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RomWBW/Source/HBIOS/ppide.asm
b1ackmai1er 78f65522b7 Dev (#108) 
* added hack to handle tunes

* quiet clean

* added chmod for execution

* suppress warnings

* Multi-boot fixes

* the windows build somehow thinks that these filesystems are cpm3.

* credit and primitive instructions

* Update sd.asm

Cosmetic fix.

* make compile shut up about conditionals

* Add bin2asm for linus and update build to process font files under linix

* fixed quoted double quote bug, added tests

* added tests

* added bin2asm for font file source creation

* Revert linux bin2asm font stuff

* added rule for font source generation

* build fonts

* added directory mapping cache.  if the same directory is being hit
as last run, we don't need to rebuild the map.  will likely break if
you are running more than one at a time, in that the cache will be
ineffective.  also, if the directory contents change, this will also break.

* removed strip.  breaks osx

* added directory tag so . isn't matched all over the place

* added real cache validation

* fixed build

* this file is copied from optdsk.lib or optcmd.lib

* install to ../HBIOS

* prerequisite verbosity

* diff soft failure and casefn speedup

* added lzsa

* added lzsa

* removed strip. breaks on osx

* added clobber

* added code to handle multiple platform rom builds with rom size override

* added align and 0x55 hex syntax

* default to hd64180

* added N8 capability

* added SBC_std.rom to default build

* added support for binary diff

* diff fixes

* clean, identical build.  font source generator emitted .align.  this does not match the windows build

* Upgrade NZCOM to latest

* Misc. Cleanup

* fixed expression parser bug : ~(1|2) returned 0xfe

* added diff build option

* Update Makefile

Makefile enhancement to better handle ncurses library from Bob Dunlop.

* Update sd.asm

Back out hack for uz80as now that Curt fixed it.

* Misc. Cleanup

* UNA Catchup

UNA support was lacking some of the more recent behavior changes.  This corrects most of it.

* Add github action for building RomWBW

* Bump Pre-release Version

* Update build.yml

Added "make clean" which will remove temporary files without removing final binary outputs.

* Update Makefile

Build all ROM variants by default in Linux/Mac build.

* Update Makefile

* Update Makefile

* Update Makefile

* Update Makefile

* Update Makefile

* Update Makefile

* Update Makefile

* Update Makefile

* Update Makefile

* Update for GitHub Build

Case issue in TASM includes showing up in GitHub build.  This should correct that.

* Added an gitignore files to exclude generated files

* Removed Tunes/clean.cmd and Tunes/ReadMe.txt - as make clean removes them

* Build.sh: marked as executable

chmod +x Build.sh

* Fix to HBIOS/build.sh

When adding files to rom disk, if files were missing, it would error out.

It appears the intent is to skip non-existing files.

Updated to log out correctly for missing files - and continue operation.

* Update Microsoft NASCOM BASIC.docx

Nascom manual, text version by Jan S (full name unknown)

* Fix issue with Apps/Tune not making

If dest directory does not exist, fails to make Apps

* Create ReadMe.txt

* Update Makefile

* Update Build.sh

* Make .gitignores for Tools/unix more specific

* cpmtools Update

Updated cpmtools applications (Windows only).  Removed hack in diskdefs that is no longer required.

* HBIOS Proxy Temp Stack Enhancement

Reuse the bounce buffer area as the temporary stack space required briefly in HBX_INVOKE when transitioning banks.  Increases size of temporary stack space to 64 bytes.

* Update ReadMe.txt

* HBIOS - clean up TMPSTK

* Update hbios.asm

Minor cosmetic changes.

* Build Process Updates

Minor udpates to build process to improve consistency between Windows and Mac/Linux builds.

* Update hbios.asm

Add improved interrupt protection to HBIOS PEEK, POKE, and BNKCPY functions.

* hbios - wrap hbx_bnkcpy

* hbios - adjust hbx_peek hbx_poke guards

* Update hbios.asm

Adjusted used of DI/EI for PEEK and POKE to regain a bit of INTSTK space.  Added code so that HB_INVBNK can be used as a flag indicating if HBIOS is active, $FF is inactive, anything else means active.

* Add HBIOS MuTex

* Initial Nascom basic ecb-vdu graphics

set and reset for 80x25b screen with 256 character mod

* Finalize Pre-release 34

Final support for FreeRTOS

* Update nascom.asm

Optimization, cleanup, tabs and white spaces

* IDE & PPIDE Cleanup

* Clean up

Make version include files common.

* Update Makefile

* Update Makefile

* Build Test

* Build Test

* Build Fixes

* Update nascom.asm

Cleanup

* Update nascom.asm

Optimization

* hbios - temp stack tweak

* Update hbios.asm

Comments on HBX_BUF usage.

* Update nascom.asm

Optimization

* Update nascom.asm

Setup ECB-VDU build option, remove debug code

* Update nascom.asm

Set default build. update initialization

* Update nascom.asm

Make CLS clear vdu screen

* Update nascom.asm

Fixup top screen line not showing

* Add SC131 Support

Also cleaned up some ReadMe files.

* HBIOS SCZ180 - remove mutex special files

* HBIOS SCZ180 - adjust mutex comment

* Misc. Cleanup

Includes some minor improvements to contents in some disk images.

* Delete FAT.COM

Changing case of FAT.COM extension to lowercase.

* Create FAT.com

Completing change of case in extension of FAT.com.

* Update Makefile

Remove ROM variants that just have the HBIOS MUTEX enabled.  Users can easily enable this in a custom build.

* Cleanup

Removed hack from Images Makefile.  Fixed use of DEFSERCFG in various places.

* GitHub CI Updates

Adds automation of build and release assets upon release.

* Prerelease 36

General cleanup

* Build Script Cleanups

* Config File Cleanups

* Update RomWBW Architecture

General refresh for v2.9.2

* Update vdu.asm

Removed a hack in VDU driver that has existed for 8 years.  :-)

* Fix CONSOLE Constant

Rename CIODEV_CONSOLE constant to CIO_CONSOLE because it is a unit code, not a device type code.

Retabify TastyBasic.

* Minor Bug Fixes

- Disk assignment edge case
- CP/M 3 accidental fall thru
- Cosmetic updates

* Update util.z80

* Documentation Cleanup

* Documentation Update

* Documentation Update

* Documentation Updates

* Documentation Updates

* Create Common.inc

* Documentation Updates

* Documentation Updates

* doc - a few random fixes

* Documentation Cleanup

* Fix IM 0 Build Error in ACIA

* Documentation Updates

* Documentation Cleanup

* Remove OSLDR

The OSLDR application was badly broken and almost impossible to fix with new expanded OS support.

* Bug Fixes

- Init RAM disk at boot under CP/M 3
- Fix ACR activation in TUNE

* FD Motor Timeout

- Made FDC motor timeout smaller and more consistent across different speed CPUs
- Added "boot" messaging to RTC

* Cleanup

* Cleanup

- Fix SuperZAP to work under NZCOM and ZPM3
- Finalize standard config files

* Minor Changes

- Slight change to ZAP configuration
- Added ZSDOS.ZRL to NZCOM image

* ZDE Upgrade

- Upgraded ZDE 1.6 -> 1.6a

* Config File Tuning

* Pre-release for Testing

* cfg - mutex consistent config language

* Bump to Version 3.0

* Update SD Card How-To

Thanks David!

* update ReadMe.md

Remove some odd `\`.

* Update ReadMe.txt

* Update ReadMe.md

* Update Generated Doc Files

* Improve XModem Startup

- Extended startup timeout for XM.COM so that it doesn't timeout so quickly while host is selecing a file to send.
- Updated SD Card How-To from David Reese.

* XModem Timing Refinements

* TMS Driver Z180 Improvements

- TMS driver udpated to insert Z180 I/O waitstates internally so other code can run at full speed.
- Updated How-To documents from David.
- Fixed TUNE app to properly restore Z180 I/O waitstates after manipulating them.

* CLRDIR and ZDE updates

- CLRDIR has been updated by Max Scane for CP/M 3 compatibility.
- A minor issue in the preconfigured ZDE VT100 terminal escape sequences was corrected.

* Fix Auto CRT Console Switch on CP/M 3

* Handle lack of RTC better

DSRTC driver now correctly returns an error if there is no RTC present.

* Minor RTC Updates

* Finalize v3.0.1

Cleanup release for v3.0

* New ROMLDR and INTRTC driver

- Refactored romldr.asm
- Added new periodic timer based RTC driver

* CP/M 3 Date Hack

- Hack to allow INTRTC to increment time without destroying the date

* Update romldr.asm

Work around minor Linux build inconsistency

* Update Apps for New Version

* Revert "Update Apps for New Version"

This reverts commit ad80432252.

* Revert "Update romldr.asm"

This reverts commit 4a9825cd57.

* Revert "CP/M 3 Date Hack"

This reverts commit 153b494e61.

* Revert "New ROMLDR and INTRTC driver"

This reverts commit d9bed4563e.

* Start v3.1 Development

* Update FDISK80.COM

Updated FDISK80 to allow reserving up to 256 slices.

* Update sd.asm

For Z180 CSIO, ensure that xmit is finished, before asserting CS for next transaction.

* Add RC2014 UART, Improve SD protocol fix

- RC2014 and related platforms will autodetect a UART at 0xA0 and 0xA8
- Ensure that CS fully brackets all SD I/O

* ROMLDR Improvements

.com files can now be started from CP/M and size of .com files has been reduced so they always fit.

* Update commit.yml

Run commit build in all branches

* Update commit.yml

Run commit build for master and dev branches

* Improved clock driver auto-detect/fallback

* SIO driver now CTC aware

The SIO driver can now use a CTC (if available) to provide much more flexible baud rate programming.

* CTC driver fine tuning

* Update xmdm125.asm

Fixed a small issue in core XM125 code that caused a file write error message to not be displayed when it should be.

* CF Card compatibility improvement

Older CF Cards did not reset IDE registers to defaults values when reset.  Implemented a work around.

* Update ACIA detection

ACIA should no longer be detected if there is also a UART module in the system.

* Handle CTC anomaly

Small update to accommodate CTC behavior that occurs when the CTC trigger is more than half the CTC clock.

* Update acia.asm

Updated ACIA detection to use primary ACIA port instead of phantom port.

* Update acia.asm

Fix bug in ACIA detection.

Thanks Alan!

* MacOS Build Improvement

Build script updated to improve compatibility with MacOS.

Credit to Fredrik Axtelius for this.

* HBIOS Makefile - use env vars for target

Allow build ROM targets to be restricted to just one platform thru use of ENV vars:

ROM_PLATFORM - if defined to a known platform, only this platform is build - defaults to std config
ROM_CONFIG - sets the desired platform config - defaults to std

if the above ENVs are not defined, builds all ROMs

* Added some more gitignores

* Whitespace changes (crlf)

* HBIOS: Force the assembly to fail for vdu drivers if function table count is not correct

* Whitespace: trailing whitespaces

* makefile: updated some make scripts to use  when calling subdir makefiles

* linux build: update to Build.sh fix for some platforms

The initialization of the Rom dat file used the pipe (|) operator to build an initial empty file.

But the pipe operator | may sometimes return a non-zero exit code for some linux platforms, if the
the streams are closed before dd has fully processed the stream.

This issue occured on a travis linux ubuntu image.

Solution was to change to redirection.

* Bump version

* Enhance CTC periodic timer

Add ability to use TIMER mode in CTC driver to generate priodic interrupts.

* HBIOS: Added support for sound drivers

New sound driver support with initial support for the SN76489 chip

New build configuration entry:
* SN76489ENABLE

Ports are currently locked in with:
* SN76489_PORT_LEFT       .EQU    $FC     ; PORTS FOR ACCESSING THE SN76489 CHIP (LEFT)
* SN76489_PORT_RIGHT      .EQU    $F8     ; PORTS FOR ACCESSING THE SN76489 CHIP (LEFT)

* Miscellaneous Cleanup

No functional changes.

Co-authored-by: curt mayer <curt@zen-room.org>
Co-authored-by: Wayne Warthen <wwarthen@gmail.com>
Co-authored-by: ed <linux@maidavale.org>
Co-authored-by: Dean Netherton <dnetherton@dius.com.au>
Co-authored-by: ed <ed@maidavale.org>
Co-authored-by: Phillip Stevens <phillip.stevens@gmail.com>
Co-authored-by: Dean Netherton <dean.netherton@gmail.com>
2020-04-24 06:17:22 +08:00

1630 lines
44 KiB
NASM
Raw Blame History

;
;=============================================================================
; PPIDE DISK DRIVER
;=============================================================================
;
; TODO:
; - FIX SCALER CONSTANT
; - GOPARTNER NEEDS TO HANDLE "NO PARTNER" CONDITION
;
; NOTES:
; - WELL KNOWN PPIDE PORT ADDRESSES:
; $60 - SBC/ZETA ONBOARD PPI
; $20 - ECB DISKIO3, RC FAMILY
; $44 - ECB MULTI-FUNCTION PIC
; $80 - N8 ONBOARD PPI
; $4C - DYNO ONBOARD PPI
;
; THE CONTROL PORT OF THE 8255 IS PROGRAMMED AS NEEDED TO READ OR WRITE
; DATA ON THE IDE BUS. PORT C OF THE 8255 IS ALWAYS IN OUTPUT MODE BECAUSE
; IT IS DRIVING THE ADDRESS BUS AND CONTROL SIGNALS. PORTS A & B WILL BE
; PLACED IN READ OR WRITE MODE DEPENDING ON THE DIRECTION OF THE DATA BUS.
;
PPIDE_DIR_READ .EQU %10010010 ; IDE BUS DATA INPUT MODE
PPIDE_DIR_WRITE .EQU %10000000 ; IDE BUS DATA OUTPUT MODE
;
; PORT C OF THE 8255 IS USED TO DRIVE THE IDE INTERFACE ADDRESS BUS
; AND VARIOUS CONTROL SIGNALS. THE CONSTANTS BELOW REFLECT THESE
; ASSIGNMENTS.
;
PPIDE_CTL_DA0 .EQU %00000001 ; DRIVE ADDRESS BUS - BIT 0 (DA0)
PPIDE_CTL_DA1 .EQU %00000010 ; DRIVE ADDRESS BUS - BIT 1 (DA1)
PPIDE_CTL_DA2 .EQU %00000100 ; DRIVE ADDRESS BUS - BIT 2 (DA2)
PPIDE_CTL_CS1 .EQU %00001000 ; DRIVE CHIP SELECT 0 (ACTIVE LOW, INVERTED)
PPIDE_CTL_CS3 .EQU %00010000 ; DRIVE CHIP SELECT 1 (ACTIVE LOW, INVERTED)
PPIDE_CTL_DIOW .EQU %00100000 ; DRIVE I/O WRITE (ACTIVE LOW, INVERTED)
PPIDE_CTL_DIOR .EQU %01000000 ; DRIVE I/O READ (ACTIVE LOW, INVERTED)
PPIDE_CTL_RESET .EQU %10000000 ; DRIVE RESET (ACTIVE LOW, INVERTED)
;
; +-----------------------------------------------------------------------+
; | CONTROL BLOCK REGISTERS (CS3FX) |
; +-----------------------+-------+-------+-------------------------------+
; | REGISTER | PORT | DIR | DESCRIPTION |
; +-----------------------+-------+-------+-------------------------------+
; | PPIDE_REG_ALTSTAT | 0x06 | R | ALTERNATE STATUS REGISTER |
; | PPIDE_REG_CTRL | 0x06 | W | DEVICE CONTROL REGISTER |
; | PPIDE_REG_DRVADR | 0x07 | R | DRIVE ADDRESS REGISTER |
; +-----------------------+-------+-------+-------------------------------+
;
; +-----------------------+-------+-------+-------------------------------+
; | COMMAND BLOCK REGISTERS (CS1FX) |
; +-----------------------+-------+-------+-------------------------------+
; | REGISTER | PORT | DIR | DESCRIPTION |
; +-----------------------+-------+-------+-------------------------------+
; | PPIDE_REG_DATA | 0x00 | R/W | DATA INPUT/OUTPUT |
; | PPIDE_REG_ERR | 0x01 | R | ERROR REGISTER |
; | PPIDE_REG_FEAT | 0x01 | W | FEATURES REGISTER |
; | PPIDE_REG_COUNT | 0x02 | R/W | SECTOR COUNT REGISTER |
; | PPIDE_REG_SECT | 0x03 | R/W | SECTOR NUMBER REGISTER |
; | PPIDE_REG_CYLLO | 0x04 | R/W | CYLINDER NUM REGISTER (LSB) |
; | PPIDE_REG_CYLHI | 0x05 | R/W | CYLINDER NUM REGISTER (MSB) |
; | PPIDE_REG_DRVHD | 0x06 | R/W | DRIVE/HEAD REGISTER |
; | PPIDE_REG_LBA0* | 0x03 | R/W | LBA BYTE 0 (BITS 0-7) |
; | PPIDE_REG_LBA1* | 0x04 | R/W | LBA BYTE 1 (BITS 8-15) |
; | PPIDE_REG_LBA2* | 0x05 | R/W | LBA BYTE 2 (BITS 16-23) |
; | PPIDE_REG_LBA3* | 0x06 | R/W | LBA BYTE 3 (BITS 24-27) |
; | PPIDE_REG_STAT | 0x07 | R | STATUS REGISTER |
; | PPIDE_REG_CMD | 0x07 | W | COMMAND REGISTER (EXECUTE) |
; +-----------------------+-------+-------+-------------------------------+
; * LBA0-3 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
;
; CONTROL VALUES TO USE WHEN ACCESSING THE VARIOUS IDE DEVICE REGISTERS
;
PPIDE_REG_DATA .EQU PPIDE_CTL_CS1 | $00 ; DATA INPUT/OUTPUT (R/W)
PPIDE_REG_ERR .EQU PPIDE_CTL_CS1 | $01 ; ERROR REGISTER (R)
PPIDE_REG_FEAT .EQU PPIDE_CTL_CS1 | $01 ; FEATURES REGISTER (W)
PPIDE_REG_COUNT .EQU PPIDE_CTL_CS1 | $02 ; SECTOR COUNT REGISTER (R/W)
PPIDE_REG_SECT .EQU PPIDE_CTL_CS1 | $03 ; SECTOR NUMBER REGISTER (R/W)
PPIDE_REG_CYLLO .EQU PPIDE_CTL_CS1 | $04 ; CYLINDER NUM REGISTER (LSB) (R/W)
PPIDE_REG_CYLHI .EQU PPIDE_CTL_CS1 | $05 ; CYLINDER NUM REGISTER (MSB) (R/W)
PPIDE_REG_DRVHD .EQU PPIDE_CTL_CS1 | $06 ; DRIVE/HEAD REGISTER (R/W)
PPIDE_REG_LBA0 .EQU PPIDE_CTL_CS1 | $03 ; LBA BYTE 0 (BITS 0-7) (R/W)
PPIDE_REG_LBA1 .EQU PPIDE_CTL_CS1 | $04 ; LBA BYTE 1 (BITS 8-15) (R/W)
PPIDE_REG_LBA2 .EQU PPIDE_CTL_CS1 | $05 ; LBA BYTE 2 (BITS 16-23) (R/W)
PPIDE_REG_LBA3 .EQU PPIDE_CTL_CS1 | $06 ; LBA BYTE 3 (BITS 24-27) (R/W)
PPIDE_REG_STAT .EQU PPIDE_CTL_CS1 | $07 ; STATUS REGISTER (R)
PPIDE_REG_CMD .EQU PPIDE_CTL_CS1 | $07 ; COMMAND REGISTER (EXECUTE) (W)
PPIDE_REG_ALTSTAT .EQU PPIDE_CTL_CS3 | $06 ; ALTERNATE STATUS REGISTER (R)
PPIDE_REG_CTRL .EQU PPIDE_CTL_CS3 | $06 ; DEVICE CONTROL REGISTER (W)
PPIDE_REG_DRVADR .EQU PPIDE_CTL_CS3 | $07 ; DRIVE ADDRESS REGISTER (R)
;
; COMMAND BYTES
;
PPIDE_CMD_RECAL .EQU $10
PPIDE_CMD_READ .EQU $20
PPIDE_CMD_WRITE .EQU $30
PPIDE_CMD_IDDEV .EQU $EC
PPIDE_CMD_SETFEAT .EQU $EF
;
; FEATURE BYTES
;
PPIDE_FEAT_ENABLE8BIT .EQU $01
PPIDE_FEAT_DISABLE8BIT .EQU $81
;
; PPIDE DEVICE TYPES
;
PPIDE_TYPEUNK .EQU 0
PPIDE_TYPEATA .EQU 1
PPIDE_TYPEATAPI .EQU 2
;
; PPIDE DEVICE STATUS CODES
;
PPIDE_STOK .EQU 0
PPIDE_STINVUNIT .EQU -1
PPIDE_STNOMEDIA .EQU -2
PPIDE_STCMDERR .EQU -3
PPIDE_STIOERR .EQU -4
PPIDE_STRDYTO .EQU -5
PPIDE_STDRQTO .EQU -6
PPIDE_STBSYTO .EQU -7
;
; DRIVE SELECTION BYTES (FOR USE IN DRIVE/HEAD REGISTER)
;
;PPIDE_DRVSEL:
PPIDE_DRVMASTER .EQU %11100000 ; LBA, MASTER DEVICE
PPIDE_DRVSLAVE .EQU %11110000 ; LBA, SLAVE DEVICE
;
; PPIDE DEVICE CONFIGURATION
;
PPIDE_CFGSIZ .EQU 18 ; SIZE OF CFG TBL ENTRIES
;
; PER DEVICE DATA OFFSETS
;
PPIDE_DEV .EQU 0 ; OFFSET OF DEVICE NUMBER (BYTE)
PPIDE_STAT .EQU 1 ; LAST STATUS (BYTE)
PPIDE_TYPE .EQU 2 ; DEVICE TYPE (BYTE)
PPIDE_ACC .EQU 3 ; ACCESS FLAG BITS BIT 0=MASTER, 1=8BIT (BYTE)
PPIDE_MED .EQU 4 ; MEDIA FLAG BITS BIT 0=CF, 1=LBA (BYTE)
PPIDE_MEDCAP .EQU 5 ; MEDIA CAPACITY (DWORD)
PPIDE_LBA .EQU 9 ; OFFSET OF LBA (DWORD)
PPIDE_DATALO .EQU 13 ; BASE PORT AND IDE DATA BUS LSB (8255 PORT A) (BYTE)
PPIDE_CTL .EQU 14 ; IDE ADDRESS BUS AND CONTROL SIGNALS (8255 PORT C)(BYTE)
PPIDE_PPI .EQU 15 ; 8255 CONTROL PORT(BYTE)
PPIDE_PARTNER .EQU 16 ; PARTNER DEVICE (MASTER <-> SLAVE) (WORD)
;
PPIDE_ACC_MAS .EQU %00000001 ; UNIT IS MASTER (ELSE SLAVE)
PPIDE_ACC_8BIT .EQU %00000010 ; UNIT WANTS 8 BIT I/O (ELSE 16 BIT)
;
PPIDE_MED_CF .EQU %00000001 ; MEDIA IS CF CARD
PPIDE_MED_LBA .EQU %00000010 ; MEDIA HAS LBA CAPABILITY
;
PPIDE_DEVCNT .EQU PPIDECNT * 2
;
PPIDE_CFGTBL:
;
#IF (PPIDECNT >= 1)
;
PPIDE_DEV0M: ; DEVICE 0, MASTER
.DB 0 ; DRIVER RELATIVE DEVICE NUMBER (ASSIGNED DURING INIT)
.DB 0 ; DEVICE STATUS
.DB 0 ; DEVICE TYPE
.DB PPIDE_ACC_MAS | (PPIDE0A8BIT & PPIDE_ACC_8BIT) ; UNIT ACCESS FLAGS
.DB 0 ; MEDIA FLAGS
.DW 0,0 ; DEVICE CAPACITY
.DW 0,0 ; CURRENT LBA
.DB PPIDE0BASE ; DATALO
.DB PPIDE0BASE+2 ; CTL
.DB PPIDE0BASE+3 ; PPI
.DW PPIDE_DEV0S ; PARTNER
;
PPIDE_DEV0S: ; DEVICE 0, SLAVE
.DB 0 ; DRIVER RELATIVE DEVICE NUMBER (ASSIGNED DURING INIT)
.DB 0 ; DEVICE STATUS
.DB 0 ; DEVICE TYPE
.DB (PPIDE0B8BIT & PPIDE_ACC_8BIT) ; UNIT ACCESS FLAGS
.DB 0 ; MEDIA FLAGS
.DW 0,0 ; DEVICE CAPACITY
.DW 0,0 ; CURRENT LBA
.DB PPIDE0BASE ; DATALO
.DB PPIDE0BASE+2 ; CTL
.DB PPIDE0BASE+3 ; PPI
.DW PPIDE_DEV0M ; PARTNER
;
#ENDIF
;
#IF (PPIDECNT >= 2)
;
PPIDE_DEV1M: ; DEVICE 1, MASTER
.DB 0 ; DRIVER RELATIVE DEVICE NUMBER (ASSIGNED DURING INIT)
.DB 0 ; DEVICE STATUS
.DB 0 ; DEVICE TYPE
.DB PPIDE_ACC_MAS | (PPIDE1A8BIT & PPIDE_ACC_8BIT) ; UNIT ACCESS FLAGS
.DB 0 ; MEDIA FLAGS
.DW 0,0 ; DEVICE CAPACITY
.DW 0,0 ; CURRENT LBA
.DB PPIDE1BASE ; DATALO
.DB PPIDE1BASE+2 ; CTL
.DB PPIDE1BASE+3 ; PPI
.DW PPIDE_DEV1S ; PARTNER
;
PPIDE_DEV1S: ; DEVICE 1, SLAVE
.DB 0 ; DRIVER RELATIVE DEVICE NUMBER (ASSIGNED DURING INIT)
.DB 0 ; DEVICE STATUS
.DB 0 ; DEVICE TYPE
.DB (PPIDE1B8BIT & PPIDE_ACC_8BIT) ; UNIT ACCESS FLAGS
.DB 0 ; MEDIA FLAGS
.DW 0,0 ; DEVICE CAPACITY
.DW 0,0 ; CURRENT LBA
.DB PPIDE1BASE ; DATALO
.DB PPIDE1BASE+2 ; CTL
.DB PPIDE1BASE+3 ; PPI
.DW PPIDE_DEV1M ; PARTNER
;
#ENDIF
;
#IF (PPIDECNT >= 3)
;
PPIDE_DEV2M: ; DEVICE 2, MASTER
.DB 0 ; DRIVER RELATIVE DEVICE NUMBER (ASSIGNED DURING INIT)
.DB 0 ; DEVICE STATUS
.DB 0 ; DEVICE TYPE
.DB PPIDE_ACC_MAS | (PPIDE2A8BIT & PPIDE_ACC_8BIT) ; UNIT ACCESS FLAGS
.DB 0 ; MEDIA FLAGS
.DW 0,0 ; DEVICE CAPACITY
.DW 0,0 ; CURRENT LBA
.DB PPIDE2BASE ; DATALO
.DB PPIDE2BASE+2 ; CTL
.DB PPIDE2BASE+3 ; PPI
.DW PPIDE_DEV2S ; PARTNER
;
PPIDE_DEV2S: ; DEVICE 2, SLAVE
.DB 0 ; DRIVER RELATIVE DEVICE NUMBER (ASSIGNED DURING INIT)
.DB 0 ; DEVICE STATUS
.DB 0 ; DEVICE TYPE
.DB (PPIDE2B8BIT & PPIDE_ACC_8BIT) ; UNIT ACCESS FLAGS
.DB 0 ; MEDIA FLAGS
.DW 0,0 ; DEVICE CAPACITY
.DW 0,0 ; CURRENT LBA
.DB PPIDE2BASE ; DATALO
.DB PPIDE2BASE+2 ; CTL
.DB PPIDE2BASE+3 ; PPI
.DW PPIDE_DEV2M ; PARTNER
;
#ENDIF
;
#IF ($ - PPIDE_CFGTBL) != (PPIDE_DEVCNT * PPIDE_CFGSIZ)
.ECHO "*** INVALID PPIDE CONFIG TABLE ***\n"
#ENDIF
;
.DB $FF ; END OF TABLE MARKER
;
; 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.
;
PPIDE_TONORM .EQU 200 ; NORMAL TIMEOUT IS 10 SECS
PPIDE_TOFAST .EQU 10 ; FAST TIMEOUT IS 0.5 SECS
;
;=============================================================================
; INITIALIZATION ENTRY POINT
;=============================================================================
;
PPIDE_INIT:
; COMPUTE CPU SPEED COMPENSATED TIMEOUT SCALER
; AT 1MHZ, THE SCALER IS 218 (50000US / 229TS = 218)
; SCALER IS THEREFORE 218 * CPU SPEED IN MHZ
LD DE,218 ; LOAD SCALER FOR 1MHZ
LD A,(CB_CPUMHZ) ; LOAD CPU SPEED IN MHZ
CALL MULT8X16 ; HL := DE * A
LD (PPIDE_TOSCALER),HL ; SAVE IT
;
XOR A ; ZERO ACCUM
LD (PPIDE_DEVNUM),A ; INIT DEV UNIT NUM FOR DYNAMIC ASSIGNMENT
LD IY,PPIDE_CFGTBL ; POINT TO START OF CONFIG TABLE
;
PPIDE_INIT1:
LD A,(IY) ; LOAD FIRST BYTE TO CHECK FOR END
CP $FF ; CHECK FOR END OF TABLE VALUE
JR NZ,PPIDE_INIT2 ; IF NOT END OF TABLE, CONTINUE
XOR A ; SIGNAL SUCCESS
RET ; AND RETURN
;
PPIDE_INIT2:
BIT 0,(IY+PPIDE_ACC) ; MASTER?
JR Z,PPIDE_INIT4 ; IF NOT MASTER, SKIP AHEAD
;
CALL NEWLINE ; FORMATTING
PRTS("PPIDE:$") ; LABEL FOR IO ADDRESS
;
PRTS(" IO=0x$") ; LABEL FOR IO ADDRESS
LD A,(IY+PPIDE_DATALO) ; GET IO BASE ADDRES
CALL PRTHEXBYTE ; DISPLAY IT
;
CALL PPIDE_DETECT ; PROBE FOR INTERFACE
JR Z,PPIDE_INIT3 ; GOT IT, MOVE ON TO INIT UNITS
CALL PC_SPACE ; FORMATTING
LD DE,PPIDE_STR_NOPPI ; NO PPI MESSAGE
CALL WRITESTR ; DISPLAY IT
JR PPIDE_INIT4 ; SKIP CFG ENTRY
;
PPIDE_INIT3:
CALL PPIDE_RESET ; RESET THE BUS
CALL PPIDE_INIT5 ; DETECT/INIT MASTER
PUSH IY ; SAVE CFG PTR
CALL PPIDE_GOPARTNER ; SWITCH IY TO PARTNER CFG
CALL PPIDE_INIT5 ; DETECT/INIT SLAVE
POP IY ; RESTORE CFG PTR
;
PPIDE_INIT4:
LD DE,PPIDE_CFGSIZ ; SIZE OF CFG TABLE ENTRY
ADD IY,DE ; BUMP POINTER
JR PPIDE_INIT1 ; AND LOOP
;
PPIDE_INIT5:
; UPDATE DRIVER RELATIVE UNIT NUMBER IN CONFIG TABLE
LD A,(PPIDE_DEVNUM) ; GET NEXT UNIT NUM TO ASSIGN
LD (IY+PPIDE_DEV),A ; UPDATE IT
INC A ; BUMP TO NEXT UNIT NUM TO ASSIGN
LD (PPIDE_DEVNUM),A ; SAVE IT
;
; ADD UNIT TO GLOBAL DISK UNIT TABLE
LD BC,PPIDE_FNTBL ; BC := FUNC TABLE ADR
PUSH IY ; CFG ENTRY POINTER
POP DE ; COPY TO DE
CALL DIO_ADDENT ; ADD ENTRY TO GLOBAL DISK DEV TABLE
;
; CHECK FOR BAD STATUS
LD A,(IY+PPIDE_STAT) ; GET STATUS
OR A ; SET FLAGS
JP NZ,PPIDE_PRTSTAT ; EXIT VIA PRINT STATUS
;
CALL PPIDE_PRTPREFIX ; PRINT DEVICE PREFIX
;
LD DE,PPIDE_STR_8BIT
BIT 1,(IY+PPIDE_ACC) ; 8 BIT ACCESS?
CALL NZ,WRITESTR
;
; PRINT LBA/NOLBA
CALL PC_SPACE ; FORMATTING
BIT 1,(IY+PPIDE_MED) ; TEST LBA FLAG
LD DE,PPIDE_STR_NO ; POINT TO "NO" STRING
CALL Z,WRITESTR ; PRINT "NO" BEFORE "LBA" IF LBA NOT SUPPORTED
PRTS("LBA$") ; PRINT "LBA" REGARDLESS
;
; PRINT STORAGE CAPACITY (BLOCK COUNT)
PRTS(" BLOCKS=0x$") ; PRINT FIELD LABEL
LD A,PPIDE_MEDCAP ; OFFSET TO CAPACITY FIELD
CALL LDHLIYA ; HL := IY + A, REG A TRASHED
CALL LD32 ; GET THE CAPACITY VALUE
CALL PRTHEX32 ; PRINT HEX VALUE
;
; PRINT STORAGE SIZE IN MB
PRTS(" SIZE=$") ; 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$") ; PRINT SUFFIX
;
RET
;
;----------------------------------------------------------------------
; PROBE FOR PPI HARDWARE
;----------------------------------------------------------------------
;
; ON RETURN, ZF SET INDICATES HARDWARE FOUND
;
PPIDE_DETECT:
;
; TEST FOR PPI EXISTENCE
; WE SETUP THE PPI TO WRITE, THEN WRITE A VALUE OF ZERO
; TO PORT A (DATALO), THEN READ IT BACK. IF THE PPI IS THERE
; THEN THE BUS HOLD CIRCUITRY WILL READ BACK THE ZERO. SINCE
; WE ARE IN WRITE MODE, AN IDE CONTROLLER WILL NOT BE ABLE TO
; INTERFERE WITH THE VALUE BEING READ.
;
LD A,PPIDE_DIR_WRITE ; SET DATA BUS DIRECTION TO WRITE
LD C,(IY+PPIDE_PPI) ; PPI CONTROL WORD
OUT (C),A ; WRITE IT
;
LD C,(IY+PPIDE_DATALO) ; PPI PORT A, DATALO
XOR A ; VALUE ZERO
OUT (C),A ; PUSH VALUE TO PORT
IN A,(C) ; GET PORT VALUE
#IF (PPIDETRACE >= 3)
CALL PC_SPACE
CALL PRTHEXBYTE
#ENDIF
OR A ; SET FLAGS
RET ; AND RETURN
;
;=============================================================================
; DRIVER FUNCTION TABLE
;=============================================================================
;
PPIDE_FNTBL:
.DW PPIDE_STATUS
.DW PPIDE_RESET
.DW PPIDE_SEEK
.DW PPIDE_READ
.DW PPIDE_WRITE
.DW PPIDE_VERIFY
.DW PPIDE_FORMAT
.DW PPIDE_DEVICE
.DW PPIDE_MEDIA
.DW PPIDE_DEFMED
.DW PPIDE_CAP
.DW PPIDE_GEOM
#IF (($ - PPIDE_FNTBL) != (DIO_FNCNT * 2))
.ECHO "*** INVALID PPIDE FUNCTION TABLE ***\n"
#ENDIF
;
PPIDE_VERIFY:
PPIDE_FORMAT:
PPIDE_DEFMED:
CALL PANIC ; NOT IMPLEMENTED
;
;
;
PPIDE_READ:
CALL HB_DSKREAD ; HOOK HBIOS DISK READ SUPERVISOR
LD BC,PPIDE_RDSEC ; GET ADR OF SECTOR READ FUNC
LD (PPIDE_IOFNADR),BC ; SAVE IT AS PENDING IO FUNC
JR PPIDE_IO ; CONTINUE TO GENERIC IO ROUTINE
;
;
;
PPIDE_WRITE:
CALL HB_DSKWRITE ; HOOK HBIOS DISK WRITE SUPERVISOR
LD BC,PPIDE_WRSEC ; GET ADR OF SECTOR WRITE FUNC
LD (PPIDE_IOFNADR),BC ; SAVE IT AS PENDING IO FUNC
JR PPIDE_IO ; CONTINUE TO GENERIC IO ROUTINE
;
;
;
PPIDE_IO:
LD (PPIDE_DSKBUF),HL ; SAVE DISK BUFFER ADDRESS
LD A,E ; BLOCK COUNT TO A
OR A ; SET FLAGS
RET Z ; ZERO SECTOR I/O, RETURN W/ E=0 & A=0
LD B,A ; INIT SECTOR DOWNCOUNTER
LD C,0 ; INIT SECTOR READ/WRITE COUNT
#IF (PPIDETRACE == 1)
LD HL,PPIDE_PRTERR ; SET UP PPIDE_PRTERR
PUSH HL ; ... TO FILTER ALL EXITS
#ENDIF
PUSH BC ; SAVE COUNTERS
CALL PPIDE_SELUNIT ; HARDWARE SELECTION OF TARGET UNIT
CALL PPIDE_CHKERR ; CHECK FOR ERR STATUS AND RESET IF SO
POP BC ; RESTORE COUNTERS
JR NZ,PPIDE_IO3 ; BAIL OUT ON ERROR
PPIDE_IO1:
PUSH BC ; SAVE COUNTERS
LD HL,(PPIDE_IOFNADR) ; GET PENDING IO FUNCTION ADDRESS
CALL JPHL ; ... AND CALL IT
JR NZ,PPIDE_IO2 ; IF ERROR, SKIP INCREMENT
; INCREMENT LBA
LD A,PPIDE_LBA ; LBA OFFSET
CALL LDHLIYA ; HL := IY + A, REG A TRASHED
CALL INC32HL ; INCREMENT THE VALUE
; INCREMENT DMA
LD HL,PPIDE_DSKBUF+1 ; POINT TO MSB OF BUFFER ADR
INC (HL) ; BUMP DMA BY
INC (HL) ; ... 512 BYTES
XOR A ; SIGNAL SUCCESS
PPIDE_IO2:
POP BC ; RECOVER COUNTERS
JR NZ,PPIDE_IO3 ; IF ERROR, BAIL OUT
INC C ; BUMP COUNT OF SECTORS READ
DJNZ PPIDE_IO1 ; LOOP AS NEEDED
PPIDE_IO3:
LD E,C ; SECTOR READ COUNT TO E
LD HL,(PPIDE_DSKBUF) ; CURRENT DMA TO HL
OR A ; SET FLAGS BASED ON RETURN CODE
RET ; AND RETURN, A HAS RETURN CODE
;
;
;
PPIDE_STATUS:
; RETURN UNIT STATUS
LD A,(IY+PPIDE_STAT) ; GET STATUS OF SELECTED DEVICE
OR A ; SET FLAGS
RET ; AND RETURN
;
;
;
PPIDE_DEVICE:
LD D,DIODEV_PPIDE ; D := DEVICE TYPE
LD E,(IY+PPIDE_DEV) ; E := PHYSICAL DEVICE NUMBER
BIT 0,(IY+PPIDE_MED) ; TEST CF BIT IN FLAGS
LD C,%00000000 ; ASSUME NON-REMOVABLE HARD DISK
JR Z,PPIDE_DEVICE1 ; IF Z, WE ARE DONE
LD C,%01001000 ; OTHERWISE REMOVABLE COMPACT FLASH
PPIDE_DEVICE1:
XOR A ; SIGNAL SUCCESS
RET
;
; IDE_GETMED
;
PPIDE_MEDIA:
LD A,E ; GET FLAGS
OR A ; SET FLAGS
JR Z,PPIDE_MEDIA2 ; JUST REPORT CURRENT STATUS AND MEDIA
;
; GET CURRENT STATUS
LD A,(IY+PPIDE_STAT) ; GET STATUS
OR A ; SET FLAGS
JR NZ,PPIDE_MEDIA1 ; ERROR ACTIVE, GO RIGHT TO RESET
;
; USE IDENTIFY COMMAND TO CHECK DEVICE
LD HL,PPIDE_TIMEOUT ; POINT TO TIMEOUT
LD (HL),PPIDE_TOFAST ; USE FAST TIMEOUT DURING IDENTIFY COMMAND
CALL PPIDE_SELUNIT ; HARDWARE SELECTION OF TARGET UNIT
CALL PPIDE_IDENTIFY ; EXECUTE IDENTIFY COMMAND
LD HL,PPIDE_TIMEOUT ; POINT TO TIMEOUT
LD (HL),PPIDE_TONORM ; BACK TO NORMAL TIMEOUT
JR Z,PPIDE_MEDIA2 ; IF SUCCESS, BYPASS RESET
;
PPIDE_MEDIA1:
CALL PPIDE_RESET ; RESET IDE INTERFACE
;
PPIDE_MEDIA2:
LD A,(IY+PPIDE_STAT) ; 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
;
;
;
PPIDE_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 (IY+PPIDE_LBA+0),L ; SAVE NEW LBA
LD (IY+PPIDE_LBA+1),H ; ...
LD (IY+PPIDE_LBA+2),E ; ...
LD (IY+PPIDE_LBA+3),D ; ...
XOR A ; SIGNAL SUCCESS
RET ; AND RETURN
;
;
;
PPIDE_CAP:
LD A,(IY+PPIDE_STAT) ; GET STATUS
PUSH AF ; SAVE IT
LD A,PPIDE_MEDCAP ; OFFSET TO CAPACITY FIELD
CALL LDHLIYA ; HL := IY + A, REG A TRASHED
CALL LD32 ; GET THE CURRENT CAPACITY INTO DE:HL
LD BC,512 ; 512 BYTES PER BLOCK
POP AF ; RECOVER STATUS
OR A ; SET FLAGS
RET
;
;
;
PPIDE_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 PPIDE_CAP ; GET TOTAL BLOCKS IN DE:HL, BLOCK SIZE TO BC
LD L,H ; DIVPPIDE BY 256 FOR # TRACKS
LD H,E ; ... HIGH BYTE DISCARDED, RESULT IN HL
LD D,16 | $80 ; HEADS / CYL = 16, SET LBA CAPABILITY BIT
LD E,16 ; SECTORS / TRACK = 16
RET ; DONE, A STILL HAS PPIDE_CAP STATUS
;
;=============================================================================
; FUNCTION SUPPORT ROUTINES
;=============================================================================
;
;
;
PPIDE_SETFEAT:
PUSH AF
#IF (PPIDETRACE >= 3)
CALL PPIDE_PRTPREFIX
PRTS(" SETFEAT$")
#ENDIF
LD A,(PPIDE_DRVHD)
;OUT (PPIDE_REG_DRVHD),A
CALL PPIDE_OUT
.DB PPIDE_REG_DRVHD
#IF (PPIDETRACE >= 3)
CALL PC_SPACE
CALL PRTHEXBYTE
#ENDIF
POP AF
;OUT (PPIDE_REG_FEAT),A ; SET THE FEATURE VALUE
CALL PPIDE_OUT
.DB PPIDE_REG_FEAT
#IF (PPIDETRACE >= 3)
CALL PC_SPACE
CALL PRTHEXBYTE
#ENDIF
LD A,PPIDE_CMD_SETFEAT ; CMD = SETFEAT
LD (PPIDE_CMD),A ; SAVE IT
JP PPIDE_RUNCMD ; RUN COMMAND AND EXIT
;
;
;
PPIDE_IDENTIFY:
#IF (PPIDETRACE >= 3)
CALL PPIDE_PRTPREFIX
PRTS(" IDDEV$")
#ENDIF
LD A,(PPIDE_DRVHD)
;OUT (PPIDE_REG_DRVHD),A
CALL PPIDE_OUT
.DB PPIDE_REG_DRVHD
#IF (PPIDETRACE >= 3)
CALL PC_SPACE
CALL PRTHEXBYTE
#ENDIF
LD A,PPIDE_CMD_IDDEV
LD (PPIDE_CMD),A
CALL PPIDE_RUNCMD
RET NZ
LD HL,HB_WRKBUF
JP PPIDE_GETBUF ; EXIT THRU BUFRD
;
;
;
PPIDE_RDSEC:
;
#IF (PPIDETRACE >= 3)
CALL PPIDE_PRTPREFIX
PRTS(" READ$")
#ENDIF
LD A,(PPIDE_DRVHD)
;OUT (PPIDE_REG_DRVHD),A
CALL PPIDE_OUT
.DB PPIDE_REG_DRVHD
#IF (PPIDETRACE >= 3)
CALL PC_SPACE
CALL PRTHEXBYTE
#ENDIF
CALL PPIDE_SETADDR ; SETUP CYL, TRK, HEAD
LD A,PPIDE_CMD_READ
LD (PPIDE_CMD),A
CALL PPIDE_RUNCMD
RET NZ
LD HL,(PPIDE_DSKBUF)
JP PPIDE_GETBUF
;
;
;
PPIDE_WRSEC:
;
#IF (PPIDETRACE >= 3)
CALL PPIDE_PRTPREFIX
PRTS(" WRITE$")
#ENDIF
LD A,(PPIDE_DRVHD)
;OUT (PPIDE_REG_DRVHD),A
CALL PPIDE_OUT
.DB PPIDE_REG_DRVHD
#IF (PPIDETRACE >= 3)
CALL PC_SPACE
CALL PRTHEXBYTE
#ENDIF
CALL PPIDE_SETADDR ; SETUP CYL, TRK, HEAD
LD A,PPIDE_CMD_WRITE
LD (PPIDE_CMD),A
CALL PPIDE_RUNCMD
RET NZ
LD HL,(PPIDE_DSKBUF)
JP PPIDE_PUTBUF
;
;
;
PPIDE_SETADDR:
; SEND 3 LOWEST BYTES OF LBA IN REVERSE ORDER
; IDE_IO_LBA3 HAS ALREADY BEEN SET
; HSTLBA2-0 --> IDE_IO_LBA2-0
LD A,(IY+PPIDE_LBA+2)
#IF (PPIDETRACE >= 3)
CALL PC_SPACE
CALL PRTHEXBYTE
#ENDIF
CALL PPIDE_OUT
.DB PPIDE_REG_LBA2
;
LD A,(IY+PPIDE_LBA+1)
#IF (PPIDETRACE >= 3)
CALL PC_SPACE
CALL PRTHEXBYTE
#ENDIF
CALL PPIDE_OUT
.DB PPIDE_REG_LBA1
;
LD A,(IY+PPIDE_LBA+0)
#IF (PPIDETRACE >= 3)
CALL PC_SPACE
CALL PRTHEXBYTE
#ENDIF
CALL PPIDE_OUT
.DB PPIDE_REG_LBA0
;
LD A,1
#IF (PPIDETRACE >= 3)
CALL PC_SPACE
CALL PRTHEXBYTE
#ENDIF
CALL PPIDE_OUT
.DB PPIDE_REG_COUNT
;
#IF (DSKYENABLE)
CALL PPIDE_DSKY
#ENDIF
;
RET
;
;=============================================================================
; COMMAND PROCESSING
;=============================================================================
;
PPIDE_RUNCMD:
CALL PPIDE_WAITRDY ; WAIT FOR DRIVE READY
RET NZ ; BAIL OUT ON TIMEOUT
;
LD A,(PPIDE_CMD) ; GET THE COMMAND
#IF (PPIDETRACE >= 3)
CALL PC_SPACE
CALL PRTHEXBYTE
#ENDIF
;OUT (PPIDE_REG_CMD),A ; SEND IT (STARTS EXECUTION)
CALL PPIDE_OUT
.DB PPIDE_REG_CMD
#IF (PPIDETRACE >= 3)
PRTS(" -->$")
#ENDIF
;
CALL PPIDE_WAITBSY ; WAIT FOR DRIVE READY (COMMAND DONE)
RET NZ ; BAIL OUT ON TIMEOUT
;
CALL PPIDE_GETRES
JP NZ,PPIDE_CMDERR
RET
;
;
;
PPIDE_GETBUF:
#IF (PPIDETRACE >= 3)
PRTS(" GETBUF$")
#ENDIF
;
; WAIT FOR BUFFER
CALL PPIDE_WAITDRQ ; WAIT FOR BUFFER READY
RET NZ ; BAIL OUT IF TIMEOUT
;
; SETUP PPI TO READ
LD A,PPIDE_DIR_READ ; SET DATA BUS DIRECTION TO READ
;OUT (PPIDE_IO_PPI),A ; DO IT
LD C,(IY+PPIDE_PPI) ; PPI CONTROL WORD
OUT (C),A ; WRITE IT
;
; SELECT READ/WRITE IDE REGISTER
LD A,PPIDE_REG_DATA ; DATA REGISTER
;OUT (PPIDE_IO_CTL),A ; DO IT
LD C,(IY+PPIDE_CTL) ; SET IDE ADDRESS
OUT (C),A ; DO IT
LD E,A ; E := READ UNASSERTED
XOR PPIDE_CTL_DIOR ; SWAP THE READ LINE BIT
LD D,A ; D := READ ASSERTED
;
; LOOP SETUP
XOR A ; IMPORTANT, NEEDED FOR LOOP END COMPARISON
LD B,0 ; 256 ITERATIONS
LD C,(IY+PPIDE_CTL) ; SET IDE ADDRESS
;
BIT 1,(IY+PPIDE_ACC) ; 8 BIT?
JR Z,PPIDE_GETBUF1 ; IF NOT, DO 16 BIT
CALL PPIDE_GETBUF8 ; FIRST PASS (FIRST 256 BYTES)
CALL PPIDE_GETBUF8 ; SECOND PASS (LAST 256 BYTES)
JR PPIDE_GETBUF2 ; CONTINUE
PPIDE_GETBUF1:
CALL PPIDE_GETBUF16 ; FIRST PASS (FIRST 256 BYTES)
CALL PPIDE_GETBUF16 ; SECOND PASS (LAST 256 BYTES)
PPIDE_GETBUF2:
CALL PPIDE_WAITRDY ; PROBLEMS IF THIS IS REMOVED!
RET NZ
CALL PPIDE_GETRES
JP NZ,PPIDE_IOERR
RET
;
PPIDE_GETBUF8: ; 8 BIT WIDE READ LOOP
; ENTER W/ C = PPIDE_IO_CTL
OUT (C),D ; ASSERT READ
DEC C ; CTL -> MSB
DEC C ; MSB -> LSB
INI ; READ FROM LSB
INC C ; LSB -> MSB
INC C ; MSB -> CTL
OUT (C),E ; DEASSERT READ
CP B ; B == A == 0?
JR NZ,PPIDE_GETBUF8 ; LOOP UNTIL DONE
RET
;
PPIDE_GETBUF16: ; 16 BIT WIDE READ LOOP
; ENTER W/ C = PPIDE_IO_CTL
OUT (C),D ; ASSERT READ
DEC C ; CTL -> MSB
DEC C ; MSB -> LSB
INI ; READ FROM LSB
INC C ; LSB -> MSB
INI ; READ MSB FOR 16 BIT
INC C ; MSB -> CTL
OUT (C),E ; DEASSERT READ
CP B ; B == A == 0?
JR NZ,PPIDE_GETBUF16 ; LOOP UNTIL DONE
RET
;
;
;
PPIDE_PUTBUF:
#IF (PPIDETRACE >= 3)
PRTS(" PUTBUF$")
#ENDIF
;
; WAIT FOR BUFFER
CALL PPIDE_WAITDRQ ; WAIT FOR BUFFER READY
RET NZ ; BAIL OUT IF TIMEOUT
;
; SETUP PPI TO WRITE
LD A,PPIDE_DIR_WRITE ; SET DATA BUS DIRECTION TO WRITE
;OUT (PPIDE_IO_PPI),A ; DO IT
LD C,(IY+PPIDE_PPI) ; PPI CONTROL WORD
OUT (C),A ; WRITE IT
;
; SELECT READ/WRITE IDE REGISTER
LD A,PPIDE_REG_DATA ; DATA REGISTER
;OUT (PPIDE_IO_CTL),A ; DO IT
LD C,(IY+PPIDE_CTL) ; SET IDE ADDRESS
OUT (C),A ; DO IT
LD E,A ; E := WRITE UNASSERTED
XOR PPIDE_CTL_DIOW ; SWAP THE READ LINE BIT
LD D,A ; D := WRITE ASSERTED
;
; LOOP SETUP
XOR A ; IMPORTANT, NEEDED FOR LOOP END COMPARISON
LD B,0 ; 256 ITERATIONS
LD C,(IY+PPIDE_CTL) ; SET IDE ADDRESS
;
BIT 1,(IY+PPIDE_ACC) ; 8 BIT?
JR Z,PPIDE_PUTBUF1 ; IF NOT, DO 16 BIT
CALL PPIDE_PUTBUF8 ; FIRST PASS (FIRST 256 BYTES)
CALL PPIDE_PUTBUF8 ; SECOND PASS (LAST 256 BYTES)
JR PPIDE_PUTBUF2 ; CONTINUE
PPIDE_PUTBUF1:
CALL PPIDE_PUTBUF16 ; FIRST PASS (FIRST 256 BYTES)
CALL PPIDE_PUTBUF16 ; SECOND PASS (LAST 256 BYTES)
PPIDE_PUTBUF2:
CALL PPIDE_WAITRDY ; PROBLEMS IF THIS IS REMOVED!
RET NZ
CALL PPIDE_GETRES
JP NZ,PPIDE_IOERR
RET
;
PPIDE_PUTBUF8: ; 8 BIT WIDE WRITE LOOP
DEC C ; CTL -> MSB
DEC C ; MSB -> LSB
OUTI ; WRITE NEXT BYTE (LSB)
INC C ; LSB -> MSB
INC C ; MSB -> CTL
OUT (C),D ; ASSERT WRITE
OUT (C),E ; DEASSERT WRITE
CP B ; B == A == 0?
JR NZ,PPIDE_PUTBUF8 ; LOOP UNTIL DONE
RET
;
PPIDE_PUTBUF16: ; 16 BIT WIDE WRITE LOOP
DEC C ; CTL -> MSB
DEC C ; MSB -> LSB
OUTI ; WRITE NEXT BYTE (LSB)
INC C ; LSB -> MSB
OUTI ; WRITE NEXT BYTE (MSB)
INC C ; MSB -> CTL
OUT (C),D ; ASSERT WRITE
OUT (C),E ; DEASSERT WRITE
CP B ; B == A == 0?
JR NZ,PPIDE_PUTBUF16 ; LOOP UNTIL DONE
RET
;
;
;
PPIDE_GETRES:
;IN A,(PPIDE_REG_STAT) ; READ STATUS
CALL PPIDE_IN
.DB PPIDE_REG_STAT
#IF (PPIDETRACE >= 3)
CALL PC_SPACE
CALL PRTHEXBYTE
#ENDIF
AND %00000001 ; ERROR BIT SET?
RET Z ; NOPE, RETURN WITH ZF
;
;IN A,(PPIDE_REG_ERR) ; READ ERROR REGISTER
CALL PPIDE_IN
.DB PPIDE_REG_ERR
#IF (PPIDETRACE >= 3)
CALL PC_SPACE
CALL PRTHEXBYTE
#ENDIF
OR $FF ; FORCE NZ TO SIGNAL ERROR
RET ; RETURN
;
;=============================================================================
; HARDWARE INTERFACE ROUTINES
;=============================================================================
;
; SOFT RESET OF ALL DEVICES ON BUS
;
PPIDE_RESET:
#IF (PPIDETRACE >= 3)
CALL PPIDE_PRTPREFIX
PRTS(" RESET$")
#ENDIF
;
; OLDER CF CARDS DO NOT SEEM TO SET THE
; REGISTERS ON RESET, SO HERE WE FAKE THINGS BY
; SETTING THEM AS A RESET WOULD
#IF (IDETRACE >= 3)
PRTS(" FAKE$")
#ENDIF
XOR A
;OUT (IDE_IO_CYLLO),A
CALL PPIDE_OUT
.DB PPIDE_REG_CYLLO
;OUT (IDE_IO_CYLHI),A
CALL PPIDE_OUT
.DB PPIDE_REG_CYLHI
INC A
;OUT (IDE_IO_COUNT),A
CALL PPIDE_OUT
.DB PPIDE_REG_COUNT
;OUT (IDE_IO_SECT),A
CALL PPIDE_OUT
.DB PPIDE_REG_SECT
;
; SETUP PPI TO READ
LD A,PPIDE_DIR_READ ; SET DATA BUS DIRECTION TO READ
;OUT (PPIDE_IO_PPI),A ; DO IT
LD C,(IY+PPIDE_PPI) ; PPI CONTROL WORD
OUT (C),A ; WRITE IT
;
; PULSE IDE RESET LINE
LD A,PPIDE_CTL_RESET
;OUT (PPIDE_IO_CTL),A
LD C,(IY+PPIDE_CTL) ; SET IDE ADDRESS
OUT (C),A
LD DE,20
CALL VDELAY
XOR A
;OUT (PPIDE_IO_CTL),A
OUT (C),A
LD DE,20
CALL VDELAY
;
LD A,%00001010 ; SET ~IEN, NO INTERRUPTS
;OUT (PPIDE_REG_CTRL),A
CALL PPIDE_OUT
.DB PPIDE_REG_CTRL
;
; SPEC ALLOWS UP TO 450MS FOR DEVICES TO ASSERT THEIR PRESENCE
; VIA -DASP. I ENCOUNTER PROBLEMS LATER ON IF I DON'T WAIT HERE
; FOR THAT TO OCCUR. THUS FAR, IT APPEARS THAT 150MS IS SUFFICIENT
; FOR ANY DEVICE ENCOUNTERED. MAY NEED TO EXTEND BACK TO 500MS
; IF A SLOWER DEVICE IS ENCOUNTERED.
;
;LD DE,500000/16 ; ~500MS
LD DE,150000/16 ; ~???MS
CALL VDELAY
;
; INITIALIZE THE INDIVIDUAL UNITS (MASTER AND SLAVE).
; BASED ON TESTING, IT APPEARS THAT THE MASTER UNIT MUST
; BE DONE FIRST OR THIS BEHAVES BADLY.
PUSH IY ; SAVE CFG PTR
BIT 0,(IY+PPIDE_ACC) ; MASTER?
CALL Z,PPIDE_GOPARTNER ; IF NOT, SWITCH TO MASTER
CALL PPIDE_INITUNIT ; INIT CURRENT UNIT
CALL PPIDE_GOPARTNER ; POINT TO SLAVE
CALL PPIDE_INITUNIT ; INIT PARTNER UNIT
POP IY ; RECOVER ORIG CFG PTR
;
XOR A ; SIGNAL SUCCESS
RET ; AND DONE
;
;
;
PPIDE_INITUNIT:
CALL PPIDE_SELUNIT ; SELECT UNIT
RET NZ ; ABORT IF ERROR
LD HL,PPIDE_TIMEOUT ; POINT TO TIMEOUT
LD (HL),PPIDE_TONORM ; SET NORMAL TIMEOUT
CALL PPIDE_PROBE ; DO PROBE
RET NZ ; JUST RETURN IF NOTHING THERE
CALL PPIDE_INITDEV ; IF FOUND, ATTEMPT TO INIT DEVICE
RET ; DONE
;
; TAKE ANY ACTIONS REQUIRED TO SELECT DESIRED PHYSICAL UNIT
;
PPIDE_SELUNIT:
#IF (PPIDETRACE >= 3)
CALL PPIDE_PRTPREFIX
PRTS(" SELUNIT$")
#ENDIF
BIT 0,(IY+PPIDE_ACC) ; MASTER?
JR Z,PPIDE_SELUNIT1 ; HANDLE SLAVE
LD A,PPIDE_DRVMASTER ; MASTER
JR PPIDE_SELUNIT2
PPIDE_SELUNIT1:
LD A,PPIDE_DRVSLAVE ; SLAVE
PPIDE_SELUNIT2:
LD (PPIDE_DRVHD),A ; SAVE IT
XOR A ; SUCCESS
RET
;
;
;
PPIDE_PROBE:
#IF (PPIDETRACE >= 3)
CALL PPIDE_PRTPREFIX
PRTS(" PROBE$") ; LABEL FOR IO ADDRESS
#ENDIF
;
LD A,(PPIDE_DRVHD)
;OUT (IDE_IO_DRVHD),A
CALL PPIDE_OUT
.DB PPIDE_REG_DRVHD
#IF (PPIDETRACE >= 3)
CALL PC_SPACE
CALL PRTHEXBYTE
#ENDIF
CALL DELAY ; DELAY ~16US
;
; BELOW TESTS FOR EXISTENCE OF AN IDE CONTROLLER ON THE
; PPIDE INTERFACE. WE WRITE A VALUE OF ZERO FIRST SO THAT
; THE PPI BUS HOLD WILL RETURN A VALUE OF ZERO IF THERE IS
; NOTHING CONNECTED TO PPI PORT A. THEN WE READ THE STATUS
; REGISTER. IF AN IDE CONTROLLER IS THERE, IT SHOULD ALWAYS
; RETURN SOMETHING OTHER THAN ZERO. IF AN IDE CONTROLLER IS
; THERE, THEN THE VALUE WRITTEN TO PPI PORT A IS IGNORED
; BECAUSE THE WRITE SIGNAL IS NEVER PULSED.
XOR A
;OUT (PPIDE_IO_DATALO),A
LD C,(IY+PPIDE_DATALO) ; PPI PORT A, DATALO
OUT (C),A
; IN A,(PPIDE_REG_STAT) ; GET STATUS
CALL PPIDE_IN
.DB PPIDE_REG_STAT
#IF (PPIDETRACE >= 3)
CALL PC_SPACE
CALL PRTHEXBYTE
#ENDIF
OR A
JP Z,PPIDE_NOMEDIA
;
#IF (PPIDETRACE >= 3)
CALL PPIDE_REGDUMP
#ENDIF
;
;JR PPIDE_PROBE1 ; *DEBUG*
;
PPIDE_PROBE0:
CALL PPIDE_WAITBSY ; WAIT FOR BUSY TO CLEAR
JP NZ,PPIDE_NOMEDIA ; CONVERT TIMEOUT TO NO MEDIA AND RETURN
;
#IF (PPIDETRACE >= 3)
CALL PPIDE_REGDUMP
#ENDIF
;
; CHECK STATUS
; IN A,(PPIDE_REG_STAT) ; GET STATUS
CALL PPIDE_IN
.DB PPIDE_REG_STAT
#IF (PPIDETRACE >= 3)
CALL PC_SPACE
CALL PRTHEXBYTE ; IF DEBUG, PRINT STATUS
#ENDIF
OR A ; SET FLAGS TO TEST FOR ZERO
JP Z,PPIDE_NOMEDIA ; CONTINUE IF NON-ZERO
;
; CHECK SIGNATURE
#IF (PPIDETRACE >= 3)
CALL PC_SPACE
#ENDIF
;IN A,(PPIDE_REG_COUNT)
CALL PPIDE_IN
.DB PPIDE_REG_COUNT
#IF (PPIDETRACE >= 3)
CALL PRTHEXBYTE
#ENDIF
CP $01
JP NZ,PPIDE_NOMEDIA
#IF (PPIDETRACE >= 3)
CALL PC_SPACE
#ENDIF
;IN A,(PPIDE_REG_SECT)
CALL PPIDE_IN
.DB PPIDE_REG_SECT
#IF (PPIDETRACE >= 3)
CALL PRTHEXBYTE
#ENDIF
CP $01
JP NZ,PPIDE_NOMEDIA
#IF (PPIDETRACE >= 3)
CALL PC_SPACE
#ENDIF
;IN A,(PPIDE_REG_CYLLO)
CALL PPIDE_IN
.DB PPIDE_REG_CYLLO
#IF (PPIDETRACE >= 3)
CALL PRTHEXBYTE
#ENDIF
CP $00
JP NZ,PPIDE_NOMEDIA
#IF (PPIDETRACE >= 3)
CALL PC_SPACE
#ENDIF
;IN A,(PPIDE_REG_CYLHI)
CALL PPIDE_IN
.DB PPIDE_REG_CYLHI
#IF (PPIDETRACE >= 3)
CALL PRTHEXBYTE
#ENDIF
CP $00
JP NZ,PPIDE_NOMEDIA
;
PPIDE_PROBE1:
; SIGNATURE MATCHES ATA DEVICE, RECORD TYPE AND RETURN SUCCESS
LD A,PPIDE_TYPEATA ; TYPE = ATA
LD (IY+PPIDE_TYPE),A ; SET IT IN INSTANCE DATA
XOR A ; SIGNAL SUCCESS
RET ; DONE, NOTE THAT A=0 AND Z IS SET
;
; (RE)INITIALIZE DEVICE
;
PPIDE_INITDEV:
;
LD A,(IY+PPIDE_TYPE) ; GET THE DEVICE TYPE
OR A ; SET FLAGS
JP Z,PPIDE_NOMEDIA ; EXIT SETTING NO MEDIA STATUS
;
BIT 1,(IY+PPIDE_ACC) ; 8 BIT ACCESS?
JR Z,PPIDE_INITDEV0 ; NO, DO 16 BIT INIT
LD A,PPIDE_FEAT_ENABLE8BIT ; FEATURE VALUE = ENABLE 8-BIT PIO
CALL PPIDE_SETFEAT ; SET FEATURE
RET NZ ; BAIL OUT ON ERROR
JR PPIDE_INITDEV00 ; CONTINUE
;
PPIDE_INITDEV0:
; "REAL" IDE DRIVES MAY NOT ACCEPT THE DISABLE8BIT FEATURE COMMAND,
; SO IT IS ONLY AN ERROR IF WE ARE ATTEMPTING TO ENABLE8BIT.
; CREDIT TO ED BRINDLEY FOR THIS CORRECTION. SO ERROR RETURN IGNORED HERE.
LD A,PPIDE_FEAT_DISABLE8BIT ; FEATURE VALUE = ENABLE 8-BIT PIO
CALL PPIDE_SETFEAT ; SET FEATURE, IGNORE ERRORS
;
PPIDE_INITDEV00:
;
CALL PPIDE_IDENTIFY ; EXECUTE PPIDENTIFY COMMAND
RET NZ ; BAIL OUT ON ERROR
;
LD DE,HB_WRKBUF ; POINT TO BUFFER
#IF (PPIDETRACE >= 3)
CALL DUMP_BUFFER ; DUMP IT IF DEBUGGING
#ENDIF
;
LD (IY+PPIDE_MED),0 ; CLEAR MEDIA FLAGS
;
; 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,PPIDE_INITDEV1 ; IF NO MATCH, NOT CF
INC HL
LD A,$84 ; SECOND BYTE OF MARKER IS $84
CP (HL) ; COMPARE
JR NZ,PPIDE_INITDEV1 ; IF NOT MATCH, NOT CF
SET 0,(IY+PPIDE_MED) ; SET FLAGS BIT FOR CF MEDIA
;
PPIDE_INITDEV1:
; DETERMINE IF LBA CAPABLE
LD A,(HB_WRKBUF+98+1) ; GET BYTE WITH LBA BIT FROM BUFFER
BIT 1,A ; CHECK THE LBA BIT
JR Z,PPIDE_INITDEV2 ; NOT SET, BYPASS
SET 1,(IY+PPIDE_MED) ; SET FLAGS BIT FOR LBA
;
PPIDE_INITDEV2:
; GET DEVICE CAPACITY AND SAVE IT
LD A,PPIDE_MEDCAP ; OFFSET TO CAPACITY FIELD
CALL LDHLIYA ; HL := IY + A, REG A TRASHED
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)
XOR A ; A := 0 (STATUS = OK)
LD (IY+PPIDE_STAT),A ; SAVE IT
;
RET ; RETURN, A=0, Z SET
;
; SWITCH IY POINTER FROM CURRENT UNIT CFG TO PARTNER UNIT CFG
;
PPIDE_GOPARTNER:
PUSH HL ; SAVE HL
LD L,(IY+PPIDE_PARTNER) ; GET PARTNER ENTRY
LD H,(IY+PPIDE_PARTNER+1) ; ...
PUSH HL ; MOVE HL
POP IY ; ... TO IY
POP HL ; RESTORE INCOMING HL
RET ; AND DONE
;
; CHECK CURRENT DEVICE FOR ERROR STATUS AND ATTEMPT TO RECOVER
; VIA RESET IF DEVICE IS IN ERROR.
;
PPIDE_CHKERR:
LD A,(IY+PPIDE_STAT) ; GET STATUS
OR A ; SET FLAGS
CALL NZ,PPIDE_RESET ; IF ERROR STATUS, RESET BUS
RET
;
;
;
PPIDE_WAITRDY:
LD A,(PPIDE_TIMEOUT) ; GET TIMEOUT IN 0.05 SECS
LD B,A ; PUT IN OUTER LOOP VAR
PPIDE_WAITRDY1:
LD DE,(PPIDE_TOSCALER) ; CPU SPEED SCALER TO INNER LOOP VAR
PPIDE_WAITRDY2:
;IN A,(PPIDE_REG_STAT) ; READ STATUS
CALL PPIDE_IN
.DB PPIDE_REG_STAT
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,PPIDE_WAITRDY2 ; INNER LOOP RETURN
DJNZ PPIDE_WAITRDY1 ; OUTER LOOP RETURN
JP PPIDE_RDYTO ; EXIT WITH RDYTO ERR
;
;
;
PPIDE_WAITDRQ:
LD A,(PPIDE_TIMEOUT) ; GET TIMEOUT IN 0.05 SECS
LD B,A ; PUT IN OUTER LOOP VAR
PPIDE_WAITDRQ1:
LD DE,(PPIDE_TOSCALER) ; CPU SPEED SCALER TO INNER LOOP VAR
PPIDE_WAITDRQ2:
;IN A,(PPIDE_REG_STAT) ; READ STATUS
CALL PPIDE_IN
.DB PPIDE_REG_STAT
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,PPIDE_WAITDRQ2
DJNZ PPIDE_WAITDRQ1
JP PPIDE_DRQTO ; EXIT WITH BUFTO ERR
;
;
;
PPIDE_WAITBSY:
LD A,(PPIDE_TIMEOUT) ; GET TIMEOUT IN 0.05 SECS
LD B,A ; PUT IN OUTER LOOP VAR
PPIDE_WAITBSY1:
LD DE,(PPIDE_TOSCALER) ; CPU SPEED SCALER TO INNER LOOP VAR
PPIDE_WAITBSY2:
;IN A,(PPIDE_REG_STAT) ; READ STATUS
CALL PPIDE_IN ; 17TS + 170TS
.DB PPIDE_REG_STAT ; 0TS
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,PPIDE_WAITBSY2 ; 12TS
DJNZ PPIDE_WAITBSY1 ; -----
JP PPIDE_BSYTO ; EXIT WITH BSYTO ERR ; 229TS
;
; READ A VALUE FROM THE DEVICE POINTED TO BY IY AND RETURN IT IN A
;
PPIDE_IN:
EX (SP),HL ; GET PARM POINTER ; 19TS
PUSH BC ; SAVE INCOMING BC ; 11TS
LD A,PPIDE_DIR_READ ; SET DATA BUS DIRECTION TO READ ; 7TS
;OUT (PPIDE_IO_PPI),A ; DO IT ; 11TS
LD C,(IY+PPIDE_PPI) ; PPI CONTROL WORD
OUT (C),A ; WRITE IT
;
LD B,(HL) ; GET CTL PORT VALUE ; 7TS
;LD C,PPIDE_IO_CTL ; SETUP PORT TO WRITE ; 7TS
;LD C,(IY+PPIDE_CTL) ; SET IDE ADDRESS
DEC C ; SET IDE ADDRESS
OUT (C),B ; SET ADDRESS LINES ; 12TS
SET 6,B ; TURN ON READ BIT ; 8TS
OUT (C),B ; ASSERT READ LINE ; 12TS
;
;IN A,(PPIDE_IO_DATALO) ; GET DATA VALUE FROM DEVICE ; 11TS
DEC C
DEC C
IN A,(C) ; GET DATA VALUE FROM DEVICE
INC C
INC C
;
RES 6,B ; CLEAR READ BIT ; 8TS
OUT (C),B ; DEASSERT READ LINE ; 12TS
POP BC ; RECOVER INCOMING BC ; 10TS
INC HL ; POINT PAST PARM ; 6TS
EX (SP),HL ; RESTORE STACK ; 19TS
RET ; 10TS
;
; OUTPUT VALUE IN A TO THE DEVICE POINTED TO BY IY
;
PPIDE_OUT:
; *** TODO *** FIX ORDER OF SET/CLEAR WRITE LINE
EX (SP),HL ; GET PARM POINTER
PUSH BC ; SAVE INCOMING BC
PUSH AF ; PRESERVE INCOMING VALUE
LD A,PPIDE_DIR_WRITE ; SET DATA BUS DIRECTION TO WRITE
;OUT (PPIDE_IO_PPI),A ; DO IT
LD C,(IY+PPIDE_PPI) ; PPI CONTROL WORD
OUT (C),A ; WRITE IT
POP AF ; RECOVER VALUE TO WRITE
;
LD B,(HL) ; GET IDE ADDRESS VALUE
;LD C,PPIDE_IO_CTL ; SETUP PORT TO WRITE
;LD C,(IY+PPIDE_CTL) ; SET IDE ADDRESS
DEC C ; SET IDE ADDRESS
OUT (C),B ; SET ADDRESS LINES
SET 5,B ; TURN ON WRITE BIT
OUT (C),B ; ASSERT WRITE LINE
;
DEC C
DEC C
;OUT (PPIDE_IO_DATALO),A ; SEND DATA VALUE TO DEVICE
OUT (C),A ; SEND DATA VALUE TO DEVICE
INC C
INC C
;
RES 5,B ; CLEAR WRITE BIT
OUT (C),B ; DEASSERT WRITE LINE
POP BC ; RECOVER INCOMING BC
INC HL ; POINT PAST PARM
EX (SP),HL ; RESTORE STACK
RET
;
;=============================================================================
; ERROR HANDLING AND DIAGNOSTICS
;=============================================================================
;
; ERROR HANDLERS
;
PPIDE_INVUNIT:
LD A,PPIDE_STINVUNIT
JR PPIDE_ERR2 ; SPECIAL CASE FOR INVALID UNIT
;
PPIDE_NOMEDIA:
LD A,PPIDE_STNOMEDIA
JR PPIDE_ERR
;
PPIDE_CMDERR:
LD A,PPIDE_STCMDERR
JR PPIDE_ERR
;
PPIDE_IOERR:
LD A,PPIDE_STIOERR
JR PPIDE_ERR
;
PPIDE_RDYTO:
LD A,PPIDE_STRDYTO
JR PPIDE_ERR
;
PPIDE_DRQTO:
LD A,PPIDE_STDRQTO
JR PPIDE_ERR
;
PPIDE_BSYTO:
LD A,PPIDE_STBSYTO
JR PPIDE_ERR
;
PPIDE_ERR:
LD (IY+PPIDE_STAT),A ; SAVE NEW STATUS
;
PPIDE_ERR2:
#IF (PPIDETRACE >= 2)
CALL PPIDE_PRTSTAT
CALL PPIDE_REGDUMP
#ENDIF
OR A ; SET FLAGS
RET
;
;
;
PPIDE_PRTERR:
RET Z ; DONE IF NO ERRORS
; FALL THRU TO PPIDE_PRTSTAT
;
; PRINT STATUS STRING (STATUS NUM IN A)
;
PPIDE_PRTSTAT:
PUSH AF
PUSH DE
PUSH HL
OR A
LD DE,PPIDE_STR_STOK
JR Z,PPIDE_PRTSTAT1
INC A
LD DE,PPIDE_STR_STINVUNIT
JR Z,PPIDE_PRTSTAT2 ; INVALID UNIT IS SPECIAL CASE
INC A
LD DE,PPIDE_STR_STNOMEDIA
JR Z,PPIDE_PRTSTAT1
INC A
LD DE,PPIDE_STR_STCMDERR
JR Z,PPIDE_PRTSTAT1
INC A
LD DE,PPIDE_STR_STIOERR
JR Z,PPIDE_PRTSTAT1
INC A
LD DE,PPIDE_STR_STRDYTO
JR Z,PPIDE_PRTSTAT1
INC A
LD DE,PPIDE_STR_STDRQTO
JR Z,PPIDE_PRTSTAT1
INC A
LD DE,PPIDE_STR_STBSYTO
JR Z,PPIDE_PRTSTAT1
LD DE,PPIDE_STR_STUNK
PPIDE_PRTSTAT1:
CALL PPIDE_PRTPREFIX ; PRINT UNIT PREFIX
JR PPIDE_PRTSTAT3
PPIDE_PRTSTAT2:
CALL NEWLINE
PRTS("PPIDE:$") ; NO UNIT NUM IN PREFIX FOR INVALID UNIT
PPIDE_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
;
PPIDE_REGDUMP:
PUSH AF
PUSH BC
push DE
CALL PC_SPACE
CALL PC_LBKT
LD A,PPIDE_DIR_READ ; SET DATA BUS DIRECTION TO READ
;OUT (PPIDE_IO_PPI),A ; DO IT
LD C,(IY+PPIDE_PPI) ; PPI CONTROL WORD
OUT (C),A ; WRITE IT
LD C,(IY+PPIDE_CTL) ; SET IDE ADDRESS
LD E,PPIDE_REG_CMD
LD B,7
PPIDE_REGDUMP1:
LD A,E ; REGISTER ADDRESS
;OUT (PPIDE_IO_CTL),A ; SET IT
OUT (C),A ; REGISTER ADDRESS
XOR PPIDE_CTL_DIOR ; SET BIT TO ASSERT READ LINE
;OUT (PPIDE_IO_CTL),A ; ASSERT READ
OUT (C),A ; ASSERT READ
;IN A,(PPIDE_IO_DATALO) ; GET VALUE
DEC C ; CTL -> MSB
DEC C ; MSB -> LSB
IN A,(C) ; GET VALUE
INC C ; LSB -> MSB
INC C ; MSB -> CTL
CALL PRTHEXBYTE ; DISPLAY IT
;LD A,C ; RELOAD ADDRESS W/ READ UNASSERTED
;OUT (PPIDE_IO_CTL),A ; AND SET IT
OUT (C),E ; RELOAD ADDRESS W/ READ UNASSERTED
;DEC C ; NEXT LOWER REGISTER
DEC E ; NEXT LOWER REGISTER
DEC B ; DEC LOOP COUNTER
CALL NZ,PC_SPACE ; FORMATTING
JR NZ,PPIDE_REGDUMP1 ; LOOP AS NEEDED
CALL PC_RBKT ; FORMATTING
POP DE
POP BC
POP AF
RET
;
; PRINT DIAGNONSTIC PREFIX
;
PPIDE_PRTPREFIX:
PUSH AF
CALL NEWLINE
PRTS("PPIDE$")
LD A,(IY+PPIDE_DEV) ; GET CURRENT DEVICE NUM
ADD A,'0'
CALL COUT
CALL PC_COLON
POP AF
RET
;
;
;
#IF (DSKYENABLE)
PPIDE_DSKY:
LD HL,DSKY_HEXBUF ; POINT TO DSKY BUFFER
CALL PPIDE_IN
.DB PPIDE_REG_DRVHD
LD (HL),A ; SAVE IN BUFFER
INC HL ; INCREMENT BUFFER POINTER
CALL PPIDE_IN
.DB PPIDE_REG_CYLHI
LD (HL),A ; SAVE IN BUFFER
INC HL ; INCREMENT BUFFER POINTER
CALL PPIDE_IN
.DB PPIDE_REG_CYLLO
LD (HL),A ; SAVE IN BUFFER
INC HL ; INCREMENT BUFFER POINTER
CALL PPIDE_IN
.DB PPIDE_REG_SECT
LD (HL),A ; SAVE IN BUFFER
CALL DSKY_HEXOUT ; SEND IT TO DSKY
RET
#ENDIF
;
;=============================================================================
; STRING DATA
;=============================================================================
;
PPIDE_STR_STOK .TEXT "OK$"
PPIDE_STR_STINVUNIT .TEXT "INVALID UNIT$"
PPIDE_STR_STNOMEDIA .TEXT "NO MEDIA$"
PPIDE_STR_STCMDERR .TEXT "COMMAND ERROR$"
PPIDE_STR_STIOERR .TEXT "IO ERROR$"
PPIDE_STR_STRDYTO .TEXT "READY TIMEOUT$"
PPIDE_STR_STDRQTO .TEXT "DRQ TIMEOUT$"
PPIDE_STR_STBSYTO .TEXT "BUSY TIMEOUT$"
PPIDE_STR_STUNK .TEXT "UNKNOWN ERROR$"
;
PPIDE_STR_NO .TEXT "NO$"
PPIDE_STR_NOPPI .TEXT "PPI NOT PRESENT$"
PPIDE_STR_8BIT .TEXT " 8-BIT$"
;
;=============================================================================
; DATA STORAGE
;=============================================================================
;
PPIDE_TIMEOUT .DB PPIDE_TONORM ; WAIT FUNCS TIMEOUT IN TENTHS OF SEC
PPIDE_TOSCALER .DW CPUMHZ * 218 ; WAIT FUNCS SCALER FOR CPU SPEED
;
PPIDE_CMD .DB 0 ; PENDING COMMAND TO PROCESS
PPIDE_IOFNADR .DW 0 ; PENDING IO FUNCTION ADDRESS
PPIDE_DRVHD .DB 0 ; CURRENT DRIVE/HEAD MASK
;
PPIDE_DSKBUF .DW 0 ; ACTIVE DISK BUFFER
;
PPIDE_DEVNUM .DB 0 ; TEMP DEVICE NUM USED DURING INIT
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