618 lines
20 KiB
C
618 lines
20 KiB
C
/*
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* File : drv_nand.c
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* This file is part of RT-Thread RTOS
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* COPYRIGHT (C) 2008 - 2012, RT-Thread Development Team
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*
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* The license and distribution terms for this file may be
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* found in the file LICENSE in this distribution or at
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* http://www.rt-thread.org/license/LICENSE
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*
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* Change Logs:
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* Date Author Notes
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* 2017-04-10 lizhen9880 the first version
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*/
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#include "drv_nand.h"
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#include <rtdevice.h>
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#include <string.h>
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#ifdef RT_USING_NFTL
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#include <nftl.h>
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#endif
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#define NAND_DEBUG rt_kprintf
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/* nandflash confg */
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#define PAGES_PER_BLOCK 64
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#define PAGE_DATA_SIZE 2048
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#define PAGE_OOB_SIZE 64
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#define ECC_SIZE 4
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#define SET_NAND_CMD(_c) do{*(volatile rt_uint8_t*)(NAND_ADDRESS|NAND_CMD) = _c;}while(0)
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#define SET_NAND_ADD(_a) do{*(volatile rt_uint8_t*)(NAND_ADDRESS|NAND_ADDR) = _a;}while(0)
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#define SET_NAND_DAT(_d) do{*(volatile rt_uint8_t*)NAND_ADDRESS = _d;}while(0)
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#define GET_NAND_DAT(_d) do{_d = *(volatile rt_uint8_t*)NAND_ADDRESS;}while(0)
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static struct stm32f4_nand _device;
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static rt_bool_t read_status(rt_uint8_t cmd);
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NAND_HandleTypeDef NAND_Handler; //NAND FLASH句柄
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//NAND延时
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void NAND_Delay(volatile rt_uint32_t i)
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{
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while(i>0)i--;
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}
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//等待RB信号为某个电平
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//rb:0,等待RB==0
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// 1,等待RB==1
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//返回值:0,成功
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// 1,超时
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rt_uint8_t NAND_WaitRB(volatile rt_uint8_t rb)
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{
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volatile rt_uint16_t time=0;
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while(time<10000)
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{
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time++;
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if(NAND_RB==rb)
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{
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// NAND_DEBUG("time:%d/%d R/B:%d\n",time,10000,rb);
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return 0;
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}
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}
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// NAND_DEBUG("timeOUT\n");
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return 1;
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}
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//读NAND状态
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//返回值:NAND状态值
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//bit0:0,成功;1,错误(编程/擦除/READ)
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//bit6:0,Busy;1,Ready
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rt_uint8_t NAND_ReadStatus(void)
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{
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volatile rt_uint8_t data=0;
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SET_NAND_CMD(NAND_READSTA);//发送读状态命令
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data++;data++;data++;data++;data++; //加延时,防止-O2优化,导致的错误.
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data=*(volatile rt_uint8_t*)NAND_ADDRESS; //读取状态值
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return data;
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}
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//等待NAND准备好
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//返回值:NSTA_TIMEOUT 等待超时了
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// NSTA_READY 已经准备好
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static rt_uint8_t wait_for_ready(void)
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{
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rt_uint8_t status=0;
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volatile rt_uint32_t time=0;
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while(1) //等待ready
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{
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status=NAND_ReadStatus(); //获取状态值
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if(status&NSTA_READY)break;
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time++;
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if(time>=0X1FFFF)return NSTA_TIMEOUT;//超时
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}
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return NSTA_READY;//准备好
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}
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//复位NAND
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//返回值:0,成功;
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// 其他,失败
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static rt_uint8_t nand_reset(void)
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{
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SET_NAND_CMD(NAND_RESET);//复位NAND
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if(wait_for_ready()==NSTA_READY)return 0;//复位成功
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else return 1; //复位失败
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}
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//读取NAND FLASH的ID
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//返回值:0,成功;
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// 其他,失败
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rt_uint8_t NAND_ModeSet(rt_uint8_t mode)
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{
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SET_NAND_CMD(NAND_FEATURE);
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SET_NAND_ADD(0X01);
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SET_NAND_DAT(mode);
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SET_NAND_DAT(0);
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SET_NAND_DAT(0);
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SET_NAND_DAT(0);
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if(wait_for_ready()==NSTA_READY)return 0;//成功
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else return 1; //失败
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}
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//初始化NAND FLASH
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void NAND_Init(void)
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{
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FMC_NAND_PCC_TimingTypeDef ComSpaceTiming,AttSpaceTiming;
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NAND_Handler.Instance=FMC_NAND_DEVICE;
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NAND_Handler.Init.NandBank=FMC_NAND_BANK3; //NAND挂在BANK3上
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NAND_Handler.Init.Waitfeature=FMC_NAND_PCC_WAIT_FEATURE_DISABLE; //关闭等待特性
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NAND_Handler.Init.MemoryDataWidth=FMC_NAND_PCC_MEM_BUS_WIDTH_8; //8位数据宽度
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NAND_Handler.Init.EccComputation=FMC_NAND_ECC_DISABLE; //不使用ECC
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NAND_Handler.Init.ECCPageSize=FMC_NAND_ECC_PAGE_SIZE_2048BYTE; //ECC页大小为2k
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NAND_Handler.Init.TCLRSetupTime=0; //设置TCLR(tCLR=CLE到RE的延时)=(TCLR+TSET+2)*THCLK,THCLK=1/180M=5.5ns
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NAND_Handler.Init.TARSetupTime=1; //设置TAR(tAR=ALE到RE的延时)=(TAR+TSET+2)*THCLK,THCLK=1/180M=5.5n。
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ComSpaceTiming.SetupTime=2; //建立时间
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ComSpaceTiming.WaitSetupTime=3; //等待时间
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ComSpaceTiming.HoldSetupTime=2; //保持时间
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ComSpaceTiming.HiZSetupTime=1; //高阻态时间
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AttSpaceTiming.SetupTime=2; //建立时间
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AttSpaceTiming.WaitSetupTime=3; //等待时间
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AttSpaceTiming.HoldSetupTime=2; //保持时间
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AttSpaceTiming.HiZSetupTime=1; //高阻态时间
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HAL_NAND_Init(&NAND_Handler,&ComSpaceTiming,&AttSpaceTiming);
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nand_reset(); //复位NAND
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// delay_ms(100);
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wait_for_ready();
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NAND_ModeSet(4); //设置为MODE4,高速模式
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}
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//NAND FALSH底层驱动,引脚配置,时钟使能
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//此函数会被HAL_NAND_Init()调用
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void HAL_NAND_MspInit(NAND_HandleTypeDef *hnand)
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{
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GPIO_InitTypeDef GPIO_Initure;
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__HAL_RCC_FMC_CLK_ENABLE(); //使能FMC时钟
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__HAL_RCC_GPIOD_CLK_ENABLE(); //使能GPIOD时钟
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__HAL_RCC_GPIOE_CLK_ENABLE(); //使能GPIOE时钟
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__HAL_RCC_GPIOG_CLK_ENABLE(); //使能GPIOG时钟
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//初始化PD6 R/B引脚
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GPIO_Initure.Pin=GPIO_PIN_6;
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GPIO_Initure.Mode=GPIO_MODE_INPUT; //输入
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GPIO_Initure.Pull=GPIO_PULLUP; //上拉
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GPIO_Initure.Speed=GPIO_SPEED_HIGH; //高速
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HAL_GPIO_Init(GPIOD,&GPIO_Initure);
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//初始化PG9 NCE3引脚
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GPIO_Initure.Pin=GPIO_PIN_9;
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GPIO_Initure.Mode=GPIO_MODE_AF_PP; //输入
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GPIO_Initure.Pull=GPIO_NOPULL; //上拉
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GPIO_Initure.Speed=GPIO_SPEED_HIGH; //高速
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GPIO_Initure.Alternate=GPIO_AF12_FMC; //复用为FMC
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HAL_GPIO_Init(GPIOG,&GPIO_Initure);
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//初始化PD0,1,4,5,11,12,14,15
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GPIO_Initure.Pin=GPIO_PIN_0|GPIO_PIN_1|GPIO_PIN_4|GPIO_PIN_5|\
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GPIO_PIN_11|GPIO_PIN_12|GPIO_PIN_14|GPIO_PIN_15;
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GPIO_Initure.Pull=GPIO_NOPULL;
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HAL_GPIO_Init(GPIOD,&GPIO_Initure);
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//初始化PE7,8,9,10
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GPIO_Initure.Pin=GPIO_PIN_7|GPIO_PIN_8|GPIO_PIN_9|GPIO_PIN_10;
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HAL_GPIO_Init(GPIOE,&GPIO_Initure);
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}
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//读NAND状态
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//返回值:NAND状态值
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//bit0:0,成功;1,错误(编程/擦除/READ)
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//bit6:0,Busy;1,Ready
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static rt_bool_t read_status(rt_uint8_t cmd)
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{
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volatile rt_uint8_t value=0;
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SET_NAND_CMD(NAND_READSTA);//发送读状态命令
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value++;value++;value++;value++;value++; //加延时,防止-O2优化,导致的错误.
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value=*(volatile rt_uint8_t*)NAND_ADDRESS; //读取状态值
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switch (cmd)
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{
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case NAND_WRITE0:
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case NAND_ERASE1:
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if (value & 0x01) /* Erase/Program failure(1) or pass(0) */
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return (RT_FALSE);
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else
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return (RT_TRUE);
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case NAND_AREA_TRUE1: /* bit 5 and 6, Read busy(0) or ready(1) */
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return (RT_TRUE);
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default:
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break;
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}
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return (RT_FALSE);
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}
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static rt_err_t nand_MT29F4G08_readid(struct rt_mtd_nand_device *device)
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{
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rt_uint32_t id;
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SET_NAND_CMD(NAND_READID); //发送读取ID命令
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SET_NAND_ADD(0X00);
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GET_NAND_DAT(_device.id[0]);//ID一共有5个字节
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GET_NAND_DAT(_device.id[1]);
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GET_NAND_DAT(_device.id[2]);
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GET_NAND_DAT(_device.id[3]);
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GET_NAND_DAT(_device.id[4]);
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//镁光的NAND FLASH的ID一共5个字节,但是为了方便我们只取4个字节组成一个32位的ID值
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//根据NAND FLASH的数据手册,只要是镁光的NAND FLASH,那么一个字节ID的第一个字节都是0X2C
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//所以我们就可以抛弃这个0X2C,只取后面四字节的ID值。
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id=((rt_uint32_t)_device.id[1])<<24|((rt_uint32_t)_device.id[2])<<16|((rt_uint32_t)_device.id[3])<<8|_device.id[4];
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rt_kprintf("\nNAND ID: 0x%08X\n", id);
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return RT_EOK;
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}
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static rt_err_t nand_datacorrect(uint32_t generatedEcc, uint32_t readEcc, uint8_t *data)
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{
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#define ECC_MASK28 0x0FFFFFFF /* 28 valid ECC parity bits. */
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#define ECC_MASK 0x05555555 /* 14 ECC parity bits. */
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rt_uint32_t count, bitNum, byteAddr;
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rt_uint32_t mask;
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rt_uint32_t syndrome;
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rt_uint32_t eccP; /* 14 even ECC parity bits. */
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rt_uint32_t eccPn; /* 14 odd ECC parity bits. */
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syndrome = (generatedEcc ^ readEcc) & ECC_MASK28;
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if (syndrome == 0)
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return (RT_MTD_EOK); /* No errors in data. */
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eccPn = syndrome & ECC_MASK; /* Get 14 odd parity bits. */
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eccP = (syndrome >> 1) & ECC_MASK; /* Get 14 even parity bits. */
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if ((eccPn ^ eccP) == ECC_MASK) /* 1-bit correctable error ? */
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{
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bitNum = (eccP & 0x01) |
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((eccP >> 1) & 0x02) |
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((eccP >> 2) & 0x04);
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NAND_DEBUG("ECC bit %d\n",bitNum);
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byteAddr = ((eccP >> 6) & 0x001) |
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((eccP >> 7) & 0x002) |
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((eccP >> 8) & 0x004) |
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((eccP >> 9) & 0x008) |
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((eccP >> 10) & 0x010) |
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((eccP >> 11) & 0x020) |
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((eccP >> 12) & 0x040) |
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((eccP >> 13) & 0x080) |
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((eccP >> 14) & 0x100) |
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((eccP >> 15) & 0x200) |
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((eccP >> 16) & 0x400) ;
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data[ byteAddr ] ^= 1 << bitNum;
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return RT_MTD_EOK;
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}
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/* Count number of one's in the syndrome. */
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count = 0;
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mask = 0x00800000;
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while (mask)
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{
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if (syndrome & mask)
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count++;
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mask >>= 1;
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}
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if (count == 1) /* Error in the ECC itself. */
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return RT_MTD_EECC;
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return -RT_MTD_EECC; /* Unable to correct data. */
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#undef ECC_MASK
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#undef ECC_MASK24
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}
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static rt_err_t nand_MT29F4G08_readpage(struct rt_mtd_nand_device *device,
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rt_off_t page,
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rt_uint8_t *data,
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rt_uint32_t data_len,
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rt_uint8_t *spare,
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rt_uint32_t spare_len)
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{
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rt_uint32_t index;
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rt_uint32_t gecc, recc;
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rt_uint8_t tmp[4];
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rt_err_t result;
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rt_uint32_t i;
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page = page + device->block_start * device->pages_per_block;
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if (page/device->pages_per_block > device->block_end)
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{
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return -RT_MTD_EIO;
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}
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result = RT_MTD_EOK;
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rt_mutex_take(&_device.lock, RT_WAITING_FOREVER);
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if (data && data_len)
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{
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SET_NAND_CMD(NAND_AREA_A); //发送地址
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SET_NAND_ADD((rt_uint8_t)(0&0xFF));
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SET_NAND_ADD((rt_uint8_t)(0>>8));
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SET_NAND_ADD((rt_uint8_t)(page & 0xFF));
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SET_NAND_ADD((rt_uint8_t)(page >> 8));
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SET_NAND_ADD((rt_uint8_t)(page >> 16));
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SET_NAND_CMD(NAND_AREA_TRUE1);
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//下面两行代码是等待R/B引脚变为低电平,其实主要起延时作用的,等待NAND操作R/B引脚。因为我们是通过
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//将STM32的NWAIT引脚(NAND的R/B引脚)配置为普通IO,代码中通过读取NWAIT引脚的电平来判断NAND是否准备
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//就绪的。这个也就是模拟的方法,所以在速度很快的时候有可能NAND还没来得及操作R/B引脚来表示NAND的忙
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//闲状态,就读取了R/B引脚,这个时候肯定会出错的,事实上确实是会出错!
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NAND_WaitRB(0); //等待RB=0
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//下面2行代码是真正判断NAND是否准备好的
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NAND_WaitRB(1); //等待RB=1
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FMC_NAND_ECC_Enable(NAND_Handler.Instance,FMC_NAND_BANK3);
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for (i = 0; i < data_len; i ++)
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{
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GET_NAND_DAT(data[i]);
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}
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gecc = FMC_NAND_GetECC(NAND_Handler.Instance,(uint32_t*)&gecc,FMC_NAND_BANK3,10);
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if (data_len == PAGE_DATA_SIZE)
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{
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for (index = 0; index < ECC_SIZE; index ++)
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{
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GET_NAND_DAT(tmp[index]);
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}
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if (spare && spare_len)
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{
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for (i = ECC_SIZE; i < spare_len; i ++)
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{
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GET_NAND_DAT(spare[i]);
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}
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rt_memcpy(spare, tmp , ECC_SIZE);
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}
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recc = (tmp[3] << 24) | (tmp[2] << 16) | (tmp[1] << 8) | tmp[0];
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if (recc != 0xFFFFFFFF && gecc != 0)
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result = nand_datacorrect(gecc, recc, data);
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if (result != RT_MTD_EOK)
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NAND_DEBUG("page: %d, gecc %X, recc %X>",page, gecc, recc);
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goto _exit;
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}
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}
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if (spare && spare_len)
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{
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SET_NAND_CMD(NAND_AREA_A); //发送地址
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SET_NAND_ADD((rt_uint8_t)(PAGE_DATA_SIZE&0xFF));
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SET_NAND_ADD((rt_uint8_t)(PAGE_DATA_SIZE>>8));
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SET_NAND_ADD((rt_uint8_t)(page & 0xFF));
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SET_NAND_ADD((rt_uint8_t)(page >> 8));
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SET_NAND_ADD((rt_uint8_t)(page >> 16));
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SET_NAND_CMD(NAND_AREA_TRUE1);
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//下面两行代码是等待R/B引脚变为低电平,其实主要起延时作用的,等待NAND操作R/B引脚。因为我们是通过
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//将STM32的NWAIT引脚(NAND的R/B引脚)配置为普通IO,代码中通过读取NWAIT引脚的电平来判断NAND是否准备
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//就绪的。这个也就是模拟的方法,所以在速度很快的时候有可能NAND还没来得及操作R/B引脚来表示NAND的忙
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//闲状态,就读取了R/B引脚,这个时候肯定会出错的,事实上确实是会出错!
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NAND_WaitRB(0); //等待RB=0
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//下面2行代码是真正判断NAND是否准备好的
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NAND_WaitRB(1); //等待RB=1
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for (i = 0; i < spare_len; i ++)
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{
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GET_NAND_DAT(spare[i]);
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}
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}
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_exit:
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rt_mutex_release(&_device.lock);
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return (result);
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}
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static rt_err_t nand_MT29F4G08_writepage(struct rt_mtd_nand_device *device,
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rt_off_t page,
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const rt_uint8_t *data,
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rt_uint32_t data_len,
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const rt_uint8_t *spare,
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rt_uint32_t spare_len)
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{
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rt_err_t result;
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rt_uint32_t gecc;
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rt_uint32_t i;
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page = page + device->block_start * device->pages_per_block;
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if (page/device->pages_per_block > device->block_end)
|
||
{
|
||
return -RT_MTD_EIO;
|
||
}
|
||
|
||
result = RT_MTD_EOK;
|
||
rt_mutex_take(&_device.lock, RT_WAITING_FOREVER);
|
||
|
||
if (data && data_len)
|
||
{
|
||
SET_NAND_CMD(NAND_WRITE0); //发送地址
|
||
SET_NAND_ADD((rt_uint8_t)(0&0xFF));
|
||
SET_NAND_ADD((rt_uint8_t)(0>>8));
|
||
SET_NAND_ADD((rt_uint8_t)(page & 0xFF));
|
||
SET_NAND_ADD((rt_uint8_t)(page >> 8));
|
||
SET_NAND_ADD((rt_uint8_t)(page >> 16));
|
||
|
||
FMC_NAND_ECC_Enable(NAND_Handler.Instance,FMC_NAND_BANK3);
|
||
|
||
for (i = 0; i < data_len; i ++)
|
||
{
|
||
SET_NAND_DAT(data[i]);
|
||
}
|
||
gecc = FMC_NAND_GetECC(NAND_Handler.Instance,(uint32_t*)&gecc,FMC_NAND_BANK3,10);
|
||
|
||
FMC_NAND_ECC_Disable(NAND_Handler.Instance,FMC_NAND_BANK3);
|
||
|
||
if (data_len == PAGE_DATA_SIZE)
|
||
{
|
||
SET_NAND_DAT((uint8_t)gecc);
|
||
SET_NAND_DAT((uint8_t)(gecc >> 8));
|
||
SET_NAND_DAT((uint8_t)(gecc >> 16));
|
||
SET_NAND_DAT((uint8_t)(gecc >> 24));
|
||
|
||
if (spare && spare_len)
|
||
{
|
||
for (i = ECC_SIZE; i < spare_len; i ++)
|
||
{
|
||
SET_NAND_DAT(spare[i]);
|
||
}
|
||
}
|
||
|
||
}
|
||
SET_NAND_CMD(NAND_WRITE_TURE1);
|
||
if(wait_for_ready()!=NSTA_READY)
|
||
{
|
||
nand_reset();
|
||
result = -RT_MTD_EIO;//失败
|
||
}
|
||
goto _exit;
|
||
}
|
||
|
||
if (spare && spare_len)
|
||
{
|
||
SET_NAND_CMD(NAND_WRITE0); //发送地址
|
||
SET_NAND_ADD((rt_uint8_t)(PAGE_DATA_SIZE&0xFF));
|
||
SET_NAND_ADD((rt_uint8_t)(PAGE_DATA_SIZE>>8));
|
||
SET_NAND_ADD((rt_uint8_t)(page & 0xFF));
|
||
SET_NAND_ADD((rt_uint8_t)(page >> 8));
|
||
SET_NAND_ADD((rt_uint8_t)(page >> 16));
|
||
|
||
if (spare && spare_len)
|
||
for (i = ECC_SIZE; i < spare_len; i ++)
|
||
{
|
||
SET_NAND_DAT(spare[i]);
|
||
}
|
||
SET_NAND_CMD(NAND_WRITE_TURE1);
|
||
if(wait_for_ready()!=NSTA_READY)
|
||
{
|
||
nand_reset();
|
||
result = -RT_MTD_EIO;//失败
|
||
}
|
||
}
|
||
|
||
_exit:
|
||
rt_mutex_release(&_device.lock);
|
||
|
||
return (result);
|
||
|
||
}
|
||
|
||
static rt_err_t nand_MT29F4G08_eraseblock(struct rt_mtd_nand_device *device,
|
||
rt_uint32_t block)
|
||
{
|
||
unsigned int blockPage;
|
||
rt_err_t result;
|
||
/* add the start blocks */
|
||
block = block + device->block_start;
|
||
blockPage = (block << 6);
|
||
result = RT_MTD_EOK;
|
||
|
||
rt_mutex_take(&_device.lock, RT_WAITING_FOREVER);
|
||
|
||
SET_NAND_CMD(NAND_ERASE0); //发送地址
|
||
SET_NAND_ADD((rt_uint8_t)blockPage);
|
||
SET_NAND_ADD((rt_uint8_t)(blockPage>>8));
|
||
SET_NAND_ADD((rt_uint8_t)(blockPage>>16));
|
||
SET_NAND_CMD(NAND_ERASE1);
|
||
if(wait_for_ready()!=NSTA_READY)
|
||
{
|
||
nand_reset();
|
||
result = -RT_MTD_EIO;//失败
|
||
}
|
||
rt_mutex_release(&_device.lock);
|
||
return result;
|
||
}
|
||
|
||
static rt_err_t nand_MT29F4G08_pagecopy(struct rt_mtd_nand_device *device,
|
||
rt_off_t src_page,
|
||
rt_off_t dst_page)
|
||
{
|
||
rt_err_t result = RT_MTD_EOK;
|
||
rt_uint32_t source_block=0,dest_block=0;
|
||
src_page = src_page + device->block_start * device->pages_per_block;
|
||
dst_page = dst_page + device->block_start * device->pages_per_block;
|
||
//判断源页和目的页是否在同一个plane中
|
||
source_block=src_page/device->pages_per_block;
|
||
dest_block=dst_page/device->pages_per_block;
|
||
if((source_block%2)!=(dest_block%2))return RT_MTD_ESRC; //不在同一个plane内
|
||
|
||
SET_NAND_CMD(NAND_MOVEDATA_CMD0);//发送命令0X00
|
||
SET_NAND_ADD((rt_uint8_t)(0&0xFF)); //发送源页地址
|
||
SET_NAND_ADD((rt_uint8_t)(0>>8));
|
||
SET_NAND_ADD((rt_uint8_t)(src_page & 0xFF));
|
||
SET_NAND_ADD((rt_uint8_t)(src_page >> 8));
|
||
SET_NAND_ADD((rt_uint8_t)(src_page >> 16));
|
||
SET_NAND_CMD(NAND_MOVEDATA_CMD1);//发送命令0X35
|
||
|
||
//下面两行代码是等待R/B引脚变为低电平,其实主要起延时作用的,等待NAND操作R/B引脚。因为我们是通过
|
||
//将STM32的NWAIT引脚(NAND的R/B引脚)配置为普通IO,代码中通过读取NWAIT引脚的电平来判断NAND是否准备
|
||
//就绪的。这个也就是模拟的方法,所以在速度很快的时候有可能NAND还没来得及操作R/B引脚来表示NAND的忙
|
||
//闲状态,结果我们就读取了R/B引脚,这个时候肯定会出错的,事实上确实是会出错!大家也可以将下面两行
|
||
//代码换成延时函数,只不过这里我们为了效率所以没有用延时函数。
|
||
result=NAND_WaitRB(0); //等待RB=0
|
||
if(result)return -RT_MTD_EIO; //超时退出
|
||
//下面2行代码是真正判断NAND是否准备好的
|
||
result=NAND_WaitRB(1); //等待RB=1
|
||
if(result)return -RT_MTD_EIO; //超时退出
|
||
|
||
SET_NAND_CMD(NAND_MOVEDATA_CMD2);//发送命令0X85
|
||
SET_NAND_ADD((rt_uint8_t)(0&0xFF)); //发送目的页地址
|
||
SET_NAND_ADD((rt_uint8_t)(0>>8));
|
||
SET_NAND_ADD((rt_uint8_t)(dst_page & 0xFF));
|
||
SET_NAND_ADD((rt_uint8_t)(dst_page >> 8));
|
||
SET_NAND_ADD((rt_uint8_t)(dst_page >> 16));
|
||
SET_NAND_CMD(NAND_MOVEDATA_CMD3);//发送命令0X10
|
||
|
||
if(wait_for_ready()!=NSTA_READY)
|
||
{
|
||
nand_reset();
|
||
return -RT_MTD_EIO;//失败
|
||
}
|
||
|
||
return RT_MTD_EOK;
|
||
|
||
|
||
}
|
||
|
||
static rt_err_t nand_MT29F4G08_checkblock(struct rt_mtd_nand_device* device, rt_uint32_t block)
|
||
{
|
||
return (RT_MTD_EOK);
|
||
}
|
||
|
||
static rt_err_t nand_MT29F4G08_markbad(struct rt_mtd_nand_device* device, rt_uint32_t block)
|
||
{
|
||
return (RT_MTD_EOK);
|
||
}
|
||
|
||
static const struct rt_mtd_nand_driver_ops ops =
|
||
{
|
||
nand_MT29F4G08_readid,
|
||
nand_MT29F4G08_readpage,
|
||
nand_MT29F4G08_writepage,
|
||
nand_MT29F4G08_pagecopy,
|
||
nand_MT29F4G08_eraseblock,
|
||
nand_MT29F4G08_checkblock,
|
||
nand_MT29F4G08_markbad,
|
||
};
|
||
static struct rt_mtd_nand_device _partition[1];
|
||
|
||
int nand_MT29F4G08_hw_init(void)
|
||
{
|
||
NAND_Init();
|
||
rt_mutex_init(&_device.lock, "nand", RT_IPC_FLAG_FIFO);
|
||
/* register nand0 */
|
||
_partition[0].page_size = PAGE_DATA_SIZE;
|
||
_partition[0].pages_per_block = PAGES_PER_BLOCK;
|
||
_partition[0].plane_num = 2;
|
||
_partition[0].oob_size = PAGE_OOB_SIZE;
|
||
_partition[0].oob_free = PAGE_OOB_SIZE - ((PAGE_DATA_SIZE) * 3 / 256);
|
||
_partition[0].block_start = 0;
|
||
_partition[0].block_end = 4095;
|
||
|
||
_partition[0].block_total = _partition[0].block_end - _partition[0].block_start;
|
||
_partition[0].ops = &ops;
|
||
|
||
rt_mtd_nand_register_device("nand0", &_partition[0]);
|
||
nand_MT29F4G08_readid(&_partition[0]);
|
||
|
||
return RT_EOK;
|
||
}
|
||
INIT_BOARD_EXPORT(nand_MT29F4G08_hw_init);
|