Opus Challenger
The Opus Challenger is a peripheral for the BBC Microcomputer series that provides double-density floppy disc and RAM disc storage. Plugging into the 1 MHz bus and auxiliary power connector, the external case contains an Opus-branded Mitsubishi 5¼" DSDD 80-track disc drive, a WD 1770 floppy drive controller and either 256 KiB or 512 KiB of RAM.
The accompanying ROM enables the user to treat the RAM as one or two virtual DFS floppy drives up to 256 kilobytes each, or one 512 kilobyte ADFS volume on a Master series computer. It also provides access to data on floppy disc in either Acorn DFS format or in the proprietary double-density format of Opus DDOS, giving data capacities of up to 200 KiB and 360 KiB per disc, respectively.
Hardware
Challenger 3 is the definitive model of the expansion unit; its label design incorporating a '3-in-1' device raises confusion but it appears in Opus's first advertisements for the Challenger in October 1985, [verify] and so likely indicates the first released model.
The four registers of the WD 1770 floppy drive controller and three auxiliary registers are mapped to the end of the FRED address space:
Address | Source on read | Destination on write |
---|---|---|
&FCF8 | Status register | Control register |
&FCF9 | Track register | Track register |
&FCFA | Sector register | Sector register |
&FCFB | Data register | Data register |
&FCFC | Undefined | Control latch |
&FCFE | Undefined | MSB JIM paging register |
&FCFF | Undefined | LSB JIM paging register |
Bits 2..0 of the MSB JIM paging register select one of eight 64 KiB banks to make available the full 256 KiB or 512 KiB of the Challenger's RAM, according to the unit's size. In 256 KiB units banks 4 to 7 map to empty sockets; the ROM detects the unit type by probing bank 4 for a response.
The control latch is a write-only register at &FCFC, laid out as follows:
Bit | Meaning |
---|---|
7..6 | Not used |
5 | Density select (0 = double density; 1 = single density) |
4 | Controller reset (0 = reset controller; 1 = enable controller) |
3 | Unit 2 select (0 = disable drives 6/7; 1 = enable) |
2 | Unit 1 select (0 = disable drives 1/3; 1 = enable) |
1 | Unit 0 select (0 = disable drives 0/2; 1 = enable) |
0 | Side select (0 = bottom/even drives; 1 = top/odd drives) |
At most one unit select bit may be set at any time.
An extension connector is provided inside the Challenger unit to connect another device to the 1 MHz bus. However, as the Challenger ROM generates a large number of dummy read cycles throughout page &FC, the device must be designed with care.
Slogger Computers advertised a Challenger 4 at the end of 1987 with up to 1024 KiB of memory fitted, but details of the device and its firmware are yet to be confirmed.
Firmware
The accompanying firmware, named Opus Challenger and latterly Slogger Challenger, branched from the Opus DDOS 3.45 codebase at approximately revision 3.0, in October 1985. Like DDOS it is thus a derivative of Acorn DFS.
The code has been extensively reworked to use only the Challenger unit's RAM
for workspace, leaving PAGE at &E00 in most cases. This entailed adding
support for a second address space to the data transfer platform inherited
from DDOS, so that sectors could be transferred either to user memory or
directly into the workspace. With over ¾ KiB of the ROM devoted to
paging the correct part of RAM into the JIM window, space was reclaimed by
removing Teletext decorations and the Tube hosting code, and by replacing
some *commands with *OPT
settings ported from Opus EDOS, where
they operate natively.
Conversely, the rudimentary RAM disc support in DDOS has been expanded with increasingly comprehensive floppy drive emulation via OSWORD &7F. Later versions eliminate the Can't extend error by transparently moving other files on the volume to make more room for a sequential file.
To ease the use of programs with hard-coded drive numbers, a
*CONFIG
facility maps six, later eight, logical drives to
either floppy or RAM disc as needed. A *MAP
command is added
to DDOS's *STAT
and *TAPEDISK
commands to aid file
and disc management.
Developments in the Challenger code were fed back into the DDOS branch, such as RLE disc formatting; and after the fork some bugs were still fixed in parallel.
Challenger does not comply with the conventions Acorn previously introduced for use of the 1 MHz Bus. The Advanced User Guide identifies location &EE as a RAM copy of the JIM paging register at &FCFF, which Challenger neither references or updates. The firmware assigns all pages in JIM to its own purposes, disregarding Acorn's reservation of the bottom 32 kilobytes. And as mentioned, volumes of spurious reads of FRED addresses will incite other hardware extensions to clear interrupts, mis-set latches or drop bytes of serial data.
Challenger 2.00
In 1987 Slogger Software, having acquired the Challenger product from Opus Supplies, produced and marketed a version of Acorn ADFS for use with the Master Series computers and the Challenger 3. It consists of Challenger 2.00 and the adapted ADFS in one 32 KiB ROM; the ADFS half of the ROM calls a private entry point in its DFS-compatible neighbour to perform disc access and other low-level functions. While ADFS also makes use of the Master's HAZEL memory and 65C12 instructions, Challenger 2.00 is assembled to stand alone on Master or Model B and use only the Challenger unit's RAM for workspace, as before.
Naturally, the new ADFS can employ the expanded RAM for mass storage in its own format: 512 KiB expansion units can host a single ADFS volume or two DFS volumes in mutual exclusion. To keep Challenger and ADFS from corrupting the other's RAM disc – and to prevent trouble from programs – Challenger maintains a 'density flag', set during formatting, which disables any access calls made in the opposite density. In this way the solid-state memory chips are made to act as either 'single density RAM' or 'double density RAM'!
A batch of prototypes retrieved from Slogger in 2009 included both titles on two 16 KiB chips as well as a 32 KiB twin pack and so, whether or not it was shipped separately, Challenger 2.00 runs happily on the Model B barring one mild bug introduced while catering to the presence of ADFS.
Development history
Features of the known releases of Challenger, along with those of related ROMs, are summarised in the following table:
Title | Version | Date | Description |
---|---|---|---|
DDOS | Conjectured prototype | 1983–4 | Has commands *4080 , *DENSITY , *CAT * (catalogue all volumes on drive), and Teletext graphics. OSGBPB 5 omits CSD drive number.
|
EDOS | 0.4 | 1984 | Coded to loose spec of DDOS prototype; Acorn implementation not adhered to. 2½ KiB less code. *CAT file list indented by one column instead of two, misinterpreting DDOS's Teletext display. Features an LBA layer on top of OSWORD &7F.
|
DDOS | 3.x5 rev. 0.2 | 1 Oct 1984 | Has *ROMID command. *XCAT replaces *CAT * . OSGBPB 5 returns CSD drive number.
|
DDOS | 3.x5 rev. 3.0 | 16 Oct 1985 | The current filename is initialised to all spaces. |
Challenger | 1.00 | 1985 | Branched from DDOS 3.45. Streamlined, but vestigial DDOS code remains. *CONFIG R and RLE formatting present, *CAT * reinstated. *OPT settings 6, 8, 9 ported from EDOS replace *4080 and *DENSITY . No Tube host. OSGBPB 5 omits CSD drive number again.
|
DDOS | 3.x6 | 1 Mar 1986 | OSBGET sets N and Z from A. Write protect test removed, write protect error reported separately from disc faults and not retried. |
Challenger | 1.01 | 1985 | Vestiges removed. 8 logical drives. "Can't extend" error eliminated. *FORMAT formats RAM discs.
|
Challenger | 1.03 | 1987 | OSWORD &7F writes to special register &1A correctly. Realistic Read ID emulation. |
Challenger | 2.00 | 1987 | Simplified graphics. Master system calls. ChADFS support. Name of Opus does not appear. |
DDCPM
Slogger[verify] released an edition of CP/M to run on a BBC Micro fitted with Challenger and a Z80 second processor. DDCPM discs were formatted in both densities with a DFS-compatible bootstrap segment at the start of drive 0 and the rest of the disc formatted in double density.
This release of CP/M was able to use the RAM discs in place of floppies.
See also
- Tom Seddon's disassembly of Challenger on GitHub
- Greg Cook's disassembly of Challenger 2.00 with commentary