// This files include various function uses to evaluate lights // To use deferred directional shadow with cascaded shadow map, // it is required to define USE_DEFERRED_DIRECTIONAL_SHADOWS before including this files //----------------------------------------------------------------------------- // Directional Light evaluation helper //----------------------------------------------------------------------------- float3 EvaluateCookie_Directional(LightLoopContext lightLoopContext, DirectionalLightData lightData, float3 positionWS) { // Translate and rotate 'positionWS' into the light space. // 'lightData.right' and 'lightData.up' are pre-scaled on CPU. float3 lightToSample = positionWS - lightData.positionWS; float3x3 lightToWorld = float3x3(lightData.right, lightData.up, lightData.forward); float3 positionLS = mul(lightToSample, transpose(lightToWorld)); // Perform orthographic projection. float2 positionCS = positionLS.xy; // Remap the texture coordinates from [-1, 1]^2 to [0, 1]^2. float2 positionNDC = positionCS * 0.5 + 0.5; // Tile the texture if the 'repeat' wrap mode is enabled. positionNDC = lightData.tileCookie ? frac(positionNDC) : positionNDC; // We let the sampler handle clamping to border. return SampleCookie2D(lightLoopContext, positionNDC, lightData.cookieIndex); } // None of the outputs are premultiplied. void EvaluateLight_Directional(LightLoopContext lightLoopContext, PositionInputs posInput, DirectionalLightData lightData, BakeLightingData bakeLightingData, float3 N, float3 L, out float3 color, out float attenuation) { float3 positionWS = posInput.positionWS; float shadow = 1.0; float shadowMask = 1.0; color = lightData.color; attenuation = 1.0; #ifdef SHADOWS_SHADOWMASK // shadowMaskSelector.x is -1 if there is no shadow mask // Note that we override shadow value (in case we don't have any dynamic shadow) shadow = shadowMask = (lightData.shadowMaskSelector.x >= 0.0) ? dot(bakeLightingData.bakeShadowMask, lightData.shadowMaskSelector) : 1.0; #endif [branch] if (lightData.shadowIndex >= 0) { #ifdef USE_DEFERRED_DIRECTIONAL_SHADOWS shadow = LOAD_TEXTURE2D(_DeferredShadowTexture, posInput.positionSS).x; #else shadow = GetDirectionalShadowAttenuation(lightLoopContext.shadowContext, positionWS, N, lightData.shadowIndex, L, posInput.positionSS); #endif #ifdef SHADOWS_SHADOWMASK float fade = saturate(posInput.linearDepth * lightData.fadeDistanceScaleAndBias.x + lightData.fadeDistanceScaleAndBias.y); // See comment in EvaluateBSDF_Punctual shadow = lightData.dynamicShadowCasterOnly ? min(shadowMask, shadow) : shadow; shadow = lerp(shadow, shadowMask, fade); // Caution to lerp parameter: fade is the reverse of shadowDimmer // Note: There is no shadowDimmer when there is no shadow mask #endif } // Note: no volumetric attenuation along shadow rays for directional lights. attenuation *= shadow; [branch] if (lightData.cookieIndex >= 0) { float3 cookie = EvaluateCookie_Directional(lightLoopContext, lightData, positionWS); color *= cookie; } } //----------------------------------------------------------------------------- // Punctual Light evaluation helper //----------------------------------------------------------------------------- float4 EvaluateCookie_Punctual(LightLoopContext lightLoopContext, LightData lightData, float3 positionWS) { int lightType = lightData.lightType; // Translate and rotate 'positionWS' into the light space. // 'lightData.right' and 'lightData.up' are pre-scaled on CPU. float3 lightToSample = positionWS - lightData.positionWS; float3x3 lightToWorld = float3x3(lightData.right, lightData.up, lightData.forward); float3 positionLS = mul(lightToSample, transpose(lightToWorld)); float4 cookie; [branch] if (lightType == GPULIGHTTYPE_POINT) { cookie.rgb = SampleCookieCube(lightLoopContext, positionLS, lightData.cookieIndex); cookie.a = 1; } else { // Perform orthographic or perspective projection. float perspectiveZ = (lightType != GPULIGHTTYPE_PROJECTOR_BOX) ? positionLS.z : 1.0; float2 positionCS = positionLS.xy / perspectiveZ; bool isInBounds = Max3(abs(positionCS.x), abs(positionCS.y), 1.0 - positionLS.z) <= 1.0; // Remap the texture coordinates from [-1, 1]^2 to [0, 1]^2. float2 positionNDC = positionCS * 0.5 + 0.5; // Manually clamp to border (black). cookie.rgb = SampleCookie2D(lightLoopContext, positionNDC, lightData.cookieIndex); cookie.a = isInBounds ? 1 : 0; } return cookie; } float GetPunctualShapeAttenuation(LightData lightData, float3 L, float distSq) { // Note: lightData.invSqrAttenuationRadius is 0 when applyRangeAttenuation is false float attenuation = GetDistanceAttenuation(distSq, lightData.invSqrAttenuationRadius); // Reminder: lights are oriented backward (-Z) return attenuation * GetAngleAttenuation(L, -lightData.forward, lightData.angleScale, lightData.angleOffset); } // None of the outputs are premultiplied. void EvaluateLight_Punctual(LightLoopContext lightLoopContext, PositionInputs posInput, LightData lightData, BakeLightingData bakeLightingData, float3 N, float3 L, float dist, float distSq, out float3 color, out float attenuation) { float3 positionWS = posInput.positionWS; float shadow = 1.0; float shadowMask = 1.0; color = lightData.color; attenuation = GetPunctualShapeAttenuation(lightData, L, distSq); #ifdef SHADOWS_SHADOWMASK // shadowMaskSelector.x is -1 if there is no shadow mask // Note that we override shadow value (in case we don't have any dynamic shadow) shadow = shadowMask = (lightData.shadowMaskSelector.x >= 0.0) ? dot(bakeLightingData.bakeShadowMask, lightData.shadowMaskSelector) : 1.0; #endif [branch] if (lightData.shadowIndex >= 0) { // TODO: make projector lights cast shadows. float3 offset = float3(0.0, 0.0, 0.0); // GetShadowPosOffset(nDotL, normal); float4 L_dist = float4(L, dist); shadow = GetPunctualShadowAttenuation(lightLoopContext.shadowContext, positionWS + offset, N, lightData.shadowIndex, L_dist, posInput.positionSS); #ifdef SHADOWS_SHADOWMASK // Note: Legacy Unity have two shadow mask mode. ShadowMask (ShadowMask contain static objects shadow and ShadowMap contain only dynamic objects shadow, final result is the minimun of both value) // and ShadowMask_Distance (ShadowMask contain static objects shadow and ShadowMap contain everything and is blend with ShadowMask based on distance (Global distance setup in QualitySettigns)). // HDRenderPipeline change this behavior. Only ShadowMask mode is supported but we support both blend with distance AND minimun of both value. Distance is control by light. // The following code do this. // The min handle the case of having only dynamic objects in the ShadowMap // The second case for blend with distance is handled with ShadowDimmer. ShadowDimmer is define manually and by shadowDistance by light. // With distance, ShadowDimmer become one and only the ShadowMask appear, we get the blend with distance behavior. shadow = lightData.dynamicShadowCasterOnly ? min(shadowMask, shadow) : shadow; shadow = lerp(shadowMask, shadow, lightData.shadowDimmer); #else shadow = lerp(1.0, shadow, lightData.shadowDimmer); #endif } #if (SHADEROPTIONS_VOLUMETRIC_LIGHTING_PRESET != 0) [flatten] if (lightData.lightType == GPULIGHTTYPE_PROJECTOR_BOX) { float3 lightToSample = positionWS - lightData.positionWS; dist = dot(-lightToSample, L); } shadow *= TransmittanceHomogeneousMedium(_GlobalFog_Extinction, dist); #endif attenuation *= shadow; // Projector lights always have cookies, so we can perform clipping inside the if(). [branch] if (lightData.cookieIndex >= 0) { float4 cookie = EvaluateCookie_Punctual(lightLoopContext, lightData, positionWS); color *= cookie.rgb; attenuation *= cookie.a; } }