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freebsd-nq/sys/dev/aic7xxx/aic7xxx.reg
Justin T. Gibbs dd1290f033 aic7xxx.c: 
Filter incoming transfer negotiation requests to ensure they
	never exceed the settings specified by the user.

	In restart sequencer attempt to deal with a bug in the aic7895.
	If a third party reset occurs at just the right time, the
	stack register can lock up.  When restarting the sequencer
	after handling the SCSI reset, poke SEQADDR1 before resting
	the sequencers program counter.

	When something strange happens, dump the card's transaction
	state via ahc_dump_card_state().  This should aid in debugging.

	Handle request sense transactions via the QINFIFO instead of
	attaching them to the waiting queue directly.  The waiting
	queue consumes card SCB resources and, in the pathological case
	of every target on the bus beating our selection attemps and
	issuing a check condition, could have caused us to run out
	of SCBs.  I have never seen this happen, and only early
	cards with 3 or 4 SCBs had any real chance of ever getting
	into this state.

	Add additional sequencer interrupt codes to support firmware
	diagnostics.  The diagnostic code is enabled with the
	AHC_DEBUG_SEQUENCER kernel option.

	Make it possible to switch into and out of target mode on
	the fly.  The card comes up by default as an initiator but
	will switch into target mode as soon as an enable lun operation
	is performed.  As always, target mode behavior is gated
	by the AHC_TMODE_ENABLE kernel option so most users will
	not be affected by this change.

	In ahc_update_target_msg_request(), also issue a new
	request if the ppr_options have changed.

	Never issue a PPR as a target.  It is forbidden by the spec.

	Correct a bug in ahc_parse_msg() that prevented us from
	responding to PPR messages as a target.

	Mark SCBs that are on the untagged queue with a flag instead
	of checking several fields in the SCB to see if the SCB should
	be on the queue.  This makes it easier for things like automatic
	request sense requests to be queued without touching the
	untagged queues even though they are untagged requests.

	When dealing with ignore wide residue messages that occur
	in the middle of a transfer, reset HADDR, not SHADDR for
	non-ultra2 chips.  Although SHADDR is where the firmware
	fetches the ending transfer address for a save data pointers
	request, it is readonly. Setting HADDR has the side effect
	of also updating SHADDR.

	Cleanup the output of ahc_dump_card_state() by nulling out the
	free scb list in the non-paging case.  The free list is only
	used if we must page SCBs.

	Correct the transmission of cdbs > 12 bytes in length.  When
	swapping HSCBs prior to notifing the sequencer of the new
	transaction, the bus address pointer for the cdb must also
	be recalculated to reflect its new location.  We now defer
	the calculation of the cdb address until just before queing
	it to the card.

	When pulling transfer negotiation settings out of scratch
	ram, convert 5MHz/clock doubled settings to 10MHz.

	Add a new function ahc_qinfifo_requeue_tail() for use by
	error recovery actions and auto-request sense operations.
	These operations always occur when the sequencer is paused,
	so we can avoid the extra expense incurred in the normal
	SCB queue method.

	Use the BMOV instruction for all single byte moves on
	controllers that support it.  The bmov instruction is
	twice as fast as an AND with an immediate of 0xFF as
	is used on older controllers.

	Correct a few bugs in ahc_dump_card_state().  If we have
	hardware assisted queue registers, use them to get the
	sequencer's idea of the head of the queue.  When enumerating
	the untagged queue, it helps to use the correct index for
	the queue.

aic7xxx.h:

	Indicate via a feature flag, which controllers can take
	on both the target and the initiator role at the same time.

	Add the AHC_SEQUENCER_DEBUG flag.

	Add the SCB_CDB32_PTR flag used for dealing with cdbs
	with lengths between 13 and 32 bytes.

	Add new prototypes.

aic7xxx.reg:
	Allow the SCSIBUSL register to be written to.  This is
	required to fix a selection timeout problem on the 7892/99.

	Cleanup the sequencer interrupt codes so that all debugging
	codes are grouped at the end of the list.

	Correct the definition of the ULTRA_ENB and DISC_DSB locations
	in scratch ram.  This prevented the driver from properly honoring
	these settings when no serial eeprom was available.

	Remove an unused sequencer flag.

aic7xxx.seq:
	Just before a potential select-out, clear the SCSIBUSL
	register.  Occasionally, during a selection timeout, the
	contents of the register may be presented on the bus,
	causing much confusion.

	Add sequencer diagnostic code to detect software and or
	hardware bugs.  The code attempts to verify most list
	operations so any corruption is caught before it occurs.
	We also track information about why a particular reconnection
	request was rejected.

	Don't clobber the digital REQ/ACK filter setting in SXFRCTL0
	when clearing the channel.

	Fix a target mode bug that would cause us to return busy
	status instead of queue full in respnse to a tagged transaction.

	Cleanup the overrun case.  It turns out that by simply
	butting the chip in bitbucket mode, it will ack any
	bytes until the phase changes.  This drasticaly simplifies
	things.

	Prior to leaving the data phase, make sure that the S/G
	preload queue is empty.

	Remove code to place a request sense request on the waiting
	queue.  This is all handled by the kernel now.

	Change the semantics of "findSCB".  In the past, findSCB
	ensured that a freshly paged in SCB appeared on the disconnected
	list.  The problem with this is that there is no guarantee that
	the paged in SCB is for a disconnected transation.  We now
	defer any list manipulation to the caller who usually discards
	the SCB via the free list.

	Inline some busy target table operations.

	Add a critical section to protect adding an SCB to
	the disconnected list.

aic7xxx_freebsd.c:
	Handle changes in the transfer negotiation setting API
	to filter incoming requests.  No filtering is necessary
	for "goal" requests from the XPT.

	Set the SCB_CDB32_PTR flag when queing a transaction with
	a large cdb.

	In ahc_timeout, only take action if the active SCB is
	the timedout SCB.  This deals with the case of two
	transactions to the same device with different timeout
	values.

	Use ahc_qinfifo_requeu_tail() instead of home grown
	version.

aic7xxx_inline.h:
	Honor SCB_CDB32_PTR when queuing a new request.

aic7xxx_pci.c:
	Use the maximum data fifo threshold for all chips.
2000-10-31 18:43:29 +00:00

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/*
* Aic7xxx register and scratch ram definitions.
*
* Copyright (c) 1994-2000 Justin Gibbs.
* All rights reserved.
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions
* are met:
* 1. Redistributions of source code must retain the above copyright
* notice, this list of conditions, and the following disclaimer,
* without modification.
* 2. The name of the author may not be used to endorse or promote products
* derived from this software without specific prior written permission.
*
* Alternatively, this software may be distributed under the terms of the
* GNU Public License ("GPL").
*
* THIS SOFTWARE IS PROVIDED BY THE AUTHOR AND CONTRIBUTORS ``AS IS'' AND
* ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
* IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE
* ARE DISCLAIMED. IN NO EVENT SHALL THE AUTHOR OR CONTRIBUTORS BE LIABLE FOR
* ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL
* DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS
* OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION)
* HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT
* LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY
* OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF
* SUCH DAMAGE.
*
* $Id: //depot/src/aic7xxx/aic7xxx.reg#5 $
*
* $FreeBSD$
*/
/*
* This file is processed by the aic7xxx_asm utility for use in assembling
* firmware for the aic7xxx family of SCSI host adapters as well as to generate
* a C header file for use in the kernel portion of the Aic7xxx driver.
*
* All page numbers refer to the Adaptec AIC-7770 Data Book available from
* Adaptec's Technical Documents Department 1-800-934-2766
*/
/*
* SCSI Sequence Control (p. 3-11).
* Each bit, when set starts a specific SCSI sequence on the bus
*/
register SCSISEQ {
address 0x000
access_mode RW
bit TEMODE 0x80
bit ENSELO 0x40
bit ENSELI 0x20
bit ENRSELI 0x10
bit ENAUTOATNO 0x08
bit ENAUTOATNI 0x04
bit ENAUTOATNP 0x02
bit SCSIRSTO 0x01
}
/*
* SCSI Transfer Control 0 Register (pp. 3-13).
* Controls the SCSI module data path.
*/
register SXFRCTL0 {
address 0x001
access_mode RW
bit DFON 0x80
bit DFPEXP 0x40
bit FAST20 0x20
bit CLRSTCNT 0x10
bit SPIOEN 0x08
bit SCAMEN 0x04
bit CLRCHN 0x02
}
/*
* SCSI Transfer Control 1 Register (pp. 3-14,15).
* Controls the SCSI module data path.
*/
register SXFRCTL1 {
address 0x002
access_mode RW
bit BITBUCKET 0x80
bit SWRAPEN 0x40
bit ENSPCHK 0x20
mask STIMESEL 0x18
bit ENSTIMER 0x04
bit ACTNEGEN 0x02
bit STPWEN 0x01 /* Powered Termination */
}
/*
* SCSI Control Signal Read Register (p. 3-15).
* Reads the actual state of the SCSI bus pins
*/
register SCSISIGI {
address 0x003
access_mode RO
bit CDI 0x80
bit IOI 0x40
bit MSGI 0x20
bit ATNI 0x10
bit SELI 0x08
bit BSYI 0x04
bit REQI 0x02
bit ACKI 0x01
/*
* Possible phases in SCSISIGI
*/
mask PHASE_MASK CDI|IOI|MSGI
mask P_DATAOUT 0x00
mask P_DATAIN IOI
mask P_DATAOUT_DT P_DATAOUT|MSGI
mask P_DATAIN_DT P_DATAIN|MSGI
mask P_COMMAND CDI
mask P_MESGOUT CDI|MSGI
mask P_STATUS CDI|IOI
mask P_MESGIN CDI|IOI|MSGI
}
/*
* SCSI Control Signal Write Register (p. 3-16).
* Writing to this register modifies the control signals on the bus. Only
* those signals that are allowed in the current mode (Initiator/Target) are
* asserted.
*/
register SCSISIGO {
address 0x003
access_mode WO
bit CDO 0x80
bit IOO 0x40
bit MSGO 0x20
bit ATNO 0x10
bit SELO 0x08
bit BSYO 0x04
bit REQO 0x02
bit ACKO 0x01
/*
* Possible phases to write into SCSISIG0
*/
mask PHASE_MASK CDI|IOI|MSGI
mask P_DATAOUT 0x00
mask P_DATAIN IOI
mask P_COMMAND CDI
mask P_MESGOUT CDI|MSGI
mask P_STATUS CDI|IOI
mask P_MESGIN CDI|IOI|MSGI
}
/*
* SCSI Rate Control (p. 3-17).
* Contents of this register determine the Synchronous SCSI data transfer
* rate and the maximum synchronous Req/Ack offset. An offset of 0 in the
* SOFS (3:0) bits disables synchronous data transfers. Any offset value
* greater than 0 enables synchronous transfers.
*/
register SCSIRATE {
address 0x004
access_mode RW
bit WIDEXFER 0x80 /* Wide transfer control */
bit ENABLE_CRC 0x40 /* CRC for D-Phases */
bit SINGLE_EDGE 0x10 /* Disable DT Transfers */
mask SXFR 0x70 /* Sync transfer rate */
mask SXFR_ULTRA2 0x0f /* Sync transfer rate */
mask SOFS 0x0f /* Sync offset */
}
/*
* SCSI ID (p. 3-18).
* Contains the ID of the board and the current target on the
* selected channel.
*/
register SCSIID {
address 0x005
access_mode RW
mask TID 0xf0 /* Target ID mask */
mask TWIN_TID 0x70
bit TWIN_CHNLB 0x80
mask OID 0x0f /* Our ID mask */
/*
* SCSI Maximum Offset (p. 4-61 aic7890/91 Data Book)
* The aic7890/91 allow an offset of up to 127 transfers in both wide
* and narrow mode.
*/
alias SCSIOFFSET
mask SOFS_ULTRA2 0x7f /* Sync offset U2 chips */
}
/*
* SCSI Latched Data (p. 3-19).
* Read/Write latches used to transfer data on the SCSI bus during
* Automatic or Manual PIO mode. SCSIDATH can be used for the
* upper byte of a 16bit wide asynchronouse data phase transfer.
*/
register SCSIDATL {
address 0x006
access_mode RW
}
register SCSIDATH {
address 0x007
access_mode RW
}
/*
* SCSI Transfer Count (pp. 3-19,20)
* These registers count down the number of bytes transferred
* across the SCSI bus. The counter is decremented only once
* the data has been safely transferred. SDONE in SSTAT0 is
* set when STCNT goes to 0
*/
register STCNT {
address 0x008
size 3
access_mode RW
}
/* ALT_MODE register on Ultra160 chips */
register OPTIONMODE {
address 0x008
access_mode RW
bit AUTORATEEN 0x80
bit AUTOACKEN 0x40
bit ATNMGMNTEN 0x20
bit BUSFREEREV 0x10
bit EXPPHASEDIS 0x08
bit SCSIDATL_IMGEN 0x04
bit AUTO_MSGOUT_DE 0x02
bit DIS_MSGIN_DUALEDGE 0x01
mask OPTIONMODE_DEFAULTS AUTO_MSGOUT_DE|DIS_MSGIN_DUALEDGE
}
/* ALT_MODE register on Ultra160 chips */
register TARGCRCCNT {
address 0x00a
size 2
access_mode RW
}
/*
* Clear SCSI Interrupt 0 (p. 3-20)
* Writing a 1 to a bit clears the associated SCSI Interrupt in SSTAT0.
*/
register CLRSINT0 {
address 0x00b
access_mode WO
bit CLRSELDO 0x40
bit CLRSELDI 0x20
bit CLRSELINGO 0x10
bit CLRSWRAP 0x08
bit CLRSPIORDY 0x02
}
/*
* SCSI Status 0 (p. 3-21)
* Contains one set of SCSI Interrupt codes
* These are most likely of interest to the sequencer
*/
register SSTAT0 {
address 0x00b
access_mode RO
bit TARGET 0x80 /* Board acting as target */
bit SELDO 0x40 /* Selection Done */
bit SELDI 0x20 /* Board has been selected */
bit SELINGO 0x10 /* Selection In Progress */
bit SWRAP 0x08 /* 24bit counter wrap */
bit IOERR 0x08 /* LVD Tranceiver mode changed */
bit SDONE 0x04 /* STCNT = 0x000000 */
bit SPIORDY 0x02 /* SCSI PIO Ready */
bit DMADONE 0x01 /* DMA transfer completed */
}
/*
* Clear SCSI Interrupt 1 (p. 3-23)
* Writing a 1 to a bit clears the associated SCSI Interrupt in SSTAT1.
*/
register CLRSINT1 {
address 0x00c
access_mode WO
bit CLRSELTIMEO 0x80
bit CLRATNO 0x40
bit CLRSCSIRSTI 0x20
bit CLRBUSFREE 0x08
bit CLRSCSIPERR 0x04
bit CLRPHASECHG 0x02
bit CLRREQINIT 0x01
}
/*
* SCSI Status 1 (p. 3-24)
*/
register SSTAT1 {
address 0x00c
access_mode RO
bit SELTO 0x80
bit ATNTARG 0x40
bit SCSIRSTI 0x20
bit PHASEMIS 0x10
bit BUSFREE 0x08
bit SCSIPERR 0x04
bit PHASECHG 0x02
bit REQINIT 0x01
}
/*
* SCSI Status 2 (pp. 3-25,26)
*/
register SSTAT2 {
address 0x00d
access_mode RO
bit OVERRUN 0x80
bit SHVALID 0x40 /* Shaddow Layer non-zero */
bit EXP_ACTIVE 0x10 /* SCSI Expander Active */
bit CRCVALERR 0x08 /* CRC doesn't match (U3 only) */
bit CRCENDERR 0x04 /* No terminal CRC packet (U3 only) */
bit CRCREQERR 0x02 /* Illegal CRC packet req (U3 only) */
bit DUAL_EDGE_ERR 0x01 /* Incorrect data phase (U3 only) */
mask SFCNT 0x1f
}
/*
* SCSI Status 3 (p. 3-26)
*/
register SSTAT3 {
address 0x00e
access_mode RO
mask SCSICNT 0xf0
mask OFFCNT 0x0f
}
/*
* SCSI ID for the aic7890/91 chips
*/
register SCSIID_ULTRA2 {
address 0x00f
access_mode RW
mask TID 0xf0 /* Target ID mask */
mask OID 0x0f /* Our ID mask */
}
/*
* SCSI Interrupt Mode 1 (p. 3-28)
* Setting any bit will enable the corresponding function
* in SIMODE0 to interrupt via the IRQ pin.
*/
register SIMODE0 {
address 0x010
access_mode RW
bit ENSELDO 0x40
bit ENSELDI 0x20
bit ENSELINGO 0x10
bit ENSWRAP 0x08
bit ENIOERR 0x08 /* LVD Tranceiver mode changes */
bit ENSDONE 0x04
bit ENSPIORDY 0x02
bit ENDMADONE 0x01
}
/*
* SCSI Interrupt Mode 1 (pp. 3-28,29)
* Setting any bit will enable the corresponding function
* in SIMODE1 to interrupt via the IRQ pin.
*/
register SIMODE1 {
address 0x011
access_mode RW
bit ENSELTIMO 0x80
bit ENATNTARG 0x40
bit ENSCSIRST 0x20
bit ENPHASEMIS 0x10
bit ENBUSFREE 0x08
bit ENSCSIPERR 0x04
bit ENPHASECHG 0x02
bit ENREQINIT 0x01
}
/*
* SCSI Data Bus (High) (p. 3-29)
* This register reads data on the SCSI Data bus directly.
*/
register SCSIBUSL {
address 0x012
access_mode RW
}
register SCSIBUSH {
address 0x013
access_mode RW
}
/*
* SCSI/Host Address (p. 3-30)
* These registers hold the host address for the byte about to be
* transferred on the SCSI bus. They are counted up in the same
* manner as STCNT is counted down. SHADDR should always be used
* to determine the address of the last byte transferred since HADDR
* can be skewed by write ahead.
*/
register SHADDR {
address 0x014
size 4
access_mode RO
}
/*
* Selection Timeout Timer (p. 3-30)
*/
register SELTIMER {
address 0x018
access_mode RW
bit STAGE6 0x20
bit STAGE5 0x10
bit STAGE4 0x08
bit STAGE3 0x04
bit STAGE2 0x02
bit STAGE1 0x01
alias TARGIDIN
}
/*
* Selection/Reselection ID (p. 3-31)
* Upper four bits are the device id. The ONEBIT is set when the re/selecting
* device did not set its own ID.
*/
register SELID {
address 0x019
access_mode RW
mask SELID_MASK 0xf0
bit ONEBIT 0x08
}
register SCAMCTL {
address 0x01a
access_mode RW
bit ENSCAMSELO 0x80
bit CLRSCAMSELID 0x40
bit ALTSTIM 0x20
bit DFLTTID 0x10
mask SCAMLVL 0x03
}
/*
* Target Mode Selecting in ID bitmask (aic7890/91/96/97)
*/
register TARGID {
address 0x01b
size 2
access_mode RW
}
/*
* Serial Port I/O Cabability register (p. 4-95 aic7860 Data Book)
* Indicates if external logic has been attached to the chip to
* perform the tasks of accessing a serial eeprom, testing termination
* strength, and performing cable detection. On the aic7860, most of
* these features are handled on chip, but on the aic7855 an attached
* aic3800 does the grunt work.
*/
register SPIOCAP {
address 0x01b
access_mode RW
bit SOFT1 0x80
bit SOFT0 0x40
bit SOFTCMDEN 0x20
bit HAS_BRDCTL 0x10 /* External Board control */
bit SEEPROM 0x08 /* External serial eeprom logic */
bit EEPROM 0x04 /* Writable external BIOS ROM */
bit ROM 0x02 /* Logic for accessing external ROM */
bit SSPIOCPS 0x01 /* Termination and cable detection */
}
register BRDCTL {
address 0x01d
bit BRDDAT7 0x80
bit BRDDAT6 0x40
bit BRDDAT5 0x20
bit BRDSTB 0x10
bit BRDCS 0x08
bit BRDRW 0x04
bit BRDCTL1 0x02
bit BRDCTL0 0x01
/* 7890 Definitions */
bit BRDDAT4 0x10
bit BRDDAT3 0x08
bit BRDDAT2 0x04
bit BRDRW_ULTRA2 0x02
bit BRDSTB_ULTRA2 0x01
}
/*
* Serial EEPROM Control (p. 4-92 in 7870 Databook)
* Controls the reading and writing of an external serial 1-bit
* EEPROM Device. In order to access the serial EEPROM, you must
* first set the SEEMS bit that generates a request to the memory
* port for access to the serial EEPROM device. When the memory
* port is not busy servicing another request, it reconfigures
* to allow access to the serial EEPROM. When this happens, SEERDY
* gets set high to verify that the memory port access has been
* granted.
*
* After successful arbitration for the memory port, the SEECS bit of
* the SEECTL register is connected to the chip select. The SEECK,
* SEEDO, and SEEDI are connected to the clock, data out, and data in
* lines respectively. The SEERDY bit of SEECTL is useful in that it
* gives us an 800 nsec timer. After a write to the SEECTL register,
* the SEERDY goes high 800 nsec later. The one exception to this is
* when we first request access to the memory port. The SEERDY goes
* high to signify that access has been granted and, for this case, has
* no implied timing.
*
* See 93cx6.c for detailed information on the protocol necessary to
* read the serial EEPROM.
*/
register SEECTL {
address 0x01e
bit EXTARBACK 0x80
bit EXTARBREQ 0x40
bit SEEMS 0x20
bit SEERDY 0x10
bit SEECS 0x08
bit SEECK 0x04
bit SEEDO 0x02
bit SEEDI 0x01
}
/*
* SCSI Block Control (p. 3-32)
* Controls Bus type and channel selection. In a twin channel configuration
* addresses 0x00-0x1e are gated to the appropriate channel based on this
* register. SELWIDE allows for the coexistence of 8bit and 16bit devices
* on a wide bus.
*/
register SBLKCTL {
address 0x01f
access_mode RW
bit DIAGLEDEN 0x80 /* Aic78X0 only */
bit DIAGLEDON 0x40 /* Aic78X0 only */
bit AUTOFLUSHDIS 0x20
bit SELBUSB 0x08
bit ENAB40 0x08 /* LVD transceiver active */
bit ENAB20 0x04 /* SE/HVD transceiver active */
bit SELWIDE 0x02
bit XCVR 0x01 /* External transceiver active */
}
/*
* Sequencer Control (p. 3-33)
* Error detection mode and speed configuration
*/
register SEQCTL {
address 0x060
access_mode RW
bit PERRORDIS 0x80
bit PAUSEDIS 0x40
bit FAILDIS 0x20
bit FASTMODE 0x10
bit BRKADRINTEN 0x08
bit STEP 0x04
bit SEQRESET 0x02
bit LOADRAM 0x01
}
/*
* Sequencer RAM Data (p. 3-34)
* Single byte window into the Scratch Ram area starting at the address
* specified by SEQADDR0 and SEQADDR1. To write a full word, simply write
* four bytes in succession. The SEQADDRs will increment after the most
* significant byte is written
*/
register SEQRAM {
address 0x061
access_mode RW
}
/*
* Sequencer Address Registers (p. 3-35)
* Only the first bit of SEQADDR1 holds addressing information
*/
register SEQADDR0 {
address 0x062
access_mode RW
}
register SEQADDR1 {
address 0x063
access_mode RW
mask SEQADDR1_MASK 0x01
}
/*
* Accumulator
* We cheat by passing arguments in the Accumulator up to the kernel driver
*/
register ACCUM {
address 0x064
access_mode RW
accumulator
}
register SINDEX {
address 0x065
access_mode RW
sindex
}
register DINDEX {
address 0x066
access_mode RW
}
register ALLONES {
address 0x069
access_mode RO
allones
}
register ALLZEROS {
address 0x06a
access_mode RO
allzeros
}
register NONE {
address 0x06a
access_mode WO
none
}
register FLAGS {
address 0x06b
access_mode RO
bit ZERO 0x02
bit CARRY 0x01
}
register SINDIR {
address 0x06c
access_mode RO
}
register DINDIR {
address 0x06d
access_mode WO
}
register FUNCTION1 {
address 0x06e
access_mode RW
}
register STACK {
address 0x06f
access_mode RO
}
/*
* Board Control (p. 3-43)
*/
register BCTL {
address 0x084
access_mode RW
bit ACE 0x08
bit ENABLE 0x01
}
/*
* On the aic78X0 chips, Board Control is replaced by the DSCommand
* register (p. 4-64)
*/
register DSCOMMAND0 {
address 0x084
access_mode RW
bit CACHETHEN 0x80 /* Cache Threshold enable */
bit DPARCKEN 0x40 /* Data Parity Check Enable */
bit MPARCKEN 0x20 /* Memory Parity Check Enable */
bit EXTREQLCK 0x10 /* External Request Lock */
/* aic7890/91/96/97 only */
bit INTSCBRAMSEL 0x08 /* Internal SCB RAM Select */
bit RAMPS 0x04 /* External SCB RAM Present */
bit USCBSIZE32 0x02 /* Use 32byte SCB Page Size */
bit CIOPARCKEN 0x01 /* Internal bus parity error enable */
}
/*
* Bus On/Off Time (p. 3-44)
*/
register BUSTIME {
address 0x085
access_mode RW
mask BOFF 0xf0
mask BON 0x0f
}
/*
* Bus Speed (p. 3-45) aic7770 only
*/
register BUSSPD {
address 0x086
access_mode RW
mask DFTHRSH 0xc0
mask STBOFF 0x38
mask STBON 0x07
mask DFTHRSH_100 0xc0
mask DFTHRSH_75 0x80
}
/* aic7850/55/60/70/80/95 only */
register DSPCISTATUS {
address 0x086
mask DFTHRSH_100 0xc0
}
/* aic7890/91/96/97 only */
register HS_MAILBOX {
address 0x086
mask HOST_MAILBOX 0xF0
mask SEQ_MAILBOX 0x0F
mask HOST_TQINPOS 0x80 /* Boundary at either 0 or 128 */
}
const HOST_MAILBOX_SHIFT 4
const SEQ_MAILBOX_SHIFT 0
/*
* Host Control (p. 3-47) R/W
* Overall host control of the device.
*/
register HCNTRL {
address 0x087
access_mode RW
bit POWRDN 0x40
bit SWINT 0x10
bit IRQMS 0x08
bit PAUSE 0x04
bit INTEN 0x02
bit CHIPRST 0x01
bit CHIPRSTACK 0x01
}
/*
* Host Address (p. 3-48)
* This register contains the address of the byte about
* to be transferred across the host bus.
*/
register HADDR {
address 0x088
size 4
access_mode RW
}
register HCNT {
address 0x08c
size 3
access_mode RW
}
/*
* SCB Pointer (p. 3-49)
* Gate one of the SCBs into the SCBARRAY window.
*/
register SCBPTR {
address 0x090
access_mode RW
}
/*
* Interrupt Status (p. 3-50)
* Status for system interrupts
*/
register INTSTAT {
address 0x091
access_mode RW
bit BRKADRINT 0x08
bit SCSIINT 0x04
bit CMDCMPLT 0x02
bit SEQINT 0x01
mask BAD_PHASE SEQINT /* unknown scsi bus phase */
mask SEND_REJECT 0x10|SEQINT /* sending a message reject */
mask NO_IDENT 0x20|SEQINT /* no IDENTIFY after reconnect*/
mask NO_MATCH 0x30|SEQINT /* no cmd match for reconnect */
mask IGN_WIDE_RES 0x40|SEQINT /* Complex IGN Wide Res Msg */
mask RESIDUAL 0x50|SEQINT /* Residual byte count != 0 */
mask HOST_MSG_LOOP 0x60|SEQINT /*
* The bus is ready for the
* host to perform another
* message transaction. This
* mechanism is used for things
* like sync/wide negotiation
* that require a kernel based
* message state engine.
*/
mask BAD_STATUS 0x70|SEQINT /* Bad status from target */
mask PERR_DETECTED 0x80|SEQINT /*
* Either the phase_lock
* or inb_next routine has
* noticed a parity error.
*/
mask DATA_OVERRUN 0x90|SEQINT /*
* Target attempted to write
* beyond the bounds of its
* command.
*/
mask BOGUS_TAG 0xa0|SEQINT /*
* Sequencer given an SCB with
* a Tag value of 0xFF.
*/
mask SCBPTR_MISMATCH 0xb0|SEQINT /*
* In the SCB paging case, our
* SCBPTR is not the same as
* we originally set prior to
* download of a new scb.
*/
mask SCB_MISMATCH 0xc0|SEQINT /*
* Downloaded SCB's tag does
* not match the entry we
* intended to download.
*/
mask ABORT_QINSCB 0xd0|SEQINT /*
* An SCB was aborted
* during download.
* Informational.
*/
mask NO_FREE_SCB 0xe0|SEQINT /*
* get_free_or_disc_scb failed.
*/
mask OUT_OF_RANGE 0xf0|SEQINT
mask SEQINT_MASK 0xf0|SEQINT /* SEQINT Status Codes */
mask INT_PEND (BRKADRINT|SEQINT|SCSIINT|CMDCMPLT)
}
/*
* Hard Error (p. 3-53)
* Reporting of catastrophic errors. You usually cannot recover from
* these without a full board reset.
*/
register ERROR {
address 0x092
access_mode RO
bit CIOPARERR 0x80 /* Ultra2 only */
bit PCIERRSTAT 0x40 /* PCI only */
bit MPARERR 0x20 /* PCI only */
bit DPARERR 0x10 /* PCI only */
bit SQPARERR 0x08
bit ILLOPCODE 0x04
bit ILLSADDR 0x02
bit ILLHADDR 0x01
}
/*
* Clear Interrupt Status (p. 3-52)
*/
register CLRINT {
address 0x092
access_mode WO
bit CLRPARERR 0x10 /* PCI only */
bit CLRBRKADRINT 0x08
bit CLRSCSIINT 0x04
bit CLRCMDINT 0x02
bit CLRSEQINT 0x01
}
register DFCNTRL {
address 0x093
access_mode RW
bit PRELOADEN 0x80 /* aic7890 only */
bit WIDEODD 0x40
bit SCSIEN 0x20
bit SDMAEN 0x10
bit SDMAENACK 0x10
bit HDMAEN 0x08
bit HDMAENACK 0x08
bit DIRECTION 0x04
bit FIFOFLUSH 0x02
bit FIFORESET 0x01
}
register DFSTATUS {
address 0x094
access_mode RO
bit PRELOAD_AVAIL 0x80
bit DWORDEMP 0x20
bit MREQPEND 0x10
bit HDONE 0x08
bit DFTHRESH 0x04
bit FIFOFULL 0x02
bit FIFOEMP 0x01
}
register DFWADDR {
address 0x95
access_mode RW
}
register DFRADDR {
address 0x97
access_mode RW
}
register DFDAT {
address 0x099
access_mode RW
}
/*
* SCB Auto Increment (p. 3-59)
* Byte offset into the SCB Array and an optional bit to allow auto
* incrementing of the address during download and upload operations
*/
register SCBCNT {
address 0x09a
access_mode RW
bit SCBAUTO 0x80
mask SCBCNT_MASK 0x1f
}
/*
* Queue In FIFO (p. 3-60)
* Input queue for queued SCBs (commands that the seqencer has yet to start)
*/
register QINFIFO {
address 0x09b
access_mode RW
}
/*
* Queue In Count (p. 3-60)
* Number of queued SCBs
*/
register QINCNT {
address 0x09c
access_mode RO
}
/*
* Queue Out FIFO (p. 3-61)
* Queue of SCBs that have completed and await the host
*/
register QOUTFIFO {
address 0x09d
access_mode WO
}
register CRCCONTROL1 {
address 0x09d
access_mode RW
bit CRCONSEEN 0x80
bit CRCVALCHKEN 0x40
bit CRCENDCHKEN 0x20
bit CRCREQCHKEN 0x10
bit TARGCRCENDEN 0x08
bit TARGCRCCNTEN 0x04
}
/*
* Queue Out Count (p. 3-61)
* Number of queued SCBs in the Out FIFO
*/
register QOUTCNT {
address 0x09e
access_mode RO
}
register SCSIPHASE {
address 0x09e
access_mode RO
bit STATUS_PHASE 0x20
bit COMMAND_PHASE 0x10
bit MSG_IN_PHASE 0x08
bit MSG_OUT_PHASE 0x04
bit DATA_IN_PHASE 0x02
bit DATA_OUT_PHASE 0x01
}
/*
* Special Function
*/
register SFUNCT {
address 0x09f
access_mode RW
bit ALT_MODE 0x80
}
/*
* SCB Definition (p. 5-4)
*/
scb {
address 0x0a0
SCB_CDB_PTR {
size 4
alias SCB_RESIDUAL_DATACNT
alias SCB_CDB_STORE
alias SCB_TARGET_INFO
}
SCB_RESIDUAL_SGPTR {
size 4
}
SCB_SCSI_STATUS {
size 1
}
SCB_CDB_STORE_PAD {
size 3
}
SCB_DATAPTR {
size 4
}
SCB_DATACNT {
/*
* The last byte is really the high address bits for
* the data address.
*/
size 4
bit SG_LAST_SEG 0x80 /* In the fourth byte */
mask SG_HIGH_ADDR_BITS 0x7F /* In the fourth byte */
}
SCB_SGPTR {
size 4
bit SG_RESID_VALID 0x04 /* In the first byte */
bit SG_FULL_RESID 0x02 /* In the first byte */
bit SG_LIST_NULL 0x01 /* In the first byte */
}
SCB_CONTROL {
size 1
bit TARGET_SCB 0x80
bit DISCENB 0x40
bit TAG_ENB 0x20
bit MK_MESSAGE 0x10
bit ULTRAENB 0x08
bit DISCONNECTED 0x04
mask SCB_TAG_TYPE 0x03
}
SCB_SCSIID {
size 1
bit TWIN_CHNLB 0x80
mask TWIN_TID 0x70
mask TID 0xf0
mask OID 0x0f
}
SCB_LUN {
mask LID 0xff
size 1
}
SCB_TAG {
size 1
}
SCB_CDB_LEN {
size 1
}
SCB_SCSIRATE {
size 1
}
SCB_SCSIOFFSET {
size 1
}
SCB_NEXT {
size 1
}
SCB_64_SPARE {
size 16
}
SCB_64_BTT {
size 16
}
}
const SCB_UPLOAD_SIZE 32
const SCB_DOWNLOAD_SIZE 32
const SCB_DOWNLOAD_SIZE_64 48
const SG_SIZEOF 0x08 /* sizeof(struct ahc_dma) */
/* --------------------- AHA-2840-only definitions -------------------- */
register SEECTL_2840 {
address 0x0c0
access_mode RW
bit CS_2840 0x04
bit CK_2840 0x02
bit DO_2840 0x01
}
register STATUS_2840 {
address 0x0c1
access_mode RW
bit EEPROM_TF 0x80
mask BIOS_SEL 0x60
mask ADSEL 0x1e
bit DI_2840 0x01
}
/* --------------------- AIC-7870-only definitions -------------------- */
register CCHADDR {
address 0x0E0
size 8
}
register CCHCNT {
address 0x0E8
}
register CCSGRAM {
address 0x0E9
}
register CCSGADDR {
address 0x0EA
}
register CCSGCTL {
address 0x0EB
bit CCSGDONE 0x80
bit CCSGEN 0x08
bit SG_FETCH_NEEDED 0x02 /* Bit used for software state */
bit CCSGRESET 0x01
}
register CCSCBCNT {
address 0xEF
}
register CCSCBCTL {
address 0x0EE
bit CCSCBDONE 0x80
bit ARRDONE 0x40 /* SCB Array prefetch done */
bit CCARREN 0x10
bit CCSCBEN 0x08
bit CCSCBDIR 0x04
bit CCSCBRESET 0x01
}
register CCSCBADDR {
address 0x0ED
}
register CCSCBRAM {
address 0xEC
}
/*
* SCB bank address (7895/7896/97 only)
*/
register SCBBADDR {
address 0x0F0
access_mode RW
}
register CCSCBPTR {
address 0x0F1
}
register HNSCB_QOFF {
address 0x0F4
}
register SNSCB_QOFF {
address 0x0F6
}
register SDSCB_QOFF {
address 0x0F8
}
register QOFF_CTLSTA {
address 0x0FA
bit SCB_AVAIL 0x40
bit SNSCB_ROLLOVER 0x20
bit SDSCB_ROLLOVER 0x10
mask SCB_QSIZE 0x07
mask SCB_QSIZE_256 0x06
}
register DFF_THRSH {
address 0x0FB
mask WR_DFTHRSH 0x70
mask RD_DFTHRSH 0x07
mask RD_DFTHRSH_MIN 0x00
mask RD_DFTHRSH_25 0x01
mask RD_DFTHRSH_50 0x02
mask RD_DFTHRSH_63 0x03
mask RD_DFTHRSH_75 0x04
mask RD_DFTHRSH_85 0x05
mask RD_DFTHRSH_90 0x06
mask RD_DFTHRSH_MAX 0x07
mask WR_DFTHRSH_MIN 0x00
mask WR_DFTHRSH_25 0x10
mask WR_DFTHRSH_50 0x20
mask WR_DFTHRSH_63 0x30
mask WR_DFTHRSH_75 0x40
mask WR_DFTHRSH_85 0x50
mask WR_DFTHRSH_90 0x60
mask WR_DFTHRSH_MAX 0x70
}
register SG_CACHE_PRE {
access_mode WO
address 0x0fc
mask SG_ADDR_MASK 0xf8
bit ODD_SEG 0x04
bit LAST_SEG 0x02
bit LAST_SEG_DONE 0x01
}
register SG_CACHE_SHADOW {
access_mode RO
address 0x0fc
mask SG_ADDR_MASK 0xf8
bit ODD_SEG 0x04
bit LAST_SEG 0x02
bit LAST_SEG_DONE 0x01
}
/* ---------------------- Scratch RAM Offsets ------------------------- */
/* These offsets are either to values that are initialized by the board's
* BIOS or are specified by the sequencer code.
*
* The host adapter card (at least the BIOS) uses 20-2f for SCSI
* device information, 32-33 and 5a-5f as well. As it turns out, the
* BIOS trashes 20-2f, writing the synchronous negotiation results
* on top of the BIOS values, so we re-use those for our per-target
* scratchspace (actually a value that can be copied directly into
* SCSIRATE). The kernel driver will enable synchronous negotiation
* for all targets that have a value other than 0 in the lower four
* bits of the target scratch space. This should work regardless of
* whether the bios has been installed.
*/
scratch_ram {
address 0x020
/*
* 1 byte per target starting at this address for configuration values
*/
CMDSIZE_TABLE {
alias TARG_SCSIRATE
size 8
}
BUSY_TARGETS {
size 8
}
/*
* Bit vector of targets that have ULTRA enabled as set by
* the BIOS. The Sequencer relies on a per-SCB field to
* control whether to enable Ultra transfers or not. During
* initialization, we read this field and reuse it for 2
* entries in the busy target table.
*/
ULTRA_ENB {
size 2
}
/*
* Bit vector of targets that have disconnection disabled as set by
* the BIOS. The Sequencer relies in a per-SCB field to control the
* disconnect priveldge. During initialization, we read this field
* and reuse it for 2 entries in the busy target table.
*/
DISC_DSB {
size 2
}
BUSY_TARGETS_TAIL {
size 4
}
/*
* Partial transfer past cacheline end to be
* transferred using an extra S/G.
*/
MWI_RESIDUAL {
size 1
}
/*
* SCBID of the next SCB to be started by the controller.
*/
NEXT_QUEUED_SCB {
size 1
}
/*
* Single byte buffer used to designate the type or message
* to send to a target.
*/
MSG_OUT {
size 1
}
/* Parameters for DMA Logic */
DMAPARAMS {
size 1
bit PRELOADEN 0x80
bit WIDEODD 0x40
bit SCSIEN 0x20
bit SDMAEN 0x10
bit SDMAENACK 0x10
bit HDMAEN 0x08
bit HDMAENACK 0x08
bit DIRECTION 0x04
bit FIFOFLUSH 0x02
bit FIFORESET 0x01
}
SEQ_FLAGS {
size 1
bit IDENTIFY_SEEN 0x80
bit TARGET_CMD_IS_TAGGED 0x40
bit DPHASE 0x20
/* Target flags */
bit TARG_CMD_PENDING 0x10
bit CMDPHASE_PENDING 0x08
bit DPHASE_PENDING 0x04
bit SPHASE_PENDING 0x02
bit NO_DISCONNECT 0x01
}
/*
* Temporary storage for the
* target/channel/lun of a
* reconnecting target
*/
SAVED_SCSIID {
size 1
}
SAVED_LUN {
size 1
}
/*
* The last bus phase as seen by the sequencer.
*/
LASTPHASE {
size 1
bit CDI 0x80
bit IOI 0x40
bit MSGI 0x20
mask PHASE_MASK CDI|IOI|MSGI
mask P_DATAOUT 0x00
mask P_DATAIN IOI
mask P_COMMAND CDI
mask P_MESGOUT CDI|MSGI
mask P_STATUS CDI|IOI
mask P_MESGIN CDI|IOI|MSGI
mask P_BUSFREE 0x01
}
/*
* head of list of SCBs awaiting
* selection
*/
WAITING_SCBH {
size 1
}
/*
* head of list of SCBs that are
* disconnected. Used for SCB
* paging.
*/
DISCONNECTED_SCBH {
size 1
}
/*
* head of list of SCBs that are
* not in use. Used for SCB paging.
*/
FREE_SCBH {
size 1
}
/*
* Address of the hardware scb array in the host.
*/
HSCB_ADDR {
size 4
}
/*
* Base address of our shared data with the kernel driver in host
* memory. This includes the qoutfifo and target mode
* incoming command queue.
*/
SHARED_DATA_ADDR {
size 4
}
KERNEL_QINPOS {
size 1
}
QINPOS {
size 1
}
QOUTPOS {
size 1
}
/*
* Kernel and sequencer offsets into the queue of
* incoming target mode command descriptors. The
* queue is full when the KERNEL_TQINPOS == TQINPOS.
*/
KERNEL_TQINPOS {
size 1
}
TQINPOS {
size 1
}
ARG_1 {
size 1
mask SEND_MSG 0x80
mask SEND_SENSE 0x40
mask SEND_REJ 0x20
mask MSGOUT_PHASEMIS 0x10
mask EXIT_MSG_LOOP 0x08
mask CONT_MSG_LOOP 0x04
mask CONT_TARG_SESSION 0x02
alias RETURN_1
}
ARG_2 {
size 1
alias RETURN_2
}
/*
* Snapshot of MSG_OUT taken after each message is sent.
*/
LAST_MSG {
size 1
}
/*
* Interrupt kernel for a message to this target on
* the next transaction. This is usually used for
* negotiation requests.
*/
TARGET_MSG_REQUEST {
size 2
}
/*
* Sequences the kernel driver has okayed for us. This allows
* the driver to do things like prevent initiator or target
* operations.
*/
SCSISEQ_TEMPLATE {
size 1
bit ENSELO 0x40
bit ENSELI 0x20
bit ENRSELI 0x10
bit ENAUTOATNO 0x08
bit ENAUTOATNI 0x04
bit ENAUTOATNP 0x02
}
/*
* Track whether the transfer byte count for
* the current data phase is odd.
*/
DATA_COUNT_ODD {
size 1
}
/*
* The initiator specified tag for this target mode transaction.
*/
INITIATOR_TAG {
size 1
}
/*
* These are reserved registers in the card's scratch ram. Some of
* the values are specified in the AHA2742 technical reference manual
* and are initialized by the BIOS at boot time.
*/
SCSICONF {
address 0x05a
size 1
bit TERM_ENB 0x80
bit RESET_SCSI 0x40
bit ENSPCHK 0x20
mask HSCSIID 0x07 /* our SCSI ID */
mask HWSCSIID 0x0f /* our SCSI ID if Wide Bus */
}
INTDEF {
address 0x05c
size 1
bit EDGE_TRIG 0x80
mask VECTOR 0x0f
}
HOSTCONF {
address 0x05d
size 1
}
HA_274_BIOSCTRL {
address 0x05f
size 1
mask BIOSMODE 0x30
mask BIOSDISABLED 0x30
bit CHANNEL_B_PRIMARY 0x08
}
/*
* Per target SCSI offset values for Ultra2 controllers.
*/
TARG_OFFSET {
address 0x070
size 16
}
}
const TID_SHIFT 4
const SCB_LIST_NULL 0xff
const TARGET_CMD_CMPLT 0xfe
const CCSGADDR_MAX 0x80
const CCSGRAM_MAXSEGS 16
/* WDTR Message values */
const BUS_8_BIT 0x00
const BUS_16_BIT 0x01
const BUS_32_BIT 0x02
/* Offset maximums */
const MAX_OFFSET_8BIT 0x0f
const MAX_OFFSET_16BIT 0x08
const MAX_OFFSET_ULTRA2 0x7f
const HOST_MSG 0xff
/* Target mode command processing constants */
const CMD_GROUP_CODE_SHIFT 0x05
const STATUS_BUSY 0x08
const STATUS_QUEUE_FULL 0x28
const SCB_TARGET_PHASES 0
const SCB_TARGET_DATA_DIR 1
const SCB_TARGET_STATUS 2
const SCB_INITIATOR_TAG 3
const TARGET_DATA_IN 1
/*
* Downloaded (kernel inserted) constants
*/
/* Offsets into the SCBID array where different data is stored */
const QOUTFIFO_OFFSET download
const QINFIFO_OFFSET download
const CACHESIZE_MASK download
const INVERTED_CACHESIZE_MASK download
const SG_PREFETCH_CNT download
const SG_PREFETCH_ALIGN_MASK download
const SG_PREFETCH_ADDR_MASK download
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