[Original] [serialization]. Simple Digital Photo Frame Based on FPGA-nioii SBTE part (software part)-SD card (SPI mode) Driver

Source: Internet
Author: User
Tags usleep
Document directory
  • Step 1 Add the sd_card folder to the APP project path
  • Step 2 write code
  • Step 3 call the SD card driver Function

In the previous section, we completed the configuration of the niosii SBTE. The following describes how to compile an SD card Driver Based on existing references (manual and code.

Prepare tools and materials

1. WinHex

2. Efronc's blog post SD/MMC interface and power-on sequence, SD/MMC internal registers, and command set in SD/mmc spi Mode

Step 1: add the sd_card folder to the APP project path

For details about how to add images, refer to [original] [serialization]. The simple digital photo frame based on FPGA-nioii SBTE part (software part)-configuration work.

Step 2 write code

SD cards have many standards. The simplest SD 1-line mode is used here, that is, SPI mode.

Code 2.1 sd_card.h

#ifndef SD_CARD_H_#define SD_CARD_H_#include "my_types.h"#include "my_regs.h"#define ENABLE_SD_CARD_DEBUG // turn on debug messagevoid SD_CARD_Port_Init();void SD_CARD_Write_Byte(u8 byte);u8 SD_CARD_Read_Byte();u8 SD_CARD_Write_CMD(u8 *CMD);//u8 SD_CARD_Init();u8 SD_CARD_Write_Sector(u32 addr,u8 *buf);u8 SD_CARD_Read_Sector(u8 *CMD,u8 *buf,u16 n_bytes);u8 SD_CARD_Read_Sector_Start(u32 sector);void SD_CARD_Read_Data(u16 n_bytes,u8 *buf);void SD_CARD_Read_Data_LBA(u32 LBA,u16 n_bytes,u8 *buf);void SD_CARD_Read_Sector_End();u8 SD_CARD_Read_CSD(u8 *buf);u8 SD_CARD_Read_CID(u8 *buf);void SD_CARD_Get_Info(void);void SD_CARD_DEMO(void);#endif /* SD_CARD_H_ */

5th ~ Six rows: add custom macros to unify the code style. Line 3: Turn On the debug information display switch. After debugging is correct, you can add comments to turn off the switch.

Line 3 void SD_CARD_Port_Init () is the initial function of the SPI interface.

13th ~ Line 14 void SD_CARD_Write_Byte (u8 byte) and u8 SD_CARD_Read_Byte () are the function for writing bytes and reading bytes for SPI.

Line 2: u8 SD_CARD_Write_CMD (u8 * CMD). Write the command function for the SD card.

Row 17th u8 SD_CARD_Init () is the SD card initialization function. This function requires special attention because SD cards in SPI mode require low-speed data transmission and receiving to initialize the SD card.

18th ~ Row 19 u8 SD_CARD_Write_Sector (u32 addr, u8 * buf) and u8 SD_CARD_Read_Sector (u8 * CMD, u8 * buf, 2010n_bytes) are SD card write and read block functions; note that the SD card contains 512 bytes, and each slice of the SD card viewed through WinHex is 512 bytes. For the sake of unified style, Sector is written here.

Line 3 void SD_CARD_Read_Data_LBA (u32 LBA, 2010n_bytes, u8 * buf) is easy to use. Its Parameter LBA is the sector address that can be viewed in Winhex and the logical block address. With this function, our subsequent work is convenient.

24th ~ Line 25 u8 SD_CARD_Read_CSD (u8 * buf) and u8 SD_CARD_Read_CID (u8 * buf) are the functions used to read the CSD and CID registers of the SD card.

For other functions, refer to the source code for self-resolution.

Code 2.2 sd_card.c

#include <unistd.h>#include "sd_card.h"// debug switch#ifdef ENABLE_SD_CARD_DEBUG  #include "debug.h"  #define SD_CARD_DEBUG(x)  DEBUG(x)#else  #define SD_CARD_DEBUG(x)#endif// error macro#define INIT_CMD0_ERROR   0x01#define INIT_CMD1_ERROR   0x02#define WRITE_BLOCK_ERROR 0x03#define READ_BLOCK_ERROR  0x04// SD-CARD(SPI mode) initial with low speed// insert a certain delay#define SD_CARD_INIT_DELAY usleep(10)// CID info structuretypedef union{  u8 data[16];  struct  {    u8 MID;   // Manufacture ID; Binary    u8 OLD[2];// OEM/Application ID; ASCII    u8 PNM[5];// Product Name; ASCII    u8 PRV;   // Product Revision; BCD    u8 PSN[4];// Serial Number; Binary    u8 MDT[2];// Manufacture Data Code; BCD; upper 4 bits of first byte are reserved    u8 CRC;   // CRC7_checksum; Binary; LSB are reserved  };}CID_Info_STR;// CSD info structuretypedef struct{  u8 data[16];  u32 capacity_MB;  u8 READ_BL_LEN;  u16 C_SIZE;  u8 C_SIZE_MULT;}CSD_Info_STR;// flagsu16 gByteOffset=0;       // byte offset in one sectoru16 gSectorOffset=0;     // sector offset in SD-CARDbool gSectorOpened=FALSE;// set to 1 when a sector is opened.bool gSD_CARDInit=FALSE; // set it to 1 when SD-CARD is initialized// SD-CARD port initvoid SD_CARD_Port_Init(){  sd_CLK=1;  sd_DOUT=1;  sd_nCS=1;}// write a byte to SD-CARDvoid SD_CARD_Write_Byte(u8 byte){  u8 i;  for(i=0;i<8;i++)  { // MSB First    sd_DIN=(byte >> (7-i)) & 0x1;    sd_CLK=0;if(gSD_CARDInit) SD_CARD_INIT_DELAY;    sd_CLK=1;if(gSD_CARDInit) SD_CARD_INIT_DELAY;  }}// read a byte to SD-CARDu8 SD_CARD_Read_Byte(){  u8 i,byte;  byte=0;  for(i=0;i<8;i++)  { // MSB First    sd_CLK=0;if(gSD_CARDInit) SD_CARD_INIT_DELAY;    byte<<=1;if(sd_DOUT) byte++;    sd_CLK=1;if(gSD_CARDInit) SD_CARD_INIT_DELAY;  }  return byte;}// write a command to SD-CARD// return: the second byte of response register of SD-CARDu8 SD_CARD_Write_CMD(u8 *CMD){  u8 temp,retry;  u8 i;  sd_nCS=1; // set chipselect (disable SD-CARD)  SD_CARD_Write_Byte(0xFF); // send 8 clock impulse  sd_nCS=0; // clear chipselect (enable SD-CARD)  // write 6 bytes command to SD-CARD  for(i=0;i<6;i++) SD_CARD_Write_Byte(*CMD++);  // get 16 bits response  SD_CARD_Read_Byte(); // read the first byte, ignore it.  retry=0;  do  { // only last 8 bits is valid    temp=SD_CARD_Read_Byte();    retry++;  }  while((temp==0xff) && (retry<100));  return temp;}// SD-CARD initialization(SPI mode)u8 SD_CARD_Init(){  u8 retry,temp;  u8 i;  u8 CMD[]={0x40,0x00,0x00,0x00,0x00,0x95};  SD_CARD_Port_Init();    usleep(1000);  SD_CARD_DEBUG(("SD-CARD Init!\n"));  gSD_CARDInit=TRUE; // Set init flag of SD-CARD    for(i=0;i<10;i++) SD_CARD_Write_Byte(0xff);// send 74 clock at least!!!  // write CMD0 to SD-CARD  retry=0;  do  { // retry 200 times to write CMD0    temp=SD_CARD_Write_CMD(CMD);    retry++;    if(retry==200) return INIT_CMD0_ERROR;// CMD0 error!  }  while(temp!=1);  //write CMD1 to SD-CARD  CMD[0]=0x41;// Command 1  CMD[5]=0xFF;  retry=0;  do  { // retry 100 times to write CMD1    temp=SD_CARD_Write_CMD(CMD);    retry++;    if(retry==100)  return INIT_CMD1_ERROR;// CMD1 error!  }  while(temp!=0);  gSD_CARDInit=FALSE; // clear init flag of SD-CARD  sd_nCS=1; // disable SD-CARD  SD_CARD_DEBUG(("SD-CARD Init Suc!\n"));  return 0x55;// All commands have been taken.}// writing a Block(512Byte, 1 sector) to SD-CARD// return 0 if sector writing is completed.u8 SD_CARD_Write_Sector(u32 addr,u8 *buf){  u8 temp,retry;  u16 i;  // CMD24 for writing blocks  u8 CMD[]={0x58,0x00,0x00,0x00,0x00,0xFF};  SD_CARD_DEBUG(("Write A Sector Starts!!\n"));  addr=addr << 9;// addr=addr * 512  CMD[1]=((addr & 0xFF000000) >>24 );  CMD[2]=((addr & 0x00FF0000) >>16 );  CMD[3]=((addr & 0x0000FF00) >>8 );  // write CMD24 to SD-CARD(write 1 block/512 bytes, 1 sector)  retry=0;  do  { // retry 100 times to write CMD24    temp=SD_CARD_Write_CMD(CMD);    retry++;    if(retry==100) return(temp);//CMD24 error!  }  while(temp!=0);  // before writing, send 100 clock to SD-CARD  for(i=0;i<100;i++) SD_CARD_Read_Byte();  // write start byte to SD-CARD  SD_CARD_Write_Byte(0xFE);  SD_CARD_DEBUG(("\n"));  // now write real bolck data(512 bytes) to SD-CARD  for(i=0;i<512;i++) SD_CARD_Write_Byte(*buf++);  SD_CARD_DEBUG(("CRC-Byte\n"));  SD_CARD_Write_Byte(0xFF);// dummy CRC  SD_CARD_Write_Byte(0xFF);// dummy CRC  // read response  temp=SD_CARD_Read_Byte();  if( (temp & 0x1F)!=0x05 ) // data block accepted ?  {    sd_nCS=1; // disable SD-CARD    return WRITE_BLOCK_ERROR;// error!  }  // wait till SD-CARD is not busy  while(SD_CARD_Read_Byte()!=0xff){};  sd_nCS=1; // disable SD-CARD  SD_CARD_DEBUG(("Write Sector suc!!\n"));  return 0;}// read bytes in a block(normally 512KB, 1 sector) from SD-CARD// return 0 if no error.u8 SD_CARD_Read_Sector(u8 *CMD,u8 *buf,u16 n_bytes){  u16 i;  u8 retry,temp;  // write CMD to SD-CARD  retry=0;  do  { // Retry 100 times to write CMD    temp=SD_CARD_Write_CMD(CMD);    retry++;    if(retry==100) return READ_BLOCK_ERROR;// block read error!  }  while(temp!=0);  // read start byte form SD-CARD (0xFE/Start Byte)  while(SD_CARD_Read_Byte()!=0xfe);  // read bytes in a block(normally 512KB, 1 sector) from SD-CARD  for(i=0;i<n_bytes;i++)  *buf++=SD_CARD_Read_Byte();  SD_CARD_Read_Byte();// dummy CRC  SD_CARD_Read_Byte();// dummy CRC  sd_nCS=1; // disable SD-CARD  return 0;}// return: [0]-success or something error!u8 SD_CARD_Read_Sector_Start(u32 sector){  u8 retry;  // CMD16 for reading Blocks  u8 CMD[]={0x51,0x00,0x00,0x00,0x00,0xFF};  u8 temp;  // address conversation(logic block address-->byte address)  sector=sector << 9;// sector=sector * 512  CMD[1]=((sector & 0xFF000000) >>24 );  CMD[2]=((sector & 0x00FF0000) >>16 );  CMD[3]=((sector & 0x0000FF00) >>8 );  // write CMD16 to SD-CARD  retry=0;  do  {    temp=SD_CARD_Write_CMD(CMD);    retry++;    if(retry==100) return READ_BLOCK_ERROR;// READ_BLOCK_ERROR  }  while( temp!=0 );    // read start byte form SD-CARD (feh/start byte)  while (SD_CARD_Read_Byte() != 0xfe);  SD_CARD_DEBUG(("Open a Sector Succ!\n"));  gSectorOpened=TRUE;  return 0;}void SD_CARD_Read_Data(u16 n_bytes,u8 *buf){  u16 i;  for(i=0;((i<n_bytes) && (gByteOffset<512));i++)  {    *buf++=SD_CARD_Read_Byte();    gByteOffset++;// increase byte offset in a sector  }  if(gByteOffset==512)  {     SD_CARD_Read_Byte(); // Dummy CRC    SD_CARD_Read_Byte(); // Dummy CRC    gByteOffset=0;       // clear byte offset in a sector    gSectorOffset++;     // one sector is read completely    gSectorOpened=FALSE; // set to 1 when a sector is opened    sd_nCS=1;            // disable SD-CARD  }}// read block date by logic block address(sector offset)void SD_CARD_Read_Data_LBA(u32 LBA,u16 n_bytes,u8 *buf){ // if one sector is read completely; open the next sector  if(gByteOffset==0) SD_CARD_Read_Sector_Start(LBA);  SD_CARD_Read_Data(n_bytes,buf);}// dummy read out the rest bytes in a sectorvoid SD_CARD_Read_Sector_End(){  u8 temp[1];  while((gByteOffset!=0x00) | (gSectorOpened==TRUE))    SD_CARD_Read_Data(1,temp); // dummy read  }// read CSD registers of SD-CARD// return 0 if no error.u8 SD_CARD_Read_CSD(u8 *buf){ // command for reading CSD registers  u8 CMD[]={0x49,0x00,0x00,0x00,0x00,0xFF};  return SD_CARD_Read_Sector(CMD,buf,16);// read 16 bytes}// read CID register of SD-CARD// return 0 if no error.u8 SD_CARD_Read_CID(u8 *buf){ // command for reading CID registers  u8 CMD[]={0x4A,0x00,0x00,0x00,0x00,0xFF};  return SD_CARD_Read_Sector(CMD,buf,16);//read 16 bytes}void SD_CARD_Get_Info(void){  CID_Info_STR CID;  CSD_Info_STR CSD;  SD_CARD_Read_CID(CID.data);  SD_CARD_DEBUG(("SD-CARD CID:\n"));  SD_CARD_DEBUG(("  Manufacturer ID(MID): 0x%.2X\n", CID.MID));  SD_CARD_DEBUG(("  OEM/Application ID(OLD): %c%c\n", CID.OLD[0], CID.OLD[1]));  SD_CARD_DEBUG(("  Product Name(PNM): %c%c%c%c%c\n", CID.PNM[0], CID.PNM[1], CID.PNM[2], CID.PNM[3], CID.PNM[4]));  SD_CARD_DEBUG(("  Product Revision: 0x%.2X\n", CID.PRV));  SD_CARD_DEBUG(("  Serial Number(PSN): 0x%.2X%.2X%.2X%.2X\n", CID.PSN[0], CID.PSN[1], CID.PSN[2], CID.PSN[3]));  SD_CARD_DEBUG(("  Manufacture Date Code(MDT): 0x%.1X%.2X\n", CID.MDT[0] & 0x0F, CID.MDT[1]));  SD_CARD_DEBUG(("  CRC-7 Checksum(CRC7):0x%.2X\n", CID.CRC >> 1));  SD_CARD_Read_CSD(CSD.data);  CSD.C_SIZE = ((CSD.data[6]&0x03) << 10) | (CSD.data[7] << 2) | ((CSD.data[8]&0xC0) >>6);  CSD.C_SIZE_MULT = ((CSD.data[9]&0x03) << 1) | ((CSD.data[10]&0x80) >> 7);  CSD.READ_BL_LEN = (CSD.data[5]&0x0F);  CSD.capacity_MB = (((CSD.C_SIZE)+1) << (((CSD.C_SIZE_MULT) +2) + (CSD.READ_BL_LEN))) >> 20;  SD_CARD_DEBUG(("SD-CARD CSD:\n"));  SD_CARD_DEBUG(("  max.read data block length: %d\n", 1<<CSD.READ_BL_LEN));  SD_CARD_DEBUG(("  device size: %d\n", CSD.C_SIZE));  SD_CARD_DEBUG(("  device size multiplier: %d\n", CSD.C_SIZE_MULT));  SD_CARD_DEBUG(("  device capacity: %d MB\n", CSD.capacity_MB));}void SD_CARD_DEMO(void){  u16 i;  u8 buf[512];  // init SD-CARD  while(SD_CARD_Init() != 0x55);  // Get CID & CSD  SD_CARD_Get_Info();  // read the 1st block(sector) of SD-Card  SD_CARD_Read_Data_LBA(0,512,buf);  for(i=0; i<512; i++)  {    SD_CARD_DEBUG(("%.2X ", buf[i]));    if((i+1) % 16 == 0) SD_CARD_DEBUG(("\n"));  }}

The source code is very long. I will briefly describe the important points.

Row 3 declares a global bool variable bool gSD_CARDInit = FALSE. We set this variable to one or zero in the u8 SD_CARD_Init () function, and then in the void SD_CARD_Write_Byte (u8 byte) Function) and u8 SD_CARD_Read_Byte () detect this variable to achieve slow speed SPI initialization SD card.

Let's take void SD_CARD_Write_Byte (u8 byte) for instructions.

// read a byte to SD-CARDu8 SD_CARD_Read_Byte(){  u8 i,byte;  byte=0;  for(i=0;i<8;i++)  { // MSB First    sd_CLK=0;if(gSD_CARDInit) SD_CARD_INIT_DELAY;    byte<<=1;if(sd_DOUT) byte++;    sd_CLK=1;if(gSD_CARDInit) SD_CARD_INIT_DELAY;  }  return byte;}

Because the GPIO is used to simulate the SPI bus, while the GPIO of the nio ii (100 MHz Nios/f) is slow, the speed of 25 MHz can be achieved without delay. However, you must use

For a clock lower than kHz, You need to insert a proper delay. I have mentioned before that the latency of the niosii is inaccurate. Therefore, the latency needs to be debugged multiple times. In row 23rd, I used a macro to set the latency for insertion.

Because the CID register information is aligned with the byte information, 27th ~ 40 rows, using a consortium to store CID registers. The CSD registers are scattered, so the consortium is not used, but the struct (44th ~ 51 rows) to store information. This is mainly intended to facilitate understanding, but it is a waste of storage.

In the void SD_CARD_DEMO (void) function of Row 3, initialize the SD card and then read the content of its 326th blocks (slices.

For details about the Register structure, storage structure, and command system of SD (SPI), read the relevant information carefully.

Step 3 call the SD card driver Function

Code 3.1 main. c

# Include <stdio. h> // printf () # include <unistd. h> // usleep () # include "my_types.h" // data type # include "debug. h "// debug # include" sd_card.h "# define ENABLE_APP_DEBUG // turn on debug message # ifdef ENABLE_APP_DEBUG # define APP_DEBUG (x) DEBUG (x) # else # define APP_DEBUG (x) # endifint main (void) {SD_CARD_DEMO (); while (1) {} return 0 ;}

The jtag-uart printed information is as follows.

(Yellow indicates the SD card initialization debugging information, Green indicates the CID register information, and blue indicates the CSD register information)

(0th slice content)

Next we will use WinHex to read the content of the first sector of the SD card. Pay attention to the comparison.

 

The comparison data shows that the SD_CARD_Read_Data_LBA function can read SD card blocks.

Other problems

The following describes how to read binary files from the SD card. I will first create a file using nots3++ (or notepad), save it as a location of the SD card, and name it test. bin.

For simplicity, I directly save sd_card.h to my SD card (FAT32 format), Named test. bin.

 

(View the properties of test. bin)

File data within FAT16/32It is always stored continuously from the 0th byte of a sector.If the file is large, n slices need to be stored consecutively. Note that if the last slice is not full, add 0. By viewing the attributes, we can see that the file size of test. bin is 718 bytes, that is, 718/512 = 1.4 is required, and 2 is used, that is, two sectors. The following uses WinHex to view how the file data is stored. Crtl + F7: Open the directory viewer and select the test. binfile. Note that the id of test. bin and the slice address displayed in the lower left corner are transplanted. Drag

Drag the text until the end of the text. Observe and, that is, occupy two sectors: 81,336th and 81337. If you know the sector address and the byte offset in the sector, you can use the void SD_CARD_Read_Data_LBA (u32 LBA, 2010n_bytes, u8 * buf) function to read the desired data.

 

Source code download

LCD _at_nios_nii_part.zip

Directory

1 [original] [serialization]. A simple digital photo frame based on FPGA-Quartus II (hardware)

2 [original] [serialization]. Simple Digital Photo Frame Based on the System-nioii SBTE part (software part)-Configuration

3 [original] [serialization]. Simple Digital Photo Frame Based on FPGA-nioii SBTE part (software part)-SD card (SPI mode) Driver

4 [original] [serialization]. Easy digital photo frame based on systems-nioii SBTE part (software part)-TFT-LCD (ILI9325 Controller) Drive

5 [original] [serialization]. A simple digital photo frame based on FPGA-nioii SBTE part (software part)-read image files from the SD card and then display on the TFT-LCD

6 [original] [serialization]. Simple Digital Photo Frame Based on the System-nioii SBTE part (software part)-Optimization

7 [original] [serialization]. Easy Digital Photo Frame Based on FPGA-nioii SBTE part (software part)-ADS7843 touch screen driver test

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