RetroConnector/DSK Image
Charles Mangin d70b4c865a updated readme
new, all imagemagick command, no more python required.
2017-07-25 11:55:37 -04:00
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BLANK-PRODOS.dsk KansasFest 2015 mass update 2015-07-26 23:49:26 -04:00
BLANK-PRODOS.dsk.png Update BLANK-PRODOS.dsk.png with the new code 2015-09-01 17:16:31 +09:00
DSK-Image.py Merge branch 'master' into pr/4 2016-10-04 15:21:44 -04:00
readme.md updated readme 2017-07-25 11:55:37 -04:00

At 2015s KansasFest [http://kansasfest.org], I had the idea to convert Apple II disk images, of the kind used to run in an emulator, to actual images, of the kind you can view with your eyeballs. I was using the DSK format, which is one of several common image formats.

The resulting images were illuminating and pretty, but flawed. DSK, being abstracted from the original bits, no longer represents actual bytes on disk. Plus, it doesnt work reliably for copy-protected disks. I wanted to see the bits. The closest representation we can get is whats called EDD, named for the Essential Disk Duplicator. I wont go into the details, but its a hardware method of imaging a floppy that captures bytes before they are interpreted by the Apple II, and is more of a one-to-one to bytes on disk.

So, I recently polished off the original script, dug a little more into imagemagick, and learned about the EDD format itself.

The resulting images are much more detailed and nuanced. A few samples are included in the Images directory.

And heres all it takes. One line of imagemagick command line arguments:

    filename=EDD-FILENAME;convert -depth 8 -size 16384x141 gray:"$filename" -crop '6554x141!+0+0' -scale 100%x800% -flip -virtual-pixel 'transparent' +distort Polar '1024 256' "$filename".png

Ill break it down:

    filename=EDD-FILENAME;

your EDD file name goes here.

    convert -depth 8 -size 16384×141 gray:”$filename”

“convert” is the imagemagick command. This tells it to create an 8 bits-per-pixel greyscale image, based on the bytes in the EDD file defined above. The size is based on the EDD format, which stores 2.5 copies of each disk track in a bistream 16384 bytes long. There are 141 quarter-tracks in the EDD file, so that is the vertical resolution.

    -crop 6554×141!+0+0

crops the resulting image down to 6554 bytes wide (1x track instead of 2.5) starting at the top left corner.

    -scale 100%x800% -flip

stretches the vertical resolution by 800% and flips it vertically. This is optional, but if you stop here, the resulting image is easier to “read” the tracks.

The resulting image at this step looks like this.

    -virtual-pixel transparent +distort Polar 1024 256

distorts the rectangular image around a circle 1024 pixels in diameter, with a hole 256 pixels in the middle. This roughly represents the floppy disk media. The background, instead of consisting of stretched out pixels from the edge, is transparent.

    “$filename”.png

Finally, write the result to a PNG file with the same filename as your EDD, with PNG extension.

Caveats:

The EDD file contains “about” 2.5 rotations of each track. The variability of hardware and each disk means the track length in bytes isnt precisely 6554 bytes. In some examples, you can see the “seam” where the track length isnt exactly 1.

At 8 bits-per-pixel, the image is more visually appealing than a true representation of the bits. Fiddling with the values can get you a 1 bit-per-pixel version, as well as higher resolution. The size of the above images is chosen for portability, not any specific function or utility.

The EDD files Im using are from Project Applesauce by John Keoni Morris. His hardware, unlike the EDD card and its clones, synchronizes the tracks of the resulting EDD, and so are going to have better/different properties to other typical EDD files found online.