#ifndef SPRITE_VERTEX_LIGHTING_INCLUDED #define SPRITE_VERTEX_LIGHTING_INCLUDED #include "ShaderShared.cginc" #include "SpriteLighting.cginc" #include "SpriteSpecular.cginc" //////////////////////////////////////// // Defines // //Define to use spot lights (more expensive) #define SPOT_LIGHTS //Have to process lighting per pixel if using normal maps or a diffuse ramp or rim lighting or specular #if defined(_NORMALMAP) || defined(_DIFFUSE_RAMP) || defined(_RIM_LIGHTING) || defined(SPECULAR) #define PER_PIXEL_LIGHTING #endif //Turn off bump mapping and diffuse ramping on older shader models as they dont support needed number of outputs #if defined(PER_PIXEL_LIGHTING) && (SHADER_TARGET < 30) #undef PER_PIXEL_LIGHTING #undef _NORMALMAP #undef _DIFFUSE_RAMP #undef _RIM_LIGHTING #endif //In D3D9 only have a max of 9 TEXCOORD so can't have diffuse ramping or fog or rim lighting if processing lights per pixel #if defined(SHADER_API_D3D9) && defined(PER_PIXEL_LIGHTING) #if defined(_NORMALMAP) #undef _DIFFUSE_RAMP #undef _FOG #undef _RIM_LIGHTING #elif defined(_DIFFUSE_RAMP) #undef _FOG #undef _RIM_LIGHTING #elif defined(_RIM_LIGHTING) #undef _FOG #undef _DIFFUSE_RAMP #else #undef _DIFFUSE_RAMP #undef _RIM_LIGHTING #endif #endif #if defined(PER_PIXEL_LIGHTING) #if defined(_NORMALMAP) && defined(_DIFFUSE_RAMP) #define ATTENUATIONS TEXCOORD9 #if defined(_RIM_LIGHTING) #define _POS_WORLD_INDEX TEXCOORD10 #define _FOG_COORD_INDEX 11 #else #define _FOG_COORD_INDEX 10 #endif #elif defined(_NORMALMAP) != defined(_DIFFUSE_RAMP) #define ATTENUATIONS TEXCOORD8 #if defined(_RIM_LIGHTING) #define _POS_WORLD_INDEX TEXCOORD9 #define _FOG_COORD_INDEX 10 #else #define _FOG_COORD_INDEX 9 #endif #else //!_DIFFUSE_RAMP && !_NORMALMAP #if defined(_RIM_LIGHTING) #define _POS_WORLD_INDEX TEXCOORD8 #define _FOG_COORD_INDEX 9 #else #define _FOG_COORD_INDEX 8 #endif #endif #else //!PER_PIXEL_LIGHTING #define _FOG_COORD_INDEX 2 #endif //////////////////////////////////////// // Vertex output struct // struct VertexOutput { float4 pos : SV_POSITION; fixed4 color : COLOR; float3 texcoord : TEXCOORD0; #if defined(PER_PIXEL_LIGHTING) half4 VertexLightInfo0 : TEXCOORD1; half4 VertexLightInfo1 : TEXCOORD2; half4 VertexLightInfo2 : TEXCOORD3; half4 VertexLightInfo3 : TEXCOORD4; half4 VertexLightInfo4 : TEXCOORD5; #if defined(_NORMALMAP) half4 normalWorld : TEXCOORD6; half4 tangentWorld : TEXCOORD7; half4 binormalWorld : TEXCOORD8; #else half3 normalWorld : TEXCOORD6; half3 VertexLightInfo5 : TEXCOORD7; #endif #if defined(_DIFFUSE_RAMP) half4 LightAttenuations : ATTENUATIONS; #endif #if defined(_RIM_LIGHTING) float4 posWorld : _POS_WORLD_INDEX; #endif #else //!PER_PIXEL_LIGHTING half3 FullLighting : TEXCOORD1; #endif // !PER_PIXEL_LIGHTING #if defined(_FOG) UNITY_FOG_COORDS(_FOG_COORD_INDEX) #endif // _FOG UNITY_VERTEX_OUTPUT_STEREO }; //////////////////////////////////////// // Light calculations // struct VertexLightInfo { half3 lightDirection; fixed3 lightColor; #if defined(_DIFFUSE_RAMP) float attenuation; #endif // _DIFFUSE_RAMP }; inline VertexLightInfo getVertexLightAttenuatedInfo(int index, float3 viewPos) { VertexLightInfo lightInfo; //For directional lights unity_LightPosition.w is set to zero lightInfo.lightDirection = unity_LightPosition[index].xyz - viewPos.xyz * unity_LightPosition[index].w; float lengthSq = dot(lightInfo.lightDirection, lightInfo.lightDirection); // don't produce NaNs if some vertex position overlaps with the light lengthSq = max(lengthSq, 0.000001); lightInfo.lightDirection *= rsqrt(lengthSq); float attenuation = 1.0 / (1.0 + lengthSq * unity_LightAtten[index].z); #if defined(SPOT_LIGHTS) //Spot light attenuation - for non-spot lights unity_LightAtten.x is set to -1 and y is set to 1 { float rho = max (0, dot(lightInfo.lightDirection, unity_SpotDirection[index].xyz)); float spotAtt = (rho - unity_LightAtten[index].x) * unity_LightAtten[index].y; attenuation *= saturate(spotAtt); } #endif // SPOT_LIGHTS //If using a diffuse ramp texture then need to pass through the lights attenuation, otherwise premultiply the light color with it #if defined(_DIFFUSE_RAMP) lightInfo.lightColor = unity_LightColor[index].rgb; lightInfo.attenuation = attenuation; #else lightInfo.lightColor = unity_LightColor[index].rgb * attenuation; #endif // _DIFFUSE_RAMP return lightInfo; } //Magic constants used to tweak ambient to approximate pixel shader spherical harmonics static const fixed3 worldUp = fixed3(0, 1, 0); static const float skyGroundDotMul = 2.5; static const float minEquatorMix = 0.5; static const float equatorColorBlur = 0.33; fixed3 calculateAmbientLight(half3 normalWorld) { #if defined(_SPHERICAL_HARMONICS) float upDot = dot(normalWorld, worldUp); //Fade between a flat lerp from sky to ground and a 3 way lerp based on how bright the equator light is. //This simulates how directional lights get blurred using spherical harmonics //Work out color from ground and sky, ignoring equator float adjustedDot = upDot * skyGroundDotMul; fixed3 skyGroundColor = lerp(unity_AmbientGround, unity_AmbientSky, saturate((adjustedDot + 1.0) * 0.5)); //Work out equator lights brightness float equatorBright = saturate(dot(unity_AmbientEquator.rgb, unity_AmbientEquator.rgb)); //Blur equator color with sky and ground colors based on how bright it is. fixed3 equatorBlurredColor = lerp(unity_AmbientEquator, saturate(unity_AmbientEquator + unity_AmbientGround + unity_AmbientSky), equatorBright * equatorColorBlur); //Work out 3 way lerp inc equator light fixed3 equatorColor = lerp(equatorBlurredColor, unity_AmbientGround, -upDot) * step(upDot, 0) + lerp(equatorBlurredColor, unity_AmbientSky, upDot) * step(0, upDot); //Mix the two colors together based on how bright the equator light is return lerp(skyGroundColor, equatorColor, saturate(equatorBright + minEquatorMix)); #else // !_SPHERICAL_HARMONICS //Flat ambient is just the sky color return unity_AmbientSky.rgb; #endif // !_SPHERICAL_HARMONICS } //////////////////////////////////////// // Light Packing Functions // #if defined(_DIFFUSE_RAMP) inline fixed3 calculateLightDiffuse(fixed3 lightColor, half3 viewNormal, half3 lightViewDir, float attenuation) { float angleDot = max(0, dot(viewNormal, lightViewDir)); fixed3 lightDiffuse = calculateRampedDiffuse(lightColor, attenuation, angleDot); return lightDiffuse; } #else inline fixed3 calculateLightDiffuse(fixed3 attenuatedLightColor, half3 viewNormal, half3 lightViewDir) { float angleDot = max(0, dot(viewNormal, lightViewDir)); fixed3 lightDiffuse = attenuatedLightColor * angleDot; return lightDiffuse; } #endif // _NORMALMAP #if defined(PER_PIXEL_LIGHTING) #define VERTEX_LIGHT_0_DIR VertexLightInfo0.xyz #define VERTEX_LIGHT_0_R VertexLightInfo4.x #define VERTEX_LIGHT_0_G VertexLightInfo4.y #define VERTEX_LIGHT_0_B VertexLightInfo4.z #define VERTEX_LIGHT_1_DIR VertexLightInfo1.xyz #define VERTEX_LIGHT_1_R VertexLightInfo0.w #define VERTEX_LIGHT_1_G VertexLightInfo1.w #define VERTEX_LIGHT_1_B VertexLightInfo2.w #define VERTEX_LIGHT_2_DIR VertexLightInfo2.xyz #define VERTEX_LIGHT_2_R VertexLightInfo3.w #define VERTEX_LIGHT_2_G VertexLightInfo4.w #define VERTEX_LIGHT_2_B texcoord.z #define VERTEX_LIGHT_3_DIR VertexLightInfo3.xyz #if defined(_NORMALMAP) #define VERTEX_LIGHT_3_R normalWorld.w #define VERTEX_LIGHT_3_G tangentWorld.w #define VERTEX_LIGHT_3_B binormalWorld.w #else #define VERTEX_LIGHT_3_R VertexLightInfo5.x #define VERTEX_LIGHT_3_G VertexLightInfo5.y #define VERTEX_LIGHT_3_B VertexLightInfo5.z #endif #if defined(_DIFFUSE_RAMP) #define LIGHT_DIFFUSE_ATTEN_0 LightAttenuations.x #define LIGHT_DIFFUSE_ATTEN_1 LightAttenuations.y #define LIGHT_DIFFUSE_ATTEN_2 LightAttenuations.z #define LIGHT_DIFFUSE_ATTEN_3 LightAttenuations.w #define PACK_VERTEX_LIGHT_DIFFUSE(index, output, lightInfo) \ { \ output.LIGHT_DIFFUSE_ATTEN_##index = lightInfo.attenuation; \ } #define ADD_VERTEX_LIGHT_DIFFUSE(index, diffuse, input, lightColor, viewNormal, lightViewDir) \ { \ diffuse += calculateLightDiffuse(lightColor, viewNormal, lightViewDir, input.LIGHT_DIFFUSE_ATTEN_##index); \ } #else #define PACK_VERTEX_LIGHT_DIFFUSE(index, output, lightInfo) #define ADD_VERTEX_LIGHT_DIFFUSE(index, diffuse, input, lightColor, viewNormal, lightViewDir) \ { \ diffuse += calculateLightDiffuse(lightColor, viewNormal, lightViewDir); \ } #endif #define PACK_VERTEX_LIGHT(index, output, viewPos) \ { \ VertexLightInfo lightInfo = getVertexLightAttenuatedInfo(index, viewPos); \ output.VERTEX_LIGHT_##index##_DIR = lightInfo.lightDirection; \ output.VERTEX_LIGHT_##index##_R = lightInfo.lightColor.r; \ output.VERTEX_LIGHT_##index##_G = lightInfo.lightColor.g; \ output.VERTEX_LIGHT_##index##_B = lightInfo.lightColor.b; \ PACK_VERTEX_LIGHT_DIFFUSE(index, output, lightInfo); \ } #define ADD_VERTEX_LIGHT(index, input, viewNormal, diffuse) \ { \ half3 lightViewDir = input.VERTEX_LIGHT_##index##_DIR; \ fixed3 lightColor = fixed3(input.VERTEX_LIGHT_##index##_R, input.VERTEX_LIGHT_##index##_G, input.VERTEX_LIGHT_##index##_B); \ ADD_VERTEX_LIGHT_DIFFUSE(index, diffuse, input, lightColor, viewNormal, lightViewDir) \ } #if defined(SPECULAR) #define ADD_VERTEX_LIGHT_SPEC(index, input, viewNormal, specData, combinedLightData, indirectDiffuse, indirectSpecular) \ { \ half3 lightViewDir = input.VERTEX_LIGHT_##index##_DIR; \ fixed3 lightColor = fixed3(input.VERTEX_LIGHT_##index##_R, input.VERTEX_LIGHT_##index##_G, input.VERTEX_LIGHT_##index##_B); \ SpecularLightData lightData = calculatePhysicsBasedSpecularLight(specData.specColor, specData.oneMinusReflectivity, specData.smoothness, viewNormal, fixed3(0,0,1), lightViewDir, lightColor, indirectDiffuse, indirectSpecular); \ combinedLightData.lighting += lightData.lighting; \ combinedLightData.specular += lightData.specular; \ } #endif #else //!PER_PIXEL_LIGHTING //////////////////////////////////////// // Vertex Only Functions // inline fixed3 calculateLightDiffuse(int index, float3 viewPos, half3 viewNormal) { VertexLightInfo lightInfo = getVertexLightAttenuatedInfo(index, viewPos); float angleDot = max(0, dot(viewNormal, lightInfo.lightDirection)); return lightInfo.lightColor * angleDot; } #endif // !PER_PIXEL_LIGHTING //////////////////////////////////////// // Vertex program // VertexOutput vert(VertexInput input) { VertexOutput output; UNITY_SETUP_INSTANCE_ID(input); UNITY_INITIALIZE_VERTEX_OUTPUT_STEREO(output); output.pos = calculateLocalPos(input.vertex); output.color = calculateVertexColor(input.color); output.texcoord = float3(calculateTextureCoord(input.texcoord), 0); float3 viewPos = UnityObjectToViewPos(input.vertex); //float3 viewPos = mul(UNITY_MATRIX_MV, input.vertex); // #if defined(FIXED_NORMALS_BACKFACE_RENDERING) || defined(_RIM_LIGHTING) float4 powWorld = calculateWorldPos(input.vertex); #endif float backFaceSign = 1; #if defined(FIXED_NORMALS_BACKFACE_RENDERING) backFaceSign = calculateBackfacingSign(powWorld.xyz); #endif #if defined(PER_PIXEL_LIGHTING) #if defined(_RIM_LIGHTING) output.posWorld = powWorld; #endif PACK_VERTEX_LIGHT(0, output, viewPos) PACK_VERTEX_LIGHT(1, output, viewPos) PACK_VERTEX_LIGHT(2, output, viewPos) PACK_VERTEX_LIGHT(3, output, viewPos) output.normalWorld.xyz = calculateSpriteWorldNormal(input, backFaceSign); #if defined(_NORMALMAP) output.tangentWorld.xyz = calculateWorldTangent(input.tangent); output.binormalWorld.xyz = calculateSpriteWorldBinormal(input, output.normalWorld, output.tangentWorld, backFaceSign); #endif #else // !PER_PIXEL_LIGHTING //Just pack full lighting float3 viewNormal = calculateSpriteViewNormal(input, backFaceSign); //Get Ambient diffuse float3 normalWorld = calculateSpriteWorldNormal(input, backFaceSign); fixed3 ambient = calculateAmbientLight(normalWorld); fixed3 diffuse = calculateLightDiffuse(0, viewPos, viewNormal); diffuse += calculateLightDiffuse(1, viewPos, viewNormal); diffuse += calculateLightDiffuse(2, viewPos, viewNormal); diffuse += calculateLightDiffuse(3, viewPos, viewNormal); output.FullLighting = ambient + diffuse; #endif // !PER_PIXEL_LIGHTING #if defined(_FOG) UNITY_TRANSFER_FOG(output, output.pos); #endif // _FOG return output; } //////////////////////////////////////// // Fragment program // fixed4 frag(VertexOutput input) : SV_Target { fixed4 texureColor = calculateTexturePixel(input.texcoord.xy); RETURN_UNLIT_IF_ADDITIVE_SLOT(texureColor, input.color) // shall be called before ALPHA_CLIP ALPHA_CLIP(texureColor, input.color) #if defined(PER_PIXEL_LIGHTING) #if defined(_NORMALMAP) half3 normalWorld = calculateNormalFromBumpMap(input.texcoord.xy, input.tangentWorld.xyz, input.binormalWorld.xyz, input.normalWorld.xyz); #else half3 normalWorld = input.normalWorld.xyz; #endif //Get Ambient diffuse fixed3 ambient = calculateAmbientLight(normalWorld); half3 normalView = normalize(mul((float3x3)UNITY_MATRIX_V, normalWorld)); #if defined(SPECULAR) SpecularCommonData specData = getSpecularData(input.texcoord.xy, texureColor, input.color); SpecularLightData combinedLightData = (SpecularLightData)0; ADD_VERTEX_LIGHT_SPEC(0, input, normalView, specData, combinedLightData, ambient, unity_IndirectSpecColor.rgb) ADD_VERTEX_LIGHT_SPEC(1, input, normalView, specData, combinedLightData, fixed3(0,0,0), fixed3(0,0,0)) ADD_VERTEX_LIGHT_SPEC(2, input, normalView, specData, combinedLightData, fixed3(0,0,0), fixed3(0,0,0)) ADD_VERTEX_LIGHT_SPEC(3, input, normalView, specData, combinedLightData, fixed3(0,0,0), fixed3(0,0,0)) fixed4 pixel = calculateLitPixel(fixed4(specData.diffColor, specData.alpha), combinedLightData.lighting); pixel.rgb += combinedLightData.specular * specData.alpha; APPLY_EMISSION_SPECULAR(pixel, input.texcoord) #else //Find vertex light diffuse fixed3 diffuse = fixed3(0,0,0); //Add each vertex light to diffuse ADD_VERTEX_LIGHT(0, input, normalView, diffuse) ADD_VERTEX_LIGHT(1, input, normalView, diffuse) ADD_VERTEX_LIGHT(2, input, normalView, diffuse) ADD_VERTEX_LIGHT(3, input, normalView, diffuse) fixed3 lighting = ambient + diffuse; APPLY_EMISSION(lighting, input.texcoord.xy) fixed4 pixel = calculateLitPixel(texureColor, input.color, lighting); #endif #if defined(_RIM_LIGHTING) pixel.rgb = applyRimLighting(input.posWorld, normalWorld, pixel); #endif #else // !PER_PIXEL_LIGHTING APPLY_EMISSION(input.FullLighting, input.texcoord.xy) fixed4 pixel = calculateLitPixel(texureColor, input.color, input.FullLighting); #endif // !PER_PIXEL_LIGHTING COLORISE(pixel) APPLY_FOG(pixel, input) return pixel; } #endif // SPRITE_VERTEX_LIGHTING_INCLUDED