sknjpn/FlagsManager

## FlagsManager
using System.Linq;
using System.Collections.Generic;
using UnityEngine;
using System;

public class FlagsManager : MonoBehaviour
{
    [SerializeField] int FieldSizeX = 50;
    [SerializeField] int FieldSizeZ = 60;
    [SerializeField] float TileSize = 2.0f;

    [SerializeField] Function functionRed = null;
    [SerializeField] Function functionBlue = null;
    [SerializeField] Material material = null;
    [SerializeField] Mesh landMesh = null;

    private List<Flag> flags = null;
    private Mesh mesh;

    public List<Flag> Flags { get => flags; set => flags = value; }

    public static FlagsManager Instance = null;

    void Start()
    {
        Instance = this;

        // Flag登録
        flags = GetComponentsInChildren<Flag>().ToList();
    }

    void OnValidate()
    {
        Instance = this;

        // Flag登録
        flags = GetComponentsInChildren<Flag>().ToList();

        UpdateMesh();
    }

    private void UpdateMesh()
    {
        mesh = new Mesh();

        // Mesh生成
        var vertices = new Vector3[(FieldSizeX + 1) * (FieldSizeZ + 1) + FieldSizeX * FieldSizeZ];

        // 四角形の頂点
        for (int x = 0; x <= FieldSizeX; ++x)
        {
            for (int z = 0; z <= FieldSizeZ; ++z)
            {
                var position = new Vector3(x - FieldSizeX / 2, 32, z - FieldSizeZ / 2) * TileSize;

                // 座標修正
                RaycastHit hit_info;
                if (Physics.Raycast(position, -Vector3.up, out hit_info, Mathf.Infinity, 1 << 8))
                    position = hit_info.point + 0.1f * Vector3.up;

                vertices[x + z * (FieldSizeX + 1)] = position;
            }
        }

        // 四角形の中心
        for (int x = 0; x < FieldSizeX; ++x)
        {
            for (int z = 0; z < FieldSizeZ; ++z)
            {
                var position = new Vector3(0.5f + x - FieldSizeX / 2, 32, 0.5f + z - FieldSizeZ / 2) * TileSize;

                // 座標修正
                RaycastHit hit_info;
                if (Physics.Raycast(position, -Vector3.up, out hit_info, Mathf.Infinity, 1 << 8))
                    position = new Vector3(hit_info.point.x, ((float)Math.Round(hit_info.point.y * 1.0f) / 1.0f), hit_info.point.z);

                vertices[(FieldSizeX + 1) * (FieldSizeZ + 1) + x + z * FieldSizeX] = position;
            }
        }

        var indexs = new List<int>[flags.Count];
        for (int i = 0; i < flags.Count; ++i)
            indexs[i] = new List<int>();

        for (int x = 0; x < FieldSizeX; ++x)
        {
            for (int z = 0; z < FieldSizeZ; ++z)
            {
                int p0 = x + z * (FieldSizeX + 1);
                int p1 = (x + 1) + z * (FieldSizeX + 1);
                int p2 = (x + 1) + (z + 1) * (FieldSizeX + 1);
                int p3 = x + (z + 1) * (FieldSizeX + 1);
                int p4 = (FieldSizeX + 1) * (FieldSizeZ + 1) + x + z * FieldSizeX;
                int n = (x + z * FieldSizeX) * 3 * 2;


                // 座標修正
                RaycastHit hit_info;
                bool cp0 = Physics.Raycast(vertices[p0] + Vector3.up, -Vector3.up, out hit_info, Mathf.Infinity, 1 << 11);
                bool cp1 = Physics.Raycast(vertices[p1] + Vector3.up, -Vector3.up, out hit_info, Mathf.Infinity, 1 << 11);
                bool cp2 = Physics.Raycast(vertices[p2] + Vector3.up, -Vector3.up, out hit_info, Mathf.Infinity, 1 << 11);
                bool cp3 = Physics.Raycast(vertices[p3] + Vector3.up, -Vector3.up, out hit_info, Mathf.Infinity, 1 << 11);
                bool cp4 = Physics.Raycast(vertices[p4] + Vector3.up, -Vector3.up, out hit_info, Mathf.Infinity, 1 << 11);

                var flag = GetNearestFlag((vertices[p0] + vertices[p1] + vertices[p2] + vertices[p3]) / 4.0f);

                // Flag
                var flag1 = GetNearestFlag((vertices[p1] + vertices[p0] + vertices[p4]) / 3.0f);
                var flag2 = GetNearestFlag((vertices[p2] + vertices[p1] + vertices[p4]) / 3.0f);
                var flag3 = GetNearestFlag((vertices[p3] + vertices[p2] + vertices[p4]) / 3.0f);
                var flag4 = GetNearestFlag((vertices[p0] + vertices[p3] + vertices[p4]) / 3.0f);
                if (cp4 && cp1 && cp0)
                {
                    indexs[GetNumberOfFlag(flag)].Add(p1);
                    indexs[GetNumberOfFlag(flag)].Add(p0);
                    indexs[GetNumberOfFlag(flag)].Add(p4);
                }
                if (cp4 && cp2 && cp1)
                {
                    indexs[GetNumberOfFlag(flag)].Add(p2);
                    indexs[GetNumberOfFlag(flag)].Add(p1);
                    indexs[GetNumberOfFlag(flag)].Add(p4);
                }
                if (cp4 && cp3 && cp2)
                {
                    indexs[GetNumberOfFlag(flag)].Add(p3);
                    indexs[GetNumberOfFlag(flag)].Add(p2);
                    indexs[GetNumberOfFlag(flag)].Add(p4);
                }
                if (cp4 && cp0 && cp3)
                {
                    indexs[GetNumberOfFlag(flag)].Add(p0);
                    indexs[GetNumberOfFlag(flag)].Add(p3);
                    indexs[GetNumberOfFlag(flag)].Add(p4);
                }
            }
        }

        mesh.vertices = vertices;
        mesh.colors = Enumerable.Repeat(Color.white, vertices.Length).ToArray();
        mesh.subMeshCount = flags.Count;
        for (int i = 0; i < flags.Count; ++i)
            mesh.SetTriangles(indexs[i], i);
        mesh.RecalculateBounds();
        mesh.RecalculateNormals();

        GetComponent<MeshFilter>().mesh = mesh;

        // Material割り当て
        GetComponent<MeshRenderer>().materials = Enumerable.Repeat(material, flags.Count).ToArray();
    }

    private void UpdateMaterials()
    {
        for (int i = 0; i < flags.Count; ++i)
        {
            if (flags[i].OccupationFunction == null) GetComponent<MeshRenderer>().materials[i].color = new Color(1.0f, 1.0f, 1.0f, 0.25f);
            if (flags[i].OccupationFunction == functionRed) GetComponent<MeshRenderer>().materials[i].color = new Color(1.0f, 0.0f, 0.0f, 0.5f);
            if (flags[i].OccupationFunction == functionBlue) GetComponent<MeshRenderer>().materials[i].color = new Color(0.0f, 0.0f, 1.0f, 0.5f);
        }
    }

    void Update()
    {
        UpdateMaterials();
    }

    private int GetNumberOfFlag(Flag flag)
    {
        for (int i = 0; i < flags.Count; ++i)
            if (flag == flags[i]) return i;

        // おかしい
        return -1;
    }

    public float GetDistanceToFlagFrom(Vector3 position)
    {
        return flags.Min(f => (f.transform.position - position).magnitude);
    }

    public Flag GetNearestFlag(Vector3 position)
    {
        position = new Vector3((int)position.x + 0.5f, 128.0f, (int)position.z + 0.5f);

        RaycastHit hit_info;
        if (Physics.Raycast(position, -Vector3.up, out hit_info, Mathf.Infinity, 1 << 8))
            position = hit_info.point;

        return flags.OrderByDescending(f => (f.transform.position - position).magnitude).Last();
    }
}
	using System.Linq;
	using System.Collections.Generic;
	using UnityEngine;
	using System;

	public class FlagsManager : MonoBehaviour
	{
	[SerializeField] int FieldSizeX = 50;
	[SerializeField] int FieldSizeZ = 60;
	[SerializeField] float TileSize = 2.0f;

	[SerializeField] Function functionRed = null;
	[SerializeField] Function functionBlue = null;
	[SerializeField] Material material = null;
	[SerializeField] Mesh landMesh = null;

	private List<Flag> flags = null;
	private Mesh mesh;

	public List<Flag> Flags { get => flags; set => flags = value; }

	public static FlagsManager Instance = null;

	void Start()
	{
	Instance = this;

	// Flag登録
	flags = GetComponentsInChildren<Flag>().ToList();
	}

	void OnValidate()
	{
	Instance = this;

	// Flag登録
	flags = GetComponentsInChildren<Flag>().ToList();

	UpdateMesh();
	}

	private void UpdateMesh()
	{
	mesh = new Mesh();

	// Mesh生成
	var vertices = new Vector3[(FieldSizeX + 1) * (FieldSizeZ + 1) + FieldSizeX * FieldSizeZ];

	// 四角形の頂点
	for (int x = 0; x <= FieldSizeX; ++x)
	{
	for (int z = 0; z <= FieldSizeZ; ++z)
	{
	var position = new Vector3(x - FieldSizeX / 2, 32, z - FieldSizeZ / 2) * TileSize;

	// 座標修正
	RaycastHit hit_info;
	if (Physics.Raycast(position, -Vector3.up, out hit_info, Mathf.Infinity, 1 << 8))
	position = hit_info.point + 0.1f * Vector3.up;

	vertices[x + z * (FieldSizeX + 1)] = position;
	}
	}

	// 四角形の中心
	for (int x = 0; x < FieldSizeX; ++x)
	{
	for (int z = 0; z < FieldSizeZ; ++z)
	{
	var position = new Vector3(0.5f + x - FieldSizeX / 2, 32, 0.5f + z - FieldSizeZ / 2) * TileSize;

	// 座標修正
	RaycastHit hit_info;
	if (Physics.Raycast(position, -Vector3.up, out hit_info, Mathf.Infinity, 1 << 8))
	position = new Vector3(hit_info.point.x, ((float)Math.Round(hit_info.point.y * 1.0f) / 1.0f), hit_info.point.z);

	vertices[(FieldSizeX + 1) * (FieldSizeZ + 1) + x + z * FieldSizeX] = position;
	}
	}

	var indexs = new List<int>[flags.Count];
	for (int i = 0; i < flags.Count; ++i)
	indexs[i] = new List<int>();

	for (int x = 0; x < FieldSizeX; ++x)
	{
	for (int z = 0; z < FieldSizeZ; ++z)
	{
	int p0 = x + z * (FieldSizeX + 1);
	int p1 = (x + 1) + z * (FieldSizeX + 1);
	int p2 = (x + 1) + (z + 1) * (FieldSizeX + 1);
	int p3 = x + (z + 1) * (FieldSizeX + 1);
	int p4 = (FieldSizeX + 1) * (FieldSizeZ + 1) + x + z * FieldSizeX;
	int n = (x + z * FieldSizeX) * 3 * 2;


	// 座標修正
	RaycastHit hit_info;
	bool cp0 = Physics.Raycast(vertices[p0] + Vector3.up, -Vector3.up, out hit_info, Mathf.Infinity, 1 << 11);
	bool cp1 = Physics.Raycast(vertices[p1] + Vector3.up, -Vector3.up, out hit_info, Mathf.Infinity, 1 << 11);
	bool cp2 = Physics.Raycast(vertices[p2] + Vector3.up, -Vector3.up, out hit_info, Mathf.Infinity, 1 << 11);
	bool cp3 = Physics.Raycast(vertices[p3] + Vector3.up, -Vector3.up, out hit_info, Mathf.Infinity, 1 << 11);
	bool cp4 = Physics.Raycast(vertices[p4] + Vector3.up, -Vector3.up, out hit_info, Mathf.Infinity, 1 << 11);

	var flag = GetNearestFlag((vertices[p0] + vertices[p1] + vertices[p2] + vertices[p3]) / 4.0f);

	// Flag
	var flag1 = GetNearestFlag((vertices[p1] + vertices[p0] + vertices[p4]) / 3.0f);
	var flag2 = GetNearestFlag((vertices[p2] + vertices[p1] + vertices[p4]) / 3.0f);
	var flag3 = GetNearestFlag((vertices[p3] + vertices[p2] + vertices[p4]) / 3.0f);
	var flag4 = GetNearestFlag((vertices[p0] + vertices[p3] + vertices[p4]) / 3.0f);
	if (cp4 && cp1 && cp0)
	{
	indexs[GetNumberOfFlag(flag)].Add(p1);
	indexs[GetNumberOfFlag(flag)].Add(p0);
	indexs[GetNumberOfFlag(flag)].Add(p4);
	}
	if (cp4 && cp2 && cp1)
	{
	indexs[GetNumberOfFlag(flag)].Add(p2);
	indexs[GetNumberOfFlag(flag)].Add(p1);
	indexs[GetNumberOfFlag(flag)].Add(p4);
	}
	if (cp4 && cp3 && cp2)
	{
	indexs[GetNumberOfFlag(flag)].Add(p3);
	indexs[GetNumberOfFlag(flag)].Add(p2);
	indexs[GetNumberOfFlag(flag)].Add(p4);
	}
	if (cp4 && cp0 && cp3)
	{
	indexs[GetNumberOfFlag(flag)].Add(p0);
	indexs[GetNumberOfFlag(flag)].Add(p3);
	indexs[GetNumberOfFlag(flag)].Add(p4);
	}
	}
	}

	mesh.vertices = vertices;
	mesh.colors = Enumerable.Repeat(Color.white, vertices.Length).ToArray();
	mesh.subMeshCount = flags.Count;
	for (int i = 0; i < flags.Count; ++i)
	mesh.SetTriangles(indexs[i], i);
	mesh.RecalculateBounds();
	mesh.RecalculateNormals();

	GetComponent<MeshFilter>().mesh = mesh;

	// Material割り当て
	GetComponent<MeshRenderer>().materials = Enumerable.Repeat(material, flags.Count).ToArray();
	}

	private void UpdateMaterials()
	{
	for (int i = 0; i < flags.Count; ++i)
	{
	if (flags[i].OccupationFunction == null) GetComponent<MeshRenderer>().materials[i].color = new Color(1.0f, 1.0f, 1.0f, 0.25f);
	if (flags[i].OccupationFunction == functionRed) GetComponent<MeshRenderer>().materials[i].color = new Color(1.0f, 0.0f, 0.0f, 0.5f);
	if (flags[i].OccupationFunction == functionBlue) GetComponent<MeshRenderer>().materials[i].color = new Color(0.0f, 0.0f, 1.0f, 0.5f);
	}
	}

	void Update()
	{
	UpdateMaterials();
	}

	private int GetNumberOfFlag(Flag flag)
	{
	for (int i = 0; i < flags.Count; ++i)
	if (flag == flags[i]) return i;

	// おかしい
	return -1;
	}

	public float GetDistanceToFlagFrom(Vector3 position)
	{
	return flags.Min(f => (f.transform.position - position).magnitude);
	}

	public Flag GetNearestFlag(Vector3 position)
	{
	position = new Vector3((int)position.x + 0.5f, 128.0f, (int)position.z + 0.5f);

	RaycastHit hit_info;
	if (Physics.Raycast(position, -Vector3.up, out hit_info, Mathf.Infinity, 1 << 8))
	position = hit_info.point;

	return flags.OrderByDescending(f => (f.transform.position - position).magnitude).Last();
	}
	}