mattercontrol/MatterControlLib/DesignTools/Operations/CurveObject3D.cs

/*
Copyright (c) 2018, Lars Brubaker, John Lewin
All rights reserved.

Redistribution and use in source and binary forms, with or without
modification, are permitted provided that the following conditions are met:

1. Redistributions of source code must retain the above copyright notice, this
   list of conditions and the following disclaimer.
2. Redistributions in binary form must reproduce the above copyright notice,
   this list of conditions and the following disclaimer in the documentation
   and/or other materials provided with the distribution.

THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" AND
ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED
WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE
DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT OWNER OR CONTRIBUTORS BE LIABLE FOR
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(INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES;
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SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.

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*/

using System;
using System.Collections.Generic;
using System.ComponentModel;
using System.ComponentModel.DataAnnotations;
using System.Diagnostics;
using System.Linq;
using System.Threading;
using MatterHackers.Agg;
using MatterHackers.Agg.UI;
using MatterHackers.DataConverters3D;
using MatterHackers.Localizations;
using MatterHackers.MatterControl.DesignTools.Operations;
using MatterHackers.MatterControl.PartPreviewWindow;
using MatterHackers.MatterControl.PartPreviewWindow.View3D;
using MatterHackers.MeshVisualizer;
using MatterHackers.PolygonMesh;
using MatterHackers.RenderOpenGl.OpenGl;
using MatterHackers.VectorMath;

namespace MatterHackers.MatterControl.DesignTools
{
	public class CurveObject3D : MeshWrapperObject3D, IEditorDraw
	{
		public double Diameter { get; set; } = double.MinValue;

		[Range(0, 100, ErrorMessage = "Value for {0} must be between {1} and {2}.")]
		[Description("Where to start the bend as a percent of the width of the part")]
		public double StartPercent { get; set; } = 50;

		[DisplayName("Bend Up")]
		public bool BendCcw { get; set; } = true;

		// holds where we rotate the object
		Vector2 rotationCenter;
			
		public CurveObject3D()
		{
			Name = "Curve".Localize();
		}

		private void Rebuild(UndoBuffer undoBuffer)
		{
			this.DebugDepth("Rebuild");
			bool propertyUpdated = Diameter == double.MinValue;
			if (StartPercent < 0
				|| StartPercent > 100)
			{
				StartPercent = Math.Min(100, Math.Max(0, StartPercent));
				propertyUpdated = true;
			}

			using (RebuildLock())
			{
				ResetMeshWrapperMeshes(Object3DPropertyFlags.All, CancellationToken.None);

				// remember the current matrix then clear it so the parts will rotate at the original wrapped position
				var currentMatrix = Matrix;
				Matrix = Matrix4X4.Identity;

				var meshWrapperEnumerator = WrappedObjects();

				var aabb = this.GetAxisAlignedBoundingBox();

				if (Diameter == double.MinValue)
				{
					// uninitialized set to a reasonable value
					Diameter = (int)aabb.XSize;
					// TODO: ensure that the editor display value is updated
				}

				if (Diameter > 0)
				{
					var radius = Diameter / 2;
					var circumference = MathHelper.Tau * radius;
					rotationCenter = new Vector2(aabb.minXYZ.X + (aabb.maxXYZ.X - aabb.minXYZ.X) * (StartPercent / 100), aabb.maxXYZ.Y + radius);
					foreach (var object3Ds in meshWrapperEnumerator)
					{
						var matrix = object3Ds.original.WorldMatrix(this);
						var curvedMesh = object3Ds.meshCopy.Mesh;

						// split long edges so it will be curved
						if (false)
						{
							int sidesPerRotation = 30;
							double numRotations = aabb.XSize / circumference;
							double numberOfCuts = numRotations * sidesPerRotation;
							var maxXLength = aabb.XSize / numberOfCuts;

							// convert the mesh into vertex and face arrays
							double[] v;
							int[] f;
							curvedMesh.ToVerticesAndFaces(out v, out f);
							MeshHelper.Transform(v, matrix);

							// make lists so we can add to them
							var vL = new List<double>(v);
							var fL = new List<int>(f);

							var facesToRemove = new List<int>();
							// check the edge of every face
							for (int i = 0; i < fL.Count; i += 3)
							{
								// if the edge is > maxXLength
								// add a new vertex at the split
								// add two new faces
								// mark this face for removal
							}

							// convert the lists back into the mesh
						}

						if (!BendCcw)
						{
							// rotate around so it will bend correctly
							matrix *= Matrix4X4.CreateTranslation(0, -aabb.maxXYZ.Y, 0);
							matrix *= Matrix4X4.CreateRotationX(MathHelper.Tau / 2);
							matrix *= Matrix4X4.CreateTranslation(0, aabb.maxXYZ.Y - aabb.YSize, 0);
						}

						var matrixInv = matrix.Inverted;
						for (int i = 0; i < curvedMesh.Vertices.Count; i++)
						{
							var worldPosition = Vector3.Transform(curvedMesh.Vertices[i].Position, (Matrix4X4)matrix);

							var angleToRotate = ((worldPosition.X - rotationCenter.X) / circumference) * MathHelper.Tau - MathHelper.Tau / 4;
							var distanceFromCenter = rotationCenter.Y - worldPosition.Y;

							var rotatePosition = new Vector3(Math.Cos(angleToRotate), Math.Sin(angleToRotate), 0) * distanceFromCenter;
							rotatePosition.Z = worldPosition.Z;
							var worldWithBend = rotatePosition + new Vector3(rotationCenter.X, radius + aabb.maxXYZ.Y, 0);
							curvedMesh.Vertices[i].Position = Vector3.Transform(worldWithBend, matrixInv);
						}

						// the vertices need to be resorted as they have moved relative to each other
						//curvedMesh.Vertices.Sort();

						curvedMesh.MarkAsChanged();
						curvedMesh.CalculateNormals();
					}

					if (!BendCcw)
					{
						// fix the stored center so we draw correctly
						rotationCenter = new Vector2(rotationCenter.X, aabb.minXYZ.Y - radius);
					}
				}

				// set the matrix back
				Matrix = currentMatrix;
			}

			base.OnInvalidate(new InvalidateArgs(this, InvalidateType.Mesh));
			if(propertyUpdated)
			{
				base.OnInvalidate(new InvalidateArgs(this, InvalidateType.Properties));
			}
		}

		public override void OnInvalidate(InvalidateArgs invalidateType)
		{
			if ((invalidateType.InvalidateType == InvalidateType.Content
				|| invalidateType.InvalidateType == InvalidateType.Matrix
				|| invalidateType.InvalidateType == InvalidateType.Mesh)
				&& invalidateType.Source != this
				&& !RebuildLocked)
			{
				Rebuild(null);
			}
			else if (invalidateType.InvalidateType == InvalidateType.Properties
				&& invalidateType.Source == this)
			{
				Rebuild(null);
			}
			else
			{
				base.OnInvalidate(invalidateType);
			}
		}

		public void DrawEditor(object sender, DrawEventArgs e)
		{
			if (sender is InteractionLayer layer
				&& layer.Scene.SelectedItem != null
				&& layer.Scene.SelectedItem.DescendantsAndSelf().Where((i) => i == this).Any())
			{
				// we want to measure the 
				var currentMatrixInv = Matrix.Inverted;
				var aabb = this.GetAxisAlignedBoundingBox(currentMatrixInv);

				layer.World.RenderCylinderOutline(this.WorldMatrix(), new Vector3(rotationCenter, aabb.Center.Z), Diameter, aabb.ZSize, 30, Color.Red);
			}

			// turn the lighting back on
			GL.Enable(EnableCap.Lighting);
		}
	}
}