drivers/scsi/cpqfcTSi2c.c - android_kernel_oneplus_msm8996 - Gitiles

 /* Copyright(c) 2000, Compaq Computer Corporation
  * Fibre Channel Host Bus Adapter
  * 64-bit, 66MHz PCI
  * Originally developed and tested on:
  * (front): [chip] Tachyon TS HPFC-5166A/1.2  L2C1090 ...
  *          SP# P225CXCBFIEL6T, Rev XC
  *          SP# 161290-001, Rev XD
  * (back): Board No. 010008-001 A/W Rev X5, FAB REV X5
  *
  * 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, 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.
  * Written by Don Zimmerman
 */
 // These functions control the NVRAM I2C hardware on
 // non-intelligent Fibre Host Adapters.
 // The primary purpose is to read the HBA's NVRAM to get adapter's
 // manufactured WWN to copy into Tachyon chip registers
 // Orignal source author unknown

 #include <linux/types.h>
 enum boolean { FALSE, TRUE } ;


 #ifndef UCHAR
 typedef __u8 UCHAR;
 #endif
 #ifndef BOOLEAN
 typedef __u8 BOOLEAN;
 #endif
 #ifndef USHORT
 typedef __u16 USHORT;
 #endif
 #ifndef ULONG
 typedef __u32 ULONG;
 #endif


 #include <linux/string.h>
 #include <linux/pci.h>
 #include <linux/delay.h>
 #include <linux/sched.h>
 #include <asm/io.h>  // struct pt_regs for IRQ handler & Port I/O

 #include "cpqfcTSchip.h"

 static void tl_i2c_tx_byte( void* GPIOout, UCHAR data );
 /*static BOOLEAN tl_write_i2c_page_portion( void* GPIOin, void* GPIOout,
   USHORT startOffset,  // e.g. 0x2f for WWN start
   USHORT count,
   UCHAR *buf );
 */

 //
 // Tachlite GPIO2, GPIO3 (I2C) DEFINES
 // The NVRAM chip NM24C03 defines SCL (serial clock) and SDA (serial data)
 // GPIO2 drives SDA, and GPIO3 drives SCL
 //
 // Since Tachlite inverts the state of the GPIO 0-3 outputs, SET writes 0
 // and clear writes 1. The input lines (read in TL status) is NOT inverted
 // This really helps confuse the code and debugging.

 #define SET_DATA_HI  0x0
 #define SET_DATA_LO  0x8
 #define SET_CLOCK_HI 0x0
 #define SET_CLOCK_LO 0x4

 #define SENSE_DATA_HI  0x8
 #define SENSE_DATA_LO  0x0
 #define SENSE_CLOCK_HI 0x4
 #define SENSE_CLOCK_LO 0x0

 #define SLAVE_READ_ADDRESS    0xA1
 #define SLAVE_WRITE_ADDRESS   0xA0


 static void i2c_delay(ULONG mstime);
 static void tl_i2c_clock_pulse( UCHAR , void* GPIOout);
 static UCHAR tl_read_i2c_data( void* );


 //-----------------------------------------------------------------------------
 //
 //      Name:   I2C_RX_ACK
 //
 //      This routine receives an acknowledge over the I2C bus.
 //
 //-----------------------------------------------------------------------------
 static unsigned short tl_i2c_rx_ack( void* GPIOin, void* GPIOout )
 {
   unsigned long value;

 	// do clock pulse, let data line float high
   tl_i2c_clock_pulse( SET_DATA_HI, GPIOout );

 	// slave must drive data low for acknowledge
   value = tl_read_i2c_data( GPIOin);
   if (value & SENSE_DATA_HI )
     return( FALSE );

   return( TRUE );
 }
 //-----------------------------------------------------------------------------
 //
 //      Name:   READ_I2C_REG
 //
 //      This routine reads the I2C control register using the global
 //      IO address stored in gpioreg.
 //
 //-----------------------------------------------------------------------------
 static UCHAR tl_read_i2c_data( void* gpioreg )
 {
   return( (UCHAR)(readl( gpioreg ) & 0x08L) ); // GPIO3
 }
 //-----------------------------------------------------------------------------
 //
 //      Name:   WRITE_I2C_REG
 //
 //      This routine writes the I2C control register using the global
 //      IO address stored in gpioreg.
 //      In Tachlite, we don't want to modify other bits in TL Control reg.
 //
 //-----------------------------------------------------------------------------
 static void tl_write_i2c_reg( void* gpioregOUT, UCHAR value )
 {
   ULONG  temp;

 	// First read the register and clear out the old bits
   temp = readl( gpioregOUT ) & 0xfffffff3L;

 	// Now or in the new data and send it back out
   writel( temp | value, gpioregOUT);
 }
 //-----------------------------------------------------------------------------
 //
 //      Name:   I2C_TX_START
 //
 //      This routine transmits a start condition over the I2C bus.
 //      1. Set SCL (clock, GPIO2) HIGH, set SDA (data, GPIO3) HIGH,
 //      wait 5us to stabilize.
 //      2. With SCL still HIGH, drive SDA low.  The low transition marks
 //         the start condition to NM24Cxx (the chip)
 //      NOTE! In TL control reg., output 1 means chip sees LOW
 //
 //-----------------------------------------------------------------------------
 static unsigned short tl_i2c_tx_start( void* GPIOin, void* GPIOout )
 {
   unsigned short i;
   ULONG value;

   if ( !(tl_read_i2c_data(GPIOin) & SENSE_DATA_HI))
   {
     // start with clock high, let data float high
     tl_write_i2c_reg(  GPIOout, SET_DATA_HI | SET_CLOCK_HI );

     // keep sending clock pulses if slave is driving data line
     for (i = 0; i < 10; i++)
     {
       tl_i2c_clock_pulse( SET_DATA_HI, GPIOout );

       if ( tl_read_i2c_data(GPIOin) & SENSE_DATA_HI )
 	break;
     }

 		// if he's still driving data low after 10 clocks, abort
     value = tl_read_i2c_data( GPIOin ); // read status
     if (!(value & 0x08) )
       return( FALSE );
   }


 	// To START, bring data low while clock high
   tl_write_i2c_reg(  GPIOout, SET_CLOCK_HI | SET_DATA_LO );

   i2c_delay(0);

   return( TRUE );                           // TX start successful
 }
 //-----------------------------------------------------------------------------
 //
 //      Name:   I2C_TX_STOP
 //
 //      This routine transmits a stop condition over the I2C bus.
 //
 //-----------------------------------------------------------------------------

 static unsigned short tl_i2c_tx_stop( void* GPIOin, void* GPIOout )
 {
   int i;

   for (i = 0; i < 10; i++)
   {
   // Send clock pulse, drive data line low
     tl_i2c_clock_pulse( SET_DATA_LO, GPIOout );

   // To STOP, bring data high while clock high
     tl_write_i2c_reg(  GPIOout, SET_DATA_HI | SET_CLOCK_HI );

   // Give the data line time to float high
     i2c_delay(0);

   // If slave is driving data line low, there's a problem; retry
     if ( tl_read_i2c_data(GPIOin) & SENSE_DATA_HI )
       return( TRUE );  // TX STOP successful!
   }

   return( FALSE );                      // error
 }
 //-----------------------------------------------------------------------------
 //
 //      Name:   I2C_TX_uchar
 //
 //      This routine transmits a byte across the I2C bus.
 //
 //-----------------------------------------------------------------------------
 static void tl_i2c_tx_byte( void* GPIOout, UCHAR data )
 {
   UCHAR bit;

   for (bit = 0x80; bit; bit >>= 1)
   {
     if( data & bit )
       tl_i2c_clock_pulse( (UCHAR)SET_DATA_HI, GPIOout);
     else
       tl_i2c_clock_pulse( (UCHAR)SET_DATA_LO, GPIOout);
   }
 }
 //-----------------------------------------------------------------------------
 //
 //      Name:   I2C_RX_uchar
 //
 //      This routine receives a byte across the I2C bus.
 //
 //-----------------------------------------------------------------------------
 static UCHAR tl_i2c_rx_byte( void* GPIOin, void* GPIOout )
 {
   UCHAR bit;
   UCHAR data = 0;


   for (bit = 0x80; bit; bit >>= 1) {
     // do clock pulse, let data line float high
     tl_i2c_clock_pulse( SET_DATA_HI, GPIOout );

     // read data line
     if ( tl_read_i2c_data( GPIOin) & 0x08 )
       data |= bit;
   }

   return (data);
 }
 //*****************************************************************************
 //*****************************************************************************
 // Function:   read_i2c_nvram
 // Arguments:  UCHAR count     number of bytes to read
 //             UCHAR *buf      area to store the bytes read
 // Returns:    0 - failed
 //             1 - success
 //*****************************************************************************
 //*****************************************************************************
 unsigned long cpqfcTS_ReadNVRAM( void* GPIOin, void* GPIOout , USHORT count,
 	UCHAR *buf )
 {
   unsigned short i;

   if( !( tl_i2c_tx_start(GPIOin, GPIOout) ))
     return FALSE;

   // Select the NVRAM for "dummy" write, to set the address
   tl_i2c_tx_byte( GPIOout , SLAVE_WRITE_ADDRESS );
   if ( !tl_i2c_rx_ack(GPIOin, GPIOout ) )
     return( FALSE );

   // Now send the address where we want to start reading
   tl_i2c_tx_byte( GPIOout , 0 );
   if ( !tl_i2c_rx_ack(GPIOin, GPIOout ) )
     return( FALSE );

   // Send a repeated start condition and select the
   //  slave for reading now.
   if( tl_i2c_tx_start(GPIOin, GPIOout) )
     tl_i2c_tx_byte( GPIOout, SLAVE_READ_ADDRESS );

   if ( !tl_i2c_rx_ack(GPIOin, GPIOout) )
     return( FALSE );

   // this loop will now read out the data and store it
   //  in the buffer pointed to by buf
   for ( i=0; i<count; i++)
   {
     *buf++ = tl_i2c_rx_byte(GPIOin, GPIOout);

     // Send ACK by holding data line low for 1 clock
     if ( i < (count-1) )
       tl_i2c_clock_pulse( 0x08, GPIOout );
     else {
 	// Don't send ack for final byte
       tl_i2c_clock_pulse( SET_DATA_HI, GPIOout );
     }
   }

   tl_i2c_tx_stop(GPIOin, GPIOout);

   return( TRUE );
 }

 //****************************************************************
 //
 //
 //
 // routines to set and clear the data and clock bits
 //
 //
 //
 //****************************************************************

 static void tl_set_clock(void* gpioreg)
 {
   ULONG ret_val;

   ret_val = readl( gpioreg );
   ret_val &= 0xffffffFBL;  // clear GPIO2 (SCL)
   writel( ret_val, gpioreg);
 }

 static void tl_clr_clock(void* gpioreg)
 {
   ULONG ret_val;

   ret_val = readl( gpioreg );
   ret_val |= SET_CLOCK_LO;
   writel( ret_val, gpioreg);
 }

 //*****************************************************************
 //
 //
 // This routine will advance the clock by one period
 //
 //
 //*****************************************************************
 static void tl_i2c_clock_pulse( UCHAR value, void* GPIOout  )
 {
   ULONG ret_val;

   // clear the clock bit
   tl_clr_clock( GPIOout );

   i2c_delay(0);


   // read the port to preserve non-I2C bits
   ret_val = readl( GPIOout );

   // clear the data & clock bits
   ret_val &= 0xFFFFFFf3;

   // write the value passed in...
   // data can only change while clock is LOW!
   ret_val |= value;           // the data
   ret_val |= SET_CLOCK_LO;    // the clock
   writel( ret_val, GPIOout );

   i2c_delay(0);


   //set clock bit
   tl_set_clock( GPIOout);
 }


 //*****************************************************************
 //
 //
 // This routine returns the 64-bit WWN
 //
 //
 //*****************************************************************
 int cpqfcTS_GetNVRAM_data( UCHAR *wwnbuf, UCHAR *buf )
 {
   ULONG len;
   ULONG sub_len;
   ULONG ptr_inc;
   ULONG i;
   ULONG j;
   UCHAR *data_ptr;
   UCHAR  z;
   UCHAR  name;
   UCHAR  sub_name;
   UCHAR  done;
   int iReturn=0;  // def. 0 offset is failure to find WWN field


   data_ptr = (UCHAR *)buf;

   done = FALSE;
   i = 0;

   while ( (i < 128) && (!done) )
   {
     z = data_ptr[i];\
     if ( !(z & 0x80) )
     {
       len  = 1 + (z & 0x07);

       name = (z & 0x78) >> 3;
       if (name == 0x0F)
         done = TRUE;
     }
     else
     {
       name = z & 0x7F;
       len  = 3 + data_ptr[i+1] + (data_ptr[i+2] << 8);

       switch (name)
       {
       case 0x0D:
 	//
 	  j = i + 3;
 	  //
 	  if ( data_ptr[j] == 0x3b ) {
 	    len = 6;
 	    break;
 	  }

 	  while ( j<(i+len) ) {
 	    sub_name = (data_ptr[j] & 0x3f);
 	    sub_len  = data_ptr[j+1] +
 	               (data_ptr[j+2] << 8);
             ptr_inc  = sub_len + 3;
 	    switch (sub_name)
 	    {
 	    case 0x3C:
               memcpy( wwnbuf, &data_ptr[j+3], 8);
               iReturn = j+3;
               break;
             default:
               break;
 	    }
 	    j += ptr_inc;
           }
 	  break;
         default:
 	  break;
       }
     }
   //
     i += len;
   }  // end while
   return iReturn;
 }


 // define a short 5 micro sec delay, and longer (ms) delay

 static void i2c_delay(ULONG mstime)
 {
   ULONG i;

 // NOTE: we only expect to use these delays when reading
 // our adapter's NVRAM, which happens only during adapter reset.
 // Delay technique from "Linux Device Drivers", A. Rubini
 // (1st Ed.) pg 137.

 //  printk(" delay %lx  ", mstime);
   if( mstime ) // ms delay?
   {
     // delay technique
     for( i=0; i < mstime; i++)
       udelay(1000); // 1ms per loop

   }
   else  // 5 micro sec delay

     udelay( 5 ); // micro secs

 //  printk("done\n");
 }
	/* Copyright(c) 2000, Compaq Computer Corporation
	* Fibre Channel Host Bus Adapter
	* 64-bit, 66MHz PCI
	* Originally developed and tested on:
	* (front): [chip] Tachyon TS HPFC-5166A/1.2 L2C1090 ...
	* SP# P225CXCBFIEL6T, Rev XC
	* SP# 161290-001, Rev XD
	* (back): Board No. 010008-001 A/W Rev X5, FAB REV X5
	*
	* 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, 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.
	* Written by Don Zimmerman
	*/
	// These functions control the NVRAM I2C hardware on
	// non-intelligent Fibre Host Adapters.
	// The primary purpose is to read the HBA's NVRAM to get adapter's
	// manufactured WWN to copy into Tachyon chip registers
	// Orignal source author unknown

	#include <linux/types.h>
	enum boolean { FALSE, TRUE } ;


	#ifndef UCHAR
	typedef __u8 UCHAR;
	#endif
	#ifndef BOOLEAN
	typedef __u8 BOOLEAN;
	#endif
	#ifndef USHORT
	typedef __u16 USHORT;
	#endif
	#ifndef ULONG
	typedef __u32 ULONG;
	#endif


	#include <linux/string.h>
	#include <linux/pci.h>
	#include <linux/delay.h>
	#include <linux/sched.h>
	#include <asm/io.h> // struct pt_regs for IRQ handler & Port I/O

	#include "cpqfcTSchip.h"

	static void tl_i2c_tx_byte( void* GPIOout, UCHAR data );
	/static BOOLEAN tl_write_i2c_page_portion( void GPIOin, void* GPIOout,
	USHORT startOffset, // e.g. 0x2f for WWN start
	USHORT count,
	UCHAR *buf );
	*/

	//
	// Tachlite GPIO2, GPIO3 (I2C) DEFINES
	// The NVRAM chip NM24C03 defines SCL (serial clock) and SDA (serial data)
	// GPIO2 drives SDA, and GPIO3 drives SCL
	//
	// Since Tachlite inverts the state of the GPIO 0-3 outputs, SET writes 0
	// and clear writes 1. The input lines (read in TL status) is NOT inverted
	// This really helps confuse the code and debugging.

	#define SET_DATA_HI 0x0
	#define SET_DATA_LO 0x8
	#define SET_CLOCK_HI 0x0
	#define SET_CLOCK_LO 0x4

	#define SENSE_DATA_HI 0x8
	#define SENSE_DATA_LO 0x0
	#define SENSE_CLOCK_HI 0x4
	#define SENSE_CLOCK_LO 0x0

	#define SLAVE_READ_ADDRESS 0xA1
	#define SLAVE_WRITE_ADDRESS 0xA0


	static void i2c_delay(ULONG mstime);
	static void tl_i2c_clock_pulse( UCHAR , void* GPIOout);
	static UCHAR tl_read_i2c_data( void* );


	//-----------------------------------------------------------------------------
	//
	// Name: I2C_RX_ACK
	//
	// This routine receives an acknowledge over the I2C bus.
	//
	//-----------------------------------------------------------------------------
	static unsigned short tl_i2c_rx_ack( void* GPIOin, void* GPIOout )
	{
	unsigned long value;

	// do clock pulse, let data line float high
	tl_i2c_clock_pulse( SET_DATA_HI, GPIOout );

	// slave must drive data low for acknowledge
	value = tl_read_i2c_data( GPIOin);
	if (value & SENSE_DATA_HI )
	return( FALSE );

	return( TRUE );
	}
	//-----------------------------------------------------------------------------
	//
	// Name: READ_I2C_REG
	//
	// This routine reads the I2C control register using the global
	// IO address stored in gpioreg.
	//
	//-----------------------------------------------------------------------------
	static UCHAR tl_read_i2c_data( void* gpioreg )
	{
	return( (UCHAR)(readl( gpioreg ) & 0x08L) ); // GPIO3
	}
	//-----------------------------------------------------------------------------
	//
	// Name: WRITE_I2C_REG
	//
	// This routine writes the I2C control register using the global
	// IO address stored in gpioreg.
	// In Tachlite, we don't want to modify other bits in TL Control reg.
	//
	//-----------------------------------------------------------------------------
	static void tl_write_i2c_reg( void* gpioregOUT, UCHAR value )
	{
	ULONG temp;

	// First read the register and clear out the old bits
	temp = readl( gpioregOUT ) & 0xfffffff3L;

	// Now or in the new data and send it back out
	writel( temp \| value, gpioregOUT);
	}
	//-----------------------------------------------------------------------------
	//
	// Name: I2C_TX_START
	//
	// This routine transmits a start condition over the I2C bus.
	// 1. Set SCL (clock, GPIO2) HIGH, set SDA (data, GPIO3) HIGH,
	// wait 5us to stabilize.
	// 2. With SCL still HIGH, drive SDA low. The low transition marks
	// the start condition to NM24Cxx (the chip)
	// NOTE! In TL control reg., output 1 means chip sees LOW
	//
	//-----------------------------------------------------------------------------
	static unsigned short tl_i2c_tx_start( void* GPIOin, void* GPIOout )
	{
	unsigned short i;
	ULONG value;

	if ( !(tl_read_i2c_data(GPIOin) & SENSE_DATA_HI))
	{
	// start with clock high, let data float high
	tl_write_i2c_reg( GPIOout, SET_DATA_HI \| SET_CLOCK_HI );

	// keep sending clock pulses if slave is driving data line
	for (i = 0; i < 10; i++)
	{
	tl_i2c_clock_pulse( SET_DATA_HI, GPIOout );

	if ( tl_read_i2c_data(GPIOin) & SENSE_DATA_HI )
	break;
	}

	// if he's still driving data low after 10 clocks, abort
	value = tl_read_i2c_data( GPIOin ); // read status
	if (!(value & 0x08) )
	return( FALSE );
	}


	// To START, bring data low while clock high
	tl_write_i2c_reg( GPIOout, SET_CLOCK_HI \| SET_DATA_LO );

	i2c_delay(0);

	return( TRUE ); // TX start successful
	}
	//-----------------------------------------------------------------------------
	//
	// Name: I2C_TX_STOP
	//
	// This routine transmits a stop condition over the I2C bus.
	//
	//-----------------------------------------------------------------------------

	static unsigned short tl_i2c_tx_stop( void* GPIOin, void* GPIOout )
	{
	int i;

	for (i = 0; i < 10; i++)
	{
	// Send clock pulse, drive data line low
	tl_i2c_clock_pulse( SET_DATA_LO, GPIOout );

	// To STOP, bring data high while clock high
	tl_write_i2c_reg( GPIOout, SET_DATA_HI \| SET_CLOCK_HI );

	// Give the data line time to float high
	i2c_delay(0);

	// If slave is driving data line low, there's a problem; retry
	if ( tl_read_i2c_data(GPIOin) & SENSE_DATA_HI )
	return( TRUE ); // TX STOP successful!
	}

	return( FALSE ); // error
	}
	//-----------------------------------------------------------------------------
	//
	// Name: I2C_TX_uchar
	//
	// This routine transmits a byte across the I2C bus.
	//
	//-----------------------------------------------------------------------------
	static void tl_i2c_tx_byte( void* GPIOout, UCHAR data )
	{
	UCHAR bit;

	for (bit = 0x80; bit; bit >>= 1)
	{
	if( data & bit )
	tl_i2c_clock_pulse( (UCHAR)SET_DATA_HI, GPIOout);
	else
	tl_i2c_clock_pulse( (UCHAR)SET_DATA_LO, GPIOout);
	}
	}
	//-----------------------------------------------------------------------------
	//
	// Name: I2C_RX_uchar
	//
	// This routine receives a byte across the I2C bus.
	//
	//-----------------------------------------------------------------------------
	static UCHAR tl_i2c_rx_byte( void* GPIOin, void* GPIOout )
	{
	UCHAR bit;
	UCHAR data = 0;


	for (bit = 0x80; bit; bit >>= 1) {
	// do clock pulse, let data line float high
	tl_i2c_clock_pulse( SET_DATA_HI, GPIOout );

	// read data line
	if ( tl_read_i2c_data( GPIOin) & 0x08 )
	data \|= bit;
	}

	return (data);
	}
	//*****************************************************************************
	//*****************************************************************************
	// Function: read_i2c_nvram
	// Arguments: UCHAR count number of bytes to read
	// UCHAR *buf area to store the bytes read
	// Returns: 0 - failed
	// 1 - success
	//*****************************************************************************
	//*****************************************************************************
	unsigned long cpqfcTS_ReadNVRAM( void* GPIOin, void* GPIOout , USHORT count,
	UCHAR *buf )
	{
	unsigned short i;

	if( !( tl_i2c_tx_start(GPIOin, GPIOout) ))
	return FALSE;

	// Select the NVRAM for "dummy" write, to set the address
	tl_i2c_tx_byte( GPIOout , SLAVE_WRITE_ADDRESS );
	if ( !tl_i2c_rx_ack(GPIOin, GPIOout ) )
	return( FALSE );

	// Now send the address where we want to start reading
	tl_i2c_tx_byte( GPIOout , 0 );
	if ( !tl_i2c_rx_ack(GPIOin, GPIOout ) )
	return( FALSE );

	// Send a repeated start condition and select the
	// slave for reading now.
	if( tl_i2c_tx_start(GPIOin, GPIOout) )
	tl_i2c_tx_byte( GPIOout, SLAVE_READ_ADDRESS );

	if ( !tl_i2c_rx_ack(GPIOin, GPIOout) )
	return( FALSE );

	// this loop will now read out the data and store it
	// in the buffer pointed to by buf
	for ( i=0; i<count; i++)
	{
	*buf++ = tl_i2c_rx_byte(GPIOin, GPIOout);

	// Send ACK by holding data line low for 1 clock
	if ( i < (count-1) )
	tl_i2c_clock_pulse( 0x08, GPIOout );
	else {
	// Don't send ack for final byte
	tl_i2c_clock_pulse( SET_DATA_HI, GPIOout );
	}
	}

	tl_i2c_tx_stop(GPIOin, GPIOout);

	return( TRUE );
	}

	//****************************************************************
	//
	//
	//
	// routines to set and clear the data and clock bits
	//
	//
	//
	//****************************************************************

	static void tl_set_clock(void* gpioreg)
	{
	ULONG ret_val;

	ret_val = readl( gpioreg );
	ret_val &= 0xffffffFBL; // clear GPIO2 (SCL)
	writel( ret_val, gpioreg);
	}

	static void tl_clr_clock(void* gpioreg)
	{
	ULONG ret_val;

	ret_val = readl( gpioreg );
	ret_val \|= SET_CLOCK_LO;
	writel( ret_val, gpioreg);
	}

	//*****************************************************************
	//
	//
	// This routine will advance the clock by one period
	//
	//
	//*****************************************************************
	static void tl_i2c_clock_pulse( UCHAR value, void* GPIOout )
	{
	ULONG ret_val;

	// clear the clock bit
	tl_clr_clock( GPIOout );

	i2c_delay(0);


	// read the port to preserve non-I2C bits
	ret_val = readl( GPIOout );

	// clear the data & clock bits
	ret_val &= 0xFFFFFFf3;

	// write the value passed in...
	// data can only change while clock is LOW!
	ret_val \|= value; // the data
	ret_val \|= SET_CLOCK_LO; // the clock
	writel( ret_val, GPIOout );

	i2c_delay(0);


	//set clock bit
	tl_set_clock( GPIOout);
	}




	//*****************************************************************
	//
	//
	// This routine returns the 64-bit WWN
	//
	//
	//*****************************************************************
	int cpqfcTS_GetNVRAM_data( UCHAR wwnbuf, UCHAR buf )
	{
	ULONG len;
	ULONG sub_len;
	ULONG ptr_inc;
	ULONG i;
	ULONG j;
	UCHAR *data_ptr;
	UCHAR z;
	UCHAR name;
	UCHAR sub_name;
	UCHAR done;
	int iReturn=0; // def. 0 offset is failure to find WWN field



	data_ptr = (UCHAR *)buf;

	done = FALSE;
	i = 0;

	while ( (i < 128) && (!done) )
	{
	z = data_ptr[i];\
	if ( !(z & 0x80) )
	{
	len = 1 + (z & 0x07);

	name = (z & 0x78) >> 3;
	if (name == 0x0F)
	done = TRUE;
	}
	else
	{
	name = z & 0x7F;
	len = 3 + data_ptr[i+1] + (data_ptr[i+2] << 8);

	switch (name)
	{
	case 0x0D:
	//
	j = i + 3;
	//
	if ( data_ptr[j] == 0x3b ) {
	len = 6;
	break;
	}

	while ( j<(i+len) ) {
	sub_name = (data_ptr[j] & 0x3f);
	sub_len = data_ptr[j+1] +
	(data_ptr[j+2] << 8);
	ptr_inc = sub_len + 3;
	switch (sub_name)
	{
	case 0x3C:
	memcpy( wwnbuf, &data_ptr[j+3], 8);
	iReturn = j+3;
	break;
	default:
	break;
	}
	j += ptr_inc;
	}
	break;
	default:
	break;
	}
	}
	//
	i += len;
	} // end while
	return iReturn;
	}





	// define a short 5 micro sec delay, and longer (ms) delay

	static void i2c_delay(ULONG mstime)
	{
	ULONG i;

	// NOTE: we only expect to use these delays when reading
	// our adapter's NVRAM, which happens only during adapter reset.
	// Delay technique from "Linux Device Drivers", A. Rubini
	// (1st Ed.) pg 137.

	// printk(" delay %lx ", mstime);
	if( mstime ) // ms delay?
	{
	// delay technique
	for( i=0; i < mstime; i++)
	udelay(1000); // 1ms per loop

	}
	else // 5 micro sec delay

	udelay( 5 ); // micro secs

	// printk("done\n");
	}