Contributors: 25
Author Tokens Token Proportion Commits Commit Proportion
Justin T. Gibbs 3080 77.17% 11 18.97%
Linus Torvalds 562 14.08% 3 5.17%
Linus Torvalds (pre-git) 100 2.51% 19 32.76%
Hannes Reinecke 89 2.23% 4 6.90%
James Bottomley 57 1.43% 1 1.72%
Pekka J Enberg 26 0.65% 1 1.72%
Arjan van de Ven 17 0.43% 1 1.72%
Mark Salyzyn 11 0.28% 1 1.72%
Adrian Bunk 8 0.20% 1 1.72%
Andrew Morton 6 0.15% 1 1.72%
Denys Vlasenko 4 0.10% 1 1.72%
Alan Cox 4 0.10% 1 1.72%
Mathias Krause 4 0.10% 1 1.72%
Steven Cole 3 0.08% 1 1.72%
Tom Rix 3 0.08% 1 1.72%
Luben Tuikov 3 0.08% 1 1.72%
Christoph Hellwig 3 0.08% 1 1.72%
Olaf Hering 2 0.05% 1 1.72%
Vaibhav Gupta 2 0.05% 1 1.72%
Joe Perches 2 0.05% 1 1.72%
Tobias Klauser 1 0.03% 1 1.72%
Michael Opdenacker 1 0.03% 1 1.72%
Mariusz Kozlowski 1 0.03% 1 1.72%
Randy Dunlap 1 0.03% 1 1.72%
Harvey Harrison 1 0.03% 1 1.72%
Total 3991 58


/*
 * Product specific probe and attach routines for:
 *	aic7901 and aic7902 SCSI controllers
 *
 * Copyright (c) 1994-2001 Justin T. Gibbs.
 * Copyright (c) 2000-2002 Adaptec Inc.
 * All rights reserved.
 *
 * Redistribution and use in source and binary forms, with or without
 * modification, are permitted provided that the following conditions
 * are met:
 * 1. Redistributions of source code must retain the above copyright
 *    notice, this list of conditions, and the following disclaimer,
 *    without modification.
 * 2. Redistributions in binary form must reproduce at minimum a disclaimer
 *    substantially similar to the "NO WARRANTY" disclaimer below
 *    ("Disclaimer") and any redistribution must be conditioned upon
 *    including a substantially similar Disclaimer requirement for further
 *    binary redistribution.
 * 3. Neither the names of the above-listed copyright holders nor the names
 *    of any contributors may be used to endorse or promote products derived
 *    from this software without specific prior written permission.
 *
 * Alternatively, this software may be distributed under the terms of the
 * GNU General Public License ("GPL") version 2 as published by the Free
 * Software Foundation.
 *
 * NO WARRANTY
 * THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS
 * "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT
 * LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTIBILITY AND FITNESS FOR
 * A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT
 * HOLDERS OR CONTRIBUTORS BE LIABLE FOR SPECIAL, EXEMPLARY, OR CONSEQUENTIAL
 * DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS
 * OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION)
 * HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT,
 * STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING
 * IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE
 * POSSIBILITY OF SUCH DAMAGES.
 *
 * $Id: //depot/aic7xxx/aic7xxx/aic79xx_pci.c#92 $
 */

#include "aic79xx_osm.h"
#include "aic79xx_inline.h"
#include "aic79xx_pci.h"

static inline uint64_t
ahd_compose_id(u_int device, u_int vendor, u_int subdevice, u_int subvendor)
{
	uint64_t id;

	id = subvendor
	   | (subdevice << 16)
	   | ((uint64_t)vendor << 32)
	   | ((uint64_t)device << 48);

	return (id);
}

#define ID_AIC7902_PCI_REV_A4		0x3
#define ID_AIC7902_PCI_REV_B0		0x10
#define SUBID_HP			0x0E11

#define DEVID_9005_HOSTRAID(id) ((id) & 0x80)

#define DEVID_9005_TYPE(id) ((id) & 0xF)
#define		DEVID_9005_TYPE_HBA		0x0	/* Standard Card */
#define		DEVID_9005_TYPE_HBA_2EXT	0x1	/* 2 External Ports */
#define		DEVID_9005_TYPE_IROC		0x8	/* Raid(0,1,10) Card */
#define		DEVID_9005_TYPE_MB		0xF	/* On Motherboard */

#define DEVID_9005_MFUNC(id) ((id) & 0x10)

#define DEVID_9005_PACKETIZED(id) ((id) & 0x8000)

#define SUBID_9005_TYPE(id) ((id) & 0xF)
#define		SUBID_9005_TYPE_HBA		0x0	/* Standard Card */
#define		SUBID_9005_TYPE_MB		0xF	/* On Motherboard */

#define SUBID_9005_AUTOTERM(id)	(((id) & 0x10) == 0)

#define SUBID_9005_LEGACYCONN_FUNC(id) ((id) & 0x20)

#define SUBID_9005_SEEPTYPE(id) (((id) & 0x0C0) >> 6)
#define		SUBID_9005_SEEPTYPE_NONE	0x0
#define		SUBID_9005_SEEPTYPE_4K		0x1

static ahd_device_setup_t ahd_aic7901_setup;
static ahd_device_setup_t ahd_aic7901A_setup;
static ahd_device_setup_t ahd_aic7902_setup;
static ahd_device_setup_t ahd_aic790X_setup;

static const struct ahd_pci_identity ahd_pci_ident_table[] =
{
	/* aic7901 based controllers */
	{
		ID_AHA_29320A,
		ID_ALL_MASK,
		"Adaptec 29320A Ultra320 SCSI adapter",
		ahd_aic7901_setup
	},
	{
		ID_AHA_29320ALP,
		ID_ALL_MASK,
		"Adaptec 29320ALP PCIx Ultra320 SCSI adapter",
		ahd_aic7901_setup
	},
	{
		ID_AHA_29320LPE,
		ID_ALL_MASK,
		"Adaptec 29320LPE PCIe Ultra320 SCSI adapter",
		ahd_aic7901_setup
	},
	/* aic7901A based controllers */
	{
		ID_AHA_29320LP,
		ID_ALL_MASK,
		"Adaptec 29320LP Ultra320 SCSI adapter",
		ahd_aic7901A_setup
	},
	/* aic7902 based controllers */	
	{
		ID_AHA_29320,
		ID_ALL_MASK,
		"Adaptec 29320 Ultra320 SCSI adapter",
		ahd_aic7902_setup
	},
	{
		ID_AHA_29320B,
		ID_ALL_MASK,
		"Adaptec 29320B Ultra320 SCSI adapter",
		ahd_aic7902_setup
	},
	{
		ID_AHA_39320,
		ID_ALL_MASK,
		"Adaptec 39320 Ultra320 SCSI adapter",
		ahd_aic7902_setup
	},
	{
		ID_AHA_39320_B,
		ID_ALL_MASK,
		"Adaptec 39320 Ultra320 SCSI adapter",
		ahd_aic7902_setup
	},
	{
		ID_AHA_39320_B_DELL,
		ID_ALL_MASK,
		"Adaptec (Dell OEM) 39320 Ultra320 SCSI adapter",
		ahd_aic7902_setup
	},
	{
		ID_AHA_39320A,
		ID_ALL_MASK,
		"Adaptec 39320A Ultra320 SCSI adapter",
		ahd_aic7902_setup
	},
	{
		ID_AHA_39320D,
		ID_ALL_MASK,
		"Adaptec 39320D Ultra320 SCSI adapter",
		ahd_aic7902_setup
	},
	{
		ID_AHA_39320D_HP,
		ID_ALL_MASK,
		"Adaptec (HP OEM) 39320D Ultra320 SCSI adapter",
		ahd_aic7902_setup
	},
	{
		ID_AHA_39320D_B,
		ID_ALL_MASK,
		"Adaptec 39320D Ultra320 SCSI adapter",
		ahd_aic7902_setup
	},
	{
		ID_AHA_39320D_B_HP,
		ID_ALL_MASK,
		"Adaptec (HP OEM) 39320D Ultra320 SCSI adapter",
		ahd_aic7902_setup
	},
	/* Generic chip probes for devices we don't know 'exactly' */
	{
		ID_AIC7901 & ID_9005_GENERIC_MASK,
		ID_9005_GENERIC_MASK,
		"Adaptec AIC7901 Ultra320 SCSI adapter",
		ahd_aic7901_setup
	},
	{
		ID_AIC7901A & ID_DEV_VENDOR_MASK,
		ID_DEV_VENDOR_MASK,
		"Adaptec AIC7901A Ultra320 SCSI adapter",
		ahd_aic7901A_setup
	},
	{
		ID_AIC7902 & ID_9005_GENERIC_MASK,
		ID_9005_GENERIC_MASK,
		"Adaptec AIC7902 Ultra320 SCSI adapter",
		ahd_aic7902_setup
	}
};

static const u_int ahd_num_pci_devs = ARRAY_SIZE(ahd_pci_ident_table);
		
#define	DEVCONFIG		0x40
#define		PCIXINITPAT	0x0000E000ul
#define			PCIXINIT_PCI33_66	0x0000E000ul
#define			PCIXINIT_PCIX50_66	0x0000C000ul
#define			PCIXINIT_PCIX66_100	0x0000A000ul
#define			PCIXINIT_PCIX100_133	0x00008000ul
#define	PCI_BUS_MODES_INDEX(devconfig)	\
	(((devconfig) & PCIXINITPAT) >> 13)
static const char *pci_bus_modes[] =
{
	"PCI bus mode unknown",
	"PCI bus mode unknown",
	"PCI bus mode unknown",
	"PCI bus mode unknown",
	"PCI-X 101-133MHz",
	"PCI-X 67-100MHz",
	"PCI-X 50-66MHz",
	"PCI 33 or 66MHz"
};

#define		TESTMODE	0x00000800ul
#define		IRDY_RST	0x00000200ul
#define		FRAME_RST	0x00000100ul
#define		PCI64BIT	0x00000080ul
#define		MRDCEN		0x00000040ul
#define		ENDIANSEL	0x00000020ul
#define		MIXQWENDIANEN	0x00000008ul
#define		DACEN		0x00000004ul
#define		STPWLEVEL	0x00000002ul
#define		QWENDIANSEL	0x00000001ul

#define	DEVCONFIG1		0x44
#define		PREQDIS		0x01

#define	CSIZE_LATTIME		0x0c
#define		CACHESIZE	0x000000fful
#define		LATTIME		0x0000ff00ul

static int	ahd_check_extport(struct ahd_softc *ahd);
static void	ahd_configure_termination(struct ahd_softc *ahd,
					  u_int adapter_control);
static void	ahd_pci_split_intr(struct ahd_softc *ahd, u_int intstat);
static void	ahd_pci_intr(struct ahd_softc *ahd);

const struct ahd_pci_identity *
ahd_find_pci_device(ahd_dev_softc_t pci)
{
	uint64_t  full_id;
	uint16_t  device;
	uint16_t  vendor;
	uint16_t  subdevice;
	uint16_t  subvendor;
	const struct ahd_pci_identity *entry;
	u_int	  i;

	vendor = ahd_pci_read_config(pci, PCIR_DEVVENDOR, /*bytes*/2);
	device = ahd_pci_read_config(pci, PCIR_DEVICE, /*bytes*/2);
	subvendor = ahd_pci_read_config(pci, PCI_SUBSYSTEM_VENDOR_ID, /*bytes*/2);
	subdevice = ahd_pci_read_config(pci, PCI_SUBSYSTEM_ID, /*bytes*/2);
	full_id = ahd_compose_id(device,
				 vendor,
				 subdevice,
				 subvendor);

	/*
	 * Controllers, mask out the IROC/HostRAID bit
	 */
	
	full_id &= ID_ALL_IROC_MASK;

	for (i = 0; i < ahd_num_pci_devs; i++) {
		entry = &ahd_pci_ident_table[i];
		if (entry->full_id == (full_id & entry->id_mask)) {
			/* Honor exclusion entries. */
			if (entry->name == NULL)
				return (NULL);
			return (entry);
		}
	}
	return (NULL);
}

int
ahd_pci_config(struct ahd_softc *ahd, const struct ahd_pci_identity *entry)
{
	u_int		 command;
	uint32_t	 devconfig;
	uint16_t	 subvendor; 
	int		 error;

	ahd->description = entry->name;
	/*
	 * Record if this is an HP board.
	 */
	subvendor = ahd_pci_read_config(ahd->dev_softc,
					PCI_SUBSYSTEM_VENDOR_ID, /*bytes*/2);
	if (subvendor == SUBID_HP)
		ahd->flags |= AHD_HP_BOARD;

	error = entry->setup(ahd);
	if (error != 0)
		return (error);
	
	devconfig = ahd_pci_read_config(ahd->dev_softc, DEVCONFIG, /*bytes*/4);
	if ((devconfig & PCIXINITPAT) == PCIXINIT_PCI33_66) {
		ahd->chip |= AHD_PCI;
		/* Disable PCIX workarounds when running in PCI mode. */
		ahd->bugs &= ~AHD_PCIX_BUG_MASK;
	} else {
		ahd->chip |= AHD_PCIX;
	}
	ahd->bus_description = pci_bus_modes[PCI_BUS_MODES_INDEX(devconfig)];

	ahd_power_state_change(ahd, AHD_POWER_STATE_D0);

	error = ahd_pci_map_registers(ahd);
	if (error != 0)
		return (error);

	/*
	 * If we need to support high memory, enable dual
	 * address cycles.  This bit must be set to enable
	 * high address bit generation even if we are on a
	 * 64bit bus (PCI64BIT set in devconfig).
	 */
	if ((ahd->flags & (AHD_39BIT_ADDRESSING|AHD_64BIT_ADDRESSING)) != 0) {
		if (bootverbose)
			printk("%s: Enabling 39Bit Addressing\n",
			       ahd_name(ahd));
		devconfig = ahd_pci_read_config(ahd->dev_softc,
						DEVCONFIG, /*bytes*/4);
		devconfig |= DACEN;
		ahd_pci_write_config(ahd->dev_softc, DEVCONFIG,
				     devconfig, /*bytes*/4);
	}
	
	/* Ensure busmastering is enabled */
	command = ahd_pci_read_config(ahd->dev_softc, PCIR_COMMAND, /*bytes*/2);
	command |= PCIM_CMD_BUSMASTEREN;
	ahd_pci_write_config(ahd->dev_softc, PCIR_COMMAND, command, /*bytes*/2);

	error = ahd_softc_init(ahd);
	if (error != 0)
		return (error);

	ahd->bus_intr = ahd_pci_intr;

	error = ahd_reset(ahd, /*reinit*/FALSE);
	if (error != 0)
		return (ENXIO);

	ahd->pci_cachesize =
	    ahd_pci_read_config(ahd->dev_softc, CSIZE_LATTIME,
				/*bytes*/1) & CACHESIZE;
	ahd->pci_cachesize *= 4;

	ahd_set_modes(ahd, AHD_MODE_SCSI, AHD_MODE_SCSI);
	/* See if we have a SEEPROM and perform auto-term */
	error = ahd_check_extport(ahd);
	if (error != 0)
		return (error);

	/* Core initialization */
	error = ahd_init(ahd);
	if (error != 0)
		return (error);
	ahd->init_level++;

	/*
	 * Allow interrupts now that we are completely setup.
	 */
	return ahd_pci_map_int(ahd);
}

void __maybe_unused
ahd_pci_suspend(struct ahd_softc *ahd)
{
	/*
	 * Save chip register configuration data for chip resets
	 * that occur during runtime and resume events.
	 */
	ahd->suspend_state.pci_state.devconfig =
	    ahd_pci_read_config(ahd->dev_softc, DEVCONFIG, /*bytes*/4);
	ahd->suspend_state.pci_state.command =
	    ahd_pci_read_config(ahd->dev_softc, PCIR_COMMAND, /*bytes*/1);
	ahd->suspend_state.pci_state.csize_lattime =
	    ahd_pci_read_config(ahd->dev_softc, CSIZE_LATTIME, /*bytes*/1);

}

void __maybe_unused
ahd_pci_resume(struct ahd_softc *ahd)
{
	ahd_pci_write_config(ahd->dev_softc, DEVCONFIG,
			     ahd->suspend_state.pci_state.devconfig, /*bytes*/4);
	ahd_pci_write_config(ahd->dev_softc, PCIR_COMMAND,
			     ahd->suspend_state.pci_state.command, /*bytes*/1);
	ahd_pci_write_config(ahd->dev_softc, CSIZE_LATTIME,
			     ahd->suspend_state.pci_state.csize_lattime, /*bytes*/1);
}

/*
 * Perform some simple tests that should catch situations where
 * our registers are invalidly mapped.
 */
int
ahd_pci_test_register_access(struct ahd_softc *ahd)
{
	uint32_t cmd;
	u_int	 targpcistat;
	u_int	 pci_status1;
	int	 error;
	uint8_t	 hcntrl;

	error = EIO;

	/*
	 * Enable PCI error interrupt status, but suppress NMIs
	 * generated by SERR raised due to target aborts.
	 */
	cmd = ahd_pci_read_config(ahd->dev_softc, PCIR_COMMAND, /*bytes*/2);
	ahd_pci_write_config(ahd->dev_softc, PCIR_COMMAND,
			     cmd & ~PCIM_CMD_SERRESPEN, /*bytes*/2);

	/*
	 * First a simple test to see if any
	 * registers can be read.  Reading
	 * HCNTRL has no side effects and has
	 * at least one bit that is guaranteed to
	 * be zero so it is a good register to
	 * use for this test.
	 */
	hcntrl = ahd_inb(ahd, HCNTRL);
	if (hcntrl == 0xFF)
		goto fail;

	/*
	 * Next create a situation where write combining
	 * or read prefetching could be initiated by the
	 * CPU or host bridge.  Our device does not support
	 * either, so look for data corruption and/or flaged
	 * PCI errors.  First pause without causing another
	 * chip reset.
	 */
	hcntrl &= ~CHIPRST;
	ahd_outb(ahd, HCNTRL, hcntrl|PAUSE);
	while (ahd_is_paused(ahd) == 0)
		;

	/* Clear any PCI errors that occurred before our driver attached. */
	ahd_set_modes(ahd, AHD_MODE_CFG, AHD_MODE_CFG);
	targpcistat = ahd_inb(ahd, TARGPCISTAT);
	ahd_outb(ahd, TARGPCISTAT, targpcistat);
	pci_status1 = ahd_pci_read_config(ahd->dev_softc,
					  PCIR_STATUS + 1, /*bytes*/1);
	ahd_pci_write_config(ahd->dev_softc, PCIR_STATUS + 1,
			     pci_status1, /*bytes*/1);
	ahd_set_modes(ahd, AHD_MODE_SCSI, AHD_MODE_SCSI);
	ahd_outb(ahd, CLRINT, CLRPCIINT);

	ahd_outb(ahd, SEQCTL0, PERRORDIS);
	ahd_outl(ahd, SRAM_BASE, 0x5aa555aa);
	if (ahd_inl(ahd, SRAM_BASE) != 0x5aa555aa)
		goto fail;

	if ((ahd_inb(ahd, INTSTAT) & PCIINT) != 0) {
		ahd_set_modes(ahd, AHD_MODE_CFG, AHD_MODE_CFG);
		targpcistat = ahd_inb(ahd, TARGPCISTAT);
		if ((targpcistat & STA) != 0)
			goto fail;
	}

	error = 0;

fail:
	if ((ahd_inb(ahd, INTSTAT) & PCIINT) != 0) {

		ahd_set_modes(ahd, AHD_MODE_CFG, AHD_MODE_CFG);
		targpcistat = ahd_inb(ahd, TARGPCISTAT);

		/* Silently clear any latched errors. */
		ahd_outb(ahd, TARGPCISTAT, targpcistat);
		pci_status1 = ahd_pci_read_config(ahd->dev_softc,
						  PCIR_STATUS + 1, /*bytes*/1);
		ahd_pci_write_config(ahd->dev_softc, PCIR_STATUS + 1,
				     pci_status1, /*bytes*/1);
		ahd_outb(ahd, CLRINT, CLRPCIINT);
	}
	ahd_outb(ahd, SEQCTL0, PERRORDIS|FAILDIS);
	ahd_pci_write_config(ahd->dev_softc, PCIR_COMMAND, cmd, /*bytes*/2);
	return (error);
}

/*
 * Check the external port logic for a serial eeprom
 * and termination/cable detection contrls.
 */
static int
ahd_check_extport(struct ahd_softc *ahd)
{
	struct	vpd_config vpd;
	struct	seeprom_config *sc;
	u_int	adapter_control;
	int	have_seeprom;
	int	error;

	sc = ahd->seep_config;
	have_seeprom = ahd_acquire_seeprom(ahd);
	if (have_seeprom) {
		u_int start_addr;

		/*
		 * Fetch VPD for this function and parse it.
		 */
		if (bootverbose) 
			printk("%s: Reading VPD from SEEPROM...",
			       ahd_name(ahd));

		/* Address is always in units of 16bit words */
		start_addr = ((2 * sizeof(*sc))
			    + (sizeof(vpd) * (ahd->channel - 'A'))) / 2;

		error = ahd_read_seeprom(ahd, (uint16_t *)&vpd,
					 start_addr, sizeof(vpd)/2,
					 /*bytestream*/TRUE);
		if (error == 0)
			error = ahd_parse_vpddata(ahd, &vpd);
		if (bootverbose) 
			printk("%s: VPD parsing %s\n",
			       ahd_name(ahd),
			       error == 0 ? "successful" : "failed");

		if (bootverbose) 
			printk("%s: Reading SEEPROM...", ahd_name(ahd));

		/* Address is always in units of 16bit words */
		start_addr = (sizeof(*sc) / 2) * (ahd->channel - 'A');

		error = ahd_read_seeprom(ahd, (uint16_t *)sc,
					 start_addr, sizeof(*sc)/2,
					 /*bytestream*/FALSE);

		if (error != 0) {
			printk("Unable to read SEEPROM\n");
			have_seeprom = 0;
		} else {
			have_seeprom = ahd_verify_cksum(sc);

			if (bootverbose) {
				if (have_seeprom == 0)
					printk ("checksum error\n");
				else
					printk ("done.\n");
			}
		}
		ahd_release_seeprom(ahd);
	}

	if (!have_seeprom) {
		u_int	  nvram_scb;

		/*
		 * Pull scratch ram settings and treat them as
		 * if they are the contents of an seeprom if
		 * the 'ADPT', 'BIOS', or 'ASPI' signature is found
		 * in SCB 0xFF.  We manually compose the data as 16bit
		 * values to avoid endian issues.
		 */
		ahd_set_scbptr(ahd, 0xFF);
		nvram_scb = ahd_inb_scbram(ahd, SCB_BASE + NVRAM_SCB_OFFSET);
		if (nvram_scb != 0xFF
		 && ((ahd_inb_scbram(ahd, SCB_BASE + 0) == 'A'
		   && ahd_inb_scbram(ahd, SCB_BASE + 1) == 'D'
		   && ahd_inb_scbram(ahd, SCB_BASE + 2) == 'P'
		   && ahd_inb_scbram(ahd, SCB_BASE + 3) == 'T')
		  || (ahd_inb_scbram(ahd, SCB_BASE + 0) == 'B'
		   && ahd_inb_scbram(ahd, SCB_BASE + 1) == 'I'
		   && ahd_inb_scbram(ahd, SCB_BASE + 2) == 'O'
		   && ahd_inb_scbram(ahd, SCB_BASE + 3) == 'S')
		  || (ahd_inb_scbram(ahd, SCB_BASE + 0) == 'A'
		   && ahd_inb_scbram(ahd, SCB_BASE + 1) == 'S'
		   && ahd_inb_scbram(ahd, SCB_BASE + 2) == 'P'
		   && ahd_inb_scbram(ahd, SCB_BASE + 3) == 'I'))) {
			uint16_t *sc_data;
			int	  i;

			ahd_set_scbptr(ahd, nvram_scb);
			sc_data = (uint16_t *)sc;
			for (i = 0; i < 64; i += 2)
				*sc_data++ = ahd_inw_scbram(ahd, SCB_BASE+i);
			have_seeprom = ahd_verify_cksum(sc);
			if (have_seeprom)
				ahd->flags |= AHD_SCB_CONFIG_USED;
		}
	}

#ifdef AHD_DEBUG
	if (have_seeprom != 0
	 && (ahd_debug & AHD_DUMP_SEEPROM) != 0) {
		uint16_t *sc_data;
		int	  i;

		printk("%s: Seeprom Contents:", ahd_name(ahd));
		sc_data = (uint16_t *)sc;
		for (i = 0; i < (sizeof(*sc)); i += 2)
			printk("\n\t0x%.4x", sc_data[i]);
		printk("\n");
	}
#endif

	if (!have_seeprom) {
		if (bootverbose)
			printk("%s: No SEEPROM available.\n", ahd_name(ahd));
		ahd->flags |= AHD_USEDEFAULTS;
		error = ahd_default_config(ahd);
		adapter_control = CFAUTOTERM|CFSEAUTOTERM;
		kfree(ahd->seep_config);
		ahd->seep_config = NULL;
	} else {
		error = ahd_parse_cfgdata(ahd, sc);
		adapter_control = sc->adapter_control;
	}
	if (error != 0)
		return (error);

	ahd_configure_termination(ahd, adapter_control);

	return (0);
}

static void
ahd_configure_termination(struct ahd_softc *ahd, u_int adapter_control)
{
	int	 error;
	u_int	 sxfrctl1;
	uint8_t	 termctl;
	uint32_t devconfig;

	devconfig = ahd_pci_read_config(ahd->dev_softc, DEVCONFIG, /*bytes*/4);
	devconfig &= ~STPWLEVEL;
	if ((ahd->flags & AHD_STPWLEVEL_A) != 0)
		devconfig |= STPWLEVEL;
	if (bootverbose)
		printk("%s: STPWLEVEL is %s\n",
		       ahd_name(ahd), (devconfig & STPWLEVEL) ? "on" : "off");
	ahd_pci_write_config(ahd->dev_softc, DEVCONFIG, devconfig, /*bytes*/4);
 
	/* Make sure current sensing is off. */
	if ((ahd->flags & AHD_CURRENT_SENSING) != 0) {
		(void)ahd_write_flexport(ahd, FLXADDR_ROMSTAT_CURSENSECTL, 0);
	}

	/*
	 * Read to sense.  Write to set.
	 */
	error = ahd_read_flexport(ahd, FLXADDR_TERMCTL, &termctl);
	if ((adapter_control & CFAUTOTERM) == 0) {
		if (bootverbose)
			printk("%s: Manual Primary Termination\n",
			       ahd_name(ahd));
		termctl &= ~(FLX_TERMCTL_ENPRILOW|FLX_TERMCTL_ENPRIHIGH);
		if ((adapter_control & CFSTERM) != 0)
			termctl |= FLX_TERMCTL_ENPRILOW;
		if ((adapter_control & CFWSTERM) != 0)
			termctl |= FLX_TERMCTL_ENPRIHIGH;
	} else if (error != 0) {
		printk("%s: Primary Auto-Term Sensing failed! "
		       "Using Defaults.\n", ahd_name(ahd));
		termctl = FLX_TERMCTL_ENPRILOW|FLX_TERMCTL_ENPRIHIGH;
	}

	if ((adapter_control & CFSEAUTOTERM) == 0) {
		if (bootverbose)
			printk("%s: Manual Secondary Termination\n",
			       ahd_name(ahd));
		termctl &= ~(FLX_TERMCTL_ENSECLOW|FLX_TERMCTL_ENSECHIGH);
		if ((adapter_control & CFSELOWTERM) != 0)
			termctl |= FLX_TERMCTL_ENSECLOW;
		if ((adapter_control & CFSEHIGHTERM) != 0)
			termctl |= FLX_TERMCTL_ENSECHIGH;
	} else if (error != 0) {
		printk("%s: Secondary Auto-Term Sensing failed! "
		       "Using Defaults.\n", ahd_name(ahd));
		termctl |= FLX_TERMCTL_ENSECLOW|FLX_TERMCTL_ENSECHIGH;
	}

	/*
	 * Now set the termination based on what we found.
	 */
	sxfrctl1 = ahd_inb(ahd, SXFRCTL1) & ~STPWEN;
	ahd->flags &= ~AHD_TERM_ENB_A;
	if ((termctl & FLX_TERMCTL_ENPRILOW) != 0) {
		ahd->flags |= AHD_TERM_ENB_A;
		sxfrctl1 |= STPWEN;
	}
	/* Must set the latch once in order to be effective. */
	ahd_outb(ahd, SXFRCTL1, sxfrctl1|STPWEN);
	ahd_outb(ahd, SXFRCTL1, sxfrctl1);

	error = ahd_write_flexport(ahd, FLXADDR_TERMCTL, termctl);
	if (error != 0) {
		printk("%s: Unable to set termination settings!\n",
		       ahd_name(ahd));
	} else if (bootverbose) {
		printk("%s: Primary High byte termination %sabled\n",
		       ahd_name(ahd),
		       (termctl & FLX_TERMCTL_ENPRIHIGH) ? "En" : "Dis");

		printk("%s: Primary Low byte termination %sabled\n",
		       ahd_name(ahd),
		       (termctl & FLX_TERMCTL_ENPRILOW) ? "En" : "Dis");

		printk("%s: Secondary High byte termination %sabled\n",
		       ahd_name(ahd),
		       (termctl & FLX_TERMCTL_ENSECHIGH) ? "En" : "Dis");

		printk("%s: Secondary Low byte termination %sabled\n",
		       ahd_name(ahd),
		       (termctl & FLX_TERMCTL_ENSECLOW) ? "En" : "Dis");
	}
	return;
}

#define	DPE	0x80
#define SSE	0x40
#define	RMA	0x20
#define	RTA	0x10
#define STA	0x08
#define DPR	0x01

static const char *split_status_source[] =
{
	"DFF0",
	"DFF1",
	"OVLY",
	"CMC",
};

static const char *pci_status_source[] =
{
	"DFF0",
	"DFF1",
	"SG",
	"CMC",
	"OVLY",
	"NONE",
	"MSI",
	"TARG"
};

static const char *split_status_strings[] =
{
	"%s: Received split response in %s.\n",
	"%s: Received split completion error message in %s\n",
	"%s: Receive overrun in %s\n",
	"%s: Count not complete in %s\n",
	"%s: Split completion data bucket in %s\n",
	"%s: Split completion address error in %s\n",
	"%s: Split completion byte count error in %s\n",
	"%s: Signaled Target-abort to early terminate a split in %s\n"
};

static const char *pci_status_strings[] =
{
	"%s: Data Parity Error has been reported via PERR# in %s\n",
	"%s: Target initial wait state error in %s\n",
	"%s: Split completion read data parity error in %s\n",
	"%s: Split completion address attribute parity error in %s\n",
	"%s: Received a Target Abort in %s\n",
	"%s: Received a Master Abort in %s\n",
	"%s: Signal System Error Detected in %s\n",
	"%s: Address or Write Phase Parity Error Detected in %s.\n"
};

static void
ahd_pci_intr(struct ahd_softc *ahd)
{
	uint8_t		pci_status[8];
	ahd_mode_state	saved_modes;
	u_int		pci_status1;
	u_int		intstat;
	u_int		i;
	u_int		reg;
	
	intstat = ahd_inb(ahd, INTSTAT);

	if ((intstat & SPLTINT) != 0)
		ahd_pci_split_intr(ahd, intstat);

	if ((intstat & PCIINT) == 0)
		return;

	printk("%s: PCI error Interrupt\n", ahd_name(ahd));
	saved_modes = ahd_save_modes(ahd);
	ahd_dump_card_state(ahd);
	ahd_set_modes(ahd, AHD_MODE_CFG, AHD_MODE_CFG);
	for (i = 0, reg = DF0PCISTAT; i < 8; i++, reg++) {

		if (i == 5)
			continue;
		pci_status[i] = ahd_inb(ahd, reg);
		/* Clear latched errors.  So our interrupt deasserts. */
		ahd_outb(ahd, reg, pci_status[i]);
	}

	for (i = 0; i < 8; i++) {
		u_int bit;
	
		if (i == 5)
			continue;

		for (bit = 0; bit < 8; bit++) {

			if ((pci_status[i] & (0x1 << bit)) != 0) {
				const char *s;

				s = pci_status_strings[bit];
				if (i == 7/*TARG*/ && bit == 3)
					s = "%s: Signaled Target Abort\n";
				printk(s, ahd_name(ahd), pci_status_source[i]);
			}
		}	
	}
	pci_status1 = ahd_pci_read_config(ahd->dev_softc,
					  PCIR_STATUS + 1, /*bytes*/1);
	ahd_pci_write_config(ahd->dev_softc, PCIR_STATUS + 1,
			     pci_status1, /*bytes*/1);
	ahd_restore_modes(ahd, saved_modes);
	ahd_outb(ahd, CLRINT, CLRPCIINT);
	ahd_unpause(ahd);
}

static void
ahd_pci_split_intr(struct ahd_softc *ahd, u_int intstat)
{
	uint8_t		split_status[4];
	uint8_t		split_status1[4];
	uint8_t		sg_split_status[2];
	uint8_t		sg_split_status1[2];
	ahd_mode_state	saved_modes;
	u_int		i;
	uint16_t	pcix_status;

	/*
	 * Check for splits in all modes.  Modes 0 and 1
	 * additionally have SG engine splits to look at.
	 */
	pcix_status = ahd_pci_read_config(ahd->dev_softc, PCIXR_STATUS,
					  /*bytes*/2);
	printk("%s: PCI Split Interrupt - PCI-X status = 0x%x\n",
	       ahd_name(ahd), pcix_status);
	saved_modes = ahd_save_modes(ahd);
	for (i = 0; i < 4; i++) {
		ahd_set_modes(ahd, i, i);

		split_status[i] = ahd_inb(ahd, DCHSPLTSTAT0);
		split_status1[i] = ahd_inb(ahd, DCHSPLTSTAT1);
		/* Clear latched errors.  So our interrupt deasserts. */
		ahd_outb(ahd, DCHSPLTSTAT0, split_status[i]);
		ahd_outb(ahd, DCHSPLTSTAT1, split_status1[i]);
		if (i > 1)
			continue;
		sg_split_status[i] = ahd_inb(ahd, SGSPLTSTAT0);
		sg_split_status1[i] = ahd_inb(ahd, SGSPLTSTAT1);
		/* Clear latched errors.  So our interrupt deasserts. */
		ahd_outb(ahd, SGSPLTSTAT0, sg_split_status[i]);
		ahd_outb(ahd, SGSPLTSTAT1, sg_split_status1[i]);
	}

	for (i = 0; i < 4; i++) {
		u_int bit;

		for (bit = 0; bit < 8; bit++) {

			if ((split_status[i] & (0x1 << bit)) != 0)
				printk(split_status_strings[bit], ahd_name(ahd),
				       split_status_source[i]);

			if (i > 1)
				continue;

			if ((sg_split_status[i] & (0x1 << bit)) != 0)
				printk(split_status_strings[bit], ahd_name(ahd), "SG");
		}
	}
	/*
	 * Clear PCI-X status bits.
	 */
	ahd_pci_write_config(ahd->dev_softc, PCIXR_STATUS,
			     pcix_status, /*bytes*/2);
	ahd_outb(ahd, CLRINT, CLRSPLTINT);
	ahd_restore_modes(ahd, saved_modes);
}

static int
ahd_aic7901_setup(struct ahd_softc *ahd)
{

	ahd->chip = AHD_AIC7901;
	ahd->features = AHD_AIC7901_FE;
	return (ahd_aic790X_setup(ahd));
}

static int
ahd_aic7901A_setup(struct ahd_softc *ahd)
{

	ahd->chip = AHD_AIC7901A;
	ahd->features = AHD_AIC7901A_FE;
	return (ahd_aic790X_setup(ahd));
}

static int
ahd_aic7902_setup(struct ahd_softc *ahd)
{
	ahd->chip = AHD_AIC7902;
	ahd->features = AHD_AIC7902_FE;
	return (ahd_aic790X_setup(ahd));
}

static int
ahd_aic790X_setup(struct ahd_softc *ahd)
{
	ahd_dev_softc_t pci;
	u_int rev;

	pci = ahd->dev_softc;
	rev = ahd_pci_read_config(pci, PCIR_REVID, /*bytes*/1);
	if (rev < ID_AIC7902_PCI_REV_A4) {
		printk("%s: Unable to attach to unsupported chip revision %d\n",
		       ahd_name(ahd), rev);
		ahd_pci_write_config(pci, PCIR_COMMAND, 0, /*bytes*/2);
		return (ENXIO);
	}
	ahd->channel = ahd_get_pci_function(pci) + 'A';
	if (rev < ID_AIC7902_PCI_REV_B0) {
		/*
		 * Enable A series workarounds.
		 */
		ahd->bugs |= AHD_SENT_SCB_UPDATE_BUG|AHD_ABORT_LQI_BUG
			  |  AHD_PKT_BITBUCKET_BUG|AHD_LONG_SETIMO_BUG
			  |  AHD_NLQICRC_DELAYED_BUG|AHD_SCSIRST_BUG
			  |  AHD_LQO_ATNO_BUG|AHD_AUTOFLUSH_BUG
			  |  AHD_CLRLQO_AUTOCLR_BUG|AHD_PCIX_MMAPIO_BUG
			  |  AHD_PCIX_CHIPRST_BUG|AHD_PCIX_SCBRAM_RD_BUG
			  |  AHD_PKTIZED_STATUS_BUG|AHD_PKT_LUN_BUG
			  |  AHD_MDFF_WSCBPTR_BUG|AHD_REG_SLOW_SETTLE_BUG
			  |  AHD_SET_MODE_BUG|AHD_BUSFREEREV_BUG
			  |  AHD_NONPACKFIFO_BUG|AHD_PACED_NEGTABLE_BUG
			  |  AHD_FAINT_LED_BUG;

		/*
		 * IO Cell parameter setup.
		 */
		AHD_SET_PRECOMP(ahd, AHD_PRECOMP_CUTBACK_29);

		if ((ahd->flags & AHD_HP_BOARD) == 0)
			AHD_SET_SLEWRATE(ahd, AHD_SLEWRATE_DEF_REVA);
	} else {
		/* This is revision B and newer. */
		extern uint32_t aic79xx_slowcrc;
		u_int devconfig1;

		ahd->features |= AHD_RTI|AHD_NEW_IOCELL_OPTS
			      |  AHD_NEW_DFCNTRL_OPTS|AHD_FAST_CDB_DELIVERY
			      |  AHD_BUSFREEREV_BUG;
		ahd->bugs |= AHD_LQOOVERRUN_BUG|AHD_EARLY_REQ_BUG;

		/* If the user requested that the SLOWCRC bit to be set. */
		if (aic79xx_slowcrc)
			ahd->features |= AHD_AIC79XXB_SLOWCRC;

		/*
		 * Some issues have been resolved in the 7901B.
		 */
		if ((ahd->features & AHD_MULTI_FUNC) != 0)
			ahd->bugs |= AHD_INTCOLLISION_BUG|AHD_ABORT_LQI_BUG;

		/*
		 * IO Cell parameter setup.
		 */
		AHD_SET_PRECOMP(ahd, AHD_PRECOMP_CUTBACK_29);
		AHD_SET_SLEWRATE(ahd, AHD_SLEWRATE_DEF_REVB);
		AHD_SET_AMPLITUDE(ahd, AHD_AMPLITUDE_DEF);

		/*
		 * Set the PREQDIS bit for H2B which disables some workaround
		 * that doesn't work on regular PCI busses.
		 * XXX - Find out exactly what this does from the hardware
		 * 	 folks!
		 */
		devconfig1 = ahd_pci_read_config(pci, DEVCONFIG1, /*bytes*/1);
		ahd_pci_write_config(pci, DEVCONFIG1,
				     devconfig1|PREQDIS, /*bytes*/1);
		devconfig1 = ahd_pci_read_config(pci, DEVCONFIG1, /*bytes*/1);
	}

	return (0);
}