avr-projects/devel/sd_bad/sd.c

#include "main.h"
#include "sd.h"
#include "sdcomm_spi.h"
#include "spi.h"

static uint8_t response[5];
static uint8_t argument[4];

int sd_card_present()
{
	return (!(P3IN & 0x01));
}

/* This function initializes the SD card. It returns 1 if
	initialization was successful, 0 otherwise.

	sd_context_t *sdc -- pointer to a data structure containing
						information about the card. For now, the
						timeouts MUST be specified in advance. This
						function does not yet calculate them from the
						card data.
*/

int sd_initialize(sd_context_t *sdc)
{
	char i, j;
	/* SPI SD initialization sequence:
	* CMD0
	* CMD55
	* ACMD41
	* CMD58
	* (Note there is no CMD2 or CMD3 in SPI mode. These
	* instructions are devoted to addressing on the SD bus.)
	*
	* SD memory card SD initialization sequence:
	* CMD0
	* CMD55
	* ACMD41
	* CMD2
	* CMD3
	*/
	sdc->busyflag = 0;
	for (i = 0; i < 4; i++)
		argument[i] = 0;

	/* Delay for at least 74 clock cycles. This means to actually
	* *clock* out at least 74 clock cycles with no data present on
	* the clock. In SPI mode, send at least 10 idle bytes (0xFF). */

	spi_cs_assert();
	sd_delay(100);
	spi_cs_deassert();
	sd_delay(2);

	/* Put the card in the idle state */
	if (sd_send_command(sdc, CMD0, CMD0_R, response, argument) == 0)
		return 0;

	/* Now wait until the card goes idle. Retry at most SD_IDLE_WAIT_MAX
	times */

	j = 0;
	do
	{
		j++;
		/* Flag the next command as an application-specific command */
		if (sd_send_command(sdc, CMD55, CMD55_R, response, argument) == 1)
		{
			/* Tell the card to send its OCR */
			sd_send_command(sdc, ACMD41, ACMD41_R, response, argument);
		}
		else
		{
			/* No response, bail early */
			j = SD_IDLE_WAIT_MAX;
		}
	}
	while ((response[0] & MSK_IDLE) == MSK_IDLE && j < SD_IDLE_WAIT_MAX);

	/* As long as we didn’t hit the timeout, assume we’re OK. */
	if (j >= SD_IDLE_WAIT_MAX)
		return 0;

	if (sd_send_command(sdc, CMD58, CMD58_R, response, argument) == 0)
		return 0;

	/* At a very minimum, we must allow 3.3V. */
	if ((response[2] & MSK_OCR_33) != MSK_OCR_33)
		return 0;

	/* Set the block length */
	if (sd_set_blocklen(sdc, SD_BLOCKSIZE) != 1)
		return 0;

	/* If we got this far, initialization was OK.
	 */
	return 1;
}

/*
	This function reads a single block from the SD card at block
	blockaddr. The buffer must be preallocated. Returns 1 if the
	command was successful, zero otherwise.

	This is an ASYNCHRONOUS call.

	The transfer will not be complete when the function returns.
	If you want to explicitly wait until any pending transfers are
	finished, use the command sd_wait_notbusy(sdc).

	sd_context_t *sdc
	 -- a pointer to an sd device context structure,
		populated  by the function sd_initialize()

	u32 blockaddr
	 -- The block address to read from the card.
		This is a block address, not a linear address.

	uint8_t *data
	 -- The data, a pointer to an array of uint8_ts.
*/

int sd_read_block(sd_context_t *sdc, uint32_t blockaddr,
				  uint8_t *data)
{
	unsigned long int i = 0;
	uint8_t tmp;
	uint8_t blank = 0xFF;

	/* Adjust the block address to a linear address */
	blockaddr <<= SD_BLOCKSIZE_NBITS;

	/* Wait until any old transfers are finished */
	sd_wait_notbusy(sdc);

	/* Pack the address */
	sd_packarg(argument, blockaddr);

	/* Need to add size checking */
	if (sd_send_command(sdc, CMD17, CMD17_R, response, argument) == 0)
		return 0;

	/* Check for an error, like a misaligned read */
	if (response[0] != 0)
		return 0;

	/* Re-assert CS to continue the transfer */
	spi_cs_assert();

	/* Wait for the token */
	i = 0;
	do
	{
		tmp = spi_rcv_byte();
		i++;
	}
	while ((tmp == 0xFF) && i < sdc->timeout_read);

	if ((tmp & MSK_TOK_DATAERROR) == 0)
	{
		/* Clock out a byte before returning */
		spi_send_byte(0xFF);

		/* The card returned an error response. Bail and return 0 */
		return 0;
	}

	/* Prime the interrupt flags so things happen in the correct order. */
	IFG1 &= ~URXIFG0;
	IFG1 &= ~UTXIFG0;

	/* Get the block */
	/* Source DMA address: receive register. */
	DMA0SA = U0RXBUF_;

	/* Destination DMA address: the user data buffer. */
	DMA0DA = (unsigned short) data;

	/* The size of the block to be transferred */
	DMA0SZ = SD_BLOCKSIZE;

	/* Configure the DMA transfer*/
	DMA0CTL =
		DMADT_0 |    /* Single transfer mode */
		DMASBDB |    /* Byte mode */
		DMAEN |      /* Enable DMA */
		DMADSTINCR1 | DMADSTINCR0; /* Increment the destination address */

	/* We depend on the DMA priorities here. Both triggers occur at
	the same time, since the source is identical. DMA0 is handled
	first, and retrieves the byte. DMA1 is triggered next, and
	sends the next byte. */

	/* Source DMA address: constant 0xFF (don’t increment)*/
	DMA1SA = (unsigned short) &blank;

	/* Destination DMA address: the transmit buffer. */
	DMA1DA = U0TXBUF_;

	/* Increment the destination address */
	/* The size of the block to be transferred */
	DMA1SZ = SD_BLOCKSIZE - 1;

	/* Configure the DMA transfer*/
	DMA1CTL =
		DMADT_0 |  /* Single transfer mode */
		DMASBDB |  /* Byte mode */
		DMAEN; /* Enable DMA */

	/* DMA trigger is UART receive for both DMA0 and DMA1 */
	DMACTL0 = DMA0TSEL_3 | DMA1TSEL_3;

	/* Kick off the transfer by sending the first byte */
	U0TXBUF = 0xFF;

	return 1;
}


/*
	This function writes a single block to the SD card at block
	blockaddr. Returns 1 if the command was successful, zero
	otherwise.

	This is an ASYNCHRONOUS call. The transfer will not be complete
	when the function returns. If you want to explicitly wait until
	any pending transfers are finished, use the command
	sd_wait_notbusy(sdc).

	sd_context_t *sdc
	 -- a pointer to an sd device context structure,
		populated by the function sd_initialize()

	u32 blockaddr
	 -- The block address to read from the card.
		This is a block address, not a linear address.

	uint8_t *data
	 -- The data, a pointer to an array of unsigned
		chars.
*/
int sd_write_block(sd_context_t *sdc, uint32_t blockaddr,
				   uint8_t *data)
{
	/* Adjust the block address to a linear address */
	blockaddr <<= SD_BLOCKSIZE_NBITS;

	/* Wait until any old transfers are finished */
	sd_wait_notbusy(sdc);

	/* Pack the address */
	sd_packarg(argument, blockaddr);

	if (sd_send_command(sdc, CMD24, CMD24_R, response, argument) == 0)
		return 0;

	/* Check for an error, like a misaligned write */
	if (response[0] != 0)
		return 0;

	/* Re-assert CS to continue the transfer */
	spi_cs_assert();

	/* The write command needs an additional 8 clock cycles before
	* the block write is started. */
	spi_rcv_byte();

	/* Clear any pending flags */
	IFG1 &= ~(URXIFG0 | UTXIFG0);

	/* Get the block */
	/* Source DMA address: the data buffer. */
	DMA0SA = (unsigned short)data;

	/* Destination DMA address: the UART send register. */
	DMA0DA = U0TXBUF_;

	/* The size of the block to be transferred */
	DMA0SZ = SD_BLOCKSIZE;

	/* Configure the DMA transfer*/
	DMA0CTL =
		DMADT_0 |    /* Single transfer mode */
		DMASBDB |    /* Byte mode */
		DMAEN |      /* Enable DMA */
		DMASRCINCR1 | DMASRCINCR0; /* Increment the source address */

	/* DMA trigger is UART send */
	DMACTL0 = DMA0TSEL_3;

	/* Kick off the transfer by sending the first byte, the "start block"
	* token */
	U0TXBUF = SD_TOK_WRITE_STARTBLOCK;

	/* Signal that the card may be busy, so any subsequent commands
	should wait for the busy signalling to end (indicated by a
	nonzero response). */
	sdc->busyflag = 1;

	return 1;
}

/*
    This function synchronously waits until any pending block transfers
	are finished. If your program needs to ensure a block has finished
	transferring, call this function.

	Note that sd_read_block() and sd_write_block() already call this
	function internally before attempting a new transfer, so there are
	only two times when a user would need to use this function.

	1) When the processor will be shutting down. All pending
	writes should be finished first.

	2) When the user needs the results of an sd_read_block() call
	right away.
*/
void sd_wait_notbusy(sd_context_t *sdc)
{
	/* Just twiddle our thumbs until the transfer’s done */
	while ((DMA0CTL & DMAEN) != 0) { }

	/* Reset the DMA controller */
	DMACTL0 = 0;

	/* Ignore the checksum */
	sd_delay(4);

	/* Check for the busy flag (set on a write block) */
	if (sdc->busyflag == 1)
	{
		while (spi_rcv_byte() != 0xFF);
	}

	sdc->busyflag = 0;

	/* Deassert CS */
	spi_cs_deassert();

	/* Send some extra clocks so the card can resynchronize on the next
	transfer */

	sd_delay(2);
}


void sd_packarg(uint8_t *argument, uint32_t value)
{
	argument[3] = (uint8_t)(value >> 24);
	argument[2] = (uint8_t)(value >> 16);
	argument[1] = (uint8_t)(value >> 8);
	argument[0] = (uint8_t)(value);
}

int sd_send_command(sd_context_t *sdc,
					uint8_t cmd, uint8_t response_type,
					uint8_t *response, uint8_t *argument)
{
	int i;
	char response_length;
	uint8_t tmp;
	spi_cs_assert();

	/* All data is sent MSB first, and MSb first */
	/* Send the header/command */
	/* Format:
	cmd[7:6] : 01
	cmd[5:0] : command */
	spi_send_byte((cmd & 0x3F) | 0x40);
	for (i = 3; i >= 0; i--)
	{
		spi_send_byte(argument[i]);
	}

	/* This is the CRC. It only matters what we put here for the first
	command. Otherwise, the CRC is ignored for SPI mode unless we
	enable CRC checking. */
	spi_send_byte(0x95);

	response_length = 0;
	switch (response_type)
	{
		case R1:
		case R1B:
			response_length = 1;
			break;
		case R2:
			response_length = 2;
			break;
		case R3:
			response_length = 5;
			break;
		default:
			break;
	}

	/* Wait for a response. A response can be recognized by the
	start bit (a zero) */
	i = 0;
	do
	{
		tmp = spi_rcv_byte();
		i++;
	}
	while (((tmp & 0x80) != 0) && i < SD_CMD_TIMEOUT);

	/* Just bail if we never got a response */
	if (i >= SD_CMD_TIMEOUT)
	{
		spi_cs_deassert();
		return 0;
	}

	for (i = response_length - 1; i >= 0; i--)
	{
		response[i] = tmp;
		/* This handles the trailing-byte requirement. */
		tmp = spi_rcv_byte();
	}

	/* If the response is a "busy" type (R1B), then there’s some
	* special handling that needs to be done. The card will
	* output a continuous stream of zeros, so the end of the BUSY
	* state is signaled by any nonzero response. The bus idles
	* high.
	*/
	i = 0;
	if (response_type == R1B)
	{
		do
		{
			i++;
			tmp = spi_rcv_byte();
		}
		/* This should never time out, unless SDI is grounded.
		* Don’t bother forcing a timeout condition here. */
		while (tmp != 0xFF);

		spi_send_byte(0xFF);
	}

	spi_cs_deassert();
	return 1;
}

void sd_delay(char number)
{
	char i;

	/* Null for now */
	for (i = 0; i < number; i++)
	{
		/* Clock out an idle byte (0xFF) */
		spi_send_byte(0xFF);
	}
}

/* Set the block length for all future block transactions */
/* Returns 1 if the function was successful */
int sd_set_blocklen(sd_context_t *sdc, uint32_t length)
{
	/* Pack the block length */
	sd_packarg(argument, length);

	return (sd_send_command(sdc, CMD16, CMD16_R, response, argument));
}