/*
==================
RB_NV20_DiffuseColorFragment
==================
*/
static void RB_NV20_DiffuseColorFragment(void)
{
	if (r_useCombinerDisplayLists.GetBool()) {
		qglCallList(fragmentDisplayListBase + FPROG_DIFFUSE_COLOR);
		return;
	}

	// program the nvidia register combiners
	qglCombinerParameteriNV(GL_NUM_GENERAL_COMBINERS_NV, 1);

	// stage 0 is free, so we always do the multiply of the vertex color
	// when the vertex color is inverted, qglCombinerInputNV(GL_VARIABLE_B_NV) will be changed
	qglCombinerInputNV(GL_COMBINER0_NV, GL_RGB, GL_VARIABLE_A_NV,
	                   GL_TEXTURE0_ARB, GL_UNSIGNED_IDENTITY_NV, GL_RGB);
	qglCombinerInputNV(GL_COMBINER0_NV, GL_RGB, GL_VARIABLE_B_NV,
	                   GL_PRIMARY_COLOR_NV, GL_UNSIGNED_IDENTITY_NV, GL_RGB);
	qglCombinerOutputNV(GL_COMBINER0_NV, GL_RGB,
	                    GL_TEXTURE0_ARB, GL_DISCARD_NV, GL_DISCARD_NV,
	                    GL_NONE, GL_NONE, GL_FALSE, GL_FALSE, GL_FALSE);

	qglCombinerOutputNV(GL_COMBINER0_NV, GL_ALPHA,
	                    GL_DISCARD_NV, GL_DISCARD_NV, GL_DISCARD_NV,
	                    GL_NONE, GL_NONE, GL_FALSE, GL_FALSE, GL_FALSE);


	// for GL_CONSTANT_COLOR0_NV * TEXTURE0 * TEXTURE1
	qglFinalCombinerInputNV(GL_VARIABLE_A_NV, GL_CONSTANT_COLOR0_NV,
	                        GL_UNSIGNED_IDENTITY_NV, GL_RGB);
	qglFinalCombinerInputNV(GL_VARIABLE_B_NV, GL_E_TIMES_F_NV,
	                        GL_UNSIGNED_IDENTITY_NV, GL_RGB);
	qglFinalCombinerInputNV(GL_VARIABLE_C_NV, GL_ZERO,
	                        GL_UNSIGNED_IDENTITY_NV, GL_RGB);
	qglFinalCombinerInputNV(GL_VARIABLE_D_NV, GL_ZERO,
	                        GL_UNSIGNED_IDENTITY_NV, GL_RGB);
	qglFinalCombinerInputNV(GL_VARIABLE_E_NV, GL_TEXTURE0_ARB,
	                        GL_UNSIGNED_IDENTITY_NV, GL_RGB);
	qglFinalCombinerInputNV(GL_VARIABLE_F_NV, GL_TEXTURE1_ARB,
	                        GL_UNSIGNED_IDENTITY_NV, GL_RGB);
	qglFinalCombinerInputNV(GL_VARIABLE_G_NV, GL_ZERO,
	                        GL_UNSIGNED_IDENTITY_NV, GL_ALPHA);

}
Example #2
0
/*
==================
RB_RenderInteraction

backEnd.vLight
backEnd.lightScale


backEnd.depthFunc must be equal for alpha tested surfaces to work right,
it is set to lessThan for blended transparent surfaces

This expects a bumpmap stage before a diffuse stage before a specular stage
The material code is responsible for guaranteeing that, but conditional stages
can still make it invalid.

you can't blend two bumpmaps, but you can change bump maps between
blended diffuse / specular maps to get the same effect


==================
*/
static void RB_RenderInteraction( const drawSurf_t *surf ) {
	const idMaterial	*surfaceShader = surf->material;
	const float			*surfaceRegs = surf->shaderRegisters;
	const viewLight_t	*vLight = backEnd.vLight;
	const idMaterial	*lightShader = vLight->lightShader;
	const float			*lightRegs = vLight->shaderRegisters;
	static idPlane		lightProject[4];	// reused across function calls
	const srfTriangles_t	*tri = surf->geo;
	const shaderStage_t	*lastBumpStage = NULL;

	RB_LogComment( "---------- RB_RenderInteraction %s on %s ----------\n", 
		lightShader->GetName(), surfaceShader->GetName() );

	// change the matrix and light projection vectors if needed
	if ( surf->space != backEnd.currentSpace ) {
		backEnd.currentSpace = surf->space;
		qglLoadMatrixf( surf->space->modelViewMatrix );

		for ( int i = 0 ; i < 4 ; i++ ) {
			R_GlobalPlaneToLocal( surf->space->modelMatrix, backEnd.vLight->lightProject[i], lightProject[i] );
		}
	}

	// change the scissor if needed
	if ( r_useScissor.GetBool() && !backEnd.currentScissor.Equals( surf->scissorRect ) ) {
		backEnd.currentScissor = surf->scissorRect;
		qglScissor( backEnd.viewDef->viewport.x1 + backEnd.currentScissor.x1, 
			backEnd.viewDef->viewport.y1 + backEnd.currentScissor.y1,
			backEnd.currentScissor.x2 + 1 - backEnd.currentScissor.x1,
			backEnd.currentScissor.y2 + 1 - backEnd.currentScissor.y1 );
	}

	// hack depth range if needed
	if ( surf->space->weaponDepthHack ) {
		RB_EnterWeaponDepthHack();
	}

	if ( surf->space->modelDepthHack != 0.0f ) {
		RB_EnterModelDepthHack( surf->space->modelDepthHack );
	}


	// set the vertex arrays, which may not all be enabled on a given pass
	idDrawVert	*ac = (idDrawVert *)vertexCache.Position(tri->ambientCache);
	qglVertexPointer( 3, GL_FLOAT, sizeof( idDrawVert ), ac->xyz.ToFloatPtr() );
	GL_SelectTexture( 0 );
	qglTexCoordPointer( 2, GL_FLOAT, sizeof( idDrawVert ), ac->st.ToFloatPtr() );
	qglColorPointer( 4, GL_UNSIGNED_BYTE, sizeof( idDrawVert ), ac->color );


	// go through the individual stages
	for ( int i = 0 ; i < surfaceShader->GetNumStages() ; i++ ) {
		const shaderStage_t	*surfaceStage = surfaceShader->GetStage( i );

		// ignore ambient stages while drawing interactions
		if ( surfaceStage->lighting == SL_AMBIENT ) {
			continue;
		}

		// ignore stages that fail the condition
		if ( !surfaceRegs[ surfaceStage->conditionRegister ] ) {
			continue;
		}

		//-----------------------------------------------------
		//
		// bump / falloff
		//
		//-----------------------------------------------------
		if ( surfaceStage->lighting == SL_BUMP ) {
			// render light falloff * bumpmap lighting

			if ( surfaceStage->vertexColor != SVC_IGNORE ) {
				common->Printf( "shader %s: vertexColor on a bump stage\n",
					surfaceShader->GetName() );
			}

			// check for RGBA modulations in the stage, which are also illegal?

			// save the bump map stage for the specular calculation and diffuse
			// error checking
			lastBumpStage = surfaceStage;

			//
			// ambient lights combine non-directional bump and falloff
			// and write to the alpha channel
			//
			if ( lightShader->IsAmbientLight() ) {
				GL_State( GLS_COLORMASK | GLS_DEPTHMASK | backEnd.depthFunc );

				// texture 0 will be the per-surface bump map
				GL_SelectTexture( 0 );
				qglEnableClientState( GL_TEXTURE_COORD_ARRAY );

				RB_BindStageTexture( surfaceRegs, &surfaceStage->texture, surf );
				// development aid
				if ( r_skipBump.GetBool() ) {
					globalImages->flatNormalMap->Bind();
				}

				// texture 1 will be the light falloff
				GL_SelectTexture( 1 );

				qglEnable( GL_TEXTURE_GEN_S );
				qglTexGenfv( GL_S, GL_OBJECT_PLANE, lightProject[3].ToFloatPtr() );
				qglTexCoord2f( 0, 0.5 );
				vLight->falloffImage->Bind();

				qglCombinerParameteriNV( GL_NUM_GENERAL_COMBINERS_NV, 2 );

				// set the constant color to a bit of an angle
				qglCombinerParameterfvNV( GL_CONSTANT_COLOR0_NV, tr.ambientLightVector.ToFloatPtr() );

				// stage 0 sets primary_color = bump dot constant color
				qglCombinerInputNV( GL_COMBINER0_NV, GL_RGB, GL_VARIABLE_A_NV, 
					GL_CONSTANT_COLOR0_NV, GL_EXPAND_NORMAL_NV, GL_RGB );
				qglCombinerInputNV( GL_COMBINER0_NV, GL_RGB, GL_VARIABLE_B_NV, 
					GL_TEXTURE0_ARB, GL_EXPAND_NORMAL_NV, GL_RGB );
				qglCombinerOutputNV( GL_COMBINER0_NV, GL_RGB, 
					GL_PRIMARY_COLOR_NV, GL_DISCARD_NV, GL_DISCARD_NV,
					GL_NONE, GL_NONE, GL_TRUE, GL_FALSE, GL_FALSE );

				// stage 1 alpha sets primary_color = primary_color * falloff
				qglCombinerInputNV( GL_COMBINER1_NV, GL_ALPHA, GL_VARIABLE_A_NV, 
					GL_PRIMARY_COLOR_NV, GL_UNSIGNED_IDENTITY_NV, GL_BLUE );
				qglCombinerInputNV( GL_COMBINER1_NV, GL_ALPHA, GL_VARIABLE_B_NV, 
					GL_TEXTURE1_ARB, GL_UNSIGNED_IDENTITY_NV, GL_ALPHA );
				qglCombinerOutputNV( GL_COMBINER1_NV, GL_ALPHA, 
					GL_PRIMARY_COLOR_NV, GL_DISCARD_NV, GL_DISCARD_NV,
					GL_NONE, GL_NONE, GL_FALSE, GL_FALSE, GL_FALSE );

				// final combiner takes the result for the alpha channel
				qglFinalCombinerInputNV( GL_VARIABLE_A_NV, GL_ZERO,
					GL_UNSIGNED_IDENTITY_NV, GL_RGB );
				qglFinalCombinerInputNV( GL_VARIABLE_B_NV, GL_ZERO,
					GL_UNSIGNED_IDENTITY_NV, GL_RGB );
				qglFinalCombinerInputNV( GL_VARIABLE_C_NV, GL_ZERO,
					GL_UNSIGNED_IDENTITY_NV, GL_RGB );
				qglFinalCombinerInputNV( GL_VARIABLE_D_NV, GL_ZERO,
					GL_UNSIGNED_IDENTITY_NV, GL_RGB );
				qglFinalCombinerInputNV( GL_VARIABLE_G_NV, GL_PRIMARY_COLOR_NV,
					GL_UNSIGNED_IDENTITY_NV, GL_ALPHA );

				// draw it
				RB_DrawElementsWithCounters( tri );

				globalImages->BindNull();
				qglDisable( GL_TEXTURE_GEN_S );

				GL_SelectTexture( 0 );
				RB_FinishStageTexture( &surfaceStage->texture, surf );
				continue;
			}

			//
			// draw light falloff to the alpha channel
			//
			GL_State( GLS_COLORMASK | GLS_DEPTHMASK | backEnd.depthFunc );
			qglDisableClientState( GL_TEXTURE_COORD_ARRAY );
			qglDisableClientState( GL_COLOR_ARRAY );
			qglEnable( GL_TEXTURE_GEN_S );
			qglTexGenfv( GL_S, GL_OBJECT_PLANE, lightProject[3].ToFloatPtr() );
			qglTexCoord2f( 0, 0.5 );
			vLight->falloffImage->Bind();

			// make sure a combiner output doesn't step on the texture
			qglCombinerParameteriNV( GL_NUM_GENERAL_COMBINERS_NV, 1 );
			qglCombinerOutputNV( GL_COMBINER0_NV, GL_ALPHA, 
				GL_DISCARD_NV, GL_DISCARD_NV, GL_DISCARD_NV,
				GL_NONE, GL_NONE, GL_FALSE, GL_FALSE, GL_FALSE );

			// final combiner
			qglFinalCombinerInputNV( GL_VARIABLE_A_NV, GL_ZERO,
				GL_UNSIGNED_IDENTITY_NV, GL_RGB );
			qglFinalCombinerInputNV( GL_VARIABLE_B_NV, GL_ZERO,
				GL_UNSIGNED_IDENTITY_NV, GL_RGB );
			qglFinalCombinerInputNV( GL_VARIABLE_C_NV, GL_ZERO,
				GL_UNSIGNED_IDENTITY_NV, GL_RGB );
			qglFinalCombinerInputNV( GL_VARIABLE_D_NV, GL_ZERO,
				GL_UNSIGNED_IDENTITY_NV, GL_RGB );
			qglFinalCombinerInputNV( GL_VARIABLE_G_NV, GL_TEXTURE0_ARB,
				GL_UNSIGNED_IDENTITY_NV, GL_ALPHA );

			// draw it
			RB_DrawElementsWithCounters( tri );

			qglDisable( GL_TEXTURE_GEN_S );

			//
			// draw the bump map result onto the alpha channel
			//
			GL_State( GLS_SRCBLEND_DST_ALPHA | GLS_DSTBLEND_ZERO | GLS_COLORMASK | GLS_DEPTHMASK 
				| backEnd.depthFunc );

			// texture 0 will be the per-surface bump map
			GL_SelectTexture( 0 );
			qglEnableClientState( GL_TEXTURE_COORD_ARRAY );
			RB_BindStageTexture( surfaceRegs, &surfaceStage->texture, surf );

			// texture 1 is the normalization cube map
			// the texccords are the non-normalized vector towards the light origin
			GL_SelectTexture( 1 );
			globalImages->normalCubeMapImage->Bind();
			qglEnableClientState( GL_TEXTURE_COORD_ARRAY );
			qglTexCoordPointer( 3, GL_FLOAT, sizeof( lightingCache_t ), ((lightingCache_t *)vertexCache.Position(tri->lightingCache))->localLightVector.ToFloatPtr() );

			qglDisableClientState( GL_COLOR_ARRAY );

			// program the nvidia register combiners
			// I just want alpha = Dot( texture0, texture1 )
			qglCombinerParameteriNV( GL_NUM_GENERAL_COMBINERS_NV, 1 );

			// stage 0 rgb performs the dot product
			// SPARE0 = TEXTURE0 dot TEXTURE1
			qglCombinerInputNV( GL_COMBINER0_NV, GL_RGB, GL_VARIABLE_A_NV, 
				GL_TEXTURE1_ARB, GL_EXPAND_NORMAL_NV, GL_RGB );
			qglCombinerInputNV( GL_COMBINER0_NV, GL_RGB, GL_VARIABLE_B_NV, 
				GL_TEXTURE0_ARB, GL_EXPAND_NORMAL_NV, GL_RGB );
			qglCombinerOutputNV( GL_COMBINER0_NV, GL_RGB, 
				GL_SPARE0_NV, GL_DISCARD_NV, GL_DISCARD_NV,
				GL_NONE, GL_NONE, GL_TRUE, GL_FALSE, GL_FALSE );

			// final combiner just takes the dot result and puts it in alpha
			qglFinalCombinerInputNV( GL_VARIABLE_G_NV, GL_SPARE0_NV,
				GL_UNSIGNED_IDENTITY_NV, GL_BLUE );

			// draw it
			RB_DrawElementsWithCounters( tri );

			globalImages->BindNull();
			qglDisableClientState( GL_TEXTURE_COORD_ARRAY );

			GL_SelectTexture( 0 );
			RB_FinishStageTexture( &surfaceStage->texture, surf );
			continue;
		}

		if ( surfaceStage->lighting == SL_DIFFUSE ) {
			if ( !lastBumpStage ) {
				common->Printf( "shader %s: diffuse stage without a preceeding bumpmap stage\n",
					surfaceShader->GetName() );
				continue;
			}
		}

		//-----------------------------------------------------
		//
		// specular exponent modification of the bump / falloff
		//
		//-----------------------------------------------------
		if ( surfaceStage->lighting == SL_SPECULAR ) {
			// put specular bump map into alpha channel, then treat as a diffuse

			// allow the specular to be skipped as a user speed optimization
			if ( r_skipSpecular.GetBool() ) {
				continue;
			}

			// ambient lights don't have specular
			if ( lightShader->IsAmbientLight() ) {
				continue;
			}

			if ( !lastBumpStage ) {
				common->Printf( "shader %s: specular stage without a preceeding bumpmap stage\n",
					surfaceShader->GetName() );
				continue;
			}

			GL_State( GLS_SRCBLEND_DST_ALPHA | GLS_DSTBLEND_SRC_ALPHA | GLS_COLORMASK | GLS_DEPTHMASK 
				| backEnd.depthFunc );

			// texture 0 will be the per-surface bump map
			GL_SelectTexture( 0 );
			qglEnableClientState( GL_TEXTURE_COORD_ARRAY );
			RB_BindStageTexture( surfaceRegs, &lastBumpStage->texture, surf );

			// development aid
			if ( r_skipBump.GetBool() ) {
				globalImages->flatNormalMap->Bind();
			}

			// texture 1 is the normalization cube map
			// indexed by the dynamic halfangle texcoords
			GL_SelectTexture( 1 );
			globalImages->normalCubeMapImage->Bind();
			qglEnableClientState( GL_TEXTURE_COORD_ARRAY );
			qglTexCoordPointer( 4, GL_FLOAT, 0, vertexCache.Position( surf->dynamicTexCoords ) );

			// program the nvidia register combiners
			qglCombinerParameteriNV( GL_NUM_GENERAL_COMBINERS_NV, 2 );

			// stage 0 rgb performs the dot product
			// GL_PRIMARY_COLOR_NV = ( TEXTURE0 dot TEXTURE1 - 0.5 ) * 2
			// the scale and bias steepen the specular curve
			qglCombinerInputNV( GL_COMBINER0_NV, GL_RGB, GL_VARIABLE_A_NV, 
				GL_TEXTURE1_ARB, GL_EXPAND_NORMAL_NV, GL_RGB );
			qglCombinerInputNV( GL_COMBINER0_NV, GL_RGB, GL_VARIABLE_B_NV, 
				GL_TEXTURE0_ARB, GL_EXPAND_NORMAL_NV, GL_RGB );
			qglCombinerOutputNV( GL_COMBINER0_NV, GL_RGB, 
				GL_PRIMARY_COLOR_NV, GL_DISCARD_NV, GL_DISCARD_NV,
				GL_SCALE_BY_TWO_NV, GL_BIAS_BY_NEGATIVE_ONE_HALF_NV, GL_TRUE, GL_FALSE, GL_FALSE );

			// stage 0 alpha does nothing
			qglCombinerOutputNV( GL_COMBINER0_NV, GL_ALPHA, 
				GL_DISCARD_NV, GL_DISCARD_NV, GL_DISCARD_NV,
				GL_NONE, GL_NONE, GL_FALSE, GL_FALSE, GL_FALSE );

			// stage 1 rgb does nothing
			qglCombinerOutputNV( GL_COMBINER1_NV, GL_RGB, 
				GL_PRIMARY_COLOR_NV, GL_DISCARD_NV, GL_DISCARD_NV,
				GL_NONE, GL_NONE, GL_FALSE, GL_FALSE, GL_FALSE );

			// stage 1 alpha takes bump * bump
			// PRIMARY_COLOR = ( GL_PRIMARY_COLOR_NV * GL_PRIMARY_COLOR_NV - 0.5 ) * 2
			// the scale and bias steepen the specular curve
			qglCombinerInputNV( GL_COMBINER1_NV, GL_ALPHA, GL_VARIABLE_A_NV, 
				GL_PRIMARY_COLOR_NV, GL_UNSIGNED_IDENTITY_NV, GL_BLUE );
			qglCombinerInputNV( GL_COMBINER1_NV, GL_ALPHA, GL_VARIABLE_B_NV, 
				GL_PRIMARY_COLOR_NV, GL_UNSIGNED_IDENTITY_NV, GL_BLUE );
			qglCombinerOutputNV( GL_COMBINER1_NV, GL_ALPHA, 
				GL_PRIMARY_COLOR_NV, GL_DISCARD_NV, GL_DISCARD_NV,
				GL_SCALE_BY_TWO_NV, GL_BIAS_BY_NEGATIVE_ONE_HALF_NV, GL_FALSE, GL_FALSE, GL_FALSE );

			// final combiner
			qglFinalCombinerInputNV( GL_VARIABLE_D_NV, GL_PRIMARY_COLOR_NV,
				GL_UNSIGNED_IDENTITY_NV, GL_RGB );
			qglFinalCombinerInputNV( GL_VARIABLE_A_NV, GL_ZERO,
				GL_UNSIGNED_IDENTITY_NV, GL_RGB );
			qglFinalCombinerInputNV( GL_VARIABLE_B_NV, GL_ZERO,
				GL_UNSIGNED_IDENTITY_NV, GL_RGB );
			qglFinalCombinerInputNV( GL_VARIABLE_C_NV, GL_ZERO,
				GL_UNSIGNED_IDENTITY_NV, GL_RGB );
			qglFinalCombinerInputNV( GL_VARIABLE_G_NV, GL_PRIMARY_COLOR_NV,
				GL_UNSIGNED_IDENTITY_NV, GL_ALPHA );

			// draw it
			RB_DrawElementsWithCounters( tri );

			globalImages->BindNull();
			qglDisableClientState( GL_TEXTURE_COORD_ARRAY );

			GL_SelectTexture( 0 );

			RB_FinishStageTexture( &lastBumpStage->texture, surf );

			// the bump map in the alpha channel is now corrupted, so a normal diffuse
			// map can't be drawn unless a new bumpmap is put down
			lastBumpStage = NULL;

			// fall through to the common handling of diffuse and specular projected lighting
		}

		//-----------------------------------------------------
		//
		// projected light / surface color for diffuse and specular maps
		//
		//-----------------------------------------------------
		if ( surfaceStage->lighting == SL_DIFFUSE || surfaceStage->lighting == SL_SPECULAR ) {
			// don't trash alpha
			GL_State( GLS_SRCBLEND_DST_ALPHA | GLS_DSTBLEND_ONE | GLS_ALPHAMASK | GLS_DEPTHMASK 
			| backEnd.depthFunc );

			// texture 0 will get the surface color texture
			GL_SelectTexture( 0 );
			qglEnableClientState( GL_TEXTURE_COORD_ARRAY );
			RB_BindStageTexture( surfaceRegs, &surfaceStage->texture, surf );

			// development aid
			if ( ( surfaceStage->lighting == SL_DIFFUSE && r_skipDiffuse.GetBool() )
				|| ( surfaceStage->lighting == SL_SPECULAR && r_skipSpecular.GetBool() ) ) {
				globalImages->blackImage->Bind();
			}

			// texture 1 will get the light projected texture
			GL_SelectTexture( 1 );
			qglDisableClientState( GL_TEXTURE_COORD_ARRAY );
			qglEnable( GL_TEXTURE_GEN_S );
			qglEnable( GL_TEXTURE_GEN_T );
			qglEnable( GL_TEXTURE_GEN_Q );
			qglTexGenfv( GL_S, GL_OBJECT_PLANE, lightProject[0].ToFloatPtr() );
			qglTexGenfv( GL_T, GL_OBJECT_PLANE, lightProject[1].ToFloatPtr() );
			qglTexGenfv( GL_Q, GL_OBJECT_PLANE, lightProject[2].ToFloatPtr() );

			// texture0 * texture1 * primaryColor * constantColor
			qglCombinerParameteriNV( GL_NUM_GENERAL_COMBINERS_NV, 1 );

			// SPARE0 = TEXTURE0 * PRIMARY_COLOR
			// SPARE1 = TEXTURE1 * CONSTANT_COLOR
			qglCombinerInputNV( GL_COMBINER0_NV, GL_RGB, GL_VARIABLE_A_NV, 
				GL_TEXTURE0_ARB, GL_UNSIGNED_IDENTITY_NV, GL_RGB );
			// variable B will be overriden based on the stage vertexColor option
			if ( surfaceStage->vertexColor == SVC_MODULATE ) {
				qglCombinerInputNV( GL_COMBINER0_NV, GL_RGB, GL_VARIABLE_B_NV, 
					GL_PRIMARY_COLOR_NV, GL_UNSIGNED_IDENTITY_NV, GL_RGB );
				qglEnableClientState( GL_COLOR_ARRAY );
			} else if ( surfaceStage->vertexColor == SVC_INVERSE_MODULATE ) {
				qglCombinerInputNV( GL_COMBINER0_NV, GL_RGB, GL_VARIABLE_B_NV, 
					GL_PRIMARY_COLOR_NV, GL_UNSIGNED_INVERT_NV, GL_RGB );
				qglEnableClientState( GL_COLOR_ARRAY );
			} else {	// SVC_IGNORE
				qglCombinerInputNV( GL_COMBINER0_NV, GL_RGB, GL_VARIABLE_B_NV, 
					GL_ZERO, GL_UNSIGNED_INVERT_NV, GL_RGB );
				qglDisableClientState( GL_COLOR_ARRAY );
			}
			qglCombinerInputNV( GL_COMBINER0_NV, GL_RGB, GL_VARIABLE_C_NV, 
				GL_TEXTURE1_ARB, GL_UNSIGNED_IDENTITY_NV, GL_RGB );
			qglCombinerInputNV( GL_COMBINER0_NV, GL_RGB, GL_VARIABLE_D_NV, 
				GL_CONSTANT_COLOR1_NV, GL_UNSIGNED_IDENTITY_NV, GL_RGB );
			qglCombinerOutputNV( GL_COMBINER0_NV, GL_RGB, 
				GL_SPARE0_NV, GL_SPARE1_NV, GL_DISCARD_NV,
				GL_NONE, GL_NONE, GL_FALSE, GL_FALSE, GL_FALSE );

			// final combiner
			qglFinalCombinerInputNV( GL_VARIABLE_A_NV, GL_SPARE1_NV,
				GL_UNSIGNED_IDENTITY_NV, GL_RGB );
			qglFinalCombinerInputNV( GL_VARIABLE_B_NV, GL_SPARE0_NV,
				GL_UNSIGNED_IDENTITY_NV, GL_RGB );
			qglFinalCombinerInputNV( GL_VARIABLE_C_NV, GL_ZERO,
				GL_UNSIGNED_IDENTITY_NV, GL_RGB );
			qglFinalCombinerInputNV( GL_VARIABLE_D_NV, GL_ZERO,
				GL_UNSIGNED_IDENTITY_NV, GL_RGB );
			qglFinalCombinerInputNV( GL_VARIABLE_G_NV, GL_ZERO,
				GL_UNSIGNED_IDENTITY_NV, GL_ALPHA );

			// for all light stages, multiply the projected color by the surface
			// color, and blend with the framebuffer
			for ( int j = 0 ; j < lightShader->GetNumStages() ; j++ ) {
				const shaderStage_t	*lightStage = lightShader->GetStage( j );
				float	color[4];

				// ignore stages that fail the condition
				if ( !lightRegs[ lightStage->conditionRegister ] ) {
					continue;
				}

				// set the color to the light color times the surface color
				color[0] = backEnd.lightScale
					* lightRegs[ lightStage->color.registers[0] ]
					* surfaceRegs[ surfaceStage->color.registers[0] ];
				color[1] = backEnd.lightScale
					* lightRegs[ lightStage->color.registers[1] ]
					* surfaceRegs[ surfaceStage->color.registers[1] ];
				color[2] = backEnd.lightScale
					* lightRegs[ lightStage->color.registers[2] ]
					* surfaceRegs[ surfaceStage->color.registers[2] ];
				color[3] = 1;

				// don't draw if it would be all black
				if ( color[0] == 0 && color[1] == 0 && color[2] == 0 ) {
					continue;
				}

				qglCombinerParameterfvNV( GL_CONSTANT_COLOR1_NV, color );

				RB_BindStageTexture( lightRegs, &lightStage->texture, surf );

				RB_DrawElementsWithCounters( tri );

				RB_FinishStageTexture( &lightStage->texture, surf );
			}

			if ( surfaceStage->vertexColor != SVC_IGNORE ) {
				qglDisableClientState( GL_COLOR_ARRAY );
			}

			qglDisable( GL_TEXTURE_GEN_S );
			qglDisable( GL_TEXTURE_GEN_T );
			qglDisable( GL_TEXTURE_GEN_Q );

			globalImages->BindNull();
			GL_SelectTexture( 0 );
			RB_FinishStageTexture( &surfaceStage->texture, surf );

			continue;
		}

	}
	// unhack depth range if needed
	if ( surf->space->weaponDepthHack || surf->space->modelDepthHack != 0.0f ) {
		RB_LeaveDepthHack();
	}
}
/*
==================
RB_NV20_BumpAndLightFragment
==================
*/
static void RB_NV20_BumpAndLightFragment(void)
{
	if (r_useCombinerDisplayLists.GetBool()) {
		qglCallList(fragmentDisplayListBase + FPROG_BUMP_AND_LIGHT);
		return;
	}

	// program the nvidia register combiners
	qglCombinerParameteriNV(GL_NUM_GENERAL_COMBINERS_NV, 3);

	// stage 0 rgb performs the dot product
	// SPARE0 = TEXTURE0 dot TEXTURE1
	qglCombinerInputNV(GL_COMBINER0_NV, GL_RGB, GL_VARIABLE_A_NV,
	                   GL_TEXTURE1_ARB, GL_EXPAND_NORMAL_NV, GL_RGB);
	qglCombinerInputNV(GL_COMBINER0_NV, GL_RGB, GL_VARIABLE_B_NV,
	                   GL_TEXTURE0_ARB, GL_EXPAND_NORMAL_NV, GL_RGB);
	qglCombinerOutputNV(GL_COMBINER0_NV, GL_RGB,
	                    GL_SPARE0_NV, GL_DISCARD_NV, GL_DISCARD_NV,
	                    GL_NONE, GL_NONE, GL_TRUE, GL_FALSE, GL_FALSE);


	// stage 1 rgb multiplies texture 2 and 3 together
	// SPARE1 = TEXTURE2 * TEXTURE3
	qglCombinerInputNV(GL_COMBINER1_NV, GL_RGB, GL_VARIABLE_A_NV,
	                   GL_TEXTURE2_ARB, GL_UNSIGNED_IDENTITY_NV, GL_RGB);
	qglCombinerInputNV(GL_COMBINER1_NV, GL_RGB, GL_VARIABLE_B_NV,
	                   GL_TEXTURE3_ARB, GL_UNSIGNED_IDENTITY_NV, GL_RGB);
	qglCombinerOutputNV(GL_COMBINER1_NV, GL_RGB,
	                    GL_SPARE1_NV, GL_DISCARD_NV, GL_DISCARD_NV,
	                    GL_NONE, GL_NONE, GL_FALSE, GL_FALSE, GL_FALSE);

	// stage 1 alpha does nohing

	// stage 2 color multiplies spare0 * spare 1 just for debugging
	// SPARE0 = SPARE0 * SPARE1
	qglCombinerInputNV(GL_COMBINER2_NV, GL_RGB, GL_VARIABLE_A_NV,
	                   GL_SPARE0_NV, GL_UNSIGNED_IDENTITY_NV, GL_RGB);
	qglCombinerInputNV(GL_COMBINER2_NV, GL_RGB, GL_VARIABLE_B_NV,
	                   GL_SPARE1_NV, GL_UNSIGNED_IDENTITY_NV, GL_RGB);
	qglCombinerOutputNV(GL_COMBINER2_NV, GL_RGB,
	                    GL_SPARE0_NV, GL_DISCARD_NV, GL_DISCARD_NV,
	                    GL_NONE, GL_NONE, GL_FALSE, GL_FALSE, GL_FALSE);

	// stage 2 alpha multiples spare0 * spare 1
	// SPARE0 = SPARE0 * SPARE1
	qglCombinerInputNV(GL_COMBINER2_NV, GL_ALPHA, GL_VARIABLE_A_NV,
	                   GL_SPARE0_NV, GL_UNSIGNED_IDENTITY_NV, GL_BLUE);
	qglCombinerInputNV(GL_COMBINER2_NV, GL_ALPHA, GL_VARIABLE_B_NV,
	                   GL_SPARE1_NV, GL_UNSIGNED_IDENTITY_NV, GL_BLUE);
	qglCombinerOutputNV(GL_COMBINER2_NV, GL_ALPHA,
	                    GL_SPARE0_NV, GL_DISCARD_NV, GL_DISCARD_NV,
	                    GL_NONE, GL_NONE, GL_FALSE, GL_FALSE, GL_FALSE);

	// final combiner
	qglFinalCombinerInputNV(GL_VARIABLE_D_NV, GL_SPARE0_NV,
	                        GL_UNSIGNED_IDENTITY_NV, GL_RGB);
	qglFinalCombinerInputNV(GL_VARIABLE_A_NV, GL_ZERO,
	                        GL_UNSIGNED_IDENTITY_NV, GL_RGB);
	qglFinalCombinerInputNV(GL_VARIABLE_B_NV, GL_ZERO,
	                        GL_UNSIGNED_IDENTITY_NV, GL_RGB);
	qglFinalCombinerInputNV(GL_VARIABLE_C_NV, GL_ZERO,
	                        GL_UNSIGNED_IDENTITY_NV, GL_RGB);
	qglFinalCombinerInputNV(GL_VARIABLE_G_NV, GL_SPARE0_NV,
	                        GL_UNSIGNED_IDENTITY_NV, GL_ALPHA);
}
/*
==================
RB_NV20_DiffuseAndSpecularColorFragment
==================
*/
static void RB_NV20_DiffuseAndSpecularColorFragment(void)
{
	if (r_useCombinerDisplayLists.GetBool()) {
		qglCallList(fragmentDisplayListBase + FPROG_DIFFUSE_AND_SPECULAR_COLOR);
		return;
	}

	// program the nvidia register combiners
	qglCombinerParameteriNV(GL_NUM_GENERAL_COMBINERS_NV, 3);

	// GL_CONSTANT_COLOR0_NV will be the diffuse color
	// GL_CONSTANT_COLOR1_NV will be the specular color

	// stage 0 rgb performs the dot product
	// GL_SECONDARY_COLOR_NV = ( TEXTURE0 dot TEXTURE1 - 0.5 ) * 2
	// the scale and bias steepen the specular curve
	qglCombinerInputNV(GL_COMBINER0_NV, GL_RGB, GL_VARIABLE_A_NV,
	                   GL_TEXTURE1_ARB, GL_EXPAND_NORMAL_NV, GL_RGB);
	qglCombinerInputNV(GL_COMBINER0_NV, GL_RGB, GL_VARIABLE_B_NV,
	                   GL_TEXTURE0_ARB, GL_EXPAND_NORMAL_NV, GL_RGB);
	qglCombinerOutputNV(GL_COMBINER0_NV, GL_RGB,
	                    GL_SECONDARY_COLOR_NV, GL_DISCARD_NV, GL_DISCARD_NV,
	                    GL_SCALE_BY_TWO_NV, GL_BIAS_BY_NEGATIVE_ONE_HALF_NV, GL_TRUE, GL_FALSE, GL_FALSE);

	// stage 0 alpha does nothing

	// stage 1 color takes bump * bump
	// PRIMARY_COLOR = ( GL_SECONDARY_COLOR_NV * GL_SECONDARY_COLOR_NV - 0.5 ) * 2
	// the scale and bias steepen the specular curve
	qglCombinerInputNV(GL_COMBINER1_NV, GL_RGB, GL_VARIABLE_A_NV,
	                   GL_SECONDARY_COLOR_NV, GL_UNSIGNED_IDENTITY_NV, GL_RGB);
	qglCombinerInputNV(GL_COMBINER1_NV, GL_RGB, GL_VARIABLE_B_NV,
	                   GL_SECONDARY_COLOR_NV, GL_UNSIGNED_IDENTITY_NV, GL_RGB);
	qglCombinerOutputNV(GL_COMBINER1_NV, GL_RGB,
	                    GL_SECONDARY_COLOR_NV, GL_DISCARD_NV, GL_DISCARD_NV,
	                    GL_SCALE_BY_TWO_NV, GL_BIAS_BY_NEGATIVE_ONE_HALF_NV, GL_FALSE, GL_FALSE, GL_FALSE);

	// stage 1 alpha does nothing

	// stage 2 color
	// PRIMARY_COLOR = ( PRIMARY_COLOR * TEXTURE3 ) * 2
	// SPARE0 = 1.0 * 1.0 (needed for final combiner)
	qglCombinerInputNV(GL_COMBINER2_NV, GL_RGB, GL_VARIABLE_A_NV,
	                   GL_SECONDARY_COLOR_NV, GL_UNSIGNED_IDENTITY_NV, GL_RGB);
	qglCombinerInputNV(GL_COMBINER2_NV, GL_RGB, GL_VARIABLE_B_NV,
	                   GL_TEXTURE3_ARB, GL_UNSIGNED_IDENTITY_NV, GL_RGB);
	qglCombinerInputNV(GL_COMBINER2_NV, GL_RGB, GL_VARIABLE_C_NV,
	                   GL_ZERO, GL_UNSIGNED_INVERT_NV, GL_RGB);
	qglCombinerInputNV(GL_COMBINER2_NV, GL_RGB, GL_VARIABLE_D_NV,
	                   GL_ZERO, GL_UNSIGNED_INVERT_NV, GL_RGB);
	qglCombinerOutputNV(GL_COMBINER2_NV, GL_RGB,
	                    GL_SECONDARY_COLOR_NV, GL_SPARE0_NV, GL_DISCARD_NV,
	                    GL_SCALE_BY_TWO_NV, GL_NONE, GL_FALSE, GL_FALSE, GL_FALSE);

	// stage 2 alpha does nothing

	// final combiner = TEXTURE2_ARB * CONSTANT_COLOR0_NV + PRIMARY_COLOR_NV * CONSTANT_COLOR1_NV
	// alpha = GL_ZERO
	qglFinalCombinerInputNV(GL_VARIABLE_A_NV, GL_CONSTANT_COLOR1_NV,
	                        GL_UNSIGNED_IDENTITY_NV, GL_RGB);
	qglFinalCombinerInputNV(GL_VARIABLE_B_NV, GL_SECONDARY_COLOR_NV,
	                        GL_UNSIGNED_IDENTITY_NV, GL_RGB);
	qglFinalCombinerInputNV(GL_VARIABLE_C_NV, GL_ZERO,
	                        GL_UNSIGNED_IDENTITY_NV, GL_RGB);
	qglFinalCombinerInputNV(GL_VARIABLE_D_NV, GL_E_TIMES_F_NV,
	                        GL_UNSIGNED_IDENTITY_NV, GL_RGB);
	qglFinalCombinerInputNV(GL_VARIABLE_E_NV, GL_TEXTURE2_ARB,
	                        GL_UNSIGNED_IDENTITY_NV, GL_RGB);
	qglFinalCombinerInputNV(GL_VARIABLE_F_NV, GL_CONSTANT_COLOR0_NV,
	                        GL_UNSIGNED_IDENTITY_NV, GL_RGB);
	qglFinalCombinerInputNV(GL_VARIABLE_G_NV, GL_ZERO,
	                        GL_UNSIGNED_IDENTITY_NV, GL_ALPHA);
}
/*
==================
RB_NV20_SpecularColorFragment
==================
*/
static void RB_NV20_SpecularColorFragment(void)
{
	if (r_useCombinerDisplayLists.GetBool()) {
		qglCallList(fragmentDisplayListBase + FPROG_SPECULAR_COLOR);
		return;
	}

	// program the nvidia register combiners
	qglCombinerParameteriNV(GL_NUM_GENERAL_COMBINERS_NV, 4);

	// we want GL_CONSTANT_COLOR1_NV * PRIMARY_COLOR * TEXTURE2 * TEXTURE3 * specular( TEXTURE0 * TEXTURE1 )

	// stage 0 rgb performs the dot product
	// GL_SPARE0_NV = ( TEXTURE0 dot TEXTURE1 - 0.5 ) * 2
	// TEXTURE2 = TEXTURE2 * PRIMARY_COLOR
	// the scale and bias steepen the specular curve
	qglCombinerInputNV(GL_COMBINER0_NV, GL_RGB, GL_VARIABLE_A_NV,
	                   GL_TEXTURE1_ARB, GL_EXPAND_NORMAL_NV, GL_RGB);
	qglCombinerInputNV(GL_COMBINER0_NV, GL_RGB, GL_VARIABLE_B_NV,
	                   GL_TEXTURE0_ARB, GL_EXPAND_NORMAL_NV, GL_RGB);
	qglCombinerOutputNV(GL_COMBINER0_NV, GL_RGB,
	                    GL_SPARE0_NV, GL_DISCARD_NV, GL_DISCARD_NV,
	                    GL_SCALE_BY_TWO_NV, GL_BIAS_BY_NEGATIVE_ONE_HALF_NV, GL_TRUE, GL_FALSE, GL_FALSE);

	// stage 0 alpha does nothing

	// stage 1 color takes bump * bump
	// GL_SPARE0_NV = ( GL_SPARE0_NV * GL_SPARE0_NV - 0.5 ) * 2
	// the scale and bias steepen the specular curve
	qglCombinerInputNV(GL_COMBINER1_NV, GL_RGB, GL_VARIABLE_A_NV,
	                   GL_SPARE0_NV, GL_UNSIGNED_IDENTITY_NV, GL_RGB);
	qglCombinerInputNV(GL_COMBINER1_NV, GL_RGB, GL_VARIABLE_B_NV,
	                   GL_SPARE0_NV, GL_UNSIGNED_IDENTITY_NV, GL_RGB);
	qglCombinerOutputNV(GL_COMBINER1_NV, GL_RGB,
	                    GL_SPARE0_NV, GL_DISCARD_NV, GL_DISCARD_NV,
	                    GL_SCALE_BY_TWO_NV, GL_BIAS_BY_NEGATIVE_ONE_HALF_NV, GL_FALSE, GL_FALSE, GL_FALSE);

	// stage 1 alpha does nothing

	// stage 2 color
	// GL_SPARE0_NV = GL_SPARE0_NV * TEXTURE3
	// SECONDARY_COLOR = CONSTANT_COLOR * TEXTURE2
	qglCombinerInputNV(GL_COMBINER2_NV, GL_RGB, GL_VARIABLE_A_NV,
	                   GL_SPARE0_NV, GL_UNSIGNED_IDENTITY_NV, GL_RGB);
	qglCombinerInputNV(GL_COMBINER2_NV, GL_RGB, GL_VARIABLE_B_NV,
	                   GL_TEXTURE3_ARB, GL_UNSIGNED_IDENTITY_NV, GL_RGB);
	qglCombinerInputNV(GL_COMBINER2_NV, GL_RGB, GL_VARIABLE_C_NV,
	                   GL_CONSTANT_COLOR1_NV, GL_UNSIGNED_IDENTITY_NV, GL_RGB);
	qglCombinerInputNV(GL_COMBINER2_NV, GL_RGB, GL_VARIABLE_D_NV,
	                   GL_TEXTURE2_ARB, GL_UNSIGNED_IDENTITY_NV, GL_RGB);
	qglCombinerOutputNV(GL_COMBINER2_NV, GL_RGB,
	                    GL_SPARE0_NV, GL_SECONDARY_COLOR_NV, GL_DISCARD_NV,
	                    GL_NONE, GL_NONE, GL_FALSE, GL_FALSE, GL_FALSE);

	// stage 2 alpha does nothing


	// stage 3 scales the texture by the vertex color
	qglCombinerInputNV(GL_COMBINER3_NV, GL_RGB, GL_VARIABLE_A_NV,
	                   GL_SECONDARY_COLOR_NV, GL_UNSIGNED_IDENTITY_NV, GL_RGB);
	qglCombinerInputNV(GL_COMBINER3_NV, GL_RGB, GL_VARIABLE_B_NV,
	                   GL_PRIMARY_COLOR_NV, GL_UNSIGNED_IDENTITY_NV, GL_RGB);
	qglCombinerOutputNV(GL_COMBINER3_NV, GL_RGB,
	                    GL_SECONDARY_COLOR_NV, GL_DISCARD_NV, GL_DISCARD_NV,
	                    GL_NONE, GL_NONE, GL_FALSE, GL_FALSE, GL_FALSE);

	// stage 3 alpha does nothing

	// final combiner = GL_SPARE0_NV * SECONDARY_COLOR + PRIMARY_COLOR * SECONDARY_COLOR
	qglFinalCombinerInputNV(GL_VARIABLE_A_NV, GL_SPARE0_NV,
	                        GL_UNSIGNED_IDENTITY_NV, GL_RGB);
	qglFinalCombinerInputNV(GL_VARIABLE_B_NV, GL_SECONDARY_COLOR_NV,
	                        GL_UNSIGNED_IDENTITY_NV, GL_RGB);
	qglFinalCombinerInputNV(GL_VARIABLE_C_NV, GL_ZERO,
	                        GL_UNSIGNED_IDENTITY_NV, GL_RGB);
	qglFinalCombinerInputNV(GL_VARIABLE_D_NV, GL_E_TIMES_F_NV,
	                        GL_UNSIGNED_IDENTITY_NV, GL_RGB);
	qglFinalCombinerInputNV(GL_VARIABLE_E_NV, GL_SPARE0_NV,
	                        GL_UNSIGNED_IDENTITY_NV, GL_RGB);
	qglFinalCombinerInputNV(GL_VARIABLE_F_NV, GL_SECONDARY_COLOR_NV,
	                        GL_UNSIGNED_IDENTITY_NV, GL_RGB);
	qglFinalCombinerInputNV(GL_VARIABLE_G_NV, GL_ZERO,
	                        GL_UNSIGNED_IDENTITY_NV, GL_ALPHA);
}