goat3d: libs/anim/anim.c annotate

goat3d

annotate libs/anim/anim.c @ 29:3d669155709d

- switched the unix build to use the internal vmath/anim as well - fixed a memory corruption issue which was caused by including the system-wide installed version of the anim.h header file - started the ass2goat assimp->goat3d converter

author	John Tsiombikas <nuclear@member.fsf.org>
date	Sun, 29 Sep 2013 21:53:03 +0300
parents
children	0ecb788a87f7

rev	line source
nuclear@27	1 #include <stdlib.h>
nuclear@27	2 #include <limits.h>
nuclear@27	3 #include <assert.h>
nuclear@27	4 #include "anim.h"
nuclear@27	5 #include "dynarr.h"
nuclear@27	6
nuclear@27	7 #define ROT_USE_SLERP
nuclear@27	8
nuclear@27	9 static void invalidate_cache(struct anm_node *node);
nuclear@27	10
nuclear@27	11 int anm_init_node(struct anm_node *node)
nuclear@27	12 {
nuclear@27	13 int i, j;
nuclear@27	14 static const float defaults[] = {
nuclear@27	15 0.0f, 0.0f, 0.0f, /* default position */
nuclear@27	16 0.0f, 0.0f, 0.0f, 1.0f, /* default rotation quat */
nuclear@27	17 1.0f, 1.0f, 1.0f /* default scale factor */
nuclear@27	18 };
nuclear@27	19
nuclear@27	20 memset(node, 0, sizeof *node);
nuclear@27	21
nuclear@27	22 for(i=0; i<ANM_NUM_TRACKS; i++) {
nuclear@27	23 if(anm_init_track(node->tracks + i) == -1) {
nuclear@27	24 for(j=0; j<i; j++) {
nuclear@27	25 anm_destroy_track(node->tracks + i);
nuclear@27	26 }
nuclear@27	27 }
nuclear@27	28 anm_set_track_default(node->tracks + i, defaults[i]);
nuclear@27	29 }
nuclear@27	30
nuclear@27	31 node->cache.time = ANM_TIME_INVAL;
nuclear@27	32 node->cache.inv_time = ANM_TIME_INVAL;
nuclear@27	33 return 0;
nuclear@27	34 }
nuclear@27	35
nuclear@27	36 void anm_destroy_node(struct anm_node *node)
nuclear@27	37 {
nuclear@27	38 int i;
nuclear@27	39 free(node->name);
nuclear@27	40
nuclear@27	41 for(i=0; i<ANM_NUM_TRACKS; i++) {
nuclear@27	42 anm_destroy_track(node->tracks + i);
nuclear@27	43 }
nuclear@27	44 }
nuclear@27	45
nuclear@27	46 void anm_destroy_node_tree(struct anm_node *tree)
nuclear@27	47 {
nuclear@27	48 struct anm_node c, tmp;
nuclear@27	49
nuclear@27	50 if(!tree) return;
nuclear@27	51
nuclear@27	52 c = tree->child;
nuclear@27	53 while(c) {
nuclear@27	54 tmp = c;
nuclear@27	55 c = c->next;
nuclear@27	56
nuclear@27	57 anm_destroy_node_tree(tmp);
nuclear@27	58 }
nuclear@27	59 anm_destroy_node(tree);
nuclear@27	60 }
nuclear@27	61
nuclear@27	62 struct anm_node *anm_create_node(void)
nuclear@27	63 {
nuclear@27	64 struct anm_node *n;
nuclear@27	65
nuclear@27	66 if((n = malloc(sizeof *n))) {
nuclear@27	67 if(anm_init_node(n) == -1) {
nuclear@27	68 free(n);
nuclear@27	69 return 0;
nuclear@27	70 }
nuclear@27	71 }
nuclear@27	72 return n;
nuclear@27	73 }
nuclear@27	74
nuclear@27	75 void anm_free_node(struct anm_node *node)
nuclear@27	76 {
nuclear@27	77 anm_destroy_node(node);
nuclear@27	78 free(node);
nuclear@27	79 }
nuclear@27	80
nuclear@27	81 void anm_free_node_tree(struct anm_node *tree)
nuclear@27	82 {
nuclear@27	83 struct anm_node c, tmp;
nuclear@27	84
nuclear@27	85 if(!tree) return;
nuclear@27	86
nuclear@27	87 c = tree->child;
nuclear@27	88 while(c) {
nuclear@27	89 tmp = c;
nuclear@27	90 c = c->next;
nuclear@27	91
nuclear@27	92 anm_free_node_tree(tmp);
nuclear@27	93 }
nuclear@27	94
nuclear@27	95 anm_free_node(tree);
nuclear@27	96 }
nuclear@27	97
nuclear@27	98 int anm_set_node_name(struct anm_node node, const char name)
nuclear@27	99 {
nuclear@27	100 char *str;
nuclear@27	101
nuclear@27	102 if(!(str = malloc(strlen(name) + 1))) {
nuclear@27	103 return -1;
nuclear@27	104 }
nuclear@27	105 strcpy(str, name);
nuclear@27	106 free(node->name);
nuclear@27	107 node->name = str;
nuclear@27	108 return 0;
nuclear@27	109 }
nuclear@27	110
nuclear@27	111 const char anm_get_node_name(struct anm_node node)
nuclear@27	112 {
nuclear@27	113 return node->name ? node->name : "";
nuclear@27	114 }
nuclear@27	115
nuclear@27	116 void anm_set_interpolator(struct anm_node *node, enum anm_interpolator in)
nuclear@27	117 {
nuclear@27	118 int i;
nuclear@27	119
nuclear@27	120 for(i=0; i<ANM_NUM_TRACKS; i++) {
nuclear@27	121 anm_set_track_interpolator(node->tracks + i, in);
nuclear@27	122 }
nuclear@27	123 invalidate_cache(node);
nuclear@27	124 }
nuclear@27	125
nuclear@27	126 void anm_set_extrapolator(struct anm_node *node, enum anm_extrapolator ex)
nuclear@27	127 {
nuclear@27	128 int i;
nuclear@27	129
nuclear@27	130 for(i=0; i<ANM_NUM_TRACKS; i++) {
nuclear@27	131 anm_set_track_extrapolator(node->tracks + i, ex);
nuclear@27	132 }
nuclear@27	133 invalidate_cache(node);
nuclear@27	134 }
nuclear@27	135
nuclear@27	136 void anm_link_node(struct anm_node p, struct anm_node c)
nuclear@27	137 {
nuclear@27	138 c->next = p->child;
nuclear@27	139 p->child = c;
nuclear@27	140
nuclear@27	141 c->parent = p;
nuclear@27	142 invalidate_cache(c);
nuclear@27	143 }
nuclear@27	144
nuclear@27	145 int anm_unlink_node(struct anm_node p, struct anm_node c)
nuclear@27	146 {
nuclear@27	147 struct anm_node *iter;
nuclear@27	148
nuclear@27	149 if(p->child == c) {
nuclear@27	150 p->child = c->next;
nuclear@27	151 c->next = 0;
nuclear@27	152 invalidate_cache(c);
nuclear@27	153 return 0;
nuclear@27	154 }
nuclear@27	155
nuclear@27	156 iter = p->child;
nuclear@27	157 while(iter->next) {
nuclear@27	158 if(iter->next == c) {
nuclear@27	159 iter->next = c->next;
nuclear@27	160 c->next = 0;
nuclear@27	161 invalidate_cache(c);
nuclear@27	162 return 0;
nuclear@27	163 }
nuclear@27	164 }
nuclear@27	165 return -1;
nuclear@27	166 }
nuclear@27	167
nuclear@27	168 void anm_set_position(struct anm_node *node, vec3_t pos, anm_time_t tm)
nuclear@27	169 {
nuclear@27	170 anm_set_value(node->tracks + ANM_TRACK_POS_X, tm, pos.x);
nuclear@27	171 anm_set_value(node->tracks + ANM_TRACK_POS_Y, tm, pos.y);
nuclear@27	172 anm_set_value(node->tracks + ANM_TRACK_POS_Z, tm, pos.z);
nuclear@27	173 invalidate_cache(node);
nuclear@27	174 }
nuclear@27	175
nuclear@27	176 vec3_t anm_get_node_position(struct anm_node *node, anm_time_t tm)
nuclear@27	177 {
nuclear@27	178 vec3_t v;
nuclear@27	179 v.x = anm_get_value(node->tracks + ANM_TRACK_POS_X, tm);
nuclear@27	180 v.y = anm_get_value(node->tracks + ANM_TRACK_POS_Y, tm);
nuclear@27	181 v.z = anm_get_value(node->tracks + ANM_TRACK_POS_Z, tm);
nuclear@27	182 return v;
nuclear@27	183 }
nuclear@27	184
nuclear@27	185 void anm_set_rotation(struct anm_node *node, quat_t rot, anm_time_t tm)
nuclear@27	186 {
nuclear@27	187 anm_set_value(node->tracks + ANM_TRACK_ROT_X, tm, rot.x);
nuclear@27	188 anm_set_value(node->tracks + ANM_TRACK_ROT_Y, tm, rot.y);
nuclear@27	189 anm_set_value(node->tracks + ANM_TRACK_ROT_Z, tm, rot.z);
nuclear@27	190 anm_set_value(node->tracks + ANM_TRACK_ROT_W, tm, rot.w);
nuclear@27	191 invalidate_cache(node);
nuclear@27	192 }
nuclear@27	193
nuclear@27	194 quat_t anm_get_node_rotation(struct anm_node *node, anm_time_t tm)
nuclear@27	195 {
nuclear@27	196 #ifndef ROT_USE_SLERP
nuclear@27	197 quat_t q;
nuclear@27	198 q.x = anm_get_value(node->tracks + ANM_TRACK_ROT_X, tm);
nuclear@27	199 q.y = anm_get_value(node->tracks + ANM_TRACK_ROT_Y, tm);
nuclear@27	200 q.z = anm_get_value(node->tracks + ANM_TRACK_ROT_Z, tm);
nuclear@27	201 q.w = anm_get_value(node->tracks + ANM_TRACK_ROT_W, tm);
nuclear@27	202 return q;
nuclear@27	203 #else
nuclear@27	204 int idx0, idx1, last_idx;
nuclear@27	205 anm_time_t tstart, tend;
nuclear@27	206 float t, dt;
nuclear@27	207 struct anm_track track_x, track_y, track_z, track_w;
nuclear@27	208 quat_t q, q1, q2;
nuclear@27	209
nuclear@27	210 track_x = node->tracks + ANM_TRACK_ROT_X;
nuclear@27	211 track_y = node->tracks + ANM_TRACK_ROT_Y;
nuclear@27	212 track_z = node->tracks + ANM_TRACK_ROT_Z;
nuclear@27	213 track_w = node->tracks + ANM_TRACK_ROT_W;
nuclear@27	214
nuclear@27	215 if(!track_x->count) {
nuclear@27	216 q.x = track_x->def_val;
nuclear@27	217 q.y = track_y->def_val;
nuclear@27	218 q.z = track_z->def_val;
nuclear@27	219 q.w = track_w->def_val;
nuclear@27	220 return q;
nuclear@27	221 }
nuclear@27	222
nuclear@27	223 last_idx = track_x->count - 1;
nuclear@27	224
nuclear@27	225 tstart = track_x->keys[0].time;
nuclear@27	226 tend = track_x->keys[last_idx].time;
nuclear@27	227
nuclear@27	228 if(tstart == tend) {
nuclear@27	229 q.x = track_x->keys[0].val;
nuclear@27	230 q.y = track_y->keys[0].val;
nuclear@27	231 q.z = track_z->keys[0].val;
nuclear@27	232 q.w = track_w->keys[0].val;
nuclear@27	233 return q;
nuclear@27	234 }
nuclear@27	235
nuclear@27	236 tm = anm_remap_time(track_x, tm, tstart, tend);
nuclear@27	237
nuclear@27	238 idx0 = anm_get_key_interval(track_x, tm);
nuclear@27	239 assert(idx0 >= 0 && idx0 < track_x->count);
nuclear@27	240 idx1 = idx0 + 1;
nuclear@27	241
nuclear@27	242 if(idx0 == last_idx) {
nuclear@27	243 q.x = track_x->keys[idx0].val;
nuclear@27	244 q.y = track_y->keys[idx0].val;
nuclear@27	245 q.z = track_z->keys[idx0].val;
nuclear@27	246 q.w = track_w->keys[idx0].val;
nuclear@27	247 return q;
nuclear@27	248 }
nuclear@27	249
nuclear@27	250 dt = (float)(track_x->keys[idx1].time - track_x->keys[idx0].time);
nuclear@27	251 t = (float)(tm - track_x->keys[idx0].time) / dt;
nuclear@27	252
nuclear@27	253 q1.x = track_x->keys[idx0].val;
nuclear@27	254 q1.y = track_y->keys[idx0].val;
nuclear@27	255 q1.z = track_z->keys[idx0].val;
nuclear@27	256 q1.w = track_w->keys[idx0].val;
nuclear@27	257
nuclear@27	258 q2.x = track_x->keys[idx1].val;
nuclear@27	259 q2.y = track_y->keys[idx1].val;
nuclear@27	260 q2.z = track_z->keys[idx1].val;
nuclear@27	261 q2.w = track_w->keys[idx1].val;
nuclear@27	262
nuclear@27	263 /*q1 = quat_normalize(q1);
nuclear@27	264 q2 = quat_normalize(q2);*/
nuclear@27	265
nuclear@27	266 return quat_slerp(q1, q2, t);
nuclear@27	267 #endif
nuclear@27	268 }
nuclear@27	269
nuclear@27	270 void anm_set_scaling(struct anm_node *node, vec3_t scl, anm_time_t tm)
nuclear@27	271 {
nuclear@27	272 anm_set_value(node->tracks + ANM_TRACK_SCL_X, tm, scl.x);
nuclear@27	273 anm_set_value(node->tracks + ANM_TRACK_SCL_Y, tm, scl.y);
nuclear@27	274 anm_set_value(node->tracks + ANM_TRACK_SCL_Z, tm, scl.z);
nuclear@27	275 invalidate_cache(node);
nuclear@27	276 }
nuclear@27	277
nuclear@27	278 vec3_t anm_get_node_scaling(struct anm_node *node, anm_time_t tm)
nuclear@27	279 {
nuclear@27	280 vec3_t v;
nuclear@27	281 v.x = anm_get_value(node->tracks + ANM_TRACK_SCL_X, tm);
nuclear@27	282 v.y = anm_get_value(node->tracks + ANM_TRACK_SCL_Y, tm);
nuclear@27	283 v.z = anm_get_value(node->tracks + ANM_TRACK_SCL_Z, tm);
nuclear@27	284 return v;
nuclear@27	285 }
nuclear@27	286
nuclear@27	287
nuclear@27	288 vec3_t anm_get_position(struct anm_node *node, anm_time_t tm)
nuclear@27	289 {
nuclear@27	290 mat4_t xform;
nuclear@27	291 vec3_t pos = {0.0, 0.0, 0.0};
nuclear@27	292
nuclear@27	293 if(!node->parent) {
nuclear@27	294 return anm_get_node_position(node, tm);
nuclear@27	295 }
nuclear@27	296
nuclear@27	297 anm_get_matrix(node, xform, tm);
nuclear@27	298 return v3_transform(pos, xform);
nuclear@27	299 }
nuclear@27	300
nuclear@27	301 quat_t anm_get_rotation(struct anm_node *node, anm_time_t tm)
nuclear@27	302 {
nuclear@27	303 quat_t rot, prot;
nuclear@27	304 rot = anm_get_node_rotation(node, tm);
nuclear@27	305
nuclear@27	306 if(!node->parent) {
nuclear@27	307 return rot;
nuclear@27	308 }
nuclear@27	309
nuclear@27	310 prot = anm_get_rotation(node->parent, tm);
nuclear@27	311 return quat_mul(prot, rot);
nuclear@27	312 }
nuclear@27	313
nuclear@27	314 vec3_t anm_get_scaling(struct anm_node *node, anm_time_t tm)
nuclear@27	315 {
nuclear@27	316 vec3_t s, ps;
nuclear@27	317 s = anm_get_node_scaling(node, tm);
nuclear@27	318
nuclear@27	319 if(!node->parent) {
nuclear@27	320 return s;
nuclear@27	321 }
nuclear@27	322
nuclear@27	323 ps = anm_get_scaling(node->parent, tm);
nuclear@27	324 return v3_mul(s, ps);
nuclear@27	325 }
nuclear@27	326
nuclear@27	327 void anm_set_pivot(struct anm_node *node, vec3_t piv)
nuclear@27	328 {
nuclear@27	329 node->pivot = piv;
nuclear@27	330 }
nuclear@27	331
nuclear@27	332 vec3_t anm_get_pivot(struct anm_node *node)
nuclear@27	333 {
nuclear@27	334 return node->pivot;
nuclear@27	335 }
nuclear@27	336
nuclear@27	337 void anm_get_node_matrix(struct anm_node *node, mat4_t mat, anm_time_t tm)
nuclear@27	338 {
nuclear@27	339 int i;
nuclear@27	340 mat4_t rmat;
nuclear@27	341 vec3_t pos, scale;
nuclear@27	342 quat_t rot;
nuclear@27	343
nuclear@27	344 pos = anm_get_node_position(node, tm);
nuclear@27	345 rot = anm_get_node_rotation(node, tm);
nuclear@27	346 scale = anm_get_node_scaling(node, tm);
nuclear@27	347
nuclear@27	348 m4_set_translation(mat, node->pivot.x, node->pivot.y, node->pivot.z);
nuclear@27	349
nuclear@27	350 quat_to_mat4(rmat, rot);
nuclear@27	351 for(i=0; i<3; i++) {
nuclear@27	352 mat[i][0] = rmat[i][0];
nuclear@27	353 mat[i][1] = rmat[i][1];
nuclear@27	354 mat[i][2] = rmat[i][2];
nuclear@27	355 }
nuclear@27	356 /* this loop is equivalent to: m4_mult(mat, mat, rmat); */
nuclear@27	357
nuclear@27	358 mat[0][0] = scale.x; mat[0][1] = scale.y; mat[0][2] *= scale.z; mat[0][3] += pos.x;
nuclear@27	359 mat[1][0] = scale.x; mat[1][1] = scale.y; mat[1][2] *= scale.z; mat[1][3] += pos.y;
nuclear@27	360 mat[2][0] = scale.x; mat[2][1] = scale.y; mat[2][2] *= scale.z; mat[2][3] += pos.z;
nuclear@27	361
nuclear@27	362 m4_translate(mat, -node->pivot.x, -node->pivot.y, -node->pivot.z);
nuclear@27	363
nuclear@27	364 /* that's basically: pivot * rotation * translation * scaling * -pivot */
nuclear@27	365 }
nuclear@27	366
nuclear@27	367 void anm_get_node_inv_matrix(struct anm_node *node, mat4_t mat, anm_time_t tm)
nuclear@27	368 {
nuclear@27	369 mat4_t tmp;
nuclear@27	370 anm_get_node_matrix(node, tmp, tm);
nuclear@27	371 m4_inverse(mat, tmp);
nuclear@27	372 }
nuclear@27	373
nuclear@27	374 void anm_get_matrix(struct anm_node *node, mat4_t mat, anm_time_t tm)
nuclear@27	375 {
nuclear@27	376 if(node->cache.time != tm) {
nuclear@27	377 anm_get_node_matrix(node, node->cache.matrix, tm);
nuclear@27	378
nuclear@27	379 if(node->parent) {
nuclear@27	380 mat4_t parent_mat;
nuclear@27	381
nuclear@27	382 anm_get_matrix(node->parent, parent_mat, tm);
nuclear@27	383 m4_mult(node->cache.matrix, parent_mat, node->cache.matrix);
nuclear@27	384 }
nuclear@27	385 node->cache.time = tm;
nuclear@27	386 }
nuclear@27	387 m4_copy(mat, node->cache.matrix);
nuclear@27	388 }
nuclear@27	389
nuclear@27	390 void anm_get_inv_matrix(struct anm_node *node, mat4_t mat, anm_time_t tm)
nuclear@27	391 {
nuclear@27	392 if(node->cache.inv_time != tm) {
nuclear@27	393 anm_get_matrix(node, mat, tm);
nuclear@27	394 m4_inverse(node->cache.inv_matrix, mat);
nuclear@27	395 node->cache.inv_time = tm;
nuclear@27	396 }
nuclear@27	397 m4_copy(mat, node->cache.inv_matrix);
nuclear@27	398 }
nuclear@27	399
nuclear@27	400 anm_time_t anm_get_start_time(struct anm_node *node)
nuclear@27	401 {
nuclear@27	402 int i;
nuclear@27	403 struct anm_node *c;
nuclear@27	404 anm_time_t res = LONG_MAX;
nuclear@27	405
nuclear@27	406 for(i=0; i<ANM_NUM_TRACKS; i++) {
nuclear@27	407 if(node->tracks[i].count) {
nuclear@27	408 anm_time_t tm = node->tracks[i].keys[0].time;
nuclear@27	409 if(tm < res) {
nuclear@27	410 res = tm;
nuclear@27	411 }
nuclear@27	412 }
nuclear@27	413 }
nuclear@27	414
nuclear@27	415 c = node->child;
nuclear@27	416 while(c) {
nuclear@27	417 anm_time_t tm = anm_get_start_time(c);
nuclear@27	418 if(tm < res) {
nuclear@27	419 res = tm;
nuclear@27	420 }
nuclear@27	421 c = c->next;
nuclear@27	422 }
nuclear@27	423 return res;
nuclear@27	424 }
nuclear@27	425
nuclear@27	426 anm_time_t anm_get_end_time(struct anm_node *node)
nuclear@27	427 {
nuclear@27	428 int i;
nuclear@27	429 struct anm_node *c;
nuclear@27	430 anm_time_t res = LONG_MIN;
nuclear@27	431
nuclear@27	432 for(i=0; i<ANM_NUM_TRACKS; i++) {
nuclear@27	433 if(node->tracks[i].count) {
nuclear@27	434 anm_time_t tm = node->tracks[i].keys[node->tracks[i].count - 1].time;
nuclear@27	435 if(tm > res) {
nuclear@27	436 res = tm;
nuclear@27	437 }
nuclear@27	438 }
nuclear@27	439 }
nuclear@27	440
nuclear@27	441 c = node->child;
nuclear@27	442 while(c) {
nuclear@27	443 anm_time_t tm = anm_get_end_time(c);
nuclear@27	444 if(tm > res) {
nuclear@27	445 res = tm;
nuclear@27	446 }
nuclear@27	447 c = c->next;
nuclear@27	448 }
nuclear@27	449 return res;
nuclear@27	450 }
nuclear@27	451
nuclear@27	452 static void invalidate_cache(struct anm_node *node)
nuclear@27	453 {
nuclear@27	454 node->cache.time = node->cache.inv_time = ANM_TIME_INVAL;
nuclear@27	455 }