private void Update(Context context)
{
if (_dirtyLength)
{
VertexAttributeDoubleVector3 positionAttribute = new VertexAttributeDoubleVector3("position", 6);
positionAttribute.Values.Add(new Vector3D(0, 0, 0));
positionAttribute.Values.Add(new Vector3D(_length, 0, 0));
positionAttribute.Values.Add(new Vector3D(0, 0, 0));
positionAttribute.Values.Add(new Vector3D(0, _length, 0));
positionAttribute.Values.Add(new Vector3D(0, 0, 0));
positionAttribute.Values.Add(new Vector3D(0, 0, _length));
VertexAttributeRGBA colorAttribute = new VertexAttributeRGBA("color", 6);
colorAttribute.AddColor(Color.Red);
colorAttribute.AddColor(Color.Red);
colorAttribute.AddColor(Color.Green);
colorAttribute.AddColor(Color.Green);
colorAttribute.AddColor(Color.Blue);
colorAttribute.AddColor(Color.Blue);
Mesh mesh = new Mesh();
mesh.PrimitiveType = PrimitiveType.Lines;
mesh.Attributes.Add(positionAttribute);
mesh.Attributes.Add(colorAttribute);
_polyline.Set(context, mesh);
_dirtyLength = false;
}
_polyline.Width = Width;
}
private void Update(Context context)
{
if (_dirtyLength)
{
VertexAttributeDoubleVector3 positionAttribute = new VertexAttributeDoubleVector3("position", 6);
positionAttribute.Values.Add(new Vector3D(0, 0, 0));
positionAttribute.Values.Add(new Vector3D(_length, 0, 0));
positionAttribute.Values.Add(new Vector3D(0, 0, 0));
positionAttribute.Values.Add(new Vector3D(0, _length, 0));
positionAttribute.Values.Add(new Vector3D(0, 0, 0));
positionAttribute.Values.Add(new Vector3D(0, 0, _length));
VertexAttributeRGBA colorAttribute = new VertexAttributeRGBA("color", 6);
colorAttribute.AddColor(Color.Red);
colorAttribute.AddColor(Color.Red);
colorAttribute.AddColor(Color.Green);
colorAttribute.AddColor(Color.Green);
colorAttribute.AddColor(Color.Blue);
colorAttribute.AddColor(Color.Blue);
Mesh mesh = new Mesh();
mesh.PrimitiveType = PrimitiveType.Lines;
mesh.Attributes.Add(positionAttribute);
mesh.Attributes.Add(colorAttribute);
_polyline.Set(context, mesh);
_dirtyLength = false;
}
_polyline.Width = Width;
}
public static Mesh Compute(Vector3D length)
{
if (length.X < 0 || length.Y < 0 || length.Z < 0)
{
throw new ArgumentOutOfRangeException("length");
}
Mesh mesh = new Mesh();
mesh.PrimitiveType = PrimitiveType.Triangles;
mesh.FrontFaceWindingOrder = WindingOrder.Counterclockwise;
VertexAttributeDoubleVector3 positionsAttribute = new VertexAttributeDoubleVector3("position", 8);
mesh.Attributes.Add(positionsAttribute);
IndicesUnsignedShort indices = new IndicesUnsignedShort(24);
mesh.Indices = indices;
//
// 8 corner points
//
IList<Vector3D> positions = positionsAttribute.Values;
Vector3D corner = 0.5 * length;
positions.Add(new Vector3D(-corner.X, -corner.Y, -corner.Z));
positions.Add(new Vector3D(corner.X, -corner.Y, -corner.Z));
positions.Add(new Vector3D(corner.X, corner.Y, -corner.Z));
positions.Add(new Vector3D(-corner.X, corner.Y, -corner.Z));
positions.Add(new Vector3D(-corner.X, -corner.Y, corner.Z));
positions.Add(new Vector3D(corner.X, -corner.Y, corner.Z));
positions.Add(new Vector3D(corner.X, corner.Y, corner.Z));
positions.Add(new Vector3D(-corner.X, corner.Y, corner.Z));
//
// 6 faces, 2 triangles each
//
indices.AddTriangle(new TriangleIndicesUnsignedShort(4, 5, 6)); // Top: plane z = corner.Z
indices.AddTriangle(new TriangleIndicesUnsignedShort(4, 6, 7));
indices.AddTriangle(new TriangleIndicesUnsignedShort(1, 0, 3)); // Bottom: plane z = -corner.Z
indices.AddTriangle(new TriangleIndicesUnsignedShort(1, 3, 2));
indices.AddTriangle(new TriangleIndicesUnsignedShort(1, 6, 5)); // Side: plane x = corner.X
indices.AddTriangle(new TriangleIndicesUnsignedShort(1, 2, 6));
indices.AddTriangle(new TriangleIndicesUnsignedShort(2, 3, 7)); // Side: plane y = corner.Y
indices.AddTriangle(new TriangleIndicesUnsignedShort(2, 7, 6));
indices.AddTriangle(new TriangleIndicesUnsignedShort(3, 0, 4)); // Side: plane x = -corner.X
indices.AddTriangle(new TriangleIndicesUnsignedShort(3, 4, 7));
indices.AddTriangle(new TriangleIndicesUnsignedShort(0, 1, 5)); // Side: plane y = -corner.Y
indices.AddTriangle(new TriangleIndicesUnsignedShort(0, 5, 4));
return mesh;
}
public static Mesh Compute(int numberOfSubdivisions)
{
if (numberOfSubdivisions < 0)
{
throw new ArgumentOutOfRangeException("numberOfSubdivisions");
}
Mesh mesh = new Mesh();
mesh.PrimitiveType = PrimitiveType.Triangles;
mesh.FrontFaceWindingOrder = WindingOrder.Counterclockwise;
VertexAttributeDoubleVector3 positionsAttribute = new VertexAttributeDoubleVector3(
"position", SubdivisionUtility.NumberOfVertices(numberOfSubdivisions));
mesh.Attributes.Add(positionsAttribute);
IndicesUnsignedInt indices = new IndicesUnsignedInt(3 * SubdivisionUtility.NumberOfTriangles(numberOfSubdivisions));
mesh.Indices = indices;
//
// Initial tetrahedron
//
double negativeRootTwoOverThree = -Math.Sqrt(2.0) / 3.0;
const double negativeOneThird = -1.0 / 3.0;
double rootSixOverThree = Math.Sqrt(6.0) / 3.0;
IList<Vector3D> positions = positionsAttribute.Values;
positions.Add(new Vector3D(0, 0, 1));
positions.Add(new Vector3D(0, (2.0 * Math.Sqrt(2.0)) / 3.0, negativeOneThird));
positions.Add(new Vector3D(-rootSixOverThree, negativeRootTwoOverThree, negativeOneThird));
positions.Add(new Vector3D(rootSixOverThree, negativeRootTwoOverThree, negativeOneThird));
Subdivide(positions, indices, new TriangleIndicesUnsignedInt(0, 1, 2), numberOfSubdivisions);
Subdivide(positions, indices, new TriangleIndicesUnsignedInt(0, 2, 3), numberOfSubdivisions);
Subdivide(positions, indices, new TriangleIndicesUnsignedInt(0, 3, 1), numberOfSubdivisions);
Subdivide(positions, indices, new TriangleIndicesUnsignedInt(1, 3, 2), numberOfSubdivisions);
return mesh;
}
public static Mesh Compute(Ellipsoid ellipsoid, int numberOfSlicePartitions, int numberOfStackPartitions, GeographicGridEllipsoidVertexAttributes vertexAttributes)
{
if (numberOfSlicePartitions < 3)
{
throw new ArgumentOutOfRangeException("numberOfSlicePartitions");
}
if (numberOfStackPartitions < 2)
{
throw new ArgumentOutOfRangeException("numberOfStackPartitions");
}
if ((vertexAttributes & GeographicGridEllipsoidVertexAttributes.Position) != GeographicGridEllipsoidVertexAttributes.Position)
{
throw new ArgumentException("Positions must be provided.", "vertexAttributes");
}
Mesh mesh = new Mesh();
mesh.PrimitiveType = PrimitiveType.Triangles;
mesh.FrontFaceWindingOrder = WindingOrder.Counterclockwise;
int numberOfVertices = NumberOfVertices(numberOfSlicePartitions, numberOfStackPartitions);
VertexAttributeDoubleVector3 positionsAttribute = new VertexAttributeDoubleVector3("position", numberOfVertices);
mesh.Attributes.Add(positionsAttribute);
IndicesUnsignedInt indices = new IndicesUnsignedInt(3 * NumberOfTriangles(numberOfSlicePartitions, numberOfStackPartitions));
mesh.Indices = indices;
IList<Vector3H> normals = null;
if ((vertexAttributes & GeographicGridEllipsoidVertexAttributes.Normal) == GeographicGridEllipsoidVertexAttributes.Normal)
{
VertexAttributeHalfFloatVector3 normalsAttribute = new VertexAttributeHalfFloatVector3("normal", numberOfVertices);
mesh.Attributes.Add(normalsAttribute);
normals = normalsAttribute.Values;
}
IList<Vector2H> textureCoordinates = null;
if ((vertexAttributes & GeographicGridEllipsoidVertexAttributes.TextureCoordinate) == GeographicGridEllipsoidVertexAttributes.TextureCoordinate)
{
VertexAttributeHalfFloatVector2 textureCoordinateAttribute = new VertexAttributeHalfFloatVector2("textureCoordinate", numberOfVertices);
mesh.Attributes.Add(textureCoordinateAttribute);
textureCoordinates = textureCoordinateAttribute.Values;
}
//
// Create lookup table
//
double[] cosTheta = new double[numberOfSlicePartitions];
double[] sinTheta = new double[numberOfSlicePartitions];
for (int j = 0; j < numberOfSlicePartitions; ++j)
{
double theta = Trig.TwoPi * (((double)j) / numberOfSlicePartitions);
cosTheta[j] = Math.Cos(theta);
sinTheta[j] = Math.Sin(theta);
}
//
// Create positions
//
IList<Vector3D> positions = positionsAttribute.Values;
positions.Add(new Vector3D(0, 0, ellipsoid.Radii.Z));
for (int i = 1; i < numberOfStackPartitions; ++i)
{
double phi = Math.PI * (((double)i) / numberOfStackPartitions);
double sinPhi = Math.Sin(phi);
double xSinPhi = ellipsoid.Radii.X * sinPhi;
double ySinPhi = ellipsoid.Radii.Y * sinPhi;
double zCosPhi = ellipsoid.Radii.Z * Math.Cos(phi);
for (int j = 0; j < numberOfSlicePartitions; ++j)
{
positions.Add(new Vector3D(cosTheta[j] * xSinPhi, sinTheta[j] * ySinPhi, zCosPhi));
}
}
positions.Add(new Vector3D(0, 0, -ellipsoid.Radii.Z));
if ((normals != null) || (textureCoordinates != null))
{
for (int i = 0; i < positions.Count; ++i)
{
Vector3D deticSurfaceNormal = ellipsoid.GeodeticSurfaceNormal(positions[i]);
if (normals != null)
{
normals.Add(deticSurfaceNormal.ToVector3H());
}
if (textureCoordinates != null)
{
textureCoordinates.Add(SubdivisionUtility.ComputeTextureCoordinate(deticSurfaceNormal));
}
}
}
//
// Triangle fan top row
//
for (int j = 1; j < numberOfSlicePartitions; ++j)
{
indices.AddTriangle(new TriangleIndicesUnsignedInt(0, j, j + 1));
}
indices.AddTriangle(new TriangleIndicesUnsignedInt(0, numberOfSlicePartitions, 1));
//
// Middle rows are triangle strips
//
for (int i = 0; i < numberOfStackPartitions - 2; ++i)
{
int topRowOffset = (i * numberOfSlicePartitions) + 1;
int bottomRowOffset = ((i + 1) * numberOfSlicePartitions) + 1;
for (int j = 0; j < numberOfSlicePartitions - 1; ++j)
{
indices.AddTriangle(new TriangleIndicesUnsignedInt(bottomRowOffset + j, bottomRowOffset + j + 1, topRowOffset + j + 1));
indices.AddTriangle(new TriangleIndicesUnsignedInt(bottomRowOffset + j, topRowOffset + j + 1, topRowOffset + j));
}
indices.AddTriangle(new TriangleIndicesUnsignedInt(bottomRowOffset + numberOfSlicePartitions - 1, bottomRowOffset, topRowOffset));
indices.AddTriangle(new TriangleIndicesUnsignedInt(bottomRowOffset + numberOfSlicePartitions - 1, topRowOffset, topRowOffset + numberOfSlicePartitions - 1));
}
//
// Triangle fan bottom row
//
int lastPosition = positions.Count - 1;
for (int j = lastPosition - 1; j > lastPosition - numberOfSlicePartitions; --j)
{
indices.AddTriangle(new TriangleIndicesUnsignedInt(lastPosition, j, j - 1));
}
indices.AddTriangle(new TriangleIndicesUnsignedInt(lastPosition, lastPosition - numberOfSlicePartitions, lastPosition - 1));
return mesh;
}
public PolygonShapefile(
Shapefile shapefile,
Context context,
Ellipsoid globeShape,
ShapefileAppearance appearance)
{
Verify.ThrowIfNull(shapefile);
Verify.ThrowIfNull(context);
Verify.ThrowIfNull(globeShape);
_polyline = new OutlinedPolylineTexture();
_polygons = new List <Polygon>();
VertexAttributeDoubleVector3 positionAttribute = new VertexAttributeDoubleVector3("position");
VertexAttributeRGBA colorAttribute = new VertexAttributeRGBA("color");
VertexAttributeRGBA outlineColorAttribute = new VertexAttributeRGBA("outlineColor");
IndicesUnsignedInt indices = new IndicesUnsignedInt();
Random r = new Random(3);
IList <Vector3D> positions = new List <Vector3D>();
foreach (Shape shape in shapefile)
{
if (shape.ShapeType != ShapeType.Polygon)
{
throw new NotSupportedException("The type of an individual shape does not match the Shapefile type.");
}
PolygonShape polygonShape = (PolygonShape)shape;
for (int j = 0; j < polygonShape.Count; ++j)
{
Color color = Color.FromArgb(127, r.Next(256), r.Next(256), r.Next(256));
positions.Clear();
ShapePart part = polygonShape[j];
for (int i = 0; i < part.Count; ++i)
{
Vector2D point = part[i];
positions.Add(globeShape.ToVector3D(Trig.ToRadians(new Geodetic3D(point.X, point.Y))));
//
// For polyline
//
positionAttribute.Values.Add(globeShape.ToVector3D(Trig.ToRadians(new Geodetic3D(point.X, point.Y))));
colorAttribute.AddColor(color);
outlineColorAttribute.AddColor(Color.Black);
if (i != 0)
{
indices.Values.Add((uint)positionAttribute.Values.Count - 2);
indices.Values.Add((uint)positionAttribute.Values.Count - 1);
}
}
try
{
Polygon p = new Polygon(context, globeShape, positions);
p.Color = color;
_polygons.Add(p);
}
catch (ArgumentOutOfRangeException) // Not enough positions after cleaning
{
}
}
}
Mesh mesh = new Mesh();
mesh.PrimitiveType = PrimitiveType.Lines;
mesh.Attributes.Add(positionAttribute);
mesh.Attributes.Add(colorAttribute);
mesh.Attributes.Add(outlineColorAttribute);
mesh.Indices = indices;
_polyline.Set(context, mesh);
}
public void VertexAttributeDoubleVector3()
{
Mesh mesh = new Mesh();
VertexAttributeDoubleVector3 attribute = new VertexAttributeDoubleVector3("position");
mesh.Attributes.Add(attribute);
Assert.AreEqual("position", mesh.Attributes["position"].Name);
Assert.AreEqual(VertexAttributeType.EmulatedDoubleVector3, mesh.Attributes["position"].Datatype);
}
public Polygon(Context context, Ellipsoid globeShape, IEnumerable <Vector3D> positions)
{
Verify.ThrowIfNull(context);
Verify.ThrowIfNull(globeShape);
//
// Pipeline Stage 1a: Clean up - Remove duplicate positions
//
List <Vector3D> cleanPositions = (List <Vector3D>)SimplePolygonAlgorithms.Cleanup(positions);
//
// Pipeline Stage 1b: Clean up - Swap winding order
//
EllipsoidTangentPlane plane = new EllipsoidTangentPlane(globeShape, cleanPositions);
ICollection <Vector2D> positionsOnPlane = plane.ComputePositionsOnPlane(cleanPositions);
if (SimplePolygonAlgorithms.ComputeWindingOrder(positionsOnPlane) == PolygonWindingOrder.Clockwise)
{
cleanPositions.Reverse();
//((List<Vector2D>)positionsOnPlane).Reverse();
}
//
// Pipeline Stage 2: Triangulate
//
IndicesUnsignedInt indices = EarClippingOnEllipsoid.Triangulate(cleanPositions);
//IndicesInt32 indices = EarClipping.Triangulate(positionsOnPlane);
//
// Pipeline Stage 3: Subdivide
//
TriangleMeshSubdivisionResult result = TriangleMeshSubdivision.Compute(cleanPositions, indices, Trig.ToRadians(1));
//
// Pipeline Stage 4: Set height
//
VertexAttributeDoubleVector3 positionsAttribute = new VertexAttributeDoubleVector3(
"position", (result.Indices.Values.Count / 3) + 2);
foreach (Vector3D position in result.Positions)
{
positionsAttribute.Values.Add(globeShape.ScaleToGeocentricSurface(position));
}
Mesh mesh = new Mesh();
mesh.PrimitiveType = PrimitiveType.Triangles;
mesh.FrontFaceWindingOrder = WindingOrder.Counterclockwise;
mesh.Attributes.Add(positionsAttribute);
mesh.Indices = result.Indices;
ShaderProgram sp = Device.CreateShaderProgram(
EmbeddedResources.GetText("OpenGlobe.Scene.Renderables.Polygon.Shaders.PolygonVS.glsl"),
EmbeddedResources.GetText("OpenGlobe.Scene.Renderables.Polygon.Shaders.PolygonFS.glsl"));
((Uniform <Vector3F>)sp.Uniforms["u_globeOneOverRadiiSquared"]).Value = globeShape.OneOverRadiiSquared.ToVector3F();
_colorUniform = (Uniform <Vector4F>)sp.Uniforms["u_color"];
_drawState = new DrawState();
_drawState.RenderState.Blending.Enabled = true;
_drawState.RenderState.Blending.SourceRGBFactor = SourceBlendingFactor.SourceAlpha;
_drawState.RenderState.Blending.SourceAlphaFactor = SourceBlendingFactor.SourceAlpha;
_drawState.RenderState.Blending.DestinationRGBFactor = DestinationBlendingFactor.OneMinusSourceAlpha;
_drawState.RenderState.Blending.DestinationAlphaFactor = DestinationBlendingFactor.OneMinusSourceAlpha;
_drawState.ShaderProgram = sp;
_meshBuffers = Device.CreateMeshBuffers(mesh, _drawState.ShaderProgram.VertexAttributes, BufferHint.StaticDraw);
_primitiveType = mesh.PrimitiveType;
Color = Color.White;
}
public static Mesh Compute(Ellipsoid ellipsoid, int numberOfSubdivisions, SubdivisionEllipsoidVertexAttributes vertexAttributes)
{
if (numberOfSubdivisions < 0)
{
throw new ArgumentOutOfRangeException("numberOfSubdivisions");
}
if ((vertexAttributes & SubdivisionEllipsoidVertexAttributes.Position) != SubdivisionEllipsoidVertexAttributes.Position)
{
throw new ArgumentException("Positions must be provided.", "vertexAttributes");
}
Mesh mesh = new Mesh();
mesh.PrimitiveType = PrimitiveType.Triangles;
mesh.FrontFaceWindingOrder = WindingOrder.Counterclockwise;
int numberOfVertices = SubdivisionUtility.NumberOfVertices(numberOfSubdivisions);
VertexAttributeDoubleVector3 positionsAttribute = new VertexAttributeDoubleVector3("position", numberOfVertices);
mesh.Attributes.Add(positionsAttribute);
IndicesUnsignedInt indices = new IndicesUnsignedInt(3 * SubdivisionUtility.NumberOfTriangles(numberOfSubdivisions));
mesh.Indices = indices;
SubdivisionMesh subdivisionMesh = new SubdivisionMesh();
subdivisionMesh.Ellipsoid = ellipsoid;
subdivisionMesh.Positions = positionsAttribute.Values;
subdivisionMesh.Indices = indices;
if ((vertexAttributes & SubdivisionEllipsoidVertexAttributes.Normal) == SubdivisionEllipsoidVertexAttributes.Normal)
{
VertexAttributeHalfFloatVector3 normalsAttribute = new VertexAttributeHalfFloatVector3("normal", numberOfVertices);
mesh.Attributes.Add(normalsAttribute);
subdivisionMesh.Normals = normalsAttribute.Values;
}
if ((vertexAttributes & SubdivisionEllipsoidVertexAttributes.TextureCoordinate) == SubdivisionEllipsoidVertexAttributes.TextureCoordinate)
{
VertexAttributeHalfFloatVector2 textureCoordinateAttribute = new VertexAttributeHalfFloatVector2("textureCoordinate", numberOfVertices);
mesh.Attributes.Add(textureCoordinateAttribute);
subdivisionMesh.TextureCoordinate = textureCoordinateAttribute.Values;
}
//
// Initial tetrahedron
//
double negativeRootTwoOverThree = -Math.Sqrt(2.0) / 3.0;
const double negativeOneThird = -1.0 / 3.0;
double rootSixOverThree = Math.Sqrt(6.0) / 3.0;
Vector3D n0 = new Vector3D(0, 0, 1);
Vector3D n1 = new Vector3D(0, (2.0 * Math.Sqrt(2.0)) / 3.0, negativeOneThird);
Vector3D n2 = new Vector3D(-rootSixOverThree, negativeRootTwoOverThree, negativeOneThird);
Vector3D n3 = new Vector3D(rootSixOverThree, negativeRootTwoOverThree, negativeOneThird);
Vector3D p0 = n0.MultiplyComponents(ellipsoid.Radii);
Vector3D p1 = n1.MultiplyComponents(ellipsoid.Radii);
Vector3D p2 = n2.MultiplyComponents(ellipsoid.Radii);
Vector3D p3 = n3.MultiplyComponents(ellipsoid.Radii);
subdivisionMesh.Positions.Add(p0);
subdivisionMesh.Positions.Add(p1);
subdivisionMesh.Positions.Add(p2);
subdivisionMesh.Positions.Add(p3);
if ((subdivisionMesh.Normals != null) || (subdivisionMesh.TextureCoordinate != null))
{
Vector3D d0 = ellipsoid.GeodeticSurfaceNormal(p0);
Vector3D d1 = ellipsoid.GeodeticSurfaceNormal(p1);
Vector3D d2 = ellipsoid.GeodeticSurfaceNormal(p2);
Vector3D d3 = ellipsoid.GeodeticSurfaceNormal(p3);
if (subdivisionMesh.Normals != null)
{
subdivisionMesh.Normals.Add(d0.ToVector3H());
subdivisionMesh.Normals.Add(d1.ToVector3H());
subdivisionMesh.Normals.Add(d2.ToVector3H());
subdivisionMesh.Normals.Add(d3.ToVector3H());
}
if (subdivisionMesh.TextureCoordinate != null)
{
subdivisionMesh.TextureCoordinate.Add(SubdivisionUtility.ComputeTextureCoordinate(d0));
subdivisionMesh.TextureCoordinate.Add(SubdivisionUtility.ComputeTextureCoordinate(d1));
subdivisionMesh.TextureCoordinate.Add(SubdivisionUtility.ComputeTextureCoordinate(d2));
subdivisionMesh.TextureCoordinate.Add(SubdivisionUtility.ComputeTextureCoordinate(d3));
}
}
Subdivide(subdivisionMesh, new TriangleIndicesUnsignedInt(0, 1, 2), numberOfSubdivisions);
Subdivide(subdivisionMesh, new TriangleIndicesUnsignedInt(0, 2, 3), numberOfSubdivisions);
Subdivide(subdivisionMesh, new TriangleIndicesUnsignedInt(0, 3, 1), numberOfSubdivisions);
Subdivide(subdivisionMesh, new TriangleIndicesUnsignedInt(1, 3, 2), numberOfSubdivisions);
return mesh;
}
public static MeshBuffers CreateMeshBuffers(Mesh mesh, ShaderVertexAttributeCollection shaderAttributes, BufferHint usageHint)
{
if (mesh == null)
{
throw new ArgumentNullException("mesh");
}
if (shaderAttributes == null)
{
throw new ArgumentNullException("shaderAttributes");
}
MeshBuffers meshBuffers = new MeshBuffers();
if (mesh.Indices != null)
{
if (mesh.Indices.Datatype == IndicesType.UnsignedShort)
{
IList <ushort> meshIndices = ((IndicesUnsignedShort)mesh.Indices).Values;
ushort[] indices = new ushort[meshIndices.Count];
for (int j = 0; j < meshIndices.Count; ++j)
{
indices[j] = meshIndices[j];
}
IndexBuffer indexBuffer = Device.CreateIndexBuffer(usageHint, indices.Length * sizeof(ushort));
indexBuffer.CopyFromSystemMemory(indices);
meshBuffers.IndexBuffer = indexBuffer;
}
else if (mesh.Indices.Datatype == IndicesType.UnsignedInt)
{
IList <uint> meshIndices = ((IndicesUnsignedInt)mesh.Indices).Values;
uint[] indices = new uint[meshIndices.Count];
for (int j = 0; j < meshIndices.Count; ++j)
{
indices[j] = meshIndices[j];
}
IndexBuffer indexBuffer = Device.CreateIndexBuffer(usageHint, indices.Length * sizeof(uint));
indexBuffer.CopyFromSystemMemory(indices);
meshBuffers.IndexBuffer = indexBuffer;
}
else
{
throw new NotSupportedException("mesh.Indices.Datatype " +
mesh.Indices.Datatype.ToString() + " is not supported.");
}
}
//
// Emulated double precision vectors are a special case: one mesh vertex attribute
// yields two shader vertex attributes. As such, these are handled separately before
// normal attributes.
//
HashSet <string> ignoreAttributes = new HashSet <string>();
foreach (VertexAttribute attribute in mesh.Attributes)
{
if (attribute is VertexAttributeDoubleVector3)
{
VertexAttributeDoubleVector3 emulated = (VertexAttributeDoubleVector3)attribute;
int highLocation = -1;
int lowLocation = -1;
foreach (ShaderVertexAttribute shaderAttribute in shaderAttributes)
{
if (shaderAttribute.Name == emulated.Name + "High")
{
highLocation = shaderAttribute.Location;
}
else if (shaderAttribute.Name == emulated.Name + "Low")
{
lowLocation = shaderAttribute.Location;
}
if ((highLocation != -1) && (lowLocation != -1))
{
break;
}
}
if ((highLocation == -1) && (lowLocation == -1))
{
//
// The shader did not have either attribute. No problem.
//
continue;
}
else if ((highLocation == -1) || (lowLocation == -1))
{
throw new ArgumentException("An emulated double vec3 mesh attribute requires both " + emulated.Name + "High and " + emulated.Name + "Low vertex attributes, but the shader only contains one matching attribute.");
}
//
// Copy both high and low parts into a single vertex buffer.
//
IList <Vector3D> values = ((VertexAttribute <Vector3D>)attribute).Values;
Vector3F[] vertices = new Vector3F[2 * values.Count];
int j = 0;
for (int i = 0; i < values.Count; ++i)
{
EmulatedVector3D v = new EmulatedVector3D(values[i]);
vertices[j++] = v.High;
vertices[j++] = v.Low;
}
VertexBuffer vertexBuffer = Device.CreateVertexBuffer(usageHint, ArraySizeInBytes.Size(vertices));
vertexBuffer.CopyFromSystemMemory(vertices);
int stride = 2 * SizeInBytes <Vector3F> .Value;
meshBuffers.Attributes[highLocation] =
new VertexBufferAttribute(vertexBuffer, ComponentDatatype.Float, 3, false, 0, stride);
meshBuffers.Attributes[lowLocation] =
new VertexBufferAttribute(vertexBuffer, ComponentDatatype.Float, 3, false, SizeInBytes <Vector3F> .Value, stride);
ignoreAttributes.Add(emulated.Name + "High");
ignoreAttributes.Add(emulated.Name + "Low");
}
}
// TODO: Not tested exhaustively
foreach (ShaderVertexAttribute shaderAttribute in shaderAttributes)
{
if (ignoreAttributes.Contains(shaderAttribute.Name))
{
continue;
}
if (!mesh.Attributes.Contains(shaderAttribute.Name))
{
throw new ArgumentException("Shader requires vertex attribute \"" + shaderAttribute.Name + "\", which is not present in mesh.");
}
VertexAttribute attribute = mesh.Attributes[shaderAttribute.Name];
if (attribute.Datatype == VertexAttributeType.EmulatedDoubleVector3)
{
IList <Vector3D> values = ((VertexAttribute <Vector3D>)attribute).Values;
Vector3F[] valuesArray = new Vector3F[values.Count];
for (int i = 0; i < values.Count; ++i)
{
valuesArray[i] = values[i].ToVector3F();
}
VertexBuffer vertexBuffer = Device.CreateVertexBuffer(usageHint, ArraySizeInBytes.Size(valuesArray));
vertexBuffer.CopyFromSystemMemory(valuesArray);
meshBuffers.Attributes[shaderAttribute.Location] =
new VertexBufferAttribute(vertexBuffer, ComponentDatatype.Float, 3);
}
else if (attribute.Datatype == VertexAttributeType.HalfFloat)
{
VertexBuffer vertexBuffer = CreateVertexBuffer(((VertexAttribute <Half>)attribute).Values, usageHint);
meshBuffers.Attributes[shaderAttribute.Location] =
new VertexBufferAttribute(vertexBuffer, ComponentDatatype.HalfFloat, 1);
}
else if (attribute.Datatype == VertexAttributeType.HalfFloatVector2)
{
VertexBuffer vertexBuffer = CreateVertexBuffer(((VertexAttribute <Vector2H>)attribute).Values, usageHint);
meshBuffers.Attributes[shaderAttribute.Location] =
new VertexBufferAttribute(vertexBuffer, ComponentDatatype.HalfFloat, 2);
}
else if (attribute.Datatype == VertexAttributeType.HalfFloatVector3)
{
VertexBuffer vertexBuffer = CreateVertexBuffer(((VertexAttribute <Vector3H>)attribute).Values, usageHint);
meshBuffers.Attributes[shaderAttribute.Location] =
new VertexBufferAttribute(vertexBuffer, ComponentDatatype.HalfFloat, 3);
}
else if (attribute.Datatype == VertexAttributeType.HalfFloatVector4)
{
VertexBuffer vertexBuffer = CreateVertexBuffer(((VertexAttribute <Vector4H>)attribute).Values, usageHint);
meshBuffers.Attributes[shaderAttribute.Location] =
new VertexBufferAttribute(vertexBuffer, ComponentDatatype.HalfFloat, 4);
}
else if (attribute.Datatype == VertexAttributeType.Float)
{
VertexBuffer vertexBuffer = CreateVertexBuffer(((VertexAttribute <float>)attribute).Values, usageHint);
meshBuffers.Attributes[shaderAttribute.Location] =
new VertexBufferAttribute(vertexBuffer, ComponentDatatype.Float, 1);
}
else if (attribute.Datatype == VertexAttributeType.FloatVector2)
{
VertexBuffer vertexBuffer = CreateVertexBuffer(((VertexAttribute <Vector2F>)attribute).Values, usageHint);
meshBuffers.Attributes[shaderAttribute.Location] =
new VertexBufferAttribute(vertexBuffer, ComponentDatatype.Float, 2);
}
else if (attribute.Datatype == VertexAttributeType.FloatVector3)
{
VertexBuffer vertexBuffer = CreateVertexBuffer(((VertexAttribute <Vector3F>)attribute).Values, usageHint);
meshBuffers.Attributes[shaderAttribute.Location] =
new VertexBufferAttribute(vertexBuffer, ComponentDatatype.Float, 3);
}
else if (attribute.Datatype == VertexAttributeType.FloatVector4)
{
VertexBuffer vertexBuffer = CreateVertexBuffer(((VertexAttribute <Vector4F>)attribute).Values, usageHint);
meshBuffers.Attributes[shaderAttribute.Location] =
new VertexBufferAttribute(vertexBuffer, ComponentDatatype.Float, 4);
}
else if (attribute.Datatype == VertexAttributeType.UnsignedByte)
{
if (attribute is VertexAttributeRGBA)
{
VertexBuffer vertexBuffer = CreateVertexBuffer(((VertexAttribute <byte>)attribute).Values, usageHint);
meshBuffers.Attributes[shaderAttribute.Location] =
new VertexBufferAttribute(vertexBuffer, ComponentDatatype.UnsignedByte, 4, true, 0, 0);
}
else if (attribute is VertexAttributeRGB)
{
VertexBuffer vertexBuffer = CreateVertexBuffer(((VertexAttribute <byte>)attribute).Values, usageHint);
meshBuffers.Attributes[shaderAttribute.Location] =
new VertexBufferAttribute(vertexBuffer, ComponentDatatype.UnsignedByte, 3, true, 0, 0);
}
else
{
VertexBuffer vertexBuffer = CreateVertexBuffer(((VertexAttribute <byte>)attribute).Values, usageHint);
meshBuffers.Attributes[shaderAttribute.Location] =
new VertexBufferAttribute(vertexBuffer, ComponentDatatype.UnsignedByte, 1);
}
}
else
{
Debug.Fail("attribute.Datatype");
}
}
return(meshBuffers);
}
public TriangleMeshTerrainTile(Context context, TerrainTile tile)
{
ShaderProgram silhouetteSP = Device.CreateShaderProgram(
EmbeddedResources.GetText("OpenGlobe.Scene.Terrain.TriangleMeshTerrainTile.SilhouetteVS.glsl"),
EmbeddedResources.GetText("OpenGlobe.Scene.Terrain.TriangleMeshTerrainTile.SilhouetteGS.glsl"),
EmbeddedResources.GetText("OpenGlobe.Scene.Terrain.TriangleMeshTerrainTile.SilhouetteFS.glsl"));
Uniform <float> fillDistance = (Uniform <float>)silhouetteSP.Uniforms["u_fillDistance"];
fillDistance.Value = 1.5f;
_silhouetteHeightExaggeration = (Uniform <float>)silhouetteSP.Uniforms["u_heightExaggeration"];
ShaderProgram sp = Device.CreateShaderProgram(
EmbeddedResources.GetText("OpenGlobe.Scene.Terrain.TriangleMeshTerrainTile.TerrainVS.glsl"),
EmbeddedResources.GetText("OpenGlobe.Scene.Terrain.TriangleMeshTerrainTile.TerrainFS.glsl"));
_tileMinimumHeight = tile.MinimumHeight;
_tileMaximumHeight = tile.MaximumHeight;
_heightExaggeration = (Uniform <float>)sp.Uniforms["u_heightExaggeration"];
_minimumHeight = (Uniform <float>)sp.Uniforms["u_minimumHeight"];
_maximumHeight = (Uniform <float>)sp.Uniforms["u_maximumHeight"];
HeightExaggeration = 1;
///////////////////////////////////////////////////////////////////
Mesh mesh = new Mesh();
mesh.PrimitiveType = PrimitiveType.Triangles;
mesh.FrontFaceWindingOrder = WindingOrder.Counterclockwise;
int numberOfPositions = tile.Resolution.X * tile.Resolution.Y;
VertexAttributeDoubleVector3 positionsAttribute = new VertexAttributeDoubleVector3("position", numberOfPositions);
IList <Vector3D> positions = positionsAttribute.Values;
mesh.Attributes.Add(positionsAttribute);
int numberOfPartitionsX = tile.Resolution.X - 1;
int numberOfPartitionsY = tile.Resolution.Y - 1;
int numberOfIndices = (numberOfPartitionsX * numberOfPartitionsY) * 6;
IndicesUnsignedInt indices = new IndicesUnsignedInt(numberOfIndices);
mesh.Indices = indices;
//
// Positions
//
Vector2D lowerLeft = tile.Extent.LowerLeft;
Vector2D toUpperRight = tile.Extent.UpperRight - lowerLeft;
int heightIndex = 0;
for (int y = 0; y <= numberOfPartitionsY; ++y)
{
double deltaY = y / (double)numberOfPartitionsY;
double currentY = lowerLeft.Y + (deltaY * toUpperRight.Y);
for (int x = 0; x <= numberOfPartitionsX; ++x)
{
double deltaX = x / (double)numberOfPartitionsX;
double currentX = lowerLeft.X + (deltaX * toUpperRight.X);
positions.Add(new Vector3D(currentX, currentY, tile.Heights[heightIndex++]));
}
}
//
// Indices
//
int rowDelta = numberOfPartitionsX + 1;
int i = 0;
for (int y = 0; y < numberOfPartitionsY; ++y)
{
for (int x = 0; x < numberOfPartitionsX; ++x)
{
indices.AddTriangle(new TriangleIndicesUnsignedInt(i, i + 1, rowDelta + (i + 1)));
indices.AddTriangle(new TriangleIndicesUnsignedInt(i, rowDelta + (i + 1), rowDelta + i));
i += 1;
}
i += 1;
}
_drawState = new DrawState();
_drawState.RenderState.FacetCulling.FrontFaceWindingOrder = mesh.FrontFaceWindingOrder;
_drawState.ShaderProgram = sp;
_drawState.VertexArray = context.CreateVertexArray(mesh, sp.VertexAttributes, BufferHint.StaticDraw);
_silhouetteDrawState = new DrawState();
_silhouetteDrawState.RenderState.FacetCulling.Enabled = false;
_silhouetteDrawState.RenderState.DepthMask = false;
_silhouetteDrawState.VertexArray = _drawState.VertexArray;
_silhouetteDrawState.ShaderProgram = silhouetteSP;
_primitiveType = mesh.PrimitiveType;
_clearColor = new ClearState();
_clearColor.Buffers = ClearBuffers.ColorBuffer;
//
// Only depth needs to be cleared but include stencil for speed.
//
_clearDepthStencil = new ClearState();
_clearDepthStencil.Buffers = ClearBuffers.DepthBuffer | ClearBuffers.StencilBuffer;
}
public PolylineShapefile(
Shapefile shapefile,
Context context,
Ellipsoid globeShape,
ShapefileAppearance appearance)
{
Verify.ThrowIfNull(shapefile);
Verify.ThrowIfNull(context);
Verify.ThrowIfNull(globeShape);
Verify.ThrowIfNull(appearance);
_polyline = new OutlinedPolylineTexture();
int positionsCount = 0;
int indicesCount = 0;
PolylineCapacities(shapefile, out positionsCount, out indicesCount);
VertexAttributeDoubleVector3 positionAttribute = new VertexAttributeDoubleVector3("position", positionsCount);
VertexAttributeRGBA colorAttribute = new VertexAttributeRGBA("color", positionsCount);
VertexAttributeRGBA outlineColorAttribute = new VertexAttributeRGBA("outlineColor", positionsCount);
IndicesUnsignedInt indices = new IndicesUnsignedInt(indicesCount);
foreach (Shape shape in shapefile)
{
if (shape.ShapeType != ShapeType.Polyline)
{
throw new NotSupportedException("The type of an individual shape does not match the Shapefile type.");
}
PolylineShape polylineShape = (PolylineShape)shape;
for (int j = 0; j < polylineShape.Count; ++j)
{
ShapePart part = polylineShape[j];
for (int i = 0; i < part.Count; ++i)
{
Vector2D point = part[i];
positionAttribute.Values.Add(globeShape.ToVector3D(Trig.ToRadians(new Geodetic3D(point.X, point.Y))));
colorAttribute.AddColor(appearance.PolylineColor);
outlineColorAttribute.AddColor(appearance.PolylineOutlineColor);
if (i != 0)
{
indices.Values.Add((uint)positionAttribute.Values.Count - 2);
indices.Values.Add((uint)positionAttribute.Values.Count - 1);
}
}
}
}
Mesh mesh = new Mesh();
mesh.PrimitiveType = PrimitiveType.Lines;
mesh.Attributes.Add(positionAttribute);
mesh.Attributes.Add(colorAttribute);
mesh.Attributes.Add(outlineColorAttribute);
mesh.Indices = indices;
_polyline.Set(context, mesh);
_polyline.Width = appearance.PolylineWidth;
_polyline.OutlineWidth = appearance.PolylineOutlineWidth;
}
public PolygonShapefile(
Shapefile shapefile,
Context context,
Ellipsoid globeShape,
ShapefileAppearance appearance)
{
Verify.ThrowIfNull(shapefile);
Verify.ThrowIfNull(context);
Verify.ThrowIfNull(globeShape);
_polyline = new OutlinedPolylineTexture();
_polygons = new List<Polygon>();
VertexAttributeDoubleVector3 positionAttribute = new VertexAttributeDoubleVector3("position");
VertexAttributeRGBA colorAttribute = new VertexAttributeRGBA("color");
VertexAttributeRGBA outlineColorAttribute = new VertexAttributeRGBA("outlineColor");
IndicesUnsignedInt indices = new IndicesUnsignedInt();
Random r = new Random(3);
IList<Vector3D> positions = new List<Vector3D>();
foreach (Shape shape in shapefile)
{
if (shape.ShapeType != ShapeType.Polygon)
{
throw new NotSupportedException("The type of an individual shape does not match the Shapefile type.");
}
PolygonShape polygonShape = (PolygonShape)shape;
for (int j = 0; j < polygonShape.Count; ++j)
{
Color color = Color.FromArgb(127, r.Next(256), r.Next(256), r.Next(256));
positions.Clear();
ShapePart part = polygonShape[j];
for (int i = 0; i < part.Count; ++i)
{
Vector2D point = part[i];
positions.Add(globeShape.ToVector3D(Trig.ToRadians(new Geodetic3D(point.X, point.Y))));
//
// For polyline
//
positionAttribute.Values.Add(globeShape.ToVector3D(Trig.ToRadians(new Geodetic3D(point.X, point.Y))));
colorAttribute.AddColor(color);
outlineColorAttribute.AddColor(Color.Black);
if (i != 0)
{
indices.Values.Add((uint)positionAttribute.Values.Count - 2);
indices.Values.Add((uint)positionAttribute.Values.Count - 1);
}
}
try
{
Polygon p = new Polygon(context, globeShape, positions);
p.Color = color;
_polygons.Add(p);
}
catch (ArgumentOutOfRangeException) // Not enough positions after cleaning
{
}
}
}
Mesh mesh = new Mesh();
mesh.PrimitiveType = PrimitiveType.Lines;
mesh.Attributes.Add(positionAttribute);
mesh.Attributes.Add(colorAttribute);
mesh.Attributes.Add(outlineColorAttribute);
mesh.Indices = indices;
_polyline.Set(context, mesh);
}
public TriangleMeshTerrainTile(Context context, TerrainTile tile)
{
ShaderProgram silhouetteSP = Device.CreateShaderProgram(
EmbeddedResources.GetText("OpenGlobe.Scene.Terrain.TriangleMeshTerrainTile.SilhouetteVS.glsl"),
EmbeddedResources.GetText("OpenGlobe.Scene.Terrain.TriangleMeshTerrainTile.SilhouetteGS.glsl"),
EmbeddedResources.GetText("OpenGlobe.Scene.Terrain.TriangleMeshTerrainTile.SilhouetteFS.glsl"));
Uniform<float> fillDistance = (Uniform<float>)silhouetteSP.Uniforms["u_fillDistance"];
fillDistance.Value = 1.5f;
_silhouetteHeightExaggeration = (Uniform<float>)silhouetteSP.Uniforms["u_heightExaggeration"];
ShaderProgram sp = Device.CreateShaderProgram(
EmbeddedResources.GetText("OpenGlobe.Scene.Terrain.TriangleMeshTerrainTile.TerrainVS.glsl"),
EmbeddedResources.GetText("OpenGlobe.Scene.Terrain.TriangleMeshTerrainTile.TerrainFS.glsl"));
_tileMinimumHeight = tile.MinimumHeight;
_tileMaximumHeight = tile.MaximumHeight;
_heightExaggeration = (Uniform<float>)sp.Uniforms["u_heightExaggeration"];
_minimumHeight = (Uniform<float>)sp.Uniforms["u_minimumHeight"];
_maximumHeight = (Uniform<float>)sp.Uniforms["u_maximumHeight"];
HeightExaggeration = 1;
///////////////////////////////////////////////////////////////////
Mesh mesh = new Mesh();
mesh.PrimitiveType = PrimitiveType.Triangles;
mesh.FrontFaceWindingOrder = WindingOrder.Counterclockwise;
int numberOfPositions = tile.Resolution.X * tile.Resolution.Y;
VertexAttributeDoubleVector3 positionsAttribute = new VertexAttributeDoubleVector3("position", numberOfPositions);
IList<Vector3D> positions = positionsAttribute.Values;
mesh.Attributes.Add(positionsAttribute);
int numberOfPartitionsX = tile.Resolution.X - 1;
int numberOfPartitionsY = tile.Resolution.Y - 1;
int numberOfIndices = (numberOfPartitionsX * numberOfPartitionsY) * 6;
IndicesUnsignedInt indices = new IndicesUnsignedInt(numberOfIndices);
mesh.Indices = indices;
//
// Positions
//
Vector2D lowerLeft = tile.Extent.LowerLeft;
Vector2D toUpperRight = tile.Extent.UpperRight - lowerLeft;
int heightIndex = 0;
for (int y = 0; y <= numberOfPartitionsY; ++y)
{
double deltaY = y / (double)numberOfPartitionsY;
double currentY = lowerLeft.Y + (deltaY * toUpperRight.Y);
for (int x = 0; x <= numberOfPartitionsX; ++x)
{
double deltaX = x / (double)numberOfPartitionsX;
double currentX = lowerLeft.X + (deltaX * toUpperRight.X);
positions.Add(new Vector3D(currentX, currentY, tile.Heights[heightIndex++]));
}
}
//
// Indices
//
int rowDelta = numberOfPartitionsX + 1;
int i = 0;
for (int y = 0; y < numberOfPartitionsY; ++y)
{
for (int x = 0; x < numberOfPartitionsX; ++x)
{
indices.AddTriangle(new TriangleIndicesUnsignedInt(i, i + 1, rowDelta + (i + 1)));
indices.AddTriangle(new TriangleIndicesUnsignedInt(i, rowDelta + (i + 1), rowDelta + i));
i += 1;
}
i += 1;
}
_drawState = new DrawState();
_drawState.RenderState.FacetCulling.FrontFaceWindingOrder = mesh.FrontFaceWindingOrder;
_drawState.ShaderProgram = sp;
_drawState.VertexArray = context.CreateVertexArray(mesh, sp.VertexAttributes, BufferHint.StaticDraw);
_silhouetteDrawState = new DrawState();
_silhouetteDrawState.RenderState.FacetCulling.Enabled = false;
_silhouetteDrawState.RenderState.DepthMask = false;
_silhouetteDrawState.VertexArray = _drawState.VertexArray;
_silhouetteDrawState.ShaderProgram = silhouetteSP;
_primitiveType = mesh.PrimitiveType;
_clearColor = new ClearState();
_clearColor.Buffers = ClearBuffers.ColorBuffer;
//
// Only depth needs to be cleared but include stencil for speed.
//
_clearDepthStencil = new ClearState();
_clearDepthStencil.Buffers = ClearBuffers.DepthBuffer | ClearBuffers.StencilBuffer;
}
public void Set(Context context, IList<Vector3D> positions)
{
//
// This method expects that the positions are ordered in a repeated pattern of
// below terrain, above terrain pairs.
//
// Wall mesh
//
Mesh wallMesh = new Mesh();
wallMesh.PrimitiveType = PrimitiveType.TriangleStrip;
//
// Positions
//
int numberOfLineSegments = (positions.Count / 2) - 1;
int numberOfVertices = 2 + numberOfLineSegments + numberOfLineSegments;
VertexAttributeDoubleVector3 positionsAttribute = new VertexAttributeDoubleVector3("position", numberOfVertices);
IList<Vector3D> tempPositions = positionsAttribute.Values;
wallMesh.Attributes.Add(positionsAttribute);
foreach (Vector3D v in positions)
{
tempPositions.Add(v);
}
//
// Vertex array
//
_wallVA = context.CreateVertexArray(wallMesh, _wallSP.VertexAttributes, BufferHint.StaticDraw);
//
// Line mesh
//
Mesh lineMesh = new Mesh();
lineMesh.PrimitiveType = PrimitiveType.LineStrip;
//
// Positions
//
positionsAttribute = new VertexAttributeDoubleVector3("position", numberOfVertices);
tempPositions = positionsAttribute.Values;
lineMesh.Attributes.Add(positionsAttribute);
foreach (Vector3D v in positions)
{
tempPositions.Add(v);
}
//
// Indices
//
int numIndices = 4 * numberOfLineSegments;
ushort[] indices = new ushort[numIndices];
int baseIndex = 1;
for (int i = 0; i < numIndices; i += 4, baseIndex += 2)
{
indices[i] = (ushort)baseIndex;
indices[i + 1] = (ushort)(baseIndex - 1);
indices[i + 2] = (ushort)(baseIndex + 1);
indices[i + 3] = (ushort)(baseIndex + 2);
}
IndexBuffer indexBuffer = Device.CreateIndexBuffer(BufferHint.StaticDraw, numIndices * sizeof(ushort));
indexBuffer.CopyFromSystemMemory(indices);
//
// Vertex array
//
_lineVA = context.CreateVertexArray(lineMesh, _wallSP.VertexAttributes, BufferHint.StaticDraw);
_lineVA.IndexBuffer = indexBuffer;
//
// State
//
_wallDrawState = new DrawState();
_wallDrawState.RenderState.FacetCulling.Enabled = false;
_wallDrawState.RenderState.DepthTest.Enabled = false;
_wallDrawState.RenderState.DepthMask = false;
_wallDrawState.VertexArray = _lineVA;
_wallDrawState.ShaderProgram = _wallSP;
_shadowVolumePassOne = new DrawState();
_shadowVolumePassOne.VertexArray = _lineVA;
_shadowVolumePassOne.ShaderProgram = _shadowVolumeSP;
_shadowVolumePassOne.RenderState.FacetCulling.Enabled = false;
_shadowVolumePassOne.RenderState.DepthMask = false;
_shadowVolumePassOne.RenderState.ColorMask = new ColorMask(false, false, false, false);
StencilTest stOne = _shadowVolumePassOne.RenderState.StencilTest;
stOne.Enabled = true;
stOne.FrontFace.DepthFailStencilPassOperation = StencilOperation.Decrement;
stOne.BackFace.DepthFailStencilPassOperation = StencilOperation.Increment;
_shadowVolumePassTwo = new DrawState();
_shadowVolumePassTwo.VertexArray = _lineVA;
_shadowVolumePassTwo.ShaderProgram = _shadowVolumeSP;
_shadowVolumePassTwo.RenderState.DepthMask = false;
StencilTest stTwo = _shadowVolumePassTwo.RenderState.StencilTest;
stTwo.Enabled = true;
stTwo.FrontFace.DepthFailStencilPassOperation = StencilOperation.Zero;
stTwo.FrontFace.DepthPassStencilPassOperation = StencilOperation.Zero;
stTwo.FrontFace.Function = StencilTestFunction.NotEqual;
stTwo.BackFace.DepthFailStencilPassOperation = StencilOperation.Zero;
stTwo.BackFace.DepthPassStencilPassOperation = StencilOperation.Zero;
stTwo.BackFace.Function = StencilTestFunction.NotEqual;
}
public Polygon(Context context, Ellipsoid globeShape, IEnumerable<Vector3D> positions)
{
Verify.ThrowIfNull(context);
Verify.ThrowIfNull(globeShape);
//
// Pipeline Stage 1a: Clean up - Remove duplicate positions
//
List<Vector3D> cleanPositions = (List<Vector3D>)SimplePolygonAlgorithms.Cleanup(positions);
//
// Pipeline Stage 1b: Clean up - Swap winding order
//
EllipsoidTangentPlane plane = new EllipsoidTangentPlane(globeShape, cleanPositions);
ICollection<Vector2D> positionsOnPlane = plane.ComputePositionsOnPlane(cleanPositions);
if (SimplePolygonAlgorithms.ComputeWindingOrder(positionsOnPlane) == PolygonWindingOrder.Clockwise)
{
cleanPositions.Reverse();
//((List<Vector2D>)positionsOnPlane).Reverse();
}
//
// Pipeline Stage 2: Triangulate
//
IndicesUnsignedInt indices = EarClippingOnEllipsoid.Triangulate(cleanPositions);
//IndicesInt32 indices = EarClipping.Triangulate(positionsOnPlane);
//
// Pipeline Stage 3: Subdivide
//
TriangleMeshSubdivisionResult result = TriangleMeshSubdivision.Compute(cleanPositions, indices, Trig.ToRadians(1));
//
// Pipeline Stage 4: Set height
//
VertexAttributeDoubleVector3 positionsAttribute = new VertexAttributeDoubleVector3(
"position", (result.Indices.Values.Count / 3) + 2);
foreach (Vector3D position in result.Positions)
{
positionsAttribute.Values.Add(globeShape.ScaleToGeocentricSurface(position));
}
Mesh mesh = new Mesh();
mesh.PrimitiveType = PrimitiveType.Triangles;
mesh.FrontFaceWindingOrder = WindingOrder.Counterclockwise;
mesh.Attributes.Add(positionsAttribute);
mesh.Indices = result.Indices;
ShaderProgram sp = Device.CreateShaderProgram(
EmbeddedResources.GetText("OpenGlobe.Scene.Renderables.Polygon.Shaders.PolygonVS.glsl"),
EmbeddedResources.GetText("OpenGlobe.Scene.Renderables.Polygon.Shaders.PolygonFS.glsl"));
((Uniform<Vector3F>)sp.Uniforms["u_globeOneOverRadiiSquared"]).Value = globeShape.OneOverRadiiSquared.ToVector3F();
_colorUniform = (Uniform<Vector4F>)sp.Uniforms["u_color"];
_drawState = new DrawState();
_drawState.RenderState.Blending.Enabled = true;
_drawState.RenderState.Blending.SourceRGBFactor = SourceBlendingFactor.SourceAlpha;
_drawState.RenderState.Blending.SourceAlphaFactor = SourceBlendingFactor.SourceAlpha;
_drawState.RenderState.Blending.DestinationRGBFactor = DestinationBlendingFactor.OneMinusSourceAlpha;
_drawState.RenderState.Blending.DestinationAlphaFactor = DestinationBlendingFactor.OneMinusSourceAlpha;
_drawState.ShaderProgram = sp;
_meshBuffers = Device.CreateMeshBuffers(mesh, _drawState.ShaderProgram.VertexAttributes, BufferHint.StaticDraw);
_primitiveType = mesh.PrimitiveType;
Color = Color.White;
}
public PolylineShapefile(
Shapefile shapefile,
Context context,
Ellipsoid globeShape,
ShapefileAppearance appearance)
{
Verify.ThrowIfNull(shapefile);
Verify.ThrowIfNull(context);
Verify.ThrowIfNull(globeShape);
Verify.ThrowIfNull(appearance);
_polyline = new OutlinedPolylineTexture();
int positionsCount = 0;
int indicesCount = 0;
PolylineCapacities(shapefile, out positionsCount, out indicesCount);
VertexAttributeDoubleVector3 positionAttribute = new VertexAttributeDoubleVector3("position", positionsCount);
VertexAttributeRGBA colorAttribute = new VertexAttributeRGBA("color", positionsCount);
VertexAttributeRGBA outlineColorAttribute = new VertexAttributeRGBA("outlineColor", positionsCount);
IndicesUnsignedInt indices = new IndicesUnsignedInt(indicesCount);
foreach (Shape shape in shapefile)
{
if (shape.ShapeType != ShapeType.Polyline)
{
throw new NotSupportedException("The type of an individual shape does not match the Shapefile type.");
}
PolylineShape polylineShape = (PolylineShape)shape;
for (int j = 0; j < polylineShape.Count; ++j)
{
ShapePart part = polylineShape[j];
for (int i = 0; i < part.Count; ++i)
{
Vector2D point = part[i];
positionAttribute.Values.Add(globeShape.ToVector3D(Trig.ToRadians(new Geodetic3D(point.X, point.Y))));
colorAttribute.AddColor(appearance.PolylineColor);
outlineColorAttribute.AddColor(appearance.PolylineOutlineColor);
if (i != 0)
{
indices.Values.Add((uint)positionAttribute.Values.Count - 2);
indices.Values.Add((uint)positionAttribute.Values.Count - 1);
}
}
}
}
Mesh mesh = new Mesh();
mesh.PrimitiveType = PrimitiveType.Lines;
mesh.Attributes.Add(positionAttribute);
mesh.Attributes.Add(colorAttribute);
mesh.Attributes.Add(outlineColorAttribute);
mesh.Indices = indices;
_polyline.Set(context, mesh);
_polyline.Width = appearance.PolylineWidth;
_polyline.OutlineWidth = appearance.PolylineOutlineWidth;
}
public void Set(Context context, IList <Vector3D> positions)
{
//
// This method expects that the positions are ordered in a repeated pattern of
// below terrain, above terrain pairs.
//
// Wall mesh
//
Mesh wallMesh = new Mesh();
wallMesh.PrimitiveType = PrimitiveType.TriangleStrip;
//
// Positions
//
int numberOfLineSegments = (positions.Count / 2) - 1;
int numberOfVertices = 2 + numberOfLineSegments + numberOfLineSegments;
VertexAttributeDoubleVector3 positionsAttribute = new VertexAttributeDoubleVector3("position", numberOfVertices);
IList <Vector3D> tempPositions = positionsAttribute.Values;
wallMesh.Attributes.Add(positionsAttribute);
foreach (Vector3D v in positions)
{
tempPositions.Add(v);
}
//
// Vertex array
//
_wallVA = context.CreateVertexArray(wallMesh, _wallSP.VertexAttributes, BufferHint.StaticDraw);
//
// Line mesh
//
Mesh lineMesh = new Mesh();
lineMesh.PrimitiveType = PrimitiveType.LineStrip;
//
// Positions
//
positionsAttribute = new VertexAttributeDoubleVector3("position", numberOfVertices);
tempPositions = positionsAttribute.Values;
lineMesh.Attributes.Add(positionsAttribute);
foreach (Vector3D v in positions)
{
tempPositions.Add(v);
}
//
// Indices
//
int numIndices = 4 * numberOfLineSegments;
ushort[] indices = new ushort[numIndices];
int baseIndex = 1;
for (int i = 0; i < numIndices; i += 4, baseIndex += 2)
{
indices[i] = (ushort)baseIndex;
indices[i + 1] = (ushort)(baseIndex - 1);
indices[i + 2] = (ushort)(baseIndex + 1);
indices[i + 3] = (ushort)(baseIndex + 2);
}
IndexBuffer indexBuffer = Device.CreateIndexBuffer(BufferHint.StaticDraw, numIndices * sizeof(ushort));
indexBuffer.CopyFromSystemMemory(indices);
//
// Vertex array
//
_lineVA = context.CreateVertexArray(lineMesh, _wallSP.VertexAttributes, BufferHint.StaticDraw);
_lineVA.IndexBuffer = indexBuffer;
//
// State
//
_wallDrawState = new DrawState();
_wallDrawState.RenderState.FacetCulling.Enabled = false;
_wallDrawState.RenderState.DepthTest.Enabled = false;
_wallDrawState.RenderState.DepthMask = false;
_wallDrawState.VertexArray = _lineVA;
_wallDrawState.ShaderProgram = _wallSP;
_shadowVolumePassOne = new DrawState();
_shadowVolumePassOne.VertexArray = _lineVA;
_shadowVolumePassOne.ShaderProgram = _shadowVolumeSP;
_shadowVolumePassOne.RenderState.FacetCulling.Enabled = false;
_shadowVolumePassOne.RenderState.DepthMask = false;
_shadowVolumePassOne.RenderState.ColorMask = new ColorMask(false, false, false, false);
StencilTest stOne = _shadowVolumePassOne.RenderState.StencilTest;
stOne.Enabled = true;
stOne.FrontFace.DepthFailStencilPassOperation = StencilOperation.Decrement;
stOne.BackFace.DepthFailStencilPassOperation = StencilOperation.Increment;
_shadowVolumePassTwo = new DrawState();
_shadowVolumePassTwo.VertexArray = _lineVA;
_shadowVolumePassTwo.ShaderProgram = _shadowVolumeSP;
_shadowVolumePassTwo.RenderState.DepthMask = false;
StencilTest stTwo = _shadowVolumePassTwo.RenderState.StencilTest;
stTwo.Enabled = true;
stTwo.FrontFace.DepthFailStencilPassOperation = StencilOperation.Zero;
stTwo.FrontFace.DepthPassStencilPassOperation = StencilOperation.Zero;
stTwo.FrontFace.Function = StencilTestFunction.NotEqual;
stTwo.BackFace.DepthFailStencilPassOperation = StencilOperation.Zero;
stTwo.BackFace.DepthPassStencilPassOperation = StencilOperation.Zero;
stTwo.BackFace.Function = StencilTestFunction.NotEqual;
}
public static Mesh Compute(Ellipsoid ellipsoid, int numberOfPartitions, CubeMapEllipsoidVertexAttributes vertexAttributes)
{
if (numberOfPartitions < 0)
{
throw new ArgumentOutOfRangeException("numberOfPartitions");
}
if ((vertexAttributes & CubeMapEllipsoidVertexAttributes.Position) != CubeMapEllipsoidVertexAttributes.Position)
{
throw new ArgumentException("Positions must be provided.", "vertexAttributes");
}
Mesh mesh = new Mesh();
mesh.PrimitiveType = PrimitiveType.Triangles;
mesh.FrontFaceWindingOrder = WindingOrder.Counterclockwise;
int numberOfVertices = NumberOfVertices(numberOfPartitions);
VertexAttributeDoubleVector3 positionsAttribute = new VertexAttributeDoubleVector3("position", numberOfVertices);
mesh.Attributes.Add(positionsAttribute);
IndicesUnsignedInt indices = new IndicesUnsignedInt(3 * NumberOfTriangles(numberOfPartitions));
mesh.Indices = indices;
CubeMapMesh CubeMapMesh = new CubeMapMesh();
CubeMapMesh.Ellipsoid = ellipsoid;
CubeMapMesh.NumberOfPartitions = numberOfPartitions;
CubeMapMesh.Positions = positionsAttribute.Values;
CubeMapMesh.Indices = indices;
if ((vertexAttributes & CubeMapEllipsoidVertexAttributes.Normal) == CubeMapEllipsoidVertexAttributes.Normal)
{
VertexAttributeHalfFloatVector3 normalsAttribute = new VertexAttributeHalfFloatVector3("normal", numberOfVertices);
mesh.Attributes.Add(normalsAttribute);
CubeMapMesh.Normals = normalsAttribute.Values;
}
if ((vertexAttributes & CubeMapEllipsoidVertexAttributes.TextureCoordinate) == CubeMapEllipsoidVertexAttributes.TextureCoordinate)
{
VertexAttributeHalfFloatVector2 textureCoordinateAttribute = new VertexAttributeHalfFloatVector2("textureCoordinate", numberOfVertices);
mesh.Attributes.Add(textureCoordinateAttribute);
CubeMapMesh.TextureCoordinate = textureCoordinateAttribute.Values;
}
//
// Initial cube. In the plane, z = -1:
//
// +y
// |
// Q2 * p3 Q1
// / | \
// p0 *--+--* p2 +x
// \ | /
// Q3 * p1 Q4
// |
//
// Similarly, p4 to p7 are in the plane z = 1.
//
CubeMapMesh.Positions.Add(new Vector3D(-1, 0, -1));
CubeMapMesh.Positions.Add(new Vector3D(0, -1, -1));
CubeMapMesh.Positions.Add(new Vector3D(1, 0, -1));
CubeMapMesh.Positions.Add(new Vector3D(0, 1, -1));
CubeMapMesh.Positions.Add(new Vector3D(-1, 0, 1));
CubeMapMesh.Positions.Add(new Vector3D(0, -1, 1));
CubeMapMesh.Positions.Add(new Vector3D(1, 0, 1));
CubeMapMesh.Positions.Add(new Vector3D(0, 1, 1));
//
// Edges
//
// 0 -> 1, 1 -> 2, 2 -> 3, 3 -> 0. Plane z = -1
// 4 -> 5, 5 -> 6, 6 -> 7, 7 -> 4. Plane z = 1
// 0 -> 4, 1 -> 5, 2 -> 6, 3 -> 7. From plane z = -1 to plane z - 1
//
int[] edge0to1 = AddEdgePositions(0, 1, CubeMapMesh);
int[] edge1to2 = AddEdgePositions(1, 2, CubeMapMesh);
int[] edge2to3 = AddEdgePositions(2, 3, CubeMapMesh);
int[] edge3to0 = AddEdgePositions(3, 0, CubeMapMesh);
int[] edge4to5 = AddEdgePositions(4, 5, CubeMapMesh);
int[] edge5to6 = AddEdgePositions(5, 6, CubeMapMesh);
int[] edge6to7 = AddEdgePositions(6, 7, CubeMapMesh);
int[] edge7to4 = AddEdgePositions(7, 4, CubeMapMesh);
int[] edge0to4 = AddEdgePositions(0, 4, CubeMapMesh);
int[] edge1to5 = AddEdgePositions(1, 5, CubeMapMesh);
int[] edge2to6 = AddEdgePositions(2, 6, CubeMapMesh);
int[] edge3to7 = AddEdgePositions(3, 7, CubeMapMesh);
AddFaceTriangles(edge0to4, edge0to1, edge1to5, edge4to5, CubeMapMesh); // Q3 Face
AddFaceTriangles(edge1to5, edge1to2, edge2to6, edge5to6, CubeMapMesh); // Q4 Face
AddFaceTriangles(edge2to6, edge2to3, edge3to7, edge6to7, CubeMapMesh); // Q1 Face
AddFaceTriangles(edge3to7, edge3to0, edge0to4, edge7to4, CubeMapMesh); // Q2 Face
AddFaceTriangles(ReversedArray(edge7to4), edge4to5, edge5to6, ReversedArray(edge6to7), CubeMapMesh); // Plane z = 1
AddFaceTriangles(edge1to2, ReversedArray(edge0to1), ReversedArray(edge3to0), edge2to3, CubeMapMesh); // Plane z = -1
CubeToEllipsoid(CubeMapMesh);
return mesh;
}
