kamyker/PointCacheBakeTool.Mesh.cs

## PointCacheBakeTool.Mesh.cs
using System.Linq;
using System.Collections.Generic;
using UnityEngine;
using System;

namespace UnityEditor.Experimental.VFX.Utility
{
    partial class PointCacheBakeTool : EditorWindow
    {
        public enum MeshBakeMode
        {
            Vertex,
            Triangle
        }

        public enum Distribution
        {
            Sequential,
            Random,
            RandomUniformArea
        }

        Distribution m_Distribution = Distribution.RandomUniformArea;
        MeshBakeMode m_MeshBakeMode = MeshBakeMode.Triangle;
        PCache.Format m_OutputFormat = PCache.Format.Ascii;

        bool m_ExportUV = false;
        bool m_ExportNormals = true;
        bool m_ExportColors = false;

        Mesh m_Mesh;
        int m_OutputPointCount = 4096;
        int m_SeedMesh;

        void OnGUI_Mesh()
        {
            GUILayout.Label("Mesh Baking", EditorStyles.boldLabel);
            m_Mesh = (Mesh)EditorGUILayout.ObjectField(Contents.mesh, m_Mesh, typeof(Mesh), false);
            m_Distribution = (Distribution)EditorGUILayout.EnumPopup(Contents.distribution, m_Distribution);
            if (m_Distribution != Distribution.RandomUniformArea)
                m_MeshBakeMode = (MeshBakeMode)EditorGUILayout.EnumPopup(Contents.meshBakeMode, m_MeshBakeMode);

            m_ExportNormals = EditorGUILayout.Toggle("Export Normals", m_ExportNormals);
            m_ExportColors = EditorGUILayout.Toggle("Export Colors", m_ExportColors);
            m_ExportUV = EditorGUILayout.Toggle("Export UVs", m_ExportUV);

            m_OutputPointCount = EditorGUILayout.IntField("Point Count", m_OutputPointCount);
            if (m_Distribution != Distribution.Sequential)
                m_SeedMesh = EditorGUILayout.IntField("Seed", m_SeedMesh);

            m_OutputFormat = (PCache.Format)EditorGUILayout.EnumPopup("File Format", m_OutputFormat);

            if (m_Mesh != null)
            {
                if (GUILayout.Button("Save to pCache file..."))
                {
                    string fileName = EditorUtility.SaveFilePanelInProject("pCacheFile", m_Mesh.name, "pcache", "Save PCache");
                    if (!string.IsNullOrEmpty(fileName))
                    {
                        try
                        {
                            EditorUtility.DisplayProgressBar("pCache bake tool", "Capturing data...", 0.0f);
                            var file = ComputePCacheFromMesh();
                            if (file != null)
                            {
                                EditorUtility.DisplayProgressBar("pCache bake tool", "Saving pCache file", 1.0f);
                                file.SaveToFile(fileName, m_OutputFormat);
                            }
                        }
                        catch (System.Exception e)
                        {
                            Debug.LogException(e);
                        }
                        EditorUtility.ClearProgressBar();
                    }
                }
                EditorGUILayout.Space();

                using (new GUILayout.VerticalScope(EditorStyles.helpBox))
                {
                    EditorGUILayout.LabelField("Mesh Statistics", EditorStyles.boldLabel);
                    EditorGUI.indentLevel++;
                    EditorGUILayout.IntField("Vertices", m_Mesh.vertexCount);
                    EditorGUILayout.IntField("Triangles", m_Mesh.triangles.Length);
                    EditorGUILayout.IntField("Sub Meshes", m_Mesh.subMeshCount);
                    EditorGUI.indentLevel--;
                }
            }

            EditorGUILayout.Space();
        }

        class MeshData
        {
            public struct Vertex
            {
                public Vector3 position;
                public Color color;
                public Vector3 normal;
                public Vector4 tangent;
                public Vector4[] uvs;

                public static Vertex operator+(Vertex a, Vertex b)
                {
                    if (a.uvs.Length != b.uvs.Length)
                        throw new InvalidOperationException("Adding compatible vertex");

                    var r = new Vertex()
                    {
                        position = a.position + b.position,
                        color = a.color + b.color,
                        normal = a.normal + b.normal,
                        tangent = a.tangent + b.tangent,
                        uvs = new Vector4[a.uvs.Length]
                    };

                    for (int i = 0; i < a.uvs.Length; ++i)
                        r.uvs[i] = a.uvs[i] + b.uvs[i];

                    return r;
                }

                public static Vertex operator*(float a, Vertex b)
                {
                    var r = new Vertex()
                    {
                        position = a * b.position,
                        color = a * b.color,
                        normal = a * b.normal,
                        tangent = a * b.tangent,
                        uvs = new Vector4[b.uvs.Length]
                    };

                    for (int i = 0; i < b.uvs.Length; ++i)
                        r.uvs[i] = a * b.uvs[i];

                    return r;
                }
            };

            public struct Triangle
            {
                public int a, b, c;
            };

            public Vertex[] vertices;
            public Triangle[] triangles;
        }

        static MeshData ComputeDataCache(Mesh input)
        {
            var positions = input.vertices;
            var normals = input.normals;
            var tangents = input.tangents;
            var colors = input.colors;
            var uvs = new List<Vector4[]>();

            normals = normals.Length == input.vertexCount ? normals : null;
            tangents = tangents.Length == input.vertexCount ? tangents : null;
            colors = colors.Length == input.vertexCount ? colors : null;

            for (int i = 0; i < 8; ++i)
            {
                var uv = new List<Vector4>();
                input.GetUVs(i, uv);
                if (uv.Count == input.vertexCount)
                {
                    uvs.Add(uv.ToArray());
                }
                else
                {
                    break;
                }
            }

            var meshData = new MeshData();
            meshData.vertices = new MeshData.Vertex[input.vertexCount];
            for (int i = 0; i < input.vertexCount; ++i)
            {
                meshData.vertices[i] = new MeshData.Vertex()
                {
                    position = positions[i],
                    color = colors != null ? colors[i] : Color.white,
                    normal = normals != null ? normals[i] : Vector3.up,
                    tangent = tangents != null ? tangents[i] : Vector4.one,
                    uvs = Enumerable.Range(0, uvs.Count).Select(c => uvs[c][i]).ToArray()
                };
            }

            meshData.triangles = new MeshData.Triangle[input.triangles.Length / 3];
            var triangles = input.triangles;
            for (int i = 0; i < meshData.triangles.Length; ++i)
            {
                meshData.triangles[i] = new MeshData.Triangle()
                {
                    a = triangles[i * 3 + 0],
                    b = triangles[i * 3 + 1],
                    c = triangles[i * 3 + 2],
                };
            }
            return meshData;
        }

        abstract class Picker
        {
            public abstract MeshData.Vertex GetNext();

            protected Picker(MeshData data)
            {
                m_cacheData = data;
            }

            //See http://inis.jinr.ru/sl/vol1/CMC/Graphics_Gems_1,ed_A.Glassner.pdf (p24) uniform distribution from two numbers in triangle generating barycentric coordinate
            protected readonly static  Vector2 center_of_sampling = new Vector2(4.0f / 9.0f, 3.0f / 4.0f);
            protected MeshData.Vertex Interpolate(MeshData.Triangle triangle, Vector2 p)
            {
                return Interpolate(m_cacheData.vertices[triangle.a], m_cacheData.vertices[triangle.b], m_cacheData.vertices[triangle.c], p);
            }

            protected static MeshData.Vertex Interpolate(MeshData.Vertex A, MeshData.Vertex B, MeshData.Vertex C, Vector2 p)
            {
                float s = p.x;
                float t = Mathf.Sqrt(p.y);
                float a = 1.0f - t;
                float b = (1 - s) * t;
                float c = s * t;

                var r = a * A + b * B + c * C;
                r.normal = r.normal.normalized;
                var tangent = new Vector3(r.tangent.x, r.tangent.y, r.tangent.z).normalized;
                r.tangent = new Vector4(tangent.x, tangent.y, tangent.z, r.tangent.w > 0.0f ? 1.0f : -1.0f);
                return r;
            }

            protected MeshData m_cacheData;
        }

        abstract class RandomPicker : Picker
        {
            protected RandomPicker(MeshData data, int seed) : base(data)
            {
                m_Rand = new System.Random(seed);
            }

            protected float GetNextRandFloat()
            {
                return (float)m_Rand.NextDouble(); //[0; 1[
            }

            protected System.Random m_Rand;
        }

        class RandomPickerVertex : RandomPicker
        {
            public RandomPickerVertex(MeshData data, int seed) : base(data, seed)
            {
            }

            public override sealed MeshData.Vertex GetNext()
            {
                int randomIndex = m_Rand.Next(0, m_cacheData.vertices.Length);
                return m_cacheData.vertices[randomIndex];
            }
        }

        class SequentialPickerVertex : Picker
        {
            private uint m_Index = 0;
            public SequentialPickerVertex(MeshData data) : base(data)
            {
            }

            public override sealed MeshData.Vertex GetNext()
            {
                var r = m_cacheData.vertices[m_Index];
                m_Index++;
                if (m_Index >= m_cacheData.vertices.Length)
                    m_Index = 0;
                return r;
            }
        }

        class RandomPickerTriangle : RandomPicker
        {
            public RandomPickerTriangle(MeshData data, int seed) : base(data, seed)
            {
            }

            public override sealed MeshData.Vertex GetNext()
            {
                var index = m_Rand.Next(0, m_cacheData.triangles.Length);
                var rand = new Vector2(GetNextRandFloat(), GetNextRandFloat());
                return Interpolate(m_cacheData.triangles[index], rand);
            }
        }

        class RandomPickerUniformArea : RandomPicker
        {
            private double[] m_accumulatedAreaTriangles;

            private double ComputeTriangleArea(MeshData.Triangle t)
            {
                var A = m_cacheData.vertices[t.a].position;
                var B = m_cacheData.vertices[t.b].position;
                var C = m_cacheData.vertices[t.c].position;
                return 0.5f * Vector3.Cross(B - A, C - A).magnitude;
            }

            public RandomPickerUniformArea(MeshData data, int seed) : base(data, seed)
            {
                m_accumulatedAreaTriangles = new double[data.triangles.Length];
                m_accumulatedAreaTriangles[0] = ComputeTriangleArea(data.triangles[0]);
                for (int i = 1; i < data.triangles.Length; ++i)
                {
                    m_accumulatedAreaTriangles[i] = m_accumulatedAreaTriangles[i - 1] + ComputeTriangleArea(data.triangles[i]);
                }
            }

            private uint FindIndexOfArea(double area)
            {
                uint min = 0;
                uint max = (uint)m_accumulatedAreaTriangles.Length - 1;
                uint mid = max >> 1;
                while (max >= min)
                {
                    if (mid > m_accumulatedAreaTriangles.Length)
                        throw new InvalidOperationException("Cannot Find FindIndexOfArea");

                    if (m_accumulatedAreaTriangles[mid] >= area &&
                        (mid == 0 || (m_accumulatedAreaTriangles[mid - 1] < area)))
                    {
                        return mid;
                    }
                    else if (area < m_accumulatedAreaTriangles[mid])
                    {
                        max = mid - 1;
                    }
                    else
                    {
                        min = mid + 1;
                    }
                    mid = (min + max) >> 1;
                }
                throw new InvalidOperationException("Cannot FindIndexOfArea");
            }

            public override sealed MeshData.Vertex GetNext()
            {
                var areaPosition = m_Rand.NextDouble() * m_accumulatedAreaTriangles.Last();
                uint areaIndex = FindIndexOfArea(areaPosition);

                var rand = new Vector2(GetNextRandFloat(), GetNextRandFloat());
                return Interpolate(m_cacheData.triangles[areaIndex], rand);
            }
        }

        class SequentialPickerTriangle : Picker
        {
            private uint m_Index = 0;
            public SequentialPickerTriangle(MeshData data) : base(data)
            {
            }

            public override sealed MeshData.Vertex GetNext()
            {
                var t = m_cacheData.triangles[m_Index];
                m_Index++;
                if (m_Index >= m_cacheData.triangles.Length)
                    m_Index = 0;
                return Interpolate(t, center_of_sampling);
            }
        }

        PCache ComputePCacheFromMesh()
        {
            var meshCache = ComputeDataCache(m_Mesh);

            Picker picker = null;
            if (m_Distribution == Distribution.Sequential)
            {
                if (m_MeshBakeMode == MeshBakeMode.Vertex)
                {
                    picker = new SequentialPickerVertex(meshCache);
                }
                else if (m_MeshBakeMode == MeshBakeMode.Triangle)
                {
                    picker = new SequentialPickerTriangle(meshCache);
                }
            }
            else if (m_Distribution == Distribution.Random)
            {
                if (m_MeshBakeMode == MeshBakeMode.Vertex)
                {
                    picker = new RandomPickerVertex(meshCache, m_SeedMesh);
                }
                else if (m_MeshBakeMode == MeshBakeMode.Triangle)
                {
                    picker = new RandomPickerTriangle(meshCache, m_SeedMesh);
                }
            }
            else if (m_Distribution == Distribution.RandomUniformArea)
            {
                picker = new RandomPickerUniformArea(meshCache, m_SeedMesh);
            }
            if (picker == null)
                throw new InvalidOperationException("Unable to find picker");

            var positions = new List<Vector3>();
            var normals = m_ExportNormals ? new List<Vector3>() : null;
            var colors = m_ExportColors ? new List<Vector4>() : null;
            var uvs = m_ExportUV ? new List<Vector4>() : null;

            for (int i = 0; i < m_OutputPointCount; ++i)
            {
                if (i % 64 == 0)
                {
                    var cancel = EditorUtility.DisplayCancelableProgressBar("pCache bake tool", string.Format("Sampling data... {0}/{1}", i, m_OutputPointCount), (float)i / (float)m_OutputPointCount);
                    if (cancel)
                    {
                        return null;
                    }
                }

                var vertex = picker.GetNext();
                positions.Add(vertex.position);
                if (m_ExportNormals) normals.Add(vertex.normal);
                if (m_ExportColors) colors.Add(vertex.color);
                if (m_ExportUV) uvs.Add(vertex.uvs.Any() ? vertex.uvs[0] : Vector4.zero);
            }

            var file = new PCache();
            file.AddVector3Property("position");
            if (m_ExportNormals) file.AddVector3Property("normal");
            if (m_ExportColors) file.AddColorProperty("color");
            if (m_ExportUV) file.AddVector4Property("uv");

            EditorUtility.DisplayProgressBar("pCache bake tool", "Generating pCache...", 0.0f);
            file.SetVector3Data("position", positions);
            if (m_ExportNormals) file.SetVector3Data("normal", normals);
            if (m_ExportColors) file.SetColorData("color", colors);
            if (m_ExportUV) file.SetVector4Data("uv", uvs);

            EditorUtility.ClearProgressBar();
            return file;
        }

        static partial class Contents
        {
            public static GUIContent meshBakeMode = new GUIContent("Bake Mode");
            public static GUIContent distribution = new GUIContent("Distribution");
            public static GUIContent mesh = new GUIContent("Mesh");
        }
    }
}
	using System.Linq;
	using System.Collections.Generic;
	using UnityEngine;
	using System;

	namespace UnityEditor.Experimental.VFX.Utility
	{
	partial class PointCacheBakeTool : EditorWindow
	{
	public enum MeshBakeMode
	{
	Vertex,
	Triangle
	}

	public enum Distribution
	{
	Sequential,
	Random,
	RandomUniformArea
	}

	Distribution m_Distribution = Distribution.RandomUniformArea;
	MeshBakeMode m_MeshBakeMode = MeshBakeMode.Triangle;
	PCache.Format m_OutputFormat = PCache.Format.Ascii;

	bool m_ExportUV = false;
	bool m_ExportNormals = true;
	bool m_ExportColors = false;

	Mesh m_Mesh;
	int m_OutputPointCount = 4096;
	int m_SeedMesh;

	void OnGUI_Mesh()
	{
	GUILayout.Label("Mesh Baking", EditorStyles.boldLabel);
	m_Mesh = (Mesh)EditorGUILayout.ObjectField(Contents.mesh, m_Mesh, typeof(Mesh), false);
	m_Distribution = (Distribution)EditorGUILayout.EnumPopup(Contents.distribution, m_Distribution);
	if (m_Distribution != Distribution.RandomUniformArea)
	m_MeshBakeMode = (MeshBakeMode)EditorGUILayout.EnumPopup(Contents.meshBakeMode, m_MeshBakeMode);

	m_ExportNormals = EditorGUILayout.Toggle("Export Normals", m_ExportNormals);
	m_ExportColors = EditorGUILayout.Toggle("Export Colors", m_ExportColors);
	m_ExportUV = EditorGUILayout.Toggle("Export UVs", m_ExportUV);

	m_OutputPointCount = EditorGUILayout.IntField("Point Count", m_OutputPointCount);
	if (m_Distribution != Distribution.Sequential)
	m_SeedMesh = EditorGUILayout.IntField("Seed", m_SeedMesh);

	m_OutputFormat = (PCache.Format)EditorGUILayout.EnumPopup("File Format", m_OutputFormat);

	if (m_Mesh != null)
	{
	if (GUILayout.Button("Save to pCache file..."))
	{
	string fileName = EditorUtility.SaveFilePanelInProject("pCacheFile", m_Mesh.name, "pcache", "Save PCache");
	if (!string.IsNullOrEmpty(fileName))
	{
	try
	{
	EditorUtility.DisplayProgressBar("pCache bake tool", "Capturing data...", 0.0f);
	var file = ComputePCacheFromMesh();
	if (file != null)
	{
	EditorUtility.DisplayProgressBar("pCache bake tool", "Saving pCache file", 1.0f);
	file.SaveToFile(fileName, m_OutputFormat);
	}
	}
	catch (System.Exception e)
	{
	Debug.LogException(e);
	}
	EditorUtility.ClearProgressBar();
	}
	}
	EditorGUILayout.Space();

	using (new GUILayout.VerticalScope(EditorStyles.helpBox))
	{
	EditorGUILayout.LabelField("Mesh Statistics", EditorStyles.boldLabel);
	EditorGUI.indentLevel++;
	EditorGUILayout.IntField("Vertices", m_Mesh.vertexCount);
	EditorGUILayout.IntField("Triangles", m_Mesh.triangles.Length);
	EditorGUILayout.IntField("Sub Meshes", m_Mesh.subMeshCount);
	EditorGUI.indentLevel--;
	}
	}

	EditorGUILayout.Space();
	}

	class MeshData
	{
	public struct Vertex
	{
	public Vector3 position;
	public Color color;
	public Vector3 normal;
	public Vector4 tangent;
	public Vector4[] uvs;

	public static Vertex operator+(Vertex a, Vertex b)
	{
	if (a.uvs.Length != b.uvs.Length)
	throw new InvalidOperationException("Adding compatible vertex");

	var r = new Vertex()
	{
	position = a.position + b.position,
	color = a.color + b.color,
	normal = a.normal + b.normal,
	tangent = a.tangent + b.tangent,
	uvs = new Vector4[a.uvs.Length]
	};

	for (int i = 0; i < a.uvs.Length; ++i)
	r.uvs[i] = a.uvs[i] + b.uvs[i];

	return r;
	}

	public static Vertex operator*(float a, Vertex b)
	{
	var r = new Vertex()
	{
	position = a * b.position,
	color = a * b.color,
	normal = a * b.normal,
	tangent = a * b.tangent,
	uvs = new Vector4[b.uvs.Length]
	};

	for (int i = 0; i < b.uvs.Length; ++i)
	r.uvs[i] = a * b.uvs[i];

	return r;
	}
	};

	public struct Triangle
	{
	public int a, b, c;
	};

	public Vertex[] vertices;
	public Triangle[] triangles;
	}

	static MeshData ComputeDataCache(Mesh input)
	{
	var positions = input.vertices;
	var normals = input.normals;
	var tangents = input.tangents;
	var colors = input.colors;
	var uvs = new List<Vector4[]>();

	normals = normals.Length == input.vertexCount ? normals : null;
	tangents = tangents.Length == input.vertexCount ? tangents : null;
	colors = colors.Length == input.vertexCount ? colors : null;

	for (int i = 0; i < 8; ++i)
	{
	var uv = new List<Vector4>();
	input.GetUVs(i, uv);
	if (uv.Count == input.vertexCount)
	{
	uvs.Add(uv.ToArray());
	}
	else
	{
	break;
	}
	}

	var meshData = new MeshData();
	meshData.vertices = new MeshData.Vertex[input.vertexCount];
	for (int i = 0; i < input.vertexCount; ++i)
	{
	meshData.vertices[i] = new MeshData.Vertex()
	{
	position = positions[i],
	color = colors != null ? colors[i] : Color.white,
	normal = normals != null ? normals[i] : Vector3.up,
	tangent = tangents != null ? tangents[i] : Vector4.one,
	uvs = Enumerable.Range(0, uvs.Count).Select(c => uvs[c][i]).ToArray()
	};
	}

	meshData.triangles = new MeshData.Triangle[input.triangles.Length / 3];
	var triangles = input.triangles;
	for (int i = 0; i < meshData.triangles.Length; ++i)
	{
	meshData.triangles[i] = new MeshData.Triangle()
	{
	a = triangles[i * 3 + 0],
	b = triangles[i * 3 + 1],
	c = triangles[i * 3 + 2],
	};
	}
	return meshData;
	}

	abstract class Picker
	{
	public abstract MeshData.Vertex GetNext();

	protected Picker(MeshData data)
	{
	m_cacheData = data;
	}

	//See http://inis.jinr.ru/sl/vol1/CMC/Graphics_Gems_1,ed_A.Glassner.pdf (p24) uniform distribution from two numbers in triangle generating barycentric coordinate
	protected readonly static Vector2 center_of_sampling = new Vector2(4.0f / 9.0f, 3.0f / 4.0f);
	protected MeshData.Vertex Interpolate(MeshData.Triangle triangle, Vector2 p)
	{
	return Interpolate(m_cacheData.vertices[triangle.a], m_cacheData.vertices[triangle.b], m_cacheData.vertices[triangle.c], p);
	}

	protected static MeshData.Vertex Interpolate(MeshData.Vertex A, MeshData.Vertex B, MeshData.Vertex C, Vector2 p)
	{
	float s = p.x;
	float t = Mathf.Sqrt(p.y);
	float a = 1.0f - t;
	float b = (1 - s) * t;
	float c = s * t;

	var r = a * A + b * B + c * C;
	r.normal = r.normal.normalized;
	var tangent = new Vector3(r.tangent.x, r.tangent.y, r.tangent.z).normalized;
	r.tangent = new Vector4(tangent.x, tangent.y, tangent.z, r.tangent.w > 0.0f ? 1.0f : -1.0f);
	return r;
	}

	protected MeshData m_cacheData;
	}

	abstract class RandomPicker : Picker
	{
	protected RandomPicker(MeshData data, int seed) : base(data)
	{
	m_Rand = new System.Random(seed);
	}

	protected float GetNextRandFloat()
	{
	return (float)m_Rand.NextDouble(); //[0; 1[
	}

	protected System.Random m_Rand;
	}

	class RandomPickerVertex : RandomPicker
	{
	public RandomPickerVertex(MeshData data, int seed) : base(data, seed)
	{
	}

	public override sealed MeshData.Vertex GetNext()
	{
	int randomIndex = m_Rand.Next(0, m_cacheData.vertices.Length);
	return m_cacheData.vertices[randomIndex];
	}
	}

	class SequentialPickerVertex : Picker
	{
	private uint m_Index = 0;
	public SequentialPickerVertex(MeshData data) : base(data)
	{
	}

	public override sealed MeshData.Vertex GetNext()
	{
	var r = m_cacheData.vertices[m_Index];
	m_Index++;
	if (m_Index >= m_cacheData.vertices.Length)
	m_Index = 0;
	return r;
	}
	}

	class RandomPickerTriangle : RandomPicker
	{
	public RandomPickerTriangle(MeshData data, int seed) : base(data, seed)
	{
	}

	public override sealed MeshData.Vertex GetNext()
	{
	var index = m_Rand.Next(0, m_cacheData.triangles.Length);
	var rand = new Vector2(GetNextRandFloat(), GetNextRandFloat());
	return Interpolate(m_cacheData.triangles[index], rand);
	}
	}

	class RandomPickerUniformArea : RandomPicker
	{
	private double[] m_accumulatedAreaTriangles;

	private double ComputeTriangleArea(MeshData.Triangle t)
	{
	var A = m_cacheData.vertices[t.a].position;
	var B = m_cacheData.vertices[t.b].position;
	var C = m_cacheData.vertices[t.c].position;
	return 0.5f * Vector3.Cross(B - A, C - A).magnitude;
	}

	public RandomPickerUniformArea(MeshData data, int seed) : base(data, seed)
	{
	m_accumulatedAreaTriangles = new double[data.triangles.Length];
	m_accumulatedAreaTriangles[0] = ComputeTriangleArea(data.triangles[0]);
	for (int i = 1; i < data.triangles.Length; ++i)
	{
	m_accumulatedAreaTriangles[i] = m_accumulatedAreaTriangles[i - 1] + ComputeTriangleArea(data.triangles[i]);
	}
	}

	private uint FindIndexOfArea(double area)
	{
	uint min = 0;
	uint max = (uint)m_accumulatedAreaTriangles.Length - 1;
	uint mid = max >> 1;
	while (max >= min)
	{
	if (mid > m_accumulatedAreaTriangles.Length)
	throw new InvalidOperationException("Cannot Find FindIndexOfArea");

	if (m_accumulatedAreaTriangles[mid] >= area &&
	(mid == 0 \|\| (m_accumulatedAreaTriangles[mid - 1] < area)))
	{
	return mid;
	}
	else if (area < m_accumulatedAreaTriangles[mid])
	{
	max = mid - 1;
	}
	else
	{
	min = mid + 1;
	}
	mid = (min + max) >> 1;
	}
	throw new InvalidOperationException("Cannot FindIndexOfArea");
	}

	public override sealed MeshData.Vertex GetNext()
	{
	var areaPosition = m_Rand.NextDouble() * m_accumulatedAreaTriangles.Last();
	uint areaIndex = FindIndexOfArea(areaPosition);

	var rand = new Vector2(GetNextRandFloat(), GetNextRandFloat());
	return Interpolate(m_cacheData.triangles[areaIndex], rand);
	}
	}

	class SequentialPickerTriangle : Picker
	{
	private uint m_Index = 0;
	public SequentialPickerTriangle(MeshData data) : base(data)
	{
	}

	public override sealed MeshData.Vertex GetNext()
	{
	var t = m_cacheData.triangles[m_Index];
	m_Index++;
	if (m_Index >= m_cacheData.triangles.Length)
	m_Index = 0;
	return Interpolate(t, center_of_sampling);
	}
	}

	PCache ComputePCacheFromMesh()
	{
	var meshCache = ComputeDataCache(m_Mesh);

	Picker picker = null;
	if (m_Distribution == Distribution.Sequential)
	{
	if (m_MeshBakeMode == MeshBakeMode.Vertex)
	{
	picker = new SequentialPickerVertex(meshCache);
	}
	else if (m_MeshBakeMode == MeshBakeMode.Triangle)
	{
	picker = new SequentialPickerTriangle(meshCache);
	}
	}
	else if (m_Distribution == Distribution.Random)
	{
	if (m_MeshBakeMode == MeshBakeMode.Vertex)
	{
	picker = new RandomPickerVertex(meshCache, m_SeedMesh);
	}
	else if (m_MeshBakeMode == MeshBakeMode.Triangle)
	{
	picker = new RandomPickerTriangle(meshCache, m_SeedMesh);
	}
	}
	else if (m_Distribution == Distribution.RandomUniformArea)
	{
	picker = new RandomPickerUniformArea(meshCache, m_SeedMesh);
	}
	if (picker == null)
	throw new InvalidOperationException("Unable to find picker");

	var positions = new List<Vector3>();
	var normals = m_ExportNormals ? new List<Vector3>() : null;
	var colors = m_ExportColors ? new List<Vector4>() : null;
	var uvs = m_ExportUV ? new List<Vector4>() : null;

	for (int i = 0; i < m_OutputPointCount; ++i)
	{
	if (i % 64 == 0)
	{
	var cancel = EditorUtility.DisplayCancelableProgressBar("pCache bake tool", string.Format("Sampling data... {0}/{1}", i, m_OutputPointCount), (float)i / (float)m_OutputPointCount);
	if (cancel)
	{
	return null;
	}
	}

	var vertex = picker.GetNext();
	positions.Add(vertex.position);
	if (m_ExportNormals) normals.Add(vertex.normal);
	if (m_ExportColors) colors.Add(vertex.color);
	if (m_ExportUV) uvs.Add(vertex.uvs.Any() ? vertex.uvs[0] : Vector4.zero);
	}

	var file = new PCache();
	file.AddVector3Property("position");
	if (m_ExportNormals) file.AddVector3Property("normal");
	if (m_ExportColors) file.AddColorProperty("color");
	if (m_ExportUV) file.AddVector4Property("uv");

	EditorUtility.DisplayProgressBar("pCache bake tool", "Generating pCache...", 0.0f);
	file.SetVector3Data("position", positions);
	if (m_ExportNormals) file.SetVector3Data("normal", normals);
	if (m_ExportColors) file.SetColorData("color", colors);
	if (m_ExportUV) file.SetVector4Data("uv", uvs);

	EditorUtility.ClearProgressBar();
	return file;
	}

	static partial class Contents
	{
	public static GUIContent meshBakeMode = new GUIContent("Bake Mode");
	public static GUIContent distribution = new GUIContent("Distribution");
	public static GUIContent mesh = new GUIContent("Mesh");
	}
	}
	}