dhewm3/neo/renderer/Material.cpp

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2011-11-22 21:28:15 +00:00
/*
===========================================================================
Doom 3 GPL Source Code
Copyright (C) 1999-2011 id Software LLC, a ZeniMax Media company.
2011-11-22 21:28:15 +00:00
2011-12-06 16:14:59 +00:00
This file is part of the Doom 3 GPL Source Code ("Doom 3 Source Code").
2011-11-22 21:28:15 +00:00
Doom 3 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 3 of the License, or
(at your option) any later version.
Doom 3 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 Doom 3 Source Code. If not, see <http://www.gnu.org/licenses/>.
In addition, the Doom 3 Source Code is also subject to certain additional terms. You should have received a copy of these additional terms immediately following the terms and conditions of the GNU General Public License which accompanied the Doom 3 Source Code. If not, please request a copy in writing from id Software at the address below.
If you have questions concerning this license or the applicable additional terms, you may contact in writing id Software LLC, c/o ZeniMax Media Inc., Suite 120, Rockville, Maryland 20850 USA.
===========================================================================
*/
#include "sys/platform.h"
#include "idlib/math/Interpolate.h"
#include "renderer/Cinematic.h"
#include "renderer/tr_local.h"
#include "ui/Window.h"
#include "ui/UserInterface.h"
#include "sound/sound.h"
#include "renderer/Material.h"
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/*
Any errors during parsing just set MF_DEFAULTED and return, rather than throwing
a hard error. This will cause the material to fall back to default material,
but otherwise let things continue.
Each material may have a set of calculations that must be evaluated before
drawing with it.
Every expression that a material uses can be evaluated at one time, which
will allow for perfect common subexpression removal when I get around to
writing it.
Without this, scrolling an entire surface could result in evaluating the
same texture matrix calculations a half dozen times.
Open question: should I allow arbitrary per-vertex color, texCoord, and vertex
calculations to be specified in the material code?
Every stage will definately have a valid image pointer.
We might want the ability to change the sort value based on conditionals,
but it could be a hassle to implement,
*/
// keep all of these on the stack, when they are static it makes material parsing non-reentrant
typedef struct mtrParsingData_s {
bool registerIsTemporary[MAX_EXPRESSION_REGISTERS];
float shaderRegisters[MAX_EXPRESSION_REGISTERS];
expOp_t shaderOps[MAX_EXPRESSION_OPS];
shaderStage_t parseStages[MAX_SHADER_STAGES];
bool registersAreConstant;
bool forceOverlays;
} mtrParsingData_t;
/*
=============
idMaterial::CommonInit
=============
*/
void idMaterial::CommonInit() {
desc = "<none>";
renderBump = "";
contentFlags = CONTENTS_SOLID;
surfaceFlags = SURFTYPE_NONE;
materialFlags = 0;
sort = SS_BAD;
coverage = MC_BAD;
cullType = CT_FRONT_SIDED;
deform = DFRM_NONE;
numOps = 0;
ops = NULL;
numRegisters = 0;
expressionRegisters = NULL;
constantRegisters = NULL;
numStages = 0;
numAmbientStages = 0;
stages = NULL;
editorImage = NULL;
lightFalloffImage = NULL;
shouldCreateBackSides = false;
entityGui = 0;
fogLight = false;
blendLight = false;
ambientLight = false;
noFog = false;
hasSubview = false;
allowOverlays = true;
unsmoothedTangents = false;
gui = NULL;
memset( deformRegisters, 0, sizeof( deformRegisters ) );
editorAlpha = 1.0;
spectrum = 0;
polygonOffset = 0;
suppressInSubview = false;
refCount = 0;
portalSky = false;
decalInfo.stayTime = 10000;
decalInfo.fadeTime = 4000;
decalInfo.start[0] = 1;
decalInfo.start[1] = 1;
decalInfo.start[2] = 1;
decalInfo.start[3] = 1;
decalInfo.end[0] = 0;
decalInfo.end[1] = 0;
decalInfo.end[2] = 0;
decalInfo.end[3] = 0;
}
/*
=============
idMaterial::idMaterial
=============
*/
idMaterial::idMaterial() {
CommonInit();
// we put this here instead of in CommonInit, because
// we don't want it cleared when a material is purged
surfaceArea = 0;
}
/*
=============
idMaterial::~idMaterial
=============
*/
idMaterial::~idMaterial() {
}
/*
===============
idMaterial::FreeData
===============
*/
void idMaterial::FreeData() {
int i;
if ( stages ) {
// delete any idCinematic textures
for ( i = 0; i < numStages; i++ ) {
if ( stages[i].texture.cinematic != NULL ) {
delete stages[i].texture.cinematic;
stages[i].texture.cinematic = NULL;
}
if ( stages[i].newStage != NULL ) {
Mem_Free( stages[i].newStage );
stages[i].newStage = NULL;
}
}
R_StaticFree( stages );
stages = NULL;
}
if ( expressionRegisters != NULL ) {
R_StaticFree( expressionRegisters );
expressionRegisters = NULL;
}
if ( constantRegisters != NULL ) {
R_StaticFree( constantRegisters );
constantRegisters = NULL;
}
if ( ops != NULL ) {
R_StaticFree( ops );
ops = NULL;
}
}
/*
==============
idMaterial::GetEditorImage
==============
*/
idImage *idMaterial::GetEditorImage( void ) const {
if ( editorImage ) {
return editorImage;
}
// if we don't have an editorImageName, use the first stage image
if ( !editorImageName.Length()) {
// _D3XP :: First check for a diffuse image, then use the first
if ( numStages && stages ) {
int i;
for( i = 0; i < numStages; i++ ) {
if ( stages[i].lighting == SL_DIFFUSE ) {
editorImage = stages[i].texture.image;
break;
}
}
if ( !editorImage ) {
editorImage = stages[0].texture.image;
}
} else {
editorImage = globalImages->defaultImage;
}
} else {
// look for an explicit one
editorImage = globalImages->ImageFromFile( editorImageName, TF_DEFAULT, true, TR_REPEAT, TD_DEFAULT );
}
if ( !editorImage ) {
editorImage = globalImages->defaultImage;
}
return editorImage;
}
// info parms
typedef struct {
const char *name;
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int clearSolid, surfaceFlags, contents;
} infoParm_t;
static const infoParm_t infoParms[] = {
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// game relevant attributes
{"solid", 0, 0, CONTENTS_SOLID }, // may need to override a clearSolid
{"water", 1, 0, CONTENTS_WATER }, // used for water
{"playerclip", 0, 0, CONTENTS_PLAYERCLIP }, // solid to players
{"monsterclip", 0, 0, CONTENTS_MONSTERCLIP }, // solid to monsters
{"moveableclip",0, 0, CONTENTS_MOVEABLECLIP },// solid to moveable entities
{"ikclip", 0, 0, CONTENTS_IKCLIP }, // solid to IK
{"blood", 0, 0, CONTENTS_BLOOD }, // used to detect blood decals
{"trigger", 0, 0, CONTENTS_TRIGGER }, // used for triggers
{"aassolid", 0, 0, CONTENTS_AAS_SOLID }, // solid for AAS
{"aasobstacle", 0, 0, CONTENTS_AAS_OBSTACLE },// used to compile an obstacle into AAS that can be enabled/disabled
{"flashlight_trigger", 0, 0, CONTENTS_FLASHLIGHT_TRIGGER }, // used for triggers that are activated by the flashlight
{"nonsolid", 1, 0, 0 }, // clears the solid flag
{"nullNormal", 0, SURF_NULLNORMAL,0 }, // renderbump will draw as 0x80 0x80 0x80
// utility relevant attributes
{"areaportal", 1, 0, CONTENTS_AREAPORTAL }, // divides areas
{"qer_nocarve", 1, 0, CONTENTS_NOCSG}, // don't cut brushes in editor
{"discrete", 1, SURF_DISCRETE, 0 }, // surfaces should not be automatically merged together or
// clipped to the world,
// because they represent discrete objects like gui shaders
// mirrors, or autosprites
{"noFragment", 0, SURF_NOFRAGMENT, 0 },
{"slick", 0, SURF_SLICK, 0 },
{"collision", 0, SURF_COLLISION, 0 },
{"noimpact", 0, SURF_NOIMPACT, 0 }, // don't make impact explosions or marks
{"nodamage", 0, SURF_NODAMAGE, 0 }, // no falling damage when hitting
{"ladder", 0, SURF_LADDER, 0 }, // climbable
{"nosteps", 0, SURF_NOSTEPS, 0 }, // no footsteps
// material types for particle, sound, footstep feedback
{"metal", 0, SURFTYPE_METAL, 0 }, // metal
{"stone", 0, SURFTYPE_STONE, 0 }, // stone
{"flesh", 0, SURFTYPE_FLESH, 0 }, // flesh
{"wood", 0, SURFTYPE_WOOD, 0 }, // wood
{"cardboard", 0, SURFTYPE_CARDBOARD, 0 }, // cardboard
{"liquid", 0, SURFTYPE_LIQUID, 0 }, // liquid
{"glass", 0, SURFTYPE_GLASS, 0 }, // glass
{"plastic", 0, SURFTYPE_PLASTIC, 0 }, // plastic
{"ricochet", 0, SURFTYPE_RICOCHET, 0 }, // behaves like metal but causes a ricochet sound
// unassigned surface types
{"surftype10", 0, SURFTYPE_10, 0 },
{"surftype11", 0, SURFTYPE_11, 0 },
{"surftype12", 0, SURFTYPE_12, 0 },
{"surftype13", 0, SURFTYPE_13, 0 },
{"surftype14", 0, SURFTYPE_14, 0 },
{"surftype15", 0, SURFTYPE_15, 0 },
};
static const int numInfoParms = sizeof(infoParms) / sizeof (infoParms[0]);
/*
===============
idMaterial::CheckSurfaceParm
See if the current token matches one of the surface parm bit flags
===============
*/
bool idMaterial::CheckSurfaceParm( idToken *token ) {
for ( int i = 0 ; i < numInfoParms ; i++ ) {
if ( !token->Icmp( infoParms[i].name ) ) {
if ( infoParms[i].surfaceFlags & SURF_TYPE_MASK ) {
// ensure we only have one surface type set
surfaceFlags &= ~SURF_TYPE_MASK;
}
surfaceFlags |= infoParms[i].surfaceFlags;
contentFlags |= infoParms[i].contents;
if ( infoParms[i].clearSolid ) {
contentFlags &= ~CONTENTS_SOLID;
}
return true;
}
}
return false;
}
/*
===============
idMaterial::MatchToken
Sets defaultShader and returns false if the next token doesn't match
===============
*/
bool idMaterial::MatchToken( idLexer &src, const char *match ) {
if ( !src.ExpectTokenString( match ) ) {
SetMaterialFlag( MF_DEFAULTED );
return false;
}
return true;
}
/*
=================
idMaterial::ParseSort
=================
*/
void idMaterial::ParseSort( idLexer &src ) {
idToken token;
if ( !src.ReadTokenOnLine( &token ) ) {
src.Warning( "missing sort parameter" );
SetMaterialFlag( MF_DEFAULTED );
return;
}
if ( !token.Icmp( "subview" ) ) {
sort = SS_SUBVIEW;
} else if ( !token.Icmp( "opaque" ) ) {
sort = SS_OPAQUE;
}else if ( !token.Icmp( "decal" ) ) {
sort = SS_DECAL;
} else if ( !token.Icmp( "far" ) ) {
sort = SS_FAR;
} else if ( !token.Icmp( "medium" ) ) {
sort = SS_MEDIUM;
} else if ( !token.Icmp( "close" ) ) {
sort = SS_CLOSE;
} else if ( !token.Icmp( "almostNearest" ) ) {
sort = SS_ALMOST_NEAREST;
} else if ( !token.Icmp( "nearest" ) ) {
sort = SS_NEAREST;
} else if ( !token.Icmp( "postProcess" ) ) {
sort = SS_POST_PROCESS;
} else if ( !token.Icmp( "portalSky" ) ) {
sort = SS_PORTAL_SKY;
} else {
sort = atof( token );
}
}
/*
=================
idMaterial::ParseDecalInfo
=================
*/
void idMaterial::ParseDecalInfo( idLexer &src ) {
idToken token;
decalInfo.stayTime = src.ParseFloat() * 1000;
decalInfo.fadeTime = src.ParseFloat() * 1000;
float start[4], end[4];
src.Parse1DMatrix( 4, start );
src.Parse1DMatrix( 4, end );
for ( int i = 0 ; i < 4 ; i++ ) {
decalInfo.start[i] = start[i];
decalInfo.end[i] = end[i];
}
}
/*
=============
idMaterial::GetExpressionConstant
=============
*/
int idMaterial::GetExpressionConstant( float f ) {
int i;
for ( i = EXP_REG_NUM_PREDEFINED ; i < numRegisters ; i++ ) {
if ( !pd->registerIsTemporary[i] && pd->shaderRegisters[i] == f ) {
return i;
}
}
if ( numRegisters == MAX_EXPRESSION_REGISTERS ) {
common->Warning( "GetExpressionConstant: material '%s' hit MAX_EXPRESSION_REGISTERS", GetName() );
SetMaterialFlag( MF_DEFAULTED );
return 0;
}
pd->registerIsTemporary[i] = false;
pd->shaderRegisters[i] = f;
numRegisters++;
return i;
}
/*
=============
idMaterial::GetExpressionTemporary
=============
*/
int idMaterial::GetExpressionTemporary( void ) {
if ( numRegisters == MAX_EXPRESSION_REGISTERS ) {
common->Warning( "GetExpressionTemporary: material '%s' hit MAX_EXPRESSION_REGISTERS", GetName() );
SetMaterialFlag( MF_DEFAULTED );
return 0;
}
pd->registerIsTemporary[numRegisters] = true;
numRegisters++;
return numRegisters - 1;
}
/*
=============
idMaterial::GetExpressionOp
=============
*/
expOp_t *idMaterial::GetExpressionOp( void ) {
if ( numOps == MAX_EXPRESSION_OPS ) {
common->Warning( "GetExpressionOp: material '%s' hit MAX_EXPRESSION_OPS", GetName() );
SetMaterialFlag( MF_DEFAULTED );
return &pd->shaderOps[0];
}
return &pd->shaderOps[numOps++];
}
/*
=================
idMaterial::EmitOp
=================
*/
int idMaterial::EmitOp( int a, int b, expOpType_t opType ) {
expOp_t *op;
// optimize away identity operations
if ( opType == OP_TYPE_ADD ) {
if ( !pd->registerIsTemporary[a] && pd->shaderRegisters[a] == 0 ) {
return b;
}
if ( !pd->registerIsTemporary[b] && pd->shaderRegisters[b] == 0 ) {
return a;
}
if ( !pd->registerIsTemporary[a] && !pd->registerIsTemporary[b] ) {
return GetExpressionConstant( pd->shaderRegisters[a] + pd->shaderRegisters[b] );
}
}
if ( opType == OP_TYPE_MULTIPLY ) {
if ( !pd->registerIsTemporary[a] && pd->shaderRegisters[a] == 1 ) {
return b;
}
if ( !pd->registerIsTemporary[a] && pd->shaderRegisters[a] == 0 ) {
return a;
}
if ( !pd->registerIsTemporary[b] && pd->shaderRegisters[b] == 1 ) {
return a;
}
if ( !pd->registerIsTemporary[b] && pd->shaderRegisters[b] == 0 ) {
return b;
}
if ( !pd->registerIsTemporary[a] && !pd->registerIsTemporary[b] ) {
return GetExpressionConstant( pd->shaderRegisters[a] * pd->shaderRegisters[b] );
}
}
op = GetExpressionOp();
op->opType = opType;
op->a = a;
op->b = b;
op->c = GetExpressionTemporary();
return op->c;
}
/*
=================
idMaterial::ParseEmitOp
=================
*/
int idMaterial::ParseEmitOp( idLexer &src, int a, expOpType_t opType, int priority ) {
int b;
b = ParseExpressionPriority( src, priority );
return EmitOp( a, b, opType );
}
/*
=================
idMaterial::ParseTerm
Returns a register index
=================
*/
int idMaterial::ParseTerm( idLexer &src ) {
idToken token;
int a, b;
src.ReadToken( &token );
if ( token == "(" ) {
a = ParseExpression( src );
MatchToken( src, ")" );
return a;
}
if ( !token.Icmp( "time" ) ) {
pd->registersAreConstant = false;
return EXP_REG_TIME;
}
if ( !token.Icmp( "parm0" ) ) {
pd->registersAreConstant = false;
return EXP_REG_PARM0;
}
if ( !token.Icmp( "parm1" ) ) {
pd->registersAreConstant = false;
return EXP_REG_PARM1;
}
if ( !token.Icmp( "parm2" ) ) {
pd->registersAreConstant = false;
return EXP_REG_PARM2;
}
if ( !token.Icmp( "parm3" ) ) {
pd->registersAreConstant = false;
return EXP_REG_PARM3;
}
if ( !token.Icmp( "parm4" ) ) {
pd->registersAreConstant = false;
return EXP_REG_PARM4;
}
if ( !token.Icmp( "parm5" ) ) {
pd->registersAreConstant = false;
return EXP_REG_PARM5;
}
if ( !token.Icmp( "parm6" ) ) {
pd->registersAreConstant = false;
return EXP_REG_PARM6;
}
if ( !token.Icmp( "parm7" ) ) {
pd->registersAreConstant = false;
return EXP_REG_PARM7;
}
if ( !token.Icmp( "parm8" ) ) {
pd->registersAreConstant = false;
return EXP_REG_PARM8;
}
if ( !token.Icmp( "parm9" ) ) {
pd->registersAreConstant = false;
return EXP_REG_PARM9;
}
if ( !token.Icmp( "parm10" ) ) {
pd->registersAreConstant = false;
return EXP_REG_PARM10;
}
if ( !token.Icmp( "parm11" ) ) {
pd->registersAreConstant = false;
return EXP_REG_PARM11;
}
if ( !token.Icmp( "global0" ) ) {
pd->registersAreConstant = false;
return EXP_REG_GLOBAL0;
}
if ( !token.Icmp( "global1" ) ) {
pd->registersAreConstant = false;
return EXP_REG_GLOBAL1;
}
if ( !token.Icmp( "global2" ) ) {
pd->registersAreConstant = false;
return EXP_REG_GLOBAL2;
}
if ( !token.Icmp( "global3" ) ) {
pd->registersAreConstant = false;
return EXP_REG_GLOBAL3;
}
if ( !token.Icmp( "global4" ) ) {
pd->registersAreConstant = false;
return EXP_REG_GLOBAL4;
}
if ( !token.Icmp( "global5" ) ) {
pd->registersAreConstant = false;
return EXP_REG_GLOBAL5;
}
if ( !token.Icmp( "global6" ) ) {
pd->registersAreConstant = false;
return EXP_REG_GLOBAL6;
}
if ( !token.Icmp( "global7" ) ) {
pd->registersAreConstant = false;
return EXP_REG_GLOBAL7;
}
if ( !token.Icmp( "fragmentPrograms" ) ) {
return GetExpressionConstant( (float) glConfig.ARBFragmentProgramAvailable );
}
if ( !token.Icmp( "sound" ) ) {
pd->registersAreConstant = false;
return EmitOp( 0, 0, OP_TYPE_SOUND );
}
// parse negative numbers
if ( token == "-" ) {
src.ReadToken( &token );
if ( token.type == TT_NUMBER || token == "." ) {
return GetExpressionConstant( -(float) token.GetFloatValue() );
}
src.Warning( "Bad negative number '%s'", token.c_str() );
SetMaterialFlag( MF_DEFAULTED );
return 0;
}
if ( token.type == TT_NUMBER || token == "." || token == "-" ) {
return GetExpressionConstant( (float) token.GetFloatValue() );
}
// see if it is a table name
const idDeclTable *table = static_cast<const idDeclTable *>( declManager->FindType( DECL_TABLE, token.c_str(), false ) );
if ( !table ) {
src.Warning( "Bad term '%s'", token.c_str() );
SetMaterialFlag( MF_DEFAULTED );
return 0;
}
// parse a table expression
MatchToken( src, "[" );
b = ParseExpression( src );
MatchToken( src, "]" );
return EmitOp( table->Index(), b, OP_TYPE_TABLE );
}
/*
=================
idMaterial::ParseExpressionPriority
Returns a register index
=================
*/
#define TOP_PRIORITY 4
int idMaterial::ParseExpressionPriority( idLexer &src, int priority ) {
idToken token;
int a;
if ( priority == 0 ) {
return ParseTerm( src );
}
a = ParseExpressionPriority( src, priority - 1 );
if ( TestMaterialFlag( MF_DEFAULTED ) ) { // we have a parse error
return 0;
}
if ( !src.ReadToken( &token ) ) {
// we won't get EOF in a real file, but we can
// when parsing from generated strings
return a;
}
if ( priority == 1 && token == "*" ) {
return ParseEmitOp( src, a, OP_TYPE_MULTIPLY, priority );
}
if ( priority == 1 && token == "/" ) {
return ParseEmitOp( src, a, OP_TYPE_DIVIDE, priority );
}
if ( priority == 1 && token == "%" ) { // implied truncate both to integer
return ParseEmitOp( src, a, OP_TYPE_MOD, priority );
}
if ( priority == 2 && token == "+" ) {
return ParseEmitOp( src, a, OP_TYPE_ADD, priority );
}
if ( priority == 2 && token == "-" ) {
return ParseEmitOp( src, a, OP_TYPE_SUBTRACT, priority );
}
if ( priority == 3 && token == ">" ) {
return ParseEmitOp( src, a, OP_TYPE_GT, priority );
}
if ( priority == 3 && token == ">=" ) {
return ParseEmitOp( src, a, OP_TYPE_GE, priority );
}
if ( priority == 3 && token == "<" ) {
return ParseEmitOp( src, a, OP_TYPE_LT, priority );
}
if ( priority == 3 && token == "<=" ) {
return ParseEmitOp( src, a, OP_TYPE_LE, priority );
}
if ( priority == 3 && token == "==" ) {
return ParseEmitOp( src, a, OP_TYPE_EQ, priority );
}
if ( priority == 3 && token == "!=" ) {
return ParseEmitOp( src, a, OP_TYPE_NE, priority );
}
if ( priority == 4 && token == "&&" ) {
return ParseEmitOp( src, a, OP_TYPE_AND, priority );
}
if ( priority == 4 && token == "||" ) {
return ParseEmitOp( src, a, OP_TYPE_OR, priority );
}
// assume that anything else terminates the expression
// not too robust error checking...
src.UnreadToken( &token );
return a;
}
/*
=================
idMaterial::ParseExpression
Returns a register index
=================
*/
int idMaterial::ParseExpression( idLexer &src ) {
return ParseExpressionPriority( src, TOP_PRIORITY );
}
/*
===============
idMaterial::ClearStage
===============
*/
void idMaterial::ClearStage( shaderStage_t *ss ) {
ss->drawStateBits = 0;
ss->conditionRegister = GetExpressionConstant( 1 );
ss->color.registers[0] =
ss->color.registers[1] =
ss->color.registers[2] =
ss->color.registers[3] = GetExpressionConstant( 1 );
}
/*
===============
idMaterial::NameToSrcBlendMode
===============
*/
int idMaterial::NameToSrcBlendMode( const idStr &name ) {
if ( !name.Icmp( "GL_ONE" ) ) {
return GLS_SRCBLEND_ONE;
} else if ( !name.Icmp( "GL_ZERO" ) ) {
return GLS_SRCBLEND_ZERO;
} else if ( !name.Icmp( "GL_DST_COLOR" ) ) {
return GLS_SRCBLEND_DST_COLOR;
} else if ( !name.Icmp( "GL_ONE_MINUS_DST_COLOR" ) ) {
return GLS_SRCBLEND_ONE_MINUS_DST_COLOR;
} else if ( !name.Icmp( "GL_SRC_ALPHA" ) ) {
return GLS_SRCBLEND_SRC_ALPHA;
} else if ( !name.Icmp( "GL_ONE_MINUS_SRC_ALPHA" ) ) {
return GLS_SRCBLEND_ONE_MINUS_SRC_ALPHA;
} else if ( !name.Icmp( "GL_DST_ALPHA" ) ) {
return GLS_SRCBLEND_DST_ALPHA;
} else if ( !name.Icmp( "GL_ONE_MINUS_DST_ALPHA" ) ) {
return GLS_SRCBLEND_ONE_MINUS_DST_ALPHA;
} else if ( !name.Icmp( "GL_SRC_ALPHA_SATURATE" ) ) {
return GLS_SRCBLEND_ALPHA_SATURATE;
}
common->Warning( "unknown blend mode '%s' in material '%s'", name.c_str(), GetName() );
SetMaterialFlag( MF_DEFAULTED );
return GLS_SRCBLEND_ONE;
}
/*
===============
idMaterial::NameToDstBlendMode
===============
*/
int idMaterial::NameToDstBlendMode( const idStr &name ) {
if ( !name.Icmp( "GL_ONE" ) ) {
return GLS_DSTBLEND_ONE;
} else if ( !name.Icmp( "GL_ZERO" ) ) {
return GLS_DSTBLEND_ZERO;
} else if ( !name.Icmp( "GL_SRC_ALPHA" ) ) {
return GLS_DSTBLEND_SRC_ALPHA;
} else if ( !name.Icmp( "GL_ONE_MINUS_SRC_ALPHA" ) ) {
return GLS_DSTBLEND_ONE_MINUS_SRC_ALPHA;
} else if ( !name.Icmp( "GL_DST_ALPHA" ) ) {
return GLS_DSTBLEND_DST_ALPHA;
} else if ( !name.Icmp( "GL_ONE_MINUS_DST_ALPHA" ) ) {
return GLS_DSTBLEND_ONE_MINUS_DST_ALPHA;
} else if ( !name.Icmp( "GL_SRC_COLOR" ) ) {
return GLS_DSTBLEND_SRC_COLOR;
} else if ( !name.Icmp( "GL_ONE_MINUS_SRC_COLOR" ) ) {
return GLS_DSTBLEND_ONE_MINUS_SRC_COLOR;
}
common->Warning( "unknown blend mode '%s' in material '%s'", name.c_str(), GetName() );
SetMaterialFlag( MF_DEFAULTED );
return GLS_DSTBLEND_ONE;
}
/*
================
idMaterial::ParseBlend
================
*/
void idMaterial::ParseBlend( idLexer &src, shaderStage_t *stage ) {
idToken token;
int srcBlend, dstBlend;
if ( !src.ReadToken( &token ) ) {
return;
}
// blending combinations
if ( !token.Icmp( "blend" ) ) {
stage->drawStateBits = GLS_SRCBLEND_SRC_ALPHA | GLS_DSTBLEND_ONE_MINUS_SRC_ALPHA;
return;
}
if ( !token.Icmp( "add" ) ) {
stage->drawStateBits = GLS_SRCBLEND_ONE | GLS_DSTBLEND_ONE;
return;
}
if ( !token.Icmp( "filter" ) || !token.Icmp( "modulate" ) ) {
stage->drawStateBits = GLS_SRCBLEND_DST_COLOR | GLS_DSTBLEND_ZERO;
return;
}
if ( !token.Icmp( "none" ) ) {
// none is used when defining an alpha mask that doesn't draw
stage->drawStateBits = GLS_SRCBLEND_ZERO | GLS_DSTBLEND_ONE;
return;
}
if ( !token.Icmp( "bumpmap" ) ) {
stage->lighting = SL_BUMP;
return;
}
if ( !token.Icmp( "diffusemap" ) ) {
stage->lighting = SL_DIFFUSE;
return;
}
if ( !token.Icmp( "specularmap" ) ) {
stage->lighting = SL_SPECULAR;
return;
}
srcBlend = NameToSrcBlendMode( token );
MatchToken( src, "," );
if ( !src.ReadToken( &token ) ) {
return;
}
dstBlend = NameToDstBlendMode( token );
stage->drawStateBits = srcBlend | dstBlend;
}
/*
================
idMaterial::ParseVertexParm
If there is a single value, it will be repeated across all elements
If there are two values, 3 = 0.0, 4 = 1.0
if there are three values, 4 = 1.0
================
*/
void idMaterial::ParseVertexParm( idLexer &src, newShaderStage_t *newStage ) {
idToken token;
src.ReadTokenOnLine( &token );
int parm = token.GetIntValue();
if ( !token.IsNumeric() || parm < 0 || parm >= MAX_VERTEX_PARMS ) {
common->Warning( "bad vertexParm number\n" );
SetMaterialFlag( MF_DEFAULTED );
return;
}
if ( parm >= newStage->numVertexParms ) {
newStage->numVertexParms = parm+1;
}
newStage->vertexParms[parm][0] = ParseExpression( src );
src.ReadTokenOnLine( &token );
if ( !token[0] || token.Icmp( "," ) ) {
newStage->vertexParms[parm][1] =
newStage->vertexParms[parm][2] =
newStage->vertexParms[parm][3] = newStage->vertexParms[parm][0];
return;
}
newStage->vertexParms[parm][1] = ParseExpression( src );
src.ReadTokenOnLine( &token );
if ( !token[0] || token.Icmp( "," ) ) {
newStage->vertexParms[parm][2] = GetExpressionConstant( 0 );
newStage->vertexParms[parm][3] = GetExpressionConstant( 1 );
return;
}
newStage->vertexParms[parm][2] = ParseExpression( src );
src.ReadTokenOnLine( &token );
if ( !token[0] || token.Icmp( "," ) ) {
newStage->vertexParms[parm][3] = GetExpressionConstant( 1 );
return;
}
newStage->vertexParms[parm][3] = ParseExpression( src );
}
/*
================
idMaterial::ParseFragmentMap
================
*/
void idMaterial::ParseFragmentMap( idLexer &src, newShaderStage_t *newStage ) {
const char *str;
textureFilter_t tf;
textureRepeat_t trp;
textureDepth_t td;
cubeFiles_t cubeMap;
bool allowPicmip;
idToken token;
tf = TF_DEFAULT;
trp = TR_REPEAT;
td = TD_DEFAULT;
allowPicmip = true;
cubeMap = CF_2D;
src.ReadTokenOnLine( &token );
int unit = token.GetIntValue();
if ( !token.IsNumeric() || unit < 0 || unit >= MAX_FRAGMENT_IMAGES ) {
common->Warning( "bad fragmentMap number\n" );
SetMaterialFlag( MF_DEFAULTED );
return;
}
// unit 1 is the normal map.. make sure it gets flagged as the proper depth
if ( unit == 1 ) {
td = TD_BUMP;
}
if ( unit >= newStage->numFragmentProgramImages ) {
newStage->numFragmentProgramImages = unit+1;
}
while( 1 ) {
src.ReadTokenOnLine( &token );
if ( !token.Icmp( "cubeMap" ) ) {
cubeMap = CF_NATIVE;
continue;
}
if ( !token.Icmp( "cameraCubeMap" ) ) {
cubeMap = CF_CAMERA;
continue;
}
if ( !token.Icmp( "nearest" ) ) {
tf = TF_NEAREST;
continue;
}
if ( !token.Icmp( "linear" ) ) {
tf = TF_LINEAR;
continue;
}
if ( !token.Icmp( "clamp" ) ) {
trp = TR_CLAMP;
continue;
}
if ( !token.Icmp( "noclamp" ) ) {
trp = TR_REPEAT;
continue;
}
if ( !token.Icmp( "zeroclamp" ) ) {
trp = TR_CLAMP_TO_ZERO;
continue;
}
if ( !token.Icmp( "alphazeroclamp" ) ) {
trp = TR_CLAMP_TO_ZERO_ALPHA;
continue;
}
if ( !token.Icmp( "forceHighQuality" ) ) {
td = TD_HIGH_QUALITY;
continue;
}
if ( !token.Icmp( "uncompressed" ) || !token.Icmp( "highquality" ) ) {
if ( !globalImages->image_ignoreHighQuality.GetInteger() ) {
td = TD_HIGH_QUALITY;
}
continue;
}
if ( !token.Icmp( "nopicmip" ) ) {
allowPicmip = false;
continue;
}
// assume anything else is the image name
src.UnreadToken( &token );
break;
}
str = R_ParsePastImageProgram( src );
newStage->fragmentProgramImages[unit] =
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globalImages->ImageFromFile( str, tf, allowPicmip, trp, td, cubeMap );
if ( !newStage->fragmentProgramImages[unit] ) {
newStage->fragmentProgramImages[unit] = globalImages->defaultImage;
}
}
/*
===============
idMaterial::MultiplyTextureMatrix
===============
*/
void idMaterial::MultiplyTextureMatrix( textureStage_t *ts, int registers[2][3] ) {
int old[2][3];
if ( !ts->hasMatrix ) {
ts->hasMatrix = true;
memcpy( ts->matrix, registers, sizeof( ts->matrix ) );
return;
}
memcpy( old, ts->matrix, sizeof( old ) );
// multiply the two maticies
ts->matrix[0][0] = EmitOp(
EmitOp( old[0][0], registers[0][0], OP_TYPE_MULTIPLY ),
EmitOp( old[0][1], registers[1][0], OP_TYPE_MULTIPLY ), OP_TYPE_ADD );
ts->matrix[0][1] = EmitOp(
EmitOp( old[0][0], registers[0][1], OP_TYPE_MULTIPLY ),
EmitOp( old[0][1], registers[1][1], OP_TYPE_MULTIPLY ), OP_TYPE_ADD );
ts->matrix[0][2] = EmitOp(
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EmitOp(
EmitOp( old[0][0], registers[0][2], OP_TYPE_MULTIPLY ),
EmitOp( old[0][1], registers[1][2], OP_TYPE_MULTIPLY ), OP_TYPE_ADD ),
old[0][2], OP_TYPE_ADD );
ts->matrix[1][0] = EmitOp(
EmitOp( old[1][0], registers[0][0], OP_TYPE_MULTIPLY ),
EmitOp( old[1][1], registers[1][0], OP_TYPE_MULTIPLY ), OP_TYPE_ADD );
ts->matrix[1][1] = EmitOp(
EmitOp( old[1][0], registers[0][1], OP_TYPE_MULTIPLY ),
EmitOp( old[1][1], registers[1][1], OP_TYPE_MULTIPLY ), OP_TYPE_ADD );
ts->matrix[1][2] = EmitOp(
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EmitOp(
EmitOp( old[1][0], registers[0][2], OP_TYPE_MULTIPLY ),
EmitOp( old[1][1], registers[1][2], OP_TYPE_MULTIPLY ), OP_TYPE_ADD ),
old[1][2], OP_TYPE_ADD );
}
/*
=================
idMaterial::ParseStage
An open brace has been parsed
{
if <expression>
map <imageprogram>
"nearest" "linear" "clamp" "zeroclamp" "uncompressed" "highquality" "nopicmip"
scroll, scale, rotate
}
=================
*/
void idMaterial::ParseStage( idLexer &src, const textureRepeat_t trpDefault ) {
idToken token;
const char *str;
shaderStage_t *ss;
textureStage_t *ts;
textureFilter_t tf;
textureRepeat_t trp;
textureDepth_t td;
cubeFiles_t cubeMap;
bool allowPicmip;
char imageName[MAX_IMAGE_NAME];
int a, b;
int matrix[2][3];
newShaderStage_t newStage;
if ( numStages >= MAX_SHADER_STAGES ) {
SetMaterialFlag( MF_DEFAULTED );
common->Warning( "material '%s' exceeded %i stages", GetName(), MAX_SHADER_STAGES );
}
tf = TF_DEFAULT;
trp = trpDefault;
td = TD_DEFAULT;
allowPicmip = true;
cubeMap = CF_2D;
imageName[0] = 0;
memset( &newStage, 0, sizeof( newStage ) );
ss = &pd->parseStages[numStages];
ts = &ss->texture;
ClearStage( ss );
while ( 1 ) {
if ( TestMaterialFlag( MF_DEFAULTED ) ) { // we have a parse error
return;
}
if ( !src.ExpectAnyToken( &token ) ) {
SetMaterialFlag( MF_DEFAULTED );
return;
}
// the close brace for the entire material ends the draw block
if ( token == "}" ) {
break;
}
//BSM Nerve: Added for stage naming in the material editor
if( !token.Icmp( "name") ) {
src.SkipRestOfLine();
continue;
}
// image options
if ( !token.Icmp( "blend" ) ) {
ParseBlend( src, ss );
continue;
}
if ( !token.Icmp( "map" ) ) {
str = R_ParsePastImageProgram( src );
idStr::Copynz( imageName, str, sizeof( imageName ) );
continue;
}
if ( !token.Icmp( "remoteRenderMap" ) ) {
ts->dynamic = DI_REMOTE_RENDER;
ts->width = src.ParseInt();
ts->height = src.ParseInt();
continue;
}
if ( !token.Icmp( "mirrorRenderMap" ) ) {
ts->dynamic = DI_MIRROR_RENDER;
ts->width = src.ParseInt();
ts->height = src.ParseInt();
ts->texgen = TG_SCREEN;
continue;
}
if ( !token.Icmp( "xrayRenderMap" ) ) {
ts->dynamic = DI_XRAY_RENDER;
ts->width = src.ParseInt();
ts->height = src.ParseInt();
ts->texgen = TG_SCREEN;
continue;
}
if ( !token.Icmp( "screen" ) ) {
ts->texgen = TG_SCREEN;
continue;
}
if ( !token.Icmp( "screen2" ) ) {
ts->texgen = TG_SCREEN2;
continue;
}
if ( !token.Icmp( "glassWarp" ) ) {
ts->texgen = TG_GLASSWARP;
continue;
}
if ( !token.Icmp( "videomap" ) ) {
// note that videomaps will always be in clamp mode, so texture
// coordinates had better be in the 0 to 1 range
if ( !src.ReadToken( &token ) ) {
common->Warning( "missing parameter for 'videoMap' keyword in material '%s'", GetName() );
continue;
}
bool loop = false;
if ( !token.Icmp( "loop" ) ) {
loop = true;
if ( !src.ReadToken( &token ) ) {
common->Warning( "missing parameter for 'videoMap' keyword in material '%s'", GetName() );
continue;
}
}
ts->cinematic = idCinematic::Alloc();
ts->cinematic->InitFromFile( token.c_str(), loop );
continue;
}
if ( !token.Icmp( "soundmap" ) ) {
if ( !src.ReadToken( &token ) ) {
common->Warning( "missing parameter for 'soundmap' keyword in material '%s'", GetName() );
continue;
}
ts->cinematic = new idSndWindow();
ts->cinematic->InitFromFile( token.c_str(), true );
continue;
}
if ( !token.Icmp( "cubeMap" ) ) {
str = R_ParsePastImageProgram( src );
idStr::Copynz( imageName, str, sizeof( imageName ) );
cubeMap = CF_NATIVE;
continue;
}
if ( !token.Icmp( "cameraCubeMap" ) ) {
str = R_ParsePastImageProgram( src );
idStr::Copynz( imageName, str, sizeof( imageName ) );
cubeMap = CF_CAMERA;
continue;
}
if ( !token.Icmp( "ignoreAlphaTest" ) ) {
ss->ignoreAlphaTest = true;
continue;
}
if ( !token.Icmp( "nearest" ) ) {
tf = TF_NEAREST;
continue;
}
if ( !token.Icmp( "linear" ) ) {
tf = TF_LINEAR;
continue;
}
if ( !token.Icmp( "clamp" ) ) {
trp = TR_CLAMP;
continue;
}
if ( !token.Icmp( "noclamp" ) ) {
trp = TR_REPEAT;
continue;
}
if ( !token.Icmp( "zeroclamp" ) ) {
trp = TR_CLAMP_TO_ZERO;
continue;
}
if ( !token.Icmp( "alphazeroclamp" ) ) {
trp = TR_CLAMP_TO_ZERO_ALPHA;
continue;
}
if ( !token.Icmp( "uncompressed" ) || !token.Icmp( "highquality" ) ) {
if ( !globalImages->image_ignoreHighQuality.GetInteger() ) {
td = TD_HIGH_QUALITY;
}
continue;
}
if ( !token.Icmp( "forceHighQuality" ) ) {
td = TD_HIGH_QUALITY;
continue;
}
if ( !token.Icmp( "nopicmip" ) ) {
allowPicmip = false;
continue;
}
if ( !token.Icmp( "vertexColor" ) ) {
ss->vertexColor = SVC_MODULATE;
continue;
}
if ( !token.Icmp( "inverseVertexColor" ) ) {
ss->vertexColor = SVC_INVERSE_MODULATE;
continue;
}
// privatePolygonOffset
else if ( !token.Icmp( "privatePolygonOffset" ) ) {
if ( !src.ReadTokenOnLine( &token ) ) {
ss->privatePolygonOffset = 1;
continue;
}
// explict larger (or negative) offset
src.UnreadToken( &token );
ss->privatePolygonOffset = src.ParseFloat();
continue;
}
// texture coordinate generation
if ( !token.Icmp( "texGen" ) ) {
src.ExpectAnyToken( &token );
if ( !token.Icmp( "normal" ) ) {
ts->texgen = TG_DIFFUSE_CUBE;
} else if ( !token.Icmp( "reflect" ) ) {
ts->texgen = TG_REFLECT_CUBE;
} else if ( !token.Icmp( "skybox" ) ) {
ts->texgen = TG_SKYBOX_CUBE;
} else if ( !token.Icmp( "wobbleSky" ) ) {
ts->texgen = TG_WOBBLESKY_CUBE;
texGenRegisters[0] = ParseExpression( src );
texGenRegisters[1] = ParseExpression( src );
texGenRegisters[2] = ParseExpression( src );
} else {
common->Warning( "bad texGen '%s' in material %s", token.c_str(), GetName() );
SetMaterialFlag( MF_DEFAULTED );
}
continue;
}
if ( !token.Icmp( "scroll" ) || !token.Icmp( "translate" ) ) {
a = ParseExpression( src );
MatchToken( src, "," );
b = ParseExpression( src );
matrix[0][0] = GetExpressionConstant( 1 );
matrix[0][1] = GetExpressionConstant( 0 );
matrix[0][2] = a;
matrix[1][0] = GetExpressionConstant( 0 );
matrix[1][1] = GetExpressionConstant( 1 );
matrix[1][2] = b;
MultiplyTextureMatrix( ts, matrix );
continue;
}
if ( !token.Icmp( "scale" ) ) {
a = ParseExpression( src );
MatchToken( src, "," );
b = ParseExpression( src );
// this just scales without a centering
matrix[0][0] = a;
matrix[0][1] = GetExpressionConstant( 0 );
matrix[0][2] = GetExpressionConstant( 0 );
matrix[1][0] = GetExpressionConstant( 0 );
matrix[1][1] = b;
matrix[1][2] = GetExpressionConstant( 0 );
MultiplyTextureMatrix( ts, matrix );
continue;
}
if ( !token.Icmp( "centerScale" ) ) {
a = ParseExpression( src );
MatchToken( src, "," );
b = ParseExpression( src );
// this subtracts 0.5, then scales, then adds 0.5
matrix[0][0] = a;
matrix[0][1] = GetExpressionConstant( 0 );
matrix[0][2] = EmitOp( GetExpressionConstant( 0.5 ), EmitOp( GetExpressionConstant( 0.5 ), a, OP_TYPE_MULTIPLY ), OP_TYPE_SUBTRACT );
matrix[1][0] = GetExpressionConstant( 0 );
matrix[1][1] = b;
matrix[1][2] = EmitOp( GetExpressionConstant( 0.5 ), EmitOp( GetExpressionConstant( 0.5 ), b, OP_TYPE_MULTIPLY ), OP_TYPE_SUBTRACT );
MultiplyTextureMatrix( ts, matrix );
continue;
}
if ( !token.Icmp( "shear" ) ) {
a = ParseExpression( src );
MatchToken( src, "," );
b = ParseExpression( src );
// this subtracts 0.5, then shears, then adds 0.5
matrix[0][0] = GetExpressionConstant( 1 );
matrix[0][1] = a;
matrix[0][2] = EmitOp( GetExpressionConstant( -0.5 ), a, OP_TYPE_MULTIPLY );
matrix[1][0] = b;
matrix[1][1] = GetExpressionConstant( 1 );
matrix[1][2] = EmitOp( GetExpressionConstant( -0.5 ), b, OP_TYPE_MULTIPLY );
MultiplyTextureMatrix( ts, matrix );
continue;
}
if ( !token.Icmp( "rotate" ) ) {
const idDeclTable *table;
int sinReg, cosReg;
// in cycles
a = ParseExpression( src );
table = static_cast<const idDeclTable *>( declManager->FindType( DECL_TABLE, "sinTable", false ) );
if ( !table ) {
common->Warning( "no sinTable for rotate defined" );
SetMaterialFlag( MF_DEFAULTED );
return;
}
sinReg = EmitOp( table->Index(), a, OP_TYPE_TABLE );
table = static_cast<const idDeclTable *>( declManager->FindType( DECL_TABLE, "cosTable", false ) );
if ( !table ) {
common->Warning( "no cosTable for rotate defined" );
SetMaterialFlag( MF_DEFAULTED );
return;
}
cosReg = EmitOp( table->Index(), a, OP_TYPE_TABLE );
// this subtracts 0.5, then rotates, then adds 0.5
matrix[0][0] = cosReg;
matrix[0][1] = EmitOp( GetExpressionConstant( 0 ), sinReg, OP_TYPE_SUBTRACT );
matrix[0][2] = EmitOp( EmitOp( EmitOp( GetExpressionConstant( -0.5 ), cosReg, OP_TYPE_MULTIPLY ),
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EmitOp( GetExpressionConstant( 0.5 ), sinReg, OP_TYPE_MULTIPLY ), OP_TYPE_ADD ),
GetExpressionConstant( 0.5 ), OP_TYPE_ADD );
matrix[1][0] = sinReg;
matrix[1][1] = cosReg;
matrix[1][2] = EmitOp( EmitOp( EmitOp( GetExpressionConstant( -0.5 ), sinReg, OP_TYPE_MULTIPLY ),
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EmitOp( GetExpressionConstant( -0.5 ), cosReg, OP_TYPE_MULTIPLY ), OP_TYPE_ADD ),
GetExpressionConstant( 0.5 ), OP_TYPE_ADD );
MultiplyTextureMatrix( ts, matrix );
continue;
}
// color mask options
if ( !token.Icmp( "maskRed" ) ) {
ss->drawStateBits |= GLS_REDMASK;
continue;
}
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if ( !token.Icmp( "maskGreen" ) ) {
ss->drawStateBits |= GLS_GREENMASK;
continue;
}
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if ( !token.Icmp( "maskBlue" ) ) {
ss->drawStateBits |= GLS_BLUEMASK;
continue;
}
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if ( !token.Icmp( "maskAlpha" ) ) {
ss->drawStateBits |= GLS_ALPHAMASK;
continue;
}
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if ( !token.Icmp( "maskColor" ) ) {
ss->drawStateBits |= GLS_COLORMASK;
continue;
}
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if ( !token.Icmp( "maskDepth" ) ) {
ss->drawStateBits |= GLS_DEPTHMASK;
continue;
}
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if ( !token.Icmp( "alphaTest" ) ) {
ss->hasAlphaTest = true;
ss->alphaTestRegister = ParseExpression( src );
coverage = MC_PERFORATED;
continue;
}
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// shorthand for 2D modulated
if ( !token.Icmp( "colored" ) ) {
ss->color.registers[0] = EXP_REG_PARM0;
ss->color.registers[1] = EXP_REG_PARM1;
ss->color.registers[2] = EXP_REG_PARM2;
ss->color.registers[3] = EXP_REG_PARM3;
pd->registersAreConstant = false;
continue;
}
if ( !token.Icmp( "color" ) ) {
ss->color.registers[0] = ParseExpression( src );
MatchToken( src, "," );
ss->color.registers[1] = ParseExpression( src );
MatchToken( src, "," );
ss->color.registers[2] = ParseExpression( src );
MatchToken( src, "," );
ss->color.registers[3] = ParseExpression( src );
continue;
}
if ( !token.Icmp( "red" ) ) {
ss->color.registers[0] = ParseExpression( src );
continue;
}
if ( !token.Icmp( "green" ) ) {
ss->color.registers[1] = ParseExpression( src );
continue;
}
if ( !token.Icmp( "blue" ) ) {
ss->color.registers[2] = ParseExpression( src );
continue;
}
if ( !token.Icmp( "alpha" ) ) {
ss->color.registers[3] = ParseExpression( src );
continue;
}
if ( !token.Icmp( "rgb" ) ) {
ss->color.registers[0] = ss->color.registers[1] =
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ss->color.registers[2] = ParseExpression( src );
continue;
}
if ( !token.Icmp( "rgba" ) ) {
ss->color.registers[0] = ss->color.registers[1] =
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ss->color.registers[2] = ss->color.registers[3] = ParseExpression( src );
continue;
}
if ( !token.Icmp( "if" ) ) {
ss->conditionRegister = ParseExpression( src );
continue;
}
if ( !token.Icmp( "program" ) ) {
if ( src.ReadTokenOnLine( &token ) ) {
newStage.vertexProgram = R_FindARBProgram( GL_VERTEX_PROGRAM_ARB, token.c_str() );
newStage.fragmentProgram = R_FindARBProgram( GL_FRAGMENT_PROGRAM_ARB, token.c_str() );
}
continue;
}
if ( !token.Icmp( "fragmentProgram" ) ) {
if ( src.ReadTokenOnLine( &token ) ) {
newStage.fragmentProgram = R_FindARBProgram( GL_FRAGMENT_PROGRAM_ARB, token.c_str() );
}
continue;
}
if ( !token.Icmp( "vertexProgram" ) ) {
if ( src.ReadTokenOnLine( &token ) ) {
newStage.vertexProgram = R_FindARBProgram( GL_VERTEX_PROGRAM_ARB, token.c_str() );
}
continue;
}
if ( !token.Icmp( "megaTexture" ) ) {
if ( src.ReadTokenOnLine( &token ) ) {
newStage.megaTexture = new idMegaTexture;
if ( !newStage.megaTexture->InitFromMegaFile( token.c_str() ) ) {
delete newStage.megaTexture;
SetMaterialFlag( MF_DEFAULTED );
continue;
}
newStage.vertexProgram = R_FindARBProgram( GL_VERTEX_PROGRAM_ARB, "megaTexture.vfp" );
newStage.fragmentProgram = R_FindARBProgram( GL_FRAGMENT_PROGRAM_ARB, "megaTexture.vfp" );
continue;
}
}
if ( !token.Icmp( "vertexParm" ) ) {
ParseVertexParm( src, &newStage );
continue;
}
if ( !token.Icmp( "fragmentMap" ) ) {
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ParseFragmentMap( src, &newStage );
continue;
}
common->Warning( "unknown token '%s' in material '%s'", token.c_str(), GetName() );
SetMaterialFlag( MF_DEFAULTED );
return;
}
// if we are using newStage, allocate a copy of it
if ( newStage.fragmentProgram || newStage.vertexProgram ) {
ss->newStage = (newShaderStage_t *)Mem_Alloc( sizeof( newStage ) );
*(ss->newStage) = newStage;
}
// successfully parsed a stage
numStages++;
// select a compressed depth based on what the stage is
if ( td == TD_DEFAULT ) {
switch( ss->lighting ) {
case SL_BUMP:
td = TD_BUMP;
break;
case SL_DIFFUSE:
td = TD_DIFFUSE;
break;
case SL_SPECULAR:
td = TD_SPECULAR;
break;
default:
break;
}
}
// now load the image with all the parms we parsed
if ( imageName[0] ) {
ts->image = globalImages->ImageFromFile( imageName, tf, allowPicmip, trp, td, cubeMap );
if ( !ts->image ) {
ts->image = globalImages->defaultImage;
}
} else if ( !ts->cinematic && !ts->dynamic && !ss->newStage ) {
common->Warning( "material '%s' had stage with no image", GetName() );
ts->image = globalImages->defaultImage;
}
}
/*
===============
idMaterial::ParseDeform
===============
*/
void idMaterial::ParseDeform( idLexer &src ) {
idToken token;
if ( !src.ExpectAnyToken( &token ) ) {
return;
}
if ( !token.Icmp( "sprite" ) ) {
deform = DFRM_SPRITE;
cullType = CT_TWO_SIDED;
SetMaterialFlag( MF_NOSHADOWS );
return;
}
if ( !token.Icmp( "tube" ) ) {
deform = DFRM_TUBE;
cullType = CT_TWO_SIDED;
SetMaterialFlag( MF_NOSHADOWS );
return;
}
if ( !token.Icmp( "flare" ) ) {
deform = DFRM_FLARE;
cullType = CT_TWO_SIDED;
deformRegisters[0] = ParseExpression( src );
SetMaterialFlag( MF_NOSHADOWS );
return;
}
if ( !token.Icmp( "expand" ) ) {
deform = DFRM_EXPAND;
deformRegisters[0] = ParseExpression( src );
return;
}
if ( !token.Icmp( "move" ) ) {
deform = DFRM_MOVE;
deformRegisters[0] = ParseExpression( src );
return;
}
if ( !token.Icmp( "turbulent" ) ) {
deform = DFRM_TURB;
if ( !src.ExpectAnyToken( &token ) ) {
src.Warning( "deform particle missing particle name" );
SetMaterialFlag( MF_DEFAULTED );
return;
}
deformDecl = declManager->FindType( DECL_TABLE, token.c_str(), true );
deformRegisters[0] = ParseExpression( src );
deformRegisters[1] = ParseExpression( src );
deformRegisters[2] = ParseExpression( src );
return;
}
if ( !token.Icmp( "eyeBall" ) ) {
deform = DFRM_EYEBALL;
return;
}
if ( !token.Icmp( "particle" ) ) {
deform = DFRM_PARTICLE;
if ( !src.ExpectAnyToken( &token ) ) {
src.Warning( "deform particle missing particle name" );
SetMaterialFlag( MF_DEFAULTED );
return;
}
deformDecl = declManager->FindType( DECL_PARTICLE, token.c_str(), true );
return;
}
if ( !token.Icmp( "particle2" ) ) {
deform = DFRM_PARTICLE2;
if ( !src.ExpectAnyToken( &token ) ) {
src.Warning( "deform particle missing particle name" );
SetMaterialFlag( MF_DEFAULTED );
return;
}
deformDecl = declManager->FindType( DECL_PARTICLE, token.c_str(), true );
return;
}
src.Warning( "Bad deform type '%s'", token.c_str() );
SetMaterialFlag( MF_DEFAULTED );
}
/*
==============
idMaterial::AddImplicitStages
If a material has diffuse or specular stages without any
bump stage, add an implicit _flat bumpmap stage.
If a material has a bump stage but no diffuse or specular
stage, add a _white diffuse stage.
It is valid to have either a diffuse or specular without the other.
It is valid to have a reflection map and a bump map for bumpy reflection
==============
*/
void idMaterial::AddImplicitStages( const textureRepeat_t trpDefault /* = TR_REPEAT */ ) {
char buffer[1024];
idLexer newSrc;
bool hasDiffuse = false;
bool hasSpecular = false;
bool hasBump = false;
bool hasReflection = false;
for ( int i = 0 ; i < numStages ; i++ ) {
if ( pd->parseStages[i].lighting == SL_BUMP ) {
hasBump = true;
}
if ( pd->parseStages[i].lighting == SL_DIFFUSE ) {
hasDiffuse = true;
}
if ( pd->parseStages[i].lighting == SL_SPECULAR ) {
hasSpecular = true;
}
if ( pd->parseStages[i].texture.texgen == TG_REFLECT_CUBE ) {
hasReflection = true;
}
}
// if it doesn't have an interaction at all, don't add anything
if ( !hasBump && !hasDiffuse && !hasSpecular ) {
return;
}
if ( numStages == MAX_SHADER_STAGES ) {
return;
}
if ( !hasBump ) {
idStr::snPrintf( buffer, sizeof( buffer ), "blend bumpmap\nmap _flat\n}\n" );
newSrc.LoadMemory( buffer, strlen(buffer), "bumpmap" );
newSrc.SetFlags( LEXFL_NOFATALERRORS | LEXFL_NOSTRINGCONCAT | LEXFL_NOSTRINGESCAPECHARS | LEXFL_ALLOWPATHNAMES );
ParseStage( newSrc, trpDefault );
newSrc.FreeSource();
}
if ( !hasDiffuse && !hasSpecular && !hasReflection ) {
idStr::snPrintf( buffer, sizeof( buffer ), "blend diffusemap\nmap _white\n}\n" );
newSrc.LoadMemory( buffer, strlen(buffer), "diffusemap" );
newSrc.SetFlags( LEXFL_NOFATALERRORS | LEXFL_NOSTRINGCONCAT | LEXFL_NOSTRINGESCAPECHARS | LEXFL_ALLOWPATHNAMES );
ParseStage( newSrc, trpDefault );
newSrc.FreeSource();
}
}
/*
===============
idMaterial::SortInteractionStages
The renderer expects bump, then diffuse, then specular
There can be multiple bump maps, followed by additional
diffuse and specular stages, which allows cross-faded bump mapping.
Ambient stages can be interspersed anywhere, but they are
ignored during interactions, and all the interaction
stages are ignored during ambient drawing.
===============
*/
void idMaterial::SortInteractionStages() {
int j;
for ( int i = 0 ; i < numStages ; i = j ) {
// find the next bump map
for ( j = i + 1 ; j < numStages ; j++ ) {
if ( pd->parseStages[j].lighting == SL_BUMP ) {
// if the very first stage wasn't a bumpmap,
// this bumpmap is part of the first group
if ( pd->parseStages[i].lighting != SL_BUMP ) {
continue;
}
break;
}
}
// bubble sort everything bump / diffuse / specular
for ( int l = 1 ; l < j-i ; l++ ) {
for ( int k = i ; k < j-l ; k++ ) {
if ( pd->parseStages[k].lighting > pd->parseStages[k+1].lighting ) {
shaderStage_t temp;
temp = pd->parseStages[k];
pd->parseStages[k] = pd->parseStages[k+1];
pd->parseStages[k+1] = temp;
}
}
}
}
}
/*
=================
idMaterial::ParseMaterial
The current text pointer is at the explicit text definition of the
Parse it into the global material variable. Later functions will optimize it.
If there is any error during parsing, defaultShader will be set.
=================
*/
void idMaterial::ParseMaterial( idLexer &src ) {
idToken token;
char buffer[1024];
const char *str;
idLexer newSrc;
int i;
numOps = 0;
numRegisters = EXP_REG_NUM_PREDEFINED; // leave space for the parms to be copied in
for ( i = 0 ; i < numRegisters ; i++ ) {
pd->registerIsTemporary[i] = true; // they aren't constants that can be folded
}
numStages = 0;
textureRepeat_t trpDefault = TR_REPEAT; // allow a global setting for repeat
while ( 1 ) {
if ( TestMaterialFlag( MF_DEFAULTED ) ) { // we have a parse error
return;
}
if ( !src.ExpectAnyToken( &token ) ) {
SetMaterialFlag( MF_DEFAULTED );
return;
}
// end of material definition
if ( token == "}" ) {
break;
}
else if ( !token.Icmp( "qer_editorimage") ) {
src.ReadTokenOnLine( &token );
editorImageName = token.c_str();
src.SkipRestOfLine();
continue;
}
// description
else if ( !token.Icmp( "description") ) {
src.ReadTokenOnLine( &token );
desc = token.c_str();
continue;
}
// check for the surface / content bit flags
else if ( CheckSurfaceParm( &token ) ) {
continue;
}
// polygonOffset
else if ( !token.Icmp( "polygonOffset" ) ) {
SetMaterialFlag( MF_POLYGONOFFSET );
if ( !src.ReadTokenOnLine( &token ) ) {
polygonOffset = 1;
continue;
}
// explict larger (or negative) offset
polygonOffset = token.GetFloatValue();
continue;
}
// noshadow
else if ( !token.Icmp( "noShadows" ) ) {
SetMaterialFlag( MF_NOSHADOWS );
continue;
}
else if ( !token.Icmp( "suppressInSubview" ) ) {
suppressInSubview = true;
continue;
}
else if ( !token.Icmp( "portalSky" ) ) {
portalSky = true;
continue;
}
// noSelfShadow
else if ( !token.Icmp( "noSelfShadow" ) ) {
SetMaterialFlag( MF_NOSELFSHADOW );
continue;
}
// noPortalFog
else if ( !token.Icmp( "noPortalFog" ) ) {
SetMaterialFlag( MF_NOPORTALFOG );
continue;
}
// forceShadows allows nodraw surfaces to cast shadows
else if ( !token.Icmp( "forceShadows" ) ) {
SetMaterialFlag( MF_FORCESHADOWS );
continue;
}
// overlay / decal suppression
else if ( !token.Icmp( "noOverlays" ) ) {
allowOverlays = false;
continue;
}
// moster blood overlay forcing for alpha tested or translucent surfaces
else if ( !token.Icmp( "forceOverlays" ) ) {
pd->forceOverlays = true;
continue;
}
// translucent
else if ( !token.Icmp( "translucent" ) ) {
coverage = MC_TRANSLUCENT;
continue;
}
// global zero clamp
else if ( !token.Icmp( "zeroclamp" ) ) {
trpDefault = TR_CLAMP_TO_ZERO;
continue;
}
// global clamp
else if ( !token.Icmp( "clamp" ) ) {
trpDefault = TR_CLAMP;
continue;
}
// global clamp
else if ( !token.Icmp( "alphazeroclamp" ) ) {
trpDefault = TR_CLAMP_TO_ZERO;
continue;
}
// forceOpaque is used for skies-behind-windows
else if ( !token.Icmp( "forceOpaque" ) ) {
coverage = MC_OPAQUE;
continue;
}
// twoSided
else if ( !token.Icmp( "twoSided" ) ) {
cullType = CT_TWO_SIDED;
// twoSided implies no-shadows, because the shadow
// volume would be coplanar with the surface, giving depth fighting
// we could make this no-self-shadows, but it may be more important
// to receive shadows from no-self-shadow monsters
SetMaterialFlag( MF_NOSHADOWS );
}
// backSided
else if ( !token.Icmp( "backSided" ) ) {
cullType = CT_BACK_SIDED;
// the shadow code doesn't handle this, so just disable shadows.
// We could fix this in the future if there was a need.
SetMaterialFlag( MF_NOSHADOWS );
}
// foglight
else if ( !token.Icmp( "fogLight" ) ) {
fogLight = true;
continue;
}
// blendlight
else if ( !token.Icmp( "blendLight" ) ) {
blendLight = true;
continue;
}
// ambientLight
else if ( !token.Icmp( "ambientLight" ) ) {
ambientLight = true;
continue;
}
// mirror
else if ( !token.Icmp( "mirror" ) ) {
sort = SS_SUBVIEW;
coverage = MC_OPAQUE;
continue;
}
// noFog
else if ( !token.Icmp( "noFog" ) ) {
noFog = true;
continue;
}
// unsmoothedTangents
else if ( !token.Icmp( "unsmoothedTangents" ) ) {
unsmoothedTangents = true;
continue;
}
// lightFallofImage <imageprogram>
// specifies the image to use for the third axis of projected
// light volumes
else if ( !token.Icmp( "lightFalloffImage" ) ) {
str = R_ParsePastImageProgram( src );
idStr copy;
copy = str; // so other things don't step on it
lightFalloffImage = globalImages->ImageFromFile( copy, TF_DEFAULT, false, TR_CLAMP /* TR_CLAMP_TO_ZERO */, TD_DEFAULT );
continue;
}
// guisurf <guifile> | guisurf entity
// an entity guisurf must have an idUserInterface
// specified in the renderEntity
else if ( !token.Icmp( "guisurf" ) ) {
src.ReadTokenOnLine( &token );
if ( !token.Icmp( "entity" ) ) {
entityGui = 1;
} else if ( !token.Icmp( "entity2" ) ) {
entityGui = 2;
} else if ( !token.Icmp( "entity3" ) ) {
entityGui = 3;
} else {
gui = uiManager->FindGui( token.c_str(), true );
}
continue;
}
// sort
else if ( !token.Icmp( "sort" ) ) {
ParseSort( src );
continue;
}
// spectrum <integer>
else if ( !token.Icmp( "spectrum" ) ) {
src.ReadTokenOnLine( &token );
spectrum = atoi( token.c_str() );
continue;
}
// deform < sprite | tube | flare >
else if ( !token.Icmp( "deform" ) ) {
ParseDeform( src );
continue;
}
// decalInfo <staySeconds> <fadeSeconds> ( <start rgb> ) ( <end rgb> )
else if ( !token.Icmp( "decalInfo" ) ) {
ParseDecalInfo( src );
continue;
}
// renderbump <args...>
else if ( !token.Icmp( "renderbump") ) {
src.ParseRestOfLine( renderBump );
continue;
}
// diffusemap for stage shortcut
else if ( !token.Icmp( "diffusemap" ) ) {
str = R_ParsePastImageProgram( src );
idStr::snPrintf( buffer, sizeof( buffer ), "blend diffusemap\nmap %s\n}\n", str );
newSrc.LoadMemory( buffer, strlen(buffer), "diffusemap" );
newSrc.SetFlags( LEXFL_NOFATALERRORS | LEXFL_NOSTRINGCONCAT | LEXFL_NOSTRINGESCAPECHARS | LEXFL_ALLOWPATHNAMES );
ParseStage( newSrc, trpDefault );
newSrc.FreeSource();
continue;
}
// specularmap for stage shortcut
else if ( !token.Icmp( "specularmap" ) ) {
str = R_ParsePastImageProgram( src );
idStr::snPrintf( buffer, sizeof( buffer ), "blend specularmap\nmap %s\n}\n", str );
newSrc.LoadMemory( buffer, strlen(buffer), "specularmap" );
newSrc.SetFlags( LEXFL_NOFATALERRORS | LEXFL_NOSTRINGCONCAT | LEXFL_NOSTRINGESCAPECHARS | LEXFL_ALLOWPATHNAMES );
ParseStage( newSrc, trpDefault );
newSrc.FreeSource();
continue;
}
// normalmap for stage shortcut
else if ( !token.Icmp( "bumpmap" ) ) {
str = R_ParsePastImageProgram( src );
idStr::snPrintf( buffer, sizeof( buffer ), "blend bumpmap\nmap %s\n}\n", str );
newSrc.LoadMemory( buffer, strlen(buffer), "bumpmap" );
newSrc.SetFlags( LEXFL_NOFATALERRORS | LEXFL_NOSTRINGCONCAT | LEXFL_NOSTRINGESCAPECHARS | LEXFL_ALLOWPATHNAMES );
ParseStage( newSrc, trpDefault );
newSrc.FreeSource();
continue;
}
// DECAL_MACRO for backwards compatibility with the preprocessor macros
else if ( !token.Icmp( "DECAL_MACRO" ) ) {
// polygonOffset
SetMaterialFlag( MF_POLYGONOFFSET );
polygonOffset = 1;
// discrete
surfaceFlags |= SURF_DISCRETE;
contentFlags &= ~CONTENTS_SOLID;
// sort decal
sort = SS_DECAL;
// noShadows
SetMaterialFlag( MF_NOSHADOWS );
continue;
}
else if ( token == "{" ) {
// create the new stage
ParseStage( src, trpDefault );
continue;
}
else {
common->Warning( "unknown general material parameter '%s' in '%s'", token.c_str(), GetName() );
SetMaterialFlag( MF_DEFAULTED );
return;
}
}
// add _flat or _white stages if needed
AddImplicitStages();
// order the diffuse / bump / specular stages properly
SortInteractionStages();
// if we need to do anything with normals (lighting or environment mapping)
// and two sided lighting was asked for, flag
// shouldCreateBackSides() and change culling back to single sided,
// so we get proper tangent vectors on both sides
// we can't just call ReceivesLighting(), because the stages are still
// in temporary form
if ( cullType == CT_TWO_SIDED ) {
for ( i = 0 ; i < numStages ; i++ ) {
if ( pd->parseStages[i].lighting != SL_AMBIENT || pd->parseStages[i].texture.texgen != TG_EXPLICIT ) {
if ( cullType == CT_TWO_SIDED ) {
cullType = CT_FRONT_SIDED;
shouldCreateBackSides = true;
}
break;
}
}
}
// currently a surface can only have one unique texgen for all the stages on old hardware
texgen_t firstGen = TG_EXPLICIT;
for ( i = 0; i < numStages; i++ ) {
if ( pd->parseStages[i].texture.texgen != TG_EXPLICIT ) {
if ( firstGen == TG_EXPLICIT ) {
firstGen = pd->parseStages[i].texture.texgen;
} else if ( firstGen != pd->parseStages[i].texture.texgen ) {
common->Warning( "material '%s' has multiple stages with a texgen", GetName() );
break;
}
}
}
}
/*
=========================
idMaterial::SetGui
=========================
*/
void idMaterial::SetGui( const char *_gui ) const {
gui = uiManager->FindGui( _gui, true, false, true );
}
/*
=========================
idMaterial::Parse
Parses the current material definition and finds all necessary images.
=========================
*/
bool idMaterial::Parse( const char *text, const int textLength ) {
idLexer src;
idToken token;
mtrParsingData_t parsingData;
src.LoadMemory( text, textLength, GetFileName(), GetLineNum() );
src.SetFlags( DECL_LEXER_FLAGS );
src.SkipUntilString( "{" );
// reset to the unparsed state
CommonInit();
memset( &parsingData, 0, sizeof( parsingData ) );
pd = &parsingData; // this is only valid during parse
// parse it
ParseMaterial( src );
// if we are doing an fs_copyfiles, also reference the editorImage
if ( cvarSystem->GetCVarInteger( "fs_copyFiles" ) ) {
GetEditorImage();
}
//
// count non-lit stages
numAmbientStages = 0;
int i;
for ( i = 0 ; i < numStages ; i++ ) {
if ( pd->parseStages[i].lighting == SL_AMBIENT ) {
numAmbientStages++;
}
}
// see if there is a subview stage
if ( sort == SS_SUBVIEW ) {
hasSubview = true;
} else {
hasSubview = false;
for ( i = 0 ; i < numStages ; i++ ) {
if ( pd->parseStages[i].texture.dynamic ) {
hasSubview = true;
}
}
}
// automatically determine coverage if not explicitly set
if ( coverage == MC_BAD ) {
// automatically set MC_TRANSLUCENT if we don't have any interaction stages and
2011-11-22 21:28:15 +00:00
// the first stage is blended and not an alpha test mask or a subview
if ( !numStages ) {
// non-visible
coverage = MC_TRANSLUCENT;
} else if ( numStages != numAmbientStages ) {
// we have an interaction draw
coverage = MC_OPAQUE;
} else if (
2011-11-22 21:28:15 +00:00
( pd->parseStages[0].drawStateBits & GLS_DSTBLEND_BITS ) != GLS_DSTBLEND_ZERO ||
( pd->parseStages[0].drawStateBits & GLS_SRCBLEND_BITS ) == GLS_SRCBLEND_DST_COLOR ||
( pd->parseStages[0].drawStateBits & GLS_SRCBLEND_BITS ) == GLS_SRCBLEND_ONE_MINUS_DST_COLOR ||
( pd->parseStages[0].drawStateBits & GLS_SRCBLEND_BITS ) == GLS_SRCBLEND_DST_ALPHA ||
( pd->parseStages[0].drawStateBits & GLS_SRCBLEND_BITS ) == GLS_SRCBLEND_ONE_MINUS_DST_ALPHA
) {
// blended with the destination
coverage = MC_TRANSLUCENT;
} else {
coverage = MC_OPAQUE;
}
}
// translucent automatically implies noshadows
if ( coverage == MC_TRANSLUCENT ) {
SetMaterialFlag( MF_NOSHADOWS );
} else {
// mark the contents as opaque
contentFlags |= CONTENTS_OPAQUE;
}
// if we are translucent, draw with an alpha in the editor
if ( coverage == MC_TRANSLUCENT ) {
editorAlpha = 0.5;
} else {
editorAlpha = 1.0;
}
// the sorts can make reasonable defaults
if ( sort == SS_BAD ) {
if ( TestMaterialFlag(MF_POLYGONOFFSET) ) {
sort = SS_DECAL;
} else if ( coverage == MC_TRANSLUCENT ) {
sort = SS_MEDIUM;
} else {
sort = SS_OPAQUE;
}
}
// anything that references _currentRender will automatically get sort = SS_POST_PROCESS
// and coverage = MC_TRANSLUCENT
for ( i = 0 ; i < numStages ; i++ ) {
shaderStage_t *pStage = &pd->parseStages[i];
if ( pStage->texture.image == globalImages->currentRenderImage ) {
if ( sort != SS_PORTAL_SKY ) {
sort = SS_POST_PROCESS;
coverage = MC_TRANSLUCENT;
}
break;
}
if ( pStage->newStage ) {
for ( int j = 0 ; j < pStage->newStage->numFragmentProgramImages ; j++ ) {
if ( pStage->newStage->fragmentProgramImages[j] == globalImages->currentRenderImage ) {
if ( sort != SS_PORTAL_SKY ) {
sort = SS_POST_PROCESS;
coverage = MC_TRANSLUCENT;
}
i = numStages;
break;
}
}
}
}
// set the drawStateBits depth flags
for ( i = 0 ; i < numStages ; i++ ) {
shaderStage_t *pStage = &pd->parseStages[i];
if ( sort == SS_POST_PROCESS ) {
// post-process effects fill the depth buffer as they draw, so only the
// topmost post-process effect is rendered
pStage->drawStateBits |= GLS_DEPTHFUNC_LESS;
} else if ( coverage == MC_TRANSLUCENT || pStage->ignoreAlphaTest ) {
// translucent surfaces can extend past the exactly marked depth buffer
pStage->drawStateBits |= GLS_DEPTHFUNC_LESS | GLS_DEPTHMASK;
} else {
// opaque and perforated surfaces must exactly match the depth buffer,
// which gets alpha test correct
pStage->drawStateBits |= GLS_DEPTHFUNC_EQUAL | GLS_DEPTHMASK;
}
}
// determine if this surface will accept overlays / decals
if ( pd->forceOverlays ) {
// explicitly flaged in material definition
allowOverlays = true;
} else {
if ( !IsDrawn() ) {
allowOverlays = false;
}
if ( Coverage() != MC_OPAQUE ) {
allowOverlays = false;
}
if ( GetSurfaceFlags() & SURF_NOIMPACT ) {
allowOverlays = false;
}
}
// add a tiny offset to the sort orders, so that different materials
// that have the same sort value will at least sort consistantly, instead
// of flickering back and forth
/* this messed up in-game guis
if ( sort != SS_SUBVIEW ) {
int hash, l;
l = name.Length();
hash = 0;
for ( int i = 0 ; i < l ; i++ ) {
hash ^= name[i];
}
sort += hash * 0.01;
}
*/
if (numStages) {
stages = (shaderStage_t *)R_StaticAlloc( numStages * sizeof( stages[0] ) );
memcpy( stages, pd->parseStages, numStages * sizeof( stages[0] ) );
}
if ( numOps ) {
ops = (expOp_t *)R_StaticAlloc( numOps * sizeof( ops[0] ) );
memcpy( ops, pd->shaderOps, numOps * sizeof( ops[0] ) );
}
if ( numRegisters ) {
expressionRegisters = (float *)R_StaticAlloc( numRegisters * sizeof( expressionRegisters[0] ) );
memcpy( expressionRegisters, pd->shaderRegisters, numRegisters * sizeof( expressionRegisters[0] ) );
}
// see if the registers are completely constant, and don't need to be evaluated
// per-surface
CheckForConstantRegisters();
pd = NULL; // the pointer will be invalid after exiting this function
// finish things up
if ( TestMaterialFlag( MF_DEFAULTED ) ) {
MakeDefault();
return false;
}
return true;
}
/*
===================
idMaterial::Print
===================
*/
static const char *opNames[] = {
2011-11-22 21:28:15 +00:00
"OP_TYPE_ADD",
"OP_TYPE_SUBTRACT",
"OP_TYPE_MULTIPLY",
"OP_TYPE_DIVIDE",
"OP_TYPE_MOD",
"OP_TYPE_TABLE",
"OP_TYPE_GT",
"OP_TYPE_GE",
"OP_TYPE_LT",
"OP_TYPE_LE",
"OP_TYPE_EQ",
"OP_TYPE_NE",
"OP_TYPE_AND",
"OP_TYPE_OR"
};
void idMaterial::Print() const {
int i;
for ( i = EXP_REG_NUM_PREDEFINED ; i < GetNumRegisters() ; i++ ) {
common->Printf( "register %i: %f\n", i, expressionRegisters[i] );
}
common->Printf( "\n" );
for ( i = 0 ; i < numOps ; i++ ) {
const expOp_t *op = &ops[i];
if ( op->opType == OP_TYPE_TABLE ) {
common->Printf( "%i = %s[ %i ]\n", op->c, declManager->DeclByIndex( DECL_TABLE, op->a )->GetName(), op->b );
} else {
common->Printf( "%i = %i %s %i\n", op->c, op->a, opNames[ op->opType ], op->b );
}
}
}
/*
===============
idMaterial::Save
===============
*/
bool idMaterial::Save( const char *fileName ) {
return ReplaceSourceFileText();
}
/*
===============
idMaterial::AddReference
===============
*/
void idMaterial::AddReference() {
refCount++;
for ( int i = 0; i < numStages; i++ ) {
shaderStage_t *s = &stages[i];
if ( s->texture.image ) {
s->texture.image->AddReference();
}
}
}
/*
===============
idMaterial::EvaluateRegisters
Parameters are taken from the localSpace and the renderView,
then all expressions are evaluated, leaving the material registers
set to their apropriate values.
===============
*/
void idMaterial::EvaluateRegisters( float *registers, const float shaderParms[MAX_ENTITY_SHADER_PARMS],
const viewDef_t *view, idSoundEmitter *soundEmitter ) const {
int i, b;
expOp_t *op;
// copy the material constants
for ( i = EXP_REG_NUM_PREDEFINED ; i < numRegisters ; i++ ) {
registers[i] = expressionRegisters[i];
}
// copy the local and global parameters
registers[EXP_REG_TIME] = view->floatTime;
registers[EXP_REG_PARM0] = shaderParms[0];
registers[EXP_REG_PARM1] = shaderParms[1];
registers[EXP_REG_PARM2] = shaderParms[2];
registers[EXP_REG_PARM3] = shaderParms[3];
registers[EXP_REG_PARM4] = shaderParms[4];
registers[EXP_REG_PARM5] = shaderParms[5];
registers[EXP_REG_PARM6] = shaderParms[6];
registers[EXP_REG_PARM7] = shaderParms[7];
registers[EXP_REG_PARM8] = shaderParms[8];
registers[EXP_REG_PARM9] = shaderParms[9];
registers[EXP_REG_PARM10] = shaderParms[10];
registers[EXP_REG_PARM11] = shaderParms[11];
registers[EXP_REG_GLOBAL0] = view->renderView.shaderParms[0];
registers[EXP_REG_GLOBAL1] = view->renderView.shaderParms[1];
registers[EXP_REG_GLOBAL2] = view->renderView.shaderParms[2];
registers[EXP_REG_GLOBAL3] = view->renderView.shaderParms[3];
registers[EXP_REG_GLOBAL4] = view->renderView.shaderParms[4];
registers[EXP_REG_GLOBAL5] = view->renderView.shaderParms[5];
registers[EXP_REG_GLOBAL6] = view->renderView.shaderParms[6];
registers[EXP_REG_GLOBAL7] = view->renderView.shaderParms[7];
op = ops;
for ( i = 0 ; i < numOps ; i++, op++ ) {
switch( op->opType ) {
case OP_TYPE_ADD:
registers[op->c] = registers[op->a] + registers[op->b];
break;
case OP_TYPE_SUBTRACT:
registers[op->c] = registers[op->a] - registers[op->b];
break;
case OP_TYPE_MULTIPLY:
registers[op->c] = registers[op->a] * registers[op->b];
break;
case OP_TYPE_DIVIDE:
registers[op->c] = registers[op->a] / registers[op->b];
break;
case OP_TYPE_MOD:
b = (int)registers[op->b];
b = b != 0 ? b : 1;
registers[op->c] = (int)registers[op->a] % b;
break;
case OP_TYPE_TABLE:
{
const idDeclTable *table = static_cast<const idDeclTable *>( declManager->DeclByIndex( DECL_TABLE, op->a ) );
registers[op->c] = table->TableLookup( registers[op->b] );
}
break;
case OP_TYPE_SOUND:
if ( soundEmitter ) {
registers[op->c] = soundEmitter->CurrentAmplitude();
} else {
registers[op->c] = 0;
}
break;
case OP_TYPE_GT:
registers[op->c] = registers[ op->a ] > registers[op->b];
break;
case OP_TYPE_GE:
registers[op->c] = registers[ op->a ] >= registers[op->b];
break;
case OP_TYPE_LT:
registers[op->c] = registers[ op->a ] < registers[op->b];
break;
case OP_TYPE_LE:
registers[op->c] = registers[ op->a ] <= registers[op->b];
break;
case OP_TYPE_EQ:
registers[op->c] = registers[ op->a ] == registers[op->b];
break;
case OP_TYPE_NE:
registers[op->c] = registers[ op->a ] != registers[op->b];
break;
case OP_TYPE_AND:
registers[op->c] = registers[ op->a ] && registers[op->b];
break;
case OP_TYPE_OR:
registers[op->c] = registers[ op->a ] || registers[op->b];
break;
default:
common->FatalError( "R_EvaluateExpression: bad opcode" );
}
}
}
/*
=============
idMaterial::Texgen
=============
*/
texgen_t idMaterial::Texgen() const {
if ( stages ) {
for ( int i = 0; i < numStages; i++ ) {
if ( stages[ i ].texture.texgen != TG_EXPLICIT ) {
return stages[ i ].texture.texgen;
}
}
}
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return TG_EXPLICIT;
}
/*
=============
idMaterial::GetImageWidth
=============
*/
int idMaterial::GetImageWidth( void ) const {
assert( GetStage(0) && GetStage(0)->texture.image );
return GetStage(0)->texture.image->uploadWidth;
}
/*
=============
idMaterial::GetImageHeight
=============
*/
int idMaterial::GetImageHeight( void ) const {
assert( GetStage(0) && GetStage(0)->texture.image );
return GetStage(0)->texture.image->uploadHeight;
}
/*
=============
idMaterial::CinematicLength
=============
*/
int idMaterial::CinematicLength() const {
if ( !stages || !stages[0].texture.cinematic ) {
return 0;
}
return stages[0].texture.cinematic->AnimationLength();
}
/*
=============
idMaterial::UpdateCinematic
=============
*/
void idMaterial::UpdateCinematic( int time ) const {
if ( !stages || !stages[0].texture.cinematic || !backEnd.viewDef ) {
return;
}
stages[0].texture.cinematic->ImageForTime( tr.primaryRenderView.time );
}
/*
=============
idMaterial::CloseCinematic
=============
*/
void idMaterial::CloseCinematic( void ) const {
for( int i = 0; i < numStages; i++ ) {
if ( stages[i].texture.cinematic ) {
stages[i].texture.cinematic->Close();
delete stages[i].texture.cinematic;
stages[i].texture.cinematic = NULL;
}
}
}
/*
=============
idMaterial::ResetCinematicTime
=============
*/
void idMaterial::ResetCinematicTime( int time ) const {
for( int i = 0; i < numStages; i++ ) {
if ( stages[i].texture.cinematic ) {
stages[i].texture.cinematic->ResetTime( time );
}
}
}
/*
=============
idMaterial::ConstantRegisters
=============
*/
const float *idMaterial::ConstantRegisters() const {
if ( !r_useConstantMaterials.GetBool() ) {
return NULL;
}
return constantRegisters;
}
/*
==================
idMaterial::CheckForConstantRegisters
As of 5/2/03, about half of the unique materials loaded on typical
maps are constant, but 2/3 of the surface references are.
This is probably an optimization of dubious value.
==================
*/
void idMaterial::CheckForConstantRegisters() {
if ( !pd->registersAreConstant ) {
return;
}
// evaluate the registers once, and save them
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constantRegisters = (float *)R_ClearedStaticAlloc( GetNumRegisters() * sizeof( float ) );
float shaderParms[MAX_ENTITY_SHADER_PARMS];
memset( shaderParms, 0, sizeof( shaderParms ) );
viewDef_t viewDef;
memset( &viewDef, 0, sizeof( viewDef ) );
EvaluateRegisters( constantRegisters, shaderParms, &viewDef, 0 );
}
/*
===================
idMaterial::ImageName
===================
*/
const char *idMaterial::ImageName( void ) const {
if ( numStages == 0 ) {
return "_scratch";
}
idImage *image = stages[0].texture.image;
if ( image ) {
return image->imgName;
}
return "_scratch";
}
/*
===================
idMaterial::SetImageClassifications
Just for image resource tracking.
===================
*/
void idMaterial::SetImageClassifications( int tag ) const {
for ( int i = 0 ; i < numStages ; i++ ) {
idImage *image = stages[i].texture.image;
if ( image ) {
image->SetClassification( tag );
}
}
}
/*
=================
idMaterial::Size
=================
*/
size_t idMaterial::Size( void ) const {
return sizeof( idMaterial );
}
/*
===================
idMaterial::SetDefaultText
===================
*/
bool idMaterial::SetDefaultText( void ) {
// if there exists an image with the same name
if ( 1 ) { //fileSystem->ReadFile( GetName(), NULL ) != -1 ) {
char generated[2048];
idStr::snPrintf( generated, sizeof( generated ),
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"material %s // IMPLICITLY GENERATED\n"
"{\n"
"{\n"
"blend blend\n"
"colored\n"
"map \"%s\"\n"
"clamp\n"
"}\n"
"}\n", GetName(), GetName() );
SetText( generated );
return true;
} else {
return false;
}
}
/*
===================
idMaterial::DefaultDefinition
===================
*/
const char *idMaterial::DefaultDefinition() const {
return
"{\n"
"\t" "{\n"
"\t\t" "blend\tblend\n"
"\t\t" "map\t\t_default\n"
"\t" "}\n"
"}";
}
/*
===================
idMaterial::GetBumpStage
===================
*/
const shaderStage_t *idMaterial::GetBumpStage( void ) const {
for ( int i = 0 ; i < numStages ; i++ ) {
if ( stages[i].lighting == SL_BUMP ) {
return &stages[i];
}
}
return NULL;
}
/*
===================
idMaterial::ReloadImages
===================
*/
void idMaterial::ReloadImages( bool force ) const
{
for ( int i = 0 ; i < numStages ; i++ ) {
if ( stages[i].newStage ) {
for ( int j = 0 ; j < stages[i].newStage->numFragmentProgramImages ; j++ ) {
if ( stages[i].newStage->fragmentProgramImages[j] ) {
stages[i].newStage->fragmentProgramImages[j]->Reload( false, force );
}
}
} else if ( stages[i].texture.image ) {
stages[i].texture.image->Reload( false, force );
}
}
}