/* * The Clear BSD License * Copyright (c) 2015, Freescale Semiconductor, Inc. * Copyright (c) 2016 - 2017 , NXP * All rights reserved. * * * Redistribution and use in source and binary forms, with or without modification, * are permitted (subject to the limitations in the disclaimer below) provided * that the following conditions are met: * * o Redistributions of source code must retain the above copyright notice, this list * of conditions and the following disclaimer. * * o Redistributions in binary form must reproduce the above copyright notice, this * list of conditions and the following disclaimer in the documentation and/or * other materials provided with the distribution. * * o Neither the name of copyright holder nor the names of its * contributors may be used to endorse or promote products derived from this * software without specific prior written permission. * * NO EXPRESS OR IMPLIED LICENSES TO ANY PARTY'S PATENT RIGHTS ARE GRANTED BY THIS LICENSE. * THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" AND * ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED * WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE * DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT HOLDER OR CONTRIBUTORS BE LIABLE FOR * ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES * (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; * LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON * ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT * (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS * SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. */ #ifndef _FSL_CLOCK_H_ #define _FSL_CLOCK_H_ #include "fsl_common.h" /*! @addtogroup clock */ /*! @{ */ /*! @file */ /******************************************************************************* * Configurations ******************************************************************************/ /*! @brief Configures whether to check a parameter in a function. * * Some MCG settings must be changed with conditions, for example: * 1. MCGIRCLK settings, such as the source, divider, and the trim value should not change when * MCGIRCLK is used as a system clock source. * 2. MCG_C7[OSCSEL] should not be changed when the external reference clock is used * as a system clock source. For example, in FBE/BLPE/PBE modes. * 3. The users should only switch between the supported clock modes. * * MCG functions check the parameter and MCG status before setting, if not allowed * to change, the functions return error. The parameter checking increases code size, * if code size is a critical requirement, change #MCG_CONFIG_CHECK_PARAM to 0 to * disable parameter checking. */ #ifndef MCG_CONFIG_CHECK_PARAM #define MCG_CONFIG_CHECK_PARAM 0U #endif /*! @brief Configure whether driver controls clock * * When set to 0, peripheral drivers will enable clock in initialize function * and disable clock in de-initialize function. When set to 1, peripheral * driver will not control the clock, application could contol the clock out of * the driver. * * @note All drivers share this feature switcher. If it is set to 1, application * should handle clock enable and disable for all drivers. */ #if !(defined(FSL_SDK_DISABLE_DRIVER_CLOCK_CONTROL)) #define FSL_SDK_DISABLE_DRIVER_CLOCK_CONTROL 0 #endif /******************************************************************************* * Definitions ******************************************************************************/ /*! @name Driver version */ /*@{*/ /*! @brief CLOCK driver version 2.2.1. */ #define FSL_CLOCK_DRIVER_VERSION (MAKE_VERSION(2, 2, 1)) /*@}*/ /*! @brief External XTAL0 (OSC0) clock frequency. * * The XTAL0/EXTAL0 (OSC0) clock frequency in Hz. When the clock is set up, use the * function CLOCK_SetXtal0Freq to set the value in the clock driver. For example, * if XTAL0 is 8 MHz: * @code * CLOCK_InitOsc0(...); // Set up the OSC0 * CLOCK_SetXtal0Freq(80000000); // Set the XTAL0 value to the clock driver. * @endcode * * This is important for the multicore platforms where only one core needs to set up the * OSC0 using the CLOCK_InitOsc0. All other cores need to call the CLOCK_SetXtal0Freq * to get a valid clock frequency. */ extern uint32_t g_xtal0Freq; /*! @brief External XTAL32/EXTAL32/RTC_CLKIN clock frequency. * * The XTAL32/EXTAL32/RTC_CLKIN clock frequency in Hz. When the clock is set up, use the * function CLOCK_SetXtal32Freq to set the value in the clock driver. * * This is important for the multicore platforms where only one core needs to set up * the clock. All other cores need to call the CLOCK_SetXtal32Freq * to get a valid clock frequency. */ extern uint32_t g_xtal32Freq; /*! @brief IRC48M clock frequency in Hz. */ #define MCG_INTERNAL_IRC_48M 48000000U #if (defined(OSC) && !(defined(OSC0))) #define OSC0 OSC #endif /*! @brief Clock ip name array for DMAMUX. */ #define DMAMUX_CLOCKS \ { \ kCLOCK_Dmamux0 \ } /*! @brief Clock ip name array for RTC. */ #define RTC_CLOCKS \ { \ kCLOCK_Rtc0 \ } /*! @brief Clock ip name array for SAI. */ #define SAI_CLOCKS \ { \ kCLOCK_Sai0 \ } /*! @brief Clock ip name array for PORT. */ #define PORT_CLOCKS \ { \ kCLOCK_PortA, kCLOCK_PortB, kCLOCK_PortC, kCLOCK_PortD, kCLOCK_PortE \ } /*! @brief Clock ip name array for FLEXBUS. */ #define FLEXBUS_CLOCKS \ { \ kCLOCK_Flexbus0 \ } /*! @brief Clock ip name array for EWM. */ #define EWM_CLOCKS \ { \ kCLOCK_Ewm0 \ } /*! @brief Clock ip name array for PIT. */ #define PIT_CLOCKS \ { \ kCLOCK_Pit0 \ } /*! @brief Clock ip name array for DSPI. */ #define DSPI_CLOCKS \ { \ kCLOCK_Spi0, kCLOCK_Spi1, kCLOCK_Spi2 \ } /*! @brief Clock ip name array for EMVSIM. */ #define EMVSIM_CLOCKS \ { \ kCLOCK_Emvsim0, kCLOCK_Emvsim1 \ } /*! @brief Clock ip name array for QSPI. */ #define QSPI_CLOCKS \ { \ kCLOCK_Qspi0 \ } /*! @brief Clock ip name array for SDHC. */ #define SDHC_CLOCKS \ { \ kCLOCK_Sdhc0 \ } /*! @brief Clock ip name array for FTM. */ #define FTM_CLOCKS \ { \ kCLOCK_Ftm0, kCLOCK_Ftm1, kCLOCK_Ftm2, kCLOCK_Ftm3 \ } /*! @brief Clock ip name array for EDMA. */ #define EDMA_CLOCKS \ { \ kCLOCK_Dma0 \ } /*! @brief Clock ip name array for LPUART. */ #define LPUART_CLOCKS \ { \ kCLOCK_Lpuart0, kCLOCK_Lpuart1, kCLOCK_Lpuart2, kCLOCK_Lpuart3, kCLOCK_Lpuart4 \ } /*! @brief Clock ip name array for DAC. */ #define DAC_CLOCKS \ { \ kCLOCK_Dac0 \ } /*! @brief Clock ip name array for LPTMR. */ #define LPTMR_CLOCKS \ { \ kCLOCK_Lptmr0, kCLOCK_Lptmr1 \ } /*! @brief Clock ip name array for ADC16. */ #define ADC16_CLOCKS \ { \ kCLOCK_Adc0 \ } /*! @brief Clock ip name array for SDRAM. */ #define SDRAM_CLOCKS \ { \ kCLOCK_Sdramc0 \ } /*! @brief Clock ip name array for TRNG. */ #define TRNG_CLOCKS \ { \ kCLOCK_Trng0 \ } /*! @brief Clock ip name array for MPU. */ #define SYSMPU_CLOCKS \ { \ kCLOCK_Sysmpu0 \ } /*! @brief Clock ip name array for FLEXIO. */ #define FLEXIO_CLOCKS \ { \ kCLOCK_Flexio0 \ } /*! @brief Clock ip name array for VREF. */ #define VREF_CLOCKS \ { \ kCLOCK_Vref0 \ } /*! @brief Clock ip name array for CMT. */ #define CMT_CLOCKS \ { \ kCLOCK_Cmt0 \ } /*! @brief Clock ip name array for TPM. */ #define TPM_CLOCKS \ { \ kCLOCK_IpInvalid, kCLOCK_Tpm1, kCLOCK_Tpm2 \ } /*! @brief Clock ip name array for TSI. */ #define TSI_CLOCKS \ { \ kCLOCK_Tsi0 \ } /*! @brief Clock ip name array for LTC. */ #define LTC_CLOCKS \ { \ kCLOCK_Ltc0 \ } /*! @brief Clock ip name array for CRC. */ #define CRC_CLOCKS \ { \ kCLOCK_Crc0 \ } /*! @brief Clock ip name array for I2C. */ #define I2C_CLOCKS \ { \ kCLOCK_I2c0, kCLOCK_I2c1, kCLOCK_I2c2, kCLOCK_I2c3 \ } /*! @brief Clock ip name array for PDB. */ #define PDB_CLOCKS \ { \ kCLOCK_Pdb0 \ } /*! @brief Clock ip name array for FTF. */ #define FTF_CLOCKS \ { \ kCLOCK_Ftf0 \ } /*! @brief Clock ip name array for CMP. */ #define CMP_CLOCKS \ { \ kCLOCK_Cmp0, kCLOCK_Cmp1 \ } /*! * @brief LPO clock frequency. */ #define LPO_CLK_FREQ 1000U /*! @brief Peripherals clock source definition. */ #define SYS_CLK kCLOCK_CoreSysClk #define BUS_CLK kCLOCK_BusClk #define I2C0_CLK_SRC BUS_CLK #define I2C1_CLK_SRC BUS_CLK #define I2C2_CLK_SRC BUS_CLK #define I2C3_CLK_SRC BUS_CLK #define DSPI0_CLK_SRC BUS_CLK #define DSPI1_CLK_SRC BUS_CLK #define DSPI2_CLK_SRC BUS_CLK /*! @brief Clock name used to get clock frequency. */ typedef enum _clock_name { /* ----------------------------- System layer clock -------------------------------*/ kCLOCK_CoreSysClk, /*!< Core/system clock */ kCLOCK_PlatClk, /*!< Platform clock */ kCLOCK_BusClk, /*!< Bus clock */ kCLOCK_FlexBusClk, /*!< FlexBus clock */ kCLOCK_FlashClk, /*!< Flash clock */ kCLOCK_FastPeriphClk, /*!< Fast peripheral clock */ kCLOCK_PllFllSelClk, /*!< The clock after SIM[PLLFLLSEL]. */ /* ---------------------------------- OSC clock -----------------------------------*/ kCLOCK_Er32kClk, /*!< External reference 32K clock (ERCLK32K) */ kCLOCK_Osc0ErClk, /*!< OSC0 external reference clock (OSC0ERCLK) */ kCLOCK_Osc1ErClk, /*!< OSC1 external reference clock (OSC1ERCLK) */ kCLOCK_Osc0ErClkUndiv, /*!< OSC0 external reference undivided clock(OSC0ERCLK_UNDIV). */ /* ----------------------------- MCG and MCG-Lite clock ---------------------------*/ kCLOCK_McgFixedFreqClk, /*!< MCG fixed frequency clock (MCGFFCLK) */ kCLOCK_McgInternalRefClk, /*!< MCG internal reference clock (MCGIRCLK) */ kCLOCK_McgFllClk, /*!< MCGFLLCLK */ kCLOCK_McgPll0Clk, /*!< MCGPLL0CLK */ kCLOCK_McgPll1Clk, /*!< MCGPLL1CLK */ kCLOCK_McgExtPllClk, /*!< EXT_PLLCLK */ kCLOCK_McgPeriphClk, /*!< MCG peripheral clock (MCGPCLK) */ kCLOCK_McgIrc48MClk, /*!< MCG IRC48M clock */ /* --------------------------------- Other clock ----------------------------------*/ kCLOCK_LpoClk, /*!< LPO clock */ } clock_name_t; /*! @brief USB clock source definition. */ typedef enum _clock_usb_src { kCLOCK_UsbSrcPll0 = SIM_SOPT2_USBSRC(1U) | SIM_SOPT2_PLLFLLSEL(1U), /*!< Use PLL0. */ kCLOCK_UsbSrcIrc48M = SIM_SOPT2_USBSRC(1U) | SIM_SOPT2_PLLFLLSEL(3U), /*!< Use IRC48M. */ kCLOCK_UsbSrcExt = SIM_SOPT2_USBSRC(0U) /*!< Use USB_CLKIN. */ } clock_usb_src_t; /*------------------------------------------------------------------------------ clock_gate_t definition: 31 16 0 ----------------------------------------------------------------- | SIM_SCGC register offset | control bit offset in SCGC | ----------------------------------------------------------------- For example, the SDHC clock gate is controlled by SIM_SCGC3[17], the SIM_SCGC3 offset in SIM is 0x1030, then kClockGateSdhc0 is defined as kClockGateSdhc0 = (0x1030 << 16) | 17; ------------------------------------------------------------------------------*/ #define CLK_GATE_REG_OFFSET_SHIFT 16U #define CLK_GATE_REG_OFFSET_MASK 0xFFFF0000U #define CLK_GATE_BIT_SHIFT_SHIFT 0U #define CLK_GATE_BIT_SHIFT_MASK 0x0000FFFFU #define CLK_GATE_DEFINE(reg_offset, bit_shift) \ ((((reg_offset) << CLK_GATE_REG_OFFSET_SHIFT) & CLK_GATE_REG_OFFSET_MASK) | \ (((bit_shift) << CLK_GATE_BIT_SHIFT_SHIFT) & CLK_GATE_BIT_SHIFT_MASK)) #define CLK_GATE_ABSTRACT_REG_OFFSET(x) (((x)&CLK_GATE_REG_OFFSET_MASK) >> CLK_GATE_REG_OFFSET_SHIFT) #define CLK_GATE_ABSTRACT_BITS_SHIFT(x) (((x)&CLK_GATE_BIT_SHIFT_MASK) >> CLK_GATE_BIT_SHIFT_SHIFT) /*! @brief Clock gate name used for CLOCK_EnableClock/CLOCK_DisableClock. */ typedef enum _clock_ip_name { kCLOCK_IpInvalid = 0U, kCLOCK_I2c2 = CLK_GATE_DEFINE(0x1028U, 6U), kCLOCK_I2c3 = CLK_GATE_DEFINE(0x1028U, 7U), kCLOCK_Lpuart0 = CLK_GATE_DEFINE(0x102CU, 4U), kCLOCK_Lpuart1 = CLK_GATE_DEFINE(0x102CU, 5U), kCLOCK_Lpuart2 = CLK_GATE_DEFINE(0x102CU, 6U), kCLOCK_Lpuart3 = CLK_GATE_DEFINE(0x102CU, 7U), kCLOCK_Tpm1 = CLK_GATE_DEFINE(0x102CU, 9U), kCLOCK_Tpm2 = CLK_GATE_DEFINE(0x102CU, 10U), kCLOCK_Dac0 = CLK_GATE_DEFINE(0x102CU, 12U), kCLOCK_Ltc0 = CLK_GATE_DEFINE(0x102CU, 17U), kCLOCK_Emvsim0 = CLK_GATE_DEFINE(0x102CU, 20U), kCLOCK_Emvsim1 = CLK_GATE_DEFINE(0x102CU, 21U), kCLOCK_Lpuart4 = CLK_GATE_DEFINE(0x102CU, 22U), kCLOCK_Qspi0 = CLK_GATE_DEFINE(0x102CU, 26U), kCLOCK_Flexio0 = CLK_GATE_DEFINE(0x102CU, 31U), kCLOCK_Trng0 = CLK_GATE_DEFINE(0x1030U, 0U), kCLOCK_Spi2 = CLK_GATE_DEFINE(0x1030U, 12U), kCLOCK_Sdhc0 = CLK_GATE_DEFINE(0x1030U, 17U), kCLOCK_Ftm3 = CLK_GATE_DEFINE(0x1030U, 25U), kCLOCK_Ewm0 = CLK_GATE_DEFINE(0x1034U, 1U), kCLOCK_Cmt0 = CLK_GATE_DEFINE(0x1034U, 2U), kCLOCK_I2c0 = CLK_GATE_DEFINE(0x1034U, 6U), kCLOCK_I2c1 = CLK_GATE_DEFINE(0x1034U, 7U), kCLOCK_Usbfs0 = CLK_GATE_DEFINE(0x1034U, 18U), kCLOCK_Cmp0 = CLK_GATE_DEFINE(0x1034U, 19U), kCLOCK_Cmp1 = CLK_GATE_DEFINE(0x1034U, 19U), kCLOCK_Vref0 = CLK_GATE_DEFINE(0x1034U, 20U), kCLOCK_Lptmr0 = CLK_GATE_DEFINE(0x1038U, 0U), kCLOCK_Lptmr1 = CLK_GATE_DEFINE(0x1038U, 4U), kCLOCK_Tsi0 = CLK_GATE_DEFINE(0x1038U, 5U), kCLOCK_PortA = CLK_GATE_DEFINE(0x1038U, 9U), kCLOCK_PortB = CLK_GATE_DEFINE(0x1038U, 10U), kCLOCK_PortC = CLK_GATE_DEFINE(0x1038U, 11U), kCLOCK_PortD = CLK_GATE_DEFINE(0x1038U, 12U), kCLOCK_PortE = CLK_GATE_DEFINE(0x1038U, 13U), kCLOCK_Ftf0 = CLK_GATE_DEFINE(0x103CU, 0U), kCLOCK_Dmamux0 = CLK_GATE_DEFINE(0x103CU, 1U), kCLOCK_Spi0 = CLK_GATE_DEFINE(0x103CU, 12U), kCLOCK_Spi1 = CLK_GATE_DEFINE(0x103CU, 13U), kCLOCK_Sai0 = CLK_GATE_DEFINE(0x103CU, 15U), kCLOCK_Crc0 = CLK_GATE_DEFINE(0x103CU, 18U), kCLOCK_Usbdcd0 = CLK_GATE_DEFINE(0x103CU, 21U), kCLOCK_Pdb0 = CLK_GATE_DEFINE(0x103CU, 22U), kCLOCK_Pit0 = CLK_GATE_DEFINE(0x103CU, 23U), kCLOCK_Ftm0 = CLK_GATE_DEFINE(0x103CU, 24U), kCLOCK_Ftm1 = CLK_GATE_DEFINE(0x103CU, 25U), kCLOCK_Ftm2 = CLK_GATE_DEFINE(0x103CU, 26U), kCLOCK_Adc0 = CLK_GATE_DEFINE(0x103CU, 27U), kCLOCK_Rtc0 = CLK_GATE_DEFINE(0x103CU, 29U), kCLOCK_Flexbus0 = CLK_GATE_DEFINE(0x1040U, 0U), kCLOCK_Dma0 = CLK_GATE_DEFINE(0x1040U, 1U), kCLOCK_Sysmpu0 = CLK_GATE_DEFINE(0x1040U, 2U), kCLOCK_Sdramc0 = CLK_GATE_DEFINE(0x1040U, 3U), } clock_ip_name_t; /*!@brief SIM configuration structure for clock setting. */ typedef struct _sim_clock_config { uint8_t pllFllSel; /*!< PLL/FLL/IRC48M selection. */ uint8_t pllFllDiv; /*!< PLLFLLSEL clock divider divisor. */ uint8_t pllFllFrac; /*!< PLLFLLSEL clock divider fraction. */ uint8_t er32kSrc; /*!< ERCLK32K source selection. */ uint32_t clkdiv1; /*!< SIM_CLKDIV1. */ } sim_clock_config_t; /*! @brief OSC work mode. */ typedef enum _osc_mode { kOSC_ModeExt = 0U, /*!< Use an external clock. */ #if (defined(MCG_C2_EREFS_MASK) && !(defined(MCG_C2_EREFS0_MASK))) kOSC_ModeOscLowPower = MCG_C2_EREFS_MASK, /*!< Oscillator low power. */ #else kOSC_ModeOscLowPower = MCG_C2_EREFS0_MASK, /*!< Oscillator low power. */ #endif kOSC_ModeOscHighGain = 0U #if (defined(MCG_C2_EREFS_MASK) && !(defined(MCG_C2_EREFS0_MASK))) | MCG_C2_EREFS_MASK #else | MCG_C2_EREFS0_MASK #endif #if (defined(MCG_C2_HGO_MASK) && !(defined(MCG_C2_HGO0_MASK))) | MCG_C2_HGO_MASK, /*!< Oscillator high gain. */ #else | MCG_C2_HGO0_MASK, /*!< Oscillator high gain. */ #endif } osc_mode_t; /*! @brief Oscillator capacitor load setting.*/ enum _osc_cap_load { kOSC_Cap2P = OSC_CR_SC2P_MASK, /*!< 2 pF capacitor load */ kOSC_Cap4P = OSC_CR_SC4P_MASK, /*!< 4 pF capacitor load */ kOSC_Cap8P = OSC_CR_SC8P_MASK, /*!< 8 pF capacitor load */ kOSC_Cap16P = OSC_CR_SC16P_MASK /*!< 16 pF capacitor load */ }; /*! @brief OSCERCLK enable mode. */ enum _oscer_enable_mode { kOSC_ErClkEnable = OSC_CR_ERCLKEN_MASK, /*!< Enable. */ kOSC_ErClkEnableInStop = OSC_CR_EREFSTEN_MASK /*!< Enable in stop mode. */ }; /*! @brief OSC configuration for OSCERCLK. */ typedef struct _oscer_config { uint8_t enableMode; /*!< OSCERCLK enable mode. OR'ed value of @ref _oscer_enable_mode. */ uint8_t erclkDiv; /*!< Divider for OSCERCLK.*/ } oscer_config_t; /*! * @brief OSC Initialization Configuration Structure * * Defines the configuration data structure to initialize the OSC. * When porting to a new board, set the following members * according to the board setting: * 1. freq: The external frequency. * 2. workMode: The OSC module mode. */ typedef struct _osc_config { uint32_t freq; /*!< External clock frequency. */ uint8_t capLoad; /*!< Capacitor load setting. */ osc_mode_t workMode; /*!< OSC work mode setting. */ oscer_config_t oscerConfig; /*!< Configuration for OSCERCLK. */ } osc_config_t; /*! @brief MCG FLL reference clock source select. */ typedef enum _mcg_fll_src { kMCG_FllSrcExternal, /*!< External reference clock is selected */ kMCG_FllSrcInternal /*!< The slow internal reference clock is selected */ } mcg_fll_src_t; /*! @brief MCG internal reference clock select */ typedef enum _mcg_irc_mode { kMCG_IrcSlow, /*!< Slow internal reference clock selected */ kMCG_IrcFast /*!< Fast internal reference clock selected */ } mcg_irc_mode_t; /*! @brief MCG DCO Maximum Frequency with 32.768 kHz Reference */ typedef enum _mcg_dmx32 { kMCG_Dmx32Default, /*!< DCO has a default range of 25% */ kMCG_Dmx32Fine /*!< DCO is fine-tuned for maximum frequency with 32.768 kHz reference */ } mcg_dmx32_t; /*! @brief MCG DCO range select */ typedef enum _mcg_drs { kMCG_DrsLow, /*!< Low frequency range */ kMCG_DrsMid, /*!< Mid frequency range */ kMCG_DrsMidHigh, /*!< Mid-High frequency range */ kMCG_DrsHigh /*!< High frequency range */ } mcg_drs_t; /*! @brief MCG PLL reference clock select */ typedef enum _mcg_pll_ref_src { kMCG_PllRefOsc0, /*!< Selects OSC0 as PLL reference clock */ kMCG_PllRefOsc1 /*!< Selects OSC1 as PLL reference clock */ } mcg_pll_ref_src_t; /*! @brief MCGOUT clock source. */ typedef enum _mcg_clkout_src { kMCG_ClkOutSrcOut, /*!< Output of the FLL is selected (reset default) */ kMCG_ClkOutSrcInternal, /*!< Internal reference clock is selected */ kMCG_ClkOutSrcExternal, /*!< External reference clock is selected */ } mcg_clkout_src_t; /*! @brief MCG Automatic Trim Machine Select */ typedef enum _mcg_atm_select { kMCG_AtmSel32k, /*!< 32 kHz Internal Reference Clock selected */ kMCG_AtmSel4m /*!< 4 MHz Internal Reference Clock selected */ } mcg_atm_select_t; /*! @brief MCG OSC Clock Select */ typedef enum _mcg_oscsel { kMCG_OscselOsc, /*!< Selects System Oscillator (OSCCLK) */ kMCG_OscselRtc, /*!< Selects 32 kHz RTC Oscillator */ kMCG_OscselIrc /*!< Selects 48 MHz IRC Oscillator */ } mcg_oscsel_t; /*! @brief MCG PLLCS select */ typedef enum _mcg_pll_clk_select { kMCG_PllClkSelPll0, /*!< PLL0 output clock is selected */ kMCG_PllClkSelPll1 /* PLL1 output clock is selected */ } mcg_pll_clk_select_t; /*! @brief MCG clock monitor mode. */ typedef enum _mcg_monitor_mode { kMCG_MonitorNone, /*!< Clock monitor is disabled. */ kMCG_MonitorInt, /*!< Trigger interrupt when clock lost. */ kMCG_MonitorReset /*!< System reset when clock lost. */ } mcg_monitor_mode_t; /*! @brief MCG status. */ enum _mcg_status { kStatus_MCG_ModeUnreachable = MAKE_STATUS(kStatusGroup_MCG, 0), /*!< Can't switch to target mode. */ kStatus_MCG_ModeInvalid = MAKE_STATUS(kStatusGroup_MCG, 1), /*!< Current mode invalid for the specific function. */ kStatus_MCG_AtmBusClockInvalid = MAKE_STATUS(kStatusGroup_MCG, 2), /*!< Invalid bus clock for ATM. */ kStatus_MCG_AtmDesiredFreqInvalid = MAKE_STATUS(kStatusGroup_MCG, 3), /*!< Invalid desired frequency for ATM. */ kStatus_MCG_AtmIrcUsed = MAKE_STATUS(kStatusGroup_MCG, 4), /*!< IRC is used when using ATM. */ kStatus_MCG_AtmHardwareFail = MAKE_STATUS(kStatusGroup_MCG, 5), /*!< Hardware fail occurs during ATM. */ kStatus_MCG_SourceUsed = MAKE_STATUS(kStatusGroup_MCG, 6) /*!< Can't change the clock source because it is in use. */ }; /*! @brief MCG status flags. */ enum _mcg_status_flags_t { kMCG_Osc0LostFlag = (1U << 0U), /*!< OSC0 lost. */ kMCG_Osc0InitFlag = (1U << 1U), /*!< OSC0 crystal initialized. */ kMCG_RtcOscLostFlag = (1U << 4U), /*!< RTC OSC lost. */ kMCG_Pll0LostFlag = (1U << 5U), /*!< PLL0 lost. */ kMCG_Pll0LockFlag = (1U << 6U), /*!< PLL0 locked. */ }; /*! @brief MCG internal reference clock (MCGIRCLK) enable mode definition. */ enum _mcg_irclk_enable_mode { kMCG_IrclkEnable = MCG_C1_IRCLKEN_MASK, /*!< MCGIRCLK enable. */ kMCG_IrclkEnableInStop = MCG_C1_IREFSTEN_MASK /*!< MCGIRCLK enable in stop mode. */ }; /*! @brief MCG PLL clock enable mode definition. */ enum _mcg_pll_enable_mode { kMCG_PllEnableIndependent = MCG_C5_PLLCLKEN0_MASK, /*!< MCGPLLCLK enable independent of the MCG clock mode. Generally, the PLL is disabled in FLL modes (FEI/FBI/FEE/FBE). Setting the PLL clock enable independent, enables the PLL in the FLL modes. */ kMCG_PllEnableInStop = MCG_C5_PLLSTEN0_MASK /*!< MCGPLLCLK enable in STOP mode. */ }; /*! @brief MCG mode definitions */ typedef enum _mcg_mode { kMCG_ModeFEI = 0U, /*!< FEI - FLL Engaged Internal */ kMCG_ModeFBI, /*!< FBI - FLL Bypassed Internal */ kMCG_ModeBLPI, /*!< BLPI - Bypassed Low Power Internal */ kMCG_ModeFEE, /*!< FEE - FLL Engaged External */ kMCG_ModeFBE, /*!< FBE - FLL Bypassed External */ kMCG_ModeBLPE, /*!< BLPE - Bypassed Low Power External */ kMCG_ModePBE, /*!< PBE - PLL Bypassed External */ kMCG_ModePEE, /*!< PEE - PLL Engaged External */ kMCG_ModeError /*!< Unknown mode */ } mcg_mode_t; /*! @brief MCG PLL configuration. */ typedef struct _mcg_pll_config { uint8_t enableMode; /*!< Enable mode. OR'ed value of @ref _mcg_pll_enable_mode. */ uint8_t prdiv; /*!< Reference divider PRDIV. */ uint8_t vdiv; /*!< VCO divider VDIV. */ } mcg_pll_config_t; /*! @brief MCG mode change configuration structure * * When porting to a new board, set the following members * according to the board setting: * 1. frdiv: If the FLL uses the external reference clock, set this * value to ensure that the external reference clock divided by frdiv is * in the 31.25 kHz to 39.0625 kHz range. * 2. The PLL reference clock divider PRDIV: PLL reference clock frequency after * PRDIV should be in the FSL_FEATURE_MCG_PLL_REF_MIN to * FSL_FEATURE_MCG_PLL_REF_MAX range. */ typedef struct _mcg_config { mcg_mode_t mcgMode; /*!< MCG mode. */ /* ----------------------- MCGIRCCLK settings ------------------------ */ uint8_t irclkEnableMode; /*!< MCGIRCLK enable mode. */ mcg_irc_mode_t ircs; /*!< Source, MCG_C2[IRCS]. */ uint8_t fcrdiv; /*!< Divider, MCG_SC[FCRDIV]. */ /* ------------------------ MCG FLL settings ------------------------- */ uint8_t frdiv; /*!< Divider MCG_C1[FRDIV]. */ mcg_drs_t drs; /*!< DCO range MCG_C4[DRST_DRS]. */ mcg_dmx32_t dmx32; /*!< MCG_C4[DMX32]. */ mcg_oscsel_t oscsel; /*!< OSC select MCG_C7[OSCSEL]. */ /* ------------------------ MCG PLL settings ------------------------- */ mcg_pll_config_t pll0Config; /*!< MCGPLL0CLK configuration. */ } mcg_config_t; /******************************************************************************* * API ******************************************************************************/ #if defined(__cplusplus) extern "C" { #endif /* __cplusplus */ /*! * @brief Enable the clock for specific IP. * * @param name Which clock to enable, see \ref clock_ip_name_t. */ static inline void CLOCK_EnableClock(clock_ip_name_t name) { uint32_t regAddr = SIM_BASE + CLK_GATE_ABSTRACT_REG_OFFSET((uint32_t)name); (*(volatile uint32_t *)regAddr) |= (1U << CLK_GATE_ABSTRACT_BITS_SHIFT((uint32_t)name)); } /*! * @brief Disable the clock for specific IP. * * @param name Which clock to disable, see \ref clock_ip_name_t. */ static inline void CLOCK_DisableClock(clock_ip_name_t name) { uint32_t regAddr = SIM_BASE + CLK_GATE_ABSTRACT_REG_OFFSET((uint32_t)name); (*(volatile uint32_t *)regAddr) &= ~(1U << CLK_GATE_ABSTRACT_BITS_SHIFT((uint32_t)name)); } /*! * @brief Set ERCLK32K source. * * @param src The value to set ERCLK32K clock source. */ static inline void CLOCK_SetEr32kClock(uint32_t src) { SIM->SOPT1 = ((SIM->SOPT1 & ~SIM_SOPT1_OSC32KSEL_MASK) | SIM_SOPT1_OSC32KSEL(src)); } /*! * @brief Set SDHC0 clock source. * * @param src The value to set SDHC0 clock source. */ static inline void CLOCK_SetSdhc0Clock(uint32_t src) { SIM->SOPT2 = ((SIM->SOPT2 & ~SIM_SOPT2_SDHCSRC_MASK) | SIM_SOPT2_SDHCSRC(src)); } /*! * @brief Set EMVSIM clock source. * * @param src The value to set EMVSIM clock source. */ static inline void CLOCK_SetEmvsimClock(uint32_t src) { SIM->SOPT2 = ((SIM->SOPT2 & ~SIM_SOPT2_EMVSIMSRC_MASK) | SIM_SOPT2_EMVSIMSRC(src)); } /*! * @brief Set LPUART clock source. * * @param src The value to set LPUART clock source. */ static inline void CLOCK_SetLpuartClock(uint32_t src) { SIM->SOPT2 = ((SIM->SOPT2 & ~SIM_SOPT2_LPUARTSRC_MASK) | SIM_SOPT2_LPUARTSRC(src)); } /*! * @brief Set TPM clock source. * * @param src The value to set TPM clock source. */ static inline void CLOCK_SetTpmClock(uint32_t src) { SIM->SOPT2 = ((SIM->SOPT2 & ~SIM_SOPT2_TPMSRC_MASK) | SIM_SOPT2_TPMSRC(src)); } /*! * @brief Set FLEXIO clock source. * * @param src The value to set FLEXIO clock source. */ static inline void CLOCK_SetFlexio0Clock(uint32_t src) { SIM->SOPT2 = ((SIM->SOPT2 & ~SIM_SOPT2_FLEXIOSRC_MASK) | SIM_SOPT2_FLEXIOSRC(src)); } /*! * @brief Set debug trace clock source. * * @param src The value to set debug trace clock source. */ static inline void CLOCK_SetTraceClock(uint32_t src, uint32_t divValue, uint32_t fracValue) { SIM->SOPT2 = ((SIM->SOPT2 & ~SIM_SOPT2_TRACECLKSEL_MASK) | SIM_SOPT2_TRACECLKSEL(src)); SIM->CLKDIV4 = SIM_CLKDIV4_TRACEDIV(divValue) | SIM_CLKDIV4_TRACEFRAC(fracValue); } /*! * @brief Set PLLFLLSEL clock source. * * @param src The value to set PLLFLLSEL clock source. */ static inline void CLOCK_SetPllFllSelClock(uint32_t src, uint32_t divValue, uint32_t fracValue) { SIM->SOPT2 = ((SIM->SOPT2 & ~SIM_SOPT2_PLLFLLSEL_MASK) | SIM_SOPT2_PLLFLLSEL(src)); SIM->CLKDIV3 = SIM_CLKDIV3_PLLFLLDIV(divValue) | SIM_CLKDIV3_PLLFLLFRAC(fracValue); } /*! * @brief Set CLKOUT source. * * @param src The value to set CLKOUT source. */ static inline void CLOCK_SetClkOutClock(uint32_t src) { SIM->SOPT2 = ((SIM->SOPT2 & ~SIM_SOPT2_CLKOUTSEL_MASK) | SIM_SOPT2_CLKOUTSEL(src)); } /*! * @brief Set RTC_CLKOUT source. * * @param src The value to set RTC_CLKOUT source. */ static inline void CLOCK_SetRtcClkOutClock(uint32_t src) { SIM->SOPT2 = ((SIM->SOPT2 & ~SIM_SOPT2_RTCCLKOUTSEL_MASK) | SIM_SOPT2_RTCCLKOUTSEL(src)); } /*! @brief Enable USB FS clock. * * @param src USB FS clock source. * @param freq The frequency specified by src. * @retval true The clock is set successfully. * @retval false The clock source is invalid to get proper USB FS clock. */ bool CLOCK_EnableUsbfs0Clock(clock_usb_src_t src, uint32_t freq); /*! @brief Disable USB FS clock. * * Disable USB FS clock. */ static inline void CLOCK_DisableUsbfs0Clock(void) { CLOCK_DisableClock(kCLOCK_Usbfs0); } /*! * @brief System clock divider * * Set the SIM_CLKDIV1[OUTDIV1], SIM_CLKDIV1[OUTDIV2], SIM_CLKDIV1[OUTDIV3], SIM_CLKDIV1[OUTDIV4]. * * @param outdiv1 Clock 1 output divider value. * * @param outdiv2 Clock 2 output divider value. * * @param outdiv3 Clock 3 output divider value. * * @param outdiv4 Clock 4 output divider value. */ static inline void CLOCK_SetOutDiv(uint32_t outdiv1, uint32_t outdiv2, uint32_t outdiv3, uint32_t outdiv4) { SIM->CLKDIV1 = SIM_CLKDIV1_OUTDIV1(outdiv1) | SIM_CLKDIV1_OUTDIV2(outdiv2) | SIM_CLKDIV1_OUTDIV3(outdiv3) | SIM_CLKDIV1_OUTDIV4(outdiv4); } /*! * @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. * The MCG must be properly configured before using this function. * * @param clockName Clock names defined in clock_name_t * @return Clock frequency value in Hertz */ uint32_t CLOCK_GetFreq(clock_name_t clockName); /*! * @brief Get the core clock or system clock frequency. * * @return Clock frequency in Hz. */ uint32_t CLOCK_GetCoreSysClkFreq(void); /*! * @brief Get the platform clock frequency. * * @return Clock frequency in Hz. */ uint32_t CLOCK_GetPlatClkFreq(void); /*! * @brief Get the bus clock frequency. * * @return Clock frequency in Hz. */ uint32_t CLOCK_GetBusClkFreq(void); /*! * @brief Get the flexbus clock frequency. * * @return Clock frequency in Hz. */ uint32_t CLOCK_GetFlexBusClkFreq(void); /*! * @brief Get the flash clock frequency. * * @return Clock frequency in Hz. */ uint32_t CLOCK_GetFlashClkFreq(void); /*! * @brief Get the output clock frequency selected by SIM[PLLFLLSEL]. * * @return Clock frequency in Hz. */ uint32_t CLOCK_GetPllFllSelClkFreq(void); /*! * @brief Get the external reference 32K clock frequency (ERCLK32K). * * @return Clock frequency in Hz. */ uint32_t CLOCK_GetEr32kClkFreq(void); /*! * @brief Get the OSC0 external reference undivided clock frequency (OSC0ERCLK_UNDIV). * * @return Clock frequency in Hz. */ uint32_t CLOCK_GetOsc0ErClkUndivFreq(void); /*! * @brief Get the OSC0 external reference clock frequency (OSC0ERCLK). * * @return Clock frequency in Hz. */ uint32_t CLOCK_GetOsc0ErClkFreq(void); /*! * @brief Get the OSC0 external reference divided clock frequency. * * @return Clock frequency in Hz. */ uint32_t CLOCK_GetOsc0ErClkDivFreq(void); /*! * @brief Set the clock configure in SIM module. * * This function sets system layer clock settings in SIM module. * * @param config Pointer to the configure structure. */ void CLOCK_SetSimConfig(sim_clock_config_t const *config); /*! * @brief Set the system clock dividers in SIM to safe value. * * The system level clocks (core clock, bus clock, flexbus clock and flash clock) * must be in allowed ranges. During MCG clock mode switch, the MCG output clock * changes then the system level clocks may be out of range. This function could * be used before MCG mode change, to make sure system level clocks are in allowed * range. * * @param config Pointer to the configure structure. */ static inline void CLOCK_SetSimSafeDivs(void) { SIM->CLKDIV1 = 0x01140000U; } /*! @name MCG frequency functions. */ /*@{*/ /*! * @brief Gets the MCG output clock (MCGOUTCLK) frequency. * * This function gets the MCG output clock frequency in Hz based on the current MCG * register value. * * @return The frequency of MCGOUTCLK. */ uint32_t CLOCK_GetOutClkFreq(void); /*! * @brief Gets the MCG FLL clock (MCGFLLCLK) frequency. * * This function gets the MCG FLL clock frequency in Hz based on the current MCG * register value. The FLL is enabled in FEI/FBI/FEE/FBE mode and * disabled in low power state in other modes. * * @return The frequency of MCGFLLCLK. */ uint32_t CLOCK_GetFllFreq(void); /*! * @brief Gets the MCG internal reference clock (MCGIRCLK) frequency. * * This function gets the MCG internal reference clock frequency in Hz based * on the current MCG register value. * * @return The frequency of MCGIRCLK. */ uint32_t CLOCK_GetInternalRefClkFreq(void); /*! * @brief Gets the MCG fixed frequency clock (MCGFFCLK) frequency. * * This function gets the MCG fixed frequency clock frequency in Hz based * on the current MCG register value. * * @return The frequency of MCGFFCLK. */ uint32_t CLOCK_GetFixedFreqClkFreq(void); /*! * @brief Gets the MCG PLL0 clock (MCGPLL0CLK) frequency. * * This function gets the MCG PLL0 clock frequency in Hz based on the current MCG * register value. * * @return The frequency of MCGPLL0CLK. */ uint32_t CLOCK_GetPll0Freq(void); /*@}*/ /*! @name MCG clock configuration. */ /*@{*/ /*! * @brief Enables or disables the MCG low power. * * Enabling the MCG low power disables the PLL and FLL in bypass modes. In other words, * in FBE and PBE modes, enabling low power sets the MCG to BLPE mode. In FBI and * PBI modes, enabling low power sets the MCG to BLPI mode. * When disabling the MCG low power, the PLL or FLL are enabled based on MCG settings. * * @param enable True to enable MCG low power, false to disable MCG low power. */ static inline void CLOCK_SetLowPowerEnable(bool enable) { if (enable) { MCG->C2 |= MCG_C2_LP_MASK; } else { MCG->C2 &= ~MCG_C2_LP_MASK; } } /*! * @brief Configures the Internal Reference clock (MCGIRCLK). * * This function sets the \c MCGIRCLK base on parameters. It also selects the IRC * source. If the fast IRC is used, this function sets the fast IRC divider. * This function also sets whether the \c MCGIRCLK is enabled in stop mode. * Calling this function in FBI/PBI/BLPI modes may change the system clock. As a result, * using the function in these modes it is not allowed. * * @param enableMode MCGIRCLK enable mode, OR'ed value of @ref _mcg_irclk_enable_mode. * @param ircs MCGIRCLK clock source, choose fast or slow. * @param fcrdiv Fast IRC divider setting (\c FCRDIV). * @retval kStatus_MCG_SourceUsed Because the internall reference clock is used as a clock source, * the confuration should not be changed. Otherwise, a glitch occurs. * @retval kStatus_Success MCGIRCLK configuration finished successfully. */ status_t CLOCK_SetInternalRefClkConfig(uint8_t enableMode, mcg_irc_mode_t ircs, uint8_t fcrdiv); /*! * @brief Selects the MCG external reference clock. * * Selects the MCG external reference clock source, changes the MCG_C7[OSCSEL], * and waits for the clock source to be stable. Because the external reference * clock should not be changed in FEE/FBE/BLPE/PBE/PEE modes, do not call this function in these modes. * * @param oscsel MCG external reference clock source, MCG_C7[OSCSEL]. * @retval kStatus_MCG_SourceUsed Because the external reference clock is used as a clock source, * the confuration should not be changed. Otherwise, a glitch occurs. * @retval kStatus_Success External reference clock set successfully. */ status_t CLOCK_SetExternalRefClkConfig(mcg_oscsel_t oscsel); /*! * @brief Set the FLL external reference clock divider value. * * Sets the FLL external reference clock divider value, the register MCG_C1[FRDIV]. * * @param frdiv The FLL external reference clock divider value, MCG_C1[FRDIV]. */ static inline void CLOCK_SetFllExtRefDiv(uint8_t frdiv) { MCG->C1 = (MCG->C1 & ~MCG_C1_FRDIV_MASK) | MCG_C1_FRDIV(frdiv); } /*! * @brief Enables the PLL0 in FLL mode. * * This function sets us the PLL0 in FLL mode and reconfigures * the PLL0. Ensure that the PLL reference * clock is enabled before calling this function and that the PLL0 is not used as a clock source. * The function CLOCK_CalcPllDiv gets the correct PLL * divider values. * * @param config Pointer to the configuration structure. */ void CLOCK_EnablePll0(mcg_pll_config_t const *config); /*! * @brief Disables the PLL0 in FLL mode. * * This function disables the PLL0 in FLL mode. It should be used together with the * @ref CLOCK_EnablePll0. */ static inline void CLOCK_DisablePll0(void) { MCG->C5 &= ~(MCG_C5_PLLCLKEN0_MASK | MCG_C5_PLLSTEN0_MASK); } /*! * @brief Calculates the PLL divider setting for a desired output frequency. * * This function calculates the correct reference clock divider (\c PRDIV) and * VCO divider (\c VDIV) to generate a desired PLL output frequency. It returns the * closest frequency match with the corresponding \c PRDIV/VDIV * returned from parameters. If a desired frequency is not valid, this function * returns 0. * * @param refFreq PLL reference clock frequency. * @param desireFreq Desired PLL output frequency. * @param prdiv PRDIV value to generate desired PLL frequency. * @param vdiv VDIV value to generate desired PLL frequency. * @return Closest frequency match that the PLL was able generate. */ uint32_t CLOCK_CalcPllDiv(uint32_t refFreq, uint32_t desireFreq, uint8_t *prdiv, uint8_t *vdiv); /*@}*/ /*! @name MCG clock lock monitor functions. */ /*@{*/ /*! * @brief Sets the OSC0 clock monitor mode. * * This function sets the OSC0 clock monitor mode. See @ref mcg_monitor_mode_t for details. * * @param mode Monitor mode to set. */ void CLOCK_SetOsc0MonitorMode(mcg_monitor_mode_t mode); /*! * @brief Sets the RTC OSC clock monitor mode. * * This function sets the RTC OSC clock monitor mode. See @ref mcg_monitor_mode_t for details. * * @param mode Monitor mode to set. */ void CLOCK_SetRtcOscMonitorMode(mcg_monitor_mode_t mode); /*! * @brief Sets the PLL0 clock monitor mode. * * This function sets the PLL0 clock monitor mode. See @ref mcg_monitor_mode_t for details. * * @param mode Monitor mode to set. */ void CLOCK_SetPll0MonitorMode(mcg_monitor_mode_t mode); /*! * @brief Gets the MCG status flags. * * This function gets the MCG clock status flags. All status flags are * returned as a logical OR of the enumeration @ref _mcg_status_flags_t. To * check a specific flag, compare the return value with the flag. * * Example: * @code // To check the clock lost lock status of OSC0 and PLL0. uint32_t mcgFlags; mcgFlags = CLOCK_GetStatusFlags(); if (mcgFlags & kMCG_Osc0LostFlag) { // OSC0 clock lock lost. Do something. } if (mcgFlags & kMCG_Pll0LostFlag) { // PLL0 clock lock lost. Do something. } @endcode * * @return Logical OR value of the @ref _mcg_status_flags_t. */ uint32_t CLOCK_GetStatusFlags(void); /*! * @brief Clears the MCG status flags. * * This function clears the MCG clock lock lost status. The parameter is a logical * OR value of the flags to clear. See @ref _mcg_status_flags_t. * * Example: * @code // To clear the clock lost lock status flags of OSC0 and PLL0. CLOCK_ClearStatusFlags(kMCG_Osc0LostFlag | kMCG_Pll0LostFlag); @endcode * * @param mask The status flags to clear. This is a logical OR of members of the * enumeration @ref _mcg_status_flags_t. */ void CLOCK_ClearStatusFlags(uint32_t mask); /*@}*/ /*! * @name OSC configuration * @{ */ /*! * @brief Configures the OSC external reference clock (OSCERCLK). * * This function configures the OSC external reference clock (OSCERCLK). * This is an example to enable the OSCERCLK in normal and stop modes and also set * the output divider to 1: * @code oscer_config_t config = { .enableMode = kOSC_ErClkEnable | kOSC_ErClkEnableInStop, .erclkDiv = 1U, }; OSC_SetExtRefClkConfig(OSC, &config); @endcode * * @param base OSC peripheral address. * @param config Pointer to the configuration structure. */ static inline void OSC_SetExtRefClkConfig(OSC_Type *base, oscer_config_t const *config) { uint8_t reg = base->CR; reg &= ~(OSC_CR_ERCLKEN_MASK | OSC_CR_EREFSTEN_MASK); reg |= config->enableMode; base->CR = reg; base->DIV = OSC_DIV_ERPS(config->erclkDiv); } /*! * @brief Sets the capacitor load configuration for the oscillator. * * This function sets the specified capacitors configuration for the oscillator. * This should be done in the early system level initialization function call * based on the system configuration. * * @param base OSC peripheral address. * @param capLoad OR'ed value for the capacitor load option, see \ref _osc_cap_load. * * Example: @code // To enable only 2 pF and 8 pF capacitor load, please use like this. OSC_SetCapLoad(OSC, kOSC_Cap2P | kOSC_Cap8P); @endcode */ static inline void OSC_SetCapLoad(OSC_Type *base, uint8_t capLoad) { uint8_t reg = base->CR; reg &= ~(OSC_CR_SC2P_MASK | OSC_CR_SC4P_MASK | OSC_CR_SC8P_MASK | OSC_CR_SC16P_MASK); reg |= capLoad; base->CR = reg; } /*! * @brief Initializes the OSC0. * * This function initializes the OSC0 according to the board configuration. * * @param config Pointer to the OSC0 configuration structure. */ void CLOCK_InitOsc0(osc_config_t const *config); /*! * @brief Deinitializes the OSC0. * * This function deinitializes the OSC0. */ void CLOCK_DeinitOsc0(void); /* @} */ /*! * @name External clock frequency * @{ */ /*! * @brief Sets the XTAL0 frequency based on board settings. * * @param freq The XTAL0/EXTAL0 input clock frequency in Hz. */ static inline void CLOCK_SetXtal0Freq(uint32_t freq) { g_xtal0Freq = freq; } /*! * @brief Sets the XTAL32/RTC_CLKIN frequency based on board settings. * * @param freq The XTAL32/EXTAL32/RTC_CLKIN input clock frequency in Hz. */ static inline void CLOCK_SetXtal32Freq(uint32_t freq) { g_xtal32Freq = freq; } /* @} */ /*! * @name MCG auto-trim machine. * @{ */ /*! * @brief Auto trims the internal reference clock. * * This function trims the internal reference clock by using the external clock. If * successful, it returns the kStatus_Success and the frequency after * trimming is received in the parameter @p actualFreq. If an error occurs, * the error code is returned. * * @param extFreq External clock frequency, which should be a bus clock. * @param desireFreq Frequency to trim to. * @param actualFreq Actual frequency after trimming. * @param atms Trim fast or slow internal reference clock. * @retval kStatus_Success ATM success. * @retval kStatus_MCG_AtmBusClockInvalid The bus clock is not in allowed range for the ATM. * @retval kStatus_MCG_AtmDesiredFreqInvalid MCGIRCLK could not be trimmed to the desired frequency. * @retval kStatus_MCG_AtmIrcUsed Could not trim because MCGIRCLK is used as a bus clock source. * @retval kStatus_MCG_AtmHardwareFail Hardware fails while trimming. */ status_t CLOCK_TrimInternalRefClk(uint32_t extFreq, uint32_t desireFreq, uint32_t *actualFreq, mcg_atm_select_t atms); /* @} */ /*! @name MCG mode functions. */ /*@{*/ /*! * @brief Gets the current MCG mode. * * This function checks the MCG registers and determines the current MCG mode. * * @return Current MCG mode or error code; See @ref mcg_mode_t. */ mcg_mode_t CLOCK_GetMode(void); /*! * @brief Sets the MCG to FEI mode. * * This function sets the MCG to FEI mode. If setting to FEI mode fails * from the current mode, this function returns an error. * * @param dmx32 DMX32 in FEI mode. * @param drs The DCO range selection. * @param fllStableDelay Delay function to ensure that the FLL is stable. Passing * NULL does not cause a delay. * @retval kStatus_MCG_ModeUnreachable Could not switch to the target mode. * @retval kStatus_Success Switched to the target mode successfully. * @note If @p dmx32 is set to kMCG_Dmx32Fine, the slow IRC must not be trimmed * to a frequency above 32768 Hz. */ status_t CLOCK_SetFeiMode(mcg_dmx32_t dmx32, mcg_drs_t drs, void (*fllStableDelay)(void)); /*! * @brief Sets the MCG to FEE mode. * * This function sets the MCG to FEE mode. If setting to FEE mode fails * from the current mode, this function returns an error. * * @param frdiv FLL reference clock divider setting, FRDIV. * @param dmx32 DMX32 in FEE mode. * @param drs The DCO range selection. * @param fllStableDelay Delay function to make sure FLL is stable. Passing * NULL does not cause a delay. * * @retval kStatus_MCG_ModeUnreachable Could not switch to the target mode. * @retval kStatus_Success Switched to the target mode successfully. */ status_t CLOCK_SetFeeMode(uint8_t frdiv, mcg_dmx32_t dmx32, mcg_drs_t drs, void (*fllStableDelay)(void)); /*! * @brief Sets the MCG to FBI mode. * * This function sets the MCG to FBI mode. If setting to FBI mode fails * from the current mode, this function returns an error. * * @param dmx32 DMX32 in FBI mode. * @param drs The DCO range selection. * @param fllStableDelay Delay function to make sure FLL is stable. If the FLL * is not used in FBI mode, this parameter can be NULL. Passing * NULL does not cause a delay. * @retval kStatus_MCG_ModeUnreachable Could not switch to the target mode. * @retval kStatus_Success Switched to the target mode successfully. * @note If @p dmx32 is set to kMCG_Dmx32Fine, the slow IRC must not be trimmed * to frequency above 32768 Hz. */ status_t CLOCK_SetFbiMode(mcg_dmx32_t dmx32, mcg_drs_t drs, void (*fllStableDelay)(void)); /*! * @brief Sets the MCG to FBE mode. * * This function sets the MCG to FBE mode. If setting to FBE mode fails * from the current mode, this function returns an error. * * @param frdiv FLL reference clock divider setting, FRDIV. * @param dmx32 DMX32 in FBE mode. * @param drs The DCO range selection. * @param fllStableDelay Delay function to make sure FLL is stable. If the FLL * is not used in FBE mode, this parameter can be NULL. Passing NULL * does not cause a delay. * @retval kStatus_MCG_ModeUnreachable Could not switch to the target mode. * @retval kStatus_Success Switched to the target mode successfully. */ status_t CLOCK_SetFbeMode(uint8_t frdiv, mcg_dmx32_t dmx32, mcg_drs_t drs, void (*fllStableDelay)(void)); /*! * @brief Sets the MCG to BLPI mode. * * This function sets the MCG to BLPI mode. If setting to BLPI mode fails * from the current mode, this function returns an error. * * @retval kStatus_MCG_ModeUnreachable Could not switch to the target mode. * @retval kStatus_Success Switched to the target mode successfully. */ status_t CLOCK_SetBlpiMode(void); /*! * @brief Sets the MCG to BLPE mode. * * This function sets the MCG to BLPE mode. If setting to BLPE mode fails * from the current mode, this function returns an error. * * @retval kStatus_MCG_ModeUnreachable Could not switch to the target mode. * @retval kStatus_Success Switched to the target mode successfully. */ status_t CLOCK_SetBlpeMode(void); /*! * @brief Sets the MCG to PBE mode. * * This function sets the MCG to PBE mode. If setting to PBE mode fails * from the current mode, this function returns an error. * * @param pllcs The PLL selection, PLLCS. * @param config Pointer to the PLL configuration. * @retval kStatus_MCG_ModeUnreachable Could not switch to the target mode. * @retval kStatus_Success Switched to the target mode successfully. * * @note * 1. The parameter \c pllcs selects the PLL. For platforms with * only one PLL, the parameter pllcs is kept for interface compatibility. * 2. The parameter \c config is the PLL configuration structure. On some * platforms, it is possible to choose the external PLL directly, which renders the * configuration structure not necessary. In this case, pass in NULL. * For example: CLOCK_SetPbeMode(kMCG_OscselOsc, kMCG_PllClkSelExtPll, NULL); */ status_t CLOCK_SetPbeMode(mcg_pll_clk_select_t pllcs, mcg_pll_config_t const *config); /*! * @brief Sets the MCG to PEE mode. * * This function sets the MCG to PEE mode. * * @retval kStatus_MCG_ModeUnreachable Could not switch to the target mode. * @retval kStatus_Success Switched to the target mode successfully. * * @note This function only changes the CLKS to use the PLL/FLL output. If the * PRDIV/VDIV are different than in the PBE mode, set them up * in PBE mode and wait. When the clock is stable, switch to PEE mode. */ status_t CLOCK_SetPeeMode(void); /*! * @brief Switches the MCG to FBE mode from the external mode. * * This function switches the MCG from external modes (PEE/PBE/BLPE/FEE) to the FBE mode quickly. * The external clock is used as the system clock souce and PLL is disabled. However, * the FLL settings are not configured. This is a lite function with a small code size, which is useful * during the mode switch. For example, to switch from PEE mode to FEI mode: * * @code * CLOCK_ExternalModeToFbeModeQuick(); * CLOCK_SetFeiMode(...); * @endcode * * @retval kStatus_Success Switched successfully. * @retval kStatus_MCG_ModeInvalid If the current mode is not an external mode, do not call this function. */ status_t CLOCK_ExternalModeToFbeModeQuick(void); /*! * @brief Switches the MCG to FBI mode from internal modes. * * This function switches the MCG from internal modes (PEI/PBI/BLPI/FEI) to the FBI mode quickly. * The MCGIRCLK is used as the system clock souce and PLL is disabled. However, * FLL settings are not configured. This is a lite function with a small code size, which is useful * during the mode switch. For example, to switch from PEI mode to FEE mode: * * @code * CLOCK_InternalModeToFbiModeQuick(); * CLOCK_SetFeeMode(...); * @endcode * * @retval kStatus_Success Switched successfully. * @retval kStatus_MCG_ModeInvalid If the current mode is not an internal mode, do not call this function. */ status_t CLOCK_InternalModeToFbiModeQuick(void); /*! * @brief Sets the MCG to FEI mode during system boot up. * * This function sets the MCG to FEI mode from the reset mode. It can also be used to * set up MCG during system boot up. * * @param dmx32 DMX32 in FEI mode. * @param drs The DCO range selection. * @param fllStableDelay Delay function to ensure that the FLL is stable. * * @retval kStatus_MCG_ModeUnreachable Could not switch to the target mode. * @retval kStatus_Success Switched to the target mode successfully. * @note If @p dmx32 is set to kMCG_Dmx32Fine, the slow IRC must not be trimmed * to frequency above 32768 Hz. */ status_t CLOCK_BootToFeiMode(mcg_dmx32_t dmx32, mcg_drs_t drs, void (*fllStableDelay)(void)); /*! * @brief Sets the MCG to FEE mode during system bootup. * * This function sets MCG to FEE mode from the reset mode. It can also be used to * set up the MCG during system boot up. * * @param oscsel OSC clock select, OSCSEL. * @param frdiv FLL reference clock divider setting, FRDIV. * @param dmx32 DMX32 in FEE mode. * @param drs The DCO range selection. * @param fllStableDelay Delay function to ensure that the FLL is stable. * * @retval kStatus_MCG_ModeUnreachable Could not switch to the target mode. * @retval kStatus_Success Switched to the target mode successfully. */ status_t CLOCK_BootToFeeMode( mcg_oscsel_t oscsel, uint8_t frdiv, mcg_dmx32_t dmx32, mcg_drs_t drs, void (*fllStableDelay)(void)); /*! * @brief Sets the MCG to BLPI mode during system boot up. * * This function sets the MCG to BLPI mode from the reset mode. It can also be used to * set up the MCG during sytem boot up. * * @param fcrdiv Fast IRC divider, FCRDIV. * @param ircs The internal reference clock to select, IRCS. * @param ircEnableMode The MCGIRCLK enable mode, OR'ed value of @ref _mcg_irclk_enable_mode. * * @retval kStatus_MCG_SourceUsed Could not change MCGIRCLK setting. * @retval kStatus_Success Switched to the target mode successfully. */ status_t CLOCK_BootToBlpiMode(uint8_t fcrdiv, mcg_irc_mode_t ircs, uint8_t ircEnableMode); /*! * @brief Sets the MCG to BLPE mode during sytem boot up. * * This function sets the MCG to BLPE mode from the reset mode. It can also be used to * set up the MCG during sytem boot up. * * @param oscsel OSC clock select, MCG_C7[OSCSEL]. * * @retval kStatus_MCG_ModeUnreachable Could not switch to the target mode. * @retval kStatus_Success Switched to the target mode successfully. */ status_t CLOCK_BootToBlpeMode(mcg_oscsel_t oscsel); /*! * @brief Sets the MCG to PEE mode during system boot up. * * This function sets the MCG to PEE mode from reset mode. It can also be used to * set up the MCG during system boot up. * * @param oscsel OSC clock select, MCG_C7[OSCSEL]. * @param pllcs The PLL selection, PLLCS. * @param config Pointer to the PLL configuration. * * @retval kStatus_MCG_ModeUnreachable Could not switch to the target mode. * @retval kStatus_Success Switched to the target mode successfully. */ status_t CLOCK_BootToPeeMode(mcg_oscsel_t oscsel, mcg_pll_clk_select_t pllcs, mcg_pll_config_t const *config); /*! * @brief Sets the MCG to a target mode. * * This function sets MCG to a target mode defined by the configuration * structure. If switching to the target mode fails, this function * chooses the correct path. * * @param config Pointer to the target MCG mode configuration structure. * @return Return kStatus_Success if switched successfully; Otherwise, it returns an error code #_mcg_status. * * @note If the external clock is used in the target mode, ensure that it is * enabled. For example, if the OSC0 is used, set up OSC0 correctly before calling this * function. */ status_t CLOCK_SetMcgConfig(mcg_config_t const *config); /*@}*/ #if defined(__cplusplus) } #endif /* __cplusplus */ /*! @} */ #endif /* _FSL_CLOCK_H_ */