get_pllsrc_frequency(), STM32_PLL3_M_DIVISOR, STM32_PLL3_N_MULTIPLIER, STM32_PLL3_P_DIVISOR); break; case STM32_SRC_PLL3_Q: *rate = get_pllout_frequency(get_pllsrc_frequency(), STM32_PLL3_M_DIVISOR, STM32_PLL3_N_MULTIPLIER, STM32_PLL3_Q_DIVISOR); break; case STM32_SRC_PLL3_R: *rate = get_pllout_frequency(get_pllsrc_frequency(), STM32_PLL3_M_DIVISOR, STM32_PLL3_N_MULTIPLIER, STM32_PLL3_R_DIVISOR); break; #endif /* STM32_PLL3_ENABLED */ default: return -ENOTSUP; } return 0; } static struct clock_control_driver_api stm32_clock_control_api = { .on = stm32_clock_control_on, .off = stm32_clock_control_off, .get_rate = stm32_clock_control_get_subsys_rate, .configure = stm32_clock_control_configure, }; __unused static void set_up_fixed_clock_sources(void) { if (IS_ENABLED(STM32_HSE_ENABLED)) { /* Enable HSE oscillator */ if (IS_ENABLED(STM32_HSE_BYPASS)) { LL_RCC_HSE_EnableBypass(); } else { LL_RCC_HSE_DisableBypass(); } LL_RCC_HSE_Enable(); while (LL_RCC_HSE_IsReady() != 1) { } /* Check if we need to enable HSE clock security system or not */ #if STM32_HSE_CSS z_arm_nmi_set_handler(HAL_RCC_NMI_IRQHandler); LL_RCC_HSE_EnableCSS(); #endif /* STM32_HSE_CSS */ } if (IS_ENABLED(STM32_HSI_ENABLED)) { /* Enable HSI oscillator */ LL_RCC_HSI_Enable(); while (LL_RCC_HSI_IsReady() != 1) { } /* HSI divider configuration */ LL_RCC_HSI_SetDivider(hsi_divider(STM32_HSI_DIVISOR)); } if (IS_ENABLED(STM32_CSI_ENABLED)) { /* Enable CSI oscillator */ LL_RCC_CSI_Enable(); while (LL_RCC_CSI_IsReady() != 1) { } } if (IS_ENABLED(STM32_LSI_ENABLED)) { /* Enable LSI oscillator */ LL_RCC_LSI_Enable(); while (LL_RCC_LSI_IsReady() != 1) { } } if (IS_ENABLED(STM32_LSE_ENABLED)) { /* Enable backup domain */ LL_PWR_EnableBkUpAccess(); /* Configure driving capability */ LL_RCC_LSE_SetDriveCapability(STM32_LSE_DRIVING << RCC_BDCR_LSEDRV_Pos); if (IS_ENABLED(STM32_LSE_BYPASS)) { /* Configure LSE bypass */ LL_RCC_LSE_EnableBypass(); } /* Enable LSE oscillator */ LL_RCC_LSE_Enable(); while (LL_RCC_LSE_IsReady() != 1) { } } if (IS_ENABLED(STM32_HSI48_ENABLED)) { LL_RCC_HSI48_Enable(); while (LL_RCC_HSI48_IsReady() != 1) { } } } /* * Unconditionally switch the system clock source to HSI. */ __unused static void stm32_clock_switch_to_hsi(void) { /* Enable HSI if not enabled */ if (LL_RCC_HSI_IsReady() != 1) { /* Enable HSI */ LL_RCC_HSI_Enable(); while (LL_RCC_HSI_IsReady() != 1) { /* Wait for HSI ready */ } } /* Set HSI as SYSCLCK source */ LL_RCC_SetSysClkSource(LL_RCC_SYS_CLKSOURCE_HSI); while (LL_RCC_GetSysClkSource() != LL_RCC_SYS_CLKSOURCE_STATUS_HSI) { } } __unused static int set_up_plls(void) { #if defined(STM32_PLL_ENABLED) || defined(STM32_PLL2_ENABLED) || defined(STM32_PLL3_ENABLED) int r; uint32_t vco_input_range; uint32_t vco_output_range; /* * Case of chain-loaded applications: * Switch to HSI and disable the PLL before configuration. * (Switching to HSI makes sure we have a SYSCLK source in * case we're currently running from the PLL we're about to * turn off and reconfigure.) * */ if (LL_RCC_GetSysClkSource() == LL_RCC_SYS_CLKSOURCE_STATUS_PLL1) { stm32_clock_switch_to_hsi(); LL_RCC_SetAHBPrescaler(LL_RCC_SYSCLK_DIV_1); } LL_RCC_PLL1_Disable(); /* Configure PLL source */ /* Can be HSE , HSI 64Mhz/HSIDIV, CSI 4MHz*/ if (IS_ENABLED(STM32_PLL_SRC_HSE)) { /* Main PLL configuration and activation */ LL_RCC_PLL_SetSource(LL_RCC_PLLSOURCE_HSE); } else if (IS_ENABLED(STM32_PLL_SRC_CSI)) { /* Main PLL configuration and activation */ LL_RCC_PLL_SetSource(LL_RCC_PLLSOURCE_CSI); } else if (IS_ENABLED(STM32_PLL_SRC_HSI)) { /* Main PLL configuration and activation */ LL_RCC_PLL_SetSource(LL_RCC_PLLSOURCE_HSI); } else { return -ENOTSUP; } #if defined(STM32_PLL_ENABLED) r = get_vco_input_range(STM32_PLL_M_DIVISOR, &vco_input_range); if (r < 0) { return r; } vco_output_range = get_vco_output_range(vco_input_range); LL_RCC_PLL1_SetM(STM32_PLL_M_DIVISOR); LL_RCC_PLL1_SetVCOInputRange(vco_input_range); LL_RCC_PLL1_SetVCOOutputRange(vco_output_range); LL_RCC_PLL1_SetN(STM32_PLL_N_MULTIPLIER); /* FRACN disable DIVP,DIVQ,DIVR enable*/ LL_RCC_PLL1FRACN_Disable(); if (IS_ENABLED(STM32_PLL_P_ENABLED)) { LL_RCC_PLL1_SetP(STM32_PLL_P_DIVISOR); LL_RCC_PLL1P_Enable(); } if (IS_ENABLED(STM32_PLL_Q_ENABLED)) { LL_RCC_PLL1_SetQ(STM32_PLL_Q_DIVISOR); LL_RCC_PLL1Q_Enable(); } if (IS_ENABLED(STM32_PLL_R_ENABLED)) { LL_RCC_PLL1_SetR(STM32_PLL_R_DIVISOR); LL_RCC_PLL1R_Enable(); } LL_RCC_PLL1_Enable(); while (LL_RCC_PLL1_IsReady() != 1U) { } #endif /* STM32_PLL_ENABLED */ #if defined(STM32_PLL2_ENABLED) r = get_vco_input_range(STM32_PLL2_M_DIVISOR, &vco_input_range); if (r < 0) { return r; } vco_output_range = get_vco_output_range(vco_input_range); LL_RCC_PLL2_SetM(STM32_PLL2_M_DIVISOR); LL_RCC_PLL2_SetVCOInputRange(vco_input_range); LL_RCC_PLL2_SetVCOOutputRange(vco_output_range); LL_RCC_PLL2_SetN(STM32_PLL2_N_MULTIPLIER); LL_RCC_PLL2FRACN_Disable(); if (IS_ENABLED(STM32_PLL2_P_ENABLED)) { LL_RCC_PLL2_SetP(STM32_PLL2_P_DIVISOR); LL_RCC_PLL2P_Enable(); } if (IS_ENABLED(STM32_PLL2_Q_ENABLED)) { LL_RCC_PLL2_SetQ(STM32_PLL2_Q_DIVISOR); LL_RCC_PLL2Q_Enable(); } if (IS_ENABLED(STM32_PLL2_R_ENABLED)) { LL_RCC_PLL2_SetR(STM32_PLL2_R_DIVISOR); LL_RCC_PLL2R_Enable(); } LL_RCC_PLL2_Enable(); while (LL_RCC_PLL2_IsReady() != 1U) { } #endif /* STM32_PLL2_ENABLED */ #if defined(STM32_PLL3_ENABLED) r = get_vco_input_range(STM32_PLL3_M_DIVISOR, &vco_input_range); if (r < 0) { return r; } vco_output_range = get_vco_output_range(vco_input_range); LL_RCC_PLL3_SetM(STM32_PLL3_M_DIVISOR); LL_RCC_PLL3_SetVCOInputRange(vco_input_range); LL_RCC_PLL3_SetVCOOutputRange(vco_output_range); LL_RCC_PLL3_SetN(STM32_PLL3_N_MULTIPLIER); LL_RCC_PLL3FRACN_Disable(); if (IS_ENABLED(STM32_PLL3_P_ENABLED)) { LL_RCC_PLL3_SetP(STM32_PLL3_P_DIVISOR); LL_RCC_PLL3P_Enable(); } if (IS_ENABLED(STM32_PLL3_Q_ENABLED)) { LL_RCC_PLL3_SetQ(STM32_PLL3_Q_DIVISOR); LL_RCC_PLL3Q_Enable(); } if (IS_ENABLED(STM32_PLL3_R_ENABLED)) { LL_RCC_PLL3_SetR(STM32_PLL3_R_DIVISOR); LL_RCC_PLL3R_Enable(); } LL_RCC_PLL3_Enable(); while (LL_RCC_PLL3_IsReady() != 1U) { } #endif /* STM32_PLL3_ENABLED */ #else /* Init PLL source to None */ LL_RCC_PLL_SetSource(LL_RCC_PLLSOURCE_NONE); #endif /* STM32_PLL_ENABLED || STM32_PLL2_ENABLED || STM32_PLL3_ENABLED */ return 0; } int stm32_clock_control_init(const struct device *dev) { int r = 0; #if defined(CONFIG_CPU_CORTEX_M7) uint32_t old_hclk_freq; uint32_t new_hclk_freq; /* HW semaphore Clock enable */ #if defined(CONFIG_SOC_STM32H7A3XX) || defined(CONFIG_SOC_STM32H7A3XXQ) || \ defined(CONFIG_SOC_STM32H7B0XX) || defined(CONFIG_SOC_STM32H7B0XXQ) || \ defined(CONFIG_SOC_STM32H7B3XX) || defined(CONFIG_SOC_STM32H7B3XXQ) LL_AHB2_GRP1_EnableClock(LL_AHB2_GRP1_PERIPH_HSEM); #else LL_AHB4_GRP1_EnableClock(LL_AHB4_GRP1_PERIPH_HSEM); #endif z_stm32_hsem_lock(CFG_HW_RCC_SEMID, HSEM_LOCK_DEFAULT_RETRY); /* Configure MCO1/MCO2 based on Kconfig */ stm32_clock_control_mco_init(); /* Set up individual enabled clocks */ set_up_fixed_clock_sources(); /* Set up PLLs */ r = set_up_plls(); if (r < 0) { return r; } /* Configure Voltage scale to comply with the desired system frequency */ prepare_regulator_voltage_scale(); /* Current hclk value */ old_hclk_freq = get_hclk_frequency(); /* AHB is HCLK clock to configure */ new_hclk_freq = get_bus_clock(CONFIG_SYS_CLOCK_HW_CYCLES_PER_SEC, STM32_HPRE); /* Set flash latency */ /* AHB/AXI/HCLK clock is SYSCLK / HPRE */ /* If freq increases, set flash latency before any clock setting */ if (new_hclk_freq > old_hclk_freq) { LL_SetFlashLatency(new_hclk_freq); } /* Preset the prescalers prior to choosing SYSCLK */ /* Prevents APB clock to go over limits */ /* Set buses (Sys,AHB, APB1, APB2 & APB4) prescalers */ LL_RCC_SetSysPrescaler(sysclk_prescaler(STM32_D1CPRE)); LL_RCC_SetAHBPrescaler(ahb_prescaler(STM32_HPRE)); LL_RCC_SetAPB1Prescaler(apb1_prescaler(STM32_D2PPRE1)); LL_RCC_SetAPB2Prescaler(apb2_prescaler(STM32_D2PPRE2)); LL_RCC_SetAPB3Prescaler(apb3_prescaler(STM32_D1PPRE)); LL_RCC_SetAPB4Prescaler(apb4_prescaler(STM32_D3PPRE)); /* Set up sys clock */ if (IS_ENABLED(STM32_SYSCLK_SRC_PLL)) { /* Set PLL1 as System Clock Source */ LL_RCC_SetSysClkSource(LL_RCC_SYS_CLKSOURCE_PLL1); while (LL_RCC_GetSysClkSource() != LL_RCC_SYS_CLKSOURCE_STATUS_PLL1) { } } else if (IS_ENABLED(STM32_SYSCLK_SRC_HSE)) { /* Set sysclk source to HSE */ LL_RCC_SetSysClkSource(LL_RCC_SYS_CLKSOURCE_HSE); while (LL_RCC_GetSysClkSource() != LL_RCC_SYS_CLKSOURCE_STATUS_HSE) { } } else if (IS_ENABLED(STM32_SYSCLK_SRC_HSI)) { /* Set sysclk source to HSI */ stm32_clock_switch_to_hsi(); } else if (IS_ENABLED(STM32_SYSCLK_SRC_CSI)) { /* Set sysclk source to CSI */ LL_RCC_SetSysClkSource(LL_RCC_SYS_CLKSOURCE_CSI); while (LL_RCC_GetSysClkSource() != LL_RCC_SYS_CLKSOURCE_STATUS_CSI) { } } else { return -ENOTSUP; } /* Set FLASH latency */ /* AHB/AXI/HCLK clock is SYSCLK / HPRE */ /* If freq not increased, set flash latency after all clock setting */ if (new_hclk_freq <= old_hclk_freq) { LL_SetFlashLatency(new_hclk_freq); } optimize_regulator_voltage_scale(CONFIG_SYS_CLOCK_HW_CYCLES_PER_SEC); z_stm32_hsem_unlock(CFG_HW_RCC_SEMID); #endif /* CONFIG_CPU_CORTEX_M7 */ ARG_UNUSED(dev); /* Update CMSIS variable */ SystemCoreClock = CONFIG_SYS_CLOCK_HW_CYCLES_PER_SEC; return r; } #if defined(STM32_HSE_CSS) void __weak stm32_hse_css_callback(void) {} /* Called by the HAL in response to an HSE CSS interrupt */ void HAL_RCC_CSSCallback(void) { stm32_hse_css_callback(); } #endif /** * @brief RCC device, note that priority is intentionally set to 1 so * that the device init runs just after SOC init */ DEVICE_DT_DEFINE(DT_NODELABEL(rcc), &stm32_clock_control_init, NULL, NULL, NULL, PRE_KERNEL_1, CONFIG_CLOCK_CONTROL_INIT_PRIORITY, &stm32_clock_control_api);