/* * Copyright (c) 2015, Freescale Semiconductor, Inc. * Copyright 2016 - 2020, NXP * All rights reserved. * * SPDX-License-Identifier: BSD-3-Clause */ #include "fsl_clock.h" /******************************************************************************* * Definitions ******************************************************************************/ /* Component ID definition, used by tools. */ #ifndef FSL_COMPONENT_ID #define FSL_COMPONENT_ID "platform.drivers.clock" #endif #define SCG_SIRC_LOW_RANGE_FREQ 2000000U /* Slow IRC low range clock frequency. */ #define SCG_SIRC_HIGH_RANGE_FREQ 8000000U /* Slow IRC high range clock frequency. */ #define SCG_FIRC_FREQ0 48000000U /* Fast IRC trimed clock frequency(48MHz). */ #define SCG_LPFLL_FREQ0 48000000U /* LPFLL trimed clock frequency(48MHz). */ #define SCG_CSR_SCS_VAL ((SCG->CSR & SCG_CSR_SCS_MASK) >> SCG_CSR_SCS_SHIFT) #define SCG_SOSCDIV_SOSCDIV2_VAL ((SCG->SOSCDIV & SCG_SOSCDIV_SOSCDIV2_MASK) >> SCG_SOSCDIV_SOSCDIV2_SHIFT) #define SCG_SIRCDIV_SIRCDIV2_VAL ((SCG->SIRCDIV & SCG_SIRCDIV_SIRCDIV2_MASK) >> SCG_SIRCDIV_SIRCDIV2_SHIFT) #define SCG_FIRCDIV_FIRCDIV2_VAL ((SCG->FIRCDIV & SCG_FIRCDIV_FIRCDIV2_MASK) >> SCG_FIRCDIV_FIRCDIV2_SHIFT) #define SCG_LPFLLDIV_LPFLLDIV2_VAL ((SCG->LPFLLDIV & SCG_LPFLLDIV_LPFLLDIV2_MASK) >> SCG_LPFLLDIV_LPFLLDIV2_SHIFT) #define SCG_SIRCCFG_RANGE_VAL ((SCG->SIRCCFG & SCG_SIRCCFG_RANGE_MASK) >> SCG_SIRCCFG_RANGE_SHIFT) #define SCG_FIRCCFG_RANGE_VAL ((SCG->FIRCCFG & SCG_FIRCCFG_RANGE_MASK) >> SCG_FIRCCFG_RANGE_SHIFT) #define SCG_LPFLLCFG_FSEL_VAL ((SCG->LPFLLCFG & SCG_LPFLLCFG_FSEL_MASK) >> SCG_LPFLLCFG_FSEL_SHIFT) #define PCC_PCS_VAL(reg) (((reg)&PCC_CLKCFG_PCS_MASK) >> PCC_CLKCFG_PCS_SHIFT) /******************************************************************************* * Variables ******************************************************************************/ /* External XTAL0 (OSC0) clock frequency. */ volatile uint32_t g_xtal0Freq; /******************************************************************************* * Prototypes ******************************************************************************/ /******************************************************************************* * Code ******************************************************************************/ /*! * brief Get the external reference clock frequency (ERCLK). * * return Clock frequency in Hz. */ uint32_t CLOCK_GetErClkFreq(void) { if ((SCG->SOSCCSR & SCG_SOSCCSR_SOSCEN_MASK) != 0U) { /* Please call CLOCK_SetXtal0Freq base on board setting before using OSC0 clock. */ assert(g_xtal0Freq); return g_xtal0Freq; } else { return 0U; } } /*! * brief Get the flash clock frequency. * * return Clock frequency in Hz. */ uint32_t CLOCK_GetFlashClkFreq(void) { return CLOCK_GetSysClkFreq(kSCG_SysClkSlow); } /*! * brief Get the bus clock frequency. * * return Clock frequency in Hz. */ uint32_t CLOCK_GetBusClkFreq(void) { return CLOCK_GetSysClkFreq(kSCG_SysClkSlow); } /*! * brief Get the core clock or system clock frequency. * * return Clock frequency in Hz. */ uint32_t CLOCK_GetCoreSysClkFreq(void) { return CLOCK_GetSysClkFreq(kSCG_SysClkCore); } /*! * brief Gets the clock frequency for a specific clock name. * * This function checks the current clock configurations and then calculates * the clock frequency for a specific clock name defined in clock_name_t. * * param clockName Clock names defined in clock_name_t * return Clock frequency value in hertz */ uint32_t CLOCK_GetFreq(clock_name_t clockName) { uint32_t freq; switch (clockName) { case kCLOCK_CoreSysClk: freq = CLOCK_GetSysClkFreq(kSCG_SysClkCore); break; case kCLOCK_BusClk: case kCLOCK_FlashClk: freq = CLOCK_GetSysClkFreq(kSCG_SysClkSlow); break; case kCLOCK_ScgSysOscClk: freq = CLOCK_GetSysOscFreq(); break; case kCLOCK_ScgSircClk: freq = CLOCK_GetSircFreq(); break; case kCLOCK_ScgFircClk: freq = CLOCK_GetFircFreq(); break; case kCLOCK_ScgLpFllClk: freq = CLOCK_GetLpFllFreq(); break; case kCLOCK_ScgSysOscAsyncDiv2Clk: freq = CLOCK_GetSysOscAsyncFreq(kSCG_AsyncDiv2Clk); break; case kCLOCK_ScgSircAsyncDiv2Clk: freq = CLOCK_GetSircAsyncFreq(kSCG_AsyncDiv2Clk); break; case kCLOCK_ScgFircAsyncDiv2Clk: freq = CLOCK_GetFircAsyncFreq(kSCG_AsyncDiv2Clk); break; case kCLOCK_ScgLpFllAsyncDiv2Clk: freq = CLOCK_GetLpFllAsyncFreq(kSCG_AsyncDiv2Clk); break; case kCLOCK_LpoClk: freq = LPO_CLK_FREQ; break; case kCLOCK_ErClk: freq = CLOCK_GetErClkFreq(); break; default: freq = 0U; break; } return freq; } /*! * brief Gets the clock frequency for a specific IP module. * * This function gets the IP module clock frequency based on PCC registers. It is * only used for the IP modules which could select clock source by PCC[PCS]. * * param name Which peripheral to get, see \ref clock_ip_name_t. * return Clock frequency value in hertz */ uint32_t CLOCK_GetIpFreq(clock_ip_name_t name) { uint32_t reg = (*(volatile uint32_t *)((uint32_t)name)); scg_async_clk_t asycClk; uint32_t freq; assert(reg & PCC_CLKCFG_PR_MASK); asycClk = kSCG_AsyncDiv2Clk; switch (PCC_PCS_VAL(reg)) { case (uint32_t)kCLOCK_IpSrcSysOscAsync: freq = CLOCK_GetSysOscAsyncFreq(asycClk); break; case (uint32_t)kCLOCK_IpSrcSircAsync: freq = CLOCK_GetSircAsyncFreq(asycClk); break; case (uint32_t)kCLOCK_IpSrcFircAsync: freq = CLOCK_GetFircAsyncFreq(asycClk); break; case (uint32_t)kCLOCK_IpSrcLpFllAsync: freq = CLOCK_GetLpFllAsyncFreq(asycClk); break; default: freq = 0U; break; } return freq; } /*! * brief Gets the SCG system clock frequency. * * This function gets the SCG system clock frequency. These clocks are used for * core, platform, external, and bus clock domains. * * param type Which type of clock to get, core clock or slow clock. * return Clock frequency. */ uint32_t CLOCK_GetSysClkFreq(scg_sys_clk_t type) { uint32_t freq; scg_sys_clk_config_t sysClkConfig; CLOCK_GetCurSysClkConfig(&sysClkConfig); /* Get the main clock for SoC platform. */ switch (sysClkConfig.src) { case (uint8_t)kSCG_SysClkSrcSysOsc: freq = CLOCK_GetSysOscFreq(); break; case (uint8_t)kSCG_SysClkSrcSirc: freq = CLOCK_GetSircFreq(); break; case (uint8_t)kSCG_SysClkSrcFirc: freq = CLOCK_GetFircFreq(); break; case (uint8_t)kSCG_SysClkSrcLpFll: freq = CLOCK_GetLpFllFreq(); break; default: freq = 0U; break; } freq /= ((uint32_t)sysClkConfig.divCore + 1UL); /* divided by the DIVCORE firstly. */ if (kSCG_SysClkSlow == type) { freq /= ((uint32_t)sysClkConfig.divSlow + 1UL); } else { /* Add comment to prevent the case of MISRA C-2012 rule 15.7 */ } return freq; } /*! * brief Initializes the SCG system OSC. * * This function enables the SCG system OSC clock according to the * configuration. * * param config Pointer to the configuration structure. * retval kStatus_Success System OSC is initialized. * retval kStatus_SCG_Busy System OSC has been enabled and is used by the system clock. * retval kStatus_ReadOnly System OSC control register is locked. * * note This function can't detect whether the system OSC has been enabled and * used by an IP. */ status_t CLOCK_InitSysOsc(const scg_sosc_config_t *config) { assert(config); uint8_t range = 0U; /* SCG_SOSCCFG[RANGE] */ status_t status; uint8_t tmp8; /* If crystal oscillator used, need to get RANGE value base on frequency. */ if (kSCG_SysOscModeExt != config->workMode) { if ((config->freq >= 32768U) && (config->freq <= 40000U)) { range = 1U; } else if ((config->freq >= 1000000U) && (config->freq <= 8000000U)) { range = 2U; } else if ((config->freq >= 8000000U) && (config->freq <= 32000000U)) { range = 3U; } else { return kStatus_InvalidArgument; } } /* De-init the SOSC first. */ status = CLOCK_DeinitSysOsc(); if (kStatus_Success != status) { return status; } /* Now start to set up OSC clock. */ /* Step 1. Setup dividers. */ SCG->SOSCDIV = SCG_SOSCDIV_SOSCDIV2(config->div2); /* Step 2. Set OSC configuration. */ SCG->SOSCCFG = (uint32_t)(config->workMode) | SCG_SOSCCFG_RANGE(range); /* Step 3. Enable clock. */ /* SCG->SOSCCSR = SCG_SOSCCSR_SOSCEN_MASK | (config->enableMode); */ tmp8 = config->enableMode; tmp8 |= SCG_SOSCCSR_SOSCEN_MASK; SCG->SOSCCSR = tmp8; /* Step 4. Wait for OSC clock to be valid. */ while (0UL == (SCG->SOSCCSR & SCG_SOSCCSR_SOSCVLD_MASK)) { } /* Step 5. Enabe monitor. */ SCG->SOSCCSR |= (uint32_t)config->monitorMode; return kStatus_Success; } /*! * brief De-initializes the SCG system OSC. * * This function disables the SCG system OSC clock. * * retval kStatus_Success System OSC is deinitialized. * retval kStatus_SCG_Busy System OSC is used by the system clock. * retval kStatus_ReadOnly System OSC control register is locked. * * note This function can't detect whether the system OSC is used by an IP. */ status_t CLOCK_DeinitSysOsc(void) { uint32_t reg = SCG->SOSCCSR; status_t status; /* If clock is used by system, return error. */ if ((reg & SCG_SOSCCSR_SOSCSEL_MASK) != 0UL) { status = kStatus_SCG_Busy; } /* If configure register is locked, return error. */ else if ((reg & SCG_SOSCCSR_LK_MASK) != 0UL) { status = kStatus_ReadOnly; } else { SCG->SOSCCSR = SCG_SOSCCSR_SOSCERR_MASK; status = kStatus_Success; } return status; } /*! * brief Gets the SCG system OSC clock frequency (SYSOSC). * * return Clock frequency; If the clock is invalid, returns 0. */ uint32_t CLOCK_GetSysOscFreq(void) { uint32_t freq; if ((SCG->SOSCCSR & SCG_SOSCCSR_SOSCVLD_MASK) != 0UL) /* System OSC clock is valid. */ { /* Please call CLOCK_SetXtal0Freq base on board setting before using OSC0 clock. */ assert(g_xtal0Freq); freq = g_xtal0Freq; } else { freq = 0U; } return freq; } /*! * brief Gets the SCG asynchronous clock frequency from the system OSC. * * param type The asynchronous clock type. * return Clock frequency; If the clock is invalid, returns 0. */ uint32_t CLOCK_GetSysOscAsyncFreq(scg_async_clk_t type) { uint32_t oscFreq = CLOCK_GetSysOscFreq(); uint32_t divider = 0U; uint32_t freq; /* Get divider. */ if (oscFreq != 0UL) { switch (type) { case kSCG_AsyncDiv2Clk: /* SOSCDIV2_CLK. */ divider = SCG_SOSCDIV_SOSCDIV2_VAL; break; default: divider = 0U; break; } } if (divider != 0U) { freq = (oscFreq >> (divider - 1U)); } else /* Output disabled. */ { freq = 0U; } return freq; } /*! * brief Initializes the SCG slow IRC clock. * * This function enables the SCG slow IRC clock according to the * configuration. * * param config Pointer to the configuration structure. * retval kStatus_Success SIRC is initialized. * retval kStatus_SCG_Busy SIRC has been enabled and is used by system clock. * retval kStatus_ReadOnly SIRC control register is locked. * * note This function can't detect whether the system OSC has been enabled and * used by an IP. */ status_t CLOCK_InitSirc(const scg_sirc_config_t *config) { assert(config); status_t status; /* De-init the SIRC first. */ status = CLOCK_DeinitSirc(); if (status == kStatus_Success) { /* Now start to set up SIRC clock. */ /* Step 1. Setup dividers. */ SCG->SIRCDIV = SCG_SIRCDIV_SIRCDIV2(config->div2); /* Step 2. Set SIRC configuration. */ SCG->SIRCCFG = SCG_SIRCCFG_RANGE(config->range); /* Step 3. Enable clock. */ SCG->SIRCCSR = SCG_SIRCCSR_SIRCEN_MASK | config->enableMode; /* Step 4. Wait for SIRC clock to be valid. */ while (0UL == (SCG->SIRCCSR & SCG_SIRCCSR_SIRCVLD_MASK)) { } } return status; } /*! * brief De-initializes the SCG slow IRC. * * This function disables the SCG slow IRC. * * retval kStatus_Success SIRC is deinitialized. * retval kStatus_SCG_Busy SIRC is used by system clock. * retval kStatus_ReadOnly SIRC control register is locked. * * note This function can't detect whether the SIRC is used by an IP. */ status_t CLOCK_DeinitSirc(void) { uint32_t reg = SCG->SIRCCSR; status_t status; /* If clock is used by system, return error. */ if ((reg & SCG_SIRCCSR_SIRCSEL_MASK) != 0UL) { status = kStatus_SCG_Busy; } /* If configure register is locked, return error. */ else if ((reg & SCG_SIRCCSR_LK_MASK) != 0UL) { status = kStatus_ReadOnly; } else { SCG->SIRCCSR = 0U; status = kStatus_Success; } return status; } /*! * brief Gets the SCG SIRC clock frequency. * * return Clock frequency; If the clock is invalid, returns 0. */ uint32_t CLOCK_GetSircFreq(void) { static const uint32_t sircFreq[] = {SCG_SIRC_LOW_RANGE_FREQ, SCG_SIRC_HIGH_RANGE_FREQ}; uint32_t freq; if ((SCG->SIRCCSR & SCG_SIRCCSR_SIRCVLD_MASK) != 0UL) /* SIRC is valid. */ { freq = sircFreq[SCG_SIRCCFG_RANGE_VAL]; } else { freq = 0U; } return freq; } /*! * brief Gets the SCG asynchronous clock frequency from the SIRC. * * param type The asynchronous clock type. * return Clock frequency; If the clock is invalid, returns 0. */ uint32_t CLOCK_GetSircAsyncFreq(scg_async_clk_t type) { uint32_t sircFreq = CLOCK_GetSircFreq(); uint32_t divider = 0U; uint32_t freq; /* Get divider. */ if (sircFreq != 0UL) { switch (type) { case kSCG_AsyncDiv2Clk: /* SIRCDIV2_CLK. */ divider = SCG_SIRCDIV_SIRCDIV2_VAL; break; default: divider = 0U; break; } } if (divider != 0UL) { freq = (sircFreq >> (divider - 1U)); } else /* Output disabled. */ { freq = 0U; } return freq; } /*! * brief Initializes the SCG fast IRC clock. * * This function enables the SCG fast IRC clock according to the configuration. * * param config Pointer to the configuration structure. * retval kStatus_Success FIRC is initialized. * retval kStatus_SCG_Busy FIRC has been enabled and is used by the system clock. * retval kStatus_ReadOnly FIRC control register is locked. * * note This function can't detect whether the FIRC has been enabled and * used by an IP. */ status_t CLOCK_InitFirc(const scg_firc_config_t *config) { assert(config); status_t status; /* De-init the FIRC first. */ status = CLOCK_DeinitFirc(); if (kStatus_Success != status) { return status; } /* Now start to set up FIRC clock. */ /* Step 1. Setup dividers. */ SCG->FIRCDIV = SCG_FIRCDIV_FIRCDIV2(config->div2); /* Step 2. Set FIRC configuration. */ SCG->FIRCCFG = SCG_FIRCCFG_RANGE(config->range); /* Step 3. Set trimming configuration. */ if ((config->trimConfig) != NULL) { SCG->FIRCTCFG = SCG_FIRCTCFG_TRIMDIV(config->trimConfig->trimDiv) | SCG_FIRCTCFG_TRIMSRC(config->trimConfig->trimSrc); /* TODO: Write FIRCSTAT cause bus error: TKT266932. */ if (kSCG_FircTrimNonUpdate == config->trimConfig->trimMode) { SCG->FIRCSTAT = SCG_FIRCSTAT_TRIMCOAR(config->trimConfig->trimCoar) | SCG_FIRCSTAT_TRIMFINE(config->trimConfig->trimFine); } /* trim mode. */ SCG->FIRCCSR = (uint32_t)(config->trimConfig->trimMode); if ((SCG->FIRCCSR & SCG_FIRCCSR_FIRCERR_MASK) != 0UL) { return kStatus_Fail; } } /* Step 4. Enable clock. */ SCG->FIRCCSR |= (SCG_FIRCCSR_FIRCEN_MASK | config->enableMode); /* Step 5. Wait for FIRC clock to be valid. */ while (0UL == (SCG->FIRCCSR & SCG_FIRCCSR_FIRCVLD_MASK)) { } return kStatus_Success; } /*! * brief De-initializes the SCG fast IRC. * * This function disables the SCG fast IRC. * * retval kStatus_Success FIRC is deinitialized. * retval kStatus_SCG_Busy FIRC is used by the system clock. * retval kStatus_ReadOnly FIRC control register is locked. * * note This function can't detect whether the FIRC is used by an IP. */ status_t CLOCK_DeinitFirc(void) { uint32_t reg = SCG->FIRCCSR; status_t status = kStatus_Success; /* If clock is used by system, return error. */ if ((reg & SCG_FIRCCSR_FIRCSEL_MASK) != 0UL) { status = kStatus_SCG_Busy; } /* If configure register is locked, return error. */ else if ((reg & SCG_FIRCCSR_LK_MASK) != 0UL) { status = kStatus_ReadOnly; } else { SCG->FIRCCSR = SCG_FIRCCSR_FIRCERR_MASK; } return status; } /*! * brief Gets the SCG FIRC clock frequency. * * return Clock frequency; If the clock is invalid, returns 0. */ uint32_t CLOCK_GetFircFreq(void) { uint32_t freq; static const uint32_t fircFreq[] = { SCG_FIRC_FREQ0, }; if ((SCG->FIRCCSR & SCG_FIRCCSR_FIRCVLD_MASK) != 0UL) /* FIRC is valid. */ { freq = fircFreq[SCG_FIRCCFG_RANGE_VAL]; } else { freq = 0U; } return freq; } /*! * brief Gets the SCG asynchronous clock frequency from the FIRC. * * param type The asynchronous clock type. * return Clock frequency; If the clock is invalid, returns 0. */ uint32_t CLOCK_GetFircAsyncFreq(scg_async_clk_t type) { uint32_t fircFreq = CLOCK_GetFircFreq(); uint32_t divider = 0U; uint32_t freq; /* Get divider. */ if (fircFreq != 0UL) { switch (type) { case kSCG_AsyncDiv2Clk: /* FIRCDIV2_CLK. */ divider = SCG_FIRCDIV_FIRCDIV2_VAL; break; default: divider = 0U; break; } } if (divider != 0U) { freq = (fircFreq >> (divider - 1U)); } else /* Output disabled. */ { freq = 0U; } return freq; } /*! * brief Initializes the SCG LPFLL clock. * * This function enables the SCG LPFLL clock according to the configuration. * * param config Pointer to the configuration structure. * retval kStatus_Success LPFLL is initialized. * retval kStatus_SCG_Busy LPFLL has been enabled and is used by the system clock. * retval kStatus_ReadOnly LPFLL control register is locked. * * note This function can't detect whether the LPFLL has been enabled and * used by an IP. */ status_t CLOCK_InitLpFll(const scg_lpfll_config_t *config) { assert(config); status_t status; /* De-init the LPFLL first. */ status = CLOCK_DeinitLpFll(); if (kStatus_Success != status) { return status; } /* Now start to set up LPFLL clock. */ /* Step 1. Setup dividers. */ SCG->LPFLLDIV = SCG_LPFLLDIV_LPFLLDIV2(config->div2); /* Step 2. Set LPFLL configuration. */ SCG->LPFLLCFG = SCG_LPFLLCFG_FSEL(config->range); /* Step 3. Set trimming configuration. */ if ((config->trimConfig) != NULL) { SCG->LPFLLTCFG = SCG_LPFLLTCFG_TRIMDIV(config->trimConfig->trimDiv) | SCG_LPFLLTCFG_TRIMSRC(config->trimConfig->trimSrc) | SCG_LPFLLTCFG_LOCKW2LSB(config->trimConfig->lockMode); if (kSCG_LpFllTrimNonUpdate == config->trimConfig->trimMode) { SCG->LPFLLSTAT = config->trimConfig->trimValue; } /* Trim mode. */ SCG->LPFLLCSR = (uint32_t)(config->trimConfig->trimMode); if ((SCG->LPFLLCSR & SCG_LPFLLCSR_LPFLLERR_MASK) != 0UL) { return kStatus_Fail; } } /* Step 4. Enable clock. */ SCG->LPFLLCSR |= ((uint32_t)SCG_LPFLLCSR_LPFLLEN_MASK | config->enableMode); /* Step 5. Wait for LPFLL clock to be valid. */ while (0UL == (SCG->LPFLLCSR & SCG_LPFLLCSR_LPFLLVLD_MASK)) { } /* Step 6. Wait for LPFLL trim lock. */ if (((config->trimConfig) != NULL) && (kSCG_LpFllTrimUpdate == config->trimConfig->trimMode)) { while (0UL == (SCG->LPFLLCSR & SCG_LPFLLCSR_LPFLLTRMLOCK_MASK)) { } } return kStatus_Success; } /*! * brief De-initializes the SCG LPFLL. * * This function disables the SCG LPFLL. * * retval kStatus_Success LPFLL is deinitialized. * retval kStatus_SCG_Busy LPFLL is used by the system clock. * retval kStatus_ReadOnly LPFLL control register is locked. * * note This function can't detect whether the LPFLL is used by an IP. */ status_t CLOCK_DeinitLpFll(void) { uint32_t reg = SCG->LPFLLCSR; status_t status; /* If clock is used by system, return error. */ if ((reg & SCG_LPFLLCSR_LPFLLSEL_MASK) != 0UL) { status = kStatus_SCG_Busy; } /* If configure register is locked, return error. */ else if ((reg & SCG_LPFLLCSR_LK_MASK) != 0UL) { status = kStatus_ReadOnly; } else { SCG->LPFLLCSR = SCG_LPFLLCSR_LPFLLERR_MASK; status = kStatus_Success; } return status; } /*! * brief Gets the SCG LPFLL clock frequency. * * return Clock frequency in Hz; If the clock is invalid, returns 0. */ uint32_t CLOCK_GetLpFllFreq(void) { uint32_t freq; static const uint32_t lpfllFreq[] = { SCG_LPFLL_FREQ0, }; if ((SCG->LPFLLCSR & SCG_LPFLLCSR_LPFLLVLD_MASK) != 0UL) /* LPFLL is valid. */ { freq = lpfllFreq[SCG_LPFLLCFG_FSEL_VAL]; } else { freq = 0U; } return freq; } /*! * brief Gets the SCG asynchronous clock frequency from the LPFLL. * * param type The asynchronous clock type. * return Clock frequency in Hz; If the clock is invalid, returns 0. */ uint32_t CLOCK_GetLpFllAsyncFreq(scg_async_clk_t type) { uint32_t lpfllFreq = CLOCK_GetLpFllFreq(); uint32_t divider = 0U; uint32_t freq; /* Get divider. */ if (lpfllFreq != 0UL) { switch (type) { case kSCG_AsyncDiv2Clk: /* LPFLLDIV2_CLK. */ divider = SCG_LPFLLDIV_LPFLLDIV2_VAL; break; default: divider = 0U; break; } } if (divider != 0UL) { freq = lpfllFreq >> (divider - 1U); } else /* Output disabled. */ { freq = 0U; } return freq; }