Monday, May 25, 2026

"VDC Hires," or "If you want to program a Commodore right, do it yourself, because AI is not your friend"

AI: What could go wrong?🤔

Don't get me wrong. I love AI. I also hate AI. It's been great to me for writing C# utilities for work, or SQL queries, reviewing code, writing scripts in languages I don't even know (LUA) -- yeah that looks right, let's put that in production.

But for Commodore? Spoilers -- it's really horrible. I'll get back to that later.

My "fun" task for the day? I want to finally program high resolution graphics on my C128 VDC 80 column screen. It's well capable of 80x25. And I bought my C128D with 64K RAM specifically knowing it could do that high resolution graphics well. The original only came with 16K, and when it arrived COD at my door in 1987, I refused it and sent it back because of 11th hour nearly buyers remorse, delaying my gratification to wait a few more weeks for the newer C128D to arrive with more RAM.

The C64 could only do 320x200 graphics because it's a 40 column machine. The C128 had 80 columns and thus twice the resolution because it included two graphics chips and had two separate video outputs. BASIC 7.0 finally supported 320x200, but not graphics specific to the 80 column chip. I even purchased GEOS 128 with mouse and 1750 memory expansion, and saw the fulfillment of 640x200 graphics.

But was I fulfilled? No.

I am a programmer. Features don't exist until I code the programs that make them exist. I enjoy the process of learning APIs and languages, and developing new skills.

Later in 1988 I investigated the VDC (C128's 80 column video display controller) closer, with the guide of some magazine articles, and close scrutiny of the Commodore 128 Programmer's Guide which had a mere 4 pages of a minimalistic datasheet. I remember wanting to know how to do it. But as far as I got with changing and programming the VDC registers was a 40 column mode, and an 80x50 interlaced text mode. The former was released as RGB64, and the later was released as node-m (a unique terminal program). Graphics abilities unique to the C128 were not accomplished by me. Not in the 80s.

Now it's nearly 40 years later. VDC graphics programming is still a challenge I want to conquer. It's 2026, in the golden age of AI, technical assistants available at our fingertips.

Could AI provide me a working sample? No. I went round and round with it for hours. Gave up, and came back another weekend day for hours. Did it work? No. Was I close? Maybe.

One web link from AI gave a hint though. The reference was Commodore 128 Programming Secrets. The sample program on page 274, Figure 5-4, was short, just 25 lines, and didn't look very complicated. Obviously this was a joke, you can't achieve such a lofty goal as complicated VDC graphics in just 25 lines. There weren't even very many VDC register writes. But I typed it in, and once I figured out some decent parameters to feed it at runtime (10, -10, 1, -1), the results were presented on screen.

Commodore 128 Programming Secrets
640x200 monochrome graphics sample

But how could this be? All that I learned researching with AI taught me it was so much more complicated than this. Then I reviewed the code, and my assumptions, and the paths AI had taken me down had to be set aside.

The algorithm in a nutshell is

Initialize raster graphics mode, giving up text screen, attributes, and character images
Write to screen memory as bytes going across, then down. First and high bits are on the left, last and low bits are on the right. In other words, use math.
Follow VDC register rules. And use block fill feature for speed.

I already knew the rules. Well, I did in 1988. And I've learned and relearned them over the years as I've dabbled in VDC programming. Nothing too special, but enough to know the basics. But there is the trappings too. And when you don't use something every day it's easy to forget even the basics. So let's write down the rules here so we all can refer back to them someday.

VDC rules

Access to VDC is through two C128 memory-mapped locations:

D600 is generally used to store a register number (and read status)
D601 is used to store a register value

VDC is controlled through its registers.
Access to VDC RAM (16K or 64) is only through the registers as well.
Want to write to a register? Store the register index in D600, then wait for the high bit to be set on D600 before storing the desired value in D601.
Want to read a register? store the register index in D600, then wait for the high bit to be set on D600 before reading the value from D601.
Want to write to memory? At some point you have to set the address using registers 18, 19. After that you can set the value in register 31.
For a block fill, you must write one memory value first, then you can write a count of the remaining slots you also want to fill. If you want to store 100 bytes total, you store 99 here.
Values in registers 18 (high), 19 (low) auto-increment, so either reading or writing various values to consecutive bytes doesn't require rewriting the address. But reading from the address, and writing back to it will require rewriting the address, otherwise it has jumped forward by one.
Screen memory is pointed to by registers 12, 13.
Attribute memory is pointed to by registers 20, 21.
Character images is pointed to by register 28 (high 3 bits). Shift those bits down and multiply by $2000 to get the VDC RAM address, or in reverse shift up.
VDC defaults to 16K RAM operation. 64K mode will scramble how the data is addressed, so would require reinitializing the screen, attributes, and characters.
Graphics mode (bit 7 of register 25) means that the VDC will render to the monitor line and byte by byte or bit by bit from screen memory.
640x200 monochrome requires 16000 bytes, so not enough left for screen, attributes, characters.
Other graphic modes are possible including using attributes for choosing different colors for cells, and even changing the dimensions of the cell (allows for more color changes). I'm not versed in this yet.
There are plenty of registers you should not change unless you understand them well, or are willing to take a risk.
C128D includes 8568 chip with the addition of an IRQ line when command completed (not wired to anything), and Sync Polarity options in a new register 37.
Attributes are different than C64 color memory. These are whole bytes! The lower 4 bits are RGBI (red/green/blue/intensity). The upper 4 bits are (character set, reverse, underline, and blink). The character set bit option lets you have 512 different characters on screen at any one time. And the reverse bit is useful for game developer, but not necessary for the Commodore character sets as they already have reverse in their latter half of their sets.
Attributes are optional. See AttrEnable bit 6 in register 25 for turning it off (0).

Tricks

BANK 15 (shown as the first F digit below in the monitor listing) is the default bank when C128 starts up. This memory map has access to I/O and KERNAL ROM.
C128 KERNAL already has routines for writing/reading to/from the VDC registers. These can be leveraged from BASIC as needed, especially useful for prototyping.
SYS DEC("CDDA"),,R : RREG V : REM Read VDC Register
SYS DEC("CDCC"),V,R : REM Write VDC register
C128 KERNAL has a routine to reset character images in the VDC RAM. JSR FF62. (Thanks AI for that tidbit scraped off the web.)
SCNCLR is a good way to reset screen and attribute memory. Similar to GRAPHIC 5,1 and PRINT CHR$(147).

. fcdca  a2 1f    ldx #$1f
. fcdcc  8e 00 d6 stx $d600
. fcdcf  2c 00 d6 bit $d600
. fcdd2  10 fb    bpl $cdcf
. fcdd4  8d 01 d6 sta $d601
. fcdd7  60       rts

. fcdd8  a2 1f    ldx #$1f
. fcdda  8e 00 d6 stx $d600
. fcddd  2c 00 d6 bit $d600
. fcde0  10 fb    bpl $cddd
. fcde2  ad 01 d6 lda $d601
. fcde5  60       rts

Arguing with AI

I got fed up with AI. Mostly because it didn't work just vibe coding. I kept delivering results from programs, and they still wouldn't work. But I also argued.

I had to explain I didn't have BASIC 8.0, only 7.0
Explaining GRAPHIC 5 doesn't actually have anything to do with graphics
No, the processor doesn't have direct access to VDC RAM
Variable names cannot have underscores
Variable names must be two letters at most to differentiate from each other
Spaces are not required between keywords and variable names
Just arguing about nonsense that the AI had completely backwards.
AI putting in comments REM Completely Fixed Version
Explaining the right way of doing things, and AI insisting it was right instead
Explaining the right way of doing things, and AI treating me as I had led it astray in the first place, that it was my fault
No you can't prompt for values on the same screen trying to draw graphics. But you can use the 40 column screen simultaneously using GRAPHIC 0
No, that order of code is correct, if we change it, it will fail worse
Telling me there are two bugs, then listing three bugs
Outright hallucinations

So maybe it's a little unfair. These AIs have been around for a short time, and modern programming is a lot different than Commodore 128 programming. And there are so many options with the VDC, many not quite documented, more trial and error, through experience, not examples. With folks talking about the various options, AI can get these intertwined and mixed up.

Now that we know the answer, can we assist AI in providing us a working answer? I have a collection of AIs available to me. Let's try a simple prompt, and a complex prompt, and turn up the thinking as high as we can go.

Short prompt

Please provide me a Commodore 128 BASIC 7.0 working example of drawing a circle on the VDC 640x200 display in monochrome bitmapped mode using any facilities in a stock C128 available. Please provide a BASIC listing output in lowercase text only that will be accepted by a Commodore 128.

LLMs tested:

Qwen2.5-Coder 14B

gpt5-mini (High)

Windows 11 Copilot

Gemini

OpenAI 5.3-Codex (High)

Claude Sonnet 4.6 (Adaptive)

AI results

Out of the gate, Qwen2.5-Coder 14B, running on my own GPU mind you, produced remarks in uppercase, thought that simple pokes to addresses based on the coordinates would hit video memory, but worst of all used bit shifting ala C which is not present in Commodore BASIC 7.0. Also the while/wend loop should have been do while ... loop.

110 d = 3 - (radius << 1)

120 rem draw circle using Bresenham's algorithm
130 while x <= y

140 rem plot eight points of the circle
150 poke cx + x, cy + y : poke cx - x, cy + y

Actually Codex got the closest... it followed directions, produced a valid program free of syntax errors, it runs, and while it fails to clear the screen, an oval shape does appear.

5.3-Codex (High) result

I should have started and stayed with Codex a bit longer. I could have worked from this sample, fixing clearing the screen, and changing the aspect ratio of the circle would have been challenges I could have worked through. Looking back at my history I had started with it, and it had failed for me though, and led me down some more complicated paths.

In contrast, Windows 11 CoPilot produced a version with syntax errors. It didn't quite understand the syntax of Commodore BASIC 7.0. That's not how functions work, and you don't assign a value to a sys command.

30 def fnw(v,r):bank15:sys52684=0:rem placeholder

Gemini produced this listing:

10 graphic 5,1
20 color 0,2,1
30 circle 1,320,100,60,60
40 getkey a$
50 graphic 0,1

Resulting in the following, because CIRCLE doesn't work in 80 column mode, because it's a text mode, not a graphics mode. No GRAPHIC command will put you in a graphics mode using VDC.

?NO GRAPHICS AREA ERROR IN 30

Claude Sonnet 4.6 (Adaptive) thought for 19m 2s and I reached my 5 hour limit before being prompted to upgrade to a paid plan. That was a lot of thinking! I'm not upgrading to program an 8-bit computer. Wake up the next morning, hit continue, and immediately it produces a similar program like Gemini did. Similar error resulted, this time in line 40. Nice, line 50 draws on the text screen. But line 60 thinks inkey$ does something... it stays empty forever. Sonnet, if you were taking notes from Gemini, you should have copied it's line 40 instead. And switching to the 40 column screen was unnecessary. The other commands are nice though, but no circle produced.

10 graphic 5,1
20 color 0,1
30 color 1,2
40 circle 1,320,100,80,80
50 char 1,1,23,"press any key to exit"
60 do : loop until inkey$<>""
70 graphic 0,1
80 end

gpt5-mini (High) keeps prompting in Visual Studio Code for browsing web pages and is stuck on thinking Commodore has vpeek/vpoke, and because of Graphic command in BASIC 7.0, it must have commands for VDC, but it keeps looking and looking... after about 8 prompts to browse web pages I'm stopping it, it just keeps looking at general programming html sites (and one PDF).

My solution (disclaimer: Claude did earlier find a logic error in my code that fixed a problem I was having, turned into one of my rules for VDC about register reads auto advancing the memory pointer, and having to reset it to write a changed value). So reviewing code worked out, but generating it not so much. My own developed solution is attached:

No AI generated code here, but was AI reviewed

100 rem-----------------------------------------------------------------------
110 rem vdc 640x200 monochrome
120 rem copyright (c) 2026 by david r. van wagner
130 rem mit license
140 rem
150 rem davevw.com
160 rem github.com/davevw
170 rem mit license
180 rem-----------------------------------------------------------------------
190 def fnac(x)=2*atn(sqr(1-x*x)/(1+x))
200 trap 900
210 graphic5,1:fast
220 for i=1 to 21:print chr$(17);:next
230 data 1,2,4,8,16,32,64,128:dimbi(7):fori=0to7:readbi(i):next
240 print"screen";:r=12:gosub 1040:gosub 1050:sc=ad
250 print"attrs ";:r=20:gosub 1040:gosub 1050:at=ad
260 print"chars ";:r=28:gosub 1000:ad=int(v/32)*8192:gosub1050:cr=ad
270 for i=1 to 1000:next:scnclr
280 r=25:gosub 1000:v=v and (255-64) or 128:gosub 1010
290 ad=sc:gosub1060:wait dec("d600"),128:f=0:c=16000:gosub 1070
300 for x=0 to 639:a=fnac((x-320)/321):y=int(99*sin(a)+100):gosub1080
310 y=199-y:gosub 1080:next x
320 getkey a$
900 r=25:gosub 1000:v=v and 127 or 64:gosub 1010:sys dec("ff62"):scnclr
910 if er<>-1 then print err$(err)" at line "el
999 end:rem ******* reusable subroutines *******
1000 sys(dec("cdda")),,r:rreg v:return:rem ** read vdc reg r into v **
1010 sys(dec("cdcc")),v,r:return:rem ** write vdc reg r value v **
1020 sys(dec("cdcf")),v:return:rem ** write next byte **
1030 sys(dec("cddd")):rreg v:return:rem ** read next byte **
1040 gosub 1000:ad=v*256:r=r+1:gosub 1000:ad=ad+v:return:rem ** get address **
1050 printusing" ##";r-1;:printusing" ##";r;:printusing" #####";ad:return:****
1060 r=18:v=ad/256:gosub1010:r=19:v=adand255:gosub1010:return:rem *update addr*
1070 i=0:do while i<c:rem ** block fill (begin) **
1071 r=31:v=f:gosub 1010
1072 v=c-i-1:if v>0 then begin
1073 :ifv>255thenv=255
1074 :r=30:gosub1010
1075 bend
1076 i=i+v+1
1077 wait dec("d600"),128
1078 loop
1079 return:rem ** block fill (end) **
1080 ad=sc+int(y)*80+int(x/8):gosub1060:rem ** plot (begin) **
1081 r=31:gosub1000:n=v or bi(7-(xand7)):gosub1060:r=31:v=n:gosub1010
1082 return:rem ** plot (end) **

Granted, this is more of an oval. I was going for a large oval on all of the screen: 319 radius on the x axis, and 99 radius on the y axis. The arc cosine is my attempt at a more intact circle.

Conclusion

I will continue to use AI for certain things, but Commodore vibe coding is not there yet for my needs when I don't have the answers. AI and myself went down a long path of unknowns, assumptions, inaccuracies, and under/over-complexities. What ended up working was digging in for myself, trying little things, and lots of credit goes to Commodore 128 Programming Secrets as it produced a sample program that did the job.

The elusive detail was that when turning on bitmap mode in the VDC, screen memory (not character memory) is where the raster data goes. And with an original 16K RAM attached to VDC, there's no room for attributes, so disable them. How would an AI know this?

Noted, I may have tricked the AIs, by not giving them all the detail they needed, especially that VDC graphics primitives are not present in Commodore 128 ROMs and BASIC commands. And some of my earlier AI prompts dived right into 64K options that overcomplicated the situation.

I could update the prompts to guide AI closer to the answers, now that I know the answers, but what's the point? I didn't have all the answers, so I was searching. I should have probably stuck with web searches rather than trust AI to solely come up with the answer.

You have to be pretty smart to use AI effectively. I may have failed myself this round using AI. Throwing too much faith into AI is also a mistake.

Remember there are no guarantees. So try to have fun on the journey, learning, even when some paths lead to failure. But in the end, don't give up. There are other paths and you may find them next time. Don't give up on programming/researching yourself, and don't give up on AI as its capabilities are remarkable. Learn new things, learn new ways of doing things, and next time might be better and more efficient solution.

Saturday, May 23, 2026

Cardputer Game Station now has support for BLE controllers

The whole reason for my latest projects was to integrate and use controllers with Cardputer Game Station. It supports emulation of some of my favorite consoles and thus their games.

Link: https://github.com/davervw/Cardputer-Game-Station-Emulators

Firmware is also posted on M5Stack M5Burner

Atari 2600
Atari 7800
GameBoy
GameBoy Color
NES

I have some of the original consoles myself and a collection of games. I enjoy playing these on the go!

D-pad support is implemented, so use the d-pad on the Xbox controller. Set your controller to pairing, and this version of Cardputer Game Station should pair with it. Also works with other BLE (not Classic Bluetooth though) controllers. I also have a cute little BLE controller I bought from AliExpress for cheap.

Note: Classic Bluetooth is not supported by ESP32-S3. The newer ESP32's that have Bluetooth only do BLE.

Sunday, May 17, 2026

Gamepad Test

My goal is to play some games on ESP32 hardware. One step to get there is create a test app to pair with existing game controllers.

Classic (not the newest) ESP32 boards support Bluetooth Classic and BLE. ESP32-S3, C3, C6 for examples only support BLE. ESP32-P4 doesn't support wireless directly at all, it uses a C6 as a wireless coprocessor. Thus it's useful to see what controllers you can attach.

Instructions:

Auto binds to pairing device
gampad activity shows here
and see serial monitoring
for more devices & info

Also see: m5_minijoystickc_gamepad

BLE HID Gamepad firmware for M5Stack MiniJoyC

It's not just another pretty face. Time to get serious about retro gaming.

Up, Left, Right, Down, Fire (M5) and second button (click joystick). Not just a d-pad. Is also mirrored as xpot, ypot, so can do paddle games, or analog joystick games.

Go play some games!

Link: github.com/davervw/m5_minijoystickc_gamepad

Also posted on M5Stack M5Burner

Sunday, May 10, 2026

Palm Portable Keyboard for my custom Commodore Emulators

It's finally here! After years of anticipation and a weird workaround, the ideal solution is implemented and working. I can finally use my Palm Portable Keyboard (PPK) with my custom emulators for Commodore 8-bits. Github: ppk_bluetooth_for_cbm

PPK BLE adapter for wearable/portable emulators of 8-bit CBM systems

History

The Palm Portable Keyboard was released for the Palm Pilot PDA lineup in late 1999. I remember getting mine right away for US$99 from Circuit City. The Palm IIIc came out in early 2000 and got one of those too. To date my longest use was to write up notes on a plane ride. (Let's just not think too much about me leaving/losing the keyboard in the seatback pocket. Ouch! Rushed out and got a replacement at $99.) Back in the day, it was mostly for the cool factor. I loved gadgets, and between the Palm III color and the keyboard, and the Kodak color camera, I had some pretty cool gadgets. I knew I was cool, even if no one else believed.

Fast forward to 2020 when I'm enjoying building emulators for Commodore 64, 128, and Vic-20 on wearable and portable platforms based on ESP32 and similar. One real need was to input into these devices. With the STM32F4 I had gotten USB-OTG to work, and mapped a standard USB keyboard to trick the Commodore into thinking a normal matrix keyboard was present. The Teensy 4.1 target was a direct port of that keyboard code as it had an optional external USB host port. Also worth a mention of leveraging the same algorithms and data to support keyboard mapping with my Typescript port.

STM32F4 with USG OTG

Teensy 4.1 with keyboard cord off top of photo

Once I had a wearable emulator on my wrist, I also looked for keyboard solutions. On one July 4th holiday vacation I was able to research and implement a web page helper that translated keystrokes in the keyboard and sent them as Commodore scan codes over USB serial to the emulated system. And I also found a way to leverage this on my Android phone so it would host the web page and transmit over its USB serial (OTG) to the emulated target host.

Wires and phone required in 2023

More development later, and I had an adapter for a real Commodore keyboard to serial TX line (plus 5V/GND input), that could plug into the Grove connector of the M5Stack targets. Sure it was fun to plug in a real C128D keyboard into a system with a 2" LCD; quite the show off I am, looking for a good laugh. But it also worked!

More work (and purchases) later and I had M5Stack's CardKB keyboard, and wrote drivers for that to convert to scan code presses and releases for Commodore.

And then I created a Bluetooth (BLE) adapter to convert serial/I2C connections to a wireless connection. The keyboard and the wrist emulator could be used with direct wiring. Much to the delight of portability and more showing off.

External Commodore Keyboard Scan Code Protocol

Out of necessity, a standardized protocol was born by accident. Standardized to my implementations only so far, but I was for sure the beneficiary of such technological advance.

The protocol depends on two features:

1. Serial transmission of changes

2. List of Commodore 64/128 scan code values, comma separated, newline (serial only) terminated

Example:

15,7

which means left shift and up/dn key (= cursor up)

The emulators targets (see Unified branch of github.com/davervw/c-simple-emu6502-cbm) support this protocol over USB serial, Grove port (UART RX), and custom BLE service depending on hardware capabilities. Internally the list of scan codes is used to provide feedback from I/O read/write processing from the 6502 checking to see what lines are connected. So while I could have implemented a more binary or compact format of transmitting this data, I enjoy the diagnostic capability of seeing the values clearly when necessary.

The keyboard hosts utilizing this protocol include the key scan codes helper for the web (USB serial out), two instantiations of 25-pin matrix to UART TX supporting real Commodore keyboards, and a BLE bridge firmware with a Grove connector (e.g. on M5Stick-C).

The scenarios that work include

1. Type from my Windows keyboard, adapted to scan codes sent over USB serial (any of the targets). Keyboard and target are both wired via USB. A web page is making the translation and bridging between the keyboard and USB serial.

2. Connect Commodore keyboard adapter directly to Grove port on one of the various M5Stack devices: M5Core, M5Core2, M5CoreS3, Tab5. This looks like a Commodore keyboard wired through a mess so tied to the target.

3. BLE adapter takes scenario #2 and cuts the wire between the adapter mess and the target. The target appears free and clear of any wires (if self powered). The adapter can be tucked into/under/next to the keyboard. While this acts as a Commodore BLE keyboard, the keyboard itself has a mess of wires, power supply, and adapters.

The BLE adapter actually accepts THREE different inputs. USB serial (from PC host), Grove UART RX, and Grove I2C for CardKB). Note that CardKB isn't using my keyboard standard as an input because it has its own protocol, and I didn't feel like reprogramming it. CardKB drivers are in both the BLE adapter, and in the emulator itself for supporting direct connection. Both CardKB uses are converting and outputting the Commodore scan codes internally.

4. USB host adapter takes a standard USB keyboard and converts to UART TX. This can be cross wired from Grove port to Grove port, or be used in conjunction with #3 (great!! more adapters to the mess) to appear as a USB to BLE wireless adapter.

So I've created an ecosystem of keyboard compatibility built on a custom "standard" so parts can work together and interchange/swap. It allows for flexibility, and interconnections. And when a new keyboard input source comes along (like PPK), implementing the current standard brings extra value to the table.

PPK BLE adapter firmware customized for Commodore

The pre-existing firmware for the Bluetooth adapter as developed by pymo took the obvious choice - present as a standard Bluetooth HID keyboard. That solution works for Windows, Mac, Android, iPhone, and others. It's a great standard. But it doesn't directly translate to a great Commodore keyboard experience. And I don't have a general BLE HID solution integrated into my emulators yet either.

With the way things are with my custom Commodore scan code protocol, it made sense to revise the PPK BLE adapter directly, take advantage of all keys present including Fn and special purpose keys, and map them to what makes sense for Commodore. And add extra value too!

Palm Portable Keyboard

       1   2   3   4   5   6   7   8   9   0   -   =  Back     Date
    Tab Q   W   E   R   T   Y   U   I   O   P   [   ]    \     Phone
    Caps A   S   D   F   G   H   J   K   L   ;   '   Enter     To Do
    LShf  Z   X   C   V   B   N   M   ,   .   /   RShft Up     Memo
    Ctl Fn Alt Cmd {Space  Bar}Spc2 ` Done{Delete}Lt Dn Rt

Let's compare to the layout of my favorite Commodore system, which is a superset of C64

Commodore 128

    Esc Tab Alt Cap     Help LF 40/80 NoScroll     Up Dn Lt Rt         F1  F3  F5  F7

    ←   1   2   3   4   5   6   7   8   9   0   +   -   £   CH   Dl    7   8   9   +
    Cntl Q   W   E   R   T   Y   U   I   O   P   @   *   ↑   {Rest}    4   5   6   -
    RS SL A   S   D   F   G   H   J   K   L   :   ;   =   {Return }    1   2   3   {Enter}
    C=  Sh  Z  X   C   V   B   N   M   ,   .   /   {Shif} Up/Dn L/R    {0   }  .   {Enter}
               {Space                       Bar} 

These are the symbolic key mappings I came up with

PPK C64 Normal

       1   2   3   4   5   6   7   8   9   0   -   =  Back     F1
    Tab q   w   e   r   t   y   u   i   o   p   [   ]    £     F3
    Cap  a   s   d   f   g   h   j   k   l   ;   '   Retrn     F5
    LShf  z   x   c   v   b   n   m   ,   .   /   RShft Up     F7
    Ctr Fn Alt Cbm {Space  Bar}Rest ` Stop{Delete}Lt Dn Rt

PPK C64 Shift

       !   @   #   $   %   ↑   &   *   (   )   ←   +   Ins     F2
    Tab Q   W   E   R   T   Y   U   I   O   P   {   }    |     F4
    Cap  A   S   D   F   G   H   J   K   L   :   "   Retrn     F6
    LShf  Z   X   C   V   B   N   M   <   >   ?   RShft Up     F8
    Ctr Fn Alt Cbm {Space  Bar}Rest ~ Stop{Delete}Lt Dn Rt

PPK C64 Fn (and Numlock)

                               7   8   9   +       =  Home     Help
                                4   5   6   -                  LineFeed
                                 1   2   3   En      Enter     40/80Display
    LShf                          0   0   .   En  RShft Up     NoScroll
                                      Esc {Home } Lt Dn Rt

PPK C64 Caps (C128 only via emulator)

       1   2   3   4   5   6   7   8   9   0   -   =  Back     F1
    Tab Q   W   E   R   T   Y   U   I   O   P   [   ]    £     F3
    Cap  A   S   D   F   G   H   J   K   L   ;   '   Retrn     F5
    LShf  Z   X   C   V   B   N   M   ,   .   /   RShft Up     F7
    Ctr Fn Alt Cbm {Space  Bar}Rest ` Stop{Delete}Lt Dn Rt

Reference

Fn Backspace and Fn Del maps to Home key for moving cursor to upper left on Commodore
Fn Shift Backspace and Fn Shift Del map to Clear key to erase Commodore screen
Fn = toggles NumLock mode, sends unique C128 scan codes for numeric keypad, Enter, and arrow keys. Hold a key with Fn to send the opposite scan code if necessary.
Fn LShift RShift toggles shift lock mode, mimicking the positional switch on Commodore
Caps acts as a toggle switch to represent the positional switch on the Commodore 128. Whether letters are shifted (capitalized), and punctuation is not shifted is the job of the C128 ROM.
Fn Done is Esc
Alt works only in the C128 mode of the emulator

The end result is a full-featured Commodore 128 keyboard for use with Commodore 128 emulation. (And some standard ASCII keys [{}~`|] not present with Commodore, so more useful in non-Commodore emulation). And by the way, the Commodore 64 and Vic-20 emulations map the extra C128 keys to its own matrices automatically -- unlike a real Commodore 128, etc. For instance, the four arrow keys and numeric keypad don't work in C64 mode on a real C128, but they do in the emulated system -- appearing as if the original 64 key matrix keys were pressed instead. This is implemented in the emulator itself. The keyboard is optimistic and reports everything expecting a C128 on the other end. The emulator maps extra keys down to C64 keys, and if in Vic-20 mode, unscrambles into the Vic-20 scan codes too.

(C64 and Vic-20 share the same exact keyboard, but the lines were reordered when connected to the I/O chips. The same keyboard would work in the C128 except for the missing keys - the C128 is a superset. How do I know this? I use both a real Vic-20 and real C128D keyboard interchangeably connected to my self designed Commodore to UART Tx [Grove] adapter, and they work interchangeably in my emulator. How cool would it be to build a C128D replacement keyboard from a Vic-20 keyboard in case? That would blow some minds.)

Operation

1. Plug in the 3D printed Bluetooth adapter and circuit into the PPK to automatically turn it on and start transmitting that it is in pairing mode (rapid Green flashes).

2. Turn on or reset the Commodore Emulated system (e.g. M5CoreS3 or Sunton)

3. Wait for Commodore to boot

4. Should be paired (occasional Green flashes)

5. Type away!

Sunton 7" tablet (Perler bead frame) and PPK BLE

Conclusion

If you have a Palm Portable Keyboard (PPK), access to a version 2 PPK BLE adapter from pymo / Xinming Chen, and you need your wearable or portable Commodore fix with access to a compatible embedded target, then of course this project is for you! Enjoy the ultimate in retro portability without wires. And look cool doing it!

Tuesday, April 28, 2026

BLE GamePad for Cardputer-Game-Station-Emulators

There's a new game in town. And by new, I mean old. Name that game and controller.

Link: https://github.com/davervw/ble_gamepad_KanoPixelKit

Update (23 May 2026): The original firmware was custom BLE driver. The new firmware is standard BLE driver so works with Windows, Android, etc.

Friday, June 20, 2025

Keyboard Editor/Driver for Commodore 64

Keymap Editor for C64

This utility (available from github) allows the user to specify how to remap physical key locations on the Commodore 64 keyboard to different PETSCII keystrokes.

The original intent is to put punctuation keys where they are supposed to go compared to modern keyboard layouts. If one is using an authentic keyboard or equivalent then you may reach for the wrong key if trying to type an @, quotes, or colon.

Control keys revised with numeric keypad

One scenario you may not have thought of is to create a temporary palette of Commodore graphics characters in a custom configuration for programming a game or screen, where the graphics characters are not presently mapped to the keyboard, or not in intuitive locations. You can always restore to the default keyboard mapping, or load another preferred one.

The popular scenario for non-US users is for international keyboard layouts: to match regional differences in layouts, and to support characters not present in the US character map, including corresponding character font image differences. There are existing ROMs that include modified layouts and character images and are available at zimmers.net. Some have slight differences, and some have great differences; changes may also be focused on the upper/lowercase character set in comparison with the upper/graphics set.

Danish ROMs example

Alternatively to having different ROMs, one could modify in RAM including the character set with a font editor, and manually revise the keyboard layouts with the utility I am describing here.

Font editor is also available

Remapping punctuation example

Here are some step by step instructions for remapping the punctuation

1. Start your Commodore 64

2. Insert c-keymaps disk (or 64keymaps.prg)

3. LOAD "64KEYMAPS 49152",8,1

4. SYS 49152

5. Navigate to full colon key with cursor keys

6. Type new key to use: single quote ', and it will appear in its place

7. Press cursor left to return to that key

8. Press home to switch to mapping when shift key is pressed

9. Type new key to use: double quote ", and it will appear in its place

10. Navigate to the punctuation in the numeric key row (still in shift key map), and update them according to your preferences, e.g. !"#$%^&*()

11. When changes are to your liking, press F7 to Save

12. The program exits to BASIC showing you a driver program entry and has typed SAVE" for you. Complete the filename, end the quotes (probably using the original keystroke if not active yet) and add comma 8 for the disk drive, and press RETURN.

13. Once saved, you are welcome to VERIFY as well, and/or make sure your drive is not blinking red

14. To activate the driver, one need only RUN this program in memory. Validate the keys are mapped as expected.

15. When your computer is restarted, you need only load and run the driver you saved to apply the key mapping. The editor is the 49152 program.

16. Whenever the editor is in upper memory, you can return to it with SYS 49152. Whatever active keyboard mapping is in effect will be displayed for editing, whether that be from ROM or RAM.

17. To return to the ROM keyboard mapping, press STOP+RESTORE and verify normal operation (but if the keyboard is not working, or system is locked up, you may have to reset the C64 computer).

18. Whenever the RAM driver is running, editing will use the new mapping, but changes are not applied until you press F7 for Save. When the program for the driver is displayed be very careful not to LOAD over it (like a directory), or your system will lock up because the system was relying on the keyboard driver between addresses $0800 and $09FF. To avoid this, press RUN or STOP+RESTORE first before loading a new program. RUN will move the start of BASIC programs up to $0A00.

Advanced uses

Some keys are not typeable, or you may want to choose them visually. Also, any navigation controls cannot immediately be typed for mapping as they will move the cursor around, etc.

So to get to the character selection screen, press RETURN on a key to edit.

Character selection "picker"

To choose a character, navigate to it and press RETURN, and the display will return to the main editor screen with that character replacing the previous one.

Alternatively, you can select most characters by typing them, and the current keyboard mapping will be displayed as navigation will move to the typed character.

If you need to find a keystroke that is a navigation control (e.g. cursor key, RETURN), then press F3 first, and then any key, and that corresponding key will be selected. You have the option to continue navigating, or press RETURN or STOP to return to editing.

Conclusion

While the editor is MIT LICENSE (do most anything with it, but give me credit if you republish, distribute), the driver portion is considered Public Domain as it is trivial, do with the bytes $0800-$09FF any way you see fit, though many bytes $08FC-$09FF are the mapping bytes and will be mostly copies from Commodore ROMs, so tread carefully with redistribution, or just use for personal use.

Hopefully you find this pair of utilities (editor and driver) useful and/or entertaining. Enjoy!