ioq3/code/renderergl2/tr_shader.c
Zack Middleton 5d60f6035a OpenGL2: Fix hack for tcMod transform on merged lightmaps
When using merged lightmaps, only change tcMod transform for tcGen
lightmap.
2024-02-10 16:23:54 -05:00

4027 lines
100 KiB
C

/*
===========================================================================
Copyright (C) 1999-2005 Id Software, Inc.
This file is part of Quake III Arena source code.
Quake III Arena source code is free software; you can redistribute it
and/or modify it under the terms of the GNU General Public License as
published by the Free Software Foundation; either version 2 of the License,
or (at your option) any later version.
Quake III Arena source code is distributed in the hope that it will be
useful, but WITHOUT ANY WARRANTY; without even the implied warranty of
MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
GNU General Public License for more details.
You should have received a copy of the GNU General Public License
along with Quake III Arena source code; if not, write to the Free Software
Foundation, Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA
===========================================================================
*/
#include "tr_local.h"
// tr_shader.c -- this file deals with the parsing and definition of shaders
static char *s_shaderText;
// the shader is parsed into these global variables, then copied into
// dynamically allocated memory if it is valid.
static shaderStage_t stages[MAX_SHADER_STAGES];
static shader_t shader;
static texModInfo_t texMods[MAX_SHADER_STAGES][TR_MAX_TEXMODS];
static int shader_realLightmapIndex;
#define FILE_HASH_SIZE 1024
static shader_t* hashTable[FILE_HASH_SIZE];
#define MAX_SHADERTEXT_HASH 2048
static char **shaderTextHashTable[MAX_SHADERTEXT_HASH];
/*
================
return a hash value for the filename
================
*/
#ifdef __GNUCC__
#warning TODO: check if long is ok here
#endif
static long generateHashValue( const char *fname, const int size ) {
int i;
long hash;
char letter;
hash = 0;
i = 0;
while (fname[i] != '\0') {
letter = tolower(fname[i]);
if (letter =='.') break; // don't include extension
if (letter =='\\') letter = '/'; // damn path names
if (letter == PATH_SEP) letter = '/'; // damn path names
hash+=(long)(letter)*(i+119);
i++;
}
hash = (hash ^ (hash >> 10) ^ (hash >> 20));
hash &= (size-1);
return hash;
}
void R_RemapShader(const char *shaderName, const char *newShaderName, const char *timeOffset) {
char strippedName[MAX_QPATH];
int hash;
shader_t *sh, *sh2;
qhandle_t h;
sh = R_FindShaderByName( shaderName );
if (sh == NULL || sh == tr.defaultShader) {
h = RE_RegisterShaderLightMap(shaderName, 0);
sh = R_GetShaderByHandle(h);
}
if (sh == NULL || sh == tr.defaultShader) {
ri.Printf( PRINT_WARNING, "WARNING: R_RemapShader: shader %s not found\n", shaderName );
return;
}
sh2 = R_FindShaderByName( newShaderName );
if (sh2 == NULL || sh2 == tr.defaultShader) {
h = RE_RegisterShaderLightMap(newShaderName, 0);
sh2 = R_GetShaderByHandle(h);
}
if (sh2 == NULL || sh2 == tr.defaultShader) {
ri.Printf( PRINT_WARNING, "WARNING: R_RemapShader: new shader %s not found\n", newShaderName );
return;
}
// remap all the shaders with the given name
// even tho they might have different lightmaps
COM_StripExtension(shaderName, strippedName, sizeof(strippedName));
hash = generateHashValue(strippedName, FILE_HASH_SIZE);
for (sh = hashTable[hash]; sh; sh = sh->next) {
if (Q_stricmp(sh->name, strippedName) == 0) {
if (sh != sh2) {
sh->remappedShader = sh2;
} else {
sh->remappedShader = NULL;
}
}
}
if (timeOffset) {
sh2->timeOffset = atof(timeOffset);
}
}
/*
===============
ParseVector
===============
*/
static qboolean ParseVector( char **text, int count, float *v ) {
char *token;
int i;
// FIXME: spaces are currently required after parens, should change parseext...
token = COM_ParseExt( text, qfalse );
if ( strcmp( token, "(" ) ) {
ri.Printf( PRINT_WARNING, "WARNING: missing parenthesis in shader '%s'\n", shader.name );
return qfalse;
}
for ( i = 0 ; i < count ; i++ ) {
token = COM_ParseExt( text, qfalse );
if ( !token[0] ) {
ri.Printf( PRINT_WARNING, "WARNING: missing vector element in shader '%s'\n", shader.name );
return qfalse;
}
v[i] = atof( token );
}
token = COM_ParseExt( text, qfalse );
if ( strcmp( token, ")" ) ) {
ri.Printf( PRINT_WARNING, "WARNING: missing parenthesis in shader '%s'\n", shader.name );
return qfalse;
}
return qtrue;
}
/*
===============
NameToAFunc
===============
*/
static unsigned NameToAFunc( const char *funcname )
{
if ( !Q_stricmp( funcname, "GT0" ) )
{
return GLS_ATEST_GT_0;
}
else if ( !Q_stricmp( funcname, "LT128" ) )
{
return GLS_ATEST_LT_80;
}
else if ( !Q_stricmp( funcname, "GE128" ) )
{
return GLS_ATEST_GE_80;
}
ri.Printf( PRINT_WARNING, "WARNING: invalid alphaFunc name '%s' in shader '%s'\n", funcname, shader.name );
return 0;
}
/*
===============
NameToSrcBlendMode
===============
*/
static int NameToSrcBlendMode( const char *name )
{
if ( !Q_stricmp( name, "GL_ONE" ) )
{
return GLS_SRCBLEND_ONE;
}
else if ( !Q_stricmp( name, "GL_ZERO" ) )
{
return GLS_SRCBLEND_ZERO;
}
else if ( !Q_stricmp( name, "GL_DST_COLOR" ) )
{
return GLS_SRCBLEND_DST_COLOR;
}
else if ( !Q_stricmp( name, "GL_ONE_MINUS_DST_COLOR" ) )
{
return GLS_SRCBLEND_ONE_MINUS_DST_COLOR;
}
else if ( !Q_stricmp( name, "GL_SRC_ALPHA" ) )
{
return GLS_SRCBLEND_SRC_ALPHA;
}
else if ( !Q_stricmp( name, "GL_ONE_MINUS_SRC_ALPHA" ) )
{
return GLS_SRCBLEND_ONE_MINUS_SRC_ALPHA;
}
else if ( !Q_stricmp( name, "GL_DST_ALPHA" ) )
{
if (r_ignoreDstAlpha->integer)
return GLS_SRCBLEND_ONE;
return GLS_SRCBLEND_DST_ALPHA;
}
else if ( !Q_stricmp( name, "GL_ONE_MINUS_DST_ALPHA" ) )
{
if (r_ignoreDstAlpha->integer)
return GLS_SRCBLEND_ZERO;
return GLS_SRCBLEND_ONE_MINUS_DST_ALPHA;
}
else if ( !Q_stricmp( name, "GL_SRC_ALPHA_SATURATE" ) )
{
return GLS_SRCBLEND_ALPHA_SATURATE;
}
ri.Printf( PRINT_WARNING, "WARNING: unknown blend mode '%s' in shader '%s', substituting GL_ONE\n", name, shader.name );
return GLS_SRCBLEND_ONE;
}
/*
===============
NameToDstBlendMode
===============
*/
static int NameToDstBlendMode( const char *name )
{
if ( !Q_stricmp( name, "GL_ONE" ) )
{
return GLS_DSTBLEND_ONE;
}
else if ( !Q_stricmp( name, "GL_ZERO" ) )
{
return GLS_DSTBLEND_ZERO;
}
else if ( !Q_stricmp( name, "GL_SRC_ALPHA" ) )
{
return GLS_DSTBLEND_SRC_ALPHA;
}
else if ( !Q_stricmp( name, "GL_ONE_MINUS_SRC_ALPHA" ) )
{
return GLS_DSTBLEND_ONE_MINUS_SRC_ALPHA;
}
else if ( !Q_stricmp( name, "GL_DST_ALPHA" ) )
{
if (r_ignoreDstAlpha->integer)
return GLS_DSTBLEND_ONE;
return GLS_DSTBLEND_DST_ALPHA;
}
else if ( !Q_stricmp( name, "GL_ONE_MINUS_DST_ALPHA" ) )
{
if (r_ignoreDstAlpha->integer)
return GLS_DSTBLEND_ZERO;
return GLS_DSTBLEND_ONE_MINUS_DST_ALPHA;
}
else if ( !Q_stricmp( name, "GL_SRC_COLOR" ) )
{
return GLS_DSTBLEND_SRC_COLOR;
}
else if ( !Q_stricmp( name, "GL_ONE_MINUS_SRC_COLOR" ) )
{
return GLS_DSTBLEND_ONE_MINUS_SRC_COLOR;
}
ri.Printf( PRINT_WARNING, "WARNING: unknown blend mode '%s' in shader '%s', substituting GL_ONE\n", name, shader.name );
return GLS_DSTBLEND_ONE;
}
/*
===============
NameToGenFunc
===============
*/
static genFunc_t NameToGenFunc( const char *funcname )
{
if ( !Q_stricmp( funcname, "sin" ) )
{
return GF_SIN;
}
else if ( !Q_stricmp( funcname, "square" ) )
{
return GF_SQUARE;
}
else if ( !Q_stricmp( funcname, "triangle" ) )
{
return GF_TRIANGLE;
}
else if ( !Q_stricmp( funcname, "sawtooth" ) )
{
return GF_SAWTOOTH;
}
else if ( !Q_stricmp( funcname, "inversesawtooth" ) )
{
return GF_INVERSE_SAWTOOTH;
}
else if ( !Q_stricmp( funcname, "noise" ) )
{
return GF_NOISE;
}
ri.Printf( PRINT_WARNING, "WARNING: invalid genfunc name '%s' in shader '%s'\n", funcname, shader.name );
return GF_SIN;
}
/*
===================
ParseWaveForm
===================
*/
static void ParseWaveForm( char **text, waveForm_t *wave )
{
char *token;
token = COM_ParseExt( text, qfalse );
if ( token[0] == 0 )
{
ri.Printf( PRINT_WARNING, "WARNING: missing waveform parm in shader '%s'\n", shader.name );
return;
}
wave->func = NameToGenFunc( token );
// BASE, AMP, PHASE, FREQ
token = COM_ParseExt( text, qfalse );
if ( token[0] == 0 )
{
ri.Printf( PRINT_WARNING, "WARNING: missing waveform parm in shader '%s'\n", shader.name );
return;
}
wave->base = atof( token );
token = COM_ParseExt( text, qfalse );
if ( token[0] == 0 )
{
ri.Printf( PRINT_WARNING, "WARNING: missing waveform parm in shader '%s'\n", shader.name );
return;
}
wave->amplitude = atof( token );
token = COM_ParseExt( text, qfalse );
if ( token[0] == 0 )
{
ri.Printf( PRINT_WARNING, "WARNING: missing waveform parm in shader '%s'\n", shader.name );
return;
}
wave->phase = atof( token );
token = COM_ParseExt( text, qfalse );
if ( token[0] == 0 )
{
ri.Printf( PRINT_WARNING, "WARNING: missing waveform parm in shader '%s'\n", shader.name );
return;
}
wave->frequency = atof( token );
}
/*
===================
ParseTexMod
===================
*/
static void ParseTexMod( char *_text, shaderStage_t *stage )
{
const char *token;
char **text = &_text;
texModInfo_t *tmi;
if ( stage->bundle[0].numTexMods == TR_MAX_TEXMODS ) {
ri.Error( ERR_DROP, "ERROR: too many tcMod stages in shader '%s'", shader.name );
return;
}
tmi = &stage->bundle[0].texMods[stage->bundle[0].numTexMods];
stage->bundle[0].numTexMods++;
token = COM_ParseExt( text, qfalse );
//
// turb
//
if ( !Q_stricmp( token, "turb" ) )
{
token = COM_ParseExt( text, qfalse );
if ( token[0] == 0 )
{
ri.Printf( PRINT_WARNING, "WARNING: missing tcMod turb parms in shader '%s'\n", shader.name );
return;
}
tmi->wave.base = atof( token );
token = COM_ParseExt( text, qfalse );
if ( token[0] == 0 )
{
ri.Printf( PRINT_WARNING, "WARNING: missing tcMod turb in shader '%s'\n", shader.name );
return;
}
tmi->wave.amplitude = atof( token );
token = COM_ParseExt( text, qfalse );
if ( token[0] == 0 )
{
ri.Printf( PRINT_WARNING, "WARNING: missing tcMod turb in shader '%s'\n", shader.name );
return;
}
tmi->wave.phase = atof( token );
token = COM_ParseExt( text, qfalse );
if ( token[0] == 0 )
{
ri.Printf( PRINT_WARNING, "WARNING: missing tcMod turb in shader '%s'\n", shader.name );
return;
}
tmi->wave.frequency = atof( token );
tmi->type = TMOD_TURBULENT;
}
//
// scale
//
else if ( !Q_stricmp( token, "scale" ) )
{
token = COM_ParseExt( text, qfalse );
if ( token[0] == 0 )
{
ri.Printf( PRINT_WARNING, "WARNING: missing scale parms in shader '%s'\n", shader.name );
return;
}
tmi->scale[0] = atof( token );
token = COM_ParseExt( text, qfalse );
if ( token[0] == 0 )
{
ri.Printf( PRINT_WARNING, "WARNING: missing scale parms in shader '%s'\n", shader.name );
return;
}
tmi->scale[1] = atof( token );
tmi->type = TMOD_SCALE;
}
//
// scroll
//
else if ( !Q_stricmp( token, "scroll" ) )
{
token = COM_ParseExt( text, qfalse );
if ( token[0] == 0 )
{
ri.Printf( PRINT_WARNING, "WARNING: missing scale scroll parms in shader '%s'\n", shader.name );
return;
}
tmi->scroll[0] = atof( token );
token = COM_ParseExt( text, qfalse );
if ( token[0] == 0 )
{
ri.Printf( PRINT_WARNING, "WARNING: missing scale scroll parms in shader '%s'\n", shader.name );
return;
}
tmi->scroll[1] = atof( token );
tmi->type = TMOD_SCROLL;
}
//
// stretch
//
else if ( !Q_stricmp( token, "stretch" ) )
{
token = COM_ParseExt( text, qfalse );
if ( token[0] == 0 )
{
ri.Printf( PRINT_WARNING, "WARNING: missing stretch parms in shader '%s'\n", shader.name );
return;
}
tmi->wave.func = NameToGenFunc( token );
token = COM_ParseExt( text, qfalse );
if ( token[0] == 0 )
{
ri.Printf( PRINT_WARNING, "WARNING: missing stretch parms in shader '%s'\n", shader.name );
return;
}
tmi->wave.base = atof( token );
token = COM_ParseExt( text, qfalse );
if ( token[0] == 0 )
{
ri.Printf( PRINT_WARNING, "WARNING: missing stretch parms in shader '%s'\n", shader.name );
return;
}
tmi->wave.amplitude = atof( token );
token = COM_ParseExt( text, qfalse );
if ( token[0] == 0 )
{
ri.Printf( PRINT_WARNING, "WARNING: missing stretch parms in shader '%s'\n", shader.name );
return;
}
tmi->wave.phase = atof( token );
token = COM_ParseExt( text, qfalse );
if ( token[0] == 0 )
{
ri.Printf( PRINT_WARNING, "WARNING: missing stretch parms in shader '%s'\n", shader.name );
return;
}
tmi->wave.frequency = atof( token );
tmi->type = TMOD_STRETCH;
}
//
// transform
//
else if ( !Q_stricmp( token, "transform" ) )
{
token = COM_ParseExt( text, qfalse );
if ( token[0] == 0 )
{
ri.Printf( PRINT_WARNING, "WARNING: missing transform parms in shader '%s'\n", shader.name );
return;
}
tmi->matrix[0][0] = atof( token );
token = COM_ParseExt( text, qfalse );
if ( token[0] == 0 )
{
ri.Printf( PRINT_WARNING, "WARNING: missing transform parms in shader '%s'\n", shader.name );
return;
}
tmi->matrix[0][1] = atof( token );
token = COM_ParseExt( text, qfalse );
if ( token[0] == 0 )
{
ri.Printf( PRINT_WARNING, "WARNING: missing transform parms in shader '%s'\n", shader.name );
return;
}
tmi->matrix[1][0] = atof( token );
token = COM_ParseExt( text, qfalse );
if ( token[0] == 0 )
{
ri.Printf( PRINT_WARNING, "WARNING: missing transform parms in shader '%s'\n", shader.name );
return;
}
tmi->matrix[1][1] = atof( token );
token = COM_ParseExt( text, qfalse );
if ( token[0] == 0 )
{
ri.Printf( PRINT_WARNING, "WARNING: missing transform parms in shader '%s'\n", shader.name );
return;
}
tmi->translate[0] = atof( token );
token = COM_ParseExt( text, qfalse );
if ( token[0] == 0 )
{
ri.Printf( PRINT_WARNING, "WARNING: missing transform parms in shader '%s'\n", shader.name );
return;
}
tmi->translate[1] = atof( token );
tmi->type = TMOD_TRANSFORM;
}
//
// rotate
//
else if ( !Q_stricmp( token, "rotate" ) )
{
token = COM_ParseExt( text, qfalse );
if ( token[0] == 0 )
{
ri.Printf( PRINT_WARNING, "WARNING: missing tcMod rotate parms in shader '%s'\n", shader.name );
return;
}
tmi->rotateSpeed = atof( token );
tmi->type = TMOD_ROTATE;
}
//
// entityTranslate
//
else if ( !Q_stricmp( token, "entityTranslate" ) )
{
tmi->type = TMOD_ENTITY_TRANSLATE;
}
else
{
ri.Printf( PRINT_WARNING, "WARNING: unknown tcMod '%s' in shader '%s'\n", token, shader.name );
}
}
/*
===================
ParseStage
===================
*/
static qboolean ParseStage( shaderStage_t *stage, char **text )
{
char *token;
int depthMaskBits = GLS_DEPTHMASK_TRUE, blendSrcBits = 0, blendDstBits = 0, atestBits = 0, depthFuncBits = 0;
qboolean depthMaskExplicit = qfalse;
stage->active = qtrue;
while ( 1 )
{
token = COM_ParseExt( text, qtrue );
if ( !token[0] )
{
ri.Printf( PRINT_WARNING, "WARNING: no matching '}' found\n" );
return qfalse;
}
if ( token[0] == '}' )
{
break;
}
//
// map <name>
//
else if ( !Q_stricmp( token, "map" ) )
{
token = COM_ParseExt( text, qfalse );
if ( !token[0] )
{
ri.Printf( PRINT_WARNING, "WARNING: missing parameter for 'map' keyword in shader '%s'\n", shader.name );
return qfalse;
}
if ( !Q_stricmp( token, "$whiteimage" ) )
{
stage->bundle[0].image[0] = tr.whiteImage;
continue;
}
else if ( !Q_stricmp( token, "$lightmap" ) )
{
stage->bundle[0].isLightmap = qtrue;
if ( shader.lightmapIndex < 0 || !tr.lightmaps ) {
stage->bundle[0].image[0] = tr.whiteImage;
} else {
stage->bundle[0].image[0] = tr.lightmaps[shader.lightmapIndex];
}
continue;
}
else if ( !Q_stricmp( token, "$deluxemap" ) )
{
if (!tr.worldDeluxeMapping)
{
ri.Printf( PRINT_WARNING, "WARNING: shader '%s' wants a deluxe map in a map compiled without them\n", shader.name );
return qfalse;
}
stage->bundle[0].isLightmap = qtrue;
if ( shader.lightmapIndex < 0 ) {
stage->bundle[0].image[0] = tr.whiteImage;
} else {
stage->bundle[0].image[0] = tr.deluxemaps[shader.lightmapIndex];
}
continue;
}
else
{
imgType_t type = IMGTYPE_COLORALPHA;
imgFlags_t flags = IMGFLAG_NONE;
if (!shader.noMipMaps)
flags |= IMGFLAG_MIPMAP;
if (!shader.noPicMip)
flags |= IMGFLAG_PICMIP;
if (stage->type == ST_NORMALMAP || stage->type == ST_NORMALPARALLAXMAP)
{
type = IMGTYPE_NORMAL;
flags |= IMGFLAG_NOLIGHTSCALE;
if (stage->type == ST_NORMALPARALLAXMAP)
type = IMGTYPE_NORMALHEIGHT;
}
else
{
if (r_genNormalMaps->integer)
flags |= IMGFLAG_GENNORMALMAP;
}
stage->bundle[0].image[0] = R_FindImageFile( token, type, flags );
if ( !stage->bundle[0].image[0] )
{
ri.Printf( PRINT_WARNING, "WARNING: R_FindImageFile could not find '%s' in shader '%s'\n", token, shader.name );
return qfalse;
}
}
}
//
// clampmap <name>
//
else if ( !Q_stricmp( token, "clampmap" ) )
{
imgType_t type = IMGTYPE_COLORALPHA;
imgFlags_t flags = IMGFLAG_CLAMPTOEDGE;
token = COM_ParseExt( text, qfalse );
if ( !token[0] )
{
ri.Printf( PRINT_WARNING, "WARNING: missing parameter for 'clampmap' keyword in shader '%s'\n", shader.name );
return qfalse;
}
if (!shader.noMipMaps)
flags |= IMGFLAG_MIPMAP;
if (!shader.noPicMip)
flags |= IMGFLAG_PICMIP;
if (stage->type == ST_NORMALMAP || stage->type == ST_NORMALPARALLAXMAP)
{
type = IMGTYPE_NORMAL;
flags |= IMGFLAG_NOLIGHTSCALE;
if (stage->type == ST_NORMALPARALLAXMAP)
type = IMGTYPE_NORMALHEIGHT;
}
else
{
if (r_genNormalMaps->integer)
flags |= IMGFLAG_GENNORMALMAP;
}
stage->bundle[0].image[0] = R_FindImageFile( token, type, flags );
if ( !stage->bundle[0].image[0] )
{
ri.Printf( PRINT_WARNING, "WARNING: R_FindImageFile could not find '%s' in shader '%s'\n", token, shader.name );
return qfalse;
}
}
//
// animMap <frequency> <image1> .... <imageN>
//
else if ( !Q_stricmp( token, "animMap" ) )
{
int totalImages = 0;
token = COM_ParseExt( text, qfalse );
if ( !token[0] )
{
ri.Printf( PRINT_WARNING, "WARNING: missing parameter for 'animMap' keyword in shader '%s'\n", shader.name );
return qfalse;
}
stage->bundle[0].imageAnimationSpeed = atof( token );
// parse up to MAX_IMAGE_ANIMATIONS animations
while ( 1 ) {
int num;
token = COM_ParseExt( text, qfalse );
if ( !token[0] ) {
break;
}
num = stage->bundle[0].numImageAnimations;
if ( num < MAX_IMAGE_ANIMATIONS ) {
imgFlags_t flags = IMGFLAG_NONE;
if (!shader.noMipMaps)
flags |= IMGFLAG_MIPMAP;
if (!shader.noPicMip)
flags |= IMGFLAG_PICMIP;
stage->bundle[0].image[num] = R_FindImageFile( token, IMGTYPE_COLORALPHA, flags );
if ( !stage->bundle[0].image[num] )
{
ri.Printf( PRINT_WARNING, "WARNING: R_FindImageFile could not find '%s' in shader '%s'\n", token, shader.name );
return qfalse;
}
stage->bundle[0].numImageAnimations++;
}
totalImages++;
}
if ( totalImages > MAX_IMAGE_ANIMATIONS ) {
ri.Printf( PRINT_WARNING, "WARNING: ignoring excess images for 'animMap' (found %d, max is %d) in shader '%s'\n",
totalImages, MAX_IMAGE_ANIMATIONS, shader.name );
}
}
else if ( !Q_stricmp( token, "videoMap" ) )
{
token = COM_ParseExt( text, qfalse );
if ( !token[0] )
{
ri.Printf( PRINT_WARNING, "WARNING: missing parameter for 'videoMap' keyword in shader '%s'\n", shader.name );
return qfalse;
}
stage->bundle[0].videoMapHandle = ri.CIN_PlayCinematic( token, 0, 0, 256, 256, (CIN_loop | CIN_silent | CIN_shader));
if (stage->bundle[0].videoMapHandle != -1) {
stage->bundle[0].isVideoMap = qtrue;
stage->bundle[0].image[0] = tr.scratchImage[stage->bundle[0].videoMapHandle];
} else {
ri.Printf( PRINT_WARNING, "WARNING: could not load '%s' for 'videoMap' keyword in shader '%s'\n", token, shader.name );
}
}
//
// alphafunc <func>
//
else if ( !Q_stricmp( token, "alphaFunc" ) )
{
token = COM_ParseExt( text, qfalse );
if ( !token[0] )
{
ri.Printf( PRINT_WARNING, "WARNING: missing parameter for 'alphaFunc' keyword in shader '%s'\n", shader.name );
return qfalse;
}
atestBits = NameToAFunc( token );
}
//
// depthFunc <func>
//
else if ( !Q_stricmp( token, "depthfunc" ) )
{
token = COM_ParseExt( text, qfalse );
if ( !token[0] )
{
ri.Printf( PRINT_WARNING, "WARNING: missing parameter for 'depthfunc' keyword in shader '%s'\n", shader.name );
return qfalse;
}
if ( !Q_stricmp( token, "lequal" ) )
{
depthFuncBits = 0;
}
else if ( !Q_stricmp( token, "equal" ) )
{
depthFuncBits = GLS_DEPTHFUNC_EQUAL;
}
else
{
ri.Printf( PRINT_WARNING, "WARNING: unknown depthfunc '%s' in shader '%s'\n", token, shader.name );
continue;
}
}
//
// detail
//
else if ( !Q_stricmp( token, "detail" ) )
{
stage->isDetail = qtrue;
}
//
// blendfunc <srcFactor> <dstFactor>
// or blendfunc <add|filter|blend>
//
else if ( !Q_stricmp( token, "blendfunc" ) )
{
token = COM_ParseExt( text, qfalse );
if ( token[0] == 0 )
{
ri.Printf( PRINT_WARNING, "WARNING: missing parm for blendFunc in shader '%s'\n", shader.name );
continue;
}
// check for "simple" blends first
if ( !Q_stricmp( token, "add" ) ) {
blendSrcBits = GLS_SRCBLEND_ONE;
blendDstBits = GLS_DSTBLEND_ONE;
} else if ( !Q_stricmp( token, "filter" ) ) {
blendSrcBits = GLS_SRCBLEND_DST_COLOR;
blendDstBits = GLS_DSTBLEND_ZERO;
} else if ( !Q_stricmp( token, "blend" ) ) {
blendSrcBits = GLS_SRCBLEND_SRC_ALPHA;
blendDstBits = GLS_DSTBLEND_ONE_MINUS_SRC_ALPHA;
} else {
// complex double blends
blendSrcBits = NameToSrcBlendMode( token );
token = COM_ParseExt( text, qfalse );
if ( token[0] == 0 )
{
ri.Printf( PRINT_WARNING, "WARNING: missing parm for blendFunc in shader '%s'\n", shader.name );
continue;
}
blendDstBits = NameToDstBlendMode( token );
}
// clear depth mask for blended surfaces
if ( !depthMaskExplicit )
{
depthMaskBits = 0;
}
}
//
// stage <type>
//
else if(!Q_stricmp(token, "stage"))
{
token = COM_ParseExt(text, qfalse);
if(token[0] == 0)
{
ri.Printf(PRINT_WARNING, "WARNING: missing parameters for stage in shader '%s'\n", shader.name);
continue;
}
if(!Q_stricmp(token, "diffuseMap"))
{
stage->type = ST_DIFFUSEMAP;
}
else if(!Q_stricmp(token, "normalMap") || !Q_stricmp(token, "bumpMap"))
{
stage->type = ST_NORMALMAP;
VectorSet4(stage->normalScale, r_baseNormalX->value, r_baseNormalY->value, 1.0f, r_baseParallax->value);
}
else if(!Q_stricmp(token, "normalParallaxMap") || !Q_stricmp(token, "bumpParallaxMap"))
{
if (r_parallaxMapping->integer)
stage->type = ST_NORMALPARALLAXMAP;
else
stage->type = ST_NORMALMAP;
VectorSet4(stage->normalScale, r_baseNormalX->value, r_baseNormalY->value, 1.0f, r_baseParallax->value);
}
else if(!Q_stricmp(token, "specularMap"))
{
stage->type = ST_SPECULARMAP;
VectorSet4(stage->specularScale, 1.0f, 1.0f, 1.0f, 1.0f);
}
else
{
ri.Printf(PRINT_WARNING, "WARNING: unknown stage parameter '%s' in shader '%s'\n", token, shader.name);
continue;
}
}
//
// specularReflectance <value>
//
else if (!Q_stricmp(token, "specularreflectance"))
{
token = COM_ParseExt(text, qfalse);
if ( token[0] == 0 )
{
ri.Printf( PRINT_WARNING, "WARNING: missing parameter for specular reflectance in shader '%s'\n", shader.name );
continue;
}
if (r_pbr->integer)
{
// interpret specularReflectance < 0.5 as nonmetal
stage->specularScale[1] = (atof(token) < 0.5f) ? 0.0f : 1.0f;
}
else
{
stage->specularScale[0] =
stage->specularScale[1] =
stage->specularScale[2] = atof( token );
}
}
//
// specularExponent <value>
//
else if (!Q_stricmp(token, "specularexponent"))
{
float exponent;
token = COM_ParseExt(text, qfalse);
if ( token[0] == 0 )
{
ri.Printf( PRINT_WARNING, "WARNING: missing parameter for specular exponent in shader '%s'\n", shader.name );
continue;
}
exponent = atof( token );
if (r_pbr->integer)
stage->specularScale[0] = 1.0f - powf(2.0f / (exponent + 2.0), 0.25);
else
{
// Change shininess to gloss
// Assumes max exponent of 8190 and min of 0, must change here if altered in lightall_fp.glsl
exponent = CLAMP(exponent, 0.0f, 8190.0f);
stage->specularScale[3] = (log2f(exponent + 2.0f) - 1.0f) / 12.0f;
}
}
//
// gloss <value>
//
else if (!Q_stricmp(token, "gloss"))
{
float gloss;
token = COM_ParseExt(text, qfalse);
if ( token[0] == 0 )
{
ri.Printf( PRINT_WARNING, "WARNING: missing parameter for gloss in shader '%s'\n", shader.name );
continue;
}
gloss = atof(token);
if (r_pbr->integer)
stage->specularScale[0] = 1.0f - exp2f(-3.0f * gloss);
else
stage->specularScale[3] = gloss;
}
//
// roughness <value>
//
else if (!Q_stricmp(token, "roughness"))
{
float roughness;
token = COM_ParseExt(text, qfalse);
if (token[0] == 0)
{
ri.Printf(PRINT_WARNING, "WARNING: missing parameter for roughness in shader '%s'\n", shader.name);
continue;
}
roughness = atof(token);
if (r_pbr->integer)
stage->specularScale[0] = 1.0 - roughness;
else
{
if (roughness >= 0.125)
stage->specularScale[3] = log2f(1.0f / roughness) / 3.0f;
else
stage->specularScale[3] = 1.0f;
}
}
//
// parallaxDepth <value>
//
else if (!Q_stricmp(token, "parallaxdepth"))
{
token = COM_ParseExt(text, qfalse);
if ( token[0] == 0 )
{
ri.Printf( PRINT_WARNING, "WARNING: missing parameter for parallaxDepth in shader '%s'\n", shader.name );
continue;
}
stage->normalScale[3] = atof( token );
}
//
// normalScale <xy>
// or normalScale <x> <y>
// or normalScale <x> <y> <height>
//
else if (!Q_stricmp(token, "normalscale"))
{
token = COM_ParseExt(text, qfalse);
if ( token[0] == 0 )
{
ri.Printf( PRINT_WARNING, "WARNING: missing parameter for normalScale in shader '%s'\n", shader.name );
continue;
}
stage->normalScale[0] = atof( token );
token = COM_ParseExt(text, qfalse);
if ( token[0] == 0 )
{
// one value, applies to X/Y
stage->normalScale[1] = stage->normalScale[0];
continue;
}
stage->normalScale[1] = atof( token );
token = COM_ParseExt(text, qfalse);
if ( token[0] == 0 )
{
// two values, no height
continue;
}
stage->normalScale[3] = atof( token );
}
//
// specularScale <rgb> <gloss>
// or specularScale <metallic> <smoothness> with r_pbr 1
// or specularScale <r> <g> <b>
// or specularScale <r> <g> <b> <gloss>
//
else if (!Q_stricmp(token, "specularscale"))
{
token = COM_ParseExt(text, qfalse);
if ( token[0] == 0 )
{
ri.Printf( PRINT_WARNING, "WARNING: missing parameter for specularScale in shader '%s'\n", shader.name );
continue;
}
stage->specularScale[0] = atof( token );
token = COM_ParseExt(text, qfalse);
if ( token[0] == 0 )
{
ri.Printf( PRINT_WARNING, "WARNING: missing parameter for specularScale in shader '%s'\n", shader.name );
continue;
}
stage->specularScale[1] = atof( token );
token = COM_ParseExt(text, qfalse);
if ( token[0] == 0 )
{
if (r_pbr->integer)
{
// two values, metallic then smoothness
float smoothness = stage->specularScale[1];
stage->specularScale[1] = (stage->specularScale[0] < 0.5f) ? 0.0f : 1.0f;
stage->specularScale[0] = smoothness;
}
else
{
// two values, rgb then gloss
stage->specularScale[3] = stage->specularScale[1];
stage->specularScale[1] =
stage->specularScale[2] = stage->specularScale[0];
}
continue;
}
stage->specularScale[2] = atof( token );
token = COM_ParseExt(text, qfalse);
if ( token[0] == 0 )
{
// three values, rgb
continue;
}
stage->specularScale[3] = atof( token );
}
//
// rgbGen
//
else if ( !Q_stricmp( token, "rgbGen" ) )
{
token = COM_ParseExt( text, qfalse );
if ( token[0] == 0 )
{
ri.Printf( PRINT_WARNING, "WARNING: missing parameters for rgbGen in shader '%s'\n", shader.name );
continue;
}
if ( !Q_stricmp( token, "wave" ) )
{
ParseWaveForm( text, &stage->rgbWave );
stage->rgbGen = CGEN_WAVEFORM;
}
else if ( !Q_stricmp( token, "const" ) )
{
vec3_t color;
VectorClear( color );
ParseVector( text, 3, color );
stage->constantColor[0] = 255 * color[0];
stage->constantColor[1] = 255 * color[1];
stage->constantColor[2] = 255 * color[2];
stage->rgbGen = CGEN_CONST;
}
else if ( !Q_stricmp( token, "identity" ) )
{
stage->rgbGen = CGEN_IDENTITY;
}
else if ( !Q_stricmp( token, "identityLighting" ) )
{
stage->rgbGen = CGEN_IDENTITY_LIGHTING;
}
else if ( !Q_stricmp( token, "entity" ) )
{
stage->rgbGen = CGEN_ENTITY;
}
else if ( !Q_stricmp( token, "oneMinusEntity" ) )
{
stage->rgbGen = CGEN_ONE_MINUS_ENTITY;
}
else if ( !Q_stricmp( token, "vertex" ) )
{
stage->rgbGen = CGEN_VERTEX;
if ( stage->alphaGen == 0 ) {
stage->alphaGen = AGEN_VERTEX;
}
}
else if ( !Q_stricmp( token, "exactVertex" ) )
{
stage->rgbGen = CGEN_EXACT_VERTEX;
}
else if ( !Q_stricmp( token, "vertexLit" ) )
{
stage->rgbGen = CGEN_VERTEX_LIT;
if ( stage->alphaGen == 0 ) {
stage->alphaGen = AGEN_VERTEX;
}
}
else if ( !Q_stricmp( token, "exactVertexLit" ) )
{
stage->rgbGen = CGEN_EXACT_VERTEX_LIT;
}
else if ( !Q_stricmp( token, "lightingDiffuse" ) )
{
stage->rgbGen = CGEN_LIGHTING_DIFFUSE;
}
else if ( !Q_stricmp( token, "oneMinusVertex" ) )
{
stage->rgbGen = CGEN_ONE_MINUS_VERTEX;
}
else
{
ri.Printf( PRINT_WARNING, "WARNING: unknown rgbGen parameter '%s' in shader '%s'\n", token, shader.name );
continue;
}
}
//
// alphaGen
//
else if ( !Q_stricmp( token, "alphaGen" ) )
{
token = COM_ParseExt( text, qfalse );
if ( token[0] == 0 )
{
ri.Printf( PRINT_WARNING, "WARNING: missing parameters for alphaGen in shader '%s'\n", shader.name );
continue;
}
if ( !Q_stricmp( token, "wave" ) )
{
ParseWaveForm( text, &stage->alphaWave );
stage->alphaGen = AGEN_WAVEFORM;
}
else if ( !Q_stricmp( token, "const" ) )
{
token = COM_ParseExt( text, qfalse );
stage->constantColor[3] = 255 * atof( token );
stage->alphaGen = AGEN_CONST;
}
else if ( !Q_stricmp( token, "identity" ) )
{
stage->alphaGen = AGEN_IDENTITY;
}
else if ( !Q_stricmp( token, "entity" ) )
{
stage->alphaGen = AGEN_ENTITY;
}
else if ( !Q_stricmp( token, "oneMinusEntity" ) )
{
stage->alphaGen = AGEN_ONE_MINUS_ENTITY;
}
else if ( !Q_stricmp( token, "vertex" ) )
{
stage->alphaGen = AGEN_VERTEX;
}
else if ( !Q_stricmp( token, "lightingSpecular" ) )
{
stage->alphaGen = AGEN_LIGHTING_SPECULAR;
}
else if ( !Q_stricmp( token, "oneMinusVertex" ) )
{
stage->alphaGen = AGEN_ONE_MINUS_VERTEX;
}
else if ( !Q_stricmp( token, "portal" ) )
{
stage->alphaGen = AGEN_PORTAL;
token = COM_ParseExt( text, qfalse );
if ( token[0] == 0 )
{
shader.portalRange = 256;
ri.Printf( PRINT_WARNING, "WARNING: missing range parameter for alphaGen portal in shader '%s', defaulting to 256\n", shader.name );
}
else
{
shader.portalRange = atof( token );
}
}
else
{
ri.Printf( PRINT_WARNING, "WARNING: unknown alphaGen parameter '%s' in shader '%s'\n", token, shader.name );
continue;
}
}
//
// tcGen <function>
//
else if ( !Q_stricmp(token, "texgen") || !Q_stricmp( token, "tcGen" ) )
{
token = COM_ParseExt( text, qfalse );
if ( token[0] == 0 )
{
ri.Printf( PRINT_WARNING, "WARNING: missing texgen parm in shader '%s'\n", shader.name );
continue;
}
if ( !Q_stricmp( token, "environment" ) )
{
stage->bundle[0].tcGen = TCGEN_ENVIRONMENT_MAPPED;
}
else if ( !Q_stricmp( token, "lightmap" ) )
{
stage->bundle[0].tcGen = TCGEN_LIGHTMAP;
}
else if ( !Q_stricmp( token, "texture" ) || !Q_stricmp( token, "base" ) )
{
stage->bundle[0].tcGen = TCGEN_TEXTURE;
}
else if ( !Q_stricmp( token, "vector" ) )
{
ParseVector( text, 3, stage->bundle[0].tcGenVectors[0] );
ParseVector( text, 3, stage->bundle[0].tcGenVectors[1] );
stage->bundle[0].tcGen = TCGEN_VECTOR;
}
else
{
ri.Printf( PRINT_WARNING, "WARNING: unknown texgen parm in shader '%s'\n", shader.name );
}
}
//
// tcMod <type> <...>
//
else if ( !Q_stricmp( token, "tcMod" ) )
{
char buffer[1024] = "";
while ( 1 )
{
token = COM_ParseExt( text, qfalse );
if ( token[0] == 0 )
break;
Q_strcat( buffer, sizeof (buffer), token );
Q_strcat( buffer, sizeof (buffer), " " );
}
ParseTexMod( buffer, stage );
continue;
}
//
// depthmask
//
else if ( !Q_stricmp( token, "depthwrite" ) )
{
depthMaskBits = GLS_DEPTHMASK_TRUE;
depthMaskExplicit = qtrue;
continue;
}
else
{
ri.Printf( PRINT_WARNING, "WARNING: unknown parameter '%s' in shader '%s'\n", token, shader.name );
return qfalse;
}
}
//
// if cgen isn't explicitly specified, use either identity or identitylighting
//
if ( stage->rgbGen == CGEN_BAD ) {
if ( blendSrcBits == 0 ||
blendSrcBits == GLS_SRCBLEND_ONE ||
blendSrcBits == GLS_SRCBLEND_SRC_ALPHA ) {
stage->rgbGen = CGEN_IDENTITY_LIGHTING;
} else {
stage->rgbGen = CGEN_IDENTITY;
}
}
//
// implicitly assume that a GL_ONE GL_ZERO blend mask disables blending
//
if ( ( blendSrcBits == GLS_SRCBLEND_ONE ) &&
( blendDstBits == GLS_DSTBLEND_ZERO ) )
{
blendDstBits = blendSrcBits = 0;
depthMaskBits = GLS_DEPTHMASK_TRUE;
}
// decide which agens we can skip
if ( stage->alphaGen == AGEN_IDENTITY ) {
if ( stage->rgbGen == CGEN_IDENTITY
|| stage->rgbGen == CGEN_LIGHTING_DIFFUSE ) {
stage->alphaGen = AGEN_SKIP;
}
}
//
// compute state bits
//
stage->stateBits = depthMaskBits |
blendSrcBits | blendDstBits |
atestBits |
depthFuncBits;
return qtrue;
}
/*
===============
ParseDeform
deformVertexes wave <spread> <waveform> <base> <amplitude> <phase> <frequency>
deformVertexes normal <frequency> <amplitude>
deformVertexes move <vector> <waveform> <base> <amplitude> <phase> <frequency>
deformVertexes bulge <bulgeWidth> <bulgeHeight> <bulgeSpeed>
deformVertexes projectionShadow
deformVertexes autoSprite
deformVertexes autoSprite2
deformVertexes text[0-7]
===============
*/
static void ParseDeform( char **text ) {
char *token;
deformStage_t *ds;
token = COM_ParseExt( text, qfalse );
if ( token[0] == 0 )
{
ri.Printf( PRINT_WARNING, "WARNING: missing deform parm in shader '%s'\n", shader.name );
return;
}
if ( shader.numDeforms == MAX_SHADER_DEFORMS ) {
ri.Printf( PRINT_WARNING, "WARNING: MAX_SHADER_DEFORMS in '%s'\n", shader.name );
return;
}
ds = &shader.deforms[ shader.numDeforms ];
shader.numDeforms++;
if ( !Q_stricmp( token, "projectionShadow" ) ) {
ds->deformation = DEFORM_PROJECTION_SHADOW;
return;
}
if ( !Q_stricmp( token, "autosprite" ) ) {
ds->deformation = DEFORM_AUTOSPRITE;
return;
}
if ( !Q_stricmp( token, "autosprite2" ) ) {
ds->deformation = DEFORM_AUTOSPRITE2;
return;
}
if ( !Q_stricmpn( token, "text", 4 ) ) {
int n;
n = token[4] - '0';
if ( n < 0 || n > 7 ) {
n = 0;
}
ds->deformation = DEFORM_TEXT0 + n;
return;
}
if ( !Q_stricmp( token, "bulge" ) ) {
token = COM_ParseExt( text, qfalse );
if ( token[0] == 0 )
{
ri.Printf( PRINT_WARNING, "WARNING: missing deformVertexes bulge parm in shader '%s'\n", shader.name );
return;
}
ds->bulgeWidth = atof( token );
token = COM_ParseExt( text, qfalse );
if ( token[0] == 0 )
{
ri.Printf( PRINT_WARNING, "WARNING: missing deformVertexes bulge parm in shader '%s'\n", shader.name );
return;
}
ds->bulgeHeight = atof( token );
token = COM_ParseExt( text, qfalse );
if ( token[0] == 0 )
{
ri.Printf( PRINT_WARNING, "WARNING: missing deformVertexes bulge parm in shader '%s'\n", shader.name );
return;
}
ds->bulgeSpeed = atof( token );
ds->deformation = DEFORM_BULGE;
return;
}
if ( !Q_stricmp( token, "wave" ) )
{
token = COM_ParseExt( text, qfalse );
if ( token[0] == 0 )
{
ri.Printf( PRINT_WARNING, "WARNING: missing deformVertexes parm in shader '%s'\n", shader.name );
return;
}
if ( atof( token ) != 0 )
{
ds->deformationSpread = 1.0f / atof( token );
}
else
{
ds->deformationSpread = 100.0f;
ri.Printf( PRINT_WARNING, "WARNING: illegal div value of 0 in deformVertexes command for shader '%s'\n", shader.name );
}
ParseWaveForm( text, &ds->deformationWave );
ds->deformation = DEFORM_WAVE;
return;
}
if ( !Q_stricmp( token, "normal" ) )
{
token = COM_ParseExt( text, qfalse );
if ( token[0] == 0 )
{
ri.Printf( PRINT_WARNING, "WARNING: missing deformVertexes parm in shader '%s'\n", shader.name );
return;
}
ds->deformationWave.amplitude = atof( token );
token = COM_ParseExt( text, qfalse );
if ( token[0] == 0 )
{
ri.Printf( PRINT_WARNING, "WARNING: missing deformVertexes parm in shader '%s'\n", shader.name );
return;
}
ds->deformationWave.frequency = atof( token );
ds->deformation = DEFORM_NORMALS;
return;
}
if ( !Q_stricmp( token, "move" ) ) {
int i;
for ( i = 0 ; i < 3 ; i++ ) {
token = COM_ParseExt( text, qfalse );
if ( token[0] == 0 ) {
ri.Printf( PRINT_WARNING, "WARNING: missing deformVertexes parm in shader '%s'\n", shader.name );
return;
}
ds->moveVector[i] = atof( token );
}
ParseWaveForm( text, &ds->deformationWave );
ds->deformation = DEFORM_MOVE;
return;
}
ri.Printf( PRINT_WARNING, "WARNING: unknown deformVertexes subtype '%s' found in shader '%s'\n", token, shader.name );
}
/*
===============
ParseSkyParms
skyParms <outerbox> <cloudheight> <innerbox>
===============
*/
static void ParseSkyParms( char **text ) {
char *token;
static char *suf[6] = {"rt", "bk", "lf", "ft", "up", "dn"};
char pathname[MAX_QPATH];
int i;
imgFlags_t imgFlags = IMGFLAG_MIPMAP | IMGFLAG_PICMIP;
// outerbox
token = COM_ParseExt( text, qfalse );
if ( token[0] == 0 ) {
ri.Printf( PRINT_WARNING, "WARNING: 'skyParms' missing parameter in shader '%s'\n", shader.name );
return;
}
if ( strcmp( token, "-" ) ) {
for (i=0 ; i<6 ; i++) {
Com_sprintf( pathname, sizeof(pathname), "%s_%s.tga"
, token, suf[i] );
shader.sky.outerbox[i] = R_FindImageFile( ( char * ) pathname, IMGTYPE_COLORALPHA, imgFlags | IMGFLAG_CLAMPTOEDGE );
if ( !shader.sky.outerbox[i] ) {
shader.sky.outerbox[i] = tr.defaultImage;
}
}
}
// cloudheight
token = COM_ParseExt( text, qfalse );
if ( token[0] == 0 ) {
ri.Printf( PRINT_WARNING, "WARNING: 'skyParms' missing parameter in shader '%s'\n", shader.name );
return;
}
shader.sky.cloudHeight = atof( token );
if ( !shader.sky.cloudHeight ) {
shader.sky.cloudHeight = 512;
}
R_InitSkyTexCoords( shader.sky.cloudHeight );
// innerbox
token = COM_ParseExt( text, qfalse );
if ( token[0] == 0 ) {
ri.Printf( PRINT_WARNING, "WARNING: 'skyParms' missing parameter in shader '%s'\n", shader.name );
return;
}
if ( strcmp( token, "-" ) ) {
for (i=0 ; i<6 ; i++) {
Com_sprintf( pathname, sizeof(pathname), "%s_%s.tga"
, token, suf[i] );
shader.sky.innerbox[i] = R_FindImageFile( ( char * ) pathname, IMGTYPE_COLORALPHA, imgFlags );
if ( !shader.sky.innerbox[i] ) {
shader.sky.innerbox[i] = tr.defaultImage;
}
}
}
shader.isSky = qtrue;
}
/*
=================
ParseSort
=================
*/
void ParseSort( char **text ) {
char *token;
token = COM_ParseExt( text, qfalse );
if ( token[0] == 0 ) {
ri.Printf( PRINT_WARNING, "WARNING: missing sort parameter in shader '%s'\n", shader.name );
return;
}
if ( !Q_stricmp( token, "portal" ) ) {
shader.sort = SS_PORTAL;
} else if ( !Q_stricmp( token, "sky" ) ) {
shader.sort = SS_ENVIRONMENT;
} else if ( !Q_stricmp( token, "opaque" ) ) {
shader.sort = SS_OPAQUE;
}else if ( !Q_stricmp( token, "decal" ) ) {
shader.sort = SS_DECAL;
} else if ( !Q_stricmp( token, "seeThrough" ) ) {
shader.sort = SS_SEE_THROUGH;
} else if ( !Q_stricmp( token, "banner" ) ) {
shader.sort = SS_BANNER;
} else if ( !Q_stricmp( token, "additive" ) ) {
shader.sort = SS_BLEND1;
} else if ( !Q_stricmp( token, "nearest" ) ) {
shader.sort = SS_NEAREST;
} else if ( !Q_stricmp( token, "underwater" ) ) {
shader.sort = SS_UNDERWATER;
} else {
shader.sort = atof( token );
}
}
// this table is also present in q3map
typedef struct {
char *name;
int clearSolid, surfaceFlags, contents;
} infoParm_t;
infoParm_t infoParms[] = {
// server relevant contents
{"water", 1, 0, CONTENTS_WATER },
{"slime", 1, 0, CONTENTS_SLIME }, // mildly damaging
{"lava", 1, 0, CONTENTS_LAVA }, // very damaging
{"playerclip", 1, 0, CONTENTS_PLAYERCLIP },
{"monsterclip", 1, 0, CONTENTS_MONSTERCLIP },
{"nodrop", 1, 0, CONTENTS_NODROP }, // don't drop items or leave bodies (death fog, lava, etc)
{"nonsolid", 1, SURF_NONSOLID, 0}, // clears the solid flag
// utility relevant attributes
{"origin", 1, 0, CONTENTS_ORIGIN }, // center of rotating brushes
{"trans", 0, 0, CONTENTS_TRANSLUCENT }, // don't eat contained surfaces
{"detail", 0, 0, CONTENTS_DETAIL }, // don't include in structural bsp
{"structural", 0, 0, CONTENTS_STRUCTURAL }, // force into structural bsp even if trnas
{"areaportal", 1, 0, CONTENTS_AREAPORTAL }, // divides areas
{"clusterportal", 1,0, CONTENTS_CLUSTERPORTAL }, // for bots
{"donotenter", 1, 0, CONTENTS_DONOTENTER }, // for bots
{"fog", 1, 0, CONTENTS_FOG}, // carves surfaces entering
{"sky", 0, SURF_SKY, 0 }, // emit light from an environment map
{"lightfilter", 0, SURF_LIGHTFILTER, 0 }, // filter light going through it
{"alphashadow", 0, SURF_ALPHASHADOW, 0 }, // test light on a per-pixel basis
{"hint", 0, SURF_HINT, 0 }, // use as a primary splitter
// server attributes
{"slick", 0, SURF_SLICK, 0 },
{"noimpact", 0, SURF_NOIMPACT, 0 }, // don't make impact explosions or marks
{"nomarks", 0, SURF_NOMARKS, 0 }, // don't make impact marks, but still explode
{"ladder", 0, SURF_LADDER, 0 },
{"nodamage", 0, SURF_NODAMAGE, 0 },
{"metalsteps", 0, SURF_METALSTEPS,0 },
{"flesh", 0, SURF_FLESH, 0 },
{"nosteps", 0, SURF_NOSTEPS, 0 },
// drawsurf attributes
{"nodraw", 0, SURF_NODRAW, 0 }, // don't generate a drawsurface (or a lightmap)
{"pointlight", 0, SURF_POINTLIGHT, 0 }, // sample lighting at vertexes
{"nolightmap", 0, SURF_NOLIGHTMAP,0 }, // don't generate a lightmap
{"nodlight", 0, SURF_NODLIGHT, 0 }, // don't ever add dynamic lights
{"dust", 0, SURF_DUST, 0} // leave a dust trail when walking on this surface
};
/*
===============
ParseSurfaceParm
surfaceparm <name>
===============
*/
static void ParseSurfaceParm( char **text ) {
char *token;
int numInfoParms = ARRAY_LEN( infoParms );
int i;
token = COM_ParseExt( text, qfalse );
for ( i = 0 ; i < numInfoParms ; i++ ) {
if ( !Q_stricmp( token, infoParms[i].name ) ) {
shader.surfaceFlags |= infoParms[i].surfaceFlags;
shader.contentFlags |= infoParms[i].contents;
#if 0
if ( infoParms[i].clearSolid ) {
si->contents &= ~CONTENTS_SOLID;
}
#endif
break;
}
}
}
/*
=================
ParseShader
The current text pointer is at the explicit text definition of the
shader. Parse it into the global shader variable. Later functions
will optimize it.
=================
*/
static qboolean ParseShader( char **text )
{
char *token;
int s;
s = 0;
token = COM_ParseExt( text, qtrue );
if ( token[0] != '{' )
{
ri.Printf( PRINT_WARNING, "WARNING: expecting '{', found '%s' instead in shader '%s'\n", token, shader.name );
return qfalse;
}
while ( 1 )
{
token = COM_ParseExt( text, qtrue );
if ( !token[0] )
{
ri.Printf( PRINT_WARNING, "WARNING: no concluding '}' in shader %s\n", shader.name );
return qfalse;
}
// end of shader definition
if ( token[0] == '}' )
{
break;
}
// stage definition
else if ( token[0] == '{' )
{
if ( s >= MAX_SHADER_STAGES ) {
ri.Printf( PRINT_WARNING, "WARNING: too many stages in shader %s (max is %i)\n", shader.name, MAX_SHADER_STAGES );
return qfalse;
}
if ( !ParseStage( &stages[s], text ) )
{
return qfalse;
}
stages[s].active = qtrue;
s++;
continue;
}
// skip stuff that only the QuakeEdRadient needs
else if ( !Q_stricmpn( token, "qer", 3 ) ) {
SkipRestOfLine( text );
continue;
}
// sun parms
else if ( !Q_stricmp( token, "q3map_sun" ) || !Q_stricmp( token, "q3map_sunExt" ) || !Q_stricmp( token, "q3gl2_sun" ) ) {
float a, b;
qboolean isGL2Sun = qfalse;
if (!Q_stricmp( token, "q3gl2_sun" ) && r_sunShadows->integer )
{
isGL2Sun = qtrue;
tr.sunShadows = qtrue;
}
token = COM_ParseExt( text, qfalse );
tr.sunLight[0] = atof( token );
token = COM_ParseExt( text, qfalse );
tr.sunLight[1] = atof( token );
token = COM_ParseExt( text, qfalse );
tr.sunLight[2] = atof( token );
VectorNormalize( tr.sunLight );
token = COM_ParseExt( text, qfalse );
a = atof( token );
VectorScale( tr.sunLight, a, tr.sunLight);
token = COM_ParseExt( text, qfalse );
a = atof( token );
a = a / 180 * M_PI;
token = COM_ParseExt( text, qfalse );
b = atof( token );
b = b / 180 * M_PI;
tr.sunDirection[0] = cos( a ) * cos( b );
tr.sunDirection[1] = sin( a ) * cos( b );
tr.sunDirection[2] = sin( b );
if (isGL2Sun)
{
token = COM_ParseExt( text, qfalse );
tr.sunShadowScale = atof(token);
// parse twice, since older shaders may include mapLightScale before sunShadowScale
if (token[0]) {
token = COM_ParseExt( text, qfalse );
if (token[0]) {
tr.sunShadowScale = atof(token);
}
}
}
if (token[0]) {
SkipRestOfLine( text );
}
continue;
}
// tonemap parms
else if ( !Q_stricmp( token, "q3gl2_tonemap" ) ) {
token = COM_ParseExt( text, qfalse );
tr.toneMinAvgMaxLevel[0] = atof( token );
token = COM_ParseExt( text, qfalse );
tr.toneMinAvgMaxLevel[1] = atof( token );
token = COM_ParseExt( text, qfalse );
tr.toneMinAvgMaxLevel[2] = atof( token );
token = COM_ParseExt( text, qfalse );
tr.autoExposureMinMax[0] = atof( token );
token = COM_ParseExt( text, qfalse );
tr.autoExposureMinMax[1] = atof( token );
SkipRestOfLine( text );
continue;
}
else if ( !Q_stricmp( token, "deformVertexes" ) ) {
ParseDeform( text );
continue;
}
else if ( !Q_stricmp( token, "tesssize" ) ) {
SkipRestOfLine( text );
continue;
}
else if ( !Q_stricmp( token, "clampTime" ) ) {
token = COM_ParseExt( text, qfalse );
if (token[0]) {
shader.clampTime = atof(token);
}
}
// skip stuff that only the q3map needs
else if ( !Q_stricmpn( token, "q3map", 5 ) ) {
SkipRestOfLine( text );
continue;
}
// skip stuff that only q3map or the server needs
else if ( !Q_stricmp( token, "surfaceParm" ) ) {
ParseSurfaceParm( text );
continue;
}
// no mip maps
else if ( !Q_stricmp( token, "nomipmaps" ) )
{
shader.noMipMaps = qtrue;
shader.noPicMip = qtrue;
continue;
}
// no picmip adjustment
else if ( !Q_stricmp( token, "nopicmip" ) )
{
shader.noPicMip = qtrue;
continue;
}
// polygonOffset
else if ( !Q_stricmp( token, "polygonOffset" ) )
{
shader.polygonOffset = qtrue;
continue;
}
// entityMergable, allowing sprite surfaces from multiple entities
// to be merged into one batch. This is a savings for smoke
// puffs and blood, but can't be used for anything where the
// shader calcs (not the surface function) reference the entity color or scroll
else if ( !Q_stricmp( token, "entityMergable" ) )
{
shader.entityMergable = qtrue;
continue;
}
// fogParms
else if ( !Q_stricmp( token, "fogParms" ) )
{
if ( !ParseVector( text, 3, shader.fogParms.color ) ) {
return qfalse;
}
if ( r_greyscale->integer )
{
float luminance;
luminance = LUMA( shader.fogParms.color[0], shader.fogParms.color[1], shader.fogParms.color[2] );
VectorSet( shader.fogParms.color, luminance, luminance, luminance );
}
else if ( r_greyscale->value )
{
float luminance;
luminance = LUMA( shader.fogParms.color[0], shader.fogParms.color[1], shader.fogParms.color[2] );
shader.fogParms.color[0] = LERP( shader.fogParms.color[0], luminance, r_greyscale->value );
shader.fogParms.color[1] = LERP( shader.fogParms.color[1], luminance, r_greyscale->value );
shader.fogParms.color[2] = LERP( shader.fogParms.color[2], luminance, r_greyscale->value );
}
token = COM_ParseExt( text, qfalse );
if ( !token[0] )
{
ri.Printf( PRINT_WARNING, "WARNING: missing parm for 'fogParms' keyword in shader '%s'\n", shader.name );
continue;
}
shader.fogParms.depthForOpaque = atof( token );
// skip any old gradient directions
SkipRestOfLine( text );
continue;
}
// portal
else if ( !Q_stricmp(token, "portal") )
{
shader.sort = SS_PORTAL;
shader.isPortal = qtrue;
continue;
}
// skyparms <cloudheight> <outerbox> <innerbox>
else if ( !Q_stricmp( token, "skyparms" ) )
{
ParseSkyParms( text );
continue;
}
// light <value> determines flaring in q3map, not needed here
else if ( !Q_stricmp(token, "light") )
{
COM_ParseExt( text, qfalse );
continue;
}
// cull <face>
else if ( !Q_stricmp( token, "cull") )
{
token = COM_ParseExt( text, qfalse );
if ( token[0] == 0 )
{
ri.Printf( PRINT_WARNING, "WARNING: missing cull parms in shader '%s'\n", shader.name );
continue;
}
if ( !Q_stricmp( token, "none" ) || !Q_stricmp( token, "twosided" ) || !Q_stricmp( token, "disable" ) )
{
shader.cullType = CT_TWO_SIDED;
}
else if ( !Q_stricmp( token, "back" ) || !Q_stricmp( token, "backside" ) || !Q_stricmp( token, "backsided" ) )
{
shader.cullType = CT_BACK_SIDED;
}
else
{
ri.Printf( PRINT_WARNING, "WARNING: invalid cull parm '%s' in shader '%s'\n", token, shader.name );
}
continue;
}
// sort
else if ( !Q_stricmp( token, "sort" ) )
{
ParseSort( text );
continue;
}
else
{
ri.Printf( PRINT_WARNING, "WARNING: unknown general shader parameter '%s' in '%s'\n", token, shader.name );
return qfalse;
}
}
//
// ignore shaders that don't have any stages, unless it is a sky or fog
//
if ( s == 0 && !shader.isSky && !(shader.contentFlags & CONTENTS_FOG ) ) {
return qfalse;
}
shader.explicitlyDefined = qtrue;
return qtrue;
}
/*
========================================================================================
SHADER OPTIMIZATION AND FOGGING
========================================================================================
*/
/*
===================
ComputeStageIteratorFunc
See if we can use on of the simple fastpath stage functions,
otherwise set to the generic stage function
===================
*/
static void ComputeStageIteratorFunc( void )
{
shader.optimalStageIteratorFunc = RB_StageIteratorGeneric;
//
// see if this should go into the sky path
//
if ( shader.isSky )
{
shader.optimalStageIteratorFunc = RB_StageIteratorSky;
return;
}
}
/*
===================
ComputeVertexAttribs
Check which vertex attributes we only need, so we
don't need to submit/copy all of them.
===================
*/
static void ComputeVertexAttribs(void)
{
int i, stage;
// dlights always need ATTR_NORMAL
shader.vertexAttribs = ATTR_POSITION | ATTR_NORMAL;
// portals always need normals, for SurfIsOffscreen()
if (shader.isPortal)
{
shader.vertexAttribs |= ATTR_NORMAL;
}
if (shader.defaultShader)
{
shader.vertexAttribs |= ATTR_TEXCOORD;
return;
}
if(shader.numDeforms)
{
for ( i = 0; i < shader.numDeforms; i++)
{
deformStage_t *ds = &shader.deforms[i];
switch (ds->deformation)
{
case DEFORM_BULGE:
shader.vertexAttribs |= ATTR_NORMAL | ATTR_TEXCOORD;
break;
case DEFORM_AUTOSPRITE:
shader.vertexAttribs |= ATTR_NORMAL | ATTR_COLOR;
break;
case DEFORM_WAVE:
case DEFORM_NORMALS:
case DEFORM_TEXT0:
case DEFORM_TEXT1:
case DEFORM_TEXT2:
case DEFORM_TEXT3:
case DEFORM_TEXT4:
case DEFORM_TEXT5:
case DEFORM_TEXT6:
case DEFORM_TEXT7:
shader.vertexAttribs |= ATTR_NORMAL;
break;
default:
case DEFORM_NONE:
case DEFORM_MOVE:
case DEFORM_PROJECTION_SHADOW:
case DEFORM_AUTOSPRITE2:
break;
}
}
}
for ( stage = 0; stage < MAX_SHADER_STAGES; stage++ )
{
shaderStage_t *pStage = &stages[stage];
if ( !pStage->active )
{
break;
}
if (pStage->glslShaderGroup == tr.lightallShader)
{
shader.vertexAttribs |= ATTR_NORMAL;
if ((pStage->glslShaderIndex & LIGHTDEF_LIGHTTYPE_MASK) && !(r_normalMapping->integer == 0 && r_specularMapping->integer == 0))
{
shader.vertexAttribs |= ATTR_TANGENT;
}
switch (pStage->glslShaderIndex & LIGHTDEF_LIGHTTYPE_MASK)
{
case LIGHTDEF_USE_LIGHTMAP:
case LIGHTDEF_USE_LIGHT_VERTEX:
shader.vertexAttribs |= ATTR_LIGHTDIRECTION;
break;
default:
break;
}
}
for (i = 0; i < NUM_TEXTURE_BUNDLES; i++)
{
if ( pStage->bundle[i].image[0] == 0 )
{
continue;
}
switch(pStage->bundle[i].tcGen)
{
case TCGEN_TEXTURE:
shader.vertexAttribs |= ATTR_TEXCOORD;
break;
case TCGEN_LIGHTMAP:
shader.vertexAttribs |= ATTR_LIGHTCOORD;
break;
case TCGEN_ENVIRONMENT_MAPPED:
shader.vertexAttribs |= ATTR_NORMAL;
break;
default:
break;
}
}
switch(pStage->rgbGen)
{
case CGEN_EXACT_VERTEX:
case CGEN_VERTEX:
case CGEN_EXACT_VERTEX_LIT:
case CGEN_VERTEX_LIT:
case CGEN_ONE_MINUS_VERTEX:
shader.vertexAttribs |= ATTR_COLOR;
break;
case CGEN_LIGHTING_DIFFUSE:
shader.vertexAttribs |= ATTR_NORMAL;
break;
default:
break;
}
switch(pStage->alphaGen)
{
case AGEN_LIGHTING_SPECULAR:
shader.vertexAttribs |= ATTR_NORMAL;
break;
case AGEN_VERTEX:
case AGEN_ONE_MINUS_VERTEX:
shader.vertexAttribs |= ATTR_COLOR;
break;
default:
break;
}
}
}
static void CollapseStagesToLightall(shaderStage_t *diffuse,
shaderStage_t *normal, shaderStage_t *specular, shaderStage_t *lightmap,
qboolean useLightVector, qboolean useLightVertex, qboolean parallax, qboolean tcgen)
{
int defs = 0;
//ri.Printf(PRINT_ALL, "shader %s has diffuse %s", shader.name, diffuse->bundle[0].image[0]->imgName);
// reuse diffuse, mark others inactive
diffuse->type = ST_GLSL;
if (lightmap)
{
//ri.Printf(PRINT_ALL, ", lightmap");
diffuse->bundle[TB_LIGHTMAP] = lightmap->bundle[0];
defs |= LIGHTDEF_USE_LIGHTMAP;
}
else if (useLightVector)
{
defs |= LIGHTDEF_USE_LIGHT_VECTOR;
}
else if (useLightVertex)
{
defs |= LIGHTDEF_USE_LIGHT_VERTEX;
}
if (r_deluxeMapping->integer && tr.worldDeluxeMapping && lightmap && shader.lightmapIndex >= 0)
{
//ri.Printf(PRINT_ALL, ", deluxemap");
diffuse->bundle[TB_DELUXEMAP] = lightmap->bundle[0];
diffuse->bundle[TB_DELUXEMAP].image[0] = tr.deluxemaps[shader.lightmapIndex];
}
if (r_normalMapping->integer)
{
image_t *diffuseImg;
if (normal)
{
//ri.Printf(PRINT_ALL, ", normalmap %s", normal->bundle[0].image[0]->imgName);
diffuse->bundle[TB_NORMALMAP] = normal->bundle[0];
if (parallax && r_parallaxMapping->integer)
defs |= LIGHTDEF_USE_PARALLAXMAP;
VectorCopy4(normal->normalScale, diffuse->normalScale);
}
else if ((lightmap || useLightVector || useLightVertex) && (diffuseImg = diffuse->bundle[TB_DIFFUSEMAP].image[0]))
{
char normalName[MAX_QPATH];
image_t *normalImg;
imgFlags_t normalFlags = (diffuseImg->flags & ~IMGFLAG_GENNORMALMAP) | IMGFLAG_NOLIGHTSCALE;
// try a normalheight image first
COM_StripExtension(diffuseImg->imgName, normalName, MAX_QPATH);
Q_strcat(normalName, MAX_QPATH, "_nh");
normalImg = R_FindImageFile(normalName, IMGTYPE_NORMALHEIGHT, normalFlags);
if (normalImg)
{
parallax = qtrue;
}
else
{
// try a normal image ("_n" suffix)
normalName[strlen(normalName) - 1] = '\0';
normalImg = R_FindImageFile(normalName, IMGTYPE_NORMAL, normalFlags);
}
if (normalImg)
{
diffuse->bundle[TB_NORMALMAP] = diffuse->bundle[0];
diffuse->bundle[TB_NORMALMAP].numImageAnimations = 0;
diffuse->bundle[TB_NORMALMAP].image[0] = normalImg;
if (parallax && r_parallaxMapping->integer)
defs |= LIGHTDEF_USE_PARALLAXMAP;
VectorSet4(diffuse->normalScale, r_baseNormalX->value, r_baseNormalY->value, 1.0f, r_baseParallax->value);
}
}
}
if (r_specularMapping->integer)
{
image_t *diffuseImg;
if (specular)
{
//ri.Printf(PRINT_ALL, ", specularmap %s", specular->bundle[0].image[0]->imgName);
diffuse->bundle[TB_SPECULARMAP] = specular->bundle[0];
VectorCopy4(specular->specularScale, diffuse->specularScale);
}
else if ((lightmap || useLightVector || useLightVertex) && (diffuseImg = diffuse->bundle[TB_DIFFUSEMAP].image[0]))
{
char specularName[MAX_QPATH];
image_t *specularImg;
imgFlags_t specularFlags = (diffuseImg->flags & ~IMGFLAG_GENNORMALMAP) | IMGFLAG_NOLIGHTSCALE;
COM_StripExtension(diffuseImg->imgName, specularName, MAX_QPATH);
Q_strcat(specularName, MAX_QPATH, "_s");
specularImg = R_FindImageFile(specularName, IMGTYPE_COLORALPHA, specularFlags);
if (specularImg)
{
diffuse->bundle[TB_SPECULARMAP] = diffuse->bundle[0];
diffuse->bundle[TB_SPECULARMAP].numImageAnimations = 0;
diffuse->bundle[TB_SPECULARMAP].image[0] = specularImg;
VectorSet4(diffuse->specularScale, 1.0f, 1.0f, 1.0f, 1.0f);
}
}
}
if (tcgen || diffuse->bundle[0].numTexMods)
{
defs |= LIGHTDEF_USE_TCGEN_AND_TCMOD;
}
//ri.Printf(PRINT_ALL, ".\n");
diffuse->glslShaderGroup = tr.lightallShader;
diffuse->glslShaderIndex = defs;
}
static int CollapseStagesToGLSL(void)
{
int i, j, numStages;
qboolean skip = qfalse;
// skip shaders with deforms
if (shader.numDeforms != 0)
{
skip = qtrue;
}
if (!skip)
{
// if 2+ stages and first stage is lightmap, switch them
// this makes it easier for the later bits to process
if (stages[0].active && stages[0].bundle[0].tcGen == TCGEN_LIGHTMAP && stages[1].active)
{
int blendBits = stages[1].stateBits & ( GLS_DSTBLEND_BITS | GLS_SRCBLEND_BITS );
if (blendBits == (GLS_DSTBLEND_SRC_COLOR | GLS_SRCBLEND_ZERO)
|| blendBits == (GLS_DSTBLEND_ZERO | GLS_SRCBLEND_DST_COLOR))
{
int stateBits0 = stages[0].stateBits;
int stateBits1 = stages[1].stateBits;
shaderStage_t swapStage;
swapStage = stages[0];
stages[0] = stages[1];
stages[1] = swapStage;
stages[0].stateBits = stateBits0;
stages[1].stateBits = stateBits1;
}
}
}
if (!skip)
{
// scan for shaders that aren't supported
for (i = 0; i < MAX_SHADER_STAGES; i++)
{
shaderStage_t *pStage = &stages[i];
if (!pStage->active)
continue;
if (pStage->adjustColorsForFog)
{
skip = qtrue;
break;
}
if (pStage->bundle[0].tcGen == TCGEN_LIGHTMAP)
{
int blendBits = pStage->stateBits & ( GLS_DSTBLEND_BITS | GLS_SRCBLEND_BITS );
if (blendBits != (GLS_DSTBLEND_SRC_COLOR | GLS_SRCBLEND_ZERO)
&& blendBits != (GLS_DSTBLEND_ZERO | GLS_SRCBLEND_DST_COLOR))
{
skip = qtrue;
break;
}
}
switch(pStage->bundle[0].tcGen)
{
case TCGEN_TEXTURE:
case TCGEN_LIGHTMAP:
case TCGEN_ENVIRONMENT_MAPPED:
case TCGEN_VECTOR:
break;
default:
skip = qtrue;
break;
}
switch(pStage->alphaGen)
{
case AGEN_LIGHTING_SPECULAR:
case AGEN_PORTAL:
skip = qtrue;
break;
default:
break;
}
}
}
if (!skip)
{
qboolean usedLightmap = qfalse;
for (i = 0; i < MAX_SHADER_STAGES; i++)
{
shaderStage_t *pStage = &stages[i];
shaderStage_t *diffuse, *normal, *specular, *lightmap;
qboolean parallax, tcgen, diffuselit, vertexlit;
if (!pStage->active)
continue;
// skip normal and specular maps
if (pStage->type != ST_COLORMAP)
continue;
// skip lightmaps
if (pStage->bundle[0].tcGen == TCGEN_LIGHTMAP)
continue;
diffuse = pStage;
normal = NULL;
parallax = qfalse;
specular = NULL;
lightmap = NULL;
// we have a diffuse map, find matching normal, specular, and lightmap
for (j = i + 1; j < MAX_SHADER_STAGES; j++)
{
shaderStage_t *pStage2 = &stages[j];
if (!pStage2->active)
continue;
switch(pStage2->type)
{
case ST_NORMALMAP:
if (!normal)
{
normal = pStage2;
}
break;
case ST_NORMALPARALLAXMAP:
if (!normal)
{
normal = pStage2;
parallax = qtrue;
}
break;
case ST_SPECULARMAP:
if (!specular)
{
specular = pStage2;
}
break;
case ST_COLORMAP:
if (pStage2->bundle[0].tcGen == TCGEN_LIGHTMAP)
{
int blendBits = pStage->stateBits & ( GLS_DSTBLEND_BITS | GLS_SRCBLEND_BITS );
// Only add lightmap to blendfunc filter stage if it's the first time lightmap is used
// otherwise it will cause the shader to be darkened by the lightmap multiple times.
if (!usedLightmap || (blendBits != (GLS_DSTBLEND_SRC_COLOR | GLS_SRCBLEND_ZERO)
&& blendBits != (GLS_DSTBLEND_ZERO | GLS_SRCBLEND_DST_COLOR)))
{
lightmap = pStage2;
usedLightmap = qtrue;
}
}
break;
default:
break;
}
}
tcgen = qfalse;
if (diffuse->bundle[0].tcGen == TCGEN_ENVIRONMENT_MAPPED
|| diffuse->bundle[0].tcGen == TCGEN_LIGHTMAP
|| diffuse->bundle[0].tcGen == TCGEN_VECTOR)
{
tcgen = qtrue;
}
diffuselit = qfalse;
if (diffuse->rgbGen == CGEN_LIGHTING_DIFFUSE)
{
diffuselit = qtrue;
}
vertexlit = qfalse;
if (diffuse->rgbGen == CGEN_VERTEX_LIT || diffuse->rgbGen == CGEN_EXACT_VERTEX_LIT)
{
vertexlit = qtrue;
}
CollapseStagesToLightall(diffuse, normal, specular, lightmap, diffuselit, vertexlit, parallax, tcgen);
}
// deactivate lightmap stages
for (i = 0; i < MAX_SHADER_STAGES; i++)
{
shaderStage_t *pStage = &stages[i];
if (!pStage->active)
continue;
if (pStage->bundle[0].tcGen == TCGEN_LIGHTMAP)
{
pStage->active = qfalse;
}
}
}
// deactivate normal and specular stages
for (i = 0; i < MAX_SHADER_STAGES; i++)
{
shaderStage_t *pStage = &stages[i];
if (!pStage->active)
continue;
if (pStage->type == ST_NORMALMAP)
{
pStage->active = qfalse;
}
if (pStage->type == ST_NORMALPARALLAXMAP)
{
pStage->active = qfalse;
}
if (pStage->type == ST_SPECULARMAP)
{
pStage->active = qfalse;
}
}
// remove inactive stages
numStages = 0;
for (i = 0; i < MAX_SHADER_STAGES; i++)
{
if (!stages[i].active)
continue;
if (i == numStages)
{
numStages++;
continue;
}
stages[numStages] = stages[i];
stages[i].active = qfalse;
numStages++;
}
// convert any remaining lightmap stages with no blending or blendfunc filter
// to a lighting pass with a white texture
// only do this with r_sunlightMode non-zero, as it's only for correct shadows.
if (r_sunlightMode->integer && shader.numDeforms == 0)
{
for (i = 0; i < MAX_SHADER_STAGES; i++)
{
shaderStage_t *pStage = &stages[i];
int blendBits;
if (!pStage->active)
continue;
if (pStage->adjustColorsForFog)
continue;
if (pStage->bundle[TB_DIFFUSEMAP].tcGen != TCGEN_LIGHTMAP)
continue;
blendBits = pStage->stateBits & (GLS_DSTBLEND_BITS | GLS_SRCBLEND_BITS);
if (blendBits != 0 &&
blendBits != (GLS_DSTBLEND_SRC_COLOR | GLS_SRCBLEND_ZERO) &&
blendBits != (GLS_DSTBLEND_ZERO | GLS_SRCBLEND_DST_COLOR)) {
continue;
}
pStage->glslShaderGroup = tr.lightallShader;
pStage->glslShaderIndex = LIGHTDEF_USE_LIGHTMAP;
pStage->bundle[TB_LIGHTMAP] = pStage->bundle[TB_DIFFUSEMAP];
pStage->bundle[TB_DIFFUSEMAP].image[0] = tr.whiteImage;
pStage->bundle[TB_DIFFUSEMAP].isLightmap = qfalse;
pStage->bundle[TB_DIFFUSEMAP].tcGen = TCGEN_TEXTURE;
}
}
// convert any remaining lightingdiffuse stages to a lighting pass
if (shader.numDeforms == 0)
{
for (i = 0; i < MAX_SHADER_STAGES; i++)
{
shaderStage_t *pStage = &stages[i];
if (!pStage->active)
continue;
if (pStage->adjustColorsForFog)
continue;
if (pStage->rgbGen == CGEN_LIGHTING_DIFFUSE)
{
pStage->glslShaderGroup = tr.lightallShader;
pStage->glslShaderIndex = LIGHTDEF_USE_LIGHT_VECTOR;
if (pStage->bundle[0].tcGen != TCGEN_TEXTURE || pStage->bundle[0].numTexMods != 0)
pStage->glslShaderIndex |= LIGHTDEF_USE_TCGEN_AND_TCMOD;
}
}
}
return numStages;
}
/*
=============
FixRenderCommandList
https://zerowing.idsoftware.com/bugzilla/show_bug.cgi?id=493
Arnout: this is a nasty issue. Shaders can be registered after drawsurfaces are generated
but before the frame is rendered. This will, for the duration of one frame, cause drawsurfaces
to be rendered with bad shaders. To fix this, need to go through all render commands and fix
sortedIndex.
==============
*/
static void FixRenderCommandList( int newShader ) {
renderCommandList_t *cmdList = &backEndData->commands;
if( cmdList ) {
const void *curCmd = cmdList->cmds;
while ( 1 ) {
curCmd = PADP(curCmd, sizeof(void *));
switch ( *(const int *)curCmd ) {
case RC_SET_COLOR:
{
const setColorCommand_t *sc_cmd = (const setColorCommand_t *)curCmd;
curCmd = (const void *)(sc_cmd + 1);
break;
}
case RC_STRETCH_PIC:
{
const stretchPicCommand_t *sp_cmd = (const stretchPicCommand_t *)curCmd;
curCmd = (const void *)(sp_cmd + 1);
break;
}
case RC_DRAW_SURFS:
{
int i;
drawSurf_t *drawSurf;
shader_t *shader;
int fogNum;
int entityNum;
int dlightMap;
int pshadowMap;
int sortedIndex;
const drawSurfsCommand_t *ds_cmd = (const drawSurfsCommand_t *)curCmd;
for( i = 0, drawSurf = ds_cmd->drawSurfs; i < ds_cmd->numDrawSurfs; i++, drawSurf++ ) {
R_DecomposeSort( drawSurf->sort, &entityNum, &shader, &fogNum, &dlightMap, &pshadowMap );
sortedIndex = (( drawSurf->sort >> QSORT_SHADERNUM_SHIFT ) & (MAX_SHADERS-1));
if( sortedIndex >= newShader ) {
sortedIndex++;
drawSurf->sort = (sortedIndex << QSORT_SHADERNUM_SHIFT) | entityNum | ( fogNum << QSORT_FOGNUM_SHIFT ) | ( (int)pshadowMap << QSORT_PSHADOW_SHIFT) | (int)dlightMap;
}
}
curCmd = (const void *)(ds_cmd + 1);
break;
}
case RC_DRAW_BUFFER:
{
const drawBufferCommand_t *db_cmd = (const drawBufferCommand_t *)curCmd;
curCmd = (const void *)(db_cmd + 1);
break;
}
case RC_SWAP_BUFFERS:
{
const swapBuffersCommand_t *sb_cmd = (const swapBuffersCommand_t *)curCmd;
curCmd = (const void *)(sb_cmd + 1);
break;
}
case RC_END_OF_LIST:
default:
return;
}
}
}
}
/*
==============
SortNewShader
Positions the most recently created shader in the tr.sortedShaders[]
array so that the shader->sort key is sorted reletive to the other
shaders.
Sets shader->sortedIndex
==============
*/
static void SortNewShader( void ) {
int i;
float sort;
shader_t *newShader;
newShader = tr.shaders[ tr.numShaders - 1 ];
sort = newShader->sort;
for ( i = tr.numShaders - 2 ; i >= 0 ; i-- ) {
if ( tr.sortedShaders[ i ]->sort <= sort ) {
break;
}
tr.sortedShaders[i+1] = tr.sortedShaders[i];
tr.sortedShaders[i+1]->sortedIndex++;
}
// Arnout: fix rendercommandlist
// https://zerowing.idsoftware.com/bugzilla/show_bug.cgi?id=493
FixRenderCommandList( i+1 );
newShader->sortedIndex = i+1;
tr.sortedShaders[i+1] = newShader;
}
/*
====================
GeneratePermanentShader
====================
*/
static shader_t *GeneratePermanentShader( void ) {
shader_t *newShader;
int i, b;
int size, hash;
if ( tr.numShaders == MAX_SHADERS ) {
ri.Printf( PRINT_WARNING, "WARNING: GeneratePermanentShader - MAX_SHADERS hit\n");
return tr.defaultShader;
}
newShader = ri.Hunk_Alloc( sizeof( shader_t ), h_low );
*newShader = shader;
if ( shader.sort <= SS_OPAQUE ) {
newShader->fogPass = FP_EQUAL;
} else if ( shader.contentFlags & CONTENTS_FOG ) {
newShader->fogPass = FP_LE;
}
tr.shaders[ tr.numShaders ] = newShader;
newShader->index = tr.numShaders;
tr.sortedShaders[ tr.numShaders ] = newShader;
newShader->sortedIndex = tr.numShaders;
tr.numShaders++;
for ( i = 0 ; i < newShader->numUnfoggedPasses ; i++ ) {
if ( !stages[i].active ) {
break;
}
newShader->stages[i] = ri.Hunk_Alloc( sizeof( stages[i] ), h_low );
*newShader->stages[i] = stages[i];
for ( b = 0 ; b < NUM_TEXTURE_BUNDLES ; b++ ) {
size = newShader->stages[i]->bundle[b].numTexMods * sizeof( texModInfo_t );
newShader->stages[i]->bundle[b].texMods = ri.Hunk_Alloc( size, h_low );
Com_Memcpy( newShader->stages[i]->bundle[b].texMods, stages[i].bundle[b].texMods, size );
}
}
SortNewShader();
hash = generateHashValue(newShader->name, FILE_HASH_SIZE);
newShader->next = hashTable[hash];
hashTable[hash] = newShader;
return newShader;
}
/*
=================
VertexLightingCollapse
If vertex lighting is enabled, only render a single
pass, trying to guess which is the correct one to best approximate
what it is supposed to look like.
=================
*/
static void VertexLightingCollapse( void ) {
int stage;
shaderStage_t *bestStage;
int bestImageRank;
int rank;
// if we aren't opaque, just use the first pass
if ( shader.sort == SS_OPAQUE ) {
// pick the best texture for the single pass
bestStage = &stages[0];
bestImageRank = -999999;
for ( stage = 0; stage < MAX_SHADER_STAGES; stage++ ) {
shaderStage_t *pStage = &stages[stage];
if ( !pStage->active ) {
break;
}
rank = 0;
if ( pStage->bundle[0].isLightmap ) {
rank -= 100;
}
if ( pStage->bundle[0].tcGen != TCGEN_TEXTURE ) {
rank -= 5;
}
if ( pStage->bundle[0].numTexMods ) {
rank -= 5;
}
if ( pStage->rgbGen != CGEN_IDENTITY && pStage->rgbGen != CGEN_IDENTITY_LIGHTING ) {
rank -= 3;
}
if ( rank > bestImageRank ) {
bestImageRank = rank;
bestStage = pStage;
}
}
stages[0].bundle[0] = bestStage->bundle[0];
stages[0].stateBits &= ~( GLS_DSTBLEND_BITS | GLS_SRCBLEND_BITS );
stages[0].stateBits |= GLS_DEPTHMASK_TRUE;
if ( shader.lightmapIndex == LIGHTMAP_NONE ) {
stages[0].rgbGen = CGEN_LIGHTING_DIFFUSE;
} else {
stages[0].rgbGen = CGEN_EXACT_VERTEX;
}
stages[0].alphaGen = AGEN_SKIP;
} else {
// don't use a lightmap (tesla coils)
if ( stages[0].bundle[0].isLightmap ) {
stages[0] = stages[1];
}
// if we were in a cross-fade cgen, hack it to normal
if ( stages[0].rgbGen == CGEN_ONE_MINUS_ENTITY || stages[1].rgbGen == CGEN_ONE_MINUS_ENTITY ) {
stages[0].rgbGen = CGEN_IDENTITY_LIGHTING;
}
if ( ( stages[0].rgbGen == CGEN_WAVEFORM && stages[0].rgbWave.func == GF_SAWTOOTH )
&& ( stages[1].rgbGen == CGEN_WAVEFORM && stages[1].rgbWave.func == GF_INVERSE_SAWTOOTH ) ) {
stages[0].rgbGen = CGEN_IDENTITY_LIGHTING;
}
if ( ( stages[0].rgbGen == CGEN_WAVEFORM && stages[0].rgbWave.func == GF_INVERSE_SAWTOOTH )
&& ( stages[1].rgbGen == CGEN_WAVEFORM && stages[1].rgbWave.func == GF_SAWTOOTH ) ) {
stages[0].rgbGen = CGEN_IDENTITY_LIGHTING;
}
}
for ( stage = 1; stage < MAX_SHADER_STAGES; stage++ ) {
shaderStage_t *pStage = &stages[stage];
if ( !pStage->active ) {
break;
}
Com_Memset( pStage, 0, sizeof( *pStage ) );
}
}
/*
=================
FixFatLightmapTexCoords
Handle edge cases of altering lightmap texcoords for fat lightmap atlas
=================
*/
static void FixFatLightmapTexCoords(void)
{
texModInfo_t *tmi;
int lightmapnum;
int stage;
int size;
int i;
if ( !r_mergeLightmaps->integer || tr.fatLightmapCols <= 0) {
return;
}
if ( shader.lightmapIndex < 0 ) {
// no internal lightmap, texcoords were not modified
return;
}
lightmapnum = shader_realLightmapIndex;
if (tr.worldDeluxeMapping)
lightmapnum >>= 1;
lightmapnum %= (tr.fatLightmapCols * tr.fatLightmapRows);
for ( stage = 0; stage < MAX_SHADER_STAGES; stage++ ) {
shaderStage_t *pStage = &stages[stage];
if ( !pStage->active ) {
break;
}
if ( pStage->bundle[0].isLightmap ) {
// fix tcMod transform for internal lightmaps, it may be used by q3map2 lightstyles
if ( pStage->bundle[0].tcGen == TCGEN_LIGHTMAP ) {
for ( i = 0; i < pStage->bundle[0].numTexMods; i++ ) {
tmi = &pStage->bundle[0].texMods[i];
if ( tmi->type == TMOD_TRANSFORM ) {
tmi->translate[0] /= (float)tr.fatLightmapCols;
tmi->translate[1] /= (float)tr.fatLightmapRows;
}
}
}
// fix tcGen environment for internal lightmaps to be limited to the sub-image of the atlas
// this is done last so other tcMods are applied first in the 0.0 to 1.0 space
if ( pStage->bundle[0].tcGen == TCGEN_ENVIRONMENT_MAPPED ) {
if ( pStage->bundle[0].numTexMods == TR_MAX_TEXMODS ) {
ri.Printf( PRINT_DEVELOPER, "WARNING: too many tcmods to fix lightmap texcoords for r_mergeLightmaps in shader '%s'", shader.name );
} else {
tmi = &pStage->bundle[0].texMods[pStage->bundle[0].numTexMods];
pStage->bundle[0].numTexMods++;
tmi->matrix[0][0] = 1.0f / tr.fatLightmapCols;
tmi->matrix[0][1] = 0;
tmi->matrix[1][0] = 0;
tmi->matrix[1][1] = 1.0f / tr.fatLightmapRows;
tmi->translate[0] = ( lightmapnum % tr.fatLightmapCols ) / (float)tr.fatLightmapCols;
tmi->translate[1] = ( lightmapnum / tr.fatLightmapCols ) / (float)tr.fatLightmapRows;
tmi->type = TMOD_TRANSFORM;
}
}
}
// add a tcMod transform for external lightmaps to convert back to the original texcoords
else if ( pStage->bundle[0].tcGen == TCGEN_LIGHTMAP ) {
if ( pStage->bundle[0].numTexMods == TR_MAX_TEXMODS ) {
ri.Printf( PRINT_DEVELOPER, "WARNING: too many tcmods to fix lightmap texcoords for r_mergeLightmaps in shader '%s'", shader.name );
} else {
size = pStage->bundle[0].numTexMods * sizeof( texModInfo_t );
if ( size ) {
memmove( &pStage->bundle[0].texMods[1], &pStage->bundle[0].texMods[0], size );
}
tmi = &pStage->bundle[0].texMods[0];
pStage->bundle[0].numTexMods++;
tmi->matrix[0][0] = tr.fatLightmapCols;
tmi->matrix[0][1] = 0;
tmi->matrix[1][0] = 0;
tmi->matrix[1][1] = tr.fatLightmapRows;
tmi->translate[0] = -( lightmapnum % tr.fatLightmapCols );
tmi->translate[1] = -( lightmapnum / tr.fatLightmapCols );
tmi->type = TMOD_TRANSFORM;
}
}
}
}
/*
===============
InitShader
===============
*/
static void InitShaderEx( const char *name, int lightmapIndex, int realLightmapIndex ) {
int i;
// clear the global shader
Com_Memset( &shader, 0, sizeof( shader ) );
Com_Memset( &stages, 0, sizeof( stages ) );
Q_strncpyz( shader.name, name, sizeof( shader.name ) );
shader.lightmapIndex = lightmapIndex;
shader_realLightmapIndex = realLightmapIndex;
for ( i = 0 ; i < MAX_SHADER_STAGES ; i++ ) {
stages[i].bundle[0].texMods = texMods[i];
// default normal/specular
VectorSet4(stages[i].normalScale, 0.0f, 0.0f, 0.0f, 0.0f);
if (r_pbr->integer)
{
stages[i].specularScale[0] = r_baseGloss->value;
}
else
{
stages[i].specularScale[0] =
stages[i].specularScale[1] =
stages[i].specularScale[2] = r_baseSpecular->value;
stages[i].specularScale[3] = r_baseGloss->value;
}
}
}
static void InitShader( const char *name, int lightmapIndex ) {
InitShaderEx( name, lightmapIndex, lightmapIndex );
}
/*
=========================
FinishShader
Returns a freshly allocated shader with all the needed info
from the current global working shader
=========================
*/
static shader_t *FinishShader( void ) {
int stage;
qboolean hasLightmapStage;
qboolean vertexLightmap;
hasLightmapStage = qfalse;
vertexLightmap = qfalse;
//
// set sky stuff appropriate
//
if ( shader.isSky ) {
shader.sort = SS_ENVIRONMENT;
}
//
// set polygon offset
//
if ( shader.polygonOffset && !shader.sort ) {
shader.sort = SS_DECAL;
}
//
// set appropriate stage information
//
for ( stage = 0; stage < MAX_SHADER_STAGES; ) {
shaderStage_t *pStage = &stages[stage];
if ( !pStage->active ) {
break;
}
// check for a missing texture
if ( !pStage->bundle[0].image[0] ) {
ri.Printf( PRINT_WARNING, "Shader %s has a stage with no image\n", shader.name );
pStage->active = qfalse;
stage++;
continue;
}
//
// ditch this stage if it's detail and detail textures are disabled
//
if ( pStage->isDetail && !r_detailTextures->integer )
{
int index;
for(index = stage + 1; index < MAX_SHADER_STAGES; index++)
{
if(!stages[index].active)
break;
}
if(index < MAX_SHADER_STAGES)
memmove(pStage, pStage + 1, sizeof(*pStage) * (index - stage));
else
{
if(stage + 1 < MAX_SHADER_STAGES)
memmove(pStage, pStage + 1, sizeof(*pStage) * (index - stage - 1));
Com_Memset(&stages[index - 1], 0, sizeof(*stages));
}
continue;
}
//
// default texture coordinate generation
//
if ( pStage->bundle[0].isLightmap ) {
if ( pStage->bundle[0].tcGen == TCGEN_BAD ) {
pStage->bundle[0].tcGen = TCGEN_LIGHTMAP;
}
hasLightmapStage = qtrue;
} else {
if ( pStage->bundle[0].tcGen == TCGEN_BAD ) {
pStage->bundle[0].tcGen = TCGEN_TEXTURE;
}
}
// not a true lightmap but we want to leave existing
// behaviour in place and not print out a warning
//if (pStage->rgbGen == CGEN_VERTEX) {
// vertexLightmap = qtrue;
//}
//
// determine sort order and fog color adjustment
//
if ( ( pStage->stateBits & ( GLS_SRCBLEND_BITS | GLS_DSTBLEND_BITS ) ) &&
( stages[0].stateBits & ( GLS_SRCBLEND_BITS | GLS_DSTBLEND_BITS ) ) ) {
int blendSrcBits = pStage->stateBits & GLS_SRCBLEND_BITS;
int blendDstBits = pStage->stateBits & GLS_DSTBLEND_BITS;
// fog color adjustment only works for blend modes that have a contribution
// that aproaches 0 as the modulate values aproach 0 --
// GL_ONE, GL_ONE
// GL_ZERO, GL_ONE_MINUS_SRC_COLOR
// GL_SRC_ALPHA, GL_ONE_MINUS_SRC_ALPHA
// modulate, additive
if ( ( ( blendSrcBits == GLS_SRCBLEND_ONE ) && ( blendDstBits == GLS_DSTBLEND_ONE ) ) ||
( ( blendSrcBits == GLS_SRCBLEND_ZERO ) && ( blendDstBits == GLS_DSTBLEND_ONE_MINUS_SRC_COLOR ) ) ) {
pStage->adjustColorsForFog = ACFF_MODULATE_RGB;
}
// strict blend
else if ( ( blendSrcBits == GLS_SRCBLEND_SRC_ALPHA ) && ( blendDstBits == GLS_DSTBLEND_ONE_MINUS_SRC_ALPHA ) )
{
pStage->adjustColorsForFog = ACFF_MODULATE_ALPHA;
}
// premultiplied alpha
else if ( ( blendSrcBits == GLS_SRCBLEND_ONE ) && ( blendDstBits == GLS_DSTBLEND_ONE_MINUS_SRC_ALPHA ) )
{
pStage->adjustColorsForFog = ACFF_MODULATE_RGBA;
} else {
// we can't adjust this one correctly, so it won't be exactly correct in fog
}
// don't screw with sort order if this is a portal or environment
if ( !shader.sort ) {
// see through item, like a grill or grate
if ( pStage->stateBits & GLS_DEPTHMASK_TRUE ) {
shader.sort = SS_SEE_THROUGH;
} else {
shader.sort = SS_BLEND0;
}
}
}
stage++;
}
// there are times when you will need to manually apply a sort to
// opaque alpha tested shaders that have later blend passes
if ( !shader.sort ) {
shader.sort = SS_OPAQUE;
}
//
// if we are in r_vertexLight mode, never use a lightmap texture
//
if ( stage > 1 && ( (r_vertexLight->integer && !r_uiFullScreen->integer) || glConfig.hardwareType == GLHW_PERMEDIA2 ) ) {
VertexLightingCollapse();
hasLightmapStage = qfalse;
}
FixFatLightmapTexCoords();
//
// look for multitexture potential
//
stage = CollapseStagesToGLSL();
if ( shader.lightmapIndex >= 0 && !hasLightmapStage ) {
if (vertexLightmap) {
ri.Printf( PRINT_DEVELOPER, "WARNING: shader '%s' has VERTEX forced lightmap!\n", shader.name );
} else {
ri.Printf( PRINT_DEVELOPER, "WARNING: shader '%s' has lightmap but no lightmap stage!\n", shader.name );
// Don't set this, it will just add duplicate shaders to the hash
//shader.lightmapIndex = LIGHTMAP_NONE;
}
}
//
// compute number of passes
//
shader.numUnfoggedPasses = stage;
// fogonly shaders don't have any normal passes
if (stage == 0 && !shader.isSky)
shader.sort = SS_FOG;
// determine which stage iterator function is appropriate
ComputeStageIteratorFunc();
// determine which vertex attributes this shader needs
ComputeVertexAttribs();
return GeneratePermanentShader();
}
//========================================================================================
/*
====================
FindShaderInShaderText
Scans the combined text description of all the shader files for
the given shader name.
return NULL if not found
If found, it will return a valid shader
=====================
*/
static char *FindShaderInShaderText( const char *shadername ) {
char *token, *p;
int i, hash;
hash = generateHashValue(shadername, MAX_SHADERTEXT_HASH);
if(shaderTextHashTable[hash])
{
for (i = 0; shaderTextHashTable[hash][i]; i++)
{
p = shaderTextHashTable[hash][i];
token = COM_ParseExt(&p, qtrue);
if(!Q_stricmp(token, shadername))
return p;
}
}
p = s_shaderText;
if ( !p ) {
return NULL;
}
// look for label
while ( 1 ) {
token = COM_ParseExt( &p, qtrue );
if ( token[0] == 0 ) {
break;
}
if ( !Q_stricmp( token, shadername ) ) {
return p;
}
else {
// skip the definition
SkipBracedSection( &p, 0 );
}
}
return NULL;
}
/*
==================
R_FindShaderByName
Will always return a valid shader, but it might be the
default shader if the real one can't be found.
==================
*/
shader_t *R_FindShaderByName( const char *name ) {
char strippedName[MAX_QPATH];
int hash;
shader_t *sh;
if ( (name==NULL) || (name[0] == 0) ) {
return tr.defaultShader;
}
COM_StripExtension(name, strippedName, sizeof(strippedName));
hash = generateHashValue(strippedName, FILE_HASH_SIZE);
//
// see if the shader is already loaded
//
for (sh=hashTable[hash]; sh; sh=sh->next) {
// NOTE: if there was no shader or image available with the name strippedName
// then a default shader is created with lightmapIndex == LIGHTMAP_NONE, so we
// have to check all default shaders otherwise for every call to R_FindShader
// with that same strippedName a new default shader is created.
if (Q_stricmp(sh->name, strippedName) == 0) {
// match found
return sh;
}
}
return tr.defaultShader;
}
/*
===============
R_FindShader
Will always return a valid shader, but it might be the
default shader if the real one can't be found.
In the interest of not requiring an explicit shader text entry to
be defined for every single image used in the game, three default
shader behaviors can be auto-created for any image:
If lightmapIndex == LIGHTMAP_NONE, then the image will have
dynamic diffuse lighting applied to it, as appropriate for most
entity skin surfaces.
If lightmapIndex == LIGHTMAP_2D, then the image will be used
for 2D rendering unless an explicit shader is found
If lightmapIndex == LIGHTMAP_BY_VERTEX, then the image will use
the vertex rgba modulate values, as appropriate for misc_model
pre-lit surfaces.
Other lightmapIndex values will have a lightmap stage created
and src*dest blending applied with the texture, as appropriate for
most world construction surfaces.
===============
*/
shader_t *R_FindShader( const char *name, int lightmapIndex, qboolean mipRawImage ) {
return R_FindShaderEx( name, lightmapIndex, mipRawImage, lightmapIndex );
}
shader_t *R_FindShaderEx( const char *name, int lightmapIndex, qboolean mipRawImage, int realLightmapIndex ) {
char strippedName[MAX_QPATH];
int hash;
char *shaderText;
image_t *image;
shader_t *sh;
if ( name[0] == 0 ) {
return tr.defaultShader;
}
// use (fullbright) vertex lighting if the bsp file doesn't have
// lightmaps
if ( lightmapIndex >= 0 && lightmapIndex >= tr.numLightmaps ) {
lightmapIndex = LIGHTMAP_BY_VERTEX;
} else if ( lightmapIndex < LIGHTMAP_2D ) {
// negative lightmap indexes cause stray pointers (think tr.lightmaps[lightmapIndex])
ri.Printf( PRINT_WARNING, "WARNING: shader '%s' has invalid lightmap index of %d\n", name, lightmapIndex );
lightmapIndex = LIGHTMAP_BY_VERTEX;
}
COM_StripExtension(name, strippedName, sizeof(strippedName));
hash = generateHashValue(strippedName, FILE_HASH_SIZE);
//
// see if the shader is already loaded
//
for (sh = hashTable[hash]; sh; sh = sh->next) {
// NOTE: if there was no shader or image available with the name strippedName
// then a default shader is created with lightmapIndex == LIGHTMAP_NONE, so we
// have to check all default shaders otherwise for every call to R_FindShader
// with that same strippedName a new default shader is created.
if ( (sh->lightmapIndex == lightmapIndex || sh->defaultShader) &&
!Q_stricmp(sh->name, strippedName)) {
// match found
return sh;
}
}
InitShaderEx( strippedName, lightmapIndex, realLightmapIndex );
//
// attempt to define shader from an explicit parameter file
//
shaderText = FindShaderInShaderText( strippedName );
if ( shaderText ) {
// enable this when building a pak file to get a global list
// of all explicit shaders
if ( r_printShaders->integer ) {
ri.Printf( PRINT_ALL, "*SHADER* %s\n", name );
}
if ( !ParseShader( &shaderText ) ) {
// had errors, so use default shader
shader.defaultShader = qtrue;
}
sh = FinishShader();
return sh;
}
//
// if not defined in the in-memory shader descriptions,
// look for a single supported image file
//
{
imgFlags_t flags;
flags = IMGFLAG_NONE;
if (mipRawImage)
{
flags |= IMGFLAG_MIPMAP | IMGFLAG_PICMIP;
if (r_genNormalMaps->integer)
flags |= IMGFLAG_GENNORMALMAP;
}
else
{
flags |= IMGFLAG_CLAMPTOEDGE;
}
image = R_FindImageFile( name, IMGTYPE_COLORALPHA, flags );
if ( !image ) {
ri.Printf( PRINT_DEVELOPER, "Couldn't find image file for shader %s\n", name );
shader.defaultShader = qtrue;
return FinishShader();
}
}
//
// create the default shading commands
//
if ( shader.lightmapIndex == LIGHTMAP_NONE ) {
// dynamic colors at vertexes
stages[0].bundle[0].image[0] = image;
stages[0].active = qtrue;
stages[0].rgbGen = CGEN_LIGHTING_DIFFUSE;
stages[0].stateBits = GLS_DEFAULT;
} else if ( shader.lightmapIndex == LIGHTMAP_BY_VERTEX ) {
// explicit colors at vertexes
stages[0].bundle[0].image[0] = image;
stages[0].active = qtrue;
stages[0].rgbGen = CGEN_EXACT_VERTEX;
stages[0].alphaGen = AGEN_SKIP;
stages[0].stateBits = GLS_DEFAULT;
} else if ( shader.lightmapIndex == LIGHTMAP_2D ) {
// GUI elements
stages[0].bundle[0].image[0] = image;
stages[0].active = qtrue;
stages[0].rgbGen = CGEN_VERTEX;
stages[0].alphaGen = AGEN_VERTEX;
stages[0].stateBits = GLS_DEPTHTEST_DISABLE |
GLS_SRCBLEND_SRC_ALPHA |
GLS_DSTBLEND_ONE_MINUS_SRC_ALPHA;
} else if ( shader.lightmapIndex == LIGHTMAP_WHITEIMAGE ) {
// fullbright level
stages[0].bundle[0].image[0] = tr.whiteImage;
stages[0].active = qtrue;
stages[0].rgbGen = CGEN_IDENTITY_LIGHTING;
stages[0].stateBits = GLS_DEFAULT;
stages[1].bundle[0].image[0] = image;
stages[1].active = qtrue;
stages[1].rgbGen = CGEN_IDENTITY;
stages[1].stateBits |= GLS_SRCBLEND_DST_COLOR | GLS_DSTBLEND_ZERO;
} else {
// two pass lightmap
stages[0].bundle[0].image[0] = tr.lightmaps[shader.lightmapIndex];
stages[0].bundle[0].isLightmap = qtrue;
stages[0].active = qtrue;
stages[0].rgbGen = CGEN_IDENTITY; // lightmaps are scaled on creation
// for identitylight
stages[0].stateBits = GLS_DEFAULT;
stages[1].bundle[0].image[0] = image;
stages[1].active = qtrue;
stages[1].rgbGen = CGEN_IDENTITY;
stages[1].stateBits |= GLS_SRCBLEND_DST_COLOR | GLS_DSTBLEND_ZERO;
}
return FinishShader();
}
qhandle_t RE_RegisterShaderFromImage(const char *name, int lightmapIndex, image_t *image, qboolean mipRawImage) {
int hash;
shader_t *sh;
hash = generateHashValue(name, FILE_HASH_SIZE);
// probably not necessary since this function
// only gets called from tr_font.c with lightmapIndex == LIGHTMAP_2D
// but better safe than sorry.
if ( lightmapIndex >= tr.numLightmaps ) {
lightmapIndex = LIGHTMAP_WHITEIMAGE;
}
//
// see if the shader is already loaded
//
for (sh=hashTable[hash]; sh; sh=sh->next) {
// NOTE: if there was no shader or image available with the name strippedName
// then a default shader is created with lightmapIndex == LIGHTMAP_NONE, so we
// have to check all default shaders otherwise for every call to R_FindShader
// with that same strippedName a new default shader is created.
if ( (sh->lightmapIndex == lightmapIndex || sh->defaultShader) &&
// index by name
!Q_stricmp(sh->name, name)) {
// match found
return sh->index;
}
}
InitShader( name, lightmapIndex );
//
// create the default shading commands
//
if ( shader.lightmapIndex == LIGHTMAP_NONE ) {
// dynamic colors at vertexes
stages[0].bundle[0].image[0] = image;
stages[0].active = qtrue;
stages[0].rgbGen = CGEN_LIGHTING_DIFFUSE;
stages[0].stateBits = GLS_DEFAULT;
} else if ( shader.lightmapIndex == LIGHTMAP_BY_VERTEX ) {
// explicit colors at vertexes
stages[0].bundle[0].image[0] = image;
stages[0].active = qtrue;
stages[0].rgbGen = CGEN_EXACT_VERTEX;
stages[0].alphaGen = AGEN_SKIP;
stages[0].stateBits = GLS_DEFAULT;
} else if ( shader.lightmapIndex == LIGHTMAP_2D ) {
// GUI elements
stages[0].bundle[0].image[0] = image;
stages[0].active = qtrue;
stages[0].rgbGen = CGEN_VERTEX;
stages[0].alphaGen = AGEN_VERTEX;
stages[0].stateBits = GLS_DEPTHTEST_DISABLE |
GLS_SRCBLEND_SRC_ALPHA |
GLS_DSTBLEND_ONE_MINUS_SRC_ALPHA;
} else if ( shader.lightmapIndex == LIGHTMAP_WHITEIMAGE ) {
// fullbright level
stages[0].bundle[0].image[0] = tr.whiteImage;
stages[0].active = qtrue;
stages[0].rgbGen = CGEN_IDENTITY_LIGHTING;
stages[0].stateBits = GLS_DEFAULT;
stages[1].bundle[0].image[0] = image;
stages[1].active = qtrue;
stages[1].rgbGen = CGEN_IDENTITY;
stages[1].stateBits |= GLS_SRCBLEND_DST_COLOR | GLS_DSTBLEND_ZERO;
} else {
// two pass lightmap
stages[0].bundle[0].image[0] = tr.lightmaps[shader.lightmapIndex];
stages[0].bundle[0].isLightmap = qtrue;
stages[0].active = qtrue;
stages[0].rgbGen = CGEN_IDENTITY; // lightmaps are scaled on creation
// for identitylight
stages[0].stateBits = GLS_DEFAULT;
stages[1].bundle[0].image[0] = image;
stages[1].active = qtrue;
stages[1].rgbGen = CGEN_IDENTITY;
stages[1].stateBits |= GLS_SRCBLEND_DST_COLOR | GLS_DSTBLEND_ZERO;
}
sh = FinishShader();
return sh->index;
}
/*
====================
RE_RegisterShader
This is the exported shader entry point for the rest of the system
It will always return an index that will be valid.
This should really only be used for explicit shaders, because there is no
way to ask for different implicit lighting modes (vertex, lightmap, etc)
====================
*/
qhandle_t RE_RegisterShaderLightMap( const char *name, int lightmapIndex ) {
shader_t *sh;
if ( strlen( name ) >= MAX_QPATH ) {
ri.Printf( PRINT_ALL, "Shader name exceeds MAX_QPATH\n" );
return 0;
}
sh = R_FindShader( name, lightmapIndex, qtrue );
// we want to return 0 if the shader failed to
// load for some reason, but R_FindShader should
// still keep a name allocated for it, so if
// something calls RE_RegisterShader again with
// the same name, we don't try looking for it again
if ( sh->defaultShader ) {
return 0;
}
return sh->index;
}
/*
====================
RE_RegisterShader
This is the exported shader entry point for the rest of the system
It will always return an index that will be valid.
This should really only be used for explicit shaders, because there is no
way to ask for different implicit lighting modes (vertex, lightmap, etc)
====================
*/
qhandle_t RE_RegisterShader( const char *name ) {
shader_t *sh;
if ( strlen( name ) >= MAX_QPATH ) {
ri.Printf( PRINT_ALL, "Shader name exceeds MAX_QPATH\n" );
return 0;
}
sh = R_FindShader( name, LIGHTMAP_2D, qtrue );
// we want to return 0 if the shader failed to
// load for some reason, but R_FindShader should
// still keep a name allocated for it, so if
// something calls RE_RegisterShader again with
// the same name, we don't try looking for it again
if ( sh->defaultShader ) {
return 0;
}
return sh->index;
}
/*
====================
RE_RegisterShaderNoMip
For menu graphics that should never be picmiped
====================
*/
qhandle_t RE_RegisterShaderNoMip( const char *name ) {
shader_t *sh;
if ( strlen( name ) >= MAX_QPATH ) {
ri.Printf( PRINT_ALL, "Shader name exceeds MAX_QPATH\n" );
return 0;
}
sh = R_FindShader( name, LIGHTMAP_2D, qfalse );
// we want to return 0 if the shader failed to
// load for some reason, but R_FindShader should
// still keep a name allocated for it, so if
// something calls RE_RegisterShader again with
// the same name, we don't try looking for it again
if ( sh->defaultShader ) {
return 0;
}
return sh->index;
}
/*
====================
R_GetShaderByHandle
When a handle is passed in by another module, this range checks
it and returns a valid (possibly default) shader_t to be used internally.
====================
*/
shader_t *R_GetShaderByHandle( qhandle_t hShader ) {
if ( hShader < 0 ) {
ri.Printf( PRINT_WARNING, "R_GetShaderByHandle: out of range hShader '%d'\n", hShader );
return tr.defaultShader;
}
if ( hShader >= tr.numShaders ) {
ri.Printf( PRINT_WARNING, "R_GetShaderByHandle: out of range hShader '%d'\n", hShader );
return tr.defaultShader;
}
return tr.shaders[hShader];
}
/*
===============
R_ShaderList_f
Dump information on all valid shaders to the console
A second parameter will cause it to print in sorted order
===============
*/
void R_ShaderList_f (void) {
int i;
int count;
shader_t *shader;
ri.Printf (PRINT_ALL, "-----------------------\n");
count = 0;
for ( i = 0 ; i < tr.numShaders ; i++ ) {
if ( ri.Cmd_Argc() > 1 ) {
shader = tr.sortedShaders[i];
} else {
shader = tr.shaders[i];
}
ri.Printf( PRINT_ALL, "%i ", shader->numUnfoggedPasses );
if (shader->lightmapIndex >= 0 ) {
ri.Printf (PRINT_ALL, "L ");
} else {
ri.Printf (PRINT_ALL, " ");
}
if ( shader->explicitlyDefined ) {
ri.Printf( PRINT_ALL, "E " );
} else {
ri.Printf( PRINT_ALL, " " );
}
if ( shader->optimalStageIteratorFunc == RB_StageIteratorGeneric ) {
ri.Printf( PRINT_ALL, "gen " );
} else if ( shader->optimalStageIteratorFunc == RB_StageIteratorSky ) {
ri.Printf( PRINT_ALL, "sky " );
} else {
ri.Printf( PRINT_ALL, " " );
}
if ( shader->defaultShader ) {
ri.Printf (PRINT_ALL, ": %s (DEFAULTED)\n", shader->name);
} else {
ri.Printf (PRINT_ALL, ": %s\n", shader->name);
}
count++;
}
ri.Printf (PRINT_ALL, "%i total shaders\n", count);
ri.Printf (PRINT_ALL, "------------------\n");
}
/*
====================
ScanAndLoadShaderFiles
Finds and loads all .shader files, combining them into
a single large text block that can be scanned for shader names
=====================
*/
#define MAX_SHADER_FILES 4096
static void ScanAndLoadShaderFiles( void )
{
char **shaderFiles;
char *buffers[MAX_SHADER_FILES] = {NULL};
char *p;
int numShaderFiles;
int i;
char *oldp, *token, *hashMem, *textEnd;
int shaderTextHashTableSizes[MAX_SHADERTEXT_HASH], hash, size;
char shaderName[MAX_QPATH];
int shaderLine;
long sum = 0, summand;
// scan for shader files
shaderFiles = ri.FS_ListFiles( "scripts", ".shader", &numShaderFiles );
if ( !shaderFiles || !numShaderFiles )
{
ri.Printf( PRINT_WARNING, "WARNING: no shader files found\n" );
return;
}
if ( numShaderFiles > MAX_SHADER_FILES ) {
numShaderFiles = MAX_SHADER_FILES;
}
// load and parse shader files
for ( i = 0; i < numShaderFiles; i++ )
{
char filename[MAX_QPATH];
// look for a .mtr file first
{
char *ext;
Com_sprintf( filename, sizeof( filename ), "scripts/%s", shaderFiles[i] );
if ( (ext = strrchr(filename, '.')) )
{
strcpy(ext, ".mtr");
}
if ( ri.FS_ReadFile( filename, NULL ) <= 0 )
{
Com_sprintf( filename, sizeof( filename ), "scripts/%s", shaderFiles[i] );
}
}
ri.Printf( PRINT_DEVELOPER, "...loading '%s'\n", filename );
summand = ri.FS_ReadFile( filename, (void **)&buffers[i] );
if ( !buffers[i] )
ri.Error( ERR_DROP, "Couldn't load %s", filename );
// Do a simple check on the shader structure in that file to make sure one bad shader file cannot fuck up all other shaders.
p = buffers[i];
COM_BeginParseSession(filename);
while(1)
{
token = COM_ParseExt(&p, qtrue);
if(!*token)
break;
Q_strncpyz(shaderName, token, sizeof(shaderName));
shaderLine = COM_GetCurrentParseLine();
token = COM_ParseExt(&p, qtrue);
if(token[0] != '{' || token[1] != '\0')
{
ri.Printf(PRINT_WARNING, "WARNING: Ignoring shader file %s. Shader \"%s\" on line %d missing opening brace",
filename, shaderName, shaderLine);
if (token[0])
{
ri.Printf(PRINT_WARNING, " (found \"%s\" on line %d)", token, COM_GetCurrentParseLine());
}
ri.Printf(PRINT_WARNING, ".\n");
ri.FS_FreeFile(buffers[i]);
buffers[i] = NULL;
break;
}
if(!SkipBracedSection(&p, 1))
{
ri.Printf(PRINT_WARNING, "WARNING: Ignoring shader file %s. Shader \"%s\" on line %d missing closing brace.\n",
filename, shaderName, shaderLine);
ri.FS_FreeFile(buffers[i]);
buffers[i] = NULL;
break;
}
}
if (buffers[i])
sum += summand;
}
// build single large buffer
s_shaderText = ri.Hunk_Alloc( sum + numShaderFiles*2, h_low );
s_shaderText[ 0 ] = '\0';
textEnd = s_shaderText;
// free in reverse order, so the temp files are all dumped
for ( i = numShaderFiles - 1; i >= 0 ; i-- )
{
if ( !buffers[i] )
continue;
strcat( textEnd, buffers[i] );
strcat( textEnd, "\n" );
textEnd += strlen( textEnd );
ri.FS_FreeFile( buffers[i] );
}
COM_Compress( s_shaderText );
// free up memory
ri.FS_FreeFileList( shaderFiles );
Com_Memset(shaderTextHashTableSizes, 0, sizeof(shaderTextHashTableSizes));
size = 0;
p = s_shaderText;
// look for shader names
while ( 1 ) {
token = COM_ParseExt( &p, qtrue );
if ( token[0] == 0 ) {
break;
}
hash = generateHashValue(token, MAX_SHADERTEXT_HASH);
shaderTextHashTableSizes[hash]++;
size++;
SkipBracedSection(&p, 0);
}
size += MAX_SHADERTEXT_HASH;
hashMem = ri.Hunk_Alloc( size * sizeof(char *), h_low );
for (i = 0; i < MAX_SHADERTEXT_HASH; i++) {
shaderTextHashTable[i] = (char **) hashMem;
hashMem = ((char *) hashMem) + ((shaderTextHashTableSizes[i] + 1) * sizeof(char *));
}
Com_Memset(shaderTextHashTableSizes, 0, sizeof(shaderTextHashTableSizes));
p = s_shaderText;
// look for shader names
while ( 1 ) {
oldp = p;
token = COM_ParseExt( &p, qtrue );
if ( token[0] == 0 ) {
break;
}
hash = generateHashValue(token, MAX_SHADERTEXT_HASH);
shaderTextHashTable[hash][shaderTextHashTableSizes[hash]++] = oldp;
SkipBracedSection(&p, 0);
}
return;
}
/*
====================
CreateInternalShaders
====================
*/
static void CreateInternalShaders( void ) {
tr.numShaders = 0;
// init the default shader
InitShader( "<default>", LIGHTMAP_NONE );
stages[0].bundle[0].image[0] = tr.defaultImage;
stages[0].active = qtrue;
stages[0].stateBits = GLS_DEFAULT;
tr.defaultShader = FinishShader();
// shadow shader is just a marker
Q_strncpyz( shader.name, "<stencil shadow>", sizeof( shader.name ) );
shader.sort = SS_STENCIL_SHADOW;
tr.shadowShader = FinishShader();
}
static void CreateExternalShaders( void ) {
tr.projectionShadowShader = R_FindShader( "projectionShadow", LIGHTMAP_NONE, qtrue );
tr.flareShader = R_FindShader( "flareShader", LIGHTMAP_NONE, qtrue );
// Hack to make fogging work correctly on flares. Fog colors are calculated
// in tr_flare.c already.
if(!tr.flareShader->defaultShader)
{
int index;
for(index = 0; index < tr.flareShader->numUnfoggedPasses; index++)
{
tr.flareShader->stages[index]->adjustColorsForFog = ACFF_NONE;
tr.flareShader->stages[index]->stateBits |= GLS_DEPTHTEST_DISABLE;
}
}
tr.sunShader = R_FindShader( "sun", LIGHTMAP_NONE, qtrue );
tr.sunFlareShader = R_FindShader( "gfx/2d/sunflare", LIGHTMAP_NONE, qtrue);
// HACK: if sunflare is missing, make one using the flare image or dlight image
if (tr.sunFlareShader->defaultShader)
{
image_t *image;
if (!tr.flareShader->defaultShader && tr.flareShader->stages[0] && tr.flareShader->stages[0]->bundle[0].image[0])
image = tr.flareShader->stages[0]->bundle[0].image[0];
else
image = tr.dlightImage;
InitShader( "gfx/2d/sunflare", LIGHTMAP_NONE );
stages[0].bundle[0].image[0] = image;
stages[0].active = qtrue;
stages[0].stateBits = GLS_DEFAULT;
tr.sunFlareShader = FinishShader();
}
}
/*
==================
R_InitShaders
==================
*/
void R_InitShaders( void ) {
ri.Printf( PRINT_ALL, "Initializing Shaders\n" );
Com_Memset(hashTable, 0, sizeof(hashTable));
CreateInternalShaders();
ScanAndLoadShaderFiles();
CreateExternalShaders();
}