That was quick: In a surprising turn of events, Romantique Tp themselves came in just one day after the last blog post went up, updated me with their current and much more positive opinion on Sound Canvas VA, and confirmed that real SC-88Pro hardware clamps invalid Reverb Macro values to the specified range. I promised to release a new Sound Canvas VA BGM pack for free once I knew the exact behavior of real hardware, so let's go right back to Seihou and also integrate the necessary SysEx patches into the game's MIDI player behind a toggle. This would also be a great occasion to quickly incorporate some long overdue code maintenance and build system improvements, and a migration to C++ modules in particular. When I started the Shuusou Gyoku Linux port a year ago, the combination of modules and <windows.h> threw lots of weird errors and even crashed the Visual Studio compiler. But nowadays, Microsoft even uses modules in the Office code base. This must mean that these issues are fixed by now, right?
Well, there's still a bug that causes the modularized C++ standard library to be basically unusable in combination with the static analyzer, and somehow, I was the first one to report it. So it's 3½ years after C++20 was finalized, and somehow, modules are still a bleeding-edge feature and a second-class citizen in even the compiler that supports them the best. I want fast compile times already! 😕
Thankfully, Microsoft agrees that this is a bug, and will work on it at some point. While we're waiting, let's return to the original plan of decompiling the endings of the one PC-98 Touhou game that still needed them decompiled.
After the textless slideshows of TH01, TH02 was the first Touhou game to feature lore text in its endings. Given that this game stores its 📝 in-game dialog text in fixed-size plaintext files, you wouldn't expect anything more fancy for the endings either, so it's not surprising to see that the END?.TXT files use the same concept, with 44 visible bytes per line followed by two bytes of padding for the CR/LF newline sequence. Each of these lines is typed to the screen in full, with all whitespace and a fixed time for each 2-byte chunk.
As a result, everything surrounding the text is just as hardcoded as TH01's endings were, which once again opens up the possibility of freely integrating all sorts of creative animations without the overhead of an interpreter. Sadly, TH02 only makes use of this freedom in a mere two cases: the picture scrolling effect from Reimu's head to Marisa's head in the Bad Endings, and a single hardware palette change in the Good Endings.
Powered by master.lib's egc_shift_down().
Same image, different palette. Note how the palette for 2️⃣ must still contain a green color for the VRAM-rendered bold text, which the image is not supposed to use.
Hardcoding also still made sense for this game because of how the ending text is structured. The Good and Bad Endings for the individual shot types respectively share 55% and 77% of their text, and both only diverge after the first 27 lines. In straight-line procedural code, this translates to one branch for each shot type at a single point, neatly matching the high-level structure of these endings.
But that's the end of the positive or neutral aspects I can find in these scripts. The worst part, by far, is ZUN's approach to displaying the text in alternating colors, and how it impacts the entire structure of the code.
The simplest solution would have involved a hardcoded array with the color of each line, just like how the in-game dialogs store the face IDs for each text box. But for whatever reason, ZUN did not apply this piece of wisdom to the endings and instead hardcoded these color changes by… mutating a global variable before calling the text typing function for every individual line. This approach ruins any possibility of compressing the script code into loops. While ZUN did use loops, all of them are very short because they can only last until the next color change. In the end, the code contains 90 explicitly spelled-out calls to the 5-parameter line typing function that only vary in the pointer to each line and in the slower speed used for the one or two final lines of each ending. As usual, I've deduplicated the code in the ReC98 repository down to a sensible level, but here's the full inlined and macro-expanded horror:
It's highly likely that this is what ZUN hacked into his PC-98 and was staring at back in 1997.
All this redundancy bloats the two script functions for the 6 endings to a whopping 3,344 bytes inside TH02's MAINE.EXE. In particular, the single function that covers the three Good Endings ends up with a total of 631 x86 ASM instructions, making it the single largest function in TH02 and the 7th longest function in all of PC-98 Touhou. If the 📝 single-executable build for TH02's debloated and anniversary branches ends up needing a few more KB to reduce its size below the original MAIN.EXE, there are lots of opportunities to compress it all.
The ending text can also be fast-forwarded by holding any key. As we've come to expect for this sort of ZUN code, the text typing function runs its own rendering loop with VSync delays and input detection, which means that we 📝 once📝 again have to talk about the infamous quirk of the PC-98 keyboard controller in relation to held keys. We've still got 54 not yet decompiled calls to input detection functions left in this codebase, are you excited yet?!
Holding any key speeds up the text of all ending lines before the last one by displaying two kana/kanji instead of one per rendered frame and reducing the delay between the rendered frames to 1/3 of its regular length. In pseudocode:
for(i = 0; i < number_of_2_byte_chunks_on_displayed_line; i++) {
input = convert_current_pc98_bios_input_state_to_game_specific_bitflags();
add_chunk_to_internal_text_buffer(i);
blit_internal_text_buffer_from_the_beginning();
if(input == INPUT_NONE) {
// Basic case, no key pressed
frame_delay(frames_per_chunk);
} else if((i % 2) == 1) {
// Key pressed, chunk number is odd.
frame_delay(frames_per_chunk / 3);
} else {
// Key pressed, chunk number is even.
// No delay; next iteration adds to the same frame.
}
}
This is exactly the kind of code you would write if you wanted to deliberately maximize the impact of this hardware quirk. If the game happens to read the current input state right after a key up scancode for the last previously held and game-relevant key, it will then wrongly take the branch that uninterruptibly waits for the regular, non-divided amount of VSync interrupts. In my tests, this broke the rhythm of the fast-forwarded text about once per line. Note how this branch can also be taken on an even chunk: Rendering glyphs straight from font ROM to VRAM is not exactly cheap, and if each iteration (needlessly) blits one more full-width glyph than the last one, the probability of a key up scancode arriving in the middle of a frame only increases.
The fact that TH02 allows any of the supported input keys to be held points to another detail of this quirk I haven't mentioned so far. If you press multiple keys at once, the PC-98's keyboard controller only sends the periodic key up scancodes as long as you are holding the last key you pressed. Because the controller only remembers this last key, pressing and releasing any other key would get rid of these scancodes for all keys you are still holding.
As usual, this ZUN bug only occurs on real hardware and with DOSBox-X's correct emulation of the PC-98 keyboard controller.
After the ending, we get to witness the most seamless transition between ending and Staff Roll in any Touhou game as the BGM immediately changes to the Staff Roll theme, and the ending picture is shifted into the same place where the Staff Roll pictures will appear. Except that the code misses the exact position by four pixels, and cuts off another four pixels at the right edge of the picture:
Also, note the green 1-pixel line at the right edge of this specific picture. This is a bug in the .PI file where the picture is indeed shifted one pixel to the left.
What follows is a comparatively large amount of unused content for a single scene. It starts right at the end of this underappreciated 11-frame animation loaded from ENDFT.BFT:
Wastefully using the 4bpp BFNT format. The single frame at the end of the animation is unused; while it might look identical to the ZUN glyphs later on in the Staff Roll, that's only because both are independently rendered boldfaced versions of the same font ROM glyphs. Then again, it does prove that ZUN created this animation on a PC-98 model made by NEC, as the Epson clones used a font ROM with a distinctly different look.
TH02's Staff Roll is also unique for the pre-made screenshots of all 5 stages that get shown together with a fancy rotating rectangle animation while the Staff Roll progresses in sync with the BGM. The first interesting detail shows up immediately after the first image, where the code jumps over one of the 320×200 quarters in ED06.PI, leaving the screenshot of the Stage 2 midboss unused.
All of the cutscenes in PC-98 Touhou store their pictures as 320×200 quarters within a single 640×400 .PI file. Anywhere else, all four quarters are supposed to be displayed with the same palette specified in the .PI header, but TH02's Staff Roll screenshots are also unique in how all quarters beyond the top-left one require palettes loaded from external .RGB files to look right. Consequently, the game doesn't clearly specify the intended palette of this unused screenshot, and leaves two possibilities:
The unused second 320×200 quarter of TH02's ED06.PI, displayed in the Stage 2 color palette used in-game.
The unused second 320×200 quarter of TH02's ED06.PI, displayed in the palette specified in the .PI header. These are the colors you'd see when looking at the file in a .PI viewer, when converting it into another format with the usual tools, or in sprite rips that don't take TH02's hardcoded palette changes into account. These colors are only intended for the Stage 1 screenshot in the top-left quarter of the file.
The unused second 320×200 quarter of TH02's ED06.PI, displayed in the palette from ED06B.RGB, which the game uses for the following screenshot of the Meira fight. As it's from the same stage, it almost matches the in-game colors seen in 1️⃣, and only differs in the white color (#FFF) being slightly red-tinted (#FCC).
It might seem obvious that the Stage 2 palette in 1️⃣ is the correct one, but ZUN indeed uses ED06B.RGB with the red-tinted white color for the following screenshot of the Meira fight. Not only does this palette not match Meira's in-game appearance, but it also discolors the rectangle animation and the surrounding Staff Roll text:
Also, that tearing on frame #1 is not a recording artifact, but the expected result of yet another VSync-related landmine. 💣 This time, it's caused by the combination of 1) the entire sequence from the ending to the verdict screen being single-buffered, and 2) this animation always running immediately after an expensive operation (640×400 .PI image loading and blitting to VRAM, 320×200 VRAM inter-page copy, or hardware palette loading from a packed file), without waiting for the VSync interrupt. This makes it highly likely for the first frame of this animation to start rendering at a point where the (real or emulated) electron beam has already traveled over a significant portion of the screen.
But when I went into Stage 2 to compare these colors to the in-game palette, I found something even more curious. ZUN obviously made this screenshot with the Reimu-C shot type, but one of the shot sprites looks slightly different from how it does in-game. These screenshots must have been made earlier in development when the sprite didn't yet feature the second ring at the top. The same applies to the Stage 4 screenshot later on:
Finally, the rotating rectangle animation delivers one more minor rendering bug. Each of the 20 frames removes the largest and outermost rectangle from VRAM by redrawing it in the same black color of the background before drawing the remaining rectangles on top. The corners of these rectangles are placed on a shrinking circle that starts with a radius of 256 pixels and is centered at (192, 200), which results in a maximum possible X coordinate of 448 for the rightmost corner of the rectangle. However, the Staff Roll text starts at an X coordinate of 416, causing the first two full-width glyphs to still fall within the area of the circle. Each line of text is also only rendered once before the animation. So if any of the rectangles then happens to be placed at an angle that causes its edges to overlap the text, its removal will cut small holes of black pixels into the glyphs:
The green dotted circle corresponds to the newest/smallest rectangle. Note how ZUN only happened to avoid the holes for the two final animations by choosing an initial angle and angular velocity that causes the resulting rectangles to just barely avoid touching the TEST PLAYER glyphs.
At least the following verdict screen manages to have no bugs aside from the slightly imperfect centering of its table values, and only comes with a small amount of additional bloat. Let's get right to the mapping from skill points to the 12 title strings from END3.TXT, because one of them is not like the others:
Skill
Title
≥100
神を超えた巫女!!
90 - 99
もはや神の領域!!
80 - 99
A級シューター!!
78 - 79
うきうきゲーマー!
77
バニラはーもにー!
70 - 76
うきうきゲーマー!
60 - 69
どきどきゲーマー!
50 - 59
要練習ゲーマー
40 - 49
非ゲーマー級
30 - 39
ちょっとだめ
20 - 29
非人間級
10 - 19
人間でない何か
≤9
死んでいいよ、いやいやまじで
Looks like I'm the first one to document the required skill points as well? Everyoneelse just copy-pastes END3.TXT without providing context.
So how would you get exactly 77 and achieve vanilla harmony? Here's the formula:
* Ranges from 0 (Easy) to 3 (Lunatic). † Across all 5 stages.
With Easy Mode capping out at 85, this is possible on every difficulty, although it requires increasingly perfect play the lower you go. Reaching 77 on purpose, however, pretty much demands a careful route through the entire game, as every collected and missed item will influence the item_skill in some way. This almost feels it's like the ultimate challenge that this game has to offer. Looking forward to the first Vanilla Harmony% run!
And with that, TH02's MAINE.EXE is both fully position-independent and ready for translation. There's a tiny bit of undecompiled bit of code left in the binary, but I'll leave that for rounding up a future TH02 decompilation push.
With one of the game's skill-based formulas decompiled, it's fitting to round out the second push with the other two. The in-game bonus tables at the end of a stage also have labels that we'd eventually like to translate, after all.
The bonus formula for the 4 regular stages is also the first place where we encounter TH02's rank value, as well as the only instance in PC-98 Touhou where the game actually displays a rank-derived value to the player. KirbyComment and Colin Douglas Howell accurately documented the rank mechanics over at Touhou Wiki two years ago, which helped quite a bit as rank would have been slightly out of scope for these two pushes. 📝 Similar to TH01, TH02's rank value only affects bullet speed, but the exact details of how rank is factored in will have to wait until RE progress arrives at this game's bullet system.
These bonuses are calculated by taking a sum of various gameplay metrics and multiplying it with the amount of point items collected during the stage. In the 4 regular stages, the sum consists of:
難易度
Difficulty level* × 2,000
ステージ
(Rank + 16) × 200
ボム
max((2,500 - (Bombs used* × 500)), 0)
ミス
max((3,000 - (Lives lost* × 1,000)), 0)
靈撃初期数
(4 - Starting bombs) × 800
靈夢初期数
(5 - Starting lives) × 1,000
* Within this stage, across all continues.
Yup, 封魔録.TXT does indeed document this correctly.
As rank can range from -6 to +4 on Easy and +16 on the other difficulties, this sum can range between:
Easy
Normal
Hard
Lunatic
Minimum
2,800
4,800
6,800
8,800
Maximum
16,700
21,100
23,100
25,100
The sum for the Extra Stage is not documented in 封魔録.TXT:
クリア
10,000
ミス回数
max((20,000 - (Lives lost × 4,000)), 0)
ボム回数
max((20,000 - (Bombs used × 4,000)), 0)
クリアタイム
⌊max((20,000 - Boss fight frames*), 0) ÷ 10⌋ × 10
* Amount of frames spent fighting Evil Eye Σ, counted from the end of the pre-boss dialog until the start of the defeat animation.
And that's two pushes packed full of the most bloated and copy-pasted code that's unique to TH02! So bloated, in fact, that TH02 RE as a whole jumped by almost 7%, which in turn finally pushed overall RE% over the 60% mark. 🎉 It's been a while since we hit a similar milestone; 50% overall RE happened almost 2 years ago during 📝 P0204, a month before I completed the TH01 decompilation.
Next up: Continuing to wait for Microsoft to fix the static analyzer bug until May at the latest, and working towards the newly popular dreams of TH03 netplay by looking at some of its foundational gameplay code.
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!
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:
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?
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:
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.
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:
Colors 0 or 1 can't be used, because those don't include any of the bits that can stay constant between frames.
If the lowest bit of a palette color index has no effect on the displayed color, text drawn in either of the two colors won't be visually affected by the polygon animation and will always appear on top. TH04 and TH05 rely on this property with their colors 2/3, 4/5, and 6/7 being identical, but this would work in TH02 and TH03 as well.
But this doesn't apply to TH02 and TH03's palettes, so how do they do it? The secret: They simply include all text pixels in nopoly_B. This allows text to use any color with an odd palette index – the lowest bit then won't be affected by the polygons ORed into the first bitplane, and the other bitplanes remain unchanged.
TH04 is a curious case. Ostensibly, it seems to remove support for odd text colors, probably because the new 10-frame fade-in animation on the comment text would require at least the comment area in VRAM to be captured into nopoly_B on every one of the 10 frames. However, the initial pixels of the tracklist are still included in nopoly_B, which would allow those to still use any odd color in this game. ZUN only removed those from nopoly_B in TH05, where it had to be changed because that game lets you scroll and browse through multiple tracklists.
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:
Due to the polygon animation, the Music Room is one of the few double-buffered menus in PC-98 Touhou, rendering to both VRAM pages on alternate frames instead of using the other page to store a background image. Unfortunately though, this doesn't actually translate to tearing-free rendering because ZUN's initial implementation for TH02 mixed up the order of the required operations. You're supposed to first wait for the GDC's VSync interrupt and then, within the display's vertical blanking interval, write to the relevant I/O ports to flip the accessed and shown pages. Doing it the other way around and flipping as soon as you're finished with the last draw call of a frame means that you'll very likely hit a point where the (real or emulated) electron beam is still traveling across the screen. This ensures that there will be a tearing line somewhere on the screen on all but the fastest PC-98 models that can render an entire frame of the Music Room completely within the vertical blanking interval, causing the very issue that double-buffering was supposed to prevent.
ZUN only fixed this landmine in TH05.
The polygons have a fixed vertex count and radius depending on their index, everything else is randomized. They are also never reinitialized while OP.EXE is running – if you leave the Music Room and reenter it, they will continue animating from the same position.
TH02 and TH04 don't handle it at all, causing held keys to be processed again after about a second.
TH03 and TH05 correctly work around the quirk, at the usual cost of a 614.4 µs delay per frame. Except that the delay is actually twice as long in frames in which a previously held key is released, because this code is a mess.
But even in 2024, DOSBox-X is the only emulator that actually replicates this detail of real hardware. On anything else, keyboard input will behave as ZUN intended it to. At least I've now mentioned this once for every game, and can just link back to this blog post for the other menus we still have to go through, in case their game-specific behavior matches this one.
TH02 is the only game that
separately lists the stage and boss themes of the main game, rather than following the in-game order of appearance,
continues playing the selected track when leaving the Music Room,
always loads both MIDI and PMD versions, regardless of the currently selected mode, and
does not stop the currently playing track before loading the new one into the PMD and MMD drivers.
The combination of 2) and 3) allows you to leave the Music Room and change the music mode in the Option menu to listen to the same track in the other version, without the game changing back to the title screen theme. 4), however, might cause the PMD and MMD drivers to play garbage for a short while if the music data is loaded from a slow storage device that takes longer than a single period of the OPN timer to fill the driver's song buffer. Probably not worth mentioning anymore though, now that people no longer try fitting PC-98 Touhou games on floppy disks.
Exactly 40 (TH02/TH03) / 38 (TH04/TH05) visible bytes per line,
padded with 2 bytes that can hold a CR/LF newline sequence for easier editing.
Every track starts with a title line that mostly just duplicates the names from the hardcoded tracklist,
followed by a fixed 19 (TH02/TH03/TH04) / 9 (TH05) comment lines.
In TH04 and TH05, lines can start with a semicolon (;) to prevent them from being rendered. This is purely a performance hint, and is visually equivalent to filling the line with spaces.
All in all, the quality of the code is even slightly below the already poor standard for PC-98 Touhou: More VRAM page copies than necessary, conditional logic that is nested way too deeply, a distinct avoidance of state in favor of loops within loops, and – of course – a couple of gotos to jump around as needed.
In TH05, this gets so bad with the scrolling and game-changing tracklist that it all gives birth to a wonderfully obscure inconsistency: When pressing both ⬆️/⬇️ and ⬅️/➡️ at the same time, the game first processes the vertical input and then the horizontal one in the next frame, making it appear as if the latter takes precedence. Except when the cursor is highlighting the first (⬆️ ) or 12th (⬇️ ) element of the list, and said list element is not the first track (⬆️ ) or the quit option (⬇️ ), in which case the horizontal input is ignored.
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…
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.
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.
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.
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:
First off, the text area has a size of 480×64 pixels. This means that it
does not correspond to the tiled area painted into TH05's
EDBK?.PI images:
The yellow area is designated for character names.
Since the font weight can be customized, all text is rendered to VRAM.
This also includes gaiji, despite them ignoring the font weight
setting.
The system supports automatic line breaks on a per-glyph basis, which
move the text cursor to the beginning of the red text area. This might seem like a piece of long-forgotten
ancient wisdom at first, considering the absence of automatic line breaks in
Windows Touhou. However, ZUN probably implemented it more out of pure
necessity: Text in VRAM needs to be unblitted when starting a new box, which
is way more straightforward and performant if you only need to worry
about a fixed area.
The system also automatically starts a new (key press-separated) text
box after the end of the 4th line. However, the text cursor is
also unconditionally moved to the top-left corner of the yellow name
area when this happens, which is almost certainly not what you expect, given
that automatic line breaks stay within the red area. A script author might
as well add the necessary text box change commands manually, if you're
forced to anticipate the automatic ones anyway…
Due to ZUN forgetting an unblitting call during the TH05 refactoring of the
box background buffer, this feature is even completely broken in that game,
as any new text will simply be blitted on top of the old one:
Wait, why are we already talking about game-specific differences after
all? Also, note how the ⏎ animation appears one line below where you'd
expect it.
Overall, the system is geared toward exclusively full-width text. As
exemplified by the 2014 static English patches and the screenshots in this
blog post, half-width text is possible, but comes with a lot of
asterisks attached:
Each loop of the script interpreter starts by looking at the next
byte to distinguish commands from text. However, this step also skips
over every ASCII space and control character, i.e., every byte
≤ 32. If you only intend to display full-width glyphs anyway, this
sort of makes sense: You gain complete freedom when it comes to the
physical layout of these script files, and it especially allows commands
to be freely separated with spaces and line breaks for improved
readability. Still, enforcing commands to be separated exclusively by
line breaks might have been even better for readability, and would have
freed up ASCII spaces for regular text…
Non-command text is blindly processed and rendered two bytes at a
time. The rendering function interprets these bytes as a Shift-JIS
string, so you can use half-width characters here. While the
second byte can even be an ASCII 0x20 space due to the
parser's blindness, all half-width characters must still occur in pairs
that can't be interrupted by commands:
As a workaround for at least the ASCII space issue, you can replace
them with any of the unassigned
Shift-JIS lead bytes – 0x80, 0xA0, or
anything between 0xF0 and 0xFF inclusive.
That's what you see in all screenshots of this post that display
half-width spaces.
Finally, did you know that you can hold ESC to fast-forward
through these cutscenes, which skips most frame delays and reduces the rest?
Due to the blocking nature of all commands, the ESC key state is
only updated between commands or 2-byte text groups though, so it can't
interrupt an ongoing delay.
Superficially, the list of game-specific differences doesn't look too long,
and can be summarized in a rather short table:
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. 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:
The final official 0.23 release of master.lib has a bug in
graph_gaiji_put*(). To calculate the JIS X 0208 code point for
a gaiji, it is enough to ADD 5680h onto the gaiji ID. However,
these functions accidentally use ADC instead, which incorrectly
adds the x86 carry flag on top, causing weird off-by-one errors based on the
previous program state. ZUN did fix this bug directly inside master.lib for
TH04 and TH05, but still needed to work around it in TH03 by subtracting 1
from the intended gaiji ID. Anyone up for maintaining a bug-fixed master.lib
repository?
The worst piece of bloat comes from TH03 and TH04 needlessly
switching the visibility of VRAM pages while blitting a new 320×200 picture.
This makes it much harder to understand the code, as the mere existence of
these page switches is enough to suggest a more complex interplay between
the two VRAM pages which doesn't actually exist. Outside this visibility
switch, page 0 is always supposed to be shown, and page 1 is always used
for temporarily storing pixels that are later crossfaded onto page 0. This
is also the only reason why TH03 has to render text and gaiji onto both VRAM
pages to begin with… and because TH04 doesn't, changing the picture in the
middle of a string of text is technically bugged in that game, even though
you only get to temporarily see the new text on very underclocked PC-98
systems.
These performance implications made me wonder why cutscenes even bother with
writing to the second VRAM page anyway, before copying each crossfade step
to the visible one.
📝 We learned in June how costly EGC-"accelerated" inter-page copies are;
shouldn't it be faster to just blit the image once rather than twice?
Well, master.lib decodes .PI images into a packed-pixel format, and
unpacking such a representation into bitplanes on the fly is just about the
worst way of blitting you could possibly imagine on a PC-98. EGC inter-page
copies are already fairly disappointing at 42 cycles for every 16 pixels, if
we look at the i486 and ignore VRAM latencies. But under the same
conditions, packed-pixel unpacking comes in at 81 cycles for every 8
pixels, or almost 4× slower. On lower-end systems, that can easily sum up to
more than one frame for a 320×200 image. While I'd argue that the resulting
tearing could have been an acceptable part of the transition between two
images, it's understandable why you'd want to avoid it in favor of the
pure effect on a slower framerate.
Really makes me wonder why master.lib didn't just directly decode .PI images
into bitplanes. The performance impact on load times should have been
negligible? It's such a good format for
the often dithered 16-color artwork you typically see on PC-98, and
deserves better than master.lib's implementation which is both slow to
decode and slow to blit.
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.
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
.
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:
Numeric parameters are read as sequences of up to 3 ASCII digits. This
limits them to a range from 0 to 999 inclusive, with 000 and
0 being equivalent. Because there's no further sentinel
character, any further digit from the 4th one onwards is
interpreted as regular text.
Filename parameters must be terminated with a space or newline and are
limited to 12 characters, which translates to 8.3 basenames without any
directory component. Any further characters are ignored and displayed as
text as well.
Each .PI image can contain up to four 320×200 pictures ("quarters") for
the cutscene picture area. In the script commands, they are numbered like
this:
0
1
2
3
\@
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.
\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.
🐞 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.
\c15
Changes the text color to VRAM color 15.
\c=字,15
Adds a color map entry: If 字 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.
\e0
Plays the sound effect with the given ID.
\f
(no-op)
\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.
\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.
\g8
Plays a blocking 8-frame screen shake
animation.
\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.
@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.
@h
Shows the gaiji.
@t
Shows the gaiji.
@!
Shows the gaiji.
@?
Shows the gaiji.
@!!
Shows the gaiji.
@!?
Shows the gaiji.
\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.
\m$
Stops the currently playing BGM.
\m*
Restarts playback of the currently loaded BGM from the
beginning.
\m,filename
Stops the currently playing BGM, loads a new one from the given
file, and starts playback.
\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.
\p
(no-op)
\p-
Deallocates the loaded .PI image.
\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-.
\pp
Sets the hardware palette to the one of the loaded .PI image.
\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.
\p=
Runs \pp followed by \p@.
\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.
\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.
\v1
Sets the number of frames to wait between every 2 bytes of rendered
text.
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.
\v2
\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.
\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
\wk64
\wmk64,64
\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.
\=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.
\==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.
\$
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.
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.
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:
Establish basic UTF-8 parsing for less painful manual editing of the
source files
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 that Neko Project II auto-generates if you
don't provide either.
(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:
Implement text subdivisions at a sensible granularity while retaining
automatic line and box breaks
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)
Implement a custom Unicode font system (glyphs would be taken from GNU
Unifont unless translators provide a different 8×16 font for their
language)
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)
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)
Add a nice language selection option to the main menu
(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.
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…
This approach ruins any possibility of compressing the script code into loops. While ZUN did use loops, all of them are very short because they can only last until the next color change. In the end, the code contains 90 explicitly spelled-out calls to the 5-parameter line typing function that only vary in the pointer to each line and in the slower speed used for the one or two final lines of each ending. As usual, I've deduplicated the code in the ReC98 repository down to a sensible level, but here's the full inlined and macro-expanded horror:
frame at the end of the animation is unused; while it might look identical to the ZUN glyphs later on in the Staff Roll, that's only because both are independently rendered boldfaced versions of the same font ROM glyphs. Then again, it does prove that ZUN created this animation on a PC-98 model made by NEC, as the Epson clones used a font ROM with a distinctly different look.
These screenshots must have been made earlier in development when the sprite didn't yet feature the second ring at the top. The same applies to the Stage 4 screenshot later on:
TH03
TH04
TH05
, past right edge of current row
gaiji. Not to be confused with 
gaiji.
gaiji.
gaiji.
gaiji.
gaiji.
gaiji.
that Neko Project II auto-generates if you
don't provide either.