CUBEBITE
161007_BDK_EEPROM
Dependencies: mbed
Fork of
161006_BDK_SPImaster
by 
CUBEBITE
main.cpp
- Committer:
- bcup
- Date:
- 2016-10-07
- Revision:
- 7:d2710f5d6f66
- Parent:
- 6:50376de8d756
- Child:
- 8:2599e5a13e05
File content as of revision 7:d2710f5d6f66:
#include "mbed.h"
#include <SPI.h>
#define DEBUG_SPI
#ifdef DEBUG_SPI
#define PRINTD(arg1,arg2...) printf(arg1,##arg2)
#endif
#define SPI_MOSI PA_7
#define SPI_MISO PA_6
#define SPI_SCLK PA_5
#define SPI_SSEL PA_4
SPI spi_master(SPI_MOSI,SPI_MISO,SPI_SCLK); // MOSI, MISO, SCLK(CLK,SCK)
DigitalOut cs(SPI_SSEL);
Serial pc_serial(USBTX, USBRX);
void SPI_INIT()
{
pc_serial.printf("Set SPI init..\n");
pc_serial.printf("Set SPI format..\n");
spi_master.format(8,0);
pc_serial.printf("Set frequency to default..\n");
//spi_master.frequency(50000000); // default 1MHz
spi_master.frequency(1000000);
}
/*
void SPI_Write()
{
char temp;
int i,value;
char response;
char tx_cnt = -1;
char rx_cnt = -1;
char tx_buffer[255]={0};
char rx_buffer[255]={0};
PRINTD("\n==========MASTER==========\n");
PRINTD("DATA SEND START...\n");
PRINTD("Lock SPI BUS..\n");
while(1)
{
temp=getchar();
tx_buffer[++tx_cnt]=temp;
if(temp==0x0d)
{
tx_buffer[tx_cnt]=0;
PRINTD("\nData send Finish...\n");
for(i=0;i<=tx_cnt;++i)
{
PRINTD("%c[%02x]",tx_buffer[i],tx_buffer[i]);
}
PRINTD("\n\n");
spi_master.lock();
for(i=0;i<=tx_cnt;++i)
{
value=tx_buffer[i];
PRINTD("[M]write[%d]=%c[%02x]\n",i,value,value);
cs=0;
response=spi_master.write(value);
cs=-1;
PRINTD("[M]receive=%c[%x]\n",response,response);
rx_buffer[++rx_cnt]=response;
}
spi_master.unlock();
for(i=0;i<255;++i)
{
tx_buffer[i]=0;
}
for(i=0;i<=tx_cnt;i++)
{
PRINTD("init_tx_buffer[%d]=%c\n",i,tx_buffer[i]);
}
tx_cnt=-1;
}
else
{
PRINTD("%c[%02x]",tx_buffer[tx_cnt],tx_buffer[tx_cnt]);
}
}
}
*/
#define EEPROM_WREN 0x06 // Write Enable
#define EEPROM_WRDI 0x04 // Write Disable
#define EEPROM_RDSR 0x05 // Read Status Register
#define EEPROM_WRSR 0x01 // Write Status Register
#define EEPROM_READ 0x03 // Read EEPROM Memory
#define EEPROM_WRITE 0x02 // Write EEPROM Memory
#define EEPROM_MULTIREAD 0x07 // Write EEPROM Memory
enum cubeMenu { EEPROM_Write_Enable = 1 ,
EEPROM_Write_Disable,
EEPROM_Read_Status,
EEPROM_Write_Status,
EEPROM_Write_Memory,
EEPROM_Read_Memory,
TEST_Multi_Byte_Read,
EXIT_Program = 9
};
void print_menu(void)
{
pc_serial.printf("\n\n\n\n\n\n\n");
pc_serial.printf("-----------[MENU]----------\n");
pc_serial.printf("1) Write Enable\n");//, cubeMenu.EEPROM_Write_Enable);
pc_serial.printf("2) Write Disable\n");//, cubeMenu.EEPROM_Write_Disable);
pc_serial.printf("3) Read Status Register\n");//, cubeMenu.EEPROM_Read_Status);
pc_serial.printf("4) Write Status Register\n");//,cubeMenu.EEPROM_Write_Status);
pc_serial.printf("5) Write Memory\n");//, cubeMenu.EEPROM_Write_Memory);
pc_serial.printf("6) Read Memory\n");//, cubeMenu.EEPROM_Read_Memory);
pc_serial.printf("7) multi byte read\n");//, cubeMenu.TEST_Multi_Byte_Read);
pc_serial.printf("9) Exit program\n");//, cubeMenu.EXIT_Program);
pc_serial.printf("---------------------------\n");
pc_serial.printf("input menu : ");
}
void spi_start(void)
{
spi_master.lock();
cs = 0;
wait_us(0);
}
void spi_end(void)
{
wait_us(10);
cs = 1;
spi_master.unlock();
}
void spi_dummy_write(void)
{
char dummy_read;
spi_start();
dummy_read = spi_master.write( 0x00 );
spi_end();
}
/*
@convertedData : converted Data
@sourceBuf : ASCII data array
@lenght : sourceBuf length
@return : 0 is valid hex format, other is error
*/
int converHex(char * convertedData, char * sourceBuf, int length)
{
int ret = 0;
char tempBuf[length];
*convertedData = 0;
for(int iCnt = 0 ; iCnt < length ; iCnt++)
{
if( ('0' <= *(sourceBuf+iCnt)) && ('9' >= *(sourceBuf+iCnt)) )
{
tempBuf[iCnt] = (*(sourceBuf+iCnt) - 48);
}
else if( ('A' <= *(sourceBuf+iCnt)) && ('F' >= *(sourceBuf+iCnt)) )
{
tempBuf[iCnt] = (*(sourceBuf+iCnt) - 55);
}
else if( ('a' <= *(sourceBuf+iCnt)) && ('f' >= *(sourceBuf+iCnt)) )
{
tempBuf[iCnt] = (*(sourceBuf+iCnt) - 87);
}
else // error
{
ret = -1;
return ret;
}
}
//pc_serial.printf("[TEST] tempBuf[0] = 0x%02X\n", tempBuf[0]);
//pc_serial.printf("[TEST] tempBuf[1] = 0x%02X\n", tempBuf[1]);
*convertedData = ((tempBuf[0] & 0x0F) << 4) | (tempBuf[1] & 0x0F);
//pc_serial.printf("[TEST] convertedData = 0x%02X\n", *convertedData);
return ret;
}
// @@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@ main();
int main()
{
char dummyRead;
char inputMenuNum = 0;
char statusReg = 0x00;
char test_data[10]={0};
int spiTxCnt = 0;
int spiRxCnt = 0;
char spiTxReadyFlag = 0;
int res;
int spiRxTempBuf = 0;
char serialRxBuf[255];
char spiRxBuf[255];
int serialRxLen = 0;
char eepAddrBuf[2] = {0};
char eepAddr = 0;
char eepDataBuf[2] = {0};
char eepData = 0;
int eepReadData = 0;
int maxInputCnt = 0;
int ret;
SPI_INIT();
spi_dummy_write();
pc_serial.printf("\n\n========== SPI Master for EEPROM [Start] ==========\n");
while(1)
{
print_menu();
inputMenuNum = pc_serial.getc();
pc_serial.printf("[DEBUG] input menu number = %c\n", inputMenuNum);
if( ('0' < inputMenuNum) && ('9' >= inputMenuNum) )
{
inputMenuNum = inputMenuNum - 48;
}
else
{
pc_serial.printf("[INFO] correct input menu number.. please retry..\n");
wait(1);
continue;
}
spi_start();
switch(inputMenuNum)
{
case 1: // Write Enable =================================[OK]
pc_serial.printf("[DEBUG] Write Enable progress..\n");
dummyRead = spi_master.write(EEPROM_WREN);
break;
case 2: // Write Disable =================================[OK]
pc_serial.printf("[DEBUG] Write Disable progress..\n");
dummyRead = spi_master.write(EEPROM_WRDI);
break;
case 3: // Read Status Register =================================[OK]
pc_serial.printf("[DEBUG] Read Status Register progress..\n");
spi_master.write(EEPROM_RDSR);
statusReg = spi_master.write(EEPROM_RDSR);
// TODO : print statusReg data to serial
pc_serial.printf("[INFO] Status Register Data : 0x%02X\n", statusReg);
break;
case 4: // Write Status Register =================================
pc_serial.printf("[DEBUG] Write Status Register progress..\n");
// TODO : input data for serial
spi_master.write(EEPROM_WRSR);
spi_master.write(statusReg);
break;
case 5: // Write Memory =================================
pc_serial.printf("[DEBUG] Write Memory progress..\n");
// EEPROM Address input
maxInputCnt = 3;
while(maxInputCnt--)
{
pc_serial.printf("input Address (hex format : 00~FF) : ");
for(int iCnt = 0 ; iCnt < 2 ; ++iCnt)
{
eepAddrBuf[iCnt] = pc_serial.getc();
pc_serial.printf("%c", eepAddrBuf[iCnt]);
}
ret = converHex(&eepAddr , eepAddrBuf, 2);
if(0 == ret)
{
//pc_serial.printf("\n[DEBUG] before convert hex [0x%02x] \n", eepAddr);
break;
}
else // error
{
pc_serial.printf("\n[INFO] hex formet error!\n");
continue;
}
}
if(0 == ret)
{
// EEPROM data input
maxInputCnt = 3;
while(maxInputCnt--)
{
pc_serial.printf("\ninput Data (hex format : 00~FF) : ");
for(int iCnt = 0 ; iCnt < 2 ; ++iCnt)
{
eepDataBuf[iCnt] = pc_serial.getc();
pc_serial.printf("%c", eepDataBuf[iCnt]);
}
int ret = converHex(&eepData , eepDataBuf, 2);
if(0 == ret)
{
pc_serial.printf("\n[INFO] SPI Write Memory.... Start! \n");
//pc_serial.printf("\n[DEBUG] Addr[0x%02X] Data[0x%02X] \n", eepAddr, eepData);
spi_master.write(EEPROM_RDSR);
if(! (spi_master.write(EEPROM_RDSR) & 0x01) )
{
spi_master.write(EEPROM_WRITE);
spi_master.write(eepAddr);
spi_master.write(eepData);
pc_serial.printf("\n[INFO] SPI Write success \n");
}
else
{
pc_serial.printf("\n[INFO] SPI Write fail.. device is busy! \n");
}
break;
}
else // error
{
pc_serial.printf("\n[INFO] hex formet error!\n");
continue;
}
}
}
break;
case 6: // Read Memory =================================
pc_serial.printf("[DEBUG] Read Memory progress..\n");
// EEPROM Address input
maxInputCnt = 3;
while(maxInputCnt--)
{
pc_serial.printf("input Address (hex format : 00~FF) : ");
for(int iCnt = 0 ; iCnt < 2 ; ++iCnt)
{
eepAddrBuf[iCnt] = pc_serial.getc();
pc_serial.printf("%c", eepAddrBuf[iCnt]);
}
ret = converHex(&eepAddr , eepAddrBuf, 2);
if(0 == ret)
{
//pc_serial.printf("\n[DEBUG] before convert hex [0x%02x] \n", eepAddr);
spi_master.write(EEPROM_READ);
spi_master.write(eepAddr);
eepReadData = spi_master.write(0);
pc_serial.printf("\n[DEBUG] Read EEPROM Addr[0x%02X] Data[0x%02X] \n", eepAddr, eepReadData);
break;
}
else // error
{
pc_serial.printf("\n[INFO] hex formet error!\n");
continue;
}
}
break;
case 7:
pc_serial.printf("\n[DEBUG] TEST_Multi_Byte_Read\n");
maxInputCnt = 3;
while(maxInputCnt--)
{
pc_serial.printf("input Address (hex format : 00~FF) : ");
for(int iCnt = 0 ; iCnt < 2 ; ++iCnt)
{
eepAddrBuf[iCnt] = pc_serial.getc();
pc_serial.printf("%c", eepAddrBuf[iCnt]);
}
ret = converHex(&eepAddr , eepAddrBuf, 2);
if(0 == ret)
{
spi_master.write(EEPROM_MULTIREAD);
spi_master.write(eepAddr);
for(int i=0;i<10;i++)
{
//test_data[i] = spi_master.write(0);
//spi_master.write(++eepAddr);
test_data[i] = spi_master.write(0);
}
for(int i=0;i<10;i++)
{
printf("\n[DEBUG] Read EEPROM Data[0x%02X]\n",test_data[i]);
}
//pc_serial.printf("\n[DEBUG] Read EEPROM Addr[0x%02X]\n", eepAddr);
break;
}
else // error
{
pc_serial.printf("\n[INFO] hex formet error!\n");
continue;
}
}
break;
case 9:
spi_end();
pc_serial.printf("exit program... thank you\n");
//return 0;
default:
}
spi_end();
}
while(1)
{
if(0 != pc_serial.readable()) // wait serial input..
{
pc_serial.scanf("%s", serialRxBuf);
serialRxLen = strlen(serialRxBuf);
pc_serial.printf("len=[%d] %s\n", serialRxLen, serialRxBuf);
spiTxReadyFlag = 1;
}
if(1 == spiTxReadyFlag)
{
// SPI Send Start
spi_master.lock();
cs = 0;
for(spiTxCnt = 0 ; spiTxCnt < serialRxLen + 1 ; ++spiTxCnt)
{
//printf("send Cnt[%d] [0x%02X]\n", spiTxCnt, serialRxBuf[spiTxCnt]);
spi_master.write(serialRxBuf[spiTxCnt]);
//res=spi_master.write(serialRxBuf[spiTxCnt]);
//PRINTD("res=%c 0x[%02x]\n",res,res);
//spiRxBuf[spiRxCnt++]=res;
}
cs = 1;
spi_master.unlock();
spiTxReadyFlag = 0;
}
/* TODO " ----(SPI)-----> master --> serial " */
#if 0
if(res!=0)
{
PRINTD("res=%d\n",res);
PRINTD("res=%s\n",spiRxBuf);
}
#endif
}
#if 0 // 161005_BDK_backup2 start
int send_data;
SPI_INIT();
while(1)
{
SPI_Write();
}
#endif // 161005_BDK_backup2 end
return 0;
}