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mirror of https://github.com/hsoft/collapseos.git synced 2024-11-14 13:48:06 +11:00
collapseos/recipes/rc2014/avr.md
Virgil Dupras eafcb0c440 avrpgm: add EEPROM support
also, verify all 3 first bytes of SPI commands. I'm not sure why
I wasn't doing that, probably because I was getting a lot of AVR
err and thought that only 2 bytes of the cmd were echoed. But now,
with a reliable SPI setup, verifying 3 bytes seems to work.
2020-10-05 19:36:49 -04:00

2.9 KiB

Making an ATmega328P blink

Collapse OS has an AVR assembler and an AVR programmer. If you have a SPI relay as described in the SD card recipe, then you almost have all it takes to make an ATmega328P blink.

First, read doc/avr.txt. You'll see that it tells you how to build an AVR programmer that works with your SPI relay. You might already have such device. For example, I use the same device as the one I connect to my Sparkfun AVR Pocket Programmer, but I've added an on/off switch to it. I then use a 6-pin ribbon cable to connect it to my SPI relay.

If you have a SD card connected to the same SPI relay, you'll face a timing challenge: SD specs specifies that the minimum SPI clock is 100kHz, but depending on your setup, you might end up with an effective SCK below that. My own clock setup looks like this:

I have a RC2014 Dual clock which allows me to have easy access to many clock speeds, but the slowest option is 300kHz, not slow enough. My SPI relay has a pin for input clock override, and I built a pluggable 4040 with a switch that selects a divisor. I plug that module in my SPI relay, then I plug that into my RC2014 Dual clock. When doing SD card stuff, I select the "no division" position, and when I communicate with the AVR chip, I move the switch to increase the divisor.

Once you've done this, you can test that you can communicate with your AVR chip by doing 160 163 LOADR (turn off your programmer or else it might mess up the SPI bus and prevent you from using your SD card) and then running:

1 asp$ aspfl@ .x 0 (spie)

(Replace 1 by your SPI device ID) If everything works fine, you'll get the value of the low fuse of the chip.

A blink program for the ATmega328P in Collapse OS would look like this:

50 LOAD ( avra ) 65 66 LOADR ( atmega328p ) H@ ORG !
DDRB 5 SBI, PORTB 5 CBI,
R16 TCCR0B IN, R16 0x05 ORI, TCCR0B R16 OUT,
R1 CLR,
L1 LBL! ( loop )
    R16 TIFR0 IN,
    R16 0 ( TOV0 ) SBRS,
        L1 ( loop ) ' RJMP LBL, ( no overflow )
    R16 0x01 LDI, TIFR0 R16 OUT,
    R1 INC,
    PORTB 5 CBI,
    R1 7 SBRS,
        PORTB 5 SBI,
    L1 ( loop ) ' RJMP LBL,

See doc/asm.txt for details. For now, you'll paste this into an arbitrary unused block. Let's use 999.

$ cd recipes/rc2014
$ xsel > blk/999
$ rm blkfs
$ make
$ dd if=blkfs of=/dev/<your-sdcard> bs=1024

Now, with your updated SD card in your RC2014, let's assemble this binary:

999 LOAD
H@ CREATE end ,
CREATE wordcnt end ORG @ - 2 / ,
: write 1 asp$ asperase wordcnt 0 DO
ORG @ I 2 * + @ I aspfb! LOOP
0 aspfp! 0 (spie) ;
write

The first line assembles a 16 words binary beginning at ORG @, then the rest of the lines are about writing these 16 words to the AVR chip (see doc/avr.txt for details). After you've run this, if everything went well, that chip if it has a LED attached to PB5, will make that LED blink slowly.