/* * Copyright 2019 NXP * All rights reserved. * * SPDX-License-Identifier: BSD-3-Clause */ #include "fsl_common.h" #include "fsl_clock.h" /******************************************************************************* * Definitions ******************************************************************************/ /* Component ID definition, used by tools. */ #ifndef FSL_COMPONENT_ID #define FSL_COMPONENT_ID "platform.drivers.clock" #endif #define FracPLL_GNRL_CTL_Offset (0U) #define FracPLL_FDIV_CTL0_Offset (4U) #define FracPLL_FDIV_CTL1_Offset (8U) #define IntegerPLL_GNRL_CTL_Offset (0U) #define IntegerPLL_DIV_CTL_Offset (4U) /******************************************************************************* * Prototypes ******************************************************************************/ /******************************************************************************* * Variables ******************************************************************************/ /******************************************************************************* * Code ******************************************************************************/ /*! * 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; uint32_t temp; switch (clockName) { case kCLOCK_CoreM7Clk: freq = CLOCK_GetCoreM7Freq(); break; case kCLOCK_AxiClk: freq = CLOCK_GetAxiFreq(); break; case kCLOCK_AhbClk: freq = CLOCK_GetAhbFreq(); break; case kCLOCK_IpgClk: { temp = CLOCK_GetAhbFreq(); freq = temp / CLOCK_GetRootPostDivider(kCLOCK_RootIpg); break; } case kCLOCK_EnetIpgClk: freq = CLOCK_GetEnetAxiFreq(); break; case kCLOCK_Osc24MClk: freq = OSC24M_CLK_FREQ; break; case kCLOCK_ArmPllClk: freq = CLOCK_GetPllFreq(kCLOCK_ArmPllCtrl); break; case kCLOCK_DramPllClk: freq = CLOCK_GetPllFreq(kCLOCK_DramPllCtrl); break; case kCLOCK_VpuPllClk: freq = CLOCK_GetPllFreq(kCLOCK_VpuPllCtrl); break; case kCLOCK_SysPll1Clk: freq = CLOCK_GetPllFreq(kCLOCK_SystemPll1Ctrl); break; case kCLOCK_SysPll1Div2Clk: freq = CLOCK_GetPllFreq(kCLOCK_SystemPll1Ctrl) / 2U; break; case kCLOCK_SysPll1Div3Clk: freq = CLOCK_GetPllFreq(kCLOCK_SystemPll1Ctrl) / 3U; break; case kCLOCK_SysPll1Div4Clk: freq = CLOCK_GetPllFreq(kCLOCK_SystemPll1Ctrl) / 4U; break; case kCLOCK_SysPll1Div5Clk: freq = CLOCK_GetPllFreq(kCLOCK_SystemPll1Ctrl) / 5U; break; case kCLOCK_SysPll1Div6Clk: freq = CLOCK_GetPllFreq(kCLOCK_SystemPll1Ctrl) / 6U; break; case kCLOCK_SysPll1Div8Clk: freq = CLOCK_GetPllFreq(kCLOCK_SystemPll1Ctrl) / 8U; break; case kCLOCK_SysPll1Div10Clk: freq = CLOCK_GetPllFreq(kCLOCK_SystemPll1Ctrl) / 10U; break; case kCLOCK_SysPll1Div20Clk: freq = CLOCK_GetPllFreq(kCLOCK_SystemPll1Ctrl) / 20U; break; case kCLOCK_SysPll2Clk: freq = CLOCK_GetPllFreq(kCLOCK_SystemPll2Ctrl); break; case kCLOCK_SysPll2Div2Clk: freq = CLOCK_GetPllFreq(kCLOCK_SystemPll2Ctrl) / 2U; break; case kCLOCK_SysPll2Div3Clk: freq = CLOCK_GetPllFreq(kCLOCK_SystemPll2Ctrl) / 3U; break; case kCLOCK_SysPll2Div4Clk: freq = CLOCK_GetPllFreq(kCLOCK_SystemPll2Ctrl) / 4U; break; case kCLOCK_SysPll2Div5Clk: freq = CLOCK_GetPllFreq(kCLOCK_SystemPll2Ctrl) / 5U; break; case kCLOCK_SysPll2Div6Clk: freq = CLOCK_GetPllFreq(kCLOCK_SystemPll2Ctrl) / 6U; break; case kCLOCK_SysPll2Div8Clk: freq = CLOCK_GetPllFreq(kCLOCK_SystemPll2Ctrl) / 8U; break; case kCLOCK_SysPll2Div10Clk: freq = CLOCK_GetPllFreq(kCLOCK_SystemPll2Ctrl) / 10U; break; case kCLOCK_SysPll2Div20Clk: freq = CLOCK_GetPllFreq(kCLOCK_SystemPll2Ctrl) / 20U; break; case kCLOCK_SysPll3Clk: freq = CLOCK_GetPllFreq(kCLOCK_SystemPll3Ctrl); break; case kCLOCK_AudioPll1Clk: freq = CLOCK_GetPllFreq(kCLOCK_AudioPll1Ctrl); break; case kCLOCK_AudioPll2Clk: freq = CLOCK_GetPllFreq(kCLOCK_AudioPll2Ctrl); break; case kCLOCK_VideoPll1Clk: freq = CLOCK_GetPllFreq(kCLOCK_VideoPll1Ctrl); break; case kCLOCK_ExtClk1: case kCLOCK_ExtClk2: case kCLOCK_ExtClk3: case kCLOCK_ExtClk4: freq = CLKPAD_FREQ; break; default: freq = 0U; break; } return freq; } /*! * brief Gets the frequency of selected clock root. * * param clockRoot The clock root used to get the frequency, please refer to @ref clock_root_t. * return The frequency of selected clock root. */ uint32_t CLOCK_GetClockRootFreq(clock_root_t clockRoot) { static const clock_name_t clockRootSourceArray[][8] = CLOCK_ROOT_SOURCE; static const clock_root_control_t clockRootControlArray[] = CLOCK_ROOT_CONTROL_TUPLE; clock_root_control_t clockRootControl = clockRootControlArray[(uint8_t)clockRoot]; uint32_t freq = 0U; uint32_t pre = CLOCK_GetRootPreDivider(clockRootControl); uint32_t post = CLOCK_GetRootPostDivider(clockRootControl); uint32_t mux = CLOCK_GetRootMux(clockRootControl); clock_name_t clockSourceName; clockSourceName = clockRootSourceArray[(uint8_t)clockRoot][mux]; assert(clockSourceName != kCLOCK_NoneName); freq = CLOCK_GetFreq(clockSourceName); if (clockRoot == kCLOCK_IpgClkRoot) { freq /= CLOCK_GetRootPostDivider(kCLOCK_RootIpg); } if (clockRoot == kCLOCK_AudioIpgClkRoot) { freq /= CLOCK_GetRootPostDivider(kCLOCK_RootAudioIpg); } return freq / pre / post; } /*! * brief Get the CCM Cortex M7 core frequency. * * return Clock frequency; If the clock is invalid, returns 0. */ uint32_t CLOCK_GetCoreM7Freq(void) { uint32_t freq; uint32_t pre = CLOCK_GetRootPreDivider(kCLOCK_RootM7); uint32_t post = CLOCK_GetRootPostDivider(kCLOCK_RootM7); switch (CLOCK_GetRootMux(kCLOCK_RootM7)) { case (uint32_t)kCLOCK_M7RootmuxOsc24M: freq = OSC24M_CLK_FREQ; break; case (uint32_t)kCLOCK_M7RootmuxSysPll2Div5: freq = CLOCK_GetPllFreq(kCLOCK_SystemPll2Ctrl) / 5U; break; case (uint32_t)kCLOCK_M7RootmuxSysPll2Div4: freq = CLOCK_GetPllFreq(kCLOCK_SystemPll2Ctrl) / 4U; break; case (uint32_t)kCLOCK_M7RootmuxSysVpuPll: freq = CLOCK_GetPllFreq(kCLOCK_VpuPllCtrl); break; case (uint32_t)kCLOCK_M7RootmuxSysPll1: freq = CLOCK_GetPllFreq(kCLOCK_SystemPll1Ctrl); break; case (uint32_t)kCLOCK_M7RootmuxAudioPll1: freq = CLOCK_GetPllFreq(kCLOCK_AudioPll1Ctrl); break; case (uint32_t)kCLOCK_M7RootmuxVideoPll1: freq = CLOCK_GetPllFreq(kCLOCK_VideoPll1Ctrl); break; case (uint32_t)kCLOCK_M7RootmuxSysPll3: freq = CLOCK_GetPllFreq(kCLOCK_SystemPll3Ctrl); break; default: freq = 0U; break; } return freq / pre / post; } /*! * brief Get the CCM Axi bus frequency. * * return Clock frequency; If the clock is invalid, returns 0. */ uint32_t CLOCK_GetAxiFreq(void) { uint32_t freq; uint32_t pre = CLOCK_GetRootPreDivider(kCLOCK_RootMainAxi); uint32_t post = CLOCK_GetRootPostDivider(kCLOCK_RootMainAxi); switch (CLOCK_GetRootMux(kCLOCK_RootMainAxi)) { case (uint32_t)kCLOCK_AxiRootmuxOsc24M: freq = OSC24M_CLK_FREQ; break; case (uint32_t)kCLOCK_AxiRootmuxSysPll2Div3: freq = CLOCK_GetPllFreq(kCLOCK_SystemPll2Ctrl) / 3U; break; case (uint32_t)kCLOCK_AxiRootmuxSysPll2Div4: freq = CLOCK_GetPllFreq(kCLOCK_SystemPll2Ctrl) / 4U; break; case (uint32_t)kCLOCK_AxiRootmuxSysPll2: freq = CLOCK_GetPllFreq(kCLOCK_SystemPll2Ctrl); break; case (uint32_t)kCLOCK_AxiRootmuxAudioPll1: freq = CLOCK_GetPllFreq(kCLOCK_AudioPll1Ctrl); break; case (uint32_t)kCLOCK_AxiRootmuxVideoPll1: freq = CLOCK_GetPllFreq(kCLOCK_VideoPll1Ctrl); break; case (uint32_t)kCLOCK_AxiRootmuxSysPll1Div8: freq = CLOCK_GetPllFreq(kCLOCK_SystemPll1Ctrl) / 8UL; break; case (uint32_t)kCLOCK_AxiRootmuxSysPll1: freq = CLOCK_GetPllFreq(kCLOCK_SystemPll1Ctrl); break; default: freq = 0U; break; } return freq / pre / post; } /*! * brief Get the CCM Ahb bus frequency. * * return Clock frequency; If the clock is invalid, returns 0. */ uint32_t CLOCK_GetAhbFreq(void) { uint32_t freq; uint32_t pre = CLOCK_GetRootPreDivider(kCLOCK_RootAhb); uint32_t post = CLOCK_GetRootPostDivider(kCLOCK_RootAhb); switch (CLOCK_GetRootMux(kCLOCK_RootAhb)) { case (uint32_t)kCLOCK_AhbRootmuxOsc24M: freq = OSC24M_CLK_FREQ; break; case (uint32_t)kCLOCK_AhbRootmuxSysPll1Div6: freq = CLOCK_GetPllFreq(kCLOCK_SystemPll1Ctrl) / 6U; break; case (uint32_t)kCLOCK_AhbRootmuxSysPll1Div2: freq = CLOCK_GetPllFreq(kCLOCK_SystemPll1Ctrl) / 2U; break; case (uint32_t)kCLOCK_AhbRootmuxSysPll1: freq = CLOCK_GetPllFreq(kCLOCK_SystemPll1Ctrl); break; case (uint32_t)kCLOCK_AhbRootmuxSysPll2Div8: freq = CLOCK_GetPllFreq(kCLOCK_SystemPll2Ctrl) / 8U; break; case (uint32_t)kCLOCK_AhbRootmuxSysPll3: freq = CLOCK_GetPllFreq(kCLOCK_SystemPll3Ctrl); break; case (uint32_t)kCLOCK_AhbRootmuxAudioPll1: freq = CLOCK_GetPllFreq(kCLOCK_AudioPll1Ctrl); break; case (uint32_t)kCLOCK_AhbRootmuxVideoPll1: freq = CLOCK_GetPllFreq(kCLOCK_VideoPll1Ctrl); break; default: freq = 0U; break; } return freq / pre / post; } /*! * brief Get the CCM Enet AXI bus frequency. * * return Clock frequency; If the clock is invalid, returns 0. */ uint32_t CLOCK_GetEnetAxiFreq(void) { uint32_t freq; uint32_t pre = CLOCK_GetRootPreDivider(kCLOCK_RootEnetAxi); uint32_t post = CLOCK_GetRootPostDivider(kCLOCK_RootEnetAxi); switch (CLOCK_GetRootMux(kCLOCK_RootEnetAxi)) { case (uint32_t)kCLOCK_EnetAxiRootmuxOsc24M: freq = OSC24M_CLK_FREQ; break; case (uint32_t)kCLOCK_EnetAxiRootmuxSysPll1Div3: freq = CLOCK_GetPllFreq(kCLOCK_SystemPll1Ctrl) / 3U; break; case (uint32_t)kCLOCK_EnetAxiRootmuxSysPll1: freq = CLOCK_GetPllFreq(kCLOCK_SystemPll1Ctrl); break; case (uint32_t)kCLOCK_EnetAxiRootmuxSysPll2Div4: freq = CLOCK_GetPllFreq(kCLOCK_SystemPll2Ctrl) / 4U; break; case (uint32_t)kCLOCK_EnetAxiRootmuxSysPll2Div5: freq = CLOCK_GetPllFreq(kCLOCK_SystemPll2Ctrl) / 5U; break; case (uint32_t)kCLOCK_EnetAxiRootmuxAudioPll1: freq = CLOCK_GetPllFreq(kCLOCK_AudioPll1Ctrl); break; case (uint32_t)kCLOCK_EnetAxiRootmuxVideoPll1: freq = CLOCK_GetPllFreq(kCLOCK_VideoPll1Ctrl); break; case (uint32_t)kCLOCK_EnetAxiRootmuxSysPll3: freq = CLOCK_GetPllFreq(kCLOCK_SystemPll3Ctrl); break; default: freq = 0U; break; } return freq / pre / post; } /*! * brief Gets PLL reference clock frequency. * * param type fractional pll type. * return Clock frequency */ uint32_t CLOCK_GetPllRefClkFreq(clock_pll_ctrl_t ctrl) { uint32_t refClkFreq = 0U; uint8_t clkSel = 0U; if (ctrl < kCLOCK_ArmPllCtrl) { clkSel = (uint8_t)((CCM_ANALOG_TUPLE_REG(CCM_ANALOG, ctrl) & CCM_ANALOG_AUDIO_PLL1_GEN_CTRL_PLL_REF_CLK_SEL_MASK)); } else { clkSel = (uint8_t)(CCM_ANALOG_TUPLE_REG(CCM_ANALOG, ctrl) & CCM_ANALOG_SYS_PLL1_GEN_CTRL_PLL_REF_CLK_SEL_MASK); } switch (clkSel) { case kANALOG_PllRefOsc24M: refClkFreq = OSC24M_CLK_FREQ; break; case kANALOG_PllPadClk: /* The value of PAD CLK need user to define according to the actual condition. */ refClkFreq = CLKPAD_FREQ; break; default: refClkFreq = 0U; break; } return refClkFreq; } /*! * brief Gets PLL clock frequency. * * param type fractional pll type. * return Clock frequency */ uint32_t CLOCK_GetPllFreq(clock_pll_ctrl_t pll) { uint32_t pllFreq = 0U; uint32_t pllRefFreq = 0U; bool intergerPllBypass = false; bool fracPllBypass = false; pllRefFreq = CLOCK_GetPllRefClkFreq(pll); switch (pll) { /* Integer PLL frequency */ case kCLOCK_ArmPllCtrl: intergerPllBypass = CLOCK_IsPllBypassed(CCM_ANALOG, kCLOCK_ArmPllPwrBypassCtrl); break; case kCLOCK_SystemPll1Ctrl: intergerPllBypass = CLOCK_IsPllBypassed(CCM_ANALOG, kCLOCK_SysPll1InternalPll1BypassCtrl); break; case kCLOCK_SystemPll2Ctrl: intergerPllBypass = CLOCK_IsPllBypassed(CCM_ANALOG, kCLOCK_SysPll2InternalPll1BypassCtrl); break; case kCLOCK_SystemPll3Ctrl: intergerPllBypass = CLOCK_IsPllBypassed(CCM_ANALOG, kCLOCK_SysPll3InternalPll1BypassCtrl); break; /* Fractional PLL frequency */ case kCLOCK_AudioPll1Ctrl: fracPllBypass = CLOCK_IsPllBypassed(CCM_ANALOG, kCLOCK_AudioPll1BypassCtrl); break; case kCLOCK_AudioPll2Ctrl: fracPllBypass = CLOCK_IsPllBypassed(CCM_ANALOG, kCLOCK_AudioPll2BypassCtrl); break; case kCLOCK_VideoPll1Ctrl: fracPllBypass = CLOCK_IsPllBypassed(CCM_ANALOG, kCLOCK_VideoPll1BypassCtrl); break; case kCLOCK_DramPllCtrl: fracPllBypass = CLOCK_IsPllBypassed(CCM_ANALOG, kCLOCK_DramPllInternalPll1BypassCtrl); break; default: fracPllBypass = false; break; } if (pll < kCLOCK_ArmPllCtrl) { if (fracPllBypass) { pllFreq = pllRefFreq; } else { pllFreq = CLOCK_GetFracPllFreq(CCM_ANALOG, pll, pllRefFreq); } } else { if (intergerPllBypass) { /* if PLL is bypass, return reference clock directly */ pllFreq = pllRefFreq; } else { pllFreq = CLOCK_GetIntegerPllFreq(CCM_ANALOG, pll, pllRefFreq, false); } } return (uint32_t)pllFreq; } /*! * brief Initializes the ANALOG ARM PLL. * * param config Pointer to the configuration structure(see ref ccm_analog_integer_pll_config_t enumeration). * * note This function can't detect whether the Arm PLL has been enabled and * used by some IPs. */ void CLOCK_InitArmPll(const ccm_analog_integer_pll_config_t *config) { assert(config != NULL); /* Integer PLL configuration */ CLOCK_InitIntegerPll(CCM_ANALOG, config, kCLOCK_ArmPllCtrl); /* Disable PLL bypass */ CLOCK_SetPllBypass(CCM_ANALOG, kCLOCK_ArmPllPwrBypassCtrl, false); /* Enable and power up PLL clock. */ CLOCK_EnableAnalogClock(CCM_ANALOG, kCLOCK_ArmPllClke); /* Wait for PLL to be locked. */ while (!CLOCK_IsPllLocked(CCM_ANALOG, kCLOCK_ArmPllCtrl)) { } } /*! * brief De-initialize the ARM PLL. */ void CLOCK_DeinitArmPll(void) { CLOCK_PowerDownPll(CCM_ANALOG, kCLOCK_ArmPllCtrl); } /*! * brief Initializes the ANALOG AUDIO PLL1. * * param config Pointer to the configuration structure(see ref ccm_analog_frac_pll_config_t enumeration). * * note This function can't detect whether the AUDIO PLL has been enabled and * used by some IPs. */ void CLOCK_InitAudioPll1(const ccm_analog_frac_pll_config_t *config) { assert(config != NULL); /* Disable PLL bypass */ CLOCK_SetPllBypass(CCM_ANALOG, kCLOCK_AudioPll1BypassCtrl, false); /* Fractional pll configuration */ CLOCK_InitFracPll(CCM_ANALOG, config, kCLOCK_AudioPll1Ctrl); /* Enable and power up PLL clock. */ CLOCK_EnableAnalogClock(CCM_ANALOG, kCLOCK_AudioPll1Clke); /* Wait for PLL to be locked. */ while (!CLOCK_IsPllLocked(CCM_ANALOG, kCLOCK_AudioPll1Ctrl)) { } } /*! * brief De-initialize the Audio PLL1. */ void CLOCK_DeinitAudioPll1(void) { CLOCK_PowerDownPll(CCM_ANALOG, kCLOCK_AudioPll1Ctrl); } /*! * brief Initializes the ANALOG AUDIO PLL2. * * param config Pointer to the configuration structure(see ref ccm_analog_frac_pll_config_t enumeration). * * note This function can't detect whether the AUDIO PLL has been enabled and * used by some IPs. */ void CLOCK_InitAudioPll2(const ccm_analog_frac_pll_config_t *config) { assert(config != NULL); /* Disable PLL bypass */ CLOCK_SetPllBypass(CCM_ANALOG, kCLOCK_AudioPll2BypassCtrl, false); /* Fractional pll configuration */ CLOCK_InitFracPll(CCM_ANALOG, config, kCLOCK_AudioPll2Ctrl); /* Enable and power up PLL clock. */ CLOCK_EnableAnalogClock(CCM_ANALOG, kCLOCK_AudioPll2Clke); /* Wait for PLL to be locked. */ while (!CLOCK_IsPllLocked(CCM_ANALOG, kCLOCK_AudioPll2Ctrl)) { } } /*! * brief De-initialize the Audio PLL2. */ void CLOCK_DeinitAudioPll2(void) { CLOCK_PowerDownPll(CCM_ANALOG, kCLOCK_AudioPll2Ctrl); } /*! * brief Initializes the ANALOG VIDEO PLL1. * * param config Pointer to the configuration structure(see ref ccm_analog_frac_pll_config_t enumeration). * */ void CLOCK_InitVideoPll1(const ccm_analog_frac_pll_config_t *config) { assert(config != NULL); /* Disable PLL bypass */ CLOCK_SetPllBypass(CCM_ANALOG, kCLOCK_VideoPll1BypassCtrl, false); /* Fractional pll configuration */ CLOCK_InitFracPll(CCM_ANALOG, config, kCLOCK_VideoPll1Ctrl); /* Enable and power up PLL clock. */ CLOCK_EnableAnalogClock(CCM_ANALOG, kCLOCK_VideoPll1Clke); /* Wait for PLL to be locked. */ while (!CLOCK_IsPllLocked(CCM_ANALOG, kCLOCK_VideoPll1Ctrl)) { } } /*! * brief De-initialize the Video PLL1. */ void CLOCK_DeinitVideoPll1(void) { CLOCK_PowerDownPll(CCM_ANALOG, kCLOCK_VideoPll1Ctrl); } /*! * brief Initializes the ANALOG SYS PLL1. * * param config Pointer to the configuration structure(see ref ccm_analog_integer_pll_config_t enumeration). * * note This function can't detect whether the SYS PLL has been enabled and * used by some IPs. */ void CLOCK_InitSysPll1(const ccm_analog_integer_pll_config_t *config) { assert(config != NULL); /* Integer PLL configuration */ CLOCK_InitIntegerPll(CCM_ANALOG, config, kCLOCK_SystemPll1Ctrl); /* Disable PLL bypass */ CLOCK_SetPllBypass(CCM_ANALOG, kCLOCK_SysPll1InternalPll1BypassCtrl, false); /* Enable and power up PLL clock. */ CLOCK_EnableAnalogClock(CCM_ANALOG, kCLOCK_SystemPll1Clke); /* Wait for PLL to be locked. */ while (!CLOCK_IsPllLocked(CCM_ANALOG, kCLOCK_SystemPll1Ctrl)) { } } /*! * brief De-initialize the System PLL1. */ void CLOCK_DeinitSysPll1(void) { CLOCK_PowerDownPll(CCM_ANALOG, kCLOCK_SystemPll1Ctrl); } /*! * brief Initializes the ANALOG SYS PLL2. * * param config Pointer to the configuration structure(see ref ccm_analog_integer_pll_config_t enumeration). * * note This function can't detect whether the SYS PLL has been enabled and * used by some IPs. */ void CLOCK_InitSysPll2(const ccm_analog_integer_pll_config_t *config) { assert(config != NULL); /* Integer PLL configuration */ CLOCK_InitIntegerPll(CCM_ANALOG, config, kCLOCK_SystemPll2Ctrl); /* Disable PLL bypass */ CLOCK_SetPllBypass(CCM_ANALOG, kCLOCK_SysPll2InternalPll1BypassCtrl, false); /* Enable and power up PLL clock. */ CLOCK_EnableAnalogClock(CCM_ANALOG, kCLOCK_SystemPll2Clke); /* Wait for PLL to be locked. */ while (!CLOCK_IsPllLocked(CCM_ANALOG, kCLOCK_SystemPll2Ctrl)) { } } /*! * brief De-initialize the System PLL2. */ void CLOCK_DeinitSysPll2(void) { CLOCK_PowerDownPll(CCM_ANALOG, kCLOCK_SystemPll2Ctrl); } /*! * brief Initializes the ANALOG SYS PLL3. * * param config Pointer to the configuration structure(see ref ccm_analog_integer_pll_config_t enumeration). * * note This function can't detect whether the SYS PLL has been enabled and * used by some IPs. */ void CLOCK_InitSysPll3(const ccm_analog_integer_pll_config_t *config) { assert(config != NULL); /* Integer PLL configuration */ CLOCK_InitIntegerPll(CCM_ANALOG, config, kCLOCK_SystemPll3Ctrl); /* Disable PLL bypass */ CLOCK_SetPllBypass(CCM_ANALOG, kCLOCK_SysPll3InternalPll1BypassCtrl, false); /* Enable and power up PLL clock. */ CLOCK_EnableAnalogClock(CCM_ANALOG, kCLOCK_SystemPll3Clke); /* Wait for PLL to be locked. */ while (!CLOCK_IsPllLocked(CCM_ANALOG, kCLOCK_SystemPll3Ctrl)) { } } /*! * brief De-initialize the System PLL3. */ void CLOCK_DeinitSysPll3(void) { CLOCK_PowerDownPll(CCM_ANALOG, kCLOCK_SystemPll3Ctrl); } /*! * brief Initializes the ANALOG Fractional PLL. * * param base CCM ANALOG base address. * param config Pointer to the configuration structure(see ref ccm_analog_frac_pll_config_t enumeration). * param type fractional pll type. * */ void CLOCK_InitFracPll(CCM_ANALOG_Type *base, const ccm_analog_frac_pll_config_t *config, clock_pll_ctrl_t type) { assert(config != NULL); assert((config->mainDiv >= 64U) && (config->mainDiv <= 1023U)); assert((config->preDiv >= 1U) && (config->preDiv <= 63U)); assert(config->postDiv <= 6U); assert(type < kCLOCK_ArmPllCtrl); uint32_t fracCfg0 = CCM_ANALOG_TUPLE_REG_OFF(base, type, FracPLL_GNRL_CTL_Offset) & ~((uint32_t)1 << CCM_ANALOG_AUDIO_PLL1_GEN_CTRL_PLL_RST_SHIFT); uint32_t fracCfg1 = CCM_ANALOG_TUPLE_REG_OFF(base, type, FracPLL_FDIV_CTL0_Offset); uint32_t fracCfg2 = CCM_ANALOG_TUPLE_REG_OFF(base, type, FracPLL_FDIV_CTL1_Offset); /* power down the fractional PLL first */ CCM_ANALOG_TUPLE_REG_OFF(base, type, FracPLL_GNRL_CTL_Offset) = fracCfg0; CCM_ANALOG_TUPLE_REG_OFF(base, type, FracPLL_FDIV_CTL0_Offset) = (fracCfg1 & (~(CCM_ANALOG_AUDIO_PLL1_FDIV_CTL0_PLL_MAIN_DIV_MASK | CCM_ANALOG_AUDIO_PLL1_FDIV_CTL0_PLL_PRE_DIV_MASK | CCM_ANALOG_AUDIO_PLL1_FDIV_CTL0_PLL_POST_DIV_MASK))) | CCM_ANALOG_AUDIO_PLL1_FDIV_CTL0_PLL_MAIN_DIV(config->mainDiv) | CCM_ANALOG_AUDIO_PLL1_FDIV_CTL0_PLL_PRE_DIV(config->preDiv) | CCM_ANALOG_AUDIO_PLL1_FDIV_CTL0_PLL_POST_DIV(config->postDiv); CCM_ANALOG_TUPLE_REG_OFF(base, type, FracPLL_FDIV_CTL1_Offset) = (fracCfg2 & (~(CCM_ANALOG_AUDIO_PLL1_FDIV_CTL1_PLL_DSM_MASK))) | CCM_ANALOG_AUDIO_PLL1_FDIV_CTL1_PLL_DSM(config->dsm); /* power up the fractional pll */ CCM_ANALOG_TUPLE_REG_OFF(base, type, FracPLL_GNRL_CTL_Offset) |= CCM_ANALOG_AUDIO_PLL1_GEN_CTRL_PLL_RST_MASK; } /*! * brief Gets the ANALOG Fractional PLL clock frequency. * * param base CCM_ANALOG base pointer. * param type fractional pll type. * param fractional pll reference clock frequency * * return Clock frequency */ uint32_t CLOCK_GetFracPllFreq(CCM_ANALOG_Type *base, clock_pll_ctrl_t type, uint32_t refClkFreq) { assert(type < kCLOCK_ArmPllCtrl); uint32_t fracCfg1 = CCM_ANALOG_TUPLE_REG_OFF(base, type, FracPLL_FDIV_CTL0_Offset); uint32_t fracCfg2 = CCM_ANALOG_TUPLE_REG_OFF(base, type, FracPLL_FDIV_CTL1_Offset); uint64_t fracClk = 0U; uint32_t mainDiv = CCM_BIT_FIELD_EXTRACTION(fracCfg1, CCM_ANALOG_AUDIO_PLL1_FDIV_CTL0_PLL_MAIN_DIV_MASK, CCM_ANALOG_AUDIO_PLL1_FDIV_CTL0_PLL_MAIN_DIV_SHIFT); uint8_t preDiv = (uint8_t)CCM_BIT_FIELD_EXTRACTION(fracCfg1, CCM_ANALOG_AUDIO_PLL1_FDIV_CTL0_PLL_PRE_DIV_MASK, CCM_ANALOG_AUDIO_PLL1_FDIV_CTL0_PLL_PRE_DIV_SHIFT); uint8_t postDiv = (uint8_t)CCM_BIT_FIELD_EXTRACTION(fracCfg1, CCM_ANALOG_AUDIO_PLL1_FDIV_CTL0_PLL_POST_DIV_MASK, CCM_ANALOG_AUDIO_PLL1_FDIV_CTL0_PLL_POST_DIV_SHIFT); uint32_t dsm = CCM_BIT_FIELD_EXTRACTION(fracCfg2, CCM_ANALOG_AUDIO_PLL1_FDIV_CTL1_PLL_DSM_MASK, CCM_ANALOG_AUDIO_PLL1_FDIV_CTL1_PLL_DSM_SHIFT); fracClk = (uint64_t)((uint64_t)refClkFreq * ((uint64_t)mainDiv * 65536ULL + dsm) / (65536ULL * (uint32_t)preDiv * (1ULL << postDiv))); return (uint32_t)fracClk; } /*! * brief Initializes the ANALOG Integer PLL. * * param base CCM ANALOG base address * param config Pointer to the configuration structure(see ref ccm_analog_integer_pll_config_t enumeration). * param type integer pll type * */ void CLOCK_InitIntegerPll(CCM_ANALOG_Type *base, const ccm_analog_integer_pll_config_t *config, clock_pll_ctrl_t type) { assert(config != NULL); assert((config->mainDiv >= 64U) && (config->mainDiv <= 1023U)); assert((config->preDiv >= 1U) && (config->preDiv <= 63U)); assert(config->postDiv <= 6U); assert(type >= kCLOCK_SystemPll1Ctrl); uint32_t integerCfg0 = CCM_ANALOG_TUPLE_REG_OFF(base, type, IntegerPLL_GNRL_CTL_Offset) & ~((uint32_t)1 << CCM_ANALOG_SYS_PLL1_GEN_CTRL_PLL_RST_SHIFT); uint32_t integerCfg1 = CCM_ANALOG_TUPLE_REG_OFF(base, type, IntegerPLL_DIV_CTL_Offset); /* power down the Integer PLL first */ CCM_ANALOG_TUPLE_REG_OFF(base, type, IntegerPLL_GNRL_CTL_Offset) = integerCfg0; /* pll mux configuration */ CCM_ANALOG_TUPLE_REG_OFF(base, type, IntegerPLL_GNRL_CTL_Offset) = (integerCfg0 & (~CCM_ANALOG_SYS_PLL1_GEN_CTRL_PLL_REF_CLK_SEL_MASK)) | config->refSel; /* divider configuration */ CCM_ANALOG_TUPLE_REG_OFF(base, type, IntegerPLL_DIV_CTL_Offset) = (integerCfg1 & (~(CCM_ANALOG_SYS_PLL1_FDIV_CTL0_PLL_MAIN_DIV_MASK | CCM_ANALOG_SYS_PLL1_FDIV_CTL0_PLL_PRE_DIV_MASK | CCM_ANALOG_SYS_PLL1_FDIV_CTL0_PLL_POST_DIV_MASK))) | CCM_ANALOG_SYS_PLL1_FDIV_CTL0_PLL_MAIN_DIV(config->mainDiv) | CCM_ANALOG_SYS_PLL1_FDIV_CTL0_PLL_PRE_DIV(config->preDiv) | CCM_ANALOG_SYS_PLL1_FDIV_CTL0_PLL_POST_DIV(config->postDiv); /* power up the Integer PLL */ CCM_ANALOG_TUPLE_REG_OFF(base, type, IntegerPLL_GNRL_CTL_Offset) |= CCM_ANALOG_SYS_PLL1_GEN_CTRL_PLL_RST_MASK; } /*! * brief Get the ANALOG Integer PLL clock frequency. * * param base CCM ANALOG base address. * param type integer pll type * param pll1Bypass pll1 bypass flag * * return Clock frequency */ uint32_t CLOCK_GetIntegerPllFreq(CCM_ANALOG_Type *base, clock_pll_ctrl_t type, uint32_t refClkFreq, bool pll1Bypass) { assert(type >= kCLOCK_SystemPll1Ctrl); uint32_t integerCfg1 = CCM_ANALOG_TUPLE_REG_OFF(base, type, IntegerPLL_DIV_CTL_Offset); uint64_t pllOutClock = 0U; uint32_t mainDiv = CCM_BIT_FIELD_EXTRACTION(integerCfg1, CCM_ANALOG_SYS_PLL1_FDIV_CTL0_PLL_MAIN_DIV_MASK, CCM_ANALOG_SYS_PLL1_FDIV_CTL0_PLL_MAIN_DIV_SHIFT); uint8_t preDiv = (uint8_t)CCM_BIT_FIELD_EXTRACTION(integerCfg1, CCM_ANALOG_SYS_PLL1_FDIV_CTL0_PLL_PRE_DIV_MASK, CCM_ANALOG_SYS_PLL1_FDIV_CTL0_PLL_PRE_DIV_SHIFT); uint8_t postDiv = (uint8_t)CCM_BIT_FIELD_EXTRACTION(integerCfg1, CCM_ANALOG_SYS_PLL1_FDIV_CTL0_PLL_POST_DIV_MASK, CCM_ANALOG_SYS_PLL1_FDIV_CTL0_PLL_POST_DIV_SHIFT); if (pll1Bypass) { pllOutClock = refClkFreq; } else { pllOutClock = (uint64_t)refClkFreq * mainDiv / (((uint64_t)(1U) << postDiv) * preDiv); } return (uint32_t)pllOutClock; } /*! * brief Set root clock divider * Note: The PRE and POST dividers in this function are the actually divider, software will map it to register value * * param ccmRootClk Root control (see ref clock_root_control_t enumeration) * param pre Pre divider value (1-8) * param post Post divider value (1-64) */ void CLOCK_SetRootDivider(clock_root_control_t ccmRootClk, uint32_t pre, uint32_t post) { assert((pre <= 8U) && (pre != 0U)); assert((post <= 64U) && (post != 0U)); CCM_REG(ccmRootClk) = (CCM_REG(ccmRootClk) & (~(CCM_TARGET_ROOT_PRE_PODF_MASK | CCM_TARGET_ROOT_POST_PODF_MASK))) | CCM_TARGET_ROOT_PRE_PODF(pre - 1U) | CCM_TARGET_ROOT_POST_PODF(post - 1U); } /*! * brief Update clock root in one step, for dynamical clock switching * Note: The PRE and POST dividers in this function are the actually divider, software will map it to register value * * param ccmRootClk Root control (see ref clock_root_control_t enumeration) * param root mux value (see ref _ccm_rootmux_xxx enumeration) * param pre Pre divider value (0-7, divider=n+1) * param post Post divider value (0-63, divider=n+1) */ void CLOCK_UpdateRoot(clock_root_control_t ccmRootClk, uint32_t mux, uint32_t pre, uint32_t post) { assert((pre <= 8U) && (pre != 0U)); assert((post <= 64U) && (post != 0U)); CCM_REG(ccmRootClk) = (CCM_REG(ccmRootClk) & (~(CCM_TARGET_ROOT_MUX_MASK | CCM_TARGET_ROOT_PRE_PODF_MASK | CCM_TARGET_ROOT_POST_PODF_MASK))) | CCM_TARGET_ROOT_MUX(mux) | CCM_TARGET_ROOT_PRE_PODF(pre - 1U) | CCM_TARGET_ROOT_POST_PODF(post - 1U); } /*! * brief Enable CCGR clock gate and root clock gate for each module * User should set specific gate for each module according to the description * of the table of system clocks, gating and override in CCM chapter of * reference manual. Take care of that one module may need to set more than * one clock gate. * * param ccmGate Gate control for each module (see ref clock_ip_name_t enumeration). */ void CLOCK_EnableClock(clock_ip_name_t ccmGate) { uint32_t clockType = CLOCK_GATE_TYPE(ccmGate); uint32_t ccgr = CCM_TUPLE_CCGR(ccmGate); uint32_t rootClk = 0U; if (CLOCK_GATE_IN_AUDIOMIX == clockType) { uint32_t offset = AUDIOMIX_TUPLE_OFFSET(ccmGate); uint32_t gate = AUDIOMIX_TUPLE_GATE(ccmGate); rootClk = AUDIOMIX_TUPLE_ROOT(ccmGate); *(volatile uint32_t *)((uintptr_t)AUDIOMIX + offset) |= (uint32_t)1U << gate; } else { CCM_REG_SET(ccgr) = (uint32_t)kCLOCK_ClockNeededAll; rootClk = CCM_TUPLE_ROOT(ccmGate); } /* if root clock is 0xFFFFU, then skip enable root clock */ if (rootClk != 0xFFFFU) { CCM_REG_SET(rootClk) = CCM_TARGET_ROOT_SET_ENABLE_MASK; } } /*! * brief Disable CCGR clock gate for the each module * User should set specific gate for each module according to the description * of the table of system clocks, gating and override in CCM chapter of * reference manual. Take care of that one module may need to set more than * one clock gate. * * param ccmGate Gate control for each module (see ref clock_ip_name_t enumeration). */ void CLOCK_DisableClock(clock_ip_name_t ccmGate) { uint32_t ccgr = CCM_TUPLE_CCGR(ccmGate); uint32_t clockType = CLOCK_GATE_TYPE(ccmGate); uint32_t rootClk = 0U; if (CLOCK_GATE_IN_AUDIOMIX == clockType) { uint32_t offset = AUDIOMIX_TUPLE_OFFSET(ccmGate); uint32_t gate = AUDIOMIX_TUPLE_GATE(ccmGate); rootClk = AUDIOMIX_TUPLE_ROOT(ccmGate); *(volatile uint32_t *)((uintptr_t)AUDIOMIX + offset) &= ~((uint32_t)1U << gate); } else { CCM_REG(ccgr) = (uint32_t)kCLOCK_ClockNotNeeded; rootClk = CCM_TUPLE_ROOT(ccmGate); } /* if root clock is 0xFFFFU, then skip disable root clock */ if (rootClk != 0xFFFFU) { CCM_REG_CLR(rootClk) = CCM_TARGET_ROOT_CLR_ENABLE_MASK; } }