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@@ -244,7 +244,7 @@ namespace Nz
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BoundingVolumef boundingVolume(renderable->GetAABB());
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boundingVolume.Update(worldInstance->GetWorldMatrix());
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if (!frustum.Contains(boundingVolume.aabb))
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if (!frustum.Contains(boundingVolume))
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continue;
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auto& visibleRenderable = m_visibleRenderables.emplace_back();
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@@ -259,6 +259,20 @@ namespace Nz
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visibilityHash = CombineHash(visibilityHash, std::hash<const void*>()(worldInstance.get()));
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}
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// TODO: Lights update shouldn't trigger a rebuild of the depth prepass
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m_visibleLights.clear();
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for (auto&& [light, lightData] : m_lights)
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{
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const BoundingVolumef& boundingVolume = light->GetBoundingVolume();
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// TODO: Use more precise tests for point lights (frustum/sphere is cheap)
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if (renderMask & lightData.renderMask && frustum.Contains(boundingVolume))
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{
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m_visibleLights.push_back(light);
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visibilityHash = CombineHash(visibilityHash, std::hash<const void*>()(light));
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}
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}
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if (viewerData.visibilityHash != visibilityHash)
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{
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viewerData.rebuildDepthPrepass = true;
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@@ -317,26 +331,26 @@ namespace Nz
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renderableBoundingVolume.Update(renderableData.worldInstance->GetWorldMatrix());
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// Select lights (TODO: Cull lights in frustum)
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m_visibleLights.clear();
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for (auto&& [light, lightData] : m_lights)
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m_renderableLights.clear();
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for (const Light* light : m_visibleLights)
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{
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const BoundingVolumef& boundingVolume = light->GetBoundingVolume();
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if ((renderMask & lightData.renderMask) && boundingVolume.Intersect(renderableBoundingVolume.aabb))
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m_visibleLights.push_back(light);
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if (boundingVolume.Intersect(renderableBoundingVolume.aabb))
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m_renderableLights.push_back(light);
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}
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// Sort lights
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std::sort(m_visibleLights.begin(), m_visibleLights.end(), [&](Light* lhs, Light* rhs)
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std::sort(m_renderableLights.begin(), m_renderableLights.end(), [&](const Light* lhs, const Light* rhs)
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{
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return lhs->ComputeContributionScore(renderableBoundingVolume) < rhs->ComputeContributionScore(renderableBoundingVolume);
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});
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std::size_t lightCount = std::min(m_visibleLights.size(), MaxLightCountPerDraw);
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std::size_t lightCount = std::min(m_renderableLights.size(), MaxLightCountPerDraw);
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LightKey lightKey;
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lightKey.fill(nullptr);
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for (std::size_t i = 0; i < lightCount; ++i)
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lightKey[i] = m_visibleLights[i];
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lightKey[i] = m_renderableLights[i];
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RenderBufferView lightUboView;
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@@ -383,7 +397,7 @@ namespace Nz
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UInt8* lightPtr = static_cast<UInt8*>(lightDataPtr) + lightOffsets.lightsOffset;
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for (std::size_t i = 0; i < lightCount; ++i)
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{
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m_visibleLights[i]->FillLightData(lightPtr);
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m_renderableLights[i]->FillLightData(lightPtr);
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lightPtr += lightOffsets.lightSize;
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}
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Jérôme Leclercq