927 lines
32 KiB
C#
927 lines
32 KiB
C#
using System;
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using System.Collections.Generic;
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using System.Globalization;
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using System.Linq;
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using System.Text;
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using UnityEditor.ShaderGraph;
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using System.Text.RegularExpressions;
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using UnityEditor.ShaderGraph.Drawing;
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using UnityEngine;
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using UnityEngine.Pool;
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using UnityEngine.Rendering.ShaderGraph;
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namespace UnityEditor.Graphing
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{
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class SlotConfigurationException : Exception
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{
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public SlotConfigurationException(string message)
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: base(message)
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{ }
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}
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static class NodeUtils
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{
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static string NodeDocSuffix = "-Node";
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public static void SlotConfigurationExceptionIfBadConfiguration(AbstractMaterialNode node, IEnumerable<int> expectedInputSlots, IEnumerable<int> expectedOutputSlots)
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{
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var missingSlots = new List<int>();
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var inputSlots = expectedInputSlots as IList<int> ?? expectedInputSlots.ToList();
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missingSlots.AddRange(inputSlots.Except(node.GetInputSlots<MaterialSlot>().Select(x => x.id)));
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var outputSlots = expectedOutputSlots as IList<int> ?? expectedOutputSlots.ToList();
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missingSlots.AddRange(outputSlots.Except(node.GetOutputSlots<MaterialSlot>().Select(x => x.id)));
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if (missingSlots.Count == 0)
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return;
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var toPrint = missingSlots.Select(x => x.ToString());
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throw new SlotConfigurationException(string.Format("Missing slots {0} on node {1}", string.Join(", ", toPrint.ToArray()), node));
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}
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public static IEnumerable<IEdge> GetAllEdges(AbstractMaterialNode node)
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{
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var result = new List<IEdge>();
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var validSlots = ListPool<MaterialSlot>.Get();
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validSlots.AddRange(node.GetInputSlots<MaterialSlot>());
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for (int index = 0; index < validSlots.Count; index++)
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{
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var inputSlot = validSlots[index];
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result.AddRange(node.owner.GetEdges(inputSlot.slotReference));
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}
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validSlots.Clear();
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validSlots.AddRange(node.GetOutputSlots<MaterialSlot>());
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for (int index = 0; index < validSlots.Count; index++)
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{
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var outputSlot = validSlots[index];
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result.AddRange(node.owner.GetEdges(outputSlot.slotReference));
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}
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ListPool<MaterialSlot>.Release(validSlots);
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return result;
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}
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public static string GetDuplicateSafeNameForSlot(AbstractMaterialNode node, int slotId, string name)
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{
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List<MaterialSlot> slots = new List<MaterialSlot>();
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node.GetSlots(slots);
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name = name.Trim();
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return GraphUtil.SanitizeName(slots.Where(p => p.id != slotId).Select(p => p.RawDisplayName()), "{0} ({1})", name);
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}
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// CollectNodesNodeFeedsInto looks at the current node and calculates
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// which child nodes it depends on for it's calculation.
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// Results are returned depth first so by processing each node in
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// order you can generate a valid code block.
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public enum IncludeSelf
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{
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Include,
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Exclude
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}
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public static SlotReference DepthFirstCollectRedirectNodeFromNode(RedirectNodeData node)
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{
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var inputSlot = node.FindSlot<MaterialSlot>(RedirectNodeData.kInputSlotID);
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foreach (var edge in node.owner.GetEdges(inputSlot.slotReference))
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{
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// get the input details
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var outputSlotRef = edge.outputSlot;
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var inputNode = outputSlotRef.node;
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// If this is a redirect node we continue to look for the top one
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if (inputNode is RedirectNodeData redirectNode)
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{
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return DepthFirstCollectRedirectNodeFromNode(redirectNode);
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}
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return outputSlotRef;
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}
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// If no edges it is the first redirect node without an edge going into it and we should return the slot ref
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return node.GetSlotReference(RedirectNodeData.kInputSlotID);
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}
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public static void DepthFirstCollectNodesFromNode(List<AbstractMaterialNode> nodeList, AbstractMaterialNode node,
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IncludeSelf includeSelf = IncludeSelf.Include, List<KeyValuePair<ShaderKeyword, int>> keywordPermutation = null, bool ignoreActiveState = false)
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{
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// no where to start
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if (node == null)
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return;
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// already added this node
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if (nodeList.Contains(node))
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return;
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IEnumerable<int> ids;
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// If this node is a keyword node and we have an active keyword permutation
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// The only valid port id is the port that corresponds to that keywords value in the active permutation
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if (node is KeywordNode keywordNode && keywordPermutation != null)
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{
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var valueInPermutation = keywordPermutation.Where(x => x.Key == keywordNode.keyword).FirstOrDefault();
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ids = new int[] { keywordNode.GetSlotIdForPermutation(valueInPermutation) };
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}
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else
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{
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ids = node.GetInputSlots<MaterialSlot>().Select(x => x.id);
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}
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foreach (var slot in ids)
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{
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foreach (var edge in node.owner.GetEdges(node.GetSlotReference(slot)))
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{
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var outputNode = edge.outputSlot.node;
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if (outputNode != null)
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DepthFirstCollectNodesFromNode(nodeList, outputNode, keywordPermutation: keywordPermutation, ignoreActiveState: ignoreActiveState);
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}
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}
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if (includeSelf == IncludeSelf.Include && (node.isActive || ignoreActiveState))
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nodeList.Add(node);
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}
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internal static List<AbstractMaterialNode> GetParentNodes(AbstractMaterialNode node)
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{
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List<AbstractMaterialNode> nodeList = new List<AbstractMaterialNode>();
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var ids = node.GetInputSlots<MaterialSlot>().Select(x => x.id);
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foreach (var slot in ids)
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{
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if (node.owner == null)
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break;
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foreach (var edge in node.owner.GetEdges(node.FindSlot<MaterialSlot>(slot).slotReference))
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{
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var outputNode = ((Edge)edge).outputSlot.node;
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if (outputNode != null)
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{
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nodeList.Add(outputNode);
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}
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}
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}
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return nodeList;
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}
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private static bool ActiveLeafExists(AbstractMaterialNode node)
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{
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//if our active state has been explicitly set to a value use it
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switch (node.activeState)
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{
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case AbstractMaterialNode.ActiveState.Implicit:
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break;
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case AbstractMaterialNode.ActiveState.ExplicitInactive:
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return false;
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case AbstractMaterialNode.ActiveState.ExplicitActive:
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return true;
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}
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List<AbstractMaterialNode> parentNodes = GetParentNodes(node);
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//at this point we know we are not explicitly set to a state,
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//so there is no reason to be inactive
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if (parentNodes.Count == 0)
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{
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return true;
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}
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bool output = false;
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foreach (var parent in parentNodes)
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{
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output |= ActiveLeafExists(parent);
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if (output)
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{
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break;
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}
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}
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return output;
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}
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private static List<AbstractMaterialNode> GetChildNodes(AbstractMaterialNode node)
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{
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List<AbstractMaterialNode> nodeList = new List<AbstractMaterialNode>();
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var ids = node.GetOutputSlots<MaterialSlot>().Select(x => x.id);
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foreach (var slot in ids)
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{
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foreach (var edge in node.owner.GetEdges(node.FindSlot<MaterialSlot>(slot).slotReference))
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{
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var inputNode = ((Edge)edge).inputSlot.node;
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if (inputNode != null)
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{
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nodeList.Add(inputNode);
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}
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}
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}
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return nodeList;
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}
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private static bool ActiveRootExists(AbstractMaterialNode node)
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{
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//if our active state has been explicitly set to a value use it
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switch (node.activeState)
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{
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case AbstractMaterialNode.ActiveState.Implicit:
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break;
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case AbstractMaterialNode.ActiveState.ExplicitInactive:
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return false;
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case AbstractMaterialNode.ActiveState.ExplicitActive:
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return true;
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}
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List<AbstractMaterialNode> childNodes = GetChildNodes(node);
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//at this point we know we are not explicitly set to a state,
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//so there is no reason to be inactive
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if (childNodes.Count == 0)
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{
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return true;
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}
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bool output = false;
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foreach (var child in childNodes)
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{
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output |= ActiveRootExists(child);
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if (output)
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{
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break;
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}
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}
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return output;
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}
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private static void ActiveTreeExists(AbstractMaterialNode node, out bool activeLeaf, out bool activeRoot, out bool activeTree)
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{
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activeLeaf = ActiveLeafExists(node);
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activeRoot = ActiveRootExists(node);
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activeTree = activeRoot && activeLeaf;
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}
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//First pass check if node is now active after a change, so just check if there is a valid "tree" : a valid upstream input path,
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// and a valid downstream output path, or "leaf" and "root". If this changes the node's active state, then anything connected may
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// change as well, so update the "forrest" or all connectected trees of this nodes leaves.
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// NOTE: I cannot think if there is any case where the entirety of the connected graph would need to change, but if there are bugs
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// on certain nodes farther away from the node not updating correctly, a possible solution may be to get the entirety of the connected
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// graph instead of just what I have declared as the "local" connected graph
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public static void ReevaluateActivityOfConnectedNodes(AbstractMaterialNode node, PooledHashSet<AbstractMaterialNode> changedNodes = null)
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{
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var forest = GetForest(node);
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ReevaluateActivityOfNodeList(forest, changedNodes);
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}
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public static void ReevaluateActivityOfNodeList(IEnumerable<AbstractMaterialNode> nodes, PooledHashSet<AbstractMaterialNode> changedNodes = null)
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{
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bool getChangedNodes = changedNodes != null;
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foreach (AbstractMaterialNode n in nodes)
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{
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if (n.activeState != AbstractMaterialNode.ActiveState.Implicit)
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continue;
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ActiveTreeExists(n, out _, out _, out bool at);
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if (n.isActive != at && getChangedNodes)
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{
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changedNodes.Add(n);
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}
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n.SetActive(at, false);
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}
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}
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//Go to the leaves of the node, then get all trees with those leaves
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private static HashSet<AbstractMaterialNode> GetForest(AbstractMaterialNode node)
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{
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var initial = new HashSet<AbstractMaterialNode> { node };
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var upstream = new HashSet<AbstractMaterialNode>();
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PreviewManager.PropagateNodes(initial, PreviewManager.PropagationDirection.Upstream, upstream);
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var forest = new HashSet<AbstractMaterialNode>();
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PreviewManager.PropagateNodes(upstream, PreviewManager.PropagationDirection.Downstream, forest);
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return forest;
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}
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public static void GetDownsteamNodesForNode(List<AbstractMaterialNode> nodeList, AbstractMaterialNode node)
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{
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// no where to start
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if (node == null)
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return;
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// Recursively traverse downstream from the original node
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// Traverse down each edge and continue on any connected downstream nodes
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// Only nodes with no nodes further downstream are added to node list
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bool hasDownstream = false;
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var ids = node.GetOutputSlots<MaterialSlot>().Select(x => x.id);
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foreach (var slot in ids)
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{
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foreach (var edge in node.owner.GetEdges(node.FindSlot<MaterialSlot>(slot).slotReference))
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{
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var inputNode = ((Edge)edge).inputSlot.node;
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if (inputNode != null)
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{
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hasDownstream = true;
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GetDownsteamNodesForNode(nodeList, inputNode);
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}
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}
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}
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// No more nodes downstream from here
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if (!hasDownstream)
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nodeList.Add(node);
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}
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public static void CollectNodeSet(HashSet<AbstractMaterialNode> nodeSet, MaterialSlot slot)
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{
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var node = slot.owner;
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var graph = node.owner;
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foreach (var edge in graph.GetEdges(node.GetSlotReference(slot.id)))
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{
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var outputNode = edge.outputSlot.node;
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if (outputNode != null)
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{
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CollectNodeSet(nodeSet, outputNode);
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}
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}
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}
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public static void CollectNodeSet(HashSet<AbstractMaterialNode> nodeSet, AbstractMaterialNode node)
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{
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if (!nodeSet.Add(node))
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{
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return;
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}
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using (ListPool<MaterialSlot>.Get(out var slots))
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{
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node.GetInputSlots(slots);
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foreach (var slot in slots)
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{
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CollectNodeSet(nodeSet, slot);
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}
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}
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}
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public static void CollectNodesNodeFeedsInto(List<AbstractMaterialNode> nodeList, AbstractMaterialNode node, IncludeSelf includeSelf = IncludeSelf.Include)
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{
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if (node == null)
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return;
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if (nodeList.Contains(node))
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return;
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foreach (var slot in node.GetOutputSlots<MaterialSlot>())
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{
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foreach (var edge in node.owner.GetEdges(slot.slotReference))
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{
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var inputNode = edge.inputSlot.node;
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CollectNodesNodeFeedsInto(nodeList, inputNode);
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}
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}
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if (includeSelf == IncludeSelf.Include)
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nodeList.Add(node);
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}
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public static string GetDocumentationString(string pageName)
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{
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return Documentation.GetPageLink(pageName.Replace(" ", "-") + NodeDocSuffix);
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}
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static Stack<MaterialSlot> s_SlotStack = new Stack<MaterialSlot>();
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public static ShaderStage GetEffectiveShaderStage(MaterialSlot initialSlot, bool goingBackwards)
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{
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var graph = initialSlot.owner.owner;
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s_SlotStack.Clear();
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s_SlotStack.Push(initialSlot);
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while (s_SlotStack.Any())
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{
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var slot = s_SlotStack.Pop();
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ShaderStage stage;
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if (slot.stageCapability.TryGetShaderStage(out stage))
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return stage;
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if (goingBackwards && slot.isInputSlot)
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{
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foreach (var edge in graph.GetEdges(slot.slotReference))
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{
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var node = edge.outputSlot.node;
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s_SlotStack.Push(node.FindOutputSlot<MaterialSlot>(edge.outputSlot.slotId));
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}
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}
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else if (!goingBackwards && slot.isOutputSlot)
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{
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foreach (var edge in graph.GetEdges(slot.slotReference))
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{
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var node = edge.inputSlot.node;
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s_SlotStack.Push(node.FindInputSlot<MaterialSlot>(edge.inputSlot.slotId));
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}
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}
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else
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{
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var ownerSlots = Enumerable.Empty<MaterialSlot>();
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if (goingBackwards && slot.isOutputSlot)
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ownerSlots = slot.owner.GetInputSlots<MaterialSlot>(slot);
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else if (!goingBackwards && slot.isInputSlot)
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ownerSlots = slot.owner.GetOutputSlots<MaterialSlot>(slot);
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foreach (var ownerSlot in ownerSlots)
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s_SlotStack.Push(ownerSlot);
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}
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}
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// We default to fragment shader stage if all connected nodes were compatible with both.
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return ShaderStage.Fragment;
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}
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public static ShaderStageCapability GetEffectiveShaderStageCapability(MaterialSlot initialSlot, bool goingBackwards)
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{
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var graph = initialSlot.owner.owner;
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s_SlotStack.Clear();
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s_SlotStack.Push(initialSlot);
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ShaderStageCapability capabilities = ShaderStageCapability.All;
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while (s_SlotStack.Any())
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{
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var slot = s_SlotStack.Pop();
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// Clear any stages from the total capabilities that this slot doesn't support (e.g. if this is vertex, clear pixel)
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capabilities &= slot.stageCapability;
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// Can early out if we know nothing is compatible, otherwise we have to keep checking everything we can reach.
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if (capabilities == ShaderStageCapability.None)
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return capabilities;
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if (goingBackwards && slot.isInputSlot)
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{
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foreach (var edge in graph.GetEdges(slot.slotReference))
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{
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var node = edge.outputSlot.node;
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s_SlotStack.Push(node.FindOutputSlot<MaterialSlot>(edge.outputSlot.slotId));
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}
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}
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else if (!goingBackwards && slot.isOutputSlot)
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{
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foreach (var edge in graph.GetEdges(slot.slotReference))
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{
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var node = edge.inputSlot.node;
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s_SlotStack.Push(node.FindInputSlot<MaterialSlot>(edge.inputSlot.slotId));
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}
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}
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else
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{
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var ownerSlots = Enumerable.Empty<MaterialSlot>();
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if (goingBackwards && slot.isOutputSlot)
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ownerSlots = slot.owner.GetInputSlots<MaterialSlot>(slot);
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else if (!goingBackwards && slot.isInputSlot)
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ownerSlots = slot.owner.GetOutputSlots<MaterialSlot>(slot);
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foreach (var ownerSlot in ownerSlots)
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s_SlotStack.Push(ownerSlot);
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}
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}
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return capabilities;
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}
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public static string GetSlotDimension(ConcreteSlotValueType slotValue)
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{
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switch (slotValue)
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{
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case ConcreteSlotValueType.Vector1:
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return String.Empty;
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case ConcreteSlotValueType.Vector2:
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return "2";
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case ConcreteSlotValueType.Vector3:
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return "3";
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case ConcreteSlotValueType.Vector4:
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return "4";
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case ConcreteSlotValueType.Matrix2:
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return "2x2";
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case ConcreteSlotValueType.Matrix3:
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return "3x3";
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case ConcreteSlotValueType.Matrix4:
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return "4x4";
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case ConcreteSlotValueType.PropertyConnectionState:
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return String.Empty;
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default:
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return "Error";
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}
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}
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// NOTE: there are several bugs here.. we should use ConvertToValidHLSLIdentifier() instead
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public static string GetHLSLSafeName(string input)
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{
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char[] arr = input.ToCharArray();
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arr = Array.FindAll<char>(arr, (c => (Char.IsLetterOrDigit(c))));
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var safeName = new string(arr);
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if (safeName.Length > 1 && char.IsDigit(safeName[0]))
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{
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safeName = $"var{safeName}";
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}
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return safeName;
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}
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|
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static readonly string[] k_HLSLNumericKeywords =
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{
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"float",
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"half", // not technically in HLSL spec, but prob should be
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"real", // Unity thing, but included here
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"int",
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"uint",
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"bool",
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"min10float",
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"min16float",
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"min12int",
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"min16int",
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"min16uint"
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};
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|
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static readonly string[] k_HLSLNumericKeywordSuffixes =
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{
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"",
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"1", "2", "3", "4",
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"1x1", "1x2", "1x3", "1x4",
|
|
"2x1", "2x2", "2x3", "2x4",
|
|
"3x1", "3x2", "3x3", "3x4",
|
|
"4x1", "4x2", "4x3", "4x4"
|
|
};
|
|
|
|
static HashSet<string> m_ShaderLabKeywords = new HashSet<string>()
|
|
{
|
|
// these should all be lowercase, as shaderlab keywords are case insensitive
|
|
"properties",
|
|
"range",
|
|
"bind",
|
|
"bindchannels",
|
|
"tags",
|
|
"lod",
|
|
"shader",
|
|
"subshader",
|
|
"category",
|
|
"fallback",
|
|
"dependency",
|
|
"customeditor",
|
|
"rect",
|
|
"any",
|
|
"float",
|
|
"color",
|
|
"int",
|
|
"integer",
|
|
"vector",
|
|
"matrix",
|
|
"2d",
|
|
"cube",
|
|
"3d",
|
|
"2darray",
|
|
"cubearray",
|
|
"name",
|
|
"settexture",
|
|
"true",
|
|
"false",
|
|
"on",
|
|
"off",
|
|
"separatespecular",
|
|
"offset",
|
|
"zwrite",
|
|
"zclip",
|
|
"conservative",
|
|
"ztest",
|
|
"alphatest",
|
|
"fog",
|
|
"stencil",
|
|
"colormask",
|
|
"alphatomask",
|
|
"cull",
|
|
"front",
|
|
"material",
|
|
"ambient",
|
|
"diffuse",
|
|
"specular",
|
|
"emission",
|
|
"shininess",
|
|
"blend",
|
|
"blendop",
|
|
"colormaterial",
|
|
"lighting",
|
|
"pass",
|
|
"grabpass",
|
|
"usepass",
|
|
"gpuprogramid",
|
|
"add",
|
|
"sub",
|
|
"revsub",
|
|
"min",
|
|
"max",
|
|
"logicalclear",
|
|
"logicalset",
|
|
"logicalcopy",
|
|
"logicalcopyinverted",
|
|
"logicalnoop",
|
|
"logicalinvert",
|
|
"logicaland",
|
|
"logicalnand",
|
|
"logicalor",
|
|
"logicalnor",
|
|
"logicalxor",
|
|
"logicalequiv",
|
|
"logicalandreverse",
|
|
"logicalandinverted",
|
|
"logicalorreverse",
|
|
"logicalorinverted",
|
|
"multiply",
|
|
"screen",
|
|
"overlay",
|
|
"darken",
|
|
"lighten",
|
|
"colordodge",
|
|
"colorburn",
|
|
"hardlight",
|
|
"softlight",
|
|
"difference",
|
|
"exclusion",
|
|
"hslhue",
|
|
"hslsaturation",
|
|
"hslcolor",
|
|
"hslluminosity",
|
|
"zero",
|
|
"one",
|
|
"dstcolor",
|
|
"srccolor",
|
|
"oneminusdstcolor",
|
|
"srcalpha",
|
|
"oneminussrccolor",
|
|
"dstalpha",
|
|
"oneminusdstalpha",
|
|
"srcalphasaturate",
|
|
"oneminussrcalpha",
|
|
"constantcolor",
|
|
"oneminusconstantcolor",
|
|
"constantalpha",
|
|
"oneminusconstantalpha",
|
|
};
|
|
|
|
static HashSet<string> m_HLSLKeywords = new HashSet<string>()
|
|
{
|
|
"AppendStructuredBuffer",
|
|
"asm",
|
|
"asm_fragment",
|
|
"auto",
|
|
"BlendState",
|
|
"break",
|
|
"Buffer",
|
|
"ByteAddressBuffer",
|
|
"case",
|
|
"catch",
|
|
"cbuffer",
|
|
"centroid",
|
|
"char",
|
|
"class",
|
|
"column_major",
|
|
"compile",
|
|
"compile_fragment",
|
|
"CompileShader",
|
|
"const",
|
|
"const_cast",
|
|
"continue",
|
|
"ComputeShader",
|
|
"ConsumeStructuredBuffer",
|
|
"default",
|
|
"delete",
|
|
"DepthStencilState",
|
|
"DepthStencilView",
|
|
"discard",
|
|
"do",
|
|
"double",
|
|
"DomainShader",
|
|
"dynamic_cast",
|
|
"dword",
|
|
"else",
|
|
"enum",
|
|
"explicit",
|
|
"export",
|
|
"extern",
|
|
"false",
|
|
"for",
|
|
"friend",
|
|
"fxgroup",
|
|
"GeometryShader",
|
|
"goto",
|
|
"groupshared",
|
|
"half",
|
|
"Hullshader",
|
|
"if",
|
|
"in",
|
|
"inline",
|
|
"inout",
|
|
"InputPatch",
|
|
"interface",
|
|
"line",
|
|
"lineadj",
|
|
"linear",
|
|
"LineStream",
|
|
"long",
|
|
"matrix",
|
|
"mutable",
|
|
"namespace",
|
|
"new",
|
|
"nointerpolation",
|
|
"noperspective",
|
|
"NULL",
|
|
"operator",
|
|
"out",
|
|
"OutputPatch",
|
|
"packoffset",
|
|
"pass",
|
|
"pixelfragment",
|
|
"PixelShader",
|
|
"point",
|
|
"PointStream",
|
|
"precise",
|
|
"private",
|
|
"protected",
|
|
"public",
|
|
"RasterizerState",
|
|
"reinterpret_cast",
|
|
"RenderTargetView",
|
|
"return",
|
|
"register",
|
|
"row_major",
|
|
"RWBuffer",
|
|
"RWByteAddressBuffer",
|
|
"RWStructuredBuffer",
|
|
"RWTexture1D",
|
|
"RWTexture1DArray",
|
|
"RWTexture2D",
|
|
"RWTexture2DArray",
|
|
"RWTexture3D",
|
|
"sample",
|
|
"sampler",
|
|
"SamplerState",
|
|
"SamplerComparisonState",
|
|
"shared",
|
|
"short",
|
|
"signed",
|
|
"sizeof",
|
|
"snorm",
|
|
"stateblock",
|
|
"stateblock_state",
|
|
"static",
|
|
"static_cast",
|
|
"string",
|
|
"struct",
|
|
"switch",
|
|
"StructuredBuffer",
|
|
"tbuffer",
|
|
"technique",
|
|
"technique10",
|
|
"technique11",
|
|
"template",
|
|
"texture",
|
|
"Texture1D",
|
|
"Texture1DArray",
|
|
"Texture2D",
|
|
"Texture2DArray",
|
|
"Texture2DMS",
|
|
"Texture2DMSArray",
|
|
"Texture3D",
|
|
"TextureCube",
|
|
"TextureCubeArray",
|
|
"this",
|
|
"throw",
|
|
"true",
|
|
"try",
|
|
"typedef",
|
|
"typename",
|
|
"triangle",
|
|
"triangleadj",
|
|
"TriangleStream",
|
|
"uniform",
|
|
"unorm",
|
|
"union",
|
|
"unsigned",
|
|
"using",
|
|
"vector",
|
|
"vertexfragment",
|
|
"VertexShader",
|
|
"virtual",
|
|
"void",
|
|
"volatile",
|
|
"while"
|
|
};
|
|
|
|
static HashSet<string> m_ShaderGraphKeywords = new HashSet<string>()
|
|
{
|
|
"Gradient",
|
|
"UnitySamplerState",
|
|
"UnityTexture2D",
|
|
"UnityTexture2DArray",
|
|
"UnityTexture3D",
|
|
"UnityTextureCube"
|
|
};
|
|
|
|
static bool m_HLSLKeywordDictionaryBuilt = false;
|
|
|
|
public static bool IsHLSLKeyword(string id)
|
|
{
|
|
if (!m_HLSLKeywordDictionaryBuilt)
|
|
{
|
|
foreach (var numericKeyword in k_HLSLNumericKeywords)
|
|
foreach (var suffix in k_HLSLNumericKeywordSuffixes)
|
|
m_HLSLKeywords.Add(numericKeyword + suffix);
|
|
|
|
m_HLSLKeywordDictionaryBuilt = true;
|
|
}
|
|
|
|
bool isHLSLKeyword = m_HLSLKeywords.Contains(id);
|
|
|
|
return isHLSLKeyword;
|
|
}
|
|
|
|
public static bool IsShaderLabKeyWord(string id)
|
|
{
|
|
bool isShaderLabKeyword = m_ShaderLabKeywords.Contains(id.ToLower());
|
|
return isShaderLabKeyword;
|
|
}
|
|
|
|
public static bool IsShaderGraphKeyWord(string id)
|
|
{
|
|
bool isShaderGraphKeyword = m_ShaderGraphKeywords.Contains(id);
|
|
return isShaderGraphKeyword;
|
|
}
|
|
|
|
public static string ConvertToValidHLSLIdentifier(string originalId, Func<string, bool> isDisallowedIdentifier = null)
|
|
{
|
|
// Converts " 1 var * q-30 ( 0 ) (1) " to "_1_var_q_30_0_1"
|
|
if (originalId == null)
|
|
originalId = "";
|
|
|
|
var result = Regex.Replace(originalId, @"^[^A-Za-z0-9_]+|[^A-Za-z0-9_]+$", ""); // trim leading/trailing bad characters (excl '_').
|
|
result = Regex.Replace(result, @"[^A-Za-z0-9]+", "_"); // replace sequences of bad characters with underscores (incl '_').
|
|
|
|
if (result.Length == 0 || Char.IsDigit(result[0]) || IsHLSLKeyword(result) || (isDisallowedIdentifier?.Invoke(result) ?? false))
|
|
result = "_" + result;
|
|
|
|
return result;
|
|
}
|
|
|
|
private static string GetDisplaySafeName(string input)
|
|
{
|
|
//strip valid display characters from slot name
|
|
//current valid characters are whitespace and ( ) _ separators
|
|
StringBuilder cleanName = new StringBuilder();
|
|
foreach (var c in input)
|
|
{
|
|
if (c != ' ' && c != '(' && c != ')' && c != '_')
|
|
cleanName.Append(c);
|
|
}
|
|
|
|
return cleanName.ToString();
|
|
}
|
|
|
|
public static bool ValidateSlotName(string inName, out string errorMessage)
|
|
{
|
|
//check for invalid characters between display safe and hlsl safe name
|
|
if (GetDisplaySafeName(inName) != GetHLSLSafeName(inName) && GetDisplaySafeName(inName) != ConvertToValidHLSLIdentifier(inName))
|
|
{
|
|
errorMessage = "Slot name(s) found invalid character(s). Valid characters: A-Z, a-z, 0-9, _ ( ) ";
|
|
return true;
|
|
}
|
|
|
|
//if clean, return null and false
|
|
errorMessage = null;
|
|
return false;
|
|
}
|
|
|
|
public static string FloatToShaderValue(float value)
|
|
{
|
|
if (Single.IsPositiveInfinity(value))
|
|
{
|
|
return "1.#INF";
|
|
}
|
|
if (Single.IsNegativeInfinity(value))
|
|
{
|
|
return "-1.#INF";
|
|
}
|
|
if (Single.IsNaN(value))
|
|
{
|
|
return "NAN";
|
|
}
|
|
|
|
return value.ToString(CultureInfo.InvariantCulture);
|
|
}
|
|
|
|
// A number large enough to become Infinity (~FLOAT_MAX_VALUE * 10) + explanatory comment
|
|
private const string k_ShaderLabInfinityAlternatrive = "3402823500000000000000000000000000000000 /* Infinity */";
|
|
|
|
// ShaderLab doesn't support Scientific Notion nor Infinity. To stop from generating a broken shader we do this.
|
|
public static string FloatToShaderValueShaderLabSafe(float value)
|
|
{
|
|
if (Single.IsPositiveInfinity(value))
|
|
{
|
|
return k_ShaderLabInfinityAlternatrive;
|
|
}
|
|
if (Single.IsNegativeInfinity(value))
|
|
{
|
|
return "-" + k_ShaderLabInfinityAlternatrive;
|
|
}
|
|
if (Single.IsNaN(value))
|
|
{
|
|
return "NAN"; // A real error has occured, in this case we should break the shader.
|
|
}
|
|
|
|
// For single point precision, reserve 54 spaces (e-45 min + ~9 digit precision). See floating-point-numeric-types (Microsoft docs).
|
|
return value.ToString("0.######################################################", CultureInfo.InvariantCulture);
|
|
}
|
|
}
|
|
}
|