drivers/media/usb/tm6000/tm6000.h


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/*
 *  tm6000.h - driver for TM5600/TM6000/TM6010 USB video capture devices
 *
 *  Copyright (C) 2006-2007 Mauro Carvalho Chehab <mchehab@infradead.org>
 *
 *  Copyright (C) 2007 Michel Ludwig <michel.ludwig@gmail.com>
 *	- DVB-T support
 *
 *  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 version 2
 *
 *  This program is distributed in the hope that it will be useful,
 *  but WITHOUT ANY WARRANTY; without even the implied warranty of
 *  MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
 *  GNU General Public License for more details.
 *
 *  You should have received a copy of the GNU General Public License
 *  along with this program; if not, write to the Free Software
 *  Foundation, Inc., 675 Mass Ave, Cambridge, MA 02139, USA.
 */

#include <linux/videodev2.h>
#include <media/v4l2-common.h>
#include <media/videobuf-vmalloc.h>
#include "tm6000-usb-isoc.h"
#include <linux/i2c.h>
#include <linux/mutex.h>
#include <media/v4l2-device.h>
#include <media/v4l2-ctrls.h>
#include <media/v4l2-fh.h>

#include <linux/dvb/frontend.h>
#include "dvb_demux.h"
#include "dvb_frontend.h"
#include "dmxdev.h"

/* Inputs */
enum tm6000_itype {
	TM6000_INPUT_TV	= 1,
	TM6000_INPUT_COMPOSITE1,
	TM6000_INPUT_COMPOSITE2,
	TM6000_INPUT_SVIDEO,
	TM6000_INPUT_DVB,
	TM6000_INPUT_RADIO,
};

enum tm6000_mux {
	TM6000_VMUX_VIDEO_A = 1,
	TM6000_VMUX_VIDEO_B,
	TM6000_VMUX_VIDEO_AB,
	TM6000_AMUX_ADC1,
	TM6000_AMUX_ADC2,
	TM6000_AMUX_SIF1,
	TM6000_AMUX_SIF2,
	TM6000_AMUX_I2S,
};

enum tm6000_devtype {
	TM6000 = 0,
	TM5600,
	TM6010,
};

struct tm6000_input {
	enum tm6000_itype	type;
	enum tm6000_mux		vmux;
	enum tm6000_mux		amux;
	unsigned int		v_gpio;
	unsigned int		a_gpio;
};

/* ------------------------------------------------------------------
 *	Basic structures
 * ------------------------------------------------------------------
 */

struct tm6000_fmt {
	char  *name;
	u32   fourcc;          /* v4l2 format id */
	int   depth;
};

/* buffer for one video frame */
struct tm6000_buffer {
	/* common v4l buffer stuff -- must be first */
	struct videobuf_buffer vb;

	struct tm6000_fmt      *fmt;
};

struct tm6000_dmaqueue {
	struct list_head       active;
	struct list_head       queued;

	/* thread for generating video stream*/
	struct task_struct         *kthread;
	wait_queue_head_t          wq;
	/* Counters to control fps rate */
	int                        frame;
	int                        ini_jiffies;
};

/* device states */
enum tm6000_core_state {
	DEV_INITIALIZED   = 0x01,
	DEV_DISCONNECTED  = 0x02,
	DEV_MISCONFIGURED = 0x04,
};

/* io methods */
enum tm6000_io_method {
	IO_NONE,
	IO_READ,
	IO_MMAP,
};

enum tm6000_mode {
	TM6000_MODE_UNKNOWN = 0,
	TM6000_MODE_ANALOG,
	TM6000_MODE_DIGITAL,
};

struct tm6000_gpio {
	int		tuner_reset;
	int		tuner_on;
	int		demod_reset;
	int		demod_on;
	int		power_led;
	int		dvb_led;
	int		ir;
};

struct tm6000_capabilities {
	unsigned int    has_tuner:1;
	unsigned int    has_tda9874:1;
	unsigned int    has_dvb:1;
	unsigned int    has_zl10353:1;
	unsigned int    has_eeprom:1;
	unsigned int    has_remote:1;
	unsigned int    has_radio:1;
};

struct tm6000_dvb {
	struct dvb_adapter	adapter;
	struct dvb_demux	demux;
	struct dvb_frontend	*frontend;
	struct dmxdev		dmxdev;
	unsigned int		streams;
	struct urb		*bulk_urb;
	struct mutex		mutex;
};

struct snd_tm6000_card {
	struct snd_card			*card;
	spinlock_t			reg_lock;
	struct tm6000_core		*core;
	struct snd_pcm_substream	*substream;

	/* temporary data for buffer fill processing */
	unsigned			buf_pos;
	unsigned			period_pos;
};

struct tm6000_endpoint {
	struct usb_host_endpoint	*endp;
	__u8				bInterfaceNumber;
	__u8				bAlternateSetting;
	unsigned			maxsize;
};

#define TM6000_QUIRK_NO_USB_DELAY (1 << 0)

struct tm6000_core {
	/* generic device properties */
	char				name[30];	/* name (including minor) of the device */
	int				model;		/* index in the device_data struct */
	int				devno;		/* marks the number of this device */
	enum tm6000_devtype		dev_type;	/* type of device */
	unsigned char			eedata[256];	/* Eeprom data */
	unsigned			eedata_size;	/* Size of the eeprom info */

	v4l2_std_id                     norm;           /* Current norm */
	int				width, height;	/* Selected resolution */

	enum tm6000_core_state		state;

	/* Device Capabilities*/
	struct tm6000_capabilities	caps;

	/* Used to load alsa/dvb */
        struct work_struct		request_module_wk;

	/* Tuner configuration */
	int				tuner_type;		/* type of the tuner */
	int				tuner_addr;		/* tuner address */

	struct tm6000_gpio		gpio;

	char				*ir_codes;

	__u8				radio;

	/* Demodulator configuration */
	int				demod_addr;	/* demodulator address */

	int				audio_bitrate;
	/* i2c i/o */
	struct i2c_adapter		i2c_adap;
	struct i2c_client		i2c_client;


	/* extension */
	struct list_head		devlist;

	/* video for linux */
	int				users;

	/* various device info */
	struct tm6000_fh		*resources;	/* Points to fh that is streaming */
	bool				is_res_read;

	struct video_device		*vfd;
	struct video_device		*radio_dev;
	struct tm6000_dmaqueue		vidq;
	struct v4l2_device		v4l2_dev;
	struct v4l2_ctrl_handler	ctrl_handler;
	struct v4l2_ctrl_handler	radio_ctrl_handler;

	int				input;
	struct tm6000_input		vinput[3];	/* video input */
	struct tm6000_input		rinput;		/* radio input */

	int				freq;
	unsigned int			fourcc;

	enum tm6000_mode		mode;

	int				ctl_mute;             /* audio */
	int				ctl_volume;
	int				amode;

	/* DVB-T support */
	struct tm6000_dvb		*dvb;

	/* audio support */
	struct snd_tm6000_card		*adev;
	struct work_struct		wq_trigger;   /* Trigger to start/stop audio for alsa module */
	atomic_t			stream_started;  /* stream should be running if true */

	struct tm6000_IR		*ir;

	/* locks */
	struct mutex			lock;
	struct mutex			usb_lock;

	/* usb transfer */
	struct usb_device		*udev;		/* the usb device */

	struct tm6000_endpoint		bulk_in, bulk_out, isoc_in, isoc_out;
	struct tm6000_endpoint		int_in, int_out;

	/* scaler!=0 if scaler is active*/
	int				scaler;

		/* Isoc control struct */
	struct usb_isoc_ctl          isoc_ctl;

	spinlock_t                   slock;

	/* urb dma buffers */
	char				**urb_buffer;
	dma_addr_t			*urb_dma;
	unsigned int			urb_size;

	unsigned long quirks;
};

enum tm6000_ops_type {
	TM6000_AUDIO = 0x10,
	TM6000_DVB = 0x20,
};

struct tm6000_ops {
	struct list_head	next;
	char			*name;
	enum tm6000_ops_type	type;
	int (*init)(struct tm6000_core *);
	int (*fini)(struct tm6000_core *);
	int (*fillbuf)(struct tm6000_core *, char *buf, int size);
};

struct tm6000_fh {
	struct v4l2_fh		     fh;
	struct tm6000_core           *dev;
	unsigned int                 radio;

	/* video capture */
	struct tm6000_fmt            *fmt;
	unsigned int                 width, height;
	struct videobuf_queue        vb_vidq;

	enum v4l2_buf_type           type;
};

#define TM6000_STD	(V4L2_STD_PAL|V4L2_STD_PAL_N|V4L2_STD_PAL_Nc|    \
			V4L2_STD_PAL_M|V4L2_STD_PAL_60|V4L2_STD_NTSC_M| \
			V4L2_STD_NTSC_M_JP|V4L2_STD_SECAM)

/* In tm6000-cards.c */

int tm6000_tuner_callback(void *ptr, int component, int command, int arg);
int tm6000_xc5000_callback(void *ptr, int component, int command, int arg);
int tm6000_cards_setup(struct tm6000_core *dev);
void tm6000_flash_led(struct tm6000_core *dev, u8 state);

/* In tm6000-core.c */

int tm6000_read_write_usb(struct tm6000_core *dev, u8 reqtype, u8 req,
			   u16 value, u16 index, u8 *buf, u16 len);
int tm6000_get_reg(struct tm6000_core *dev, u8 req, u16 value, u16 index);
int tm6000_get_reg16(struct tm6000_core *dev, u8 req, u16 value, u16 index);
int tm6000_get_reg32(struct tm6000_core *dev, u8 req, u16 value, u16 index);
int tm6000_set_reg(struct tm6000_core *dev, u8 req, u16 value, u16 index);
int tm6000_set_reg_mask(struct tm6000_core *dev, u8 req, u16 value,
						u16 index, u16 mask);
int tm6000_i2c_reset(struct tm6000_core *dev, u16 tsleep);
int tm6000_init(struct tm6000_core *dev);
int tm6000_reset(struct tm6000_core *dev);

int tm6000_init_analog_mode(struct tm6000_core *dev);
int tm6000_init_digital_mode(struct tm6000_core *dev);
int tm6000_set_audio_bitrate(struct tm6000_core *dev, int bitrate);
int tm6000_set_audio_rinput(struct tm6000_core *dev);
int tm6000_tvaudio_set_mute(struct tm6000_core *dev, u8 mute);
void tm6000_set_volume(struct tm6000_core *dev, int vol);

int tm6000_v4l2_register(struct tm6000_core *dev);
int tm6000_v4l2_unregister(struct tm6000_core *dev);
int tm6000_v4l2_exit(void);
void tm6000_set_fourcc_format(struct tm6000_core *dev);

void tm6000_remove_from_devlist(struct tm6000_core *dev);
void tm6000_add_into_devlist(struct tm6000_core *dev);
int tm6000_register_extension(struct tm6000_ops *ops);
void tm6000_unregister_extension(struct tm6000_ops *ops);
void tm6000_init_extension(struct tm6000_core *dev);
void tm6000_close_extension(struct tm6000_core *dev);
int tm6000_call_fillbuf(struct tm6000_core *dev, enum tm6000_ops_type type,
			char *buf, int size);


/* In tm6000-stds.c */
void tm6000_get_std_res(struct tm6000_core *dev);
int tm6000_set_standard(struct tm6000_core *dev);

/* In tm6000-i2c.c */
int tm6000_i2c_register(struct tm6000_core *dev);
int tm6000_i2c_unregister(struct tm6000_core *dev);

/* In tm6000-queue.c */

int tm6000_v4l2_mmap(struct file *filp, struct vm_area_struct *vma);

int tm6000_vidioc_streamon(struct file *file, void *priv,
			   enum v4l2_buf_type i);
int tm6000_vidioc_streamoff(struct file *file, void *priv,
			    enum v4l2_buf_type i);
int tm6000_vidioc_reqbufs(struct file *file, void *priv,
			  struct v4l2_requestbuffers *rb);
int tm6000_vidioc_querybuf(struct file *file, void *priv,
			   struct v4l2_buffer *b);
int tm6000_vidioc_qbuf(struct file *file, void *priv, struct v4l2_buffer *b);
int tm6000_vidioc_dqbuf(struct file *file, void *priv, struct v4l2_buffer *b);
ssize_t tm6000_v4l2_read(struct file *filp, char __user * buf, size_t count,
			 loff_t *f_pos);
unsigned int tm6000_v4l2_poll(struct file *file,
			      struct poll_table_struct *wait);
int tm6000_queue_init(struct tm6000_core *dev);

/* In tm6000-alsa.c */
/*int tm6000_audio_init(struct tm6000_core *dev, int idx);*/

/* In tm6000-input.c */
int tm6000_ir_init(struct tm6000_core *dev);
int tm6000_ir_fini(struct tm6000_core *dev);
void tm6000_ir_wait(struct tm6000_core *dev, u8 state);
int tm6000_ir_int_start(struct tm6000_core *dev);
void tm6000_ir_int_stop(struct tm6000_core *dev);

/* Debug stuff */

extern int tm6000_debug;

#define dprintk(dev, level, fmt, arg...) do {\
	if (tm6000_debug & level) \
		printk(KERN_INFO "(%lu) %s %s :"fmt, jiffies, \
			 dev->name, __func__ , ##arg); } while (0)

#define V4L2_DEBUG_REG		0x0004
#define V4L2_DEBUG_I2C		0x0008
#define V4L2_DEBUG_QUEUE	0x0010
#define V4L2_DEBUG_ISOC		0x0020
#define V4L2_DEBUG_RES_LOCK	0x0040	/* Resource locking */
#define V4L2_DEBUG_OPEN		0x0080	/* video open/close debug */

#define tm6000_err(fmt, arg...) do {\
	printk(KERN_ERR "tm6000 %s :"fmt, \
		__func__ , ##arg); } while (0)

/*

  Linux Driver for BusLogic MultiMaster and FlashPoint SCSI Host Adapters

  Copyright 1995-1998 by Leonard N. Zubkoff <lnz@dandelion.com>

  This program is free software; you may redistribute and/or modify it under
  the terms of the GNU General Public License Version 2 as published by the
  Free Software Foundation.

  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 complete details.

  The author respectfully requests that any modifications to this software be
  sent directly to him for evaluation and testing.

  Special thanks to Wayne Yen, Jin-Lon Hon, and Alex Win of BusLogic, whose
  advice has been invaluable, to David Gentzel, for writing the original Linux
  BusLogic driver, and to Paul Gortmaker, for being such a dedicated test site.

  Finally, special thanks to Mylex/BusLogic for making the FlashPoint SCCB
  Manager available as freely redistributable source code.

*/

#define BusLogic_DriverVersion		"2.1.16"
#define BusLogic_DriverDate		"18 July 2002"

#include <linux/module.h>
#include <linux/init.h>
#include <linux/interrupt.h>
#include <linux/types.h>
#include <linux/blkdev.h>
#include <linux/delay.h>
#include <linux/ioport.h>
#include <linux/mm.h>
#include <linux/stat.h>
#include <linux/pci.h>
#include <linux/spinlock.h>
#include <linux/jiffies.h>
#include <linux/dma-mapping.h>
#include <scsi/scsicam.h>

#include <asm/dma.h>
#include <asm/io.h>
#include <asm/system.h>

#include <scsi/scsi.h>
#include <scsi/scsi_cmnd.h>
#include <scsi/scsi_device.h>
#include <scsi/scsi_host.h>
#include <scsi/scsi_tcq.h>
#include "BusLogic.h"
#include "FlashPoint.c"

#ifndef FAILURE
#define FAILURE (-1)
#endif

static struct scsi_host_template Bus_Logic_template;

/*
  BusLogic_DriverOptionsCount is a count of the number of BusLogic Driver
  Options specifications provided via the Linux Kernel Command Line or via
  the Loadable Kernel Module Installation Facility.
*/

static int BusLogic_DriverOptionsCount;


/*
  BusLogic_DriverOptions is an array of Driver Options structures representing
  BusLogic Driver Options specifications provided via the Linux Kernel Command
  Line or via the Loadable Kernel Module Installation Facility.
*/

static struct BusLogic_DriverOptions BusLogic_DriverOptions[BusLogic_MaxHostAdapters];


/*
  BusLogic can be assigned a string by insmod.
*/

MODULE_LICENSE("GPL");
#ifdef MODULE
static char *BusLogic;
module_param(BusLogic, charp, 0);
#endif


/*
  BusLogic_ProbeOptions is a set of Probe Options to be applied across
  all BusLogic Host Adapters.
*/

static struct BusLogic_ProbeOptions BusLogic_ProbeOptions;


/*
  BusLogic_GlobalOptions is a set of Global Options to be applied across
  all BusLogic Host Adapters.
*/

static struct BusLogic_GlobalOptions BusLogic_GlobalOptions;

static LIST_HEAD(BusLogic_host_list);

/*
  BusLogic_ProbeInfoCount is the number of entries in BusLogic_ProbeInfoList.
*/

static int BusLogic_ProbeInfoCount;


/*
  BusLogic_ProbeInfoList is the list of I/O Addresses and Bus Probe Information
  to be checked for potential BusLogic Host Adapters.  It is initialized by
  interrogating the PCI Configuration Space on PCI machines as well as from the
  list of standard BusLogic I/O Addresses.
*/

static struct BusLogic_ProbeInfo *BusLogic_ProbeInfoList;


/*
  BusLogic_CommandFailureReason holds a string identifying the reason why a
  call to BusLogic_Command failed.  It is only non-NULL when BusLogic_Command
  returns a failure code.
*/

static char *BusLogic_CommandFailureReason;

/*
  BusLogic_AnnounceDriver announces the Driver Version and Date, Author's
  Name, Copyright Notice, and Electronic Mail Address.
*/

static void BusLogic_AnnounceDriver(struct BusLogic_HostAdapter *HostAdapter)
{
	BusLogic_Announce("***** BusLogic SCSI Driver Version " BusLogic_DriverVersion " of " BusLogic_DriverDate " *****\n", HostAdapter);
	BusLogic_Announce("Copyright 1995-1998 by Leonard N. Zubkoff " "<lnz@dandelion.com>\n", HostAdapter);
}


/*
  BusLogic_DriverInfo returns the Host Adapter Name to identify this SCSI
  Driver and Host Adapter.
*/

static const char *BusLogic_DriverInfo(struct Scsi_Host *Host)
{
	struct BusLogic_HostAdapter *HostAdapter = (struct BusLogic_HostAdapter *) Host->hostdata;
	return HostAdapter->FullModelName;
}

/*
  BusLogic_InitializeCCBs initializes a group of Command Control Blocks (CCBs)
  for Host Adapter from the BlockSize bytes located at BlockPointer.  The newly
  created CCBs are added to Host Adapter's free list.
*/

static void BusLogic_InitializeCCBs(struct BusLogic_HostAdapter *HostAdapter, void *BlockPointer, int BlockSize, dma_addr_t BlockPointerHandle)
{
	struct BusLogic_CCB *CCB = (struct BusLogic_CCB *) BlockPointer;
	unsigned int offset = 0;
	memset(BlockPointer, 0, BlockSize);
	CCB->AllocationGroupHead = BlockPointerHandle;
	CCB->AllocationGroupSize = BlockSize;
	while ((BlockSize -= sizeof(struct BusLogic_CCB)) >= 0) {
		CCB->Status = BusLogic_CCB_Free;
		CCB->HostAdapter = HostAdapter;
		CCB->DMA_Handle = (u32) BlockPointerHandle + offset;
		if (BusLogic_FlashPointHostAdapterP(HostAdapter)) {
			CCB->CallbackFunction = BusLogic_QueueCompletedCCB;
			CCB->BaseAddress = HostAdapter->FlashPointInfo.BaseAddress;
		}
		CCB->Next = HostAdapter->Free_CCBs;
		CCB->NextAll = HostAdapter->All_CCBs;
		HostAdapter->Free_CCBs = CCB;
		HostAdapter->All_CCBs = CCB;
		HostAdapter->AllocatedCCBs++;
		CCB++;
		offset += sizeof(struct BusLogic_CCB);
	}
}


/*
  BusLogic_CreateInitialCCBs allocates the initial CCBs for Host Adapter.
*/

static bool __init BusLogic_CreateInitialCCBs(struct BusLogic_HostAdapter *HostAdapter)
{
	int BlockSize = BusLogic_CCB_AllocationGroupSize * sizeof(struct BusLogic_CCB);
	void *BlockPointer;
	dma_addr_t BlockPointerHandle;
	while (HostAdapter->AllocatedCCBs < HostAdapter->InitialCCBs) {
		BlockPointer = pci_alloc_consistent(HostAdapter->PCI_Device, BlockSize, &BlockPointerHandle);
		if (BlockPointer == NULL) {
			BusLogic_Error("UNABLE TO ALLOCATE CCB GROUP - DETACHING\n", HostAdapter);
			return false;
		}
		BusLogic_InitializeCCBs(HostAdapter, BlockPointer, BlockSize, BlockPointerHandle);
	}
	return true;
}


/*
  BusLogic_DestroyCCBs deallocates the CCBs for Host Adapter.
*/

static void BusLogic_DestroyCCBs(struct BusLogic_HostAdapter *HostAdapter)
{
	struct BusLogic_CCB *NextCCB = HostAdapter->All_CCBs, *CCB, *Last_CCB = NULL;
	HostAdapter->All_CCBs = NULL;
	HostAdapter->Free_CCBs = NULL;
	while ((CCB = NextCCB) != NULL) {
		NextCCB = CCB->NextAll;
		if (CCB->AllocationGroupHead) {
			if (Last_CCB)
				pci_free_consistent(HostAdapter->PCI_Device, Last_CCB->AllocationGroupSize, Last_CCB, Last_CCB->AllocationGroupHead);
			Last_CCB = CCB;
		}
	}
	if (Last_CCB)
		pci_free_consistent(HostAdapter->PCI_Device, Last_CCB->AllocationGroupSize, Last_CCB, Last_CCB->AllocationGroupHead);
}


/*
  BusLogic_CreateAdditionalCCBs allocates Additional CCBs for Host Adapter.  If
  allocation fails and there are no remaining CCBs available, the Driver Queue
  Depth is decreased to a known safe value to avoid potential deadlocks when
  multiple host adapters share the same IRQ Channel.
*/

static void BusLogic_CreateAdditionalCCBs(struct BusLogic_HostAdapter *HostAdapter, int AdditionalCCBs, bool SuccessMessageP)
{
	int BlockSize = BusLogic_CCB_AllocationGroupSize * sizeof(struct BusLogic_CCB);
	int PreviouslyAllocated = HostAdapter->AllocatedCCBs;
	void *BlockPointer;
	dma_addr_t BlockPointerHandle;
	if (AdditionalCCBs <= 0)
		return;
	while (HostAdapter->AllocatedCCBs - PreviouslyAllocated < AdditionalCCBs) {
		BlockPointer = pci_alloc_consistent(HostAdapter->PCI_Device, BlockSize, &BlockPointerHandle);
		if (BlockPointer == NULL)
			break;
		BusLogic_InitializeCCBs(HostAdapter, BlockPointer, BlockSize, BlockPointerHandle);
	}
	if (HostAdapter->AllocatedCCBs > PreviouslyAllocated) {
		if (SuccessMessageP)
			BusLogic_Notice("Allocated %d additional CCBs (total now %d)\n", HostAdapter, HostAdapter->AllocatedCCBs - PreviouslyAllocated, HostAdapter->AllocatedCCBs);
		return;
	}
	BusLogic_Notice("Failed to allocate additional CCBs\n", HostAdapter);
	if (HostAdapter->DriverQueueDepth > HostAdapter->AllocatedCCBs - HostAdapter->TargetDeviceCount) {
		HostAdapter->DriverQueueDepth = HostAdapter->AllocatedCCBs - HostAdapter->TargetDeviceCount;
		HostAdapter->SCSI_Host->can_queue = HostAdapter->DriverQueueDepth;
	}
}

/*
  BusLogic_AllocateCCB allocates a CCB from Host Adapter's free list,
  allocating more memory from the Kernel if necessary.  The Host Adapter's
  Lock should already have been acquired by the caller.
*/

static struct BusLogic_CCB *BusLogic_AllocateCCB(struct BusLogic_HostAdapter
						 *HostAdapter)
{
	static unsigned long SerialNumber = 0;
	struct BusLogic_CCB *CCB;
	CCB = HostAdapter->Free_CCBs;
	if (CCB != NULL) {
		CCB->SerialNumber = ++SerialNumber;
		HostAdapter->Free_CCBs = CCB->Next;
		CCB->Next = NULL;
		if (HostAdapter->Free_CCBs == NULL)
			BusLogic_CreateAdditionalCCBs(HostAdapter, HostAdapter->IncrementalCCBs, true);
		return CCB;
	}
	BusLogic_CreateAdditionalCCBs(HostAdapter, HostAdapter->IncrementalCCBs, true);
	CCB = HostAdapter->Free_CCBs;
	if (CCB == NULL)
		return NULL;
	CCB->SerialNumber = ++SerialNumber;
	HostAdapter->Free_CCBs = CCB->Next;
	CCB->Next = NULL;
	return CCB;
}


/*
  BusLogic_DeallocateCCB deallocates a CCB, returning it to the Host Adapter's
  free list.  The Host Adapter's Lock should already have been acquired by the
  caller.
*/

static void BusLogic_DeallocateCCB(struct BusLogic_CCB *CCB)
{
	struct BusLogic_HostAdapter *HostAdapter = CCB->HostAdapter;

	scsi_dma_unmap(CCB->Command);
	pci_unmap_single(HostAdapter->PCI_Device, CCB->SenseDataPointer,
			 CCB->SenseDataLength, PCI_DMA_FROMDEVICE);

	CCB->Command = NULL;
	CCB->Status = BusLogic_CCB_Free;
	CCB->Next = HostAdapter->Free_CCBs;
	HostAdapter->Free_CCBs = CCB;
}


/*
  BusLogic_Command sends the command OperationCode to HostAdapter, optionally
  providing ParameterLength bytes of ParameterData and receiving at most
  ReplyLength bytes of ReplyData; any excess reply data is received but
  discarded.

  On success, this function returns the number of reply bytes read from
  the Host Adapter (including any discarded data); on failure, it returns
  -1 if the command was invalid, or -2 if a timeout occurred.

  BusLogic_Command is called exclusively during host adapter detection and
  initialization, so performance and latency are not critical, and exclusive
  access to the Host Adapter hardware is assumed.  Once the host adapter and
  driver are initialized, the only Host Adapter command that is issued is the
  single byte Execute Mailbox Command operation code, which does not require
  waiting for the Host Adapter Ready bit to be set in the Status Register.
*/

static int BusLogic_Command(struct BusLogic_HostAdapter *HostAdapter, enum BusLogic_OperationCode OperationCode, void *ParameterData, int ParameterLength, void *ReplyData, int ReplyLength)
{
	unsigned char *ParameterPointer = (unsigned char *) ParameterData;
	unsigned char *ReplyPointer = (unsigned char *) ReplyData;
	union BusLogic_StatusRegister StatusRegister;
	union BusLogic_InterruptRegister InterruptRegister;
	unsigned long ProcessorFlags = 0;
	int ReplyBytes = 0, Result;
	long TimeoutCounter;
	/*
	   Clear out the Reply Data if provided.
	 */
	if (ReplyLength > 0)
		memset(ReplyData, 0, ReplyLength);
	/*
	   If the IRQ Channel has not yet been acquired, then interrupts must be
	   disabled while issuing host adapter commands since a Command Complete
	   interrupt could occur if the IRQ Channel was previously enabled by another
	   BusLogic Host Adapter or another driver sharing the same IRQ Channel.
	 */
	if (!HostAdapter->IRQ_ChannelAcquired)
		local_irq_save(ProcessorFlags);
	/*
	   Wait for the Host Adapter Ready bit to be set and the Command/Parameter
	   Register Busy bit to be reset in the Status Register.
	 */
	TimeoutCounter = 10000;
	while (--TimeoutCounter >= 0) {
		StatusRegister.All = BusLogic_ReadStatusRegister(HostAdapter);
		if (StatusRegister.sr.HostAdapterReady && !StatusRegister.sr.CommandParameterRegisterBusy)
			break;
		udelay(100);
	}
	if (TimeoutCounter < 0) {
		BusLogic_CommandFailureReason = "Timeout waiting for Host Adapter Ready";
		Result = -2;
		goto Done;
	}
	/*
	   Write the OperationCode to the Command/Parameter Register.
	 */
	HostAdapter->HostAdapterCommandCompleted = false;
	BusLogic_WriteCommandParameterRegister(HostAdapter, OperationCode);
	/*
	   Write any additional Parameter Bytes.
	 */
	TimeoutCounter = 10000;
	while (ParameterLength > 0 && --TimeoutCounter >= 0) {
		/*
		   Wait 100 microseconds to give the Host Adapter enough time to determine
		   whether the last value written to the Command/Parameter Register was
		   valid or not.  If the Command Complete bit is set in the Interrupt
		   Register, then the Command Invalid bit in the Status Register will be
		   reset if the Operation Code or Parameter was valid and the command
		   has completed, or set if the Operation Code or Parameter was invalid.
		   If the Data In Register Ready bit is set in the Status Register, then
		   the Operation Code was valid, and data is waiting to be read back
		   from the Host Adapter.  Otherwise, wait for the Command/Parameter
		   Register Busy bit in the Status Register to be reset.
		 */
		udelay(100);
		InterruptRegister.All = BusLogic_ReadInterruptRegister(HostAdapter);
		StatusRegister.All = BusLogic_ReadStatusRegister(HostAdapter);
		if (InterruptRegister.ir.CommandComplete)
			break;
		if (HostAdapter->HostAdapterCommandCompleted)
			break;
		if (StatusRegister.sr.DataInRegisterReady)
			break;
		if (StatusRegister.sr.CommandParameterRegisterBusy)
			continue;
		BusLogic_WriteCommandParameterRegister(HostAdapter, *ParameterPointer++);
		ParameterLength--;
	}
	if (TimeoutCounter < 0) {
		BusLogic_CommandFailureReason = "Timeout waiting for Parameter Acceptance";
		Result = -2;
		goto Done;
	}
	/*
	   The Modify I/O Address command does not cause a Command Complete Interrupt.
	 */
	if (OperationCode == BusLogic_ModifyIOAddress) {
		StatusRegister.All = BusLogic_ReadStatusRegister(HostAdapter);
		if (StatusRegister.sr.CommandInvalid) {
			BusLogic_CommandFailureReason = "Modify I/O Address Invalid";
			Result = -1;
			goto Done;
		}
		if (BusLogic_GlobalOptions.TraceConfiguration)
			BusLogic_Notice("BusLogic_Command(%02X) Status = %02X: " "(Modify I/O Address)\n", HostAdapter, OperationCode, StatusRegister.All);
		Result = 0;
		goto Done;
	}
	/*
	   Select an appropriate timeout value for awaiting command completion.
	 */
	switch (OperationCode) {
	case BusLogic_InquireInstalledDevicesID0to7:
	case BusLogic_InquireInstalledDevicesID8to15:
	case BusLogic_InquireTargetDevices:
		/* Approximately 60 seconds. */
		TimeoutCounter = 60 * 10000;
		break;
	default:
		/* Approximately 1 second. */
		TimeoutCounter = 10000;
		break;
	}
	/*
	   Receive any Reply Bytes, waiting for either the Command Complete bit to
	   be set in the Interrupt Register, or for the Interrupt Handler to set the
	   Host Adapter Command Completed bit in the Host Adapter structure.
	 */
	while (--TimeoutCounter >= 0) {
		InterruptRegister.All = BusLogic_ReadInterruptRegister(HostAdapter);
		StatusRegister.All = BusLogic_ReadStatusRegister(HostAdapter);
		if (InterruptRegister.ir.CommandComplete)
			break;
		if (HostAdapter->HostAdapterCommandCompleted)
			break;
		if (StatusRegister.sr.DataInRegisterReady) {
			if (++ReplyBytes <= ReplyLength)
				*ReplyPointer++ = BusLogic_ReadDataInRegister(HostAdapter);
			else
				BusLogic_ReadDataInRegister(HostAdapter);
		}
		if (OperationCode == BusLogic_FetchHostAdapterLocalRAM && StatusRegister.sr.HostAdapterReady)
			break;
		udelay(100);
	}
	if (TimeoutCounter < 0) {
		BusLogic_CommandFailureReason = "Timeout waiting for Command Complete";
		Result = -2;
		goto Done;
	}
	/*
	   Clear any pending Command Complete Interrupt.
	 */
	BusLogic_InterruptReset(HostAdapter);
	/*
	   Provide tracing information if requested.
	 */
	if (BusLogic_GlobalOptions.TraceConfiguration) {
		int i;
		BusLogic_Notice("BusLogic_Command(%02X) Status = %02X: %2d ==> %2d:", HostAdapter, OperationCode, StatusRegister.All, ReplyLength, ReplyBytes);
		if (ReplyLength > ReplyBytes)
			ReplyLength = ReplyBytes;
		for (i = 0; i < ReplyLength; i++)
			BusLogic_Notice(" %02X", HostAdapter, ((unsigned char *) ReplyData)[i]);
		BusLogic_Notice("\n", HostAdapter);
	}
	/*
	   Process Command Invalid conditions.
	 */
	if (StatusRegister.sr.CommandInvalid) {
		/*
		   Some early BusLogic Host Adapters may not recover properly from
		   a Command Invalid condition, so if this appears to be the case,
		   a Soft Reset is issued to the Host Adapter.  Potentially invalid
		   commands are never attempted after Mailbox Initialization is
		   performed, so there should be no Host Adapter state lost by a
		   Soft Reset in response to a Command Invalid condition.
		 */
		udelay(1000);
		StatusRegister.All = BusLogic_ReadStatusRegister(HostAdapter);
		if (StatusRegister.sr.CommandInvalid ||
		    StatusRegister.sr.Reserved ||
		    StatusRegister.sr.DataInRegisterReady ||
		    StatusRegister.sr.CommandParameterRegisterBusy || !StatusRegister.sr.HostAdapterReady || !StatusRegister.sr.InitializationRequired || StatusRegister.sr.DiagnosticActive || StatusRegister.sr.DiagnosticFailure) {
			BusLogic_SoftReset(HostAdapter);
			udelay(1000);
		}
		BusLogic_CommandFailureReason = "Command Invalid";
		Result = -1;
		goto Done;
	}
	/*
	   Handle Excess Parameters Supplied conditions.
	 */
	if (ParameterLength > 0) {
		BusLogic_CommandFailureReason = "Excess Parameters Supplied";
		Result = -1;
		goto Done;
	}
	/*
	   Indicate the command completed successfully.
	 */
	BusLogic_CommandFailureReason = NULL;
	Result = ReplyBytes;
	/*
	   Restore the interrupt status if necessary and return.
	 */
      Done:
	if (!HostAdapter->IRQ_ChannelAcquired)
		local_irq_restore(ProcessorFlags);
	return Result;
}


/*
  BusLogic_AppendProbeAddressISA appends a single ISA I/O Address to the list
  of I/O Address and Bus Probe Information to be checked for potential BusLogic
  Host Adapters.
*/

static void __init BusLogic_AppendProbeAddressISA(unsigned long IO_Address)
{
	struct BusLogic_ProbeInfo *ProbeInfo;
	if (BusLogic_ProbeInfoCount >= BusLogic_MaxHostAdapters)
		return;
	ProbeInfo = &BusLogic_ProbeInfoList[BusLogic_ProbeInfoCount++];
	ProbeInfo->HostAdapterType = BusLogic_MultiMaster;
	ProbeInfo->HostAdapterBusType = BusLogic_ISA_Bus;
	ProbeInfo->IO_Address = IO_Address;
	ProbeInfo->PCI_Device = NULL;
}


/*
  BusLogic_InitializeProbeInfoListISA initializes the list of I/O Address and
  Bus Probe Information to be checked for potential BusLogic SCSI Host Adapters
  only from the list of standard BusLogic MultiMaster ISA I/O Addresses.
*/

static void __init BusLogic_InitializeProbeInfoListISA(struct BusLogic_HostAdapter
						       *PrototypeHostAdapter)
{
	/*
	   If BusLogic Driver Options specifications requested that ISA Bus Probes
	   be inhibited, do not proceed further.
	 */
	if (BusLogic_ProbeOptions.NoProbeISA)
		return;
	/*
	   Append the list of standard BusLogic MultiMaster ISA I/O Addresses.
	 */
	if (!BusLogic_ProbeOptions.LimitedProbeISA || BusLogic_ProbeOptions.Probe330)
		BusLogic_AppendProbeAddressISA(0x330);
	if (!BusLogic_ProbeOptions.LimitedProbeISA || BusLogic_ProbeOptions.Probe334)
		BusLogic_AppendProbeAddressISA(0x334);
	if (!BusLogic_ProbeOptions.LimitedProbeISA || BusLogic_ProbeOptions.Probe230)
		BusLogic_AppendProbeAddressISA(0x230);
	if (!BusLogic_ProbeOptions.LimitedProbeISA || BusLogic_ProbeOptions.Probe234)
		BusLogic_AppendProbeAddressISA(0x234);
	if (!BusLogic_ProbeOptions.LimitedProbeISA || BusLogic_ProbeOptions.Probe130)
		BusLogic_AppendProbeAddressISA(0x130);
	if (!BusLogic_ProbeOptions.LimitedProbeISA || BusLogic_ProbeOptions.Probe134)
		BusLogic_AppendProbeAddressISA(0x134);
}


#ifdef CONFIG_PCI


/*
  BusLogic_SortProbeInfo sorts a section of BusLogic_ProbeInfoList in order
  of increasing PCI Bus and Device Number.
*/

static void __init BusLogic_SortProbeInfo(struct BusLogic_ProbeInfo *ProbeInfoList, int ProbeInfoCount)
{
	int LastInterchange = ProbeInfoCount - 1, Bound, j;
	while (LastInterchange > 0) {
		Bound = LastInterchange;
		LastInterchange = 0;
		for (j = 0; j < Bound; j++) {
			struct BusLogic_ProbeInfo *ProbeInfo1 = &ProbeInfoList[j];
			struct BusLogic_ProbeInfo *ProbeInfo2 = &ProbeInfoList[j + 1];
			if (ProbeInfo1->Bus > ProbeInfo2->Bus || (ProbeInfo1->Bus == ProbeInfo2->Bus && (ProbeInfo1->Device > ProbeInfo2->Device))) {
				struct BusLogic_ProbeInfo TempProbeInfo;
				memcpy(&TempProbeInfo, ProbeInfo1, sizeof(struct BusLogic_ProbeInfo));
				memcpy(ProbeInfo1, ProbeInfo2, sizeof(struct BusLogic_ProbeInfo));
				memcpy(ProbeInfo2, &TempProbeInfo, sizeof(struct BusLogic_ProbeInfo));
				LastInterchange = j;
			}
		}
	}
}


/*
  BusLogic_InitializeMultiMasterProbeInfo initializes the list of I/O Address
  and Bus Probe Information to be checked for potential BusLogic MultiMaster
  SCSI Host Adapters by interrogating the PCI Configuration Space on PCI
  machines as well as from the list of standard BusLogic MultiMaster ISA
  I/O Addresses.  It returns the number of PCI MultiMaster Host Adapters found.
*/

static int __init BusLogic_InitializeMultiMasterProbeInfo(struct BusLogic_HostAdapter
							  *PrototypeHostAdapter)
{
	struct BusLogic_ProbeInfo *PrimaryProbeInfo = &BusLogic_ProbeInfoList[BusLogic_ProbeInfoCount];
	int NonPrimaryPCIMultiMasterIndex = BusLogic_ProbeInfoCount + 1;
	int NonPrimaryPCIMultiMasterCount = 0, PCIMultiMasterCount = 0;
	bool ForceBusDeviceScanningOrder = false;
	bool ForceBusDeviceScanningOrderChecked = false;
	bool StandardAddressSeen[6];
	struct pci_dev *PCI_Device = NULL;
	int i;
	if (BusLogic_ProbeInfoCount >= BusLogic_MaxHostAdapters)
		return 0;
	BusLogic_ProbeInfoCount++;
	for (i = 0; i < 6; i++)
		StandardAddressSeen[i] = false;
	/*
	   Iterate over the MultiMaster PCI Host Adapters.  For each enumerated host
	   adapter, determine whether its ISA Compatible I/O Port is enabled and if
	   so, whether it is assigned the Primary I/O Address.  A host adapter that is
	   assigned the Primary I/O Address will always be the preferred boot device.
	   The MultiMaster BIOS will first recognize a host adapter at the Primary I/O
	   Address, then any other PCI host adapters, and finally any host adapters
	   located at the remaining standard ISA I/O Addresses.  When a PCI host
	   adapter is found with its ISA Compatible I/O Port enabled, a command is
	   issued to disable the ISA Compatible I/O Port, and it is noted that the
	   particular standard ISA I/O Address need not be probed.
	 */
	PrimaryProbeInfo->IO_Address = 0;
	while ((PCI_Device = pci_get_device(PCI_VENDOR_ID_BUSLOGIC, PCI_DEVICE_ID_BUSLOGIC_MULTIMASTER, PCI_Device)) != NULL) {
		struct BusLogic_HostAdapter *HostAdapter = PrototypeHostAdapter;
		struct BusLogic_PCIHostAdapterInformation PCIHostAdapterInformation;
		enum BusLogic_ISACompatibleIOPort ModifyIOAddressRequest;
		unsigned char Bus;
		unsigned char Device;
		unsigned int IRQ_Channel;
		unsigned long BaseAddress0;
		unsigned long BaseAddress1;
		unsigned long IO_Address;
		unsigned long PCI_Address;

		if (pci_enable_device(PCI_Device))
			continue;

		if (pci_set_dma_mask(PCI_Device, DMA_BIT_MASK(32) ))
			continue;

		Bus = PCI_Device->bus->number;
		Device = PCI_Device->devfn >> 3;
		IRQ_Channel = PCI_Device->irq;
		IO_Address = BaseAddress0 = pci_resource_start(PCI_Device, 0);
		PCI_Address = BaseAddress1 = pci_resource_start(PCI_Device, 1);

		if (pci_resource_flags(PCI_Device, 0) & IORESOURCE_MEM) {
			BusLogic_Error("BusLogic: Base Address0 0x%X not I/O for " "MultiMaster Host Adapter\n", NULL, BaseAddress0);
			BusLogic_Error("at PCI Bus %d Device %d I/O Address 0x%X\n", NULL, Bus, Device, IO_Address);
			continue;
		}
		if (pci_resource_flags(PCI_Device, 1) & IORESOURCE_IO) {
			BusLogic_Error("BusLogic: Base Address1 0x%X not Memory for " "MultiMaster Host Adapter\n", NULL, BaseAddress1);
			BusLogic_Error("at PCI Bus %d Device %d PCI Address 0x%X\n", NULL, Bus, Device, PCI_Address);
			continue;
		}
		if (IRQ_Channel == 0) {
			BusLogic_Error("BusLogic: IRQ Channel %d invalid for " "MultiMaster Host Adapter\n", NULL, IRQ_Channel);
			BusLogic_Error("at PCI Bus %d Device %d I/O Address 0x%X\n", NULL, Bus, Device, IO_Address);
			continue;
		}
		if (BusLogic_GlobalOptions.TraceProbe) {
			BusLogic_Notice("BusLogic: PCI MultiMaster Host Adapter " "detected at\n", NULL);
			BusLogic_Notice("BusLogic: PCI Bus %d Device %d I/O Address " "0x%X PCI Address 0x%X\n", NULL, Bus, Device, IO_Address, PCI_Address);
		}
		/*
		   Issue the Inquire PCI Host Adapter Information command to determine
		   the ISA Compatible I/O Port.  If the ISA Compatible I/O Port is
		   known and enabled, note that the particular Standard ISA I/O
		   Address should not be probed.
		 */
		HostAdapter->IO_Address = IO_Address;
		BusLogic_InterruptReset(HostAdapter);
		if (BusLogic_Command(HostAdapter, BusLogic_InquirePCIHostAdapterInformation, NULL, 0, &PCIHostAdapterInformation, sizeof(PCIHostAdapterInformation))
		    == sizeof(PCIHostAdapterInformation)) {
			if (PCIHostAdapterInformation.ISACompatibleIOPort < 6)
				StandardAddressSeen[PCIHostAdapterInformation.ISACompatibleIOPort] = true;
		} else
			PCIHostAdapterInformation.ISACompatibleIOPort = BusLogic_IO_Disable;
		/*
		 * Issue the Modify I/O Address command to disable the ISA Compatible
		 * I/O Port.  On PCI Host Adapters, the Modify I/O Address command
		 * allows modification of the ISA compatible I/O Address that the Host
		 * Adapter responds to; it does not affect the PCI compliant I/O Address
		 * assigned at system initialization.
		 */
		ModifyIOAddressRequest = BusLogic_IO_Disable;
		BusLogic_Command(HostAdapter, BusLogic_ModifyIOAddress, &ModifyIOAddressRequest, sizeof(ModifyIOAddressRequest), NULL, 0);
		/*
		   For the first MultiMaster Host Adapter enumerated, issue the Fetch
		   Host Adapter Local RAM command to read byte 45 of the AutoSCSI area,
		   for the setting of the "Use Bus And Device # For PCI Scanning Seq."
		   option.  Issue the Inquire Board ID command since this option is
		   only valid for the BT-948/958/958D.
		 */
		if (!ForceBusDeviceScanningOrderChecked) {
			struct BusLogic_FetchHostAdapterLocalRAMRequest FetchHostAdapterLocalRAMRequest;
			struct BusLogic_AutoSCSIByte45 AutoSCSIByte45;
			struct BusLogic_BoardID BoardID;
			FetchHostAdapterLocalRAMRequest.ByteOffset = BusLogic_AutoSCSI_BaseOffset + 45;
			FetchHostAdapterLocalRAMRequest.ByteCount = sizeof(AutoSCSIByte45);
			BusLogic_Command(HostAdapter, BusLogic_FetchHostAdapterLocalRAM, &FetchHostAdapterLocalRAMRequest, sizeof(FetchHostAdapterLocalRAMRequest), &AutoSCSIByte45, sizeof(AutoSCSIByte45));
			BusLogic_Command(HostAdapter, BusLogic_InquireBoardID, NULL, 0, &BoardID, sizeof(BoardID));
			if (BoardID.FirmwareVersion1stDigit == '5')
				ForceBusDeviceScanningOrder = AutoSCSIByte45.ForceBusDeviceScanningOrder;
			ForceBusDeviceScanningOrderChecked = true;
		}
		/*
		   Determine whether this MultiMaster Host Adapter has its ISA
		   Compatible I/O Port enabled and is assigned the Primary I/O Address.
		   If it does, then it is the Primary MultiMaster Host Adapter and must
		   be recognized first.  If it does not, then it is added to the list
		   for probing after any Primary MultiMaster Host Adapter is probed.
		 */
		if (PCIHostAdapterInformation.ISACompatibleIOPort == BusLogic_IO_330) {
			PrimaryProbeInfo->HostAdapterType = BusLogic_MultiMaster;
			PrimaryProbeInfo->HostAdapterBusType = BusLogic_PCI_Bus;
			PrimaryProbeInfo->IO_Address = IO_Address;
			PrimaryProbeInfo->PCI_Address = PCI_Address;
			PrimaryProbeInfo->Bus = Bus;
			PrimaryProbeInfo->Device = Device;
			PrimaryProbeInfo->IRQ_Channel = IRQ_Channel;
			PrimaryProbeInfo->PCI_Device = pci_dev_get(PCI_Device);
			PCIMultiMasterCount++;
		} else if (BusLogic_ProbeInfoCount < BusLogic_MaxHostAdapters) {
			struct BusLogic_ProbeInfo *ProbeInfo = &BusLogic_ProbeInfoList[BusLogic_ProbeInfoCount++];
			ProbeInfo->HostAdapterType = BusLogic_MultiMaster;
			ProbeInfo->HostAdapterBusType = BusLogic_PCI_Bus;
			ProbeInfo->IO_Address = IO_Address;
			ProbeInfo->PCI_Address = PCI_Address;
			ProbeInfo->Bus = Bus;
			ProbeInfo->Device = Device;
			ProbeInfo->IRQ_Channel = IRQ_Channel;
			ProbeInfo->PCI_Device = pci_dev_get(PCI_Device);
			NonPrimaryPCIMultiMasterCount++;
			PCIMultiMasterCount++;
		} else
			BusLogic_Warning("BusLogic: Too many Host Adapters " "detected\n", NULL);
	}
	/*
	   If the AutoSCSI "Use Bus And Device # For PCI Scanning Seq." option is ON
	   for the first enumerated MultiMaster Host Adapter, and if that host adapter
	   is a BT-948/958/958D, then the MultiMaster BIOS will recognize MultiMaster
	   Host Adapters in the order of increasing PCI Bus and Device Number.  In
	   that case, sort the probe information into the same order the BIOS uses.
	   If this option is OFF, then the MultiMaster BIOS will recognize MultiMaster
	   Host Adapters in the order they are enumerated by the PCI BIOS, and hence
	   no sorting is necessary.
	 */
	if (ForceBusDeviceScanningOrder)
		BusLogic_SortProbeInfo(&BusLogic_ProbeInfoList[NonPrimaryPCIMultiMasterIndex], NonPrimaryPCIMultiMasterCount);
	/*
	   If no PCI MultiMaster Host Adapter is assigned the Primary I/O Address,
	   then the Primary I/O Address must be probed explicitly before any PCI
	   host adapters are probed.
	 */
	if (!BusLogic_ProbeOptions.NoProbeISA)
		if (PrimaryProbeInfo->IO_Address == 0 &&
				(!BusLogic_ProbeOptions.LimitedProbeISA ||
				 BusLogic_ProbeOptions.Probe330)) {
			PrimaryProbeInfo->HostAdapterType = BusLogic_MultiMaster;
			PrimaryProbeInfo->HostAdapterBusType = BusLogic_ISA_Bus;
			PrimaryProbeInfo->IO_Address = 0x330;
		}
	/*
	   Append the list of standard BusLogic MultiMaster ISA I/O Addresses,
	   omitting the Primary I/O Address which has already been handled.
	 */
	if (!BusLogic_ProbeOptions.NoProbeISA) {
		if (!StandardAddressSeen[1] &&
				(!BusLogic_ProbeOptions.LimitedProbeISA ||
				 BusLogic_ProbeOptions.Probe334))
			BusLogic_AppendProbeAddressISA(0x334);
		if (!StandardAddressSeen[2] &&
				(!BusLogic_ProbeOptions.LimitedProbeISA ||
				 BusLogic_ProbeOptions.Probe230))
			BusLogic_AppendProbeAddressISA(0x230);
		if (!StandardAddressSeen[3] &&
				(!BusLogic_ProbeOptions.LimitedProbeISA ||
				 BusLogic_ProbeOptions.Probe234))
			BusLogic_AppendProbeAddressISA(0x234);
		if (!StandardAddressSeen[4] &&
				(!BusLogic_ProbeOptions.LimitedProbeISA ||
				 BusLogic_ProbeOptions.Probe130))
			BusLogic_AppendProbeAddressISA(0x130);
		if (!StandardAddressSeen[5] &&
				(!BusLogic_ProbeOptions.LimitedProbeISA ||
				 BusLogic_ProbeOptions.Probe134))
			BusLogic_AppendProbeAddressISA(0x134);
	}
	/*
	   Iterate over the older non-compliant MultiMaster PCI Host Adapters,
	   noting the PCI bus location and assigned IRQ Channel.
	 */
	PCI_Device = NULL;
	while ((PCI_Device = pci_get_device(PCI_VENDOR_ID_BUSLOGIC, PCI_DEVICE_ID_BUSLOGIC_MULTIMASTER_NC, PCI_Device)) != NULL) {
		unsigned char Bus;
		unsigned char Device;
		unsigned int IRQ_Channel;
		unsigned long IO_Address;

		if (pci_enable_device(PCI_Device))
			continue;

		if (pci_set_dma_mask(PCI_Device, DMA_BIT_MASK(32)))
			continue;

		Bus = PCI_Device->bus->number;
		Device = PCI_Device->devfn >> 3;
		IRQ_Channel = PCI_Device->irq;
		IO_Address = pci_resource_start(PCI_Device, 0);

		if (IO_Address == 0 || IRQ_Channel == 0)
			continue;
		for (i = 0; i < BusLogic_ProbeInfoCount; i++) {
			struct BusLogic_ProbeInfo *ProbeInfo = &BusLogic_ProbeInfoList[i];
			if (ProbeInfo->IO_Address == IO_Address && ProbeInfo->HostAdapterType == BusLogic_MultiMaster) {
				ProbeInfo->HostAdapterBusType = BusLogic_PCI_Bus;
				ProbeInfo->PCI_Address = 0;
				ProbeInfo->Bus = Bus;
				ProbeInfo->Device = Device;
				ProbeInfo->IRQ_Channel = IRQ_Channel;
				ProbeInfo->PCI_Device = pci_dev_get(PCI_Device);
				break;
			}
		}
	}
	return PCIMultiMasterCount;
}


/*
  BusLogic_InitializeFlashPointProbeInfo initializes the list of I/O Address
  and Bus Probe Information to be checked for potential BusLogic FlashPoint
  Host Adapters by interrogating the PCI Configuration Space.  It returns the
  number of FlashPoint Host Adapters found.
*/

static int __init BusLogic_InitializeFlashPointProbeInfo(struct BusLogic_HostAdapter
							 *PrototypeHostAdapter)
{
	int FlashPointIndex = BusLogic_ProbeInfoCount, FlashPointCount = 0;
	struct pci_dev *PCI_Device = NULL;
	/*
	   Interrogate PCI Configuration Space for any FlashPoint Host Adapters.
	 */
	while ((PCI_Device = pci_get_device(PCI_VENDOR_ID_BUSLOGIC, PCI_DEVICE_ID_BUSLOGIC_FLASHPOINT, PCI_Device)) != NULL) {
		unsigned char Bus;
		unsigned char Device;
		unsigned int IRQ_Channel;
		unsigned long BaseAddress0;
		unsigned long BaseAddress1;
		unsigned long IO_Address;
		unsigned long PCI_Address;

		if (pci_enable_device(PCI_Device))
			continue;

		if (pci_set_dma_mask(PCI_Device, DMA_BIT_MASK(32)))
			continue;

		Bus = PCI_Device->bus->number;
		Device = PCI_Device->devfn >> 3;
		IRQ_Channel = PCI_Device->irq;
		IO_Address = BaseAddress0 = pci_resource_start(PCI_Device, 0);
		PCI_Address = BaseAddress1 = pci_resource_start(PCI_Device, 1);
#ifdef CONFIG_SCSI_FLASHPOINT
		if (pci_resource_flags(PCI_Device, 0) & IORESOURCE_MEM) {
			BusLogic_Error("BusLogic: Base Address0 0x%X not I/O for " "FlashPoint Host Adapter\n", NULL, BaseAddress0);
			BusLogic_Error("at PCI Bus %d Device %d I/O Address 0x%X\n", NULL, Bus, Device, IO_Address);
			continue;
		}
		if (pci_resource_flags(PCI_Device, 1) & IORESOURCE_IO) {
			BusLogic_Error("BusLogic: Base Address1 0x%X not Memory for " "FlashPoint Host Adapter\n", NULL, BaseAddress1);
			BusLogic_Error("at PCI Bus %d Device %d PCI Address 0x%X\n", NULL, Bus, Device, PCI_Address);
			continue;
		}
		if (IRQ_Channel == 0) {
			BusLogic_Error("BusLogic: IRQ Channel %d invalid for " "FlashPoint Host Adapter\n", NULL, IRQ_Channel);
			BusLogic_Error("at PCI Bus %d Device %d I/O Address 0x%X\n", NULL, Bus, Device, IO_Address);
			continue;
		}
		if (BusLogic_GlobalOptions.TraceProbe) {
			BusLogic_Notice("BusLogic: FlashPoint Host Adapter " "detected at\n", NULL);
			BusLogic_Notice("BusLogic: PCI Bus %d Device %d I/O Address " "0x%X PCI Address 0x%X\n", NULL, Bus, Device, IO_Address, PCI_Address);
		}
		if (BusLogic_ProbeInfoCount < BusLogic_MaxHostAdapters) {
			struct BusLogic_ProbeInfo *ProbeInfo = &BusLogic_ProbeInfoList[BusLogic_ProbeInfoCount++];
			ProbeInfo->HostAdapterType = BusLogic_FlashPoint;
			ProbeInfo->HostAdapterBusType = BusLogic_PCI_Bus;
			ProbeInfo->IO_Address = IO_Address;
			ProbeInfo->PCI_Address = PCI_Address;
			ProbeInfo->Bus = Bus;
			ProbeInfo->Device = Device;
			ProbeInfo->IRQ_Channel = IRQ_Channel;
			ProbeInfo->PCI_Device = pci_dev_get(PCI_Device);
			FlashPointCount++;
		} else
			BusLogic_Warning("BusLogic: Too many Host Adapters " "detected\n", NULL);
#else
		BusLogic_Error("BusLogic: FlashPoint Host Adapter detected at " "PCI Bus %d Device %d\n", NULL, Bus, Device);
		BusLogic_Error("BusLogic: I/O Address 0x%X PCI Address 0x%X, irq %d, " "but FlashPoint\n", NULL, IO_Address, PCI_Address, IRQ_Channel);
		BusLogic_Error("BusLogic: support was omitted in this kernel " "configuration.\n", NULL);
#endif
	}
	/*
	   The FlashPoint BIOS will scan for FlashPoint Host Adapters in the order of
	   increasing PCI Bus and Device Number, so sort the probe information into
	   the same order the BIOS uses.
	 */
	BusLogic_SortProbeInfo(&BusLogic_ProbeInfoList[FlashPointIndex], FlashPointCount);
	return FlashPointCount;
}


/*
  BusLogic_InitializeProbeInfoList initializes the list of I/O Address and Bus
  Probe Information to be checked for potential BusLogic SCSI Host Adapters by
  interrogating the PCI Configuration Space on PCI machines as well as from the
  list of standard BusLogic MultiMaster ISA I/O Addresses.  By default, if both
  FlashPoint and PCI MultiMaster Host Adapters are present, this driver will
  probe for FlashPoint Host Adapters first unless the BIOS primary disk is
  controlled by the first PCI MultiMaster Host Adapter, in which case
  MultiMaster Host Adapters will be probed first.  The BusLogic Driver Options
  specifications "MultiMasterFirst" and "FlashPointFirst" can be used to force
  a particular probe order.
*/

static void __init BusLogic_InitializeProbeInfoList(struct BusLogic_HostAdapter
						    *PrototypeHostAdapter)
{
	/*
	   If a PCI BIOS is present, interrogate it for MultiMaster and FlashPoint
	   Host Adapters; otherwise, default to the standard ISA MultiMaster probe.
	 */
	if (!BusLogic_ProbeOptions.NoProbePCI) {
		if (BusLogic_ProbeOptions.MultiMasterFirst) {
			BusLogic_InitializeMultiMasterProbeInfo(PrototypeHostAdapter);
			BusLogic_InitializeFlashPointProbeInfo(PrototypeHostAdapter);
		} else if (BusLogic_ProbeOptions.FlashPointFirst) {
			BusLogic_InitializeFlashPointProbeInfo(PrototypeHostAdapter);
			BusLogic_InitializeMultiMasterProbeInfo(PrototypeHostAdapter);
		} else {
			int FlashPointCount = BusLogic_InitializeFlashPointProbeInfo(PrototypeHostAdapter);
			int PCIMultiMasterCount = BusLogic_InitializeMultiMasterProbeInfo(PrototypeHostAdapter);
			if (FlashPointCount > 0 && PCIMultiMasterCount > 0) {
				struct BusLogic_ProbeInfo *ProbeInfo = &BusLogic_ProbeInfoList[FlashPointCount];
				struct BusLogic_HostAdapter *HostAdapter = PrototypeHostAdapter;
				struct BusLogic_FetchHostAdapterLocalRAMRequest FetchHostAdapterLocalRAMRequest;
				struct BusLogic_BIOSDriveMapByte Drive0MapByte;
				while (ProbeInfo->HostAdapterBusType != BusLogic_PCI_Bus)
					ProbeInfo++;
				HostAdapter->IO_Address = ProbeInfo->IO_Address;
				FetchHostAdapterLocalRAMRequest.ByteOffset = BusLogic_BIOS_BaseOffset + BusLogic_BIOS_DriveMapOffset + 0;
				FetchHostAdapterLocalRAMRequest.ByteCount = sizeof(Drive0MapByte);
				BusLogic_Command(HostAdapter, BusLogic_FetchHostAdapterLocalRAM, &FetchHostAdapterLocalRAMRequest, sizeof(FetchHostAdapterLocalRAMRequest), &Drive0MapByte, sizeof(Drive0MapByte));
				/*
				   If the Map Byte for BIOS Drive 0 indicates that BIOS Drive 0
				   is controlled by this PCI MultiMaster Host Adapter, then
				   reverse the probe order so that MultiMaster Host Adapters are
				   probed before FlashPoint Host Adapters.
				 */
				if (Drive0MapByte.DiskGeometry != BusLogic_BIOS_Disk_Not_Installed) {
					struct BusLogic_ProbeInfo SavedProbeInfo[BusLogic_MaxHostAdapters];
					int MultiMasterCount = BusLogic_ProbeInfoCount - FlashPointCount;
					memcpy(SavedProbeInfo, BusLogic_ProbeInfoList, BusLogic_ProbeInfoCount * sizeof(struct BusLogic_ProbeInfo));
					memcpy(&BusLogic_ProbeInfoList[0], &SavedProbeInfo[FlashPointCount], MultiMasterCount * sizeof(struct BusLogic_ProbeInfo));
					memcpy(&BusLogic_ProbeInfoList[MultiMasterCount], &SavedProbeInfo[0], FlashPointCount * sizeof(struct BusLogic_ProbeInfo));
				}
			}
		}
	} else
		BusLogic_InitializeProbeInfoListISA(PrototypeHostAdapter);
}


#else
#define BusLogic_InitializeProbeInfoList(adapter) \
		BusLogic_InitializeProbeInfoListISA(adapter)
#endif				/* CONFIG_PCI */


/*
  BusLogic_Failure prints a standardized error message, and then returns false.
*/

static bool BusLogic_Failure(struct BusLogic_HostAdapter *HostAdapter, char *ErrorMessage)
{
	BusLogic_AnnounceDriver(HostAdapter);
	if (HostAdapter->HostAdapterBusType == BusLogic_PCI_Bus) {
		BusLogic_Error("While configuring BusLogic PCI Host Adapter at\n", HostAdapter);
		BusLogic_Error("Bus %d Device %d I/O Address 0x%X PCI Address 0x%X:\n", HostAdapter, HostAdapter->Bus, HostAdapter->Device, HostAdapter->IO_Address, HostAdapter->PCI_Address);
	} else
		BusLogic_Error("While configuring BusLogic Host Adapter at " "I/O Address 0x%X:\n", HostAdapter, HostAdapter->IO_Address);
	BusLogic_Error("%s FAILED - DETACHING\n", HostAdapter, ErrorMessage);
	if (BusLogic_CommandFailureReason != NULL)
		BusLogic_Error("ADDITIONAL FAILURE INFO - %s\n", HostAdapter, BusLogic_CommandFailureReason);
	return false;
}


/*
  BusLogic_ProbeHostAdapter probes for a BusLogic Host Adapter.
*/

static bool __init BusLogic_ProbeHostAdapter(struct BusLogic_HostAdapter *HostAdapter)
{
	union BusLogic_StatusRegister StatusRegister;
	union BusLogic_InterruptRegister InterruptRegister;
	union BusLogic_GeometryRegister GeometryRegister;
	/*
	   FlashPoint Host Adapters are Probed by the FlashPoint SCCB Manager.
	 */
	if (BusLogic_FlashPointHostAdapterP(HostAdapter)) {
		struct FlashPoint_Info *FlashPointInfo = &HostAdapter->FlashPointInfo;
		FlashPointInfo->BaseAddress = (u32) HostAdapter->IO_Address;
		FlashPointInfo->IRQ_Channel = HostAdapter->IRQ_Channel;
		FlashPointInfo->Present = false;
		if (!(FlashPoint_ProbeHostAdapter(FlashPointInfo) == 0 && FlashPointInfo->Present)) {
			BusLogic_Error("BusLogic: FlashPoint Host Adapter detected at " "PCI Bus %d Device %d\n", HostAdapter, HostAdapter->Bus, HostAdapter->Device);
			BusLogic_Error("BusLogic: I/O Address 0x%X PCI Address 0x%X, " "but FlashPoint\n", HostAdapter, HostAdapter->IO_Address, HostAdapter->PCI_Address);
			BusLogic_Error("BusLogic: Probe Function failed to validate it.\n", HostAdapter);
			return false;
		}
		if (BusLogic_GlobalOptions.TraceProbe)
			BusLogic_Notice("BusLogic_Probe(0x%X): FlashPoint Found\n", HostAdapter, HostAdapter->IO_Address);
		/*
		   Indicate the Host Adapter Probe completed successfully.
		 */
		return true;
	}
	/*
	   Read the Status, Interrupt, and Geometry Registers to test if there are I/O
	   ports that respond, and to check the values to determine if they are from a
	   BusLogic Host Adapter.  A nonexistent I/O port will return 0xFF, in which
	   case there is definitely no BusLogic Host Adapter at this base I/O Address.
	   The test here is a subset of that used by the BusLogic Host Adapter BIOS.
	 */
	StatusRegister.All = BusLogic_ReadStatusRegister(HostAdapter);
	InterruptRegister.All = BusLogic_ReadInterruptRegister(HostAdapter);
	GeometryRegister.All = BusLogic_ReadGeometryRegister(HostAdapter);
	if (BusLogic_GlobalOptions.TraceProbe)
		BusLogic_Notice("BusLogic_Probe(0x%X): Status 0x%02X, Interrupt 0x%02X, " "Geometry 0x%02X\n", HostAdapter, HostAdapter->IO_Address, StatusRegister.All, InterruptRegister.All, GeometryRegister.All);
	if (StatusRegister.All == 0 || StatusRegister.sr.DiagnosticActive || StatusRegister.sr.CommandParameterRegisterBusy || StatusRegister.sr.Reserved || StatusRegister.sr.CommandInvalid || InterruptRegister.ir.Reserved != 0)
		return false;
	/*
	   Check the undocumented Geometry Register to test if there is an I/O port
	   that responded.  Adaptec Host Adapters do not implement the Geometry
	   Register, so this test helps serve to avoid incorrectly recognizing an
	   Adaptec 1542A or 1542B as a BusLogic.  Unfortunately, the Adaptec 1542C
	   series does respond to the Geometry Register I/O port, but it will be
	   rejected later when the Inquire Extended Setup Information command is
	   issued in BusLogic_CheckHostAdapter.  The AMI FastDisk Host Adapter is a
	   BusLogic clone that implements the same interface as earlier BusLogic
	   Host Adapters, including the undocumented commands, and is therefore
	   supported by this driver.  However, the AMI FastDisk always returns 0x00
	   upon reading the Geometry Register, so the extended translation option
	   should always be left disabled on the AMI FastDisk.
	 */
	if (GeometryRegister.All == 0xFF)
		return false;
	/*
	   Indicate the Host Adapter Probe completed successfully.
	 */
	return true;
}


/*
  BusLogic_HardwareResetHostAdapter issues a Hardware Reset to the Host Adapter
  and waits for Host Adapter Diagnostics to complete.  If HardReset is true, a
  Hard Reset is performed which also initiates a SCSI Bus Reset.  Otherwise, a
  Soft Reset is performed which only resets the Host Adapter without forcing a
  SCSI Bus Reset.
*/

static bool BusLogic_HardwareResetHostAdapter(struct BusLogic_HostAdapter
						 *HostAdapter, bool HardReset)
{
	union BusLogic_StatusRegister StatusRegister;
	int TimeoutCounter;
	/*
	   FlashPoint Host Adapters are Hard Reset by the FlashPoint SCCB Manager.
	 */
	if (BusLogic_FlashPointHostAdapterP(HostAdapter)) {
		struct FlashPoint_Info *FlashPointInfo = &HostAdapter->FlashPointInfo;
		FlashPointInfo->HostSoftReset = !HardReset;
		FlashPointInfo->ReportDataUnderrun = true;
		HostAdapter->CardHandle = FlashPoint_HardwareResetHostAdapter(FlashPointInfo);
		if (HostAdapter->CardHandle == FlashPoint_BadCardHandle)
			return false;
		/*
		   Indicate the Host Adapter Hard Reset completed successfully.
		 */
		return true;
	}
	/*
	   Issue a Hard Reset or Soft Reset Command to the Host Adapter.  The Host
	   Adapter should respond by setting Diagnostic Active in the Status Register.
	 */
	if (HardReset)
		BusLogic_HardReset(HostAdapter);
	else
		BusLogic_SoftReset(HostAdapter);
	/*
	   Wait until Diagnostic Active is set in the Status Register.
	 */
	TimeoutCounter = 5 * 10000;
	while (--TimeoutCounter >= 0) {
		StatusRegister.All = BusLogic_ReadStatusRegister(HostAdapter);
		if (StatusRegister.sr.DiagnosticActive)
			break;
		udelay(100);
	}
	if (BusLogic_GlobalOptions.TraceHardwareReset)
		BusLogic_Notice("BusLogic_HardwareReset(0x%X): Diagnostic Active, " "Status 0x%02X\n", HostAdapter, HostAdapter->IO_Address, StatusRegister.All);
	if (TimeoutCounter < 0)
		return false;
	/*
	   Wait 100 microseconds to allow completion of any initial diagnostic
	   activity which might leave the contents of the Status Register
	   unpredictable.
	 */
	udelay(100);
	/*
	   Wait until Diagnostic Active is reset in the Status Register.
	 */
	TimeoutCounter = 10 * 10000;
	while (--TimeoutCounter >= 0) {
		StatusRegister.All = BusLogic_ReadStatusRegister(HostAdapter);
		if (!StatusRegister.sr.DiagnosticActive)
			break;
		udelay(100);
	}
	if (BusLogic_GlobalOptions.TraceHardwareReset)
		BusLogic_Notice("BusLogic_HardwareReset(0x%X): Diagnostic Completed, " "Status 0x%02X\n", HostAdapter, HostAdapter->IO_Address, StatusRegister.All);
	if (TimeoutCounter < 0)
		return false;
	/*
	   Wait until at least one of the Diagnostic Failure, Host Adapter Ready,
	   or Data In Register Ready bits is set in the Status Register.
	 */
	TimeoutCounter = 10000;
	while (--TimeoutCounter >= 0) {
		StatusRegister.All = BusLogic_ReadStatusRegister(HostAdapter);
		if (StatusRegister.sr.DiagnosticFailure || StatusRegister.sr.HostAdapterReady || StatusRegister.sr.DataInRegisterReady)
			break;
		udelay(100);
	}
	if (BusLogic_GlobalOptions.TraceHardwareReset)
		BusLogic_Notice("BusLogic_HardwareReset(0x%X): Host Adapter Ready, " "Status 0x%02X\n", HostAdapter, HostAdapter->IO_Address, StatusRegister.All);
	if (TimeoutCounter < 0)
		return false;
	/*
	   If Diagnostic Failure is set or Host Adapter Ready is reset, then an
	   error occurred during the Host Adapter diagnostics.  If Data In Register
	   Ready is set, then there is an Error Code available.
	 */
	if (StatusRegister.sr.DiagnosticFailure || !StatusRegister.sr.HostAdapterReady) {
		BusLogic_CommandFailureReason = NULL;
		BusLogic_Failure(HostAdapter, "HARD RESET DIAGNOSTICS");
		BusLogic_Error("HOST ADAPTER STATUS REGISTER = %02X\n", HostAdapter, StatusRegister.All);
		if (StatusRegister.sr.DataInRegisterReady) {
			unsigned char ErrorCode = BusLogic_ReadDataInRegister(HostAdapter);
			BusLogic_Error("HOST ADAPTER ERROR CODE = %d\n", HostAdapter, ErrorCode);
		}
		return false;
	}
	/*
	   Indicate the Host Adapter Hard Reset completed successfully.
	 */
	return true;
}


/*
  BusLogic_CheckHostAdapter checks to be sure this really is a BusLogic
  Host Adapter.
*/

static bool __init BusLogic_CheckHostAdapter(struct BusLogic_HostAdapter *HostAdapter)
{
	struct BusLogic_ExtendedSetupInformation ExtendedSetupInformation;
	unsigned char RequestedReplyLength;
	bool Result = true;
	/*
	   FlashPoint Host Adapters do not require this protection.
	 */
	if (BusLogic_FlashPointHostAdapterP(HostAdapter))
		return true;
	/*
	   Issue the Inquire Extended Setup Information command.  Only genuine
	   BusLogic Host Adapters and true clones support this command.  Adaptec 1542C
	   series Host Adapters that respond to the Geometry Register I/O port will
	   fail this command.
	 */
	RequestedReplyLength = sizeof(ExtendedSetupInformation);
	if (BusLogic_Command(HostAdapter, BusLogic_InquireExtendedSetupInformation, &RequestedReplyLength, sizeof(RequestedReplyLength), &ExtendedSetupInformation, sizeof(ExtendedSetupInformation))
	    != sizeof(ExtendedSetupInformation))
		Result = false;
	/*
	   Provide tracing information if requested and return.
	 */
	if (BusLogic_GlobalOptions.TraceProbe)
		BusLogic_Notice("BusLogic_Check(0x%X): MultiMaster %s\n", HostAdapter, HostAdapter->IO_Address, (Result ? "Found" : "Not Found"));
	return Result;
}


/*
  BusLogic_ReadHostAdapterConfiguration reads the Configuration Information
  from Host Adapter and initializes the Host Adapter structure.
*/

static bool __init BusLogic_ReadHostAdapterConfiguration(struct BusLogic_HostAdapter
							    *HostAdapter)
{
	struct BusLogic_BoardID BoardID;
	struct BusLogic_Configuration Configuration;
	struct BusLogic_SetupInformation SetupInformation;
	struct BusLogic_ExtendedSetupInformation ExtendedSetupInformation;
	unsigned char HostAdapterModelNumber[5];
	unsigned char FirmwareVersion3rdDigit;
	unsigned char FirmwareVersionLetter;
	struct BusLogic_PCIHostAdapterInformation PCIHostAdapterInformation;
	struct BusLogic_FetchHostAdapterLocalRAMRequest FetchHostAdapterLocalRAMRequest;
	struct BusLogic_AutoSCSIData AutoSCSIData;
	union BusLogic_GeometryRegister GeometryRegister;
	unsigned char RequestedReplyLength;
	unsigned char *TargetPointer, Character;
	int TargetID, i;
	/*
	   Configuration Information for FlashPoint Host Adapters is provided in the
	   FlashPoint_Info structure by the FlashPoint SCCB Manager's Probe Function.
	   Initialize fields in the Host Adapter structure from the FlashPoint_Info
	   structure.
	 */
	if (BusLogic_FlashPointHostAdapterP(HostAdapter)) {
		struct FlashPoint_Info *FlashPointInfo = &HostAdapter->FlashPointInfo;
		TargetPointer = HostAdapter->ModelName;
		*TargetPointer++ = 'B';
		*TargetPointer++ = 'T';
		*TargetPointer++ = '-';
		for (i = 0; i < sizeof(FlashPointInfo->ModelNumber); i++)
			*TargetPointer++ = FlashPointInfo->ModelNumber[i];
		*TargetPointer++ = '\0';
		strcpy(HostAdapter->FirmwareVersion, FlashPoint_FirmwareVersion);
		HostAdapter->SCSI_ID = FlashPointInfo->SCSI_ID;
		HostAdapter->ExtendedTranslationEnabled = FlashPointInfo->ExtendedTranslationEnabled;
		HostAdapter->ParityCheckingEnabled = FlashPointInfo->ParityCheckingEnabled;
		HostAdapter->BusResetEnabled = !FlashPointInfo->HostSoftReset;
		HostAdapter->LevelSensitiveInterrupt = true;
		HostAdapter->HostWideSCSI = FlashPointInfo->HostWideSCSI;
		HostAdapter->HostDifferentialSCSI = false;
		HostAdapter->HostSupportsSCAM = true;
		HostAdapter->HostUltraSCSI = true;
		HostAdapter->ExtendedLUNSupport = true;
		HostAdapter->TerminationInfoValid = true;
		HostAdapter->LowByteTerminated = FlashPointInfo->LowByteTerminated;
		HostAdapter->HighByteTerminated = FlashPointInfo->HighByteTerminated;
		HostAdapter->SCAM_Enabled = FlashPointInfo->SCAM_Enabled;
		HostAdapter->SCAM_Level2 = FlashPointInfo->SCAM_Level2;
		HostAdapter->DriverScatterGatherLimit = BusLogic_ScatterGatherLimit;
		HostAdapter->MaxTargetDevices = (HostAdapter->HostWideSCSI ? 16 : 8);
		HostAdapter->MaxLogicalUnits = 32;
		HostAdapter->InitialCCBs = 4 * BusLogic_CCB_AllocationGroupSize;
		HostAdapter->IncrementalCCBs = BusLogic_CCB_AllocationGroupSize;
		HostAdapter->DriverQueueDepth = 255;
		HostAdapter->HostAdapterQueueDepth = HostAdapter->DriverQueueDepth;
		HostAdapter->SynchronousPermitted = FlashPointInfo->SynchronousPermitted;
		HostAdapter->FastPermitted = FlashPointInfo->FastPermitted;
		HostAdapter->UltraPermitted = FlashPointInfo->UltraPermitted;
		HostAdapter->WidePermitted = FlashPointInfo->WidePermitted;
		HostAdapter->DisconnectPermitted = FlashPointInfo->DisconnectPermitted;
		HostAdapter->TaggedQueuingPermitted = 0xFFFF;
		goto Common;
	}
	/*
	   Issue the Inquire Board ID command.
	 */
	if (BusLogic_Command(HostAdapter, BusLogic_InquireBoardID, NULL, 0, &BoardID, sizeof(BoardID)) != sizeof(BoardID))
		return BusLogic_Failure(HostAdapter, "INQUIRE BOARD ID");
	/*
	   Issue the Inquire Configuration command.
	 */
	if (BusLogic_Command(HostAdapter, BusLogic_InquireConfiguration, NULL, 0, &Configuration, sizeof(Configuration))
	    != sizeof(Configuration))
		return BusLogic_Failure(HostAdapter, "INQUIRE CONFIGURATION");
	/*
	   Issue the Inquire Setup Information command.
	 */
	RequestedReplyLength = sizeof(SetupInformation);
	if (BusLogic_Command(HostAdapter, BusLogic_InquireSetupInformation, &RequestedReplyLength, sizeof(RequestedReplyLength), &SetupInformation, sizeof(SetupInformation))
	    != sizeof(SetupInformation))
		return BusLogic_Failure(HostAdapter, "INQUIRE SETUP INFORMATION");
	/*
	   Issue the Inquire Extended Setup Information command.
	 */
	RequestedReplyLength = sizeof(ExtendedSetupInformation);
	if (BusLogic_Command(HostAdapter, BusLogic_InquireExtendedSetupInformation, &RequestedReplyLength, sizeof(RequestedReplyLength), &ExtendedSetupInformation, sizeof(ExtendedSetupInformation))
	    != sizeof(ExtendedSetupInformation))
		return BusLogic_Failure(HostAdapter, "INQUIRE EXTENDED SETUP INFORMATION");
	/*
	   Issue the Inquire Firmware Version 3rd Digit command.
	 */
	FirmwareVersion3rdDigit = '\0';
	if (BoardID.FirmwareVersion1stDigit > '0')
		if (BusLogic_Command(HostAdapter, BusLogic_InquireFirmwareVersion3rdDigit, NULL, 0, &FirmwareVersion3rdDigit, sizeof(FirmwareVersion3rdDigit))
		    != sizeof(FirmwareVersion3rdDigit))
			return BusLogic_Failure(HostAdapter, "INQUIRE FIRMWARE 3RD DIGIT");
	/*
	   Issue the Inquire Host Adapter Model Number command.
	 */
	if (ExtendedSetupInformation.BusType == 'A' && BoardID.FirmwareVersion1stDigit == '2')
		/* BusLogic BT-542B ISA 2.xx */
		strcpy(HostAdapterModelNumber, "542B");
	else if (ExtendedSetupInformation.BusType == 'E' && BoardID.FirmwareVersion1stDigit == '2' && (BoardID.FirmwareVersion2ndDigit <= '1' || (BoardID.FirmwareVersion2ndDigit == '2' && FirmwareVersion3rdDigit == '0')))
		/* BusLogic BT-742A EISA 2.1x or 2.20 */
		strcpy(HostAdapterModelNumber, "742A");
	else if (ExtendedSetupInformation.BusType == 'E' && BoardID.FirmwareVersion1stDigit == '0')
		/* AMI FastDisk EISA Series 441 0.x */
		strcpy(HostAdapterModelNumber, "747A");
	else {
		RequestedReplyLength = sizeof(HostAdapterModelNumber);
		if (BusLogic_Command(HostAdapter, BusLogic_InquireHostAdapterModelNumber, &RequestedReplyLength, sizeof(RequestedReplyLength), &HostAdapterModelNumber, sizeof(HostAdapterModelNumber))
		    != sizeof(HostAdapterModelNumber))
			return BusLogic_Failure(HostAdapter, "INQUIRE HOST ADAPTER MODEL NUMBER");
	}
	/*
	   BusLogic MultiMaster Host Adapters can be identified by their model number
	   and the major version number of their firmware as follows:

	   5.xx       BusLogic "W" Series Host Adapters:
	   BT-948/958/958D
	   4.xx       BusLogic "C" Series Host Adapters:
	   BT-946C/956C/956CD/747C/757C/757CD/445C/545C/540CF
	   3.xx       BusLogic "S" Series Host Adapters:
	   BT-747S/747D/757S/757D/445S/545S/542D
	   BT-542B/742A (revision H)
	   2.xx       BusLogic "A" Series Host Adapters:
	   BT-542B/742A (revision G and below)
	   0.xx       AMI FastDisk VLB/EISA BusLogic Clone Host Adapter
	 */
	/*
	   Save the Model Name and Host Adapter Name in the Host Adapter structure.
	 */
	TargetPointer = HostAdapter->ModelName;
	*TargetPointer++ = 'B';
	*TargetPointer++ = 'T';
	*TargetPointer++ = '-';
	for (i = 0; i < sizeof(HostAdapterModelNumber); i++) {
		Character = HostAdapterModelNumber[i];
		if (Character == ' ' || Character == '\0')
			break;
		*TargetPointer++ = Character;
	}
	*TargetPointer++ = '\0';
	/*
	   Save the Firmware Version in the Host Adapter structure.
	 */
	TargetPointer = HostAdapter->FirmwareVersion;
	*TargetPointer++ = BoardID.FirmwareVersion1stDigit;
	*TargetPointer++ = '.';
	*TargetPointer++ = BoardID.FirmwareVersion2ndDigit;
	if (FirmwareVersion3rdDigit != ' ' && FirmwareVersion3rdDigit != '\0')
		*TargetPointer++ = FirmwareVersion3rdDigit;
	*TargetPointer = '\0';
	/*
	   Issue the Inquire Firmware Version Letter command.
	 */
	if (strcmp(HostAdapter->FirmwareVersion, "3.3") >= 0) {
		if (BusLogic_Command(HostAdapter, BusLogic_InquireFirmwareVersionLetter, NULL, 0, &FirmwareVersionLetter, sizeof(FirmwareVersionLetter))
		    != sizeof(FirmwareVersionLetter))
			return BusLogic_Failure(HostAdapter, "INQUIRE FIRMWARE VERSION LETTER");
		if (FirmwareVersionLetter != ' ' && FirmwareVersionLetter != '\0')
			*TargetPointer++ = FirmwareVersionLetter;
		*TargetPointer = '\0';
	}
	/*
	   Save the Host Adapter SCSI ID in the Host Adapter structure.
	 */
	HostAdapter->SCSI_ID = Configuration.HostAdapterID;
	/*
	   Determine the Bus Type and save it in the Host Adapter structure, determine
	   and save the IRQ Channel if necessary, and determine and save the DMA
	   Channel for ISA Host Adapters.
	 */
	HostAdapter->HostAdapterBusType = BusLogic_HostAdapterBusTypes[HostAdapter->ModelName[3] - '4'];
	if (HostAdapter->IRQ_Channel == 0) {
		if (Configuration.IRQ_Channel9)
			HostAdapter->IRQ_Channel = 9;
		else if (Configuration.IRQ_Channel10)
			HostAdapter->IRQ_Channel = 10;
		else if (Configuration.IRQ_Channel11)
			HostAdapter->IRQ_Channel = 11;
		else if (Configuration.IRQ_Channel12)
			HostAdapter->IRQ_Channel = 12;
		else if (Configuration.IRQ_Channel14)
			HostAdapter->IRQ_Channel = 14;
		else if (Configuration.IRQ_Channel15)
			HostAdapter->IRQ_Channel = 15;
	}
	if (HostAdapter->HostAdapterBusType == BusLogic_ISA_Bus) {
		if (Configuration.DMA_Channel5)
			HostAdapter->DMA_Channel = 5;
		else if (Configuration.DMA_Channel6)
			HostAdapter->DMA_Channel = 6;
		else if (Configuration.DMA_Channel7)
			HostAdapter->DMA_Channel = 7;
	}
	/*
	   Determine whether Extended Translation is enabled and save it in
	   the Host Adapter structure.
	 */
	GeometryRegister.All = BusLogic_ReadGeometryRegister(HostAdapter);
	HostAdapter->ExtendedTranslationEnabled = GeometryRegister.gr.ExtendedTranslationEnabled;
	/*
	   Save the Scatter Gather Limits, Level Sensitive Interrupt flag, Wide
	   SCSI flag, Differential SCSI flag, SCAM Supported flag, and
	   Ultra SCSI flag in the Host Adapter structure.
	 */
	HostAdapter->HostAdapterScatterGatherLimit = ExtendedSetupInformation.ScatterGatherLimit;
	HostAdapter->DriverScatterGatherLimit = HostAdapter->HostAdapterScatterGatherLimit;
	if (HostAdapter->HostAdapterScatterGatherLimit > BusLogic_ScatterGatherLimit)
		HostAdapter->DriverScatterGatherLimit = BusLogic_ScatterGatherLimit;
	if (ExtendedSetupInformation.Misc.LevelSensitiveInterrupt)
		HostAdapter->LevelSensitiveInterrupt = true;
	HostAdapter->HostWideSCSI = ExtendedSetupInformation.HostWideSCSI;
	HostAdapter->HostDifferentialSCSI = ExtendedSetupInformation.HostDifferentialSCSI;
	HostAdapter->HostSupportsSCAM = ExtendedSetupInformation.HostSupportsSCAM;
	HostAdapter->HostUltraSCSI = ExtendedSetupInformation.HostUltraSCSI;
	/*
	   Determine whether Extended LUN Format CCBs are supported and save the
	   information in the Host Adapter structure.
	 */
	if (HostAdapter->FirmwareVersion[0] == '5' || (HostAdapter->FirmwareVersion[0] == '4' && HostAdapter->HostWideSCSI))
		HostAdapter->ExtendedLUNSupport = true;
	/*
	   Issue the Inquire PCI Host Adapter Information command to read the
	   Termination Information from "W" series MultiMaster Host Adapters.
	 */
	if (HostAdapter->FirmwareVersion[0] == '5') {
		if (BusLogic_Command(HostAdapter, BusLogic_InquirePCIHostAdapterInformation, NULL, 0, &PCIHostAdapterInformation, sizeof(PCIHostAdapterInformation))
		    != sizeof(PCIHostAdapterInformation))
			return BusLogic_Failure(HostAdapter, "INQUIRE PCI HOST ADAPTER INFORMATION");
		/*
		   Save the Termination Information in the Host Adapter structure.
		 */
		if (PCIHostAdapterInformation.GenericInfoValid) {
			HostAdapter->TerminationInfoValid = true;
			HostAdapter->LowByteTerminated = PCIHostAdapterInformation.LowByteTerminated;
			HostAdapter->HighByteTerminated = PCIHostAdapterInformation.HighByteTerminated;
		}
	}
	/*
	   Issue the Fetch Host Adapter Local RAM command to read the AutoSCSI data
	   from "W" and "C" series MultiMaster Host Adapters.
	 */
	if (HostAdapter->FirmwareVersion[0] >= '4') {
		FetchHostAdapterLocalRAMRequest.ByteOffset = BusLogic_AutoSCSI_BaseOffset;
		FetchHostAdapterLocalRAMRequest.ByteCount = sizeof(AutoSCSIData);
		if (BusLogic_Command(HostAdapter, BusLogic_FetchHostAdapterLocalRAM, &FetchHostAdapterLocalRAMRequest, sizeof(FetchHostAdapterLocalRAMRequest), &AutoSCSIData, sizeof(AutoSCSIData))
		    != sizeof(AutoSCSIData))
			return BusLogic_Failure(HostAdapter, "FETCH HOST ADAPTER LOCAL RAM");
		/*
		   Save the Parity Checking Enabled, Bus Reset Enabled, and Termination
		   Information in the Host Adapter structure.
		 */
		HostAdapter->ParityCheckingEnabled = AutoSCSIData.ParityCheckingEnabled;
		HostAdapter->BusResetEnabled = AutoSCSIData.BusResetEnabled;
		if (HostAdapter->FirmwareVersion[0] == '4') {
			HostAdapter->TerminationInfoValid = true;
			HostAdapter->LowByteTerminated = AutoSCSIData.LowByteTerminated;
			HostAdapter->HighByteTerminated = AutoSCSIData.HighByteTerminated;
		}
		/*
		   Save the Wide Permitted, Fast Permitted, Synchronous Permitted,
		   Disconnect Permitted, Ultra Permitted, and SCAM Information in the
		   Host Adapter structure.
		 */
		HostAdapter->WidePermitted = AutoSCSIData.WidePermitted;
		HostAdapter->FastPermitted = AutoSCSIData.FastPermitted;
		HostAdapter->SynchronousPermitted = AutoSCSIData.SynchronousPermitted;
		HostAdapter->DisconnectPermitted = AutoSCSIData.DisconnectPermitted;
		if (HostAdapter->HostUltraSCSI)
			HostAdapter->UltraPermitted = AutoSCSIData.UltraPermitted;
		if (HostAdapter->HostSupportsSCAM) {
			HostAdapter->SCAM_Enabled = AutoSCSIData.SCAM_Enabled;
			HostAdapter->SCAM_Level2 = AutoSCSIData.SCAM_Level2;
		}
	}
	/*
	   Initialize fields in the Host Adapter structure for "S" and "A" series
	   MultiMaster Host Adapters.
	 */
	if (HostAdapter->FirmwareVersion[0] < '4') {
		if (SetupInformation.SynchronousInitiationEnabled) {
			HostAdapter->SynchronousPermitted = 0xFF;
			if (HostAdapter->HostAdapterBusType == BusLogic_EISA_Bus) {
				if (ExtendedSetupInformation.Misc.FastOnEISA)
					HostAdapter->FastPermitted = 0xFF;
				if (strcmp(HostAdapter->ModelName, "BT-757") == 0)
					HostAdapter->WidePermitted = 0xFF;
			}
		}
		HostAdapter->DisconnectPermitted = 0xFF;
		HostAdapter->ParityCheckingEnabled = SetupInformation.ParityCheckingEnabled;
		HostAdapter->BusResetEnabled = true;
	}
	/*
	   Determine the maximum number of Target IDs and Logical Units supported by
	   this driver for Wide and Narrow Host Adapters.
	 */
	HostAdapter->MaxTargetDevices = (HostAdapter->HostWideSCSI ? 16 : 8);
	HostAdapter->MaxLogicalUnits = (HostAdapter->ExtendedLUNSupport ? 32 : 8);
	/*
	   Select appropriate values for the Mailbox Count, Driver Queue Depth,
	   Initial CCBs, and Incremental CCBs variables based on whether or not Strict
	   Round Robin Mode is supported.  If Strict Round Robin Mode is supported,
	   then there is no performance degradation in using the maximum possible
	   number of Outgoing and Incoming Mailboxes and allowing the Tagged and
	   Untagged Queue Depths to determine the actual utilization.  If Strict Round
	   Robin Mode is not supported, then the Host Adapter must scan all the
	   Outgoing Mailboxes whenever an Outgoing Mailbox entry is made, which can
	   cause a substantial performance penalty.  The host adapters actually have
	   room to store the following number of CCBs internally; that is, they can
	   internally queue and manage this many active commands on the SCSI bus
	   simultaneously.  Performance measurements demonstrate that the Driver Queue
	   Depth should be set to the Mailbox Count, rather than the Host Adapter
	   Queue Depth (internal CCB capacity), as it is more efficient to have the
	   queued commands waiting in Outgoing Mailboxes if necessary than to block
	   the process in the higher levels of the SCSI Subsystem.

	   192          BT-948/958/958D
	   100          BT-946C/956C/956CD/747C/757C/757CD/445C
	   50   BT-545C/540CF
	   30   BT-747S/747D/757S/757D/445S/545S/542D/542B/742A
	 */
	if (HostAdapter->FirmwareVersion[0] == '5')
		HostAdapter->HostAdapterQueueDepth = 192;
	else if (HostAdapter->FirmwareVersion[0] == '4')
		HostAdapter->HostAdapterQueueDepth = (HostAdapter->HostAdapterBusType != BusLogic_ISA_Bus ? 100 : 50);
	else
		HostAdapter->HostAdapterQueueDepth = 30;
	if (strcmp(HostAdapter->FirmwareVersion, "3.31") >= 0) {
		HostAdapter->StrictRoundRobinModeSupport = true;
		HostAdapter->MailboxCount = BusLogic_MaxMailboxes;
	} else {
		HostAdapter->StrictRoundRobinModeSupport = false;
		HostAdapter->MailboxCount = 32;
	}
	HostAdapter->DriverQueueDepth = HostAdapter->MailboxCount;
	HostAdapter->InitialCCBs = 4 * BusLogic_CCB_AllocationGroupSize;
	HostAdapter->IncrementalCCBs = BusLogic_CCB_AllocationGroupSize;
	/*
	   Tagged Queuing support is available and operates properly on all "W" series
	   MultiMaster Host Adapters, on "C" series MultiMaster Host Adapters with
	   firmware version 4.22 and above, and on "S" series MultiMaster Host
	   Adapters with firmware version 3.35 and above.
	 */
	HostAdapter->TaggedQueuingPermitted = 0;
	switch (HostAdapter->FirmwareVersion[0]) {
	case '5':
		HostAdapter->TaggedQueuingPermitted = 0xFFFF;
		break;
	case '4':
		if (strcmp(HostAdapter->FirmwareVersion, "4.22") >= 0)
			HostAdapter->TaggedQueuingPermitted = 0xFFFF;
		break;
	case '3':
		if (strcmp(HostAdapter->FirmwareVersion, "3.35") >= 0)
			HostAdapter->TaggedQueuingPermitted = 0xFFFF;
		break;
	}
	/*
	   Determine the Host Adapter BIOS Address if the BIOS is enabled and
	   save it in the Host Adapter structure.  The BIOS is disabled if the
	   BIOS_Address is 0.
	 */
	HostAdapter->BIOS_Address = ExtendedSetupInformation.BIOS_Address << 12;
	/*
	   ISA Host Adapters require Bounce Buffers if there is more than 16MB memory.
	 */
	if (HostAdapter->HostAdapterBusType == BusLogic_ISA_Bus && (void *) high_memory > (void *) MAX_DMA_ADDRESS)
		HostAdapter->BounceBuffersRequired = true;
	/*
	   BusLogic BT-445S Host Adapters prior to board revision E have a hardware
	   bug whereby when the BIOS is enabled, transfers to/from the same address
	   range the BIOS occupies modulo 16MB are handled incorrectly.  Only properly
	   functioning BT-445S Host Adapters have firmware version 3.37, so require
	   that ISA Bounce Buffers be used for the buggy BT-445S models if there is
	   more than 16MB memory.
	 */
	if (HostAdapter->BIOS_Address > 0 && strcmp(HostAdapter->ModelName, "BT-445S") == 0 && strcmp(HostAdapter->FirmwareVersion, "3.37") < 0 && (void *) high_memory > (void *) MAX_DMA_ADDRESS)
		HostAdapter->BounceBuffersRequired = true;
	/*
	   Initialize parameters common to MultiMaster and FlashPoint Host Adapters.
	 */
      Common:
	/*
	   Initialize the Host Adapter Full Model Name from the Model Name.
	 */
	strcpy(HostAdapter->FullModelName, "BusLogic ");
	strcat(HostAdapter->FullModelName, HostAdapter->ModelName);
	/*
	   Select an appropriate value for the Tagged Queue Depth either from a
	   BusLogic Driver Options specification, or based on whether this Host
	   Adapter requires that ISA Bounce Buffers be used.  The Tagged Queue Depth
	   is left at 0 for automatic determination in BusLogic_SelectQueueDepths.
	   Initialize the Untagged Queue Depth.
	 */
	for (TargetID = 0; TargetID < BusLogic_MaxTargetDevices; TargetID++) {
		unsigned char QueueDepth = 0;
		if (HostAdapter->DriverOptions != NULL && HostAdapter->DriverOptions->QueueDepth[TargetID] > 0)
			QueueDepth = HostAdapter->DriverOptions->QueueDepth[TargetID];
		else if (HostAdapter->BounceBuffersRequired)
			QueueDepth = BusLogic_TaggedQueueDepthBB;
		HostAdapter->QueueDepth[TargetID] = QueueDepth;
	}
	if (HostAdapter->BounceBuffersRequired)
		HostAdapter->UntaggedQueueDepth = BusLogic_UntaggedQueueDepthBB;
	else
		HostAdapter->UntaggedQueueDepth = BusLogic_UntaggedQueueDepth;
	if (HostAdapter->DriverOptions != NULL)
		HostAdapter->CommonQueueDepth = HostAdapter->DriverOptions->CommonQueueDepth;
	if (HostAdapter->CommonQueueDepth > 0 && HostAdapter->CommonQueueDepth < HostAdapter->UntaggedQueueDepth)
		HostAdapter->UntaggedQueueDepth = HostAdapter->CommonQueueDepth;
	/*
	   Tagged Queuing is only allowed if Disconnect/Reconnect is permitted.
	   Therefore, mask the Tagged Queuing Permitted Default bits with the
	   Disconnect/Reconnect Permitted bits.
	 */
	HostAdapter->TaggedQueuingPermitted &= HostAdapter->DisconnectPermitted;
	/*
	   Combine the default Tagged Queuing Permitted bits with any BusLogic Driver
	   Options Tagged Queuing specification.
	 */
	if (HostAdapter->DriverOptions != NULL)
		HostAdapter->TaggedQueuingPermitted =
		    (HostAdapter->DriverOptions->TaggedQueuingPermitted & HostAdapter->DriverOptions->TaggedQueuingPermittedMask) | (HostAdapter->TaggedQueuingPermitted & ~HostAdapter->DriverOptions->TaggedQueuingPermittedMask);

	/*
	   Select an appropriate value for Bus Settle Time either from a BusLogic
	   Driver Options specification, or from BusLogic_DefaultBusSettleTime.
	 */
	if (HostAdapter->DriverOptions != NULL && HostAdapter->DriverOptions->BusSettleTime > 0)
		HostAdapter->BusSettleTime = HostAdapter->DriverOptions->BusSettleTime;
	else
		HostAdapter->BusSettleTime = BusLogic_DefaultBusSettleTime;
	/*
	   Indicate reading the Host Adapter Configuration completed successfully.
	 */
	return true;
}


/*
  BusLogic_ReportHostAdapterConfiguration reports the configuration of
  Host Adapter.
*/

static bool __init BusLogic_ReportHostAdapterConfiguration(struct BusLogic_HostAdapter
							      *HostAdapter)
{
	unsigned short AllTargetsMask = (1 << HostAdapter->MaxTargetDevices) - 1;
	unsigned short SynchronousPermitted, FastPermitted;
	unsigned short UltraPermitted, WidePermitted;
	unsigned short DisconnectPermitted, TaggedQueuingPermitted;
	bool CommonSynchronousNegotiation, CommonTaggedQueueDepth;
	char SynchronousString[BusLogic_MaxTargetDevices + 1];
	char WideString[BusLogic_MaxTargetDevices + 1];
	char DisconnectString[BusLogic_MaxTargetDevices + 1];
	char TaggedQueuingString[BusLogic_MaxTargetDevices + 1];
	char *SynchronousMessage = SynchronousString;
	char *WideMessage = WideString;
	char *DisconnectMessage = DisconnectString;
	char *TaggedQueuingMessage = TaggedQueuingString;
	int TargetID;
	BusLogic_Info("Configuring BusLogic Model %s %s%s%s%s SCSI Host Adapter\n",
		      HostAdapter, HostAdapter->ModelName,
		      BusLogic_HostAdapterBusNames[HostAdapter->HostAdapterBusType], (HostAdapter->HostWideSCSI ? " Wide" : ""), (HostAdapter->HostDifferentialSCSI ? " Differential" : ""), (HostAdapter->HostUltraSCSI ? " Ultra" : ""));
	BusLogic_Info("  Firmware Version: %s, I/O Address: 0x%X, " "IRQ Channel: %d/%s\n", HostAdapter, HostAdapter->FirmwareVersion, HostAdapter->IO_Address, HostAdapter->IRQ_Channel, (HostAdapter->LevelSensitiveInterrupt ? "Level" : "Edge"));
	if (HostAdapter->HostAdapterBusType != BusLogic_PCI_Bus) {
		BusLogic_Info("  DMA Channel: ", HostAdapter);
		if (HostAdapter->DMA_Channel > 0)
			BusLogic_Info("%d, ", HostAdapter, HostAdapter->DMA_Channel);
		else
			BusLogic_Info("None, ", HostAdapter);
		if (HostAdapter->BIOS_Address > 0)
			BusLogic_Info("BIOS Address: 0x%X, ", HostAdapter, HostAdapter->BIOS_Address);
		else
			BusLogic_Info("BIOS Address: None, ", HostAdapter);
	} else {
		BusLogic_Info("  PCI Bus: %d, Device: %d, Address: ", HostAdapter, HostAdapter->Bus, HostAdapter->Device);
		if (HostAdapter->PCI_Address > 0)
			BusLogic_Info("0x%X, ", HostAdapter, HostAdapter->PCI_Address);
		else
			BusLogic_Info("Unassigned, ", HostAdapter);
	}
	BusLogic_Info("Host Adapter SCSI ID: %d\n", HostAdapter, HostAdapter->SCSI_ID);
	BusLogic_Info("  Parity Checking: %s, Extended Translation: %s\n", HostAdapter, (HostAdapter->ParityCheckingEnabled ? "Enabled" : "Disabled"), (HostAdapter->ExtendedTranslationEnabled ? "Enabled" : "Disabled"));
	AllTargetsMask &= ~(1 << HostAdapter->SCSI_ID);
	SynchronousPermitted = HostAdapter->SynchronousPermitted & AllTargetsMask;
	FastPermitted = HostAdapter->FastPermitted & AllTargetsMask;
	UltraPermitted = HostAdapter->UltraPermitted & AllTargetsMask;
	if ((BusLogic_MultiMasterHostAdapterP(HostAdapter) && (HostAdapter->FirmwareVersion[0] >= '4' || HostAdapter->HostAdapterBusType == BusLogic_EISA_Bus)) || BusLogic_FlashPointHostAdapterP(HostAdapter)) {
		CommonSynchronousNegotiation = false;
		if (SynchronousPermitted == 0) {
			SynchronousMessage = "Disabled";
			CommonSynchronousNegotiation = true;
		} else if (SynchronousPermitted == AllTargetsMask) {
			if (FastPermitted == 0) {
				SynchronousMessage = "Slow";
				CommonSynchronousNegotiation = true;
			} else if (FastPermitted == AllTargetsMask) {
				if (UltraPermitted == 0) {
					SynchronousMessage = "Fast";
					CommonSynchronousNegotiation = true;
				} else if (UltraPermitted == AllTargetsMask) {
					SynchronousMessage = "Ultra";
					CommonSynchronousNegotiation = true;
				}
			}
		}
		if (!CommonSynchronousNegotiation) {
			for (TargetID = 0; TargetID < HostAdapter->MaxTargetDevices; TargetID++)
				SynchronousString[TargetID] = ((!(SynchronousPermitted & (1 << TargetID))) ? 'N' : (!(FastPermitted & (1 << TargetID)) ? 'S' : (!(UltraPermitted & (1 << TargetID)) ? 'F' : 'U')));
			SynchronousString[HostAdapter->SCSI_ID] = '#';
			SynchronousString[HostAdapter->MaxTargetDevices] = '\0';
		}
	} else
		SynchronousMessage = (SynchronousPermitted == 0 ? "Disabled" : "Enabled");
	WidePermitted = HostAdapter->WidePermitted & AllTargetsMask;
	if (WidePermitted == 0)
		WideMessage = "Disabled";
	else if (WidePermitted == AllTargetsMask)
		WideMessage = "Enabled";
	else {
		for (TargetID = 0; TargetID < HostAdapter->MaxTargetDevices; TargetID++)
			WideString[TargetID] = ((WidePermitted & (1 << TargetID)) ? 'Y' : 'N');
		WideString[HostAdapter->SCSI_ID] = '#';
		WideString[HostAdapter->MaxTargetDevices] = '\0';
	}
	DisconnectPermitted = HostAdapter->DisconnectPermitted & AllTargetsMask;
	if (DisconnectPermitted == 0)
		DisconnectMessage = "Disabled";
	else if (DisconnectPermitted == AllTargetsMask)
		DisconnectMessage = "Enabled";
	else {
		for (TargetID = 0; TargetID < HostAdapter->MaxTargetDevices; TargetID++)
			DisconnectString[TargetID] = ((DisconnectPermitted & (1 << TargetID)) ? 'Y' : 'N');
		DisconnectString[HostAdapter->SCSI_ID] = '#';
		DisconnectString[HostAdapter->MaxTargetDevices] = '\0';
	}
	TaggedQueuingPermitted = HostAdapter->TaggedQueuingPermitted & AllTargetsMask;
	if (TaggedQueuingPermitted == 0)
		TaggedQueuingMessage = "Disabled";
	else if (TaggedQueuingPermitted == AllTargetsMask)
		TaggedQueuingMessage = "Enabled";
	else {
		for (TargetID = 0; TargetID < HostAdapter->MaxTargetDevices; TargetID++)
			TaggedQueuingString[TargetID] = ((TaggedQueuingPermitted & (1 << TargetID)) ? 'Y' : 'N');
		TaggedQueuingString[HostAdapter->SCSI_ID] = '#';
		TaggedQueuingString[HostAdapter->MaxTargetDevices] = '\0';
	}
	BusLogic_Info("  Synchronous Negotiation: %s, Wide Negotiation: %s\n", HostAdapter, SynchronousMessage, WideMessage);
	BusLogic_Info("  Disconnect/Reconnect: %s, Tagged Queuing: %s\n", HostAdapter, DisconnectMessage, TaggedQueuingMessage);
	if (BusLogic_MultiMasterHostAdapterP(HostAdapter)) {
		BusLogic_Info("  Scatter/Gather Limit: %d of %d segments, " "Mailboxes: %d\n", HostAdapter, HostAdapter->DriverScatterGatherLimit, HostAdapter->HostAdapterScatterGatherLimit, HostAdapter->MailboxCount);
		BusLogic_Info("  Driver Queue Depth: %d, " "Host Adapter Queue Depth: %d\n", HostAdapter, HostAdapter->DriverQueueDepth, HostAdapter->HostAdapterQueueDepth);
	} else
		BusLogic_Info("  Driver Queue Depth: %d, " "Scatter/Gather Limit: %d segments\n", HostAdapter, HostAdapter->DriverQueueDepth, HostAdapter->DriverScatterGatherLimit);
	BusLogic_Info("  Tagged Queue Depth: ", HostAdapter);
	CommonTaggedQueueDepth = true;
	for (TargetID = 1; TargetID < HostAdapter->MaxTargetDevices; TargetID++)
		if (HostAdapter->QueueDepth[TargetID] != HostAdapter->QueueDepth[0]) {
			CommonTaggedQueueDepth = false;
			break;
		}
	if (CommonTaggedQueueDepth) {
		if (HostAdapter->QueueDepth[0] > 0)
			BusLogic_Info("%d", HostAdapter, HostAdapter->QueueDepth[0]);
		else
			BusLogic_Info("Automatic", HostAdapter);
	} else
		BusLogic_Info("Individual", HostAdapter);
	BusLogic_Info(", Untagged Queue Depth: %d\n", HostAdapter, HostAdapter->UntaggedQueueDepth);
	if (HostAdapter->TerminationInfoValid) {
		if (HostAdapter->HostWideSCSI)
			BusLogic_Info("  SCSI Bus Termination: %s", HostAdapter, (HostAdapter->LowByteTerminated ? (HostAdapter->HighByteTerminated ? "Both Enabled" : "Low Enabled")
										  : (HostAdapter->HighByteTerminated ? "High Enabled" : "Both Disabled")));
		else
			BusLogic_Info("  SCSI Bus Termination: %s", HostAdapter, (HostAdapter->LowByteTerminated ? "Enabled" : "Disabled"));
		if (HostAdapter->HostSupportsSCAM)
			BusLogic_Info(", SCAM: %s", HostAdapter, (HostAdapter->SCAM_Enabled ? (HostAdapter->SCAM_Level2 ? "Enabled, Level 2" : "Enabled, Level 1")
								  : "Disabled"));
		BusLogic_Info("\n", HostAdapter);
	}
	/*
	   Indicate reporting the Host Adapter configuration completed successfully.
	 */
	return true;
}


/*
  BusLogic_AcquireResources acquires the system resources necessary to use
  Host Adapter.
*/

static bool __init BusLogic_AcquireResources(struct BusLogic_HostAdapter *HostAdapter)
{
	if (HostAdapter->IRQ_Channel == 0) {
		BusLogic_Error("NO LEGAL INTERRUPT CHANNEL ASSIGNED - DETACHING\n", HostAdapter);
		return false;
	}
	/*
	   Acquire shared access to the IRQ Channel.
	 */
	if (request_irq(HostAdapter->IRQ_Channel, BusLogic_InterruptHandler, IRQF_SHARED, HostAdapter->FullModelName, HostAdapter) < 0) {
		BusLogic_Error("UNABLE TO ACQUIRE IRQ CHANNEL %d - DETACHING\n", HostAdapter, HostAdapter->IRQ_Channel);
		return false;
	}
	HostAdapter->IRQ_ChannelAcquired = true;
	/*
	   Acquire exclusive access to the DMA Channel.
	 */
	if (HostAdapter->DMA_Channel > 0) {
		if (request_dma(HostAdapter->DMA_Channel, HostAdapter->FullModelName) < 0) {
			BusLogic_Error("UNABLE TO ACQUIRE DMA CHANNEL %d - DETACHING\n", HostAdapter, HostAdapter->DMA_Channel);
			return false;
		}
		set_dma_mode(HostAdapter->DMA_Channel, DMA_MODE_CASCADE);
		enable_dma(HostAdapter->DMA_Channel);
		HostAdapter->DMA_ChannelAcquired = true;
	}
	/*
	   Indicate the System Resource Acquisition completed successfully,
	 */
	return true;
}


/*
  BusLogic_ReleaseResources releases any system resources previously acquired
  by BusLogic_AcquireResources.
*/

static void BusLogic_ReleaseResources(struct BusLogic_HostAdapter *HostAdapter)
{
	/*
	   Release shared access to the IRQ Channel.
	 */
	if (HostAdapter->IRQ_ChannelAcquired)
		free_irq(HostAdapter->IRQ_Channel, HostAdapter);
	/*
	   Release exclusive access to the DMA Channel.
	 */
	if (HostAdapter->DMA_ChannelAcquired)
		free_dma(HostAdapter->DMA_Channel);
	/*
	   Release any allocated memory structs not released elsewhere
	 */
	if (HostAdapter->MailboxSpace)
		pci_free_consistent(HostAdapter->PCI_Device, HostAdapter->MailboxSize, HostAdapter->MailboxSpace, HostAdapter->MailboxSpaceHandle);
	pci_dev_put(HostAdapter->PCI_Device);
	HostAdapter->MailboxSpace = NULL;
	HostAdapter->MailboxSpaceHandle = 0;
	HostAdapter->MailboxSize = 0;
}


/*
  BusLogic_InitializeHostAdapter initializes Host Adapter.  This is the only
  function called during SCSI Host Adapter detection which modifies the state
  of the Host Adapter from its initial power on or hard reset state.
*/

static bool BusLogic_InitializeHostAdapter(struct BusLogic_HostAdapter
					      *HostAdapter)
{
	struct BusLogic_ExtendedMailboxRequest ExtendedMailboxRequest;
	enum BusLogic_RoundRobinModeRequest RoundRobinModeRequest;
	enum BusLogic_SetCCBFormatRequest SetCCBFormatRequest;
	int TargetID;
	/*
	   Initialize the pointers to the first and last CCBs that are queued for
	   completion processing.
	 */
	HostAdapter->FirstCompletedCCB = NULL;
	HostAdapter->LastCompletedCCB = NULL;
	/*
	   Initialize the Bus Device Reset Pending CCB, Tagged Queuing Active,
	   Command Successful Flag, Active Commands, and Commands Since Reset
	   for each Target Device.
	 */
	for (TargetID = 0; TargetID < HostAdapter->MaxTargetDevices; TargetID++) {
		HostAdapter->BusDeviceResetPendingCCB[TargetID] = NULL;
		HostAdapter->TargetFlags[TargetID].TaggedQueuingActive = false;
		HostAdapter->TargetFlags[TargetID].CommandSuccessfulFlag = false;
		HostAdapter->ActiveCommands[TargetID] = 0;
		HostAdapter->CommandsSinceReset[TargetID] = 0;
	}
	/*
	   FlashPoint Host Adapters do not use Outgoing and Incoming Mailboxes.
	 */
	if (BusLogic_FlashPointHostAdapterP(HostAdapter))
		goto Done;
	/*
	   Initialize the Outgoing and Incoming Mailbox pointers.
	 */
	HostAdapter->MailboxSize = HostAdapter->MailboxCount * (sizeof(struct BusLogic_OutgoingMailbox) + sizeof(struct BusLogic_IncomingMailbox));
	HostAdapter->MailboxSpace = pci_alloc_consistent(HostAdapter->PCI_Device, HostAdapter->MailboxSize, &HostAdapter->MailboxSpaceHandle);
	if (HostAdapter->MailboxSpace == NULL)
		return BusLogic_Failure(HostAdapter, "MAILBOX ALLOCATION");
	HostAdapter->FirstOutgoingMailbox = (struct BusLogic_OutgoingMailbox *) HostAdapter->MailboxSpace;
	HostAdapter->LastOutgoingMailbox = HostAdapter->FirstOutgoingMailbox + HostAdapter->MailboxCount - 1;
	HostAdapter->NextOutgoingMailbox = HostAdapter->FirstOutgoingMailbox;
	HostAdapter->FirstIncomingMailbox = (struct BusLogic_IncomingMailbox *) (HostAdapter->LastOutgoingMailbox + 1);
	HostAdapter->LastIncomingMailbox = HostAdapter->FirstIncomingMailbox + HostAdapter->MailboxCount - 1;
	HostAdapter->NextIncomingMailbox = HostAdapter->FirstIncomingMailbox;

	/*
	   Initialize the Outgoing and Incoming Mailbox structures.
	 */
	memset(HostAdapter->FirstOutgoingMailbox, 0, HostAdapter->MailboxCount * sizeof(struct BusLogic_OutgoingMailbox));
	memset(HostAdapter->FirstIncomingMailbox, 0, HostAdapter->MailboxCount * sizeof(struct BusLogic_IncomingMailbox));
	/*
	   Initialize the Host Adapter's Pointer to the Outgoing/Incoming Mailboxes.
	 */
	ExtendedMailboxRequest.MailboxCount = HostAdapter->MailboxCount;
	ExtendedMailboxRequest.BaseMailboxAddress = (u32) HostAdapter->MailboxSpaceHandle;
	if (BusLogic_Command(HostAdapter, BusLogic_InitializeExtendedMailbox, &ExtendedMailboxRequest, sizeof(ExtendedMailboxRequest), NULL, 0) < 0)
		return BusLogic_Failure(HostAdapter, "MAILBOX INITIALIZATION");
	/*
	   Enable Strict Round Robin Mode if supported by the Host Adapter.  In
	   Strict Round Robin Mode, the Host Adapter only looks at the next Outgoing
	   Mailbox for each new command, rather than scanning through all the
	   Outgoing Mailboxes to find any that have new commands in them.  Strict
	   Round Robin Mode is significantly more efficient.
	 */
	if (HostAdapter->StrictRoundRobinModeSupport) {
		RoundRobinModeRequest = BusLogic_StrictRoundRobinMode;
		if (BusLogic_Command(HostAdapter, BusLogic_EnableStrictRoundRobinMode, &RoundRobinModeRequest, sizeof(RoundRobinModeRequest), NULL, 0) < 0)
			return BusLogic_Failure(HostAdapter, "ENABLE STRICT ROUND ROBIN MODE");
	}
	/*
	   For Host Adapters that support Extended LUN Format CCBs, issue the Set CCB
	   Format command to allow 32 Logical Units per Target Device.
	 */
	if (HostAdapter->ExtendedLUNSupport) {
		SetCCBFormatRequest = BusLogic_ExtendedLUNFormatCCB;
		if (BusLogic_Command(HostAdapter, BusLogic_SetCCBFormat, &SetCCBFormatRequest, sizeof(SetCCBFormatRequest), NULL, 0) < 0)
			return BusLogic_Failure(HostAdapter, "SET CCB FORMAT");
	}
	/*
	   Announce Successful Initialization.
	 */
      Done:
	if (!HostAdapter->HostAdapterInitialized) {
		BusLogic_Info("*** %s Initialized Successfully ***\n", HostAdapter, HostAdapter->FullModelName);
		BusLogic_Info("\n", HostAdapter);
	} else
		BusLogic_Warning("*** %s Initialized Successfully ***\n", HostAdapter, HostAdapter->FullModelName);
	HostAdapter->HostAdapterInitialized = true;
	/*
	   Indicate the Host Adapter Initialization completed successfully.
	 */
	return true;
}


/*
  BusLogic_TargetDeviceInquiry inquires about the Target Devices accessible
  through Host Adapter.
*/

static bool __init BusLogic_TargetDeviceInquiry(struct BusLogic_HostAdapter
						   *HostAdapter)
{
	u16 InstalledDevices;
	u8 InstalledDevicesID0to7[8];
	struct BusLogic_SetupInformation SetupInformation;
	u8 SynchronousPeriod[BusLogic_MaxTargetDevices];
	unsigned char RequestedReplyLength;
	int TargetID;
	/*
	   Wait a few seconds between the Host Adapter Hard Reset which initiates
	   a SCSI Bus Reset and issuing any SCSI Commands.  Some SCSI devices get
	   confused if they receive SCSI Commands too soon after a SCSI Bus Reset.
	 */
	BusLogic_Delay(HostAdapter->BusSettleTime);
	/*
	   FlashPoint Host Adapters do not provide for Target Device Inquiry.
	 */
	if (BusLogic_FlashPointHostAdapterP(HostAdapter))
		return true;
	/*
	   Inhibit the Target Device Inquiry if requested.
	 */
	if (HostAdapter->DriverOptions != NULL && HostAdapter->DriverOptions->LocalOptions.InhibitTargetInquiry)