istereo

annotate src/sanegl.c @ 24:70309d71c899

added the texture translation
author John Tsiombikas <nuclear@mutantstargoat.com>
date Thu, 08 Sep 2011 03:06:46 +0300
parents 2c5620f0670c
children fd39c0198935
rev   line source
nuclear@2 1 /*
nuclear@2 2 SaneGL - a small library to bring back sanity to OpenGL ES 2.x
nuclear@2 3 Copyright (C) 2011 John Tsiombikas <nuclear@member.fsf.org>
nuclear@2 4
nuclear@2 5 This program is free software: you can redistribute it and/or modify
nuclear@2 6 it under the terms of the GNU General Public License as published by
nuclear@2 7 the Free Software Foundation, either version 3 of the License, or
nuclear@2 8 (at your option) any later version.
nuclear@2 9
nuclear@2 10 This program is distributed in the hope that it will be useful,
nuclear@2 11 but WITHOUT ANY WARRANTY; without even the implied warranty of
nuclear@2 12 MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
nuclear@2 13 GNU General Public License for more details.
nuclear@2 14
nuclear@2 15 You should have received a copy of the GNU General Public License
nuclear@2 16 along with this program. If not, see <http://www.gnu.org/licenses/>.
nuclear@2 17 */
nuclear@2 18
nuclear@2 19 #include <stdio.h>
nuclear@3 20 #include <stdlib.h>
nuclear@2 21 #include <string.h>
nuclear@1 22 #include <math.h>
nuclear@2 23 #include <assert.h>
nuclear@1 24 #include "sanegl.h"
nuclear@1 25
nuclear@1 26 #define MMODE_IDX(x) ((x) - GL_MODELVIEW)
nuclear@1 27 #define MAT_STACK_SIZE 32
nuclear@1 28 #define MAT_IDENT {1, 0, 0, 0, 0, 1, 0, 0, 0, 0, 1, 0, 0, 0, 0, 1}
nuclear@1 29
nuclear@1 30 #define MAX_VERTS 512
nuclear@1 31
nuclear@2 32 static void gl_draw_immediate(void);
nuclear@2 33
nuclear@1 34 typedef struct { float x, y; } vec2_t;
nuclear@1 35 typedef struct { float x, y, z; } vec3_t;
nuclear@1 36 typedef struct { float x, y, z, w; } vec4_t;
nuclear@1 37
nuclear@1 38 static int mm_idx = 0;
nuclear@1 39 static float mat_stack[3][MAT_STACK_SIZE][16] = {{MAT_IDENT}, {MAT_IDENT}, {MAT_IDENT}};
nuclear@1 40 static int stack_top[3];
nuclear@1 41 static float mat_mvp[16];
nuclear@1 42 static int mvp_valid;
nuclear@1 43 static int prim = -1;
nuclear@1 44
nuclear@1 45 static vec3_t cur_normal;
nuclear@1 46 static vec4_t cur_color, cur_attrib;
nuclear@1 47 static vec2_t cur_texcoord;
nuclear@1 48
nuclear@1 49 static vec4_t *vert_arr, *col_arr, *attr_arr;
nuclear@1 50 static vec3_t *norm_arr;
nuclear@1 51 static vec2_t *texc_arr;
nuclear@2 52 /*static unsigned int vbuf, cbuf, nbuf, tbuf, abuf;*/
nuclear@2 53 static int vloc, nloc, cloc, tloc, aloc = -1;
nuclear@2 54
nuclear@2 55 static int num_verts, vert_calls;
nuclear@2 56 static int cur_prog;
nuclear@1 57
nuclear@1 58
nuclear@1 59 void gl_matrix_mode(int mm)
nuclear@1 60 {
nuclear@1 61 mm_idx = MMODE_IDX(mm);
nuclear@1 62 }
nuclear@1 63
nuclear@1 64 void gl_push_matrix(void)
nuclear@1 65 {
nuclear@1 66 int top = stack_top[mm_idx];
nuclear@1 67
nuclear@1 68 memcpy(mat_stack[mm_idx][top + 1], mat_stack[mm_idx][top], 16 * sizeof(float));
nuclear@1 69 stack_top[mm_idx]++;
nuclear@1 70 mvp_valid = 0;
nuclear@1 71 }
nuclear@1 72
nuclear@1 73 void gl_pop_matrix(void)
nuclear@1 74 {
nuclear@1 75 stack_top[mm_idx]--;
nuclear@1 76 mvp_valid = 0;
nuclear@1 77 }
nuclear@1 78
nuclear@1 79 void gl_load_identity(void)
nuclear@1 80 {
nuclear@1 81 static const float idmat[] = MAT_IDENT;
nuclear@1 82 int top = stack_top[mm_idx];
nuclear@1 83 float *mat = mat_stack[mm_idx][top];
nuclear@1 84
nuclear@1 85 memcpy(mat, idmat, sizeof idmat);
nuclear@1 86 mvp_valid = 0;
nuclear@1 87 }
nuclear@1 88
nuclear@1 89 void gl_load_matrixf(const float *m)
nuclear@1 90 {
nuclear@1 91 int top = stack_top[mm_idx];
nuclear@1 92 float *mat = mat_stack[mm_idx][top];
nuclear@1 93
nuclear@1 94 memcpy(mat, m, 16 * sizeof *mat);
nuclear@1 95 mvp_valid = 0;
nuclear@1 96 }
nuclear@1 97
nuclear@1 98 #define M(i, j) ((i << 2) + j)
nuclear@1 99
nuclear@1 100 void gl_mult_matrixf(const float *m2)
nuclear@1 101 {
nuclear@1 102 int i, j;
nuclear@1 103 int top = stack_top[mm_idx];
nuclear@1 104 float *m1 = mat_stack[mm_idx][top];
nuclear@1 105 float res[16];
nuclear@1 106
nuclear@1 107 for(i=0; i<4; i++) {
nuclear@1 108 for(j=0; j<4; j++) {
nuclear@1 109 res[M(i,j)] = m1[M(i,0)] * m2[M(0,j)] +
nuclear@1 110 m1[M(i,1)] * m2[M(1,j)] +
nuclear@1 111 m1[M(i,2)] * m2[M(2,j)] +
nuclear@1 112 m1[M(i,3)] * m2[M(3,j)];
nuclear@1 113 }
nuclear@1 114 }
nuclear@1 115
nuclear@1 116 memcpy(m1, res, sizeof res);
nuclear@1 117 mvp_valid = 0;
nuclear@1 118 }
nuclear@1 119
nuclear@1 120 void gl_translatef(float x, float y, float z)
nuclear@1 121 {
nuclear@1 122 float mat[] = MAT_IDENT;
nuclear@1 123
nuclear@1 124 mat[12] = x;
nuclear@1 125 mat[13] = y;
nuclear@1 126 mat[14] = z;
nuclear@1 127
nuclear@1 128 gl_mult_matrixf(mat);
nuclear@1 129 }
nuclear@1 130
nuclear@1 131 void gl_rotatef(float angle, float x, float y, float z)
nuclear@1 132 {
nuclear@1 133 float mat[] = MAT_IDENT;
nuclear@1 134
nuclear@1 135 float angle_rad = M_PI * angle / 180.0;
nuclear@1 136 float sina = sin(angle_rad);
nuclear@1 137 float cosa = cos(angle_rad);
nuclear@1 138 float one_minus_cosa = 1.0 - cosa;
nuclear@1 139 float nxsq = x * x;
nuclear@1 140 float nysq = y * y;
nuclear@1 141 float nzsq = z * z;
nuclear@1 142
nuclear@1 143 mat[0] = nxsq + (1.0 - nxsq) * cosa;
nuclear@1 144 mat[4] = x * y * one_minus_cosa - z * sina;
nuclear@1 145 mat[8] = x * z * one_minus_cosa + y * sina;
nuclear@1 146 mat[1] = x * y * one_minus_cosa + z * sina;
nuclear@1 147 mat[5] = nysq + (1.0 - nysq) * cosa;
nuclear@1 148 mat[9] = y * z * one_minus_cosa - x * sina;
nuclear@1 149 mat[2] = x * z * one_minus_cosa - y * sina;
nuclear@1 150 mat[6] = y * z * one_minus_cosa + x * sina;
nuclear@1 151 mat[10] = nzsq + (1.0 - nzsq) * cosa;
nuclear@1 152
nuclear@1 153 gl_mult_matrixf(mat);
nuclear@1 154 }
nuclear@1 155
nuclear@1 156 void gl_scalef(float x, float y, float z)
nuclear@1 157 {
nuclear@1 158 float mat[] = MAT_IDENT;
nuclear@1 159
nuclear@1 160 mat[0] = x;
nuclear@1 161 mat[5] = y;
nuclear@1 162 mat[10] = z;
nuclear@1 163
nuclear@1 164 gl_mult_matrixf(mat);
nuclear@1 165 }
nuclear@1 166
nuclear@1 167 void gl_ortho(float left, float right, float bottom, float top, float near, float far)
nuclear@1 168 {
nuclear@1 169 float mat[] = MAT_IDENT;
nuclear@1 170
nuclear@1 171 float dx = right - left;
nuclear@1 172 float dy = top - bottom;
nuclear@1 173 float dz = far - near;
nuclear@1 174
nuclear@1 175 float tx = -(right + left) / dx;
nuclear@1 176 float ty = -(top + bottom) / dy;
nuclear@1 177 float tz = -(far + near) / dz;
nuclear@1 178
nuclear@1 179 float sx = 2.0 / dx;
nuclear@1 180 float sy = 2.0 / dy;
nuclear@1 181 float sz = -2.0 / dz;
nuclear@1 182
nuclear@1 183 mat[0] = sx;
nuclear@1 184 mat[5] = sy;
nuclear@1 185 mat[10] = sz;
nuclear@1 186 mat[12] = tx;
nuclear@1 187 mat[13] = ty;
nuclear@1 188 mat[14] = tz;
nuclear@1 189
nuclear@1 190 gl_mult_matrixf(mat);
nuclear@1 191 }
nuclear@1 192
nuclear@1 193 void gl_frustum(float left, float right, float bottom, float top, float near, float far)
nuclear@1 194 {
nuclear@1 195 float mat[] = MAT_IDENT;
nuclear@1 196
nuclear@1 197 float dx = right - left;
nuclear@1 198 float dy = top - bottom;
nuclear@1 199 float dz = far - near;
nuclear@1 200
nuclear@1 201 float a = (right + left) / dx;
nuclear@1 202 float b = (top + bottom) / dy;
nuclear@1 203 float c = -(far + near) / dz;
nuclear@1 204 float d = -2.0 * far * near / dz;
nuclear@1 205
nuclear@1 206 mat[0] = 2.0 * near / dx;
nuclear@1 207 mat[5] = 2.0 * near / dy;
nuclear@1 208 mat[8] = a;
nuclear@1 209 mat[9] = b;
nuclear@1 210 mat[10] = c;
nuclear@1 211 mat[11] = -1.0;
nuclear@1 212 mat[14] = d;
nuclear@1 213
nuclear@1 214 gl_mult_matrixf(mat);
nuclear@1 215 }
nuclear@1 216
nuclear@1 217 void glu_perspective(float vfov, float aspect, float near, float far)
nuclear@1 218 {
nuclear@21 219 float vfov_rad = M_PI * vfov / 180.0;
nuclear@21 220 float x = near * tan(vfov_rad / 2.0);
nuclear@1 221 gl_frustum(-aspect * x, aspect * x, -x, x, near, far);
nuclear@1 222 }
nuclear@1 223
nuclear@1 224 void gl_apply_xform(unsigned int prog)
nuclear@1 225 {
nuclear@1 226 int loc, mvidx, pidx, tidx, mvtop, ptop, ttop;
nuclear@1 227
nuclear@1 228 mvidx = MMODE_IDX(GL_MODELVIEW);
nuclear@1 229 pidx = MMODE_IDX(GL_PROJECTION);
nuclear@1 230 tidx = MMODE_IDX(GL_TEXTURE);
nuclear@1 231
nuclear@1 232 mvtop = stack_top[mvidx];
nuclear@1 233 ptop = stack_top[pidx];
nuclear@1 234 ttop = stack_top[tidx];
nuclear@1 235
nuclear@2 236 assert(prog);
nuclear@2 237
nuclear@1 238 if((loc = glGetUniformLocation(prog, "matrix_modelview")) != -1) {
nuclear@2 239 glUniformMatrix4fv(loc, 1, 0, mat_stack[mvidx][mvtop]);
nuclear@1 240 }
nuclear@1 241
nuclear@1 242 if((loc = glGetUniformLocation(prog, "matrix_projection")) != -1) {
nuclear@2 243 glUniformMatrix4fv(loc, 1, 0, mat_stack[pidx][ptop]);
nuclear@1 244 }
nuclear@1 245
nuclear@1 246 if((loc = glGetUniformLocation(prog, "matrix_texture")) != -1) {
nuclear@2 247 glUniformMatrix4fv(loc, 1, 0, mat_stack[tidx][ttop]);
nuclear@1 248 }
nuclear@1 249
nuclear@1 250 if((loc = glGetUniformLocation(prog, "matrix_normal")) != -1) {
nuclear@1 251 float nmat[9];
nuclear@1 252
nuclear@1 253 nmat[0] = mat_stack[mvidx][mvtop][0];
nuclear@1 254 nmat[1] = mat_stack[mvidx][mvtop][1];
nuclear@1 255 nmat[2] = mat_stack[mvidx][mvtop][2];
nuclear@1 256 nmat[3] = mat_stack[mvidx][mvtop][4];
nuclear@1 257 nmat[4] = mat_stack[mvidx][mvtop][5];
nuclear@1 258 nmat[5] = mat_stack[mvidx][mvtop][6];
nuclear@1 259 nmat[6] = mat_stack[mvidx][mvtop][8];
nuclear@1 260 nmat[7] = mat_stack[mvidx][mvtop][9];
nuclear@1 261 nmat[8] = mat_stack[mvidx][mvtop][10];
nuclear@2 262 glUniformMatrix3fv(loc, 1, 0, nmat);
nuclear@1 263 }
nuclear@1 264
nuclear@1 265 if((loc = glGetUniformLocation(prog, "matrix_modelview_projection")) != -1) {
nuclear@1 266 if(!mvp_valid) {
nuclear@1 267 /* TODO calc mvp */
nuclear@1 268 }
nuclear@2 269 glUniformMatrix4fv(loc, 1, 0, mat_mvp);
nuclear@1 270 }
nuclear@1 271 }
nuclear@2 272
nuclear@2 273
nuclear@2 274 /* immediate mode rendering */
nuclear@2 275 void gl_begin(int p)
nuclear@2 276 {
nuclear@2 277 if(!vert_arr) {
nuclear@2 278 vert_arr = malloc(MAX_VERTS * sizeof *vert_arr);
nuclear@2 279 norm_arr = malloc(MAX_VERTS * sizeof *norm_arr);
nuclear@2 280 texc_arr = malloc(MAX_VERTS * sizeof *texc_arr);
nuclear@2 281 col_arr = malloc(MAX_VERTS * sizeof *col_arr);
nuclear@2 282 attr_arr = malloc(MAX_VERTS * sizeof *attr_arr);
nuclear@2 283 assert(vert_arr && norm_arr && texc_arr && col_arr && attr_arr);
nuclear@2 284 }
nuclear@2 285
nuclear@2 286 prim = p;
nuclear@2 287 num_verts = vert_calls = 0;
nuclear@2 288
nuclear@2 289 glGetIntegerv(GL_CURRENT_PROGRAM, &cur_prog);
nuclear@2 290 assert(cur_prog);
nuclear@2 291
nuclear@2 292 gl_apply_xform(cur_prog);
nuclear@2 293
nuclear@2 294 vloc = glGetAttribLocation(cur_prog, "attr_vertex");
nuclear@2 295 nloc = glGetAttribLocation(cur_prog, "attr_normal");
nuclear@2 296 cloc = glGetAttribLocation(cur_prog, "attr_color");
nuclear@2 297 tloc = glGetAttribLocation(cur_prog, "attr_texcoord");
nuclear@2 298 }
nuclear@2 299
nuclear@2 300 void gl_end(void)
nuclear@2 301 {
nuclear@2 302 if(num_verts > 0) {
nuclear@2 303 gl_draw_immediate();
nuclear@2 304 }
nuclear@2 305 aloc = -1;
nuclear@2 306 }
nuclear@2 307
nuclear@2 308 static void gl_draw_immediate(void)
nuclear@2 309 {
nuclear@2 310 int glprim;
nuclear@2 311
nuclear@2 312 if(vloc == -1) {
nuclear@2 313 fprintf(stderr, "gl_draw_immediate call with vloc == -1\n");
nuclear@2 314 return;
nuclear@2 315 }
nuclear@2 316
nuclear@2 317 glprim = prim == GL_QUADS ? GL_TRIANGLES : prim;
nuclear@2 318
nuclear@2 319 glVertexAttribPointer(vloc, 4, GL_FLOAT, 0, 0, vert_arr);
nuclear@2 320 glEnableVertexAttribArray(vloc);
nuclear@2 321
nuclear@2 322 if(nloc != -1) {
nuclear@2 323 glVertexAttribPointer(nloc, 3, GL_FLOAT, 0, 0, norm_arr);
nuclear@2 324 glEnableVertexAttribArray(nloc);
nuclear@2 325 }
nuclear@2 326
nuclear@2 327 if(cloc != -1) {
nuclear@2 328 glVertexAttribPointer(cloc, 4, GL_FLOAT, 0, 0, col_arr);
nuclear@2 329 glEnableVertexAttribArray(cloc);
nuclear@2 330 }
nuclear@2 331
nuclear@2 332 if(tloc != -1) {
nuclear@2 333 glVertexAttribPointer(tloc, 2, GL_FLOAT, 0, 0, texc_arr);
nuclear@2 334 glEnableVertexAttribArray(tloc);
nuclear@2 335 }
nuclear@2 336
nuclear@2 337 if(aloc != -1) {
nuclear@2 338 glVertexAttribPointer(aloc, 4, GL_FLOAT, 0, 0, attr_arr);
nuclear@2 339 glEnableVertexAttribArray(aloc);
nuclear@2 340 }
nuclear@2 341
nuclear@2 342 glDrawArrays(glprim, 0, num_verts);
nuclear@2 343
nuclear@2 344 glDisableVertexAttribArray(vloc);
nuclear@2 345 if(nloc != -1) {
nuclear@2 346 glDisableVertexAttribArray(nloc);
nuclear@2 347 }
nuclear@2 348 if(cloc != -1) {
nuclear@2 349 glDisableVertexAttribArray(cloc);
nuclear@2 350 }
nuclear@2 351 if(tloc != -1) {
nuclear@2 352 glDisableVertexAttribArray(tloc);
nuclear@2 353 }
nuclear@2 354 if(aloc != -1) {
nuclear@2 355 glDisableVertexAttribArray(aloc);
nuclear@2 356 }
nuclear@2 357 }
nuclear@2 358
nuclear@2 359
nuclear@2 360 void gl_vertex2f(float x, float y)
nuclear@2 361 {
nuclear@2 362 gl_vertex4f(x, y, 0.0f, 1.0f);
nuclear@2 363 }
nuclear@2 364
nuclear@2 365 void gl_vertex3f(float x, float y, float z)
nuclear@2 366 {
nuclear@2 367 gl_vertex4f(x, y, z, 1.0f);
nuclear@2 368 }
nuclear@2 369
nuclear@2 370 void gl_vertex4f(float x, float y, float z, float w)
nuclear@2 371 {
nuclear@2 372 int i, buffer_full;
nuclear@2 373
nuclear@2 374 if(prim == GL_QUADS && vert_calls % 4 == 3) {
nuclear@2 375 for(i=0; i<2; i++) {
nuclear@2 376 if(aloc != -1) {
nuclear@2 377 attr_arr[num_verts] = attr_arr[num_verts - 3 + i];
nuclear@2 378 }
nuclear@2 379 if(cloc != -1) {
nuclear@2 380 col_arr[num_verts] = col_arr[num_verts - 3 + i];
nuclear@2 381 }
nuclear@2 382 if(tloc != -1) {
nuclear@2 383 texc_arr[num_verts] = texc_arr[num_verts - 3 + i];
nuclear@2 384 }
nuclear@2 385 if(nloc != -1) {
nuclear@2 386 norm_arr[num_verts] = norm_arr[num_verts - 3 + i];
nuclear@2 387 }
nuclear@2 388 vert_arr[num_verts] = vert_arr[num_verts - 3 + i];
nuclear@2 389 num_verts++;
nuclear@2 390 }
nuclear@2 391 }
nuclear@2 392
nuclear@2 393 vert_arr[num_verts].x = x;
nuclear@2 394 vert_arr[num_verts].y = y;
nuclear@2 395 vert_arr[num_verts].z = z;
nuclear@2 396 vert_arr[num_verts].w = w;
nuclear@2 397
nuclear@2 398 if(cloc != -1) {
nuclear@2 399 col_arr[num_verts] = cur_color;
nuclear@2 400 }
nuclear@2 401 if(nloc != -1) {
nuclear@2 402 norm_arr[num_verts] = cur_normal;
nuclear@2 403 }
nuclear@2 404 if(tloc != -1) {
nuclear@2 405 texc_arr[num_verts] = cur_texcoord;
nuclear@2 406 }
nuclear@2 407 if(aloc != -1) {
nuclear@2 408 attr_arr[num_verts] = cur_attrib;
nuclear@2 409 }
nuclear@2 410
nuclear@2 411 vert_calls++;
nuclear@2 412 num_verts++;
nuclear@2 413
nuclear@2 414 if(prim == GL_QUADS) {
nuclear@2 415 /* leave space for 6 more worst-case and don't allow flushes mid-quad */
nuclear@2 416 buffer_full = num_verts >= MAX_VERTS - 6 && vert_calls % 4 == 0;
nuclear@2 417 } else {
nuclear@2 418 buffer_full = num_verts >= MAX_VERTS - prim;
nuclear@2 419 }
nuclear@2 420
nuclear@2 421 if(buffer_full) {
nuclear@2 422 gl_draw_immediate();
nuclear@3 423 gl_begin(prim); /* reset everything */
nuclear@2 424 }
nuclear@2 425 }
nuclear@2 426
nuclear@2 427
nuclear@2 428 void gl_normal3f(float x, float y, float z)
nuclear@2 429 {
nuclear@2 430 cur_normal.x = x;
nuclear@2 431 cur_normal.y = y;
nuclear@2 432 cur_normal.z = z;
nuclear@2 433 }
nuclear@2 434
nuclear@2 435
nuclear@2 436 void gl_color3f(float r, float g, float b)
nuclear@2 437 {
nuclear@2 438 cur_color.x = r;
nuclear@2 439 cur_color.y = g;
nuclear@2 440 cur_color.z = b;
nuclear@2 441 cur_color.w = 1.0f;
nuclear@2 442 }
nuclear@2 443
nuclear@2 444 void gl_color4f(float r, float g, float b, float a)
nuclear@2 445 {
nuclear@2 446 cur_color.x = r;
nuclear@2 447 cur_color.y = g;
nuclear@2 448 cur_color.z = b;
nuclear@2 449 cur_color.w = a;
nuclear@2 450 }
nuclear@2 451
nuclear@2 452
nuclear@2 453 void gl_texcoord1f(float s)
nuclear@2 454 {
nuclear@2 455 cur_texcoord.x = s;
nuclear@2 456 cur_texcoord.y = 0.0f;
nuclear@2 457 }
nuclear@2 458
nuclear@2 459 void gl_texcoord2f(float s, float t)
nuclear@2 460 {
nuclear@2 461 cur_texcoord.x = s;
nuclear@2 462 cur_texcoord.y = t;
nuclear@2 463 }
nuclear@2 464
nuclear@2 465 void gl_vertex_attrib2f(int loc, float x, float y)
nuclear@2 466 {
nuclear@2 467 aloc = loc;
nuclear@2 468 cur_attrib.x = x;
nuclear@2 469 cur_attrib.y = y;
nuclear@2 470 cur_attrib.z = 0.0f;
nuclear@2 471 cur_attrib.w = 1.0f;
nuclear@2 472 }
nuclear@2 473
nuclear@2 474 void gl_vertex_attrib3f(int loc, float x, float y, float z)
nuclear@2 475 {
nuclear@2 476 aloc = loc;
nuclear@2 477 cur_attrib.x = x;
nuclear@2 478 cur_attrib.y = y;
nuclear@2 479 cur_attrib.z = z;
nuclear@2 480 cur_attrib.w = 1.0f;
nuclear@2 481 }
nuclear@2 482
nuclear@2 483 void gl_vertex_attrib4f(int loc, float x, float y, float z, float w)
nuclear@2 484 {
nuclear@2 485 aloc = loc;
nuclear@2 486 cur_attrib.x = x;
nuclear@2 487 cur_attrib.y = y;
nuclear@2 488 cur_attrib.z = z;
nuclear@2 489 cur_attrib.w = w;
nuclear@2 490 }