XCEngine/engine/assets/builtin/shaders/forward-lit.shader

Shader "Builtin Forward Lit"
{
    Properties
    {
        _BaseColor ("Base Color", Color) = (1,1,1,1) [Semantic(BaseColor)]
        _Cutoff ("Alpha Cutoff", Range) = 0.5 [Semantic(AlphaCutoff)]
        _MainTex ("Base Map", 2D) = "white" [Semantic(BaseColorTexture)]
    }
    HLSLINCLUDE
    cbuffer PerObjectConstants
    {
        float4x4 gProjectionMatrix;
        float4x4 gViewMatrix;
        float4x4 gModelMatrix;
        float4x4 gNormalMatrix;
    };

    static const int XC_MAX_ADDITIONAL_LIGHTS = 8;

    struct AdditionalLightData
    {
        float4 colorAndIntensity;
        float4 positionAndRange;
        float4 directionAndType;
        float4 spotAnglesAndFlags;
    };

    cbuffer LightingConstants
    {
        float4 gMainLightDirectionAndIntensity;
        float4 gMainLightColorAndFlags;
        float4 gLightingParams;
        AdditionalLightData gAdditionalLights[XC_MAX_ADDITIONAL_LIGHTS];
    };

    cbuffer MaterialConstants
    {
        float4 gBaseColorFactor;
        float4 gAlphaCutoffParams;
    };

    cbuffer ShadowReceiverConstants
    {
        float4x4 gWorldToShadowMatrix;
        float4 gShadowBiasAndTexelSize;
        float4 gShadowOptions;
    };

    Texture2D BaseColorTexture;
    SamplerState LinearClampSampler;
    Texture2D ShadowMapTexture;
    SamplerState ShadowMapSampler;

    struct VSInput
    {
        float3 position : POSITION;
        float3 normal : NORMAL;
        float2 texcoord : TEXCOORD0;
    };

    struct PSInput
    {
        float4 position : SV_POSITION;
        float3 normalWS : TEXCOORD0;
        float2 texcoord : TEXCOORD1;
        float3 positionWS : TEXCOORD2;
    };

    PSInput MainVS(VSInput input)
    {
        PSInput output;
        const float4 positionWS = mul(gModelMatrix, float4(input.position, 1.0f));
        const float4 positionVS = mul(gViewMatrix, positionWS);
        output.position = mul(gProjectionMatrix, positionVS);
        output.normalWS = mul((float3x3)gNormalMatrix, input.normal);
        output.texcoord = input.texcoord;
        output.positionWS = positionWS.xyz;
        return output;
    }

    float ComputeShadowAttenuation(float3 positionWS)
    {
    #ifndef XC_MAIN_LIGHT_SHADOWS
        return 1.0f;
    #else
        if (gShadowOptions.x < 0.5f) {
            return 1.0f;
        }

        const float4 shadowClip = mul(gWorldToShadowMatrix, float4(positionWS, 1.0f));
        if (shadowClip.w <= 0.0f) {
            return 1.0f;
        }

        const float3 shadowNdc = shadowClip.xyz / shadowClip.w;
    #if UNITY_UV_STARTS_AT_TOP
        const float shadowUvY = shadowNdc.y * -0.5f + 0.5f;
    #else
        const float shadowUvY = shadowNdc.y * 0.5f + 0.5f;
    #endif
        const float2 shadowUv = float2(shadowNdc.x * 0.5f + 0.5f, shadowUvY);
    #if UNITY_NEAR_CLIP_VALUE < 0
        if (shadowUv.x < 0.0f || shadowUv.x > 1.0f ||
            shadowUv.y < 0.0f || shadowUv.y > 1.0f ||
            shadowNdc.z < -1.0f || shadowNdc.z > 1.0f) {
            return 1.0f;
        }

        const float receiverDepth = shadowNdc.z * 0.5f + 0.5f - gShadowBiasAndTexelSize.x;
    #else
        if (shadowUv.x < 0.0f || shadowUv.x > 1.0f ||
            shadowUv.y < 0.0f || shadowUv.y > 1.0f ||
            shadowNdc.z < 0.0f || shadowNdc.z > 1.0f) {
            return 1.0f;
        }

        const float receiverDepth = shadowNdc.z - gShadowBiasAndTexelSize.x;
    #endif
        const float shadowDepth = ShadowMapTexture.Sample(ShadowMapSampler, shadowUv).r;
        const float shadowStrength = saturate(gShadowBiasAndTexelSize.w);
        return receiverDepth <= shadowDepth ? 1.0f : (1.0f - shadowStrength);
    #endif
    }

    float ComputeRangeAttenuation(float distanceSq, float range)
    {
        if (range <= 0.0f) {
            return 0.0f;
        }

        const float clampedRange = max(range, 0.0001f);
        const float rangeSq = clampedRange * clampedRange;
        if (distanceSq >= rangeSq) {
            return 0.0f;
        }

        const float distance = sqrt(max(distanceSq, 0.0f));
        const float normalized = saturate(1.0f - distance / clampedRange);
        return normalized * normalized;
    }

    float ComputeSpotAttenuation(AdditionalLightData light, float3 directionToLightWS)
    {
        const float cosOuter = light.spotAnglesAndFlags.x;
        const float cosInner = light.spotAnglesAndFlags.y;
        const float3 spotAxisToLightWS = normalize(light.directionAndType.xyz);
        const float cosTheta = dot(spotAxisToLightWS, directionToLightWS);
        return saturate((cosTheta - cosOuter) / max(cosInner - cosOuter, 1e-4f));
    }

    float3 EvaluateAdditionalLight(AdditionalLightData light, float3 normalWS, float3 positionWS)
    {
        const float lightType = light.directionAndType.w;
        const float3 lightColor = light.colorAndIntensity.rgb;
        const float lightIntensity = light.colorAndIntensity.w;

        float3 directionToLightWS = float3(0.0f, 0.0f, 0.0f);
        float attenuation = 1.0f;

        if (lightType < 0.5f) {
            directionToLightWS = normalize(light.directionAndType.xyz);
        } else {
            const float3 lightVectorWS = light.positionAndRange.xyz - positionWS;
            const float distanceSq = dot(lightVectorWS, lightVectorWS);
            if (distanceSq <= 1e-6f) {
                return 0.0f.xxx;
            }

            directionToLightWS = lightVectorWS * rsqrt(distanceSq);
            attenuation = ComputeRangeAttenuation(distanceSq, light.positionAndRange.w);
            if (attenuation <= 0.0f) {
                return 0.0f.xxx;
            }

            if (lightType > 1.5f) {
                attenuation *= ComputeSpotAttenuation(light, directionToLightWS);
                if (attenuation <= 0.0f) {
                    return 0.0f.xxx;
                }
            }
        }

        const float diffuse = saturate(dot(normalWS, directionToLightWS));
        if (diffuse <= 0.0f) {
            return 0.0f.xxx;
        }

        return lightColor * (diffuse * lightIntensity * attenuation);
    }

    float4 MainPS(PSInput input) : SV_TARGET
    {
        float4 baseColor = BaseColorTexture.Sample(LinearClampSampler, input.texcoord) * gBaseColorFactor;
    #ifdef XC_ALPHA_TEST
        clip(baseColor.a - gAlphaCutoffParams.x);
    #endif

        const int additionalLightCount = min((int)gLightingParams.x, XC_MAX_ADDITIONAL_LIGHTS);
        if (gMainLightColorAndFlags.a < 0.5f && additionalLightCount == 0) {
            return baseColor;
        }

        const float3 normalWS = normalize(input.normalWS);
        float3 lighting = gLightingParams.yyy;

        if (gMainLightColorAndFlags.a >= 0.5f) {
            const float3 directionToLightWS = normalize(gMainLightDirectionAndIntensity.xyz);
            const float diffuse = saturate(dot(normalWS, directionToLightWS));
            const float shadowAttenuation =
                diffuse > 0.0f ? ComputeShadowAttenuation(input.positionWS) : 1.0f;
            lighting +=
                gMainLightColorAndFlags.rgb *
                (diffuse * gMainLightDirectionAndIntensity.w * shadowAttenuation);
        }

        [unroll]
        for (int lightIndex = 0; lightIndex < XC_MAX_ADDITIONAL_LIGHTS; ++lightIndex) {
            if (lightIndex >= additionalLightCount) {
                break;
            }

            lighting += EvaluateAdditionalLight(gAdditionalLights[lightIndex], normalWS, input.positionWS);
        }

        return float4(baseColor.rgb * lighting, baseColor.a);
    }
    ENDHLSL
    SubShader
    {
        Cull Back
        ZWrite On
        ZTest LEqual
        Pass
        {
            Name "ForwardLit"
            Tags { "LightMode" = "ForwardLit" }
            HLSLPROGRAM
            #pragma target 4.5
            #pragma vertex MainVS
            #pragma fragment MainPS
            #pragma multi_compile _ XC_MAIN_LIGHT_SHADOWS
            #pragma shader_feature_local _ XC_ALPHA_TEST
            ENDHLSL
        }
    }
}