1117783731
* PLAYER -> GET_PLAYER(globalCtx) * ACTIVE_CAM -> GET_ACTIVE_CAM(globalCtx) * PR Suggestions * formatter * Add brackets * remove from actorfixer.py * Bring back actorfixer.py change
32 KiB
The rest of the functions in the actor
Up: Contents Previous: Beginning decompilation: the Init function and the Actor struct
Now what?
Following the scheme we gave last time, we have three options:
func_80A87BECfunc_80A87C30func_80A87F44
Another option is to look at Destroy, which for smaller actors can often be done straight after Init, since it usually just removes colliders and deallocates dynapoly. However, glancing at the three given functions' assembly, there is an obvious standout:
glabel func_80A87F44
/* 00744 80A87F44 AFA40000 */ sw $a0, 0x0000($sp)
/* 00748 80A87F48 03E00008 */ jr $ra
/* 0074C 80A87F4C AFA50004 */ sw $a1, 0x0004($sp)
This is a classic "function with two arguments that does nothing". So we can simply comment out the appropriate pragma and put
void func_80A87F44(Actor* thisx, GlobalContext* globalCtx) {
}
in the C file.
Destroy
Destroy will be a dead end, but we might as well do it now. Remaking the context and using mips2c on it (main 4 function, so change the prototype to use EnJj* this!) gives
void EnJj_Destroy(EnJj *this, GlobalContext *globalCtx) {
GlobalContext *temp_a3;
s16 temp_v0;
temp_v0 = this->dyna.actor.params;
temp_a3 = globalCtx;
if (temp_v0 == -1) {
globalCtx = temp_a3;
DynaPoly_DeleteBgActor(temp_a3, &temp_a3->colCtx.dyna, (s32) this->dyna.bgId);
Collider_DestroyCylinder(globalCtx, &this->collider);
return;
}
if ((temp_v0 != 0) && (temp_v0 != 1)) {
return;
}
DynaPoly_DeleteBgActor(temp_a3, &temp_a3->colCtx.dyna, (s32) this->dyna.bgId);
}
Again remember to return the first argument to Actor* this and put EnJj* this = THIS; in the function body. Based on what we know about this actor already, we expect this to be another switch. Rearranging it as such, and removing the likely fake temp_v0 gives
void EnJj_Destroy(Actor* thisx, GlobalContext* globalCtx) {
EnJj* this = THIS;
GlobalContext* temp_a3;
temp_a3 = globalCtx;
switch (this->dyna.actor.params) {
case -1:
DynaPoly_DeleteBgActor(globalCtx, &globalCtx->colCtx.dyna, this->dyna.bgId);
Collider_DestroyCylinder(globalCtx, &this->collider);
break;
case 0:
case 1:
DynaPoly_DeleteBgActor(temp_a3, &temp_a3->colCtx.dyna, this->dyna.bgId);
break;
}
}
Using ./diff.py -mwo3 EnJj_Destroy shows that this matches already, but it seems like the temp usage should be more consistent. A little experimentation shows that
void EnJj_Destroy(Actor* thisx, GlobalContext* globalCtx) {
EnJj* this = THIS;
switch (this->dyna.actor.params) {
case -1:
DynaPoly_DeleteBgActor(globalCtx, &globalCtx->colCtx.dyna, this->dyna.bgId);
Collider_DestroyCylinder(globalCtx, &this->collider);
break;
case 0:
case 1:
DynaPoly_DeleteBgActor(globalCtx, &globalCtx->colCtx.dyna, this->dyna.bgId);
break;
}
}
also matches, with no need for the GlobalContext* temp.
Action Functions
func_80A87BEC
Of the two functions we have available, func_80A87BEC is shorter, so we do that next. Since we haven't changed any types or header file information, there is no need to remake the context. mips2c gives
void func_80A87BEC(EnJj *this, GlobalContext *globalCtx) {
if (this->dyna.actor.xzDistToPlayer < 300.0f) {
func_80A87800(this, &func_80A87B9C);
}
}
We see that this function just sets another action function when Link is close enough to the actor. All we have to do to this is remove the &, and prototype func_80A87B9C to be an action function. Notably, this time it is not used before it is defined, so we don't need a prototype at the top: putting a placeholder one in at the function position will do, i.e. our total edits this time are
#pragma GLOBAL_ASM("asm/non_matchings/overlays/actors/ovl_En_Jj/func_80A87B9C.s")
void func_80A87B9C(EnJj *this, GlobalContext *globalCtx);
// #pragma GLOBAL_ASM("asm/non_matchings/overlays/actors/ovl_En_Jj/func_80A87BEC.s")
void func_80A87BEC(EnJj *this, GlobalContext *globalCtx) {
if (this->dyna.actor.xzDistToPlayer < 300.0f) {
func_80A87800(this, func_80A87B9C);
}
}
We can now either follow this chain of action functions down, or start with the other one. We will go down in this case: it is usually easier to keep track that way.
func_80A87B9C
We can remake the context, but it's simpler to just stick the function prototype we made at the bottom of the context. Either way, mips2c gives us
void func_80A87B9C(EnJj *this, GlobalContext *globalCtx) {
s16 temp_v0;
temp_v0 = this->unk308;
if ((s32) temp_v0 >= -0x1450) {
this->unk308 = (s16) (temp_v0 - 0x66);
if ((s32) this->unk308 < -0xA28) {
func_8003EBF8(globalCtx, &globalCtx->colCtx.dyna, this->childActor->unk14C);
}
}
}
Here's a new variable for our actor struct! Don't be deceived by the s32 cast in the comparison: mips2c always does that if it's not sure. The reliable one is the s16 cast lower down. (An s32 doesn't fit in the space we have anyway). So the actor struct is now
typedef struct EnJj {
/* 0x0000 */ DynaPolyActor dyna;
/* 0x0164 */ SkelAnime skelAnime;
/* 0x01A8 */ Vec3s jointTable[22];
/* 0x022C */ Vec3s morphTable[22];
/* 0x02B0 */ ColliderCylinder collider;
/* 0x02FC */ EnJjActionFunc actionFunc;
/* 0x0300 */ Actor* childActor;
/* 0x0304 */ char unk_304[0x4];
/* 0x0308 */ s16 unk_308;
/* 0x030A */ s16 unk_30A;
/* 0x030C */ char unk_30C[0x2];
/* 0x030E */ s8 unk_30E;
/* 0x030F */ s8 unk_30F;
/* 0x0310 */ s8 unk_310;
/* 0x0311 */ s8 unk_311;
/* 0x0312 */ char unk_312[0x2];
} EnJj; // size = 0x0314
We can eliminate the temp since it's use in a simple way one after the other. this->unk308 = (s16) (this->unk308 - 0x66); can be written as this->unk308 -= 0x66;.
In the func_8003EBF8 we see that we should have at least made this->childActor a DynaPolyActor*, so that the last argument is its bgId. To avoid compiler warnings, we also need to cast the Actor_SpawnAsChild as such in Init,
this->childActor = (DynaPolyActor*)Actor_SpawnAsChild(...)
Doing so, we are left with
void func_80A87B9C(EnJj *this, GlobalContext *globalCtx) {
if (this->unk_308 >= -0x1450) {
this->unk_308 -= 0x66;
if (this->unk_308 < -0xA28) {
func_8003EBF8(globalCtx, &globalCtx->colCtx.dyna, this->childActor->bgId);
}
}
}
The diff shows this doesn't match:
It's not obvious why this doesn't match: the branching is correct, but it's loading stuff in the wrong order. Now is therefore a good time to introduce the permuter.
The permuter
The permuter is a useful program for when you run out of ideas: it assigns a function a score based on how much it differs from the original code, then does random stuff that is known to improve matching, keeping ones that give better scores. It is not going to fix your control flow, but it does reasonably well on instruction differences and regalloc. It also has an option to worry about stack differences as well (--stack-diffs).
To use the permuter, clone the decomp-permuter repo from the link given in Discord. First, import the C file and MIPS of the function to compare using
./import.py <path_to_c> <path_to_func_name.s>
It will put it in a subdirectory of nonmatchings. You then run
./permuter.py nonmatchings/<function_name>/
to produce suggestions. There are various arguments that can be used, of which the most important initially is -j: -jN tells it to use N CPU threads.
Suggestions are saved in the directory it imported the function into.
The first suggestion looks plausible:
--- before
+++ after
@@ -1390,12 +1390,14 @@
} EnJj;
void func_80A87B9C(EnJj *this, GlobalContext *globalCtx)
{
- if (this->unk_308 >= (-0x1450))
+ DynaPolyActor *new_var;
+ new_var = this->childActor;
+ if (this->unk_308 > ((-0x1450) - 1))
{
this->unk_308 -= 0x66;
if (this->unk_308 < (-0xA28))
{
- func_8003EBF8(globalCtx, &globalCtx->colCtx.dyna, this->childActor->bgId);
+ func_8003EBF8(globalCtx, &globalCtx->colCtx.dyna, new_var->bgId);
}
}
In particular, adding a temp for the actor. Some of the rest is rather puzzling, but let's just try the actor temp,
void func_80A87B9C(EnJj *this, GlobalContext *globalCtx) {
DynaPolyActor* child = this->childActor;
if (this->unk_308 >= -0x1450) {
this->unk_308 -= 0x66;
if (this->unk_308 < -0xA28) {
func_8003EBF8(globalCtx, &globalCtx->colCtx.dyna, child->bgId);
}
}
}
Hooray, that worked. The function now matches (as you can check by running make -j). In this case we are lucky and got a couple of 0s almost immediately. This will often not be the case, and you may have to go through multiple iterations to improve things. Or you get more ideas for what to do without the permuter necessarily doing everything for you.
However, the hex values look a bit strange, and it turns out the decimal equivalents look less strange, so it's a good idea to translate them:
void func_80A87B9C(EnJj *this, GlobalContext *globalCtx) {
DynaPolyActor* child = this->childActor;
if (this->unk_308 >= -5200) {
this->unk_308 -= 102;
if (this->unk_308 < -2600) {
func_8003EBF8(globalCtx, &globalCtx->colCtx.dyna, child->bgId);
}
}
}
With that, we have reached the end of this action function chain, and now have to look at func_80A87C30
func_80A87C30
Remaking the context and running mips2c on the assembly gives
void func_80A87C30(EnJj *this, GlobalContext *globalCtx) {
if ((Math_Vec3f_DistXZ(&D_80A88CF0, globalCtx->unk1C44 + 0x24) < 300.0f) && (globalCtx->isPlayerDroppingFish(globalCtx) != 0)) {
this->unk_30C = 0x64;
func_80A87800(this, &func_80A87CEC);
}
this->collider.dim.pos.x = -0x4DD;
this->collider.dim.pos.y = 0x14;
this->collider.dim.pos.z = -0x30;
CollisionCheck_SetOC(globalCtx, &globalCtx->colChkCtx, (Collider *) &this->collider);
}
If you know anything about this game, this is obviously the function that begins the process of the swallowing Link cutscene. Performing minor cleanups reduces us to
void func_80A87C30(EnJj *this, GlobalContext *globalCtx) {
if ((Math_Vec3f_DistXZ(&D_80A88CF0, globalCtx->unk1C44 + 0x24) < 300.0f) && (globalCtx->isPlayerDroppingFish(globalCtx) != 0)) {
this->unk_30C = 100;
func_80A87800(this, func_80A87CEC);
}
this->collider.dim.pos.x = -1245;
this->collider.dim.pos.y = 20;
this->collider.dim.pos.z = -48;
CollisionCheck_SetOC(globalCtx, &globalCtx->colChkCtx, &this->collider);
}
There are three things left to do to this function:
- prototype the new action function,
func_80A87CEC. This one is used before its definition, so needs to be prototyped at the top of the file. - extern
D_80A88CF0, and since the arguments ofMath_Vec3f_DistXZareVec3fs, convert it to floats. To do float conversion, either use an online converter, or get an extension for VSCode that can do it. The data becomes
extern Vec3f D_80A88CF0;
// static Vec3f D_80A88CF0 = { -1589.0f, 53.0f, -43.0f };
(you must include the .0f parts even for integer floats: it can affect codegen, and as such it is part of our style).
- replace the mysterious
globalCtx->unk1C44 + 0x24. The first part is so common that most people on decomp know it by heart: it is the location of the Player actor.+ 0x24is obviously an offset that leats to aVec3f, and if you look in the actor struct, you find that this is the location ofworld.pos. To usePlayer, we putPlayer* player = GET_PLAYER(globalCtx)at the top of the function.
NOTE: mips_to_c will now output something like &globalCtx->actorCtx.actorLists[2].head for the Player pointer instead: this makes a lot more sense, but is not so easy to spot in the ASM without the characteristic 1C44.
After all this, the function becomes
void func_80A87C30(EnJj *this, GlobalContext *globalCtx) {
Player* player = GET_PLAYER(globalCtx);
if ((Math_Vec3f_DistXZ(&D_80A88CF0, &player->actor.world.pos) < 300.0f) && (globalCtx->isPlayerDroppingFish(globalCtx) != 0)) {
this->unk_30C = 100;
func_80A87800(this, func_80A87CEC);
}
this->collider.dim.pos.x = -1245;
this->collider.dim.pos.y = 20;
this->collider.dim.pos.z = -48;
CollisionCheck_SetOC(globalCtx, &globalCtx->colChkCtx, &this->collider);
}
One issue we have swept under the carpet thus far is what unk_30C is: we still have it as padding. For this we have to look at the MIPS, since mips2c hasn't told us. Scanning through the file, we find
/* 00498 80A87C98 A60E030C */ sh $t6, 0x030C($s0) ## 0000030C
which tells us that unk_30C is an s16, filling another gap in the struct:
typedef struct EnJj {
/* 0x0000 */ DynaPolyActor dyna;
/* 0x0164 */ SkelAnime skelAnime;
/* 0x01A8 */ Vec3s jointTable[22];
/* 0x022C */ Vec3s morphTable[22];
/* 0x02B0 */ ColliderCylinder collider;
/* 0x02FC */ EnJjActionFunc actionFunc;
/* 0x0300 */ DynaPolyActor* childActor;
/* 0x0304 */ char unk_304[0x4];
/* 0x0308 */ s16 unk_308;
/* 0x030A */ s16 unk_30A;
/* 0x030C */ s16 unk_30C;
/* 0x030E */ s8 unk_30E;
/* 0x030F */ s8 unk_30F;
/* 0x0310 */ s8 unk_310;
/* 0x0311 */ s8 unk_311;
/* 0x0312 */ char unk_312[0x2];
} EnJj; // size = 0x0314
The diff now looks fine for this function, but it gives compiler warnings about CollisionCheck_SetOC(globalCtx, &globalCtx->colChkCtx, &this->collider);: the last argument is the wrong type: we need to give it &this->collider.base instead, which points to the same address, but is the right type. So the matching function is
void func_80A87C30(EnJj *this, GlobalContext *globalCtx) {
Player* player = GET_PLAYER(globalCtx);
if ((Math_Vec3f_DistXZ(&D_80A88CF0, &player->actor.world.pos) < 300.0f) && (globalCtx->isPlayerDroppingFish(globalCtx) != 0)) {
this->unk_30C = 100;
func_80A87800(this, func_80A87CEC);
}
this->collider.dim.pos.x = -1245;
this->collider.dim.pos.y = 20;
this->collider.dim.pos.z = -48;
CollisionCheck_SetOC(globalCtx, &globalCtx->colChkCtx, &this->collider.base);
}
Again we have only one choice for our next function, namely func_80A87CEC.
func_80A87CEC
Remaking the context and running mips2c on the assembly gives
void func_80A87CEC(EnJj *this, GlobalContext *globalCtx) {
DynaPolyActor *sp1C;
DynaPolyActor *temp_v1;
s16 temp_v0;
temp_v0 = this->unk_30C;
temp_v1 = this->childActor;
if ((s32) temp_v0 > 0) {
this->unk_30C = temp_v0 - 1;
return;
}
sp1C = temp_v1;
globalCtx = globalCtx;
func_80A87800(this, &func_80A87EF0);
globalCtx->csCtx.segment = &D_80A88164;
gSaveContext.cutsceneTrigger = (u8)1U;
func_8003EBF8(globalCtx, &globalCtx->colCtx.dyna, (s32) temp_v1->bgId);
func_8005B1A4(globalCtx->cameraPtrs[globalCtx->activeCamera]);
gSaveContext.unkEDA = (u16) (gSaveContext.unkEDA | 0x400);
func_80078884((u16)0x4802U);
}
Easy things to sort out:
-
func_80A87EF0is another action function. Again it is defined below, so needs a prototype at the top. -
We have another unknown symbol,
D_80A88164. This is the massive chunk of data that makes up the cutscene (of Jabu swallowing Link). We will worry about it when we have decompiled the rest of the actor. For now just extern it asUNK_TYPE. -
We can remove the casts from
(u8)1Uand just leave1. -
globalCtx->cameraPtrs[globalCtx->activeCamera]has a macro: it isGET_ACTIVE_CAM(globalCtx), so this line can be written as
func_8005B1A4(GET_ACTIVE_CAM(globalCtx));
gSaveContext.unkEDAwe have dealt with before: it isgSaveContext.eventChkInf[3]. This is a flag-setting function; it can be written more compactly as
gSaveContext.unkEDA |= 0x400
- The last function is an audio function: we can look up the argument in
sfx.hand find it isNA_SE_SY_CORRECT_CHIME
It remains to work out which, if any, of the temps are real. Based on our previous experience, we expect temp_v1 to be real. sp1C is unused and hence unlikely to be real. temp_v0 is only used in the short if and so probably not real. Checking the diff shows that our suspicions were correct:
void func_80A87CEC(EnJj *this, GlobalContext *globalCtx) {
DynaPolyActor *child = this->childActor;
if (this->unk_30C > 0) {
this->unk_30C--;
return;
}
func_80A87800(this, func_80A87EF0);
globalCtx->csCtx.segment = &D_80A88164;
gSaveContext.cutsceneTrigger = 1;
func_8003EBF8(globalCtx, &globalCtx->colCtx.dyna, child->bgId);
func_8005B1A4(GET_ACTIVE_CAM(globalCtx));
gSaveContext.eventChkInf[3] |= 0x400;
func_80078884(NA_SE_SY_CORRECT_CHIME);
}
matches, but generates a complier warning for func_8005B1A4, which it can't find. To fix this, add it to functions.h, in as near as possible the correct position in numerical order. Some detective work with VSCode's Search shows that this function lives in z_camera.c, and its prototype is s16 func_8005B1A4(Camera* camera), so add this line to functions.h at the bottom of the camera functions part.
Lastly, we prefer to limit use of early returns, and use elses instead if possible. That applies here: the function can be rewritten as
void func_80A87CEC(EnJj* this, GlobalContext* globalCtx) {
DynaPolyActor* child = this->childActor;
if (this->unk_30C > 0) {
this->unk_30C--;
} else {
func_80A87800(this, func_80A87EF0);
globalCtx->csCtx.segment = &D_80A88164;
gSaveContext.cutsceneTrigger = 1;
func_8003EBF8(globalCtx, &globalCtx->colCtx.dyna, child->bgId);
func_8005B1A4(GET_ACTIVE_CAM(globalCtx));
gSaveContext.eventChkInf[3] |= 0x400;
func_80078884(NA_SE_SY_CORRECT_CHIME);
}
}
and still match. (Early returns are used after an Actor_Kill and in a few other situations, but generally avoided for elses elsewhere if possible. Talking of which...)
func_80A87EF0
mips2c with updated context gives
void func_80A87EF0(EnJj *this, GlobalContext *globalCtx) {
char *temp_a0;
u16 temp_v0;
temp_v0 = (u16) this->unk_30A;
if ((temp_v0 & 4) == 0) {
this->unk_30A = temp_v0 | 4;
temp_a0 = this->unk_304;
if (temp_a0 != 0) {
this = this;
Actor_Kill((Actor *) temp_a0);
this->dyna.actor.child = NULL;
}
}
}
Now we're a bit stuck: this tells us that this->unk_304 is an Actor*, but we know nothing else about it. So just make it an actor for the time being. As before, this->unk_304 is a pointer, so we should compare temp_a0 to NULL.
We also find in the MIPS
lhu $v0, 0x030A($a0)
which at last tells us that unk_30A is actually a u16. We can now eliminate temp_v0, and replace the == 0 by a !(...), which leaves
void func_80A87EF0(EnJj *this, GlobalContext *globalCtx) {
Actor *temp_a0;
if (!(this->unk_30A & 4)) {
this->unk_30A |= 4;
temp_a0 = this->unk_304;
if (temp_a0 != 0) {
Actor_Kill(temp_a0);
this->dyna.actor.child = NULL;
}
}
}
although we are as yet none the wiser as to which actor unk_304 actually points to.
Again we have run out of action functions. The rules suggest that we now look at Update.
Update
Update runs every frame and updates the properties of the actor, and usually runs the action functions once per frame. As before we change the first argument to EnJj* this to get it to use our actor's struct. mips2c gives
void EnJj_Update(EnJj *this, GlobalContext *globalCtx) {
if ((globalCtx->csCtx.state != CS_STATE_IDLE) && (globalCtx->unk1D94 != 0)) {
func_80A87D94();
} else {
this->actionFunc(this);
if (this->skelAnime.curFrame == 41.0f) {
Audio_PlayActorSound2((Actor *) this, (u16)0x28B6U);
}
}
func_80A87B1C(this);
SkelAnime_Update(&this->skelAnime);
Actor_SetScale((Actor *) this, 0.087f);
this->skelAnime.jointTable->unk40 = (s16) this->unk_308;
}
This has several problems: firstly, the action function is called with the wrong argument. We should thus be suspicious of previous functions this actor calls, and decompile them mith mips2c without context if necessary, if only to find out how many arguments they have. We find that func_80A87D94 definitely takes EnJj* this, GlobalContext* globalCtx as arguments. Again, put this prototype at the function location above to avoid compiler warnings.
unk40 of an array of Vec3ss is 0x40 = 0x6 * 0xA + 0x4, so is actually this->skelAnime.jointTable[10].z
Lastly, what is globalCtx->unk1D94? It is at globalCtx->csCtx + 0x30, or globalCtx->csCtx.npcActions + 0x8, which is globalCtx->csCtx.npcActions[2] since this is an array of pointers. Hence it is a pointer, and so should be compared to NULL. Looking up the sfx Id again, we end up with
void EnJj_Update(Actor *thisx, GlobalContext *globalCtx) {
EnJj* this = THIS;
if ((globalCtx->csCtx.state != CS_STATE_IDLE) && (globalCtx->csCtx.npcActions[2] != NULL)) {
func_80A87D94(this, globalCtx);
} else {
this->actionFunc(this, globalCtx);
if (this->skelAnime.curFrame == 41.0f) {
Audio_PlayActorSound2(&this->dyna.actor, NA_SE_EV_JABJAB_GROAN);
}
}
func_80A87B1C(this);
SkelAnime_Update(&this->skelAnime);
Actor_SetScale(&this->dyna.actor, 0.087f);
this->skelAnime.jointTable[10].z = this->unk_308;
}
which matches.
3 more functions to go: the two functions called here, and Draw.
func_80A87B1C
Now our typing problems come home to roost:
void func_80A87B1C(EnJj *this) {
s8 temp_t8;
u8 temp_v0;
u8 temp_v0_2;
temp_v0 = (u8) this->unk_30F;
if ((s32) temp_v0 > 0) {
this->unk_30F = temp_v0 - 1;
return;
}
temp_t8 = (u8) this->unk_30E + 1;
this->unk_30E = temp_t8;
if ((temp_t8 & 0xFF) >= 3) {
temp_v0_2 = (u8) this->unk_310;
this->unk_30E = 0;
if ((s32) temp_v0_2 > 0) {
this->unk_310 = temp_v0_2 - 1;
return;
}
this = this;
this->unk_30F = Rand_S16Offset((u16)0x14, (u16)0x14);
this->unk_310 = (s8) (u8) this->unk_311;
}
}
From this we can read off that unk_30F is a u8, unk_30E is a u8, unk_310 is a u8, and unk_311 is a u8. Giving mips2c new context and trying again,
void func_80A87B1C(EnJj *this) {
u8 temp_t8;
u8 temp_v0;
u8 temp_v0_2;
temp_v0 = this->unk_30F;
if ((s32) temp_v0 > 0) {
this->unk_30F = temp_v0 - 1;
return;
}
temp_t8 = this->unk_30E + 1;
this->unk_30E = temp_t8;
if ((temp_t8 & 0xFF) >= 3) {
temp_v0_2 = this->unk_310;
this->unk_30E = 0;
if ((s32) temp_v0_2 > 0) {
this->unk_310 = temp_v0_2 - 1;
return;
}
this = this;
this->unk_30F = Rand_S16Offset((u16)0x14, (u16)0x14);
this->unk_310 = this->unk_311;
}
}
and all the weird casts are gone. Eliminating the temps, replacing the hex, discarding pointless definitions, and replacing early returns by elses, we end up with
void func_80A87B1C(EnJj* this) {
if (this->unk_30F > 0) {
this->unk_30F--;
} else {
this->unk_30E++;
if ((this->unk_30E & 0xFF) >= 3) {
this->unk_30E = 0;
if (this->unk_310 > 0) {
this->unk_310--;
} else {
this->unk_30F = Rand_S16Offset(20, 20);
this->unk_310 = this->unk_311;
}
}
}
}
Sadly this doesn't match:
You will also find that the permuter is essentially useless here: most solutions it offers look very fake. But there's already something a bit weird in here: why does it do this->unk_30E & 0xFF explicitly in the comparison? It turns out if you remove this, the function matches: the compiler does this calculation automatically when doing comparisons with u8s anyway.
func_80A87D94
This is our last ordinary function. Unfortunately, even with new context, mips2c gives us a bit of a mess:
void func_80A87D94(EnJj *this, GlobalContext *globalCtx) {
s16 temp_v0_2;
u16 temp_t1;
u16 temp_t4;
u16 temp_t7;
u16 temp_t9;
u16 temp_v0;
u16 temp_v1;
u16 temp_v1_2;
u16 temp_v1_3;
u16 phi_v1;
temp_v0 = *globalCtx->unk1D94;
if (temp_v0 != 1) {
if (temp_v0 != 2) {
if (temp_v0 != 3) {
phi_v1 = this->unk_30A;
} else {
temp_v1 = this->unk_30A;
temp_t7 = temp_v1 | 2;
phi_v1 = temp_v1;
if ((temp_v1 & 2) == 0) {
this->unk_30E = 0;
this->unk_30F = 0;
this->unk_310 = 1;
this->unk_311 = 0;
this->unk_30A = temp_t7;
phi_v1 = temp_t7 & 0xFFFF;
}
}
} else {
temp_t1 = this->unk_30A | 1;
temp_v1_2 = temp_t1 & 0xFFFF;
this->unk_30A = temp_t1;
phi_v1 = temp_v1_2;
if ((temp_v1_2 & 8) == 0) {
this->unk_304 = Actor_SpawnAsChild(&globalCtx->actorCtx, (Actor *) this, globalCtx, (u16)0x101, -1100.0f, 105.0f, -27.0f, 0, 0, 0, 0);
temp_t4 = this->unk_30A | 8;
this->unk_30A = temp_t4;
phi_v1 = temp_t4 & 0xFFFF;
}
}
} else {
temp_v1_3 = this->unk_30A;
phi_v1 = temp_v1_3;
if ((temp_v1_3 & 2) != 0) {
this->unk_30E = 0;
this->unk_30F = Rand_S16Offset((u16)0x14, (u16)0x14);
this->unk_310 = 0;
temp_t9 = this->unk_30A ^ 2;
this->unk_311 = 0;
this->unk_30A = temp_t9;
phi_v1 = temp_t9 & 0xFFFF;
}
}
if ((phi_v1 & 1) != 0) {
Audio_PlayActorSound2((Actor *) this, (u16)0x206DU);
temp_v0_2 = this->unk_308;
if ((s32) temp_v0_2 >= -0x1450) {
this->unk_308 = temp_v0_2 - 0x66;
}
}
}
At the top we have
temp_v0 = *globalCtx->unk1D94;
if (temp_v0 != 1) {
if (temp_v0 != 2) {
if (temp_v0 != 3) {
Firstly, we are now comparing with the value of globalCtx->unk1D94, not just using a pointer, so we need the first thing in globalCtx->csCtx.npcActions[2]. This turns out to be globalCtx->csCtx.npcActions[2]->action.
The if structure here is another classic indicator of a switch: nested, with the same variable compared multiple times. If you were to diff this as-is, you would find that the code is in completely the wrong order. Reading how the ifs work, we see that if temp_v0 is 1, it executes the outermost else block, if it is 2, the middle, if 3, the innermost, and if it is anything else, the contents of the innermost if. Hence this becomes
void func_80A87D94(EnJj *this, GlobalContext *globalCtx) {
s16 temp_v0_2;
u16 temp_t1;
u16 temp_t4;
u16 temp_t7;
u16 temp_t9;
// u16 temp_v0;
u16 temp_v1;
u16 temp_v1_2;
u16 temp_v1_3;
u16 phi_v1;
switch (globalCtx->csCtx.npcActions[2]->action) {
case 1:
temp_v1_3 = this->unk_30A;
phi_v1 = temp_v1_3;
if ((temp_v1_3 & 2) != 0) {
this->unk_30E = 0;
this->unk_30F = Rand_S16Offset((u16)0x14, (u16)0x14);
this->unk_310 = 0;
temp_t9 = this->unk_30A ^ 2;
this->unk_311 = 0;
this->unk_30A = temp_t9;
phi_v1 = temp_t9 & 0xFFFF;
}
break;
case 2:
temp_t1 = this->unk_30A | 1;
temp_v1_2 = temp_t1 & 0xFFFF;
this->unk_30A = temp_t1;
phi_v1 = temp_v1_2;
if ((temp_v1_2 & 8) == 0) {
this->unk_304 = Actor_SpawnAsChild(&globalCtx->actorCtx, (Actor *) this, globalCtx, (u16)0x101, -1100.0f, 105.0f, -27.0f, 0, 0, 0, 0);
temp_t4 = this->unk_30A | 8;
this->unk_30A = temp_t4;
phi_v1 = temp_t4 & 0xFFFF;
}
break;
case 3:
temp_v1 = this->unk_30A;
temp_t7 = temp_v1 | 2;
phi_v1 = temp_v1;
if ((temp_v1 & 2) == 0) {
this->unk_30E = 0;
this->unk_30F = 0;
this->unk_310 = 1;
this->unk_311 = 0;
this->unk_30A = temp_t7;
phi_v1 = temp_t7 & 0xFFFF;
}
break;
default:
phi_v1 = this->unk_30A;
break;
}
if ((phi_v1 & 1) != 0) {
Audio_PlayActorSound2((Actor *) this, (u16)0x206DU);
temp_v0_2 = this->unk_308;
if ((s32) temp_v0_2 >= -0x1450) {
this->unk_308 = temp_v0_2 - 0x66;
}
}
}
(notice that this time we need a default to deal with the innermost if contents). If you try to replace 0x206D in the Audio_PlayActorSound2, you will find there is no such sfxId in the list: this is because some sound effects have an extra offset of 0x800 to do with setting flags. Adding 0x800 to the sfxId shows that this sound effect is NA_SE_EV_JABJAB_BREATHE. To correct this to the id in the function, we have a macro SFX_FLAG, and it should therefore be
Audio_PlayActorSound2(&this->dyna.actor, NA_SE_EV_JABJAB_BREATHE - SFX_FLAG);
As usual, most of the remaining temps look fake. The only one that does not is possibly phi_v1. However, the way in which they are used here makes it hard to tell if they are fake, and if so, how to replace them. I encourage you to try this yourself, with the aid of the diff script; the final, matching result, with other cleanup, is hidden below
Matching C for `func_80A87D94`
void func_80A87D94(EnJj* this, GlobalContext* globalCtx) {
switch (globalCtx->csCtx.npcActions[2]->action) {
case 1:
if ((this->unk_30A & 2) != 0) {
this->unk_30E = 0;
this->unk_30F = Rand_S16Offset(20, 20);
this->unk_310 = 0;
this->unk_311 = 0;
this->unk_30A ^= 2;
}
break;
case 2:
this->unk_30A |= 1;
if ((this->unk_30A & 8) == 0) {
this->unk_304 = Actor_SpawnAsChild(&globalCtx->actorCtx, &this->dyna.actor, globalCtx, ACTOR_EFF_DUST,
-1100.0f, 105.0f, -27.0f, 0, 0, 0, 0);
this->unk_30A |= 8;
}
break;
case 3:
if ((this->unk_30A & 2) == 0) {
this->unk_30E = 0;
this->unk_30F = 0;
this->unk_310 = 1;
this->unk_311 = 0;
this->unk_30A |= 2;
}
break;
}
if ((this->unk_30A & 1) != 0) {
Audio_PlayActorSound2(&this->dyna.actor, NA_SE_EV_JABJAB_BREATHE - SFX_FLAG);
if (this->unk_308 >= -5200) {
this->unk_308 -= 102;
}
}
}
With that, the last remaining function is EnJj_Draw. Draw functions have an extra layer of macroing that is required, so we shall cover them separately.
Next: Draw functions