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https://github.com/fadden/6502bench.git
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b3dacc2613
There's no "standard" coordinate system, so the choice is arbitrary. However, an examination of the Transporter mesh in Elite revealed that the mesh was designed for a left-handed coordinate system. We can compensate for that trivially in the Elite visualizer, but we might as well match what they're doing. (The only change required in the code is a couple of sign changes on the Z coordinate, and an update to the rotation matrix.) This also downsizes Matrix44 to Matrix33, exposes the rotation mode enum, and adds a left-handed ZYX rotation mode. This does mean that meshes that put the front at +Z will show their backsides initially, since we're now oriented as if we're flying the ships rather than facing them. I considered adding a 180-degree Y rotation (with a tweak to the rotation matrix handedness to correct the first rotation axis) to have them facing by default, but figured that might be confusing since +Z is supposed to be away. Anybody who really wants it to be the other way can trivially flip the coordinates in their visualizer (negate xc/zc). The Z coordinates in the visualization test project were flipped so that the design is still facing the viewer at rotation (0,0,0).
163 lines
5.6 KiB
C#
163 lines
5.6 KiB
C#
/*
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* Copyright 2020 faddenSoft
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*
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* Licensed under the Apache License, Version 2.0 (the "License");
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* you may not use this file except in compliance with the License.
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* You may obtain a copy of the License at
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*
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* http://www.apache.org/licenses/LICENSE-2.0
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*
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* Unless required by applicable law or agreed to in writing, software
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* distributed under the License is distributed on an "AS IS" BASIS,
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* WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
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* See the License for the specific language governing permissions and
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* limitations under the License.
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*/
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using System;
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using System.Collections.Generic;
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using System.Text;
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namespace PluginCommon {
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/// <summary>
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/// Simple 4x4 matrix.
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/// </summary>
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public class Matrix33 {
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private const int DIM = 3;
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public double[,] Val {
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get { return mVal; }
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private set { mVal = value; }
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}
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private double[,] mVal;
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public Matrix33() {
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Val = new double[DIM, DIM];
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}
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public void Clear() {
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for (int col = 0; col < DIM; col++) {
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for (int row = 0; row < DIM; row++) {
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Val[col, row] = 0.0;
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}
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}
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}
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public void SetToIdentity() {
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Clear();
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Val[0, 0] = Val[1, 1] = Val[2, 2] = 1.0;
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}
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/// <summary>
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/// Rotation mode. Determines the order in which axes are rotated, and whether the
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/// rotation is for a right-handed or left-handed system.
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/// </summary>
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public enum RotMode { XYZ_RRR, ZYX_RRR, ZYX_LLL, ZXY_RRR };
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/// <summary>
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/// Sets the matrix to perform rotation about Euler angles X/Y/Z, with a
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/// configurable order.
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/// </summary>
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/// <param name="xdeg">Rotation about the X axis, in degrees.</param>
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/// <param name="ydeg">Rotation about the Y axis, in degrees.</param>
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/// <param name="zdeg">Rotation about the Z axis, in degrees.</param>
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public void SetRotationEuler(int xdeg, int ydeg, int zdeg, RotMode mode) {
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const double degToRad = Math.PI / 180.0;
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double xrad = xdeg * degToRad;
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double yrad = ydeg * degToRad;
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double zrad = zdeg * degToRad;
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double cx = Math.Cos(xrad);
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double sx = Math.Sin(xrad);
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double cy = Math.Cos(yrad);
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double sy = Math.Sin(yrad);
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double cz = Math.Cos(zrad);
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double sz = Math.Sin(zrad);
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double sycx = sy * cx;
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double sysx = sy * sx;
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switch (mode) {
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case RotMode.ZYX_RRR:
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// R = Rz * Ry * Rx, right-handed
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Val[0, 0] = cz * cy;
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Val[0, 1] = sz * cy;
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Val[0, 2] = -sy;
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Val[1, 0] = cz * sysx - sz * cx;
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Val[1, 1] = sz * sysx + cz * cx;
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Val[1, 2] = cy * sx;
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Val[2, 0] = cz * sycx + sz * sx;
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Val[2, 1] = sz * sycx - cz * sx;
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Val[2, 2] = cy * cx;
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break;
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case RotMode.ZYX_LLL:
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// R = Rz * Ry * Rx, left-handed
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Val[0, 0] = cz * cy;
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Val[0, 1] = -sz * cy;
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Val[0, 2] = sy;
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Val[1, 0] = cz * sysx + sz * cx;
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Val[1, 1] = -sz * sysx + cz * cx;
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Val[1, 2] = -cy * sx;
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Val[2, 0] = -cz * sycx + sz * sx;
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Val[2, 1] = sz * sycx + cz * sx;
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Val[2, 2] = cy * cx;
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break;
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case RotMode.XYZ_RRR:
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// R = Rx * Ry * Rz
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Val[0, 0] = cz * cy;
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Val[0, 1] = -sz * cy;
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Val[0, 2] = sy;
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Val[1, 0] = cz * sysx + sz * cx;
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Val[1, 1] = -sz * sysx + cz * cx;
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Val[1, 2] = -cy * sx;
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Val[2, 0] = -cz * sycx + sz * sx;
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Val[2, 1] = sz * sycx + cz * sx;
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Val[2, 2] = cy * cx;
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break;
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case RotMode.ZXY_RRR:
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// R = Rz * Rx * Ry
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double cysx = cy * sx;
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Val[0, 0] = cz * cy + sz * sysx;
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Val[0, 1] = -sz * cy + cz * sysx;
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Val[0, 2] = sy * cx;
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Val[1, 0] = sz * cx;
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Val[1, 1] = cz * cx;
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Val[1, 2] = -sx;
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Val[2, 0] = -cz * sy + sz * cysx;
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Val[2, 1] = sz * sy + cz * cysx;
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Val[2, 2] = cy * cx;
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break;
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}
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}
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/// <summary>
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/// Multiplies a 3-element vector.
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/// </summary>
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/// <param name="vec">Column vector to multiply.</param>
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/// <returns>Result vector.</returns>
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public Vector3 Multiply(Vector3 vec) {
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double rx = vec.X * Val[0, 0] + vec.Y * Val[1, 0] + vec.Z * Val[2, 0];
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double ry = vec.X * Val[0, 1] + vec.Y * Val[1, 1] + vec.Z * Val[2, 1];
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double rz = vec.X * Val[0, 2] + vec.Y * Val[1, 2] + vec.Z * Val[2, 2];
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return new Vector3(rx, ry, rz);
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}
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public override string ToString() {
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StringBuilder sb = new StringBuilder();
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for (int row = 0; row < DIM; row++) {
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sb.AppendLine();
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sb.AppendFormat("|{0,8:N3} {1,8:N3} {2,8:N3}|",
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Val[0, row], Val[1, row], Val[2, row]);
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}
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return sb.ToString();
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}
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}
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}
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