ld33_umonster: src/meshgen.cc annotate

ld33_umonster

annotate src/meshgen.cc @ 4:7b1fa527b51b

added torus mesh gen

author	John Tsiombikas <nuclear@member.fsf.org>
date	Sun, 23 Aug 2015 04:31:29 +0300
parents	35349df5392d
children	1b30bd381667

rev	line source
nuclear@0	1 #include <stdio.h>
nuclear@0	2 #include "meshgen.h"
nuclear@0	3 #include "mesh.h"
nuclear@0	4
nuclear@0	5 // -------- sphere --------
nuclear@0	6
nuclear@0	7 #define SURAD(u) ((u) * 2.0 * M_PI)
nuclear@0	8 #define SVRAD(v) ((v) * M_PI)
nuclear@0	9
nuclear@0	10 static Vector3 sphvec(float theta, float phi)
nuclear@0	11 {
nuclear@0	12 return Vector3(sin(theta) * sin(phi),
nuclear@0	13 cos(phi),
nuclear@0	14 cos(theta) * sin(phi));
nuclear@0	15 }
nuclear@0	16
nuclear@0	17 void gen_sphere(Mesh *mesh, float rad, int usub, int vsub, float urange, float vrange)
nuclear@0	18 {
nuclear@0	19 if(usub < 4) usub = 4;
nuclear@0	20 if(vsub < 2) vsub = 2;
nuclear@0	21
nuclear@0	22 int uverts = usub + 1;
nuclear@0	23 int vverts = vsub + 1;
nuclear@0	24
nuclear@0	25 int num_verts = uverts * vverts;
nuclear@0	26 int num_quads = usub * vsub;
nuclear@0	27 int num_tri = num_quads * 2;
nuclear@0	28
nuclear@0	29 mesh->clear();
nuclear@0	30 Vector3 varr = (Vector3)mesh->set_attrib_data(MESH_ATTR_VERTEX, 3, num_verts, 0);
nuclear@0	31 Vector3 narr = (Vector3)mesh->set_attrib_data(MESH_ATTR_NORMAL, 3, num_verts, 0);
nuclear@0	32 Vector3 tarr = (Vector3)mesh->set_attrib_data(MESH_ATTR_TANGENT, 3, num_verts, 0);
nuclear@0	33 Vector2 uvarr = (Vector2)mesh->set_attrib_data(MESH_ATTR_TEXCOORD, 2, num_verts, 0);
nuclear@0	34 unsigned int idxarr = mesh->set_index_data(num_tri 3, 0);
nuclear@0	35
nuclear@0	36 float du = urange / (float)(uverts - 1);
nuclear@0	37 float dv = vrange / (float)(vverts - 1);
nuclear@0	38
nuclear@0	39 float u = 0.0;
nuclear@0	40 for(int i=0; i<uverts; i++) {
nuclear@4	41 float theta = u * 2.0 * M_PI;
nuclear@0	42
nuclear@0	43 float v = 0.0;
nuclear@0	44 for(int j=0; j<vverts; j++) {
nuclear@4	45 float phi = v * M_PI;
nuclear@0	46
nuclear@0	47 Vector3 pos = sphvec(theta, phi);
nuclear@0	48
nuclear@0	49 varr++ = pos rad;
nuclear@0	50 *narr++ = pos;
nuclear@0	51 *tarr++ = (sphvec(theta + 0.1f, (float)M_PI / 2.0f) - sphvec(theta - 0.1f, (float)M_PI / 2.0f)).normalized();
nuclear@0	52 uvarr++ = Vector2(u urange, v * vrange);
nuclear@0	53
nuclear@0	54 if(i < usub && j < vsub) {
nuclear@0	55 int idx = i * vverts + j;
nuclear@0	56 *idxarr++ = idx;
nuclear@0	57 *idxarr++ = idx + 1;
nuclear@0	58 *idxarr++ = idx + vverts + 1;
nuclear@0	59
nuclear@0	60 *idxarr++ = idx;
nuclear@0	61 *idxarr++ = idx + vverts + 1;
nuclear@0	62 *idxarr++ = idx + vverts;
nuclear@0	63 }
nuclear@0	64
nuclear@0	65 v += dv;
nuclear@0	66 }
nuclear@0	67 u += du;
nuclear@0	68 }
nuclear@0	69 }
nuclear@0	70
nuclear@4	71 // -------- torus -----------
nuclear@4	72 static Vector3 torusvec(float theta, float phi, float mr, float rr)
nuclear@4	73 {
nuclear@4	74 theta = -theta;
nuclear@4	75
nuclear@4	76 float rx = -cos(phi) * rr + mr;
nuclear@4	77 float ry = sin(phi) * rr;
nuclear@4	78 float rz = 0.0;
nuclear@4	79
nuclear@4	80 float x = rx * sin(theta) + rz * cos(theta);
nuclear@4	81 float y = ry;
nuclear@4	82 float z = -rx * cos(theta) + rz * sin(theta);
nuclear@4	83
nuclear@4	84 return Vector3(x, y, z);
nuclear@4	85 }
nuclear@4	86
nuclear@4	87 void gen_torus(Mesh *mesh, float mainrad, float ringrad, int usub, int vsub, float urange, float vrange)
nuclear@4	88 {
nuclear@4	89 if(usub < 4) usub = 4;
nuclear@4	90 if(vsub < 2) vsub = 2;
nuclear@4	91
nuclear@4	92 int uverts = usub + 1;
nuclear@4	93 int vverts = vsub + 1;
nuclear@4	94
nuclear@4	95 int num_verts = uverts * vverts;
nuclear@4	96 int num_quads = usub * vsub;
nuclear@4	97 int num_tri = num_quads * 2;
nuclear@4	98
nuclear@4	99 mesh->clear();
nuclear@4	100 Vector3 varr = (Vector3)mesh->set_attrib_data(MESH_ATTR_VERTEX, 3, num_verts, 0);
nuclear@4	101 Vector3 narr = (Vector3)mesh->set_attrib_data(MESH_ATTR_NORMAL, 3, num_verts, 0);
nuclear@4	102 Vector3 tarr = (Vector3)mesh->set_attrib_data(MESH_ATTR_TANGENT, 3, num_verts, 0);
nuclear@4	103 Vector2 uvarr = (Vector2)mesh->set_attrib_data(MESH_ATTR_TEXCOORD, 2, num_verts, 0);
nuclear@4	104 unsigned int idxarr = mesh->set_index_data(num_tri 3, 0);
nuclear@4	105
nuclear@4	106 float du = urange / (float)(uverts - 1);
nuclear@4	107 float dv = vrange / (float)(vverts - 1);
nuclear@4	108
nuclear@4	109 float u = 0.0;
nuclear@4	110 for(int i=0; i<uverts; i++) {
nuclear@4	111 float theta = u * 2.0 * M_PI;
nuclear@4	112
nuclear@4	113 float v = 0.0;
nuclear@4	114 for(int j=0; j<vverts; j++) {
nuclear@4	115 float phi = v * 2.0 * M_PI;
nuclear@4	116
nuclear@4	117 Vector3 pos = torusvec(theta, phi, mainrad, ringrad);
nuclear@4	118 Vector3 cent = torusvec(theta, phi, mainrad, 0.0);
nuclear@4	119
nuclear@4	120 *varr++ = pos;
nuclear@4	121 *narr++ = (pos - cent) / ringrad;
nuclear@4	122
nuclear@4	123 Vector3 pprev = torusvec(theta - 0.1f, phi, mainrad, ringrad);
nuclear@4	124 Vector3 pnext = torusvec(theta + 0.1f, phi, mainrad, ringrad);
nuclear@4	125
nuclear@4	126 *tarr++ = (pnext - pprev).normalized();
nuclear@4	127 uvarr++ = Vector2(u urange, v * vrange);
nuclear@4	128
nuclear@4	129 if(i < usub && j < vsub) {
nuclear@4	130 int idx = i * vverts + j;
nuclear@4	131 *idxarr++ = idx;
nuclear@4	132 *idxarr++ = idx + 1;
nuclear@4	133 *idxarr++ = idx + vverts + 1;
nuclear@4	134
nuclear@4	135 *idxarr++ = idx;
nuclear@4	136 *idxarr++ = idx + vverts + 1;
nuclear@4	137 *idxarr++ = idx + vverts;
nuclear@4	138 }
nuclear@4	139
nuclear@4	140 v += dv;
nuclear@4	141 }
nuclear@4	142 u += du;
nuclear@4	143 }
nuclear@4	144 }
nuclear@4	145
nuclear@0	146
nuclear@0	147 // -------- cylinder --------
nuclear@0	148
nuclear@0	149 static Vector3 cylvec(float theta, float height)
nuclear@0	150 {
nuclear@0	151 return Vector3(sin(theta), height, cos(theta));
nuclear@0	152 }
nuclear@0	153
nuclear@0	154 void gen_cylinder(Mesh *mesh, float rad, float height, int usub, int vsub, int capsub, float urange, float vrange)
nuclear@0	155 {
nuclear@0	156 if(usub < 4) usub = 4;
nuclear@0	157 if(vsub < 1) vsub = 1;
nuclear@0	158
nuclear@0	159 int uverts = usub + 1;
nuclear@0	160 int vverts = vsub + 1;
nuclear@0	161
nuclear@0	162 int num_body_verts = uverts * vverts;
nuclear@0	163 int num_body_quads = usub * vsub;
nuclear@0	164 int num_body_tri = num_body_quads * 2;
nuclear@0	165
nuclear@0	166 int capvverts = capsub ? capsub + 1 : 0;
nuclear@0	167 int num_cap_verts = uverts * capvverts;
nuclear@0	168 int num_cap_quads = usub * capsub;
nuclear@0	169 int num_cap_tri = num_cap_quads * 2;
nuclear@0	170
nuclear@0	171 int num_verts = num_body_verts + num_cap_verts * 2;
nuclear@0	172 int num_tri = num_body_tri + num_cap_tri * 2;
nuclear@0	173
nuclear@0	174 mesh->clear();
nuclear@0	175 Vector3 varr = (Vector3)mesh->set_attrib_data(MESH_ATTR_VERTEX, 3, num_verts, 0);
nuclear@0	176 Vector3 narr = (Vector3)mesh->set_attrib_data(MESH_ATTR_NORMAL, 3, num_verts, 0);
nuclear@0	177 Vector3 tarr = (Vector3)mesh->set_attrib_data(MESH_ATTR_TANGENT, 3, num_verts, 0);
nuclear@0	178 Vector2 uvarr = (Vector2)mesh->set_attrib_data(MESH_ATTR_TEXCOORD, 2, num_verts, 0);
nuclear@0	179 unsigned int idxarr = mesh->set_index_data(num_tri 3, 0);
nuclear@0	180
nuclear@0	181 float du = urange / (float)(uverts - 1);
nuclear@0	182 float dv = vrange / (float)(vverts - 1);
nuclear@0	183
nuclear@0	184 float u = 0.0;
nuclear@0	185 for(int i=0; i<uverts; i++) {
nuclear@0	186 float theta = SURAD(u);
nuclear@0	187
nuclear@0	188 float v = 0.0;
nuclear@0	189 for(int j=0; j<vverts; j++) {
nuclear@0	190 float y = (v - 0.5) * height;
nuclear@0	191 Vector3 pos = cylvec(theta, y);
nuclear@0	192
nuclear@0	193 varr++ = Vector3(pos.x rad, pos.y, pos.z * rad);
nuclear@0	194 *narr++ = Vector3(pos.x, 0.0, pos.z);
nuclear@0	195 *tarr++ = (cylvec(theta + 0.1, 0.0) - cylvec(theta - 0.1, 0.0)).normalized();
nuclear@0	196 uvarr++ = Vector2(u urange, v * vrange);
nuclear@0	197
nuclear@0	198 if(i < usub && j < vsub) {
nuclear@0	199 int idx = i * vverts + j;
nuclear@0	200
nuclear@0	201 *idxarr++ = idx;
nuclear@0	202 *idxarr++ = idx + vverts + 1;
nuclear@0	203 *idxarr++ = idx + 1;
nuclear@0	204
nuclear@0	205 *idxarr++ = idx;
nuclear@0	206 *idxarr++ = idx + vverts;
nuclear@0	207 *idxarr++ = idx + vverts + 1;
nuclear@0	208 }
nuclear@0	209
nuclear@0	210 v += dv;
nuclear@0	211 }
nuclear@0	212 u += du;
nuclear@0	213 }
nuclear@0	214
nuclear@0	215
nuclear@0	216 // now the cap!
nuclear@0	217 if(!capsub) {
nuclear@0	218 return;
nuclear@0	219 }
nuclear@0	220
nuclear@0	221 dv = 1.0 / (float)(capvverts - 1);
nuclear@0	222
nuclear@0	223 u = 0.0;
nuclear@0	224 for(int i=0; i<uverts; i++) {
nuclear@0	225 float theta = SURAD(u);
nuclear@0	226
nuclear@0	227 float v = 0.0;
nuclear@0	228 for(int j=0; j<capvverts; j++) {
nuclear@0	229 float r = v * rad;
nuclear@0	230
nuclear@0	231 Vector3 pos = cylvec(theta, height / 2.0) * r;
nuclear@0	232 pos.y = height / 2.0;
nuclear@0	233 Vector3 tang = (cylvec(theta + 0.1, 0.0) - cylvec(theta - 0.1, 0.0)).normalized();
nuclear@0	234
nuclear@0	235 *varr++ = pos;
nuclear@0	236 *narr++ = Vector3(0, 1, 0);
nuclear@0	237 *tarr++ = tang;
nuclear@0	238 uvarr++ = Vector2(u urange, v);
nuclear@0	239
nuclear@0	240 pos.y = -height / 2.0;
nuclear@0	241 *varr++ = pos;
nuclear@0	242 *narr++ = Vector3(0, -1, 0);
nuclear@0	243 *tarr++ = -tang;
nuclear@0	244 uvarr++ = Vector2(u urange, v);
nuclear@0	245
nuclear@0	246 if(i < usub && j < capsub) {
nuclear@0	247 unsigned int idx = num_body_verts + (i * capvverts + j) * 2;
nuclear@0	248
nuclear@0	249 unsigned int vidx[4] = {
nuclear@0	250 idx,
nuclear@0	251 idx + capvverts * 2,
nuclear@0	252 idx + (capvverts + 1) * 2,
nuclear@0	253 idx + 2
nuclear@0	254 };
nuclear@0	255
nuclear@0	256 *idxarr++ = vidx[0];
nuclear@0	257 *idxarr++ = vidx[2];
nuclear@0	258 *idxarr++ = vidx[1];
nuclear@0	259 *idxarr++ = vidx[0];
nuclear@0	260 *idxarr++ = vidx[3];
nuclear@0	261 *idxarr++ = vidx[2];
nuclear@0	262
nuclear@0	263 *idxarr++ = vidx[0] + 1;
nuclear@0	264 *idxarr++ = vidx[1] + 1;
nuclear@0	265 *idxarr++ = vidx[2] + 1;
nuclear@0	266 *idxarr++ = vidx[0] + 1;
nuclear@0	267 *idxarr++ = vidx[2] + 1;
nuclear@0	268 *idxarr++ = vidx[3] + 1;
nuclear@0	269 }
nuclear@0	270
nuclear@0	271 v += dv;
nuclear@0	272 }
nuclear@0	273 u += du;
nuclear@0	274 }
nuclear@0	275 }
nuclear@0	276
nuclear@0	277 // -------- cone --------
nuclear@0	278
nuclear@0	279 static Vector3 conevec(float theta, float y, float height)
nuclear@0	280 {
nuclear@0	281 float scale = 1.0 - y / height;
nuclear@0	282 return Vector3(sin(theta) * scale, y, cos(theta) * scale);
nuclear@0	283 }
nuclear@0	284
nuclear@0	285 void gen_cone(Mesh *mesh, float rad, float height, int usub, int vsub, int capsub, float urange, float vrange)
nuclear@0	286 {
nuclear@0	287 if(usub < 4) usub = 4;
nuclear@0	288 if(vsub < 1) vsub = 1;
nuclear@0	289
nuclear@0	290 int uverts = usub + 1;
nuclear@0	291 int vverts = vsub + 1;
nuclear@0	292
nuclear@0	293 int num_body_verts = uverts * vverts;
nuclear@0	294 int num_body_quads = usub * vsub;
nuclear@0	295 int num_body_tri = num_body_quads * 2;
nuclear@0	296
nuclear@0	297 int capvverts = capsub ? capsub + 1 : 0;
nuclear@0	298 int num_cap_verts = uverts * capvverts;
nuclear@0	299 int num_cap_quads = usub * capsub;
nuclear@0	300 int num_cap_tri = num_cap_quads * 2;
nuclear@0	301
nuclear@0	302 int num_verts = num_body_verts + num_cap_verts;
nuclear@0	303 int num_tri = num_body_tri + num_cap_tri;
nuclear@0	304
nuclear@0	305 mesh->clear();
nuclear@0	306 Vector3 varr = (Vector3)mesh->set_attrib_data(MESH_ATTR_VERTEX, 3, num_verts, 0);
nuclear@0	307 Vector3 narr = (Vector3)mesh->set_attrib_data(MESH_ATTR_NORMAL, 3, num_verts, 0);
nuclear@0	308 Vector3 tarr = (Vector3)mesh->set_attrib_data(MESH_ATTR_TANGENT, 3, num_verts, 0);
nuclear@0	309 Vector2 uvarr = (Vector2)mesh->set_attrib_data(MESH_ATTR_TEXCOORD, 2, num_verts, 0);
nuclear@0	310 unsigned int idxarr = mesh->set_index_data(num_tri 3, 0);
nuclear@0	311
nuclear@0	312 float du = urange / (float)(uverts - 1);
nuclear@0	313 float dv = vrange / (float)(vverts - 1);
nuclear@0	314
nuclear@0	315 float u = 0.0;
nuclear@0	316 for(int i=0; i<uverts; i++) {
nuclear@0	317 float theta = SURAD(u);
nuclear@0	318
nuclear@0	319 float v = 0.0;
nuclear@0	320 for(int j=0; j<vverts; j++) {
nuclear@0	321 float y = v * height;
nuclear@0	322 Vector3 pos = conevec(theta, y, height);
nuclear@0	323
nuclear@0	324 Vector3 tang = (conevec(theta + 0.1, 0.0, height) - conevec(theta - 0.1, 0.0, height)).normalized();
nuclear@0	325 Vector3 bitang = (conevec(theta, y + 0.1, height) - pos).normalized();
nuclear@0	326
nuclear@0	327 varr++ = Vector3(pos.x rad, pos.y, pos.z * rad);
nuclear@0	328 *narr++ = cross_product(tang, bitang);
nuclear@0	329 *tarr++ = tang;
nuclear@0	330 uvarr++ = Vector2(u urange, v * vrange);
nuclear@0	331
nuclear@0	332 if(i < usub && j < vsub) {
nuclear@0	333 int idx = i * vverts + j;
nuclear@0	334
nuclear@0	335 *idxarr++ = idx;
nuclear@0	336 *idxarr++ = idx + vverts + 1;
nuclear@0	337 *idxarr++ = idx + 1;
nuclear@0	338
nuclear@0	339 *idxarr++ = idx;
nuclear@0	340 *idxarr++ = idx + vverts;
nuclear@0	341 *idxarr++ = idx + vverts + 1;
nuclear@0	342 }
nuclear@0	343
nuclear@0	344 v += dv;
nuclear@0	345 }
nuclear@0	346 u += du;
nuclear@0	347 }
nuclear@0	348
nuclear@0	349
nuclear@0	350 // now the bottom cap!
nuclear@0	351 if(!capsub) {
nuclear@0	352 return;
nuclear@0	353 }
nuclear@0	354
nuclear@0	355 dv = 1.0 / (float)(capvverts - 1);
nuclear@0	356
nuclear@0	357 u = 0.0;
nuclear@0	358 for(int i=0; i<uverts; i++) {
nuclear@0	359 float theta = SURAD(u);
nuclear@0	360
nuclear@0	361 float v = 0.0;
nuclear@0	362 for(int j=0; j<capvverts; j++) {
nuclear@0	363 float r = v * rad;
nuclear@0	364
nuclear@0	365 Vector3 pos = conevec(theta, 0.0, height) * r;
nuclear@0	366 Vector3 tang = (cylvec(theta + 0.1, 0.0) - cylvec(theta - 0.1, 0.0)).normalized();
nuclear@0	367
nuclear@0	368 *varr++ = pos;
nuclear@0	369 *narr++ = Vector3(0, -1, 0);
nuclear@0	370 *tarr++ = tang;
nuclear@0	371 uvarr++ = Vector2(u urange, v);
nuclear@0	372
nuclear@0	373 if(i < usub && j < capsub) {
nuclear@0	374 unsigned int idx = num_body_verts + i * capvverts + j;
nuclear@0	375
nuclear@0	376 unsigned int vidx[4] = {
nuclear@0	377 idx,
nuclear@0	378 idx + capvverts,
nuclear@0	379 idx + (capvverts + 1),
nuclear@0	380 idx + 1
nuclear@0	381 };
nuclear@0	382
nuclear@0	383 *idxarr++ = vidx[0];
nuclear@0	384 *idxarr++ = vidx[1];
nuclear@0	385 *idxarr++ = vidx[2];
nuclear@0	386 *idxarr++ = vidx[0];
nuclear@0	387 *idxarr++ = vidx[2];
nuclear@0	388 *idxarr++ = vidx[3];
nuclear@0	389 }
nuclear@0	390
nuclear@0	391 v += dv;
nuclear@0	392 }
nuclear@0	393 u += du;
nuclear@0	394 }
nuclear@0	395 }
nuclear@0	396
nuclear@0	397
nuclear@0	398 // -------- plane --------
nuclear@0	399
nuclear@0	400 void gen_plane(Mesh *mesh, float width, float height, int usub, int vsub)
nuclear@0	401 {
nuclear@0	402 gen_heightmap(mesh, width, height, usub, vsub, 0);
nuclear@0	403 }
nuclear@0	404
nuclear@0	405
nuclear@0	406 // ----- heightmap ------
nuclear@0	407
nuclear@0	408 void gen_heightmap(Mesh mesh, float width, float height, int usub, int vsub, float (hf)(float, float, void), void hfdata)
nuclear@0	409 {
nuclear@0	410 if(usub < 1) usub = 1;
nuclear@0	411 if(vsub < 1) vsub = 1;
nuclear@0	412
nuclear@0	413 mesh->clear();
nuclear@0	414
nuclear@0	415 int uverts = usub + 1;
nuclear@0	416 int vverts = vsub + 1;
nuclear@0	417 int num_verts = uverts * vverts;
nuclear@0	418
nuclear@0	419 int num_quads = usub * vsub;
nuclear@0	420 int num_tri = num_quads * 2;
nuclear@0	421
nuclear@0	422 Vector3 varr = (Vector3)mesh->set_attrib_data(MESH_ATTR_VERTEX, 3, num_verts, 0);
nuclear@0	423 Vector3 narr = (Vector3)mesh->set_attrib_data(MESH_ATTR_NORMAL, 3, num_verts, 0);
nuclear@0	424 Vector3 tarr = (Vector3)mesh->set_attrib_data(MESH_ATTR_TANGENT, 3, num_verts, 0);
nuclear@0	425 Vector2 uvarr = (Vector2)mesh->set_attrib_data(MESH_ATTR_TEXCOORD, 2, num_verts, 0);
nuclear@0	426 unsigned int idxarr = mesh->set_index_data(num_tri 3, 0);
nuclear@0	427
nuclear@0	428 float du = 1.0 / (float)usub;
nuclear@0	429 float dv = 1.0 / (float)vsub;
nuclear@0	430
nuclear@0	431 float u = 0.0;
nuclear@0	432 for(int i=0; i<uverts; i++) {
nuclear@0	433 float v = 0.0;
nuclear@0	434 for(int j=0; j<vverts; j++) {
nuclear@0	435 float x = (u - 0.5) * width;
nuclear@0	436 float y = (v - 0.5) * height;
nuclear@0	437 float z = hf ? hf(u, v, hfdata) : 0.0;
nuclear@0	438
nuclear@0	439 Vector3 normal = Vector3(0, 0, 1);
nuclear@0	440 if(hf) {
nuclear@0	441 float u1z = hf(u + du, v, hfdata);
nuclear@0	442 float v1z = hf(u, v + dv, hfdata);
nuclear@0	443
nuclear@0	444 Vector3 tang = Vector3(du * width, 0, u1z - z);
nuclear@0	445 Vector3 bitan = Vector3(0, dv * height, v1z - z);
nuclear@0	446 normal = cross_product(tang, bitan).normalized();
nuclear@0	447 }
nuclear@0	448
nuclear@0	449 *varr++ = Vector3(x, y, z);
nuclear@0	450 *narr++ = normal;
nuclear@0	451 *tarr++ = Vector3(1, 0, 0);
nuclear@0	452 *uvarr++ = Vector2(u, v);
nuclear@0	453
nuclear@0	454 if(i < usub && j < vsub) {
nuclear@0	455 int idx = i * vverts + j;
nuclear@0	456
nuclear@0	457 *idxarr++ = idx;
nuclear@0	458 *idxarr++ = idx + vverts + 1;
nuclear@0	459 *idxarr++ = idx + 1;
nuclear@0	460
nuclear@0	461 *idxarr++ = idx;
nuclear@0	462 *idxarr++ = idx + vverts;
nuclear@0	463 *idxarr++ = idx + vverts + 1;
nuclear@0	464 }
nuclear@0	465
nuclear@0	466 v += dv;
nuclear@0	467 }
nuclear@0	468 u += du;
nuclear@0	469 }
nuclear@0	470 }
nuclear@0	471
nuclear@1	472 // ----- box ------
nuclear@1	473 void gen_box(Mesh *mesh, float xsz, float ysz, float zsz, int usub, int vsub)
nuclear@1	474 {
nuclear@1	475 static const float face_angles[][2] = {
nuclear@1	476 {0, 0},
nuclear@1	477 {M_PI / 2.0, 0},
nuclear@1	478 {M_PI, 0},
nuclear@1	479 {3.0 * M_PI / 2.0, 0},
nuclear@1	480 {0, M_PI / 2.0},
nuclear@1	481 {0, -M_PI / 2.0}
nuclear@1	482 };
nuclear@0	483
nuclear@1	484 if(usub < 1) usub = 1;
nuclear@1	485 if(vsub < 1) vsub = 1;
nuclear@1	486
nuclear@1	487 mesh->clear();
nuclear@1	488
nuclear@1	489 for(int i=0; i<6; i++) {
nuclear@2	490 Matrix4x4 xform, dir_xform;
nuclear@1	491 Mesh m;
nuclear@1	492
nuclear@1	493 gen_plane(&m, 1, 1, usub, vsub);
nuclear@1	494 xform.rotate(Vector3(face_angles[i][1], face_angles[i][0], 0));
nuclear@2	495 dir_xform = xform;
nuclear@1	496 xform.translate(Vector3(0, 0, 0.5));
nuclear@2	497 m.apply_xform(xform, dir_xform);
nuclear@1	498
nuclear@1	499 mesh->append(m);
nuclear@1	500 }
nuclear@1	501
nuclear@1	502 Matrix4x4 scale;
nuclear@1	503 scale.set_scaling(Vector3(xsz, ysz, zsz));
nuclear@1	504 mesh->apply_xform(scale, Matrix4x4::identity);
nuclear@1	505 }
nuclear@1	506
nuclear@1	507 /*
nuclear@0	508 void gen_box(Mesh *mesh, float xsz, float ysz, float zsz)
nuclear@0	509 {
nuclear@0	510 mesh->clear();
nuclear@0	511
nuclear@0	512 const int num_faces = 6;
nuclear@0	513 int num_verts = num_faces * 4;
nuclear@0	514 int num_tri = num_faces * 2;
nuclear@0	515
nuclear@0	516 float x = xsz / 2.0;
nuclear@0	517 float y = ysz / 2.0;
nuclear@0	518 float z = zsz / 2.0;
nuclear@0	519
nuclear@0	520 Vector3 varr = (Vector3)mesh->set_attrib_data(MESH_ATTR_VERTEX, 3, num_verts, 0);
nuclear@0	521 Vector3 narr = (Vector3)mesh->set_attrib_data(MESH_ATTR_NORMAL, 3, num_verts, 0);
nuclear@0	522 Vector3 tarr = (Vector3)mesh->set_attrib_data(MESH_ATTR_TANGENT, 3, num_verts, 0);
nuclear@0	523 Vector2 uvarr = (Vector2)mesh->set_attrib_data(MESH_ATTR_TEXCOORD, 2, num_verts, 0);
nuclear@0	524 unsigned int idxarr = mesh->set_index_data(num_tri 3, 0);
nuclear@0	525
nuclear@0	526 static const Vector2 uv[] = { Vector2(0, 0), Vector2(1, 0), Vector2(1, 1), Vector2(0, 1) };
nuclear@0	527
nuclear@0	528 // front
nuclear@0	529 for(int i=0; i<4; i++) {
nuclear@0	530 *narr++ = Vector3(0, 0, 1);
nuclear@0	531 *tarr++ = Vector3(1, 0, 0);
nuclear@0	532 *uvarr++ = uv[i];
nuclear@0	533 }
nuclear@0	534 *varr++ = Vector3(-x, -y, z);
nuclear@0	535 *varr++ = Vector3(x, -y, z);
nuclear@0	536 *varr++ = Vector3(x, y, z);
nuclear@0	537 *varr++ = Vector3(-x, y, z);
nuclear@0	538 // right
nuclear@0	539 for(int i=0; i<4; i++) {
nuclear@0	540 *narr++ = Vector3(1, 0, 0);
nuclear@0	541 *tarr++ = Vector3(0, 0, -1);
nuclear@0	542 *uvarr++ = uv[i];
nuclear@0	543 }
nuclear@0	544 *varr++ = Vector3(x, -y, z);
nuclear@0	545 *varr++ = Vector3(x, -y, -z);
nuclear@0	546 *varr++ = Vector3(x, y, -z);
nuclear@0	547 *varr++ = Vector3(x, y, z);
nuclear@0	548 // back
nuclear@0	549 for(int i=0; i<4; i++) {
nuclear@0	550 *narr++ = Vector3(0, 0, -1);
nuclear@0	551 *tarr++ = Vector3(-1, 0, 0);
nuclear@0	552 *uvarr++ = uv[i];
nuclear@0	553 }
nuclear@0	554 *varr++ = Vector3(x, -y, -z);
nuclear@0	555 *varr++ = Vector3(-x, -y, -z);
nuclear@0	556 *varr++ = Vector3(-x, y, -z);
nuclear@0	557 *varr++ = Vector3(x, y, -z);
nuclear@0	558 // left
nuclear@0	559 for(int i=0; i<4; i++) {
nuclear@0	560 *narr++ = Vector3(-1, 0, 0);
nuclear@0	561 *tarr++ = Vector3(0, 0, 1);
nuclear@0	562 *uvarr++ = uv[i];
nuclear@0	563 }
nuclear@0	564 *varr++ = Vector3(-x, -y, -z);
nuclear@0	565 *varr++ = Vector3(-x, -y, z);
nuclear@0	566 *varr++ = Vector3(-x, y, z);
nuclear@0	567 *varr++ = Vector3(-x, y, -z);
nuclear@0	568 // top
nuclear@0	569 for(int i=0; i<4; i++) {
nuclear@0	570 *narr++ = Vector3(0, 1, 0);
nuclear@0	571 *tarr++ = Vector3(1, 0, 0);
nuclear@0	572 *uvarr++ = uv[i];
nuclear@0	573 }
nuclear@0	574 *varr++ = Vector3(-x, y, z);
nuclear@0	575 *varr++ = Vector3(x, y, z);
nuclear@0	576 *varr++ = Vector3(x, y, -z);
nuclear@0	577 *varr++ = Vector3(-x, y, -z);
nuclear@0	578 // bottom
nuclear@0	579 for(int i=0; i<4; i++) {
nuclear@0	580 *narr++ = Vector3(0, -1, 0);
nuclear@0	581 *tarr++ = Vector3(1, 0, 0);
nuclear@0	582 *uvarr++ = uv[i];
nuclear@0	583 }
nuclear@0	584 *varr++ = Vector3(-x, -y, -z);
nuclear@0	585 *varr++ = Vector3(x, -y, -z);
nuclear@0	586 *varr++ = Vector3(x, -y, z);
nuclear@0	587 *varr++ = Vector3(-x, -y, z);
nuclear@0	588
nuclear@0	589 // index array
nuclear@0	590 static const int faceidx[] = {0, 1, 2, 0, 2, 3};
nuclear@0	591 for(int i=0; i<num_faces; i++) {
nuclear@0	592 for(int j=0; j<6; j++) {
nuclear@0	593 idxarr++ = faceidx[j] + i 4;
nuclear@0	594 }
nuclear@0	595 }
nuclear@0	596 }
nuclear@1	597 */
nuclear@0	598
nuclear@0	599 static inline Vector3 rev_vert(float u, float v, Vector2 (rf)(float, float, void), void *cls)
nuclear@0	600 {
nuclear@0	601 Vector2 pos = rf(u, v, cls);
nuclear@0	602
nuclear@0	603 float angle = u * 2.0 * M_PI;
nuclear@0	604 float x = pos.x * cos(angle);
nuclear@0	605 float y = pos.y;
nuclear@0	606 float z = pos.x * sin(angle);
nuclear@0	607
nuclear@0	608 return Vector3(x, y, z);
nuclear@0	609 }
nuclear@0	610
nuclear@0	611 // ------ surface of revolution -------
nuclear@0	612 void gen_revol(Mesh mesh, int usub, int vsub, Vector2 (rfunc)(float, float, void), void cls)
nuclear@0	613 {
nuclear@0	614 gen_revol(mesh, usub, vsub, rfunc, 0, cls);
nuclear@0	615 }
nuclear@0	616
nuclear@0	617 void gen_revol(Mesh mesh, int usub, int vsub, Vector2 (rfunc)(float, float, void*),
nuclear@0	618 Vector2 (nfunc)(float, float, void), void *cls)
nuclear@0	619 {
nuclear@0	620 if(!rfunc) return;
nuclear@0	621 if(usub < 3) usub = 3;
nuclear@0	622 if(vsub < 1) vsub = 1;
nuclear@0	623
nuclear@0	624 mesh->clear();
nuclear@0	625
nuclear@0	626 int uverts = usub + 1;
nuclear@0	627 int vverts = vsub + 1;
nuclear@0	628 int num_verts = uverts * vverts;
nuclear@0	629
nuclear@0	630 int num_quads = usub * vsub;
nuclear@0	631 int num_tri = num_quads * 2;
nuclear@0	632
nuclear@0	633 Vector3 varr = (Vector3)mesh->set_attrib_data(MESH_ATTR_VERTEX, 3, num_verts, 0);
nuclear@0	634 Vector3 narr = (Vector3)mesh->set_attrib_data(MESH_ATTR_NORMAL, 3, num_verts, 0);
nuclear@0	635 Vector3 tarr = (Vector3)mesh->set_attrib_data(MESH_ATTR_TANGENT, 3, num_verts, 0);
nuclear@0	636 Vector2 uvarr = (Vector2)mesh->set_attrib_data(MESH_ATTR_TEXCOORD, 2, num_verts, 0);
nuclear@0	637 unsigned int idxarr = mesh->set_index_data(num_tri 3, 0);
nuclear@0	638
nuclear@0	639 float du = 1.0 / (float)(uverts - 1);
nuclear@0	640 float dv = 1.0 / (float)(vverts - 1);
nuclear@0	641
nuclear@0	642 float u = 0.0;
nuclear@0	643 for(int i=0; i<uverts; i++) {
nuclear@0	644 float v = 0.0;
nuclear@0	645 for(int j=0; j<vverts; j++) {
nuclear@0	646 Vector3 pos = rev_vert(u, v, rfunc, cls);
nuclear@0	647
nuclear@0	648 Vector3 nextu = rev_vert(fmod(u + du, 1.0), v, rfunc, cls);
nuclear@0	649 Vector3 tang = nextu - pos;
nuclear@0	650 if(tang.length_sq() < 1e-6) {
nuclear@0	651 float new_v = v > 0.5 ? v - dv * 0.25 : v + dv * 0.25;
nuclear@0	652 nextu = rev_vert(fmod(u + du, 1.0), new_v, rfunc, cls);
nuclear@0	653 tang = nextu - pos;
nuclear@0	654 }
nuclear@0	655
nuclear@0	656 Vector3 normal;
nuclear@0	657 if(nfunc) {
nuclear@0	658 normal = rev_vert(u, v, nfunc, cls);
nuclear@0	659 } else {
nuclear@0	660 Vector3 nextv = rev_vert(u, v + dv, rfunc, cls);
nuclear@0	661 Vector3 bitan = nextv - pos;
nuclear@0	662 if(bitan.length_sq() < 1e-6) {
nuclear@0	663 nextv = rev_vert(u, v - dv, rfunc, cls);
nuclear@0	664 bitan = pos - nextv;
nuclear@0	665 }
nuclear@0	666
nuclear@0	667 normal = cross_product(tang, bitan);
nuclear@0	668 }
nuclear@0	669
nuclear@0	670 *varr++ = pos;
nuclear@0	671 *narr++ = normal.normalized();
nuclear@0	672 *tarr++ = tang.normalized();
nuclear@0	673 *uvarr++ = Vector2(u, v);
nuclear@0	674
nuclear@0	675 if(i < usub && j < vsub) {
nuclear@0	676 int idx = i * vverts + j;
nuclear@0	677
nuclear@0	678 *idxarr++ = idx;
nuclear@0	679 *idxarr++ = idx + vverts + 1;
nuclear@0	680 *idxarr++ = idx + 1;
nuclear@0	681
nuclear@0	682 *idxarr++ = idx;
nuclear@0	683 *idxarr++ = idx + vverts;
nuclear@0	684 *idxarr++ = idx + vverts + 1;
nuclear@0	685 }
nuclear@0	686
nuclear@0	687 v += dv;
nuclear@0	688 }
nuclear@0	689 u += du;
nuclear@0	690 }
nuclear@0	691 }