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423 lines
16 KiB
423 lines
16 KiB
//========= Copyright Valve Corporation, All rights reserved. ============//
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#ifndef COMMON_VERTEXLITGENERIC_DX9_H_
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#define COMMON_VERTEXLITGENERIC_DX9_H_
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#include "common_ps_fxc.h"
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// We store four light colors and positions in an
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// array of three of these structures like so:
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//
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// x y z w
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// +------+------+------+------+
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// | L0.rgb | |
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// +------+------+------+ |
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// | L0.pos | L3 |
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// +------+------+------+ rgb |
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// | L1.rgb | |
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// +------+------+------+------+
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// | L1.pos | |
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// +------+------+------+ |
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// | L2.rgb | L3 |
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// +------+------+------+ pos |
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// | L2.pos | |
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// +------+------+------+------+
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//
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struct PixelShaderLightInfo
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{
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float4 color;
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float4 pos;
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};
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#define cOverbright 2.0f
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#define cOOOverbright 0.5f
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#define LIGHTTYPE_NONE 0
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#define LIGHTTYPE_SPOT 1
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#define LIGHTTYPE_POINT 2
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#define LIGHTTYPE_DIRECTIONAL 3
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// Better suited to Pixel shader models, 11 instructions in pixel shader
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// ... actually, now only 9: mul, cmp, cmp, mul, mad, mad, mad, mad, mad
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float3 PixelShaderAmbientLight( const float3 worldNormal, const float3 cAmbientCube[6] )
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{
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float3 linearColor, nSquared = worldNormal * worldNormal;
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float3 isNegative = ( worldNormal >= 0.0 ) ? 0 : nSquared;
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float3 isPositive = ( worldNormal >= 0.0 ) ? nSquared : 0;
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linearColor = isPositive.x * cAmbientCube[0] + isNegative.x * cAmbientCube[1] +
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isPositive.y * cAmbientCube[2] + isNegative.y * cAmbientCube[3] +
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isPositive.z * cAmbientCube[4] + isNegative.z * cAmbientCube[5];
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return linearColor;
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}
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// Better suited to Vertex shader models
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// Six VS instructions due to use of constant indexing (slt, mova, mul, mul, mad, mad)
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float3 VertexShaderAmbientLight( const float3 worldNormal, const float3 cAmbientCube[6] )
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{
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float3 nSquared = worldNormal * worldNormal;
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int3 isNegative = ( worldNormal < 0.0 );
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float3 linearColor;
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linearColor = nSquared.x * cAmbientCube[isNegative.x] +
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nSquared.y * cAmbientCube[isNegative.y+2] +
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nSquared.z * cAmbientCube[isNegative.z+4];
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return linearColor;
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}
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float3 AmbientLight( const float3 worldNormal, const float3 cAmbientCube[6] )
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{
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// Vertex shader cases
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#ifdef SHADER_MODEL_VS_1_0
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return VertexShaderAmbientLight( worldNormal, cAmbientCube );
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#elif SHADER_MODEL_VS_1_1
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return VertexShaderAmbientLight( worldNormal, cAmbientCube );
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#elif SHADER_MODEL_VS_2_0
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return VertexShaderAmbientLight( worldNormal, cAmbientCube );
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#elif SHADER_MODEL_VS_3_0
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return VertexShaderAmbientLight( worldNormal, cAmbientCube );
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#else
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// Pixel shader case
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return PixelShaderAmbientLight( worldNormal, cAmbientCube );
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#endif
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}
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//-----------------------------------------------------------------------------
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// Purpose: Compute scalar diffuse term with various optional tweaks such as
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// Half Lambert and ambient occlusion
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//-----------------------------------------------------------------------------
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float3 DiffuseTerm(const bool bHalfLambert, const float3 worldNormal, const float3 lightDir,
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const bool bDoAmbientOcclusion, const float fAmbientOcclusion,
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const bool bDoLightingWarp, in sampler lightWarpSampler )
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{
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float fResult;
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float NDotL = dot( worldNormal, lightDir ); // Unsaturated dot (-1 to 1 range)
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if ( bHalfLambert )
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{
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fResult = saturate(NDotL * 0.5 + 0.5); // Scale and bias to 0 to 1 range
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if ( !bDoLightingWarp )
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{
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fResult *= fResult; // Square
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}
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}
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else
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{
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fResult = saturate( NDotL ); // Saturate pure Lambertian term
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}
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if ( bDoAmbientOcclusion )
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{
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// Raise to higher powers for darker AO values
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// float fAOPower = lerp( 4.0f, 1.0f, fAmbientOcclusion );
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// result *= pow( NDotL * 0.5 + 0.5, fAOPower );
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fResult *= fAmbientOcclusion;
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}
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float3 fOut = float3( fResult, fResult, fResult );
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if ( bDoLightingWarp )
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{
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fOut = 2.0f * tex1D( lightWarpSampler, fResult );
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}
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return fOut;
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}
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float3 PixelShaderDoGeneralDiffuseLight( const float fAtten, const float3 worldPos, const float3 worldNormal,
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in sampler NormalizeSampler,
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const float3 vPosition, const float3 vColor, const bool bHalfLambert,
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const bool bDoAmbientOcclusion, const float fAmbientOcclusion,
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const bool bDoLightingWarp, in sampler lightWarpSampler )
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{
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#if (defined(SHADER_MODEL_PS_2_B) || defined(SHADER_MODEL_PS_3_0))
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float3 lightDir = normalize( vPosition - worldPos );
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#else
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float3 lightDir = NormalizeWithCubemap( NormalizeSampler, vPosition - worldPos );
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#endif
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return vColor * fAtten * DiffuseTerm( bHalfLambert, worldNormal, lightDir, bDoAmbientOcclusion, fAmbientOcclusion, bDoLightingWarp, lightWarpSampler );
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}
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float3 PixelShaderGetLightVector( const float3 worldPos, PixelShaderLightInfo cLightInfo[3], int nLightIndex )
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{
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if ( nLightIndex == 3 )
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{
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// Unpack light 3 from w components...
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float3 vLight3Pos = float3( cLightInfo[1].pos.w, cLightInfo[2].color.w, cLightInfo[2].pos.w );
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return normalize( vLight3Pos - worldPos );
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}
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else
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{
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return normalize( cLightInfo[nLightIndex].pos - worldPos );
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}
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}
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float3 PixelShaderGetLightColor( PixelShaderLightInfo cLightInfo[3], int nLightIndex )
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{
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if ( nLightIndex == 3 )
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{
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// Unpack light 3 from w components...
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return float3( cLightInfo[0].color.w, cLightInfo[0].pos.w, cLightInfo[1].color.w );
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}
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else
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{
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return cLightInfo[nLightIndex].color.rgb;
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}
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}
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void SpecularAndRimTerms( const float3 vWorldNormal, const float3 vLightDir, const float fSpecularExponent,
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const float3 vEyeDir, const bool bDoAmbientOcclusion, const float fAmbientOcclusion,
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const bool bDoSpecularWarp, in sampler specularWarpSampler, const float fFresnel,
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const float3 color, const bool bDoRimLighting, const float fRimExponent,
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// Outputs
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out float3 specularLighting, out float3 rimLighting )
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{
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rimLighting = float3(0.0f, 0.0f, 0.0f);
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//float3 vReflect = reflect( -vEyeDir, vWorldNormal ); // Reflect view through normal
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float3 vReflect = 2 * vWorldNormal * dot( vWorldNormal , vEyeDir ) - vEyeDir; // Reflect view through normal
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float LdotR = saturate(dot( vReflect, vLightDir )); // L.R (use half-angle instead?)
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specularLighting = pow( LdotR, fSpecularExponent ); // Raise to specular exponent
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// Optionally warp as function of scalar specular and fresnel
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if ( bDoSpecularWarp )
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specularLighting *= tex2D( specularWarpSampler, float2(specularLighting.x, fFresnel) ); // Sample at { (L.R)^k, fresnel }
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specularLighting *= saturate(dot( vWorldNormal, vLightDir )); // Mask with N.L
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specularLighting *= color; // Modulate with light color
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if ( bDoAmbientOcclusion ) // Optionally modulate with ambient occlusion
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specularLighting *= fAmbientOcclusion;
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if ( bDoRimLighting ) // Optionally do rim lighting
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{
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rimLighting = pow( LdotR, fRimExponent ); // Raise to rim exponent
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rimLighting *= saturate(dot( vWorldNormal, vLightDir )); // Mask with N.L
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rimLighting *= color; // Modulate with light color
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}
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}
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// Traditional fresnel term approximation
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float Fresnel( const float3 vNormal, const float3 vEyeDir )
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{
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float fresnel = saturate( 1 - dot( vNormal, vEyeDir ) ); // 1-(N.V) for Fresnel term
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return fresnel * fresnel; // Square for a more subtle look
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}
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// Traditional fresnel term approximation which uses 4th power (square twice)
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float Fresnel4( const float3 vNormal, const float3 vEyeDir )
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{
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float fresnel = saturate( 1 - dot( vNormal, vEyeDir ) ); // 1-(N.V) for Fresnel term
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fresnel = fresnel * fresnel; // Square
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return fresnel * fresnel; // Square again for a more subtle look
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}
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//
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// Custom Fresnel with low, mid and high parameters defining a piecewise continuous function
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// with traditional fresnel (0 to 1 range) as input. The 0 to 0.5 range blends between
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// low and mid while the 0.5 to 1 range blends between mid and high
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//
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// |
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// | . M . . . H
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// | .
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// L
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// |
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// +----------------
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// 0 1
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//
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float Fresnel( const float3 vNormal, const float3 vEyeDir, float3 vRanges )
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{
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//float result, f = Fresnel( vNormal, vEyeDir ); // Traditional Fresnel
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//if ( f > 0.5f )
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// result = lerp( vRanges.y, vRanges.z, (2*f)-1 ); // Blend between mid and high values
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//else
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// result = lerp( vRanges.x, vRanges.y, 2*f ); // Blend between low and mid values
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// note: vRanges is now encoded as ((mid-min)*2, mid, (max-mid)*2) to optimize math
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float f = saturate( 1 - dot( vNormal, vEyeDir ) );
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f = f*f - 0.5;
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return vRanges.y + (f >= 0.0 ? vRanges.z : vRanges.x) * f;
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}
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void PixelShaderDoSpecularLight( const float3 vWorldPos, const float3 vWorldNormal, const float fSpecularExponent, const float3 vEyeDir,
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const float fAtten, const float3 vLightColor, const float3 vLightDir,
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const bool bDoAmbientOcclusion, const float fAmbientOcclusion,
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const bool bDoSpecularWarp, in sampler specularWarpSampler, float fFresnel,
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const bool bDoRimLighting, const float fRimExponent,
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// Outputs
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out float3 specularLighting, out float3 rimLighting )
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{
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// Compute Specular and rim terms
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SpecularAndRimTerms( vWorldNormal, vLightDir, fSpecularExponent,
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vEyeDir, bDoAmbientOcclusion, fAmbientOcclusion,
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bDoSpecularWarp, specularWarpSampler, fFresnel, vLightColor * fAtten,
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bDoRimLighting, fRimExponent, specularLighting, rimLighting );
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}
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float3 PixelShaderDoLightingLinear( const float3 worldPos, const float3 worldNormal,
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const float3 staticLightingColor, const bool bStaticLight,
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const bool bAmbientLight, const float4 lightAtten, const float3 cAmbientCube[6],
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in sampler NormalizeSampler, const int nNumLights, PixelShaderLightInfo cLightInfo[3],
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const bool bHalfLambert, const bool bDoAmbientOcclusion, const float fAmbientOcclusion,
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const bool bDoLightingWarp, in sampler lightWarpSampler )
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{
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float3 linearColor = 0.0f;
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if ( bStaticLight )
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{
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// The static lighting comes in in gamma space and has also been premultiplied by $cOOOverbright
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// need to get it into
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// linear space so that we can do adds.
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linearColor += GammaToLinear( staticLightingColor * cOverbright );
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}
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if ( bAmbientLight )
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{
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float3 ambient = AmbientLight( worldNormal, cAmbientCube );
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if ( bDoAmbientOcclusion )
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ambient *= fAmbientOcclusion * fAmbientOcclusion; // Note squaring...
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linearColor += ambient;
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}
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if ( nNumLights > 0 )
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{
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linearColor += PixelShaderDoGeneralDiffuseLight( lightAtten.x, worldPos, worldNormal, NormalizeSampler,
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cLightInfo[0].pos, cLightInfo[0].color, bHalfLambert,
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bDoAmbientOcclusion, fAmbientOcclusion,
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bDoLightingWarp, lightWarpSampler );
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if ( nNumLights > 1 )
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{
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linearColor += PixelShaderDoGeneralDiffuseLight( lightAtten.y, worldPos, worldNormal, NormalizeSampler,
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cLightInfo[1].pos, cLightInfo[1].color, bHalfLambert,
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bDoAmbientOcclusion, fAmbientOcclusion,
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bDoLightingWarp, lightWarpSampler );
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if ( nNumLights > 2 )
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{
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linearColor += PixelShaderDoGeneralDiffuseLight( lightAtten.z, worldPos, worldNormal, NormalizeSampler,
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cLightInfo[2].pos, cLightInfo[2].color, bHalfLambert,
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bDoAmbientOcclusion, fAmbientOcclusion,
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bDoLightingWarp, lightWarpSampler );
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if ( nNumLights > 3 )
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{
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// Unpack the 4th light's data from tight constant packing
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float3 vLight3Color = float3( cLightInfo[0].color.w, cLightInfo[0].pos.w, cLightInfo[1].color.w );
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float3 vLight3Pos = float3( cLightInfo[1].pos.w, cLightInfo[2].color.w, cLightInfo[2].pos.w );
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linearColor += PixelShaderDoGeneralDiffuseLight( lightAtten.w, worldPos, worldNormal, NormalizeSampler,
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vLight3Pos, vLight3Color, bHalfLambert,
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bDoAmbientOcclusion, fAmbientOcclusion,
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bDoLightingWarp, lightWarpSampler );
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}
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}
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}
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}
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return linearColor;
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}
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void PixelShaderDoSpecularLighting( const float3 worldPos, const float3 worldNormal, const float fSpecularExponent, const float3 vEyeDir,
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const float4 lightAtten, const int nNumLights, PixelShaderLightInfo cLightInfo[3],
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const bool bDoAmbientOcclusion, const float fAmbientOcclusion,
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const bool bDoSpecularWarp, in sampler specularWarpSampler, float fFresnel,
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const bool bDoRimLighting, const float fRimExponent,
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// Outputs
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out float3 specularLighting, out float3 rimLighting )
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{
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specularLighting = rimLighting = float3( 0.0f, 0.0f, 0.0f );
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float3 localSpecularTerm, localRimTerm;
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if( nNumLights > 0 )
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{
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PixelShaderDoSpecularLight( worldPos, worldNormal, fSpecularExponent, vEyeDir,
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lightAtten.x, PixelShaderGetLightColor( cLightInfo, 0 ),
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PixelShaderGetLightVector( worldPos, cLightInfo, 0 ),
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bDoAmbientOcclusion, fAmbientOcclusion,
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bDoSpecularWarp, specularWarpSampler, fFresnel,
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bDoRimLighting, fRimExponent,
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localSpecularTerm, localRimTerm );
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specularLighting += localSpecularTerm; // Accumulate specular and rim terms
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rimLighting += localRimTerm;
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}
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if( nNumLights > 1 )
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{
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PixelShaderDoSpecularLight( worldPos, worldNormal, fSpecularExponent, vEyeDir,
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lightAtten.y, PixelShaderGetLightColor( cLightInfo, 1 ),
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PixelShaderGetLightVector( worldPos, cLightInfo, 1 ),
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bDoAmbientOcclusion, fAmbientOcclusion,
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bDoSpecularWarp, specularWarpSampler, fFresnel,
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bDoRimLighting, fRimExponent,
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localSpecularTerm, localRimTerm );
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specularLighting += localSpecularTerm; // Accumulate specular and rim terms
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rimLighting += localRimTerm;
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}
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if( nNumLights > 2 )
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{
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PixelShaderDoSpecularLight( worldPos, worldNormal, fSpecularExponent, vEyeDir,
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lightAtten.z, PixelShaderGetLightColor( cLightInfo, 2 ),
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PixelShaderGetLightVector( worldPos, cLightInfo, 2 ),
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bDoAmbientOcclusion, fAmbientOcclusion,
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bDoSpecularWarp, specularWarpSampler, fFresnel,
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bDoRimLighting, fRimExponent,
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localSpecularTerm, localRimTerm );
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specularLighting += localSpecularTerm; // Accumulate specular and rim terms
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rimLighting += localRimTerm;
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}
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if( nNumLights > 3 )
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{
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PixelShaderDoSpecularLight( worldPos, worldNormal, fSpecularExponent, vEyeDir,
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lightAtten.w, PixelShaderGetLightColor( cLightInfo, 3 ),
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PixelShaderGetLightVector( worldPos, cLightInfo, 3 ),
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bDoAmbientOcclusion, fAmbientOcclusion,
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bDoSpecularWarp, specularWarpSampler, fFresnel,
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bDoRimLighting, fRimExponent,
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localSpecularTerm, localRimTerm );
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specularLighting += localSpecularTerm; // Accumulate specular and rim terms
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rimLighting += localRimTerm;
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}
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}
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float3 PixelShaderDoRimLighting( const float3 worldNormal, const float3 vEyeDir, const float3 cAmbientCube[6], float fFresnel )
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{
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float3 vReflect = reflect( -vEyeDir, worldNormal ); // Reflect view through normal
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return fFresnel * PixelShaderAmbientLight( vEyeDir, cAmbientCube );
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}
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// Called directly by newer shaders or through the following wrapper for older shaders
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float3 PixelShaderDoLighting( const float3 worldPos, const float3 worldNormal,
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const float3 staticLightingColor, const bool bStaticLight,
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const bool bAmbientLight, const float4 lightAtten, const float3 cAmbientCube[6],
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in sampler NormalizeSampler, const int nNumLights, PixelShaderLightInfo cLightInfo[3],
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const bool bHalfLambert,
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// New optional/experimental parameters
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const bool bDoAmbientOcclusion, const float fAmbientOcclusion,
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const bool bDoLightingWarp, in sampler lightWarpSampler )
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{
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float3 linearColor = PixelShaderDoLightingLinear( worldPos, worldNormal, staticLightingColor,
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bStaticLight, bAmbientLight, lightAtten,
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cAmbientCube, NormalizeSampler, nNumLights, cLightInfo, bHalfLambert,
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bDoAmbientOcclusion, fAmbientOcclusion,
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bDoLightingWarp, lightWarpSampler );
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// go ahead and clamp to the linear space equivalent of overbright 2 so that we match
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// everything else.
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// linearColor = HuePreservingColorClamp( linearColor, pow( 2.0f, 2.2 ) );
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return linearColor;
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}
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#endif //#ifndef COMMON_VERTEXLITGENERIC_DX9_H_
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