libanim: src/anim.c annotate

libanim

annotate src/anim.c @ 62:eb024fa08fe6

avoid starting an animation blend transition with the same animation as source and target

author	John Tsiombikas <nuclear@member.fsf.org>
date	Mon, 30 Dec 2013 15:22:44 +0200
parents	09e267e7ed4a
children	b52f3e23e06f 60a46a122b0f

rev	line source
nuclear@1	1 #include <stdlib.h>
nuclear@0	2 #include <limits.h>
nuclear@0	3 #include <assert.h>
nuclear@0	4 #include "anim.h"
nuclear@0	5 #include "dynarr.h"
nuclear@0	6
nuclear@7	7 #define ROT_USE_SLERP
nuclear@7	8
nuclear@0	9 static void invalidate_cache(struct anm_node *node);
nuclear@0	10
nuclear@21	11 int anm_init_animation(struct anm_animation *anim)
nuclear@0	12 {
nuclear@0	13 int i, j;
nuclear@0	14 static const float defaults[] = {
nuclear@0	15 0.0f, 0.0f, 0.0f, /* default position */
nuclear@0	16 0.0f, 0.0f, 0.0f, 1.0f, /* default rotation quat */
nuclear@0	17 1.0f, 1.0f, 1.0f /* default scale factor */
nuclear@0	18 };
nuclear@0	19
nuclear@21	20 anim->name = 0;
nuclear@21	21
nuclear@21	22 for(i=0; i<ANM_NUM_TRACKS; i++) {
nuclear@21	23 if(anm_init_track(anim->tracks + i) == -1) {
nuclear@21	24 for(j=0; j<i; j++) {
nuclear@21	25 anm_destroy_track(anim->tracks + i);
nuclear@21	26 }
nuclear@21	27 }
nuclear@21	28 anm_set_track_default(anim->tracks + i, defaults[i]);
nuclear@21	29 }
nuclear@21	30 return 0;
nuclear@21	31 }
nuclear@21	32
nuclear@21	33 void anm_destroy_animation(struct anm_animation *anim)
nuclear@21	34 {
nuclear@21	35 int i;
nuclear@21	36 for(i=0; i<ANM_NUM_TRACKS; i++) {
nuclear@21	37 anm_destroy_track(anim->tracks + i);
nuclear@21	38 }
nuclear@21	39 free(anim->name);
nuclear@21	40 }
nuclear@21	41
nuclear@22	42 void anm_set_animation_name(struct anm_animation anim, const char name)
nuclear@22	43 {
nuclear@22	44 char *newname = malloc(strlen(name) + 1);
nuclear@22	45 if(!newname) return;
nuclear@22	46
nuclear@23	47 strcpy(newname, name);
nuclear@23	48
nuclear@22	49 free(anim->name);
nuclear@22	50 anim->name = newname;
nuclear@22	51 }
nuclear@22	52
nuclear@21	53 /* ---- node implementation ----- */
nuclear@21	54
nuclear@21	55 int anm_init_node(struct anm_node *node)
nuclear@21	56 {
nuclear@0	57 memset(node, 0, sizeof *node);
nuclear@0	58
nuclear@21	59 node->cur_anim[1] = -1;
nuclear@21	60
nuclear@21	61 if(!(node->animations = dynarr_alloc(1, sizeof *node->animations))) {
nuclear@21	62 return -1;
nuclear@21	63 }
nuclear@21	64 if(anm_init_animation(node->animations) == -1) {
nuclear@21	65 dynarr_free(node->animations);
nuclear@21	66 return -1;
nuclear@21	67 }
nuclear@21	68
nuclear@0	69 /* initialize thread-local matrix cache */
nuclear@0	70 pthread_key_create(&node->cache_key, 0);
nuclear@10	71 pthread_mutex_init(&node->cache_list_lock, 0);
nuclear@0	72
nuclear@0	73 return 0;
nuclear@0	74 }
nuclear@0	75
nuclear@0	76 void anm_destroy_node(struct anm_node *node)
nuclear@0	77 {
nuclear@0	78 int i;
nuclear@0	79 free(node->name);
nuclear@0	80
nuclear@0	81 for(i=0; i<ANM_NUM_TRACKS; i++) {
nuclear@21	82 anm_destroy_animation(node->animations + i);
nuclear@0	83 }
nuclear@21	84 dynarr_free(node->animations);
nuclear@0	85
nuclear@0	86 /* destroy thread-specific cache */
nuclear@0	87 pthread_key_delete(node->cache_key);
nuclear@0	88
nuclear@0	89 while(node->cache_list) {
nuclear@0	90 struct mat_cache *tmp = node->cache_list;
nuclear@0	91 node->cache_list = tmp->next;
nuclear@0	92 free(tmp);
nuclear@0	93 }
nuclear@0	94 }
nuclear@0	95
nuclear@0	96 void anm_destroy_node_tree(struct anm_node *tree)
nuclear@0	97 {
nuclear@0	98 struct anm_node c, tmp;
nuclear@0	99
nuclear@0	100 if(!tree) return;
nuclear@0	101
nuclear@0	102 c = tree->child;
nuclear@0	103 while(c) {
nuclear@0	104 tmp = c;
nuclear@0	105 c = c->next;
nuclear@0	106
nuclear@0	107 anm_destroy_node_tree(tmp);
nuclear@0	108 }
nuclear@0	109 anm_destroy_node(tree);
nuclear@0	110 }
nuclear@0	111
nuclear@0	112 struct anm_node *anm_create_node(void)
nuclear@0	113 {
nuclear@0	114 struct anm_node *n;
nuclear@0	115
nuclear@0	116 if((n = malloc(sizeof *n))) {
nuclear@0	117 if(anm_init_node(n) == -1) {
nuclear@0	118 free(n);
nuclear@0	119 return 0;
nuclear@0	120 }
nuclear@0	121 }
nuclear@0	122 return n;
nuclear@0	123 }
nuclear@0	124
nuclear@0	125 void anm_free_node(struct anm_node *node)
nuclear@0	126 {
nuclear@0	127 anm_destroy_node(node);
nuclear@0	128 free(node);
nuclear@0	129 }
nuclear@0	130
nuclear@0	131 void anm_free_node_tree(struct anm_node *tree)
nuclear@0	132 {
nuclear@0	133 struct anm_node c, tmp;
nuclear@0	134
nuclear@0	135 if(!tree) return;
nuclear@0	136
nuclear@0	137 c = tree->child;
nuclear@0	138 while(c) {
nuclear@0	139 tmp = c;
nuclear@0	140 c = c->next;
nuclear@0	141
nuclear@0	142 anm_free_node_tree(tmp);
nuclear@0	143 }
nuclear@0	144
nuclear@0	145 anm_free_node(tree);
nuclear@0	146 }
nuclear@0	147
nuclear@0	148 int anm_set_node_name(struct anm_node node, const char name)
nuclear@0	149 {
nuclear@0	150 char *str;
nuclear@0	151
nuclear@0	152 if(!(str = malloc(strlen(name) + 1))) {
nuclear@0	153 return -1;
nuclear@0	154 }
nuclear@0	155 strcpy(str, name);
nuclear@0	156 free(node->name);
nuclear@0	157 node->name = str;
nuclear@0	158 return 0;
nuclear@0	159 }
nuclear@0	160
nuclear@0	161 const char anm_get_node_name(struct anm_node node)
nuclear@0	162 {
nuclear@0	163 return node->name ? node->name : "";
nuclear@0	164 }
nuclear@0	165
nuclear@0	166 void anm_link_node(struct anm_node p, struct anm_node c)
nuclear@0	167 {
nuclear@0	168 c->next = p->child;
nuclear@0	169 p->child = c;
nuclear@0	170
nuclear@0	171 c->parent = p;
nuclear@0	172 invalidate_cache(c);
nuclear@0	173 }
nuclear@0	174
nuclear@0	175 int anm_unlink_node(struct anm_node p, struct anm_node c)
nuclear@0	176 {
nuclear@0	177 struct anm_node *iter;
nuclear@0	178
nuclear@0	179 if(p->child == c) {
nuclear@0	180 p->child = c->next;
nuclear@0	181 c->next = 0;
nuclear@0	182 invalidate_cache(c);
nuclear@0	183 return 0;
nuclear@0	184 }
nuclear@0	185
nuclear@0	186 iter = p->child;
nuclear@0	187 while(iter->next) {
nuclear@0	188 if(iter->next == c) {
nuclear@0	189 iter->next = c->next;
nuclear@0	190 c->next = 0;
nuclear@0	191 invalidate_cache(c);
nuclear@0	192 return 0;
nuclear@0	193 }
nuclear@0	194 }
nuclear@0	195 return -1;
nuclear@0	196 }
nuclear@0	197
nuclear@21	198 void anm_set_pivot(struct anm_node *node, vec3_t piv)
nuclear@21	199 {
nuclear@21	200 node->pivot = piv;
nuclear@21	201 }
nuclear@21	202
nuclear@21	203 vec3_t anm_get_pivot(struct anm_node *node)
nuclear@21	204 {
nuclear@21	205 return node->pivot;
nuclear@21	206 }
nuclear@21	207
nuclear@21	208
nuclear@21	209 /* animation management */
nuclear@21	210
nuclear@21	211 int anm_use_node_animation(struct anm_node *node, int aidx)
nuclear@21	212 {
nuclear@21	213 if(aidx == node->cur_anim[0] && node->cur_anim[1] == -1) {
nuclear@21	214 return 0; /* no change, no invalidation */
nuclear@21	215 }
nuclear@21	216
nuclear@21	217 if(aidx < 0 \|\| aidx >= anm_get_animation_count(node)) {
nuclear@21	218 return -1;
nuclear@21	219 }
nuclear@21	220
nuclear@21	221 node->cur_anim[0] = aidx;
nuclear@21	222 node->cur_anim[1] = -1;
nuclear@21	223 node->cur_mix = 0;
nuclear@24	224 node->blend_dur = -1;
nuclear@21	225
nuclear@21	226 invalidate_cache(node);
nuclear@21	227 return 0;
nuclear@21	228 }
nuclear@21	229
nuclear@21	230 int anm_use_node_animations(struct anm_node *node, int aidx, int bidx, float t)
nuclear@21	231 {
nuclear@21	232 int num_anim;
nuclear@21	233
nuclear@21	234 if(node->cur_anim[0] == aidx && node->cur_anim[1] == bidx &&
nuclear@21	235 fabs(t - node->cur_mix) < 1e-6) {
nuclear@21	236 return 0; /* no change, no invalidation */
nuclear@21	237 }
nuclear@21	238
nuclear@21	239 num_anim = anm_get_animation_count(node);
nuclear@21	240 if(aidx < 0 \|\| aidx >= num_anim) {
nuclear@21	241 return anm_use_animation(node, bidx);
nuclear@21	242 }
nuclear@21	243 if(bidx < 0 \|\| bidx >= num_anim) {
nuclear@21	244 return anm_use_animation(node, aidx);
nuclear@21	245 }
nuclear@21	246 node->cur_anim[0] = aidx;
nuclear@21	247 node->cur_anim[1] = bidx;
nuclear@21	248 node->cur_mix = t;
nuclear@21	249
nuclear@21	250 invalidate_cache(node);
nuclear@21	251 return 0;
nuclear@21	252 }
nuclear@21	253
nuclear@21	254 int anm_use_animation(struct anm_node *node, int aidx)
nuclear@21	255 {
nuclear@21	256 struct anm_node *child;
nuclear@21	257
nuclear@21	258 if(anm_use_node_animation(node, aidx) == -1) {
nuclear@21	259 return -1;
nuclear@21	260 }
nuclear@21	261
nuclear@21	262 child = node->child;
nuclear@21	263 while(child) {
nuclear@21	264 if(anm_use_animation(child, aidx) == -1) {
nuclear@21	265 return -1;
nuclear@21	266 }
nuclear@21	267 child = child->next;
nuclear@21	268 }
nuclear@21	269 return 0;
nuclear@21	270 }
nuclear@21	271
nuclear@21	272 int anm_use_animations(struct anm_node *node, int aidx, int bidx, float t)
nuclear@21	273 {
nuclear@21	274 struct anm_node *child;
nuclear@21	275
nuclear@21	276 if(anm_use_node_animations(node, aidx, bidx, t) == -1) {
nuclear@21	277 return -1;
nuclear@21	278 }
nuclear@21	279
nuclear@21	280 child = node->child;
nuclear@21	281 while(child) {
nuclear@21	282 if(anm_use_animations(child, aidx, bidx, t) == -1) {
nuclear@21	283 return -1;
nuclear@21	284 }
nuclear@21	285 child = child->next;
nuclear@21	286 }
nuclear@21	287 return 0;
nuclear@21	288
nuclear@21	289 }
nuclear@21	290
nuclear@24	291 void anm_set_node_animation_offset(struct anm_node *node, anm_time_t offs, int which)
nuclear@24	292 {
nuclear@24	293 if(which < 0 \|\| which >= 2) {
nuclear@24	294 return;
nuclear@24	295 }
nuclear@24	296 node->cur_anim_offset[which] = offs;
nuclear@24	297 }
nuclear@24	298
nuclear@24	299 anm_time_t anm_get_animation_offset(const struct anm_node *node, int which)
nuclear@24	300 {
nuclear@24	301 if(which < 0 \|\| which >= 2) {
nuclear@24	302 return 0;
nuclear@24	303 }
nuclear@24	304 return node->cur_anim_offset[which];
nuclear@24	305 }
nuclear@24	306
nuclear@24	307 void anm_set_animation_offset(struct anm_node *node, anm_time_t offs, int which)
nuclear@24	308 {
nuclear@24	309 struct anm_node *c = node->child;
nuclear@24	310 while(c) {
nuclear@24	311 anm_set_animation_offset(c, offs, which);
nuclear@24	312 c = c->next;
nuclear@24	313 }
nuclear@24	314
nuclear@24	315 anm_set_node_animation_offset(node, offs, which);
nuclear@24	316 }
nuclear@24	317
nuclear@24	318 int anm_get_active_animation_index(const struct anm_node *node, int which)
nuclear@21	319 {
nuclear@21	320 if(which < 0 \|\| which >= 2) return -1;
nuclear@21	321 return node->cur_anim[which];
nuclear@21	322 }
nuclear@21	323
nuclear@24	324 struct anm_animation anm_get_active_animation(const struct anm_node node, int which)
nuclear@21	325 {
nuclear@21	326 int idx = anm_get_active_animation_index(node, which);
nuclear@21	327 if(idx < 0 \|\| idx >= anm_get_animation_count(node)) {
nuclear@21	328 return 0;
nuclear@21	329 }
nuclear@21	330 return node->animations + idx;
nuclear@21	331 }
nuclear@21	332
nuclear@24	333 float anm_get_active_animation_mix(const struct anm_node *node)
nuclear@21	334 {
nuclear@21	335 return node->cur_mix;
nuclear@21	336 }
nuclear@21	337
nuclear@24	338 int anm_get_animation_count(const struct anm_node *node)
nuclear@21	339 {
nuclear@21	340 return dynarr_size(node->animations);
nuclear@21	341 }
nuclear@21	342
nuclear@21	343 int anm_add_node_animation(struct anm_node *node)
nuclear@21	344 {
nuclear@21	345 struct anm_animation newanim;
nuclear@21	346 anm_init_animation(&newanim);
nuclear@21	347
nuclear@21	348 node->animations = dynarr_push(node->animations, &newanim);
nuclear@21	349 return 0;
nuclear@21	350 }
nuclear@21	351
nuclear@21	352 int anm_remove_node_animation(struct anm_node *node, int idx)
nuclear@21	353 {
nuclear@21	354 fprintf(stderr, "anm_remove_animation: unimplemented!");
nuclear@21	355 abort();
nuclear@21	356 return 0;
nuclear@21	357 }
nuclear@21	358
nuclear@21	359 int anm_add_animation(struct anm_node *node)
nuclear@21	360 {
nuclear@21	361 struct anm_node *child;
nuclear@21	362
nuclear@21	363 if(anm_add_node_animation(node) == -1) {
nuclear@21	364 return -1;
nuclear@21	365 }
nuclear@21	366
nuclear@21	367 child = node->child;
nuclear@21	368 while(child) {
nuclear@21	369 if(anm_add_animation(child)) {
nuclear@21	370 return -1;
nuclear@21	371 }
nuclear@21	372 child = child->next;
nuclear@21	373 }
nuclear@21	374 return 0;
nuclear@21	375 }
nuclear@21	376
nuclear@21	377 int anm_remove_animation(struct anm_node *node, int idx)
nuclear@21	378 {
nuclear@21	379 struct anm_node *child;
nuclear@21	380
nuclear@21	381 if(anm_remove_node_animation(node, idx) == -1) {
nuclear@21	382 return -1;
nuclear@21	383 }
nuclear@21	384
nuclear@21	385 child = node->child;
nuclear@21	386 while(child) {
nuclear@21	387 if(anm_remove_animation(child, idx) == -1) {
nuclear@21	388 return -1;
nuclear@21	389 }
nuclear@21	390 child = child->next;
nuclear@21	391 }
nuclear@21	392 return 0;
nuclear@21	393 }
nuclear@21	394
nuclear@21	395 struct anm_animation anm_get_animation(struct anm_node node, int idx)
nuclear@21	396 {
nuclear@21	397 if(idx < 0 \|\| idx > anm_get_animation_count(node)) {
nuclear@21	398 return 0;
nuclear@21	399 }
nuclear@21	400 return node->animations + idx;
nuclear@21	401 }
nuclear@21	402
nuclear@21	403 struct anm_animation anm_get_animation_by_name(struct anm_node node, const char *name)
nuclear@21	404 {
nuclear@21	405 return anm_get_animation(node, anm_find_animation(node, name));
nuclear@21	406 }
nuclear@21	407
nuclear@21	408 int anm_find_animation(struct anm_node node, const char name)
nuclear@21	409 {
nuclear@21	410 int i, count = anm_get_animation_count(node);
nuclear@21	411 for(i=0; i<count; i++) {
nuclear@21	412 if(strcmp(node->animations[i].name, name) == 0) {
nuclear@21	413 return i;
nuclear@21	414 }
nuclear@21	415 }
nuclear@21	416 return -1;
nuclear@21	417 }
nuclear@21	418
nuclear@21	419 /* all the rest act on the current animation(s) */
nuclear@21	420
nuclear@21	421 void anm_set_interpolator(struct anm_node *node, enum anm_interpolator in)
nuclear@21	422 {
nuclear@21	423 int i;
nuclear@21	424 struct anm_animation *anim = anm_get_active_animation(node, 0);
nuclear@21	425 if(!anim) return;
nuclear@21	426
nuclear@21	427 for(i=0; i<ANM_NUM_TRACKS; i++) {
nuclear@21	428 anm_set_track_interpolator(anim->tracks + i, in);
nuclear@21	429 }
nuclear@21	430 invalidate_cache(node);
nuclear@21	431 }
nuclear@21	432
nuclear@21	433 void anm_set_extrapolator(struct anm_node *node, enum anm_extrapolator ex)
nuclear@21	434 {
nuclear@21	435 int i;
nuclear@21	436 struct anm_animation *anim = anm_get_active_animation(node, 0);
nuclear@21	437 if(!anim) return;
nuclear@21	438
nuclear@21	439 for(i=0; i<ANM_NUM_TRACKS; i++) {
nuclear@21	440 anm_set_track_extrapolator(anim->tracks + i, ex);
nuclear@21	441 }
nuclear@21	442 invalidate_cache(node);
nuclear@21	443 }
nuclear@21	444
nuclear@23	445 void anm_set_node_active_animation_name(struct anm_node node, const char name)
nuclear@23	446 {
nuclear@23	447 struct anm_animation *anim = anm_get_active_animation(node, 0);
nuclear@23	448 if(!anim) return;
nuclear@23	449
nuclear@23	450 anm_set_animation_name(anim, name);
nuclear@23	451 }
nuclear@23	452
nuclear@23	453 void anm_set_active_animation_name(struct anm_node node, const char name)
nuclear@23	454 {
nuclear@23	455 struct anm_node *child;
nuclear@23	456
nuclear@23	457 anm_set_node_active_animation_name(node, name);
nuclear@23	458
nuclear@23	459 child = node->child;
nuclear@23	460 while(child) {
nuclear@23	461 anm_set_active_animation_name(child, name);
nuclear@23	462 child = child->next;
nuclear@23	463 }
nuclear@23	464 }
nuclear@23	465
nuclear@23	466 const char anm_get_active_animation_name(struct anm_node node)
nuclear@23	467 {
nuclear@23	468 struct anm_animation *anim = anm_get_active_animation(node, 0);
nuclear@23	469 if(anim) {
nuclear@23	470 return anim->name;
nuclear@23	471 }
nuclear@23	472 return 0;
nuclear@23	473 }
nuclear@23	474
nuclear@24	475 /* ---- high level animation blending ---- */
nuclear@24	476 void anm_transition(struct anm_node *node, int anmidx, anm_time_t start, anm_time_t dur)
nuclear@24	477 {
nuclear@24	478 struct anm_node *c = node->child;
nuclear@25	479
nuclear@25	480 if(anmidx == node->cur_anim[0]) {
nuclear@25	481 return;
nuclear@25	482 }
nuclear@25	483
nuclear@24	484 while(c) {
nuclear@24	485 anm_transition(c, anmidx, start, dur);
nuclear@24	486 c = c->next;
nuclear@24	487 }
nuclear@24	488
nuclear@24	489 anm_node_transition(node, anmidx, start, dur);
nuclear@24	490 }
nuclear@24	491
nuclear@24	492 void anm_node_transition(struct anm_node *node, int anmidx, anm_time_t start, anm_time_t dur)
nuclear@24	493 {
nuclear@25	494 if(anmidx == node->cur_anim[0]) {
nuclear@25	495 return;
nuclear@25	496 }
nuclear@25	497
nuclear@24	498 node->cur_anim[1] = anmidx;
nuclear@24	499 node->cur_anim_offset[1] = start;
nuclear@24	500 node->blend_dur = dur;
nuclear@24	501 }
nuclear@24	502
nuclear@24	503
nuclear@24	504 #define BLEND_START_TM node->cur_anim_offset[1]
nuclear@24	505
nuclear@24	506 static anm_time_t animation_time(struct anm_node *node, anm_time_t tm, int which)
nuclear@24	507 {
nuclear@24	508 float t;
nuclear@24	509
nuclear@24	510 if(node->blend_dur >= 0) {
nuclear@24	511 /* we're in transition... */
nuclear@24	512 t = (float)(tm - BLEND_START_TM) / (float)node->blend_dur;
nuclear@24	513 if(t < 0.0) t = 0.0;
nuclear@24	514
nuclear@24	515 node->cur_mix = t;
nuclear@24	516
nuclear@24	517 if(t > 1.0) {
nuclear@24	518 /* switch completely over to the target animation and stop blending */
nuclear@24	519 anm_use_node_animation(node, node->cur_anim[1]);
nuclear@24	520 node->cur_anim_offset[0] = node->cur_anim_offset[1];
nuclear@24	521 }
nuclear@24	522 }
nuclear@24	523
nuclear@24	524 return tm - node->cur_anim_offset[which];
nuclear@24	525 }
nuclear@24	526
nuclear@24	527
nuclear@0	528 void anm_set_position(struct anm_node *node, vec3_t pos, anm_time_t tm)
nuclear@0	529 {
nuclear@21	530 struct anm_animation *anim = anm_get_active_animation(node, 0);
nuclear@21	531 if(!anim) return;
nuclear@21	532
nuclear@21	533 anm_set_value(anim->tracks + ANM_TRACK_POS_X, tm, pos.x);
nuclear@21	534 anm_set_value(anim->tracks + ANM_TRACK_POS_Y, tm, pos.y);
nuclear@21	535 anm_set_value(anim->tracks + ANM_TRACK_POS_Z, tm, pos.z);
nuclear@0	536 invalidate_cache(node);
nuclear@0	537 }
nuclear@0	538
nuclear@24	539
nuclear@0	540 vec3_t anm_get_node_position(struct anm_node *node, anm_time_t tm)
nuclear@0	541 {
nuclear@0	542 vec3_t v;
nuclear@24	543 anm_time_t tm0 = animation_time(node, tm, 0);
nuclear@21	544 struct anm_animation *anim0 = anm_get_active_animation(node, 0);
nuclear@21	545 struct anm_animation *anim1 = anm_get_active_animation(node, 1);
nuclear@21	546
nuclear@21	547 if(!anim0) {
nuclear@21	548 return v3_cons(0, 0, 0);
nuclear@21	549 }
nuclear@21	550
nuclear@24	551 v.x = anm_get_value(anim0->tracks + ANM_TRACK_POS_X, tm0);
nuclear@24	552 v.y = anm_get_value(anim0->tracks + ANM_TRACK_POS_Y, tm0);
nuclear@24	553 v.z = anm_get_value(anim0->tracks + ANM_TRACK_POS_Z, tm0);
nuclear@21	554
nuclear@21	555 if(anim1) {
nuclear@21	556 vec3_t v1;
nuclear@24	557 anm_time_t tm1 = animation_time(node, tm, 1);
nuclear@24	558 v1.x = anm_get_value(anim1->tracks + ANM_TRACK_POS_X, tm1);
nuclear@24	559 v1.y = anm_get_value(anim1->tracks + ANM_TRACK_POS_Y, tm1);
nuclear@24	560 v1.z = anm_get_value(anim1->tracks + ANM_TRACK_POS_Z, tm1);
nuclear@21	561
nuclear@21	562 v.x = v.x + (v1.x - v.x) * node->cur_mix;
nuclear@21	563 v.y = v.y + (v1.y - v.y) * node->cur_mix;
nuclear@21	564 v.z = v.z + (v1.z - v.z) * node->cur_mix;
nuclear@21	565 }
nuclear@21	566
nuclear@0	567 return v;
nuclear@0	568 }
nuclear@0	569
nuclear@0	570 void anm_set_rotation(struct anm_node *node, quat_t rot, anm_time_t tm)
nuclear@0	571 {
nuclear@21	572 struct anm_animation *anim = anm_get_active_animation(node, 0);
nuclear@21	573 if(!anim) return;
nuclear@21	574
nuclear@21	575 anm_set_value(anim->tracks + ANM_TRACK_ROT_X, tm, rot.x);
nuclear@21	576 anm_set_value(anim->tracks + ANM_TRACK_ROT_Y, tm, rot.y);
nuclear@21	577 anm_set_value(anim->tracks + ANM_TRACK_ROT_Z, tm, rot.z);
nuclear@21	578 anm_set_value(anim->tracks + ANM_TRACK_ROT_W, tm, rot.w);
nuclear@0	579 invalidate_cache(node);
nuclear@0	580 }
nuclear@0	581
nuclear@21	582 static quat_t get_node_rotation(struct anm_node node, anm_time_t tm, struct anm_animation anim)
nuclear@0	583 {
nuclear@7	584 #ifndef ROT_USE_SLERP
nuclear@7	585 quat_t q;
nuclear@21	586 q.x = anm_get_value(anim->tracks + ANM_TRACK_ROT_X, tm);
nuclear@21	587 q.y = anm_get_value(anim->tracks + ANM_TRACK_ROT_Y, tm);
nuclear@21	588 q.z = anm_get_value(anim->tracks + ANM_TRACK_ROT_Z, tm);
nuclear@21	589 q.w = anm_get_value(anim->tracks + ANM_TRACK_ROT_W, tm);
nuclear@7	590 return q;
nuclear@7	591 #else
nuclear@0	592 int idx0, idx1, last_idx;
nuclear@0	593 anm_time_t tstart, tend;
nuclear@0	594 float t, dt;
nuclear@0	595 struct anm_track track_x, track_y, track_z, track_w;
nuclear@0	596 quat_t q, q1, q2;
nuclear@0	597
nuclear@21	598 track_x = anim->tracks + ANM_TRACK_ROT_X;
nuclear@21	599 track_y = anim->tracks + ANM_TRACK_ROT_Y;
nuclear@21	600 track_z = anim->tracks + ANM_TRACK_ROT_Z;
nuclear@21	601 track_w = anim->tracks + ANM_TRACK_ROT_W;
nuclear@0	602
nuclear@0	603 if(!track_x->count) {
nuclear@0	604 q.x = track_x->def_val;
nuclear@0	605 q.y = track_y->def_val;
nuclear@0	606 q.z = track_z->def_val;
nuclear@0	607 q.w = track_w->def_val;
nuclear@0	608 return q;
nuclear@0	609 }
nuclear@0	610
nuclear@0	611 last_idx = track_x->count - 1;
nuclear@0	612
nuclear@0	613 tstart = track_x->keys[0].time;
nuclear@0	614 tend = track_x->keys[last_idx].time;
nuclear@6	615
nuclear@6	616 if(tstart == tend) {
nuclear@6	617 q.x = track_x->keys[0].val;
nuclear@6	618 q.y = track_y->keys[0].val;
nuclear@6	619 q.z = track_z->keys[0].val;
nuclear@6	620 q.w = track_w->keys[0].val;
nuclear@6	621 return q;
nuclear@6	622 }
nuclear@6	623
nuclear@0	624 tm = anm_remap_time(track_x, tm, tstart, tend);
nuclear@0	625
nuclear@0	626 idx0 = anm_get_key_interval(track_x, tm);
nuclear@0	627 assert(idx0 >= 0 && idx0 < track_x->count);
nuclear@0	628 idx1 = idx0 + 1;
nuclear@0	629
nuclear@6	630 if(idx0 == last_idx) {
nuclear@6	631 q.x = track_x->keys[idx0].val;
nuclear@6	632 q.y = track_y->keys[idx0].val;
nuclear@6	633 q.z = track_z->keys[idx0].val;
nuclear@6	634 q.w = track_w->keys[idx0].val;
nuclear@6	635 return q;
nuclear@6	636 }
nuclear@6	637
nuclear@0	638 dt = (float)(track_x->keys[idx1].time - track_x->keys[idx0].time);
nuclear@0	639 t = (float)(tm - track_x->keys[idx0].time) / dt;
nuclear@0	640
nuclear@0	641 q1.x = track_x->keys[idx0].val;
nuclear@0	642 q1.y = track_y->keys[idx0].val;
nuclear@0	643 q1.z = track_z->keys[idx0].val;
nuclear@0	644 q1.w = track_w->keys[idx0].val;
nuclear@0	645
nuclear@0	646 q2.x = track_x->keys[idx1].val;
nuclear@0	647 q2.y = track_y->keys[idx1].val;
nuclear@0	648 q2.z = track_z->keys[idx1].val;
nuclear@0	649 q2.w = track_w->keys[idx1].val;
nuclear@0	650
nuclear@9	651 /*q1 = quat_normalize(q1);
nuclear@9	652 q2 = quat_normalize(q2);*/
nuclear@9	653
nuclear@0	654 return quat_slerp(q1, q2, t);
nuclear@7	655 #endif
nuclear@0	656 }
nuclear@0	657
nuclear@21	658 quat_t anm_get_node_rotation(struct anm_node *node, anm_time_t tm)
nuclear@21	659 {
nuclear@21	660 quat_t q;
nuclear@24	661 anm_time_t tm0 = animation_time(node, tm, 0);
nuclear@21	662 struct anm_animation *anim0 = anm_get_active_animation(node, 0);
nuclear@21	663 struct anm_animation *anim1 = anm_get_active_animation(node, 1);
nuclear@21	664
nuclear@21	665 if(!anim0) {
nuclear@21	666 return quat_identity();
nuclear@21	667 }
nuclear@21	668
nuclear@24	669 q = get_node_rotation(node, tm0, anim0);
nuclear@21	670
nuclear@21	671 if(anim1) {
nuclear@24	672 anm_time_t tm1 = animation_time(node, tm, 1);
nuclear@24	673 quat_t q1 = get_node_rotation(node, tm1, anim1);
nuclear@21	674
nuclear@21	675 q = quat_slerp(q, q1, node->cur_mix);
nuclear@21	676 }
nuclear@21	677 return q;
nuclear@21	678 }
nuclear@21	679
nuclear@0	680 void anm_set_scaling(struct anm_node *node, vec3_t scl, anm_time_t tm)
nuclear@0	681 {
nuclear@21	682 struct anm_animation *anim = anm_get_active_animation(node, 0);
nuclear@21	683 if(!anim) return;
nuclear@21	684
nuclear@21	685 anm_set_value(anim->tracks + ANM_TRACK_SCL_X, tm, scl.x);
nuclear@21	686 anm_set_value(anim->tracks + ANM_TRACK_SCL_Y, tm, scl.y);
nuclear@21	687 anm_set_value(anim->tracks + ANM_TRACK_SCL_Z, tm, scl.z);
nuclear@0	688 invalidate_cache(node);
nuclear@0	689 }
nuclear@0	690
nuclear@0	691 vec3_t anm_get_node_scaling(struct anm_node *node, anm_time_t tm)
nuclear@0	692 {
nuclear@0	693 vec3_t v;
nuclear@24	694 anm_time_t tm0 = animation_time(node, tm, 0);
nuclear@21	695 struct anm_animation *anim0 = anm_get_active_animation(node, 0);
nuclear@21	696 struct anm_animation *anim1 = anm_get_active_animation(node, 1);
nuclear@21	697
nuclear@21	698 if(!anim0) {
nuclear@21	699 return v3_cons(1, 1, 1);
nuclear@21	700 }
nuclear@21	701
nuclear@24	702 v.x = anm_get_value(anim0->tracks + ANM_TRACK_SCL_X, tm0);
nuclear@24	703 v.y = anm_get_value(anim0->tracks + ANM_TRACK_SCL_Y, tm0);
nuclear@24	704 v.z = anm_get_value(anim0->tracks + ANM_TRACK_SCL_Z, tm0);
nuclear@21	705
nuclear@21	706 if(anim1) {
nuclear@21	707 vec3_t v1;
nuclear@24	708 anm_time_t tm1 = animation_time(node, tm, 1);
nuclear@24	709 v1.x = anm_get_value(anim1->tracks + ANM_TRACK_SCL_X, tm1);
nuclear@24	710 v1.y = anm_get_value(anim1->tracks + ANM_TRACK_SCL_Y, tm1);
nuclear@24	711 v1.z = anm_get_value(anim1->tracks + ANM_TRACK_SCL_Z, tm1);
nuclear@21	712
nuclear@21	713 v.x = v.x + (v1.x - v.x) * node->cur_mix;
nuclear@21	714 v.y = v.y + (v1.y - v.y) * node->cur_mix;
nuclear@21	715 v.z = v.z + (v1.z - v.z) * node->cur_mix;
nuclear@21	716 }
nuclear@21	717
nuclear@0	718 return v;
nuclear@0	719 }
nuclear@0	720
nuclear@0	721
nuclear@0	722 vec3_t anm_get_position(struct anm_node *node, anm_time_t tm)
nuclear@0	723 {
nuclear@0	724 mat4_t xform;
nuclear@0	725 vec3_t pos = {0.0, 0.0, 0.0};
nuclear@0	726
nuclear@0	727 if(!node->parent) {
nuclear@0	728 return anm_get_node_position(node, tm);
nuclear@0	729 }
nuclear@0	730
nuclear@0	731 anm_get_matrix(node, xform, tm);
nuclear@0	732 return v3_transform(pos, xform);
nuclear@0	733 }
nuclear@0	734
nuclear@0	735 quat_t anm_get_rotation(struct anm_node *node, anm_time_t tm)
nuclear@0	736 {
nuclear@0	737 quat_t rot, prot;
nuclear@0	738 rot = anm_get_node_rotation(node, tm);
nuclear@0	739
nuclear@0	740 if(!node->parent) {
nuclear@0	741 return rot;
nuclear@0	742 }
nuclear@0	743
nuclear@0	744 prot = anm_get_rotation(node->parent, tm);
nuclear@0	745 return quat_mul(prot, rot);
nuclear@0	746 }
nuclear@0	747
nuclear@0	748 vec3_t anm_get_scaling(struct anm_node *node, anm_time_t tm)
nuclear@0	749 {
nuclear@0	750 vec3_t s, ps;
nuclear@0	751 s = anm_get_node_scaling(node, tm);
nuclear@0	752
nuclear@0	753 if(!node->parent) {
nuclear@0	754 return s;
nuclear@0	755 }
nuclear@0	756
nuclear@0	757 ps = anm_get_scaling(node->parent, tm);
nuclear@0	758 return v3_mul(s, ps);
nuclear@0	759 }
nuclear@0	760
nuclear@5	761 void anm_get_node_matrix(struct anm_node *node, mat4_t mat, anm_time_t tm)
nuclear@5	762 {
nuclear@9	763 int i;
nuclear@9	764 mat4_t rmat;
nuclear@5	765 vec3_t pos, scale;
nuclear@5	766 quat_t rot;
nuclear@5	767
nuclear@5	768 pos = anm_get_node_position(node, tm);
nuclear@5	769 rot = anm_get_node_rotation(node, tm);
nuclear@5	770 scale = anm_get_node_scaling(node, tm);
nuclear@5	771
nuclear@9	772 m4_set_translation(mat, node->pivot.x, node->pivot.y, node->pivot.z);
nuclear@5	773
nuclear@5	774 quat_to_mat4(rmat, rot);
nuclear@9	775 for(i=0; i<3; i++) {
nuclear@9	776 mat[i][0] = rmat[i][0];
nuclear@9	777 mat[i][1] = rmat[i][1];
nuclear@9	778 mat[i][2] = rmat[i][2];
nuclear@9	779 }
nuclear@9	780 /* this loop is equivalent to: m4_mult(mat, mat, rmat); */
nuclear@5	781
nuclear@9	782 mat[0][0] = scale.x; mat[0][1] = scale.y; mat[0][2] *= scale.z; mat[0][3] += pos.x;
nuclear@9	783 mat[1][0] = scale.x; mat[1][1] = scale.y; mat[1][2] *= scale.z; mat[1][3] += pos.y;
nuclear@9	784 mat[2][0] = scale.x; mat[2][1] = scale.y; mat[2][2] *= scale.z; mat[2][3] += pos.z;
nuclear@9	785
nuclear@9	786 m4_translate(mat, -node->pivot.x, -node->pivot.y, -node->pivot.z);
nuclear@9	787
nuclear@9	788 /* that's basically: pivot * rotation * translation * scaling * -pivot */
nuclear@5	789 }
nuclear@5	790
nuclear@5	791 void anm_get_node_inv_matrix(struct anm_node *node, mat4_t mat, anm_time_t tm)
nuclear@5	792 {
nuclear@5	793 mat4_t tmp;
nuclear@5	794 anm_get_node_matrix(node, tmp, tm);
nuclear@5	795 m4_inverse(mat, tmp);
nuclear@5	796 }
nuclear@5	797
nuclear@20	798 void anm_eval_node(struct anm_node *node, anm_time_t tm)
nuclear@20	799 {
nuclear@20	800 anm_get_node_matrix(node, node->matrix, tm);
nuclear@20	801 }
nuclear@20	802
nuclear@20	803 void anm_eval(struct anm_node *node, anm_time_t tm)
nuclear@20	804 {
nuclear@20	805 struct anm_node *c;
nuclear@20	806
nuclear@20	807 anm_eval_node(node, tm);
nuclear@20	808
nuclear@20	809 if(node->parent) {
nuclear@20	810 /* due to post-order traversal, the parent matrix is already evaluated */
nuclear@20	811 m4_mult(node->matrix, node->parent->matrix, node->matrix);
nuclear@20	812 }
nuclear@20	813
nuclear@20	814 /* recersively evaluate all children */
nuclear@20	815 c = node->child;
nuclear@20	816 while(c) {
nuclear@20	817 anm_eval(c, tm);
nuclear@20	818 c = c->next;
nuclear@20	819 }
nuclear@20	820 }
nuclear@20	821
nuclear@0	822 void anm_get_matrix(struct anm_node *node, mat4_t mat, anm_time_t tm)
nuclear@0	823 {
nuclear@0	824 struct mat_cache *cache = pthread_getspecific(node->cache_key);
nuclear@0	825 if(!cache) {
nuclear@0	826 cache = malloc(sizeof *cache);
nuclear@0	827 assert(cache);
nuclear@0	828
nuclear@0	829 pthread_mutex_lock(&node->cache_list_lock);
nuclear@0	830 cache->next = node->cache_list;
nuclear@0	831 node->cache_list = cache;
nuclear@0	832 pthread_mutex_unlock(&node->cache_list_lock);
nuclear@0	833
nuclear@0	834 cache->time = ANM_TIME_INVAL;
nuclear@2	835 cache->inv_time = ANM_TIME_INVAL;
nuclear@0	836 pthread_setspecific(node->cache_key, cache);
nuclear@0	837 }
nuclear@0	838
nuclear@0	839 if(cache->time != tm) {
nuclear@5	840 anm_get_node_matrix(node, cache->matrix, tm);
nuclear@0	841
nuclear@0	842 if(node->parent) {
nuclear@0	843 mat4_t parent_mat;
nuclear@0	844
nuclear@4	845 anm_get_matrix(node->parent, parent_mat, tm);
nuclear@0	846 m4_mult(cache->matrix, parent_mat, cache->matrix);
nuclear@0	847 }
nuclear@0	848 cache->time = tm;
nuclear@0	849 }
nuclear@0	850 m4_copy(mat, cache->matrix);
nuclear@0	851 }
nuclear@0	852
nuclear@0	853 void anm_get_inv_matrix(struct anm_node *node, mat4_t mat, anm_time_t tm)
nuclear@0	854 {
nuclear@0	855 struct mat_cache *cache = pthread_getspecific(node->cache_key);
nuclear@0	856 if(!cache) {
nuclear@0	857 cache = malloc(sizeof *cache);
nuclear@0	858 assert(cache);
nuclear@0	859
nuclear@0	860 pthread_mutex_lock(&node->cache_list_lock);
nuclear@0	861 cache->next = node->cache_list;
nuclear@0	862 node->cache_list = cache;
nuclear@0	863 pthread_mutex_unlock(&node->cache_list_lock);
nuclear@0	864
nuclear@0	865 cache->inv_time = ANM_TIME_INVAL;
nuclear@2	866 cache->inv_time = ANM_TIME_INVAL;
nuclear@0	867 pthread_setspecific(node->cache_key, cache);
nuclear@0	868 }
nuclear@0	869
nuclear@0	870 if(cache->inv_time != tm) {
nuclear@0	871 anm_get_matrix(node, mat, tm);
nuclear@0	872 m4_inverse(cache->inv_matrix, mat);
nuclear@0	873 cache->inv_time = tm;
nuclear@0	874 }
nuclear@0	875 m4_copy(mat, cache->inv_matrix);
nuclear@0	876 }
nuclear@0	877
nuclear@0	878 anm_time_t anm_get_start_time(struct anm_node *node)
nuclear@0	879 {
nuclear@21	880 int i, j;
nuclear@0	881 struct anm_node *c;
nuclear@0	882 anm_time_t res = LONG_MAX;
nuclear@0	883
nuclear@21	884 for(j=0; j<2; j++) {
nuclear@21	885 struct anm_animation *anim = anm_get_active_animation(node, j);
nuclear@21	886 if(!anim) break;
nuclear@21	887
nuclear@21	888 for(i=0; i<ANM_NUM_TRACKS; i++) {
nuclear@21	889 if(anim->tracks[i].count) {
nuclear@21	890 anm_time_t tm = anim->tracks[i].keys[0].time;
nuclear@21	891 if(tm < res) {
nuclear@21	892 res = tm;
nuclear@21	893 }
nuclear@0	894 }
nuclear@0	895 }
nuclear@0	896 }
nuclear@0	897
nuclear@0	898 c = node->child;
nuclear@0	899 while(c) {
nuclear@0	900 anm_time_t tm = anm_get_start_time(c);
nuclear@0	901 if(tm < res) {
nuclear@0	902 res = tm;
nuclear@0	903 }
nuclear@0	904 c = c->next;
nuclear@0	905 }
nuclear@0	906 return res;
nuclear@0	907 }
nuclear@0	908
nuclear@0	909 anm_time_t anm_get_end_time(struct anm_node *node)
nuclear@0	910 {
nuclear@21	911 int i, j;
nuclear@0	912 struct anm_node *c;
nuclear@0	913 anm_time_t res = LONG_MIN;
nuclear@0	914
nuclear@21	915 for(j=0; j<2; j++) {
nuclear@21	916 struct anm_animation *anim = anm_get_active_animation(node, j);
nuclear@21	917 if(!anim) break;
nuclear@21	918
nuclear@21	919 for(i=0; i<ANM_NUM_TRACKS; i++) {
nuclear@21	920 if(anim->tracks[i].count) {
nuclear@21	921 anm_time_t tm = anim->tracks[i].keys[anim->tracks[i].count - 1].time;
nuclear@21	922 if(tm > res) {
nuclear@21	923 res = tm;
nuclear@21	924 }
nuclear@0	925 }
nuclear@0	926 }
nuclear@0	927 }
nuclear@0	928
nuclear@0	929 c = node->child;
nuclear@0	930 while(c) {
nuclear@0	931 anm_time_t tm = anm_get_end_time(c);
nuclear@0	932 if(tm > res) {
nuclear@0	933 res = tm;
nuclear@0	934 }
nuclear@0	935 c = c->next;
nuclear@0	936 }
nuclear@0	937 return res;
nuclear@0	938 }
nuclear@0	939
nuclear@0	940 static void invalidate_cache(struct anm_node *node)
nuclear@0	941 {
nuclear@0	942 struct mat_cache *cache = pthread_getspecific(node->cache_key);
nuclear@0	943 if(cache) {
nuclear@13	944 cache->time = cache->inv_time = ANM_TIME_INVAL;
nuclear@0	945 }
nuclear@0	946 }