higan utilizes “Game Paks”, or game folders, for loading games. It uses the icarus import tool to create these gamepaks from individual game ROM files.
Gamepaks are an attempt to simulate physical Nintendo Game Paks in digital form. The idea is that for each game, one folder acts as a gamepak, and contains all data that is specific to said game.
Much as your save data is bound to a physical cartridge, so too is your save data to a game folder.
Let’s say you store all your games in the
If they were stored as game paks,
you would only have to configure one path:
…and you might wind up with a structure like this:
📂 C:\Games 📂 Super Mario Kart (NA).sfc 📄 program.rom 📄 save.ram 📄 cheats.bml 📄 uPD7725.program.rom 📄 uPD7725.data.rom 📂 Dai Kaijuu Monogatari II (JP).sfc 📄 program.rom 📄 save.ram 📄 rtc.ram 📄 state-1.bst
On the other hand, if you use the traditional organization scheme most emulators use, you have to configure five paths:
|Save State path||
…and you would wind up with a structure like this:
📂 C:\Games 📂 ROMs 📄 Super Mario Kart (NA).sfc 📄 Dai Kaijuu Monogatari II (JP).sfc 📂 Saves 📄 Super Mario Kart (NA).srm 📄 Dai Kaijuu Monogatari II (JP).srm 📄 Dai Kaijuu Monogatari II (JP).rtc 📂 Firmware 📄 dsp1.program.rom 📄 dsp1.data.rom 📂 Cheats 📄 Super Mario Kart (NA).cht 📂 States 📄 Dai Kaijuu Monogatari II (JP).bst
It’s very important that everyone understand that the move from loading individual game ROM files with path configurations for each file type over to using folders for each individual game was not an arbitrary or capricious change.
It was born out of necessity as bsnes grew beyond all other SNES emulators that came before it, to support many new scenarios where single game ROM files were simply no longer adequate.
I’m very much aware that many people do not like this design, and that many have refused to even consider using higan over it. However, I hope people will at least read through this article and try to understand my rationale.
Not all video game cartridges are the same: Nintendo cartridges contain complex mapping hardware that can exist in many configurations. For the US SNES set alone, there are 85 unique board configurations comprising 49 unique mapping combinations. And there are many more board types in the Japanese SFC set.
The old notion of “LoROM” and “HiROM” only barely begin to describe things. And indeed, emulators have long used many hacks to work around incompatibilies caused by such over-simplification.
I started work on an SNES preservation project, where my goal was to purchase every commercial SNES game, and analyze the full 16MB address space to produce bit-perfect mappings. This work is now available in icarus.
Instead of “good enough” to run games through the use of hacks, bsnes’ memory mapping is perfect for all games that I have dumped and verified. And if you’ve followed bsnes over the years, you’ll know that I aim for perfection.
The information on the board layouts and memory mapping are not included with raw game ROM dumps: it must be stored somewhere.
By creating the icarus tool, I have been able to include this mapping information in a central database. However, I can never hope to describe every SNES game in existence: not the least because new homebrew software continues to be made to this day.
Further, we have stumbled across multiple examples of prototypes and tech demos that do not have valid registration headers for heuristics to work on.
Thus, for these reasons, it was necessary to allow external files to specify customized memory mapping for individual games.
For just two examples, this has allowed bsnes to be the only SNES emulator capable of running both the DSP-1 tech demo ROM and neviksti’s 96mbit Star Ocean hack.
These mapping files must reside somewhere, and I have placed them inside higan gamepaks as “manifest.bml” files.
In the past, SNES emulators used a technique known as HLE (high level emulation) to support SNES coprocessors. For example, the DSP1 coprocessor is used in games such as Super Mario Kart and Pilotwings.
HLE is, however, a flawed and imprecise method of emulation. It relies on pure speculation to simulate, rather than emulate, the behavior of chips. This leads to inaccuracies, and a total lack of timing which results in software running much faster than it really should.
Through years of hard work, funding, and help, bsnes became the first SNES emulator to truly emulate SNES coprocessor firmware.
In actuality, coprocessors are actual CPUs with their own program firmware running inside of them. This LLE (low level emulation) requires this firmware to be made available to it.
This has allowed bsnes to be the first emulator to ever emulate games such as SD Gundam GX and the Hayazashi Nidan Morita Shougi games.
However, this firmware is also not included with simple game ROM images. Like the memory mapping file, it must be stored somewhere.
It gets even more complicated … take the case of Super Mario Kart. There have been two revisions of this game: one with the DSP1, and one with the DSP1B, which is a bug-fix version of the original. The game ROM is 100% identical for both versions of this cartridge. By keeping the firmware separate from the game itself, it is not possible to allow both cartridges to be emulated.
Further, there is now the potential for homebrew to take advantage of these coprocessors with their very own firmware, allowing potentially very exciting future homebrew developers.
So for these reasons, firmware needs to be bundled with each game. And once again, as with memory map manifests, I include this data inside each gamepak.
bsnes also became the first (and is currently the only) emulator to support the competition cartridges: Campus Challenge ‘92 and Powerfest ‘94.
Unlike traditional games, these boards consist of three separate games, and a master control program that selects between them.
There was a need to be able to store all four game pieces in such a way that they could be loaded together and played.
Once again, gamepaks provided the solution: each individual game is stored inside of one gamepak, and the entire competition cartridge can be loaded and played as one unit.
That’s not to say gamepaks are strictly a matter of necessity. They truly do offer many compelling advantages over the old paradigm of separating files by type.
If you look at the example, gamepaks offer a clear organization advantage over traditional game ROM file storage.
If you ever wish to copy a specific game to another location, you need only locate the game, copy it, and paste it in another location. All data comes along with it and is ready to go. Just like a real Nintendo Game Pak.
If you want to rename a game, you only need to change the name of one single item and you are finished.
Whereas with the traditional method, you must go into (potentially) multiple folders to copy each individual piece, or risk losing data. And when you want to rename things, you must repeat yourself several times. Make one mistake, and the data will no longer match up. And this tends to accumulate cruft as game ROMs are removed or renamed, but stale save data remains.
With gamepaks, you need only (optionally) set one single path location to where you want your games stored.
Whereas with game files sorted by type, you must either configure several separate paths for each file type, or have everything jumbled together into one giant mess of a single folder.
Gamepaks are also very friendly to debuggers. It becomes easy to store lots of development files right inside the gamepak: CPU instruction trace logs, memory RAM dumps, memory usage analysis logs, source code, symbol files, etc.
This avoids having to add several additional path configuration options, or completely flood folders with unintuitive file extensions. It also makes cleaning up the results trivial: simply delete the Debug/ folder inside of a gamepak, and you’re good to go.
The split nature of files also aids in development: if you are working on NES software, the program ROM (instructions) and character ROM (graphics) are cleanly separated. You can load one into your disassembler, and the other into your tile editor, without cross-contamination of unrelated data that would show up as garbage.
If you want to locate the save RAM for a game, which file name is more
game.srm? If you want to locate the program ROM,
which is more apparent?
This has further benefits for a multi-system emulator like higan.
Traditionally, NES emulators use the .sav extension for save RAM, whereas SNES emulators use the .srm extension. NES emulators use the .nes extension for the program ROMs, whereas SNES emulators use the .sfc extension.
With higan, each system has a consistent naming convention: your save RAM is
Of course, that’s not to say it’s all positive. There are two issues caused by gamepaks.
Although this format would be trivial for other emulators to support, it’s unlikely that many will choose to do so.
Few emulators are as in-depth as bsnes is, so there usually isn’t a strong impetus to support such flexibility.
This creates a problem when one wants to run the same game on multiple emulators.
I’ve designed the icarus tool to try and ease this burden as much as possible, but at the end of the day, you will need to keep around two copies of games if you wish to run them in multiple emulators.
For the most part, this generally shouldn’t be an issue for most. As bsnes offers 100% compatibility with zero known bugs, there’s no need to work around bugs by switching between emulators as one used to have to do in the past.
However, this can be a source of frustration if one is using another emulator for specific features higan lacks such as debugging, tool-assisted speedruns, or netplay.
Unfortunately, the most popular operating system with >90% market share lacks the ability out of the box to support folder associations.
So by default, it’s not possible to associate a gamepak with higan to open once double-clicked.
However, I have created the kaijuu Windows Explorer shell extension to alleviate this pain point entirely. After installing kaijuu, you can do many useful things, including associating folders that end in specific extensions like .sfc with higan.
Of course, it’s still a drawback as you have to install kaijuu, as it doesn’t seem appropriate to bundle it in with higan.
In reality, it’s traditional retro game emulators that act highly unusual: higan stores game data in the same way pretty much every other class of application does.
When you install games from Steam, each game goes into its own directory.
When you download music, each song goes into a folder for each album.
When you download TV series, each episode goes into a folder for each show.
It’s always been the norm for humans to sort by “item”, and not by “file extension”, it’s just that the very first major retro emulator was designed for a different time and with no foresight into the nuance that would arise in the future.
And because technology is typically dictated by “first to ship” rather than technical superiority, we’ve been stuck with that bad decision ever since.