While SGI’s workstations once sold for five or six figures, surviving examples can now often be had for just a few hundred dollars on eBay. The MIPS-based hardware was potent for its time, often used for 3D rendering work for video games, films, or for scientific purposes. IRIX was SGI’s own OS built specifically to support these use cases.
The IRIX Network is a hobbyist community that loves these old machines and their software. The group hopes to raise $6,500 through crowdfunding to reverse-engineer IRIX. The hope is to use those learnings to create an open-source derivative version named IRIX-32, based on IRIX 5.3, the last 32-bit version of the OS.
Seeing the guts of devices is a fascination that many hackers share. [Txyz] tore down a 2nd gen Google Nest Hub for all of us to enjoy. The video after the break is well produced and relaxing to watch as various heat shields are removed and debug cables are soldered on.
The main SOC is an Amlogic S905D3G, a 4-core A55-based SoC. The important chips are meticulously documented, and it’s a fascinating look inside a device common in many people’s homes. One chip that’s of note is the BGT60TR13C, otherwise known as Project Soli. It is an 8x10mm chip that uses radar to detect movement with sub-millimeter accuracy. This allows the device to measure your sleep quality or recognize gestures. Luckily for us, [Txyz] has included a datasheet and a block diagram. First, the chip fills a FIFO with data samples. Once full, it will issue an interrupt to the main SoC, which empties the buffer via SPI.
The debug cables allowed him to capture traces of the SPI commands to the BGT60TR13C. [Txyz] focused on decoding the various data blocks and the configuration registers. Unfortunately, only a few registers are documented in the datasheet, and it isn’t apparent what they do.
Karaoke is a very popular pastime in Seoul — there are venues where you can sing on a stage, sing in rooms with your friends, and even sing solo in coin-operated karaoke booths on the bullet train. Apparently it is also popular in North Korea as well — [Martyn Williams] of the North Korea Tech blog reported on an interesting teardown by web hacker [Will Scott]. It is the Tianchi v700 machine, a Chinese product tailored for North Korean users, obtained online back in 2020.
Unlike the karaoke machines encountered by this author in South Korea, the v700 form factor is a 19.5-inch Android tablet with touch-screen and all the necessary interfaces you’d expect: external video, speakers, and microphone, as well as WiFi and Ethernet for content upgrade and online payment systems. Not surprisingly, the connectivity aspects of the machine are not used in the North Korean model, but with a large catalog of pre-loaded music, it’s perfectly usable as a stand-alone device.
[Will] dug into the innards of the machine and discovered it was powered by an Allwinner ARM processor (seemingly the H6 V200, a quad-core ARM Cortex-A53). He also found it uses a swappable external disk to hold the songs, but all the files were encrypted. You can read more details in the blog post linked above, but eventually he was successful in decoding the disk and accessing the material.
The V700 consults both “/proc/cpuinfo” to learn the CPU serial number of the device it is on, and a binary file associated with the device file system structure as part of its method for determining its AES (Advanced Encryption Standard) key. It then ignores all of these device-specific items, and reverts back to a static key “87654321” stored in the binary.
All the songs on the disk were posted up on the Internet Archive. Check them out if you’re curious what North Korean karaoke songs sound and look like. One video that caught our attention was about CNC machines (see the video linked below the break). [Martyn] has been covering technology issues related to North Korea since 2011. In 2016, he learned after the fact that his website had been banned by the South Korean authorities. Believing this was in error, he appealed the ban and eventually prevailed in the courts. We wrote about some of [Will]’s research on consumer computing technology back in 2017 if you’re interested in learning more.
Here’s a question for you: How do you reverse engineer a circuit when you don’t even have it in hand? It’s an interesting problem, and it adds a level of difficulty to the already iffy proposition that reverse engineering generally presents. And yet, not only did [themole] find a way to replicate a comms board for his oil burner, he extended and enhanced the circuit for integration into his home automation network.
By way of backstory, [themole] has a wonky Buderus oil burner, which occasionally goes into safety mode and shuts down. With one too many cold showers as a result, he looked for ways to communicate with the burner controller. Luckily, Buderus sells just the thing — a serial port module that plugs into a spare slot in the controller. Unluckily, the board costs a bundle, and that’s even if you can find it. So armed with nothing but photos of the front and back of the board, the finding of which was a true stroke of luck, he set about figuring out the circuit.
With only a dozen components or so and a couple of connectors, the OEM board gave up its secrets pretty easily; it’s really just a level shifter to make the boiler talk RS-232. But that’s a little passé these days, and [the78mole] was more interested in a WiFi connection. So his version of the card includes an ESP32 module, which handles wireless duties as well as the logic needed to talk to the burner using the Buderus proprietary protocol. The module plugs right into the burner controller and connects it to ESPHome, so no more cold showers for [themole].
We thought this one was pretty cool, especially the way [themole] used the online photos of the board to not only trace the circuit but to get accurate — mostly — measurements of the board using an online measuring tool. That’s a tip we’ll keep in our back pocket.
We’re no strangers to unusual clocks here at Hackaday, and some of our favorites make time a little more tangible like [Kyle Rankin]’s knitting clock.
Inspired by our coverage of [Siren Elise Wilhelmsen]’s knitting clock, [Rankin] decided to build one of his own. Since details on the build from the original artist were sparse, he had to reverse engineer how the device worked. He identified that a knitting clock is essentially a knitting machine with a stepper motor replacing the hand crank.
Using a Raspberry Pi with an Adafruit motor hat connected to a stepper motor and a 3D printed motor adapter, [Rankin] was able to drive the knitting machine to do a complete round of knitting every twelve hours. By marking one of the knitting pegs as an hour hand, the clock works as a traditional clock in addition to its year-long knitting task. [Rankin] says he still has some fine tuning to work on, but that he’s happy to have had the chance to combine so many of his interests into a single project.
Running a debugger like gdb with real-mode 16-bit code on the x86 platform is not the easiest thing to do, but incredibly useful when it comes to analyzing BIOS firmware and DOS software. Although it’s possible to analyze a BIOS image after running it through a disassembler, there is a lot that can only be done when the software is running on the real hardware. This is where [Davidson Francis] decided that some BREAD would be useful, as in BIOS Reverse Engineering & Advanced Debugging.
What BREAD does is provide some injectable code that with e.g. a BIOS replaces the normal boot logo with the debugger stub. This stub communicates with a bridge via the serial port, with the gdb client connecting to this bridge. Since DOS programs are also often 16-bit real-mode, these can be similarly modified to provide light-weight in-situ debugging and analysis. We imagine that this software can be very useful both for software archaeology and embedded purposes.
There are very few legal ways of obtaining ROM files for video games, and Nintendo’s lawyers are extremely keen on at least reminding you of the fact that you need to own the game cart before obtaining the ROM. With cart in hand, though, most will grab a cart reader to download the game files. While this is a tried-and-true method, for GameBoy games this extra piece of hardware isn’t strictly required. [Travis Goodspeed] is here to show us a method of obtaining ROM files from photographs of the game itself.
Of course, the chips inside the game cart will need to be decapped in order to obtain the pictures, and the pictures will need to be of high quality in order to grab the information. [Travis] is more than capable of this task in his home lab, but some work is still required after this step.
The individual bits in the Game Boy cartridges are created by metal vias on the chip, which are extremely small, but still visible under a microscope. He also has a CAD program that he developed to take this visual information and extract the data from it, which creates a ROM file that’s just as good as any obtained with a cart reader.
This might end up being slightly more work especially if you have to decap the chips and take the photographs yourself, but it’s nonetheless a clever way of obtaining ROM files due to this quirk of Game Boy technology. Encoding data into physical hardware like this is also an excellent way of ensuring that it doesn’t degrade over time. Here are some other methods for long-term data storage.