BMOW title
Floppy Emu banner

Mac ROM-inator II: The Thickening

Mac ROM-inator II rominatorii-front-and-back

The Mac ROM-inator II is back in stock – get yours now at the BMOW Store. The ROM-inator II is a replacement ROM SIMM for Macintosh II series computers and the Mac SE/30, adding a bootable ROM disk, 32-bit cleanliness, HD20 hard disk support, and more. Read more about it at the project’s home page.

One small mystery has followed the Mac ROM SIMM project from its earliest days, even before BMOW took over the project from Doug Brown. Experience has found the Mac SE/30 to be much pickier about replacement ROM SIMMs than other Macintosh II series computers. On many SE/30 machines, the computer won’t boot with a ROM-inator II SIMM installed until the SIMM is shimmed or braced with clips or rubber bands. Why? Neither Doug nor I ever found a satisfactory answer. While it isn’t difficult to do, it’s an added step that isn’t needed for other machines.

Over the years, a few SE/30 owners have suggested the ROM-inator II SIMM is too loose in the SE/30 ROM socket, and one person had success manually tinning the SIMM pads to make them slightly thicker. I was never fully convinced about this theory. Why would it only affect the SE/30 and not other machines? And anyway the replacement SIMM was the same thickness as the original ROM SIMM (about 1.2 mm), to the limit of my caliper’s measuring abilities. The exact thickness is hard to pin down, since it varies slightly at different regions on the PCB, and there’s also a +/- 10% thickness tolerance from the manufacturer.

I recently learned something that made me reconsider the thickness theory. Back in 1970s and 1980s, PCB thickness was sometimes specified in mils (thousands of an inch) rather than in millimeters. 50 mil PCBs (1.27 mm) were a common thickness, but today these have all but disappeared. Now 1.2 mm is the closest standard thickness, and that’s what was used for all the previous generations of ROM-inator SIMMs.

Is it possible the original SE/30 SIMM was 50 mils (1.27 mm) nominal thickness, with a matching thickness socket, while all the other Macintosh II models used 1.2 mm nominal SIMMs and sockets? That would be a little surprising, but it could explain the behavior I’ve seen. With a 10% thickness tolerance, that means original SE/30 ROM SIMMs would be anywhere from 1.14 to 1.40 mm thick, and ROM-inator II SIMMs would be anywhere from 1.08 to 1.32 mm thick. It’s conceivable that the ROM-inator II SIMMs at the thin end of the distribution, under 1.14 mm thick, might have trouble in SE/30 machines.

It’s still just a theory, but it seems like a plausible one. I spoke to my local SIMM manufacturing partner about getting a thicker PCB, but unfortunately 50 mil PCBs were not available. To complicate matters further, if you’re concerned about differences of a hundredth of a millimeter, then you also need to consider the thickness of the PCB’s copper layer and any plating on the copper. Much of this calculation went over my head, but eventually my local partner was able to find a Korean manufacturer who could create a 1.27 mm stackup with 10% tolerance. The new batch of ROM-inator II SIMMs in the store today were made by that manufacturer.

So there you have it. If I’ve done this correctly, the nominal thickness of a new ROM-inator II SIMM should be a whopping 0.07 mm greater than before, an increase of about six percent. Will that do anything to help the SE/30? Especially when the thickness tolerance is still larger than the new increase in thickness? Honestly I’m not sure, but I’m interested to find out. Maybe it will behave the same as the ones from the previous manufacturer, which would be anti-climactic but fine. Or maybe it will provide some new clues for this long-running SE/30 ROM SIMM mystery.

Be the first to comment! 

Redesigning an Acrylic Case

The acrylic case for BMOW’s Floppy Emu disk emulator is back in stock, along with the deluxe bundle of Floppy Emu with the case and SD card. Get them now at the BMOW store. This is a new version of the laser-cut acrylic case that I’m excited to introduce today.

Eagle-eyed readers may notice that this case looks subtly different from the previous version. I call it a “sandwich style” design because the top and bottom panels overhang the sides, holding the side pieces between them like cheese held between slices of bread. This differs from the previous case, whose six panels with interlocking notches were joined at flush edges with no overhang. The sandwich style ensures that all the side pieces are locked securely in place, and can’t wiggle loose after assembly.

The changes continue inside the case, with the addition of a button guide for the button plungers. The button guide serves several important purposes. During assembly, it makes it possible to stand up the button plungers on the Floppy Emu’s buttons without the plungers falling over, so the top panel can be lowered down over them to finish the case assembly. This is much easier than the old method of suspending the plungers from the top panel with tape. After assembly, the button guide provides a second point of support for each plunger, ensuring that it moves straight up and down without unwanted angles or slippage. This also means the plungers’ functioning is independent of the case screw tightness, without any need to fine-tune the screws.

The last big change for the case is the introduction of top-panel engraved symbols for the power and status LEDs, instead of light pipes. The light pipes were fun, but they made case assembly substantially more difficult, and they’re not necessary when the top panel already functions nicely as an LED diffuser. The engraved symbols with diffuse LEDs give the new case a more minimalist look.

You may be surprised to learn this is something like the 15th version of the Floppy Emu case since I started making them! Most of those earlier revisions were small adjustments to fit or style, so this sandwich style redesign is the first really significant change. I’ve seeded some experienced Floppy Emu beta testers with the new case, and they report it takes about half the time for assembly and is better all-around. I hope you enjoy it!

Read 4 comments and join the conversation 

Retro Puzzle Contest: Solution

On Monday I posted a retro puzzle contest for vintage computing fans. Starting with only a confusing image of jumbled 8-bit characters, I promised that players would proceed through a tricky series of nested challenges, ultimately leading to the name of a person. If you’ve read the book (or seen the movie) Ready Player One, then you’ve seen this type of puzzle chain. I predicted that knowledge of vintage computers, software engineering, and 1980s cultural references would be helpful. And I offered a $100 gift certificate to whoever solved the puzzle and identified the mystery person first.

SPOILER ALERT! The puzzle was solved by the pseudonymous “frogor”, 28 hours after it was first posted. Congratulations! I’m going to describe the solution here, and the several different layers of the puzzle’s challenges. If you’d like to attempt solving the puzzle yourself first, read no further! It’s not an easy puzzle, and you won’t solve it in 5 minutes, maybe not in 5 hours, but you’ll find a retro-techno-challenge that’s worthy of the time you invest in it. See the original puzzle announcement here.

Level 1

The puzzle begins with a 39 x 26 grid of random-looking letters, numbers, and symbols. OK, now what? Several people suggested that it was some type of ASCII autostereogram image. Others thought that if they squinted, they could sort of imagine three rows of large letter-type structures, separated by hearts. Interesting theories, but if you could simply stare at the first clue and see the answer, that would hardly be a “series of challenges”. No, that wouldn’t be a puzzle worthy of this audience.

But there are a lot of hearts in the image – what might their significance be? Also diamonds, clubs, and spades. And all the glyphs look conspicuously bitmap-y, like the glory days of 8-bit computers. And then there’s the odd choice of blue-on-blue color scheme. Hmm.

Identifying the font used in the image seems like a good idea. So how can you do that? If you’re lucky, you’ll recognize it immediately, because you were immersed in it for hours every day during your formative years. Otherwise, you will probably have to brainstorm the names of various vintage computers, look for examples of their character set fonts, and see if they look like a match. Some people pointed to code page 437, and others to PETSCII, which both look close but aren’t quite right. Some of their glyphs have slightly different shapes than the clue’s image, and a few glyphs from the clue’s image aren’t present in code page 437 or PETSCII fonts.

The font used here is actually ATASCII, from the Atari 8-bit series of home computers sold between 1979-1991. The blue-on-blue color scheme is a clue. Those are the default text colors used by the Atari 8-bit computers. And all those hearts? The heart is the first entry in the ATASCII character set.

Level 2

Atari font, check. Now what? Maybe it’s a clue? “Atari” plus random gibberish symbols equals the name of the mystery person? Maybe not.

A font map is a mapping between numbers and glyphs. In the case of ATASCII, there are 256 different glyphs corresponding to the numbers 0 through 255 – one byte. For example, the heart is ATASCII value 0, and the capital A is ATASCII value 65 (hex 0x41). Converting all the glyphs to the equivalent byte value seems like it could be useful, but how?

If you’re a masochist, you could open two side-by-side windows with the image from the clue and the ATASCII font map, and do the conversion by hand. There are about 1000 glyphs in the image from the level 1 clue, so this would take a long time, and you’d probably make some mistakes.

A better solution might be to write a small program to automate the process. Inspection of the clue’s image shows that each glyph is 8 x 8 pixels. So write a program to compare each 8 x 8 block from the clue’s image with 8 x 8 blocks from the ATASCII map, until it finds a match, and then record which ATASCII entry it was.

Even better, use some existing software to do the conversion for you. Frogor writes “I used ImageMagick with some character tables to break apart the grid into individual characters and automate mapping them to their character set byte values.”

When the conversion is done, you’ll have an array of 1014 bytes.

Level 3

Now what can you do with this array of bytes? What is it? It seems to have some kind of structure: there are a large number of 0 bytes, and other values like 17 (hex 0x11) appear very frequently. It’s definitely not random data.

Making sense of the data is tricky. Maybe you can try to guess what sort of data I would put here, knowing the parameters and theme of the puzzle contest. Or maybe you have lots of hacking experience, and can recognize the raw forms of common file types and data structures just by staring at the bytes.

The people from level 1 who thought they could see three rows of large letter-type structures actually had a good idea. Frogor writes “I tried to figure out what my output -was- and could very definitely see some data structure by shifting the rows of hex bytes one character at a time. Since ‘file’ didn’t recognize it, I guessed it might be an image encoding of some sort ā€“ GraphicConverter RAW Import has an -amazing- visualizer which lets you play with the various settings until I tried as a last ditch effort a color encoding I probably should have started with.”

Yes, the bytes are a simple two-color bitmap, in raw form without any headers or other metadata. It’s just a grid of pixels. If you write each byte in binary, with a black pixel for a 1 bit and a white pixel for a 0 bit, then the 39 x 26 grid of glyphs from the first clue is converted into a 312 x 26 two-color bitmap image. Each one-byte glyph has eight bits which encode eight pixels horizontally, so the converted bitmap is eight times wider than the original grid of glyphs. And oh, what a bitmap it is.

Level 4

The upper-right of the bitmap says “BMOW RETRO PUZZLE AUG 2020”. Good, that tells you you’re in the right place. Then there’s some kind of weird code, and a couple of clock / arrow things pointing in different directions. Right.

It doesn’t take a rocket surgeon to recognize that this is some type of substitution cypher. Those boxy and wedgy shapes with dots inside them are clustered into groups that look like words, and the clusters


appear twice, on both the second line and the third. Maybe you immediately recognize this as the Pigpen Cypher, a classic cypher that’s often used in games and puzzles. Or maybe you search Google for “cypher with lines with dots inside them”, and are rewarded with Pigpen Cypher as the top result.

It seems Frogor was initially stumped, but was saved by outside help. “The next stage of decoding gave a tantalizing clue in the first row ā€“ but figuring out the second and third rows I credit to a suggestion of a friend.”

Performing a Pigpen substitution for the second and third rows of the bitmap reveals some new text. But two of the dots don’t seem to be part of the Pigpen cypher.

Level 5

Here’s where knowledge of 1980s cultural references comes into play. “We see farther.” If you were alive in the 80s and were involved in the home computer scene, you recognize this as the slogan of game developer Electronic Arts. And if you don’t recognize it, Electronic Arts is the top search result for this phrase.

The other lines are just lists of numbers. There’s also a mystery dot on each line, and those clock / arrow things at the end of each line. What’s this all about? What if you replace the numbers with the corresponding letters of the alphabet? It sounds worth a try. That gives you DI·FCDG and H·CEFG. Ugh.

Maybe the numbers are referencing one of the people on this iconic Electronic Arts “We See Farther” poster?

Maybe those clock / arrow things are pointing to someone on the poster? Or maybe they aren’t actually clocks or arrows, but compasses pointing north and east? That looks interesting! In that case, the mystery dots could be decimal points for a latitude and longitude in decimal degrees format. Frogor says “in hindsight the helpers on the right side were nice confirmation of being on the right path”.

What is at:

49.6347 degrees north
8.3567 degrees east

Google Maps provides a quick and ready answer for the latitude / longitude lookup.

Level 6

The location is somewhere in Germany, at something called “Worms Hbf”. Your German-speaking friend or a dictionary will tell you that Hbf is an abbreviation for Hauptbahnhof, the main train station in a city. Investigating the map further confirms that 49.6347 N, 8.3567 E is the location of the central train station in the city of Worms, Germany.

Level 7




We see farther. Electronic Arts. Worms. All the pieces are here, but what do they mean? Is there some other clue in these words? If there’s some connection here, it’s not obvious.

If you go back to that Electronic Arts poster again, and take a closer look:

DAVID MAYNARD (arms folded) never intended that his innocently entitled WORMS? should become the Air Force’s secret I.Q. test for alien species. He does not endorse the wanton gambling cult that has sprung up around this product. And he deeply regrets the inhumane uses it has been put to by the Bulgarian Secret Police. “WORMS?”, he says, “was only meant as a lighthearted exploration of limited artificial intelligence using pretty light and simple music.” Right, David.

Seven levels deep into the puzzle, the mystery person is finally revealed! Phew! Success at last.

Creating the Puzzle

My original inspiration for this puzzle was simply “encode some stuff in ATASCII”. My first computer was an Atari 800, and I spent many hours staring at its strange square letters and symbols. They’re etched in my brain.

The idea to use an obscured latitude and longitude came from Brainchase. If you have kids that enjoy puzzles, they’ll love Brainchase. Or forget your kids and sign up for yourself. The first levels of their puzzles are simple enough for even young kids, but to finish them all requires hardcore problem-solving skills. And they have super cool prizes like buried treasure.

Eventually I arrived at the central idea: a latitude/longitude that points to a city whose name is also an English word, that when combined with another phrase, will uniquely identify somebody. “We see farther” jumped into my head immediately as a recognizable 1980s phrase that fit the puzzle’s retro-computer theme. I played loads of EA games as a kid, and also worked at Electronic Arts for many years as an adult.

To make the puzzle fit together, I needed to find an EA game whose name was also the name of a city. And it couldn’t be just any EA game, it needed to be an early game from the era when “We see farther” was still in use. There are no cities named “Archon” or “Pinball Construction Set”, but Worms fit the bill perfectly. So you see, I didn’t actually choose the mystery person. I chose the puzzle format, and the identity of the mystery person was determined for me.

Finding a latitude/longitude for Worms was harder than I expected. A city is a large place; it doesn’t have a precise latitude/longitude. No matter what coordinates I entered into Google Maps, the default behavior was to show a very zoomed-in view of streets and individual buildings, rather than a regional or national map of Germany. I worried this might give people the wrong idea. Would they understand that the clue meant the whole city of Worms, and not some random shopping mall or Burger King in the city? What building should I point to? I eventually settled on the train station as a stand-in for the city itself.

For the Pigpen cipher, I created a custom Pigpen font using Bitfontmaker2. This probably wasn’t necessary, but it was fun to type my secret messages in plaintext and have them automatically rendered in Pigpen. The other elements of the bitmap were drawn in by hand, to create the finished bitmap shown in level 4.

I used LVGL’s Online Image Converter to turn the bitmap into an array of hexadecimal bytes. Then I wrote a short Python program to turn the hex bytes into decimal bytes spread across DATA statements for use with BASIC. As a final step, I wrote an ATARI BASIC program and ran it in the Atari800MacX emulator.

10 FOR R=1 TO 26
20 FOR X=1 TO 39
40 PRINT CHR$(27);CHR$(NUM);
1000 DATA 65, 31, 192, 32, 143, ...

CHR$(27) is the escape sequence. It ensures that control characters like tabs, newlines, and the bell are rendered as ATASCII glyphs instead of performing their control functions. Running this BASIC program created the finished image used for the first clue at level 1. Because the image came from a real (emulated) Atari rather than some paint program, I could be confident the glyphs, colors, and spacing were 100% accurate. This ensured that people could correctly identify the font, and do a pixel-by-pixel comparison against the ATASCII font map if necessary.

A Sequel?

I really enjoyed developing this puzzle, even though it took a long time to create. I also enjoyed watching other people’s thought processes as they tried to solve it. A friend of mine “live-texted” me his progress, which was lots of fun, even though he never finished.

I was a little bit disappointed that more people didn’t attempt the puzzle. Maybe lots of people took a brief look at it, weren’t sure where to begin, and immediately gave up. Or maybe people didn’t really understand what kind of puzzle it was, or why it might be interesting and worthwhile for them to invest time in solving it.

That leads to thoughts of a sequel. Now that puzzle #1 is done, and more people understand what this puzzle format it all about, I’m hoping there might be greater interest in a new one. I would enjoy the challenge. Would you?

Read 3 comments and join the conversation 

Floppy Emu Restock and Retro Puzzle Contest

The BMOW Floppy Emu disk emulator is back in stock and shipping now. Get yours and other BMOW hardware goodies at the store. But before you place your order, you might wish to try your hand at a special challenge.

Are you ready to test your nerd skills and win some prizes? It was quieter than usual around BMOW labs during the out-of-stock period, so I used the opportunity to design a devious retro-computing puzzle. What’s this crazy mess of blue and white symbols? Beginning with only this clue, skilled retro-nerds will work through a series of challenges that will eventually lead to the name of a person. Knowledge of vintage computers, software design, and 1980s cultural references will be helpful. Whoever is first to post the mystery person’s name in the comments section here wins a $100 BMOW gift certificate and one million internet fame points! You may use Google or any other tools you think might help. This is not an easy puzzle, but BMOW readers are a crafty and clever bunch. Ready… go!

Read 11 comments and join the conversation 

The International Shipping Mess

International package shipments through the US Post Office have seen major disruptions in the past months thanks to COVID-19. It’s slower than a sad mule hauling a sack of letters. The delays have caused lots of headaches for BMOW customers and for me. To be candid, it’s a mess. It’s hard to understand, because some packages still get delivered quickly, but others are delayed for months with no updates to their tracking info.

The problem seems to be that the post office uses cargo space on commercial airlines, but since COVID-19 hit, international commercial airline traffic has been reduced to almost nothing. Huge stockpiles of outbound mail are piling up in warehouses, waiting for space on an outbound flight. The US Post Office has started shipping some packages by sea again, returning to the methods used decades ago. Even after the packages reach the destination country, they face additional delays due to lack of staff and extra safety precautions.

As of today, June 23, I estimate that at least half my international shipments are still experiencing major delays, and many shipments from 2+ months ago still haven’t been delivered yet. Most people have been patient in the face of these delays, but I’m approaching a decision point regarding how to handle severely delayed orders. It’s not my fault that COVID-19 has upended the international shipping landscape, but it’s not the customers’ fault either, and I can’t expect them to wait forever. Soon I may have to look at offering tens of thousands of dollars in refunds for missing shipments, which would be disastrous. My method of self-insurance anticipates that packages will occasionally get lost and need to be refunded, but it’s based on an expected loss rate about 1%, not 50% or more. Sending replacement shipments to everybody isn’t really an option, and the replacements would likely experience similar delays.

In the face of this shipping environment, I’ve considered temporarily halting sales outside the USA. I’m very reluctant to do that, because international sales are almost half my total order volume. And many international shipments continue to arrive as quickly as before, typically in a week or two. I haven’t been able to find a pattern that explains which shipments will be delayed, except that shipments going east (mostly Europe) and south (central and South America) are more likely to be delayed than shipments to Canada and shipments going west (Asia and Australia).

Another alternative might be to require customers outside the USA to pay for a premium shipping service like FedEx or DHL. Those services are slower than before, but should still be much faster than the regular post office. But the cost would be very high, perhaps $50 shipping fee for a typical package to Europe. For many orders, that would make the cost of shipping higher than the cost of the goods themselves. The complexity and hassle for me would also increase. My current custom-made shipping solution is tightly integrated with the US Postal Service and relies on living close by a local post office. I’ve done a few experimental shipments with DHL, and the time and care needed to send a single package is much greater than with the post office. Still, this may be the best option from among the unappealing options that are available.

If you’re one of the customers who’s been impacted by this, Iā€™m very sorry for the delay, and thank you for your continued patience.

Read 12 comments and join the conversation 

Acrylic Cases Back in Stock

Acrylic cases for the BMOW Floppy Emu and ADB-USB Wombat are back in stock. If you’ve been waiting for one of these, your wait is over. The Floppy Emu cases were held up longer than expected due to international shipping delays, which continue to be a major challenge. The Wombat cases are made locally, but the manufacturer has mostly transitioned to making emergency medical protective equipment and is processing other work slowly. To compound the problem, the first delivery of Wombat cases were somehow mis-cut at 15/16ths the correct size. The whole batch had to be thrown in the trash, and new cases re-cut. Sometimes even the simple things are hard!

Read 3 comments and join the conversation 

Older Posts »