boards/evkmimx8mq/driver_examples/gpio/led_output/clock_config.c - mcuxpresso_sdk - Git at Google

 /*
  * Copyright 2017 NXP
  * All rights reserved.
  *
  * SPDX-License-Identifier: BSD-3-Clause
  */

 /*
  * TEXT BELOW IS USED AS SETTING FOR TOOLS *************************************
 !!GlobalInfo
 product: Pins v4.0
 processor: MIMX8MQ6xxxJZ
 package_id: MIMX8MQ6DVAJZ
 mcu_data: ksdk2_0
 processor_version: 0.0.0
  * BE CAREFUL MODIFYING THIS COMMENT - IT IS YAML SETTINGS FOR TOOLS ***********
  */

 #include "fsl_common.h"
 #include "clock_config.h"

 /*******************************************************************************
  * Definitions
  ******************************************************************************/

 /* OSC 27M configuration */
 const osc_config_t g_osc27MConfig = {
     .oscMode = kOSC_OscMode,
     .oscDiv  = 1U,
 };

 /* OSC 25M configuration */
 const osc_config_t g_osc25MConfig = {
     .oscMode = kOSC_OscMode,
     .oscDiv  = 1U,
 };

 /* AUDIO PLL1 configuration */
 const ccm_analog_frac_pll_config_t g_audioPll1Config = {
     .refSel      = kANALOG_PllRefOsc25M, /*!< PLL reference OSC25M */
     .refDiv      = 5U,                   /*!< PLL input = 25 / 5 = 5M */
     .fractionDiv = 0U,
     .intDiv      = 64U, /*!< Integer and fractional Divider output  = 5 * (1 + 64) * 8 = 2600MHZ */
     .outDiv      = 4U,  /*!< Pll out frequency  = 2600 / 4 = 650MHZ */
 };

 /* AUDIO PLL2 configuration */
 const ccm_analog_frac_pll_config_t g_audioPll2Config = {
     .refSel      = kANALOG_PllRefOsc25M, /*!< PLL reference OSC25M */
     .refDiv      = 5U,                   /*!< PLL input = 25 / 5 = 5M */
     .fractionDiv = 0U,
     .intDiv      = 64U, /*!< Integer and fractional Divider output  = 5 * (1 + 64) * 8 = 2600MHZ */
     .outDiv      = 4U,  /*!< Pll out frequency  = 2600 / 4 = 650MHZ */
 };

 /* VIDEO PLL1 configuration */
 const ccm_analog_frac_pll_config_t g_videoPll1Config = {
     .refSel      = kANALOG_PllRefOsc25M, /*!< PLL reference OSC25M */
     .refDiv      = 5U,                   /*!< PLL input = 25 / 5 = 5M */
     .fractionDiv = 0U,
     .intDiv      = 64U, /*!< Integer and fractional Divider output  = 5 * (1 + 64) * 8 = 2600MHZ */
     .outDiv      = 4U,  /*!< Pll out frequency  = 2600 / 4 = 650MHZ */
 };

 /* SYSTEM PLL1 configuration */
 const ccm_analog_sscg_pll_config_t g_sysPll1Config = {
     .refSel       = kANALOG_PllRefOsc25M, /*!< PLL reference OSC25M */
     .refDiv1      = 1U,                   /*!< PLL1 input = 25 / 1 = 25MHZ */
     .loopDivider1 = 32U,                  /*!< PLL1 output  = 25 * 32 * 2 = 1600MHZ */
     .refDiv2      = 24U,                  /*!< PLL2 input  = 1600 / 24 = 66.66MHZ */
     .loopDivider2 = 12U,                  /*!< PLL2 output  = 12 * 66.66 * 2 = 1600MHZ */
     .outDiv       = 1U,                   /*!< PLL output = 1600 / 2 / 1 = 800MHZ */
 };

 /* SYSTEM PLL2 configuration */
 const ccm_analog_sscg_pll_config_t g_sysPll2Config = {
     .refSel       = kANALOG_PllRefOsc25M, /*!< PLL reference OSC25M */
     .refDiv1      = 1U,                   /*!< PLL1 input = 25 / 1 = 25MHZ */
     .loopDivider1 = 32U,                  /*!< PLL1 output  = 25 * 32 * 2 = 1600MHZ */
     .refDiv2      = 16U,                  /*!< PLL2 input  = 1600 / 16 = 100MHZ */
     .loopDivider2 = 10U,                  /*!< PLL2 output  = 10 * 100 * 2 = 2000MHZ */
     .outDiv       = 1U,                   /*!< PLL output = 2000 / 2 / 1 = 1000MHZ */
 };

 /* SYSTEM PLL3 configuration */
 const ccm_analog_sscg_pll_config_t g_sysPll3Config = {
     .refSel       = kANALOG_PllRefOsc25M, /*!< PLL reference OSC25M */
     .refDiv1      = 1U,                   /*!< PLL1 input = 25 / 1 = 25MHZ */
     .loopDivider1 = 32U,                  /*!< PLL1 output  = 25 * 32 * 2 = 1600MHZ */
     .refDiv2      = 16U,                  /*!< PLL2 input  = 1600 / 16 = 100MHZ */
     .loopDivider2 = 10U,                  /*!< PLL2 output  = 10 * 100 * 2 = 2000MHZ */
     .outDiv       = 1U,                   /*!< PLL output = 2000 / 2 / 1 = 1000MHZ */
 };

 /*******************************************************************************
  * Variables
  ******************************************************************************/

 /*******************************************************************************
  * Code
  ******************************************************************************/
 void BOARD_BootClockRUN(void)
 {
     /* OSC configuration */
     CLOCK_InitOSC25M(&g_osc25MConfig);
     CLOCK_InitOSC27M(&g_osc27MConfig);

     /* The following steps just show how to configure the PLL clock sources using the clock driver on M4 core side .
      * Please note that the ROM has already configured the SYSTEM PLL1 to 800Mhz when power up the SOC, meanwhile A core
      * would enable the Div output for SYSTEM PLL1 & PLL2 by U-Boot.
      * Therefore, there is no need to configure the system PLL again on M4 side, otherwise it would have a risk to make
      * the SOC hang.
      */

     /* switch AHB NOC root to 25M first in order to configure the SYSTEM PLL1. */
     //    CLOCK_SetRootMux(kCLOCK_RootAhb, kCLOCK_AhbRootmuxOsc25m);
     //    CLOCK_SetRootMux(kCLOCK_RootNoc, kCLOCK_NocRootmuxOsc25m);
     /* switch AXI root to 25M first in order to configure the SYSTEM PLL2. */
     //    CLOCK_SetRootMux(kCLOCK_RootAxi, kCLOCK_AxiRootmuxOsc25m);

     //    CLOCK_InitSysPll1(&g_sysPll1Config); /* init SYSTEM PLL1 run at 800MHZ */
     //    CLOCK_InitSysPll2(&g_sysPll2Config); /* init SYSTEM PLL2 run at 1000MHZ */
     //    CLOCK_InitSysPll3(&g_sysPll3Config); /* init SYSTEM PLL3 run at 1000MHZ */
     //
     //    CLOCK_InitAudioPll1(&g_audioPll1Config); /* init AUDIO PLL1 run at 650MHZ */
     //    CLOCK_InitAudioPll2(&g_audioPll2Config); /* init AUDIO PLL2 run at 650MHZ */
     //    CLOCK_InitVideoPll1(&g_videoPll1Config); /* init VIDEO PLL1 run at 650MHZ */

     CLOCK_SetRootDivider(kCLOCK_RootM4, 1U, 1U);
     CLOCK_SetRootMux(kCLOCK_RootM4, kCLOCK_M4RootmuxSysPll1Div3); /* switch cortex-m4 to SYSTEM PLL1 DIV3 */
     //    CLOCK_SetRootMux(kCLOCK_RootNoc, kCLOCK_NocRootmuxSysPll1);   /* change back to SYSTEM PLL1*/

     CLOCK_SetRootDivider(kCLOCK_RootAhb, 1U, 1U);
     CLOCK_SetRootMux(kCLOCK_RootAhb, kCLOCK_AhbRootmuxSysPll1Div6); /* switch AHB to SYSTEM PLL1 DIV6 = 133MHZ */

     CLOCK_SetRootDivider(kCLOCK_RootAxi, 3U, 1U);
     CLOCK_SetRootMux(kCLOCK_RootAxi, kCLOCK_AxiRootmuxSysPll1); /* switch AXI to SYSTEM PLL1 = 266MHZ */

     CLOCK_SetRootMux(kCLOCK_RootUart2, kCLOCK_UartRootmuxSysPll1Div10); /* Set UART source to SysPLL1 Div10 80MHZ */
     CLOCK_SetRootDivider(kCLOCK_RootUart2, 1U, 1U);                     /* Set root clock to 80MHZ/ 1= 80MHZ */

     CLOCK_EnableClock(kCLOCK_Rdc); /* Enable RDC clock */

     /* The purpose to enable the following modules clock is to make sure the M4 core could work normally when A53 core
      * enters the low power status.*/
     // CLOCK_EnableClock(kCLOCK_Sim_m);
     // CLOCK_EnableClock(kCLOCK_Sim_main);
     // CLOCK_EnableClock(kCLOCK_Sim_s);
     // CLOCK_EnableClock(kCLOCK_Sim_wakeup);
     // CLOCK_EnableClock(kCLOCK_Debug);
     // CLOCK_EnableClock(kCLOCK_Dram);
     // CLOCK_EnableClock(kCLOCK_Sec_Debug);

     /* Disable unused PLL */
     CLOCK_DeinitSysPll3();
     CLOCK_DeinitVideoPll1();
     CLOCK_DeinitAudioPll1();
     CLOCK_DeinitAudioPll2();
     /* Update core clock */
     SystemCoreClockUpdate();
 }
	/*
	* Copyright 2017 NXP
	* All rights reserved.
	*
	* SPDX-License-Identifier: BSD-3-Clause
	*/

	/*
	* TEXT BELOW IS USED AS SETTING FOR TOOLS *************************************
	!!GlobalInfo
	product: Pins v4.0
	processor: MIMX8MQ6xxxJZ
	package_id: MIMX8MQ6DVAJZ
	mcu_data: ksdk2_0
	processor_version: 0.0.0
	* BE CAREFUL MODIFYING THIS COMMENT - IT IS YAML SETTINGS FOR TOOLS ***********
	*/

	#include "fsl_common.h"
	#include "clock_config.h"

	/*******************************************************************************
	* Definitions
	******************************************************************************/

	/* OSC 27M configuration */
	const osc_config_t g_osc27MConfig = {
	.oscMode = kOSC_OscMode,
	.oscDiv = 1U,
	};

	/* OSC 25M configuration */
	const osc_config_t g_osc25MConfig = {
	.oscMode = kOSC_OscMode,
	.oscDiv = 1U,
	};

	/* AUDIO PLL1 configuration */
	const ccm_analog_frac_pll_config_t g_audioPll1Config = {
	.refSel = kANALOG_PllRefOsc25M, /!< PLL reference OSC25M /
	.refDiv = 5U, /!< PLL input = 25 / 5 = 5M /
	.fractionDiv = 0U,
	.intDiv = 64U, /!< Integer and fractional Divider output = 5 (1 + 64) * 8 = 2600MHZ */
	.outDiv = 4U, /!< Pll out frequency = 2600 / 4 = 650MHZ /
	};

	/* AUDIO PLL2 configuration */
	const ccm_analog_frac_pll_config_t g_audioPll2Config = {
	.refSel = kANALOG_PllRefOsc25M, /!< PLL reference OSC25M /
	.refDiv = 5U, /!< PLL input = 25 / 5 = 5M /
	.fractionDiv = 0U,
	.intDiv = 64U, /!< Integer and fractional Divider output = 5 (1 + 64) * 8 = 2600MHZ */
	.outDiv = 4U, /!< Pll out frequency = 2600 / 4 = 650MHZ /
	};

	/* VIDEO PLL1 configuration */
	const ccm_analog_frac_pll_config_t g_videoPll1Config = {
	.refSel = kANALOG_PllRefOsc25M, /!< PLL reference OSC25M /
	.refDiv = 5U, /!< PLL input = 25 / 5 = 5M /
	.fractionDiv = 0U,
	.intDiv = 64U, /!< Integer and fractional Divider output = 5 (1 + 64) * 8 = 2600MHZ */
	.outDiv = 4U, /!< Pll out frequency = 2600 / 4 = 650MHZ /
	};

	/* SYSTEM PLL1 configuration */
	const ccm_analog_sscg_pll_config_t g_sysPll1Config = {
	.refSel = kANALOG_PllRefOsc25M, /!< PLL reference OSC25M /
	.refDiv1 = 1U, /!< PLL1 input = 25 / 1 = 25MHZ /
	.loopDivider1 = 32U, /!< PLL1 output = 25 32 * 2 = 1600MHZ */
	.refDiv2 = 24U, /!< PLL2 input = 1600 / 24 = 66.66MHZ /
	.loopDivider2 = 12U, /!< PLL2 output = 12 66.66 * 2 = 1600MHZ */
	.outDiv = 1U, /!< PLL output = 1600 / 2 / 1 = 800MHZ /
	};

	/* SYSTEM PLL2 configuration */
	const ccm_analog_sscg_pll_config_t g_sysPll2Config = {
	.refSel = kANALOG_PllRefOsc25M, /!< PLL reference OSC25M /
	.refDiv1 = 1U, /!< PLL1 input = 25 / 1 = 25MHZ /
	.loopDivider1 = 32U, /!< PLL1 output = 25 32 * 2 = 1600MHZ */
	.refDiv2 = 16U, /!< PLL2 input = 1600 / 16 = 100MHZ /
	.loopDivider2 = 10U, /!< PLL2 output = 10 100 * 2 = 2000MHZ */
	.outDiv = 1U, /!< PLL output = 2000 / 2 / 1 = 1000MHZ /
	};

	/* SYSTEM PLL3 configuration */
	const ccm_analog_sscg_pll_config_t g_sysPll3Config = {
	.refSel = kANALOG_PllRefOsc25M, /!< PLL reference OSC25M /
	.refDiv1 = 1U, /!< PLL1 input = 25 / 1 = 25MHZ /
	.loopDivider1 = 32U, /!< PLL1 output = 25 32 * 2 = 1600MHZ */
	.refDiv2 = 16U, /!< PLL2 input = 1600 / 16 = 100MHZ /
	.loopDivider2 = 10U, /!< PLL2 output = 10 100 * 2 = 2000MHZ */
	.outDiv = 1U, /!< PLL output = 2000 / 2 / 1 = 1000MHZ /
	};

	/*******************************************************************************
	* Variables
	******************************************************************************/

	/*******************************************************************************
	* Code
	******************************************************************************/
	void BOARD_BootClockRUN(void)
	{
	/* OSC configuration */
	CLOCK_InitOSC25M(&g_osc25MConfig);
	CLOCK_InitOSC27M(&g_osc27MConfig);

	/* The following steps just show how to configure the PLL clock sources using the clock driver on M4 core side .
	* Please note that the ROM has already configured the SYSTEM PLL1 to 800Mhz when power up the SOC, meanwhile A core
	* would enable the Div output for SYSTEM PLL1 & PLL2 by U-Boot.
	* Therefore, there is no need to configure the system PLL again on M4 side, otherwise it would have a risk to make
	* the SOC hang.
	*/

	/* switch AHB NOC root to 25M first in order to configure the SYSTEM PLL1. */
	// CLOCK_SetRootMux(kCLOCK_RootAhb, kCLOCK_AhbRootmuxOsc25m);
	// CLOCK_SetRootMux(kCLOCK_RootNoc, kCLOCK_NocRootmuxOsc25m);
	/* switch AXI root to 25M first in order to configure the SYSTEM PLL2. */
	// CLOCK_SetRootMux(kCLOCK_RootAxi, kCLOCK_AxiRootmuxOsc25m);

	// CLOCK_InitSysPll1(&g_sysPll1Config); /* init SYSTEM PLL1 run at 800MHZ */
	// CLOCK_InitSysPll2(&g_sysPll2Config); /* init SYSTEM PLL2 run at 1000MHZ */
	// CLOCK_InitSysPll3(&g_sysPll3Config); /* init SYSTEM PLL3 run at 1000MHZ */
	//
	// CLOCK_InitAudioPll1(&g_audioPll1Config); /* init AUDIO PLL1 run at 650MHZ */
	// CLOCK_InitAudioPll2(&g_audioPll2Config); /* init AUDIO PLL2 run at 650MHZ */
	// CLOCK_InitVideoPll1(&g_videoPll1Config); /* init VIDEO PLL1 run at 650MHZ */

	CLOCK_SetRootDivider(kCLOCK_RootM4, 1U, 1U);
	CLOCK_SetRootMux(kCLOCK_RootM4, kCLOCK_M4RootmuxSysPll1Div3); /* switch cortex-m4 to SYSTEM PLL1 DIV3 */
	// CLOCK_SetRootMux(kCLOCK_RootNoc, kCLOCK_NocRootmuxSysPll1); /* change back to SYSTEM PLL1*/

	CLOCK_SetRootDivider(kCLOCK_RootAhb, 1U, 1U);
	CLOCK_SetRootMux(kCLOCK_RootAhb, kCLOCK_AhbRootmuxSysPll1Div6); /* switch AHB to SYSTEM PLL1 DIV6 = 133MHZ */

	CLOCK_SetRootDivider(kCLOCK_RootAxi, 3U, 1U);
	CLOCK_SetRootMux(kCLOCK_RootAxi, kCLOCK_AxiRootmuxSysPll1); /* switch AXI to SYSTEM PLL1 = 266MHZ */

	CLOCK_SetRootMux(kCLOCK_RootUart2, kCLOCK_UartRootmuxSysPll1Div10); /* Set UART source to SysPLL1 Div10 80MHZ */
	CLOCK_SetRootDivider(kCLOCK_RootUart2, 1U, 1U); /* Set root clock to 80MHZ/ 1= 80MHZ */

	CLOCK_EnableClock(kCLOCK_Rdc); /* Enable RDC clock */

	/* The purpose to enable the following modules clock is to make sure the M4 core could work normally when A53 core
	* enters the low power status.*/
	// CLOCK_EnableClock(kCLOCK_Sim_m);
	// CLOCK_EnableClock(kCLOCK_Sim_main);
	// CLOCK_EnableClock(kCLOCK_Sim_s);
	// CLOCK_EnableClock(kCLOCK_Sim_wakeup);
	// CLOCK_EnableClock(kCLOCK_Debug);
	// CLOCK_EnableClock(kCLOCK_Dram);
	// CLOCK_EnableClock(kCLOCK_Sec_Debug);

	/* Disable unused PLL */
	CLOCK_DeinitSysPll3();
	CLOCK_DeinitVideoPll1();
	CLOCK_DeinitAudioPll1();
	CLOCK_DeinitAudioPll2();
	/* Update core clock */
	SystemCoreClockUpdate();
	}