board/bf537-stamp/stm_m25p64.c - github/trini/u-boot - Gitiles

 /****************************************************************************
  *  SPI flash driver for M25P64
  ****************************************************************************/
 #include <common.h>
 #include <linux/ctype.h>
 #include <asm/io.h>

 #if defined(CONFIG_SPI)

 /* Application definitions */

 #define	NUM_SECTORS	128	/* number of sectors */
 #define SECTOR_SIZE	0x10000
 #define NOP_NUM		1000

 #define COMMON_SPI_SETTINGS (SPE|MSTR|CPHA|CPOL) /* Settings to the SPI_CTL */
 #define TIMOD01 (0x01)	/* stes the SPI to work with core instructions */

 /* Flash commands */
 #define	SPI_WREN	(0x06)	/*Set Write Enable Latch */
 #define	SPI_WRDI	(0x04)	/*Reset Write Enable Latch */
 #define	SPI_RDSR	(0x05)	/*Read Status Register */
 #define	SPI_WRSR	(0x01)	/*Write Status Register */
 #define	SPI_READ	(0x03)	/*Read data from memory */
 #define	SPI_FAST_READ	(0x0B)	/*Read data from memory */
 #define	SPI_PP		(0x02)	/*Program Data into memory */
 #define	SPI_SE		(0xD8)	/*Erase one sector in memory */
 #define	SPI_BE		(0xC7)	/*Erase all memory */
 #define	WIP		(0x1)	/*Check the write in progress bit of the SPI status register */
 #define	WEL		(0x2)	/*Check the write enable bit of the SPI status register */

 #define	TIMEOUT		350000000

 typedef enum {
 	NO_ERR,
 	POLL_TIMEOUT,
 	INVALID_SECTOR,
 	INVALID_BLOCK,
 } ERROR_CODE;

 void spi_init_f(void);
 void spi_init_r(void);
 ssize_t spi_read(uchar *, int, uchar *, int);
 ssize_t spi_write(uchar *, int, uchar *, int);

 char ReadStatusRegister(void);
 void Wait_For_SPIF(void);
 void SetupSPI(const int spi_setting);
 void SPI_OFF(void);
 void SendSingleCommand(const int iCommand);

 ERROR_CODE GetSectorNumber(unsigned long ulOffset, int *pnSector);
 ERROR_CODE EraseBlock(int nBlock);
 ERROR_CODE ReadData(unsigned long ulStart, long lCount, int *pnData);
 ERROR_CODE WriteData(unsigned long ulStart, long lCount, int *pnData);
 ERROR_CODE Wait_For_Status(char Statusbit);
 ERROR_CODE Wait_For_WEL(void);

 /*
  * Function:    spi_init_f
  * Description: Init SPI-Controller (ROM part)
  * return:      ---
  */
 void spi_init_f(void)
 {
 }

 /*
  * Function:    spi_init_r
  * Description: Init SPI-Controller (RAM part) -
  *		 The malloc engine is ready and we can move our buffers to
  *		 normal RAM
  *  return:      ---
  */
 void spi_init_r(void)
 {
 	return;
 }

 /*
  * Function:    spi_write
  */
 ssize_t spi_write(uchar * addr, int alen, uchar * buffer, int len)
 {
 	unsigned long offset;
 	int start_block, end_block;
 	int start_byte, end_byte;
 	ERROR_CODE result = NO_ERR;
 	uchar temp[SECTOR_SIZE];
 	int i, num;

 	offset = addr[0] << 16 | addr[1] << 8 | addr[2];
 	/* Get the start block number */
 	result = GetSectorNumber(offset, &start_block);
 	if (result == INVALID_SECTOR) {
 		printf("Invalid sector! ");
 		return 0;
 	}
 	/* Get the end block number */
 	result = GetSectorNumber(offset + len - 1, &end_block);
 	if (result == INVALID_SECTOR) {
 		printf("Invalid sector! ");
 		return 0;
 	}

 	for (num = start_block; num <= end_block; num++) {
 		ReadData(num * SECTOR_SIZE, SECTOR_SIZE, (int *)temp);
 		start_byte = num * SECTOR_SIZE;
 		end_byte = (num + 1) * SECTOR_SIZE - 1;
 		if (start_byte < offset)
 			start_byte = offset;
 		if (end_byte > (offset + len))
 			end_byte = (offset + len - 1);
 		for (i = start_byte; i <= end_byte; i++)
 			temp[i - num * SECTOR_SIZE] = buffer[i - offset];
 		EraseBlock(num);
 		result = WriteData(num * SECTOR_SIZE, SECTOR_SIZE, (int *)temp);
 		if (result != NO_ERR)
 			return 0;
 		printf(".");
 	}
 	return len;
 }

 /*
  * Function: spi_read
  */
 ssize_t spi_read(uchar * addr, int alen, uchar * buffer, int len)
 {
 	unsigned long offset;
 	offset = addr[0] << 16 | addr[1] << 8 | addr[2];
 	ReadData(offset, len, (int *)buffer);
 	return len;
 }

 void SendSingleCommand(const int iCommand)
 {
 	unsigned short dummy;

 	/* turns on the SPI in single write mode */
 	SetupSPI((COMMON_SPI_SETTINGS | TIMOD01));

 	/* sends the actual command to the SPI TX register */
 	*pSPI_TDBR = iCommand;
 	sync();

 	/* The SPI status register will be polled to check the SPIF bit */
 	Wait_For_SPIF();

 	dummy = *pSPI_RDBR;

 	/* The SPI will be turned off */
 	SPI_OFF();

 }

 void SetupSPI(const int spi_setting)
 {

 	if (icache_status() || dcache_status())
 		udelay(CONFIG_CCLK_HZ / 50000000);
 	/*sets up the PF10 to be the slave select of the SPI */
 	*pPORTF_FER |= (PF10 | PF11 | PF12 | PF13);
 	*pSPI_FLG = 0xFF02;
 	*pSPI_BAUD = CONFIG_SPI_BAUD;
 	*pSPI_CTL = spi_setting;
 	sync();

 	*pSPI_FLG = 0xFD02;
 	sync();
 }

 void SPI_OFF(void)
 {

 	*pSPI_CTL = 0x0400;	/* disable SPI */
 	*pSPI_FLG = 0;
 	*pSPI_BAUD = 0;
 	sync();
 	udelay(CONFIG_CCLK_HZ / 50000000);

 }

 void Wait_For_SPIF(void)
 {
 	unsigned short dummyread;
 	while ((*pSPI_STAT & TXS)) ;
 	while (!(*pSPI_STAT & SPIF)) ;
 	while (!(*pSPI_STAT & RXS)) ;
 	/* Read dummy to empty the receive register */
 	dummyread = *pSPI_RDBR;
 }

 ERROR_CODE Wait_For_WEL(void)
 {
 	int i;
 	char status_register = 0;
 	ERROR_CODE ErrorCode = NO_ERR;

 	for (i = 0; i < TIMEOUT; i++) {
 		status_register = ReadStatusRegister();
 		if ((status_register & WEL)) {
 			ErrorCode = NO_ERR;
 			break;
 		}
 		ErrorCode = POLL_TIMEOUT;	/* Time out error */
 	};

 	return ErrorCode;
 }

 ERROR_CODE Wait_For_Status(char Statusbit)
 {
 	int i;
 	char status_register = 0xFF;
 	ERROR_CODE ErrorCode = NO_ERR;

 	for (i = 0; i < TIMEOUT; i++) {
 		status_register = ReadStatusRegister();
 		if (!(status_register & Statusbit)) {
 			ErrorCode = NO_ERR;
 			break;
 		}
 		ErrorCode = POLL_TIMEOUT;	/* Time out error */
 	};

 	return ErrorCode;
 }

 char ReadStatusRegister(void)
 {
 	char status_register = 0;

 	SetupSPI((COMMON_SPI_SETTINGS | TIMOD01));	/* Turn on the SPI */

 	*pSPI_TDBR = SPI_RDSR;	/* send instruction to read status register */
 	sync();
 	Wait_For_SPIF();	/*wait until the instruction has been sent */
 	*pSPI_TDBR = 0;		/*send dummy to receive the status register */
 	sync();
 	Wait_For_SPIF();	/*wait until the data has been sent */
 	status_register = *pSPI_RDBR;	/*read the status register */

 	SPI_OFF();		/* Turn off the SPI */

 	return status_register;
 }

 ERROR_CODE GetSectorNumber(unsigned long ulOffset, int *pnSector)
 {
 	int nSector = 0;
 	ERROR_CODE ErrorCode = NO_ERR;

 	if (ulOffset > (NUM_SECTORS * 0x10000 - 1)) {
 		ErrorCode = INVALID_SECTOR;
 		return ErrorCode;
 	}

 	nSector = (int)ulOffset / 0x10000;
 	*pnSector = nSector;

 	return ErrorCode;
 }

 ERROR_CODE EraseBlock(int nBlock)
 {
 	unsigned long ulSectorOff = 0x0, ShiftValue;
 	ERROR_CODE ErrorCode = NO_ERR;

 	/* if the block is invalid just return */
 	if ((nBlock < 0) || (nBlock > NUM_SECTORS)) {
 		ErrorCode = INVALID_BLOCK;
 		return ErrorCode;
 	}
 	/* figure out the offset of the block in flash */
 	if ((nBlock >= 0) && (nBlock < NUM_SECTORS)) {
 		ulSectorOff = (nBlock * SECTOR_SIZE);

 	} else {
 		ErrorCode = INVALID_BLOCK;
 		return ErrorCode;
 	}

 	/* A write enable instruction must previously have been executed */
 	SendSingleCommand(SPI_WREN);

 	/* The status register will be polled to check the write enable latch "WREN" */
 	ErrorCode = Wait_For_WEL();

 	if (POLL_TIMEOUT == ErrorCode) {
 		printf("SPI Erase block error\n");
 		return ErrorCode;
 	} else

 	/* Turn on the SPI to send single commands */
 	SetupSPI((COMMON_SPI_SETTINGS | TIMOD01));

 	/*
 	 * Send the erase block command to the flash followed by the 24 address
 	 * to point to the start of a sector
 	 */
 	*pSPI_TDBR = SPI_SE;
 	sync();
 	Wait_For_SPIF();
 	/* Send the highest byte of the 24 bit address at first */
 	ShiftValue = (ulSectorOff >> 16);
 	*pSPI_TDBR = ShiftValue;
 	sync();
 	/* Wait until the instruction has been sent */
 	Wait_For_SPIF();
 	/* Send the middle byte of the 24 bit address  at second */
 	ShiftValue = (ulSectorOff >> 8);
 	*pSPI_TDBR = ShiftValue;
 	sync();
 	/* Wait until the instruction has been sent */
 	Wait_For_SPIF();
 	/* Send the lowest byte of the 24 bit address finally */
 	*pSPI_TDBR = ulSectorOff;
 	sync();
 	/* Wait until the instruction has been sent */
 	Wait_For_SPIF();

 	/* Turns off the SPI */
 	SPI_OFF();

 	/* Poll the status register to check the Write in Progress bit */
 	/* Sector erase takes time */
 	ErrorCode = Wait_For_Status(WIP);

 	/* block erase should be complete */
 	return ErrorCode;
 }

 /*
  * ERROR_CODE ReadData()
  * Read a value from flash for verify purpose
  * Inputs:	unsigned long ulStart - holds the SPI start address
  *			int pnData - pointer to store value read from flash
  *			long lCount - number of elements to read
  */
 ERROR_CODE ReadData(unsigned long ulStart, long lCount, int *pnData)
 {
 	unsigned long ShiftValue;
 	char *cnData;
 	int i;

 	/* Pointer cast to be able to increment byte wise */

 	cnData = (char *)pnData;
 	/* Start SPI interface */
 	SetupSPI((COMMON_SPI_SETTINGS | TIMOD01));

 #ifdef CONFIG_SPI_FLASH_FAST_READ
 	/* Send the read command to SPI device */
 	*pSPI_TDBR = SPI_FAST_READ;
 #else
 	/* Send the read command to SPI device */
 	*pSPI_TDBR = SPI_READ;
 #endif
 	sync();
 	/* Wait until the instruction has been sent */
 	Wait_For_SPIF();
 	/* Send the highest byte of the 24 bit address at first */
 	ShiftValue = (ulStart >> 16);
 	/* Send the byte to the SPI device */
 	*pSPI_TDBR = ShiftValue;
 	sync();
 	/* Wait until the instruction has been sent */
 	Wait_For_SPIF();
 	/* Send the middle byte of the 24 bit address  at second */
 	ShiftValue = (ulStart >> 8);
 	/* Send the byte to the SPI device */
 	*pSPI_TDBR = ShiftValue;
 	sync();
 	/* Wait until the instruction has been sent */
 	Wait_For_SPIF();
 	/* Send the lowest byte of the 24 bit address finally */
 	*pSPI_TDBR = ulStart;
 	sync();
 	/* Wait until the instruction has been sent */
 	Wait_For_SPIF();

 #ifdef CONFIG_SPI_FLASH_FAST_READ
 	/* Send dummy for FAST_READ */
 	*pSPI_TDBR = 0;
 	sync();
 	/* Wait until the instruction has been sent */
 	Wait_For_SPIF();
 #endif

 	/* After the SPI device address has been placed on the MOSI pin the data can be */
 	/* received on the MISO pin. */
 	for (i = 0; i < lCount; i++) {
 		*pSPI_TDBR = 0;
 		sync();
 		while (!(*pSPI_STAT & RXS)) ;
 		*cnData++ = *pSPI_RDBR;

 		if ((i >= SECTOR_SIZE) && (i % SECTOR_SIZE == 0))
 			printf(".");
 	}

 	/* Turn off the SPI */
 	SPI_OFF();

 	return NO_ERR;
 }

 ERROR_CODE WriteFlash(unsigned long ulStartAddr, long lTransferCount,
 		      int *iDataSource, long *lWriteCount)
 {

 	unsigned long ulWAddr;
 	long lWTransferCount = 0;
 	int i;
 	char iData;
 	char *temp = (char *)iDataSource;
 	ERROR_CODE ErrorCode = NO_ERR;

 	/* First, a Write Enable Command must be sent to the SPI. */
 	SendSingleCommand(SPI_WREN);

 	/*
 	 * Second, the SPI Status Register will be tested whether the
 	 * Write Enable Bit has been set
 	 */
 	ErrorCode = Wait_For_WEL();
 	if (POLL_TIMEOUT == ErrorCode) {
 		printf("SPI Write Time Out\n");
 		return ErrorCode;
 	} else
 		/* Third, the 24 bit address will be shifted out
 		 * the SPI MOSI bytewise.
 		 * Turns the SPI on
 		 */
 		SetupSPI((COMMON_SPI_SETTINGS | TIMOD01));
 	*pSPI_TDBR = SPI_PP;
 	sync();
 	/*wait until the instruction has been sent */
 	Wait_For_SPIF();
 	ulWAddr = (ulStartAddr >> 16);
 	*pSPI_TDBR = ulWAddr;
 	sync();
 	/*wait until the instruction has been sent */
 	Wait_For_SPIF();
 	ulWAddr = (ulStartAddr >> 8);
 	*pSPI_TDBR = ulWAddr;
 	sync();
 	/*wait until the instruction has been sent */
 	Wait_For_SPIF();
 	ulWAddr = ulStartAddr;
 	*pSPI_TDBR = ulWAddr;
 	sync();
 	/*wait until the instruction has been sent */
 	Wait_For_SPIF();
 	/*
 	 * Fourth, maximum number of 256 bytes will be taken from the Buffer
 	 * and sent to the SPI device.
 	 */
 	for (i = 0; (i < lTransferCount) && (i < 256); i++, lWTransferCount++) {
 		iData = *temp;
 		*pSPI_TDBR = iData;
 		sync();
 		/*wait until the instruction has been sent */
 		Wait_For_SPIF();
 		temp++;
 	}

 	/* Turns the SPI off */
 	SPI_OFF();

 	/*
 	 * Sixth, the SPI Write in Progress Bit must be toggled to ensure the
 	 * programming is done before start of next transfer
 	 */
 	ErrorCode = Wait_For_Status(WIP);

 	if (POLL_TIMEOUT == ErrorCode) {
 		printf("SPI Program Time out!\n");
 		return ErrorCode;
 	} else

 		*lWriteCount = lWTransferCount;

 	return ErrorCode;
 }

 ERROR_CODE WriteData(unsigned long ulStart, long lCount, int *pnData)
 {

 	unsigned long ulWStart = ulStart;
 	long lWCount = lCount, lWriteCount;
 	long *pnWriteCount = &lWriteCount;

 	ERROR_CODE ErrorCode = NO_ERR;

 	while (lWCount != 0) {
 		ErrorCode = WriteFlash(ulWStart, lWCount, pnData, pnWriteCount);

 		/*
 		 * After each function call of WriteFlash the counter
 		 * must be adjusted
 		 */
 		lWCount -= *pnWriteCount;

 		/* Also, both address pointers must be recalculated. */
 		ulWStart += *pnWriteCount;
 		pnData += *pnWriteCount / 4;
 	}

 	/* return the appropriate error code */
 	return ErrorCode;
 }

 #endif				/* CONFIG_SPI */
	/****************************************************************************
	* SPI flash driver for M25P64
	****************************************************************************/
	#include <common.h>
	#include <linux/ctype.h>
	#include <asm/io.h>

	#if defined(CONFIG_SPI)

	/* Application definitions */

	#define NUM_SECTORS 128 /* number of sectors */
	#define SECTOR_SIZE 0x10000
	#define NOP_NUM 1000

	#define COMMON_SPI_SETTINGS (SPE\|MSTR\|CPHA\|CPOL) /* Settings to the SPI_CTL */
	#define TIMOD01 (0x01) /* stes the SPI to work with core instructions */

	/* Flash commands */
	#define SPI_WREN (0x06) /Set Write Enable Latch /
	#define SPI_WRDI (0x04) /Reset Write Enable Latch /
	#define SPI_RDSR (0x05) /Read Status Register /
	#define SPI_WRSR (0x01) /Write Status Register /
	#define SPI_READ (0x03) /Read data from memory /
	#define SPI_FAST_READ (0x0B) /Read data from memory /
	#define SPI_PP (0x02) /Program Data into memory /
	#define SPI_SE (0xD8) /Erase one sector in memory /
	#define SPI_BE (0xC7) /Erase all memory /
	#define WIP (0x1) /Check the write in progress bit of the SPI status register /
	#define WEL (0x2) /Check the write enable bit of the SPI status register /

	#define TIMEOUT 350000000

	typedef enum {
	NO_ERR,
	POLL_TIMEOUT,
	INVALID_SECTOR,
	INVALID_BLOCK,
	} ERROR_CODE;

	void spi_init_f(void);
	void spi_init_r(void);
	ssize_t spi_read(uchar , int, uchar , int);
	ssize_t spi_write(uchar , int, uchar , int);

	char ReadStatusRegister(void);
	void Wait_For_SPIF(void);
	void SetupSPI(const int spi_setting);
	void SPI_OFF(void);
	void SendSingleCommand(const int iCommand);

	ERROR_CODE GetSectorNumber(unsigned long ulOffset, int *pnSector);
	ERROR_CODE EraseBlock(int nBlock);
	ERROR_CODE ReadData(unsigned long ulStart, long lCount, int *pnData);
	ERROR_CODE WriteData(unsigned long ulStart, long lCount, int *pnData);
	ERROR_CODE Wait_For_Status(char Statusbit);
	ERROR_CODE Wait_For_WEL(void);

	/*
	* Function: spi_init_f
	* Description: Init SPI-Controller (ROM part)
	* return: ---
	*/
	void spi_init_f(void)
	{
	}

	/*
	* Function: spi_init_r
	* Description: Init SPI-Controller (RAM part) -
	* The malloc engine is ready and we can move our buffers to
	* normal RAM
	* return: ---
	*/
	void spi_init_r(void)
	{
	return;
	}

	/*
	* Function: spi_write
	*/
	ssize_t spi_write(uchar * addr, int alen, uchar * buffer, int len)
	{
	unsigned long offset;
	int start_block, end_block;
	int start_byte, end_byte;
	ERROR_CODE result = NO_ERR;
	uchar temp[SECTOR_SIZE];
	int i, num;

	offset = addr[0] << 16 \| addr[1] << 8 \| addr[2];
	/* Get the start block number */
	result = GetSectorNumber(offset, &start_block);
	if (result == INVALID_SECTOR) {
	printf("Invalid sector! ");
	return 0;
	}
	/* Get the end block number */
	result = GetSectorNumber(offset + len - 1, &end_block);
	if (result == INVALID_SECTOR) {
	printf("Invalid sector! ");
	return 0;
	}

	for (num = start_block; num <= end_block; num++) {
	ReadData(num * SECTOR_SIZE, SECTOR_SIZE, (int *)temp);
	start_byte = num * SECTOR_SIZE;
	end_byte = (num + 1) * SECTOR_SIZE - 1;
	if (start_byte < offset)
	start_byte = offset;
	if (end_byte > (offset + len))
	end_byte = (offset + len - 1);
	for (i = start_byte; i <= end_byte; i++)
	temp[i - num * SECTOR_SIZE] = buffer[i - offset];
	EraseBlock(num);
	result = WriteData(num * SECTOR_SIZE, SECTOR_SIZE, (int *)temp);
	if (result != NO_ERR)
	return 0;
	printf(".");
	}
	return len;
	}

	/*
	* Function: spi_read
	*/
	ssize_t spi_read(uchar * addr, int alen, uchar * buffer, int len)
	{
	unsigned long offset;
	offset = addr[0] << 16 \| addr[1] << 8 \| addr[2];
	ReadData(offset, len, (int *)buffer);
	return len;
	}

	void SendSingleCommand(const int iCommand)
	{
	unsigned short dummy;

	/* turns on the SPI in single write mode */
	SetupSPI((COMMON_SPI_SETTINGS \| TIMOD01));

	/* sends the actual command to the SPI TX register */
	*pSPI_TDBR = iCommand;
	sync();

	/* The SPI status register will be polled to check the SPIF bit */
	Wait_For_SPIF();

	dummy = *pSPI_RDBR;

	/* The SPI will be turned off */
	SPI_OFF();

	}

	void SetupSPI(const int spi_setting)
	{

	if (icache_status() \|\| dcache_status())
	udelay(CONFIG_CCLK_HZ / 50000000);
	/sets up the PF10 to be the slave select of the SPI /
	*pPORTF_FER \|= (PF10 \| PF11 \| PF12 \| PF13);
	*pSPI_FLG = 0xFF02;
	*pSPI_BAUD = CONFIG_SPI_BAUD;
	*pSPI_CTL = spi_setting;
	sync();

	*pSPI_FLG = 0xFD02;
	sync();
	}

	void SPI_OFF(void)
	{

	pSPI_CTL = 0x0400; / disable SPI */
	*pSPI_FLG = 0;
	*pSPI_BAUD = 0;
	sync();
	udelay(CONFIG_CCLK_HZ / 50000000);

	}

	void Wait_For_SPIF(void)
	{
	unsigned short dummyread;
	while ((*pSPI_STAT & TXS)) ;
	while (!(*pSPI_STAT & SPIF)) ;
	while (!(*pSPI_STAT & RXS)) ;
	/* Read dummy to empty the receive register */
	dummyread = *pSPI_RDBR;
	}

	ERROR_CODE Wait_For_WEL(void)
	{
	int i;
	char status_register = 0;
	ERROR_CODE ErrorCode = NO_ERR;

	for (i = 0; i < TIMEOUT; i++) {
	status_register = ReadStatusRegister();
	if ((status_register & WEL)) {
	ErrorCode = NO_ERR;
	break;
	}
	ErrorCode = POLL_TIMEOUT; /* Time out error */
	};

	return ErrorCode;
	}

	ERROR_CODE Wait_For_Status(char Statusbit)
	{
	int i;
	char status_register = 0xFF;
	ERROR_CODE ErrorCode = NO_ERR;

	for (i = 0; i < TIMEOUT; i++) {
	status_register = ReadStatusRegister();
	if (!(status_register & Statusbit)) {
	ErrorCode = NO_ERR;
	break;
	}
	ErrorCode = POLL_TIMEOUT; /* Time out error */
	};

	return ErrorCode;
	}

	char ReadStatusRegister(void)
	{
	char status_register = 0;

	SetupSPI((COMMON_SPI_SETTINGS \| TIMOD01)); /* Turn on the SPI */

	pSPI_TDBR = SPI_RDSR; / send instruction to read status register */
	sync();
	Wait_For_SPIF(); /wait until the instruction has been sent /
	pSPI_TDBR = 0; /send dummy to receive the status register */
	sync();
	Wait_For_SPIF(); /wait until the data has been sent /
	status_register = pSPI_RDBR; /read the status register */

	SPI_OFF(); /* Turn off the SPI */

	return status_register;
	}

	ERROR_CODE GetSectorNumber(unsigned long ulOffset, int *pnSector)
	{
	int nSector = 0;
	ERROR_CODE ErrorCode = NO_ERR;

	if (ulOffset > (NUM_SECTORS * 0x10000 - 1)) {
	ErrorCode = INVALID_SECTOR;
	return ErrorCode;
	}

	nSector = (int)ulOffset / 0x10000;
	*pnSector = nSector;

	return ErrorCode;
	}

	ERROR_CODE EraseBlock(int nBlock)
	{
	unsigned long ulSectorOff = 0x0, ShiftValue;
	ERROR_CODE ErrorCode = NO_ERR;

	/* if the block is invalid just return */
	if ((nBlock < 0) \|\| (nBlock > NUM_SECTORS)) {
	ErrorCode = INVALID_BLOCK;
	return ErrorCode;
	}
	/* figure out the offset of the block in flash */
	if ((nBlock >= 0) && (nBlock < NUM_SECTORS)) {
	ulSectorOff = (nBlock * SECTOR_SIZE);

	} else {
	ErrorCode = INVALID_BLOCK;
	return ErrorCode;
	}

	/* A write enable instruction must previously have been executed */
	SendSingleCommand(SPI_WREN);

	/* The status register will be polled to check the write enable latch "WREN" */
	ErrorCode = Wait_For_WEL();

	if (POLL_TIMEOUT == ErrorCode) {
	printf("SPI Erase block error\n");
	return ErrorCode;
	} else

	/* Turn on the SPI to send single commands */
	SetupSPI((COMMON_SPI_SETTINGS \| TIMOD01));

	/*
	* Send the erase block command to the flash followed by the 24 address
	* to point to the start of a sector
	*/
	*pSPI_TDBR = SPI_SE;
	sync();
	Wait_For_SPIF();
	/* Send the highest byte of the 24 bit address at first */
	ShiftValue = (ulSectorOff >> 16);
	*pSPI_TDBR = ShiftValue;
	sync();
	/* Wait until the instruction has been sent */
	Wait_For_SPIF();
	/* Send the middle byte of the 24 bit address at second */
	ShiftValue = (ulSectorOff >> 8);
	*pSPI_TDBR = ShiftValue;
	sync();
	/* Wait until the instruction has been sent */
	Wait_For_SPIF();
	/* Send the lowest byte of the 24 bit address finally */
	*pSPI_TDBR = ulSectorOff;
	sync();
	/* Wait until the instruction has been sent */
	Wait_For_SPIF();

	/* Turns off the SPI */
	SPI_OFF();

	/* Poll the status register to check the Write in Progress bit */
	/* Sector erase takes time */
	ErrorCode = Wait_For_Status(WIP);

	/* block erase should be complete */
	return ErrorCode;
	}

	/*
	* ERROR_CODE ReadData()
	* Read a value from flash for verify purpose
	* Inputs: unsigned long ulStart - holds the SPI start address
	* int pnData - pointer to store value read from flash
	* long lCount - number of elements to read
	*/
	ERROR_CODE ReadData(unsigned long ulStart, long lCount, int *pnData)
	{
	unsigned long ShiftValue;
	char *cnData;
	int i;

	/* Pointer cast to be able to increment byte wise */

	cnData = (char *)pnData;
	/* Start SPI interface */
	SetupSPI((COMMON_SPI_SETTINGS \| TIMOD01));

	#ifdef CONFIG_SPI_FLASH_FAST_READ
	/* Send the read command to SPI device */
	*pSPI_TDBR = SPI_FAST_READ;
	#else
	/* Send the read command to SPI device */
	*pSPI_TDBR = SPI_READ;
	#endif
	sync();
	/* Wait until the instruction has been sent */
	Wait_For_SPIF();
	/* Send the highest byte of the 24 bit address at first */
	ShiftValue = (ulStart >> 16);
	/* Send the byte to the SPI device */
	*pSPI_TDBR = ShiftValue;
	sync();
	/* Wait until the instruction has been sent */
	Wait_For_SPIF();
	/* Send the middle byte of the 24 bit address at second */
	ShiftValue = (ulStart >> 8);
	/* Send the byte to the SPI device */
	*pSPI_TDBR = ShiftValue;
	sync();
	/* Wait until the instruction has been sent */
	Wait_For_SPIF();
	/* Send the lowest byte of the 24 bit address finally */
	*pSPI_TDBR = ulStart;
	sync();
	/* Wait until the instruction has been sent */
	Wait_For_SPIF();

	#ifdef CONFIG_SPI_FLASH_FAST_READ
	/* Send dummy for FAST_READ */
	*pSPI_TDBR = 0;
	sync();
	/* Wait until the instruction has been sent */
	Wait_For_SPIF();
	#endif

	/* After the SPI device address has been placed on the MOSI pin the data can be */
	/* received on the MISO pin. */
	for (i = 0; i < lCount; i++) {
	*pSPI_TDBR = 0;
	sync();
	while (!(*pSPI_STAT & RXS)) ;
	cnData++ = pSPI_RDBR;

	if ((i >= SECTOR_SIZE) && (i % SECTOR_SIZE == 0))
	printf(".");
	}

	/* Turn off the SPI */
	SPI_OFF();

	return NO_ERR;
	}

	ERROR_CODE WriteFlash(unsigned long ulStartAddr, long lTransferCount,
	int iDataSource, long lWriteCount)
	{

	unsigned long ulWAddr;
	long lWTransferCount = 0;
	int i;
	char iData;
	char temp = (char )iDataSource;
	ERROR_CODE ErrorCode = NO_ERR;

	/* First, a Write Enable Command must be sent to the SPI. */
	SendSingleCommand(SPI_WREN);

	/*
	* Second, the SPI Status Register will be tested whether the
	* Write Enable Bit has been set
	*/
	ErrorCode = Wait_For_WEL();
	if (POLL_TIMEOUT == ErrorCode) {
	printf("SPI Write Time Out\n");
	return ErrorCode;
	} else
	/* Third, the 24 bit address will be shifted out
	* the SPI MOSI bytewise.
	* Turns the SPI on
	*/
	SetupSPI((COMMON_SPI_SETTINGS \| TIMOD01));
	*pSPI_TDBR = SPI_PP;
	sync();
	/wait until the instruction has been sent /
	Wait_For_SPIF();
	ulWAddr = (ulStartAddr >> 16);
	*pSPI_TDBR = ulWAddr;
	sync();
	/wait until the instruction has been sent /
	Wait_For_SPIF();
	ulWAddr = (ulStartAddr >> 8);
	*pSPI_TDBR = ulWAddr;
	sync();
	/wait until the instruction has been sent /
	Wait_For_SPIF();
	ulWAddr = ulStartAddr;
	*pSPI_TDBR = ulWAddr;
	sync();
	/wait until the instruction has been sent /
	Wait_For_SPIF();
	/*
	* Fourth, maximum number of 256 bytes will be taken from the Buffer
	* and sent to the SPI device.
	*/
	for (i = 0; (i < lTransferCount) && (i < 256); i++, lWTransferCount++) {
	iData = *temp;
	*pSPI_TDBR = iData;
	sync();
	/wait until the instruction has been sent /
	Wait_For_SPIF();
	temp++;
	}

	/* Turns the SPI off */
	SPI_OFF();

	/*
	* Sixth, the SPI Write in Progress Bit must be toggled to ensure the
	* programming is done before start of next transfer
	*/
	ErrorCode = Wait_For_Status(WIP);

	if (POLL_TIMEOUT == ErrorCode) {
	printf("SPI Program Time out!\n");
	return ErrorCode;
	} else

	*lWriteCount = lWTransferCount;

	return ErrorCode;
	}

	ERROR_CODE WriteData(unsigned long ulStart, long lCount, int *pnData)
	{

	unsigned long ulWStart = ulStart;
	long lWCount = lCount, lWriteCount;
	long *pnWriteCount = &lWriteCount;

	ERROR_CODE ErrorCode = NO_ERR;

	while (lWCount != 0) {
	ErrorCode = WriteFlash(ulWStart, lWCount, pnData, pnWriteCount);

	/*
	* After each function call of WriteFlash the counter
	* must be adjusted
	*/
	lWCount -= *pnWriteCount;

	/* Also, both address pointers must be recalculated. */
	ulWStart += *pnWriteCount;
	pnData += *pnWriteCount / 4;
	}

	/* return the appropriate error code */
	return ErrorCode;
	}

	#endif /* CONFIG_SPI */