97 lines
2.5 KiB
C++
97 lines
2.5 KiB
C++
// Copyright Epic Games, Inc. All Rights Reserved.
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#pragma once
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#include "CoreMinimal.h"
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enum class ELightmapUVVersion : int32
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{
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BitByBit = 0,
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Segments = 1,
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SmallChartPacking = 2,
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ScaleChartsOrderingFix = 3,
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ChartJoiningLFix = 4,
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Allocator2DFlipFix = 5,
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ConsiderLightmapPadding = 6,
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ForceLightmapPadding = 7,
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Segments2D = 8,
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OptimalSurfaceArea = 9,
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ScaleByEdgesLength = 10,
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Latest = ScaleByEdgesLength
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};
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/**
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* Contains the vertices that are most dominated by that bone. Vertices are in Bone space.
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* Not used at runtime, but useful for fitting physics assets etc.
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*/
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struct FBoneVertInfo
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{
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// Invariant: Arrays should be same length!
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TArray<FVector3f> Positions;
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TArray<FVector3f> Normals;
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};
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/** Helper struct for building acceleration structures. */
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struct FIndexAndZ
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{
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float Z;
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int32 Index;
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/** Default constructor. */
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FIndexAndZ() {}
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/** Initialization constructor. */
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FIndexAndZ(int32 InIndex, FVector3f V)
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{
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Z = 0.30f * V.X + 0.33f * V.Y + 0.37f * V.Z;
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Index = InIndex;
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}
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};
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/** Sorting function for vertex Z/index pairs. */
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struct FCompareIndexAndZ
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{
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FORCEINLINE bool operator()(FIndexAndZ const& A, FIndexAndZ const& B) const { return A.Z < B.Z; }
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};
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/**
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* Returns true if the specified points are about equal
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*/
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inline bool PointsEqual(const FVector3f& V1, const FVector3f& V2, float ComparisonThreshold)
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{
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if (FMath::Abs(V1.X - V2.X) > ComparisonThreshold
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|| FMath::Abs(V1.Y - V2.Y) > ComparisonThreshold
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|| FMath::Abs(V1.Z - V2.Z) > ComparisonThreshold)
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{
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return false;
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}
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return true;
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}
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namespace TriangleUtilities
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{
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/*
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* This function compute the area of a triangle, it will return zero if the triangle is degenerated
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*/
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static float ComputeTriangleArea(const FVector3f& PointA, const FVector3f& PointB, const FVector3f& PointC)
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{
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return FVector3f::CrossProduct((PointB - PointA), (PointC - PointA)).Size() / 2.0f;
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}
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/*
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* This function compute the angle of a triangle corner, it will return zero if the triangle is degenerated
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*/
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static float ComputeTriangleCornerAngle(const FVector3f& PointA, const FVector3f& PointB, const FVector3f& PointC)
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{
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FVector3f E1 = (PointB - PointA);
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FVector3f E2 = (PointC - PointA);
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//Normalize both edges (unit vector) of the triangle so we get a dotProduct result that will be a valid acos input [-1, 1]
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if (!E1.Normalize() || !E2.Normalize())
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{
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//Return a null ratio if the polygon is degenerate
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return 0.0f;
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}
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float DotProduct = FVector3f::DotProduct(E1, E2);
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return FMath::Acos(DotProduct);
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}
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} |