; ;============================================================================= ; IDE DISK DRIVER ;============================================================================= ; ; TODO: ; - IMPLEMENT IDE_INITDEVICE ; - HANDLE SECONDARY INTERFACE ON DIDE ; - IMPLEMENT INTELLIGENT RESET, CHECK IF DEVICE IS ACTUALLY BROKEN BEFORE RESET ; ; +-----------------------------------------------------------------------+ ; | CONTROL BLOCK REGISTERS | ; +-----------------------+-------+-------+-------------------------------+ ; | REGISTER | PORT | DIR | DESCRIPTION | ; +-----------------------+-------+-------+-------------------------------+ ; | IDE_IO_ALTSTAT | 0x0E | R | ALTERNATE STATUS REGISTER | ; | IDE_IO_CTRL | 0x0E | W | DEVICE CONTROL REGISTER | ; | IDE_IO_DRVADR | 0x0F | R | DRIVE ADDRESS REGISTER | ; +-----------------------+-------+-------+-------------------------------+ ; ; +-----------------------+-------+-------+-------------------------------+ ; | COMMAND BLOCK REGISTERS | ; +-----------------------+-------+-------+-------------------------------+ ; | REGISTER | PORT | DIR | DESCRIPTION | ; +-----------------------+-------+-------+-------------------------------+ ; | IDE_IO_DATA | 0x00 | R/W | DATA INPUT/OUTPUT | ; | IDE_IO_ERR | 0x01 | R | ERROR REGISTER | ; | IDE_IO_FEAT | 0x01 | W | FEATURES REGISTER | ; | IDE_IO_COUNT | 0x02 | R/W | SECTOR COUNT REGISTER | ; | IDE_IO_SECT | 0x03 | R/W | SECTOR NUMBER REGISTER | ; | IDE_IO_CYLLO | 0x04 | R/W | CYLINDER NUM REGISTER (LSB) | ; | IDE_IO_CYLHI | 0x05 | R/W | CYLINDER NUM REGISTER (MSB) | ; | IDE_IO_DRVHD | 0x06 | R/W | DRIVE/HEAD REGISTER | ; | IDE_IO_LBA0* | 0x03 | R/W | LBA BYTE 0 (BITS 0-7) | ; | IDE_IO_LBA1* | 0x04 | R/W | LBA BYTE 1 (BITS 8-15) | ; | IDE_IO_LBA2* | 0x05 | R/W | LBA BYTE 2 (BITS 16-23) | ; | IDE_IO_LBA3* | 0x06 | R/W | LBA BYTE 3 (BITS 24-27) | ; | IDE_IO_STAT | 0x07 | R | STATUS REGISTER | ; | IDE_IO_CMD | 0x07 | W | COMMAND REGISTER (EXECUTE) | ; +-----------------------+-------+-------+-------------------------------+ ; * LBA0-4 ARE ALTERNATE DEFINITIONS OF SECT, CYL, AND DRVHD PORTS ; ; === STATUS REGISTER === ; ; 7 6 5 4 3 2 1 0 ; +-------+-------+-------+-------+-------+-------+-------+-------+ ; | BSY | DRDY | DWF | DSC | DRQ | CORR | IDX | ERR | ; +-------+-------+-------+-------+-------+-------+-------+-------+ ; ; BSY: BUSY ; DRDY: DRIVE READY ; DWF: DRIVE WRITE FAULT ; DSC: DRIVE SEEK COMPLETE ; DRQ: DATA REQUEST ; CORR: CORRECTED DATA ; IDX: INDEX ; ERR: ERROR ; ; === ERROR REGISTER === ; ; 7 6 5 4 3 2 1 0 ; +-------+-------+-------+-------+-------+-------+-------+-------+ ; | BBK | UNC | MC | IDNF | MCR | ABRT | TK0NF | AMNF | ; +-------+-------+-------+-------+-------+-------+-------+-------+ ; (VALID WHEN ERR BIT IS SET IN STATUS REGISTER) ; ; BBK: BAD BLOCK DETECTED ; UNC: UNCORRECTABLE DATA ERROR ; MC: MEDIA CHANGED ; IDNF: ID NOT FOUND ; MCR: MEDIA CHANGE REQUESTED ; ABRT: ABORTED COMMAND ; TK0NF: TRACK 0 NOT FOUND ; AMNF: ADDRESS MARK NOT FOUND ; ; === DRIVE/HEAD / LBA3 REGISTER === ; ; 7 6 5 4 3 2 1 0 ; +-------+-------+-------+-------+-------+-------+-------+-------+ ; | 1 | L | 1 | DRV | HS3 | HS2 | HS1 | HS0 | ; +-------+-------+-------+-------+-------+-------+-------+-------+ ; ; L: 0 = CHS ADDRESSING, 1 = LBA ADDRESSING ; DRV: 0 = DRIVE 0 (PRIMARY) SELECTED, 1 = DRIVE 1 (SLAVE) SELECTED ; HS: CHS = HEAD ADDRESS (0-15), LBA = BITS 24-27 OF LBA ; ; === DEVICE CONTROL REGISTER === ; ; 7 6 5 4 3 2 1 0 ; +-------+-------+-------+-------+-------+-------+-------+-------+ ; | X | X | X | X | 1 | SRST | ~IEN | 0 | ; +-------+-------+-------+-------+-------+-------+-------+-------+ ; ; SRST: SOFTWARE RESET ; ~IEN: INTERRUPT ENABLE ; #IF (IDETRACE >= 3) #DEFINE DCALL CALL #ELSE #DEFINE DCALL \; #ENDIF ; ; UNIT MAPPING IS AS FOLLOWS: ; IDE0: PRIMARY MASTER ; IDE1: PRIMARY SLAVE ; IDE2: SECONDARY MASTER ; IDE3: SECONDARY SLAVE ; IDE_UNITCNT .EQU 2 ; ASSUME ONLY PRIMARY INTERFACE ; #IF (IDEMODE == IDEMODE_MK4) IDE_IO_BASE .EQU MK4_IDE #ELSE IDE_IO_BASE .EQU $20 #ENDIF #IF ((IDEMODE == IDEMODE_DIO) | (IDEMODE == IDEMODE_MK4)) #IF (IDE8BIT) IDE_IO_DATA .EQU $IDE_IO_BASE + $00 ; DATA PORT (8 BIT PIO) (R/W) #ELSE IDE_IO_DATALO .EQU $IDE_IO_BASE + $00 ; DATA PORT (16 BIT PIO LO BYTE) (R/W) IDE_IO_DATAHI .EQU $IDE_IO_BASE + $08 ; DATA PORT (16 BIT PIO HI BYTE) (R/W) IDE_IO_DATA .EQU IDE_IO_DATALO #ENDIF #ENDIF ; #IF (IDEMODE == IDEMODE_DIDE) IDE_UNITCNT .SET 4 ; DIDE HAS PRIMARY AND SECONDARY INTERACES #IF (IDE8BIT) IDE_IO_DATA .EQU $IDE_IO_BASE + $00 ; DATA PORT (8 BIT PIO) (R/W) #ELSE IDE_IO_DATA .EQU $IDE_IO_BASE + $08 ; DATA PORT (16 BIT PIO LO/HI BYTES) (R/W) IDE_IO_DMA .EQU $IDE_IO_BASE + $09 ; DATA PORT (16 BIT DMA LO/HI BYTES) (R/W) #ENDIF #ENDIF ; ;IDE_IO_DATA .EQU $IDE_IO_BASE + $00 ; DATA INPUT/OUTPUT (R/W) IDE_IO_ERR .EQU $IDE_IO_BASE + $01 ; ERROR REGISTER (R) IDE_IO_FEAT .EQU $IDE_IO_BASE + $01 ; FEATURES REGISTER (W) IDE_IO_COUNT .EQU $IDE_IO_BASE + $02 ; SECTOR COUNT REGISTER (R/W) IDE_IO_SECT .EQU $IDE_IO_BASE + $03 ; SECTOR NUMBER REGISTER (R/W) IDE_IO_CYLLO .EQU $IDE_IO_BASE + $04 ; CYLINDER NUM REGISTER (LSB) (R/W) IDE_IO_CYLHI .EQU $IDE_IO_BASE + $05 ; CYLINDER NUM REGISTER (MSB) (R/W) IDE_IO_DRVHD .EQU $IDE_IO_BASE + $06 ; DRIVE/HEAD REGISTER (R/W) IDE_IO_LBA0 .EQU $IDE_IO_BASE + $03 ; LBA BYTE 0 (BITS 0-7) (R/W) IDE_IO_LBA1 .EQU $IDE_IO_BASE + $03 ; LBA BYTE 1 (BITS 8-15) (R/W) IDE_IO_LBA2 .EQU $IDE_IO_BASE + $03 ; LBA BYTE 2 (BITS 16-23) (R/W) IDE_IO_LBA3 .EQU $IDE_IO_BASE + $03 ; LBA BYTE 3 (BITS 24-27) (R/W) IDE_IO_STAT .EQU $IDE_IO_BASE + $07 ; STATUS REGISTER (R) IDE_IO_CMD .EQU $IDE_IO_BASE + $07 ; COMMAND REGISTER (EXECUTE) (W) IDE_IO_ALTSTAT .EQU $IDE_IO_BASE + $0E ; ALTERNATE STATUS REGISTER (R) IDE_IO_CTRL .EQU $IDE_IO_BASE + $0E ; DEVICE CONTROL REGISTER (W) IDE_IO_DRVADR .EQU $IDE_IO_BASE + $0F ; DRIVE ADDRESS REGISTER (R) ; ; COMMAND BYTES ; IDE_CIDE_RECAL .EQU $10 IDE_CIDE_READ .EQU $20 IDE_CIDE_WRITE .EQU $30 IDE_CIDE_IDDEV .EQU $EC IDE_CIDE_SETFEAT .EQU $EF ; ; FEATURE BYTES ; IDE_FEAT_ENABLE8BIT .EQU $01 IDE_FEAT_DISABLE8BIT .EQU $81 ; ; IDE DEVICE TYPES ; IDE_TYPEUNK .EQU 0 IDE_TYPEATA .EQU 1 IDE_TYPEATAPI .EQU 2 ; ; IDE DEVICE STATUS ; IDE_STOK .EQU 0 IDE_STINVUNIT .EQU -1 IDE_STNOMEDIA .EQU -2 IDE_STCMDERR .EQU -3 IDE_STIOERR .EQU -4 IDE_STRDYTO .EQU -5 IDE_STDRQTO .EQU -6 IDE_STBSYTO .EQU -7 ; ; DRIVE SELECTION BYTES (FOR USE IN DRIVE/HEAD REGISTER) ; IDE_DRVSEL: IDE_DRVMASTER .DB %11100000 ; LBA, MASTER DEVICE IDE_DRVSLAVE .DB %11110000 ; LBA, SLAVE DEVICE ; ; PER UNIT DATA OFFSETS (CAREFUL NOT TO EXCEED PER UNIT SPACE IN IDE_UNITDATA) ; SEE IDE_UNITDATA IN DATA STORAGE BELOW ; IDE_STAT .EQU 0 ; LAST STATUS (1 BYTE) IDE_TYPE .EQU 1 ; DEVICE TYPE (1 BYTE) IDE_CAPACITY .EQU 2 ; DEVICE CAPACITY (1 DWORD/4 BYTES) IDE_CFFLAG .EQU 6 ; CF FLAG (1 BYTE), NON-ZERO=CF ; ; THE IDE_WAITXXX FUNCTIONS ARE BUILT TO TIMEOUT AS NEEDED SO DRIVER WILL ; NOT HANG IF DEVICE IS UNRESPONSIVE. DIFFERENT TIMEOUTS ARE USED DEPENDING ; ON THE SITUATION. GENERALLY, THE FAST TIMEOUT IS USED TO PROBE FOR DEVICES ; USING FUNCTIONS THAT PERFORM NO I/O. OTHERWISE THE NORMAL TIMEOUT IS USED. ; IDE SPEC ALLOWS FOR UP TO 30 SECS MAX TO RESPOND. IN PRACTICE, THIS IS WAY ; TOO LONG, BUT IF YOU ARE USING A VERY OLD DEVICE, THESE TIMEOUTS MAY NEED TO ; BE ADJUSTED. NOTE THAT THESE ARE BYTE VALUES, SO YOU CANNOT EXCEED 255. ; THE TIMEOUTS ARE IN UNITS OF .05 SECONDS. ; IDE_TONORM .EQU 200 ; NORMAL TIMEOUT IS 10 SECS IDE_TOFAST .EQU 10 ; FAST TIMEOUT IS 0.5 SECS ; ; MACRO TO RETURN POINTER TO FIELD WITHIN UNIT DATA ; #DEFINE IDE_DPTR(FIELD) CALL IDE_DPTRIMP \ .DB FIELD ; ;============================================================================= ; INITIALIZATION ENTRY POINT ;============================================================================= ; IDE_INIT: CALL NEWLINE ; FORMATTING PRTS("IDE:$") ; LABEL FOR IO ADDRESS ; ; SETUP THE DISPATCH TABLE ENTRIES ; LD B,IDE_UNITCNT ; LOOP CONTROL LD C,0 ; PHYSICAL UNIT INDEX IDE_INIT0: PUSH BC ; SAVE LOOP CONTROL LD B,C ; PHYSICAL UNIT LD C,DIODEV_IDE ; DEVICE TYPE LD DE,0 ; UNIT DATA BLOB ADDRESS CALL DIO_ADDENT ; ADD ENTRY, BC IS NOT DESTROYED POP BC ; RESTORE LOOP CONTROL INC C ; NEXT PHYSICAL UNIT DJNZ IDE_INIT0 ; LOOP UNTIL DONE ; ; COMPUTE CPU SPEED COMPENSATED TIMEOUT SCALER ; AT 1MHZ, THE SCALER IS 961 (50000US / 52TS = 961) ; SCALER IS THEREFORE 961 * CPU SPEED IN MHZ LD DE,961 ; LOAD SCALER FOR 1MHZ LD A,(HCB + HCB_CPUMHZ) ; LOAD CPU SPEED IN MHZ CALL MULT8X16 ; HL := DE * A LD (IDE_TOSCALER),HL ; SAVE IT ; #IF (IDEMODE == IDEMODE_DIO) PRTS(" MODE=DIO$") #ENDIF #IF (IDEMODE == IDEMODE_DIDE) PRTS(" MODE=DIDE$") #ENDIF #IF (IDEMODE == IDEMODE_MK4) PRTS(" MODE=MK4$") #ENDIF ; PRINT IDE INTERFACE PORT ADDRESS PRTS(" IO=0x$") ; LABEL FOR IO ADDRESS LD A,IDE_IO_DATA ; GET IO ADDRESS CALL PRTHEXBYTE ; PRINT IT ; ; PRINT UNIT COUNT PRTS(" UNITS=$") ; PRINT LABEL FOR UNIT COUNT LD A,IDE_UNITCNT ; GET UNIT COUNT CALL PRTDECB ; PRINT IT IN DECIMAL ; ; INITIALIZE THE IDE INTERFACE NOW CALL IDE_RESET ; DO HARDWARE SETUP/INIT RET NZ ; ABORT IF RESET FAILS ; ; DEVICE DISPLAY LOOP LD B,IDE_UNITCNT ; LOOP ONCE PER UNIT LD C,0 ; C IS UNIT INDEX IDE_INIT1: LD A,C ; UNIT NUM TO ACCUM PUSH BC ; SAVE LOOP CONTROL CALL IDE_INIT2 ; DISPLAY UNIT INFO POP BC ; RESTORE LOOP CONTROL INC C ; INCREMENT UNIT INDEX DJNZ IDE_INIT1 ; LOOP UNTIL DONE RET ; DONE ; IDE_INIT2: LD (IDE_UNIT),A ; SET CURRENT UNIT ; ; CHECK FOR BAD STATUS IDE_DPTR(IDE_STAT) ; GET STATUS ADR IN HL, AF TRASHED LD A,(HL) OR A JP NZ,IDE_PRTSTAT ; CALL IDE_PRTPREFIX ; PRINT DEVICE PREFIX ; #IF (IDE8BIT) PRTS(" 8BIT$") #ENDIF ; ; PRINT LBA/NOLBA CALL PC_SPACE ; FORMATTING LD HL,HB_WRKBUF ; POINT TO BUFFER START LD DE,98+1 ; OFFSET OF BYTE CONTAINING LBA FLAG ADD HL,DE ; POINT TO FINAL BUFFER ADDRESS LD A,(HL) ; GET THE BYTE BIT 1,A ; CHECK THE LBA BIT LD DE,IDE_STR_NO ; POINT TO "NO" STRING CALL Z,WRITESTR ; PRINT "NO" BEFORE "LBA" IF LBA NOT SUPPORTED PRTS("LBA$") ; PRINT "LBA" REGARDLESS ; ; PRINT STORAGE CAPACITY (BLOCK COUNT) PRTS(" BLOCKS=0x$") ; PRINT FIELD LABEL IDE_DPTR(IDE_CAPACITY) ; SET HL TO ADR OF DEVICE CAPACITY CALL LD32 ; GET THE CAPACITY VALUE CALL PRTHEX32 ; PRINT HEX VALUE ; ; PRINT STORAGE SIZE IN MB PRTS(" SIZE=$") ; PRINT FIELD LABEL LD B,11 ; 11 BIT SHIFT TO CONVERT BLOCKS --> MB CALL SRL32 ; RIGHT SHIFT CALL PRTDEC ; PRINT LOW WORD IN DECIMAL (HIGH WORD DISCARDED) PRTS("MB$") ; PRINT SUFFIX ; XOR A ; SIGNAL SUCCESS RET ; RETURN WITH A=0, AND Z SET ; ;============================================================================= ; FUNCTION DISPATCH ENTRY POINT ;============================================================================= ; IDE_DISPATCH: ; VERIFY AND SAVE THE TARGET DEVICE/UNIT LOCALLY IN DRIVER LD A,C ; DEVICE/UNIT FROM C AND $0F ; ISOLATE UNIT NUM CP IDE_UNITCNT CALL NC,PANIC ; PANIC IF TOO HIGH LD (IDE_UNIT),A ; SAVE IT ; ; DISPATCH ACCORDING TO DISK SUB-FUNCTION LD A,B ; GET REQUESTED FUNCTION AND $0F ; ISOLATE SUB-FUNCTION JP Z,IDE_STATUS ; SUB-FUNC 0: STATUS DEC A JP Z,IDE_RESET ; SUB-FUNC 1: RESET DEC A JP Z,IDE_SEEK ; SUB-FUNC 2: SEEK DEC A JP Z,IDE_READ ; SUB-FUNC 3: READ SECTORS DEC A JP Z,IDE_WRITE ; SUB-FUNC 4: WRITE SECTORS DEC A JP Z,IDE_VERIFY ; SUB-FUNC 5: VERIFY SECTORS DEC A JP Z,IDE_FORMAT ; SUB-FUNC 6: FORMAT TRACK DEC A JP Z,IDE_DEVICE ; SUB-FUNC 7: DEVICE REPORT DEC A JP Z,IDE_MEDIA ; SUB-FUNC 8: MEDIA REPORT DEC A JP Z,IDE_DEFMED ; SUB-FUNC 9: DEFINE MEDIA DEC A JP Z,IDE_CAP ; SUB-FUNC 10: REPORT CAPACITY DEC A JP Z,IDE_GEOM ; SUB-FUNC 11: REPORT GEOMETRY ; IDE_VERIFY: IDE_FORMAT: IDE_DEFMED: CALL PANIC ; INVALID SUB-FUNCTION ; ; ; IDE_READ: LD (IDE_DSKBUF),HL ; SAVE DISK BUFFER ADDRESS #IF (IDETRACE == 1) LD HL,IDE_PRTERR ; SET UP IDE_PRTERR PUSH HL ; ... TO FILTER ALL EXITS #ENDIF CALL IDE_SELUNIT ; HARDWARE SELECTION OF TARGET UNIT JP IDE_RDSEC ; ; ; IDE_WRITE: LD (IDE_DSKBUF),HL ; SAVE DISK BUFFER ADDRESS #IF (IDETRACE == 1) LD HL,IDE_PRTERR ; SET UP IDE_PRTERR PUSH HL ; ... TO FILTER ALL EXITS #ENDIF CALL IDE_SELUNIT ; HARDWARE SELECTION OF TARGET UNIT JP IDE_WRSEC ; ; ; IDE_STATUS: ; RETURN UNIT STATUS IDE_DPTR(IDE_STAT) ; HL := ADR OF STATUS, AF TRASHED LD A,(HL) ; GET STATUS OF SELECTED UNIT OR A ; SET FLAGS RET ; AND RETURN ; ; ; IDE_DEVICE: LD D,DIODEV_IDE ; D := DEVICE TYPE LD E,C ; E := PHYSICAL UNIT IDE_DPTR(IDE_CFFLAG) ; POINT TO CF FLAG LD A,(HL) ; GET FLAG OR A ; SET ACCUM FLAGS LD C,%00000000 ; ASSUME NON-REMOVABLE HARD DISK JR Z,IDE_DEVICE1 ; IF Z, WE ARE DONE LD C,%01001000 ; OTHERWISE REMOVABLE COMPACT FLASH IDE_DEVICE1: XOR A ; SIGNAL SUCCESS RET ; ; IDE_GETMED ; IDE_MEDIA: LD A,E ; GET FLAGS OR A ; SET FLAGS JR Z,IDE_MEDIA2 ; JUST REPORT CURRENT STATUS AND MEDIA ; ; GET CURRENT STATUS IDE_DPTR(IDE_STAT) ; POINT TO UNIT STATUS LD A,(HL) ; GET STATUS OR A ; SET FLAGS JR NZ,IDE_MEDIA1 ; ERROR ACTIVE, TO RIGHT TO RESET ; ; USE IDENTIFY COMMAND TO CHECK DEVICE LD HL,IDE_TIMEOUT ; POINT TO TIMEOUT LD (HL),IDE_TOFAST ; USE FAST TIMEOUT DURING IDENTIFY COMMAND CALL IDE_IDENTIFY ; EXECUTE IDENTIFY COMMAND LD HL,IDE_TIMEOUT ; POINT TO TIMEOUT LD (HL),IDE_TONORM ; BACK TO NORMAL TIMEOUT JR Z,IDE_MEDIA2 ; IF SUCCESS, BYPASS RESET ; IDE_MEDIA1: CALL IDE_RESET ; RESET IDE INTERFACE ; IDE_MEDIA2: IDE_DPTR(IDE_STAT) ; POINT TO UNIT STATUS LD A,(HL) ; GET STATUS OR A ; SET FLAGS LD D,0 ; NO MEDIA CHANGE DETECTED LD E,MID_HD ; ASSUME WE ARE OK RET Z ; RETURN IF GOOD INIT LD E,MID_NONE ; SIGNAL NO MEDIA RET ; AND RETURN ; ; ; IDE_SEEK: BIT 7,D ; CHECK FOR LBA FLAG CALL Z,HB_CHS2LBA ; CLEAR MEANS CHS, CONVERT TO LBA RES 7,D ; CLEAR FLAG REGARDLESS (DOES NO HARM IF ALREADY LBA) LD BC,HSTLBA ; POINT TO LBA STORAGE CALL ST32 ; SAVE LBA ADDRESS XOR A ; SIGNAL SUCCESS RET ; AND RETURN ; ; ; IDE_CAP: IDE_DPTR(IDE_CAPACITY) ; POINT HL TO CAPACITY OF CUR UNIT CALL LD32 ; GET THE CURRENT CAPACITY DO DE:HL LD BC,512 ; 512 BYTES PER BLOCK IDE_DPTR(IDE_STAT) ; POINT TO UNIT STATUS LD A,(HL) ; GET STATUS OR A ; SET FLAGS RET ; ; ; IDE_GEOM: ; FOR LBA, WE SIMULATE CHS ACCESS USING 16 HEADS AND 16 SECTORS ; RETURN HS:CC -> DE:HL, SET HIGH BIT OF D TO INDICATE LBA CAPABLE CALL IDE_CAP ; GET TOTAL BLOCKS IN DE:HL, BLOCK SIZE TO BC LD L,H ; DIVIDE BY 256 FOR # TRACKS LD H,E ; ... HIGH BYTE DISCARDED, RESULT IN HL LD D,16 | $80 ; HEADS / CYL = 16, SET LBA CAPABILITY BIT LD E,16 ; SECTORS / TRACK = 16 RET ; DONE, A STILL HAS IDE_CAP STATUS ; ;============================================================================= ; FUNCTION SUPPORT ROUTINES ;============================================================================= ; IDE_SETFEAT: PUSH AF #IF (IDETRACE >= 3) CALL IDE_PRTPREFIX PRTS(" SETFEAT$") #ENDIF LD A,(IDE_DRVHD) OUT (IDE_IO_DRVHD),A DCALL PC_SPACE DCALL PRTHEXBYTE POP AF OUT (IDE_IO_FEAT),A ; SET THE FEATURE VALUE DCALL PC_SPACE DCALL PRTHEXBYTE LD A,IDE_CIDE_SETFEAT ; CMD = SETFEAT LD (IDE_CMD),A ; SAVE IT JP IDE_RUNCMD ; RUN COMMAND AND EXIT ; ; ; IDE_IDENTIFY: #IF (IDETRACE >= 3) CALL IDE_PRTPREFIX PRTS(" IDDEV$") #ENDIF LD A,(IDE_DRVHD) OUT (IDE_IO_DRVHD),A DCALL PC_SPACE DCALL PRTHEXBYTE LD A,IDE_CIDE_IDDEV LD (IDE_CMD),A CALL IDE_RUNCMD RET NZ LD HL,HB_WRKBUF JP IDE_GETBUF ; EXIT THRU BUFRD ; ; ; IDE_RDSEC: CALL IDE_CHKDEVICE RET NZ ; #IF (IDETRACE >= 3) CALL IDE_PRTPREFIX PRTS(" READ$") #ENDIF LD A,(IDE_DRVHD) OUT (IDE_IO_DRVHD),A DCALL PC_SPACE DCALL PRTHEXBYTE CALL IDE_SETADDR ; SETUP CYL, TRK, HEAD LD A,IDE_CIDE_READ LD (IDE_CMD),A CALL IDE_RUNCMD RET NZ LD HL,(IDE_DSKBUF) JP IDE_GETBUF ; ; ; IDE_WRSEC: CALL IDE_CHKDEVICE RET NZ ; #IF (IDETRACE >= 3) CALL IDE_PRTPREFIX PRTS(" WRITE$") #ENDIF LD A,(IDE_DRVHD) OUT (IDE_IO_DRVHD),A DCALL PC_SPACE DCALL PRTHEXBYTE CALL IDE_SETADDR ; SETUP CYL, TRK, HEAD LD A,IDE_CIDE_WRITE LD (IDE_CMD),A CALL IDE_RUNCMD RET NZ LD HL,(IDE_DSKBUF) JP IDE_PUTBUF ; ; ; IDE_SETADDR: ; SEND 3 LOWEST BYTES OF LBA IN REVERSE ORDER ; IDE_IO_LBA3 HAS ALREADY BEEN SET ; HSTLBA2-0 --> IDE_IO_LBA2-0 LD C,IDE_IO_LBA0 + 3 ; STARTING IO PORT (NOT PRE-DEC BELOW) LD HL,HSTLBA + 2 ; STARTING LBA BYTE ADR LD B,3 ; SEND 3 BYTES IDE_SETADDR1: ; #IF (IDETRACE >= 3) LD A,(HL) CALL PC_SPACE CALL PRTHEXBYTE #ENDIF ; DEC C ; NEXT PORT OUTD ; SEND NEXT BYTE JR NZ,IDE_SETADDR1 ; LOOP TILL DONE ; ; SEND COUNT OF BLOCKS TO TRANSFER ; 1 --> IDE_IO_COUNT LD A,1 ; COUNT VALUE IS 1 BLOCK ; #IF (IDETRACE >= 3) DCALL PC_SPACE DCALL PRTHEXBYTE #ENDIF ; DEC C ; PORT := IDE_IO_COUNT OUT (C),A ; SEND IT ; #IF (DSKYENABLE) CALL IDE_DSKY #ENDIF ; RET ; ;============================================================================= ; COMMAND PROCESSING ;============================================================================= ; IDE_RUNCMD: CALL IDE_WAITRDY ; WAIT FOR DRIVE READY RET NZ ; BAIL OUT ON TIMEOUT ; LD A,(IDE_CMD) ; GET THE COMMAND DCALL PC_SPACE DCALL PRTHEXBYTE OUT (IDE_IO_CMD),A ; SEND IT (STARTS EXECUTION) #IF (IDETRACE >= 3) PRTS(" -->$") #ENDIF ; CALL IDE_WAITBSY ; WAIT FOR DRIVE READY (COMMAND DONE) RET NZ ; BAIL OUT ON TIMEOUT ; CALL IDE_GETRES JP NZ,IDE_CMDERR RET ; ; ; IDE_GETBUF: #IF (IDETRACE >= 3) PRTS(" GETBUF$") #ENDIF CALL IDE_WAITDRQ ; WAIT FOR BUFFER READY RET NZ ; BAIL OUT IF TIMEOUT ;LD HL,(IDE_DSKBUF) LD B,0 #IF (IDE8BIT | (IDEMODE == IDEMODE_DIDE)) LD C,IDE_IO_DATA INIR INIR ;X1: ; NOP ; INI ; JR NZ,X1 ;X2: ; NOP ; INI ; JR NZ,X2 #ELSE LD C,IDE_IO_DATAHI IDE_GETBUF1: IN A,(IDE_IO_DATALO) ; READ THE LO BYTE LD (HL),A ; SAVE IN BUFFER INC HL ; INC BUFFER POINTER INI ; READ AND SAVE HI BYTE, INC HL, DEC B JP NZ,IDE_GETBUF1 ; LOOP AS NEEDED #ENDIF CALL IDE_WAITRDY ; PROBLEMS IF THIS IS REMOVED! CALL IDE_GETRES JP NZ,IDE_IOERR RET ; ; ; IDE_PUTBUF: #IF (IDETRACE >= 3) PRTS(" GETBUF$") #ENDIF CALL IDE_WAITDRQ ; WAIT FOR BUFFER READY RET NZ ; BAIL OUT IF TIMEOUT ; ;LD HL,(IDE_DSKBUF) LD B,0 #IF (IDE8BIT | (IDEMODE == IDEMODE_DIDE)) LD C,IDE_IO_DATA OTIR OTIR #ELSE LD C,IDE_IO_DATAHI IDE_PUTBUF1: LD A,(HL) ; GET THE LO BYTE AND KEEP IT IN A FOR LATER INC HL ; BUMP TO NEXT BYTE IN BUFFER OUTI ; WRITE HI BYTE, INC HL, DEC B OUT (IDE_IO_DATALO),A ; NOW WRITE THE SAVED LO BYTE TO LO BYTE JP NZ,IDE_PUTBUF1 ; LOOP AS NEEDED #ENDIF CALL IDE_WAITRDY ; PROBLEMS IF THIS IS REMOVED! CALL IDE_GETRES JP NZ,IDE_IOERR RET ; ; ; IDE_GETRES: IN A,(IDE_IO_STAT) ; GET STATUS DCALL PC_SPACE DCALL PRTHEXBYTE AND %00000001 ; ERROR BIT SET? RET Z ; NOPE, RETURN WITH ZF ; IN A,(IDE_IO_ERR) ; READ ERROR REGISTER DCALL PC_SPACE DCALL PRTHEXBYTE OR $FF ; FORCE NZ TO SIGNAL ERROR RET ; RETURN ; ;============================================================================= ; HARDWARE INTERFACE ROUTINES ;============================================================================= ; ; RESET ALL DEVICES ON BUS ; IDE_RESET: ; #IF (PLATFORM == PLT_MK4) ; USE HARDWARE RESET LINE LD A,$80 ; HIGH BIT OF XAR IS IDE RESET OUT (MK4_XAR),A LD DE,2 ; DELAY 32US (SPEC IS >= 25US) CALL VDELAY XOR A ; CLEAR RESET BIT OUT (MK4_XAR),A #ELSE ; INITIATE SOFT RESET LD A,%00001110 ; NO INTERRUPTS, ASSERT RESET BOTH DRIVES OUT (IDE_IO_CTRL),A #ENDIF ; LD DE,2 ; DELAY 32US (SPEC IS >= 25US) CALL VDELAY ; ; CONFIGURE OPERATION AND END SOFT RESET LD A,%00001010 ; NO INTERRUPTS, DEASSERT RESET OUT (IDE_IO_CTRL),A ; PUSH TO REGISTER ; ; SPEC ALLOWS UP TO 450MS FOR DEVICES TO ASSERT THEIR PRESENCE ; VIA -DASP. I ENCOUNTER PROBLEMS LATER ON IF I DON'T WAIT HERE ; FOR THAT TO OCCUR. THUS FAR, IT APPEARS THAT 150MS IS SUFFICIENT ; FOR ANY DEVICE ENCOUNTERED. MAY NEED TO EXTEND BACK TO 500MS ; IF A SLOWER DEVICE IS ENCOUNTERED. ; ;LD DE,500000/16 ; ~500MS LD DE,150000/16 ; ~???MS CALL VDELAY ; ; CLEAR OUT ALL DATA (FOR ALL UNITS) LD HL,IDE_UDATA LD BC,IDE_UDLEN XOR A CALL FILL ; LD A,(IDE_UNIT) ; GET THE CURRENT UNIT SELECTION PUSH AF ; AND SAVE IT ; PROBE / INITIALIZE ALL UNITS LD B,IDE_UNITCNT ; NUMBER OF UNITS TO TRY LD C,0 ; UNIT INDEX FOR LOOP IDE_RESET1: LD A,C ; UNIT NUMBER TO A PUSH BC CALL IDE_INITUNIT ; PROBE/INIT UNIT POP BC INC C ; NEXT UNIT DJNZ IDE_RESET1 ; LOOP AS NEEDED ; POP AF ; RECOVER ORIGINAL UNIT NUMBER LD (IDE_UNIT),A ; AND SAVE IT ; XOR A ; SIGNAL SUCCESS RET ; AND DONE ; ; ; IDE_INITUNIT: LD (IDE_UNIT),A ; SET ACTIVE UNIT CALL IDE_SELUNIT ; SELECT UNIT RET NZ ; ABORT IF ERROR LD HL,IDE_TIMEOUT ; POINT TO TIMEOUT LD (HL),IDE_TOFAST ; USE FAST TIMEOUT DURING INIT CALL IDE_PROBE ; DO PROBE CALL Z,IDE_INITDEV ; IF FOUND, ATTEMPT TO INIT DEVICE LD HL,IDE_TIMEOUT ; POINT TO TIMEOUT LD (HL),IDE_TONORM ; BACK TO NORMAL TIMEOUT RET ; ; TAKE ANY ACTIONS REQUIRED TO SELECT DESIRED PHYSICAL UNIT ; UNIT IS SPECIFIED IN IDE_UNIT ; REGISTER A IS DESTROYED ; IDE_SELUNIT: LD A,(IDE_UNIT) ; GET UNIT CP IDE_UNITCNT ; CHECK VALIDITY (EXCEED UNIT COUNT?) JP NC,IDE_INVUNIT ; HANDLE INVALID UNIT ; #IF (IDEMODE == IDEMODE_DIDE) ; SELECT PRIMARY/SECONDARY INTERFACE FOR DIDE HARDWARE #ENDIF ; ; DETERMINE AND SAVE DRIVE/HEAD VALUE FOR SELECTED UNIT PUSH HL ; SAVE HL LD A,(IDE_UNIT) ; GET CURRENT UNIT AND $01 ; LS BIT DETERMINES MASTER/SLAVE LD HL,IDE_DRVSEL CALL ADDHLA LD A,(HL) ; LOAD DRIVE/HEAD VALUE POP HL ; RECOVER HL LD (IDE_DRVHD),A ; SAVE IT ; XOR A ; SIGNAL SUCCESS RET ; AND DONE ; ; ; IDE_PROBE: #IF (IDETRACE >= 3) CALL IDE_PRTPREFIX PRTS(" PROBE$") ; LABEL FOR IO ADDRESS #ENDIF ; LD A,(IDE_DRVHD) OUT (IDE_IO_DRVHD),A DCALL PC_SPACE DCALL PRTHEXBYTE CALL DELAY ; DELAY ~16US ; DCALL IDE_REGDUMP ; ;JR IDE_PROBE1 ; *DEBUG* ; IDE_PROBE0: CALL IDE_WAITBSY ; WAIT FOR BUSY TO CLEAR JP NZ,IDE_NOMEDIA ; CONVERT TIMEOUT TO NO MEDIA AND RETURN ; DCALL IDE_REGDUMP ; ; CHECK STATUS IN A,(IDE_IO_STAT) ; GET STATUS DCALL PC_SPACE DCALL PRTHEXBYTE ; IF DEBUG, PRINT STATUS OR A ; SET FLAGS TO TEST FOR ZERO JP Z,IDE_NOMEDIA ; ; CHECK SIGNATURE DCALL PC_SPACE IN A,(IDE_IO_COUNT) DCALL PRTHEXBYTE CP $01 JP NZ,IDE_NOMEDIA DCALL PC_SPACE IN A,(IDE_IO_SECT) DCALL PRTHEXBYTE CP $01 JP NZ,IDE_NOMEDIA DCALL PC_SPACE IN A,(IDE_IO_CYLLO) DCALL PRTHEXBYTE CP $00 JP NZ,IDE_NOMEDIA DCALL PC_SPACE IN A,(IDE_IO_CYLHI) DCALL PRTHEXBYTE CP $00 JP NZ,IDE_NOMEDIA ; IDE_PROBE1: ; SIGNATURE MATCHES ATA DEVICE, RECORD TYPE AND RETURN SUCCESS IDE_DPTR(IDE_TYPE) ; POINT HL TO UNIT TYPE FIELD, A IS TRASHED LD (HL),IDE_TYPEATA ; SET THE DEVICE TYPE XOR A ; SIGNAL SUCCESS RET ; DONE, NOTE THAT A=0 AND Z IS SET ; ; (RE)INITIALIZE DEVICE ; IDE_INITDEV: ; IDE_DPTR(IDE_TYPE) ; POINT HL TO UNIT TYPE FIELD, A IS TRASHED LD A,(HL) ; GET THE DEVICE TYPE OR A ; SET FLAGS JP Z,IDE_NOMEDIA ; EXIT SETTING NO MEDIA STATUS ; ; CLEAR OUT UNIT SPECIFIC DATA, BUT PRESERVE THE EXISTING ; VALUE OF THE UNIT TYPE WHICH WAS ESTABLISHED BY THE DEVICE ; PROBES WHEN THE IDE BUS WAS RESET PUSH AF ; SAVE UNIT TYPE VALUE FROM ABOVE PUSH HL ; SAVE UNIT TYPE FIELD POINTER IDE_DPTR(0) ; SET HL TO START OF UNIT DATA LD BC,IDE_UDLEN XOR A CALL FILL POP HL ; RECOVER UNIT TYPE FIELD POINTER POP AF ; RECOVER UNIT TYPE VALUE LD (HL),A ; AND PUT IT BACK ; #IF (IDE8BIT) LD A,IDE_FEAT_ENABLE8BIT ; FEATURE VALUE = ENABLE 8-BIT PIO #ELSE LD A,IDE_FEAT_DISABLE8BIT ; FEATURE VALUE = DISABLE 8-BIT PIO #ENDIF CALL IDE_SETFEAT ; SET FEATURE RET NZ ; BAIL OUT ON ERROR ; CALL IDE_IDENTIFY ; EXECUTE IDENTIFY COMMAND RET NZ ; BAIL OUT ON ERROR ; LD DE,HB_WRKBUF ; POINT TO BUFFER DCALL DUMP_BUFFER ; DUMP IT IF DEBUGGING ; ; DETERMINE IF CF DEVICE LD HL,HB_WRKBUF ; FIRST WORD OF IDENTIFY DATA HAS CF FLAG LD A,$8A ; FIRST BYTE OF MARKER IS $8A CP (HL) ; COMPARE JR NZ,IDE_INITDEV1 ; IF NO MATCH, NOT CF INC HL LD A,$84 ; SECOND BYTE OF MARKER IS $84 CP (HL) ; COMPARE JR NZ,IDE_INITDEV1 ; IF NOT MATCH, NOT CF IDE_DPTR(IDE_CFFLAG) ; POINT HL TO CF FLAG FIELD LD A,$FF ; SET FLAG VALUE TO NON-ZERO (TRUE) LD (HL),A ; SAVE IT ; IDE_INITDEV1: ; GET DEVICE CAPACITY AND SAVE IT IDE_DPTR(IDE_CAPACITY) ; POINT HL TO UNIT CAPACITY FIELD PUSH HL ; SAVE POINTER LD HL,HB_WRKBUF ; POINT TO BUFFER START LD A,120 ; OFFSET OF SECTOR COUNT CALL ADDHLA ; POINT TO ADDRESS OF SECTOR COUNT CALL LD32 ; LOAD IT TO DE:HL POP BC ; RECOVER POINTER TO CAPACITY ENTRY CALL ST32 ; SAVE CAPACITY ; ; RESET CARD STATUS TO 0 (OK) IDE_DPTR(IDE_STAT) ; HL := ADR OF STATUS, AF TRASHED XOR A ; A := 0 (STATUS = OK) LD (HL),A ; SAVE IT ; RET ; RETURN, A=0, Z SET ; ; ; IDE_CHKDEVICE: IDE_DPTR(IDE_STAT) LD A,(HL) OR A RET Z ; RETURN IF ALL IS WELL ; ; ATTEMPT TO REINITIALIZE HERE??? JP IDE_ERR RET ; ; ; IDE_WAITRDY: LD A,(IDE_TIMEOUT) ; GET TIMEOUT IN 0.05 SECS LD B,A ; PUT IN OUTER LOOP VAR IDE_WAITRDY1: LD DE,(IDE_TOSCALER) ; CPU SPPED SCALER TO INNER LOOP VAR IDE_WAITRDY2: IN A,(IDE_IO_STAT) ; READ STATUS LD C,A ; SAVE IT AND %11000000 ; ISOLATE BUSY AND RDY BITS XOR %01000000 ; WE WANT BUSY(7) TO BE 0 AND RDY(6) TO BE 1 RET Z ; ALL SET, RETURN WITH Z SET DEC DE LD A,D OR E JR NZ,IDE_WAITRDY2 ; INNER LOOP RETURN DJNZ IDE_WAITRDY1 ; OUTER LOOP RETURN JP IDE_RDYTO ; EXIT WITH RDYTO ERR ; ; ; IDE_WAITDRQ: LD A,(IDE_TIMEOUT) ; GET TIMEOUT IN 0.05 SECS LD B,A ; PUT IN OUTER LOOP VAR IDE_WAITDRQ1: LD DE,(IDE_TOSCALER) ; CPU SPPED SCALER TO INNER LOOP VAR IDE_WAITDRQ2: IN A,(IDE_IO_STAT) ; WAIT FOR DRIVE'S 512 BYTE READ BUFFER LD C,A ; SAVE IT AND %10001000 ; TO FILL (OR READY TO FILL) XOR %00001000 RET Z DEC DE LD A,D OR E JR NZ,IDE_WAITDRQ2 DJNZ IDE_WAITDRQ1 JP IDE_DRQTO ; EXIT WITH BUFTO ERR ; ; ; IDE_WAITBSY: LD A,(IDE_TIMEOUT) ; GET TIMEOUT IN 0.05 SECS LD B,A ; PUT IN OUTER LOOP VAR IDE_WAITBSY1: LD DE,(IDE_TOSCALER) ; CPU SPPED SCALER TO INNER LOOP VAR IDE_WAITBSY2: IN A,(IDE_IO_STAT) ; WAIT FOR DRIVE'S 512 BYTE READ BUFFER ; 11TS LD C,A ; SAVE IT ; 4TS AND %10000000 ; TO FILL (OR READY TO FILL) ; 7TS RET Z ; 5TS DEC DE ; 6TS LD A,D ; 4TS OR E ; 4TS JR NZ,IDE_WAITBSY2 ; 12TS DJNZ IDE_WAITBSY1 ; ----- JP IDE_BSYTO ; EXIT WITH BSYTO ERR ; 52TS ; ;============================================================================= ; ERROR HANDLING AND DIAGNOSTICS ;============================================================================= ; ; ERROR HANDLERS ; IDE_INVUNIT: LD A,IDE_STINVUNIT JR IDE_ERR2 ; SPECIAL CASE FOR INVALID UNIT ; IDE_NOMEDIA: LD A,IDE_STNOMEDIA JR IDE_ERR ; IDE_CMDERR: LD A,IDE_STCMDERR JR IDE_ERR ; IDE_IOERR: LD A,IDE_STIOERR JR IDE_ERR ; IDE_RDYTO: LD A,IDE_STRDYTO JR IDE_ERR ; IDE_DRQTO: LD A,IDE_STDRQTO JR IDE_ERR ; IDE_BSYTO: LD A,IDE_STBSYTO JR IDE_ERR ; IDE_ERR: PUSH HL ; IS THIS NEEDED? PUSH AF ; SAVE INCOMING STATUS IDE_DPTR(IDE_STAT) ; GET STATUS ADR IN HL, AF TRASHED POP AF ; RESTORE INCOMING STATUS LD (HL),A ; UPDATE STATUS POP HL ; IS THIS NEEDED? IDE_ERR2: #IF (IDETRACE >= 2) CALL IDE_PRTSTAT CALL IDE_REGDUMP #ENDIF OR A ; SET FLAGS RET ; ; ; IDE_PRTERR: RET Z ; DONE IF NO ERRORS ; FALL THRU TO IDE_PRTSTAT ; ; PRINT STATUS STRING (STATUS NUM IN A) ; IDE_PRTSTAT: PUSH AF PUSH DE PUSH HL OR A LD DE,IDE_STR_STOK JR Z,IDE_PRTSTAT1 INC A LD DE,IDE_STR_STINVUNIT JR Z,IDE_PRTSTAT2 ; INVALID UNIT IS SPECIAL CASE INC A LD DE,IDE_STR_STNOMEDIA JR Z,IDE_PRTSTAT1 INC A LD DE,IDE_STR_STCMDERR JR Z,IDE_PRTSTAT1 INC A LD DE,IDE_STR_STIOERR JR Z,IDE_PRTSTAT1 INC A LD DE,IDE_STR_STRDYTO JR Z,IDE_PRTSTAT1 INC A LD DE,IDE_STR_STDRQTO JR Z,IDE_PRTSTAT1 INC A LD DE,IDE_STR_STBSYTO JR Z,IDE_PRTSTAT1 LD DE,IDE_STR_STUNK IDE_PRTSTAT1: CALL IDE_PRTPREFIX ; PRINT UNIT PREFIX JR IDE_PRTSTAT3 IDE_PRTSTAT2: CALL NEWLINE PRTS("IDE:$") ; NO UNIT NUM IN PREFIX FOR INVALID UNIT IDE_PRTSTAT3: CALL PC_SPACE ; FORMATTING CALL WRITESTR POP HL POP DE POP AF RET ; ; PRINT ALL REGISTERS DIRECTLY FROM DEVICE ; DEVICE MUST BE SELECTED PRIOR TO CALL ; IDE_REGDUMP: PUSH AF PUSH BC CALL PC_SPACE CALL PC_LBKT LD C,IDE_IO_CMD LD B,7 IDE_REGDUMP1: IN A,(C) CALL PRTHEXBYTE DEC C DEC B CALL NZ,PC_SPACE JR NZ,IDE_REGDUMP1 CALL PC_RBKT POP BC POP AF RET ; ; PRINT DIAGNONSTIC PREFIX ; IDE_PRTPREFIX: PUSH AF CALL NEWLINE PRTS("IDE$") LD A,(IDE_UNIT) ADD A,'0' CALL COUT CALL PC_COLON POP AF RET ; ; ; #IF (DSKYENABLE) IDE_DSKY: LD HL,DSKY_HEXBUF ; POINT TO DSKY BUFFER IN A,(IDE_IO_DRVHD) ; GET DRIVE/HEAD LD (HL),A ; SAVE IN BUFFER INC HL ; INCREMENT BUFFER POINTER IN A,(IDE_IO_CYLHI) ; GET DRIVE/HEAD LD (HL),A ; SAVE IN BUFFER INC HL ; INCREMENT BUFFER POINTER IN A,(IDE_IO_CYLLO) ; GET DRIVE/HEAD LD (HL),A ; SAVE IN BUFFER INC HL ; INCREMENT BUFFER POINTER IN A,(IDE_IO_SECT) ; GET DRIVE/HEAD LD (HL),A ; SAVE IN BUFFER CALL DSKY_HEXOUT ; SEND IT TO DSKY RET #ENDIF ; ;============================================================================= ; STRING DATA ;============================================================================= ; IDE_STR_STOK .TEXT "OK$" IDE_STR_STINVUNIT .TEXT "INVALID UNIT$" IDE_STR_STNOMEDIA .TEXT "NO MEDIA$" IDE_STR_STCMDERR .TEXT "COMMAND ERROR$" IDE_STR_STIOERR .TEXT "IO ERROR$" IDE_STR_STRDYTO .TEXT "READY TIMEOUT$" IDE_STR_STDRQTO .TEXT "DRQ TIMEOUT$" IDE_STR_STBSYTO .TEXT "BUSY TIMEOUT$" IDE_STR_STUNK .TEXT "UNKNOWN ERROR$" ; IDE_STR_NO .TEXT "NO$" ; ;============================================================================= ; DATA STORAGE ;============================================================================= ; IDE_TIMEOUT .DB IDE_TONORM ; WAIT FUNCS TIMEOUT IN TENTHS OF SEC IDE_TOSCALER .DW CPUMHZ * 961 ; WAIT FUNCS SCALER FOR CPU SPEED ; IDE_CMD .DB 0 ; PENDING COMMAND TO PROCESS IDE_DRVHD .DB 0 ; CURRENT DRIVE/HEAD MASK ; IDE_UNIT .DB 0 ; ACTIVE UNIT, DEFAULT TO ZERO IDE_DSKBUF .DW 0 ; ACTIVE DISK BUFFER ; ; UNIT SPECIFIC DATA STORAGE ; IDE_UDATA .FILL IDE_UNITCNT*8,0 ; PER UNIT DATA, 8 BYTES IDE_DLEN .EQU $ - IDE_UDATA ; LENGTH OF ENTIRE DATA STORAGE FOR ALL UNITS IDE_UDLEN .EQU IDE_DLEN / IDE_UNITCNT ; LENGTH OF PER UNIT DATA ; ;============================================================================= ; HELPER ROUTINES ;============================================================================= ; ; IMPLEMENTATION FOR MACRO IDE_DPTR ; SET HL TO ADDRESS OF FIELD WITHIN PER UNIT DATA ; HL := ADR OF IDE_UNITDATA[(IDE_UNIT)][(SP)] ; ENTER WITH TOP-OF-STACK = ADDRESS OF FIELD OFFSET ; AF IS TRASHED ; IDE_DPTRIMP: LD HL,IDE_UDATA ; POINT TO START OF UNIT DATA ARRAY LD A,(IDE_UNIT) ; GET CURRENT UNIT NUM RLCA ; MULTIPLY BY RLCA ; ... SIZE OF PER UNIT DATA RLCA ; ... (8 BYTES) EX (SP),HL ; GET PTR TO FIELD OFFSET VALUE FROM TOS ADD A,(HL) ; ADD IT TO START OF UNIT DATA IN ACCUM INC HL ; BUMP HL TO NEXT REAL INSTRUCTION EX (SP),HL ; AND PUT IT BACK ON STACK, HL GETS ADR OF START OF DATA JP ADDHLA ; CALC FINAL ADR IN HL AND RETURN