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📝 Posted:
🚚 Summary of:
P0264, P0265
Commits:
46cd6e7...78728f6, 78728f6...ff19bed
💰 Funded by:
Blue Bolt, [Anonymous], iruleatgames
🏷 Tags:

Oh, it's 2024 already and I didn't even have a delivery for December or January? Yeah… I can only repeat what I said at the end of November, although the finish line is actually in sight now. With 10 pushes across 4 repositories and a blog post that has already reached a word count of 9,240, the Shuusou Gyoku SC-88Pro BGM release is going to break 📝 both the push record set by TH01 Sariel two years ago, and 📝 the blog post length record set by the last Shuusou Gyoku delivery. Until that's done though, let's clear some more PC-98 Touhou pushes out of the backlog, and continue the preparation work for the non-ASCII translation project starting later this year.

But first, we got another free bugfix according to my policy! 📝 Back in April 2022 when I researched the Divide Error crash that can occur in TH04's Stage 4 Marisa fight, I proposed and implemented four possible workarounds and let the community pick one of them for the generally recommended small bugfix mod. I still pushed the others onto individual branches in case the gameplay community ever wants to look more closely into them and maybe pick a different one… except that I accidentally pushed the wrong code for the warp workaround, probably because I got confused with the second warp variant I developed later on.
Fortunately, I still had the intended code for both variants lying around, and used the occasion to merge the current master branch into all of these mod branches. Thanks to wyatt8740 for spotting and reporting this oversight!

  1. The Music Room background masking effect
  2. The GRCG's plane disabling flags
  3. Text color restrictions
  4. The entire messy rest of the Music Room code
  5. TH04's partially consistent congratulation picture on Easy Mode
  6. TH02's boss position and damage variables

As the final piece of code shared in largely identical form between 4 of the 5 games, the Music Rooms were the biggest remaining piece of low-hanging fruit that guaranteed big finalization% gains for comparatively little effort. They seemed to be especially easy because I already decompiled TH02's Music Room together with the rest of that game's OP.EXE back in early 2015, when this project focused on just raw decompilation with little to no research. 9 years of increased standards later though, it turns out that I missed a lot of details, and ended up renaming most variables and functions. Combined with larger-than-expected changes in later games and the usual quality level of ZUN's menu code, this ended up taking noticeably longer than the single push I expected.

The undoubtedly most interesting part about this screen is the animation in the background, with the spinning and falling polygons cutting into a single-color background to reveal a spacey image below. However, the only background image loaded in the Music Room is OP3.PI (TH02/TH03) or MUSIC3.PI (TH04/TH05), which looks like this in a .PI viewer or when converted into another image format with the usual tools:

TH02's Music Room background in its on-disk state TH03's Music Room background in its on-disk state TH04's Music Room background in its on-disk state TH05's Music Room background in its on-disk state
Let's call this "the blank image".

That is definitely the color that appears on top of the polygons, but where is the spacey background? If there is no other .PI file where it could come from, it has to be somewhere in that same file, right? :thonk:
And indeed: This effect is another bitplane/color palette trick, exactly like the 📝 three falling stars in the background of TH04's Stage 5. If we set every bit on the first bitplane and thus change any of the resulting even hardware palette color indices to odd ones, we reveal a full second 8-color sub-image hiding in the same .PI file:

TH02's Music Room background, with all bits in the first bitplane set to reveal the spacey background image, and the full color palette at the bottom TH03's Music Room background, with all bits in the first bitplane set to reveal the spacey background image, and the full color palette at the bottom TH04's Music Room background, with all bits in the first bitplane set to reveal the spacey background image, and the full color palette at the bottom TH05's Music Room background, with all bits in the first bitplane set to reveal the spacey background image, and the full color palette at the bottom
The spacey sub-image. Never before seen!1!! …OK, touhou-memories beat me by a month. Let's add each image's full 16-color palette to deliver some additional value.

On a high level, the first bitplane therefore acts as a stencil buffer that selects between the blank and spacey sub-image for every pixel. The important part here, however, is that the first bitplane of the blank sub-images does not consist entirely of 0 bits, but does have 1 bits at the pixels that represent the caption that's supposed to be overlaid on top of the animation. Since there now are some pixels that should always be taken from the spacey sub-image regardless of whether they're covered by a polygon, the game can no longer just clear the first bitplane at the start of every frame. Instead, it has to keep a separate copy of the first bitplane's original state (called nopoly_B in the code), captured right after it blitted the .PI image to VRAM. Turns out that this copy also comes in quite handy with the text, but more on that later.


Then, the game simply draws polygons onto only the reblitted first bitplane to conditionally set the respective bits. ZUN used master.lib's grcg_polygon_c() function for this, which means that we can entirely thank the uncredited master.lib developers for this iconic animation – if they hadn't included such a function, the Music Rooms would most certainly look completely different.
This is where we get to complete the series on the PC-98 GRCG chip with the last remaining four bits of its mode register. So far, we only needed the highest bit (0x80) to either activate or deactivate it, and the bit below (0x40) to choose between the 📝 RMW and 📝 TCR/📝 TDW modes. But you can also use the lowest four bits to restrict the GRCG's operations to any subset of the four bitplanes, leaving the other ones untouched:

// Enable the GRCG (0x80) in regular RMW mode (0x40). All bitplanes are
// enabled and written according to the contents of the tile register.
outportb(0x7C, 0xC0);

// The same, but limiting writes to the first bitplane by disabling the
// second (0x02), third (0x04), and fourth (0x08) one, as done in the
// PC-98 Touhou Music Rooms.
outportb(0x7C, 0xCE);

// Regular GRCG blitting code to any VRAM segment…
pokeb(0xA8000, offset, …);

// We're done, turn off the GRCG.
outportb(0x7C, 0x00);

This could be used for some unusual effects when writing to two or three of the four planes, but it seems rather pointless for this specific case at first. If we only want to write to a single plane, why not just do so directly, without the GRCG? Using that chip only involves more hardware and is therefore slower by definition, and the blitting code would be the same, right?
This is another one of these questions that would be interesting to benchmark one day, but in this case, the reason is purely practical: All of master.lib's polygon drawing functions expect the GRCG to be running in RMW mode. They write their pixels as bitmasks where 1 and 0 represent pixels that should or should not change, and leave it to the GRCG to combine these masks with its tile register and OR the result into the bitplanes instead of doing so themselves. Since GRCG writes are done via MOV instructions, not using the GRCG would turn these bitmasks into actual dot patterns, overwriting any previous contents of each VRAM byte that gets modified.
Technically, you'd only have to replace a few MOV instructions with OR to build a non-GRCG version of such a function, but why would you do that if you haven't measured polygon drawing to be an actual bottleneck.

Three overlapping Music Room polygons rendered using master.lib's grcg_polygon_c() function with a disabled GRCGThree overlapping Music Room polygons rendered as in the original game, with the GRCG enabled
An example with three polygons drawn from top to bottom. Without the GRCG, edges of later polygons overwrite any previously drawn pixels within the same VRAM byte. Note how treating bitmasks as dot patterns corrupts even those areas where the background image had nonzero bits in its first bitplane.

As far as complexity is concerned though, the worst part is the implicit logic that allows all this text to show up on top of the polygons in the first place. If every single piece of text is only rendered a single time, how can it appear on top of the polygons if those are drawn every frame?
Depending on the game (because of course it's game-specific), the answer involves either the individual bits of the text color index or the actual contents of the palette:

The contents of nopoly_B with each game's first track selected.

Finally, here's a list of all the smaller details that turn the Music Rooms into such a mess:

And that's all the Music Rooms! The OP.EXE binaries of TH04 and especially TH05 are now very close to being 100% RE'd, with only the respective High Score menus and TH04's title animation still missing. As for actual completion though, the finalization% metric is more relevant as it also includes the ZUN Soft logo, which I RE'd on paper but haven't decompiled. I'm 📝 still hoping that this will be the final piece of code I decompile for these two games, and that no one pays to get it done earlier… :onricdennat:


For the rest of the second push, there was a specific goal I wanted to reach for the remaining anything budget, which was blocked by a few functions at the beginning of TH04's and TH05's MAINE.EXE. In another anticlimactic development, this involved yet another way too early decompilation of a main() function…
Generally, this main() function just calls the top-level functions of all other ending-related screens in sequence, but it also handles the TH04-exclusive congratulating All Clear images within itself. After a 1CC, these are an additional reward on top of the Good Ending, showing the player character wearing a different outfit depending on the selected difficulty. On Easy Mode, however, the Good Ending is unattainable because the game always ends after Stage 5 with a Bad Ending, but ZUN still chose to show the EASY ALL CLEAR!! image in this case, regardless of how many continues you used.
While this might seem inconsistent with the other difficulties, it is consistent within Easy Mode itself, as the enforced Bad Ending after Stage 5 also doesn't distinguish between the number of continues. Also, Try to Normal Rank!! could very well be ZUN's roundabout way of implying "because this is how you avoid the Bad Ending".

With that out of the way, I was finally able to separate the VRAM text renderer of TH04 and TH05 into its own assembly unit, 📝 finishing the technical debt repayment project that I couldn't complete in 2021 due to assembly-time code segment label arithmetic in the data segment. This now allows me to translate this undecompilable self-modifying mess of ASM into C++ for the non-ASCII translation project, and thus unify the text renderers of all games and enhance them with support for Unicode characters loaded from a bitmap font. As the final finalized function in the SHARED segment, it also allowed me to remove 143 lines of particularly ugly segmentation workarounds 🙌


The remaining 1/6th of the second push provided the perfect occasion for some light TH02 PI work. The global boss position and damage variables represented some equally low-hanging fruit, being easily identified global variables that aren't part of a larger structure in this game. In an interesting twist, TH02 is the only game that uses an increasing damage value to track boss health rather than decreasing HP, and also doesn't internally distinguish between bosses and midbosses as far as these variables are concerned. Obviously, there's quite a bit of state left to be RE'd, not least because Marisa is doing her own thing with a bunch of redundant copies of her position, but that was too complex to figure out right now.

Also doing their own thing are the Five Magic Stones, which need five positions rather than a single one. Since they don't move, the game doesn't have to keep 📝 separate position variables for both VRAM pages, and can handle their positions in a much simpler way that made for a nice final commit.
And for the first time in a long while, I quite like what ZUN did there! Not only are their positions stored in an array that is indexed with a consistent ID for every stone, but these IDs also follow the order you fight the stones in: The two inner ones use 0 and 1, the two outer ones use 2 and 3, and the one in the center uses 4. This might look like an odd choice at first because it doesn't match their horizontal order on the playfield. But then you notice that ZUN uses this property in the respective phase control functions to iterate over only the subrange of active stones, and you realize how brilliant it actually is.

Screenshot of TH02's Five Magic Stones, with the first two (both internally and in the order you fight them in) alive and activated Screenshot of TH02's Five Magic Stones, with the second two (both internally and in the order you fight them in) alive and activated Screenshot of TH02's Five Magic Stones, with the last one (both internally and in the order you fight them in) alive and activated

This seems like a really basic thing to get excited about, especially since the rest of their data layout sure isn't perfect. Splitting each piece of state and even the individual X and Y coordinates into separate 5-element arrays is still counter-productive because the game ends up paying more memory and CPU cycles to recalculate the element offsets over and over again than this would have ever saved in cache misses on a 486. But that's a minor issue that could be fixed with a few regex replacements, not a misdesigned architecture that would require a full rewrite to clean it up. Compared to the hardcoded and bloated mess that was 📝 YuugenMagan's five eyes, this is definitely an improvement worthy of the good-code tag. The first actual one in two years, and a welcome change after the Music Room!

These three pieces of data alone yielded a whopping 5% of overall TH02 PI in just 1/6th of a push, bringing that game comfortably over the 60% PI mark. MAINE.EXE is guaranteed to reach 100% PI before I start working on the non-ASCII translations, but at this rate, it might even be realistic to go for 100% PI on MAIN.EXE as well? Or at least technical position independence, without the false positives.

Next up: Shuusou Gyoku SC-88Pro BGM. It's going to be wild.

📝 Posted:
🚚 Summary of:
P0262, P0263
Commits:
ae2fc28...741d889, 741d889...46cd6e7
💰 Funded by:
Blue Bolt, [Anonymous]
🏷 Tags:

And once again, the Shuusou Gyoku task was too complex to be satisfyingly solved within a single month. Even just finding provably correct loop sections in both the original and arranged MIDI files required some rather involved detection algorithms. I could have just defined what sounded like correct loops, but the results of these algorithms were quite surprising indeed. Turns out that not even Seihou is safe from ZUN quirks, and some tracks technically loop much later than you'd think they do, or don't loop at all. And since I then wanted to put these MIDI loops back into the game to ensure perfect synchronization between the recordings and MIDI versions, I ended up rewriting basically all the MIDI code in a cross-platform way. This rewrite also uncovered a pbg bug that has traveled from Shuusou Gyoku into Windows Touhou, where it survived until ZUN ultimately removed all MIDI code in TH11 (!)

Fortunately, the backlog still had enough general PC-98 Touhou funds that I could spend on picking some soon-important low-hanging fruit, giving me something to deliver for the end of the month after all. TH04 and TH05 use almost identical code for their main/option menus, so decompiling it would make number go up quite significantly and the associated blog post won't be that long…

Wait, what's this, a bug report from touhou-memories concerning the website?

  1. Tab switchers tended to break on certain Firefox versions, and
  2. video playback didn't work on Microsoft Edge at all?

Those are definitely some high-priority bugs that demand immediate attention.

  1. Microsoft Edge's anti-support of AV1
  2. TH04/TH05's main/option menu
  3. TH04/TH05's first-launch sound setup menu
  4. TH05's title animation ☯️

The tab switcher issue was easily fixed by replacing the previous z-index trickery with a more robust solution involving the hidden attribute. The second one, however, is much more aggravating, because video playback on Edge has been broken ever since I 📝 switched the preferred video codec to AV1.
This goes so far beyond not supporting a specific codec. Usually, unsupported codecs aren't supposed to be an issue: As soon as you start using the HTML <video> tag, you'll learn that not every browser supports all codecs. And so you set up an encoding pipeline to serve each video in a mix of new and ancient formats, put the <source> tag of the most preferred codec first, and rest assured that browsers will fall back on the best-supported option as necessary. Except that Edge doesn't even try, and insists on staying on a non-playing AV1 video. 🙄

The codecs parameter for the <source> type attribute was the first potential solution I came across. Specifying the video codec down to the finest encoding details right in the HTML markup sounds like a good idea, similar to specifying sizes of images and videos to prevent layout reflows on long pages during the initial page load. So why was this the first time I heard of this feature? The fact that there isn't a simple ffprobe -show_html_codecs_string command to retrieve this string might already give a clue about how useful it is in practice. Instead, you have to manually piece the string together by grepping your way through all of a video's metadata
…and then it still doesn't change anything about Edge's behavior, even when also specifying the string for the VP9 and VP8 sources. Calling the infamously ridiculous HTMLMediaElement.canPlayType() method with a representative parameter of "video/webm; codecs=av01.1.04M.08.0.000.01.13.00.0" explains why: Both the AV1-supporting Chrome and Edge return "probably", but only the former can actually play this format. 🤦

But wait, there is an AV1 video extension in the Microsoft Store that would add support to any unspecified favorite video app. Except that it stopped working inside Edge as of version 116. And even if it did: If you can't query the presence of this extension via JavaScript, it might as well not exist at all.
Not to mention that the favorite video app part is obviously a lie as a lot of widely preferred Windows video apps are bundled with their own codecs, and have probably long supported AV1.

In the end, there's no way around the utter desperation move of removing the AV1 <source> for Edge users. Serving each video in two other formats means that we can at least do something here – try visiting the GitHub release page of the P0234-1 TH01 Anniversary Edition build in Edge and you also don't get to see anything, because that video uses AV1 and GitHub understandably doesn't re-encode every uploaded video into a variety of old formats.
Just for comparison, I tried both that page and the ReC98 blog on an old Android 6 phone from 2014, and even that phone picked and played the AV1 videos with the latest available Chrome and Firefox versions. This was the phone whose available Firefox version didn't support VP9 in 2019, which was my initial reason for adding the VP8 versions. Looks like it's finally time to drop those… 🤔 Maybe in the far future once I start running out of space on this server.

Removing the <source> tags can be done in one of two places:

  1. server-side, detecting Edge via the User-Agent header, or
  2. client-side, using navigator.userAgentData.brands.

I went with 2) because more dynamic server-side code would only move us further away from static site generation, which would make a lot of sense as the next evolutionary step in the architecture of this website. The client-side solution is much simpler too, and we can defer the deletion until a user actually hovers over a specific video.
And while we're at it, let's also add a popup complaining about this whole state of affairs. Edge is heavily marketed inside Windows as "the modern browser recommended by Microsoft", and you sure wouldn't expect low-quality chroma-subsampled VP9 from such a tagline. With such a level of anti-support for AV1, Edge users deserve to know exactly what's going on, especially since this post also explains what they will encounter on other websites.

A popup on top of a ReC98 blog video, showing the caption "⚠️ Edge does not support AV1, falling back on low-quality video…"
That's the polite way of putting it.

Alright, where was I? For TH01, the main menu was the last thing I decompiled before the 100% finalization mark, so it's rather anticlimactic to already cover the TH04/TH05 one now, with both of the games still being very far away from 100%, just because people will soon want to translate the description text in the bottom-right corner of the screen. But then again, the ZUN Soft logo animation would make for an even nicer final piece of decompiled code, especially since the bouncing-ball logo from TH01, TH02, and TH03 was the very first decompilation I did, all the way back in 2015.

The code quality of ZUN's VRAM-based menus has barely increased between TH01 and TH05. Both the top-level and option menu still need to know the bounding rectangle of the other one to unblit the right pixels when switching between the two. And since ZUN sure loved hardcoded and copy-pasted numbers in the PC-98 days, the coordinates both tend to be excessively large, and excessively wrong. :zunpet: Luckily, each menu item comes with its own correct unblitting rectangle, which avoids any graphical glitches that would otherwise occur.
As for actual observable quirks and bugs, these menus only contain one of each, and both are exclusive to TH04:

And yes, these videos do have a frame rate of 2 FPS.

Now that 100% finalization of their OP.EXE binaries is within reach, all this bloat made me think about the viability of a 📝 single-executable build for TH04's and TH05's debloated and anniversary versions. It would be really nice to have such a build ready before I start working on the non-ASCII translations – not just because they will be based on the anniversary branch by default, but also because it would significantly help their development if there are 4 fewer executables to worry about.
However, it's not as simple for these games as it was for TH01. The unique code in their OP.EXE and MAINE.EXE binaries is much larger than Borland's easily removed C++ exception handler, so I'd have to remove a lot more bloat to keep the resulting single binary at or below the size of the original MAIN.EXE. But I'm sure going to try.


Speaking of code that can be debloated for great effect: The second push of this delivery focused on the first-launch sound setup menu, whose BGM and sound effect submenus are almost complete code duplicates of each other. The debloated branch could easily remove more than half of the code in there, yielding another ≈800 bytes in case we need them.
If hex-editing MIKO.CFG is more convenient for you than deleting that file, you can set its first byte to FF to re-trigger this menu. Decompiling this screen was not only relevant now because it contains text rendered with font ROM glyphs and it would help dig our way towards more important strings in the data segment, but also because of its visual style. I can imagine many potential mods that might want to use the same backgrounds and box graphics for their menus.

TH04's first-launch sound setup menu, showing the BGM mode selectionTH05's first-launch sound setup menu, showing the sound effect mode selection
How about an initial language selection menu in the same style?

With the two submenus being shown in a fixed sequence, there's not a lot of room for the code to do anything wrong, and it's even more identical between the two games than the main menu already was. Thankfully, ZUN just reblits the respective options in the new color when moving the cursor, with no 📝 palette tricks. TH04's background image only uses 7 colors, so he could have easily reserved 3 colors for that. In exchange, the TH05 image gets to use the full 16 colors with no change to the code.


Rounding out this delivery, we also got TH05's rolling Yin-Yang Orb animation before the title screen… and it's just more bloat and landmines on a smaller scale that might be noticeable on slower PC-98 models. In total, there are three unnecessary inter-page copies of the entire VRAM that can easily insert lag frames, and two minor page-switching landmines that can potentially lead to tearing on the first frame of the roll or fade animation. Clearly, ZUN did not have smoothness or code quality in mind there, as evidenced by the fact that this animation simply displays 8 .PI files in sequence. But hey, a short animation like this is 📝 another perfectly appropriate place for a quick-and-dirty solution if you develop with a deadline.
And that's 1.30% of all PC-98 Touhou code finalized in two pushes! We're slowly running out of these big shared pieces of ASM code…

I've been neglecting TH03's OP.EXE quite a bit since it simply doesn't contain any translatable plaintext outside the Music Room. All menu labels are gaiji, and even the character selection menu displays its monochrome character names using the 4-plane sprites from CHNAME.BFT. Splitting off half of its data into a separate .ASM file was more akin to getting out a jackhammer to free up the room in front of the third remaining Music Room, but now we're there, and I can decompile all three of them in a natural way, with all referenced data.
Next up, therefore: Doing just that, securing another important piece of text for the upcoming non-ASCII translations and delivering another big piece of easily finalized code. I'm going to work full-time on ReC98 for almost all of December, and delivering that and the Shuusou Gyoku SC-88Pro recording BGM back-to-back should free up about half of the slightly higher cap for this month.

📝 Posted:
🚚 Summary of:
P0258, P0259, P0260, P0261
Commits:
5876755...e8a0b3e, e8a0b3e...dfaa3c6, dfaa3c6...ed9ee93, ed9ee93...ae2fc28
💰 Funded by:
Blue Bolt, [Anonymous], Yanga, Splashman
🏷 Tags:

And we're back to PC-98 Touhou for a brief interruption of the ongoing Shuusou Gyoku Linux port. Let's clear some of the Touhou-related progress from the backlog, and use the unconstrained nature of these contributions to prepare the 📝 upcoming non-ASCII translations commissioned by Touhou Patch Center. The current budget won't cover all of my ambitions, but it would at least be nice if all text in these games was feasibly translatable by the time I officially start working on that project.

At a little over 3 pushes, it might be surprising to see that this took longer than the 📝 TH03/TH04/TH05 cutscene system. It's obvious that TH02 started out with a different system for in-game dialog, but while TH04 and TH05 look identical on the surface, they only actually share 30% of their dialog code. So this felt more like decompiling 2.4 distinct systems, as opposed to one identical base with tons of game-specific differences on top.

The table of contents was pretty popular last time around, so let's have another one:

  1. Overview of TH04's dialog system
  2. Changes introduced in TH05
  3. Command reference for the TH04 and TH05 systems
  4. Overview of TH02's dialog system
  5. TH02's face portrait images
  6. Bugs during TH02's dialog box slide-in animation
  7. Bugs and quirks in Mima's defeat dialog (might be lore-relevant)
  8. TH03 win messages

Let's start with the ones from TH04 and TH05, since they are not that broken. For TH04, ZUN started out by copy-pasting the cutscene system, causing the result to inherit many of the caveats I already described in the cutscene blog post:

Then, however, he greatly simplified the system. Mainly, this was done by moving text rendering from the PC-98 graphics chip to the text chip, which avoids the need for any text-related unblitting code, but ZUN also added a bunch of smaller changes:

While it would seem that TH05 has no issues with ASCII 0x20 spaces, the text as a whole is still blindly processed two bytes at a time, and any commands can only appear at even byte positions within a line. I dimmed the VRAM pixels to 25% of their original brightness to make the text easier to read.
The same text backported to TH04, additionally demonstrating how that game's dialog system inherited the whitespace skipping behavior of TH03's cutscene system. Just like there, ASCII 0x20 spaces only work at odd byte positions because the game treats them as the trailing byte of a full-width Shift-JIS codepoint. I don't know how large the budget for the upcoming non-ASCII translations will be, but I'm going to fix this even in the very basic fully static variant. I dimmed the VRAM pixels to 25% of their original brightness to make the text easier to read.
Demonstrating the lack of automatic line or box breaks in TH05's dialog systemDemonstrating the lack of automatic line or box breaks in TH04's dialog system, in addition to its lack of support for ASCII 0x20 spaces carried over from TH03's cutscene system

TH05 then moved from TH04's plaintext scripts to the binary .TX2 format while removing all the unused commands copy-pasted from the cutscene system. Except for a single additional command intended to clear a text box, TH05's dialog system only supports a strict subset of the features of TH04's system.
This change also introduced the following differences compared to TH04:

Writing the 0x02 byte to text RAM results in an SX character, which is simply the PC-98 font ROM's glyph for that Shift-JIS codepoint.
Also note how each face change is now preceded by two frames of delay.
No problem in TH04. Note how the dialog also runs a bit faster – TH04 only adds the aforementioned one frame of delay to each face change, and has fewer two-byte chunks of text to display overall.

For modding these files, you probably want to use TXDEF from -Tom-'s MysticTK. It decodes these files into a text representation, and its encoder then takes care of the character-specific byte offsets in the 10-byte header. This text representation simplifies the format a lot by avoiding all corner cases and landmines you'd experience during hex-editing – most notably by interpreting the box-starting 0x0D as a command to show text that takes a string parameter, avoiding the broken calls to script commands in the middle of text. However, you'd still have to manually ensure an even number of bytes on every line of text.

In the entry function of TH05's dialog loop, we also encounter the hack that is responsible for properly handling 📝 ZUN's hidden Extra Stage replay. Since the dialog loop doesn't access the replay inputs but still requires key presses to advance through the boxes, ZUN chose to just skip the dialog altogether in the specific case of the Extra Stage replay being active, and replicated all sprite management commands from the dialog script by just hardcoding them.
And you know what? Not only do I not mind this hack, but I would have preferred it over the actual dialog system! The aforementioned sprite management commands effectively boil down to manual memory management, deallocating all stage enemy and midboss sprites and thus ensuring that the boss sprites end up at specific master.lib sprite IDs (patnums). The hardcoded boss rendering function then expects these sprites to be available at these exact IDs… which means that the otherwise hardcoded bosses can't render properly without the dialog script running before them. :zunpet:
There is absolutely no excuse for the game to burden dialog scripts with this functionality. Sure, delayed deallocation would allow them to blit stage-specific sprites, but the original games don't do that; probably because none of the two games feature an unblitting command. And even if they did, it would have still been cleaner to expose the boss-specific sprite setup as a single script command that can then also be called from game code if the script didn't do so. Commands like these just are a recipe for crashes, especially with parsers that expect fullwidth Shift-JIS text and where misaligned ASCII text can easily cause these commands to be skipped.

But then again, it does make for funny screenshot material if you accidentally the deallocation and then see bosses being turned into stage enemies:

TH04's dialog before the Stage 4 Marisa fight without deallocating the stage sprites inside the script, causing Marisa to be turned into one of the stage enemiesTH04's dialog before the Stage 6 Yuuka fight without deallocating the stage sprites inside the script, causing Yuuka to be turned into two different cels of the same stage enemyTH05's dialog before the Louise fight without deallocating the stage sprites inside the script, causing Louise to be turned into one of the ice enemies from TH05's Stage 2TH05's dialog before the Louise fight without deallocating the stage sprites inside the script, causing Mai and Yuki to be turned into a windmill and fairy/demon enemy, respectively
Some of the more amusing consequences of not calling the sprite-deallocating :th04: \c /  :th05: 0x04 command inside a dialog script.
In the case of 4️⃣, the game then even crashes on this frame at the end of the dialog, in a way that resembles the infamous 📝 TH04 crash before Stage 5 Yuuka if no EMS driver is loaded. Both the stage- and boss-specific BFNT sprites are loaded into memory at this point, leaving no room for the 256×256-pixel background image on the size-limited master.lib heap.

With all the general details out of the way, here's the command reference:

:th04: :th05:
0
1
0x00
0x01
Selects either the player character (0) or the boss (1) as the currently speaking character, and moves the cursor to the beginning of the text box. In TH04, this command also directly starts the new dialog box, which is probably why it's not prefixed with a \ as it only makes sense outside of text. TH05 requires a separate 0x0D command to do the same.
\=1 0x02 0x!! Replaces the face portrait of the currently active speaking character with image #1 within her .CD2 file.
\=255 0x02 0xFF Removes the face portrait from the currently active text box.
\l,filename 0x03 filename 0x00 Calls master.lib's super_entry_bfnt() function, which loads sprites from a BFNT file to consecutive IDs starting at the current patnum write cursor.
\c 0x04 Deallocates all stage-specific BFNT sprites (i.e., stage enemies and midbosses), freeing up conventional RAM for the boss sprites and ensuring that master.lib's patnum write cursor ends up at :th04: 128 / :th05: 180.
In TH05's Extra Stage, this command also replaces 📝 the sprites loaded from MIKO16.BFT with the ones from ST06_16.BFT.
\d Deallocates all face portrait images.
The game automatically does this at the end of each dialog sequence. However, ZUN wanted to load Stage 6 Yuuka's 76 KiB of additional animations inside the script via \l, and would have once again run up against the master.lib heap size limit without that extra free memory.
\m,filename 0x05 filename 0x00 Stops the currently playing BGM, loads a new one from the given file, and starts playback.
\m$ 0x05 $ 0x00 Stops the currently playing BGM.
Note that TH05 interprets $ as a null-terminated filename as well.
\m* Restarts playback of the currently loaded BGM from the beginning.
\b0,0,0 0x06 0x!!!! 0x!!!! 0x!! Blits the master.lib patnum with the ID indicated by the third parameter to the current VRAM page at the top-left screen position indicated by the first two parameters.
\e0 Plays the sound effect with the given ID.
\t100 Sets palette brightness via master.lib's palette_settone() to any value from 0 (fully black) to 200 (fully white). 100 corresponds to the palette's original colors.
\fo1
\fi1
Calls master.lib's palette_black_out() or palette_black_in() to play a hardware palette fade animation from or to black, spending roughly 1 frame on each of the 16 fade steps.
\wo1
\wi1
0x09 0x!!
0x0A 0x!!
Calls master.lib's palette_white_out() or palette_white_in() to play a hardware palette fade animation from or to white, spending roughly 1 frame on each of the 16 fade steps.
The TH05 version of 0x09 also clears the text in both boxes before the animation.
\n 0x0B Starts a new line by resetting the X coordinate of the TRAM cursor to the left edge of the text area and incrementing the Y coordinate.
The new line will always be the next one below the last one that was properly started, regardless of whether the text previously wrapped to the next TRAM row at the edge of the screen.
\g8 Plays a blocking 8-frame screen shake animation. Copy-pasted from the cutscene parser, but actually used right at the end of the dialog shown before TH04's Bad Ending.
\ga0 0x0C 0x!! Shows the gaiji with the given ID from 0 to 255 at the current cursor position, ignoring the per-glyph delay.
\k0 Waits 0 frames (0 = forever) for any key to be pressed before continuing script execution.
0x0D Starts a new dialog box with the previously selected speaker. All text until the next 0xFF command will appear on screen.
Inside dialogs, this is a no-op.
0x0E Takes the current dialog cursor as the top-left corner of a 240×48-pixel rectangle, and replaces all text RAM characters within that rectangle with whitespace.
This is only used to clear the player character's text box before Shinki's final いくよ‼ box. Shinki has two consecutive text boxes in all 4 scripts here, and ZUN probably wanted to clear the otherwise blue text to imply a dramatic pause before Shinki's final sentence. Nice touch.
(You could, however, also use it after a box-ending 0xFF command to mess with text RAM in general.)
\# Quits the currently running loop. This returns from either the text loop to the command loop, or it ends the dialog sequence by returning from the command loop back to gameplay. If this stage of the game later starts another dialog sequence, it will start at the next script byte.
\$ Like \#, but first waits for any key to be pressed.
0xFF Behaves like TH04's \$ in the text loop, and like \# in the command loop. Hence, it's not possible in TH05 to automatically end a text box and advance to the next one without waiting for a key press.
Unused commands are in gray.

At the end of the day, you might criticize the system for how its landmines make it annoying to mod in ASCII text, but it all works and does what it's supposed to. ZUN could have written the cleanest single and central Shift-JIS iterator that properly chunks a byte buffer into halfwidth and fullwidth codepoints, and I'd still be throwing it out for the upcoming non-ASCII translations in favor of something that either also supports UTF-8 or performs dictionary lookups with a full box of text.
The only actual bug can be found in the input detection, which once again doesn't correctly handle the infamous key up/key down scancode quirk of PC-98 keyboards. All it takes is one wrongly placed input polling call, and suddenly you have to think about how the update cycle behind the PC-98 keyboard state bytes might cause the game to run the regular 2-frame delay for a single 2-byte chunk of text before it shows the full text of a box after all… But even this bug is highly theoretical and could probably only be observed very, very rarely, and exclusively on real hardware.


The same can't be said about TH02 though, but more on that later. Let's first take a look at its data, which started out much simpler in that game. The STAGE?.TXT files contain just raw Shift-JIS text with no trace of commands or structure. Turning on the whitespace display feature in your editor reveals how the dialog system even assumes a fixed byte length for each box: 36 bytes per line which will appear on screen, followed by 4 bytes of padding, which the original files conveniently use to visually split the lines via a CR/LF newline sequence. Make sure to disable trimming of trailing whitespace in your editor to not ruin the file when modding the text… :onricdennat:

靈夢:あんた、まだ名前も聞いてないの··
······に覚えられないわよ。・・・・・··
里香:あたいは、里香よ。覚えときなさ··
・・・い。・・・・・・················
Two boxes from TH02's STAGE5.TXT with visualized whitespace. These also demonstrate how the CR/LF newlines only make up 2 of the 4 padding bytes, and require each line to be padded with two more bytes; you could not use these trailing spaces for actual text. Also note how the exquisite mixture of fullwidth and halfwidth spaces demands the text to be viewed with only the most metrically consistent monospace fonts to preserve the intended alignment. 🍷 It appears quite misaligned on my phone.

Consequently, everything else is hardcoded – every effect shown between text boxes, the face portrait shown for each box, and even how many boxes are part of each dialog sequence. Which means that the source code now contains a long hardcoded list of face IDs for most of the text boxes in the game, with the rest being part of the dedicated hardcoded dialog scripts for 2/3 of the game's stages.
Without the restriction to a fixed set of scripting commands, TH02 naturally gravitated to having the most varied dialog sequences of all PC-98 Touhou games. This flexibility certainly facilitated Mima's grand entrance animation in Stage 4, or the different lines in Stage 4 and 5 depending on whether you already used a continue or not. Marisa's post-boss dialog even inserts the number of continues into the text itself – by, you guessed it, writing to hardcoded byte offsets inside the dialog text before printing it to the screen. :godzun: But once again, I have nothing to criticize here – not even the fact that the alternate dialog scripts have to mutate the "box cursor" to jump to the intended boxes within the file. I know that some people in my audience like VMs, but I would have considered it more bloated if ZUN had implemented a full-blown scripting language just to handle all these special cases.


Another unique aspect of TH02 is the way it stores its face portraits, which are infamous for how hard they are to find in the original data files. These sprites are actually map tiles, stored in MIKO_K.MPN, and drawn using the same functions used to blit the regular map tiles to the 📝 tile source area in VRAM. We can only guess why ZUN chose this one out of the three graphics formats he used in TH02:

TH02's MIKO_K.PTN, arranged into a 16×16-tile layout that reveals how these tiles are combined into face portraits.
MPNDEF from -Tom-'s MysticTK conveniently uses this exact layout in its .BMP output. Earlier MPNDEF versions crashed when converting this file as its 256 tiles led to an 8-bit overflow bug, so make sure you've updated to the current version from the end of October 2023 if you want to convert this file yourself. The format stores the 4 bitplanes of each 16×16 tile in order, so good luck finding a different planar image viewer that would support both such a tiled layout and a custom palette. Sometimes, a weird internal format is the best type of obfuscation. :tannedcirno:
TH02's MIKO_K.PTN with the 16×16 tile grid overlaid

And since you're certainly wondering about all these black tiles at the edges: Yes, these are not only part of the file and pad it from the required 240×192 pixels to 256×256, but also kept in memory during a stage, wasting 9.5 KiB of conventional RAM. That's 172 seconds of potential input replay data, just for those people who might still think that we need EMS for replays.


Alright, we've got the text, we've got the faces, let's slide in the box and display it all on screen. Apparently though, we also have to blit the player and option sprites using raw, low-level master.lib function calls in the process? :thonk: This can't be right, especially because ZUN always blits the option sprite associated with the Reimu-A shot type, regardless of which one the player actually selected. And if you keep moving above the box area before the dialog starts, you get to see exactly how wrong this is:

Let's look closer at Reimu's sprite during the slide-in animation, and in the two frames before:

Zoomed-in area around Reimu's sprite from frame 35 of the video aboveZoomed-in area around Reimu's sprite from frame 36 of the video aboveZoomed-in area around Reimu's sprite from frame 37 of the video above

This one image shows off no less than 4 bugs:

  1. ZUN blits the stationary player sprite here, regardless of whether the player was previously moving left or right. This is a nice way of indicating that Reimu stops moving once the dialog starts, but maybe ZUN should have unblitted the old sprite so that the new one wouldn't have appeared on top. The game only unblits the 384×64 pixels covered by the dialog box on every frame of the slide-in animation, so Reimu would only appear correctly if her sprite happened to be entirely located within that area.
  2. All sprites are shifted up by 1 pixel in frame 2️⃣. This one is not a bug in the dialog system, but in the main game loop. The game runs the relevant actions in the following order:

    1. Invalidate any map tiles covered by entities
    2. Redraw invalidated tiles
    3. Decrement the Y coordinate at the top of VRAM according to the scroll speed
    4. Update and render all game entities
    5. Scroll in new tiles as necessary according to the scroll speed, and report whether the game has scrolled one pixel past the end of the map
    6. If that happened, pretend it didn't by incrementing the value calculated in #3 for all further frames and skipping to #8.
    7. Issue a GDC SCROLL command to reflect the line calculated in #3 on the display
    8. Wait for VSync
    9. Flip VRAM pages
    10. Start boss if we're past the end of the map

    The problem here: Once the dialog starts, the game has already rendered an entire new frame, with all sprites being offset by a new Y scroll offset, without adjusting the graphics GDC's scroll registers to compensate. Hence, the Y position in 3️⃣ is the correct one, and the whole existence of frame 2️⃣ is a bug in itself. (Well… OK, probably a quirk because speedrunning exists, and it would be pretty annoying to synchronize any video regression tests of the future TH02 Anniversary Edition if it renders one fewer frame in the middle of a stage.)

  3. ZUN blits the option sprites to their position from frame 1️⃣. This brings us back to 📝 TH02's special way of retaining the previous and current position in a two-element array, indexed with a VRAM page ID. Normally, this would be equivalent to using dedicated prev and cur structure fields and you'd just index it with the back page for every rendering call. But if you then decide to go single-buffered for dialogs and render them onto the front page instead… :zunpet:
    Note that fixing bug #2 would not cancel out this one – the sprites would then simply be rendered to their position in the frame before 1️⃣.

  4. And of course, the fixed option sprite ID also counts as a bug.

As for the boxes themselves, it's yet another loop that prints 2-byte chunks of Shift-JIS text at an even slower fixed interval of 3 frames. In an interesting quirk though, ZUN assumes that every box starts with the name of the speaking character in its first two fullwidth Shift-JIS characters, followed by a fullwidth colon. These 6 bytes are displayed immediately at the start of every box, without the usual delay. The resulting alignment looks rather janky with Genjii, whose single right-padded kanji looks quite awkward with the fullwidth space between the name and the colon. Kind of makes you wonder why ZUN just didn't spell out his proper name, 玄爺, instead, but I get the stylistic difference.
In Stage 4, the two-kanji assumption then breaks with Marisa's three-kanji name, which causes the full-width colon to be printed as the first delayed character in each of her boxes:


That's all the issues and quirks in the system itself. The scripts themselves don't leave much room for bugs as they basically just loop over the hardcoded face ID array at this level… until we reach the end of the game. Previously, the slide-in animation could simply use the tile invalidation and re-rendering system to unblit the box on each frame, which also explained why Reimu had to be separately rendered on top. But this no longer works with a custom-rendered boss background, and so the game just chooses to flood-fill the area with graphics chip color #0:

Then again, transferring pixels from the back page would be just as wrong as they lag one frame behind. No way around capturing these 384×64 pixels to main memory here… Oh well, this flood-fill at least adds even more legibility on top of the already half-transparent text box. A property that the following dialog sequence unfortunately lacks…

For Mima's final defeat dialog though, ZUN chose to not even show the box. He might have realized the issue by that point, or simply preferred the more dramatic effect this had on the lines. The resulting issues, however, might even have ramifications for such un-technical things as lore and character dynamics. :zunpet: As it turns out, the code for this dialog sequence does in fact render Mima's smiling face for all boxes?! You only don't see it in the original game because it's rendered to the other VRAM page that remains invisible during the dialog sequence:

Caution, flashing lights.

Here's how I interpret the situation:

So, the future TH02 Anniversary Edition will fix the bug by showing the back page, but retain the quirk by rewriting the dialog code to not blit the face.


And with that, we've secured all in-game dialog for the upcoming non-ASCII translations! The remaining 2/3 of the last push made for a good occasion to also decompile the small amount of code related to TH03's win messages, stored in the @0?TX.TXT files. Similar to TH02's dialog format, these files are also split into fixed-size blocks of 3×60 bytes. But this time, TH03 loads all 60 bytes of a line, including the CR/LF line breaking codepoints in the original files, into the statically allocated buffer that it renders from. These control characters are then only filtered to whitespace by ZUN's graph_putsa_fx() function. If you remove the line breaks, you get to use the full 60 bytes on every line.
The final commits went to the MIKO.CFG loading and saving functions used in TH04's and TH05's OP.EXE, as well as TH04's game startup code to finally catch up with 📝 TH05's counterpart from over 3 years ago. This brought us right in front of the main menu rendering code in both TH04 and TH05, which is identical in both games and will be tackled in the next PC-98 Touhou delivery.

Next up, though: Returning to Shuusou Gyoku, and adding support for SC-88Pro recordings as BGM. Which may or may not come with a slight controversy…

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And then, the supposed boilerplate code revealed yet another confusing issue that quickly forced me back to serial work, leading to no parallel progress made with Shuusou Gyoku after all. 🥲 The list of functions I put together for the first ½ of this push seemed so boring at first, and I was so sure that there was almost nothing I could possibly talk about:

That's three instances of ZUN removing sprites way earlier than you'd want to, intentionally deciding against those sprites flying smoothly in and out of the playfield. Clearly, there has to be a system and a reason behind it.

Turns out that it can be almost completely blamed on master.lib. None of the super_*() sprite blitting functions can clip the rendered sprite to the edges of VRAM, and much less to the custom playfield rectangle we would actually want here. This is exactly the wrong choice to make for a game engine: Not only is the game developer now stuck with either rendering the sprite in full or not at all, but they're also left with the burden of manually calculating when not to display a sprite.
However, strictly limiting the top-left screen-space coordinate to (0, 0) and the bottom-right one to (640, 400) would actually stop rendering some of the sprites much earlier than the clipping conditions we encounter in these games. So what's going on there?

The answer is a combination of playfield borders, hardware scrolling, and master.lib needing to provide at least some help to support the latter. Hardware scrolling on PC-98 works by dividing VRAM into two vertical partitions along the Y-axis and telling the GDC to display one of them at the top of the screen and the other one below. The contents of VRAM remain unmodified throughout, which raises the interesting question of how to deal with sprites that reach the vertical edges of VRAM. If the top VRAM row that starts at offset 0x0000 ends up being displayed below the bottom row of VRAM that starts at offset 0x7CB0 for 399 of the 400 possible scrolling positions, wouldn't we then need to vertically wrap most of the rendered sprites?
For this reason, master.lib provides the super_roll_*() functions, which unconditionally perform exactly this vertical wrapping. But this creates a new problem: If these functions still can't clip, and don't even know which VRAM rows currently correspond to the top and bottom row of the screen (since master.lib's graph_scrollup() function doesn't retain this information), won't we also see sprites wrapping around the actual edges of the screen? That's something we certainly wouldn't want in a vertically scrolling game…
The answer is yes, and master.lib offers no solution for this issue. But this is where the playfield borders come in, and helpfully cover 16 pixels at the top and 16 pixels at the bottom of the screen. As a result, they can hide up to 32 rows of potentially wrapped sprite pixels below them:


The earliest possible frame that TH05 can start rendering the Stage 5 midboss on. Hiding the text layer reveals how master.lib did in fact "blindly" render the top part of her sprite to the bottom of the playfield. That's where her sprite starts before it is correctly wrapped around to the top of VRAM.
If we scrolled VRAM by another 200 pixels (and faked an equally shifted TRAM for demonstration purposes), we get an equally valid game scene that points out why a vertically scrolling PC-98 game must wrap all sprites at the vertical edges of VRAM to begin with.
Also, note how the HP bar has filled up quite a bit before the midboss can actually appear on screen.
VRAM contents of the first possible frame that TH05's Stage 5 midboss can appear on, at their original scrolling position. Also featuring the 64×64 bounding box of the midboss sprite.VRAM contents of the first possible frame that TH05's Stage 5 midboss can appear on, scrolled down by a further 200 pixels. Also featuring the 64×64 bounding box of the midboss sprite.

And that's how the lowest possible top Y coordinate for sprites blitted using the master.lib super_roll_*() functions during the scrolling portions of TH02, TH04, and TH05 is not 0, but -16. Any lower, and you would actually see some of the sprite's upper pixels at the bottom of the playfield, as there are no more opaque black text cells to cover them. Theoretically, you could lower this number for some animation frames that start with multiple rows of transparent pixels, but I thankfully haven't found any instance of ZUN using such a hack. So far, at least… :godzun:
Visualized like that, it all looks quite simple and logical, but for days, I did not realize that these sprites were rendered to a scrolling VRAM. This led to a much more complicated initial explanation involving the invisible extra space of VRAM between offsets 0x7D00 and 0x7FFF that effectively grant a hidden additional 9.6 lines below the playfield. Or even above, since PC-98 hardware ignores the highest bit of any offset into a VRAM bitplane segment (& 0x7FFF), which prevents blitting operations from accidentally reaching into a different bitplane. Together with the aforementioned rows of transparent pixels at the top of these midboss sprites, the math would have almost worked out exactly. :tannedcirno:

The need for manual clipping also applies to the X-axis. Due to the lack of scrolling in this dimension, the boundaries there are much more straightforward though. The minimum left coordinate of a sprite can't fall below 0 because any smaller coordinate would wrap around into the 📝 tile source area and overwrite some of the pixels there, which we obviously don't want to re-blit every frame. Similarly, the right coordinate must not extend into the HUD, which starts at 448 pixels.
The last part might be surprising if you aren't familiar with the PC-98 text chip. Contrary to the CGA and VGA text modes of IBM-compatibles, PC-98 text cells can only use a single color for either their foreground or background, with the other pixels being transparent and always revealing the pixels in VRAM below. If you look closely at the HUD in the images above, you can see how the background of cells with gaiji glyphs is slightly brighter (◼ #100) than the opaque black cells (◼ #000) surrounding them. This rather custom color clearly implies that those pixels must have been rendered by the graphics GDC. If any other sprite was rendered below the HUD, you would equally see it below the glyphs.

So in the end, I did find the clear and logical system I was looking for, and managed to reduce the new clipping conditions down to a set of basic rules for each edge. Unfortunately, we also need a second macro for each edge to differentiate between sprites that are smaller or larger than the playfield border, which is treated as either 32×32 (for super_roll_*()) or 32×16 (for non-"rolling" super_*() functions). Since smaller sprites can be fully contained within this border, the games can stop rendering them as soon as their bottom-right coordinate is no longer seen within the playfield, by comparing against the clipping boundaries with <= and >=. For example, a 16×16 sprite would be completely invisible once it reaches (16, 0), so it would still be rendered at (17, 1). A larger sprite during the scrolling part of a stage, like, say, the 64×64 midbosses, would still be rendered if their top-left coordinate was (0, -16), so ZUN used < and > comparisons to at least get an additional pixel before having to stop rendering such a sprite. Turbo C++ 4.0J sadly can't constant-fold away such a difference in comparison operators.

And for the most part, ZUN did follow this system consistently. Except for, of course, the typical mistakes you make when faced with such manual decisions, like how he treated TH04's Stage 4 midboss as a "small" sprite below 32×32 pixels (it's 64×64), losing that precious one extra pixel. Or how the entire rendering code for the 48×48 boss explosion sprite pretends that it's actually 64×64 pixels large, which causes even the initial transformation into screen space to be misaligned from the get-go. :zunpet: But these are additional bugs on top of the single one that led to all this research.
Because that's what this is, a bug. 🐞 Every resulting pixel boundary is a systematic result of master.lib's unfortunate lack of clipping. It's as much of a bug as TH01's byte-aligned rendering of entities whose internal position is not byte-aligned. In both cases, the entities are alive, simulated, and partake in collision detection, but their rendered appearance doesn't accurately reflect their internal position.
Initially, I classified 📝 the sudden pop-in of TH05's Stage 5 midboss as a quirk because we had no conclusive evidence that this wasn't intentional, but now we do. There have been multiple explanations for why ZUN put borders around the playfield, but master.lib's lack of sprite clipping might be the biggest reason.

And just like byte-aligned rendering, the clipping conditions can easily be removed when porting the game away from PC-98 hardware. That's also what uth05win chose to do: By using OpenGL and not having to rely on hardware scrolling, it can simply place every sprite as a textured quad at its exact position in screen space, and then draw the black playfield borders on top in the end to clip everything in a single draw call. This way, the Stage 5 midboss can smoothly fly into the playfield, just as defined by its movement code:

The entire smooth Stage 5 midboss entrance animation as shown in uth05win. If the simultaneous appearance of the Enemy!! label doesn't lend further proof to this having been ZUN's actual intention, I don't know what will.

Meanwhile, I designed the interface of the 📝 generic blitter used in the TH01 Anniversary Edition entirely around clipping the blitted sprite at any explicit combination of VRAM edges. This was nothing I tacked on in the end, but a core aspect that informed the architecture of the code from the very beginning. You really want to have one and only one place where sprite clipping is done right – and only once per sprite, regardless of how many bitplanes you want to write to.


Which brings us to the goal that the final ¼ of this push went toward. I thought I was going to start cleaning up the 📝 player movement and rendering code, but that turned out too complicated for that amount of time – especially if you want to start with just cleanup, preserving all original bugs for the time being.
Fixing and smoothening player and Orb movement would be the next big task in Anniversary Edition development, needing about 3 pushes. It would start with more performance research into runtime-shifting of larger sprites, followed by extending my generic blitter according to the results, writing new optimized loaders for the original image formats, and finally rewriting all rendering code accordingly. With that code in place, we can then start cleaning up and fixing the unique code for each boss, one by one.

Until that's funded, the code still contains a few smaller and easier pieces of code that are equally related to rendering bugs, but could be dealt with in a more incremental way. Line rendering is one of those, and first needs some refactoring of every call site, including 📝 the rotating squares around Mima and 📝 YuugenMagan's pentagram. So far, I managed to remove another 1,360 bytes from the binary within this final ¼ of a push, but there's still quite a bit to do in that regard.
This is the perfect kind of feature for smaller (micro-)transactions. Which means that we've now got meaningful TH01 code cleanup and Anniversary Edition subtasks at every price range, no matter whether you want to invest a lot or just a little into this goal.

If you can, because Ember2528 revealed the plan behind his Shuusou Gyoku contributions: A full-on Linux port of the game, which will be receiving all the funding it needs to happen. 🐧 Next up, therefore: Turning this into my main project within ReC98 for the next couple of months, and getting started by shipping the long-awaited first step towards that goal.
I've raised the cap to avoid the potential of rounding errors, which might prevent the last needed Shuusou Gyoku push from being correctly funded. I already had to pick the larger one of the two pending TH02 transactions for this push, because we would have mathematically ended up 1/25500 short of a full push with the smaller transaction. :onricdennat: And if I'm already at it, I might as well free up enough capacity to potentially ship the complete OpenGL backend in a single delivery, which is currently estimated to cost 7 pushes in total.

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🎉 After almost 3 years, TH04 finally caught up to TH05 and is now 100% position-independent as well! 🎉

For a refresher on what this means and does not mean, check the announcements from back in 2019 and 2020 when we chased the goal for TH05's 📝 OP.EXE and 📝 the rest of the game. These also feature some demo videos that show off the kind of mods you were able to efficiently code back then. With the occasional reverse-engineering attention it received over the years, TH04's code should now be slightly easier to work with than TH05's was back in the day. Although not by much – TH04 has remained relatively unpopular among backers, and only received more than the funded attention because it shares most of its core code with the more popular TH05. Which, coincidentally, ended up becoming 📝 the reason for getting this done now.
Not that it matters a lot. Ever since we reached 100% PI for TH05, community and backer interest in position independence has dropped to near zero. We just didn't end up seeing the expected large amount of community-made mods that PI was meant to facilitate, and even the 📝 100% decompilation of TH01 changed nothing about that. But that's OK; after all, I do appreciate the business of continually getting commissioned for all the 📝 large-scale mods. Not focusing on PI is also the correct choice for everyone who likes reading these blog posts, as it often means that I can't go that much into detail due to cutting corners and piling up technical debt left and right.

Surprisingly, this only took 1.25 pushes, almost twice as fast as expected. As that's closer to 1 push than it is to 2, I'm OK with releasing it like this – especially since it was originally meant to come out three days ago. 🍋 Unfortunately, it was delayed thanks to surprising website bugs and a certain piece of code that was way more difficult to document than it was to decompile… The next push will have slightly less content in exchange, though.


📝 P0240 and P0241 already covered the final remaining structures, so I only needed to do some superficial RE to prove the remaining numeric literals as either constants or memory addresses. For example, I initially thought I'd have to decompile the dissolve animations in the staff roll, but I only needed to identify a single function pointer type to prove all false positives as screen coordinates there. Now, the TH04 staff roll would be another fast and cheap decompilation, similar to the custom entity types of TH04. (And TH05 as well!)

The one piece of code I did have to decompile was Stage 4's carpet lighting animation, thanks to hex literals that were way too complicated to leave in ASM. And this one probably takes the crown for TH04's worst set of landmines and bloat that still somehow results in no observable bugs or quirks.
This animation starts at frame 1664, roughly 29.5 seconds into the stage, and quickly turns the stage background into a repeated row of dark-red plaid carpet tiles by moving out from the center of the playfield towards the edges. Afterward, the animation repeats with a brighter set of tiles that is then used for the rest of the stage. As I explained 📝 a while ago in the context of TH02, the stage tile and map formats in PC-98 Touhou can't express animations, so all of this needed to be hardcoded in the binary.

A row of the carpet tiles from TH04's Stage 4, at the lowest light levelA row of the carpet tiles from TH04's Stage 4, at the medium light levelA row of the carpet tiles from TH04's Stage 4, at the highest light level
The repeating 384×16 row of carpet tiles at the beginning of TH04's Stage 4 in all three light levels, shown twice for better visibility.

And ZUN did start out making the right decision by only using fully-lit carpet tiles for all tile sections defined in ST03.MAP. This way, the animation can simply disable itself after it completed, letting the rest of the stage render normally and use new tile sections that are only defined for the final light level. This means that the "initial" dark version of the carpet is as much a result of hardcoded tile manipulation as the animation itself.
But then, ZUN proceeded to implement it all by directly manipulating the ring buffer of on-screen tiles. This is the lowest level before the tiles are rendered, and rather detached from the defined content of the 📝 .MAP tile sections. Which leads to a whole lot of problems:

  1. If you decide to do this kind of tile ring modification, it should ideally happen at a very specific point: after scrolling in new tiles into the ring buffer, but before blitting any scrolled or invalidated tiles to VRAM based on the ring buffer. Which is not where ZUN chose to put it, as he placed the call to the stage-specific render function after both of those operations. :zunpet: By the time the function is called, the tile renderer has already blitted a few lines of the fully-lit carpet tiles from the defined .MAP tile section, matching the scroll speed. Fortunately, these are hidden behind the black TRAM cells above and below the playfield…

  2. Still, the code needs to get rid of them before they would become visible. ZUN uses the regular tile invalidation function for this, which will only cause actual redraws on the next frame. Again, the tile rendering call has already happened by the time the Stage 4-specific rendering function gets called.
    But wait, this game also flips VRAM pages between frames to provide a tear-free gameplay experience. This means that the intended redraw of the new tiles actually hits the wrong VRAM page. :tannedcirno: And sure, the code does attempt to invalidate these newly blitted lines every frame – but only relative to the current VRAM Y coordinate that represents the top of the hardware-scrolled screen. Once we're back on the original VRAM page on the next frame, the lines we initially set out to remove could have already scrolled past that point, making it impossible to ever catch up with them in this way.
    The only real "solution": Defining the height of the tile invalidation rectangle at 3× the scroll speed, which ensures that each invalidation call covers 3 frames worth of newly scrolled-in lines. This is not intuitive at all, and requires an understanding of everything I have just written to even arrive at this conclusion. Needless to say that ZUN didn't comprehend it either, and just hardcoded an invalidation height that happened to be enough for the small scroll speeds defined in ST03.STD for the first 30 seconds of the stage.

  3. The effect must consistently modify the tile ring buffer to "fix" any new tiles, overriding them with the intended light level. During the animation, the code not only needs to set the old light level for any tiles that are still waiting to be replaced, but also the new light level for any tiles that were replaced – and ZUN forgot the second part. :zunpet: As a result, newly scrolled-in tiles within the already animated area will "remain" untouched at light level 2 if the scroll speed is fast enough during the transition from light level 0 to 1.

All that means that we only have to raise the scroll speed for the effect to fall apart. Let's try, say, 4 pixels per frame rather than the original 0.25:

By hiding the text RAM layer and revealing what's below the usually opaque black cells above and below the playfield, we can observe all three landmines – 1) and 2) throughout light level 0, and 3) during the transition from level 0 to 1.

All of this could have been so much simpler and actually stable if ZUN applied the tile changes directly onto the .MAP. This is a much more intuitive way of expressing what is supposed to happen to the map, and would have reduced the code to the actually necessary tile changes for the first frame and each individual frame of the animation. It would have still required a way to force these changes into the tile ring buffer, but ZUN could have just used his existing full-playfield redraw functions for that. In any case, there would have been no need for any per-frame tile fixing and redrawing. The CPU cycles saved this way could have then maybe been put towards writing the tile-replacing part of the animation in C++ rather than ASM…


Wow, that was an unreasonable amount of research into a feature that superficially works fine, just because its decompiled code didn't make sense. :onricdennat: To end on a more positive note, here are some minor new discoveries that might actually matter to someone:

Next up: ¾ of a push filled with random boilerplate, finalization, and TH01 code cleanup work, while I finish the preparations for Shuusou Gyoku's OpenGL backend. This month, everything should finally work out as intended: I'll complete both tasks in parallel, ship the former to free up the cap, and then ship the latter once its 5th push is fully funded.

📝 Posted:
🚚 Summary of:
P0240, P0241
Commits:
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Well, well. My original plan was to ship the first step of Shuusou Gyoku OpenGL support on the next day after this delivery. But unfortunately, the complications just kept piling up, to a point where the required solutions definitely blow the current budget for that goal. I'm currently sitting on over 70 commits that would take at least 5 pushes to deliver as a meaningful release, and all of that is just rearchitecting work, preparing the game for a not too Windows-specific OpenGL backend in the first place. I haven't even written a single line of OpenGL yet… 🥲
This shifts the intended Big Release Month™ to June after all. Now I know that the next round of Shuusou Gyoku features should better start with the SC-88Pro recordings, which are much more likely to get done within their current budget. At least I've already completed the configuration versioning system required for that goal, which leaves only the actual audio part.

So, TH04 position independence. Thanks to a bit of funding for stage dialogue RE, non-ASCII translations will soon become viable, which finally presents a reason to push TH04 to 100% position independence after 📝 TH05 had been there for almost 3 years. I haven't heard back from Touhou Patch Center about how much they want to be involved in funding this goal, if at all, but maybe other backers are interested as well.
And sure, it would be entirely possible to implement non-ASCII translations in a way that retains the layout of the original binaries and can be easily compared at a binary level, in case we consider translations to be a critical piece of infrastructure. This wouldn't even just be an exercise in needless perfectionism, and we only have to look to Shuusou Gyoku to realize why: Players expected that my builds were compatible with existing SpoilerAL SSG files, which was something I hadn't even considered the need for. I mean, the game is open-source 📝 and I made it easy to build. You can just fork the code, implement all the practice features you want in a much more efficient way, and I'd probably even merge your code into my builds then?
But I get it – recompiling the game yields just yet another build that can't be easily compared to the original release. A cheat table is much more trustworthy in giving players the confidence that they're still practicing the same original game. And given the current priorities of my backers, it'll still take a while for me to implement proof by replay validation, which will ultimately free every part of the community from depending on the original builds of both Seihou and PC-98 Touhou.

However, such an implementation within the original binary layout would significantly drive up the budget of non-ASCII translations, and I sure don't want to constantly maintain this layout during development. So, let's chase TH04 position independence like it's 2020, and quickly cover a larger amount of PI-relevant structures and functions at a shallow level. The only parts I decompiled for now contain calculations whose intent can't be clearly communicated in ASM. Hitbox visualizations or other more in-depth research would have to wait until I get to the proper decompilation of these features.
But even this shallow work left us with a large amount of TH04-exclusive code that had its worst parts RE'd and could be decompiled fairly quickly. If you want to see big TH04 finalization% gains, general TH04 progress would be a very good investment.


The first push went to the often-mentioned stage-specific custom entities that share a single statically allocated buffer. Back in 2020, I 📝 wrongly claimed that these were a TH05 innovation, but the system actually originated in TH04. Both games use a 26-byte structure, but TH04 only allocates a 32-element array rather than TH05's 64-element one. The conclusions from back then still apply, but I also kept wondering why these games used a static array for these entities to begin with. You know what they call an area of memory that you can cleanly repurpose for things? That's right, a heap! :tannedcirno: And absolutely no one would mind one additional heap allocation at the start of a stage, next to the ones for all the sprites and portraits.
However, we are still running in Real Mode with segmented memory. Accessing anything outside a common data segment involves modifying segment registers, which has a nonzero CPU cycle cost, and Turbo C++ 4.0J is terrible at optimizing away the respective instructions. Does this matter? Probably not, but you don't take "risks" like these if you're in a permanent micro-optimization mindset… :godzun:

In TH04, this system is used for:

  1. Kurumi's symmetric bullet spawn rays, fired from her hands towards the left and right edges of the playfield. These are rather infamous for being the last thing you see before 📝 the Divide Error crash that can happen in ZUN's original build. Capped to 6 entities.

  2. The 4 📝 bits used in Marisa's Stage 4 boss fight. Coincidentally also related to the rare Divide Error crash in that fight.

  3. Stage 4 Reimu's spinning orbs. Note how the game uses two different sets of sprites just to have two different outline colors. This was probably better than messing with the palette, which can easily cause unintended effects if you only have 16 colors to work with. Heck, I have an entire blog post tag just to highlight these cases. Capped to the full 32 entities.

  4. The chasing cross bullets, seen in Phase 14 of the same Stage 6 Yuuka fight. Featuring some smart sprite work, making use of point symmetry to achieve a fluid animation in just 4 frames. This is good-code in sprite form. Capped to 31 entities, because the 32nd custom entity during this fight is defined to be…

  5. The single purple pulsating and shrinking safety circle, seen in Phase 4 of the same fight. The most interesting aspect here is actually still related to the cross bullets, whose spawn function is wrongly limited to 32 entities and could theoretically overwrite this circle. :zunpet: This is strictly landmine territory though:

    • Yuuka never uses these bullets and the safety circle simultaneously
    • She never spawns more than 24 cross bullets
    • All cross bullets are fast enough to have left the screen by the time Yuuka restarts the corresponding subpattern
    • The cross bullets spawn at Yuuka's center position, and assign its Q12.4 coordinates to structure fields that the safety circle interprets as raw pixels. The game does try to render the circle afterward, but since Yuuka's static position during this phase is nowhere near a valid pixel coordinate, it is immediately clipped.

  6. The flashing lines seen in Phase 5 of the Gengetsu fight, telegraphing the slightly random bullet columns.

    The spawn column lines in the TH05 Gengetsu fight, in the first of their two flashing colors.The spawn column lines in the TH05 Gengetsu fight, in the second of their two flashing colors.

These structures only took 1 push to reverse-engineer rather than the 2 I needed for their TH05 counterparts because they are much simpler in this game. The "structure" for Gengetsu's lines literally uses just a single X position, with the remaining 24 bytes being basically padding. The only minor bug I found on this shallow level concerns Marisa's bits, which are clipped at the right and bottom edges of the playfield 16 pixels earlier than you would expect:


The remaining push went to a bunch of smaller structures and functions:


To top off the second push, we've got the vertically scrolling checkerboard background during the Stage 6 Yuuka fight, made up of 32×32 squares. This one deserves a special highlight just because of its needless complexity. You'd think that even a performant implementation would be pretty simple:

  1. Set the GRCG to TDW mode
  2. Set the GRCG tile to one of the two square colors
  3. Start with Y as the current scroll offset, and X as some indicator of which color is currently shown at the start of each row of squares
  4. Iterate over all lines of the playfield, filling in all pixels that should be displayed in the current color, skipping over the other ones
  5. Count down Y for each line drawn
  6. If Y reaches 0, reset it to 32 and flip X
  7. At the bottom of the playfield, change the GRCG tile to the other color, and repeat with the initial value of X flipped

The most important aspect of this algorithm is how it reduces GRCG state changes to a minimum, avoiding the costly port I/O that we've identified time and time again as one of the main bottlenecks in TH01. With just 2 state variables and 3 loops, the resulting code isn't that complex either. A naive implementation that just drew the squares from top to bottom in a single pass would barely be simpler, but much slower: By changing the GRCG tile on every color, such an implementation would burn a low 5-digit number of CPU cycles per frame for the 12×11.5-square checkerboard used in the game.
And indeed, ZUN retained all important aspects of this algorithm… but still implemented it all in ASM, with a ridiculous layer of x86 segment arithmetic on top? :zunpet: Which blows up the complexity to 4 state variables, 5 nested loops, and a bunch of constants in unusual units. I'm not sure what this code is supposed to optimize for, especially with that rather questionable register allocation that nevertheless leaves one of the general-purpose registers unused. :onricdennat: Fortunately, the function was still decompilable without too many code generation hacks, and retains the 5 nested loops in all their goto-connected glory. If you want to add a checkerboard to your next PC-98 demo, just stick to the algorithm I gave above.
(Using a single XOR for flipping the starting X offset between 32 and 64 pixels is pretty nice though, I have to give him that.)


This makes for a good occasion to talk about the third and final GRCG mode, completing the series I started with my previous coverage of the 📝 RMW and 📝 TCR modes. The TDW (Tile Data Write) mode is the simplest of the three and just writes the 8×1 GRCG tile into VRAM as-is, without applying any alpha bitmask. This makes it perfect for clearing rectangular areas of pixels – or even all of VRAM by doing a single memset():

// Set up the GRCG in TDW mode.
outportb(0x7C, 0x80);

// Fill the tile register with color #7 (0111 in binary).
outportb(0x7E, 0xFF); // Plane 0: (B): (********)
outportb(0x7E, 0xFF); // Plane 1: (R): (********)
outportb(0x7E, 0xFF); // Plane 2: (G): (********)
outportb(0x7E, 0x00); // Plane 3: (E): (        )

// Set the 32 pixels at the top-left corner of VRAM to the exact contents of
// the tile register, effectively repeating the tile 4 times. In TDW mode, the
// GRCG ignores the CPU-supplied operand, so we might as well just pass the
// contents of a register with the intended width. This eliminates useless load
// instructions in the compiled assembly, and even sort of signals to readers
// of this code that we do not care about the source value.
*reinterpret_cast<uint32_t far *>(MK_FP(0xA800, 0)) = _EAX;

// Fill the entirety of VRAM with the GRCG tile. A simple C one-liner that will
// probably compile into a single `REP STOS` instruction. Unfortunately, Turbo
// C++ 4.0J only ever generates the 16-bit `REP STOSW` here, even when using
// the `__memset__` intrinsic and when compiling in 386 mode. When targeting
// that CPU and above, you'd ideally want `REP STOSD` for twice the speed.
memset(MK_FP(0xA800, 0), _AL, ((640 / 8) * 400));

However, this might make you wonder why TDW mode is even necessary. If it's functionally equivalent to RMW mode with a CPU-supplied bitmask made up entirely of 1 bits (i.e., 0xFF, 0xFFFF, or 0xFFFFFFFF), what's the point? The difference lies in the hardware implementation: If all you need to do is write tile data to VRAM, you don't need the read and modify parts of RMW mode which require additional processing time. The PC-9801 Programmers' Bible claims a speedup of almost 2× when using TDW mode over equivalent operations in RMW mode.
And that's the only performance claim I found, because none of these old PC-98 hardware and programming books did any benchmarks. Then again, it's not too interesting of a question to benchmark either, as the byte-aligned nature of TDW blitting severely limits its use in a game engine anyway. Sure, maybe it makes sense to temporarily switch from RMW to TDW mode if you've identified a large rectangular and byte-aligned section within a sprite that could be blitted without a bitmask? But the necessary identification work likely nullifies the performance gained from TDW mode, I'd say. In any case, that's pretty deep micro-optimization territory. Just use TDW mode for the few cases it's good at, and stick to RMW mode for the rest.

So is this all that can be said about the GRCG? Not quite, because there are 4 bits I haven't talked about yet…


And now we're just 5.37% away from 100% position independence for TH04! From this point, another 2 pushes should be enough to reach this goal. It might not look like we're that close based on the current estimate, but a big chunk of the remaining numbers are false positives from the player shot control functions. Since we've got a very special deadline to hit, I'm going to cobble these two pushes together from the two current general subscriptions and the rest of the backlog. But you can, of course, still invest in this goal to allow the existing contributions to go to something else.
… Well, if the store was actually open. :thonk: So I'd better continue with a quick task to free up some capacity sooner rather than later. Next up, therefore: Back to TH02, and its item and player systems. Shouldn't take that long, I'm not expecting any surprises there. (Yeah, I know, famous last words…)

📝 Posted:
🚚 Summary of:
P0235, P0236, P0237
Commits:
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💰 Funded by:
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So, TH02! Being the only game whose main binary hadn't seen any dedicated attention ever, we get to start the TH02-related blog posts at the very beginning with the most foundational pieces of code. The stage tile system is the best place to start here: It not only blocks every entity that is rendered on top of these tiles, but is curiously placed right next to master.lib code in TH02, and would need to be separated out into its own translation unit before we can do the same with all the master.lib functions.

In late 2018, I already RE'd 📝 TH04's and TH05's stage tile implementation, but haven't properly documented it on this blog yet, so this post is also going to include the details that are unique to those games. On a high level, the stage tile system works identically in all three games:

The differences between the three games can best be summarized in a table:

:th02: TH02 :th04: TH04 :th05: TH05
Tile image file extension .MPN
Tile section format .MAP
Tile section order defined as part of .DT1 .STD
Tile section index format 0-based ID 0-based ID × 2
Tile image index format Index between 0 and 100, 1 byte VRAM offset in tile source area, 2 bytes
Scroll speed control Hardcoded Part of the .STD format, defined per referenced tile section
Redraw granularity Full tiles (16×16) Half tiles (16×8)
Rows per tile section 8 5
Maximum number of tile sections 16 32
Lowest number of tile sections used 5 (Stage 3 / Extra) 8 (Stage 6) 11 (Stage 2 / 4)
Highest number of tile sections used 13 (Stage 4) 19 (Extra) 24 (Stage 3)
Maximum length of a map 320 sections (static buffer) 256 sections (format limitation)
Shortest map 14 sections (Stage 5) 20 sections (Stage 5) 15 sections (Stage 2)
Longest map 143 sections (Stage 4) 95 sections (Stage 4) 40 sections (Stage 1 / 4 / Extra)

The most interesting part about stage tiles is probably the fact that some of the .MAP files contain unused tile sections. 👀 Many of these are empty, duplicates, or don't really make sense, but a few are unique, fit naturally into their respective stage, and might have been part of the map during development. In TH02, we can find three unused sections in Stage 5:

Section 0 of TH02's STAGE4.MAPSection 1 of TH02's STAGE4.MAPSection 2 of TH02's STAGE4.MAPSection 3 of TH02's STAGE4.MAPSection 4 of TH02's STAGE4.MAPSection 5 of TH02's STAGE4.MAPSection 6 of TH02's STAGE4.MAPSection 7 of TH02's STAGE4.MAP
The non-empty tile sections defined in TH02's STAGE4.MAP, showing off three unused ones.
These unused tile sections are much more common in the later games though, where we can find them in TH04's Stage 3, 4, and 5, and TH05's Stage 1, 2, and 4. I'll document those once I get to finalize the tile rendering code of these games, to leave some more content for that blog post. TH04/TH05 tile code would be quite an effective investment of your money in general, as most of it is identical across both games. Or how about going for a full-on PC-98 Touhou map viewer and editor GUI?


Compared to TH04 and TH05, TH02's stage tile code definitely feels like ZUN was just starting to understand how to pull off smooth vertical scrolling on a PC-98. As such, it comes with a few inefficiencies and suboptimal implementation choices:

Even though this was ZUN's first attempt at scrolling tiles, he already saw it fit to write most of the code in assembly. This was probably a reaction to all of TH01's performance issues, and the frame rate reduction workarounds he implemented to keep the game from slowing down too much in busy places. "If TH01 was all C++ and slow, TH02 better contain more ASM code, and then it will be fast, right?" :zunpet:
Another reason for going with ASM might be found in the kind of documentation that may have been available to ZUN. Last year, the PC-98 community discovered and scanned two new game programming tutorial books from 1991 (1, 2). Their example code is not only entirely written in assembly, but restricts itself to the bare minimum of x86 instructions that were available on the 8086 CPU used by the original PC-9801 model 9 years earlier. Such code is not only suboptimal on the 486, but can often be actually worse than what your C++ compiler would generate. TH02 is where the trend of bad hand-written ASM code started, and it 📝 only intensified in ZUN's later games. So, don't copy code from these books unless you absolutely want to target the earlier 8086 and 286 models. Which, 📝 as we've gathered from the recent blitting benchmark results, are not all too common among current real-hardware owners.
That said, all that ASM code really only impacts readability and maintainability. Apart from the aforementioned issues, the algorithms themselves are mostly fine – especially since most EGC and GRCG operations are decently batched this time around, in contrast to TH01.


Luckily, the tile functions merely use inline assembly within a typical C function and can therefore be at least part of a C++ source file, even if the result is pretty ugly. This time, we can actually be sure that they weren't written directly in a .ASM file, because they feature x86 instruction encodings that can only be generated with Turbo C++ 4.0J's inline assembler, not with TASM. The same can't unfortunately be said about the following function in the same segment, which marks the tiles covered by the spark sprites for redrawing. In this one, it took just one dumb hand-written ASM inconsistency in the function's epilog to make the entire function undecompilable.
The standard x86 instruction sequence to set up a stack frame in a function prolog looks like this:

PUSH	BP
MOV 	BP, SP
SUB 	SP, ?? ; if the function needs the stack for local variables
When compiling without optimizations, Turbo C++ 4.0J will replace this sequence with a single ENTER instruction. That one is two bytes smaller, but much slower on every x86 CPU except for the 80186 where it was introduced.
In functions without local variables, BP and SP remain identical, and a single POP BP is all that's needed in the epilog to tear down such a stack frame before returning from the function. Otherwise, the function needs an additional MOV SP, BP instruction to pop all local variables. With x86 being the helpful CISC architecture that it is, the 80186 also introduced the LEAVE instruction to perform both tasks. Unlike ENTER, this single instruction is faster than the raw two instructions on a lot of x86 CPUs (and even current ones!), and it's always smaller, taking up just 1 byte instead of 3.
So what if you use LEAVE even if your function doesn't use local variables? :thonk: The fact that the instruction first does the equivalent of MOV SP, BP doesn't matter if these registers are identical, and who cares about the additional CPU cycles of LEAVE compared to just POP BP, right? So that's definitely something you could theoretically do, but not something that any compiler would ever generate.

And so, TH02 MAIN.EXE decompilation already hits the first brick wall after two pushes. Awesome! :godzun: Theoretically, we could slowly mash through this wall using the 📝 code generator. But having such an inconsistency in the function epilog would mean that we'd have to keep Turbo C++ 4.0J from emitting any epilog or prolog code so that we can write our own. This means that we'd once again have to hide any use of the SI and DI registers from the compiler… and doing that requires code generation macros for 22 of the 49 instructions of the function in question, almost none of which we currently have. So, this gets quite silly quite fast, especially if we only need to do it for one single byte.

Instead, wouldn't it be much better if we had a separate build step between compile and link time that allowed us to replicate mistakes like these by just patching the compiled .OBJ files? These files still contain the names of exported functions for linking, which would allow us to look up the code of a function in a robust manner, navigate to specific instructions using a disassembler, replace them, and write the modified .OBJ back to disk before linking. Such a system could then naturally expand to cover all other decompilation issues, culminating in a full-on optimizer that could even recreate ZUN's self-modifying code. At that point, we would have sealed away all of ZUN's ugly ASM code within a separate build step, and could finally decompile everything into readable C++.

Pulling that off would require a significant tooling investment though. Patching that one byte in TH02's spark invalidation function could be done within 1 or 2 pushes, but that's just one issue, and we currently have 32 other .ASM files with undecompilable code. Also, note that this is fundamentally different from what we're doing with the debloated branch and the Anniversary Editions. Mistake patching would purely be about having readable code on master that compiles into ZUN's exact binaries, without fixing weird code. The Anniversary Editions go much further and rewrite such code in a much more fundamental way, improving it further than mistake patching ever could.
Right now, the Anniversary Editions seem much more popular, which suggests that people just want 100% RE as fast as possible so that I can start working on them. In that case, why bother with such undecompilable functions, and not just leave them in raw and unreadable x86 opcode form if necessary… :tannedcirno: But let's first see how much backer support there actually is for mistake patching before falling back on that.

The best part though: Once we've made a decision and then covered TH02's spark and particle systems, that was it, and we will have already RE'd all ZUN-written PC-98-specific blitting code in this game. Every further sprite or shape is rendered via master.lib, and is thus decently abstracted. Guess I'll need to update 📝 the assessment of which PC-98 Touhou game is the easiest to port, because it sure isn't TH01, as we've seen with all the work required for the first Anniversary Edition build.


Until then, there are still enough parts of the game that don't use any of the remaining few functions in the _TEXT segment. Previously, I mentioned in the 📝 status overview blog post that TH02 had a seemingly weird sprite system, but the spark and point popup (〇一二三四五六七八九十×÷) structures showed that the game just stores the current and previous position of its entities in a slightly different way compared to the rest of PC-98 Touhou. Instead of having dedicated structure fields, TH02 uses two-element arrays indexed with the active VRAM page. Same thing, and such a pattern even helps during RE since it's easy to spot once you know what to look for.
There's not much to criticize about the point popup system, except for maybe a landmine that causes sprite glitches when trying to display more than 99,990 points. Sadly, the final push in this delivery was rounded out by yet another piece of code at the opposite end of the quality spectrum. The particle and smear effects for Reimu's bomb animations consist almost entirely of assembly bloat, which would just be replaced with generic calls to the generic blitter in this game's future Anniversary Edition.

If I continue to decompile TH02 while avoiding the brick wall, items would be next, but they probably require two pushes. Next up, therefore: Integrating Stripe as an alternative payment provider into the order form. There have been at least three people who reported issues with PayPal, and Stripe has been working much better in tests. In the meantime, here's a temporary Stripe order link for everyone. This one is not connected to the cap yet, so please make sure to stay within whatever value is currently shown on the front page – I will treat any excess money as donations. :onricdennat: If there's some time left afterward, I might also add some small improvements to the TH01 Anniversary Edition.

📝 Posted:
🚚 Summary of:
P0227, P0228
Commits:
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💰 Funded by:
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Starting the year with a delivery that wasn't delayed until the last day of the month for once, nice! Still, very soon and high-maintenance did not go well together…

It definitely wasn't Sara's fault though. As you would expect from a Stage 1 Boss, her code was no challenge at all. Most of the TH02, TH04, and TH05 bosses follow the same overall structure, so let's introduce a new table to replace most of the boilerplate overview text:

Phase # Patterns HP boundary Timeout condition
Sprite of Sara in TH05 (Entrance) 4,650 288 frames
2 4 2,550 2,568 frames (= 32 patterns)
3 4 450 5,296 frames (= 24 patterns)
4 1 0 1,300 frames
Total 9 9,452 frames

And that's all the gameplay-relevant detail that ZUN put into Sara's code. It doesn't even make sense to describe the remaining patterns in depth, as their groups can significantly change between difficulties and rank values. The 📝 general code structure of TH05 bosses won't ever make for good-code, but Sara's code is just a lesser example of what I already documented for Shinki.
So, no bugs, no unused content, only inconsequential bloat to be found here, and less than 1 push to get it done… That makes 9 PC-98 Touhou bosses decompiled, with 22 to go, and gets us over the sweet 50% overall finalization mark! 🎉 And sure, it might be possible to pass through the lasers in Sara's final pattern, but the boss script just controls the origin, angle, and activity of lasers, so any quirk there would be part of the laser code… wait, you can do what?!?


TH05 expands TH04's one-off code for Yuuka's Master and Double Sparks into a more featureful laser system, and Sara is the first boss to show it off. Thus, it made sense to look at it again in more detail and finalize the code I had purportedly 📝 reverse-engineered over 4 years ago. That very short delivery notice already hinted at a very time-consuming future finalization of this code, and that prediction certainly came true. On the surface, all of the low-level laser ray rendering and collision detection code is undecompilable: It uses the SI and DI registers without Turbo C++'s safety backups on the stack, and its helper functions take their input and output parameters from convenient registers, completely ignoring common calling conventions. And just to raise the confusion even further, the code doesn't just set these registers for the helper function calls and then restores their original values, but permanently shifts them via additions and subtractions. Unfortunately, these convenient registers also include the BP base pointer to the stack frame of a function… and shifting that register throws any intuition behind accessed local variables right out of the window for a good part of the function, requiring a correctly shifted view of the stack frame just to make sense of it again. :godzun: How could such code even have been written?! This goes well beyond the already wrong assumption that using more stack space is somehow bad, and straight into the territory of self-inflicted pain.

So while it's not a lot of instructions, it's quite dense and really hard to follow. This code would really benefit from a decompilation that anchors all this madness as much as possible in existing C++ structures… so let's decompile it anyway? :tannedcirno:
Doing so would involve emitting lots of raw machine code bytes to hide the SI and DI registers from the compiler, but I already had a certain 📝 batshit insane compiler bug workaround abstraction lying around that could make such code more readable. Hilariously, it only took this one additional use case for that abstraction to reveal itself as premature and way too complicated. :onricdennat: Expanding the core idea into a full-on x86 instruction generator ended up simplifying the code structure a lot. All we really want there is a way to set all potential parameters to e.g. a specific form of the MOV instruction, which can all be expressed as the parameters to a force-inlined __emit__() function. Type safety can help by providing overloads for different operand widths here, but there really is no need for classes, templates, or explicit specialization of templates based on classes. We only need a couple of enums with opcode, register, and prefix constants from the x86 reference documentation, and a set of associated macros that token-paste pseudoregisters onto the prefixes of these enum constants.
And that's how you get a custom compile-time assembler in a 1994 C++ compiler and expand the limits of decompilability even further. What's even truly left now? Self-modifying code, layout tricks that can't be replicated with regularly structured control flow… and that's it. That leaves quite a few functions I previously considered undecompilable to be revisited once I get to work on making this game more portable.

With that, we've turned the low-level laser code into the expected horrible monstrosity that exposes all the hidden complexity in those few ASM instructions. The high-level part should be no big deal now… except that we're immediately bombarded with Fixup overflow errors at link time? Oh well, time to finally learn the true way of fixing this highly annoying issue in a second new piece of decompilation tech – and one that might actually be useful for other x86 Real Mode retro developers at that.
Earlier in the RE history of TH04 and TH05, I often wrote about the need to split the two original code segments into multiple segments within two groups, which makes it possible to slot in code from different translation units at arbitrary places within the original segment. If we don't want to define a unique segment name for each of these slotted-in translation units, we need a way to set custom segment and group names in C land. Turbo C++ offers two #pragmas for that:

For the most part, these #pragmas work well, but they seemed to not help much when it came to calling near functions declared in different segments within the same group. It took a bit of trial and error to figure out what was actually going on in that case, but there is a clear logic to it:

Summarized in code:

#pragma option -zCfoo_TEXT -zPfoo

void bar(void);
void near qux(void); // defined somewhere else, maybe in a different segment

#pragma codeseg baz_TEXT baz

// Despite the segment change in the line above, this function will still be
// put into `foo_TEXT`, the active segment during the first appearance of the
// function name.
void bar(void) {
}

// This function hasn't been declared yet, so it will go into `baz_TEXT` as
// expected.
void baz(void) {
	// This `near` function pointer will be calculated by subtracting the
	// flat/linear address of qux() inside the binary from the base address
	// of qux()'s declared segment, i.e., `foo_TEXT`.
	void (near *ptr_to_qux)(void) = qux;
}

So yeah, you might have to put #pragma codeseg into your headers to tell the linker about the correct segment of a near function in advance. 🤯 This is an important insight for everyone using this compiler, and I'm shocked that none of the Borland C++ books documented the interaction of code segment definitions and near references at least at this level of clarity. The TASM manuals did have a few pages on the topic of groups, but that syntax obviously doesn't apply to a C compiler. Fixup overflows in particular are such a common error and really deserved better than the unhelpful 🤷 of an explanation that ended up in the User's Guide. Maybe this whole technique of custom code segment names was considered arcane even by 1993, judging from the mere three sentences that #pragma codeseg was documented with? Still, it must have been common knowledge among Amusement Makers, because they couldn't have built these exact binaries without knowing about these details. This is the true solution to 📝 any issues involving references to near functions, and I'm glad to see that ZUN did not in fact lie to the compiler. 👍


OK, but now the remaining laser code compiles, and we get to write C++ code to draw some hitboxes during the two collision-detected states of each laser. These confirm what the low-level code from earlier already uncovered: Collision detection against lasers is done by testing a 12×12-pixel box at every 16 pixels along the length of a laser, which leaves obvious 4-pixel gaps at regular intervals that the player can just pass through. :zunpet: This adds 📝 yet 📝 another 📝 quirk to the growing list of quirks that were either intentional or must have been deliberately left in the game after their initial discovery. This is what constants were invented for, and there really is no excuse for not using them – especially during intoxicated coding, and/or if you don't have a compile-time abstraction for Q12.4 literals.

When detecting laser collisions, the game checks the player's single center coordinate against any of the aforementioned 12×12-pixel boxes. Therefore, it's correct to split these 12×12 pixels into two 6×6-pixel boxes and assign the other half to the player for a more natural visualization. Always remember that hitbox visualizations need to keep all colliding entities in mind – 📝 assigning a constant-sized hitbox to "the player" and "the bullets" will be wrong in most other cases.

Using subpixel coordinates in collision detection also introduces a slight inaccuracy into any hitbox visualization recorded in-engine on a 16-color PC-98. Since we have to render discrete pixels, we cannot exactly place a Q12.4 coordinate in the 93.75% of cases where the fractional part is non-zero. This is why pretty much every laser segment hitbox in the video above shows up as 7×7 rather than 6×6: The actual W×H area of each box is 13 pixels smaller, but since the hitbox lies between these pixels, we cannot indicate where it lies exactly, and have to err on the side of caution. It's also why Reimu's box slightly changes size as she moves: Her non-diagonal movement speed is 3.5 pixels per frame, and the constant focused movement in the video above halves that to 1.75 pixels, making her end up on an exact pixel every 4 frames. Looking forward to the glorious future of displays that will allow us to scale up the playfield to 16× its original pixel size, thus rendering the game at its exact internal resolution of 6144×5888 pixels. Such a port would definitely add a lot of value to the game…

The remaining high-level laser code is rather unremarkable for the most part, but raises one final interesting question: With no explicitly defined limit, how wide can a laser be? Looking at the laser structure's 1-byte width field and the unsigned comparisons all throughout the update and rendering code, the answer seems to be an obvious 255 pixels. However, the laser system also contains an automated shrinking state, which can be most notably seen in Mai's wheel pattern. This state shrinks a laser by 2 pixels every 2 frames until it reached a width of 0. This presents a problem with odd widths, which would fall below 0 and overflow back to 255 due to the unsigned nature of this variable. So rather than, I don't know, treating width values of 0 as invalid and stopping at a width of 1, or even adding a condition for that specific case, the code just performs a signed comparison, effectively limiting the width of a shrinkable laser to a maximum of 127 pixels. :zunpet: This small signedness inconsistency now forces the distinction between shrinkable and non-shrinkable lasers onto every single piece of code that uses lasers. Yet another instance where 📝 aiming for a cinematic 30 FPS look made the resulting code much more complicated than if ZUN had just evenly spread out the subtraction across 2 frames. 🤷
Oh well, it's not as if any of the fixed lasers in the original scripts came close to any of these limits. Moving lasers are much more streamlined and limited to begin with: Since they're hardcoded to 6 pixels, the game can safely assume that they're always thinner than the 28 pixels they get gradually widened to during their decay animation.

Finally, in case you were missing a mention of hitboxes in the previous paragraph: Yes, the game always uses the aforementioned 12×12 boxes, regardless of a laser's width.

This video also showcases the 127-pixel limit because I wanted to include the shrink animation for a seamless loop.

That was what, 50% of this blog post just being about complications that made laser difficult for no reason? Next up: The first TH01 Anniversary Edition build, where I finally get to reap the rewards of having a 100% decompiled game and write some good code for once.

📝 Posted:
🚚 Summary of:
P0223, P0224, P0225
Commits:
139746c...371292d, 371292d...8118e61, 8118e61...4f85326
💰 Funded by:
rosenrose, Blue Bolt, Splashman, -Tom-, Yanga, Enderwolf, 32th System
🏷 Tags:

More than three months without any reverse-engineering progress! It's been way too long. Coincidentally, we're at least back with a surprising 1.25% of overall RE, achieved within just 3 pushes. The ending script system is not only more or less the same in TH04 and TH05, but actually originated in TH03, where it's also used for the cutscenes before stages 8 and 9. This means that it was one of the final pieces of code shared between three of the four remaining games, which I got to decompile at roughly 3× the usual speed, or ⅓ of the price.
The only other bargains of this nature remain in OP.EXE. The Music Room is largely equivalent in all three remaining games as well, and the sound device selection, ZUN Soft logo screens, and main/option menus are the same in TH04 and TH05. A lot of that code is in the "technically RE'd but not yet decompiled" ASM form though, so it would shift Finalized% more significantly than RE%. Therefore, make sure to order the new Finalization option rather than Reverse-engineering if you want to make number go up.

  1. General overview
  2. Game-specific differences
  3. Command reference
  4. Thoughts about translation support

So, cutscenes. On the surface, the .TXT files look simple enough: You directly write the text that should appear on the screen into the file without any special markup, and add commands to define visuals, music, and other effects at any place within the script. Let's start with the basics of how text is rendered, which are the same in all three games:


Superficially, the list of game-specific differences doesn't look too long, and can be summarized in a rather short table:

:th03: TH03 :th04: TH04 :th05: TH05
Script size limit 65536 bytes (heap-allocated) 8192 bytes (statically allocated)
Delay between every 2 bytes of text 1 frame by default, customizable via \v None
Text delay when holding ESC Varying speed-up factor None
Visibility of new text Immediately typed onto the screen Rendered onto invisible VRAM page, faded in on wait commands
Visibility of old text Unblitted when starting a new box Left on screen until crossfaded out with new text
Key binding for advancing the script Any key ⏎ Return, Shot, or ESC
Animation while waiting for an advance key None ⏎⃣, past right edge of current row
Inexplicable delays None 1 frame before changing pictures and after rendering new text boxes
Additional delay per interpreter loop 614.4 µs None 614.4 µs
The 614.4 µs correspond to the necessary delay for working around the repeated key up and key down events sent by PC-98 keyboards when holding down a key. While the absence of this delay significantly speeds up TH04's interpreter, it's also the reason why that game will stop recognizing a held ESC key after a few seconds, requiring you to press it again.

It's when you get into the implementation that the combined three systems reveal themselves as a giant mess, with more like 56 differences between the games. :zunpet: Every single new weird line of code opened up another can of worms, which ultimately made all of this end up with 24 pieces of bloat and 14 bugs. The worst of these should be quite interesting for the general PC-98 homebrew developers among my audience:


That brings us to the individual script commands… and yes, I'm going to document every single one of them. Some of their interactions and edge cases are not clear at all from just looking at the code.

Almost all commands are preceded by… well, a 0x5C lead byte. :thonk: Which raises the question of whether we should document it as an ASCII-encoded \ backslash, or a Shift-JIS-encoded ¥ yen sign. From a gaijin perspective, it seems obvious that it's a backslash, as it's consistently displayed as one in most of the editors you would actually use nowadays. But interestingly, iconv -f shift-jis -t utf-8 does convert any 0x5C lead bytes to actual ¥ U+00A5 YEN SIGN code points :tannedcirno:.
Ultimately, the distinction comes down to the font. There are fonts that still render 0x5C as ¥, but mainly do so out of an obvious concern about backward compatibility to JIS X 0201, where this mapping originated. Unsurprisingly, this group includes MS Gothic/Mincho, the old Japanese fonts from Windows 3.1, but even Meiryo and Yu Gothic/Mincho, Microsoft's modern Japanese fonts. Meanwhile, pretty much every other modern font, and freely licensed ones in particular, render this code point as \, even if you set your editor to Shift-JIS. And while ZUN most definitely saw it as a ¥, documenting this code point as \ is less ambiguous in the long run. It can only possibly correspond to one specific code point in either Shift-JIS or UTF-8, and will remain correct even if we later mod the cutscene system to support full-blown Unicode.

Now we've only got to clarify the parameter syntax, and then we can look at the big table of commands:

:th03: :th04: :th05: \@ Clears both VRAM pages by filling them with VRAM color 0.
🐞 In TH03 and TH04, this command does not update the internal text area background used for unblitting. This bug effectively restricts usage of this command to either the beginning of a script (before the first background image is shown) or its end (after no more new text boxes are started). See the image below for an example of using it anywhere else.
:th03: :th04: :th05: \b2 Sets the font weight to a value between 0 (raw font ROM glyphs) to 3 (very thicc). Specifying any other value has no effect.
:th04: :th05: 🐞 In TH04 and TH05, \b3 leads to glitched pixels when rendering half-width glyphs due to a bug in the newly micro-optimized ASM version of 📝 graph_putsa_fx(); see the image below for an example.
In these games, the parameter also directly corresponds to the graph_putsa_fx() effect function, removing the sanity check that was present in TH03. In exchange, you can also access the four dissolve masks for the bold font (\b2) by specifying a parameter between 4 (fewest pixels) to 7 (most pixels). Demo video below.
:th03: :th04: :th05: \c15 Changes the text color to VRAM color 15.
:th05: \c=,15 Adds a color map entry: If is the first code point inside the name area on a new line, the text color is automatically set to 15. Up to 8 such entries can be registered before overflowing the statically allocated buffer.
🐞 The comma is assumed to be present even if the color parameter is omitted.
:th03: :th04: :th05: \e0 Plays the sound effect with the given ID.
:th03: :th04: :th05: \f (no-op)
:th03: :th04: :th05: \fi1
\fo1
Calls master.lib's palette_black_in() or palette_black_out() to play a hardware palette fade animation from or to black, spending roughly 1 frame on each of the 16 fade steps.
:th03: :th04: :th05: \fm1 Fades out BGM volume via PMD's AH=02h interrupt call, in a non-blocking way. The fade speed can range from 1 (slowest) to 127 (fastest).
Values from 128 to 255 technically correspond to AH=02h's fade-in feature, which can't be used from cutscene scripts because it requires BGM volume to first be lowered via AH=19h, and there is no command to do that.
:th03: :th04: :th05: \g8 Plays a blocking 8-frame screen shake animation.
:th03: :th04: \ga0 Shows the gaiji with the given ID from 0 to 255 at the current cursor position. Even in TH03, gaiji always ignore the text delay interval configured with \v.
:th05: @3 TH05's replacement for the \ga command from TH03 and TH04. The default ID of 3 corresponds to the ♫ gaiji. Not to be confused with \@, which starts with a backslash, unlike this command.
:th05: @h Shows the 🎔 gaiji.
:th05: @t Shows the 💦 gaiji.
:th05: @! Shows the ! gaiji.
:th05: @? Shows the ? gaiji.
:th05: @!! Shows the ‼ gaiji.
:th05: @!? Shows the ⁉ gaiji.
:th03: :th04: :th05: \k0 Waits 0 frames (0 = forever) for an advance key to be pressed before continuing script execution. Before waiting, TH05 crossfades in any new text that was previously rendered to the invisible VRAM page…
🐞 …but TH04 doesn't, leaving the text invisible during the wait time. As a workaround, \vp1 can be used before \k to immediately display that text without a fade-in animation.
:th03: :th04: :th05: \m$ Stops the currently playing BGM.
:th03: :th04: :th05: \m* Restarts playback of the currently loaded BGM from the beginning.
:th03: :th04: :th05: \m,filename Stops the currently playing BGM, loads a new one from the given file, and starts playback.
:th03: :th04: :th05: \n Starts a new line at the leftmost X coordinate of the box, i.e., the start of the name area. This is how scripts can "change" the name of the currently speaking character, or use the entire 480×64 pixels without being restricted to the non-name area.
Note that automatic line breaks already move the cursor into a new line. Using this command at the "end" of a line with the maximum number of 30 full-width glyphs would therefore start a second new line and leave the previously started line empty.
If this command moved the cursor into the 5th line of a box, \s is executed afterward, with any of \n's parameters passed to \s.
:th03: :th04: :th05: \p (no-op)
:th03: :th04: :th05: \p- Deallocates the loaded .PI image.
:th03: :th04: :th05: \p,filename Loads the .PI image with the given file into the single .PI slot available to cutscenes. TH04 and TH05 automatically deallocate any previous image, 🐞 TH03 would leak memory without a manual prior call to \p-.
:th03: :th04: :th05: \pp Sets the hardware palette to the one of the loaded .PI image.
:th03: :th04: :th05: \p@ Sets the loaded .PI image as the full-screen 640×400 background image and overwrites both VRAM pages with its pixels, retaining the current hardware palette.
:th03: :th04: :th05: \p= Runs \pp followed by \p@.
:th03: :th04: :th05: \s0
\s-
Ends a text box and starts a new one. Fades in any text rendered to the invisible VRAM page, then waits 0 frames (0 = forever) for an advance key to be pressed. Afterward, the new text box is started with the cursor moved to the top-left corner of the name area.
\s- skips the wait time and starts the new box immediately.
:th03: :th04: :th05: \t100 Sets palette brightness via master.lib's palette_settone() to any value from 0 (fully black) to 200 (fully white). 100 corresponds to the palette's original colors. Preceded by a 1-frame delay unless ESC is held.
:th03: \v1 Sets the number of frames to wait between every 2 bytes of rendered text.
:th04: Sets the number of frames to spend on each of the 4 fade steps when crossfading between old and new text. The game-specific default value is also used before the first use of this command.
:th05: \v2
:th03: :th04: :th05: \vp0 Shows VRAM page 0. Completely useless in TH03 (this game always synchronizes both VRAM pages at a command boundary), only of dubious use in TH04 (for working around a bug in \k), and the games always return to their intended shown page before every blitting operation anyway. A debloated mod of this game would just remove this command, as it exposes an implementation detail that script authors should not need to worry about. None of the original scripts use it anyway.
:th03: :th04: :th05: \w64
  • \w and \wk wait for the given number of frames
  • \wm and \wmk wait until PMD has played back the current BGM for the total number of measures, including loops, given in the first parameter, and fall back on calling \w and \wk with the second parameter as the frame number if BGM is disabled.
    🐞 Neither PMD nor MMD reset the internal measure when stopping playback. If no BGM is playing and the previous BGM hasn't been played back for at least the given number of measures, this command will deadlock.
Since both TH04 and TH05 fade in any new text from the invisible VRAM page, these commands can be used to simulate TH03's typing effect in those games. Demo video below.
Contrary to \k and \s, specifying 0 frames would simply remove any frame delay instead of waiting forever.
The TH03-exclusive k variants allow the delay to be interrupted if ⏎ Return or Shot are held down. TH04 and TH05 recognize the k as well, but removed its functionality.
All of these commands have no effect if ESC is held.
\wm64,64
:th03: \wk64
\wmk64,64
:th03: :th04: :th05: \wi1
\wo1
Calls master.lib's palette_white_in() or palette_white_out() to play a hardware palette fade animation from or to white, spending roughly 1 frame on each of the 16 fade steps.
:th03: :th04: :th05: \=4 Immediately displays the given quarter of the loaded .PI image in the picture area, with no fade effect. Any value ≥ 4 resets the picture area to black.
:th03: :th04: :th05: \==4,1 Crossfades the picture area between its current content and quarter #4 of the loaded .PI image, spending 1 frame on each of the 4 fade steps unless ESC is held. Any value ≥ 4 is replaced with quarter #0.
:th03: :th04: :th05: \$ Stops script execution. Must be called at the end of each file; otherwise, execution continues into whatever lies after the script buffer in memory.
TH05 automatically deallocates the loaded .PI image, TH03 and TH04 require a separate manual call to \p- to not leak its memory.
Bold values signify the default if the parameter is omitted; \c is therefore equivalent to \c15.
Using the \@ command in the middle of a TH03 or TH04 cutscene script
The \@ bug. Yes, the ¥ is fake. It was easier to GIMP it than to reword the sentences so that the backslashes landed on the second byte of a 2-byte half-width character pair. :onricdennat:
Cutscene font weights in TH03Cutscene font weights in TH05, demonstrating the <code>\b3</code> bug that also affects TH04Cutscene font weights in TH03, rendered at a hypothetical unaligned X positionCutscene font weights in TH05, rendered at a hypothetical unaligned X position
The font weights and effects available through \b, including the glitch with \b3 in TH04 and TH05.
Font weight 3 is technically not rendered correctly in TH03 either; if you compare 1️⃣ with 4️⃣, you notice a single missing column of pixels at the left side of each glyph, which would extend into the previous VRAM byte. Ironically, the TH04/TH05 version is more correct in this regard: For half-width glyphs, it preserves any further pixel columns generated by the weight functions in the high byte of the 16-dot glyph variable. Unlike TH03, which still cuts them off when rendering text to unaligned X positions (3️⃣), TH04 and TH05 do bit-rotate them towards their correct place (4️⃣). It's only at byte-aligned X positions (2️⃣) where they remain at their internally calculated place, and appear on screen as these glitched pixel columns, 15 pixels away from the glyph they belong to. It's easy to blame bugs like these on micro-optimized ASM code, but in this instance, you really can't argue against it if the original C++ version was equally incorrect.
Combining \b and s- into a partial dissolve animation. The speed can be controlled with \v.
Simulating TH03's typing effect in TH04 and TH05 via \w. Even prettier in TH05 where we also get an additional fade animation after the box ends.

So yeah, that's the cutscene system. I'm dreading the moment I will have to deal with the other command interpreter in these games, i.e., the stage enemy system. Luckily, that one is completely disconnected from any other system, so I won't have to deal with it until we're close to finishing MAIN.EXE… that is, unless someone requests it before. And it won't involve text encodings or unblitting…


The cutscene system got me thinking in greater detail about how I would implement translations, being one of the main dependencies behind them. This goal has been on the order form for a while and could soon be implemented for these cutscenes, with 100% PI being right around the corner for the TH03 and TH04 cutscene executables.
Once we're there, the "Virgin" old-school way of static translation patching for Latin-script languages could be implemented fairly quickly:

  1. Establish basic UTF-8 parsing for less painful manual editing of the source files
  2. Procedurally generate glyphs for the few required additional letters based on existing font ROM glyphs. For example, we'd generate ä by painting two short lines on top of the font ROM's a glyph, or generate ¿ by vertically flipping the question mark. This way, the text retains a consistent look regardless of whether the translated game is run with an NEC or EPSON font ROM, or the hideous abomination that Neko Project II auto-generates if you don't provide either.
  3. (Optional) Change automatic line breaks to work on a per-word basis, rather than per-glyph

That's it – script editing and distribution would be handled by your local translation group. It might seem as if this would also work for Greek and Cyrillic scripts due to their presence in the PC-98 font ROM, but I'm not sure if I want to attempt procedurally shrinking these glyphs from 16×16 to 8×16… For any more thorough solution, we'd need to go for a more "Chad" kind of full-blown translation support:

  1. Implement text subdivisions at a sensible granularity while retaining automatic line and box breaks
  2. Compile translatable text into a Japanese→target language dictionary (I'm too old to develop any further translation systems that would overwrite modded source text with translations of the original text)
  3. Implement a custom Unicode font system (glyphs would be taken from GNU Unifont unless translators provide a different 8×16 font for their language)
  4. Combine the text compiler with the font compiler to only store needed glyphs as part of the translation's font file (dealing with a multi-MB font file would be rather ugly in a Real Mode game)
  5. Write a simple install/update/patch stacking tool that supports both .HDI and raw-file DOSBox-X scenarios (it's different enough from thcrap to warrant a separate tool – each patch stack would be statically compiled into a single package file in the game's directory)
  6. Add a nice language selection option to the main menu
  7. (Optional) Support proportional fonts

Which sounds more like a separate project to be commissioned from Touhou Patch Center's Open Collective funds, separate from the ReC98 cap. This way, we can make sure that the feature is completely implemented, and I can talk with every interested translator to make sure that their language works.
It's still cheaper overall to do this on PC-98 than to first port the games to a modern system and then translate them. On the other hand, most of the tasks in the Chad variant (3, 4, 5, and half of 2) purely deal with the difficulty of getting arbitrary Unicode characters to work natively in a PC-98 DOS game at all, and would be either unnecessary or trivial if we had already ported the game. Depending on where the patrons' interests lie, it may not be worth it. So let's see what all of you think about which way we should go, or whether it's worth doing at all. (Edit (2022-12-01): With Splashman's order towards the stage dialogue system, we've pretty much confirmed that it is.) Maybe we want to meet in the middle – using e.g. procedural glyph generation for dynamic translations to keep text rendering consistent with the rest of the PC-98 system, and just not support non-Latin-script languages in the beginning? In any case, I've added both options to the order form.
Edit (2023-07-28): Touhou Patch Center has agreed to fund a basic feature set somewhere between the Virgin and Chad level. Check the 📝 dedicated announcement blog post for more details and ideas, and to find out how you can support this goal!


Surprisingly, there was still a bit of RE work left in the third push after all of this, which I filled with some small rendering boilerplate. Since I also wanted to include TH02's playfield overlay functions, 1/15 of that last push went towards getting a TH02-exclusive function out of the way, which also ended up including that game in this delivery. :tannedcirno:
The other small function pointed out how TH05's Stage 5 midboss pops into the playfield quite suddenly, since its clipping test thinks it's only 32 pixels tall rather than 64:

Good chance that the pop-in might have been intended.
Edit (2023-06-30): Actually, it's a 📝 systematic consequence of ZUN having to work around the lack of clipping in master.lib's sprite functions.
There's even another quirk here: The white flash during its first frame is actually carried over from the previous midboss, which the game still considers as actively getting hit by the player shot that defeated it. It's the regular boilerplate code for rendering a midboss that resets the responsible damage variable, and that code doesn't run during the defeat explosion animation.

Next up: Staying with TH05 and looking at more of the pattern code of its boss fights. Given the remaining TH05 budget, it makes the most sense to continue in in-game order, with Sara and the Stage 2 midboss. If more money comes in towards this goal, I could alternatively go for the Mai & Yuki fight and immediately develop a pretty fix for the cheeto storage glitch. Also, there's a rather intricate pull request for direct ZMBV decoding on the website that I've still got to review…

📝 Posted:
🚚 Summary of:
P0190, P0191, P0192
Commits:
5734815...293e16a, 293e16a...71cb7b5, 71cb7b5...e1f3f9f
💰 Funded by:
nrook, -Tom-, [Anonymous]
🏷 Tags:

The important things first:

So, Shinki! As far as final boss code is concerned, she's surprisingly economical, with 📝 her background animations making up more than ⅓ of her entire code. Going straight from TH01's 📝 final 📝 bosses to TH05's final boss definitely showed how much ZUN had streamlined danmaku pattern code by the end of PC-98 Touhou. Don't get me wrong, there is still room for improvement: TH05 not only 📝 reuses the same 16 bytes of generic boss state we saw in TH04 last month, but also uses them 4× as often, and even for midbosses. Most importantly though, defining danmaku patterns using a single global instance of the group template structure is just bad no matter how you look at it:

Declaring a separate structure instance with the static data for every pattern would be both safer and more space-efficient, and there's more than enough space left for that in the game's data segment.
But all in all, the pattern functions are short, sweet, and easy to follow. The "devil" pattern is significantly more complex than the others, but still far from TH01's final bosses at their worst. I especially like the clear architectural separation between "one-shot pattern" functions that return true once they're done, and "looping pattern" functions that run as long as they're being called from a boss's main function. Not many all too interesting things in these pattern functions for the most part, except for two pieces of evidence that Shinki was coded after Yumeko:


Speaking about that wing sprite: If you look at ST05.BB2 (or any other file with a large sprite, for that matter), you notice a rather weird file layout:

Raw file layout of TH05's ST05.BB2, demonstrating master.lib's supposed BFNT width limit of 64 pixels
A large sprite split into multiple smaller ones with a width of 64 pixels each? What's this, hardware sprite limitations? On my PC-98?!

And it's not a limitation of the sprite width field in the BFNT+ header either. Instead, it's master.lib's BFNT functions which are limited to sprite widths up to 64 pixels… or at least that's what MASTER.MAN claims. Whatever the restriction was, it seems to be completely nonexistent as of master.lib version 0.23, and none of the master.lib functions used by the games have any issues with larger sprites.
Since ZUN stuck to the supposed 64-pixel width limit though, it's now the game that expects Shinki's winged form to consist of 4 physical sprites, not just 1. Any conversion from another, more logical sprite sheet layout back into BFNT+ must therefore replicate the original number of sprites. Otherwise, the sequential IDs ("patnums") assigned to every newly loaded sprite no longer match ZUN's hardcoded IDs, causing the game to crash. This is exactly what used to happen with -Tom-'s MysticTK automation scripts, which combined these exact sprites into a single large one. This issue has now been fixed – just in case there are some underground modders out there who used these scripts and wonder why their game crashed as soon as the Shinki fight started.


And then the code quality takes a nosedive with Shinki's main function. :onricdennat: Even in TH05, these boss and midboss update functions are still very imperative:

The biggest WTF in there, however, goes to using one of the 16 state bytes as a "relative phase" variable for differentiating between boss phases that share the same branch within the switch(boss.phase) statement. While it's commendable that ZUN tried to reduce code duplication for once, he could have just branched depending on the actual boss.phase variable? The same state byte is then reused in the "devil" pattern to track the activity state of the big jerky lasers in the second half of the pattern. If you somehow managed to end the phase after the first few bullets of the pattern, but before these lasers are up, Shinki's update function would think that you're still in the phase before the "devil" pattern. The main function then sequence-breaks right to the defeat phase, skipping the final pattern with the burning Makai background. Luckily, the HP boundaries are far away enough to make this impossible in practice.
The takeaway here: If you want to use the state bytes for your custom boss script mods, alias them to your own 16-byte structure, and limit each of the bytes to a clearly defined meaning across your entire boss script.

One final discovery that doesn't seem to be documented anywhere yet: Shinki actually has a hidden bomb shield during her two purple-wing phases. uth05win got this part slightly wrong though: It's not a complete shield, and hitting Shinki will still deal 1 point of chip damage per frame. For comparison, the first phase lasts for 3,000 HP, and the "devil" pattern phase lasts for 5,800 HP.

And there we go, 3rd PC-98 Touhou boss script* decompiled, 28 to go! 🎉 In case you were expecting a fix for the Shinki death glitch: That one is more appropriately fixed as part of the Mai & Yuki script. It also requires new code, should ideally look a bit prettier than just removing cheetos between one frame and the next, and I'd still like it to fit within the original position-dependent code layout… Let's do that some other time.
Not much to say about the Stage 1 midboss, or midbosses in general even, except that their update functions have to imperatively handle even more subsystems, due to the relative lack of helper functions.


The remaining ¾ of the third push went to a bunch of smaller RE and finalization work that would have hardly got any attention otherwise, to help secure that 50% RE mark. The nicest piece of code in there shows off what looks like the optimal way of setting up the 📝 GRCG tile register for monochrome blitting in a variable color:

mov ah, palette_index ; Any other non-AL 8-bit register works too.
                      ; (x86 only supports AL as the source operand for OUTs.)

rept 4                ; For all 4 bitplanes…
    shr ah,  1        ; Shift the next color bit into the x86 carry flag
    sbb al,  al       ; Extend the carry flag to a full byte
                      ; (CF=0 → 0x00, CF=1 → 0xFF)
    out 7Eh, al       ; Write AL to the GRCG tile register
endm

Thanks to Turbo C++'s inlining capabilities, the loop body even decompiles into a surprisingly nice one-liner. What a beautiful micro-optimization, at a place where micro-optimization doesn't hurt and is almost expected.
Unfortunately, the micro-optimizations went all downhill from there, becoming increasingly dumb and undecompilable. Was it really necessary to save 4 x86 instructions in the highly unlikely case of a new spark sprite being spawned outside the playfield? That one 2D polar→Cartesian conversion function then pointed out Turbo C++ 4.0J's woefully limited support for 32-bit micro-optimizations. The code generation for 32-bit 📝 pseudo-registers is so bad that they almost aren't worth using for arithmetic operations, and the inline assembler just flat out doesn't support anything 32-bit. No use in decompiling a function that you'd have to entirely spell out in machine code, especially if the same function already exists in multiple other, more idiomatic C++ variations.
Rounding out the third push, we got the TH04/TH05 DEMO?.REC replay file reading code, which should finally prove that nothing about the game's original replay system could serve as even just the foundation for community-usable replays. Just in case anyone was still thinking that.


Next up: Back to TH01, with the Elis fight! Got a bit of room left in the cap again, and there are a lot of things that would make a lot of sense now:

📝 Posted:
🚚 Summary of:
P0189
Commits:
22abdd1...b4876b6
💰 Funded by:
Arandui, Lmocinemod
🏷 Tags:

(Before we start: Make sure you've read the current version of the FAQ section on a potential takedown of this project, updated in light of the recent DMCA claims against PC-98 Touhou game downloads.)


Slight change of plans, because we got instructions for reliably reproducing the TH04 Kurumi Divide Error crash! Major thanks to Colin Douglas Howell. With those, it also made sense to immediately look at the crash in the Stage 4 Marisa fight as well. This way, I could release both of the obligatory bugfix mods at the same time.
Especially since it turned out that I was wrong: Both crashes are entirely unrelated to the custom entity structure that would have required PI-centric progress. They are completely specific to Kurumi's and Marisa's danmaku-pattern code, and really are two separate bugs with no connection to each other. All of the necessary research nicely fit into Arandui's 0.5 pushes, with no further deep understanding required here.

But why were there still three weeks between Colin's message and this blog post? DMCA distractions aside: There are no easy fixes this time, unlike 📝 back when I looked at the Stage 5 Yuuka crash. Just like how division by zero is undefined in mathematics, it's also, literally, undefined what should happen instead of these two Divide error crashes. This means that any possible "fix" can only ever be a fanfiction interpretation of the intentions behind ZUN's code. The gameplay community should be aware of this, and might decide to handle these cases differently. And if we have to go into fanfiction territory to work around crashes in the canon games, we'd better document what exactly we're fixing here and how, as comprehensible as possible.

  1. Kurumi's crash
  2. Marisa's crash

With that out of the way, let's look at Kurumi's crash first, since it's way easier to grasp. This one is known to primarily happen to new players, and it's easy to see why:

The pattern that causes the crash in Kurumi's fight. Also demonstrates how the number of bullets in a ring is always halved on Easy Mode after the rank-based tuning, leading to just a 3-ring on playperf = 16.

So, what should the workaround look like? Obviously, we want to modify neither the default number of ring bullets nor the tuning algorithm – that would change all other non-crashing variations of this pattern on other difficulties and ranks, creating a fork of the original gameplay. Instead, I came up with four possible workarounds that all seemed somewhat logical to me:

  1. Firing no bullet, i.e., interpreting 0-ring literally. This would create the only constellation in which a call to the bullet group spawn functions would not spawn at least one new bullet.
  2. Firing a "1-ring", i.e., a single bullet. This would be consistent with how the bullet spawn functions behave for "0-way" stack and spread groups.
  3. Firing a "∞-ring", i.e., 200 bullets, which is as much as the game's cap on 16×16 bullets would allow. This would poke fun at the whole "division by zero" idea… but given that we're still talking about Easy Mode (and especially new players) here, it might be a tad too cruel. Certainly the most trollish interpretation.
  4. Triggering an immediate Game Over, exchanging the hard crash for a softer and more controlled shutdown. Certainly the option that would be closest to the behavior of the original games, and perhaps the only one to be accepted in Serious, High-Level Play™.

As I was writing this post, it felt increasingly wrong for me to make this decision. So I once again went to Twitter, where 56.3% voted in favor of the 1-bullet option. Good that I asked! I myself was more leaning towards the 0-bullet interpretation, which only got 28.7% of the vote. Also interesting are the 2.3% in favor of the Game Over option but I get it, low-rank Easy Mode isn't exactly the most competitive mode of playing TH04.
There are reports of Kurumi crashing on higher difficulties as well, but I could verify none of them. If they aren't fixed by this workaround, they're caused by an entirely different bug that we have yet to discover.


Onto the Stage 4 Marisa crash then, which does in fact apply to all difficulty levels. I was also wrong on this one – it's a hell of a lot more intricate than being just a division by the number of on-screen bits. Without having decompiled the entire fight, I can't give a completely accurate picture of what happens there yet, but here's the rough idea:

Reference points for Marisa's point-reflected movement. Cyan: Marisa's position, green: (192, 112), yellow: the intended end point.
One of the two patterns in TH04's Stage 4 Marisa boss fight that feature frame number-dependent point-reflected movement. The bits were hacked to self-destruct on the respective frame.

tl;dr: "Game crashes if last bit destroyed within 4-frame window near end of two patterns". For an informed decision on a new movement behavior for these last 8 frames, we definitely need to know all the details behind the crash though. Here's what I would interpret into the code:

  1. Not moving at all, i.e., interpreting 0 as the middle ground between positive and negative movement. This would also make sense because a 12-frame duration implies 100% of the movement to consist of the braking phase – and Marisa wasn't moving before, after all.
  2. Move at maximum speed, i.e., dividing by 1 rather than 0. Since the movement duration is still 12 in this case, Marisa will immediately start braking. In total, she will move exactly ¾ of the way from her initial position to (192, 112) within the 8 frames before the pattern ends.
  3. Directly warping to (192, 112) on frame 0, and to the point-reflected target on 4, respectively. This "emulates" the division by zero by moving Marisa at infinite speed to the exact two points indicated by the velocity formula. It also fits nicely into the 8 frames we have to fill here. Sure, Marisa can't reach these points at any other duration, but why shouldn't she be able to, with infinite speed? Then again, if Marisa is far away enough from (192, 112), this workaround would warp her across the entire playfield. Can Marisa teleport according to lore? I have no idea… :tannedcirno:
  4. Triggering an immediate Game O– hell no, this is the Stage 4 boss, people already hate losing runs to this bug!

Asking Twitter worked great for the Kurumi workaround, so let's do it again! Gotta attach a screenshot of an earlier draft of this blog post though, since this stuff is impossible to explain in tweets…

…and it went through the roof, becoming the most successful ReC98 tweet so far?! Apparently, y'all really like to just look at descriptions of overly complex bugs that I'd consider way beyond the typical attention span that can be expected from Twitter. Unfortunately, all those tweet impressions didn't quite translate into poll turnout. The results were pretty evenly split between 1) and 2), with option 1) just coming out slightly ahead at 49.1%, compared to 41.5% of option 2).

(And yes, I only noticed after creating the poll that warping to both the green and yellow points made more sense than warping to just one of the two. Let's hope that this additional variant wouldn't have shifted the results too much. Both warp options only got 9.4% of the vote after all, and no one else came up with the idea either. :onricdennat: In the end, you can always merge together your preferred combination of workarounds from the Git branches linked below.)


So here you go: The new definitive version of TH04, containing not only the community-chosen Kurumi and Stage 4 Marisa workaround variant, but also the 📝 No-EMS bugfix from last year. Edit (2022-05-31): This package is outdated, 📝 the current version is here! 2022-04-18-community-choice-fixes.zip Oh, and let's also add spaztron64's TH03 GDC clock fix from 2019 because why not. This binary was built from the community_choice_fixes branch, and you can find the code for all the individual workarounds on these branches:

Again, because it can't be stated often enough: These fixes are fanfiction. The gameplay community should be aware of this, and might decide to handle these cases differently.


With all of that taking way more time to evaluate and document, this research really had to become part of a proper push, instead of just being covered in the quick non-push blog post I initially intended. With ½ of a push left at the end, TH05's Stage 1-5 boss background rendering functions fit in perfectly there. If you wonder how these static backdrop images even need any boss-specific code to begin with, you're right – it's basically the same function copy-pasted 4 times, differing only in the backdrop image coordinates and some other inconsequential details.
Only Sara receives a nice variation of the typical 📝 blocky entrance animation: The usually opaque bitmap data from ST00.BB is instead used as a transition mask from stage tiles to the backdrop image, by making clever use of the tile invalidation system:

TH04 uses the same effect a bit more frequently, for its first three bosses.

Next up: Shinki, for real this time! I've already managed to decompile 10 of her 11 danmaku patterns within a little more than one push – and yes, that one is included in there. Looks like I've slightly overestimated the amount of work required for TH04's and TH05's bosses…

📝 Posted:
🚚 Summary of:
P0186, P0187, P0188
Commits:
a21ab3d...bab5634, bab5634...426a531, 426a531...e881f95
💰 Funded by:
Blue Bolt, [Anonymous], nrook
🏷 Tags:

Did you know that moving on top of a boss sprite doesn't kill the player in TH04, only in TH05?

Screenshot of Reimu moving on top of Stage 6 Yuuka, demonstrating the lack of boss↔player collision in TH04
Yup, Reimu is not getting hit… yet.

That's the first of only three interesting discoveries in these 3 pushes, all of which concern TH04. But yeah, 3 for something as seemingly simple as these shared boss functions… that's still not quite the speed-up I had hoped for. While most of this can be blamed, again, on TH04 and all of its hardcoded complexities, there still was a lot of work to be done on the maintenance front as well. These functions reference a bunch of code I RE'd years ago and that still had to be brought up to current standards, with the dependencies reaching from 📝 boss explosions over 📝 text RAM overlay functionality up to in-game dialog loading.

The latter provides a good opportunity to talk a bit about x86 memory segmentation. Many aspiring PC-98 developers these days are very scared of it, with some even going as far as to rather mess with Protected Mode and DOS extenders just so that they don't have to deal with it. I wonder where that fear comes from… Could it be because every modern programming language I know of assumes memory to be flat, and lacks any standard language-level features to even express something like segments and offsets? That's why compilers have a hard time targeting 16-bit x86 these days: Doing anything interesting on the architecture requires giving the programmer full control over segmentation, which always comes down to adding the typical non-standard language extensions of compilers from back in the day. And as soon as DOS stopped being used, these extensions no longer made sense and were subsequently removed from newer tools. A good example for this can be found in an old version of the NASM manual: The project started as an attempt to make x86 assemblers simple again by throwing out most of the segmentation features from MASM-style assemblers, which made complete sense in 1996 when 16-bit DOS and Windows were already on their way out. But there was a point to all those features, and that's why ReC98 still has to use the supposedly inferior TASM.

Not that this fear of segmentation is completely unfounded: All the segmentation-related keywords, directives, and #pragmas provided by Borland C++ and TASM absolutely can be the cause of many weird runtime bugs. Even if the compiler or linker catches them, you are often left with confusing error messages that aged just as poorly as memory segmentation itself.
However, embracing the concept does provide quite the opportunity for optimizations. While it definitely was a very crazy idea, there is a small bit of brilliance to be gained from making proper use of all these segmentation features. Case in point: The buffer for the in-game dialog scripts in TH04 and TH05.

// Thanks to the semantics of `far` pointers, we only need a single 32-bit
// pointer variable for the following code.
extern unsigned char far *dialog_p;

// This master.lib function returns a `void __seg *`, which is a 16-bit
// segment-only pointer. Converting to a `far *` yields a full segment:offset
// pointer to offset 0000h of that segment.
dialog_p = (unsigned char far *)hmem_allocbyte(/* … */);

// Running the dialog script involves pointer arithmetic. On a far pointer,
// this only affects the 16-bit offset part, complete with overflow at 64 KiB,
// from FFFFh back to 0000h.
dialog_p += /* … */;
dialog_p += /* … */;
dialog_p += /* … */;

// Since the segment part of the pointer is still identical to the one we
// allocated above, we can later correctly free the buffer by pulling the
// segment back out of the pointer.
hmem_free((void __seg *)dialog_p);

If dialog_p was a huge pointer, any pointer arithmetic would have also adjusted the segment part, requiring a second pointer to store the base address for the hmem_free call. Doing that will also be necessary for any port to a flat memory model. Depending on how you look at it, this compression of two logical pointers into a single variable is either quite nice, or really, really dumb in its reliance on the precise memory model of one single architecture. :tannedcirno:


Why look at dialog loading though, wasn't this supposed to be all about shared boss functions? Well, TH04 unnecessarily puts certain stage-specific code into the boss defeat function, such as loading the alternate Stage 5 Yuuka defeat dialog before a Bad Ending, or initializing Gengetsu after Mugetsu's defeat in the Extra Stage.
That's TH04's second core function with an explicit conditional branch for Gengetsu, after the 📝 dialog exit code we found last year during EMS research. And I've heard people say that Shinki was the most hardcoded fight in PC-98 Touhou… Really, Shinki is a perfectly regular boss, who makes proper use of all internal mechanics in the way they were intended, and doesn't blast holes into the architecture of the game. Even within TH05, it's Mai and Yuki who rely on hacks and duplicated code, not Shinki.

The worst part about this though? How the function distinguishes Mugetsu from Gengetsu. Once again, it uses its own global variable to track whether it is called the first or the second time within TH04's Extra Stage, unrelated to the same variable used in the dialog exit function. But this time, it's not just any newly created, single-use variable, oh no. In a misguided attempt to micro-optimize away a few bytes of conventional memory, TH04 reserves 16 bytes of "generic boss state", which can (and are) freely used for anything a boss doesn't want to store in a more dedicated variable.
It might have been worth it if the bosses actually used most of these 16 bytes, but the majority just use (the same) two, with only Stage 4 Reimu using a whopping seven different ones. To reverse-engineer the various uses of these variables, I pretty much had to map out which of the undecompiled danmaku-pattern functions corresponds to which boss fight. In the end, I assigned 29 different variable names for each of the semantically different use cases, which made up another full push on its own.

Now, 16 bytes of wildly shared state, isn't that the perfect recipe for bugs? At least during this cursory look, I haven't found any obvious ones yet. If they do exist, it's more likely that they involve reused state from earlier bosses – just how the Shinki death glitch in TH05 is caused by reusing cheeto data from way back in Stage 4 – and hence require much more boss-specific progress.
And yes, it might have been way too early to look into all these tiny details of specific boss scripts… but then, this happened:

TH04 crashing to the DOS prompt in the Stage 4 Marisa fight, right as the last of her bits is destroyed

Looks similar to another screenshot of a crash in the same fight that was reported in December, doesn't it? I was too much in a hurry to figure it out exactly, but notice how both crashes happen right as the last of Marisa's four bits is destroyed. KirbyComment has suspected this to be the cause for a while, and now I can pretty much confirm it to be an unguarded division by the number of on-screen bits in Marisa-specific pattern code. But what's the cause for Kurumi then? :thonk:
As for fixing it, I can go for either a fast or a slow option:

  1. Superficially fixing only this crash will probably just take a fraction of a push.
  2. But I could also go for a deeper understanding by looking at TH04's version of the 📝 custom entity structure. It not only stores the data of Marisa's bits, but is also very likely to be involved in Kurumi's crash, and would get TH04 a lot closer to 100% PI. Taking that look will probably need at least 2 pushes, and might require another 3-4 to completely decompile Marisa's fight, and 2-3 to decompile Kurumi's.

OK, now that that's out of the way, time to finish the boss defeat function… but not without stumbling over the third of TH04's quirks, relating to the Clear Bonus for the main game or the Extra Stage:

And after another few collision-related functions, we're now truly, finally ready to decompile bosses in both TH04 and TH05! Just as the anything funds were running out… :onricdennat: The remaining ¼ of the third push then went to Shinki's 32×32 ball bullets, rounding out this delivery with a small self-contained piece of the first TH05 boss we're probably going to look at.

Next up, though: I'm not sure, actually. Both Shinki and Elis seem just a little bit larger than the 2¼ or 4 pushes purchased so far, respectively. Now that there's a bunch of room left in the cap again, I'll just let the next contribution decide – with a preference for Shinki in case of a tie. And if it will take longer than usual for the store to sell out again this time (heh), there's still the 📝 PC-98 text RAM JIS trail word rendering research waiting to be documented.

📝 Posted:
🚚 Summary of:
P0184, P0185
Commits:
f9d983e...f918298, f918298...a21ab3d
💰 Funded by:
-Tom-, Blue Bolt, [Anonymous]
🏷 Tags:

Two years after 📝 the first look at TH04's and TH05's bullets, we finally get to finish their logic code by looking at the special motion types. Bullets as a whole still aren't completely finished as the rendering code is still waiting to be RE'd, but now we've got everything about them that's required for decompiling the midboss and boss fights of these games.

Just like the motion types of TH01's pellets, the ones we've got here really are special enough to warrant an enum, despite all the overlap in the "slow down and turn" and "bounce at certain edges of the playfield" types. Sure, including them in the bitfield I proposed two years ago would have allowed greater variety, but it wouldn't have saved any memory. On the contrary: These types use a single global state variable for the maximum turn count and delta speed, which a proper customizable architecture would have to integrate into the bullet structure. Maybe it is possible to stuff everything into the same amount of bytes, but not without first completely rearchitecting the bullet structure and removing every single piece of redundancy in there. Simply extending the system by adding a new enum value for a new motion type would be way more straightforward for modders.

Speaking about memory, TH05 already extends the bullet structure by 6 bytes for the "exact linear movement" type exclusive to that game. This type is particularly interesting for all the prospective PC-98 game developers out there, as it nicely points out the precision limits of Q12.4 subpixels.
Regular bullet movement works by adding a Q12.4 velocity to a Q12.4 position every frame, with the velocity typically being calculated only once on spawn time from an 8-bit angle and a Q12.4 speed. Quantization errors from this initial calculation can quickly compound over all the frames a bullet spends moving across the playfield. If a bullet is only supposed to move on a straight line though, there is a more precise way of calculating its position: By storing the origin point, movement angle, and total distance traveled, you can perform a full polar→Cartesian transformation every frame. Out of the 10 danmaku patterns in TH05 that use this motion type, the difference to regular bullet movement can be best seen in Louise's final pattern:

Louise's final pattern in its original form, demonstrating exact linear bullet movement. Note how each bullet spawns slightly behind the delay cloud: ZUN simply forgot to shift the fixed origin point along with it.
The same pattern with standard bullet movement, corrupting its intended appearance. No delay cloud-related oversights here though, at least.

Not far away from the regular bullet code, we've also got the movement function for the infamous curve / "cheeto" bullets. I would have almost called them "cheetos" in the code as well, which surely fits more nicely into 8.3 filenames than "curve bullets" does, but eh, trademarks…

As for hitboxes, we got a 16×16 one on the head node, and a 12×12 one on the 16 trail nodes. The latter simply store the position of the head node during the last 16 frames, Snake style. But what you're all here for is probably the turning and homing algorithm, right? Boiled down to its essence, it works like this:

// [head] points to the controlled "head" part of a curve bullet entity.
// Angles are stored with 8 bits representing a full circle, providing free
// normalization on arithmetic overflow.
// The directions are ordered as you would expect:
// • 0x00: right	(sin(0x00) =  0, cos(0x00) = +1)
// • 0x40: down 	(sin(0x40) = +1, cos(0x40) =  0)
// • 0x80: left 	(sin(0x80) =  0, cos(0x80) = -1)
// • 0xC0: up   	(sin(0xC0) = -1, cos(0xC0) =  0)
uint8_t angle_delta = (head->angle - player_angle_from(
	head->pos.cur.x, head->pos.cur.y
));

// Stop turning if the player is 1/128ths of a circle away from this bullet
const uint8_t SNAP = 0x02;

// Else, turn either clockwise or counterclockwise by 1/256th of a circle,
// depending on what would reach the player the fastest.
if((angle_delta > SNAP) && (angle_delta < static_cast<uint8_t>(-SNAP))) {
	angle_delta = (angle_delta >= 0x80) ? -0x01 : +0x01;
}
head_p->angle -= angle_delta;

5 lines of code, and not all too difficult to follow once you are familiar with 8-bit angles… unlike what ZUN actually wrote. Which is 26 lines, and includes an unused "friction" variable that is never set to any value that makes a difference in the formula. :zunpet: uth05win correctly saw through that all and simplified this code to something equivalent to my explanation. Redoing that work certainly wasted a bit of my time, and means that I now definitely need to spend another push on RE'ing all the shared boss functions before I can start with Shinki.

So while a curve bullet's speed does get faster over time, its angular velocity is always limited to 1/256th of a circle per frame. This reveals the optimal strategy for dodging them: Maximize this delta angle by staying as close to 180° away from their current direction as possible, and let their acceleration do the rest.

At least that's the theory for dodging a single one. As a danmaku designer, you can now of course place other bullets at these technically optimal places to prevent a curve bullet pattern from being cheesed like that. I certainly didn't record the video above in a single take either… :tannedcirno:


After another bunch of boring entity spawn and update functions, the playfield shaking feature turned out as the most notable (and tricky) one to round out these two pushes. It's actually implemented quite well in how it simply "un-shakes" the screen by just marking every stage tile to be redrawn. In the context of all the other tile invalidation that can take place during a frame, that's definitely more performant than 📝 doing another EGC-accelerated memmove(). Due to these two games being double-buffered via page flipping, this invalidation only really needs to happen for the frame after the next one though. The immediately next frame will show the regular, un-shaken playfield on the other VRAM page first, except during the multi-frame shake animation when defeating a midboss, where it will also appear shifted in a different direction… 😵 Yeah, no wonder why ZUN just always invalidates all stage tiles for the next two frames after every shaking animation, which is guaranteed to handle both sporadic single-frame shakes and continuous ones. So close to good-code here.

Finally, this delivery was delayed a bit because -Tom- requested his round-up amount to be limited to the cap in the future. Since that makes it kind of hard to explain on a static page how much money he will exactly provide, I now properly modeled these discounts in the website code. The exact round-up amount is now included in both the pre-purchase breakdown, as well as the cap bar on the main page.
With that in place, the system is now also set up for round-up offers from other patrons. If you'd also like to support certain goals in this way, with any amount of money, now's the time for getting in touch with me about that. Known contributors only, though! 😛

Next up: The final bunch of shared boring boss functions. Which certainly will give me a break from all the maintenance and research work, and speed up delivery progress again… right?

📝 Posted:
🚚 Summary of:
P0168, P0169
Commits:
c2de6ab...8b046da, 8b046da...479b766
💰 Funded by:
rosenrose, Blue Bolt
🏷 Tags:

EMS memory! The infamous stopgap measure between the 640 KiB ("ought to be enough for everyone") of conventional memory offered by DOS from the very beginning, and the later XMS standard for accessing all the rest of memory up to 4 GiB in the x86 Protected Mode. With an optionally active EMS driver, TH04 and TH05 will make use of EMS memory to preload a bunch of situational .CDG images at the beginning of MAIN.EXE:

  1. The "eye catch" game title image, shown while stages are loaded
  2. The character-specific background image, shown while bombing
  3. The player character dialog portraits
  4. TH05 additionally stores the boss portraits there, preloading them at the beginning of each stage. (TH04 instead keeps them in conventional memory during the entire stage.)

Once these images are needed, they can then be copied into conventional memory and accessed as usual.

Uh… wait, copied? It certainly would have been possible to map EMS memory to a regular 16-bit Real Mode segment for direct access, bank-switching out rarely used system or peripheral memory in exchange for the EMS data. However, master.lib doesn't expose this functionality, and only provides functions for copying data from EMS to regular memory and vice versa.
But even that still makes EMS an excellent fit for the large image files it's used for, as it's possible to directly copy their pixel data from EMS to VRAM. (Yes, I tried!) Well… would, because ZUN doesn't do that either, and always naively copies the images to newly allocated conventional memory first. In essence, this dumbs down EMS into just another layer of the memory hierarchy, inserted between conventional memory and disk: Not quite as slow as disk, but still requiring that memcpy() to retrieve the data. Most importantly though: Using EMS in this way does not increase the total amount of memory simultaneously accessible to the game. After all, some other data will have to be freed from conventional memory to make room for the newly loaded data.


The most idiomatic way to define the game-specific layout of the EMS area would be either a struct or an enum. Unfortunately, the total size of all these images exceeds the range of a 16-bit value, and Turbo C++ 4.0J supports neither 32-bit enums (which are silently degraded to 16-bit) nor 32-bit structs (which simply don't compile). That still leaves raw compile-time constants though, you only have to manually define the offset to each image in terms of the size of its predecessor. But instead of doing that, ZUN just placed each image at a nice round decimal offset, each slightly larger than the actual memory required by the previous image, just to make sure that everything fits. :tannedcirno: This results not only in quite a bit of unnecessary padding, but also in technically the single biggest amount of "wasted" memory in PC-98 Touhou: Out of the 180,000 (TH04) and 320,000 (TH05) EMS bytes requested, the game only uses 135,552 (TH04) and 175,904 (TH05) bytes. But hey, it's EMS, so who cares, right? Out of all the opportunities to take shortcuts during development, this is among the most acceptable ones. Any actual PC-98 model that could run these two games comes with plenty of memory for this to not turn into an actual issue.

On to the EMS-using functions themselves, which are the definition of "cross-cutting concerns". Most of these have a fallback path for the non-EMS case, and keep the loaded .CDG images in memory if they are immediately needed. Which totally makes sense, but also makes it difficult to find names that reflect all the global state changed by these functions. Every one of these is also just called from a single place, so inlining them would have saved me a lot of naming and documentation trouble there.
The TH04 version of the EMS allocation code was actually displayed on ZUN's monitor in the 2010 MAG・ネット documentary; WindowsTiger already transcribed the low-quality video image in 2019. By 2015 ReC98 standards, I would have just run with that, but the current project goal is to write better code than ZUN, so I didn't. 😛 We sure ain't going to use magic numbers for EMS offsets.

The dialog init and exit code then is completely different in both games, yet equally cross-cutting. TH05 goes even further in saving conventional memory, loading each individual player or boss portrait into a single .CDG slot immediately before blitting it to VRAM and freeing the pixel data again. People who play TH05 without an active EMS driver are surely going to enjoy the hard drive access lag between each portrait change… :godzun: TH04, on the other hand, also abuses the dialog exit function to preload the Mugetsu defeat / Gengetsu entrance and Gengetsu defeat portraits, using a static variable to track how often the function has been called during the Extra Stage… who needs function parameters anyway, right? :zunpet:

This is also the function in which TH04 infamously crashes after the Stage 5 pre-boss dialog when playing with Reimu and without any active EMS driver. That crash is what motivated this look into the games' EMS usage… but the code looks perfectly fine? Oh well, guess the crash is not related to EMS then. Next u–

OK, of course I can't leave it like that. Everyone is expecting a fix now, and I still got half of a push left over after decompiling the regular EMS code. Also, I've now RE'd every function that could possibly be involved in the crash, and this is very likely to be the last time I'll be looking at them.


Turns out that the bug has little to do with EMS, and everything to do with ZUN limiting the amount of conventional RAM that TH04's MAIN.EXE is allowed to use, and then slightly miscalculating this upper limit. Playing Stage 5 with Reimu is the most asset-intensive configuration in this game, due to the combination of

The star image used in TH04's Stage 5.
The star image used in TH04's Stage 5.

Remove any single one of the above points, and this crash would have never occurred. But with all of them combined, the total amount of memory consumed by TH04's MAIN.EXE just barely exceeds ZUN's limit of 320,000 bytes, by no more than 3,840 bytes, the size of the star image.

But wait: As we established earlier, EMS does nothing to reduce the amount of conventional memory used by the game. In fact, if you disabled TH04's EMS handling, you'd still get this crash even if you are running an EMS driver and loaded DOS into the High Memory Area to free up as much conventional RAM as possible. How can EMS then prevent this crash in the first place?

The answer: It's only because ZUN's usage of EMS bypasses the need to load the cached images back out of the XOR-encrypted 東方幻想.郷 packfile. Leaving aside the general stupidity of any game data file encryption*, master.lib's decryption implementation is also quite wasteful: It uses a separate buffer that receives fixed-size chunks of the file, before decrypting every individual byte and copying it to its intended destination buffer. That really resembles the typical slowness of a C fread() implementation more than it does the highly optimized ASM code that master.lib purports to be… And how large is this well-hidden decryption buffer? 4 KiB. :onricdennat:

So, looking back at the game, here is what happens once the Stage 5 pre-battle dialog ends:

  1. Reimu's bomb background image, which was previously freed to make space for her dialog portraits, has to be loaded back into conventional memory from disk
  2. BB0.CDG is found inside the 東方幻想.郷 packfile
  3. file_ropen() ends up allocating a 4 KiB buffer for the encrypted packfile data, getting us the decisive ~4 KiB closer to the memory limit
  4. The .CDG loader tries to allocate 52 608 contiguous bytes for the pixel data of Reimu's bomb image
  5. This would exceed the memory limit, so hmem_allocbyte() fails and returns a nullptr
  6. ZUN doesn't check for this case (as usual)
  7. The pixel data is loaded to address 0000:0000, overwriting the Interrupt Vector Table and whatever comes after
  8. The game crashes
The final frame rendered before the TH04 Stage 5 Reimu No-EMS crash
The final frame rendered by a crashing TH04.

The 4 KiB encryption buffer would only be freed by the corresponding file_close() call, which of course never happens because the game crashes before it gets there. At one point, I really did suspect the cause to be some kind of memory leak or fragmentation inside master.lib, which would have been quite delightful to fix.
Instead, the most straightforward fix here is to bump up that memory limit by at least 4 KiB. Certainly easier than squeezing in a cdg_free() call for the star image before the pre-boss dialog without breaking position dependence.

Or, even better, let's nuke all these memory limits from orbit because they make little sense to begin with, and fix every other potential out-of-memory crash that modders would encounter when adding enough data to any of the 4 games that impose such limits on themselves. Unless you want to launch other binaries (which need to do their own memory allocations) after launching the game, there's really no reason to restrict the amount of memory available to a DOS process. Heck, whenever DOS creates a new one, it assigns all remaining free memory by default anyway.
Removing the memory limits also removes one of ZUN's few error checks, which end up quitting the game if there isn't at least a given maximum amount of conventional RAM available. While it might be tempting to reserve enough memory at the beginning of execution and then never check any allocation for a potential failure, that's exactly where something like TH04's crash comes from.
This game is also still running on DOS, where such an initial allocation failure is very unlikely to happen – no one fills close to half of conventional RAM with TSRs and then tries running one of these games. It might have been useful to detect systems with less than 640 KiB of actual, physical RAM, but none of the PC-98 models with that little amount of memory are fast enough to run these games to begin with. How ironic… a place where ZUN actually added an error check, and then it's mostly pointless.

Here's an archive that contains both fix variants, just in case. These were compiled from the th04_noems_crash_fix and mem_assign_all branches, and contain as little code changes as possible.
Edit (2022-04-18): For TH04, you probably want to download the 📝 community choice fix package instead, which contains this fix along with other workarounds for the Divide error crashes. 2021-11-29-Memory-limit-fixes.zip

So yeah, quite a complex bug, leaving no time for the TH03 scorefile format research after all. Next up: Raising prices.

📝 Posted:
🚚 Summary of:
P0149, P0150, P0151, P0152
Commits:
e1a26bb...05e4c4a, 05e4c4a...768251d, 768251d...4d24ca5, 4d24ca5...81fc861
💰 Funded by:
Blue Bolt, Ember2528, -Tom-, [Anonymous]
🏷 Tags:

…or maybe not that soon, as it would have only wasted time to untangle the bullet update commits from the rest of the progress. So, here's all the bullet spawning code in TH04 and TH05 instead. I hope you're ready for this, there's a lot to talk about!

(For the sake of readability, "bullets" in this blog post refers to the white 8×8 pellets and all 16×16 bullets loaded from MIKO16.BFT, nothing else.)


But first, what was going on 📝 in 2020? Spent 4 pushes on the basic types and constants back then, still ended up confusing a couple of things, and even getting some wrong. Like how TH05's "bullet slowdown" flag actually always prevents slowdown and fires bullets at a constant speed instead. :tannedcirno: Or how "random spread" is not the best term to describe that unused bullet group type in TH04.
Or that there are two distinct ways of clearing all bullets on screen, which deserve different names:

Mechanic #1: Clearing bullets for a custom amount of time, awarding 1000 points for all bullets alive on the first frame, and 100 points for all bullets spawned during the clear time.
Mechanic #2: Zapping bullets for a fixed 16 frames, awarding a semi-exponential and loudly announced Bonus!! for all bullets alive on the first frame, and preventing new bullets from being spawned during those 16 frames. In TH04 at least; thanks to a ZUN bug, zapping got reduced to 1 frame and no animation in TH05…

Bullets are zapped at the end of most midboss and boss phases, and cleared everywhere else – most notably, during bombs, when losing a life, or as rewards for extends or a maximized Dream bonus. The Bonus!! points awarded for zapping bullets are calculated iteratively, so it's not trivial to give an exact formula for these. For a small number 𝑛 of bullets, it would exactly be 5𝑛³ - 10𝑛² + 15𝑛 points – or, using uth05win's (correct) recursive definition, Bonus(𝑛) = Bonus(𝑛-1) + 15𝑛² - 5𝑛 + 10. However, one of the internal step variables is capped at a different number of points for each difficulty (and game), after which the points only increase linearly. Hence, "semi-exponential".


On to TH04's bullet spawn code then, because that one can at least be decompiled. And immediately, we have to deal with a pointless distinction between regular bullets, with either a decelerating or constant velocity, and special bullets, with preset velocity changes during their lifetime. That preset has to be set somewhere, so why have separate functions? In TH04, this separation continues even down to the lowest level of functions, where values are written into the global bullet array. TH05 merges those two functions into one, but then goes too far and uses self-modifying code to save a grand total of two local variables… Luckily, the rest of its actual code is identical to TH04.

Most of the complexity in bullet spawning comes from the (thankfully shared) helper function that calculates the velocities of the individual bullets within a group. Both games handle each group type via a large switch statement, which is where TH04 shows off another Turbo C++ 4.0 optimization: If the range of case values is too sparse to be meaningfully expressed in a jump table, it usually generates a linear search through a second value table. But with the -G command-line option, it instead generates branching code for a binary search through the set of cases. 𝑂(log 𝑛) as the worst case for a switch statement in a C++ compiler from 1994… that's so cool. But still, why are the values in TH04's group type enum all over the place to begin with? :onricdennat:
Unfortunately, this optimization is pretty rare in PC-98 Touhou. It only shows up here and in a few places in TH02, compared to at least 50 switch value tables.

In all of its micro-optimized pointlessness, TH05's undecompilable version at least fixes some of TH04's redundancy. While it's still not even optimal, it's at least a decently written piece of ASM… if you take the time to understand what's going on there, because it certainly took quite a bit of that to verify that all of the things which looked like bugs or quirks were in fact correct. And that's how the code for this function ended up with 35% comments and blank lines before I could confidently call it "reverse-engineered"…
Oh well, at least it finally fixes a correctness issue from TH01 and TH04, where an invalid bullet group type would fill all remaining slots in the bullet array with identical versions of the first bullet.

Something that both games also share in these functions is an over-reliance on globals for return values or other local state. The most ridiculous example here: Tuning the speed of a bullet based on rank actually mutates the global bullet template… which ZUN then works around by adding a wrapper function around both regular and special bullet spawning, which saves the base speed before executing that function, and restores it afterward. :zunpet: Add another set of wrappers to bypass that exact tuning, and you've expanded your nice 1-function interface to 4 functions. Oh, and did I mention that TH04 pointlessly duplicates the first set of wrapper functions for 3 of the 4 difficulties, which can't even be explained with "debugging reasons"? That's 10 functions then… and probably explains why I've procrastinated this feature for so long.

At this point, I also finally stopped decompiling ZUN's original ASM just for the sake of it. All these small TH05 functions would look horribly unidiomatic, are identical to their decompiled TH04 counterparts anyway, except for some unique constant… and, in the case of TH05's rank-based speed tuning function, actually become undecompilable as soon as we want to return a C++ class to preserve the semantic meaning of the return value. Mainly, this is because Turbo C++ does not allow register pseudo-variables like _AX or _AL to be cast into class types, even if their size matches. Decompiling that function would have therefore lowered the quality of the rest of the decompiled code, in exchange for the additional maintenance and compile-time cost of another translation unit. Not worth it – and for a TH05 port, you'd already have to decompile all the rest of the bullet spawning code anyway!


The only thing in there that was still somewhat worth being decompiled was the pre-spawn clipping and collision detection function. Due to what's probably a micro-optimization mistake, the TH05 version continues to spawn a bullet even if it was spawned on top of the player. This might sound like it has a different effect on gameplay… until you realize that the player got hit in this case and will either lose a life or deathbomb, both of which will cause all on-screen bullets to be cleared anyway. So it's at most a visual glitch.

But while we're at it, can we please stop talking about hitboxes? At least in the context of TH04 and TH05 bullets. The actual collision detection is described way better as a kill delta of 8×8 pixels between the center points of the player and a bullet. You can distribute these pixels to any combination of bullet and player "hitboxes" that make up 8×8. 4×4 around both the player and bullets? 1×1 for bullets, and 8×8 for the player? All equally valid… or perhaps none of them, once you keep in mind that other entity types might have different kill deltas. With that in mind, the concept of a "hitbox" turns into just a confusing abstraction.

The same is true for the 36×44 graze box delta. For some reason, this one is not exactly around the center of a bullet, but shifted to the right by 2 pixels. So, a bullet can be grazed up to 20 pixels right of the player, but only up to 16 pixels left of the player. uth05win also spotted this… and rotated the deltas clockwise by 90°?!


Which brings us to the bullet updates… for which I still had to research a decompilation workaround, because 📝 P0148 turned out to not help at all? Instead, the solution was to lie to the compiler about the true segment distance of the popup function and declare its signature far rather than near. This allowed ZUN to save that ridiculous overhead of 1 additional far function call/return per frame, and those precious 2 bytes in the BSS segment that he didn't have to spend on a segment value. 📝 Another function that didn't have just a single declaration in a common header file… really, 📝 how were these games even built???

The function itself is among the longer ones in both games. It especially stands out in the indentation department, with 7 levels at its most indented point – and that's the minimum of what's possible without goto. Only two more notable discoveries there:

  1. Bullets are the only entity affected by Slow Mode. If the number of bullets on screen is ≥ (24 + (difficulty * 8) + rank) in TH04, or (42 + (difficulty * 8)) in TH05, Slow Mode reduces the frame rate by 33%, by waiting for one additional VSync event every two frames.
    The code also reveals a second tier, with 50% slowdown for a slightly higher number of bullets, but that conditional branch can never be executed :zunpet:
  2. Bullets must have been grazed in a previous frame before they can be collided with. (Note how this does not apply to bullets that spawned on top of the player, as explained earlier!)

Whew… When did ReC98 turn into a full-on code review?! 😅 And after all this, we're still not done with TH04 and TH05 bullets, with all the special movement types still missing. That should be less than one push though, once we get to it. Next up: Back to TH01 and Konngara! Now have fun rewriting the Touhou Wiki Gameplay pages 😛

📝 Posted:
🚚 Summary of:
P0148
Commits:
c940059...e1a26bb
💰 Funded by:
[Anonymous]
🏷 Tags:

Back after taking way too long to get Touhou Patch Center's MediaWiki update feature complete… I'm still waiting for more translators to test and review the new translation interface before delivering and deploying it all, which will most likely lead to another break from ReC98 within the next few months. For now though, I'm happy to have mostly addressed the nagging responsibility I still had after willing that site into existence, and to be back working on ReC98. 🙂

As announced, the next few pushes will focus on TH04's and TH05's bullet spawning code, before I get to put all that accumulated TH01 money towards finishing all of konngara's code in TH01. For a full picture of what's happening with bullets, we'd really also like to have the bullet update function as readable C code though.
Clearing all bullets on the playfield will trigger a Bonus!! popup, displayed as 📝 gaiji in that proportional font. Unfortunately, TLINK refused to link the code as soon as I referenced the function for animating the popups at the top of the playfield? Which can only mean that we have to decompile that function first… :thonk:

So, let's turn that piece of technical debt into a full push, and first decompile another random set of previously reverse-engineered TH04 and TH05 functions. Most of these are stored in a different place within the two MAIN.EXE binaries, and the tried-and-true method of matching segment names would therefore have introduced several unnecessary translation units. So I resorted to a segment splitting technique I should have started using way earlier: Simply creating new segments with names derived from their functions, at the exact positions they're needed. All the new segment start and end directives do bloat the ASM code somewhat, and certainly contributed to this push barely removing any actual lines of code. However, what we get in return is total freedom as far as decompilation order is concerned, 📝 which should be the case for any ReC project, really. And in the end, all these tiny code segments will cancel out anyway.
If only we could do the same with the data segment…


The popup function happened to be the final one I RE'd before my long break in the spring of 2019. Back then, I didn't even bother looking into that 64-frame delay between changing popups, and what that meant for the game.
Each of these popups stays on screen for 128 frames, during which, of course, another popup-worthy event might happen. Handling this cleanly without removing previous popups too early would involve some sort of event queue, whose size might even be meaningfully limited to the number of distinct events that can happen. But still, that'd be a data structure, and we're not gonna have that! :zunpet: Instead, ZUN simply keeps two variables for the new and current popup ID. During an active popup, any change to that ID will only be committed once the current popup has been shown for at least 64 frames. And during that time, that new ID can be freely overwritten with a different one, which drops any previous, undisplayed event. But surely, there won't be more than two events happening within 63 frames, right? :tannedcirno:

The rest was fairly uneventful – no newly RE'd functions in this push, after all – until I reached the widely used helper function for applying the current vertical scrolling offset to a Y coordinate. Its combination of a function parameter, the pascal calling convention, and no stack frame was previously thought to be undecompilable… except that it isn't, and the decompilation didn't even require any new workarounds to be developed? Good thing that I already forgot how impossible it was to decompile the first function I looked at that fell into this category!
Oh well, this discovery wasn't too groundbreaking. Looking back at all the other functions with that combination only revealed a grand total of 1 additional one where a decompilation made sense: TH05's version of snd_kaja_interrupt(), which is now compiled from the same C++ file for all 4 games that use it. And well, looks like some quirks really remain unnoticed and undocumented until you look at a function for the 11th time: Its return value is undefined if BGM is inactive – that is, if the user disabled it, or if no FM board is installed. Not that it matters for the original code, which never uses this function to retrieve anything from KAJA's drivers. But people apparently do copy ReC98 code into their own projects, so it is something to keep in mind.


All in all, nothing quite at jank level in this one, but we were surely grazing that tag. Next up, with that out of the way: The bullet update/step function! Very soon in fact, since I've mostly got it done already.

📝 Posted:
🚚 Summary of:
P0147
Commits:
456b621...c940059
💰 Funded by:
Ember2528, -Tom-
🏷 Tags:

Didn't quite get to cover background rendering for TH05's Stage 1-5 bosses in this one, as I had to reverse-engineer two more fundamental parts involved in boss background rendering before.

First, we got the those blocky transitions from stage tiles to bomb and boss backgrounds, loaded from BB*.BB and ST*.BB, respectively. These files store 16 frames of animation, with every bit corresponding to a 16×16 tile on the playfield. With 384×368 pixels to be covered, that would require 69 bytes per frame. But since that's a very odd number to work with in micro-optimized ASM, ZUN instead stores 512×512 pixels worth of bits, ending up with a frame size of 128 bytes, and a per-frame waste of 59 bytes. :tannedcirno: At least it was possible to decompile the core blitting function as __fastcall for once.
But wait, TH05 comes with, and loads, a bomb .BB file for every character, not just for the Reimu and Yuuka bomb transitions you see in-game… 🤔 Restoring those unused stage tile → bomb image transition animations for Mima and Marisa isn't that trivial without having decompiled their actual bomb animation functions before, so stay tuned!

Interestingly though, the code leaves out what would look like the most obvious optimization: All stage tiles are unconditionally redrawn each frame before they're erased again with the 16×16 blocks, no matter if they weren't covered by such a block in the previous frame, or are going to be covered by such a block in this frame. The same is true for the static bomb and boss background images, where ZUN simply didn't write a .CDG blitting function that takes the dirty tile array into account. If VRAM writes on PC-98 really were as slow as the games' README.TXT files claim them to be, shouldn't all the optimization work have gone towards minimizing them? :thonk: Oh well, it's not like I have any idea what I'm talking about here. I'd better stop talking about anything relating to VRAM performance on PC-98… :onricdennat:


Second, it finally was time to solve the long-standing confusion about all those callbacks that are supposed to render the playfield background. Given the aforementioned static bomb background images, ZUN chose to make this needlessly complicated. And so, we have two callback function pointers: One during bomb animations, one outside of bomb animations, and each boss update function is responsible for keeping the former in sync with the latter. :zunpet:

Other than that, this was one of the smoothest pushes we've had in a while; the hardest parts of boss background rendering all were part of 📝 the last push. Once you figured out that ZUN does indeed dynamically change hardware color #0 based on the current boss phase, the remaining one function for Shinki, and all of EX-Alice's background rendering becomes very straightforward and understandable.


Meanwhile, -Tom- told me about his plans to publicly release 📝 his TH05 scripting toolkit once TH05's MAIN.EXE would hit around 50% RE! That pretty much defines what the next bunch of generic TH05 pushes will go towards: bullets, shared boss code, and one full, concrete boss script to demonstrate how it's all combined. Next up, therefore: TH04's bullet firing code…? Yes, TH04's. I want to see what I'm doing before I tackle the undecompilable mess that is TH05's bullet firing code, and you all probably want readable code for that feature as well. Turns out it's also the perfect place for Blue Bolt's pending contributions.

📝 Posted:
🚚 Summary of:
P0139
Commits:
864e864...d985811
💰 Funded by:
[Anonymous]
🏷 Tags:

Technical debt, part 10… in which two of the PMD-related functions came with such complex ramifications that they required one full push after all, leaving no room for the additional decompilations I wanted to do. At least, this did end up being the final one, completing all SHARED segments for the time being.


The first one of these functions determines the BGM and sound effect modes, combining the resident type of the PMD driver with the Option menu setting. The TH04 and TH05 version is apparently coded quite smartly, as PC-98 Touhou only needs to distinguish "OPN- / PC-9801-26K-compatible sound sources handled by PMD.COM" from "everything else", since all other PMD varieties are OPNA- / PC-9801-86-compatible.
Therefore, I only documented those two results returned from PMD's AH=09h function. I'll leave a comprehensive, fully documented enum to interested contributors, since that would involve research into basically the entire history of the PC-9800 series, and even the clearly out-of-scope PC-88VA. After all, distinguishing between more versions of the PMD driver in the Option menu (and adding new sprites for them!) is strictly mod territory.


The honor of being the final decompiled function in any SHARED segment went to TH04's snd_load(). TH04 contains by far the sanest version of this function: Readable C code, no new ZUN bugs (and still missing file I/O error handling, of course)… but wait, what about that actual file read syscall, using the INT 21h, AH=3Fh DOS file read API? Reading up to a hardcoded number of bytes into PMD's or MMD's song or sound effect buffer, 20 KiB in TH02-TH04, 64 KiB in TH05… that's kind of weird. About time we looked closer into this. :thonk:

Turns out that no, KAJA's driver doesn't give you the full 64 KiB of one memory segment for these, as especially TH05's code might suggest to anyone unfamiliar with these drivers. :zunpet: Instead, you can customize the size of these buffers on its command line. In GAME.BAT, ZUN allocates 8 KiB for FM songs, 2 KiB for sound effects, and 12 KiB for MMD files in TH02… which means that the hardcoded sizes in snd_load() are completely wrong, no matter how you look at them. :onricdennat: Consequently, this read syscall will overflow PMD's or MMD's song or sound effect buffer if the given file is larger than the respective buffer size.
Now, ZUN could have simply hardcoded the sizes from GAME.BAT instead, and it would have been fine. As it also turns out though, PMD has an API function (AH=22h) to retrieve the actual buffer sizes, provided for exactly that purpose. There is little excuse not to use it, as it also gives you PMD's default sizes if you don't specify any yourself.
(Unless your build process enumerates all PMD files that are part of the game, and bakes the largest size into both snd_load() and GAME.BAT. That would even work with MMD, which doesn't have an equivalent for AH=22h.)

What'd be the consequence of loading a larger file then? Well, since we don't get a full segment, let's look at the theoretical limit first.
PMD prefers to keep both its driver code and the data buffers in a single memory segment. As a result, the limit for the combined size of the song, instrument, and sound effect buffer is determined by the amount of code in the driver itself. In PMD86 version 4.8o (bundled with TH04 and TH05) for example, the remaining size for these buffers is exactly 45,555 bytes. Being an actually good programmer who doesn't blindly trust user input, KAJA thankfully validates the sizes given via the /M, /V, and /E command-line options before letting the driver reside in memory, and shuts down with an error message if they exceed 40 KiB. Would have been even better if he calculated the exact size – even in the current PMD version 4.8s from January 2020, it's still a hardcoded value (see line 8581).
Either way: If the file is larger than this maximum, the concrete effect is down to the INT 21h, AH=3Fh implementation in the underlying DOS version. DOS 3.3 treats the destination address as linear and reads past the end of the segment, DOS 5.0 and DOSBox-X truncate the number of bytes to not exceed the remaining space in the segment, and maybe there's even a DOS that wraps around and ends up overwriting the PMD driver code. In any case: You will overwrite what's after the driver in memory – typically, the game .EXE and its master.lib functions.

It almost feels like a happy accident that this doesn't cause issues in the original games. The largest PMD file in any of the 4 games, the -86 version of 幽夢 ~ Inanimate Dream, takes up 8,099 bytes, just under the 8,192 byte limit for BGM. For modders, I'd really recommend implementing this properly, with PMD's AH=22h function and error handling, once position independence has been reached.

Whew, didn't think I'd be doing more research into KAJA's drivers during regular ReC98 development! That's probably been the final time though, as all involved functions are now decompiled, and I'm unlikely to iterate over them again.


And that's it! Repaid the biggest chunk of technical debt, time for some actual progress again. Next up: Reopening the store tomorrow, and waiting for new priorities. If we got nothing by Sunday, I'm going to put the pending [Anonymous] pushes towards some work on the website.

📝 Posted:
🚚 Summary of:
P0137
Commits:
07bfcf2...8d953dc
💰 Funded by:
[Anonymous]
🏷 Tags:

Whoops, the build was broken again? Since P0127 from mid-November 2020, on TASM32 version 5.3, which also happens to be the one in the DevKit… That version changed the alignment for the default segments of certain memory models when requesting .386 support. And since redefining segment alignment apparently is highly illegal and absolutely has to be a build error, some of the stand-alone .ASM translation units didn't assemble anymore on this version. I've only spotted this on my own because I casually compiled ReC98 somewhere else – on my development system, I happened to have TASM32 version 5.0 in the PATH during all this time.
At least this was a good occasion to get rid of some weird segment alignment workarounds from 2015, and replace them with the superior convention of using the USE16 modifier for the .MODEL directive.

ReC98 would highly benefit from a build server – both in order to immediately spot issues like this one, and as a service for modders. Even more so than the usual open-source project of its size, I would say. But that might be exactly because it doesn't seem like something you can trivially outsource to one of the big CI providers for open-source projects, and quickly set it up with a few lines of YAML.
That might still work in the beginning, and we might get by with a regular 64-bit Windows 10 and DOSBox running the exact build tools from the DevKit. Ideally, though, such a server should really run the optimal configuration of a 32-bit Windows 10, allowing both the 32-bit and the 16-bit build step to run natively, which already is something that no popular CI service out there offers. Then, we'd optimally expand to Linux, every other Windows version down to 95, emulated PC-98 systems, other TASM versions… yeah, it'd be a lot. An experimental project all on its own, with additional hosting costs and probably diminishing returns, the more it expands…
I've added it as a category to the order form, let's see how much interest there is once the store reopens (which will be at the beginning of May, at the latest). That aside, it would 📝 also be a great project for outside contributors!


So, technical debt, part 8… and right away, we're faced with TH03's low-level input function, which 📝 once 📝 again 📝 insists on being word-aligned in a way we can't fake without duplicating translation units. Being undecompilable isn't exactly the best property for a function that has been interesting to modders in the past: In 2018, spaztron64 created an ASM-level mod that hardcoded more ergonomic key bindings for human-vs-human multiplayer mode: 2021-04-04-TH03-WASD-2player.zip However, this remapping attempt remained quite limited, since we hadn't (and still haven't) reached full position independence for TH03 yet. There's quite some potential for size optimizations in this function, which would allow more BIOS key groups to already be used right now, but it's not all that obvious to modders who aren't intimately familiar with x86 ASM. Therefore, I really wouldn't want to keep such a long and important function in ASM if we don't absolutely have to…

… and apparently, that's all the motivation I needed? So I took the risk, and spent the first half of this push on reverse-engineering TCC.EXE, to hopefully find a way to get word-aligned code segments out of Turbo C++ after all.

And there is! The -WX option, used for creating DPMI applications, messes up all sorts of code generation aspects in weird ways, but does in fact mark the code segment as word-aligned. We can consider ourselves quite lucky that we get to use Turbo C++ 4.0, because this feature isn't available in any previous version of Borland's C++ compilers.
That allowed us to restore all the decompilations I previously threw away… well, two of the three, that lookup table generator was too much of a mess in C. :tannedcirno: But what an abuse this is. The subtly different code generation has basically required one creative workaround per usage of -WX. For example, enabling that option causes the regular PUSH BP and POP BP prolog and epilog instructions to be wrapped with INC BP and DEC BP, for some reason:

a_function_compiled_with_wx proc
	inc 	bp    	; ???
	push	bp
	mov 	bp, sp
	    	      	; [… function code …]
	pop 	bp
	dec 	bp    	; ???
	ret
a_function_compiled_with_wx endp

Luckily again, all the functions that currently require -WX don't set up a stack frame and don't take any parameters.
While this hasn't directly been an issue so far, it's been pretty close: snd_se_reset(void) is one of the functions that require word alignment. Previously, it shared a translation unit with the immediately following snd_se_play(int new_se), which does take a parameter, and therefore would have had its prolog and epilog code messed up by -WX. Since the latter function has a consistent (and thus, fakeable) alignment, I simply split that code segment into two, with a new -WX translation unit for just snd_se_reset(void). Problem solved – after all, two C++ translation units are still better than one ASM translation unit. :onricdennat: Especially with all the previous #include improvements.

The rest was more of the usual, getting us 74% done with repaying the technical debt in the SHARED segment. A lot of the remaining 26% is TH04 needing to catch up with TH03 and TH05, which takes comparatively little time. With some good luck, we might get this done within the next push… that is, if we aren't confronted with all too many more disgusting decompilations, like the two functions that ended this push. If we are, we might be needing 10 pushes to complete this after all, but that piece of research was definitely worth the delay. Next up: One more of these.

📝 Posted:
🚚 Summary of:
P0135, P0136
Commits:
a6eed55...252c13d, 252c13d...07bfcf2
💰 Funded by:
[Anonymous]
🏷 Tags:

Alright, no more big code maintenance tasks that absolutely need to be done right now. Time to really focus on parts 6 and 7 of repaying technical debt, right? Except that we don't get to speed up just yet, as TH05's barely decompilable PMD file loading function is rather… complicated.
Fun fact: Whenever I see an unusual sequence of x86 instructions in PC-98 Touhou, I first consult the disassembly of Wolfenstein 3D. That game was originally compiled with the quite similar Borland C++ 3.0, so it's quite helpful to compare its ASM to the officially released source code. If I find the instructions in question, they mostly come from that game's ASM code, leading to the amusing realization that "even John Carmack was unable to get these instructions out of this compiler" :onricdennat: This time though, Wolfenstein 3D did point me to Borland's intrinsics for common C functions like memcpy() and strchr(), available via #pragma intrinsic. Bu~t those unfortunately still generate worse code than what ZUN micro-optimized here. Commenting how these sequences of instructions should look in C is unfortunately all I could do here.
The conditional branches in this function did compile quite nicely though, clarifying the control flow, and clearly exposing a ZUN bug: TH05's snd_load() will hang in an infinite loop when trying to load a non-existing -86 BGM file (with a .M2 extension) if the corresponding -26 BGM file (with a .M extension) doesn't exist either.

Unsurprisingly, the PMD channel monitoring code in TH05's Music Room remains undecompilable outside the two most "high-level" initialization and rendering functions. And it's not because there's data in the middle of the code segment – that would have actually been possible with some #pragmas to ensure that the data and code segments have the same name. As soon as the SI and DI registers are referenced anywhere, Turbo C++ insists on emitting prolog code to save these on the stack at the beginning of the function, and epilog code to restore them from there before returning. Found that out in September 2019, and confirmed that there's no way around it. All the small helper functions here are quite simply too optimized, throwing away any concern for such safety measures. 🤷
Oh well, the two functions that were decompilable at least indicate that I do try.


Within that same 6th push though, we've finally reached the one function in TH05 that was blocking further progress in TH04, allowing that game to finally catch up with the others in terms of separated translation units. Feels good to finally delete more of those .ASM files we've decompiled a while ago… finally!

But since that was just getting started, the most satisfying development in both of these pushes actually came from some more experiments with macros and inline functions for near-ASM code. By adding "unused" dummy parameters for all relevant registers, the exact input registers are made more explicit, which might help future port authors who then maybe wouldn't have to look them up in an x86 instruction reference quite as often. At its best, this even allows us to declare certain functions with the __fastcall convention and express their parameter lists as regular C, with no additional pseudo-registers or macros required.
As for output registers, Turbo C++'s code generation turns out to be even more amazing than previously thought when it comes to returning pseudo-registers from inline functions. A nice example for how this can improve readability can be found in this piece of TH02 code for polling the PC-98 keyboard state using a BIOS interrupt:

inline uint8_t keygroup_sense(uint8_t group) {
	_AL = group;
	_AH = 0x04;
	geninterrupt(0x18);
	// This turns the output register of this BIOS call into the return value
	// of this function. Surprisingly enough, this does *not* naively generate
	// the `MOV AL, AH` instruction you might expect here!
	return _AH;
}

void input_sense(void)
{
	// As a result, this assignment becomes `_AH = _AH`, which Turbo C++
	// never emits as such, giving us only the three instructions we need.
	_AH = keygroup_sense(8);

	// Whereas this one gives us the one additional `MOV BH, AH` instruction
	// we'd expect, and nothing more.
	_BH = keygroup_sense(7);

	// And now it's obvious what both of these registers contain, from just
	// the assignments above.
	if(_BH & K7_ARROW_UP || _AH & K8_NUM_8) {
		key_det |= INPUT_UP;
	}
	// […]
}

I love it. No inline assembly, as close to idiomatic C code as something like this is going to get, yet still compiling into the minimum possible number of x86 instructions on even a 1994 compiler. This is how I keep this project interesting for myself during chores like these. :tannedcirno: We might have even reached peak inline already?

And that's 65% of technical debt in the SHARED segment repaid so far. Next up: Two more of these, which might already complete that segment? Finally!

📝 Posted:
🚚 Summary of:
P0133
Commits:
045450c...1d5db71
💰 Funded by:
[Anonymous]
🏷 Tags:

Wow, 31 commits in a single push? Well, what the last push had in progress, this one had in maintenance. The 📝 master.lib header transition absolutely had to be completed in this one, for my own sanity. And indeed, it reduced the build time for the entirety of ReC98 to about 27 seconds on my system, just as expected in the original announcement. Looking forward to even faster build times with the upcoming #include improvements I've got up my sleeve! The port authors of the future are going to appreciate those quite a bit.

As for the new translation units, the funniest one is probably TH05's function for blitting the 1-color .CDG images used for the main menu options. Which is so optimized that it becomes decompilable again, by ditching the self-modifying code of its TH04 counterpart in favor of simply making better use of CPU registers. The resulting C code is still a mess, but what can you do. :tannedcirno:
This was followed by even more TH05 functions that clearly weren't compiled from C, as evidenced by their padding bytes. It's about time I've documented my lack of ideas of how to get those out of Turbo C++. :onricdennat:

And just like in the previous push, I also had to 📝 throw away a decompiled TH02 function purely due to alignment issues. Couldn't have been a better one though, no one's going to miss a residency check for the MMD driver that is largely identical to the corresponding (and indeed decompilable) function for the PMD driver. Both of those should have been merged into a single function anyway, given how they also mutate the game's sound configuration flags…

In the end, I've slightly slowed down with this one, with only 37% of technical debt done after this 4th dedicated push. Next up: One more of these, centered around TH05's stupidly optimized .PI functions. Maybe also with some more reverse-engineering, after not having done any for 1½ months?

📝 Posted:
🚚 Summary of:
P0126, P0127
Commits:
6c22af7...8b01657, 8b01657...dc65b59
💰 Funded by:
Blue Bolt, [Anonymous]
🏷 Tags:

Alright, back to continuing the master.hpp transition started in P0124, and repaying technical debt. The last blog post already announced some ridiculous decompilations… and in fact, not a single one of the functions in these two pushes was decompilable into idiomatic C/C++ code.

As usual, that didn't keep me from trying though. The TH04 and TH05 version of the infamous 16-pixel-aligned, EGC-accelerated rectangle blitting function from page 1 to page 0 was fairly average as far as unreasonable decompilations are concerned.
The big blocker in TH03's MAIN.EXE, however, turned out to be the .MRS functions, used to render the gauge attack portraits and bomb backgrounds. The blitting code there uses the additional FS and GS segment registers provided by the Intel 386… which

  1. are not supported by Turbo C++'s inline assembler, and
  2. can't be turned into pointers, due to a compiler bug in Turbo C++ that generates wrong segment prefix opcodes for the _FS and _GS pseudo-registers.

Apparently I'm the first one to even try doing that with this compiler? I haven't found any other mention of this bug…
Compiling via assembly (#pragma inline) would work around this bug and generate the correct instructions. But that would incur yet another dependency on a 16-bit TASM, for something honestly quite insignificant.

What we can always do, however, is using __emit__() to simply output x86 opcodes anywhere in a function. Unlike spelled-out inline assembly, that can even be used in helper functions that are supposed to inline… which does in fact allow us to fully abstract away this compiler bug. Regular if() comparisons with pseudo-registers wouldn't inline, but "converting" them into C++ template function specializations does. All that's left is some C preprocessor abuse to turn the pseudo-registers into types, and then we do retain a normal-looking poke() call in the blitting functions in the end. 🤯

Yeah… the result is batshit insane. I may have gone too far in a few places…


One might certainly argue that all these ridiculous decompilations actually hurt the preservation angle of this project. "Clearly, ZUN couldn't have possibly written such unreasonable C++ code. So why pretend he did, and not just keep it all in its more natural ASM form?" Well, there are several reasons:

Unfortunately, these pushes also demonstrated a second disadvantage in trying to decompile everything possible: Since Turbo C++ lacks TASM's fine-grained ability to enforce code alignment on certain multiples of bytes, it might actually be unfeasible to link in a C-compiled object file at its intended original position in some of the .EXE files it's used in. Which… you're only going to notice once you encounter such a case. Due to the slightly jumbled order of functions in the 📝 second, shared code segment, that might be long after you decompiled and successfully linked in the function everywhere else.

And then you'll have to throw away that decompilation after all 😕 Oh well. In this specific case (the lookup table generator for horizontally flipping images), that decompilation was a mess anyway, and probably helped nobody. I could have added a dummy .OBJ that does nothing but enforce the needed 2-byte alignment before the function if I really insisted on keeping the C version, but it really wasn't worth it.


Now that I've also described yet another meta-issue, maybe there'll really be nothing to say about the next technical debt pushes? :onricdennat: Next up though: Back to actual progress again, with TH01. Which maybe even ends up pushing that game over the 50% RE mark?

📝 Posted:
🚚 Summary of:
P0119
Commits:
cbf14eb...453dd3c
💰 Funded by:
[Anonymous], -Tom-
🏷 Tags:

So, TH05 OP.EXE. The first half of this push started out nicely, with an easy decompilation of the entire player character selection menu. Typical ZUN quality, with not much to say about it. While the overall function structure is identical to its TH04 counterpart, the two games only really share small snippets inside these functions, and do need to be RE'd separately.

The high score viewing (not registration) menu would have been next. Unfortunately, it calls one of the GENSOU.SCR loading functions… which are all a complete mess that still needed to be sorted out first. 5 distinct functions in 6 binaries, and of course TH05 also micro-optimized its MAIN.EXE version to directly use the DOS INT 21h file loading API instead of master.lib's wrappers. Could have all been avoided with a single method on the score data structure, taking a player character ID and a difficulty level as parameters…

So, no score menu in this push then. Looking at the other end of the ASM code though, we find the starting functions for the main game, the Extra Stage, and the demo replays, which did fit perfectly to round out this push.

Which is where we find an easter egg! 🥚 If you've ever looked into 怪綺談2.DAT, you might have noticed 6 .REC files with replays for the Demo Play mode. However, the game only ever seems to cycle between 4 replays. So what's in the other two, and why are they 40 KB instead of just 10 KB like the others? Turns out that they combine into a full Extra Stage Clear replay with Mima, with 3 bombs and 1 death, obviously recorded by ZUN himself. The split into two files for the stage (DEMO4.REC) and boss (DEMO5.REC) portion is merely an attempt to limit the amount of simultaneously allocated heap memory.
To watch this replay without modding the game, unlock the Extra Stage with all 4 characters, then hold both the ⬅️ left and ➡️ right arrow keys in the main menu while waiting for the usual demo replay. I can't possibly be the first one to discover this, but I couldn't find any other mention of it.
Edit (2021-03-15): ZUN did in fact document this replay in Section 6 of TH05's OMAKE.TXT, along with the exact method to view it. Thanks to Popfan for the discovery!

Here's a recording of the whole replay:

Note how the boss dialogue is skipped. MAIN.EXE actually contains no less than 6 if() branches just to distinguish this overly long replay from the regular ones.


I'd really like to do the TH04 and TH05 main menus in parallel, since we can expect a bit more shared code after all the initial differences. Therefore, I'm going to put the next "anything" push towards covering the TH04 version of those functions. Next up though, it's back to TH01, with more redundant image format code…

📝 Posted:
🚚 Summary of:
P0118
Commits:
0bb5bc3...cbf14eb
💰 Funded by:
-Tom-, Ember2528
🏷 Tags:

🎉 TH05 is finally fully position-independent! 🎉 To celebrate this milestone, -Tom- coded a little demo, which we recorded on both an emulator and on real PC-98 hardware:

For all the new people who are unfamiliar with PC-98 Touhou internals: Boss behavior is hardcoded into MAIN.EXE, rather than being scriptable via separate .ECL files like in Windows Touhou. That's what makes this kind of a big deal.


What does this mean?

You can now freely add or remove both data and code anywhere in TH05, by editing the ReC98 codebase, writing your mod in ASM or C/C++, and recompiling the code. Since all absolute memory addresses have now been converted to labels, this will work without causing any instability. See the position independence section in the FAQ for a more thorough explanation about why this was a problem.

By extension, this also means that it's now theoretically possible to use a different compiler on the source code. But:

What does this not mean?

The original ZUN code hasn't been completely reverse-engineered yet, let alone decompiled. As the final PC-98 Touhou game, TH05 also happens to have the largest amount of actual ZUN-written ASM that can't ever be decompiled within ReC98's constraints of a legit source code reconstruction. But a lot of the originally-in-C code is also still in ASM, which might make modding a bit inconvenient right now. And while I have decompiled a bunch of functions, I selected them largely because they would help with PI (as requested by the backers), and not because they are particularly relevant to typical modding interests.

As a result, the code might also be a bit confusingly organized. There's quite a conflict between various goals there: On the one hand, I'd like to only have a single instance of every function shared with earlier games, as well as reduce ZUN's code duplication within a single game. On the other hand, this leads to quite a lot of code being scattered all over the place and then #include-pasted back together, except for the places where 📝 this doesn't work, and you'd have to use multiple translation units anyway… I'm only beginning to figure out the best structure here, and some more reverse-engineering attention surely won't hurt.

Also, keep in mind that the code still targets x86 Real Mode. To work effectively in this codebase, you'd need some familiarity with memory segmentation, and how to express it all in code. This tends to make even regular C++ development about an order of magnitude harder, especially once you want to interface with the remaining ASM code. That part made -Tom- struggle quite a bit with implementing his custom scripting language for the demo above. For now, he built that demo on quite a limited foundation – which is why he also chose to release neither the build nor the source publically for the time being.
So yeah, you're definitely going to need the TASM and Borland C++ manuals there.

tl;dr: We now know everything about this game's data, but not quite as much about this game's code.

So, how long until source ports become a realistic project?

You probably want to wait for 100% RE, which is when everything that can be decompiled has been decompiled.

Unless your target system is 16-bit Windows, in which case you could theoretically start right away. 📝 Again, this would be the ideal first system to port PC-98 Touhou to: It would require all the generic portability work to remove the dependency on PC-98 hardware, thus paving the way for a subsequent port to modern systems, yet you could still just drop in any undecompiled ASM.

Porting to IBM-compatible DOS would only be a harder and less universally useful version of that. You'd then simply exchange one architecture, with its idiosyncrasies and limits, for another, with its own set of idiosyncrasies and limits. (Unless, of course, you already happen to be intimately familiar with that architecture.) The fact that master.lib provides DOS/V support would have only mattered if ZUN consistently used it to abstract away PC-98 hardware at every single place in the code, which is definitely not the case.


The list of actually interesting findings in this push is, 📝 again, very short. Probably the most notable discovery: The low-level part of the code that renders Marisa's laser from her TH04 Illusion Laser shot type is still present in TH05. Insert wild mass guessing about potential beta version shot types… Oh, and did you know that the order of background images in the Extra Stage staff roll differs by character?

Next up: Finally driving up the RE% bar again, by decompiling some TH05 main menu code.

📝 Posted:
🚚 Summary of:
P0117
Commits:
03048c3...0bb5bc3
💰 Funded by:
[Anonymous]
🏷 Tags:

Wouldn't it be a bit disappointing to have TH05 completely position-independent, but have it still require hex-editing of the original ZUN.COM to mod its gaiji characters? As in, these custom "text" glyphs, available to the PC-98 text RAM:

TH05 gaiji characters

Especially since we now even have a sprite converter… the lack of which was exactly 📝 what made rebuilding ZUN.COM not that worthwhile before. So, before the big release, let's get all the remaining ZUN.COM sub-binaries of TH04 and TH05 dumped into .ASM files, and re-assembled and linked during the build process.

This is also the moment in which Egor's 2018 reimplementation of O. Morikawa's comcstm finally gets to shine. Back then, I considered it too early to even bother with ZUN.COM and reimplementing the .COM wrapper that ZUN originally used to bundle multiple smaller executables into that single binary. But now that the time is right, it is nice to have that code, as it allowed me to get these rebuilds done in half a push. Otherwise, it would have surely required one or two dedicated ones.

Since we like correctness here, newly dumped ZUN code means that it also has to be included in the RE% baseline calculation. This is why TH04's and TH05's overall RE% bars have gone back a tiny bit… in case you remember how they previously looked like :tannedcirno: After all, I would like to figure out where all that memory allocated during TH04's and TH05's memory check is freed, if at all.


Alright, one half of a push left… Y'know, getting rid of those last few PI false positives is actually one of the most annoying chores in this project, and quite stressful as well: I have to convince myself that the remaining false positives are, in fact, not memory references, but with way too little time for in-depth RE and to denote what they are instead. In that situation, everyone (including myself!) is anticipating that PI goal, and no one is really interested in RE. (Well… that is, until they actually get to developing their mod. But more on that tomorrow. :onricdennat:) Which means that it boils down to quite some hasty, dumb, and superficial RE around those remaining numbers.

So, in the hope of making it less annoying for the other 4 games in the future, let's systematically cover the sources of those remaining false positives in TH05, over all games. I/O port accesses with either the port or the value in registers (and thus, no longer as an immediate argument to the IN or OUT instructions, which the PI counter can clearly ingore), palette color arithmetic, or heck, 0xFF constants that obviously just mean "-1" and are not a reference to offset 0xFF in the data segment. All of this, of course, once again had a way bigger effect on everything but an almost position-independent TH05… but hey, that's the sort of thing you reserve the "anything" pushes for. And that's also how we get some of the single biggest PI% gains we have seen so far, and will be seeing before the 100% PI mark. And yes, those will continue in the next push.

Alright! Big release tomorrow…

📝 Posted:
🚚 Summary of:
P0115, P0116
Commits:
967bb8b...e5328a3, e5328a3...03048c3
💰 Funded by:
Lmocinemod, Blue Bolt, [Anonymous]
🏷 Tags:

Finally, after a long while, we've got two pushes with barely anything to talk about! Continuing the road towards 100% PI for TH05, these were exactly the two pushes that TH05 MAINE.EXE PI was estimated to additionally cost, relative to TH04's. Consequently, they mostly went to TH05's unique data structures in the ending cutscenes, the score name registration menu, and the staff roll.

A unique feature in there is TH05's support for automatic text color changes in its ending scripts, based on the first full-width Shift-JIS codepoint in a line. The \c=codepoint,color commands at the top of the _ED??.TXT set up exactly this codepoint→color mapping. As far as I can tell, TH05 is the only Touhou game with a feature like this – even the Windows Touhou games went back to manually spelling out each color change.

The orb particles in TH05's staff roll also try to be a bit unique by using 32-bit X and Y subpixel variables for their current position. With still just 4 fractional bits, I can't really tell yet whether the extended range was actually necessary. Maybe due to how the "camera scrolling" through "space" was implemented? All other entities were pretty much the usual fare, though.
12.4, 4.4, and now a 28.4 fixed-point format… yup, 📝 C++ templates were definitely the right choice.

At the end of its staff roll, TH05 not only displays the usual performance verdict, but then scrolls in the scores at the end of each stage before switching to the high score menu. The simplest way to smoothly scroll between two full screens on a PC-98 involves a separate bitmap… which is exactly what TH05 does here, reserving 28,160 bytes of its global data segment for just one overly large monochrome 320×704 bitmap where both the screens are rendered to. That's… one benefit of splitting your game into multiple executables, I guess? :tannedcirno:
Not sure if it's common knowledge that you can actually scroll back and forth between the two screens with the Up and Down keys before moving to the score menu. I surely didn't know that before. But it makes sense – might as well get the most out of that memory.


The necessary groundwork for all of this may have actually made TH04's (yes, TH04's) MAINE.EXE technically position-independent. Didn't quite reach the same goal for TH05's – but what we did reach is ⅔ of all PC-98 Touhou code now being position-independent! Next up: Celebrating even more milestones, as -Tom- is about to finish development on his TH05 MAIN.EXE PI demo…

📝 Posted:
🚚 Summary of:
P0111, P0112
Commits:
8b5c146...4ef4c9e, 4ef4c9e...e447a2d
💰 Funded by:
[Anonymous], Blue Bolt
🏷 Tags:

Only one newly ordered push since I've reopened the store? Great, that's all the justification I needed for the extended maintenance delay that was part of these two pushes 😛

Having to write comments to explain whether coordinates are relative to the top-left corner of the screen or the top-left corner of the playfield has finally become old. So, I introduced distinct types for all the coordinate systems we typically encounter, applying them to all code decompiled so far. Note how the planar nature of PC-98 VRAM meant that X and Y coordinates also had to be different from each other. On the X side, there's mainly the distinction between the [0; 640] screen space and the corresponding [0; 80] VRAM byte space. On the Y side, we also have the [0; 400] screen space, but the visible area of VRAM might be limited to [0; 200] when running in the PC-98's line-doubled 640×200 mode. A VRAM Y coordinate also always implies an added offset for vertical scrolling.
During all of the code reconstruction, these types can only have a documenting purpose. Turning them into anything more than just typedefs to int, in order to define conversion operators between them, simply won't recompile into identical binaries. Modding and porting projects, however, now have a nice foundation for doing just that, and can entirely lift coordinate system transformations into the type system, without having to proofread all the meaningless int declarations themselves.


So, what was left in terms of memory references? EX-Alice's fire waves were our final unknown entity that can collide with the player. Decently implemented, with little to say about them.

That left the bomb animation structures as the one big remaining PI blocker. They started out nice and simple in TH04, with a small 6-byte star animation structure used for both Reimu and Marisa. TH05, however, gave each character her own animation… and what the hell is going on with Reimu's blue stars there? Nope, not going to figure this out on ASM level.

A decompilation first required some more bomb-related variables to be named though. Since this was part of a generic RE push, it made sense to do this in all 5 games… which then led to nice PI gains in anything but TH05. :tannedcirno: Most notably, we now got the "pulling all items to player" flag in TH04 and TH05, which is actually separate from bombing. The obvious cheat mod is left as an exercise to the reader.


So, TH05 bomb animations. Just like the 📝 custom entity types of this game, all 4 characters share the same memory, with the superficially same 10-byte structure.
But let's just look at the very first field. Seen from a low level, it's a simple struct { int x, y; } pos, storing the current position of the character-specific bomb animation entity. But all 4 characters use this field differently:

Therefore, I decompiled it as 4 separate structures once again, bundled into an union of arrays.

As for Reimu… yup, that's some pointer arithmetic straight out of Jigoku* for setting and updating the positions of the falling star trails. :zunpet: While that certainly required several comments to wrap my head around the current array positions, the one "bug" in all this arithmetic luckily has no effect on the game.
There is a small glitch with the growing circles, though. They are spawned at the end of the loop, with their position taken from the star pointer… but after that pointer has already been incremented. On the last loop iteration, this leads to an out-of-bounds structure access, with the position taken from some unknown EX-Alice data, which is 0 during most of the game. If you look at the animation, you can easily spot these bugged circles, consistently growing from the top-left corner (0, 0) of the playfield:


After all that, there was barely enough remaining time to filter out and label the final few memory references. But now, TH05's MAIN.EXE is technically position-independent! 🎉 -Tom- is going to work on a pretty extensive demo of this unprecedented level of efficient Touhou game modding. For a more impactful effect of both the 100% PI mark and that demo, I'll be delaying the push covering the remaining false positives in that binary until that demo is done. I've accumulated a pretty huge backlog of minor maintenance issues by now…
Next up though: The first part of the long-awaited build system improvements. I've finally come up with a way of sanely accelerating the 32-bit build part on most setups you could possibly want to build ReC98 on, without making the building experience worse for the other few setups.

📝 Posted:
🚚 Summary of:
P0110
Commits:
2c7d86b...8b5c146
💰 Funded by:
[Anonymous], Blue Bolt
🏷 Tags:

… and just as I explained 📝 in the last post how decompilation is typically more sensible and efficient than ASM-level reverse-engineering, we have this push demonstrating a counter-example. The reason why the background particles and lines in the Shinki and EX-Alice battles contributed so much to position dependence was simply because they're accessed in a relatively large amount of functions, one for each different animation. Too many to spend the remaining precious crowdfunded time on reverse-engineering or even decompiling them all, especially now that everyone anticipates 100% PI for TH05's MAIN.EXE.

Therefore, I only decompiled the two functions of the line structure that also demonstrate best how it works, which in turn also helped with RE. Sadly, this revealed that we actually can't 📝 overload operator =() to get that nice assignment syntax for 12.4 fixed-point values, because one of those new functions relies on Turbo C++'s built-in optimizations for trivially copyable structures. Still, impressive that this abstraction caused no other issues for almost one year.

As for the structures themselves… nope, nothing to criticize this time! Sure, one good particle system would have been awesome, instead of having separate structures for the Stage 2 "starfield" particles and the one used in Shinki's battle, with hardcoded animations for both. But given the game's short development time, that was quite an acceptable compromise, I'd say.
And as for the lines, there just has to be a reason why the game reserves 20 lines per set, but only renders lines #0, #6, #12, and #18. We'll probably see once we get to look at those animation functions more closely.

This was quite a 📝 TH03-style RE push, which yielded way more PI% than RE%. But now that that's done, I can finally not get distracted by all that stuff when looking at the list of remaining memory references. Next up: The last few missing structures in TH05's MAIN.EXE!

📝 Posted:
🚚 Summary of:
P0109
Commits:
dcf4e2c...2c7d86b
💰 Funded by:
[Anonymous], Blue Bolt
🏷 Tags:

Back to TH05! Thanks to the good funding situation, I can strike a nice balance between getting TH05 position-independent as quickly as possible, and properly reverse-engineering some missing important parts of the game. Once 100% PI will get the attention of modders, the code will then be in better shape, and a bit more usable than if I just rushed that goal.

By now, I'm apparently also pretty spoiled by TH01's immediate decompilability, after having worked on that game for so long. Reverse-engineering in ASM land is pretty annoying, after all, since it basically boils down to meticulously editing a piece of ASM into something I can confidently call "reverse-engineered". Most of the time, simply decompiling that piece of code would take just a little bit longer, but be massively more useful. So, I immediately tried decompiling with TH05… and it just worked, at every place I tried!? Whatever the issue was that made 📝 segment splitting so annoying at my first attempt, I seem to have completely solved it in the meantime. 🤷 So yeah, backers can now request pretty much any part of TH04 and TH05 to be decompiled immediately, with no additional segment splitting cost.

(Protip for everyone interested in starting their own ReC project: Just declare one segment per function, right from the start, then group them together to restore the original code segmentation…)


Except that TH05 then just throws more of its infamous micro-optimized and undecompilable ASM at you. 🙄 This push covered the function that adjusts the bullet group template based on rank and the selected difficulty, called every time such a group is configured. Which, just like pretty much all of TH05's bullet spawning code, is one of those undecompilable functions. If C allowed labels of other functions as goto targets, it might have been decompilable into something useful to modders… maybe. But like this, there's no point in even trying.

This is such a terrible idea from a software architecture point of view, I can't even. Because now, you suddenly have to mirror your C++ declarations in ASM land, and keep them in sync with each other. I'm always happy when I get to delete an ASM declaration from the codebase once I've decompiled all the instances where it was referenced. But for TH05, we now have to keep those declarations around forever. 😕 And all that for a performance increase you probably couldn't even measure. Oh well, pulling off Galaxy Brain-level ASM optimizations is kind of fun if you don't have portability plans… I guess?

If I started a full fangame mod of a PC-98 Touhou game, I'd base it on TH04 rather than TH05, and backport selected features from TH05 as needed. Just because it was released later doesn't make it better, and this is by far not the only one of ZUN's micro-optimizations that just went way too far.

Dropping down to ASM also makes it easier to introduce weird quirks. Decompiled, one of TH05's tuning conditions for stack groups on Easy Mode would look something like:

case BP_STACK:
	// […]
	if(spread_angle_delta >= 2) {
		stack_bullet_count--;
	}

The fields of the bullet group template aren't typically reset when setting up a new group. So, spread_angle_delta in the context of a stack group effectively refers to "the delta angle of the last spread group that was fired before this stack – whenever that was". uth05win also spotted this quirk, considered it a bug, and wrote fanfiction by changing spread_angle_delta to stack_bullet_count.
As usual for functions that occur in more than one game, I also decompiled the TH04 bullet group tuning function, and it's perfectly sane, with no such quirks.


In the more PI-focused parts of this push, we got the TH05-exclusive smooth boss movement functions, for flying randomly or towards a given point. Pretty unspectacular for the most part, but we've got yet another uth05win inconsistency in the latter one. Once the Y coordinate gets close enough to the target point, it actually speeds up twice as much as the X coordinate would, whereas uth05win used the same speedup factors for both. This might make uth05win a couple of frames slower in all boss fights from Stage 3 on. Hard to measure though – and boss movement partly depends on RNG anyway.


Next up: Shinki's background animations – which are actually the single biggest source of position dependence left in TH05.

📝 Posted:
🚚 Summary of:
P0088, P0089
Commits:
97ce7b7...da6b856, da6b856...90252cc
💰 Funded by:
-Tom-, [Anonymous], Blue Bolt
🏷 Tags:

As expected, we've now got the TH04 and TH05 stage enemy structure, finishing position independence for all big entity types. This one was quite straightfoward, as the .STD scripting system is pretty simple.

Its most interesting aspect can be found in the way timing is handled. In Windows Touhou, all .ECL script instructions come with a frame field that defines when they are executed. In TH04's and TH05's .STD scripts, on the other hand, it's up to each individual instruction to add a frame time parameter, anywhere in its parameter list. This frame time defines for how long this instruction should be repeatedly executed, before it manually advances the instruction pointer to the next one. From what I've seen so far, these instruction typically apply their effect on the first frame they run on, and then do nothing for the remaining frames.
Oh, and you can't nest the LOOP instruction, since the enemy structure only stores one single counter for the current loop iteration.

Just from the structure, the only innovation introduced by TH05 seems to have been enemy subtypes. These can be used to parametrize scripts via conditional jumps based on this value, as a first attempt at cutting down the need to duplicate entire scripts for similar enemy behavior. And thanks to TH05's favorable segment layout, this game's version of the .STD enemy script interpreter is even immediately ready for decompilation, in one single future push.

As far as I can tell, that now only leaves

until TH05's MAIN.EXE is completely position-independent.
Which, however, won't be all it needs for that 100% PI rating on the front page. And with that many false positives, it's quite easy to get lost with immediately reverse-engineering everything around them. This time, the rendering of the text dissolve circles, used for the stage and BGM title popups, caught my eye… and since the high-level code to handle all of that was near the end of a segment in both TH04 and TH05, I just decided to immediately decompile it all. Like, how hard could it possibly be? Sure, it needed another segment split, which was a bit harder due to all the existing ASM referencing code in that segment, but certainly not impossible…

Oh wait, this code depends on 9 other sets of identifiers that haven't been declared in C land before, some of which require vast reorganizations to bring them up to current consistency standards. Whoops! Good thing that this is the part of the project I'm still offering for free…
Among the referenced functions was tiles_invalidate_around(), which marks the stage background tiles within a rectangular area to be redrawn this frame. And this one must have had the hardest function signature to figure out in all of PC-98 Touhou, because it actually seems impossible. Looking at all the ways the game passes the center coordinate to this function, we have

  1. X and Y as 16-bit integer literals, merged into a single PUSH of a 32-bit immediate
  2. X and Y calculated and pushed independently from each other
  3. by-value copies of entire Point instances

Any single declaration would only lead to at most two of the three cases generating the original instructions. No way around separately declaring the function in every translation unit then, with the correct parameter list for the respective calls. That's how ZUN must have also written it.

Oh well, we would have needed to do all of this some time. At least there were quite a bit of insights to be gained from the actual decompilation, where using const references actually made it possible to turn quite a number of potentially ugly macros into wholesome inline functions.

But still, TH04 and TH05 will come out of ReC98's decompilation as one big mess. A lot of further manual decompilation and refactoring, beyond the limits of the original binary, would be needed to make these games portable to any non-PC-98, non-x86 architecture.
And yes, that includes IBM-compatible DOS – which, for some reason, a number of people see as the obvious choice for a first system to port PC-98 Touhou to. This will barely be easier. Sure, you'll save the effort of decompiling all the remaining original ASM. But even with master.lib's MASTER_DOSV setting, these games still very much rely on PC-98 hardware, with corresponding assumptions all over ZUN's code. You will need to provide abstractions for the PC-98's superimposed text mode, the gaiji, and planar 4-bit color access in general, exchanging the use of the PC-98's GRCG and EGC blitter chips with something else. At that point, you might as well port the game to one generic 640×400 framebuffer and away from the constraints of DOS, resulting in that Doom source code-like situation which made that game easily portable to every architecture to begin with. But ZUN just wasn't a John Carmack, sorry.

Or what do I know. I've never programmed for IBM-compatible DOS, but maybe ReC98's audience does include someone who is intimately familiar with IBM-compatible DOS so that the constraints aren't much of an issue for them? But even then, 16-bit Windows would make much more sense as a first porting target if you don't want to bother with that undecompilable ASM.

At least I won't have to look at TH04 and TH05 for quite a while now. :tannedcirno: The delivery delays have made it obvious that my life has become pretty busy again, probably until September. With a total of 9 TH01 pushes from monthly subscriptions now waiting in the backlog, the shop will stay closed until I've caught up with most of these. Which I'm quite hyped for!

📝 Posted:
🚚 Summary of:
P0086, P0087
Commits:
54ee99b...24b96cd, 24b96cd...97ce7b7
💰 Funded by:
[Anonymous], Blue Bolt, -Tom-
🏷 Tags:

Alright, the score popup numbers shown when collecting items or defeating (mid)bosses. The second-to-last remaining big entity type in TH05… with quite some PI false positives in the memory range occupied by its data. Good thing I still got some outstanding generic RE pushes that haven't been claimed for anything more specific in over a month! These conveniently allowed me to RE most of these functions right away, the right way.

Most of the false positives were boss HP values, passed to a "boss phase end" function which sets the HP value at which the next phase should end. Stage 6 Yuuka, Mugetsu, and EX-Alice have their own copies of this function, in which they also reset certain boss-specific global variables. Since I always like to cover all varieties of such duplicated functions at once, it made sense to reverse-engineer all the involved variables while I was at it… and that's why this was exactly the right time to cover the implementation details of Stage 6 Yuuka's parasol and vanishing animations in TH04. :zunpet:

With still a bit of time left in that RE push afterwards, I could also start looking into some of the smaller functions that didn't quite fit into other pushes. The most notable one there was a simple function that aims from any point to the current player position. Which actually only became a separate function in TH05, probably since it's called 27 times in total. That's 27 places no longer being blocked from further RE progress.

WindowsTiger already did most of the work for the score popup numbers in January, which meant that I only had to review it and bring it up to ReC98's current coding styles and standards. This one turned out to be one of those rare features whose TH05 implementation is significantly less insane than the TH04 one. Both games lazily redraw only the tiles of the stage background that were drawn over in the previous frame, and try their best to minimize the amount of tiles to be redrawn in this way. For these popup numbers, this involves calculating the on-screen width, based on the exact number of digits in the point value. TH04 calculates this width every frame during the rendering function, and even resorts to setting that field through the digit iteration pointer via self-modifying code… yup. TH05, on the other hand, simply calculates the width once when spawning a new popup number, during the conversion of the point value to binary-coded decimal. The "×2" multiplier suffix being removed in TH05 certainly also helped in simplifying that feature in this game.

And that's ⅓ of TH05 reverse-engineered! Next up, one more TH05 PI push, in which the stage enemies hopefully finish all the big entity types. Maybe it will also be accompanied by another RE push? In any case, that will be the last piece of TH05 progress for quite some time. The next TH01 stretch will consist of 6 pushes at the very least, and I currently have no idea of how much time I can spend on ReC98 a month from now…

📝 Posted:
🚚 Summary of:
P0085
Commits:
110d6dd...54ee99b
💰 Funded by:
-Tom-
🏷 Tags:

Wait, PI for FUUIN.EXE is mainly blocked by the high score menu? That one should really be properly decompiled in a separate RE push, since it's also present in largely identical form in REIIDEN.EXE… but I currently lack the explicit funding to do that.

And as it turns out, I shouldn't really capture any of the existing generic RE contributions for it either. Back in 2018 when I ran the crowdfunding on the Touhou Patch Center Discord server, I said that generic RE contributions would never go towards TH01. No one was interested in that game back then, and as it's significantly different from all the other games, it made sense to only cover it if explicitly requested.
As Touhou Patch Center still remains one of the biggest supporters and advertisers for ReC98, someone recently believed that this rule was still in effect, despite not being mentioned anywhere on this website.

Fast forward to today, and TH01 has become the single most supported game lately, with plenty of incomplete pushes still open to be completed. Reverse-engineering it has proven to be quite efficient, yielding lots of completion percentage points per push. This, I suppose, is exactly what backers that don't give any specific priorities are mainly interested in. Therefore, I will allocate future partial contributions to TH01, whenever it makes sense.

So, instead of rushing TH01 PI, let's wait for Ember2528's April subscription, and get the 25% total RE milestone with some TH05 PI progress instead. This one primarily focused on the gather circles (spirals…?), the third-last missing entity type in TH05. These are rendered using the same 8×8 pellet sprite introduced in TH02… except that the actual pellets received a darkened bottom part in TH04 . Which, in turn, is actually rendered quite efficiently – the games first render the top white part of all pellets, followed by the bottom gray part of all pellets. The PC-98 GRCG is used throughout the process, doing its typical job of accelerating monochrome blitting, and by arranging the rendering like this, only two GRCG color changes are required to draw any number of pellets. I guess that makes it quite a worthwhile optimization? Don't ask me for specific performance numbers or even saved cycles, though :onricdennat:

Next up, one more TH05 PI push!

📝 Posted:
🚚 Summary of:
P0078, P0079
Commits:
f4eb7a8...9e52cb1, 9e52cb1...cd48aa3
💰 Funded by:
iruleatgames, -Tom-
🏷 Tags:

To finish this TH05 stretch, we've got a feature that's exclusive to TH05 for once! As the final memory management innovation in PC-98 Touhou, TH05 provides a single static (64 * 26)-byte array for storing up to 64 entities of a custom type, specific to a stage or boss portion. (Edit (2023-05-29): This system actually debuted in 📝 TH04, where it was used for much simpler entities.)

TH05 uses this array for

  1. the Stage 2 star particles,
  2. Alice's puppets,
  3. the tip of curve ("jello") bullets,
  4. Mai's snowballs and Yuki's fireballs,
  5. Yumeko's swords,
  6. and Shinki's 32×32 bullets,

which makes sense, given that only one of those will be active at any given time.

On the surface, they all appear to share the same 26-byte structure, with consistently sized fields, merely using its 5 generic fields for different purposes. Looking closer though, there actually are differences in the signedness of certain fields across the six types. uth05win chose to declare them as entirely separate structures, and given all the semantic differences (pixels vs. subpixels, regular vs. tiny master.lib sprites, …), it made sense to do the same in ReC98. It quickly turned out to be the only solution to meet my own standards of code readability.

Which blew this one up to two pushes once again… But now, modders can trivially resize any of those structures without affecting the other types within the original (64 * 26)-byte boundary, even without full position independence. While you'd still have to reduce the type-specific number of distinct entities if you made any structure larger, you could also have more entities with fewer structure members.

As for the types themselves, they're full of redundancy once again – as you might have already expected from seeing #4, #5, and #6 listed as unrelated to each other. Those could have indeed been merged into a single 32×32 bullet type, supporting all the unique properties of #4 (destructible, with optional revenge bullets), #5 (optional number of twirl animation frames before they begin to move) and #6 (delay clouds). The *_add(), *_update(), and *_render() functions of #5 and #6 could even already be completely reverse-engineered from just applying the structure onto the ASM, with the ones of #3 and #4 only needing one more RE push.

But perhaps the most interesting discovery here is in the curve bullets: TH05 only renders every second one of the 17 nodes in a curve bullet, yet hit-tests every single one of them. In practice, this is an acceptable optimization though – you only start to notice jagged edges and gaps between the fragments once their speed exceeds roughly 11 pixels per second:

And that brings us to the last 20% of TH05 position independence! But first, we'll have more cheap and fast TH01 progress.

📝 Posted:
🚚 Summary of:
P0076, P0077
Commits:
222fc99...9ae9754, 9ae9754...f4eb7a8
💰 Funded by:
[Anonymous], -Tom-, Splashman
🏷 Tags:

Well, that took twice as long as I thought, with the two pushes containing a lot more maintenance than actual new research. Spending some time improving both field names and types in 32th System's TH03 resident structure finally gives us all of those structures. Which means that we can now cover all the remaining decompilable ZUN.COM parts at once…

Oh wait, their main() functions have stayed largely identical since TH02? Time to clean up and separate that first, then… and combine two recent code generation observations into the solution to a decompilation puzzle from 4½ years ago. Alright, time to decomp-

Oh wait, we'd kinda like to properly RE all the code in TH03-TH05 that deals with loading and saving .CFG files. Almost every outside contributor wanted to grab this supposedly low-hanging fruit a lot earlier, but (of course) always just for a single game, while missing how the format evolved.

So, ZUN.COM. For some reason, people seem to consider it particularly important, even though it contains neither any game logic nor any code specific to PC-98 hardware… All that this decompilable part does is to initialize a game's .CFG file, allocate an empty resident structure using master.lib functions, release it after you quit the game, error-check all that, and print some playful messages~ (OK, TH05's also directly fills the resident structure with all data from MIKO.CFG, which all the other games do in OP.EXE.) At least modders can now freely change and extend all the resident structures, as well as the .CFG files? And translators can translate those messages that you won't see on a decently fast emulator anyway? Have fun, I guess 🤷‍

And you can in fact do this right now – even for TH04 and TH05, whose ZUN.COM currently isn't rebuilt by ReC98. There is actually a rather involved reason for this:

So yeah, no meaningful RE and PI progress at any of these levels. Heck, even as a modder, you can just replace the zun zun_res (TH02), zun -5 (TH03), or zun -s (TH04/TH05) calls in GAME.BAT with a direct call to your modified *RES*.COM. And with the alternative being "manually typing 0 and 1 bits into a text file", editing the sprites in TH05's GJINIT.COM is way more comfortable in a binary sprite editor anyway.

For me though, the best part in all of this was that it finally made sense to throw out the old Borland C++ run-time assembly slices 🗑 This giant waste of time became obvious 5 years ago, but any ASM dump of a .COM file would have needed rather ugly workarounds without those slices. Now that all .COM binaries that were originally written in C are compiled from C, we can all enjoy slightly faster grepping over the entire repository, which now has 229 fewer files. Productivity will skyrocket! :tannedcirno:

Next up: Three weeks of almost full-time ReC98 work! Two more PI-focused pushes to finish this TH05 stretch first, before switching priorities to TH01 again.

📝 Posted:
🚚 Summary of:
P0072, P0073, P0074, P0075
Commits:
4bb04ab...cea3ea6, cea3ea6...5286417, 5286417...1807906, 1807906...222fc99
💰 Funded by:
[Anonymous], -Tom-, Myles
🏷 Tags:

Long time no see! And this is exactly why I've been procrastinating bullets while there was still meaningful progress to be had in other parts of TH04 and TH05: There was bound to be quite some complexity in this most central piece of game logic, and so I couldn't possibly get to a satisfying understanding in just one push.

Or in two, because their rendering involves another bunch of micro-optimized functions adapted from master.lib.

Or in three, because we'd like to actually name all the bullet sprites, since there are a number of sprite ID-related conditional branches. And so, I was refining things I supposedly RE'd in the the commits from the first push until the very end of the fourth.

When we talk about "bullets" in TH04 and TH05, we mean just two things: the white 8×8 pellets, with a cap of 240 in TH04 and 180 in TH05, and any 16×16 sprites from MIKO16.BFT, with a cap of 200 in TH04 and 220 in TH05. These are by far the most common types of… err, "things the player can collide with", and so ZUN provides a whole bunch of pre-made motion, animation, and n-way spread / ring / stack group options for those, which can be selected by simply setting a few fields in the bullet template. All the other "non-bullets" have to be fired and controlled individually.

Which is nothing new, since uth05win covered this part pretty accurately – I don't think anyone could just make up these structure member overloads. The interesting insights here all come from applying this research to TH04, and figuring out its differences compared to TH05. The most notable one there is in the default groups: TH05 allows you to add a stack to any single bullet, n-way spread or ring, but TH04 only lets you create stacks separately from n-way spreads and rings, and thus gets by with fewer fields in its bullet template structure. On the other hand, TH04 has a separate "n-way spread with random angles, yet still aimed at the player" group? Which seems to be unused, at least as far as midbosses and bosses are concerned; can't say anything about stage enemies yet.

In fact, TH05's larger bullet template structure illustrates that these distinct group types actually are a rather redundant piece of over-engineering. You can perfectly indicate any permutation of the basic groups through just the stack bullet count (1 = no stack), spread bullet count (1 = no spread), and spread delta angle (0 = ring instead of spread). Add a 4-flag bitfield to cover the rest (aim to player, randomize angle, randomize speed, force single bullet regardless of difficulty or rank), and the result would be less redundant and even slightly more capable.

Even those 4 pushes didn't quite finish all of the bullet-related types, stopping just shy of the most trivial and consistent enum that defines special movement. This also left us in a 📝 TH03-like situation, in which we're still a bit away from actually converting all this research into actual RE%. Oh well, at least this got us way past 50% in overall position independence. On to the second half! 🎉

For the next push though, we'll first have a quick detour to the remaining C code of all the ZUN.COM binaries. Now that the 📝 TH04 and TH05 resident structures no longer block those, -Tom- has requested TH05's RES_KSO.COM to be covered in one of his outstanding pushes. And since 32th System recently RE'd TH03's resident structure, it makes sense to also review and merge that, before decompiling all three remaining RES_*.COM binaries in hopefully a single push. It might even get done faster than that, in which case I'll then review and merge some more of WindowsTiger's research.

📝 Posted:
🚚 Summary of:
P0065
Commits:
9faa29a...042b780
💰 Funded by:
Touhou Patch Center
🏷 Tags:

A~nd resident structures ended up being exactly the right thing to start off the new year with. WindowsTiger and spaztron64 have already been pushing for them with their own reverse-engineering, and together with my own recent GENSOU.SCR RE work, we've clarified just enough context around the harder-to-explain values to make both TH04's and TH05's structures fit nicely into the typical time frame of a single push.

With all the apparently obvious and seemingly just duplicated values, it has always been easy to do a superficial job for most of the structure, then lose motivation for the last few unknown fields. Pretty glad to got this finally covered; I've heard that people are going to write trainer tools now?

Also, where better to slot in a push that, in terms of figures, seems to deliver 0% RE and only miniscule PI progress, than at the end of Touhou Patch Center's 5-push order that already had multiple pushes yielding above-average progress? :onricdennat: As usual, we'll be reaping the rewards of this work in the next few TH04/TH05 pushes…

…whenever they get funded, that is, as for January, the backers have shifted the priorities towards TH01 and TH03. TH01 especially is something I'm quite excited about, as we're finally going to see just how fast this bloated game is really going to progress. Are you excited?

📝 Posted:
🚚 Summary of:
P0064
Commits:
80cec5b...9faa29a
💰 Funded by:
Touhou Patch Center
🏷 Tags:

🎉 TH04's and TH05's OP.EXE are now fully position-independent! 🎉

What does this mean?

You can now add any data or code to the main menus of the two games, by simply editing the ReC98 source, writing your mod in ASM or C/C++, and recompiling the code. Since all absolute memory addresses have now been converted to labels, this will work without causing any instability. See the position independence section in the FAQ for a more thorough explanation about why this was a problem.

What does this not mean?

The original ZUN code hasn't been completely reverse-engineered yet, let alone decompiled. Pretty much all of that is still ASM, which might make modding a bit inconvenient right now.

Since this push was otherwise pretty unremarkable, I made a video demonstrating a few basic things you can do with this:

Now, what to do for the last outstanding Touhou Patch Center push? Bullets, or resident structures? :thonk:

📝 Posted:
🚚 Summary of:
P0063
Commits:
034ae4b...8dbb450
💰 Funded by:
-Tom-
🏷 Tags:

Almost!

Just like most of the time, it was more sensible to cover GENSOU.SCR, the last structure missing in TH05's OP.EXE, everywhere it's used, rather than just rushing out OP.EXE position independence. I did have to look into all of the functions to fully RE it after all, and to find out whether the unused fields actually are unused. The only thing that kept this push from yielding even more above-average progress was the sheer inconsistency in how the games implemented the operations on this PC-98 equivalent of score*.dat:

Technically though, TH05's OP.EXE is position-independent now, and the rest are (should be? :tannedcirno:) merely false positives. However, TH04's is still missing another structure, in addition to its false positives. So, let's wait with the big announcement until the next push… which will also come with a demo video of what will be possible then.

📝 Posted:
🚚 Summary of:
P0062
Commits:
1d6fbb8...f275e04
💰 Funded by:
Touhou Patch Center
🏷 Tags:

Big gains, as expected, but not much to say about this one. With TH05 Reimu being way too easy to decompile after 📝 the shot control groundwork done in October, there was enough time to give the comprehensive PI false-positive treatment to two other sets of functions present in TH04's and TH05's OP.EXE. One of them, master.lib's super_*() functions, was used a lot in TH02, more than in any other game… I wonder how much more that game will progress without even focusing on it in particular.

Alright then! 100% PI for TH04's and TH05's OP.EXE upcoming… (Edit: Already got funding to cover this!)

📝 Posted:
🚚 Summary of:
P0060
Commits:
29385dd...73f5ae7
💰 Funded by:
Touhou Patch Center
🏷 Tags:

So, where to start? Well, TH04 bullets are hard, so let's procrastinate start with TH03 instead :tannedcirno: The 📝 sprite display functions are the obvious blocker for any structure describing a sprite, and therefore most meaningful PI gains in that game… and I actually did manage to fit a decompilation of those three functions into exactly the amount of time that the Touhou Patch Center community votes alloted to TH03 reverse-engineering!

And a pretty amazing one at that. The original code was so obviously written in ASM and was just barely decompilable by exclusively using register pseudovariables and a bit of goto, but I was able to abstract most of that away, not least thanks to a few helpful optimization properties of Turbo C++… seriously, I can't stop marveling at this ancient compiler. The end result is both readable, clear, and dare I say portable?! To anyone interested in porting TH03, take a look. How painful would it be to port that away from 16-bit x86?

However, this push is also a typical example that the RE/PI priorities can only control what I look at, and the outcome can actually differ greatly. Even though the priorities were 65% RE and 35% PI, the progress outcome was +0.13% RE and +1.35% PI. But hey, we've got one more push with a focus on TH03 PI, so maybe that one will include more RE than PI, and then everything will end up just as ordered? :onricdennat:

📝 Posted:
🚚 Summary of:
P0059
Commits:
01de290...8b62780
💰 Funded by:
[Anonymous], -Tom-
🏷 Tags:

With no feedback to 📝 last week's blog post, I assume you all are fine with how things are going? Alright then, another one towards position independence, with the same approach as before…

Since -Tom- wanted to learn something about how the PC-98 EGC is used in TH04 and TH05, I took a look at master.lib's egc_shift_*() functions. These simply do a hardware-accelerated memmove() of any VRAM region, and are used for screen shaking effects. Hover over the image below for the raw effect:

Demonstration of an egc_shift_left() call

Then, I finally wanted to take a look at the bullet structures, but it required way too much reverse-engineering to even start within ¾ of a position independence push. Even with the help of uth05win – bullet handling was changed quite a bit from TH04 to TH05.

What I ultimately settled on was more raw, "boring" PI work based around an already known set of functions. For this one, I looked at vector construction… and this time, that actually made the games a little bit more position-independent, and wasn't just all about removing false positives from the calculation. This was one of the few sets of functions that would also apply to TH01, and it revealed just how chaotically that game was coded. This one commit shows three ways how ZUN stored regular 2D points in TH01:

… yeah. But in more productive news, this did actually lay the groundwork for TH04 and TH05 bullet structures. Which might even be coming up within the next big, 5-push order from Touhou Patch Center? These are the priorities I got from them, let's see how close I can get!

📝 Posted:
🚚 Summary of:
P0057, P0058
Commits:
1cb9731...ac7540d, ac7540d...fef0299
💰 Funded by:
[Anonymous], -Tom-
🏷 Tags:

So, here we have the first two pushes with an explicit focus on position independence… and they start out looking barely different from regular reverse-engineering? They even already deduplicate a bunch of item-related code, which was simple enough that it required little additional work? Because the actual work, once again, was in comparing uth05win's interpretations and naming choices with the original PC-98 code? So that we only ended up removing a handful of memory references there?

(Oh well, you can mod item drops now!)

So, continuing to interpret PI as a mere by-product of reverse-engineering might ultimately drive up the total PI cost quite a bit. But alright then, let's systematically clear out some false positives by looking at master.lib function calls instead… and suddenly we get the PI progress we were looking for, nicely spread out over all games since TH02. That kinda makes it sound like useless work, only done because it's dictated by some counting algorithm on a website. But decompilation will want to convert all of these values to decimal anyway. We're merely doing that right now, across all games.

Then again, it doesn't actually make any game more position-independent, and only proves how position-independent it already was. So I'm really wondering right now whether I should just rush actual position independence by simply identifying structures and their sizes, and not bother with members or false positives until that's done. That would certainly get the job done for TH04 and TH05 in just a few more pushes, but then leave all the proving work (and the road to 100% PI on the front page) to reverse-engineering.

I don't know. Would it be worth it to have a game that's "maybe fully position-independent", only for there to maybe be rare edge cases where it isn't?

Or maybe, continuing to strike a balance between identifying false positives (fast) and reverse-engineering structures (slow) will continue to work out like it did now, and make us end up close to the current estimate, which was attractive enough to sell out the crowdfunding for the first time… 🤔

Please give feedback! If possible, by Friday evening UTC+1, before I start working on the next PI push, this time with a focus on TH04.

📝 Posted:
🚚 Summary of:
P0036, P0037
Commits:
a533b5d...82b0e1d, 82b0e1d...e7e1cbc
💰 Funded by:
zorg
🏷 Tags:

And just in time for zorg's last outstanding pushes, the TH05 shot type control functions made the speedup happen!

It would have been really nice to also include Reimu's shot control functions in this last push, but figuring out this entire system, with its weird bitflags and switch statement micro-optimizations, was once again taking way longer than it should have. Especially with my new-found insistence on turning this obvious copy-pasta into something somewhat readable and terse…

But with such a rather tabular visual structure, things should now be moddable in hopefully easily consistent way. Of course, since we're only at 54% position independence for MAIN.EXE, this isn't possible yet without crashing the game, but modifying damage would already work.

Despite my earlier claims of ZUN only having used C++ in TH01, as it's the only game using new and delete, it's now pretty much confirmed that ZUN used it for all games, as inlined functions (and by extension, C++ class methods) are the only way to get certain instructions out of the Turbo C++ code generator. Also, I've kept my promise and started really filling that decompilation pattern file.

And now, with the reverse-engineering backlog finally being cleared out, we wait for the next orders, and the direction they might focus on…

📝 Posted:
🚚 Summary of:
P0034, P0035
Commits:
6cdd229...6f1f367, 6f1f367...a533b5d
💰 Funded by:
zorg
🏷 Tags:

Deathbombs confirmed, in both TH04 and TH05! On the surface, it's the same 8-frame window as in most Windows games, but due to the slightly lower PC-98 frame rate of 56.4 Hz, it's actually slightly more lenient in TH04 and TH05.

The last function in front of the TH05 shot type control functions marks the player's previous position in VRAM to be redrawn. But as it turns out, "player" not only means "the player's option satellites on shot levels ≥ 2", but also "the explosion animation if you lose a life", which required reverse-engineering both things, ultimately leading to the confirmation of deathbombs.

It actually was kind of surprising that we then had reverse-engineered everything related to rendering all three things mentioned above, and could also cover the player rendering function right now. Luckily, TH05 didn't decide to also micro-optimize that function into un-decompilability; in fact, it wasn't changed at all from TH04. Unlike the one invalidation function whose decompilation would have actually been the goal here…

But now, we've finally gotten to where we wanted to… and only got 2 outstanding decompilation pushes left. Time to get the website ready for hosting an actual crowdfunding campaign, I'd say – It'll make a better impression if people can still see things being delivered after the big announcement.

📝 Posted:
🚚 Summary of:
P0031, P0032, P0033
Commits:
dea40ad...9f764fa, 9f764fa...e6294c2, e6294c2...6cdd229
💰 Funded by:
zorg
🏷 Tags:

The glacial pace continues, with TH05's unnecessarily, inappropriately micro-optimized, and hence, un-decompilable code for rendering the current and high score, as well as the enemy health / dream / power bars. While the latter might still pass as well-written ASM, the former goes to such ridiculous levels that it ends up being technically buggy. If you enjoy quality ZUN code, it's definitely worth a read.

In TH05, this all still is at the end of code segment #1, but in TH04, the same code lies all over the same segment. And since I really wanted to move that code into its final form now, I finally did the research into decompiling from anywhere else in a segment.

Turns out we actually can! It's kinda annoying, though: After splitting the segment after the function we want to decompile, we then need to group the two new segments back together into one "virtual segment" matching the original one. But since all ASM in ReC98 heavily relies on being assembled in MASM mode, we then start to suffer from MASM's group addressing quirk. Which then forces us to manually prefix every single function call

with the group name. It's stupidly boring busywork, because of all the function calls you mustn't prefix. Special tooling might make this easier, but I don't have it, and I'm not getting crowdfunded for it.

So while you now definitely can request any specific thing in any of the 5 games to be decompiled right now, it will take slightly longer, and cost slightly more.
(Except for that one big segment in TH04, of course.)

Only one function away from the TH05 shot type control functions now!

📝 Posted:
🚚 Summary of:
P0029, P0030
Commits:
6ff427a...c7fc4ca, c7fc4ca...dea40ad
💰 Funded by:
zorg
🏷 Tags:

Here we go, new C code! …eh, it will still take a bit to really get decompilation going at the speeds I was hoping for. Especially with the sheer amount of stuff that is set in the first few significant functions we actually can decompile, which now all has to be correctly declared in the C world. Turns out I spent the last 2 years screwing up the case of exported functions, and even some of their names, so that it didn't actually reflect their calling convention… yup. That's just the stuff you tend to forget while it doesn't matter.

To make up for that, I decided to research whether we can make use of some C++ features to improve code readability after all. Previously, it seemed that TH01 was the only game that included any C++ code, whereas TH02 and later seemed to be 100% C and ASM. However, during the development of the soon to be released new build system, I noticed that even this old compiler from the mid-90's, infamous for prioritizing compile speeds over all but the most trivial optimizations, was capable of quite surprising levels of automatic inlining with class methods…

…leading the research to culminate in the mindblow that is 9d121c7 – yes, we can use C++ class methods and operator overloading to make the code more readable, while still generating the same code than if we had just used C and preprocessor macros.

Looks like there's now the potential for a few pull requests from outside devs that apply C++ features to improve the legibility of previously decompiled and terribly macro-ridden code. So, if anyone wants to help without spending money…

📝 Posted:
🚚 Summary of:
P0028
Commits:
6023f5c...6ff427a
💰 Funded by:
zorg
🏷 Tags:

Back to actual development! Starting off this stretch with something fairly mechanical, the few remaining generic boss and midboss state variables. And once we start converting the constant numbers used for and around those variables into decimal, the estimated position independence probability immediately jumped by 5.31% for TH04's MAIN.EXE, and 4.49% for TH05's – despite not having made the game any more position- independent than it was before. Yup… lots of false positives in there, but who can really know for sure without having put in the work.

But now, we've RE'd enough to finally decompile something again next, 4 years after the last decompilation of anything!

📝 Posted:
🚚 Summary of:
P0051, P0052, P0053
Commits:
6ed8e60...3ba536a
💰 Funded by:
-Tom-
🏷 Tags:

Boss explosions! And… urgh, I really also had to wade through that overly complicated HUD rendering code. Even though I had to pick -Tom-'s 7th push here as well, the worst of that is still to come. TH04 and TH05 exclusively store the current and high score internally as unpacked little-endian BCD, with some pretty dense ASM code involving the venerable x86 BCD instructions to update it.

So, what's actually the goal here. Since I was given no priorities :onricdennat:, I still haven't had to (potentially) waste time researching whether we really can decompile from anywhere else inside a segment other than backwards from the end. So, the most efficient place for decompilation right now still is the end of TH05's main_01_TEXT segment. With maybe 1 or 2 more reverse-engineering commits, we'd have everything for an efficient decompilation up to sub_123AD. And that mass of code just happens to include all the shot type control functions, and makes up 3,007 instructions in total, or 12% of the entire remaining unknown code in MAIN.EXE.

So, the most reasonable thing would be to actually put some of the upcoming decompilation pushes towards reverse-engineering that missing part. I don't think that's a bad deal since it will allow us to mod TH05 shot types in C sooner, but zorg and qp might disagree :thonk:

Next up: thcrap TL notes, followed by finally finishing GhostPhanom's old ReC98 future-proofing pushes. I really don't want to decompile without a proper build system.

📝 Posted:
🚚 Summary of:
P0049, P0050
Commits:
893bd46...6ed8e60
💰 Funded by:
-Tom-
🏷 Tags:

Sometimes, "strategically picking things to reverse-engineer" unfortunately also means "having to move seemingly random and utterly uninteresting stuff, which will only make sense later, out of the way". Really, this was so boring. Gonna get a lot more exciting in the next ones though.

📝 Posted:
🚚 Summary of:
P0047, P0048
Commits:
9a2c6f7...893bd46
💰 Funded by:
-Tom-
🏷 Tags:

So, let's continue with player shots! …eh, or maybe not directly, since they involve two other structure types in TH05, which we'd have to cover first. One of them is a different sort of sprite, and since I like me some context in my reverse-engineering, let's disable every other sprite type first to figure out what it is.

One of those other sprite types were the little sparks flying away from killed stage enemies, midbosses, and grazed bullets; easy enough to also RE right now. Turns out they use the same 8 hardcoded 8×8 sprites in TH02, TH04, and TH05. Except that it's actually 64 16×8 sprites, because ZUN wanted to pre-shift them for all 8 possible start pixels within a planar VRAM byte (rather than, like, just writing a few instructions to shift them programmatically), leading to them taking up 1,024 bytes rather than just 64.
Oh, and the thing I wanted to RE *actually* was the decay animation whenever a shot hits something. Not too complex either, especially since it's exclusive to TH05.

And since there was some time left and I actually have to pick some of the next RE places strategically to best prepare for the upcoming 17 decompilation pushes, here's two more function pointers for good measure.

📝 Posted:
🚚 Summary of:
P0046
Commits:
612beb8...deb45ea
💰 Funded by:
-Tom-
🏷 Tags:

Stumbled across one more drawing function in the way… which was only a duplicated and seemingly pointlessly micro-optimized copy of master.lib's super_roll_put_tiny() function, used for fast display of 4-color 16×16 sprites.

With this out of the way, we can tackle player shot sprite animation next. This will get rid of a lot of code, since every power level of every character's shot type is implemented in its own function. Which makes up thousands of instructions in both TH04 and TH05 that we can nicely decompile in the future without going through a dedicated reverse-engineering step.

📝 Posted:
🚚 Summary of:
P0043, P0044, P0045
Commits:
261d503...612beb8
💰 Funded by:
-Tom-
🏷 Tags:

Turns out I had only been about half done with the drawing routines. The rest was all related to redrawing the scrolling stage backgrounds after other sprites were drawn on top. Since the PC-98 does have hardware-accelerated scrolling, but no hardware-accelerated sprites, everything that draws animated sprites into a scrolling VRAM must then also make sure that the background tiles covered by the sprite are redrawn in the next frame, which required a bit of ZUN code. And that are the functions that have been in the way of the expected rapid reverse-engineering progress that uth05win was supposed to bring. So, looks like everything's going to go really fast now?

📝 Posted:
🚚 Summary of:
P0025, P0026, P0027
Commits:
0cde4b7...261d503
💰 Funded by:
zorg
🏷 Tags:

… yeah, no, we won't get very far without figuring out these drawing routines.
Which process data that comes from the .STD files. Which has various arrays related to the background… including one to specify the scrolling speed. And wait, setting that to 0 actually is what starts a boss battle?

So, have a TH05 Boss Rush patch: 2018-12-26-TH05BossRush.zip Theoretically, this should have also worked for TH04, but for some reason, the Stage 3 boss gets stuck on the first phase if we do this?

Here's the diff for the Boss Rush. Turning it into a thcrap-style Skipgame patch is left as an exercise for the reader.

📝 Posted:
🚚 Summary of:
P0023, P0024
Commits:
807df3d...0cde4b7
💰 Funded by:
zorg
🏷 Tags:

Actually, I lied, and lasers ended up coming with everything that makes reverse-engineering ZUN code so difficult: weirdly reused variables, unexpected structures within structures, and those TH05-specific nasty, premature ASM micro-optimizations that will waste a lot of time during decompilation, since the majority of the code actually was C, except for where it wasn't.

📝 Posted:
🚚 Summary of:
P0042
Commits:
f3b6137...807df3d
💰 Funded by:
-Tom-
🏷 Tags:

Laser… is not difficult. In fact, out of the remaining entity types I checked, it's the easiest one to fully grasp from uth05win alone, as it's only drawn using master.lib's line, circle, and polygon functions. Everything else ends up calling… something sprite-related that needs to be RE'd separately, and which uth05win doesn't help with, at all.

Oh, and since the speed of shoot-out lasers (as used by TH05's Stage 2 boss, for example) always depends on rank, we also got this variable now.

This only covers the structure itself – uth05win's member names for the LASER structure were not only a bit too unclear, but also plain wrong and misleading in one instance. The actual implementation will follow in the next one.

📝 Posted:
🚚 Summary of:
P0041
Commits:
b03bc91...f3b6137
💰 Funded by:
-Tom-
🏷 Tags:

So, after introducing instruction number statistics… let's go for over 2,000 lines that won't show up there immediately :tannedcirno: That being (mid-)boss HP, position, and sprite ID variables for TH04/TH05. Doesn't sound like much, but it kind of is if you insist on decimal numbers for easier comparison with uth05win's source code.

📝 Posted:
🚚 Summary of:
P0040
Commits:
d7483c0...b03bc91
💰 Funded by:
-Tom-
🏷 Tags:

Let's start this stretch with a pretty simple entity type, the growing and shrinking circles shown during bomb animations and around bosses in TH04 and TH05. Which can be drawn in varying colors… wait, what's all this inlined and duplicated GRCG mode and color setting code? Let's move that out into macros too, it takes up too much space when grepping for constants, and will raise a "wait, what was that I/O port doing again" question for most people reading the code again after a few months.

🎉 With this push, we've also hit a milestone! Less than 200,000 unknown x86 instructions remain until we've completely reverse-engineered all of PC-98 Touhou.

📝 Posted:
🚚 Summary of:
P0009
Commits:
79cc3ed...141baa4
💰 Funded by:
DTM
🏷 Tags:

While we're waiting for Bruno to release the next thcrap build with ANM header patching, here are the resulting commits of the ReC98 CDG/CD2 special offer purchased by DTM, reverse-engineering all code that covers these formats.

📝 Posted:
🚚 Summary of:
P0019, P0020, P0021, P0022
Commits:
c592464, cbe8a37, 8dfc2cd, 79cc3ed
💰 Funded by:
zorg
🏷 Tags:
> OK, let's do a quick ReC98 update before going back to thcrap, shouldn't take long > Hm, all that input code is kind of in the way, would be nice to cover that first to ease comparisons with uth05win's source code > What the hell, why does ZUN do this? Need to do more research > … > OK, research done, wait, what are those other functions doing? > Wha, everything about this is just ever so slightly awkward

Which ended up turning this one update into 2/10, 3/10, 4/10 and 5/10 of zorg's reverse-engineering commits. But at least we now got all shared input functions of TH02-TH05 covered and well understood.

📝 Posted:
🚚 Summary of:
P0018
Commits:
746681d...178d589
💰 Funded by:
zorg
🏷 Tags:

What do you do if the TH06 text image feature for thcrap should have been done 3 days™ ago, but keeps getting more and more complex, and you have a ton of other pushes to deliver anyway? Get some distraction with some light ReC98 reverse-engineering work. This is where it becomes very obvious how much uth05win helps us with all the games, not just TH05.

5a5c347 is the most important one in there, this was the missing substructure that now makes every other sprite-like structure trivial to figure out.

📝 Posted:
🚚 Summary of:
P0008
Commits:
47e5601...d62dd06
💰 Funded by:
-Tom-
🏷 Tags:

You could use this to get a homing Mima, for example.