rt-thread/bsp/xplorer4330/libraries/lpc_ip/emc_001.c

275 lines
9.5 KiB
C

/*
* @brief EMC Registers and control functions
*
* @note
* Copyright(C) NXP Semiconductors, 2012
* All rights reserved.
*
* @par
* Software that is described herein is for illustrative purposes only
* which provides customers with programming information regarding the
* LPC products. This software is supplied "AS IS" without any warranties of
* any kind, and NXP Semiconductors and its licensor disclaim any and
* all warranties, express or implied, including all implied warranties of
* merchantability, fitness for a particular purpose and non-infringement of
* intellectual property rights. NXP Semiconductors assumes no responsibility
* or liability for the use of the software, conveys no license or rights under any
* patent, copyright, mask work right, or any other intellectual property rights in
* or to any products. NXP Semiconductors reserves the right to make changes
* in the software without notification. NXP Semiconductors also makes no
* representation or warranty that such application will be suitable for the
* specified use without further testing or modification.
*
* @par
* Permission to use, copy, modify, and distribute this software and its
* documentation is hereby granted, under NXP Semiconductors' and its
* licensor's relevant copyrights in the software, without fee, provided that it
* is used in conjunction with NXP Semiconductors microcontrollers. This
* copyright, permission, and disclaimer notice must appear in all copies of
* this code.
*/
#include "emc_001.h"
/*****************************************************************************
* Private types/enumerations/variables
****************************************************************************/
/*****************************************************************************
* Public types/enumerations/variables
****************************************************************************/
/*****************************************************************************
* Private functions
****************************************************************************/
/* DIV function with result rounded up */
#define EMC_DIV_ROUND_UP(x, y) ((x + y - 1) / y)
#ifndef EMC_SUPPORT_ONLY_PL172
/* Get ARM External Memory Controller Version */
static uint32_t EMC_GetARMPeripheralID(IP_EMC_001_Type *pEMC)
{
uint32_t *RegAdd;
RegAdd = (uint32_t *) ((uint32_t) pEMC + 0xFE0);
return (RegAdd[0] & 0xFF) | ((RegAdd[1] & 0xFF) << 8) |
((RegAdd[2] & 0xFF) << 16) | (RegAdd[3] << 24);
}
#endif
/* Calculate Clock Count from Timing Unit(nanoseconds) */
static uint32_t EMC_TimingParamConvert(uint32_t EMC_Clock, int32_t input_ns, uint32_t adjust)
{
uint32_t temp;
if (input_ns < 0) {
return (-input_ns) >> 8;
}
temp = EMC_Clock / 1000000; /* MHz calculation */
temp = temp * input_ns / 1000;
/* round up */
temp += 0xFF;
/* convert to simple integer number format */
temp >>= 8;
if (temp > adjust) {
return temp - adjust;
}
return 0;
}
/* Get Dynamic Memory Device Colum len */
static uint32_t EMC_GetColsLen(uint32_t DynConfig)
{
uint32_t DevBusWidth;
DevBusWidth = (DynConfig >> EMC_DYN_CONFIG_DEV_BUS_BIT) & 0x03;
if (DevBusWidth == 2) {
return 8;
}
else if (DevBusWidth == 1) {
return ((DynConfig >> (EMC_DYN_CONFIG_DEV_SIZE_BIT + 1)) & 0x03) + 8;
}
else if (DevBusWidth == 0) {
return ((DynConfig >> (EMC_DYN_CONFIG_DEV_SIZE_BIT + 1)) & 0x03) + 9;
}
return 0;
}
/*****************************************************************************
* Public functions
****************************************************************************/
/* Initializes the Dynamic Controller according to the specified parameters
in the IP_EMC_DYN_CONFIG_Type */
void IP_EMC_Dynamic_Init(IP_EMC_001_Type *pEMC, IP_EMC_DYN_CONFIG_Type *Dynamic_Config, uint32_t EMC_Clock)
{
uint32_t ChipSelect, tmpclk;
int i;
for (ChipSelect = 0; ChipSelect < 4; ChipSelect++) {
IP_EMC_001_Type *EMC_Reg_add = (IP_EMC_001_Type *) ((uint32_t) pEMC + (ChipSelect << 5));
EMC_Reg_add->DYNAMICRASCAS0 = Dynamic_Config->DevConfig[ChipSelect].RAS |
((Dynamic_Config->DevConfig[ChipSelect].ModeRegister <<
(8 - EMC_DYN_MODE_CAS_BIT)) & 0xF00);
EMC_Reg_add->DYNAMICCONFIG0 = Dynamic_Config->DevConfig[ChipSelect].DynConfig;
}
pEMC->DYNAMICREADCONFIG = Dynamic_Config->ReadConfig; /* Read strategy */
pEMC->DYNAMICRP = EMC_TimingParamConvert(EMC_Clock, Dynamic_Config->tRP, 1);
pEMC->DYNAMICRAS = EMC_TimingParamConvert(EMC_Clock, Dynamic_Config->tRAS, 1);
pEMC->DYNAMICSREX = EMC_TimingParamConvert(EMC_Clock, Dynamic_Config->tSREX, 1);
pEMC->DYNAMICAPR = EMC_TimingParamConvert(EMC_Clock, Dynamic_Config->tAPR, 1);
pEMC->DYNAMICDAL = EMC_TimingParamConvert(EMC_Clock, Dynamic_Config->tDAL, 0);
pEMC->DYNAMICWR = EMC_TimingParamConvert(EMC_Clock, Dynamic_Config->tWR, 1);
pEMC->DYNAMICRC = EMC_TimingParamConvert(EMC_Clock, Dynamic_Config->tRC, 1);
pEMC->DYNAMICRFC = EMC_TimingParamConvert(EMC_Clock, Dynamic_Config->tRFC, 1);
pEMC->DYNAMICXSR = EMC_TimingParamConvert(EMC_Clock, Dynamic_Config->tXSR, 1);
pEMC->DYNAMICRRD = EMC_TimingParamConvert(EMC_Clock, Dynamic_Config->tRRD, 1);
pEMC->DYNAMICMRD = EMC_TimingParamConvert(EMC_Clock, Dynamic_Config->tMRD, 1);
/* TIM_Waitus(100); */
/*TODO: if Timer driver is ready, it should replace below "for" delay technic */
for (i = 0; i < 1000; i++) { /* wait 100us */
}
pEMC->DYNAMICCONTROL = 0x00000183; /* Issue NOP command */
/* TIM_Waitus(200); */ /* wait 200us */
/*TODO: if Timer driver is ready, it should replace below "for" delay technic */
for (i = 0; i < 1000; i++) {}
pEMC->DYNAMICCONTROL = 0x00000103; /* Issue PALL command */
pEMC->DYNAMICREFRESH = 2; /* ( 2 * 16 ) -> 32 clock cycles */
/* TIM_Waitus(200); */ /* wait 200us */
for (i = 0; i < 80; i++) {}
tmpclk = EMC_DIV_ROUND_UP(EMC_TimingParamConvert(EMC_Clock, Dynamic_Config->RefreshPeriod, 0), 16);
pEMC->DYNAMICREFRESH = tmpclk;
pEMC->DYNAMICCONTROL = 0x00000083; /* Issue MODE command */
for (ChipSelect = 0; ChipSelect < 4; ChipSelect++) {
/*uint32_t burst_length;*/
uint32_t DynAddr;
uint8_t Col_len;
Col_len = EMC_GetColsLen(Dynamic_Config->DevConfig[ChipSelect].DynConfig);
/* get bus wide: if 32bit, len is 4 else if 16bit len is 2 */
/* burst_length = 1 << ((((Dynamic_Config->DynConfig[ChipSelect] >> 14) & 1)^1) +1); */
if (Dynamic_Config->DevConfig[ChipSelect].DynConfig & (1 << EMC_DYN_CONFIG_DATA_BUS_WIDTH_BIT)) {
/*32bit bus */
/*burst_length = 2;*/
Col_len += 2;
}
else {
/*burst_length = 4;*/
Col_len += 1;
}
DynAddr = Dynamic_Config->DevConfig[ChipSelect].BaseAddr;
if (DynAddr != 0) {
uint32_t temp;
uint32_t ModeRegister;
ModeRegister = Dynamic_Config->DevConfig[ChipSelect].ModeRegister;
temp = *((volatile uint32_t *) (DynAddr | (ModeRegister << Col_len)));
temp = temp;
}
}
pEMC->DYNAMICCONTROL = 0x00000000; /* Issue NORMAL command */
/* enable buffers */
pEMC->DYNAMICCONFIG0 |= 1 << 19;
pEMC->DYNAMICCONFIG1 |= 1 << 19;
pEMC->DYNAMICCONFIG2 |= 1 << 19;
pEMC->DYNAMICCONFIG3 |= 1 << 19;
}
/* Set Deep Sleep Mode for Dynamic Memory Controller */
void IP_EMC_Dynamic_DeepSleepMode(IP_EMC_001_Type *pEMC, uint32_t Enable)
{
if (Enable) {
pEMC->DYNAMICCONTROL |= 1 << EMC_DYN_CONTROL_DEEPSLEEP_BIT;
}
else {
pEMC->DYNAMICCONTROL &= ~(1 << EMC_DYN_CONTROL_DEEPSLEEP_BIT);
}
}
/* Enable Dynamic Memory Controller */
void IP_EMC_Dynamic_Enable(IP_EMC_001_Type *pEMC, uint8_t Enable)
{
if (Enable) {
pEMC->DYNAMICCONTROL |= EMC_DYN_CONTROL_ENABLE;
}
else {
pEMC->DYNAMICCONTROL &= ~EMC_DYN_CONTROL_ENABLE;
}
}
/* Initializes the Static Controller according to the specified parameters
* in the IP_EMC_STATIC_CONFIG_Type
*/
void IP_EMC_Static_Init(IP_EMC_001_Type *pEMC, IP_EMC_STATIC_CONFIG_Type *Static_Config, uint32_t EMC_Clock)
{
IP_EMC_001_Type *EMC_Reg_add = (IP_EMC_001_Type *) ((uint32_t) pEMC + ((Static_Config->ChipSelect) << 5));
EMC_Reg_add->STATICCONFIG0 = Static_Config->Config;
EMC_Reg_add->STATICWAITWEN0 = EMC_TimingParamConvert(EMC_Clock, Static_Config->WaitWen, 1);
EMC_Reg_add->STATICWAITOEN0 = EMC_TimingParamConvert(EMC_Clock, Static_Config->WaitOen, 0);
EMC_Reg_add->STATICWAITRD0 = EMC_TimingParamConvert(EMC_Clock, Static_Config->WaitRd, 1);
EMC_Reg_add->STATICWAITPAG0 = EMC_TimingParamConvert(EMC_Clock, Static_Config->WaitPage, 1);
EMC_Reg_add->STATICWAITWR0 = EMC_TimingParamConvert(EMC_Clock, Static_Config->WaitWr, 2);
EMC_Reg_add->STATICWAITTURN0 = EMC_TimingParamConvert(EMC_Clock, Static_Config->WaitTurn, 1);
}
/* Mirror CS1 to CS0 and DYCS0 */
void IP_EMC_Mirror(IP_EMC_001_Type *pEMC, uint32_t Enable)
{
if (Enable) {
pEMC->CONTROL |= 1 << 1;
}
else {
pEMC->CONTROL &= ~(1 << 1);
}
}
/* Enable EMC */
void IP_EMC_Enable(IP_EMC_001_Type *pEMC, uint32_t Enable)
{
if (Enable) {
pEMC->CONTROL |= 1;
}
else {
pEMC->CONTROL &= ~(1);
}
}
/* Set EMC LowPower Mode */
void IP_EMC_LowPowerMode(IP_EMC_001_Type *pEMC, uint32_t Enable)
{
if (Enable) {
pEMC->CONTROL |= 1 << 2;
}
else {
pEMC->CONTROL &= ~(1 << 2);
}
}
/* Initialize EMC */
void IP_EMC_Init(IP_EMC_001_Type *pEMC, uint32_t Enable, uint32_t ClockRatio, uint32_t EndianMode)
{
pEMC->CONFIG = (EndianMode ? 1 : 0) | ((ClockRatio ? 1 : 0) << 8);
/* Enable EMC 001 Normal Memory Map, No low power mode */
pEMC->CONTROL = (Enable ? 1 : 0);
}
/* Set Static Memory Extended Wait in Clock */
void IP_EMC_SetStaticExtendedWait(IP_EMC_001_Type *pEMC, uint32_t Wait16Clks)
{
pEMC->STATICEXTENDEDWAIT = Wait16Clks;
}