/// <summary> /// A Shapefile MultiPoint Shape /// </summary> /// <param name="recordNumber">The record number in the Shapefile</param> /// <param name="metadata">Metadata about the shape</param> /// <param name="dataRecord">IDataRecord associated with the metadata</param> /// <param name="shapeData">The shape record as a byte array</param> /// <exception cref="ArgumentNullException">Thrown if shapeData is null</exception> /// <exception cref="InvalidOperationException">Thrown if an error occurs parsing shapeData</exception> protected internal ShapeMultiPoint(int recordNumber, StringDictionary metadata, IDataRecord dataRecord, byte[] shapeData) : base(ShapeType.MultiPoint, recordNumber, metadata, dataRecord) { // metadata is validated by the base class if (shapeData == null) { throw new ArgumentNullException("shapeData"); } // Note, shapeData includes an 8 byte header so positions below are +8 // Position Field Value Type Number Order // Byte 0 Shape Type 8 Integer 1 Little // Byte 4 Box Box Double 4 Little // Byte 36 NumPoints Num Points Integer 1 Little // Byte 40 Points Points Point NumPoints Little // validation step 1 - must have at least 8 + 4 + (4*8) + 4 bytes = 48 if (shapeData.Length < 48) { throw new InvalidOperationException("Invalid shape data"); } // extract bounding box and points _boundingBox = ParseBoundingBox(shapeData, 12, ProvidedOrder.Little); int numPoints = EndianBitConverter.ToInt32(shapeData, 44, ProvidedOrder.Little); // validation step 2 - we're expecting 16 * numPoints + 48 bytes total if (shapeData.Length != 48 + (16 * numPoints)) { throw new InvalidOperationException("Invalid shape data"); } // now extract the points _points = new PointD[numPoints]; for (int pointNum = 0; pointNum < numPoints; pointNum++) { _points[pointNum] = new PointD(EndianBitConverter.ToDouble(shapeData, 48 + (16 * pointNum), ProvidedOrder.Little), EndianBitConverter.ToDouble(shapeData, 56 + (16 * pointNum), ProvidedOrder.Little)); } }
/// <summary> /// A Shapefile Point Shape /// </summary> /// <param name="recordNumber">The record number in the Shapefile</param> /// <param name="metadata">Metadata about the shape</param> /// <param name="dataRecord">IDataRecord associated with the metadata</param> /// <param name="shapeData">The shape record as a byte array</param> /// <exception cref="ArgumentNullException">Thrown if shapeData is null</exception> /// <exception cref="InvalidOperationException">Thrown if an error occurs parsing shapeData</exception> protected internal ShapePoint(int recordNumber, StringDictionary metadata, IDataRecord dataRecord, byte[] shapeData) : base(ShapeType.Point, recordNumber, metadata, dataRecord) { // metadata is validated by the base class if (shapeData == null) { throw new ArgumentNullException("shapeData"); } // Note, shapeData includes an 8 byte header so positions below are +8 // Position Field Value Type Number Order // Byte 0 Shape Type 1 Integer 1 Little // Byte 4 X X Double 1 Little // Byte 12 Y Y Double 1 Little // validation - shapedata should be 8 + 4 + 8 + 8 = 28 bytes long if (shapeData.Length != 28) { throw new InvalidOperationException("Invalid shape data"); } _point = new PointD(EndianBitConverter.ToDouble(shapeData, 12, ProvidedOrder.Little), EndianBitConverter.ToDouble(shapeData, 20, ProvidedOrder.Little)); }
/// <summary> /// Function is basically the same as Shape.ParsePolyLineOrPolygon, it is just /// extended to handle the M extreme values /// </summary> /// <param name="shapeData">The shape record as a byte array</param> /// <param name="boundingBox">Returns the bounding box</param> /// <param name="parts">Returns the list of parts</param> private void ParsePolyLineM(byte[] shapeData, out RectangleD boundingBox, out List<PointD[]> parts) { boundingBox = new RectangleD(); parts = null; // metadata is validated by the base class if (shapeData == null) { throw new ArgumentNullException("shapeData"); } // Note, shapeData includes an 8 byte header so positions below are +8 // Position Field Value Type Number Order // Byte 0 Shape Type 23 Integer 1 Little // Byte 4 Box Box Double 4 Little // Byte 36 NumParts NumParts Integer 1 Little // Byte 40 NumPoints NumPoints Integer 1 Little // Byte 44 Parts Parts Integer NumParts Little // Byte X Points Points Point NumPoints Little // Byte Y* Mmin Mmin Double 1 Little // Byte Y + 8* Mmax Mmax Double 1 Little // Byte Y + 16* Marray Marray Double NumPoints Little // // *optional // validation step 1 - must have at least 8 + 4 + (4*8) + 4 + 4 bytes = 52 if (shapeData.Length < 44) { throw new InvalidOperationException("Invalid shape data"); } // extract bounding box, number of parts and number of points boundingBox = ParseBoundingBox(shapeData, 12, ProvidedOrder.Little); int numParts = EndianBitConverter.ToInt32(shapeData, 44, ProvidedOrder.Little); int numPoints = EndianBitConverter.ToInt32(shapeData, 48, ProvidedOrder.Little); // validation step 2 - we're expecting 4 * numParts + (16 + 8 * numPoints for m extremes and values) + 16 * numPoints + 52 bytes total if (shapeData.Length != 52 + (4 * numParts) + 16 + 8 * numPoints + (16 * numPoints)) { throw new InvalidOperationException("Invalid shape data"); } // now extract the parts int partsOffset = 52 + (4 * numParts); parts = new List<PointD[]>(numParts); for (int part = 0; part < numParts; part++) { // this is the index of the start of the part in the points array int startPart = (EndianBitConverter.ToInt32(shapeData, 52 + (4 * part), ProvidedOrder.Little) * 16) + partsOffset; int numBytes; if (part == numParts - 1) { // it's the last part so we go to the end of the point array numBytes = shapeData.Length - startPart; // remove bytes for M extreme block numBytes -= numPoints * 8 + 16; } else { // we need to get the next part int nextPart = (EndianBitConverter.ToInt32(shapeData, 52 + (4 * (part + 1)), ProvidedOrder.Little) * 16) + partsOffset; numBytes = nextPart - startPart; } // the number of 16-byte points to read for this segment int numPointsInPart = (numBytes) / 16; PointD[] points = new PointD[numPointsInPart]; for (int point = 0; point < numPointsInPart; point++) { points[point] = new PointD(EndianBitConverter.ToDouble(shapeData, startPart + (16 * point), ProvidedOrder.Little), EndianBitConverter.ToDouble(shapeData, startPart + 8 + (16 * point), ProvidedOrder.Little)); } parts.Add(points); } // parse M information Mmin = EndianBitConverter.ToDouble(shapeData, 52 + (4 * numParts) + (16 * numPoints), ProvidedOrder.Little); Mmax = EndianBitConverter.ToDouble(shapeData, 52 + 8 + (4 * numParts) + (16 * numPoints), ProvidedOrder.Little); M.Clear(); for (int i = 0; i < numPoints; i++) { double _m = EndianBitConverter.ToDouble(shapeData, 52 + 16 + (4 * numParts) + (16 * numPoints) + i * 8, ProvidedOrder.Little); M.Add(_m); } }
/// <summary> /// The PolygonZ shape share the same structure, this method parses the bounding box /// and list of parts for both /// </summary> /// <param name="shapeData">The shape record as a byte array</param> /// <param name="boundingBox">Returns the bounding box</param> /// <param name="parts">Returns the list of parts</param> protected void ParsePolygonZ(byte[] shapeData, out RectangleD boundingBox, out List<PointD[]> parts) { boundingBox = new RectangleD(); parts = null; // metadata is validated by the base class if (shapeData == null) { throw new ArgumentNullException("shapeData"); } // Note, shapeData includes an 8 byte header so positions below are +8 // Position Field Value Type Number Order // Byte 0 Shape Type 25 Integer 1 Little // Byte 4 Box Box Double 4 Little // Byte 36 NumParts NumParts Integer 1 Little // Byte 40 NumPoints NumPoints Integer 1 Little // Byte 44 Parts Parts Integer NumParts Little // Byte X Points Points Point NumPoints Little // Byte Y Zmin Zmin Double 1 Little // Byte Y+8 Zmax Zmax Double 1 Little // Byte Y+16 Zarray Zarray Double NumPoints Little // Byte Z* Mmin Mmin Double 1 Little // Byte Z+8* Mmax Mmax Double 1 Little // Byte Z+16* Marray Marray Double NumPoints Little // Byte M* Mmin Mmin Double 1 Little // Byte Z+8* Mmax Mmax Double 1 Little // Byte Z+16* Marray Marray Double NumPoints Little // // Note: X = 44 + (4 * NumParts), Y = X + (16 * NumPoints), Z = Y + 16 + (8 * NumPoints) // * optional // validation step 1 - must have at least 8 + 4 + (4*8) + 4 + 4 bytes = 52 if (shapeData.Length < 44) { throw new InvalidOperationException("Invalid shape data"); } // extract bounding box, number of parts and number of points boundingBox = ParseBoundingBox(shapeData, 12, ProvidedOrder.Little); int numParts = EndianBitConverter.ToInt32(shapeData, 44, ProvidedOrder.Little); int numPoints = EndianBitConverter.ToInt32(shapeData, 48, ProvidedOrder.Little); // validation step 2 - we're expecting 4 * numParts + 16 * numPoints + 52 bytes total if (shapeData.Length != 52 + (4 * numParts) + (16 * numPoints) && shapeData.Length != 52 + (4 * numParts) + (16 * numPoints) + 16 + (8 * numPoints) && shapeData.Length != 52 + (4 * numParts) + (16 * numPoints) + 16 + (8 * numPoints) + 16 + (8 * numPoints)) { throw new InvalidOperationException("Invalid shape data"); } // now extract the parts int partsOffset = 52 + (4 * numParts); parts = new List<PointD[]>(numParts); for (var part = 0; part < numParts; part++) { // this is the index of the start of the part in the points array var startPart = (EndianBitConverter.ToInt32(shapeData, 52 + (4 * part), ProvidedOrder.Little) * 16) + partsOffset; int numBytes; if (part == numParts - 1) { // it's the last part so we go to the end of the point array numBytes = shapeData.Length - startPart; } else { // we need to get the next part var nextPart = (EndianBitConverter.ToInt32(shapeData, 52 + (4 * (part + 1)), ProvidedOrder.Little) * 16) + partsOffset; numBytes = nextPart - startPart; } // the number of 16-byte points to read for this segment var numPointsInPart = Math.Min(numBytes / 16, numPoints); var points = new PointD[numPointsInPart]; for (var point = 0; point < numPointsInPart; point++) { points[point] = new PointD(EndianBitConverter.ToDouble(shapeData, startPart + (16 * point), ProvidedOrder.Little), EndianBitConverter.ToDouble(shapeData, startPart + 8 + (16 * point), ProvidedOrder.Little)); } parts.Add(points); } }