예제 #1
0
        void BuildLightData(CommandBuffer cmd, HDCamera hdCamera, List <HDAdditionalLightData> lightArray)
        {
            // Also we need to build the light list data
            if (m_LightDataGPUArray == null || m_LightDataGPUArray.count != lightArray.Count)
            {
                ResizeLightDataBuffer(lightArray.Count);
            }

            // Build the data for every light
            for (int lightIdx = 0; lightIdx < lightArray.Count; ++lightIdx)
            {
                var lightData = new LightData();

                HDAdditionalLightData additionalLightData = lightArray[lightIdx];
                // When the user deletes a light source in the editor, there is a single frame where the light is null before the collection of light in the scene is triggered
                // the workaround for this is simply to add an invalid light for that frame
                if (additionalLightData == null)
                {
                    m_LightDataCPUArray[lightIdx] = lightData;
                    continue;
                }
                Light light = additionalLightData.gameObject.GetComponent <Light>();

                // Both of these positions are non-camera-relative.
                float distanceToCamera  = (light.gameObject.transform.position - hdCamera.camera.transform.position).magnitude;
                float lightDistanceFade = HDUtils.ComputeLinearDistanceFade(distanceToCamera, additionalLightData.fadeDistance);

                bool contributesToLighting = ((additionalLightData.lightDimmer > 0) && (additionalLightData.affectDiffuse || additionalLightData.affectSpecular)) || (additionalLightData.volumetricDimmer > 0);
                contributesToLighting = contributesToLighting && (lightDistanceFade > 0);

                if (!contributesToLighting)
                {
                    continue;
                }

                lightData.lightLayers = additionalLightData.GetLightLayers();
                LightCategory lightCategory = LightCategory.Count;
                GPULightType  gpuLightType  = GPULightType.Point;
                GetLightGPUType(additionalLightData, light, ref gpuLightType, ref lightCategory);

                lightData.lightType = gpuLightType;

                lightData.positionRWS = light.gameObject.transform.position - hdCamera.camera.transform.position;

                bool applyRangeAttenuation = additionalLightData.applyRangeAttenuation && (gpuLightType != GPULightType.ProjectorBox);

                lightData.range = light.range;

                if (applyRangeAttenuation)
                {
                    lightData.rangeAttenuationScale = 1.0f / (light.range * light.range);
                    lightData.rangeAttenuationBias  = 1.0f;

                    if (lightData.lightType == GPULightType.Rectangle)
                    {
                        // Rect lights are currently a special case because they use the normalized
                        // [0, 1] attenuation range rather than the regular [0, r] one.
                        lightData.rangeAttenuationScale = 1.0f;
                    }
                }
                else // Don't apply any attenuation but do a 'step' at range
                {
                    // Solve f(x) = b - (a * x)^2 where x = (d/r)^2.
                    // f(0) = huge -> b = huge.
                    // f(1) = 0    -> huge - a^2 = 0 -> a = sqrt(huge).
                    const float hugeValue = 16777216.0f;
                    const float sqrtHuge  = 4096.0f;
                    lightData.rangeAttenuationScale = sqrtHuge / (light.range * light.range);
                    lightData.rangeAttenuationBias  = hugeValue;

                    if (lightData.lightType == GPULightType.Rectangle)
                    {
                        // Rect lights are currently a special case because they use the normalized
                        // [0, 1] attenuation range rather than the regular [0, r] one.
                        lightData.rangeAttenuationScale = sqrtHuge;
                    }
                }

                Color value = light.color.linear * light.intensity;
                if (additionalLightData.useColorTemperature)
                {
                    value *= Mathf.CorrelatedColorTemperatureToRGB(light.colorTemperature);
                }
                lightData.color = new Vector3(value.r, value.g, value.b);

                lightData.forward = light.transform.forward;
                lightData.up      = light.transform.up;
                lightData.right   = light.transform.right;

                if (lightData.lightType == GPULightType.ProjectorBox)
                {
                    // Rescale for cookies and windowing.
                    lightData.right *= 2.0f / Mathf.Max(additionalLightData.shapeWidth, 0.001f);
                    lightData.up    *= 2.0f / Mathf.Max(additionalLightData.shapeHeight, 0.001f);
                }
                else if (lightData.lightType == GPULightType.ProjectorPyramid)
                {
                    // Get width and height for the current frustum
                    var spotAngle = light.spotAngle;

                    float frustumWidth, frustumHeight;

                    if (additionalLightData.aspectRatio >= 1.0f)
                    {
                        frustumHeight = 2.0f * Mathf.Tan(spotAngle * 0.5f * Mathf.Deg2Rad);
                        frustumWidth  = frustumHeight * additionalLightData.aspectRatio;
                    }
                    else
                    {
                        frustumWidth  = 2.0f * Mathf.Tan(spotAngle * 0.5f * Mathf.Deg2Rad);
                        frustumHeight = frustumWidth / additionalLightData.aspectRatio;
                    }

                    // Rescale for cookies and windowing.
                    lightData.right *= 2.0f / frustumWidth;
                    lightData.up    *= 2.0f / frustumHeight;
                }

                if (lightData.lightType == GPULightType.Spot)
                {
                    var spotAngle = light.spotAngle;

                    var innerConePercent      = additionalLightData.GetInnerSpotPercent01();
                    var cosSpotOuterHalfAngle = Mathf.Clamp(Mathf.Cos(spotAngle * 0.5f * Mathf.Deg2Rad), 0.0f, 1.0f);
                    var sinSpotOuterHalfAngle = Mathf.Sqrt(1.0f - cosSpotOuterHalfAngle * cosSpotOuterHalfAngle);
                    var cosSpotInnerHalfAngle = Mathf.Clamp(Mathf.Cos(spotAngle * 0.5f * innerConePercent * Mathf.Deg2Rad), 0.0f, 1.0f); // inner cone

                    var val = Mathf.Max(0.0001f, (cosSpotInnerHalfAngle - cosSpotOuterHalfAngle));
                    lightData.angleScale  = 1.0f / val;
                    lightData.angleOffset = -cosSpotOuterHalfAngle * lightData.angleScale;

                    // Rescale for cookies and windowing.
                    float cotOuterHalfAngle = cosSpotOuterHalfAngle / sinSpotOuterHalfAngle;
                    lightData.up    *= cotOuterHalfAngle;
                    lightData.right *= cotOuterHalfAngle;
                }
                else
                {
                    // These are the neutral values allowing GetAngleAnttenuation in shader code to return 1.0
                    lightData.angleScale  = 0.0f;
                    lightData.angleOffset = 1.0f;
                }

                if (lightData.lightType != GPULightType.Directional && lightData.lightType != GPULightType.ProjectorBox)
                {
                    // Store the squared radius of the light to simulate a fill light.
                    lightData.size = new Vector2(additionalLightData.shapeRadius * additionalLightData.shapeRadius, 0);
                }

                if (lightData.lightType == GPULightType.Rectangle || lightData.lightType == GPULightType.Tube)
                {
                    lightData.size = new Vector2(additionalLightData.shapeWidth, additionalLightData.shapeHeight);
                }

                lightData.lightDimmer           = lightDistanceFade * (additionalLightData.lightDimmer);
                lightData.diffuseDimmer         = lightDistanceFade * (additionalLightData.affectDiffuse ? additionalLightData.lightDimmer : 0);
                lightData.specularDimmer        = lightDistanceFade * (additionalLightData.affectSpecular ? additionalLightData.lightDimmer * hdCamera.frameSettings.specularGlobalDimmer : 0);
                lightData.volumetricLightDimmer = lightDistanceFade * (additionalLightData.volumetricDimmer);

                lightData.contactShadowIndex       = -1;
                lightData.cookieIndex              = -1;
                lightData.shadowIndex              = -1;
                lightData.rayTracedAreaShadowIndex = -1;

                if (light != null && light.cookie != null)
                {
                    // TODO: add texture atlas support for cookie textures.
                    switch (light.type)
                    {
                    case LightType.Spot:
                        lightData.cookieIndex = m_LightLoop.cookieTexArray.FetchSlice(cmd, light.cookie);
                        break;

                    case LightType.Point:
                        lightData.cookieIndex = m_LightLoop.cubeCookieTexArray.FetchSlice(cmd, light.cookie);
                        break;
                    }
                }
                else if (light.type == LightType.Spot && additionalLightData.spotLightShape != SpotLightShape.Cone)
                {
                    // Projectors lights must always have a cookie texture.
                    // As long as the cache is a texture array and not an atlas, the 4x4 white texture will be rescaled to 128
                    lightData.cookieIndex = m_LightLoop.cookieTexArray.FetchSlice(cmd, Texture2D.whiteTexture);
                }
                else if (lightData.lightType == GPULightType.Rectangle && additionalLightData.areaLightCookie != null)
                {
                    lightData.cookieIndex = m_LightLoop.areaLightCookieManager.FetchSlice(cmd, additionalLightData.areaLightCookie);
                }

                {
                    lightData.shadowDimmer           = 1.0f;
                    lightData.volumetricShadowDimmer = 1.0f;
                }

                {
                    // fix up shadow information
                    lightData.shadowIndex = additionalLightData.shadowIndex;
                }

                // Value of max smoothness is from artists point of view, need to convert from perceptual smoothness to roughness
                lightData.minRoughness = (1.0f - additionalLightData.maxSmoothness) * (1.0f - additionalLightData.maxSmoothness);

                // No usage for the shadow masks
                lightData.shadowMaskSelector = Vector4.zero;
                {
                    // use -1 to say that we don't use shadow mask
                    lightData.shadowMaskSelector.x = -1.0f;
                    lightData.nonLightMappedOnly   = 0;
                }

                // Set the data for this light
                m_LightDataCPUArray[lightIdx] = lightData;
            }

            //Push the data to the GPU
            m_LightDataGPUArray.SetData(m_LightDataCPUArray);
        }