r_shadow.c

   1
   2 #include "quakedef.h"
   3 #include "r_shadow.h"
   4
   5 #define SHADOWSTAGE_NONE 0
   6 #define SHADOWSTAGE_STENCIL 1
   7 #define SHADOWSTAGE_LIGHT 2
   8 #define SHADOWSTAGE_ERASESTENCIL 3
   9
  10 int r_shadowstage = SHADOWSTAGE_NONE;
  11
  12 mempool_t *r_shadow_mempool;
  13
  14 int maxshadowelements;
  15 int *shadowelements;
  16 int maxtrianglefacinglight;
  17 qbyte *trianglefacinglight;
  18
  19 rtexturepool_t *r_shadow_texturepool;
  20 rtexture_t *r_shadow_normalsattenuationtexture;
  21 rtexture_t *r_shadow_normalscubetexture;
  22 rtexture_t *r_shadow_attenuation2dtexture;
  23 rtexture_t *r_shadow_blankbumptexture;
  24
  25 cvar_t r_shadow1 = {0, "r_shadow1", "2"};
  26 cvar_t r_shadow2 = {0, "r_shadow2", "0"};
  27 cvar_t r_shadow3 = {0, "r_shadow3", "32768"};
  28 cvar_t r_shadow4 = {0, "r_shadow4", "0"};
  29 cvar_t r_shadow5 = {0, "r_shadow5", "0"};
  30 cvar_t r_shadow6 = {0, "r_shadow6", "0"};
  31 cvar_t r_light_realtime = {0, "r_light_realtime", "0"};
  32 cvar_t r_light_quality = {0, "r_light_quality", "1"};
  33 cvar_t r_light_gloss = {0, "r_light_gloss", "0"};
  34 cvar_t r_light_debuglight = {0, "r_light_debuglight", "-1"};
  35
  36 void r_shadow_start(void)
  37 {
  38         // allocate vertex processing arrays
  39         r_shadow_mempool = Mem_AllocPool("R_Shadow");
  40         maxshadowelements = 0;
  41         shadowelements = NULL;
  42         maxtrianglefacinglight = 0;
  43         trianglefacinglight = NULL;
  44         r_shadow_normalsattenuationtexture = NULL;
  45         r_shadow_normalscubetexture = NULL;
  46         r_shadow_attenuation2dtexture = NULL;
  47         r_shadow_blankbumptexture = NULL;
  48         r_shadow_texturepool = NULL;
  49 }
  50
  51 void r_shadow_shutdown(void)
  52 {
  53         r_shadow_normalsattenuationtexture = NULL;
  54         r_shadow_normalscubetexture = NULL;
  55         r_shadow_attenuation2dtexture = NULL;
  56         r_shadow_blankbumptexture = NULL;
  57         R_FreeTexturePool(&r_shadow_texturepool);
  58         maxshadowelements = 0;
  59         shadowelements = NULL;
  60         maxtrianglefacinglight = 0;
  61         trianglefacinglight = NULL;
  62         Mem_FreePool(&r_shadow_mempool);
  63 }
  64
  65 void r_shadow_newmap(void)
  66 {
  67 }
  68
  69 void R_Shadow_Init(void)
  70 {
  71         Cvar_RegisterVariable(&r_shadow1);
  72         Cvar_RegisterVariable(&r_shadow2);
  73         Cvar_RegisterVariable(&r_shadow3);
  74         Cvar_RegisterVariable(&r_shadow4);
  75         Cvar_RegisterVariable(&r_shadow5);
  76         Cvar_RegisterVariable(&r_shadow6);
  77         Cvar_RegisterVariable(&r_light_realtime);
  78         Cvar_RegisterVariable(&r_light_quality);
  79         Cvar_RegisterVariable(&r_light_gloss);
  80         Cvar_RegisterVariable(&r_light_debuglight);
  81         R_RegisterModule("R_Shadow", r_shadow_start, r_shadow_shutdown, r_shadow_newmap);
  82 }
  83
  84 void R_Shadow_Volume(int numverts, int numtris, float *vertex, int *elements, int *neighbors, vec3_t relativelightorigin, float lightradius, float projectdistance)
  85 {
  86         int i, *e, *n, *out, tris;
  87         float *v0, *v1, *v2, temp[3], f;
  88         if (projectdistance < 0.1)
  89         {
  90                 Con_Printf("R_Shadow_Volume: projectdistance %f\n");
  91                 return;
  92         }
  93 // terminology:
  94 //
  95 // frontface:
  96 // a triangle facing the light source
  97 //
  98 // backface:
  99 // a triangle not facing the light source
 100 //
 101 // shadow volume:
 102 // an extrusion of the backfaces, beginning at the original geometry and
 103 // ending further from the light source than the original geometry
 104 // (presumably at least as far as the light's radius, if the light has a
 105 // radius at all), capped at both front and back to avoid any problems
 106 //
 107 // description:
 108 // draws the shadow volumes of the model.
 109 // requirements:
 110 // vertex loations must already be in vertex before use.
 111 // vertex must have capacity for numverts * 2.
 112
 113         // make sure trianglefacinglight is big enough for this volume
 114         if (maxtrianglefacinglight < numtris)
 115         {
 116                 maxtrianglefacinglight = numtris;
 117                 if (trianglefacinglight)
 118                         Mem_Free(trianglefacinglight);
 119                 trianglefacinglight = Mem_Alloc(r_shadow_mempool, maxtrianglefacinglight);
 120         }
 121
 122         // make sure shadowelements is big enough for this volume
 123         if (maxshadowelements < numtris * 24)
 124         {
 125                 maxshadowelements = numtris * 24;
 126                 if (shadowelements)
 127                         Mem_Free(shadowelements);
 128                 shadowelements = Mem_Alloc(r_shadow_mempool, maxshadowelements * sizeof(int));
 129         }
 130
 131         // make projected vertices
 132         // by clever use of elements we'll construct the whole shadow from
 133         // the unprojected vertices and these projected vertices
 134         for (i = 0, v0 = vertex, v1 = vertex + numverts * 4;i < numverts;i++, v0 += 4, v1 += 4)
 135         {
 136 #if 1
 137                 v1[0] = v0[0] + 50.0f * (v0[0] - relativelightorigin[0]);
 138                 v1[1] = v0[1] + 50.0f * (v0[1] - relativelightorigin[1]);
 139                 v1[2] = v0[2] + 50.0f * (v0[2] - relativelightorigin[2]);
 140 #elif 0
 141                 VectorSubtract(v0, relativelightorigin, temp);
 142                 f = lightradius / sqrt(DotProduct(temp,temp));
 143                 if (f < 1)
 144                         f = 1;
 145                 VectorMA(relativelightorigin, f, temp, v1);
 146 #else
 147                 VectorSubtract(v0, relativelightorigin, temp);
 148                 f = projectdistance / sqrt(DotProduct(temp,temp));
 149                 VectorMA(v0, f, temp, v1);
 150 #endif
 151         }
 152
 153         // check which triangles are facing the light
 154         for (i = 0, e = elements;i < numtris;i++, e += 3)
 155         {
 156                 // calculate triangle facing flag
 157                 v0 = vertex + e[0] * 4;
 158                 v1 = vertex + e[1] * 4;
 159                 v2 = vertex + e[2] * 4;
 160                 // we do not need to normalize the surface normal because both sides
 161                 // of the comparison use it, therefore they are both multiplied the
 162                 // same amount...  furthermore the subtract can be done on the
 163                 // vectors, saving a little bit of math in the dotproducts
 164 #if 0
 165                 // fast version
 166                 // subtracts v1 from v0 and v2, combined into a crossproduct,
 167                 // combined with a dotproduct of the light location relative to the
 168                 // first point of the triangle (any point works, since the triangle
 169                 // is obviously flat), and finally a comparison to determine if the
 170                 // light is infront of the triangle (the goal of this statement)
 171                 trianglefacinglight[i] =
 172                    (relativelightorigin[0] - v0[0]) * ((v0[1] - v1[1]) * (v2[2] - v1[2]) - (v0[2] - v1[2]) * (v2[1] - v1[1]))
 173                  + (relativelightorigin[1] - v0[1]) * ((v0[2] - v1[2]) * (v2[0] - v1[0]) - (v0[0] - v1[0]) * (v2[2] - v1[2]))
 174                  + (relativelightorigin[2] - v0[2]) * ((v0[0] - v1[0]) * (v2[1] - v1[1]) - (v0[1] - v1[1]) * (v2[0] - v1[0])) > 0;
 175 #else
 176                 // readable version
 177                 {
 178                 float dir0[3], dir1[3];
 179
 180                 // calculate two mostly perpendicular edge directions
 181                 VectorSubtract(v0, v1, dir0);
 182                 VectorSubtract(v2, v1, dir1);
 183
 184                 // we have two edge directions, we can calculate a third vector from
 185                 // them, which is the direction of the surface normal (it's magnitude
 186                 // is not 1 however)
 187                 CrossProduct(dir0, dir1, temp);
 188
 189                 // this is entirely unnecessary, but kept for clarity
 190                 //VectorNormalize(temp);
 191
 192                 // compare distance of light along normal, with distance of any point
 193                 // of the triangle along the same normal (the triangle is planar,
 194                 // I.E. flat, so all points give the same answer)
 195                 // the normal is not normalized because it is used on both sides of
 196                 // the comparison, so it's magnitude does not matter
 197                 //trianglefacinglight[i] = DotProduct(relativelightorigin, temp) >= DotProduct(v0, temp);
 198                 f = DotProduct(relativelightorigin, temp) - DotProduct(v0, temp);
 199                 trianglefacinglight[i] = f > 0 && f < lightradius * sqrt(DotProduct(temp, temp));
 200                 }
 201 #endif
 202         }
 203
 204         // output triangle elements
 205         out = shadowelements;
 206         tris = 0;
 207
 208         // check each backface for bordering frontfaces,
 209         // and cast shadow polygons from those edges,
 210         // also create front and back caps for shadow volume
 211         for (i = 0, e = elements, n = neighbors;i < numtris;i++, e += 3, n += 3)
 212         {
 213                 if (!trianglefacinglight[i])
 214                 {
 215                         // triangle is backface and therefore casts shadow,
 216                         // output front and back caps for shadow volume
 217 #if 1
 218                         // front cap (with flipped winding order)
 219                         out[0] = e[0];
 220                         out[1] = e[2];
 221                         out[2] = e[1];
 222                         // rear cap
 223                         out[3] = e[0] + numverts;
 224                         out[4] = e[1] + numverts;
 225                         out[5] = e[2] + numverts;
 226                         out += 6;
 227                         tris += 2;
 228 #else if 1
 229                         // rear cap
 230                         out[0] = e[0] + numverts;
 231                         out[1] = e[1] + numverts;
 232                         out[2] = e[2] + numverts;
 233                         out += 3;
 234                         tris += 1;
 235 #endif
 236                         // check the edges
 237                         if (n[0] < 0 || trianglefacinglight[n[0]])
 238                         {
 239                                 out[0] = e[0];
 240                                 out[1] = e[1];
 241                                 out[2] = e[1] + numverts;
 242                                 out[3] = e[0];
 243                                 out[4] = e[1] + numverts;
 244                                 out[5] = e[0] + numverts;
 245                                 out += 6;
 246                                 tris += 2;
 247                         }
 248                         if (n[1] < 0 || trianglefacinglight[n[1]])
 249                         {
 250                                 out[0] = e[1];
 251                                 out[1] = e[2];
 252                                 out[2] = e[2] + numverts;
 253                                 out[3] = e[1];
 254                                 out[4] = e[2] + numverts;
 255                                 out[5] = e[1] + numverts;
 256                                 out += 6;
 257                                 tris += 2;
 258                         }
 259                         if (n[2] < 0 || trianglefacinglight[n[2]])
 260                         {
 261                                 out[0] = e[2];
 262                                 out[1] = e[0];
 263                                 out[2] = e[0] + numverts;
 264                                 out[3] = e[2];
 265                                 out[4] = e[0] + numverts;
 266                                 out[5] = e[2] + numverts;
 267                                 out += 6;
 268                                 tris += 2;
 269                         }
 270                 }
 271         }
 272         R_Shadow_RenderVolume(numverts * 2, tris, shadowelements);
 273 }
 274
 275 void R_Shadow_RenderVolume(int numverts, int numtris, int *elements)
 276 {
 277         if (!numverts || !numtris)
 278                 return;
 279         // draw the volume
 280         if (r_shadowstage == SHADOWSTAGE_STENCIL)
 281         {
 282                 // increment stencil if backface is behind depthbuffer
 283                 qglCullFace(GL_BACK); // quake is backwards, this culls front faces
 284                 qglStencilOp(GL_KEEP, GL_INCR, GL_KEEP);
 285                 R_Mesh_Draw(numverts, numtris, elements);
 286                 // decrement stencil if frontface is behind depthbuffer
 287                 qglCullFace(GL_FRONT); // quake is backwards, this culls back faces
 288                 qglStencilOp(GL_KEEP, GL_DECR, GL_KEEP);
 289                 R_Mesh_Draw(numverts, numtris, elements);
 290         }
 291         else
 292                 R_Mesh_Draw(numverts, numtris, elements);
 293 }
 294
 295 float r_shadow_atten1, r_shadow_atten2, r_shadow_atten5;
 296 #define ATTEN3DSIZE 64
 297 static void R_Shadow_Make3DTextures(void)
 298 {
 299         int x, y, z;
 300         float v[3], intensity, ilen, bordercolor[4];
 301         qbyte *data;
 302         if (r_light_quality.integer != 1 || !gl_texture3d)
 303                 return;
 304         data = Mem_Alloc(tempmempool, ATTEN3DSIZE * ATTEN3DSIZE * ATTEN3DSIZE * 4);
 305         for (z = 0;z < ATTEN3DSIZE;z++)
 306         {
 307                 for (y = 0;y < ATTEN3DSIZE;y++)
 308                 {
 309                         for (x = 0;x < ATTEN3DSIZE;x++)
 310                         {
 311                                 v[0] = (x + 0.5f) * (2.0f / (float) ATTEN3DSIZE) - 1.0f;
 312                                 v[1] = (y + 0.5f) * (2.0f / (float) ATTEN3DSIZE) - 1.0f;
 313                                 v[2] = (z + 0.5f) * (2.0f / (float) ATTEN3DSIZE) - 1.0f;
 314                                 intensity = 1.0f - sqrt(DotProduct(v, v));
 315                                 if (intensity > 0)
 316                                         intensity *= intensity;
 317                                 ilen = 127.0f * bound(0, intensity * r_shadow_atten1, 1) / sqrt(DotProduct(v, v));
 318                                 data[((z*ATTEN3DSIZE+y)*ATTEN3DSIZE+x)*4+0] = 128.0f + ilen * v[0];
 319                                 data[((z*ATTEN3DSIZE+y)*ATTEN3DSIZE+x)*4+1] = 128.0f + ilen * v[1];
 320                                 data[((z*ATTEN3DSIZE+y)*ATTEN3DSIZE+x)*4+2] = 128.0f + ilen * v[2];
 321                                 data[((z*ATTEN3DSIZE+y)*ATTEN3DSIZE+x)*4+3] = 255;
 322                         }
 323                 }
 324         }
 325         r_shadow_normalsattenuationtexture = R_LoadTexture3D(r_shadow_texturepool, "normalsattenuation", ATTEN3DSIZE, ATTEN3DSIZE, ATTEN3DSIZE, data, TEXTYPE_RGBA, TEXF_PRECACHE | TEXF_CLAMP | TEXF_ALWAYSPRECACHE, NULL);
 326         bordercolor[0] = 0.5f;
 327         bordercolor[1] = 0.5f;
 328         bordercolor[2] = 0.5f;
 329         bordercolor[3] = 1.0f;
 330         qglTexParameterfv(GL_TEXTURE_3D, GL_TEXTURE_BORDER_COLOR, bordercolor);
 331         Mem_Free(data);
 332 }
 333
 334 static void R_Shadow_MakeTextures(void)
 335 {
 336         int x, y, d, side;
 337         float v[3], s, t, intensity;
 338         qbyte *data;
 339         data = Mem_Alloc(tempmempool, 6*128*128*4);
 340         R_FreeTexturePool(&r_shadow_texturepool);
 341         r_shadow_texturepool = R_AllocTexturePool();
 342         r_shadow_atten1 = r_shadow1.value;
 343         r_shadow_atten2 = r_shadow2.value;
 344         r_shadow_atten5 = r_shadow5.value;
 345         for (y = 0;y < 128;y++)
 346         {
 347                 for (x = 0;x < 128;x++)
 348                 {
 349                         data[((0*128+y)*128+x)*4+0] = 128;
 350                         data[((0*128+y)*128+x)*4+1] = 128;
 351                         data[((0*128+y)*128+x)*4+2] = 255;
 352                         data[((0*128+y)*128+x)*4+3] = 255;
 353                 }
 354         }
 355         r_shadow_blankbumptexture = R_LoadTexture2D(r_shadow_texturepool, "blankbump", 128, 128, data, TEXTYPE_RGBA, TEXF_PRECACHE, NULL);
 356         for (side = 0;side < 6;side++)
 357         {
 358                 for (y = 0;y < 128;y++)
 359                 {
 360                         for (x = 0;x < 128;x++)
 361                         {
 362                                 s = (x + 0.5f) * (2.0f / 128.0f) - 1.0f;
 363                                 t = (y + 0.5f) * (2.0f / 128.0f) - 1.0f;
 364                                 switch(side)
 365                                 {
 366                                 case 0:
 367                                         v[0] = 1;
 368                                         v[1] = -t;
 369                                         v[2] = -s;
 370                                         break;
 371                                 case 1:
 372                                         v[0] = -1;
 373                                         v[1] = -t;
 374                                         v[2] = s;
 375                                         break;
 376                                 case 2:
 377                                         v[0] = s;
 378                                         v[1] = 1;
 379                                         v[2] = t;
 380                                         break;
 381                                 case 3:
 382                                         v[0] = s;
 383                                         v[1] = -1;
 384                                         v[2] = -t;
 385                                         break;
 386                                 case 4:
 387                                         v[0] = s;
 388                                         v[1] = -t;
 389                                         v[2] = 1;
 390                                         break;
 391                                 case 5:
 392                                         v[0] = -s;
 393                                         v[1] = -t;
 394                                         v[2] = -1;
 395                                         break;
 396                                 }
 397                                 intensity = 127.0f / sqrt(DotProduct(v, v));
 398                                 data[((side*128+y)*128+x)*4+0] = 128.0f + intensity * v[0];
 399                                 data[((side*128+y)*128+x)*4+1] = 128.0f + intensity * v[1];
 400                                 data[((side*128+y)*128+x)*4+2] = 128.0f + intensity * v[2];
 401                                 data[((side*128+y)*128+x)*4+3] = 255;
 402                         }
 403                 }
 404         }
 405         r_shadow_normalscubetexture = R_LoadTextureCubeMap(r_shadow_texturepool, "normalscube", 128, data, TEXTYPE_RGBA, TEXF_PRECACHE | TEXF_CLAMP, NULL);
 406         for (y = 0;y < 128;y++)
 407         {
 408                 for (x = 0;x < 128;x++)
 409                 {
 410                         v[0] = (x + 0.5f) * (2.0f / 128.0f) - 1.0f;
 411                         v[1] = (y + 0.5f) * (2.0f / 128.0f) - 1.0f;
 412                         v[2] = 0;
 413                         intensity = 1.0f - sqrt(DotProduct(v, v));
 414                         if (intensity > 0)
 415                                 intensity *= intensity;
 416                         intensity = bound(0, intensity * r_shadow_atten1 * 256.0f, 255.0f);
 417                         d = bound(0, intensity, 255);
 418                         data[((0*128+y)*128+x)*4+0] = d;
 419                         data[((0*128+y)*128+x)*4+1] = d;
 420                         data[((0*128+y)*128+x)*4+2] = d;
 421                         data[((0*128+y)*128+x)*4+3] = d;
 422                 }
 423         }
 424         r_shadow_attenuation2dtexture = R_LoadTexture2D(r_shadow_texturepool, "attenuation2d", 128, 128, data, TEXTYPE_RGBA, TEXF_PRECACHE | TEXF_CLAMP | TEXF_ALPHA | TEXF_MIPMAP, NULL);
 425         Mem_Free(data);
 426         R_Shadow_Make3DTextures();
 427 }
 428
 429 void R_Shadow_Stage_Begin(void)
 430 {
 431         rmeshstate_t m;
 432
 433         if (r_light_quality.integer == 1 && !gl_texture3d)
 434         {
 435                 Con_Printf("3D texture support not detected, falling back on slower 2D + 1D + normalization lighting\n");
 436                 Cvar_SetValueQuick(&r_light_quality, 0);
 437         }
 438         //cl.worldmodel->numlights = min(cl.worldmodel->numlights, 1);
 439         if (!r_shadow_attenuation2dtexture
 440          || (r_light_quality.integer == 1 && !r_shadow_normalsattenuationtexture)
 441          || r_shadow1.value != r_shadow_atten1
 442          || r_shadow2.value != r_shadow_atten2
 443          || r_shadow5.value != r_shadow_atten5)
 444                 R_Shadow_MakeTextures();
 445
 446         memset(&m, 0, sizeof(m));
 447         m.blendfunc1 = GL_ONE;
 448         m.blendfunc2 = GL_ZERO;
 449         R_Mesh_State(&m);
 450         GL_Color(0, 0, 0, 1);
 451         r_shadowstage = SHADOWSTAGE_NONE;
 452 }
 453
 454 void R_Shadow_Stage_ShadowVolumes(void)
 455 {
 456         rmeshstate_t m;
 457         memset(&m, 0, sizeof(m));
 458         R_Mesh_TextureState(&m);
 459         GL_Color(1, 1, 1, 1);
 460         qglColorMask(0, 0, 0, 0);
 461         qglDisable(GL_BLEND);
 462         qglDepthMask(0);
 463         qglDepthFunc(GL_LESS);
 464         qglClearStencil(0);
 465         qglClear(GL_STENCIL_BUFFER_BIT);
 466         qglEnable(GL_STENCIL_TEST);
 467         qglStencilOp(GL_KEEP, GL_KEEP, GL_KEEP);
 468         qglStencilFunc(GL_ALWAYS, 0, 0xFF);
 469         qglEnable(GL_CULL_FACE);
 470         qglEnable(GL_DEPTH_TEST);
 471         r_shadowstage = SHADOWSTAGE_STENCIL;
 472 }
 473
 474 void R_Shadow_Stage_Light(void)
 475 {
 476         rmeshstate_t m;
 477         memset(&m, 0, sizeof(m));
 478         R_Mesh_TextureState(&m);
 479         qglActiveTexture(GL_TEXTURE0_ARB);
 480
 481         qglEnable(GL_BLEND);
 482         qglBlendFunc(GL_ONE, GL_ONE);
 483         GL_Color(1, 1, 1, 1);
 484         qglColorMask(1, 1, 1, 1);
 485         qglDepthMask(0);
 486         qglDepthFunc(GL_EQUAL);
 487         qglEnable(GL_STENCIL_TEST);
 488         qglStencilOp(GL_KEEP, GL_KEEP, GL_KEEP);
 489         // only draw light where this geometry was already rendered AND the
 490         // stencil is 0 (non-zero means shadow)
 491         qglStencilFunc(GL_EQUAL, 0, 0xFF);
 492         qglEnable(GL_CULL_FACE);
 493         qglEnable(GL_DEPTH_TEST);
 494         r_shadowstage = SHADOWSTAGE_LIGHT;
 495 }
 496
 497 void R_Shadow_Stage_EraseShadowVolumes(void)
 498 {
 499         rmeshstate_t m;
 500         memset(&m, 0, sizeof(m));
 501         R_Mesh_TextureState(&m);
 502         GL_Color(1, 1, 1, 1);
 503         qglColorMask(0, 0, 0, 0);
 504         qglDisable(GL_BLEND);
 505         qglDepthMask(0);
 506         qglDepthFunc(GL_LESS);
 507         qglClearStencil(0);
 508         qglClear(GL_STENCIL_BUFFER_BIT);
 509         qglEnable(GL_STENCIL_TEST);
 510         qglStencilOp(GL_ZERO, GL_KEEP, GL_KEEP);
 511         qglStencilFunc(GL_NOTEQUAL, 0, 0xFF);
 512         qglDisable(GL_CULL_FACE);
 513         qglDisable(GL_DEPTH_TEST);
 514         r_shadowstage = SHADOWSTAGE_ERASESTENCIL;
 515 }
 516
 517 void R_Shadow_Stage_End(void)
 518 {
 519         // attempt to restore state to what Mesh_State thinks it is
 520         qglDisable(GL_BLEND);
 521         qglBlendFunc(GL_ONE, GL_ZERO);
 522         qglDepthMask(1);
 523         // now restore the rest of the state to normal
 524         GL_Color(1, 1, 1, 1);
 525         qglColorMask(1, 1, 1, 1);
 526         qglDepthFunc(GL_LEQUAL);
 527         qglDisable(GL_STENCIL_TEST);
 528         qglStencilOp(GL_KEEP, GL_KEEP, GL_KEEP);
 529         qglStencilFunc(GL_ALWAYS, 0, 0xFF);
 530         qglEnable(GL_CULL_FACE);
 531         qglEnable(GL_DEPTH_TEST);
 532         r_shadowstage = SHADOWSTAGE_NONE;
 533 }
 534
 535 void R_Shadow_GenTexCoords_Attenuation2D1D(float *out2d, float *out1d, int numverts, const float *vertex, const float *svectors, const float *tvectors, const float *normals, const vec3_t relativelightorigin, float lightradius)
 536 {
 537         int i;
 538         float lightvec[3], iradius;
 539         iradius = 0.5f / lightradius;
 540         for (i = 0;i < numverts;i++, vertex += 4, svectors += 4, tvectors += 4, normals += 4, out2d += 4, out1d += 4)
 541         {
 542                 VectorSubtract(vertex, relativelightorigin, lightvec);
 543                 out2d[0] = 0.5f + DotProduct(svectors, lightvec) * iradius;
 544                 out2d[1] = 0.5f + DotProduct(tvectors, lightvec) * iradius;
 545                 out2d[2] = 0;
 546                 out1d[0] = 0.5f + DotProduct(normals, lightvec) * iradius;
 547                 out1d[1] = 0.5f;
 548                 out1d[2] = 0;
 549         }
 550 }
 551
 552 void R_Shadow_GenTexCoords_Diffuse_Attenuation3D(float *out, int numverts, const float *vertex, const float *svectors, const float *tvectors, const float *normals, const vec3_t relativelightorigin, float lightradius)
 553 {
 554         int i;
 555         float lightvec[3], iradius;
 556         iradius = 0.5f / lightradius;
 557         for (i = 0;i < numverts;i++, vertex += 4, svectors += 4, tvectors += 4, normals += 4, out += 4)
 558         {
 559                 VectorSubtract(vertex, relativelightorigin, lightvec);
 560                 out[0] = 0.5f + DotProduct(svectors, lightvec) * iradius;
 561                 out[1] = 0.5f + DotProduct(tvectors, lightvec) * iradius;
 562                 out[2] = 0.5f + DotProduct(normals, lightvec) * iradius;
 563         }
 564 }
 565
 566 void R_Shadow_GenTexCoords_Diffuse_NormalCubeMap(float *out, int numverts, const float *vertex, const float *svectors, const float *tvectors, const float *normals, const vec3_t relativelightorigin)
 567 {
 568         int i;
 569         float lightdir[3];
 570         for (i = 0;i < numverts;i++, vertex += 4, svectors += 4, tvectors += 4, normals += 4, out += 4)
 571         {
 572                 VectorSubtract(vertex, relativelightorigin, lightdir);
 573                 // the cubemap normalizes this for us
 574                 out[0] = DotProduct(svectors, lightdir);
 575                 out[1] = DotProduct(tvectors, lightdir);
 576                 out[2] = DotProduct(normals, lightdir);
 577         }
 578 }
 579
 580 void R_Shadow_GenTexCoords_Specular_Attenuation3D(float *out, int numverts, const float *vertex, const float *svectors, const float *tvectors, const float *normals, const vec3_t relativelightorigin, const vec3_t relativeeyeorigin, float lightradius)
 581 {
 582         int i;
 583         float lightdir[3], eyedir[3], halfdir[3], lightdirlen, iradius;
 584         iradius = 0.5f / lightradius;
 585         for (i = 0;i < numverts;i++, vertex += 4, svectors += 4, tvectors += 4, normals += 4, out += 4)
 586         {
 587                 VectorSubtract(vertex, relativelightorigin, lightdir);
 588                 // this is used later to make the attenuation correct
 589                 lightdirlen = sqrt(DotProduct(lightdir, lightdir)) * iradius;
 590                 VectorNormalizeFast(lightdir);
 591                 VectorSubtract(vertex, relativeeyeorigin, eyedir);
 592                 VectorNormalizeFast(eyedir);
 593                 VectorAdd(lightdir, eyedir, halfdir);
 594                 VectorNormalizeFast(halfdir);
 595                 out[0] = 0.5f + DotProduct(svectors, halfdir) * lightdirlen;
 596                 out[1] = 0.5f + DotProduct(tvectors, halfdir) * lightdirlen;
 597                 out[2] = 0.5f + DotProduct(normals, halfdir) * lightdirlen;
 598         }
 599 }
 600
 601 void R_Shadow_GenTexCoords_Specular_NormalCubeMap(float *out, int numverts, const float *vertex, const float *svectors, const float *tvectors, const float *normals, const vec3_t relativelightorigin, const vec3_t relativeeyeorigin)
 602 {
 603         int i;
 604         float lightdir[3], eyedir[3], halfdir[3];
 605         for (i = 0;i < numverts;i++, vertex += 4, svectors += 4, tvectors += 4, normals += 4, out += 4)
 606         {
 607                 VectorSubtract(vertex, relativelightorigin, lightdir);
 608                 VectorNormalizeFast(lightdir);
 609                 VectorSubtract(vertex, relativeeyeorigin, eyedir);
 610                 VectorNormalizeFast(eyedir);
 611                 VectorAdd(lightdir, eyedir, halfdir);
 612                 // the cubemap normalizes this for us
 613                 out[0] = DotProduct(svectors, halfdir);
 614                 out[1] = DotProduct(tvectors, halfdir);
 615                 out[2] = DotProduct(normals, halfdir);
 616         }
 617 }
 618
 619 void R_Shadow_GenTexCoords_LightCubeMap(float *out, int numverts, const float *vertex, const vec3_t relativelightorigin)
 620 {
 621         int i;
 622         // FIXME: this needs to be written
 623         // this code assumes the vertices are in worldspace (a false assumption)
 624         for (i = 0;i < numverts;i++, vertex += 4, out += 4)
 625                 VectorSubtract(vertex, relativelightorigin, out);
 626 }
 627
 628 void R_Shadow_RenderLighting(int numverts, int numtriangles, const int *elements, const float *svectors, const float *tvectors, const float *normals, const float *texcoords, const float *relativelightorigin, const float *relativeeyeorigin, float lightradius, const float *lightcolor, rtexture_t *basetexture, rtexture_t *glosstexture, rtexture_t *bumptexture, rtexture_t *lightcubemap)
 629 {
 630         int mult;
 631         float scale, colorscale;
 632         rmeshstate_t m;
 633         memset(&m, 0, sizeof(m));
 634         if (!bumptexture)
 635                 bumptexture = r_shadow_blankbumptexture;
 636         // colorscale accounts for how much we multiply the brightness during combine
 637         if (r_light_quality.integer == 1)
 638         {
 639                 if (r_textureunits.integer >= 4)
 640                         colorscale = r_colorscale * 0.125f / r_shadow3.value;
 641                 else
 642                         colorscale = r_colorscale * 0.5f / r_shadow3.value;
 643         }
 644         else
 645                 colorscale = r_colorscale * 0.5f / r_shadow3.value;
 646         // limit mult to 64 for sanity sake
 647         for (mult = 1, scale = ixtable[mult];mult < 64 && (lightcolor[0] * scale * colorscale > 1 || lightcolor[1] * scale * colorscale > 1 || lightcolor[2] * scale * colorscale > 1);mult++, scale = ixtable[mult]);
 648         colorscale *= scale;
 649         for (;mult > 0;mult--)
 650         {
 651                 if (r_light_quality.integer == 1)
 652                 {
 653                         if (r_textureunits.integer >= 4)
 654                         {
 655                                 // 4 texture 3D path, two pass
 656                                 m.tex[0] = R_GetTexture(bumptexture);
 657                                 m.tex3d[1] = R_GetTexture(r_shadow_normalsattenuationtexture);
 658                                 m.tex[2] = R_GetTexture(basetexture);
 659                                 m.texcubemap[3] = R_GetTexture(lightcubemap);
 660                                 m.tex[3] = R_GetTexture(r_notexture);
 661                                 m.texcombinergb[0] = GL_REPLACE;
 662                                 m.texcombinergb[1] = GL_DOT3_RGB_ARB;
 663                                 m.texcombinergb[2] = GL_MODULATE;
 664                                 m.texcombinergb[3] = GL_MODULATE;
 665                                 m.texrgbscale[1] = 2;
 666                                 m.texrgbscale[3] = 4;
 667                                 R_Mesh_TextureState(&m);
 668                                 GL_Color(lightcolor[0] * colorscale, lightcolor[1] * colorscale, lightcolor[2] * colorscale, 1);
 669                                 memcpy(varray_texcoord[0], texcoords, numverts * sizeof(float[4]));
 670                                 memcpy(varray_texcoord[2], texcoords, numverts * sizeof(float[4]));
 671                                 if (lightcubemap)
 672                                         R_Shadow_GenTexCoords_LightCubeMap(varray_texcoord[3], numverts, varray_vertex, relativelightorigin);
 673                                 else
 674                                 {
 675                                         qglActiveTexture(GL_TEXTURE3_ARB);
 676                                         qglTexEnvi(GL_TEXTURE_ENV, GL_SOURCE0_RGB_ARB, GL_PRIMARY_COLOR_ARB);
 677                                 }
 678                                 R_Shadow_GenTexCoords_Diffuse_Attenuation3D(varray_texcoord[1], numverts, varray_vertex, svectors, tvectors, normals, relativelightorigin, lightradius);
 679                                 R_Mesh_Draw(numverts, numtriangles, elements);
 680                                 if (!lightcubemap)
 681                                 {
 682                                         qglActiveTexture(GL_TEXTURE3_ARB);
 683                                         qglTexEnvi(GL_TEXTURE_ENV, GL_SOURCE0_RGB_ARB, GL_TEXTURE);
 684                                 }
 685                                 if (r_light_gloss.integer && glosstexture)
 686                                 {
 687                                         m.tex[2] = R_GetTexture(glosstexture);
 688                                         R_Mesh_TextureState(&m);
 689                                         R_Shadow_GenTexCoords_Specular_Attenuation3D(varray_texcoord[1], numverts, varray_vertex, svectors, tvectors, normals, relativelightorigin, relativeeyeorigin, lightradius);
 690                                         if (!lightcubemap)
 691                                         {
 692                                                 qglActiveTexture(GL_TEXTURE3_ARB);
 693                                                 qglTexEnvi(GL_TEXTURE_ENV, GL_SOURCE0_RGB_ARB, GL_PRIMARY_COLOR_ARB);
 694                                         }
 695                                         R_Mesh_Draw(numverts, numtriangles, elements);
 696                                         if (!lightcubemap)
 697                                         {
 698                                                 qglActiveTexture(GL_TEXTURE3_ARB);
 699                                                 qglTexEnvi(GL_TEXTURE_ENV, GL_SOURCE0_RGB_ARB, GL_TEXTURE);
 700                                         }
 701                                 }
 702                         }
 703                         else
 704                         {
 705                                 // 2 texture 3D path, four pass
 706                                 m.tex[0] = R_GetTexture(bumptexture);
 707                                 m.tex3d[1] = R_GetTexture(r_shadow_normalsattenuationtexture);
 708                                 m.texcombinergb[1] = GL_DOT3_RGBA_ARB;
 709                                 m.texalphascale[1] = 2;
 710                                 R_Mesh_TextureState(&m);
 711                                 qglColorMask(0,0,0,1);
 712                                 qglDisable(GL_BLEND);
 713                                 GL_Color(1,1,1,1);
 714                                 memcpy(varray_texcoord[0], texcoords, numverts * sizeof(float[4]));
 715                                 R_Shadow_GenTexCoords_Diffuse_Attenuation3D(varray_texcoord[1], numverts, varray_vertex, svectors, tvectors, normals, relativelightorigin, lightradius);
 716                                 R_Mesh_Draw(numverts, numtriangles, elements);
 717
 718                                 m.tex[0] = R_GetTexture(basetexture);
 719                                 m.tex3d[1] = 0;
 720                                 m.texcubemap[1] = R_GetTexture(lightcubemap);
 721                                 m.texcombinergb[1] = GL_MODULATE;
 722                                 m.texrgbscale[1] = 1;
 723                                 m.texalphascale[1] = 1;
 724                                 R_Mesh_TextureState(&m);
 725                                 qglColorMask(1,1,1,1);
 726                                 qglBlendFunc(GL_DST_ALPHA, GL_ONE);
 727                                 qglEnable(GL_BLEND);
 728                                 GL_Color(lightcolor[0] * colorscale, lightcolor[1] * colorscale, lightcolor[2] * colorscale, 1);
 729                                 if (lightcubemap)
 730                                         R_Shadow_GenTexCoords_LightCubeMap(varray_texcoord[1], numverts, varray_vertex, relativelightorigin);
 731                                 R_Mesh_Draw(numverts, numtriangles, elements);
 732                         }
 733                 }
 734                 else
 735                 {
 736                         // 2 texture no3D path, six pass
 737                         m.tex[0] = R_GetTexture(r_shadow_attenuation2dtexture);
 738                         m.tex[1] = R_GetTexture(r_shadow_attenuation2dtexture);
 739                         R_Mesh_TextureState(&m);
 740                         qglColorMask(0,0,0,1);
 741                         qglDisable(GL_BLEND);
 742                         GL_Color(1,1,1,1);
 743                         R_Shadow_GenTexCoords_Attenuation2D1D(varray_texcoord[0], varray_texcoord[1], numverts, varray_vertex, svectors, tvectors, normals, relativelightorigin, lightradius);
 744                         R_Mesh_Draw(numverts, numtriangles, elements);
 745
 746                         m.tex[0] = R_GetTexture(bumptexture);
 747                         m.tex[1] = 0;
 748                         m.texcubemap[1] = R_GetTexture(r_shadow_normalscubetexture);
 749                         m.texcombinergb[1] = GL_DOT3_RGBA_ARB;
 750                         m.texalphascale[1] = 2;
 751                         R_Mesh_TextureState(&m);
 752                         qglBlendFunc(GL_DST_ALPHA, GL_ZERO);
 753                         qglEnable(GL_BLEND);
 754                         memcpy(varray_texcoord[0], texcoords, numverts * sizeof(float[4]));
 755                         R_Shadow_GenTexCoords_Diffuse_NormalCubeMap(varray_texcoord[1], numverts, varray_vertex, svectors, tvectors, normals, relativelightorigin);
 756                         R_Mesh_Draw(numverts, numtriangles, elements);
 757
 758                         m.tex[0] = R_GetTexture(basetexture);
 759                         m.texcubemap[1] = R_GetTexture(lightcubemap);
 760                         m.texcombinergb[1] = GL_MODULATE;
 761                         m.texrgbscale[1] = 1;
 762                         m.texalphascale[1] = 1;
 763                         R_Mesh_TextureState(&m);
 764                         qglColorMask(1,1,1,1);
 765                         qglBlendFunc(GL_DST_ALPHA, GL_ONE);
 766                         GL_Color(lightcolor[0] * colorscale, lightcolor[1] * colorscale, lightcolor[2] * colorscale, 1);
 767                         if (lightcubemap)
 768                                 R_Shadow_GenTexCoords_LightCubeMap(varray_texcoord[1], numverts, varray_vertex, relativelightorigin);
 769                         R_Mesh_Draw(numverts, numtriangles, elements);
 770                 }
 771         }
 772 }
 773