sysend.c.bak

INTEL IXP425的VXWORKS BSP

*
* sys557IntAck - acknowledge an 82557 interrupt
*
* This routine performs any 82557 interrupt acknowledge that may be
* required.  This typically involves an operation to some interrupt
* control hardware.
*
* This routine gets called from the 82557 driver's interrupt handler.
*
* This routine assumes that the PCI configuration information has already
* been setup.
*
* RETURNS: OK, or ERROR if the interrupt could not be acknowledged.
*/

LOCAL STATUS sys557IntAck
    (
    int	unit		/* unit number */
    )
{
    FEI_RESOURCE * pReso = &feiResources [unit];

    switch (pReso->boardType)
	{
	case PRO100B:		/* handle PRO100B LAN Adapter */
        case INBUSINESS:
        case XX82559ER:
	    /* no addition work necessary for the PRO100B */
	    break;

	default:
	    return (ERROR);
	}

    return (OK);
    }

/*******************************************************************************
*
* sys557IntEnable - enable 82557 interrupts
*
* This routine enables 82557 interrupts.  This may involve operations on
* interrupt control hardware.
*
* The 82557 driver calls this routine throughout normal operation to terminate
* critical sections of code.
*
* This routine assumes that the PCI configuration information has already
* been setup.
*
* RETURNS: OK, or ERROR if interrupts could not be enabled.
*/

LOCAL STATUS sys557IntEnable
    (
    int	unit		/* unit number */
    )
{
    FEI_RESOURCE * pReso = &feiResources [unit];

    switch (pReso->boardType)
	{
	case PRO100B:		/* handle PRO100B LAN Adapter */
        case INBUSINESS:
        case XX82559ER:
            intEnable (pReso->irq);
	    break;

	default:
	    return (ERROR);
	}

    return (OK);
    }

/*******************************************************************************
*
* sys557IntDisable - disable 82557 interrupts
*
* This routine disables 82557 interrupts.  This may involve operations on
* interrupt control hardware.
*
* The 82557 driver calls this routine throughout normal operation to enter
* critical sections of code.
*
* This routine assumes that the PCI configuration information has already
* been setup.
*
* RETURNS: OK, or ERROR if interrupts could not be disabled.
*/

LOCAL STATUS sys557IntDisable
    (
    int	unit		/* unit number */
    )
{
    FEI_RESOURCE * pReso = &feiResources [unit];

    switch (pReso->boardType)
	{
	case PRO100B:		/* handle PRO100B LAN Adapter */
        case INBUSINESS:
        case XX82559ER:
            intDisable (pReso->irq); 
	    break;

	default:
	    return (ERROR);
	}

    return (OK);
    }

/*******************************************************************************
*
* sys557eepromRead - read a word from the 82557 EEPROM
*
* RETURNS: the EEPROM data word read in.
*/

LOCAL UINT16 sys557eepromRead
    (
    int	unit,		/* unit number */
    int	location	/* address of word to be read */
    )
{
    UINT32 iobase = feiResources[unit].iobaseCsr;
    UINT16 retval = 0;
    UINT16 dataval;

    UINT32 eeaddr = iobase + SCB_EEPROM;
    int cmdlen = 27;
    int readcmd = EE_CMD_READ << 22;

    readcmd = readcmd | (location << 16);

    /*Enable EEPROM*/
    sysPciOutWord(eeaddr, EE_ENB | EE_SK);
    
    do
    {
	dataval = (readcmd & (1 << cmdlen)) ?  EE_WRITE_1 : EE_WRITE_0;
	sysPciOutWord(eeaddr, dataval);	
	sysDelay();
	sysPciOutWord(eeaddr, dataval | EE_SK);
	sysDelay();
	dataval=sysInWord(eeaddr);
	retval = (retval << 1) | ((dataval & EE_DO) ? 1 : 0);
 
    } while(cmdlen-- > 0);

    sysPciOutWord(eeaddr, EE_ENB);

    sysPciOutWord(eeaddr, EE_ENB & ~EE_CS);
    return retval;

    

#if 0
    sysPciOutWord (iobase + SCB_EEPROM, EE_CS);	/* enable EEPROM */

    /* write the READ opcode */

    for (ix = EE_CMD_BITS - 1; ix >= 0; ix--)
	{
        dataval = (EE_CMD_READ & (1 << ix)) ? EE_DI : 0;
        sysPciOutWord (iobase + SCB_EEPROM, EE_CS | dataval);
        sysDelay ();	/* delay for one I/O READ cycle */
        sysPciOutWord (iobase + SCB_EEPROM, EE_CS | dataval | EE_SK);
        sysDelay ();	/* delay for one I/O READ cycle */
        sysPciOutWord (iobase + SCB_EEPROM, EE_CS | dataval);
        sysDelay ();	/* delay for one I/O READ cycle */
        }

    /* write the location */

    for (ix = EE_ADDR_BITS - 1; ix >= 0; ix--)
	{
        dataval = (location & (1 << ix)) ? EE_DI : 0;
        sysPciOutWord (iobase + SCB_EEPROM, EE_CS | dataval);
        sysDelay ();	/* delay for one I/O READ cycle */
        sysPciOutWord (iobase + SCB_EEPROM, EE_CS | dataval | EE_SK);
        sysDelay ();	/* delay for one I/O READ cycle */
        sysPciOutWord (iobase + SCB_EEPROM, EE_CS | dataval);
        sysDelay ();	/* delay for one I/O READ cycle */
	dummy = sysInWord (iobase + SCB_EEPROM);
        }

    if ((dummy & EE_DO) == 0)		/* dummy read */
	;

    /* read the data */

    for (ix = EE_DATA_BITS - 1; ix >= 0; ix--)
	{
        sysPciOutWord (iobase + SCB_EEPROM, EE_CS | EE_SK);
        sysDelay ();	/* delay for one I/O READ cycle */
        retval = (retval << 1) |
	         ((sysInWord (iobase + SCB_EEPROM) & EE_DO) ? 1 : 0);
        sysPciOutWord (iobase + SCB_EEPROM, EE_CS);
        sysDelay ();	/* delay for one I/O READ cycle */
        }

    sysPciOutWord (iobase + SCB_EEPROM, 0x00);	/* disable EEPROM */

    return (retval);
#endif
    }

/*******************************************************************************
*
* sys557mdioRead - read MDIO
*
* RETURNS: read value
*/

LOCAL UINT32 sys557mdioRead
    (
    int	unit,		/* unit number */
    int phyId,		/* PHY ID */
    int location	/* location to read */
    )
{
    UINT32 iobase = feiResources[unit].iobaseCsr;
    int timeout   = 64*4;	/* <64 usec. to complete, typ 27 ticks */
    int val;

    sysPciOutLong (iobase + SCB_MDI, 0x08000000 | (location<<16) | (phyId<<21));
    do  {
        sysDelay ();	/* delay for one I/O READ cycle */
        val = sysInLong (iobase + SCB_MDI);
        if (--timeout < 0)
            printf ("sys557mdioRead() timed out with val = %8.8x.\n", val);
        } while (! (val & 0x10000000));

    return (val & 0xffff);
    }

/*******************************************************************************
*
* sys557mdioWrite - write MDIO
*
* RETURNS: write value
*/

LOCAL UINT32 sys557mdioWrite
    (
    int unit,		/* unit number */
    int phyId,		/* PHY ID */
    int location,	/* location to write */
    int value		/* value to write */
    )
{
    UINT32 iobase = feiResources[unit].iobaseCsr;
    int timeout   = 64*4;	/* <64 usec. to complete, typ 27 ticks */
    int val;

    sysPciOutLong (iobase + SCB_MDI,
		0x04000000 | (location<<16) | (phyId<<21) | value);
    do  {
        sysDelay ();	/* delay for one I/O READ cycle */
        val = sysInLong (iobase + SCB_MDI);
        if (--timeout < 0)
            printf ("sys557mdioWrite() timed out with val = %8.8x.\n", val);
        } while (! (val & 0x10000000));

    return (val & 0xffff);
    }

/*******************************************************************************
*
* sys557Show - shows 82557 configuration
*
* This routine shows the (Intel Pro Express 100) configuration
*
* RETURNS: N/A
*/

void sys557Show
    (
    int	unit		/* unit number */
    )
{
    FEI_RESOURCE * pReso = &feiResources [unit];
    UINT32 iobase       = pReso->iobaseCsr;
    UCHAR etheraddr[6];
    int ix;
    int iy;

    if (unit > IXP425_PCI_MAX_DEV)
	{
	printf ("Illegal unit number %d\n", unit);
	return;
	}

    if (pReso->boardType == UNKNOWN)
	{
	printf ("Unit %d not an FEI device\n", unit);
	return;
	}

    for (ix = 0, iy = 0; ix < 3; ix++)
	{
        etheraddr[iy++] = pReso->eeprom[ix];
        etheraddr[iy++] = pReso->eeprom[ix] >> 8;
        }
    printf ("fei%d: Intel EtherExpress Pro 10/100 at %#8x ", unit, iobase);
    for (ix = 0; ix < 5; ix++)
    	printf ("%2.2X:", etheraddr[ix]);
    printf ("%2.2X\n", etheraddr[ix]);

    printf ("CSR mem base address = %x, Flash mem base address = %x\n",
	    pReso->membaseCsr, pReso->membaseFlash);

    if (pReso->eeprom[3] & 0x03)
        printf ("Receiver lock-up bug exists -- enabling work-around.\n");

    printf ("Board assembly %4.4x%2.2x-%3.3d, Physical connectors present:",
	pReso->eeprom[8], pReso->eeprom[9]>>8, pReso->eeprom[9] & 0xff);
    for (ix = 0; ix < 4; ix++)
	if (pReso->eeprom[5] & (1 << ix))
	    printf ("%s", connectors [ix]);

    printf ("\nPrimary interface chip %s PHY #%d.\n",
	phys[(pReso->eeprom[6]>>8)&15], pReso->eeprom[6] & 0x1f);
    if (pReso->eeprom[7] & 0x0700)
	printf ("Secondary interface chip %s.\n",
		phys[(pReso->eeprom[7]>>8)&7]);

#if	FALSE  /* we don't show PHY specific info at this time */
    /* ToDo: Read and set PHY registers through MDIO port. */
    for (ix = 0; ix < 2; ix++)
	printf ("MDIO register %d is %4.4x.\n",
		ix, sys557mdioRead (unit, pReso->eeprom[6] & 0x1f, ix));
    for (ix = 5; ix < 7; ix++)
	printf ("MDIO register %d is %4.4x.\n",
		ix, sys557mdioRead (unit, pReso->eeprom[6] & 0x1f, ix));
    printf ("MDIO register %d is %4.4x.\n",
	    25, sys557mdioRead (unit, pReso->eeprom[6] & 0x1f, 25));
#endif	/* FALSE */

    if (pReso->timeout < 0)
        {		/* Test optimized out. */
	printf ("Self test failed, status %8.8x:\n"
	        " Failure to initialize the 82557.\n"
	        " Verify that the card is a bus-master capable slot.\n",
	        pReso->pResults[1]);
	}
    else
        {
	printf ("General self-test: %s.\n"
	        " Serial sub-system self-test: %s.\n"
	        " Internal registers self-test: %s.\n"
	        " ROM checksum self-test: %s (%#8.8x).\n",
	        pReso->pResults[1] & 0x1000 ? "failed" : "passed",
	        pReso->pResults[1] & 0x0020 ? "failed" : "passed",
	        pReso->pResults[1] & 0x0008 ? "failed" : "passed",
	        pReso->pResults[1] & 0x0004 ? "failed" : "passed",
	        pReso->pResults[0]);
        }
    }

#endif /* INCLUDE_FEI82557END */

/*******************************************************************************
*
* sysDelay - a small delay
*
*/

void sysDelay (void)
    {

    sysMicroDelay(PCI_CONFIG_DELAY); 

    return;
    }

/******************************************************************************
*
* sys557EndPciToPhys - translate a Pci address to a physical address
*
* This function converts a Pci address to a physical address. This only works
* for PCI Memory space.
*
* RETURNS: the physical adddress
*/

UINT32 sys557EndPciToPhys
    (
    int		unit,
    UINT32      PciAddr /* PCI address */
    )
    {
    return((UINT32)sysPciToPhys((void *)PciAddr));
    }

/******************************************************************************
*
* sys557EndPhysToPci - translate a physical address to a Pci address
*
* This function converts a physical address to a Pci address. This only works
* for PCI Memory space.
*
* RETURNS: the Pci adddress
*/

UINT32 sys557EndPhysToPci
    (
    int		unit,
    UINT32      PhysAddr        /* Physical address */
    )
    {
    return ((UINT32)sysPhysToPci((void *)PhysAddr));
    }



#endif /* INCLUDE_END */