arch/cris/arch-v10/drivers/eeprom.c - linux/kernel/git/klassert/ipsec-next - Git at Google

 /*!*****************************************************************************
 *!
 *!  Implements an interface for i2c compatible eeproms to run under Linux.
 *!  Supports 2k, 8k(?) and 16k. Uses adaptive timing adjustments by
 *!  Johan.Adolfsson@axis.com
 *!
 *!  Probing results:
 *!    8k or not is detected (the assumes 2k or 16k)
 *!    2k or 16k detected using test reads and writes.
 *!
 *!------------------------------------------------------------------------
 *!  HISTORY
 *!
 *!  DATE          NAME              CHANGES
 *!  ----          ----              -------
 *!  Aug  28 1999  Edgar Iglesias    Initial Version
 *!  Aug  31 1999  Edgar Iglesias    Allow simultaneous users.
 *!  Sep  03 1999  Edgar Iglesias    Updated probe.
 *!  Sep  03 1999  Edgar Iglesias    Added bail-out stuff if we get interrupted
 *!                                  in the spin-lock.
 *!
 *!  $Log: eeprom.c,v $
 *!  Revision 1.12  2005/06/19 17:06:46  starvik
 *!  Merge of Linux 2.6.12.
 *!
 *!  Revision 1.11  2005/01/26 07:14:46  starvik
 *!  Applied diff from kernel janitors (Nish Aravamudan).
 *!
 *!  Revision 1.10  2003/09/11 07:29:48  starvik
 *!  Merge of Linux 2.6.0-test5
 *!
 *!  Revision 1.9  2003/07/04 08:27:37  starvik
 *!  Merge of Linux 2.5.74
 *!
 *!  Revision 1.8  2003/04/09 05:20:47  starvik
 *!  Merge of Linux 2.5.67
 *!
 *!  Revision 1.6  2003/02/10 07:19:28  starvik
 *!  Removed misplaced ;
 *!
 *!  Revision 1.5  2002/12/11 13:13:57  starvik
 *!  Added arch/ to v10 specific includes
 *!  Added fix from Linux 2.4 in serial.c (flush_to_flip_buffer)
 *!
 *!  Revision 1.4  2002/11/20 11:56:10  starvik
 *!  Merge of Linux 2.5.48
 *!
 *!  Revision 1.3  2002/11/18 13:16:06  starvik
 *!  Linux 2.5 port of latest 2.4 drivers
 *!
 *!  Revision 1.8  2001/06/15 13:24:29  jonashg
 *!  * Added verification of pointers from userspace in read and write.
 *!  * Made busy counter volatile.
 *!  * Added define for initial write delay.
 *!  * Removed warnings by using loff_t instead of unsigned long.
 *!
 *!  Revision 1.7  2001/06/14 15:26:54  jonashg
 *!  Removed test because condition is always true.
 *!
 *!  Revision 1.6  2001/06/14 15:18:20  jonashg
 *!  Kb -> kB (makes quite a difference if you don't know if you have 2k or 16k).
 *!
 *!  Revision 1.5  2001/06/14 14:39:51  jonashg
 *!  Forgot to use name when registering the driver.
 *!
 *!  Revision 1.4  2001/06/14 14:35:47  jonashg
 *!  * Gave driver a name and used it in printk's.
 *!  * Cleanup.
 *!
 *!  Revision 1.3  2001/03/19 16:04:46  markusl
 *!  Fixed init of fops struct
 *!
 *!  Revision 1.2  2001/03/19 10:35:07  markusl
 *!  2.4 port of eeprom driver
 *!
 *!  Revision 1.8  2000/05/18 10:42:25  edgar
 *!  Make sure to end write cycle on _every_ write
 *!
 *!  Revision 1.7  2000/01/17 17:41:01  johana
 *!  Adjusted probing and return -ENOSPC when writing outside EEPROM
 *!
 *!  Revision 1.6  2000/01/17 15:50:36  johana
 *!  Added adaptive timing adjustments and fixed autoprobing for 2k and 16k(?)
 *!  EEPROMs
 *!
 *!  Revision 1.5  1999/09/03 15:07:37  edgar
 *!  Added bail-out check to the spinlock
 *!
 *!  Revision 1.4  1999/09/03 12:11:17  bjornw
 *!  Proper atomicity (need to use spinlocks, not if's). users -> busy.
 *!
 *!
 *!        (c) 1999 Axis Communications AB, Lund, Sweden
 *!*****************************************************************************/

 #include <linux/kernel.h>
 #include <linux/sched.h>
 #include <linux/fs.h>
 #include <linux/init.h>
 #include <linux/delay.h>
 #include <linux/interrupt.h>
 #include <linux/wait.h>
 #include <asm/uaccess.h>
 #include "i2c.h"

 #define D(x)

 /* If we should use adaptive timing or not: */
 //#define EEPROM_ADAPTIVE_TIMING

 #define EEPROM_MAJOR_NR 122  /* use a LOCAL/EXPERIMENTAL major for now */
 #define EEPROM_MINOR_NR 0

 /* Empirical sane initial value of the delay, the value will be adapted to
  * what the chip needs when using EEPROM_ADAPTIVE_TIMING.
  */
 #define INITIAL_WRITEDELAY_US 4000
 #define MAX_WRITEDELAY_US 10000 /* 10 ms according to spec for 2KB EEPROM */

 /* This one defines how many times to try when eeprom fails. */
 #define EEPROM_RETRIES 10

 #define EEPROM_2KB (2 * 1024)
 /*#define EEPROM_4KB (4 * 1024)*/ /* Exists but not used in Axis products */
 #define EEPROM_8KB (8 * 1024 - 1 ) /* Last byte has write protection bit */
 #define EEPROM_16KB (16 * 1024)

 #define i2c_delay(x) udelay(x)

 /*
  *  This structure describes the attached eeprom chip.
  *  The values are probed for.
  */

 struct eeprom_type
 {
   unsigned long size;
   unsigned long sequential_write_pagesize;
   unsigned char select_cmd;
   unsigned long usec_delay_writecycles; /* Min time between write cycles
 					   (up to 10ms for some models) */
   unsigned long usec_delay_step; /* For adaptive algorithm */
   int adapt_state; /* 1 = To high , 0 = Even, -1 = To low */

   /* this one is to keep the read/write operations atomic */
   wait_queue_head_t wait_q;
   volatile int busy;
   int retry_cnt_addr; /* Used to keep track of number of retries for
                          adaptive timing adjustments */
   int retry_cnt_read;
 };

 static int  eeprom_open(struct inode * inode, struct file * file);
 static loff_t  eeprom_lseek(struct file * file, loff_t offset, int orig);
 static ssize_t  eeprom_read(struct file * file, char * buf, size_t count,
                             loff_t *off);
 static ssize_t  eeprom_write(struct file * file, const char * buf, size_t count,
                              loff_t *off);
 static int eeprom_close(struct inode * inode, struct file * file);

 static int  eeprom_address(unsigned long addr);
 static int  read_from_eeprom(char * buf, int count);
 static int eeprom_write_buf(loff_t addr, const char * buf, int count);
 static int eeprom_read_buf(loff_t addr, char * buf, int count);

 static void eeprom_disable_write_protect(void);


 static const char eeprom_name[] = "eeprom";

 /* chip description */
 static struct eeprom_type eeprom;

 /* This is the exported file-operations structure for this device. */
 const struct file_operations eeprom_fops =
 {
   .llseek  = eeprom_lseek,
   .read    = eeprom_read,
   .write   = eeprom_write,
   .open    = eeprom_open,
   .release = eeprom_close
 };

 /* eeprom init call. Probes for different eeprom models. */

 int __init eeprom_init(void)
 {
   init_waitqueue_head(&eeprom.wait_q);
   eeprom.busy = 0;

 #ifdef CONFIG_ETRAX_I2C_EEPROM_PROBE
 #define EETEXT "Found"
 #else
 #define EETEXT "Assuming"
 #endif
   if (register_chrdev(EEPROM_MAJOR_NR, eeprom_name, &eeprom_fops))
   {
     printk(KERN_INFO "%s: unable to get major %d for eeprom device\n",
            eeprom_name, EEPROM_MAJOR_NR);
     return -1;
   }

   printk("EEPROM char device v0.3, (c) 2000 Axis Communications AB\n");

   /*
    *  Note: Most of this probing method was taken from the printserver (5470e)
    *        codebase. It did not contain a way of finding the 16kB chips
    *        (M24128 or variants). The method used here might not work
    *        for all models. If you encounter problems the easiest way
    *        is probably to define your model within #ifdef's, and hard-
    *        code it.
    */

   eeprom.size = 0;
   eeprom.usec_delay_writecycles = INITIAL_WRITEDELAY_US;
   eeprom.usec_delay_step = 128;
   eeprom.adapt_state = 0;

 #ifdef CONFIG_ETRAX_I2C_EEPROM_PROBE
   i2c_start();
   i2c_outbyte(0x80);
   if(!i2c_getack())
   {
     /* It's not 8k.. */
     int success = 0;
     unsigned char buf_2k_start[16];

     /* Im not sure this will work... :) */
     /* assume 2kB, if failure go for 16kB */
     /* Test with 16kB settings.. */
     /* If it's a 2kB EEPROM and we address it outside it's range
      * it will mirror the address space:
      * 1. We read two locations (that are mirrored),
      *    if the content differs * it's a 16kB EEPROM.
      * 2. if it doesn't differ - write different value to one of the locations,
      *    check the other - if content still is the same it's a 2k EEPROM,
      *    restore original data.
      */
 #define LOC1 8
 #define LOC2 (0x1fb) /*1fb, 3ed, 5df, 7d1 */

    /* 2k settings */
     i2c_stop();
     eeprom.size = EEPROM_2KB;
     eeprom.select_cmd = 0xA0;
     eeprom.sequential_write_pagesize = 16;
     if( eeprom_read_buf( 0, buf_2k_start, 16 ) == 16 )
     {
       D(printk("2k start: '%16.16s'\n", buf_2k_start));
     }
     else
     {
       printk(KERN_INFO "%s: Failed to read in 2k mode!\n", eeprom_name);
     }

     /* 16k settings */
     eeprom.size = EEPROM_16KB;
     eeprom.select_cmd = 0xA0;
     eeprom.sequential_write_pagesize = 64;

     {
       unsigned char loc1[4], loc2[4], tmp[4];
       if( eeprom_read_buf(LOC2, loc2, 4) == 4)
       {
         if( eeprom_read_buf(LOC1, loc1, 4) == 4)
         {
           D(printk("0 loc1: (%i) '%4.4s' loc2 (%i) '%4.4s'\n",
                    LOC1, loc1, LOC2, loc2));
 #if 0
           if (memcmp(loc1, loc2, 4) != 0 )
           {
             /* It's 16k */
             printk(KERN_INFO "%s: 16k detected in step 1\n", eeprom_name);
             eeprom.size = EEPROM_16KB;
             success = 1;
           }
           else
 #endif
           {
             /* Do step 2 check */
             /* Invert value */
             loc1[0] = ~loc1[0];
             if (eeprom_write_buf(LOC1, loc1, 1) == 1)
             {
               /* If 2k EEPROM this write will actually write 10 bytes
                * from pos 0
                */
               D(printk("1 loc1: (%i) '%4.4s' loc2 (%i) '%4.4s'\n",
                        LOC1, loc1, LOC2, loc2));
               if( eeprom_read_buf(LOC1, tmp, 4) == 4)
               {
                 D(printk("2 loc1: (%i) '%4.4s' tmp '%4.4s'\n",
                          LOC1, loc1, tmp));
                 if (memcmp(loc1, tmp, 4) != 0 )
                 {
                   printk(KERN_INFO "%s: read and write differs! Not 16kB\n",
                          eeprom_name);
                   loc1[0] = ~loc1[0];

                   if (eeprom_write_buf(LOC1, loc1, 1) == 1)
                   {
                     success = 1;
                   }
                   else
                   {
                     printk(KERN_INFO "%s: Restore 2k failed during probe,"
                            " EEPROM might be corrupt!\n", eeprom_name);

                   }
                   i2c_stop();
                   /* Go to 2k mode and write original data */
                   eeprom.size = EEPROM_2KB;
                   eeprom.select_cmd = 0xA0;
                   eeprom.sequential_write_pagesize = 16;
                   if( eeprom_write_buf(0, buf_2k_start, 16) == 16)
                   {
                   }
                   else
                   {
                     printk(KERN_INFO "%s: Failed to write back 2k start!\n",
                            eeprom_name);
                   }

                   eeprom.size = EEPROM_2KB;
                 }
               }

               if(!success)
               {
                 if( eeprom_read_buf(LOC2, loc2, 1) == 1)
                 {
                   D(printk("0 loc1: (%i) '%4.4s' loc2 (%i) '%4.4s'\n",
                            LOC1, loc1, LOC2, loc2));
                   if (memcmp(loc1, loc2, 4) == 0 )
                   {
                     /* Data the same, must be mirrored -> 2k */
                     /* Restore data */
                     printk(KERN_INFO "%s: 2k detected in step 2\n", eeprom_name);
                     loc1[0] = ~loc1[0];
                     if (eeprom_write_buf(LOC1, loc1, 1) == 1)
                     {
                       success = 1;
                     }
                     else
                     {
                       printk(KERN_INFO "%s: Restore 2k failed during probe,"
                              " EEPROM might be corrupt!\n", eeprom_name);

                     }

                     eeprom.size = EEPROM_2KB;
                   }
                   else
                   {
                     printk(KERN_INFO "%s: 16k detected in step 2\n",
                            eeprom_name);
                     loc1[0] = ~loc1[0];
                     /* Data differs, assume 16k */
                     /* Restore data */
                     if (eeprom_write_buf(LOC1, loc1, 1) == 1)
                     {
                       success = 1;
                     }
                     else
                     {
                       printk(KERN_INFO "%s: Restore 16k failed during probe,"
                              " EEPROM might be corrupt!\n", eeprom_name);
                     }

                     eeprom.size = EEPROM_16KB;
                   }
                 }
               }
             }
           } /* read LOC1 */
         } /* address LOC1 */
         if (!success)
         {
           printk(KERN_INFO "%s: Probing failed!, using 2KB!\n", eeprom_name);
           eeprom.size = EEPROM_2KB;
         }
       } /* read */
     }
   }
   else
   {
     i2c_outbyte(0x00);
     if(!i2c_getack())
     {
       /* No 8k */
       eeprom.size = EEPROM_2KB;
     }
     else
     {
       i2c_start();
       i2c_outbyte(0x81);
       if (!i2c_getack())
       {
         eeprom.size = EEPROM_2KB;
       }
       else
       {
         /* It's a 8kB */
         i2c_inbyte();
         eeprom.size = EEPROM_8KB;
       }
     }
   }
   i2c_stop();
 #elif defined(CONFIG_ETRAX_I2C_EEPROM_16KB)
   eeprom.size = EEPROM_16KB;
 #elif defined(CONFIG_ETRAX_I2C_EEPROM_8KB)
   eeprom.size = EEPROM_8KB;
 #elif defined(CONFIG_ETRAX_I2C_EEPROM_2KB)
   eeprom.size = EEPROM_2KB;
 #endif

   switch(eeprom.size)
   {
    case (EEPROM_2KB):
      printk("%s: " EETEXT " i2c compatible 2kB eeprom.\n", eeprom_name);
      eeprom.sequential_write_pagesize = 16;
      eeprom.select_cmd = 0xA0;
      break;
    case (EEPROM_8KB):
      printk("%s: " EETEXT " i2c compatible 8kB eeprom.\n", eeprom_name);
      eeprom.sequential_write_pagesize = 16;
      eeprom.select_cmd = 0x80;
      break;
    case (EEPROM_16KB):
      printk("%s: " EETEXT " i2c compatible 16kB eeprom.\n", eeprom_name);
      eeprom.sequential_write_pagesize = 64;
      eeprom.select_cmd = 0xA0;
      break;
    default:
      eeprom.size = 0;
      printk("%s: Did not find a supported eeprom\n", eeprom_name);
      break;
   }


   eeprom_disable_write_protect();

   return 0;
 }

 /* Opens the device. */

 static int eeprom_open(struct inode * inode, struct file * file)
 {

   if(iminor(inode) != EEPROM_MINOR_NR)
      return -ENXIO;
   if(imajor(inode) != EEPROM_MAJOR_NR)
      return -ENXIO;

   if( eeprom.size > 0 )
   {
     /* OK */
     return 0;
   }

   /* No EEprom found */
   return -EFAULT;
 }

 /* Changes the current file position. */

 static loff_t eeprom_lseek(struct file * file, loff_t offset, int orig)
 {
 /*
  *  orig 0: position from begning of eeprom
  *  orig 1: relative from current position
  *  orig 2: position from last eeprom address
  */

   switch (orig)
   {
    case 0:
      file->f_pos = offset;
      break;
    case 1:
      file->f_pos += offset;
      break;
    case 2:
      file->f_pos = eeprom.size - offset;
      break;
    default:
      return -EINVAL;
   }

   /* truncate position */
   if (file->f_pos < 0)
   {
     file->f_pos = 0;
     return(-EOVERFLOW);
   }

   if (file->f_pos >= eeprom.size)
   {
     file->f_pos = eeprom.size - 1;
     return(-EOVERFLOW);
   }

   return ( file->f_pos );
 }

 /* Reads data from eeprom. */

 static int eeprom_read_buf(loff_t addr, char * buf, int count)
 {
   struct file f;

   f.f_pos = addr;
   return eeprom_read(&f, buf, count, &addr);
 }


 /* Reads data from eeprom. */

 static ssize_t eeprom_read(struct file * file, char * buf, size_t count, loff_t *off)
 {
   int read=0;
   unsigned long p = file->f_pos;

   unsigned char page;

   if(p >= eeprom.size)  /* Address i 0 - (size-1) */
   {
     return -EFAULT;
   }

   wait_event_interruptible(eeprom.wait_q, !eeprom.busy);
   if (signal_pending(current))
     return -EINTR;

   eeprom.busy++;

   page = (unsigned char) (p >> 8);

   if(!eeprom_address(p))
   {
     printk(KERN_INFO "%s: Read failed to address the eeprom: "
            "0x%08X (%i) page: %i\n", eeprom_name, (int)p, (int)p, page);
     i2c_stop();

     /* don't forget to wake them up */
     eeprom.busy--;
     wake_up_interruptible(&eeprom.wait_q);
     return -EFAULT;
   }

   if( (p + count) > eeprom.size)
   {
     /* truncate count */
     count = eeprom.size - p;
   }

   /* stop dummy write op and initiate the read op */
   i2c_start();

   /* special case for small eeproms */
   if(eeprom.size < EEPROM_16KB)
   {
     i2c_outbyte( eeprom.select_cmd | 1 | (page << 1) );
   }

   /* go on with the actual read */
   read = read_from_eeprom( buf, count);

   if(read > 0)
   {
     file->f_pos += read;
   }

   eeprom.busy--;
   wake_up_interruptible(&eeprom.wait_q);
   return read;
 }

 /* Writes data to eeprom. */

 static int eeprom_write_buf(loff_t addr, const char * buf, int count)
 {
   struct file f;

   f.f_pos = addr;

   return eeprom_write(&f, buf, count, &addr);
 }


 /* Writes data to eeprom. */

 static ssize_t eeprom_write(struct file * file, const char * buf, size_t count,
                             loff_t *off)
 {
   int i, written, restart=1;
   unsigned long p;

   if (!access_ok(VERIFY_READ, buf, count))
   {
     return -EFAULT;
   }

   wait_event_interruptible(eeprom.wait_q, !eeprom.busy);
   /* bail out if we get interrupted */
   if (signal_pending(current))
     return -EINTR;
   eeprom.busy++;
   for(i = 0; (i < EEPROM_RETRIES) && (restart > 0); i++)
   {
     restart = 0;
     written = 0;
     p = file->f_pos;


     while( (written < count) && (p < eeprom.size))
     {
       /* address the eeprom */
       if(!eeprom_address(p))
       {
         printk(KERN_INFO "%s: Write failed to address the eeprom: "
                "0x%08X (%i) \n", eeprom_name, (int)p, (int)p);
         i2c_stop();

         /* don't forget to wake them up */
         eeprom.busy--;
         wake_up_interruptible(&eeprom.wait_q);
         return -EFAULT;
       }
 #ifdef EEPROM_ADAPTIVE_TIMING
       /* Adaptive algorithm to adjust timing */
       if (eeprom.retry_cnt_addr > 0)
       {
         /* To Low now */
         D(printk(">D=%i d=%i\n",
                eeprom.usec_delay_writecycles, eeprom.usec_delay_step));

         if (eeprom.usec_delay_step < 4)
         {
           eeprom.usec_delay_step++;
           eeprom.usec_delay_writecycles += eeprom.usec_delay_step;
         }
         else
         {

           if (eeprom.adapt_state > 0)
           {
             /* To Low before */
             eeprom.usec_delay_step *= 2;
             if (eeprom.usec_delay_step > 2)
             {
               eeprom.usec_delay_step--;
             }
             eeprom.usec_delay_writecycles += eeprom.usec_delay_step;
           }
           else if (eeprom.adapt_state < 0)
           {
             /* To High before (toggle dir) */
             eeprom.usec_delay_writecycles += eeprom.usec_delay_step;
             if (eeprom.usec_delay_step > 1)
             {
               eeprom.usec_delay_step /= 2;
               eeprom.usec_delay_step--;
             }
           }
         }

         eeprom.adapt_state = 1;
       }
       else
       {
         /* To High (or good) now */
         D(printk("<D=%i d=%i\n",
                eeprom.usec_delay_writecycles, eeprom.usec_delay_step));

         if (eeprom.adapt_state < 0)
         {
           /* To High before */
           if (eeprom.usec_delay_step > 1)
           {
             eeprom.usec_delay_step *= 2;
             eeprom.usec_delay_step--;

             if (eeprom.usec_delay_writecycles > eeprom.usec_delay_step)
             {
               eeprom.usec_delay_writecycles -= eeprom.usec_delay_step;
             }
           }
         }
         else if (eeprom.adapt_state > 0)
         {
           /* To Low before (toggle dir) */
           if (eeprom.usec_delay_writecycles > eeprom.usec_delay_step)
           {
             eeprom.usec_delay_writecycles -= eeprom.usec_delay_step;
           }
           if (eeprom.usec_delay_step > 1)
           {
             eeprom.usec_delay_step /= 2;
             eeprom.usec_delay_step--;
           }

           eeprom.adapt_state = -1;
         }

         if (eeprom.adapt_state > -100)
         {
           eeprom.adapt_state--;
         }
         else
         {
           /* Restart adaption */
           D(printk("#Restart\n"));
           eeprom.usec_delay_step++;
         }
       }
 #endif /* EEPROM_ADAPTIVE_TIMING */
       /* write until we hit a page boundary or count */
       do
       {
         i2c_outbyte(buf[written]);
         if(!i2c_getack())
         {
           restart=1;
           printk(KERN_INFO "%s: write error, retrying. %d\n", eeprom_name, i);
           i2c_stop();
           break;
         }
         written++;
         p++;
       } while( written < count && ( p % eeprom.sequential_write_pagesize ));

       /* end write cycle */
       i2c_stop();
       i2c_delay(eeprom.usec_delay_writecycles);
     } /* while */
   } /* for  */

   eeprom.busy--;
   wake_up_interruptible(&eeprom.wait_q);
   if (written == 0 && file->f_pos >= eeprom.size){
     return -ENOSPC;
   }
   file->f_pos += written;
   return written;
 }

 /* Closes the device. */

 static int eeprom_close(struct inode * inode, struct file * file)
 {
   /* do nothing for now */
   return 0;
 }

 /* Sets the current address of the eeprom. */

 static int eeprom_address(unsigned long addr)
 {
   int i;
   unsigned char page, offset;

   page   = (unsigned char) (addr >> 8);
   offset = (unsigned char)  addr;

   for(i = 0; i < EEPROM_RETRIES; i++)
   {
     /* start a dummy write for addressing */
     i2c_start();

     if(eeprom.size == EEPROM_16KB)
     {
       i2c_outbyte( eeprom.select_cmd );
       i2c_getack();
       i2c_outbyte(page);
     }
     else
     {
       i2c_outbyte( eeprom.select_cmd | (page << 1) );
     }
     if(!i2c_getack())
     {
       /* retry */
       i2c_stop();
       /* Must have a delay here.. 500 works, >50, 100->works 5th time*/
       i2c_delay(MAX_WRITEDELAY_US / EEPROM_RETRIES * i);
       /* The chip needs up to 10 ms from write stop to next start */

     }
     else
     {
       i2c_outbyte(offset);

       if(!i2c_getack())
       {
         /* retry */
         i2c_stop();
       }
       else
         break;
     }
   }


   eeprom.retry_cnt_addr = i;
   D(printk("%i\n", eeprom.retry_cnt_addr));
   if(eeprom.retry_cnt_addr == EEPROM_RETRIES)
   {
     /* failed */
     return 0;
   }
   return 1;
 }

 /* Reads from current address. */

 static int read_from_eeprom(char * buf, int count)
 {
   int i, read=0;

   for(i = 0; i < EEPROM_RETRIES; i++)
   {
     if(eeprom.size == EEPROM_16KB)
     {
       i2c_outbyte( eeprom.select_cmd | 1 );
     }

     if(i2c_getack())
     {
       break;
     }
   }

   if(i == EEPROM_RETRIES)
   {
     printk(KERN_INFO "%s: failed to read from eeprom\n", eeprom_name);
     i2c_stop();

     return -EFAULT;
   }

   while( (read < count))
   {
     if (put_user(i2c_inbyte(), &buf[read++]))
     {
       i2c_stop();

       return -EFAULT;
     }

     /*
      *  make sure we don't ack last byte or you will get very strange
      *  results!
      */
     if(read < count)
     {
       i2c_sendack();
     }
   }

   /* stop the operation */
   i2c_stop();

   return read;
 }

 /* Disables write protection if applicable. */

 #define DBP_SAVE(x)
 #define ax_printf printk
 static void eeprom_disable_write_protect(void)
 {
   /* Disable write protect */
   if (eeprom.size == EEPROM_8KB)
   {
     /* Step 1 Set WEL = 1 (write 00000010 to address 1FFFh */
     i2c_start();
     i2c_outbyte(0xbe);
     if(!i2c_getack())
     {
       DBP_SAVE(ax_printf("Get ack returns false\n"));
     }
     i2c_outbyte(0xFF);
     if(!i2c_getack())
     {
       DBP_SAVE(ax_printf("Get ack returns false 2\n"));
     }
     i2c_outbyte(0x02);
     if(!i2c_getack())
     {
       DBP_SAVE(ax_printf("Get ack returns false 3\n"));
     }
     i2c_stop();

     i2c_delay(1000);

     /* Step 2 Set RWEL = 1 (write 00000110 to address 1FFFh */
     i2c_start();
     i2c_outbyte(0xbe);
     if(!i2c_getack())
     {
       DBP_SAVE(ax_printf("Get ack returns false 55\n"));
     }
     i2c_outbyte(0xFF);
     if(!i2c_getack())
     {
       DBP_SAVE(ax_printf("Get ack returns false 52\n"));
     }
     i2c_outbyte(0x06);
     if(!i2c_getack())
     {
       DBP_SAVE(ax_printf("Get ack returns false 53\n"));
     }
     i2c_stop();

     /* Step 3 Set BP1, BP0, and/or WPEN bits (write 00000110 to address 1FFFh */
     i2c_start();
     i2c_outbyte(0xbe);
     if(!i2c_getack())
     {
       DBP_SAVE(ax_printf("Get ack returns false 56\n"));
     }
     i2c_outbyte(0xFF);
     if(!i2c_getack())
     {
       DBP_SAVE(ax_printf("Get ack returns false 57\n"));
     }
     i2c_outbyte(0x06);
     if(!i2c_getack())
     {
       DBP_SAVE(ax_printf("Get ack returns false 58\n"));
     }
     i2c_stop();

     /* Write protect disabled */
   }
 }

 module_init(eeprom_init);
	/!****************************************************************************
	*!
	*! Implements an interface for i2c compatible eeproms to run under Linux.
	*! Supports 2k, 8k(?) and 16k. Uses adaptive timing adjustments by
	*! Johan.Adolfsson@axis.com
	*!
	*! Probing results:
	*! 8k or not is detected (the assumes 2k or 16k)
	*! 2k or 16k detected using test reads and writes.
	*!
	*!------------------------------------------------------------------------
	*! HISTORY
	*!
	*! DATE NAME CHANGES
	*! ---- ---- -------
	*! Aug 28 1999 Edgar Iglesias Initial Version
	*! Aug 31 1999 Edgar Iglesias Allow simultaneous users.
	*! Sep 03 1999 Edgar Iglesias Updated probe.
	*! Sep 03 1999 Edgar Iglesias Added bail-out stuff if we get interrupted
	*! in the spin-lock.
	*!
	*! $Log: eeprom.c,v $
	*! Revision 1.12 2005/06/19 17:06:46 starvik
	*! Merge of Linux 2.6.12.
	*!
	*! Revision 1.11 2005/01/26 07:14:46 starvik
	*! Applied diff from kernel janitors (Nish Aravamudan).
	*!
	*! Revision 1.10 2003/09/11 07:29:48 starvik
	*! Merge of Linux 2.6.0-test5
	*!
	*! Revision 1.9 2003/07/04 08:27:37 starvik
	*! Merge of Linux 2.5.74
	*!
	*! Revision 1.8 2003/04/09 05:20:47 starvik
	*! Merge of Linux 2.5.67
	*!
	*! Revision 1.6 2003/02/10 07:19:28 starvik
	*! Removed misplaced ;
	*!
	*! Revision 1.5 2002/12/11 13:13:57 starvik
	*! Added arch/ to v10 specific includes
	*! Added fix from Linux 2.4 in serial.c (flush_to_flip_buffer)
	*!
	*! Revision 1.4 2002/11/20 11:56:10 starvik
	*! Merge of Linux 2.5.48
	*!
	*! Revision 1.3 2002/11/18 13:16:06 starvik
	*! Linux 2.5 port of latest 2.4 drivers
	*!
	*! Revision 1.8 2001/06/15 13:24:29 jonashg
	! Added verification of pointers from userspace in read and write.
	! Made busy counter volatile.
	! Added define for initial write delay.
	! Removed warnings by using loff_t instead of unsigned long.
	*!
	*! Revision 1.7 2001/06/14 15:26:54 jonashg
	*! Removed test because condition is always true.
	*!
	*! Revision 1.6 2001/06/14 15:18:20 jonashg
	*! Kb -> kB (makes quite a difference if you don't know if you have 2k or 16k).
	*!
	*! Revision 1.5 2001/06/14 14:39:51 jonashg
	*! Forgot to use name when registering the driver.
	*!
	*! Revision 1.4 2001/06/14 14:35:47 jonashg
	! Gave driver a name and used it in printk's.
	! Cleanup.
	*!
	*! Revision 1.3 2001/03/19 16:04:46 markusl
	*! Fixed init of fops struct
	*!
	*! Revision 1.2 2001/03/19 10:35:07 markusl
	*! 2.4 port of eeprom driver
	*!
	*! Revision 1.8 2000/05/18 10:42:25 edgar
	*! Make sure to end write cycle on _every_ write
	*!
	*! Revision 1.7 2000/01/17 17:41:01 johana
	*! Adjusted probing and return -ENOSPC when writing outside EEPROM
	*!
	*! Revision 1.6 2000/01/17 15:50:36 johana
	*! Added adaptive timing adjustments and fixed autoprobing for 2k and 16k(?)
	*! EEPROMs
	*!
	*! Revision 1.5 1999/09/03 15:07:37 edgar
	*! Added bail-out check to the spinlock
	*!
	*! Revision 1.4 1999/09/03 12:11:17 bjornw
	*! Proper atomicity (need to use spinlocks, not if's). users -> busy.
	*!
	*!
	*! (c) 1999 Axis Communications AB, Lund, Sweden
	!****************************************************************************/

	#include <linux/kernel.h>
	#include <linux/sched.h>
	#include <linux/fs.h>
	#include <linux/init.h>
	#include <linux/delay.h>
	#include <linux/interrupt.h>
	#include <linux/wait.h>
	#include <asm/uaccess.h>
	#include "i2c.h"

	#define D(x)

	/* If we should use adaptive timing or not: */
	//#define EEPROM_ADAPTIVE_TIMING

	#define EEPROM_MAJOR_NR 122 /* use a LOCAL/EXPERIMENTAL major for now */
	#define EEPROM_MINOR_NR 0

	/* Empirical sane initial value of the delay, the value will be adapted to
	* what the chip needs when using EEPROM_ADAPTIVE_TIMING.
	*/
	#define INITIAL_WRITEDELAY_US 4000
	#define MAX_WRITEDELAY_US 10000 /* 10 ms according to spec for 2KB EEPROM */

	/* This one defines how many times to try when eeprom fails. */
	#define EEPROM_RETRIES 10

	#define EEPROM_2KB (2 * 1024)
	/#define EEPROM_4KB (4 1024)/ / Exists but not used in Axis products */
	#define EEPROM_8KB (8 * 1024 - 1 ) /* Last byte has write protection bit */
	#define EEPROM_16KB (16 * 1024)

	#define i2c_delay(x) udelay(x)

	/*
	* This structure describes the attached eeprom chip.
	* The values are probed for.
	*/

	struct eeprom_type
	{
	unsigned long size;
	unsigned long sequential_write_pagesize;
	unsigned char select_cmd;
	unsigned long usec_delay_writecycles; /* Min time between write cycles
	(up to 10ms for some models) */
	unsigned long usec_delay_step; /* For adaptive algorithm */
	int adapt_state; /* 1 = To high , 0 = Even, -1 = To low */

	/* this one is to keep the read/write operations atomic */
	wait_queue_head_t wait_q;
	volatile int busy;
	int retry_cnt_addr; /* Used to keep track of number of retries for
	adaptive timing adjustments */
	int retry_cnt_read;
	};

	static int eeprom_open(struct inode * inode, struct file * file);
	static loff_t eeprom_lseek(struct file * file, loff_t offset, int orig);
	static ssize_t eeprom_read(struct file * file, char * buf, size_t count,
	loff_t *off);
	static ssize_t eeprom_write(struct file * file, const char * buf, size_t count,
	loff_t *off);
	static int eeprom_close(struct inode * inode, struct file * file);

	static int eeprom_address(unsigned long addr);
	static int read_from_eeprom(char * buf, int count);
	static int eeprom_write_buf(loff_t addr, const char * buf, int count);
	static int eeprom_read_buf(loff_t addr, char * buf, int count);

	static void eeprom_disable_write_protect(void);


	static const char eeprom_name[] = "eeprom";

	/* chip description */
	static struct eeprom_type eeprom;

	/* This is the exported file-operations structure for this device. */
	const struct file_operations eeprom_fops =
	{
	.llseek = eeprom_lseek,
	.read = eeprom_read,
	.write = eeprom_write,
	.open = eeprom_open,
	.release = eeprom_close
	};

	/* eeprom init call. Probes for different eeprom models. */

	int __init eeprom_init(void)
	{
	init_waitqueue_head(&eeprom.wait_q);
	eeprom.busy = 0;

	#ifdef CONFIG_ETRAX_I2C_EEPROM_PROBE
	#define EETEXT "Found"
	#else
	#define EETEXT "Assuming"
	#endif
	if (register_chrdev(EEPROM_MAJOR_NR, eeprom_name, &eeprom_fops))
	{
	printk(KERN_INFO "%s: unable to get major %d for eeprom device\n",
	eeprom_name, EEPROM_MAJOR_NR);
	return -1;
	}

	printk("EEPROM char device v0.3, (c) 2000 Axis Communications AB\n");

	/*
	* Note: Most of this probing method was taken from the printserver (5470e)
	* codebase. It did not contain a way of finding the 16kB chips
	* (M24128 or variants). The method used here might not work
	* for all models. If you encounter problems the easiest way
	* is probably to define your model within #ifdef's, and hard-
	* code it.
	*/

	eeprom.size = 0;
	eeprom.usec_delay_writecycles = INITIAL_WRITEDELAY_US;
	eeprom.usec_delay_step = 128;
	eeprom.adapt_state = 0;

	#ifdef CONFIG_ETRAX_I2C_EEPROM_PROBE
	i2c_start();
	i2c_outbyte(0x80);
	if(!i2c_getack())
	{
	/* It's not 8k.. */
	int success = 0;
	unsigned char buf_2k_start[16];

	/* Im not sure this will work... :) */
	/* assume 2kB, if failure go for 16kB */
	/* Test with 16kB settings.. */
	/* If it's a 2kB EEPROM and we address it outside it's range
	* it will mirror the address space:
	* 1. We read two locations (that are mirrored),
	* if the content differs * it's a 16kB EEPROM.
	* 2. if it doesn't differ - write different value to one of the locations,
	* check the other - if content still is the same it's a 2k EEPROM,
	* restore original data.
	*/
	#define LOC1 8
	#define LOC2 (0x1fb) /1fb, 3ed, 5df, 7d1 /

	/* 2k settings */
	i2c_stop();
	eeprom.size = EEPROM_2KB;
	eeprom.select_cmd = 0xA0;
	eeprom.sequential_write_pagesize = 16;
	if( eeprom_read_buf( 0, buf_2k_start, 16 ) == 16 )
	{
	D(printk("2k start: '%16.16s'\n", buf_2k_start));
	}
	else
	{
	printk(KERN_INFO "%s: Failed to read in 2k mode!\n", eeprom_name);
	}

	/* 16k settings */
	eeprom.size = EEPROM_16KB;
	eeprom.select_cmd = 0xA0;
	eeprom.sequential_write_pagesize = 64;

	{
	unsigned char loc1[4], loc2[4], tmp[4];
	if( eeprom_read_buf(LOC2, loc2, 4) == 4)
	{
	if( eeprom_read_buf(LOC1, loc1, 4) == 4)
	{
	D(printk("0 loc1: (%i) '%4.4s' loc2 (%i) '%4.4s'\n",
	LOC1, loc1, LOC2, loc2));
	#if 0
	if (memcmp(loc1, loc2, 4) != 0 )
	{
	/* It's 16k */
	printk(KERN_INFO "%s: 16k detected in step 1\n", eeprom_name);
	eeprom.size = EEPROM_16KB;
	success = 1;
	}
	else
	#endif
	{
	/* Do step 2 check */
	/* Invert value */
	loc1[0] = ~loc1[0];
	if (eeprom_write_buf(LOC1, loc1, 1) == 1)
	{
	/* If 2k EEPROM this write will actually write 10 bytes
	* from pos 0
	*/
	D(printk("1 loc1: (%i) '%4.4s' loc2 (%i) '%4.4s'\n",
	LOC1, loc1, LOC2, loc2));
	if( eeprom_read_buf(LOC1, tmp, 4) == 4)
	{
	D(printk("2 loc1: (%i) '%4.4s' tmp '%4.4s'\n",
	LOC1, loc1, tmp));
	if (memcmp(loc1, tmp, 4) != 0 )
	{
	printk(KERN_INFO "%s: read and write differs! Not 16kB\n",
	eeprom_name);
	loc1[0] = ~loc1[0];

	if (eeprom_write_buf(LOC1, loc1, 1) == 1)
	{
	success = 1;
	}
	else
	{
	printk(KERN_INFO "%s: Restore 2k failed during probe,"
	" EEPROM might be corrupt!\n", eeprom_name);

	}
	i2c_stop();
	/* Go to 2k mode and write original data */
	eeprom.size = EEPROM_2KB;
	eeprom.select_cmd = 0xA0;
	eeprom.sequential_write_pagesize = 16;
	if( eeprom_write_buf(0, buf_2k_start, 16) == 16)
	{
	}
	else
	{
	printk(KERN_INFO "%s: Failed to write back 2k start!\n",
	eeprom_name);
	}

	eeprom.size = EEPROM_2KB;
	}
	}

	if(!success)
	{
	if( eeprom_read_buf(LOC2, loc2, 1) == 1)
	{
	D(printk("0 loc1: (%i) '%4.4s' loc2 (%i) '%4.4s'\n",
	LOC1, loc1, LOC2, loc2));
	if (memcmp(loc1, loc2, 4) == 0 )
	{
	/* Data the same, must be mirrored -> 2k */
	/* Restore data */
	printk(KERN_INFO "%s: 2k detected in step 2\n", eeprom_name);
	loc1[0] = ~loc1[0];
	if (eeprom_write_buf(LOC1, loc1, 1) == 1)
	{
	success = 1;
	}
	else
	{
	printk(KERN_INFO "%s: Restore 2k failed during probe,"
	" EEPROM might be corrupt!\n", eeprom_name);

	}

	eeprom.size = EEPROM_2KB;
	}
	else
	{
	printk(KERN_INFO "%s: 16k detected in step 2\n",
	eeprom_name);
	loc1[0] = ~loc1[0];
	/* Data differs, assume 16k */
	/* Restore data */
	if (eeprom_write_buf(LOC1, loc1, 1) == 1)
	{
	success = 1;
	}
	else
	{
	printk(KERN_INFO "%s: Restore 16k failed during probe,"
	" EEPROM might be corrupt!\n", eeprom_name);
	}

	eeprom.size = EEPROM_16KB;
	}
	}
	}
	}
	} /* read LOC1 */
	} /* address LOC1 */
	if (!success)
	{
	printk(KERN_INFO "%s: Probing failed!, using 2KB!\n", eeprom_name);
	eeprom.size = EEPROM_2KB;
	}
	} /* read */
	}
	}
	else
	{
	i2c_outbyte(0x00);
	if(!i2c_getack())
	{
	/* No 8k */
	eeprom.size = EEPROM_2KB;
	}
	else
	{
	i2c_start();
	i2c_outbyte(0x81);
	if (!i2c_getack())
	{
	eeprom.size = EEPROM_2KB;
	}
	else
	{
	/* It's a 8kB */
	i2c_inbyte();
	eeprom.size = EEPROM_8KB;
	}
	}
	}
	i2c_stop();
	#elif defined(CONFIG_ETRAX_I2C_EEPROM_16KB)
	eeprom.size = EEPROM_16KB;
	#elif defined(CONFIG_ETRAX_I2C_EEPROM_8KB)
	eeprom.size = EEPROM_8KB;
	#elif defined(CONFIG_ETRAX_I2C_EEPROM_2KB)
	eeprom.size = EEPROM_2KB;
	#endif

	switch(eeprom.size)
	{
	case (EEPROM_2KB):
	printk("%s: " EETEXT " i2c compatible 2kB eeprom.\n", eeprom_name);
	eeprom.sequential_write_pagesize = 16;
	eeprom.select_cmd = 0xA0;
	break;
	case (EEPROM_8KB):
	printk("%s: " EETEXT " i2c compatible 8kB eeprom.\n", eeprom_name);
	eeprom.sequential_write_pagesize = 16;
	eeprom.select_cmd = 0x80;
	break;
	case (EEPROM_16KB):
	printk("%s: " EETEXT " i2c compatible 16kB eeprom.\n", eeprom_name);
	eeprom.sequential_write_pagesize = 64;
	eeprom.select_cmd = 0xA0;
	break;
	default:
	eeprom.size = 0;
	printk("%s: Did not find a supported eeprom\n", eeprom_name);
	break;
	}



	eeprom_disable_write_protect();

	return 0;
	}

	/* Opens the device. */

	static int eeprom_open(struct inode * inode, struct file * file)
	{

	if(iminor(inode) != EEPROM_MINOR_NR)
	return -ENXIO;
	if(imajor(inode) != EEPROM_MAJOR_NR)
	return -ENXIO;

	if( eeprom.size > 0 )
	{
	/* OK */
	return 0;
	}

	/* No EEprom found */
	return -EFAULT;
	}

	/* Changes the current file position. */

	static loff_t eeprom_lseek(struct file * file, loff_t offset, int orig)
	{
	/*
	* orig 0: position from begning of eeprom
	* orig 1: relative from current position
	* orig 2: position from last eeprom address
	*/

	switch (orig)
	{
	case 0:
	file->f_pos = offset;
	break;
	case 1:
	file->f_pos += offset;
	break;
	case 2:
	file->f_pos = eeprom.size - offset;
	break;
	default:
	return -EINVAL;
	}

	/* truncate position */
	if (file->f_pos < 0)
	{
	file->f_pos = 0;
	return(-EOVERFLOW);
	}

	if (file->f_pos >= eeprom.size)
	{
	file->f_pos = eeprom.size - 1;
	return(-EOVERFLOW);
	}

	return ( file->f_pos );
	}

	/* Reads data from eeprom. */

	static int eeprom_read_buf(loff_t addr, char * buf, int count)
	{
	struct file f;

	f.f_pos = addr;
	return eeprom_read(&f, buf, count, &addr);
	}



	/* Reads data from eeprom. */

	static ssize_t eeprom_read(struct file * file, char * buf, size_t count, loff_t *off)
	{
	int read=0;
	unsigned long p = file->f_pos;

	unsigned char page;

	if(p >= eeprom.size) /* Address i 0 - (size-1) */
	{
	return -EFAULT;
	}

	wait_event_interruptible(eeprom.wait_q, !eeprom.busy);
	if (signal_pending(current))
	return -EINTR;

	eeprom.busy++;

	page = (unsigned char) (p >> 8);

	if(!eeprom_address(p))
	{
	printk(KERN_INFO "%s: Read failed to address the eeprom: "
	"0x%08X (%i) page: %i\n", eeprom_name, (int)p, (int)p, page);
	i2c_stop();

	/* don't forget to wake them up */
	eeprom.busy--;
	wake_up_interruptible(&eeprom.wait_q);
	return -EFAULT;
	}

	if( (p + count) > eeprom.size)
	{
	/* truncate count */
	count = eeprom.size - p;
	}

	/* stop dummy write op and initiate the read op */
	i2c_start();

	/* special case for small eeproms */
	if(eeprom.size < EEPROM_16KB)
	{
	i2c_outbyte( eeprom.select_cmd \| 1 \| (page << 1) );
	}

	/* go on with the actual read */
	read = read_from_eeprom( buf, count);

	if(read > 0)
	{
	file->f_pos += read;
	}

	eeprom.busy--;
	wake_up_interruptible(&eeprom.wait_q);
	return read;
	}

	/* Writes data to eeprom. */

	static int eeprom_write_buf(loff_t addr, const char * buf, int count)
	{
	struct file f;

	f.f_pos = addr;

	return eeprom_write(&f, buf, count, &addr);
	}


	/* Writes data to eeprom. */

	static ssize_t eeprom_write(struct file * file, const char * buf, size_t count,
	loff_t *off)
	{
	int i, written, restart=1;
	unsigned long p;

	if (!access_ok(VERIFY_READ, buf, count))
	{
	return -EFAULT;
	}

	wait_event_interruptible(eeprom.wait_q, !eeprom.busy);
	/* bail out if we get interrupted */
	if (signal_pending(current))
	return -EINTR;
	eeprom.busy++;
	for(i = 0; (i < EEPROM_RETRIES) && (restart > 0); i++)
	{
	restart = 0;
	written = 0;
	p = file->f_pos;


	while( (written < count) && (p < eeprom.size))
	{
	/* address the eeprom */
	if(!eeprom_address(p))
	{
	printk(KERN_INFO "%s: Write failed to address the eeprom: "
	"0x%08X (%i) \n", eeprom_name, (int)p, (int)p);
	i2c_stop();

	/* don't forget to wake them up */
	eeprom.busy--;
	wake_up_interruptible(&eeprom.wait_q);
	return -EFAULT;
	}
	#ifdef EEPROM_ADAPTIVE_TIMING
	/* Adaptive algorithm to adjust timing */
	if (eeprom.retry_cnt_addr > 0)
	{
	/* To Low now */
	D(printk(">D=%i d=%i\n",
	eeprom.usec_delay_writecycles, eeprom.usec_delay_step));

	if (eeprom.usec_delay_step < 4)
	{
	eeprom.usec_delay_step++;
	eeprom.usec_delay_writecycles += eeprom.usec_delay_step;
	}
	else
	{

	if (eeprom.adapt_state > 0)
	{
	/* To Low before */
	eeprom.usec_delay_step *= 2;
	if (eeprom.usec_delay_step > 2)
	{
	eeprom.usec_delay_step--;
	}
	eeprom.usec_delay_writecycles += eeprom.usec_delay_step;
	}
	else if (eeprom.adapt_state < 0)
	{
	/* To High before (toggle dir) */
	eeprom.usec_delay_writecycles += eeprom.usec_delay_step;
	if (eeprom.usec_delay_step > 1)
	{
	eeprom.usec_delay_step /= 2;
	eeprom.usec_delay_step--;
	}
	}
	}

	eeprom.adapt_state = 1;
	}
	else
	{
	/* To High (or good) now */
	D(printk("<D=%i d=%i\n",
	eeprom.usec_delay_writecycles, eeprom.usec_delay_step));

	if (eeprom.adapt_state < 0)
	{
	/* To High before */
	if (eeprom.usec_delay_step > 1)
	{
	eeprom.usec_delay_step *= 2;
	eeprom.usec_delay_step--;

	if (eeprom.usec_delay_writecycles > eeprom.usec_delay_step)
	{
	eeprom.usec_delay_writecycles -= eeprom.usec_delay_step;
	}
	}
	}
	else if (eeprom.adapt_state > 0)
	{
	/* To Low before (toggle dir) */
	if (eeprom.usec_delay_writecycles > eeprom.usec_delay_step)
	{
	eeprom.usec_delay_writecycles -= eeprom.usec_delay_step;
	}
	if (eeprom.usec_delay_step > 1)
	{
	eeprom.usec_delay_step /= 2;
	eeprom.usec_delay_step--;
	}

	eeprom.adapt_state = -1;
	}

	if (eeprom.adapt_state > -100)
	{
	eeprom.adapt_state--;
	}
	else
	{
	/* Restart adaption */
	D(printk("#Restart\n"));
	eeprom.usec_delay_step++;
	}
	}
	#endif /* EEPROM_ADAPTIVE_TIMING */
	/* write until we hit a page boundary or count */
	do
	{
	i2c_outbyte(buf[written]);
	if(!i2c_getack())
	{
	restart=1;
	printk(KERN_INFO "%s: write error, retrying. %d\n", eeprom_name, i);
	i2c_stop();
	break;
	}
	written++;
	p++;
	} while( written < count && ( p % eeprom.sequential_write_pagesize ));

	/* end write cycle */
	i2c_stop();
	i2c_delay(eeprom.usec_delay_writecycles);
	} /* while */
	} /* for */

	eeprom.busy--;
	wake_up_interruptible(&eeprom.wait_q);
	if (written == 0 && file->f_pos >= eeprom.size){
	return -ENOSPC;
	}
	file->f_pos += written;
	return written;
	}

	/* Closes the device. */

	static int eeprom_close(struct inode * inode, struct file * file)
	{
	/* do nothing for now */
	return 0;
	}

	/* Sets the current address of the eeprom. */

	static int eeprom_address(unsigned long addr)
	{
	int i;
	unsigned char page, offset;

	page = (unsigned char) (addr >> 8);
	offset = (unsigned char) addr;

	for(i = 0; i < EEPROM_RETRIES; i++)
	{
	/* start a dummy write for addressing */
	i2c_start();

	if(eeprom.size == EEPROM_16KB)
	{
	i2c_outbyte( eeprom.select_cmd );
	i2c_getack();
	i2c_outbyte(page);
	}
	else
	{
	i2c_outbyte( eeprom.select_cmd \| (page << 1) );
	}
	if(!i2c_getack())
	{
	/* retry */
	i2c_stop();
	/* Must have a delay here.. 500 works, >50, 100->works 5th time*/
	i2c_delay(MAX_WRITEDELAY_US / EEPROM_RETRIES * i);
	/* The chip needs up to 10 ms from write stop to next start */

	}
	else
	{
	i2c_outbyte(offset);

	if(!i2c_getack())
	{
	/* retry */
	i2c_stop();
	}
	else
	break;
	}
	}


	eeprom.retry_cnt_addr = i;
	D(printk("%i\n", eeprom.retry_cnt_addr));
	if(eeprom.retry_cnt_addr == EEPROM_RETRIES)
	{
	/* failed */
	return 0;
	}
	return 1;
	}

	/* Reads from current address. */

	static int read_from_eeprom(char * buf, int count)
	{
	int i, read=0;

	for(i = 0; i < EEPROM_RETRIES; i++)
	{
	if(eeprom.size == EEPROM_16KB)
	{
	i2c_outbyte( eeprom.select_cmd \| 1 );
	}

	if(i2c_getack())
	{
	break;
	}
	}

	if(i == EEPROM_RETRIES)
	{
	printk(KERN_INFO "%s: failed to read from eeprom\n", eeprom_name);
	i2c_stop();

	return -EFAULT;
	}

	while( (read < count))
	{
	if (put_user(i2c_inbyte(), &buf[read++]))
	{
	i2c_stop();

	return -EFAULT;
	}

	/*
	* make sure we don't ack last byte or you will get very strange
	* results!
	*/
	if(read < count)
	{
	i2c_sendack();
	}
	}

	/* stop the operation */
	i2c_stop();

	return read;
	}

	/* Disables write protection if applicable. */

	#define DBP_SAVE(x)
	#define ax_printf printk
	static void eeprom_disable_write_protect(void)
	{
	/* Disable write protect */
	if (eeprom.size == EEPROM_8KB)
	{
	/* Step 1 Set WEL = 1 (write 00000010 to address 1FFFh */
	i2c_start();
	i2c_outbyte(0xbe);
	if(!i2c_getack())
	{
	DBP_SAVE(ax_printf("Get ack returns false\n"));
	}
	i2c_outbyte(0xFF);
	if(!i2c_getack())
	{
	DBP_SAVE(ax_printf("Get ack returns false 2\n"));
	}
	i2c_outbyte(0x02);
	if(!i2c_getack())
	{
	DBP_SAVE(ax_printf("Get ack returns false 3\n"));
	}
	i2c_stop();

	i2c_delay(1000);

	/* Step 2 Set RWEL = 1 (write 00000110 to address 1FFFh */
	i2c_start();
	i2c_outbyte(0xbe);
	if(!i2c_getack())
	{
	DBP_SAVE(ax_printf("Get ack returns false 55\n"));
	}
	i2c_outbyte(0xFF);
	if(!i2c_getack())
	{
	DBP_SAVE(ax_printf("Get ack returns false 52\n"));
	}
	i2c_outbyte(0x06);
	if(!i2c_getack())
	{
	DBP_SAVE(ax_printf("Get ack returns false 53\n"));
	}
	i2c_stop();

	/* Step 3 Set BP1, BP0, and/or WPEN bits (write 00000110 to address 1FFFh */
	i2c_start();
	i2c_outbyte(0xbe);
	if(!i2c_getack())
	{
	DBP_SAVE(ax_printf("Get ack returns false 56\n"));
	}
	i2c_outbyte(0xFF);
	if(!i2c_getack())
	{
	DBP_SAVE(ax_printf("Get ack returns false 57\n"));
	}
	i2c_outbyte(0x06);
	if(!i2c_getack())
	{
	DBP_SAVE(ax_printf("Get ack returns false 58\n"));
	}
	i2c_stop();

	/* Write protect disabled */
	}
	}

	module_init(eeprom_init);