kernel-ark/drivers/scsi/53c7xx.scr

1592 lines
46 KiB
Plaintext
Raw Normal View History

#undef DEBUG
#undef EVENTS
#undef NO_SELECTION_TIMEOUT
#define BIG_ENDIAN
; 53c710 driver. Modified from Drew Eckhardts driver
; for 53c810 by Richard Hirst [richard@sleepie.demon.co.uk]
;
; I have left the script for the 53c8xx family in here, as it is likely
; to be useful to see what I changed when bug hunting.
; NCR 53c810 driver, main script
; Sponsored by
; iX Multiuser Multitasking Magazine
; hm@ix.de
;
; Copyright 1993, 1994, 1995 Drew Eckhardt
; Visionary Computing
; (Unix and Linux consulting and custom programming)
; drew@PoohSticks.ORG
; +1 (303) 786-7975
;
; TolerANT and SCSI SCRIPTS are registered trademarks of NCR Corporation.
;
; PRE-ALPHA
;
; For more information, please consult
;
; NCR 53C810
; PCI-SCSI I/O Processor
; Data Manual
;
; NCR 53C710
; SCSI I/O Processor
; Programmers Guide
;
; NCR Microelectronics
; 1635 Aeroplaza Drive
; Colorado Springs, CO 80916
; 1+ (719) 578-3400
;
; Toll free literature number
; +1 (800) 334-5454
;
; IMPORTANT : This code is self modifying due to the limitations of
; the NCR53c7,8xx series chips. Persons debugging this code with
; the remote debugger should take this into account, and NOT set
; breakpoints in modified instructions.
;
; Design:
; The NCR53c7,8xx family of SCSI chips are busmasters with an onboard
; microcontroller using a simple instruction set.
;
; So, to minimize the effects of interrupt latency, and to maximize
; throughput, this driver offloads the practical maximum amount
; of processing to the SCSI chip while still maintaining a common
; structure.
;
; Where tradeoffs were needed between efficiency on the older
; chips and the newer NCR53c800 series, the NCR53c800 series
; was chosen.
;
; While the NCR53c700 and NCR53c700-66 lacked the facilities to fully
; automate SCSI transfers without host processor intervention, this
; isn't the case with the NCR53c710 and newer chips which allow
;
; - reads and writes to the internal registers from within the SCSI
; scripts, allowing the SCSI SCRIPTS(tm) code to save processor
; state so that multiple threads of execution are possible, and also
; provide an ALU for loop control, etc.
;
; - table indirect addressing for some instructions. This allows
; pointers to be located relative to the DSA ((Data Structure
; Address) register.
;
; These features make it possible to implement a mailbox style interface,
; where the same piece of code is run to handle I/O for multiple threads
; at once minimizing our need to relocate code. Since the NCR53c700/
; NCR53c800 series have a unique combination of features, making a
; a standard ingoing/outgoing mailbox system, costly, I've modified it.
;
; - Mailboxes are a mixture of code and data. This lets us greatly
; simplify the NCR53c810 code and do things that would otherwise
; not be possible.
;
; The saved data pointer is now implemented as follows :
;
; Control flow has been architected such that if control reaches
; munge_save_data_pointer, on a restore pointers message or
; reconnection, a jump to the address formerly in the TEMP register
; will allow the SCSI command to resume execution.
;
;
; Note : the DSA structures must be aligned on 32 bit boundaries,
; since the source and destination of MOVE MEMORY instructions
; must share the same alignment and this is the alignment of the
; NCR registers.
;
; For some systems (MVME166, for example) dmode is always the same, so don't
; waste time writing it
#if 1
#define DMODE_MEMORY_TO_NCR
#define DMODE_MEMORY_TO_MEMORY
#define DMODE_NCR_TO_MEMORY
#else
#define DMODE_MEMORY_TO_NCR MOVE dmode_memory_to_ncr TO DMODE
#define DMODE_MEMORY_TO_MEMORY MOVE dmode_memory_to_memory TO DMODE
#define DMODE_NCR_TO_MEMORY MOVE dmode_ncr_to_memory TO DMODE
#endif
ABSOLUTE dsa_temp_lun = 0 ; Patch to lun for current dsa
ABSOLUTE dsa_temp_next = 0 ; Patch to dsa next for current dsa
ABSOLUTE dsa_temp_addr_next = 0 ; Patch to address of dsa next address
; for current dsa
ABSOLUTE dsa_temp_sync = 0 ; Patch to address of per-target
; sync routine
ABSOLUTE dsa_sscf_710 = 0 ; Patch to address of per-target
; sscf value (53c710)
ABSOLUTE dsa_temp_target = 0 ; Patch to id for current dsa
ABSOLUTE dsa_temp_addr_saved_pointer = 0; Patch to address of per-command
; saved data pointer
ABSOLUTE dsa_temp_addr_residual = 0 ; Patch to address of per-command
; current residual code
ABSOLUTE dsa_temp_addr_saved_residual = 0; Patch to address of per-command
; saved residual code
ABSOLUTE dsa_temp_addr_new_value = 0 ; Address of value for JUMP operand
ABSOLUTE dsa_temp_addr_array_value = 0 ; Address to copy to
ABSOLUTE dsa_temp_addr_dsa_value = 0 ; Address of this DSA value
;
; Once a device has initiated reselection, we need to compare it
; against the singly linked list of commands which have disconnected
; and are pending reselection. These commands are maintained in
; an unordered singly linked list of DSA structures, through the
; DSA pointers at their 'centers' headed by the reconnect_dsa_head
; pointer.
;
; To avoid complications in removing commands from the list,
; I minimize the amount of expensive (at eight operations per
; addition @ 500-600ns each) pointer operations which must
; be done in the NCR driver by precomputing them on the
; host processor during dsa structure generation.
;
; The fixed-up per DSA code knows how to recognize the nexus
; associated with the corresponding SCSI command, and modifies
; the source and destination pointers for the MOVE MEMORY
; instruction which is executed when reselected_ok is called
; to remove the command from the list. Similarly, DSA is
; loaded with the address of the next DSA structure and
; reselected_check_next is called if a failure occurs.
;
; Perhaps more concisely, the net effect of the mess is
;
; for (dsa = reconnect_dsa_head, dest = &reconnect_dsa_head,
; src = NULL; dsa; dest = &dsa->next, dsa = dsa->next) {
; src = &dsa->next;
; if (target_id == dsa->id && target_lun == dsa->lun) {
; *dest = *src;
; break;
; }
; }
;
; if (!dsa)
; error (int_err_unexpected_reselect);
; else
; longjmp (dsa->jump_resume, 0);
;
;
#if (CHIP != 700) && (CHIP != 70066)
; Define DSA structure used for mailboxes
ENTRY dsa_code_template
dsa_code_template:
ENTRY dsa_code_begin
dsa_code_begin:
; RGH: Don't care about TEMP and DSA here
DMODE_MEMORY_TO_NCR
MOVE MEMORY 4, dsa_temp_addr_dsa_value, addr_scratch
DMODE_MEMORY_TO_MEMORY
#if (CHIP == 710)
MOVE MEMORY 4, addr_scratch, saved_dsa
; We are about to go and select the device, so must set SSCF bits
MOVE MEMORY 4, dsa_sscf_710, addr_scratch
#ifdef BIG_ENDIAN
MOVE SCRATCH3 TO SFBR
#else
MOVE SCRATCH0 TO SFBR
#endif
MOVE SFBR TO SBCL
MOVE MEMORY 4, saved_dsa, addr_dsa
#else
CALL scratch_to_dsa
#endif
CALL select
; Handle the phase mismatch which may have resulted from the
; MOVE FROM dsa_msgout if we returned here. The CLEAR ATN
; may or may not be necessary, and we should update script_asm.pl
; to handle multiple pieces.
CLEAR ATN
CLEAR ACK
; Replace second operand with address of JUMP instruction dest operand
; in schedule table for this DSA. Becomes dsa_jump_dest in 53c7,8xx.c.
ENTRY dsa_code_fix_jump
dsa_code_fix_jump:
MOVE MEMORY 4, NOP_insn, 0
JUMP select_done
; wrong_dsa loads the DSA register with the value of the dsa_next
; field.
;
wrong_dsa:
#if (CHIP == 710)
; NOTE DSA is corrupt when we arrive here!
#endif
; Patch the MOVE MEMORY INSTRUCTION such that
; the destination address is the address of the OLD
; next pointer.
;
MOVE MEMORY 4, dsa_temp_addr_next, reselected_ok_patch + 8
DMODE_MEMORY_TO_NCR
;
; Move the _contents_ of the next pointer into the DSA register as
; the next I_T_L or I_T_L_Q tupple to check against the established
; nexus.
;
MOVE MEMORY 4, dsa_temp_next, addr_scratch
DMODE_MEMORY_TO_MEMORY
#if (CHIP == 710)
MOVE MEMORY 4, addr_scratch, saved_dsa
MOVE MEMORY 4, saved_dsa, addr_dsa
#else
CALL scratch_to_dsa
#endif
JUMP reselected_check_next
ABSOLUTE dsa_save_data_pointer = 0
ENTRY dsa_code_save_data_pointer
dsa_code_save_data_pointer:
#if (CHIP == 710)
; When we get here, TEMP has been saved in jump_temp+4, DSA is corrupt
; We MUST return with DSA correct
MOVE MEMORY 4, jump_temp+4, dsa_temp_addr_saved_pointer
; HARD CODED : 24 bytes needs to agree with 53c7,8xx.h
MOVE MEMORY 24, dsa_temp_addr_residual, dsa_temp_addr_saved_residual
CLEAR ACK
#ifdef DEBUG
INT int_debug_saved
#endif
MOVE MEMORY 4, saved_dsa, addr_dsa
JUMP jump_temp
#else
DMODE_NCR_TO_MEMORY
MOVE MEMORY 4, addr_temp, dsa_temp_addr_saved_pointer
DMODE_MEMORY_TO_MEMORY
; HARD CODED : 24 bytes needs to agree with 53c7,8xx.h
MOVE MEMORY 24, dsa_temp_addr_residual, dsa_temp_addr_saved_residual
CLEAR ACK
#ifdef DEBUG
INT int_debug_saved
#endif
RETURN
#endif
ABSOLUTE dsa_restore_pointers = 0
ENTRY dsa_code_restore_pointers
dsa_code_restore_pointers:
#if (CHIP == 710)
; TEMP and DSA are corrupt when we get here, but who cares!
MOVE MEMORY 4, dsa_temp_addr_saved_pointer, jump_temp + 4
; HARD CODED : 24 bytes needs to agree with 53c7,8xx.h
MOVE MEMORY 24, dsa_temp_addr_saved_residual, dsa_temp_addr_residual
CLEAR ACK
; Restore DSA, note we don't care about TEMP
MOVE MEMORY 4, saved_dsa, addr_dsa
#ifdef DEBUG
INT int_debug_restored
#endif
JUMP jump_temp
#else
DMODE_MEMORY_TO_NCR
MOVE MEMORY 4, dsa_temp_addr_saved_pointer, addr_temp
DMODE_MEMORY_TO_MEMORY
; HARD CODED : 24 bytes needs to agree with 53c7,8xx.h
MOVE MEMORY 24, dsa_temp_addr_saved_residual, dsa_temp_addr_residual
CLEAR ACK
#ifdef DEBUG
INT int_debug_restored
#endif
RETURN
#endif
ABSOLUTE dsa_check_reselect = 0
; dsa_check_reselect determines whether or not the current target and
; lun match the current DSA
ENTRY dsa_code_check_reselect
dsa_code_check_reselect:
#if (CHIP == 710)
/* Arrives here with DSA correct */
/* Assumes we are always ID 7 */
MOVE LCRC TO SFBR ; LCRC has our ID and his ID bits set
JUMP REL (wrong_dsa), IF NOT dsa_temp_target, AND MASK 0x80
#else
MOVE SSID TO SFBR ; SSID contains 3 bit target ID
; FIXME : we need to accommodate bit fielded and binary here for '7xx/'8xx chips
JUMP REL (wrong_dsa), IF NOT dsa_temp_target, AND MASK 0xf8
#endif
;
; Hack - move to scratch first, since SFBR is not writeable
; via the CPU and hence a MOVE MEMORY instruction.
;
DMODE_MEMORY_TO_NCR
MOVE MEMORY 1, reselected_identify, addr_scratch
DMODE_MEMORY_TO_MEMORY
#ifdef BIG_ENDIAN
; BIG ENDIAN ON MVME16x
MOVE SCRATCH3 TO SFBR
#else
MOVE SCRATCH0 TO SFBR
#endif
; FIXME : we need to accommodate bit fielded and binary here for '7xx/'8xx chips
; Are you sure about that? richard@sleepie.demon.co.uk
JUMP REL (wrong_dsa), IF NOT dsa_temp_lun, AND MASK 0xf8
; Patch the MOVE MEMORY INSTRUCTION such that
; the source address is the address of this dsa's
; next pointer.
MOVE MEMORY 4, dsa_temp_addr_next, reselected_ok_patch + 4
CALL reselected_ok
#if (CHIP == 710)
; Restore DSA following memory moves in reselected_ok
; dsa_temp_sync doesn't really care about DSA, but it has an
; optional debug INT so a valid DSA is a good idea.
MOVE MEMORY 4, saved_dsa, addr_dsa
#endif
CALL dsa_temp_sync
; Release ACK on the IDENTIFY message _after_ we've set the synchronous
; transfer parameters!
CLEAR ACK
; Implicitly restore pointers on reselection, so a RETURN
; will transfer control back to the right spot.
CALL REL (dsa_code_restore_pointers)
RETURN
ENTRY dsa_zero
dsa_zero:
ENTRY dsa_code_template_end
dsa_code_template_end:
; Perform sanity check for dsa_fields_start == dsa_code_template_end -
; dsa_zero, puke.
ABSOLUTE dsa_fields_start = 0 ; Sanity marker
; pad 48 bytes (fix this RSN)
ABSOLUTE dsa_next = 48 ; len 4 Next DSA
; del 4 Previous DSA address
ABSOLUTE dsa_cmnd = 56 ; len 4 Scsi_Cmnd * for this thread.
ABSOLUTE dsa_select = 60 ; len 4 Device ID, Period, Offset for
; table indirect select
ABSOLUTE dsa_msgout = 64 ; len 8 table indirect move parameter for
; select message
ABSOLUTE dsa_cmdout = 72 ; len 8 table indirect move parameter for
; command
ABSOLUTE dsa_dataout = 80 ; len 4 code pointer for dataout
ABSOLUTE dsa_datain = 84 ; len 4 code pointer for datain
ABSOLUTE dsa_msgin = 88 ; len 8 table indirect move for msgin
ABSOLUTE dsa_status = 96 ; len 8 table indirect move for status byte
ABSOLUTE dsa_msgout_other = 104 ; len 8 table indirect for normal message out
; (Synchronous transfer negotiation, etc).
ABSOLUTE dsa_end = 112
ABSOLUTE schedule = 0 ; Array of JUMP dsa_begin or JUMP (next),
; terminated by a call to JUMP wait_reselect
; Linked lists of DSA structures
ABSOLUTE reconnect_dsa_head = 0 ; Link list of DSAs which can reconnect
ABSOLUTE addr_reconnect_dsa_head = 0 ; Address of variable containing
; address of reconnect_dsa_head
; These select the source and destination of a MOVE MEMORY instruction
ABSOLUTE dmode_memory_to_memory = 0x0
ABSOLUTE dmode_memory_to_ncr = 0x0
ABSOLUTE dmode_ncr_to_memory = 0x0
ABSOLUTE addr_scratch = 0x0
ABSOLUTE addr_temp = 0x0
#if (CHIP == 710)
ABSOLUTE saved_dsa = 0x0
ABSOLUTE emulfly = 0x0
ABSOLUTE addr_dsa = 0x0
#endif
#endif /* CHIP != 700 && CHIP != 70066 */
; Interrupts -
; MSB indicates type
; 0 handle error condition
; 1 handle message
; 2 handle normal condition
; 3 debugging interrupt
; 4 testing interrupt
; Next byte indicates specific error
; XXX not yet implemented, I'm not sure if I want to -
; Next byte indicates the routine the error occurred in
; The LSB indicates the specific place the error occurred
ABSOLUTE int_err_unexpected_phase = 0x00000000 ; Unexpected phase encountered
ABSOLUTE int_err_selected = 0x00010000 ; SELECTED (nee RESELECTED)
ABSOLUTE int_err_unexpected_reselect = 0x00020000
ABSOLUTE int_err_check_condition = 0x00030000
ABSOLUTE int_err_no_phase = 0x00040000
ABSOLUTE int_msg_wdtr = 0x01000000 ; WDTR message received
ABSOLUTE int_msg_sdtr = 0x01010000 ; SDTR received
ABSOLUTE int_msg_1 = 0x01020000 ; single byte special message
; received
ABSOLUTE int_norm_select_complete = 0x02000000 ; Select complete, reprogram
; registers.
ABSOLUTE int_norm_reselect_complete = 0x02010000 ; Nexus established
ABSOLUTE int_norm_command_complete = 0x02020000 ; Command complete
ABSOLUTE int_norm_disconnected = 0x02030000 ; Disconnected
ABSOLUTE int_norm_aborted =0x02040000 ; Aborted *dsa
ABSOLUTE int_norm_reset = 0x02050000 ; Generated BUS reset.
ABSOLUTE int_norm_emulateintfly = 0x02060000 ; 53C710 Emulated intfly
ABSOLUTE int_debug_break = 0x03000000 ; Break point
#ifdef DEBUG
ABSOLUTE int_debug_scheduled = 0x03010000 ; new I/O scheduled
ABSOLUTE int_debug_idle = 0x03020000 ; scheduler is idle
ABSOLUTE int_debug_dsa_loaded = 0x03030000 ; dsa reloaded
ABSOLUTE int_debug_reselected = 0x03040000 ; NCR reselected
ABSOLUTE int_debug_head = 0x03050000 ; issue head overwritten
ABSOLUTE int_debug_disconnected = 0x03060000 ; disconnected
ABSOLUTE int_debug_disconnect_msg = 0x03070000 ; got message to disconnect
ABSOLUTE int_debug_dsa_schedule = 0x03080000 ; in dsa_schedule
ABSOLUTE int_debug_reselect_check = 0x03090000 ; Check for reselection of DSA
ABSOLUTE int_debug_reselected_ok = 0x030a0000 ; Reselection accepted
#endif
ABSOLUTE int_debug_panic = 0x030b0000 ; Panic driver
#ifdef DEBUG
ABSOLUTE int_debug_saved = 0x030c0000 ; save/restore pointers
ABSOLUTE int_debug_restored = 0x030d0000
ABSOLUTE int_debug_sync = 0x030e0000 ; Sanity check synchronous
; parameters.
ABSOLUTE int_debug_datain = 0x030f0000 ; going into data in phase
; now.
ABSOLUTE int_debug_check_dsa = 0x03100000 ; Sanity check DSA against
; SDID.
#endif
ABSOLUTE int_test_1 = 0x04000000 ; Test 1 complete
ABSOLUTE int_test_2 = 0x04010000 ; Test 2 complete
ABSOLUTE int_test_3 = 0x04020000 ; Test 3 complete
; These should start with 0x05000000, with low bits incrementing for
; each one.
#ifdef EVENTS
ABSOLUTE int_EVENT_SELECT = 0
ABSOLUTE int_EVENT_DISCONNECT = 0
ABSOLUTE int_EVENT_RESELECT = 0
ABSOLUTE int_EVENT_COMPLETE = 0
ABSOLUTE int_EVENT_IDLE = 0
ABSOLUTE int_EVENT_SELECT_FAILED = 0
ABSOLUTE int_EVENT_BEFORE_SELECT = 0
ABSOLUTE int_EVENT_RESELECT_FAILED = 0
#endif
ABSOLUTE NCR53c7xx_msg_abort = 0 ; Pointer to abort message
ABSOLUTE NCR53c7xx_msg_reject = 0 ; Pointer to reject message
ABSOLUTE NCR53c7xx_zero = 0 ; long with zero in it, use for source
ABSOLUTE NCR53c7xx_sink = 0 ; long to dump worthless data in
ABSOLUTE NOP_insn = 0 ; NOP instruction
; Pointer to message, potentially multi-byte
ABSOLUTE msg_buf = 0
; Pointer to holding area for reselection information
ABSOLUTE reselected_identify = 0
ABSOLUTE reselected_tag = 0
; Request sense command pointer, it's a 6 byte command, should
; be constant for all commands since we always want 16 bytes of
; sense and we don't need to change any fields as we did under
; SCSI-I when we actually cared about the LUN field.
;EXTERNAL NCR53c7xx_sense ; Request sense command
#if (CHIP != 700) && (CHIP != 70066)
; dsa_schedule
; PURPOSE : after a DISCONNECT message has been received, and pointers
; saved, insert the current DSA structure at the head of the
; disconnected queue and fall through to the scheduler.
;
; CALLS : OK
;
; INPUTS : dsa - current DSA structure, reconnect_dsa_head - list
; of disconnected commands
;
; MODIFIES : SCRATCH, reconnect_dsa_head
;
; EXITS : always passes control to schedule
ENTRY dsa_schedule
dsa_schedule:
#ifdef DEBUG
INT int_debug_dsa_schedule
#endif
;
; Calculate the address of the next pointer within the DSA
; structure of the command that is currently disconnecting
;
#if (CHIP == 710)
; Read what should be the current DSA from memory - actual DSA
; register is probably corrupt
MOVE MEMORY 4, saved_dsa, addr_scratch
#else
CALL dsa_to_scratch
#endif
MOVE SCRATCH0 + dsa_next TO SCRATCH0
MOVE SCRATCH1 + 0 TO SCRATCH1 WITH CARRY
MOVE SCRATCH2 + 0 TO SCRATCH2 WITH CARRY
MOVE SCRATCH3 + 0 TO SCRATCH3 WITH CARRY
; Point the next field of this DSA structure at the current disconnected
; list
DMODE_NCR_TO_MEMORY
MOVE MEMORY 4, addr_scratch, dsa_schedule_insert + 8
DMODE_MEMORY_TO_MEMORY
dsa_schedule_insert:
MOVE MEMORY 4, reconnect_dsa_head, 0
; And update the head pointer.
#if (CHIP == 710)
; Read what should be the current DSA from memory - actual DSA
; register is probably corrupt
MOVE MEMORY 4, saved_dsa, addr_scratch
#else
CALL dsa_to_scratch
#endif
DMODE_NCR_TO_MEMORY
MOVE MEMORY 4, addr_scratch, reconnect_dsa_head
DMODE_MEMORY_TO_MEMORY
/* Temporarily, see what happens. */
#ifndef ORIGINAL
#if (CHIP != 710)
MOVE SCNTL2 & 0x7f TO SCNTL2
#endif
CLEAR ACK
#endif
#if (CHIP == 710)
; Time to correct DSA following memory move
MOVE MEMORY 4, saved_dsa, addr_dsa
#endif
WAIT DISCONNECT
#ifdef EVENTS
INT int_EVENT_DISCONNECT;
#endif
#ifdef DEBUG
INT int_debug_disconnected
#endif
JUMP schedule
#endif
;
; select
;
; PURPOSE : establish a nexus for the SCSI command referenced by DSA.
; On success, the current DSA structure is removed from the issue
; queue. Usually, this is entered as a fall-through from schedule,
; although the contingent allegiance handling code will write
; the select entry address to the DSP to restart a command as a
; REQUEST SENSE. A message is sent (usually IDENTIFY, although
; additional SDTR or WDTR messages may be sent). COMMAND OUT
; is handled.
;
; INPUTS : DSA - SCSI command, issue_dsa_head
;
; CALLS : NOT OK
;
; MODIFIES : SCRATCH, issue_dsa_head
;
; EXITS : on reselection or selection, go to select_failed
; otherwise, RETURN so control is passed back to
; dsa_begin.
;
ENTRY select
select:
#ifdef EVENTS
INT int_EVENT_BEFORE_SELECT
#endif
#ifdef DEBUG
INT int_debug_scheduled
#endif
CLEAR TARGET
; XXX
;
; In effect, SELECTION operations are backgrounded, with execution
; continuing until code which waits for REQ or a fatal interrupt is
; encountered.
;
; So, for more performance, we could overlap the code which removes
; the command from the NCRs issue queue with the selection, but
; at this point I don't want to deal with the error recovery.
;
#if (CHIP != 700) && (CHIP != 70066)
#if (CHIP == 710)
; Enable selection timer
#ifdef NO_SELECTION_TIMEOUT
MOVE CTEST7 & 0xff TO CTEST7
#else
MOVE CTEST7 & 0xef TO CTEST7
#endif
#endif
SELECT ATN FROM dsa_select, select_failed
JUMP select_msgout, WHEN MSG_OUT
ENTRY select_msgout
select_msgout:
#if (CHIP == 710)
; Disable selection timer
MOVE CTEST7 | 0x10 TO CTEST7
#endif
MOVE FROM dsa_msgout, WHEN MSG_OUT
#else
ENTRY select_msgout
SELECT ATN 0, select_failed
select_msgout:
MOVE 0, 0, WHEN MSGOUT
#endif
#ifdef EVENTS
INT int_EVENT_SELECT
#endif
RETURN
;
; select_done
;
; PURPOSE: continue on to normal data transfer; called as the exit
; point from dsa_begin.
;
; INPUTS: dsa
;
; CALLS: OK
;
;
select_done:
#if (CHIP == 710)
; NOTE DSA is corrupt when we arrive here!
MOVE MEMORY 4, saved_dsa, addr_dsa
#endif
#ifdef DEBUG
ENTRY select_check_dsa
select_check_dsa:
INT int_debug_check_dsa
#endif
; After a successful selection, we should get either a CMD phase or
; some transfer request negotiation message.
JUMP cmdout, WHEN CMD
INT int_err_unexpected_phase, WHEN NOT MSG_IN
select_msg_in:
CALL msg_in, WHEN MSG_IN
JUMP select_msg_in, WHEN MSG_IN
cmdout:
INT int_err_unexpected_phase, WHEN NOT CMD
#if (CHIP == 700)
INT int_norm_selected
#endif
ENTRY cmdout_cmdout
cmdout_cmdout:
#if (CHIP != 700) && (CHIP != 70066)
MOVE FROM dsa_cmdout, WHEN CMD
#else
MOVE 0, 0, WHEN CMD
#endif /* (CHIP != 700) && (CHIP != 70066) */
;
; data_transfer
; other_out
; other_in
; other_transfer
;
; PURPOSE : handle the main data transfer for a SCSI command in
; several parts. In the first part, data_transfer, DATA_IN
; and DATA_OUT phases are allowed, with the user provided
; code (usually dynamically generated based on the scatter/gather
; list associated with a SCSI command) called to handle these
; phases.
;
; After control has passed to one of the user provided
; DATA_IN or DATA_OUT routines, back calls are made to
; other_transfer_in or other_transfer_out to handle non-DATA IN
; and DATA OUT phases respectively, with the state of the active
; data pointer being preserved in TEMP.
;
; On completion, the user code passes control to other_transfer
; which causes DATA_IN and DATA_OUT to result in unexpected_phase
; interrupts so that data overruns may be trapped.
;
; INPUTS : DSA - SCSI command
;
; CALLS : OK in data_transfer_start, not ok in other_out and other_in, ok in
; other_transfer
;
; MODIFIES : SCRATCH
;
; EXITS : if STATUS IN is detected, signifying command completion,
; the NCR jumps to command_complete. If MSG IN occurs, a
; CALL is made to msg_in. Otherwise, other_transfer runs in
; an infinite loop.
;
ENTRY data_transfer
data_transfer:
JUMP cmdout_cmdout, WHEN CMD
CALL msg_in, WHEN MSG_IN
INT int_err_unexpected_phase, WHEN MSG_OUT
JUMP do_dataout, WHEN DATA_OUT
JUMP do_datain, WHEN DATA_IN
JUMP command_complete, WHEN STATUS
JUMP data_transfer
ENTRY end_data_transfer
end_data_transfer:
;
; FIXME: On NCR53c700 and NCR53c700-66 chips, do_dataout/do_datain
; should be fixed up whenever the nexus changes so it can point to the
; correct routine for that command.
;
#if (CHIP != 700) && (CHIP != 70066)
; Nasty jump to dsa->dataout
do_dataout:
#if (CHIP == 710)
MOVE MEMORY 4, saved_dsa, addr_scratch
#else
CALL dsa_to_scratch
#endif
MOVE SCRATCH0 + dsa_dataout TO SCRATCH0
MOVE SCRATCH1 + 0 TO SCRATCH1 WITH CARRY
MOVE SCRATCH2 + 0 TO SCRATCH2 WITH CARRY
MOVE SCRATCH3 + 0 TO SCRATCH3 WITH CARRY
DMODE_NCR_TO_MEMORY
MOVE MEMORY 4, addr_scratch, dataout_to_jump + 4
DMODE_MEMORY_TO_MEMORY
dataout_to_jump:
MOVE MEMORY 4, 0, dataout_jump + 4
#if (CHIP == 710)
; Time to correct DSA following memory move
MOVE MEMORY 4, saved_dsa, addr_dsa
#endif
dataout_jump:
JUMP 0
; Nasty jump to dsa->dsain
do_datain:
#if (CHIP == 710)
MOVE MEMORY 4, saved_dsa, addr_scratch
#else
CALL dsa_to_scratch
#endif
MOVE SCRATCH0 + dsa_datain TO SCRATCH0
MOVE SCRATCH1 + 0 TO SCRATCH1 WITH CARRY
MOVE SCRATCH2 + 0 TO SCRATCH2 WITH CARRY
MOVE SCRATCH3 + 0 TO SCRATCH3 WITH CARRY
DMODE_NCR_TO_MEMORY
MOVE MEMORY 4, addr_scratch, datain_to_jump + 4
DMODE_MEMORY_TO_MEMORY
ENTRY datain_to_jump
datain_to_jump:
MOVE MEMORY 4, 0, datain_jump + 4
#if (CHIP == 710)
; Time to correct DSA following memory move
MOVE MEMORY 4, saved_dsa, addr_dsa
#endif
#ifdef DEBUG
INT int_debug_datain
#endif
datain_jump:
JUMP 0
#endif /* (CHIP != 700) && (CHIP != 70066) */
; Note that other_out and other_in loop until a non-data phase
; is discovered, so we only execute return statements when we
; can go on to the next data phase block move statement.
ENTRY other_out
other_out:
#if 0
INT 0x03ffdead
#endif
INT int_err_unexpected_phase, WHEN CMD
JUMP msg_in_restart, WHEN MSG_IN
INT int_err_unexpected_phase, WHEN MSG_OUT
INT int_err_unexpected_phase, WHEN DATA_IN
JUMP command_complete, WHEN STATUS
JUMP other_out, WHEN NOT DATA_OUT
#if (CHIP == 710)
; TEMP should be OK, as we got here from a call in the user dataout code.
#endif
RETURN
ENTRY other_in
other_in:
#if 0
INT 0x03ffdead
#endif
INT int_err_unexpected_phase, WHEN CMD
JUMP msg_in_restart, WHEN MSG_IN
INT int_err_unexpected_phase, WHEN MSG_OUT
INT int_err_unexpected_phase, WHEN DATA_OUT
JUMP command_complete, WHEN STATUS
JUMP other_in, WHEN NOT DATA_IN
#if (CHIP == 710)
; TEMP should be OK, as we got here from a call in the user datain code.
#endif
RETURN
ENTRY other_transfer
other_transfer:
INT int_err_unexpected_phase, WHEN CMD
CALL msg_in, WHEN MSG_IN
INT int_err_unexpected_phase, WHEN MSG_OUT
INT int_err_unexpected_phase, WHEN DATA_OUT
INT int_err_unexpected_phase, WHEN DATA_IN
JUMP command_complete, WHEN STATUS
JUMP other_transfer
;
; msg_in_restart
; msg_in
; munge_msg
;
; PURPOSE : process messages from a target. msg_in is called when the
; caller hasn't read the first byte of the message. munge_message
; is called when the caller has read the first byte of the message,
; and left it in SFBR. msg_in_restart is called when the caller
; hasn't read the first byte of the message, and wishes RETURN
; to transfer control back to the address of the conditional
; CALL instruction rather than to the instruction after it.
;
; Various int_* interrupts are generated when the host system
; needs to intervene, as is the case with SDTR, WDTR, and
; INITIATE RECOVERY messages.
;
; When the host system handles one of these interrupts,
; it can respond by reentering at reject_message,
; which rejects the message and returns control to
; the caller of msg_in or munge_msg, accept_message
; which clears ACK and returns control, or reply_message
; which sends the message pointed to by the DSA
; msgout_other table indirect field.
;
; DISCONNECT messages are handled by moving the command
; to the reconnect_dsa_queue.
#if (CHIP == 710)
; NOTE: DSA should be valid when we get here - we cannot save both it
; and TEMP in this routine.
#endif
;
; INPUTS : DSA - SCSI COMMAND, SFBR - first byte of message (munge_msg
; only)
;
; CALLS : NO. The TEMP register isn't backed up to allow nested calls.
;
; MODIFIES : SCRATCH, DSA on DISCONNECT
;
; EXITS : On receipt of SAVE DATA POINTER, RESTORE POINTERS,
; and normal return from message handlers running under
; Linux, control is returned to the caller. Receipt
; of DISCONNECT messages pass control to dsa_schedule.
;
ENTRY msg_in_restart
msg_in_restart:
; XXX - hackish
;
; Since it's easier to debug changes to the statically
; compiled code, rather than the dynamically generated
; stuff, such as
;
; MOVE x, y, WHEN data_phase
; CALL other_z, WHEN NOT data_phase
; MOVE x, y, WHEN data_phase
;
; I'd like to have certain routines (notably the message handler)
; restart on the conditional call rather than the next instruction.
;
; So, subtract 8 from the return address
MOVE TEMP0 + 0xf8 TO TEMP0
MOVE TEMP1 + 0xff TO TEMP1 WITH CARRY
MOVE TEMP2 + 0xff TO TEMP2 WITH CARRY
MOVE TEMP3 + 0xff TO TEMP3 WITH CARRY
ENTRY msg_in
msg_in:
MOVE 1, msg_buf, WHEN MSG_IN
munge_msg:
JUMP munge_extended, IF 0x01 ; EXTENDED MESSAGE
JUMP munge_2, IF 0x20, AND MASK 0xdf ; two byte message
;
; XXX - I've seen a handful of broken SCSI devices which fail to issue
; a SAVE POINTERS message before disconnecting in the middle of
; a transfer, assuming that the DATA POINTER will be implicitly
; restored.
;
; Historically, I've often done an implicit save when the DISCONNECT
; message is processed. We may want to consider having the option of
; doing that here.
;
JUMP munge_save_data_pointer, IF 0x02 ; SAVE DATA POINTER
JUMP munge_restore_pointers, IF 0x03 ; RESTORE POINTERS
JUMP munge_disconnect, IF 0x04 ; DISCONNECT
INT int_msg_1, IF 0x07 ; MESSAGE REJECT
INT int_msg_1, IF 0x0f ; INITIATE RECOVERY
#ifdef EVENTS
INT int_EVENT_SELECT_FAILED
#endif
JUMP reject_message
munge_2:
JUMP reject_message
;
; The SCSI standard allows targets to recover from transient
; error conditions by backing up the data pointer with a
; RESTORE POINTERS message.
;
; So, we must save and restore the _residual_ code as well as
; the current instruction pointer. Because of this messiness,
; it is simpler to put dynamic code in the dsa for this and to
; just do a simple jump down there.
;
munge_save_data_pointer:
#if (CHIP == 710)
; We have something in TEMP here, so first we must save that
MOVE TEMP0 TO SFBR
MOVE SFBR TO SCRATCH0
MOVE TEMP1 TO SFBR
MOVE SFBR TO SCRATCH1
MOVE TEMP2 TO SFBR
MOVE SFBR TO SCRATCH2
MOVE TEMP3 TO SFBR
MOVE SFBR TO SCRATCH3
MOVE MEMORY 4, addr_scratch, jump_temp + 4
; Now restore DSA
MOVE MEMORY 4, saved_dsa, addr_dsa
#endif
MOVE DSA0 + dsa_save_data_pointer TO SFBR
MOVE SFBR TO SCRATCH0
MOVE DSA1 + 0xff TO SFBR WITH CARRY
MOVE SFBR TO SCRATCH1
MOVE DSA2 + 0xff TO SFBR WITH CARRY
MOVE SFBR TO SCRATCH2
MOVE DSA3 + 0xff TO SFBR WITH CARRY
MOVE SFBR TO SCRATCH3
DMODE_NCR_TO_MEMORY
MOVE MEMORY 4, addr_scratch, jump_dsa_save + 4
DMODE_MEMORY_TO_MEMORY
jump_dsa_save:
JUMP 0
munge_restore_pointers:
#if (CHIP == 710)
; The code at dsa_restore_pointers will RETURN, but we don't care
; about TEMP here, as it will overwrite it anyway.
#endif
MOVE DSA0 + dsa_restore_pointers TO SFBR
MOVE SFBR TO SCRATCH0
MOVE DSA1 + 0xff TO SFBR WITH CARRY
MOVE SFBR TO SCRATCH1
MOVE DSA2 + 0xff TO SFBR WITH CARRY
MOVE SFBR TO SCRATCH2
MOVE DSA3 + 0xff TO SFBR WITH CARRY
MOVE SFBR TO SCRATCH3
DMODE_NCR_TO_MEMORY
MOVE MEMORY 4, addr_scratch, jump_dsa_restore + 4
DMODE_MEMORY_TO_MEMORY
jump_dsa_restore:
JUMP 0
munge_disconnect:
#ifdef DEBUG
INT int_debug_disconnect_msg
#endif
/*
* Before, we overlapped processing with waiting for disconnect, but
* debugging was beginning to appear messy. Temporarily move things
* to just before the WAIT DISCONNECT.
*/
#ifdef ORIGINAL
#if (CHIP == 710)
; Following clears Unexpected Disconnect bit. What do we do?
#else
MOVE SCNTL2 & 0x7f TO SCNTL2
#endif
CLEAR ACK
#endif
#if (CHIP != 700) && (CHIP != 70066)
JUMP dsa_schedule
#else
WAIT DISCONNECT
INT int_norm_disconnected
#endif
munge_extended:
CLEAR ACK
INT int_err_unexpected_phase, WHEN NOT MSG_IN
MOVE 1, msg_buf + 1, WHEN MSG_IN
JUMP munge_extended_2, IF 0x02
JUMP munge_extended_3, IF 0x03
JUMP reject_message
munge_extended_2:
CLEAR ACK
MOVE 1, msg_buf + 2, WHEN MSG_IN
JUMP reject_message, IF NOT 0x02 ; Must be WDTR
CLEAR ACK
MOVE 1, msg_buf + 3, WHEN MSG_IN
INT int_msg_wdtr
munge_extended_3:
CLEAR ACK
MOVE 1, msg_buf + 2, WHEN MSG_IN
JUMP reject_message, IF NOT 0x01 ; Must be SDTR
CLEAR ACK
MOVE 2, msg_buf + 3, WHEN MSG_IN
INT int_msg_sdtr
ENTRY reject_message
reject_message:
SET ATN
CLEAR ACK
MOVE 1, NCR53c7xx_msg_reject, WHEN MSG_OUT
RETURN
ENTRY accept_message
accept_message:
CLEAR ATN
CLEAR ACK
RETURN
ENTRY respond_message
respond_message:
SET ATN
CLEAR ACK
MOVE FROM dsa_msgout_other, WHEN MSG_OUT
RETURN
;
; command_complete
;
; PURPOSE : handle command termination when STATUS IN is detected by reading
; a status byte followed by a command termination message.
;
; Normal termination results in an INTFLY instruction, and
; the host system can pick out which command terminated by
; examining the MESSAGE and STATUS buffers of all currently
; executing commands;
;
; Abnormal (CHECK_CONDITION) termination results in an
; int_err_check_condition interrupt so that a REQUEST SENSE
; command can be issued out-of-order so that no other command
; clears the contingent allegiance condition.
;
;
; INPUTS : DSA - command
;
; CALLS : OK
;
; EXITS : On successful termination, control is passed to schedule.
; On abnormal termination, the user will usually modify the
; DSA fields and corresponding buffers and return control
; to select.
;
ENTRY command_complete
command_complete:
MOVE FROM dsa_status, WHEN STATUS
#if (CHIP != 700) && (CHIP != 70066)
MOVE SFBR TO SCRATCH0 ; Save status
#endif /* (CHIP != 700) && (CHIP != 70066) */
ENTRY command_complete_msgin
command_complete_msgin:
MOVE FROM dsa_msgin, WHEN MSG_IN
; Indicate that we should be expecting a disconnect
#if (CHIP != 710)
MOVE SCNTL2 & 0x7f TO SCNTL2
#else
; Above code cleared the Unexpected Disconnect bit, what do we do?
#endif
CLEAR ACK
#if (CHIP != 700) && (CHIP != 70066)
WAIT DISCONNECT
;
; The SCSI specification states that when a UNIT ATTENTION condition
; is pending, as indicated by a CHECK CONDITION status message,
; the target shall revert to asynchronous transfers. Since
; synchronous transfers parameters are maintained on a per INITIATOR/TARGET
; basis, and returning control to our scheduler could work on a command
; running on another lun on that target using the old parameters, we must
; interrupt the host processor to get them changed, or change them ourselves.
;
; Once SCSI-II tagged queueing is implemented, things will be even more
; hairy, since contingent allegiance conditions exist on a per-target/lun
; basis, and issuing a new command with a different tag would clear it.
; In these cases, we must interrupt the host processor to get a request
; added to the HEAD of the queue with the request sense command, or we
; must automatically issue the request sense command.
#if 0
MOVE SCRATCH0 TO SFBR
JUMP command_failed, IF 0x02
#endif
#if (CHIP == 710)
#if defined(MVME16x_INTFLY)
; For MVME16x (ie CHIP=710) we will force an INTFLY by triggering a software
; interrupt (SW7). We can use SCRATCH, as we are about to jump to
; schedule, which corrupts it anyway. Will probably remove this later,
; but want to check performance effects first.
#define INTFLY_ADDR 0xfff40070
MOVE 0 TO SCRATCH0
MOVE 0x80 TO SCRATCH1
MOVE 0 TO SCRATCH2
MOVE 0 TO SCRATCH3
MOVE MEMORY 4, addr_scratch, INTFLY_ADDR
#else
INT int_norm_emulateintfly
#endif
#else
INTFLY
#endif
#endif /* (CHIP != 700) && (CHIP != 70066) */
#if (CHIP == 710)
; Time to correct DSA following memory move
MOVE MEMORY 4, saved_dsa, addr_dsa
#endif
#ifdef EVENTS
INT int_EVENT_COMPLETE
#endif
#if (CHIP != 700) && (CHIP != 70066)
JUMP schedule
command_failed:
INT int_err_check_condition
#else
INT int_norm_command_complete
#endif
;
; wait_reselect
;
; PURPOSE : This is essentially the idle routine, where control lands
; when there are no new processes to schedule. wait_reselect
; waits for reselection, selection, and new commands.
;
; When a successful reselection occurs, with the aid
; of fixed up code in each DSA, wait_reselect walks the
; reconnect_dsa_queue, asking each dsa if the target ID
; and LUN match its.
;
; If a match is found, a call is made back to reselected_ok,
; which through the miracles of self modifying code, extracts
; the found DSA from the reconnect_dsa_queue and then
; returns control to the DSAs thread of execution.
;
; INPUTS : NONE
;
; CALLS : OK
;
; MODIFIES : DSA,
;
; EXITS : On successful reselection, control is returned to the
; DSA which called reselected_ok. If the WAIT RESELECT
; was interrupted by a new commands arrival signaled by
; SIG_P, control is passed to schedule. If the NCR is
; selected, the host system is interrupted with an
; int_err_selected which is usually responded to by
; setting DSP to the target_abort address.
ENTRY wait_reselect
wait_reselect:
#ifdef EVENTS
int int_EVENT_IDLE
#endif
#ifdef DEBUG
int int_debug_idle
#endif
WAIT RESELECT wait_reselect_failed
reselected:
#ifdef EVENTS
int int_EVENT_RESELECT
#endif
CLEAR TARGET
DMODE_MEMORY_TO_MEMORY
; Read all data needed to reestablish the nexus -
MOVE 1, reselected_identify, WHEN MSG_IN
; We used to CLEAR ACK here.
#if (CHIP != 700) && (CHIP != 70066)
#ifdef DEBUG
int int_debug_reselected
#endif
; Point DSA at the current head of the disconnected queue.
DMODE_MEMORY_TO_NCR
MOVE MEMORY 4, reconnect_dsa_head, addr_scratch
DMODE_MEMORY_TO_MEMORY
#if (CHIP == 710)
MOVE MEMORY 4, addr_scratch, saved_dsa
#else
CALL scratch_to_dsa
#endif
; Fix the update-next pointer so that the reconnect_dsa_head
; pointer is the one that will be updated if this DSA is a hit
; and we remove it from the queue.
MOVE MEMORY 4, addr_reconnect_dsa_head, reselected_ok_patch + 8
#if (CHIP == 710)
; Time to correct DSA following memory move
MOVE MEMORY 4, saved_dsa, addr_dsa
#endif
ENTRY reselected_check_next
reselected_check_next:
#ifdef DEBUG
INT int_debug_reselect_check
#endif
; Check for a NULL pointer.
MOVE DSA0 TO SFBR
JUMP reselected_not_end, IF NOT 0
MOVE DSA1 TO SFBR
JUMP reselected_not_end, IF NOT 0
MOVE DSA2 TO SFBR
JUMP reselected_not_end, IF NOT 0
MOVE DSA3 TO SFBR
JUMP reselected_not_end, IF NOT 0
INT int_err_unexpected_reselect
reselected_not_end:
;
; XXX the ALU is only eight bits wide, and the assembler
; wont do the dirt work for us. As long as dsa_check_reselect
; is negative, we need to sign extend with 1 bits to the full
; 32 bit width of the address.
;
; A potential work around would be to have a known alignment
; of the DSA structure such that the base address plus
; dsa_check_reselect doesn't require carrying from bytes
; higher than the LSB.
;
MOVE DSA0 TO SFBR
MOVE SFBR + dsa_check_reselect TO SCRATCH0
MOVE DSA1 TO SFBR
MOVE SFBR + 0xff TO SCRATCH1 WITH CARRY
MOVE DSA2 TO SFBR
MOVE SFBR + 0xff TO SCRATCH2 WITH CARRY
MOVE DSA3 TO SFBR
MOVE SFBR + 0xff TO SCRATCH3 WITH CARRY
DMODE_NCR_TO_MEMORY
MOVE MEMORY 4, addr_scratch, reselected_check + 4
DMODE_MEMORY_TO_MEMORY
#if (CHIP == 710)
; Time to correct DSA following memory move
MOVE MEMORY 4, saved_dsa, addr_dsa
#endif
reselected_check:
JUMP 0
;
;
#if (CHIP == 710)
; We have problems here - the memory move corrupts TEMP and DSA. This
; routine is called from DSA code, and patched from many places. Scratch
; is probably free when it is called.
; We have to:
; copy temp to scratch, one byte at a time
; write scratch to patch a jump in place of the return
; do the move memory
; jump to the patched in return address
; DSA is corrupt when we get here, and can be left corrupt
ENTRY reselected_ok
reselected_ok:
MOVE TEMP0 TO SFBR
MOVE SFBR TO SCRATCH0
MOVE TEMP1 TO SFBR
MOVE SFBR TO SCRATCH1
MOVE TEMP2 TO SFBR
MOVE SFBR TO SCRATCH2
MOVE TEMP3 TO SFBR
MOVE SFBR TO SCRATCH3
MOVE MEMORY 4, addr_scratch, reselected_ok_jump + 4
reselected_ok_patch:
MOVE MEMORY 4, 0, 0
reselected_ok_jump:
JUMP 0
#else
ENTRY reselected_ok
reselected_ok:
reselected_ok_patch:
MOVE MEMORY 4, 0, 0 ; Patched : first word
; is address of
; successful dsa_next
; Second word is last
; unsuccessful dsa_next,
; starting with
; dsa_reconnect_head
; We used to CLEAR ACK here.
#ifdef DEBUG
INT int_debug_reselected_ok
#endif
#ifdef DEBUG
INT int_debug_check_dsa
#endif
RETURN ; Return control to where
#endif
#else
INT int_norm_reselected
#endif /* (CHIP != 700) && (CHIP != 70066) */
selected:
INT int_err_selected;
;
; A select or reselect failure can be caused by one of two conditions :
; 1. SIG_P was set. This will be the case if the user has written
; a new value to a previously NULL head of the issue queue.
;
; 2. The NCR53c810 was selected or reselected by another device.
;
; 3. The bus was already busy since we were selected or reselected
; before starting the command.
wait_reselect_failed:
#ifdef EVENTS
INT int_EVENT_RESELECT_FAILED
#endif
; Check selected bit.
#if (CHIP == 710)
; Must work out how to tell if we are selected....
#else
MOVE SIST0 & 0x20 TO SFBR
JUMP selected, IF 0x20
#endif
; Reading CTEST2 clears the SIG_P bit in the ISTAT register.
MOVE CTEST2 & 0x40 TO SFBR
JUMP schedule, IF 0x40
; Check connected bit.
; FIXME: this needs to change if we support target mode
MOVE ISTAT & 0x08 TO SFBR
JUMP reselected, IF 0x08
; FIXME : Something bogus happened, and we shouldn't fail silently.
#if 0
JUMP schedule
#else
INT int_debug_panic
#endif
select_failed:
#if (CHIP == 710)
; Disable selection timer
MOVE CTEST7 | 0x10 TO CTEST7
#endif
#ifdef EVENTS
int int_EVENT_SELECT_FAILED
#endif
; Otherwise, mask the selected and reselected bits off SIST0
#if (CHIP ==710)
; Let's assume we don't get selected for now
MOVE SSTAT0 & 0x10 TO SFBR
#else
MOVE SIST0 & 0x30 TO SFBR
JUMP selected, IF 0x20
#endif
JUMP reselected, IF 0x10
; If SIGP is set, the user just gave us another command, and
; we should restart or return to the scheduler.
; Reading CTEST2 clears the SIG_P bit in the ISTAT register.
MOVE CTEST2 & 0x40 TO SFBR
JUMP select, IF 0x40
; Check connected bit.
; FIXME: this needs to change if we support target mode
; FIXME: is this really necessary?
MOVE ISTAT & 0x08 TO SFBR
JUMP reselected, IF 0x08
; FIXME : Something bogus happened, and we shouldn't fail silently.
#if 0
JUMP schedule
#else
INT int_debug_panic
#endif
;
; test_1
; test_2
;
; PURPOSE : run some verification tests on the NCR. test_1
; copies test_src to test_dest and interrupts the host
; processor, testing for cache coherency and interrupt
; problems in the processes.
;
; test_2 runs a command with offsets relative to the
; DSA on entry, and is useful for miscellaneous experimentation.
;
; Verify that interrupts are working correctly and that we don't
; have a cache invalidation problem.
ABSOLUTE test_src = 0, test_dest = 0
ENTRY test_1
test_1:
MOVE MEMORY 4, test_src, test_dest
INT int_test_1
;
; Run arbitrary commands, with test code establishing a DSA
;
ENTRY test_2
test_2:
CLEAR TARGET
#if (CHIP == 710)
; Enable selection timer
#ifdef NO_SELECTION_TIMEOUT
MOVE CTEST7 & 0xff TO CTEST7
#else
MOVE CTEST7 & 0xef TO CTEST7
#endif
#endif
SELECT ATN FROM 0, test_2_fail
JUMP test_2_msgout, WHEN MSG_OUT
ENTRY test_2_msgout
test_2_msgout:
#if (CHIP == 710)
; Disable selection timer
MOVE CTEST7 | 0x10 TO CTEST7
#endif
MOVE FROM 8, WHEN MSG_OUT
MOVE FROM 16, WHEN CMD
MOVE FROM 24, WHEN DATA_IN
MOVE FROM 32, WHEN STATUS
MOVE FROM 40, WHEN MSG_IN
#if (CHIP != 710)
MOVE SCNTL2 & 0x7f TO SCNTL2
#endif
CLEAR ACK
WAIT DISCONNECT
test_2_fail:
#if (CHIP == 710)
; Disable selection timer
MOVE CTEST7 | 0x10 TO CTEST7
#endif
INT int_test_2
ENTRY debug_break
debug_break:
INT int_debug_break
;
; initiator_abort
; target_abort
;
; PURPOSE : Abort the currently established nexus from with initiator
; or target mode.
;
;
ENTRY target_abort
target_abort:
SET TARGET
DISCONNECT
CLEAR TARGET
JUMP schedule
ENTRY initiator_abort
initiator_abort:
SET ATN
;
; The SCSI-I specification says that targets may go into MSG out at
; their leisure upon receipt of the ATN single. On all versions of the
; specification, we can't change phases until REQ transitions true->false,
; so we need to sink/source one byte of data to allow the transition.
;
; For the sake of safety, we'll only source one byte of data in all
; cases, but to accommodate the SCSI-I dain bramage, we'll sink an
; arbitrary number of bytes.
JUMP spew_cmd, WHEN CMD
JUMP eat_msgin, WHEN MSG_IN
JUMP eat_datain, WHEN DATA_IN
JUMP eat_status, WHEN STATUS
JUMP spew_dataout, WHEN DATA_OUT
JUMP sated
spew_cmd:
MOVE 1, NCR53c7xx_zero, WHEN CMD
JUMP sated
eat_msgin:
MOVE 1, NCR53c7xx_sink, WHEN MSG_IN
JUMP eat_msgin, WHEN MSG_IN
JUMP sated
eat_status:
MOVE 1, NCR53c7xx_sink, WHEN STATUS
JUMP eat_status, WHEN STATUS
JUMP sated
eat_datain:
MOVE 1, NCR53c7xx_sink, WHEN DATA_IN
JUMP eat_datain, WHEN DATA_IN
JUMP sated
spew_dataout:
MOVE 1, NCR53c7xx_zero, WHEN DATA_OUT
sated:
#if (CHIP != 710)
MOVE SCNTL2 & 0x7f TO SCNTL2
#endif
MOVE 1, NCR53c7xx_msg_abort, WHEN MSG_OUT
WAIT DISCONNECT
INT int_norm_aborted
#if (CHIP != 710)
;
; dsa_to_scratch
; scratch_to_dsa
;
; PURPOSE :
; The NCR chips cannot do a move memory instruction with the DSA register
; as the source or destination. So, we provide a couple of subroutines
; that let us switch between the DSA register and scratch register.
;
; Memory moves to/from the DSPS register also don't work, but we
; don't use them.
;
;
dsa_to_scratch:
MOVE DSA0 TO SFBR
MOVE SFBR TO SCRATCH0
MOVE DSA1 TO SFBR
MOVE SFBR TO SCRATCH1
MOVE DSA2 TO SFBR
MOVE SFBR TO SCRATCH2
MOVE DSA3 TO SFBR
MOVE SFBR TO SCRATCH3
RETURN
scratch_to_dsa:
MOVE SCRATCH0 TO SFBR
MOVE SFBR TO DSA0
MOVE SCRATCH1 TO SFBR
MOVE SFBR TO DSA1
MOVE SCRATCH2 TO SFBR
MOVE SFBR TO DSA2
MOVE SCRATCH3 TO SFBR
MOVE SFBR TO DSA3
RETURN
#endif
#if (CHIP == 710)
; Little patched jump, used to overcome problems with TEMP getting
; corrupted on memory moves.
jump_temp:
JUMP 0
#endif