1 | //--------------------------------------------------------------------------------------
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2 | // File: EnvMap.fx
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3 | //
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4 | // The effect file for the OptimizedMesh sample.
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5 | //
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6 | // Copyright (c) Microsoft Corporation. All rights reserved.
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7 | //--------------------------------------------------------------------------------------
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8 |
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9 |
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10 | /// size of the cube map taken from the reference point of the object
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11 | #define CUBEMAP_SIZE 128
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12 | /// size of the cube map for diffuse/glossy reflections
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13 | int LR_CUBEMAP_SIZE;
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14 | #define PI 3.14159f
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15 |
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16 |
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17 | //--------------------------------------------------------------------------------------
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18 | // Global variables
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19 | //--------------------------------------------------------------------------------------
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20 |
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21 |
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22 | float4x4 World; ///< World matrix for the current object
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23 | float4x4 WorldIT; ///< World matrix IT (inverse transposed) to transform surface normals of the current object
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24 | float4x4 WorldView; ///< World * View matrix
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25 | //float4x4 WorldViewIT; ///< World * View IT (inverse transposed) to transform surface normals of the current object
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26 | float4x4 WorldViewProjection; ///< World * View * Projection matrix
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27 |
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28 | float texel_size; ///< upload this constant every time the viewport changes
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29 |
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30 | float4 eyePos; ///< current eye (camera) position
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31 | float4 reference_pos; ///< Reference point for the last cube map generation.
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32 |
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33 | int nFace; ///<
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34 | int iShowCubeMap; ///<
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35 | float4 objColor;
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36 |
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37 | float intensity, shininess, brightness;
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38 |
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39 |
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40 | //--------------------------------------------------------------------------------------
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41 | // Textures & texture samplers
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42 | //--------------------------------------------------------------------------------------
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43 |
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44 |
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45 | texture EnvironmentMap, SmallEnvironmentMap, PreconvolvedEnvironmentMap, Decoration;
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46 |
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47 | sampler EnvironmentMapSampler = sampler_state
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48 | {
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49 | /*MinFilter = LINEAR;
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50 | MagFilter = LINEAR;
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51 | MipFilter = LINEAR;*/
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52 | Texture = <EnvironmentMap>;
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53 | AddressU = WRAP;
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54 | AddressV = WRAP;
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55 | };
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56 |
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57 | sampler PreconvolvedEnvironmentMapSampler = sampler_state
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58 | {
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59 | MinFilter = LINEAR;
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60 | MagFilter = LINEAR;
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61 | //MipFilter = LINEAR;
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62 | Texture = <PreconvolvedEnvironmentMap>;
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63 | AddressU = WRAP;
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64 | AddressV = WRAP;
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65 | };
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66 |
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67 | sampler SmallEnvironmentMapSampler = sampler_state
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68 | {
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69 | // MinFilter = Point;
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70 | // MagFilter = Point;
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71 |
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72 | MinFilter = LINEAR;
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73 | MagFilter = LINEAR;
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74 |
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75 | //MipFilter = Point;
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76 | Texture = <SmallEnvironmentMap>;
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77 | AddressU = WRAP;
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78 | AddressV = WRAP;
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79 | };
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80 |
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81 | sampler DecorationSampler = sampler_state
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82 | {
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83 | Texture = <Decoration>;
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84 | MinFilter = LINEAR;
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85 | MagFilter = LINEAR;
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86 | //MipFilter = LINEAR;
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87 | AddressU = CLAMP; //WRAP;
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88 | AddressV = CLAMP; //WRAP;
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89 | };
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90 |
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91 |
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92 |
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93 | //--------------------------------------------------------------------------------------
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94 | // Shader programs
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95 | //--------------------------------------------------------------------------------------
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96 |
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97 |
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98 |
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99 | void ReduceTextureVS( float4 position : POSITION,
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100 | float4 color0 : COLOR0,
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101 | float3 Normal : NORMAL,
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102 | float2 Tex : TEXCOORD0,
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103 | out float4 hposition : POSITION,
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104 | out float4 color : COLOR0,
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105 | out float2 oTex : TEXCOORD0,
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106 | out float4 pos : TEXCOORD1 )
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107 | {
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108 | pos = position;
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109 | hposition = pos;
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110 | color = color0;
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111 | oTex = Tex;
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112 | }
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113 |
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114 | /**
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115 | \brief Downsamples a cube map face.
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116 | */
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117 | #define _ReduceTexturePS( M ) \
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118 | float4 ReduceTexture##M##PS( float2 Tex : TEXCOORD0, \
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119 | float4 pos : TEXCOORD1, \
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120 | float4 color0 : COLOR0 ) : COLOR0 \
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121 | { \
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122 | /* offset to texel center */ \
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123 | pos.xy += float2(1/(float)CUBEMAP_SIZE, -1/(float)CUBEMAP_SIZE); \
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124 | /* transform position into texture coord */ \
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125 | float2 tpos = pos.xy/2+0.5; /* rescale from -1..1 into range 0..1 */ \
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126 | tpos.y = 1-tpos.y; \
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127 | \
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128 | float2 t; \
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129 | float4 color = 0; \
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130 | const int RATE = CUBEMAP_SIZE / M; \
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131 | \
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132 | for (int i = 0; i < RATE; i++) \
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133 | for (int j = 0; j < RATE; j++) \
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134 | { \
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135 | t.x = tpos.x + i/(float)CUBEMAP_SIZE; \
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136 | t.y = tpos.y + j/(float)CUBEMAP_SIZE; \
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137 | color += tex2D(DecorationSampler, t) / (RATE * RATE); \
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138 | } \
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139 | return color; \
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140 | } // end of macro definition
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141 |
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142 | _ReduceTexturePS( 2 );
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143 | _ReduceTexturePS( 4 );
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144 | _ReduceTexturePS( 8 );
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145 | _ReduceTexturePS( 16 );
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146 |
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147 |
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148 |
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149 | //--------------------------------------------------------------------------------------
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150 | // Method #0: CLASSIC (pre-convolved)
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151 | //--------------------------------------------------------------------------------------
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152 |
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153 |
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154 |
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155 | /// \brief Returns the precalculated contribution of a texel with regard to the specified query direction.
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156 | ///
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157 | /// \param q <b>query direction</b> (i.e. surface normal in diffuse case, ideal reflection direction in specular case).
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158 | /// \param L vector pointing to the texel center
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159 | float4 GetContr(float3 q, float3 L)
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160 | // Lin * a * ( dw )
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161 | // -- actually, dw is calculated by the caller --
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162 | {
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163 | //float shininess = 1;
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164 | float fcos = max(dot(L, q), 0);
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165 | // diffuse
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166 | if (shininess <= 0)
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167 | return 0.2 * fcos * texCUBE( SmallEnvironmentMapSampler, L);
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168 | else
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169 | {
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170 | // some ad-hoc formula to avoid darkening
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171 | float brightness = (pow(shininess,0.8)*0.2);
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172 | return brightness * pow(fcos, shininess) * texCUBE( SmallEnvironmentMapSampler, L);
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173 | }
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174 | }
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175 |
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176 | /// \brief Input for vertex shader ConvolutionVS().
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177 | struct _ConvolutionVS_input {
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178 | float4 Position : POSITION;
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179 | };
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180 |
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181 | /// \brief Input for pixel shader ::_ConvolutionPS().
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182 | struct _ConvolutionVS_output {
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183 | float4 hPosition : POSITION;
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184 | float3 Position : TEXCOORD0;
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185 | };
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186 |
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187 | _ConvolutionVS_output ConvolutionVS(_ConvolutionVS_input IN) {
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188 | _ConvolutionVS_output OUT;
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189 | OUT.hPosition = IN.Position;
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190 |
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191 | float2 pos = IN.Position.xy; // -1..1
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192 |
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193 | pos.x += 0.5f / LR_CUBEMAP_SIZE;
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194 | pos.y -= 0.5f / LR_CUBEMAP_SIZE;
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195 |
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196 | if (nFace == 0) OUT.Position = float3(1, pos.y, -pos.x);
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197 | if (nFace == 1) OUT.Position = float3(-1, pos.y, pos.x);
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198 | if (nFace == 2) OUT.Position = float3(pos.x, 1, -pos.y);
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199 | if (nFace == 3) OUT.Position = float3(pos.x,-1, pos.y);
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200 | if (nFace == 4) OUT.Position = float3(pos.xy, 1);
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201 | if (nFace == 5) OUT.Position = float3(-pos.x, pos.y,-1);
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202 |
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203 | return OUT;
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204 | }
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205 |
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206 | /**
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207 | \brief Convolves the values of a cube map of resoultion MxM.
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208 |
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209 | Calculates the diffuse/specular irradiance map of resolution #LR_CUBEMAP_SIZE by summing up the contributions of all cube map texels
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210 | with regard to the current query direction.
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211 | */
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212 |
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213 | #define _ConvolutionPS( M ) \
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214 | float4 Convolution##M##PS( _ConvolutionVS_output IN ) : COLOR \
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215 | { \
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216 | /* input position = query direction for the result */ \
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217 | float3 q = normalize( IN.Position ); \
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218 | float4 color = 0; \
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219 | \
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220 | for (int i = 0; i < M; i++) \
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221 | for (int j = 0; j < M; j++) \
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222 | { \
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223 | float u = (i+0.5) / (float)M; \
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224 | float v = (j+0.5) / (float)M; \
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225 | float3 pos = float3( 2*u-1, 1-2*v, 1 ); \
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226 | \
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227 | float r = length(pos); \
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228 | pos /= r; \
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229 | \
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230 | float4 dcolor = 0; \
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231 | float3 L; \
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232 | L = float3(pos.z, pos.y, -pos.x); dcolor += GetContr( q, L ); \
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233 | L = float3(-pos.z, pos.y, pos.x); dcolor += GetContr( q, L ); \
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234 | L = float3(pos.x, pos.z, -pos.y); dcolor += GetContr( q, L ); \
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235 | L = float3(pos.x, -pos.z, pos.y); dcolor += GetContr( q, L ); \
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236 | L = float3(pos.x, pos.y, pos.z); dcolor += GetContr( q, L ); \
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237 | L = float3(-pos.x, pos.y, -pos.z); dcolor += GetContr( q, L ); \
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238 | \
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239 | float dw = 4 / (r*r*r); \
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240 | color += dcolor * dw; \
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241 | } \
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242 | \
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243 | return color / (M * M); \
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244 | } /* end of macro definition */
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245 |
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246 | _ConvolutionPS( 2 );
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247 | _ConvolutionPS( 4 );
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248 | _ConvolutionPS( 8 );
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249 | _ConvolutionPS( 16 );
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250 |
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251 | /// \brief Input for vertex shader EnvMapVS().
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252 | struct _EnvMapVS_input
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253 | {
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254 | float4 Position : POSITION;
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255 | float3 Normal : NORMAL;
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256 | float2 TexCoord : TEXCOORD0;
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257 | };
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258 |
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259 | /// \brief Input for pixel shaders EnvMapDiffuseClassicPS(), ::_EnvMapDiffuseLocalizedPS(), EnvMapDiffuseLocalized5TexPS().
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260 | struct _EnvMapVS_output
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261 | {
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262 | float4 hPosition : POSITION;
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263 | float2 TexCoord : TEXCOORD0;
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264 | float3 Normal : TEXCOORD1;
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265 | float3 View : TEXCOORD2;
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266 | float3 Position : TEXCOORD3;
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267 | };
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268 |
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269 | _EnvMapVS_output EnvMapVS( _EnvMapVS_input IN )
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270 | {
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271 | _EnvMapVS_output OUT;
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272 |
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273 | OUT.Position = mul( IN.Position, World ).xyz; // scale & offset
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274 | OUT.View = normalize( OUT.Position - eyePos );
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275 | //OUT.Normal = IN.Normal;
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276 | OUT.Normal = mul( IN.Normal, WorldIT ).xyz; // allow distortion/rotation
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277 |
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278 | OUT.TexCoord = IN.TexCoord;
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279 |
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280 | OUT.hPosition = mul( IN.Position, WorldViewProjection );
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281 | return OUT;
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282 | }
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283 |
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284 | /// \brief Determines diffuse or specular illumination with a single lookup into #PreconvolvedEnvironmentMap.
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285 | /// PreconvolvedEnvironmentMap is bound to EnvMap::pCubeTexturePreConvolved (cube map of resolution #LR_CUBEMAP_SIZE).
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286 | float4 EnvMapDiffuseClassicPS( _EnvMapVS_output IN ) : COLOR
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287 | {
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288 | IN.View = normalize( IN.View );
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289 | IN.Normal = normalize( IN.Normal );
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290 |
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291 | float3 R = reflect(IN.View, IN.Normal);
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292 |
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293 | if (shininess <= 0) // diffuse
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294 | return intensity * texCUBE(PreconvolvedEnvironmentMapSampler, IN.Normal) *2;
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295 | else // specular
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296 | return intensity * texCUBE(PreconvolvedEnvironmentMapSampler, R) *2;
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297 | }
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298 |
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299 |
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300 |
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301 | //--------------------------------------------------------------------------------------
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302 | // Method #1-#2: OUR METHOD
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303 | //--------------------------------------------------------------------------------------
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304 |
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305 |
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306 |
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307 | /// \brief Calculates the contribution of a single texel of #SmallEnvironmentMap to the illumination of the shaded point.
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308 | /// To compute reflectivity, precalculated integral values are used.
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309 | ///
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310 | /// \param L vector pointing to the center of the texel under examination. We assume that the largest coordinate component
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311 | /// of L is equal to one, i.e. L points to the face of a cube of edge length of 2.
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312 | /// \param pos is the position of the shaded point
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313 | /// \param N is the surface normal at the shaded point
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314 | /// \param V is the viewing direction at the shaded point
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315 |
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316 |
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317 | float4 GetContr(int M, float3 L, float3 pos, float3 N, float3 V) // Phong-Blinn
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318 | // L is strictly non-normalized
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319 | {
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320 | float l = length(L);
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321 | L = normalize(L);
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322 |
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323 | //Lin
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324 | float4 Lin = texCUBE(SmallEnvironmentMapSampler, L);
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325 |
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326 | //dw
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327 | float dw = 4 / (M*M*l*l*l + 4/2/3.1416f);
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328 |
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329 | float dws = dw;
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330 |
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331 | //r
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332 | float doy = texCUBE(SmallEnvironmentMapSampler, L).a;
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333 | float dxy = length(pos - L * doy);
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334 |
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335 | //dws
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336 | //dws = (doy*doy * dw) / (dxy*dxy*(1 - dw/3.1416f) + doy*doy*dw/3.1416f); // localization:
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337 | //dws = (doy*doy * dw) / (dxy*dxy*(1 - dw/2/3.1416f) + doy*doy*dw/2/3.1416f); // localization:
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338 |
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339 | float den = 1 + doy*doy / (dxy*dxy) * ( (2*3.1416f)*(2*3.1416f) / ((2*3.1416f-dw)*(2*3.1416f-dw)) - 1 );
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340 | dws = 2*3.1416f * (1 - 1/sqrt(den));
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341 |
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342 | float3 LL = L * doy - pos; // L should start from the object (and not from the reference point) !!!
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343 | LL = normalize(LL);
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344 |
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345 | float3 H = normalize(L + V); // halfway vector
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346 | float3 R = reflect(-V, N); // reflection vector
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347 |
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348 | // from texture
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349 |
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350 | float4 color = 0;
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351 |
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352 | float cos_value;
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353 | if (shininess <= 0)
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354 | cos_value = dot(N,L); // diffuse
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355 | else cos_value = dot(R,L); // specular
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356 |
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357 | float2 tex;
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358 | tex.x = (cos_value + 1)/2;
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359 | tex.y = dws/2/PI;
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360 |
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361 | // lookup into precalculated reflectivity values
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362 | cos_value = tex2D(DecorationSampler, tex).g * 3;
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363 | color = Lin * 0.5 * cos_value;
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364 |
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365 | return color;
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366 | }
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367 |
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368 | // Method #1
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369 |
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370 | /// \brief Calculates diffuse or specular contributions of all texels in #SmallEnvironmentMap to the current point.
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371 | /// For each texel of #SmallEnvironmentMap, function GetContr(int,float3,float3,float3,float3) is called.
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372 |
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373 | #define _EnvMapDiffuseLocalizedPS( M ) \
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374 | float4 EnvMapDiffuseLocalized##M##PS( _EnvMapVS_output IN ) : COLOR \
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375 | { \
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376 | IN.View = -normalize( IN.View ); \
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377 | IN.Normal = normalize( IN.Normal ); \
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378 | IN.Position -= reference_pos.xyz; /* relative to the ref.point */ \
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379 | \
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380 | float3 R = -reflect( IN.View, IN.Normal ); /* reflection direction */ \
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381 | \
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382 | float4 I = 0; \
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383 | \
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384 | for (int x = 0; x < M; x++) /* foreach texel */ \
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385 | for (int y = 0; y < M; y++) \
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386 | { \
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387 | /* compute intensity for 6 texels with equal solid angles */ \
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388 | \
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389 | float2 tpos = float2( (x+0.5f)/M, (y+0.5f)/M ); /* texture coord (0..1) */ \
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390 | \
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391 | float2 p = float2(tpos.x, 1-tpos.y); \
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392 | p.xy = 2*p.xy - 1; /* position (-1..1) */ \
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393 | \
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394 | I += GetContr( M, float3(p.x, p.y, 1), IN.Position, IN.Normal, IN.View ); \
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395 | I += GetContr( M, float3(p.x, p.y, -1), IN.Position, IN.Normal, IN.View ); \
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396 | I += GetContr( M, float3(p.x, 1, p.y), IN.Position, IN.Normal, IN.View ); \
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397 | I += GetContr( M, float3(p.x, -1, p.y), IN.Position, IN.Normal, IN.View ); \
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398 | I += GetContr( M, float3(1, p.x, p.y), IN.Position, IN.Normal, IN.View ); \
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399 | I += GetContr( M, float3(-1, p.x, p.y), IN.Position, IN.Normal, IN.View ); \
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400 | } \
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401 | \
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402 | return intensity * I; \
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403 | } // end of macro definition
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404 |
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405 | _EnvMapDiffuseLocalizedPS( 2 );
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406 | _EnvMapDiffuseLocalizedPS( 4 );
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407 | _EnvMapDiffuseLocalizedPS( 8 );
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408 | _EnvMapDiffuseLocalizedPS( 16 );
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409 |
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410 |
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411 | // Method #2
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412 |
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413 | /// \brief Calculates diffuse or specular contributions of the 5 "most important" texels of #SmallEnvironmentMap to the current point.
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414 | /// For these texels, function GetContr(int,float3,float3,float3,float3) is called.
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415 |
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416 | float4 EnvMapDiffuseLocalized5TexPS( _EnvMapVS_output IN ) : COLOR
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417 | {
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418 | IN.View = -normalize( IN.View );
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419 | IN.Normal = normalize( IN.Normal );
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420 | // translate reference point to the origin
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421 | IN.Position -= reference_pos.xyz;
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422 |
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423 | float3 R = -reflect( IN.View, IN.Normal ); // reflection direction
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424 |
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425 | float4 I = 0;
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426 |
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427 | float3 q;
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428 | if ( shininess <= 0 )
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429 | q = IN.Normal; // diffuse
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430 | else
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431 | q = R;
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432 |
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433 | float rr = max( max(abs(q.x), abs(q.y)), abs(q.z) ); // select the largest component
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434 | q /= rr; // scale the largest component to value +/-1
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435 |
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436 | float3 offset1 = float3(1,0,0); // default: largest: z
|
---|
437 | float3 offset2 = float3(0,1,0); // select: x,y
|
---|
438 |
|
---|
439 | if (abs(q.x) > abs(q.y) && abs(q.x) > abs(q.z)) { // largest: x
|
---|
440 | offset1 = float3(0,0,1); // select y,z
|
---|
441 | }
|
---|
442 | if (abs(q.y) > abs(q.x) && abs(q.y) > abs(q.z)) { // largest: y
|
---|
443 | offset2 = float3(0,0,1); // select x,z
|
---|
444 | }
|
---|
445 |
|
---|
446 | I += GetContr( LR_CUBEMAP_SIZE, q, IN.Position, IN.Normal, IN.View );
|
---|
447 | I += GetContr( LR_CUBEMAP_SIZE, q + offset1*(2.0/LR_CUBEMAP_SIZE), IN.Position, IN.Normal, IN.View );
|
---|
448 | I += GetContr( LR_CUBEMAP_SIZE, q - offset1*(2.0/LR_CUBEMAP_SIZE), IN.Position, IN.Normal, IN.View );
|
---|
449 | I += GetContr( LR_CUBEMAP_SIZE, q + offset2*(2.0/LR_CUBEMAP_SIZE), IN.Position, IN.Normal, IN.View );
|
---|
450 | I += GetContr( LR_CUBEMAP_SIZE, q - offset2*(2.0/LR_CUBEMAP_SIZE), IN.Position, IN.Normal, IN.View );
|
---|
451 |
|
---|
452 | // since only 5 texels are considered, the result gets darker.
|
---|
453 | // LR_CUBEMAP_SIZE is present to compensate this.
|
---|
454 | return intensity * I * LR_CUBEMAP_SIZE / 2;
|
---|
455 | }
|
---|
456 |
|
---|
457 | // Method #3
|
---|
458 |
|
---|
459 | /// \brief Calculates diffuse or specular contributions of the 5 "most important" texels of #SmallEnvironmentMap to the current point.
|
---|
460 | /// For these texels, function GetContr(int,float3,float3,float3,float3) is called.
|
---|
461 | float4 GetContibution(float3 L1, float3 L2, float3 L3, float3 L4, float3 pos, float3 N, float d)
|
---|
462 | {
|
---|
463 | L1 = d * normalize(L1);
|
---|
464 | L2 = d * normalize(L2);
|
---|
465 | L3 = d * normalize(L3);
|
---|
466 | L4 = d * normalize(L4);
|
---|
467 |
|
---|
468 | float3 r1 = normalize(L1 - pos);
|
---|
469 | float3 r2 = normalize(L2 - pos);
|
---|
470 | float3 r3 = normalize(L3 - pos);
|
---|
471 | float3 r4 = normalize(L4 - pos);
|
---|
472 |
|
---|
473 |
|
---|
474 | float kd = 0.3; // 0.3
|
---|
475 | /*
|
---|
476 | float3 R;
|
---|
477 | R = cross(r1, r2);
|
---|
478 | float tri1 = asin(length(R)) * dot(R, N);
|
---|
479 | R = cross(r2, r3);
|
---|
480 | float tri2 = asin(length(R)) * dot(R, N);
|
---|
481 | R = cross(r3, r4);
|
---|
482 | float tri3 = asin(length(R)) * dot(R, N);
|
---|
483 | R = cross(r4, r1);
|
---|
484 | float tri4 = asin(length(R)) * dot(R, N);
|
---|
485 | */
|
---|
486 |
|
---|
487 | float tri1 = acos(dot(r1, r2)) * dot(cross(r1, r2), N);
|
---|
488 | float tri2 = acos(dot(r2, r3)) * dot(cross(r2, r3), N);
|
---|
489 | float tri3 = acos(dot(r3, r4)) * dot(cross(r3, r4), N);
|
---|
490 | float tri4 = acos(dot(r4, r1)) * dot(cross(r4, r1), N);
|
---|
491 |
|
---|
492 | return max(tri1 + tri2 + tri3 + tri4, 0);
|
---|
493 | //return tri1 + tri2 + tri3 + tri4;
|
---|
494 | }
|
---|
495 |
|
---|
496 | float4 EnvMapDiffuseLocalizedNewPS( _EnvMapVS_output IN ) : COLOR
|
---|
497 | {
|
---|
498 | float M = 4.0;
|
---|
499 | IN.View = -normalize( IN.View );
|
---|
500 | IN.Normal = normalize( IN.Normal );
|
---|
501 | IN.Position -= reference_pos.xyz;
|
---|
502 | float3 pos = IN.Position.xyz;
|
---|
503 |
|
---|
504 | //return reference_pos;
|
---|
505 | //return texCUBE(SmallEnvironmentMapSampler, pos);
|
---|
506 |
|
---|
507 | float3 N =IN.Normal;
|
---|
508 | float3 R = -reflect( IN.View, IN.Normal );
|
---|
509 |
|
---|
510 | float4 I = 0;
|
---|
511 | float3 L1, L2, L3, L4, L;
|
---|
512 | float4 Le;
|
---|
513 | float d;
|
---|
514 | float width = 1.0 / M;
|
---|
515 |
|
---|
516 | for (int x = 0; x < M; x++)
|
---|
517 | for (int y = 0; y < M; y++)
|
---|
518 | {
|
---|
519 | float2 p, tpos;
|
---|
520 | tpos.x = (x + 0.5) * width; // 0..1
|
---|
521 | tpos.y = (y + 0.5) * width; // 0..1
|
---|
522 |
|
---|
523 | p = tpos.xy;
|
---|
524 | p = 2.0 * p - 1.0; //-1..1
|
---|
525 |
|
---|
526 | L1 = float3(p.x - width, p.y - width, 1);
|
---|
527 | L2 = float3(p.x + width, p.y - width, 1);
|
---|
528 | L3 = float3(p.x + width, p.y + width, 1);
|
---|
529 | L4 = float3(p.x - width, p.y + width, 1);
|
---|
530 | L = float3(p.x, p.y, 1);
|
---|
531 | Le = float4(texCUBE(SmallEnvironmentMapSampler, L).rgb, 1);
|
---|
532 | d = texCUBE(SmallEnvironmentMapSampler, L).a;
|
---|
533 |
|
---|
534 | I += 0.5 * Le * GetContibution( L1, L2, L3, L4, pos, N, d);
|
---|
535 | //I += Le / 16.0;
|
---|
536 | }
|
---|
537 |
|
---|
538 | for (int x = 0; x < M; x++)
|
---|
539 | for (int y = 0; y < M; y++)
|
---|
540 | {
|
---|
541 | float2 p, tpos;
|
---|
542 | tpos.x = (x + 0.5) * width; // 0..1
|
---|
543 | tpos.y = (y + 0.5) * width; // 0..1
|
---|
544 |
|
---|
545 | p = tpos.xy;
|
---|
546 | p = 2.0 * p - 1.0; //-1..1
|
---|
547 |
|
---|
548 | L4 = float3(p.x - width, p.y - width, -1);
|
---|
549 | L3 = float3(p.x + width, p.y - width, -1);
|
---|
550 | L2 = float3(p.x + width, p.y + width, -1);
|
---|
551 | L1 = float3(p.x - width, p.y + width, -1);
|
---|
552 | L = float3(p.x, p.y, -1);
|
---|
553 | Le = float4(texCUBE(SmallEnvironmentMapSampler, L).rgb, 1);
|
---|
554 | d = texCUBE(SmallEnvironmentMapSampler, L).a;
|
---|
555 |
|
---|
556 | I += 0.5 * Le * GetContibution( L1, L2, L3, L4, pos, N, d);
|
---|
557 | //I += Le / 16.0;
|
---|
558 | }
|
---|
559 |
|
---|
560 | for (int x = 0; x < M; x++)
|
---|
561 | for (int y = 0; y < M; y++)
|
---|
562 | {
|
---|
563 | float2 p, tpos;
|
---|
564 | tpos.x = (x + 0.5) * width; // 0..1
|
---|
565 | tpos.y = (y + 0.5) * width; // 0..1
|
---|
566 |
|
---|
567 | p = tpos.xy;
|
---|
568 | p = 2.0 * p - 1.0; //-1..1
|
---|
569 |
|
---|
570 | L4 = float3(p.x - width, 1, p.y - width);
|
---|
571 | L3 = float3(p.x + width, 1, p.y - width);
|
---|
572 | L2 = float3(p.x + width, 1, p.y + width);
|
---|
573 | L1 = float3(p.x - width, 1, p.y + width);
|
---|
574 | L = float3(p.x, 1, p.y);
|
---|
575 | Le = float4(texCUBE(SmallEnvironmentMapSampler, L).rgb, 1);
|
---|
576 | d = texCUBE(SmallEnvironmentMapSampler, L).a;
|
---|
577 |
|
---|
578 | I += 0.5 * Le * GetContibution( L1, L2, L3, L4, pos, N, d);
|
---|
579 | //I += Le / 16.0;
|
---|
580 | }
|
---|
581 |
|
---|
582 | for (int x = 0; x < M; x++)
|
---|
583 | for (int y = 0; y < M; y++)
|
---|
584 | {
|
---|
585 | float2 p, tpos;
|
---|
586 | tpos.x = (x + 0.5) * width; // 0..1
|
---|
587 | tpos.y = (y + 0.5) * width; // 0..1
|
---|
588 |
|
---|
589 | p = tpos.xy;
|
---|
590 | p = 2.0 * p - 1.0; //-1..1
|
---|
591 |
|
---|
592 | L1 = float3(p.x - width, -1, p.y - width);
|
---|
593 | L2 = float3(p.x + width, -1, p.y - width);
|
---|
594 | L3 = float3(p.x + width, -1, p.y + width);
|
---|
595 | L4 = float3(p.x - width, -1, p.y + width);
|
---|
596 | L = float3(p.x, -1, p.y);
|
---|
597 | Le = float4(texCUBE(SmallEnvironmentMapSampler, L).rgb, 1);
|
---|
598 | d = texCUBE(SmallEnvironmentMapSampler, L).a;
|
---|
599 |
|
---|
600 | I += 0.5 * Le * GetContibution( L1, L2, L3, L4, pos, N, d);
|
---|
601 | //I += Le / 16.0;
|
---|
602 | }
|
---|
603 | for (int x = 0; x < M; x++)
|
---|
604 | for (int y = 0; y < M; y++)
|
---|
605 | {
|
---|
606 | float2 p, tpos;
|
---|
607 | tpos.x = (x + 0.5) * width; // 0..1
|
---|
608 | tpos.y = (y + 0.5) * width; // 0..1
|
---|
609 |
|
---|
610 | p = tpos.xy;
|
---|
611 | p = 2.0 * p - 1.0; //-1..1
|
---|
612 |
|
---|
613 | L1 = float3(1, p.x - width, p.y - width);
|
---|
614 | L2 = float3(1, p.x + width, p.y - width);
|
---|
615 | L3 = float3(1, p.x + width, p.y + width);
|
---|
616 | L4 = float3(1, p.x - width, p.y + width);
|
---|
617 | L = float3(1, p.x, p.y);
|
---|
618 | Le = float4(texCUBE(SmallEnvironmentMapSampler, L).rgb, 1);
|
---|
619 | d = texCUBE(SmallEnvironmentMapSampler, L).a;
|
---|
620 |
|
---|
621 | I += 0.5 * Le * GetContibution( L1, L2, L3, L4, pos, N, d);
|
---|
622 | //I += Le / 16.0;
|
---|
623 | }
|
---|
624 |
|
---|
625 | for (int x = 0; x < M; x++)
|
---|
626 | for (int y = 0; y < M; y++)
|
---|
627 | {
|
---|
628 | float2 p, tpos;
|
---|
629 | tpos.x = (x + 0.5) * width; // 0..1
|
---|
630 | tpos.y = (y + 0.5) * width; // 0..1
|
---|
631 |
|
---|
632 | p = tpos.xy;
|
---|
633 | p = 2.0 * p - 1.0; //-1..1
|
---|
634 |
|
---|
635 | L4 = float3(-1, p.x - width, p.y - width);
|
---|
636 | L3 = float3(-1, p.x + width, p.y - width);
|
---|
637 | L2 = float3(-1, p.x + width, p.y + width);
|
---|
638 | L1 = float3(-1, p.x - width, p.y + width);
|
---|
639 | L = float3(-1, p.x, p.y);
|
---|
640 | Le = float4(texCUBE(SmallEnvironmentMapSampler, L).rgb, 1);
|
---|
641 | d = texCUBE(SmallEnvironmentMapSampler, L).a;
|
---|
642 |
|
---|
643 | I += 0.5 * Le * GetContibution( L1, L2, L3, L4, pos, N, d);
|
---|
644 | //I += Le / 16.0;
|
---|
645 | }
|
---|
646 | return intensity * I;
|
---|
647 | }
|
---|
648 |
|
---|
649 |
|
---|
650 | //--------------------------------------------------------------------------------------
|
---|
651 | // Shading the environment
|
---|
652 | //--------------------------------------------------------------------------------------
|
---|
653 |
|
---|
654 | /// \brief Input for vertex shader IlluminatedSceneVS().
|
---|
655 | struct _IlluminatedSceneVS_input {
|
---|
656 | float4 Position : POSITION;
|
---|
657 | float3 Normal : NORMAL;
|
---|
658 | float2 TexCoord : TEXCOORD0;
|
---|
659 | };
|
---|
660 |
|
---|
661 | /// \brief Input for pixel shader IlluminatedScenePS().
|
---|
662 | struct _IlluminatedSceneVS_output {
|
---|
663 | float4 hPosition : POSITION;
|
---|
664 | float2 TexCoord : TEXCOORD0;
|
---|
665 | float3 Position : TEXCOORD1;
|
---|
666 | };
|
---|
667 |
|
---|
668 | _IlluminatedSceneVS_output IlluminatedSceneVS( _IlluminatedSceneVS_input IN )
|
---|
669 | {
|
---|
670 | _IlluminatedSceneVS_output OUT;
|
---|
671 | OUT.hPosition = mul( IN.Position, WorldViewProjection );
|
---|
672 |
|
---|
673 | // texel_size as uniform parameter
|
---|
674 | OUT.hPosition.x -= texel_size * OUT.hPosition.w;
|
---|
675 | OUT.hPosition.y += texel_size * OUT.hPosition.w;
|
---|
676 |
|
---|
677 | if (iShowCubeMap > 0)
|
---|
678 | {
|
---|
679 | // if one of the cube maps is displayed on the walls,
|
---|
680 | // position is simply forwarded
|
---|
681 | OUT.Position = IN.Position;
|
---|
682 | }
|
---|
683 | else
|
---|
684 | {
|
---|
685 | // also consider camera orientation
|
---|
686 | OUT.Position = mul( IN.Position, WorldView );
|
---|
687 | }
|
---|
688 |
|
---|
689 | OUT.TexCoord = IN.TexCoord;
|
---|
690 | return OUT;
|
---|
691 | }
|
---|
692 |
|
---|
693 | /// Displays the environment with a simple shading
|
---|
694 | float4 IlluminatedScenePS( _IlluminatedSceneVS_output IN ) : COLOR0
|
---|
695 | {
|
---|
696 | float3 color = objColor * tex2D(DecorationSampler, IN.TexCoord);
|
---|
697 |
|
---|
698 | if (iShowCubeMap > 0)
|
---|
699 | {
|
---|
700 | // if one of the cube maps should be displayed on the walls,
|
---|
701 | // display it
|
---|
702 | color = texCUBE(EnvironmentMapSampler, IN.Position) * intensity;
|
---|
703 | }
|
---|
704 | else if (brightness>0)
|
---|
705 | {
|
---|
706 | // create an exponential falloff for each face of the room
|
---|
707 | float3 L = float3(2*IN.TexCoord.x-1, 2*IN.TexCoord.y-1, -1);
|
---|
708 | L = normalize(L);
|
---|
709 | float3 N = float3(0,0,1);
|
---|
710 | color *= abs(pow(dot(L,N), 4)) * brightness;
|
---|
711 | }
|
---|
712 | else color *= 0.7;
|
---|
713 |
|
---|
714 | float dist = length( IN.Position );
|
---|
715 | return float4(color, dist);
|
---|
716 | }
|
---|
717 |
|
---|
718 |
|
---|
719 |
|
---|
720 |
|
---|
721 | //--------------------------------------------------------------------------------------
|
---|
722 | // Techniques
|
---|
723 | //--------------------------------------------------------------------------------------
|
---|
724 |
|
---|
725 |
|
---|
726 | /// a helpful macro to define techniques with a common vertex program
|
---|
727 | #define TechniqueUsingCommonVS(name); \
|
---|
728 | technique name \
|
---|
729 | { \
|
---|
730 | pass p0 \
|
---|
731 | { \
|
---|
732 | VertexShader = compile vs_3_0 EnvMapVS(); \
|
---|
733 | PixelShader = compile ps_3_0 name##PS(); \
|
---|
734 | } \
|
---|
735 | }
|
---|
736 |
|
---|
737 | TechniqueUsingCommonVS( EnvMapDiffuseClassic );
|
---|
738 | TechniqueUsingCommonVS( EnvMapDiffuseLocalized5Tex );
|
---|
739 |
|
---|
740 | //TechniqueUsingCommonVS( EnvMapDiffuseLocalized );
|
---|
741 | TechniqueUsingCommonVS( EnvMapDiffuseLocalized2 );
|
---|
742 | TechniqueUsingCommonVS( EnvMapDiffuseLocalized4 );
|
---|
743 | TechniqueUsingCommonVS( EnvMapDiffuseLocalized8 );
|
---|
744 | TechniqueUsingCommonVS( EnvMapDiffuseLocalized16 );
|
---|
745 |
|
---|
746 | TechniqueUsingCommonVS( EnvMapDiffuseLocalizedNew );
|
---|
747 | //TechniqueUsingCommonVS( EnvMapDiffuseLocalizedNew4 );
|
---|
748 | //TechniqueUsingCommonVS( EnvMapDiffuseLocalizedNew8 );
|
---|
749 | //TechniqueUsingCommonVS( EnvMapDiffuseLocalizedNew16 );
|
---|
750 |
|
---|
751 | #define ReduceTextureTechnique(M); \
|
---|
752 | technique ReduceTexture##M \
|
---|
753 | { \
|
---|
754 | pass p0 \
|
---|
755 | { \
|
---|
756 | VertexShader = compile vs_3_0 ReduceTextureVS(); \
|
---|
757 | PixelShader = compile ps_3_0 ReduceTexture##M##PS(); \
|
---|
758 | } \
|
---|
759 | }
|
---|
760 |
|
---|
761 | ReduceTextureTechnique( 2 );
|
---|
762 | ReduceTextureTechnique( 4 );
|
---|
763 | ReduceTextureTechnique( 8 );
|
---|
764 | ReduceTextureTechnique( 16 );
|
---|
765 |
|
---|
766 | #define ConvolutionTechnique(M); \
|
---|
767 | technique Convolution##M \
|
---|
768 | { \
|
---|
769 | pass p0 \
|
---|
770 | { \
|
---|
771 | VertexShader = compile vs_3_0 ConvolutionVS(); \
|
---|
772 | PixelShader = compile ps_3_0 Convolution##M##PS(); \
|
---|
773 | } \
|
---|
774 | }
|
---|
775 |
|
---|
776 | ConvolutionTechnique( 2 );
|
---|
777 | ConvolutionTechnique( 4 );
|
---|
778 | ConvolutionTechnique( 8 );
|
---|
779 | ConvolutionTechnique( 16 );
|
---|
780 |
|
---|
781 | /// a helpful macro to define techniques
|
---|
782 | /// where the name of EnvMapVS program is <TechniqueName>VS
|
---|
783 | /// and the name of PS program is <TechniqueName>PS
|
---|
784 | #define Technique(name); \
|
---|
785 | technique name \
|
---|
786 | { \
|
---|
787 | pass p0 \
|
---|
788 | { \
|
---|
789 | VertexShader = compile vs_3_0 name##VS(); \
|
---|
790 | PixelShader = compile ps_3_0 name##PS(); \
|
---|
791 | } \
|
---|
792 | }
|
---|
793 |
|
---|
794 | Technique( IlluminatedScene );
|
---|
795 | //Technique( Convolution );
|
---|
796 | //Technique( ReduceTexture ); |
---|