Пример #1
0
 private double?GetDataValue(int itemNum, int timeIdx)
 {
     if (_dfs2File.ItemInfo[itemNum].DataType == DfsSimpleType.Float)
     {
         var datastruct = (IDfsItemData <float>)_dfs2File.ReadItemTimeStep(itemNum + 1, timeIdx);
         // ReSharper disable CompareOfFloatsByEqualityOperator
         if (datastruct.Data[0] != _deleteValueFloat)
         // ReSharper restore CompareOfFloatsByEqualityOperator
         {
             return(Convert.ToDouble(datastruct.Data[0]));
         }
     }
     else if (_dfs2File.ItemInfo[itemNum].DataType == DfsSimpleType.Double)
     {
         var datastruct = (IDfsItemData <double>)_dfs2File.ReadItemTimeStep(itemNum + 1, timeIdx);
         // ReSharper disable CompareOfFloatsByEqualityOperator
         if (datastruct.Data[0] != _deleteValueDouble)
         // ReSharper restore CompareOfFloatsByEqualityOperator
         {
             return(datastruct.Data[0]);
         }
     }
     // if values are not real, return null.
     return(null);
 }
Пример #2
0
        static void Main(string[] args)
        {
            string filename = @"..\..\TestData\OresundHD.dfs2";

            // Load the file
            Dfs2File dfs2File = DfsFileFactory.Dfs2FileOpen(filename);

            // Print out some info on the spatial axis
            IDfsAxisEqD2 axis = (IDfsAxisEqD2)dfs2File.SpatialAxis;

            Console.Out.WriteLine("Size of grid    : {0} x {1}", axis.XCount, axis.YCount);
            Console.Out.WriteLine("Projection      : " + dfs2File.FileInfo.Projection.WKTString);

            // Print out some info of the first item
            IDfsSimpleDynamicItemInfo dynamicItemInfo = dfs2File.ItemInfo[0];

            Console.Out.WriteLine("Item 1 name     : " + dynamicItemInfo.Name);
            Console.Out.WriteLine("Item 1 datatype : " + dynamicItemInfo.DataType);

            // This iterates through the first 5 time steps and print out the value in the grid
            // at index (3,4) for the first item
            for (int i = 0; i < 5; i++)
            {
                IDfsItemData2D <float> data2D = (IDfsItemData2D <float>)dfs2File.ReadItemTimeStep(1, i);
                float value = data2D[3, 4];
                Console.Out.WriteLine("Value in time step {0} = {1}", i, value);
            }
        }
Пример #3
0
        /// <summary>
        /// Example of how to get from a geographical coordinate to an (j,k) index
        /// in the 2D grid. It also shows how to get the closest cell value and how
        /// to perform bilinear interpolation.
        /// <para>
        /// The method assumes that the OresundHD.dfs2 test file is the input file.
        /// </para>
        /// </summary>
        /// <param name="filename">Path and name of OresundHD.dfs2 test file</param>
        public static void GetjkIndexForGeoCoordinate(string filename)
        {
            Dfs2File file = DfsFileFactory.Dfs2FileOpen(filename);

            // The spatial axis is a EqD2 axis
            IDfsAxisEqD2 axis = (IDfsAxisEqD2)file.SpatialAxis;

            // Data for first time step
            IDfsItemData2D <float> data = (IDfsItemData2D <float>)file.ReadItemTimeStep(1, 0);

            // Get the projection and create a cartography object
            IDfsProjection projection = file.FileInfo.Projection;

            DHI.Projections.Cartography cart = new DHI.Projections.Cartography(projection.WKTString, projection.Longitude, projection.Latitude, projection.Orientation);

            // Coordinates just south of Amager
            double lon = 12.59;
            double lat = 55.54;

            // Get the (x,y) grid coordinates
            double x;
            double y;

            cart.Geo2Xy(lon, lat, out x, out y);

            Console.Out.WriteLine("Grid coordinates          (x,y) = ({0:0.000},{1:0.000})", x, y);
            Console.Out.WriteLine("Relative grid coordinates (x,y) = ({0:0.000},{1:0.000})", x / axis.Dx, y / axis.Dy);

            // Calculate the cell indices of the lon-lat coordinate.
            // The cell extents from its center and +/- 1/2 dx and dy
            // in each direction
            int j = (int)(x / axis.Dx + 0.5); // 30
            int k = (int)(y / axis.Dy + 0.5); // 27

            Console.Out.WriteLine("Value in cell ({0},{1})           = {2}", j, k, data[j, k]);

            // If you want to interpolate between the values, calculate
            // the (j,k) indices of lower left corner and do bilinear interpolation.
            // This procedure does not take delete values into account!!!
            j = (int)(x / axis.Dx);                 // 30
            k = (int)(y / axis.Dy);                 // 26

            double xFrac = (x % axis.Dx) / axis.Dx; // fraction of j+1 value
            double yFrac = (y % axis.Dy) / axis.Dy; // fraction of k+1 value

            double vk   = (1 - xFrac) * data[j, k] + xFrac * data[j + 1, k];
            double vkp1 = (1 - xFrac) * data[j, k + 1] + xFrac * data[j + 1, k + 1];
            double v    = (1 - yFrac) * vk + yFrac * vkp1;

            Console.Out.WriteLine("Interpolated value              = {0}", v);

            file.Close();
        }
Пример #4
0
        /// <summary>
        /// Introductory example of how to load a dfs2 file.
        /// <para>
        /// The method assumes that the OresundHD.dfs2 test file
        /// is the input file.
        /// </para>
        /// </summary>
        /// <param name="filename">path and name of OresundHD.dfs2 test file</param>
        public static void ReadingDfs2File(string filename)
        {
            // Open the file as a dfs2 file
            Dfs2File dfs2File = DfsFileFactory.Dfs2FileOpen(filename);

            // Spatial axis for this file is a 2D equidistant axis
            IDfsAxisEqD2 axisEqD2 = ((IDfsAxisEqD2)dfs2File.SpatialAxis);
            double       dx       = axisEqD2.Dx;                         // 900
            double       dy       = axisEqD2.Dy;                         // 900

            // Header information is contained in the IDfsFileInfo
            IDfsFileInfo fileInfo         = dfs2File.FileInfo;
            int          steps            = fileInfo.TimeAxis.NumberOfTimeSteps; // 13
            string       projectionString = fileInfo.Projection.WKTString;       // "UTM-33"

            // Information on each of the dynamic items, here the first one
            IDfsSimpleDynamicItemInfo dynamicItemInfo = dfs2File.ItemInfo[0];
            string        nameOfFirstDynamicItem      = dynamicItemInfo.Name;     // "H Water Depth m"
            DfsSimpleType typeOfFirstDynamicItem      = dynamicItemInfo.DataType; // Float

            // Read data of first item, third time step (items start by 1, timesteps by 0),
            // assuming data is of type float.
            IDfsItemData2D <float> data2D = (IDfsItemData2D <float>)dfs2File.ReadItemTimeStep(1, 2);
            // Get the value at (i,j) = (3,4) of the item and timestep
            float value = data2D[3, 4];                                  // 11.3634329

            // This iterates through all the timesteps and items in the file
            // For performance reasons it is important to iterate over time steps
            // first and items second.
            for (int i = 0; i < steps; i++)
            {
                for (int j = 1; j <= dfs2File.ItemInfo.Count; j++)
                {
                    data2D = (IDfsItemData2D <float>)dfs2File.ReadItemTimeStep(j, i);
                    value  = data2D[3, 4];
                }
            }
        }
Пример #5
0
        /// <summary>
        /// Create dfsu and mesh file from dfs2 file.
        /// <para>
        /// Note 1: Boundary code is set to land value at
        ///         all boundaries of mesh and dfsu file.
        ///         These must be updated to something "better"
        ///         if to use as input in another simulation.
        /// </para>
        /// <para>
        /// Note 2: P and Q values are not rotated with the
        ///         grid, but should be so, if used in the
        ///         projected coordinate system. It must take
        ///         the 327 degrees rotation into account.
        /// </para>
        /// </summary>
        /// <param name="dfs2Filename">Name of input dfs2 file, e.g. the OresundHD.dfs2</param>
        /// <param name="meshFilename">Name of output mesh file</param>
        /// <param name="dfsuFilename">Name of output dfsu file</param>
        public static void CreateDfsuFromDfs2(string dfs2Filename, string meshFilename, string dfsuFilename)
        {
            // Open file
            Dfs2File dfs2 = DfsFileFactory.Dfs2FileOpen(dfs2Filename);

            // Read bathymetry from first static item
            IDfsStaticItem bathymetryItem = dfs2.ReadStaticItemNext();

            float[] bathymetry = (float[])bathymetryItem.Data;

            // Extract spatial axis
            IDfsAxisEqD2 spatialAxis = (IDfsAxisEqD2)dfs2.SpatialAxis;
            // Some convenience variables
            double dx     = spatialAxis.Dx;
            double dy     = spatialAxis.Dy;
            double x0     = spatialAxis.X0;
            double y0     = spatialAxis.Y0;
            int    xCount = spatialAxis.XCount;
            int    yCount = spatialAxis.YCount;

            // First custom block (index 0) contains the M21_MISC values,
            // where the 4th (index 3) is the land value
            float landValue = (float)dfs2.FileInfo.CustomBlocks[0][3];

            //-----------------------------------------
            // Find out which elements in the dfs2 grid that is not a land value
            // and include all those elements and their surrounding nodes in mesh

            // Arrays indicating if element and node in grid is used or not in mesh
            bool[,] elmts = new bool[xCount, yCount];
            int[,] nodes  = new int[xCount + 1, yCount + 1];

            // Loop over all elements in 2D grid
            for (int l = 0; l < yCount; l++)
            {
                for (int k = 0; k < xCount; k++)
                {
                    // If bathymetry is not land value, use element.
                    if (bathymetry[k + l * xCount] != landValue)
                    {
                        // element [l,k] is used, and also the 4 nodes around it
                        elmts[k, l]         = true;
                        nodes[k, l]         = 1;
                        nodes[k + 1, l]     = 1;
                        nodes[k, l + 1]     = 1;
                        nodes[k + 1, l + 1] = 1;
                    }
                }
            }

            //-----------------------------------------
            // Create new mest nodes

            // Cartography object can convert grid (x,y) to projection (east,north)
            IDfsProjection proj = dfs2.FileInfo.Projection;

            DHI.Projections.Cartography cart = new DHI.Projections.Cartography(proj.WKTString, proj.Longitude, proj.Latitude, proj.Orientation);

            // New mesh nodes
            List <double> X    = new List <double>();
            List <double> Y    = new List <double>();
            List <float>  Zf   = new List <float>();  // float values for dfsu file
            List <double> Zd   = new List <double>(); // double values for mesh file
            List <int>    Code = new List <int>();

            // Loop over all nodes
            int nodesCount = 0;

            for (int l = 0; l < yCount + 1; l++)
            {
                for (int k = 0; k < xCount + 1; k++)
                {
                    // Check if node is included in mesh
                    if (nodes[k, l] > 0)
                    {
                        // Convert from mesh (x,y) to projection (east,north)
                        double east, north;
                        cart.Xy2Proj((k - 0.5) * dx + x0, (l - 0.5) * dy + y0, out east, out north);

                        // Average Z on node from neighbouring grid cell values, cell value is used
                        // unless they are outside grid or has land values
                        double z      = 0;
                        int    zCount = 0;
                        if (k > 0 && l > 0 && bathymetry[k - 1 + (l - 1) * xCount] != landValue)
                        {
                            zCount++;                z += bathymetry[k - 1 + (l - 1) * xCount];
                        }
                        if (k < xCount && l > 0 && bathymetry[k + (l - 1) * xCount] != landValue)
                        {
                            zCount++;                z += bathymetry[k + (l - 1) * xCount];
                        }
                        if (k > 0 && l < yCount && bathymetry[k - 1 + (l) * xCount] != landValue)
                        {
                            zCount++;                z += bathymetry[k - 1 + (l) * xCount];
                        }
                        if (k < xCount && l < yCount && bathymetry[k + (l) * xCount] != landValue)
                        {
                            zCount++;                z += bathymetry[k + (l) * xCount];
                        }

                        if (zCount > 0)
                        {
                            z /= zCount;
                        }
                        else
                        {
                            z = landValue;
                        }

                        // Store new node number and add node
                        nodesCount++;
                        nodes[k, l] = nodesCount; // this is the node number to use in the element table
                        X.Add(east);
                        Y.Add(north);
                        Zf.Add((float)z);
                        Zd.Add(z);
                        Code.Add(zCount == 4 ? 0 : 1); // Land boundary if zCount < 4
                    }
                }
            }

            // New mesh elements
            List <int[]> elmttable2 = new List <int[]>();

            for (int l = 0; l < yCount; l++)
            {
                for (int k = 0; k < xCount; k++)
                {
                    // Check if element is included in mesh
                    if (elmts[k, l])
                    {
                        // For this element, add the four surrounding nodes,
                        // counter-clockwise order
                        int[] newNodes = new int[4];
                        newNodes[0] = nodes[k, l];
                        newNodes[1] = nodes[k + 1, l];
                        newNodes[2] = nodes[k + 1, l + 1];
                        newNodes[3] = nodes[k, l + 1];
                        elmttable2.Add(newNodes);
                    }
                }
            }

            //-----------------------------------------
            // Create mesh
            {
                // Create 2D dfsu file
                MeshBuilder builder = new MeshBuilder();

                // Setup header and geometry
                builder.SetNodes(X.ToArray(), Y.ToArray(), Zd.ToArray(), Code.ToArray());
                builder.SetElements(elmttable2.ToArray());
                builder.SetProjection(dfs2.FileInfo.Projection);

                // Create new file
                MeshFile mesh = builder.CreateMesh();
                mesh.Write(meshFilename);
            }

            //-----------------------------------------
            // Create dfsu file
            {
                // dfs2 time axis
                IDfsEqCalendarAxis timeAxis = (IDfsEqCalendarAxis)dfs2.FileInfo.TimeAxis;

                // Create 2D dfsu file
                DfsuBuilder builder = DfsuBuilder.Create(DfsuFileType.Dfsu2D);

                // Setup header and geometry
                builder.SetNodes(X.ToArray(), Y.ToArray(), Zf.ToArray(), Code.ToArray());
                builder.SetElements(elmttable2.ToArray());
                builder.SetProjection(dfs2.FileInfo.Projection);
                builder.SetTimeInfo(timeAxis.StartDateTime, timeAxis.TimeStepInSeconds());
                builder.SetZUnit(eumUnit.eumUmeter);

                // Add dynamic items, copying from dfs2 file
                for (int i = 0; i < dfs2.ItemInfo.Count; i++)
                {
                    IDfsSimpleDynamicItemInfo itemInfo = dfs2.ItemInfo[i];
                    builder.AddDynamicItem(itemInfo.Name, itemInfo.Quantity);
                }

                // Create new file
                DfsuFile dfsu = builder.CreateFile(dfsuFilename);

                // Add dfs2 data to dfsu file
                float[] dfsuData = new float[dfsu.NumberOfElements];
                for (int i = 0; i < dfs2.FileInfo.TimeAxis.NumberOfTimeSteps; i++)
                {
                    for (int j = 0; j < dfs2.ItemInfo.Count; j++)
                    {
                        // Read dfs2 grid data
                        IDfsItemData2D <float> itemData = (IDfsItemData2D <float>)dfs2.ReadItemTimeStep(j + 1, i);
                        // Extract 2D grid data to dfsu data array
                        int lk = 0;
                        for (int l = 0; l < yCount; l++)
                        {
                            for (int k = 0; k < xCount; k++)
                            {
                                if (elmts[k, l])
                                {
                                    dfsuData[lk++] = itemData[k, l];
                                }
                            }
                        }
                        // write data
                        dfsu.WriteItemTimeStepNext(itemData.Time, dfsuData);
                    }
                }
                dfsu.Close();
            }

            dfs2.Close();
        }