public static List <itemWellLayerVoi> calVoi()
{
Voronoi voroObject = new Voronoi(0.1);
int iExtentDis = 200; //外边距
List <itemWellLayerVoi> listLayerVoronoi = new List <itemWellLayerVoi>();
// 读入小层数据字典
List <ItemDicLayerDataStatic> listData = cIODicLayerDataStatic.readDicLayerData2struct();
// 按小层顺序筛选,并计算voronoi,通过voronic 求取每个井层的面积
foreach (string xcm in cProjectData.ltStrProjectXCM)
{
//写到每个小层文件夹内
string filePath = Path.Combine(cProjectManager.dirPathLayerDir, xcm, cProjectManager.fileNameGE);
StreamWriter swGe = new StreamWriter(filePath, false, Encoding.UTF8);
List <ItemDicLayerDataStatic> listCurrentLayerData = listData.FindAll(p => p.sXCM == xcm);
//如果没填得检查一遍
//内部会排序并有对应的ID
//尽量让排序后的sizes和Voronoi内部的size是同一个顺序,这块需要校验=Y的情况
List <PointD> sites = new List <PointD>();
foreach (ItemDicLayerDataStatic well in listCurrentLayerData)
{
sites.Add(new PointD(well.dbX, well.dbY));
}
double[] xVal = new double[sites.Count];
double[] yVal = new double[sites.Count];
for (int i = 0; i < sites.Count; i++)
{
xVal[i] = sites[i].X;
yVal[i] = sites[i].Y;
string sLine = i + " " + xVal[i] + " " + yVal[i];
swGe.WriteLine(sLine);
}
double minX = cProjectData.ltProjectWell.Min(p => p.dbX) - iExtentDis;
double maxX = cProjectData.ltProjectWell.Max(p => p.dbX) + iExtentDis;
double minY = cProjectData.ltProjectWell.Min(p => p.dbY) - iExtentDis;
double maxY = cProjectData.ltProjectWell.Max(p => p.dbY) + iExtentDis;
List <GraphEdge> list_ge = voroObject.generateVoronoi(xVal, yVal, minX, maxX, minY, maxY);
for (int i = 0; i < list_ge.Count; i++)
{
Point p1 = new Point((int)list_ge[i].x1, (int)list_ge[i].y1);
Point p2 = new Point((int)list_ge[i].x2, (int)list_ge[i].y2);
string sLine = " size1: " + list_ge[i].site1 + " " + list_ge[i].x1.ToString("0.0") + " " + list_ge[i].y1.ToString("0.0") + " size2: " + list_ge[i].site2 + " " + list_ge[i].x2.ToString("0.0") + " " + list_ge[i].y2.ToString("0.0");
swGe.WriteLine(sLine);
}
swGe.Close();
//定义一个数据结构 就是返回 顶点序列,边的顺或者逆时针方向的结构列表
//注意 这里安装sites的个数找 但是 ge里egde存的是
List <List <PointD> > list_ClockPoints = new List <List <PointD> >();
for (int i = 0; i < sites.Count; i++)
{
List <PointD> points = new List <PointD>();
List <GraphEdge> ListEdgeCur = new List <GraphEdge>();
foreach (GraphEdge ge in list_ge)
{
if ((ge.site2 == i || ge.site1 == i) && (!(ge.x1 == ge.x2 && ge.y1 == ge.y2)))
{
ListEdgeCur.Add(ge); //收集环绕顶点的所有边
}
}
foreach (GraphEdge ge in ListEdgeCur)
{
PointD p1 = new PointD(ge.x1, ge.y1);
PointD p2 = new PointD(ge.x2, ge.y2);
if (points.FindIndex(p => p.X == p1.X && p.Y == p1.Y) < 0)
{
points.Add(p1);
}
if (points.FindIndex(p => p.X == p2.X && p.Y == p2.Y) < 0)
{
points.Add(p2); //获得顶点
}
}
List <PointD> PointDistinct = points.Distinct().ToList();
//按序号找到所有的顶点,按顺时针或者逆时针排序后输出
list_ClockPoints.Add(cSortPoints.sortPoints(PointDistinct, sites[i]));
}
//有了 listCurrentLayerData和对应的list_ClockPoints,加上对应的密度,体积系数就能按容积法求出面积,然后输出了
for (int i = 0; i < listCurrentLayerData.Count; i++)
{
itemWellLayerVoi item = new itemWellLayerVoi();
item.sJH = listCurrentLayerData[i].sJH;
item.sXCM = listCurrentLayerData[i].sXCM;
item.dbX = listCurrentLayerData[i].dbX;
item.dbY = listCurrentLayerData[i].dbY;
item.ltdpVertex = list_ClockPoints[i];//顶点
listLayerVoronoi.Add(item);
}
}//end of layerXCM foreach
return(listLayerVoronoi);
}//end of calRes
public FormCalReservor()
{
InitializeComponent();
setPanel();
voroObject = new Voronoi(0.1);
}
