collapseos/recipes/rc2014/eeprom/README.md

# Writing to a AT28 from Collapse OS

## Goal

Write in an AT28 EEPROM from within Collapse OS so that you can have it update
itself.

## Gathering parts

* A RC2014 Classic
* An extra AT28C64B
* 1x 40106 inverter gates
* Proto board, RC2014 header pins, wires, IC sockets, etc.

## Building the EEPROM holder

The AT28 is SRAM compatible so you could use a RAM module for it. However,
there is only one RAM module with the Classic version of the RC2014 and we
need it to run Collapse OS.

You could probably use the 64K RAM module for this purpose, but I don't have one
and I haven't tried it. For this recipe, I built my own module which is the same
as the regular ROM module but with `WR` wired and geared for address range
`0x2000-0x3fff`.

If you're tempted by the idea of hacking your existing RC2014 ROM module by
wiring `WR` and write directly to the range `0x0000-0x1fff` while running it,
be aware that it's not that easy. I was also tempted by this idea, tried it,
but on bootup, it seems that some random `WR` triggers happen and it corrupts
the EEPROM contents. Theoretically, we could go around that by putting the AT28
in write protection mode, but I preferred building my own module.

I don't think you need a schematic. It's really simple.

### Building the binary

You build the binary by modifying the base recipe's `xcomp` unit. This binary
is missing 2 things: Addressed devices and the AT28 Driver.

Addressed devices are at B140. If you read that block, you'll see that it tells
you to load block 142. Open the `xcomp` unit and locate the ACIA driver loading
line. Insert your new load line after that one.

Do the same thing with the AT28 driver (B590)

You also have to modify the initialization sequence at the end of the `xcomp`
unit to include `ADEV$`.

Build again, write `os.com` to EEPROM.

## Writing contents to the AT28

The driver provides `AT28!` which can be plugged in adev's `A!*`.

First, upload your binary to some place in memory, for example `a000`. To do so,
run this from your modern computer:

    ./upload <tty device> a000 <filename>

Then, activate `AT28!` with `' AT28! A!* !` and then run
`0xa000 0x2000 <size-of-bin> AMOVE`. `AT28!` checks every myte for integrity,
so it there's no error, you should be fine. Your content is now on the EEPROM!

Why not upload content directly to `0x2000` after having activated `AT28!`?
Technically, you could. It was my first idea too. However, at the time of this
writing, I always get weird mismatch errors about halfway through. Maybe that
the ACIA interrupt does something wrong...
Add at28w app and recipe This allows us to write to an AT28 EEPROM from within collapse os. 2019-06-15 04:15:30 +10:00			`# Writing to a AT28 from Collapse OS`

			`## Goal`

			`Write in an AT28 EEPROM from within Collapse OS so that you can have it update`
			`itself.`

			`## Gathering parts`

rc2014: complete the EEPROM recipe 2020-04-14 04:41:02 +10:00			`* A RC2014 Classic`
Add at28w app and recipe This allows us to write to an AT28 EEPROM from within collapse os. 2019-06-15 04:15:30 +10:00			`* An extra AT28C64B`
			`* 1x 40106 inverter gates`
			`* Proto board, RC2014 header pins, wires, IC sockets, etc.`

			`## Building the EEPROM holder`

			`The AT28 is SRAM compatible so you could use a RAM module for it. However,`
			`there is only one RAM module with the Classic version of the RC2014 and we`
			`need it to run Collapse OS.`

			`You could probably use the 64K RAM module for this purpose, but I don't have one`
			`and I haven't tried it. For this recipe, I built my own module which is the same`
			as the regular ROM module but with `WR` wired and geared for address range
			`0x2000-0x3fff`.

			`If you're tempted by the idea of hacking your existing RC2014 ROM module by`
			wiring `WR` and write directly to the range `0x0000-0x1fff` while running it,
			`be aware that it's not that easy. I was also tempted by this idea, tried it,`
			but on bootup, it seems that some random `WR` triggers happen and it corrupts
doc: minor improvements 2019-11-05 06:45:10 +11:00			`the EEPROM contents. Theoretically, we could go around that by putting the AT28`
Add at28w app and recipe This allows us to write to an AT28 EEPROM from within collapse os. 2019-06-15 04:15:30 +10:00			`in write protection mode, but I preferred building my own module.`

			`I don't think you need a schematic. It's really simple.`

rc2014: adapt recipe to single stage xcomp It's now much easier... 2020-05-15 01:32:51 +10:00			`### Building the binary`
Add at28w app and recipe This allows us to write to an AT28 EEPROM from within collapse os. 2019-06-15 04:15:30 +10:00
rc2014: adapt recipe to single stage xcomp It's now much easier... 2020-05-15 01:32:51 +10:00			You build the binary by modifying the base recipe's `xcomp` unit. This binary
			`is missing 2 things: Addressed devices and the AT28 Driver.`
recipes/rc2014: include readln directly in stage 1 XPACK is more efficient than stripfc was, we can pack more stuff in 8K. We now have enough space to fit readln. 2020-04-27 04:52:55 +10:00
rc2014: adapt recipe to single stage xcomp It's now much easier... 2020-05-15 01:32:51 +10:00			`Addressed devices are at B140. If you read that block, you'll see that it tells`
			you to load block 142. Open the `xcomp` unit and locate the ACIA driver loading
			`line. Insert your new load line after that one.`
recipes/rc2014: include readln directly in stage 1 XPACK is more efficient than stripfc was, we can pack more stuff in 8K. We now have enough space to fit readln. 2020-04-27 04:52:55 +10:00
Gather all RC2014 drivers into a single "RC2014 Recipe section" 2020-05-14 04:56:38 +10:00			`Do the same thing with the AT28 driver (B590)`
recipes/rc2014: include readln directly in stage 1 XPACK is more efficient than stripfc was, we can pack more stuff in 8K. We now have enough space to fit readln. 2020-04-27 04:52:55 +10:00
rc2014: adapt recipe to single stage xcomp It's now much easier... 2020-05-15 01:32:51 +10:00			You also have to modify the initialization sequence at the end of the `xcomp`
			unit to include `ADEV$`.
recipes/rc2014: include readln directly in stage 1 XPACK is more efficient than stripfc was, we can pack more stuff in 8K. We now have enough space to fit readln. 2020-04-27 04:52:55 +10:00
rc2014: adapt recipe to single stage xcomp It's now much easier... 2020-05-15 01:32:51 +10:00			Build again, write `os.com` to EEPROM.
Add at28w app and recipe This allows us to write to an AT28 EEPROM from within collapse os. 2019-06-15 04:15:30 +10:00
			`## Writing contents to the AT28`

rc2014: complete the EEPROM recipe 2020-04-14 04:41:02 +10:00			The driver provides `AT28!` which can be plugged in adev's `A!*`.
Add at28w app and recipe This allows us to write to an AT28 EEPROM from within collapse os. 2019-06-15 04:15:30 +10:00
recipes/rc2014/sdcard: now works under Forth! 2020-04-20 06:56:37 +10:00			First, upload your binary to some place in memory, for example `a000`. To do so,
rc2014: complete the EEPROM recipe 2020-04-14 04:41:02 +10:00			`run this from your modern computer:`
Add at28w app and recipe This allows us to write to an AT28 EEPROM from within collapse os. 2019-06-15 04:15:30 +10:00
rc2014: complete the EEPROM recipe 2020-04-14 04:41:02 +10:00			`./upload <tty device> a000 <filename>`
Add at28w app and recipe This allows us to write to an AT28 EEPROM from within collapse os. 2019-06-15 04:15:30 +10:00
rc2014: complete the EEPROM recipe 2020-04-14 04:41:02 +10:00			Then, activate `AT28!` with `' AT28! A!* !` and then run
			`0xa000 0x2000 <size-of-bin> AMOVE`. `AT28!` checks every myte for integrity,
			`so it there's no error, you should be fine. Your content is now on the EEPROM!`
Add at28w app and recipe This allows us to write to an AT28 EEPROM from within collapse os. 2019-06-15 04:15:30 +10:00
rc2014: complete the EEPROM recipe 2020-04-14 04:41:02 +10:00			Why not upload content directly to `0x2000` after having activated `AT28!`?
			`Technically, you could. It was my first idea too. However, at the time of this`
			`writing, I always get weird mismatch errors about halfway through. Maybe that`
			`the ACIA interrupt does something wrong...`