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using System;
using System.Collections.Generic;
using UnityEngine;
using UnityEngine.Rendering;
using UnityEngine.Experimental.Rendering;
using UnityEngine.XR;
// Very basic scriptable rendering loop example:
// - Use with BasicRenderPipelineShader.shader (the loop expects "BasicPass" pass type to exist)
// - Supports up to 8 enabled lights in the scene (directional, point or spot)
// - Does the same physically based BRDF as the Standard shader
// - No shadows
// - This loop also does not setup lightmaps, light probes, reflection probes or light cookies
[ExecuteInEditMode]
public class BasicRenderPipeline : RenderPipelineAsset
{
public bool UseIntermediateRenderTargetBlit;
#if UNITY_EDITOR
[UnityEditor.MenuItem("RenderPipeline/Create BasicRenderPipeline")]
static void CreateBasicRenderPipeline()
{
var instance = ScriptableObject.CreateInstance<BasicRenderPipeline>();
UnityEditor.AssetDatabase.CreateAsset(instance, "Assets/BasicRenderPipelineTutorial/BasicRenderPipeline.asset");
}
#endif
protected override IRenderPipeline InternalCreatePipeline()
{
return new BasicRenderPipelineInstance(UseIntermediateRenderTargetBlit);
}
}
public class BasicRenderPipelineInstance : RenderPipeline
{
bool useIntermediateBlit;
public BasicRenderPipelineInstance()
{
useIntermediateBlit = false;
}
public BasicRenderPipelineInstance(bool useIntermediate)
{
useIntermediateBlit = useIntermediate;
}
public override void Render(ScriptableRenderContext renderContext, Camera[] cameras)
{
base.Render(renderContext, cameras);
BasicRendering.Render(renderContext, cameras, useIntermediateBlit);
}
}
public static class BasicRendering
{
static void ConfigureAndBindIntermediateRenderTarget(ScriptableRenderContext context, Camera cam, bool stereoEnabled, out RenderTargetIdentifier intermediateRTID, out bool isRTTexArray)
{
var intermediateRT = Shader.PropertyToID("_IntermediateTarget");
intermediateRTID = new RenderTargetIdentifier(intermediateRT);
isRTTexArray = false;
var bindIntermediateRTCmd = CommandBufferPool.Get("Bind intermediate RT");
if (stereoEnabled)
{
RenderTextureDescriptor xrDesc = XRSettings.eyeTextureDesc;
xrDesc.depthBufferBits = 24;
if (xrDesc.dimension == TextureDimension.Tex2DArray)
isRTTexArray = true;
bindIntermediateRTCmd.GetTemporaryRT(intermediateRT, xrDesc, FilterMode.Point);
}
else
{
int w = cam.pixelWidth;
int h = cam.pixelHeight;
bindIntermediateRTCmd.GetTemporaryRT(intermediateRT, w, h, 24, FilterMode.Point, RenderTextureFormat.Default, RenderTextureReadWrite.Default, 1, true);
}
if (isRTTexArray)
bindIntermediateRTCmd.SetRenderTarget(intermediateRTID, 0, CubemapFace.Unknown, -1); // depthSlice == -1 => bind all slices
else
bindIntermediateRTCmd.SetRenderTarget(intermediateRTID);
context.ExecuteCommandBuffer(bindIntermediateRTCmd);
CommandBufferPool.Release(bindIntermediateRTCmd);
}
static void BlitFromIntermediateToCameraTarget(ScriptableRenderContext context, RenderTargetIdentifier intermediateRTID, bool isRTTexArray)
{
var blitIntermediateRTCmd = CommandBufferPool.Get("Copy intermediate RT to default RT");
if (isRTTexArray)
{
// Currently, Blit does not allow specification of a slice in a texture array.
// It can use the CurrentActive render texture's bound slices, so we use that
// as a temporary workaround.
blitIntermediateRTCmd.SetRenderTarget(BuiltinRenderTextureType.CameraTarget, 0, CubemapFace.Unknown, -1);
blitIntermediateRTCmd.Blit(intermediateRTID, BuiltinRenderTextureType.CurrentActive);
}
else
blitIntermediateRTCmd.Blit(intermediateRTID, BuiltinRenderTextureType.CameraTarget);
context.ExecuteCommandBuffer(blitIntermediateRTCmd);
CommandBufferPool.Release(blitIntermediateRTCmd);
}
// Main entry point for our scriptable render loop
public static void Render(ScriptableRenderContext context, IEnumerable<Camera> cameras, bool useIntermediateBlitPath)
{
bool stereoEnabled = XRSettings.isDeviceActive;
foreach (var camera in cameras)
{
// Culling
ScriptableCullingParameters cullingParams;
// Stereo-aware culling parameters are configured to perform a single cull for both eyes
if (!CullResults.GetCullingParameters(camera, stereoEnabled, out cullingParams))
continue;
CullResults cull = new CullResults();
CullResults.Cull(ref cullingParams, context, ref cull);
// Setup camera for rendering (sets render target, view/projection matrices and other
// per-camera built-in shader variables).
// If stereo is enabled, we also configure stereo matrices, viewports, and XR device render targets
context.SetupCameraProperties(camera, stereoEnabled);
// Draws in-between [Start|Stop]MultiEye are stereo-ized by engine
if (stereoEnabled)
context.StartMultiEye(camera);
RenderTargetIdentifier intermediateRTID = new RenderTargetIdentifier(BuiltinRenderTextureType.CurrentActive);
bool isIntermediateRTTexArray = false;
if (useIntermediateBlitPath)
{
ConfigureAndBindIntermediateRenderTarget(context, camera, stereoEnabled, out intermediateRTID, out isIntermediateRTTexArray);
}
// clear depth buffer
var cmd = CommandBufferPool.Get();
cmd.ClearRenderTarget(true, false, Color.black);
context.ExecuteCommandBuffer(cmd);
CommandBufferPool.Release(cmd);
// Setup global lighting shader variables
SetupLightShaderVariables(cull.visibleLights, context);
// Draw opaque objects using BasicPass shader pass
var settings = new DrawRendererSettings(cull, camera, new ShaderPassName("BasicPass"));
settings.sorting.flags = SortFlags.CommonOpaque;
settings.inputFilter.SetQueuesOpaque();
context.DrawRenderers(ref settings);
// Draw skybox
context.DrawSkybox(camera);
// Draw transparent objects using BasicPass shader pass
settings.sorting.flags = SortFlags.CommonTransparent;
settings.inputFilter.SetQueuesTransparent();
context.DrawRenderers(ref settings);
if (useIntermediateBlitPath)
{
BlitFromIntermediateToCameraTarget(context, intermediateRTID, isIntermediateRTTexArray);
}
if (stereoEnabled)
{
context.StopMultiEye(camera);
// StereoEndRender will reset state on the camera to pre-Stereo settings,
// and invoke XR based events/callbacks.
context.StereoEndRender(camera);
}
context.Submit();
}
}
// Setup lighting variables for shader to use
private static void SetupLightShaderVariables(List<VisibleLight> lights, ScriptableRenderContext context)
{
// We only support up to 8 visible lights here. More complex approaches would
// be doing some sort of per-object light setups, but here we go for simplest possible
// approach.
const int kMaxLights = 8;
// Just take first 8 lights. Possible improvements: sort lights by intensity or distance
// to the viewer, so that "most important" lights in the scene are picked, and not the 8
// that happened to be first.
int lightCount = Mathf.Min(lights.Count, kMaxLights);
// Prepare light data
Vector4[] lightColors = new Vector4[kMaxLights];
Vector4[] lightPositions = new Vector4[kMaxLights];
Vector4[] lightSpotDirections = new Vector4[kMaxLights];
Vector4[] lightAtten = new Vector4[kMaxLights];
for (var i = 0; i < lightCount; ++i)
{
VisibleLight light = lights[i];
lightColors[i] = light.finalColor;
if (light.lightType == LightType.Directional)
{
// light position for directional lights is: (-direction, 0)
var dir = light.localToWorld.GetColumn(2);
lightPositions[i] = new Vector4(-dir.x, -dir.y, -dir.z, 0);
}
else
{
// light position for point/spot lights is: (position, 1)
var pos = light.localToWorld.GetColumn(3);
lightPositions[i] = new Vector4(pos.x, pos.y, pos.z, 1);
}
// attenuation set in a way where distance attenuation can be computed:
// float lengthSq = dot(toLight, toLight);
// float atten = 1.0 / (1.0 + lengthSq * LightAtten[i].z);
// and spot cone attenuation:
// float rho = max (0, dot(normalize(toLight), SpotDirection[i].xyz));
// float spotAtt = (rho - LightAtten[i].x) * LightAtten[i].y;
// spotAtt = saturate(spotAtt);
// and the above works for all light types, i.e. spot light code works out
// to correct math for point & directional lights as well.
float rangeSq = light.range * light.range;
float quadAtten = (light.lightType == LightType.Directional) ? 0.0f : 25.0f / rangeSq;
// spot direction & attenuation
if (light.lightType == LightType.Spot)
{
var dir = light.localToWorld.GetColumn(2);
lightSpotDirections[i] = new Vector4(-dir.x, -dir.y, -dir.z, 0);
float radAngle = Mathf.Deg2Rad * light.spotAngle;
float cosTheta = Mathf.Cos(radAngle * 0.25f);
float cosPhi = Mathf.Cos(radAngle * 0.5f);
float cosDiff = cosTheta - cosPhi;
lightAtten[i] = new Vector4(cosPhi, (cosDiff != 0.0f) ? 1.0f / cosDiff : 1.0f, quadAtten, rangeSq);
}
else
{
// non-spot light
lightSpotDirections[i] = new Vector4(0, 0, 1, 0);
lightAtten[i] = new Vector4(-1, 1, quadAtten, rangeSq);
}
}
// ambient lighting spherical harmonics values
const int kSHCoefficients = 7;
Vector4[] shConstants = new Vector4[kSHCoefficients];
SphericalHarmonicsL2 ambientSH = RenderSettings.ambientProbe * RenderSettings.ambientIntensity;
GetShaderConstantsFromNormalizedSH(ref ambientSH, shConstants);
// setup global shader variables to contain all the data computed above
CommandBuffer cmd = CommandBufferPool.Get();
cmd.SetGlobalVectorArray("globalLightColor", lightColors);
cmd.SetGlobalVectorArray("globalLightPos", lightPositions);
cmd.SetGlobalVectorArray("globalLightSpotDir", lightSpotDirections);
cmd.SetGlobalVectorArray("globalLightAtten", lightAtten);
cmd.SetGlobalVector("globalLightCount", new Vector4(lightCount, 0, 0, 0));
cmd.SetGlobalVectorArray("globalSH", shConstants);
context.ExecuteCommandBuffer(cmd);
CommandBufferPool.Release(cmd);
}
// Prepare L2 spherical harmonics values for efficient evaluation in a shader
private static void GetShaderConstantsFromNormalizedSH(ref SphericalHarmonicsL2 ambientProbe, Vector4[] outCoefficients)
{
for (int channelIdx = 0; channelIdx < 3; ++channelIdx)
{
// Constant + Linear
// In the shader we multiply the normal is not swizzled, so it's normal.xyz.
// Swizzle the coefficients to be in { x, y, z, DC } order.
outCoefficients[channelIdx].x = ambientProbe[channelIdx, 3];
outCoefficients[channelIdx].y = ambientProbe[channelIdx, 1];
outCoefficients[channelIdx].z = ambientProbe[channelIdx, 2];
outCoefficients[channelIdx].w = ambientProbe[channelIdx, 0] - ambientProbe[channelIdx, 6];
// Quadratic polynomials
outCoefficients[channelIdx + 3].x = ambientProbe[channelIdx, 4];
outCoefficients[channelIdx + 3].y = ambientProbe[channelIdx, 5];
outCoefficients[channelIdx + 3].z = ambientProbe[channelIdx, 6] * 3.0f;
outCoefficients[channelIdx + 3].w = ambientProbe[channelIdx, 7];
}
// Final quadratic polynomial
outCoefficients[6].x = ambientProbe[0, 8];
outCoefficients[6].y = ambientProbe[1, 8];
outCoefficients[6].z = ambientProbe[2, 8];
outCoefficients[6].w = 1.0f;
}
}