cpu/mpc8260/i2c.c - github/trini/u-boot - Gitiles

 /*
  * (C) Copyright 2000
  * Paolo Scaffardi, AIRVENT SAM s.p.a - RIMINI(ITALY), arsenio@tin.it
  *
  * (C) Copyright 2000 Sysgo Real-Time Solutions, GmbH <www.elinos.com>
  * Marius Groeger <mgroeger@sysgo.de>
  *
  * See file CREDITS for list of people who contributed to this
  * project.
  *
  * This program is free software; you can redistribute it and/or
  * modify it under the terms of the GNU General Public License as
  * published by the Free Software Foundation; either version 2 of
  * the License, or (at your option) any later version.
  *
  * This program is distributed in the hope that it will be useful,
  * but WITHOUT ANY WARRANTY; without even the implied warranty of
  * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
  * GNU General Public License for more details.
  *
  * You should have received a copy of the GNU General Public License
  * along with this program; if not, write to the Free Software
  * Foundation, Inc., 59 Temple Place, Suite 330, Boston,
  * MA 02111-1307 USA
  */

 #include <common.h>

 #if defined(CONFIG_HARD_I2C)

 #include <asm/cpm_8260.h>
 #include <i2c.h>

 /* define to enable debug messages */
 #undef  DEBUG_I2C

 /* uSec to wait between polls of the i2c */
 #define DELAY_US	100
 /* uSec to wait for the CPM to start processing the buffer */
 #define START_DELAY_US	1000

 /*
  * tx/rx per-byte timeout: we delay DELAY_US uSec between polls so the
  * timeout will be (tx_length + rx_length) * DELAY_US * TOUT_LOOP
  */
 #define TOUT_LOOP 5

 /*-----------------------------------------------------------------------
  * Set default values
  */
 #ifndef	CFG_I2C_SPEED
 #define	CFG_I2C_SPEED	50000
 #endif

 #ifndef	CFG_I2C_SLAVE
 #define	CFG_I2C_SLAVE	0xFE
 #endif
 /*-----------------------------------------------------------------------
  */

 typedef void (*i2c_ecb_t)(int, int, void *);    /* error callback function */

 /* This structure keeps track of the bd and buffer space usage. */
 typedef struct i2c_state {
 	int		rx_idx;		/* index   to next free Rx BD */
 	int		tx_idx;		/* index   to next free Tx BD */
 	void		*rxbd;		/* pointer to next free Rx BD */
 	void		*txbd;		/* pointer to next free Tx BD */
 	int		tx_space;	/* number  of Tx bytes left   */
 	unsigned char	*tx_buf;	/* pointer to free Tx area    */
 	i2c_ecb_t	err_cb;		/* error callback function    */
 	void		*cb_data;	/* private data to be passed  */
 } i2c_state_t;

 /* flags for i2c_send() and i2c_receive() */
 #define	I2CF_ENABLE_SECONDARY	0x01	/* secondary_address is valid	*/
 #define	I2CF_START_COND		0x02	/* tx: generate start condition	*/
 #define I2CF_STOP_COND		0x04	/* tx: generate stop  condition	*/

 /* return codes */
 #define I2CERR_NO_BUFFERS	1	/* no more BDs or buffer space	*/
 #define I2CERR_MSG_TOO_LONG	2	/* tried to send/receive to much data   */
 #define I2CERR_TIMEOUT		3	/* timeout in i2c_doio()	*/
 #define I2CERR_QUEUE_EMPTY	4	/* i2c_doio called without send/receive */
 #define I2CERR_IO_ERROR		5	/* had an error during comms	*/

 /* error callback flags */
 #define I2CECB_RX_ERR		0x10	/* this is a receive error	*/
 #define     I2CECB_RX_OV	0x02	/* receive overrun error	*/
 #define     I2CECB_RX_MASK	0x0f	/* mask for error bits		*/
 #define I2CECB_TX_ERR		0x20	/* this is a transmit error	*/
 #define     I2CECB_TX_CL	0x01	/* transmit collision error	*/
 #define     I2CECB_TX_UN	0x02	/* transmit underflow error	*/
 #define     I2CECB_TX_NAK	0x04	/* transmit no ack error	*/
 #define     I2CECB_TX_MASK	0x0f	/* mask for error bits		*/
 #define I2CECB_TIMEOUT		0x40	/* this is a timeout error	*/

 #define ERROR_I2C_NONE		0
 #define ERROR_I2C_LENGTH	1

 #define I2C_WRITE_BIT		0x00
 #define I2C_READ_BIT		0x01

 #define I2C_RXTX_LEN	128	/* maximum tx/rx buffer length */


 #define NUM_RX_BDS 4
 #define NUM_TX_BDS 4
 #define MAX_TX_SPACE 256

 typedef struct I2C_BD
 {
   unsigned short status;
   unsigned short length;
   unsigned char *addr;
 } I2C_BD;
 #define BD_I2C_TX_START 0x0400  /* special status for i2c: Start condition */

 #define BD_I2C_TX_CL	0x0001	/* collision error */
 #define BD_I2C_TX_UN	0x0002	/* underflow error */
 #define BD_I2C_TX_NAK	0x0004	/* no acknowledge error */
 #define BD_I2C_TX_ERR	(BD_I2C_TX_NAK|BD_I2C_TX_UN|BD_I2C_TX_CL)

 #define BD_I2C_RX_ERR	BD_SC_OV

 #ifdef DEBUG_I2C
 #define PRINTD(x) printf x
 #else
 #define PRINTD(x)
 #endif

 /*
  * Returns the best value of I2BRG to meet desired clock speed of I2C with
  * input parameters (clock speed, filter, and predivider value).
  * It returns computer speed value and the difference between it and desired
  * speed.
  */
 static inline int
 i2c_roundrate(int hz, int speed, int filter, int modval,
 		int *brgval, int *totspeed)
 {
     int moddiv = 1 << (5-(modval & 3)), brgdiv, div;

     PRINTD(("\t[I2C] trying hz=%d, speed=%d, filter=%d, modval=%d\n",
 	hz, speed, filter, modval));

     div = moddiv * speed;
     brgdiv = (hz + div - 1) / div;

     PRINTD(("\t\tmoddiv=%d, brgdiv=%d\n", moddiv, brgdiv));

     *brgval = ((brgdiv + 1) / 2) - 3 - (2*filter);

     if ((*brgval < 0) || (*brgval > 255)) {
 	  PRINTD(("\t\trejected brgval=%d\n", *brgval));
 	  return -1;
     }

     brgdiv = 2 * (*brgval + 3 + (2 * filter));
     div = moddiv * brgdiv ;
     *totspeed = hz / div;

     PRINTD(("\t\taccepted brgval=%d, totspeed=%d\n", *brgval, *totspeed));

     return  0;
 }

 /*
  * Sets the I2C clock predivider and divider to meet required clock speed.
  */
 static int i2c_setrate(int hz, int speed)
 {
     immap_t	*immap = (immap_t *)CFG_IMMR ;
     volatile i2c8260_t *i2c = (i2c8260_t *)&immap->im_i2c;
     int brgval,
 	  modval,	/* 0-3 */
 	  bestspeed_diff = speed,
 	  bestspeed_brgval=0,
 	  bestspeed_modval=0,
 	  bestspeed_filter=0,
 	  totspeed,
 	  filter = 0; /* Use this fixed value */

 	for (modval = 0; modval < 4; modval++)
 	{
 		if (i2c_roundrate (hz, speed, filter, modval, &brgval, &totspeed) == 0)
 		{
 			int diff = speed - totspeed ;

 			if ((diff >= 0) && (diff < bestspeed_diff))
 			{
 				bestspeed_diff 	= diff ;
 				bestspeed_modval 	= modval;
 				bestspeed_brgval 	= brgval;
 				bestspeed_filter 	= filter;
 			}
 		}
 	}

     PRINTD(("[I2C] Best is:\n"));
     PRINTD(("[I2C] CPU=%dhz RATE=%d F=%d I2MOD=%08x I2BRG=%08x DIFF=%dhz\n",
 		   hz, speed,
 		   bestspeed_filter, bestspeed_modval, bestspeed_brgval,
 		   bestspeed_diff));

     i2c->i2c_i2mod |= ((bestspeed_modval & 3) << 1) | (bestspeed_filter << 3);
     i2c->i2c_i2brg = bestspeed_brgval & 0xff;

     PRINTD(("[I2C] i2mod=%08x i2brg=%08x\n", i2c->i2c_i2mod, i2c->i2c_i2brg));

     return 1 ;
 }

 void i2c_init(int speed, int slaveadd)
 {
 	DECLARE_GLOBAL_DATA_PTR;

 	volatile immap_t *immap = (immap_t *)CFG_IMMR ;
 	volatile cpm8260_t *cp = (cpm8260_t *)&immap->im_cpm;
 	volatile i2c8260_t *i2c	= (i2c8260_t *)&immap->im_i2c;
 	volatile iic_t *iip;
 	ulong rbase, tbase;
 	volatile I2C_BD *rxbd, *txbd;
 	uint dpaddr;

 #ifdef CFG_I2C_INIT_BOARD
 	/* call board specific i2c bus reset routine before accessing the   */
 	/* environment, which might be in a chip on that bus. For details   */
 	/* about this problem see doc/I2C_Edge_Conditions.                  */
 	i2c_init_board();
 #endif

 	dpaddr = *((unsigned short*)(&immap->im_dprambase[PROFF_I2C_BASE]));
 	if (dpaddr == 0) {
 	    /* need to allocate dual port ram */
 	    dpaddr = m8260_cpm_dpalloc(64 +
 		(NUM_RX_BDS * sizeof(I2C_BD)) + (NUM_TX_BDS * sizeof(I2C_BD)) +
 		MAX_TX_SPACE, 64);
 	    *((unsigned short*)(&immap->im_dprambase[PROFF_I2C_BASE])) = dpaddr;
 	}

 	/*
 	 * initialise data in dual port ram:
 	 *
 	 * 	  dpaddr -> parameter ram (64 bytes)
 	 *         rbase -> rx BD         (NUM_RX_BDS * sizeof(I2C_BD) bytes)
 	 *         tbase -> tx BD         (NUM_TX_BDS * sizeof(I2C_BD) bytes)
 	 *                  tx buffer     (MAX_TX_SPACE bytes)
 	 */

 	iip = (iic_t *)&immap->im_dprambase[dpaddr];
 	memset((void*)iip, 0, sizeof(iic_t));

 	rbase = dpaddr + 64;
 	tbase = rbase + NUM_RX_BDS * sizeof(I2C_BD);

 	/* Disable interrupts */
 	i2c->i2c_i2mod = 0x00;
 	i2c->i2c_i2cmr = 0x00;
 	i2c->i2c_i2cer = 0xff;
 	i2c->i2c_i2add = slaveadd;

 	/*
 	 * Set the I2C BRG Clock division factor from desired i2c rate
 	 * and current CPU rate (we assume sccr dfbgr field is 0;
 	 * divide BRGCLK by 1)
 	 */
 	PRINTD(("[I2C] Setting rate...\n"));
 	i2c_setrate (gd->brg_clk, CFG_I2C_SPEED) ;

 	/* Set I2C controller in master mode */
 	i2c->i2c_i2com = 0x01;

 	/* Initialize Tx/Rx parameters */
 	iip->iic_rbase = rbase;
 	iip->iic_tbase = tbase;
 	rxbd = (I2C_BD *)((unsigned char *)&immap->im_dprambase[iip->iic_rbase]);
 	txbd = (I2C_BD *)((unsigned char *)&immap->im_dprambase[iip->iic_tbase]);

 	PRINTD(("[I2C] rbase = %04x\n", iip->iic_rbase));
 	PRINTD(("[I2C] tbase = %04x\n", iip->iic_tbase));
 	PRINTD(("[I2C] rxbd = %08x\n", (int)rxbd));
 	PRINTD(("[I2C] txbd = %08x\n", (int)txbd));

 	/* Set big endian byte order */
 	iip->iic_tfcr = 0x10;
 	iip->iic_rfcr = 0x10;

 	/* Set maximum receive size. */
 	iip->iic_mrblr = I2C_RXTX_LEN;

     cp->cp_cpcr = mk_cr_cmd(CPM_CR_I2C_PAGE,
 							CPM_CR_I2C_SBLOCK,
 							0x00,
 							CPM_CR_INIT_TRX) | CPM_CR_FLG;
     do {
 		__asm__ __volatile__ ("eieio");
     } while (cp->cp_cpcr & CPM_CR_FLG);

 	/* Clear events and interrupts */
 	i2c->i2c_i2cer = 0xff;
 	i2c->i2c_i2cmr = 0x00;
 }

 static
 void i2c_newio(i2c_state_t *state)
 {
 	volatile immap_t *immap = (immap_t *)CFG_IMMR ;
 	volatile iic_t *iip;
 	uint dpaddr;

 	PRINTD(("[I2C] i2c_newio\n"));

 	dpaddr = *((unsigned short*)(&immap->im_dprambase[PROFF_I2C_BASE]));
 	iip = (iic_t *)&immap->im_dprambase[dpaddr];
 	state->rx_idx = 0;
 	state->tx_idx = 0;
 	state->rxbd = (void*)&immap->im_dprambase[iip->iic_rbase];
 	state->txbd = (void*)&immap->im_dprambase[iip->iic_tbase];
 	state->tx_space = MAX_TX_SPACE;
 	state->tx_buf = (uchar*)state->txbd + NUM_TX_BDS * sizeof(I2C_BD);
 	state->err_cb = NULL;
 	state->cb_data = NULL;

 	PRINTD(("[I2C] rxbd = %08x\n", (int)state->rxbd));
 	PRINTD(("[I2C] txbd = %08x\n", (int)state->txbd));
 	PRINTD(("[I2C] tx_buf = %08x\n", (int)state->tx_buf));

 	/* clear the buffer memory */
 	memset((char *)state->tx_buf, 0, MAX_TX_SPACE);
 }

 static
 int i2c_send(i2c_state_t *state,
 			 unsigned char address,
 			 unsigned char secondary_address,
 			 unsigned int flags,
 			 unsigned short size,
 			 unsigned char *dataout)
 {
 	volatile I2C_BD *txbd;
 	int i,j;

 	PRINTD(("[I2C] i2c_send add=%02d sec=%02d flag=%02d size=%d\n",
 			address, secondary_address, flags, size));

 	/* trying to send message larger than BD */
 	if (size > I2C_RXTX_LEN)
 	  return I2CERR_MSG_TOO_LONG;

 	/* no more free bds */
 	if (state->tx_idx >= NUM_TX_BDS || state->tx_space < (2 + size))
 	  return I2CERR_NO_BUFFERS;

 	txbd = (I2C_BD *)state->txbd;
 	txbd->addr = state->tx_buf;

 	PRINTD(("[I2C] txbd = %08x\n", (int)txbd));

     if (flags & I2CF_START_COND)
     {
 	PRINTD(("[I2C] Formatting addresses...\n"));
 	if (flags & I2CF_ENABLE_SECONDARY)
 	{
 		txbd->length = size + 2;  /* Length of message plus dest addresses */
 		txbd->addr[0] = address << 1;
 		txbd->addr[1] = secondary_address;
 		i = 2;
 	}
 	else
 	{
 		txbd->length = size + 1;  /* Length of message plus dest address */
 		txbd->addr[0] = address << 1;  /* Write destination address to BD */
 		i = 1;
 	}
     }
     else
     {
 	txbd->length = size;  /* Length of message */
 	i = 0;
     }

 	/* set up txbd */
 	txbd->status = BD_SC_READY;
 	if (flags & I2CF_START_COND)
 	  txbd->status |= BD_I2C_TX_START;
 	if (flags & I2CF_STOP_COND)
 	  txbd->status |= BD_SC_LAST | BD_SC_WRAP;

 	/* Copy data to send into buffer */
 	PRINTD(("[I2C] copy data...\n"));
 	for(j = 0; j < size; i++, j++)
 	  txbd->addr[i] = dataout[j];

 	PRINTD(("[I2C] txbd: length=0x%04x status=0x%04x addr[0]=0x%02x addr[1]=0x%02x\n",
 		   txbd->length,
 		   txbd->status,
 		   txbd->addr[0],
 		   txbd->addr[1]));

 	/* advance state */
 	state->tx_buf += txbd->length;
 	state->tx_space -= txbd->length;
 	state->tx_idx++;
 	state->txbd = (void*)(txbd + 1);

 	return 0;
 }

 static
 int i2c_receive(i2c_state_t *state,
 				unsigned char address,
 				unsigned char secondary_address,
 				unsigned int flags,
 				unsigned short size_to_expect,
 				unsigned char *datain)
 {
 	volatile I2C_BD *rxbd, *txbd;

 	PRINTD(("[I2C] i2c_receive %02d %02d %02d\n", address, secondary_address, flags));

 	/* Expected to receive too much */
 	if (size_to_expect > I2C_RXTX_LEN)
 	  return I2CERR_MSG_TOO_LONG;

 	/* no more free bds */
 	if (state->tx_idx >= NUM_TX_BDS || state->rx_idx >= NUM_RX_BDS
 		 || state->tx_space < 2)
 	  return I2CERR_NO_BUFFERS;

 	rxbd = (I2C_BD *)state->rxbd;
 	txbd = (I2C_BD *)state->txbd;

 	PRINTD(("[I2C] rxbd = %08x\n", (int)rxbd));
 	PRINTD(("[I2C] txbd = %08x\n", (int)txbd));

 	txbd->addr = state->tx_buf;

 	/* set up TXBD for destination address */
 	if (flags & I2CF_ENABLE_SECONDARY)
 	{
 		txbd->length = 2;
 		txbd->addr[0] = address << 1;   /* Write data */
 		txbd->addr[1] = secondary_address;  /* Internal address */
 		txbd->status = BD_SC_READY;
 	}
 	else
 	{
 		txbd->length = 1 + size_to_expect;
 		txbd->addr[0] = (address << 1) | 0x01;
 		txbd->status = BD_SC_READY;
 		memset(&txbd->addr[1], 0, txbd->length);
 	}

 	/* set up rxbd for reception */
 	rxbd->status = BD_SC_EMPTY;
 	rxbd->length = size_to_expect;
 	rxbd->addr = datain;

 	txbd->status |= BD_I2C_TX_START;
 	if (flags & I2CF_STOP_COND)
 	{
 		txbd->status |= BD_SC_LAST | BD_SC_WRAP;
 		rxbd->status |= BD_SC_WRAP;
 	}

 	PRINTD(("[I2C] txbd: length=0x%04x status=0x%04x addr[0]=0x%02x addr[1]=0x%02x\n",
 		   txbd->length,
 		   txbd->status,
 		   txbd->addr[0],
 		   txbd->addr[1]));
 	PRINTD(("[I2C] rxbd: length=0x%04x status=0x%04x addr[0]=0x%02x addr[1]=0x%02x\n",
 		   rxbd->length,
 		   rxbd->status,
 		   rxbd->addr[0],
 		   rxbd->addr[1]));

 	/* advance state */
 	state->tx_buf += txbd->length;
 	state->tx_space -= txbd->length;
 	state->tx_idx++;
 	state->txbd = (void*)(txbd + 1);
 	state->rx_idx++;
 	state->rxbd = (void*)(rxbd + 1);

 	return 0;
 }


 static
 int i2c_doio(i2c_state_t *state)
 {
 	volatile immap_t *immap = (immap_t *)CFG_IMMR ;
 	volatile iic_t *iip;
 	volatile i2c8260_t *i2c	= (i2c8260_t *)&immap->im_i2c;
 	volatile I2C_BD *txbd, *rxbd;
 	int  n, i, b, rxcnt = 0, rxtimeo = 0, txcnt = 0, txtimeo = 0, rc = 0;
 	uint dpaddr;

 	PRINTD(("[I2C] i2c_doio\n"));

 	if (state->tx_idx <= 0 && state->rx_idx <= 0) {
 		PRINTD(("[I2C] No I/O is queued\n"));
 		return I2CERR_QUEUE_EMPTY;
 	}

 	dpaddr = *((unsigned short*)(&immap->im_dprambase[PROFF_I2C_BASE]));
 	iip = (iic_t *)&immap->im_dprambase[dpaddr];
 	iip->iic_rbptr = iip->iic_rbase;
 	iip->iic_tbptr = iip->iic_tbase;

 	/* Enable I2C */
 	PRINTD(("[I2C] Enabling I2C...\n"));
 	i2c->i2c_i2mod |= 0x01;

 	/* Begin transmission */
 	i2c->i2c_i2com |= 0x80;

 	/* Loop until transmit & receive completed */

 	if ((n = state->tx_idx) > 0) {

 		txbd = ((I2C_BD*)state->txbd) - n;
 		for (i = 0; i < n; i++) {
 			txtimeo += TOUT_LOOP * txbd->length;
 			txbd++;
 		}

 		txbd--; /* wait until last in list is done */

 		PRINTD(("[I2C] Transmitting...(txbd=0x%08lx)\n", (ulong)txbd));

 		udelay(START_DELAY_US);	/* give it time to start */
 		while((txbd->status & BD_SC_READY) && (++txcnt < txtimeo)) {
 			udelay(DELAY_US);
 			if (ctrlc())
 				return (-1);
 			__asm__ __volatile__ ("eieio");
 		}
 	}

 	if (txcnt < txtimeo && (n = state->rx_idx) > 0) {

 		rxbd = ((I2C_BD*)state->rxbd) - n;
 		for (i = 0; i < n; i++) {
 			rxtimeo += TOUT_LOOP * rxbd->length;
 			rxbd++;
 		}

 		rxbd--; /* wait until last in list is done */

 		PRINTD(("[I2C] Receiving...(rxbd=0x%08lx)\n", (ulong)rxbd));

 		udelay(START_DELAY_US);	/* give it time to start */
 		while((rxbd->status & BD_SC_EMPTY) && (++rxcnt < rxtimeo)) {
 			udelay(DELAY_US);
 			if (ctrlc())
 				return (-1);
 			__asm__ __volatile__ ("eieio");
 		}
 	}

 	/* Turn off I2C */
 	i2c->i2c_i2mod &= ~0x01;

 	if ((n = state->tx_idx) > 0) {
 		for (i = 0; i < n; i++) {
 			txbd = ((I2C_BD*)state->txbd) - (n - i);
 			if ((b = txbd->status & BD_I2C_TX_ERR) != 0) {
 				if (state->err_cb != NULL)
 					(*state->err_cb)(I2CECB_TX_ERR|b, i,
 						state->cb_data);
 				if (rc == 0)
 					rc = I2CERR_IO_ERROR;
 			}
 		}
 	}

 	if ((n = state->rx_idx) > 0) {
 		for (i = 0; i < n; i++) {
 			rxbd = ((I2C_BD*)state->rxbd) - (n - i);
 			if ((b = rxbd->status & BD_I2C_RX_ERR) != 0) {
 				if (state->err_cb != NULL)
 					(*state->err_cb)(I2CECB_RX_ERR|b, i,
 						state->cb_data);
 				if (rc == 0)
 					rc = I2CERR_IO_ERROR;
 			}
 		}
 	}

 	if ((txtimeo > 0 && txcnt >= txtimeo) || \
 	    (rxtimeo > 0 && rxcnt >= rxtimeo)) {
 		if (state->err_cb != NULL)
 			(*state->err_cb)(I2CECB_TIMEOUT, -1, state->cb_data);
 		if (rc == 0)
 			rc = I2CERR_TIMEOUT;
 	}

 	return (rc);
 }

 static void
 i2c_probe_callback(int flags, int xnum, void *data)
 {
 	/*
 	 * the only acceptable errors are a transmit NAK or a receive
 	 * overrun - tx NAK means the device does not exist, rx OV
 	 * means the device must have responded to the slave address
 	 * even though the transfer failed
 	 */
 	if (flags == (I2CECB_TX_ERR|I2CECB_TX_NAK))
 		*(int *)data |= 1;
 	if (flags == (I2CECB_RX_ERR|I2CECB_RX_OV))
 		*(int *)data |= 2;
 }

 int
 i2c_probe(uchar chip)
 {
 	i2c_state_t state;
 	int rc, err_flag;
 	uchar buf[1];

 	i2c_newio(&state);

 	state.err_cb = i2c_probe_callback;
 	state.cb_data = (void *) &err_flag;
 	err_flag = 0;

 	rc = i2c_receive(&state, chip, 0, I2CF_START_COND|I2CF_STOP_COND, 1, buf);

 	if (rc != 0)
 		return (rc);	/* probe failed */

 	rc = i2c_doio(&state);

 	if (rc == 0)
 		return (0);	/* device exists - read succeeded */

 	if (rc == I2CERR_TIMEOUT)
 		return (-1);	/* device does not exist - timeout */

 	if (rc != I2CERR_IO_ERROR || err_flag == 0)
 		return (rc);	/* probe failed */

 	if (err_flag & 1)
 		return (-1);	/* device does not exist - had transmit NAK */

 	return (0);	/* device exists - had receive overrun */
 }


 int
 i2c_read(uchar chip, uint addr, int alen, uchar *buffer, int len)
 {
 	i2c_state_t state;
 	uchar xaddr[4];
 	int rc;

 	xaddr[0] = (addr >> 24) & 0xFF;
 	xaddr[1] = (addr >> 16) & 0xFF;
 	xaddr[2] = (addr >>  8) & 0xFF;
 	xaddr[3] =  addr        & 0xFF;

 #ifdef CFG_I2C_EEPROM_ADDR_OVERFLOW
 	 /*
 	  * EEPROM chips that implement "address overflow" are ones
 	  * like Catalyst 24WC04/08/16 which has 9/10/11 bits of address
 	  * and the extra bits end up in the "chip address" bit slots.
 	  * This makes a 24WC08 (1Kbyte) chip look like four 256 byte
 	  * chips.
 	  *
 	  * Note that we consider the length of the address field to still
 	  * be one byte because the extra address bits are hidden in the
 	  * chip address.
 	  */
 	chip |= ((addr >> (alen * 8)) & CFG_I2C_EEPROM_ADDR_OVERFLOW);
 #endif

 	i2c_newio(&state);

 	rc = i2c_send(&state, chip, 0, I2CF_START_COND, alen, &xaddr[4-alen]);
 	if (rc != 0) {
 		printf("i2c_read: i2c_send failed (%d)\n", rc);
 		return 1;
 	}

 	rc = i2c_receive(&state, chip, 0, I2CF_STOP_COND, len, buffer);
 	if (rc != 0) {
 		printf("i2c_read: i2c_receive failed (%d)\n", rc);
 		return 1;
 	}

 	rc = i2c_doio(&state);
 	if (rc != 0) {
 		printf("i2c_read: i2c_doio failed (%d)\n", rc);
 		return 1;
 	}
 	return 0;
 }

 int
 i2c_write(uchar chip, uint addr, int alen, uchar *buffer, int len)
 {
 	i2c_state_t state;
 	uchar xaddr[4];
 	int rc;

 	xaddr[0] = (addr >> 24) & 0xFF;
 	xaddr[1] = (addr >> 16) & 0xFF;
 	xaddr[2] = (addr >>  8) & 0xFF;
 	xaddr[3] =  addr        & 0xFF;

 #ifdef CFG_I2C_EEPROM_ADDR_OVERFLOW
 	 /*
 	  * EEPROM chips that implement "address overflow" are ones
 	  * like Catalyst 24WC04/08/16 which has 9/10/11 bits of address
 	  * and the extra bits end up in the "chip address" bit slots.
 	  * This makes a 24WC08 (1Kbyte) chip look like four 256 byte
 	  * chips.
 	  *
 	  * Note that we consider the length of the address field to still
 	  * be one byte because the extra address bits are hidden in the
 	  * chip address.
 	  */
 	chip |= ((addr >> (alen * 8)) & CFG_I2C_EEPROM_ADDR_OVERFLOW);
 #endif

 	i2c_newio(&state);

 	rc = i2c_send(&state, chip, 0, I2CF_START_COND, alen, &xaddr[4-alen]);
 	if (rc != 0) {
 		printf("i2c_write: first i2c_send failed (%d)\n", rc);
 		return 1;
 	}

 	rc = i2c_send(&state, 0, 0, I2CF_STOP_COND, len, buffer);
 	if (rc != 0) {
 		printf("i2c_write: second i2c_send failed (%d)\n", rc);
 		return 1;
 	}

 	rc = i2c_doio(&state);
 	if (rc != 0) {
 		printf("i2c_write: i2c_doio failed (%d)\n", rc);
 		return 1;
 	}
 	return 0;
 }

 uchar
 i2c_reg_read(uchar chip, uchar reg)
 {
 	char buf;

 	i2c_read(chip, reg, 1, &buf, 1);

 	return (buf);
 }

 void
 i2c_reg_write(uchar chip, uchar reg, uchar val)
 {
 	i2c_write(chip, reg, 1, &val, 1);
 }

 #endif	/* CONFIG_HARD_I2C */
	/*
	* (C) Copyright 2000
	* Paolo Scaffardi, AIRVENT SAM s.p.a - RIMINI(ITALY), arsenio@tin.it
	*
	* (C) Copyright 2000 Sysgo Real-Time Solutions, GmbH <www.elinos.com>
	* Marius Groeger <mgroeger@sysgo.de>
	*
	* See file CREDITS for list of people who contributed to this
	* project.
	*
	* This program is free software; you can redistribute it and/or
	* modify it under the terms of the GNU General Public License as
	* published by the Free Software Foundation; either version 2 of
	* the License, or (at your option) any later version.
	*
	* This program is distributed in the hope that it will be useful,
	* but WITHOUT ANY WARRANTY; without even the implied warranty of
	* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
	* GNU General Public License for more details.
	*
	* You should have received a copy of the GNU General Public License
	* along with this program; if not, write to the Free Software
	* Foundation, Inc., 59 Temple Place, Suite 330, Boston,
	* MA 02111-1307 USA
	*/

	#include <common.h>

	#if defined(CONFIG_HARD_I2C)

	#include <asm/cpm_8260.h>
	#include <i2c.h>

	/* define to enable debug messages */
	#undef DEBUG_I2C

	/* uSec to wait between polls of the i2c */
	#define DELAY_US 100
	/* uSec to wait for the CPM to start processing the buffer */
	#define START_DELAY_US 1000

	/*
	* tx/rx per-byte timeout: we delay DELAY_US uSec between polls so the
	* timeout will be (tx_length + rx_length) * DELAY_US * TOUT_LOOP
	*/
	#define TOUT_LOOP 5

	/*-----------------------------------------------------------------------
	* Set default values
	*/
	#ifndef CFG_I2C_SPEED
	#define CFG_I2C_SPEED 50000
	#endif

	#ifndef CFG_I2C_SLAVE
	#define CFG_I2C_SLAVE 0xFE
	#endif
	/*-----------------------------------------------------------------------
	*/

	typedef void (i2c_ecb_t)(int, int, void ); /* error callback function */

	/* This structure keeps track of the bd and buffer space usage. */
	typedef struct i2c_state {
	int rx_idx; /* index to next free Rx BD */
	int tx_idx; /* index to next free Tx BD */
	void rxbd; / pointer to next free Rx BD */
	void txbd; / pointer to next free Tx BD */
	int tx_space; /* number of Tx bytes left */
	unsigned char tx_buf; / pointer to free Tx area */
	i2c_ecb_t err_cb; /* error callback function */
	void cb_data; / private data to be passed */
	} i2c_state_t;

	/* flags for i2c_send() and i2c_receive() */
	#define I2CF_ENABLE_SECONDARY 0x01 /* secondary_address is valid */
	#define I2CF_START_COND 0x02 /* tx: generate start condition */
	#define I2CF_STOP_COND 0x04 /* tx: generate stop condition */

	/* return codes */
	#define I2CERR_NO_BUFFERS 1 /* no more BDs or buffer space */
	#define I2CERR_MSG_TOO_LONG 2 /* tried to send/receive to much data */
	#define I2CERR_TIMEOUT 3 /* timeout in i2c_doio() */
	#define I2CERR_QUEUE_EMPTY 4 /* i2c_doio called without send/receive */
	#define I2CERR_IO_ERROR 5 /* had an error during comms */

	/* error callback flags */
	#define I2CECB_RX_ERR 0x10 /* this is a receive error */
	#define I2CECB_RX_OV 0x02 /* receive overrun error */
	#define I2CECB_RX_MASK 0x0f /* mask for error bits */
	#define I2CECB_TX_ERR 0x20 /* this is a transmit error */
	#define I2CECB_TX_CL 0x01 /* transmit collision error */
	#define I2CECB_TX_UN 0x02 /* transmit underflow error */
	#define I2CECB_TX_NAK 0x04 /* transmit no ack error */
	#define I2CECB_TX_MASK 0x0f /* mask for error bits */
	#define I2CECB_TIMEOUT 0x40 /* this is a timeout error */

	#define ERROR_I2C_NONE 0
	#define ERROR_I2C_LENGTH 1

	#define I2C_WRITE_BIT 0x00
	#define I2C_READ_BIT 0x01

	#define I2C_RXTX_LEN 128 /* maximum tx/rx buffer length */


	#define NUM_RX_BDS 4
	#define NUM_TX_BDS 4
	#define MAX_TX_SPACE 256

	typedef struct I2C_BD
	{
	unsigned short status;
	unsigned short length;
	unsigned char *addr;
	} I2C_BD;
	#define BD_I2C_TX_START 0x0400 /* special status for i2c: Start condition */

	#define BD_I2C_TX_CL 0x0001 /* collision error */
	#define BD_I2C_TX_UN 0x0002 /* underflow error */
	#define BD_I2C_TX_NAK 0x0004 /* no acknowledge error */
	#define BD_I2C_TX_ERR (BD_I2C_TX_NAK\|BD_I2C_TX_UN\|BD_I2C_TX_CL)

	#define BD_I2C_RX_ERR BD_SC_OV

	#ifdef DEBUG_I2C
	#define PRINTD(x) printf x
	#else
	#define PRINTD(x)
	#endif

	/*
	* Returns the best value of I2BRG to meet desired clock speed of I2C with
	* input parameters (clock speed, filter, and predivider value).
	* It returns computer speed value and the difference between it and desired
	* speed.
	*/
	static inline int
	i2c_roundrate(int hz, int speed, int filter, int modval,
	int brgval, int totspeed)
	{
	int moddiv = 1 << (5-(modval & 3)), brgdiv, div;

	PRINTD(("\t[I2C] trying hz=%d, speed=%d, filter=%d, modval=%d\n",
	hz, speed, filter, modval));

	div = moddiv * speed;
	brgdiv = (hz + div - 1) / div;

	PRINTD(("\t\tmoddiv=%d, brgdiv=%d\n", moddiv, brgdiv));

	brgval = ((brgdiv + 1) / 2) - 3 - (2filter);

	if ((brgval < 0) \|\| (brgval > 255)) {
	PRINTD(("\t\trejected brgval=%d\n", *brgval));
	return -1;
	}

	brgdiv = 2 * (brgval + 3 + (2 filter));
	div = moddiv * brgdiv ;
	*totspeed = hz / div;

	PRINTD(("\t\taccepted brgval=%d, totspeed=%d\n", brgval, totspeed));

	return 0;
	}

	/*
	* Sets the I2C clock predivider and divider to meet required clock speed.
	*/
	static int i2c_setrate(int hz, int speed)
	{
	immap_t immap = (immap_t )CFG_IMMR ;
	volatile i2c8260_t i2c = (i2c8260_t )&immap->im_i2c;
	int brgval,
	modval, /* 0-3 */
	bestspeed_diff = speed,
	bestspeed_brgval=0,
	bestspeed_modval=0,
	bestspeed_filter=0,
	totspeed,
	filter = 0; /* Use this fixed value */

	for (modval = 0; modval < 4; modval++)
	{
	if (i2c_roundrate (hz, speed, filter, modval, &brgval, &totspeed) == 0)
	{
	int diff = speed - totspeed ;

	if ((diff >= 0) && (diff < bestspeed_diff))
	{
	bestspeed_diff = diff ;
	bestspeed_modval = modval;
	bestspeed_brgval = brgval;
	bestspeed_filter = filter;
	}
	}
	}

	PRINTD(("[I2C] Best is:\n"));
	PRINTD(("[I2C] CPU=%dhz RATE=%d F=%d I2MOD=%08x I2BRG=%08x DIFF=%dhz\n",
	hz, speed,
	bestspeed_filter, bestspeed_modval, bestspeed_brgval,
	bestspeed_diff));

	i2c->i2c_i2mod \|= ((bestspeed_modval & 3) << 1) \| (bestspeed_filter << 3);
	i2c->i2c_i2brg = bestspeed_brgval & 0xff;

	PRINTD(("[I2C] i2mod=%08x i2brg=%08x\n", i2c->i2c_i2mod, i2c->i2c_i2brg));

	return 1 ;
	}

	void i2c_init(int speed, int slaveadd)
	{
	DECLARE_GLOBAL_DATA_PTR;

	volatile immap_t immap = (immap_t )CFG_IMMR ;
	volatile cpm8260_t cp = (cpm8260_t )&immap->im_cpm;
	volatile i2c8260_t i2c = (i2c8260_t )&immap->im_i2c;
	volatile iic_t *iip;
	ulong rbase, tbase;
	volatile I2C_BD rxbd, txbd;
	uint dpaddr;

	#ifdef CFG_I2C_INIT_BOARD
	/* call board specific i2c bus reset routine before accessing the */
	/* environment, which might be in a chip on that bus. For details */
	/* about this problem see doc/I2C_Edge_Conditions. */
	i2c_init_board();
	#endif

	dpaddr = ((unsigned short)(&immap->im_dprambase[PROFF_I2C_BASE]));
	if (dpaddr == 0) {
	/* need to allocate dual port ram */
	dpaddr = m8260_cpm_dpalloc(64 +
	(NUM_RX_BDS * sizeof(I2C_BD)) + (NUM_TX_BDS * sizeof(I2C_BD)) +
	MAX_TX_SPACE, 64);
	((unsigned short)(&immap->im_dprambase[PROFF_I2C_BASE])) = dpaddr;
	}

	/*
	* initialise data in dual port ram:
	*
	* dpaddr -> parameter ram (64 bytes)
	* rbase -> rx BD (NUM_RX_BDS * sizeof(I2C_BD) bytes)
	* tbase -> tx BD (NUM_TX_BDS * sizeof(I2C_BD) bytes)
	* tx buffer (MAX_TX_SPACE bytes)
	*/

	iip = (iic_t *)&immap->im_dprambase[dpaddr];
	memset((void*)iip, 0, sizeof(iic_t));

	rbase = dpaddr + 64;
	tbase = rbase + NUM_RX_BDS * sizeof(I2C_BD);

	/* Disable interrupts */
	i2c->i2c_i2mod = 0x00;
	i2c->i2c_i2cmr = 0x00;
	i2c->i2c_i2cer = 0xff;
	i2c->i2c_i2add = slaveadd;

	/*
	* Set the I2C BRG Clock division factor from desired i2c rate
	* and current CPU rate (we assume sccr dfbgr field is 0;
	* divide BRGCLK by 1)
	*/
	PRINTD(("[I2C] Setting rate...\n"));
	i2c_setrate (gd->brg_clk, CFG_I2C_SPEED) ;

	/* Set I2C controller in master mode */
	i2c->i2c_i2com = 0x01;

	/* Initialize Tx/Rx parameters */
	iip->iic_rbase = rbase;
	iip->iic_tbase = tbase;
	rxbd = (I2C_BD )((unsigned char )&immap->im_dprambase[iip->iic_rbase]);
	txbd = (I2C_BD )((unsigned char )&immap->im_dprambase[iip->iic_tbase]);

	PRINTD(("[I2C] rbase = %04x\n", iip->iic_rbase));
	PRINTD(("[I2C] tbase = %04x\n", iip->iic_tbase));
	PRINTD(("[I2C] rxbd = %08x\n", (int)rxbd));
	PRINTD(("[I2C] txbd = %08x\n", (int)txbd));

	/* Set big endian byte order */
	iip->iic_tfcr = 0x10;
	iip->iic_rfcr = 0x10;

	/* Set maximum receive size. */
	iip->iic_mrblr = I2C_RXTX_LEN;

	cp->cp_cpcr = mk_cr_cmd(CPM_CR_I2C_PAGE,
	CPM_CR_I2C_SBLOCK,
	0x00,
	CPM_CR_INIT_TRX) \| CPM_CR_FLG;
	do {
	__asm__ __volatile__ ("eieio");
	} while (cp->cp_cpcr & CPM_CR_FLG);

	/* Clear events and interrupts */
	i2c->i2c_i2cer = 0xff;
	i2c->i2c_i2cmr = 0x00;
	}

	static
	void i2c_newio(i2c_state_t *state)
	{
	volatile immap_t immap = (immap_t )CFG_IMMR ;
	volatile iic_t *iip;
	uint dpaddr;

	PRINTD(("[I2C] i2c_newio\n"));

	dpaddr = ((unsigned short)(&immap->im_dprambase[PROFF_I2C_BASE]));
	iip = (iic_t *)&immap->im_dprambase[dpaddr];
	state->rx_idx = 0;
	state->tx_idx = 0;
	state->rxbd = (void*)&immap->im_dprambase[iip->iic_rbase];
	state->txbd = (void*)&immap->im_dprambase[iip->iic_tbase];
	state->tx_space = MAX_TX_SPACE;
	state->tx_buf = (uchar)state->txbd + NUM_TX_BDS sizeof(I2C_BD);
	state->err_cb = NULL;
	state->cb_data = NULL;

	PRINTD(("[I2C] rxbd = %08x\n", (int)state->rxbd));
	PRINTD(("[I2C] txbd = %08x\n", (int)state->txbd));
	PRINTD(("[I2C] tx_buf = %08x\n", (int)state->tx_buf));

	/* clear the buffer memory */
	memset((char *)state->tx_buf, 0, MAX_TX_SPACE);
	}

	static
	int i2c_send(i2c_state_t *state,
	unsigned char address,
	unsigned char secondary_address,
	unsigned int flags,
	unsigned short size,
	unsigned char *dataout)
	{
	volatile I2C_BD *txbd;
	int i,j;

	PRINTD(("[I2C] i2c_send add=%02d sec=%02d flag=%02d size=%d\n",
	address, secondary_address, flags, size));

	/* trying to send message larger than BD */
	if (size > I2C_RXTX_LEN)
	return I2CERR_MSG_TOO_LONG;

	/* no more free bds */
	if (state->tx_idx >= NUM_TX_BDS \|\| state->tx_space < (2 + size))
	return I2CERR_NO_BUFFERS;

	txbd = (I2C_BD *)state->txbd;
	txbd->addr = state->tx_buf;

	PRINTD(("[I2C] txbd = %08x\n", (int)txbd));

	if (flags & I2CF_START_COND)
	{
	PRINTD(("[I2C] Formatting addresses...\n"));
	if (flags & I2CF_ENABLE_SECONDARY)
	{
	txbd->length = size + 2; /* Length of message plus dest addresses */
	txbd->addr[0] = address << 1;
	txbd->addr[1] = secondary_address;
	i = 2;
	}
	else
	{
	txbd->length = size + 1; /* Length of message plus dest address */
	txbd->addr[0] = address << 1; /* Write destination address to BD */
	i = 1;
	}
	}
	else
	{
	txbd->length = size; /* Length of message */
	i = 0;
	}

	/* set up txbd */
	txbd->status = BD_SC_READY;
	if (flags & I2CF_START_COND)
	txbd->status \|= BD_I2C_TX_START;
	if (flags & I2CF_STOP_COND)
	txbd->status \|= BD_SC_LAST \| BD_SC_WRAP;

	/* Copy data to send into buffer */
	PRINTD(("[I2C] copy data...\n"));
	for(j = 0; j < size; i++, j++)
	txbd->addr[i] = dataout[j];

	PRINTD(("[I2C] txbd: length=0x%04x status=0x%04x addr[0]=0x%02x addr[1]=0x%02x\n",
	txbd->length,
	txbd->status,
	txbd->addr[0],
	txbd->addr[1]));

	/* advance state */
	state->tx_buf += txbd->length;
	state->tx_space -= txbd->length;
	state->tx_idx++;
	state->txbd = (void*)(txbd + 1);

	return 0;
	}

	static
	int i2c_receive(i2c_state_t *state,
	unsigned char address,
	unsigned char secondary_address,
	unsigned int flags,
	unsigned short size_to_expect,
	unsigned char *datain)
	{
	volatile I2C_BD rxbd, txbd;

	PRINTD(("[I2C] i2c_receive %02d %02d %02d\n", address, secondary_address, flags));

	/* Expected to receive too much */
	if (size_to_expect > I2C_RXTX_LEN)
	return I2CERR_MSG_TOO_LONG;

	/* no more free bds */
	if (state->tx_idx >= NUM_TX_BDS \|\| state->rx_idx >= NUM_RX_BDS
	\|\| state->tx_space < 2)
	return I2CERR_NO_BUFFERS;

	rxbd = (I2C_BD *)state->rxbd;
	txbd = (I2C_BD *)state->txbd;

	PRINTD(("[I2C] rxbd = %08x\n", (int)rxbd));
	PRINTD(("[I2C] txbd = %08x\n", (int)txbd));

	txbd->addr = state->tx_buf;

	/* set up TXBD for destination address */
	if (flags & I2CF_ENABLE_SECONDARY)
	{
	txbd->length = 2;
	txbd->addr[0] = address << 1; /* Write data */
	txbd->addr[1] = secondary_address; /* Internal address */
	txbd->status = BD_SC_READY;
	}
	else
	{
	txbd->length = 1 + size_to_expect;
	txbd->addr[0] = (address << 1) \| 0x01;
	txbd->status = BD_SC_READY;
	memset(&txbd->addr[1], 0, txbd->length);
	}

	/* set up rxbd for reception */
	rxbd->status = BD_SC_EMPTY;
	rxbd->length = size_to_expect;
	rxbd->addr = datain;

	txbd->status \|= BD_I2C_TX_START;
	if (flags & I2CF_STOP_COND)
	{
	txbd->status \|= BD_SC_LAST \| BD_SC_WRAP;
	rxbd->status \|= BD_SC_WRAP;
	}

	PRINTD(("[I2C] txbd: length=0x%04x status=0x%04x addr[0]=0x%02x addr[1]=0x%02x\n",
	txbd->length,
	txbd->status,
	txbd->addr[0],
	txbd->addr[1]));
	PRINTD(("[I2C] rxbd: length=0x%04x status=0x%04x addr[0]=0x%02x addr[1]=0x%02x\n",
	rxbd->length,
	rxbd->status,
	rxbd->addr[0],
	rxbd->addr[1]));

	/* advance state */
	state->tx_buf += txbd->length;
	state->tx_space -= txbd->length;
	state->tx_idx++;
	state->txbd = (void*)(txbd + 1);
	state->rx_idx++;
	state->rxbd = (void*)(rxbd + 1);

	return 0;
	}


	static
	int i2c_doio(i2c_state_t *state)
	{
	volatile immap_t immap = (immap_t )CFG_IMMR ;
	volatile iic_t *iip;
	volatile i2c8260_t i2c = (i2c8260_t )&immap->im_i2c;
	volatile I2C_BD txbd, rxbd;
	int n, i, b, rxcnt = 0, rxtimeo = 0, txcnt = 0, txtimeo = 0, rc = 0;
	uint dpaddr;

	PRINTD(("[I2C] i2c_doio\n"));

	if (state->tx_idx <= 0 && state->rx_idx <= 0) {
	PRINTD(("[I2C] No I/O is queued\n"));
	return I2CERR_QUEUE_EMPTY;
	}

	dpaddr = ((unsigned short)(&immap->im_dprambase[PROFF_I2C_BASE]));
	iip = (iic_t *)&immap->im_dprambase[dpaddr];
	iip->iic_rbptr = iip->iic_rbase;
	iip->iic_tbptr = iip->iic_tbase;

	/* Enable I2C */
	PRINTD(("[I2C] Enabling I2C...\n"));
	i2c->i2c_i2mod \|= 0x01;

	/* Begin transmission */
	i2c->i2c_i2com \|= 0x80;

	/* Loop until transmit & receive completed */

	if ((n = state->tx_idx) > 0) {

	txbd = ((I2C_BD*)state->txbd) - n;
	for (i = 0; i < n; i++) {
	txtimeo += TOUT_LOOP * txbd->length;
	txbd++;
	}

	txbd--; /* wait until last in list is done */

	PRINTD(("[I2C] Transmitting...(txbd=0x%08lx)\n", (ulong)txbd));

	udelay(START_DELAY_US); /* give it time to start */
	while((txbd->status & BD_SC_READY) && (++txcnt < txtimeo)) {
	udelay(DELAY_US);
	if (ctrlc())
	return (-1);
	__asm__ __volatile__ ("eieio");
	}
	}

	if (txcnt < txtimeo && (n = state->rx_idx) > 0) {

	rxbd = ((I2C_BD*)state->rxbd) - n;
	for (i = 0; i < n; i++) {
	rxtimeo += TOUT_LOOP * rxbd->length;
	rxbd++;
	}

	rxbd--; /* wait until last in list is done */

	PRINTD(("[I2C] Receiving...(rxbd=0x%08lx)\n", (ulong)rxbd));

	udelay(START_DELAY_US); /* give it time to start */
	while((rxbd->status & BD_SC_EMPTY) && (++rxcnt < rxtimeo)) {
	udelay(DELAY_US);
	if (ctrlc())
	return (-1);
	__asm__ __volatile__ ("eieio");
	}
	}

	/* Turn off I2C */
	i2c->i2c_i2mod &= ~0x01;

	if ((n = state->tx_idx) > 0) {
	for (i = 0; i < n; i++) {
	txbd = ((I2C_BD*)state->txbd) - (n - i);
	if ((b = txbd->status & BD_I2C_TX_ERR) != 0) {
	if (state->err_cb != NULL)
	(*state->err_cb)(I2CECB_TX_ERR\|b, i,
	state->cb_data);
	if (rc == 0)
	rc = I2CERR_IO_ERROR;
	}
	}
	}

	if ((n = state->rx_idx) > 0) {
	for (i = 0; i < n; i++) {
	rxbd = ((I2C_BD*)state->rxbd) - (n - i);
	if ((b = rxbd->status & BD_I2C_RX_ERR) != 0) {
	if (state->err_cb != NULL)
	(*state->err_cb)(I2CECB_RX_ERR\|b, i,
	state->cb_data);
	if (rc == 0)
	rc = I2CERR_IO_ERROR;
	}
	}
	}

	if ((txtimeo > 0 && txcnt >= txtimeo) \|\| \
	(rxtimeo > 0 && rxcnt >= rxtimeo)) {
	if (state->err_cb != NULL)
	(*state->err_cb)(I2CECB_TIMEOUT, -1, state->cb_data);
	if (rc == 0)
	rc = I2CERR_TIMEOUT;
	}

	return (rc);
	}

	static void
	i2c_probe_callback(int flags, int xnum, void *data)
	{
	/*
	* the only acceptable errors are a transmit NAK or a receive
	* overrun - tx NAK means the device does not exist, rx OV
	* means the device must have responded to the slave address
	* even though the transfer failed
	*/
	if (flags == (I2CECB_TX_ERR\|I2CECB_TX_NAK))
	(int )data \|= 1;
	if (flags == (I2CECB_RX_ERR\|I2CECB_RX_OV))
	(int )data \|= 2;
	}

	int
	i2c_probe(uchar chip)
	{
	i2c_state_t state;
	int rc, err_flag;
	uchar buf[1];

	i2c_newio(&state);

	state.err_cb = i2c_probe_callback;
	state.cb_data = (void *) &err_flag;
	err_flag = 0;

	rc = i2c_receive(&state, chip, 0, I2CF_START_COND\|I2CF_STOP_COND, 1, buf);

	if (rc != 0)
	return (rc); /* probe failed */

	rc = i2c_doio(&state);

	if (rc == 0)
	return (0); /* device exists - read succeeded */

	if (rc == I2CERR_TIMEOUT)
	return (-1); /* device does not exist - timeout */

	if (rc != I2CERR_IO_ERROR \|\| err_flag == 0)
	return (rc); /* probe failed */

	if (err_flag & 1)
	return (-1); /* device does not exist - had transmit NAK */

	return (0); /* device exists - had receive overrun */
	}


	int
	i2c_read(uchar chip, uint addr, int alen, uchar *buffer, int len)
	{
	i2c_state_t state;
	uchar xaddr[4];
	int rc;

	xaddr[0] = (addr >> 24) & 0xFF;
	xaddr[1] = (addr >> 16) & 0xFF;
	xaddr[2] = (addr >> 8) & 0xFF;
	xaddr[3] = addr & 0xFF;

	#ifdef CFG_I2C_EEPROM_ADDR_OVERFLOW
	/*
	* EEPROM chips that implement "address overflow" are ones
	* like Catalyst 24WC04/08/16 which has 9/10/11 bits of address
	* and the extra bits end up in the "chip address" bit slots.
	* This makes a 24WC08 (1Kbyte) chip look like four 256 byte
	* chips.
	*
	* Note that we consider the length of the address field to still
	* be one byte because the extra address bits are hidden in the
	* chip address.
	*/
	chip \|= ((addr >> (alen * 8)) & CFG_I2C_EEPROM_ADDR_OVERFLOW);
	#endif

	i2c_newio(&state);

	rc = i2c_send(&state, chip, 0, I2CF_START_COND, alen, &xaddr[4-alen]);
	if (rc != 0) {
	printf("i2c_read: i2c_send failed (%d)\n", rc);
	return 1;
	}

	rc = i2c_receive(&state, chip, 0, I2CF_STOP_COND, len, buffer);
	if (rc != 0) {
	printf("i2c_read: i2c_receive failed (%d)\n", rc);
	return 1;
	}

	rc = i2c_doio(&state);
	if (rc != 0) {
	printf("i2c_read: i2c_doio failed (%d)\n", rc);
	return 1;
	}
	return 0;
	}

	int
	i2c_write(uchar chip, uint addr, int alen, uchar *buffer, int len)
	{
	i2c_state_t state;
	uchar xaddr[4];
	int rc;

	xaddr[0] = (addr >> 24) & 0xFF;
	xaddr[1] = (addr >> 16) & 0xFF;
	xaddr[2] = (addr >> 8) & 0xFF;
	xaddr[3] = addr & 0xFF;

	#ifdef CFG_I2C_EEPROM_ADDR_OVERFLOW
	/*
	* EEPROM chips that implement "address overflow" are ones
	* like Catalyst 24WC04/08/16 which has 9/10/11 bits of address
	* and the extra bits end up in the "chip address" bit slots.
	* This makes a 24WC08 (1Kbyte) chip look like four 256 byte
	* chips.
	*
	* Note that we consider the length of the address field to still
	* be one byte because the extra address bits are hidden in the
	* chip address.
	*/
	chip \|= ((addr >> (alen * 8)) & CFG_I2C_EEPROM_ADDR_OVERFLOW);
	#endif

	i2c_newio(&state);

	rc = i2c_send(&state, chip, 0, I2CF_START_COND, alen, &xaddr[4-alen]);
	if (rc != 0) {
	printf("i2c_write: first i2c_send failed (%d)\n", rc);
	return 1;
	}

	rc = i2c_send(&state, 0, 0, I2CF_STOP_COND, len, buffer);
	if (rc != 0) {
	printf("i2c_write: second i2c_send failed (%d)\n", rc);
	return 1;
	}

	rc = i2c_doio(&state);
	if (rc != 0) {
	printf("i2c_write: i2c_doio failed (%d)\n", rc);
	return 1;
	}
	return 0;
	}

	uchar
	i2c_reg_read(uchar chip, uchar reg)
	{
	char buf;

	i2c_read(chip, reg, 1, &buf, 1);

	return (buf);
	}

	void
	i2c_reg_write(uchar chip, uchar reg, uchar val)
	{
	i2c_write(chip, reg, 1, &val, 1);
	}

	#endif /* CONFIG_HARD_I2C */