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1607 lines
56 KiB
Plaintext
1607 lines
56 KiB
Plaintext
;
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; File: SCSIMgr96.a
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;
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; Contains: SCSI Mgr for the 53C96
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;
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; Written by: Far Too Many People
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;
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; Copyright: © 1990-1993 by Apple Computer, Inc. All rights reserved.
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;
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; Change History (most recent first):
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;
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; <SM11> 9/13/93 SAM Removed a redundant definition of Translate24to32.
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; <SM10> 1/26/93 SAM Put in a PDMDebug only mod to CyclePhases to drop into macsbug
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; when it gets called. Only call HwPriv's FlushRangeCodeCache at
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; the end of data xfer calls only on 040s running VM.
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; <SM9> 11/3/92 SWC Changed SCSIEqu.a->SCSI.a.
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; <SM8> 10/18/92 CCH Added nop's to support non-serial IO space, and conditionals to
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; use byte accesses to the DREQ register.
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; <4> 5/22/92 DTY #1029009 <jab>: Modified DREQ bit testing from global (setup in
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; SCSIInit96).
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; <3> 5/1/92 JSM Don’t use isUniversal conditional, which was always commented
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; out anyway.
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; <2> 10/24/91 SAM Changed an include of HardwareEqu to HardwarePrivEqu.
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; <1> 10/24/91 SAM Rolled in Regatta file.
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;
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; Regatta Change History
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;
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; <3> 8/21/91 SAM (PDW) Added a FlushCacheRange call of the BusErrVct (long word
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; at 8) after replacing my BEH with the previous BEH. This is to
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; fix VM_On/BEHandler bug which is apparently a bug with MOVE16
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; instructions that cause Access Errors (page faults).
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; <2> 8/19/91 SAM (PDW) SendCmd_96 did not correctly detect a premature end of
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; command phase. Added a wait for FIFO empty or phase change to
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; detect this. Turned slow_cable mode off after sending command
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; (like we did before B2).
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; <1> 8/8/91 SAM (PDW) Checked into Regatta for the first time with lots of
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; changes over the TERROR sources.
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; <0> 8/8/91 SAM Split off from 7.0 GM sources.
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;
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; Terror Change History:
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;
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; <T9> 6/27/91 djw (actually PDW) Removed all traces of SCSIBusy and FreeHook
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; stuff. Made minimum CDB 1 byte instead of 2. Added slow cable
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; mode to command phase to improve reliability. Added multi-stage
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; select modeling to handle many more odd phase transitions.
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; Rewrote CyclePhase to handle all phases instead of just data
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; phases and also to handle new Select sequence flags.
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; Jump-vectorized CyclePhase_96.
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; <T8> 6/14/91 djw (actually PDW) Made mods to Interrupt handling of Select to work
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; with devices that go from Select to Status phz (like the
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; LaserWriter SC). Also eliminated wait for Select complete
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; interrupt at end of Command - we can do it in data phz or
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; Complete. Changed Select watchdog to be longer than the timeout
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; value used by the '96 (512mS vs 256mS).
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; <T7> 6/9/91 BG Rolled in Paul Wolf's SCSI changes: Rearranged headers to work
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; more consistently between test INIT and ROM builds. (Should not
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; affect ROM build).
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; <T6> 5/24/91 CCH Rolled in Paul Wolf's SCSI fixes: Reworked DoSCSISelect_D96
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; procs: Disabled automatic redirection of select if a device
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; disappears. Added 512mS delay after SCSIReset to fix Quantum
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; Q250 bug and to be consistent with all old CPUs.
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; <T5> 4/22/91 BG (actually JMA) Reworked DoSCSIComplete proc and fix SendCmd.
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; <T4> 3/30/91 BG (actually JMA) Reworked SendCmd and DoSCSISelect procs; fixed
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; SCSIStat bug; incorporated new FS hook fix but still is UNUSED.
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; <T3> 2/17/91 BG (actually JMA) Added Error calls, removed _Debugger calls, fixed
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; CyclePhase bug, added DoSCSIBusy_96 support & move stuff around.
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; <T2> 1/5/91 BG (actually JMA) Added functionalities.
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; <T1> 12/7/90 JMA Checked into TERROR for the first time.
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;
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;========================================================================== <T3>
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MACHINE MC68020
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BLANKS ON
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STRING ASIS
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PRINT OFF
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LOAD 'StandardEqu.d'
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INCLUDE 'HardwarePrivateEqu.a'
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INCLUDE 'SCSI.a'
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INCLUDE 'SCSIPriv.a'
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INCLUDE 'UniversalEqu.a'
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INCLUDE 'SCSIEqu96.a'
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PRINT ON
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SCSI96 PROC EXPORT
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EXPORT SCSIMgr_96
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EXPORT DoSCSICmd_96, DoSCSIComplete_96
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EXPORT DoSCSISelect_S96, DoSCSISelect_D96 ; <T2>
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EXPORT DoSCSISelAtn_S96, DoSCSISelAtn_D96, CyclePhase_96 ; <T9>
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EXPORT DoSCSIStat_96, DoSCSIMsgOut_96
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EXPORT SwapMMU, SCSIpcTo32bit, Error
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EXPORT Unimplemented_96
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EXPORT DoSCSIReset_96, DoSCSIGet_96 ; <T2>
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EXPORT DoSCSIMsgIn_96 ; <T2>
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EXPORT NewSCSIRead_96, NewSCSIWrite_96
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EXPORT NewSCSIWBlind_96, NewSCSIRBlind_96
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EXPORT SCSIpcTo32Bit ; <T9>
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EXPORT Error, SCSIErr_96 ; <T9>
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IMPORT Xfer1Byte, WaitForSCSIIntrp, WaitForIntNoTime
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IMPORT Wt4DREQorInt, HandleSelInProg
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WITH scsiPB, scsiPrivPB
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WITH scsiGlobalRecord, dcInstr
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VMGlobals EQU $0B78 ; Pointer to VM's globals (yeah, yeah, had to do it) <SM10> SAM
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;==========================================================================
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;-------------------------------------------------------------
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;
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; A SCSI Function request handler. SCSI's are invoked by params on
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; stack followed by a routine selector Int, and return address.
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; NOTE: SCSIMgr is a Toolbox trap & follows Pascal calling conventions.
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;
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; A4 is set up by StdEntry and contains a pointer to the SCSI Manager global
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; area in the system heap.
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;
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SCSIMgr_96: ; "Normal" 680x0 CPU's with "SCSIGlobals" lomem
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move.l (sp)+,a0 ; get the return address
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move.w (sp)+,d0 ; function selector (word)
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move.l a0,-(sp) ; push the return address
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cmp.w #numSelectors,d0 ; valid selector?
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bhs.s Unimplemented_96 ; Sorry, Charlie
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link a6,#LocalSize ; locals for bus error stuff
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movem.l a2-a5/d2-d7,-(sp) ; save registers
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movea.l SCSIGlobals,a4 ; get pointer to SCSI Manager globals
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scsiMgrCommon
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move.l base5380(a4),a3 ;
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moveq.l #0,zeroReg
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moveq.l #0,d4 ; needed by read/write
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move.w d0,d1 ; save a copy of selector
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move.l 0(a4,d0.w*4),a0 ; indexed addressing
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jmp (a0) ; and go there
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;--------------------------------------------------------------------------
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;
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StdExit
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movem.l (sp)+, a2-a5/d2-d7 ; restore these guys
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unlk a6
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move.l (sp)+, a0 ; get return address
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add.w d0, sp ; fixup the stack <T4>
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jmp (a0)
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;--------------------------------------------------------------------------
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;
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; Common code when exiting old SCSI Mgr after an error
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;
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; Uses : d0, a0
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ExitCleanup:
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move.b zeroReg, G_State(a4) ; clear out SCSI Mgr semaphore
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; (from ClearState proc, SCSIMgrNew.a)
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rts ; <T3>
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;----------------------------------------------------------------
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;
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; Unimplemented selector (or out of range)
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;
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Unimplemented_96
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moveq.l #dsCoreErr, d0 ; unimplemented core routine <T3>
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_SysError ; sorry, Charlie <T3>
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@1 bra.s @1 ; not safe to continue
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;--------------------------------------------------------------------------
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;
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; FUNCTION SCSIStat: INTEGER;
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; (8)
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;
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; Get SCSI bus status.
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;
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; A bit-to-bit bus and status register mapping is not possible from the 53C80 to 53C96.
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; Consequently, we fake the status and return what we think the status should be.
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; Also note that we OR the two SCSI bus stati(?) because only 2 situations are possbile:
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; 1) One bus is active and the other idle 2) both buses are idle.
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;
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; The following list is the status bit map:
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; signal names in parenthesis are the closest c96 status bit equivalents
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;
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; 53c80 Status Bit 53c96 Status Bits
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; DBP n/a
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; SEL n/a
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; I/O I/O
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; C/D C/D
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; MSG MSG
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; REQ n/a (1 if scBusy)
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; BSY n/a (1 if scBusy)
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; RST n/a <T4>
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; ACK n/a
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; ATN n/a
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; BSY ERR n/a <T4>
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; PHS MAT n/a
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; INT REQ n/a (INT PEND)
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; PRT ERR n/a <T4>
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; DMA REQ DREQ (DMA REQ) <T4>
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; END DMA n/a
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;
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; G_FakeStat contains fake bit values that different procs of the SCSI manager
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; have set or cleared. The values in it reflect the best-guessed status of the
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; bus as determined by the SCSI manager.
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;
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; Uses: d0, d1, d2
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;
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; Return Codes:
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; noErr
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DoSCSIStat_96
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and.w #$FFF2, G_FakeStat(a4) ; clear phase bits first, except SEL <T4>
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move.l a3, -(sp) ; save a3
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clr.l d1 ;
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move.l base539x0(a4), a3 ; load ptr for SBus0 <T2>
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move.b rSTA(a3), d1 ; read this bus' status <T2>
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TestFor SCSI96_2Exists ; do we have a 2nd SCSI96 chip? <T2>
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beq.s @noSCSI96 ; bra. if no 2nd SCSI96 <T2>
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move.l base539x1(a4), a3 ; load ptr for SBus1 <T2>
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or.b rSTA(a3), d1 ; OR this bus' status <T2>
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@noSCSI96 ; <T2>
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move.l (sp)+, a3 ; restore a3
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andi.b #iPhaseMsk, d1 ; mask off the rest to get phase bits
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lsl.b #2, d1 ; position the MSG-CD-IO bits
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or.w d1, G_FakeStat(a4) ;
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moveq.l #aBSY+aSEL, D0 ; what are Busy and Sel signals set to?
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and.w G_FakeStat(a4), D0
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cmp.w #aBSY, D0 ; if Busy but no Sel,
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bne.s @1 ;
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or.w #aREQ, G_FakeStat(a4) ; set REQ also
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bra.s @2
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@1
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and.w #$FFFF-aREQ, G_FakeStat(a4) ; else, clear REQ
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@2
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move.w G_FakeStat(a4), 8(a6) ; 8(a6) <- Bus and Status
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bra.s NoByteExit ; 9(a6) <- Current SCSI Bus Status
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;--------------------------------------------------------------------------
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;
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; FUNCTION SCSIReset: INTEGER;
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; (8)
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;
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; If we have two scsi buses, hard reset both since the interface does not provide a <T2>
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; way for the client to specify a target bus in a dual-SCSI bus system. <T2>
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;
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; Uses: a0, a3, d0, d2, d3
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;
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; Return Codes:
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; noErr
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DoSCSIReset_96
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move.l a3, -(sp) ; save a3 <T2>
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movea.l jvResetBus(a4), a0 ; get address of SCSI reset routine <T2>
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move.l base539x0(a4), a3 ; load ptr for SBus0 <T2>
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jsr (a0) ; reset SCSI bus and kill all requests <T2>
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TestFor SCSI96_2Exists ; do we have a second SCSI96 chip? <T2>
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beq.s @noSCSI96 ; bra. if no 2nd SCSI96 <T2>
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movea.l jvResetBus(a4), a0 ; get address of SCSI reset routine <T2>
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move.l base539x1(a4), a3 ; load ptr for SBus1 <T2>
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jsr (a0) ; reset SCSI bus and kill all requests <T2>
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@noSCSI96 ; <T2>
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move.l (sp)+, a3 ; restore a3
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move.l #0, G_FakeStat(a4) ; clear fake status
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move.w zeroReg, 8(a6) ; always returns 0 status
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bsr.s ExitCleanup ; clean up to leave
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moveq.l #0, d2 ; clear upper word <T6> thru next <T6>
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move.w TimeDBRA, d2 ; get # of DBRAs per mS
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lsl.l #8, d2 ; multiply by …
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lsl.l #1, d2 ; …512
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move.l d2, d3 ; ...a 512mS wait
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swap d3
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@1
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dbra d2, @1 ; d2 low word of counter
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dbra d3, @1 ; d3 high word <T6>
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NoByteExit
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moveq.l #0, d0 ; no arguments to clean up
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bra.w StdExit
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;--------------------------------------------------------------------------
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;
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; FUNCTION SCSIGet: INTEGER;
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; (8)
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;
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; SCSI arbitration is now an integrated operation with SELECT
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; in the 5394/5396. It is here only for backward compatibility. We will fake
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; an asserted BSY & SEL signals just in case the user above decides to perform
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; a SCSIStat.
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;
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; IMPORTANT: SCSIMgr clients MUST still call SCSIGet before SCSISelect. This will be enforced in <T4>
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; SCSISelect. G_State will be used as a flag to indicate that SCSIGet was called.
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;
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; Uses: d0, d1, d2, d3
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;
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; Return Codes:
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; noErr
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DoSCSIGet_96
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bset.b #scBusy, G_State(a4) ; set to SCSI busy state <T2>
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bne.s @isBusy ; if nonzero, SCSI Mgr is in use <T2>
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; move.l zeroReg, d0 ; disable SCSI interrupts with old SCSI Mgr
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; movea.l jvDisEnable(a4), a0 ; addr of interrupt enable/disable routine
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; jsr (a0) ; disable interrupts
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move.w #aBSY+aSEL, G_FakeStat(a4) ; Set to a fake successful arb status
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moveq.l #noErr, d0 ; no error
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@exit ; <T2>
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move.w d0, 8(a6) ; return code
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bra.s NoByteExit
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@isBusy ; <T2>
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moveq.l #scMgrBusyErr ,d0 ; SCSI Mgr is busy <T2>
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bra.s @exit ; bail out in order to avoid deadlock <T2>
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;--------------------------------------------------------------------------
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;
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; FUNCTION SCSISelect(TargID:INTEGER): INTEGER;
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; FUNCTION SCSISelAtn(TargID:INTEGER): INTEGER;
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; (8) (10)
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;
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; Select the target at TargID on the "virtual" SCSI bus. Returns 0 for success, or error.
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; Selection can be done with or without the ATN line.
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;
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; This proc sets up the proper SCSI chip addresses for Select_96 for dual-bus machines.
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; It uses the G_SCSIDevMapX bitmap for each bus with 1 bit for each ID on that bus to
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; decide which bus to send a selection attempt to. During initialization of the SCSI
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; manager, these bitmaps are cleared, indicating that no device has been detected at
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; any of the SCSI IDs for either bus. The proper bit is set the first time a successful
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; select of that ID on that bus is performed.
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;
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; Functionally, if no device has been seen on either the internal or external buses,
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; the internal bus will be checked first and if that fails, the external bus is checked.
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; If both fail (if no device is at that ID on either bus) then neither bit will have
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; been set. Also, if a device has been seen once at a certain ID, then that ID will
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; only be accessible from that bus until the next reboot.
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;
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; This routine will first check the state of the requested ID's external bit. If it
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; is set, the first and only selection attempt is performed on bus 1 otherwise it is
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; attempted on bus 0. If the bus 0 select fails, then the bus 0 bitmap is checked to
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; see if there was previously a device at that ID. If there wasn't then a selection
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; is sent to bus 1 as well.
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DoSCSISelect_D96
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DoSCSISelAtn_D96
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bset.b #scBusy, G_State(a4) ; set SCSI busy state here too for those who bypass SCSIGet <T4>
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move.w G_FakeStat(a4), -(sp) ; save fake status <T4>
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move.w #aBSY, (sp) ; assume successful selection, set fake status <T4>
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moveq.l #0, d6 ; clear upper bits <T6> thru next <T6>
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move.w 8(a6), d6 ; get the target's ID
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cmp.w #scsiSelAtn, d1 ; select with ATN?
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bne.s @noATN ; no ATN
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;@wATN
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bset.l #16, d6 ; use ATN
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ori.w #aATN, (sp) ; assume successful select w/ATN, set fake status <T4>
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@noATN
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move.l d6, G_TargetID(a4) ; remember destination ID & ATN bit
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btst.b d6, G_SCSIDevMap1(a4) ; if this device is marked as on bus 1...
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bne.s @SBus1 ; then try select on bus 1
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@SBus0 ; else try select on bus 0
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move.l base539x0(a4), a3 ; load SCSI base 0
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move.l a3, base5380(a4) ; expected SCSI base adrs for this ID for SCSIRead/Write/Complete etc.
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move.l pdma5380(a4), a0 ; pdma5380 contains DREQ regr address
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move.l d6, d0 ; copy target ID
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bsr.w Select_96 ; try it
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bne.s @fldSel0 ; branch if select failed
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bset.b d6, G_SCSIDevMap0(a4) ; else record this device's existence
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bra.s @exit
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@fldSel0
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btst.b d6, G_SCSIDevMap0(a4) ; if this device was marked as on bus 0
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bne.s CommonSelErrXit ; then we return an error
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; else we try bus 1
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@SBus1
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move.l base539x1(a4), a3 ; load SCSI base 1
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move.l a3, base5380(a4) ; expected SCSI base adrs for this ID for SCSIRead/Write/Complete etc.
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move.l hhsk5380(a4), a0 ; hhsk5380 contains DREQ regr address
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move.l d6, d0 ; copy target ID
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bsr.w Select_96 ; try it
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bne.s CommonSelErrXit ; branch if select failed
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bset.b d6, G_SCSIDevMap1(a4) ; else record this device's existence
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;; bra.s @exit
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@exit
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move.w (sp)+, G_FakeStat(a4) ; save new fake status <T4>
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move.l a0, G_SCSIDREQ(a4) ; save SCSI DREQ regr for SCSIRead/Write/Complete etc.
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move.w d0, 10(a6) ; return the result
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moveq.l #2, d0 ; stack cleanup
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bra.w StdExit ; <T6> from prev <T6>
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;-----------------
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CommonSelErrXit ; common Select error exit
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clr.w (sp) ; set failed fake status
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move.l d0, -(sp) ; save d0
|
||
bsr.w ExitCleanup ; clean up to leave
|
||
move.l (sp)+, d0 ; restore d0
|
||
move.l #scsiSelect, d6 ; load proc ID
|
||
bsr.w Error ; call Error proc - for debug
|
||
move.w (sp)+, G_FakeStat(a4) ; save new fake status
|
||
move.w d0, 10(a6) ; return the result
|
||
moveq.l #2, d0 ; stack cleanup
|
||
bra.w StdExit ; special exit <T9>
|
||
|
||
|
||
|
||
|
||
;--------------------------------------------------------------------------
|
||
;
|
||
; FUNCTION SCSISelect(TargID:INTEGER): INTEGER;
|
||
; FUNCTION SCSISelAtn(TargID:INTEGER): INTEGER;
|
||
; (8) (10)
|
||
;
|
||
; Select the target on the bus. Returns 0 for success, or error.
|
||
; Selection can be done with or without the ATN line.
|
||
; Single SCSI BUS Select Proc
|
||
|
||
DoSCSISelect_S96
|
||
DoSCSISelAtn_S96
|
||
bset.b #scBusy, G_State(a4) ; set SCSI busy state here too for those who bypass SCSIGet <T4>
|
||
move.w G_FakeStat(a4), -(sp) ; save fake status <T4>
|
||
move.w #aBSY, (sp) ; assume successful selection, set fake status <T4>
|
||
|
||
moveq.l #0, d0 ; clear upper bits
|
||
move.w 8(a6), d0 ; get the target's ID
|
||
cmp.w #scsiSelAtn, d1 ; select with ATN?
|
||
bne.s @noATN ; no ATN
|
||
bset.l #16, d0 ; use ATN
|
||
ori.w #aATN, (sp) ; assume successful select w/ATN, set fake status <T4>
|
||
@noATN
|
||
move.l d6, G_TargetID(a4) ; remember destination ID & ATN bit <T9>
|
||
move.l pdma5380(a4), a0 ; pdma5380 contains DREQ regr address
|
||
bsr.w Select_96 ; try it
|
||
bne.s CommonSelErrXit ; branch if error <T4>
|
||
@exit
|
||
move.w (sp)+, G_FakeStat(a4) ; save new fake status <T4>
|
||
move.l a0, G_SCSIDREQ(a4) ; save SCSI DREQ regr
|
||
move.w d0, 10(a6) ; return the result
|
||
moveq.l #2, d0 ; stack cleanup
|
||
bra.w StdExit
|
||
|
||
|
||
|
||
|
||
;--------------------------------------------------------------------------
|
||
;
|
||
; FUNCTION SCSICmd(Buffer:Ptr, Count:INTEGER): INTEGER;
|
||
; (10) (8) (14)
|
||
;
|
||
; Send the target the given command.
|
||
;
|
||
; Return Codes:
|
||
; noErr, scPhaseErr, scCommErr
|
||
|
||
DoSCSICmd_96
|
||
move.l 10(a6), a2 ; get command buffer address
|
||
move.w 8(a6), d2 ; get the length
|
||
bsr.w SendCMD_96 ; send it
|
||
bne.s @err ; bra. if error
|
||
@exit ; <T3> thru next T3>
|
||
move.w d0, 14(a6) ; return the result
|
||
moveq.l #6, d0
|
||
bra.w StdExit
|
||
@err
|
||
move.l d0, -(sp) ; save d0
|
||
move.l (sp)+, d0 ; restore d0
|
||
|
||
move.l #scsiCmd, d6 ; load proc ID
|
||
bsr.w Error ; call Error proc - for debug
|
||
bra.s @exit ; <T3>
|
||
|
||
|
||
|
||
|
||
;--------------------------------------------------------------------------
|
||
;
|
||
; SCSIRead, SCSIRBlind, SCSIWrite, SCSIWBlind
|
||
;
|
||
; Called by: Toolbox Trap Dispatcher
|
||
;
|
||
; Calls: Transfer, primitive data transfer routines
|
||
;
|
||
; On entry: a3 - SCSI read base address
|
||
; a4 - pointer to SCSI Manager globals
|
||
;
|
||
; Internal: a1 - TIB scan pointer
|
||
;
|
||
; Function: Performs TIB interpretation, and data transfers.
|
||
|
||
NewSCSIWBlind_96
|
||
moveq.l #scsiWriteFast, d4 ; select the fast write routine
|
||
bra.s dataCommon_96 ; continue
|
||
NewSCSIWrite_96
|
||
moveq.l #scsiWriteSlow, d4 ; select the slow write routine
|
||
bra.s dataCommon_96 ; continue
|
||
NewSCSIRBlind_96
|
||
moveq.l #scsiReadFast, d4 ; select the fast read routine
|
||
bra.s startRead_96 ; continue
|
||
NewSCSIRead_96
|
||
moveq.l #scsiReadSlow, d4 ; select the slow read routine
|
||
startRead_96
|
||
|
||
dataCommon_96
|
||
|
||
move.l 8(a6), a1 ; get the TIB pointer
|
||
bra.s @exec ; tighten loop by branching first
|
||
|
||
@c_compare
|
||
bset.l #scsiCompBit, d4 ; add offset to use the compare routines
|
||
; FALL THROUGH to @c_inc ; continue
|
||
|
||
@c_inc
|
||
movea.l jvTransfer(a4), a0 ; get the address of the transfer routine
|
||
jsr (a0) ; go to the transfer routine
|
||
bne.s @data_end ; if error, bail out
|
||
add.l d1, scParam1(a1) ; increment the pointer
|
||
bclr.l #scsiCompBit, d4 ; remove offset for the compare routines
|
||
; FALL THROUGH to @next_cmd ; continue
|
||
|
||
@next_cmd
|
||
@c_nop ; also NOP, just skip the command
|
||
add.w #scSize, a1 ; point to the next TIB instruction
|
||
; FALL THROUGH to @exec
|
||
|
||
@exec
|
||
move.w scOpcode(a1), d1 ; get the function opcode
|
||
move.l scParam1(a1), a2 ; get the generic address
|
||
move.l scParam2(a1), d2 ; get the generic count
|
||
|
||
cmp.w #maxOpcode, d1 ; valid opcode ?
|
||
bhi.s @c_badop ; return err if not
|
||
|
||
add.w d1,d1 ; index times two
|
||
jmp @JmpTable(d1.w) ; jump into table
|
||
|
||
@JmpTable ;
|
||
bra.s @c_badop ; 0 is not a valid opcode
|
||
bra.s @c_inc ; 1
|
||
bra.s @c_noinc ; 2
|
||
bra.s @c_add ; 3
|
||
bra.s @c_move ; 4
|
||
bra.s @c_loop ; 5
|
||
bra.s @c_nop ; 6
|
||
bra.s @c_stop ; 7
|
||
bra.s @c_compare ; 8
|
||
|
||
@c_badop
|
||
moveq.l #scBadparmsErr, d0 ; bad opcode
|
||
bra.s @data_end
|
||
|
||
@c_noinc ; NOINC addr,count
|
||
movea.l jvTransfer(a4), a0 ; get the address of the transfer routine
|
||
jsr (a0) ; go to the transfer routine
|
||
|
||
bne.s @data_end ; if error, exit
|
||
bra.s @next_cmd ; else process next command
|
||
|
||
@c_add ; ADD addr,data
|
||
add.l d2, (a2) ; the count added to the where
|
||
bra.s @next_cmd ; process the next command
|
||
|
||
@c_move ; MOVE addr1,addr2
|
||
move.l d2, a0 ; get the destination address
|
||
move.l (a2), (a0) ; simple enough
|
||
bra.s @next_cmd ; process the next command
|
||
|
||
@c_loop ; LOOP relative addr,count
|
||
tst.l d2 ; check for zero loop count
|
||
beq.s @next_cmd ; if count is already zero, quit loop
|
||
subq.l #1, d2 ; drop the count
|
||
move.l d2, scParam2(a1) ; put the count back for next time
|
||
beq.s @next_cmd ; if count exhausted, don't loop
|
||
add.l a2, a1 ; modify the command pointer
|
||
bra.s @exec ; and process the next command
|
||
|
||
@c_stop
|
||
moveq.l #noErr, d0 ; indicate no error
|
||
; FALL THROUGH to @data_end ; <C846>
|
||
|
||
|
||
@data_end
|
||
cmpi.b #cpu68040,CPUFlag ; Do we have an 040? <SM10>
|
||
bne.s @TheRealExit ; -> No. No MOVE16. No Problem.
|
||
cmpi.l #-1,VMGlobals ; VM running?
|
||
beq.s @TheRealExit ; -> No, no VM, no problem
|
||
|
||
|
||
;--- Flush the cache line that contains location 8 (because of MOVE16 bug) <3> thru next <3>
|
||
|
||
movem.l D0-D2, -(sp)
|
||
moveq.l #9, D0 ; FlushCacheRange HWPriv selector
|
||
move.l #8, A0 ; starting address of flush range
|
||
move.l #4, A1 ; length of range
|
||
_HWPriv
|
||
movem.l (sp)+, D0-D2 ; restore regs <3> from last <3>
|
||
|
||
;--- exit and return result
|
||
|
||
@TheRealExit
|
||
move.w d0, 12(a6) ; return the result
|
||
moveq.l #4, d0 ; stack cleanup
|
||
bra.w StdExit
|
||
|
||
|
||
|
||
|
||
|
||
;--------------------------------------------------------------------------
|
||
;
|
||
; FUNCTION SCSIComplete(VAR Stat, Message: INTEGER; wait:LongInt): INTEGER;
|
||
; (16) (12) (8) (20)
|
||
;
|
||
; Complete the SCSI command by:
|
||
; 1) Sending command complete sequence byte to get status & msg bytes from target
|
||
; 2) Sending message accepted command to complete the cycle
|
||
;
|
||
; Return Codes:
|
||
; noErr, scCommErr, scPhaseErr, scComplPhaseErr
|
||
|
||
DoSCSIComplete_96
|
||
move.w zeroReg, -(sp) ; assume no_error return value
|
||
move.l Ticks, d4 ; get current time
|
||
add.l 8(a6), d4 ; add count to start ticks
|
||
jsr HandleSelInProg
|
||
bne.w @phaseErr
|
||
@chkStatus
|
||
moveq.l #iPhaseMsk, d3 ; load mask bits for phase value
|
||
and.b rSTA(a3), d3 ; get phase bits
|
||
cmpi.b #iStatus, d3 ; are we in status phase?
|
||
bne.w @phaseErr ;
|
||
@inPhase ; we should be in status phase.
|
||
move.b #cCmdComp, rCMD(a3) ; load cmd complete code
|
||
if nonSerializedIO Then
|
||
nop ; Force write to complete. <SM8>
|
||
endif
|
||
jsr WaitForSCSIIntrp ; Wait for intrp w/ timeout
|
||
; on exit d5 = rF0S|rINT|0|rSTA
|
||
beq.w @noStatus ; Branch if timedout
|
||
@gotStatus
|
||
clr.l d2
|
||
move.b rFFO(a3), d2 ; read status byte from FIFO
|
||
move.l 16(a6), a1 ; get the Status ptr
|
||
move.w d2, (a1) ; return status byte
|
||
@gotMsg
|
||
move.b rFFO(a3), d2 ; read msg byte from FIFO
|
||
move.l 12(a6), a1 ; get the Message ptr
|
||
move.w d2,(a1) ; return the msg byte
|
||
|
||
; ;move.l d5, d0 ; <T8> thru next <T8>
|
||
; ;andi.b #iPhaseMsk, d0 ; we should be in msg-in phase.
|
||
; ;cmpi.b #iMsgIn, d0 ; & *ACK still asserted
|
||
; ;bne.s @cmdErr <T8> from last <T8>
|
||
|
||
move.b #cMsgAcep, rCMD(a3) ; load msg accepted code which de-asserts *ACK
|
||
if nonSerializedIO Then
|
||
nop ; Force write to complete. <SM8>
|
||
endif
|
||
jsr WaitForSCSIIntrp ; Wait for intrp w/ timeout
|
||
; on exit d5 = rFOS|rINT|0|rSTA
|
||
beq.w @badAcpt ; Branch if timedout
|
||
|
||
@completeDone
|
||
move.l #0, G_FakeStat(a4) ; clear fake status
|
||
move.w (sp)+, 20(a6) ; return error
|
||
bsr.w ExitCleanup ; clean up to leave
|
||
|
||
moveq.l #12, d0 ; stack cleanup
|
||
bra.w StdExit ; <T3>
|
||
|
||
@phaseErr ; only called for Complete phase errors
|
||
move.w #scPhaseErr, (sp) ; phase Err but try getting us to status phase <T9>
|
||
jsr ([jvCyclePhase,a4]) ; get us to status phase if possible
|
||
beq.s @1 ; if cyclephz has no error, keep old one
|
||
move.w d0, (sp) ; else save this new error in (sp)
|
||
@1
|
||
moveq.l #iPhaseMsk, d3 ; load mask bits for phase value
|
||
and.b rSTA(a3), d3 ; get phase bits
|
||
cmpi.b #iStatus, d3 ; are we in status phase?
|
||
beq.w @inPhase ; yes - go get the data
|
||
@checkTime
|
||
cmp.l Ticks, d4 ; got the time, pal?
|
||
bhi.w @chkStatus ; bra. & check phase if we still have time...
|
||
; btst.b #FCIntPend, G_State96(a4) ; timed out; were we waiting for a slow peripheral? <T9>
|
||
; beq.s @completeDone ; no - exit with whatever status we've got
|
||
@timedOut
|
||
@noStatus ;
|
||
@badAcpt
|
||
@notDSCErr
|
||
@cmdErr
|
||
move.w #scCommErr, (sp) ; return status
|
||
@badComp
|
||
move.l (sp), d0 ; load error
|
||
move.l #scsiComplete, d6 ; load proc ID
|
||
bsr.w Error ; call Error proc - for debug
|
||
bra.s @completeDone ; <T5>
|
||
|
||
|
||
|
||
|
||
|
||
;--------------------------------------------------------------------------
|
||
;
|
||
; FUNCTION SCSIMsgIn(VAR Message: INTEGER): INTEGER;
|
||
; (8) (12)
|
||
;
|
||
; Receive a message from the target.
|
||
;
|
||
; Return Codes:
|
||
; noErr, scCommErr, scPhaseErr
|
||
|
||
DoSCSIMsgIn_96 ; SCSIMsgIn added
|
||
bsr.w GetMsg_96
|
||
bne.s @err ; bra. if error <T3>
|
||
move.l 8(a6), a1 ; get the Message ptr
|
||
move.w d2, (a1) ; return the Message byte
|
||
@exit
|
||
move.w d0, 12(a6) ; return error
|
||
moveq.l #4, d0 ; stack cleanup <T3> thru next <T3>
|
||
bra.w StdExit
|
||
@err
|
||
move.l #scsiMsgIn, d6 ; load proc ID
|
||
bsr.w Error ; call Error proc - for debug
|
||
bra.s @exit ; <T3>
|
||
|
||
|
||
|
||
|
||
|
||
;--------------------------------------------------------------------------
|
||
;
|
||
; FUNCTION SCSIMsgOut(Message: INTEGER): INTEGER;
|
||
; (8) (10)
|
||
;
|
||
; Send a message to the target.
|
||
;
|
||
; Return Codes:
|
||
; noErr, scCommErr, scPhaseErr
|
||
|
||
DoSCSIMsgOut_96 ; SCSIMsgOut added
|
||
move.w 8(a6), d2 ; get the Message in d2
|
||
bsr SendMsg_96
|
||
bne.s @err ; <T3> thru next <T3>
|
||
@exit
|
||
move.w d0, 10(a6) ; return error
|
||
moveq.l #2, d0 ; stack cleanup
|
||
bra.w StdExit
|
||
@err
|
||
move.l #scsiMsgIn, d6 ; load proc ID
|
||
bsr.w Error ; call Error proc - for debug
|
||
bra.s @exit
|
||
|
||
|
||
|
||
|
||
|
||
;----------------------------------------------------------------
|
||
; Select Device.
|
||
; In the 5396, arbitration, selection and command-send operations are integrated operations.
|
||
; We need the target id and the actual command descriptor block in order to exploit the
|
||
; capabilities of the chip. Unfortunately, the old SCSI manager was structured for separate
|
||
; such operations. This proc is an attempt to remain compatible to that type of operation.
|
||
; Our goal is to select a target and report the success or failure of that operation.
|
||
; This is accomplished by:
|
||
; 1) Loading transfer count, TC, with one in order to activate the select process
|
||
; 2) Using DMA mode in order to allow us to send the actual CDB during DoSCSICmd proc.
|
||
;
|
||
; Upon exit, we should be in transfer phase waiting for the client to perform either a
|
||
; command send or msg-out--if select w/ ATN. The c96 would be ready and waiting for the
|
||
; CDB or message byte because we told it to expect at least 1 byte of data.
|
||
;
|
||
; Select w/ ATN asserts the ATTENTION line during selection process. This allows the
|
||
; client to perform a 1 byte msg-out via SCSIMsgOut. The ATN line is deasserted
|
||
; prior to sending the msg byte.
|
||
;
|
||
; --> A0 = DAFB register address for this c96 (for reading DREQ state)
|
||
; d0.w --> Target ID
|
||
; d0.b16 --> If bit 16 of d0 is set, then ATN is asserted during selection.
|
||
; This is useful for telling the target that we
|
||
; want to send it a message before the command phase.
|
||
;
|
||
; Uses: d0, d1, d2, d3
|
||
|
||
Select_96
|
||
; set MMU Mode to 32-bit for DREQ test later on
|
||
move.b MMU32Bit, -(sp) ; save current mode on stack
|
||
move.l d0, -(sp) ; save D0
|
||
jsr SCSIpcTo32bit ; use pc relative
|
||
moveq #true32B, d0 ; switch to 32-bit mode to look at SCSI config regr
|
||
jsr SwapMMU ; do it, call _SwapMMUMode jump vector
|
||
move.l (sp)+, d0 ; restore D0
|
||
|
||
; Set up chip for select process (flush FIFO, init dest ID)
|
||
move.b d0, rDID(a3) ; load select bus ID w/ target ID
|
||
move.b #cFlshFFO, rCMD(a3) ; Flush FIFO, make sure it's empty
|
||
if nonSerializedIO Then
|
||
nop ; Force write to complete. <SM8>
|
||
endif
|
||
|
||
btst.l #16, d0 ; is this a Sel w/Atn?
|
||
bne.s @withAtn
|
||
|
||
; If Select w/o Atn then set up for 1 DMA byte (last byte of command block) and start process
|
||
@withoutATN
|
||
move.b zeroReg, rXCM(a3) ; tell chip that we will be sending 1
|
||
move.b #1, rXCL(a3) ; DMA byte (in command phase)
|
||
move.b #cDMASelWOAtn, rCMD(a3) ; issue Select w/o Atn cmd
|
||
if nonSerializedIO Then
|
||
nop ; Force write to complete. <SM8>
|
||
endif
|
||
bset.b #NeedCmdSent, G_State96(a4) ; flag=expect to see a COMMAND phase next <T9>
|
||
bra.s @2
|
||
|
||
; If Select w/Atn then set up for 2 DMA bytes (msg_out byte + last byte of command block)
|
||
@withATN
|
||
move.b zeroReg, rXCM(a3) ; tell chip that we will be sending 2
|
||
move.b #1, rXCL(a3) ; DMA bytes (1 in msg_out, 1 in command)
|
||
move.b #cDMASelWAtn, rCMD(a3) ; issue Select w/ Atn cmd
|
||
if nonSerializedIO Then
|
||
nop ; Force write to complete. <SM8>
|
||
endif
|
||
bset.b #NeedMsgOut, G_State96(a4) ; flag=expect to see a MESSAGE_OUT phase next <T9>
|
||
@2
|
||
bset.b #SelInProg, G_State96(a4) ; set flag->select is in prog, expect intrpt <T8><T9>
|
||
|
||
|
||
; Set up >512mS timeout for select operation to get somewhere (probably more like 2 seconds)
|
||
moveq.l #0, d1 ; clear upper word
|
||
move.w TimeSCSIDB, d1 ; get # of DBRAs
|
||
lsl.l #8, d1 ; multiply by 256
|
||
lsl.l #1, d1 ; multiply by 2 <T8> thru next <T8>
|
||
move.l d1, d2 ; ...a 512mS wait for overall watchdog
|
||
swap d2
|
||
|
||
moveq.l #-1,d3 ; for debug - last four rSTA reads
|
||
moveq.l #-1,d4 ; for debug - last four rSQS reads
|
||
|
||
|
||
; We have told the chip to start it, now we wait for an indication that it has completed a
|
||
; selection. Several things can happen:
|
||
; - the target at the requested ID may not exist or may not respond to the select. In
|
||
; this case we will receive a Disconnect interrupt from the chip.
|
||
; - the target may select OK but go into something other than Command phz (if Sel w/o Atn)
|
||
; or Message_Out phz (if Sel w/Atn). Here we will see a Function Complete/Bus Service
|
||
; interrupt.
|
||
; - the target may select OK and go into the expected phz - the SUCCESS case. When this
|
||
; happens, the chip will assert DREQ because it wants the Command (or Msg_Out) byte.
|
||
; - the bus may be hung and the chip is unable to arbitrate. We detect this by timing
|
||
; out on the whole process.
|
||
;
|
||
; So basically, this is a 3-way wait for:
|
||
; 1) DREQ asserted
|
||
; 2) interrupt
|
||
; 3) loop timed out
|
||
|
||
|
||
;———————————————————
|
||
@waitLoop
|
||
; Check for a REQ from the target (within valid phase)
|
||
IF forPDMDebug THEN ; <SM8>
|
||
move.b (a0), d5 ; read DAFB regr (a0=DAFB register addr)
|
||
ELSE
|
||
move.l (a0), d5 ; read DAFB regr (a0=DAFB register addr)
|
||
ENDIF
|
||
move.b G_bitDREQ(a4),d0 ; load DREQ bit position <4> jab
|
||
btst.l d0, d5 ; DREQ ? <4> jab
|
||
bne.s @gotDREQ ; yes: then we have a REQ for Msg_Out or Cmd byte
|
||
|
||
; Check for an int - either Disconnected (fld select) or Bus Service/Func. Cmplt (good select)
|
||
lsl.l #8,d3 ; shift old rSTA reads up a byte
|
||
move.b rSTA(a3),d3
|
||
move.b d3,d0
|
||
btst.l #bINT,d0 ; check for intrp bit ie. timeout or weird phase
|
||
dbne d1, @waitLoop ; if intrp then non-normal select op so exit.
|
||
dbne d2, @waitLoop ; loop until count exhausted or intrp detected
|
||
; count is up or intrp detected so we're outta' here
|
||
beq @timedOut
|
||
;———————————————————
|
||
|
||
; If we got an interrupt, it means that the select command is complete. Either the target did
|
||
; not respond (i.e. didn't exist) or it was selected but went to an unexpected phase.
|
||
@gotINT ; else we got an interrupt
|
||
move.b rSTA(a3), d3 ; read status for debug
|
||
move.b rINT(a3), d1 ; clear intrp bit
|
||
move.b d3, lastSTAread(a4) ; store in case anybody wants to know…
|
||
move.b d1, lastINTread(a4) ; …what kind of INT we got
|
||
bclr.b #FCIntPend, G_State96(a4) ; clear the FC Int pend flag <T9>
|
||
bclr.b #SelInProg, G_State96(a4) ; and clear the SelectInProgress flag <T9>
|
||
bclr.b #NeedMsgOut, G_State96(a4) ; and Message_Out <T9>
|
||
bclr.b #NeedCmdSent, G_State96(a4) ; and Command expected flags <T9>
|
||
|
||
; Was it a disconnect interrupt? (i.e. a failed select?)
|
||
btst.l #bDSC,d1 ; (i.e. timed-out then bus free)
|
||
beq @goodSEL ; no - assume it is a good select then
|
||
@badSEL ; <T8> from last <T8>
|
||
moveq.l #scCommErr, d2 ; select timeout
|
||
bra.s @exit
|
||
|
||
@timedOut
|
||
moveq.l #scArbNBErr, d2 ; select timeout <T9>
|
||
bra @exit ; branch if our watchdog timed out
|
||
|
||
@gotDREQ
|
||
@goodSEL
|
||
moveq.l #noErr, d2 ; successful selection
|
||
@exit
|
||
move.b (sp)+, d0 ; switch to previous mode
|
||
jsr SwapMMU ; do it, call _SwapMMUMode jump vector
|
||
move.l d2, d0
|
||
rts
|
||
|
||
|
||
|
||
; Check for non-zero sequence value - means select has completed and
|
||
;@1 lsl.l #8,d4 ; shift old rSQS reads up a byte
|
||
; move.b rSQS(a3), d4 ; determine where we are in select sequence
|
||
; move.b d4,d0 ; make copy for checking
|
||
; and.b #iSQSMsk, d0 ; did we get somewhere in the sequence?
|
||
; beq.s @zeroSSV ; i.e. a non-zero seq.step value
|
||
|
||
; If we have a non-zero phase value and non-zero sequence, then we had a good select
|
||
; lsl.l #8,d3 ; shift old rSTA reads up a byte
|
||
; move.b rSTA(a3), d3 ; get phase value
|
||
; move.b d3,d0
|
||
; and.b #iPhaseMsk, d0 ; look for info xfer phz (i.e. non zero)
|
||
; bne.s @goodSEL ; bra if not in bus-free (we have a data_out hole here)
|
||
|
||
|
||
|
||
|
||
|
||
|
||
;--------------------------------------------------------------------------
|
||
;
|
||
; Send Command. # bytes in d2. Command block pointer is in a2.
|
||
;
|
||
; d0 - <-- error (if any)
|
||
; d2 - --> number of command bytes
|
||
; d5 - <-- xxxx|xxxx|xxxx|rSTA
|
||
;
|
||
; a2 - ptr to command block
|
||
; a3 - SCSI read base address
|
||
; a4 - ptr to SCSI Mgr globals
|
||
;
|
||
; The command descriptor block is sent using both pseudo-DMA and non-pDMA. The non-pDMA
|
||
; send appears as preloaded data in the FIFO. The last byte is send via pDMA to satisfy
|
||
; the transfer count and DMA-mode of the c96. See SELECT proc.
|
||
;
|
||
;
|
||
; Reminder: Check this routine to make sure it still works with
|
||
; Tape Backup 40SC drive. See note in SCSIMgrOld.a, SendCMD routine.
|
||
;
|
||
; Uses: d0, d1, d3, d5
|
||
;
|
||
; Error Codes:
|
||
; scPhaseErr, scCommErr
|
||
;
|
||
; STILL NEEDS: If somehow we end up here but did not have NeedCmdSent but we are actually in Cmd Phase,
|
||
; we should probably go ahead and do it anyway - just do the transfer with all rFFO (no rDMA).
|
||
|
||
SendCMD_96
|
||
btst.b #NeedCmdSent, G_State96(a4) ; are we expecting a command phase here?
|
||
beq @notExpected ; no - handle it without DMA
|
||
move.b #iCommand, d1 ; set up wait for command phase
|
||
jsr Wt4DREQorInt ; yes - wait till target REQs or screws up
|
||
beq @gotInt ; if Int then we're not in Command phase
|
||
; else, we are, so send the bytes
|
||
@sendBytes
|
||
ori.b #SlowCableMode,rCF1(a3) ; set Slow cable mode for the command bytes <T9>
|
||
subq.l #1, d2 ; adjust for DMA of last byte <T9>
|
||
bra.s @btmLoadFIFO ; bra to dbra for zero case (1 byte CDB) <T9>
|
||
@loadFIFO ; loading the FIFO w/o pseudo-DMA will simulate
|
||
move.b (a2)+, rFFO(a3) ; preloading of the FIFO...we then pDMA the
|
||
@btmLoadFIFO ; <T9>
|
||
dbra d2, @loadFIFO ; last byte in order to satisfy the c96's DMA <T2>
|
||
; circuitry & get us that intrp. <T2>
|
||
if nonSerializedIO Then
|
||
nop ; Force write to complete. <SM8>
|
||
endif
|
||
|
||
btst.b #NeedCmdSent, G_State96(a4) ; were we expecting a command phase here? <2> thru next <2>
|
||
beq.s @skipDMA
|
||
|
||
; Wait for either FIFO empty or a phase change
|
||
|
||
@wt4EmptyOrPhz
|
||
moveq.l #iFOFMsk, d1 ; use mask to get FIFO flag field
|
||
and.b rFOS(a3), d1 ; how many bytes left in FIFO?
|
||
beq.s @lastCmdByte ; if none, send the last command byte
|
||
|
||
moveq.l #iPhaseMsk, d1 ;
|
||
and.b rSTA(a3), d1 ; are we in command phase?
|
||
cmp.b #iCommand, d1 ;
|
||
beq.s @wt4EmptyOrPhz ; yes - loop again
|
||
@lastCmdByte
|
||
moveq.l #iPhaseMsk, d1 ;
|
||
and.b rSTA(a3), d1 ; get phase bits before sending last byte <2> from prev <2>
|
||
|
||
move.b (a2)+, rDMA(a3) ; Use psuedo DMA to load last byte <T2>
|
||
if nonSerializedIO Then
|
||
nop ; Force write to complete. <SM8>
|
||
endif
|
||
|
||
bclr.b #NeedCmdSent,G_State96(a4) ; no longer need command sent and, <T9>
|
||
bset.b #FCIntPend,G_State96(a4) ; now we can expect a FunctionCmplt interrupt <T9>
|
||
cmp.b #iCommand, d1 ; were we in command phz b4 last byte? <2>
|
||
bne.s @phaseErr ; no - then we had a phase error <2>
|
||
@skipDMA
|
||
moveq.l #iPhaseMsk, d3 ; load mask bits for phase value
|
||
and.b rSTA(a3), d3 ; get phase value
|
||
cmpi.b #iCommand, d3 ; are we in command phase?
|
||
beq.s @cmdHack ; bra. if we're still in cmd phase
|
||
@cmdOK
|
||
; we no longer waste a wait here for the FC interrupt but instead do it in a data <T8>
|
||
; phase or in SCSIComplete with a call to HandleSelInProg.
|
||
|
||
moveq.l #noErr, d0 ; no error <T9>
|
||
@cmdExit ; At this point, we're out of cmd phase
|
||
and.b #$FF-SlowCableMode,rCF1(a3) ; turn-off Slow cable mode <T9>
|
||
if nonSerializedIO Then
|
||
nop ; Force write to complete. <SM8>
|
||
endif
|
||
tst.w d0 ;
|
||
rts
|
||
|
||
; This is a hack for the Tape Backup 40SC drive. 40SC asserts an extra REQ on
|
||
; 10-byte commands, which appears as a request for an 11th byte (that's what
|
||
; the SCSI standard says!) On very fast CPU's, this extra REQ hangs over to
|
||
; the next phase of the transaction, causing a phase error, and causes the
|
||
; transaction to fail. This delay code will wait at most 256ms
|
||
; for a phase change before continuing.
|
||
; NOTE: On the c96, this code is probably worthless since the chip will fill
|
||
; any additional bytes (for any additional REQs) after the DREQ is fulfilled
|
||
; whether we wait for it or not. (See state diagram in Emulex lit.)
|
||
@cmdHack
|
||
move.l zeroReg, d0 ; clear upper word
|
||
move.w TimeSCSIDB, d0 ; get SCSI DBRA's ms timing constant
|
||
lsl.l #8, d0 ; wait at least 256ms for the tape drive
|
||
move.l d0, d2 ; set up d2 as high word
|
||
swap d2 ;
|
||
@hack
|
||
moveq.l #iPhaseMsk, d3 ; load mask bits for phase value
|
||
and.b rSTA(a3), d3 ; get phase value
|
||
cmpi.b #iCommand, d3 ; are we in command phase?
|
||
dbne.w d0, @hack ; loop until not cmd phase or timeout
|
||
dbne.w d2, @hack ; high word of timeout
|
||
bra.s @cmdOk
|
||
|
||
; We got our select_process complete interrupt - set our state reflecting that
|
||
@gotInt
|
||
bclr.b #FCIntPend, G_State96(a4) ; clear the FC Int pend flag <Taa>
|
||
bclr.b #SelInProg, G_State96(a4) ; and clear the SelectInProgress flag <Taa>
|
||
bclr.b #NeedMsgOut, G_State96(a4) ; and Message_Out <Taa>
|
||
bclr.b #NeedCmdSent, G_State96(a4) ; and Command expected flags <Taa>
|
||
move.b #cFlshFFO, rCMD(a3) ; flush the FIFO of unused Command bytes
|
||
if nonSerializedIO Then
|
||
nop ; Force write to complete. <SM8>
|
||
endif
|
||
@phaseErr
|
||
moveq.l #scPhaseErr, d0 ; phase error <T5>
|
||
move.l #scsiCmd, d6 ; load proc ID <T5>
|
||
bsr.w Error ; call Error proc - for debug <T5>
|
||
bra.s @cmdExit ; <T5>
|
||
|
||
|
||
@notExpected
|
||
moveq.l #iPhaseMsk, d3 ; load mask bits for phase value
|
||
and.b rSTA(a3), d3 ; get phase value
|
||
cmpi.b #iCommand, d3 ; are we in command phase?
|
||
bne.w @phaseErr ; bra. on phase err
|
||
addq.l #1, d2 ; adjust for DMA of last byte <T9>
|
||
bra.w @sendBytes
|
||
|
||
|
||
|
||
|
||
;--------------------------------------------------------------------------
|
||
;
|
||
; GetMsg - get a message byte from target and return in d2
|
||
;
|
||
; Uses: d0, d2, d3
|
||
;
|
||
; Return Codes:
|
||
; noErr, scCommErr, scPhaseErr
|
||
|
||
GetMsg_96
|
||
moveq.l #iPhaseMsk, d3 ; load mask bits for phase value
|
||
and.b rSTA(a3), d3 ; get phase value
|
||
cmpi.b #iMsgIn, d3 ; are we in MsgIn phase already?
|
||
bne.s @phaseErr ;
|
||
|
||
move.b #cIOXfer, rCMD(a3) ; load Transfer cmd byte in CMD regr
|
||
if nonSerializedIO Then
|
||
nop ; Force write to complete. <SM8>
|
||
endif
|
||
jsr WaitForSCSIIntrp ; Wait for intrp w/ timeout <T3>
|
||
; on exit d5 = xxxx|rSQS|rSTA|rINT
|
||
beq.s @timedOut ; Branch if timedout
|
||
|
||
move.b rFFO(a3), d2 ; xfer fifo msg byte into d2 w/ *ACK still asserted
|
||
; now, unconditionally accept the message byte
|
||
move.b #cMsgAcep, rCMD(a3) ; load msg accepted code which de-asserts *ACK
|
||
if nonSerializedIO Then
|
||
nop ; Force write to complete. <SM8>
|
||
endif
|
||
jsr WaitForSCSIIntrp ; Wait for intrp w/ timeout <T3>
|
||
; on exit d5 = rFOS|rINT|0|rSTA
|
||
beq.s @timedOut ; Branch if timedout
|
||
|
||
; check for disconnect or bus service intrp
|
||
; <--- here!
|
||
moveq.l #noErr, d0
|
||
rts
|
||
|
||
|
||
@dscErr
|
||
@timedOut
|
||
moveq.l #scCommErr, d0 ; comm error
|
||
bra.s @badGetMsg
|
||
@phaseErr
|
||
moveq.l #scPhaseErr, d0
|
||
@badGetMsg
|
||
move.l #0, G_FakeStat(a4) ; Set to a fake stat
|
||
tst.l d0 ; set the condition code <T3>
|
||
rts
|
||
|
||
|
||
|
||
|
||
;--------------------------------------------------------------------------
|
||
;
|
||
; SendMsg - Send a message byte to the target (in d2 on entry)
|
||
;
|
||
; This proc assumes that the ATTENTION line has been asserted via SEL w/ ATN.
|
||
; Note that only 1 msg byte can be sent via this method.
|
||
;
|
||
; Entry:
|
||
; --> d2 message byte to send
|
||
; --> a3 base address of 53c96
|
||
;
|
||
; Exit:
|
||
; <-- d0 result code
|
||
;
|
||
; Uses: d0, d1, d3
|
||
;
|
||
; Error Codes:
|
||
; noErr, scCommErr, scPhaseErr
|
||
|
||
SendMsg_96
|
||
btst.b #NeedMsgOut,G_State96(a4) ; did we send a Select w/ATN?
|
||
beq.s @unexpected ; no - just phase err out of here then
|
||
|
||
move.b #iMsgOut, d1 ; set up wait for command phase
|
||
jsr Wt4DREQorInt
|
||
beq.s @gotInt ; if we got an interrupt, something's wrong
|
||
|
||
move.b rSTA(a3), d3 ; get phase value <T9> to next <T9>
|
||
and.b #iPhaseMsk, d3 ; load mask bits for phase value
|
||
cmpi.b #iMsgOut, d3 ; are we in MsgOut phase already?
|
||
bne.s @phaseErr ;
|
||
|
||
@inPhase ; We probably got here from Select w/ATN which means
|
||
; ATN is deasserted prior to transfer of msg byte
|
||
move.b d2, rFFO(a3) ; xfer msg byte
|
||
if nonSerializedIO Then
|
||
nop ; Force write to complete. <SM8>
|
||
endif
|
||
bclr.b #NeedMsgOut,G_State96(a4) ; did we send a Select w/ATN?
|
||
beq.s @needXfer ; no - just split
|
||
bset.b #NeedCmdSent,G_State96(a4) ; yes - we took care of MsgOut, now we need to send command
|
||
bra.s @noErr
|
||
@needXfer
|
||
jsr Xfer1Byte
|
||
bra.s @noErr
|
||
|
||
|
||
@unexpected ; wait for 256mS for correct phase
|
||
jsr HandleSelInProg
|
||
bne.s @phaseErr
|
||
|
||
moveq.l #0, d1 ; clear upper word
|
||
move.w TimeSCSIDB, d1 ; get # of DBRAs
|
||
lsl.l #8, d1 ; multiply by 256
|
||
move.l d1, d3 ; ...a 256mS wait
|
||
swap d3
|
||
|
||
@1
|
||
move.b rSTA(a3), d3 ; get phase value <T9> to next <T9>
|
||
and.b #iPhaseMsk, d3 ; load mask bits for phase value
|
||
cmpi.b #iMsgOut, d3 ; are we in MsgOut phase already?
|
||
beq.s @inPhase ; yes - send byte
|
||
dbra d1, @1 ;
|
||
dbra d3, @1 ; loop until done
|
||
|
||
|
||
@gotInt ;
|
||
bclr.b #FCIntPend, G_State96(a4) ; clear the FC Int pend flag
|
||
bclr.b #SelInProg, G_State96(a4) ; and clear the SelectInProgress flag
|
||
bclr.b #NeedMsgOut, G_State96(a4) ; and Message_Out <T9>
|
||
bclr.b #NeedCmdSent, G_State96(a4) ; and Command expected flags <T9>
|
||
@phaseErr
|
||
moveq.l #scPhaseErr, d0 ; phase error
|
||
bra.s @clrATN ;
|
||
|
||
@commErr
|
||
moveq.l #scCommErr, d0 ; comm error
|
||
bra.s @clrATN ;
|
||
|
||
@noErr
|
||
moveq.l #noErr, d0 ; no error
|
||
@clrATN
|
||
and.w #$FFFF-aATN,G_FakeStat(a4) ; clear fake ATN bit! <T9> from prev <T9>
|
||
tst.w d0 ; return results in status register
|
||
rts
|
||
|
||
|
||
|
||
|
||
;-------------------------------------------------------------------------- <T3>
|
||
;
|
||
; CyclePhase_96 -- we may have to discard data or write filler bytes to get to
|
||
; the desired phase, status phase.
|
||
;
|
||
; This routine is broken into two main sections; standard I/O and psuedo-DMA. The DMA
|
||
; sequence is used in case we are in the middle of a failed DMA transfer which left the
|
||
; transfer count nonzero. We only have to handle psuedo-DMA in data phase. All other
|
||
; phases (and normal I/O mode data phase) are handled 1 byte at a time by individual
|
||
; phase handling code with, after each byte, returns to check the next phase to see
|
||
; where to go next.
|
||
;
|
||
; Phase Action
|
||
; ————— ——————
|
||
; Command: We send as many EE bytes as needed to get out of phase. If the select sequence
|
||
; flag 'NeedCmdSent' is set, it turns out that the chip will do the fill by itself
|
||
; once we send 1 rDMA byte (thereby completing the transfer) using
|
||
; rDMA. We also set the flag 'FCIntPend' bit if 'NeedCmdSent' was set.
|
||
;
|
||
; Msg_Out: We send as many 08(NOP) bytes as needed to get out of phase. If the select
|
||
; sequence flag 'NeedMsgOut' flag is set we set the flag 'NeedCmdSent' and continue.
|
||
;
|
||
; Data_In: We bitbucket as many bytes as needed to clear phase.
|
||
;
|
||
; Data_Out: We send as many EE bytes as needed to get out of phase.
|
||
;
|
||
;
|
||
; Note: We need to check if the SCSIMgr is busy in order to differentiate between <T2>
|
||
; IDLE bus phase and DATA OUT phase. They both have phase value = 0. <T2>
|
||
;
|
||
; Uses: d0
|
||
|
||
CyclePhase_96 ; (accessed thru jvCyclePhase)
|
||
btst.b #scBusy, G_State(a4) ; check if SCSIMgr is active <T2>
|
||
beq.s @xferErr ; bra. if not
|
||
|
||
IF forPDMDebug THEN ; Till Jimmy stops ignoring DREQ... <SM10>
|
||
PEA @FuckedUpStr
|
||
_DebugStr
|
||
ENDIF
|
||
|
||
@checkNextPhase ; <T9> to next <T9>
|
||
moveq.l #iPhaseMsk, d0 ; load mask bits for phase value
|
||
and.b rSTA(a3), d0 ; get phase bits
|
||
|
||
; cmp #iDataOut, d0 ;
|
||
beq.s @inDataPhase ;
|
||
|
||
cmp #iDataIn, d0 ;
|
||
beq.s @inDataPhase ;
|
||
|
||
cmp #iCommand, d0 ;
|
||
beq @shoveCommand ;
|
||
|
||
cmp #iMsgOut, d0 ;
|
||
beq.w @shoveMsgOut ;
|
||
|
||
cmp #iMsgIn, d0 ;
|
||
beq.w @bitbucketMsgIn ;
|
||
|
||
cmp #iStatus, d0 ;
|
||
bne.s @xferErr
|
||
@okExit
|
||
move.w #scComplPhaseErr, d0 ; tell SCSIComplete we had to read/write junk <T2>
|
||
rts ; err code is saved
|
||
|
||
@xferErr ; <T3>
|
||
clr.l d0 ; no recovery
|
||
rts
|
||
|
||
IF forPDMDebug THEN
|
||
STRING PASCAL
|
||
@FuckedUpStr DC.W 'SCSIMgr is in CyclePhases. Bitbucketting Data...'
|
||
STRING ASIS
|
||
ENDIF
|
||
|
||
; If data phase, check if we have been transferring with psuedo-DMA, if so, continue.
|
||
@inDataPhase
|
||
move.b rCMD(a3), d1 ; what was our most recent command?
|
||
cmp.b #cDMAXfer, d1 ; IF command was DMAXfer AND …
|
||
bne.s @notDMA ;
|
||
tst.b rXCL(a3) ; …there are outstanding pDMA transfers …
|
||
bne.w @pDMA ; THEN go finish them up with psuedo-DMA
|
||
tst.b rXCM(a3)
|
||
bne.w @pDMA
|
||
@notDMA
|
||
cmp.b #iDataOut, d0 ; ELSE … what phase?
|
||
beq.s @shoveDataOut ; data_out - shove data using IO xfers
|
||
;; bra.s @bitbucketData ; data_in - bit bucket using normal IO xfers
|
||
|
||
; Grab and bit bucket a data_in bytes until we've gone into another phase
|
||
@bitbucketData
|
||
jsr Xfer1Byte ; xfer 1 byte and wait for intrp w/o timeout
|
||
; on exit d5 = rFOS|rINT|0|rSTA
|
||
bne.s @xferErr ; bra. on xfer error
|
||
move.b rFFO(a3), d0 ; just empty the FIFO
|
||
bra.s @checkNextPhase
|
||
|
||
|
||
; Dump out data_out bytes until we've gone into another phase
|
||
@shoveDataOut
|
||
move.b #$EE, rFFO(a3) ; load filler byte into FIFO
|
||
if nonSerializedIO Then
|
||
nop ; Force write to complete. <SM8>
|
||
endif
|
||
jsr Xfer1Byte ; xfer 1 byte and wait for intrp w/o timeout
|
||
; on exit d5 = rFOS|rINT|0|rSTA
|
||
bne.s @xferErr ; bra. on xfer error
|
||
bra.s @checkNextPhase
|
||
|
||
|
||
; Dump out Command bytes until we've gone into another phase
|
||
@shoveCommand
|
||
bclr.b #NeedCmdSent, G_State96(a4) ; did we expect this?
|
||
beq.s @nonDMA ; no - bra, do xfer using FIFO
|
||
move.b #$EE, rDMA(a3) ; yes - use DMA (since chip is waiting for it)
|
||
if nonSerializedIO Then
|
||
nop ; Force write to complete. <SM8>
|
||
endif
|
||
bset.b #FCIntPend,G_State96(a4) ; we took care of cmd, now expect FC interrupt
|
||
jsr WaitForSCSIIntrp
|
||
beq.s @timedOut ; bra if timedout
|
||
bclr.b #FCIntPend, G_State96(a4) ; clear the FC Int pend flag
|
||
bclr.b #SelInProg, G_State96(a4) ; clear the select in progress flag
|
||
@timedOut ; if we timed out, something's haywire
|
||
bra.s @2 ; trying again is as good as anything else
|
||
@nonDMA
|
||
move.b #$EE, rFFO(a3) ; load filler byte into FIFO
|
||
if nonSerializedIO Then
|
||
nop ; Force write to complete. <SM8>
|
||
endif
|
||
jsr Xfer1Byte ; xfer 1 byte and wait for intrp w/o timeout
|
||
bne.s @xferErr ; bra. on xfer error
|
||
@2
|
||
bra.s @checkNextPhase
|
||
|
||
|
||
; Dump out message_out bytes until we've gone into another phase
|
||
@shoveMsgOut
|
||
move.b #$08, rFFO(a3) ; load filler byte into FIFO (NOP message)
|
||
if nonSerializedIO Then
|
||
nop ; Force write to complete. <SM8>
|
||
endif
|
||
bclr.b #NeedMsgOut, G_State96(a4) ; did we expect this?
|
||
beq.s @needXferCmd ; no - branch
|
||
bset.b #NeedCmdSent,G_State96(a4) ; yes - taking care of MsgOut, now we need cmd
|
||
bra.s @skipXferCmd
|
||
@needXferCmd
|
||
jsr Xfer1Byte ; xfer 1 byte and wait for intrp w/o timeout
|
||
bne.s @xferErr ; bra. on xfer error
|
||
@skipXferCmd
|
||
bra.s @checkNextPhase
|
||
|
||
|
||
; Grab and bit bucket message bytes until we've gone into another phase
|
||
@bitbucketMsgIn
|
||
jsr Xfer1Byte ; xfer 1 byte and wait for intrp w/o timeout
|
||
bne.s @xferErr ; bra. on xfer error
|
||
move.b rFFO(a3), d0 ; just empty the FIFO
|
||
move.b #cMsgAcep, rCMD(a3) ; load msg accepted code which de-asserts ACK
|
||
if nonSerializedIO Then
|
||
nop ; Force write to complete. <SM8>
|
||
endif
|
||
jsr WaitForSCSIIntrp ; Wait for intrp w/ timeout
|
||
; on exit d5 = rFOS|rINT|0|rSTA
|
||
bra.s @checkNextPhase
|
||
|
||
|
||
;
|
||
; Use pseudo-DMA to clean up pending pDMA transfers ie. recovery from bus timeout <JMA> to next <JMA>
|
||
; It is entirely possible that we might have to use non-pDMA to complete the cleanup
|
||
; which is what the upper half of cyclePhase does.
|
||
|
||
@pDMA
|
||
jsr SCSIpcTo32bit ; use pc relative
|
||
move.b MMU32Bit, -(sp) ; save current mode on stack
|
||
moveq #true32B, d0 ; switch to 32-bit mode to look at SCSI config regr
|
||
jsr SwapMMU ; do it, call _SwapMMUMode jump vector
|
||
move.l G_SCSIDREQ(a4), a0 ; G_SCSIDREQ contains DREQ regr address
|
||
|
||
moveq.l #iPhaseMsk, d0 ;
|
||
and.b rSTA(a3), d0 ;
|
||
cmp #iDataOut, d0 ; what phase?
|
||
beq.s @pDMAwrite ; data_out - pDMAwrite
|
||
;; bra.s @pDMAread ; data_in - pDMAread
|
||
|
||
; Read data bytes using DMA until DREQ goes away
|
||
|
||
@pDMAread
|
||
btst.b #bINT, rSTA(a3) ; poll for intrp hopefully from TC zero
|
||
bne.s @readAll ; bra. if we got one
|
||
IF forPDMDebug THEN ; <SM8>
|
||
move.b (a0), d5 ; read DAFB regr (a0=DAFB register addr)
|
||
ELSE
|
||
move.l (a0), d5 ; read DAFB regr (a0=DAFB register addr)
|
||
ENDIF
|
||
move.b G_bitDREQ(a4),d0 ; load DREQ bit position <4> jab
|
||
btst.l d0, d5 ; DREQ ? <4> jab
|
||
beq.s @pDMAread ; bra. if inactive
|
||
move.w rDMA(a3), d5 ; bit-bucket data
|
||
bra.s @pDMAread
|
||
@readAll ; Intrp will occur when REQ is asserted for the next phase
|
||
jsr WaitForIntNoTime ; Expecting an intrp, clear it when occurs
|
||
; on exit d5 = rFOS|rINT|0|rSTA
|
||
bra.s @pDMADone ; check if we reached status phase
|
||
|
||
|
||
; Write data bytes using DMA until DREQ goes away
|
||
|
||
@pDMAwrite
|
||
btst.b #bINT, rSTA(a3) ; poll for intrp hopefully from TC zero
|
||
bne.s @writeAll ; bra. if we filled all data
|
||
IF forPDMDebug THEN ; <SM8>
|
||
move.b (a0), d5 ; read DAFB regr (a0=DAFB register addr)
|
||
ELSE
|
||
move.l (a0), d5 ; read DAFB regr (a0=DAFB register addr)
|
||
ENDIF
|
||
move.b G_bitDREQ(a4),d0 ; load DREQ bit position <4> jab
|
||
btst.l d0, d5 ; DREQ ? <4> jab
|
||
beq.s @pDMAwrite ; bra. if inactive
|
||
move.w #$EEEE, rDMA(a3) ; load filler data into FIFO
|
||
if nonSerializedIO Then
|
||
nop ; Force write to complete. <SM8>
|
||
endif
|
||
bra.s @pDMAwrite
|
||
@writeAll ; Intrp will occur when REQ is asserted for the next phase
|
||
jsr WaitForIntNoTime ; Expecting an intrp, clear it when occurs
|
||
; on exit d5 = rFOS|rINT|0|rSTA
|
||
|
||
; Return to previous MMUMode and check for next phase to cycle out of
|
||
|
||
@pDMADone
|
||
move.b (sp)+, d0 ; switch to previous mode
|
||
jsr SwapMMU ; do it, call _SwapMMUMode jump vector
|
||
bra.w @checkNextPhase ; go check for next phase to cycle out of
|
||
; <T9> from prev <T9>
|
||
|
||
|
||
|
||
|
||
;_______________________________________________________________________ <T2> thru next <T2>
|
||
;
|
||
; SCSIpcTo32Bit
|
||
; Inputs: none
|
||
; Destroys: A0, D0
|
||
; Calls: _Translate24To32
|
||
;
|
||
; Function: Converts the PC to a 32-bit address.
|
||
;
|
||
; Routine from EdiskDrvr.a
|
||
;_______________________________________________________________________
|
||
|
||
SCSIpcTo32Bit
|
||
IF not forROM THEN ; SM is always in 32-bit mode
|
||
move.l (sp), d0 ; put return address in d0
|
||
_Translate24to32 ; convert the address to 32-bit mode
|
||
move.l d0, (sp) ; save the new return address
|
||
ENDIF
|
||
rts ; <T2>
|
||
|
||
|
||
|
||
|
||
;_______________________________________________________________________
|
||
;
|
||
; TestForDREQ
|
||
; This is good for a one time only test. If the value of DREQ
|
||
; needs to be determined in a loop, use something else.
|
||
;_______________________________________________________________________
|
||
;
|
||
TestForDREQ
|
||
jsr SCSIpcTo32bit ; use pc relative
|
||
moveq #true32B, d0 ; switch to 32-bit mode to look at SCSI config regr
|
||
jsr SwapMMU ; (sets up d0 with previous mode)
|
||
|
||
move.l G_SCSIDREQ(a4), a0 ; G_SCSIDREQ contains DREQ regr address
|
||
IF forPDMDebug THEN ; <SM8>
|
||
move.b (a0), d5 ; read DAFB regr (a0=DAFB register addr)
|
||
ELSE
|
||
move.l (a0), d5 ; read DAFB regr (a0=DAFB register addr)
|
||
ENDIF
|
||
|
||
jsr SwapMMU ; return to previous mode (in d0)
|
||
|
||
move.b G_bitDREQ(a4),d0 ; load DREQ bit position <4> jab
|
||
btst.l d0, d5 ; DREQ ? <4> jab
|
||
rts
|
||
|
||
|
||
|
||
|
||
;--------------------------------------------------------------------------
|
||
;
|
||
; Error -- proc call by most top level SCSI proc when an error occurs
|
||
; Primarily for debugging.
|
||
;
|
||
; Called by: SCSISelect(S/D,ATN), SCSICmd, SCSIRead(Slow/Fast), SCSIWrite(Slow/Fast),
|
||
; SCSIComp(Slow/Fast), SCSIMsgIn, SCSIMsgOut, SCSIComplete
|
||
;
|
||
; d0 -> SCSI error code
|
||
; d6 -> SCSI proc ID
|
||
;
|
||
; Uses: a0
|
||
|
||
Error
|
||
movea.l jvErr(a4), a0 ; get address of error routine
|
||
jsr (a0) ;
|
||
rts
|
||
|
||
|
||
|
||
|
||
|
||
;--------------------------------------------------------------------------
|
||
;
|
||
; SCSIErr -- Primarily for debugging.
|
||
;
|
||
SCSIErr_96
|
||
rts ;
|
||
|
||
|
||
|
||
|
||
|
||
;--------------------------------------------------------------------------
|
||
;
|
||
; SwapMMU
|
||
; Swaps MMU into mode specified in D0. Returns previous
|
||
; MMUMode in D0.
|
||
;
|
||
; Registers : D0 affected as above. No others affected.
|
||
;
|
||
SwapMMU
|
||
IF not forROM THEN
|
||
movem.l d1/a0, -(sp)
|
||
jsr ([jSwapMMU]) ; do it, call _SwapMMUMode jump vector(smashes d1/a0)
|
||
movem.l (sp)+, d1/a0
|
||
ENDIF
|
||
rts
|
||
|
||
|
||
;==========================================================================
|
||
|
||
ENDWITH
|
||
|
||
END
|