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authorteravus2012-12-23 15:21:25 -0500
committerteravus2012-12-23 15:21:25 -0500
commit92e4f9f412046f8f7926c99c9e56c3a8b6b2edbf (patch)
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parentRevert "Whitespace change to trigger bot" (diff)
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* Initial commit of BulletSimN (BulletSNPlugin). Purely C# implementation of BulletSim. This is designed to be /as close as possible/ to the BulletSim plugin while still being entirely in the managed space to make keeping it up to date easy as possible (no thinking work). This implementation is /slower/ then the c++ version just because it's fully managed, so it's not appropriate for huge sims, but it will run small ones OK. At the moment, it supports all known features of BulletSim. Think of it like.. POS but everything works. To use this plugin, set the physics plugin to BulletSimN.
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1/*
2 * Copyright (c) Contributors, http://opensimulator.org/
3 * See CONTRIBUTORS.TXT for a full list of copyright holders.
4 *
5 * Redistribution and use in source and binary forms, with or without
6 * modification, are permitted provided that the following conditions are met:
7 * * Redistributions of source code must retain the above copyright
8 * notice, this list of conditions and the following disclaimer.
9 * * Redistributions in binary form must reproduce the above copyright
10 * notice, this list of conditions and the following disclaimer in the
11 * documentation and/or other materials provided with the distribution.
12 * * Neither the name of the OpenSimulator Project nor the
13 * names of its contributors may be used to endorse or promote products
14 * derived from this software without specific prior written permission.
15 *
16 * THIS SOFTWARE IS PROVIDED BY THE DEVELOPERS ``AS IS'' AND ANY
17 * EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED
18 * WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE
19 * DISCLAIMED. IN NO EVENT SHALL THE CONTRIBUTORS BE LIABLE FOR ANY
20 * DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES
21 * (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES;
22 * LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND
23 * ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
24 * (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS
25 * SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
26 *
27 */
28using System;
29using System.Collections.Generic;
30using System.Text;
31using OpenMetaverse;
32using OpenSim.Framework;
33
34namespace OpenSim.Region.Physics.BulletSNPlugin
35{
36public abstract class BSMotor
37{
38 // Timescales and other things can be turned off by setting them to 'infinite'.
39 public const float Infinite = 12345.6f;
40 public readonly static Vector3 InfiniteVector = new Vector3(BSMotor.Infinite, BSMotor.Infinite, BSMotor.Infinite);
41
42 public BSMotor(string useName)
43 {
44 UseName = useName;
45 PhysicsScene = null;
46 Enabled = true;
47 }
48 public virtual bool Enabled { get; set; }
49 public virtual void Reset() { }
50 public virtual void Zero() { }
51 public virtual void GenerateTestOutput(float timeStep) { }
52
53 // A name passed at motor creation for easily identifyable debugging messages.
54 public string UseName { get; private set; }
55
56 // Used only for outputting debug information. Might not be set so check for null.
57 public BSScene PhysicsScene { get; set; }
58 protected void MDetailLog(string msg, params Object[] parms)
59 {
60 if (PhysicsScene != null)
61 {
62 if (PhysicsScene.VehicleLoggingEnabled)
63 {
64 PhysicsScene.DetailLog(msg, parms);
65 }
66 }
67 }
68}
69
70// Motor which moves CurrentValue to TargetValue over TimeScale seconds.
71// The TargetValue decays in TargetValueDecayTimeScale and
72// the CurrentValue will be held back by FrictionTimeScale.
73// This motor will "zero itself" over time in that the targetValue will
74// decay to zero and the currentValue will follow it to that zero.
75// The overall effect is for the returned correction value to go from large
76// values (the total difference between current and target minus friction)
77// to small and eventually zero values.
78// TimeScale and TargetDelayTimeScale may be 'infinite' which means no decay.
79
80// For instance, if something is moving at speed X and the desired speed is Y,
81// CurrentValue is X and TargetValue is Y. As the motor is stepped, new
82// values of CurrentValue are returned that approach the TargetValue.
83// The feature of decaying TargetValue is so vehicles will eventually
84// come to a stop rather than run forever. This can be disabled by
85// setting TargetValueDecayTimescale to 'infinite'.
86// The change from CurrentValue to TargetValue is linear over TimeScale seconds.
87public class BSVMotor : BSMotor
88{
89 // public Vector3 FrameOfReference { get; set; }
90 // public Vector3 Offset { get; set; }
91
92 public virtual float TimeScale { get; set; }
93 public virtual float TargetValueDecayTimeScale { get; set; }
94 public virtual Vector3 FrictionTimescale { get; set; }
95 public virtual float Efficiency { get; set; }
96
97 public virtual float ErrorZeroThreshold { get; set; }
98
99 public virtual Vector3 TargetValue { get; protected set; }
100 public virtual Vector3 CurrentValue { get; protected set; }
101 public virtual Vector3 LastError { get; protected set; }
102
103 public virtual bool ErrorIsZero
104 { get {
105 return (LastError == Vector3.Zero || LastError.LengthSquared() <= ErrorZeroThreshold);
106 }
107 }
108
109 public BSVMotor(string useName)
110 : base(useName)
111 {
112 TimeScale = TargetValueDecayTimeScale = BSMotor.Infinite;
113 Efficiency = 1f;
114 FrictionTimescale = BSMotor.InfiniteVector;
115 CurrentValue = TargetValue = Vector3.Zero;
116 ErrorZeroThreshold = 0.001f;
117 }
118 public BSVMotor(string useName, float timeScale, float decayTimeScale, Vector3 frictionTimeScale, float efficiency)
119 : this(useName)
120 {
121 TimeScale = timeScale;
122 TargetValueDecayTimeScale = decayTimeScale;
123 FrictionTimescale = frictionTimeScale;
124 Efficiency = efficiency;
125 CurrentValue = TargetValue = Vector3.Zero;
126 }
127 public void SetCurrent(Vector3 current)
128 {
129 CurrentValue = current;
130 }
131 public void SetTarget(Vector3 target)
132 {
133 TargetValue = target;
134 }
135 public override void Zero()
136 {
137 base.Zero();
138 CurrentValue = TargetValue = Vector3.Zero;
139 }
140
141 // Compute the next step and return the new current value
142 public virtual Vector3 Step(float timeStep)
143 {
144 if (!Enabled) return TargetValue;
145
146 Vector3 origTarget = TargetValue; // DEBUG
147 Vector3 origCurrVal = CurrentValue; // DEBUG
148
149 Vector3 correction = Vector3.Zero;
150 Vector3 error = TargetValue - CurrentValue;
151 if (!error.ApproxEquals(Vector3.Zero, ErrorZeroThreshold))
152 {
153 correction = Step(timeStep, error);
154
155 CurrentValue += correction;
156
157 // The desired value reduces to zero which also reduces the difference with current.
158 // If the decay time is infinite, don't decay at all.
159 float decayFactor = 0f;
160 if (TargetValueDecayTimeScale != BSMotor.Infinite)
161 {
162 decayFactor = (1.0f / TargetValueDecayTimeScale) * timeStep;
163 TargetValue *= (1f - decayFactor);
164 }
165
166 // The amount we can correct the error is reduced by the friction
167 Vector3 frictionFactor = Vector3.Zero;
168 if (FrictionTimescale != BSMotor.InfiniteVector)
169 {
170 // frictionFactor = (Vector3.One / FrictionTimescale) * timeStep;
171 // Individual friction components can be 'infinite' so compute each separately.
172 frictionFactor.X = (FrictionTimescale.X == BSMotor.Infinite) ? 0f : (1f / FrictionTimescale.X);
173 frictionFactor.Y = (FrictionTimescale.Y == BSMotor.Infinite) ? 0f : (1f / FrictionTimescale.Y);
174 frictionFactor.Z = (FrictionTimescale.Z == BSMotor.Infinite) ? 0f : (1f / FrictionTimescale.Z);
175 frictionFactor *= timeStep;
176 CurrentValue *= (Vector3.One - frictionFactor);
177 }
178
179 MDetailLog("{0}, BSVMotor.Step,nonZero,{1},origCurr={2},origTarget={3},timeStep={4},err={5},corr={6}",
180 BSScene.DetailLogZero, UseName, origCurrVal, origTarget,
181 timeStep, error, correction);
182 MDetailLog("{0}, BSVMotor.Step,nonZero,{1},tgtDecayTS={2},decayFact={3},frictTS={4},frictFact={5},tgt={6},curr={7}",
183 BSScene.DetailLogZero, UseName,
184 TargetValueDecayTimeScale, decayFactor, FrictionTimescale, frictionFactor,
185 TargetValue, CurrentValue);
186 }
187 else
188 {
189 // Difference between what we have and target is small. Motor is done.
190 CurrentValue = TargetValue;
191 MDetailLog("{0}, BSVMotor.Step,zero,{1},origTgt={2},origCurr={3},ret={4}",
192 BSScene.DetailLogZero, UseName, origCurrVal, origTarget, CurrentValue);
193 }
194
195 return CurrentValue;
196 }
197 public virtual Vector3 Step(float timeStep, Vector3 error)
198 {
199 if (!Enabled) return Vector3.Zero;
200
201 LastError = error;
202 Vector3 returnCorrection = Vector3.Zero;
203 if (!error.ApproxEquals(Vector3.Zero, ErrorZeroThreshold))
204 {
205 // correction = error / secondsItShouldTakeToCorrect
206 Vector3 correctionAmount;
207 if (TimeScale == 0f || TimeScale == BSMotor.Infinite)
208 correctionAmount = error * timeStep;
209 else
210 correctionAmount = error / TimeScale * timeStep;
211
212 returnCorrection = correctionAmount;
213 MDetailLog("{0}, BSVMotor.Step,nonZero,{1},timeStep={2},timeScale={3},err={4},corr={5}",
214 BSScene.DetailLogZero, UseName, timeStep, TimeScale, error, correctionAmount);
215 }
216 return returnCorrection;
217 }
218
219 // The user sets all the parameters and calls this which outputs values until error is zero.
220 public override void GenerateTestOutput(float timeStep)
221 {
222 // maximum number of outputs to generate.
223 int maxOutput = 50;
224 MDetailLog("{0},BSVMotor.Test,{1},===================================== BEGIN Test Output", BSScene.DetailLogZero, UseName);
225 MDetailLog("{0},BSVMotor.Test,{1},timeScale={2},targDlyTS={3},frictTS={4},eff={5},curr={6},tgt={7}",
226 BSScene.DetailLogZero, UseName,
227 TimeScale, TargetValueDecayTimeScale, FrictionTimescale, Efficiency,
228 CurrentValue, TargetValue);
229
230 LastError = BSMotor.InfiniteVector;
231 while (maxOutput-- > 0 && !LastError.ApproxEquals(Vector3.Zero, ErrorZeroThreshold))
232 {
233 Vector3 lastStep = Step(timeStep);
234 MDetailLog("{0},BSVMotor.Test,{1},cur={2},tgt={3},lastError={4},lastStep={5}",
235 BSScene.DetailLogZero, UseName, CurrentValue, TargetValue, LastError, lastStep);
236 }
237 MDetailLog("{0},BSVMotor.Test,{1},===================================== END Test Output", BSScene.DetailLogZero, UseName);
238
239
240 }
241
242 public override string ToString()
243 {
244 return String.Format("<{0},curr={1},targ={2},decayTS={3},frictTS={4}>",
245 UseName, CurrentValue, TargetValue, TargetValueDecayTimeScale, FrictionTimescale);
246 }
247}
248
249public class BSFMotor : BSMotor
250{
251 public float TimeScale { get; set; }
252 public float DecayTimeScale { get; set; }
253 public float Friction { get; set; }
254 public float Efficiency { get; set; }
255
256 public float Target { get; private set; }
257 public float CurrentValue { get; private set; }
258
259 public BSFMotor(string useName, float timeScale, float decayTimescale, float friction, float efficiency)
260 : base(useName)
261 {
262 }
263 public void SetCurrent(float target)
264 {
265 }
266 public void SetTarget(float target)
267 {
268 }
269 public virtual float Step(float timeStep)
270 {
271 return 0f;
272 }
273}
274
275// Proportional, Integral, Derivitive Motor
276// Good description at http://www.answers.com/topic/pid-controller . Includes processes for choosing p, i and d factors.
277public class BSPIDVMotor : BSVMotor
278{
279 // Larger makes more overshoot, smaller means converge quicker. Range of 0.1 to 10.
280 public Vector3 proportionFactor { get; set; }
281 public Vector3 integralFactor { get; set; }
282 public Vector3 derivFactor { get; set; }
283
284 // Arbritrary factor range.
285 // EfficiencyHigh means move quickly to the correct number. EfficiencyLow means might over correct.
286 public float EfficiencyHigh = 0.4f;
287 public float EfficiencyLow = 4.0f;
288
289 // Running integration of the error
290 Vector3 RunningIntegration { get; set; }
291
292 public BSPIDVMotor(string useName)
293 : base(useName)
294 {
295 proportionFactor = new Vector3(1.00f, 1.00f, 1.00f);
296 integralFactor = new Vector3(1.00f, 1.00f, 1.00f);
297 derivFactor = new Vector3(1.00f, 1.00f, 1.00f);
298 RunningIntegration = Vector3.Zero;
299 LastError = Vector3.Zero;
300 }
301
302 public override void Zero()
303 {
304 base.Zero();
305 }
306
307 public override float Efficiency
308 {
309 get { return base.Efficiency; }
310 set
311 {
312 base.Efficiency = Util.Clamp(value, 0f, 1f);
313 // Compute factors based on efficiency.
314 // If efficiency is high (1f), use a factor value that moves the error value to zero with little overshoot.
315 // If efficiency is low (0f), use a factor value that overcorrects.
316 // TODO: might want to vary contribution of different factor depending on efficiency.
317 float factor = ((1f - this.Efficiency) * EfficiencyHigh + EfficiencyLow) / 3f;
318 // float factor = (1f - this.Efficiency) * EfficiencyHigh + EfficiencyLow;
319 proportionFactor = new Vector3(factor, factor, factor);
320 integralFactor = new Vector3(factor, factor, factor);
321 derivFactor = new Vector3(factor, factor, factor);
322 }
323 }
324
325 // Ignore Current and Target Values and just advance the PID computation on this error.
326 public override Vector3 Step(float timeStep, Vector3 error)
327 {
328 if (!Enabled) return Vector3.Zero;
329
330 // Add up the error so we can integrate over the accumulated errors
331 RunningIntegration += error * timeStep;
332
333 // A simple derivitive is the rate of change from the last error.
334 Vector3 derivFactor = (error - LastError) * timeStep;
335 LastError = error;
336
337 // Correction = -(proportionOfPresentError + accumulationOfPastError + rateOfChangeOfError)
338 Vector3 ret = -(
339 error * proportionFactor
340 + RunningIntegration * integralFactor
341 + derivFactor * derivFactor
342 );
343
344 return ret;
345 }
346}
347}