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git-svn-id: https://rt-thread.googlecode.com/svn/trunk@1130 bbd45198-f89e-11dd-88c7-29a3b14d5316
This commit is contained in:
wangjiyang 2010-11-28 08:25:31 +00:00
parent 61f7e58f7a
commit dc5e5b7fa6
8 changed files with 2462 additions and 0 deletions

200
bsp/evb4020/src/rtconfig.h Executable file
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/* RT-Thread config file */
#ifndef __RTTHREAD_CFG_H__
#define __RTTHREAD_CFG_H__
/* RT_NAME_MAX*/
#define RT_NAME_MAX 8
/* RT_ALIGN_SIZE*/
#define RT_ALIGN_SIZE 4
/* PRIORITY_MAX */
#define RT_THREAD_PRIORITY_MAX 256
/* Tick per Second */
#define RT_TICK_PER_SECOND 100
/* SECTION: RT_DEBUG */
/* Thread Debug */
#define RT_DEBUG
/* #define RT_THREAD_DEBUG */
#define RT_USING_OVERFLOW_CHECK
/* Using Hook */
#define RT_USING_HOOK
/* Using Software Timer */
#define RT_USING_TIMER_SOFT
#define RT_TIMER_THREAD_PRIO 8
#define RT_TIMER_THREAD_STACK_SIZE 512
#define RT_TIMER_TICK_PER_SECOND 10
/* SECTION: IPC */
/* Using Semaphore */
#define RT_USING_SEMAPHORE
/* Using Mutex */
#define RT_USING_MUTEX
/* Using Event */
#define RT_USING_EVENT
/* Using MailBox */
#define RT_USING_MAILBOX
/* Using Message Queue */
#define RT_USING_MESSAGEQUEUE
/* SECTION: Memory Management */
/* Using Memory Pool Management*/
#define RT_USING_MEMPOOL
/* Using Dynamic Heap Management */
#define RT_USING_HEAP
/* Using Small MM */
/* #define RT_USING_SMALL_MEM */
/* Using SLAB Allocator */
#define RT_USING_SLAB
/* SECTION: Device System */
/* Using Device System */
#define RT_USING_DEVICE
/* SECTION: Console options */
/* the buffer size of console */
#define RT_CONSOLEBUF_SIZE 128
/* SECTION: finsh, a C-Express shell */
/* Using FinSH as Shell*/
#define RT_USING_FINSH
#define FINSH_USING_SYMTAB
#define FINSH USING DESCRIPTION
/* SECTION: a runtime libc library */
/* a runtime libc library */
/* #define RT_USING_NEWLIB */
/* SECTION: a mini libc */
/* SECTION: C++ support */
/* Using C++ support */
/* #define RT_USING_CPLUSPLUS */
/* SECTION: Device filesystem support */
/* using DFS support */
#define RT_USING_DFS
#define RT_USING_DFS_ELMFATFS
/* #define RT_USING_DFS_YAFFS2 */
/* #define DFS_USING_WORKDIR */
/* the max number of mounted filesystem */
#define DFS_FILESYSTEMS_MAX 2
/* the max number of opened files */
#define DFS_FD_MAX 16
/* the max number of cached sector */
#define DFS_CACHE_MAX_NUM 4
/* SECTION: lwip, a lighwight TCP/IP protocol stack */
/* Using lighweight TCP/IP protocol stack */
//#define RT_USING_LWIP
#define RT_LWIP_DNS
/* Trace LwIP protocol */
/* #define RT_LWIP_DEBUG */
/* Enable ICMP protocol */
#define RT_LWIP_ICMP
/* Enable IGMP protocol */
#define RT_LWIP_IGMP
/* Enable UDP protocol */
#define RT_LWIP_UDP
/* Enable TCP protocol */
#define RT_LWIP_TCP
/* the number of simulatenously active TCP connections*/
#define RT_LWIP_TCP_PCB_NUM 5
/* TCP sender buffer space */
#define RT_LWIP_TCP_SND_BUF 1024*10
/* TCP receive window. */
#define RT_LWIP_TCP_WND 1024
/* Enable SNMP protocol */
/* #define RT_LWIP_SNMP */
/* Using DHCP */
/* #define RT_LWIP_DHCP */
#define RT_LWIP_DNS
/* ip address of target */
#define RT_LWIP_IPADDR0 192
#define RT_LWIP_IPADDR1 168
#define RT_LWIP_IPADDR2 1
#define RT_LWIP_IPADDR3 30
/* gateway address of target */
#define RT_LWIP_GWADDR0 192
#define RT_LWIP_GWADDR1 168
#define RT_LWIP_GWADDR2 1
#define RT_LWIP_GWADDR3 1
/* mask address of target */
#define RT_LWIP_MSKADDR0 255
#define RT_LWIP_MSKADDR1 255
#define RT_LWIP_MSKADDR2 255
#define RT_LWIP_MSKADDR3 0
/* the number of blocks for pbuf */
#define RT_LWIP_PBUF_NUM 16
/* thread priority of tcpip thread */
#define RT_LWIP_TCPTHREAD_PRIORITY 128
/* mail box size of tcpip thread to wait for */
#define RT_LWIP_TCPTHREAD_MBOX_SIZE 8
/* thread stack size of tcpip thread */
#define RT_LWIP_TCPTHREAD_STACKSIZE 4096
/* thread priority of ethnetif thread */
#define RT_LWIP_ETHTHREAD_PRIORITY 144
/* mail box size of ethnetif thread to wait for */
#define RT_LWIP_ETHTHREAD_MBOX_SIZE 32
/* thread stack size of ethnetif thread */
#define RT_LWIP_ETHTHREAD_STACKSIZE 1024
/* SECTION: RTGUI support */
/* using RTGUI support */
#define RT_USING_RTGUI
/* name length of RTGUI object */
#define RTGUI_NAME_MAX 16
/* support 16 weight font */
#define RTGUI_USING_FONT16
/* support 16 weight font */
#define RTGUI_USING_FONT12
/* support Chinese font */
#define RTGUI_USING_FONTHZ
/* use DFS as file interface */
#define RTGUI_USING_DFS_FILERW
/* use font file as Chinese font */
/* #define RTGUI_USING_HZ_FILE */
/* use Chinese bitmap font */
#define RTGUI_USING_HZ_BMP
/* use small size in RTGUI */
/* #define RTGUI_USING_SMALL_SIZE */
/* use mouse cursor */
/* #define RTGUI_USING_MOUSE_CURSOR */
#endif

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bsp/evb4020/src/sdcard.c Executable file
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/*
* File : sdcard.c
* This file is part of RT-Thread RTOS
* COPYRIGHT (C) 2006, 2007, RT-Thread Develop Team
*
* The license and distribution terms for this file may be
* found in the file LICENSE in this distribution or at
* http://www.rt-thread.org/license/LICENSE
*
* Change Logs:
* Date Author Notes
* 2007-12-02 Yi.Qiu the first version
* 2010-01-01 Bernard Modify for mini2440
* 2010-10-13 Wangmeng Added sep4020 support
*/
#include "sdcard.h"
#include <dfs_config.h>
volatile rt_int32_t RCA;
#ifdef RT_USING_DFS
/* RT-Thread Device Driver Interface */
#include <rtthread.h>
#include <dfs_fs.h>
/*GLOBAL SD DEVICE PONITER*/
static struct sd_device *ptr_sddev;
static rt_uint8_t gsec_buf[SECTOR_SIZE];
#define USE_TIMEOUT
/*This file is to power on/off the SEP4020 SDC*/
/**
* This function will power on/off the SEP4020 SDC
*
* @param sd_ctl: 0/power on; 1/power off
* @return none
*
*/
static void sd_pwr(int sd_ctl)
{
if (sd_ctl)
{
*(RP)GPIO_PORTA_SEL |= 0x0200;
*(RP)GPIO_PORTA_DIR &= (~0x0200);
*(RP)GPIO_PORTA_DATA |= 0x0200;
}
else
{
*(RP)GPIO_PORTA_SEL |= 0x0200;
*(RP)GPIO_PORTA_DIR &= (~0x0200);
*(RP)GPIO_PORTA_DATA &= (~0x0200);
}
}
/*a nop operation to delay*/
static void delay (U32 j)
{
U32 i;
for (i=0;i<j;i++)
{};
}
/*
* Send the command to set the data transfer mode
* @param cmd:the command to sent
* @param arg:the argument of the command
* @param mode:SDC transfer mode
* @param blk_len:the block size of each data
* @param num:number of blocks
* @param mask:sdc interrupt mask
*/
static rt_err_t cmd_data(U16 cmd,U32 arg,U16 mode,U16 blk_len,U16 num,U16 mask)
{
U32 i;
#ifdef USE_TIMEOUT
U32 to = 10000;
#endif
*(RP)SDC_CLOCK_CONTROL = 0Xff00; //配置SD时钟512分频,关闭SD 时钟
*(RP)SDC_CLOCK_CONTROL = 0Xff04; //打开SD时钟512分频,开启SD 时钟
*(RP)SDC_INTERRUPT_STATUS_MASK = mask; //中断状态屏蔽寄存器赋值
*(RP)SDC_TRANSFER_MODE = mode; //传输模式选择寄存器赋值
*(RP)SDC_BLOCK_SIZE = blk_len; //数据块长度寄存器赋值
*(RP)SDC_BLOCK_COUNT = num; //数据块数目寄存器赋值
*(RP)SDC_ARGUMENT = arg; //命令参数寄存器赋值
*(RP)SDC_COMMAND = cmd; //命令控制寄存器赋值
delay(10);
i = *(RP)SDC_INTERRUPT_STATUS & 0x1000;
while(i != 0x1000) //判断:是否命令发送完毕,并且收到响应
{
i = *(RP)SDC_INTERRUPT_STATUS & 0x1000;
#ifdef USE_TIMEOUT
to --;
if(!to)
{
EOUT("%s TIMEOUT\n",__FUNCTION__);
return RT_ETIMEOUT;
}
#endif
}
delay(160);
#ifdef USE_TIMEOUT
//DBOUT("cmd_data TO is %d\n",to);
#endif
return *(RP)SDC_RESPONSE0; //返回命令反馈信息
}
static rt_err_t cmd_response(U16 Cmd,U32 Arg,U16 TransMode,U16 BlkLen,U16 Nob,U16 IntMask)
{
U32 i;
#ifdef USE_TIMEOUT
U32 to = 50000;
#endif
*(RP)SDC_CLOCK_CONTROL=0Xff00; //配置SD时钟
*(RP)SDC_CLOCK_CONTROL=0Xff04; //打开SD时钟
*(RP)SDC_INTERRUPT_STATUS_MASK=IntMask; //中断状态屏蔽寄存器赋值
*(RP)SDC_TRANSFER_MODE=TransMode; //传输模式选择寄存器赋值
*(RP)SDC_BLOCK_SIZE=BlkLen; //数据块长度寄存器赋值
*(RP)SDC_BLOCK_COUNT=Nob; //数据块数目寄存器赋值
*(RP)SDC_ARGUMENT=Arg; //命令参数寄存器赋值
*(RP)SDC_COMMAND=Cmd; //命令控制寄存器赋值
delay(10);
i = *(RP)SDC_INTERRUPT_STATUS & 0x1040;
while(i != 0x1040) //判断:命令发送完毕,并且收到响应,数据传输完毕。这三项是否已经都完成。
{
i = *(RP)SDC_INTERRUPT_STATUS & 0x1040;
#ifdef USE_TIMEOUT
to--;
if(!to)
{
EOUT("%s Timeout\n",__FUNCTION__);
return RT_ETIMEOUT;
}
#endif
}
//DBOUT("cmd_response TO is %d\n",to);
delay(100);
return RT_EOK; //返回命令反馈信息
}
static rt_err_t cmd_wait(U16 Cmd,U32 Arg,U16 IntMask )
{
int i;
#ifdef USE_TIMEOUT
U32 to=200000;
#endif
*(RP)SDC_CLOCK_CONTROL=0Xff00; //配置SD时钟
*(RP)SDC_CLOCK_CONTROL=0Xff04; //打开SD时钟
*(RP)SDC_COMMAND=Cmd; //命令控制寄存器赋值
*(RP)SDC_INTERRUPT_STATUS_MASK=IntMask; //中断状态屏蔽寄存器赋值
*(RP)SDC_ARGUMENT=Arg; //命令参数寄存器赋值
i = *(RP)SDC_INTERRUPT_STATUS & 0x1000;
while(i != 0x1000) //判断:是否命令发送完毕,并且收到响应
{
i = *(RP)SDC_INTERRUPT_STATUS & 0x1000;
#ifdef USE_TIMEOUT
to--;
if(!to)
{
EOUT("%s Timeout\n",__FUNCTION__);
return RT_ETIMEOUT;
}
#endif
}
//DBOUT("cmd_wait TO is %d\n",to);
delay(10);
return RT_EOK; //返回命令反馈信息以及数值1
}
/**
* This function will set a hook function, which will be invoked when a memory
* block is allocated from heap memory.
*
* @param hook the hook function
*/
static rt_err_t sd_init(void)
{
rt_err_t err;
#ifdef USE_TIMEOUT
rt_uint32_t to=1000;
#endif
sd_pwr(1);
*(RP)SDC_SOFTWARE_RESET=0x0; //触发软复位,对其写0是进行reset
delay(200);
*(RP)SDC_SOFTWARE_RESET=0x1; //不触发软复位
delay(200);
cmd_wait(0x08,0x0,0xfff); //CMD0命令发送使能
do
{
err = cmd_wait(0x6ea,0x0,0xfff); //CMD55,以切换到ACMD命令
#ifdef USE_TIMEOUT
if(err != RT_EOK)
{
EOUT("cmd_wait err in %s\n",__FUNCTION__);
return RT_ETIMEOUT;
}
#endif
delay(3);
err = cmd_wait(0x52a,0x80ff8000,0xfff); //ACMD41向SD控制器发送命令等待SD控制器确认收到命令
if(err != RT_EOK)
{
EOUT("cmd_wait err in %s\n",__FUNCTION__);
return RT_ETIMEOUT;
}
#ifdef USE_TIMEOUT
to--;
if(!to)
{
EOUT("%s timeout\n",__FUNCTION__);
return RT_ETIMEOUT;
}
#endif
}while(*(RP)SDC_RESPONSE0<0X80008000);
#ifdef USE_TIMEOUT
//DBOUT("%s TO is %d\n",__FUNCTION__,to);
#endif
cmd_data(0x49,0X0,0X0,0x0,0x0,0Xfff);//CMD2发送CID
cmd_data(0x6a,0X0,0X0,0x0,0x0,0Xfff);//CMD3询问卡片发出新的相关地址
RCA = *(RP)SDC_RESPONSE0;
cmd_data(0xea,RCA,0X0,0x0,0x0,0Xfff);//CMD7设置选择性的相关参数
return RT_EOK;
}
/**
* This function will set a hook function, which will be invoked when a memory
* block is allocated from heap memory.
*
* @param hook the hook function
*/
static rt_err_t sd_readblock(rt_uint32_t address, rt_uint8_t* buf)
{
U32 complete,i;
rt_uint8_t temp;
rt_err_t err;
UNUSED rt_uint32_t discard;
#ifdef USE_TIMEOUT
rt_uint32_t to = 10;
#endif
//rt_kprintf("in readblock:%x\n",address);
//Clear all the errors & interrups
*(RP)DMAC_INTINTERRCLR |= 0x1;
*(RP)DMAC_INTINTERRCLR &= ~0x1;
*(RP)DMAC_INTTCCLEAR |= 0x1;
*(RP)DMAC_INTTCCLEAR &= ~0x1;
/*Clear read fifo*/
*(RP)(SDC_INTERRUPT_STATUS_MASK) = ~(0x1<<9); //don't mask fifo empty
while((*(RP)SDC_INTERRUPT_STATUS)&0x200 != 0x200)
discard = *(RP)SDC_READ_BUFER_ACCESS;
/*DMAC2,word,size=0x80*/
*(RP)DMAC_C2SRCADDR = SDC_READ_BUFER_ACCESS;
*(RP)DMAC_C2DESTADDR = (rt_uint32_t)buf;
*(RP)DMAC_C2CONTROL =0x20249b;
*(RP)DMAC_C2CONFIGURATION = 0x38d;
err = cmd_wait(0x6ea,RCA,0xfff);
if(err != RT_EOK)
{
rt_set_errno(err);
return err;
}
err = cmd_wait(0xca,0x2,0xfff);
if(err != RT_EOK)
{
rt_set_errno(err);
return err;
}
err = cmd_response(0x22e,address,0X1,0x0200,0x1,0Xfff); //CMD17 4bit mode
if(err != RT_EOK)
{
rt_set_errno(err);
return err;
}
complete = *(RP)SDC_INTERRUPT_STATUS;
/*CRC*/
if((complete |0xfffffffd) !=0xfffffffd)
{
rt_kprintf("CRC ERROR!!!\n");
complete = *(RP)SDC_INTERRUPT_STATUS;
}
while(((*(RP)( DMAC_INTTCSTATUS)) & 0x4) != 0x4 )
{
delay(10);
#ifdef USE_TIMEOUT
to--;
if(!to)
{
EOUT("%s TIMEOUT\n",__FUNCTION__);
return RT_ETIMEOUT;
}
#endif
}
#ifdef USE_TIMEOUT
//DBOUT("%s timeout is %d\n",__FUNCTION__,to);
#endif
/*for the buf is big-endian we must reverse it*/
for(i = 0;i<0x80;i++)
{
temp = buf[0];
buf[0] = buf[3];
buf[3] = temp;
temp = buf[1];
buf[1] = buf[2];
buf[2] = temp;
buf += 4;
}
return RT_EOK;
}
static rt_uint8_t sd_readmultiblock(rt_uint32_t address, rt_uint8_t* buf,rt_uint32_t size)
{
rt_int32_t index;
rt_uint8_t status=RT_EOK;
for(index = 0;index < size;index++)
{
status = sd_readblock(address+index*SECTOR_SIZE,buf+index*SECTOR_SIZE);
if(status!=RT_EOK)
break;
}
return status;
}
/**
* This function will set a hook function, which will be invoked when a memory
* block is allocated from heap memory.
*
* @param hook the hook function
*/
static rt_uint8_t sd_writeblock(rt_uint32_t address, rt_uint8_t* buf)
{
U32 complete;
rt_uint8_t temp;
rt_uint8_t *ptr = buf;
rt_err_t err;
#ifdef USE_TIMEOUT
rt_uint32_t to = 10;
#endif
int i;
rt_kprintf("in writeblock:%x\n",address);
/*for the buf is big-endian we must reverse it*/
for(i = 0;i<0x80;i++)
{
temp = ptr[0];
ptr[0] = ptr[3];
ptr[3] = temp;
temp = ptr[1];
ptr[1] = ptr[2];
ptr[2] = temp;
ptr += 4;
}
//Clear all the errors & interrups
*(RP)DMAC_INTINTERRCLR |= 0x1;
*(RP)DMAC_INTINTERRCLR &= ~0x1;
*(RP)DMAC_INTTCCLEAR |= 0x1;
*(RP)DMAC_INTTCCLEAR &= ~0x1;
//***********************配置DMA2进行四位写*************************
*(RP)DMAC_C2SRCADDR = (U32)buf; //DMAC道2源地址赋为0x30200000
*(RP)DMAC_C2DESTADDR = SDC_WRITE_BUFER_ACCESS; //DMAC道2目的地址赋为发送FIFO的地址
*(RP)DMAC_C2CONTROL = 0x20149b; //传输尺寸0x080,源地址增加目的地址不增加传输宽度32bit传输的数目4
*(RP)DMAC_C2CONFIGURATION = 0x380b; //不屏蔽传输中断,屏蔽错误中断,通道使能,传输类型:存储器到外设
err = cmd_wait(0x6ea,RCA,0xfff); //CMD55以切换到ACMD命令
if(err != RT_EOK)
{
rt_set_errno(err);
return err;
}
err = cmd_wait(0xca,0x2,0xfff); //ACMD6定义数据线宽度48 位短反馈,无数据传输
if(err != RT_EOK)
{
rt_set_errno(err);
return err;
}
err = cmd_response(0x30e,address,0X3,0x0200,0x1,0Xfff); //CMD24 1bit mode
if(err != RT_EOK)
{
rt_set_errno(err);
return err;
}
complete = *(RP)SDC_INTERRUPT_STATUS;
if((complete |0xfffffffe) !=0xfffffffe) //响应超时错误
{
//printf("CRC ERROR");
complete = *(RP)SDC_INTERRUPT_STATUS;
}
while(((*(RP)( DMAC_INTTCSTATUS)) & 0x4) != 0x4 )
{
delay(10);
#ifdef USE_TIMEOUT
to--;
if(!to)
{
EOUT("%s TIMEOUT\n",__FUNCTION__);
}
#endif
}
#ifdef USE_TIMEOUT
//DBOUT("%s timeout is %d\n",__FUNCTION__,to);
#endif
return RT_EOK;
}
/**
* This function will set a hook function, which will be invoked when a memory
* block is allocated from heap memory.
*
* @param hook the hook function
*/
static rt_err_t rt_sdcard_init(rt_device_t dev)
{
return 0;
}
/**
* This function will set a hook function, which will be invoked when a memory
* block is allocated from heap memory.
*
* @param hook the hook function
*/
static rt_err_t rt_sdcard_open(rt_device_t dev, rt_uint16_t oflag)
{
return 0;
}
/**
* This function will set a hook function, which will be invoked when a memory
* block is allocated from heap memory.
*
* @param hook the hook function
*/
static rt_err_t rt_sdcard_close(rt_device_t dev)
{
return 0;
}
/**
* This function will set a hook function, which will be invoked when a memory
* block is allocated from heap memory.
*
* @param hook the hook function
*/
static rt_err_t rt_sdcard_control(rt_device_t dev, rt_uint8_t cmd, void *args)
{
rt_kprintf("cmd = %d\n",cmd);
RT_ASSERT(dev != RT_NULL);
if (cmd == RT_DEVICE_CTRL_BLK_GETGEOME)
{
struct rt_device_blk_geometry *geometry;
geometry = (struct rt_device_blk_geometry *)args;
if (geometry == RT_NULL) return -RT_ERROR;
geometry->bytes_per_sector = 512;
geometry->block_size = 0x200000;
//if (CardType == SDIO_HIGH_CAPACITY_SD_CARD)
// geometry->sector_count = (SDCardInfo.SD_csd.DeviceSize + 1) * 1024;
//else
geometry->sector_count = 0x200000;//SDCardInfo.CardCapacity/SDCardInfo.CardBlockSize;
}
return RT_EOK;
}
/**
* This function will set a hook function, which will be invoked when a memory
* block is allocated from heap memory.
*
* @param hook the hook function
*/
static rt_size_t rt_sdcard_read(rt_device_t dev, rt_off_t pos, void* buffer, rt_size_t size)
{
rt_uint32_t retry = 3;
rt_uint8_t status;
rt_uint32_t index;
///*take the semaphore
struct dfs_partition *part = (struct dfs_partition *)dev->private;
rt_sem_take(part->lock, RT_WAITING_FOREVER);
while(retry--)
{
if (((rt_uint32_t)buffer % 4 != 0) ||
((rt_uint32_t)buffer > 0x20080000))
{
for(index = 0;index < size;index++)
{
status = sd_readblock((part->offset + pos) * SECTOR_SIZE,ptr_sddev->sec_buf);
if(status != RT_EOK)
break;
rt_memcpy((rt_uint8_t *)buffer + (index * SECTOR_SIZE),ptr_sddev->sec_buf,SECTOR_SIZE);
}
}
else
{
for(index = 0;index<size;index++)
{
status = sd_readblock((pos) * SECTOR_SIZE,(rt_uint8_t*)buffer + index * SECTOR_SIZE);
if(status != RT_EOK)
break;
}
}
}
rt_sem_release(part->lock);
if (status == RT_EOK)
return size;
rt_kprintf("read failed: %d, buffer 0x%08x\n", status, buffer);
return 0;
}
/**
* This function will set a hook function, which will be invoked when a memory
* block is allocated from heap memory.
*
* @param hook the hook function
*/
static rt_size_t rt_sdcard_write (rt_device_t dev, rt_off_t pos, const void* buffer, rt_size_t size)
{
int i;
rt_uint8_t status;
struct dfs_partition *part = (struct dfs_partition *)dev->private;
if ( dev == RT_NULL )
{
rt_set_errno(-DFS_STATUS_EINVAL);
return 0;
}
rt_sem_take(part->lock, RT_WAITING_FOREVER);
if (((rt_uint32_t)buffer % 4 != 0) ||
((rt_uint32_t)buffer > 0x20080000))
{
rt_uint32_t index;
for(index=0;index<size;index++)
{
rt_memcpy(ptr_sddev->sec_buf, ((rt_uint8_t*)buffer + index * SECTOR_SIZE), SECTOR_SIZE);
status = sd_writeblock((part->offset + index + pos)*SECTOR_SIZE,ptr_sddev->sec_buf);
}
}
else
{
for(i=0;i<size;i++)
{
status = sd_writeblock((part->offset + i + pos)*SECTOR_SIZE,
(rt_uint8_t*)((rt_uint8_t*)buffer + i * SECTOR_SIZE));
if (status != RT_EOK) break;
}
}
rt_sem_release(part->lock);
if (status == RT_EOK)
return size;
rt_kprintf("read failed: %d, buffer 0x%08x\n", status, buffer);
return 0;
}
rt_err_t rt_hw_sdcard_exit()
{
if(ptr_sddev->device != RT_NULL)
rt_free(ptr_sddev->device);
if(ptr_sddev->part != RT_NULL)
rt_free(ptr_sddev->part);
if(ptr_sddev != RT_NULL)
rt_free(ptr_sddev);
return RT_EOK;
}
/**
* This function will init sd card
*
* @param void
*/
rt_err_t rt_hw_sdcard_init()
{
/*For test*/
rt_err_t err;
rt_int32_t i;
char dname[4];
char sname[8];
/*Initialize structure*/
ptr_sddev = (struct sd_device*)rt_malloc(sizeof(struct sd_device));
if(ptr_sddev == RT_NULL)
{
EOUT("Failed to allocate sdcard device structure\n");
return RT_ENOMEM;
}
/*sdcard intialize*/
err = sd_init();
if(err != RT_EOK)
goto FAIL2;
/*set sector buffer*/
ptr_sddev->sec_buf = gsec_buf;
ptr_sddev->buf_size = SECTOR_SIZE;
ptr_sddev->sdc = (struct sd_c*)SD_BASE;
//DBOUT("allocate partition sector buffer OK!");
err = sd_readblock(0,ptr_sddev->sec_buf);
if(err != RT_EOK)
{
EOUT("read first block error\n");
goto FAIL2;
}
/*sdcard driver initialize*/
ptr_sddev->part = (struct dfs_partition*)rt_malloc(4 * sizeof(struct dfs_partition));
if(ptr_sddev->part == RT_NULL)
{
EOUT("allocate partition failed\n");
err = RT_ENOMEM;
goto FAIL2;
}
/*alloc device buffer*/
ptr_sddev->device = (struct rt_device*)rt_malloc(4 * sizeof(struct rt_device));
if(ptr_sddev->device == RT_NULL)
{
EOUT("allocate device failed\n");
err = RT_ENOMEM;
goto FAIL1;
}
ptr_sddev->part_num = 0;
err = sd_readblock(0,ptr_sddev->sec_buf);
if(err != RT_EOK)
{
EOUT("Read block 0 to initialize ERROR\n");
goto FAIL1;
}
for(i=0; i<4; i++)
{
/* get the first partition */
err = dfs_filesystem_get_partition(&(ptr_sddev->part[i]), ptr_sddev->sec_buf, i);
if (err == RT_EOK)
{
rt_snprintf(dname, 4, "sd%d", i);
rt_snprintf(sname, 8, "sem_sd%d", i);
ptr_sddev->part[i].lock = rt_sem_create(sname, 1, RT_IPC_FLAG_FIFO);
/* register sdcard device */
ptr_sddev->device[i].init = rt_sdcard_init;
ptr_sddev->device[i].open = rt_sdcard_open;
ptr_sddev->device[i].close = rt_sdcard_close;
ptr_sddev->device[i].read = rt_sdcard_read;
ptr_sddev->device[i].write = rt_sdcard_write;
ptr_sddev->device[i].control = rt_sdcard_control;
ptr_sddev->device[i].private= &ptr_sddev->part[i];
err = rt_device_register(&ptr_sddev->device[i], dname,
RT_DEVICE_FLAG_RDWR | RT_DEVICE_FLAG_REMOVABLE | RT_DEVICE_FLAG_STANDALONE);
if(err == RT_EOK)
ptr_sddev->part_num++;
}
else
{
if(i == 0)
{
/* there is no partition table */
ptr_sddev->part[0].offset = 0;
ptr_sddev->part[0].size = 0;
ptr_sddev->part[0].lock = rt_sem_create("sem_sd0", 1, RT_IPC_FLAG_FIFO);
/* register sdcard device */
ptr_sddev->device[0].init = rt_sdcard_init;
ptr_sddev->device[0].open = rt_sdcard_open;
ptr_sddev->device[0].close = rt_sdcard_close;
ptr_sddev->device[0].read = rt_sdcard_read;
ptr_sddev->device[0].write = rt_sdcard_write;
ptr_sddev->device[0].control = rt_sdcard_control;
ptr_sddev->device[0].private= &ptr_sddev->part[0];
err = rt_device_register(&ptr_sddev->device[0], "sd0",
RT_DEVICE_FLAG_RDWR | RT_DEVICE_FLAG_REMOVABLE | RT_DEVICE_FLAG_STANDALONE);
if(err == RT_EOK)
ptr_sddev->part_num++;
break;
}
}
}
if(ptr_sddev->part_num == 0)
goto FAIL0;
return err;
FAIL0:
rt_free(ptr_sddev->device);
ptr_sddev->device = RT_NULL;
FAIL1:
rt_free(ptr_sddev->part);
ptr_sddev->part = RT_NULL;
FAIL2:
rt_free(ptr_sddev);
ptr_sddev = RT_NULL;
return err;
}
#endif

51
bsp/evb4020/src/sdcard.h Executable file
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#ifndef __SDCARD_H
#define __SDCARD_H
#include <rtthread.h>
#ifdef RT_USING_DFS
#include <sep4020.h>
#define INICLK 300000
#define SDCLK 24000000 //PCLK=49.392MHz
#define MMCCLK 15000000 //PCLK=49.392MHz
/*struct of the SDC*/
struct sd_c
{
__IO rt_uint32_t clk_ctl;
__IO rt_uint32_t soft_rst;
__IO rt_uint32_t arg;
__IO rt_uint32_t cmd;
__IO rt_uint32_t blk_sz;
__IO rt_uint32_t blk_cnt;
__IO rt_uint32_t trans_mode;
__O rt_uint32_t response0;
__O rt_uint32_t response1;
__O rt_uint32_t response2;
__O rt_uint32_t response3;
__IO rt_uint32_t rd_to_ctl;
__IO rt_uint32_t int_stat;
__IO rt_uint32_t int_stat_mask;
__O rt_uint32_t rx_fifo;
__I rt_uint32_t tx_fifo;
};
/*sdcard driver structure*/
struct sd_device
{
struct rt_device *device; /*rt_device*/
struct sd_c *sdc; /*SDCARD register*/
struct dfs_partition *part; /*dfs partitions*/
rt_uint8_t *sec_buf; /*sdcard buffer*/
rt_uint32_t part_num; /*partiont numbers*/
rt_uint32_t buf_size; /*buffer size*/
};
#endif
#endif

867
bsp/evb4020/src/sep4020.h Executable file
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#ifndef __SEP4020_H
#define __SEP4020_H
#include <rtthread.h>
/*Core definations*/
#define SVCMODE
#define Mode_USR 0x10
#define Mode_FIQ 0x11
#define Mode_IRQ 0x12
#define Mode_SVC 0x13
#define Mode_ABT 0x17
#define Mode_UND 0x1B
#define Mode_SYS 0x1F
/*
*
*/
#define ESRAM_BASE 0x04000000
#define INTC_BASE 0x10000000
#define PMU_BASE 0x10001000
#define RTC_BASE 0x10002000
#define WD_BASE 0x10002000
#define TIMER_BASE 0x10003000
#define PWM_BASE 0x10004000
#define UART0_BASE 0X10005000
#define UART1_BASE 0X10006000
#define UART2_BASE 0X10007000
#define UART3_BASE 0X10008000
#define SSI_BASE 0X10009000
#define I2S_BASE 0x1000A000
#define MMC_BASE 0x1000B000
#define SD_BASE 0x1000B000
#define SMC0_BASE 0x1000C000
#define SMC1_BASE 0x1000D000
#define USBD_BASE 0x1000E000
#define GPIO_BASE 0x1000F000
#define EMI_BASE 0x11000000
#define DMAC_BASE 0x11001000
#define LCDC_BASE 0x11002000
#define MAC_BASE 0x11003000
#define AMBA_BASE 0x11005000
/*
* INTC模块
* : 0x10000000
*/
#define INTC_IER (INTC_BASE+0X000) /* IRQ中断允许寄存器 */
#define INTC_IMR (INTC_BASE+0X008) /* IRQ中断屏蔽寄存器 */
#define INTC_IFR (INTC_BASE+0X010) /* IRQ软件强制中断寄存器 */
#define INTC_IRSR (INTC_BASE+0X018) /* IRQ未处理中断状态寄存器 */
#define INTC_ISR (INTC_BASE+0X020) /* IRQ中断状态寄存器 */
#define INTC_IMSR (INTC_BASE+0X028) /* IRQ屏蔽中断状态寄存器 */
#define INTC_IFSR (INTC_BASE+0X030) /* IRQ中断最终状态寄存器 */
#define INTC_FIER (INTC_BASE+0X0C0) /* FIQ中断允许寄存器 */
#define INTC_FIMR (INTC_BASE+0X0C4) /* FIQ中断屏蔽寄存器 */
#define INTC_FIFR (INTC_BASE+0X0C8) /* FIQ软件强制中断寄存器 */
#define INTC_FIRSR (INTC_BASE+0X0CC) /* FIQ未处理中断状态寄存器 */
#define INTC_FISR (INTC_BASE+0X0D0) /* FIQ中断状态寄存器 */
#define INTC_FIFSR (INTC_BASE+0X0D4) /* FIQ中断最终状态寄存器 */
#define INTC_IPLR (INTC_BASE+0X0D8) /* IRQ中断优先级寄存器 */
#define INTC_ICR1 (INTC_BASE+0X0DC) /* IRQ内部中断优先级控制寄存器1 */
#define INTC_ICR2 (INTC_BASE+0X0E0) /* IRQ内部中断优先级控制寄存器2 */
#define INTC_EXICR1 (INTC_BASE+0X0E4) /* IRQ外部中断优先级控制寄存器1 */
#define INTC_EXICR2 (INTC_BASE+0X0E8) /* IRQ外部中断优先级控制寄存器2 */
/*
* PMU模块
* : 0x10001000
*/
#define PMU_PLTR (PMU_BASE+0X000) /* PLL的稳定过渡时间 */
#define PMU_PMCR (PMU_BASE+0X004) /* 系统主时钟PLL的控制寄存器 */
#define PMU_PUCR (PMU_BASE+0X008) /* USB时钟PLL的控制寄存器 */
#define PMU_PCSR (PMU_BASE+0X00C) /* 内部模块时钟源供给的控制寄存器 */
#define PMU_PDSLOW (PMU_BASE+0X010) /* SLOW状态下时钟的分频因子 */
#define PMU_PMDR (PMU_BASE+0X014) /* 芯片工作模式寄存器 */
#define PMU_RCTR (PMU_BASE+0X018) /* Reset控制寄存器 */
#define PMU_CLRWAKUP (PMU_BASE+0X01C) /* WakeUp清除寄存器 */
/*
* RTC模块
* : 0x10002000
*/
#define RTC_STA_YMD (RTC_BASE+0X000) /* 年, 月, 日计数寄存器 */
#define RTC_STA_HMS (RTC_BASE+0X004) /* 小时, 分钟, 秒寄存器 */
#define RTC_ALARM_ALL (RTC_BASE+0X008) /* 定时月, 日, 时, 分寄存器 */
#define RTC_CTR (RTC_BASE+0X00C) /* 控制寄存器 */
#define RTC_INT_EN (RTC_BASE+0X010) /* 中断使能寄存器 */
#define RTC_INT_STS (RTC_BASE+0X014) /* 中断状态寄存器 */
#define RTC_SAMP (RTC_BASE+0X018) /* 采样周期寄存器 */
#define RTC_WD_CNT (RTC_BASE+0X01C) /* Watch-Dog计数值寄存器 */
#define RTC_WD_SEV (RTC_BASE+0X020) /* Watch-Dog服务寄存器 */
#define RTC_CONFIG_CHECK (RTC_BASE+0X024) /* 配置时间确认寄存器 (在配置时间之前先写0xaaaaaaaa) */
#define RTC_KEY0 (RTC_BASE+0X02C) /* 密钥寄存器 */
/*
* TIMER模块
* : 0x10003000
*/
#define TIMER_T1LCR (TIMER_BASE+0X000) /* 通道1加载计数寄存器 */
#define TIMER_T1CCR (TIMER_BASE+0X004) /* 通道1当前计数值寄存器 */
#define TIMER_T1CR (TIMER_BASE+0X008) /* 通道1控制寄存器 */
#define TIMER_T1ISCR (TIMER_BASE+0X00C) /* 通道1中断状态清除寄存器 */
#define TIMER_T1IMSR (TIMER_BASE+0X010) /* 通道1中断屏蔽状态寄存器 */
#define TIMER_T2LCR (TIMER_BASE+0X020) /* 通道2加载计数寄存器 */
#define TIMER_T2CCR (TIMER_BASE+0X024) /* 通道2当前计数值寄存器 */
#define TIMER_T2CR (TIMER_BASE+0X028) /* 通道2控制寄存器 */
#define TIMER_T2ISCR (TIMER_BASE+0X02C) /* 通道2中断状态清除寄存器 */
#define TIMER_T2IMSR (TIMER_BASE+0X030) /* 通道2中断屏蔽状态寄存器 */
#define TIMER_T3LCR (TIMER_BASE+0X040) /* 通道3加载计数寄存器 */
#define TIMER_T3CCR (TIMER_BASE+0X044) /* 通道3当前计数值寄存器 */
#define TIMER_T3CR (TIMER_BASE+0X048) /* 通道3控制寄存器 */
#define TIMER_T3ISCR (TIMER_BASE+0X04C) /* 通道3中断状态清除寄存器 */
#define TIMER_T3IMSR (TIMER_BASE+0X050) /* 通道3中断屏蔽状态寄存器 */
#define TIMER_T3CAPR (TIMER_BASE+0X054) /* 通道3捕获寄存器 */
#define TIMER_T4LCR (TIMER_BASE+0X060) /* 通道4加载计数寄存器 */
#define TIMER_T4CCR (TIMER_BASE+0X064) /* 通道4当前计数值寄存器 */
#define TIMER_T4CR (TIMER_BASE+0X068) /* 通道4控制寄存器 */
#define TIMER_T4ISCR (TIMER_BASE+0X06C) /* 通道4中断状态清除寄存器 */
#define TIMER_T4IMSR (TIMER_BASE+0X070) /* 通道4中断屏蔽状态寄存器 */
#define TIMER_T4CAPR (TIMER_BASE+0X074) /* 通道4捕获寄存器 */
#define TIMER_T5LCR (TIMER_BASE+0X080) /* 通道5加载计数寄存器 */
#define TIMER_T5CCR (TIMER_BASE+0X084) /* 通道5当前计数值寄存器 */
#define TIMER_T5CR (TIMER_BASE+0X088) /* 通道5控制寄存器 */
#define TIMER_T5ISCR (TIMER_BASE+0X08C) /* 通道5中断状态清除寄存器 */
#define TIMER_T5IMSR (TIMER_BASE+0X090) /* 通道5中断屏蔽状态寄存器 */
#define TIMER_T5CAPR (TIMER_BASE+0X094) /* 通道5捕获寄存器 */
#define TIMER_T6LCR (TIMER_BASE+0X0A0) /* 通道6加载计数寄存器 */
#define TIMER_T6CCR (TIMER_BASE+0X0A4) /* 通道6当前计数值寄存器 */
#define TIMER_T6CR (TIMER_BASE+0X0A8) /* 通道6控制寄存器 */
#define TIMER_T6ISCR (TIMER_BASE+0X0AC) /* 通道6中断状态清除寄存器 */
#define TIMER_T6IMSR (TIMER_BASE+0X0B0) /* 通道6中断屏蔽状态寄存器 */
#define TIMER_T6CAPR (TIMER_BASE+0X0B4) /* 通道6捕获寄存器 */
#define TIMER_T7LCR (TIMER_BASE+0X0C0) /* 通道7加载计数寄存器 */
#define TIMER_T7CCR (TIMER_BASE+0X0C4) /* 通道7当前计数值寄存器 */
#define TIMER_T7CR (TIMER_BASE+0X0C8) /* 通道7控制寄存器 */
#define TIMER_T7ISCR (TIMER_BASE+0X0CC) /* 通道7中断状态清除寄存器 */
#define TIMER_T7IMSR (TIMER_BASE+0X0D0) /* 通道7中断屏蔽状态寄存器 */
#define TIMER_T8LCR (TIMER_BASE+0X0E0) /* 通道8加载计数寄存器 */
#define TIMER_T8CCR (TIMER_BASE+0X0E4) /* 通道8当前计数值寄存器 */
#define TIMER_T8CR (TIMER_BASE+0X0E8) /* 通道8控制寄存器 */
#define TIMER_T8ISCR (TIMER_BASE+0X0EC) /* 通道8中断状态清除寄存器 */
#define TIMER_T8IMSR (TIMER_BASE+0X0F0) /* 通道8中断屏蔽状态寄存器 */
#define TIMER_T9LCR (TIMER_BASE+0X100) /* 通道9加载计数寄存器 */
#define TIMER_T9CCR (TIMER_BASE+0X104) /* 通道9当前计数值寄存器 */
#define TIMER_T9CR (TIMER_BASE+0X108) /* 通道9控制寄存器 */
#define TIMER_T9ISCR (TIMER_BASE+0X10C) /* 通道9中断状态清除寄存器 */
#define TIMER_T9IMSR (TIMER_BASE+0X110) /* 通道9中断屏蔽状态寄存器 */
#define TIMER_T10LCR (TIMER_BASE+0X120) /* 通道10加载计数寄存器 */
#define TIMER_T10CCR (TIMER_BASE+0X124) /* 通道10当前计数值寄存器 */
#define TIMER_T10CR (TIMER_BASE+0X128) /* 通道10控制寄存器 */
#define TIMER_T10ISCR (TIMER_BASE+0X12C) /* 通道10中断状态清除寄存器 */
#define TIMER_T10IMSR (TIMER_BASE+0X130) /* 通道10中断屏蔽状态寄存器 */
#define TIMER_TIMSR (TIMER_BASE+0X140) /* TIMER中断屏蔽状态寄存器 */
#define TIMER_TISCR (TIMER_BASE+0X144) /* TIMER中断状态清除寄存器 */
#define TIMER_TISR (TIMER_BASE+0X148) /* TIMER中断状态寄存器 */
/*
* PWM模块
* : 0x10004000
*/
#define PWM0_CTRL (PWM_BASE+0X000) /* PWM0控制寄存器 */
#define PWM0_DIV (PWM_BASE+0X004) /* PWM0分频寄存器 */
#define PWM0_PERIOD (PWM_BASE+0X008) /* PWM0周期寄存器 */
#define PWM0_DATA (PWM_BASE+0X00C) /* PWM0数据寄存器 */
#define PWM0_CNT (PWM_BASE+0X010) /* PWM0计数寄存器 */
#define PWM0_STATUS (PWM_BASE+0X014) /* PWM0状态寄存器 */
#define PWM1_CTRL (PWM_BASE+0X020) /* PWM1控制寄存器 */
#define PWM1_DIV (PWM_BASE+0X024) /* PWM1分频寄存器 */
#define PWM1_PERIOD (PWM_BASE+0X028) /* PWM1周期寄存器 */
#define PWM1_DATA (PWM_BASE+0X02C) /* PWM1数据寄存器 */
#define PWM1_CNT (PWM_BASE+0X030) /* PWM1计数寄存器 */
#define PWM1_STATUS (PWM_BASE+0X034) /* PWM1状态寄存器 */
#define PWM2_CTRL (PWM_BASE+0X040) /* PWM2控制寄存器 */
#define PWM2_DIV (PWM_BASE+0X044) /* PWM2分频寄存器 */
#define PWM2_PERIOD (PWM_BASE+0X048) /* PWM2周期寄存器 */
#define PWM2_DATA (PWM_BASE+0X04C) /* PWM2数据寄存器 */
#define PWM2_CNT (PWM_BASE+0X050) /* PWM2计数寄存器 */
#define PWM2_STATUS (PWM_BASE+0X054) /* PWM2状态寄存器 */
#define PWM3_CTRL (PWM_BASE+0X060) /* PWM3控制寄存器 */
#define PWM3_DIV (PWM_BASE+0X064) /* PWM3分频寄存器 */
#define PWM3_PERIOD (PWM_BASE+0X068) /* PWM3周期寄存器 */
#define PWM3_DATA (PWM_BASE+0X06C) /* PWM3数据寄存器 */
#define PWM3_CNT (PWM_BASE+0X070) /* PWM3计数寄存器 */
#define PWM3_STATUS (PWM_BASE+0X074) /* PWM3状态寄存器 */
#define PWM_INTMASK (PWM_BASE+0X080) /* PWM中断屏蔽寄存器 */
#define PWM_INT (PWM_BASE+0X084) /* PWM中断寄存器 */
#define PWM_ENABLE (PWM_BASE+0X088) /* PWM使能寄存器 */
/*
* UART0模块
* : 0x10005000
*/
#define UART0_DLBL (UART0_BASE+0X000) /* 波特率设置低八位寄存器 */
#define UART0_RXFIFO (UART0_BASE+0X000) /* 接收FIFO */
#define UART0_TXFIFO (UART0_BASE+0X000) /* 发送FIFO */
#define UART0_DLBH (UART0_BASE+0X004) /* 波特率设置高八位寄存器 */
#define UART0_IER (UART0_BASE+0X004) /* 中断使能寄存器 */
#define UART0_IIR (UART0_BASE+0X008) /* 中断识别寄存器 */
#define UART0_FCR (UART0_BASE+0X008) /* FIFO控制寄存器 */
#define UART0_LCR (UART0_BASE+0X00C) /* 行控制寄存器 */
#define UART0_MCR (UART0_BASE+0X010) /* Modem控制寄存器 */
#define UART0_LSR (UART0_BASE+0X014) /* 行状态寄存器 */
#define UART0_MSR (UART0_BASE+0X018) /* Modem状态寄存器 */
/*
* UART1模块
* : 0x10006000
*/
#define UART1_DLBL (UART1_BASE+0X000) /* 波特率设置低八位寄存器 */
#define UART1_RXFIFO (UART1_BASE+0X000) /* 接收FIFO */
#define UART1_TXFIFO (UART1_BASE+0X000) /* 发送FIFO */
#define UART1_DLBH (UART1_BASE+0X004) /* 波特率设置高八位寄存器 */
#define UART1_IER (UART1_BASE+0X004) /* 中断使能寄存器 */
#define UART1_IIR (UART1_BASE+0X008) /* 中断识别寄存器 */
#define UART1_FCR (UART1_BASE+0X008) /* FIFO控制寄存器 */
#define UART1_LCR (UART1_BASE+0X00C) /* 行控制寄存器 */
#define UART1_MCR (UART1_BASE+0X010) /* Modem控制寄存器 */
#define UART1_LSR (UART1_BASE+0X014) /* 行状态寄存器 */
#define UART1_MSR (UART1_BASE+0X018) /* Modem状态寄存器 */
/*
* UART2模块
* : 0x10007000
*/
#define UART2_DLBL (UART2_BASE+0X000) /* 波特率设置低八位寄存器 */
#define UART2_RXFIFO (UART2_BASE+0X000) /* 接收FIFO */
#define UART2_TXFIFO (UART2_BASE+0X000) /* 发送FIFO */
#define UART2_DLBH (UART2_BASE+0X004) /* 波特率设置高八位寄存器 */
#define UART2_IER (UART2_BASE+0X004) /* 中断使能寄存器 */
#define UART2_IIR (UART2_BASE+0X008) /* 中断识别寄存器 */
#define UART2_FCR (UART2_BASE+0X008) /* FIFO控制寄存器 */
#define UART2_LCR (UART2_BASE+0X00C) /* 行控制寄存器 */
#define UART2_MCR (UART2_BASE+0X010) /* Modem控制寄存器 */
#define UART2_LSR (UART2_BASE+0X014) /* 行状态寄存器 */
#define UART2_MSR (UART2_BASE+0X018) /* Modem状态寄存器 */
/*
* UART3模块
* : 0x10008000
*/
#define UART3_DLBL (UART3_BASE+0X000) /* 波特率设置低八位寄存器 */
#define UART3_RXFIFO (UART3_BASE+0X000) /* 接收FIFO */
#define UART3_TXFIFO (UART3_BASE+0X000) /* 发送FIFO */
#define UART3_DLBH (UART3_BASE+0X004) /* 波特率设置高八位寄存器 */
#define UART3_IER (UART3_BASE+0X004) /* 中断使能寄存器 */
#define UART3_IIR (UART3_BASE+0X008) /* 中断识别寄存器 */
#define UART3_FCR (UART3_BASE+0X008) /* FIFO控制寄存器 */
#define UART3_LCR (UART3_BASE+0X00C) /* 行控制寄存器 */
#define UART3_MCR (UART3_BASE+0X010) /* Modem控制寄存器 */
#define UART3_LSR (UART3_BASE+0X014) /* 行状态寄存器 */
#define UART3_MSR (UART3_BASE+0X018) /* Modem状态寄存器 */
/*
* SSI模块
* : 0x10009000
*/
#define SSI_CONTROL0 (SSI_BASE+0X000) /* 控制寄存器0 */
#define SSI_CONTROL1 (SSI_BASE+0X004) /* 控制寄存器1 */
#define SSI_SSIENR (SSI_BASE+0X008) /* SSI使能寄存器 */
#define SSI_MWCR (SSI_BASE+0X00C) /* Microwire控制寄存器 */
#define SSI_SER (SSI_BASE+0X010) /* 从设备使能寄存器 */
#define SSI_BAUDR (SSI_BASE+0X014) /* 波特率设置寄存器 */
#define SSI_TXFTLR (SSI_BASE+0X018) /* 发送FIFO阈值寄存器 */
#define SSI_RXFTLR (SSI_BASE+0X01C) /* 接收FIFO阈值寄存器 */
#define SSI_TXFLR (SSI_BASE+0X020) /* 发送FIFO状态寄存器 */
#define SSI_RXFLR (SSI_BASE+0X024) /* 接收FIFO状态寄存器 */
#define SSI_SR (SSI_BASE+0X028) /* 状态寄存器 */
#define SSI_IMR (SSI_BASE+0X02C) /* 中断屏蔽寄存器 */
#define SSI_ISR (SSI_BASE+0X030) /* 中断最终状态寄存器 */
#define SSI_RISR (SSI_BASE+0X034) /* 中断原始状态寄存器 */
#define SSI_TXOICR (SSI_BASE+0X038) /* 发送FIFO上溢中断清除寄存器 */
#define SSI_RXOICR (SSI_BASE+0X03C) /* 接收FIFO上溢中断清除寄存器 */
#define SSI_RXUICR (SSI_BASE+0X040) /* 接收FIFO下溢中断清除寄存器 */
#define SSI_ICR (SSI_BASE+0X02C) /* 中断清除寄存器 */
#define SSI_DMACR (SSI_BASE+0X04C) /* DMA控制寄存器 */
#define SSI_DMATDLR (SSI_BASE+0X050) /* DMA发送状态寄存器 */
#define SSI_DMARDLR (SSI_BASE+0X054) /* DMA接收状态寄存器 */
#define SSI_DR (SSI_BASE+0X060) /* 数据寄存器 */
/*
* I2S模块
* : 0x1000A000
*/
#define I2S_CTRL (I2S_BASE+0X000) /* I2S控制寄存器 */
#define I2S_DATA (I2S_BASE+0X004) /* I2S数据寄存器 */
#define I2S_INT (I2S_BASE+0X008) /* I2S中断寄存器 */
#define I2S_STATUS (I2S_BASE+0X00C) /* I2S状态寄存器 */
/*
* SD模块
* : 0x1000B000
*/
#define SDC_CLOCK_CONTROL (SD_BASE+0x00) /* SDIO时钟控制寄存器 */
#define SDC_SOFTWARE_RESET (SD_BASE+0X04) /* SDIO软件复位寄存器 */
#define SDC_ARGUMENT (SD_BASE+0X08) /* SDIO命令参数寄存器 */
#define SDC_COMMAND (SD_BASE+0X0C) /* SDIO命令控制寄存器 */
#define SDC_BLOCK_SIZE (SD_BASE+0X10) /* SDIO数据块长度寄存器 */
#define SDC_BLOCK_COUNT (SD_BASE+0X14) /* SDIO数据块数目寄存器 */
#define SDC_TRANSFER_MODE (SD_BASE+0X18) /* SDIO传输模式选择寄存器 */
#define SDC_RESPONSE0 (SD_BASE+0X1c) /* SDIO响应寄存器0 */
#define SDC_RESPONSE1 (SD_BASE+0X20) /* SDIO响应寄存器1 */
#define SDC_RESPONSE2 (SD_BASE+0X24) /* SDIO响应寄存器2 */
#define SDC_RESPONSE3 (SD_BASE+0X28) /* SDIO响应寄存器3 */
#define SDC_READ_TIMEOUT_CONTROL (SD_BASE+0X2c) /* SDIO读超时控制寄存器 */
#define SDC_INTERRUPT_STATUS (SD_BASE+0X30) /* SDIO中断状态寄存器 */
#define SDC_INTERRUPT_STATUS_MASK (SD_BASE+0X34) /* SDIO中断状态屏蔽寄存器 */
#define SDC_READ_BUFER_ACCESS (SD_BASE+0X38) /* SDIO接收FIFO */
#define SDC_WRITE_BUFER_ACCESS (SD_BASE+0X3c) /* SDIO发送FIFO */
/*
* SMC0模块
* : 0x1000C000
*/
#define SMC0_CTRL (SMC0_BASE+0X000) /* SMC0控制寄存器 */
#define SMC0_INT (SMC0_BASE+0X004) /* SMC0中断寄存器 */
#define SMC0_FD (SMC0_BASE+0X008) /* SMC0基本单元时间寄存器 */
#define SMC0_CT (SMC0_BASE+0X00C) /* SMC0字符传输时间寄存器 */
#define SMC0_BT (SMC0_BASE+0X010) /* SMC0块传输时间寄存器 */
/*
* SMC1模块
* : 0x1000D000
*/
#define SMC1_CTRL (SMC1_BASE+0X000) /* SMC1控制寄存器 */
#define SMC1_INT (SMC1_BASE+0X004) /* SMC1中断寄存器 */
#define SMC1_FD (SMC1_BASE+0X008) /* SMC1基本单元时间寄存器 */
#define SMC1_CT (SMC1_BASE+0X00C) /* SMC1字符传输时间寄存器 */
#define SMC1_BT (SMC1_BASE+0X010) /* SMC1块传输时间寄存器 */
/*
* USBD模块
* : 0x1000E000
*/
#define USBD_PROTOCOLINTR (USBD_BASE+0X000) /* USB协议中断寄存器 */
#define USBD_INTRMASK (USBD_BASE+0X004) /* USB中断屏蔽寄存器 */
#define USBD_INTRCTRL (USBD_BASE+0X008) /* USB中断类型控制寄存器 */
#define USBD_EPINFO (USBD_BASE+0X00C) /* USB活动端点状态寄存器 */
#define USBD_BCONFIGURATIONVALUE (USBD_BASE+0X010) /* SET_CCONFIGURATION记录 */
#define USBD_BMATTRIBUTES (USBD_BASE+0X014) /* 当前配置属性寄存器 */
#define USBD_DEVSPEED (USBD_BASE+0X018) /* 当前设备工作速度寄存器 */
#define USBD_FRAMENUMBER (USBD_BASE+0X01C) /* 记录当前SOF包内的帧号 */
#define USBD_EPTRANSACTIONS0 (USBD_BASE+0X020) /* 记录下次要求的传输次数 */
#define USBD_EPTRANSACTIONS1 (USBD_BASE+0X024) /* 记录下次要求的传输次数 */
#define USBD_APPIFUPDATE (USBD_BASE+0X028) /* 接口号快速更新寄存器 */
#define USBD_CFGINTERFACE0 (USBD_BASE+0X02C) /* 记录接口的值 */
#define USBD_CFGINTERFACE1 (USBD_BASE+0X030) /* 记录接口的值 */
#define USBD_CFGINTERFACE2 (USBD_BASE+0X034) /* 记录接口的值 */
#define USBD_CFGINTERFACE3 (USBD_BASE+0X038) /* 记录接口的值 */
#define USBD_CFGINTERFACE4 (USBD_BASE+0X03C) /* 记录接口的值 */
#define USBD_CFGINTERFACE5 (USBD_BASE+0X040) /* 记录接口的值 */
#define USBD_CFGINTERFACE6 (USBD_BASE+0X044) /* 记录接口的值 */
#define USBD_CFGINTERFACE7 (USBD_BASE+0X048) /* 记录接口的值 */
#define USBD_CFGINTERFACE8 (USBD_BASE+0X04C) /* 记录接口的值 */
#define USBD_CFGINTERFACE9 (USBD_BASE+0X050) /* 记录接口的值 */
#define USBD_CFGINTERFACE10 (USBD_BASE+0X054) /* 记录接口的值 */
#define USBD_CFGINTERFACE11 (USBD_BASE+0X058) /* 记录接口的值 */
#define USBD_CFGINTERFACE12 (USBD_BASE+0X05C) /* 记录接口的值 */
#define USBD_CFGINTERFACE13 (USBD_BASE+0X060) /* 记录接口的值 */
#define USBD_CFGINTERFACE14 (USBD_BASE+0X064) /* 记录接口的值 */
#define USBD_CFGINTERFACE15 (USBD_BASE+0X068) /* 记录接口的值 */
#define USBD_CFGINTERFACE16 (USBD_BASE+0X06C) /* 记录接口的值 */
#define USBD_CFGINTERFACE17 (USBD_BASE+0X070) /* 记录接口的值 */
#define USBD_CFGINTERFACE18 (USBD_BASE+0X074) /* 记录接口的值 */
#define USBD_CFGINTERFACE19 (USBD_BASE+0X078) /* 记录接口的值 */
#define USBD_CFGINTERFACE20 (USBD_BASE+0X07C) /* 记录接口的值 */
#define USBD_CFGINTERFACE21 (USBD_BASE+0X080) /* 记录接口的值 */
#define USBD_CFGINTERFACE22 (USBD_BASE+0X084) /* 记录接口的值 */
#define USBD_CFGINTERFACE23 (USBD_BASE+0X088) /* 记录接口的值 */
#define USBD_CFGINTERFACE24 (USBD_BASE+0X08C) /* 记录接口的值 */
#define USBD_CFGINTERFACE25 (USBD_BASE+0X090) /* 记录接口的值 */
#define USBD_CFGINTERFACE26 (USBD_BASE+0X094) /* 记录接口的值 */
#define USBD_CFGINTERFACE27 (USBD_BASE+0X098) /* 记录接口的值 */
#define USBD_CFGINTERFACE28 (USBD_BASE+0X09C) /* 记录接口的值 */
#define USBD_CFGINTERFACE29 (USBD_BASE+0X0A0) /* 记录接口的值 */
#define USBD_CFGINTERFACE30 (USBD_BASE+0X0A4) /* 记录接口的值 */
#define USBD_CFGINTERFACE31 (USBD_BASE+0X0A8) /* 记录接口的值 */
#define USBD_PKTPASSEDCTRL (USBD_BASE+0X0AC) /* 记录成功接收的包数 */
#define USBD_PKTDROPPEDCTRL (USBD_BASE+0X0B0) /* 记录丢失的包数 */
#define USBD_CRCERRCTRL (USBD_BASE+0X0B4) /* 记录CRC错误的包数 */
#define USBD_BITSTUFFERRCTRL (USBD_BASE+0X0B8) /* 记录位填充错误的包数 */
#define USBD_PIDERRCTRL (USBD_BASE+0X0BC) /* 记录PID错误的包数 */
#define USBD_FRAMINGERRCTL (USBD_BASE+0X0C0) /* 记录有SYNC和EOP的包数 */
#define USBD_TXPKTCTRL (USBD_BASE+0X0C4) /* 记录发送包的数量 */
#define USBD_STATCTRLOV (USBD_BASE+0X0C8) /* 记录统计寄存器溢出情况 */
#define USBD_TXLENGTH (USBD_BASE+0X0CC) /* 记录每次IN传输事务包长度 */
#define USBD_RXLENGTH (USBD_BASE+0X0D0) /* 记录OUT传输事务包长度 */
#define USBD_RESUME (USBD_BASE+0X0D4) /* USB唤醒寄存器 */
#define USBD_READFLAG (USBD_BASE+0X0D8) /* 读异步状态寄存器标志 */
#define USBD_RECEIVETYPE (USBD_BASE+0X0DC) /* 传输状态寄存器 */
#define USBD_APPLOCK (USBD_BASE+0X0E0) /* 锁信号寄存器 */
#define USBD_EP0OUTADDR (USBD_BASE+0X100) /* 端点0端点号和方向 */
#define USBD_EP0OUTBMATTR (USBD_BASE+0X104) /* 端点0类型寄存器 */
#define USBD_EP0OUTMAXPKTSIZE (USBD_BASE+0X108) /* 端点0最大包尺寸寄存器 */
#define USBD_EP0OUTIFNUM (USBD_BASE+0X10C) /* 端点0接口号寄存器 */
#define USBD_EP0OUTSTAT (USBD_BASE+0X110) /* 端点0状态寄存器 */
#define USBD_EP0OUTBMREQTYPE (USBD_BASE+0X114) /* 端点0 SETUP事务请求类 */
#define USBD_EP0OUTBREQUEST (USBD_BASE+0X118) /* 端点0 SETUP事务请求内容 */
#define USBD_EP0OUTWVALUE (USBD_BASE+0X11C) /* 端点0 SETUP事务请求值 */
#define USBD_EP0OUTWINDEX (USBD_BASE+0X120) /* 端点0 SETUP事务请求索引 */
#define USBD_EP0OUTWLENGTH (USBD_BASE+0X120) /* 端点0 SETUP事务请求长度 */
#define USBD_EP0OUTSYNCHFRAME (USBD_BASE+0X128) /* 端点0同步包帧号 */
#define USBD_EP1OUTADDR (USBD_BASE+0X12C) /* 端点1输出端点号和方向 */
#define USBD_EP1OUTBMATTR (USBD_BASE+0X130) /* 端点1输出类型寄存器 */
#define USBD_EP1OUTMAXPKTSIZE (USBD_BASE+0X134) /* 端点1输出最大包尺寸寄存器 */
#define USBD_EP1OUTIFNUM (USBD_BASE+0X138) /* 端点1输出接口号寄存器 */
#define USBD_EP1OUTSTAT (USBD_BASE+0X13C) /* 端点1输出状态寄存器 */
#define USBD_EP1OUTBMREQTYPE (USBD_BASE+0X140) /* 端点1输出SETUP事务请求类型 */
#define USBD_EP1OUTBREQUEST (USBD_BASE+0X144) /* 端点1输出SETUP事务请求内容 */
#define USBD_EP1OUTWVALUE (USBD_BASE+0X148) /* 端点1输出SETUP事务请求值 */
#define USBD_EP1OUTWINDX (USBD_BASE+0X14C) /* 端点1输出SETUP事务请求索引 */
#define USBD_EP1OUTWLENGH (USBD_BASE+0X150) /* 端点1输出SETUP事务请求域长度 */
#define USBD_EP1OUTSYNCHFRAME (USBD_BASE+0X154) /* 端点1输出同步包帧号 */
#define USBD_EP1INADDR (USBD_BASE+0X158) /* 端点1输入端点号和方向 */
#define USBD_EP1INBMATTR (USBD_BASE+0X15C) /* 端点1输入类型寄存器 */
#define USBD_EP1INMAXPKTSIZE (USBD_BASE+0X160) /* 端点1输入最大包尺寸寄存器 */
#define USBD_EP1INIFNUM (USBD_BASE+0X164) /* 端点1输入接口号寄存器 */
#define USBD_EP1INSTAT (USBD_BASE+0X168) /* 端点1输入状态寄存器 */
#define USBD_EP1INBMREQTYPE (USBD_BASE+0X16C) /* 端点1输入SETUP事务请求类型 */
#define USBD_EP1INBREQUEST (USBD_BASE+0X170) /* 端点1输入SETUP事务请求内容 */
#define USBD_EP1INWVALUE (USBD_BASE+0X174) /* 端点1输入SETUP事务请求值 */
#define USBD_EP1INWINDEX (USBD_BASE+0X178) /* 端点1输入SETUP事务请求索引 */
#define USBD_EP1INWLENGTH (USBD_BASE+0X17C) /* 端点1输入SETUP事务请求域长度 */
#define USBD_EP1INSYNCHFRAME (USBD_BASE+0X180) /* 端点1输入同步包帧号 */
#define USBD_EP2OUTADDR (USBD_BASE+0X184) /* 端点2输出端点号和方向 */
#define USBD_EP2OUTBMATTR (USBD_BASE+0X188) /* 端点2输出类型寄存器 */
#define USBD_EP2OUTMAXPKTSIZE (USBD_BASE+0X18C) /* 端点2输出最大包尺寸寄存器 */
#define USBD_EP2OUTIFNUM (USBD_BASE+0X190) /* 端点2输出接口号寄存器 */
#define USBD_EP2OUTSTAT (USBD_BASE+0X194) /* 端点2输出状态寄存器 */
#define USBD_EP2OUTBMREQTYPE (USBD_BASE+0X198) /* 端点2输出SETUP事务请求类型 */
#define USBD_EP2OUTBREQUEST (USBD_BASE+0X19C) /* 端点2输出SETUP事务请求内容 */
#define USBD_EP2OUTWVALUE (USBD_BASE+0X1A0) /* 端点2输出SETUP事务请求值 */
#define USBD_EP2OUTWINDEX (USBD_BASE+0X1A4) /* 端点2输出SETUP事务请求索引 */
#define USBD_EP2OUTWLENGTH (USBD_BASE+0X1A8) /* 端点2输出SETUP事务请求域长度 */
#define USBD_EP2OUTSYNCHFRAME (USBD_BASE+0X1AC) /* 端点2输出同步包帧号 */
#define USBD_EP2INADDR (USBD_BASE+0X1B0) /* 端点2输入端点号和方向 */
#define USBD_EP2INBMATTR (USBD_BASE+0X1B4) /* 端点2输入类型寄存器 */
#define USBD_EP2INMAXPKTSIZE (USBD_BASE+0X1B8) /* 端点2输入最大包尺寸寄存器 */
#define USBD_EP2INIFNUM (USBD_BASE+0X1BC) /* 端点2输入接口号寄存器 */
#define USBD_EP2INSTAT (USBD_BASE+0X1C0) /* 端点2输入状态寄存器 */
#define USBD_EP2INBMREQTYPE (USBD_BASE+0X1C4) /* 端点2输入SETUP事务请求类型 */
#define USBD_EP2INBREQUEST (USBD_BASE+0X1C8) /* 端点2输入SETUP事务请求内容 */
#define USBD_EP2INWVALUE (USBD_BASE+0X1CC) /* 端点2输入SETUP事务请求值 */
#define USBD_EP2INWINDEX (USBD_BASE+0X1D0) /* 端点2输入SETUP事务请求索引 */
#define USBD_EP2INWLENGTH (USBD_BASE+0X1D4) /* 端点2输入SETUP事务请求域长度 */
#define USBD_EP2INSYNCHFRAME (USBD_BASE+0X1D8) /* 端点2输入同步包帧号 */
#define USBD_RXFIFO (USBD_BASE+0X200) /* 接受FIFO */
#define USBD_TXFIFO (USBD_BASE+0X300) /* 发送FIFO */
/*
* GPIO模块
* : 0x1000F000
*/
#define GPIO_DBCLK_DIV (GPIO_BASE+0X000) /* 去毛刺采用时钟分频比配置寄存器 */
#define GPIO_PORTA_DIR (GPIO_BASE+0X004) /* A组端口输入输出方向配置寄存器 */
#define GPIO_PORTA_SEL (GPIO_BASE+0X008) /* A组端口通用用途选择配置寄存器 */
#define GPIO_PORTA_INCTL (GPIO_BASE+0X00C) /* A组端口通用用途输入时类型配置寄存器 */
#define GPIO_PORTA_INTRCTL (GPIO_BASE+0X010) /* A组端口中断触发类型配置寄存器 */
#define GPIO_PORTA_INTRCLR (GPIO_BASE+0X014) /* A组端口通用用途中断清除配置寄存器 */
#define GPIO_PORTA_DATA (GPIO_BASE+0X018) /* A组端口通用用途数据配置寄存器 */
#define GPIO_PORTB_DIR (GPIO_BASE+0X01C) /* B组端口输入输出方向配置寄存器 */
#define GPIO_PORTB_SEL (GPIO_BASE+0X020) /* B组端口通用用途选择配置寄存器 */
#define GPIO_PORTB_DATA (GPIO_BASE+0X024) /* B组端口通用用途数据配置寄存器 */
#define GPIO_PORTC_DIR (GPIO_BASE+0X028) /* C组端口输入输出方向配置寄存器 */
#define GPIO_PORTC_SEL (GPIO_BASE+0X02C) /* C组端口通用用途选择配置寄存器 */
#define GPIO_PORTC_DATA (GPIO_BASE+0X030) /* C组端口通用用途数据配置寄存器 */
#define GPIO_PORTD_DIR (GPIO_BASE+0X034) /* D组端口输入输出方向配置寄存器 */
#define GPIO_PORTD_SEL (GPIO_BASE+0X038) /* D组端口通用用途选择配置寄存器 */
#define GPIO_PORTD_SPECII (GPIO_BASE+0X03C) /* D组端口专用用途2选择配置寄存器 */
#define GPIO_PORTD_DATA (GPIO_BASE+0X040) /* D组端口通用用途数据配置寄存器 */
#define GPIO_PORTE_DIR (GPIO_BASE+0X044) /* E组端口输入输出方向配置寄存器 */
#define GPIO_PORTE_SEL (GPIO_BASE+0X048) /* E组端口通用用途选择配置寄存器 */
#define GPIO_PORTE_DATA (GPIO_BASE+0X04C) /* E组端口通用用途数据配置寄存器 */
#define GPIO_PORTF_DIR (GPIO_BASE+0X050) /* F组端口输入输出方向配置寄存器 */
#define GPIO_PORTF_SEL (GPIO_BASE+0X054) /* F组端口通用用途选择配置寄存器 */
#define GPIO_PORTF_INCTL (GPIO_BASE+0X058) /* F组端口通用用途输入时类型配置寄存器 */
#define GPIO_PORTF_INTRCTL (GPIO_BASE+0X05C) /* F组端口中断触发类型配置寄存器 */
#define GPIO_PORTF_INTRCLR (GPIO_BASE+0X060) /* F组端口通用用途中断清除配置寄存器 */
#define GPIO_PORTF_DATA (GPIO_BASE+0X064) /* F组端口通用用途数据配置寄存器 */
#define GPIO_PORTG_DIR (GPIO_BASE+0X068) /* G组端口输入输出方向配置寄存器 */
#define GPIO_PORTG_SEL (GPIO_BASE+0X06C) /* G组端口通用用途选择配置寄存器 */
#define GPIO_PORTG_DATA (GPIO_BASE+0X070) /* G组端口通用用途数据配置寄存器 */
#define GPIO_PORTH_DIR (GPIO_BASE+0X07C) /* H组端口输入输出方向配置寄存器 */
#define GPIO_PORTH_SEL (GPIO_BASE+0X078) /* H组端口通用用途选择配置寄存器 */
#define GPIO_PORTH_DATA (GPIO_BASE+0X07C) /* H组端口通用用途数据配置寄存器 */
#define GPIO_PORTI_DIR (GPIO_BASE+0X080) /* I组端口输入输出方向配置寄存器 */
#define GPIO_PORTI_SEL (GPIO_BASE+0X084) /* I组端口通用用途选择配置寄存器 */
#define GPIO_PORTI_DATA (GPIO_BASE+0X088) /* I组端口通用用途数据配置寄存器 */
/*
* EMI模块
* : 0x11000000
*/
#define EMI_CSACONF (EMI_BASE+0X000) /* CSA参数配置寄存器 */
#define EMI_CSBCONF (EMI_BASE+0X004) /* CSB参数配置寄存器 */
#define EMI_CSCCONF (EMI_BASE+0X008) /* CSC参数配置寄存器 */
#define EMI_CSDCONF (EMI_BASE+0X00C) /* CSD参数配置寄存器 */
#define EMI_CSECONF (EMI_BASE+0X010) /* CSE参数配置寄存器 */
#define EMI_CSFCONF (EMI_BASE+0X014) /* CSF参数配置寄存器 */
#define EMI_SDCONF1 (EMI_BASE+0X018) /* SDRAM时序配置寄存器1 */
#define EMI_SDCONF2 (EMI_BASE+0X01C) /* SDRAM时序配置寄存器2, SDRAM初始化用到的配置信息 */
#define EMI_REMAPCONF (EMI_BASE+0X020) /* 片选空间及地址映射REMAP配置寄存器 */
#define EMI_NAND_ADDR1 (EMI_BASE+0X100) /* NAND FLASH的地址寄存器1 */
#define EMI_NAND_COM (EMI_BASE+0X104) /* NAND FLASH的控制字寄存器 */
#define EMI_NAND_STA (EMI_BASE+0X10C) /* NAND FLASH的状态寄存器 */
#define EMI_ERR_ADDR1 (EMI_BASE+0X110) /* 读操作出错的地址寄存器1 */
#define EMI_ERR_ADDR2 (EMI_BASE+0X114) /* 读操作出错的地址寄存器2 */
#define EMI_NAND_CONF1 (EMI_BASE+0X118) /* NAND FLASH的配置器存器1 */
#define EMI_NAND_INTR (EMI_BASE+0X11C) /* NAND FLASH中断寄存器 */
#define EMI_NAND_ECC (EMI_BASE+0X120) /* ECC校验完成寄存器 */
#define EMI_NAND_IDLE (EMI_BASE+0X124) /* NAND FLASH空闲寄存器 */
#define EMI_NAND_CONF2 (EMI_BASE+0X128) /* NAND FLASH的配置器存器2 */
#define EMI_NAND_ADDR2 (EMI_BASE+0X12C) /* NAND FLASH的地址寄存器2 */
#define EMI_NAND_DATA (EMI_BASE+0X200) /* NAND FLASH的数据寄存器 */
/*
* DMAC模块
* : 0x11001000
*/
#define DMAC_INTSTATUS (DMAC_BASE+0X020) /* DAMC中断状态寄存器。 */
#define DMAC_INTTCSTATUS (DMAC_BASE+0X050) /* DMAC传输完成中断状态寄存器 */
#define DMAC_INTTCCLEAR (DMAC_BASE+0X060) /* DMAC传输完成中断状态清除寄存器 */
#define DMAC_INTERRORSTATUS (DMAC_BASE+0X080) /* DMAC传输错误中断状态寄存器 */
#define DMAC_INTINTERRCLR (DMAC_BASE+0X090) /* DMAC传输错误中断状态清除寄存器 */
#define DMAC_ENBLDCHNS (DMAC_BASE+0X0B0) /* DMAC通道使能状态寄存器 */
#define DMAC_C0SRCADDR (DMAC_BASE+0X000) /* DMAC道0源地址寄存器 */
#define DMAC_C0DESTADD (DMAC_BASE+0X004) /* DMAC道0目的地址寄存器 */
#define DMAC_C0CONTROL (DMAC_BASE+0X00C) /* DMAC道0控制寄存器 */
#define DMAC_C0CONFIGURATION (DMAC_BASE+0X010) /* DMAC道0配置寄存器 */
#define DMAC_C0DESCRIPTOR (DMAC_BASE+0X01C) /* DMAC道0链表地址寄存器 */
#define DMAC_C1SRCADDR (DMAC_BASE+0X100) /* DMAC道1源地址寄存器 */
#define DMAC_C1DESTADDR (DMAC_BASE+0X104) /* DMAC道1目的地址寄存器 */
#define DMAC_C1CONTROL (DMAC_BASE+0X10C) /* DMAC道1控制寄存器 */
#define DMAC_C1CONFIGURATION (DMAC_BASE+0X110) /* DMAC道1配置寄存器 */
#define DMAC_C1DESCRIPTOR (DMAC_BASE+0X114) /* DMAC道1链表地址寄存器 */
#define DMAC_C2SRCADDR (DMAC_BASE+0X200) /* DMAC道2源地址寄存器 */
#define DMAC_C2DESTADDR (DMAC_BASE+0X204) /* DMAC道2目的地址寄存器 */
#define DMAC_C2CONTROL (DMAC_BASE+0X20C) /* DMAC道2控制寄存器 */
#define DMAC_C2CONFIGURATION (DMAC_BASE+0X210) /* DMAC道2配置寄存器 */
#define DMAC_C2DESCRIPTOR (DMAC_BASE+0X214) /* DMAC道2链表地址寄存器 */
#define DMAC_C3SRCADDR (DMAC_BASE+0X300) /* DMAC道3源地址寄存器 */
#define DMAC_C3DESTADDR (DMAC_BASE+0X304) /* DMAC道3目的地址寄存器 */
#define DMAC_C3CONTROL (DMAC_BASE+0X30C) /* DMAC道3控制寄存器 */
#define DMAC_C3CONFIGURATION (DMAC_BASE+0X310) /* DMAC道3配置寄存器 */
#define DMAC_C3DESCRIPTOR (DMAC_BASE+0X314) /* DMAC道3链表地址寄存器 */
#define DMAC_C4SRCADDR (DMAC_BASE+0X400) /* DMAC道4源地址寄存器 */
#define DMAC_C4DESTADDR (DMAC_BASE+0X404) /* DMAC道4目的地址寄存器 */
#define DMAC_C4CONTROL (DMAC_BASE+0X40C) /* DMAC道4控制寄存器 */
#define DMAC_C4CONFIGURATION (DMAC_BASE+0X410) /* DMAC道4配置寄存器 */
#define DMAC_C4DESCRIPTOR (DMAC_BASE+0X414) /* DMAC道4链表地址寄存器 */
#define DMAC_C5SRCADDR (DMAC_BASE+0X500) /* DMAC道5源地址寄存器 */
#define DMAC_C5DESTADDR (DMAC_BASE+0X504) /* DMAC道5目的地址寄存器 */
#define DMAC_C5CONTROL (DMAC_BASE+0X50C) /* DMAC道5控制寄存器 */
#define DMAC_C5CONFIGURATION (DMAC_BASE+0X510) /* DMAC道5配置寄存器 */
#define DMAC_C5DESCRIPTOR (DMAC_BASE+0X514) /* DMAC道5链表地址寄存器 */
/*
* LCDC模块
* : 0x11002000
*/
#define LCDC_SSA (LCDC_BASE+0X000) /* 屏幕起始地址寄存器 */
#define LCDC_SIZE (LCDC_BASE+0X004) /* 屏幕尺寸寄存器 */
#define LCDC_PCR (LCDC_BASE+0X008) /* 面板配置寄存器 */
#define LCDC_HCR (LCDC_BASE+0X00C) /* 水平配置寄存器 */
#define LCDC_VCR (LCDC_BASE+0X010) /* 垂直配置寄存器 */
#define LCDC_PWMR (LCDC_BASE+0X014) /* PWM对比度控制寄存器 */
#define LCDC_LECR (LCDC_BASE+0X018) /* 使能控制寄存器 */
#define LCDC_DMACR (LCDC_BASE+0X01C) /* DMA控制寄存器 */
#define LCDC_LCDISREN (LCDC_BASE+0X020) /* 中断使能寄存器 */
#define LCDC_LCDISR (LCDC_BASE+0X024) /* 中断状态寄存器 */
#define LCDC_LGPMR (LCDC_BASE+0X040) /* 灰度调色映射寄存器组 (16个32bit寄存器) */
/*
* MAC模块
* : 0x11003000
*/
#define MAC_CTRL (MAC_BASE+0X000) /* MAC控制寄存器 */
#define MAC_INTSRC (MAC_BASE+0X004) /* MAC中断源寄存器 */
#define MAC_INTMASK (MAC_BASE+0X008) /* MAC中断屏蔽寄存器 */
#define MAC_IPGT (MAC_BASE+0X00C) /* 连续帧间隔寄存器 */
#define MAC_IPGR1 (MAC_BASE+0X010) /* 等待窗口寄存器 */
#define MAC_IPGR2 (MAC_BASE+0X014) /* 等待窗口寄存器 */
#define MAC_PACKETLEN (MAC_BASE+0X018) /* 帧长度寄存器 */
#define MAC_COLLCONF (MAC_BASE+0X01C) /* 碰撞重发寄存器 */
#define MAC_TXBD_NUM (MAC_BASE+0X020) /* 发送描述符寄存器 */
#define MAC_FLOWCTRL (MAC_BASE+0X024) /* 流控寄存器 */
#define MAC_MII_CTRL (MAC_BASE+0X028) /* PHY控制寄存器 */
#define MAC_MII_CMD (MAC_BASE+0X02C) /* PHY命令寄存器 */
#define MAC_MII_ADDRESS (MAC_BASE+0X030) /* PHY地址寄存器 */
#define MAC_MII_TXDATA (MAC_BASE+0X034) /* PHY写数据寄存器 */
#define MAC_MII_RXDATA (MAC_BASE+0X038) /* PHY读数据寄存器 */
#define MAC_MII_STATUS (MAC_BASE+0X03C) /* PHY状态寄存器 */
#define MAC_ADDR0 (MAC_BASE+0X040) /* MAC地址寄存器 */
#define MAC_ADDR1 (MAC_BASE+0X044) /* MAC地址寄存器 */
#define MAC_HASH0 (MAC_BASE+0X048) /* MAC HASH寄存器 */
#define MAC_HASH1 (MAC_BASE+0X04C) /* MAC HASH寄存器 */
#define MAC_TXPAUSE (MAC_BASE+0X050) /* MAC控制帧寄存器 */
#define MAC_TX_BD (MAC_BASE+0X400)
#define MAC_RX_BD (MAC_BASE+0X600)
/*
**************************************
* Error Codes:
* IF SUCCESS RETURN 0, ELSE RETURN OTHER ERROR CODE,
* parameter error return (-33)/E_PAR,
* hardware error reture (-99)/E_HA
**************************************
*/
#define E_OK 0 /* Normal completion */
#define E_SYS (-5) /* System error */
#define E_NOMEM (-10) /* Insufficient memory */
#define E_NOSPT (-17) /* Feature not supported */
#define E_INOSPT (-18) /* Feature not supported by ITRON/FILE specification */
#define E_RSFN (-20) /* Reserved function code number */
#define E_RSATR (-24) /* Reserved attribute */
#define E_PAR (-33) /* Parameter error */
#define E_ID (-35) /* Invalid ID number */
#define E_NOEXS (-52) /* Object does not exist */
#define E_OBJ (-63) /* Invalid object state */
#define E_MACV (-65) /* Memory access disabled or memory access violation */
#define E_OACV (-66) /* Object access violation */
#define E_CTX (-69) /* Context error */
#define E_QOVR (-73) /* Queuing or nesting overflow */
#define E_DLT (-81) /* Object being waited for was deleted */
#define E_TMOUT (-85) /* Polling failure or timeout exceeded */
#define E_RLWAI (-86) /* WAIT state was forcibly released */
#define E_HA (-99) /* HARD WARE ERROR */
/*
**************************************
* PMU
**************************************
*/
#define CLK_SGPT (1 << 16)
#define CLK_SI2S (1 << 15)
#define CLK_SSMC (1 << 14)
#define CLK_SMAC (1 << 13)
#define CLK_SUSB (1 << 12)
#define CLK_SUART3 (1 << 11)
#define CLK_SUART2 (1 << 10)
#define CLK_SUART1 (1 << 9)
#define CLK_SUART0 (1 << 8)
#define CLK_SSSI (1 << 7)
#define CLK_SAC97 (1 << 6)
#define CLK_SMMCSD (1 << 5)
#define CLK_SEMI (1 << 4)
#define CLK_SDMAC (1 << 3)
#define CLK_SPWM (1 << 2)
#define CLK_SLCDC (1 << 1)
#define CLK_SESRAM (1)
/*Interrupt Sources*/
#define INTSRC_RTC 31
#define INTSRC_DMAC 30
#define INTSRC_EMI 29
#define INTSRC_MAC 28
#define INTSRC_TIMER1 27
#define INTSRC_TIMER2 26
#define INTSRC_TIMER3 25
#define INTSRC_UART0 24
#define INTSRC_UART1 23
#define INTSRC_UART2 22
#define INTSRC_UART3 21
#define INTSRC_PWM 20
#define INTSRC_LCDC 19
#define INTSRC_I2S 18
#define INTSRC_SSI 17
#define INTSRC_USB 15
#define INTSRC_SMC0 14
#define INTSRC_SMC1 13
#define INTSRC_SDIO 12
#define INTSRC_EXINT10 11
#define INTSRC_EXINT9 10
#define INTSRC_EXINT8 9
#define INTSRC_EXINT7 8
#define INTSRC_EXINT6 7
#define INTSRC_EXINT5 6
#define INTSRC_EXINT4 5
#define INTSRC_EXINT3 4
#define INTSRC_EXINT2 3
#define INTSRC_EXINT1 2
#define INTSRC_EXINT0 1
#define INTSRC_NULL 0
/*Sereral useful macros*/
#define set_plevel(plevel) *(RP)INTC_IPLR = plevel //设置普通中断的优先级门限,只有优先级大于此值的中断才能通过
#define set_int_force(intnum) *(RP)INTC_IFR = (1 << intnum) //置1后软件强制该位对应的中断源发出中断信号
#define enable_irq(intnum) *(RP)INTC_IER |= (1 << intnum) //置1后允许中断源的IRQ 中断信号
#define disable_irq( intnum) *(RP)INTC_IER &= ~(1<< intnum) //置0后不允许中断源的IRQ 中断信号
#define mask_irq(intnum) *(RP)INTC_IMR |= (1 << intnum) //置1后屏蔽对应的IRQ 中断信号
#define unmask_irq(intnum) *(RP)INTC_IMR &= ~(1 << intnum) //置0后通过对应的IRQ 中断信号
#define mask_all_irq() *(RP)INTC_IMR = 0xFFFFFFFF //屏蔽对应的IRQ 中断信号
#define unmask_all_irq() *(RP)INTC_IMR = 0x00000000 //通过对应的IRQ 中断信号
#define enable_all_irq() *(RP)INTC_IER = 0XFFFFFFFF //允许中断源的IRQ 中断信号
#define disable_all_irq() *(RP)INTC_IER = 0X00000000 //不允许中断源的IRQ 中断信号
#define InitInt() do{mask_all_irq(); enable_all_irq();}while(0)
/*
**************************************
* Typedef
**************************************
*/
typedef char S8; /* signed 8-bit integer */
typedef short S16; /* signed 16-bit integer */
typedef long S32; /* signed 32-bit integer */
typedef unsigned char U8; /* unsigned 8-bit integer */
typedef unsigned short U16; /* unsigned 16-bit integer */
typedef unsigned long U32; /* unsigned 32-bit integer */
typedef volatile U32 * RP;
typedef volatile U16 * RP16;
typedef volatile U8 * RP8;
typedef void *VP; /* pointer to an unpredictable data type */
typedef void (*FP)(); /* program start address */
#ifndef _BOOL_TYPE_
#define _BOOL_TYPE_
typedef int BOOL; /* Boolean value. TRUE (1) or FALSE (0). */
#endif
typedef int ER; /* Error code. A signed integer. */
/**
* IO definitions
*
* define access restrictions to peripheral registers
*/
#define __I volatile const /*!< defines 'read only' permissions */
#define __O volatile /*!< defines 'write only' permissions */
#define __IO volatile /*!< defines 'read / write' permissions */
#define __iomem volatile
/*Macros for debug*/
#define EOUT(fmt,...) \
do \
{ \
rt_kprintf("EOUT:(%s:%i) ",__FILE__,__LINE__); \
rt_kprintf(fmt,##__VA_ARGS__); \
}while(0)
#define RT_DEBUG
#ifdef RT_DEBUG
#define DBOUT(fmt,...) \
do \
{ \
rt_kprintf("DBOUT:(%s:%i) ",__FILE__,__LINE__); \
rt_kprintf(fmt,##__VA_ARGS__); \
}while(0)
#else
#define DBOUT(fmt,...) \
do{}while(0)
#endif
#ifdef RT_DEBUG
#define ASSERT(arg) \
if((arg) == 0) \
{ \
while(1) \
{ \
rt_kprintf("have a assert failure\n"); \
} \
}
#else
#define ASSERT(arg) \
do \
{ \
}while(0)
#endif
#define write_reg(reg,value) \
do \
{ \
*(RP)(reg) = value; \
}while(0)
#define read_reg(reg) (*(RP)reg)
struct rt_hw_register
{
rt_uint32_t r0;
rt_uint32_t r1;
rt_uint32_t r2;
rt_uint32_t r3;
rt_uint32_t r4;
rt_uint32_t r5;
rt_uint32_t r6;
rt_uint32_t r7;
rt_uint32_t r8;
rt_uint32_t r9;
rt_uint32_t r10;
rt_uint32_t fp;
rt_uint32_t ip;
rt_uint32_t sp;
rt_uint32_t lr;
rt_uint32_t pc;
rt_uint32_t cpsr;
rt_uint32_t ORIG_r0;
};
/*@}*/
#endif

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/*
* File : serial.c
* This file is part of RT-Thread RTOS
* COPYRIGHT (C) 2006, RT-Thread Development Team
*
* The license and distribution terms for this file may be
* found in the file LICENSE in this distribution or at
* http://openlab.rt-thread.com/license/LICENSE
*
* Change Logs:
* Date Author Notes
* 2006-03-13 Bernard first version
* 2009-04-20 yi.qiu modified according bernard's stm32 version
* 2010-10-6 wangmeng added sep4020 surpport
*/
#include <rtthread.h>
#include <rthw.h>
#include "serial.h"
/**
* @addtogroup SEP4020
*/
/*@{*/
/* RT-Thread Device Interface */
/**
* This function initializes serial
*/
static rt_err_t rt_serial_init (rt_device_t dev)
{
struct serial_device* uart = (struct serial_device*) dev->private;
if (!(dev->flag & RT_DEVICE_FLAG_ACTIVATED))
{
if (dev->flag & RT_DEVICE_FLAG_INT_RX)
{
rt_memset(uart->int_rx->rx_buffer, 0,
sizeof(uart->int_rx->rx_buffer));
uart->int_rx->read_index = uart->int_rx->save_index = 0;
}
if (dev->flag & RT_DEVICE_FLAG_INT_TX)
{
rt_memset(uart->int_tx->tx_buffer, 0,
sizeof(uart->int_tx->tx_buffer));
uart->int_tx->write_index = uart->int_tx->save_index = 0;
}
dev->flag |= RT_DEVICE_FLAG_ACTIVATED;
}
return RT_EOK;
}
/* save a char to serial buffer */
static void rt_serial_savechar(struct serial_device* uart, char ch)
{
rt_base_t level;
/* disable interrupt */
level = rt_hw_interrupt_disable();
uart->int_rx->rx_buffer[uart->int_rx->save_index] = ch;
uart->int_rx->save_index ++;
if (uart->int_rx->save_index >= UART_RX_BUFFER_SIZE)
uart->int_rx->save_index = 0;
/* if the next position is read index, discard this 'read char' */
if (uart->int_rx->save_index == uart->int_rx->read_index)
{
uart->int_rx->read_index ++;
if (uart->int_rx->read_index >= UART_RX_BUFFER_SIZE)
uart->int_rx->read_index = 0;
}
/* enable interrupt */
rt_hw_interrupt_enable(level);
}
static rt_err_t rt_serial_open(rt_device_t dev, rt_uint16_t oflag)
{
RT_ASSERT(dev != RT_NULL);
return RT_EOK;
}
static rt_err_t rt_serial_close(rt_device_t dev)
{
RT_ASSERT(dev != RT_NULL);
return RT_EOK;
}
static rt_size_t rt_serial_read (rt_device_t dev, rt_off_t pos, void* buffer, rt_size_t size)
{
rt_uint8_t* ptr;
rt_err_t err_code;
struct serial_device* uart;
ptr = buffer;
err_code = RT_EOK;
uart = (struct serial_device*)dev->private;
if (dev->flag & RT_DEVICE_FLAG_INT_RX)
{
rt_base_t level;
/* interrupt mode Rx */
while (size)
{
if (uart->int_rx->read_index != uart->int_rx->save_index)
{
*ptr++ = uart->int_rx->rx_buffer[uart->int_rx->read_index];
size --;
/* disable interrupt */
level = rt_hw_interrupt_disable();
uart->int_rx->read_index ++;
if (uart->int_rx->read_index >= UART_RX_BUFFER_SIZE)
uart->int_rx->read_index = 0;
/* enable interrupt */
rt_hw_interrupt_enable(level);
}
else
{
/* set error code */
err_code = -RT_EEMPTY;
break;
}
}
}
else
{
/* polling mode */
while ((rt_uint32_t)ptr - (rt_uint32_t)buffer < size)
{
while (uart->uart_device->lsr & USTAT_RCV_READY)
{
*ptr = uart->uart_device->dlbl_fifo.txfifo & 0xff;
ptr ++;
}
}
}
/* set error code */
rt_set_errno(err_code);
return (rt_uint32_t)ptr - (rt_uint32_t)buffer;
}
static rt_size_t rt_serial_write (rt_device_t dev, rt_off_t pos, const void* buffer, rt_size_t size)
{
rt_uint8_t* ptr;
rt_err_t err_code;
struct serial_device* uart;
err_code = RT_EOK;
ptr = (rt_uint8_t*)buffer;
uart = (struct serial_device*)dev->private;
if (dev->flag & RT_DEVICE_FLAG_INT_TX)
{
/* interrupt mode Tx */
while (uart->int_tx->save_index != uart->int_tx->write_index)
{
/* save on tx buffer */
uart->int_tx->tx_buffer[uart->int_tx->save_index] = *ptr++;
-- size;
/* move to next position */
uart->int_tx->save_index ++;
/* wrap save index */
if (uart->int_tx->save_index >= UART_TX_BUFFER_SIZE)
uart->int_tx->save_index = 0;
}
/* set error code */
if (size > 0)
err_code = -RT_EFULL;
}
else
{
/* polling mode */
while (size)
{
/*
* to be polite with serial console add a line feed
* to the carriage return character
*/
if (*ptr == '\n' && (dev->flag & RT_DEVICE_FLAG_STREAM))
{
while (!(uart->uart_device->lsr & USTAT_TXB_EMPTY));
uart->uart_device->dlbl_fifo.txfifo = '\r';
}
while (!(uart->uart_device->lsr & USTAT_TXB_EMPTY));
uart->uart_device->dlbl_fifo.txfifo = (*ptr & 0x1FF);
++ptr; --size;
}
}
/* set error code */
rt_set_errno(err_code);
return (rt_uint32_t)ptr - (rt_uint32_t)buffer;
}
static rt_err_t rt_serial_control (rt_device_t dev, rt_uint8_t cmd, void *args)
{
RT_ASSERT(dev != RT_NULL);
switch (cmd)
{
case RT_DEVICE_CTRL_SUSPEND:
/* suspend device */
dev->flag |= RT_DEVICE_FLAG_SUSPENDED;
break;
case RT_DEVICE_CTRL_RESUME:
/* resume device */
dev->flag &= ~RT_DEVICE_FLAG_SUSPENDED;
break;
}
return RT_EOK;
}
/*
* serial register
*/
rt_err_t rt_hw_serial_register(rt_device_t device, const char* name, rt_uint32_t flag, struct serial_device *serial)
{
RT_ASSERT(device != RT_NULL);
device->type = RT_Device_Class_Char;
device->rx_indicate = RT_NULL;
device->tx_complete = RT_NULL;
device->init = rt_serial_init;
device->open = rt_serial_open;
device->close = rt_serial_close;
device->read = rt_serial_read;
device->write = rt_serial_write;
device->control = rt_serial_control;
device->private = serial;
/* register a character device */
return rt_device_register(device, name, RT_DEVICE_FLAG_RDWR | flag);
}
/* ISR for serial interrupt */
void rt_hw_serial_isr(rt_device_t device)
{
struct serial_device* uart = (struct serial_device*) device->private;
/* interrupt mode receive */
RT_ASSERT(device->flag & RT_DEVICE_FLAG_INT_RX);
/* save on rx buffer */
while (uart->uart_device->lsr & USTAT_RCV_READY)
{
rt_serial_savechar(uart, uart->uart_device->dlbl_fifo.rxfifo & 0xff);
}
/* invoke callback */
if (device->rx_indicate != RT_NULL)
{
rt_size_t rx_length;
/* get rx length */
rx_length = uart->int_rx->read_index > uart->int_rx->save_index ?
UART_RX_BUFFER_SIZE - uart->int_rx->read_index + uart->int_rx->save_index :
uart->int_rx->save_index - uart->int_rx->read_index;
device->rx_indicate(device, rx_length);
}
}
/*@}*/

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/*
* File : serial.c
* This file is part of RT-Thread RTOS
* COPYRIGHT (C) 2006, RT-Thread Development Team
*
* The license and distribution terms for this file may be
* found in the file LICENSE in this distribution or at
* http://openlab.rt-thread.com/license/LICENSE
*
* Change Logs:
* Date Author Notes
* 2006-03-13 Bernard first version
* 2009-04-20 yi.qiu modified according bernard's stm32 version
* 2010-10-6 wangmeng added sep4020 surpport
*/
#ifndef __SERIAL_H__
#define __SERIAL_H__
#include <sep4020.h>
#define USTAT_RCV_READY 0x01 /* receive data ready */
#define USTAT_TXB_EMPTY 0x40 /* tx buffer empty */
#define BPS 115200 /* serial baudrate */
#define UART_RX_BUFFER_SIZE 64
#define UART_TX_BUFFER_SIZE 64
/*For sep4020's uart have several secondary function*/
/*we use union to decribe it*/
union dlbl_fifo
{
rt_uint32_t dlbl;
rt_uint32_t rxfifo;
rt_uint32_t txfifo;
};
union dlbh_ier
{
rt_uint32_t dlbh;
rt_uint32_t ier;
};
union iir_fcr
{
rt_uint32_t iir;
rt_uint32_t fcr;
};
struct serial_int_rx
{
rt_uint8_t rx_buffer[UART_RX_BUFFER_SIZE];
rt_uint32_t read_index, save_index;
};
struct serial_int_tx
{
rt_uint8_t tx_buffer[UART_TX_BUFFER_SIZE];
rt_uint32_t write_index, save_index;
};
typedef struct uartport
{
union dlbl_fifo dlbl_fifo;
union dlbh_ier dlbh_ier;
union iir_fcr iir_fcr;
rt_uint32_t lcr;
rt_uint32_t mcr;
rt_uint32_t lsr;
rt_uint32_t msr;
}uartport;
struct serial_device
{
uartport* uart_device;
/* rx structure */
struct serial_int_rx* int_rx;
/* tx structure */
struct serial_int_tx* int_tx;
};
rt_err_t rt_hw_serial_register(rt_device_t device, const char* name, rt_uint32_t flag, struct serial_device *serial);
void rt_hw_serial_isr(rt_device_t device);
#endif

119
bsp/evb4020/src/startup.c Executable file
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#include <rthw.h>
#include <rtthread.h>
#include <sep4020.h>
#include <board.h>
#include <serial.h>
#include <finsh.h>
#ifdef RT_USING_LWIP
#include <lwip/sys.h>
#include <netif/ethernetif.h>
#endif
#define SDRAM_BASE 0x30000000
#ifdef __CC_ARM
extern int Image$$RW_RAM1$$ZI$$Limit;
#endif
extern void rt_application_init(void);
extern void finsh_system_init(void);
extern void sd_init(void);
extern rt_uint8_t sd_readblock(rt_uint32_t address, rt_uint8_t* buf);
extern rt_uint8_t sd_writeblock(rt_uint32_t address, rt_uint8_t* buf);
extern struct serial_device uart0;
extern struct rt_device uart0_device;
void rtthread_startup()
{
/* init hardware interrupt */
rt_hw_interrupt_init();
/* init board */
rt_hw_board_init();
/* show version */
rt_show_version();
/* init tick */
rt_system_tick_init();
/* init kernel object */
rt_system_object_init();
/* init timer system */
rt_system_timer_init();
/* init heap memory system */
#ifdef __CC_ARM
rt_kprintf("base=%p\n",&Image$$RW_RAM1$$ZI$$Limit);
rt_system_heap_init((void*)&Image$$RW_RAM1$$ZI$$Limit, (void*)(SDRAM_BASE + 0x200000));
#else
rt_system_heap_init(&__bss_end, (void*)0x34000000);
#endif
/* init scheduler system */
rt_system_scheduler_init();
#ifdef RT_USING_DEVICE
/* register uart0 */
rt_hw_serial_register(&uart0_device, "uart0",
RT_DEVICE_FLAG_RDWR | RT_DEVICE_FLAG_INT_RX | RT_DEVICE_FLAG_STREAM,
&uart0);
#ifdef RT_USING_DFS
rt_hw_sdcard_init();
#endif
#ifdef RT_USING_LWIP
eth_system_device_init();
rt_hw_dm9161_init();
#endif
/*init all registed devices */
rt_device_init_all();
#endif
/* init application */
rt_application_init();
#ifdef RT_USING_FINSH
/* init finsh */
finsh_system_init();
#ifdef RT_USING_DEVICE
finsh_set_device("uart0");
#endif
#endif
/* init idle thread */
rt_thread_idle_init();
/* start scheduler */
rt_system_scheduler_start();
/* never reach here */
return ;
}
int main()
{
rt_uint32_t UNUSED level;
/* disable interrupt first */
level = rt_hw_interrupt_disable();
/* startup RT-Thread RTOS */
rtthread_startup();
return 0;
}

63
bsp/evb4020/src/tcpsendpacket.c Executable file
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#include <rtthread.h>
#include <lwip/netdb.h> /* 为了解析主机名需要包含netdb.h头文件 */
#include <lwip/sockets.h> /* 使用BSD socket需要包含sockets.h头文件 */
void tcp_senddata(const char* url, int port, int length)
{
struct hostent *host;
int sock, err, result, timeout, index;
struct sockaddr_in server_addr;
rt_uint8_t *buffer_ptr;
/* 通过函数入口参数url获得host地址如果是域名会做域名解析 */
host = gethostbyname(url);
/* 创建一个socket类型是SOCKET_STREAMTCP类型 */
if ((sock = socket(AF_INET, SOCK_STREAM, IPPROTO_TCP)) == -1)
{
/* 创建socket失败 */
rt_kprintf("Socket error\n");
return;
}
/* 神奇内存 */
buffer_ptr = rt_malloc(length);
/* 构造发生数据 */
for (index = 0; index < length; index ++)
buffer_ptr[index] = index & 0xff;
timeout = 100;
/* 设置发送超时时间100ms */
lwip_setsockopt(sock, SOL_SOCKET, SO_SNDTIMEO, &timeout, sizeof(timeout));
/* 初始化预连接的服务端地址 */
server_adlidr.sin_family = AF_INET;
server_addr.sin_port = htons(port);
server_addr.sin_addr = *((struct in_addr *)host->h_addr);
rt_memset(&(server_addr.sin_zero), 0, sizeof(server_addr.sin_zero));
/* 连接到服务端 */
err = connect(sock, (struct sockaddr *)&server_addr, sizeof(struct sockaddr));
rt_kprintf("TCP thread connect error code: %d\n", err);
while(1)
{
/* 发送数据到sock连接 */
result = send(sock, buffer_ptr, length, MSG_DONTWAIT);
if(result == -1) //数据发送错误处理
{
rt_kprintf("TCP thread send error: %d\n", result);
lwip_close(sock); //关闭连接,重新创建连接
rt_thread_delay(10);
if ((sock = socket(AF_INET, SOCK_STREAM, IPPROTO_TCP)) == -1)
rt_kprintf("TCP Socket error:%d\n",sock);
err = connect(sock, (struct sockaddr *)&server_addr, sizeof(struct sockaddr));
rt_kprintf("TCP thread connect error code: %d\n", err);
}
}
}
#ifdef RT_USING_FINSH
#include <finsh.h>
/* 输出tcpclient函数到finsh shell中 */
FINSH_FUNCTION_EXPORT(tcp_senddata, send a packet through tcp connection);
#endif