// r_main.c
#include "quakedef.h"
+#include "cl_dyntexture.h"
#include "r_shadow.h"
#include "polygon.h"
+#include "image.h"
mempool_t *r_main_mempool;
rtexturepool_t *r_main_texturepool;
r_view_t r_view;
r_viewcache_t r_viewcache;
+cvar_t r_depthfirst = {CVAR_SAVE, "r_depthfirst", "1", "renders a depth-only version of the scene before normal rendering begins to eliminate overdraw, values: 0 = off, 1 = world depth, 2 = world and model depth"};
cvar_t r_nearclip = {0, "r_nearclip", "1", "distance from camera of nearclip plane" };
+cvar_t r_showbboxes = {0, "r_showbboxes", "0", "shows bounding boxes of server entities, value controls opacity scaling (1 = 10%, 10 = 100%)"};
cvar_t r_showsurfaces = {0, "r_showsurfaces", "0", "1 shows surfaces as different colors, or a value of 2 shows triangle draw order (for analyzing whether meshes are optimized for vertex cache)"};
cvar_t r_showtris = {0, "r_showtris", "0", "shows triangle outlines, value controls brightness (can be above 1)"};
cvar_t r_shownormals = {0, "r_shownormals", "0", "shows per-vertex surface normals and tangent vectors for bumpmapped lighting"};
cvar_t r_drawportals = {0, "r_drawportals", "0", "shows portals (separating polygons) in world interior in quake1 maps"};
cvar_t r_drawentities = {0, "r_drawentities","1", "draw entities (doors, players, projectiles, etc)"};
cvar_t r_drawviewmodel = {0, "r_drawviewmodel","1", "draw your weapon model"};
+cvar_t r_cullentities_trace = {0, "r_cullentities_trace", "1", "probabistically cull invisible entities"};
+cvar_t r_cullentities_trace_samples = {0, "r_cullentities_trace_samples", "2", "number of samples to test for entity culling"};
+cvar_t r_cullentities_trace_enlarge = {0, "r_cullentities_trace_enlarge", "0", "box enlargement for entity culling"};
+cvar_t r_cullentities_trace_delay = {0, "r_cullentities_trace_delay", "1", "number of seconds until the entity gets actually culled"};
cvar_t r_speeds = {0, "r_speeds","0", "displays rendering statistics and per-subsystem timings"};
-cvar_t r_fullbright = {0, "r_fullbright","0", "make everything bright cheat (not allowed in multiplayer)"};
+cvar_t r_fullbright = {0, "r_fullbright","0", "makes map very bright and renders faster"};
cvar_t r_wateralpha = {CVAR_SAVE, "r_wateralpha","1", "opacity of water polygons"};
cvar_t r_dynamic = {CVAR_SAVE, "r_dynamic","1", "enables dynamic lights (rocket glow and such)"};
cvar_t r_fullbrights = {CVAR_SAVE, "r_fullbrights", "1", "enables glowing pixels in quake textures (changes need r_restart to take effect)"};
cvar_t r_shadows = {CVAR_SAVE, "r_shadows", "0", "casts fake stencil shadows from models onto the world (rtlights are unaffected by this)"};
cvar_t r_shadows_throwdistance = {CVAR_SAVE, "r_shadows_throwdistance", "500", "how far to cast shadows from models"};
-cvar_t r_q1bsp_skymasking = {0, "r_qb1sp_skymasking", "1", "allows sky polygons in quake1 maps to obscure other geometry"};
+cvar_t r_q1bsp_skymasking = {0, "r_q1bsp_skymasking", "1", "allows sky polygons in quake1 maps to obscure other geometry"};
+cvar_t r_polygonoffset_submodel_factor = {0, "r_polygonoffset_submodel_factor", "0", "biases depth values of world submodels such as doors, to prevent z-fighting artifacts in Quake maps"};
+cvar_t r_polygonoffset_submodel_offset = {0, "r_polygonoffset_submodel_offset", "2", "biases depth values of world submodels such as doors, to prevent z-fighting artifacts in Quake maps"};
cvar_t gl_fogenable = {0, "gl_fogenable", "0", "nehahra fog enable (for Nehahra compatibility only)"};
cvar_t gl_fogdensity = {0, "gl_fogdensity", "0.25", "nehahra fog density (recommend values below 0.1) (for Nehahra compatibility only)"};
cvar_t r_textureunits = {0, "r_textureunits", "32", "number of hardware texture units reported by driver (note: setting this to 1 turns off gl_combine)"};
-cvar_t r_glsl = {0, "r_glsl", "1", "enables use of OpenGL 2.0 pixel shaders for lighting"};
-cvar_t r_glsl_offsetmapping = {0, "r_glsl_offsetmapping", "0", "offset mapping effect (also known as parallax mapping or virtual displacement mapping)"};
-cvar_t r_glsl_offsetmapping_reliefmapping = {0, "r_glsl_offsetmapping_reliefmapping", "0", "relief mapping effect (higher quality)"};
-cvar_t r_glsl_offsetmapping_scale = {0, "r_glsl_offsetmapping_scale", "0.04", "how deep the offset mapping effect is"};
-cvar_t r_glsl_deluxemapping = {0, "r_glsl_deluxemapping", "1", "use per pixel lighting on deluxemap-compiled q3bsp maps (or a value of 2 forces deluxemap shading even without deluxemaps)"};
+cvar_t r_glsl = {CVAR_SAVE, "r_glsl", "1", "enables use of OpenGL 2.0 pixel shaders for lighting"};
+cvar_t r_glsl_offsetmapping = {CVAR_SAVE, "r_glsl_offsetmapping", "0", "offset mapping effect (also known as parallax mapping or virtual displacement mapping)"};
+cvar_t r_glsl_offsetmapping_reliefmapping = {CVAR_SAVE, "r_glsl_offsetmapping_reliefmapping", "0", "relief mapping effect (higher quality)"};
+cvar_t r_glsl_offsetmapping_scale = {CVAR_SAVE, "r_glsl_offsetmapping_scale", "0.04", "how deep the offset mapping effect is"};
+cvar_t r_glsl_deluxemapping = {CVAR_SAVE, "r_glsl_deluxemapping", "1", "use per pixel lighting on deluxemap-compiled q3bsp maps (or a value of 2 forces deluxemap shading even without deluxemaps)"};
+cvar_t r_glsl_contrastboost = {CVAR_SAVE, "r_glsl_contrastboost", "1", "by how much to multiply the contrast in dark areas (1 is no change)"};
+
+cvar_t r_water = {CVAR_SAVE, "r_water", "0", "whether to use reflections and refraction on water surfaces (note: r_wateralpha must be set below 1)"};
+cvar_t r_water_clippingplanebias = {CVAR_SAVE, "r_water_clippingplanebias", "1", "a rather technical setting which avoids black pixels around water edges"};
+cvar_t r_water_resolutionmultiplier = {CVAR_SAVE, "r_water_resolutionmultiplier", "0.5", "multiplier for screen resolution when rendering refracted/reflected scenes, 1 is full quality, lower values are faster"};
+cvar_t r_water_refractdistort = {CVAR_SAVE, "r_water_refractdistort", "0.01", "how much water refractions shimmer"};
+cvar_t r_water_reflectdistort = {CVAR_SAVE, "r_water_reflectdistort", "0.01", "how much water reflections shimmer"};
cvar_t r_lerpsprites = {CVAR_SAVE, "r_lerpsprites", "1", "enables animation smoothing on sprites (requires r_lerpmodels 1)"};
cvar_t r_lerpmodels = {CVAR_SAVE, "r_lerpmodels", "1", "enables animation smoothing on models"};
cvar_t gl_lightmaps = {0, "gl_lightmaps", "0", "draws only lightmaps, no texture (for level designers)"};
-cvar_t r_test = {0, "r_test", "0", "internal development use only, leave it alone (usually does nothing anyway)"}; // used for testing renderer code changes, otherwise does nothing
+cvar_t r_test = {0, "r_test", "0", "internal development use only, leave it alone (usually does nothing anyway)"};
cvar_t r_batchmode = {0, "r_batchmode", "1", "selects method of rendering multiple surfaces with one driver call (values are 0, 1, 2, etc...)"};
+cvar_t r_track_sprites = {CVAR_SAVE, "r_track_sprites", "1", "track SPR_LABEL* sprites by putting them as indicator at the screen border to rotate to"};
+cvar_t r_track_sprites_flags = {CVAR_SAVE, "r_track_sprites_flags", "1", "1: Rotate sprites accodringly, 2: Make it a continuous rotation"};
+cvar_t r_track_sprites_scalew = {CVAR_SAVE, "r_track_sprites_scalew", "1", "width scaling of tracked sprites"};
+cvar_t r_track_sprites_scaleh = {CVAR_SAVE, "r_track_sprites_scaleh", "1", "height scaling of tracked sprites"};
+
+extern qboolean v_flipped_state;
typedef struct r_glsl_bloomshader_s
{
}
r_bloomstate;
+typedef struct r_waterstate_waterplane_s
+{
+ rtexture_t *texture_refraction;
+ rtexture_t *texture_reflection;
+ mplane_t plane;
+ int materialflags; // combined flags of all water surfaces on this plane
+ unsigned char pvsbits[(32768+7)>>3]; // FIXME: buffer overflow on huge maps
+ qboolean pvsvalid;
+}
+r_waterstate_waterplane_t;
+
+#define MAX_WATERPLANES 16
+
+static struct r_waterstate_s
+{
+ qboolean enabled;
+
+ qboolean renderingscene; // true while rendering a refraction or reflection texture, disables water surfaces
+
+ int waterwidth, waterheight;
+ int texturewidth, textureheight;
+
+ int maxwaterplanes; // same as MAX_WATERPLANES
+ int numwaterplanes;
+ r_waterstate_waterplane_t waterplanes[MAX_WATERPLANES];
+
+ float screenscale[2];
+ float screencenter[2];
+}
+r_waterstate;
+
// shadow volume bsp struct with automatically growing nodes buffer
svbsp_t r_svbsp;
rtexture_t *r_texture_blanknormalmap;
rtexture_t *r_texture_white;
+rtexture_t *r_texture_grey128;
rtexture_t *r_texture_black;
rtexture_t *r_texture_notexture;
rtexture_t *r_texture_whitecube;
rtexture_t *r_texture_fogattenuation;
//rtexture_t *r_texture_fogintensity;
-// information about each possible shader permutation
-r_glsl_permutation_t r_glsl_permutations[SHADERPERMUTATION_COUNT];
-// currently selected permutation
-r_glsl_permutation_t *r_glsl_permutation;
-
-// temporary variable used by a macro
-int fogtableindex;
+char r_qwskincache[MAX_SCOREBOARD][MAX_QPATH];
+skinframe_t *r_qwskincache_skinframe[MAX_SCOREBOARD];
// vertex coordinates for a quad that covers the screen exactly
const static float r_screenvertex3f[12] =
r_refdef.fog_density = r_refdef.fog_red = r_refdef.fog_green = r_refdef.fog_blue = 0.0f;
}
-// FIXME: move this to client?
-void FOG_registercvars(void)
+float FogPoint_World(const vec3_t p)
{
- int x;
- double r, alpha;
-
- if (gamemode == GAME_NEHAHRA)
- {
- Cvar_RegisterVariable (&gl_fogenable);
- Cvar_RegisterVariable (&gl_fogdensity);
- Cvar_RegisterVariable (&gl_fogred);
- Cvar_RegisterVariable (&gl_foggreen);
- Cvar_RegisterVariable (&gl_fogblue);
- Cvar_RegisterVariable (&gl_fogstart);
- Cvar_RegisterVariable (&gl_fogend);
- }
+ unsigned int fogmasktableindex = (unsigned int)(VectorDistance((p), r_view.origin) * r_refdef.fogmasktabledistmultiplier);
+ return r_refdef.fogmasktable[min(fogmasktableindex, FOGMASKTABLEWIDTH - 1)];
+}
- r = (-1.0/256.0) * (FOGTABLEWIDTH * FOGTABLEWIDTH);
- for (x = 0;x < FOGTABLEWIDTH;x++)
- {
- alpha = exp(r / ((double)x*(double)x));
- if (x == FOGTABLEWIDTH - 1)
- alpha = 1;
- r_refdef.fogtable[x] = bound(0, alpha, 1);
- }
+float FogPoint_Model(const vec3_t p)
+{
+ unsigned int fogmasktableindex = (unsigned int)(VectorDistance((p), rsurface.modelorg) * r_refdef.fogmasktabledistmultiplier);
+ return r_refdef.fogmasktable[min(fogmasktableindex, FOGMASKTABLEWIDTH - 1)];
}
static void R_BuildBlankTextures(void)
{
unsigned char data[4];
- data[0] = 128; // normal X
+ data[2] = 128; // normal X
data[1] = 128; // normal Y
- data[2] = 255; // normal Z
+ data[0] = 255; // normal Z
data[3] = 128; // height
- r_texture_blanknormalmap = R_LoadTexture2D(r_main_texturepool, "blankbump", 1, 1, data, TEXTYPE_RGBA, TEXF_PRECACHE, NULL);
+ r_texture_blanknormalmap = R_LoadTexture2D(r_main_texturepool, "blankbump", 1, 1, data, TEXTYPE_BGRA, TEXF_PRECACHE | TEXF_PERSISTENT, NULL);
data[0] = 255;
data[1] = 255;
data[2] = 255;
data[3] = 255;
- r_texture_white = R_LoadTexture2D(r_main_texturepool, "blankwhite", 1, 1, data, TEXTYPE_RGBA, TEXF_PRECACHE, NULL);
+ r_texture_white = R_LoadTexture2D(r_main_texturepool, "blankwhite", 1, 1, data, TEXTYPE_BGRA, TEXF_PRECACHE | TEXF_PERSISTENT, NULL);
+ data[0] = 128;
+ data[1] = 128;
+ data[2] = 128;
+ data[3] = 255;
+ r_texture_grey128 = R_LoadTexture2D(r_main_texturepool, "blankgrey128", 1, 1, data, TEXTYPE_BGRA, TEXF_PRECACHE | TEXF_PERSISTENT, NULL);
data[0] = 0;
data[1] = 0;
data[2] = 0;
data[3] = 255;
- r_texture_black = R_LoadTexture2D(r_main_texturepool, "blankblack", 1, 1, data, TEXTYPE_RGBA, TEXF_PRECACHE, NULL);
+ r_texture_black = R_LoadTexture2D(r_main_texturepool, "blankblack", 1, 1, data, TEXTYPE_BGRA, TEXF_PRECACHE | TEXF_PERSISTENT, NULL);
}
static void R_BuildNoTexture(void)
}
}
}
- r_texture_notexture = R_LoadTexture2D(r_main_texturepool, "notexture", 16, 16, &pix[0][0][0], TEXTYPE_RGBA, TEXF_MIPMAP, NULL);
+ r_texture_notexture = R_LoadTexture2D(r_main_texturepool, "notexture", 16, 16, &pix[0][0][0], TEXTYPE_BGRA, TEXF_MIPMAP | TEXF_PERSISTENT, NULL);
}
static void R_BuildWhiteCube(void)
{
unsigned char data[6*1*1*4];
- data[ 0] = 255;data[ 1] = 255;data[ 2] = 255;data[ 3] = 255;
- data[ 4] = 255;data[ 5] = 255;data[ 6] = 255;data[ 7] = 255;
- data[ 8] = 255;data[ 9] = 255;data[10] = 255;data[11] = 255;
- data[12] = 255;data[13] = 255;data[14] = 255;data[15] = 255;
- data[16] = 255;data[17] = 255;data[18] = 255;data[19] = 255;
- data[20] = 255;data[21] = 255;data[22] = 255;data[23] = 255;
- r_texture_whitecube = R_LoadTextureCubeMap(r_main_texturepool, "whitecube", 1, data, TEXTYPE_RGBA, TEXF_PRECACHE | TEXF_CLAMP, NULL);
+ memset(data, 255, sizeof(data));
+ r_texture_whitecube = R_LoadTextureCubeMap(r_main_texturepool, "whitecube", 1, data, TEXTYPE_BGRA, TEXF_PRECACHE | TEXF_CLAMP | TEXF_PERSISTENT, NULL);
}
static void R_BuildNormalizationCube(void)
break;
}
intensity = 127.0f / sqrt(DotProduct(v, v));
- data[side][y][x][0] = (unsigned char)(128.0f + intensity * v[0]);
+ data[side][y][x][2] = (unsigned char)(128.0f + intensity * v[0]);
data[side][y][x][1] = (unsigned char)(128.0f + intensity * v[1]);
- data[side][y][x][2] = (unsigned char)(128.0f + intensity * v[2]);
+ data[side][y][x][0] = (unsigned char)(128.0f + intensity * v[2]);
data[side][y][x][3] = 255;
}
}
}
- r_texture_normalizationcube = R_LoadTextureCubeMap(r_main_texturepool, "normalcube", NORMSIZE, &data[0][0][0][0], TEXTYPE_RGBA, TEXF_PRECACHE | TEXF_CLAMP, NULL);
+ r_texture_normalizationcube = R_LoadTextureCubeMap(r_main_texturepool, "normalcube", NORMSIZE, &data[0][0][0][0], TEXTYPE_BGRA, TEXF_PRECACHE | TEXF_CLAMP | TEXF_PERSISTENT, NULL);
}
static void R_BuildFogTexture(void)
{
int x, b;
- double r, alpha;
#define FOGWIDTH 64
unsigned char data1[FOGWIDTH][4];
//unsigned char data2[FOGWIDTH][4];
- r = (-1.0/256.0) * (FOGWIDTH * FOGWIDTH);
for (x = 0;x < FOGWIDTH;x++)
{
- alpha = exp(r / ((double)x*(double)x));
- if (x == FOGWIDTH - 1)
- alpha = 1;
- b = (int)(256.0 * alpha);
- b = bound(0, b, 255);
- data1[x][0] = 255 - b;
- data1[x][1] = 255 - b;
- data1[x][2] = 255 - b;
+ b = (int)(r_refdef.fogmasktable[x * (FOGMASKTABLEWIDTH - 1) / (FOGWIDTH - 1)] * 255);
+ data1[x][0] = b;
+ data1[x][1] = b;
+ data1[x][2] = b;
data1[x][3] = 255;
- //data2[x][0] = b;
- //data2[x][1] = b;
- //data2[x][2] = b;
+ //data2[x][0] = 255 - b;
+ //data2[x][1] = 255 - b;
+ //data2[x][2] = 255 - b;
//data2[x][3] = 255;
}
- r_texture_fogattenuation = R_LoadTexture2D(r_main_texturepool, "fogattenuation", FOGWIDTH, 1, &data1[0][0], TEXTYPE_RGBA, TEXF_PRECACHE | TEXF_FORCELINEAR | TEXF_CLAMP, NULL);
- //r_texture_fogintensity = R_LoadTexture2D(r_main_texturepool, "fogintensity", FOGWIDTH, 1, &data2[0][0], TEXTYPE_RGBA, TEXF_PRECACHE | TEXF_FORCELINEAR | TEXF_CLAMP, NULL);
+ r_texture_fogattenuation = R_LoadTexture2D(r_main_texturepool, "fogattenuation", FOGWIDTH, 1, &data1[0][0], TEXTYPE_BGRA, TEXF_PRECACHE | TEXF_FORCELINEAR | TEXF_CLAMP | TEXF_PERSISTENT, NULL);
+ //r_texture_fogintensity = R_LoadTexture2D(r_main_texturepool, "fogintensity", FOGWIDTH, 1, &data2[0][0], TEXTYPE_BGRA, TEXF_PRECACHE | TEXF_FORCELINEAR | TEXF_CLAMP, NULL);
}
static const char *builtinshaderstring =
"// common definitions between vertex shader and fragment shader:\n"
"\n"
"#ifdef __GLSL_CG_DATA_TYPES\n"
-"#define myhalf half\n"
-"#define myhvec2 hvec2\n"
-"#define myhvec3 hvec3\n"
-"#define myhvec4 hvec4\n"
+"# define myhalf half\n"
+"# define myhvec2 hvec2\n"
+"# define myhvec3 hvec3\n"
+"# define myhvec4 hvec4\n"
"#else\n"
-"#define myhalf float\n"
-"#define myhvec2 vec2\n"
-"#define myhvec3 vec3\n"
-"#define myhvec4 vec4\n"
+"# define myhalf float\n"
+"# define myhvec2 vec2\n"
+"# define myhvec3 vec3\n"
+"# define myhvec4 vec4\n"
"#endif\n"
"\n"
"varying vec2 TexCoord;\n"
"varying vec2 TexCoordLightmap;\n"
"\n"
+"//#ifdef MODE_LIGHTSOURCE\n"
"varying vec3 CubeVector;\n"
+"//#endif\n"
+"\n"
+"//#ifdef MODE_LIGHTSOURCE\n"
"varying vec3 LightVector;\n"
+"//#else\n"
+"//# ifdef MODE_LIGHTDIRECTION\n"
+"//varying vec3 LightVector;\n"
+"//# endif\n"
+"//#endif\n"
+"\n"
"varying vec3 EyeVector;\n"
-"#ifdef USEFOG\n"
+"//#ifdef USEFOG\n"
"varying vec3 EyeVectorModelSpace;\n"
-"#endif\n"
+"//#endif\n"
"\n"
"varying vec3 VectorS; // direction of S texcoord (sometimes crudely called tangent)\n"
"varying vec3 VectorT; // direction of T texcoord (sometimes crudely called binormal)\n"
"varying vec3 VectorR; // direction of R texcoord (surface normal)\n"
"\n"
+"//#ifdef MODE_WATER\n"
+"varying vec4 ModelViewProjectionPosition;\n"
+"//#else\n"
+"//# ifdef MODE_REFRACTION\n"
+"//varying vec4 ModelViewProjectionPosition;\n"
+"//# else\n"
+"//# ifdef USEREFLECTION\n"
+"//varying vec4 ModelViewProjectionPosition;\n"
+"//# endif\n"
+"//# endif\n"
+"//#endif\n"
+"\n"
+"\n"
"\n"
"\n"
"\n"
" gl_FrontColor = gl_Color;\n"
" // copy the surface texcoord\n"
" TexCoord = vec2(gl_TextureMatrix[0] * gl_MultiTexCoord0);\n"
-"#if !defined(MODE_LIGHTSOURCE) && !defined(MODE_LIGHTDIRECTION)\n"
+"#ifndef MODE_LIGHTSOURCE\n"
+"# ifndef MODE_LIGHTDIRECTION\n"
" TexCoordLightmap = vec2(gl_MultiTexCoord4);\n"
+"# endif\n"
"#endif\n"
"\n"
"#ifdef MODE_LIGHTSOURCE\n"
" VectorR = gl_MultiTexCoord3.xyz;\n"
"#endif\n"
"\n"
-" // transform vertex to camera space, using ftransform to match non-VS\n"
+"//#if defined(MODE_WATER) || defined(MODE_REFRACTION) || defined(USEREFLECTION)\n"
+"// ModelViewProjectionPosition = gl_Vertex * gl_ModelViewProjectionMatrix;\n"
+"// //ModelViewProjectionPosition_svector = (gl_Vertex + vec4(gl_MultiTexCoord1.xyz, 0)) * gl_ModelViewProjectionMatrix - ModelViewProjectionPosition;\n"
+"// //ModelViewProjectionPosition_tvector = (gl_Vertex + vec4(gl_MultiTexCoord2.xyz, 0)) * gl_ModelViewProjectionMatrix - ModelViewProjectionPosition;\n"
+"//#endif\n"
+"\n"
+"// transform vertex to camera space, using ftransform to match non-VS\n"
" // rendering\n"
" gl_Position = ftransform();\n"
+"\n"
+"#ifdef MODE_WATER\n"
+" ModelViewProjectionPosition = gl_Position;\n"
+"#endif\n"
+"#ifdef MODE_REFRACTION\n"
+" ModelViewProjectionPosition = gl_Position;\n"
+"#endif\n"
+"#ifdef USEREFLECTION\n"
+" ModelViewProjectionPosition = gl_Position;\n"
+"#endif\n"
"}\n"
"\n"
"#endif // VERTEX_SHADER\n"
"// fragment shader specific:\n"
"#ifdef FRAGMENT_SHADER\n"
"\n"
+"// 13 textures, we can only use up to 16 on DX9-class hardware\n"
"uniform sampler2D Texture_Normal;\n"
"uniform sampler2D Texture_Color;\n"
"uniform sampler2D Texture_Gloss;\n"
"uniform samplerCube Texture_Cube;\n"
+"uniform sampler2D Texture_Attenuation;\n"
"uniform sampler2D Texture_FogMask;\n"
"uniform sampler2D Texture_Pants;\n"
"uniform sampler2D Texture_Shirt;\n"
"uniform sampler2D Texture_Lightmap;\n"
"uniform sampler2D Texture_Deluxemap;\n"
"uniform sampler2D Texture_Glow;\n"
+"uniform sampler2D Texture_Reflection;\n"
+"uniform sampler2D Texture_Refraction;\n"
"\n"
"uniform myhvec3 LightColor;\n"
"uniform myhvec3 AmbientColor;\n"
"uniform myhvec3 Color_Shirt;\n"
"uniform myhvec3 FogColor;\n"
"\n"
+"//#ifdef MODE_WATER\n"
+"uniform vec4 DistortScaleRefractReflect;\n"
+"uniform vec4 ScreenScaleRefractReflect;\n"
+"uniform vec4 ScreenCenterRefractReflect;\n"
+"uniform myhvec4 RefractColor;\n"
+"uniform myhvec4 ReflectColor;\n"
+"uniform myhalf ReflectFactor;\n"
+"uniform myhalf ReflectOffset;\n"
+"//#else\n"
+"//# ifdef MODE_REFRACTION\n"
+"//uniform vec4 DistortScaleRefractReflect;\n"
+"//uniform vec4 ScreenScaleRefractReflect;\n"
+"//uniform vec4 ScreenCenterRefractReflect;\n"
+"//uniform myhvec4 RefractColor;\n"
+"//# ifdef USEREFLECTION\n"
+"//uniform myhvec4 ReflectColor;\n"
+"//# endif\n"
+"//# else\n"
+"//# ifdef USEREFLECTION\n"
+"//uniform vec4 DistortScaleRefractReflect;\n"
+"//uniform vec4 ScreenScaleRefractReflect;\n"
+"//uniform vec4 ScreenCenterRefractReflect;\n"
+"//uniform myhvec4 ReflectColor;\n"
+"//# endif\n"
+"//# endif\n"
+"//#endif\n"
+"\n"
"uniform myhalf GlowScale;\n"
"uniform myhalf SceneBrightness;\n"
+"#ifdef USECONTRASTBOOST\n"
+"uniform myhalf ContrastBoostCoeff;\n"
+"#endif\n"
"\n"
"uniform float OffsetMapping_Scale;\n"
"uniform float OffsetMapping_Bias;\n"
"uniform myhalf SpecularScale;\n"
"uniform myhalf SpecularPower;\n"
"\n"
-"void main(void)\n"
-"{\n"
-" // apply offsetmapping\n"
"#ifdef USEOFFSETMAPPING\n"
-" vec2 TexCoordOffset = TexCoord;\n"
-"#define TexCoord TexCoordOffset\n"
-"\n"
-" vec3 eyedir = vec3(normalize(EyeVector));\n"
-" float depthbias = 1.0 - eyedir.z; // should this be a -?\n"
-" depthbias = 1.0 - depthbias * depthbias;\n"
-"\n"
+"vec2 OffsetMapping(vec2 TexCoord)\n"
+"{\n"
"#ifdef USEOFFSETMAPPING_RELIEFMAPPING\n"
" // 14 sample relief mapping: linear search and then binary search\n"
-" //vec3 OffsetVector = vec3(EyeVector.xy * (1.0 / EyeVector.z) * depthbias * OffsetMapping_Scale * vec2(-0.1, 0.1), -0.1);\n"
-" //vec3 OffsetVector = vec3(normalize(EyeVector.xy) * OffsetMapping_Scale * vec2(-0.1, 0.1), -0.1);\n"
-" vec3 OffsetVector = vec3(eyedir.xy * OffsetMapping_Scale * vec2(-0.1, 0.1), -0.1);\n"
-" vec3 RT = vec3(TexCoord - OffsetVector.xy * 10.0, 1.0) + OffsetVector;\n"
-" if (RT.z > texture2D(Texture_Normal, RT.xy).a) RT += OffsetVector;\n"
-" if (RT.z > texture2D(Texture_Normal, RT.xy).a) RT += OffsetVector;\n"
-" if (RT.z > texture2D(Texture_Normal, RT.xy).a) RT += OffsetVector;\n"
-" if (RT.z > texture2D(Texture_Normal, RT.xy).a) RT += OffsetVector;\n"
-" if (RT.z > texture2D(Texture_Normal, RT.xy).a) RT += OffsetVector;\n"
-" if (RT.z > texture2D(Texture_Normal, RT.xy).a) RT += OffsetVector;\n"
-" if (RT.z > texture2D(Texture_Normal, RT.xy).a) RT += OffsetVector;\n"
-" if (RT.z > texture2D(Texture_Normal, RT.xy).a) RT += OffsetVector;\n"
-" if (RT.z > texture2D(Texture_Normal, RT.xy).a) RT += OffsetVector;OffsetVector *= 0.5;RT -= OffsetVector;\n"
-" if (RT.z > texture2D(Texture_Normal, RT.xy).a) RT += OffsetVector;OffsetVector *= 0.5;RT -= OffsetVector;\n"
-" if (RT.z > texture2D(Texture_Normal, RT.xy).a) RT += OffsetVector;OffsetVector *= 0.5;RT -= OffsetVector;\n"
-" if (RT.z > texture2D(Texture_Normal, RT.xy).a) RT += OffsetVector;OffsetVector *= 0.5;RT -= OffsetVector;\n"
-" if (RT.z > texture2D(Texture_Normal, RT.xy).a) RT += OffsetVector;OffsetVector *= 0.5;RT -= OffsetVector;\n"
-" if (RT.z > texture2D(Texture_Normal, RT.xy).a) RT += OffsetVector;OffsetVector *= 0.5;RT -= OffsetVector;\n"
-" TexCoord = RT.xy;\n"
-"#elif 1\n"
+" // this basically steps forward a small amount repeatedly until it finds\n"
+" // itself inside solid, then jitters forward and back using decreasing\n"
+" // amounts to find the impact\n"
+" //vec3 OffsetVector = vec3(EyeVector.xy * ((1.0 / EyeVector.z) * OffsetMapping_Scale) * vec2(-1, 1), -1);\n"
+" //vec3 OffsetVector = vec3(normalize(EyeVector.xy) * OffsetMapping_Scale * vec2(-1, 1), -1);\n"
+" vec3 OffsetVector = vec3(normalize(EyeVector).xy * OffsetMapping_Scale * vec2(-1, 1), -1);\n"
+" vec3 RT = vec3(TexCoord, 1);\n"
+" OffsetVector *= 0.1;\n"
+" RT += OffsetVector * step(texture2D(Texture_Normal, RT.xy).a, RT.z);\n"
+" RT += OffsetVector * step(texture2D(Texture_Normal, RT.xy).a, RT.z);\n"
+" RT += OffsetVector * step(texture2D(Texture_Normal, RT.xy).a, RT.z);\n"
+" RT += OffsetVector * step(texture2D(Texture_Normal, RT.xy).a, RT.z);\n"
+" RT += OffsetVector * step(texture2D(Texture_Normal, RT.xy).a, RT.z);\n"
+" RT += OffsetVector * step(texture2D(Texture_Normal, RT.xy).a, RT.z);\n"
+" RT += OffsetVector * step(texture2D(Texture_Normal, RT.xy).a, RT.z);\n"
+" RT += OffsetVector * step(texture2D(Texture_Normal, RT.xy).a, RT.z);\n"
+" RT += OffsetVector * step(texture2D(Texture_Normal, RT.xy).a, RT.z);\n"
+" RT += OffsetVector * (step(texture2D(Texture_Normal, RT.xy).a, RT.z) - 0.5);\n"
+" RT += OffsetVector * (step(texture2D(Texture_Normal, RT.xy).a, RT.z) * 0.5 - 0.25);\n"
+" RT += OffsetVector * (step(texture2D(Texture_Normal, RT.xy).a, RT.z) * 0.25 - 0.125);\n"
+" RT += OffsetVector * (step(texture2D(Texture_Normal, RT.xy).a, RT.z) * 0.125 - 0.0625);\n"
+" RT += OffsetVector * (step(texture2D(Texture_Normal, RT.xy).a, RT.z) * 0.0625 - 0.03125);\n"
+" return RT.xy;\n"
+"#else\n"
" // 3 sample offset mapping (only 3 samples because of ATI Radeon 9500-9800/X300 limits)\n"
-" //vec2 OffsetVector = vec2(EyeVector.xy * (1.0 / EyeVector.z) * depthbias) * OffsetMapping_Scale * vec2(-0.333, 0.333);\n"
-" //vec2 OffsetVector = vec2(normalize(EyeVector.xy)) * OffsetMapping_Scale * vec2(-0.333, 0.333);\n"
-" vec2 OffsetVector = vec2(eyedir.xy) * OffsetMapping_Scale * vec2(-0.333, 0.333);\n"
-" //TexCoord += OffsetVector * 3.0;\n"
-" TexCoord -= OffsetVector * texture2D(Texture_Normal, TexCoord).a;\n"
-" TexCoord -= OffsetVector * texture2D(Texture_Normal, TexCoord).a;\n"
-" TexCoord -= OffsetVector * texture2D(Texture_Normal, TexCoord).a;\n"
-"#elif 0\n"
-" // 10 sample offset mapping\n"
-" //vec2 OffsetVector = vec2(EyeVector.xy * (1.0 / EyeVector.z) * depthbias) * OffsetMapping_Scale * vec2(-0.333, 0.333);\n"
-" //vec2 OffsetVector = vec2(normalize(EyeVector.xy)) * OffsetMapping_Scale * vec2(-0.333, 0.333);\n"
-" vec2 OffsetVector = vec2(eyedir.xy) * OffsetMapping_Scale * vec2(-0.1, 0.1);\n"
-" //TexCoord += OffsetVector * 3.0;\n"
-" TexCoord -= OffsetVector * texture2D(Texture_Normal, TexCoord).a;\n"
+" // this basically moves forward the full distance, and then backs up based\n"
+" // on height of samples\n"
+" //vec2 OffsetVector = vec2(EyeVector.xy * ((1.0 / EyeVector.z) * OffsetMapping_Scale) * vec2(-1, 1));\n"
+" //vec2 OffsetVector = vec2(normalize(EyeVector.xy) * OffsetMapping_Scale * vec2(-1, 1));\n"
+" vec2 OffsetVector = vec2(normalize(EyeVector).xy * OffsetMapping_Scale * vec2(-1, 1));\n"
+" TexCoord += OffsetVector;\n"
+" OffsetVector *= 0.333;\n"
" TexCoord -= OffsetVector * texture2D(Texture_Normal, TexCoord).a;\n"
" TexCoord -= OffsetVector * texture2D(Texture_Normal, TexCoord).a;\n"
" TexCoord -= OffsetVector * texture2D(Texture_Normal, TexCoord).a;\n"
-" TexCoord -= OffsetVector * texture2D(Texture_Normal, TexCoord).a;\n"
-" TexCoord -= OffsetVector * texture2D(Texture_Normal, TexCoord).a;\n"
-" TexCoord -= OffsetVector * texture2D(Texture_Normal, TexCoord).a;\n"
-" TexCoord -= OffsetVector * texture2D(Texture_Normal, TexCoord).a;\n"
-" TexCoord -= OffsetVector * texture2D(Texture_Normal, TexCoord).a;\n"
-" TexCoord -= OffsetVector * texture2D(Texture_Normal, TexCoord).a;\n"
-"#elif 1\n"
-" // parallax mapping as described in the paper\n"
-" // 'Parallax Mapping with Offset Limiting: A Per-Pixel Approximation of Uneven Surfaces' by Terry Welsh\n"
-" // The paper provides code in the ARB fragment program assembly language\n"
-" // I translated it to GLSL but may have done something wrong - SavageX\n"
-" // LordHavoc: removed bias and simplified to one line\n"
-" // LordHavoc: this is just a single sample offsetmapping...\n"
-" TexCoordOffset += vec2(eyedir.x, -1.0 * eyedir.y) * OffsetMapping_Scale * texture2D(Texture_Normal, TexCoord).a;\n"
-"#else\n"
-" // parallax mapping as described in the paper\n"
-" // 'Parallax Mapping with Offset Limiting: A Per-Pixel Approximation of Uneven Surfaces' by Terry Welsh\n"
-" // The paper provides code in the ARB fragment program assembly language\n"
-" // I translated it to GLSL but may have done something wrong - SavageX\n"
-" float height = texture2D(Texture_Normal, TexCoord).a;\n"
-" height = (height - 0.5) * OffsetMapping_Scale; // bias and scale\n"
-" TexCoordOffset += height * vec2(eyedir.x, -1.0 * eyedir.y);\n"
+" return TexCoord;\n"
+"#endif\n"
+"}\n"
+"#endif // USEOFFSETMAPPING\n"
+"\n"
+"#ifdef MODE_WATER\n"
+"\n"
+"// water pass\n"
+"void main(void)\n"
+"{\n"
+"#ifdef USEOFFSETMAPPING\n"
+" // apply offsetmapping\n"
+" vec2 TexCoordOffset = OffsetMapping(TexCoord);\n"
+"#define TexCoord TexCoordOffset\n"
+"#endif\n"
+"\n"
+" vec4 ScreenScaleRefractReflectIW = ScreenScaleRefractReflect * (1.0 / ModelViewProjectionPosition.w);\n"
+" //vec4 ScreenTexCoord = (ModelViewProjectionPosition.xyxy + normalize(myhvec3(texture2D(Texture_Normal, TexCoord)) - myhvec3(0.5)).xyxy * DistortScaleRefractReflect * 100) * ScreenScaleRefractReflectIW + ScreenCenterRefractReflect;\n"
+" vec4 ScreenTexCoord = ModelViewProjectionPosition.xyxy * ScreenScaleRefractReflectIW + ScreenCenterRefractReflect + vec2(normalize(myhvec3(texture2D(Texture_Normal, TexCoord)) - myhvec3(0.5))).xyxy * DistortScaleRefractReflect;\n"
+" float Fresnel = pow(min(1.0, 1.0 - float(normalize(EyeVector).z)), 5.0) * ReflectFactor + ReflectOffset;\n"
+" gl_FragColor = mix(texture2D(Texture_Refraction, ScreenTexCoord.xy) * RefractColor, texture2D(Texture_Reflection, ScreenTexCoord.zw) * ReflectColor, Fresnel);\n"
+"}\n"
+"\n"
+"#else // MODE_WATER\n"
+"#ifdef MODE_REFRACTION\n"
+"\n"
+"// refraction pass\n"
+"void main(void)\n"
+"{\n"
+"#ifdef USEOFFSETMAPPING\n"
+" // apply offsetmapping\n"
+" vec2 TexCoordOffset = OffsetMapping(TexCoord);\n"
+"#define TexCoord TexCoordOffset\n"
"#endif\n"
+"\n"
+" vec2 ScreenScaleRefractReflectIW = ScreenScaleRefractReflect.xy * (1.0 / ModelViewProjectionPosition.w);\n"
+" //vec2 ScreenTexCoord = (ModelViewProjectionPosition.xy + normalize(myhvec3(texture2D(Texture_Normal, TexCoord)) - myhvec3(0.5)).xy * DistortScaleRefractReflect.xy * 100) * ScreenScaleRefractReflectIW + ScreenCenterRefractReflect.xy;\n"
+" vec2 ScreenTexCoord = ModelViewProjectionPosition.xy * ScreenScaleRefractReflectIW + ScreenCenterRefractReflect.xy + vec2(normalize(myhvec3(texture2D(Texture_Normal, TexCoord)) - myhvec3(0.5))).xy * DistortScaleRefractReflect.xy;\n"
+" gl_FragColor = texture2D(Texture_Refraction, ScreenTexCoord) * RefractColor;\n"
+"}\n"
+"\n"
+"#else // MODE_REFRACTION\n"
+"void main(void)\n"
+"{\n"
+"#ifdef USEOFFSETMAPPING\n"
+" // apply offsetmapping\n"
+" vec2 TexCoordOffset = OffsetMapping(TexCoord);\n"
+"#define TexCoord TexCoordOffset\n"
"#endif\n"
"\n"
" // combine the diffuse textures (base, pants, shirt)\n"
"#ifdef MODE_LIGHTSOURCE\n"
" // light source\n"
"\n"
-" // get the surface normal and light normal\n"
+" // calculate surface normal, light normal, and specular normal\n"
+" // compute color intensity for the two textures (colormap and glossmap)\n"
+" // scale by light color and attenuation as efficiently as possible\n"
+" // (do as much scalar math as possible rather than vector math)\n"
+"# ifdef USESPECULAR\n"
" myhvec3 surfacenormal = normalize(myhvec3(texture2D(Texture_Normal, TexCoord)) - myhvec3(0.5));\n"
" myhvec3 diffusenormal = myhvec3(normalize(LightVector));\n"
+" myhvec3 specularnormal = normalize(diffusenormal + myhvec3(normalize(EyeVector)));\n"
"\n"
" // calculate directional shading\n"
-" color.rgb *= AmbientScale + DiffuseScale * myhalf(max(float(dot(surfacenormal, diffusenormal)), 0.0));\n"
-"#ifdef USESPECULAR\n"
-" myhvec3 specularnormal = normalize(diffusenormal + myhvec3(normalize(EyeVector)));\n"
-" color.rgb += myhvec3(texture2D(Texture_Gloss, TexCoord)) * SpecularScale * pow(myhalf(max(float(dot(surfacenormal, specularnormal)), 0.0)), SpecularPower);\n"
-"#endif\n"
+" color.rgb = LightColor * myhalf(texture2D(Texture_Attenuation, vec2(length(CubeVector), 0.0))) * (color.rgb * (AmbientScale + DiffuseScale * myhalf(max(float(dot(surfacenormal, diffusenormal)), 0.0))) + (SpecularScale * pow(myhalf(max(float(dot(surfacenormal, specularnormal)), 0.0)), SpecularPower)) * myhvec3(texture2D(Texture_Gloss, TexCoord)));\n"
+"# else\n"
+"# ifdef USEDIFFUSE\n"
+" myhvec3 surfacenormal = normalize(myhvec3(texture2D(Texture_Normal, TexCoord)) - myhvec3(0.5));\n"
+" myhvec3 diffusenormal = myhvec3(normalize(LightVector));\n"
"\n"
-"#ifdef USECUBEFILTER\n"
+" // calculate directional shading\n"
+" color.rgb = color.rgb * LightColor * (myhalf(texture2D(Texture_Attenuation, vec2(length(CubeVector), 0.0))) * (AmbientScale + DiffuseScale * myhalf(max(float(dot(surfacenormal, diffusenormal)), 0.0))));\n"
+"# else\n"
+" // calculate directionless shading\n"
+" color.rgb = color.rgb * LightColor * myhalf(texture2D(Texture_Attenuation, vec2(length(CubeVector), 0.0)));\n"
+"# endif\n"
+"# endif\n"
+"\n"
+"# ifdef USECUBEFILTER\n"
" // apply light cubemap filter\n"
" //color.rgb *= normalize(CubeVector) * 0.5 + 0.5;//vec3(textureCube(Texture_Cube, CubeVector));\n"
" color.rgb *= myhvec3(textureCube(Texture_Cube, CubeVector));\n"
-"#endif\n"
-"\n"
-" // apply light color\n"
-" color.rgb *= LightColor;\n"
-"\n"
-" // apply attenuation\n"
-" //\n"
-" // the attenuation is (1-(x*x+y*y+z*z)) which gives a large bright\n"
-" // center and sharp falloff at the edge, this is about the most efficient\n"
-" // we can get away with as far as providing illumination.\n"
-" //\n"
-" // pow(1-(x*x+y*y+z*z), 4) is far more realistic but needs large lights to\n"
-" // provide significant illumination, large = slow = pain.\n"
-" color.rgb *= myhalf(max(1.0 - dot(CubeVector, CubeVector), 0.0));\n"
+"# endif\n"
+" color *= myhvec4(gl_Color);\n"
+"#endif // MODE_LIGHTSOURCE\n"
"\n"
"\n"
"\n"
"\n"
-"#elif defined(MODE_LIGHTDIRECTION)\n"
+"#ifdef MODE_LIGHTDIRECTION\n"
" // directional model lighting\n"
-"\n"
+"# ifdef USESPECULAR\n"
" // get the surface normal and light normal\n"
" myhvec3 surfacenormal = normalize(myhvec3(texture2D(Texture_Normal, TexCoord)) - myhvec3(0.5));\n"
-" myhvec3 diffusenormal = myhvec3(normalize(LightVector));\n"
+" myhvec3 diffusenormal = myhvec3(LightVector);\n"
"\n"
" // calculate directional shading\n"
" color.rgb *= AmbientColor + DiffuseColor * myhalf(max(float(dot(surfacenormal, diffusenormal)), 0.0));\n"
-"#ifdef USESPECULAR\n"
" myhvec3 specularnormal = normalize(diffusenormal + myhvec3(normalize(EyeVector)));\n"
" color.rgb += myhvec3(texture2D(Texture_Gloss, TexCoord)) * SpecularColor * pow(myhalf(max(float(dot(surfacenormal, specularnormal)), 0.0)), SpecularPower);\n"
-"#endif\n"
+"# else\n"
+"# ifdef USEDIFFUSE\n"
+" // get the surface normal and light normal\n"
+" myhvec3 surfacenormal = normalize(myhvec3(texture2D(Texture_Normal, TexCoord)) - myhvec3(0.5));\n"
+" myhvec3 diffusenormal = myhvec3(LightVector);\n"
+"\n"
+" // calculate directional shading\n"
+" color.rgb *= AmbientColor + DiffuseColor * myhalf(max(float(dot(surfacenormal, diffusenormal)), 0.0));\n"
+"# else\n"
+" color.rgb *= AmbientColor;\n"
+"# endif\n"
+"# endif\n"
+"\n"
+" color *= myhvec4(gl_Color);\n"
+"#endif // MODE_LIGHTDIRECTION\n"
"\n"
"\n"
"\n"
"\n"
-"#elif defined(MODE_LIGHTDIRECTIONMAP_MODELSPACE) || defined(MODE_LIGHTDIRECTIONMAP_TANGENTSPACE)\n"
+"#ifdef MODE_LIGHTDIRECTIONMAP_MODELSPACE\n"
" // deluxemap lightmapping using light vectors in modelspace (evil q3map2)\n"
"\n"
" // get the surface normal and light normal\n"
" myhvec3 surfacenormal = normalize(myhvec3(texture2D(Texture_Normal, TexCoord)) - myhvec3(0.5));\n"
"\n"
-"#ifdef MODE_LIGHTDIRECTIONMAP_MODELSPACE\n"
" myhvec3 diffusenormal_modelspace = myhvec3(texture2D(Texture_Deluxemap, TexCoordLightmap)) - myhvec3(0.5);\n"
" myhvec3 diffusenormal = normalize(myhvec3(dot(diffusenormal_modelspace, myhvec3(VectorS)), dot(diffusenormal_modelspace, myhvec3(VectorT)), dot(diffusenormal_modelspace, myhvec3(VectorR))));\n"
-"#else\n"
+" // calculate directional shading\n"
+" myhvec3 tempcolor = color.rgb * (DiffuseScale * myhalf(max(float(dot(surfacenormal, diffusenormal)), 0.0)));\n"
+"# ifdef USESPECULAR\n"
+" myhvec3 specularnormal = myhvec3(normalize(diffusenormal + myhvec3(normalize(EyeVector))));\n"
+" tempcolor += myhvec3(texture2D(Texture_Gloss, TexCoord)) * SpecularScale * pow(myhalf(max(float(dot(surfacenormal, specularnormal)), 0.0)), SpecularPower);\n"
+"# endif\n"
+"\n"
+" // apply lightmap color\n"
+" color.rgb = myhvec4(tempcolor,1) * myhvec4(texture2D(Texture_Lightmap, TexCoordLightmap)) * myhvec4(gl_Color) + myhvec4(color.rgb * AmbientScale, 0);\n"
+"#endif // MODE_LIGHTDIRECTIONMAP_MODELSPACE\n"
+"\n"
+"\n"
+"\n"
+"\n"
+"#ifdef MODE_LIGHTDIRECTIONMAP_TANGENTSPACE\n"
+" // deluxemap lightmapping using light vectors in tangentspace (hmap2 -light)\n"
+"\n"
+" // get the surface normal and light normal\n"
+" myhvec3 surfacenormal = normalize(myhvec3(texture2D(Texture_Normal, TexCoord)) - myhvec3(0.5));\n"
+"\n"
" myhvec3 diffusenormal = normalize(myhvec3(texture2D(Texture_Deluxemap, TexCoordLightmap)) - myhvec3(0.5));\n"
-"#endif\n"
" // calculate directional shading\n"
" myhvec3 tempcolor = color.rgb * (DiffuseScale * myhalf(max(float(dot(surfacenormal, diffusenormal)), 0.0)));\n"
-"#ifdef USESPECULAR\n"
+"# ifdef USESPECULAR\n"
" myhvec3 specularnormal = myhvec3(normalize(diffusenormal + myhvec3(normalize(EyeVector))));\n"
" tempcolor += myhvec3(texture2D(Texture_Gloss, TexCoord)) * SpecularScale * pow(myhalf(max(float(dot(surfacenormal, specularnormal)), 0.0)), SpecularPower);\n"
-"#endif\n"
+"# endif\n"
"\n"
" // apply lightmap color\n"
-" color.rgb = tempcolor * myhvec3(texture2D(Texture_Lightmap, TexCoordLightmap)) + color.rgb * AmbientScale;\n"
+" color = myhvec4(tempcolor, 1) * myhvec4(texture2D(Texture_Lightmap, TexCoordLightmap)) * myhvec4(gl_Color) + myhvec4(color.rgb * AmbientScale, 0);\n"
+"#endif // MODE_LIGHTDIRECTIONMAP_TANGENTSPACE\n"
"\n"
"\n"
-"#else // MODE none (lightmap)\n"
+"\n"
+"\n"
+"#ifdef MODE_LIGHTMAP\n"
" // apply lightmap color\n"
-" color.rgb *= myhvec3(texture2D(Texture_Lightmap, TexCoordLightmap)) * DiffuseScale + myhvec3(AmbientScale);\n"
-"#endif // MODE\n"
+" color *= myhvec4(texture2D(Texture_Lightmap, TexCoordLightmap)) * myhvec4(gl_Color) * myhvec4(myhvec3(DiffuseScale), 1) + myhvec4(myhvec3(AmbientScale), 0);\n"
+"#endif // MODE_LIGHTMAP\n"
+"\n"
+"\n"
+"\n"
+"\n"
+"\n"
+"\n"
"\n"
-" color *= myhvec4(gl_Color);\n"
"\n"
"#ifdef USEGLOW\n"
" color.rgb += myhvec3(texture2D(Texture_Glow, TexCoord)) * GlowScale;\n"
"#endif\n"
"\n"
+"#ifndef MODE_LIGHTSOURCE\n"
+"# ifdef USEREFLECTION\n"
+" vec4 ScreenScaleRefractReflectIW = ScreenScaleRefractReflect * (1.0 / ModelViewProjectionPosition.w);\n"
+" //vec4 ScreenTexCoord = (ModelViewProjectionPosition.xyxy + normalize(myhvec3(texture2D(Texture_Normal, TexCoord)) - myhvec3(0.5)).xyxy * DistortScaleRefractReflect * 100) * ScreenScaleRefractReflectIW + ScreenCenterRefractReflect;\n"
+" vec4 ScreenTexCoord = ModelViewProjectionPosition.xyxy * ScreenScaleRefractReflectIW + ScreenCenterRefractReflect + vec3(normalize(myhvec3(texture2D(Texture_Normal, TexCoord)) - myhvec3(0.5))).xyxy * DistortScaleRefractReflect;\n"
+" color.rgb = mix(color.rgb, myhvec3(texture2D(Texture_Reflection, ScreenTexCoord.zw)) * ReflectColor.rgb, ReflectColor.a);\n"
+"# endif\n"
+"#endif\n"
+"\n"
"#ifdef USEFOG\n"
" // apply fog\n"
-" myhalf fog = myhalf(texture2D(Texture_FogMask, myhvec2(length(EyeVectorModelSpace)*FogRangeRecip, 0.0)).x);\n"
-" color.rgb = color.rgb * fog + FogColor * (1.0 - fog);\n"
+" color.rgb = mix(FogColor, color.rgb, myhalf(texture2D(Texture_FogMask, myhvec2(length(EyeVectorModelSpace)*FogRangeRecip, 0.0))));\n"
+"#endif\n"
+"\n"
+"#ifdef USECONTRASTBOOST\n"
+" color.rgb = color.rgb / (ContrastBoostCoeff * color.rgb + myhvec3(1, 1, 1));\n"
"#endif\n"
"\n"
" color.rgb *= SceneBrightness;\n"
"\n"
" gl_FragColor = vec4(color);\n"
"}\n"
+"#endif // MODE_REFRACTION\n"
+"#endif // MODE_WATER\n"
"\n"
"#endif // FRAGMENT_SHADER\n"
;
+#define SHADERPERMUTATION_COLORMAPPING (1<<0) // indicates this is a colormapped skin
+#define SHADERPERMUTATION_CONTRASTBOOST (1<<1) // r_glsl_contrastboost boosts the contrast at low color levels (similar to gamma)
+#define SHADERPERMUTATION_FOG (1<<2) // tint the color by fog color or black if using additive blend mode
+#define SHADERPERMUTATION_CUBEFILTER (1<<3) // (lightsource) use cubemap light filter
+#define SHADERPERMUTATION_GLOW (1<<4) // (lightmap) blend in an additive glow texture
+#define SHADERPERMUTATION_DIFFUSE (1<<5) // (lightsource) whether to use directional shading
+#define SHADERPERMUTATION_SPECULAR (1<<6) // (lightsource or deluxemapping) render specular effects
+#define SHADERPERMUTATION_REFLECTION (1<<7) // normalmap-perturbed reflection of the scene infront of the surface, preformed as an overlay on the surface
+#define SHADERPERMUTATION_OFFSETMAPPING (1<<8) // adjust texcoords to roughly simulate a displacement mapped surface
+#define SHADERPERMUTATION_OFFSETMAPPING_RELIEFMAPPING (1<<9) // adjust texcoords to accurately simulate a displacement mapped surface (requires OFFSETMAPPING to also be set!)
+#define SHADERPERMUTATION_MODEBASE (1<<10) // multiplier for the SHADERMODE_ values to get a valid index
+
// NOTE: MUST MATCH ORDER OF SHADERPERMUTATION_* DEFINES!
-const char *permutationinfo[][2] =
+const char *shaderpermutationinfo[][2] =
{
- {"#define MODE_LIGHTSOURCE\n", " lightsource"},
- {"#define MODE_LIGHTDIRECTIONMAP_MODELSPACE\n", " lightdirectionmap_modelspace"},
- {"#define MODE_LIGHTDIRECTIONMAP_TANGENTSPACE\n", " lightdirectionmap_tangentspace"},
- {"#define MODE_LIGHTDIRECTION\n", " lightdirection"},
- {"#define USEGLOW\n", " glow"},
- {"#define USEFOG\n", " fog"},
{"#define USECOLORMAPPING\n", " colormapping"},
- {"#define USESPECULAR\n", " specular"},
+ {"#define USECONTRASTBOOST\n", " contrastboost"},
+ {"#define USEFOG\n", " fog"},
{"#define USECUBEFILTER\n", " cubefilter"},
+ {"#define USEGLOW\n", " glow"},
+ {"#define USEDIFFUSE\n", " diffuse"},
+ {"#define USESPECULAR\n", " specular"},
+ {"#define USEREFLECTION\n", " reflection"},
{"#define USEOFFSETMAPPING\n", " offsetmapping"},
{"#define USEOFFSETMAPPING_RELIEFMAPPING\n", " reliefmapping"},
{NULL, NULL}
};
-void R_GLSL_CompilePermutation(const char *filename, int permutation)
+// this enum is multiplied by SHADERPERMUTATION_MODEBASE
+typedef enum shadermode_e
+{
+ SHADERMODE_LIGHTMAP, // (lightmap) use directional pixel shading from fixed light direction (q3bsp)
+ SHADERMODE_LIGHTDIRECTIONMAP_MODELSPACE, // (lightmap) use directional pixel shading from texture containing modelspace light directions (deluxemap)
+ SHADERMODE_LIGHTDIRECTIONMAP_TANGENTSPACE, // (lightmap) use directional pixel shading from texture containing tangentspace light directions (deluxemap)
+ SHADERMODE_LIGHTDIRECTION, // (lightmap) use directional pixel shading from fixed light direction (q3bsp)
+ SHADERMODE_LIGHTSOURCE, // (lightsource) use directional pixel shading from light source (rtlight)
+ SHADERMODE_REFRACTION, // refract background (the material is rendered normally after this pass)
+ SHADERMODE_WATER, // refract background and reflection (the material is rendered normally after this pass)
+ SHADERMODE_COUNT
+}
+shadermode_t;
+
+// NOTE: MUST MATCH ORDER OF SHADERMODE_* ENUMS!
+const char *shadermodeinfo[][2] =
+{
+ {"#define MODE_LIGHTMAP\n", " lightmap"},
+ {"#define MODE_LIGHTDIRECTIONMAP_MODELSPACE\n", " lightdirectionmap_modelspace"},
+ {"#define MODE_LIGHTDIRECTIONMAP_TANGENTSPACE\n", " lightdirectionmap_tangentspace"},
+ {"#define MODE_LIGHTDIRECTION\n", " lightdirection"},
+ {"#define MODE_LIGHTSOURCE\n", " lightsource"},
+ {"#define MODE_REFRACTION\n", " refraction"},
+ {"#define MODE_WATER\n", " water"},
+ {NULL, NULL}
+};
+
+#define SHADERPERMUTATION_INDICES (SHADERPERMUTATION_MODEBASE * SHADERMODE_COUNT)
+
+typedef struct r_glsl_permutation_s
+{
+ // indicates if we have tried compiling this permutation already
+ qboolean compiled;
+ // 0 if compilation failed
+ int program;
+ // locations of detected uniforms in program object, or -1 if not found
+ int loc_Texture_Normal;
+ int loc_Texture_Color;
+ int loc_Texture_Gloss;
+ int loc_Texture_Cube;
+ int loc_Texture_Attenuation;
+ int loc_Texture_FogMask;
+ int loc_Texture_Pants;
+ int loc_Texture_Shirt;
+ int loc_Texture_Lightmap;
+ int loc_Texture_Deluxemap;
+ int loc_Texture_Glow;
+ int loc_Texture_Refraction;
+ int loc_Texture_Reflection;
+ int loc_FogColor;
+ int loc_LightPosition;
+ int loc_EyePosition;
+ int loc_LightColor;
+ int loc_Color_Pants;
+ int loc_Color_Shirt;
+ int loc_FogRangeRecip;
+ int loc_AmbientScale;
+ int loc_DiffuseScale;
+ int loc_SpecularScale;
+ int loc_SpecularPower;
+ int loc_GlowScale;
+ int loc_SceneBrightness; // or: Scenebrightness * ContrastBoost
+ int loc_OffsetMapping_Scale;
+ int loc_AmbientColor;
+ int loc_DiffuseColor;
+ int loc_SpecularColor;
+ int loc_LightDir;
+ int loc_ContrastBoostCoeff; // 1 - 1/ContrastBoost
+ int loc_DistortScaleRefractReflect;
+ int loc_ScreenScaleRefractReflect;
+ int loc_ScreenCenterRefractReflect;
+ int loc_RefractColor;
+ int loc_ReflectColor;
+ int loc_ReflectFactor;
+ int loc_ReflectOffset;
+}
+r_glsl_permutation_t;
+
+// information about each possible shader permutation
+r_glsl_permutation_t r_glsl_permutations[SHADERPERMUTATION_INDICES];
+// currently selected permutation
+r_glsl_permutation_t *r_glsl_permutation;
+
+// these are additional flags used only by R_GLSL_CompilePermutation
+#define SHADERTYPE_USES_VERTEXSHADER (1<<0)
+#define SHADERTYPE_USES_GEOMETRYSHADER (1<<1)
+#define SHADERTYPE_USES_FRAGMENTSHADER (1<<2)
+
+static void R_GLSL_CompilePermutation(const char *filename, int permutation, int shadertype)
{
int i;
qboolean shaderfound;
- r_glsl_permutation_t *p = r_glsl_permutations + (permutation & SHADERPERMUTATION_COUNTMASK);
+ r_glsl_permutation_t *p = r_glsl_permutations + permutation;
int vertstrings_count;
int geomstrings_count;
int fragstrings_count;
char *shaderstring;
- const char *vertstrings_list[SHADERPERMUTATION_COUNT+1];
- const char *geomstrings_list[SHADERPERMUTATION_COUNT+1];
- const char *fragstrings_list[SHADERPERMUTATION_COUNT+1];
+ const char *vertstrings_list[32+1];
+ const char *geomstrings_list[32+1];
+ const char *fragstrings_list[32+1];
char permutationname[256];
if (p->compiled)
return;
geomstrings_count = 1;
fragstrings_count = 1;
permutationname[0] = 0;
- for (i = 0;permutationinfo[i][0];i++)
+ i = permutation / SHADERPERMUTATION_MODEBASE;
+ vertstrings_list[vertstrings_count++] = shadermodeinfo[i][0];
+ geomstrings_list[geomstrings_count++] = shadermodeinfo[i][0];
+ fragstrings_list[fragstrings_count++] = shadermodeinfo[i][0];
+ strlcat(permutationname, shadermodeinfo[i][1], sizeof(permutationname));
+ for (i = 0;shaderpermutationinfo[i][0];i++)
{
if (permutation & (1<<i))
{
- vertstrings_list[vertstrings_count++] = permutationinfo[i][0];
- geomstrings_list[geomstrings_count++] = permutationinfo[i][0];
- fragstrings_list[fragstrings_count++] = permutationinfo[i][0];
- strlcat(permutationname, permutationinfo[i][1], sizeof(permutationname));
+ vertstrings_list[vertstrings_count++] = shaderpermutationinfo[i][0];
+ geomstrings_list[geomstrings_count++] = shaderpermutationinfo[i][0];
+ fragstrings_list[fragstrings_count++] = shaderpermutationinfo[i][0];
+ strlcat(permutationname, shaderpermutationinfo[i][1], sizeof(permutationname));
}
else
{
shaderfound = false;
if (shaderstring)
{
- Con_DPrintf("GLSL shader text for \"%s\" loaded from disk\n", filename);
+ Con_DPrint("from disk... ");
vertstrings_list[vertstrings_count++] = shaderstring;
geomstrings_list[geomstrings_count++] = shaderstring;
fragstrings_list[fragstrings_count++] = shaderstring;
}
else if (!strcmp(filename, "glsl/default.glsl"))
{
- Con_DPrintf("GLSL shader text for \"%s\" loaded from engine\n", filename);
vertstrings_list[vertstrings_count++] = builtinshaderstring;
geomstrings_list[geomstrings_count++] = builtinshaderstring;
fragstrings_list[fragstrings_count++] = builtinshaderstring;
shaderfound = true;
}
// clear any lists that are not needed by this shader
- if (!(permutation & SHADERPERMUTATION_USES_VERTEXSHADER))
+ if (!(shadertype & SHADERTYPE_USES_VERTEXSHADER))
vertstrings_count = 0;
- if (!(permutation & SHADERPERMUTATION_USES_GEOMETRYSHADER))
+ if (!(shadertype & SHADERTYPE_USES_GEOMETRYSHADER))
geomstrings_count = 0;
- if (!(permutation & SHADERPERMUTATION_USES_FRAGMENTSHADER))
+ if (!(shadertype & SHADERTYPE_USES_FRAGMENTSHADER))
fragstrings_count = 0;
// compile the shader program
if (shaderfound && vertstrings_count + geomstrings_count + fragstrings_count)
p->loc_Texture_Color = qglGetUniformLocationARB(p->program, "Texture_Color");
p->loc_Texture_Gloss = qglGetUniformLocationARB(p->program, "Texture_Gloss");
p->loc_Texture_Cube = qglGetUniformLocationARB(p->program, "Texture_Cube");
+ p->loc_Texture_Attenuation = qglGetUniformLocationARB(p->program, "Texture_Attenuation");
p->loc_Texture_FogMask = qglGetUniformLocationARB(p->program, "Texture_FogMask");
p->loc_Texture_Pants = qglGetUniformLocationARB(p->program, "Texture_Pants");
p->loc_Texture_Shirt = qglGetUniformLocationARB(p->program, "Texture_Shirt");
p->loc_Texture_Lightmap = qglGetUniformLocationARB(p->program, "Texture_Lightmap");
p->loc_Texture_Deluxemap = qglGetUniformLocationARB(p->program, "Texture_Deluxemap");
p->loc_Texture_Glow = qglGetUniformLocationARB(p->program, "Texture_Glow");
+ p->loc_Texture_Refraction = qglGetUniformLocationARB(p->program, "Texture_Refraction");
+ p->loc_Texture_Reflection = qglGetUniformLocationARB(p->program, "Texture_Reflection");
p->loc_FogColor = qglGetUniformLocationARB(p->program, "FogColor");
p->loc_LightPosition = qglGetUniformLocationARB(p->program, "LightPosition");
p->loc_EyePosition = qglGetUniformLocationARB(p->program, "EyePosition");
p->loc_DiffuseColor = qglGetUniformLocationARB(p->program, "DiffuseColor");
p->loc_SpecularColor = qglGetUniformLocationARB(p->program, "SpecularColor");
p->loc_LightDir = qglGetUniformLocationARB(p->program, "LightDir");
+ p->loc_ContrastBoostCoeff = qglGetUniformLocationARB(p->program, "ContrastBoostCoeff");
+ p->loc_DistortScaleRefractReflect = qglGetUniformLocationARB(p->program, "DistortScaleRefractReflect");
+ p->loc_ScreenScaleRefractReflect = qglGetUniformLocationARB(p->program, "ScreenScaleRefractReflect");
+ p->loc_ScreenCenterRefractReflect = qglGetUniformLocationARB(p->program, "ScreenCenterRefractReflect");
+ p->loc_RefractColor = qglGetUniformLocationARB(p->program, "RefractColor");
+ p->loc_ReflectColor = qglGetUniformLocationARB(p->program, "ReflectColor");
+ p->loc_ReflectFactor = qglGetUniformLocationARB(p->program, "ReflectFactor");
+ p->loc_ReflectOffset = qglGetUniformLocationARB(p->program, "ReflectOffset");
// initialize the samplers to refer to the texture units we use
if (p->loc_Texture_Normal >= 0) qglUniform1iARB(p->loc_Texture_Normal, 0);
if (p->loc_Texture_Color >= 0) qglUniform1iARB(p->loc_Texture_Color, 1);
if (p->loc_Texture_Lightmap >= 0) qglUniform1iARB(p->loc_Texture_Lightmap, 7);
if (p->loc_Texture_Deluxemap >= 0) qglUniform1iARB(p->loc_Texture_Deluxemap, 8);
if (p->loc_Texture_Glow >= 0) qglUniform1iARB(p->loc_Texture_Glow, 9);
+ if (p->loc_Texture_Attenuation >= 0) qglUniform1iARB(p->loc_Texture_Attenuation, 10);
+ if (p->loc_Texture_Refraction >= 0) qglUniform1iARB(p->loc_Texture_Refraction, 11);
+ if (p->loc_Texture_Reflection >= 0) qglUniform1iARB(p->loc_Texture_Reflection, 12);
CHECKGLERROR
qglUseProgramObjectARB(0);CHECKGLERROR
+ if (developer.integer)
+ Con_Printf("GLSL shader %s :%s compiled.\n", filename, permutationname);
}
else
- Con_Printf("permutation%s failed for shader %s, some features may not work properly!\n", permutationname, "glsl/default.glsl");
+ {
+ if (developer.integer)
+ Con_Printf("GLSL shader %s :%s failed! source code line offset for above errors is %i.\n", permutationname, filename, -(vertstrings_count - 1));
+ else
+ Con_Printf("GLSL shader %s :%s failed! some features may not work properly.\n", permutationname, filename);
+ }
if (shaderstring)
Mem_Free(shaderstring);
}
void R_GLSL_Restart_f(void)
{
int i;
- for (i = 0;i < SHADERPERMUTATION_COUNT;i++)
+ for (i = 0;i < SHADERPERMUTATION_INDICES;i++)
if (r_glsl_permutations[i].program)
GL_Backend_FreeProgram(r_glsl_permutations[i].program);
memset(r_glsl_permutations, 0, sizeof(r_glsl_permutations));
}
-int R_SetupSurfaceShader(const vec3_t lightcolorbase, qboolean modellighting)
+void R_GLSL_DumpShader_f(void)
+{
+ int i;
+
+ qfile_t *file = FS_Open("glsl/default.glsl", "w", false, false);
+ if(!file)
+ {
+ Con_Printf("failed to write to glsl/default.glsl\n");
+ return;
+ }
+
+ FS_Print(file, "// The engine may define the following macros:\n");
+ FS_Print(file, "// #define VERTEX_SHADER\n// #define GEOMETRY_SHADER\n// #define FRAGMENT_SHADER\n");
+ for (i = 0;shadermodeinfo[i][0];i++)
+ FS_Printf(file, "// %s", shadermodeinfo[i][0]);
+ for (i = 0;shaderpermutationinfo[i][0];i++)
+ FS_Printf(file, "// %s", shaderpermutationinfo[i][0]);
+ FS_Print(file, "\n");
+ FS_Print(file, builtinshaderstring);
+ FS_Close(file);
+
+ Con_Printf("glsl/default.glsl written\n");
+}
+
+extern rtexture_t *r_shadow_attenuationgradienttexture;
+extern rtexture_t *r_shadow_attenuation2dtexture;
+extern rtexture_t *r_shadow_attenuation3dtexture;
+int R_SetupSurfaceShader(const vec3_t lightcolorbase, qboolean modellighting, float ambientscale, float diffusescale, float specularscale, rsurfacepass_t rsurfacepass)
{
// select a permutation of the lighting shader appropriate to this
// combination of texture, entity, light source, and fogging, only use the
// minimum features necessary to avoid wasting rendering time in the
// fragment shader on features that are not being used
const char *shaderfilename = NULL;
- int permutation = 0;
- float specularscale = rsurface_texture->specularscale;
+ unsigned int permutation = 0;
+ unsigned int shadertype = 0;
+ shadermode_t mode = 0;
r_glsl_permutation = NULL;
+ shaderfilename = "glsl/default.glsl";
+ shadertype = SHADERTYPE_USES_VERTEXSHADER | SHADERTYPE_USES_FRAGMENTSHADER;
// TODO: implement geometry-shader based shadow volumes someday
- if (r_shadow_rtlight)
+ if (r_glsl_offsetmapping.integer)
+ {
+ permutation |= SHADERPERMUTATION_OFFSETMAPPING;
+ if (r_glsl_offsetmapping_reliefmapping.integer)
+ permutation |= SHADERPERMUTATION_OFFSETMAPPING_RELIEFMAPPING;
+ }
+ if (rsurfacepass == RSURFPASS_BACKGROUND)
+ {
+ // distorted background
+ if (rsurface.texture->currentmaterialflags & MATERIALFLAG_WATERSHADER)
+ mode = SHADERMODE_WATER;
+ else
+ mode = SHADERMODE_REFRACTION;
+ }
+ else if (rsurfacepass == RSURFPASS_RTLIGHT)
{
// light source
- shaderfilename = "glsl/default.glsl";
- permutation = SHADERPERMUTATION_MODE_LIGHTSOURCE | SHADERPERMUTATION_USES_VERTEXSHADER | SHADERPERMUTATION_USES_FRAGMENTSHADER;
- specularscale *= r_shadow_rtlight->specularscale;
- if (r_shadow_rtlight->currentcubemap != r_texture_whitecube)
+ mode = SHADERMODE_LIGHTSOURCE;
+ if (rsurface.rtlight->currentcubemap != r_texture_whitecube)
permutation |= SHADERPERMUTATION_CUBEFILTER;
+ if (diffusescale > 0)
+ permutation |= SHADERPERMUTATION_DIFFUSE;
if (specularscale > 0)
- permutation |= SHADERPERMUTATION_SPECULAR;
+ permutation |= SHADERPERMUTATION_SPECULAR | SHADERPERMUTATION_DIFFUSE;
if (r_refdef.fogenabled)
permutation |= SHADERPERMUTATION_FOG;
- if (rsurface_texture->colormapping)
+ if (rsurface.texture->colormapping)
permutation |= SHADERPERMUTATION_COLORMAPPING;
- if (r_glsl_offsetmapping.integer)
- {
- permutation |= SHADERPERMUTATION_OFFSETMAPPING;
- if (r_glsl_offsetmapping_reliefmapping.integer)
- permutation |= SHADERPERMUTATION_OFFSETMAPPING_RELIEFMAPPING;
- }
+ if(r_glsl_contrastboost.value > 1 || r_glsl_contrastboost.value < 0)
+ permutation |= SHADERPERMUTATION_CONTRASTBOOST;
+ if (rsurface.texture->currentmaterialflags & MATERIALFLAG_REFLECTION)
+ permutation |= SHADERPERMUTATION_REFLECTION;
}
- else if (rsurface_texture->currentmaterialflags & MATERIALFLAG_FULLBRIGHT)
+ else if (rsurface.texture->currentmaterialflags & MATERIALFLAG_FULLBRIGHT)
{
- // bright unshaded geometry
- shaderfilename = "glsl/default.glsl";
- permutation = SHADERPERMUTATION_USES_VERTEXSHADER | SHADERPERMUTATION_USES_FRAGMENTSHADER;
- if (rsurface_texture->currentskinframe->glow)
+ // unshaded geometry (fullbright or ambient model lighting)
+ mode = SHADERMODE_LIGHTMAP;
+ if (rsurface.texture->currentskinframe->glow)
permutation |= SHADERPERMUTATION_GLOW;
if (r_refdef.fogenabled)
permutation |= SHADERPERMUTATION_FOG;
- if (rsurface_texture->colormapping)
+ if (rsurface.texture->colormapping)
permutation |= SHADERPERMUTATION_COLORMAPPING;
if (r_glsl_offsetmapping.integer)
{
if (r_glsl_offsetmapping_reliefmapping.integer)
permutation |= SHADERPERMUTATION_OFFSETMAPPING_RELIEFMAPPING;
}
+ if(r_glsl_contrastboost.value > 1 || r_glsl_contrastboost.value < 0)
+ permutation |= SHADERPERMUTATION_CONTRASTBOOST;
+ if (rsurface.texture->currentmaterialflags & MATERIALFLAG_REFLECTION)
+ permutation |= SHADERPERMUTATION_REFLECTION;
}
- else if (modellighting)
+ else if (rsurface.texture->currentmaterialflags & MATERIALFLAG_MODELLIGHT_DIRECTIONAL)
{
// directional model lighting
- shaderfilename = "glsl/default.glsl";
- permutation = SHADERPERMUTATION_USES_VERTEXSHADER | SHADERPERMUTATION_USES_FRAGMENTSHADER;
- permutation |= SHADERPERMUTATION_MODE_LIGHTDIRECTION;
- if (rsurface_texture->currentskinframe->glow)
+ mode = SHADERMODE_LIGHTDIRECTION;
+ if (rsurface.texture->currentskinframe->glow)
permutation |= SHADERPERMUTATION_GLOW;
+ permutation |= SHADERPERMUTATION_DIFFUSE;
if (specularscale > 0)
permutation |= SHADERPERMUTATION_SPECULAR;
if (r_refdef.fogenabled)
permutation |= SHADERPERMUTATION_FOG;
- if (rsurface_texture->colormapping)
+ if (rsurface.texture->colormapping)
permutation |= SHADERPERMUTATION_COLORMAPPING;
- if (r_glsl_offsetmapping.integer)
- {
- permutation |= SHADERPERMUTATION_OFFSETMAPPING;
- if (r_glsl_offsetmapping_reliefmapping.integer)
- permutation |= SHADERPERMUTATION_OFFSETMAPPING_RELIEFMAPPING;
- }
+ if(r_glsl_contrastboost.value > 1 || r_glsl_contrastboost.value < 0)
+ permutation |= SHADERPERMUTATION_CONTRASTBOOST;
+ if (rsurface.texture->currentmaterialflags & MATERIALFLAG_REFLECTION)
+ permutation |= SHADERPERMUTATION_REFLECTION;
+ }
+ else if (rsurface.texture->currentmaterialflags & MATERIALFLAG_MODELLIGHT)
+ {
+ // ambient model lighting
+ mode = SHADERMODE_LIGHTDIRECTION;
+ if (rsurface.texture->currentskinframe->glow)
+ permutation |= SHADERPERMUTATION_GLOW;
+ if (r_refdef.fogenabled)
+ permutation |= SHADERPERMUTATION_FOG;
+ if (rsurface.texture->colormapping)
+ permutation |= SHADERPERMUTATION_COLORMAPPING;
+ if(r_glsl_contrastboost.value > 1 || r_glsl_contrastboost.value < 0)
+ permutation |= SHADERPERMUTATION_CONTRASTBOOST;
+ if (rsurface.texture->currentmaterialflags & MATERIALFLAG_REFLECTION)
+ permutation |= SHADERPERMUTATION_REFLECTION;
}
else
{
// lightmapped wall
- shaderfilename = "glsl/default.glsl";
- permutation = SHADERPERMUTATION_USES_VERTEXSHADER | SHADERPERMUTATION_USES_FRAGMENTSHADER;
- if (r_glsl_deluxemapping.integer >= 1 && rsurface_lightmaptexture && r_refdef.worldmodel && r_refdef.worldmodel->brushq3.deluxemapping)
+ if (r_glsl_deluxemapping.integer >= 1 && rsurface.uselightmaptexture && r_refdef.worldmodel && r_refdef.worldmodel->brushq3.deluxemapping)
{
// deluxemapping (light direction texture)
- if (rsurface_lightmaptexture && r_refdef.worldmodel && r_refdef.worldmodel->brushq3.deluxemapping && r_refdef.worldmodel->brushq3.deluxemapping_modelspace)
- permutation |= SHADERPERMUTATION_MODE_LIGHTDIRECTIONMAP_MODELSPACE;
+ if (rsurface.uselightmaptexture && r_refdef.worldmodel && r_refdef.worldmodel->brushq3.deluxemapping && r_refdef.worldmodel->brushq3.deluxemapping_modelspace)
+ mode = SHADERMODE_LIGHTDIRECTIONMAP_MODELSPACE;
else
- permutation |= SHADERPERMUTATION_MODE_LIGHTDIRECTIONMAP_TANGENTSPACE;
+ mode = SHADERMODE_LIGHTDIRECTIONMAP_TANGENTSPACE;
if (specularscale > 0)
- permutation |= SHADERPERMUTATION_SPECULAR;
+ permutation |= SHADERPERMUTATION_SPECULAR | SHADERPERMUTATION_DIFFUSE;
}
else if (r_glsl_deluxemapping.integer >= 2)
{
// fake deluxemapping (uniform light direction in tangentspace)
- permutation |= SHADERPERMUTATION_MODE_LIGHTDIRECTIONMAP_TANGENTSPACE;
+ mode = SHADERMODE_LIGHTDIRECTIONMAP_TANGENTSPACE;
if (specularscale > 0)
- permutation |= SHADERPERMUTATION_SPECULAR;
+ permutation |= SHADERPERMUTATION_SPECULAR | SHADERPERMUTATION_DIFFUSE;
}
else
{
// ordinary lightmapping
- permutation |= 0;
+ mode = SHADERMODE_LIGHTMAP;
}
- if (rsurface_texture->currentskinframe->glow)
+ if (rsurface.texture->currentskinframe->glow)
permutation |= SHADERPERMUTATION_GLOW;
if (r_refdef.fogenabled)
permutation |= SHADERPERMUTATION_FOG;
- if (rsurface_texture->colormapping)
+ if (rsurface.texture->colormapping)
permutation |= SHADERPERMUTATION_COLORMAPPING;
- if (r_glsl_offsetmapping.integer)
- {
- permutation |= SHADERPERMUTATION_OFFSETMAPPING;
- if (r_glsl_offsetmapping_reliefmapping.integer)
- permutation |= SHADERPERMUTATION_OFFSETMAPPING_RELIEFMAPPING;
- }
+ if(r_glsl_contrastboost.value > 1 || r_glsl_contrastboost.value < 0)
+ permutation |= SHADERPERMUTATION_CONTRASTBOOST;
+ if (rsurface.texture->currentmaterialflags & MATERIALFLAG_REFLECTION)
+ permutation |= SHADERPERMUTATION_REFLECTION;
}
- if (!r_glsl_permutations[permutation & SHADERPERMUTATION_COUNTMASK].program)
+ permutation |= mode * SHADERPERMUTATION_MODEBASE;
+ if (!r_glsl_permutations[permutation].program)
{
- if (!r_glsl_permutations[permutation & SHADERPERMUTATION_COUNTMASK].compiled)
- R_GLSL_CompilePermutation(shaderfilename, permutation);
- if (!r_glsl_permutations[permutation & SHADERPERMUTATION_COUNTMASK].program)
+ if (!r_glsl_permutations[permutation].compiled)
+ R_GLSL_CompilePermutation(shaderfilename, permutation, shadertype);
+ if (!r_glsl_permutations[permutation].program)
{
// remove features until we find a valid permutation
- int i;
- for (i = SHADERPERMUTATION_COUNT-1;;i>>=1)
+ unsigned int i;
+ for (i = (SHADERPERMUTATION_MODEBASE >> 1);;i>>=1)
{
+ if (!i)
+ {
+ Con_Printf("OpenGL 2.0 shaders disabled - unable to find a working shader permutation fallback on this driver (set r_glsl 1 if you want to try again)\n");
+ Cvar_SetValueQuick(&r_glsl, 0);
+ return 0; // no bit left to clear
+ }
// reduce i more quickly whenever it would not remove any bits
- if (permutation < i)
+ if (!(permutation & i))
continue;
- permutation &= i;
- if (!r_glsl_permutations[permutation & SHADERPERMUTATION_COUNTMASK].compiled)
- R_GLSL_CompilePermutation(shaderfilename, permutation);
- if (r_glsl_permutations[permutation & SHADERPERMUTATION_COUNTMASK].program)
+ permutation &= ~i;
+ if (!r_glsl_permutations[permutation].compiled)
+ R_GLSL_CompilePermutation(shaderfilename, permutation, shadertype);
+ if (r_glsl_permutations[permutation].program)
break;
- if (!i)
- return 0; // utterly failed
}
}
}
- r_glsl_permutation = r_glsl_permutations + (permutation & SHADERPERMUTATION_COUNTMASK);
+ r_glsl_permutation = r_glsl_permutations + permutation;
CHECKGLERROR
qglUseProgramObjectARB(r_glsl_permutation->program);CHECKGLERROR
- R_Mesh_TexMatrix(0, &rsurface_texture->currenttexmatrix);
- if (permutation & SHADERPERMUTATION_MODE_LIGHTSOURCE)
+ if (mode == SHADERMODE_LIGHTSOURCE)
{
- if (r_glsl_permutation->loc_Texture_Cube >= 0 && r_shadow_rtlight) R_Mesh_TexBindCubeMap(3, R_GetTexture(r_shadow_rtlight->currentcubemap));
- if (r_glsl_permutation->loc_LightPosition >= 0) qglUniform3fARB(r_glsl_permutation->loc_LightPosition, r_shadow_entitylightorigin[0], r_shadow_entitylightorigin[1], r_shadow_entitylightorigin[2]);
- if (r_glsl_permutation->loc_LightColor >= 0) qglUniform3fARB(r_glsl_permutation->loc_LightColor, lightcolorbase[0], lightcolorbase[1], lightcolorbase[2]);
- if (r_glsl_permutation->loc_AmbientScale >= 0) qglUniform1fARB(r_glsl_permutation->loc_AmbientScale, r_shadow_rtlight->ambientscale);
- if (r_glsl_permutation->loc_DiffuseScale >= 0) qglUniform1fARB(r_glsl_permutation->loc_DiffuseScale, r_shadow_rtlight->diffusescale);
- if (r_glsl_permutation->loc_SpecularScale >= 0) qglUniform1fARB(r_glsl_permutation->loc_SpecularScale, specularscale);
+ if (r_glsl_permutation->loc_LightPosition >= 0) qglUniform3fARB(r_glsl_permutation->loc_LightPosition, rsurface.entitylightorigin[0], rsurface.entitylightorigin[1], rsurface.entitylightorigin[2]);
+ if (permutation & SHADERPERMUTATION_DIFFUSE)
+ {
+ if (r_glsl_permutation->loc_LightColor >= 0) qglUniform3fARB(r_glsl_permutation->loc_LightColor, lightcolorbase[0], lightcolorbase[1], lightcolorbase[2]);
+ if (r_glsl_permutation->loc_AmbientScale >= 0) qglUniform1fARB(r_glsl_permutation->loc_AmbientScale, ambientscale);
+ if (r_glsl_permutation->loc_DiffuseScale >= 0) qglUniform1fARB(r_glsl_permutation->loc_DiffuseScale, diffusescale);
+ if (r_glsl_permutation->loc_SpecularScale >= 0) qglUniform1fARB(r_glsl_permutation->loc_SpecularScale, specularscale);
+ }
+ else
+ {
+ // ambient only is simpler
+ if (r_glsl_permutation->loc_LightColor >= 0) qglUniform3fARB(r_glsl_permutation->loc_LightColor, lightcolorbase[0] * ambientscale, lightcolorbase[1] * ambientscale, lightcolorbase[2] * ambientscale);
+ if (r_glsl_permutation->loc_AmbientScale >= 0) qglUniform1fARB(r_glsl_permutation->loc_AmbientScale, 1);
+ if (r_glsl_permutation->loc_DiffuseScale >= 0) qglUniform1fARB(r_glsl_permutation->loc_DiffuseScale, 0);
+ if (r_glsl_permutation->loc_SpecularScale >= 0) qglUniform1fARB(r_glsl_permutation->loc_SpecularScale, 0);
+ }
}
- else if (permutation & SHADERPERMUTATION_MODE_LIGHTDIRECTION)
+ else if (mode == SHADERMODE_LIGHTDIRECTION)
{
if (r_glsl_permutation->loc_AmbientColor >= 0)
- qglUniform3fARB(r_glsl_permutation->loc_AmbientColor, rsurface_entity->modellight_ambient[0], rsurface_entity->modellight_ambient[1], rsurface_entity->modellight_ambient[2]);
+ qglUniform3fARB(r_glsl_permutation->loc_AmbientColor, rsurface.modellight_ambient[0] * ambientscale, rsurface.modellight_ambient[1] * ambientscale, rsurface.modellight_ambient[2] * ambientscale);
if (r_glsl_permutation->loc_DiffuseColor >= 0)
- qglUniform3fARB(r_glsl_permutation->loc_DiffuseColor, rsurface_entity->modellight_diffuse[0], rsurface_entity->modellight_diffuse[1], rsurface_entity->modellight_diffuse[2]);
+ qglUniform3fARB(r_glsl_permutation->loc_DiffuseColor, rsurface.modellight_diffuse[0] * diffusescale, rsurface.modellight_diffuse[1] * diffusescale, rsurface.modellight_diffuse[2] * diffusescale);
if (r_glsl_permutation->loc_SpecularColor >= 0)
- qglUniform3fARB(r_glsl_permutation->loc_SpecularColor, rsurface_entity->modellight_diffuse[0] * rsurface_texture->specularscale, rsurface_entity->modellight_diffuse[1] * rsurface_texture->specularscale, rsurface_entity->modellight_diffuse[2] * rsurface_texture->specularscale);
+ qglUniform3fARB(r_glsl_permutation->loc_SpecularColor, rsurface.modellight_diffuse[0] * specularscale, rsurface.modellight_diffuse[1] * specularscale, rsurface.modellight_diffuse[2] * specularscale);
if (r_glsl_permutation->loc_LightDir >= 0)
- qglUniform3fARB(r_glsl_permutation->loc_LightDir, rsurface_entity->modellight_lightdir[0], rsurface_entity->modellight_lightdir[1], rsurface_entity->modellight_lightdir[2]);
+ qglUniform3fARB(r_glsl_permutation->loc_LightDir, rsurface.modellight_lightdir[0], rsurface.modellight_lightdir[1], rsurface.modellight_lightdir[2]);
}
else
{
if (r_glsl_permutation->loc_DiffuseScale >= 0) qglUniform1fARB(r_glsl_permutation->loc_DiffuseScale, r_refdef.lightmapintensity * 2.0f);
if (r_glsl_permutation->loc_SpecularScale >= 0) qglUniform1fARB(r_glsl_permutation->loc_SpecularScale, r_refdef.lightmapintensity * specularscale * 2.0f);
}
- if (r_glsl_permutation->loc_Texture_Normal >= 0) R_Mesh_TexBind(0, R_GetTexture(rsurface_texture->currentskinframe->nmap));
- if (r_glsl_permutation->loc_Texture_Color >= 0) R_Mesh_TexBind(1, R_GetTexture(rsurface_texture->basetexture));
- if (r_glsl_permutation->loc_Texture_Gloss >= 0) R_Mesh_TexBind(2, R_GetTexture(rsurface_texture->glosstexture));
- //if (r_glsl_permutation->loc_Texture_Cube >= 0 && permutation & SHADERPERMUTATION_MODE_LIGHTSOURCE) R_Mesh_TexBindCubeMap(3, R_GetTexture(r_shadow_rtlight->currentcubemap));
- if (r_glsl_permutation->loc_Texture_FogMask >= 0) R_Mesh_TexBind(4, R_GetTexture(r_texture_fogattenuation));
- if (r_glsl_permutation->loc_Texture_Pants >= 0) R_Mesh_TexBind(5, R_GetTexture(rsurface_texture->currentskinframe->pants));
- if (r_glsl_permutation->loc_Texture_Shirt >= 0) R_Mesh_TexBind(6, R_GetTexture(rsurface_texture->currentskinframe->shirt));
- //if (r_glsl_permutation->loc_Texture_Lightmap >= 0) R_Mesh_TexBind(7, R_GetTexture(r_texture_white));
- //if (r_glsl_permutation->loc_Texture_Deluxemap >= 0) R_Mesh_TexBind(8, R_GetTexture(r_texture_blanknormalmap));
- if (r_glsl_permutation->loc_Texture_Glow >= 0) R_Mesh_TexBind(9, R_GetTexture(rsurface_texture->currentskinframe->glow));
if (r_glsl_permutation->loc_GlowScale >= 0) qglUniform1fARB(r_glsl_permutation->loc_GlowScale, r_hdr_glowintensity.value);
- if (r_glsl_permutation->loc_SceneBrightness >= 0) qglUniform1fARB(r_glsl_permutation->loc_SceneBrightness, r_view.colorscale);
+ if (r_glsl_permutation->loc_ContrastBoostCoeff >= 0)
+ {
+ // The formula used is actually:
+ // color.rgb *= SceneBrightness;
+ // color.rgb *= ContrastBoost / ((ContrastBoost - 1) * color.rgb + 1);
+ // I simplify that to
+ // color.rgb *= [[SceneBrightness * ContrastBoost]];
+ // color.rgb /= [[(ContrastBoost - 1) / ContrastBoost]] * color.rgb + 1;
+ // and Black:
+ // color.rgb = [[SceneBrightness * ContrastBoost]] * color.rgb / ([[(ContrastBoost - 1) * SceneBrightness]] * color.rgb + 1);
+ // and do [[calculations]] here in the engine
+ qglUniform1fARB(r_glsl_permutation->loc_ContrastBoostCoeff, (r_glsl_contrastboost.value - 1) * r_view.colorscale);
+ if (r_glsl_permutation->loc_SceneBrightness >= 0) qglUniform1fARB(r_glsl_permutation->loc_SceneBrightness, r_view.colorscale * r_glsl_contrastboost.value);
+ }
+ else
+ if (r_glsl_permutation->loc_SceneBrightness >= 0) qglUniform1fARB(r_glsl_permutation->loc_SceneBrightness, r_view.colorscale);
if (r_glsl_permutation->loc_FogColor >= 0)
{
// additive passes are only darkened by fog, not tinted
- if (r_shadow_rtlight || (rsurface_texture->currentmaterialflags & MATERIALFLAG_ADD))
+ if (rsurface.rtlight || (rsurface.texture->currentmaterialflags & MATERIALFLAG_ADD))
qglUniform3fARB(r_glsl_permutation->loc_FogColor, 0, 0, 0);
else
+ /*
+ {
+ vec3_t fogvec;
+ // color.rgb *= SceneBrightness;
+ VectorScale(r_refdef.fogcolor, r_view.colorscale, fogvec);
+ if(r_glsl_permutation->loc_ContrastBoostCoeff >= 0) // need to support contrast boost
+ {
+ // color.rgb *= ContrastBoost / ((ContrastBoost - 1) * color.rgb + 1);
+ fogvec[0] *= r_glsl_contrastboost.value / ((r_glsl_contrastboost.value - 1) * fogvec[0] + 1);
+ fogvec[1] *= r_glsl_contrastboost.value / ((r_glsl_contrastboost.value - 1) * fogvec[1] + 1);
+ fogvec[2] *= r_glsl_contrastboost.value / ((r_glsl_contrastboost.value - 1) * fogvec[2] + 1);
+ }
+ qglUniform3fARB(r_glsl_permutation->loc_FogColor, fogvec[0], fogvec[1], fogvec[2]);
+ }
+ */
qglUniform3fARB(r_glsl_permutation->loc_FogColor, r_refdef.fogcolor[0], r_refdef.fogcolor[1], r_refdef.fogcolor[2]);
}
- if (r_glsl_permutation->loc_EyePosition >= 0) qglUniform3fARB(r_glsl_permutation->loc_EyePosition, rsurface_modelorg[0], rsurface_modelorg[1], rsurface_modelorg[2]);
+ if (r_glsl_permutation->loc_EyePosition >= 0) qglUniform3fARB(r_glsl_permutation->loc_EyePosition, rsurface.modelorg[0], rsurface.modelorg[1], rsurface.modelorg[2]);
if (r_glsl_permutation->loc_Color_Pants >= 0)
{
- if (rsurface_texture->currentskinframe->pants)
- qglUniform3fARB(r_glsl_permutation->loc_Color_Pants, rsurface_entity->colormap_pantscolor[0], rsurface_entity->colormap_pantscolor[1], rsurface_entity->colormap_pantscolor[2]);
+ if (rsurface.texture->currentskinframe->pants)
+ qglUniform3fARB(r_glsl_permutation->loc_Color_Pants, rsurface.colormap_pantscolor[0], rsurface.colormap_pantscolor[1], rsurface.colormap_pantscolor[2]);
else
qglUniform3fARB(r_glsl_permutation->loc_Color_Pants, 0, 0, 0);
}
if (r_glsl_permutation->loc_Color_Shirt >= 0)
{
- if (rsurface_texture->currentskinframe->shirt)
- qglUniform3fARB(r_glsl_permutation->loc_Color_Shirt, rsurface_entity->colormap_shirtcolor[0], rsurface_entity->colormap_shirtcolor[1], rsurface_entity->colormap_shirtcolor[2]);
+ if (rsurface.texture->currentskinframe->shirt)
+ qglUniform3fARB(r_glsl_permutation->loc_Color_Shirt, rsurface.colormap_shirtcolor[0], rsurface.colormap_shirtcolor[1], rsurface.colormap_shirtcolor[2]);
else
qglUniform3fARB(r_glsl_permutation->loc_Color_Shirt, 0, 0, 0);
}
if (r_glsl_permutation->loc_FogRangeRecip >= 0) qglUniform1fARB(r_glsl_permutation->loc_FogRangeRecip, r_refdef.fograngerecip);
- if (r_glsl_permutation->loc_SpecularPower >= 0) qglUniform1fARB(r_glsl_permutation->loc_SpecularPower, rsurface_texture->specularpower);
+ if (r_glsl_permutation->loc_SpecularPower >= 0) qglUniform1fARB(r_glsl_permutation->loc_SpecularPower, rsurface.texture->specularpower);
if (r_glsl_permutation->loc_OffsetMapping_Scale >= 0) qglUniform1fARB(r_glsl_permutation->loc_OffsetMapping_Scale, r_glsl_offsetmapping_scale.value);
+ if (r_glsl_permutation->loc_DistortScaleRefractReflect >= 0) qglUniform4fARB(r_glsl_permutation->loc_DistortScaleRefractReflect, r_water_refractdistort.value * rsurface.texture->refractfactor, r_water_refractdistort.value * rsurface.texture->refractfactor, r_water_reflectdistort.value * rsurface.texture->reflectfactor, r_water_reflectdistort.value * rsurface.texture->reflectfactor);
+ if (r_glsl_permutation->loc_ScreenScaleRefractReflect >= 0) qglUniform4fARB(r_glsl_permutation->loc_ScreenScaleRefractReflect, r_waterstate.screenscale[0], r_waterstate.screenscale[1], r_waterstate.screenscale[0], r_waterstate.screenscale[1]);
+ if (r_glsl_permutation->loc_ScreenCenterRefractReflect >= 0) qglUniform4fARB(r_glsl_permutation->loc_ScreenCenterRefractReflect, r_waterstate.screencenter[0], r_waterstate.screencenter[1], r_waterstate.screencenter[0], r_waterstate.screencenter[1]);
+ if (r_glsl_permutation->loc_RefractColor >= 0) qglUniform4fvARB(r_glsl_permutation->loc_RefractColor, 1, rsurface.texture->refractcolor4f);
+ if (r_glsl_permutation->loc_ReflectColor >= 0) qglUniform4fvARB(r_glsl_permutation->loc_ReflectColor, 1, rsurface.texture->reflectcolor4f);
+ if (r_glsl_permutation->loc_ReflectFactor >= 0) qglUniform1fARB(r_glsl_permutation->loc_ReflectFactor, rsurface.texture->reflectmax - rsurface.texture->reflectmin);
+ if (r_glsl_permutation->loc_ReflectOffset >= 0) qglUniform1fARB(r_glsl_permutation->loc_ReflectOffset, rsurface.texture->reflectmin);
CHECKGLERROR
return permutation;
}
-void R_SwitchSurfaceShader(int permutation)
+#define SKINFRAME_HASH 1024
+
+struct
{
- if (r_glsl_permutation != r_glsl_permutations + (permutation & SHADERPERMUTATION_COUNTMASK))
- {
- r_glsl_permutation = r_glsl_permutations + (permutation & SHADERPERMUTATION_COUNTMASK);
- CHECKGLERROR
- qglUseProgramObjectARB(r_glsl_permutation->program);
- CHECKGLERROR
- }
+ int loadsequence; // incremented each level change
+ memexpandablearray_t array;
+ skinframe_t *hash[SKINFRAME_HASH];
+}
+r_skinframe;
+
+void R_SkinFrame_PrepareForPurge(void)
+{
+ r_skinframe.loadsequence++;
+ // wrap it without hitting zero
+ if (r_skinframe.loadsequence >= 200)
+ r_skinframe.loadsequence = 1;
+}
+
+void R_SkinFrame_MarkUsed(skinframe_t *skinframe)
+{
+ if (!skinframe)
+ return;
+ // mark the skinframe as used for the purging code
+ skinframe->loadsequence = r_skinframe.loadsequence;
+}
+
+void R_SkinFrame_Purge(void)
+{
+ int i;
+ skinframe_t *s;
+ for (i = 0;i < SKINFRAME_HASH;i++)
+ {
+ for (s = r_skinframe.hash[i];s;s = s->next)
+ {
+ if (s->loadsequence && s->loadsequence != r_skinframe.loadsequence)
+ {
+ if (s->merged == s->base)
+ s->merged = NULL;
+ // FIXME: maybe pass a pointer to the pointer to R_PurgeTexture and reset it to NULL inside? [11/29/2007 Black]
+ R_PurgeTexture(s->stain );s->stain = NULL;
+ R_PurgeTexture(s->merged);s->merged = NULL;
+ R_PurgeTexture(s->base );s->base = NULL;
+ R_PurgeTexture(s->pants );s->pants = NULL;
+ R_PurgeTexture(s->shirt );s->shirt = NULL;
+ R_PurgeTexture(s->nmap );s->nmap = NULL;
+ R_PurgeTexture(s->gloss );s->gloss = NULL;
+ R_PurgeTexture(s->glow );s->glow = NULL;
+ R_PurgeTexture(s->fog );s->fog = NULL;
+ s->loadsequence = 0;
+ }
+ }
+ }
+}
+
+skinframe_t *R_SkinFrame_FindNextByName( skinframe_t *last, const char *name ) {
+ skinframe_t *item;
+ char basename[MAX_QPATH];
+
+ Image_StripImageExtension(name, basename, sizeof(basename));
+
+ if( last == NULL ) {
+ int hashindex;
+ hashindex = CRC_Block((unsigned char *)basename, strlen(basename)) & (SKINFRAME_HASH - 1);
+ item = r_skinframe.hash[hashindex];
+ } else {
+ item = last->next;
+ }
+
+ // linearly search through the hash bucket
+ for( ; item ; item = item->next ) {
+ if( !strcmp( item->basename, basename ) ) {
+ return item;
+ }
+ }
+ return NULL;
+}
+
+skinframe_t *R_SkinFrame_Find(const char *name, int textureflags, int comparewidth, int compareheight, int comparecrc, qboolean add)
+{
+ skinframe_t *item;
+ int hashindex;
+ char basename[MAX_QPATH];
+
+ Image_StripImageExtension(name, basename, sizeof(basename));
+
+ hashindex = CRC_Block((unsigned char *)basename, strlen(basename)) & (SKINFRAME_HASH - 1);
+ for (item = r_skinframe.hash[hashindex];item;item = item->next)
+ if (!strcmp(item->basename, basename) && item->textureflags == textureflags && item->comparewidth == comparewidth && item->compareheight == compareheight && item->comparecrc == comparecrc)
+ break;
+
+ if (!item) {
+ rtexture_t *dyntexture;
+ // check whether its a dynamic texture
+ dyntexture = CL_GetDynTexture( basename );
+ if (!add && !dyntexture)
+ return NULL;
+ item = (skinframe_t *)Mem_ExpandableArray_AllocRecord(&r_skinframe.array);
+ memset(item, 0, sizeof(*item));
+ strlcpy(item->basename, basename, sizeof(item->basename));
+ item->base = dyntexture; // either NULL or dyntexture handle
+ item->textureflags = textureflags;
+ item->comparewidth = comparewidth;
+ item->compareheight = compareheight;
+ item->comparecrc = comparecrc;
+ item->next = r_skinframe.hash[hashindex];
+ r_skinframe.hash[hashindex] = item;
+ }
+ else if( item->base == NULL )
+ {
+ rtexture_t *dyntexture;
+ // check whether its a dynamic texture
+ // this only needs to be done because Purge doesnt delete skinframes - only sets the texture pointers to NULL and we need to restore it before returing.. [11/29/2007 Black]
+ dyntexture = CL_GetDynTexture( basename );
+ item->base = dyntexture; // either NULL or dyntexture handle
+ }
+
+ R_SkinFrame_MarkUsed(item);
+ return item;
+}
+
+skinframe_t *R_SkinFrame_LoadExternal(const char *name, int textureflags, qboolean complain)
+{
+ // FIXME: it should be possible to disable loading various layers using
+ // cvars, to prevent wasted loading time and memory usage if the user does
+ // not want them
+ qboolean loadnormalmap = true;
+ qboolean loadgloss = true;
+ qboolean loadpantsandshirt = true;
+ qboolean loadglow = true;
+ int j;
+ unsigned char *pixels;
+ unsigned char *bumppixels;
+ unsigned char *basepixels = NULL;
+ int basepixels_width;
+ int basepixels_height;
+ skinframe_t *skinframe;
+
+ if (cls.state == ca_dedicated)
+ return NULL;
+
+ // return an existing skinframe if already loaded
+ // if loading of the first image fails, don't make a new skinframe as it
+ // would cause all future lookups of this to be missing
+ skinframe = R_SkinFrame_Find(name, textureflags, 0, 0, 0, false);
+ if (skinframe && skinframe->base)
+ return skinframe;
+
+ basepixels = loadimagepixelsbgra(name, complain, true);
+ if (basepixels == NULL)
+ return NULL;
+
+ // we've got some pixels to store, so really allocate this new texture now
+ if (!skinframe)
+ skinframe = R_SkinFrame_Find(name, textureflags, 0, 0, 0, true);
+ skinframe->stain = NULL;
+ skinframe->merged = NULL;
+ skinframe->base = r_texture_notexture;
+ skinframe->pants = NULL;
+ skinframe->shirt = NULL;
+ skinframe->nmap = r_texture_blanknormalmap;
+ skinframe->gloss = NULL;
+ skinframe->glow = NULL;
+ skinframe->fog = NULL;
+
+ basepixels_width = image_width;
+ basepixels_height = image_height;
+ skinframe->base = R_LoadTexture2D (r_main_texturepool, skinframe->basename, basepixels_width, basepixels_height, basepixels, TEXTYPE_BGRA, skinframe->textureflags & (gl_texturecompression_color.integer ? ~0 : ~TEXF_COMPRESS), NULL);
+
+ if (textureflags & TEXF_ALPHA)
+ {
+ for (j = 3;j < basepixels_width * basepixels_height * 4;j += 4)
+ if (basepixels[j] < 255)
+ break;
+ if (j < basepixels_width * basepixels_height * 4)
+ {
+ // has transparent pixels
+ pixels = (unsigned char *)Mem_Alloc(tempmempool, image_width * image_height * 4);
+ for (j = 0;j < image_width * image_height * 4;j += 4)
+ {
+ pixels[j+0] = 255;
+ pixels[j+1] = 255;
+ pixels[j+2] = 255;
+ pixels[j+3] = basepixels[j+3];
+ }
+ skinframe->fog = R_LoadTexture2D (r_main_texturepool, va("%s_mask", skinframe->basename), image_width, image_height, pixels, TEXTYPE_BGRA, skinframe->textureflags & (gl_texturecompression_color.integer ? ~0 : ~TEXF_COMPRESS), NULL);
+ Mem_Free(pixels);
+ }
+ }
+
+ // _norm is the name used by tenebrae and has been adopted as standard
+ if (loadnormalmap)
+ {
+ if ((pixels = loadimagepixelsbgra(va("%s_norm", skinframe->basename), false, false)) != NULL)
+ {
+ skinframe->nmap = R_LoadTexture2D (r_main_texturepool, va("%s_nmap", skinframe->basename), image_width, image_height, pixels, TEXTYPE_BGRA, skinframe->textureflags & (gl_texturecompression_normal.integer ? ~0 : ~TEXF_COMPRESS), NULL);
+ Mem_Free(pixels);
+ pixels = NULL;
+ }
+ else if (r_shadow_bumpscale_bumpmap.value > 0 && (bumppixels = loadimagepixelsbgra(va("%s_bump", skinframe->basename), false, false)) != NULL)
+ {
+ pixels = (unsigned char *)Mem_Alloc(tempmempool, image_width * image_height * 4);
+ Image_HeightmapToNormalmap_BGRA(bumppixels, pixels, image_width, image_height, false, r_shadow_bumpscale_bumpmap.value);
+ skinframe->nmap = R_LoadTexture2D (r_main_texturepool, va("%s_nmap", skinframe->basename), image_width, image_height, pixels, TEXTYPE_BGRA, skinframe->textureflags & (gl_texturecompression_normal.integer ? ~0 : ~TEXF_COMPRESS), NULL);
+ Mem_Free(pixels);
+ Mem_Free(bumppixels);
+ }
+ else if (r_shadow_bumpscale_basetexture.value > 0)
+ {
+ pixels = (unsigned char *)Mem_Alloc(tempmempool, basepixels_width * basepixels_height * 4);
+ Image_HeightmapToNormalmap_BGRA(basepixels, pixels, basepixels_width, basepixels_height, false, r_shadow_bumpscale_basetexture.value);
+ skinframe->nmap = R_LoadTexture2D (r_main_texturepool, va("%s_nmap", skinframe->basename), basepixels_width, basepixels_height, pixels, TEXTYPE_BGRA, skinframe->textureflags & (gl_texturecompression_normal.integer ? ~0 : ~TEXF_COMPRESS), NULL);
+ Mem_Free(pixels);
+ }
+ }
+ // _luma is supported for tenebrae compatibility
+ // (I think it's a very stupid name, but oh well)
+ // _glow is the preferred name
+ if (loadglow && ((pixels = loadimagepixelsbgra(va("%s_glow", skinframe->basename), false, false)) != NULL || (pixels = loadimagepixelsbgra(va("%s_luma", skinframe->basename), false, false)) != NULL)) {skinframe->glow = R_LoadTexture2D (r_main_texturepool, va("%s_glow", skinframe->basename), image_width, image_height, pixels, TEXTYPE_BGRA, skinframe->textureflags & (gl_texturecompression_glow.integer ? ~0 : ~TEXF_COMPRESS), NULL);Mem_Free(pixels);pixels = NULL;}
+ if (loadgloss && (pixels = loadimagepixelsbgra(va("%s_gloss", skinframe->basename), false, false)) != NULL) {skinframe->gloss = R_LoadTexture2D (r_main_texturepool, va("%s_gloss", skinframe->basename), image_width, image_height, pixels, TEXTYPE_BGRA, skinframe->textureflags & (gl_texturecompression_gloss.integer ? ~0 : ~TEXF_COMPRESS), NULL);Mem_Free(pixels);pixels = NULL;}
+ if (loadpantsandshirt && (pixels = loadimagepixelsbgra(va("%s_pants", skinframe->basename), false, false)) != NULL) {skinframe->pants = R_LoadTexture2D (r_main_texturepool, va("%s_pants", skinframe->basename), image_width, image_height, pixels, TEXTYPE_BGRA, skinframe->textureflags & (gl_texturecompression_color.integer ? ~0 : ~TEXF_COMPRESS), NULL);Mem_Free(pixels);pixels = NULL;}
+ if (loadpantsandshirt && (pixels = loadimagepixelsbgra(va("%s_shirt", skinframe->basename), false, false)) != NULL) {skinframe->shirt = R_LoadTexture2D (r_main_texturepool, va("%s_shirt", skinframe->basename), image_width, image_height, pixels, TEXTYPE_BGRA, skinframe->textureflags & (gl_texturecompression_color.integer ? ~0 : ~TEXF_COMPRESS), NULL);Mem_Free(pixels);pixels = NULL;}
+
+ if (basepixels)
+ Mem_Free(basepixels);
+
+ return skinframe;
+}
+
+static rtexture_t *R_SkinFrame_TextureForSkinLayer(const unsigned char *in, int width, int height, const char *name, const unsigned int *palette, int textureflags, qboolean force)
+{
+ int i;
+ if (!force)
+ {
+ for (i = 0;i < width*height;i++)
+ if (((unsigned char *)&palette[in[i]])[3] > 0)
+ break;
+ if (i == width*height)
+ return NULL;
+ }
+ return R_LoadTexture2D (r_main_texturepool, name, width, height, in, TEXTYPE_PALETTE, textureflags, palette);
+}
+
+// this is only used by .spr32 sprites, HL .spr files, HL .bsp files
+skinframe_t *R_SkinFrame_LoadInternalBGRA(const char *name, int textureflags, const unsigned char *skindata, int width, int height)
+{
+ int i;
+ unsigned char *temp1, *temp2;
+ skinframe_t *skinframe;
+
+ if (cls.state == ca_dedicated)
+ return NULL;
+
+ // if already loaded just return it, otherwise make a new skinframe
+ skinframe = R_SkinFrame_Find(name, textureflags, width, height, skindata ? CRC_Block(skindata, width*height*4) : 0, true);
+ if (skinframe && skinframe->base)
+ return skinframe;
+
+ skinframe->stain = NULL;
+ skinframe->merged = NULL;
+ skinframe->base = r_texture_notexture;
+ skinframe->pants = NULL;
+ skinframe->shirt = NULL;
+ skinframe->nmap = r_texture_blanknormalmap;
+ skinframe->gloss = NULL;
+ skinframe->glow = NULL;
+ skinframe->fog = NULL;
+
+ // if no data was provided, then clearly the caller wanted to get a blank skinframe
+ if (!skindata)
+ return NULL;
+
+ if (r_shadow_bumpscale_basetexture.value > 0)
+ {
+ temp1 = (unsigned char *)Mem_Alloc(tempmempool, width * height * 8);
+ temp2 = temp1 + width * height * 4;
+ Image_HeightmapToNormalmap_BGRA(skindata, temp2, width, height, false, r_shadow_bumpscale_basetexture.value);
+ skinframe->nmap = R_LoadTexture2D(r_main_texturepool, va("%s_nmap", skinframe->basename), width, height, temp2, TEXTYPE_BGRA, skinframe->textureflags | TEXF_ALPHA, NULL);
+ Mem_Free(temp1);
+ }
+ skinframe->base = skinframe->merged = R_LoadTexture2D(r_main_texturepool, skinframe->basename, width, height, skindata, TEXTYPE_BGRA, skinframe->textureflags, NULL);
+ if (textureflags & TEXF_ALPHA)
+ {
+ for (i = 3;i < width * height * 4;i += 4)
+ if (skindata[i] < 255)
+ break;
+ if (i < width * height * 4)
+ {
+ unsigned char *fogpixels = (unsigned char *)Mem_Alloc(tempmempool, width * height * 4);
+ memcpy(fogpixels, skindata, width * height * 4);
+ for (i = 0;i < width * height * 4;i += 4)
+ fogpixels[i] = fogpixels[i+1] = fogpixels[i+2] = 255;
+ skinframe->fog = R_LoadTexture2D(r_main_texturepool, va("%s_fog", skinframe->basename), width, height, fogpixels, TEXTYPE_BGRA, skinframe->textureflags, NULL);
+ Mem_Free(fogpixels);
+ }
+ }
+
+ return skinframe;
+}
+
+skinframe_t *R_SkinFrame_LoadInternalQuake(const char *name, int textureflags, int loadpantsandshirt, int loadglowtexture, const unsigned char *skindata, int width, int height)
+{
+ int i;
+ unsigned char *temp1, *temp2;
+ skinframe_t *skinframe;
+
+ if (cls.state == ca_dedicated)
+ return NULL;
+
+ // if already loaded just return it, otherwise make a new skinframe
+ skinframe = R_SkinFrame_Find(name, textureflags, width, height, skindata ? CRC_Block(skindata, width*height) : 0, true);
+ if (skinframe && skinframe->base)
+ return skinframe;
+
+ skinframe->stain = NULL;
+ skinframe->merged = NULL;
+ skinframe->base = r_texture_notexture;
+ skinframe->pants = NULL;
+ skinframe->shirt = NULL;
+ skinframe->nmap = r_texture_blanknormalmap;
+ skinframe->gloss = NULL;
+ skinframe->glow = NULL;
+ skinframe->fog = NULL;
+
+ // if no data was provided, then clearly the caller wanted to get a blank skinframe
+ if (!skindata)
+ return NULL;
+
+ if (r_shadow_bumpscale_basetexture.value > 0)
+ {
+ temp1 = (unsigned char *)Mem_Alloc(tempmempool, width * height * 8);
+ temp2 = temp1 + width * height * 4;
+ // use either a custom palette or the quake palette
+ Image_Copy8bitBGRA(skindata, temp1, width * height, palette_bgra_complete);
+ Image_HeightmapToNormalmap_BGRA(temp1, temp2, width, height, false, r_shadow_bumpscale_basetexture.value);
+ skinframe->nmap = R_LoadTexture2D(r_main_texturepool, va("%s_nmap", skinframe->basename), width, height, temp2, TEXTYPE_BGRA, skinframe->textureflags | TEXF_ALPHA, NULL);
+ Mem_Free(temp1);
+ }
+ // use either a custom palette, or the quake palette
+ skinframe->base = skinframe->merged = R_SkinFrame_TextureForSkinLayer(skindata, width, height, va("%s_merged", skinframe->basename), (loadglowtexture ? palette_bgra_nofullbrights : ((skinframe->textureflags & TEXF_ALPHA) ? palette_bgra_transparent : palette_bgra_complete)), skinframe->textureflags, true); // all
+ if (loadglowtexture)
+ skinframe->glow = R_SkinFrame_TextureForSkinLayer(skindata, width, height, va("%s_glow", skinframe->basename), palette_bgra_onlyfullbrights, skinframe->textureflags, false); // glow
+ if (loadpantsandshirt)
+ {
+ skinframe->pants = R_SkinFrame_TextureForSkinLayer(skindata, width, height, va("%s_pants", skinframe->basename), palette_bgra_pantsaswhite, skinframe->textureflags, false); // pants
+ skinframe->shirt = R_SkinFrame_TextureForSkinLayer(skindata, width, height, va("%s_shirt", skinframe->basename), palette_bgra_shirtaswhite, skinframe->textureflags, false); // shirt
+ }
+ if (skinframe->pants || skinframe->shirt)
+ skinframe->base = R_SkinFrame_TextureForSkinLayer(skindata, width, height, va("%s_nospecial", skinframe->basename), loadglowtexture ? palette_bgra_nocolormapnofullbrights : palette_bgra_nocolormap, skinframe->textureflags, false); // no special colors
+ if (textureflags & TEXF_ALPHA)
+ {
+ for (i = 0;i < width * height;i++)
+ if (((unsigned char *)palette_bgra_alpha)[skindata[i]*4+3] < 255)
+ break;
+ if (i < width * height)
+ skinframe->fog = R_SkinFrame_TextureForSkinLayer(skindata, width, height, va("%s_fog", skinframe->basename), palette_bgra_alpha, skinframe->textureflags, true); // fog mask
+ }
+
+ return skinframe;
+}
+
+skinframe_t *R_SkinFrame_LoadMissing(void)
+{
+ skinframe_t *skinframe;
+
+ if (cls.state == ca_dedicated)
+ return NULL;
+
+ skinframe = R_SkinFrame_Find("missing", TEXF_PRECACHE, 0, 0, 0, true);
+ skinframe->stain = NULL;
+ skinframe->merged = NULL;
+ skinframe->base = r_texture_notexture;
+ skinframe->pants = NULL;
+ skinframe->shirt = NULL;
+ skinframe->nmap = r_texture_blanknormalmap;
+ skinframe->gloss = NULL;
+ skinframe->glow = NULL;
+ skinframe->fog = NULL;
+
+ return skinframe;
}
void gl_main_start(void)
{
+ int x;
+ double r, alpha;
+
+ r = (-1.0/256.0) * (FOGMASKTABLEWIDTH * FOGMASKTABLEWIDTH);
+ for (x = 0;x < FOGMASKTABLEWIDTH;x++)
+ {
+ alpha = 1 - exp(r / ((double)x*(double)x));
+ if (x == FOGMASKTABLEWIDTH - 1)
+ alpha = 0;
+ r_refdef.fogmasktable[x] = bound(0, alpha, 1);
+ }
+
+ memset(r_qwskincache, 0, sizeof(r_qwskincache));
+ memset(r_qwskincache_skinframe, 0, sizeof(r_qwskincache_skinframe));
+
+ // set up r_skinframe loading system for textures
+ memset(&r_skinframe, 0, sizeof(r_skinframe));
+ r_skinframe.loadsequence = 1;
+ Mem_ExpandableArray_NewArray(&r_skinframe.array, r_main_mempool, sizeof(skinframe_t), 256);
+
r_main_texturepool = R_AllocTexturePool();
R_BuildBlankTextures();
R_BuildNoTexture();
}
R_BuildFogTexture();
memset(&r_bloomstate, 0, sizeof(r_bloomstate));
+ memset(&r_waterstate, 0, sizeof(r_waterstate));
memset(r_glsl_permutations, 0, sizeof(r_glsl_permutations));
memset(&r_svbsp, 0, sizeof (r_svbsp));
}
void gl_main_shutdown(void)
{
+ memset(r_qwskincache, 0, sizeof(r_qwskincache));
+ memset(r_qwskincache_skinframe, 0, sizeof(r_qwskincache_skinframe));
+
+ // clear out the r_skinframe state
+ Mem_ExpandableArray_FreeArray(&r_skinframe.array);
+ memset(&r_skinframe, 0, sizeof(r_skinframe));
+
if (r_svbsp.nodes)
Mem_Free(r_svbsp.nodes);
memset(&r_svbsp, 0, sizeof (r_svbsp));
R_FreeTexturePool(&r_main_texturepool);
r_texture_blanknormalmap = NULL;
r_texture_white = NULL;
+ r_texture_grey128 = NULL;
r_texture_black = NULL;
r_texture_whitecube = NULL;
r_texture_normalizationcube = NULL;
memset(&r_bloomstate, 0, sizeof(r_bloomstate));
+ memset(&r_waterstate, 0, sizeof(r_waterstate));
R_GLSL_Restart_f();
}
{
r_main_mempool = Mem_AllocPool("Renderer", 0, NULL);
- Cmd_AddCommand("r_glsl_restart", R_GLSL_Restart_f, "unloads GLSL shaders, they will then be reloaded as needed\n");
- FOG_registercvars(); // FIXME: move this fog stuff to client?
+ Cmd_AddCommand("r_glsl_restart", R_GLSL_Restart_f, "unloads GLSL shaders, they will then be reloaded as needed");
+ Cmd_AddCommand("r_glsl_dumpshader", R_GLSL_DumpShader_f, "dumps the engine internal default.glsl shader into glsl/default.glsl");
+ // FIXME: the client should set up r_refdef.fog stuff including the fogmasktable
+ if (gamemode == GAME_NEHAHRA)
+ {
+ Cvar_RegisterVariable (&gl_fogenable);
+ Cvar_RegisterVariable (&gl_fogdensity);
+ Cvar_RegisterVariable (&gl_fogred);
+ Cvar_RegisterVariable (&gl_foggreen);
+ Cvar_RegisterVariable (&gl_fogblue);
+ Cvar_RegisterVariable (&gl_fogstart);
+ Cvar_RegisterVariable (&gl_fogend);
+ }
+ Cvar_RegisterVariable(&r_depthfirst);
Cvar_RegisterVariable(&r_nearclip);
+ Cvar_RegisterVariable(&r_showbboxes);
Cvar_RegisterVariable(&r_showsurfaces);
Cvar_RegisterVariable(&r_showtris);
Cvar_RegisterVariable(&r_shownormals);
Cvar_RegisterVariable(&r_showdisabledepthtest);
Cvar_RegisterVariable(&r_drawportals);
Cvar_RegisterVariable(&r_drawentities);
+ Cvar_RegisterVariable(&r_cullentities_trace);
+ Cvar_RegisterVariable(&r_cullentities_trace_samples);
+ Cvar_RegisterVariable(&r_cullentities_trace_enlarge);
+ Cvar_RegisterVariable(&r_cullentities_trace_delay);
Cvar_RegisterVariable(&r_drawviewmodel);
Cvar_RegisterVariable(&r_speeds);
Cvar_RegisterVariable(&r_fullbrights);
Cvar_RegisterVariable(&r_shadows);
Cvar_RegisterVariable(&r_shadows_throwdistance);
Cvar_RegisterVariable(&r_q1bsp_skymasking);
+ Cvar_RegisterVariable(&r_polygonoffset_submodel_factor);
+ Cvar_RegisterVariable(&r_polygonoffset_submodel_offset);
Cvar_RegisterVariable(&r_textureunits);
Cvar_RegisterVariable(&r_glsl);
Cvar_RegisterVariable(&r_glsl_offsetmapping);
Cvar_RegisterVariable(&r_glsl_offsetmapping_reliefmapping);
Cvar_RegisterVariable(&r_glsl_offsetmapping_scale);
Cvar_RegisterVariable(&r_glsl_deluxemapping);
+ Cvar_RegisterVariable(&r_water);
+ Cvar_RegisterVariable(&r_water_resolutionmultiplier);
+ Cvar_RegisterVariable(&r_water_clippingplanebias);
+ Cvar_RegisterVariable(&r_water_refractdistort);
+ Cvar_RegisterVariable(&r_water_reflectdistort);
Cvar_RegisterVariable(&r_lerpsprites);
Cvar_RegisterVariable(&r_lerpmodels);
Cvar_RegisterVariable(&r_waterscroll);
Cvar_RegisterVariable(&r_bloom_colorsubtract);
Cvar_RegisterVariable(&r_hdr);
Cvar_RegisterVariable(&r_hdr_scenebrightness);
+ Cvar_RegisterVariable(&r_glsl_contrastboost);
Cvar_RegisterVariable(&r_hdr_glowintensity);
Cvar_RegisterVariable(&r_hdr_range);
Cvar_RegisterVariable(&r_smoothnormals_areaweighting);
if (gamemode == GAME_NEHAHRA || gamemode == GAME_TENEBRAE)
Cvar_SetValue("r_fullbrights", 0);
R_RegisterModule("GL_Main", gl_main_start, gl_main_shutdown, gl_main_newmap);
+
+ Cvar_RegisterVariable(&r_track_sprites);
+ Cvar_RegisterVariable(&r_track_sprites_flags);
+ Cvar_RegisterVariable(&r_track_sprites_scalew);
+ Cvar_RegisterVariable(&r_track_sprites_scaleh);
}
extern void R_Textures_Init(void);
{
int i;
mplane_t *p;
- for (i = 0;i < 4;i++)
+ for (i = 0;i < r_view.numfrustumplanes;i++)
{
+ // skip nearclip plane, it often culls portals when you are very close, and is almost never useful
+ if (i == 4)
+ continue;
p = r_view.frustum + i;
switch(p->signbits)
{
return false;
}
+int R_CullBoxCustomPlanes(const vec3_t mins, const vec3_t maxs, int numplanes, const mplane_t *planes)
+{
+ int i;
+ const mplane_t *p;
+ for (i = 0;i < numplanes;i++)
+ {
+ p = planes + i;
+ switch(p->signbits)
+ {
+ default:
+ case 0:
+ if (p->normal[0]*maxs[0] + p->normal[1]*maxs[1] + p->normal[2]*maxs[2] < p->dist)
+ return true;
+ break;
+ case 1:
+ if (p->normal[0]*mins[0] + p->normal[1]*maxs[1] + p->normal[2]*maxs[2] < p->dist)
+ return true;
+ break;
+ case 2:
+ if (p->normal[0]*maxs[0] + p->normal[1]*mins[1] + p->normal[2]*maxs[2] < p->dist)
+ return true;
+ break;
+ case 3:
+ if (p->normal[0]*mins[0] + p->normal[1]*mins[1] + p->normal[2]*maxs[2] < p->dist)
+ return true;
+ break;
+ case 4:
+ if (p->normal[0]*maxs[0] + p->normal[1]*maxs[1] + p->normal[2]*mins[2] < p->dist)
+ return true;
+ break;
+ case 5:
+ if (p->normal[0]*mins[0] + p->normal[1]*maxs[1] + p->normal[2]*mins[2] < p->dist)
+ return true;
+ break;
+ case 6:
+ if (p->normal[0]*maxs[0] + p->normal[1]*mins[1] + p->normal[2]*mins[2] < p->dist)
+ return true;
+ break;
+ case 7:
+ if (p->normal[0]*mins[0] + p->normal[1]*mins[1] + p->normal[2]*mins[2] < p->dist)
+ return true;
+ break;
+ }
+ }
+ return false;
+}
+
//==================================================================================
static void R_UpdateEntityLighting(entity_render_t *ent)
// move the light direction into modelspace coordinates for lighting code
Matrix4x4_Transform3x3(&ent->inversematrix, tempdiffusenormal, ent->modellight_lightdir);
- VectorNormalize(ent->modellight_lightdir);
+ if(VectorLength2(ent->modellight_lightdir) > 0)
+ {
+ VectorNormalize(ent->modellight_lightdir);
+ }
+ else
+ {
+ VectorSet(ent->modellight_lightdir, 0, 0, 1); // have to set SOME valid vector here
+ }
// scale ambient and directional light contributions according to rendering variables
ent->modellight_ambient[0] *= ent->colormod[0] * r_refdef.lightmapintensity;
if (!r_drawentities.integer)
return;
- renderimask = r_refdef.envmap ? (RENDER_EXTERIORMODEL | RENDER_VIEWMODEL) : (chase_active.integer ? 0 : RENDER_EXTERIORMODEL);
+ renderimask = r_refdef.envmap ? (RENDER_EXTERIORMODEL | RENDER_VIEWMODEL) : ((chase_active.integer || r_waterstate.renderingscene) ? RENDER_VIEWMODEL : RENDER_EXTERIORMODEL);
if (r_refdef.worldmodel && r_refdef.worldmodel->brush.BoxTouchingVisibleLeafs)
{
// worldmodel can check visibility
for (i = 0;i < r_refdef.numentities;i++)
{
ent = r_refdef.entities[i];
- r_viewcache.entityvisible[i] = !(ent->flags & renderimask) && !R_CullBox(ent->mins, ent->maxs) && ((ent->effects & EF_NODEPTHTEST) || r_refdef.worldmodel->brush.BoxTouchingVisibleLeafs(r_refdef.worldmodel, r_viewcache.world_leafvisible, ent->mins, ent->maxs));
+ r_viewcache.entityvisible[i] = !(ent->flags & renderimask) && ((ent->model->type == mod_sprite && (ent->model->sprite.sprnum_type == SPR_LABEL || ent->model->sprite.sprnum_type == SPR_LABEL_SCALE)) || !R_CullBox(ent->mins, ent->maxs)) && ((ent->effects & EF_NODEPTHTEST) || (ent->flags & RENDER_VIEWMODEL) || r_refdef.worldmodel->brush.BoxTouchingVisibleLeafs(r_refdef.worldmodel, r_viewcache.world_leafvisible, ent->mins, ent->maxs));
+
+ }
+ if(r_cullentities_trace.integer)
+ {
+ for (i = 0;i < r_refdef.numentities;i++)
+ {
+ ent = r_refdef.entities[i];
+ if(r_viewcache.entityvisible[i] && !(ent->effects & EF_NODEPTHTEST) && !(ent->flags & RENDER_VIEWMODEL) && !(ent->model && (ent->model->name[0] == '*')))
+ {
+ if(Mod_CanSeeBox_Trace(r_cullentities_trace_samples.integer, r_cullentities_trace_enlarge.value, r_refdef.worldmodel, r_view.origin, ent->mins, ent->maxs))
+ ent->last_trace_visibility = realtime;
+ if(ent->last_trace_visibility < realtime - r_cullentities_trace_delay.value)
+ r_viewcache.entityvisible[i] = 0;
+ }
+ }
}
}
else
for (i = 0;i < r_refdef.numentities;i++)
{
ent = r_refdef.entities[i];
- r_viewcache.entityvisible[i] = !(ent->flags & renderimask) && !R_CullBox(ent->mins, ent->maxs);
+ r_viewcache.entityvisible[i] = !(ent->flags & renderimask) && ((ent->model->type == mod_sprite && (ent->model->sprite.sprnum_type == SPR_LABEL || ent->model->sprite.sprnum_type == SPR_LABEL_SCALE)) || !R_CullBox(ent->mins, ent->maxs));
}
}
return sky;
}
-void R_DrawNoModel(entity_render_t *ent);
-void R_DrawModels(void)
+static void R_DrawNoModel(entity_render_t *ent);
+static void R_DrawModels(void)
{
int i;
entity_render_t *ent;
}
}
+static void R_DrawModelsDepth(void)
+{
+ int i;
+ entity_render_t *ent;
+
+ if (!r_drawentities.integer)
+ return;
+
+ for (i = 0;i < r_refdef.numentities;i++)
+ {
+ if (!r_viewcache.entityvisible[i])
+ continue;
+ ent = r_refdef.entities[i];
+ if (ent->model && ent->model->DrawDepth != NULL)
+ ent->model->DrawDepth(ent);
+ }
+}
+
+static void R_DrawModelsDebug(void)
+{
+ int i;
+ entity_render_t *ent;
+
+ if (!r_drawentities.integer)
+ return;
+
+ for (i = 0;i < r_refdef.numentities;i++)
+ {
+ if (!r_viewcache.entityvisible[i])
+ continue;
+ ent = r_refdef.entities[i];
+ if (ent->model && ent->model->DrawDebug != NULL)
+ ent->model->DrawDebug(ent);
+ }
+}
+
+static void R_DrawModelsAddWaterPlanes(void)
+{
+ int i;
+ entity_render_t *ent;
+
+ if (!r_drawentities.integer)
+ return;
+
+ for (i = 0;i < r_refdef.numentities;i++)
+ {
+ if (!r_viewcache.entityvisible[i])
+ continue;
+ ent = r_refdef.entities[i];
+ if (ent->model && ent->model->DrawAddWaterPlanes != NULL)
+ ent->model->DrawAddWaterPlanes(ent);
+ }
+}
+
static void R_View_SetFrustum(void)
{
+ int i;
+ double slopex, slopey;
+
// break apart the view matrix into vectors for various purposes
Matrix4x4_ToVectors(&r_view.matrix, r_view.forward, r_view.left, r_view.up, r_view.origin);
VectorNegate(r_view.left, r_view.right);
r_view.frustum[5].dist = m[15] + m[14];
#endif
+ if (r_view.useperspective)
+ {
+ slopex = 1.0 / r_view.frustum_x;
+ slopey = 1.0 / r_view.frustum_y;
+ VectorMA(r_view.forward, -slopex, r_view.left, r_view.frustum[0].normal);
+ VectorMA(r_view.forward, slopex, r_view.left, r_view.frustum[1].normal);
+ VectorMA(r_view.forward, -slopey, r_view.up , r_view.frustum[2].normal);
+ VectorMA(r_view.forward, slopey, r_view.up , r_view.frustum[3].normal);
+ VectorCopy(r_view.forward, r_view.frustum[4].normal);
+
+ // Leaving those out was a mistake, those were in the old code, and they
+ // fix a reproducable bug in this one: frustum culling got fucked up when viewmatrix was an identity matrix
+ // I couldn't reproduce it after adding those normalizations. --blub
+ VectorNormalize(r_view.frustum[0].normal);
+ VectorNormalize(r_view.frustum[1].normal);
+ VectorNormalize(r_view.frustum[2].normal);
+ VectorNormalize(r_view.frustum[3].normal);
+
+ // calculate frustum corners, which are used to calculate deformed frustum planes for shadow caster culling
+ VectorMAMAMAM(1, r_view.origin, 1024, r_view.forward, -1024 * slopex, r_view.left, -1024 * slopey, r_view.up, r_view.frustumcorner[0]);
+ VectorMAMAMAM(1, r_view.origin, 1024, r_view.forward, 1024 * slopex, r_view.left, -1024 * slopey, r_view.up, r_view.frustumcorner[1]);
+ VectorMAMAMAM(1, r_view.origin, 1024, r_view.forward, -1024 * slopex, r_view.left, 1024 * slopey, r_view.up, r_view.frustumcorner[2]);
+ VectorMAMAMAM(1, r_view.origin, 1024, r_view.forward, 1024 * slopex, r_view.left, 1024 * slopey, r_view.up, r_view.frustumcorner[3]);
+
+ r_view.frustum[0].dist = DotProduct (r_view.origin, r_view.frustum[0].normal);
+ r_view.frustum[1].dist = DotProduct (r_view.origin, r_view.frustum[1].normal);
+ r_view.frustum[2].dist = DotProduct (r_view.origin, r_view.frustum[2].normal);
+ r_view.frustum[3].dist = DotProduct (r_view.origin, r_view.frustum[3].normal);
+ r_view.frustum[4].dist = DotProduct (r_view.origin, r_view.frustum[4].normal) + r_refdef.nearclip;
+ }
+ else
+ {
+ VectorScale(r_view.left, -r_view.ortho_x, r_view.frustum[0].normal);
+ VectorScale(r_view.left, r_view.ortho_x, r_view.frustum[1].normal);
+ VectorScale(r_view.up, -r_view.ortho_y, r_view.frustum[2].normal);
+ VectorScale(r_view.up, r_view.ortho_y, r_view.frustum[3].normal);
+ VectorCopy(r_view.forward, r_view.frustum[4].normal);
+ r_view.frustum[0].dist = DotProduct (r_view.origin, r_view.frustum[0].normal) + r_view.ortho_x;
+ r_view.frustum[1].dist = DotProduct (r_view.origin, r_view.frustum[1].normal) + r_view.ortho_x;
+ r_view.frustum[2].dist = DotProduct (r_view.origin, r_view.frustum[2].normal) + r_view.ortho_y;
+ r_view.frustum[3].dist = DotProduct (r_view.origin, r_view.frustum[3].normal) + r_view.ortho_y;
+ r_view.frustum[4].dist = DotProduct (r_view.origin, r_view.frustum[4].normal) + r_refdef.nearclip;
+ }
+ r_view.numfrustumplanes = 5;
+ if (r_view.useclipplane)
+ {
+ r_view.numfrustumplanes = 6;
+ r_view.frustum[5] = r_view.clipplane;
+ }
- VectorMAM(1, r_view.forward, 1.0 / -r_view.frustum_x, r_view.left, r_view.frustum[0].normal);
- VectorMAM(1, r_view.forward, 1.0 / r_view.frustum_x, r_view.left, r_view.frustum[1].normal);
- VectorMAM(1, r_view.forward, 1.0 / -r_view.frustum_y, r_view.up, r_view.frustum[2].normal);
- VectorMAM(1, r_view.forward, 1.0 / r_view.frustum_y, r_view.up, r_view.frustum[3].normal);
- VectorCopy(r_view.forward, r_view.frustum[4].normal);
- VectorNormalize(r_view.frustum[0].normal);
- VectorNormalize(r_view.frustum[1].normal);
- VectorNormalize(r_view.frustum[2].normal);
- VectorNormalize(r_view.frustum[3].normal);
- r_view.frustum[0].dist = DotProduct (r_view.origin, r_view.frustum[0].normal);
- r_view.frustum[1].dist = DotProduct (r_view.origin, r_view.frustum[1].normal);
- r_view.frustum[2].dist = DotProduct (r_view.origin, r_view.frustum[2].normal);
- r_view.frustum[3].dist = DotProduct (r_view.origin, r_view.frustum[3].normal);
- r_view.frustum[4].dist = DotProduct (r_view.origin, r_view.frustum[4].normal) + r_refdef.nearclip;
- PlaneClassify(&r_view.frustum[0]);
- PlaneClassify(&r_view.frustum[1]);
- PlaneClassify(&r_view.frustum[2]);
- PlaneClassify(&r_view.frustum[3]);
- PlaneClassify(&r_view.frustum[4]);
+ for (i = 0;i < r_view.numfrustumplanes;i++)
+ PlaneClassify(r_view.frustum + i);
// LordHavoc: note to all quake engine coders, Quake had a special case
// for 90 degrees which assumed a square view (wrong), so I removed it,
void R_View_Update(void)
{
R_View_SetFrustum();
- R_View_WorldVisibility();
+ R_View_WorldVisibility(r_view.useclipplane);
R_View_UpdateEntityVisible();
}
-void R_SetupView(const matrix4x4_t *matrix)
+void R_SetupView(void)
{
- if (r_refdef.rtworldshadows || r_refdef.rtdlightshadows)
+ if (!r_view.useperspective)
+ GL_SetupView_Mode_Ortho(-r_view.ortho_x, -r_view.ortho_y, r_view.ortho_x, r_view.ortho_y, -r_refdef.farclip, r_refdef.farclip);
+ else if (r_refdef.rtworldshadows || r_refdef.rtdlightshadows)
GL_SetupView_Mode_PerspectiveInfiniteFarClip(r_view.frustum_x, r_view.frustum_y, r_refdef.nearclip);
else
GL_SetupView_Mode_Perspective(r_view.frustum_x, r_view.frustum_y, r_refdef.nearclip, r_refdef.farclip);
- GL_SetupView_Orientation_FromEntity(matrix);
+ GL_SetupView_Orientation_FromEntity(&r_view.matrix);
+
+ if (r_view.useclipplane)
+ {
+ // LordHavoc: couldn't figure out how to make this approach the
+ vec_t dist = r_view.clipplane.dist - r_water_clippingplanebias.value;
+ vec_t viewdist = DotProduct(r_view.origin, r_view.clipplane.normal);
+ if (viewdist < r_view.clipplane.dist + r_water_clippingplanebias.value)
+ dist = r_view.clipplane.dist;
+ GL_SetupView_ApplyCustomNearClipPlane(r_view.clipplane.normal[0], r_view.clipplane.normal[1], r_view.clipplane.normal[2], dist);
+ }
}
void R_ResetViewRendering2D(void)
GL_AlphaTest(false);
GL_ScissorTest(false);
GL_DepthMask(false);
+ GL_DepthRange(0, 1);
GL_DepthTest(false);
R_Mesh_Matrix(&identitymatrix);
R_Mesh_ResetTextureState();
- qglPolygonOffset(r_refdef.polygonfactor, r_refdef.polygonoffset);CHECKGLERROR
+ GL_PolygonOffset(0, 0);
qglEnable(GL_POLYGON_OFFSET_FILL);CHECKGLERROR
qglDepthFunc(GL_LEQUAL);CHECKGLERROR
qglDisable(GL_STENCIL_TEST);CHECKGLERROR
// GL is weird because it's bottom to top, r_view.y is top to bottom
qglViewport(r_view.x, vid.height - (r_view.y + r_view.height), r_view.width, r_view.height);CHECKGLERROR
- R_SetupView(&r_view.matrix);
+ R_SetupView();
GL_Scissor(r_view.x, r_view.y, r_view.width, r_view.height);
GL_Color(1, 1, 1, 1);
GL_ColorMask(r_view.colormask[0], r_view.colormask[1], r_view.colormask[2], 1);
GL_AlphaTest(false);
GL_ScissorTest(true);
GL_DepthMask(true);
+ GL_DepthRange(0, 1);
GL_DepthTest(true);
R_Mesh_Matrix(&identitymatrix);
R_Mesh_ResetTextureState();
- qglPolygonOffset(r_refdef.polygonfactor, r_refdef.polygonoffset);CHECKGLERROR
+ GL_PolygonOffset(r_refdef.polygonfactor, r_refdef.polygonoffset);
qglEnable(GL_POLYGON_OFFSET_FILL);CHECKGLERROR
qglDepthFunc(GL_LEQUAL);CHECKGLERROR
qglDisable(GL_STENCIL_TEST);CHECKGLERROR
qglStencilMask(~0);CHECKGLERROR
qglStencilFunc(GL_ALWAYS, 128, ~0);CHECKGLERROR
qglStencilOp(GL_KEEP, GL_KEEP, GL_KEEP);CHECKGLERROR
- GL_CullFace(GL_FRONT); // quake is backwards, this culls back faces
+ GL_CullFace(r_view.cullface_back);
}
/*
"#endif // FRAGMENT_SHADER\n"
*/
-void R_RenderScene(void);
+void R_RenderScene(qboolean addwaterplanes);
-void R_Bloom_StartFrame(void)
+static void R_Water_StartFrame(void)
{
- int bloomtexturewidth, bloomtextureheight, screentexturewidth, screentextureheight;
+ int i;
+ int waterwidth, waterheight, texturewidth, textureheight;
+ r_waterstate_waterplane_t *p;
- // set bloomwidth and bloomheight to the bloom resolution that will be
+ // set waterwidth and waterheight to the water resolution that will be
// used (often less than the screen resolution for faster rendering)
- r_bloomstate.bloomwidth = bound(1, r_bloom_resolution.integer, r_view.width);
- r_bloomstate.bloomheight = r_bloomstate.bloomwidth * r_view.height / r_view.width;
- r_bloomstate.bloomheight = bound(1, r_bloomstate.bloomheight, r_view.height);
+ waterwidth = (int)bound(1, r_view.width * r_water_resolutionmultiplier.value, r_view.width);
+ waterheight = (int)bound(1, r_view.height * r_water_resolutionmultiplier.value, r_view.height);
// calculate desired texture sizes
- if (gl_support_arb_texture_non_power_of_two)
+ // can't use water if the card does not support the texture size
+ if (!r_water.integer || !r_glsl.integer || !gl_support_fragment_shader || waterwidth > gl_max_texture_size || waterheight > gl_max_texture_size)
+ texturewidth = textureheight = waterwidth = waterheight = 0;
+ else if (gl_support_arb_texture_non_power_of_two)
{
- screentexturewidth = r_view.width;
- screentextureheight = r_view.height;
- bloomtexturewidth = r_bloomstate.bloomwidth;
- bloomtextureheight = r_bloomstate.bloomheight;
+ texturewidth = waterwidth;
+ textureheight = waterheight;
}
else
{
- for (screentexturewidth = 1;screentexturewidth < vid.width ;screentexturewidth *= 2);
- for (screentextureheight = 1;screentextureheight < vid.height ;screentextureheight *= 2);
- for (bloomtexturewidth = 1;bloomtexturewidth < r_bloomstate.bloomwidth ;bloomtexturewidth *= 2);
- for (bloomtextureheight = 1;bloomtextureheight < r_bloomstate.bloomheight;bloomtextureheight *= 2);
+ for (texturewidth = 1;texturewidth < waterwidth ;texturewidth *= 2);
+ for (textureheight = 1;textureheight < waterheight;textureheight *= 2);
}
- if (r_hdr.integer)
+ // allocate textures as needed
+ if (r_waterstate.waterwidth != waterwidth || r_waterstate.waterheight != waterheight || r_waterstate.texturewidth != texturewidth || r_waterstate.textureheight != textureheight)
{
- screentexturewidth = screentextureheight = 0;
+ r_waterstate.maxwaterplanes = MAX_WATERPLANES;
+ for (i = 0, p = r_waterstate.waterplanes;i < r_waterstate.maxwaterplanes;i++, p++)
+ {
+ if (p->texture_refraction)
+ R_FreeTexture(p->texture_refraction);
+ p->texture_refraction = NULL;
+ if (p->texture_reflection)
+ R_FreeTexture(p->texture_reflection);
+ p->texture_reflection = NULL;
+ }
+ memset(&r_waterstate, 0, sizeof(r_waterstate));
+ r_waterstate.waterwidth = waterwidth;
+ r_waterstate.waterheight = waterheight;
+ r_waterstate.texturewidth = texturewidth;
+ r_waterstate.textureheight = textureheight;
}
- else if (r_bloom.integer)
+
+ if (r_waterstate.waterwidth)
{
+ r_waterstate.enabled = true;
+
+ // set up variables that will be used in shader setup
+ r_waterstate.screenscale[0] = 0.5f * (float)waterwidth / (float)texturewidth;
+ r_waterstate.screenscale[1] = 0.5f * (float)waterheight / (float)textureheight;
+ r_waterstate.screencenter[0] = 0.5f * (float)waterwidth / (float)texturewidth;
+ r_waterstate.screencenter[1] = 0.5f * (float)waterheight / (float)textureheight;
}
- else
+
+ r_waterstate.maxwaterplanes = MAX_WATERPLANES;
+ r_waterstate.numwaterplanes = 0;
+}
+
+static void R_Water_AddWaterPlane(msurface_t *surface)
+{
+ int triangleindex, planeindex;
+ const int *e;
+ vec_t f;
+ vec3_t vert[3];
+ vec3_t normal;
+ vec3_t center;
+ r_waterstate_waterplane_t *p;
+ // just use the first triangle with a valid normal for any decisions
+ VectorClear(normal);
+ VectorClear(center);
+ for (triangleindex = 0, e = rsurface.modelelement3i + surface->num_firsttriangle * 3;triangleindex < surface->num_triangles;triangleindex++, e += 3)
{
- screentexturewidth = screentextureheight = 0;
- bloomtexturewidth = bloomtextureheight = 0;
+ Matrix4x4_Transform(&rsurface.matrix, rsurface.modelvertex3f + e[0]*3, vert[0]);
+ Matrix4x4_Transform(&rsurface.matrix, rsurface.modelvertex3f + e[1]*3, vert[1]);
+ Matrix4x4_Transform(&rsurface.matrix, rsurface.modelvertex3f + e[2]*3, vert[2]);
+ TriangleNormal(vert[0], vert[1], vert[2], normal);
+ if (VectorLength2(normal) >= 0.001)
+ break;
+ }
+ // now find the center of this surface
+ for (triangleindex = 0, e = rsurface.modelelement3i + surface->num_firsttriangle * 3;triangleindex < surface->num_triangles*3;triangleindex++, e++)
+ {
+ Matrix4x4_Transform(&rsurface.matrix, rsurface.modelvertex3f + e[0]*3, vert[0]);
+ VectorAdd(center, vert[0], center);
}
+ f = 1.0 / surface->num_triangles*3;
+ VectorScale(center, f, center);
- if ((!bloomtexturewidth && !bloomtextureheight) || r_bloom_resolution.integer < 4 || r_bloom_blur.value < 1 || r_bloom_blur.value >= 512 || screentexturewidth > gl_max_texture_size || screentextureheight > gl_max_texture_size || bloomtexturewidth > gl_max_texture_size || bloomtextureheight > gl_max_texture_size)
+ // find a matching plane if there is one
+ for (planeindex = 0, p = r_waterstate.waterplanes;planeindex < r_waterstate.numwaterplanes;planeindex++, p++)
+ if (fabs(PlaneDiff(vert[0], &p->plane)) < 1 && fabs(PlaneDiff(vert[1], &p->plane)) < 1 && fabs(PlaneDiff(vert[2], &p->plane)) < 1)
+ break;
+ if (planeindex >= r_waterstate.maxwaterplanes)
+ return; // nothing we can do, out of planes
+
+ // if this triangle does not fit any known plane rendered this frame, add one
+ if (planeindex >= r_waterstate.numwaterplanes)
+ {
+ // store the new plane
+ r_waterstate.numwaterplanes++;
+ VectorCopy(normal, p->plane.normal);
+ VectorNormalize(p->plane.normal);
+ p->plane.dist = DotProduct(vert[0], p->plane.normal);
+ PlaneClassify(&p->plane);
+ // flip the plane if it does not face the viewer
+ if (PlaneDiff(r_view.origin, &p->plane) < 0)
+ {
+ VectorNegate(p->plane.normal, p->plane.normal);
+ p->plane.dist *= -1;
+ PlaneClassify(&p->plane);
+ }
+ // clear materialflags and pvs
+ p->materialflags = 0;
+ p->pvsvalid = false;
+ }
+ // merge this surface's materialflags into the waterplane
+ p->materialflags |= surface->texture->currentframe->currentmaterialflags;
+ // merge this surface's PVS into the waterplane
+ if (p->materialflags & (MATERIALFLAG_WATERSHADER | MATERIALFLAG_REFRACTION | MATERIALFLAG_REFLECTION) && r_refdef.worldmodel && r_refdef.worldmodel->brush.FatPVS)
+ {
+ r_refdef.worldmodel->brush.FatPVS(r_refdef.worldmodel, r_view.origin, 2, p->pvsbits, sizeof(p->pvsbits), p->pvsvalid);
+ p->pvsvalid = true;
+ }
+}
+
+static void R_Water_ProcessPlanes(void)
+{
+ r_view_t originalview;
+ int planeindex;
+ r_waterstate_waterplane_t *p;
+
+ originalview = r_view;
+
+ // make sure enough textures are allocated
+ for (planeindex = 0, p = r_waterstate.waterplanes;planeindex < r_waterstate.numwaterplanes;planeindex++, p++)
+ {
+ if (p->materialflags & (MATERIALFLAG_WATERSHADER | MATERIALFLAG_REFRACTION))
+ {
+ if (!p->texture_refraction)
+ p->texture_refraction = R_LoadTexture2D(r_main_texturepool, va("waterplane%i_refraction", planeindex), r_waterstate.texturewidth, r_waterstate.textureheight, NULL, TEXTYPE_BGRA, TEXF_FORCELINEAR | TEXF_CLAMP | TEXF_ALWAYSPRECACHE, NULL);
+ if (!p->texture_refraction)
+ goto error;
+ }
+
+ if (p->materialflags & (MATERIALFLAG_WATERSHADER | MATERIALFLAG_REFLECTION))
+ {
+ if (!p->texture_reflection)
+ p->texture_reflection = R_LoadTexture2D(r_main_texturepool, va("waterplane%i_reflection", planeindex), r_waterstate.texturewidth, r_waterstate.textureheight, NULL, TEXTYPE_BGRA, TEXF_FORCELINEAR | TEXF_CLAMP | TEXF_ALWAYSPRECACHE, NULL);
+ if (!p->texture_reflection)
+ goto error;
+ }
+ }
+
+ // render views
+ for (planeindex = 0, p = r_waterstate.waterplanes;planeindex < r_waterstate.numwaterplanes;planeindex++, p++)
+ {
+ r_view.showdebug = false;
+ r_view.width = r_waterstate.waterwidth;
+ r_view.height = r_waterstate.waterheight;
+ r_view.useclipplane = true;
+ r_waterstate.renderingscene = true;
+
+ // render the normal view scene and copy into texture
+ // (except that a clipping plane should be used to hide everything on one side of the water, and the viewer's weapon model should be omitted)
+ if (p->materialflags & (MATERIALFLAG_WATERSHADER | MATERIALFLAG_REFRACTION))
+ {
+ r_view.clipplane = p->plane;
+ VectorNegate(r_view.clipplane.normal, r_view.clipplane.normal);
+ r_view.clipplane.dist = -r_view.clipplane.dist;
+ PlaneClassify(&r_view.clipplane);
+
+ R_RenderScene(false);
+
+ // copy view into the screen texture
+ R_Mesh_TexBind(0, R_GetTexture(p->texture_refraction));
+ GL_ActiveTexture(0);
+ CHECKGLERROR
+ qglCopyTexSubImage2D(GL_TEXTURE_2D, 0, 0, 0, r_view.x, vid.height - (r_view.y + r_view.height), r_view.width, r_view.height);CHECKGLERROR
+ }
+
+ if (p->materialflags & (MATERIALFLAG_WATERSHADER | MATERIALFLAG_REFLECTION))
+ {
+ // render reflected scene and copy into texture
+ Matrix4x4_Reflect(&r_view.matrix, p->plane.normal[0], p->plane.normal[1], p->plane.normal[2], p->plane.dist, -2);
+ r_view.clipplane = p->plane;
+ // reverse the cullface settings for this render
+ r_view.cullface_front = GL_FRONT;
+ r_view.cullface_back = GL_BACK;
+ if (r_refdef.worldmodel && r_refdef.worldmodel->brush.num_pvsclusterbytes)
+ {
+ r_view.usecustompvs = true;
+ if (p->pvsvalid)
+ memcpy(r_viewcache.world_pvsbits, p->pvsbits, r_refdef.worldmodel->brush.num_pvsclusterbytes);
+ else
+ memset(r_viewcache.world_pvsbits, 0xFF, r_refdef.worldmodel->brush.num_pvsclusterbytes);
+ }
+
+ R_ResetViewRendering3D();
+ R_ClearScreen();
+ if (r_timereport_active)
+ R_TimeReport("viewclear");
+
+ R_RenderScene(false);
+
+ R_Mesh_TexBind(0, R_GetTexture(p->texture_reflection));
+ GL_ActiveTexture(0);
+ CHECKGLERROR
+ qglCopyTexSubImage2D(GL_TEXTURE_2D, 0, 0, 0, r_view.x, vid.height - (r_view.y + r_view.height), r_view.width, r_view.height);CHECKGLERROR
+
+ R_ResetViewRendering3D();
+ R_ClearScreen();
+ if (r_timereport_active)
+ R_TimeReport("viewclear");
+ }
+
+ r_view = originalview;
+ r_view.clear = true;
+ r_waterstate.renderingscene = false;
+ }
+ return;
+error:
+ r_view = originalview;
+ r_waterstate.renderingscene = false;
+ Cvar_SetValueQuick(&r_water, 0);
+ Con_Printf("R_Water_ProcessPlanes: Error: texture creation failed! Turned off r_water.\n");
+ return;
+}
+
+void R_Bloom_StartFrame(void)
+{
+ int bloomtexturewidth, bloomtextureheight, screentexturewidth, screentextureheight;
+
+ // set bloomwidth and bloomheight to the bloom resolution that will be
+ // used (often less than the screen resolution for faster rendering)
+ r_bloomstate.bloomwidth = bound(1, r_bloom_resolution.integer, r_view.width);
+ r_bloomstate.bloomheight = r_bloomstate.bloomwidth * r_view.height / r_view.width;
+ r_bloomstate.bloomheight = bound(1, r_bloomstate.bloomheight, r_view.height);
+
+ // calculate desired texture sizes
+ if (gl_support_arb_texture_non_power_of_two)
+ {
+ screentexturewidth = r_view.width;
+ screentextureheight = r_view.height;
+ bloomtexturewidth = r_bloomstate.bloomwidth;
+ bloomtextureheight = r_bloomstate.bloomheight;
+ }
+ else
+ {
+ for (screentexturewidth = 1;screentexturewidth < vid.width ;screentexturewidth *= 2);
+ for (screentextureheight = 1;screentextureheight < vid.height ;screentextureheight *= 2);
+ for (bloomtexturewidth = 1;bloomtexturewidth < r_bloomstate.bloomwidth ;bloomtexturewidth *= 2);
+ for (bloomtextureheight = 1;bloomtextureheight < r_bloomstate.bloomheight;bloomtextureheight *= 2);
+ }
+
+ if (r_hdr.integer)
+ {
+ screentexturewidth = screentextureheight = 0;
+ }
+ else if (r_bloom.integer)
+ {
+ }
+ else
+ {
+ screentexturewidth = screentextureheight = 0;
+ bloomtexturewidth = bloomtextureheight = 0;
+ }
+
+ if ((!bloomtexturewidth && !bloomtextureheight) || r_bloom_resolution.integer < 4 || r_bloom_blur.value < 1 || r_bloom_blur.value >= 512 || screentexturewidth > gl_max_texture_size || screentextureheight > gl_max_texture_size || bloomtexturewidth > gl_max_texture_size || bloomtextureheight > gl_max_texture_size)
{
// can't use bloom if the parameters are too weird
// can't use bloom if the card does not support the texture size
r_bloomstate.screentexturewidth = screentexturewidth;
r_bloomstate.screentextureheight = screentextureheight;
if (r_bloomstate.screentexturewidth && r_bloomstate.screentextureheight)
- r_bloomstate.texture_screen = R_LoadTexture2D(r_main_texturepool, "screen", r_bloomstate.screentexturewidth, r_bloomstate.screentextureheight, NULL, TEXTYPE_RGBA, TEXF_FORCENEAREST | TEXF_CLAMP | TEXF_ALWAYSPRECACHE, NULL);
+ r_bloomstate.texture_screen = R_LoadTexture2D(r_main_texturepool, "screen", r_bloomstate.screentexturewidth, r_bloomstate.screentextureheight, NULL, TEXTYPE_BGRA, TEXF_FORCENEAREST | TEXF_CLAMP | TEXF_ALWAYSPRECACHE, NULL);
}
if (r_bloomstate.bloomtexturewidth != bloomtexturewidth || r_bloomstate.bloomtextureheight != bloomtextureheight)
{
r_bloomstate.bloomtexturewidth = bloomtexturewidth;
r_bloomstate.bloomtextureheight = bloomtextureheight;
if (r_bloomstate.bloomtexturewidth && r_bloomstate.bloomtextureheight)
- r_bloomstate.texture_bloom = R_LoadTexture2D(r_main_texturepool, "bloom", r_bloomstate.bloomtexturewidth, r_bloomstate.bloomtextureheight, NULL, TEXTYPE_RGBA, TEXF_FORCELINEAR | TEXF_CLAMP | TEXF_ALWAYSPRECACHE, NULL);
+ r_bloomstate.texture_bloom = R_LoadTexture2D(r_main_texturepool, "bloom", r_bloomstate.bloomtexturewidth, r_bloomstate.bloomtextureheight, NULL, TEXTYPE_BGRA, TEXF_FORCELINEAR | TEXF_CLAMP | TEXF_ALWAYSPRECACHE, NULL);
}
// set up a texcoord array for the full resolution screen image
r_refdef.stats.bloom++;
R_ResetViewRendering2D();
- R_Mesh_VertexPointer(r_screenvertex3f);
- R_Mesh_ColorPointer(NULL);
- R_Mesh_TexCoordPointer(0, 2, r_bloomstate.screentexcoord2f);
+ R_Mesh_VertexPointer(r_screenvertex3f, 0, 0);
+ R_Mesh_ColorPointer(NULL, 0, 0);
+ R_Mesh_TexCoordPointer(0, 2, r_bloomstate.screentexcoord2f, 0, 0);
R_Mesh_TexBind(0, R_GetTexture(r_bloomstate.texture_screen));
// copy view into the screen texture
GL_BlendFunc(GL_ONE, GL_ZERO);
GL_Color(colorscale, colorscale, colorscale, 1);
// TODO: optimize with multitexture or GLSL
- R_Mesh_Draw(0, 4, 2, polygonelements);
+ R_Mesh_Draw(0, 4, 2, polygonelements, 0, 0);
r_refdef.stats.bloom_drawpixels += r_bloomstate.bloomwidth * r_bloomstate.bloomheight;
// we now have a bloom image in the framebuffer
r_refdef.stats.bloom++;
R_ResetViewRendering2D();
- R_Mesh_VertexPointer(r_screenvertex3f);
- R_Mesh_ColorPointer(NULL);
+ R_Mesh_VertexPointer(r_screenvertex3f, 0, 0);
+ R_Mesh_ColorPointer(NULL, 0, 0);
// we have a bloom image in the framebuffer
CHECKGLERROR
qglViewport(r_view.x, vid.height - (r_view.y + r_bloomstate.bloomheight), r_bloomstate.bloomwidth, r_bloomstate.bloomheight);CHECKGLERROR
- for (x = 1;x < r_bloom_colorexponent.value;)
+ for (x = 1;x < min(r_bloom_colorexponent.value, 32);)
{
x *= 2;
r = bound(0, r_bloom_colorexponent.value / x, 1);
GL_BlendFunc(GL_DST_COLOR, GL_SRC_COLOR);
GL_Color(r, r, r, 1);
R_Mesh_TexBind(0, R_GetTexture(r_bloomstate.texture_bloom));
- R_Mesh_TexCoordPointer(0, 2, r_bloomstate.bloomtexcoord2f);
- R_Mesh_Draw(0, 4, 2, polygonelements);
+ R_Mesh_TexCoordPointer(0, 2, r_bloomstate.bloomtexcoord2f, 0, 0);
+ R_Mesh_Draw(0, 4, 2, polygonelements, 0, 0);
r_refdef.stats.bloom_drawpixels += r_bloomstate.bloomwidth * r_bloomstate.bloomheight;
// copy the vertically blurred bloom view to a texture
if (r_hdr.integer)
brighten *= r_hdr_range.value;
R_Mesh_TexBind(0, R_GetTexture(r_bloomstate.texture_bloom));
- R_Mesh_TexCoordPointer(0, 2, r_bloomstate.offsettexcoord2f);
+ R_Mesh_TexCoordPointer(0, 2, r_bloomstate.offsettexcoord2f, 0, 0);
for (dir = 0;dir < 2;dir++)
{
//r = (dir ? 1.0f : brighten)/(range*2+1);
r = (dir ? 1.0f : brighten)/(range*2+1)*(1 - x*x/(float)(range*range));
GL_Color(r, r, r, 1);
- R_Mesh_Draw(0, 4, 2, polygonelements);
+ R_Mesh_Draw(0, 4, 2, polygonelements, 0, 0);
r_refdef.stats.bloom_drawpixels += r_bloomstate.bloomwidth * r_bloomstate.bloomheight;
GL_BlendFunc(GL_ONE, GL_ONE);
}
{
GL_BlendFunc(GL_ONE, GL_ZERO);
R_Mesh_TexBind(0, R_GetTexture(r_bloomstate.texture_bloom));
- R_Mesh_TexCoordPointer(0, 2, r_bloomstate.bloomtexcoord2f);
+ R_Mesh_TexCoordPointer(0, 2, r_bloomstate.bloomtexcoord2f, 0, 0);
GL_Color(1, 1, 1, 1);
- R_Mesh_Draw(0, 4, 2, polygonelements);
+ R_Mesh_Draw(0, 4, 2, polygonelements, 0, 0);
r_refdef.stats.bloom_drawpixels += r_bloomstate.bloomwidth * r_bloomstate.bloomheight;
GL_BlendFunc(GL_ONE, GL_ONE);
qglBlendEquationEXT(GL_FUNC_REVERSE_SUBTRACT_EXT);
R_Mesh_TexBind(0, R_GetTexture(r_texture_white));
- R_Mesh_TexCoordPointer(0, 2, r_bloomstate.bloomtexcoord2f);
+ R_Mesh_TexCoordPointer(0, 2, r_bloomstate.bloomtexcoord2f, 0, 0);
GL_Color(r_bloom_colorsubtract.value, r_bloom_colorsubtract.value, r_bloom_colorsubtract.value, 1);
- R_Mesh_Draw(0, 4, 2, polygonelements);
+ R_Mesh_Draw(0, 4, 2, polygonelements, 0, 0);
r_refdef.stats.bloom_drawpixels += r_bloomstate.bloomwidth * r_bloomstate.bloomheight;
qglBlendEquationEXT(GL_FUNC_ADD_EXT);
// TODO: add exposure compensation features
// TODO: add fp16 framebuffer support
+ r_view.showdebug = false;
r_view.colorscale = r_bloom_colorscale.value * r_hdr_scenebrightness.value;
if (r_hdr.integer)
r_view.colorscale /= r_hdr_range.value;
- R_RenderScene();
+ r_waterstate.numwaterplanes = 0;
+ R_RenderScene(r_waterstate.enabled);
+ r_view.showdebug = true;
R_ResetViewRendering2D();
R_ClearScreen();
if (r_timereport_active)
- R_TimeReport("clear");
-
+ R_TimeReport("viewclear");
// restore the view settings
r_view.width = oldwidth;
// the bloom texture was made earlier this render, so we just need to
// blend it onto the screen...
R_ResetViewRendering2D();
- R_Mesh_VertexPointer(r_screenvertex3f);
- R_Mesh_ColorPointer(NULL);
+ R_Mesh_VertexPointer(r_screenvertex3f, 0, 0);
+ R_Mesh_ColorPointer(NULL, 0, 0);
GL_Color(1, 1, 1, 1);
GL_BlendFunc(GL_ONE, GL_ONE);
R_Mesh_TexBind(0, R_GetTexture(r_bloomstate.texture_bloom));
- R_Mesh_TexCoordPointer(0, 2, r_bloomstate.bloomtexcoord2f);
- R_Mesh_Draw(0, 4, 2, polygonelements);
+ R_Mesh_TexCoordPointer(0, 2, r_bloomstate.bloomtexcoord2f, 0, 0);
+ R_Mesh_Draw(0, 4, 2, polygonelements, 0, 0);
r_refdef.stats.bloom_drawpixels += r_view.width * r_view.height;
}
else if (r_bloomstate.enabled)
// put the original screen image back in place and blend the bloom
// texture on it
R_ResetViewRendering2D();
- R_Mesh_VertexPointer(r_screenvertex3f);
- R_Mesh_ColorPointer(NULL);
+ R_Mesh_VertexPointer(r_screenvertex3f, 0, 0);
+ R_Mesh_ColorPointer(NULL, 0, 0);
GL_Color(1, 1, 1, 1);
GL_BlendFunc(GL_ONE, GL_ZERO);
// do both in one pass if possible
R_Mesh_TexBind(0, R_GetTexture(r_bloomstate.texture_bloom));
- R_Mesh_TexCoordPointer(0, 2, r_bloomstate.bloomtexcoord2f);
+ R_Mesh_TexCoordPointer(0, 2, r_bloomstate.bloomtexcoord2f, 0, 0);
if (r_textureunits.integer >= 2 && gl_combine.integer)
{
R_Mesh_TexCombine(1, GL_ADD, GL_ADD, 1, 1);
R_Mesh_TexBind(1, R_GetTexture(r_bloomstate.texture_screen));
- R_Mesh_TexCoordPointer(1, 2, r_bloomstate.screentexcoord2f);
+ R_Mesh_TexCoordPointer(1, 2, r_bloomstate.screentexcoord2f, 0, 0);
}
else
{
- R_Mesh_Draw(0, 4, 2, polygonelements);
+ R_Mesh_Draw(0, 4, 2, polygonelements, 0, 0);
r_refdef.stats.bloom_drawpixels += r_view.width * r_view.height;
// now blend on the bloom texture
GL_BlendFunc(GL_ONE, GL_ONE);
R_Mesh_TexBind(0, R_GetTexture(r_bloomstate.texture_screen));
- R_Mesh_TexCoordPointer(0, 2, r_bloomstate.screentexcoord2f);
+ R_Mesh_TexCoordPointer(0, 2, r_bloomstate.screentexcoord2f, 0, 0);
}
- R_Mesh_Draw(0, 4, 2, polygonelements);
+ R_Mesh_Draw(0, 4, 2, polygonelements, 0, 0);
r_refdef.stats.bloom_drawpixels += r_view.width * r_view.height;
}
if (r_refdef.viewblend[3] >= (1.0f / 256.0f))
{
// apply a color tint to the whole view
R_ResetViewRendering2D();
- R_Mesh_VertexPointer(r_screenvertex3f);
- R_Mesh_ColorPointer(NULL);
+ R_Mesh_VertexPointer(r_screenvertex3f, 0, 0);
+ R_Mesh_ColorPointer(NULL, 0, 0);
GL_BlendFunc(GL_SRC_ALPHA, GL_ONE_MINUS_SRC_ALPHA);
GL_Color(r_refdef.viewblend[0], r_refdef.viewblend[1], r_refdef.viewblend[2], r_refdef.viewblend[3]);
- R_Mesh_Draw(0, 4, 2, polygonelements);
+ R_Mesh_Draw(0, 4, 2, polygonelements, 0, 0);
}
}
-void R_RenderScene(void);
+void R_RenderScene(qboolean addwaterplanes);
matrix4x4_t r_waterscrollmatrix;
r_refdef.farclip += VectorDistance(r_refdef.worldmodel->normalmins, r_refdef.worldmodel->normalmaxs);
r_refdef.nearclip = bound (0.001f, r_nearclip.value, r_refdef.farclip - 1.0f);
+ if (r_shadow_frontsidecasting.integer < 0 || r_shadow_frontsidecasting.integer > 1)
+ Cvar_SetValueQuick(&r_shadow_frontsidecasting, 1);
r_refdef.polygonfactor = 0;
r_refdef.polygonoffset = 0;
- r_refdef.shadowpolygonfactor = r_refdef.polygonfactor + r_shadow_shadow_polygonfactor.value;
- r_refdef.shadowpolygonoffset = r_refdef.polygonoffset + r_shadow_shadow_polygonoffset.value;
+ r_refdef.shadowpolygonfactor = r_refdef.polygonfactor + r_shadow_polygonfactor.value * (r_shadow_frontsidecasting.integer ? 1 : -1);
+ r_refdef.shadowpolygonoffset = r_refdef.polygonoffset + r_shadow_polygonoffset.value * (r_shadow_frontsidecasting.integer ? 1 : -1);
r_refdef.rtworld = r_shadow_realtime_world.integer;
r_refdef.rtworldshadows = r_shadow_realtime_world_shadows.integer && gl_stencil;
r_refdef.rtdlight = (r_shadow_realtime_world.integer || r_shadow_realtime_dlight.integer) && !gl_flashblend.integer && r_dynamic.integer;
- r_refdef.rtdlightshadows = r_refdef.rtdlight && (r_refdef.rtworld ? r_shadow_realtime_world_dlightshadows.integer : r_shadow_realtime_dlight_shadows.integer) && gl_stencil;
+ r_refdef.rtdlightshadows = r_refdef.rtdlight && r_shadow_realtime_dlight_shadows.integer && gl_stencil;
r_refdef.lightmapintensity = r_refdef.rtworld ? r_shadow_realtime_world_lightmaps.value : 1;
if (r_showsurfaces.integer)
{
// (0.9986 * 256 == 255.6)
r_refdef.fogrange = 400 / r_refdef.fog_density;
r_refdef.fograngerecip = 1.0f / r_refdef.fogrange;
- r_refdef.fogtabledistmultiplier = FOGTABLEWIDTH * r_refdef.fograngerecip;
+ r_refdef.fogmasktabledistmultiplier = FOGMASKTABLEWIDTH * r_refdef.fograngerecip;
// fog color was already set
}
else
R_Shadow_UpdateWorldLightSelection();
- CHECKGLERROR
- if (r_timereport_active)
- R_TimeReport("setup");
+ R_Bloom_StartFrame();
+ R_Water_StartFrame();
- R_View_Update();
+ CHECKGLERROR
if (r_timereport_active)
- R_TimeReport("visibility");
+ R_TimeReport("viewsetup");
R_ResetViewRendering3D();
- R_ClearScreen();
- if (r_timereport_active)
- R_TimeReport("clear");
+ if (r_view.clear)
+ {
+ R_ClearScreen();
+ if (r_timereport_active)
+ R_TimeReport("viewclear");
+ }
+ r_view.clear = true;
- R_Bloom_StartFrame();
+ r_view.showdebug = true;
// this produces a bloom texture to be used in R_BlendView() later
if (r_hdr.integer)
R_HDR_RenderBloomTexture();
r_view.colorscale = r_hdr_scenebrightness.value;
- R_RenderScene();
+ r_waterstate.numwaterplanes = 0;
+ R_RenderScene(r_waterstate.enabled);
R_BlendView();
if (r_timereport_active)
extern void R_DrawLightningBeams (void);
extern void VM_CL_AddPolygonsToMeshQueue (void);
extern void R_DrawPortals (void);
-void R_RenderScene(void)
+extern cvar_t cl_locs_show;
+static void R_DrawLocs(void);
+static void R_DrawEntityBBoxes(void);
+void R_RenderScene(qboolean addwaterplanes)
{
+ if (addwaterplanes)
+ {
+ R_ResetViewRendering3D();
+
+ R_View_Update();
+ if (r_timereport_active)
+ R_TimeReport("watervis");
+
+ if (cl.csqc_vidvars.drawworld && r_refdef.worldmodel && r_refdef.worldmodel->DrawAddWaterPlanes)
+ {
+ r_refdef.worldmodel->DrawAddWaterPlanes(r_refdef.worldentity);
+ if (r_timereport_active)
+ R_TimeReport("waterworld");
+ }
+
+ // don't let sound skip if going slow
+ if (r_refdef.extraupdate)
+ S_ExtraUpdate ();
+
+ R_DrawModelsAddWaterPlanes();
+ if (r_timereport_active)
+ R_TimeReport("watermodels");
+
+ R_Water_ProcessPlanes();
+ if (r_timereport_active)
+ R_TimeReport("waterscenes");
+ }
+
+ R_ResetViewRendering3D();
+
// don't let sound skip if going slow
if (r_refdef.extraupdate)
S_ExtraUpdate ();
- R_ResetViewRendering3D();
-
R_MeshQueue_BeginScene();
R_SkyStartFrame();
+ R_View_Update();
+ if (r_timereport_active)
+ R_TimeReport("visibility");
+
Matrix4x4_CreateTranslate(&r_waterscrollmatrix, sin(r_refdef.time) * 0.025 * r_waterscroll.value, sin(r_refdef.time * 0.8f) * 0.025 * r_waterscroll.value, 0);
if (cl.csqc_vidvars.drawworld)
if (R_DrawBrushModelsSky() && r_timereport_active)
R_TimeReport("bmodelsky");
+ }
- if (r_refdef.worldmodel && r_refdef.worldmodel->Draw)
- {
- r_refdef.worldmodel->Draw(r_refdef.worldentity);
- if (r_timereport_active)
- R_TimeReport("world");
- }
+ if (r_depthfirst.integer >= 1 && cl.csqc_vidvars.drawworld && r_refdef.worldmodel && r_refdef.worldmodel->DrawDepth)
+ {
+ r_refdef.worldmodel->DrawDepth(r_refdef.worldentity);
+ if (r_timereport_active)
+ R_TimeReport("worlddepth");
+ }
+ if (r_depthfirst.integer >= 2)
+ {
+ R_DrawModelsDepth();
+ if (r_timereport_active)
+ R_TimeReport("modeldepth");
+ }
+
+ if (cl.csqc_vidvars.drawworld && r_refdef.worldmodel && r_refdef.worldmodel->Draw)
+ {
+ r_refdef.worldmodel->Draw(r_refdef.worldentity);
+ if (r_timereport_active)
+ R_TimeReport("world");
}
// don't let sound skip if going slow
if (r_timereport_active)
R_TimeReport("lightning");
+ R_DrawDecals();
+ if (r_timereport_active)
+ R_TimeReport("decals");
+
R_DrawParticles();
if (r_timereport_active)
R_TimeReport("particles");
}
VM_CL_AddPolygonsToMeshQueue();
- if (r_drawportals.integer)
+ if (r_view.showdebug)
{
- R_DrawPortals();
- if (r_timereport_active)
- R_TimeReport("portals");
+ if (cl_locs_show.integer)
+ {
+ R_DrawLocs();
+ if (r_timereport_active)
+ R_TimeReport("showlocs");
+ }
+
+ if (r_drawportals.integer)
+ {
+ R_DrawPortals();
+ if (r_timereport_active)
+ R_TimeReport("portals");
+ }
+
+ if (r_showbboxes.value > 0)
+ {
+ R_DrawEntityBBoxes();
+ if (r_timereport_active)
+ R_TimeReport("bboxes");
+ }
}
if (gl_support_fragment_shader)
qglUseProgramObjectARB(0);CHECKGLERROR
}
+ if (r_view.showdebug && r_refdef.worldmodel && r_refdef.worldmodel->DrawDebug && (r_showtris.value > 0 || r_shownormals.value > 0 || r_showcollisionbrushes.value > 0))
+ {
+ r_refdef.worldmodel->DrawDebug(r_refdef.worldentity);
+ if (r_timereport_active)
+ R_TimeReport("worlddebug");
+ R_DrawModelsDebug();
+ if (r_timereport_active)
+ R_TimeReport("modeldebug");
+ }
+
+ if (gl_support_fragment_shader)
+ {
+ qglUseProgramObjectARB(0);CHECKGLERROR
+ }
+
if (cl.csqc_vidvars.drawworld)
{
R_DrawCoronas();
R_ResetViewRendering2D();
}
-/*
+static const int bboxelements[36] =
+{
+ 5, 1, 3, 5, 3, 7,
+ 6, 2, 0, 6, 0, 4,
+ 7, 3, 2, 7, 2, 6,
+ 4, 0, 1, 4, 1, 5,
+ 4, 5, 7, 4, 7, 6,
+ 1, 0, 2, 1, 2, 3,
+};
+
void R_DrawBBoxMesh(vec3_t mins, vec3_t maxs, float cr, float cg, float cb, float ca)
{
int i;
- float *v, *c, f1, f2, diff[3], vertex3f[8*3], color4f[8*4];
+ float *v, *c, f1, f2, vertex3f[8*3], color4f[8*4];
GL_BlendFunc(GL_SRC_ALPHA, GL_ONE_MINUS_SRC_ALPHA);
GL_DepthMask(false);
- GL_DepthTest(true);
+ GL_DepthRange(0, 1);
+ GL_PolygonOffset(r_refdef.polygonfactor, r_refdef.polygonoffset);
R_Mesh_Matrix(&identitymatrix);
+ R_Mesh_ResetTextureState();
- vertex3f[ 0] = mins[0];vertex3f[ 1] = mins[1];vertex3f[ 2] = mins[2];
+ vertex3f[ 0] = mins[0];vertex3f[ 1] = mins[1];vertex3f[ 2] = mins[2]; //
vertex3f[ 3] = maxs[0];vertex3f[ 4] = mins[1];vertex3f[ 5] = mins[2];
vertex3f[ 6] = mins[0];vertex3f[ 7] = maxs[1];vertex3f[ 8] = mins[2];
vertex3f[ 9] = maxs[0];vertex3f[10] = maxs[1];vertex3f[11] = mins[2];
vertex3f[15] = maxs[0];vertex3f[16] = mins[1];vertex3f[17] = maxs[2];
vertex3f[18] = mins[0];vertex3f[19] = maxs[1];vertex3f[20] = maxs[2];
vertex3f[21] = maxs[0];vertex3f[22] = maxs[1];vertex3f[23] = maxs[2];
- R_FillColors(color, 8, cr, cg, cb, ca);
+ R_FillColors(color4f, 8, cr, cg, cb, ca);
if (r_refdef.fogenabled)
{
- for (i = 0, v = vertex, c = color;i < 8;i++, v += 4, c += 4)
+ for (i = 0, v = vertex3f, c = color4f;i < 8;i++, v += 3, c += 4)
{
- f2 = VERTEXFOGTABLE(VectorDistance(v, r_view.origin));
- f1 = 1 - f2;
+ f1 = FogPoint_World(v);
+ f2 = 1 - f1;
c[0] = c[0] * f1 + r_refdef.fogcolor[0] * f2;
c[1] = c[1] * f1 + r_refdef.fogcolor[1] * f2;
c[2] = c[2] * f1 + r_refdef.fogcolor[2] * f2;
}
}
- R_Mesh_VertexPointer(vertex3f);
- R_Mesh_ColorPointer(color);
+ R_Mesh_VertexPointer(vertex3f, 0, 0);
+ R_Mesh_ColorPointer(color4f, 0, 0);
R_Mesh_ResetTextureState();
- R_Mesh_Draw(8, 12);
+ R_Mesh_Draw(0, 8, 12, bboxelements, 0, 0);
+}
+
+static void R_DrawEntityBBoxes_Callback(const entity_render_t *ent, const rtlight_t *rtlight, int numsurfaces, int *surfacelist)
+{
+ int i;
+ float color[4];
+ prvm_edict_t *edict;
+ // this function draws bounding boxes of server entities
+ if (!sv.active)
+ return;
+ SV_VM_Begin();
+ for (i = 0;i < numsurfaces;i++)
+ {
+ edict = PRVM_EDICT_NUM(surfacelist[i]);
+ switch ((int)edict->fields.server->solid)
+ {
+ case SOLID_NOT: Vector4Set(color, 1, 1, 1, 0.05);break;
+ case SOLID_TRIGGER: Vector4Set(color, 1, 0, 1, 0.10);break;
+ case SOLID_BBOX: Vector4Set(color, 0, 1, 0, 0.10);break;
+ case SOLID_SLIDEBOX: Vector4Set(color, 1, 0, 0, 0.10);break;
+ case SOLID_BSP: Vector4Set(color, 0, 0, 1, 0.05);break;
+ default: Vector4Set(color, 0, 0, 0, 0.50);break;
+ }
+ color[3] *= r_showbboxes.value;
+ color[3] = bound(0, color[3], 1);
+ GL_DepthTest(!r_showdisabledepthtest.integer);
+ GL_CullFace(r_view.cullface_front);
+ R_DrawBBoxMesh(edict->priv.server->areamins, edict->priv.server->areamaxs, color[0], color[1], color[2], color[3]);
+ }
+ SV_VM_End();
+}
+
+static void R_DrawEntityBBoxes(void)
+{
+ int i;
+ prvm_edict_t *edict;
+ vec3_t center;
+ // this function draws bounding boxes of server entities
+ if (!sv.active)
+ return;
+ SV_VM_Begin();
+ for (i = 0;i < prog->num_edicts;i++)
+ {
+ edict = PRVM_EDICT_NUM(i);
+ if (edict->priv.server->free)
+ continue;
+ VectorLerp(edict->priv.server->areamins, 0.5f, edict->priv.server->areamaxs, center);
+ R_MeshQueue_AddTransparent(center, R_DrawEntityBBoxes_Callback, (entity_render_t *)NULL, i, (rtlight_t *)NULL);
+ }
+ SV_VM_End();
}
-*/
int nomodelelements[24] =
{
GL_BlendFunc(GL_ONE, GL_ZERO);
GL_DepthMask(true);
}
+ GL_DepthRange(0, (ent->flags & RENDER_VIEWMODEL) ? 0.0625 : 1);
+ GL_PolygonOffset(r_refdef.polygonfactor, r_refdef.polygonoffset);
GL_DepthTest(!(ent->effects & EF_NODEPTHTEST));
- GL_CullFace((ent->flags & RENDER_NOCULLFACE) ? GL_NONE : GL_FRONT); // quake is backwards, this culls back faces
- R_Mesh_VertexPointer(nomodelvertex3f);
+ GL_CullFace((ent->effects & EF_DOUBLESIDED) ? GL_NONE : r_view.cullface_back);
+ R_Mesh_VertexPointer(nomodelvertex3f, 0, 0);
if (r_refdef.fogenabled)
{
vec3_t org;
memcpy(color4f, nomodelcolor4f, sizeof(float[6*4]));
- R_Mesh_ColorPointer(color4f);
+ R_Mesh_ColorPointer(color4f, 0, 0);
Matrix4x4_OriginFromMatrix(&ent->matrix, org);
- f2 = VERTEXFOGTABLE(VectorDistance(org, r_view.origin));
- f1 = 1 - f2;
+ f1 = FogPoint_World(org);
+ f2 = 1 - f1;
for (i = 0, c = color4f;i < 6;i++, c += 4)
{
c[0] = (c[0] * f1 + r_refdef.fogcolor[0] * f2);
else if (ent->alpha != 1)
{
memcpy(color4f, nomodelcolor4f, sizeof(float[6*4]));
- R_Mesh_ColorPointer(color4f);
+ R_Mesh_ColorPointer(color4f, 0, 0);
for (i = 0, c = color4f;i < 6;i++, c += 4)
c[3] *= ent->alpha;
}
else
- R_Mesh_ColorPointer(nomodelcolor4f);
+ R_Mesh_ColorPointer(nomodelcolor4f, 0, 0);
R_Mesh_ResetTextureState();
- R_Mesh_Draw(0, 6, 8, nomodelelements);
+ R_Mesh_Draw(0, 6, 8, nomodelelements, 0, 0);
}
void R_DrawNoModel(entity_render_t *ent)
vec3_t org;
Matrix4x4_OriginFromMatrix(&ent->matrix, org);
//if ((ent->effects & EF_ADDITIVE) || (ent->alpha < 1))
- R_MeshQueue_AddTransparent(ent->effects & EF_NODEPTHTEST ? r_view.origin : org, R_DrawNoModel_TransparentCallback, ent, 0, r_shadow_rtlight);
+ R_MeshQueue_AddTransparent(ent->effects & EF_NODEPTHTEST ? r_view.origin : org, R_DrawNoModel_TransparentCallback, ent, 0, rsurface.rtlight);
//else
// R_DrawNoModelCallback(ent, 0);
}
float spritetexcoord2f[4*2] = {0, 1, 0, 0, 1, 0, 1, 1};
-void R_DrawSprite(int blendfunc1, int blendfunc2, rtexture_t *texture, rtexture_t *fogtexture, int depthdisable, const vec3_t origin, const vec3_t left, const vec3_t up, float scalex1, float scalex2, float scaley1, float scaley2, float cr, float cg, float cb, float ca)
+void R_DrawSprite(int blendfunc1, int blendfunc2, rtexture_t *texture, rtexture_t *fogtexture, qboolean depthdisable, qboolean depthshort, const vec3_t origin, const vec3_t left, const vec3_t up, float scalex1, float scalex2, float scaley1, float scaley2, float cr, float cg, float cb, float ca)
{
- float fog = 0.0f, ifog;
+ float fog = 1.0f;
float vertex3f[12];
if (r_refdef.fogenabled)
- fog = VERTEXFOGTABLE(VectorDistance(origin, r_view.origin));
- ifog = 1 - fog;
+ fog = FogPoint_World(origin);
R_Mesh_Matrix(&identitymatrix);
GL_BlendFunc(blendfunc1, blendfunc2);
+
+ if(v_flipped_state)
+ {
+ scalex1 = -scalex1;
+ scalex2 = -scalex2;
+ GL_CullFace(r_view.cullface_front);
+ }
+ else
+ GL_CullFace(r_view.cullface_back);
+
GL_DepthMask(false);
+ GL_DepthRange(0, depthshort ? 0.0625 : 1);
+ GL_PolygonOffset(r_refdef.polygonfactor, r_refdef.polygonoffset);
GL_DepthTest(!depthdisable);
vertex3f[ 0] = origin[0] + left[0] * scalex2 + up[0] * scaley1;
vertex3f[10] = origin[1] + left[1] * scalex1 + up[1] * scaley1;
vertex3f[11] = origin[2] + left[2] * scalex1 + up[2] * scaley1;
- R_Mesh_VertexPointer(vertex3f);
- R_Mesh_ColorPointer(NULL);
+ R_Mesh_VertexPointer(vertex3f, 0, 0);
+ R_Mesh_ColorPointer(NULL, 0, 0);
R_Mesh_ResetTextureState();
R_Mesh_TexBind(0, R_GetTexture(texture));
- R_Mesh_TexCoordPointer(0, 2, spritetexcoord2f);
+ R_Mesh_TexCoordPointer(0, 2, spritetexcoord2f, 0, 0);
// FIXME: fixed function path can't properly handle r_view.colorscale > 1
- GL_Color(cr * ifog * r_view.colorscale, cg * ifog * r_view.colorscale, cb * ifog * r_view.colorscale, ca);
- R_Mesh_Draw(0, 4, 2, polygonelements);
+ GL_Color(cr * fog * r_view.colorscale, cg * fog * r_view.colorscale, cb * fog * r_view.colorscale, ca);
+ R_Mesh_Draw(0, 4, 2, polygonelements, 0, 0);
if (blendfunc2 == GL_ONE_MINUS_SRC_ALPHA)
{
R_Mesh_TexBind(0, R_GetTexture(fogtexture));
GL_BlendFunc(blendfunc1, GL_ONE);
+ fog = 1 - fog;
GL_Color(r_refdef.fogcolor[0] * fog * r_view.colorscale, r_refdef.fogcolor[1] * fog * r_view.colorscale, r_refdef.fogcolor[2] * fog * r_view.colorscale, ca);
- R_Mesh_Draw(0, 4, 2, polygonelements);
+ R_Mesh_Draw(0, 4, 2, polygonelements, 0, 0);
}
}
}
}
-static void R_DrawCollisionBrush(const colbrushf_t *brush)
-{
- int i;
- R_Mesh_VertexPointer(brush->points->v);
- i = (int)(((size_t)brush) / sizeof(colbrushf_t));
- GL_Color((i & 31) * (1.0f / 32.0f) * r_view.colorscale, ((i >> 5) & 31) * (1.0f / 32.0f) * r_view.colorscale, ((i >> 10) & 31) * (1.0f / 32.0f) * r_view.colorscale, 0.2f);
- GL_LockArrays(0, brush->numpoints);
- R_Mesh_Draw(0, brush->numpoints, brush->numtriangles, brush->elements);
- GL_LockArrays(0, 0);
-}
-
-static void R_DrawCollisionSurface(const entity_render_t *ent, const msurface_t *surface)
-{
- int i;
- if (!surface->num_collisiontriangles)
- return;
- R_Mesh_VertexPointer(surface->data_collisionvertex3f);
- i = (int)(((size_t)surface) / sizeof(msurface_t));
- GL_Color((i & 31) * (1.0f / 32.0f) * r_view.colorscale, ((i >> 5) & 31) * (1.0f / 32.0f) * r_view.colorscale, ((i >> 10) & 31) * (1.0f / 32.0f) * r_view.colorscale, 0.2f);
- GL_LockArrays(0, surface->num_collisionvertices);
- R_Mesh_Draw(0, surface->num_collisionvertices, surface->num_collisiontriangles, surface->data_collisionelement3i);
- GL_LockArrays(0, 0);
-}
-
static void R_Texture_AddLayer(texture_t *t, qboolean depthmask, int blendfunc1, int blendfunc2, texturelayertype_t type, rtexture_t *texture, const matrix4x4_t *matrix, float r, float g, float b, float a)
{
texturelayer_t *layer;
layer->color[3] = a;
}
+static float R_EvaluateQ3WaveFunc(q3wavefunc_t func, const float *parms)
+{
+ double index, f;
+ index = parms[2] + r_refdef.time * parms[3];
+ index -= floor(index);
+ switch (func)
+ {
+ default:
+ case Q3WAVEFUNC_NONE:
+ case Q3WAVEFUNC_NOISE:
+ case Q3WAVEFUNC_COUNT:
+ f = 0;
+ break;
+ case Q3WAVEFUNC_SIN: f = sin(index * M_PI * 2);break;
+ case Q3WAVEFUNC_SQUARE: f = index < 0.5 ? 1 : -1;break;
+ case Q3WAVEFUNC_SAWTOOTH: f = index;break;
+ case Q3WAVEFUNC_INVERSESAWTOOTH: f = 1 - index;break;
+ case Q3WAVEFUNC_TRIANGLE:
+ index *= 4;
+ f = index - floor(index);
+ if (index < 1)
+ f = f;
+ else if (index < 2)
+ f = 1 - f;
+ else if (index < 3)
+ f = -f;
+ else
+ f = -(1 - f);
+ break;
+ }
+ return (float)(parms[0] + parms[1] * f);
+}
+
void R_UpdateTextureInfo(const entity_render_t *ent, texture_t *t)
{
+ int i;
model_t *model = ent->model;
-
- // FIXME: identify models using a better check than ent->model->brush.shadowmesh
- //int lightmode = ((ent->effects & EF_FULLBRIGHT) || ent->model->brush.shadowmesh) ? 0 : 2;
+ float f;
+ float tcmat[12];
+ q3shaderinfo_layer_tcmod_t *tcmod;
// switch to an alternate material if this is a q1bsp animated material
{
{
// use an alternate animation if the entity's frame is not 0,
// and only if the texture has an alternate animation
- if (ent->frame != 0 && t->anim_total[1])
+ if (ent->frame2 != 0 && t->anim_total[1])
t = t->anim_frames[1][(t->anim_total[1] >= 2) ? ((int)(r_refdef.time * 5.0f) % t->anim_total[1]) : 0];
else
t = t->anim_frames[0][(t->anim_total[0] >= 2) ? ((int)(r_refdef.time * 5.0f) % t->anim_total[0]) : 0];
texture->currentframe = t;
}
- // pick a new currentskinframe if the material is animated
- if (t->numskinframes >= 2)
- t->currentskinframe = t->skinframes + ((int)(t->skinframerate * (cl.time - ent->frame2time)) % t->numskinframes);
+ // update currentskinframe to be a qw skin or animation frame
+ if ((i = ent->entitynumber - 1) >= 0 && i < cl.maxclients)
+ {
+ if (strcmp(r_qwskincache[i], cl.scores[i].qw_skin))
+ {
+ strlcpy(r_qwskincache[i], cl.scores[i].qw_skin, sizeof(r_qwskincache[i]));
+ Con_DPrintf("loading skins/%s\n", r_qwskincache[i]);
+ r_qwskincache_skinframe[i] = R_SkinFrame_LoadExternal(va("skins/%s", r_qwskincache[i]), TEXF_PRECACHE | (r_mipskins.integer ? TEXF_MIPMAP : 0) | TEXF_PICMIP | TEXF_COMPRESS, developer.integer > 0);
+ }
+ t->currentskinframe = r_qwskincache_skinframe[i];
+ if (t->currentskinframe == NULL)
+ t->currentskinframe = t->skinframes[(int)(t->skinframerate * (cl.time - ent->frame2time)) % t->numskinframes];
+ }
+ else if (t->numskinframes >= 2)
+ t->currentskinframe = t->skinframes[(int)(t->skinframerate * (cl.time - ent->frame2time)) % t->numskinframes];
if (t->backgroundnumskinframes >= 2)
- t->backgroundcurrentskinframe = t->backgroundskinframes + ((int)(t->backgroundskinframerate * (cl.time - ent->frame2time)) % t->backgroundnumskinframes);
+ t->backgroundcurrentskinframe = t->backgroundskinframes[(int)(t->backgroundskinframerate * (cl.time - ent->frame2time)) % t->backgroundnumskinframes];
t->currentmaterialflags = t->basematerialflags;
t->currentalpha = ent->alpha;
if (t->basematerialflags & MATERIALFLAG_WATERALPHA && (model->brush.supportwateralpha || r_novis.integer))
+ {
t->currentalpha *= r_wateralpha.value;
+ /*
+ * FIXME what is this supposed to do?
+ // if rendering refraction/reflection, disable transparency
+ if (r_waterstate.enabled && (t->currentalpha < 1 || (t->currentmaterialflags & MATERIALFLAG_ALPHA)))
+ t->currentmaterialflags |= MATERIALFLAG_WATERSHADER;
+ */
+ }
+ if(!r_waterstate.enabled)
+ t->currentmaterialflags &= ~(MATERIALFLAG_WATERSHADER | MATERIALFLAG_REFRACTION | MATERIALFLAG_REFLECTION);
if (!(ent->flags & RENDER_LIGHT))
t->currentmaterialflags |= MATERIALFLAG_FULLBRIGHT;
+ else if (rsurface.modeltexcoordlightmap2f == NULL)
+ {
+ // pick a model lighting mode
+ if (VectorLength2(ent->modellight_diffuse) >= (1.0f / 256.0f))
+ t->currentmaterialflags |= MATERIALFLAG_MODELLIGHT | MATERIALFLAG_MODELLIGHT_DIRECTIONAL;
+ else
+ t->currentmaterialflags |= MATERIALFLAG_MODELLIGHT;
+ }
if (ent->effects & EF_ADDITIVE)
- t->currentmaterialflags |= MATERIALFLAG_ADD | MATERIALFLAG_BLENDED | MATERIALFLAG_TRANSPARENT | MATERIALFLAG_NOSHADOW;
+ t->currentmaterialflags |= MATERIALFLAG_ADD | MATERIALFLAG_BLENDED | MATERIALFLAG_NOSHADOW;
else if (t->currentalpha < 1)
- t->currentmaterialflags |= MATERIALFLAG_ALPHA | MATERIALFLAG_BLENDED | MATERIALFLAG_TRANSPARENT | MATERIALFLAG_NOSHADOW;
- if (ent->flags & RENDER_NOCULLFACE)
- t->currentmaterialflags |= MATERIALFLAG_NOSHADOW;
+ t->currentmaterialflags |= MATERIALFLAG_ALPHA | MATERIALFLAG_BLENDED | MATERIALFLAG_NOSHADOW;
+ if (ent->effects & EF_DOUBLESIDED)
+ t->currentmaterialflags |= MATERIALFLAG_NOSHADOW | MATERIALFLAG_NOCULLFACE;
if (ent->effects & EF_NODEPTHTEST)
- t->currentmaterialflags |= MATERIALFLAG_NODEPTHTEST | MATERIALFLAG_NOSHADOW;
- if (t->currentmaterialflags & MATERIALFLAG_WATER && r_waterscroll.value != 0)
- t->currenttexmatrix = r_waterscrollmatrix;
- else
- t->currenttexmatrix = identitymatrix;
- if (t->backgroundnumskinframes && !(t->currentmaterialflags & MATERIALFLAG_TRANSPARENT))
+ t->currentmaterialflags |= MATERIALFLAG_SHORTDEPTHRANGE;
+ if (ent->flags & RENDER_VIEWMODEL)
+ t->currentmaterialflags |= MATERIALFLAG_SHORTDEPTHRANGE;
+ if (t->backgroundnumskinframes && !(t->currentmaterialflags & MATERIALFLAGMASK_DEPTHSORTED))
t->currentmaterialflags |= MATERIALFLAG_VERTEXTEXTUREBLEND;
+ for (i = 0, tcmod = t->tcmods;i < Q3MAXTCMODS && tcmod->tcmod;i++, tcmod++)
+ {
+ matrix4x4_t matrix;
+ switch(tcmod->tcmod)
+ {
+ case Q3TCMOD_COUNT:
+ case Q3TCMOD_NONE:
+ if (t->currentmaterialflags & MATERIALFLAG_WATER && r_waterscroll.value != 0)
+ matrix = r_waterscrollmatrix;
+ else
+ matrix = identitymatrix;
+ break;
+ case Q3TCMOD_ENTITYTRANSLATE:
+ // this is used in Q3 to allow the gamecode to control texcoord
+ // scrolling on the entity, which is not supported in darkplaces yet.
+ Matrix4x4_CreateTranslate(&matrix, 0, 0, 0);
+ break;
+ case Q3TCMOD_ROTATE:
+ Matrix4x4_CreateTranslate(&matrix, 0.5, 0.5, 0);
+ Matrix4x4_ConcatRotate(&matrix, tcmod->parms[0] * r_refdef.time, 0, 0, 1);
+ Matrix4x4_ConcatTranslate(&matrix, -0.5, -0.5, 0);
+ break;
+ case Q3TCMOD_SCALE:
+ Matrix4x4_CreateScale3(&matrix, tcmod->parms[0], tcmod->parms[1], 1);
+ break;
+ case Q3TCMOD_SCROLL:
+ Matrix4x4_CreateTranslate(&matrix, tcmod->parms[0] * r_refdef.time, tcmod->parms[1] * r_refdef.time, 0);
+ break;
+ case Q3TCMOD_STRETCH:
+ f = 1.0f / R_EvaluateQ3WaveFunc(tcmod->wavefunc, tcmod->waveparms);
+ Matrix4x4_CreateFromQuakeEntity(&matrix, 0.5f * (1 - f), 0.5 * (1 - f), 0, 0, 0, 0, f);
+ break;
+ case Q3TCMOD_TRANSFORM:
+ VectorSet(tcmat + 0, tcmod->parms[0], tcmod->parms[1], 0);
+ VectorSet(tcmat + 3, tcmod->parms[2], tcmod->parms[3], 0);
+ VectorSet(tcmat + 6, 0 , 0 , 1);
+ VectorSet(tcmat + 9, tcmod->parms[4], tcmod->parms[5], 0);
+ Matrix4x4_FromArray12FloatGL(&matrix, tcmat);
+ break;
+ case Q3TCMOD_TURBULENT:
+ // this is handled in the RSurf_PrepareVertices function
+ matrix = identitymatrix;
+ break;
+ }
+ // either replace or concatenate the transformation
+ if (i < 1)
+ t->currenttexmatrix = matrix;
+ else
+ {
+ matrix4x4_t temp = t->currenttexmatrix;
+ Matrix4x4_Concat(&t->currenttexmatrix, &matrix, &temp);
+ }
+ }
+
t->colormapping = VectorLength2(ent->colormap_pantscolor) + VectorLength2(ent->colormap_shirtcolor) >= (1.0f / 1048576.0f);
t->basetexture = (!t->colormapping && t->currentskinframe->merged) ? t->currentskinframe->merged : t->currentskinframe->base;
- t->glosstexture = r_texture_white;
+ t->glosstexture = r_texture_black;
t->backgroundbasetexture = t->backgroundnumskinframes ? ((!t->colormapping && t->backgroundcurrentskinframe->merged) ? t->backgroundcurrentskinframe->merged : t->backgroundcurrentskinframe->base) : r_texture_white;
- t->backgroundglosstexture = r_texture_white;
+ t->backgroundglosstexture = r_texture_black;
t->specularpower = r_shadow_glossexponent.value;
+ // TODO: store reference values for these in the texture?
t->specularscale = 0;
if (r_shadow_gloss.integer > 0)
{
{
if (r_shadow_glossintensity.value > 0)
{
- t->glosstexture = t->currentskinframe->gloss ? t->currentskinframe->gloss : r_texture_black;
- t->backgroundglosstexture = (t->backgroundcurrentskinframe && t->backgroundcurrentskinframe->gloss) ? t->backgroundcurrentskinframe->gloss : r_texture_black;
+ t->glosstexture = t->currentskinframe->gloss ? t->currentskinframe->gloss : r_texture_white;
+ t->backgroundglosstexture = (t->backgroundcurrentskinframe && t->backgroundcurrentskinframe->gloss) ? t->backgroundcurrentskinframe->gloss : r_texture_white;
t->specularscale = r_shadow_glossintensity.value;
}
}
else if (r_shadow_gloss.integer >= 2 && r_shadow_gloss2intensity.value > 0)
+ {
+ t->glosstexture = r_texture_white;
+ t->backgroundglosstexture = r_texture_white;
t->specularscale = r_shadow_gloss2intensity.value;
+ }
+ }
+
+ // lightmaps mode looks bad with dlights using actual texturing, so turn
+ // off the colormap and glossmap, but leave the normalmap on as it still
+ // accurately represents the shading involved
+ if (gl_lightmaps.integer && !(t->currentmaterialflags & MATERIALFLAG_BLENDED))
+ {
+ t->basetexture = r_texture_white;
+ t->specularscale = 0;
}
+ t->currentpolygonfactor = r_refdef.polygonfactor + t->basepolygonfactor;
+ t->currentpolygonoffset = r_refdef.polygonoffset + t->basepolygonoffset;
+ // submodels are biased to avoid z-fighting with world surfaces that they
+ // may be exactly overlapping (avoids z-fighting artifacts on certain
+ // doors and things in Quake maps)
+ if (ent->model->brush.submodel)
+ {
+ t->currentpolygonfactor += r_polygonoffset_submodel_factor.value;
+ t->currentpolygonoffset += r_polygonoffset_submodel_offset.value;
+ }
+
+ VectorClear(t->dlightcolor);
t->currentnumlayers = 0;
if (!(t->currentmaterialflags & MATERIALFLAG_NODRAW))
{
- if (gl_lightmaps.integer)
- R_Texture_AddLayer(t, true, GL_ONE, GL_ZERO, TEXTURELAYERTYPE_LITTEXTURE, r_texture_white, &identitymatrix, 1, 1, 1, 1);
- else if (!(t->currentmaterialflags & MATERIALFLAG_SKY))
+ if (!(t->currentmaterialflags & MATERIALFLAG_SKY))
{
int blendfunc1, blendfunc2, depthmask;
if (t->currentmaterialflags & MATERIALFLAG_ADD)
else
{
float colorscale;
+ // set the color tint used for lights affecting this surface
+ VectorSet(t->dlightcolor, ent->colormod[0] * t->currentalpha, ent->colormod[1] * t->currentalpha, ent->colormod[2] * t->currentalpha);
colorscale = 2;
// q3bsp has no lightmap updates, so the lightstylevalue that
// would normally be baked into the lightmap must be
// applied to the color
+ // FIXME: r_glsl 1 rendering doesn't support overbright lightstyles with this (the default light style is not overbright)
if (ent->model->type == mod_brushq3)
colorscale *= r_refdef.lightstylevalue[0] * (1.0f / 256.0f);
colorscale *= r_refdef.lightmapintensity;
{
int i;
if (ent->model)
- for (i = 0;i < ent->model->num_textures;i++)
+ for (i = 0;i < ent->model->num_texturesperskin;i++)
R_UpdateTextureInfo(ent, ent->model->data_textures + i);
}
-int rsurface_array_size = 0;
-float *rsurface_array_modelvertex3f = NULL;
-float *rsurface_array_modelsvector3f = NULL;
-float *rsurface_array_modeltvector3f = NULL;
-float *rsurface_array_modelnormal3f = NULL;
-float *rsurface_array_deformedvertex3f = NULL;
-float *rsurface_array_deformedsvector3f = NULL;
-float *rsurface_array_deformedtvector3f = NULL;
-float *rsurface_array_deformednormal3f = NULL;
-float *rsurface_array_color4f = NULL;
-float *rsurface_array_texcoord3f = NULL;
+rsurfacestate_t rsurface;
void R_Mesh_ResizeArrays(int newvertices)
{
float *base;
- if (rsurface_array_size >= newvertices)
+ if (rsurface.array_size >= newvertices)
return;
- if (rsurface_array_modelvertex3f)
- Mem_Free(rsurface_array_modelvertex3f);
- rsurface_array_size = (newvertices + 1023) & ~1023;
- base = (float *)Mem_Alloc(r_main_mempool, rsurface_array_size * sizeof(float[31]));
- rsurface_array_modelvertex3f = base + rsurface_array_size * 0;
- rsurface_array_modelsvector3f = base + rsurface_array_size * 3;
- rsurface_array_modeltvector3f = base + rsurface_array_size * 6;
- rsurface_array_modelnormal3f = base + rsurface_array_size * 9;
- rsurface_array_deformedvertex3f = base + rsurface_array_size * 12;
- rsurface_array_deformedsvector3f = base + rsurface_array_size * 15;
- rsurface_array_deformedtvector3f = base + rsurface_array_size * 18;
- rsurface_array_deformednormal3f = base + rsurface_array_size * 21;
- rsurface_array_texcoord3f = base + rsurface_array_size * 24;
- rsurface_array_color4f = base + rsurface_array_size * 27;
-}
-
-float *rsurface_modelvertex3f;
-float *rsurface_modelsvector3f;
-float *rsurface_modeltvector3f;
-float *rsurface_modelnormal3f;
-float *rsurface_vertex3f;
-float *rsurface_svector3f;
-float *rsurface_tvector3f;
-float *rsurface_normal3f;
-float *rsurface_lightmapcolor4f;
-vec3_t rsurface_modelorg;
-qboolean rsurface_generatedvertex;
-const entity_render_t *rsurface_entity;
-const model_t *rsurface_model;
-texture_t *rsurface_texture;
-rtexture_t *rsurface_lightmaptexture;
-rsurfmode_t rsurface_mode;
-texture_t *rsurface_glsl_texture;
-qboolean rsurface_glsl_uselightmap;
+ if (rsurface.array_modelvertex3f)
+ Mem_Free(rsurface.array_modelvertex3f);
+ rsurface.array_size = (newvertices + 1023) & ~1023;
+ base = (float *)Mem_Alloc(r_main_mempool, rsurface.array_size * sizeof(float[33]));
+ rsurface.array_modelvertex3f = base + rsurface.array_size * 0;
+ rsurface.array_modelsvector3f = base + rsurface.array_size * 3;
+ rsurface.array_modeltvector3f = base + rsurface.array_size * 6;
+ rsurface.array_modelnormal3f = base + rsurface.array_size * 9;
+ rsurface.array_deformedvertex3f = base + rsurface.array_size * 12;
+ rsurface.array_deformedsvector3f = base + rsurface.array_size * 15;
+ rsurface.array_deformedtvector3f = base + rsurface.array_size * 18;
+ rsurface.array_deformednormal3f = base + rsurface.array_size * 21;
+ rsurface.array_texcoord3f = base + rsurface.array_size * 24;
+ rsurface.array_color4f = base + rsurface.array_size * 27;
+ rsurface.array_generatedtexcoordtexture2f = base + rsurface.array_size * 31;
+}
void RSurf_CleanUp(void)
{
CHECKGLERROR
- if (rsurface_mode == RSURFMODE_GLSL)
+ if (rsurface.mode == RSURFMODE_GLSL)
{
qglUseProgramObjectARB(0);CHECKGLERROR
}
GL_AlphaTest(false);
- rsurface_mode = RSURFMODE_NONE;
- rsurface_lightmaptexture = NULL;
- rsurface_texture = NULL;
- rsurface_glsl_texture = NULL;
- rsurface_glsl_uselightmap = false;
+ rsurface.mode = RSURFMODE_NONE;
+ rsurface.uselightmaptexture = false;
+ rsurface.texture = NULL;
}
-void RSurf_ActiveEntity(const entity_render_t *ent, qboolean wantnormals, qboolean wanttangents)
+void RSurf_ActiveWorldEntity(void)
{
+ model_t *model = r_refdef.worldmodel;
RSurf_CleanUp();
- Matrix4x4_Transform(&ent->inversematrix, r_view.origin, rsurface_modelorg);
- rsurface_entity = ent;
- rsurface_model = ent->model;
- if (rsurface_array_size < rsurface_model->surfmesh.num_vertices)
- R_Mesh_ResizeArrays(rsurface_model->surfmesh.num_vertices);
- R_Mesh_Matrix(&ent->matrix);
- Matrix4x4_Transform(&ent->inversematrix, r_view.origin, rsurface_modelorg);
- if ((rsurface_entity->frameblend[0].lerp != 1 || rsurface_entity->frameblend[0].frame != 0) && rsurface_model->surfmesh.isanimated)
+ if (rsurface.array_size < model->surfmesh.num_vertices)
+ R_Mesh_ResizeArrays(model->surfmesh.num_vertices);
+ rsurface.matrix = identitymatrix;
+ rsurface.inversematrix = identitymatrix;
+ R_Mesh_Matrix(&identitymatrix);
+ VectorCopy(r_view.origin, rsurface.modelorg);
+ VectorSet(rsurface.modellight_ambient, 0, 0, 0);
+ VectorSet(rsurface.modellight_diffuse, 0, 0, 0);
+ VectorSet(rsurface.modellight_lightdir, 0, 0, 1);
+ VectorSet(rsurface.colormap_pantscolor, 0, 0, 0);
+ VectorSet(rsurface.colormap_shirtcolor, 0, 0, 0);
+ rsurface.frameblend[0].frame = 0;
+ rsurface.frameblend[0].lerp = 1;
+ rsurface.frameblend[1].frame = 0;
+ rsurface.frameblend[1].lerp = 0;
+ rsurface.frameblend[2].frame = 0;
+ rsurface.frameblend[2].lerp = 0;
+ rsurface.frameblend[3].frame = 0;
+ rsurface.frameblend[3].lerp = 0;
+ rsurface.modelvertex3f = model->surfmesh.data_vertex3f;
+ rsurface.modelvertex3f_bufferobject = model->surfmesh.vbo;
+ rsurface.modelvertex3f_bufferoffset = model->surfmesh.vbooffset_vertex3f;
+ rsurface.modelsvector3f = model->surfmesh.data_svector3f;
+ rsurface.modelsvector3f_bufferobject = model->surfmesh.vbo;
+ rsurface.modelsvector3f_bufferoffset = model->surfmesh.vbooffset_svector3f;
+ rsurface.modeltvector3f = model->surfmesh.data_tvector3f;
+ rsurface.modeltvector3f_bufferobject = model->surfmesh.vbo;
+ rsurface.modeltvector3f_bufferoffset = model->surfmesh.vbooffset_tvector3f;
+ rsurface.modelnormal3f = model->surfmesh.data_normal3f;
+ rsurface.modelnormal3f_bufferobject = model->surfmesh.vbo;
+ rsurface.modelnormal3f_bufferoffset = model->surfmesh.vbooffset_normal3f;
+ rsurface.modellightmapcolor4f = model->surfmesh.data_lightmapcolor4f;
+ rsurface.modellightmapcolor4f_bufferobject = model->surfmesh.vbo;
+ rsurface.modellightmapcolor4f_bufferoffset = model->surfmesh.vbooffset_lightmapcolor4f;
+ rsurface.modeltexcoordtexture2f = model->surfmesh.data_texcoordtexture2f;
+ rsurface.modeltexcoordtexture2f_bufferobject = model->surfmesh.vbo;
+ rsurface.modeltexcoordtexture2f_bufferoffset = model->surfmesh.vbooffset_texcoordtexture2f;
+ rsurface.modeltexcoordlightmap2f = model->surfmesh.data_texcoordlightmap2f;
+ rsurface.modeltexcoordlightmap2f_bufferobject = model->surfmesh.vbo;
+ rsurface.modeltexcoordlightmap2f_bufferoffset = model->surfmesh.vbooffset_texcoordlightmap2f;
+ rsurface.modelelement3i = model->surfmesh.data_element3i;
+ rsurface.modelelement3i_bufferobject = model->surfmesh.ebo;
+ rsurface.modellightmapoffsets = model->surfmesh.data_lightmapoffsets;
+ rsurface.modelnum_vertices = model->surfmesh.num_vertices;
+ rsurface.modelnum_triangles = model->surfmesh.num_triangles;
+ rsurface.modelsurfaces = model->data_surfaces;
+ rsurface.generatedvertex = false;
+ rsurface.vertex3f = rsurface.modelvertex3f;
+ rsurface.vertex3f_bufferobject = rsurface.modelvertex3f_bufferobject;
+ rsurface.vertex3f_bufferoffset = rsurface.modelvertex3f_bufferoffset;
+ rsurface.svector3f = rsurface.modelsvector3f;
+ rsurface.svector3f_bufferobject = rsurface.modelsvector3f_bufferobject;
+ rsurface.svector3f_bufferoffset = rsurface.modelsvector3f_bufferoffset;
+ rsurface.tvector3f = rsurface.modeltvector3f;
+ rsurface.tvector3f_bufferobject = rsurface.modeltvector3f_bufferobject;
+ rsurface.tvector3f_bufferoffset = rsurface.modeltvector3f_bufferoffset;
+ rsurface.normal3f = rsurface.modelnormal3f;
+ rsurface.normal3f_bufferobject = rsurface.modelnormal3f_bufferobject;
+ rsurface.normal3f_bufferoffset = rsurface.modelnormal3f_bufferoffset;
+ rsurface.texcoordtexture2f = rsurface.modeltexcoordtexture2f;
+}
+
+void RSurf_ActiveModelEntity(const entity_render_t *ent, qboolean wantnormals, qboolean wanttangents)
+{
+ model_t *model = ent->model;
+ RSurf_CleanUp();
+ if (rsurface.array_size < model->surfmesh.num_vertices)
+ R_Mesh_ResizeArrays(model->surfmesh.num_vertices);
+ rsurface.matrix = ent->matrix;
+ rsurface.inversematrix = ent->inversematrix;
+ R_Mesh_Matrix(&rsurface.matrix);
+ Matrix4x4_Transform(&rsurface.inversematrix, r_view.origin, rsurface.modelorg);
+ VectorCopy(ent->modellight_ambient, rsurface.modellight_ambient);
+ VectorCopy(ent->modellight_diffuse, rsurface.modellight_diffuse);
+ VectorCopy(ent->modellight_lightdir, rsurface.modellight_lightdir);
+ VectorCopy(ent->colormap_pantscolor, rsurface.colormap_pantscolor);
+ VectorCopy(ent->colormap_shirtcolor, rsurface.colormap_shirtcolor);
+ rsurface.frameblend[0] = ent->frameblend[0];
+ rsurface.frameblend[1] = ent->frameblend[1];
+ rsurface.frameblend[2] = ent->frameblend[2];
+ rsurface.frameblend[3] = ent->frameblend[3];
+ if (model->surfmesh.isanimated && (rsurface.frameblend[0].lerp != 1 || rsurface.frameblend[0].frame != 0))
{
if (wanttangents)
{
- rsurface_modelvertex3f = rsurface_array_modelvertex3f;
- rsurface_modelsvector3f = rsurface_array_modelsvector3f;
- rsurface_modeltvector3f = rsurface_array_modeltvector3f;
- rsurface_modelnormal3f = rsurface_array_modelnormal3f;
- Mod_Alias_GetMesh_Vertices(rsurface_model, rsurface_entity->frameblend, rsurface_array_modelvertex3f, rsurface_array_modelnormal3f, rsurface_array_modelsvector3f, rsurface_array_modeltvector3f);
+ rsurface.modelvertex3f = rsurface.array_modelvertex3f;
+ rsurface.modelsvector3f = rsurface.array_modelsvector3f;
+ rsurface.modeltvector3f = rsurface.array_modeltvector3f;
+ rsurface.modelnormal3f = rsurface.array_modelnormal3f;
+ Mod_Alias_GetMesh_Vertices(model, rsurface.frameblend, rsurface.array_modelvertex3f, rsurface.array_modelnormal3f, rsurface.array_modelsvector3f, rsurface.array_modeltvector3f);
}
else if (wantnormals)
{
- rsurface_modelvertex3f = rsurface_array_modelvertex3f;
- rsurface_modelsvector3f = NULL;
- rsurface_modeltvector3f = NULL;
- rsurface_modelnormal3f = rsurface_array_modelnormal3f;
- Mod_Alias_GetMesh_Vertices(rsurface_model, rsurface_entity->frameblend, rsurface_array_modelvertex3f, rsurface_array_modelnormal3f, NULL, NULL);
+ rsurface.modelvertex3f = rsurface.array_modelvertex3f;
+ rsurface.modelsvector3f = NULL;
+ rsurface.modeltvector3f = NULL;
+ rsurface.modelnormal3f = rsurface.array_modelnormal3f;
+ Mod_Alias_GetMesh_Vertices(model, rsurface.frameblend, rsurface.array_modelvertex3f, rsurface.array_modelnormal3f, NULL, NULL);
}
else
{
- rsurface_modelvertex3f = rsurface_array_modelvertex3f;
- rsurface_modelsvector3f = NULL;
- rsurface_modeltvector3f = NULL;
- rsurface_modelnormal3f = NULL;
- Mod_Alias_GetMesh_Vertices(rsurface_model, rsurface_entity->frameblend, rsurface_array_modelvertex3f, NULL, NULL, NULL);
+ rsurface.modelvertex3f = rsurface.array_modelvertex3f;
+ rsurface.modelsvector3f = NULL;
+ rsurface.modeltvector3f = NULL;
+ rsurface.modelnormal3f = NULL;
+ Mod_Alias_GetMesh_Vertices(model, rsurface.frameblend, rsurface.array_modelvertex3f, NULL, NULL, NULL);
}
- rsurface_generatedvertex = true;
+ rsurface.modelvertex3f_bufferobject = 0;
+ rsurface.modelvertex3f_bufferoffset = 0;
+ rsurface.modelsvector3f_bufferobject = 0;
+ rsurface.modelsvector3f_bufferoffset = 0;
+ rsurface.modeltvector3f_bufferobject = 0;
+ rsurface.modeltvector3f_bufferoffset = 0;
+ rsurface.modelnormal3f_bufferobject = 0;
+ rsurface.modelnormal3f_bufferoffset = 0;
+ rsurface.generatedvertex = true;
}
else
{
- rsurface_modelvertex3f = rsurface_model->surfmesh.data_vertex3f;
- rsurface_modelsvector3f = rsurface_model->surfmesh.data_svector3f;
- rsurface_modeltvector3f = rsurface_model->surfmesh.data_tvector3f;
- rsurface_modelnormal3f = rsurface_model->surfmesh.data_normal3f;
- rsurface_generatedvertex = false;
+ rsurface.modelvertex3f = model->surfmesh.data_vertex3f;
+ rsurface.modelvertex3f_bufferobject = model->surfmesh.vbo;
+ rsurface.modelvertex3f_bufferoffset = model->surfmesh.vbooffset_vertex3f;
+ rsurface.modelsvector3f = model->surfmesh.data_svector3f;
+ rsurface.modelsvector3f_bufferobject = model->surfmesh.vbo;
+ rsurface.modelsvector3f_bufferoffset = model->surfmesh.vbooffset_svector3f;
+ rsurface.modeltvector3f = model->surfmesh.data_tvector3f;
+ rsurface.modeltvector3f_bufferobject = model->surfmesh.vbo;
+ rsurface.modeltvector3f_bufferoffset = model->surfmesh.vbooffset_tvector3f;
+ rsurface.modelnormal3f = model->surfmesh.data_normal3f;
+ rsurface.modelnormal3f_bufferobject = model->surfmesh.vbo;
+ rsurface.modelnormal3f_bufferoffset = model->surfmesh.vbooffset_normal3f;
+ rsurface.generatedvertex = false;
}
- rsurface_vertex3f = rsurface_modelvertex3f;
- rsurface_svector3f = rsurface_modelsvector3f;
- rsurface_tvector3f = rsurface_modeltvector3f;
- rsurface_normal3f = rsurface_modelnormal3f;
+ rsurface.modellightmapcolor4f = model->surfmesh.data_lightmapcolor4f;
+ rsurface.modellightmapcolor4f_bufferobject = model->surfmesh.vbo;
+ rsurface.modellightmapcolor4f_bufferoffset = model->surfmesh.vbooffset_lightmapcolor4f;
+ rsurface.modeltexcoordtexture2f = model->surfmesh.data_texcoordtexture2f;
+ rsurface.modeltexcoordtexture2f_bufferobject = model->surfmesh.vbo;
+ rsurface.modeltexcoordtexture2f_bufferoffset = model->surfmesh.vbooffset_texcoordtexture2f;
+ rsurface.modeltexcoordlightmap2f = model->surfmesh.data_texcoordlightmap2f;
+ rsurface.modeltexcoordlightmap2f_bufferobject = model->surfmesh.vbo;
+ rsurface.modeltexcoordlightmap2f_bufferoffset = model->surfmesh.vbooffset_texcoordlightmap2f;
+ rsurface.modelelement3i = model->surfmesh.data_element3i;
+ rsurface.modelelement3i_bufferobject = model->surfmesh.ebo;
+ rsurface.modellightmapoffsets = model->surfmesh.data_lightmapoffsets;
+ rsurface.modelnum_vertices = model->surfmesh.num_vertices;
+ rsurface.modelnum_triangles = model->surfmesh.num_triangles;
+ rsurface.modelsurfaces = model->data_surfaces;
+ rsurface.vertex3f = rsurface.modelvertex3f;
+ rsurface.vertex3f_bufferobject = rsurface.modelvertex3f_bufferobject;
+ rsurface.vertex3f_bufferoffset = rsurface.modelvertex3f_bufferoffset;
+ rsurface.svector3f = rsurface.modelsvector3f;
+ rsurface.svector3f_bufferobject = rsurface.modelsvector3f_bufferobject;
+ rsurface.svector3f_bufferoffset = rsurface.modelsvector3f_bufferoffset;
+ rsurface.tvector3f = rsurface.modeltvector3f;
+ rsurface.tvector3f_bufferobject = rsurface.modeltvector3f_bufferobject;
+ rsurface.tvector3f_bufferoffset = rsurface.modeltvector3f_bufferoffset;
+ rsurface.normal3f = rsurface.modelnormal3f;
+ rsurface.normal3f_bufferobject = rsurface.modelnormal3f_bufferobject;
+ rsurface.normal3f_bufferoffset = rsurface.modelnormal3f_bufferoffset;
+ rsurface.texcoordtexture2f = rsurface.modeltexcoordtexture2f;
}
+static const int quadedges[6][2] = {{0, 1}, {0, 2}, {0, 3}, {1, 2}, {1, 3}, {2, 3}};
void RSurf_PrepareVerticesForBatch(qboolean generatenormals, qboolean generatetangents, int texturenumsurfaces, msurface_t **texturesurfacelist)
{
- // if vertices are dynamic (animated models), generate them into the temporary rsurface_array_model* arrays and point rsurface_model* at them instead of the static data from the model itself
- if (rsurface_generatedvertex)
+ int deformindex;
+ int texturesurfaceindex;
+ int i, j;
+ float amplitude;
+ float animpos;
+ float scale;
+ const float *v1, *in_tc;
+ float *out_tc;
+ float center[3], forward[3], right[3], up[3], v[3], newforward[3], newright[3], newup[3];
+ float waveparms[4];
+ q3shaderinfo_deform_t *deform;
+ // if vertices are dynamic (animated models), generate them into the temporary rsurface.array_model* arrays and point rsurface.model* at them instead of the static data from the model itself
+ if (rsurface.generatedvertex)
{
- if (rsurface_texture->textureflags & (Q3TEXTUREFLAG_AUTOSPRITE | Q3TEXTUREFLAG_AUTOSPRITE2))
- generatetangents = true;
- if (generatetangents)
+ if (rsurface.texture->tcgen.tcgen == Q3TCGEN_ENVIRONMENT)
generatenormals = true;
- if (generatenormals && !rsurface_modelnormal3f)
+ for (i = 0;i < Q3MAXDEFORMS;i++)
{
- rsurface_normal3f = rsurface_modelnormal3f = rsurface_array_modelnormal3f;
- Mod_BuildNormals(0, rsurface_model->surfmesh.num_vertices, rsurface_model->surfmesh.num_triangles, rsurface_modelvertex3f, rsurface_model->surfmesh.data_element3i, rsurface_array_modelnormal3f, r_smoothnormals_areaweighting.integer);
+ if (rsurface.texture->deforms[i].deform == Q3DEFORM_AUTOSPRITE)
+ {
+ generatetangents = true;
+ generatenormals = true;
+ }
+ if (rsurface.texture->deforms[i].deform != Q3DEFORM_NONE)
+ generatenormals = true;
+ }
+ if (generatenormals && !rsurface.modelnormal3f)
+ {
+ rsurface.normal3f = rsurface.modelnormal3f = rsurface.array_modelnormal3f;
+ rsurface.normal3f_bufferobject = rsurface.modelnormal3f_bufferobject = 0;
+ rsurface.normal3f_bufferoffset = rsurface.modelnormal3f_bufferoffset = 0;
+ Mod_BuildNormals(0, rsurface.modelnum_vertices, rsurface.modelnum_triangles, rsurface.modelvertex3f, rsurface.modelelement3i, rsurface.array_modelnormal3f, r_smoothnormals_areaweighting.integer);
}
- if (generatetangents && !rsurface_modelsvector3f)
+ if (generatetangents && !rsurface.modelsvector3f)
{
- rsurface_svector3f = rsurface_modelsvector3f = rsurface_array_modelsvector3f;
- rsurface_tvector3f = rsurface_modeltvector3f = rsurface_array_modeltvector3f;
- Mod_BuildTextureVectorsFromNormals(0, rsurface_model->surfmesh.num_vertices, rsurface_model->surfmesh.num_triangles, rsurface_modelvertex3f, rsurface_model->surfmesh.data_texcoordtexture2f, rsurface_modelnormal3f, rsurface_model->surfmesh.data_element3i, rsurface_array_modelsvector3f, rsurface_array_modeltvector3f, r_smoothnormals_areaweighting.integer);
+ rsurface.svector3f = rsurface.modelsvector3f = rsurface.array_modelsvector3f;
+ rsurface.svector3f_bufferobject = rsurface.modelsvector3f_bufferobject = 0;
+ rsurface.svector3f_bufferoffset = rsurface.modelsvector3f_bufferoffset = 0;
+ rsurface.tvector3f = rsurface.modeltvector3f = rsurface.array_modeltvector3f;
+ rsurface.tvector3f_bufferobject = rsurface.modeltvector3f_bufferobject = 0;
+ rsurface.tvector3f_bufferoffset = rsurface.modeltvector3f_bufferoffset = 0;
+ Mod_BuildTextureVectorsFromNormals(0, rsurface.modelnum_vertices, rsurface.modelnum_triangles, rsurface.modelvertex3f, rsurface.modeltexcoordtexture2f, rsurface.modelnormal3f, rsurface.modelelement3i, rsurface.array_modelsvector3f, rsurface.array_modeltvector3f, r_smoothnormals_areaweighting.integer);
}
}
- // if vertices are deformed (sprite flares and things in maps, possibly water waves, bulges and other deformations), generate them into rsurface_deform* arrays from whatever the rsurface_model* array pointers point to (may be static model data or generated data for an animated model)
- if (rsurface_texture->textureflags & (Q3TEXTUREFLAG_AUTOSPRITE | Q3TEXTUREFLAG_AUTOSPRITE2))
+ rsurface.vertex3f = rsurface.modelvertex3f;
+ rsurface.vertex3f_bufferobject = rsurface.modelvertex3f_bufferobject;
+ rsurface.vertex3f_bufferoffset = rsurface.modelvertex3f_bufferoffset;
+ rsurface.svector3f = rsurface.modelsvector3f;
+ rsurface.svector3f_bufferobject = rsurface.modelsvector3f_bufferobject;
+ rsurface.svector3f_bufferoffset = rsurface.modelsvector3f_bufferoffset;
+ rsurface.tvector3f = rsurface.modeltvector3f;
+ rsurface.tvector3f_bufferobject = rsurface.modeltvector3f_bufferobject;
+ rsurface.tvector3f_bufferoffset = rsurface.modeltvector3f_bufferoffset;
+ rsurface.normal3f = rsurface.modelnormal3f;
+ rsurface.normal3f_bufferobject = rsurface.modelnormal3f_bufferobject;
+ rsurface.normal3f_bufferoffset = rsurface.modelnormal3f_bufferoffset;
+ // if vertices are deformed (sprite flares and things in maps, possibly
+ // water waves, bulges and other deformations), generate them into
+ // rsurface.deform* arrays from whatever the rsurface.* arrays point to
+ // (may be static model data or generated data for an animated model, or
+ // the previous deform pass)
+ for (deformindex = 0, deform = rsurface.texture->deforms;deformindex < Q3MAXDEFORMS && deform->deform;deformindex++, deform++)
{
- int texturesurfaceindex;
- float center[3], forward[3], right[3], up[3], v[4][3];
- matrix4x4_t matrix1, imatrix1;
- Matrix4x4_Transform(&rsurface_entity->inversematrix, r_view.forward, forward);
- Matrix4x4_Transform(&rsurface_entity->inversematrix, r_view.right, right);
- Matrix4x4_Transform(&rsurface_entity->inversematrix, r_view.up, up);
- // make deformed versions of only the model vertices used by the specified surfaces
- for (texturesurfaceindex = 0;texturesurfaceindex < texturenumsurfaces;texturesurfaceindex++)
+ switch (deform->deform)
{
- int i, j;
- const msurface_t *surface = texturesurfacelist[texturesurfaceindex];
- // a single autosprite surface can contain multiple sprites...
- for (j = 0;j < surface->num_vertices - 3;j += 4)
- {
- VectorClear(center);
- for (i = 0;i < 4;i++)
- VectorAdd(center, (rsurface_modelvertex3f + 3 * surface->num_firstvertex) + (j+i) * 3, center);
- VectorScale(center, 0.25f, center);
- if (rsurface_texture->textureflags & Q3TEXTUREFLAG_AUTOSPRITE2)
- {
- forward[0] = rsurface_modelorg[0] - center[0];
- forward[1] = rsurface_modelorg[1] - center[1];
- forward[2] = 0;
+ default:
+ case Q3DEFORM_PROJECTIONSHADOW:
+ case Q3DEFORM_TEXT0:
+ case Q3DEFORM_TEXT1:
+ case Q3DEFORM_TEXT2:
+ case Q3DEFORM_TEXT3:
+ case Q3DEFORM_TEXT4:
+ case Q3DEFORM_TEXT5:
+ case Q3DEFORM_TEXT6:
+ case Q3DEFORM_TEXT7:
+ case Q3DEFORM_NONE:
+ break;
+ case Q3DEFORM_AUTOSPRITE:
+ Matrix4x4_Transform3x3(&rsurface.inversematrix, r_view.forward, newforward);
+ Matrix4x4_Transform3x3(&rsurface.inversematrix, r_view.right, newright);
+ Matrix4x4_Transform3x3(&rsurface.inversematrix, r_view.up, newup);
+ VectorNormalize(newforward);
+ VectorNormalize(newright);
+ VectorNormalize(newup);
+ // make deformed versions of only the model vertices used by the specified surfaces
+ for (texturesurfaceindex = 0;texturesurfaceindex < texturenumsurfaces;texturesurfaceindex++)
+ {
+ const msurface_t *surface = texturesurfacelist[texturesurfaceindex];
+ // a single autosprite surface can contain multiple sprites...
+ for (j = 0;j < surface->num_vertices - 3;j += 4)
+ {
+ VectorClear(center);
+ for (i = 0;i < 4;i++)
+ VectorAdd(center, (rsurface.vertex3f + 3 * surface->num_firstvertex) + (j+i) * 3, center);
+ VectorScale(center, 0.25f, center);
+ VectorCopy((rsurface.normal3f + 3 * surface->num_firstvertex) + j*3, forward);
+ VectorCopy((rsurface.svector3f + 3 * surface->num_firstvertex) + j*3, right);
+ VectorCopy((rsurface.tvector3f + 3 * surface->num_firstvertex) + j*3, up);
+ for (i = 0;i < 4;i++)
+ {
+ VectorSubtract((rsurface.vertex3f + 3 * surface->num_firstvertex) + (j+i)*3, center, v);
+ VectorMAMAMAM(1, center, DotProduct(forward, v), newforward, DotProduct(right, v), newright, DotProduct(up, v), newup, rsurface.array_deformedvertex3f + (surface->num_firstvertex+i+j) * 3);
+ }
+ }
+ Mod_BuildNormals(surface->num_firstvertex, surface->num_vertices, surface->num_triangles, rsurface.vertex3f, rsurface.modelelement3i + surface->num_firsttriangle * 3, rsurface.array_deformednormal3f, r_smoothnormals_areaweighting.integer);
+ Mod_BuildTextureVectorsFromNormals(surface->num_firstvertex, surface->num_vertices, surface->num_triangles, rsurface.vertex3f, rsurface.modeltexcoordtexture2f, rsurface.array_deformednormal3f, rsurface.modelelement3i + surface->num_firsttriangle * 3, rsurface.array_deformedsvector3f, rsurface.array_deformedtvector3f, r_smoothnormals_areaweighting.integer);
+ }
+ rsurface.vertex3f = rsurface.array_deformedvertex3f;
+ rsurface.vertex3f_bufferobject = 0;
+ rsurface.vertex3f_bufferoffset = 0;
+ rsurface.svector3f = rsurface.array_deformedsvector3f;
+ rsurface.svector3f_bufferobject = 0;
+ rsurface.svector3f_bufferoffset = 0;
+ rsurface.tvector3f = rsurface.array_deformedtvector3f;
+ rsurface.tvector3f_bufferobject = 0;
+ rsurface.tvector3f_bufferoffset = 0;
+ rsurface.normal3f = rsurface.array_deformednormal3f;
+ rsurface.normal3f_bufferobject = 0;
+ rsurface.normal3f_bufferoffset = 0;
+ break;
+ case Q3DEFORM_AUTOSPRITE2:
+ Matrix4x4_Transform3x3(&rsurface.inversematrix, r_view.forward, newforward);
+ Matrix4x4_Transform3x3(&rsurface.inversematrix, r_view.right, newright);
+ Matrix4x4_Transform3x3(&rsurface.inversematrix, r_view.up, newup);
+ VectorNormalize(newforward);
+ VectorNormalize(newright);
+ VectorNormalize(newup);
+ // make deformed versions of only the model vertices used by the specified surfaces
+ for (texturesurfaceindex = 0;texturesurfaceindex < texturenumsurfaces;texturesurfaceindex++)
+ {
+ const msurface_t *surface = texturesurfacelist[texturesurfaceindex];
+ const float *v1, *v2;
+ vec3_t start, end;
+ float f, l;
+ struct
+ {
+ float length2;
+ const float *v1;
+ const float *v2;
+ }
+ shortest[2];
+ memset(shortest, 0, sizeof(shortest));
+ // a single autosprite surface can contain multiple sprites...
+ for (j = 0;j < surface->num_vertices - 3;j += 4)
+ {
+ VectorClear(center);
+ for (i = 0;i < 4;i++)
+ VectorAdd(center, (rsurface.vertex3f + 3 * surface->num_firstvertex) + (j+i) * 3, center);
+ VectorScale(center, 0.25f, center);
+ // find the two shortest edges, then use them to define the
+ // axis vectors for rotating around the central axis
+ for (i = 0;i < 6;i++)
+ {
+ v1 = rsurface.vertex3f + 3 * (surface->num_firstvertex + quadedges[i][0]);
+ v2 = rsurface.vertex3f + 3 * (surface->num_firstvertex + quadedges[i][1]);
+#if 0
+ Debug_PolygonBegin(NULL, 0, false, 0);
+ Debug_PolygonVertex(v1[0], v1[1], v1[2], 0, 0, 1, 0, 0, 1);
+ Debug_PolygonVertex((v1[0] + v2[0]) * 0.5f + rsurface.normal3f[3 * (surface->num_firstvertex + j)+0] * 4, (v1[1] + v2[1]) * 0.5f + rsurface.normal3f[3 * (surface->num_firstvertex + j)+1], (v1[2] + v2[2]) * 0.5f + rsurface.normal3f[3 * (surface->num_firstvertex + j)+2], 0, 0, 1, 1, 0, 1);
+ Debug_PolygonVertex(v2[0], v2[1], v2[2], 0, 0, 1, 0, 0, 1);
+ Debug_PolygonEnd();
+#endif
+ l = VectorDistance2(v1, v2);
+ // this length bias tries to make sense of square polygons, assuming they are meant to be upright
+ if (v1[2] != v2[2])
+ l += (1.0f / 1024.0f);
+ if (shortest[0].length2 > l || i == 0)
+ {
+ shortest[1] = shortest[0];
+ shortest[0].length2 = l;
+ shortest[0].v1 = v1;
+ shortest[0].v2 = v2;
+ }
+ else if (shortest[1].length2 > l || i == 1)
+ {
+ shortest[1].length2 = l;
+ shortest[1].v1 = v1;
+ shortest[1].v2 = v2;
+ }
+ }
+ VectorLerp(shortest[0].v1, 0.5f, shortest[0].v2, start);
+ VectorLerp(shortest[1].v1, 0.5f, shortest[1].v2, end);
+#if 0
+ Debug_PolygonBegin(NULL, 0, false, 0);
+ Debug_PolygonVertex(start[0], start[1], start[2], 0, 0, 1, 1, 0, 1);
+ Debug_PolygonVertex(center[0] + rsurface.normal3f[3 * (surface->num_firstvertex + j)+0] * 4, center[1] + rsurface.normal3f[3 * (surface->num_firstvertex + j)+1] * 4, center[2] + rsurface.normal3f[3 * (surface->num_firstvertex + j)+2] * 4, 0, 0, 0, 1, 0, 1);
+ Debug_PolygonVertex(end[0], end[1], end[2], 0, 0, 0, 1, 1, 1);
+ Debug_PolygonEnd();
+#endif
+ // this calculates the right vector from the shortest edge
+ // and the up vector from the edge midpoints
+ VectorSubtract(shortest[0].v1, shortest[0].v2, right);
+ VectorNormalize(right);
+ VectorSubtract(end, start, up);
+ VectorNormalize(up);
+ // calculate a forward vector to use instead of the original plane normal (this is how we get a new right vector)
+ //VectorSubtract(rsurface.modelorg, center, forward);
+ Matrix4x4_Transform3x3(&rsurface.inversematrix, r_view.forward, forward);
+ VectorNegate(forward, forward);
+ VectorReflect(forward, 0, up, forward);
VectorNormalize(forward);
- right[0] = forward[1];
- right[1] = -forward[0];
- right[2] = 0;
- VectorSet(up, 0, 0, 1);
+ CrossProduct(up, forward, newright);
+ VectorNormalize(newright);
+#if 0
+ Debug_PolygonBegin(NULL, 0, false, 0);
+ Debug_PolygonVertex(center[0] + rsurface.normal3f[3 * (surface->num_firstvertex + j)+0] * 8, center[1] + rsurface.normal3f[3 * (surface->num_firstvertex + j)+1] * 8, center[2] + rsurface.normal3f[3 * (surface->num_firstvertex + j)+2] * 8, 0, 0, 1, 0, 0, 1);
+ Debug_PolygonVertex(center[0] + right[0] * 8, center[1] + right[1] * 8, center[2] + right[2] * 8, 0, 0, 0, 1, 0, 1);
+ Debug_PolygonVertex(center[0] + up [0] * 8, center[1] + up [1] * 8, center[2] + up [2] * 8, 0, 0, 0, 0, 1, 1);
+ Debug_PolygonEnd();
+#endif
+#if 0
+ Debug_PolygonBegin(NULL, 0, false, 0);
+ Debug_PolygonVertex(center[0] + forward [0] * 8, center[1] + forward [1] * 8, center[2] + forward [2] * 8, 0, 0, 1, 0, 0, 1);
+ Debug_PolygonVertex(center[0] + newright[0] * 8, center[1] + newright[1] * 8, center[2] + newright[2] * 8, 0, 0, 0, 1, 0, 1);
+ Debug_PolygonVertex(center[0] + up [0] * 8, center[1] + up [1] * 8, center[2] + up [2] * 8, 0, 0, 0, 0, 1, 1);
+ Debug_PolygonEnd();
+#endif
+ // rotate the quad around the up axis vector, this is made
+ // especially easy by the fact we know the quad is flat,
+ // so we only have to subtract the center position and
+ // measure distance along the right vector, and then
+ // multiply that by the newright vector and add back the
+ // center position
+ // we also need to subtract the old position to undo the
+ // displacement from the center, which we do with a
+ // DotProduct, the subtraction/addition of center is also
+ // optimized into DotProducts here
+ l = DotProduct(right, center);
+ for (i = 0;i < 4;i++)
+ {
+ v1 = rsurface.vertex3f + 3 * (surface->num_firstvertex + j + i);
+ f = DotProduct(right, v1) - l;
+ VectorMAMAM(1, v1, -f, right, f, newright, rsurface.array_deformedvertex3f + (surface->num_firstvertex+i+j) * 3);
+ }
+ }
+ Mod_BuildNormals(surface->num_firstvertex, surface->num_vertices, surface->num_triangles, rsurface.vertex3f, rsurface.modelelement3i + surface->num_firsttriangle * 3, rsurface.array_deformednormal3f, r_smoothnormals_areaweighting.integer);
+ Mod_BuildTextureVectorsFromNormals(surface->num_firstvertex, surface->num_vertices, surface->num_triangles, rsurface.vertex3f, rsurface.modeltexcoordtexture2f, rsurface.array_deformednormal3f, rsurface.modelelement3i + surface->num_firsttriangle * 3, rsurface.array_deformedsvector3f, rsurface.array_deformedtvector3f, r_smoothnormals_areaweighting.integer);
+ }
+ rsurface.vertex3f = rsurface.array_deformedvertex3f;
+ rsurface.vertex3f_bufferobject = 0;
+ rsurface.vertex3f_bufferoffset = 0;
+ rsurface.svector3f = rsurface.array_deformedsvector3f;
+ rsurface.svector3f_bufferobject = 0;
+ rsurface.svector3f_bufferoffset = 0;
+ rsurface.tvector3f = rsurface.array_deformedtvector3f;
+ rsurface.tvector3f_bufferobject = 0;
+ rsurface.tvector3f_bufferoffset = 0;
+ rsurface.normal3f = rsurface.array_deformednormal3f;
+ rsurface.normal3f_bufferobject = 0;
+ rsurface.normal3f_bufferoffset = 0;
+ break;
+ case Q3DEFORM_NORMAL:
+ // deform the normals to make reflections wavey
+ for (texturesurfaceindex = 0;texturesurfaceindex < texturenumsurfaces;texturesurfaceindex++)
+ {
+ const msurface_t *surface = texturesurfacelist[texturesurfaceindex];
+ for (j = 0;j < surface->num_vertices;j++)
+ {
+ float vertex[3];
+ float *normal = (rsurface.array_deformednormal3f + 3 * surface->num_firstvertex) + j*3;
+ VectorScale((rsurface.vertex3f + 3 * surface->num_firstvertex) + j*3, 0.98f, vertex);
+ VectorCopy((rsurface.normal3f + 3 * surface->num_firstvertex) + j*3, normal);
+ normal[0] += deform->parms[0] * noise4f( vertex[0], vertex[1], vertex[2], r_refdef.time * deform->parms[1]);
+ normal[1] += deform->parms[0] * noise4f( 98 + vertex[0], vertex[1], vertex[2], r_refdef.time * deform->parms[1]);
+ normal[2] += deform->parms[0] * noise4f(196 + vertex[0], vertex[1], vertex[2], r_refdef.time * deform->parms[1]);
+ VectorNormalize(normal);
+ }
+ Mod_BuildTextureVectorsFromNormals(surface->num_firstvertex, surface->num_vertices, surface->num_triangles, rsurface.vertex3f, rsurface.modeltexcoordtexture2f, rsurface.array_deformednormal3f, rsurface.modelelement3i + surface->num_firsttriangle * 3, rsurface.array_deformedsvector3f, rsurface.array_deformedtvector3f, r_smoothnormals_areaweighting.integer);
+ }
+ rsurface.svector3f = rsurface.array_deformedsvector3f;
+ rsurface.svector3f_bufferobject = 0;
+ rsurface.svector3f_bufferoffset = 0;
+ rsurface.tvector3f = rsurface.array_deformedtvector3f;
+ rsurface.tvector3f_bufferobject = 0;
+ rsurface.tvector3f_bufferoffset = 0;
+ rsurface.normal3f = rsurface.array_deformednormal3f;
+ rsurface.normal3f_bufferobject = 0;
+ rsurface.normal3f_bufferoffset = 0;
+ break;
+ case Q3DEFORM_WAVE:
+ // deform vertex array to make wavey water and flags and such
+ waveparms[0] = deform->waveparms[0];
+ waveparms[1] = deform->waveparms[1];
+ waveparms[2] = deform->waveparms[2];
+ waveparms[3] = deform->waveparms[3];
+ // this is how a divisor of vertex influence on deformation
+ animpos = deform->parms[0] ? 1.0f / deform->parms[0] : 100.0f;
+ scale = R_EvaluateQ3WaveFunc(deform->wavefunc, waveparms);
+ for (texturesurfaceindex = 0;texturesurfaceindex < texturenumsurfaces;texturesurfaceindex++)
+ {
+ const msurface_t *surface = texturesurfacelist[texturesurfaceindex];
+ for (j = 0;j < surface->num_vertices;j++)
+ {
+ float *vertex = (rsurface.array_deformedvertex3f + 3 * surface->num_firstvertex) + j*3;
+ VectorCopy((rsurface.vertex3f + 3 * surface->num_firstvertex) + j*3, vertex);
+ // if the wavefunc depends on time, evaluate it per-vertex
+ if (waveparms[3])
+ {
+ waveparms[2] = deform->waveparms[2] + (vertex[0] + vertex[1] + vertex[2]) * animpos;
+ scale = R_EvaluateQ3WaveFunc(deform->wavefunc, waveparms);
+ }
+ VectorMA(vertex, scale, (rsurface.normal3f + 3 * surface->num_firstvertex) + j*3, vertex);
+ }
+ }
+ rsurface.vertex3f = rsurface.array_deformedvertex3f;
+ rsurface.vertex3f_bufferobject = 0;
+ rsurface.vertex3f_bufferoffset = 0;
+ break;
+ case Q3DEFORM_BULGE:
+ // deform vertex array to make the surface have moving bulges
+ for (texturesurfaceindex = 0;texturesurfaceindex < texturenumsurfaces;texturesurfaceindex++)
+ {
+ const msurface_t *surface = texturesurfacelist[texturesurfaceindex];
+ for (j = 0;j < surface->num_vertices;j++)
+ {
+ scale = sin((rsurface.modeltexcoordtexture2f[2 * (surface->num_firstvertex + j)] * deform->parms[0] + r_refdef.time * deform->parms[2])) * deform->parms[1];
+ VectorMA(rsurface.vertex3f + 3 * (surface->num_firstvertex + j), scale, rsurface.normal3f + 3 * (surface->num_firstvertex + j), rsurface.array_deformedvertex3f + 3 * (surface->num_firstvertex + j));
}
- // FIXME: calculate vectors from triangle edges instead of using texture vectors as an easy way out?
- Matrix4x4_FromVectors(&matrix1, (rsurface_modelnormal3f + 3 * surface->num_firstvertex) + j*3, (rsurface_modelsvector3f + 3 * surface->num_firstvertex) + j*3, (rsurface_modeltvector3f + 3 * surface->num_firstvertex) + j*3, center);
- Matrix4x4_Invert_Simple(&imatrix1, &matrix1);
- for (i = 0;i < 4;i++)
- Matrix4x4_Transform(&imatrix1, (rsurface_modelvertex3f + 3 * surface->num_firstvertex) + (j+i)*3, v[i]);
- for (i = 0;i < 4;i++)
- VectorMAMAMAM(1, center, v[i][0], forward, v[i][1], right, v[i][2], up, rsurface_array_deformedvertex3f + (surface->num_firstvertex+i+j) * 3);
}
- Mod_BuildNormals(surface->num_firstvertex, surface->num_vertices, surface->num_triangles, rsurface_modelvertex3f, rsurface_model->surfmesh.data_element3i + surface->num_firsttriangle * 3, rsurface_array_deformednormal3f, r_smoothnormals_areaweighting.integer);
- Mod_BuildTextureVectorsFromNormals(surface->num_firstvertex, surface->num_vertices, surface->num_triangles, rsurface_modelvertex3f, rsurface_model->surfmesh.data_texcoordtexture2f, rsurface_array_deformednormal3f, rsurface_model->surfmesh.data_element3i + surface->num_firsttriangle * 3, rsurface_array_deformedsvector3f, rsurface_array_deformedtvector3f, r_smoothnormals_areaweighting.integer);
+ rsurface.vertex3f = rsurface.array_deformedvertex3f;
+ rsurface.vertex3f_bufferobject = 0;
+ rsurface.vertex3f_bufferoffset = 0;
+ break;
+ case Q3DEFORM_MOVE:
+ // deform vertex array
+ scale = R_EvaluateQ3WaveFunc(deform->wavefunc, deform->waveparms);
+ VectorScale(deform->parms, scale, waveparms);
+ for (texturesurfaceindex = 0;texturesurfaceindex < texturenumsurfaces;texturesurfaceindex++)
+ {
+ const msurface_t *surface = texturesurfacelist[texturesurfaceindex];
+ for (j = 0;j < surface->num_vertices;j++)
+ VectorAdd(rsurface.vertex3f + 3 * (surface->num_firstvertex + j), waveparms, rsurface.array_deformedvertex3f + 3 * (surface->num_firstvertex + j));
+ }
+ rsurface.vertex3f = rsurface.array_deformedvertex3f;
+ rsurface.vertex3f_bufferobject = 0;
+ rsurface.vertex3f_bufferoffset = 0;
+ break;
}
- rsurface_vertex3f = rsurface_array_deformedvertex3f;
- rsurface_svector3f = rsurface_array_deformedsvector3f;
- rsurface_tvector3f = rsurface_array_deformedtvector3f;
- rsurface_normal3f = rsurface_array_deformednormal3f;
}
- else
+ // generate texcoords based on the chosen texcoord source
+ switch(rsurface.texture->tcgen.tcgen)
+ {
+ default:
+ case Q3TCGEN_TEXTURE:
+ rsurface.texcoordtexture2f = rsurface.modeltexcoordtexture2f;
+ rsurface.texcoordtexture2f_bufferobject = rsurface.modeltexcoordtexture2f_bufferobject;
+ rsurface.texcoordtexture2f_bufferoffset = rsurface.modeltexcoordtexture2f_bufferoffset;
+ break;
+ case Q3TCGEN_LIGHTMAP:
+ rsurface.texcoordtexture2f = rsurface.modeltexcoordlightmap2f;
+ rsurface.texcoordtexture2f_bufferobject = rsurface.modeltexcoordlightmap2f_bufferobject;
+ rsurface.texcoordtexture2f_bufferoffset = rsurface.modeltexcoordlightmap2f_bufferoffset;
+ break;
+ case Q3TCGEN_VECTOR:
+ for (texturesurfaceindex = 0;texturesurfaceindex < texturenumsurfaces;texturesurfaceindex++)
+ {
+ const msurface_t *surface = texturesurfacelist[texturesurfaceindex];
+ for (j = 0, v1 = rsurface.modelvertex3f + 3 * surface->num_firstvertex, out_tc = rsurface.array_generatedtexcoordtexture2f + 2 * surface->num_firstvertex;j < surface->num_vertices;j++, v1 += 3, out_tc += 2)
+ {
+ out_tc[0] = DotProduct(v1, rsurface.texture->tcgen.parms);
+ out_tc[1] = DotProduct(v1, rsurface.texture->tcgen.parms + 3);
+ }
+ }
+ rsurface.texcoordtexture2f = rsurface.array_generatedtexcoordtexture2f;
+ rsurface.texcoordtexture2f_bufferobject = 0;
+ rsurface.texcoordtexture2f_bufferoffset = 0;
+ break;
+ case Q3TCGEN_ENVIRONMENT:
+ // make environment reflections using a spheremap
+ for (texturesurfaceindex = 0;texturesurfaceindex < texturenumsurfaces;texturesurfaceindex++)
+ {
+ const msurface_t *surface = texturesurfacelist[texturesurfaceindex];
+ const float *vertex = rsurface.modelvertex3f + 3 * surface->num_firstvertex;
+ const float *normal = rsurface.modelnormal3f + 3 * surface->num_firstvertex;
+ float *out_tc = rsurface.array_generatedtexcoordtexture2f + 2 * surface->num_firstvertex;
+ for (j = 0;j < surface->num_vertices;j++, vertex += 3, normal += 3, out_tc += 2)
+ {
+ float l, d, eyedir[3];
+ VectorSubtract(rsurface.modelorg, vertex, eyedir);
+ l = 0.5f / VectorLength(eyedir);
+ d = DotProduct(normal, eyedir)*2;
+ out_tc[0] = 0.5f + (normal[1]*d - eyedir[1])*l;
+ out_tc[1] = 0.5f - (normal[2]*d - eyedir[2])*l;
+ }
+ }
+ rsurface.texcoordtexture2f = rsurface.array_generatedtexcoordtexture2f;
+ rsurface.texcoordtexture2f_bufferobject = 0;
+ rsurface.texcoordtexture2f_bufferoffset = 0;
+ break;
+ }
+ // the only tcmod that needs software vertex processing is turbulent, so
+ // check for it here and apply the changes if needed
+ // and we only support that as the first one
+ // (handling a mixture of turbulent and other tcmods would be problematic
+ // without punting it entirely to a software path)
+ if (rsurface.texture->tcmods[0].tcmod == Q3TCMOD_TURBULENT)
{
- rsurface_vertex3f = rsurface_modelvertex3f;
- rsurface_svector3f = rsurface_modelsvector3f;
- rsurface_tvector3f = rsurface_modeltvector3f;
- rsurface_normal3f = rsurface_modelnormal3f;
+ amplitude = rsurface.texture->tcmods[0].parms[1];
+ animpos = rsurface.texture->tcmods[0].parms[2] + r_refdef.time * rsurface.texture->tcmods[0].parms[3];
+ for (texturesurfaceindex = 0;texturesurfaceindex < texturenumsurfaces;texturesurfaceindex++)
+ {
+ const msurface_t *surface = texturesurfacelist[texturesurfaceindex];
+ for (j = 0, v1 = rsurface.modelvertex3f + 3 * surface->num_firstvertex, in_tc = rsurface.texcoordtexture2f + 2 * surface->num_firstvertex, out_tc = rsurface.array_generatedtexcoordtexture2f + 2 * surface->num_firstvertex;j < surface->num_vertices;j++, v1 += 3, in_tc += 2, out_tc += 2)
+ {
+ out_tc[0] = in_tc[0] + amplitude * sin(((v1[0] + v1[2]) * 1.0 / 1024.0f + animpos) * M_PI * 2);
+ out_tc[1] = in_tc[1] + amplitude * sin(((v1[1] ) * 1.0 / 1024.0f + animpos) * M_PI * 2);
+ }
+ }
+ rsurface.texcoordtexture2f = rsurface.array_generatedtexcoordtexture2f;
+ rsurface.texcoordtexture2f_bufferobject = 0;
+ rsurface.texcoordtexture2f_bufferoffset = 0;
}
- R_Mesh_VertexPointer(rsurface_vertex3f);
+ rsurface.texcoordlightmap2f = rsurface.modeltexcoordlightmap2f;
+ rsurface.texcoordlightmap2f_bufferobject = rsurface.modeltexcoordlightmap2f_bufferobject;
+ rsurface.texcoordlightmap2f_bufferoffset = rsurface.modeltexcoordlightmap2f_bufferoffset;
+ R_Mesh_VertexPointer(rsurface.vertex3f, rsurface.vertex3f_bufferobject, rsurface.vertex3f_bufferoffset);
}
void RSurf_DrawBatch_Simple(int texturenumsurfaces, msurface_t **texturesurfacelist)
{
- int texturesurfaceindex;
+ int i, j;
const msurface_t *surface = texturesurfacelist[0];
- int firstvertex = surface->num_firstvertex;
- int endvertex = surface->num_firstvertex + surface->num_vertices;
+ const msurface_t *surface2;
+ int firstvertex;
+ int endvertex;
+ int numvertices;
+ int numtriangles;
+ // TODO: lock all array ranges before render, rather than on each surface
if (texturenumsurfaces == 1)
{
GL_LockArrays(surface->num_firstvertex, surface->num_vertices);
- R_Mesh_Draw(surface->num_firstvertex, surface->num_vertices, surface->num_triangles, (rsurface_model->surfmesh.data_element3i + 3 * surface->num_firsttriangle));
+ R_Mesh_Draw(surface->num_firstvertex, surface->num_vertices, surface->num_triangles, (rsurface.modelelement3i + 3 * surface->num_firsttriangle), rsurface.modelelement3i_bufferobject, (sizeof(int[3]) * surface->num_firsttriangle));
}
else if (r_batchmode.integer == 2)
{
#define MAXBATCHTRIANGLES 4096
int batchtriangles = 0;
int batchelements[MAXBATCHTRIANGLES*3];
- for (texturesurfaceindex = 0;texturesurfaceindex < texturenumsurfaces;texturesurfaceindex++)
+ for (i = 0;i < texturenumsurfaces;i = j)
{
- surface = texturesurfacelist[texturesurfaceindex];
- if (surface->num_triangles >= 256 || (batchtriangles == 0 && texturesurfaceindex + 1 >= texturenumsurfaces))
+ surface = texturesurfacelist[i];
+ j = i + 1;
+ if (surface->num_triangles > MAXBATCHTRIANGLES)
{
- R_Mesh_Draw(surface->num_firstvertex, surface->num_vertices, surface->num_triangles, (rsurface_model->surfmesh.data_element3i + 3 * surface->num_firsttriangle));
+ R_Mesh_Draw(surface->num_firstvertex, surface->num_vertices, surface->num_triangles, (rsurface.modelelement3i + 3 * surface->num_firsttriangle), rsurface.modelelement3i_bufferobject, (sizeof(int[3]) * surface->num_firsttriangle));
continue;
}
- if (batchtriangles + surface->num_triangles > MAXBATCHTRIANGLES)
+ memcpy(batchelements, rsurface.modelelement3i + 3 * surface->num_firsttriangle, surface->num_triangles * sizeof(int[3]));
+ batchtriangles = surface->num_triangles;
+ firstvertex = surface->num_firstvertex;
+ endvertex = surface->num_firstvertex + surface->num_vertices;
+ for (;j < texturenumsurfaces;j++)
{
- R_Mesh_Draw(firstvertex, endvertex - firstvertex, batchtriangles, batchelements);
- batchtriangles = 0;
- firstvertex = surface->num_firstvertex;
- endvertex = surface->num_firstvertex + surface->num_vertices;
+ surface2 = texturesurfacelist[j];
+ if (batchtriangles + surface2->num_triangles > MAXBATCHTRIANGLES)
+ break;
+ memcpy(batchelements + batchtriangles * 3, rsurface.modelelement3i + 3 * surface2->num_firsttriangle, surface2->num_triangles * sizeof(int[3]));
+ batchtriangles += surface2->num_triangles;
+ firstvertex = min(firstvertex, surface2->num_firstvertex);
+ endvertex = max(endvertex, surface2->num_firstvertex + surface2->num_vertices);
}
- else
+ surface2 = texturesurfacelist[j-1];
+ numvertices = endvertex - firstvertex;
+ R_Mesh_Draw(firstvertex, numvertices, batchtriangles, batchelements, 0, 0);
+ }
+ }
+ else if (r_batchmode.integer == 1)
+ {
+ for (i = 0;i < texturenumsurfaces;i = j)
+ {
+ surface = texturesurfacelist[i];
+ for (j = i + 1, surface2 = surface + 1;j < texturenumsurfaces;j++, surface2++)
+ if (texturesurfacelist[j] != surface2)
+ break;
+ surface2 = texturesurfacelist[j-1];
+ numvertices = surface2->num_firstvertex + surface2->num_vertices - surface->num_firstvertex;
+ numtriangles = surface2->num_firsttriangle + surface2->num_triangles - surface->num_firsttriangle;
+ GL_LockArrays(surface->num_firstvertex, numvertices);
+ R_Mesh_Draw(surface->num_firstvertex, numvertices, numtriangles, (rsurface.modelelement3i + 3 * surface->num_firsttriangle), rsurface.modelelement3i_bufferobject, (sizeof(int[3]) * surface->num_firsttriangle));
+ }
+ }
+ else
+ {
+ for (i = 0;i < texturenumsurfaces;i++)
+ {
+ surface = texturesurfacelist[i];
+ GL_LockArrays(surface->num_firstvertex, surface->num_vertices);
+ R_Mesh_Draw(surface->num_firstvertex, surface->num_vertices, surface->num_triangles, (rsurface.modelelement3i + 3 * surface->num_firsttriangle), rsurface.modelelement3i_bufferobject, (sizeof(int[3]) * surface->num_firsttriangle));
+ }
+ }
+}
+
+static void RSurf_DrawBatch_WithLightmapSwitching_WithWaterTextureSwitching(int texturenumsurfaces, msurface_t **texturesurfacelist, int lightmaptexunit, int deluxemaptexunit, int refractiontexunit, int reflectiontexunit)
+{
+ int i, planeindex, vertexindex;
+ float d, bestd;
+ vec3_t vert;
+ const float *v;
+ r_waterstate_waterplane_t *p, *bestp;
+ msurface_t *surface;
+ if (r_waterstate.renderingscene)
+ return;
+ for (i = 0;i < texturenumsurfaces;i++)
+ {
+ surface = texturesurfacelist[i];
+ if (lightmaptexunit >= 0)
+ R_Mesh_TexBind(lightmaptexunit, R_GetTexture(surface->lightmaptexture));
+ if (deluxemaptexunit >= 0)
+ R_Mesh_TexBind(deluxemaptexunit, R_GetTexture(surface->deluxemaptexture));
+ // pick the closest matching water plane
+ bestd = 0;
+ bestp = NULL;
+ for (planeindex = 0, p = r_waterstate.waterplanes;planeindex < r_waterstate.numwaterplanes;planeindex++, p++)
+ {
+ d = 0;
+ for (vertexindex = 0, v = rsurface.modelvertex3f + surface->num_firstvertex * 3;vertexindex < surface->num_vertices;vertexindex++, v += 3)
+ {
+ Matrix4x4_Transform(&rsurface.matrix, v, vert);
+ d += fabs(PlaneDiff(vert, &p->plane));
+ }
+ if (bestd > d || !bestp)
{
- firstvertex = min(firstvertex, surface->num_firstvertex);
- endvertex = max(endvertex, surface->num_firstvertex + surface->num_vertices);
+ bestd = d;
+ bestp = p;
}
- memcpy(batchelements + batchtriangles * 3, rsurface_model->surfmesh.data_element3i + 3 * surface->num_firsttriangle, surface->num_triangles * sizeof(int[3]));
- batchtriangles += surface->num_triangles;
}
- if (batchtriangles)
- R_Mesh_Draw(firstvertex, endvertex - firstvertex, batchtriangles, batchelements);
+ if (bestp)
+ {
+ if (refractiontexunit >= 0)
+ R_Mesh_TexBind(refractiontexunit, R_GetTexture(bestp->texture_refraction));
+ if (reflectiontexunit >= 0)
+ R_Mesh_TexBind(reflectiontexunit, R_GetTexture(bestp->texture_reflection));
+ }
+ else
+ {
+ if (refractiontexunit >= 0)
+ R_Mesh_TexBind(refractiontexunit, R_GetTexture(r_texture_black));
+ if (reflectiontexunit >= 0)
+ R_Mesh_TexBind(reflectiontexunit, R_GetTexture(r_texture_black));
+ }
+ GL_LockArrays(surface->num_firstvertex, surface->num_vertices);
+ R_Mesh_Draw(surface->num_firstvertex, surface->num_vertices, surface->num_triangles, (rsurface.modelelement3i + 3 * surface->num_firsttriangle), rsurface.modelelement3i_bufferobject, (sizeof(int[3]) * surface->num_firsttriangle));
}
- else if (r_batchmode.integer == 1)
+}
+
+static void RSurf_DrawBatch_WithLightmapSwitching(int texturenumsurfaces, msurface_t **texturesurfacelist, int lightmaptexunit, int deluxemaptexunit)
+{
+ int i;
+ int j;
+ const msurface_t *surface = texturesurfacelist[0];
+ const msurface_t *surface2;
+ int firstvertex;
+ int endvertex;
+ int numvertices;
+ int numtriangles;
+ // TODO: lock all array ranges before render, rather than on each surface
+ if (texturenumsurfaces == 1)
{
- int firsttriangle = 0;
- int endtriangle = -1;
- for (texturesurfaceindex = 0;texturesurfaceindex < texturenumsurfaces;texturesurfaceindex++)
+ R_Mesh_TexBind(lightmaptexunit, R_GetTexture(surface->lightmaptexture));
+ if (deluxemaptexunit >= 0)
+ R_Mesh_TexBind(deluxemaptexunit, R_GetTexture(surface->deluxemaptexture));
+ GL_LockArrays(surface->num_firstvertex, surface->num_vertices);
+ R_Mesh_Draw(surface->num_firstvertex, surface->num_vertices, surface->num_triangles, (rsurface.modelelement3i + 3 * surface->num_firsttriangle), rsurface.modelelement3i_bufferobject, (sizeof(int[3]) * surface->num_firsttriangle));
+ }
+ else if (r_batchmode.integer == 2)
+ {
+ #define MAXBATCHTRIANGLES 4096
+ int batchtriangles = 0;
+ int batchelements[MAXBATCHTRIANGLES*3];
+ for (i = 0;i < texturenumsurfaces;i = j)
{
- surface = texturesurfacelist[texturesurfaceindex];
- if (surface->num_firsttriangle != endtriangle)
+ surface = texturesurfacelist[i];
+ R_Mesh_TexBind(lightmaptexunit, R_GetTexture(surface->lightmaptexture));
+ if (deluxemaptexunit >= 0)
+ R_Mesh_TexBind(deluxemaptexunit, R_GetTexture(surface->deluxemaptexture));
+ j = i + 1;
+ if (surface->num_triangles > MAXBATCHTRIANGLES)
{
- if (endtriangle > firsttriangle)
- {
- GL_LockArrays(firstvertex, endvertex - firstvertex);
- R_Mesh_Draw(firstvertex, endvertex - firstvertex, endtriangle - firsttriangle, (rsurface_model->surfmesh.data_element3i + 3 * firsttriangle));
- }
- firstvertex = surface->num_firstvertex;
- endvertex = surface->num_firstvertex + surface->num_vertices;
- firsttriangle = surface->num_firsttriangle;
+ R_Mesh_Draw(surface->num_firstvertex, surface->num_vertices, surface->num_triangles, (rsurface.modelelement3i + 3 * surface->num_firsttriangle), rsurface.modelelement3i_bufferobject, (sizeof(int[3]) * surface->num_firsttriangle));
+ continue;
}
- else
+ memcpy(batchelements, rsurface.modelelement3i + 3 * surface->num_firsttriangle, surface->num_triangles * sizeof(int[3]));
+ batchtriangles = surface->num_triangles;
+ firstvertex = surface->num_firstvertex;
+ endvertex = surface->num_firstvertex + surface->num_vertices;
+ for (;j < texturenumsurfaces;j++)
{
- firstvertex = min(firstvertex, surface->num_firstvertex);
- endvertex = max(endvertex, surface->num_firstvertex + surface->num_vertices);
+ surface2 = texturesurfacelist[j];
+ if (surface2->lightmaptexture != surface->lightmaptexture || batchtriangles + surface2->num_triangles > MAXBATCHTRIANGLES)
+ break;
+ memcpy(batchelements + batchtriangles * 3, rsurface.modelelement3i + 3 * surface2->num_firsttriangle, surface2->num_triangles * sizeof(int[3]));
+ batchtriangles += surface2->num_triangles;
+ firstvertex = min(firstvertex, surface2->num_firstvertex);
+ endvertex = max(endvertex, surface2->num_firstvertex + surface2->num_vertices);
}
- endtriangle = surface->num_firsttriangle + surface->num_triangles;
+ surface2 = texturesurfacelist[j-1];
+ numvertices = endvertex - firstvertex;
+ R_Mesh_Draw(firstvertex, numvertices, batchtriangles, batchelements, 0, 0);
}
- if (endtriangle > firsttriangle)
+ }
+ else if (r_batchmode.integer == 1)
+ {
+#if 0
+ Con_Printf("%s batch sizes ignoring lightmap:", rsurface.texture->name);
+ for (i = 0;i < texturenumsurfaces;i = j)
+ {
+ surface = texturesurfacelist[i];
+ for (j = i + 1, surface2 = surface + 1;j < texturenumsurfaces;j++, surface2++)
+ if (texturesurfacelist[j] != surface2)
+ break;
+ Con_Printf(" %i", j - i);
+ }
+ Con_Printf("\n");
+ Con_Printf("%s batch sizes honoring lightmap:", rsurface.texture->name);
+#endif
+ for (i = 0;i < texturenumsurfaces;i = j)
{
- GL_LockArrays(firstvertex, endvertex - firstvertex);
- R_Mesh_Draw(firstvertex, endvertex - firstvertex, endtriangle - firsttriangle, (rsurface_model->surfmesh.data_element3i + 3 * firsttriangle));
+ surface = texturesurfacelist[i];
+ R_Mesh_TexBind(lightmaptexunit, R_GetTexture(surface->lightmaptexture));
+ if (deluxemaptexunit >= 0)
+ R_Mesh_TexBind(deluxemaptexunit, R_GetTexture(surface->deluxemaptexture));
+ for (j = i + 1, surface2 = surface + 1;j < texturenumsurfaces;j++, surface2++)
+ if (texturesurfacelist[j] != surface2 || texturesurfacelist[j]->lightmaptexture != surface->lightmaptexture)
+ break;
+#if 0
+ Con_Printf(" %i", j - i);
+#endif
+ surface2 = texturesurfacelist[j-1];
+ numvertices = surface2->num_firstvertex + surface2->num_vertices - surface->num_firstvertex;
+ numtriangles = surface2->num_firsttriangle + surface2->num_triangles - surface->num_firsttriangle;
+ GL_LockArrays(surface->num_firstvertex, numvertices);
+ R_Mesh_Draw(surface->num_firstvertex, numvertices, numtriangles, (rsurface.modelelement3i + 3 * surface->num_firsttriangle), rsurface.modelelement3i_bufferobject, (sizeof(int[3]) * surface->num_firsttriangle));
}
+#if 0
+ Con_Printf("\n");
+#endif
}
else
{
- for (texturesurfaceindex = 0;texturesurfaceindex < texturenumsurfaces;texturesurfaceindex++)
+ for (i = 0;i < texturenumsurfaces;i++)
{
- surface = texturesurfacelist[texturesurfaceindex];
+ surface = texturesurfacelist[i];
+ R_Mesh_TexBind(lightmaptexunit, R_GetTexture(surface->lightmaptexture));
+ if (deluxemaptexunit >= 0)
+ R_Mesh_TexBind(deluxemaptexunit, R_GetTexture(surface->deluxemaptexture));
GL_LockArrays(surface->num_firstvertex, surface->num_vertices);
- R_Mesh_Draw(surface->num_firstvertex, surface->num_vertices, surface->num_triangles, (rsurface_model->surfmesh.data_element3i + 3 * surface->num_firsttriangle));
+ R_Mesh_Draw(surface->num_firstvertex, surface->num_vertices, surface->num_triangles, (rsurface.modelelement3i + 3 * surface->num_firsttriangle), rsurface.modelelement3i_bufferobject, (sizeof(int[3]) * surface->num_firsttriangle));
}
}
}
{
float f = ((j + surface->num_firsttriangle) & 31) * (1.0f / 31.0f) * r_view.colorscale;
GL_Color(f, f, f, 1);
- R_Mesh_Draw(surface->num_firstvertex, surface->num_vertices, 1, (rsurface_model->surfmesh.data_element3i + 3 * (j + surface->num_firsttriangle)));
+ R_Mesh_Draw(surface->num_firstvertex, surface->num_vertices, 1, (rsurface.modelelement3i + 3 * (j + surface->num_firsttriangle)), rsurface.modelelement3i_bufferobject, (sizeof(int[3]) * (j + surface->num_firsttriangle)));
}
}
}
int k = (int)(((size_t)surface) / sizeof(msurface_t));
GL_Color((k & 15) * (1.0f / 16.0f) * r_view.colorscale, ((k >> 4) & 15) * (1.0f / 16.0f) * r_view.colorscale, ((k >> 8) & 15) * (1.0f / 16.0f) * r_view.colorscale, 1);
GL_LockArrays(surface->num_firstvertex, surface->num_vertices);
- R_Mesh_Draw(surface->num_firstvertex, surface->num_vertices, surface->num_triangles, (rsurface_model->surfmesh.data_element3i + 3 * surface->num_firsttriangle));
+ R_Mesh_Draw(surface->num_firstvertex, surface->num_vertices, surface->num_triangles, (rsurface.modelelement3i + 3 * surface->num_firsttriangle), rsurface.modelelement3i_bufferobject, (sizeof(int[3]) * surface->num_firsttriangle));
}
}
}
-static void RSurf_DrawBatch_Lightmap(int texturenumsurfaces, msurface_t **texturesurfacelist, float r, float g, float b, float a, int lightmode, qboolean applycolor, qboolean applyfog)
+static void RSurf_DrawBatch_GL11_ApplyFog(int texturenumsurfaces, msurface_t **texturesurfacelist)
{
int texturesurfaceindex;
int i;
float f;
float *v, *c, *c2;
- // TODO: optimize
- if (lightmode >= 2)
- {
- // model lighting
- vec3_t ambientcolor;
- vec3_t diffusecolor;
- vec3_t lightdir;
- VectorCopy(rsurface_entity->modellight_lightdir, lightdir);
- ambientcolor[0] = rsurface_entity->modellight_ambient[0] * r * 0.5f;
- ambientcolor[1] = rsurface_entity->modellight_ambient[1] * g * 0.5f;
- ambientcolor[2] = rsurface_entity->modellight_ambient[2] * b * 0.5f;
- diffusecolor[0] = rsurface_entity->modellight_diffuse[0] * r * 0.5f;
- diffusecolor[1] = rsurface_entity->modellight_diffuse[1] * g * 0.5f;
- diffusecolor[2] = rsurface_entity->modellight_diffuse[2] * b * 0.5f;
- if (VectorLength2(diffusecolor) > 0)
- {
- // generate color arrays for the surfaces in this list
- for (texturesurfaceindex = 0;texturesurfaceindex < texturenumsurfaces;texturesurfaceindex++)
+ if (rsurface.lightmapcolor4f)
+ {
+ // generate color arrays for the surfaces in this list
+ for (texturesurfaceindex = 0;texturesurfaceindex < texturenumsurfaces;texturesurfaceindex++)
+ {
+ const msurface_t *surface = texturesurfacelist[texturesurfaceindex];
+ for (i = 0, v = (rsurface.vertex3f + 3 * surface->num_firstvertex), c = (rsurface.lightmapcolor4f + 4 * surface->num_firstvertex), c2 = (rsurface.array_color4f + 4 * surface->num_firstvertex);i < surface->num_vertices;i++, v += 3, c += 4, c2 += 4)
{
- const msurface_t *surface = texturesurfacelist[texturesurfaceindex];
- int numverts = surface->num_vertices;
- v = rsurface_vertex3f + 3 * surface->num_firstvertex;
- c2 = rsurface_normal3f + 3 * surface->num_firstvertex;
- c = rsurface_array_color4f + 4 * surface->num_firstvertex;
- // q3-style directional shading
- for (i = 0;i < numverts;i++, v += 3, c2 += 3, c += 4)
- {
- if ((f = DotProduct(c2, lightdir)) > 0)
- VectorMA(ambientcolor, f, diffusecolor, c);
- else
- VectorCopy(ambientcolor, c);
- c[3] = a;
- }
+ f = FogPoint_Model(v);
+ c2[0] = c[0] * f;
+ c2[1] = c[1] * f;
+ c2[2] = c[2] * f;
+ c2[3] = c[3];
}
- r = 1;
- g = 1;
- b = 1;
- a = 1;
- applycolor = false;
- rsurface_lightmapcolor4f = rsurface_array_color4f;
}
- else
+ }
+ else
+ {
+ for (texturesurfaceindex = 0;texturesurfaceindex < texturenumsurfaces;texturesurfaceindex++)
{
- r = ambientcolor[0];
- g = ambientcolor[1];
- b = ambientcolor[2];
- rsurface_lightmapcolor4f = NULL;
+ const msurface_t *surface = texturesurfacelist[texturesurfaceindex];
+ for (i = 0, v = (rsurface.vertex3f + 3 * surface->num_firstvertex), c2 = (rsurface.array_color4f + 4 * surface->num_firstvertex);i < surface->num_vertices;i++, v += 3, c2 += 4)
+ {
+ f = FogPoint_Model(v);
+ c2[0] = f;
+ c2[1] = f;
+ c2[2] = f;
+ c2[3] = 1;
+ }
}
}
- else if (lightmode >= 1 || !rsurface_lightmaptexture)
+ rsurface.lightmapcolor4f = rsurface.array_color4f;
+ rsurface.lightmapcolor4f_bufferobject = 0;
+ rsurface.lightmapcolor4f_bufferoffset = 0;
+}
+
+static void RSurf_DrawBatch_GL11_ApplyColor(int texturenumsurfaces, msurface_t **texturesurfacelist, float r, float g, float b, float a)
+{
+ int texturesurfaceindex;
+ int i;
+ float *c, *c2;
+ if (!rsurface.lightmapcolor4f)
+ return;
+ for (texturesurfaceindex = 0;texturesurfaceindex < texturenumsurfaces;texturesurfaceindex++)
{
- if (texturesurfacelist[0]->lightmapinfo && texturesurfacelist[0]->lightmapinfo->stainsamples)
+ const msurface_t *surface = texturesurfacelist[texturesurfaceindex];
+ for (i = 0, c = (rsurface.lightmapcolor4f + 4 * surface->num_firstvertex), c2 = (rsurface.array_color4f + 4 * surface->num_firstvertex);i < surface->num_vertices;i++, c += 4, c2 += 4)
{
- // generate color arrays for the surfaces in this list
- for (texturesurfaceindex = 0;texturesurfaceindex < texturenumsurfaces;texturesurfaceindex++)
+ c2[0] = c[0] * r;
+ c2[1] = c[1] * g;
+ c2[2] = c[2] * b;
+ c2[3] = c[3] * a;
+ }
+ }
+ rsurface.lightmapcolor4f = rsurface.array_color4f;
+ rsurface.lightmapcolor4f_bufferobject = 0;
+ rsurface.lightmapcolor4f_bufferoffset = 0;
+}
+
+static void RSurf_DrawBatch_GL11_Lightmap(int texturenumsurfaces, msurface_t **texturesurfacelist, float r, float g, float b, float a, qboolean applycolor, qboolean applyfog)
+{
+ // TODO: optimize
+ rsurface.lightmapcolor4f = NULL;
+ rsurface.lightmapcolor4f_bufferobject = 0;
+ rsurface.lightmapcolor4f_bufferoffset = 0;
+ if (applyfog) RSurf_DrawBatch_GL11_ApplyFog(texturenumsurfaces, texturesurfacelist);
+ if (applycolor) RSurf_DrawBatch_GL11_ApplyColor(texturenumsurfaces, texturesurfacelist, r, g, b, a);
+ R_Mesh_ColorPointer(rsurface.lightmapcolor4f, rsurface.lightmapcolor4f_bufferobject, rsurface.lightmapcolor4f_bufferoffset);
+ GL_Color(r, g, b, a);
+ RSurf_DrawBatch_WithLightmapSwitching(texturenumsurfaces, texturesurfacelist, 0, -1);
+}
+
+static void RSurf_DrawBatch_GL11_Unlit(int texturenumsurfaces, msurface_t **texturesurfacelist, float r, float g, float b, float a, qboolean applycolor, qboolean applyfog)
+{
+ // TODO: optimize applyfog && applycolor case
+ // just apply fog if necessary, and tint the fog color array if necessary
+ rsurface.lightmapcolor4f = NULL;
+ rsurface.lightmapcolor4f_bufferobject = 0;
+ rsurface.lightmapcolor4f_bufferoffset = 0;
+ if (applyfog) RSurf_DrawBatch_GL11_ApplyFog(texturenumsurfaces, texturesurfacelist);
+ if (applycolor) RSurf_DrawBatch_GL11_ApplyColor(texturenumsurfaces, texturesurfacelist, r, g, b, a);
+ R_Mesh_ColorPointer(rsurface.lightmapcolor4f, rsurface.lightmapcolor4f_bufferobject, rsurface.lightmapcolor4f_bufferoffset);
+ GL_Color(r, g, b, a);
+ RSurf_DrawBatch_Simple(texturenumsurfaces, texturesurfacelist);
+}
+
+static void RSurf_DrawBatch_GL11_VertexColor(int texturenumsurfaces, msurface_t **texturesurfacelist, float r, float g, float b, float a, qboolean applycolor, qboolean applyfog)
+{
+ int texturesurfaceindex;
+ int i;
+ float *c;
+ // TODO: optimize
+ if (texturesurfacelist[0]->lightmapinfo && texturesurfacelist[0]->lightmapinfo->stainsamples)
+ {
+ // generate color arrays for the surfaces in this list
+ for (texturesurfaceindex = 0;texturesurfaceindex < texturenumsurfaces;texturesurfaceindex++)
+ {
+ const msurface_t *surface = texturesurfacelist[texturesurfaceindex];
+ for (i = 0, c = rsurface.array_color4f + 4 * surface->num_firstvertex;i < surface->num_vertices;i++, c += 4)
{
- const msurface_t *surface = texturesurfacelist[texturesurfaceindex];
- for (i = 0, c = rsurface_array_color4f + 4 * surface->num_firstvertex;i < surface->num_vertices;i++, c += 4)
+ if (surface->lightmapinfo->samples)
{
- if (surface->lightmapinfo->samples)
+ const unsigned char *lm = surface->lightmapinfo->samples + (rsurface.modellightmapoffsets + surface->num_firstvertex)[i];
+ float scale = r_refdef.lightstylevalue[surface->lightmapinfo->styles[0]] * (1.0f / 32768.0f);
+ VectorScale(lm, scale, c);
+ if (surface->lightmapinfo->styles[1] != 255)
{
- const unsigned char *lm = surface->lightmapinfo->samples + (rsurface_model->surfmesh.data_lightmapoffsets + surface->num_firstvertex)[i];
- float scale = r_refdef.lightstylevalue[surface->lightmapinfo->styles[0]] * (1.0f / 32768.0f);
- VectorScale(lm, scale, c);
- if (surface->lightmapinfo->styles[1] != 255)
+ int size3 = ((surface->lightmapinfo->extents[0]>>4)+1)*((surface->lightmapinfo->extents[1]>>4)+1)*3;
+ lm += size3;
+ scale = r_refdef.lightstylevalue[surface->lightmapinfo->styles[1]] * (1.0f / 32768.0f);
+ VectorMA(c, scale, lm, c);
+ if (surface->lightmapinfo->styles[2] != 255)
{
- int size3 = ((surface->lightmapinfo->extents[0]>>4)+1)*((surface->lightmapinfo->extents[1]>>4)+1)*3;
lm += size3;
- scale = r_refdef.lightstylevalue[surface->lightmapinfo->styles[1]] * (1.0f / 32768.0f);
+ scale = r_refdef.lightstylevalue[surface->lightmapinfo->styles[2]] * (1.0f / 32768.0f);
VectorMA(c, scale, lm, c);
- if (surface->lightmapinfo->styles[2] != 255)
+ if (surface->lightmapinfo->styles[3] != 255)
{
lm += size3;
- scale = r_refdef.lightstylevalue[surface->lightmapinfo->styles[2]] * (1.0f / 32768.0f);
+ scale = r_refdef.lightstylevalue[surface->lightmapinfo->styles[3]] * (1.0f / 32768.0f);
VectorMA(c, scale, lm, c);
- if (surface->lightmapinfo->styles[3] != 255)
- {
- lm += size3;
- scale = r_refdef.lightstylevalue[surface->lightmapinfo->styles[3]] * (1.0f / 32768.0f);
- VectorMA(c, scale, lm, c);
- }
}
}
}
- else
- VectorClear(c);
- c[3] = 1;
}
+ else
+ VectorClear(c);
+ c[3] = 1;
}
- rsurface_lightmapcolor4f = rsurface_array_color4f;
}
- else
- rsurface_lightmapcolor4f = rsurface_model->surfmesh.data_lightmapcolor4f;
+ rsurface.lightmapcolor4f = rsurface.array_color4f;
+ rsurface.lightmapcolor4f_bufferobject = 0;
+ rsurface.lightmapcolor4f_bufferoffset = 0;
}
else
{
- // just lightmap it
- rsurface_lightmapcolor4f = NULL;
- }
- if (applyfog)
- {
- if (rsurface_lightmapcolor4f)
- {
- // generate color arrays for the surfaces in this list
- for (texturesurfaceindex = 0;texturesurfaceindex < texturenumsurfaces;texturesurfaceindex++)
- {
- const msurface_t *surface = texturesurfacelist[texturesurfaceindex];
- for (i = 0, v = (rsurface_vertex3f + 3 * surface->num_firstvertex), c = (rsurface_lightmapcolor4f + 4 * surface->num_firstvertex), c2 = (rsurface_array_color4f + 4 * surface->num_firstvertex);i < surface->num_vertices;i++, v += 3, c += 4, c2 += 4)
- {
- f = 1 - VERTEXFOGTABLE(VectorDistance(v, rsurface_modelorg));
- c2[0] = c[0] * f;
- c2[1] = c[1] * f;
- c2[2] = c[2] * f;
- c2[3] = c[3];
- }
- }
- }
- else
- {
- for (texturesurfaceindex = 0;texturesurfaceindex < texturenumsurfaces;texturesurfaceindex++)
- {
- const msurface_t *surface = texturesurfacelist[texturesurfaceindex];
- for (i = 0, v = (rsurface_vertex3f + 3 * surface->num_firstvertex), c2 = (rsurface_array_color4f + 4 * surface->num_firstvertex);i < surface->num_vertices;i++, v += 3, c2 += 4)
- {
- f = 1 - VERTEXFOGTABLE(VectorDistance(v, rsurface_modelorg));
- c2[0] = f;
- c2[1] = f;
- c2[2] = f;
- c2[3] = 1;
- }
- }
- }
- rsurface_lightmapcolor4f = rsurface_array_color4f;
+ rsurface.lightmapcolor4f = rsurface.modellightmapcolor4f;
+ rsurface.lightmapcolor4f_bufferobject = rsurface.modellightmapcolor4f_bufferobject;
+ rsurface.lightmapcolor4f_bufferoffset = rsurface.modellightmapcolor4f_bufferoffset;
}
- if (applycolor && rsurface_lightmapcolor4f)
+ if (applyfog) RSurf_DrawBatch_GL11_ApplyFog(texturenumsurfaces, texturesurfacelist);
+ if (applycolor) RSurf_DrawBatch_GL11_ApplyColor(texturenumsurfaces, texturesurfacelist, r, g, b, a);
+ R_Mesh_ColorPointer(rsurface.lightmapcolor4f, rsurface.lightmapcolor4f_bufferobject, rsurface.lightmapcolor4f_bufferoffset);
+ GL_Color(r, g, b, a);
+ RSurf_DrawBatch_Simple(texturenumsurfaces, texturesurfacelist);
+}
+
+static void RSurf_DrawBatch_GL11_VertexShade(int texturenumsurfaces, msurface_t **texturesurfacelist, float r, float g, float b, float a, qboolean applycolor, qboolean applyfog)
+{
+ int texturesurfaceindex;
+ int i;
+ float f;
+ float *v, *c, *c2;
+ vec3_t ambientcolor;
+ vec3_t diffusecolor;
+ vec3_t lightdir;
+ // TODO: optimize
+ // model lighting
+ VectorCopy(rsurface.modellight_lightdir, lightdir);
+ ambientcolor[0] = rsurface.modellight_ambient[0] * r * 0.5f;
+ ambientcolor[1] = rsurface.modellight_ambient[1] * g * 0.5f;
+ ambientcolor[2] = rsurface.modellight_ambient[2] * b * 0.5f;
+ diffusecolor[0] = rsurface.modellight_diffuse[0] * r * 0.5f;
+ diffusecolor[1] = rsurface.modellight_diffuse[1] * g * 0.5f;
+ diffusecolor[2] = rsurface.modellight_diffuse[2] * b * 0.5f;
+ if (VectorLength2(diffusecolor) > 0)
{
+ // generate color arrays for the surfaces in this list
for (texturesurfaceindex = 0;texturesurfaceindex < texturenumsurfaces;texturesurfaceindex++)
{
const msurface_t *surface = texturesurfacelist[texturesurfaceindex];
- for (i = 0, c = (rsurface_lightmapcolor4f + 4 * surface->num_firstvertex), c2 = (rsurface_array_color4f + 4 * surface->num_firstvertex);i < surface->num_vertices;i++, c += 4, c2 += 4)
+ int numverts = surface->num_vertices;
+ v = rsurface.vertex3f + 3 * surface->num_firstvertex;
+ c2 = rsurface.normal3f + 3 * surface->num_firstvertex;
+ c = rsurface.array_color4f + 4 * surface->num_firstvertex;
+ // q3-style directional shading
+ for (i = 0;i < numverts;i++, v += 3, c2 += 3, c += 4)
{
- c2[0] = c[0] * r;
- c2[1] = c[1] * g;
- c2[2] = c[2] * b;
- c2[3] = c[3] * a;
+ if ((f = DotProduct(c2, lightdir)) > 0)
+ VectorMA(ambientcolor, f, diffusecolor, c);
+ else
+ VectorCopy(ambientcolor, c);
+ c[3] = a;
}
}
- rsurface_lightmapcolor4f = rsurface_array_color4f;
+ r = 1;
+ g = 1;
+ b = 1;
+ a = 1;
+ applycolor = false;
+ rsurface.lightmapcolor4f = rsurface.array_color4f;
+ rsurface.lightmapcolor4f_bufferobject = 0;
+ rsurface.lightmapcolor4f_bufferoffset = 0;
+ }
+ else
+ {
+ r = ambientcolor[0];
+ g = ambientcolor[1];
+ b = ambientcolor[2];
+ rsurface.lightmapcolor4f = NULL;
+ rsurface.lightmapcolor4f_bufferobject = 0;
+ rsurface.lightmapcolor4f_bufferoffset = 0;
}
- R_Mesh_ColorPointer(rsurface_lightmapcolor4f);
+ if (applyfog) RSurf_DrawBatch_GL11_ApplyFog(texturenumsurfaces, texturesurfacelist);
+ if (applycolor) RSurf_DrawBatch_GL11_ApplyColor(texturenumsurfaces, texturesurfacelist, r, g, b, a);
+ R_Mesh_ColorPointer(rsurface.lightmapcolor4f, rsurface.lightmapcolor4f_bufferobject, rsurface.lightmapcolor4f_bufferoffset);
GL_Color(r, g, b, a);
RSurf_DrawBatch_Simple(texturenumsurfaces, texturesurfacelist);
}
static void R_DrawTextureSurfaceList_ShowSurfaces(int texturenumsurfaces, msurface_t **texturesurfacelist)
{
- GL_DepthTest(!(rsurface_texture->currentmaterialflags & MATERIALFLAG_NODEPTHTEST));
- GL_CullFace(((rsurface_texture->textureflags & Q3TEXTUREFLAG_TWOSIDED) || (rsurface_entity->flags & RENDER_NOCULLFACE)) ? GL_NONE : GL_FRONT); // quake is backwards, this culls back faces
- if (rsurface_mode != RSURFMODE_SHOWSURFACES)
+ GL_DepthRange(0, (rsurface.texture->currentmaterialflags & MATERIALFLAG_SHORTDEPTHRANGE) ? 0.0625 : 1);
+ GL_PolygonOffset(rsurface.texture->currentpolygonfactor, rsurface.texture->currentpolygonoffset);
+ GL_DepthTest(!(rsurface.texture->currentmaterialflags & MATERIALFLAG_NODEPTHTEST));
+ GL_CullFace((rsurface.texture->currentmaterialflags & MATERIALFLAG_NOCULLFACE) ? GL_NONE : r_view.cullface_back);
+ if (rsurface.mode != RSURFMODE_SHOWSURFACES)
{
- rsurface_mode = RSURFMODE_SHOWSURFACES;
+ rsurface.mode = RSURFMODE_SHOWSURFACES;
GL_DepthMask(true);
GL_BlendFunc(GL_ONE, GL_ZERO);
- R_Mesh_ColorPointer(NULL);
+ R_Mesh_ColorPointer(NULL, 0, 0);
R_Mesh_ResetTextureState();
}
RSurf_PrepareVerticesForBatch(false, false, texturenumsurfaces, texturesurfacelist);
static void R_DrawTextureSurfaceList_Sky(int texturenumsurfaces, msurface_t **texturesurfacelist)
{
// transparent sky would be ridiculous
- if ((rsurface_texture->currentmaterialflags & MATERIALFLAG_TRANSPARENT))
+ if ((rsurface.texture->currentmaterialflags & MATERIALFLAGMASK_DEPTHSORTED))
return;
- if (rsurface_mode != RSURFMODE_SKY)
+ if (rsurface.mode != RSURFMODE_SKY)
{
- if (rsurface_mode == RSURFMODE_GLSL)
+ if (rsurface.mode == RSURFMODE_GLSL)
{
qglUseProgramObjectARB(0);CHECKGLERROR
}
- rsurface_mode = RSURFMODE_SKY;
+ rsurface.mode = RSURFMODE_SKY;
}
if (skyrendernow)
{
skyrendernow = false;
R_Sky();
// restore entity matrix
- R_Mesh_Matrix(&rsurface_entity->matrix);
+ R_Mesh_Matrix(&rsurface.matrix);
}
- GL_DepthTest(!(rsurface_texture->currentmaterialflags & MATERIALFLAG_NODEPTHTEST));
- GL_CullFace(((rsurface_texture->textureflags & Q3TEXTUREFLAG_TWOSIDED) || (rsurface_entity->flags & RENDER_NOCULLFACE)) ? GL_NONE : GL_FRONT); // quake is backwards, this culls back faces
+ GL_DepthRange(0, (rsurface.texture->currentmaterialflags & MATERIALFLAG_SHORTDEPTHRANGE) ? 0.0625 : 1);
+ GL_PolygonOffset(rsurface.texture->currentpolygonfactor, rsurface.texture->currentpolygonoffset);
+ GL_DepthTest(!(rsurface.texture->currentmaterialflags & MATERIALFLAG_NODEPTHTEST));
+ GL_CullFace((rsurface.texture->currentmaterialflags & MATERIALFLAG_NOCULLFACE) ? GL_NONE : r_view.cullface_back);
GL_DepthMask(true);
// LordHavoc: HalfLife maps have freaky skypolys so don't use
// skymasking on them, and Quake3 never did sky masking (unlike
// in Quake3 maps as it causes problems with q3map2 sky tricks,
// and skymasking also looks very bad when noclipping outside the
// level, so don't use it then either.
- if (rsurface_model->type == mod_brushq1 && r_q1bsp_skymasking.integer && !r_viewcache.world_novis)
+ if (r_refdef.worldmodel && r_refdef.worldmodel->type == mod_brushq1 && r_q1bsp_skymasking.integer && !r_viewcache.world_novis)
{
GL_Color(r_refdef.fogcolor[0] * r_view.colorscale, r_refdef.fogcolor[1] * r_view.colorscale, r_refdef.fogcolor[2] * r_view.colorscale, 1);
- R_Mesh_ColorPointer(NULL);
+ R_Mesh_ColorPointer(NULL, 0, 0);
R_Mesh_ResetTextureState();
if (skyrendermasked)
{
static void R_DrawTextureSurfaceList_GL20(int texturenumsurfaces, msurface_t **texturesurfacelist)
{
- if (rsurface_mode != RSURFMODE_GLSL)
+ if (r_waterstate.renderingscene && (rsurface.texture->currentmaterialflags & (MATERIALFLAG_WATERSHADER | MATERIALFLAG_REFRACTION | MATERIALFLAG_REFLECTION)))
+ return;
+
+ if (rsurface.mode != RSURFMODE_GLSL)
{
- rsurface_mode = RSURFMODE_GLSL;
- rsurface_glsl_texture = NULL;
- rsurface_glsl_uselightmap = false;
+ rsurface.mode = RSURFMODE_GLSL;
R_Mesh_ResetTextureState();
}
- if (rsurface_glsl_texture != rsurface_texture || rsurface_glsl_uselightmap != (rsurface_lightmaptexture != NULL))
- {
- int lightmode;
- rsurface_glsl_texture = rsurface_texture;
- rsurface_glsl_uselightmap = rsurface_lightmaptexture != NULL && !(rsurface_texture->currentmaterialflags & MATERIALFLAG_FULLBRIGHT);
- GL_DepthTest(!(rsurface_texture->currentmaterialflags & MATERIALFLAG_NODEPTHTEST));
- GL_CullFace(((rsurface_texture->textureflags & Q3TEXTUREFLAG_TWOSIDED) || (rsurface_entity->flags & RENDER_NOCULLFACE)) ? GL_NONE : GL_FRONT); // quake is backwards, this culls back faces
- GL_BlendFunc(rsurface_texture->currentlayers[0].blendfunc1, rsurface_texture->currentlayers[0].blendfunc2);
- GL_DepthMask(!(rsurface_texture->currentmaterialflags & MATERIALFLAG_BLENDED));
- GL_Color(rsurface_entity->colormod[0], rsurface_entity->colormod[1], rsurface_entity->colormod[2], rsurface_texture->currentalpha);
- // FIXME: identify models using a better check than rsurface_model->brush.shadowmesh
- lightmode = ((rsurface_entity->effects & EF_FULLBRIGHT) || rsurface_model->brush.shadowmesh) ? 0 : 2;
- R_SetupSurfaceShader(vec3_origin, lightmode == 2);
- //permutation_deluxemapping = permutation_lightmapping = R_SetupSurfaceShader(vec3_origin, lightmode == 2, false);
- //if (r_glsl_deluxemapping.integer)
- // permutation_deluxemapping = R_SetupSurfaceShader(vec3_origin, lightmode == 2, true);
- R_Mesh_TexCoordPointer(0, 2, rsurface_model->surfmesh.data_texcoordtexture2f);
- R_Mesh_TexCoordPointer(4, 2, rsurface_model->surfmesh.data_texcoordlightmap2f);
- GL_AlphaTest((rsurface_texture->currentmaterialflags & MATERIALFLAG_ALPHATEST) != 0);
- RSurf_PrepareVerticesForBatch(true, true, texturenumsurfaces, texturesurfacelist);
- R_Mesh_TexCoordPointer(1, 3, rsurface_svector3f);
- R_Mesh_TexCoordPointer(2, 3, rsurface_tvector3f);
- R_Mesh_TexCoordPointer(3, 3, rsurface_normal3f);
- if (rsurface_texture->currentmaterialflags & MATERIALFLAG_FULLBRIGHT)
- {
- R_Mesh_TexBind(7, R_GetTexture(r_texture_white));
- if (r_glsl_permutation->loc_Texture_Deluxemap >= 0)
- R_Mesh_TexBind(8, R_GetTexture(r_texture_blanknormalmap));
- R_Mesh_ColorPointer(NULL);
- }
- else if (rsurface_lightmaptexture)
- {
- R_Mesh_TexBind(7, R_GetTexture(rsurface_lightmaptexture));
- if (r_glsl_permutation->loc_Texture_Deluxemap >= 0)
- R_Mesh_TexBind(8, R_GetTexture(texturesurfacelist[0]->deluxemaptexture));
- R_Mesh_ColorPointer(NULL);
- }
- else
- {
- R_Mesh_TexBind(7, R_GetTexture(r_texture_white));
- if (r_glsl_permutation->loc_Texture_Deluxemap >= 0)
- R_Mesh_TexBind(8, R_GetTexture(r_texture_blanknormalmap));
- R_Mesh_ColorPointer(rsurface_model->surfmesh.data_lightmapcolor4f);
- }
+
+ R_Mesh_TexMatrix(0, &rsurface.texture->currenttexmatrix);
+ R_Mesh_TexBind(0, R_GetTexture(rsurface.texture->currentskinframe->nmap));
+ R_Mesh_TexBind(1, R_GetTexture(rsurface.texture->basetexture));
+ R_Mesh_TexBind(2, R_GetTexture(rsurface.texture->glosstexture));
+ R_Mesh_TexBind(4, R_GetTexture(r_texture_fogattenuation));
+ R_Mesh_TexBind(5, R_GetTexture(rsurface.texture->currentskinframe->pants));
+ R_Mesh_TexBind(6, R_GetTexture(rsurface.texture->currentskinframe->shirt));
+ if (rsurface.texture->currentmaterialflags & MATERIALFLAG_FULLBRIGHT)
+ {
+ R_Mesh_TexBind(7, R_GetTexture(r_texture_grey128));
+ R_Mesh_TexBind(8, R_GetTexture(r_texture_blanknormalmap));
+ R_Mesh_ColorPointer(NULL, 0, 0);
}
- else
- RSurf_PrepareVerticesForBatch(true, true, texturenumsurfaces, texturesurfacelist);
- if (!r_glsl_permutation)
- return;
- if (rsurface_glsl_uselightmap)
+ else if (rsurface.uselightmaptexture)
{
- R_Mesh_TexBind(7, R_GetTexture(rsurface_lightmaptexture));
- if (r_glsl_permutation->loc_Texture_Deluxemap >= 0)
- R_Mesh_TexBind(8, R_GetTexture(texturesurfacelist[0]->deluxemaptexture));
+ R_Mesh_TexBind(7, R_GetTexture(texturesurfacelist[0]->lightmaptexture));
+ R_Mesh_TexBind(8, R_GetTexture(texturesurfacelist[0]->deluxemaptexture));
+ R_Mesh_ColorPointer(NULL, 0, 0);
}
- RSurf_DrawBatch_Simple(texturenumsurfaces, texturesurfacelist);
- if (rsurface_texture->backgroundnumskinframes && !(rsurface_texture->currentmaterialflags & MATERIALFLAG_TRANSPARENT))
+ else
{
+ R_Mesh_TexBind(7, R_GetTexture(r_texture_white));
+ R_Mesh_TexBind(8, R_GetTexture(r_texture_blanknormalmap));
+ R_Mesh_ColorPointer(rsurface.modellightmapcolor4f, rsurface.modellightmapcolor4f_bufferobject, rsurface.modellightmapcolor4f_bufferoffset);
}
-}
+ R_Mesh_TexBind(9, R_GetTexture(rsurface.texture->currentskinframe->glow));
+ R_Mesh_TexBind(11, R_GetTexture(r_texture_white)); // changed per surface
+ R_Mesh_TexBind(12, R_GetTexture(r_texture_white)); // changed per surface
-static void R_DrawTextureSurfaceList_GL13(int texturenumsurfaces, msurface_t **texturesurfacelist)
-{
+ if (rsurface.texture->currentmaterialflags & (MATERIALFLAG_WATERSHADER | MATERIALFLAG_REFRACTION))
+ {
+ // render background
+ GL_BlendFunc(GL_ONE, GL_ZERO);
+ GL_DepthMask(true);
+ GL_AlphaTest(false);
+
+ GL_Color(1, 1, 1, 1);
+ R_Mesh_ColorPointer(NULL, 0, 0);
+
+ R_SetupSurfaceShader(vec3_origin, rsurface.texture->currentmaterialflags & MATERIALFLAG_MODELLIGHT, 1, 1, rsurface.texture->specularscale, RSURFPASS_BACKGROUND);
+ if (r_glsl_permutation)
+ {
+ RSurf_PrepareVerticesForBatch(true, true, texturenumsurfaces, texturesurfacelist);
+ R_Mesh_TexCoordPointer(0, 2, rsurface.texcoordtexture2f, rsurface.texcoordtexture2f_bufferobject, rsurface.texcoordtexture2f_bufferoffset);
+ R_Mesh_TexCoordPointer(1, 3, rsurface.svector3f, rsurface.svector3f_bufferobject, rsurface.svector3f_bufferoffset);
+ R_Mesh_TexCoordPointer(2, 3, rsurface.tvector3f, rsurface.tvector3f_bufferobject, rsurface.tvector3f_bufferoffset);
+ R_Mesh_TexCoordPointer(3, 3, rsurface.normal3f, rsurface.normal3f_bufferobject, rsurface.normal3f_bufferoffset);
+ R_Mesh_TexCoordPointer(4, 2, rsurface.modeltexcoordlightmap2f, rsurface.modeltexcoordlightmap2f_bufferobject, rsurface.modeltexcoordlightmap2f_bufferoffset);
+ RSurf_DrawBatch_WithLightmapSwitching_WithWaterTextureSwitching(texturenumsurfaces, texturesurfacelist, -1, -1, r_glsl_permutation->loc_Texture_Refraction ? 11 : -1, r_glsl_permutation->loc_Texture_Reflection ? 12 : -1);
+ }
+
+ GL_BlendFunc(rsurface.texture->currentlayers[0].blendfunc1, rsurface.texture->currentlayers[0].blendfunc2);
+ GL_DepthMask(false);
+ GL_AlphaTest((rsurface.texture->currentmaterialflags & MATERIALFLAG_ALPHATEST) != 0);
+ if (rsurface.texture->currentmaterialflags & MATERIALFLAG_FULLBRIGHT)
+ {
+ R_Mesh_TexBind(7, R_GetTexture(r_texture_grey128));
+ R_Mesh_TexBind(8, R_GetTexture(r_texture_blanknormalmap));
+ R_Mesh_ColorPointer(NULL, 0, 0);
+ }
+ else if (rsurface.uselightmaptexture)
+ {
+ R_Mesh_TexBind(7, R_GetTexture(texturesurfacelist[0]->lightmaptexture));
+ R_Mesh_TexBind(8, R_GetTexture(texturesurfacelist[0]->deluxemaptexture));
+ R_Mesh_ColorPointer(NULL, 0, 0);
+ }
+ else
+ {
+ R_Mesh_TexBind(7, R_GetTexture(r_texture_white));
+ R_Mesh_TexBind(8, R_GetTexture(r_texture_blanknormalmap));
+ R_Mesh_ColorPointer(rsurface.modellightmapcolor4f, rsurface.modellightmapcolor4f_bufferobject, rsurface.modellightmapcolor4f_bufferoffset);
+ }
+ R_Mesh_TexBind(11, R_GetTexture(r_texture_white)); // changed per surface
+ R_Mesh_TexBind(12, R_GetTexture(r_texture_white)); // changed per surface
+ }
+
+ R_SetupSurfaceShader(vec3_origin, rsurface.texture->currentmaterialflags & MATERIALFLAG_MODELLIGHT, 1, 1, rsurface.texture->specularscale, RSURFPASS_BASE);
+ if (!r_glsl_permutation)
+ return;
+
+ RSurf_PrepareVerticesForBatch(r_glsl_permutation->loc_Texture_Normal >= 0 || r_glsl_permutation->loc_LightDir >= 0, r_glsl_permutation->loc_Texture_Normal >= 0, texturenumsurfaces, texturesurfacelist);
+ R_Mesh_TexCoordPointer(0, 2, rsurface.texcoordtexture2f, rsurface.texcoordtexture2f_bufferobject, rsurface.texcoordtexture2f_bufferoffset);
+ R_Mesh_TexCoordPointer(1, 3, rsurface.svector3f, rsurface.svector3f_bufferobject, rsurface.svector3f_bufferoffset);
+ R_Mesh_TexCoordPointer(2, 3, rsurface.tvector3f, rsurface.tvector3f_bufferobject, rsurface.tvector3f_bufferoffset);
+ R_Mesh_TexCoordPointer(3, 3, rsurface.normal3f, rsurface.normal3f_bufferobject, rsurface.normal3f_bufferoffset);
+ R_Mesh_TexCoordPointer(4, 2, rsurface.modeltexcoordlightmap2f, rsurface.modeltexcoordlightmap2f_bufferobject, rsurface.modeltexcoordlightmap2f_bufferoffset);
+ GL_Color(rsurface.texture->currentlayers[0].color[0], rsurface.texture->currentlayers[0].color[1], rsurface.texture->currentlayers[0].color[2], rsurface.texture->currentlayers[0].color[3]);
+
+ if (r_glsl_permutation->loc_Texture_Refraction >= 0)
+ {
+ GL_BlendFunc(GL_ONE, GL_ZERO);
+ GL_DepthMask(true);
+ GL_AlphaTest(false);
+ }
+
+ if (rsurface.uselightmaptexture && !(rsurface.texture->currentmaterialflags & MATERIALFLAG_FULLBRIGHT))
+ {
+ if (r_glsl_permutation->loc_Texture_Refraction >= 0 || r_glsl_permutation->loc_Texture_Reflection >= 0)
+ RSurf_DrawBatch_WithLightmapSwitching_WithWaterTextureSwitching(texturenumsurfaces, texturesurfacelist, 7, r_glsl_permutation->loc_Texture_Deluxemap >= 0 ? 8 : -1, r_glsl_permutation->loc_Texture_Refraction >= 0 ? 11 : -1, r_glsl_permutation->loc_Texture_Reflection >= 0 ? 12 : -1);
+ else
+ RSurf_DrawBatch_WithLightmapSwitching(texturenumsurfaces, texturesurfacelist, 7, r_glsl_permutation->loc_Texture_Deluxemap >= 0 ? 8 : -1);
+ }
+ else
+ {
+ if (r_glsl_permutation->loc_Texture_Refraction >= 0 || r_glsl_permutation->loc_Texture_Reflection >= 0)
+ RSurf_DrawBatch_WithLightmapSwitching_WithWaterTextureSwitching(texturenumsurfaces, texturesurfacelist, -1, -1, r_glsl_permutation->loc_Texture_Refraction >= 0 ? 11 : -1, r_glsl_permutation->loc_Texture_Reflection >= 0 ? 12 : -1);
+ else
+ RSurf_DrawBatch_Simple(texturenumsurfaces, texturesurfacelist);
+ }
+ if (rsurface.texture->backgroundnumskinframes && !(rsurface.texture->currentmaterialflags & MATERIALFLAGMASK_DEPTHSORTED))
+ {
+ }
+}
+
+static void R_DrawTextureSurfaceList_GL13(int texturenumsurfaces, msurface_t **texturesurfacelist)
+{
// OpenGL 1.3 path - anything not completely ancient
int texturesurfaceindex;
- int lightmode;
qboolean applycolor;
qboolean applyfog;
rmeshstate_t m;
int layerindex;
const texturelayer_t *layer;
- CHECKGLERROR
- GL_DepthTest(!(rsurface_texture->currentmaterialflags & MATERIALFLAG_NODEPTHTEST));
- GL_CullFace(((rsurface_texture->textureflags & Q3TEXTUREFLAG_TWOSIDED) || (rsurface_entity->flags & RENDER_NOCULLFACE)) ? GL_NONE : GL_FRONT); // quake is backwards, this culls back faces
- // FIXME: identify models using a better check than rsurface_model->brush.shadowmesh
- lightmode = ((rsurface_entity->effects & EF_FULLBRIGHT) || rsurface_model->brush.shadowmesh) ? 0 : 2;
- if (rsurface_mode != RSURFMODE_MULTIPASS)
- rsurface_mode = RSURFMODE_MULTIPASS;
+ if (rsurface.mode != RSURFMODE_MULTIPASS)
+ rsurface.mode = RSURFMODE_MULTIPASS;
RSurf_PrepareVerticesForBatch(true, false, texturenumsurfaces, texturesurfacelist);
- for (layerindex = 0, layer = rsurface_texture->currentlayers;layerindex < rsurface_texture->currentnumlayers;layerindex++, layer++)
+
+ for (layerindex = 0, layer = rsurface.texture->currentlayers;layerindex < rsurface.texture->currentnumlayers;layerindex++, layer++)
{
vec4_t layercolor;
int layertexrgbscale;
- if (rsurface_texture->currentmaterialflags & MATERIALFLAG_ALPHATEST)
+ if (rsurface.texture->currentmaterialflags & MATERIALFLAG_ALPHATEST)
{
if (layerindex == 0)
GL_AlphaTest(true);
}
layercolor[3] = layer->color[3];
applycolor = layercolor[0] != 1 || layercolor[1] != 1 || layercolor[2] != 1 || layercolor[3] != 1;
- R_Mesh_ColorPointer(NULL);
+ R_Mesh_ColorPointer(NULL, 0, 0);
applyfog = (layer->flags & TEXTURELAYERFLAG_FOGDARKEN) != 0;
switch (layer->type)
{
case TEXTURELAYERTYPE_LITTEXTURE:
memset(&m, 0, sizeof(m));
- if (lightmode >= 1 || !rsurface_lightmaptexture)
- m.tex[0] = R_GetTexture(r_texture_white);
- else
- m.tex[0] = R_GetTexture(rsurface_lightmaptexture);
- m.pointer_texcoord[0] = rsurface_model->surfmesh.data_texcoordlightmap2f;
+ m.tex[0] = R_GetTexture(r_texture_white);
+ m.pointer_texcoord[0] = rsurface.modeltexcoordlightmap2f;
+ m.pointer_texcoord_bufferobject[0] = rsurface.modeltexcoordlightmap2f_bufferobject;
+ m.pointer_texcoord_bufferoffset[0] = rsurface.modeltexcoordlightmap2f_bufferoffset;
m.tex[1] = R_GetTexture(layer->texture);
m.texmatrix[1] = layer->texmatrix;
m.texrgbscale[1] = layertexrgbscale;
- m.pointer_texcoord[1] = rsurface_model->surfmesh.data_texcoordtexture2f;
+ m.pointer_texcoord[1] = rsurface.texcoordtexture2f;
+ m.pointer_texcoord_bufferobject[1] = rsurface.texcoordtexture2f_bufferobject;
+ m.pointer_texcoord_bufferoffset[1] = rsurface.texcoordtexture2f_bufferoffset;
R_Mesh_TextureState(&m);
- RSurf_DrawBatch_Lightmap(texturenumsurfaces, texturesurfacelist, layercolor[0], layercolor[1], layercolor[2], layercolor[3], lightmode, applycolor, applyfog);
+ if (rsurface.texture->currentmaterialflags & MATERIALFLAG_MODELLIGHT)
+ RSurf_DrawBatch_GL11_VertexShade(texturenumsurfaces, texturesurfacelist, layercolor[0], layercolor[1], layercolor[2], layercolor[3], applycolor, applyfog);
+ else if (rsurface.uselightmaptexture)
+ RSurf_DrawBatch_GL11_Lightmap(texturenumsurfaces, texturesurfacelist, layercolor[0], layercolor[1], layercolor[2], layercolor[3], applycolor, applyfog);
+ else
+ RSurf_DrawBatch_GL11_VertexColor(texturenumsurfaces, texturesurfacelist, layercolor[0], layercolor[1], layercolor[2], layercolor[3], applycolor, applyfog);
break;
case TEXTURELAYERTYPE_TEXTURE:
memset(&m, 0, sizeof(m));
m.tex[0] = R_GetTexture(layer->texture);
m.texmatrix[0] = layer->texmatrix;
m.texrgbscale[0] = layertexrgbscale;
- m.pointer_texcoord[0] = rsurface_model->surfmesh.data_texcoordtexture2f;
+ m.pointer_texcoord[0] = rsurface.texcoordtexture2f;
+ m.pointer_texcoord_bufferobject[0] = rsurface.texcoordtexture2f_bufferobject;
+ m.pointer_texcoord_bufferoffset[0] = rsurface.texcoordtexture2f_bufferoffset;
R_Mesh_TextureState(&m);
- RSurf_DrawBatch_Lightmap(texturenumsurfaces, texturesurfacelist, layercolor[0], layercolor[1], layercolor[2], layercolor[3], 0, applycolor, applyfog);
+ RSurf_DrawBatch_GL11_Unlit(texturenumsurfaces, texturesurfacelist, layercolor[0], layercolor[1], layercolor[2], layercolor[3], applycolor, applyfog);
break;
case TEXTURELAYERTYPE_FOG:
memset(&m, 0, sizeof(m));
{
m.tex[0] = R_GetTexture(layer->texture);
m.texmatrix[0] = layer->texmatrix;
- m.pointer_texcoord[0] = rsurface_model->surfmesh.data_texcoordtexture2f;
+ m.pointer_texcoord[0] = rsurface.texcoordtexture2f;
+ m.pointer_texcoord_bufferobject[0] = rsurface.texcoordtexture2f_bufferobject;
+ m.pointer_texcoord_bufferoffset[0] = rsurface.texcoordtexture2f_bufferoffset;
}
R_Mesh_TextureState(&m);
// generate a color array for the fog pass
- R_Mesh_ColorPointer(rsurface_array_color4f);
+ R_Mesh_ColorPointer(rsurface.array_color4f, 0, 0);
for (texturesurfaceindex = 0;texturesurfaceindex < texturenumsurfaces;texturesurfaceindex++)
{
int i;
float f, *v, *c;
const msurface_t *surface = texturesurfacelist[texturesurfaceindex];
- for (i = 0, v = (rsurface_vertex3f + 3 * surface->num_firstvertex), c = (rsurface_array_color4f + 4 * surface->num_firstvertex);i < surface->num_vertices;i++, v += 3, c += 4)
+ for (i = 0, v = (rsurface.vertex3f + 3 * surface->num_firstvertex), c = (rsurface.array_color4f + 4 * surface->num_firstvertex);i < surface->num_vertices;i++, v += 3, c += 4)
{
- f = VERTEXFOGTABLE(VectorDistance(v, rsurface_modelorg));
+ f = 1 - FogPoint_Model(v);
c[0] = layercolor[0];
c[1] = layercolor[1];
c[2] = layercolor[2];
GL_LockArrays(0, 0);
}
CHECKGLERROR
- if (rsurface_texture->currentmaterialflags & MATERIALFLAG_ALPHATEST)
+ if (rsurface.texture->currentmaterialflags & MATERIALFLAG_ALPHATEST)
{
qglDepthFunc(GL_LEQUAL);CHECKGLERROR
GL_AlphaTest(false);
{
// OpenGL 1.1 - crusty old voodoo path
int texturesurfaceindex;
- int lightmode;
qboolean applyfog;
rmeshstate_t m;
int layerindex;
const texturelayer_t *layer;
- CHECKGLERROR
- GL_DepthTest(!(rsurface_texture->currentmaterialflags & MATERIALFLAG_NODEPTHTEST));
- GL_CullFace(((rsurface_texture->textureflags & Q3TEXTUREFLAG_TWOSIDED) || (rsurface_entity->flags & RENDER_NOCULLFACE)) ? GL_NONE : GL_FRONT); // quake is backwards, this culls back faces
- // FIXME: identify models using a better check than rsurface_model->brush.shadowmesh
- lightmode = ((rsurface_entity->effects & EF_FULLBRIGHT) || rsurface_model->brush.shadowmesh) ? 0 : 2;
- if (rsurface_mode != RSURFMODE_MULTIPASS)
- rsurface_mode = RSURFMODE_MULTIPASS;
+ if (rsurface.mode != RSURFMODE_MULTIPASS)
+ rsurface.mode = RSURFMODE_MULTIPASS;
RSurf_PrepareVerticesForBatch(true, false, texturenumsurfaces, texturesurfacelist);
- for (layerindex = 0, layer = rsurface_texture->currentlayers;layerindex < rsurface_texture->currentnumlayers;layerindex++, layer++)
+
+ for (layerindex = 0, layer = rsurface.texture->currentlayers;layerindex < rsurface.texture->currentnumlayers;layerindex++, layer++)
{
- if (rsurface_texture->currentmaterialflags & MATERIALFLAG_ALPHATEST)
+ if (rsurface.texture->currentmaterialflags & MATERIALFLAG_ALPHATEST)
{
if (layerindex == 0)
GL_AlphaTest(true);
}
GL_DepthMask(layer->depthmask);
GL_BlendFunc(layer->blendfunc1, layer->blendfunc2);
- R_Mesh_ColorPointer(NULL);
+ R_Mesh_ColorPointer(NULL, 0, 0);
applyfog = (layer->flags & TEXTURELAYERFLAG_FOGDARKEN) != 0;
switch (layer->type)
{
// two-pass lit texture with 2x rgbscale
// first the lightmap pass
memset(&m, 0, sizeof(m));
- if (lightmode >= 1 || !rsurface_lightmaptexture)
- m.tex[0] = R_GetTexture(r_texture_white);
- else
- m.tex[0] = R_GetTexture(rsurface_lightmaptexture);
- m.pointer_texcoord[0] = rsurface_model->surfmesh.data_texcoordlightmap2f;
+ m.tex[0] = R_GetTexture(r_texture_white);
+ m.pointer_texcoord[0] = rsurface.modeltexcoordlightmap2f;
+ m.pointer_texcoord_bufferobject[0] = rsurface.modeltexcoordlightmap2f_bufferobject;
+ m.pointer_texcoord_bufferoffset[0] = rsurface.modeltexcoordlightmap2f_bufferoffset;
R_Mesh_TextureState(&m);
- RSurf_DrawBatch_Lightmap(texturenumsurfaces, texturesurfacelist, 1, 1, 1, 1, lightmode, false, false);
+ if (rsurface.texture->currentmaterialflags & MATERIALFLAG_MODELLIGHT)
+ RSurf_DrawBatch_GL11_VertexShade(texturenumsurfaces, texturesurfacelist, 1, 1, 1, 1, false, false);
+ else if (rsurface.uselightmaptexture)
+ RSurf_DrawBatch_GL11_Lightmap(texturenumsurfaces, texturesurfacelist, 1, 1, 1, 1, false, false);
+ else
+ RSurf_DrawBatch_GL11_VertexColor(texturenumsurfaces, texturesurfacelist, 1, 1, 1, 1, false, false);
GL_LockArrays(0, 0);
// then apply the texture to it
GL_BlendFunc(GL_DST_COLOR, GL_SRC_COLOR);
memset(&m, 0, sizeof(m));
m.tex[0] = R_GetTexture(layer->texture);
m.texmatrix[0] = layer->texmatrix;
- m.pointer_texcoord[0] = rsurface_model->surfmesh.data_texcoordtexture2f;
+ m.pointer_texcoord[0] = rsurface.texcoordtexture2f;
+ m.pointer_texcoord_bufferobject[0] = rsurface.texcoordtexture2f_bufferobject;
+ m.pointer_texcoord_bufferoffset[0] = rsurface.texcoordtexture2f_bufferoffset;
R_Mesh_TextureState(&m);
- RSurf_DrawBatch_Lightmap(texturenumsurfaces, texturesurfacelist, layer->color[0] * 0.5f, layer->color[1] * 0.5f, layer->color[2] * 0.5f, layer->color[3], 0, layer->color[0] != 2 || layer->color[1] != 2 || layer->color[2] != 2 || layer->color[3] != 1, false);
+ RSurf_DrawBatch_GL11_Unlit(texturenumsurfaces, texturesurfacelist, layer->color[0] * 0.5f, layer->color[1] * 0.5f, layer->color[2] * 0.5f, layer->color[3], layer->color[0] != 2 || layer->color[1] != 2 || layer->color[2] != 2 || layer->color[3] != 1, false);
}
else
{
memset(&m, 0, sizeof(m));
m.tex[0] = R_GetTexture(layer->texture);
m.texmatrix[0] = layer->texmatrix;
- m.pointer_texcoord[0] = rsurface_model->surfmesh.data_texcoordtexture2f;
+ m.pointer_texcoord[0] = rsurface.texcoordtexture2f;
+ m.pointer_texcoord_bufferobject[0] = rsurface.texcoordtexture2f_bufferobject;
+ m.pointer_texcoord_bufferoffset[0] = rsurface.texcoordtexture2f_bufferoffset;
R_Mesh_TextureState(&m);
- RSurf_DrawBatch_Lightmap(texturenumsurfaces, texturesurfacelist, layer->color[0], layer->color[1], layer->color[2], layer->color[3], lightmode == 2 ? 2 : 1, layer->color[0] != 1 || layer->color[1] != 1 || layer->color[2] != 1 || layer->color[3] != 1, applyfog);
+ if (rsurface.texture->currentmaterialflags & MATERIALFLAG_MODELLIGHT)
+ RSurf_DrawBatch_GL11_VertexShade(texturenumsurfaces, texturesurfacelist, layer->color[0], layer->color[1], layer->color[2], layer->color[3], layer->color[0] != 1 || layer->color[1] != 1 || layer->color[2] != 1 || layer->color[3] != 1, applyfog);
+ else
+ RSurf_DrawBatch_GL11_VertexColor(texturenumsurfaces, texturesurfacelist, layer->color[0], layer->color[1], layer->color[2], layer->color[3], layer->color[0] != 1 || layer->color[1] != 1 || layer->color[2] != 1 || layer->color[3] != 1, applyfog);
}
break;
case TEXTURELAYERTYPE_TEXTURE:
memset(&m, 0, sizeof(m));
m.tex[0] = R_GetTexture(layer->texture);
m.texmatrix[0] = layer->texmatrix;
- m.pointer_texcoord[0] = rsurface_model->surfmesh.data_texcoordtexture2f;
+ m.pointer_texcoord[0] = rsurface.texcoordtexture2f;
+ m.pointer_texcoord_bufferobject[0] = rsurface.texcoordtexture2f_bufferobject;
+ m.pointer_texcoord_bufferoffset[0] = rsurface.texcoordtexture2f_bufferoffset;
R_Mesh_TextureState(&m);
- RSurf_DrawBatch_Lightmap(texturenumsurfaces, texturesurfacelist, layer->color[0], layer->color[1], layer->color[2], layer->color[3], 0, layer->color[0] != 1 || layer->color[1] != 1 || layer->color[2] != 1 || layer->color[3] != 1, applyfog);
+ RSurf_DrawBatch_GL11_Unlit(texturenumsurfaces, texturesurfacelist, layer->color[0], layer->color[1], layer->color[2], layer->color[3], layer->color[0] != 1 || layer->color[1] != 1 || layer->color[2] != 1 || layer->color[3] != 1, applyfog);
break;
case TEXTURELAYERTYPE_FOG:
// singletexture fogging
- R_Mesh_ColorPointer(rsurface_array_color4f);
+ R_Mesh_ColorPointer(rsurface.array_color4f, 0, 0);
if (layer->texture)
{
memset(&m, 0, sizeof(m));
m.tex[0] = R_GetTexture(layer->texture);
m.texmatrix[0] = layer->texmatrix;
- m.pointer_texcoord[0] = rsurface_model->surfmesh.data_texcoordtexture2f;
+ m.pointer_texcoord[0] = rsurface.texcoordtexture2f;
+ m.pointer_texcoord_bufferobject[0] = rsurface.texcoordtexture2f_bufferobject;
+ m.pointer_texcoord_bufferoffset[0] = rsurface.texcoordtexture2f_bufferoffset;
R_Mesh_TextureState(&m);
}
else
int i;
float f, *v, *c;
const msurface_t *surface = texturesurfacelist[texturesurfaceindex];
- for (i = 0, v = (rsurface_vertex3f + 3 * surface->num_firstvertex), c = (rsurface_array_color4f + 4 * surface->num_firstvertex);i < surface->num_vertices;i++, v += 3, c += 4)
+ for (i = 0, v = (rsurface.vertex3f + 3 * surface->num_firstvertex), c = (rsurface.array_color4f + 4 * surface->num_firstvertex);i < surface->num_vertices;i++, v += 3, c += 4)
{
- f = VERTEXFOGTABLE(VectorDistance(v, rsurface_modelorg));
+ f = 1 - FogPoint_Model(v);
c[0] = layer->color[0];
c[1] = layer->color[1];
c[2] = layer->color[2];
GL_LockArrays(0, 0);
}
CHECKGLERROR
- if (rsurface_texture->currentmaterialflags & MATERIALFLAG_ALPHATEST)
+ if (rsurface.texture->currentmaterialflags & MATERIALFLAG_ALPHATEST)
{
qglDepthFunc(GL_LEQUAL);CHECKGLERROR
GL_AlphaTest(false);
}
}
-static void R_DrawTextureSurfaceList(int texturenumsurfaces, msurface_t **texturesurfacelist)
+static void R_DrawTextureSurfaceList(int texturenumsurfaces, msurface_t **texturesurfacelist, qboolean writedepth, qboolean depthonly)
{
- if (rsurface_texture->currentmaterialflags & MATERIALFLAG_NODRAW)
+ if (rsurface.texture->currentmaterialflags & MATERIALFLAG_NODRAW)
return;
- r_shadow_rtlight = NULL;
- r_refdef.stats.entities_surfaces += texturenumsurfaces;
+ rsurface.rtlight = NULL;
CHECKGLERROR
- if (r_showsurfaces.integer)
+ if (depthonly)
+ {
+ if ((rsurface.texture->currentmaterialflags & (MATERIALFLAG_NODEPTHTEST | MATERIALFLAG_BLENDED | MATERIALFLAG_ALPHATEST)))
+ return;
+ if (r_waterstate.renderingscene && (rsurface.texture->currentmaterialflags & (MATERIALFLAG_WATERSHADER | MATERIALFLAG_REFLECTION)))
+ return;
+ if (rsurface.mode != RSURFMODE_MULTIPASS)
+ rsurface.mode = RSURFMODE_MULTIPASS;
+ if (r_depthfirst.integer == 3)
+ {
+ int i = (int)(texturesurfacelist[0] - rsurface.modelsurfaces);
+ if (!r_view.showdebug)
+ GL_Color(0, 0, 0, 1);
+ else
+ GL_Color(((i >> 6) & 7) / 7.0f, ((i >> 3) & 7) / 7.0f, (i & 7) / 7.0f,1);
+ }
+ else
+ {
+ GL_ColorMask(0,0,0,0);
+ GL_Color(1,1,1,1);
+ }
+ GL_DepthRange(0, (rsurface.texture->currentmaterialflags & MATERIALFLAG_SHORTDEPTHRANGE) ? 0.0625 : 1);
+ GL_PolygonOffset(rsurface.texture->currentpolygonfactor, rsurface.texture->currentpolygonoffset);
+ GL_CullFace((rsurface.texture->currentmaterialflags & MATERIALFLAG_NOCULLFACE) ? GL_NONE : r_view.cullface_back);
+ GL_DepthTest(true);
+ GL_BlendFunc(GL_ONE, GL_ZERO);
+ GL_DepthMask(true);
+ GL_AlphaTest(false);
+ R_Mesh_ColorPointer(NULL, 0, 0);
+ R_Mesh_ResetTextureState();
+ RSurf_PrepareVerticesForBatch(false, false, texturenumsurfaces, texturesurfacelist);
+ RSurf_DrawBatch_Simple(texturenumsurfaces, texturesurfacelist);
+ GL_ColorMask(r_view.colormask[0], r_view.colormask[1], r_view.colormask[2], 1);
+ }
+ else if (r_depthfirst.integer == 3)
+ return;
+ else if (!r_view.showdebug && (r_showsurfaces.integer || gl_lightmaps.integer))
+ {
+ GL_Color(0, 0, 0, 1);
+ RSurf_DrawBatch_Simple(texturenumsurfaces, texturesurfacelist);
+ }
+ else if (r_showsurfaces.integer)
+ {
+ if (rsurface.mode != RSURFMODE_MULTIPASS)
+ rsurface.mode = RSURFMODE_MULTIPASS;
+ GL_DepthRange(0, (rsurface.texture->currentmaterialflags & MATERIALFLAG_SHORTDEPTHRANGE) ? 0.0625 : 1);
+ GL_PolygonOffset(rsurface.texture->currentpolygonfactor, rsurface.texture->currentpolygonoffset);
+ GL_DepthTest(true);
+ GL_CullFace((rsurface.texture->currentmaterialflags & MATERIALFLAG_NOCULLFACE) ? GL_NONE : r_view.cullface_back);
+ GL_BlendFunc(GL_ONE, GL_ZERO);
+ GL_DepthMask(writedepth);
+ GL_Color(1,1,1,1);
+ GL_AlphaTest(false);
+ R_Mesh_ColorPointer(NULL, 0, 0);
+ R_Mesh_ResetTextureState();
+ RSurf_PrepareVerticesForBatch(false, false, texturenumsurfaces, texturesurfacelist);
R_DrawTextureSurfaceList_ShowSurfaces(texturenumsurfaces, texturesurfacelist);
- else if (rsurface_texture->currentmaterialflags & MATERIALFLAG_SKY)
+ }
+ else if (gl_lightmaps.integer)
+ {
+ rmeshstate_t m;
+ if (rsurface.mode != RSURFMODE_MULTIPASS)
+ rsurface.mode = RSURFMODE_MULTIPASS;
+ GL_DepthRange(0, (rsurface.texture->currentmaterialflags & MATERIALFLAG_SHORTDEPTHRANGE) ? 0.0625 : 1);
+ GL_DepthTest(true);
+ GL_CullFace((rsurface.texture->currentmaterialflags & MATERIALFLAG_NOCULLFACE) ? GL_NONE : r_view.cullface_back);
+ GL_BlendFunc(GL_ONE, GL_ZERO);
+ GL_DepthMask(writedepth);
+ GL_Color(1,1,1,1);
+ GL_AlphaTest(false);
+ R_Mesh_ColorPointer(NULL, 0, 0);
+ memset(&m, 0, sizeof(m));
+ m.tex[0] = R_GetTexture(r_texture_white);
+ m.pointer_texcoord[0] = rsurface.modeltexcoordlightmap2f;
+ m.pointer_texcoord_bufferobject[0] = rsurface.modeltexcoordlightmap2f_bufferobject;
+ m.pointer_texcoord_bufferoffset[0] = rsurface.modeltexcoordlightmap2f_bufferoffset;
+ R_Mesh_TextureState(&m);
+ RSurf_PrepareVerticesForBatch(rsurface.texture->currentmaterialflags & MATERIALFLAG_MODELLIGHT, false, texturenumsurfaces, texturesurfacelist);
+ if (rsurface.texture->currentmaterialflags & MATERIALFLAG_MODELLIGHT)
+ RSurf_DrawBatch_GL11_VertexShade(texturenumsurfaces, texturesurfacelist, 1, 1, 1, 1, false, false);
+ else if (rsurface.uselightmaptexture)
+ RSurf_DrawBatch_GL11_Lightmap(texturenumsurfaces, texturesurfacelist, 1, 1, 1, 1, false, false);
+ else
+ RSurf_DrawBatch_GL11_VertexColor(texturenumsurfaces, texturesurfacelist, 1, 1, 1, 1, false, false);
+ }
+ else if (rsurface.texture->currentmaterialflags & MATERIALFLAG_SKY)
R_DrawTextureSurfaceList_Sky(texturenumsurfaces, texturesurfacelist);
- else if (rsurface_texture->currentnumlayers)
+ else if (rsurface.texture->currentnumlayers)
{
+ // write depth for anything we skipped on the depth-only pass earlier
+ if (rsurface.texture->currentmaterialflags & MATERIALFLAG_ALPHATEST)
+ writedepth = true;
+ GL_DepthRange(0, (rsurface.texture->currentmaterialflags & MATERIALFLAG_SHORTDEPTHRANGE) ? 0.0625 : 1);
+ GL_PolygonOffset(rsurface.texture->currentpolygonfactor, rsurface.texture->currentpolygonoffset);
+ GL_DepthTest(!(rsurface.texture->currentmaterialflags & MATERIALFLAG_NODEPTHTEST));
+ GL_CullFace((rsurface.texture->currentmaterialflags & MATERIALFLAG_NOCULLFACE) ? GL_NONE : r_view.cullface_back);
+ GL_BlendFunc(rsurface.texture->currentlayers[0].blendfunc1, rsurface.texture->currentlayers[0].blendfunc2);
+ GL_DepthMask(writedepth && !(rsurface.texture->currentmaterialflags & MATERIALFLAG_BLENDED));
+ GL_AlphaTest((rsurface.texture->currentmaterialflags & MATERIALFLAG_ALPHATEST) != 0);
if (r_glsl.integer && gl_support_fragment_shader)
R_DrawTextureSurfaceList_GL20(texturenumsurfaces, texturesurfacelist);
else if (gl_combine.integer && r_textureunits.integer >= 2)
GL_LockArrays(0, 0);
}
-#define BATCHSIZE 256
static void R_DrawSurface_TransparentCallback(const entity_render_t *ent, const rtlight_t *rtlight, int numsurfaces, int *surfacelist)
{
- int surfacelistindex;
- int batchcount;
- texture_t *t;
- msurface_t *texturesurfacelist[BATCHSIZE];
+ int i, j;
+ int texturenumsurfaces, endsurface;
+ texture_t *texture;
+ msurface_t *surface;
+ msurface_t *texturesurfacelist[1024];
+
// if the model is static it doesn't matter what value we give for
// wantnormals and wanttangents, so this logic uses only rules applicable
// to a model, knowing that they are meaningless otherwise
- if ((ent->effects & EF_FULLBRIGHT) || r_showsurfaces.integer || VectorLength2(ent->modellight_diffuse) < (1.0f / 256.0f))
- RSurf_ActiveEntity(ent, false, false);
+ if (ent == r_refdef.worldentity)
+ RSurf_ActiveWorldEntity();
+ else if ((ent->effects & EF_FULLBRIGHT) || r_showsurfaces.integer || VectorLength2(ent->modellight_diffuse) < (1.0f / 256.0f))
+ RSurf_ActiveModelEntity(ent, false, false);
else
- RSurf_ActiveEntity(ent, true, r_glsl.integer && gl_support_fragment_shader);
- batchcount = 0;
- t = NULL;
- for (surfacelistindex = 0;surfacelistindex < numsurfaces;surfacelistindex++)
- {
- msurface_t *surface = ent->model->data_surfaces + surfacelist[surfacelistindex];
+ RSurf_ActiveModelEntity(ent, true, r_glsl.integer && gl_support_fragment_shader);
- if (t != surface->texture || rsurface_lightmaptexture != surface->lightmaptexture)
+ for (i = 0;i < numsurfaces;i = j)
+ {
+ j = i + 1;
+ surface = rsurface.modelsurfaces + surfacelist[i];
+ texture = surface->texture;
+ R_UpdateTextureInfo(ent, texture);
+ rsurface.texture = texture->currentframe;
+ rsurface.uselightmaptexture = surface->lightmaptexture != NULL;
+ // scan ahead until we find a different texture
+ endsurface = min(i + 1024, numsurfaces);
+ texturenumsurfaces = 0;
+ texturesurfacelist[texturenumsurfaces++] = surface;
+ for (;j < endsurface;j++)
{
- if (batchcount > 0)
- if (!(rsurface_texture->currentmaterialflags & MATERIALFLAG_SKY)) // transparent sky is too difficult
- R_DrawTextureSurfaceList(batchcount, texturesurfacelist);
- batchcount = 0;
- t = surface->texture;
- rsurface_lightmaptexture = surface->lightmaptexture;
- R_UpdateTextureInfo(ent, t);
- rsurface_texture = t->currentframe;
+ surface = rsurface.modelsurfaces + surfacelist[j];
+ if (texture != surface->texture || rsurface.uselightmaptexture != (surface->lightmaptexture != NULL))
+ break;
+ texturesurfacelist[texturenumsurfaces++] = surface;
}
-
- texturesurfacelist[batchcount++] = surface;
+ // render the range of surfaces
+ R_DrawTextureSurfaceList(texturenumsurfaces, texturesurfacelist, true, false);
}
- if (batchcount > 0)
- if (!(rsurface_texture->currentmaterialflags & MATERIALFLAG_SKY)) // transparent sky is too difficult
- R_DrawTextureSurfaceList(batchcount, texturesurfacelist);
+
RSurf_CleanUp();
}
-void R_QueueTextureSurfaceList(int texturenumsurfaces, msurface_t **texturesurfacelist)
+void R_QueueSurfaceList(entity_render_t *ent, int numsurfaces, msurface_t **surfacelist, int flagsmask, qboolean writedepth, qboolean depthonly, qboolean addwaterplanes)
{
- int texturesurfaceindex;
+ int i, j;
vec3_t tempcenter, center;
- if (rsurface_texture->currentmaterialflags & MATERIALFLAG_BLENDED)
+ texture_t *texture;
+ // if we're rendering water textures (extra scene renders), use a separate loop to avoid burdening the main one
+ if (addwaterplanes)
+ {
+ for (i = 0;i < numsurfaces;i++)
+ if (surfacelist[i]->texture->currentframe->currentmaterialflags & (MATERIALFLAG_WATERSHADER | MATERIALFLAG_REFRACTION | MATERIALFLAG_REFLECTION))
+ R_Water_AddWaterPlane(surfacelist[i]);
+ return;
+ }
+ // break the surface list down into batches by texture and use of lightmapping
+ for (i = 0;i < numsurfaces;i = j)
{
- // drawing sky transparently would be too difficult
- if (!(rsurface_texture->currentmaterialflags & MATERIALFLAG_SKY))
+ j = i + 1;
+ // texture is the base texture pointer, rsurface.texture is the
+ // current frame/skin the texture is directing us to use (for example
+ // if a model has 2 skins and it is on skin 1, then skin 0 tells us to
+ // use skin 1 instead)
+ texture = surfacelist[i]->texture;
+ rsurface.texture = texture->currentframe;
+ rsurface.uselightmaptexture = surfacelist[i]->lightmaptexture != NULL;
+ if (!(rsurface.texture->currentmaterialflags & flagsmask))
{
- for (texturesurfaceindex = 0;texturesurfaceindex < texturenumsurfaces;texturesurfaceindex++)
- {
- const msurface_t *surface = texturesurfacelist[texturesurfaceindex];
- tempcenter[0] = (surface->mins[0] + surface->maxs[0]) * 0.5f;
- tempcenter[1] = (surface->mins[1] + surface->maxs[1]) * 0.5f;
- tempcenter[2] = (surface->mins[2] + surface->maxs[2]) * 0.5f;
- Matrix4x4_Transform(&rsurface_entity->matrix, tempcenter, center);
- R_MeshQueue_AddTransparent(rsurface_texture->currentmaterialflags & MATERIALFLAG_NODEPTHTEST ? r_view.origin : center, R_DrawSurface_TransparentCallback, rsurface_entity, surface - rsurface_model->data_surfaces, r_shadow_rtlight);
- }
+ // if this texture is not the kind we want, skip ahead to the next one
+ for (;j < numsurfaces && texture == surfacelist[j]->texture;j++)
+ ;
+ continue;
+ }
+ if (rsurface.texture->currentmaterialflags & MATERIALFLAGMASK_DEPTHSORTED)
+ {
+ // transparent surfaces get pushed off into the transparent queue
+ const msurface_t *surface = surfacelist[i];
+ if (depthonly)
+ continue;
+ tempcenter[0] = (surface->mins[0] + surface->maxs[0]) * 0.5f;
+ tempcenter[1] = (surface->mins[1] + surface->maxs[1]) * 0.5f;
+ tempcenter[2] = (surface->mins[2] + surface->maxs[2]) * 0.5f;
+ Matrix4x4_Transform(&rsurface.matrix, tempcenter, center);
+ R_MeshQueue_AddTransparent(rsurface.texture->currentmaterialflags & MATERIALFLAG_NODEPTHTEST ? r_view.origin : center, R_DrawSurface_TransparentCallback, ent, surface - rsurface.modelsurfaces, rsurface.rtlight);
+ }
+ else
+ {
+ // simply scan ahead until we find a different texture or lightmap state
+ for (;j < numsurfaces && texture == surfacelist[j]->texture && rsurface.uselightmaptexture == (surfacelist[j]->lightmaptexture != NULL);j++)
+ ;
+ // render the range of surfaces
+ R_DrawTextureSurfaceList(j - i, surfacelist + i, writedepth, depthonly);
}
}
+}
+
+float locboxvertex3f[6*4*3] =
+{
+ 1,0,1, 1,0,0, 1,1,0, 1,1,1,
+ 0,1,1, 0,1,0, 0,0,0, 0,0,1,
+ 1,1,1, 1,1,0, 0,1,0, 0,1,1,
+ 0,0,1, 0,0,0, 1,0,0, 1,0,1,
+ 0,0,1, 1,0,1, 1,1,1, 0,1,1,
+ 1,0,0, 0,0,0, 0,1,0, 1,1,0
+};
+
+int locboxelement3i[6*2*3] =
+{
+ 0, 1, 2, 0, 2, 3,
+ 4, 5, 6, 4, 6, 7,
+ 8, 9,10, 8,10,11,
+ 12,13,14, 12,14,15,
+ 16,17,18, 16,18,19,
+ 20,21,22, 20,22,23
+};
+
+void R_DrawLoc_Callback(const entity_render_t *ent, const rtlight_t *rtlight, int numsurfaces, int *surfacelist)
+{
+ int i, j;
+ cl_locnode_t *loc = (cl_locnode_t *)ent;
+ vec3_t mins, size;
+ float vertex3f[6*4*3];
+ CHECKGLERROR
+ GL_BlendFunc(GL_SRC_ALPHA, GL_ONE_MINUS_SRC_ALPHA);
+ GL_DepthMask(false);
+ GL_DepthRange(0, 1);
+ GL_PolygonOffset(r_refdef.polygonfactor, r_refdef.polygonoffset);
+ GL_DepthTest(true);
+ GL_CullFace(GL_NONE);
+ R_Mesh_Matrix(&identitymatrix);
+
+ R_Mesh_VertexPointer(vertex3f, 0, 0);
+ R_Mesh_ColorPointer(NULL, 0, 0);
+ R_Mesh_ResetTextureState();
+
+ i = surfacelist[0];
+ GL_Color(((i & 0x0007) >> 0) * (1.0f / 7.0f) * r_view.colorscale,
+ ((i & 0x0038) >> 3) * (1.0f / 7.0f) * r_view.colorscale,
+ ((i & 0x01C0) >> 6) * (1.0f / 7.0f) * r_view.colorscale,
+ surfacelist[0] < 0 ? 0.5f : 0.125f);
+
+ if (VectorCompare(loc->mins, loc->maxs))
+ {
+ VectorSet(size, 2, 2, 2);
+ VectorMA(loc->mins, -0.5f, size, mins);
+ }
else
- R_DrawTextureSurfaceList(texturenumsurfaces, texturesurfacelist);
+ {
+ VectorCopy(loc->mins, mins);
+ VectorSubtract(loc->maxs, loc->mins, size);
+ }
+
+ for (i = 0;i < 6*4*3;)
+ for (j = 0;j < 3;j++, i++)
+ vertex3f[i] = mins[j] + size[j] * locboxvertex3f[i];
+
+ R_Mesh_Draw(0, 6*4, 6*2, locboxelement3i, 0, 0);
}
-extern void R_BuildLightMap(const entity_render_t *ent, msurface_t *surface);
-void R_DrawSurfaces(entity_render_t *ent, qboolean skysurfaces)
+void R_DrawLocs(void)
{
- int i, j, k, l, endj, f, flagsmask;
- int counttriangles = 0;
- msurface_t *surface, *endsurface, **surfacechain;
- texture_t *t;
+ int index;
+ cl_locnode_t *loc, *nearestloc;
+ vec3_t center;
+ nearestloc = CL_Locs_FindNearest(cl.movement_origin);
+ for (loc = cl.locnodes, index = 0;loc;loc = loc->next, index++)
+ {
+ VectorLerp(loc->mins, 0.5f, loc->maxs, center);
+ R_MeshQueue_AddTransparent(center, R_DrawLoc_Callback, (entity_render_t *)loc, loc == nearestloc ? -1 : index, NULL);
+ }
+}
+
+void R_DrawDebugModel(entity_render_t *ent)
+{
+ int i, j, k, l, flagsmask;
+ const int *elements;
q3mbrush_t *brush;
+ msurface_t *surface;
model_t *model = ent->model;
- const int *elements;
- const int maxsurfacelist = 1024;
- int numsurfacelist = 0;
- msurface_t *surfacelist[1024];
vec3_t v;
- if (model == NULL)
- return;
- // if the model is static it doesn't matter what value we give for
- // wantnormals and wanttangents, so this logic uses only rules applicable
- // to a model, knowing that they are meaningless otherwise
- if ((ent->effects & EF_FULLBRIGHT) || r_showsurfaces.integer || VectorLength2(ent->modellight_diffuse) < (1.0f / 256.0f))
- RSurf_ActiveEntity(ent, false, false);
- else
- RSurf_ActiveEntity(ent, true, r_glsl.integer && gl_support_fragment_shader);
+ flagsmask = MATERIALFLAG_SKY | MATERIALFLAG_WATER | MATERIALFLAG_WALL;
- // update light styles
- if (!skysurfaces && model->brushq1.light_styleupdatechains)
- {
- for (i = 0;i < model->brushq1.light_styles;i++)
- {
- if (model->brushq1.light_stylevalue[i] != r_refdef.lightstylevalue[model->brushq1.light_style[i]])
- {
- model->brushq1.light_stylevalue[i] = r_refdef.lightstylevalue[model->brushq1.light_style[i]];
- if ((surfacechain = model->brushq1.light_styleupdatechains[i]))
- for (;(surface = *surfacechain);surfacechain++)
- surface->cached_dlight = true;
- }
- }
- }
+ R_Mesh_ColorPointer(NULL, 0, 0);
+ R_Mesh_ResetTextureState();
+ GL_DepthRange(0, 1);
+ GL_DepthTest(!r_showdisabledepthtest.integer);
+ GL_DepthMask(false);
+ GL_BlendFunc(GL_SRC_ALPHA, GL_ONE_MINUS_SRC_ALPHA);
- R_UpdateAllTextureInfo(ent);
- flagsmask = skysurfaces ? MATERIALFLAG_SKY : (MATERIALFLAG_WATER | MATERIALFLAG_WALL);
- f = 0;
- t = NULL;
- rsurface_lightmaptexture = NULL;
- rsurface_texture = NULL;
- numsurfacelist = 0;
- if (ent == r_refdef.worldentity)
+ if (r_showcollisionbrushes.value > 0 && model->brush.num_brushes)
{
- j = model->firstmodelsurface;
- endj = j + model->nummodelsurfaces;
- while (j < endj)
+ GL_PolygonOffset(r_refdef.polygonfactor + r_showcollisionbrushes_polygonfactor.value, r_refdef.polygonoffset + r_showcollisionbrushes_polygonoffset.value);
+ for (i = 0, brush = model->brush.data_brushes + model->firstmodelbrush;i < model->nummodelbrushes;i++, brush++)
{
- // quickly skip over non-visible surfaces
- for (;j < endj && !r_viewcache.world_surfacevisible[j];j++)
- ;
- // quickly iterate over visible surfaces
- for (;j < endj && r_viewcache.world_surfacevisible[j];j++)
+ if (brush->colbrushf && brush->colbrushf->numtriangles)
{
- // process this surface
- surface = model->data_surfaces + j;
- // if texture or lightmap has changed, start a new batch
- if (t != surface->texture || rsurface_lightmaptexture != surface->lightmaptexture)
- {
- if (numsurfacelist)
- {
- R_QueueTextureSurfaceList(numsurfacelist, surfacelist);
- numsurfacelist = 0;
- }
- t = surface->texture;
- rsurface_lightmaptexture = surface->lightmaptexture;
- rsurface_texture = t->currentframe;
- f = rsurface_texture->currentmaterialflags & flagsmask;
- }
- // if this surface fits the criteria, add it to the list
- if (f && surface->num_triangles)
- {
- // if lightmap parameters changed, rebuild lightmap texture
- if (surface->cached_dlight)
- R_BuildLightMap(ent, surface);
- // add face to draw list
- surfacelist[numsurfacelist++] = surface;
- counttriangles += surface->num_triangles;
- if (numsurfacelist >= maxsurfacelist)
- {
- R_QueueTextureSurfaceList(numsurfacelist, surfacelist);
- numsurfacelist = 0;
- }
- }
+ R_Mesh_VertexPointer(brush->colbrushf->points->v, 0, 0);
+ GL_Color((i & 31) * (1.0f / 32.0f) * r_view.colorscale, ((i >> 5) & 31) * (1.0f / 32.0f) * r_view.colorscale, ((i >> 10) & 31) * (1.0f / 32.0f) * r_view.colorscale, r_showcollisionbrushes.value);
+ R_Mesh_Draw(0, brush->colbrushf->numpoints, brush->colbrushf->numtriangles, brush->colbrushf->elements, 0, 0);
}
}
- }
- else
- {
- surface = model->data_surfaces + model->firstmodelsurface;
- endsurface = surface + model->nummodelsurfaces;
- for (;surface < endsurface;surface++)
+ for (i = 0, surface = model->data_surfaces + model->firstmodelsurface;i < model->nummodelsurfaces;i++, surface++)
{
- // if texture or lightmap has changed, start a new batch
- if (t != surface->texture || rsurface_lightmaptexture != surface->lightmaptexture)
- {
- if (numsurfacelist)
- {
- R_QueueTextureSurfaceList(numsurfacelist, surfacelist);
- numsurfacelist = 0;
- }
- t = surface->texture;
- rsurface_lightmaptexture = surface->lightmaptexture;
- rsurface_texture = t->currentframe;
- f = rsurface_texture->currentmaterialflags & flagsmask;
- }
- // if this surface fits the criteria, add it to the list
- if (f && surface->num_triangles)
+ if (surface->num_collisiontriangles)
{
- // if lightmap parameters changed, rebuild lightmap texture
- if (surface->cached_dlight)
- R_BuildLightMap(ent, surface);
- // add face to draw list
- surfacelist[numsurfacelist++] = surface;
- counttriangles += surface->num_triangles;
- if (numsurfacelist >= maxsurfacelist)
- {
- R_QueueTextureSurfaceList(numsurfacelist, surfacelist);
- numsurfacelist = 0;
- }
+ R_Mesh_VertexPointer(surface->data_collisionvertex3f, 0, 0);
+ GL_Color((i & 31) * (1.0f / 32.0f) * r_view.colorscale, ((i >> 5) & 31) * (1.0f / 32.0f) * r_view.colorscale, ((i >> 10) & 31) * (1.0f / 32.0f) * r_view.colorscale, r_showcollisionbrushes.value);
+ R_Mesh_Draw(0, surface->num_collisionvertices, surface->num_collisiontriangles, surface->data_collisionelement3i, 0, 0);
}
}
}
- if (numsurfacelist)
- R_QueueTextureSurfaceList(numsurfacelist, surfacelist);
- r_refdef.stats.entities_triangles += counttriangles;
- RSurf_CleanUp();
- if (r_showcollisionbrushes.integer && model->brush.num_brushes && !skysurfaces)
- {
- CHECKGLERROR
- R_Mesh_Matrix(&ent->matrix);
- R_Mesh_ColorPointer(NULL);
- R_Mesh_ResetTextureState();
- GL_BlendFunc(GL_SRC_ALPHA, GL_ONE);
- GL_DepthMask(false);
- GL_DepthTest(!r_showdisabledepthtest.integer);
- qglPolygonOffset(r_refdef.polygonfactor + r_showcollisionbrushes_polygonfactor.value, r_refdef.polygonoffset + r_showcollisionbrushes_polygonoffset.value);CHECKGLERROR
- for (i = 0, brush = model->brush.data_brushes + model->firstmodelbrush;i < model->nummodelbrushes;i++, brush++)
- if (brush->colbrushf && brush->colbrushf->numtriangles)
- R_DrawCollisionBrush(brush->colbrushf);
- for (i = 0, surface = model->data_surfaces + model->firstmodelsurface;i < model->nummodelsurfaces;i++, surface++)
- if (surface->num_collisiontriangles)
- R_DrawCollisionSurface(ent, surface);
- qglPolygonOffset(r_refdef.polygonfactor, r_refdef.polygonoffset);CHECKGLERROR
- }
+ GL_PolygonOffset(r_refdef.polygonfactor, r_refdef.polygonoffset);
if (r_showtris.integer || r_shownormals.integer)
{
- CHECKGLERROR
- GL_DepthTest(!r_showdisabledepthtest.integer);
- GL_DepthMask(true);
- GL_BlendFunc(GL_ONE, GL_ZERO);
- R_Mesh_ColorPointer(NULL);
- R_Mesh_ResetTextureState();
+ if (r_showdisabledepthtest.integer)
+ {
+ GL_BlendFunc(GL_SRC_ALPHA, GL_ONE_MINUS_SRC_ALPHA);
+ GL_DepthMask(false);
+ }
+ else
+ {
+ GL_BlendFunc(GL_ONE, GL_ZERO);
+ GL_DepthMask(true);
+ }
for (i = 0, j = model->firstmodelsurface, surface = model->data_surfaces + j;i < model->nummodelsurfaces;i++, j++, surface++)
{
if (ent == r_refdef.worldentity && !r_viewcache.world_surfacevisible[j])
continue;
- rsurface_texture = surface->texture->currentframe;
- if ((rsurface_texture->currentmaterialflags & flagsmask) && surface->num_triangles)
+ rsurface.texture = surface->texture->currentframe;
+ if ((rsurface.texture->currentmaterialflags & flagsmask) && surface->num_triangles)
{
RSurf_PrepareVerticesForBatch(true, true, 1, &surface);
- if (r_showtris.integer)
+ if (r_showtris.value > 0)
{
- if (!rsurface_texture->currentlayers->depthmask)
- GL_Color(r_showtris.value * r_view.colorscale, 0, 0, 1);
+ if (!rsurface.texture->currentlayers->depthmask)
+ GL_Color(r_view.colorscale, 0, 0, r_showtris.value);
else if (ent == r_refdef.worldentity)
- GL_Color(r_showtris.value * r_view.colorscale, r_showtris.value * r_view.colorscale, r_showtris.value * r_view.colorscale, 1);
+ GL_Color(r_view.colorscale, r_view.colorscale, r_view.colorscale, r_showtris.value);
else
- GL_Color(0, r_showtris.value * r_view.colorscale, 0, 1);
+ GL_Color(0, r_view.colorscale, 0, r_showtris.value);
elements = (ent->model->surfmesh.data_element3i + 3 * surface->num_firsttriangle);
CHECKGLERROR
qglBegin(GL_LINES);
for (k = 0;k < surface->num_triangles;k++, elements += 3)
{
- qglArrayElement(elements[0]);qglArrayElement(elements[1]);
- qglArrayElement(elements[1]);qglArrayElement(elements[2]);
- qglArrayElement(elements[2]);qglArrayElement(elements[0]);
+#define GLVERTEXELEMENT(n) qglVertex3f(rsurface.vertex3f[elements[n]*3+0], rsurface.vertex3f[elements[n]*3+1], rsurface.vertex3f[elements[n]*3+2])
+ GLVERTEXELEMENT(0);GLVERTEXELEMENT(1);
+ GLVERTEXELEMENT(1);GLVERTEXELEMENT(2);
+ GLVERTEXELEMENT(2);GLVERTEXELEMENT(0);
}
qglEnd();
CHECKGLERROR
}
- if (r_shownormals.integer)
+ if (r_shownormals.value > 0)
{
- GL_Color(r_shownormals.value * r_view.colorscale, 0, 0, 1);
+ GL_Color(r_view.colorscale, 0, 0, r_shownormals.value);
qglBegin(GL_LINES);
for (k = 0, l = surface->num_firstvertex;k < surface->num_vertices;k++, l++)
{
- VectorCopy(rsurface_vertex3f + l * 3, v);
+ VectorCopy(rsurface.vertex3f + l * 3, v);
qglVertex3f(v[0], v[1], v[2]);
- VectorMA(v, 8, rsurface_svector3f + l * 3, v);
+ VectorMA(v, 8, rsurface.svector3f + l * 3, v);
qglVertex3f(v[0], v[1], v[2]);
}
qglEnd();
CHECKGLERROR
- GL_Color(0, 0, r_shownormals.value * r_view.colorscale, 1);
+ GL_Color(0, 0, r_view.colorscale, r_shownormals.value);
qglBegin(GL_LINES);
for (k = 0, l = surface->num_firstvertex;k < surface->num_vertices;k++, l++)
{
- VectorCopy(rsurface_vertex3f + l * 3, v);
+ VectorCopy(rsurface.vertex3f + l * 3, v);
qglVertex3f(v[0], v[1], v[2]);
- VectorMA(v, 8, rsurface_tvector3f + l * 3, v);
+ VectorMA(v, 8, rsurface.tvector3f + l * 3, v);
qglVertex3f(v[0], v[1], v[2]);
}
qglEnd();
CHECKGLERROR
- GL_Color(0, r_shownormals.value * r_view.colorscale, 0, 1);
+ GL_Color(0, r_view.colorscale, 0, r_shownormals.value);
qglBegin(GL_LINES);
for (k = 0, l = surface->num_firstvertex;k < surface->num_vertices;k++, l++)
{
- VectorCopy(rsurface_vertex3f + l * 3, v);
+ VectorCopy(rsurface.vertex3f + l * 3, v);
qglVertex3f(v[0], v[1], v[2]);
- VectorMA(v, 8, rsurface_normal3f + l * 3, v);
+ VectorMA(v, 8, rsurface.normal3f + l * 3, v);
qglVertex3f(v[0], v[1], v[2]);
}
qglEnd();
}
}
}
- rsurface_texture = NULL;
+ rsurface.texture = NULL;
}
}
+
+extern void R_BuildLightMap(const entity_render_t *ent, msurface_t *surface);
+void R_DrawWorldSurfaces(qboolean skysurfaces, qboolean writedepth, qboolean depthonly, qboolean addwaterplanes, qboolean debug)
+{
+ int i, j, endj, f, flagsmask;
+ msurface_t *surface, **surfacechain;
+ texture_t *t;
+ model_t *model = r_refdef.worldmodel;
+ const int maxsurfacelist = 1024;
+ int numsurfacelist = 0;
+ msurface_t *surfacelist[1024];
+ if (model == NULL)
+ return;
+
+ RSurf_ActiveWorldEntity();
+
+ // update light styles
+ if (!skysurfaces && !depthonly && !addwaterplanes && model->brushq1.light_styleupdatechains)
+ {
+ for (i = 0;i < model->brushq1.light_styles;i++)
+ {
+ if (model->brushq1.light_stylevalue[i] != r_refdef.lightstylevalue[model->brushq1.light_style[i]])
+ {
+ model->brushq1.light_stylevalue[i] = r_refdef.lightstylevalue[model->brushq1.light_style[i]];
+ if ((surfacechain = model->brushq1.light_styleupdatechains[i]))
+ for (;(surface = *surfacechain);surfacechain++)
+ surface->cached_dlight = true;
+ }
+ }
+ }
+
+ R_UpdateAllTextureInfo(r_refdef.worldentity);
+ flagsmask = addwaterplanes ? (MATERIALFLAG_WATERSHADER | MATERIALFLAG_REFRACTION | MATERIALFLAG_REFLECTION) : (skysurfaces ? MATERIALFLAG_SKY : (MATERIALFLAG_WATER | MATERIALFLAG_WALL));
+
+ if (debug)
+ {
+ R_DrawDebugModel(r_refdef.worldentity);
+ return;
+ }
+
+ f = 0;
+ t = NULL;
+ rsurface.uselightmaptexture = false;
+ rsurface.texture = NULL;
+ numsurfacelist = 0;
+ j = model->firstmodelsurface;
+ endj = j + model->nummodelsurfaces;
+ while (j < endj)
+ {
+ // quickly skip over non-visible surfaces
+ for (;j < endj && !r_viewcache.world_surfacevisible[j];j++)
+ ;
+ // quickly iterate over visible surfaces
+ for (;j < endj && r_viewcache.world_surfacevisible[j];j++)
+ {
+ // process this surface
+ surface = model->data_surfaces + j;
+ // if this surface fits the criteria, add it to the list
+ if (surface->num_triangles)
+ {
+ // if lightmap parameters changed, rebuild lightmap texture
+ if (surface->cached_dlight)
+ R_BuildLightMap(r_refdef.worldentity, surface);
+ // add face to draw list
+ surfacelist[numsurfacelist++] = surface;
+ r_refdef.stats.world_triangles += surface->num_triangles;
+ if (numsurfacelist >= maxsurfacelist)
+ {
+ r_refdef.stats.world_surfaces += numsurfacelist;
+ R_QueueSurfaceList(r_refdef.worldentity, numsurfacelist, surfacelist, flagsmask, writedepth, depthonly, addwaterplanes);
+ numsurfacelist = 0;
+ }
+ }
+ }
+ }
+ r_refdef.stats.world_surfaces += numsurfacelist;
+ if (numsurfacelist)
+ R_QueueSurfaceList(r_refdef.worldentity, numsurfacelist, surfacelist, flagsmask, writedepth, depthonly, addwaterplanes);
+ RSurf_CleanUp();
+}
+
+void R_DrawModelSurfaces(entity_render_t *ent, qboolean skysurfaces, qboolean writedepth, qboolean depthonly, qboolean addwaterplanes, qboolean debug)
+{
+ int i, f, flagsmask;
+ msurface_t *surface, *endsurface, **surfacechain;
+ texture_t *t;
+ model_t *model = ent->model;
+ const int maxsurfacelist = 1024;
+ int numsurfacelist = 0;
+ msurface_t *surfacelist[1024];
+ if (model == NULL)
+ return;
+
+ // if the model is static it doesn't matter what value we give for
+ // wantnormals and wanttangents, so this logic uses only rules applicable
+ // to a model, knowing that they are meaningless otherwise
+ if (ent == r_refdef.worldentity)
+ RSurf_ActiveWorldEntity();
+ else if ((ent->effects & EF_FULLBRIGHT) || r_showsurfaces.integer || VectorLength2(ent->modellight_diffuse) < (1.0f / 256.0f))
+ RSurf_ActiveModelEntity(ent, false, false);
+ else
+ RSurf_ActiveModelEntity(ent, true, r_glsl.integer && gl_support_fragment_shader && !depthonly);
+
+ // update light styles
+ if (!skysurfaces && !depthonly && !addwaterplanes && model->brushq1.light_styleupdatechains)
+ {
+ for (i = 0;i < model->brushq1.light_styles;i++)
+ {
+ if (model->brushq1.light_stylevalue[i] != r_refdef.lightstylevalue[model->brushq1.light_style[i]])
+ {
+ model->brushq1.light_stylevalue[i] = r_refdef.lightstylevalue[model->brushq1.light_style[i]];
+ if ((surfacechain = model->brushq1.light_styleupdatechains[i]))
+ for (;(surface = *surfacechain);surfacechain++)
+ surface->cached_dlight = true;
+ }
+ }
+ }
+
+ R_UpdateAllTextureInfo(ent);
+ flagsmask = addwaterplanes ? (MATERIALFLAG_WATERSHADER | MATERIALFLAG_REFRACTION | MATERIALFLAG_REFLECTION) : (skysurfaces ? MATERIALFLAG_SKY : (MATERIALFLAG_WATER | MATERIALFLAG_WALL));
+
+ if (debug)
+ {
+ R_DrawDebugModel(ent);
+ return;
+ }
+
+ f = 0;
+ t = NULL;
+ rsurface.uselightmaptexture = false;
+ rsurface.texture = NULL;
+ numsurfacelist = 0;
+ surface = model->data_surfaces + model->firstmodelsurface;
+ endsurface = surface + model->nummodelsurfaces;
+ for (;surface < endsurface;surface++)
+ {
+ // if this surface fits the criteria, add it to the list
+ if (surface->num_triangles)
+ {
+ // if lightmap parameters changed, rebuild lightmap texture
+ if (surface->cached_dlight)
+ R_BuildLightMap(ent, surface);
+ // add face to draw list
+ surfacelist[numsurfacelist++] = surface;
+ r_refdef.stats.entities_triangles += surface->num_triangles;
+ if (numsurfacelist >= maxsurfacelist)
+ {
+ r_refdef.stats.entities_surfaces += numsurfacelist;
+ R_QueueSurfaceList(ent, numsurfacelist, surfacelist, flagsmask, writedepth, depthonly, addwaterplanes);
+ numsurfacelist = 0;
+ }
+ }
+ }
+ r_refdef.stats.entities_surfaces += numsurfacelist;
+ if (numsurfacelist)
+ R_QueueSurfaceList(ent, numsurfacelist, surfacelist, flagsmask, writedepth, depthonly, addwaterplanes);
+ RSurf_CleanUp();
+}