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And adjust rc2014/eeprom recipe
231 lines
9.8 KiB
Markdown
231 lines
9.8 KiB
Markdown
# RC2014
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The [RC2014][rc2014] is a nice and minimal z80 system that has the advantage
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of being available in an assembly kit. Assembling it yourself involves quite a
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bit of soldering due to the bus system. However, one very nice upside of that
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bus system is that each component is isolated and simple.
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The machine used in this recipe is the "Classic" RC2014 with an 8k ROM module
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, 32k of RAM, a 7.3728Mhz clock and a serial I/O.
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The ROM module being supplied in the assembly kit is an EPROM, not EEPROM, so
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you can't install Collapse OS on it. You'll have to supply your own.
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There are many options around to boot arbitrary sources. What was used in this
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recipe was a AT28C64B EEPROM module. I chose it because it's compatible with
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the 8k ROM module which is very convenient. If you do the same, however, don't
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forget to set the A14 jumper to high because what is the A14 pin on the AT27
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ROM module is the WE pin on the AT28! Setting the jumper high will keep is
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disabled.
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## Related recipes
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This recipe is for installing a minimal Collapse OS system on the RC2014. There
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are other recipes related to the RC2014:
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* [Writing to a AT28 from Collapse OS](eeprom/README.md)
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* [Accessing a MicroSD card](sdcard/README.md)
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* [Self-hosting](selfhost/README.md)
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* [Interfacing a PS/2 keyboard](ps2/README.md)
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## Recipe
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The goal is to have the shell running and accessible through the Serial I/O.
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You'll need specialized tools to write data to the AT28 EEPROM. There seems to
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be many devices around made to write in flash and EEPROM modules, but being in
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a "understand everything" mindset, I [built my own][romwrite]. This is the
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device I use in this recipe.
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### Gathering parts
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* A "classic" RC2014 with Serial I/O
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* [Forth's stage 2 binary][stage2]
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* [romwrite][romwrite] and its specified dependencies
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* [GNU screen][screen]
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* A FTDI-to-TTL cable to connect to the Serial I/O module
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### Configure your build
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Modules used in this build are configured through the `conf.fs` file in this
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folder. There isn't much to configure, but it's there.
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### Build stage 1
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Self-bootstrapping is in Forth's DNA, which is really nice, but it makes
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cross-compiling a bit tricky. It's usually much easier to bootstrap a Forth
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from itself than trying to compile it from a foreign host.
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This makes us adopt a 2 stages strategy. A tiny core is built from a foreign
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host, and then we run that tiny core on the target machine and let it bootstrap
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itself, then write our full interpreter binary.
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We could have this recipe automate that 2 stage build process all automatically,
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but that would rob you of all your fun, right? Instead, we'll run that 2nd
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stage on the RC2014 itself!
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To build your stage 1, run `make` in this folder, this will yield `stage1.bin`.
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This will contain that tiny core and, appended to it, the Forth source code it
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needs to run to bootstrap itself. When it's finished bootstrapping, you will
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get a prompt to a full Forth interpreter.
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### Emulate
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The Collapse OS project includes a RC2014 emulator suitable for this image.
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You can invoke it with `make emul`. See `emul/hw/rc2014/README.md` for details.
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### Write to the ROM
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Plug your romwrite atmega328 to your computer and identify the tty bound to it.
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In my case (arduino uno), it's `/dev/ttyACM0`. Then:
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screen /dev/ttyACM0 9600
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CTRL-A + ":quit"
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cat rom.bin | pv -L 10 > /dev/ttyACM0
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See romwrite's README for details about these commands.
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Note that this method is slow and clunky, but before long, you won't be using
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it anymore. Writing to an EEPROM is much easier and faster from a RC2014
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running Collapse OS, so once you have that first Collapse OS ROM, you'll be
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much better equipped for further toying around (unless, of course, you already
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had tools to write to EEPROM. In which case, you'll be ignoring this section
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altogether).
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### Running
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Put the AT28 in the ROM module, don't forget to set the A14 jumper high, then
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power the thing up. Connect the FTDI-to-TTL cable to the Serial I/O module and
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identify the tty bound to it (in my case, `/dev/ttyUSB0`). Then:
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screen /dev/ttyUSB0 115200
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Press the reset button on the RC2014 to have Forth begin its bootstrap process.
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Note that it has to build more than half of itself from source. It takes about
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30 seconds to complete.
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Once bootstrapping is done you should see the Collapse OS prompt. That's a full
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Forth interpreter. You can have fun right now.
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However, that long boot time is kinda annoying. Moreover, that bootstrap code
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being in source form takes precious space from our 8K ROM. That brings us to
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building stage 2.
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### Building stage 2
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You're about to learn a lot about this platform and its self-bootstrapping
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nature, but its a bumpy ride. Grab something. Why not a beer?
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Our stage 1 prompt is the result of Forth's inner core interpreting the source
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code of the Full Forth, which was appended to the binary inner core in ROM.
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This results in a compiled dictionary, in RAM, at address 0x8000+system RAM.
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Wouldn't it be great if we could save that compiled binary in ROM and save the
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system the trouble of recompiling itself on boot?
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Unfortunately, this compiled dictionary isn't usable as-is. Offsets compiled in
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there are compiled based on a 0x8000-or-so base offset. What we need is a
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0xa00-or-so base offset, that is, something suitable to be appended to the boot
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binary, in ROM, in binary form.
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Fortunately, inside the compiled source is the contents of the Linker (B120)
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which will allow us to relink our compiled dictionary so that in can be
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relocated in ROM, next to our boot binary. I won't go into relinking details.
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Look at the source. For now, let's just use it:
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RLCORE
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That command will take the dict from `' H@` up to `CURRENT`, copy it in free
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memory and then relocate it. It will print 3 addresses during its processing.
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The first address is the top copied address. The process didn't touch memory
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above this point. The second address is the wordref of the last copied entry.
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The 3rd is the bottom address of the copied dict. When that last address is
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printed, the processing is over (because we don't have a `>` prompt, we don't
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have any other indicator that the process is over).
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### Assembling the stage 2 binary
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At that point, we have a fully relocated binary in memory. Depending on our
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situations, the next steps differ.
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* If we're on a RC2014 that has writing capabilities to permanent storage,
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we'll want to assemble that binary directly on the RC2014 and write it to
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permanent storage.
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* If we're on a RC2014 that doesn't have those capabilities, we'll want to dump
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memory on our modern environment using `/tools/memdump` and then assemble that
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binary there.
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* If we're in the emulator, we'll want to dump our memory using `CTRL+E` and
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then assemble our stage 2 binary from that dump.
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In these instructions, we assume an emulated environment. I'll use actual
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offsets of an actual assembling session, but these of course are only examples.
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It is very likely that these will not be the same offsets for you.
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So you've pressed `CTRL+E` and you have a `memdump` file. Open it with a hex
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editor (I like `hexedit`) to have a look around and to decide what we'll extract
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from that memdump. `RLCORE` already gave you important offsets (in my case,
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`9a3c`, `99f6` and `8d60`), but although the beginning of will always be the
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same (`8d60`), the end offset depends on the situation.
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If you look at data between `99f6` and `9a3c`, you'll see that this data is not
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100% dictionary entry material. Some of it is buffer data allocated at
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initialization. To locate the end of a word, look for `0042`, the address for
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`EXIT`. In my case, it's at `9a1a` and it's the end of the `INIT` word.
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Moreover, the `INIT` routine that is in there is not quite what we want,
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because it doesn't contain the `HERE` adjustment that we find in `pre.fs`.
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We'll want to exclude it from our binary, so let's go a bit further, at `99cf`,
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ending at `99de`.
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So, the end of our compiled dict is actually `99de`. Alright, let's extract it:
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dd if=memdump bs=1 skip=36192 count=3198 > dict.bin
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`36192` is `8d60` and `3198` is `99de-8d60`. This needs to be prepended by the
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boot binary. We already have `stage1.bin`, but this binary contains bootstrap
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source code we don't need any more. To strip it, we'll need to `dd` it out to
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`LATEST`, in my case `098b`:
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dd if=stage1.bin bs=1 count=2443 > s1pre.bin
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Now we can combine our binaries:
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cat s1pre.bin dict.bin > stage2.bin
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Is it ready to run yet? no. There are 3 adjustments we need to manually make
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using our hex editor.
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1. We need to link `H@` to the hook word of the boot binary. In my case, it's
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a matter of writing `02` at `08ec` and `00` at `08ed`, `H@`'s prev field.
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2. We need to end our binary with a hook word. It can have a zero-length name
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and the prev field needs to properly point to the previous wordref. In my
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case, that was `RLCORE` at offset `1559` for a `stage2.bin` size of `1568`,
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which means that I appended `0F 00 00` at the end of the file.
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3. Finally, we need to adjust `LATEST` which is at offset `08`. This needs to
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point to the last wordref of the file, which is equal to the length of
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`stage2.bin` because we've just added a hook word. This means that we write
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`6B` at offset `08` and `15` at offset `09`.
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Now are we ready yet? ALMOST! There's one last thing we need to do: add runtime
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source. In our case, because we have a compiled dict, the only source we need
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to include is initialization code. We've stripped it from our stage1 earlier,
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we need to re-add it.
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Look at `xcomp.fs`. You see that `," bla bla bla"` line? That's initialization
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code. Copy it to a file like `run.fs` (without the `,"`) and build your final
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binary:
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cat stage2.bin run.fs > stage2r.bin
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That's it! our binary is ready to run!
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../../emul/hw/rc2014/classic stage2r.bin
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And there you have it, a stage2 binary that you've assembled yourself.
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[rc2014]: https://rc2014.co.uk
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[romwrite]: https://github.com/hsoft/romwrite
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[stage2]: ../../emul
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[screen]: https://www.gnu.org/software/screen/
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