ToriaAssets/Sources/Shaders/AtgStandardBRDF.cginc

// Main Physically Based BRDF
// 


half4 BRDF1_ATG_PBS (half3 diffColor, half3 specColor, half oneMinusReflectivity, half smoothness,
    half3 normal, half3 viewDir,
    UnityLight light, UnityIndirect gi,
//  added:
    half specularIntensity)
{
    half perceptualRoughness = SmoothnessToPerceptualRoughness (smoothness);
    half3 halfDir = Unity_SafeNormalize (light.dir + viewDir);

// NdotV should not be negative for visible pixels, but it can happen due to perspective projection and normal mapping
// In this case normal should be modified to become valid (i.e facing camera) and not cause weird artifacts.
// but this operation adds few ALU and users may not want it. Alternative is to simply take the abs of NdotV (less correct but works too).
// Following define allow to control this. Set it to 0 if ALU is critical on your platform.
// This correction is interesting for GGX with SmithJoint visibility function because artifacts are more visible in this case due to highlight edge of rough surface
// Edit: Disable this code by default for now as it is not compatible with two sided lighting used in SpeedTree.

//	This will be defined by the Unity BRDF
// #define UNITY_HANDLE_CORRECTLY_NEGATIVE_NDOTV 0


#if UNITY_HANDLE_CORRECTLY_NEGATIVE_NDOTV
    // The amount we shift the normal toward the view vector is defined by the dot product.
    half shiftAmount = dot(normal, viewDir);
    normal = shiftAmount < 0.0f ? normal + viewDir * (-shiftAmount + 1e-5f) : normal;
    // A re-normalization should be applied here but as the shift is small we don't do it to save ALU.
    //normal = normalize(normal);

    half nv = saturate(dot(normal, viewDir)); // TODO: this saturate should no be necessary here
#else
    half nv = abs(dot(normal, viewDir));    // This abs allow to limit artifact
#endif

    half nl = saturate(dot(normal, light.dir));
    half nh = saturate(dot(normal, halfDir));

    half lv = saturate(dot(light.dir, viewDir));
    half lh = saturate(dot(light.dir, halfDir));

    // Diffuse term
    half diffuseTerm = DisneyDiffuse(nv, nl, lh, perceptualRoughness) * nl;

    // Specular term
    // HACK: theoretically we should divide diffuseTerm by Pi and not multiply specularTerm!
    // BUT 1) that will make shader look significantly darker than Legacy ones
    // and 2) on engine side "Non-important" lights have to be divided by Pi too in cases when they are injected into ambient SH
    half roughness = PerceptualRoughnessToRoughness(perceptualRoughness);
#if UNITY_BRDF_GGX
    half V = SmithJointGGXVisibilityTerm (nl, nv, roughness);
    half D = GGXTerm (nh, roughness);
#else
    // Legacy
    half V = SmithBeckmannVisibilityTerm (nl, nv, roughness);
    half D = NDFBlinnPhongNormalizedTerm (nh, PerceptualRoughnessToSpecPower(perceptualRoughness));
#endif

    half specularTerm = V*D * UNITY_PI; // Torrance-Sparrow model, Fresnel is applied later

#   ifdef UNITY_COLORSPACE_GAMMA
        specularTerm = sqrt(max(1e-4h, specularTerm));
#   endif

    // specularTerm * nl can be NaN on Metal in some cases, use max() to make sure it's a sane value
    specularTerm = max(0, specularTerm * nl);

    // surfaceReduction = Int D(NdotH) * NdotH * Id(NdotL>0) dH = 1/(roughness^2+1)
    half surfaceReduction;
#   ifdef UNITY_COLORSPACE_GAMMA
        surfaceReduction = 1.0-0.28*roughness*perceptualRoughness;      // 1-0.28*x^3 as approximation for (1/(x^4+1))^(1/2.2) on the domain [0;1]
#   else
        surfaceReduction = 1.0 / (roughness*roughness + 1.0);           // fade \in [0.5;1]
#   endif

    // To provide true Lambert lighting, we need to be able to kill specular completely.
	specularTerm *= any(specColor) ? 1.0 : 0.0;

//  Grass
	half3 specular = specularTerm * FresnelTerm(specColor, lh)   *	  specularIntensity;

    half grazingTerm = saturate(smoothness + (1-oneMinusReflectivity));
    half3 color =   diffColor * (gi.diffuse + light.color * diffuseTerm)
                    + specular * light.color //* FresnelTerm (specColor, lh)
                    + surfaceReduction * gi.specular * FresnelLerp (specColor, grazingTerm, nv);
    return half4(color, specular.r /*1*/);
}
Add shaders 2026-05-19 12:20:15 +02:00			`// Main Physically Based BRDF`
			`//`


			`half4 BRDF1_ATG_PBS (half3 diffColor, half3 specColor, half oneMinusReflectivity, half smoothness,`
			`half3 normal, half3 viewDir,`
			`UnityLight light, UnityIndirect gi,`
			`// added:`
			`half specularIntensity)`
			`{`
			`half perceptualRoughness = SmoothnessToPerceptualRoughness (smoothness);`
			`half3 halfDir = Unity_SafeNormalize (light.dir + viewDir);`

			`// NdotV should not be negative for visible pixels, but it can happen due to perspective projection and normal mapping`
			`// In this case normal should be modified to become valid (i.e facing camera) and not cause weird artifacts.`
			`// but this operation adds few ALU and users may not want it. Alternative is to simply take the abs of NdotV (less correct but works too).`
			`// Following define allow to control this. Set it to 0 if ALU is critical on your platform.`
			`// This correction is interesting for GGX with SmithJoint visibility function because artifacts are more visible in this case due to highlight edge of rough surface`
			`// Edit: Disable this code by default for now as it is not compatible with two sided lighting used in SpeedTree.`

			`// This will be defined by the Unity BRDF`
			`// #define UNITY_HANDLE_CORRECTLY_NEGATIVE_NDOTV 0`


			`#if UNITY_HANDLE_CORRECTLY_NEGATIVE_NDOTV`
			`// The amount we shift the normal toward the view vector is defined by the dot product.`
			`half shiftAmount = dot(normal, viewDir);`
			`normal = shiftAmount < 0.0f ? normal + viewDir * (-shiftAmount + 1e-5f) : normal;`
			`// A re-normalization should be applied here but as the shift is small we don't do it to save ALU.`
			`//normal = normalize(normal);`

			`half nv = saturate(dot(normal, viewDir)); // TODO: this saturate should no be necessary here`
			`#else`
			`half nv = abs(dot(normal, viewDir)); // This abs allow to limit artifact`
			`#endif`

			`half nl = saturate(dot(normal, light.dir));`
			`half nh = saturate(dot(normal, halfDir));`

			`half lv = saturate(dot(light.dir, viewDir));`
			`half lh = saturate(dot(light.dir, halfDir));`

			`// Diffuse term`
			`half diffuseTerm = DisneyDiffuse(nv, nl, lh, perceptualRoughness) * nl;`

			`// Specular term`
			`// HACK: theoretically we should divide diffuseTerm by Pi and not multiply specularTerm!`
			`// BUT 1) that will make shader look significantly darker than Legacy ones`
			`// and 2) on engine side "Non-important" lights have to be divided by Pi too in cases when they are injected into ambient SH`
			`half roughness = PerceptualRoughnessToRoughness(perceptualRoughness);`
			`#if UNITY_BRDF_GGX`
			`half V = SmithJointGGXVisibilityTerm (nl, nv, roughness);`
			`half D = GGXTerm (nh, roughness);`
			`#else`
			`// Legacy`
			`half V = SmithBeckmannVisibilityTerm (nl, nv, roughness);`
			`half D = NDFBlinnPhongNormalizedTerm (nh, PerceptualRoughnessToSpecPower(perceptualRoughness));`
			`#endif`

			`half specularTerm = VD UNITY_PI; // Torrance-Sparrow model, Fresnel is applied later`

			`# ifdef UNITY_COLORSPACE_GAMMA`
			`specularTerm = sqrt(max(1e-4h, specularTerm));`
			`# endif`

			`// specularTerm * nl can be NaN on Metal in some cases, use max() to make sure it's a sane value`
			`specularTerm = max(0, specularTerm * nl);`

			`// surfaceReduction = Int D(NdotH) * NdotH * Id(NdotL>0) dH = 1/(roughness^2+1)`
			`half surfaceReduction;`
			`# ifdef UNITY_COLORSPACE_GAMMA`
			`surfaceReduction = 1.0-0.28roughnessperceptualRoughness; // 1-0.28*x^3 as approximation for (1/(x^4+1))^(1/2.2) on the domain [0;1]`
			`# else`
			`surfaceReduction = 1.0 / (roughness*roughness + 1.0); // fade \in [0.5;1]`
			`# endif`

			`// To provide true Lambert lighting, we need to be able to kill specular completely.`
			`specularTerm *= any(specColor) ? 1.0 : 0.0;`

			`// Grass`
			`half3 specular = specularTerm * FresnelTerm(specColor, lh) * specularIntensity;`

			`half grazingTerm = saturate(smoothness + (1-oneMinusReflectivity));`
			`half3 color = diffColor * (gi.diffuse + light.color * diffuseTerm)`
			`+ specular * light.color //* FresnelTerm (specColor, lh)`
			`+ surfaceReduction * gi.specular * FresnelLerp (specColor, grazingTerm, nv);`
			`return half4(color, specular.r /1/);`
			`}`