The ATD Model M117 is an ancient memory expansion ISA card for IBM PC and compatibles, especially 8088-class systems. The M117 can expand a system with up to 384kB of 4164-type and 41256-type DRAM, and the address ranges that the card decodes is configurable using 4 DIP switches. Most of the card's intelligence is inside a PAL16L8, whose behavior is configured using 3 of the 4 DIP switches. This is the main reason the card is rather small.
Picture of my fully-populated ATD M117 card. The PAL is the 20 pin
socketed chip in the center-right. None of the chips were originally
socketed; it took me several tries to find the bad chip :)!
For the longest time, my M117 was broken, and I was not able to figure out why thanks to not knowing the correct switch settings, which I changed from working settings long ago. If the switch settings are on TH99, I was unable to find them. I knew from when I got the card that it supported at least 384kB of RAM, but 3 banks of 9 DRAM chips each implies that at least one bank will have 256kB 41256-type DRAM. Not only did I never knew the switch settings, I forgot long ago which bank(s) should house the 41256 DRAM :).
I thought trying to fix the card would be a good learning experience, so I RE'd a schematic to figure out the PAL connections (thank goodness for continuity testers!), and then wrote some gateware to dump the PAL. Using some shell scripts and a text editor, I looked for patterns in the PAL for all eight possible switch settings. And finally, I was able to determine what each switch setting does :D!
Though I have my doubts, I have uploaded my schematic and switch REing results here, in the hopes it is useful to someone else. I had fun and willingly did this project, but I wouldn't want someone else to be in my position.
Although the main purpose of this repo is documentation, I have uploaded the source to my FPGA tools I created for the iCEBreaker to this repo as well for reference. The tools are written using the Amaranth HDL language. All of these tools are one-offs, using Amaranth as sort of a scripting language for fast turnaround. They are not in any way optimized for general usage, and- at least for now- you use them at your own risk.
Each tool uses the iCEBreaker's UART and PMOD, and 5V ports to connect to a breadboard and test/dump a 5V-powered TTL chip. I feed inputs from the iCEBreaker directly to the chips, since 3.3V is a legal TTL voltage, and I use TXS0108E breakout boards to connect outputs and/or bidirectional signals to the iCEBreaker.
I wrote paldump very quickly to dump the PAL16L8 contents, after I knew
which each pin did as well as the directions for pins which can either be
inputs or outputs.
paldump will dump the raw contents of the PAL's "data" over the UART in order
from "address" 0 to 2047. I define each input pin as an "address" bit, and each
output pin as a "data" bit using the below table. The table also shows how to
connect each iCEbreaker pin to the PAL. PAL signals are described in signals.md.
Pin Directions are from the POV of the PAL; make sure all PAL output pins are
level shifted down to 3.3V. A level shifter OE signal is provided in the
table as well:
| Signal Name | Pin Direction | iCEBreaker Connection | PAL Pin | Address Bit | Data Bit |
|---|---|---|---|---|---|
| 5V | PWR | +5V | 20 | N/A | N/A |
| GND | PWR | GND | 10 | N/A | N/A |
| SW 1 | I | PMOD1A 1 | 1 | A0 | N/A |
| SW 2 | I | PMOD1A 2 | 2 | A1 | N/A |
| SW 3 | I | PMOD1A 3 | 3 | A2 | N/A |
| A16 | I | PMOD1A 4 | 4 | A3 | N/A |
| A17 | I | PMOD1A 7 | 5 | A4 | N/A |
| A18 | I | PMOD1A 8 | 6 | A5 | N/A |
| A19 | I | PMOD1A 9 | 7 | A6 | N/A |
| Delayed /SMEM{R,W} | I | PMOD1A 10 | 8 | A7 | N/A |
| /REFRESH | I | PMOD1B 1 | 9 | A8 | N/A |
| /SMEMW | I | PMOD1B 2 | 18 | A9 | N/A |
| /SMEMR | I | PMOD1B 3 | 11 | A10 | N/A |
| /WE All Banks | O | PMOD2 1 | 19 | N/A | D0 |
| /RAS All Banks | O | PMOD2 2 | 17 | N/A | D1 |
| Data Bus Direction | O | PMOD2 3 | 16 | N/A | D2 |
| /CAS Bank 1 | O | PMOD2 4 | 15 | N/A | D3 |
| /CAS Bank 2 | O | PMOD2 7 | 14 | N/A | D4 |
| /CAS Bank 3 | O | PMOD2 8 | 13 | N/A | D5 |
| DRAM A8 All Banks | O | PMOD2 9 | 12 | N/A | D6 |
| Level Shifter OE | I | PMOD2 10 | N/A | N/A | N/A |
Once amaranth
and pyserial
are installed, you have to build the bitstream and upload it to your iCEBreaker.
I suggest building and uploading this gateware before wiring up connections to
avoid input/output conflicts on the PMODs.
- Run
python3 -m PALdump bitstream. After several seconds, this command will upload the PAL dumping gateware to your iCEBreaker. - Wire up your PAL extracted from your M117 to your iCEBreaker, including a level shifter for the PAL outputs.
- Run e.g.
python3 -m PALdump client COM10 ATD.txtorpython3 -m PALdump client --csv COM10 ATD.csvand follow the directions at the prompt; the reset button is "UBUTTON". Modify your serial port name as appropriate. - Your dumped PAL will be available in
ATD.txtorATD.csvif both dumps matched..txtand.csvoutputs are what were useful to me at the time. Perhaps in the future, I'll add PAL fusemaps or.jedoutput.
Even when I knew the correct switch settings, the card still didn't work. So I used my logic analyzer to confirm that the signals the DRAM were receiving were reasonable. It turns out one of the row/column address muxes- a 74LS158- had a bit stuck high. While I manually tested the 74LS158 to confirm it was dead, it got me motivated to write some gateware to automate testing certain TTL chips. This code was written after-the-fact, using good and bad chip samples I have, and is not ready yet.