public static void Render(ScriptableRenderContext context, IEnumerable <Camera> cameras, SimpleRenderPipeline.Mode mode)
{
foreach (var camera in cameras)
{
// Culling
ScriptableCullingParameters cullingParams;
if (!camera.TryGetCullingParameters(out cullingParams))
{
continue;
}
CullingResults cull = context.Cull(ref cullingParams);
context.SetupCameraProperties(camera);
AttachmentDescriptor color = new AttachmentDescriptor(RenderTextureFormat.ARGB32);
AttachmentDescriptor depth = new AttachmentDescriptor(RenderTextureFormat.Depth);
bool needsFinalBlit = camera.cameraType == CameraType.SceneView;
RenderTargetIdentifier tmpBuf = new RenderTargetIdentifier("TempSurface");
if (needsFinalBlit)
{
using (var cmd = new CommandBuffer())
{
cmd.GetTemporaryRT(Shader.PropertyToID("TempSurface"), camera.pixelWidth, camera.pixelHeight, 24, FilterMode.Bilinear, RenderTextureFormat.ARGB32);
context.ExecuteCommandBuffer(cmd);
}
color.ConfigureTarget(tmpBuf, false, true);
}
else
{
color.ConfigureTarget(BuiltinRenderTextureType.CameraTarget, false, true);
}
// No configure target for depth means depth will be memoryless
color.ConfigureClear(Color.blue / 3 + Color.red / 2);
depth.ConfigureClear(Color.black, 1.0f, 0);
using (var attachmentsDisposable = new NativeArray <AttachmentDescriptor>(2, Allocator.Temp))
{
var attachments = attachmentsDisposable;
const int depthIndex = 0, colorIndex = 1;
attachments[depthIndex] = depth;
attachments[colorIndex] = color;
using (context.BeginScopedRenderPass(camera.pixelWidth, camera.pixelHeight, 1, attachments, depthIndex))
{
var fs = new FilteringSettings(RenderQueueRange.opaque);
if (mode == SimpleRenderPipeline.Mode.DepthPrepass)
{
var depthPrePasssettings = new DrawingSettings(new ShaderTagId("DepthPrepass"), new SortingSettings(camera));
using (var depthOnlyDisposable = new NativeArray <int>(0, Allocator.Temp))
{
var depthArray = depthOnlyDisposable;
using (context.BeginScopedSubPass(depthArray))
{
context.DrawRenderers(cull, ref depthPrePasssettings, ref fs);
}
}
var mainPasssettings = new DrawingSettings(new ShaderTagId("AfterZPrepass"), new SortingSettings(camera));
using (var colorsDisposable = new NativeArray <int>(1, Allocator.Temp))
{
var colors = colorsDisposable;
colors[0] = colorIndex;
using (context.BeginScopedSubPass(colors))
{
context.DrawRenderers(cull, ref mainPasssettings, ref fs);
}
}
}
else if (mode == SimpleRenderPipeline.Mode.OnePassAlphaTest)
{
var mainPasssettings = new DrawingSettings(new ShaderTagId("OnePassAlphaClip"), new SortingSettings(camera));
using (var colorsDisposable = new NativeArray <int>(1, Allocator.Temp))
{
var colors = colorsDisposable;
colors[0] = colorIndex;
using (context.BeginScopedSubPass(colors))
{
context.DrawRenderers(cull, ref mainPasssettings, ref fs);
}
}
}
else if (mode == SimpleRenderPipeline.Mode.OnePassAlphaBlend)
{
var sortingSettings = new SortingSettings(camera);
sortingSettings.criteria = SortingCriteria.BackToFront;
var mainPasssettings = new DrawingSettings(new ShaderTagId("OnePassAlphaBlend"), sortingSettings);
using (var colorsDisposable = new NativeArray <int>(1, Allocator.Temp))
{
var colors = colorsDisposable;
colors[0] = colorIndex;
using (context.BeginScopedSubPass(colors))
{
context.DrawRenderers(cull, ref mainPasssettings, ref fs);
}
}
}
}
}
if (needsFinalBlit)
{
using (var cmd = new CommandBuffer())
{
cmd.Blit(tmpBuf, new RenderTargetIdentifier(BuiltinRenderTextureType.CameraTarget));
context.ExecuteCommandBuffer(cmd);
}
}
context.Submit();
}
}
void DrawDeferred(Camera camera, CullingResults cullingResults, ScriptableRenderContext context)
{
var albedo = new AttachmentDescriptor(RenderTextureFormat.ARGB32);
var specRough = new AttachmentDescriptor(RenderTextureFormat.ARGB32);
var normal = new AttachmentDescriptor(RenderTextureFormat.ARGB2101010);
var emission = new AttachmentDescriptor(RenderTextureFormat.ARGBHalf);
var depth = new AttachmentDescriptor(RenderTextureFormat.Depth);
var depthSRV = new AttachmentDescriptor(RenderTextureFormat.ARGBHalf);
// At the beginning of the render pass, clear the emission buffer to all black, and the depth buffer to 1.0f
emission.ConfigureClear(new Color(0.0f, 0.0f, 0.0f, 0.0f), 1.0f, 0);
depth.ConfigureClear(new Color(), 1.0f, 0);
//depthSRV.ConfigureClear(new Color(), 1.0f, 0);
albedo.ConfigureTarget(BuiltinRenderTextureType.CameraTarget, false, true);
var attachments = new NativeArray <AttachmentDescriptor>(5, Allocator.Temp);
const int depthIndex = 0, albedoIndex = 1, specRoughIndex = 2, normalIndex = 3, emissionIndex = 4, depthSRVIndex = 5;
attachments[depthIndex] = depth;
attachments[albedoIndex] = albedo;
attachments[specRoughIndex] = specRough;
attachments[normalIndex] = normal;
attachments[emissionIndex] = emission;
//attachments[depthSRVIndex] = depthSRV;
using (context.BeginScopedRenderPass(camera.pixelWidth, camera.pixelHeight, 1, attachments, depthIndex))
{
attachments.Dispose();
// Start the first subpass, GBuffer creation: render to albedo, specRough, normal and emission, no need to read any input attachments
var gbufferColors = new NativeArray <int>(4, Allocator.Temp);
gbufferColors[0] = albedoIndex;
gbufferColors[1] = specRoughIndex;
gbufferColors[2] = normalIndex;
gbufferColors[3] = emissionIndex;
//gbufferColors[4] = depthSRVIndex;
using (context.BeginScopedSubPass(gbufferColors))
{
gbufferColors.Dispose();
// Render the deferred G-Buffer
RenderGBuffer(camera, cullingResults, context);
}
// Second subpass, lighting: Render to the emission buffer, read from albedo, specRough, normal and depth.
// The last parameter indicates whether the depth buffer can be bound as read-only.
// Note that some renderers (notably iOS Metal) won't allow reading from the depth buffer while it's bound as Z-buffer,
// so those renderers should write the Z into an additional FP32 render target manually in the pixel shader and read from it instead
var lightingColors = new NativeArray <int>(1, Allocator.Temp);
lightingColors[0] = albedoIndex;
var lightingInputs = new NativeArray <int>(1, Allocator.Temp);
lightingInputs[0] = albedoIndex;
// lightingInputs[1] = specRoughIndex;
// lightingInputs[2] = normalIndex;
// //lightingInputs[3] = depthSRVIndex;
using (context.BeginScopedSubPass(lightingColors, lightingInputs, true))
{
lightingColors.Dispose();
lightingInputs.Dispose();
// PushGlobalShadowParams(context);
RenderDeferredLighting(camera, cullingResults, context);
}
// Third subpass, tonemapping: Render to albedo (which is bound to the camera target), read from emission.
var tonemappingColors = new NativeArray <int>(1, Allocator.Temp);
tonemappingColors[0] = albedoIndex;
var tonemappingInputs = new NativeArray <int>(1, Allocator.Temp);
tonemappingInputs[0] = albedoIndex;
using (context.BeginScopedSubPass(tonemappingColors, tonemappingInputs, true))
{
tonemappingColors.Dispose();
tonemappingInputs.Dispose();
// present frame buffer.
RenderDeferredFinalPass(context);
}
}
}
protected override void Render(ScriptableRenderContext context, Camera[] cameras)
{
BeginFrameRendering(cameras);
foreach (Camera camera in cameras)
{
BeginCameraRendering(camera);
//Culling
ScriptableCullingParameters cullingParams;
if (!camera.TryGetCullingParameters(out cullingParams))
{
continue;
}
CullingResults cull = context.Cull(ref cullingParams);
//Camera setup some builtin variables e.g. camera projection matrices etc
context.SetupCameraProperties(camera);
//Get the setting from camera component
bool drawSkyBox = camera.clearFlags == CameraClearFlags.Skybox? true : false;
bool clearDepth = camera.clearFlags == CameraClearFlags.Nothing? false : true;
bool clearColor = camera.clearFlags == CameraClearFlags.Color? true : false;
//Color Texture Descriptor
RenderTextureDescriptor colorRTDesc = new RenderTextureDescriptor(camera.pixelWidth, camera.pixelHeight);
colorRTDesc.colorFormat = m_ColorFormat;
colorRTDesc.depthBufferBits = depthBufferBits;
colorRTDesc.sRGB = (QualitySettings.activeColorSpace == ColorSpace.Linear);
colorRTDesc.msaaSamples = 1;
colorRTDesc.enableRandomWrite = false;
//Get Temp Texture for Color Texture
CommandBuffer cmdTempId = new CommandBuffer();
cmdTempId.name = "(" + camera.name + ")" + "Setup TempRT";
cmdTempId.GetTemporaryRT(m_ColorRTid, colorRTDesc, FilterMode.Bilinear);
cmdTempId.SetRenderTarget(m_ColorRT); //so that result won't flip
context.ExecuteCommandBuffer(cmdTempId);
cmdTempId.Release();
//Setup DrawSettings and FilterSettings
var sortingSettings = new SortingSettings(camera);
DrawingSettings drawSettings1 = new DrawingSettings(m_PassName1, sortingSettings);
DrawingSettings drawSettings2 = new DrawingSettings(m_PassName2, sortingSettings);
FilteringSettings filterSettings = new FilteringSettings(RenderQueueRange.all);
//Native Arrays for Attachaments
NativeArray <AttachmentDescriptor> renderPassAttachments = new NativeArray <AttachmentDescriptor>(4, Allocator.Temp);
renderPassAttachments[0] = m_Albedo;
renderPassAttachments[1] = m_Emission;
renderPassAttachments[2] = m_Output;
renderPassAttachments[3] = m_Depth;
NativeArray <int> renderPassColorAttachments = new NativeArray <int>(2, Allocator.Temp);
renderPassColorAttachments[0] = 0;
renderPassColorAttachments[1] = 1;
NativeArray <int> renderPassOutputAttachments = new NativeArray <int>(1, Allocator.Temp);
renderPassOutputAttachments[0] = 2;
//Clear Attachements
m_Output.ConfigureTarget(m_ColorRT, false, true);
m_Output.ConfigureClear(new Color(0.0f, 0.0f, 0.0f, 0.0f), 1, 0);
m_Albedo.ConfigureClear(camera.backgroundColor, 1, 0);
m_Emission.ConfigureClear(new Color(0.0f, 0.0f, 0.0f, 0.0f), 1, 0);
m_Depth.ConfigureClear(new Color(), 1, 0);
//More clean to use ScopedRenderPass instead of BeginRenderPass+EndRenderPass
using (context.BeginScopedRenderPass(camera.pixelWidth, camera.pixelHeight, 1, renderPassAttachments, 3))
{
//Output to Albedo & Emission
using (context.BeginScopedSubPass(renderPassColorAttachments, false))
{
//Opaque objects
sortingSettings.criteria = SortingCriteria.CommonOpaque;
drawSettings1.sortingSettings = sortingSettings;
filterSettings.renderQueueRange = RenderQueueRange.opaque;
context.DrawRenderers(cull, ref drawSettings1, ref filterSettings);
//Transparent objects
sortingSettings.criteria = SortingCriteria.CommonTransparent;
drawSettings1.sortingSettings = sortingSettings;
filterSettings.renderQueueRange = RenderQueueRange.transparent;
context.DrawRenderers(cull, ref drawSettings1, ref filterSettings);
}
//Read from Albedo & Emission, then output to Output
using (context.BeginScopedSubPass(renderPassOutputAttachments, renderPassColorAttachments))
{
//Skybox
if (drawSkyBox)
{
context.DrawSkybox(camera);
}
//Opaque objects
sortingSettings.criteria = SortingCriteria.CommonOpaque;
drawSettings2.sortingSettings = sortingSettings;
filterSettings.renderQueueRange = RenderQueueRange.opaque;
context.DrawRenderers(cull, ref drawSettings2, ref filterSettings);
//Transparent objects
sortingSettings.criteria = SortingCriteria.CommonTransparent;
drawSettings2.sortingSettings = sortingSettings;
filterSettings.renderQueueRange = RenderQueueRange.transparent;
context.DrawRenderers(cull, ref drawSettings2, ref filterSettings);
}
}
//Blit To Camera so that the CameraTarget has content and make sceneview works
CommandBuffer cmd = new CommandBuffer();
cmd.name = "Cam:" + camera.name + " BlitToCamera";
cmd.Blit(m_ColorRT, BuiltinRenderTextureType.CameraTarget);
context.ExecuteCommandBuffer(cmd);
cmd.Release();
//CleanUp Texture
CommandBuffer cmdclean = new CommandBuffer();
cmdclean.name = "(" + camera.name + ")" + "Clean Up";
cmdclean.ReleaseTemporaryRT(m_ColorRTid);
context.ExecuteCommandBuffer(cmdclean);
cmdclean.Release();
//Submit the CommandBuffers
context.Submit();
//CleanUp NativeArrays
renderPassAttachments.Dispose();
renderPassColorAttachments.Dispose();
renderPassOutputAttachments.Dispose();
}
}
void DeferredLightPass(ScriptableRenderContext context, CullingResults cullingResults, Camera camera)
{
var cmd = CommandBufferPool.Get("SetupGlobalLights");
SortingSettings opaqueSortingSettings = new SortingSettings(camera);
opaqueSortingSettings.criteria = SortingCriteria.CommonOpaque;
FilteringSettings opaqueFilteringSettings = new FilteringSettings(RenderQueueRange.opaque);
if (cullingResults.visibleLights.Length > 0)
{
VisibleLight lightData = cullingResults.visibleLights[0];
Vector4 dir = -lightData.localToWorldMatrix.GetColumn(2);
Vector4 lightPos = new Vector4(dir.x, dir.y, dir.z, 0.0f);
cmd.SetGlobalVector("_MainLightPosition", lightPos);
cmd.SetGlobalVector("_MainLightColor", lightData.finalColor);
}
if (cullingResults.visibleReflectionProbes.Length > 0)
{
cmd.SetGlobalTexture("unity_SpecCube0", cullingResults.visibleReflectionProbes[0].texture);
}
context.ExecuteCommandBuffer(cmd);
CommandBufferPool.Release(cmd);
bool useRenderPass = false;
if (!useRenderPass)
{
bool enableDynamicBatching = false;
bool enableInstancing = false;
PerObjectData perObjectData = PerObjectData.None;
// DrawGBuffers
DrawingSettings gBufferDrawingSettings = new DrawingSettings(ShaderPassTag.GBuffer, opaqueSortingSettings);
gBufferDrawingSettings.enableDynamicBatching = enableDynamicBatching;
gBufferDrawingSettings.enableInstancing = enableInstancing;
gBufferDrawingSettings.perObjectData = perObjectData;
cmd = CommandBufferPool.Get("Gbuffer");
cmd.SetRenderTarget(m_GBufferRTIDs, m_DepthBufferRTID);
cmd.ClearRenderTarget(true, true, camera.backgroundColor);
//CoreUtils.SetRenderTarget(cmd, m_GBufferRTIDs, m_DepthBufferRTID, ClearFlag.All);
context.ExecuteCommandBuffer(cmd);
CommandBufferPool.Release(cmd);
context.DrawRenderers(cullingResults, ref gBufferDrawingSettings, ref opaqueFilteringSettings);
cmd = CommandBufferPool.Get("DeferredLightingPass");
cmd.SetGlobalVector("unity_SpecCube0_HDR", new Vector4(1, 1, 0, 0));
// Bind buffers
cmd.SetGlobalTexture("_GBufferAlbedo", m_GBufferRTIDs[0]);
cmd.SetGlobalTexture("_GBufferNormal", m_GBufferRTIDs[1]);
cmd.SetGlobalTexture("_GBufferMetallicOcclusionSmoothness", m_GBufferRTIDs[2]);
cmd.SetGlobalTexture("_GBufferDepth", m_DepthBufferRTID);
cmd.SetGlobalInt("_TileCountX", (camera.scaledPixelWidth + 64 - 1) / 64);
cmd.SetGlobalInt("_TileCountY", (camera.scaledPixelHeight + 64 - 1) / 64);
cmd.SetGlobalVector("unity_LightData", new Vector4(6, 0, 1, 0));
//Set RenderTarget
cmd.SetRenderTarget(m_ColorBuffer, RenderBufferLoadAction.DontCare, RenderBufferStoreAction.Store);
cmd.ClearRenderTarget(true, true, Color.black, 0.0f);
//cmd.SetViewProjectionMatrices(Matrix4x4.identity, Matrix4x4.identity);
//cmd.SetViewport(camera.pixelRect);
cmd.DrawMesh(CustomRenderPipeline.fullscreenMesh, Matrix4x4.identity, m_DeferredLightingMat, 0, 0);
context.ExecuteCommandBuffer(cmd);
CommandBufferPool.Release(cmd);
//cmd.SetViewport(new Rect(0,0,camera.scaledPixelWidth, camera.scaledPixelHeight));
}
else
{
// var colorBuffer = new AttachmentDescriptor(RenderTextureFormat.ARGBHalf); // 64 bit
// var depthBuffer = new AttachmentDescriptor(RenderTextureFormat.Depth); // 32 bit
// var albedoGBuffer = new AttachmentDescriptor(RenderTextureFormat.ARGB32); // 32 bit
// var normalGBuffer = new AttachmentDescriptor(RenderTextureFormat.ARGBHalf); // 64 bit
// var pbrGBuffer = new AttachmentDescriptor(RenderTextureFormat.ARGB32); // 32
// var depthGBuffer = new AttachmentDescriptor(RenderTextureFormat.RFloat); // 32 bit
//
// colorBuffer.ConfigureClear(new Color(0.0f, 0.0f, 0.0f, 0.0f), 1.0f, 0);
// depthBuffer.ConfigureClear(new Color(), 1.0f, 0);
// colorBuffer.ConfigureTarget(BuiltinRenderTextureType.CameraTarget, true, true);
//
// var attachments = new NativeArray<AttachmentDescriptor>(6, Allocator.Temp);
// const int colorBufferId = 0, depthBufferId = 1, albedoGBufferId = 2, normalGBufferId = 3, pbrGbufferId = 4, depthGBufferId = 5;
// //const int colorBufferId = 0, albedoGBufferId = 2, normalGBufferId = 3, pbrGbufferId = 4, depthGBufferId = 5;
// attachments[colorBufferId] = colorBuffer;
// attachments[depthBufferId] = depthBuffer;
// attachments[albedoGBufferId] = albedoGBuffer;
// attachments[normalGBufferId] = normalGBuffer;
// attachments[pbrGbufferId] = pbrGBuffer;
// attachments[depthGBufferId] = depthGBuffer;
//
// using (context.BeginScopedRenderPass(camera.scaledPixelWidth, camera.scaledPixelHeight, 1, attachments, depthBufferId))
// {
// attachments.Dispose();
// var gBuffers = new NativeArray<int>(4, Allocator.Temp);
//
// //gBuffers[0] = colorBufferId;
// gBuffers[0] = albedoGBufferId;
// gBuffers[1] = normalGBufferId;
// gBuffers[2] = pbrGbufferId;
// gBuffers[3] = depthGBufferId;
// using (context.BeginScopedSubPass(gBuffers))
// {
// RenderGbufferSubPass(context, cullingResults, camera);
// }
// var lightingColors = new NativeArray<int>(1, Allocator.Temp);
// lightingColors[0] = colorBufferId;
// var lightingInputs = new NativeArray<int>(4, Allocator.Temp);
// lightingInputs[0] = albedoGBufferId;
// //lightingInputs[1] = albedoGBufferId;
// lightingInputs[1] = normalGBufferId;
// lightingInputs[2] = pbrGbufferId;
// lightingInputs[3] = depthGBufferId;
// using (context.BeginScopedSubPass(lightingColors, lightingInputs, true))
// {
// lightingColors.Dispose();
// lightingInputs.Dispose();
//
// // RenderLighting(camera, cullResults, context);
// RenderDeferredLightingSubPass(context, cullingResults, camera);
// }
//
//
// }
var albedo = new AttachmentDescriptor(RenderTextureFormat.ARGB32);
var specRough = new AttachmentDescriptor(RenderTextureFormat.ARGB32);
var normal = new AttachmentDescriptor(RenderTextureFormat.ARGB2101010);
var emission = new AttachmentDescriptor(RenderTextureFormat.ARGBHalf);
var depth = new AttachmentDescriptor(RenderTextureFormat.Depth);
emission.ConfigureClear(new Color(0.0f, 0.0f, 0.0f, 0.0f), 1.0f, 0);
depth.ConfigureClear(new Color(), 1.0f, 0);
albedo.ConfigureTarget(BuiltinRenderTextureType.CameraTarget, false, true);
var attachments = new NativeArray <AttachmentDescriptor>(5, Allocator.Temp);
const int depthIndex = 0, albedoIndex = 1, specRoughIndex = 2, normalIndex = 3, emissionIndex = 4;
attachments[depthIndex] = depth;
attachments[albedoIndex] = albedo;
attachments[specRoughIndex] = specRough;
attachments[normalIndex] = normal;
attachments[emissionIndex] = emission;
using (context.BeginScopedRenderPass(camera.pixelWidth, camera.pixelHeight, 1, attachments, depthIndex))
{
attachments.Dispose();
// Start the first subpass, GBuffer creation: render to albedo, specRough, normal and emission, no need to read any input attachments
var gbufferColors = new NativeArray <int>(4, Allocator.Temp);
gbufferColors[0] = albedoIndex;
gbufferColors[1] = specRoughIndex;
gbufferColors[2] = normalIndex;
gbufferColors[3] = emissionIndex;
using (context.BeginScopedSubPass(gbufferColors))
{
gbufferColors.Dispose();
// Render the deferred G-Buffer
RenderGbufferSubPass(context, cullingResults, camera);
}
// Second subpass, lighting: Render to the emission buffer, read from albedo, specRough, normal and depth.
// The last parameter indicates whether the depth buffer can be bound as read-only.
// Note that some renderers (notably iOS Metal) won't allow reading from the depth buffer while it's bound as Z-buffer,
// so those renderers should write the Z into an additional FP32 render target manually in the pixel shader and read from it instead
var lightingColors = new NativeArray <int>(1, Allocator.Temp);
lightingColors[0] = emissionIndex;
var lightingInputs = new NativeArray <int>(4, Allocator.Temp);
lightingInputs[0] = albedoIndex;
lightingInputs[1] = specRoughIndex;
lightingInputs[2] = normalIndex;
lightingInputs[3] = depthIndex;
using (context.BeginScopedSubPass(lightingColors, lightingInputs, true))
{
lightingColors.Dispose();
lightingInputs.Dispose();
// PushGlobalShadowParams(context);
RenderDeferredLightingSubPass(context, cullingResults, camera);
}
// Third subpass, tonemapping: Render to albedo (which is bound to the camera target), read from emission.
// var tonemappingColors = new NativeArray<int>(1, Allocator.Temp);
// tonemappingColors[0] = albedoIndex;
// var tonemappingInputs = new NativeArray<int>(1, Allocator.Temp);
// tonemappingInputs[0] = emissionIndex;
// using (context.BeginScopedSubPass(tonemappingColors, tonemappingInputs, true))
// {
// tonemappingColors.Dispose();
// tonemappingInputs.Dispose();
//
// // present frame buffer.
// // FinalPass(context);
// }
}
}
}
