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Singularity/Library/PackageCache/com.unity.shadergraph@12.1.11/Editor/Generation/Processors/GenerationUtils.cs

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first commit
2024-05-06 14:45:45 -04:00
using System;
using System.Collections.Generic;
using System.IO;
using System.Linq;
using UnityEditor.Graphing;
using UnityEditor.ShaderGraph.Internal;
using UnityEngine.Profiling;
using Pool = UnityEngine.Pool;
namespace UnityEditor.ShaderGraph
{
internal static class GenerationUtils
{
const string kErrorString = @"ERROR!";
internal static List<FieldDescriptor> GetActiveFieldsFromConditionals(ConditionalField[] conditionalFields)
{
var fields = new List<FieldDescriptor>();
if (conditionalFields != null)
{
foreach (ConditionalField conditionalField in conditionalFields)
{
if (conditionalField.condition == true)
{
fields.Add(conditionalField.field);
}
}
}
return fields;
}
internal static void GenerateSubShaderTags(Target target, SubShaderDescriptor descriptor, ShaderStringBuilder builder)
{
builder.AppendLine("Tags");
using (builder.BlockScope())
{
// Pipeline tag
if (!string.IsNullOrEmpty(descriptor.pipelineTag))
builder.AppendLine($"\"RenderPipeline\"=\"{descriptor.pipelineTag}\"");
else
builder.AppendLine("// RenderPipeline: <None>");
// Render Type
if (!string.IsNullOrEmpty(descriptor.renderType))
builder.AppendLine($"\"RenderType\"=\"{descriptor.renderType}\"");
else
builder.AppendLine("// RenderType: <None>");
// Custom shader tags.
if (!string.IsNullOrEmpty(descriptor.customTags))
builder.AppendLine(descriptor.customTags);
// Render Queue
if (!string.IsNullOrEmpty(descriptor.renderQueue))
builder.AppendLine($"\"Queue\"=\"{descriptor.renderQueue}\"");
else
builder.AppendLine("// Queue: <None>");
// ShaderGraphShader tag (so we can tell what shadergraph built)
builder.AppendLine("\"ShaderGraphShader\"=\"true\"");
if (target is IHasMetadata metadata)
builder.AppendLine($"\"ShaderGraphTargetId\"=\"{metadata.identifier}\"");
}
}
static bool IsFieldActive(FieldDescriptor field, IActiveFields activeFields, bool isOptional)
{
bool fieldActive = true;
if (!activeFields.Contains(field) && isOptional)
fieldActive = false; //if the field is optional and not inside of active fields
return fieldActive;
}
internal static void GenerateShaderStruct(StructDescriptor shaderStruct, ActiveFields activeFields, bool humanReadable, out ShaderStringBuilder structBuilder)
{
structBuilder = new ShaderStringBuilder(humanReadable: humanReadable);
structBuilder.AppendLine($"struct {shaderStruct.name}");
using (structBuilder.BlockSemicolonScope())
{
foreach (FieldDescriptor subscript in shaderStruct.fields)
{
bool fieldIsActive;
var keywordIfDefs = string.Empty;
if (activeFields.permutationCount > 0)
{
//find all active fields per permutation
var instances = activeFields.allPermutations.instances
.Where(i => IsFieldActive(subscript, i, subscript.subscriptOptions.HasFlag(StructFieldOptions.Optional))).ToList();
fieldIsActive = instances.Count > 0;
if (fieldIsActive)
keywordIfDefs = KeywordUtil.GetKeywordPermutationSetConditional(instances.Select(i => i.permutationIndex).ToList());
}
else
fieldIsActive = IsFieldActive(subscript, activeFields.baseInstance, subscript.subscriptOptions.HasFlag(StructFieldOptions.Optional));
//else just find active fields
if (fieldIsActive)
{
//if field is active:
if (subscript.HasPreprocessor())
structBuilder.AppendLine($"#if {subscript.preprocessor}");
//if in permutation, add permutation ifdef
if (!string.IsNullOrEmpty(keywordIfDefs))
structBuilder.AppendLine(keywordIfDefs);
//check for a semantic, build string if valid
string semantic = subscript.HasSemantic() ? $" : {subscript.semantic}" : string.Empty;
structBuilder.AppendLine($"{subscript.interpolation} {subscript.type} {subscript.name}{semantic};");
//if in permutation, add permutation endif
if (!string.IsNullOrEmpty(keywordIfDefs))
structBuilder.AppendLine("#endif"); //TODO: add debug collector
if (subscript.HasPreprocessor())
structBuilder.AppendLine("#endif");
}
}
}
}
internal static void GeneratePackedStruct(StructDescriptor shaderStruct, ActiveFields activeFields, out StructDescriptor packStruct)
{
packStruct = new StructDescriptor()
{
name = "Packed" + shaderStruct.name,
packFields = true,
fields = new FieldDescriptor[] { }
};
List<FieldDescriptor> packedSubscripts = new List<FieldDescriptor>();
List<FieldDescriptor> postUnpackedSubscripts = new List<FieldDescriptor>();
List<int> packedCounts = new List<int>();
foreach (FieldDescriptor subscript in shaderStruct.fields)
{
var fieldIsActive = false;
var keywordIfDefs = string.Empty;
if (activeFields.permutationCount > 0)
{
//find all active fields per permutation
var instances = activeFields.allPermutations.instances
.Where(i => IsFieldActive(subscript, i, subscript.subscriptOptions.HasFlag(StructFieldOptions.Optional))).ToList();
fieldIsActive = instances.Count > 0;
if (fieldIsActive)
keywordIfDefs = KeywordUtil.GetKeywordPermutationSetConditional(instances.Select(i => i.permutationIndex).ToList());
}
else
fieldIsActive = IsFieldActive(subscript, activeFields.baseInstance, subscript.subscriptOptions.HasFlag(StructFieldOptions.Optional));
//else just find active fields
if (fieldIsActive)
{
// special case, "UNITY_STEREO_INSTANCING_ENABLED" fields must be packed at the end of the struct because they are system generated semantics
//
if (subscript.HasPreprocessor() && (subscript.preprocessor.Contains("INSTANCING")))
postUnpackedSubscripts.Add(subscript);
// special case, "SHADER_STAGE_FRAGMENT" fields must be packed at the end of the struct,
// otherwise the vertex output struct will have different semantic ordering than the fragment input struct.
//
else if (subscript.HasPreprocessor() && (subscript.preprocessor.Contains("SHADER_STAGE_FRAGMENT")))
postUnpackedSubscripts.Add(subscript);
else if (subscript.HasSemantic() || subscript.vectorCount == 0)
packedSubscripts.Add(subscript);
else
{
// pack float field
int vectorCount = subscript.vectorCount;
// super simple packing: use the first interpolator that has room for the whole value
int interpIndex = packedCounts.FindIndex(x => (x + vectorCount <= 4));
int firstChannel;
if (interpIndex < 0 || subscript.HasPreprocessor())
{
// allocate a new interpolator
interpIndex = packedCounts.Count;
firstChannel = 0;
packedCounts.Add(vectorCount);
}
else
{
// pack into existing interpolator
firstChannel = packedCounts[interpIndex];
packedCounts[interpIndex] += vectorCount;
}
}
}
}
for (int i = 0; i < packedCounts.Count(); ++i)
{
// todo: ensure this packing adjustment doesn't waste interpolators when many preprocessors are in use.
var packedSubscript = new FieldDescriptor(packStruct.name, "interp" + i, "", "float" + packedCounts[i], "INTERP" + i, "", StructFieldOptions.Static);
packedSubscripts.Add(packedSubscript);
}
packStruct.fields = packedSubscripts.Concat(postUnpackedSubscripts).ToArray();
}
internal static void GenerateInterpolatorFunctions(StructDescriptor shaderStruct, IActiveFields activeFields, bool humanReadable, out ShaderStringBuilder interpolatorBuilder)
{
//set up function string builders and struct builder
List<int> packedCounts = new List<int>();
var packBuilder = new ShaderStringBuilder(humanReadable: humanReadable);
var unpackBuilder = new ShaderStringBuilder(humanReadable: humanReadable);
interpolatorBuilder = new ShaderStringBuilder(humanReadable: humanReadable);
string packedStruct = "Packed" + shaderStruct.name;
//declare function headers
packBuilder.AppendLine($"{packedStruct} Pack{shaderStruct.name} ({shaderStruct.name} input)");
packBuilder.AppendLine("{");
packBuilder.IncreaseIndent();
packBuilder.AppendLine($"{packedStruct} output;");
packBuilder.AppendLine($"ZERO_INITIALIZE({packedStruct}, output);");
unpackBuilder.AppendLine($"{shaderStruct.name} Unpack{shaderStruct.name} ({packedStruct} input)");
unpackBuilder.AppendLine("{");
unpackBuilder.IncreaseIndent();
unpackBuilder.AppendLine($"{shaderStruct.name} output;");
foreach (FieldDescriptor subscript in shaderStruct.fields)
{
if (IsFieldActive(subscript, activeFields, subscript.subscriptOptions.HasFlag(StructFieldOptions.Optional)))
{
int vectorCount = subscript.vectorCount;
if (subscript.HasPreprocessor())
{
packBuilder.AppendLine($"#if {subscript.preprocessor}");
unpackBuilder.AppendLine($"#if {subscript.preprocessor}");
}
if (subscript.HasSemantic() || vectorCount == 0)
{
packBuilder.AppendLine($"output.{subscript.name} = input.{subscript.name};");
unpackBuilder.AppendLine($"output.{subscript.name} = input.{subscript.name};");
}
else
{
// pack float field
// super simple packing: use the first interpolator that has room for the whole value
int interpIndex = packedCounts.FindIndex(x => (x + vectorCount <= 4));
int firstChannel;
if (interpIndex < 0 || subscript.HasPreprocessor())
{
// allocate a new interpolator
interpIndex = packedCounts.Count;
firstChannel = 0;
packedCounts.Add(vectorCount);
}
else
{
// pack into existing interpolator
firstChannel = packedCounts[interpIndex];
packedCounts[interpIndex] += vectorCount;
}
// add code to packer and unpacker -- add subscript to packedstruct
string packedChannels = ShaderSpliceUtil.GetChannelSwizzle(firstChannel, vectorCount);
string index = interpIndex.ToString();
packBuilder.AppendLine($"output.interp{index}.{packedChannels} = input.{subscript.name};");
unpackBuilder.AppendLine($"output.{subscript.name} = input.interp{index}.{packedChannels};");
}
if (subscript.HasPreprocessor())
{
packBuilder.AppendLine("#endif");
unpackBuilder.AppendLine("#endif");
}
}
}
//close function declarations
packBuilder.AppendLine("return output;");
packBuilder.DecreaseIndent();
packBuilder.AppendLine("}");
packBuilder.AppendNewLine();
unpackBuilder.AppendLine("return output;");
unpackBuilder.DecreaseIndent();
unpackBuilder.AppendLine("}");
unpackBuilder.AppendNewLine();
interpolatorBuilder.Concat(packBuilder);
interpolatorBuilder.Concat(unpackBuilder);
}
internal static void GetUpstreamNodesForShaderPass(AbstractMaterialNode outputNode, PassDescriptor pass, out List<AbstractMaterialNode> vertexNodes, out List<AbstractMaterialNode> pixelNodes)
{
// Traverse Graph Data
vertexNodes = Pool.ListPool<AbstractMaterialNode>.Get();
NodeUtils.DepthFirstCollectNodesFromNode(vertexNodes, outputNode, NodeUtils.IncludeSelf.Include);
pixelNodes = Pool.ListPool<AbstractMaterialNode>.Get();
NodeUtils.DepthFirstCollectNodesFromNode(pixelNodes, outputNode, NodeUtils.IncludeSelf.Include);
}
internal static void GetActiveFieldsAndPermutationsForNodes(PassDescriptor pass,
KeywordCollector keywordCollector, List<AbstractMaterialNode> vertexNodes, List<AbstractMaterialNode> pixelNodes,
List<int>[] vertexNodePermutations, List<int>[] pixelNodePermutations,
ActiveFields activeFields, out ShaderGraphRequirementsPerKeyword graphRequirements)
{
// Initialize requirements
ShaderGraphRequirementsPerKeyword pixelRequirements = new ShaderGraphRequirementsPerKeyword();
ShaderGraphRequirementsPerKeyword vertexRequirements = new ShaderGraphRequirementsPerKeyword();
graphRequirements = new ShaderGraphRequirementsPerKeyword();
// Evaluate all Keyword permutations
if (keywordCollector.permutations.Count > 0)
{
for (int i = 0; i < keywordCollector.permutations.Count; i++)
{
// Get active nodes for this permutation
var localVertexNodes = Pool.ListPool<AbstractMaterialNode>.Get();
var localPixelNodes = Pool.ListPool<AbstractMaterialNode>.Get();
foreach (var vertexNode in vertexNodes)
{
NodeUtils.DepthFirstCollectNodesFromNode(localVertexNodes, vertexNode, NodeUtils.IncludeSelf.Include, keywordCollector.permutations[i]);
}
foreach (var pixelNode in pixelNodes)
{
NodeUtils.DepthFirstCollectNodesFromNode(localPixelNodes, pixelNode, NodeUtils.IncludeSelf.Include, keywordCollector.permutations[i]);
}
// Track each vertex node in this permutation
foreach (AbstractMaterialNode vertexNode in localVertexNodes)
{
int nodeIndex = vertexNodes.IndexOf(vertexNode);
if (vertexNodePermutations[nodeIndex] == null)
vertexNodePermutations[nodeIndex] = new List<int>();
vertexNodePermutations[nodeIndex].Add(i);
}
// Track each pixel node in this permutation
foreach (AbstractMaterialNode pixelNode in localPixelNodes)
{
int nodeIndex = pixelNodes.IndexOf(pixelNode);
if (pixelNodePermutations[nodeIndex] == null)
pixelNodePermutations[nodeIndex] = new List<int>();
pixelNodePermutations[nodeIndex].Add(i);
}
// Get requirements for this permutation
vertexRequirements[i].SetRequirements(ShaderGraphRequirements.FromNodes(localVertexNodes, ShaderStageCapability.Vertex, false));
pixelRequirements[i].SetRequirements(ShaderGraphRequirements.FromNodes(localPixelNodes, ShaderStageCapability.Fragment, false));
// Add active fields
var conditionalFields = GetActiveFieldsFromConditionals(GetConditionalFieldsFromPixelRequirements(pixelRequirements[i].requirements));
if (activeFields[i].Contains(Fields.GraphVertex))
{
conditionalFields.AddRange(GetActiveFieldsFromConditionals(GetConditionalFieldsFromVertexRequirements(vertexRequirements[i].requirements)));
}
foreach (var field in conditionalFields)
{
activeFields[i].Add(field);
}
}
}
// No Keywords
else
{
// Get requirements
vertexRequirements.baseInstance.SetRequirements(ShaderGraphRequirements.FromNodes(vertexNodes, ShaderStageCapability.Vertex, false));
pixelRequirements.baseInstance.SetRequirements(ShaderGraphRequirements.FromNodes(pixelNodes, ShaderStageCapability.Fragment, false));
// Add active fields
var conditionalFields = GetActiveFieldsFromConditionals(GetConditionalFieldsFromPixelRequirements(pixelRequirements.baseInstance.requirements));
if (activeFields.baseInstance.Contains(Fields.GraphVertex))
{
conditionalFields.AddRange(GetActiveFieldsFromConditionals(GetConditionalFieldsFromVertexRequirements(vertexRequirements.baseInstance.requirements)));
}
foreach (var field in conditionalFields)
{
activeFields.baseInstance.Add(field);
}
}
// Build graph requirements
graphRequirements.UnionWith(pixelRequirements);
graphRequirements.UnionWith(vertexRequirements);
}
static ConditionalField[] GetConditionalFieldsFromVertexRequirements(ShaderGraphRequirements requirements)
{
return new ConditionalField[]
{
new ConditionalField(StructFields.VertexDescriptionInputs.ScreenPosition, requirements.requiresScreenPosition),
new ConditionalField(StructFields.VertexDescriptionInputs.VertexColor, requirements.requiresVertexColor),
new ConditionalField(StructFields.VertexDescriptionInputs.ObjectSpaceNormal, (requirements.requiresNormal & NeededCoordinateSpace.Object) > 0),
new ConditionalField(StructFields.VertexDescriptionInputs.ViewSpaceNormal, (requirements.requiresNormal & NeededCoordinateSpace.View) > 0),
new ConditionalField(StructFields.VertexDescriptionInputs.WorldSpaceNormal, (requirements.requiresNormal & NeededCoordinateSpace.World) > 0),
new ConditionalField(StructFields.VertexDescriptionInputs.TangentSpaceNormal, (requirements.requiresNormal & NeededCoordinateSpace.Tangent) > 0),
new ConditionalField(StructFields.VertexDescriptionInputs.ObjectSpaceViewDirection, (requirements.requiresViewDir & NeededCoordinateSpace.Object) > 0),
new ConditionalField(StructFields.VertexDescriptionInputs.ViewSpaceViewDirection, (requirements.requiresViewDir & NeededCoordinateSpace.View) > 0),
new ConditionalField(StructFields.VertexDescriptionInputs.WorldSpaceViewDirection, (requirements.requiresViewDir & NeededCoordinateSpace.World) > 0),
new ConditionalField(StructFields.VertexDescriptionInputs.TangentSpaceViewDirection, (requirements.requiresViewDir & NeededCoordinateSpace.Tangent) > 0),
new ConditionalField(StructFields.VertexDescriptionInputs.ObjectSpaceTangent, (requirements.requiresTangent & NeededCoordinateSpace.Object) > 0),
new ConditionalField(StructFields.VertexDescriptionInputs.ViewSpaceTangent, (requirements.requiresTangent & NeededCoordinateSpace.View) > 0),
new ConditionalField(StructFields.VertexDescriptionInputs.WorldSpaceTangent, (requirements.requiresTangent & NeededCoordinateSpace.World) > 0),
new ConditionalField(StructFields.VertexDescriptionInputs.TangentSpaceTangent, (requirements.requiresTangent & NeededCoordinateSpace.Tangent) > 0),
new ConditionalField(StructFields.VertexDescriptionInputs.ObjectSpaceBiTangent, (requirements.requiresBitangent & NeededCoordinateSpace.Object) > 0),
new ConditionalField(StructFields.VertexDescriptionInputs.ViewSpaceBiTangent, (requirements.requiresBitangent & NeededCoordinateSpace.View) > 0),
new ConditionalField(StructFields.VertexDescriptionInputs.WorldSpaceBiTangent, (requirements.requiresBitangent & NeededCoordinateSpace.World) > 0),
new ConditionalField(StructFields.VertexDescriptionInputs.TangentSpaceBiTangent, (requirements.requiresBitangent & NeededCoordinateSpace.Tangent) > 0),
new ConditionalField(StructFields.VertexDescriptionInputs.ObjectSpacePosition, (requirements.requiresPosition & NeededCoordinateSpace.Object) > 0),
new ConditionalField(StructFields.VertexDescriptionInputs.ViewSpacePosition, (requirements.requiresPosition & NeededCoordinateSpace.View) > 0),
new ConditionalField(StructFields.VertexDescriptionInputs.WorldSpacePosition, (requirements.requiresPosition & NeededCoordinateSpace.World) > 0),
new ConditionalField(StructFields.VertexDescriptionInputs.TangentSpacePosition, (requirements.requiresPosition & NeededCoordinateSpace.Tangent) > 0),
new ConditionalField(StructFields.VertexDescriptionInputs.AbsoluteWorldSpacePosition, (requirements.requiresPosition & NeededCoordinateSpace.AbsoluteWorld) > 0),
new ConditionalField(StructFields.VertexDescriptionInputs.ObjectSpacePositionPredisplacement, (requirements.requiresPositionPredisplacement & NeededCoordinateSpace.Object) > 0),
new ConditionalField(StructFields.VertexDescriptionInputs.ViewSpacePositionPredisplacement, (requirements.requiresPositionPredisplacement & NeededCoordinateSpace.View) > 0),
new ConditionalField(StructFields.VertexDescriptionInputs.WorldSpacePositionPredisplacement, (requirements.requiresPositionPredisplacement & NeededCoordinateSpace.World) > 0),
new ConditionalField(StructFields.VertexDescriptionInputs.TangentSpacePositionPredisplacement, (requirements.requiresPositionPredisplacement & NeededCoordinateSpace.Tangent) > 0),
new ConditionalField(StructFields.VertexDescriptionInputs.AbsoluteWorldSpacePositionPredisplacement, (requirements.requiresPositionPredisplacement & NeededCoordinateSpace.AbsoluteWorld) > 0),
new ConditionalField(StructFields.VertexDescriptionInputs.uv0, requirements.requiresMeshUVs.Contains(UVChannel.UV0)),
new ConditionalField(StructFields.VertexDescriptionInputs.uv1, requirements.requiresMeshUVs.Contains(UVChannel.UV1)),
new ConditionalField(StructFields.VertexDescriptionInputs.uv2, requirements.requiresMeshUVs.Contains(UVChannel.UV2)),
new ConditionalField(StructFields.VertexDescriptionInputs.uv3, requirements.requiresMeshUVs.Contains(UVChannel.UV3)),
new ConditionalField(StructFields.VertexDescriptionInputs.TimeParameters, requirements.requiresTime),
new ConditionalField(StructFields.VertexDescriptionInputs.BoneWeights, requirements.requiresVertexSkinning),
new ConditionalField(StructFields.VertexDescriptionInputs.BoneIndices, requirements.requiresVertexSkinning),
new ConditionalField(StructFields.VertexDescriptionInputs.VertexID, requirements.requiresVertexID),
new ConditionalField(Fields.ObjectToWorld, requirements.requiresTransforms.Contains(NeededTransform.ObjectToWorld)),
new ConditionalField(Fields.WorldToObject, requirements.requiresTransforms.Contains(NeededTransform.WorldToObject)),
};
}
static ConditionalField[] GetConditionalFieldsFromPixelRequirements(ShaderGraphRequirements requirements)
{
return new ConditionalField[]
{
new ConditionalField(StructFields.SurfaceDescriptionInputs.ScreenPosition, requirements.requiresScreenPosition),
new ConditionalField(StructFields.SurfaceDescriptionInputs.VertexColor, requirements.requiresVertexColor),
new ConditionalField(StructFields.SurfaceDescriptionInputs.FaceSign, requirements.requiresFaceSign),
new ConditionalField(StructFields.SurfaceDescriptionInputs.ObjectSpaceNormal, (requirements.requiresNormal & NeededCoordinateSpace.Object) > 0),
new ConditionalField(StructFields.SurfaceDescriptionInputs.ViewSpaceNormal, (requirements.requiresNormal & NeededCoordinateSpace.View) > 0),
new ConditionalField(StructFields.SurfaceDescriptionInputs.WorldSpaceNormal, (requirements.requiresNormal & NeededCoordinateSpace.World) > 0),
new ConditionalField(StructFields.SurfaceDescriptionInputs.TangentSpaceNormal, (requirements.requiresNormal & NeededCoordinateSpace.Tangent) > 0),
new ConditionalField(StructFields.SurfaceDescriptionInputs.ObjectSpaceViewDirection, (requirements.requiresViewDir & NeededCoordinateSpace.Object) > 0),
new ConditionalField(StructFields.SurfaceDescriptionInputs.ViewSpaceViewDirection, (requirements.requiresViewDir & NeededCoordinateSpace.View) > 0),
new ConditionalField(StructFields.SurfaceDescriptionInputs.WorldSpaceViewDirection, (requirements.requiresViewDir & NeededCoordinateSpace.World) > 0),
new ConditionalField(StructFields.SurfaceDescriptionInputs.TangentSpaceViewDirection, (requirements.requiresViewDir & NeededCoordinateSpace.Tangent) > 0),
new ConditionalField(StructFields.SurfaceDescriptionInputs.ObjectSpaceTangent, (requirements.requiresTangent & NeededCoordinateSpace.Object) > 0),
new ConditionalField(StructFields.SurfaceDescriptionInputs.ViewSpaceTangent, (requirements.requiresTangent & NeededCoordinateSpace.View) > 0),
new ConditionalField(StructFields.SurfaceDescriptionInputs.WorldSpaceTangent, (requirements.requiresTangent & NeededCoordinateSpace.World) > 0),
new ConditionalField(StructFields.SurfaceDescriptionInputs.TangentSpaceTangent, (requirements.requiresTangent & NeededCoordinateSpace.Tangent) > 0),
new ConditionalField(StructFields.SurfaceDescriptionInputs.ObjectSpaceBiTangent, (requirements.requiresBitangent & NeededCoordinateSpace.Object) > 0),
new ConditionalField(StructFields.SurfaceDescriptionInputs.ViewSpaceBiTangent, (requirements.requiresBitangent & NeededCoordinateSpace.View) > 0),
new ConditionalField(StructFields.SurfaceDescriptionInputs.WorldSpaceBiTangent, (requirements.requiresBitangent & NeededCoordinateSpace.World) > 0),
new ConditionalField(StructFields.SurfaceDescriptionInputs.TangentSpaceBiTangent, (requirements.requiresBitangent & NeededCoordinateSpace.Tangent) > 0),
new ConditionalField(StructFields.SurfaceDescriptionInputs.ObjectSpacePosition, (requirements.requiresPosition & NeededCoordinateSpace.Object) > 0),
new ConditionalField(StructFields.SurfaceDescriptionInputs.ViewSpacePosition, (requirements.requiresPosition & NeededCoordinateSpace.View) > 0),
new ConditionalField(StructFields.SurfaceDescriptionInputs.WorldSpacePosition, (requirements.requiresPosition & NeededCoordinateSpace.World) > 0),
new ConditionalField(StructFields.SurfaceDescriptionInputs.TangentSpacePosition, (requirements.requiresPosition & NeededCoordinateSpace.Tangent) > 0),
new ConditionalField(StructFields.SurfaceDescriptionInputs.AbsoluteWorldSpacePosition, (requirements.requiresPosition & NeededCoordinateSpace.AbsoluteWorld) > 0),
new ConditionalField(StructFields.SurfaceDescriptionInputs.ObjectSpacePositionPredisplacement, (requirements.requiresPositionPredisplacement & NeededCoordinateSpace.Object) > 0),
new ConditionalField(StructFields.SurfaceDescriptionInputs.ViewSpacePositionPredisplacement, (requirements.requiresPositionPredisplacement & NeededCoordinateSpace.View) > 0),
new ConditionalField(StructFields.SurfaceDescriptionInputs.WorldSpacePositionPredisplacement, (requirements.requiresPositionPredisplacement & NeededCoordinateSpace.World) > 0),
new ConditionalField(StructFields.SurfaceDescriptionInputs.TangentSpacePositionPredisplacement, (requirements.requiresPositionPredisplacement & NeededCoordinateSpace.Tangent) > 0),
new ConditionalField(StructFields.SurfaceDescriptionInputs.AbsoluteWorldSpacePositionPredisplacement, (requirements.requiresPositionPredisplacement & NeededCoordinateSpace.AbsoluteWorld) > 0),
new ConditionalField(StructFields.SurfaceDescriptionInputs.uv0, requirements.requiresMeshUVs.Contains(UVChannel.UV0)),
new ConditionalField(StructFields.SurfaceDescriptionInputs.uv1, requirements.requiresMeshUVs.Contains(UVChannel.UV1)),
new ConditionalField(StructFields.SurfaceDescriptionInputs.uv2, requirements.requiresMeshUVs.Contains(UVChannel.UV2)),
new ConditionalField(StructFields.SurfaceDescriptionInputs.uv3, requirements.requiresMeshUVs.Contains(UVChannel.UV3)),
new ConditionalField(StructFields.SurfaceDescriptionInputs.TimeParameters, requirements.requiresTime),
new ConditionalField(StructFields.SurfaceDescriptionInputs.BoneWeights, requirements.requiresVertexSkinning),
new ConditionalField(StructFields.SurfaceDescriptionInputs.BoneIndices, requirements.requiresVertexSkinning),
new ConditionalField(StructFields.SurfaceDescriptionInputs.VertexID, requirements.requiresVertexID),
new ConditionalField(Fields.ObjectToWorld, requirements.requiresTransforms.Contains(NeededTransform.ObjectToWorld)),
new ConditionalField(Fields.WorldToObject, requirements.requiresTransforms.Contains(NeededTransform.WorldToObject)),
};
}
internal static void AddRequiredFields(FieldCollection passRequiredFields, IActiveFieldsSet activeFields)
{
if (passRequiredFields != null)
{
foreach (FieldCollection.Item requiredField in passRequiredFields)
{
activeFields.AddAll(requiredField.field);
}
}
}
internal static void ApplyFieldDependencies(IActiveFields activeFields, DependencyCollection dependencies)
{
// add active fields to queue
Queue<FieldDescriptor> fieldsToPropagate = new Queue<FieldDescriptor>();
foreach (var f in activeFields.fields)
{
fieldsToPropagate.Enqueue(f);
}
// foreach field in queue:
while (fieldsToPropagate.Count > 0)
{
FieldDescriptor field = fieldsToPropagate.Dequeue();
if (activeFields.Contains(field)) // this should always be true
{
if (dependencies == null)
return;
// find all dependencies of field that are not already active
foreach (DependencyCollection.Item d in dependencies.Where(d => (d.dependency.field == field) && !activeFields.Contains(d.dependency.dependsOn)))
{
// activate them and add them to the queue
activeFields.Add(d.dependency.dependsOn);
fieldsToPropagate.Enqueue(d.dependency.dependsOn);
}
}
}
}
internal static List<MaterialSlot> FindMaterialSlotsOnNode(IEnumerable<int> slots, AbstractMaterialNode node)
{
if (slots == null)
return null;
var activeSlots = new List<MaterialSlot>();
foreach (var id in slots)
{
MaterialSlot slot = node.FindSlot<MaterialSlot>(id);
if (slot != null)
{
activeSlots.Add(slot);
}
}
return activeSlots;
}
internal static string AdaptNodeOutput(AbstractMaterialNode node, int outputSlotId, ConcreteSlotValueType convertToType)
{
var outputSlot = node.FindOutputSlot<MaterialSlot>(outputSlotId);
if (outputSlot == null)
return kErrorString;
var convertFromType = outputSlot.concreteValueType;
var rawOutput = node.GetVariableNameForSlot(outputSlotId);
if (convertFromType == convertToType)
return rawOutput;
switch (convertToType)
{
case ConcreteSlotValueType.Vector1:
return string.Format("({0}).x", rawOutput);
case ConcreteSlotValueType.Vector2:
switch (convertFromType)
{
case ConcreteSlotValueType.Vector1:
return string.Format("({0}.xx)", rawOutput);
case ConcreteSlotValueType.Vector3:
case ConcreteSlotValueType.Vector4:
return string.Format("({0}.xy)", rawOutput);
default:
return kErrorString;
}
case ConcreteSlotValueType.Vector3:
switch (convertFromType)
{
case ConcreteSlotValueType.Vector1:
return string.Format("({0}.xxx)", rawOutput);
case ConcreteSlotValueType.Vector2:
return string.Format("($precision3({0}, 0.0))", rawOutput);
case ConcreteSlotValueType.Vector4:
return string.Format("({0}.xyz)", rawOutput);
default:
return kErrorString;
}
case ConcreteSlotValueType.Vector4:
switch (convertFromType)
{
case ConcreteSlotValueType.Vector1:
return string.Format("({0}.xxxx)", rawOutput);
case ConcreteSlotValueType.Vector2:
return string.Format("($precision4({0}, 0.0, 1.0))", rawOutput);
case ConcreteSlotValueType.Vector3:
return string.Format("($precision4({0}, 1.0))", rawOutput);
default:
return kErrorString;
}
case ConcreteSlotValueType.Matrix3:
return rawOutput;
case ConcreteSlotValueType.Matrix2:
return rawOutput;
case ConcreteSlotValueType.PropertyConnectionState:
return node.GetConnnectionStateVariableNameForSlot(outputSlotId);
default:
return kErrorString;
}
}
internal static string AdaptNodeOutputForPreview(AbstractMaterialNode node, int outputSlotId)
{
string rawOutput = node.GetVariableNameForSlot(outputSlotId);
return AdaptNodeOutputForPreview(node, outputSlotId, rawOutput);
}
internal static string AdaptNodeOutputForPreview(AbstractMaterialNode node, int slotId, string variableName)
{
var slot = node.FindSlot<MaterialSlot>(slotId);
if (slot == null)
return kErrorString;
var convertFromType = slot.concreteValueType;
// preview is always dimension 4
switch (convertFromType)
{
case ConcreteSlotValueType.Vector1:
return string.Format("half4({0}, {0}, {0}, 1.0)", variableName);
case ConcreteSlotValueType.Vector2:
return string.Format("half4({0}.x, {0}.y, 0.0, 1.0)", variableName);
case ConcreteSlotValueType.Vector3:
return string.Format("half4({0}.x, {0}.y, {0}.z, 1.0)", variableName);
case ConcreteSlotValueType.Vector4:
return string.Format("half4({0}.x, {0}.y, {0}.z, 1.0)", variableName);
case ConcreteSlotValueType.Boolean:
return string.Format("half4({0}, {0}, {0}, 1.0)", variableName);
default:
return "half4(0, 0, 0, 0)";
}
}
static void GenerateSpaceTranslationSurfaceInputs(
NeededCoordinateSpace neededSpaces,
InterpolatorType interpolatorType,
ShaderStringBuilder builder,
string format = "float3 {0};")
{
if ((neededSpaces & NeededCoordinateSpace.Object) > 0)
builder.AppendLine(format, CoordinateSpace.Object.ToVariableName(interpolatorType));
if ((neededSpaces & NeededCoordinateSpace.World) > 0)
builder.AppendLine(format, CoordinateSpace.World.ToVariableName(interpolatorType));
if ((neededSpaces & NeededCoordinateSpace.View) > 0)
builder.AppendLine(format, CoordinateSpace.View.ToVariableName(interpolatorType));
if ((neededSpaces & NeededCoordinateSpace.Tangent) > 0)
builder.AppendLine(format, CoordinateSpace.Tangent.ToVariableName(interpolatorType));
if ((neededSpaces & NeededCoordinateSpace.AbsoluteWorld) > 0)
builder.AppendLine(format, CoordinateSpace.AbsoluteWorld.ToVariableName(interpolatorType));
}
internal static void GeneratePropertiesBlock(ShaderStringBuilder sb, PropertyCollector propertyCollector, KeywordCollector keywordCollector, GenerationMode mode, List<GraphInputData> graphInputs)
{
sb.AppendLine("Properties");
using (sb.BlockScope())
{
if (graphInputs == null || graphInputs.Count == 0)
{
foreach (var prop in propertyCollector.properties.Where(x => x.generatePropertyBlock))
{
prop.AppendPropertyBlockStrings(sb);
}
// Keywords use hardcoded state in preview
// Do not add them to the Property Block
if (mode == GenerationMode.Preview)
return;
foreach (var key in keywordCollector.keywords.Where(x => x.generatePropertyBlock))
{
key.AppendPropertyBlockStrings(sb);
}
}
else
{
var propertyInputs = propertyCollector.properties.Where(x => x.generatePropertyBlock).ToList();
var keywordInputs = keywordCollector.keywords.Where(x => x.generatePropertyBlock).ToList();
foreach (var input in graphInputs)
{
if (input.isKeyword && mode != GenerationMode.Preview)
{
var keyword = keywordInputs.FirstOrDefault(x => x.referenceName.CompareTo(input.referenceName) == 0);
if (keyword != null)
{
keyword.AppendPropertyBlockStrings(sb);
keywordInputs.Remove(keyword);
}
}
else if (!input.isKeyword)
{
var property = propertyInputs.FirstOrDefault(x => x.referenceName.CompareTo(input.referenceName) == 0);
if (property != null)
{
property.AppendPropertyBlockStrings(sb);
propertyInputs.Remove(property);
}
}
}
foreach (var property in propertyInputs)
{
property.AppendPropertyBlockStrings(sb);
}
if (mode != GenerationMode.Preview)
{
foreach (var keyword in keywordInputs)
{
keyword.AppendPropertyBlockStrings(sb);
}
}
}
}
}
internal static void GenerateSurfaceInputStruct(ShaderStringBuilder sb, ShaderGraphRequirements requirements, string structName)
{
sb.AppendLine($"struct {structName}");
using (sb.BlockSemicolonScope())
{
GenerateSpaceTranslationSurfaceInputs(requirements.requiresNormal, InterpolatorType.Normal, sb);
GenerateSpaceTranslationSurfaceInputs(requirements.requiresTangent, InterpolatorType.Tangent, sb);
GenerateSpaceTranslationSurfaceInputs(requirements.requiresBitangent, InterpolatorType.BiTangent, sb);
GenerateSpaceTranslationSurfaceInputs(requirements.requiresViewDir, InterpolatorType.ViewDirection, sb);
GenerateSpaceTranslationSurfaceInputs(requirements.requiresPosition, InterpolatorType.Position, sb);
GenerateSpaceTranslationSurfaceInputs(requirements.requiresPositionPredisplacement, InterpolatorType.PositionPredisplacement, sb);
if (requirements.requiresVertexColor)
sb.AppendLine("float4 {0};", ShaderGeneratorNames.VertexColor);
if (requirements.requiresScreenPosition)
sb.AppendLine("float4 {0};", ShaderGeneratorNames.ScreenPosition);
if (requirements.requiresFaceSign)
sb.AppendLine("float {0};", ShaderGeneratorNames.FaceSign);
foreach (var channel in requirements.requiresMeshUVs.Distinct())
sb.AppendLine("half4 {0};", channel.GetUVName());
if (requirements.requiresTime)
{
sb.AppendLine("float3 {0};", ShaderGeneratorNames.TimeParameters);
}
if (requirements.requiresVertexSkinning)
{
sb.AppendLine("uint4 {0};", ShaderGeneratorNames.BoneIndices);
sb.AppendLine("float4 {0};", ShaderGeneratorNames.BoneWeights);
}
if (requirements.requiresVertexID)
{
sb.AppendLine("uint {0};", ShaderGeneratorNames.VertexID);
}
}
}
internal static void GenerateSurfaceInputTransferCode(ShaderStringBuilder sb, ShaderGraphRequirements requirements, string structName, string variableName)
{
sb.AppendLine($"{structName} {variableName};");
GenerateSpaceTranslationSurfaceInputs(requirements.requiresNormal, InterpolatorType.Normal, sb, $"{variableName}.{{0}} = IN.{{0}};");
GenerateSpaceTranslationSurfaceInputs(requirements.requiresTangent, InterpolatorType.Tangent, sb, $"{variableName}.{{0}} = IN.{{0}};");
GenerateSpaceTranslationSurfaceInputs(requirements.requiresBitangent, InterpolatorType.BiTangent, sb, $"{variableName}.{{0}} = IN.{{0}};");
GenerateSpaceTranslationSurfaceInputs(requirements.requiresViewDir, InterpolatorType.ViewDirection, sb, $"{variableName}.{{0}} = IN.{{0}};");
GenerateSpaceTranslationSurfaceInputs(requirements.requiresPosition, InterpolatorType.Position, sb, $"{variableName}.{{0}} = IN.{{0}};");
GenerateSpaceTranslationSurfaceInputs(requirements.requiresPositionPredisplacement, InterpolatorType.PositionPredisplacement, sb, $"{variableName}.{{0}} = IN.{{0}};");
if (requirements.requiresVertexColor)
sb.AppendLine($"{variableName}.{ShaderGeneratorNames.VertexColor} = IN.{ShaderGeneratorNames.VertexColor};");
if (requirements.requiresScreenPosition)
sb.AppendLine($"{variableName}.{ShaderGeneratorNames.ScreenPosition} = IN.{ShaderGeneratorNames.ScreenPosition};");
if (requirements.requiresFaceSign)
sb.AppendLine($"{variableName}.{ShaderGeneratorNames.FaceSign} = IN.{ShaderGeneratorNames.FaceSign};");
foreach (var channel in requirements.requiresMeshUVs.Distinct())
sb.AppendLine($"{variableName}.{channel.GetUVName()} = IN.{channel.GetUVName()};");
if (requirements.requiresTime)
{
sb.AppendLine($"{variableName}.{ShaderGeneratorNames.TimeParameters} = IN.{ShaderGeneratorNames.TimeParameters};");
}
if (requirements.requiresVertexSkinning)
{
sb.AppendLine($"{variableName}.{ShaderGeneratorNames.BoneIndices} = IN.{ShaderGeneratorNames.BoneIndices};");
sb.AppendLine($"{variableName}.{ShaderGeneratorNames.BoneWeights} = IN.{ShaderGeneratorNames.BoneWeights};");
}
if (requirements.requiresVertexID)
{
sb.AppendLine($"{variableName}.{ShaderGeneratorNames.VertexID} = IN.{ShaderGeneratorNames.VertexID};");
}
}
internal static void GenerateSurfaceDescriptionStruct(ShaderStringBuilder surfaceDescriptionStruct, List<MaterialSlot> slots, string structName = "SurfaceDescription", IActiveFieldsSet activeFields = null, bool isSubgraphOutput = false, bool virtualTextureFeedback = false)
{
surfaceDescriptionStruct.AppendLine("struct {0}", structName);
using (surfaceDescriptionStruct.BlockSemicolonScope())
{
if (slots != null)
{
if (isSubgraphOutput)
{
var firstSlot = slots.FirstOrDefault();
if (firstSlot != null)
{
var hlslName = $"{NodeUtils.GetHLSLSafeName(firstSlot.shaderOutputName)}_{firstSlot.id}";
surfaceDescriptionStruct.AppendLine("{0} {1};", firstSlot.concreteValueType.ToShaderString(firstSlot.owner.concretePrecision), hlslName);
surfaceDescriptionStruct.AppendLine("{0} {1};", ConcreteSlotValueType.Vector4.ToShaderString(firstSlot.owner.concretePrecision), "Out");
}
else
surfaceDescriptionStruct.AppendLine("{0} {1};", ConcreteSlotValueType.Vector4.ToShaderString(ConcretePrecision.Single), "Out");
}
else
{
foreach (var slot in slots)
{
string hlslName = NodeUtils.GetHLSLSafeName(slot.shaderOutputName);
surfaceDescriptionStruct.AppendLine("{0} {1};", slot.concreteValueType.ToShaderString(slot.owner.concretePrecision), hlslName);
if (activeFields != null)
{
var structField = new FieldDescriptor(structName, hlslName, "");
activeFields.AddAll(structField);
}
}
}
}
// TODO: move this into the regular FieldDescriptor system with a conditional, doesn't belong as a special case here
if (virtualTextureFeedback)
{
surfaceDescriptionStruct.AppendLine("{0} {1};", ConcreteSlotValueType.Vector4.ToShaderString(ConcretePrecision.Single), "VTPackedFeedback");
if (!isSubgraphOutput && activeFields != null)
{
var structField = new FieldDescriptor(structName, "VTPackedFeedback", "");
activeFields.AddAll(structField);
}
}
}
}
internal static void GenerateSurfaceDescriptionFunction(
List<AbstractMaterialNode> nodes,
List<int>[] keywordPermutationsPerNode,
AbstractMaterialNode rootNode,
GraphData graph,
ShaderStringBuilder surfaceDescriptionFunction,
FunctionRegistry functionRegistry,
PropertyCollector shaderProperties,
KeywordCollector shaderKeywords,
GenerationMode mode,
string functionName = "PopulateSurfaceData",
string surfaceDescriptionName = "SurfaceDescription",
Vector1ShaderProperty outputIdProperty = null,
IEnumerable<MaterialSlot> slots = null,
string graphInputStructName = "SurfaceDescriptionInputs",
bool virtualTextureFeedback = false)
{
if (graph == null)
return;
graph.CollectShaderProperties(shaderProperties, mode);
if (mode == GenerationMode.VFX)
{
const string k_GraphProperties = "GraphProperties";
surfaceDescriptionFunction.AppendLine(String.Format("{0} {1}(SurfaceDescriptionInputs IN, {2} PROP)", surfaceDescriptionName, functionName, k_GraphProperties), false);
}
else
surfaceDescriptionFunction.AppendLine(String.Format("{0} {1}(SurfaceDescriptionInputs IN)", surfaceDescriptionName, functionName), false);
using (surfaceDescriptionFunction.BlockScope())
{
surfaceDescriptionFunction.AppendLine("{0} surface = ({0})0;", surfaceDescriptionName);
for (int i = 0; i < nodes.Count; i++)
{
GenerateDescriptionForNode(nodes[i], keywordPermutationsPerNode[i], functionRegistry, surfaceDescriptionFunction,
shaderProperties, shaderKeywords,
graph, mode);
}
functionRegistry.builder.currentNode = null;
surfaceDescriptionFunction.currentNode = null;
GenerateSurfaceDescriptionRemap(graph, rootNode, slots,
surfaceDescriptionFunction, mode);
if (virtualTextureFeedback)
{
VirtualTexturingFeedbackUtils.GenerateVirtualTextureFeedback(
nodes,
keywordPermutationsPerNode,
surfaceDescriptionFunction,
shaderKeywords);
}
surfaceDescriptionFunction.AppendLine("return surface;");
}
}
static void GenerateDescriptionForNode(
AbstractMaterialNode activeNode,
List<int> keywordPermutations,
FunctionRegistry functionRegistry,
ShaderStringBuilder descriptionFunction,
PropertyCollector shaderProperties,
KeywordCollector shaderKeywords,
GraphData graph,
GenerationMode mode)
{
if (activeNode is IGeneratesFunction functionNode)
{
functionRegistry.builder.currentNode = activeNode;
Profiler.BeginSample("GenerateNodeFunction");
functionNode.GenerateNodeFunction(functionRegistry, mode);
Profiler.EndSample();
}
if (activeNode is IGeneratesBodyCode bodyNode)
{
if (keywordPermutations != null)
descriptionFunction.AppendLine(KeywordUtil.GetKeywordPermutationSetConditional(keywordPermutations));
descriptionFunction.currentNode = activeNode;
Profiler.BeginSample("GenerateNodeCode");
bodyNode.GenerateNodeCode(descriptionFunction, mode);
Profiler.EndSample();
descriptionFunction.ReplaceInCurrentMapping(PrecisionUtil.Token, activeNode.concretePrecision.ToShaderString());
if (keywordPermutations != null)
descriptionFunction.AppendLine("#endif");
}
activeNode.CollectShaderProperties(shaderProperties, mode);
if (activeNode is SubGraphNode subGraphNode)
{
subGraphNode.CollectShaderKeywords(shaderKeywords, mode);
}
}
static void GenerateSurfaceDescriptionRemap(
GraphData graph,
AbstractMaterialNode rootNode,
IEnumerable<MaterialSlot> slots,
ShaderStringBuilder surfaceDescriptionFunction,
GenerationMode mode)
{
if (rootNode == null)
{
foreach (var input in slots)
{
if (input != null)
{
var node = input.owner;
var foundEdges = graph.GetEdges(input.slotReference).ToArray();
var hlslName = NodeUtils.GetHLSLSafeName(input.shaderOutputName);
if (foundEdges.Any())
surfaceDescriptionFunction.AppendLine($"surface.{hlslName} = {node.GetSlotValue(input.id, mode, node.concretePrecision)};");
else
surfaceDescriptionFunction.AppendLine($"surface.{hlslName} = {input.GetDefaultValue(mode, node.concretePrecision)};");
}
}
}
else if (rootNode is SubGraphOutputNode)
{
var slot = slots.FirstOrDefault();
if (slot != null)
{
var foundEdges = graph.GetEdges(slot.slotReference).ToArray();
var hlslName = $"{NodeUtils.GetHLSLSafeName(slot.shaderOutputName)}_{slot.id}";
if (foundEdges.Any())
surfaceDescriptionFunction.AppendLine($"surface.{hlslName} = {rootNode.GetSlotValue(slot.id, mode, rootNode.concretePrecision)};");
else
surfaceDescriptionFunction.AppendLine($"surface.{hlslName} = {slot.GetDefaultValue(mode, rootNode.concretePrecision)};");
surfaceDescriptionFunction.AppendLine($"surface.Out = all(isfinite(surface.{hlslName})) ? {GenerationUtils.AdaptNodeOutputForPreview(rootNode, slot.id, "surface." + hlslName)} : float4(1.0f, 0.0f, 1.0f, 1.0f);");
}
}
else
{
var slot = rootNode.GetOutputSlots<MaterialSlot>().FirstOrDefault();
if (slot != null)
{
string slotValue;
string previewOutput;
if (rootNode.isActive)
{
slotValue = rootNode.GetSlotValue(slot.id, mode, rootNode.concretePrecision);
previewOutput = GenerationUtils.AdaptNodeOutputForPreview(rootNode, slot.id);
}
else
{
slotValue = rootNode.GetSlotValue(slot.id, mode, rootNode.concretePrecision);
previewOutput = "float4(0.0f, 0.0f, 0.0f, 0.0f)";
}
surfaceDescriptionFunction.AppendLine($"surface.Out = all(isfinite({slotValue})) ? {previewOutput} : float4(1.0f, 0.0f, 1.0f, 1.0f);");
}
}
}
const string k_VertexDescriptionStructName = "VertexDescription";
internal static void GenerateVertexDescriptionStruct(ShaderStringBuilder builder, List<MaterialSlot> slots, string structName = k_VertexDescriptionStructName, IActiveFieldsSet activeFields = null)
{
builder.AppendLine("struct {0}", structName);
using (builder.BlockSemicolonScope())
{
foreach (var slot in slots)
{
string hlslName = NodeUtils.ConvertToValidHLSLIdentifier(slot.shaderOutputName);
builder.AppendLine("{0} {1};", slot.concreteValueType.ToShaderString(slot.owner.concretePrecision), hlslName);
if (activeFields != null)
{
var structField = new FieldDescriptor(structName, hlslName, "");
activeFields.AddAll(structField);
}
}
}
}
internal static void GenerateVertexDescriptionFunction(
GraphData graph,
ShaderStringBuilder builder,
FunctionRegistry functionRegistry,
PropertyCollector shaderProperties,
KeywordCollector shaderKeywords,
GenerationMode mode,
AbstractMaterialNode rootNode,
List<AbstractMaterialNode> nodes,
List<int>[] keywordPermutationsPerNode,
List<MaterialSlot> slots,
string graphInputStructName = "VertexDescriptionInputs",
string functionName = "PopulateVertexData",
string graphOutputStructName = k_VertexDescriptionStructName)
{
if (graph == null)
return;
graph.CollectShaderProperties(shaderProperties, mode);
if (mode == GenerationMode.VFX)
{
const string k_GraphProperties = "GraphProperties";
builder.AppendLine("{0} {1}({2} IN, {3} PROP)", graphOutputStructName, functionName, graphInputStructName, k_GraphProperties);
}
else
builder.AppendLine("{0} {1}({2} IN)", graphOutputStructName, functionName, graphInputStructName);
using (builder.BlockScope())
{
builder.AppendLine("{0} description = ({0})0;", graphOutputStructName);
Profiler.BeginSample("GenerateNodeDescriptions");
for (int i = 0; i < nodes.Count; i++)
{
GenerateDescriptionForNode(nodes[i], keywordPermutationsPerNode[i], functionRegistry, builder,
shaderProperties, shaderKeywords,
graph, mode);
}
Profiler.EndSample();
functionRegistry.builder.currentNode = null;
builder.currentNode = null;
if (slots.Count != 0)
{
foreach (var slot in slots)
{
var isSlotConnected = graph.GetEdges(slot.slotReference).Any();
var slotName = NodeUtils.ConvertToValidHLSLIdentifier(slot.shaderOutputName);
var slotValue = isSlotConnected ?
((AbstractMaterialNode)slot.owner).GetSlotValue(slot.id, mode, slot.owner.concretePrecision) : slot.GetDefaultValue(mode, slot.owner.concretePrecision);
builder.AppendLine("description.{0} = {1};", slotName, slotValue);
}
}
builder.AppendLine("return description;");
}
}
internal static string GetSpliceCommand(string command, string token)
{
return !string.IsNullOrEmpty(command) ? command : $"// {token}: <None>";
}
internal static string GetDefaultTemplatePath(string templateName)
{
var basePath = "Packages/com.unity.shadergraph/Editor/Generation/Templates/";
string templatePath = Path.Combine(basePath, templateName);
if (File.Exists(templatePath))
return templatePath;
throw new FileNotFoundException(string.Format(@"Cannot find a template with name ""{0}"".", templateName));
}
internal static string[] defaultDefaultSharedTemplateDirectories = new string[]
{
"Packages/com.unity.shadergraph/Editor/Generation/Templates"
};
internal static string[] GetDefaultSharedTemplateDirectories()
{
return defaultDefaultSharedTemplateDirectories;
}
// Returns null if no 'CustomEditor "___"' line should be added, otherwise the name of the ShaderGUI class.
// Note that it's okay to add an "invalid" ShaderGUI (no class found) as Unity will simply take no action if that's the case, unless if its BaseShaderGUI.
public static string FinalCustomEditorString(ICanChangeShaderGUI canChangeShaderGUI)
{
string finalOverrideName = canChangeShaderGUI.ShaderGUIOverride;
if (string.IsNullOrEmpty(finalOverrideName))
return null;
// Do not add to the final shader if the base ShaderGUI is wanted, as errors will occur.
if (finalOverrideName.Equals("BaseShaderGUI") || finalOverrideName.Equals("UnityEditor.BaseShaderGUI"))
return null;
return finalOverrideName;
}
}
}