Rasagar/Library/PackageCache/com.unity.render-pipelines.universal/ShaderLibrary/RealtimeLights.hlsl


#ifndef UNIVERSAL_REALTIME_LIGHTS_INCLUDED
#define UNIVERSAL_REALTIME_LIGHTS_INCLUDED

#include "Packages/com.unity.render-pipelines.universal/ShaderLibrary/AmbientOcclusion.hlsl"
#include "Packages/com.unity.render-pipelines.universal/ShaderLibrary/Input.hlsl"
#include "Packages/com.unity.render-pipelines.universal/ShaderLibrary/Shadows.hlsl"
#include "Packages/com.unity.render-pipelines.universal/ShaderLibrary/LightCookie/LightCookie.hlsl"
#include "Packages/com.unity.render-pipelines.universal/ShaderLibrary/Clustering.hlsl"

// Abstraction over Light shading data.
struct Light
{
    half3   direction;
    half3   color;
    float   distanceAttenuation; // full-float precision required on some platforms
    half    shadowAttenuation;
    uint    layerMask;
};

#if USE_FORWARD_PLUS && defined(LIGHTMAP_ON) && defined(LIGHTMAP_SHADOW_MIXING)
#define FORWARD_PLUS_SUBTRACTIVE_LIGHT_CHECK if (_AdditionalLightsColor[lightIndex].a > 0.0h) continue;
#else
#define FORWARD_PLUS_SUBTRACTIVE_LIGHT_CHECK
#endif

#if USE_FORWARD_PLUS
    #define LIGHT_LOOP_BEGIN(lightCount) { \
    uint lightIndex; \
    ClusterIterator _urp_internal_clusterIterator = ClusterInit(inputData.normalizedScreenSpaceUV, inputData.positionWS, 0); \
    [loop] while (ClusterNext(_urp_internal_clusterIterator, lightIndex)) { \
        lightIndex += URP_FP_DIRECTIONAL_LIGHTS_COUNT; \
        FORWARD_PLUS_SUBTRACTIVE_LIGHT_CHECK
    #define LIGHT_LOOP_END } }
#else
    #define LIGHT_LOOP_BEGIN(lightCount) \
    for (uint lightIndex = 0u; lightIndex < lightCount; ++lightIndex) {
    #define LIGHT_LOOP_END }
#endif

///////////////////////////////////////////////////////////////////////////////
//                        Attenuation Functions                               /
///////////////////////////////////////////////////////////////////////////////

// Matches Unity Vanilla HINT_NICE_QUALITY attenuation
// Attenuation smoothly decreases to light range.
float DistanceAttenuation(float distanceSqr, half2 distanceAttenuation)
{
    // We use a shared distance attenuation for additional directional and puctual lights
    // for directional lights attenuation will be 1
    float lightAtten = rcp(distanceSqr);
    float2 distanceAttenuationFloat = float2(distanceAttenuation);

    // Use the smoothing factor also used in the Unity lightmapper.
    half factor = half(distanceSqr * distanceAttenuationFloat.x);
    half smoothFactor = saturate(half(1.0) - factor * factor);
    smoothFactor = smoothFactor * smoothFactor;

    return lightAtten * smoothFactor;
}

half AngleAttenuation(half3 spotDirection, half3 lightDirection, half2 spotAttenuation)
{
    // Spot Attenuation with a linear falloff can be defined as
    // (SdotL - cosOuterAngle) / (cosInnerAngle - cosOuterAngle)
    // This can be rewritten as
    // invAngleRange = 1.0 / (cosInnerAngle - cosOuterAngle)
    // SdotL * invAngleRange + (-cosOuterAngle * invAngleRange)
    // SdotL * spotAttenuation.x + spotAttenuation.y

    // If we precompute the terms in a MAD instruction
    half SdotL = dot(spotDirection, lightDirection);
    half atten = saturate(SdotL * spotAttenuation.x + spotAttenuation.y);
    return atten * atten;
}

///////////////////////////////////////////////////////////////////////////////
//                      Light Abstraction                                    //
///////////////////////////////////////////////////////////////////////////////

Light GetMainLight()
{
    Light light;
    light.direction = half3(_MainLightPosition.xyz);
#if USE_FORWARD_PLUS
#if defined(LIGHTMAP_ON) && defined(LIGHTMAP_SHADOW_MIXING)
    light.distanceAttenuation = _MainLightColor.a;
#else
    light.distanceAttenuation = 1.0;
#endif
#else
    light.distanceAttenuation = unity_LightData.z; // unity_LightData.z is 1 when not culled by the culling mask, otherwise 0.
#endif
    light.shadowAttenuation = 1.0;
    light.color = _MainLightColor.rgb;

    light.layerMask = _MainLightLayerMask;

    return light;
}

Light GetMainLight(float4 shadowCoord)
{
    Light light = GetMainLight();
    light.shadowAttenuation = MainLightRealtimeShadow(shadowCoord);
    return light;
}

Light GetMainLight(float4 shadowCoord, float3 positionWS, half4 shadowMask)
{
    Light light = GetMainLight();
    light.shadowAttenuation = MainLightShadow(shadowCoord, positionWS, shadowMask, _MainLightOcclusionProbes);

    #if defined(_LIGHT_COOKIES)
        real3 cookieColor = SampleMainLightCookie(positionWS);
        light.color *= cookieColor;
    #endif

    return light;
}

Light GetMainLight(InputData inputData, half4 shadowMask, AmbientOcclusionFactor aoFactor)
{
    Light light = GetMainLight(inputData.shadowCoord, inputData.positionWS, shadowMask);

    #if defined(_SCREEN_SPACE_OCCLUSION) && !defined(_SURFACE_TYPE_TRANSPARENT)
    if (IsLightingFeatureEnabled(DEBUGLIGHTINGFEATUREFLAGS_AMBIENT_OCCLUSION))
    {
        light.color *= aoFactor.directAmbientOcclusion;
    }
    #endif

    return light;
}

// Fills a light struct given a perObjectLightIndex
Light GetAdditionalPerObjectLight(int perObjectLightIndex, float3 positionWS)
{
    // Abstraction over Light input constants
#if USE_STRUCTURED_BUFFER_FOR_LIGHT_DATA
    float4 lightPositionWS = _AdditionalLightsBuffer[perObjectLightIndex].position;
    half3 color = _AdditionalLightsBuffer[perObjectLightIndex].color.rgb;
    half4 distanceAndSpotAttenuation = _AdditionalLightsBuffer[perObjectLightIndex].attenuation;
    half4 spotDirection = _AdditionalLightsBuffer[perObjectLightIndex].spotDirection;
    uint lightLayerMask = _AdditionalLightsBuffer[perObjectLightIndex].layerMask;
#else
    float4 lightPositionWS = _AdditionalLightsPosition[perObjectLightIndex];
    half3 color = _AdditionalLightsColor[perObjectLightIndex].rgb;
    half4 distanceAndSpotAttenuation = _AdditionalLightsAttenuation[perObjectLightIndex];
    half4 spotDirection = _AdditionalLightsSpotDir[perObjectLightIndex];
    uint lightLayerMask = asuint(_AdditionalLightsLayerMasks[perObjectLightIndex]);
#endif

    // Directional lights store direction in lightPosition.xyz and have .w set to 0.0.
    // This way the following code will work for both directional and punctual lights.
    float3 lightVector = lightPositionWS.xyz - positionWS * lightPositionWS.w;
    float distanceSqr = max(dot(lightVector, lightVector), HALF_MIN);

    half3 lightDirection = half3(lightVector * rsqrt(distanceSqr));
    // full-float precision required on some platforms
    float attenuation = DistanceAttenuation(distanceSqr, distanceAndSpotAttenuation.xy) * AngleAttenuation(spotDirection.xyz, lightDirection, distanceAndSpotAttenuation.zw);

    Light light;
    light.direction = lightDirection;
    light.distanceAttenuation = attenuation;
    light.shadowAttenuation = 1.0; // This value can later be overridden in GetAdditionalLight(uint i, float3 positionWS, half4 shadowMask)
    light.color = color;
    light.layerMask = lightLayerMask;

    return light;
}

uint GetPerObjectLightIndexOffset()
{
#if USE_STRUCTURED_BUFFER_FOR_LIGHT_DATA
    return uint(unity_LightData.x);
#else
    return 0;
#endif
}

// Returns a per-object index given a loop index.
// This abstract the underlying data implementation for storing lights/light indices
int GetPerObjectLightIndex(uint index)
{
/////////////////////////////////////////////////////////////////////////////////////////////
// Structured Buffer Path                                                                   /
//                                                                                          /
// Lights and light indices are stored in StructuredBuffer. We can just index them.         /
// Currently all non-mobile platforms take this path :(                                     /
// There are limitation in mobile GPUs to use SSBO (performance / no vertex shader support) /
/////////////////////////////////////////////////////////////////////////////////////////////
#if USE_STRUCTURED_BUFFER_FOR_LIGHT_DATA
    uint offset = uint(unity_LightData.x);
    return _AdditionalLightsIndices[offset + index];

/////////////////////////////////////////////////////////////////////////////////////////////
// UBO path                                                                                 /
//                                                                                          /
// We store 8 light indices in half4 unity_LightIndices[2];                                 /
// Due to memory alignment unity doesn't support int[] or float[]                           /
// Even trying to reinterpret cast the unity_LightIndices to float[] won't work             /
// it will cast to float4[] and create extra register pressure. :(                          /
/////////////////////////////////////////////////////////////////////////////////////////////
#else
    // since index is uint shader compiler will implement
    // div & mod as bitfield ops (shift and mask).

    // TODO: Can we index a float4? Currently compiler is
    // replacing unity_LightIndicesX[i] with a dp4 with identity matrix.
    // u_xlat16_40 = dot(unity_LightIndices[int(u_xlatu13)], ImmCB_0_0_0[u_xlati1]);
    // This increases both arithmetic and register pressure.
    //
    // NOTE: min16float4 bug workaround.
    // Take the "vec4" part into float4 tmp variable in order to force float4 math.
    // It appears indexing half4 as min16float4 on DX11 can fail. (dp4 {min16f})
    float4 tmp = unity_LightIndices[index / 4];
    return int(tmp[index % 4]);
#endif
}

// Fills a light struct given a loop i index. This will convert the i
// index to a perObjectLightIndex
Light GetAdditionalLight(uint i, float3 positionWS)
{
#if USE_FORWARD_PLUS
    int lightIndex = i;
#else
    int lightIndex = GetPerObjectLightIndex(i);
#endif
    return GetAdditionalPerObjectLight(lightIndex, positionWS);
}

Light GetAdditionalLight(uint i, float3 positionWS, half4 shadowMask)
{
#if USE_FORWARD_PLUS
    int lightIndex = i;
#else
    int lightIndex = GetPerObjectLightIndex(i);
#endif
    Light light = GetAdditionalPerObjectLight(lightIndex, positionWS);

#if USE_STRUCTURED_BUFFER_FOR_LIGHT_DATA
    half4 occlusionProbeChannels = _AdditionalLightsBuffer[lightIndex].occlusionProbeChannels;
#else
    half4 occlusionProbeChannels = _AdditionalLightsOcclusionProbes[lightIndex];
#endif
    light.shadowAttenuation = AdditionalLightShadow(lightIndex, positionWS, light.direction, shadowMask, occlusionProbeChannels);
#if defined(_LIGHT_COOKIES)
    real3 cookieColor = SampleAdditionalLightCookie(lightIndex, positionWS);
    light.color *= cookieColor;
#endif

    return light;
}

Light GetAdditionalLight(uint i, InputData inputData, half4 shadowMask, AmbientOcclusionFactor aoFactor)
{
    Light light = GetAdditionalLight(i, inputData.positionWS, shadowMask);

    #if defined(_SCREEN_SPACE_OCCLUSION) && !defined(_SURFACE_TYPE_TRANSPARENT)
    if (IsLightingFeatureEnabled(DEBUGLIGHTINGFEATUREFLAGS_AMBIENT_OCCLUSION))
    {
        light.color *= aoFactor.directAmbientOcclusion;
    }
    #endif

    return light;
}

int GetAdditionalLightsCount()
{
#if USE_FORWARD_PLUS
    // Counting the number of lights in clustered requires traversing the bit list, and is not needed up front.
    return 0;
#else
    // TODO: we need to expose in SRP api an ability for the pipeline cap the amount of lights
    // in the culling. This way we could do the loop branch with an uniform
    // This would be helpful to support baking exceeding lights in SH as well
    return int(min(_AdditionalLightsCount.x, unity_LightData.y));
#endif
}

half4 CalculateShadowMask(InputData inputData)
{
    // To ensure backward compatibility we have to avoid using shadowMask input, as it is not present in older shaders
    #if defined(SHADOWS_SHADOWMASK) && defined(LIGHTMAP_ON)
    half4 shadowMask = inputData.shadowMask; // Shadowmask was sampled from lightmap
    #elif !defined(LIGHTMAP_ON) && (defined(PROBE_VOLUMES_L1) || defined(PROBE_VOLUMES_L2))
    half4 shadowMask = inputData.shadowMask; // Shadowmask (probe occlusion) was sampled from APV
    #elif !defined (LIGHTMAP_ON)
    half4 shadowMask = unity_ProbesOcclusion; // Sample shadowmask (probe occlusion) from legacy probes
    #else
    half4 shadowMask = half4(1, 1, 1, 1); // Fallback shadowmask, fully unoccluded
    #endif

    return shadowMask;
}

#endif
deneme 2024-08-26 13:07:20 -07:00
			`#ifndef UNIVERSAL_REALTIME_LIGHTS_INCLUDED`
			`#define UNIVERSAL_REALTIME_LIGHTS_INCLUDED`

			`#include "Packages/com.unity.render-pipelines.universal/ShaderLibrary/AmbientOcclusion.hlsl"`
			`#include "Packages/com.unity.render-pipelines.universal/ShaderLibrary/Input.hlsl"`
			`#include "Packages/com.unity.render-pipelines.universal/ShaderLibrary/Shadows.hlsl"`
			`#include "Packages/com.unity.render-pipelines.universal/ShaderLibrary/LightCookie/LightCookie.hlsl"`
			`#include "Packages/com.unity.render-pipelines.universal/ShaderLibrary/Clustering.hlsl"`

			`// Abstraction over Light shading data.`
			`struct Light`
			`{`
			`half3 direction;`
			`half3 color;`
			`float distanceAttenuation; // full-float precision required on some platforms`
			`half shadowAttenuation;`
			`uint layerMask;`
			`};`

			`#if USE_FORWARD_PLUS && defined(LIGHTMAP_ON) && defined(LIGHTMAP_SHADOW_MIXING)`
			`#define FORWARD_PLUS_SUBTRACTIVE_LIGHT_CHECK if (_AdditionalLightsColor[lightIndex].a > 0.0h) continue;`
			`#else`
			`#define FORWARD_PLUS_SUBTRACTIVE_LIGHT_CHECK`
			`#endif`

			`#if USE_FORWARD_PLUS`
			`#define LIGHT_LOOP_BEGIN(lightCount) { \`
			`uint lightIndex; \`
			`ClusterIterator _urp_internal_clusterIterator = ClusterInit(inputData.normalizedScreenSpaceUV, inputData.positionWS, 0); \`
			`[loop] while (ClusterNext(_urp_internal_clusterIterator, lightIndex)) { \`
			`lightIndex += URP_FP_DIRECTIONAL_LIGHTS_COUNT; \`
			`FORWARD_PLUS_SUBTRACTIVE_LIGHT_CHECK`
			`#define LIGHT_LOOP_END } }`
			`#else`
			`#define LIGHT_LOOP_BEGIN(lightCount) \`
			`for (uint lightIndex = 0u; lightIndex < lightCount; ++lightIndex) {`
			`#define LIGHT_LOOP_END }`
			`#endif`

			`///////////////////////////////////////////////////////////////////////////////`
			`// Attenuation Functions /`
			`///////////////////////////////////////////////////////////////////////////////`

			`// Matches Unity Vanilla HINT_NICE_QUALITY attenuation`
			`// Attenuation smoothly decreases to light range.`
			`float DistanceAttenuation(float distanceSqr, half2 distanceAttenuation)`
			`{`
			`// We use a shared distance attenuation for additional directional and puctual lights`
			`// for directional lights attenuation will be 1`
			`float lightAtten = rcp(distanceSqr);`
			`float2 distanceAttenuationFloat = float2(distanceAttenuation);`

			`// Use the smoothing factor also used in the Unity lightmapper.`
			`half factor = half(distanceSqr * distanceAttenuationFloat.x);`
			`half smoothFactor = saturate(half(1.0) - factor * factor);`
			`smoothFactor = smoothFactor * smoothFactor;`

			`return lightAtten * smoothFactor;`
			`}`

			`half AngleAttenuation(half3 spotDirection, half3 lightDirection, half2 spotAttenuation)`
			`{`
			`// Spot Attenuation with a linear falloff can be defined as`
			`// (SdotL - cosOuterAngle) / (cosInnerAngle - cosOuterAngle)`
			`// This can be rewritten as`
			`// invAngleRange = 1.0 / (cosInnerAngle - cosOuterAngle)`
			`// SdotL * invAngleRange + (-cosOuterAngle * invAngleRange)`
			`// SdotL * spotAttenuation.x + spotAttenuation.y`

			`// If we precompute the terms in a MAD instruction`
			`half SdotL = dot(spotDirection, lightDirection);`
			`half atten = saturate(SdotL * spotAttenuation.x + spotAttenuation.y);`
			`return atten * atten;`
			`}`

			`///////////////////////////////////////////////////////////////////////////////`
			`// Light Abstraction //`
			`///////////////////////////////////////////////////////////////////////////////`

			`Light GetMainLight()`
			`{`
			`Light light;`
			`light.direction = half3(_MainLightPosition.xyz);`
			`#if USE_FORWARD_PLUS`
			`#if defined(LIGHTMAP_ON) && defined(LIGHTMAP_SHADOW_MIXING)`
			`light.distanceAttenuation = _MainLightColor.a;`
			`#else`
			`light.distanceAttenuation = 1.0;`
			`#endif`
			`#else`
			`light.distanceAttenuation = unity_LightData.z; // unity_LightData.z is 1 when not culled by the culling mask, otherwise 0.`
			`#endif`
			`light.shadowAttenuation = 1.0;`
			`light.color = _MainLightColor.rgb;`

			`light.layerMask = _MainLightLayerMask;`

			`return light;`
			`}`

			`Light GetMainLight(float4 shadowCoord)`
			`{`
			`Light light = GetMainLight();`
			`light.shadowAttenuation = MainLightRealtimeShadow(shadowCoord);`
			`return light;`
			`}`

			`Light GetMainLight(float4 shadowCoord, float3 positionWS, half4 shadowMask)`
			`{`
			`Light light = GetMainLight();`
			`light.shadowAttenuation = MainLightShadow(shadowCoord, positionWS, shadowMask, _MainLightOcclusionProbes);`

			`#if defined(_LIGHT_COOKIES)`
			`real3 cookieColor = SampleMainLightCookie(positionWS);`
			`light.color *= cookieColor;`
			`#endif`

			`return light;`
			`}`

			`Light GetMainLight(InputData inputData, half4 shadowMask, AmbientOcclusionFactor aoFactor)`
			`{`
			`Light light = GetMainLight(inputData.shadowCoord, inputData.positionWS, shadowMask);`

			`#if defined(_SCREEN_SPACE_OCCLUSION) && !defined(_SURFACE_TYPE_TRANSPARENT)`
			`if (IsLightingFeatureEnabled(DEBUGLIGHTINGFEATUREFLAGS_AMBIENT_OCCLUSION))`
			`{`
			`light.color *= aoFactor.directAmbientOcclusion;`
			`}`
			`#endif`

			`return light;`
			`}`

			`// Fills a light struct given a perObjectLightIndex`
			`Light GetAdditionalPerObjectLight(int perObjectLightIndex, float3 positionWS)`
			`{`
			`// Abstraction over Light input constants`
			`#if USE_STRUCTURED_BUFFER_FOR_LIGHT_DATA`
			`float4 lightPositionWS = _AdditionalLightsBuffer[perObjectLightIndex].position;`
			`half3 color = _AdditionalLightsBuffer[perObjectLightIndex].color.rgb;`
			`half4 distanceAndSpotAttenuation = _AdditionalLightsBuffer[perObjectLightIndex].attenuation;`
			`half4 spotDirection = _AdditionalLightsBuffer[perObjectLightIndex].spotDirection;`
			`uint lightLayerMask = _AdditionalLightsBuffer[perObjectLightIndex].layerMask;`
			`#else`
			`float4 lightPositionWS = _AdditionalLightsPosition[perObjectLightIndex];`
			`half3 color = _AdditionalLightsColor[perObjectLightIndex].rgb;`
			`half4 distanceAndSpotAttenuation = _AdditionalLightsAttenuation[perObjectLightIndex];`
			`half4 spotDirection = _AdditionalLightsSpotDir[perObjectLightIndex];`
			`uint lightLayerMask = asuint(_AdditionalLightsLayerMasks[perObjectLightIndex]);`
			`#endif`

			`// Directional lights store direction in lightPosition.xyz and have .w set to 0.0.`
			`// This way the following code will work for both directional and punctual lights.`
			`float3 lightVector = lightPositionWS.xyz - positionWS * lightPositionWS.w;`
			`float distanceSqr = max(dot(lightVector, lightVector), HALF_MIN);`

			`half3 lightDirection = half3(lightVector * rsqrt(distanceSqr));`
			`// full-float precision required on some platforms`
			`float attenuation = DistanceAttenuation(distanceSqr, distanceAndSpotAttenuation.xy) * AngleAttenuation(spotDirection.xyz, lightDirection, distanceAndSpotAttenuation.zw);`

			`Light light;`
			`light.direction = lightDirection;`
			`light.distanceAttenuation = attenuation;`
			`light.shadowAttenuation = 1.0; // This value can later be overridden in GetAdditionalLight(uint i, float3 positionWS, half4 shadowMask)`
			`light.color = color;`
			`light.layerMask = lightLayerMask;`

			`return light;`
			`}`

			`uint GetPerObjectLightIndexOffset()`
			`{`
			`#if USE_STRUCTURED_BUFFER_FOR_LIGHT_DATA`
			`return uint(unity_LightData.x);`
			`#else`
			`return 0;`
			`#endif`
			`}`

			`// Returns a per-object index given a loop index.`
			`// This abstract the underlying data implementation for storing lights/light indices`
			`int GetPerObjectLightIndex(uint index)`
			`{`
			`/////////////////////////////////////////////////////////////////////////////////////////////`
			`// Structured Buffer Path /`
			`// /`
			`// Lights and light indices are stored in StructuredBuffer. We can just index them. /`
			`// Currently all non-mobile platforms take this path :( /`
			`// There are limitation in mobile GPUs to use SSBO (performance / no vertex shader support) /`
			`/////////////////////////////////////////////////////////////////////////////////////////////`
			`#if USE_STRUCTURED_BUFFER_FOR_LIGHT_DATA`
			`uint offset = uint(unity_LightData.x);`
			`return _AdditionalLightsIndices[offset + index];`

			`/////////////////////////////////////////////////////////////////////////////////////////////`
			`// UBO path /`
			`// /`
			`// We store 8 light indices in half4 unity_LightIndices[2]; /`
			`// Due to memory alignment unity doesn't support int[] or float[] /`
			`// Even trying to reinterpret cast the unity_LightIndices to float[] won't work /`
			`// it will cast to float4[] and create extra register pressure. :( /`
			`/////////////////////////////////////////////////////////////////////////////////////////////`
			`#else`
			`// since index is uint shader compiler will implement`
			`// div & mod as bitfield ops (shift and mask).`

			`// TODO: Can we index a float4? Currently compiler is`
			`// replacing unity_LightIndicesX[i] with a dp4 with identity matrix.`
			`// u_xlat16_40 = dot(unity_LightIndices[int(u_xlatu13)], ImmCB_0_0_0[u_xlati1]);`
			`// This increases both arithmetic and register pressure.`
			`//`
			`// NOTE: min16float4 bug workaround.`
			`// Take the "vec4" part into float4 tmp variable in order to force float4 math.`
			`// It appears indexing half4 as min16float4 on DX11 can fail. (dp4 {min16f})`
			`float4 tmp = unity_LightIndices[index / 4];`
			`return int(tmp[index % 4]);`
			`#endif`
			`}`

			`// Fills a light struct given a loop i index. This will convert the i`
			`// index to a perObjectLightIndex`
			`Light GetAdditionalLight(uint i, float3 positionWS)`
			`{`
			`#if USE_FORWARD_PLUS`
			`int lightIndex = i;`
			`#else`
			`int lightIndex = GetPerObjectLightIndex(i);`
			`#endif`
			`return GetAdditionalPerObjectLight(lightIndex, positionWS);`
			`}`

			`Light GetAdditionalLight(uint i, float3 positionWS, half4 shadowMask)`
			`{`
			`#if USE_FORWARD_PLUS`
			`int lightIndex = i;`
			`#else`
			`int lightIndex = GetPerObjectLightIndex(i);`
			`#endif`
			`Light light = GetAdditionalPerObjectLight(lightIndex, positionWS);`

			`#if USE_STRUCTURED_BUFFER_FOR_LIGHT_DATA`
			`half4 occlusionProbeChannels = _AdditionalLightsBuffer[lightIndex].occlusionProbeChannels;`
			`#else`
			`half4 occlusionProbeChannels = _AdditionalLightsOcclusionProbes[lightIndex];`
			`#endif`
			`light.shadowAttenuation = AdditionalLightShadow(lightIndex, positionWS, light.direction, shadowMask, occlusionProbeChannels);`
			`#if defined(_LIGHT_COOKIES)`
			`real3 cookieColor = SampleAdditionalLightCookie(lightIndex, positionWS);`
			`light.color *= cookieColor;`
			`#endif`

			`return light;`
			`}`

			`Light GetAdditionalLight(uint i, InputData inputData, half4 shadowMask, AmbientOcclusionFactor aoFactor)`
			`{`
			`Light light = GetAdditionalLight(i, inputData.positionWS, shadowMask);`

			`#if defined(_SCREEN_SPACE_OCCLUSION) && !defined(_SURFACE_TYPE_TRANSPARENT)`
			`if (IsLightingFeatureEnabled(DEBUGLIGHTINGFEATUREFLAGS_AMBIENT_OCCLUSION))`
			`{`
			`light.color *= aoFactor.directAmbientOcclusion;`
			`}`
			`#endif`

			`return light;`
			`}`

			`int GetAdditionalLightsCount()`
			`{`
			`#if USE_FORWARD_PLUS`
			`// Counting the number of lights in clustered requires traversing the bit list, and is not needed up front.`
			`return 0;`
			`#else`
			`// TODO: we need to expose in SRP api an ability for the pipeline cap the amount of lights`
			`// in the culling. This way we could do the loop branch with an uniform`
			`// This would be helpful to support baking exceeding lights in SH as well`
			`return int(min(_AdditionalLightsCount.x, unity_LightData.y));`
			`#endif`
			`}`

			`half4 CalculateShadowMask(InputData inputData)`
			`{`
			`// To ensure backward compatibility we have to avoid using shadowMask input, as it is not present in older shaders`
			`#if defined(SHADOWS_SHADOWMASK) && defined(LIGHTMAP_ON)`
			`half4 shadowMask = inputData.shadowMask; // Shadowmask was sampled from lightmap`
			`#elif !defined(LIGHTMAP_ON) && (defined(PROBE_VOLUMES_L1) \|\| defined(PROBE_VOLUMES_L2))`
			`half4 shadowMask = inputData.shadowMask; // Shadowmask (probe occlusion) was sampled from APV`
			`#elif !defined (LIGHTMAP_ON)`
			`half4 shadowMask = unity_ProbesOcclusion; // Sample shadowmask (probe occlusion) from legacy probes`
			`#else`
			`half4 shadowMask = half4(1, 1, 1, 1); // Fallback shadowmask, fully unoccluded`
			`#endif`

			`return shadowMask;`
			`}`

			`#endif`