FreeRTOS/Demo/CORTEX_MPU_LPC54018_MCUXpresso/NXP_Code/drivers/fsl_emc.c - third_party/github/FreeRTOS/FreeRTOS-Kernel - Git at Google

 /*
  * Copyright (c) 2016, Freescale Semiconductor, Inc.
  * Copyright 2016-2019 NXP
  * All rights reserved.
  *
  * SPDX-License-Identifier: BSD-3-Clause
  */

 #include "fsl_emc.h"

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

 /* Component ID definition, used by tools. */
 #ifndef FSL_COMPONENT_ID
 #define FSL_COMPONENT_ID "platform.drivers.emc"
 #endif

 /*! @brief Define macros for EMC driver. */
 #define EMC_REFRESH_CLOCK_PARAM (16U)
 #define EMC_SDRAM_WAIT_CYCLES (2000U)
 #define EMC_DYNCTL_COLUMNBASE_OFFSET (0U)
 #define EMC_DYNCTL_COLUMNBASE_MASK (0x3U)
 #define EMC_DYNCTL_COLUMNPLUS_OFFSET (3U)
 #define EMC_DYNCTL_COLUMNPLUS_MASK (0x18U)
 #define EMC_DYNCTL_BUSWIDTH_MASK (0x80U)
 #define EMC_DYNCTL_BUSADDRMAP_MASK (0x20U)
 #define EMC_DYNCTL_DEVBANKS_BITS_MASK (0x1cU)
 #define EMC_SDRAM_BANKCS_BA0_MASK (uint32_t)(0x2000)
 #define EMC_SDRAM_BANKCS_BA1_MASK (uint32_t)(0x4000)
 #define EMC_SDRAM_BANKCS_BA_MASK (EMC_SDRAM_BANKCS_BA0_MASK | EMC_SDRAM_BANKCS_BA1_MASK)
 #define EMC_DIV_ROUND_UP(n, m) (((n) + (m)-1U) / (m))

 /*******************************************************************************
  * Prototypes
  ******************************************************************************/
 /*!
  * @brief Get instance number for EMC module.
  *
  * @param base EMC peripheral base address
  */
 static uint32_t EMC_GetInstance(EMC_Type *base);

 /*!
  * @brief Get the clock cycles of EMC clock.
  * The function is used to calculate the multiple of the
  * 16 EMCCLKs between the timer_Ns period.
  *
  * @param base EMC peripheral base address
  * @param timer_Ns The timer/period in unit of nanosecond
  * @param plus The plus added to the register settings to reach the calculated cycles.
  * @return The calculated cycles.
  */
 static uint32_t EMC_CalculateTimerCycles(EMC_Type *base, uint32_t timer_Ns, uint32_t plus);

 /*!
  * @brief Get the shift value to shift the mode register content by.
  *
  * @param addrMap EMC address map for the dynamic memory configuration.
  *                It is the bit 14 ~ bit 7 of the EMC_DYNAMICCONFIG.
  * @return The offset value to shift the mode register content by.
  */
 static uint32_t EMC_ModeOffset(uint32_t addrMap);

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

 #if !(defined(FSL_SDK_DISABLE_DRIVER_CLOCK_CONTROL) && FSL_SDK_DISABLE_DRIVER_CLOCK_CONTROL)
 /*! @brief Pointers to EMC clocks for each instance. */
 static const clock_ip_name_t s_EMCClock[FSL_FEATURE_SOC_EMC_COUNT] = EMC_CLOCKS;
 #endif /* FSL_SDK_DISABLE_DRIVER_CLOCK_CONTROL */

 #if !(defined(FSL_FEATURE_EMC_HAS_NO_RESET) && FSL_FEATURE_EMC_HAS_NO_RESET)
 /*! @brief Pointers to EMC resets for each instance. */
 static const reset_ip_name_t s_emcResets[] = EMC_RSTS;
 #endif

 /*! @brief Pointers to EMC bases for each instance. */
 static const EMC_Type *const s_EMCBases[] = EMC_BASE_PTRS;

 /*! @brief Define the start address for each chip controlled by EMC. */
 static const uint32_t s_EMCDYCSBases[] = EMC_DYCS_ADDRESS;
 /*******************************************************************************
  * Code
  ******************************************************************************/

 static uint32_t EMC_GetInstance(EMC_Type *base)
 {
     uint32_t instance;

     /* Find the instance index from base address mappings. */
     for (instance = 0; instance < ARRAY_SIZE(s_EMCBases); instance++)
     {
         if (s_EMCBases[instance] == base)
         {
             break;
         }
     }

     assert(instance < ARRAY_SIZE(s_EMCBases));

     return instance;
 }

 static uint32_t EMC_CalculateTimerCycles(EMC_Type *base, uint32_t timer_Ns, uint32_t plus)
 {
     uint32_t cycles;

     cycles = CLOCK_GetEmcClkFreq() / EMC_HZ_ONEMHZ * timer_Ns;
     cycles = EMC_DIV_ROUND_UP(cycles, EMC_MILLISECS_ONESEC); /* Round up. */

     /* Decrese according to the plus. */
     if (cycles >= plus)
     {
         cycles = cycles - plus;
     }
     else
     {
         cycles = 0;
     }

     return cycles;
 }

 static uint32_t EMC_ModeOffset(uint32_t addrMap)
 {
     uint8_t offset     = 0;
     uint32_t columbase = addrMap & EMC_DYNCTL_COLUMNBASE_MASK;

     /* First calculate the column length. */
     if (columbase == 2U)
     {
         offset = 8;
     }
     else
     {
         if (0U == columbase)
         {
             offset = 9;
         }
         else
         {
             offset = 8;
         }

         /* Add column length increase check. */
         offset += (uint8_t)((addrMap & EMC_DYNCTL_COLUMNPLUS_MASK) >> EMC_DYNCTL_COLUMNPLUS_OFFSET);
     }

     /* Add Buswidth/16. */
     if (0U != (addrMap & EMC_DYNCTL_BUSWIDTH_MASK))
     {
         offset += 2U;
     }
     else
     {
         offset += 1U;
     }

     /* Add bank select bit if the sdram address map mode is RBC(row-bank-column) mode. */
     if (0U == (addrMap & EMC_DYNCTL_BUSADDRMAP_MASK))
     {
         if (0U == (addrMap & EMC_DYNCTL_DEVBANKS_BITS_MASK))
         {
             offset += 1U;
         }
         else
         {
             offset += 2U;
         }
     }

     return offset;
 }

 /*!
  * brief Initializes the basic for EMC.
  * This function ungates the EMC clock, initializes the emc system configure
  * and enable the EMC module. This function must be called in the first step to initialize
  * the external memory.
  *
  * param base EMC peripheral base address.
  * param config The EMC basic configuration.
  */
 void EMC_Init(EMC_Type *base, emc_basic_config_t *config)
 {
 #if !(defined(FSL_SDK_DISABLE_DRIVER_CLOCK_CONTROL) && FSL_SDK_DISABLE_DRIVER_CLOCK_CONTROL)
     /* Enable the clock. */
     CLOCK_EnableClock((s_EMCClock[EMC_GetInstance(base)]));
 #endif /* FSL_SDK_DISABLE_DRIVER_CLOCK_CONTROL */

 #if !(defined(FSL_FEATURE_EMC_HAS_NO_RESET) && FSL_FEATURE_EMC_HAS_NO_RESET)
     /* Reset the EMC module */
     RESET_PeripheralReset(s_emcResets[EMC_GetInstance(base)]);
 #endif

     /* Reset the EMC. */
     SYSCON->PRESETCTRL[2] |= SYSCON_PRESETCTRL_EMC_RESET_MASK;
     SYSCON->PRESETCTRL[2] &= ~SYSCON_PRESETCTRL_EMC_RESET_MASK;

     /* Set the EMC sytem configure. */
     SYSCON->EMCCLKDIV = SYSCON_EMCCLKDIV_DIV(config->emcClkDiv);

     SYSCON->EMCSYSCTRL = SYSCON_EMCSYSCTRL_EMCFBCLKINSEL(config->fbClkSrc);

     /* Set the endian mode. */
     base->CONFIG = (uint32_t)config->endian;
     /* Enable the EMC module with normal memory map mode and normal work mode. */
     base->CONTROL = EMC_CONTROL_E_MASK;
 }

 /*!
  * brief Initializes the dynamic memory controller.
  * This function initializes the dynamic memory controller in external memory controller.
  * This function must be called after EMC_Init and before accessing the external dynamic memory.
  *
  * param base EMC peripheral base address.
  * param timing The timing and latency for dynamica memory controller setting. It shall
  *        be used for all dynamica memory chips, threfore the worst timing value for all
  *        used chips must be given.
  * param configure The EMC dynamic memory controller chip independent configuration pointer.
  *       This configuration pointer is actually pointer to a configration array. the array number
  *       depends on the "totalChips".
  * param totalChips The total dynamic memory chip numbers been used or the length of the
  *        "emc_dynamic_chip_config_t" type memory.
  */
 void EMC_DynamicMemInit(EMC_Type *base,
                         emc_dynamic_timing_config_t *timing,
                         emc_dynamic_chip_config_t *config,
                         uint32_t totalChips)
 {
     assert(NULL != config);
     assert(NULL != timing);
     assert(totalChips <= EMC_DYNAMIC_MEMDEV_NUM);

     uint32_t count;
     uint32_t casLatency;
     uint32_t addr;
     uint32_t offset;
     uint32_t data;
     emc_dynamic_chip_config_t *dynamicConfig = config;

     /* Setting for dynamic memory controller chip independent configuration. */
     for (count = 0; (count < totalChips); count++)
     {
         if (NULL == dynamicConfig)
         {
             break;
         }
         else
         {
             base->DYNAMIC[dynamicConfig->chipIndex].DYNAMICCONFIG =
                 EMC_DYNAMIC_DYNAMICCONFIG_MD(dynamicConfig->dynamicDevice) | EMC_ADDRMAP(dynamicConfig->devAddrMap);
             /* Abstract CAS latency from the sdram mode reigster setting values. */
             casLatency = ((uint32_t)dynamicConfig->sdramModeReg & EMC_SDRAM_MODE_CL_MASK) >> EMC_SDRAM_MODE_CL_SHIFT;
             base->DYNAMIC[dynamicConfig->chipIndex].DYNAMICRASCAS =
                 EMC_DYNAMIC_DYNAMICRASCAS_RAS(dynamicConfig->rAS_Nclk) | EMC_DYNAMIC_DYNAMICRASCAS_CAS(casLatency);

             dynamicConfig++;
         }
     }

     /* Configure the Dynamic Memory controller timing/latency for all chips. */
     base->DYNAMICREADCONFIG = EMC_DYNAMICREADCONFIG_RD(timing->readConfig);
     base->DYNAMICRP         = EMC_CalculateTimerCycles(base, timing->tRp_Ns, 1) & EMC_DYNAMICRP_TRP_MASK;
     base->DYNAMICRAS        = EMC_CalculateTimerCycles(base, timing->tRas_Ns, 1) & EMC_DYNAMICRAS_TRAS_MASK;
     base->DYNAMICSREX       = EMC_CalculateTimerCycles(base, timing->tSrex_Ns, 1) & EMC_DYNAMICSREX_TSREX_MASK;
     base->DYNAMICAPR        = EMC_CalculateTimerCycles(base, timing->tApr_Ns, 1) & EMC_DYNAMICAPR_TAPR_MASK;
     base->DYNAMICDAL        = EMC_CalculateTimerCycles(base, timing->tDal_Ns, 0) & EMC_DYNAMICDAL_TDAL_MASK;
     base->DYNAMICWR         = EMC_CalculateTimerCycles(base, timing->tWr_Ns, 1) & EMC_DYNAMICWR_TWR_MASK;
     base->DYNAMICRC         = EMC_CalculateTimerCycles(base, timing->tRc_Ns, 1) & EMC_DYNAMICRC_TRC_MASK;
     base->DYNAMICRFC        = EMC_CalculateTimerCycles(base, timing->tRfc_Ns, 1) & EMC_DYNAMICRFC_TRFC_MASK;
     base->DYNAMICXSR        = EMC_CalculateTimerCycles(base, timing->tXsr_Ns, 1) & EMC_DYNAMICXSR_TXSR_MASK;
     base->DYNAMICRRD        = EMC_CalculateTimerCycles(base, timing->tRrd_Ns, 1) & EMC_DYNAMICRRD_TRRD_MASK;
     base->DYNAMICMRD        = EMC_DYNAMICMRD_TMRD((timing->tMrd_Nclk > 0U) ? timing->tMrd_Nclk - 1UL : 0UL);

     SDK_DelayAtLeastUs(EMC_SDRAM_NOP_DELAY_US, SDK_DEVICE_MAXIMUM_CPU_CLOCK_FREQUENCY);
     /* Step 2. issue nop command. */
     base->DYNAMICCONTROL = 0x00000183;

     SDK_DelayAtLeastUs(EMC_SDRAM_PRECHARGE_DELAY_US, SDK_DEVICE_MAXIMUM_CPU_CLOCK_FREQUENCY);
     /* Step 3. issue precharge all command. */
     base->DYNAMICCONTROL = 0x00000103;

     /* Step 4. issue two auto-refresh command. */
     base->DYNAMICREFRESH = 2;
     SDK_DelayAtLeastUs(EMC_SDRAM_AUTO_REFRESH_DELAY_US, SDK_DEVICE_MAXIMUM_CPU_CLOCK_FREQUENCY);

     base->DYNAMICREFRESH = EMC_CalculateTimerCycles(base, timing->refreshPeriod_Nanosec, 0) / EMC_REFRESH_CLOCK_PARAM;

     /* Step 5. issue a mode command and set the mode value. */
     base->DYNAMICCONTROL = 0x00000083;

     /* Calculate the mode settings here and to reach the 8 auto-refresh time requirement. */
     dynamicConfig = config;
     for (count = 0; (count < totalChips); count++)
     {
         if (NULL == dynamicConfig)
         {
             break;
         }
         else
         {
             /* Get the shift value first. */
             offset = EMC_ModeOffset(dynamicConfig->devAddrMap);
             addr   = (s_EMCDYCSBases[dynamicConfig->chipIndex] |
                     ((uint32_t)(dynamicConfig->sdramModeReg & ~EMC_SDRAM_BANKCS_BA_MASK) << offset));
             /* Set the right mode setting value. */
             data = *(volatile uint32_t *)addr;
             data = data;
             dynamicConfig++;
         }
     }

     if (kEMC_Sdram != config->dynamicDevice)
     {
         /* Add extended mode register if the low-power sdram is used. */
         base->DYNAMICCONTROL = 0x00000083;
         /* Calculate the mode settings for extended mode register. */
         dynamicConfig = config;
         for (count = 0; (count < totalChips); count++)
         {
             if (NULL == dynamicConfig)
             {
                 break;
             }
             else
             {
                 /* Get the shift value first. */
                 offset = EMC_ModeOffset(dynamicConfig->devAddrMap);
                 addr   = (s_EMCDYCSBases[dynamicConfig->chipIndex] |
                         (((uint32_t)(dynamicConfig->sdramExtModeReg & ~EMC_SDRAM_BANKCS_BA_MASK) |
                           EMC_SDRAM_BANKCS_BA1_MASK)
                          << offset));
                 /* Set the right mode setting value. */
                 data = *(volatile uint32_t *)addr;
                 data = data;
                 dynamicConfig++;
             }
         }
     }

     /* Step 6. issue normal operation command. */
     base->DYNAMICCONTROL = 0x00000000; /* Issue NORMAL command */

     /* The buffer shall be disabled when do the sdram initialization and
      * enabled after the initialization during normal opeation.
      */
     dynamicConfig = config;
     for (count = 0; (count < totalChips); count++)
     {
         if (NULL == dynamicConfig)
         {
             break;
         }
         else
         {
             base->DYNAMIC[dynamicConfig->chipIndex].DYNAMICCONFIG |= EMC_DYNAMIC_DYNAMICCONFIG_B_MASK;
             dynamicConfig++;
         }
     }
 }

 /*!
  * brief Initializes the static memory controller.
  * This function initializes the static memory controller in external memory controller.
  * This function must be called after EMC_Init and before accessing the external static memory.
  *
  * param base EMC peripheral base address.
  * param extWait_Ns The extended wait timeout or the read/write transfer time.
  *        This is common for all static memory chips and set with NULL if not required.
  * param configure The EMC static memory controller chip independent configuration pointer.
  *       This configuration pointer is actually pointer to a configration array. the array number
  *       depends on the "totalChips".
  * param totalChips The total static memory chip numbers been used or the length of the
  *        "emc_static_chip_config_t" type memory.
  */
 void EMC_StaticMemInit(EMC_Type *base, uint32_t *extWait_Ns, emc_static_chip_config_t *config, uint32_t totalChips)
 {
     assert(NULL != config);

     uint32_t count;
     emc_static_chip_config_t *staticConfig = config;

     /* Initialize extended wait. */
     if (NULL != extWait_Ns)
     {
         for (count = 0; (count < totalChips) && (staticConfig != NULL); count++)
         {
             assert(0U != (staticConfig->specailConfig & (uint32_t)kEMC_AsynchronosPageEnable));
         }

         base->STATICEXTENDEDWAIT = EMC_CalculateTimerCycles(base, *extWait_Ns, 1);
         staticConfig++;
     }

     /* Initialize the static memory chip specific configure. */
     staticConfig = config;
     for (count = 0; (count < totalChips); count++)
     {
         if (NULL == staticConfig)
         {
             break;
         }
         else
         {
             base->STATIC[staticConfig->chipIndex].STATICCONFIG =
                 (staticConfig->specailConfig | (uint32_t)staticConfig->memWidth);
             base->STATIC[staticConfig->chipIndex].STATICWAITWEN =
                 EMC_CalculateTimerCycles(base, staticConfig->tWaitWriteEn_Ns, 1);
             base->STATIC[staticConfig->chipIndex].STATICWAITOEN =
                 EMC_CalculateTimerCycles(base, staticConfig->tWaitOutEn_Ns, 0);
             base->STATIC[staticConfig->chipIndex].STATICWAITRD =
                 EMC_CalculateTimerCycles(base, staticConfig->tWaitReadNoPage_Ns, 1);
             base->STATIC[staticConfig->chipIndex].STATICWAITPAGE =
                 EMC_CalculateTimerCycles(base, staticConfig->tWaitReadPage_Ns, 1);
             base->STATIC[staticConfig->chipIndex].STATICWAITWR =
                 EMC_CalculateTimerCycles(base, staticConfig->tWaitWrite_Ns, 2);
             base->STATIC[staticConfig->chipIndex].STATICWAITTURN =
                 EMC_CalculateTimerCycles(base, staticConfig->tWaitTurn_Ns, 1);

             staticConfig++;
         }
     }
 }

 /*!
  * brief Deinitializes the EMC module and gates the clock.
  * This function gates the EMC controller clock. As a result, the EMC
  * module doesn't work after calling this function.
  *
  * param base EMC peripheral base address.
  */
 void EMC_Deinit(EMC_Type *base)
 {
     /* Deinit the EMC. */
     base->CONTROL &= ~EMC_CONTROL_E_MASK;

 #if !(defined(FSL_SDK_DISABLE_DRIVER_CLOCK_CONTROL) && FSL_SDK_DISABLE_DRIVER_CLOCK_CONTROL)
     /* Disable the clock. */
     CLOCK_DisableClock(s_EMCClock[EMC_GetInstance(base)]);
 #endif /* FSL_SDK_DISABLE_DRIVER_CLOCK_CONTROL */
 }
	/*
	* Copyright (c) 2016, Freescale Semiconductor, Inc.
	* Copyright 2016-2019 NXP
	* All rights reserved.
	*
	* SPDX-License-Identifier: BSD-3-Clause
	*/

	#include "fsl_emc.h"

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

	/* Component ID definition, used by tools. */
	#ifndef FSL_COMPONENT_ID
	#define FSL_COMPONENT_ID "platform.drivers.emc"
	#endif

	/! @brief Define macros for EMC driver. /
	#define EMC_REFRESH_CLOCK_PARAM (16U)
	#define EMC_SDRAM_WAIT_CYCLES (2000U)
	#define EMC_DYNCTL_COLUMNBASE_OFFSET (0U)
	#define EMC_DYNCTL_COLUMNBASE_MASK (0x3U)
	#define EMC_DYNCTL_COLUMNPLUS_OFFSET (3U)
	#define EMC_DYNCTL_COLUMNPLUS_MASK (0x18U)
	#define EMC_DYNCTL_BUSWIDTH_MASK (0x80U)
	#define EMC_DYNCTL_BUSADDRMAP_MASK (0x20U)
	#define EMC_DYNCTL_DEVBANKS_BITS_MASK (0x1cU)
	#define EMC_SDRAM_BANKCS_BA0_MASK (uint32_t)(0x2000)
	#define EMC_SDRAM_BANKCS_BA1_MASK (uint32_t)(0x4000)
	#define EMC_SDRAM_BANKCS_BA_MASK (EMC_SDRAM_BANKCS_BA0_MASK \| EMC_SDRAM_BANKCS_BA1_MASK)
	#define EMC_DIV_ROUND_UP(n, m) (((n) + (m)-1U) / (m))

	/*******************************************************************************
	* Prototypes
	******************************************************************************/
	/*!
	* @brief Get instance number for EMC module.
	*
	* @param base EMC peripheral base address
	*/
	static uint32_t EMC_GetInstance(EMC_Type *base);

	/*!
	* @brief Get the clock cycles of EMC clock.
	* The function is used to calculate the multiple of the
	* 16 EMCCLKs between the timer_Ns period.
	*
	* @param base EMC peripheral base address
	* @param timer_Ns The timer/period in unit of nanosecond
	* @param plus The plus added to the register settings to reach the calculated cycles.
	* @return The calculated cycles.
	*/
	static uint32_t EMC_CalculateTimerCycles(EMC_Type *base, uint32_t timer_Ns, uint32_t plus);

	/*!
	* @brief Get the shift value to shift the mode register content by.
	*
	* @param addrMap EMC address map for the dynamic memory configuration.
	* It is the bit 14 ~ bit 7 of the EMC_DYNAMICCONFIG.
	* @return The offset value to shift the mode register content by.
	*/
	static uint32_t EMC_ModeOffset(uint32_t addrMap);

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

	#if !(defined(FSL_SDK_DISABLE_DRIVER_CLOCK_CONTROL) && FSL_SDK_DISABLE_DRIVER_CLOCK_CONTROL)
	/! @brief Pointers to EMC clocks for each instance. /
	static const clock_ip_name_t s_EMCClock[FSL_FEATURE_SOC_EMC_COUNT] = EMC_CLOCKS;
	#endif /* FSL_SDK_DISABLE_DRIVER_CLOCK_CONTROL */

	#if !(defined(FSL_FEATURE_EMC_HAS_NO_RESET) && FSL_FEATURE_EMC_HAS_NO_RESET)
	/! @brief Pointers to EMC resets for each instance. /
	static const reset_ip_name_t s_emcResets[] = EMC_RSTS;
	#endif

	/! @brief Pointers to EMC bases for each instance. /
	static const EMC_Type *const s_EMCBases[] = EMC_BASE_PTRS;

	/! @brief Define the start address for each chip controlled by EMC. /
	static const uint32_t s_EMCDYCSBases[] = EMC_DYCS_ADDRESS;
	/*******************************************************************************
	* Code
	******************************************************************************/

	static uint32_t EMC_GetInstance(EMC_Type *base)
	{
	uint32_t instance;

	/* Find the instance index from base address mappings. */
	for (instance = 0; instance < ARRAY_SIZE(s_EMCBases); instance++)
	{
	if (s_EMCBases[instance] == base)
	{
	break;
	}
	}

	assert(instance < ARRAY_SIZE(s_EMCBases));

	return instance;
	}

	static uint32_t EMC_CalculateTimerCycles(EMC_Type *base, uint32_t timer_Ns, uint32_t plus)
	{
	uint32_t cycles;

	cycles = CLOCK_GetEmcClkFreq() / EMC_HZ_ONEMHZ * timer_Ns;
	cycles = EMC_DIV_ROUND_UP(cycles, EMC_MILLISECS_ONESEC); /* Round up. */

	/* Decrese according to the plus. */
	if (cycles >= plus)
	{
	cycles = cycles - plus;
	}
	else
	{
	cycles = 0;
	}

	return cycles;
	}

	static uint32_t EMC_ModeOffset(uint32_t addrMap)
	{
	uint8_t offset = 0;
	uint32_t columbase = addrMap & EMC_DYNCTL_COLUMNBASE_MASK;

	/* First calculate the column length. */
	if (columbase == 2U)
	{
	offset = 8;
	}
	else
	{
	if (0U == columbase)
	{
	offset = 9;
	}
	else
	{
	offset = 8;
	}

	/* Add column length increase check. */
	offset += (uint8_t)((addrMap & EMC_DYNCTL_COLUMNPLUS_MASK) >> EMC_DYNCTL_COLUMNPLUS_OFFSET);
	}

	/* Add Buswidth/16. */
	if (0U != (addrMap & EMC_DYNCTL_BUSWIDTH_MASK))
	{
	offset += 2U;
	}
	else
	{
	offset += 1U;
	}

	/* Add bank select bit if the sdram address map mode is RBC(row-bank-column) mode. */
	if (0U == (addrMap & EMC_DYNCTL_BUSADDRMAP_MASK))
	{
	if (0U == (addrMap & EMC_DYNCTL_DEVBANKS_BITS_MASK))
	{
	offset += 1U;
	}
	else
	{
	offset += 2U;
	}
	}

	return offset;
	}

	/*!
	* brief Initializes the basic for EMC.
	* This function ungates the EMC clock, initializes the emc system configure
	* and enable the EMC module. This function must be called in the first step to initialize
	* the external memory.
	*
	* param base EMC peripheral base address.
	* param config The EMC basic configuration.
	*/
	void EMC_Init(EMC_Type base, emc_basic_config_t config)
	{
	#if !(defined(FSL_SDK_DISABLE_DRIVER_CLOCK_CONTROL) && FSL_SDK_DISABLE_DRIVER_CLOCK_CONTROL)
	/* Enable the clock. */
	CLOCK_EnableClock((s_EMCClock[EMC_GetInstance(base)]));
	#endif /* FSL_SDK_DISABLE_DRIVER_CLOCK_CONTROL */

	#if !(defined(FSL_FEATURE_EMC_HAS_NO_RESET) && FSL_FEATURE_EMC_HAS_NO_RESET)
	/* Reset the EMC module */
	RESET_PeripheralReset(s_emcResets[EMC_GetInstance(base)]);
	#endif

	/* Reset the EMC. */
	SYSCON->PRESETCTRL[2] \|= SYSCON_PRESETCTRL_EMC_RESET_MASK;
	SYSCON->PRESETCTRL[2] &= ~SYSCON_PRESETCTRL_EMC_RESET_MASK;

	/* Set the EMC sytem configure. */
	SYSCON->EMCCLKDIV = SYSCON_EMCCLKDIV_DIV(config->emcClkDiv);

	SYSCON->EMCSYSCTRL = SYSCON_EMCSYSCTRL_EMCFBCLKINSEL(config->fbClkSrc);

	/* Set the endian mode. */
	base->CONFIG = (uint32_t)config->endian;
	/* Enable the EMC module with normal memory map mode and normal work mode. */
	base->CONTROL = EMC_CONTROL_E_MASK;
	}

	/*!
	* brief Initializes the dynamic memory controller.
	* This function initializes the dynamic memory controller in external memory controller.
	* This function must be called after EMC_Init and before accessing the external dynamic memory.
	*
	* param base EMC peripheral base address.
	* param timing The timing and latency for dynamica memory controller setting. It shall
	* be used for all dynamica memory chips, threfore the worst timing value for all
	* used chips must be given.
	* param configure The EMC dynamic memory controller chip independent configuration pointer.
	* This configuration pointer is actually pointer to a configration array. the array number
	* depends on the "totalChips".
	* param totalChips The total dynamic memory chip numbers been used or the length of the
	* "emc_dynamic_chip_config_t" type memory.
	*/
	void EMC_DynamicMemInit(EMC_Type *base,
	emc_dynamic_timing_config_t *timing,
	emc_dynamic_chip_config_t *config,
	uint32_t totalChips)
	{
	assert(NULL != config);
	assert(NULL != timing);
	assert(totalChips <= EMC_DYNAMIC_MEMDEV_NUM);

	uint32_t count;
	uint32_t casLatency;
	uint32_t addr;
	uint32_t offset;
	uint32_t data;
	emc_dynamic_chip_config_t *dynamicConfig = config;

	/* Setting for dynamic memory controller chip independent configuration. */
	for (count = 0; (count < totalChips); count++)
	{
	if (NULL == dynamicConfig)
	{
	break;
	}
	else
	{
	base->DYNAMIC[dynamicConfig->chipIndex].DYNAMICCONFIG =
	EMC_DYNAMIC_DYNAMICCONFIG_MD(dynamicConfig->dynamicDevice) \| EMC_ADDRMAP(dynamicConfig->devAddrMap);
	/* Abstract CAS latency from the sdram mode reigster setting values. */
	casLatency = ((uint32_t)dynamicConfig->sdramModeReg & EMC_SDRAM_MODE_CL_MASK) >> EMC_SDRAM_MODE_CL_SHIFT;
	base->DYNAMIC[dynamicConfig->chipIndex].DYNAMICRASCAS =
	EMC_DYNAMIC_DYNAMICRASCAS_RAS(dynamicConfig->rAS_Nclk) \| EMC_DYNAMIC_DYNAMICRASCAS_CAS(casLatency);

	dynamicConfig++;
	}
	}

	/* Configure the Dynamic Memory controller timing/latency for all chips. */
	base->DYNAMICREADCONFIG = EMC_DYNAMICREADCONFIG_RD(timing->readConfig);
	base->DYNAMICRP = EMC_CalculateTimerCycles(base, timing->tRp_Ns, 1) & EMC_DYNAMICRP_TRP_MASK;
	base->DYNAMICRAS = EMC_CalculateTimerCycles(base, timing->tRas_Ns, 1) & EMC_DYNAMICRAS_TRAS_MASK;
	base->DYNAMICSREX = EMC_CalculateTimerCycles(base, timing->tSrex_Ns, 1) & EMC_DYNAMICSREX_TSREX_MASK;
	base->DYNAMICAPR = EMC_CalculateTimerCycles(base, timing->tApr_Ns, 1) & EMC_DYNAMICAPR_TAPR_MASK;
	base->DYNAMICDAL = EMC_CalculateTimerCycles(base, timing->tDal_Ns, 0) & EMC_DYNAMICDAL_TDAL_MASK;
	base->DYNAMICWR = EMC_CalculateTimerCycles(base, timing->tWr_Ns, 1) & EMC_DYNAMICWR_TWR_MASK;
	base->DYNAMICRC = EMC_CalculateTimerCycles(base, timing->tRc_Ns, 1) & EMC_DYNAMICRC_TRC_MASK;
	base->DYNAMICRFC = EMC_CalculateTimerCycles(base, timing->tRfc_Ns, 1) & EMC_DYNAMICRFC_TRFC_MASK;
	base->DYNAMICXSR = EMC_CalculateTimerCycles(base, timing->tXsr_Ns, 1) & EMC_DYNAMICXSR_TXSR_MASK;
	base->DYNAMICRRD = EMC_CalculateTimerCycles(base, timing->tRrd_Ns, 1) & EMC_DYNAMICRRD_TRRD_MASK;
	base->DYNAMICMRD = EMC_DYNAMICMRD_TMRD((timing->tMrd_Nclk > 0U) ? timing->tMrd_Nclk - 1UL : 0UL);

	SDK_DelayAtLeastUs(EMC_SDRAM_NOP_DELAY_US, SDK_DEVICE_MAXIMUM_CPU_CLOCK_FREQUENCY);
	/* Step 2. issue nop command. */
	base->DYNAMICCONTROL = 0x00000183;

	SDK_DelayAtLeastUs(EMC_SDRAM_PRECHARGE_DELAY_US, SDK_DEVICE_MAXIMUM_CPU_CLOCK_FREQUENCY);
	/* Step 3. issue precharge all command. */
	base->DYNAMICCONTROL = 0x00000103;

	/* Step 4. issue two auto-refresh command. */
	base->DYNAMICREFRESH = 2;
	SDK_DelayAtLeastUs(EMC_SDRAM_AUTO_REFRESH_DELAY_US, SDK_DEVICE_MAXIMUM_CPU_CLOCK_FREQUENCY);

	base->DYNAMICREFRESH = EMC_CalculateTimerCycles(base, timing->refreshPeriod_Nanosec, 0) / EMC_REFRESH_CLOCK_PARAM;

	/* Step 5. issue a mode command and set the mode value. */
	base->DYNAMICCONTROL = 0x00000083;

	/* Calculate the mode settings here and to reach the 8 auto-refresh time requirement. */
	dynamicConfig = config;
	for (count = 0; (count < totalChips); count++)
	{
	if (NULL == dynamicConfig)
	{
	break;
	}
	else
	{
	/* Get the shift value first. */
	offset = EMC_ModeOffset(dynamicConfig->devAddrMap);
	addr = (s_EMCDYCSBases[dynamicConfig->chipIndex] \|
	((uint32_t)(dynamicConfig->sdramModeReg & ~EMC_SDRAM_BANKCS_BA_MASK) << offset));
	/* Set the right mode setting value. */
	data = (volatile uint32_t )addr;
	data = data;
	dynamicConfig++;
	}
	}

	if (kEMC_Sdram != config->dynamicDevice)
	{
	/* Add extended mode register if the low-power sdram is used. */
	base->DYNAMICCONTROL = 0x00000083;
	/* Calculate the mode settings for extended mode register. */
	dynamicConfig = config;
	for (count = 0; (count < totalChips); count++)
	{
	if (NULL == dynamicConfig)
	{
	break;
	}
	else
	{
	/* Get the shift value first. */
	offset = EMC_ModeOffset(dynamicConfig->devAddrMap);
	addr = (s_EMCDYCSBases[dynamicConfig->chipIndex] \|
	(((uint32_t)(dynamicConfig->sdramExtModeReg & ~EMC_SDRAM_BANKCS_BA_MASK) \|
	EMC_SDRAM_BANKCS_BA1_MASK)
	<< offset));
	/* Set the right mode setting value. */
	data = (volatile uint32_t )addr;
	data = data;
	dynamicConfig++;
	}
	}
	}

	/* Step 6. issue normal operation command. */
	base->DYNAMICCONTROL = 0x00000000; /* Issue NORMAL command */

	/* The buffer shall be disabled when do the sdram initialization and
	* enabled after the initialization during normal opeation.
	*/
	dynamicConfig = config;
	for (count = 0; (count < totalChips); count++)
	{
	if (NULL == dynamicConfig)
	{
	break;
	}
	else
	{
	base->DYNAMIC[dynamicConfig->chipIndex].DYNAMICCONFIG \|= EMC_DYNAMIC_DYNAMICCONFIG_B_MASK;
	dynamicConfig++;
	}
	}
	}

	/*!
	* brief Initializes the static memory controller.
	* This function initializes the static memory controller in external memory controller.
	* This function must be called after EMC_Init and before accessing the external static memory.
	*
	* param base EMC peripheral base address.
	* param extWait_Ns The extended wait timeout or the read/write transfer time.
	* This is common for all static memory chips and set with NULL if not required.
	* param configure The EMC static memory controller chip independent configuration pointer.
	* This configuration pointer is actually pointer to a configration array. the array number
	* depends on the "totalChips".
	* param totalChips The total static memory chip numbers been used or the length of the
	* "emc_static_chip_config_t" type memory.
	*/
	void EMC_StaticMemInit(EMC_Type base, uint32_t extWait_Ns, emc_static_chip_config_t *config, uint32_t totalChips)
	{
	assert(NULL != config);

	uint32_t count;
	emc_static_chip_config_t *staticConfig = config;

	/* Initialize extended wait. */
	if (NULL != extWait_Ns)
	{
	for (count = 0; (count < totalChips) && (staticConfig != NULL); count++)
	{
	assert(0U != (staticConfig->specailConfig & (uint32_t)kEMC_AsynchronosPageEnable));
	}

	base->STATICEXTENDEDWAIT = EMC_CalculateTimerCycles(base, *extWait_Ns, 1);
	staticConfig++;
	}

	/* Initialize the static memory chip specific configure. */
	staticConfig = config;
	for (count = 0; (count < totalChips); count++)
	{
	if (NULL == staticConfig)
	{
	break;
	}
	else
	{
	base->STATIC[staticConfig->chipIndex].STATICCONFIG =
	(staticConfig->specailConfig \| (uint32_t)staticConfig->memWidth);
	base->STATIC[staticConfig->chipIndex].STATICWAITWEN =
	EMC_CalculateTimerCycles(base, staticConfig->tWaitWriteEn_Ns, 1);
	base->STATIC[staticConfig->chipIndex].STATICWAITOEN =
	EMC_CalculateTimerCycles(base, staticConfig->tWaitOutEn_Ns, 0);
	base->STATIC[staticConfig->chipIndex].STATICWAITRD =
	EMC_CalculateTimerCycles(base, staticConfig->tWaitReadNoPage_Ns, 1);
	base->STATIC[staticConfig->chipIndex].STATICWAITPAGE =
	EMC_CalculateTimerCycles(base, staticConfig->tWaitReadPage_Ns, 1);
	base->STATIC[staticConfig->chipIndex].STATICWAITWR =
	EMC_CalculateTimerCycles(base, staticConfig->tWaitWrite_Ns, 2);
	base->STATIC[staticConfig->chipIndex].STATICWAITTURN =
	EMC_CalculateTimerCycles(base, staticConfig->tWaitTurn_Ns, 1);

	staticConfig++;
	}
	}
	}

	/*!
	* brief Deinitializes the EMC module and gates the clock.
	* This function gates the EMC controller clock. As a result, the EMC
	* module doesn't work after calling this function.
	*
	* param base EMC peripheral base address.
	*/
	void EMC_Deinit(EMC_Type *base)
	{
	/* Deinit the EMC. */
	base->CONTROL &= ~EMC_CONTROL_E_MASK;

	#if !(defined(FSL_SDK_DISABLE_DRIVER_CLOCK_CONTROL) && FSL_SDK_DISABLE_DRIVER_CLOCK_CONTROL)
	/* Disable the clock. */
	CLOCK_DisableClock(s_EMCClock[EMC_GetInstance(base)]);
	#endif /* FSL_SDK_DISABLE_DRIVER_CLOCK_CONTROL */
	}