rt-thread-official/bsp/imxrt/Libraries/imxrt1050/devices/MIMXRT1052/drivers/fsl_clock.h

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2018-09-20 23:18:14 +08:00
/*
* The Clear BSD License
* Copyright 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 the 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 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 2.1.2. */
#define FSL_CLOCK_DRIVER_VERSION (MAKE_VERSION(2, 1, 2))
/* analog pll definition */
#define CCM_ANALOG_PLL_BYPASS_SHIFT (16U)
#define CCM_ANALOG_PLL_BYPASS_CLK_SRC_MASK (0xC000U)
#define CCM_ANALOG_PLL_BYPASS_CLK_SRC_SHIFT (14U)
/*@}*/
#define CCM_TUPLE(reg, shift, mask, busyShift) \
((((uint32_t)(&((CCM_Type *)0U)->reg)) & 0xFFU) | ((shift) << 8U) | ((((mask) >> (shift)) & 0x1FFFU) << 13U) | \
((busyShift) << 26U))
#define CCM_TUPLE_REG(base, tuple) (*((volatile uint32_t *)(((uint32_t)(base)) + ((tuple)&0xFFU))))
#define CCM_TUPLE_SHIFT(tuple) (((tuple) >> 8U) & 0x1FU)
#define CCM_TUPLE_MASK(tuple) ((uint32_t)((((tuple) >> 13U) & 0x1FFFU) << ((((tuple) >> 8U) & 0x1FU))))
#define CCM_TUPLE_BUSY_SHIFT(tuple) (((tuple) >> 26U) & 0x3FU)
#define CCM_NO_BUSY_WAIT (0x20U)
/*!
* @brief CCM ANALOG tuple macros to map corresponding registers and bit fields.
*/
#define CCM_ANALOG_TUPLE(reg, shift) ((((uint32_t)(&((CCM_ANALOG_Type *)0U)->reg) & 0xFFFU) << 16U) | (shift))
#define CCM_ANALOG_TUPLE_SHIFT(tuple) (((uint32_t)tuple) & 0x1FU)
#define CCM_ANALOG_TUPLE_REG_OFF(base, tuple, off) \
(*((volatile uint32_t *)((uint32_t)base + (((uint32_t)tuple >> 16U) & 0xFFFU) + off)))
#define CCM_ANALOG_TUPLE_REG(base, tuple) CCM_ANALOG_TUPLE_REG_OFF(base, tuple, 0U)
/*!
* @brief clock1PN frequency.
*/
#define CLKPN_FREQ 0U
/*! @brief External XTAL (24M OSC/SYSOSC) clock frequency.
*
* The XTAL (24M OSC/SYSOSC) clock frequency in Hz, when the clock is setup, use the
* function CLOCK_SetXtalFreq to set the value in to clock driver. For example,
* if XTAL is 24MHz,
* @code
* CLOCK_InitExternalClk(false); // Setup the 24M OSC/SYSOSC
* CLOCK_SetXtalFreq(240000000); // Set the XTAL value to clock driver.
* @endcode
*/
extern uint32_t g_xtalFreq;
/*! @brief External RTC XTAL (32K OSC) clock frequency.
*
* The RTC XTAL (32K OSC) clock frequency in Hz, when the clock is setup, use the
* function CLOCK_SetRtcXtalFreq to set the value in to clock driver.
*/
extern uint32_t g_rtcXtalFreq;
/* For compatible with other platforms */
#define CLOCK_SetXtal0Freq CLOCK_SetXtalFreq
#define CLOCK_SetXtal32Freq CLOCK_SetRtcXtalFreq
/*! @brief Clock ip name array for ADC. */
#define ADC_CLOCKS \
{ \
kCLOCK_IpInvalid, kCLOCK_Adc1, kCLOCK_Adc2 \
}
/*! @brief Clock ip name array for AOI. */
#define AOI_CLOCKS \
{ \
kCLOCK_IpInvalid, kCLOCK_Aoi1, kCLOCK_Aoi2 \
}
/*! @brief Clock ip name array for BEE. */
#define BEE_CLOCKS \
{ \
kCLOCK_Bee \
}
/*! @brief Clock ip name array for CMP. */
#define CMP_CLOCKS \
{ \
kCLOCK_IpInvalid, kCLOCK_Acmp1, kCLOCK_Acmp2, kCLOCK_Acmp3, kCLOCK_Acmp4 \
}
/*! @brief Clock ip name array for CSI. */
#define CSI_CLOCKS \
{ \
kCLOCK_Csi \
}
/*! @brief Clock ip name array for DCDC. */
#define DCDC_CLOCKS \
{ \
kCLOCK_Dcdc \
}
/*! @brief Clock ip name array for DCP. */
#define DCP_CLOCKS \
{ \
kCLOCK_Dcp \
}
/*! @brief Clock ip name array for DMAMUX_CLOCKS. */
#define DMAMUX_CLOCKS \
{ \
kCLOCK_Dma \
}
/*! @brief Clock ip name array for DMA. */
#define EDMA_CLOCKS \
{ \
kCLOCK_Dma \
}
/*! @brief Clock ip name array for ENC. */
#define ENC_CLOCKS \
{ \
kCLOCK_IpInvalid, kCLOCK_Enc1, kCLOCK_Enc2, kCLOCK_Enc3, kCLOCK_Enc4 \
}
/*! @brief Clock ip name array for ENET. */
#define ENET_CLOCKS \
{ \
kCLOCK_Enet \
}
/*! @brief Clock ip name array for EWM. */
#define EWM_CLOCKS \
{ \
kCLOCK_Ewm0 \
}
/*! @brief Clock ip name array for FLEXCAN. */
#define FLEXCAN_CLOCKS \
{ \
kCLOCK_IpInvalid, kCLOCK_Can1, kCLOCK_Can2 \
}
/*! @brief Clock ip name array for FLEXCAN Peripheral clock. */
#define FLEXCAN_PERIPH_CLOCKS \
{ \
kCLOCK_IpInvalid, kCLOCK_Can1S, kCLOCK_Can2S \
}
/*! @brief Clock ip name array for FLEXIO. */
#define FLEXIO_CLOCKS \
{ \
kCLOCK_IpInvalid, kCLOCK_Flexio1, kCLOCK_Flexio2 \
}
/*! @brief Clock ip name array for FLEXRAM. */
#define FLEXRAM_CLOCKS \
{ \
kCLOCK_FlexRam \
}
/*! @brief Clock ip name array for FLEXSPI. */
#define FLEXSPI_CLOCKS \
{ \
kCLOCK_FlexSpi \
}
/*! @brief Clock ip name array for FLEXSPI EXSC. */
#define FLEXSPI_EXSC_CLOCKS \
{ \
kCLOCK_FlexSpiExsc \
}
/*! @brief Clock ip name array for GPIO. */
#define GPIO_CLOCKS \
{ \
kCLOCK_IpInvalid, kCLOCK_Gpio1, kCLOCK_Gpio2, kCLOCK_Gpio3, kCLOCK_Gpio4, kCLOCK_Gpio5 \
}
/*! @brief Clock ip name array for GPT. */
#define GPT_CLOCKS \
{ \
kCLOCK_IpInvalid, kCLOCK_Gpt1, kCLOCK_Gpt2 \
}
/*! @brief Clock ip name array for KPP. */
#define KPP_CLOCKS \
{ \
kCLOCK_Kpp \
}
/*! @brief Clock ip name array for LCDIF. */
#define LCDIF_CLOCKS \
{ \
kCLOCK_Lcd \
}
/*! @brief Clock ip name array for LCDIF PIXEL. */
#define LCDIF_PERIPH_CLOCKS \
{ \
kCLOCK_LcdPixel \
}
/*! @brief Clock ip name array for LPI2C. */
#define LPI2C_CLOCKS \
{ \
kCLOCK_IpInvalid, kCLOCK_Lpi2c1, kCLOCK_Lpi2c2, kCLOCK_Lpi2c3, kCLOCK_Lpi2c4 \
}
/*! @brief Clock ip name array for LPSPI. */
#define LPSPI_CLOCKS \
{ \
kCLOCK_IpInvalid, kCLOCK_Lpspi1, kCLOCK_Lpspi2, kCLOCK_Lpspi3, kCLOCK_Lpspi4 \
}
/*! @brief Clock ip name array for LPUART. */
#define LPUART_CLOCKS \
{ \
kCLOCK_IpInvalid, kCLOCK_Lpuart1, kCLOCK_Lpuart2, kCLOCK_Lpuart3, kCLOCK_Lpuart4, kCLOCK_Lpuart5, \
kCLOCK_Lpuart6, kCLOCK_Lpuart7, kCLOCK_Lpuart8 \
}
/*! @brief Clock ip name array for MQS. */
#define MQS_CLOCKS \
{ \
kCLOCK_Mqs \
}
/*! @brief Clock ip name array for OCRAM EXSC. */
#define OCRAM_EXSC_CLOCKS \
{ \
kCLOCK_OcramExsc \
}
/*! @brief Clock ip name array for PIT. */
#define PIT_CLOCKS \
{ \
kCLOCK_Pit \
}
/*! @brief Clock ip name array for PWM. */
#define PWM_CLOCKS \
{ \
{ \
kCLOCK_IpInvalid, kCLOCK_IpInvalid, kCLOCK_IpInvalid, kCLOCK_IpInvalid \
} \
, {kCLOCK_Pwm1, kCLOCK_Pwm1, kCLOCK_Pwm1, kCLOCK_Pwm1}, {kCLOCK_Pwm2, kCLOCK_Pwm2, kCLOCK_Pwm2, kCLOCK_Pwm2}, \
{kCLOCK_Pwm3, kCLOCK_Pwm3, kCLOCK_Pwm3, kCLOCK_Pwm3}, \
{ \
kCLOCK_Pwm4, kCLOCK_Pwm4, kCLOCK_Pwm4, kCLOCK_Pwm4 \
} \
}
/*! @brief Clock ip name array for PXP. */
#define PXP_CLOCKS \
{ \
kCLOCK_Pxp \
}
/*! @brief Clock ip name array for RTWDOG. */
#define RTWDOG_CLOCKS \
{ \
kCLOCK_Wdog3 \
}
/*! @brief Clock ip name array for SAI. */
#define SAI_CLOCKS \
{ \
kCLOCK_IpInvalid, kCLOCK_Sai1, kCLOCK_Sai2, kCLOCK_Sai3 \
}
/*! @brief Clock ip name array for SEMC. */
#define SEMC_CLOCKS \
{ \
kCLOCK_Semc \
}
/*! @brief Clock ip name array for SEMC EXSC. */
#define SEMC_EXSC_CLOCKS \
{ \
kCLOCK_SemcExsc \
}
/*! @brief Clock ip name array for QTIMER. */
#define TMR_CLOCKS \
{ \
kCLOCK_IpInvalid, kCLOCK_Timer1, kCLOCK_Timer2, kCLOCK_Timer3, kCLOCK_Timer4 \
}
/*! @brief Clock ip name array for TRNG. */
#define TRNG_CLOCKS \
{ \
kCLOCK_Trng \
}
/*! @brief Clock ip name array for TSC. */
#define TSC_CLOCKS \
{ \
kCLOCK_Tsc \
}
/*! @brief Clock ip name array for WDOG. */
#define WDOG_CLOCKS \
{ \
kCLOCK_IpInvalid, kCLOCK_Wdog1, kCLOCK_Wdog2 \
}
/*! @brief Clock ip name array for USDHC. */
#define USDHC_CLOCKS \
{ \
kCLOCK_IpInvalid, kCLOCK_Usdhc1, kCLOCK_Usdhc2 \
}
/*! @brief Clock ip name array for SPDIF. */
#define SPDIF_CLOCKS \
{ \
kCLOCK_Spdif \
}
/*! @brief Clock ip name array for XBARA. */
#define XBARA_CLOCKS \
{ \
kCLOCK_Xbar1 \
}
/*! @brief Clock ip name array for XBARB. */
#define XBARB_CLOCKS \
{ \
kCLOCK_IpInvalid, kCLOCK_IpInvalid, kCLOCK_Xbar2, kCLOCK_Xbar3 \
}
/*! @brief Clock name used to get clock frequency. */
typedef enum _clock_name
{
kCLOCK_CpuClk = 0x0U, /*!< CPU clock */
kCLOCK_AhbClk = 0x1U, /*!< AHB clock */
kCLOCK_SemcClk = 0x2U, /*!< SEMC clock */
kCLOCK_IpgClk = 0x3U, /*!< IPG clock */
kCLOCK_OscClk = 0x4U, /*!< OSC clock selected by PMU_LOWPWR_CTRL[OSC_SEL]. */
kCLOCK_RtcClk = 0x5U, /*!< RTC clock. (RTCCLK) */
kCLOCK_ArmPllClk = 0x6U, /*!< ARMPLLCLK. */
kCLOCK_Usb1PllClk = 0x7U, /*!< USB1PLLCLK. */
kCLOCK_Usb1PllPfd0Clk = 0x8U, /*!< USB1PLLPDF0CLK. */
kCLOCK_Usb1PllPfd1Clk = 0x9U, /*!< USB1PLLPFD1CLK. */
kCLOCK_Usb1PllPfd2Clk = 0xAU, /*!< USB1PLLPFD2CLK. */
kCLOCK_Usb1PllPfd3Clk = 0xBU, /*!< USB1PLLPFD3CLK. */
kCLOCK_Usb2PllClk = 0xCU, /*!< USB2PLLCLK. */
kCLOCK_SysPllClk = 0xDU, /*!< SYSPLLCLK. */
kCLOCK_SysPllPfd0Clk = 0xEU, /*!< SYSPLLPDF0CLK. */
kCLOCK_SysPllPfd1Clk = 0xFU, /*!< SYSPLLPFD1CLK. */
kCLOCK_SysPllPfd2Clk = 0x10U, /*!< SYSPLLPFD2CLK. */
kCLOCK_SysPllPfd3Clk = 0x11U, /*!< SYSPLLPFD3CLK. */
kCLOCK_EnetPll0Clk = 0x12U, /*!< Enet PLLCLK ref_enetpll0. */
kCLOCK_EnetPll1Clk = 0x13U, /*!< Enet PLLCLK ref_enetpll1. */
kCLOCK_AudioPllClk = 0x14U, /*!< Audio PLLCLK. */
kCLOCK_VideoPllClk = 0x15U, /*!< Video PLLCLK. */
} clock_name_t;
#define kCLOCK_CoreSysClk kCLOCK_CpuClk /*!< For compatible with other platforms without CCM. */
#define CLOCK_GetCoreSysClkFreq CLOCK_GetCpuClkFreq /*!< For compatible with other platforms without CCM. */
/*!
* @brief CCM CCGR gate control for each module independently.
*/
typedef enum _clock_ip_name
{
kCLOCK_IpInvalid = -1,
/* CCM CCGR0 */
kCLOCK_Aips_tz1 = (0U << 8U) | CCM_CCGR0_CG0_SHIFT, /*!< CCGR0, CG0 */
kCLOCK_Aips_tz2 = (0U << 8U) | CCM_CCGR0_CG1_SHIFT, /*!< CCGR0, CG1 */
kCLOCK_Mqs = (0U << 8U) | CCM_CCGR0_CG2_SHIFT, /*!< CCGR0, CG2 */
kCLOCK_FlexSpiExsc = (0U << 8U) | CCM_CCGR0_CG3_SHIFT, /*!< CCGR0, CG3 */
kCLOCK_Sim_M_Main = (0U << 8U) | CCM_CCGR0_CG4_SHIFT, /*!< CCGR0, CG4 */
kCLOCK_Dcp = (0U << 8U) | CCM_CCGR0_CG5_SHIFT, /*!< CCGR0, CG5 */
kCLOCK_Lpuart3 = (0U << 8U) | CCM_CCGR0_CG6_SHIFT, /*!< CCGR0, CG6 */
kCLOCK_Can1 = (0U << 8U) | CCM_CCGR0_CG7_SHIFT, /*!< CCGR0, CG7 */
kCLOCK_Can1S = (0U << 8U) | CCM_CCGR0_CG8_SHIFT, /*!< CCGR0, CG8 */
kCLOCK_Can2 = (0U << 8U) | CCM_CCGR0_CG9_SHIFT, /*!< CCGR0, CG9 */
kCLOCK_Can2S = (0U << 8U) | CCM_CCGR0_CG10_SHIFT, /*!< CCGR0, CG10 */
kCLOCK_Trace = (0U << 8U) | CCM_CCGR0_CG11_SHIFT, /*!< CCGR0, CG11 */
kCLOCK_Gpt2 = (0U << 8U) | CCM_CCGR0_CG12_SHIFT, /*!< CCGR0, CG12 */
kCLOCK_Gpt2S = (0U << 8U) | CCM_CCGR0_CG13_SHIFT, /*!< CCGR0, CG13 */
kCLOCK_Lpuart2 = (0U << 8U) | CCM_CCGR0_CG14_SHIFT, /*!< CCGR0, CG14 */
kCLOCK_Gpio2 = (0U << 8U) | CCM_CCGR0_CG15_SHIFT, /*!< CCGR0, CG15 */
/* CCM CCGR1 */
kCLOCK_Lpspi1 = (1U << 8U) | CCM_CCGR1_CG0_SHIFT, /*!< CCGR1, CG0 */
kCLOCK_Lpspi2 = (1U << 8U) | CCM_CCGR1_CG1_SHIFT, /*!< CCGR1, CG1 */
kCLOCK_Lpspi3 = (1U << 8U) | CCM_CCGR1_CG2_SHIFT, /*!< CCGR1, CG2 */
kCLOCK_Lpspi4 = (1U << 8U) | CCM_CCGR1_CG3_SHIFT, /*!< CCGR1, CG3 */
kCLOCK_Adc2 = (1U << 8U) | CCM_CCGR1_CG4_SHIFT, /*!< CCGR1, CG4 */
kCLOCK_Enet = (1U << 8U) | CCM_CCGR1_CG5_SHIFT, /*!< CCGR1, CG5 */
kCLOCK_Pit = (1U << 8U) | CCM_CCGR1_CG6_SHIFT, /*!< CCGR1, CG6 */
kCLOCK_Aoi2 = (1U << 8U) | CCM_CCGR1_CG7_SHIFT, /*!< CCGR1, CG7 */
kCLOCK_Adc1 = (1U << 8U) | CCM_CCGR1_CG8_SHIFT, /*!< CCGR1, CG8 */
kCLOCK_SemcExsc = (1U << 8U) | CCM_CCGR1_CG9_SHIFT, /*!< CCGR1, CG9 */
kCLOCK_Gpt1 = (1U << 8U) | CCM_CCGR1_CG10_SHIFT, /*!< CCGR1, CG10 */
kCLOCK_Gpt1S = (1U << 8U) | CCM_CCGR1_CG11_SHIFT, /*!< CCGR1, CG11 */
kCLOCK_Lpuart4 = (1U << 8U) | CCM_CCGR1_CG12_SHIFT, /*!< CCGR1, CG12 */
kCLOCK_Gpio1 = (1U << 8U) | CCM_CCGR1_CG13_SHIFT, /*!< CCGR1, CG13 */
kCLOCK_Csu = (1U << 8U) | CCM_CCGR1_CG14_SHIFT, /*!< CCGR1, CG14 */
kCLOCK_Gpio5 = (1U << 8U) | CCM_CCGR1_CG15_SHIFT, /*!< CCGR1, CG15 */
/* CCM CCGR2 */
kCLOCK_OcramExsc = (2U << 8U) | CCM_CCGR2_CG0_SHIFT, /*!< CCGR2, CG0 */
kCLOCK_Csi = (2U << 8U) | CCM_CCGR2_CG1_SHIFT, /*!< CCGR2, CG1 */
kCLOCK_IomuxcSnvs = (2U << 8U) | CCM_CCGR2_CG2_SHIFT, /*!< CCGR2, CG2 */
kCLOCK_Lpi2c1 = (2U << 8U) | CCM_CCGR2_CG3_SHIFT, /*!< CCGR2, CG3 */
kCLOCK_Lpi2c2 = (2U << 8U) | CCM_CCGR2_CG4_SHIFT, /*!< CCGR2, CG4 */
kCLOCK_Lpi2c3 = (2U << 8U) | CCM_CCGR2_CG5_SHIFT, /*!< CCGR2, CG5 */
kCLOCK_Ocotp = (2U << 8U) | CCM_CCGR2_CG6_SHIFT, /*!< CCGR2, CG6 */
kCLOCK_Xbar3 = (2U << 8U) | CCM_CCGR2_CG7_SHIFT, /*!< CCGR2, CG7 */
kCLOCK_Ipmux1 = (2U << 8U) | CCM_CCGR2_CG8_SHIFT, /*!< CCGR2, CG8 */
kCLOCK_Ipmux2 = (2U << 8U) | CCM_CCGR2_CG9_SHIFT, /*!< CCGR2, CG9 */
kCLOCK_Ipmux3 = (2U << 8U) | CCM_CCGR2_CG10_SHIFT, /*!< CCGR2, CG10 */
kCLOCK_Xbar1 = (2U << 8U) | CCM_CCGR2_CG11_SHIFT, /*!< CCGR2, CG11 */
kCLOCK_Xbar2 = (2U << 8U) | CCM_CCGR2_CG12_SHIFT, /*!< CCGR2, CG12 */
kCLOCK_Gpio3 = (2U << 8U) | CCM_CCGR2_CG13_SHIFT, /*!< CCGR2, CG13 */
kCLOCK_Lcd = (2U << 8U) | CCM_CCGR2_CG14_SHIFT, /*!< CCGR2, CG14 */
kCLOCK_Pxp = (2U << 8U) | CCM_CCGR2_CG15_SHIFT, /*!< CCGR2, CG15 */
/* CCM CCGR3 */
kCLOCK_Flexio2 = (3U << 8U) | CCM_CCGR3_CG0_SHIFT, /*!< CCGR3, CG0 */
kCLOCK_Lpuart5 = (3U << 8U) | CCM_CCGR3_CG1_SHIFT, /*!< CCGR3, CG1 */
kCLOCK_Semc = (3U << 8U) | CCM_CCGR3_CG2_SHIFT, /*!< CCGR3, CG2 */
kCLOCK_Lpuart6 = (3U << 8U) | CCM_CCGR3_CG3_SHIFT, /*!< CCGR3, CG3 */
kCLOCK_Aoi1 = (3U << 8U) | CCM_CCGR3_CG4_SHIFT, /*!< CCGR3, CG4 */
kCLOCK_LcdPixel = (3U << 8U) | CCM_CCGR3_CG5_SHIFT, /*!< CCGR3, CG5 */
kCLOCK_Gpio4 = (3U << 8U) | CCM_CCGR3_CG6_SHIFT, /*!< CCGR3, CG6 */
kCLOCK_Ewm0 = (3U << 8U) | CCM_CCGR3_CG7_SHIFT, /*!< CCGR3, CG7 */
kCLOCK_Wdog1 = (3U << 8U) | CCM_CCGR3_CG8_SHIFT, /*!< CCGR3, CG8 */
kCLOCK_FlexRam = (3U << 8U) | CCM_CCGR3_CG9_SHIFT, /*!< CCGR3, CG9 */
kCLOCK_Acmp1 = (3U << 8U) | CCM_CCGR3_CG10_SHIFT, /*!< CCGR3, CG10 */
kCLOCK_Acmp2 = (3U << 8U) | CCM_CCGR3_CG11_SHIFT, /*!< CCGR3, CG11 */
kCLOCK_Acmp3 = (3U << 8U) | CCM_CCGR3_CG12_SHIFT, /*!< CCGR3, CG12 */
kCLOCK_Acmp4 = (3U << 8U) | CCM_CCGR3_CG13_SHIFT, /*!< CCGR3, CG13 */
kCLOCK_Ocram = (3U << 8U) | CCM_CCGR3_CG14_SHIFT, /*!< CCGR3, CG14 */
kCLOCK_IomuxcSnvsGpr = (3U << 8U) | CCM_CCGR3_CG15_SHIFT, /*!< CCGR3, CG15 */
/* CCM CCGR4 */
kCLOCK_Iomuxc = (4U << 8U) | CCM_CCGR4_CG1_SHIFT, /*!< CCGR4, CG1 */
kCLOCK_IomuxcGpr = (4U << 8U) | CCM_CCGR4_CG2_SHIFT, /*!< CCGR4, CG2 */
kCLOCK_Bee = (4U << 8U) | CCM_CCGR4_CG3_SHIFT, /*!< CCGR4, CG3 */
kCLOCK_SimM7 = (4U << 8U) | CCM_CCGR4_CG4_SHIFT, /*!< CCGR4, CG4 */
kCLOCK_Tsc = (4U << 8U) | CCM_CCGR4_CG5_SHIFT, /*!< CCGR4, CG5 */
kCLOCK_SimM = (4U << 8U) | CCM_CCGR4_CG6_SHIFT, /*!< CCGR4, CG6 */
kCLOCK_SimEms = (4U << 8U) | CCM_CCGR4_CG7_SHIFT, /*!< CCGR4, CG7 */
kCLOCK_Pwm1 = (4U << 8U) | CCM_CCGR4_CG8_SHIFT, /*!< CCGR4, CG8 */
kCLOCK_Pwm2 = (4U << 8U) | CCM_CCGR4_CG9_SHIFT, /*!< CCGR4, CG9 */
kCLOCK_Pwm3 = (4U << 8U) | CCM_CCGR4_CG10_SHIFT, /*!< CCGR4, CG10 */
kCLOCK_Pwm4 = (4U << 8U) | CCM_CCGR4_CG11_SHIFT, /*!< CCGR4, CG11 */
kCLOCK_Enc1 = (4U << 8U) | CCM_CCGR4_CG12_SHIFT, /*!< CCGR4, CG12 */
kCLOCK_Enc2 = (4U << 8U) | CCM_CCGR4_CG13_SHIFT, /*!< CCGR4, CG13 */
kCLOCK_Enc3 = (4U << 8U) | CCM_CCGR4_CG14_SHIFT, /*!< CCGR4, CG14 */
kCLOCK_Enc4 = (4U << 8U) | CCM_CCGR4_CG15_SHIFT, /*!< CCGR4, CG15 */
/* CCM CCGR5 */
kCLOCK_Rom = (5U << 8U) | CCM_CCGR5_CG0_SHIFT, /*!< CCGR5, CG0 */
kCLOCK_Flexio1 = (5U << 8U) | CCM_CCGR5_CG1_SHIFT, /*!< CCGR5, CG1 */
kCLOCK_Wdog3 = (5U << 8U) | CCM_CCGR5_CG2_SHIFT, /*!< CCGR5, CG2 */
kCLOCK_Dma = (5U << 8U) | CCM_CCGR5_CG3_SHIFT, /*!< CCGR5, CG3 */
kCLOCK_Kpp = (5U << 8U) | CCM_CCGR5_CG4_SHIFT, /*!< CCGR5, CG4 */
kCLOCK_Wdog2 = (5U << 8U) | CCM_CCGR5_CG5_SHIFT, /*!< CCGR5, CG5 */
kCLOCK_Aips_tz4 = (5U << 8U) | CCM_CCGR5_CG6_SHIFT, /*!< CCGR5, CG6 */
kCLOCK_Spdif = (5U << 8U) | CCM_CCGR5_CG7_SHIFT, /*!< CCGR5, CG7 */
kCLOCK_SimMain = (5U << 8U) | CCM_CCGR5_CG8_SHIFT, /*!< CCGR5, CG8 */
kCLOCK_Sai1 = (5U << 8U) | CCM_CCGR5_CG9_SHIFT, /*!< CCGR5, CG9 */
kCLOCK_Sai2 = (5U << 8U) | CCM_CCGR5_CG10_SHIFT, /*!< CCGR5, CG10 */
kCLOCK_Sai3 = (5U << 8U) | CCM_CCGR5_CG11_SHIFT, /*!< CCGR5, CG11 */
kCLOCK_Lpuart1 = (5U << 8U) | CCM_CCGR5_CG12_SHIFT, /*!< CCGR5, CG12 */
kCLOCK_Lpuart7 = (5U << 8U) | CCM_CCGR5_CG13_SHIFT, /*!< CCGR5, CG13 */
kCLOCK_SnvsHp = (5U << 8U) | CCM_CCGR5_CG14_SHIFT, /*!< CCGR5, CG14 */
kCLOCK_SnvsLp = (5U << 8U) | CCM_CCGR5_CG15_SHIFT, /*!< CCGR5, CG15 */
/* CCM CCGR6 */
kCLOCK_UsbOh3 = (6U << 8U) | CCM_CCGR6_CG0_SHIFT, /*!< CCGR6, CG0 */
kCLOCK_Usdhc1 = (6U << 8U) | CCM_CCGR6_CG1_SHIFT, /*!< CCGR6, CG1 */
kCLOCK_Usdhc2 = (6U << 8U) | CCM_CCGR6_CG2_SHIFT, /*!< CCGR6, CG2 */
kCLOCK_Dcdc = (6U << 8U) | CCM_CCGR6_CG3_SHIFT, /*!< CCGR6, CG3 */
kCLOCK_Ipmux4 = (6U << 8U) | CCM_CCGR6_CG4_SHIFT, /*!< CCGR6, CG4 */
kCLOCK_FlexSpi = (6U << 8U) | CCM_CCGR6_CG5_SHIFT, /*!< CCGR6, CG5 */
kCLOCK_Trng = (6U << 8U) | CCM_CCGR6_CG6_SHIFT, /*!< CCGR6, CG6 */
kCLOCK_Lpuart8 = (6U << 8U) | CCM_CCGR6_CG7_SHIFT, /*!< CCGR6, CG7 */
kCLOCK_Timer4 = (6U << 8U) | CCM_CCGR6_CG8_SHIFT, /*!< CCGR6, CG8 */
kCLOCK_Aips_tz3 = (6U << 8U) | CCM_CCGR6_CG9_SHIFT, /*!< CCGR6, CG9 */
kCLOCK_SimPer = (6U << 8U) | CCM_CCGR6_CG10_SHIFT, /*!< CCGR6, CG10 */
kCLOCK_Anadig = (6U << 8U) | CCM_CCGR6_CG11_SHIFT, /*!< CCGR6, CG11 */
kCLOCK_Lpi2c4 = (6U << 8U) | CCM_CCGR6_CG12_SHIFT, /*!< CCGR6, CG12 */
kCLOCK_Timer1 = (6U << 8U) | CCM_CCGR6_CG13_SHIFT, /*!< CCGR6, CG13 */
kCLOCK_Timer2 = (6U << 8U) | CCM_CCGR6_CG14_SHIFT, /*!< CCGR6, CG14 */
kCLOCK_Timer3 = (6U << 8U) | CCM_CCGR6_CG15_SHIFT, /*!< CCGR6, CG15 */
} clock_ip_name_t;
/*! @brief OSC 24M sorce select */
typedef enum _clock_osc
{
kCLOCK_RcOsc = 0U, /*!< On chip OSC. */
kCLOCK_XtalOsc = 1U, /*!< 24M Xtal OSC */
} clock_osc_t;
/*! @brief Clock gate value */
typedef enum _clock_gate_value
{
kCLOCK_ClockNotNeeded = 0U, /*!< Clock is off during all modes. */
kCLOCK_ClockNeededRun = 1U, /*!< Clock is on in run mode, but off in WAIT and STOP modes */
kCLOCK_ClockNeededRunWait = 3U, /*!< Clock is on during all modes, except STOP mode */
} clock_gate_value_t;
/*! @brief System clock mode */
typedef enum _clock_mode_t
{
kCLOCK_ModeRun = 0U, /*!< Remain in run mode. */
kCLOCK_ModeWait = 1U, /*!< Transfer to wait mode. */
kCLOCK_ModeStop = 2U, /*!< Transfer to stop mode. */
} clock_mode_t;
/*!
* @brief MUX control names for clock mux setting.
*
* These constants define the mux control names for clock mux setting.\n
* - 0:7: REG offset to CCM_BASE in bytes.
* - 8:15: Root clock setting bit field shift.
* - 16:31: Root clock setting bit field width.
*/
typedef enum _clock_mux
{
kCLOCK_Pll3SwMux = CCM_TUPLE(CCSR,
CCM_CCSR_PLL3_SW_CLK_SEL_SHIFT,
CCM_CCSR_PLL3_SW_CLK_SEL_MASK,
CCM_NO_BUSY_WAIT), /*!< pll3_sw_clk mux name */
kCLOCK_PeriphMux = CCM_TUPLE(CBCDR,
CCM_CBCDR_PERIPH_CLK_SEL_SHIFT,
CCM_CBCDR_PERIPH_CLK_SEL_MASK,
CCM_CDHIPR_PERIPH_CLK_SEL_BUSY_SHIFT), /*!< periph mux name */
kCLOCK_SemcAltMux = CCM_TUPLE(CBCDR,
CCM_CBCDR_SEMC_ALT_CLK_SEL_SHIFT,
CCM_CBCDR_SEMC_ALT_CLK_SEL_MASK,
CCM_NO_BUSY_WAIT), /*!< semc mux name */
kCLOCK_SemcMux = CCM_TUPLE(
CBCDR, CCM_CBCDR_SEMC_CLK_SEL_SHIFT, CCM_CBCDR_SEMC_CLK_SEL_MASK, CCM_NO_BUSY_WAIT), /*!< semc mux name */
kCLOCK_PrePeriphMux = CCM_TUPLE(CBCMR,
CCM_CBCMR_PRE_PERIPH_CLK_SEL_SHIFT,
CCM_CBCMR_PRE_PERIPH_CLK_SEL_MASK,
CCM_NO_BUSY_WAIT), /*!< pre-periph mux name */
kCLOCK_TraceMux = CCM_TUPLE(
CBCMR, CCM_CBCMR_TRACE_CLK_SEL_SHIFT, CCM_CBCMR_TRACE_CLK_SEL_MASK, CCM_NO_BUSY_WAIT), /*!< trace mux name */
kCLOCK_PeriphClk2Mux = CCM_TUPLE(CBCMR,
CCM_CBCMR_PERIPH_CLK2_SEL_SHIFT,
CCM_CBCMR_PERIPH_CLK2_SEL_MASK,
CCM_NO_BUSY_WAIT), /*!< periph clock2 mux name */
kCLOCK_LpspiMux = CCM_TUPLE(
CBCMR, CCM_CBCMR_LPSPI_CLK_SEL_SHIFT, CCM_CBCMR_LPSPI_CLK_SEL_MASK, CCM_NO_BUSY_WAIT), /*!< lpspi mux name */
kCLOCK_FlexspiMux = CCM_TUPLE(CSCMR1,
CCM_CSCMR1_FLEXSPI_CLK_SEL_SHIFT,
CCM_CSCMR1_FLEXSPI_CLK_SEL_MASK,
CCM_NO_BUSY_WAIT), /*!< flexspi mux name */
kCLOCK_Usdhc2Mux = CCM_TUPLE(CSCMR1,
CCM_CSCMR1_USDHC2_CLK_SEL_SHIFT,
CCM_CSCMR1_USDHC2_CLK_SEL_MASK,
CCM_NO_BUSY_WAIT), /*!< usdhc2 mux name */
kCLOCK_Usdhc1Mux = CCM_TUPLE(CSCMR1,
CCM_CSCMR1_USDHC1_CLK_SEL_SHIFT,
CCM_CSCMR1_USDHC1_CLK_SEL_MASK,
CCM_NO_BUSY_WAIT), /*!< usdhc1 mux name */
kCLOCK_Sai3Mux = CCM_TUPLE(
CSCMR1, CCM_CSCMR1_SAI3_CLK_SEL_SHIFT, CCM_CSCMR1_SAI3_CLK_SEL_MASK, CCM_NO_BUSY_WAIT), /*!< sai3 mux name */
kCLOCK_Sai2Mux = CCM_TUPLE(
CSCMR1, CCM_CSCMR1_SAI2_CLK_SEL_SHIFT, CCM_CSCMR1_SAI2_CLK_SEL_MASK, CCM_NO_BUSY_WAIT), /*!< sai2 mux name */
kCLOCK_Sai1Mux = CCM_TUPLE(
CSCMR1, CCM_CSCMR1_SAI1_CLK_SEL_SHIFT, CCM_CSCMR1_SAI1_CLK_SEL_MASK, CCM_NO_BUSY_WAIT), /*!< sai1 mux name */
kCLOCK_PerclkMux = CCM_TUPLE(CSCMR1,
CCM_CSCMR1_PERCLK_CLK_SEL_SHIFT,
CCM_CSCMR1_PERCLK_CLK_SEL_MASK,
CCM_NO_BUSY_WAIT), /*!< perclk mux name */
kCLOCK_Flexio2Mux = CCM_TUPLE(CSCMR2,
CCM_CSCMR2_FLEXIO2_CLK_SEL_SHIFT,
CCM_CSCMR2_FLEXIO2_CLK_SEL_MASK,
CCM_NO_BUSY_WAIT), /*!< flexio2 mux name */
kCLOCK_CanMux = CCM_TUPLE(
CSCMR2, CCM_CSCMR2_CAN_CLK_SEL_SHIFT, CCM_CSCMR2_CAN_CLK_SEL_MASK, CCM_NO_BUSY_WAIT), /*!< can mux name */
kCLOCK_UartMux = CCM_TUPLE(
CSCDR1, CCM_CSCDR1_UART_CLK_SEL_SHIFT, CCM_CSCDR1_UART_CLK_SEL_MASK, CCM_NO_BUSY_WAIT), /*!< uart mux name */
kCLOCK_SpdifMux = CCM_TUPLE(
CDCDR, CCM_CDCDR_SPDIF0_CLK_SEL_SHIFT, CCM_CDCDR_SPDIF0_CLK_SEL_MASK, CCM_NO_BUSY_WAIT), /*!< spdif mux name */
kCLOCK_Flexio1Mux = CCM_TUPLE(CDCDR,
CCM_CDCDR_FLEXIO1_CLK_SEL_SHIFT,
CCM_CDCDR_FLEXIO1_CLK_SEL_MASK,
CCM_NO_BUSY_WAIT), /*!< flexio1 mux name */
kCLOCK_Lpi2cMux = CCM_TUPLE(
CSCDR2, CCM_CSCDR2_LPI2C_CLK_SEL_SHIFT, CCM_CSCDR2_LPI2C_CLK_SEL_MASK, CCM_NO_BUSY_WAIT), /*!< lpi2c mux name */
kCLOCK_LcdifPreMux = CCM_TUPLE(CSCDR2,
CCM_CSCDR2_LCDIF_PRE_CLK_SEL_SHIFT,
CCM_CSCDR2_LCDIF_PRE_CLK_SEL_MASK,
CCM_NO_BUSY_WAIT), /*!< lcdif pre mux name */
kCLOCK_CsiMux = CCM_TUPLE(
CSCDR3, CCM_CSCDR3_CSI_CLK_SEL_SHIFT, CCM_CSCDR3_CSI_CLK_SEL_MASK, CCM_NO_BUSY_WAIT), /*!< csi mux name */
} clock_mux_t;
/*!
* @brief DIV control names for clock div setting.
*
* These constants define div control names for clock div setting.\n
* - 0:7: REG offset to CCM_BASE in bytes.
* - 8:15: Root clock setting bit field shift.
* - 16:31: Root clock setting bit field width.
*/
typedef enum _clock_div
{
kCLOCK_ArmDiv = CCM_TUPLE(
CACRR, CCM_CACRR_ARM_PODF_SHIFT, CCM_CACRR_ARM_PODF_MASK, CCM_CDHIPR_ARM_PODF_BUSY_SHIFT), /*!< core div name */
kCLOCK_PeriphClk2Div = CCM_TUPLE(CBCDR,
CCM_CBCDR_PERIPH_CLK2_PODF_SHIFT,
CCM_CBCDR_PERIPH_CLK2_PODF_MASK,
CCM_NO_BUSY_WAIT), /*!< periph clock2 div name */
kCLOCK_SemcDiv = CCM_TUPLE(CBCDR,
CCM_CBCDR_SEMC_PODF_SHIFT,
CCM_CBCDR_SEMC_PODF_MASK,
CCM_CDHIPR_SEMC_PODF_BUSY_SHIFT), /*!< semc div name */
kCLOCK_AhbDiv = CCM_TUPLE(
CBCDR, CCM_CBCDR_AHB_PODF_SHIFT, CCM_CBCDR_AHB_PODF_MASK, CCM_CDHIPR_AHB_PODF_BUSY_SHIFT), /*!< ahb div name */
kCLOCK_IpgDiv =
CCM_TUPLE(CBCDR, CCM_CBCDR_IPG_PODF_SHIFT, CCM_CBCDR_IPG_PODF_MASK, CCM_NO_BUSY_WAIT), /*!< ipg div name */
kCLOCK_LpspiDiv = CCM_TUPLE(
CBCMR, CCM_CBCMR_LPSPI_PODF_SHIFT, CCM_CBCMR_LPSPI_PODF_MASK, CCM_NO_BUSY_WAIT), /*!< lpspi div name */
kCLOCK_LcdifDiv = CCM_TUPLE(
CBCMR, CCM_CBCMR_LCDIF_PODF_SHIFT, CCM_CBCMR_LCDIF_PODF_MASK, CCM_NO_BUSY_WAIT), /*!< lcdif div name */
kCLOCK_FlexspiDiv = CCM_TUPLE(
CSCMR1, CCM_CSCMR1_FLEXSPI_PODF_SHIFT, CCM_CSCMR1_FLEXSPI_PODF_MASK, CCM_NO_BUSY_WAIT), /*!< flexspi div name */
kCLOCK_PerclkDiv = CCM_TUPLE(
CSCMR1, CCM_CSCMR1_PERCLK_PODF_SHIFT, CCM_CSCMR1_PERCLK_PODF_MASK, CCM_NO_BUSY_WAIT), /*!< perclk div name */
kCLOCK_CanDiv = CCM_TUPLE(
CSCMR2, CCM_CSCMR2_CAN_CLK_PODF_SHIFT, CCM_CSCMR2_CAN_CLK_PODF_MASK, CCM_NO_BUSY_WAIT), /*!< can div name */
kCLOCK_TraceDiv = CCM_TUPLE(
CSCDR1, CCM_CSCDR1_TRACE_PODF_SHIFT, CCM_CSCDR1_TRACE_PODF_MASK, CCM_NO_BUSY_WAIT), /*!< trace div name */
kCLOCK_Usdhc2Div = CCM_TUPLE(
CSCDR1, CCM_CSCDR1_USDHC2_PODF_SHIFT, CCM_CSCDR1_USDHC2_PODF_MASK, CCM_NO_BUSY_WAIT), /*!< usdhc2 div name */
kCLOCK_Usdhc1Div = CCM_TUPLE(
CSCDR1, CCM_CSCDR1_USDHC1_PODF_SHIFT, CCM_CSCDR1_USDHC1_PODF_MASK, CCM_NO_BUSY_WAIT), /*!< usdhc1 div name */
kCLOCK_UartDiv = CCM_TUPLE(
CSCDR1, CCM_CSCDR1_UART_CLK_PODF_SHIFT, CCM_CSCDR1_UART_CLK_PODF_MASK, CCM_NO_BUSY_WAIT), /*!< uart div name */
kCLOCK_Flexio2Div = CCM_TUPLE(CS1CDR,
CCM_CS1CDR_FLEXIO2_CLK_PODF_SHIFT,
CCM_CS1CDR_FLEXIO2_CLK_PODF_MASK,
CCM_NO_BUSY_WAIT), /*!< flexio2 pre div name */
kCLOCK_Sai3PreDiv = CCM_TUPLE(CS1CDR,
CCM_CS1CDR_SAI3_CLK_PRED_SHIFT,
CCM_CS1CDR_SAI3_CLK_PRED_MASK,
CCM_NO_BUSY_WAIT), /*!< sai3 pre div name */
kCLOCK_Sai3Div = CCM_TUPLE(
CS1CDR, CCM_CS1CDR_SAI3_CLK_PODF_SHIFT, CCM_CS1CDR_SAI3_CLK_PODF_MASK, CCM_NO_BUSY_WAIT), /*!< sai3 div name */
kCLOCK_Flexio2PreDiv = CCM_TUPLE(CS1CDR,
CCM_CS1CDR_FLEXIO2_CLK_PRED_SHIFT,
CCM_CS1CDR_FLEXIO2_CLK_PRED_MASK,
CCM_NO_BUSY_WAIT), /*!< sai3 pre div name */
kCLOCK_Sai1PreDiv = CCM_TUPLE(CS1CDR,
CCM_CS1CDR_SAI1_CLK_PRED_SHIFT,
CCM_CS1CDR_SAI1_CLK_PRED_MASK,
CCM_NO_BUSY_WAIT), /*!< sai1 pre div name */
kCLOCK_Sai1Div = CCM_TUPLE(
CS1CDR, CCM_CS1CDR_SAI1_CLK_PODF_SHIFT, CCM_CS1CDR_SAI1_CLK_PODF_MASK, CCM_NO_BUSY_WAIT), /*!< sai1 div name */
kCLOCK_Sai2PreDiv = CCM_TUPLE(CS2CDR,
CCM_CS2CDR_SAI2_CLK_PRED_SHIFT,
CCM_CS2CDR_SAI2_CLK_PRED_MASK,
CCM_NO_BUSY_WAIT), /*!< sai2 pre div name */
kCLOCK_Sai2Div = CCM_TUPLE(
CS2CDR, CCM_CS2CDR_SAI2_CLK_PODF_SHIFT, CCM_CS2CDR_SAI2_CLK_PODF_MASK, CCM_NO_BUSY_WAIT), /*!< sai2 div name */
kCLOCK_Spdif0PreDiv = CCM_TUPLE(CDCDR,
CCM_CDCDR_SPDIF0_CLK_PRED_SHIFT,
CCM_CDCDR_SPDIF0_CLK_PRED_MASK,
CCM_NO_BUSY_WAIT), /*!< spdif pre div name */
kCLOCK_Spdif0Div = CCM_TUPLE(CDCDR,
CCM_CDCDR_SPDIF0_CLK_PODF_SHIFT,
CCM_CDCDR_SPDIF0_CLK_PODF_MASK,
CCM_NO_BUSY_WAIT), /*!< spdif div name */
kCLOCK_Flexio1PreDiv = CCM_TUPLE(CDCDR,
CCM_CDCDR_FLEXIO1_CLK_PRED_SHIFT,
CCM_CDCDR_FLEXIO1_CLK_PRED_MASK,
CCM_NO_BUSY_WAIT), /*!< flexio1 pre div name */
kCLOCK_Flexio1Div = CCM_TUPLE(CDCDR,
CCM_CDCDR_FLEXIO1_CLK_PODF_SHIFT,
CCM_CDCDR_FLEXIO1_CLK_PODF_MASK,
CCM_NO_BUSY_WAIT), /*!< flexio1 div name */
kCLOCK_Lpi2cDiv = CCM_TUPLE(CSCDR2,
CCM_CSCDR2_LPI2C_CLK_PODF_SHIFT,
CCM_CSCDR2_LPI2C_CLK_PODF_MASK,
CCM_NO_BUSY_WAIT), /*!< lpi2c div name */
kCLOCK_LcdifPreDiv = CCM_TUPLE(
CSCDR2, CCM_CSCDR2_LCDIF_PRED_SHIFT, CCM_CSCDR2_LCDIF_PRED_MASK, CCM_NO_BUSY_WAIT), /*!< lcdif pre div name */
kCLOCK_CsiDiv =
CCM_TUPLE(CSCDR3, CCM_CSCDR3_CSI_PODF_SHIFT, CCM_CSCDR3_CSI_PODF_MASK, CCM_NO_BUSY_WAIT), /*!< csi div name */
} clock_div_t;
/*! @brief USB clock source definition. */
typedef enum _clock_usb_src
{
kCLOCK_Usb480M = 0, /*!< Use 480M. */
kCLOCK_UsbSrcUnused = 0xFFFFFFFFU, /*!< Used when the function does not
care the clock source. */
} clock_usb_src_t;
/*! @brief Source of the USB HS PHY. */
typedef enum _clock_usb_phy_src
{
kCLOCK_Usbphy480M = 0, /*!< Use 480M. */
} clock_usb_phy_src_t;
/*!@brief PLL clock source, bypass cloco source also */
enum _clock_pll_clk_src
{
kCLOCK_PllClkSrc24M = 0U, /*!< Pll clock source 24M */
kCLOCK_PllSrcClkPN = 1U, /*!< Pll clock source CLK1_P and CLK1_N */
};
/*! @brief PLL configuration for ARM */
typedef struct _clock_arm_pll_config
{
uint32_t loopDivider; /*!< PLL loop divider. Valid range for divider value: 54-108. Fout=Fin*loopDivider/2. */
uint8_t src; /*!< Pll clock source, reference _clock_pll_clk_src */
} clock_arm_pll_config_t;
/*! @brief PLL configuration for USB */
typedef struct _clock_usb_pll_config
{
uint8_t loopDivider; /*!< PLL loop divider.
0 - Fout=Fref*20;
1 - Fout=Fref*22 */
uint8_t src; /*!< Pll clock source, reference _clock_pll_clk_src */
} clock_usb_pll_config_t;
/*! @brief PLL configuration for System */
typedef struct _clock_sys_pll_config
{
uint8_t loopDivider; /*!< PLL loop divider. Intended to be 1 (528M).
0 - Fout=Fref*20;
1 - Fout=Fref*22 */
uint32_t numerator; /*!< 30 bit numerator of fractional loop divider.*/
uint32_t denominator; /*!< 30 bit denominator of fractional loop divider */
uint8_t src; /*!< Pll clock source, reference _clock_pll_clk_src */
} clock_sys_pll_config_t;
/*! @brief PLL configuration for AUDIO and VIDEO */
typedef struct _clock_audio_pll_config
{
uint8_t loopDivider; /*!< PLL loop divider. Valid range for DIV_SELECT divider value: 27~54. */
uint8_t postDivider; /*!< Divider after the PLL, should only be 1, 2, 4, 8, 16. */
uint32_t numerator; /*!< 30 bit numerator of fractional loop divider.*/
uint32_t denominator; /*!< 30 bit denominator of fractional loop divider */
uint8_t src; /*!< Pll clock source, reference _clock_pll_clk_src */
} clock_audio_pll_config_t;
/*! @brief PLL configuration for AUDIO and VIDEO */
typedef struct _clock_video_pll_config
{
uint8_t loopDivider; /*!< PLL loop divider. Valid range for DIV_SELECT divider value: 27~54. */
uint8_t postDivider; /*!< Divider after the PLL, should only be 1, 2, 4, 8, 16. */
uint32_t numerator; /*!< 30 bit numerator of fractional loop divider.*/
uint32_t denominator; /*!< 30 bit denominator of fractional loop divider */
uint8_t src; /*!< Pll clock source, reference _clock_pll_clk_src */
} clock_video_pll_config_t;
/*! @brief PLL configuration for ENET */
typedef struct _clock_enet_pll_config
{
bool enableClkOutput; /*!< Power on and enable PLL clock output for ENET0 (ref_enetpll0). */
bool enableClkOutput25M; /*!< Power on and enable PLL clock output for ENET1 (ref_enetpll1). */
uint8_t loopDivider; /*!< Controls the frequency of the ENET0 reference clock.
b00 25MHz
b01 50MHz
b10 100MHz (not 50% duty cycle)
b11 125MHz */
uint8_t src; /*!< Pll clock source, reference _clock_pll_clk_src */
} clock_enet_pll_config_t;
/*! @brief PLL name */
typedef enum _clock_pll
{
kCLOCK_PllArm = CCM_ANALOG_TUPLE(PLL_ARM, CCM_ANALOG_PLL_ARM_ENABLE_SHIFT), /*!< PLL ARM */
kCLOCK_PllSys = CCM_ANALOG_TUPLE(PLL_SYS, CCM_ANALOG_PLL_SYS_ENABLE_SHIFT), /*!< PLL SYS */
kCLOCK_PllUsb1 = CCM_ANALOG_TUPLE(PLL_USB1, CCM_ANALOG_PLL_USB1_ENABLE_SHIFT), /*!< PLL USB1 */
kCLOCK_PllAudio = CCM_ANALOG_TUPLE(PLL_AUDIO, CCM_ANALOG_PLL_AUDIO_ENABLE_SHIFT), /*!< PLL Audio */
kCLOCK_PllVideo = CCM_ANALOG_TUPLE(PLL_VIDEO, CCM_ANALOG_PLL_VIDEO_ENABLE_SHIFT), /*!< PLL Video */
kCLOCK_PllEnet = CCM_ANALOG_TUPLE(PLL_ENET, CCM_ANALOG_PLL_ENET_ENABLE_SHIFT), /*!< PLL Enet0 */
kCLOCK_PllEnet25M = CCM_ANALOG_TUPLE(PLL_ENET, CCM_ANALOG_PLL_ENET_ENET_25M_REF_EN_SHIFT), /*!< PLL Enet1 */
kCLOCK_PllUsb2 = CCM_ANALOG_TUPLE(PLL_USB2, CCM_ANALOG_PLL_USB2_ENABLE_SHIFT), /*!< PLL USB2 */
} clock_pll_t;
/*! @brief PLL PFD name */
typedef enum _clock_pfd
{
kCLOCK_Pfd0 = 0U, /*!< PLL PFD0 */
kCLOCK_Pfd1 = 1U, /*!< PLL PFD1 */
kCLOCK_Pfd2 = 2U, /*!< PLL PFD2 */
kCLOCK_Pfd3 = 3U, /*!< PLL PFD3 */
} clock_pfd_t;
/*******************************************************************************
* API
******************************************************************************/
#if defined(__cplusplus)
extern "C" {
#endif /* __cplusplus */
/*!
* @brief Set CCM MUX node to certain value.
*
* @param mux Which mux node to set, see \ref clock_mux_t.
* @param value Clock mux value to set, different mux has different value range.
*/
static inline void CLOCK_SetMux(clock_mux_t mux, uint32_t value)
{
uint32_t busyShift;
busyShift = CCM_TUPLE_BUSY_SHIFT(mux);
CCM_TUPLE_REG(CCM, mux) = (CCM_TUPLE_REG(CCM, mux) & (~CCM_TUPLE_MASK(mux))) |
(((uint32_t)((value) << CCM_TUPLE_SHIFT(mux))) & CCM_TUPLE_MASK(mux));
assert(busyShift <= CCM_NO_BUSY_WAIT);
/* Clock switch need Handshake? */
if (CCM_NO_BUSY_WAIT != busyShift)
{
/* Wait until CCM internal handshake finish. */
while (CCM->CDHIPR & (1U << busyShift))
{
}
}
}
/*!
* @brief Get CCM MUX value.
*
* @param mux Which mux node to get, see \ref clock_mux_t.
* @return Clock mux value.
*/
static inline uint32_t CLOCK_GetMux(clock_mux_t mux)
{
return (CCM_TUPLE_REG(CCM, mux) & CCM_TUPLE_MASK(mux)) >> CCM_TUPLE_SHIFT(mux);
}
/*!
* @brief Set CCM DIV node to certain value.
*
* @param divider Which div node to set, see \ref clock_div_t.
* @param value Clock div value to set, different divider has different value range.
*/
static inline void CLOCK_SetDiv(clock_div_t divider, uint32_t value)
{
uint32_t busyShift;
busyShift = CCM_TUPLE_BUSY_SHIFT(divider);
CCM_TUPLE_REG(CCM, divider) = (CCM_TUPLE_REG(CCM, divider) & (~CCM_TUPLE_MASK(divider))) |
(((uint32_t)((value) << CCM_TUPLE_SHIFT(divider))) & CCM_TUPLE_MASK(divider));
assert(busyShift <= CCM_NO_BUSY_WAIT);
/* Clock switch need Handshake? */
if (CCM_NO_BUSY_WAIT != busyShift)
{
/* Wait until CCM internal handshake finish. */
while (CCM->CDHIPR & (1U << busyShift))
{
}
}
}
/*!
* @brief Get CCM DIV node value.
*
* @param divider Which div node to get, see \ref clock_div_t.
*/
static inline uint32_t CLOCK_GetDiv(clock_div_t divider)
{
return ((CCM_TUPLE_REG(CCM, divider) & CCM_TUPLE_MASK(divider)) >> CCM_TUPLE_SHIFT(divider));
}
/*!
* @brief Control the clock gate for specific IP.
*
* @param name Which clock to enable, see \ref clock_ip_name_t.
* @param value Clock gate value to set, see \ref clock_gate_value_t.
*/
static inline void CLOCK_ControlGate(clock_ip_name_t name, clock_gate_value_t value)
{
uint32_t index = ((uint32_t)name) >> 8U;
uint32_t shift = ((uint32_t)name) & 0x1FU;
volatile uint32_t *reg;
assert(index <= 6);
reg = ((volatile uint32_t *)&CCM->CCGR0) + index;
*reg = ((*reg) & ~(3U << shift)) | (((uint32_t)value) << shift);
}
/*!
* @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)
{
CLOCK_ControlGate(name, kCLOCK_ClockNeededRunWait);
}
/*!
* @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)
{
CLOCK_ControlGate(name, kCLOCK_ClockNotNeeded);
}
/*!
* @brief Setting the low power mode that system will enter on next assertion of dsm_request signal.
*
* @param mode Which mode to enter, see \ref clock_mode_t.
*/
static inline void CLOCK_SetMode(clock_mode_t mode)
{
CCM->CLPCR = (CCM->CLPCR & ~CCM_CLPCR_LPM_MASK) | CCM_CLPCR_LPM((uint32_t)mode);
}
/*!
* @brief Gets the OSC clock frequency.
*
* This function will return the external XTAL OSC frequency if it is selected as the source of OSC,
* otherwise internal 24MHz RC OSC frequency will be returned.
*
* @param osc OSC type to get frequency.
*
* @return Clock frequency; If the clock is invalid, returns 0.
*/
static inline uint32_t CLOCK_GetOscFreq(void)
{
return (XTALOSC24M->LOWPWR_CTRL & XTALOSC24M_LOWPWR_CTRL_OSC_SEL_MASK) ? 24000000UL : g_xtalFreq;
}
/*!
* @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 name);
/*!
* @brief Get the CCM CPU/core/system frequency.
*
* @return Clock frequency; If the clock is invalid, returns 0.
*/
static inline uint32_t CLOCK_GetCpuClkFreq(void)
{
return CLOCK_GetFreq(kCLOCK_CpuClk);
}
/*!
* @name OSC operations
* @{
*/
/*!
* @brief Initialize the external 24MHz clock.
*
* This function supports two modes:
* 1. Use external crystal oscillator.
* 2. Bypass the external crystal oscillator, using input source clock directly.
*
* After this function, please call @ref CLOCK_SetXtal0Freq to inform clock driver
* the external clock frequency.
*
* @param bypassXtalOsc Pass in true to bypass the external crystal oscillator.
* @note This device does not support bypass external crystal oscillator, so
* the input parameter should always be false.
*/
void CLOCK_InitExternalClk(bool bypassXtalOsc);
/*!
* @brief Deinitialize the external 24MHz clock.
*
* This function disables the external 24MHz clock.
*
* After this function, please call @ref CLOCK_SetXtal0Freq to set external clock
* frequency to 0.
*/
void CLOCK_DeinitExternalClk(void);
/*!
* @brief Switch the OSC.
*
* This function switches the OSC source for SoC.
*
* @param osc OSC source to switch to.
*/
void CLOCK_SwitchOsc(clock_osc_t osc);
/*!
* @brief Gets the RTC clock frequency.
*
* @return Clock frequency; If the clock is invalid, returns 0.
*/
static inline uint32_t CLOCK_GetRtcFreq(void)
{
return 32768U;
}
/*!
* @brief Set the XTAL (24M OSC) frequency based on board setting.
*
* @param freq The XTAL input clock frequency in Hz.
*/
static inline void CLOCK_SetXtalFreq(uint32_t freq)
{
g_xtalFreq = freq;
}
/*!
* @brief Set the RTC XTAL (32K OSC) frequency based on board setting.
*
* @param freq The RTC XTAL input clock frequency in Hz.
*/
static inline void CLOCK_SetRtcXtalFreq(uint32_t freq)
{
g_rtcXtalFreq = freq;
}
/*!
* @brief Initialize the RC oscillator 24MHz clock.
*/
void CLOCK_InitRcOsc24M(void);
/*!
* @brief Power down the RCOSC 24M clock.
*/
void CLOCK_DeinitRcOsc24M(void);
/* @} */
/*! @brief Enable USB HS clock.
*
* This function only enables the access to USB HS prepheral, upper layer
* should first call the @ref CLOCK_EnableUsbhs0PhyPllClock to enable the PHY
* clock to use USB HS.
*
* @param src USB HS does not care about the clock source, here must be @ref kCLOCK_UsbSrcUnused.
* @param freq USB HS does not care about the clock source, so this parameter is ignored.
* @retval true The clock is set successfully.
* @retval false The clock source is invalid to get proper USB HS clock.
*/
bool CLOCK_EnableUsbhs0Clock(clock_usb_src_t src, uint32_t freq);
/*! @brief Enable USB HS clock.
*
* This function only enables the access to USB HS prepheral, upper layer
* should first call the @ref CLOCK_EnableUsbhs0PhyPllClock to enable the PHY
* clock to use USB HS.
*
* @param src USB HS does not care about the clock source, here must be @ref kCLOCK_UsbSrcUnused.
* @param freq USB HS does not care about the clock source, so this parameter is ignored.
* @retval true The clock is set successfully.
* @retval false The clock source is invalid to get proper USB HS clock.
*/
bool CLOCK_EnableUsbhs1Clock(clock_usb_src_t src, uint32_t freq);
/*! @brief Disable USB HS PHY PLL clock.
*
* This function disables USB HS PHY PLL clock.
*/
void CLOCK_DisableUsbhs1PhyPllClock(void);
/* @} */
/*!
* @name PLL/PFD operations
* @{
*/
/*!
* @brief PLL bypass setting
*
* @param base CCM_ANALOG base pointer.
* @param pll PLL control name (see @ref ccm_analog_pll_control_t enumeration)
* @param bypass Bypass the PLL.
* - true: Bypass the PLL.
* - false:Not bypass the PLL.
*/
static inline void CLOCK_SetPllBypass(CCM_ANALOG_Type *base, clock_pll_t pll, bool bypass)
{
if (bypass)
{
CCM_ANALOG_TUPLE_REG_OFF(base, pll, 4U) = 1U << CCM_ANALOG_PLL_BYPASS_SHIFT;
}
else
{
CCM_ANALOG_TUPLE_REG_OFF(base, pll, 8U) = 1U << CCM_ANALOG_PLL_BYPASS_SHIFT;
}
}
/*!
* @brief Check if PLL is bypassed
*
* @param base CCM_ANALOG base pointer.
* @param pll PLL control name (see @ref ccm_analog_pll_control_t enumeration)
* @return PLL bypass status.
* - true: The PLL is bypassed.
* - false: The PLL is not bypassed.
*/
static inline bool CLOCK_IsPllBypassed(CCM_ANALOG_Type *base, clock_pll_t pll)
{
return (bool)(CCM_ANALOG_TUPLE_REG(base, pll) & (1U << CCM_ANALOG_PLL_BYPASS_SHIFT));
}
/*!
* @brief Check if PLL is enabled
*
* @param base CCM_ANALOG base pointer.
* @param pll PLL control name (see @ref ccm_analog_pll_control_t enumeration)
* @return PLL bypass status.
* - true: The PLL is enabled.
* - false: The PLL is not enabled.
*/
static inline bool CLOCK_IsPllEnabled(CCM_ANALOG_Type *base, clock_pll_t pll)
{
return (bool)(CCM_ANALOG_TUPLE_REG(base, pll) & (1U << CCM_ANALOG_TUPLE_SHIFT(pll)));
}
/*!
* @brief PLL bypass clock source setting.
* Note: change the bypass clock source also change the pll reference clock source.
*
* @param base CCM_ANALOG base pointer.
* @param pll PLL control name (see @ref ccm_analog_pll_control_t enumeration)
* @param src Bypass clock source, reference _clock_pll_bypass_clk_src.
*/
static inline void CLOCK_SetPllBypassRefClkSrc(CCM_ANALOG_Type *base, clock_pll_t pll, uint32_t src)
{
CCM_ANALOG_TUPLE_REG(base, pll) |= (CCM_ANALOG_TUPLE_REG(base, pll) & (~CCM_ANALOG_PLL_BYPASS_CLK_SRC_MASK)) | src;
}
/*!
* @brief Get PLL bypass clock value, it is PLL reference clock actually.
* If CLOCK1_P,CLOCK1_N is choose as the pll bypass clock source, please implement the CLKPN_FREQ define, otherwise 0
* will be returned.
* @param base CCM_ANALOG base pointer.
* @param pll PLL control name (see @ref ccm_analog_pll_control_t enumeration)
* @retval bypass reference clock frequency value.
*/
static inline uint32_t CLOCK_GetPllBypassRefClk(CCM_ANALOG_Type *base, clock_pll_t pll)
{
return (((CCM_ANALOG_TUPLE_REG(base, pll) & CCM_ANALOG_PLL_BYPASS_CLK_SRC_MASK) >>
CCM_ANALOG_PLL_BYPASS_CLK_SRC_SHIFT) == kCLOCK_PllClkSrc24M) ?
CLOCK_GetOscFreq() :
CLKPN_FREQ;
}
/*!
* @brief Initialize the ARM PLL.
*
* This function initialize the ARM PLL with specific settings
*
* @param config configuration to set to PLL.
*/
void CLOCK_InitArmPll(const clock_arm_pll_config_t *config);
/*!
* @brief De-initialize the ARM PLL.
*/
void CLOCK_DeinitArmPll(void);
/*!
* @brief Initialize the System PLL.
*
* This function initializes the System PLL with specific settings
*
* @param config Configuration to set to PLL.
*/
void CLOCK_InitSysPll(const clock_sys_pll_config_t *config);
/*!
* @brief De-initialize the System PLL.
*/
void CLOCK_DeinitSysPll(void);
/*!
* @brief Initialize the USB1 PLL.
*
* This function initializes the USB1 PLL with specific settings
*
* @param config Configuration to set to PLL.
*/
void CLOCK_InitUsb1Pll(const clock_usb_pll_config_t *config);
/*!
* @brief Deinitialize the USB1 PLL.
*/
void CLOCK_DeinitUsb1Pll(void);
/*!
* @brief Initialize the USB2 PLL.
*
* This function initializes the USB2 PLL with specific settings
*
* @param config Configuration to set to PLL.
*/
void CLOCK_InitUsb2Pll(const clock_usb_pll_config_t *config);
/*!
* @brief Deinitialize the USB2 PLL.
*/
void CLOCK_DeinitUsb2Pll(void);
/*!
* @brief Initializes the Audio PLL.
*
* This function initializes the Audio PLL with specific settings
*
* @param config Configuration to set to PLL.
*/
void CLOCK_InitAudioPll(const clock_audio_pll_config_t *config);
/*!
* @brief De-initialize the Audio PLL.
*/
void CLOCK_DeinitAudioPll(void);
/*!
* @brief Initialize the video PLL.
*
* This function configures the Video PLL with specific settings
*
* @param config configuration to set to PLL.
*/
void CLOCK_InitVideoPll(const clock_video_pll_config_t *config);
/*!
* @brief De-initialize the Video PLL.
*/
void CLOCK_DeinitVideoPll(void);
/*!
* @brief Initialize the ENET PLL.
*
* This function initializes the ENET PLL with specific settings.
*
* @param config Configuration to set to PLL.
*/
void CLOCK_InitEnetPll(const clock_enet_pll_config_t *config);
/*!
* @brief Deinitialize the ENET PLL.
*
* This function disables the ENET PLL.
*/
void CLOCK_DeinitEnetPll(void);
/*!
* @brief Get current PLL output frequency.
*
* This function get current output frequency of specific PLL
*
* @param pll pll name to get frequency.
* @return The PLL output frequency in hertz.
*/
uint32_t CLOCK_GetPllFreq(clock_pll_t pll);
/*!
* @brief Initialize the System PLL PFD.
*
* This function initializes the System PLL PFD. During new value setting,
* the clock output is disabled to prevent glitch.
*
* @param pfd Which PFD clock to enable.
* @param pfdFrac The PFD FRAC value.
* @note It is recommended that PFD settings are kept between 12-35.
*/
void CLOCK_InitSysPfd(clock_pfd_t pfd, uint8_t pfdFrac);
/*!
* @brief De-initialize the System PLL PFD.
*
* This function disables the System PLL PFD.
*
* @param pfd Which PFD clock to disable.
*/
void CLOCK_DeinitSysPfd(clock_pfd_t pfd);
/*!
* @brief Initialize the USB1 PLL PFD.
*
* This function initializes the USB1 PLL PFD. During new value setting,
* the clock output is disabled to prevent glitch.
*
* @param pfd Which PFD clock to enable.
* @param pfdFrac The PFD FRAC value.
* @note It is recommended that PFD settings are kept between 12-35.
*/
void CLOCK_InitUsb1Pfd(clock_pfd_t pfd, uint8_t pfdFrac);
/*!
* @brief De-initialize the USB1 PLL PFD.
*
* This function disables the USB1 PLL PFD.
*
* @param pfd Which PFD clock to disable.
*/
void CLOCK_DeinitUsb1Pfd(clock_pfd_t pfd);
/*!
* @brief Get current System PLL PFD output frequency.
*
* This function get current output frequency of specific System PLL PFD
*
* @param pfd pfd name to get frequency.
* @return The PFD output frequency in hertz.
*/
uint32_t CLOCK_GetSysPfdFreq(clock_pfd_t pfd);
/*!
* @brief Get current USB1 PLL PFD output frequency.
*
* This function get current output frequency of specific USB1 PLL PFD
*
* @param pfd pfd name to get frequency.
* @return The PFD output frequency in hertz.
*/
uint32_t CLOCK_GetUsb1PfdFreq(clock_pfd_t pfd);
/*! @brief Enable USB HS PHY PLL clock.
*
* This function enables the internal 480MHz USB PHY PLL clock.
*
* @param src USB HS PHY PLL 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 HS clock.
*/
bool CLOCK_EnableUsbhs0PhyPllClock(clock_usb_phy_src_t src, uint32_t freq);
/*! @brief Disable USB HS PHY PLL clock.
*
* This function disables USB HS PHY PLL clock.
*/
void CLOCK_DisableUsbhs0PhyPllClock(void);
/*! @brief Enable USB HS PHY PLL clock.
*
* This function enables the internal 480MHz USB PHY PLL clock.
*
* @param src USB HS PHY PLL 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 HS clock.
*/
bool CLOCK_EnableUsbhs1PhyPllClock(clock_usb_phy_src_t src, uint32_t freq);
/*! @brief Disable USB HS PHY PLL clock.
*
* This function disables USB HS PHY PLL clock.
*/
void CLOCK_DisableUsbhs1PhyPllClock(void);
/* @} */
#if defined(__cplusplus)
}
#endif /* __cplusplus */
/*! @} */
#endif /* _FSL_CLOCK_H_ */